From b9cf65a08e6a59e434685e894e3189c201ac6791 Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Wed, 19 Jan 2005 22:41:26 +0000 Subject: Import of libtommath 0.33 --- libtommath/LICENSE | 4 + libtommath/TODO | 16 + libtommath/bn.ilg | 6 + libtommath/bn.ind | 82 + libtommath/bn.pdf | Bin 0 -> 335112 bytes libtommath/bn.tex | 1830 ++++ libtommath/bn_error.c | 43 + libtommath/bn_fast_mp_invmod.c | 145 + libtommath/bn_fast_mp_montgomery_reduce.c | 169 + libtommath/bn_fast_s_mp_mul_digs.c | 106 + libtommath/bn_fast_s_mp_mul_high_digs.c | 98 + libtommath/bn_fast_s_mp_sqr.c | 129 + libtommath/bn_mp_2expt.c | 44 + libtommath/bn_mp_abs.c | 39 + libtommath/bn_mp_add.c | 49 + libtommath/bn_mp_add_d.c | 105 + libtommath/bn_mp_addmod.c | 37 + libtommath/bn_mp_and.c | 53 + libtommath/bn_mp_clamp.c | 40 + libtommath/bn_mp_clear.c | 40 + libtommath/bn_mp_clear_multi.c | 30 + libtommath/bn_mp_cmp.c | 39 + libtommath/bn_mp_cmp_d.c | 40 + libtommath/bn_mp_cmp_mag.c | 51 + libtommath/bn_mp_cnt_lsb.c | 49 + libtommath/bn_mp_copy.c | 64 + libtommath/bn_mp_count_bits.c | 41 + libtommath/bn_mp_div.c | 288 + libtommath/bn_mp_div_2.c | 64 + libtommath/bn_mp_div_2d.c | 93 + libtommath/bn_mp_div_3.c | 75 + libtommath/bn_mp_div_d.c | 106 + libtommath/bn_mp_dr_is_modulus.c | 39 + libtommath/bn_mp_dr_reduce.c | 90 + libtommath/bn_mp_dr_setup.c | 28 + libtommath/bn_mp_exch.c | 30 + libtommath/bn_mp_expt_d.c | 53 + libtommath/bn_mp_exptmod.c | 100 + libtommath/bn_mp_exptmod_fast.c | 318 + libtommath/bn_mp_exteuclid.c | 71 + libtommath/bn_mp_fread.c | 63 + libtommath/bn_mp_fwrite.c | 48 + libtommath/bn_mp_gcd.c | 109 + libtommath/bn_mp_get_int.c | 41 + libtommath/bn_mp_grow.c | 53 + libtommath/bn_mp_init.c | 42 + libtommath/bn_mp_init_copy.c | 28 + libtommath/bn_mp_init_multi.c | 55 + libtommath/bn_mp_init_set.c | 28 + libtommath/bn_mp_init_set_int.c | 27 + libtommath/bn_mp_init_size.c | 44 + libtommath/bn_mp_invmod.c | 39 + libtommath/bn_mp_invmod_slow.c | 171 + libtommath/bn_mp_is_square.c | 105 + libtommath/bn_mp_jacobi.c | 101 + libtommath/bn_mp_karatsuba_mul.c | 163 + libtommath/bn_mp_karatsuba_sqr.c | 117 + libtommath/bn_mp_lcm.c | 56 + libtommath/bn_mp_lshd.c | 63 + libtommath/bn_mp_mod.c | 44 + libtommath/bn_mp_mod_2d.c | 51 + libtommath/bn_mp_mod_d.c | 23 + libtommath/bn_mp_montgomery_calc_normalization.c | 56 + libtommath/bn_mp_montgomery_reduce.c | 114 + libtommath/bn_mp_montgomery_setup.c | 55 + libtommath/bn_mp_mul.c | 62 + libtommath/bn_mp_mul_2.c | 78 + libtommath/bn_mp_mul_2d.c | 81 + libtommath/bn_mp_mul_d.c | 74 + libtommath/bn_mp_mulmod.c | 37 + libtommath/bn_mp_n_root.c | 128 + libtommath/bn_mp_neg.c | 30 + libtommath/bn_mp_or.c | 46 + libtommath/bn_mp_prime_fermat.c | 58 + libtommath/bn_mp_prime_is_divisible.c | 46 + libtommath/bn_mp_prime_is_prime.c | 79 + libtommath/bn_mp_prime_miller_rabin.c | 99 + libtommath/bn_mp_prime_next_prime.c | 166 + libtommath/bn_mp_prime_rabin_miller_trials.c | 48 + libtommath/bn_mp_prime_random_ex.c | 123 + libtommath/bn_mp_radix_size.c | 67 + libtommath/bn_mp_radix_smap.c | 20 + libtommath/bn_mp_rand.c | 51 + libtommath/bn_mp_read_radix.c | 78 + libtommath/bn_mp_read_signed_bin.c | 38 + libtommath/bn_mp_read_unsigned_bin.c | 52 + libtommath/bn_mp_reduce.c | 97 + libtommath/bn_mp_reduce_2k.c | 58 + libtommath/bn_mp_reduce_2k_l.c | 58 + libtommath/bn_mp_reduce_2k_setup.c | 44 + libtommath/bn_mp_reduce_2k_setup_l.c | 40 + libtommath/bn_mp_reduce_is_2k.c | 48 + libtommath/bn_mp_reduce_is_2k_l.c | 40 + libtommath/bn_mp_reduce_setup.c | 30 + libtommath/bn_mp_rshd.c | 68 + libtommath/bn_mp_set.c | 25 + libtommath/bn_mp_set_int.c | 44 + libtommath/bn_mp_shrink.c | 31 + libtommath/bn_mp_signed_bin_size.c | 23 + libtommath/bn_mp_sqr.c | 54 + libtommath/bn_mp_sqrmod.c | 37 + libtommath/bn_mp_sqrt.c | 77 + libtommath/bn_mp_sub.c | 55 + libtommath/bn_mp_sub_d.c | 85 + libtommath/bn_mp_submod.c | 38 + libtommath/bn_mp_to_signed_bin.c | 30 + libtommath/bn_mp_to_signed_bin_n.c | 27 + libtommath/bn_mp_to_unsigned_bin.c | 45 + libtommath/bn_mp_to_unsigned_bin_n.c | 27 + libtommath/bn_mp_toom_mul.c | 279 + libtommath/bn_mp_toom_sqr.c | 222 + libtommath/bn_mp_toradix.c | 71 + libtommath/bn_mp_toradix_n.c | 85 + libtommath/bn_mp_unsigned_bin_size.c | 25 + libtommath/bn_mp_xor.c | 47 + libtommath/bn_mp_zero.c | 26 + libtommath/bn_prime_tab.c | 57 + libtommath/bn_reverse.c | 35 + libtommath/bn_s_mp_add.c | 105 + libtommath/bn_s_mp_exptmod.c | 236 + libtommath/bn_s_mp_mul_digs.c | 87 + libtommath/bn_s_mp_mul_high_digs.c | 77 + libtommath/bn_s_mp_sqr.c | 81 + libtommath/bn_s_mp_sub.c | 85 + libtommath/bncore.c | 31 + libtommath/booker.pl | 262 + libtommath/callgraph.txt | 10193 +++++++++++++++++++ libtommath/changes.txt | 337 + libtommath/demo/demo.c | 515 + libtommath/demo/timing.c | 287 + libtommath/dep.pl | 121 + libtommath/etc/2kprime.1 | 2 + libtommath/etc/2kprime.c | 80 + libtommath/etc/drprime.c | 60 + libtommath/etc/drprimes.28 | 25 + libtommath/etc/drprimes.txt | 6 + libtommath/etc/makefile | 50 + libtommath/etc/makefile.icc | 67 + libtommath/etc/makefile.msvc | 23 + libtommath/etc/mersenne.c | 140 + libtommath/etc/mont.c | 46 + libtommath/etc/pprime.c | 396 + libtommath/etc/prime.1024 | 414 + libtommath/etc/prime.512 | 205 + libtommath/etc/timer.asm | 37 + libtommath/etc/tune.c | 107 + libtommath/gen.pl | 17 + libtommath/logs/README | 13 + libtommath/logs/add.log | 16 + libtommath/logs/addsub.png | Bin 0 -> 6254 bytes libtommath/logs/expt.log | 7 + libtommath/logs/expt.png | Bin 0 -> 6605 bytes libtommath/logs/expt_2k.log | 6 + libtommath/logs/expt_2kl.log | 4 + libtommath/logs/expt_dr.log | 7 + libtommath/logs/graphs.dem | 17 + libtommath/logs/index.html | 24 + libtommath/logs/invmod.log | 0 libtommath/logs/invmod.png | Bin 0 -> 4918 bytes libtommath/logs/mult.log | 143 + libtommath/logs/mult.png | Bin 0 -> 6770 bytes libtommath/logs/mult_kara.log | 33 + libtommath/logs/sqr.log | 143 + libtommath/logs/sqr_kara.log | 33 + libtommath/logs/sub.log | 16 + libtommath/makefile | 157 + libtommath/makefile.bcc | 42 + libtommath/makefile.cygwin_dll | 49 + libtommath/makefile.icc | 114 + libtommath/makefile.msvc | 36 + libtommath/makefile.shared | 77 + libtommath/mess.sh | 4 + libtommath/mtest/logtab.h | 20 + libtommath/mtest/mpi-config.h | 86 + libtommath/mtest/mpi-types.h | 16 + libtommath/mtest/mpi.c | 3981 ++++++++ libtommath/mtest/mpi.h | 227 + libtommath/mtest/mtest.c | 304 + libtommath/pics/design_process.sxd | Bin 0 -> 6950 bytes libtommath/pics/design_process.tif | Bin 0 -> 79042 bytes libtommath/pics/expt_state.sxd | Bin 0 -> 6869 bytes libtommath/pics/expt_state.tif | Bin 0 -> 87542 bytes libtommath/pics/makefile | 35 + libtommath/pics/primality.tif | Bin 0 -> 85514 bytes libtommath/pics/radix.sxd | Bin 0 -> 6181 bytes libtommath/pics/sliding_window.sxd | Bin 0 -> 6787 bytes libtommath/pics/sliding_window.tif | Bin 0 -> 53880 bytes libtommath/poster.out | 0 libtommath/poster.pdf | Bin 0 -> 40821 bytes libtommath/poster.tex | 35 + libtommath/pre_gen/mpi.c | 8819 +++++++++++++++++ libtommath/pretty.build | 66 + libtommath/tombc/grammar.txt | 35 + libtommath/tommath.h | 567 ++ libtommath/tommath.out | 139 + libtommath/tommath.pdf | Bin 0 -> 1159120 bytes libtommath/tommath.src | 6314 ++++++++++++ libtommath/tommath.tex | 10771 +++++++++++++++++++++ libtommath/tommath_class.h | 952 ++ libtommath/tommath_superclass.h | 72 + 200 files changed, 57261 insertions(+) create mode 100644 libtommath/LICENSE create mode 100644 libtommath/TODO create mode 100644 libtommath/bn.ilg create mode 100644 libtommath/bn.ind create mode 100644 libtommath/bn.pdf create mode 100644 libtommath/bn.tex create mode 100644 libtommath/bn_error.c create mode 100644 libtommath/bn_fast_mp_invmod.c create mode 100644 libtommath/bn_fast_mp_montgomery_reduce.c create mode 100644 libtommath/bn_fast_s_mp_mul_digs.c create mode 100644 libtommath/bn_fast_s_mp_mul_high_digs.c create mode 100644 libtommath/bn_fast_s_mp_sqr.c create mode 100644 libtommath/bn_mp_2expt.c create mode 100644 libtommath/bn_mp_abs.c create mode 100644 libtommath/bn_mp_add.c create mode 100644 libtommath/bn_mp_add_d.c create mode 100644 libtommath/bn_mp_addmod.c create mode 100644 libtommath/bn_mp_and.c create mode 100644 libtommath/bn_mp_clamp.c create mode 100644 libtommath/bn_mp_clear.c create mode 100644 libtommath/bn_mp_clear_multi.c create mode 100644 libtommath/bn_mp_cmp.c create mode 100644 libtommath/bn_mp_cmp_d.c create mode 100644 libtommath/bn_mp_cmp_mag.c create mode 100644 libtommath/bn_mp_cnt_lsb.c create mode 100644 libtommath/bn_mp_copy.c create mode 100644 libtommath/bn_mp_count_bits.c create mode 100644 libtommath/bn_mp_div.c create mode 100644 libtommath/bn_mp_div_2.c create mode 100644 libtommath/bn_mp_div_2d.c create mode 100644 libtommath/bn_mp_div_3.c create mode 100644 libtommath/bn_mp_div_d.c create mode 100644 libtommath/bn_mp_dr_is_modulus.c create mode 100644 libtommath/bn_mp_dr_reduce.c create mode 100644 libtommath/bn_mp_dr_setup.c create mode 100644 libtommath/bn_mp_exch.c create mode 100644 libtommath/bn_mp_expt_d.c create mode 100644 libtommath/bn_mp_exptmod.c create mode 100644 libtommath/bn_mp_exptmod_fast.c create mode 100644 libtommath/bn_mp_exteuclid.c create mode 100644 libtommath/bn_mp_fread.c create mode 100644 libtommath/bn_mp_fwrite.c create mode 100644 libtommath/bn_mp_gcd.c create mode 100644 libtommath/bn_mp_get_int.c create mode 100644 libtommath/bn_mp_grow.c create mode 100644 libtommath/bn_mp_init.c create mode 100644 libtommath/bn_mp_init_copy.c create mode 100644 libtommath/bn_mp_init_multi.c create mode 100644 libtommath/bn_mp_init_set.c create mode 100644 libtommath/bn_mp_init_set_int.c create mode 100644 libtommath/bn_mp_init_size.c create mode 100644 libtommath/bn_mp_invmod.c create mode 100644 libtommath/bn_mp_invmod_slow.c create mode 100644 libtommath/bn_mp_is_square.c create mode 100644 libtommath/bn_mp_jacobi.c create mode 100644 libtommath/bn_mp_karatsuba_mul.c create mode 100644 libtommath/bn_mp_karatsuba_sqr.c create mode 100644 libtommath/bn_mp_lcm.c create mode 100644 libtommath/bn_mp_lshd.c create mode 100644 libtommath/bn_mp_mod.c create mode 100644 libtommath/bn_mp_mod_2d.c create mode 100644 libtommath/bn_mp_mod_d.c create mode 100644 libtommath/bn_mp_montgomery_calc_normalization.c create mode 100644 libtommath/bn_mp_montgomery_reduce.c create mode 100644 libtommath/bn_mp_montgomery_setup.c create mode 100644 libtommath/bn_mp_mul.c create mode 100644 libtommath/bn_mp_mul_2.c create mode 100644 libtommath/bn_mp_mul_2d.c create mode 100644 libtommath/bn_mp_mul_d.c create mode 100644 libtommath/bn_mp_mulmod.c create mode 100644 libtommath/bn_mp_n_root.c create mode 100644 libtommath/bn_mp_neg.c create mode 100644 libtommath/bn_mp_or.c create mode 100644 libtommath/bn_mp_prime_fermat.c create mode 100644 libtommath/bn_mp_prime_is_divisible.c create mode 100644 libtommath/bn_mp_prime_is_prime.c create mode 100644 libtommath/bn_mp_prime_miller_rabin.c create mode 100644 libtommath/bn_mp_prime_next_prime.c create mode 100644 libtommath/bn_mp_prime_rabin_miller_trials.c create mode 100644 libtommath/bn_mp_prime_random_ex.c create mode 100644 libtommath/bn_mp_radix_size.c create mode 100644 libtommath/bn_mp_radix_smap.c create mode 100644 libtommath/bn_mp_rand.c create mode 100644 libtommath/bn_mp_read_radix.c create mode 100644 libtommath/bn_mp_read_signed_bin.c create mode 100644 libtommath/bn_mp_read_unsigned_bin.c create mode 100644 libtommath/bn_mp_reduce.c create mode 100644 libtommath/bn_mp_reduce_2k.c create mode 100644 libtommath/bn_mp_reduce_2k_l.c create mode 100644 libtommath/bn_mp_reduce_2k_setup.c create mode 100644 libtommath/bn_mp_reduce_2k_setup_l.c create mode 100644 libtommath/bn_mp_reduce_is_2k.c create mode 100644 libtommath/bn_mp_reduce_is_2k_l.c create mode 100644 libtommath/bn_mp_reduce_setup.c create mode 100644 libtommath/bn_mp_rshd.c create mode 100644 libtommath/bn_mp_set.c create mode 100644 libtommath/bn_mp_set_int.c create mode 100644 libtommath/bn_mp_shrink.c create mode 100644 libtommath/bn_mp_signed_bin_size.c create mode 100644 libtommath/bn_mp_sqr.c create mode 100644 libtommath/bn_mp_sqrmod.c create mode 100644 libtommath/bn_mp_sqrt.c create mode 100644 libtommath/bn_mp_sub.c create mode 100644 libtommath/bn_mp_sub_d.c create mode 100644 libtommath/bn_mp_submod.c create mode 100644 libtommath/bn_mp_to_signed_bin.c create mode 100644 libtommath/bn_mp_to_signed_bin_n.c create mode 100644 libtommath/bn_mp_to_unsigned_bin.c create mode 100644 libtommath/bn_mp_to_unsigned_bin_n.c create mode 100644 libtommath/bn_mp_toom_mul.c create mode 100644 libtommath/bn_mp_toom_sqr.c create mode 100644 libtommath/bn_mp_toradix.c create mode 100644 libtommath/bn_mp_toradix_n.c create mode 100644 libtommath/bn_mp_unsigned_bin_size.c create mode 100644 libtommath/bn_mp_xor.c create mode 100644 libtommath/bn_mp_zero.c create mode 100644 libtommath/bn_prime_tab.c create mode 100644 libtommath/bn_reverse.c create mode 100644 libtommath/bn_s_mp_add.c create mode 100644 libtommath/bn_s_mp_exptmod.c create mode 100644 libtommath/bn_s_mp_mul_digs.c create mode 100644 libtommath/bn_s_mp_mul_high_digs.c create mode 100644 libtommath/bn_s_mp_sqr.c create mode 100644 libtommath/bn_s_mp_sub.c create mode 100644 libtommath/bncore.c create mode 100644 libtommath/booker.pl create mode 100644 libtommath/callgraph.txt create mode 100644 libtommath/changes.txt create mode 100644 libtommath/demo/demo.c create mode 100644 libtommath/demo/timing.c create mode 100644 libtommath/dep.pl create mode 100644 libtommath/etc/2kprime.1 create mode 100644 libtommath/etc/2kprime.c create mode 100644 libtommath/etc/drprime.c create mode 100644 libtommath/etc/drprimes.28 create mode 100644 libtommath/etc/drprimes.txt create mode 100644 libtommath/etc/makefile create mode 100644 libtommath/etc/makefile.icc create mode 100644 libtommath/etc/makefile.msvc create mode 100644 libtommath/etc/mersenne.c create mode 100644 libtommath/etc/mont.c create mode 100644 libtommath/etc/pprime.c create mode 100644 libtommath/etc/prime.1024 create mode 100644 libtommath/etc/prime.512 create mode 100644 libtommath/etc/timer.asm create mode 100644 libtommath/etc/tune.c create mode 100644 libtommath/gen.pl create mode 100644 libtommath/logs/README create mode 100644 libtommath/logs/add.log create mode 100644 libtommath/logs/addsub.png create mode 100644 libtommath/logs/expt.log create mode 100644 libtommath/logs/expt.png create mode 100644 libtommath/logs/expt_2k.log create mode 100644 libtommath/logs/expt_2kl.log create mode 100644 libtommath/logs/expt_dr.log create mode 100644 libtommath/logs/graphs.dem create mode 100644 libtommath/logs/index.html create mode 100644 libtommath/logs/invmod.log create mode 100644 libtommath/logs/invmod.png create mode 100644 libtommath/logs/mult.log create mode 100644 libtommath/logs/mult.png create mode 100644 libtommath/logs/mult_kara.log create mode 100644 libtommath/logs/sqr.log create mode 100644 libtommath/logs/sqr_kara.log create mode 100644 libtommath/logs/sub.log create mode 100644 libtommath/makefile create mode 100644 libtommath/makefile.bcc create mode 100644 libtommath/makefile.cygwin_dll create mode 100644 libtommath/makefile.icc create mode 100644 libtommath/makefile.msvc create mode 100644 libtommath/makefile.shared create mode 100644 libtommath/mess.sh create mode 100644 libtommath/mtest/logtab.h create mode 100644 libtommath/mtest/mpi-config.h create mode 100644 libtommath/mtest/mpi-types.h create mode 100644 libtommath/mtest/mpi.c create mode 100644 libtommath/mtest/mpi.h create mode 100644 libtommath/mtest/mtest.c create mode 100644 libtommath/pics/design_process.sxd create mode 100644 libtommath/pics/design_process.tif create mode 100644 libtommath/pics/expt_state.sxd create mode 100644 libtommath/pics/expt_state.tif create mode 100644 libtommath/pics/makefile create mode 100644 libtommath/pics/primality.tif create mode 100644 libtommath/pics/radix.sxd create mode 100644 libtommath/pics/sliding_window.sxd create mode 100644 libtommath/pics/sliding_window.tif create mode 100644 libtommath/poster.out create mode 100644 libtommath/poster.pdf create mode 100644 libtommath/poster.tex create mode 100644 libtommath/pre_gen/mpi.c create mode 100644 libtommath/pretty.build create mode 100644 libtommath/tombc/grammar.txt create mode 100644 libtommath/tommath.h create mode 100644 libtommath/tommath.out create mode 100644 libtommath/tommath.pdf create mode 100644 libtommath/tommath.src create mode 100644 libtommath/tommath.tex create mode 100644 libtommath/tommath_class.h create mode 100644 libtommath/tommath_superclass.h diff --git a/libtommath/LICENSE b/libtommath/LICENSE new file mode 100644 index 0000000..5baa792 --- /dev/null +++ b/libtommath/LICENSE @@ -0,0 +1,4 @@ +LibTomMath is hereby released into the Public Domain. + +-- Tom St Denis + diff --git a/libtommath/TODO b/libtommath/TODO new file mode 100644 index 0000000..deffba1 --- /dev/null +++ b/libtommath/TODO @@ -0,0 +1,16 @@ +things for book in order of importance... + +- Fix up pseudo-code [only] for combas that are not consistent with source +- Start in chapter 3 [basics] and work up... + - re-write to prose [less abrupt] + - clean up pseudo code [spacing] + - more examples where appropriate and figures + +Goal: + - Get sync done by mid January [roughly 8-12 hours work] + - Finish ch3-6 by end of January [roughly 12-16 hours of work] + - Finish ch7-end by mid Feb [roughly 20-24 hours of work]. + +Goal isn't "first edition" but merely cleaner to read. + + diff --git a/libtommath/bn.ilg b/libtommath/bn.ilg new file mode 100644 index 0000000..3c859f0 --- /dev/null +++ b/libtommath/bn.ilg @@ -0,0 +1,6 @@ +This is makeindex, version 2.14 [02-Oct-2002] (kpathsea + Thai support). +Scanning input file bn.idx....done (79 entries accepted, 0 rejected). +Sorting entries....done (511 comparisons). +Generating output file bn.ind....done (82 lines written, 0 warnings). +Output written in bn.ind. +Transcript written in bn.ilg. diff --git a/libtommath/bn.ind b/libtommath/bn.ind new file mode 100644 index 0000000..e5f7d4a --- /dev/null +++ b/libtommath/bn.ind @@ -0,0 +1,82 @@ +\begin{theindex} + + \item mp\_add, \hyperpage{29} + \item mp\_add\_d, \hyperpage{52} + \item mp\_and, \hyperpage{29} + \item mp\_clear, \hyperpage{11} + \item mp\_clear\_multi, \hyperpage{12} + \item mp\_cmp, \hyperpage{24} + \item mp\_cmp\_d, \hyperpage{25} + \item mp\_cmp\_mag, \hyperpage{23} + \item mp\_div, \hyperpage{30} + \item mp\_div\_2, \hyperpage{26} + \item mp\_div\_2d, \hyperpage{28} + \item mp\_div\_d, \hyperpage{52} + \item mp\_dr\_reduce, \hyperpage{40} + \item mp\_dr\_setup, \hyperpage{40} + \item MP\_EQ, \hyperpage{22} + \item mp\_error\_to\_string, \hyperpage{10} + \item mp\_expt\_d, \hyperpage{43} + \item mp\_exptmod, \hyperpage{43} + \item mp\_exteuclid, \hyperpage{51} + \item mp\_gcd, \hyperpage{51} + \item mp\_get\_int, \hyperpage{20} + \item mp\_grow, \hyperpage{16} + \item MP\_GT, \hyperpage{22} + \item mp\_init, \hyperpage{11} + \item mp\_init\_copy, \hyperpage{13} + \item mp\_init\_multi, \hyperpage{12} + \item mp\_init\_set, \hyperpage{21} + \item mp\_init\_set\_int, \hyperpage{21} + \item mp\_init\_size, \hyperpage{14} + \item mp\_int, \hyperpage{10} + \item mp\_invmod, \hyperpage{52} + \item mp\_jacobi, \hyperpage{52} + \item mp\_lcm, \hyperpage{51} + \item mp\_lshd, \hyperpage{28} + \item MP\_LT, \hyperpage{22} + \item MP\_MEM, \hyperpage{9} + \item mp\_mod, \hyperpage{35} + \item mp\_mod\_d, \hyperpage{52} + \item mp\_montgomery\_calc\_normalization, \hyperpage{38} + \item mp\_montgomery\_reduce, \hyperpage{37} + \item mp\_montgomery\_setup, \hyperpage{37} + \item mp\_mul, \hyperpage{31} + \item mp\_mul\_2, \hyperpage{26} + \item mp\_mul\_2d, \hyperpage{28} + \item mp\_mul\_d, \hyperpage{52} + \item mp\_n\_root, \hyperpage{44} + \item mp\_neg, \hyperpage{29} + \item MP\_NO, \hyperpage{9} + \item MP\_OKAY, \hyperpage{9} + \item mp\_or, \hyperpage{29} + \item mp\_prime\_fermat, \hyperpage{45} + \item mp\_prime\_is\_divisible, \hyperpage{45} + \item mp\_prime\_is\_prime, \hyperpage{46} + \item mp\_prime\_miller\_rabin, \hyperpage{45} + \item mp\_prime\_next\_prime, \hyperpage{46} + \item mp\_prime\_rabin\_miller\_trials, \hyperpage{46} + \item mp\_prime\_random, \hyperpage{47} + \item mp\_prime\_random\_ex, \hyperpage{47} + \item mp\_radix\_size, \hyperpage{49} + \item mp\_read\_radix, \hyperpage{49} + \item mp\_read\_unsigned\_bin, \hyperpage{50} + \item mp\_reduce, \hyperpage{36} + \item mp\_reduce\_2k, \hyperpage{41} + \item mp\_reduce\_2k\_setup, \hyperpage{41} + \item mp\_reduce\_setup, \hyperpage{36} + \item mp\_rshd, \hyperpage{28} + \item mp\_set, \hyperpage{19} + \item mp\_set\_int, \hyperpage{20} + \item mp\_shrink, \hyperpage{15} + \item mp\_sqr, \hyperpage{33} + \item mp\_sub, \hyperpage{29} + \item mp\_sub\_d, \hyperpage{52} + \item mp\_to\_unsigned\_bin, \hyperpage{50} + \item mp\_toradix, \hyperpage{49} + \item mp\_unsigned\_bin\_size, \hyperpage{50} + \item MP\_VAL, \hyperpage{9} + \item mp\_xor, \hyperpage{29} + \item MP\_YES, \hyperpage{9} + +\end{theindex} diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf new file mode 100644 index 0000000..9b873e1 Binary files /dev/null and b/libtommath/bn.pdf differ diff --git a/libtommath/bn.tex b/libtommath/bn.tex new file mode 100644 index 0000000..962d6ea --- /dev/null +++ b/libtommath/bn.tex @@ -0,0 +1,1830 @@ +\documentclass[b5paper]{book} +\usepackage{hyperref} +\usepackage{makeidx} +\usepackage{amssymb} +\usepackage{color} +\usepackage{alltt} +\usepackage{graphicx} +\usepackage{layout} +\def\union{\cup} +\def\intersect{\cap} +\def\getsrandom{\stackrel{\rm R}{\gets}} +\def\cross{\times} +\def\cat{\hspace{0.5em} \| \hspace{0.5em}} +\def\catn{$\|$} +\def\divides{\hspace{0.3em} | \hspace{0.3em}} +\def\nequiv{\not\equiv} +\def\approx{\raisebox{0.2ex}{\mbox{\small $\sim$}}} +\def\lcm{{\rm lcm}} +\def\gcd{{\rm gcd}} +\def\log{{\rm log}} +\def\ord{{\rm ord}} +\def\abs{{\mathit abs}} +\def\rep{{\mathit rep}} +\def\mod{{\mathit\ mod\ }} +\renewcommand{\pmod}[1]{\ ({\rm mod\ }{#1})} +\newcommand{\floor}[1]{\left\lfloor{#1}\right\rfloor} +\newcommand{\ceil}[1]{\left\lceil{#1}\right\rceil} +\def\Or{{\rm\ or\ }} +\def\And{{\rm\ and\ }} +\def\iff{\hspace{1em}\Longleftrightarrow\hspace{1em}} +\def\implies{\Rightarrow} +\def\undefined{{\rm ``undefined"}} +\def\Proof{\vspace{1ex}\noindent {\bf Proof:}\hspace{1em}} +\let\oldphi\phi +\def\phi{\varphi} +\def\Pr{{\rm Pr}} +\newcommand{\str}[1]{{\mathbf{#1}}} +\def\F{{\mathbb F}} +\def\N{{\mathbb N}} +\def\Z{{\mathbb Z}} +\def\R{{\mathbb R}} +\def\C{{\mathbb C}} +\def\Q{{\mathbb Q}} +\definecolor{DGray}{gray}{0.5} +\newcommand{\emailaddr}[1]{\mbox{$<${#1}$>$}} +\def\twiddle{\raisebox{0.3ex}{\mbox{\tiny $\sim$}}} +\def\gap{\vspace{0.5ex}} +\makeindex +\begin{document} +\frontmatter +\pagestyle{empty} +\title{LibTomMath User Manual \\ v0.33} +\author{Tom St Denis \\ tomstdenis@iahu.ca} +\maketitle +This text, the library and the accompanying textbook are all hereby placed in the public domain. This book has been +formatted for B5 [176x250] paper using the \LaTeX{} {\em book} macro package. + +\vspace{10cm} + +\begin{flushright}Open Source. Open Academia. Open Minds. + +\mbox{ } + +Tom St Denis, + +Ontario, Canada +\end{flushright} + +\tableofcontents +\listoffigures +\mainmatter +\pagestyle{headings} +\chapter{Introduction} +\section{What is LibTomMath?} +LibTomMath is a library of source code which provides a series of efficient and carefully written functions for manipulating +large integer numbers. It was written in portable ISO C source code so that it will build on any platform with a conforming +C compiler. + +In a nutshell the library was written from scratch with verbose comments to help instruct computer science students how +to implement ``bignum'' math. However, the resulting code has proven to be very useful. It has been used by numerous +universities, commercial and open source software developers. It has been used on a variety of platforms ranging from +Linux and Windows based x86 to ARM based Gameboys and PPC based MacOS machines. + +\section{License} +As of the v0.25 the library source code has been placed in the public domain with every new release. As of the v0.28 +release the textbook ``Implementing Multiple Precision Arithmetic'' has been placed in the public domain with every new +release as well. This textbook is meant to compliment the project by providing a more solid walkthrough of the development +algorithms used in the library. + +Since both\footnote{Note that the MPI files under mtest/ are copyrighted by Michael Fromberger. They are not required to use LibTomMath.} are in the +public domain everyone is entitled to do with them as they see fit. + +\section{Building LibTomMath} + +LibTomMath is meant to be very ``GCC friendly'' as it comes with a makefile well suited for GCC. However, the library will +also build in MSVC, Borland C out of the box. For any other ISO C compiler a makefile will have to be made by the end +developer. + +\subsection{Static Libraries} +To build as a static library for GCC issue the following +\begin{alltt} +make +\end{alltt} + +command. This will build the library and archive the object files in ``libtommath.a''. Now you link against +that and include ``tommath.h'' within your programs. Alternatively to build with MSVC issue the following +\begin{alltt} +nmake -f makefile.msvc +\end{alltt} + +This will build the library and archive the object files in ``tommath.lib''. This has been tested with MSVC +version 6.00 with service pack 5. + +\subsection{Shared Libraries} +To build as a shared library for GCC issue the following +\begin{alltt} +make -f makefile.shared +\end{alltt} +This requires the ``libtool'' package (common on most Linux/BSD systems). It will build LibTomMath as both shared +and static then install (by default) into /usr/lib as well as install the header files in /usr/include. The shared +library (resource) will be called ``libtommath.la'' while the static library called ``libtommath.a''. Generally +you use libtool to link your application against the shared object. + +There is limited support for making a ``DLL'' in windows via the ``makefile.cygwin\_dll'' makefile. It requires +Cygwin to work with since it requires the auto-export/import functionality. The resulting DLL and import library +``libtommath.dll.a'' can be used to link LibTomMath dynamically to any Windows program using Cygwin. + +\subsection{Testing} +To build the library and the test harness type + +\begin{alltt} +make test +\end{alltt} + +This will build the library, ``test'' and ``mtest/mtest''. The ``test'' program will accept test vectors and verify the +results. ``mtest/mtest'' will generate test vectors using the MPI library by Michael Fromberger\footnote{A copy of MPI +is included in the package}. Simply pipe mtest into test using + +\begin{alltt} +mtest/mtest | test +\end{alltt} + +If you do not have a ``/dev/urandom'' style RNG source you will have to write your own PRNG and simply pipe that into +mtest. For example, if your PRNG program is called ``myprng'' simply invoke + +\begin{alltt} +myprng | mtest/mtest | test +\end{alltt} + +This will output a row of numbers that are increasing. Each column is a different test (such as addition, multiplication, etc) +that is being performed. The numbers represent how many times the test was invoked. If an error is detected the program +will exit with a dump of the relevent numbers it was working with. + +\section{Build Configuration} +LibTomMath can configured at build time in three phases we shall call ``depends'', ``tweaks'' and ``trims''. +Each phase changes how the library is built and they are applied one after another respectively. + +To make the system more powerful you can tweak the build process. Classes are defined in the file +``tommath\_superclass.h''. By default, the symbol ``LTM\_ALL'' shall be defined which simply +instructs the system to build all of the functions. This is how LibTomMath used to be packaged. This will give you +access to every function LibTomMath offers. + +However, there are cases where such a build is not optional. For instance, you want to perform RSA operations. You +don't need the vast majority of the library to perform these operations. Aside from LTM\_ALL there is +another pre--defined class ``SC\_RSA\_1'' which works in conjunction with the RSA from LibTomCrypt. Additional +classes can be defined base on the need of the user. + +\subsection{Build Depends} +In the file tommath\_class.h you will see a large list of C ``defines'' followed by a series of ``ifdefs'' +which further define symbols. All of the symbols (technically they're macros $\ldots$) represent a given C source +file. For instance, BN\_MP\_ADD\_C represents the file ``bn\_mp\_add.c''. When a define has been enabled the +function in the respective file will be compiled and linked into the library. Accordingly when the define +is absent the file will not be compiled and not contribute any size to the library. + +You will also note that the header tommath\_class.h is actually recursively included (it includes itself twice). +This is to help resolve as many dependencies as possible. In the last pass the symbol LTM\_LAST will be defined. +This is useful for ``trims''. + +\subsection{Build Tweaks} +A tweak is an algorithm ``alternative''. For example, to provide tradeoffs (usually between size and space). +They can be enabled at any pass of the configuration phase. + +\begin{small} +\begin{center} +\begin{tabular}{|l|l|} +\hline \textbf{Define} & \textbf{Purpose} \\ +\hline BN\_MP\_DIV\_SMALL & Enables a slower, smaller and equally \\ + & functional mp\_div() function \\ +\hline +\end{tabular} +\end{center} +\end{small} + +\subsection{Build Trims} +A trim is a manner of removing functionality from a function that is not required. For instance, to perform +RSA cryptography you only require exponentiation with odd moduli so even moduli support can be safely removed. +Build trims are meant to be defined on the last pass of the configuration which means they are to be defined +only if LTM\_LAST has been defined. + +\subsubsection{Moduli Related} +\begin{small} +\begin{center} +\begin{tabular}{|l|l|} +\hline \textbf{Restriction} & \textbf{Undefine} \\ +\hline Exponentiation with odd moduli only & BN\_S\_MP\_EXPTMOD\_C \\ + & BN\_MP\_REDUCE\_C \\ + & BN\_MP\_REDUCE\_SETUP\_C \\ + & BN\_S\_MP\_MUL\_HIGH\_DIGS\_C \\ + & BN\_FAST\_S\_MP\_MUL\_HIGH\_DIGS\_C \\ +\hline Exponentiation with random odd moduli & (The above plus the following) \\ + & BN\_MP\_REDUCE\_2K\_C \\ + & BN\_MP\_REDUCE\_2K\_SETUP\_C \\ + & BN\_MP\_REDUCE\_IS\_2K\_C \\ + & BN\_MP\_DR\_IS\_MODULUS\_C \\ + & BN\_MP\_DR\_REDUCE\_C \\ + & BN\_MP\_DR\_SETUP\_C \\ +\hline Modular inverse odd moduli only & BN\_MP\_INVMOD\_SLOW\_C \\ +\hline Modular inverse (both, smaller/slower) & BN\_FAST\_MP\_INVMOD\_C \\ +\hline +\end{tabular} +\end{center} +\end{small} + +\subsubsection{Operand Size Related} +\begin{small} +\begin{center} +\begin{tabular}{|l|l|} +\hline \textbf{Restriction} & \textbf{Undefine} \\ +\hline Moduli $\le 2560$ bits & BN\_MP\_MONTGOMERY\_REDUCE\_C \\ + & BN\_S\_MP\_MUL\_DIGS\_C \\ + & BN\_S\_MP\_MUL\_HIGH\_DIGS\_C \\ + & BN\_S\_MP\_SQR\_C \\ +\hline Polynomial Schmolynomial & BN\_MP\_KARATSUBA\_MUL\_C \\ + & BN\_MP\_KARATSUBA\_SQR\_C \\ + & BN\_MP\_TOOM\_MUL\_C \\ + & BN\_MP\_TOOM\_SQR\_C \\ + +\hline +\end{tabular} +\end{center} +\end{small} + + +\section{Purpose of LibTomMath} +Unlike GNU MP (GMP) Library, LIP, OpenSSL or various other commercial kits (Miracl), LibTomMath was not written with +bleeding edge performance in mind. First and foremost LibTomMath was written to be entirely open. Not only is the +source code public domain (unlike various other GPL/etc licensed code), not only is the code freely downloadable but the +source code is also accessible for computer science students attempting to learn ``BigNum'' or multiple precision +arithmetic techniques. + +LibTomMath was written to be an instructive collection of source code. This is why there are many comments, only one +function per source file and often I use a ``middle-road'' approach where I don't cut corners for an extra 2\% speed +increase. + +Source code alone cannot really teach how the algorithms work which is why I also wrote a textbook that accompanies +the library (beat that!). + +So you may be thinking ``should I use LibTomMath?'' and the answer is a definite maybe. Let me tabulate what I think +are the pros and cons of LibTomMath by comparing it to the math routines from GnuPG\footnote{GnuPG v1.2.3 versus LibTomMath v0.28}. + +\newpage\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|l|c|c|l|} +\hline \textbf{Criteria} & \textbf{Pro} & \textbf{Con} & \textbf{Notes} \\ +\hline Few lines of code per file & X & & GnuPG $ = 300.9$, LibTomMath $ = 76.04$ \\ +\hline Commented function prototypes & X && GnuPG function names are cryptic. \\ +\hline Speed && X & LibTomMath is slower. \\ +\hline Totally free & X & & GPL has unfavourable restrictions.\\ +\hline Large function base & X & & GnuPG is barebones. \\ +\hline Four modular reduction algorithms & X & & Faster modular exponentiation. \\ +\hline Portable & X & & GnuPG requires configuration to build. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{LibTomMath Valuation} +\end{figure} + +It may seem odd to compare LibTomMath to GnuPG since the math in GnuPG is only a small portion of the entire application. +However, LibTomMath was written with cryptography in mind. It provides essentially all of the functions a cryptosystem +would require when working with large integers. + +So it may feel tempting to just rip the math code out of GnuPG (or GnuMP where it was taken from originally) in your +own application but I think there are reasons not to. While LibTomMath is slower than libraries such as GnuMP it is +not normally significantly slower. On x86 machines the difference is normally a factor of two when performing modular +exponentiations. + +Essentially the only time you wouldn't use LibTomMath is when blazing speed is the primary concern. + +\chapter{Getting Started with LibTomMath} +\section{Building Programs} +In order to use LibTomMath you must include ``tommath.h'' and link against the appropriate library file (typically +libtommath.a). There is no library initialization required and the entire library is thread safe. + +\section{Return Codes} +There are three possible return codes a function may return. + +\index{MP\_OKAY}\index{MP\_YES}\index{MP\_NO}\index{MP\_VAL}\index{MP\_MEM} +\begin{figure}[here!] +\begin{center} +\begin{small} +\begin{tabular}{|l|l|} +\hline \textbf{Code} & \textbf{Meaning} \\ +\hline MP\_OKAY & The function succeeded. \\ +\hline MP\_VAL & The function input was invalid. \\ +\hline MP\_MEM & Heap memory exhausted. \\ +\hline &\\ +\hline MP\_YES & Response is yes. \\ +\hline MP\_NO & Response is no. \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Return Codes} +\end{figure} + +The last two codes listed are not actually ``return'ed'' by a function. They are placed in an integer (the caller must +provide the address of an integer it can store to) which the caller can access. To convert one of the three return codes +to a string use the following function. + +\index{mp\_error\_to\_string} +\begin{alltt} +char *mp_error_to_string(int code); +\end{alltt} + +This will return a pointer to a string which describes the given error code. It will not work for the return codes +MP\_YES and MP\_NO. + +\section{Data Types} +The basic ``multiple precision integer'' type is known as the ``mp\_int'' within LibTomMath. This data type is used to +organize all of the data required to manipulate the integer it represents. Within LibTomMath it has been prototyped +as the following. + +\index{mp\_int} +\begin{alltt} +typedef struct \{ + int used, alloc, sign; + mp_digit *dp; +\} mp_int; +\end{alltt} + +Where ``mp\_digit'' is a data type that represents individual digits of the integer. By default, an mp\_digit is the +ISO C ``unsigned long'' data type and each digit is $28-$bits long. The mp\_digit type can be configured to suit other +platforms by defining the appropriate macros. + +All LTM functions that use the mp\_int type will expect a pointer to mp\_int structure. You must allocate memory to +hold the structure itself by yourself (whether off stack or heap it doesn't matter). The very first thing that must be +done to use an mp\_int is that it must be initialized. + +\section{Function Organization} + +The arithmetic functions of the library are all organized to have the same style prototype. That is source operands +are passed on the left and the destination is on the right. For instance, + +\begin{alltt} +mp_add(&a, &b, &c); /* c = a + b */ +mp_mul(&a, &a, &c); /* c = a * a */ +mp_div(&a, &b, &c, &d); /* c = [a/b], d = a mod b */ +\end{alltt} + +Another feature of the way the functions have been implemented is that source operands can be destination operands as well. +For instance, + +\begin{alltt} +mp_add(&a, &b, &b); /* b = a + b */ +mp_div(&a, &b, &a, &c); /* a = [a/b], c = a mod b */ +\end{alltt} + +This allows operands to be re-used which can make programming simpler. + +\section{Initialization} +\subsection{Single Initialization} +A single mp\_int can be initialized with the ``mp\_init'' function. + +\index{mp\_init} +\begin{alltt} +int mp_init (mp_int * a); +\end{alltt} + +This function expects a pointer to an mp\_int structure and will initialize the members of the structure so the mp\_int +represents the default integer which is zero. If the functions returns MP\_OKAY then the mp\_int is ready to be used +by the other LibTomMath functions. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the number */ + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\subsection{Single Free} +When you are finished with an mp\_int it is ideal to return the heap it used back to the system. The following function +provides this functionality. + +\index{mp\_clear} +\begin{alltt} +void mp_clear (mp_int * a); +\end{alltt} + +The function expects a pointer to a previously initialized mp\_int structure and frees the heap it uses. It sets the +pointer\footnote{The ``dp'' member.} within the mp\_int to \textbf{NULL} which is used to prevent double free situations. +Is is legal to call mp\_clear() twice on the same mp\_int in a row. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the number */ + + /* We're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\subsection{Multiple Initializations} +Certain algorithms require more than one large integer. In these instances it is ideal to initialize all of the mp\_int +variables in an ``all or nothing'' fashion. That is, they are either all initialized successfully or they are all +not initialized. + +The mp\_init\_multi() function provides this functionality. + +\index{mp\_init\_multi} \index{mp\_clear\_multi} +\begin{alltt} +int mp_init_multi(mp_int *mp, ...); +\end{alltt} + +It accepts a \textbf{NULL} terminated list of pointers to mp\_int structures. It will attempt to initialize them all +at once. If the function returns MP\_OKAY then all of the mp\_int variables are ready to use, otherwise none of them +are available for use. A complementary mp\_clear\_multi() function allows multiple mp\_int variables to be free'd +from the heap at the same time. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int num1, num2, num3; + int result; + + if ((result = mp_init_multi(&num1, + &num2, + &num3, NULL)) != MP\_OKAY) \{ + printf("Error initializing the numbers. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the numbers */ + + /* We're done with them. */ + mp_clear_multi(&num1, &num2, &num3, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\subsection{Other Initializers} +To initialized and make a copy of an mp\_int the mp\_init\_copy() function has been provided. + +\index{mp\_init\_copy} +\begin{alltt} +int mp_init_copy (mp_int * a, mp_int * b); +\end{alltt} + +This function will initialize $a$ and make it a copy of $b$ if all goes well. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int num1, num2; + int result; + + /* initialize and do work on num1 ... */ + + /* We want a copy of num1 in num2 now */ + if ((result = mp_init_copy(&num2, &num1)) != MP_OKAY) \{ + printf("Error initializing the copy. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now num2 is ready and contains a copy of num1 */ + + /* We're done with them. */ + mp_clear_multi(&num1, &num2, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +Another less common initializer is mp\_init\_size() which allows the user to initialize an mp\_int with a given +default number of digits. By default, all initializers allocate \textbf{MP\_PREC} digits. This function lets +you override this behaviour. + +\index{mp\_init\_size} +\begin{alltt} +int mp_init_size (mp_int * a, int size); +\end{alltt} + +The $size$ parameter must be greater than zero. If the function succeeds the mp\_int $a$ will be initialized +to have $size$ digits (which are all initially zero). + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + /* we need a 60-digit number */ + if ((result = mp_init_size(&number, 60)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the number */ + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\section{Maintenance Functions} + +\subsection{Reducing Memory Usage} +When an mp\_int is in a state where it won't be changed again\footnote{A Diffie-Hellman modulus for instance.} excess +digits can be removed to return memory to the heap with the mp\_shrink() function. + +\index{mp\_shrink} +\begin{alltt} +int mp_shrink (mp_int * a); +\end{alltt} + +This will remove excess digits of the mp\_int $a$. If the operation fails the mp\_int should be intact without the +excess digits being removed. Note that you can use a shrunk mp\_int in further computations, however, such operations +will require heap operations which can be slow. It is not ideal to shrink mp\_int variables that you will further +modify in the system (unless you are seriously low on memory). + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the number [e.g. pre-computation] */ + + /* We're done with it for now. */ + if ((result = mp_shrink(&number)) != MP_OKAY) \{ + printf("Error shrinking the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use it .... */ + + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\subsection{Adding additional digits} + +Within the mp\_int structure are two parameters which control the limitations of the array of digits that represent +the integer the mp\_int is meant to equal. The \textit{used} parameter dictates how many digits are significant, that is, +contribute to the value of the mp\_int. The \textit{alloc} parameter dictates how many digits are currently available in +the array. If you need to perform an operation that requires more digits you will have to mp\_grow() the mp\_int to +your desired size. + +\index{mp\_grow} +\begin{alltt} +int mp_grow (mp_int * a, int size); +\end{alltt} + +This will grow the array of digits of $a$ to $size$. If the \textit{alloc} parameter is already bigger than +$size$ the function will not do anything. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* use the number */ + + /* We need to add 20 digits to the number */ + if ((result = mp_grow(&number, number.alloc + 20)) != MP_OKAY) \{ + printf("Error growing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + + /* use the number */ + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\chapter{Basic Operations} +\section{Small Constants} +Setting mp\_ints to small constants is a relatively common operation. To accomodate these instances there are two +small constant assignment functions. The first function is used to set a single digit constant while the second sets +an ISO C style ``unsigned long'' constant. The reason for both functions is efficiency. Setting a single digit is quick but the +domain of a digit can change (it's always at least $0 \ldots 127$). + +\subsection{Single Digit} + +Setting a single digit can be accomplished with the following function. + +\index{mp\_set} +\begin{alltt} +void mp_set (mp_int * a, mp_digit b); +\end{alltt} + +This will zero the contents of $a$ and make it represent an integer equal to the value of $b$. Note that this +function has a return type of \textbf{void}. It cannot cause an error so it is safe to assume the function +succeeded. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number to 5 */ + mp_set(&number, 5); + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +\subsection{Long Constants} + +To set a constant that is the size of an ISO C ``unsigned long'' and larger than a single digit the following function +can be used. + +\index{mp\_set\_int} +\begin{alltt} +int mp_set_int (mp_int * a, unsigned long b); +\end{alltt} + +This will assign the value of the 32-bit variable $b$ to the mp\_int $a$. Unlike mp\_set() this function will always +accept a 32-bit input regardless of the size of a single digit. However, since the value may span several digits +this function can fail if it runs out of heap memory. + +To get the ``unsigned long'' copy of an mp\_int the following function can be used. + +\index{mp\_get\_int} +\begin{alltt} +unsigned long mp_get_int (mp_int * a); +\end{alltt} + +This will return the 32 least significant bits of the mp\_int $a$. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number to 654321 (note this is bigger than 127) */ + if ((result = mp_set_int(&number, 654321)) != MP_OKAY) \{ + printf("Error setting the value of the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + printf("number == \%lu", mp_get_int(&number)); + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +This should output the following if the program succeeds. + +\begin{alltt} +number == 654321 +\end{alltt} + +\subsection{Initialize and Setting Constants} +To both initialize and set small constants the following two functions are available. +\index{mp\_init\_set} \index{mp\_init\_set\_int} +\begin{alltt} +int mp_init_set (mp_int * a, mp_digit b); +int mp_init_set_int (mp_int * a, unsigned long b); +\end{alltt} + +Both functions work like the previous counterparts except they first mp\_init $a$ before setting the values. + +\begin{alltt} +int main(void) +\{ + mp_int number1, number2; + int result; + + /* initialize and set a single digit */ + if ((result = mp_init_set(&number1, 100)) != MP_OKAY) \{ + printf("Error setting number1: \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* initialize and set a long */ + if ((result = mp_init_set_int(&number2, 1023)) != MP_OKAY) \{ + printf("Error setting number2: \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* display */ + printf("Number1, Number2 == \%lu, \%lu", + mp_get_int(&number1), mp_get_int(&number2)); + + /* clear */ + mp_clear_multi(&number1, &number2, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} + +If this program succeeds it shall output. +\begin{alltt} +Number1, Number2 == 100, 1023 +\end{alltt} + +\section{Comparisons} + +Comparisons in LibTomMath are always performed in a ``left to right'' fashion. There are three possible return codes +for any comparison. + +\index{MP\_GT} \index{MP\_EQ} \index{MP\_LT} +\begin{figure}[here] +\begin{center} +\begin{tabular}{|c|c|} +\hline \textbf{Result Code} & \textbf{Meaning} \\ +\hline MP\_GT & $a > b$ \\ +\hline MP\_EQ & $a = b$ \\ +\hline MP\_LT & $a < b$ \\ +\hline +\end{tabular} +\end{center} +\caption{Comparison Codes for $a, b$} +\label{fig:CMP} +\end{figure} + +In figure \ref{fig:CMP} two integers $a$ and $b$ are being compared. In this case $a$ is said to be ``to the left'' of +$b$. + +\subsection{Unsigned comparison} + +An unsigned comparison considers only the digits themselves and not the associated \textit{sign} flag of the +mp\_int structures. This is analogous to an absolute comparison. The function mp\_cmp\_mag() will compare two +mp\_int variables based on their digits only. + +\index{mp\_cmp\_mag} +\begin{alltt} +int mp_cmp(mp_int * a, mp_int * b); +\end{alltt} +This will compare $a$ to $b$ placing $a$ to the left of $b$. This function cannot fail and will return one of the +three compare codes listed in figure \ref{fig:CMP}. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number1, number2; + int result; + + if ((result = mp_init_multi(&number1, &number2, NULL)) != MP_OKAY) \{ + printf("Error initializing the numbers. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number1 to 5 */ + mp_set(&number1, 5); + + /* set the number2 to -6 */ + mp_set(&number2, 6); + if ((result = mp_neg(&number2, &number2)) != MP_OKAY) \{ + printf("Error negating number2. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + switch(mp_cmp_mag(&number1, &number2)) \{ + case MP_GT: printf("|number1| > |number2|"); break; + case MP_EQ: printf("|number1| = |number2|"); break; + case MP_LT: printf("|number1| < |number2|"); break; + \} + + /* we're done with it. */ + mp_clear_multi(&number1, &number2, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +If this program\footnote{This function uses the mp\_neg() function which is discussed in section \ref{sec:NEG}.} completes +successfully it should print the following. + +\begin{alltt} +|number1| < |number2| +\end{alltt} + +This is because $\vert -6 \vert = 6$ and obviously $5 < 6$. + +\subsection{Signed comparison} + +To compare two mp\_int variables based on their signed value the mp\_cmp() function is provided. + +\index{mp\_cmp} +\begin{alltt} +int mp_cmp(mp_int * a, mp_int * b); +\end{alltt} + +This will compare $a$ to the left of $b$. It will first compare the signs of the two mp\_int variables. If they +differ it will return immediately based on their signs. If the signs are equal then it will compare the digits +individually. This function will return one of the compare conditions codes listed in figure \ref{fig:CMP}. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number1, number2; + int result; + + if ((result = mp_init_multi(&number1, &number2, NULL)) != MP_OKAY) \{ + printf("Error initializing the numbers. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number1 to 5 */ + mp_set(&number1, 5); + + /* set the number2 to -6 */ + mp_set(&number2, 6); + if ((result = mp_neg(&number2, &number2)) != MP_OKAY) \{ + printf("Error negating number2. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + switch(mp_cmp(&number1, &number2)) \{ + case MP_GT: printf("number1 > number2"); break; + case MP_EQ: printf("number1 = number2"); break; + case MP_LT: printf("number1 < number2"); break; + \} + + /* we're done with it. */ + mp_clear_multi(&number1, &number2, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +If this program\footnote{This function uses the mp\_neg() function which is discussed in section \ref{sec:NEG}.} completes +successfully it should print the following. + +\begin{alltt} +number1 > number2 +\end{alltt} + +\subsection{Single Digit} + +To compare a single digit against an mp\_int the following function has been provided. + +\index{mp\_cmp\_d} +\begin{alltt} +int mp_cmp_d(mp_int * a, mp_digit b); +\end{alltt} + +This will compare $a$ to the left of $b$ using a signed comparison. Note that it will always treat $b$ as +positive. This function is rather handy when you have to compare against small values such as $1$ (which often +comes up in cryptography). The function cannot fail and will return one of the tree compare condition codes +listed in figure \ref{fig:CMP}. + + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number to 5 */ + mp_set(&number, 5); + + switch(mp_cmp_d(&number, 7)) \{ + case MP_GT: printf("number > 7"); break; + case MP_EQ: printf("number = 7"); break; + case MP_LT: printf("number < 7"); break; + \} + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +If this program functions properly it will print out the following. + +\begin{alltt} +number < 7 +\end{alltt} + +\section{Logical Operations} + +Logical operations are operations that can be performed either with simple shifts or boolean operators such as +AND, XOR and OR directly. These operations are very quick. + +\subsection{Multiplication by two} + +Multiplications and divisions by any power of two can be performed with quick logical shifts either left or +right depending on the operation. + +When multiplying or dividing by two a special case routine can be used which are as follows. +\index{mp\_mul\_2} \index{mp\_div\_2} +\begin{alltt} +int mp_mul_2(mp_int * a, mp_int * b); +int mp_div_2(mp_int * a, mp_int * b); +\end{alltt} + +The former will assign twice $a$ to $b$ while the latter will assign half $a$ to $b$. These functions are fast +since the shift counts and maskes are hardcoded into the routines. + +\begin{small} \begin{alltt} +int main(void) +\{ + mp_int number; + int result; + + if ((result = mp_init(&number)) != MP_OKAY) \{ + printf("Error initializing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the number to 5 */ + mp_set(&number, 5); + + /* multiply by two */ + if ((result = mp\_mul\_2(&number, &number)) != MP_OKAY) \{ + printf("Error multiplying the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + switch(mp_cmp_d(&number, 7)) \{ + case MP_GT: printf("2*number > 7"); break; + case MP_EQ: printf("2*number = 7"); break; + case MP_LT: printf("2*number < 7"); break; + \} + + /* now divide by two */ + if ((result = mp\_div\_2(&number, &number)) != MP_OKAY) \{ + printf("Error dividing the number. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + switch(mp_cmp_d(&number, 7)) \{ + case MP_GT: printf("2*number/2 > 7"); break; + case MP_EQ: printf("2*number/2 = 7"); break; + case MP_LT: printf("2*number/2 < 7"); break; + \} + + /* we're done with it. */ + mp_clear(&number); + + return EXIT_SUCCESS; +\} +\end{alltt} \end{small} + +If this program is successful it will print out the following text. + +\begin{alltt} +2*number > 7 +2*number/2 < 7 +\end{alltt} + +Since $10 > 7$ and $5 < 7$. To multiply by a power of two the following function can be used. + +\index{mp\_mul\_2d} +\begin{alltt} +int mp_mul_2d(mp_int * a, int b, mp_int * c); +\end{alltt} + +This will multiply $a$ by $2^b$ and store the result in ``c''. If the value of $b$ is less than or equal to +zero the function will copy $a$ to ``c'' without performing any further actions. + +To divide by a power of two use the following. + +\index{mp\_div\_2d} +\begin{alltt} +int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d); +\end{alltt} +Which will divide $a$ by $2^b$, store the quotient in ``c'' and the remainder in ``d'. If $b \le 0$ then the +function simply copies $a$ over to ``c'' and zeroes $d$. The variable $d$ may be passed as a \textbf{NULL} +value to signal that the remainder is not desired. + +\subsection{Polynomial Basis Operations} + +Strictly speaking the organization of the integers within the mp\_int structures is what is known as a +``polynomial basis''. This simply means a field element is stored by divisions of a radix. For example, if +$f(x) = \sum_{i=0}^{k} y_ix^k$ for any vector $\vec y$ then the array of digits in $\vec y$ are said to be +the polynomial basis representation of $z$ if $f(\beta) = z$ for a given radix $\beta$. + +To multiply by the polynomial $g(x) = x$ all you have todo is shift the digits of the basis left one place. The +following function provides this operation. + +\index{mp\_lshd} +\begin{alltt} +int mp_lshd (mp_int * a, int b); +\end{alltt} + +This will multiply $a$ in place by $x^b$ which is equivalent to shifting the digits left $b$ places and inserting zeroes +in the least significant digits. Similarly to divide by a power of $x$ the following function is provided. + +\index{mp\_rshd} +\begin{alltt} +void mp_rshd (mp_int * a, int b) +\end{alltt} +This will divide $a$ in place by $x^b$ and discard the remainder. This function cannot fail as it performs the operations +in place and no new digits are required to complete it. + +\subsection{AND, OR and XOR Operations} + +While AND, OR and XOR operations are not typical ``bignum functions'' they can be useful in several instances. The +three functions are prototyped as follows. + +\index{mp\_or} \index{mp\_and} \index{mp\_xor} +\begin{alltt} +int mp_or (mp_int * a, mp_int * b, mp_int * c); +int mp_and (mp_int * a, mp_int * b, mp_int * c); +int mp_xor (mp_int * a, mp_int * b, mp_int * c); +\end{alltt} + +Which compute $c = a \odot b$ where $\odot$ is one of OR, AND or XOR. + +\section{Addition and Subtraction} + +To compute an addition or subtraction the following two functions can be used. + +\index{mp\_add} \index{mp\_sub} +\begin{alltt} +int mp_add (mp_int * a, mp_int * b, mp_int * c); +int mp_sub (mp_int * a, mp_int * b, mp_int * c) +\end{alltt} + +Which perform $c = a \odot b$ where $\odot$ is one of signed addition or subtraction. The operations are fully sign +aware. + +\section{Sign Manipulation} +\subsection{Negation} +\label{sec:NEG} +Simple integer negation can be performed with the following. + +\index{mp\_neg} +\begin{alltt} +int mp_neg (mp_int * a, mp_int * b); +\end{alltt} + +Which assigns $-a$ to $b$. + +\subsection{Absolute} +Simple integer absolutes can be performed with the following. + +\index{mp\_neg} +\begin{alltt} +int mp_abs (mp_int * a, mp_int * b); +\end{alltt} + +Which assigns $\vert a \vert$ to $b$. + +\section{Integer Division and Remainder} +To perform a complete and general integer division with remainder use the following function. + +\index{mp\_div} +\begin{alltt} +int mp_div (mp_int * a, mp_int * b, mp_int * c, mp_int * d); +\end{alltt} + +This divides $a$ by $b$ and stores the quotient in $c$ and $d$. The signed quotient is computed such that +$bc + d = a$. Note that either of $c$ or $d$ can be set to \textbf{NULL} if their value is not required. If +$b$ is zero the function returns \textbf{MP\_VAL}. + + +\chapter{Multiplication and Squaring} +\section{Multiplication} +A full signed integer multiplication can be performed with the following. +\index{mp\_mul} +\begin{alltt} +int mp_mul (mp_int * a, mp_int * b, mp_int * c); +\end{alltt} +Which assigns the full signed product $ab$ to $c$. This function actually breaks into one of four cases which are +specific multiplication routines optimized for given parameters. First there are the Toom-Cook multiplications which +should only be used with very large inputs. This is followed by the Karatsuba multiplications which are for moderate +sized inputs. Then followed by the Comba and baseline multipliers. + +Fortunately for the developer you don't really need to know this unless you really want to fine tune the system. mp\_mul() +will determine on its own\footnote{Some tweaking may be required.} what routine to use automatically when it is called. + +\begin{alltt} +int main(void) +\{ + mp_int number1, number2; + int result; + + /* Initialize the numbers */ + if ((result = mp_init_multi(&number1, + &number2, NULL)) != MP_OKAY) \{ + printf("Error initializing the numbers. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* set the terms */ + if ((result = mp_set_int(&number, 257)) != MP_OKAY) \{ + printf("Error setting number1. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + if ((result = mp_set_int(&number2, 1023)) != MP_OKAY) \{ + printf("Error setting number2. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* multiply them */ + if ((result = mp_mul(&number1, &number2, + &number1)) != MP_OKAY) \{ + printf("Error multiplying terms. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* display */ + printf("number1 * number2 == \%lu", mp_get_int(&number1)); + + /* free terms and return */ + mp_clear_multi(&number1, &number2, NULL); + + return EXIT_SUCCESS; +\} +\end{alltt} + +If this program succeeds it shall output the following. + +\begin{alltt} +number1 * number2 == 262911 +\end{alltt} + +\section{Squaring} +Since squaring can be performed faster than multiplication it is performed it's own function instead of just using +mp\_mul(). + +\index{mp\_sqr} +\begin{alltt} +int mp_sqr (mp_int * a, mp_int * b); +\end{alltt} + +Will square $a$ and store it in $b$. Like the case of multiplication there are four different squaring +algorithms all which can be called from mp\_sqr(). It is ideal to use mp\_sqr over mp\_mul when squaring terms. + +\section{Tuning Polynomial Basis Routines} + +Both of the Toom-Cook and Karatsuba multiplication algorithms are faster than the traditional $O(n^2)$ approach that +the Comba and baseline algorithms use. At $O(n^{1.464973})$ and $O(n^{1.584962})$ running times respectfully they require +considerably less work. For example, a 10000-digit multiplication would take roughly 724,000 single precision +multiplications with Toom-Cook or 100,000,000 single precision multiplications with the standard Comba (a factor +of 138). + +So why not always use Karatsuba or Toom-Cook? The simple answer is that they have so much overhead that they're not +actually faster than Comba until you hit distinct ``cutoff'' points. For Karatsuba with the default configuration, +GCC 3.3.1 and an Athlon XP processor the cutoff point is roughly 110 digits (about 70 for the Intel P4). That is, at +110 digits Karatsuba and Comba multiplications just about break even and for 110+ digits Karatsuba is faster. + +Toom-Cook has incredible overhead and is probably only useful for very large inputs. So far no known cutoff points +exist and for the most part I just set the cutoff points very high to make sure they're not called. + +A demo program in the ``etc/'' directory of the project called ``tune.c'' can be used to find the cutoff points. This +can be built with GCC as follows + +\begin{alltt} +make XXX +\end{alltt} +Where ``XXX'' is one of the following entries from the table \ref{fig:tuning}. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|l|l|} +\hline \textbf{Value of XXX} & \textbf{Meaning} \\ +\hline tune & Builds portable tuning application \\ +\hline tune86 & Builds x86 (pentium and up) program for COFF \\ +\hline tune86c & Builds x86 program for Cygwin \\ +\hline tune86l & Builds x86 program for Linux (ELF format) \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Build Names for Tuning Programs} +\label{fig:tuning} +\end{figure} + +When the program is running it will output a series of measurements for different cutoff points. It will first find +good Karatsuba squaring and multiplication points. Then it proceeds to find Toom-Cook points. Note that the Toom-Cook +tuning takes a very long time as the cutoff points are likely to be very high. + +\chapter{Modular Reduction} + +Modular reduction is process of taking the remainder of one quantity divided by another. Expressed +as (\ref{eqn:mod}) the modular reduction is equivalent to the remainder of $b$ divided by $c$. + +\begin{equation} +a \equiv b \mbox{ (mod }c\mbox{)} +\label{eqn:mod} +\end{equation} + +Of particular interest to cryptography are reductions where $b$ is limited to the range $0 \le b < c^2$ since particularly +fast reduction algorithms can be written for the limited range. + +Note that one of the four optimized reduction algorithms are automatically chosen in the modular exponentiation +algorithm mp\_exptmod when an appropriate modulus is detected. + +\section{Straight Division} +In order to effect an arbitrary modular reduction the following algorithm is provided. + +\index{mp\_mod} +\begin{alltt} +int mp_mod(mp_int *a, mp_int *b, mp_int *c); +\end{alltt} + +This reduces $a$ modulo $b$ and stores the result in $c$. The sign of $c$ shall agree with the sign +of $b$. This algorithm accepts an input $a$ of any range and is not limited by $0 \le a < b^2$. + +\section{Barrett Reduction} + +Barrett reduction is a generic optimized reduction algorithm that requires pre--computation to achieve +a decent speedup over straight division. First a $mu$ value must be precomputed with the following function. + +\index{mp\_reduce\_setup} +\begin{alltt} +int mp_reduce_setup(mp_int *a, mp_int *b); +\end{alltt} + +Given a modulus in $b$ this produces the required $mu$ value in $a$. For any given modulus this only has to +be computed once. Modular reduction can now be performed with the following. + +\index{mp\_reduce} +\begin{alltt} +int mp_reduce(mp_int *a, mp_int *b, mp_int *c); +\end{alltt} + +This will reduce $a$ in place modulo $b$ with the precomputed $mu$ value in $c$. $a$ must be in the range +$0 \le a < b^2$. + +\begin{alltt} +int main(void) +\{ + mp_int a, b, c, mu; + int result; + + /* initialize a,b to desired values, mp_init mu, + * c and set c to 1...we want to compute a^3 mod b + */ + + /* get mu value */ + if ((result = mp_reduce_setup(&mu, b)) != MP_OKAY) \{ + printf("Error getting mu. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* square a to get c = a^2 */ + if ((result = mp_sqr(&a, &c)) != MP_OKAY) \{ + printf("Error squaring. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now reduce `c' modulo b */ + if ((result = mp_reduce(&c, &b, &mu)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* multiply a to get c = a^3 */ + if ((result = mp_mul(&a, &c, &c)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now reduce `c' modulo b */ + if ((result = mp_reduce(&c, &b, &mu)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* c now equals a^3 mod b */ + + return EXIT_SUCCESS; +\} +\end{alltt} + +This program will calculate $a^3 \mbox{ mod }b$ if all the functions succeed. + +\section{Montgomery Reduction} + +Montgomery is a specialized reduction algorithm for any odd moduli. Like Barrett reduction a pre--computation +step is required. This is accomplished with the following. + +\index{mp\_montgomery\_setup} +\begin{alltt} +int mp_montgomery_setup(mp_int *a, mp_digit *mp); +\end{alltt} + +For the given odd moduli $a$ the precomputation value is placed in $mp$. The reduction is computed with the +following. + +\index{mp\_montgomery\_reduce} +\begin{alltt} +int mp_montgomery_reduce(mp_int *a, mp_int *m, mp_digit mp); +\end{alltt} +This reduces $a$ in place modulo $m$ with the pre--computed value $mp$. $a$ must be in the range +$0 \le a < b^2$. + +Montgomery reduction is faster than Barrett reduction for moduli smaller than the ``comba'' limit. With the default +setup for instance, the limit is $127$ digits ($3556$--bits). Note that this function is not limited to +$127$ digits just that it falls back to a baseline algorithm after that point. + +An important observation is that this reduction does not return $a \mbox{ mod }m$ but $aR^{-1} \mbox{ mod }m$ +where $R = \beta^n$, $n$ is the n number of digits in $m$ and $\beta$ is radix used (default is $2^{28}$). + +To quickly calculate $R$ the following function was provided. + +\index{mp\_montgomery\_calc\_normalization} +\begin{alltt} +int mp_montgomery_calc_normalization(mp_int *a, mp_int *b); +\end{alltt} +Which calculates $a = R$ for the odd moduli $b$ without using multiplication or division. + +The normal modus operandi for Montgomery reductions is to normalize the integers before entering the system. For +example, to calculate $a^3 \mbox { mod }b$ using Montgomery reduction the value of $a$ can be normalized by +multiplying it by $R$. Consider the following code snippet. + +\begin{alltt} +int main(void) +\{ + mp_int a, b, c, R; + mp_digit mp; + int result; + + /* initialize a,b to desired values, + * mp_init R, c and set c to 1.... + */ + + /* get normalization */ + if ((result = mp_montgomery_calc_normalization(&R, b)) != MP_OKAY) \{ + printf("Error getting norm. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* get mp value */ + if ((result = mp_montgomery_setup(&c, &mp)) != MP_OKAY) \{ + printf("Error setting up montgomery. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* normalize `a' so now a is equal to aR */ + if ((result = mp_mulmod(&a, &R, &b, &a)) != MP_OKAY) \{ + printf("Error computing aR. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* square a to get c = a^2R^2 */ + if ((result = mp_sqr(&a, &c)) != MP_OKAY) \{ + printf("Error squaring. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now reduce `c' back down to c = a^2R^2 * R^-1 == a^2R */ + if ((result = mp_montgomery_reduce(&c, &b, mp)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* multiply a to get c = a^3R^2 */ + if ((result = mp_mul(&a, &c, &c)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now reduce `c' back down to c = a^3R^2 * R^-1 == a^3R */ + if ((result = mp_montgomery_reduce(&c, &b, mp)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* now reduce (again) `c' back down to c = a^3R * R^-1 == a^3 */ + if ((result = mp_montgomery_reduce(&c, &b, mp)) != MP_OKAY) \{ + printf("Error reducing. \%s", + mp_error_to_string(result)); + return EXIT_FAILURE; + \} + + /* c now equals a^3 mod b */ + + return EXIT_SUCCESS; +\} +\end{alltt} + +This particular example does not look too efficient but it demonstrates the point of the algorithm. By +normalizing the inputs the reduced results are always of the form $aR$ for some variable $a$. This allows +a single final reduction to correct for the normalization and the fast reduction used within the algorithm. + +For more details consider examining the file \textit{bn\_mp\_exptmod\_fast.c}. + +\section{Restricted Dimminished Radix} + +``Dimminished Radix'' reduction refers to reduction with respect to moduli that are ameniable to simple +digit shifting and small multiplications. In this case the ``restricted'' variant refers to moduli of the +form $\beta^k - p$ for some $k \ge 0$ and $0 < p < \beta$ where $\beta$ is the radix (default to $2^{28}$). + +As in the case of Montgomery reduction there is a pre--computation phase required for a given modulus. + +\index{mp\_dr\_setup} +\begin{alltt} +void mp_dr_setup(mp_int *a, mp_digit *d); +\end{alltt} + +This computes the value required for the modulus $a$ and stores it in $d$. This function cannot fail +and does not return any error codes. After the pre--computation a reduction can be performed with the +following. + +\index{mp\_dr\_reduce} +\begin{alltt} +int mp_dr_reduce(mp_int *a, mp_int *b, mp_digit mp); +\end{alltt} + +This reduces $a$ in place modulo $b$ with the pre--computed value $mp$. $b$ must be of a restricted +dimminished radix form and $a$ must be in the range $0 \le a < b^2$. Dimminished radix reductions are +much faster than both Barrett and Montgomery reductions as they have a much lower asymtotic running time. + +Since the moduli are restricted this algorithm is not particularly useful for something like Rabin, RSA or +BBS cryptographic purposes. This reduction algorithm is useful for Diffie-Hellman and ECC where fixed +primes are acceptable. + +Note that unlike Montgomery reduction there is no normalization process. The result of this function is +equal to the correct residue. + +\section{Unrestricted Dimminshed Radix} + +Unrestricted reductions work much like the restricted counterparts except in this case the moduli is of the +form $2^k - p$ for $0 < p < \beta$. In this sense the unrestricted reductions are more flexible as they +can be applied to a wider range of numbers. + +\index{mp\_reduce\_2k\_setup} +\begin{alltt} +int mp_reduce_2k_setup(mp_int *a, mp_digit *d); +\end{alltt} + +This will compute the required $d$ value for the given moduli $a$. + +\index{mp\_reduce\_2k} +\begin{alltt} +int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d); +\end{alltt} + +This will reduce $a$ in place modulo $n$ with the pre--computed value $d$. From my experience this routine is +slower than mp\_dr\_reduce but faster for most moduli sizes than the Montgomery reduction. + +\chapter{Exponentiation} +\section{Single Digit Exponentiation} +\index{mp\_expt\_d} +\begin{alltt} +int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) +\end{alltt} +This computes $c = a^b$ using a simple binary left-to-right algorithm. It is faster than repeated multiplications by +$a$ for all values of $b$ greater than three. + +\section{Modular Exponentiation} +\index{mp\_exptmod} +\begin{alltt} +int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +\end{alltt} +This computes $Y \equiv G^X \mbox{ (mod }P\mbox{)}$ using a variable width sliding window algorithm. This function +will automatically detect the fastest modular reduction technique to use during the operation. For negative values of +$X$ the operation is performed as $Y \equiv (G^{-1} \mbox{ mod }P)^{\vert X \vert} \mbox{ (mod }P\mbox{)}$ provided that +$gcd(G, P) = 1$. + +This function is actually a shell around the two internal exponentiation functions. This routine will automatically +detect when Barrett, Montgomery, Restricted and Unrestricted Dimminished Radix based exponentiation can be used. Generally +moduli of the a ``restricted dimminished radix'' form lead to the fastest modular exponentiations. Followed by Montgomery +and the other two algorithms. + +\section{Root Finding} +\index{mp\_n\_root} +\begin{alltt} +int mp_n_root (mp_int * a, mp_digit b, mp_int * c) +\end{alltt} +This computes $c = a^{1/b}$ such that $c^b \le a$ and $(c+1)^b > a$. The implementation of this function is not +ideal for values of $b$ greater than three. It will work but become very slow. So unless you are working with very small +numbers (less than 1000 bits) I'd avoid $b > 3$ situations. Will return a positive root only for even roots and return +a root with the sign of the input for odd roots. For example, performing $4^{1/2}$ will return $2$ whereas $(-8)^{1/3}$ +will return $-2$. + +This algorithm uses the ``Newton Approximation'' method and will converge on the correct root fairly quickly. Since +the algorithm requires raising $a$ to the power of $b$ it is not ideal to attempt to find roots for large +values of $b$. If particularly large roots are required then a factor method could be used instead. For example, +$a^{1/16}$ is equivalent to $\left (a^{1/4} \right)^{1/4}$. + +\chapter{Prime Numbers} +\section{Trial Division} +\index{mp\_prime\_is\_divisible} +\begin{alltt} +int mp_prime_is_divisible (mp_int * a, int *result) +\end{alltt} +This will attempt to evenly divide $a$ by a list of primes\footnote{Default is the first 256 primes.} and store the +outcome in ``result''. That is if $result = 0$ then $a$ is not divisible by the primes, otherwise it is. Note that +if the function does not return \textbf{MP\_OKAY} the value in ``result'' should be considered undefined\footnote{Currently +the default is to set it to zero first.}. + +\section{Fermat Test} +\index{mp\_prime\_fermat} +\begin{alltt} +int mp_prime_fermat (mp_int * a, mp_int * b, int *result) +\end{alltt} +Performs a Fermat primality test to the base $b$. That is it computes $b^a \mbox{ mod }a$ and tests whether the value is +equal to $b$ or not. If the values are equal then $a$ is probably prime and $result$ is set to one. Otherwise $result$ +is set to zero. + +\section{Miller-Rabin Test} +\index{mp\_prime\_miller\_rabin} +\begin{alltt} +int mp_prime_miller_rabin (mp_int * a, mp_int * b, int *result) +\end{alltt} +Performs a Miller-Rabin test to the base $b$ of $a$. This test is much stronger than the Fermat test and is very hard to +fool (besides with Carmichael numbers). If $a$ passes the test (therefore is probably prime) $result$ is set to one. +Otherwise $result$ is set to zero. + +Note that is suggested that you use the Miller-Rabin test instead of the Fermat test since all of the failures of +Miller-Rabin are a subset of the failures of the Fermat test. + +\subsection{Required Number of Tests} +Generally to ensure a number is very likely to be prime you have to perform the Miller-Rabin with at least a half-dozen +or so unique bases. However, it has been proven that the probability of failure goes down as the size of the input goes up. +This is why a simple function has been provided to help out. + +\index{mp\_prime\_rabin\_miller\_trials} +\begin{alltt} +int mp_prime_rabin_miller_trials(int size) +\end{alltt} +This returns the number of trials required for a $2^{-96}$ (or lower) probability of failure for a given ``size'' expressed +in bits. This comes in handy specially since larger numbers are slower to test. For example, a 512-bit number would +require ten tests whereas a 1024-bit number would only require four tests. + +You should always still perform a trial division before a Miller-Rabin test though. + +\section{Primality Testing} +\index{mp\_prime\_is\_prime} +\begin{alltt} +int mp_prime_is_prime (mp_int * a, int t, int *result) +\end{alltt} +This will perform a trial division followed by $t$ rounds of Miller-Rabin tests on $a$ and store the result in $result$. +If $a$ passes all of the tests $result$ is set to one, otherwise it is set to zero. Note that $t$ is bounded by +$1 \le t < PRIME\_SIZE$ where $PRIME\_SIZE$ is the number of primes in the prime number table (by default this is $256$). + +\section{Next Prime} +\index{mp\_prime\_next\_prime} +\begin{alltt} +int mp_prime_next_prime(mp_int *a, int t, int bbs_style) +\end{alltt} +This finds the next prime after $a$ that passes mp\_prime\_is\_prime() with $t$ tests. Set $bbs\_style$ to one if you +want only the next prime congruent to $3 \mbox{ mod } 4$, otherwise set it to zero to find any next prime. + +\section{Random Primes} +\index{mp\_prime\_random} +\begin{alltt} +int mp_prime_random(mp_int *a, int t, int size, int bbs, + ltm_prime_callback cb, void *dat) +\end{alltt} +This will find a prime greater than $256^{size}$ which can be ``bbs\_style'' or not depending on $bbs$ and must pass +$t$ rounds of tests. The ``ltm\_prime\_callback'' is a typedef for + +\begin{alltt} +typedef int ltm_prime_callback(unsigned char *dst, int len, void *dat); +\end{alltt} + +Which is a function that must read $len$ bytes (and return the amount stored) into $dst$. The $dat$ variable is simply +copied from the original input. It can be used to pass RNG context data to the callback. The function +mp\_prime\_random() is more suitable for generating primes which must be secret (as in the case of RSA) since there +is no skew on the least significant bits. + +\textit{Note:} As of v0.30 of the LibTomMath library this function has been deprecated. It is still available +but users are encouraged to use the new mp\_prime\_random\_ex() function instead. + +\subsection{Extended Generation} +\index{mp\_prime\_random\_ex} +\begin{alltt} +int mp_prime_random_ex(mp_int *a, int t, + int size, int flags, + ltm_prime_callback cb, void *dat); +\end{alltt} +This will generate a prime in $a$ using $t$ tests of the primality testing algorithms. The variable $size$ +specifies the bit length of the prime desired. The variable $flags$ specifies one of several options available +(see fig. \ref{fig:primeopts}) which can be OR'ed together. The callback parameters are used as in +mp\_prime\_random(). + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|r|l|} +\hline \textbf{Flag} & \textbf{Meaning} \\ +\hline LTM\_PRIME\_BBS & Make the prime congruent to $3$ modulo $4$ \\ +\hline LTM\_PRIME\_SAFE & Make a prime $p$ such that $(p - 1)/2$ is also prime. \\ + & This option implies LTM\_PRIME\_BBS as well. \\ +\hline LTM\_PRIME\_2MSB\_OFF & Makes sure that the bit adjacent to the most significant bit \\ + & Is forced to zero. \\ +\hline LTM\_PRIME\_2MSB\_ON & Makes sure that the bit adjacent to the most significant bit \\ + & Is forced to one. \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Primality Generation Options} +\label{fig:primeopts} +\end{figure} + +\chapter{Input and Output} +\section{ASCII Conversions} +\subsection{To ASCII} +\index{mp\_toradix} +\begin{alltt} +int mp_toradix (mp_int * a, char *str, int radix); +\end{alltt} +This still store $a$ in ``str'' as a base-``radix'' string of ASCII chars. This function appends a NUL character +to terminate the string. Valid values of ``radix'' line in the range $[2, 64]$. To determine the size (exact) required +by the conversion before storing any data use the following function. + +\index{mp\_radix\_size} +\begin{alltt} +int mp_radix_size (mp_int * a, int radix, int *size) +\end{alltt} +This stores in ``size'' the number of characters (including space for the NUL terminator) required. Upon error this +function returns an error code and ``size'' will be zero. + +\subsection{From ASCII} +\index{mp\_read\_radix} +\begin{alltt} +int mp_read_radix (mp_int * a, char *str, int radix); +\end{alltt} +This will read the base-``radix'' NUL terminated string from ``str'' into $a$. It will stop reading when it reads a +character it does not recognize (which happens to include th NUL char... imagine that...). A single leading $-$ sign +can be used to denote a negative number. + +\section{Binary Conversions} + +Converting an mp\_int to and from binary is another keen idea. + +\index{mp\_unsigned\_bin\_size} +\begin{alltt} +int mp_unsigned_bin_size(mp_int *a); +\end{alltt} + +This will return the number of bytes (octets) required to store the unsigned copy of the integer $a$. + +\index{mp\_to\_unsigned\_bin} +\begin{alltt} +int mp_to_unsigned_bin(mp_int *a, unsigned char *b); +\end{alltt} +This will store $a$ into the buffer $b$ in big--endian format. Fortunately this is exactly what DER (or is it ASN?) +requires. It does not store the sign of the integer. + +\index{mp\_read\_unsigned\_bin} +\begin{alltt} +int mp_read_unsigned_bin(mp_int *a, unsigned char *b, int c); +\end{alltt} +This will read in an unsigned big--endian array of bytes (octets) from $b$ of length $c$ into $a$. The resulting +integer $a$ will always be positive. + +For those who acknowledge the existence of negative numbers (heretic!) there are ``signed'' versions of the +previous functions. + +\begin{alltt} +int mp_signed_bin_size(mp_int *a); +int mp_read_signed_bin(mp_int *a, unsigned char *b, int c); +int mp_to_signed_bin(mp_int *a, unsigned char *b); +\end{alltt} +They operate essentially the same as the unsigned copies except they prefix the data with zero or non--zero +byte depending on the sign. If the sign is zpos (e.g. not negative) the prefix is zero, otherwise the prefix +is non--zero. + +\chapter{Algebraic Functions} +\section{Extended Euclidean Algorithm} +\index{mp\_exteuclid} +\begin{alltt} +int mp_exteuclid(mp_int *a, mp_int *b, + mp_int *U1, mp_int *U2, mp_int *U3); +\end{alltt} + +This finds the triple U1/U2/U3 using the Extended Euclidean algorithm such that the following equation holds. + +\begin{equation} +a \cdot U1 + b \cdot U2 = U3 +\end{equation} + +Any of the U1/U2/U3 paramters can be set to \textbf{NULL} if they are not desired. + +\section{Greatest Common Divisor} +\index{mp\_gcd} +\begin{alltt} +int mp_gcd (mp_int * a, mp_int * b, mp_int * c) +\end{alltt} +This will compute the greatest common divisor of $a$ and $b$ and store it in $c$. + +\section{Least Common Multiple} +\index{mp\_lcm} +\begin{alltt} +int mp_lcm (mp_int * a, mp_int * b, mp_int * c) +\end{alltt} +This will compute the least common multiple of $a$ and $b$ and store it in $c$. + +\section{Jacobi Symbol} +\index{mp\_jacobi} +\begin{alltt} +int mp_jacobi (mp_int * a, mp_int * p, int *c) +\end{alltt} +This will compute the Jacobi symbol for $a$ with respect to $p$. If $p$ is prime this essentially computes the Legendre +symbol. The result is stored in $c$ and can take on one of three values $\lbrace -1, 0, 1 \rbrace$. If $p$ is prime +then the result will be $-1$ when $a$ is not a quadratic residue modulo $p$. The result will be $0$ if $a$ divides $p$ +and the result will be $1$ if $a$ is a quadratic residue modulo $p$. + +\section{Modular Inverse} +\index{mp\_invmod} +\begin{alltt} +int mp_invmod (mp_int * a, mp_int * b, mp_int * c) +\end{alltt} +Computes the multiplicative inverse of $a$ modulo $b$ and stores the result in $c$ such that $ac \equiv 1 \mbox{ (mod }b\mbox{)}$. + +\section{Single Digit Functions} + +For those using small numbers (\textit{snicker snicker}) there are several ``helper'' functions + +\index{mp\_add\_d} \index{mp\_sub\_d} \index{mp\_mul\_d} \index{mp\_div\_d} \index{mp\_mod\_d} +\begin{alltt} +int mp_add_d(mp_int *a, mp_digit b, mp_int *c); +int mp_sub_d(mp_int *a, mp_digit b, mp_int *c); +int mp_mul_d(mp_int *a, mp_digit b, mp_int *c); +int mp_div_d(mp_int *a, mp_digit b, mp_int *c, mp_digit *d); +int mp_mod_d(mp_int *a, mp_digit b, mp_digit *c); +\end{alltt} + +These work like the full mp\_int capable variants except the second parameter $b$ is a mp\_digit. These +functions fairly handy if you have to work with relatively small numbers since you will not have to allocate +an entire mp\_int to store a number like $1$ or $2$. + +\input{bn.ind} + +\end{document} diff --git a/libtommath/bn_error.c b/libtommath/bn_error.c new file mode 100644 index 0000000..1546784 --- /dev/null +++ b/libtommath/bn_error.c @@ -0,0 +1,43 @@ +#include +#ifdef BN_ERROR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static const struct { + int code; + char *msg; +} msgs[] = { + { MP_OKAY, "Successful" }, + { MP_MEM, "Out of heap" }, + { MP_VAL, "Value out of range" } +}; + +/* return a char * string for a given code */ +char *mp_error_to_string(int code) +{ + int x; + + /* scan the lookup table for the given message */ + for (x = 0; x < (int)(sizeof(msgs) / sizeof(msgs[0])); x++) { + if (msgs[x].code == code) { + return msgs[x].msg; + } + } + + /* generic reply for invalid code */ + return "Invalid error code"; +} + +#endif diff --git a/libtommath/bn_fast_mp_invmod.c b/libtommath/bn_fast_mp_invmod.c new file mode 100644 index 0000000..b5b9f10 --- /dev/null +++ b/libtommath/bn_fast_mp_invmod.c @@ -0,0 +1,145 @@ +#include +#ifdef BN_FAST_MP_INVMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes the modular inverse via binary extended euclidean algorithm, + * that is c = 1/a mod b + * + * Based on slow invmod except this is optimized for the case where b is + * odd as per HAC Note 14.64 on pp. 610 + */ +int +fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x, y, u, v, B, D; + int res, neg; + + /* 2. [modified] b must be odd */ + if (mp_iseven (b) == 1) { + return MP_VAL; + } + + /* init all our temps */ + if ((res = mp_init_multi(&x, &y, &u, &v, &B, &D, NULL)) != MP_OKAY) { + return res; + } + + /* x == modulus, y == value to invert */ + if ((res = mp_copy (b, &x)) != MP_OKAY) { + goto LBL_ERR; + } + + /* we need y = |a| */ + if ((res = mp_abs (a, &y)) != MP_OKAY) { + goto LBL_ERR; + } + + /* 3. u=x, v=y, A=1, B=0, C=0,D=1 */ + if ((res = mp_copy (&x, &u)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (&y, &v)) != MP_OKAY) { + goto LBL_ERR; + } + mp_set (&D, 1); + +top: + /* 4. while u is even do */ + while (mp_iseven (&u) == 1) { + /* 4.1 u = u/2 */ + if ((res = mp_div_2 (&u, &u)) != MP_OKAY) { + goto LBL_ERR; + } + /* 4.2 if B is odd then */ + if (mp_isodd (&B) == 1) { + if ((res = mp_sub (&B, &x, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* B = B/2 */ + if ((res = mp_div_2 (&B, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 5. while v is even do */ + while (mp_iseven (&v) == 1) { + /* 5.1 v = v/2 */ + if ((res = mp_div_2 (&v, &v)) != MP_OKAY) { + goto LBL_ERR; + } + /* 5.2 if D is odd then */ + if (mp_isodd (&D) == 1) { + /* D = (D-x)/2 */ + if ((res = mp_sub (&D, &x, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* D = D/2 */ + if ((res = mp_div_2 (&D, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 6. if u >= v then */ + if (mp_cmp (&u, &v) != MP_LT) { + /* u = u - v, B = B - D */ + if ((res = mp_sub (&u, &v, &u)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&B, &D, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } else { + /* v - v - u, D = D - B */ + if ((res = mp_sub (&v, &u, &v)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&D, &B, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* if not zero goto step 4 */ + if (mp_iszero (&u) == 0) { + goto top; + } + + /* now a = C, b = D, gcd == g*v */ + + /* if v != 1 then there is no inverse */ + if (mp_cmp_d (&v, 1) != MP_EQ) { + res = MP_VAL; + goto LBL_ERR; + } + + /* b is now the inverse */ + neg = a->sign; + while (D.sign == MP_NEG) { + if ((res = mp_add (&D, b, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + mp_exch (&D, c); + c->sign = neg; + res = MP_OKAY; + +LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); + return res; +} +#endif diff --git a/libtommath/bn_fast_mp_montgomery_reduce.c b/libtommath/bn_fast_mp_montgomery_reduce.c new file mode 100644 index 0000000..7373ae6 --- /dev/null +++ b/libtommath/bn_fast_mp_montgomery_reduce.c @@ -0,0 +1,169 @@ +#include +#ifdef BN_FAST_MP_MONTGOMERY_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes xR**-1 == x (mod N) via Montgomery Reduction + * + * This is an optimized implementation of montgomery_reduce + * which uses the comba method to quickly calculate the columns of the + * reduction. + * + * Based on Algorithm 14.32 on pp.601 of HAC. +*/ +int +fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +{ + int ix, res, olduse; + mp_word W[MP_WARRAY]; + + /* get old used count */ + olduse = x->used; + + /* grow a as required */ + if (x->alloc < n->used + 1) { + if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) { + return res; + } + } + + /* first we have to get the digits of the input into + * an array of double precision words W[...] + */ + { + register mp_word *_W; + register mp_digit *tmpx; + + /* alias for the W[] array */ + _W = W; + + /* alias for the digits of x*/ + tmpx = x->dp; + + /* copy the digits of a into W[0..a->used-1] */ + for (ix = 0; ix < x->used; ix++) { + *_W++ = *tmpx++; + } + + /* zero the high words of W[a->used..m->used*2] */ + for (; ix < n->used * 2 + 1; ix++) { + *_W++ = 0; + } + } + + /* now we proceed to zero successive digits + * from the least significant upwards + */ + for (ix = 0; ix < n->used; ix++) { + /* mu = ai * m' mod b + * + * We avoid a double precision multiplication (which isn't required) + * by casting the value down to a mp_digit. Note this requires + * that W[ix-1] have the carry cleared (see after the inner loop) + */ + register mp_digit mu; + mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); + + /* a = a + mu * m * b**i + * + * This is computed in place and on the fly. The multiplication + * by b**i is handled by offseting which columns the results + * are added to. + * + * Note the comba method normally doesn't handle carries in the + * inner loop In this case we fix the carry from the previous + * column since the Montgomery reduction requires digits of the + * result (so far) [see above] to work. This is + * handled by fixing up one carry after the inner loop. The + * carry fixups are done in order so after these loops the + * first m->used words of W[] have the carries fixed + */ + { + register int iy; + register mp_digit *tmpn; + register mp_word *_W; + + /* alias for the digits of the modulus */ + tmpn = n->dp; + + /* Alias for the columns set by an offset of ix */ + _W = W + ix; + + /* inner loop */ + for (iy = 0; iy < n->used; iy++) { + *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); + } + } + + /* now fix carry for next digit, W[ix+1] */ + W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); + } + + /* now we have to propagate the carries and + * shift the words downward [all those least + * significant digits we zeroed]. + */ + { + register mp_digit *tmpx; + register mp_word *_W, *_W1; + + /* nox fix rest of carries */ + + /* alias for current word */ + _W1 = W + ix; + + /* alias for next word, where the carry goes */ + _W = W + ++ix; + + for (; ix <= n->used * 2 + 1; ix++) { + *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); + } + + /* copy out, A = A/b**n + * + * The result is A/b**n but instead of converting from an + * array of mp_word to mp_digit than calling mp_rshd + * we just copy them in the right order + */ + + /* alias for destination word */ + tmpx = x->dp; + + /* alias for shifted double precision result */ + _W = W + n->used; + + for (ix = 0; ix < n->used + 1; ix++) { + *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); + } + + /* zero oldused digits, if the input a was larger than + * m->used+1 we'll have to clear the digits + */ + for (; ix < olduse; ix++) { + *tmpx++ = 0; + } + } + + /* set the max used and clamp */ + x->used = n->used + 1; + mp_clamp (x); + + /* if A >= m then A = A - m */ + if (mp_cmp_mag (x, n) != MP_LT) { + return s_mp_sub (x, n, x); + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_fast_s_mp_mul_digs.c b/libtommath/bn_fast_s_mp_mul_digs.c new file mode 100644 index 0000000..e1ff5f3 --- /dev/null +++ b/libtommath/bn_fast_s_mp_mul_digs.c @@ -0,0 +1,106 @@ +#include +#ifdef BN_FAST_S_MP_MUL_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Fast (comba) multiplier + * + * This is the fast column-array [comba] multiplier. It is + * designed to compute the columns of the product first + * then handle the carries afterwards. This has the effect + * of making the nested loops that compute the columns very + * simple and schedulable on super-scalar processors. + * + * This has been modified to produce a variable number of + * digits of output so if say only a half-product is required + * you don't have to compute the upper half (a feature + * required for fast Barrett reduction). + * + * Based on Algorithm 14.12 on pp.595 of HAC. + * + */ +int +fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY]; + register mp_word _W; + + /* grow the destination as required */ + if (c->alloc < digs) { + if ((res = mp_grow (c, digs)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + pa = MIN(digs, a->used + b->used); + + /* clear the carry */ + _W = 0; + for (ix = 0; ix < pa; ix++) { + int tx, ty; + int iy; + mp_digit *tmpx, *tmpy; + + /* get offsets into the two bignums */ + ty = MIN(b->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = b->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* execute loop */ + for (iz = 0; iz < iy; ++iz) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* store term */ + W[ix] = ((mp_digit)_W) & MP_MASK; + + /* make next carry */ + _W = _W >> ((mp_word)DIGIT_BIT); + } + + /* store final carry */ + W[ix] = _W; + + /* setup dest */ + olduse = c->used; + c->used = digs; + + { + register mp_digit *tmpc; + tmpc = c->dp; + for (ix = 0; ix < digs; ix++) { + /* now extract the previous digit [below the carry] */ + *tmpc++ = W[ix]; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpc++ = 0; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_fast_s_mp_mul_high_digs.c b/libtommath/bn_fast_s_mp_mul_high_digs.c new file mode 100644 index 0000000..064a9dd --- /dev/null +++ b/libtommath/bn_fast_s_mp_mul_high_digs.c @@ -0,0 +1,98 @@ +#include +#ifdef BN_FAST_S_MP_MUL_HIGH_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* this is a modified version of fast_s_mul_digs that only produces + * output digits *above* digs. See the comments for fast_s_mul_digs + * to see how it works. + * + * This is used in the Barrett reduction since for one of the multiplications + * only the higher digits were needed. This essentially halves the work. + * + * Based on Algorithm 14.12 on pp.595 of HAC. + */ +int +fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY]; + mp_word _W; + + /* grow the destination as required */ + pa = a->used + b->used; + if (c->alloc < pa) { + if ((res = mp_grow (c, pa)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + pa = a->used + b->used; + _W = 0; + for (ix = digs; ix < pa; ix++) { + int tx, ty, iy; + mp_digit *tmpx, *tmpy; + + /* get offsets into the two bignums */ + ty = MIN(b->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = b->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* execute loop */ + for (iz = 0; iz < iy; iz++) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* store term */ + W[ix] = ((mp_digit)_W) & MP_MASK; + + /* make next carry */ + _W = _W >> ((mp_word)DIGIT_BIT); + } + + /* store final carry */ + W[ix] = _W; + + /* setup dest */ + olduse = c->used; + c->used = pa; + + { + register mp_digit *tmpc; + + tmpc = c->dp + digs; + for (ix = digs; ix <= pa; ix++) { + /* now extract the previous digit [below the carry] */ + *tmpc++ = W[ix]; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpc++ = 0; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_fast_s_mp_sqr.c b/libtommath/bn_fast_s_mp_sqr.c new file mode 100644 index 0000000..d6014ab --- /dev/null +++ b/libtommath/bn_fast_s_mp_sqr.c @@ -0,0 +1,129 @@ +#include +#ifdef BN_FAST_S_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* fast squaring + * + * This is the comba method where the columns of the product + * are computed first then the carries are computed. This + * has the effect of making a very simple inner loop that + * is executed the most + * + * W2 represents the outer products and W the inner. + * + * A further optimizations is made because the inner + * products are of the form "A * B * 2". The *2 part does + * not need to be computed until the end which is good + * because 64-bit shifts are slow! + * + * Based on Algorithm 14.16 on pp.597 of HAC. + * + */ +/* the jist of squaring... + +you do like mult except the offset of the tmpx [one that starts closer to zero] +can't equal the offset of tmpy. So basically you set up iy like before then you min it with +(ty-tx) so that it never happens. You double all those you add in the inner loop + +After that loop you do the squares and add them in. + +Remove W2 and don't memset W + +*/ + +int fast_s_mp_sqr (mp_int * a, mp_int * b) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY], *tmpx; + mp_word W1; + + /* grow the destination as required */ + pa = a->used + a->used; + if (b->alloc < pa) { + if ((res = mp_grow (b, pa)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + W1 = 0; + for (ix = 0; ix < pa; ix++) { + int tx, ty, iy; + mp_word _W; + mp_digit *tmpy; + + /* clear counter */ + _W = 0; + + /* get offsets into the two bignums */ + ty = MIN(a->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = a->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* now for squaring tx can never equal ty + * we halve the distance since they approach at a rate of 2x + * and we have to round because odd cases need to be executed + */ + iy = MIN(iy, (ty-tx+1)>>1); + + /* execute loop */ + for (iz = 0; iz < iy; iz++) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* double the inner product and add carry */ + _W = _W + _W + W1; + + /* even columns have the square term in them */ + if ((ix&1) == 0) { + _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); + } + + /* store it */ + W[ix] = _W; + + /* make next carry */ + W1 = _W >> ((mp_word)DIGIT_BIT); + } + + /* setup dest */ + olduse = b->used; + b->used = a->used+a->used; + + { + mp_digit *tmpb; + tmpb = b->dp; + for (ix = 0; ix < pa; ix++) { + *tmpb++ = W[ix] & MP_MASK; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpb++ = 0; + } + } + mp_clamp (b); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_2expt.c b/libtommath/bn_mp_2expt.c new file mode 100644 index 0000000..45a6818 --- /dev/null +++ b/libtommath/bn_mp_2expt.c @@ -0,0 +1,44 @@ +#include +#ifdef BN_MP_2EXPT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes a = 2**b + * + * Simple algorithm which zeroes the int, grows it then just sets one bit + * as required. + */ +int +mp_2expt (mp_int * a, int b) +{ + int res; + + /* zero a as per default */ + mp_zero (a); + + /* grow a to accomodate the single bit */ + if ((res = mp_grow (a, b / DIGIT_BIT + 1)) != MP_OKAY) { + return res; + } + + /* set the used count of where the bit will go */ + a->used = b / DIGIT_BIT + 1; + + /* put the single bit in its place */ + a->dp[b / DIGIT_BIT] = ((mp_digit)1) << (b % DIGIT_BIT); + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_abs.c b/libtommath/bn_mp_abs.c new file mode 100644 index 0000000..34f810f --- /dev/null +++ b/libtommath/bn_mp_abs.c @@ -0,0 +1,39 @@ +#include +#ifdef BN_MP_ABS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = |a| + * + * Simple function copies the input and fixes the sign to positive + */ +int +mp_abs (mp_int * a, mp_int * b) +{ + int res; + + /* copy a to b */ + if (a != b) { + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } + } + + /* force the sign of b to positive */ + b->sign = MP_ZPOS; + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_add.c b/libtommath/bn_mp_add.c new file mode 100644 index 0000000..554b7f7 --- /dev/null +++ b/libtommath/bn_mp_add.c @@ -0,0 +1,49 @@ +#include +#ifdef BN_MP_ADD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level addition (handles signs) */ +int mp_add (mp_int * a, mp_int * b, mp_int * c) +{ + int sa, sb, res; + + /* get sign of both inputs */ + sa = a->sign; + sb = b->sign; + + /* handle two cases, not four */ + if (sa == sb) { + /* both positive or both negative */ + /* add their magnitudes, copy the sign */ + c->sign = sa; + res = s_mp_add (a, b, c); + } else { + /* one positive, the other negative */ + /* subtract the one with the greater magnitude from */ + /* the one of the lesser magnitude. The result gets */ + /* the sign of the one with the greater magnitude. */ + if (mp_cmp_mag (a, b) == MP_LT) { + c->sign = sb; + res = s_mp_sub (b, a, c); + } else { + c->sign = sa; + res = s_mp_sub (a, b, c); + } + } + return res; +} + +#endif diff --git a/libtommath/bn_mp_add_d.c b/libtommath/bn_mp_add_d.c new file mode 100644 index 0000000..bdd0280 --- /dev/null +++ b/libtommath/bn_mp_add_d.c @@ -0,0 +1,105 @@ +#include +#ifdef BN_MP_ADD_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* single digit addition */ +int +mp_add_d (mp_int * a, mp_digit b, mp_int * c) +{ + int res, ix, oldused; + mp_digit *tmpa, *tmpc, mu; + + /* grow c as required */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* if a is negative and |a| >= b, call c = |a| - b */ + if (a->sign == MP_NEG && (a->used > 1 || a->dp[0] >= b)) { + /* temporarily fix sign of a */ + a->sign = MP_ZPOS; + + /* c = |a| - b */ + res = mp_sub_d(a, b, c); + + /* fix sign */ + a->sign = c->sign = MP_NEG; + + return res; + } + + /* old number of used digits in c */ + oldused = c->used; + + /* sign always positive */ + c->sign = MP_ZPOS; + + /* source alias */ + tmpa = a->dp; + + /* destination alias */ + tmpc = c->dp; + + /* if a is positive */ + if (a->sign == MP_ZPOS) { + /* add digit, after this we're propagating + * the carry. + */ + *tmpc = *tmpa++ + b; + mu = *tmpc >> DIGIT_BIT; + *tmpc++ &= MP_MASK; + + /* now handle rest of the digits */ + for (ix = 1; ix < a->used; ix++) { + *tmpc = *tmpa++ + mu; + mu = *tmpc >> DIGIT_BIT; + *tmpc++ &= MP_MASK; + } + /* set final carry */ + ix++; + *tmpc++ = mu; + + /* setup size */ + c->used = a->used + 1; + } else { + /* a was negative and |a| < b */ + c->used = 1; + + /* the result is a single digit */ + if (a->used == 1) { + *tmpc++ = b - a->dp[0]; + } else { + *tmpc++ = b; + } + + /* setup count so the clearing of oldused + * can fall through correctly + */ + ix = 1; + } + + /* now zero to oldused */ + while (ix++ < oldused) { + *tmpc++ = 0; + } + mp_clamp(c); + + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_addmod.c b/libtommath/bn_mp_addmod.c new file mode 100644 index 0000000..13eb33f --- /dev/null +++ b/libtommath/bn_mp_addmod.c @@ -0,0 +1,37 @@ +#include +#ifdef BN_MP_ADDMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a + b (mod c) */ +int +mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_add (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_and.c b/libtommath/bn_mp_and.c new file mode 100644 index 0000000..61dc386 --- /dev/null +++ b/libtommath/bn_mp_and.c @@ -0,0 +1,53 @@ +#include +#ifdef BN_MP_AND_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* AND two ints together */ +int +mp_and (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + t.dp[ix] &= x->dp[ix]; + } + + /* zero digits above the last from the smallest mp_int */ + for (; ix < t.used; ix++) { + t.dp[ix] = 0; + } + + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_clamp.c b/libtommath/bn_mp_clamp.c new file mode 100644 index 0000000..c172611 --- /dev/null +++ b/libtommath/bn_mp_clamp.c @@ -0,0 +1,40 @@ +#include +#ifdef BN_MP_CLAMP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* trim unused digits + * + * This is used to ensure that leading zero digits are + * trimed and the leading "used" digit will be non-zero + * Typically very fast. Also fixes the sign if there + * are no more leading digits + */ +void +mp_clamp (mp_int * a) +{ + /* decrease used while the most significant digit is + * zero. + */ + while (a->used > 0 && a->dp[a->used - 1] == 0) { + --(a->used); + } + + /* reset the sign flag if used == 0 */ + if (a->used == 0) { + a->sign = MP_ZPOS; + } +} +#endif diff --git a/libtommath/bn_mp_clear.c b/libtommath/bn_mp_clear.c new file mode 100644 index 0000000..5342648 --- /dev/null +++ b/libtommath/bn_mp_clear.c @@ -0,0 +1,40 @@ +#include +#ifdef BN_MP_CLEAR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* clear one (frees) */ +void +mp_clear (mp_int * a) +{ + int i; + + /* only do anything if a hasn't been freed previously */ + if (a->dp != NULL) { + /* first zero the digits */ + for (i = 0; i < a->used; i++) { + a->dp[i] = 0; + } + + /* free ram */ + XFREE(a->dp); + + /* reset members to make debugging easier */ + a->dp = NULL; + a->alloc = a->used = 0; + a->sign = MP_ZPOS; + } +} +#endif diff --git a/libtommath/bn_mp_clear_multi.c b/libtommath/bn_mp_clear_multi.c new file mode 100644 index 0000000..24cbe73 --- /dev/null +++ b/libtommath/bn_mp_clear_multi.c @@ -0,0 +1,30 @@ +#include +#ifdef BN_MP_CLEAR_MULTI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +#include + +void mp_clear_multi(mp_int *mp, ...) +{ + mp_int* next_mp = mp; + va_list args; + va_start(args, mp); + while (next_mp != NULL) { + mp_clear(next_mp); + next_mp = va_arg(args, mp_int*); + } + va_end(args); +} +#endif diff --git a/libtommath/bn_mp_cmp.c b/libtommath/bn_mp_cmp.c new file mode 100644 index 0000000..583b5f8 --- /dev/null +++ b/libtommath/bn_mp_cmp.c @@ -0,0 +1,39 @@ +#include +#ifdef BN_MP_CMP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare two ints (signed)*/ +int +mp_cmp (mp_int * a, mp_int * b) +{ + /* compare based on sign */ + if (a->sign != b->sign) { + if (a->sign == MP_NEG) { + return MP_LT; + } else { + return MP_GT; + } + } + + /* compare digits */ + if (a->sign == MP_NEG) { + /* if negative compare opposite direction */ + return mp_cmp_mag(b, a); + } else { + return mp_cmp_mag(a, b); + } +} +#endif diff --git a/libtommath/bn_mp_cmp_d.c b/libtommath/bn_mp_cmp_d.c new file mode 100644 index 0000000..882b1c9 --- /dev/null +++ b/libtommath/bn_mp_cmp_d.c @@ -0,0 +1,40 @@ +#include +#ifdef BN_MP_CMP_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare a digit */ +int mp_cmp_d(mp_int * a, mp_digit b) +{ + /* compare based on sign */ + if (a->sign == MP_NEG) { + return MP_LT; + } + + /* compare based on magnitude */ + if (a->used > 1) { + return MP_GT; + } + + /* compare the only digit of a to b */ + if (a->dp[0] > b) { + return MP_GT; + } else if (a->dp[0] < b) { + return MP_LT; + } else { + return MP_EQ; + } +} +#endif diff --git a/libtommath/bn_mp_cmp_mag.c b/libtommath/bn_mp_cmp_mag.c new file mode 100644 index 0000000..a0f351c --- /dev/null +++ b/libtommath/bn_mp_cmp_mag.c @@ -0,0 +1,51 @@ +#include +#ifdef BN_MP_CMP_MAG_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare maginitude of two ints (unsigned) */ +int mp_cmp_mag (mp_int * a, mp_int * b) +{ + int n; + mp_digit *tmpa, *tmpb; + + /* compare based on # of non-zero digits */ + if (a->used > b->used) { + return MP_GT; + } + + if (a->used < b->used) { + return MP_LT; + } + + /* alias for a */ + tmpa = a->dp + (a->used - 1); + + /* alias for b */ + tmpb = b->dp + (a->used - 1); + + /* compare based on digits */ + for (n = 0; n < a->used; ++n, --tmpa, --tmpb) { + if (*tmpa > *tmpb) { + return MP_GT; + } + + if (*tmpa < *tmpb) { + return MP_LT; + } + } + return MP_EQ; +} +#endif diff --git a/libtommath/bn_mp_cnt_lsb.c b/libtommath/bn_mp_cnt_lsb.c new file mode 100644 index 0000000..571f03f --- /dev/null +++ b/libtommath/bn_mp_cnt_lsb.c @@ -0,0 +1,49 @@ +#include +#ifdef BN_MP_CNT_LSB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static const int lnz[16] = { + 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0 +}; + +/* Counts the number of lsbs which are zero before the first zero bit */ +int mp_cnt_lsb(mp_int *a) +{ + int x; + mp_digit q, qq; + + /* easy out */ + if (mp_iszero(a) == 1) { + return 0; + } + + /* scan lower digits until non-zero */ + for (x = 0; x < a->used && a->dp[x] == 0; x++); + q = a->dp[x]; + x *= DIGIT_BIT; + + /* now scan this digit until a 1 is found */ + if ((q & 1) == 0) { + do { + qq = q & 15; + x += lnz[qq]; + q >>= 4; + } while (qq == 0); + } + return x; +} + +#endif diff --git a/libtommath/bn_mp_copy.c b/libtommath/bn_mp_copy.c new file mode 100644 index 0000000..183ec9b --- /dev/null +++ b/libtommath/bn_mp_copy.c @@ -0,0 +1,64 @@ +#include +#ifdef BN_MP_COPY_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* copy, b = a */ +int +mp_copy (mp_int * a, mp_int * b) +{ + int res, n; + + /* if dst == src do nothing */ + if (a == b) { + return MP_OKAY; + } + + /* grow dest */ + if (b->alloc < a->used) { + if ((res = mp_grow (b, a->used)) != MP_OKAY) { + return res; + } + } + + /* zero b and copy the parameters over */ + { + register mp_digit *tmpa, *tmpb; + + /* pointer aliases */ + + /* source */ + tmpa = a->dp; + + /* destination */ + tmpb = b->dp; + + /* copy all the digits */ + for (n = 0; n < a->used; n++) { + *tmpb++ = *tmpa++; + } + + /* clear high digits */ + for (; n < b->used; n++) { + *tmpb++ = 0; + } + } + + /* copy used count and sign */ + b->used = a->used; + b->sign = a->sign; + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_count_bits.c b/libtommath/bn_mp_count_bits.c new file mode 100644 index 0000000..f3f85ac --- /dev/null +++ b/libtommath/bn_mp_count_bits.c @@ -0,0 +1,41 @@ +#include +#ifdef BN_MP_COUNT_BITS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* returns the number of bits in an int */ +int +mp_count_bits (mp_int * a) +{ + int r; + mp_digit q; + + /* shortcut */ + if (a->used == 0) { + return 0; + } + + /* get number of digits and add that */ + r = (a->used - 1) * DIGIT_BIT; + + /* take the last digit and count the bits in it */ + q = a->dp[a->used - 1]; + while (q > ((mp_digit) 0)) { + ++r; + q >>= ((mp_digit) 1); + } + return r; +} +#endif diff --git a/libtommath/bn_mp_div.c b/libtommath/bn_mp_div.c new file mode 100644 index 0000000..6b2b8f0 --- /dev/null +++ b/libtommath/bn_mp_div.c @@ -0,0 +1,288 @@ +#include +#ifdef BN_MP_DIV_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +#ifdef BN_MP_DIV_SMALL + +/* slower bit-bang division... also smaller */ +int mp_div(mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + mp_int ta, tb, tq, q; + int res, n, n2; + + /* is divisor zero ? */ + if (mp_iszero (b) == 1) { + return MP_VAL; + } + + /* if a < b then q=0, r = a */ + if (mp_cmp_mag (a, b) == MP_LT) { + if (d != NULL) { + res = mp_copy (a, d); + } else { + res = MP_OKAY; + } + if (c != NULL) { + mp_zero (c); + } + return res; + } + + /* init our temps */ + if ((res = mp_init_multi(&ta, &tb, &tq, &q, NULL) != MP_OKAY)) { + return res; + } + + + mp_set(&tq, 1); + n = mp_count_bits(a) - mp_count_bits(b); + if (((res = mp_abs(a, &ta)) != MP_OKAY) || + ((res = mp_abs(b, &tb)) != MP_OKAY) || + ((res = mp_mul_2d(&tb, n, &tb)) != MP_OKAY) || + ((res = mp_mul_2d(&tq, n, &tq)) != MP_OKAY)) { + goto LBL_ERR; + } + + while (n-- >= 0) { + if (mp_cmp(&tb, &ta) != MP_GT) { + if (((res = mp_sub(&ta, &tb, &ta)) != MP_OKAY) || + ((res = mp_add(&q, &tq, &q)) != MP_OKAY)) { + goto LBL_ERR; + } + } + if (((res = mp_div_2d(&tb, 1, &tb, NULL)) != MP_OKAY) || + ((res = mp_div_2d(&tq, 1, &tq, NULL)) != MP_OKAY)) { + goto LBL_ERR; + } + } + + /* now q == quotient and ta == remainder */ + n = a->sign; + n2 = (a->sign == b->sign ? MP_ZPOS : MP_NEG); + if (c != NULL) { + mp_exch(c, &q); + c->sign = (mp_iszero(c) == MP_YES) ? MP_ZPOS : n2; + } + if (d != NULL) { + mp_exch(d, &ta); + d->sign = (mp_iszero(d) == MP_YES) ? MP_ZPOS : n; + } +LBL_ERR: + mp_clear_multi(&ta, &tb, &tq, &q, NULL); + return res; +} + +#else + +/* integer signed division. + * c*b + d == a [e.g. a/b, c=quotient, d=remainder] + * HAC pp.598 Algorithm 14.20 + * + * Note that the description in HAC is horribly + * incomplete. For example, it doesn't consider + * the case where digits are removed from 'x' in + * the inner loop. It also doesn't consider the + * case that y has fewer than three digits, etc.. + * + * The overall algorithm is as described as + * 14.20 from HAC but fixed to treat these cases. +*/ +int mp_div (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + mp_int q, x, y, t1, t2; + int res, n, t, i, norm, neg; + + /* is divisor zero ? */ + if (mp_iszero (b) == 1) { + return MP_VAL; + } + + /* if a < b then q=0, r = a */ + if (mp_cmp_mag (a, b) == MP_LT) { + if (d != NULL) { + res = mp_copy (a, d); + } else { + res = MP_OKAY; + } + if (c != NULL) { + mp_zero (c); + } + return res; + } + + if ((res = mp_init_size (&q, a->used + 2)) != MP_OKAY) { + return res; + } + q.used = a->used + 2; + + if ((res = mp_init (&t1)) != MP_OKAY) { + goto LBL_Q; + } + + if ((res = mp_init (&t2)) != MP_OKAY) { + goto LBL_T1; + } + + if ((res = mp_init_copy (&x, a)) != MP_OKAY) { + goto LBL_T2; + } + + if ((res = mp_init_copy (&y, b)) != MP_OKAY) { + goto LBL_X; + } + + /* fix the sign */ + neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; + x.sign = y.sign = MP_ZPOS; + + /* normalize both x and y, ensure that y >= b/2, [b == 2**DIGIT_BIT] */ + norm = mp_count_bits(&y) % DIGIT_BIT; + if (norm < (int)(DIGIT_BIT-1)) { + norm = (DIGIT_BIT-1) - norm; + if ((res = mp_mul_2d (&x, norm, &x)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_mul_2d (&y, norm, &y)) != MP_OKAY) { + goto LBL_Y; + } + } else { + norm = 0; + } + + /* note hac does 0 based, so if used==5 then its 0,1,2,3,4, e.g. use 4 */ + n = x.used - 1; + t = y.used - 1; + + /* while (x >= y*b**n-t) do { q[n-t] += 1; x -= y*b**{n-t} } */ + if ((res = mp_lshd (&y, n - t)) != MP_OKAY) { /* y = y*b**{n-t} */ + goto LBL_Y; + } + + while (mp_cmp (&x, &y) != MP_LT) { + ++(q.dp[n - t]); + if ((res = mp_sub (&x, &y, &x)) != MP_OKAY) { + goto LBL_Y; + } + } + + /* reset y by shifting it back down */ + mp_rshd (&y, n - t); + + /* step 3. for i from n down to (t + 1) */ + for (i = n; i >= (t + 1); i--) { + if (i > x.used) { + continue; + } + + /* step 3.1 if xi == yt then set q{i-t-1} to b-1, + * otherwise set q{i-t-1} to (xi*b + x{i-1})/yt */ + if (x.dp[i] == y.dp[t]) { + q.dp[i - t - 1] = ((((mp_digit)1) << DIGIT_BIT) - 1); + } else { + mp_word tmp; + tmp = ((mp_word) x.dp[i]) << ((mp_word) DIGIT_BIT); + tmp |= ((mp_word) x.dp[i - 1]); + tmp /= ((mp_word) y.dp[t]); + if (tmp > (mp_word) MP_MASK) + tmp = MP_MASK; + q.dp[i - t - 1] = (mp_digit) (tmp & (mp_word) (MP_MASK)); + } + + /* while (q{i-t-1} * (yt * b + y{t-1})) > + xi * b**2 + xi-1 * b + xi-2 + + do q{i-t-1} -= 1; + */ + q.dp[i - t - 1] = (q.dp[i - t - 1] + 1) & MP_MASK; + do { + q.dp[i - t - 1] = (q.dp[i - t - 1] - 1) & MP_MASK; + + /* find left hand */ + mp_zero (&t1); + t1.dp[0] = (t - 1 < 0) ? 0 : y.dp[t - 1]; + t1.dp[1] = y.dp[t]; + t1.used = 2; + if ((res = mp_mul_d (&t1, q.dp[i - t - 1], &t1)) != MP_OKAY) { + goto LBL_Y; + } + + /* find right hand */ + t2.dp[0] = (i - 2 < 0) ? 0 : x.dp[i - 2]; + t2.dp[1] = (i - 1 < 0) ? 0 : x.dp[i - 1]; + t2.dp[2] = x.dp[i]; + t2.used = 3; + } while (mp_cmp_mag(&t1, &t2) == MP_GT); + + /* step 3.3 x = x - q{i-t-1} * y * b**{i-t-1} */ + if ((res = mp_mul_d (&y, q.dp[i - t - 1], &t1)) != MP_OKAY) { + goto LBL_Y; + } + + if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) { + goto LBL_Y; + } + + if ((res = mp_sub (&x, &t1, &x)) != MP_OKAY) { + goto LBL_Y; + } + + /* if x < 0 then { x = x + y*b**{i-t-1}; q{i-t-1} -= 1; } */ + if (x.sign == MP_NEG) { + if ((res = mp_copy (&y, &t1)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_add (&x, &t1, &x)) != MP_OKAY) { + goto LBL_Y; + } + + q.dp[i - t - 1] = (q.dp[i - t - 1] - 1UL) & MP_MASK; + } + } + + /* now q is the quotient and x is the remainder + * [which we have to normalize] + */ + + /* get sign before writing to c */ + x.sign = x.used == 0 ? MP_ZPOS : a->sign; + + if (c != NULL) { + mp_clamp (&q); + mp_exch (&q, c); + c->sign = neg; + } + + if (d != NULL) { + mp_div_2d (&x, norm, &x, NULL); + mp_exch (&x, d); + } + + res = MP_OKAY; + +LBL_Y:mp_clear (&y); +LBL_X:mp_clear (&x); +LBL_T2:mp_clear (&t2); +LBL_T1:mp_clear (&t1); +LBL_Q:mp_clear (&q); + return res; +} + +#endif + +#endif diff --git a/libtommath/bn_mp_div_2.c b/libtommath/bn_mp_div_2.c new file mode 100644 index 0000000..5777997 --- /dev/null +++ b/libtommath/bn_mp_div_2.c @@ -0,0 +1,64 @@ +#include +#ifdef BN_MP_DIV_2_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = a/2 */ +int mp_div_2(mp_int * a, mp_int * b) +{ + int x, res, oldused; + + /* copy */ + if (b->alloc < a->used) { + if ((res = mp_grow (b, a->used)) != MP_OKAY) { + return res; + } + } + + oldused = b->used; + b->used = a->used; + { + register mp_digit r, rr, *tmpa, *tmpb; + + /* source alias */ + tmpa = a->dp + b->used - 1; + + /* dest alias */ + tmpb = b->dp + b->used - 1; + + /* carry */ + r = 0; + for (x = b->used - 1; x >= 0; x--) { + /* get the carry for the next iteration */ + rr = *tmpa & 1; + + /* shift the current digit, add in carry and store */ + *tmpb-- = (*tmpa-- >> 1) | (r << (DIGIT_BIT - 1)); + + /* forward carry to next iteration */ + r = rr; + } + + /* zero excess digits */ + tmpb = b->dp + b->used; + for (x = b->used; x < oldused; x++) { + *tmpb++ = 0; + } + } + b->sign = a->sign; + mp_clamp (b); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_div_2d.c b/libtommath/bn_mp_div_2d.c new file mode 100644 index 0000000..cf103f2 --- /dev/null +++ b/libtommath/bn_mp_div_2d.c @@ -0,0 +1,93 @@ +#include +#ifdef BN_MP_DIV_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift right by a certain bit count (store quotient in c, optional remainder in d) */ +int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) +{ + mp_digit D, r, rr; + int x, res; + mp_int t; + + + /* if the shift count is <= 0 then we do no work */ + if (b <= 0) { + res = mp_copy (a, c); + if (d != NULL) { + mp_zero (d); + } + return res; + } + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + /* get the remainder */ + if (d != NULL) { + if ((res = mp_mod_2d (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + } + + /* copy */ + if ((res = mp_copy (a, c)) != MP_OKAY) { + mp_clear (&t); + return res; + } + + /* shift by as many digits in the bit count */ + if (b >= (int)DIGIT_BIT) { + mp_rshd (c, b / DIGIT_BIT); + } + + /* shift any bit count < DIGIT_BIT */ + D = (mp_digit) (b % DIGIT_BIT); + if (D != 0) { + register mp_digit *tmpc, mask, shift; + + /* mask */ + mask = (((mp_digit)1) << D) - 1; + + /* shift for lsb */ + shift = DIGIT_BIT - D; + + /* alias */ + tmpc = c->dp + (c->used - 1); + + /* carry */ + r = 0; + for (x = c->used - 1; x >= 0; x--) { + /* get the lower bits of this word in a temp */ + rr = *tmpc & mask; + + /* shift the current word and mix in the carry bits from the previous word */ + *tmpc = (*tmpc >> D) | (r << shift); + --tmpc; + + /* set the carry to the carry bits of the current word found above */ + r = rr; + } + } + mp_clamp (c); + if (d != NULL) { + mp_exch (&t, d); + } + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_div_3.c b/libtommath/bn_mp_div_3.c new file mode 100644 index 0000000..7cbafc1 --- /dev/null +++ b/libtommath/bn_mp_div_3.c @@ -0,0 +1,75 @@ +#include +#ifdef BN_MP_DIV_3_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* divide by three (based on routine from MPI and the GMP manual) */ +int +mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) +{ + mp_int q; + mp_word w, t; + mp_digit b; + int res, ix; + + /* b = 2**DIGIT_BIT / 3 */ + b = (((mp_word)1) << ((mp_word)DIGIT_BIT)) / ((mp_word)3); + + if ((res = mp_init_size(&q, a->used)) != MP_OKAY) { + return res; + } + + q.used = a->used; + q.sign = a->sign; + w = 0; + for (ix = a->used - 1; ix >= 0; ix--) { + w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); + + if (w >= 3) { + /* multiply w by [1/3] */ + t = (w * ((mp_word)b)) >> ((mp_word)DIGIT_BIT); + + /* now subtract 3 * [w/3] from w, to get the remainder */ + w -= t+t+t; + + /* fixup the remainder as required since + * the optimization is not exact. + */ + while (w >= 3) { + t += 1; + w -= 3; + } + } else { + t = 0; + } + q.dp[ix] = (mp_digit)t; + } + + /* [optional] store the remainder */ + if (d != NULL) { + *d = (mp_digit)w; + } + + /* [optional] store the quotient */ + if (c != NULL) { + mp_clamp(&q); + mp_exch(&q, c); + } + mp_clear(&q); + + return res; +} + +#endif diff --git a/libtommath/bn_mp_div_d.c b/libtommath/bn_mp_div_d.c new file mode 100644 index 0000000..9b58aa6 --- /dev/null +++ b/libtommath/bn_mp_div_d.c @@ -0,0 +1,106 @@ +#include +#ifdef BN_MP_DIV_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static int s_is_power_of_two(mp_digit b, int *p) +{ + int x; + + for (x = 1; x < DIGIT_BIT; x++) { + if (b == (((mp_digit)1)<dp[0] & ((((mp_digit)1)<used)) != MP_OKAY) { + return res; + } + + q.used = a->used; + q.sign = a->sign; + w = 0; + for (ix = a->used - 1; ix >= 0; ix--) { + w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); + + if (w >= b) { + t = (mp_digit)(w / b); + w -= ((mp_word)t) * ((mp_word)b); + } else { + t = 0; + } + q.dp[ix] = (mp_digit)t; + } + + if (d != NULL) { + *d = (mp_digit)w; + } + + if (c != NULL) { + mp_clamp(&q); + mp_exch(&q, c); + } + mp_clear(&q); + + return res; +} + +#endif diff --git a/libtommath/bn_mp_dr_is_modulus.c b/libtommath/bn_mp_dr_is_modulus.c new file mode 100644 index 0000000..5ef78a3 --- /dev/null +++ b/libtommath/bn_mp_dr_is_modulus.c @@ -0,0 +1,39 @@ +#include +#ifdef BN_MP_DR_IS_MODULUS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if a number is a valid DR modulus */ +int mp_dr_is_modulus(mp_int *a) +{ + int ix; + + /* must be at least two digits */ + if (a->used < 2) { + return 0; + } + + /* must be of the form b**k - a [a <= b] so all + * but the first digit must be equal to -1 (mod b). + */ + for (ix = 1; ix < a->used; ix++) { + if (a->dp[ix] != MP_MASK) { + return 0; + } + } + return 1; +} + +#endif diff --git a/libtommath/bn_mp_dr_reduce.c b/libtommath/bn_mp_dr_reduce.c new file mode 100644 index 0000000..9bb7ad7 --- /dev/null +++ b/libtommath/bn_mp_dr_reduce.c @@ -0,0 +1,90 @@ +#include +#ifdef BN_MP_DR_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduce "x" in place modulo "n" using the Diminished Radix algorithm. + * + * Based on algorithm from the paper + * + * "Generating Efficient Primes for Discrete Log Cryptosystems" + * Chae Hoon Lim, Pil Joong Lee, + * POSTECH Information Research Laboratories + * + * The modulus must be of a special format [see manual] + * + * Has been modified to use algorithm 7.10 from the LTM book instead + * + * Input x must be in the range 0 <= x <= (n-1)**2 + */ +int +mp_dr_reduce (mp_int * x, mp_int * n, mp_digit k) +{ + int err, i, m; + mp_word r; + mp_digit mu, *tmpx1, *tmpx2; + + /* m = digits in modulus */ + m = n->used; + + /* ensure that "x" has at least 2m digits */ + if (x->alloc < m + m) { + if ((err = mp_grow (x, m + m)) != MP_OKAY) { + return err; + } + } + +/* top of loop, this is where the code resumes if + * another reduction pass is required. + */ +top: + /* aliases for digits */ + /* alias for lower half of x */ + tmpx1 = x->dp; + + /* alias for upper half of x, or x/B**m */ + tmpx2 = x->dp + m; + + /* set carry to zero */ + mu = 0; + + /* compute (x mod B**m) + k * [x/B**m] inline and inplace */ + for (i = 0; i < m; i++) { + r = ((mp_word)*tmpx2++) * ((mp_word)k) + *tmpx1 + mu; + *tmpx1++ = (mp_digit)(r & MP_MASK); + mu = (mp_digit)(r >> ((mp_word)DIGIT_BIT)); + } + + /* set final carry */ + *tmpx1++ = mu; + + /* zero words above m */ + for (i = m + 1; i < x->used; i++) { + *tmpx1++ = 0; + } + + /* clamp, sub and return */ + mp_clamp (x); + + /* if x >= n then subtract and reduce again + * Each successive "recursion" makes the input smaller and smaller. + */ + if (mp_cmp_mag (x, n) != MP_LT) { + s_mp_sub(x, n, x); + goto top; + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_dr_setup.c b/libtommath/bn_mp_dr_setup.c new file mode 100644 index 0000000..029d310 --- /dev/null +++ b/libtommath/bn_mp_dr_setup.c @@ -0,0 +1,28 @@ +#include +#ifdef BN_MP_DR_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +void mp_dr_setup(mp_int *a, mp_digit *d) +{ + /* the casts are required if DIGIT_BIT is one less than + * the number of bits in a mp_digit [e.g. DIGIT_BIT==31] + */ + *d = (mp_digit)((((mp_word)1) << ((mp_word)DIGIT_BIT)) - + ((mp_word)a->dp[0])); +} + +#endif diff --git a/libtommath/bn_mp_exch.c b/libtommath/bn_mp_exch.c new file mode 100644 index 0000000..0ef485a --- /dev/null +++ b/libtommath/bn_mp_exch.c @@ -0,0 +1,30 @@ +#include +#ifdef BN_MP_EXCH_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* swap the elements of two integers, for cases where you can't simply swap the + * mp_int pointers around + */ +void +mp_exch (mp_int * a, mp_int * b) +{ + mp_int t; + + t = *a; + *a = *b; + *b = t; +} +#endif diff --git a/libtommath/bn_mp_expt_d.c b/libtommath/bn_mp_expt_d.c new file mode 100644 index 0000000..fdb8bd9 --- /dev/null +++ b/libtommath/bn_mp_expt_d.c @@ -0,0 +1,53 @@ +#include +#ifdef BN_MP_EXPT_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* calculate c = a**b using a square-multiply algorithm */ +int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) +{ + int res, x; + mp_int g; + + if ((res = mp_init_copy (&g, a)) != MP_OKAY) { + return res; + } + + /* set initial result */ + mp_set (c, 1); + + for (x = 0; x < (int) DIGIT_BIT; x++) { + /* square */ + if ((res = mp_sqr (c, c)) != MP_OKAY) { + mp_clear (&g); + return res; + } + + /* if the bit is set multiply */ + if ((b & (mp_digit) (((mp_digit)1) << (DIGIT_BIT - 1))) != 0) { + if ((res = mp_mul (c, &g, c)) != MP_OKAY) { + mp_clear (&g); + return res; + } + } + + /* shift to next bit */ + b <<= 1; + } + + mp_clear (&g); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_exptmod.c b/libtommath/bn_mp_exptmod.c new file mode 100644 index 0000000..7309170 --- /dev/null +++ b/libtommath/bn_mp_exptmod.c @@ -0,0 +1,100 @@ +#include +#ifdef BN_MP_EXPTMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + + +/* this is a shell function that calls either the normal or Montgomery + * exptmod functions. Originally the call to the montgomery code was + * embedded in the normal function but that wasted alot of stack space + * for nothing (since 99% of the time the Montgomery code would be called) + */ +int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +{ + int dr; + + /* modulus P must be positive */ + if (P->sign == MP_NEG) { + return MP_VAL; + } + + /* if exponent X is negative we have to recurse */ + if (X->sign == MP_NEG) { +#ifdef BN_MP_INVMOD_C + mp_int tmpG, tmpX; + int err; + + /* first compute 1/G mod P */ + if ((err = mp_init(&tmpG)) != MP_OKAY) { + return err; + } + if ((err = mp_invmod(G, P, &tmpG)) != MP_OKAY) { + mp_clear(&tmpG); + return err; + } + + /* now get |X| */ + if ((err = mp_init(&tmpX)) != MP_OKAY) { + mp_clear(&tmpG); + return err; + } + if ((err = mp_abs(X, &tmpX)) != MP_OKAY) { + mp_clear_multi(&tmpG, &tmpX, NULL); + return err; + } + + /* and now compute (1/G)**|X| instead of G**X [X < 0] */ + err = mp_exptmod(&tmpG, &tmpX, P, Y); + mp_clear_multi(&tmpG, &tmpX, NULL); + return err; +#else + /* no invmod */ + return MP_VAL; +#endif + } + +#ifdef BN_MP_DR_IS_MODULUS_C + /* is it a DR modulus? */ + dr = mp_dr_is_modulus(P); +#else + dr = 0; +#endif + +#ifdef BN_MP_REDUCE_IS_2K_C + /* if not, is it a uDR modulus? */ + if (dr == 0) { + dr = mp_reduce_is_2k(P) << 1; + } +#endif + + /* if the modulus is odd or dr != 0 use the fast method */ +#ifdef BN_MP_EXPTMOD_FAST_C + if (mp_isodd (P) == 1 || dr != 0) { + return mp_exptmod_fast (G, X, P, Y, dr); + } else { +#endif +#ifdef BN_S_MP_EXPTMOD_C + /* otherwise use the generic Barrett reduction technique */ + return s_mp_exptmod (G, X, P, Y); +#else + /* no exptmod for evens */ + return MP_VAL; +#endif +#ifdef BN_MP_EXPTMOD_FAST_C + } +#endif +} + +#endif diff --git a/libtommath/bn_mp_exptmod_fast.c b/libtommath/bn_mp_exptmod_fast.c new file mode 100644 index 0000000..255e9d9 --- /dev/null +++ b/libtommath/bn_mp_exptmod_fast.c @@ -0,0 +1,318 @@ +#include +#ifdef BN_MP_EXPTMOD_FAST_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes Y == G**X mod P, HAC pp.616, Algorithm 14.85 + * + * Uses a left-to-right k-ary sliding window to compute the modular exponentiation. + * The value of k changes based on the size of the exponent. + * + * Uses Montgomery or Diminished Radix reduction [whichever appropriate] + */ + +#ifdef MP_LOW_MEM + #define TAB_SIZE 32 +#else + #define TAB_SIZE 256 +#endif + +int +mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) +{ + mp_int M[TAB_SIZE], res; + mp_digit buf, mp; + int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + + /* use a pointer to the reduction algorithm. This allows us to use + * one of many reduction algorithms without modding the guts of + * the code with if statements everywhere. + */ + int (*redux)(mp_int*,mp_int*,mp_digit); + + /* find window size */ + x = mp_count_bits (X); + if (x <= 7) { + winsize = 2; + } else if (x <= 36) { + winsize = 3; + } else if (x <= 140) { + winsize = 4; + } else if (x <= 450) { + winsize = 5; + } else if (x <= 1303) { + winsize = 6; + } else if (x <= 3529) { + winsize = 7; + } else { + winsize = 8; + } + +#ifdef MP_LOW_MEM + if (winsize > 5) { + winsize = 5; + } +#endif + + /* init M array */ + /* init first cell */ + if ((err = mp_init(&M[1])) != MP_OKAY) { + return err; + } + + /* now init the second half of the array */ + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + if ((err = mp_init(&M[x])) != MP_OKAY) { + for (y = 1<<(winsize-1); y < x; y++) { + mp_clear (&M[y]); + } + mp_clear(&M[1]); + return err; + } + } + + /* determine and setup reduction code */ + if (redmode == 0) { +#ifdef BN_MP_MONTGOMERY_SETUP_C + /* now setup montgomery */ + if ((err = mp_montgomery_setup (P, &mp)) != MP_OKAY) { + goto LBL_M; + } +#else + err = MP_VAL; + goto LBL_M; +#endif + + /* automatically pick the comba one if available (saves quite a few calls/ifs) */ +#ifdef BN_FAST_MP_MONTGOMERY_REDUCE_C + if (((P->used * 2 + 1) < MP_WARRAY) && + P->used < (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + redux = fast_mp_montgomery_reduce; + } else +#endif + { +#ifdef BN_MP_MONTGOMERY_REDUCE_C + /* use slower baseline Montgomery method */ + redux = mp_montgomery_reduce; +#else + err = MP_VAL; + goto LBL_M; +#endif + } + } else if (redmode == 1) { +#if defined(BN_MP_DR_SETUP_C) && defined(BN_MP_DR_REDUCE_C) + /* setup DR reduction for moduli of the form B**k - b */ + mp_dr_setup(P, &mp); + redux = mp_dr_reduce; +#else + err = MP_VAL; + goto LBL_M; +#endif + } else { +#if defined(BN_MP_REDUCE_2K_SETUP_C) && defined(BN_MP_REDUCE_2K_C) + /* setup DR reduction for moduli of the form 2**k - b */ + if ((err = mp_reduce_2k_setup(P, &mp)) != MP_OKAY) { + goto LBL_M; + } + redux = mp_reduce_2k; +#else + err = MP_VAL; + goto LBL_M; +#endif + } + + /* setup result */ + if ((err = mp_init (&res)) != MP_OKAY) { + goto LBL_M; + } + + /* create M table + * + + * + * The first half of the table is not computed though accept for M[0] and M[1] + */ + + if (redmode == 0) { +#ifdef BN_MP_MONTGOMERY_CALC_NORMALIZATION_C + /* now we need R mod m */ + if ((err = mp_montgomery_calc_normalization (&res, P)) != MP_OKAY) { + goto LBL_RES; + } +#else + err = MP_VAL; + goto LBL_RES; +#endif + + /* now set M[1] to G * R mod m */ + if ((err = mp_mulmod (G, &res, P, &M[1])) != MP_OKAY) { + goto LBL_RES; + } + } else { + mp_set(&res, 1); + if ((err = mp_mod(G, P, &M[1])) != MP_OKAY) { + goto LBL_RES; + } + } + + /* compute the value at M[1<<(winsize-1)] by squaring M[1] (winsize-1) times */ + if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_RES; + } + + for (x = 0; x < (winsize - 1); x++) { + if ((err = mp_sqr (&M[1 << (winsize - 1)], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&M[1 << (winsize - 1)], P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* create upper table */ + for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) { + if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&M[x], P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* set initial mode and bit cnt */ + mode = 0; + bitcnt = 1; + buf = 0; + digidx = X->used - 1; + bitcpy = 0; + bitbuf = 0; + + for (;;) { + /* grab next digit as required */ + if (--bitcnt == 0) { + /* if digidx == -1 we are out of digits so break */ + if (digidx == -1) { + break; + } + /* read next digit and reset bitcnt */ + buf = X->dp[digidx--]; + bitcnt = (int)DIGIT_BIT; + } + + /* grab the next msb from the exponent */ + y = (mp_digit)(buf >> (DIGIT_BIT - 1)) & 1; + buf <<= (mp_digit)1; + + /* if the bit is zero and mode == 0 then we ignore it + * These represent the leading zero bits before the first 1 bit + * in the exponent. Technically this opt is not required but it + * does lower the # of trivial squaring/reductions used + */ + if (mode == 0 && y == 0) { + continue; + } + + /* if the bit is zero and mode == 1 then we square */ + if (mode == 1 && y == 0) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + continue; + } + + /* else we add it to the window */ + bitbuf |= (y << (winsize - ++bitcpy)); + mode = 2; + + if (bitcpy == winsize) { + /* ok window is filled so square as required and multiply */ + /* square first */ + for (x = 0; x < winsize; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* then multiply */ + if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + + /* empty window and reset */ + bitcpy = 0; + bitbuf = 0; + mode = 1; + } + } + + /* if bits remain then square/multiply */ + if (mode == 2 && bitcpy > 0) { + /* square then multiply if the bit is set */ + for (x = 0; x < bitcpy; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + + /* get next bit of the window */ + bitbuf <<= 1; + if ((bitbuf & (1 << winsize)) != 0) { + /* then multiply */ + if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + } + } + + if (redmode == 0) { + /* fixup result if Montgomery reduction is used + * recall that any value in a Montgomery system is + * actually multiplied by R mod n. So we have + * to reduce one more time to cancel out the factor + * of R. + */ + if ((err = redux(&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* swap res with Y */ + mp_exch (&res, Y); + err = MP_OKAY; +LBL_RES:mp_clear (&res); +LBL_M: + mp_clear(&M[1]); + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + mp_clear (&M[x]); + } + return err; +} +#endif + diff --git a/libtommath/bn_mp_exteuclid.c b/libtommath/bn_mp_exteuclid.c new file mode 100644 index 0000000..545450b --- /dev/null +++ b/libtommath/bn_mp_exteuclid.c @@ -0,0 +1,71 @@ +#include +#ifdef BN_MP_EXTEUCLID_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Extended euclidean algorithm of (a, b) produces + a*u1 + b*u2 = u3 + */ +int mp_exteuclid(mp_int *a, mp_int *b, mp_int *U1, mp_int *U2, mp_int *U3) +{ + mp_int u1,u2,u3,v1,v2,v3,t1,t2,t3,q,tmp; + int err; + + if ((err = mp_init_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL)) != MP_OKAY) { + return err; + } + + /* initialize, (u1,u2,u3) = (1,0,a) */ + mp_set(&u1, 1); + if ((err = mp_copy(a, &u3)) != MP_OKAY) { goto _ERR; } + + /* initialize, (v1,v2,v3) = (0,1,b) */ + mp_set(&v2, 1); + if ((err = mp_copy(b, &v3)) != MP_OKAY) { goto _ERR; } + + /* loop while v3 != 0 */ + while (mp_iszero(&v3) == MP_NO) { + /* q = u3/v3 */ + if ((err = mp_div(&u3, &v3, &q, NULL)) != MP_OKAY) { goto _ERR; } + + /* (t1,t2,t3) = (u1,u2,u3) - (v1,v2,v3)q */ + if ((err = mp_mul(&v1, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u1, &tmp, &t1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_mul(&v2, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u2, &tmp, &t2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_mul(&v3, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u3, &tmp, &t3)) != MP_OKAY) { goto _ERR; } + + /* (u1,u2,u3) = (v1,v2,v3) */ + if ((err = mp_copy(&v1, &u1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&v2, &u2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&v3, &u3)) != MP_OKAY) { goto _ERR; } + + /* (v1,v2,v3) = (t1,t2,t3) */ + if ((err = mp_copy(&t1, &v1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&t2, &v2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&t3, &v3)) != MP_OKAY) { goto _ERR; } + } + + /* copy result out */ + if (U1 != NULL) { mp_exch(U1, &u1); } + if (U2 != NULL) { mp_exch(U2, &u2); } + if (U3 != NULL) { mp_exch(U3, &u3); } + + err = MP_OKAY; +_ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL); + return err; +} +#endif diff --git a/libtommath/bn_mp_fread.c b/libtommath/bn_mp_fread.c new file mode 100644 index 0000000..293df3f --- /dev/null +++ b/libtommath/bn_mp_fread.c @@ -0,0 +1,63 @@ +#include +#ifdef BN_MP_FREAD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read a bigint from a file stream in ASCII */ +int mp_fread(mp_int *a, int radix, FILE *stream) +{ + int err, ch, neg, y; + + /* clear a */ + mp_zero(a); + + /* if first digit is - then set negative */ + ch = fgetc(stream); + if (ch == '-') { + neg = MP_NEG; + ch = fgetc(stream); + } else { + neg = MP_ZPOS; + } + + for (;;) { + /* find y in the radix map */ + for (y = 0; y < radix; y++) { + if (mp_s_rmap[y] == ch) { + break; + } + } + if (y == radix) { + break; + } + + /* shift up and add */ + if ((err = mp_mul_d(a, radix, a)) != MP_OKAY) { + return err; + } + if ((err = mp_add_d(a, y, a)) != MP_OKAY) { + return err; + } + + ch = fgetc(stream); + } + if (mp_cmp_d(a, 0) != MP_EQ) { + a->sign = neg; + } + + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_fwrite.c b/libtommath/bn_mp_fwrite.c new file mode 100644 index 0000000..8fa3129 --- /dev/null +++ b/libtommath/bn_mp_fwrite.c @@ -0,0 +1,48 @@ +#include +#ifdef BN_MP_FWRITE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +int mp_fwrite(mp_int *a, int radix, FILE *stream) +{ + char *buf; + int err, len, x; + + if ((err = mp_radix_size(a, radix, &len)) != MP_OKAY) { + return err; + } + + buf = OPT_CAST(char) XMALLOC (len); + if (buf == NULL) { + return MP_MEM; + } + + if ((err = mp_toradix(a, buf, radix)) != MP_OKAY) { + XFREE (buf); + return err; + } + + for (x = 0; x < len; x++) { + if (fputc(buf[x], stream) == EOF) { + XFREE (buf); + return MP_VAL; + } + } + + XFREE (buf); + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_gcd.c b/libtommath/bn_mp_gcd.c new file mode 100644 index 0000000..6265df1 --- /dev/null +++ b/libtommath/bn_mp_gcd.c @@ -0,0 +1,109 @@ +#include +#ifdef BN_MP_GCD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Greatest Common Divisor using the binary method */ +int mp_gcd (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int u, v; + int k, u_lsb, v_lsb, res; + + /* either zero than gcd is the largest */ + if (mp_iszero (a) == 1 && mp_iszero (b) == 0) { + return mp_abs (b, c); + } + if (mp_iszero (a) == 0 && mp_iszero (b) == 1) { + return mp_abs (a, c); + } + + /* optimized. At this point if a == 0 then + * b must equal zero too + */ + if (mp_iszero (a) == 1) { + mp_zero(c); + return MP_OKAY; + } + + /* get copies of a and b we can modify */ + if ((res = mp_init_copy (&u, a)) != MP_OKAY) { + return res; + } + + if ((res = mp_init_copy (&v, b)) != MP_OKAY) { + goto LBL_U; + } + + /* must be positive for the remainder of the algorithm */ + u.sign = v.sign = MP_ZPOS; + + /* B1. Find the common power of two for u and v */ + u_lsb = mp_cnt_lsb(&u); + v_lsb = mp_cnt_lsb(&v); + k = MIN(u_lsb, v_lsb); + + if (k > 0) { + /* divide the power of two out */ + if ((res = mp_div_2d(&u, k, &u, NULL)) != MP_OKAY) { + goto LBL_V; + } + + if ((res = mp_div_2d(&v, k, &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + /* divide any remaining factors of two out */ + if (u_lsb != k) { + if ((res = mp_div_2d(&u, u_lsb - k, &u, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + if (v_lsb != k) { + if ((res = mp_div_2d(&v, v_lsb - k, &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + while (mp_iszero(&v) == 0) { + /* make sure v is the largest */ + if (mp_cmp_mag(&u, &v) == MP_GT) { + /* swap u and v to make sure v is >= u */ + mp_exch(&u, &v); + } + + /* subtract smallest from largest */ + if ((res = s_mp_sub(&v, &u, &v)) != MP_OKAY) { + goto LBL_V; + } + + /* Divide out all factors of two */ + if ((res = mp_div_2d(&v, mp_cnt_lsb(&v), &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + /* multiply by 2**k which we divided out at the beginning */ + if ((res = mp_mul_2d (&u, k, c)) != MP_OKAY) { + goto LBL_V; + } + c->sign = MP_ZPOS; + res = MP_OKAY; +LBL_V:mp_clear (&u); +LBL_U:mp_clear (&v); + return res; +} +#endif diff --git a/libtommath/bn_mp_get_int.c b/libtommath/bn_mp_get_int.c new file mode 100644 index 0000000..034467b --- /dev/null +++ b/libtommath/bn_mp_get_int.c @@ -0,0 +1,41 @@ +#include +#ifdef BN_MP_GET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the lower 32-bits of an mp_int */ +unsigned long mp_get_int(mp_int * a) +{ + int i; + unsigned long res; + + if (a->used == 0) { + return 0; + } + + /* get number of digits of the lsb we have to read */ + i = MIN(a->used,(int)((sizeof(unsigned long)*CHAR_BIT+DIGIT_BIT-1)/DIGIT_BIT))-1; + + /* get most significant digit of result */ + res = DIGIT(a,i); + + while (--i >= 0) { + res = (res << DIGIT_BIT) | DIGIT(a,i); + } + + /* force result to 32-bits always so it is consistent on non 32-bit platforms */ + return res & 0xFFFFFFFFUL; +} +#endif diff --git a/libtommath/bn_mp_grow.c b/libtommath/bn_mp_grow.c new file mode 100644 index 0000000..12a78a8 --- /dev/null +++ b/libtommath/bn_mp_grow.c @@ -0,0 +1,53 @@ +#include +#ifdef BN_MP_GROW_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* grow as required */ +int mp_grow (mp_int * a, int size) +{ + int i; + mp_digit *tmp; + + /* if the alloc size is smaller alloc more ram */ + if (a->alloc < size) { + /* ensure there are always at least MP_PREC digits extra on top */ + size += (MP_PREC * 2) - (size % MP_PREC); + + /* reallocate the array a->dp + * + * We store the return in a temporary variable + * in case the operation failed we don't want + * to overwrite the dp member of a. + */ + tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * size); + if (tmp == NULL) { + /* reallocation failed but "a" is still valid [can be freed] */ + return MP_MEM; + } + + /* reallocation succeeded so set a->dp */ + a->dp = tmp; + + /* zero excess digits */ + i = a->alloc; + a->alloc = size; + for (; i < a->alloc; i++) { + a->dp[i] = 0; + } + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_init.c b/libtommath/bn_mp_init.c new file mode 100644 index 0000000..9d70554 --- /dev/null +++ b/libtommath/bn_mp_init.c @@ -0,0 +1,42 @@ +#include +#ifdef BN_MP_INIT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* init a new mp_int */ +int mp_init (mp_int * a) +{ + int i; + + /* allocate memory required and clear it */ + a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * MP_PREC); + if (a->dp == NULL) { + return MP_MEM; + } + + /* set the digits to zero */ + for (i = 0; i < MP_PREC; i++) { + a->dp[i] = 0; + } + + /* set the used to zero, allocated digits to the default precision + * and sign to positive */ + a->used = 0; + a->alloc = MP_PREC; + a->sign = MP_ZPOS; + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_init_copy.c b/libtommath/bn_mp_init_copy.c new file mode 100644 index 0000000..b1b0fa2 --- /dev/null +++ b/libtommath/bn_mp_init_copy.c @@ -0,0 +1,28 @@ +#include +#ifdef BN_MP_INIT_COPY_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* creates "a" then copies b into it */ +int mp_init_copy (mp_int * a, mp_int * b) +{ + int res; + + if ((res = mp_init (a)) != MP_OKAY) { + return res; + } + return mp_copy (b, a); +} +#endif diff --git a/libtommath/bn_mp_init_multi.c b/libtommath/bn_mp_init_multi.c new file mode 100644 index 0000000..8cb123a --- /dev/null +++ b/libtommath/bn_mp_init_multi.c @@ -0,0 +1,55 @@ +#include +#ifdef BN_MP_INIT_MULTI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +#include + +int mp_init_multi(mp_int *mp, ...) +{ + mp_err res = MP_OKAY; /* Assume ok until proven otherwise */ + int n = 0; /* Number of ok inits */ + mp_int* cur_arg = mp; + va_list args; + + va_start(args, mp); /* init args to next argument from caller */ + while (cur_arg != NULL) { + if (mp_init(cur_arg) != MP_OKAY) { + /* Oops - error! Back-track and mp_clear what we already + succeeded in init-ing, then return error. + */ + va_list clean_args; + + /* end the current list */ + va_end(args); + + /* now start cleaning up */ + cur_arg = mp; + va_start(clean_args, mp); + while (n--) { + mp_clear(cur_arg); + cur_arg = va_arg(clean_args, mp_int*); + } + va_end(clean_args); + res = MP_MEM; + break; + } + n++; + cur_arg = va_arg(args, mp_int*); + } + va_end(args); + return res; /* Assumed ok, if error flagged above. */ +} + +#endif diff --git a/libtommath/bn_mp_init_set.c b/libtommath/bn_mp_init_set.c new file mode 100644 index 0000000..0251e61 --- /dev/null +++ b/libtommath/bn_mp_init_set.c @@ -0,0 +1,28 @@ +#include +#ifdef BN_MP_INIT_SET_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* initialize and set a digit */ +int mp_init_set (mp_int * a, mp_digit b) +{ + int err; + if ((err = mp_init(a)) != MP_OKAY) { + return err; + } + mp_set(a, b); + return err; +} +#endif diff --git a/libtommath/bn_mp_init_set_int.c b/libtommath/bn_mp_init_set_int.c new file mode 100644 index 0000000..f59fd19 --- /dev/null +++ b/libtommath/bn_mp_init_set_int.c @@ -0,0 +1,27 @@ +#include +#ifdef BN_MP_INIT_SET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* initialize and set a digit */ +int mp_init_set_int (mp_int * a, unsigned long b) +{ + int err; + if ((err = mp_init(a)) != MP_OKAY) { + return err; + } + return mp_set_int(a, b); +} +#endif diff --git a/libtommath/bn_mp_init_size.c b/libtommath/bn_mp_init_size.c new file mode 100644 index 0000000..845ce2c --- /dev/null +++ b/libtommath/bn_mp_init_size.c @@ -0,0 +1,44 @@ +#include +#ifdef BN_MP_INIT_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* init an mp_init for a given size */ +int mp_init_size (mp_int * a, int size) +{ + int x; + + /* pad size so there are always extra digits */ + size += (MP_PREC * 2) - (size % MP_PREC); + + /* alloc mem */ + a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * size); + if (a->dp == NULL) { + return MP_MEM; + } + + /* set the members */ + a->used = 0; + a->alloc = size; + a->sign = MP_ZPOS; + + /* zero the digits */ + for (x = 0; x < size; x++) { + a->dp[x] = 0; + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_invmod.c b/libtommath/bn_mp_invmod.c new file mode 100644 index 0000000..46118ad --- /dev/null +++ b/libtommath/bn_mp_invmod.c @@ -0,0 +1,39 @@ +#include +#ifdef BN_MP_INVMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* hac 14.61, pp608 */ +int mp_invmod (mp_int * a, mp_int * b, mp_int * c) +{ + /* b cannot be negative */ + if (b->sign == MP_NEG || mp_iszero(b) == 1) { + return MP_VAL; + } + +#ifdef BN_FAST_MP_INVMOD_C + /* if the modulus is odd we can use a faster routine instead */ + if (mp_isodd (b) == 1) { + return fast_mp_invmod (a, b, c); + } +#endif + +#ifdef BN_MP_INVMOD_SLOW_C + return mp_invmod_slow(a, b, c); +#endif + + return MP_VAL; +} +#endif diff --git a/libtommath/bn_mp_invmod_slow.c b/libtommath/bn_mp_invmod_slow.c new file mode 100644 index 0000000..c1884c0 --- /dev/null +++ b/libtommath/bn_mp_invmod_slow.c @@ -0,0 +1,171 @@ +#include +#ifdef BN_MP_INVMOD_SLOW_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* hac 14.61, pp608 */ +int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x, y, u, v, A, B, C, D; + int res; + + /* b cannot be negative */ + if (b->sign == MP_NEG || mp_iszero(b) == 1) { + return MP_VAL; + } + + /* init temps */ + if ((res = mp_init_multi(&x, &y, &u, &v, + &A, &B, &C, &D, NULL)) != MP_OKAY) { + return res; + } + + /* x = a, y = b */ + if ((res = mp_copy (a, &x)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (b, &y)) != MP_OKAY) { + goto LBL_ERR; + } + + /* 2. [modified] if x,y are both even then return an error! */ + if (mp_iseven (&x) == 1 && mp_iseven (&y) == 1) { + res = MP_VAL; + goto LBL_ERR; + } + + /* 3. u=x, v=y, A=1, B=0, C=0,D=1 */ + if ((res = mp_copy (&x, &u)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (&y, &v)) != MP_OKAY) { + goto LBL_ERR; + } + mp_set (&A, 1); + mp_set (&D, 1); + +top: + /* 4. while u is even do */ + while (mp_iseven (&u) == 1) { + /* 4.1 u = u/2 */ + if ((res = mp_div_2 (&u, &u)) != MP_OKAY) { + goto LBL_ERR; + } + /* 4.2 if A or B is odd then */ + if (mp_isodd (&A) == 1 || mp_isodd (&B) == 1) { + /* A = (A+y)/2, B = (B-x)/2 */ + if ((res = mp_add (&A, &y, &A)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_sub (&B, &x, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* A = A/2, B = B/2 */ + if ((res = mp_div_2 (&A, &A)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_div_2 (&B, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 5. while v is even do */ + while (mp_iseven (&v) == 1) { + /* 5.1 v = v/2 */ + if ((res = mp_div_2 (&v, &v)) != MP_OKAY) { + goto LBL_ERR; + } + /* 5.2 if C or D is odd then */ + if (mp_isodd (&C) == 1 || mp_isodd (&D) == 1) { + /* C = (C+y)/2, D = (D-x)/2 */ + if ((res = mp_add (&C, &y, &C)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_sub (&D, &x, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* C = C/2, D = D/2 */ + if ((res = mp_div_2 (&C, &C)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_div_2 (&D, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 6. if u >= v then */ + if (mp_cmp (&u, &v) != MP_LT) { + /* u = u - v, A = A - C, B = B - D */ + if ((res = mp_sub (&u, &v, &u)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&A, &C, &A)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&B, &D, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } else { + /* v - v - u, C = C - A, D = D - B */ + if ((res = mp_sub (&v, &u, &v)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&C, &A, &C)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&D, &B, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* if not zero goto step 4 */ + if (mp_iszero (&u) == 0) + goto top; + + /* now a = C, b = D, gcd == g*v */ + + /* if v != 1 then there is no inverse */ + if (mp_cmp_d (&v, 1) != MP_EQ) { + res = MP_VAL; + goto LBL_ERR; + } + + /* if its too low */ + while (mp_cmp_d(&C, 0) == MP_LT) { + if ((res = mp_add(&C, b, &C)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* too big */ + while (mp_cmp_mag(&C, b) != MP_LT) { + if ((res = mp_sub(&C, b, &C)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* C is now the inverse */ + mp_exch (&C, c); + res = MP_OKAY; +LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); + return res; +} +#endif diff --git a/libtommath/bn_mp_is_square.c b/libtommath/bn_mp_is_square.c new file mode 100644 index 0000000..969d237 --- /dev/null +++ b/libtommath/bn_mp_is_square.c @@ -0,0 +1,105 @@ +#include +#ifdef BN_MP_IS_SQUARE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Check if remainders are possible squares - fast exclude non-squares */ +static const char rem_128[128] = { + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1 +}; + +static const char rem_105[105] = { + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 1, + 0, 1, 1, 1, 1, 1, 0, 1, 1, 0, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, + 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, + 1, 1, 1, 1, 0, 1, 0, 1, 1, 0, 0, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1, 1, 1, 1 +}; + +/* Store non-zero to ret if arg is square, and zero if not */ +int mp_is_square(mp_int *arg,int *ret) +{ + int res; + mp_digit c; + mp_int t; + unsigned long r; + + /* Default to Non-square :) */ + *ret = MP_NO; + + if (arg->sign == MP_NEG) { + return MP_VAL; + } + + /* digits used? (TSD) */ + if (arg->used == 0) { + return MP_OKAY; + } + + /* First check mod 128 (suppose that DIGIT_BIT is at least 7) */ + if (rem_128[127 & DIGIT(arg,0)] == 1) { + return MP_OKAY; + } + + /* Next check mod 105 (3*5*7) */ + if ((res = mp_mod_d(arg,105,&c)) != MP_OKAY) { + return res; + } + if (rem_105[c] == 1) { + return MP_OKAY; + } + + + if ((res = mp_init_set_int(&t,11L*13L*17L*19L*23L*29L*31L)) != MP_OKAY) { + return res; + } + if ((res = mp_mod(arg,&t,&t)) != MP_OKAY) { + goto ERR; + } + r = mp_get_int(&t); + /* Check for other prime modules, note it's not an ERROR but we must + * free "t" so the easiest way is to goto ERR. We know that res + * is already equal to MP_OKAY from the mp_mod call + */ + if ( (1L<<(r%11)) & 0x5C4L ) goto ERR; + if ( (1L<<(r%13)) & 0x9E4L ) goto ERR; + if ( (1L<<(r%17)) & 0x5CE8L ) goto ERR; + if ( (1L<<(r%19)) & 0x4F50CL ) goto ERR; + if ( (1L<<(r%23)) & 0x7ACCA0L ) goto ERR; + if ( (1L<<(r%29)) & 0xC2EDD0CL ) goto ERR; + if ( (1L<<(r%31)) & 0x6DE2B848L ) goto ERR; + + /* Final check - is sqr(sqrt(arg)) == arg ? */ + if ((res = mp_sqrt(arg,&t)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sqr(&t,&t)) != MP_OKAY) { + goto ERR; + } + + *ret = (mp_cmp_mag(&t,arg) == MP_EQ) ? MP_YES : MP_NO; +ERR:mp_clear(&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_jacobi.c b/libtommath/bn_mp_jacobi.c new file mode 100644 index 0000000..74cbbf3 --- /dev/null +++ b/libtommath/bn_mp_jacobi.c @@ -0,0 +1,101 @@ +#include +#ifdef BN_MP_JACOBI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes the jacobi c = (a | n) (or Legendre if n is prime) + * HAC pp. 73 Algorithm 2.149 + */ +int mp_jacobi (mp_int * a, mp_int * p, int *c) +{ + mp_int a1, p1; + int k, s, r, res; + mp_digit residue; + + /* if p <= 0 return MP_VAL */ + if (mp_cmp_d(p, 0) != MP_GT) { + return MP_VAL; + } + + /* step 1. if a == 0, return 0 */ + if (mp_iszero (a) == 1) { + *c = 0; + return MP_OKAY; + } + + /* step 2. if a == 1, return 1 */ + if (mp_cmp_d (a, 1) == MP_EQ) { + *c = 1; + return MP_OKAY; + } + + /* default */ + s = 0; + + /* step 3. write a = a1 * 2**k */ + if ((res = mp_init_copy (&a1, a)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&p1)) != MP_OKAY) { + goto LBL_A1; + } + + /* divide out larger power of two */ + k = mp_cnt_lsb(&a1); + if ((res = mp_div_2d(&a1, k, &a1, NULL)) != MP_OKAY) { + goto LBL_P1; + } + + /* step 4. if e is even set s=1 */ + if ((k & 1) == 0) { + s = 1; + } else { + /* else set s=1 if p = 1/7 (mod 8) or s=-1 if p = 3/5 (mod 8) */ + residue = p->dp[0] & 7; + + if (residue == 1 || residue == 7) { + s = 1; + } else if (residue == 3 || residue == 5) { + s = -1; + } + } + + /* step 5. if p == 3 (mod 4) *and* a1 == 3 (mod 4) then s = -s */ + if ( ((p->dp[0] & 3) == 3) && ((a1.dp[0] & 3) == 3)) { + s = -s; + } + + /* if a1 == 1 we're done */ + if (mp_cmp_d (&a1, 1) == MP_EQ) { + *c = s; + } else { + /* n1 = n mod a1 */ + if ((res = mp_mod (p, &a1, &p1)) != MP_OKAY) { + goto LBL_P1; + } + if ((res = mp_jacobi (&p1, &a1, &r)) != MP_OKAY) { + goto LBL_P1; + } + *c = s * r; + } + + /* done */ + res = MP_OKAY; +LBL_P1:mp_clear (&p1); +LBL_A1:mp_clear (&a1); + return res; +} +#endif diff --git a/libtommath/bn_mp_karatsuba_mul.c b/libtommath/bn_mp_karatsuba_mul.c new file mode 100644 index 0000000..daa78c7 --- /dev/null +++ b/libtommath/bn_mp_karatsuba_mul.c @@ -0,0 +1,163 @@ +#include +#ifdef BN_MP_KARATSUBA_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = |a| * |b| using Karatsuba Multiplication using + * three half size multiplications + * + * Let B represent the radix [e.g. 2**DIGIT_BIT] and + * let n represent half of the number of digits in + * the min(a,b) + * + * a = a1 * B**n + a0 + * b = b1 * B**n + b0 + * + * Then, a * b => + a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 + * + * Note that a1b1 and a0b0 are used twice and only need to be + * computed once. So in total three half size (half # of + * digit) multiplications are performed, a0b0, a1b1 and + * (a1-b1)(a0-b0) + * + * Note that a multiplication of half the digits requires + * 1/4th the number of single precision multiplications so in + * total after one call 25% of the single precision multiplications + * are saved. Note also that the call to mp_mul can end up back + * in this function if the a0, a1, b0, or b1 are above the threshold. + * This is known as divide-and-conquer and leads to the famous + * O(N**lg(3)) or O(N**1.584) work which is asymptopically lower than + * the standard O(N**2) that the baseline/comba methods use. + * Generally though the overhead of this method doesn't pay off + * until a certain size (N ~ 80) is reached. + */ +int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x0, x1, y0, y1, t1, x0y0, x1y1; + int B, err; + + /* default the return code to an error */ + err = MP_MEM; + + /* min # of digits */ + B = MIN (a->used, b->used); + + /* now divide in two */ + B = B >> 1; + + /* init copy all the temps */ + if (mp_init_size (&x0, B) != MP_OKAY) + goto ERR; + if (mp_init_size (&x1, a->used - B) != MP_OKAY) + goto X0; + if (mp_init_size (&y0, B) != MP_OKAY) + goto X1; + if (mp_init_size (&y1, b->used - B) != MP_OKAY) + goto Y0; + + /* init temps */ + if (mp_init_size (&t1, B * 2) != MP_OKAY) + goto Y1; + if (mp_init_size (&x0y0, B * 2) != MP_OKAY) + goto T1; + if (mp_init_size (&x1y1, B * 2) != MP_OKAY) + goto X0Y0; + + /* now shift the digits */ + x0.used = y0.used = B; + x1.used = a->used - B; + y1.used = b->used - B; + + { + register int x; + register mp_digit *tmpa, *tmpb, *tmpx, *tmpy; + + /* we copy the digits directly instead of using higher level functions + * since we also need to shift the digits + */ + tmpa = a->dp; + tmpb = b->dp; + + tmpx = x0.dp; + tmpy = y0.dp; + for (x = 0; x < B; x++) { + *tmpx++ = *tmpa++; + *tmpy++ = *tmpb++; + } + + tmpx = x1.dp; + for (x = B; x < a->used; x++) { + *tmpx++ = *tmpa++; + } + + tmpy = y1.dp; + for (x = B; x < b->used; x++) { + *tmpy++ = *tmpb++; + } + } + + /* only need to clamp the lower words since by definition the + * upper words x1/y1 must have a known number of digits + */ + mp_clamp (&x0); + mp_clamp (&y0); + + /* now calc the products x0y0 and x1y1 */ + /* after this x0 is no longer required, free temp [x0==t2]! */ + if (mp_mul (&x0, &y0, &x0y0) != MP_OKAY) + goto X1Y1; /* x0y0 = x0*y0 */ + if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) + goto X1Y1; /* x1y1 = x1*y1 */ + + /* now calc x1-x0 and y1-y0 */ + if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = x1 - x0 */ + if (mp_sub (&y1, &y0, &x0) != MP_OKAY) + goto X1Y1; /* t2 = y1 - y0 */ + if (mp_mul (&t1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ + + /* add x0y0 */ + if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) + goto X1Y1; /* t2 = x0y0 + x1y1 */ + if (mp_sub (&x0, &t1, &t1) != MP_OKAY) + goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ + + /* shift by B */ + if (mp_lshd (&t1, B) != MP_OKAY) + goto X1Y1; /* t1 = (x0y0 + x1y1 - (x1-x0)*(y1-y0))< +#ifdef BN_MP_KARATSUBA_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Karatsuba squaring, computes b = a*a using three + * half size squarings + * + * See comments of karatsuba_mul for details. It + * is essentially the same algorithm but merely + * tuned to perform recursive squarings. + */ +int mp_karatsuba_sqr (mp_int * a, mp_int * b) +{ + mp_int x0, x1, t1, t2, x0x0, x1x1; + int B, err; + + err = MP_MEM; + + /* min # of digits */ + B = a->used; + + /* now divide in two */ + B = B >> 1; + + /* init copy all the temps */ + if (mp_init_size (&x0, B) != MP_OKAY) + goto ERR; + if (mp_init_size (&x1, a->used - B) != MP_OKAY) + goto X0; + + /* init temps */ + if (mp_init_size (&t1, a->used * 2) != MP_OKAY) + goto X1; + if (mp_init_size (&t2, a->used * 2) != MP_OKAY) + goto T1; + if (mp_init_size (&x0x0, B * 2) != MP_OKAY) + goto T2; + if (mp_init_size (&x1x1, (a->used - B) * 2) != MP_OKAY) + goto X0X0; + + { + register int x; + register mp_digit *dst, *src; + + src = a->dp; + + /* now shift the digits */ + dst = x0.dp; + for (x = 0; x < B; x++) { + *dst++ = *src++; + } + + dst = x1.dp; + for (x = B; x < a->used; x++) { + *dst++ = *src++; + } + } + + x0.used = B; + x1.used = a->used - B; + + mp_clamp (&x0); + + /* now calc the products x0*x0 and x1*x1 */ + if (mp_sqr (&x0, &x0x0) != MP_OKAY) + goto X1X1; /* x0x0 = x0*x0 */ + if (mp_sqr (&x1, &x1x1) != MP_OKAY) + goto X1X1; /* x1x1 = x1*x1 */ + + /* now calc (x1-x0)**2 */ + if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + goto X1X1; /* t1 = x1 - x0 */ + if (mp_sqr (&t1, &t1) != MP_OKAY) + goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ + + /* add x0y0 */ + if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) + goto X1X1; /* t2 = x0x0 + x1x1 */ + if (mp_sub (&t2, &t1, &t1) != MP_OKAY) + goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ + + /* shift by B */ + if (mp_lshd (&t1, B) != MP_OKAY) + goto X1X1; /* t1 = (x0x0 + x1x1 - (x1-x0)*(x1-x0))< +#ifdef BN_MP_LCM_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes least common multiple as |a*b|/(a, b) */ +int mp_lcm (mp_int * a, mp_int * b, mp_int * c) +{ + int res; + mp_int t1, t2; + + + if ((res = mp_init_multi (&t1, &t2, NULL)) != MP_OKAY) { + return res; + } + + /* t1 = get the GCD of the two inputs */ + if ((res = mp_gcd (a, b, &t1)) != MP_OKAY) { + goto LBL_T; + } + + /* divide the smallest by the GCD */ + if (mp_cmp_mag(a, b) == MP_LT) { + /* store quotient in t2 such that t2 * b is the LCM */ + if ((res = mp_div(a, &t1, &t2, NULL)) != MP_OKAY) { + goto LBL_T; + } + res = mp_mul(b, &t2, c); + } else { + /* store quotient in t2 such that t2 * a is the LCM */ + if ((res = mp_div(b, &t1, &t2, NULL)) != MP_OKAY) { + goto LBL_T; + } + res = mp_mul(a, &t2, c); + } + + /* fix the sign to positive */ + c->sign = MP_ZPOS; + +LBL_T: + mp_clear_multi (&t1, &t2, NULL); + return res; +} +#endif diff --git a/libtommath/bn_mp_lshd.c b/libtommath/bn_mp_lshd.c new file mode 100644 index 0000000..398b648 --- /dev/null +++ b/libtommath/bn_mp_lshd.c @@ -0,0 +1,63 @@ +#include +#ifdef BN_MP_LSHD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift left a certain amount of digits */ +int mp_lshd (mp_int * a, int b) +{ + int x, res; + + /* if its less than zero return */ + if (b <= 0) { + return MP_OKAY; + } + + /* grow to fit the new digits */ + if (a->alloc < a->used + b) { + if ((res = mp_grow (a, a->used + b)) != MP_OKAY) { + return res; + } + } + + { + register mp_digit *top, *bottom; + + /* increment the used by the shift amount then copy upwards */ + a->used += b; + + /* top */ + top = a->dp + a->used - 1; + + /* base */ + bottom = a->dp + a->used - 1 - b; + + /* much like mp_rshd this is implemented using a sliding window + * except the window goes the otherway around. Copying from + * the bottom to the top. see bn_mp_rshd.c for more info. + */ + for (x = a->used - 1; x >= b; x--) { + *top-- = *bottom--; + } + + /* zero the lower digits */ + top = a->dp; + for (x = 0; x < b; x++) { + *top++ = 0; + } + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mod.c b/libtommath/bn_mp_mod.c new file mode 100644 index 0000000..75779bb --- /dev/null +++ b/libtommath/bn_mp_mod.c @@ -0,0 +1,44 @@ +#include +#ifdef BN_MP_MOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = a mod b, 0 <= c < b */ +int +mp_mod (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int t; + int res; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_div (a, b, NULL, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + + if (t.sign != b->sign) { + res = mp_add (b, &t, c); + } else { + res = MP_OKAY; + mp_exch (&t, c); + } + + mp_clear (&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_mod_2d.c b/libtommath/bn_mp_mod_2d.c new file mode 100644 index 0000000..589e4ba --- /dev/null +++ b/libtommath/bn_mp_mod_2d.c @@ -0,0 +1,51 @@ +#include +#ifdef BN_MP_MOD_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* calc a value mod 2**b */ +int +mp_mod_2d (mp_int * a, int b, mp_int * c) +{ + int x, res; + + /* if b is <= 0 then zero the int */ + if (b <= 0) { + mp_zero (c); + return MP_OKAY; + } + + /* if the modulus is larger than the value than return */ + if (b >= (int) (a->used * DIGIT_BIT)) { + res = mp_copy (a, c); + return res; + } + + /* copy */ + if ((res = mp_copy (a, c)) != MP_OKAY) { + return res; + } + + /* zero digits above the last digit of the modulus */ + for (x = (b / DIGIT_BIT) + ((b % DIGIT_BIT) == 0 ? 0 : 1); x < c->used; x++) { + c->dp[x] = 0; + } + /* clear the digit that is not completely outside/inside the modulus */ + c->dp[b / DIGIT_BIT] &= + (mp_digit) ((((mp_digit) 1) << (((mp_digit) b) % DIGIT_BIT)) - ((mp_digit) 1)); + mp_clamp (c); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mod_d.c b/libtommath/bn_mp_mod_d.c new file mode 100644 index 0000000..8a2ad24 --- /dev/null +++ b/libtommath/bn_mp_mod_d.c @@ -0,0 +1,23 @@ +#include +#ifdef BN_MP_MOD_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +int +mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) +{ + return mp_div_d(a, b, NULL, c); +} +#endif diff --git a/libtommath/bn_mp_montgomery_calc_normalization.c b/libtommath/bn_mp_montgomery_calc_normalization.c new file mode 100644 index 0000000..0a760cf --- /dev/null +++ b/libtommath/bn_mp_montgomery_calc_normalization.c @@ -0,0 +1,56 @@ +#include +#ifdef BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* + * shifts with subtractions when the result is greater than b. + * + * The method is slightly modified to shift B unconditionally upto just under + * the leading bit of b. This saves alot of multiple precision shifting. + */ +int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) +{ + int x, bits, res; + + /* how many bits of last digit does b use */ + bits = mp_count_bits (b) % DIGIT_BIT; + + + if (b->used > 1) { + if ((res = mp_2expt (a, (b->used - 1) * DIGIT_BIT + bits - 1)) != MP_OKAY) { + return res; + } + } else { + mp_set(a, 1); + bits = 1; + } + + + /* now compute C = A * B mod b */ + for (x = bits - 1; x < (int)DIGIT_BIT; x++) { + if ((res = mp_mul_2 (a, a)) != MP_OKAY) { + return res; + } + if (mp_cmp_mag (a, b) != MP_LT) { + if ((res = s_mp_sub (a, b, a)) != MP_OKAY) { + return res; + } + } + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_montgomery_reduce.c b/libtommath/bn_mp_montgomery_reduce.c new file mode 100644 index 0000000..3095fa7 --- /dev/null +++ b/libtommath/bn_mp_montgomery_reduce.c @@ -0,0 +1,114 @@ +#include +#ifdef BN_MP_MONTGOMERY_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes xR**-1 == x (mod N) via Montgomery Reduction */ +int +mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +{ + int ix, res, digs; + mp_digit mu; + + /* can the fast reduction [comba] method be used? + * + * Note that unlike in mul you're safely allowed *less* + * than the available columns [255 per default] since carries + * are fixed up in the inner loop. + */ + digs = n->used * 2 + 1; + if ((digs < MP_WARRAY) && + n->used < + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_mp_montgomery_reduce (x, n, rho); + } + + /* grow the input as required */ + if (x->alloc < digs) { + if ((res = mp_grow (x, digs)) != MP_OKAY) { + return res; + } + } + x->used = digs; + + for (ix = 0; ix < n->used; ix++) { + /* mu = ai * rho mod b + * + * The value of rho must be precalculated via + * montgomery_setup() such that + * it equals -1/n0 mod b this allows the + * following inner loop to reduce the + * input one digit at a time + */ + mu = (mp_digit) (((mp_word)x->dp[ix]) * ((mp_word)rho) & MP_MASK); + + /* a = a + mu * m * b**i */ + { + register int iy; + register mp_digit *tmpn, *tmpx, u; + register mp_word r; + + /* alias for digits of the modulus */ + tmpn = n->dp; + + /* alias for the digits of x [the input] */ + tmpx = x->dp + ix; + + /* set the carry to zero */ + u = 0; + + /* Multiply and add in place */ + for (iy = 0; iy < n->used; iy++) { + /* compute product and sum */ + r = ((mp_word)mu) * ((mp_word)*tmpn++) + + ((mp_word) u) + ((mp_word) * tmpx); + + /* get carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + + /* fix digit */ + *tmpx++ = (mp_digit)(r & ((mp_word) MP_MASK)); + } + /* At this point the ix'th digit of x should be zero */ + + + /* propagate carries upwards as required*/ + while (u) { + *tmpx += u; + u = *tmpx >> DIGIT_BIT; + *tmpx++ &= MP_MASK; + } + } + } + + /* at this point the n.used'th least + * significant digits of x are all zero + * which means we can shift x to the + * right by n.used digits and the + * residue is unchanged. + */ + + /* x = x/b**n.used */ + mp_clamp(x); + mp_rshd (x, n->used); + + /* if x >= n then x = x - n */ + if (mp_cmp_mag (x, n) != MP_LT) { + return s_mp_sub (x, n, x); + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_montgomery_setup.c b/libtommath/bn_mp_montgomery_setup.c new file mode 100644 index 0000000..9dfc087 --- /dev/null +++ b/libtommath/bn_mp_montgomery_setup.c @@ -0,0 +1,55 @@ +#include +#ifdef BN_MP_MONTGOMERY_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* setups the montgomery reduction stuff */ +int +mp_montgomery_setup (mp_int * n, mp_digit * rho) +{ + mp_digit x, b; + +/* fast inversion mod 2**k + * + * Based on the fact that + * + * XA = 1 (mod 2**n) => (X(2-XA)) A = 1 (mod 2**2n) + * => 2*X*A - X*X*A*A = 1 + * => 2*(1) - (1) = 1 + */ + b = n->dp[0]; + + if ((b & 1) == 0) { + return MP_VAL; + } + + x = (((b + 2) & 4) << 1) + b; /* here x*a==1 mod 2**4 */ + x *= 2 - b * x; /* here x*a==1 mod 2**8 */ +#if !defined(MP_8BIT) + x *= 2 - b * x; /* here x*a==1 mod 2**16 */ +#endif +#if defined(MP_64BIT) || !(defined(MP_8BIT) || defined(MP_16BIT)) + x *= 2 - b * x; /* here x*a==1 mod 2**32 */ +#endif +#ifdef MP_64BIT + x *= 2 - b * x; /* here x*a==1 mod 2**64 */ +#endif + + /* rho = -1/m mod b */ + *rho = (((mp_word)1 << ((mp_word) DIGIT_BIT)) - x) & MP_MASK; + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mul.c b/libtommath/bn_mp_mul.c new file mode 100644 index 0000000..f9cfa09 --- /dev/null +++ b/libtommath/bn_mp_mul.c @@ -0,0 +1,62 @@ +#include +#ifdef BN_MP_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level multiplication (handles sign) */ +int mp_mul (mp_int * a, mp_int * b, mp_int * c) +{ + int res, neg; + neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; + + /* use Toom-Cook? */ +#ifdef BN_MP_TOOM_MUL_C + if (MIN (a->used, b->used) >= TOOM_MUL_CUTOFF) { + res = mp_toom_mul(a, b, c); + } else +#endif +#ifdef BN_MP_KARATSUBA_MUL_C + /* use Karatsuba? */ + if (MIN (a->used, b->used) >= KARATSUBA_MUL_CUTOFF) { + res = mp_karatsuba_mul (a, b, c); + } else +#endif + { + /* can we use the fast multiplier? + * + * The fast multiplier can be used if the output will + * have less than MP_WARRAY digits and the number of + * digits won't affect carry propagation + */ + int digs = a->used + b->used + 1; + +#ifdef BN_FAST_S_MP_MUL_DIGS_C + if ((digs < MP_WARRAY) && + MIN(a->used, b->used) <= + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + res = fast_s_mp_mul_digs (a, b, c, digs); + } else +#endif +#ifdef BN_S_MP_MUL_DIGS_C + res = s_mp_mul (a, b, c); /* uses s_mp_mul_digs */ +#else + res = MP_VAL; +#endif + + } + c->sign = (c->used > 0) ? neg : MP_ZPOS; + return res; +} +#endif diff --git a/libtommath/bn_mp_mul_2.c b/libtommath/bn_mp_mul_2.c new file mode 100644 index 0000000..6936681 --- /dev/null +++ b/libtommath/bn_mp_mul_2.c @@ -0,0 +1,78 @@ +#include +#ifdef BN_MP_MUL_2_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = a*2 */ +int mp_mul_2(mp_int * a, mp_int * b) +{ + int x, res, oldused; + + /* grow to accomodate result */ + if (b->alloc < a->used + 1) { + if ((res = mp_grow (b, a->used + 1)) != MP_OKAY) { + return res; + } + } + + oldused = b->used; + b->used = a->used; + + { + register mp_digit r, rr, *tmpa, *tmpb; + + /* alias for source */ + tmpa = a->dp; + + /* alias for dest */ + tmpb = b->dp; + + /* carry */ + r = 0; + for (x = 0; x < a->used; x++) { + + /* get what will be the *next* carry bit from the + * MSB of the current digit + */ + rr = *tmpa >> ((mp_digit)(DIGIT_BIT - 1)); + + /* now shift up this digit, add in the carry [from the previous] */ + *tmpb++ = ((*tmpa++ << ((mp_digit)1)) | r) & MP_MASK; + + /* copy the carry that would be from the source + * digit into the next iteration + */ + r = rr; + } + + /* new leading digit? */ + if (r != 0) { + /* add a MSB which is always 1 at this point */ + *tmpb = 1; + ++(b->used); + } + + /* now zero any excess digits on the destination + * that we didn't write to + */ + tmpb = b->dp + b->used; + for (x = b->used; x < oldused; x++) { + *tmpb++ = 0; + } + } + b->sign = a->sign; + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mul_2d.c b/libtommath/bn_mp_mul_2d.c new file mode 100644 index 0000000..04cb8dd --- /dev/null +++ b/libtommath/bn_mp_mul_2d.c @@ -0,0 +1,81 @@ +#include +#ifdef BN_MP_MUL_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift left by a certain bit count */ +int mp_mul_2d (mp_int * a, int b, mp_int * c) +{ + mp_digit d; + int res; + + /* copy */ + if (a != c) { + if ((res = mp_copy (a, c)) != MP_OKAY) { + return res; + } + } + + if (c->alloc < (int)(c->used + b/DIGIT_BIT + 1)) { + if ((res = mp_grow (c, c->used + b / DIGIT_BIT + 1)) != MP_OKAY) { + return res; + } + } + + /* shift by as many digits in the bit count */ + if (b >= (int)DIGIT_BIT) { + if ((res = mp_lshd (c, b / DIGIT_BIT)) != MP_OKAY) { + return res; + } + } + + /* shift any bit count < DIGIT_BIT */ + d = (mp_digit) (b % DIGIT_BIT); + if (d != 0) { + register mp_digit *tmpc, shift, mask, r, rr; + register int x; + + /* bitmask for carries */ + mask = (((mp_digit)1) << d) - 1; + + /* shift for msbs */ + shift = DIGIT_BIT - d; + + /* alias */ + tmpc = c->dp; + + /* carry */ + r = 0; + for (x = 0; x < c->used; x++) { + /* get the higher bits of the current word */ + rr = (*tmpc >> shift) & mask; + + /* shift the current word and OR in the carry */ + *tmpc = ((*tmpc << d) | r) & MP_MASK; + ++tmpc; + + /* set the carry to the carry bits of the current word */ + r = rr; + } + + /* set final carry */ + if (r != 0) { + c->dp[(c->used)++] = r; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mul_d.c b/libtommath/bn_mp_mul_d.c new file mode 100644 index 0000000..f936361 --- /dev/null +++ b/libtommath/bn_mp_mul_d.c @@ -0,0 +1,74 @@ +#include +#ifdef BN_MP_MUL_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiply by a digit */ +int +mp_mul_d (mp_int * a, mp_digit b, mp_int * c) +{ + mp_digit u, *tmpa, *tmpc; + mp_word r; + int ix, res, olduse; + + /* make sure c is big enough to hold a*b */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow (c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* get the original destinations used count */ + olduse = c->used; + + /* set the sign */ + c->sign = a->sign; + + /* alias for a->dp [source] */ + tmpa = a->dp; + + /* alias for c->dp [dest] */ + tmpc = c->dp; + + /* zero carry */ + u = 0; + + /* compute columns */ + for (ix = 0; ix < a->used; ix++) { + /* compute product and carry sum for this term */ + r = ((mp_word) u) + ((mp_word)*tmpa++) * ((mp_word)b); + + /* mask off higher bits to get a single digit */ + *tmpc++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* send carry into next iteration */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + + /* store final carry [if any] */ + *tmpc++ = u; + + /* now zero digits above the top */ + while (ix++ < olduse) { + *tmpc++ = 0; + } + + /* set used count */ + c->used = a->used + 1; + mp_clamp(c); + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_mulmod.c b/libtommath/bn_mp_mulmod.c new file mode 100644 index 0000000..d34e90a --- /dev/null +++ b/libtommath/bn_mp_mulmod.c @@ -0,0 +1,37 @@ +#include +#ifdef BN_MP_MULMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a * b (mod c) */ +int +mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_mul (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_n_root.c b/libtommath/bn_mp_n_root.c new file mode 100644 index 0000000..7b11aa2 --- /dev/null +++ b/libtommath/bn_mp_n_root.c @@ -0,0 +1,128 @@ +#include +#ifdef BN_MP_N_ROOT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* find the n'th root of an integer + * + * Result found such that (c)**b <= a and (c+1)**b > a + * + * This algorithm uses Newton's approximation + * x[i+1] = x[i] - f(x[i])/f'(x[i]) + * which will find the root in log(N) time where + * each step involves a fair bit. This is not meant to + * find huge roots [square and cube, etc]. + */ +int mp_n_root (mp_int * a, mp_digit b, mp_int * c) +{ + mp_int t1, t2, t3; + int res, neg; + + /* input must be positive if b is even */ + if ((b & 1) == 0 && a->sign == MP_NEG) { + return MP_VAL; + } + + if ((res = mp_init (&t1)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&t2)) != MP_OKAY) { + goto LBL_T1; + } + + if ((res = mp_init (&t3)) != MP_OKAY) { + goto LBL_T2; + } + + /* if a is negative fudge the sign but keep track */ + neg = a->sign; + a->sign = MP_ZPOS; + + /* t2 = 2 */ + mp_set (&t2, 2); + + do { + /* t1 = t2 */ + if ((res = mp_copy (&t2, &t1)) != MP_OKAY) { + goto LBL_T3; + } + + /* t2 = t1 - ((t1**b - a) / (b * t1**(b-1))) */ + + /* t3 = t1**(b-1) */ + if ((res = mp_expt_d (&t1, b - 1, &t3)) != MP_OKAY) { + goto LBL_T3; + } + + /* numerator */ + /* t2 = t1**b */ + if ((res = mp_mul (&t3, &t1, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + /* t2 = t1**b - a */ + if ((res = mp_sub (&t2, a, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + /* denominator */ + /* t3 = t1**(b-1) * b */ + if ((res = mp_mul_d (&t3, b, &t3)) != MP_OKAY) { + goto LBL_T3; + } + + /* t3 = (t1**b - a)/(b * t1**(b-1)) */ + if ((res = mp_div (&t2, &t3, &t3, NULL)) != MP_OKAY) { + goto LBL_T3; + } + + if ((res = mp_sub (&t1, &t3, &t2)) != MP_OKAY) { + goto LBL_T3; + } + } while (mp_cmp (&t1, &t2) != MP_EQ); + + /* result can be off by a few so check */ + for (;;) { + if ((res = mp_expt_d (&t1, b, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + if (mp_cmp (&t2, a) == MP_GT) { + if ((res = mp_sub_d (&t1, 1, &t1)) != MP_OKAY) { + goto LBL_T3; + } + } else { + break; + } + } + + /* reset the sign of a first */ + a->sign = neg; + + /* set the result */ + mp_exch (&t1, c); + + /* set the sign of the result */ + c->sign = neg; + + res = MP_OKAY; + +LBL_T3:mp_clear (&t3); +LBL_T2:mp_clear (&t2); +LBL_T1:mp_clear (&t1); + return res; +} +#endif diff --git a/libtommath/bn_mp_neg.c b/libtommath/bn_mp_neg.c new file mode 100644 index 0000000..3a991db --- /dev/null +++ b/libtommath/bn_mp_neg.c @@ -0,0 +1,30 @@ +#include +#ifdef BN_MP_NEG_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = -a */ +int mp_neg (mp_int * a, mp_int * b) +{ + int res; + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } + if (mp_iszero(b) != MP_YES) { + b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_or.c b/libtommath/bn_mp_or.c new file mode 100644 index 0000000..dccee7e --- /dev/null +++ b/libtommath/bn_mp_or.c @@ -0,0 +1,46 @@ +#include +#ifdef BN_MP_OR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* OR two ints together */ +int mp_or (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + t.dp[ix] |= x->dp[ix]; + } + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_prime_fermat.c b/libtommath/bn_mp_prime_fermat.c new file mode 100644 index 0000000..fd74dbe --- /dev/null +++ b/libtommath/bn_mp_prime_fermat.c @@ -0,0 +1,58 @@ +#include +#ifdef BN_MP_PRIME_FERMAT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* performs one Fermat test. + * + * If "a" were prime then b**a == b (mod a) since the order of + * the multiplicative sub-group would be phi(a) = a-1. That means + * it would be the same as b**(a mod (a-1)) == b**1 == b (mod a). + * + * Sets result to 1 if the congruence holds, or zero otherwise. + */ +int mp_prime_fermat (mp_int * a, mp_int * b, int *result) +{ + mp_int t; + int err; + + /* default to composite */ + *result = MP_NO; + + /* ensure b > 1 */ + if (mp_cmp_d(b, 1) != MP_GT) { + return MP_VAL; + } + + /* init t */ + if ((err = mp_init (&t)) != MP_OKAY) { + return err; + } + + /* compute t = b**a mod a */ + if ((err = mp_exptmod (b, a, a, &t)) != MP_OKAY) { + goto LBL_T; + } + + /* is it equal to b? */ + if (mp_cmp (&t, b) == MP_EQ) { + *result = MP_YES; + } + + err = MP_OKAY; +LBL_T:mp_clear (&t); + return err; +} +#endif diff --git a/libtommath/bn_mp_prime_is_divisible.c b/libtommath/bn_mp_prime_is_divisible.c new file mode 100644 index 0000000..f85fe7c --- /dev/null +++ b/libtommath/bn_mp_prime_is_divisible.c @@ -0,0 +1,46 @@ +#include +#ifdef BN_MP_PRIME_IS_DIVISIBLE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if an integers is divisible by one + * of the first PRIME_SIZE primes or not + * + * sets result to 0 if not, 1 if yes + */ +int mp_prime_is_divisible (mp_int * a, int *result) +{ + int err, ix; + mp_digit res; + + /* default to not */ + *result = MP_NO; + + for (ix = 0; ix < PRIME_SIZE; ix++) { + /* what is a mod LBL_prime_tab[ix] */ + if ((err = mp_mod_d (a, ltm_prime_tab[ix], &res)) != MP_OKAY) { + return err; + } + + /* is the residue zero? */ + if (res == 0) { + *result = MP_YES; + return MP_OKAY; + } + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_prime_is_prime.c b/libtommath/bn_mp_prime_is_prime.c new file mode 100644 index 0000000..188053a --- /dev/null +++ b/libtommath/bn_mp_prime_is_prime.c @@ -0,0 +1,79 @@ +#include +#ifdef BN_MP_PRIME_IS_PRIME_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* performs a variable number of rounds of Miller-Rabin + * + * Probability of error after t rounds is no more than + + * + * Sets result to 1 if probably prime, 0 otherwise + */ +int mp_prime_is_prime (mp_int * a, int t, int *result) +{ + mp_int b; + int ix, err, res; + + /* default to no */ + *result = MP_NO; + + /* valid value of t? */ + if (t <= 0 || t > PRIME_SIZE) { + return MP_VAL; + } + + /* is the input equal to one of the primes in the table? */ + for (ix = 0; ix < PRIME_SIZE; ix++) { + if (mp_cmp_d(a, ltm_prime_tab[ix]) == MP_EQ) { + *result = 1; + return MP_OKAY; + } + } + + /* first perform trial division */ + if ((err = mp_prime_is_divisible (a, &res)) != MP_OKAY) { + return err; + } + + /* return if it was trivially divisible */ + if (res == MP_YES) { + return MP_OKAY; + } + + /* now perform the miller-rabin rounds */ + if ((err = mp_init (&b)) != MP_OKAY) { + return err; + } + + for (ix = 0; ix < t; ix++) { + /* set the prime */ + mp_set (&b, ltm_prime_tab[ix]); + + if ((err = mp_prime_miller_rabin (a, &b, &res)) != MP_OKAY) { + goto LBL_B; + } + + if (res == MP_NO) { + goto LBL_B; + } + } + + /* passed the test */ + *result = MP_YES; +LBL_B:mp_clear (&b); + return err; +} +#endif diff --git a/libtommath/bn_mp_prime_miller_rabin.c b/libtommath/bn_mp_prime_miller_rabin.c new file mode 100644 index 0000000..758a2c3 --- /dev/null +++ b/libtommath/bn_mp_prime_miller_rabin.c @@ -0,0 +1,99 @@ +#include +#ifdef BN_MP_PRIME_MILLER_RABIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Miller-Rabin test of "a" to the base of "b" as described in + * HAC pp. 139 Algorithm 4.24 + * + * Sets result to 0 if definitely composite or 1 if probably prime. + * Randomly the chance of error is no more than 1/4 and often + * very much lower. + */ +int mp_prime_miller_rabin (mp_int * a, mp_int * b, int *result) +{ + mp_int n1, y, r; + int s, j, err; + + /* default */ + *result = MP_NO; + + /* ensure b > 1 */ + if (mp_cmp_d(b, 1) != MP_GT) { + return MP_VAL; + } + + /* get n1 = a - 1 */ + if ((err = mp_init_copy (&n1, a)) != MP_OKAY) { + return err; + } + if ((err = mp_sub_d (&n1, 1, &n1)) != MP_OKAY) { + goto LBL_N1; + } + + /* set 2**s * r = n1 */ + if ((err = mp_init_copy (&r, &n1)) != MP_OKAY) { + goto LBL_N1; + } + + /* count the number of least significant bits + * which are zero + */ + s = mp_cnt_lsb(&r); + + /* now divide n - 1 by 2**s */ + if ((err = mp_div_2d (&r, s, &r, NULL)) != MP_OKAY) { + goto LBL_R; + } + + /* compute y = b**r mod a */ + if ((err = mp_init (&y)) != MP_OKAY) { + goto LBL_R; + } + if ((err = mp_exptmod (b, &r, a, &y)) != MP_OKAY) { + goto LBL_Y; + } + + /* if y != 1 and y != n1 do */ + if (mp_cmp_d (&y, 1) != MP_EQ && mp_cmp (&y, &n1) != MP_EQ) { + j = 1; + /* while j <= s-1 and y != n1 */ + while ((j <= (s - 1)) && mp_cmp (&y, &n1) != MP_EQ) { + if ((err = mp_sqrmod (&y, a, &y)) != MP_OKAY) { + goto LBL_Y; + } + + /* if y == 1 then composite */ + if (mp_cmp_d (&y, 1) == MP_EQ) { + goto LBL_Y; + } + + ++j; + } + + /* if y != n1 then composite */ + if (mp_cmp (&y, &n1) != MP_EQ) { + goto LBL_Y; + } + } + + /* probably prime now */ + *result = MP_YES; +LBL_Y:mp_clear (&y); +LBL_R:mp_clear (&r); +LBL_N1:mp_clear (&n1); + return err; +} +#endif diff --git a/libtommath/bn_mp_prime_next_prime.c b/libtommath/bn_mp_prime_next_prime.c new file mode 100644 index 0000000..24f93c4 --- /dev/null +++ b/libtommath/bn_mp_prime_next_prime.c @@ -0,0 +1,166 @@ +#include +#ifdef BN_MP_PRIME_NEXT_PRIME_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* finds the next prime after the number "a" using "t" trials + * of Miller-Rabin. + * + * bbs_style = 1 means the prime must be congruent to 3 mod 4 + */ +int mp_prime_next_prime(mp_int *a, int t, int bbs_style) +{ + int err, res, x, y; + mp_digit res_tab[PRIME_SIZE], step, kstep; + mp_int b; + + /* ensure t is valid */ + if (t <= 0 || t > PRIME_SIZE) { + return MP_VAL; + } + + /* force positive */ + a->sign = MP_ZPOS; + + /* simple algo if a is less than the largest prime in the table */ + if (mp_cmp_d(a, ltm_prime_tab[PRIME_SIZE-1]) == MP_LT) { + /* find which prime it is bigger than */ + for (x = PRIME_SIZE - 2; x >= 0; x--) { + if (mp_cmp_d(a, ltm_prime_tab[x]) != MP_LT) { + if (bbs_style == 1) { + /* ok we found a prime smaller or + * equal [so the next is larger] + * + * however, the prime must be + * congruent to 3 mod 4 + */ + if ((ltm_prime_tab[x + 1] & 3) != 3) { + /* scan upwards for a prime congruent to 3 mod 4 */ + for (y = x + 1; y < PRIME_SIZE; y++) { + if ((ltm_prime_tab[y] & 3) == 3) { + mp_set(a, ltm_prime_tab[y]); + return MP_OKAY; + } + } + } + } else { + mp_set(a, ltm_prime_tab[x + 1]); + return MP_OKAY; + } + } + } + /* at this point a maybe 1 */ + if (mp_cmp_d(a, 1) == MP_EQ) { + mp_set(a, 2); + return MP_OKAY; + } + /* fall through to the sieve */ + } + + /* generate a prime congruent to 3 mod 4 or 1/3 mod 4? */ + if (bbs_style == 1) { + kstep = 4; + } else { + kstep = 2; + } + + /* at this point we will use a combination of a sieve and Miller-Rabin */ + + if (bbs_style == 1) { + /* if a mod 4 != 3 subtract the correct value to make it so */ + if ((a->dp[0] & 3) != 3) { + if ((err = mp_sub_d(a, (a->dp[0] & 3) + 1, a)) != MP_OKAY) { return err; }; + } + } else { + if (mp_iseven(a) == 1) { + /* force odd */ + if ((err = mp_sub_d(a, 1, a)) != MP_OKAY) { + return err; + } + } + } + + /* generate the restable */ + for (x = 1; x < PRIME_SIZE; x++) { + if ((err = mp_mod_d(a, ltm_prime_tab[x], res_tab + x)) != MP_OKAY) { + return err; + } + } + + /* init temp used for Miller-Rabin Testing */ + if ((err = mp_init(&b)) != MP_OKAY) { + return err; + } + + for (;;) { + /* skip to the next non-trivially divisible candidate */ + step = 0; + do { + /* y == 1 if any residue was zero [e.g. cannot be prime] */ + y = 0; + + /* increase step to next candidate */ + step += kstep; + + /* compute the new residue without using division */ + for (x = 1; x < PRIME_SIZE; x++) { + /* add the step to each residue */ + res_tab[x] += kstep; + + /* subtract the modulus [instead of using division] */ + if (res_tab[x] >= ltm_prime_tab[x]) { + res_tab[x] -= ltm_prime_tab[x]; + } + + /* set flag if zero */ + if (res_tab[x] == 0) { + y = 1; + } + } + } while (y == 1 && step < ((((mp_digit)1)<= ((((mp_digit)1)< +#ifdef BN_MP_PRIME_RABIN_MILLER_TRIALS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + + +static const struct { + int k, t; +} sizes[] = { +{ 128, 28 }, +{ 256, 16 }, +{ 384, 10 }, +{ 512, 7 }, +{ 640, 6 }, +{ 768, 5 }, +{ 896, 4 }, +{ 1024, 4 } +}; + +/* returns # of RM trials required for a given bit size */ +int mp_prime_rabin_miller_trials(int size) +{ + int x; + + for (x = 0; x < (int)(sizeof(sizes)/(sizeof(sizes[0]))); x++) { + if (sizes[x].k == size) { + return sizes[x].t; + } else if (sizes[x].k > size) { + return (x == 0) ? sizes[0].t : sizes[x - 1].t; + } + } + return sizes[x-1].t + 1; +} + + +#endif diff --git a/libtommath/bn_mp_prime_random_ex.c b/libtommath/bn_mp_prime_random_ex.c new file mode 100644 index 0000000..2010ebe --- /dev/null +++ b/libtommath/bn_mp_prime_random_ex.c @@ -0,0 +1,123 @@ +#include +#ifdef BN_MP_PRIME_RANDOM_EX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* makes a truly random prime of a given size (bits), + * + * Flags are as follows: + * + * LTM_PRIME_BBS - make prime congruent to 3 mod 4 + * LTM_PRIME_SAFE - make sure (p-1)/2 is prime as well (implies LTM_PRIME_BBS) + * LTM_PRIME_2MSB_OFF - make the 2nd highest bit zero + * LTM_PRIME_2MSB_ON - make the 2nd highest bit one + * + * You have to supply a callback which fills in a buffer with random bytes. "dat" is a parameter you can + * have passed to the callback (e.g. a state or something). This function doesn't use "dat" itself + * so it can be NULL + * + */ + +/* This is possibly the mother of all prime generation functions, muahahahahaha! */ +int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback cb, void *dat) +{ + unsigned char *tmp, maskAND, maskOR_msb, maskOR_lsb; + int res, err, bsize, maskOR_msb_offset; + + /* sanity check the input */ + if (size <= 1 || t <= 0) { + return MP_VAL; + } + + /* LTM_PRIME_SAFE implies LTM_PRIME_BBS */ + if (flags & LTM_PRIME_SAFE) { + flags |= LTM_PRIME_BBS; + } + + /* calc the byte size */ + bsize = (size>>3) + ((size&7)?1:0); + + /* we need a buffer of bsize bytes */ + tmp = OPT_CAST(unsigned char) XMALLOC(bsize); + if (tmp == NULL) { + return MP_MEM; + } + + /* calc the maskAND value for the MSbyte*/ + maskAND = ((size&7) == 0) ? 0xFF : (0xFF >> (8 - (size & 7))); + + /* calc the maskOR_msb */ + maskOR_msb = 0; + maskOR_msb_offset = (size - 2) >> 3; + if (flags & LTM_PRIME_2MSB_ON) { + maskOR_msb |= 1 << ((size - 2) & 7); + } else if (flags & LTM_PRIME_2MSB_OFF) { + maskAND &= ~(1 << ((size - 2) & 7)); + } + + /* get the maskOR_lsb */ + maskOR_lsb = 0; + if (flags & LTM_PRIME_BBS) { + maskOR_lsb |= 3; + } + + do { + /* read the bytes */ + if (cb(tmp, bsize, dat) != bsize) { + err = MP_VAL; + goto error; + } + + /* work over the MSbyte */ + tmp[0] &= maskAND; + tmp[0] |= 1 << ((size - 1) & 7); + + /* mix in the maskORs */ + tmp[maskOR_msb_offset] |= maskOR_msb; + tmp[bsize-1] |= maskOR_lsb; + + /* read it in */ + if ((err = mp_read_unsigned_bin(a, tmp, bsize)) != MP_OKAY) { goto error; } + + /* is it prime? */ + if ((err = mp_prime_is_prime(a, t, &res)) != MP_OKAY) { goto error; } + if (res == MP_NO) { + continue; + } + + if (flags & LTM_PRIME_SAFE) { + /* see if (a-1)/2 is prime */ + if ((err = mp_sub_d(a, 1, a)) != MP_OKAY) { goto error; } + if ((err = mp_div_2(a, a)) != MP_OKAY) { goto error; } + + /* is it prime? */ + if ((err = mp_prime_is_prime(a, t, &res)) != MP_OKAY) { goto error; } + } + } while (res == MP_NO); + + if (flags & LTM_PRIME_SAFE) { + /* restore a to the original value */ + if ((err = mp_mul_2(a, a)) != MP_OKAY) { goto error; } + if ((err = mp_add_d(a, 1, a)) != MP_OKAY) { goto error; } + } + + err = MP_OKAY; +error: + XFREE(tmp); + return err; +} + + +#endif diff --git a/libtommath/bn_mp_radix_size.c b/libtommath/bn_mp_radix_size.c new file mode 100644 index 0000000..30b78d9 --- /dev/null +++ b/libtommath/bn_mp_radix_size.c @@ -0,0 +1,67 @@ +#include +#ifdef BN_MP_RADIX_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* returns size of ASCII reprensentation */ +int mp_radix_size (mp_int * a, int radix, int *size) +{ + int res, digs; + mp_int t; + mp_digit d; + + *size = 0; + + /* special case for binary */ + if (radix == 2) { + *size = mp_count_bits (a) + (a->sign == MP_NEG ? 1 : 0) + 1; + return MP_OKAY; + } + + /* make sure the radix is in range */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* init a copy of the input */ + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* digs is the digit count */ + digs = 0; + + /* if it's negative add one for the sign */ + if (t.sign == MP_NEG) { + ++digs; + t.sign = MP_ZPOS; + } + + /* fetch out all of the digits */ + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + ++digs; + } + mp_clear (&t); + + /* return digs + 1, the 1 is for the NULL byte that would be required. */ + *size = digs + 1; + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_radix_smap.c b/libtommath/bn_mp_radix_smap.c new file mode 100644 index 0000000..bc7517d --- /dev/null +++ b/libtommath/bn_mp_radix_smap.c @@ -0,0 +1,20 @@ +#include +#ifdef BN_MP_RADIX_SMAP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* chars used in radix conversions */ +const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz+/"; +#endif diff --git a/libtommath/bn_mp_rand.c b/libtommath/bn_mp_rand.c new file mode 100644 index 0000000..1cc47f1 --- /dev/null +++ b/libtommath/bn_mp_rand.c @@ -0,0 +1,51 @@ +#include +#ifdef BN_MP_RAND_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* makes a pseudo-random int of a given size */ +int +mp_rand (mp_int * a, int digits) +{ + int res; + mp_digit d; + + mp_zero (a); + if (digits <= 0) { + return MP_OKAY; + } + + /* first place a random non-zero digit */ + do { + d = ((mp_digit) abs (rand ())); + } while (d == 0); + + if ((res = mp_add_d (a, d, a)) != MP_OKAY) { + return res; + } + + while (digits-- > 0) { + if ((res = mp_lshd (a, 1)) != MP_OKAY) { + return res; + } + + if ((res = mp_add_d (a, ((mp_digit) abs (rand ())), a)) != MP_OKAY) { + return res; + } + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_read_radix.c b/libtommath/bn_mp_read_radix.c new file mode 100644 index 0000000..704bd0f --- /dev/null +++ b/libtommath/bn_mp_read_radix.c @@ -0,0 +1,78 @@ +#include +#ifdef BN_MP_READ_RADIX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read a string [ASCII] in a given radix */ +int mp_read_radix (mp_int * a, char *str, int radix) +{ + int y, res, neg; + char ch; + + /* make sure the radix is ok */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* if the leading digit is a + * minus set the sign to negative. + */ + if (*str == '-') { + ++str; + neg = MP_NEG; + } else { + neg = MP_ZPOS; + } + + /* set the integer to the default of zero */ + mp_zero (a); + + /* process each digit of the string */ + while (*str) { + /* if the radix < 36 the conversion is case insensitive + * this allows numbers like 1AB and 1ab to represent the same value + * [e.g. in hex] + */ + ch = (char) ((radix < 36) ? toupper (*str) : *str); + for (y = 0; y < 64; y++) { + if (ch == mp_s_rmap[y]) { + break; + } + } + + /* if the char was found in the map + * and is less than the given radix add it + * to the number, otherwise exit the loop. + */ + if (y < radix) { + if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) { + return res; + } + if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) { + return res; + } + } else { + break; + } + ++str; + } + + /* set the sign only if a != 0 */ + if (mp_iszero(a) != 1) { + a->sign = neg; + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_read_signed_bin.c b/libtommath/bn_mp_read_signed_bin.c new file mode 100644 index 0000000..814d6c1 --- /dev/null +++ b/libtommath/bn_mp_read_signed_bin.c @@ -0,0 +1,38 @@ +#include +#ifdef BN_MP_READ_SIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read signed bin, big endian, first byte is 0==positive or 1==negative */ +int +mp_read_signed_bin (mp_int * a, unsigned char *b, int c) +{ + int res; + + /* read magnitude */ + if ((res = mp_read_unsigned_bin (a, b + 1, c - 1)) != MP_OKAY) { + return res; + } + + /* first byte is 0 for positive, non-zero for negative */ + if (b[0] == 0) { + a->sign = MP_ZPOS; + } else { + a->sign = MP_NEG; + } + + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_read_unsigned_bin.c b/libtommath/bn_mp_read_unsigned_bin.c new file mode 100644 index 0000000..946457d --- /dev/null +++ b/libtommath/bn_mp_read_unsigned_bin.c @@ -0,0 +1,52 @@ +#include +#ifdef BN_MP_READ_UNSIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reads a unsigned char array, assumes the msb is stored first [big endian] */ +int +mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) +{ + int res; + + /* make sure there are at least two digits */ + if (a->alloc < 2) { + if ((res = mp_grow(a, 2)) != MP_OKAY) { + return res; + } + } + + /* zero the int */ + mp_zero (a); + + /* read the bytes in */ + while (c-- > 0) { + if ((res = mp_mul_2d (a, 8, a)) != MP_OKAY) { + return res; + } + +#ifndef MP_8BIT + a->dp[0] |= *b++; + a->used += 1; +#else + a->dp[0] = (*b & MP_MASK); + a->dp[1] |= ((*b++ >> 7U) & 1); + a->used += 2; +#endif + } + mp_clamp (a); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_reduce.c b/libtommath/bn_mp_reduce.c new file mode 100644 index 0000000..cfcb55a --- /dev/null +++ b/libtommath/bn_mp_reduce.c @@ -0,0 +1,97 @@ +#include +#ifdef BN_MP_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces x mod m, assumes 0 < x < m**2, mu is + * precomputed via mp_reduce_setup. + * From HAC pp.604 Algorithm 14.42 + */ +int +mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +{ + mp_int q; + int res, um = m->used; + + /* q = x */ + if ((res = mp_init_copy (&q, x)) != MP_OKAY) { + return res; + } + + /* q1 = x / b**(k-1) */ + mp_rshd (&q, um - 1); + + /* according to HAC this optimization is ok */ + if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) { + if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) { + goto CLEANUP; + } + } else { +#ifdef BN_S_MP_MUL_HIGH_DIGS_C + if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + goto CLEANUP; + } +#elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) + if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + goto CLEANUP; + } +#else + { + res = MP_VAL; + goto CLEANUP; + } +#endif + } + + /* q3 = q2 / b**(k+1) */ + mp_rshd (&q, um + 1); + + /* x = x mod b**(k+1), quick (no division) */ + if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) { + goto CLEANUP; + } + + /* q = q * m mod b**(k+1), quick (no division) */ + if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) { + goto CLEANUP; + } + + /* x = x - q */ + if ((res = mp_sub (x, &q, x)) != MP_OKAY) { + goto CLEANUP; + } + + /* If x < 0, add b**(k+1) to it */ + if (mp_cmp_d (x, 0) == MP_LT) { + mp_set (&q, 1); + if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) + goto CLEANUP; + if ((res = mp_add (x, &q, x)) != MP_OKAY) + goto CLEANUP; + } + + /* Back off if it's too big */ + while (mp_cmp (x, m) != MP_LT) { + if ((res = s_mp_sub (x, m, x)) != MP_OKAY) { + goto CLEANUP; + } + } + +CLEANUP: + mp_clear (&q); + + return res; +} +#endif diff --git a/libtommath/bn_mp_reduce_2k.c b/libtommath/bn_mp_reduce_2k.c new file mode 100644 index 0000000..a5a9c74 --- /dev/null +++ b/libtommath/bn_mp_reduce_2k.c @@ -0,0 +1,58 @@ +#include +#ifdef BN_MP_REDUCE_2K_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces a modulo n where n is of the form 2**p - d */ +int +mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +{ + mp_int q; + int p, res; + + if ((res = mp_init(&q)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(n); +top: + /* q = a/2**p, a = a mod 2**p */ + if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (d != 1) { + /* q = q * d */ + if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) { + goto ERR; + } + } + + /* a = a + q */ + if ((res = s_mp_add(a, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (mp_cmp_mag(a, n) != MP_LT) { + s_mp_sub(a, n, a); + goto top; + } + +ERR: + mp_clear(&q); + return res; +} + +#endif diff --git a/libtommath/bn_mp_reduce_2k_l.c b/libtommath/bn_mp_reduce_2k_l.c new file mode 100644 index 0000000..1d7e1f0 --- /dev/null +++ b/libtommath/bn_mp_reduce_2k_l.c @@ -0,0 +1,58 @@ +#include +#ifdef BN_MP_REDUCE_2K_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces a modulo n where n is of the form 2**p - d + This differs from reduce_2k since "d" can be larger + than a single digit. +*/ +int mp_reduce_2k_l(mp_int *a, mp_int *n, mp_int *d) +{ + mp_int q; + int p, res; + + if ((res = mp_init(&q)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(n); +top: + /* q = a/2**p, a = a mod 2**p */ + if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) { + goto ERR; + } + + /* q = q * d */ + if ((res = mp_mul(&q, d, &q)) != MP_OKAY) { + goto ERR; + } + + /* a = a + q */ + if ((res = s_mp_add(a, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (mp_cmp_mag(a, n) != MP_LT) { + s_mp_sub(a, n, a); + goto top; + } + +ERR: + mp_clear(&q); + return res; +} + +#endif diff --git a/libtommath/bn_mp_reduce_2k_setup.c b/libtommath/bn_mp_reduce_2k_setup.c new file mode 100644 index 0000000..5e1fb6e --- /dev/null +++ b/libtommath/bn_mp_reduce_2k_setup.c @@ -0,0 +1,44 @@ +#include +#ifdef BN_MP_REDUCE_2K_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +int +mp_reduce_2k_setup(mp_int *a, mp_digit *d) +{ + int res, p; + mp_int tmp; + + if ((res = mp_init(&tmp)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(a); + if ((res = mp_2expt(&tmp, p)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + *d = tmp.dp[0]; + mp_clear(&tmp); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_reduce_2k_setup_l.c b/libtommath/bn_mp_reduce_2k_setup_l.c new file mode 100644 index 0000000..810a456 --- /dev/null +++ b/libtommath/bn_mp_reduce_2k_setup_l.c @@ -0,0 +1,40 @@ +#include +#ifdef BN_MP_REDUCE_2K_SETUP_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +int mp_reduce_2k_setup_l(mp_int *a, mp_int *d) +{ + int res; + mp_int tmp; + + if ((res = mp_init(&tmp)) != MP_OKAY) { + return res; + } + + if ((res = mp_2expt(&tmp, mp_count_bits(a))) != MP_OKAY) { + goto ERR; + } + + if ((res = s_mp_sub(&tmp, a, d)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear(&tmp); + return res; +} +#endif diff --git a/libtommath/bn_mp_reduce_is_2k.c b/libtommath/bn_mp_reduce_is_2k.c new file mode 100644 index 0000000..fc81397 --- /dev/null +++ b/libtommath/bn_mp_reduce_is_2k.c @@ -0,0 +1,48 @@ +#include +#ifdef BN_MP_REDUCE_IS_2K_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if mp_reduce_2k can be used */ +int mp_reduce_is_2k(mp_int *a) +{ + int ix, iy, iw; + mp_digit iz; + + if (a->used == 0) { + return 0; + } else if (a->used == 1) { + return 1; + } else if (a->used > 1) { + iy = mp_count_bits(a); + iz = 1; + iw = 1; + + /* Test every bit from the second digit up, must be 1 */ + for (ix = DIGIT_BIT; ix < iy; ix++) { + if ((a->dp[iw] & iz) == 0) { + return 0; + } + iz <<= 1; + if (iz > (mp_digit)MP_MASK) { + ++iw; + iz = 1; + } + } + } + return 1; +} + +#endif diff --git a/libtommath/bn_mp_reduce_is_2k_l.c b/libtommath/bn_mp_reduce_is_2k_l.c new file mode 100644 index 0000000..ceba0ed --- /dev/null +++ b/libtommath/bn_mp_reduce_is_2k_l.c @@ -0,0 +1,40 @@ +#include +#ifdef BN_MP_REDUCE_IS_2K_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if reduce_2k_l can be used */ +int mp_reduce_is_2k_l(mp_int *a) +{ + int ix, iy; + + if (a->used == 0) { + return MP_NO; + } else if (a->used == 1) { + return MP_YES; + } else if (a->used > 1) { + /* if more than half of the digits are -1 we're sold */ + for (iy = ix = 0; ix < a->used; ix++) { + if (a->dp[ix] == MP_MASK) { + ++iy; + } + } + return (iy >= (a->used/2)) ? MP_YES : MP_NO; + + } + return MP_NO; +} + +#endif diff --git a/libtommath/bn_mp_reduce_setup.c b/libtommath/bn_mp_reduce_setup.c new file mode 100644 index 0000000..99f158a --- /dev/null +++ b/libtommath/bn_mp_reduce_setup.c @@ -0,0 +1,30 @@ +#include +#ifdef BN_MP_REDUCE_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* pre-calculate the value required for Barrett reduction + * For a given modulus "b" it calulates the value required in "a" + */ +int mp_reduce_setup (mp_int * a, mp_int * b) +{ + int res; + + if ((res = mp_2expt (a, b->used * 2 * DIGIT_BIT)) != MP_OKAY) { + return res; + } + return mp_div (a, b, a, NULL); +} +#endif diff --git a/libtommath/bn_mp_rshd.c b/libtommath/bn_mp_rshd.c new file mode 100644 index 0000000..913dda6 --- /dev/null +++ b/libtommath/bn_mp_rshd.c @@ -0,0 +1,68 @@ +#include +#ifdef BN_MP_RSHD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift right a certain amount of digits */ +void mp_rshd (mp_int * a, int b) +{ + int x; + + /* if b <= 0 then ignore it */ + if (b <= 0) { + return; + } + + /* if b > used then simply zero it and return */ + if (a->used <= b) { + mp_zero (a); + return; + } + + { + register mp_digit *bottom, *top; + + /* shift the digits down */ + + /* bottom */ + bottom = a->dp; + + /* top [offset into digits] */ + top = a->dp + b; + + /* this is implemented as a sliding window where + * the window is b-digits long and digits from + * the top of the window are copied to the bottom + * + * e.g. + + b-2 | b-1 | b0 | b1 | b2 | ... | bb | ----> + /\ | ----> + \-------------------/ ----> + */ + for (x = 0; x < (a->used - b); x++) { + *bottom++ = *top++; + } + + /* zero the top digits */ + for (; x < a->used; x++) { + *bottom++ = 0; + } + } + + /* remove excess digits */ + a->used -= b; +} +#endif diff --git a/libtommath/bn_mp_set.c b/libtommath/bn_mp_set.c new file mode 100644 index 0000000..078fd5f --- /dev/null +++ b/libtommath/bn_mp_set.c @@ -0,0 +1,25 @@ +#include +#ifdef BN_MP_SET_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set to a digit */ +void mp_set (mp_int * a, mp_digit b) +{ + mp_zero (a); + a->dp[0] = b & MP_MASK; + a->used = (a->dp[0] != 0) ? 1 : 0; +} +#endif diff --git a/libtommath/bn_mp_set_int.c b/libtommath/bn_mp_set_int.c new file mode 100644 index 0000000..bd47136 --- /dev/null +++ b/libtommath/bn_mp_set_int.c @@ -0,0 +1,44 @@ +#include +#ifdef BN_MP_SET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set a 32-bit const */ +int mp_set_int (mp_int * a, unsigned long b) +{ + int x, res; + + mp_zero (a); + + /* set four bits at a time */ + for (x = 0; x < 8; x++) { + /* shift the number up four bits */ + if ((res = mp_mul_2d (a, 4, a)) != MP_OKAY) { + return res; + } + + /* OR in the top four bits of the source */ + a->dp[0] |= (b >> 28) & 15; + + /* shift the source up to the next four bits */ + b <<= 4; + + /* ensure that digits are not clamped off */ + a->used += 1; + } + mp_clamp (a); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_shrink.c b/libtommath/bn_mp_shrink.c new file mode 100644 index 0000000..b31f9d2 --- /dev/null +++ b/libtommath/bn_mp_shrink.c @@ -0,0 +1,31 @@ +#include +#ifdef BN_MP_SHRINK_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shrink a bignum */ +int mp_shrink (mp_int * a) +{ + mp_digit *tmp; + if (a->alloc != a->used && a->used > 0) { + if ((tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * a->used)) == NULL) { + return MP_MEM; + } + a->dp = tmp; + a->alloc = a->used; + } + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_signed_bin_size.c b/libtommath/bn_mp_signed_bin_size.c new file mode 100644 index 0000000..30048cb --- /dev/null +++ b/libtommath/bn_mp_signed_bin_size.c @@ -0,0 +1,23 @@ +#include +#ifdef BN_MP_SIGNED_BIN_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the size for an signed equivalent */ +int mp_signed_bin_size (mp_int * a) +{ + return 1 + mp_unsigned_bin_size (a); +} +#endif diff --git a/libtommath/bn_mp_sqr.c b/libtommath/bn_mp_sqr.c new file mode 100644 index 0000000..b1fdb57 --- /dev/null +++ b/libtommath/bn_mp_sqr.c @@ -0,0 +1,54 @@ +#include +#ifdef BN_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes b = a*a */ +int +mp_sqr (mp_int * a, mp_int * b) +{ + int res; + +#ifdef BN_MP_TOOM_SQR_C + /* use Toom-Cook? */ + if (a->used >= TOOM_SQR_CUTOFF) { + res = mp_toom_sqr(a, b); + /* Karatsuba? */ + } else +#endif +#ifdef BN_MP_KARATSUBA_SQR_C +if (a->used >= KARATSUBA_SQR_CUTOFF) { + res = mp_karatsuba_sqr (a, b); + } else +#endif + { +#ifdef BN_FAST_S_MP_SQR_C + /* can we use the fast comba multiplier? */ + if ((a->used * 2 + 1) < MP_WARRAY && + a->used < + (1 << (sizeof(mp_word) * CHAR_BIT - 2*DIGIT_BIT - 1))) { + res = fast_s_mp_sqr (a, b); + } else +#endif +#ifdef BN_S_MP_SQR_C + res = s_mp_sqr (a, b); +#else + res = MP_VAL; +#endif + } + b->sign = MP_ZPOS; + return res; +} +#endif diff --git a/libtommath/bn_mp_sqrmod.c b/libtommath/bn_mp_sqrmod.c new file mode 100644 index 0000000..1923be4 --- /dev/null +++ b/libtommath/bn_mp_sqrmod.c @@ -0,0 +1,37 @@ +#include +#ifdef BN_MP_SQRMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = a * a (mod b) */ +int +mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_sqr (a, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, b, c); + mp_clear (&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_sqrt.c b/libtommath/bn_mp_sqrt.c new file mode 100644 index 0000000..76cec87 --- /dev/null +++ b/libtommath/bn_mp_sqrt.c @@ -0,0 +1,77 @@ +#include +#ifdef BN_MP_SQRT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* this function is less generic than mp_n_root, simpler and faster */ +int mp_sqrt(mp_int *arg, mp_int *ret) +{ + int res; + mp_int t1,t2; + + /* must be positive */ + if (arg->sign == MP_NEG) { + return MP_VAL; + } + + /* easy out */ + if (mp_iszero(arg) == MP_YES) { + mp_zero(ret); + return MP_OKAY; + } + + if ((res = mp_init_copy(&t1, arg)) != MP_OKAY) { + return res; + } + + if ((res = mp_init(&t2)) != MP_OKAY) { + goto E2; + } + + /* First approx. (not very bad for large arg) */ + mp_rshd (&t1,t1.used/2); + + /* t1 > 0 */ + if ((res = mp_div(arg,&t1,&t2,NULL)) != MP_OKAY) { + goto E1; + } + if ((res = mp_add(&t1,&t2,&t1)) != MP_OKAY) { + goto E1; + } + if ((res = mp_div_2(&t1,&t1)) != MP_OKAY) { + goto E1; + } + /* And now t1 > sqrt(arg) */ + do { + if ((res = mp_div(arg,&t1,&t2,NULL)) != MP_OKAY) { + goto E1; + } + if ((res = mp_add(&t1,&t2,&t1)) != MP_OKAY) { + goto E1; + } + if ((res = mp_div_2(&t1,&t1)) != MP_OKAY) { + goto E1; + } + /* t1 >= sqrt(arg) >= t2 at this point */ + } while (mp_cmp_mag(&t1,&t2) == MP_GT); + + mp_exch(&t1,ret); + +E1: mp_clear(&t2); +E2: mp_clear(&t1); + return res; +} + +#endif diff --git a/libtommath/bn_mp_sub.c b/libtommath/bn_mp_sub.c new file mode 100644 index 0000000..97495f4 --- /dev/null +++ b/libtommath/bn_mp_sub.c @@ -0,0 +1,55 @@ +#include +#ifdef BN_MP_SUB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level subtraction (handles signs) */ +int +mp_sub (mp_int * a, mp_int * b, mp_int * c) +{ + int sa, sb, res; + + sa = a->sign; + sb = b->sign; + + if (sa != sb) { + /* subtract a negative from a positive, OR */ + /* subtract a positive from a negative. */ + /* In either case, ADD their magnitudes, */ + /* and use the sign of the first number. */ + c->sign = sa; + res = s_mp_add (a, b, c); + } else { + /* subtract a positive from a positive, OR */ + /* subtract a negative from a negative. */ + /* First, take the difference between their */ + /* magnitudes, then... */ + if (mp_cmp_mag (a, b) != MP_LT) { + /* Copy the sign from the first */ + c->sign = sa; + /* The first has a larger or equal magnitude */ + res = s_mp_sub (a, b, c); + } else { + /* The result has the *opposite* sign from */ + /* the first number. */ + c->sign = (sa == MP_ZPOS) ? MP_NEG : MP_ZPOS; + /* The second has a larger magnitude */ + res = s_mp_sub (b, a, c); + } + } + return res; +} + +#endif diff --git a/libtommath/bn_mp_sub_d.c b/libtommath/bn_mp_sub_d.c new file mode 100644 index 0000000..4923dde --- /dev/null +++ b/libtommath/bn_mp_sub_d.c @@ -0,0 +1,85 @@ +#include +#ifdef BN_MP_SUB_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* single digit subtraction */ +int +mp_sub_d (mp_int * a, mp_digit b, mp_int * c) +{ + mp_digit *tmpa, *tmpc, mu; + int res, ix, oldused; + + /* grow c as required */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* if a is negative just do an unsigned + * addition [with fudged signs] + */ + if (a->sign == MP_NEG) { + a->sign = MP_ZPOS; + res = mp_add_d(a, b, c); + a->sign = c->sign = MP_NEG; + return res; + } + + /* setup regs */ + oldused = c->used; + tmpa = a->dp; + tmpc = c->dp; + + /* if a <= b simply fix the single digit */ + if ((a->used == 1 && a->dp[0] <= b) || a->used == 0) { + if (a->used == 1) { + *tmpc++ = b - *tmpa; + } else { + *tmpc++ = b; + } + ix = 1; + + /* negative/1digit */ + c->sign = MP_NEG; + c->used = 1; + } else { + /* positive/size */ + c->sign = MP_ZPOS; + c->used = a->used; + + /* subtract first digit */ + *tmpc = *tmpa++ - b; + mu = *tmpc >> (sizeof(mp_digit) * CHAR_BIT - 1); + *tmpc++ &= MP_MASK; + + /* handle rest of the digits */ + for (ix = 1; ix < a->used; ix++) { + *tmpc = *tmpa++ - mu; + mu = *tmpc >> (sizeof(mp_digit) * CHAR_BIT - 1); + *tmpc++ &= MP_MASK; + } + } + + /* zero excess digits */ + while (ix++ < oldused) { + *tmpc++ = 0; + } + mp_clamp(c); + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_submod.c b/libtommath/bn_mp_submod.c new file mode 100644 index 0000000..b999c85 --- /dev/null +++ b/libtommath/bn_mp_submod.c @@ -0,0 +1,38 @@ +#include +#ifdef BN_MP_SUBMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a - b (mod c) */ +int +mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_sub (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif diff --git a/libtommath/bn_mp_to_signed_bin.c b/libtommath/bn_mp_to_signed_bin.c new file mode 100644 index 0000000..0e40d0f --- /dev/null +++ b/libtommath/bn_mp_to_signed_bin.c @@ -0,0 +1,30 @@ +#include +#ifdef BN_MP_TO_SIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in signed [big endian] format */ +int +mp_to_signed_bin (mp_int * a, unsigned char *b) +{ + int res; + + if ((res = mp_to_unsigned_bin (a, b + 1)) != MP_OKAY) { + return res; + } + b[0] = (unsigned char) ((a->sign == MP_ZPOS) ? 0 : 1); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_to_signed_bin_n.c b/libtommath/bn_mp_to_signed_bin_n.c new file mode 100644 index 0000000..0f765ee --- /dev/null +++ b/libtommath/bn_mp_to_signed_bin_n.c @@ -0,0 +1,27 @@ +#include +#ifdef BN_MP_TO_SIGNED_BIN_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in signed [big endian] format */ +int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) +{ + if (*outlen < (unsigned long)mp_signed_bin_size(a)) { + return MP_VAL; + } + *outlen = mp_signed_bin_size(a); + return mp_to_signed_bin(a, b); +} +#endif diff --git a/libtommath/bn_mp_to_unsigned_bin.c b/libtommath/bn_mp_to_unsigned_bin.c new file mode 100644 index 0000000..763e346 --- /dev/null +++ b/libtommath/bn_mp_to_unsigned_bin.c @@ -0,0 +1,45 @@ +#include +#ifdef BN_MP_TO_UNSIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in unsigned [big endian] format */ +int +mp_to_unsigned_bin (mp_int * a, unsigned char *b) +{ + int x, res; + mp_int t; + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + x = 0; + while (mp_iszero (&t) == 0) { +#ifndef MP_8BIT + b[x++] = (unsigned char) (t.dp[0] & 255); +#else + b[x++] = (unsigned char) (t.dp[0] | ((t.dp[1] & 0x01) << 7)); +#endif + if ((res = mp_div_2d (&t, 8, &t, NULL)) != MP_OKAY) { + mp_clear (&t); + return res; + } + } + bn_reverse (b, x); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_to_unsigned_bin_n.c b/libtommath/bn_mp_to_unsigned_bin_n.c new file mode 100644 index 0000000..d0256b4 --- /dev/null +++ b/libtommath/bn_mp_to_unsigned_bin_n.c @@ -0,0 +1,27 @@ +#include +#ifdef BN_MP_TO_UNSIGNED_BIN_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in unsigned [big endian] format */ +int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) +{ + if (*outlen < (unsigned long)mp_unsigned_bin_size(a)) { + return MP_VAL; + } + *outlen = mp_unsigned_bin_size(a); + return mp_to_unsigned_bin(a, b); +} +#endif diff --git a/libtommath/bn_mp_toom_mul.c b/libtommath/bn_mp_toom_mul.c new file mode 100644 index 0000000..2d66779 --- /dev/null +++ b/libtommath/bn_mp_toom_mul.c @@ -0,0 +1,279 @@ +#include +#ifdef BN_MP_TOOM_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplication using the Toom-Cook 3-way algorithm + * + * Much more complicated than Karatsuba but has a lower asymptotic running time of + * O(N**1.464). This algorithm is only particularly useful on VERY large + * inputs (we're talking 1000s of digits here...). +*/ +int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) +{ + mp_int w0, w1, w2, w3, w4, tmp1, tmp2, a0, a1, a2, b0, b1, b2; + int res, B; + + /* init temps */ + if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, + &a0, &a1, &a2, &b0, &b1, + &b2, &tmp1, &tmp2, NULL)) != MP_OKAY) { + return res; + } + + /* B */ + B = MIN(a->used, b->used) / 3; + + /* a = a2 * B**2 + a1 * B + a0 */ + if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(a, &a1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a1, B); + mp_mod_2d(&a1, DIGIT_BIT * B, &a1); + + if ((res = mp_copy(a, &a2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a2, B*2); + + /* b = b2 * B**2 + b1 * B + b0 */ + if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(b, &b1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&b1, B); + mp_mod_2d(&b1, DIGIT_BIT * B, &b1); + + if ((res = mp_copy(b, &b2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&b2, B*2); + + /* w0 = a0*b0 */ + if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) { + goto ERR; + } + + /* w4 = a2 * b2 */ + if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) { + goto ERR; + } + + /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ + if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) { + goto ERR; + } + + /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ + if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) { + goto ERR; + } + + + /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ + if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) { + goto ERR; + } + + /* now solve the matrix + + 0 0 0 0 1 + 1 2 4 8 16 + 1 1 1 1 1 + 16 8 4 2 1 + 1 0 0 0 0 + + using 12 subtractions, 4 shifts, + 2 small divisions and 1 small multiplication + */ + + /* r1 - r4 */ + if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r0 */ + if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/2 */ + if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3/2 */ + if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) { + goto ERR; + } + /* r2 - r0 - r4 */ + if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1 - 8r0 */ + if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - 8r4 */ + if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + /* 3r2 - r1 - r3 */ + if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/3 */ + if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) { + goto ERR; + } + /* r3/3 */ + if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) { + goto ERR; + } + + /* at this point shift W[n] by B*n */ + if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear_multi(&w0, &w1, &w2, &w3, &w4, + &a0, &a1, &a2, &b0, &b1, + &b2, &tmp1, &tmp2, NULL); + return res; +} + +#endif diff --git a/libtommath/bn_mp_toom_sqr.c b/libtommath/bn_mp_toom_sqr.c new file mode 100644 index 0000000..8c46fea --- /dev/null +++ b/libtommath/bn_mp_toom_sqr.c @@ -0,0 +1,222 @@ +#include +#ifdef BN_MP_TOOM_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* squaring using Toom-Cook 3-way algorithm */ +int +mp_toom_sqr(mp_int *a, mp_int *b) +{ + mp_int w0, w1, w2, w3, w4, tmp1, a0, a1, a2; + int res, B; + + /* init temps */ + if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, &a0, &a1, &a2, &tmp1, NULL)) != MP_OKAY) { + return res; + } + + /* B */ + B = a->used / 3; + + /* a = a2 * B**2 + a1 * B + a0 */ + if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(a, &a1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a1, B); + mp_mod_2d(&a1, DIGIT_BIT * B, &a1); + + if ((res = mp_copy(a, &a2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a2, B*2); + + /* w0 = a0*a0 */ + if ((res = mp_sqr(&a0, &w0)) != MP_OKAY) { + goto ERR; + } + + /* w4 = a2 * a2 */ + if ((res = mp_sqr(&a2, &w4)) != MP_OKAY) { + goto ERR; + } + + /* w1 = (a2 + 2(a1 + 2a0))**2 */ + if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_sqr(&tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + + /* w3 = (a0 + 2(a1 + 2a2))**2 */ + if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_sqr(&tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + + + /* w2 = (a2 + a1 + a0)**2 */ + if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sqr(&tmp1, &w2)) != MP_OKAY) { + goto ERR; + } + + /* now solve the matrix + + 0 0 0 0 1 + 1 2 4 8 16 + 1 1 1 1 1 + 16 8 4 2 1 + 1 0 0 0 0 + + using 12 subtractions, 4 shifts, 2 small divisions and 1 small multiplication. + */ + + /* r1 - r4 */ + if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r0 */ + if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/2 */ + if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3/2 */ + if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) { + goto ERR; + } + /* r2 - r0 - r4 */ + if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1 - 8r0 */ + if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - 8r4 */ + if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + /* 3r2 - r1 - r3 */ + if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/3 */ + if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) { + goto ERR; + } + /* r3/3 */ + if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) { + goto ERR; + } + + /* at this point shift W[n] by B*n */ + if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_add(&w0, &w1, b)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, b, b)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear_multi(&w0, &w1, &w2, &w3, &w4, &a0, &a1, &a2, &tmp1, NULL); + return res; +} + +#endif diff --git a/libtommath/bn_mp_toradix.c b/libtommath/bn_mp_toradix.c new file mode 100644 index 0000000..a206d5e --- /dev/null +++ b/libtommath/bn_mp_toradix.c @@ -0,0 +1,71 @@ +#include +#ifdef BN_MP_TORADIX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* stores a bignum as a ASCII string in a given radix (2..64) */ +int mp_toradix (mp_int * a, char *str, int radix) +{ + int res, digs; + mp_int t; + mp_digit d; + char *_s = str; + + /* check range of the radix */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* quick out if its zero */ + if (mp_iszero(a) == 1) { + *str++ = '0'; + *str = '\0'; + return MP_OKAY; + } + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* if it is negative output a - */ + if (t.sign == MP_NEG) { + ++_s; + *str++ = '-'; + t.sign = MP_ZPOS; + } + + digs = 0; + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + *str++ = mp_s_rmap[d]; + ++digs; + } + + /* reverse the digits of the string. In this case _s points + * to the first digit [exluding the sign] of the number] + */ + bn_reverse ((unsigned char *)_s, digs); + + /* append a NULL so the string is properly terminated */ + *str = '\0'; + + mp_clear (&t); + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_toradix_n.c b/libtommath/bn_mp_toradix_n.c new file mode 100644 index 0000000..7d43558 --- /dev/null +++ b/libtommath/bn_mp_toradix_n.c @@ -0,0 +1,85 @@ +#include +#ifdef BN_MP_TORADIX_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* stores a bignum as a ASCII string in a given radix (2..64) + * + * Stores upto maxlen-1 chars and always a NULL byte + */ +int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) +{ + int res, digs; + mp_int t; + mp_digit d; + char *_s = str; + + /* check range of the maxlen, radix */ + if (maxlen < 3 || radix < 2 || radix > 64) { + return MP_VAL; + } + + /* quick out if its zero */ + if (mp_iszero(a) == 1) { + *str++ = '0'; + *str = '\0'; + return MP_OKAY; + } + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* if it is negative output a - */ + if (t.sign == MP_NEG) { + /* we have to reverse our digits later... but not the - sign!! */ + ++_s; + + /* store the flag and mark the number as positive */ + *str++ = '-'; + t.sign = MP_ZPOS; + + /* subtract a char */ + --maxlen; + } + + digs = 0; + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + *str++ = mp_s_rmap[d]; + ++digs; + + if (--maxlen == 1) { + /* no more room */ + break; + } + } + + /* reverse the digits of the string. In this case _s points + * to the first digit [exluding the sign] of the number] + */ + bn_reverse ((unsigned char *)_s, digs); + + /* append a NULL so the string is properly terminated */ + *str = '\0'; + + mp_clear (&t); + return MP_OKAY; +} + +#endif diff --git a/libtommath/bn_mp_unsigned_bin_size.c b/libtommath/bn_mp_unsigned_bin_size.c new file mode 100644 index 0000000..80da415 --- /dev/null +++ b/libtommath/bn_mp_unsigned_bin_size.c @@ -0,0 +1,25 @@ +#include +#ifdef BN_MP_UNSIGNED_BIN_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the size for an unsigned equivalent */ +int +mp_unsigned_bin_size (mp_int * a) +{ + int size = mp_count_bits (a); + return (size / 8 + ((size & 7) != 0 ? 1 : 0)); +} +#endif diff --git a/libtommath/bn_mp_xor.c b/libtommath/bn_mp_xor.c new file mode 100644 index 0000000..192aacc --- /dev/null +++ b/libtommath/bn_mp_xor.c @@ -0,0 +1,47 @@ +#include +#ifdef BN_MP_XOR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* XOR two ints together */ +int +mp_xor (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + + } + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_mp_zero.c b/libtommath/bn_mp_zero.c new file mode 100644 index 0000000..0097598 --- /dev/null +++ b/libtommath/bn_mp_zero.c @@ -0,0 +1,26 @@ +#include +#ifdef BN_MP_ZERO_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set to zero */ +void +mp_zero (mp_int * a) +{ + a->sign = MP_ZPOS; + a->used = 0; + memset (a->dp, 0, sizeof (mp_digit) * a->alloc); +} +#endif diff --git a/libtommath/bn_prime_tab.c b/libtommath/bn_prime_tab.c new file mode 100644 index 0000000..14306c2 --- /dev/null +++ b/libtommath/bn_prime_tab.c @@ -0,0 +1,57 @@ +#include +#ifdef BN_PRIME_TAB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +const mp_digit ltm_prime_tab[] = { + 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, + 0x0017, 0x001D, 0x001F, 0x0025, 0x0029, 0x002B, 0x002F, 0x0035, + 0x003B, 0x003D, 0x0043, 0x0047, 0x0049, 0x004F, 0x0053, 0x0059, + 0x0061, 0x0065, 0x0067, 0x006B, 0x006D, 0x0071, 0x007F, +#ifndef MP_8BIT + 0x0083, + 0x0089, 0x008B, 0x0095, 0x0097, 0x009D, 0x00A3, 0x00A7, 0x00AD, + 0x00B3, 0x00B5, 0x00BF, 0x00C1, 0x00C5, 0x00C7, 0x00D3, 0x00DF, + 0x00E3, 0x00E5, 0x00E9, 0x00EF, 0x00F1, 0x00FB, 0x0101, 0x0107, + 0x010D, 0x010F, 0x0115, 0x0119, 0x011B, 0x0125, 0x0133, 0x0137, + + 0x0139, 0x013D, 0x014B, 0x0151, 0x015B, 0x015D, 0x0161, 0x0167, + 0x016F, 0x0175, 0x017B, 0x017F, 0x0185, 0x018D, 0x0191, 0x0199, + 0x01A3, 0x01A5, 0x01AF, 0x01B1, 0x01B7, 0x01BB, 0x01C1, 0x01C9, + 0x01CD, 0x01CF, 0x01D3, 0x01DF, 0x01E7, 0x01EB, 0x01F3, 0x01F7, + 0x01FD, 0x0209, 0x020B, 0x021D, 0x0223, 0x022D, 0x0233, 0x0239, + 0x023B, 0x0241, 0x024B, 0x0251, 0x0257, 0x0259, 0x025F, 0x0265, + 0x0269, 0x026B, 0x0277, 0x0281, 0x0283, 0x0287, 0x028D, 0x0293, + 0x0295, 0x02A1, 0x02A5, 0x02AB, 0x02B3, 0x02BD, 0x02C5, 0x02CF, + + 0x02D7, 0x02DD, 0x02E3, 0x02E7, 0x02EF, 0x02F5, 0x02F9, 0x0301, + 0x0305, 0x0313, 0x031D, 0x0329, 0x032B, 0x0335, 0x0337, 0x033B, + 0x033D, 0x0347, 0x0355, 0x0359, 0x035B, 0x035F, 0x036D, 0x0371, + 0x0373, 0x0377, 0x038B, 0x038F, 0x0397, 0x03A1, 0x03A9, 0x03AD, + 0x03B3, 0x03B9, 0x03C7, 0x03CB, 0x03D1, 0x03D7, 0x03DF, 0x03E5, + 0x03F1, 0x03F5, 0x03FB, 0x03FD, 0x0407, 0x0409, 0x040F, 0x0419, + 0x041B, 0x0425, 0x0427, 0x042D, 0x043F, 0x0443, 0x0445, 0x0449, + 0x044F, 0x0455, 0x045D, 0x0463, 0x0469, 0x047F, 0x0481, 0x048B, + + 0x0493, 0x049D, 0x04A3, 0x04A9, 0x04B1, 0x04BD, 0x04C1, 0x04C7, + 0x04CD, 0x04CF, 0x04D5, 0x04E1, 0x04EB, 0x04FD, 0x04FF, 0x0503, + 0x0509, 0x050B, 0x0511, 0x0515, 0x0517, 0x051B, 0x0527, 0x0529, + 0x052F, 0x0551, 0x0557, 0x055D, 0x0565, 0x0577, 0x0581, 0x058F, + 0x0593, 0x0595, 0x0599, 0x059F, 0x05A7, 0x05AB, 0x05AD, 0x05B3, + 0x05BF, 0x05C9, 0x05CB, 0x05CF, 0x05D1, 0x05D5, 0x05DB, 0x05E7, + 0x05F3, 0x05FB, 0x0607, 0x060D, 0x0611, 0x0617, 0x061F, 0x0623, + 0x062B, 0x062F, 0x063D, 0x0641, 0x0647, 0x0649, 0x064D, 0x0653 +#endif +}; +#endif diff --git a/libtommath/bn_reverse.c b/libtommath/bn_reverse.c new file mode 100644 index 0000000..851a6e8 --- /dev/null +++ b/libtommath/bn_reverse.c @@ -0,0 +1,35 @@ +#include +#ifdef BN_REVERSE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reverse an array, used for radix code */ +void +bn_reverse (unsigned char *s, int len) +{ + int ix, iy; + unsigned char t; + + ix = 0; + iy = len - 1; + while (ix < iy) { + t = s[ix]; + s[ix] = s[iy]; + s[iy] = t; + ++ix; + --iy; + } +} +#endif diff --git a/libtommath/bn_s_mp_add.c b/libtommath/bn_s_mp_add.c new file mode 100644 index 0000000..2b378ae --- /dev/null +++ b/libtommath/bn_s_mp_add.c @@ -0,0 +1,105 @@ +#include +#ifdef BN_S_MP_ADD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level addition, based on HAC pp.594, Algorithm 14.7 */ +int +s_mp_add (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int *x; + int olduse, res, min, max; + + /* find sizes, we let |a| <= |b| which means we have to sort + * them. "x" will point to the input with the most digits + */ + if (a->used > b->used) { + min = b->used; + max = a->used; + x = a; + } else { + min = a->used; + max = b->used; + x = b; + } + + /* init result */ + if (c->alloc < max + 1) { + if ((res = mp_grow (c, max + 1)) != MP_OKAY) { + return res; + } + } + + /* get old used digit count and set new one */ + olduse = c->used; + c->used = max + 1; + + { + register mp_digit u, *tmpa, *tmpb, *tmpc; + register int i; + + /* alias for digit pointers */ + + /* first input */ + tmpa = a->dp; + + /* second input */ + tmpb = b->dp; + + /* destination */ + tmpc = c->dp; + + /* zero the carry */ + u = 0; + for (i = 0; i < min; i++) { + /* Compute the sum at one digit, T[i] = A[i] + B[i] + U */ + *tmpc = *tmpa++ + *tmpb++ + u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)DIGIT_BIT); + + /* take away carry bit from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* now copy higher words if any, that is in A+B + * if A or B has more digits add those in + */ + if (min != max) { + for (; i < max; i++) { + /* T[i] = X[i] + U */ + *tmpc = x->dp[i] + u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)DIGIT_BIT); + + /* take away carry bit from T[i] */ + *tmpc++ &= MP_MASK; + } + } + + /* add carry */ + *tmpc++ = u; + + /* clear digits above oldused */ + for (i = c->used; i < olduse; i++) { + *tmpc++ = 0; + } + } + + mp_clamp (c); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_s_mp_exptmod.c b/libtommath/bn_s_mp_exptmod.c new file mode 100644 index 0000000..01a766f --- /dev/null +++ b/libtommath/bn_s_mp_exptmod.c @@ -0,0 +1,236 @@ +#include +#ifdef BN_S_MP_EXPTMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +#ifdef MP_LOW_MEM + #define TAB_SIZE 32 +#else + #define TAB_SIZE 256 +#endif + +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +{ + mp_int M[TAB_SIZE], res, mu; + mp_digit buf; + int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + + /* find window size */ + x = mp_count_bits (X); + if (x <= 7) { + winsize = 2; + } else if (x <= 36) { + winsize = 3; + } else if (x <= 140) { + winsize = 4; + } else if (x <= 450) { + winsize = 5; + } else if (x <= 1303) { + winsize = 6; + } else if (x <= 3529) { + winsize = 7; + } else { + winsize = 8; + } + +#ifdef MP_LOW_MEM + if (winsize > 5) { + winsize = 5; + } +#endif + + /* init M array */ + /* init first cell */ + if ((err = mp_init(&M[1])) != MP_OKAY) { + return err; + } + + /* now init the second half of the array */ + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + if ((err = mp_init(&M[x])) != MP_OKAY) { + for (y = 1<<(winsize-1); y < x; y++) { + mp_clear (&M[y]); + } + mp_clear(&M[1]); + return err; + } + } + + /* create mu, used for Barrett reduction */ + if ((err = mp_init (&mu)) != MP_OKAY) { + goto LBL_M; + } + if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { + goto LBL_MU; + } + + /* create M table + * + * The M table contains powers of the base, + * e.g. M[x] = G**x mod P + * + * The first half of the table is not + * computed though accept for M[0] and M[1] + */ + if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) { + goto LBL_MU; + } + + /* compute the value at M[1<<(winsize-1)] by squaring + * M[1] (winsize-1) times + */ + if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_MU; + } + + for (x = 0; x < (winsize - 1); x++) { + if ((err = mp_sqr (&M[1 << (winsize - 1)], + &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_MU; + } + if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) + * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) + */ + for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) { + if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { + goto LBL_MU; + } + if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* setup result */ + if ((err = mp_init (&res)) != MP_OKAY) { + goto LBL_MU; + } + mp_set (&res, 1); + + /* set initial mode and bit cnt */ + mode = 0; + bitcnt = 1; + buf = 0; + digidx = X->used - 1; + bitcpy = 0; + bitbuf = 0; + + for (;;) { + /* grab next digit as required */ + if (--bitcnt == 0) { + /* if digidx == -1 we are out of digits */ + if (digidx == -1) { + break; + } + /* read next digit and reset the bitcnt */ + buf = X->dp[digidx--]; + bitcnt = (int) DIGIT_BIT; + } + + /* grab the next msb from the exponent */ + y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; + buf <<= (mp_digit)1; + + /* if the bit is zero and mode == 0 then we ignore it + * These represent the leading zero bits before the first 1 bit + * in the exponent. Technically this opt is not required but it + * does lower the # of trivial squaring/reductions used + */ + if (mode == 0 && y == 0) { + continue; + } + + /* if the bit is zero and mode == 1 then we square */ + if (mode == 1 && y == 0) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + continue; + } + + /* else we add it to the window */ + bitbuf |= (y << (winsize - ++bitcpy)); + mode = 2; + + if (bitcpy == winsize) { + /* ok window is filled so square as required and multiply */ + /* square first */ + for (x = 0; x < winsize; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* then multiply */ + if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + + /* empty window and reset */ + bitcpy = 0; + bitbuf = 0; + mode = 1; + } + } + + /* if bits remain then square/multiply */ + if (mode == 2 && bitcpy > 0) { + /* square then multiply if the bit is set */ + for (x = 0; x < bitcpy; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + + bitbuf <<= 1; + if ((bitbuf & (1 << winsize)) != 0) { + /* then multiply */ + if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + } + } + } + + mp_exch (&res, Y); + err = MP_OKAY; +LBL_RES:mp_clear (&res); +LBL_MU:mp_clear (&mu); +LBL_M: + mp_clear(&M[1]); + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + mp_clear (&M[x]); + } + return err; +} +#endif diff --git a/libtommath/bn_s_mp_mul_digs.c b/libtommath/bn_s_mp_mul_digs.c new file mode 100644 index 0000000..d9f0a56 --- /dev/null +++ b/libtommath/bn_s_mp_mul_digs.c @@ -0,0 +1,87 @@ +#include +#ifdef BN_S_MP_MUL_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplies |a| * |b| and only computes upto digs digits of result + * HAC pp. 595, Algorithm 14.12 Modified so you can control how + * many digits of output are created. + */ +int +s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + mp_int t; + int res, pa, pb, ix, iy; + mp_digit u; + mp_word r; + mp_digit tmpx, *tmpt, *tmpy; + + /* can we use the fast multiplier? */ + if (((digs) < MP_WARRAY) && + MIN (a->used, b->used) < + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_s_mp_mul_digs (a, b, c, digs); + } + + if ((res = mp_init_size (&t, digs)) != MP_OKAY) { + return res; + } + t.used = digs; + + /* compute the digits of the product directly */ + pa = a->used; + for (ix = 0; ix < pa; ix++) { + /* set the carry to zero */ + u = 0; + + /* limit ourselves to making digs digits of output */ + pb = MIN (b->used, digs - ix); + + /* setup some aliases */ + /* copy of the digit from a used within the nested loop */ + tmpx = a->dp[ix]; + + /* an alias for the destination shifted ix places */ + tmpt = t.dp + ix; + + /* an alias for the digits of b */ + tmpy = b->dp; + + /* compute the columns of the output and propagate the carry */ + for (iy = 0; iy < pb; iy++) { + /* compute the column as a mp_word */ + r = ((mp_word)*tmpt) + + ((mp_word)tmpx) * ((mp_word)*tmpy++) + + ((mp_word) u); + + /* the new column is the lower part of the result */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get the carry word from the result */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + /* set carry if it is placed below digs */ + if (ix + iy < digs) { + *tmpt = u; + } + } + + mp_clamp (&t); + mp_exch (&t, c); + + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_s_mp_mul_high_digs.c b/libtommath/bn_s_mp_mul_high_digs.c new file mode 100644 index 0000000..a060248 --- /dev/null +++ b/libtommath/bn_s_mp_mul_high_digs.c @@ -0,0 +1,77 @@ +#include +#ifdef BN_S_MP_MUL_HIGH_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplies |a| * |b| and does not compute the lower digs digits + * [meant to get the higher part of the product] + */ +int +s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + mp_int t; + int res, pa, pb, ix, iy; + mp_digit u; + mp_word r; + mp_digit tmpx, *tmpt, *tmpy; + + /* can we use the fast multiplier? */ +#ifdef BN_FAST_S_MP_MUL_HIGH_DIGS_C + if (((a->used + b->used + 1) < MP_WARRAY) + && MIN (a->used, b->used) < (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_s_mp_mul_high_digs (a, b, c, digs); + } +#endif + + if ((res = mp_init_size (&t, a->used + b->used + 1)) != MP_OKAY) { + return res; + } + t.used = a->used + b->used + 1; + + pa = a->used; + pb = b->used; + for (ix = 0; ix < pa; ix++) { + /* clear the carry */ + u = 0; + + /* left hand side of A[ix] * B[iy] */ + tmpx = a->dp[ix]; + + /* alias to the address of where the digits will be stored */ + tmpt = &(t.dp[digs]); + + /* alias for where to read the right hand side from */ + tmpy = b->dp + (digs - ix); + + for (iy = digs - ix; iy < pb; iy++) { + /* calculate the double precision result */ + r = ((mp_word)*tmpt) + + ((mp_word)tmpx) * ((mp_word)*tmpy++) + + ((mp_word) u); + + /* get the lower part */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* carry the carry */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + *tmpt = u; + } + mp_clamp (&t); + mp_exch (&t, c); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_s_mp_sqr.c b/libtommath/bn_s_mp_sqr.c new file mode 100644 index 0000000..4d12804 --- /dev/null +++ b/libtommath/bn_s_mp_sqr.c @@ -0,0 +1,81 @@ +#include +#ifdef BN_S_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ +int +s_mp_sqr (mp_int * a, mp_int * b) +{ + mp_int t; + int res, ix, iy, pa; + mp_word r; + mp_digit u, tmpx, *tmpt; + + pa = a->used; + if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) { + return res; + } + + /* default used is maximum possible size */ + t.used = 2*pa + 1; + + for (ix = 0; ix < pa; ix++) { + /* first calculate the digit at 2*ix */ + /* calculate double precision result */ + r = ((mp_word) t.dp[2*ix]) + + ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); + + /* store lower part in result */ + t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get the carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + + /* left hand side of A[ix] * A[iy] */ + tmpx = a->dp[ix]; + + /* alias for where to store the results */ + tmpt = t.dp + (2*ix + 1); + + for (iy = ix + 1; iy < pa; iy++) { + /* first calculate the product */ + r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); + + /* now calculate the double precision result, note we use + * addition instead of *2 since it's easier to optimize + */ + r = ((mp_word) *tmpt) + r + r + ((mp_word) u); + + /* store lower part */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + } + /* propagate upwards */ + while (u != ((mp_digit) 0)) { + r = ((mp_word) *tmpt) + ((mp_word) u); + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + } + } + + mp_clamp (&t); + mp_exch (&t, b); + mp_clear (&t); + return MP_OKAY; +} +#endif diff --git a/libtommath/bn_s_mp_sub.c b/libtommath/bn_s_mp_sub.c new file mode 100644 index 0000000..5b7aef9 --- /dev/null +++ b/libtommath/bn_s_mp_sub.c @@ -0,0 +1,85 @@ +#include +#ifdef BN_S_MP_SUB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ +int +s_mp_sub (mp_int * a, mp_int * b, mp_int * c) +{ + int olduse, res, min, max; + + /* find sizes */ + min = b->used; + max = a->used; + + /* init result */ + if (c->alloc < max) { + if ((res = mp_grow (c, max)) != MP_OKAY) { + return res; + } + } + olduse = c->used; + c->used = max; + + { + register mp_digit u, *tmpa, *tmpb, *tmpc; + register int i; + + /* alias for digit pointers */ + tmpa = a->dp; + tmpb = b->dp; + tmpc = c->dp; + + /* set carry to zero */ + u = 0; + for (i = 0; i < min; i++) { + /* T[i] = A[i] - B[i] - U */ + *tmpc = *tmpa++ - *tmpb++ - u; + + /* U = carry bit of T[i] + * Note this saves performing an AND operation since + * if a carry does occur it will propagate all the way to the + * MSB. As a result a single shift is enough to get the carry + */ + u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); + + /* Clear carry from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* now copy higher words if any, e.g. if A has more digits than B */ + for (; i < max; i++) { + /* T[i] = A[i] - U */ + *tmpc = *tmpa++ - u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); + + /* Clear carry from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* clear digits above used (since we may not have grown result above) */ + for (i = c->used; i < olduse; i++) { + *tmpc++ = 0; + } + } + + mp_clamp (c); + return MP_OKAY; +} + +#endif diff --git a/libtommath/bncore.c b/libtommath/bncore.c new file mode 100644 index 0000000..cf8a15a --- /dev/null +++ b/libtommath/bncore.c @@ -0,0 +1,31 @@ +#include +#ifdef BNCORE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Known optimal configurations + + CPU /Compiler /MUL CUTOFF/SQR CUTOFF +------------------------------------------------------------- + Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) + +*/ + +int KARATSUBA_MUL_CUTOFF = 88, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 128, /* Min. number of digits before Karatsuba squaring is used. */ + + TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ + TOOM_SQR_CUTOFF = 400; +#endif diff --git a/libtommath/booker.pl b/libtommath/booker.pl new file mode 100644 index 0000000..5c77e53 --- /dev/null +++ b/libtommath/booker.pl @@ -0,0 +1,262 @@ +#!/bin/perl +# +#Used to prepare the book "tommath.src" for LaTeX by pre-processing it into a .tex file +# +#Essentially you write the "tommath.src" as normal LaTex except where you want code snippets you put +# +#EXAM,file +# +#This preprocessor will then open "file" and insert it as a verbatim copy. +# +#Tom St Denis + +#get graphics type +if (shift =~ /PDF/) { + $graph = ""; +} else { + $graph = ".ps"; +} + +open(IN,"tommath.tex") or die "Can't open destination file"; + +print "Scanning for sections\n"; +$chapter = $section = $subsection = 0; +$x = 0; +while () { + print "."; + if (!(++$x % 80)) { print "\n"; } + #update the headings + if (~($_ =~ /\*/)) { + if ($_ =~ /\\chapter{.+}/) { + ++$chapter; + $section = $subsection = 0; + } elsif ($_ =~ /\\section{.+}/) { + ++$section; + $subsection = 0; + } elsif ($_ =~ /\\subsection{.+}/) { + ++$subsection; + } + } + + if ($_ =~ m/MARK/) { + @m = split(",",$_); + chomp(@m[1]); + $index1{@m[1]} = $chapter; + $index2{@m[1]} = $section; + $index3{@m[1]} = $subsection; + } +} +close(IN); + +open(IN,") { + ++$readline; + ++$srcline; + + if ($_ =~ m/MARK/) { + } elsif ($_ =~ m/EXAM/ || $_ =~ m/LIST/) { + if ($_ =~ m/EXAM/) { + $skipheader = 1; + } else { + $skipheader = 0; + } + + # EXAM,file + chomp($_); + @m = split(",",$_); + open(SRC,"<$m[1]") or die "Error:$srcline:Can't open source file $m[1]"; + + print "$srcline:Inserting $m[1]:"; + + $line = 0; + $tmp = $m[1]; + $tmp =~ s/_/"\\_"/ge; + print OUT "\\vspace{+3mm}\\begin{small}\n\\hspace{-5.1mm}{\\bf File}: $tmp\n\\vspace{-3mm}\n\\begin{alltt}\n"; + $wroteline += 5; + + if ($skipheader == 1) { + # scan till next end of comment, e.g. skip license + while () { + $text[$line++] = $_; + last if ($_ =~ /math\.libtomcrypt\.org/); + } + ; + } + + $inline = 0; + while () { + $text[$line++] = $_; + ++$inline; + chomp($_); + $_ =~ s/\t/" "/ge; + $_ =~ s/{/"^{"/ge; + $_ =~ s/}/"^}"/ge; + $_ =~ s/\\/'\symbol{92}'/ge; + $_ =~ s/\^/"\\"/ge; + + printf OUT ("%03d ", $line); + for ($x = 0; $x < length($_); $x++) { + print OUT chr(vec($_, $x, 8)); + if ($x == 75) { + print OUT "\n "; + ++$wroteline; + } + } + print OUT "\n"; + ++$wroteline; + } + $totlines = $line; + print OUT "\\end{alltt}\n\\end{small}\n"; + close(SRC); + print "$inline lines\n"; + $wroteline += 2; + } elsif ($_ =~ m/@\d+,.+@/) { + # line contains [number,text] + # e.g. @14,for (ix = 0)@ + $txt = $_; + while ($txt =~ m/@\d+,.+@/) { + @m = split("@",$txt); # splits into text, one, two + @parms = split(",",$m[1]); # splits one,two into two elements + + # now search from $parms[0] down for $parms[1] + $found1 = 0; + $found2 = 0; + for ($i = $parms[0]; $i < $totlines && $found1 == 0; $i++) { + if ($text[$i] =~ m/\Q$parms[1]\E/) { + $foundline1 = $i + 1; + $found1 = 1; + } + } + + # now search backwards + for ($i = $parms[0] - 1; $i >= 0 && $found2 == 0; $i--) { + if ($text[$i] =~ m/\Q$parms[1]\E/) { + $foundline2 = $i + 1; + $found2 = 1; + } + } + + # now use the closest match or the first if tied + if ($found1 == 1 && $found2 == 0) { + $found = 1; + $foundline = $foundline1; + } elsif ($found1 == 0 && $found2 == 1) { + $found = 1; + $foundline = $foundline2; + } elsif ($found1 == 1 && $found2 == 1) { + $found = 1; + if (($foundline1 - $parms[0]) <= ($parms[0] - $foundline2)) { + $foundline = $foundline1; + } else { + $foundline = $foundline2; + } + } else { + $found = 0; + } + + # if found replace + if ($found == 1) { + $delta = $parms[0] - $foundline; + print "Found replacement tag for \"$parms[1]\" on line $srcline which refers to line $foundline (delta $delta)\n"; + $_ =~ s/@\Q$m[1]\E@/$foundline/; + } else { + print "ERROR: The tag \"$parms[1]\" on line $srcline was not found in the most recently parsed source!\n"; + } + + # remake the rest of the line + $cnt = @m; + $txt = ""; + for ($i = 2; $i < $cnt; $i++) { + $txt = $txt . $m[$i] . "@"; + } + } + print OUT $_; + ++$wroteline; + } elsif ($_ =~ /~.+~/) { + # line contains a ~text~ pair used to refer to indexing :-) + $txt = $_; + while ($txt =~ /~.+~/) { + @m = split("~", $txt); + + # word is the second position + $word = @m[1]; + $a = $index1{$word}; + $b = $index2{$word}; + $c = $index3{$word}; + + # if chapter (a) is zero it wasn't found + if ($a == 0) { + print "ERROR: the tag \"$word\" on line $srcline was not found previously marked.\n"; + } else { + # format the tag as x, x.y or x.y.z depending on the values + $str = $a; + $str = $str . ".$b" if ($b != 0); + $str = $str . ".$c" if ($c != 0); + + if ($b == 0 && $c == 0) { + # its a chapter + if ($a <= 10) { + if ($a == 1) { + $str = "chapter one"; + } elsif ($a == 2) { + $str = "chapter two"; + } elsif ($a == 3) { + $str = "chapter three"; + } elsif ($a == 4) { + $str = "chapter four"; + } elsif ($a == 5) { + $str = "chapter five"; + } elsif ($a == 6) { + $str = "chapter six"; + } elsif ($a == 7) { + $str = "chapter seven"; + } elsif ($a == 8) { + $str = "chapter eight"; + } elsif ($a == 9) { + $str = "chapter nine"; + } elsif ($a == 2) { + $str = "chapter ten"; + } + } else { + $str = "chapter " . $str; + } + } else { + $str = "section " . $str if ($b != 0 && $c == 0); + $str = "sub-section " . $str if ($b != 0 && $c != 0); + } + + #substitute + $_ =~ s/~\Q$word\E~/$str/; + + print "Found replacement tag for marker \"$word\" on line $srcline which refers to $str\n"; + } + + # remake rest of the line + $cnt = @m; + $txt = ""; + for ($i = 2; $i < $cnt; $i++) { + $txt = $txt . $m[$i] . "~"; + } + } + print OUT $_; + ++$wroteline; + } elsif ($_ =~ m/FIGU/) { + # FIGU,file,caption + chomp($_); + @m = split(",", $_); + print OUT "\\begin{center}\n\\begin{figure}[here]\n\\includegraphics{pics/$m[1]$graph}\n"; + print OUT "\\caption{$m[2]}\n\\label{pic:$m[1]}\n\\end{figure}\n\\end{center}\n"; + $wroteline += 4; + } else { + print OUT $_; + ++$wroteline; + } +} +print "Read $readline lines, wrote $wroteline lines\n"; + +close (OUT); +close (IN); diff --git a/libtommath/callgraph.txt b/libtommath/callgraph.txt new file mode 100644 index 0000000..4dc4cba --- /dev/null +++ b/libtommath/callgraph.txt @@ -0,0 +1,10193 @@ +BN_PRIME_TAB_C + + +BN_MP_SQRT_C ++--->BN_MP_N_ROOT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_EXPT_D_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_SUB_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_ZERO_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_RSHD_C ++--->BN_MP_DIV_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_SET_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_CMP_D_C + + +BN_MP_EXCH_C + + +BN_MP_IS_SQUARE_C ++--->BN_MP_MOD_D_C +| +--->BN_MP_DIV_D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_SET_INT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_SET_INT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MOD_C +| +--->BN_MP_INIT_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_GET_INT_C ++--->BN_MP_SQRT_C +| +--->BN_MP_N_ROOT_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_EXPT_D_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_SUB_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_CLEAR_C + + +BN_MP_NEG_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C + + +BN_MP_EXPTMOD_C ++--->BN_MP_INIT_C ++--->BN_MP_INVMOD_C +| +--->BN_FAST_MP_INVMOD_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_CMP_D_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_INVMOD_SLOW_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_CMP_D_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C ++--->BN_MP_ABS_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CLEAR_MULTI_C ++--->BN_MP_DR_IS_MODULUS_C ++--->BN_MP_REDUCE_IS_2K_C +| +--->BN_MP_REDUCE_2K_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_COUNT_BITS_C ++--->BN_MP_EXPTMOD_FAST_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_MONTGOMERY_SETUP_C +| +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_MONTGOMERY_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_DR_SETUP_C +| +--->BN_MP_DR_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_REDUCE_2K_SETUP_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_REDUCE_2K_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MULMOD_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_SQR_C +| | +--->BN_MP_TOOM_SQR_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_KARATSUBA_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | +--->BN_FAST_S_MP_SQR_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C ++--->BN_S_MP_EXPTMOD_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_REDUCE_SETUP_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_SQR_C +| | +--->BN_MP_TOOM_SQR_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_KARATSUBA_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | +--->BN_FAST_S_MP_SQR_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_REDUCE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_D_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_EXCH_C + + +BN_MP_OR_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_ZERO_C + + +BN_MP_GROW_C + + +BN_MP_COUNT_BITS_C + + +BN_MP_PRIME_FERMAT_C ++--->BN_MP_CMP_D_C ++--->BN_MP_INIT_C ++--->BN_MP_EXPTMOD_C +| +--->BN_MP_INVMOD_C +| | +--->BN_FAST_MP_INVMOD_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INVMOD_SLOW_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ABS_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_DR_IS_MODULUS_C +| +--->BN_MP_REDUCE_IS_2K_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_EXPTMOD_FAST_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_MONTGOMERY_SETUP_C +| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_DR_SETUP_C +| | +--->BN_MP_DR_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_REDUCE_2K_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2D_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_COPY_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| +--->BN_S_MP_EXPTMOD_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_REDUCE_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_REDUCE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_CLEAR_C + + +BN_MP_SUBMOD_C ++--->BN_MP_INIT_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C + + +BN_MP_MOD_2D_C ++--->BN_MP_ZERO_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_MP_TORADIX_N_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_DIV_D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C + + +BN_MP_CMP_C ++--->BN_MP_CMP_MAG_C + + +BNCORE_C + + +BN_MP_TORADIX_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_DIV_D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C + + +BN_MP_ADD_D_C ++--->BN_MP_GROW_C ++--->BN_MP_SUB_D_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLAMP_C + + +BN_MP_DIV_3_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_FAST_S_MP_MUL_DIGS_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_MP_SQRMOD_C ++--->BN_MP_INIT_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C + + +BN_MP_INVMOD_C ++--->BN_FAST_MP_INVMOD_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ABS_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_DIV_2_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_CMP_D_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_INVMOD_SLOW_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_DIV_2_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_CMP_D_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C + + +BN_MP_AND_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_MUL_D_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_FAST_MP_INVMOD_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_ABS_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_CMP_D_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_FWRITE_C ++--->BN_MP_RADIX_SIZE_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_TORADIX_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C + + +BN_S_MP_SQR_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_N_ROOT_C ++--->BN_MP_INIT_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_EXPT_D_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_SQR_C +| | +--->BN_MP_TOOM_SQR_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_KARATSUBA_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_FAST_S_MP_SQR_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_SUB_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ADD_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_PRIME_RABIN_MILLER_TRIALS_C + + +BN_MP_RADIX_SIZE_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_DIV_D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C + + +BN_MP_READ_SIGNED_BIN_C ++--->BN_MP_READ_UNSIGNED_BIN_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C + + +BN_MP_PRIME_RANDOM_EX_C ++--->BN_MP_READ_UNSIGNED_BIN_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_PRIME_IS_PRIME_C +| +--->BN_MP_CMP_D_C +| +--->BN_MP_PRIME_IS_DIVISIBLE_C +| | +--->BN_MP_MOD_D_C +| | | +--->BN_MP_DIV_D_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_INIT_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_PRIME_MILLER_RABIN_C +| | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_SUB_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CNT_LSB_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXPTMOD_C +| | | +--->BN_MP_INVMOD_C +| | | | +--->BN_FAST_MP_INVMOD_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_INVMOD_SLOW_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_DR_IS_MODULUS_C +| | | +--->BN_MP_REDUCE_IS_2K_C +| | | | +--->BN_MP_REDUCE_2K_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_EXPTMOD_FAST_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_DR_SETUP_C +| | | | +--->BN_MP_DR_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_REDUCE_2K_SETUP_C +| | | | | +--->BN_MP_2EXPT_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_REDUCE_2K_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | | +--->BN_MP_2EXPT_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MULMOD_C +| | | | | +--->BN_MP_MUL_C +| | | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | | +--->BN_MP_COPY_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_MUL_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_3_C +| | | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_MOD_C +| | | | | | +--->BN_MP_DIV_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_SQR_C +| | | | | +--->BN_MP_TOOM_SQR_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_FAST_S_MP_SQR_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SQR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_S_MP_EXPTMOD_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_REDUCE_SETUP_C +| | | | | +--->BN_MP_2EXPT_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_SQR_C +| | | | | +--->BN_MP_TOOM_SQR_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_FAST_S_MP_SQR_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SQR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_REDUCE_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_C +| | | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_3_C +| | | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_SQRMOD_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_SUB_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ADD_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_2_C +| +--->BN_MP_GROW_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C + + +BN_MP_KARATSUBA_SQR_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C ++--->BN_S_MP_ADD_C +| +--->BN_MP_GROW_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C ++--->BN_MP_ADD_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CLEAR_C + + +BN_MP_INIT_COPY_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C + + +BN_MP_CLAMP_C + + +BN_MP_TOOM_SQR_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_MOD_2D_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C ++--->BN_MP_SQR_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_MUL_2_C +| +--->BN_MP_GROW_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_3_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_MOD_C ++--->BN_MP_INIT_C ++--->BN_MP_DIV_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_SET_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C + + +BN_MP_INIT_C + + +BN_MP_TOOM_MUL_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_MOD_2D_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C ++--->BN_MP_MUL_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_MUL_2_C +| +--->BN_MP_GROW_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_3_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_PRIME_IS_PRIME_C ++--->BN_MP_CMP_D_C ++--->BN_MP_PRIME_IS_DIVISIBLE_C +| +--->BN_MP_MOD_D_C +| | +--->BN_MP_DIV_D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_PRIME_MILLER_RABIN_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_SUB_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CNT_LSB_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXPTMOD_C +| | +--->BN_MP_INVMOD_C +| | | +--->BN_FAST_MP_INVMOD_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INVMOD_SLOW_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_ABS_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_DR_IS_MODULUS_C +| | +--->BN_MP_REDUCE_IS_2K_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_EXPTMOD_FAST_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_DR_SETUP_C +| | | +--->BN_MP_DR_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_REDUCE_2K_SETUP_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MULMOD_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_S_MP_EXPTMOD_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_REDUCE_SETUP_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_REDUCE_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_SQRMOD_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C + + +BN_MP_COPY_C ++--->BN_MP_GROW_C + + +BN_S_MP_SUB_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_MP_READ_UNSIGNED_BIN_C ++--->BN_MP_GROW_C ++--->BN_MP_ZERO_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLAMP_C + + +BN_MP_EXPTMOD_FAST_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_INIT_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MONTGOMERY_SETUP_C ++--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C ++--->BN_MP_MONTGOMERY_REDUCE_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C ++--->BN_MP_DR_SETUP_C ++--->BN_MP_DR_REDUCE_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C ++--->BN_MP_REDUCE_2K_SETUP_C +| +--->BN_MP_2EXPT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_GROW_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_REDUCE_2K_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| +--->BN_MP_2EXPT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MULMOD_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_EXCH_C + + +BN_MP_TO_UNSIGNED_BIN_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_SET_INT_C ++--->BN_MP_ZERO_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLAMP_C + + +BN_MP_MOD_D_C ++--->BN_MP_DIV_D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C + + +BN_MP_SQR_C ++--->BN_MP_TOOM_SQR_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_KARATSUBA_SQR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| +--->BN_MP_ADD_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_CLEAR_C ++--->BN_FAST_S_MP_SQR_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_S_MP_SQR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C + + +BN_MP_MULMOD_C ++--->BN_MP_INIT_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C + + +BN_MP_DIV_2D_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_ZERO_C ++--->BN_MP_INIT_C ++--->BN_MP_MOD_2D_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C ++--->BN_MP_RSHD_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C + + +BN_S_MP_ADD_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_FAST_S_MP_SQR_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_S_MP_MUL_DIGS_C ++--->BN_FAST_S_MP_MUL_DIGS_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_XOR_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_RADIX_SMAP_C + + +BN_MP_DR_IS_MODULUS_C + + +BN_MP_MONTGOMERY_CALC_NORMALIZATION_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_2EXPT_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_GROW_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_MUL_2_C +| +--->BN_MP_GROW_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C + + +BN_MP_SUB_C ++--->BN_S_MP_ADD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C + + +BN_MP_INIT_MULTI_C ++--->BN_MP_INIT_C ++--->BN_MP_CLEAR_C + + +BN_S_MP_MUL_HIGH_DIGS_C ++--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_PRIME_NEXT_PRIME_C ++--->BN_MP_CMP_D_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_SUB_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ADD_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MOD_D_C +| +--->BN_MP_DIV_D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_PRIME_MILLER_RABIN_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_CNT_LSB_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXPTMOD_C +| | +--->BN_MP_INVMOD_C +| | | +--->BN_FAST_MP_INVMOD_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INVMOD_SLOW_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_ABS_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_DR_IS_MODULUS_C +| | +--->BN_MP_REDUCE_IS_2K_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_EXPTMOD_FAST_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_DR_SETUP_C +| | | +--->BN_MP_DR_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_REDUCE_2K_SETUP_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MULMOD_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_S_MP_EXPTMOD_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_REDUCE_SETUP_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SQR_C +| | | | +--->BN_MP_TOOM_SQR_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_SQR_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_REDUCE_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_SQRMOD_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C + + +BN_MP_SIGNED_BIN_SIZE_C ++--->BN_MP_UNSIGNED_BIN_SIZE_C +| +--->BN_MP_COUNT_BITS_C + + +BN_MP_INVMOD_SLOW_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_CMP_D_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_LCM_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_GCD_C +| +--->BN_MP_ABS_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_CNT_LSB_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_EXCH_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_DIV_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_SET_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_REVERSE_C + + +BN_MP_PRIME_IS_DIVISIBLE_C ++--->BN_MP_MOD_D_C +| +--->BN_MP_DIV_D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C + + +BN_MP_SET_C ++--->BN_MP_ZERO_C + + +BN_MP_GCD_C ++--->BN_MP_ABS_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_ZERO_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CNT_LSB_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_EXCH_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C + + +BN_MP_READ_RADIX_C ++--->BN_MP_ZERO_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_SUB_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C + + +BN_FAST_S_MP_MUL_HIGH_DIGS_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_FAST_MP_MONTGOMERY_REDUCE_C ++--->BN_MP_GROW_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C ++--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C + + +BN_MP_DIV_D_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_DIV_3_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_REDUCE_2K_SETUP_C ++--->BN_MP_INIT_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_2EXPT_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_GROW_C ++--->BN_MP_CLEAR_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C + + +BN_MP_INIT_SET_C ++--->BN_MP_INIT_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C + + +BN_MP_REDUCE_2K_C ++--->BN_MP_INIT_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_S_MP_ADD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C + + +BN_ERROR_C + + +BN_MP_EXPT_D_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C + + +BN_S_MP_EXPTMOD_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_INIT_C ++--->BN_MP_CLEAR_C ++--->BN_MP_REDUCE_SETUP_C +| +--->BN_MP_2EXPT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_SQR_C +| +--->BN_MP_TOOM_SQR_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_KARATSUBA_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_ADD_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| +--->BN_FAST_S_MP_SQR_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SQR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_REDUCE_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_S_MP_MUL_HIGH_DIGS_C +| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_D_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_EXCH_C + + +BN_MP_ABS_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C + + +BN_MP_INIT_SET_INT_C ++--->BN_MP_INIT_C ++--->BN_MP_SET_INT_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C + + +BN_MP_SUB_D_C ++--->BN_MP_GROW_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLAMP_C + + +BN_MP_TO_SIGNED_BIN_C ++--->BN_MP_TO_UNSIGNED_BIN_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C + + +BN_MP_DIV_2_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C + + +BN_MP_REDUCE_IS_2K_C ++--->BN_MP_REDUCE_2K_C +| +--->BN_MP_INIT_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_COUNT_BITS_C + + +BN_MP_INIT_SIZE_C ++--->BN_MP_INIT_C + + +BN_MP_DIV_C ++--->BN_MP_CMP_MAG_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_ZERO_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_SET_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_ABS_C ++--->BN_MP_MUL_2D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_INIT_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_INIT_C ++--->BN_MP_INIT_COPY_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C ++--->BN_MP_RSHD_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C + + +BN_MP_CLEAR_C + + +BN_MP_MONTGOMERY_REDUCE_C ++--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C + + +BN_MP_MUL_2_C ++--->BN_MP_GROW_C + + +BN_MP_UNSIGNED_BIN_SIZE_C ++--->BN_MP_COUNT_BITS_C + + +BN_MP_ADDMOD_C ++--->BN_MP_INIT_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C + + +BN_MP_ADD_C ++--->BN_S_MP_ADD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C + + +BN_MP_RAND_C ++--->BN_MP_ZERO_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_SUB_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C + + +BN_MP_CNT_LSB_C + + +BN_MP_2EXPT_C ++--->BN_MP_ZERO_C ++--->BN_MP_GROW_C + + +BN_MP_RSHD_C ++--->BN_MP_ZERO_C + + +BN_MP_SHRINK_C + + +BN_MP_REDUCE_C ++--->BN_MP_REDUCE_SETUP_C +| +--->BN_MP_2EXPT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_S_MP_MUL_HIGH_DIGS_C +| +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_MOD_2D_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_S_MP_MUL_DIGS_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_INIT_SIZE_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_D_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C + + +BN_MP_MUL_2D_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_GROW_C ++--->BN_MP_LSHD_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C ++--->BN_MP_CLAMP_C + + +BN_MP_GET_INT_C + + +BN_MP_JACOBI_C ++--->BN_MP_CMP_D_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_CNT_LSB_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_MOD_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_CLEAR_MULTI_C ++--->BN_MP_CLEAR_C + + +BN_MP_MUL_C ++--->BN_MP_TOOM_MUL_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_2_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_3_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_KARATSUBA_MUL_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| +--->BN_MP_CLEAR_C ++--->BN_FAST_S_MP_MUL_DIGS_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_S_MP_MUL_DIGS_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C + + +BN_MP_EXTEUCLID_C ++--->BN_MP_INIT_MULTI_C +| +--->BN_MP_INIT_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_COPY_C +| +--->BN_MP_GROW_C ++--->BN_MP_DIV_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_DR_REDUCE_C ++--->BN_MP_GROW_C ++--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C + + +BN_MP_FREAD_C ++--->BN_MP_ZERO_C ++--->BN_MP_MUL_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_ADD_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_SUB_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_D_C + + +BN_MP_REDUCE_SETUP_C ++--->BN_MP_2EXPT_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_GROW_C ++--->BN_MP_DIV_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_SET_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_ABS_C +| +--->BN_MP_MUL_2D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C + + +BN_MP_MONTGOMERY_SETUP_C + + +BN_MP_KARATSUBA_MUL_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C ++--->BN_MP_INIT_SIZE_C +| +--->BN_MP_INIT_C ++--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C ++--->BN_MP_LSHD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C ++--->BN_MP_CLEAR_C + + +BN_MP_LSHD_C ++--->BN_MP_GROW_C ++--->BN_MP_RSHD_C +| +--->BN_MP_ZERO_C + + +BN_MP_PRIME_MILLER_RABIN_C ++--->BN_MP_CMP_D_C ++--->BN_MP_INIT_COPY_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C ++--->BN_MP_SUB_D_C +| +--->BN_MP_GROW_C +| +--->BN_MP_ADD_D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CNT_LSB_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_EXPTMOD_C +| +--->BN_MP_INVMOD_C +| | +--->BN_FAST_MP_INVMOD_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INVMOD_SLOW_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ABS_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_DR_IS_MODULUS_C +| +--->BN_MP_REDUCE_IS_2K_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_EXPTMOD_FAST_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_MONTGOMERY_SETUP_C +| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_DR_SETUP_C +| | +--->BN_MP_DR_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_REDUCE_2K_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| +--->BN_S_MP_EXPTMOD_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_REDUCE_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SQR_C +| | | +--->BN_MP_TOOM_SQR_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_FAST_S_MP_SQR_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SQR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_REDUCE_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_SQRMOD_C +| +--->BN_MP_SQR_C +| | +--->BN_MP_TOOM_SQR_C +| | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_KARATSUBA_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_FAST_S_MP_SQR_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SQR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_C + + +BN_MP_DR_SETUP_C + + +BN_MP_CMP_MAG_C + + diff --git a/libtommath/changes.txt b/libtommath/changes.txt new file mode 100644 index 0000000..0d1ec2e --- /dev/null +++ b/libtommath/changes.txt @@ -0,0 +1,337 @@ +December 23rd, 2004 +v0.33 -- Fixed "small" variant for mp_div() which would munge with negative dividends... + -- Fixed bug in mp_prime_random_ex() which would set the most significant byte to zero when + no special flags were set + -- Fixed overflow [minor] bug in fast_s_mp_sqr() + -- Made the makefiles easier to configure the group/user that ltm will install as + -- Fixed "final carry" bug in comba multipliers. (Volkan Ceylan) + -- Matt Johnston pointed out a missing semi-colon in mp_exptmod + +October 29th, 2004 +v0.32 -- Added "makefile.shared" for shared object support + -- Added more to the build options/configs in the manual + -- Started the Depends framework, wrote dep.pl to scan deps and + produce "callgraph.txt" ;-) + -- Wrote SC_RSA_1 which will enable close to the minimum required to perform + RSA on 32-bit [or 64-bit] platforms with LibTomCrypt + -- Merged in the small/slower mp_div replacement. You can now toggle which + you want to use as your mp_div() at build time. Saves roughly 8KB or so. + -- Renamed a few files and changed some comments to make depends system work better. + (No changes to function names) + -- Merged in new Combas that perform 2 reads per inner loop instead of the older + 3reads/2writes per inner loop of the old code. Really though if you want speed + learn to use TomsFastMath ;-) + +August 9th, 2004 +v0.31 -- "profiled" builds now :-) new timings for Intel Northwoods + -- Added "pretty" build target + -- Update mp_init() to actually assign 0's instead of relying on calloc() + -- "Wolfgang Ehrhardt" found a bug in mp_mul() where if + you multiply a negative by zero you get negative zero as the result. Oops. + -- J Harper from PeerSec let me toy with his AMD64 and I got 60-bit digits working properly + [this also means that I fixed a bug where if sizeof(int) < sizeof(mp_digit) it would bug] + +April 11th, 2004 +v0.30 -- Added "mp_toradix_n" which stores upto "n-1" least significant digits of an mp_int + -- Johan Lindh sent a patch so MSVC wouldn't whine about redefining malloc [in weird dll modes] + -- Henrik Goldman spotted a missing OPT_CAST in mp_fwrite() + -- Tuned tommath.h so that when MP_LOW_MEM is defined MP_PREC shall be reduced. + [I also allow MP_PREC to be externally defined now] + -- Sped up mp_cnt_lsb() by using a 4x4 table [e.g. 4x speedup] + -- Added mp_prime_random_ex() which is a more versatile prime generator accurate to + exact bit lengths (unlike the deprecated but still available mp_prime_random() which + is only accurate to byte lengths). See the new LTM_PRIME_* flags ;-) + -- Alex Polushin contributed an optimized mp_sqrt() as well as mp_get_int() and mp_is_square(). + I've cleaned them all up to be a little more consistent [along with one bug fix] for this release. + -- Added mp_init_set and mp_init_set_int to initialize and set small constants with one function + call. + -- Removed /etclib directory [um LibTomPoly deprecates this]. + -- Fixed mp_mod() so the sign of the result agrees with the sign of the modulus. + ++ N.B. My semester is almost up so expect updates to the textbook to be posted to the libtomcrypt.org + website. + +Jan 25th, 2004 +v0.29 ++ Note: "Henrik" from the v0.28 changelog refers to Henrik Goldman ;-) + -- Added fix to mp_shrink to prevent a realloc when used == 0 [e.g. realloc zero bytes???] + -- Made the mp_prime_rabin_miller_trials() function internal table smaller and also + set the minimum number of tests to two (sounds a bit safer). + -- Added a mp_exteuclid() which computes the extended euclidean algorithm. + -- Fixed a memory leak in s_mp_exptmod() [called when Barrett reduction is to be used] which would arise + if a multiplication or subsequent reduction failed [would not free the temp result]. + -- Made an API change to mp_radix_size(). It now returns an error code and stores the required size + through an "int star" passed to it. + +Dec 24th, 2003 +v0.28 -- Henrik Goldman suggested I add casts to the montomgery code [stores into mu...] so compilers wouldn't + spew [erroneous] diagnostics... fixed. + -- Henrik Goldman also spotted two typos. One in mp_radix_size() and another in mp_toradix(). + -- Added fix to mp_shrink() to avoid a memory leak. + -- Added mp_prime_random() which requires a callback to make truly random primes of a given nature + (idea from chat with Niels Ferguson at Crypto'03) + -- Picked up a second wind. I'm filled with Gooo. Mission Gooo! + -- Removed divisions from mp_reduce_is_2k() + -- Sped up mp_div_d() [general case] to use only one division per digit instead of two. + -- Added the heap macros from LTC to LTM. Now you can easily [by editing four lines of tommath.h] + change the name of the heap functions used in LTM [also compatible with LTC via MPI mode] + -- Added bn_prime_rabin_miller_trials() which gives the number of Rabin-Miller trials to achieve + a failure rate of less than 2^-96 + -- fixed bug in fast_mp_invmod(). The initial testing logic was wrong. An invalid input is not when + "a" and "b" are even it's when "b" is even [the algo is for odd moduli only]. + -- Started a new manual [finally]. It is incomplete and will be finished as time goes on. I had to stop + adding full demos around half way in chapter three so I could at least get a good portion of the + manual done. If you really need help using the library you can always email me! + -- My Textbook is now included as part of the package [all Public Domain] + +Sept 19th, 2003 +v0.27 -- Removed changes.txt~ which was made by accident since "kate" decided it was + a good time to re-enable backups... [kde is fun!] + -- In mp_grow() "a->dp" is not overwritten by realloc call [re: memory leak] + Now if mp_grow() fails the mp_int is still valid and can be cleared via + mp_clear() to reclaim the memory. + -- Henrik Goldman found a buffer overflow bug in mp_add_d(). Fixed. + -- Cleaned up mp_mul_d() to be much easier to read and follow. + +Aug 29th, 2003 +v0.26 -- Fixed typo that caused warning with GCC 3.2 + -- Martin Marcel noticed a bug in mp_neg() that allowed negative zeroes. + Also, Martin is the fellow who noted the bugs in mp_gcd() of 0.24/0.25. + -- Martin Marcel noticed an optimization [and slight bug] in mp_lcm(). + -- Added fix to mp_read_unsigned_bin to prevent a buffer overflow. + -- Beefed up the comments in the baseline multipliers [and montgomery] + -- Added "mont" demo to the makefile.msvc in etc/ + -- Optimized sign compares in mp_cmp from 4 to 2 cases. + +Aug 4th, 2003 +v0.25 -- Fix to mp_gcd again... oops (0,-a) == (-a, 0) == a + -- Fix to mp_clear which didn't reset the sign [Greg Rose] + -- Added mp_error_to_string() to convert return codes to strings. [Greg Rose] + -- Optimized fast_mp_invmod() to do the test for invalid inputs [both even] + first so temps don't have to be initialized if it's going to fail. + -- Optimized mp_gcd() by removing mp_div_2d calls for when one of the inputs + is odd. + -- Tons of new comments, some indentation fixups, etc. + -- mp_jacobi() returns MP_VAL if the modulus is less than or equal to zero. + -- fixed two typos in the header of each file :-) + -- LibTomMath is officially Public Domain [see LICENSE] + +July 15th, 2003 +v0.24 -- Optimized mp_add_d and mp_sub_d to not allocate temporary variables + -- Fixed mp_gcd() so the gcd of 0,0 is 0. Allows the gcd operation to be chained + e.g. (0,0,a) == a [instead of 1] + -- Should be one of the last release for a while. Working on LibTomMath book now. + -- optimized the pprime demo [/etc/pprime.c] to first make a huge table of single + digit primes then it reads them randomly instead of randomly choosing/testing single + digit primes. + +July 12th, 2003 +v0.23 -- Optimized mp_prime_next_prime() to not use mp_mod [via is_divisible()] in each + iteration. Instead now a smaller table is kept of the residues which can be updated + without division. + -- Fixed a bug in next_prime() where an input of zero would be treated as odd and + have two added to it [to move to the next odd]. + -- fixed a bug in prime_fermat() and prime_miller_rabin() which allowed the base + to be negative, zero or one. Normally the test is only valid if the base is + greater than one. + -- changed the next_prime() prototype to accept a new parameter "bbs_style" which + will find the next prime congruent to 3 mod 4. The default [bbs_style==0] will + make primes which are either congruent to 1 or 3 mod 4. + -- fixed mp_read_unsigned_bin() so that it doesn't include both code for + the case DIGIT_BIT < 8 and >= 8 + -- optimized div_d() to easy out on division by 1 [or if a == 0] and use + logical shifts if the divisor is a power of two. + -- the default DIGIT_BIT type was not int for non-default builds. Fixed. + +July 2nd, 2003 +v0.22 -- Fixed up mp_invmod so the result is properly in range now [was always congruent to the inverse...] + -- Fixed up s_mp_exptmod and mp_exptmod_fast so the lower half of the pre-computed table isn't allocated + which makes the algorithm use half as much ram. + -- Fixed the install script not to make the book :-) [which isn't included anyways] + -- added mp_cnt_lsb() which counts how many of the lsbs are zero + -- optimized mp_gcd() to use the new mp_cnt_lsb() to replace multiple divisions by two by a single division. + -- applied similar optimization to mp_prime_miller_rabin(). + -- Fixed a bug in both mp_invmod() and fast_mp_invmod() which tested for odd + via "mp_iseven() == 0" which is not valid [since zero is not even either]. + +June 19th, 2003 +v0.21 -- Fixed bug in mp_mul_d which would not handle sign correctly [would not always forward it] + -- Removed the #line lines from gen.pl [was in violation of ISO C] + +June 8th, 2003 +v0.20 -- Removed the book from the package. Added the TDCAL license document. + -- This release is officially pure-bred TDCAL again [last officially TDCAL based release was v0.16] + +June 6th, 2003 +v0.19 -- Fixed a bug in mp_montgomery_reduce() which was introduced when I tweaked mp_rshd() in the previous release. + Essentially the digits were not trimmed before the compare which cause a subtraction to occur all the time. + -- Fixed up etc/tune.c a bit to stop testing new cutoffs after 16 failures [to find more optimal points]. + Brute force ho! + + +May 29th, 2003 +v0.18 -- Fixed a bug in s_mp_sqr which would handle carries properly just not very elegantly. + (e.g. correct result, just bad looking code) + -- Fixed bug in mp_sqr which still had a 512 constant instead of MP_WARRAY + -- Added Toom-Cook multipliers [needs tuning!] + -- Added efficient divide by 3 algorithm mp_div_3 + -- Re-wrote mp_div_d to be faster than calling mp_div + -- Added in a donated BCC makefile and a single page LTM poster (ahalhabsi@sbcglobal.net) + -- Added mp_reduce_2k which reduces an input modulo n = 2**p - k for any single digit k + -- Made the exptmod system be aware of the 2k reduction algorithms. + -- Rewrote mp_dr_reduce to be smaller, simpler and easier to understand. + +May 17th, 2003 +v0.17 -- Benjamin Goldberg submitted optimized mp_add and mp_sub routines. A new gen.pl as well + as several smaller suggestions. Thanks! + -- removed call to mp_cmp in inner loop of mp_div and put mp_cmp_mag in its place :-) + -- Fixed bug in mp_exptmod that would cause it to fail for odd moduli when DIGIT_BIT != 28 + -- mp_exptmod now also returns errors if the modulus is negative and will handle negative exponents + -- mp_prime_is_prime will now return true if the input is one of the primes in the prime table + -- Damian M Gryski (dgryski@uwaterloo.ca) found a index out of bounds error in the + mp_fast_s_mp_mul_high_digs function which didn't come up before. (fixed) + -- Refactored the DR reduction code so there is only one function per file. + -- Fixed bug in the mp_mul() which would erroneously avoid the faster multiplier [comba] when it was + allowed. The bug would not cause the incorrect value to be produced just less efficient (fixed) + -- Fixed similar bug in the Montgomery reduction code. + -- Added tons of (mp_digit) casts so the 7/15/28/31 bit digit code will work flawlessly out of the box. + Also added limited support for 64-bit machines with a 60-bit digit. Both thanks to Tom Wu (tom@arcot.com) + -- Added new comments here and there, cleaned up some code [style stuff] + -- Fixed a lingering typo in mp_exptmod* that would set bitcnt to zero then one. Very silly stuff :-) + -- Fixed up mp_exptmod_fast so it would set "redux" to the comba Montgomery reduction if allowed. This + saves quite a few calls and if statements. + -- Added etc/mont.c a test of the Montgomery reduction [assuming all else works :-| ] + -- Fixed up etc/tune.c to use a wider test range [more appropriate] also added a x86 based addition which + uses RDTSC for high precision timing. + -- Updated demo/demo.c to remove MPI stuff [won't work anyways], made the tests run for 2 seconds each so its + not so insanely slow. Also made the output space delimited [and fixed up various errors] + -- Added logs directory, logs/graph.dem which will use gnuplot to make a series of PNG files + that go with the pre-made index.html. You have to build [via make timing] and run ltmtest first in the + root of the package. + -- Fixed a bug in mp_sub and mp_add where "-a - -a" or "-a + a" would produce -0 as the result [obviously invalid]. + -- Fixed a bug in mp_rshd. If the count == a.used it should zero/return [instead of shifting] + -- Fixed a "off-by-one" bug in mp_mul2d. The initial size check on alloc would be off by one if the residue + shifting caused a carry. + -- Fixed a bug where s_mp_mul_digs() would not call the Comba based routine if allowed. This made Barrett reduction + slower than it had to be. + +Mar 29th, 2003 +v0.16 -- Sped up mp_div by making normalization one shift call + -- Sped up mp_mul_2d/mp_div_2d by aliasing pointers :-) + -- Cleaned up mp_gcd to use the macros for odd/even detection + -- Added comments here and there, mostly there but occasionally here too. + +Mar 22nd, 2003 +v0.15 -- Added series of prime testing routines to lib + -- Fixed up etc/tune.c + -- Added DR reduction algorithm + -- Beefed up the manual more. + -- Fixed up demo/demo.c so it doesn't have so many warnings and it does the full series of + tests + -- Added "pre-gen" directory which will hold a "gen.pl"'ed copy of the entire lib [done at + zipup time so its always the latest] + -- Added conditional casts for C++ users [boo!] + +Mar 15th, 2003 +v0.14 -- Tons of manual updates + -- cleaned up the directory + -- added MSVC makefiles + -- source changes [that I don't recall] + -- Fixed up the lshd/rshd code to use pointer aliasing + -- Fixed up the mul_2d and div_2d to not call rshd/lshd unless needed + -- Fixed up etc/tune.c a tad + -- fixed up demo/demo.c to output comma-delimited results of timing + also fixed up timing demo to use a finer granularity for various functions + -- fixed up demo/demo.c testing to pause during testing so my Duron won't catch on fire + [stays around 31-35C during testing :-)] + +Feb 13th, 2003 +v0.13 -- tons of minor speed-ups in low level add, sub, mul_2 and div_2 which propagate + to other functions like mp_invmod, mp_div, etc... + -- Sped up mp_exptmod_fast by using new code to find R mod m [e.g. B^n mod m] + -- minor fixes + +Jan 17th, 2003 +v0.12 -- re-wrote the majority of the makefile so its more portable and will + install via "make install" on most *nix platforms + -- Re-packaged all the source as seperate files. Means the library a single + file packagage any more. Instead of just adding "bn.c" you have to add + libtommath.a + -- Renamed "bn.h" to "tommath.h" + -- Changes to the manual to reflect all of this + -- Used GNU Indent to clean up the source + +Jan 15th, 2003 +v0.11 -- More subtle fixes + -- Moved to gentoo linux [hurrah!] so made *nix specific fixes to the make process + -- Sped up the montgomery reduction code quite a bit + -- fixed up demo so when building timing for the x86 it assumes ELF format now + +Jan 9th, 2003 +v0.10 -- Pekka Riikonen suggested fixes to the radix conversion code. + -- Added baseline montgomery and comba montgomery reductions, sped up exptmods + [to a point, see bn.h for MONTGOMERY_EXPT_CUTOFF] + +Jan 6th, 2003 +v0.09 -- Updated the manual to reflect recent changes. :-) + -- Added Jacobi function (mp_jacobi) to supplement the number theory side of the lib + -- Added a Mersenne prime finder demo in ./etc/mersenne.c + +Jan 2nd, 2003 +v0.08 -- Sped up the multipliers by moving the inner loop variables into a smaller scope + -- Corrected a bunch of small "warnings" + -- Added more comments + -- Made "mtest" be able to use /dev/random, /dev/urandom or stdin for RNG data + -- Corrected some bugs where error messages were potentially ignored + -- add etc/pprime.c program which makes numbers which are provably prime. + +Jan 1st, 2003 +v0.07 -- Removed alot of heap operations from core functions to speed them up + -- Added a root finding function [and mp_sqrt macro like from MPI] + -- Added more to manual + +Dec 31st, 2002 +v0.06 -- Sped up the s_mp_add, s_mp_sub which inturn sped up mp_invmod, mp_exptmod, etc... + -- Cleaned up the header a bit more + +Dec 30th, 2002 +v0.05 -- Builds with MSVC out of the box + -- Fixed a bug in mp_invmod w.r.t. even moduli + -- Made mp_toradix and mp_read_radix use char instead of unsigned char arrays + -- Fixed up exptmod to use fewer multiplications + -- Fixed up mp_init_size to use only one heap operation + -- Note there is a slight "off-by-one" bug in the library somewhere + without the padding (see the source for comment) the library + crashes in libtomcrypt. Anyways a reasonable workaround is to pad the + numbers which will always correct it since as the numbers grow the padding + will still be beyond the end of the number + -- Added more to the manual + +Dec 29th, 2002 +v0.04 -- Fixed a memory leak in mp_to_unsigned_bin + -- optimized invmod code + -- Fixed bug in mp_div + -- use exchange instead of copy for results + -- added a bit more to the manual + +Dec 27th, 2002 +v0.03 -- Sped up s_mp_mul_high_digs by not computing the carries of the lower digits + -- Fixed a bug where mp_set_int wouldn't zero the value first and set the used member. + -- fixed a bug in s_mp_mul_high_digs where the limit placed on the result digits was not calculated properly + -- fixed bugs in add/sub/mul/sqr_mod functions where if the modulus and dest were the same it wouldn't work + -- fixed a bug in mp_mod and mp_mod_d concerning negative inputs + -- mp_mul_d didn't preserve sign + -- Many many many many fixes + -- Works in LibTomCrypt now :-) + -- Added iterations to the timing demos... more accurate. + -- Tom needs a job. + +Dec 26th, 2002 +v0.02 -- Fixed a few "slips" in the manual. This is "LibTomMath" afterall :-) + -- Added mp_cmp_mag, mp_neg, mp_abs and mp_radix_size that were missing. + -- Sped up the fast [comba] multipliers more [yahoo!] + +Dec 25th,2002 +v0.01 -- Initial release. Gimme a break. + -- Todo list, + add details to manual [e.g. algorithms] + more comments in code + example programs diff --git a/libtommath/demo/demo.c b/libtommath/demo/demo.c new file mode 100644 index 0000000..62615cd --- /dev/null +++ b/libtommath/demo/demo.c @@ -0,0 +1,515 @@ +#include + +#ifdef IOWNANATHLON +#include +#define SLEEP sleep(4) +#else +#define SLEEP +#endif + +#include "tommath.h" + +void ndraw(mp_int *a, char *name) +{ + char buf[16000]; + printf("%s: ", name); + mp_toradix(a, buf, 10); + printf("%s\n", buf); +} + +static void draw(mp_int *a) +{ + ndraw(a, ""); +} + + +unsigned long lfsr = 0xAAAAAAAAUL; + +int lbit(void) +{ + if (lfsr & 0x80000000UL) { + lfsr = ((lfsr << 1) ^ 0x8000001BUL) & 0xFFFFFFFFUL; + return 1; + } else { + lfsr <<= 1; + return 0; + } +} + +int myrng(unsigned char *dst, int len, void *dat) +{ + int x; + for (x = 0; x < len; x++) dst[x] = rand() & 0xFF; + return len; +} + + + + char cmd[4096], buf[4096]; +int main(void) +{ + mp_int a, b, c, d, e, f; + unsigned long expt_n, add_n, sub_n, mul_n, div_n, sqr_n, mul2d_n, div2d_n, gcd_n, lcm_n, inv_n, + div2_n, mul2_n, add_d_n, sub_d_n, t; + unsigned rr; + int i, n, err, cnt, ix, old_kara_m, old_kara_s; + + + mp_init(&a); + mp_init(&b); + mp_init(&c); + mp_init(&d); + mp_init(&e); + mp_init(&f); + + srand(time(NULL)); + +#if 0 + // test mp_get_int + printf("Testing: mp_get_int\n"); + for(i=0;i<1000;++i) { + t = ((unsigned long)rand()*rand()+1)&0xFFFFFFFF; + mp_set_int(&a,t); + if (t!=mp_get_int(&a)) { + printf("mp_get_int() bad result!\n"); + return 1; + } + } + mp_set_int(&a,0); + if (mp_get_int(&a)!=0) + { printf("mp_get_int() bad result!\n"); + return 1; + } + mp_set_int(&a,0xffffffff); + if (mp_get_int(&a)!=0xffffffff) + { printf("mp_get_int() bad result!\n"); + return 1; + } + + // test mp_sqrt + printf("Testing: mp_sqrt\n"); + for (i=0;i<1000;++i) { + printf("%6d\r", i); fflush(stdout); + n = (rand()&15)+1; + mp_rand(&a,n); + if (mp_sqrt(&a,&b) != MP_OKAY) + { printf("mp_sqrt() error!\n"); + return 1; + } + mp_n_root(&a,2,&a); + if (mp_cmp_mag(&b,&a) != MP_EQ) + { printf("mp_sqrt() bad result!\n"); + return 1; + } + } + + printf("\nTesting: mp_is_square\n"); + for (i=0;i<1000;++i) { + printf("%6d\r", i); fflush(stdout); + + /* test mp_is_square false negatives */ + n = (rand()&7)+1; + mp_rand(&a,n); + mp_sqr(&a,&a); + if (mp_is_square(&a,&n)!=MP_OKAY) { + printf("fn:mp_is_square() error!\n"); + return 1; + } + if (n==0) { + printf("fn:mp_is_square() bad result!\n"); + return 1; + } + + /* test for false positives */ + mp_add_d(&a, 1, &a); + if (mp_is_square(&a,&n)!=MP_OKAY) { + printf("fp:mp_is_square() error!\n"); + return 1; + } + if (n==1) { + printf("fp:mp_is_square() bad result!\n"); + return 1; + } + + } + printf("\n\n"); + + /* test for size */ + for (ix = 10; ix < 256; ix++) { + printf("Testing (not safe-prime): %9d bits \r", ix); fflush(stdout); + err = mp_prime_random_ex(&a, 8, ix, (rand()&1)?LTM_PRIME_2MSB_OFF:LTM_PRIME_2MSB_ON, myrng, NULL); + if (err != MP_OKAY) { + printf("failed with err code %d\n", err); + return EXIT_FAILURE; + } + if (mp_count_bits(&a) != ix) { + printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); + return EXIT_FAILURE; + } + } + + for (ix = 16; ix < 256; ix++) { + printf("Testing ( safe-prime): %9d bits \r", ix); fflush(stdout); + err = mp_prime_random_ex(&a, 8, ix, ((rand()&1)?LTM_PRIME_2MSB_OFF:LTM_PRIME_2MSB_ON)|LTM_PRIME_SAFE, myrng, NULL); + if (err != MP_OKAY) { + printf("failed with err code %d\n", err); + return EXIT_FAILURE; + } + if (mp_count_bits(&a) != ix) { + printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); + return EXIT_FAILURE; + } + /* let's see if it's really a safe prime */ + mp_sub_d(&a, 1, &a); + mp_div_2(&a, &a); + mp_prime_is_prime(&a, 8, &cnt); + if (cnt != MP_YES) { + printf("sub is not prime!\n"); + return EXIT_FAILURE; + } + } + + printf("\n\n"); + + mp_read_radix(&a, "123456", 10); + mp_toradix_n(&a, buf, 10, 3); + printf("a == %s\n", buf); + mp_toradix_n(&a, buf, 10, 4); + printf("a == %s\n", buf); + mp_toradix_n(&a, buf, 10, 30); + printf("a == %s\n", buf); + + +#if 0 + for (;;) { + fgets(buf, sizeof(buf), stdin); + mp_read_radix(&a, buf, 10); + mp_prime_next_prime(&a, 5, 1); + mp_toradix(&a, buf, 10); + printf("%s, %lu\n", buf, a.dp[0] & 3); + } +#endif + + /* test mp_cnt_lsb */ + printf("testing mp_cnt_lsb...\n"); + mp_set(&a, 1); + for (ix = 0; ix < 1024; ix++) { + if (mp_cnt_lsb(&a) != ix) { + printf("Failed at %d, %d\n", ix, mp_cnt_lsb(&a)); + return 0; + } + mp_mul_2(&a, &a); + } + +/* test mp_reduce_2k */ + printf("Testing mp_reduce_2k...\n"); + for (cnt = 3; cnt <= 128; ++cnt) { + mp_digit tmp; + mp_2expt(&a, cnt); + mp_sub_d(&a, 2, &a); /* a = 2**cnt - 2 */ + + + printf("\nTesting %4d bits", cnt); + printf("(%d)", mp_reduce_is_2k(&a)); + mp_reduce_2k_setup(&a, &tmp); + printf("(%d)", tmp); + for (ix = 0; ix < 1000; ix++) { + if (!(ix & 127)) {printf("."); fflush(stdout); } + mp_rand(&b, (cnt/DIGIT_BIT + 1) * 2); + mp_copy(&c, &b); + mp_mod(&c, &a, &c); + mp_reduce_2k(&b, &a, 1); + if (mp_cmp(&c, &b)) { + printf("FAILED\n"); + exit(0); + } + } + } + +/* test mp_div_3 */ + printf("Testing mp_div_3...\n"); + mp_set(&d, 3); + for (cnt = 0; cnt < 10000; ) { + mp_digit r1, r2; + + if (!(++cnt & 127)) printf("%9d\r", cnt); + mp_rand(&a, abs(rand()) % 128 + 1); + mp_div(&a, &d, &b, &e); + mp_div_3(&a, &c, &r2); + + if (mp_cmp(&b, &c) || mp_cmp_d(&e, r2)) { + printf("\n\nmp_div_3 => Failure\n"); + } + } + printf("\n\nPassed div_3 testing\n"); + +/* test the DR reduction */ + printf("testing mp_dr_reduce...\n"); + for (cnt = 2; cnt < 32; cnt++) { + printf("%d digit modulus\n", cnt); + mp_grow(&a, cnt); + mp_zero(&a); + for (ix = 1; ix < cnt; ix++) { + a.dp[ix] = MP_MASK; + } + a.used = cnt; + a.dp[0] = 3; + + mp_rand(&b, cnt - 1); + mp_copy(&b, &c); + + rr = 0; + do { + if (!(rr & 127)) { printf("%9lu\r", rr); fflush(stdout); } + mp_sqr(&b, &b); mp_add_d(&b, 1, &b); + mp_copy(&b, &c); + + mp_mod(&b, &a, &b); + mp_dr_reduce(&c, &a, (((mp_digit)1)< +#include + +ulong64 _tt; + +#ifdef IOWNANATHLON +#include +#define SLEEP sleep(4) +#else +#define SLEEP +#endif + + +void ndraw(mp_int *a, char *name) +{ + char buf[4096]; + printf("%s: ", name); + mp_toradix(a, buf, 64); + printf("%s\n", buf); +} + +static void draw(mp_int *a) +{ + ndraw(a, ""); +} + + +unsigned long lfsr = 0xAAAAAAAAUL; + +int lbit(void) +{ + if (lfsr & 0x80000000UL) { + lfsr = ((lfsr << 1) ^ 0x8000001BUL) & 0xFFFFFFFFUL; + return 1; + } else { + lfsr <<= 1; + return 0; + } +} + +/* RDTSC from Scott Duplichan */ +static ulong64 TIMFUNC (void) + { + #if defined __GNUC__ + #if defined(__i386__) || defined(__x86_64__) + unsigned long long a; + __asm__ __volatile__ ("rdtsc\nmovl %%eax,%0\nmovl %%edx,4+%0\n"::"m"(a):"%eax","%edx"); + return a; + #else /* gcc-IA64 version */ + unsigned long result; + __asm__ __volatile__("mov %0=ar.itc" : "=r"(result) :: "memory"); + while (__builtin_expect ((int) result == -1, 0)) + __asm__ __volatile__("mov %0=ar.itc" : "=r"(result) :: "memory"); + return result; + #endif + + // Microsoft and Intel Windows compilers + #elif defined _M_IX86 + __asm rdtsc + #elif defined _M_AMD64 + return __rdtsc (); + #elif defined _M_IA64 + #if defined __INTEL_COMPILER + #include + #endif + return __getReg (3116); + #else + #error need rdtsc function for this build + #endif + } + +#define DO(x) x; x; +//#define DO4(x) DO2(x); DO2(x); +//#define DO8(x) DO4(x); DO4(x); +//#define DO(x) DO8(x); DO8(x); + +int main(void) +{ + ulong64 tt, gg, CLK_PER_SEC; + FILE *log, *logb, *logc; + mp_int a, b, c, d, e, f; + int n, cnt, ix, old_kara_m, old_kara_s; + unsigned rr; + + mp_init(&a); + mp_init(&b); + mp_init(&c); + mp_init(&d); + mp_init(&e); + mp_init(&f); + + srand(time(NULL)); + + + /* temp. turn off TOOM */ + TOOM_MUL_CUTOFF = TOOM_SQR_CUTOFF = 100000; + + CLK_PER_SEC = TIMFUNC(); + sleep(1); + CLK_PER_SEC = TIMFUNC() - CLK_PER_SEC; + + printf("CLK_PER_SEC == %llu\n", CLK_PER_SEC); + + log = fopen("logs/add.log", "w"); + for (cnt = 8; cnt <= 128; cnt += 8) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_add(&a,&b,&c)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 100000); + printf("Adding\t\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); fflush(log); + } + fclose(log); + + log = fopen("logs/sub.log", "w"); + for (cnt = 8; cnt <= 128; cnt += 8) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_sub(&a,&b,&c)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 100000); + + printf("Subtracting\t\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); fflush(log); + } + fclose(log); + + /* do mult/square twice, first without karatsuba and second with */ + old_kara_m = KARATSUBA_MUL_CUTOFF; + old_kara_s = KARATSUBA_SQR_CUTOFF; + for (ix = 0; ix < 1; ix++) { + printf("With%s Karatsuba\n", (ix==0)?"out":""); + + KARATSUBA_MUL_CUTOFF = (ix==0)?9999:old_kara_m; + KARATSUBA_SQR_CUTOFF = (ix==0)?9999:old_kara_s; + + log = fopen((ix==0)?"logs/mult.log":"logs/mult_kara.log", "w"); + for (cnt = 4; cnt <= 288; cnt += 2) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_mul(&a, &b, &c)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 100); + printf("Multiplying\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); fflush(log); + } + fclose(log); + + log = fopen((ix==0)?"logs/sqr.log":"logs/sqr_kara.log", "w"); + for (cnt = 4; cnt <= 288; cnt += 2) { + SLEEP; + mp_rand(&a, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_sqr(&a, &b)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 100); + printf("Squaring\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); fflush(log); + } + fclose(log); + + } + + { + char *primes[] = { + /* 2K moduli mersenne primes */ + "6864797660130609714981900799081393217269435300143305409394463459185543183397656052122559640661454554977296311391480858037121987999716643812574028291115057151", + "531137992816767098689588206552468627329593117727031923199444138200403559860852242739162502265229285668889329486246501015346579337652707239409519978766587351943831270835393219031728127", + "10407932194664399081925240327364085538615262247266704805319112350403608059673360298012239441732324184842421613954281007791383566248323464908139906605677320762924129509389220345773183349661583550472959420547689811211693677147548478866962501384438260291732348885311160828538416585028255604666224831890918801847068222203140521026698435488732958028878050869736186900714720710555703168729087", + "1475979915214180235084898622737381736312066145333169775147771216478570297878078949377407337049389289382748507531496480477281264838760259191814463365330269540496961201113430156902396093989090226259326935025281409614983499388222831448598601834318536230923772641390209490231836446899608210795482963763094236630945410832793769905399982457186322944729636418890623372171723742105636440368218459649632948538696905872650486914434637457507280441823676813517852099348660847172579408422316678097670224011990280170474894487426924742108823536808485072502240519452587542875349976558572670229633962575212637477897785501552646522609988869914013540483809865681250419497686697771007", + "259117086013202627776246767922441530941818887553125427303974923161874019266586362086201209516800483406550695241733194177441689509238807017410377709597512042313066624082916353517952311186154862265604547691127595848775610568757931191017711408826252153849035830401185072116424747461823031471398340229288074545677907941037288235820705892351068433882986888616658650280927692080339605869308790500409503709875902119018371991620994002568935113136548829739112656797303241986517250116412703509705427773477972349821676443446668383119322540099648994051790241624056519054483690809616061625743042361721863339415852426431208737266591962061753535748892894599629195183082621860853400937932839420261866586142503251450773096274235376822938649407127700846077124211823080804139298087057504713825264571448379371125032081826126566649084251699453951887789613650248405739378594599444335231188280123660406262468609212150349937584782292237144339628858485938215738821232393687046160677362909315071", + "190797007524439073807468042969529173669356994749940177394741882673528979787005053706368049835514900244303495954950709725762186311224148828811920216904542206960744666169364221195289538436845390250168663932838805192055137154390912666527533007309292687539092257043362517857366624699975402375462954490293259233303137330643531556539739921926201438606439020075174723029056838272505051571967594608350063404495977660656269020823960825567012344189908927956646011998057988548630107637380993519826582389781888135705408653045219655801758081251164080554609057468028203308718724654081055323215860189611391296030471108443146745671967766308925858547271507311563765171008318248647110097614890313562856541784154881743146033909602737947385055355960331855614540900081456378659068370317267696980001187750995491090350108417050917991562167972281070161305972518044872048331306383715094854938415738549894606070722584737978176686422134354526989443028353644037187375385397838259511833166416134323695660367676897722287918773420968982326089026150031515424165462111337527431154890666327374921446276833564519776797633875503548665093914556482031482248883127023777039667707976559857333357013727342079099064400455741830654320379350833236245819348824064783585692924881021978332974949906122664421376034687815350484991", + + /* DR moduli */ + "14059105607947488696282932836518693308967803494693489478439861164411992439598399594747002144074658928593502845729752797260025831423419686528151609940203368612079", + "101745825697019260773923519755878567461315282017759829107608914364075275235254395622580447400994175578963163918967182013639660669771108475957692810857098847138903161308502419410142185759152435680068435915159402496058513611411688900243039", + "736335108039604595805923406147184530889923370574768772191969612422073040099331944991573923112581267542507986451953227192970402893063850485730703075899286013451337291468249027691733891486704001513279827771740183629161065194874727962517148100775228363421083691764065477590823919364012917984605619526140821797602431", + "38564998830736521417281865696453025806593491967131023221754800625044118265468851210705360385717536794615180260494208076605798671660719333199513807806252394423283413430106003596332513246682903994829528690198205120921557533726473585751382193953592127439965050261476810842071573684505878854588706623484573925925903505747545471088867712185004135201289273405614415899438276535626346098904241020877974002916168099951885406379295536200413493190419727789712076165162175783", + "542189391331696172661670440619180536749994166415993334151601745392193484590296600979602378676624808129613777993466242203025054573692562689251250471628358318743978285860720148446448885701001277560572526947619392551574490839286458454994488665744991822837769918095117129546414124448777033941223565831420390846864429504774477949153794689948747680362212954278693335653935890352619041936727463717926744868338358149568368643403037768649616778526013610493696186055899318268339432671541328195724261329606699831016666359440874843103020666106568222401047720269951530296879490444224546654729111504346660859907296364097126834834235287147", + "1487259134814709264092032648525971038895865645148901180585340454985524155135260217788758027400478312256339496385275012465661575576202252063145698732079880294664220579764848767704076761853197216563262660046602703973050798218246170835962005598561669706844469447435461092542265792444947706769615695252256130901271870341005768912974433684521436211263358097522726462083917939091760026658925757076733484173202927141441492573799914240222628795405623953109131594523623353044898339481494120112723445689647986475279242446083151413667587008191682564376412347964146113898565886683139407005941383669325997475076910488086663256335689181157957571445067490187939553165903773554290260531009121879044170766615232300936675369451260747671432073394867530820527479172464106442450727640226503746586340279816318821395210726268291535648506190714616083163403189943334431056876038286530365757187367147446004855912033137386225053275419626102417236133948503", + "1095121115716677802856811290392395128588168592409109494900178008967955253005183831872715423151551999734857184538199864469605657805519106717529655044054833197687459782636297255219742994736751541815269727940751860670268774903340296040006114013971309257028332849679096824800250742691718610670812374272414086863715763724622797509437062518082383056050144624962776302147890521249477060215148275163688301275847155316042279405557632639366066847442861422164832655874655824221577849928863023018366835675399949740429332468186340518172487073360822220449055340582568461568645259954873303616953776393853174845132081121976327462740354930744487429617202585015510744298530101547706821590188733515880733527449780963163909830077616357506845523215289297624086914545378511082534229620116563260168494523906566709418166011112754529766183554579321224940951177394088465596712620076240067370589036924024728375076210477267488679008016579588696191194060127319035195370137160936882402244399699172017835144537488486396906144217720028992863941288217185353914991583400421682751000603596655790990815525126154394344641336397793791497068253936771017031980867706707490224041075826337383538651825493679503771934836094655802776331664261631740148281763487765852746577808019633679", + + /* generic unrestricted moduli */ + "17933601194860113372237070562165128350027320072176844226673287945873370751245439587792371960615073855669274087805055507977323024886880985062002853331424203", + "2893527720709661239493896562339544088620375736490408468011883030469939904368086092336458298221245707898933583190713188177399401852627749210994595974791782790253946539043962213027074922559572312141181787434278708783207966459019479487", + "347743159439876626079252796797422223177535447388206607607181663903045907591201940478223621722118173270898487582987137708656414344685816179420855160986340457973820182883508387588163122354089264395604796675278966117567294812714812796820596564876450716066283126720010859041484786529056457896367683122960411136319", + "47266428956356393164697365098120418976400602706072312735924071745438532218237979333351774907308168340693326687317443721193266215155735814510792148768576498491199122744351399489453533553203833318691678263241941706256996197460424029012419012634671862283532342656309677173602509498417976091509154360039893165037637034737020327399910409885798185771003505320583967737293415979917317338985837385734747478364242020380416892056650841470869294527543597349250299539682430605173321029026555546832473048600327036845781970289288898317888427517364945316709081173840186150794397479045034008257793436817683392375274635794835245695887", + "436463808505957768574894870394349739623346440601945961161254440072143298152040105676491048248110146278752857839930515766167441407021501229924721335644557342265864606569000117714935185566842453630868849121480179691838399545644365571106757731317371758557990781880691336695584799313313687287468894148823761785582982549586183756806449017542622267874275103877481475534991201849912222670102069951687572917937634467778042874315463238062009202992087620963771759666448266532858079402669920025224220613419441069718482837399612644978839925207109870840278194042158748845445131729137117098529028886770063736487420613144045836803985635654192482395882603511950547826439092832800532152534003936926017612446606135655146445620623395788978726744728503058670046885876251527122350275750995227", + "11424167473351836398078306042624362277956429440521137061889702611766348760692206243140413411077394583180726863277012016602279290144126785129569474909173584789822341986742719230331946072730319555984484911716797058875905400999504305877245849119687509023232790273637466821052576859232452982061831009770786031785669030271542286603956118755585683996118896215213488875253101894663403069677745948305893849505434201763745232895780711972432011344857521691017896316861403206449421332243658855453435784006517202894181640562433575390821384210960117518650374602256601091379644034244332285065935413233557998331562749140202965844219336298970011513882564935538704289446968322281451907487362046511461221329799897350993370560697505809686438782036235372137015731304779072430260986460269894522159103008260495503005267165927542949439526272736586626709581721032189532726389643625590680105784844246152702670169304203783072275089194754889511973916207", + "1214855636816562637502584060163403830270705000634713483015101384881871978446801224798536155406895823305035467591632531067547890948695117172076954220727075688048751022421198712032848890056357845974246560748347918630050853933697792254955890439720297560693579400297062396904306270145886830719309296352765295712183040773146419022875165382778007040109957609739589875590885701126197906063620133954893216612678838507540777138437797705602453719559017633986486649523611975865005712371194067612263330335590526176087004421363598470302731349138773205901447704682181517904064735636518462452242791676541725292378925568296858010151852326316777511935037531017413910506921922450666933202278489024521263798482237150056835746454842662048692127173834433089016107854491097456725016327709663199738238442164843147132789153725513257167915555162094970853584447993125488607696008169807374736711297007473812256272245489405898470297178738029484459690836250560495461579533254473316340608217876781986188705928270735695752830825527963838355419762516246028680280988020401914551825487349990306976304093109384451438813251211051597392127491464898797406789175453067960072008590614886532333015881171367104445044718144312416815712216611576221546455968770801413440778423979", + NULL + }; + log = fopen("logs/expt.log", "w"); + logb = fopen("logs/expt_dr.log", "w"); + logc = fopen("logs/expt_2k.log", "w"); + for (n = 0; primes[n]; n++) { + SLEEP; + mp_read_radix(&a, primes[n], 10); + mp_zero(&b); + for (rr = 0; rr < (unsigned)mp_count_bits(&a); rr++) { + mp_mul_2(&b, &b); + b.dp[0] |= lbit(); + b.used += 1; + } + mp_sub_d(&a, 1, &c); + mp_mod(&b, &c, &b); + mp_set(&c, 3); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_exptmod(&c, &b, &a, &d)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 10); + mp_sub_d(&a, 1, &e); + mp_sub(&e, &b, &b); + mp_exptmod(&c, &b, &a, &e); /* c^(p-1-b) mod a */ + mp_mulmod(&e, &d, &a, &d); /* c^b * c^(p-1-b) == c^p-1 == 1 */ + if (mp_cmp_d(&d, 1)) { + printf("Different (%d)!!!\n", mp_count_bits(&a)); + draw(&d); + exit(0); + } + printf("Exponentiating\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf((n < 6) ? logc : (n < 13) ? logb : log, "%d %9llu\n", mp_count_bits(&a), tt); + } + } + fclose(log); + fclose(logb); + fclose(logc); + + log = fopen("logs/invmod.log", "w"); + for (cnt = 4; cnt <= 128; cnt += 4) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + + do { + mp_add_d(&b, 1, &b); + mp_gcd(&a, &b, &c); + } while (mp_cmp_d(&c, 1) != MP_EQ); + + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_invmod(&b, &a, &c)); + gg = (TIMFUNC() - gg)>>1; + if (tt > gg) tt = gg; + } while (++rr < 1000); + mp_mulmod(&b, &c, &a, &d); + if (mp_cmp_d(&d, 1) != MP_EQ) { + printf("Failed to invert\n"); + return 0; + } + printf("Inverting mod\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); + fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); + } + fclose(log); + + return 0; +} + diff --git a/libtommath/dep.pl b/libtommath/dep.pl new file mode 100644 index 0000000..22266e3 --- /dev/null +++ b/libtommath/dep.pl @@ -0,0 +1,121 @@ +#!/usr/bin/perl +# +# Walk through source, add labels and make classes +# +#use strict; + +my %deplist; + +#open class file and write preamble +open(CLASS, ">tommath_class.h") or die "Couldn't open tommath_class.h for writing\n"; +print CLASS "#if !(defined(LTM1) && defined(LTM2) && defined(LTM3))\n#if defined(LTM2)\n#define LTM3\n#endif\n#if defined(LTM1)\n#define LTM2\n#endif\n#define LTM1\n\n#if defined(LTM_ALL)\n"; + +foreach my $filename (glob "bn*.c") { + my $define = $filename; + + # convert filename to upper case so we can use it as a define + $define =~ tr/[a-z]/[A-Z]/; + $define =~ tr/\./_/; + print CLASS "#define $define\n"; + + # now copy text and apply #ifdef as required + my $apply = 0; + open(SRC, "<$filename"); + open(OUT, ">tmp"); + + # first line will be the #ifdef + my $line = ; + if ($line =~ /include/) { + print OUT $line; + } else { + print OUT "#include \n#ifdef $define\n$line"; + $apply = 1; + } + while () { + if (!($_ =~ /tommath\.h/)) { + print OUT $_; + } + } + if ($apply == 1) { + print OUT "#endif\n"; + } + close SRC; + close OUT; + + unlink($filename); + rename("tmp", $filename); +} +print CLASS "#endif\n\n"; + +# now do classes + +foreach my $filename (glob "bn*.c") { + open(SRC, "<$filename") or die "Can't open source file!\n"; + + # convert filename to upper case so we can use it as a define + $filename =~ tr/[a-z]/[A-Z]/; + $filename =~ tr/\./_/; + + print CLASS "#if defined($filename)\n"; + my $list = $filename; + + # scan for mp_* and make classes + while () { + my $line = $_; + while ($line =~ m/(fast_)*(s_)*mp\_[a-z_0-9]*/) { + $line = $'; + # now $& is the match, we want to skip over LTM keywords like + # mp_int, mp_word, mp_digit + if (!($& eq "mp_digit") && !($& eq "mp_word") && !($& eq "mp_int")) { + my $a = $&; + $a =~ tr/[a-z]/[A-Z]/; + $a = "BN_" . $a . "_C"; + if (!($list =~ /$a/)) { + print CLASS " #define $a\n"; + } + $list = $list . "," . $a; + } + } + } + @deplist{$filename} = $list; + + print CLASS "#endif\n\n"; + close SRC; +} + +print CLASS "#ifdef LTM3\n#define LTM_LAST\n#endif\n#include \n#include \n#else\n#define LTM_LAST\n#endif\n"; +close CLASS; + +#now let's make a cool call graph... + +open(OUT,">callgraph.txt"); +$indent = 0; +foreach (keys %deplist) { + $list = ""; + draw_func(@deplist{$_}); + print OUT "\n\n"; +} +close(OUT); + +sub draw_func() +{ + my @funcs = split(",", $_[0]); + if ($list =~ /@funcs[0]/) { + return; + } else { + $list = $list . @funcs[0]; + } + if ($indent == 0) { } + elsif ($indent >= 1) { print OUT "| " x ($indent - 1) . "+--->"; } + print OUT @funcs[0] . "\n"; + shift @funcs; + my $temp = $list; + foreach my $i (@funcs) { + ++$indent; + draw_func(@deplist{$i}); + --$indent; + } + $list = $temp; +} + + diff --git a/libtommath/etc/2kprime.1 b/libtommath/etc/2kprime.1 new file mode 100644 index 0000000..c41ded1 --- /dev/null +++ b/libtommath/etc/2kprime.1 @@ -0,0 +1,2 @@ +256-bits (k = 36113) = 115792089237316195423570985008687907853269984665640564039457584007913129603823 +512-bits (k = 38117) = 13407807929942597099574024998205846127479365820592393377723561443721764030073546976801874298166903427690031858186486050853753882811946569946433649006045979 diff --git a/libtommath/etc/2kprime.c b/libtommath/etc/2kprime.c new file mode 100644 index 0000000..d48b83e --- /dev/null +++ b/libtommath/etc/2kprime.c @@ -0,0 +1,80 @@ +/* Makes safe primes of a 2k nature */ +#include +#include + +int sizes[] = {256, 512, 768, 1024, 1536, 2048, 3072, 4096}; + +int main(void) +{ + char buf[2000]; + int x, y; + mp_int q, p; + FILE *out; + clock_t t1; + mp_digit z; + + mp_init_multi(&q, &p, NULL); + + out = fopen("2kprime.1", "w"); + for (x = 0; x < (int)(sizeof(sizes) / sizeof(sizes[0])); x++) { + top: + mp_2expt(&q, sizes[x]); + mp_add_d(&q, 3, &q); + z = -3; + + t1 = clock(); + for(;;) { + mp_sub_d(&q, 4, &q); + z += 4; + + if (z > MP_MASK) { + printf("No primes of size %d found\n", sizes[x]); + break; + } + + if (clock() - t1 > CLOCKS_PER_SEC) { + printf("."); fflush(stdout); +// sleep((clock() - t1 + CLOCKS_PER_SEC/2)/CLOCKS_PER_SEC); + t1 = clock(); + } + + /* quick test on q */ + mp_prime_is_prime(&q, 1, &y); + if (y == 0) { + continue; + } + + /* find (q-1)/2 */ + mp_sub_d(&q, 1, &p); + mp_div_2(&p, &p); + mp_prime_is_prime(&p, 3, &y); + if (y == 0) { + continue; + } + + /* test on q */ + mp_prime_is_prime(&q, 3, &y); + if (y == 0) { + continue; + } + + break; + } + + if (y == 0) { + ++sizes[x]; + goto top; + } + + mp_toradix(&q, buf, 10); + printf("\n\n%d-bits (k = %lu) = %s\n", sizes[x], z, buf); + fprintf(out, "%d-bits (k = %lu) = %s\n", sizes[x], z, buf); fflush(out); + } + + return 0; +} + + + + + diff --git a/libtommath/etc/drprime.c b/libtommath/etc/drprime.c new file mode 100644 index 0000000..0ab8ea6 --- /dev/null +++ b/libtommath/etc/drprime.c @@ -0,0 +1,60 @@ +/* Makes safe primes of a DR nature */ +#include + +int sizes[] = { 1+256/DIGIT_BIT, 1+512/DIGIT_BIT, 1+768/DIGIT_BIT, 1+1024/DIGIT_BIT, 1+2048/DIGIT_BIT, 1+4096/DIGIT_BIT }; +int main(void) +{ + int res, x, y; + char buf[4096]; + FILE *out; + mp_int a, b; + + mp_init(&a); + mp_init(&b); + + out = fopen("drprimes.txt", "w"); + for (x = 0; x < (int)(sizeof(sizes)/sizeof(sizes[0])); x++) { + top: + printf("Seeking a %d-bit safe prime\n", sizes[x] * DIGIT_BIT); + mp_grow(&a, sizes[x]); + mp_zero(&a); + for (y = 1; y < sizes[x]; y++) { + a.dp[y] = MP_MASK; + } + + /* make a DR modulus */ + a.dp[0] = -1; + a.used = sizes[x]; + + /* now loop */ + res = 0; + for (;;) { + a.dp[0] += 4; + if (a.dp[0] >= MP_MASK) break; + mp_prime_is_prime(&a, 1, &res); + if (res == 0) continue; + printf("."); fflush(stdout); + mp_sub_d(&a, 1, &b); + mp_div_2(&b, &b); + mp_prime_is_prime(&b, 3, &res); + if (res == 0) continue; + mp_prime_is_prime(&a, 3, &res); + if (res == 1) break; + } + + if (res != 1) { + printf("Error not DR modulus\n"); sizes[x] += 1; goto top; + } else { + mp_toradix(&a, buf, 10); + printf("\n\np == %s\n\n", buf); + fprintf(out, "%d-bit prime:\np == %s\n\n", mp_count_bits(&a), buf); fflush(out); + } + } + fclose(out); + + mp_clear(&a); + mp_clear(&b); + + return 0; +} + diff --git a/libtommath/etc/drprimes.28 b/libtommath/etc/drprimes.28 new file mode 100644 index 0000000..9d438ad --- /dev/null +++ b/libtommath/etc/drprimes.28 @@ -0,0 +1,25 @@ +DR safe primes for 28-bit digits. + +224-bit prime: +p == 26959946667150639794667015087019630673637144422540572481103341844143 + +532-bit prime: +p == 14059105607947488696282932836518693308967803494693489478439861164411992439598399594747002144074658928593502845729752797260025831423419686528151609940203368691747 + +784-bit prime: +p == 101745825697019260773923519755878567461315282017759829107608914364075275235254395622580447400994175578963163918967182013639660669771108475957692810857098847138903161308502419410142185759152435680068435915159402496058513611411688900243039 + +1036-bit prime: +p == 736335108039604595805923406147184530889923370574768772191969612422073040099331944991573923112581267542507986451953227192970402893063850485730703075899286013451337291468249027691733891486704001513279827771740183629161065194874727962517148100775228363421083691764065477590823919364012917984605619526140821798437127 + +1540-bit prime: +p == 38564998830736521417281865696453025806593491967131023221754800625044118265468851210705360385717536794615180260494208076605798671660719333199513807806252394423283413430106003596332513246682903994829528690198205120921557533726473585751382193953592127439965050261476810842071573684505878854588706623484573925925903505747545471088867712185004135201289273405614415899438276535626346098904241020877974002916168099951885406379295536200413493190419727789712076165162175783 + +2072-bit prime: +p == 542189391331696172661670440619180536749994166415993334151601745392193484590296600979602378676624808129613777993466242203025054573692562689251250471628358318743978285860720148446448885701001277560572526947619392551574490839286458454994488665744991822837769918095117129546414124448777033941223565831420390846864429504774477949153794689948747680362212954278693335653935890352619041936727463717926744868338358149568368643403037768649616778526013610493696186055899318268339432671541328195724261329606699831016666359440874843103020666106568222401047720269951530296879490444224546654729111504346660859907296364097126834834235287147 + +3080-bit prime: +p == 1487259134814709264092032648525971038895865645148901180585340454985524155135260217788758027400478312256339496385275012465661575576202252063145698732079880294664220579764848767704076761853197216563262660046602703973050798218246170835962005598561669706844469447435461092542265792444947706769615695252256130901271870341005768912974433684521436211263358097522726462083917939091760026658925757076733484173202927141441492573799914240222628795405623953109131594523623353044898339481494120112723445689647986475279242446083151413667587008191682564376412347964146113898565886683139407005941383669325997475076910488086663256335689181157957571445067490187939553165903773554290260531009121879044170766615232300936675369451260747671432073394867530820527479172464106442450727640226503746586340279816318821395210726268291535648506190714616083163403189943334431056876038286530365757187367147446004855912033137386225053275419626102417236133948503 + +4116-bit prime: +p == 1095121115716677802856811290392395128588168592409109494900178008967955253005183831872715423151551999734857184538199864469605657805519106717529655044054833197687459782636297255219742994736751541815269727940751860670268774903340296040006114013971309257028332849679096824800250742691718610670812374272414086863715763724622797509437062518082383056050144624962776302147890521249477060215148275163688301275847155316042279405557632639366066847442861422164832655874655824221577849928863023018366835675399949740429332468186340518172487073360822220449055340582568461568645259954873303616953776393853174845132081121976327462740354930744487429617202585015510744298530101547706821590188733515880733527449780963163909830077616357506845523215289297624086914545378511082534229620116563260168494523906566709418166011112754529766183554579321224940951177394088465596712620076240067370589036924024728375076210477267488679008016579588696191194060127319035195370137160936882402244399699172017835144537488486396906144217720028992863941288217185353914991583400421682751000603596655790990815525126154394344641336397793791497068253936771017031980867706707490224041075826337383538651825493679503771934836094655802776331664261631740148281763487765852746577808019633679 diff --git a/libtommath/etc/drprimes.txt b/libtommath/etc/drprimes.txt new file mode 100644 index 0000000..2c887ea --- /dev/null +++ b/libtommath/etc/drprimes.txt @@ -0,0 +1,6 @@ +280-bit prime: +p == 1942668892225729070919461906823518906642406839052139521251812409738904285204940164839 + +532-bit prime: +p == 14059105607947488696282932836518693308967803494693489478439861164411992439598399594747002144074658928593502845729752797260025831423419686528151609940203368691747 + diff --git a/libtommath/etc/makefile b/libtommath/etc/makefile new file mode 100644 index 0000000..99154d8 --- /dev/null +++ b/libtommath/etc/makefile @@ -0,0 +1,50 @@ +CFLAGS += -Wall -W -Wshadow -O3 -fomit-frame-pointer -funroll-loops -I../ + +# default lib name (requires install with root) +# LIBNAME=-ltommath + +# libname when you can't install the lib with install +LIBNAME=../libtommath.a + +#provable primes +pprime: pprime.o + $(CC) pprime.o $(LIBNAME) -o pprime + +# portable [well requires clock()] tuning app +tune: tune.o + $(CC) tune.o $(LIBNAME) -o tune + +# same app but using RDTSC for higher precision [requires 80586+], coff based gcc installs [e.g. ming, cygwin, djgpp] +tune86: tune.c + nasm -f coff timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86 + +# for cygwin +tune86c: tune.c + nasm -f gnuwin32 timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86 + +#make tune86 for linux or any ELF format +tune86l: tune.c + nasm -f elf -DUSE_ELF timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86l + +# spits out mersenne primes +mersenne: mersenne.o + $(CC) mersenne.o $(LIBNAME) -o mersenne + +# fines DR safe primes for the given config +drprime: drprime.o + $(CC) drprime.o $(LIBNAME) -o drprime + +# fines 2k safe primes for the given config +2kprime: 2kprime.o + $(CC) 2kprime.o $(LIBNAME) -o 2kprime + +mont: mont.o + $(CC) mont.o $(LIBNAME) -o mont + + +clean: + rm -f *.log *.o *.obj *.exe pprime tune mersenne drprime tune86 tune86l mont 2kprime pprime.dat \ + *.da *.dyn *.dpi *~ diff --git a/libtommath/etc/makefile.icc b/libtommath/etc/makefile.icc new file mode 100644 index 0000000..0a50728 --- /dev/null +++ b/libtommath/etc/makefile.icc @@ -0,0 +1,67 @@ +CC = icc + +CFLAGS += -I../ + +# optimize for SPEED +# +# -mcpu= can be pentium, pentiumpro (covers PII through PIII) or pentium4 +# -ax? specifies make code specifically for ? but compatible with IA-32 +# -x? specifies compile solely for ? [not specifically IA-32 compatible] +# +# where ? is +# K - PIII +# W - first P4 [Williamette] +# N - P4 Northwood +# P - P4 Prescott +# B - Blend of P4 and PM [mobile] +# +# Default to just generic max opts +CFLAGS += -O3 -xN -ip + +# default lib name (requires install with root) +# LIBNAME=-ltommath + +# libname when you can't install the lib with install +LIBNAME=../libtommath.a + +#provable primes +pprime: pprime.o + $(CC) pprime.o $(LIBNAME) -o pprime + +# portable [well requires clock()] tuning app +tune: tune.o + $(CC) tune.o $(LIBNAME) -o tune + +# same app but using RDTSC for higher precision [requires 80586+], coff based gcc installs [e.g. ming, cygwin, djgpp] +tune86: tune.c + nasm -f coff timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86 + +# for cygwin +tune86c: tune.c + nasm -f gnuwin32 timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86 + +#make tune86 for linux or any ELF format +tune86l: tune.c + nasm -f elf -DUSE_ELF timer.asm + $(CC) -DX86_TIMER $(CFLAGS) tune.c timer.o $(LIBNAME) -o tune86l + +# spits out mersenne primes +mersenne: mersenne.o + $(CC) mersenne.o $(LIBNAME) -o mersenne + +# fines DR safe primes for the given config +drprime: drprime.o + $(CC) drprime.o $(LIBNAME) -o drprime + +# fines 2k safe primes for the given config +2kprime: 2kprime.o + $(CC) 2kprime.o $(LIBNAME) -o 2kprime + +mont: mont.o + $(CC) mont.o $(LIBNAME) -o mont + + +clean: + rm -f *.log *.o *.obj *.exe pprime tune mersenne drprime tune86 tune86l mont 2kprime pprime.dat *.il diff --git a/libtommath/etc/makefile.msvc b/libtommath/etc/makefile.msvc new file mode 100644 index 0000000..2833372 --- /dev/null +++ b/libtommath/etc/makefile.msvc @@ -0,0 +1,23 @@ +#MSVC Makefile +# +#Tom St Denis + +CFLAGS = /I../ /Ox /DWIN32 /W3 + +pprime: pprime.obj + cl pprime.obj ../tommath.lib + +mersenne: mersenne.obj + cl mersenne.obj ../tommath.lib + +tune: tune.obj + cl tune.obj ../tommath.lib + +mont: mont.obj + cl mont.obj ../tommath.lib + +drprime: drprime.obj + cl drprime.obj ../tommath.lib + +2kprime: 2kprime.obj + cl 2kprime.obj ../tommath.lib diff --git a/libtommath/etc/mersenne.c b/libtommath/etc/mersenne.c new file mode 100644 index 0000000..1cd5b50 --- /dev/null +++ b/libtommath/etc/mersenne.c @@ -0,0 +1,140 @@ +/* Finds Mersenne primes using the Lucas-Lehmer test + * + * Tom St Denis, tomstdenis@iahu.ca + */ +#include +#include + +int +is_mersenne (long s, int *pp) +{ + mp_int n, u; + int res, k; + + *pp = 0; + + if ((res = mp_init (&n)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&u)) != MP_OKAY) { + goto LBL_N; + } + + /* n = 2^s - 1 */ + if ((res = mp_2expt(&n, s)) != MP_OKAY) { + goto LBL_MU; + } + if ((res = mp_sub_d (&n, 1, &n)) != MP_OKAY) { + goto LBL_MU; + } + + /* set u=4 */ + mp_set (&u, 4); + + /* for k=1 to s-2 do */ + for (k = 1; k <= s - 2; k++) { + /* u = u^2 - 2 mod n */ + if ((res = mp_sqr (&u, &u)) != MP_OKAY) { + goto LBL_MU; + } + if ((res = mp_sub_d (&u, 2, &u)) != MP_OKAY) { + goto LBL_MU; + } + + /* make sure u is positive */ + while (u.sign == MP_NEG) { + if ((res = mp_add (&u, &n, &u)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* reduce */ + if ((res = mp_reduce_2k (&u, &n, 1)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* if u == 0 then its prime */ + if (mp_iszero (&u) == 1) { + mp_prime_is_prime(&n, 8, pp); + if (*pp != 1) printf("FAILURE\n"); + } + + res = MP_OKAY; +LBL_MU:mp_clear (&u); +LBL_N:mp_clear (&n); + return res; +} + +/* square root of a long < 65536 */ +long +i_sqrt (long x) +{ + long x1, x2; + + x2 = 16; + do { + x1 = x2; + x2 = x1 - ((x1 * x1) - x) / (2 * x1); + } while (x1 != x2); + + if (x1 * x1 > x) { + --x1; + } + + return x1; +} + +/* is the long prime by brute force */ +int +isprime (long k) +{ + long y, z; + + y = i_sqrt (k); + for (z = 2; z <= y; z++) { + if ((k % z) == 0) + return 0; + } + return 1; +} + + +int +main (void) +{ + int pp; + long k; + clock_t tt; + + k = 3; + + for (;;) { + /* start time */ + tt = clock (); + + /* test if 2^k - 1 is prime */ + if (is_mersenne (k, &pp) != MP_OKAY) { + printf ("Whoa error\n"); + return -1; + } + + if (pp == 1) { + /* count time */ + tt = clock () - tt; + + /* display if prime */ + printf ("2^%-5ld - 1 is prime, test took %ld ticks\n", k, tt); + } + + /* goto next odd exponent */ + k += 2; + + /* but make sure its prime */ + while (isprime (k) == 0) { + k += 2; + } + } + return 0; +} diff --git a/libtommath/etc/mont.c b/libtommath/etc/mont.c new file mode 100644 index 0000000..dbf1735 --- /dev/null +++ b/libtommath/etc/mont.c @@ -0,0 +1,46 @@ +/* tests the montgomery routines */ +#include + +int main(void) +{ + mp_int modulus, R, p, pp; + mp_digit mp; + long x, y; + + srand(time(NULL)); + mp_init_multi(&modulus, &R, &p, &pp, NULL); + + /* loop through various sizes */ + for (x = 4; x < 256; x++) { + printf("DIGITS == %3ld...", x); fflush(stdout); + + /* make up the odd modulus */ + mp_rand(&modulus, x); + modulus.dp[0] |= 1; + + /* now find the R value */ + mp_montgomery_calc_normalization(&R, &modulus); + mp_montgomery_setup(&modulus, &mp); + + /* now run through a bunch tests */ + for (y = 0; y < 1000; y++) { + mp_rand(&p, x/2); /* p = random */ + mp_mul(&p, &R, &pp); /* pp = R * p */ + mp_montgomery_reduce(&pp, &modulus, mp); + + /* should be equal to p */ + if (mp_cmp(&pp, &p) != MP_EQ) { + printf("FAILURE!\n"); + exit(-1); + } + } + printf("PASSED\n"); + } + + return 0; +} + + + + + diff --git a/libtommath/etc/pprime.c b/libtommath/etc/pprime.c new file mode 100644 index 0000000..26e0d84 --- /dev/null +++ b/libtommath/etc/pprime.c @@ -0,0 +1,396 @@ +/* Generates provable primes + * + * See http://iahu.ca:8080/papers/pp.pdf for more info. + * + * Tom St Denis, tomstdenis@iahu.ca, http://tom.iahu.ca + */ +#include +#include "tommath.h" + +int n_prime; +FILE *primes; + +/* fast square root */ +static mp_digit +i_sqrt (mp_word x) +{ + mp_word x1, x2; + + x2 = x; + do { + x1 = x2; + x2 = x1 - ((x1 * x1) - x) / (2 * x1); + } while (x1 != x2); + + if (x1 * x1 > x) { + --x1; + } + + return x1; +} + + +/* generates a prime digit */ +static void gen_prime (void) +{ + mp_digit r, x, y, next; + FILE *out; + + out = fopen("pprime.dat", "wb"); + + /* write first set of primes */ + r = 3; fwrite(&r, 1, sizeof(mp_digit), out); + r = 5; fwrite(&r, 1, sizeof(mp_digit), out); + r = 7; fwrite(&r, 1, sizeof(mp_digit), out); + r = 11; fwrite(&r, 1, sizeof(mp_digit), out); + r = 13; fwrite(&r, 1, sizeof(mp_digit), out); + r = 17; fwrite(&r, 1, sizeof(mp_digit), out); + r = 19; fwrite(&r, 1, sizeof(mp_digit), out); + r = 23; fwrite(&r, 1, sizeof(mp_digit), out); + r = 29; fwrite(&r, 1, sizeof(mp_digit), out); + r = 31; fwrite(&r, 1, sizeof(mp_digit), out); + + /* get square root, since if 'r' is composite its factors must be < than this */ + y = i_sqrt (r); + next = (y + 1) * (y + 1); + + for (;;) { + do { + r += 2; /* next candidate */ + r &= MP_MASK; + if (r < 31) break; + + /* update sqrt ? */ + if (next <= r) { + ++y; + next = (y + 1) * (y + 1); + } + + /* loop if divisible by 3,5,7,11,13,17,19,23,29 */ + if ((r % 3) == 0) { + x = 0; + continue; + } + if ((r % 5) == 0) { + x = 0; + continue; + } + if ((r % 7) == 0) { + x = 0; + continue; + } + if ((r % 11) == 0) { + x = 0; + continue; + } + if ((r % 13) == 0) { + x = 0; + continue; + } + if ((r % 17) == 0) { + x = 0; + continue; + } + if ((r % 19) == 0) { + x = 0; + continue; + } + if ((r % 23) == 0) { + x = 0; + continue; + } + if ((r % 29) == 0) { + x = 0; + continue; + } + + /* now check if r is divisible by x + k={1,7,11,13,17,19,23,29} */ + for (x = 30; x <= y; x += 30) { + if ((r % (x + 1)) == 0) { + x = 0; + break; + } + if ((r % (x + 7)) == 0) { + x = 0; + break; + } + if ((r % (x + 11)) == 0) { + x = 0; + break; + } + if ((r % (x + 13)) == 0) { + x = 0; + break; + } + if ((r % (x + 17)) == 0) { + x = 0; + break; + } + if ((r % (x + 19)) == 0) { + x = 0; + break; + } + if ((r % (x + 23)) == 0) { + x = 0; + break; + } + if ((r % (x + 29)) == 0) { + x = 0; + break; + } + } + } while (x == 0); + if (r > 31) { fwrite(&r, 1, sizeof(mp_digit), out); printf("%9d\r", r); fflush(stdout); } + if (r < 31) break; + } + + fclose(out); +} + +void load_tab(void) +{ + primes = fopen("pprime.dat", "rb"); + if (primes == NULL) { + gen_prime(); + primes = fopen("pprime.dat", "rb"); + } + fseek(primes, 0, SEEK_END); + n_prime = ftell(primes) / sizeof(mp_digit); +} + +mp_digit prime_digit(void) +{ + int n; + mp_digit d; + + n = abs(rand()) % n_prime; + fseek(primes, n * sizeof(mp_digit), SEEK_SET); + fread(&d, 1, sizeof(mp_digit), primes); + return d; +} + + +/* makes a prime of at least k bits */ +int +pprime (int k, int li, mp_int * p, mp_int * q) +{ + mp_int a, b, c, n, x, y, z, v; + int res, ii; + static const mp_digit bases[] = { 2, 3, 5, 7, 11, 13, 17, 19 }; + + /* single digit ? */ + if (k <= (int) DIGIT_BIT) { + mp_set (p, prime_digit ()); + return MP_OKAY; + } + + if ((res = mp_init (&c)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&v)) != MP_OKAY) { + goto LBL_C; + } + + /* product of first 50 primes */ + if ((res = + mp_read_radix (&v, + "19078266889580195013601891820992757757219839668357012055907516904309700014933909014729740190", + 10)) != MP_OKAY) { + goto LBL_V; + } + + if ((res = mp_init (&a)) != MP_OKAY) { + goto LBL_V; + } + + /* set the prime */ + mp_set (&a, prime_digit ()); + + if ((res = mp_init (&b)) != MP_OKAY) { + goto LBL_A; + } + + if ((res = mp_init (&n)) != MP_OKAY) { + goto LBL_B; + } + + if ((res = mp_init (&x)) != MP_OKAY) { + goto LBL_N; + } + + if ((res = mp_init (&y)) != MP_OKAY) { + goto LBL_X; + } + + if ((res = mp_init (&z)) != MP_OKAY) { + goto LBL_Y; + } + + /* now loop making the single digit */ + while (mp_count_bits (&a) < k) { + fprintf (stderr, "prime has %4d bits left\r", k - mp_count_bits (&a)); + fflush (stderr); + top: + mp_set (&b, prime_digit ()); + + /* now compute z = a * b * 2 */ + if ((res = mp_mul (&a, &b, &z)) != MP_OKAY) { /* z = a * b */ + goto LBL_Z; + } + + if ((res = mp_copy (&z, &c)) != MP_OKAY) { /* c = a * b */ + goto LBL_Z; + } + + if ((res = mp_mul_2 (&z, &z)) != MP_OKAY) { /* z = 2 * a * b */ + goto LBL_Z; + } + + /* n = z + 1 */ + if ((res = mp_add_d (&z, 1, &n)) != MP_OKAY) { /* n = z + 1 */ + goto LBL_Z; + } + + /* check (n, v) == 1 */ + if ((res = mp_gcd (&n, &v, &y)) != MP_OKAY) { /* y = (n, v) */ + goto LBL_Z; + } + + if (mp_cmp_d (&y, 1) != MP_EQ) + goto top; + + /* now try base x=bases[ii] */ + for (ii = 0; ii < li; ii++) { + mp_set (&x, bases[ii]); + + /* compute x^a mod n */ + if ((res = mp_exptmod (&x, &a, &n, &y)) != MP_OKAY) { /* y = x^a mod n */ + goto LBL_Z; + } + + /* if y == 1 loop */ + if (mp_cmp_d (&y, 1) == MP_EQ) + continue; + + /* now x^2a mod n */ + if ((res = mp_sqrmod (&y, &n, &y)) != MP_OKAY) { /* y = x^2a mod n */ + goto LBL_Z; + } + + if (mp_cmp_d (&y, 1) == MP_EQ) + continue; + + /* compute x^b mod n */ + if ((res = mp_exptmod (&x, &b, &n, &y)) != MP_OKAY) { /* y = x^b mod n */ + goto LBL_Z; + } + + /* if y == 1 loop */ + if (mp_cmp_d (&y, 1) == MP_EQ) + continue; + + /* now x^2b mod n */ + if ((res = mp_sqrmod (&y, &n, &y)) != MP_OKAY) { /* y = x^2b mod n */ + goto LBL_Z; + } + + if (mp_cmp_d (&y, 1) == MP_EQ) + continue; + + /* compute x^c mod n == x^ab mod n */ + if ((res = mp_exptmod (&x, &c, &n, &y)) != MP_OKAY) { /* y = x^ab mod n */ + goto LBL_Z; + } + + /* if y == 1 loop */ + if (mp_cmp_d (&y, 1) == MP_EQ) + continue; + + /* now compute (x^c mod n)^2 */ + if ((res = mp_sqrmod (&y, &n, &y)) != MP_OKAY) { /* y = x^2ab mod n */ + goto LBL_Z; + } + + /* y should be 1 */ + if (mp_cmp_d (&y, 1) != MP_EQ) + continue; + break; + } + + /* no bases worked? */ + if (ii == li) + goto top; + +{ + char buf[4096]; + + mp_toradix(&n, buf, 10); + printf("Certificate of primality for:\n%s\n\n", buf); + mp_toradix(&a, buf, 10); + printf("A == \n%s\n\n", buf); + mp_toradix(&b, buf, 10); + printf("B == \n%s\n\nG == %d\n", buf, bases[ii]); + printf("----------------------------------------------------------------\n"); +} + + /* a = n */ + mp_copy (&n, &a); + } + + /* get q to be the order of the large prime subgroup */ + mp_sub_d (&n, 1, q); + mp_div_2 (q, q); + mp_div (q, &b, q, NULL); + + mp_exch (&n, p); + + res = MP_OKAY; +LBL_Z:mp_clear (&z); +LBL_Y:mp_clear (&y); +LBL_X:mp_clear (&x); +LBL_N:mp_clear (&n); +LBL_B:mp_clear (&b); +LBL_A:mp_clear (&a); +LBL_V:mp_clear (&v); +LBL_C:mp_clear (&c); + return res; +} + + +int +main (void) +{ + mp_int p, q; + char buf[4096]; + int k, li; + clock_t t1; + + srand (time (NULL)); + load_tab(); + + printf ("Enter # of bits: \n"); + fgets (buf, sizeof (buf), stdin); + sscanf (buf, "%d", &k); + + printf ("Enter number of bases to try (1 to 8):\n"); + fgets (buf, sizeof (buf), stdin); + sscanf (buf, "%d", &li); + + + mp_init (&p); + mp_init (&q); + + t1 = clock (); + pprime (k, li, &p, &q); + t1 = clock () - t1; + + printf ("\n\nTook %ld ticks, %d bits\n", t1, mp_count_bits (&p)); + + mp_toradix (&p, buf, 10); + printf ("P == %s\n", buf); + mp_toradix (&q, buf, 10); + printf ("Q == %s\n", buf); + + return 0; +} diff --git a/libtommath/etc/prime.1024 b/libtommath/etc/prime.1024 new file mode 100644 index 0000000..5636e2d --- /dev/null +++ b/libtommath/etc/prime.1024 @@ -0,0 +1,414 @@ +Enter # of bits: +Enter number of bases to try (1 to 8): +Certificate of primality for: +36360080703173363 + +A == +89963569 + +B == +202082249 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +4851595597739856136987139 + +A == +36360080703173363 + +B == +66715963 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +19550639734462621430325731591027 + +A == +4851595597739856136987139 + +B == +2014867 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +10409036141344317165691858509923818734539 + +A == +19550639734462621430325731591027 + +B == +266207047 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1049829549988285012736475602118094726647504414203 + +A == +10409036141344317165691858509923818734539 + +B == +50428759 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +77194737385528288387712399596835459931920358844586615003 + +A == +1049829549988285012736475602118094726647504414203 + +B == +36765367 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +35663756695365208574443215955488689578374232732893628896541201763 + +A == +77194737385528288387712399596835459931920358844586615003 + +B == +230998627 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +16711831463502165169495622246023119698415848120292671294127567620396469803 + +A == +35663756695365208574443215955488689578374232732893628896541201763 + +B == +234297127 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +6163534781560285962890718925972249753147470953579266394395432475622345597103528739 + +A == +16711831463502165169495622246023119698415848120292671294127567620396469803 + +B == +184406323 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +814258256205243497704094951432575867360065658372158511036259934640748088306764553488803787 + +A == +6163534781560285962890718925972249753147470953579266394395432475622345597103528739 + +B == +66054487 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +176469695533271657902814176811660357049007467856432383037590673407330246967781451723764079581998187 + +A == +814258256205243497704094951432575867360065658372158511036259934640748088306764553488803787 + +B == +108362239 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +44924492859445516541759485198544012102424796403707253610035148063863073596051272171194806669756971406400419 + +A == +176469695533271657902814176811660357049007467856432383037590673407330246967781451723764079581998187 + +B == +127286707 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +20600996927219343383225424320134474929609459588323857796871086845924186191561749519858600696159932468024710985371059 + +A == +44924492859445516541759485198544012102424796403707253610035148063863073596051272171194806669756971406400419 + +B == +229284691 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +6295696427695493110141186605837397185848992307978456138112526915330347715236378041486547994708748840844217371233735072572979 + +A == +20600996927219343383225424320134474929609459588323857796871086845924186191561749519858600696159932468024710985371059 + +B == +152800771 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +3104984078042317488749073016454213579257792635142218294052134804187631661145261015102617582090263808696699966840735333252107678792123 + +A == +6295696427695493110141186605837397185848992307978456138112526915330347715236378041486547994708748840844217371233735072572979 + +B == +246595759 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +26405175827665701256325699315126705508919255051121452292124404943796947287968603975320562847910946802396632302209435206627913466015741799499 + +A == +3104984078042317488749073016454213579257792635142218294052134804187631661145261015102617582090263808696699966840735333252107678792123 + +B == +4252063 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +11122146237908413610034600609460545703591095894418599759742741406628055069007082998134905595800236452010905900391505454890446585211975124558601770163 + +A == +26405175827665701256325699315126705508919255051121452292124404943796947287968603975320562847910946802396632302209435206627913466015741799499 + +B == +210605419 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1649861642047798890580354082088712649911849362201343649289384923147797960364736011515757482030049342943790127685185806092659832129486307035500638595572396187 + +A == +11122146237908413610034600609460545703591095894418599759742741406628055069007082998134905595800236452010905900391505454890446585211975124558601770163 + +B == +74170111 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +857983367126266717607389719637086684134462613006415859877666235955788392464081914127715967940968197765042399904117392707518175220864852816390004264107201177394565363 + +A == +1649861642047798890580354082088712649911849362201343649289384923147797960364736011515757482030049342943790127685185806092659832129486307035500638595572396187 + +B == +260016763 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +175995909353623703257072120479340610010337144085688850745292031336724691277374210929188442230237711063783727092685448718515661641054886101716698390145283196296702450566161283 + +A == +857983367126266717607389719637086684134462613006415859877666235955788392464081914127715967940968197765042399904117392707518175220864852816390004264107201177394565363 + +B == +102563707 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +48486002551155667224487059713350447239190772068092630563272168418880661006593537218144160068395218642353495339720640699721703003648144463556291315694787862009052641640656933232794283 + +A == +175995909353623703257072120479340610010337144085688850745292031336724691277374210929188442230237711063783727092685448718515661641054886101716698390145283196296702450566161283 + +B == +137747527 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +13156468011529105025061495011938518171328604045212410096476697450506055664012861932372156505805788068791146986282263016790631108386790291275939575123375304599622623328517354163964228279867403 + +A == +48486002551155667224487059713350447239190772068092630563272168418880661006593537218144160068395218642353495339720640699721703003648144463556291315694787862009052641640656933232794283 + +B == +135672847 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +6355194692790533601105154341731997464407930009404822926832136060319955058388106456084549316415200519472481147942263916585428906582726749131479465958107142228236909665306781538860053107680830113869123 + +A == +13156468011529105025061495011938518171328604045212410096476697450506055664012861932372156505805788068791146986282263016790631108386790291275939575123375304599622623328517354163964228279867403 + +B == +241523587 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +3157116676535430302794438027544146642863331358530722860333745617571010460905857862561870488000265751138954271040017454405707755458702044884023184574412221802502351503929935224995314581932097706874819348858083 + +A == +6355194692790533601105154341731997464407930009404822926832136060319955058388106456084549316415200519472481147942263916585428906582726749131479465958107142228236909665306781538860053107680830113869123 + +B == +248388667 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +390533129219992506725320633489467713907837370444962163378727819939092929448752905310115311180032249230394348337568973177802874166228132778126338883671958897238722734394783244237133367055422297736215754829839364158067 + +A == +3157116676535430302794438027544146642863331358530722860333745617571010460905857862561870488000265751138954271040017454405707755458702044884023184574412221802502351503929935224995314581932097706874819348858083 + +B == +61849651 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +48583654555070224891047847050732516652910250240135992225139515777200432486685999462997073444468380434359929499498804723793106565291183220444221080449740542884172281158126259373095216435009661050109711341419005972852770440739 + +A == +390533129219992506725320633489467713907837370444962163378727819939092929448752905310115311180032249230394348337568973177802874166228132778126338883671958897238722734394783244237133367055422297736215754829839364158067 + +B == +62201707 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +25733035251905120039135866524384525138869748427727001128764704499071378939227862068500633813538831598776578372709963673670934388213622433800015759585470542686333039614931682098922935087822950084908715298627996115185849260703525317419 + +A == +48583654555070224891047847050732516652910250240135992225139515777200432486685999462997073444468380434359929499498804723793106565291183220444221080449740542884172281158126259373095216435009661050109711341419005972852770440739 + +B == +264832231 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +2804594464939948901906623499531073917980499195397462605359913717827014360538186518540781517129548650937632008683280555602633122170458773895504894807182664540529077836857897972175530148107545939211339044386106111633510166695386323426241809387 + +A == +25733035251905120039135866524384525138869748427727001128764704499071378939227862068500633813538831598776578372709963673670934388213622433800015759585470542686333039614931682098922935087822950084908715298627996115185849260703525317419 + +B == +54494047 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +738136612083433720096707308165797114449914259256979340471077690416567237592465306112484843530074782721390528773594351482384711900456440808251196845265132086486672447136822046628407467459921823150600138073268385534588238548865012638209515923513516547 + +A == +2804594464939948901906623499531073917980499195397462605359913717827014360538186518540781517129548650937632008683280555602633122170458773895504894807182664540529077836857897972175530148107545939211339044386106111633510166695386323426241809387 + +B == +131594179 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +392847529056126766528615419937165193421166694172790666626558750047057558168124866940509180171236517681470100877687445134633784815352076138790217228749332398026714192707447855731679485746120589851992221508292976900578299504461333767437280988393026452846013683 + +A == +738136612083433720096707308165797114449914259256979340471077690416567237592465306112484843530074782721390528773594351482384711900456440808251196845265132086486672447136822046628407467459921823150600138073268385534588238548865012638209515923513516547 + +B == +266107603 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +168459393231883505975876919268398655632763956627405508859662408056221544310200546265681845397346956580604208064328814319465940958080244889692368602591598503944015835190587740756859842792554282496742843600573336023639256008687581291233481455395123454655488735304365627 + +A == +392847529056126766528615419937165193421166694172790666626558750047057558168124866940509180171236517681470100877687445134633784815352076138790217228749332398026714192707447855731679485746120589851992221508292976900578299504461333767437280988393026452846013683 + +B == +214408111 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +14865774288636941404884923981945833072113667565310054952177860608355263252462409554658728941191929400198053290113492910272458441655458514080123870132092365833472436407455910185221474386718838138135065780840839893113912689594815485706154461164071775481134379794909690501684643 + +A == +168459393231883505975876919268398655632763956627405508859662408056221544310200546265681845397346956580604208064328814319465940958080244889692368602591598503944015835190587740756859842792554282496742843600573336023639256008687581291233481455395123454655488735304365627 + +B == +44122723 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1213301773203241614897109856134894783021668292000023984098824423682568173639394290886185366993108292039068940333907505157813934962357206131450244004178619265868614859794316361031904412926604138893775068853175215502104744339658944443630407632290152772487455298652998368296998719996019 + +A == +14865774288636941404884923981945833072113667565310054952177860608355263252462409554658728941191929400198053290113492910272458441655458514080123870132092365833472436407455910185221474386718838138135065780840839893113912689594815485706154461164071775481134379794909690501684643 + +B == +40808563 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +186935245989515158127969129347464851990429060640910951266513740972248428651109062997368144722015290092846666943896556191257222521203647606911446635194198213436423080005867489516421559330500722264446765608763224572386410155413161172707802334865729654109050873820610813855041667633843601286843 + +A == +1213301773203241614897109856134894783021668292000023984098824423682568173639394290886185366993108292039068940333907505157813934962357206131450244004178619265868614859794316361031904412926604138893775068853175215502104744339658944443630407632290152772487455298652998368296998719996019 + +B == +77035759 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +83142661079751490510739960019112406284111408348732592580459037404394946037094409915127399165633756159385609671956087845517678367844901424617866988187132480585966721962585586730693443536100138246516868613250009028187662080828012497191775172228832247706080044971423654632146928165751885302331924491683 + +A == +186935245989515158127969129347464851990429060640910951266513740972248428651109062997368144722015290092846666943896556191257222521203647606911446635194198213436423080005867489516421559330500722264446765608763224572386410155413161172707802334865729654109050873820610813855041667633843601286843 + +B == +222383587 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +3892354773803809855317742245039794448230625839512638747643814927766738642436392673485997449586432241626440927010641564064764336402368634186618250134234189066179771240232458249806850838490410473462391401438160528157981942499581634732706904411807195259620779379274017704050790865030808501633772117217899534443 + +A == +83142661079751490510739960019112406284111408348732592580459037404394946037094409915127399165633756159385609671956087845517678367844901424617866988187132480585966721962585586730693443536100138246516868613250009028187662080828012497191775172228832247706080044971423654632146928165751885302331924491683 + +B == +23407687 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1663606652988091811284014366560171522582683318514519379924950390627250155440313691226744227787921928894551755219495501365555370027257568506349958010457682898612082048959464465369892842603765280317696116552850664773291371490339084156052244256635115997453399761029567033971998617303988376172539172702246575225837054723 + +A == +3892354773803809855317742245039794448230625839512638747643814927766738642436392673485997449586432241626440927010641564064764336402368634186618250134234189066179771240232458249806850838490410473462391401438160528157981942499581634732706904411807195259620779379274017704050790865030808501633772117217899534443 + +B == +213701827 + +G == 2 +---------------------------------------------------------------- + + +Took 33057 ticks, 1048 bits +P == 1663606652988091811284014366560171522582683318514519379924950390627250155440313691226744227787921928894551755219495501365555370027257568506349958010457682898612082048959464465369892842603765280317696116552850664773291371490339084156052244256635115997453399761029567033971998617303988376172539172702246575225837054723 +Q == 3892354773803809855317742245039794448230625839512638747643814927766738642436392673485997449586432241626440927010641564064764336402368634186618250134234189066179771240232458249806850838490410473462391401438160528157981942499581634732706904411807195259620779379274017704050790865030808501633772117217899534443 diff --git a/libtommath/etc/prime.512 b/libtommath/etc/prime.512 new file mode 100644 index 0000000..cb6ec30 --- /dev/null +++ b/libtommath/etc/prime.512 @@ -0,0 +1,205 @@ +Enter # of bits: +Enter number of bases to try (1 to 8): +Certificate of primality for: +85933926807634727 + +A == +253758023 + +B == +169322581 + +G == 5 +---------------------------------------------------------------- +Certificate of primality for: +23930198825086241462113799 + +A == +85933926807634727 + +B == +139236037 + +G == 11 +---------------------------------------------------------------- +Certificate of primality for: +6401844647261612602378676572510019 + +A == +23930198825086241462113799 + +B == +133760791 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +269731366027728777712034888684015329354259 + +A == +6401844647261612602378676572510019 + +B == +21066691 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +37942338209025571690075025099189467992329684223707 + +A == +269731366027728777712034888684015329354259 + +B == +70333567 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +15306904714258982484473490774101705363308327436988160248323 + +A == +37942338209025571690075025099189467992329684223707 + +B == +201712723 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1616744757018513392810355191503853040357155275733333124624513530099 + +A == +15306904714258982484473490774101705363308327436988160248323 + +B == +52810963 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +464222094814208047161771036072622485188658077940154689939306386289983787983 + +A == +1616744757018513392810355191503853040357155275733333124624513530099 + +B == +143566909 + +G == 5 +---------------------------------------------------------------- +Certificate of primality for: +187429931674053784626487560729643601208757374994177258429930699354770049369025096447 + +A == +464222094814208047161771036072622485188658077940154689939306386289983787983 + +B == +201875281 + +G == 5 +---------------------------------------------------------------- +Certificate of primality for: +100579220846502621074093727119851331775052664444339632682598589456666938521976625305832917563 + +A == +187429931674053784626487560729643601208757374994177258429930699354770049369025096447 + +B == +268311523 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1173616081309758475197022137833792133815753368965945885089720153370737965497134878651384030219765163 + +A == +100579220846502621074093727119851331775052664444339632682598589456666938521976625305832917563 + +B == +5834287 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +191456913489905913185935197655672585713573070349044195411728114905691721186574907738081340754373032735283623 + +A == +1173616081309758475197022137833792133815753368965945885089720153370737965497134878651384030219765163 + +B == +81567097 + +G == 5 +---------------------------------------------------------------- +Certificate of primality for: +57856530489201750164178576399448868489243874083056587683743345599898489554401618943240901541005080049321706789987519 + +A == +191456913489905913185935197655672585713573070349044195411728114905691721186574907738081340754373032735283623 + +B == +151095433 + +G == 7 +---------------------------------------------------------------- +Certificate of primality for: +13790529750452576698109671710773784949185621244122040804792403407272729038377767162233653248852099545134831722512085881814803 + +A == +57856530489201750164178576399448868489243874083056587683743345599898489554401618943240901541005080049321706789987519 + +B == +119178679 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +7075985989000817742677547821106534174334812111605018857703825637170140040509067704269696198231266351631132464035671858077052876058979 + +A == +13790529750452576698109671710773784949185621244122040804792403407272729038377767162233653248852099545134831722512085881814803 + +B == +256552363 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +1227273006232588072907488910282307435921226646895131225407452056677899411162892829564455154080310937471747140942360789623819327234258162420463 + +A == +7075985989000817742677547821106534174334812111605018857703825637170140040509067704269696198231266351631132464035671858077052876058979 + +B == +86720989 + +G == 5 +---------------------------------------------------------------- +Certificate of primality for: +446764896913554613686067036908702877942872355053329937790398156069936255759889884246832779737114032666318220500106499161852193765380831330106375235763 + +A == +1227273006232588072907488910282307435921226646895131225407452056677899411162892829564455154080310937471747140942360789623819327234258162420463 + +B == +182015287 + +G == 2 +---------------------------------------------------------------- +Certificate of primality for: +5290203010849586596974953717018896543907195901082056939587768479377028575911127944611236020459652034082251335583308070846379514569838984811187823420951275243 + +A == +446764896913554613686067036908702877942872355053329937790398156069936255759889884246832779737114032666318220500106499161852193765380831330106375235763 + +B == +5920567 + +G == 2 +---------------------------------------------------------------- + + +Took 3454 ticks, 521 bits +P == 5290203010849586596974953717018896543907195901082056939587768479377028575911127944611236020459652034082251335583308070846379514569838984811187823420951275243 +Q == 446764896913554613686067036908702877942872355053329937790398156069936255759889884246832779737114032666318220500106499161852193765380831330106375235763 diff --git a/libtommath/etc/timer.asm b/libtommath/etc/timer.asm new file mode 100644 index 0000000..35890d9 --- /dev/null +++ b/libtommath/etc/timer.asm @@ -0,0 +1,37 @@ +; x86 timer in NASM +; +; Tom St Denis, tomstdenis@iahu.ca +[bits 32] +[section .data] +time dd 0, 0 + +[section .text] + +%ifdef USE_ELF +[global t_start] +t_start: +%else +[global _t_start] +_t_start: +%endif + push edx + push eax + rdtsc + mov [time+0],edx + mov [time+4],eax + pop eax + pop edx + ret + +%ifdef USE_ELF +[global t_read] +t_read: +%else +[global _t_read] +_t_read: +%endif + rdtsc + sub eax,[time+4] + sbb edx,[time+0] + ret + \ No newline at end of file diff --git a/libtommath/etc/tune.c b/libtommath/etc/tune.c new file mode 100644 index 0000000..14aace2 --- /dev/null +++ b/libtommath/etc/tune.c @@ -0,0 +1,107 @@ +/* Tune the Karatsuba parameters + * + * Tom St Denis, tomstdenis@iahu.ca + */ +#include +#include + +/* how many times todo each size mult. Depends on your computer. For slow computers + * this can be low like 5 or 10. For fast [re: Athlon] should be 25 - 50 or so + */ +#define TIMES (1UL<<14UL) + + +#ifndef X86_TIMER + +/* generic ISO C timer */ +ulong64 LBL_T; +void t_start(void) { LBL_T = clock(); } +ulong64 t_read(void) { return clock() - LBL_T; } + +#else +extern void t_start(void); +extern ulong64 t_read(void); +#endif + +ulong64 time_mult(int size, int s) +{ + unsigned long x; + mp_int a, b, c; + ulong64 t1; + + mp_init (&a); + mp_init (&b); + mp_init (&c); + + mp_rand (&a, size); + mp_rand (&b, size); + + if (s == 1) { + KARATSUBA_MUL_CUTOFF = size; + } else { + KARATSUBA_MUL_CUTOFF = 100000; + } + + t_start(); + for (x = 0; x < TIMES; x++) { + mp_mul(&a,&b,&c); + } + t1 = t_read(); + mp_clear (&a); + mp_clear (&b); + mp_clear (&c); + return t1; +} + +ulong64 time_sqr(int size, int s) +{ + unsigned long x; + mp_int a, b; + ulong64 t1; + + mp_init (&a); + mp_init (&b); + + mp_rand (&a, size); + + if (s == 1) { + KARATSUBA_SQR_CUTOFF = size; + } else { + KARATSUBA_SQR_CUTOFF = 100000; + } + + t_start(); + for (x = 0; x < TIMES; x++) { + mp_sqr(&a,&b); + } + t1 = t_read(); + mp_clear (&a); + mp_clear (&b); + return t1; +} + +int +main (void) +{ + ulong64 t1, t2; + int x, y; + + for (x = 8; ; x += 2) { + t1 = time_mult(x, 0); + t2 = time_mult(x, 1); + printf("%d: %9llu %9llu, %9llu\n", x, t1, t2, t2 - t1); + if (t2 < t1) break; + } + y = x; + + for (x = 8; ; x += 2) { + t1 = time_sqr(x, 0); + t2 = time_sqr(x, 1); + printf("%d: %9llu %9llu, %9llu\n", x, t1, t2, t2 - t1); + if (t2 < t1) break; + } + printf("KARATSUBA_MUL_CUTOFF = %d\n", y); + printf("KARATSUBA_SQR_CUTOFF = %d\n", x); + + return 0; +} diff --git a/libtommath/gen.pl b/libtommath/gen.pl new file mode 100644 index 0000000..7236591 --- /dev/null +++ b/libtommath/gen.pl @@ -0,0 +1,17 @@ +#!/usr/bin/perl -w +# +# Generates a "single file" you can use to quickly +# add the whole source without any makefile troubles +# +use strict; + +open( OUT, ">mpi.c" ) or die "Couldn't open mpi.c for writing: $!"; +foreach my $filename (glob "bn*.c") { + open( SRC, "<$filename" ) or die "Couldn't open $filename for reading: $!"; + print OUT "/* Start: $filename */\n"; + print OUT while ; + print OUT "\n/* End: $filename */\n\n"; + close SRC or die "Error closing $filename after reading: $!"; +} +print OUT "\n/* EOF */\n"; +close OUT or die "Error closing mpi.c after writing: $!"; \ No newline at end of file diff --git a/libtommath/logs/README b/libtommath/logs/README new file mode 100644 index 0000000..ea20c81 --- /dev/null +++ b/libtommath/logs/README @@ -0,0 +1,13 @@ +To use the pretty graphs you have to first build/run the ltmtest from the root directory of the package. +Todo this type + +make timing ; ltmtest + +in the root. It will run for a while [about ten minutes on most PCs] and produce a series of .log files in logs/. + +After doing that run "gnuplot graphs.dem" to make the PNGs. If you managed todo that all so far just open index.html to view +them all :-) + +Have fun + +Tom \ No newline at end of file diff --git a/libtommath/logs/add.log b/libtommath/logs/add.log new file mode 100644 index 0000000..fa11039 --- /dev/null +++ b/libtommath/logs/add.log @@ -0,0 +1,16 @@ +480 88 +960 113 +1440 138 +1920 163 +2400 202 +2880 226 +3360 251 +3840 272 +4320 296 +4800 320 +5280 344 +5760 368 +6240 392 +6720 416 +7200 440 +7680 464 diff --git a/libtommath/logs/addsub.png b/libtommath/logs/addsub.png new file mode 100644 index 0000000..a5679ac Binary files /dev/null and b/libtommath/logs/addsub.png differ diff --git a/libtommath/logs/expt.log b/libtommath/logs/expt.log new file mode 100644 index 0000000..e65e927 --- /dev/null +++ b/libtommath/logs/expt.log @@ -0,0 +1,7 @@ +513 1499509 +769 3682671 +1025 8098887 +2049 49332743 +2561 89647783 +3073 149440713 +4097 326135364 diff --git a/libtommath/logs/expt.png b/libtommath/logs/expt.png new file mode 100644 index 0000000..9ee8bb7 Binary files /dev/null and b/libtommath/logs/expt.png differ diff --git a/libtommath/logs/expt_2k.log b/libtommath/logs/expt_2k.log new file mode 100644 index 0000000..d106280 --- /dev/null +++ b/libtommath/logs/expt_2k.log @@ -0,0 +1,6 @@ +521 1423346 +607 1841305 +1279 8375656 +2203 34104708 +3217 83830729 +4253 167916804 diff --git a/libtommath/logs/expt_2kl.log b/libtommath/logs/expt_2kl.log new file mode 100644 index 0000000..b2eb8c2 --- /dev/null +++ b/libtommath/logs/expt_2kl.log @@ -0,0 +1,4 @@ +1024 6954080 +2048 35993987 +4096 176068521 +521 1683720 diff --git a/libtommath/logs/expt_dr.log b/libtommath/logs/expt_dr.log new file mode 100644 index 0000000..6cfc874 --- /dev/null +++ b/libtommath/logs/expt_dr.log @@ -0,0 +1,7 @@ +532 1803110 +784 3607375 +1036 6089790 +1540 14739797 +2072 33251589 +3080 82794331 +4116 165212734 diff --git a/libtommath/logs/graphs.dem b/libtommath/logs/graphs.dem new file mode 100644 index 0000000..dfaf613 --- /dev/null +++ b/libtommath/logs/graphs.dem @@ -0,0 +1,17 @@ +set terminal png +set size 1.75 +set ylabel "Cycles per Operation" +set xlabel "Operand size (bits)" + +set output "addsub.png" +plot 'add.log' smooth bezier title "Addition", 'sub.log' smooth bezier title "Subtraction" + +set output "mult.png" +plot 'sqr.log' smooth bezier title "Squaring (without Karatsuba)", 'sqr_kara.log' smooth bezier title "Squaring (Karatsuba)", 'mult.log' smooth bezier title "Multiplication (without Karatsuba)", 'mult_kara.log' smooth bezier title "Multiplication (Karatsuba)" + +set output "expt.png" +plot 'expt.log' smooth bezier title "Exptmod (Montgomery)", 'expt_dr.log' smooth bezier title "Exptmod (Dimminished Radix)", 'expt_2k.log' smooth bezier title "Exptmod (2k Reduction)" + +set output "invmod.png" +plot 'invmod.log' smooth bezier title "Modular Inverse" + diff --git a/libtommath/logs/index.html b/libtommath/logs/index.html new file mode 100644 index 0000000..19fe403 --- /dev/null +++ b/libtommath/logs/index.html @@ -0,0 +1,24 @@ + + +LibTomMath Log Plots + + + +

Addition and Subtraction

+
+
+ +

Multipliers

+
+
+ +

Exptmod

+
+
+ +

Modular Inverse

+
+
+ + + \ No newline at end of file diff --git a/libtommath/logs/invmod.log b/libtommath/logs/invmod.log new file mode 100644 index 0000000..e69de29 diff --git a/libtommath/logs/invmod.png b/libtommath/logs/invmod.png new file mode 100644 index 0000000..0a8a4ad Binary files /dev/null and b/libtommath/logs/invmod.png differ diff --git a/libtommath/logs/mult.log b/libtommath/logs/mult.log new file mode 100644 index 0000000..864de46 --- /dev/null +++ b/libtommath/logs/mult.log @@ -0,0 +1,143 @@ +271 580 +390 861 +511 1177 +630 1598 +749 2115 +871 2670 +991 3276 +1111 3987 +1231 4722 +1351 5474 +1471 6281 +1589 7126 +1710 8114 +1831 8988 +1946 10038 +2071 10995 +2188 12286 +2310 13152 +2430 14480 +2549 15521 +2671 17171 +2790 18081 +2911 19754 +3031 20809 +3150 22849 +3269 23757 +3391 25772 +3508 26832 +3631 29304 +3750 30149 +3865 32581 +3988 33644 +4111 36565 +4231 37309 +4351 40152 +4471 41188 +4590 44658 +4710 45256 +4827 48538 +4951 49490 +5070 53472 +5190 53902 +5308 57619 +5431 58509 +5550 63044 +5664 63333 +5791 67542 +5911 68279 +6028 73477 +6150 73475 +6271 78189 +6390 78842 +6510 84691 +6631 84444 +6751 89721 +6871 90186 +6991 96665 +7111 96119 +7231 101937 +7350 102212 +7471 109439 +7591 108491 +7709 114965 +7829 115025 +7951 123002 +8071 121630 +8190 128725 +8311 128536 +8430 137298 +8550 135568 +8671 143265 +8791 142793 +8911 152432 +9030 150202 +9151 158616 +9271 157848 +9391 168374 +9511 165651 +9627 174775 +9750 173375 +9871 185067 +9985 181845 +10111 191708 +10229 190239 +10351 202585 +10467 198704 +10591 209193 +10711 207322 +10831 220842 +10950 215882 +11071 227761 +11191 225501 +11311 239669 +11430 234809 +11550 243511 +11671 255947 +11791 255243 +11906 267828 +12029 263437 +12149 276571 +12270 275579 +12390 288963 +12510 284001 +12631 298196 +12751 297018 +12869 310848 +12990 305369 +13111 319086 +13230 318940 +13349 333685 +13471 327495 +13588 343678 +13711 341817 +13831 357181 +13948 350440 +14071 367526 +14189 365330 +14311 381551 +14429 374149 +14549 392203 +14670 389764 +14791 406761 +14910 398652 +15026 417718 +15150 414733 +15269 432759 +15390 1037071 +15511 1053454 +15631 1069198 +15748 1086164 +15871 1112820 +15991 1129676 +16111 1145924 +16230 1163016 +16345 1179911 +16471 1197048 +16586 1214352 +16711 1232095 +16829 1249338 +16947 1266987 +17071 1284181 +17188 1302521 +17311 1320539 diff --git a/libtommath/logs/mult.png b/libtommath/logs/mult.png new file mode 100644 index 0000000..4f7a4ee Binary files /dev/null and b/libtommath/logs/mult.png differ diff --git a/libtommath/logs/mult_kara.log b/libtommath/logs/mult_kara.log new file mode 100644 index 0000000..086feaf --- /dev/null +++ b/libtommath/logs/mult_kara.log @@ -0,0 +1,33 @@ +924 16686 +1146 25334 +1371 35304 +1591 47122 +1820 61500 +2044 75254 +2266 91732 +2492 111656 +2716 129428 +2937 147508 +3164 167758 +3388 188248 +3612 210826 +3836 233814 +4059 256898 +4284 280210 +4508 310372 +4731 333902 +4955 376502 +5179 402854 +5404 432004 +5626 459010 +5849 491868 +6076 520550 +6300 547400 +6524 575968 +6747 608482 +6971 642850 +7196 673670 +7419 710680 +7644 743942 +7868 780394 +8092 817342 diff --git a/libtommath/logs/sqr.log b/libtommath/logs/sqr.log new file mode 100644 index 0000000..0898342 --- /dev/null +++ b/libtommath/logs/sqr.log @@ -0,0 +1,143 @@ +271 552 +389 883 +510 1191 +629 1572 +750 1996 +863 2428 +991 2891 +1108 3539 +1231 4182 +1351 4980 +1471 5771 +1590 6551 +1711 7313 +1830 8240 +1951 9184 +2070 10087 +2191 11140 +2311 12111 +2431 13219 +2550 14247 +2669 15353 +2791 16446 +2911 17692 +3029 18848 +3151 20028 +3268 21282 +3391 22696 +3511 23971 +3631 25303 +3751 26675 +3871 28245 +3990 29736 +4111 31124 +4229 32714 +4347 34397 +4471 35877 +4587 37269 +4710 39011 +4831 40884 +4950 42501 +5070 44005 +5191 46026 +5310 48168 +5431 49801 +5551 51385 +5671 53604 +5787 55942 +5910 57757 +6031 59391 +6151 61754 +6271 64234 +6390 66110 +6511 67845 +6627 70474 +6751 73113 +6871 75064 +6990 76940 +7111 79681 +7230 82548 +7351 84597 +7471 86507 +7591 89497 +7711 225216 +7831 232192 +7951 239583 +8071 247302 +8191 255497 +8308 261587 +8431 271490 +8550 279492 +8671 286927 +8790 294680 +8910 302974 +9030 311300 +9150 318635 +9271 326740 +9390 335304 +9511 344297 +9630 352056 +9748 358652 +9870 369723 +9991 379119 +10111 386982 +10231 396075 +10349 404396 +10470 415375 +10590 424146 +10711 433390 +10829 442662 +10950 453238 +11071 462178 +11186 469811 +11311 482529 +11431 493214 +11550 503210 +11671 513486 +11791 524244 +11911 535277 +12031 544872 +12151 555695 +12271 566893 +12391 578385 +12510 588658 +12628 596914 +12751 611324 +12871 623437 +12991 633907 +13110 645605 +13231 657684 +13351 670037 +13471 680939 +13591 693047 +13710 705363 +13829 718178 +13949 727930 +14069 739641 +14190 754817 +14310 768192 +14431 779875 +14551 792655 +14667 802847 +14791 819806 +14911 831684 +15031 844936 +15151 858813 +15270 873037 +15387 882123 +15510 899117 +15631 913465 +15750 927989 +15870 940790 +15991 954948 +16110 969483 +16231 984544 +16350 997837 +16470 1012445 +16590 1027834 +16710 1043032 +16831 1056394 +16951 1071408 +17069 1097263 +17191 1113364 +17306 1123650 diff --git a/libtommath/logs/sqr_kara.log b/libtommath/logs/sqr_kara.log new file mode 100644 index 0000000..cafe458 --- /dev/null +++ b/libtommath/logs/sqr_kara.log @@ -0,0 +1,33 @@ +922 11272 +1148 16004 +1370 21958 +1596 28684 +1817 37832 +2044 46386 +2262 56218 +2492 66388 +2716 77478 +2940 89380 +3163 103680 +3385 116274 +3612 135334 +3836 151332 +4057 164938 +4284 183178 +4508 198864 +4731 215222 +4954 231986 +5180 251660 +5404 269414 +5626 288454 +5850 307806 +6076 329458 +6299 347726 +6523 369864 +6748 387832 +6971 413010 +7194 453310 +7415 476936 +7643 497118 +7867 521394 +8091 540224 diff --git a/libtommath/logs/sub.log b/libtommath/logs/sub.log new file mode 100644 index 0000000..a42d91e --- /dev/null +++ b/libtommath/logs/sub.log @@ -0,0 +1,16 @@ +480 87 +960 114 +1440 139 +1920 159 +2400 204 +2880 228 +3360 250 +3840 273 +4320 300 +4800 321 +5280 348 +5760 370 +6240 393 +6720 420 +7200 444 +7680 466 diff --git a/libtommath/makefile b/libtommath/makefile new file mode 100644 index 0000000..164a0ab --- /dev/null +++ b/libtommath/makefile @@ -0,0 +1,157 @@ +#Makefile for GCC +# +#Tom St Denis + +#version of library +VERSION=0.33 + +CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare + +#for speed +CFLAGS += -O3 -funroll-all-loops + +#for size +#CFLAGS += -Os + +#x86 optimizations [should be valid for any GCC install though] +CFLAGS += -fomit-frame-pointer + +#debug +#CFLAGS += -g3 + +#install as this user +USER=root +GROUP=root + +default: libtommath.a + +#default files to install +LIBNAME=libtommath.a +HEADERS=tommath.h tommath_class.h tommath_superclass.h + +#LIBPATH-The directory for libtommath to be installed to. +#INCPATH-The directory to install the header files for libtommath. +#DATAPATH-The directory to install the pdf docs. +DESTDIR= +LIBPATH=/usr/lib +INCPATH=/usr/include +DATAPATH=/usr/share/doc/libtommath/pdf + +OBJECTS=bncore.o bn_mp_init.o bn_mp_clear.o bn_mp_exch.o bn_mp_grow.o bn_mp_shrink.o \ +bn_mp_clamp.o bn_mp_zero.o bn_mp_set.o bn_mp_set_int.o bn_mp_init_size.o bn_mp_copy.o \ +bn_mp_init_copy.o bn_mp_abs.o bn_mp_neg.o bn_mp_cmp_mag.o bn_mp_cmp.o bn_mp_cmp_d.o \ +bn_mp_rshd.o bn_mp_lshd.o bn_mp_mod_2d.o bn_mp_div_2d.o bn_mp_mul_2d.o bn_mp_div_2.o \ +bn_mp_mul_2.o bn_s_mp_add.o bn_s_mp_sub.o bn_fast_s_mp_mul_digs.o bn_s_mp_mul_digs.o \ +bn_fast_s_mp_mul_high_digs.o bn_s_mp_mul_high_digs.o bn_fast_s_mp_sqr.o bn_s_mp_sqr.o \ +bn_mp_add.o bn_mp_sub.o bn_mp_karatsuba_mul.o bn_mp_mul.o bn_mp_karatsuba_sqr.o \ +bn_mp_sqr.o bn_mp_div.o bn_mp_mod.o bn_mp_add_d.o bn_mp_sub_d.o bn_mp_mul_d.o \ +bn_mp_div_d.o bn_mp_mod_d.o bn_mp_expt_d.o bn_mp_addmod.o bn_mp_submod.o \ +bn_mp_mulmod.o bn_mp_sqrmod.o bn_mp_gcd.o bn_mp_lcm.o bn_fast_mp_invmod.o bn_mp_invmod.o \ +bn_mp_reduce.o bn_mp_montgomery_setup.o bn_fast_mp_montgomery_reduce.o bn_mp_montgomery_reduce.o \ +bn_mp_exptmod_fast.o bn_mp_exptmod.o bn_mp_2expt.o bn_mp_n_root.o bn_mp_jacobi.o bn_reverse.o \ +bn_mp_count_bits.o bn_mp_read_unsigned_bin.o bn_mp_read_signed_bin.o bn_mp_to_unsigned_bin.o \ +bn_mp_to_signed_bin.o bn_mp_unsigned_bin_size.o bn_mp_signed_bin_size.o \ +bn_mp_xor.o bn_mp_and.o bn_mp_or.o bn_mp_rand.o bn_mp_montgomery_calc_normalization.o \ +bn_mp_prime_is_divisible.o bn_prime_tab.o bn_mp_prime_fermat.o bn_mp_prime_miller_rabin.o \ +bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ +bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ +bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ +bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ +bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ +bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ +bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o + +libtommath.a: $(OBJECTS) + $(AR) $(ARFLAGS) libtommath.a $(OBJECTS) + ranlib libtommath.a + +#make a profiled library (takes a while!!!) +# +# This will build the library with profile generation +# then run the test demo and rebuild the library. +# +# So far I've seen improvements in the MP math +profiled: + make CFLAGS="$(CFLAGS) -fprofile-arcs -DTESTING" timing + ./ltmtest + rm -f *.a *.o ltmtest + make CFLAGS="$(CFLAGS) -fbranch-probabilities" + +#make a single object profiled library +profiled_single: + perl gen.pl + $(CC) $(CFLAGS) -fprofile-arcs -DTESTING -c mpi.c -o mpi.o + $(CC) $(CFLAGS) -DTESTING -DTIMER demo/timing.c mpi.o -o ltmtest + ./ltmtest + rm -f *.o ltmtest + $(CC) $(CFLAGS) -fbranch-probabilities -DTESTING -c mpi.c -o mpi.o + $(AR) $(ARFLAGS) libtommath.a mpi.o + ranlib libtommath.a + +install: libtommath.a + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(LIBPATH) + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) + install -g $(GROUP) -o $(USER) $(LIBNAME) $(DESTDIR)$(LIBPATH) + install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) + +test: libtommath.a demo/demo.o + $(CC) $(CFLAGS) demo/demo.o libtommath.a -o test + +mtest: test + cd mtest ; $(CC) $(CFLAGS) mtest.c -o mtest + +timing: libtommath.a + $(CC) $(CFLAGS) -DTIMER demo/timing.c libtommath.a -o ltmtest + +# makes the LTM book DVI file, requires tetex, perl and makeindex [part of tetex I think] +docdvi: tommath.src + cd pics ; make + echo "hello" > tommath.ind + perl booker.pl + latex tommath > /dev/null + latex tommath > /dev/null + makeindex tommath + latex tommath > /dev/null + +# poster, makes the single page PDF poster +poster: poster.tex + pdflatex poster + rm -f poster.aux poster.log + +# makes the LTM book PDF file, requires tetex, cleans up the LaTeX temp files +docs: docdvi + dvipdf tommath + rm -f tommath.log tommath.aux tommath.dvi tommath.idx tommath.toc tommath.lof tommath.ind tommath.ilg + cd pics ; make clean + +#LTM user manual +mandvi: bn.tex + echo "hello" > bn.ind + latex bn > /dev/null + latex bn > /dev/null + makeindex bn + latex bn > /dev/null + +#LTM user manual [pdf] +manual: mandvi + pdflatex bn >/dev/null + rm -f bn.aux bn.dvi bn.log bn.idx bn.lof bn.out bn.toc + +pretty: + perl pretty.build + +clean: + rm -f *.bat *.pdf *.o *.a *.obj *.lib *.exe *.dll etclib/*.o demo/demo.o test ltmtest mpitest mtest/mtest mtest/mtest.exe \ + *.idx *.toc *.log *.aux *.dvi *.lof *.ind *.ilg *.ps *.log *.s mpi.c *.da *.dyn *.dpi tommath.tex `find -type f | grep [~] | xargs` *.lo *.la + rm -rf .libs + cd etc ; make clean + cd pics ; make clean + +zipup: clean manual poster docs + perl gen.pl ; mv mpi.c pre_gen/ ; \ + cd .. ; rm -rf ltm* libtommath-$(VERSION) ; mkdir libtommath-$(VERSION) ; \ + cp -R ./libtommath/* ./libtommath-$(VERSION)/ ; \ + tar -c libtommath-$(VERSION)/* | bzip2 -9vvc > ltm-$(VERSION).tar.bz2 ; \ + zip -9 -r ltm-$(VERSION).zip libtommath-$(VERSION)/* diff --git a/libtommath/makefile.bcc b/libtommath/makefile.bcc new file mode 100644 index 0000000..775e9ff --- /dev/null +++ b/libtommath/makefile.bcc @@ -0,0 +1,42 @@ +# +# Borland C++Builder Makefile (makefile.bcc) +# + + +LIB = tlib +CC = bcc32 +CFLAGS = -c -O2 -I. + +OBJECTS=bncore.obj bn_mp_init.obj bn_mp_clear.obj bn_mp_exch.obj bn_mp_grow.obj bn_mp_shrink.obj \ +bn_mp_clamp.obj bn_mp_zero.obj bn_mp_set.obj bn_mp_set_int.obj bn_mp_init_size.obj bn_mp_copy.obj \ +bn_mp_init_copy.obj bn_mp_abs.obj bn_mp_neg.obj bn_mp_cmp_mag.obj bn_mp_cmp.obj bn_mp_cmp_d.obj \ +bn_mp_rshd.obj bn_mp_lshd.obj bn_mp_mod_2d.obj bn_mp_div_2d.obj bn_mp_mul_2d.obj bn_mp_div_2.obj \ +bn_mp_mul_2.obj bn_s_mp_add.obj bn_s_mp_sub.obj bn_fast_s_mp_mul_digs.obj bn_s_mp_mul_digs.obj \ +bn_fast_s_mp_mul_high_digs.obj bn_s_mp_mul_high_digs.obj bn_fast_s_mp_sqr.obj bn_s_mp_sqr.obj \ +bn_mp_add.obj bn_mp_sub.obj bn_mp_karatsuba_mul.obj bn_mp_mul.obj bn_mp_karatsuba_sqr.obj \ +bn_mp_sqr.obj bn_mp_div.obj bn_mp_mod.obj bn_mp_add_d.obj bn_mp_sub_d.obj bn_mp_mul_d.obj \ +bn_mp_div_d.obj bn_mp_mod_d.obj bn_mp_expt_d.obj bn_mp_addmod.obj bn_mp_submod.obj \ +bn_mp_mulmod.obj bn_mp_sqrmod.obj bn_mp_gcd.obj bn_mp_lcm.obj bn_fast_mp_invmod.obj bn_mp_invmod.obj \ +bn_mp_reduce.obj bn_mp_montgomery_setup.obj bn_fast_mp_montgomery_reduce.obj bn_mp_montgomery_reduce.obj \ +bn_mp_exptmod_fast.obj bn_mp_exptmod.obj bn_mp_2expt.obj bn_mp_n_root.obj bn_mp_jacobi.obj bn_reverse.obj \ +bn_mp_count_bits.obj bn_mp_read_unsigned_bin.obj bn_mp_read_signed_bin.obj bn_mp_to_unsigned_bin.obj \ +bn_mp_to_signed_bin.obj bn_mp_unsigned_bin_size.obj bn_mp_signed_bin_size.obj \ +bn_mp_xor.obj bn_mp_and.obj bn_mp_or.obj bn_mp_rand.obj bn_mp_montgomery_calc_normalization.obj \ +bn_mp_prime_is_divisible.obj bn_prime_tab.obj bn_mp_prime_fermat.obj bn_mp_prime_miller_rabin.obj \ +bn_mp_prime_is_prime.obj bn_mp_prime_next_prime.obj bn_mp_dr_reduce.obj \ +bn_mp_dr_is_modulus.obj bn_mp_dr_setup.obj bn_mp_reduce_setup.obj \ +bn_mp_toom_mul.obj bn_mp_toom_sqr.obj bn_mp_div_3.obj bn_s_mp_exptmod.obj \ +bn_mp_reduce_2k.obj bn_mp_reduce_is_2k.obj bn_mp_reduce_2k_setup.obj \ +bn_mp_radix_smap.obj bn_mp_read_radix.obj bn_mp_toradix.obj bn_mp_radix_size.obj \ +bn_mp_fread.obj bn_mp_fwrite.obj bn_mp_cnt_lsb.obj bn_error.obj \ +bn_mp_init_multi.obj bn_mp_clear_multi.obj bn_mp_exteuclid.obj bn_mp_toradix_n.obj \ +bn_mp_prime_random_ex.obj bn_mp_get_int.obj bn_mp_sqrt.obj bn_mp_is_square.obj \ +bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj + +TARGET = libtommath.lib + +$(TARGET): $(OBJECTS) + +.c.objbjbjbj: + $(CC) $(CFLAGS) $< + $(LIB) $(TARGET) -+$@ diff --git a/libtommath/makefile.cygwin_dll b/libtommath/makefile.cygwin_dll new file mode 100644 index 0000000..c90e5d9 --- /dev/null +++ b/libtommath/makefile.cygwin_dll @@ -0,0 +1,49 @@ +#Makefile for Cygwin-GCC +# +#This makefile will build a Windows DLL [doesn't require cygwin to run] in the file +#libtommath.dll. The import library is in libtommath.dll.a. Remember to add +#"-Wl,--enable-auto-import" to your client build to avoid the auto-import warnings +# +#Tom St Denis +CFLAGS += -I./ -Wall -W -Wshadow -O3 -funroll-loops -mno-cygwin + +#x86 optimizations [should be valid for any GCC install though] +CFLAGS += -fomit-frame-pointer + +default: windll + +OBJECTS=bncore.o bn_mp_init.o bn_mp_clear.o bn_mp_exch.o bn_mp_grow.o bn_mp_shrink.o \ +bn_mp_clamp.o bn_mp_zero.o bn_mp_set.o bn_mp_set_int.o bn_mp_init_size.o bn_mp_copy.o \ +bn_mp_init_copy.o bn_mp_abs.o bn_mp_neg.o bn_mp_cmp_mag.o bn_mp_cmp.o bn_mp_cmp_d.o \ +bn_mp_rshd.o bn_mp_lshd.o bn_mp_mod_2d.o bn_mp_div_2d.o bn_mp_mul_2d.o bn_mp_div_2.o \ +bn_mp_mul_2.o bn_s_mp_add.o bn_s_mp_sub.o bn_fast_s_mp_mul_digs.o bn_s_mp_mul_digs.o \ +bn_fast_s_mp_mul_high_digs.o bn_s_mp_mul_high_digs.o bn_fast_s_mp_sqr.o bn_s_mp_sqr.o \ +bn_mp_add.o bn_mp_sub.o bn_mp_karatsuba_mul.o bn_mp_mul.o bn_mp_karatsuba_sqr.o \ +bn_mp_sqr.o bn_mp_div.o bn_mp_mod.o bn_mp_add_d.o bn_mp_sub_d.o bn_mp_mul_d.o \ +bn_mp_div_d.o bn_mp_mod_d.o bn_mp_expt_d.o bn_mp_addmod.o bn_mp_submod.o \ +bn_mp_mulmod.o bn_mp_sqrmod.o bn_mp_gcd.o bn_mp_lcm.o bn_fast_mp_invmod.o bn_mp_invmod.o \ +bn_mp_reduce.o bn_mp_montgomery_setup.o bn_fast_mp_montgomery_reduce.o bn_mp_montgomery_reduce.o \ +bn_mp_exptmod_fast.o bn_mp_exptmod.o bn_mp_2expt.o bn_mp_n_root.o bn_mp_jacobi.o bn_reverse.o \ +bn_mp_count_bits.o bn_mp_read_unsigned_bin.o bn_mp_read_signed_bin.o bn_mp_to_unsigned_bin.o \ +bn_mp_to_signed_bin.o bn_mp_unsigned_bin_size.o bn_mp_signed_bin_size.o \ +bn_mp_xor.o bn_mp_and.o bn_mp_or.o bn_mp_rand.o bn_mp_montgomery_calc_normalization.o \ +bn_mp_prime_is_divisible.o bn_prime_tab.o bn_mp_prime_fermat.o bn_mp_prime_miller_rabin.o \ +bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ +bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ +bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ +bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ +bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ +bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ +bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o + +# make a Windows DLL via Cygwin +windll: $(OBJECTS) + gcc -mno-cygwin -mdll -o libtommath.dll -Wl,--out-implib=libtommath.dll.a -Wl,--export-all-symbols *.o + ranlib libtommath.dll.a + +# build the test program using the windows DLL +test: $(OBJECTS) windll + gcc $(CFLAGS) demo/demo.c libtommath.dll.a -Wl,--enable-auto-import -o test -s + cd mtest ; $(CC) -O3 -fomit-frame-pointer -funroll-loops mtest.c -o mtest -s diff --git a/libtommath/makefile.icc b/libtommath/makefile.icc new file mode 100644 index 0000000..3775b20 --- /dev/null +++ b/libtommath/makefile.icc @@ -0,0 +1,114 @@ +#Makefile for ICC +# +#Tom St Denis +CC=icc + +CFLAGS += -I./ + +# optimize for SPEED +# +# -mcpu= can be pentium, pentiumpro (covers PII through PIII) or pentium4 +# -ax? specifies make code specifically for ? but compatible with IA-32 +# -x? specifies compile solely for ? [not specifically IA-32 compatible] +# +# where ? is +# K - PIII +# W - first P4 [Williamette] +# N - P4 Northwood +# P - P4 Prescott +# B - Blend of P4 and PM [mobile] +# +# Default to just generic max opts +CFLAGS += -O3 -xN + +#install as this user +USER=root +GROUP=root + +default: libtommath.a + +#default files to install +LIBNAME=libtommath.a +HEADERS=tommath.h + +#LIBPATH-The directory for libtomcrypt to be installed to. +#INCPATH-The directory to install the header files for libtommath. +#DATAPATH-The directory to install the pdf docs. +DESTDIR= +LIBPATH=/usr/lib +INCPATH=/usr/include +DATAPATH=/usr/share/doc/libtommath/pdf + +OBJECTS=bncore.o bn_mp_init.o bn_mp_clear.o bn_mp_exch.o bn_mp_grow.o bn_mp_shrink.o \ +bn_mp_clamp.o bn_mp_zero.o bn_mp_set.o bn_mp_set_int.o bn_mp_init_size.o bn_mp_copy.o \ +bn_mp_init_copy.o bn_mp_abs.o bn_mp_neg.o bn_mp_cmp_mag.o bn_mp_cmp.o bn_mp_cmp_d.o \ +bn_mp_rshd.o bn_mp_lshd.o bn_mp_mod_2d.o bn_mp_div_2d.o bn_mp_mul_2d.o bn_mp_div_2.o \ +bn_mp_mul_2.o bn_s_mp_add.o bn_s_mp_sub.o bn_fast_s_mp_mul_digs.o bn_s_mp_mul_digs.o \ +bn_fast_s_mp_mul_high_digs.o bn_s_mp_mul_high_digs.o bn_fast_s_mp_sqr.o bn_s_mp_sqr.o \ +bn_mp_add.o bn_mp_sub.o bn_mp_karatsuba_mul.o bn_mp_mul.o bn_mp_karatsuba_sqr.o \ +bn_mp_sqr.o bn_mp_div.o bn_mp_mod.o bn_mp_add_d.o bn_mp_sub_d.o bn_mp_mul_d.o \ +bn_mp_div_d.o bn_mp_mod_d.o bn_mp_expt_d.o bn_mp_addmod.o bn_mp_submod.o \ +bn_mp_mulmod.o bn_mp_sqrmod.o bn_mp_gcd.o bn_mp_lcm.o bn_fast_mp_invmod.o bn_mp_invmod.o \ +bn_mp_reduce.o bn_mp_montgomery_setup.o bn_fast_mp_montgomery_reduce.o bn_mp_montgomery_reduce.o \ +bn_mp_exptmod_fast.o bn_mp_exptmod.o bn_mp_2expt.o bn_mp_n_root.o bn_mp_jacobi.o bn_reverse.o \ +bn_mp_count_bits.o bn_mp_read_unsigned_bin.o bn_mp_read_signed_bin.o bn_mp_to_unsigned_bin.o \ +bn_mp_to_signed_bin.o bn_mp_unsigned_bin_size.o bn_mp_signed_bin_size.o \ +bn_mp_xor.o bn_mp_and.o bn_mp_or.o bn_mp_rand.o bn_mp_montgomery_calc_normalization.o \ +bn_mp_prime_is_divisible.o bn_prime_tab.o bn_mp_prime_fermat.o bn_mp_prime_miller_rabin.o \ +bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ +bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ +bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ +bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ +bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ +bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ +bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o + +libtommath.a: $(OBJECTS) + $(AR) $(ARFLAGS) libtommath.a $(OBJECTS) + ranlib libtommath.a + +#make a profiled library (takes a while!!!) +# +# This will build the library with profile generation +# then run the test demo and rebuild the library. +# +# So far I've seen improvements in the MP math +profiled: + make -f makefile.icc CFLAGS="$(CFLAGS) -prof_gen -DTESTING" timing + ./ltmtest + rm -f *.a *.o ltmtest + make -f makefile.icc CFLAGS="$(CFLAGS) -prof_use" + +#make a single object profiled library +profiled_single: + perl gen.pl + $(CC) $(CFLAGS) -prof_gen -DTESTING -c mpi.c -o mpi.o + $(CC) $(CFLAGS) -DTESTING -DTIMER demo/demo.c mpi.o -o ltmtest + ./ltmtest + rm -f *.o ltmtest + $(CC) $(CFLAGS) -prof_use -ip -DTESTING -c mpi.c -o mpi.o + $(AR) $(ARFLAGS) libtommath.a mpi.o + ranlib libtommath.a + +install: libtommath.a + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(LIBPATH) + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) + install -g $(GROUP) -o $(USER) $(LIBNAME) $(DESTDIR)$(LIBPATH) + install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) + +test: libtommath.a demo/demo.o + $(CC) demo/demo.o libtommath.a -o test + +mtest: test + cd mtest ; $(CC) $(CFLAGS) mtest.c -o mtest + +timing: libtommath.a + $(CC) $(CFLAGS) -DTIMER demo/timing.c libtommath.a -o ltmtest + +clean: + rm -f *.bat *.pdf *.o *.a *.obj *.lib *.exe *.dll etclib/*.o demo/demo.o test ltmtest mpitest mtest/mtest mtest/mtest.exe \ + *.idx *.toc *.log *.aux *.dvi *.lof *.ind *.ilg *.ps *.log *.s mpi.c *.il etc/*.il *.dyn + cd etc ; make clean + cd pics ; make clean diff --git a/libtommath/makefile.msvc b/libtommath/makefile.msvc new file mode 100644 index 0000000..cf59943 --- /dev/null +++ b/libtommath/makefile.msvc @@ -0,0 +1,36 @@ +#MSVC Makefile +# +#Tom St Denis + +CFLAGS = /I. /Ox /DWIN32 /W4 + +default: library + +OBJECTS=bncore.obj bn_mp_init.obj bn_mp_clear.obj bn_mp_exch.obj bn_mp_grow.obj bn_mp_shrink.obj \ +bn_mp_clamp.obj bn_mp_zero.obj bn_mp_set.obj bn_mp_set_int.obj bn_mp_init_size.obj bn_mp_copy.obj \ +bn_mp_init_copy.obj bn_mp_abs.obj bn_mp_neg.obj bn_mp_cmp_mag.obj bn_mp_cmp.obj bn_mp_cmp_d.obj \ +bn_mp_rshd.obj bn_mp_lshd.obj bn_mp_mod_2d.obj bn_mp_div_2d.obj bn_mp_mul_2d.obj bn_mp_div_2.obj \ +bn_mp_mul_2.obj bn_s_mp_add.obj bn_s_mp_sub.obj bn_fast_s_mp_mul_digs.obj bn_s_mp_mul_digs.obj \ +bn_fast_s_mp_mul_high_digs.obj bn_s_mp_mul_high_digs.obj bn_fast_s_mp_sqr.obj bn_s_mp_sqr.obj \ +bn_mp_add.obj bn_mp_sub.obj bn_mp_karatsuba_mul.obj bn_mp_mul.obj bn_mp_karatsuba_sqr.obj \ +bn_mp_sqr.obj bn_mp_div.obj bn_mp_mod.obj bn_mp_add_d.obj bn_mp_sub_d.obj bn_mp_mul_d.obj \ +bn_mp_div_d.obj bn_mp_mod_d.obj bn_mp_expt_d.obj bn_mp_addmod.obj bn_mp_submod.obj \ +bn_mp_mulmod.obj bn_mp_sqrmod.obj bn_mp_gcd.obj bn_mp_lcm.obj bn_fast_mp_invmod.obj bn_mp_invmod.obj \ +bn_mp_reduce.obj bn_mp_montgomery_setup.obj bn_fast_mp_montgomery_reduce.obj bn_mp_montgomery_reduce.obj \ +bn_mp_exptmod_fast.obj bn_mp_exptmod.obj bn_mp_2expt.obj bn_mp_n_root.obj bn_mp_jacobi.obj bn_reverse.obj \ +bn_mp_count_bits.obj bn_mp_read_unsigned_bin.obj bn_mp_read_signed_bin.obj bn_mp_to_unsigned_bin.obj \ +bn_mp_to_signed_bin.obj bn_mp_unsigned_bin_size.obj bn_mp_signed_bin_size.obj \ +bn_mp_xor.obj bn_mp_and.obj bn_mp_or.obj bn_mp_rand.obj bn_mp_montgomery_calc_normalization.obj \ +bn_mp_prime_is_divisible.obj bn_prime_tab.obj bn_mp_prime_fermat.obj bn_mp_prime_miller_rabin.obj \ +bn_mp_prime_is_prime.obj bn_mp_prime_next_prime.obj bn_mp_dr_reduce.obj \ +bn_mp_dr_is_modulus.obj bn_mp_dr_setup.obj bn_mp_reduce_setup.obj \ +bn_mp_toom_mul.obj bn_mp_toom_sqr.obj bn_mp_div_3.obj bn_s_mp_exptmod.obj \ +bn_mp_reduce_2k.obj bn_mp_reduce_is_2k.obj bn_mp_reduce_2k_setup.obj \ +bn_mp_radix_smap.obj bn_mp_read_radix.obj bn_mp_toradix.obj bn_mp_radix_size.obj \ +bn_mp_fread.obj bn_mp_fwrite.obj bn_mp_cnt_lsb.obj bn_error.obj \ +bn_mp_init_multi.obj bn_mp_clear_multi.obj bn_mp_exteuclid.obj bn_mp_toradix_n.obj \ +bn_mp_prime_random_ex.obj bn_mp_get_int.obj bn_mp_sqrt.obj bn_mp_is_square.obj \ +bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj + +library: $(OBJECTS) + lib /out:tommath.lib $(OBJECTS) diff --git a/libtommath/makefile.shared b/libtommath/makefile.shared new file mode 100644 index 0000000..86a3786 --- /dev/null +++ b/libtommath/makefile.shared @@ -0,0 +1,77 @@ +#Makefile for GCC +# +#Tom St Denis +VERSION=0:33 + +CC = libtool --mode=compile gcc +CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare + +#for speed +CFLAGS += -O3 -funroll-loops + +#for size +#CFLAGS += -Os + +#x86 optimizations [should be valid for any GCC install though] +CFLAGS += -fomit-frame-pointer + +#install as this user +USER=root +GROUP=root + +default: libtommath.la + +#default files to install +LIBNAME=libtommath.la +HEADERS=tommath.h tommath_class.h tommath_superclass.h + +#LIBPATH-The directory for libtommath to be installed to. +#INCPATH-The directory to install the header files for libtommath. +#DATAPATH-The directory to install the pdf docs. +DESTDIR= +LIBPATH=/usr/lib +INCPATH=/usr/include +DATAPATH=/usr/share/doc/libtommath/pdf + +OBJECTS=bncore.o bn_mp_init.o bn_mp_clear.o bn_mp_exch.o bn_mp_grow.o bn_mp_shrink.o \ +bn_mp_clamp.o bn_mp_zero.o bn_mp_set.o bn_mp_set_int.o bn_mp_init_size.o bn_mp_copy.o \ +bn_mp_init_copy.o bn_mp_abs.o bn_mp_neg.o bn_mp_cmp_mag.o bn_mp_cmp.o bn_mp_cmp_d.o \ +bn_mp_rshd.o bn_mp_lshd.o bn_mp_mod_2d.o bn_mp_div_2d.o bn_mp_mul_2d.o bn_mp_div_2.o \ +bn_mp_mul_2.o bn_s_mp_add.o bn_s_mp_sub.o bn_fast_s_mp_mul_digs.o bn_s_mp_mul_digs.o \ +bn_fast_s_mp_mul_high_digs.o bn_s_mp_mul_high_digs.o bn_fast_s_mp_sqr.o bn_s_mp_sqr.o \ +bn_mp_add.o bn_mp_sub.o bn_mp_karatsuba_mul.o bn_mp_mul.o bn_mp_karatsuba_sqr.o \ +bn_mp_sqr.o bn_mp_div.o bn_mp_mod.o bn_mp_add_d.o bn_mp_sub_d.o bn_mp_mul_d.o \ +bn_mp_div_d.o bn_mp_mod_d.o bn_mp_expt_d.o bn_mp_addmod.o bn_mp_submod.o \ +bn_mp_mulmod.o bn_mp_sqrmod.o bn_mp_gcd.o bn_mp_lcm.o bn_fast_mp_invmod.o bn_mp_invmod.o \ +bn_mp_reduce.o bn_mp_montgomery_setup.o bn_fast_mp_montgomery_reduce.o bn_mp_montgomery_reduce.o \ +bn_mp_exptmod_fast.o bn_mp_exptmod.o bn_mp_2expt.o bn_mp_n_root.o bn_mp_jacobi.o bn_reverse.o \ +bn_mp_count_bits.o bn_mp_read_unsigned_bin.o bn_mp_read_signed_bin.o bn_mp_to_unsigned_bin.o \ +bn_mp_to_signed_bin.o bn_mp_unsigned_bin_size.o bn_mp_signed_bin_size.o \ +bn_mp_xor.o bn_mp_and.o bn_mp_or.o bn_mp_rand.o bn_mp_montgomery_calc_normalization.o \ +bn_mp_prime_is_divisible.o bn_prime_tab.o bn_mp_prime_fermat.o bn_mp_prime_miller_rabin.o \ +bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ +bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ +bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ +bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ +bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ +bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ +bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o + +libtommath.la: $(OBJECTS) + libtool --mode=link gcc *.lo -o libtommath.la -rpath $(LIBPATH) -version-info $(VERSION) + libtool --mode=link gcc *.o -o libtommath.a + libtool --mode=install install -c libtommath.la $(LIBPATH)/libtommath.la + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) + install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) + +test: libtommath.a demo/demo.o + gcc $(CFLAGS) -c demo/demo.c -o demo/demo.o + libtool --mode=link gcc -o test demo/demo.o libtommath.la + +mtest: test + cd mtest ; gcc $(CFLAGS) mtest.c -o mtest -s + +timing: libtommath.la + gcc $(CFLAGS) -DTIMER demo/timing.c libtommath.a -o ltmtest -s diff --git a/libtommath/mess.sh b/libtommath/mess.sh new file mode 100644 index 0000000..bf639ce --- /dev/null +++ b/libtommath/mess.sh @@ -0,0 +1,4 @@ +#!/bin/bash +if cvs log $1 >/dev/null 2>/dev/null; then exit 0; else echo "$1 shouldn't be here" ; exit 1; fi + + diff --git a/libtommath/mtest/logtab.h b/libtommath/mtest/logtab.h new file mode 100644 index 0000000..68462bd --- /dev/null +++ b/libtommath/mtest/logtab.h @@ -0,0 +1,20 @@ +const float s_logv_2[] = { + 0.000000000, 0.000000000, 1.000000000, 0.630929754, /* 0 1 2 3 */ + 0.500000000, 0.430676558, 0.386852807, 0.356207187, /* 4 5 6 7 */ + 0.333333333, 0.315464877, 0.301029996, 0.289064826, /* 8 9 10 11 */ + 0.278942946, 0.270238154, 0.262649535, 0.255958025, /* 12 13 14 15 */ + 0.250000000, 0.244650542, 0.239812467, 0.235408913, /* 16 17 18 19 */ + 0.231378213, 0.227670249, 0.224243824, 0.221064729, /* 20 21 22 23 */ + 0.218104292, 0.215338279, 0.212746054, 0.210309918, /* 24 25 26 27 */ + 0.208014598, 0.205846832, 0.203795047, 0.201849087, /* 28 29 30 31 */ + 0.200000000, 0.198239863, 0.196561632, 0.194959022, /* 32 33 34 35 */ + 0.193426404, 0.191958720, 0.190551412, 0.189200360, /* 36 37 38 39 */ + 0.187901825, 0.186652411, 0.185449023, 0.184288833, /* 40 41 42 43 */ + 0.183169251, 0.182087900, 0.181042597, 0.180031327, /* 44 45 46 47 */ + 0.179052232, 0.178103594, 0.177183820, 0.176291434, /* 48 49 50 51 */ + 0.175425064, 0.174583430, 0.173765343, 0.172969690, /* 52 53 54 55 */ + 0.172195434, 0.171441601, 0.170707280, 0.169991616, /* 56 57 58 59 */ + 0.169293808, 0.168613099, 0.167948779, 0.167300179, /* 60 61 62 63 */ + 0.166666667 +}; + diff --git a/libtommath/mtest/mpi-config.h b/libtommath/mtest/mpi-config.h new file mode 100644 index 0000000..dcdbd35 --- /dev/null +++ b/libtommath/mtest/mpi-config.h @@ -0,0 +1,86 @@ +/* Default configuration for MPI library */ +/* $Id: mpi-config.h,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ */ + +#ifndef MPI_CONFIG_H_ +#define MPI_CONFIG_H_ + +/* + For boolean options, + 0 = no + 1 = yes + + Other options are documented individually. + + */ + +#ifndef MP_IOFUNC +#define MP_IOFUNC 0 /* include mp_print() ? */ +#endif + +#ifndef MP_MODARITH +#define MP_MODARITH 1 /* include modular arithmetic ? */ +#endif + +#ifndef MP_NUMTH +#define MP_NUMTH 1 /* include number theoretic functions? */ +#endif + +#ifndef MP_LOGTAB +#define MP_LOGTAB 1 /* use table of logs instead of log()? */ +#endif + +#ifndef MP_MEMSET +#define MP_MEMSET 1 /* use memset() to zero buffers? */ +#endif + +#ifndef MP_MEMCPY +#define MP_MEMCPY 1 /* use memcpy() to copy buffers? */ +#endif + +#ifndef MP_CRYPTO +#define MP_CRYPTO 1 /* erase memory on free? */ +#endif + +#ifndef MP_ARGCHK +/* + 0 = no parameter checks + 1 = runtime checks, continue execution and return an error to caller + 2 = assertions; dump core on parameter errors + */ +#define MP_ARGCHK 2 /* how to check input arguments */ +#endif + +#ifndef MP_DEBUG +#define MP_DEBUG 0 /* print diagnostic output? */ +#endif + +#ifndef MP_DEFPREC +#define MP_DEFPREC 64 /* default precision, in digits */ +#endif + +#ifndef MP_MACRO +#define MP_MACRO 1 /* use macros for frequent calls? */ +#endif + +#ifndef MP_SQUARE +#define MP_SQUARE 1 /* use separate squaring code? */ +#endif + +#ifndef MP_PTAB_SIZE +/* + When building mpprime.c, we build in a table of small prime + values to use for primality testing. The more you include, + the more space they take up. See primes.c for the possible + values (currently 16, 32, 64, 128, 256, and 6542) + */ +#define MP_PTAB_SIZE 128 /* how many built-in primes? */ +#endif + +#ifndef MP_COMPAT_MACROS +#define MP_COMPAT_MACROS 1 /* define compatibility macros? */ +#endif + +#endif /* ifndef MPI_CONFIG_H_ */ + + +/* crc==3287762869, version==2, Sat Feb 02 06:43:53 2002 */ diff --git a/libtommath/mtest/mpi-types.h b/libtommath/mtest/mpi-types.h new file mode 100644 index 0000000..e097188 --- /dev/null +++ b/libtommath/mtest/mpi-types.h @@ -0,0 +1,16 @@ +/* Type definitions generated by 'types.pl' */ +typedef char mp_sign; +typedef unsigned short mp_digit; /* 2 byte type */ +typedef unsigned int mp_word; /* 4 byte type */ +typedef unsigned int mp_size; +typedef int mp_err; + +#define MP_DIGIT_BIT (CHAR_BIT*sizeof(mp_digit)) +#define MP_DIGIT_MAX USHRT_MAX +#define MP_WORD_BIT (CHAR_BIT*sizeof(mp_word)) +#define MP_WORD_MAX UINT_MAX + +#define MP_DIGIT_SIZE 2 +#define DIGIT_FMT "%04X" +#define RADIX (MP_DIGIT_MAX+1) + diff --git a/libtommath/mtest/mpi.c b/libtommath/mtest/mpi.c new file mode 100644 index 0000000..0517602 --- /dev/null +++ b/libtommath/mtest/mpi.c @@ -0,0 +1,3981 @@ +/* + mpi.c + + by Michael J. Fromberger + Copyright (C) 1998 Michael J. Fromberger, All Rights Reserved + + Arbitrary precision integer arithmetic library + + $Id: mpi.c,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ + */ + +#include "mpi.h" +#include +#include +#include + +#if MP_DEBUG +#include + +#define DIAG(T,V) {fprintf(stderr,T);mp_print(V,stderr);fputc('\n',stderr);} +#else +#define DIAG(T,V) +#endif + +/* + If MP_LOGTAB is not defined, use the math library to compute the + logarithms on the fly. Otherwise, use the static table below. + Pick which works best for your system. + */ +#if MP_LOGTAB + +/* {{{ s_logv_2[] - log table for 2 in various bases */ + +/* + A table of the logs of 2 for various bases (the 0 and 1 entries of + this table are meaningless and should not be referenced). + + This table is used to compute output lengths for the mp_toradix() + function. Since a number n in radix r takes up about log_r(n) + digits, we estimate the output size by taking the least integer + greater than log_r(n), where: + + log_r(n) = log_2(n) * log_r(2) + + This table, therefore, is a table of log_r(2) for 2 <= r <= 36, + which are the output bases supported. + */ + +#include "logtab.h" + +/* }}} */ +#define LOG_V_2(R) s_logv_2[(R)] + +#else + +#include +#define LOG_V_2(R) (log(2.0)/log(R)) + +#endif + +/* Default precision for newly created mp_int's */ +static unsigned int s_mp_defprec = MP_DEFPREC; + +/* {{{ Digit arithmetic macros */ + +/* + When adding and multiplying digits, the results can be larger than + can be contained in an mp_digit. Thus, an mp_word is used. These + macros mask off the upper and lower digits of the mp_word (the + mp_word may be more than 2 mp_digits wide, but we only concern + ourselves with the low-order 2 mp_digits) + + If your mp_word DOES have more than 2 mp_digits, you need to + uncomment the first line, and comment out the second. + */ + +/* #define CARRYOUT(W) (((W)>>DIGIT_BIT)&MP_DIGIT_MAX) */ +#define CARRYOUT(W) ((W)>>DIGIT_BIT) +#define ACCUM(W) ((W)&MP_DIGIT_MAX) + +/* }}} */ + +/* {{{ Comparison constants */ + +#define MP_LT -1 +#define MP_EQ 0 +#define MP_GT 1 + +/* }}} */ + +/* {{{ Constant strings */ + +/* Constant strings returned by mp_strerror() */ +static const char *mp_err_string[] = { + "unknown result code", /* say what? */ + "boolean true", /* MP_OKAY, MP_YES */ + "boolean false", /* MP_NO */ + "out of memory", /* MP_MEM */ + "argument out of range", /* MP_RANGE */ + "invalid input parameter", /* MP_BADARG */ + "result is undefined" /* MP_UNDEF */ +}; + +/* Value to digit maps for radix conversion */ + +/* s_dmap_1 - standard digits and letters */ +static const char *s_dmap_1 = + "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz+/"; + +#if 0 +/* s_dmap_2 - base64 ordering for digits */ +static const char *s_dmap_2 = + "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/"; +#endif + +/* }}} */ + +/* {{{ Static function declarations */ + +/* + If MP_MACRO is false, these will be defined as actual functions; + otherwise, suitable macro definitions will be used. This works + around the fact that ANSI C89 doesn't support an 'inline' keyword + (although I hear C9x will ... about bloody time). At present, the + macro definitions are identical to the function bodies, but they'll + expand in place, instead of generating a function call. + + I chose these particular functions to be made into macros because + some profiling showed they are called a lot on a typical workload, + and yet they are primarily housekeeping. + */ +#if MP_MACRO == 0 + void s_mp_setz(mp_digit *dp, mp_size count); /* zero digits */ + void s_mp_copy(mp_digit *sp, mp_digit *dp, mp_size count); /* copy */ + void *s_mp_alloc(size_t nb, size_t ni); /* general allocator */ + void s_mp_free(void *ptr); /* general free function */ +#else + + /* Even if these are defined as macros, we need to respect the settings + of the MP_MEMSET and MP_MEMCPY configuration options... + */ + #if MP_MEMSET == 0 + #define s_mp_setz(dp, count) \ + {int ix;for(ix=0;ix<(count);ix++)(dp)[ix]=0;} + #else + #define s_mp_setz(dp, count) memset(dp, 0, (count) * sizeof(mp_digit)) + #endif /* MP_MEMSET */ + + #if MP_MEMCPY == 0 + #define s_mp_copy(sp, dp, count) \ + {int ix;for(ix=0;ix<(count);ix++)(dp)[ix]=(sp)[ix];} + #else + #define s_mp_copy(sp, dp, count) memcpy(dp, sp, (count) * sizeof(mp_digit)) + #endif /* MP_MEMCPY */ + + #define s_mp_alloc(nb, ni) calloc(nb, ni) + #define s_mp_free(ptr) {if(ptr) free(ptr);} +#endif /* MP_MACRO */ + +mp_err s_mp_grow(mp_int *mp, mp_size min); /* increase allocated size */ +mp_err s_mp_pad(mp_int *mp, mp_size min); /* left pad with zeroes */ + +void s_mp_clamp(mp_int *mp); /* clip leading zeroes */ + +void s_mp_exch(mp_int *a, mp_int *b); /* swap a and b in place */ + +mp_err s_mp_lshd(mp_int *mp, mp_size p); /* left-shift by p digits */ +void s_mp_rshd(mp_int *mp, mp_size p); /* right-shift by p digits */ +void s_mp_div_2d(mp_int *mp, mp_digit d); /* divide by 2^d in place */ +void s_mp_mod_2d(mp_int *mp, mp_digit d); /* modulo 2^d in place */ +mp_err s_mp_mul_2d(mp_int *mp, mp_digit d); /* multiply by 2^d in place*/ +void s_mp_div_2(mp_int *mp); /* divide by 2 in place */ +mp_err s_mp_mul_2(mp_int *mp); /* multiply by 2 in place */ +mp_digit s_mp_norm(mp_int *a, mp_int *b); /* normalize for division */ +mp_err s_mp_add_d(mp_int *mp, mp_digit d); /* unsigned digit addition */ +mp_err s_mp_sub_d(mp_int *mp, mp_digit d); /* unsigned digit subtract */ +mp_err s_mp_mul_d(mp_int *mp, mp_digit d); /* unsigned digit multiply */ +mp_err s_mp_div_d(mp_int *mp, mp_digit d, mp_digit *r); + /* unsigned digit divide */ +mp_err s_mp_reduce(mp_int *x, mp_int *m, mp_int *mu); + /* Barrett reduction */ +mp_err s_mp_add(mp_int *a, mp_int *b); /* magnitude addition */ +mp_err s_mp_sub(mp_int *a, mp_int *b); /* magnitude subtract */ +mp_err s_mp_mul(mp_int *a, mp_int *b); /* magnitude multiply */ +#if 0 +void s_mp_kmul(mp_digit *a, mp_digit *b, mp_digit *out, mp_size len); + /* multiply buffers in place */ +#endif +#if MP_SQUARE +mp_err s_mp_sqr(mp_int *a); /* magnitude square */ +#else +#define s_mp_sqr(a) s_mp_mul(a, a) +#endif +mp_err s_mp_div(mp_int *a, mp_int *b); /* magnitude divide */ +mp_err s_mp_2expt(mp_int *a, mp_digit k); /* a = 2^k */ +int s_mp_cmp(mp_int *a, mp_int *b); /* magnitude comparison */ +int s_mp_cmp_d(mp_int *a, mp_digit d); /* magnitude digit compare */ +int s_mp_ispow2(mp_int *v); /* is v a power of 2? */ +int s_mp_ispow2d(mp_digit d); /* is d a power of 2? */ + +int s_mp_tovalue(char ch, int r); /* convert ch to value */ +char s_mp_todigit(int val, int r, int low); /* convert val to digit */ +int s_mp_outlen(int bits, int r); /* output length in bytes */ + +/* }}} */ + +/* {{{ Default precision manipulation */ + +unsigned int mp_get_prec(void) +{ + return s_mp_defprec; + +} /* end mp_get_prec() */ + +void mp_set_prec(unsigned int prec) +{ + if(prec == 0) + s_mp_defprec = MP_DEFPREC; + else + s_mp_defprec = prec; + +} /* end mp_set_prec() */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ mp_init(mp) */ + +/* + mp_init(mp) + + Initialize a new zero-valued mp_int. Returns MP_OKAY if successful, + MP_MEM if memory could not be allocated for the structure. + */ + +mp_err mp_init(mp_int *mp) +{ + return mp_init_size(mp, s_mp_defprec); + +} /* end mp_init() */ + +/* }}} */ + +/* {{{ mp_init_array(mp[], count) */ + +mp_err mp_init_array(mp_int mp[], int count) +{ + mp_err res; + int pos; + + ARGCHK(mp !=NULL && count > 0, MP_BADARG); + + for(pos = 0; pos < count; ++pos) { + if((res = mp_init(&mp[pos])) != MP_OKAY) + goto CLEANUP; + } + + return MP_OKAY; + + CLEANUP: + while(--pos >= 0) + mp_clear(&mp[pos]); + + return res; + +} /* end mp_init_array() */ + +/* }}} */ + +/* {{{ mp_init_size(mp, prec) */ + +/* + mp_init_size(mp, prec) + + Initialize a new zero-valued mp_int with at least the given + precision; returns MP_OKAY if successful, or MP_MEM if memory could + not be allocated for the structure. + */ + +mp_err mp_init_size(mp_int *mp, mp_size prec) +{ + ARGCHK(mp != NULL && prec > 0, MP_BADARG); + + if((DIGITS(mp) = s_mp_alloc(prec, sizeof(mp_digit))) == NULL) + return MP_MEM; + + SIGN(mp) = MP_ZPOS; + USED(mp) = 1; + ALLOC(mp) = prec; + + return MP_OKAY; + +} /* end mp_init_size() */ + +/* }}} */ + +/* {{{ mp_init_copy(mp, from) */ + +/* + mp_init_copy(mp, from) + + Initialize mp as an exact copy of from. Returns MP_OKAY if + successful, MP_MEM if memory could not be allocated for the new + structure. + */ + +mp_err mp_init_copy(mp_int *mp, mp_int *from) +{ + ARGCHK(mp != NULL && from != NULL, MP_BADARG); + + if(mp == from) + return MP_OKAY; + + if((DIGITS(mp) = s_mp_alloc(USED(from), sizeof(mp_digit))) == NULL) + return MP_MEM; + + s_mp_copy(DIGITS(from), DIGITS(mp), USED(from)); + USED(mp) = USED(from); + ALLOC(mp) = USED(from); + SIGN(mp) = SIGN(from); + + return MP_OKAY; + +} /* end mp_init_copy() */ + +/* }}} */ + +/* {{{ mp_copy(from, to) */ + +/* + mp_copy(from, to) + + Copies the mp_int 'from' to the mp_int 'to'. It is presumed that + 'to' has already been initialized (if not, use mp_init_copy() + instead). If 'from' and 'to' are identical, nothing happens. + */ + +mp_err mp_copy(mp_int *from, mp_int *to) +{ + ARGCHK(from != NULL && to != NULL, MP_BADARG); + + if(from == to) + return MP_OKAY; + + { /* copy */ + mp_digit *tmp; + + /* + If the allocated buffer in 'to' already has enough space to hold + all the used digits of 'from', we'll re-use it to avoid hitting + the memory allocater more than necessary; otherwise, we'd have + to grow anyway, so we just allocate a hunk and make the copy as + usual + */ + if(ALLOC(to) >= USED(from)) { + s_mp_setz(DIGITS(to) + USED(from), ALLOC(to) - USED(from)); + s_mp_copy(DIGITS(from), DIGITS(to), USED(from)); + + } else { + if((tmp = s_mp_alloc(USED(from), sizeof(mp_digit))) == NULL) + return MP_MEM; + + s_mp_copy(DIGITS(from), tmp, USED(from)); + + if(DIGITS(to) != NULL) { +#if MP_CRYPTO + s_mp_setz(DIGITS(to), ALLOC(to)); +#endif + s_mp_free(DIGITS(to)); + } + + DIGITS(to) = tmp; + ALLOC(to) = USED(from); + } + + /* Copy the precision and sign from the original */ + USED(to) = USED(from); + SIGN(to) = SIGN(from); + } /* end copy */ + + return MP_OKAY; + +} /* end mp_copy() */ + +/* }}} */ + +/* {{{ mp_exch(mp1, mp2) */ + +/* + mp_exch(mp1, mp2) + + Exchange mp1 and mp2 without allocating any intermediate memory + (well, unless you count the stack space needed for this call and the + locals it creates...). This cannot fail. + */ + +void mp_exch(mp_int *mp1, mp_int *mp2) +{ +#if MP_ARGCHK == 2 + assert(mp1 != NULL && mp2 != NULL); +#else + if(mp1 == NULL || mp2 == NULL) + return; +#endif + + s_mp_exch(mp1, mp2); + +} /* end mp_exch() */ + +/* }}} */ + +/* {{{ mp_clear(mp) */ + +/* + mp_clear(mp) + + Release the storage used by an mp_int, and void its fields so that + if someone calls mp_clear() again for the same int later, we won't + get tollchocked. + */ + +void mp_clear(mp_int *mp) +{ + if(mp == NULL) + return; + + if(DIGITS(mp) != NULL) { +#if MP_CRYPTO + s_mp_setz(DIGITS(mp), ALLOC(mp)); +#endif + s_mp_free(DIGITS(mp)); + DIGITS(mp) = NULL; + } + + USED(mp) = 0; + ALLOC(mp) = 0; + +} /* end mp_clear() */ + +/* }}} */ + +/* {{{ mp_clear_array(mp[], count) */ + +void mp_clear_array(mp_int mp[], int count) +{ + ARGCHK(mp != NULL && count > 0, MP_BADARG); + + while(--count >= 0) + mp_clear(&mp[count]); + +} /* end mp_clear_array() */ + +/* }}} */ + +/* {{{ mp_zero(mp) */ + +/* + mp_zero(mp) + + Set mp to zero. Does not change the allocated size of the structure, + and therefore cannot fail (except on a bad argument, which we ignore) + */ +void mp_zero(mp_int *mp) +{ + if(mp == NULL) + return; + + s_mp_setz(DIGITS(mp), ALLOC(mp)); + USED(mp) = 1; + SIGN(mp) = MP_ZPOS; + +} /* end mp_zero() */ + +/* }}} */ + +/* {{{ mp_set(mp, d) */ + +void mp_set(mp_int *mp, mp_digit d) +{ + if(mp == NULL) + return; + + mp_zero(mp); + DIGIT(mp, 0) = d; + +} /* end mp_set() */ + +/* }}} */ + +/* {{{ mp_set_int(mp, z) */ + +mp_err mp_set_int(mp_int *mp, long z) +{ + int ix; + unsigned long v = abs(z); + mp_err res; + + ARGCHK(mp != NULL, MP_BADARG); + + mp_zero(mp); + if(z == 0) + return MP_OKAY; /* shortcut for zero */ + + for(ix = sizeof(long) - 1; ix >= 0; ix--) { + + if((res = s_mp_mul_2d(mp, CHAR_BIT)) != MP_OKAY) + return res; + + res = s_mp_add_d(mp, + (mp_digit)((v >> (ix * CHAR_BIT)) & UCHAR_MAX)); + if(res != MP_OKAY) + return res; + + } + + if(z < 0) + SIGN(mp) = MP_NEG; + + return MP_OKAY; + +} /* end mp_set_int() */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ Digit arithmetic */ + +/* {{{ mp_add_d(a, d, b) */ + +/* + mp_add_d(a, d, b) + + Compute the sum b = a + d, for a single digit d. Respects the sign of + its primary addend (single digits are unsigned anyway). + */ + +mp_err mp_add_d(mp_int *a, mp_digit d, mp_int *b) +{ + mp_err res = MP_OKAY; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + if(SIGN(b) == MP_ZPOS) { + res = s_mp_add_d(b, d); + } else if(s_mp_cmp_d(b, d) >= 0) { + res = s_mp_sub_d(b, d); + } else { + SIGN(b) = MP_ZPOS; + + DIGIT(b, 0) = d - DIGIT(b, 0); + } + + return res; + +} /* end mp_add_d() */ + +/* }}} */ + +/* {{{ mp_sub_d(a, d, b) */ + +/* + mp_sub_d(a, d, b) + + Compute the difference b = a - d, for a single digit d. Respects the + sign of its subtrahend (single digits are unsigned anyway). + */ + +mp_err mp_sub_d(mp_int *a, mp_digit d, mp_int *b) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + if(SIGN(b) == MP_NEG) { + if((res = s_mp_add_d(b, d)) != MP_OKAY) + return res; + + } else if(s_mp_cmp_d(b, d) >= 0) { + if((res = s_mp_sub_d(b, d)) != MP_OKAY) + return res; + + } else { + mp_neg(b, b); + + DIGIT(b, 0) = d - DIGIT(b, 0); + SIGN(b) = MP_NEG; + } + + if(s_mp_cmp_d(b, 0) == 0) + SIGN(b) = MP_ZPOS; + + return MP_OKAY; + +} /* end mp_sub_d() */ + +/* }}} */ + +/* {{{ mp_mul_d(a, d, b) */ + +/* + mp_mul_d(a, d, b) + + Compute the product b = a * d, for a single digit d. Respects the sign + of its multiplicand (single digits are unsigned anyway) + */ + +mp_err mp_mul_d(mp_int *a, mp_digit d, mp_int *b) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if(d == 0) { + mp_zero(b); + return MP_OKAY; + } + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + res = s_mp_mul_d(b, d); + + return res; + +} /* end mp_mul_d() */ + +/* }}} */ + +/* {{{ mp_mul_2(a, c) */ + +mp_err mp_mul_2(mp_int *a, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if((res = mp_copy(a, c)) != MP_OKAY) + return res; + + return s_mp_mul_2(c); + +} /* end mp_mul_2() */ + +/* }}} */ + +/* {{{ mp_div_d(a, d, q, r) */ + +/* + mp_div_d(a, d, q, r) + + Compute the quotient q = a / d and remainder r = a mod d, for a + single digit d. Respects the sign of its divisor (single digits are + unsigned anyway). + */ + +mp_err mp_div_d(mp_int *a, mp_digit d, mp_int *q, mp_digit *r) +{ + mp_err res; + mp_digit rem; + int pow; + + ARGCHK(a != NULL, MP_BADARG); + + if(d == 0) + return MP_RANGE; + + /* Shortcut for powers of two ... */ + if((pow = s_mp_ispow2d(d)) >= 0) { + mp_digit mask; + + mask = (1 << pow) - 1; + rem = DIGIT(a, 0) & mask; + + if(q) { + mp_copy(a, q); + s_mp_div_2d(q, pow); + } + + if(r) + *r = rem; + + return MP_OKAY; + } + + /* + If the quotient is actually going to be returned, we'll try to + avoid hitting the memory allocator by copying the dividend into it + and doing the division there. This can't be any _worse_ than + always copying, and will sometimes be better (since it won't make + another copy) + + If it's not going to be returned, we need to allocate a temporary + to hold the quotient, which will just be discarded. + */ + if(q) { + if((res = mp_copy(a, q)) != MP_OKAY) + return res; + + res = s_mp_div_d(q, d, &rem); + if(s_mp_cmp_d(q, 0) == MP_EQ) + SIGN(q) = MP_ZPOS; + + } else { + mp_int qp; + + if((res = mp_init_copy(&qp, a)) != MP_OKAY) + return res; + + res = s_mp_div_d(&qp, d, &rem); + if(s_mp_cmp_d(&qp, 0) == 0) + SIGN(&qp) = MP_ZPOS; + + mp_clear(&qp); + } + + if(r) + *r = rem; + + return res; + +} /* end mp_div_d() */ + +/* }}} */ + +/* {{{ mp_div_2(a, c) */ + +/* + mp_div_2(a, c) + + Compute c = a / 2, disregarding the remainder. + */ + +mp_err mp_div_2(mp_int *a, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if((res = mp_copy(a, c)) != MP_OKAY) + return res; + + s_mp_div_2(c); + + return MP_OKAY; + +} /* end mp_div_2() */ + +/* }}} */ + +/* {{{ mp_expt_d(a, d, b) */ + +mp_err mp_expt_d(mp_int *a, mp_digit d, mp_int *c) +{ + mp_int s, x; + mp_err res; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if((res = mp_init(&s)) != MP_OKAY) + return res; + if((res = mp_init_copy(&x, a)) != MP_OKAY) + goto X; + + DIGIT(&s, 0) = 1; + + while(d != 0) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY) + goto CLEANUP; + } + + d >>= 1; + + if((res = s_mp_sqr(&x)) != MP_OKAY) + goto CLEANUP; + } + + s_mp_exch(&s, c); + +CLEANUP: + mp_clear(&x); +X: + mp_clear(&s); + + return res; + +} /* end mp_expt_d() */ + +/* }}} */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ Full arithmetic */ + +/* {{{ mp_abs(a, b) */ + +/* + mp_abs(a, b) + + Compute b = |a|. 'a' and 'b' may be identical. + */ + +mp_err mp_abs(mp_int *a, mp_int *b) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + SIGN(b) = MP_ZPOS; + + return MP_OKAY; + +} /* end mp_abs() */ + +/* }}} */ + +/* {{{ mp_neg(a, b) */ + +/* + mp_neg(a, b) + + Compute b = -a. 'a' and 'b' may be identical. + */ + +mp_err mp_neg(mp_int *a, mp_int *b) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + if(s_mp_cmp_d(b, 0) == MP_EQ) + SIGN(b) = MP_ZPOS; + else + SIGN(b) = (SIGN(b) == MP_NEG) ? MP_ZPOS : MP_NEG; + + return MP_OKAY; + +} /* end mp_neg() */ + +/* }}} */ + +/* {{{ mp_add(a, b, c) */ + +/* + mp_add(a, b, c) + + Compute c = a + b. All parameters may be identical. + */ + +mp_err mp_add(mp_int *a, mp_int *b, mp_int *c) +{ + mp_err res; + int cmp; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + if(SIGN(a) == SIGN(b)) { /* same sign: add values, keep sign */ + + /* Commutativity of addition lets us do this in either order, + so we avoid having to use a temporary even if the result + is supposed to replace the output + */ + if(c == b) { + if((res = s_mp_add(c, a)) != MP_OKAY) + return res; + } else { + if(c != a && (res = mp_copy(a, c)) != MP_OKAY) + return res; + + if((res = s_mp_add(c, b)) != MP_OKAY) + return res; + } + + } else if((cmp = s_mp_cmp(a, b)) > 0) { /* different sign: a > b */ + + /* If the output is going to be clobbered, we will use a temporary + variable; otherwise, we'll do it without touching the memory + allocator at all, if possible + */ + if(c == b) { + mp_int tmp; + + if((res = mp_init_copy(&tmp, a)) != MP_OKAY) + return res; + if((res = s_mp_sub(&tmp, b)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + s_mp_exch(&tmp, c); + mp_clear(&tmp); + + } else { + + if(c != a && (res = mp_copy(a, c)) != MP_OKAY) + return res; + if((res = s_mp_sub(c, b)) != MP_OKAY) + return res; + + } + + } else if(cmp == 0) { /* different sign, a == b */ + + mp_zero(c); + return MP_OKAY; + + } else { /* different sign: a < b */ + + /* See above... */ + if(c == a) { + mp_int tmp; + + if((res = mp_init_copy(&tmp, b)) != MP_OKAY) + return res; + if((res = s_mp_sub(&tmp, a)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + s_mp_exch(&tmp, c); + mp_clear(&tmp); + + } else { + + if(c != b && (res = mp_copy(b, c)) != MP_OKAY) + return res; + if((res = s_mp_sub(c, a)) != MP_OKAY) + return res; + + } + } + + if(USED(c) == 1 && DIGIT(c, 0) == 0) + SIGN(c) = MP_ZPOS; + + return MP_OKAY; + +} /* end mp_add() */ + +/* }}} */ + +/* {{{ mp_sub(a, b, c) */ + +/* + mp_sub(a, b, c) + + Compute c = a - b. All parameters may be identical. + */ + +mp_err mp_sub(mp_int *a, mp_int *b, mp_int *c) +{ + mp_err res; + int cmp; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + if(SIGN(a) != SIGN(b)) { + if(c == a) { + if((res = s_mp_add(c, b)) != MP_OKAY) + return res; + } else { + if(c != b && ((res = mp_copy(b, c)) != MP_OKAY)) + return res; + if((res = s_mp_add(c, a)) != MP_OKAY) + return res; + SIGN(c) = SIGN(a); + } + + } else if((cmp = s_mp_cmp(a, b)) > 0) { /* Same sign, a > b */ + if(c == b) { + mp_int tmp; + + if((res = mp_init_copy(&tmp, a)) != MP_OKAY) + return res; + if((res = s_mp_sub(&tmp, b)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + s_mp_exch(&tmp, c); + mp_clear(&tmp); + + } else { + if(c != a && ((res = mp_copy(a, c)) != MP_OKAY)) + return res; + + if((res = s_mp_sub(c, b)) != MP_OKAY) + return res; + } + + } else if(cmp == 0) { /* Same sign, equal magnitude */ + mp_zero(c); + return MP_OKAY; + + } else { /* Same sign, b > a */ + if(c == a) { + mp_int tmp; + + if((res = mp_init_copy(&tmp, b)) != MP_OKAY) + return res; + + if((res = s_mp_sub(&tmp, a)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + s_mp_exch(&tmp, c); + mp_clear(&tmp); + + } else { + if(c != b && ((res = mp_copy(b, c)) != MP_OKAY)) + return res; + + if((res = s_mp_sub(c, a)) != MP_OKAY) + return res; + } + + SIGN(c) = !SIGN(b); + } + + if(USED(c) == 1 && DIGIT(c, 0) == 0) + SIGN(c) = MP_ZPOS; + + return MP_OKAY; + +} /* end mp_sub() */ + +/* }}} */ + +/* {{{ mp_mul(a, b, c) */ + +/* + mp_mul(a, b, c) + + Compute c = a * b. All parameters may be identical. + */ + +mp_err mp_mul(mp_int *a, mp_int *b, mp_int *c) +{ + mp_err res; + mp_sign sgn; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + sgn = (SIGN(a) == SIGN(b)) ? MP_ZPOS : MP_NEG; + + if(c == b) { + if((res = s_mp_mul(c, a)) != MP_OKAY) + return res; + + } else { + if((res = mp_copy(a, c)) != MP_OKAY) + return res; + + if((res = s_mp_mul(c, b)) != MP_OKAY) + return res; + } + + if(sgn == MP_ZPOS || s_mp_cmp_d(c, 0) == MP_EQ) + SIGN(c) = MP_ZPOS; + else + SIGN(c) = sgn; + + return MP_OKAY; + +} /* end mp_mul() */ + +/* }}} */ + +/* {{{ mp_mul_2d(a, d, c) */ + +/* + mp_mul_2d(a, d, c) + + Compute c = a * 2^d. a may be the same as c. + */ + +mp_err mp_mul_2d(mp_int *a, mp_digit d, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if((res = mp_copy(a, c)) != MP_OKAY) + return res; + + if(d == 0) + return MP_OKAY; + + return s_mp_mul_2d(c, d); + +} /* end mp_mul() */ + +/* }}} */ + +/* {{{ mp_sqr(a, b) */ + +#if MP_SQUARE +mp_err mp_sqr(mp_int *a, mp_int *b) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if((res = mp_copy(a, b)) != MP_OKAY) + return res; + + if((res = s_mp_sqr(b)) != MP_OKAY) + return res; + + SIGN(b) = MP_ZPOS; + + return MP_OKAY; + +} /* end mp_sqr() */ +#endif + +/* }}} */ + +/* {{{ mp_div(a, b, q, r) */ + +/* + mp_div(a, b, q, r) + + Compute q = a / b and r = a mod b. Input parameters may be re-used + as output parameters. If q or r is NULL, that portion of the + computation will be discarded (although it will still be computed) + + Pay no attention to the hacker behind the curtain. + */ + +mp_err mp_div(mp_int *a, mp_int *b, mp_int *q, mp_int *r) +{ + mp_err res; + mp_int qtmp, rtmp; + int cmp; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + if(mp_cmp_z(b) == MP_EQ) + return MP_RANGE; + + /* If a <= b, we can compute the solution without division, and + avoid any memory allocation + */ + if((cmp = s_mp_cmp(a, b)) < 0) { + if(r) { + if((res = mp_copy(a, r)) != MP_OKAY) + return res; + } + + if(q) + mp_zero(q); + + return MP_OKAY; + + } else if(cmp == 0) { + + /* Set quotient to 1, with appropriate sign */ + if(q) { + int qneg = (SIGN(a) != SIGN(b)); + + mp_set(q, 1); + if(qneg) + SIGN(q) = MP_NEG; + } + + if(r) + mp_zero(r); + + return MP_OKAY; + } + + /* If we get here, it means we actually have to do some division */ + + /* Set up some temporaries... */ + if((res = mp_init_copy(&qtmp, a)) != MP_OKAY) + return res; + if((res = mp_init_copy(&rtmp, b)) != MP_OKAY) + goto CLEANUP; + + if((res = s_mp_div(&qtmp, &rtmp)) != MP_OKAY) + goto CLEANUP; + + /* Compute the signs for the output */ + SIGN(&rtmp) = SIGN(a); /* Sr = Sa */ + if(SIGN(a) == SIGN(b)) + SIGN(&qtmp) = MP_ZPOS; /* Sq = MP_ZPOS if Sa = Sb */ + else + SIGN(&qtmp) = MP_NEG; /* Sq = MP_NEG if Sa != Sb */ + + if(s_mp_cmp_d(&qtmp, 0) == MP_EQ) + SIGN(&qtmp) = MP_ZPOS; + if(s_mp_cmp_d(&rtmp, 0) == MP_EQ) + SIGN(&rtmp) = MP_ZPOS; + + /* Copy output, if it is needed */ + if(q) + s_mp_exch(&qtmp, q); + + if(r) + s_mp_exch(&rtmp, r); + +CLEANUP: + mp_clear(&rtmp); + mp_clear(&qtmp); + + return res; + +} /* end mp_div() */ + +/* }}} */ + +/* {{{ mp_div_2d(a, d, q, r) */ + +mp_err mp_div_2d(mp_int *a, mp_digit d, mp_int *q, mp_int *r) +{ + mp_err res; + + ARGCHK(a != NULL, MP_BADARG); + + if(q) { + if((res = mp_copy(a, q)) != MP_OKAY) + return res; + + s_mp_div_2d(q, d); + } + + if(r) { + if((res = mp_copy(a, r)) != MP_OKAY) + return res; + + s_mp_mod_2d(r, d); + } + + return MP_OKAY; + +} /* end mp_div_2d() */ + +/* }}} */ + +/* {{{ mp_expt(a, b, c) */ + +/* + mp_expt(a, b, c) + + Compute c = a ** b, that is, raise a to the b power. Uses a + standard iterative square-and-multiply technique. + */ + +mp_err mp_expt(mp_int *a, mp_int *b, mp_int *c) +{ + mp_int s, x; + mp_err res; + mp_digit d; + int dig, bit; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + if(mp_cmp_z(b) < 0) + return MP_RANGE; + + if((res = mp_init(&s)) != MP_OKAY) + return res; + + mp_set(&s, 1); + + if((res = mp_init_copy(&x, a)) != MP_OKAY) + goto X; + + /* Loop over low-order digits in ascending order */ + for(dig = 0; dig < (USED(b) - 1); dig++) { + d = DIGIT(b, dig); + + /* Loop over bits of each non-maximal digit */ + for(bit = 0; bit < DIGIT_BIT; bit++) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY) + goto CLEANUP; + } + + d >>= 1; + + if((res = s_mp_sqr(&x)) != MP_OKAY) + goto CLEANUP; + } + } + + /* Consider now the last digit... */ + d = DIGIT(b, dig); + + while(d) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY) + goto CLEANUP; + } + + d >>= 1; + + if((res = s_mp_sqr(&x)) != MP_OKAY) + goto CLEANUP; + } + + if(mp_iseven(b)) + SIGN(&s) = SIGN(a); + + res = mp_copy(&s, c); + +CLEANUP: + mp_clear(&x); +X: + mp_clear(&s); + + return res; + +} /* end mp_expt() */ + +/* }}} */ + +/* {{{ mp_2expt(a, k) */ + +/* Compute a = 2^k */ + +mp_err mp_2expt(mp_int *a, mp_digit k) +{ + ARGCHK(a != NULL, MP_BADARG); + + return s_mp_2expt(a, k); + +} /* end mp_2expt() */ + +/* }}} */ + +/* {{{ mp_mod(a, m, c) */ + +/* + mp_mod(a, m, c) + + Compute c = a (mod m). Result will always be 0 <= c < m. + */ + +mp_err mp_mod(mp_int *a, mp_int *m, mp_int *c) +{ + mp_err res; + int mag; + + ARGCHK(a != NULL && m != NULL && c != NULL, MP_BADARG); + + if(SIGN(m) == MP_NEG) + return MP_RANGE; + + /* + If |a| > m, we need to divide to get the remainder and take the + absolute value. + + If |a| < m, we don't need to do any division, just copy and adjust + the sign (if a is negative). + + If |a| == m, we can simply set the result to zero. + + This order is intended to minimize the average path length of the + comparison chain on common workloads -- the most frequent cases are + that |a| != m, so we do those first. + */ + if((mag = s_mp_cmp(a, m)) > 0) { + if((res = mp_div(a, m, NULL, c)) != MP_OKAY) + return res; + + if(SIGN(c) == MP_NEG) { + if((res = mp_add(c, m, c)) != MP_OKAY) + return res; + } + + } else if(mag < 0) { + if((res = mp_copy(a, c)) != MP_OKAY) + return res; + + if(mp_cmp_z(a) < 0) { + if((res = mp_add(c, m, c)) != MP_OKAY) + return res; + + } + + } else { + mp_zero(c); + + } + + return MP_OKAY; + +} /* end mp_mod() */ + +/* }}} */ + +/* {{{ mp_mod_d(a, d, c) */ + +/* + mp_mod_d(a, d, c) + + Compute c = a (mod d). Result will always be 0 <= c < d + */ +mp_err mp_mod_d(mp_int *a, mp_digit d, mp_digit *c) +{ + mp_err res; + mp_digit rem; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if(s_mp_cmp_d(a, d) > 0) { + if((res = mp_div_d(a, d, NULL, &rem)) != MP_OKAY) + return res; + + } else { + if(SIGN(a) == MP_NEG) + rem = d - DIGIT(a, 0); + else + rem = DIGIT(a, 0); + } + + if(c) + *c = rem; + + return MP_OKAY; + +} /* end mp_mod_d() */ + +/* }}} */ + +/* {{{ mp_sqrt(a, b) */ + +/* + mp_sqrt(a, b) + + Compute the integer square root of a, and store the result in b. + Uses an integer-arithmetic version of Newton's iterative linear + approximation technique to determine this value; the result has the + following two properties: + + b^2 <= a + (b+1)^2 >= a + + It is a range error to pass a negative value. + */ +mp_err mp_sqrt(mp_int *a, mp_int *b) +{ + mp_int x, t; + mp_err res; + + ARGCHK(a != NULL && b != NULL, MP_BADARG); + + /* Cannot take square root of a negative value */ + if(SIGN(a) == MP_NEG) + return MP_RANGE; + + /* Special cases for zero and one, trivial */ + if(mp_cmp_d(a, 0) == MP_EQ || mp_cmp_d(a, 1) == MP_EQ) + return mp_copy(a, b); + + /* Initialize the temporaries we'll use below */ + if((res = mp_init_size(&t, USED(a))) != MP_OKAY) + return res; + + /* Compute an initial guess for the iteration as a itself */ + if((res = mp_init_copy(&x, a)) != MP_OKAY) + goto X; + +s_mp_rshd(&x, (USED(&x)/2)+1); +mp_add_d(&x, 1, &x); + + for(;;) { + /* t = (x * x) - a */ + mp_copy(&x, &t); /* can't fail, t is big enough for original x */ + if((res = mp_sqr(&t, &t)) != MP_OKAY || + (res = mp_sub(&t, a, &t)) != MP_OKAY) + goto CLEANUP; + + /* t = t / 2x */ + s_mp_mul_2(&x); + if((res = mp_div(&t, &x, &t, NULL)) != MP_OKAY) + goto CLEANUP; + s_mp_div_2(&x); + + /* Terminate the loop, if the quotient is zero */ + if(mp_cmp_z(&t) == MP_EQ) + break; + + /* x = x - t */ + if((res = mp_sub(&x, &t, &x)) != MP_OKAY) + goto CLEANUP; + + } + + /* Copy result to output parameter */ + mp_sub_d(&x, 1, &x); + s_mp_exch(&x, b); + + CLEANUP: + mp_clear(&x); + X: + mp_clear(&t); + + return res; + +} /* end mp_sqrt() */ + +/* }}} */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ Modular arithmetic */ + +#if MP_MODARITH +/* {{{ mp_addmod(a, b, m, c) */ + +/* + mp_addmod(a, b, m, c) + + Compute c = (a + b) mod m + */ + +mp_err mp_addmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL && m != NULL && c != NULL, MP_BADARG); + + if((res = mp_add(a, b, c)) != MP_OKAY) + return res; + if((res = mp_mod(c, m, c)) != MP_OKAY) + return res; + + return MP_OKAY; + +} + +/* }}} */ + +/* {{{ mp_submod(a, b, m, c) */ + +/* + mp_submod(a, b, m, c) + + Compute c = (a - b) mod m + */ + +mp_err mp_submod(mp_int *a, mp_int *b, mp_int *m, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL && m != NULL && c != NULL, MP_BADARG); + + if((res = mp_sub(a, b, c)) != MP_OKAY) + return res; + if((res = mp_mod(c, m, c)) != MP_OKAY) + return res; + + return MP_OKAY; + +} + +/* }}} */ + +/* {{{ mp_mulmod(a, b, m, c) */ + +/* + mp_mulmod(a, b, m, c) + + Compute c = (a * b) mod m + */ + +mp_err mp_mulmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && b != NULL && m != NULL && c != NULL, MP_BADARG); + + if((res = mp_mul(a, b, c)) != MP_OKAY) + return res; + if((res = mp_mod(c, m, c)) != MP_OKAY) + return res; + + return MP_OKAY; + +} + +/* }}} */ + +/* {{{ mp_sqrmod(a, m, c) */ + +#if MP_SQUARE +mp_err mp_sqrmod(mp_int *a, mp_int *m, mp_int *c) +{ + mp_err res; + + ARGCHK(a != NULL && m != NULL && c != NULL, MP_BADARG); + + if((res = mp_sqr(a, c)) != MP_OKAY) + return res; + if((res = mp_mod(c, m, c)) != MP_OKAY) + return res; + + return MP_OKAY; + +} /* end mp_sqrmod() */ +#endif + +/* }}} */ + +/* {{{ mp_exptmod(a, b, m, c) */ + +/* + mp_exptmod(a, b, m, c) + + Compute c = (a ** b) mod m. Uses a standard square-and-multiply + method with modular reductions at each step. (This is basically the + same code as mp_expt(), except for the addition of the reductions) + + The modular reductions are done using Barrett's algorithm (see + s_mp_reduce() below for details) + */ + +mp_err mp_exptmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c) +{ + mp_int s, x, mu; + mp_err res; + mp_digit d, *db = DIGITS(b); + mp_size ub = USED(b); + int dig, bit; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + if(mp_cmp_z(b) < 0 || mp_cmp_z(m) <= 0) + return MP_RANGE; + + if((res = mp_init(&s)) != MP_OKAY) + return res; + if((res = mp_init_copy(&x, a)) != MP_OKAY) + goto X; + if((res = mp_mod(&x, m, &x)) != MP_OKAY || + (res = mp_init(&mu)) != MP_OKAY) + goto MU; + + mp_set(&s, 1); + + /* mu = b^2k / m */ + s_mp_add_d(&mu, 1); + s_mp_lshd(&mu, 2 * USED(m)); + if((res = mp_div(&mu, m, &mu, NULL)) != MP_OKAY) + goto CLEANUP; + + /* Loop over digits of b in ascending order, except highest order */ + for(dig = 0; dig < (ub - 1); dig++) { + d = *db++; + + /* Loop over the bits of the lower-order digits */ + for(bit = 0; bit < DIGIT_BIT; bit++) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY) + goto CLEANUP; + if((res = s_mp_reduce(&s, m, &mu)) != MP_OKAY) + goto CLEANUP; + } + + d >>= 1; + + if((res = s_mp_sqr(&x)) != MP_OKAY) + goto CLEANUP; + if((res = s_mp_reduce(&x, m, &mu)) != MP_OKAY) + goto CLEANUP; + } + } + + /* Now do the last digit... */ + d = *db; + + while(d) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY) + goto CLEANUP; + if((res = s_mp_reduce(&s, m, &mu)) != MP_OKAY) + goto CLEANUP; + } + + d >>= 1; + + if((res = s_mp_sqr(&x)) != MP_OKAY) + goto CLEANUP; + if((res = s_mp_reduce(&x, m, &mu)) != MP_OKAY) + goto CLEANUP; + } + + s_mp_exch(&s, c); + + CLEANUP: + mp_clear(&mu); + MU: + mp_clear(&x); + X: + mp_clear(&s); + + return res; + +} /* end mp_exptmod() */ + +/* }}} */ + +/* {{{ mp_exptmod_d(a, d, m, c) */ + +mp_err mp_exptmod_d(mp_int *a, mp_digit d, mp_int *m, mp_int *c) +{ + mp_int s, x; + mp_err res; + + ARGCHK(a != NULL && c != NULL, MP_BADARG); + + if((res = mp_init(&s)) != MP_OKAY) + return res; + if((res = mp_init_copy(&x, a)) != MP_OKAY) + goto X; + + mp_set(&s, 1); + + while(d != 0) { + if(d & 1) { + if((res = s_mp_mul(&s, &x)) != MP_OKAY || + (res = mp_mod(&s, m, &s)) != MP_OKAY) + goto CLEANUP; + } + + d /= 2; + + if((res = s_mp_sqr(&x)) != MP_OKAY || + (res = mp_mod(&x, m, &x)) != MP_OKAY) + goto CLEANUP; + } + + s_mp_exch(&s, c); + +CLEANUP: + mp_clear(&x); +X: + mp_clear(&s); + + return res; + +} /* end mp_exptmod_d() */ + +/* }}} */ +#endif /* if MP_MODARITH */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ Comparison functions */ + +/* {{{ mp_cmp_z(a) */ + +/* + mp_cmp_z(a) + + Compare a <=> 0. Returns <0 if a<0, 0 if a=0, >0 if a>0. + */ + +int mp_cmp_z(mp_int *a) +{ + if(SIGN(a) == MP_NEG) + return MP_LT; + else if(USED(a) == 1 && DIGIT(a, 0) == 0) + return MP_EQ; + else + return MP_GT; + +} /* end mp_cmp_z() */ + +/* }}} */ + +/* {{{ mp_cmp_d(a, d) */ + +/* + mp_cmp_d(a, d) + + Compare a <=> d. Returns <0 if a0 if a>d + */ + +int mp_cmp_d(mp_int *a, mp_digit d) +{ + ARGCHK(a != NULL, MP_EQ); + + if(SIGN(a) == MP_NEG) + return MP_LT; + + return s_mp_cmp_d(a, d); + +} /* end mp_cmp_d() */ + +/* }}} */ + +/* {{{ mp_cmp(a, b) */ + +int mp_cmp(mp_int *a, mp_int *b) +{ + ARGCHK(a != NULL && b != NULL, MP_EQ); + + if(SIGN(a) == SIGN(b)) { + int mag; + + if((mag = s_mp_cmp(a, b)) == MP_EQ) + return MP_EQ; + + if(SIGN(a) == MP_ZPOS) + return mag; + else + return -mag; + + } else if(SIGN(a) == MP_ZPOS) { + return MP_GT; + } else { + return MP_LT; + } + +} /* end mp_cmp() */ + +/* }}} */ + +/* {{{ mp_cmp_mag(a, b) */ + +/* + mp_cmp_mag(a, b) + + Compares |a| <=> |b|, and returns an appropriate comparison result + */ + +int mp_cmp_mag(mp_int *a, mp_int *b) +{ + ARGCHK(a != NULL && b != NULL, MP_EQ); + + return s_mp_cmp(a, b); + +} /* end mp_cmp_mag() */ + +/* }}} */ + +/* {{{ mp_cmp_int(a, z) */ + +/* + This just converts z to an mp_int, and uses the existing comparison + routines. This is sort of inefficient, but it's not clear to me how + frequently this wil get used anyway. For small positive constants, + you can always use mp_cmp_d(), and for zero, there is mp_cmp_z(). + */ +int mp_cmp_int(mp_int *a, long z) +{ + mp_int tmp; + int out; + + ARGCHK(a != NULL, MP_EQ); + + mp_init(&tmp); mp_set_int(&tmp, z); + out = mp_cmp(a, &tmp); + mp_clear(&tmp); + + return out; + +} /* end mp_cmp_int() */ + +/* }}} */ + +/* {{{ mp_isodd(a) */ + +/* + mp_isodd(a) + + Returns a true (non-zero) value if a is odd, false (zero) otherwise. + */ +int mp_isodd(mp_int *a) +{ + ARGCHK(a != NULL, 0); + + return (DIGIT(a, 0) & 1); + +} /* end mp_isodd() */ + +/* }}} */ + +/* {{{ mp_iseven(a) */ + +int mp_iseven(mp_int *a) +{ + return !mp_isodd(a); + +} /* end mp_iseven() */ + +/* }}} */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ Number theoretic functions */ + +#if MP_NUMTH +/* {{{ mp_gcd(a, b, c) */ + +/* + Like the old mp_gcd() function, except computes the GCD using the + binary algorithm due to Josef Stein in 1961 (via Knuth). + */ +mp_err mp_gcd(mp_int *a, mp_int *b, mp_int *c) +{ + mp_err res; + mp_int u, v, t; + mp_size k = 0; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + if(mp_cmp_z(a) == MP_EQ && mp_cmp_z(b) == MP_EQ) + return MP_RANGE; + if(mp_cmp_z(a) == MP_EQ) { + return mp_copy(b, c); + } else if(mp_cmp_z(b) == MP_EQ) { + return mp_copy(a, c); + } + + if((res = mp_init(&t)) != MP_OKAY) + return res; + if((res = mp_init_copy(&u, a)) != MP_OKAY) + goto U; + if((res = mp_init_copy(&v, b)) != MP_OKAY) + goto V; + + SIGN(&u) = MP_ZPOS; + SIGN(&v) = MP_ZPOS; + + /* Divide out common factors of 2 until at least 1 of a, b is even */ + while(mp_iseven(&u) && mp_iseven(&v)) { + s_mp_div_2(&u); + s_mp_div_2(&v); + ++k; + } + + /* Initialize t */ + if(mp_isodd(&u)) { + if((res = mp_copy(&v, &t)) != MP_OKAY) + goto CLEANUP; + + /* t = -v */ + if(SIGN(&v) == MP_ZPOS) + SIGN(&t) = MP_NEG; + else + SIGN(&t) = MP_ZPOS; + + } else { + if((res = mp_copy(&u, &t)) != MP_OKAY) + goto CLEANUP; + + } + + for(;;) { + while(mp_iseven(&t)) { + s_mp_div_2(&t); + } + + if(mp_cmp_z(&t) == MP_GT) { + if((res = mp_copy(&t, &u)) != MP_OKAY) + goto CLEANUP; + + } else { + if((res = mp_copy(&t, &v)) != MP_OKAY) + goto CLEANUP; + + /* v = -t */ + if(SIGN(&t) == MP_ZPOS) + SIGN(&v) = MP_NEG; + else + SIGN(&v) = MP_ZPOS; + } + + if((res = mp_sub(&u, &v, &t)) != MP_OKAY) + goto CLEANUP; + + if(s_mp_cmp_d(&t, 0) == MP_EQ) + break; + } + + s_mp_2expt(&v, k); /* v = 2^k */ + res = mp_mul(&u, &v, c); /* c = u * v */ + + CLEANUP: + mp_clear(&v); + V: + mp_clear(&u); + U: + mp_clear(&t); + + return res; + +} /* end mp_bgcd() */ + +/* }}} */ + +/* {{{ mp_lcm(a, b, c) */ + +/* We compute the least common multiple using the rule: + + ab = [a, b](a, b) + + ... by computing the product, and dividing out the gcd. + */ + +mp_err mp_lcm(mp_int *a, mp_int *b, mp_int *c) +{ + mp_int gcd, prod; + mp_err res; + + ARGCHK(a != NULL && b != NULL && c != NULL, MP_BADARG); + + /* Set up temporaries */ + if((res = mp_init(&gcd)) != MP_OKAY) + return res; + if((res = mp_init(&prod)) != MP_OKAY) + goto GCD; + + if((res = mp_mul(a, b, &prod)) != MP_OKAY) + goto CLEANUP; + if((res = mp_gcd(a, b, &gcd)) != MP_OKAY) + goto CLEANUP; + + res = mp_div(&prod, &gcd, c, NULL); + + CLEANUP: + mp_clear(&prod); + GCD: + mp_clear(&gcd); + + return res; + +} /* end mp_lcm() */ + +/* }}} */ + +/* {{{ mp_xgcd(a, b, g, x, y) */ + +/* + mp_xgcd(a, b, g, x, y) + + Compute g = (a, b) and values x and y satisfying Bezout's identity + (that is, ax + by = g). This uses the extended binary GCD algorithm + based on the Stein algorithm used for mp_gcd() + */ + +mp_err mp_xgcd(mp_int *a, mp_int *b, mp_int *g, mp_int *x, mp_int *y) +{ + mp_int gx, xc, yc, u, v, A, B, C, D; + mp_int *clean[9]; + mp_err res; + int last = -1; + + if(mp_cmp_z(b) == 0) + return MP_RANGE; + + /* Initialize all these variables we need */ + if((res = mp_init(&u)) != MP_OKAY) goto CLEANUP; + clean[++last] = &u; + if((res = mp_init(&v)) != MP_OKAY) goto CLEANUP; + clean[++last] = &v; + if((res = mp_init(&gx)) != MP_OKAY) goto CLEANUP; + clean[++last] = &gx; + if((res = mp_init(&A)) != MP_OKAY) goto CLEANUP; + clean[++last] = &A; + if((res = mp_init(&B)) != MP_OKAY) goto CLEANUP; + clean[++last] = &B; + if((res = mp_init(&C)) != MP_OKAY) goto CLEANUP; + clean[++last] = &C; + if((res = mp_init(&D)) != MP_OKAY) goto CLEANUP; + clean[++last] = &D; + if((res = mp_init_copy(&xc, a)) != MP_OKAY) goto CLEANUP; + clean[++last] = &xc; + mp_abs(&xc, &xc); + if((res = mp_init_copy(&yc, b)) != MP_OKAY) goto CLEANUP; + clean[++last] = &yc; + mp_abs(&yc, &yc); + + mp_set(&gx, 1); + + /* Divide by two until at least one of them is even */ + while(mp_iseven(&xc) && mp_iseven(&yc)) { + s_mp_div_2(&xc); + s_mp_div_2(&yc); + if((res = s_mp_mul_2(&gx)) != MP_OKAY) + goto CLEANUP; + } + + mp_copy(&xc, &u); + mp_copy(&yc, &v); + mp_set(&A, 1); mp_set(&D, 1); + + /* Loop through binary GCD algorithm */ + for(;;) { + while(mp_iseven(&u)) { + s_mp_div_2(&u); + + if(mp_iseven(&A) && mp_iseven(&B)) { + s_mp_div_2(&A); s_mp_div_2(&B); + } else { + if((res = mp_add(&A, &yc, &A)) != MP_OKAY) goto CLEANUP; + s_mp_div_2(&A); + if((res = mp_sub(&B, &xc, &B)) != MP_OKAY) goto CLEANUP; + s_mp_div_2(&B); + } + } + + while(mp_iseven(&v)) { + s_mp_div_2(&v); + + if(mp_iseven(&C) && mp_iseven(&D)) { + s_mp_div_2(&C); s_mp_div_2(&D); + } else { + if((res = mp_add(&C, &yc, &C)) != MP_OKAY) goto CLEANUP; + s_mp_div_2(&C); + if((res = mp_sub(&D, &xc, &D)) != MP_OKAY) goto CLEANUP; + s_mp_div_2(&D); + } + } + + if(mp_cmp(&u, &v) >= 0) { + if((res = mp_sub(&u, &v, &u)) != MP_OKAY) goto CLEANUP; + if((res = mp_sub(&A, &C, &A)) != MP_OKAY) goto CLEANUP; + if((res = mp_sub(&B, &D, &B)) != MP_OKAY) goto CLEANUP; + + } else { + if((res = mp_sub(&v, &u, &v)) != MP_OKAY) goto CLEANUP; + if((res = mp_sub(&C, &A, &C)) != MP_OKAY) goto CLEANUP; + if((res = mp_sub(&D, &B, &D)) != MP_OKAY) goto CLEANUP; + + } + + /* If we're done, copy results to output */ + if(mp_cmp_z(&u) == 0) { + if(x) + if((res = mp_copy(&C, x)) != MP_OKAY) goto CLEANUP; + + if(y) + if((res = mp_copy(&D, y)) != MP_OKAY) goto CLEANUP; + + if(g) + if((res = mp_mul(&gx, &v, g)) != MP_OKAY) goto CLEANUP; + + break; + } + } + + CLEANUP: + while(last >= 0) + mp_clear(clean[last--]); + + return res; + +} /* end mp_xgcd() */ + +/* }}} */ + +/* {{{ mp_invmod(a, m, c) */ + +/* + mp_invmod(a, m, c) + + Compute c = a^-1 (mod m), if there is an inverse for a (mod m). + This is equivalent to the question of whether (a, m) = 1. If not, + MP_UNDEF is returned, and there is no inverse. + */ + +mp_err mp_invmod(mp_int *a, mp_int *m, mp_int *c) +{ + mp_int g, x; + mp_err res; + + ARGCHK(a && m && c, MP_BADARG); + + if(mp_cmp_z(a) == 0 || mp_cmp_z(m) == 0) + return MP_RANGE; + + if((res = mp_init(&g)) != MP_OKAY) + return res; + if((res = mp_init(&x)) != MP_OKAY) + goto X; + + if((res = mp_xgcd(a, m, &g, &x, NULL)) != MP_OKAY) + goto CLEANUP; + + if(mp_cmp_d(&g, 1) != MP_EQ) { + res = MP_UNDEF; + goto CLEANUP; + } + + res = mp_mod(&x, m, c); + SIGN(c) = SIGN(a); + +CLEANUP: + mp_clear(&x); +X: + mp_clear(&g); + + return res; + +} /* end mp_invmod() */ + +/* }}} */ +#endif /* if MP_NUMTH */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ mp_print(mp, ofp) */ + +#if MP_IOFUNC +/* + mp_print(mp, ofp) + + Print a textual representation of the given mp_int on the output + stream 'ofp'. Output is generated using the internal radix. + */ + +void mp_print(mp_int *mp, FILE *ofp) +{ + int ix; + + if(mp == NULL || ofp == NULL) + return; + + fputc((SIGN(mp) == MP_NEG) ? '-' : '+', ofp); + + for(ix = USED(mp) - 1; ix >= 0; ix--) { + fprintf(ofp, DIGIT_FMT, DIGIT(mp, ix)); + } + +} /* end mp_print() */ + +#endif /* if MP_IOFUNC */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* {{{ More I/O Functions */ + +/* {{{ mp_read_signed_bin(mp, str, len) */ + +/* + mp_read_signed_bin(mp, str, len) + + Read in a raw value (base 256) into the given mp_int + */ + +mp_err mp_read_signed_bin(mp_int *mp, unsigned char *str, int len) +{ + mp_err res; + + ARGCHK(mp != NULL && str != NULL && len > 0, MP_BADARG); + + if((res = mp_read_unsigned_bin(mp, str + 1, len - 1)) == MP_OKAY) { + /* Get sign from first byte */ + if(str[0]) + SIGN(mp) = MP_NEG; + else + SIGN(mp) = MP_ZPOS; + } + + return res; + +} /* end mp_read_signed_bin() */ + +/* }}} */ + +/* {{{ mp_signed_bin_size(mp) */ + +int mp_signed_bin_size(mp_int *mp) +{ + ARGCHK(mp != NULL, 0); + + return mp_unsigned_bin_size(mp) + 1; + +} /* end mp_signed_bin_size() */ + +/* }}} */ + +/* {{{ mp_to_signed_bin(mp, str) */ + +mp_err mp_to_signed_bin(mp_int *mp, unsigned char *str) +{ + ARGCHK(mp != NULL && str != NULL, MP_BADARG); + + /* Caller responsible for allocating enough memory (use mp_raw_size(mp)) */ + str[0] = (char)SIGN(mp); + + return mp_to_unsigned_bin(mp, str + 1); + +} /* end mp_to_signed_bin() */ + +/* }}} */ + +/* {{{ mp_read_unsigned_bin(mp, str, len) */ + +/* + mp_read_unsigned_bin(mp, str, len) + + Read in an unsigned value (base 256) into the given mp_int + */ + +mp_err mp_read_unsigned_bin(mp_int *mp, unsigned char *str, int len) +{ + int ix; + mp_err res; + + ARGCHK(mp != NULL && str != NULL && len > 0, MP_BADARG); + + mp_zero(mp); + + for(ix = 0; ix < len; ix++) { + if((res = s_mp_mul_2d(mp, CHAR_BIT)) != MP_OKAY) + return res; + + if((res = mp_add_d(mp, str[ix], mp)) != MP_OKAY) + return res; + } + + return MP_OKAY; + +} /* end mp_read_unsigned_bin() */ + +/* }}} */ + +/* {{{ mp_unsigned_bin_size(mp) */ + +int mp_unsigned_bin_size(mp_int *mp) +{ + mp_digit topdig; + int count; + + ARGCHK(mp != NULL, 0); + + /* Special case for the value zero */ + if(USED(mp) == 1 && DIGIT(mp, 0) == 0) + return 1; + + count = (USED(mp) - 1) * sizeof(mp_digit); + topdig = DIGIT(mp, USED(mp) - 1); + + while(topdig != 0) { + ++count; + topdig >>= CHAR_BIT; + } + + return count; + +} /* end mp_unsigned_bin_size() */ + +/* }}} */ + +/* {{{ mp_to_unsigned_bin(mp, str) */ + +mp_err mp_to_unsigned_bin(mp_int *mp, unsigned char *str) +{ + mp_digit *dp, *end, d; + unsigned char *spos; + + ARGCHK(mp != NULL && str != NULL, MP_BADARG); + + dp = DIGITS(mp); + end = dp + USED(mp) - 1; + spos = str; + + /* Special case for zero, quick test */ + if(dp == end && *dp == 0) { + *str = '\0'; + return MP_OKAY; + } + + /* Generate digits in reverse order */ + while(dp < end) { + int ix; + + d = *dp; + for(ix = 0; ix < sizeof(mp_digit); ++ix) { + *spos = d & UCHAR_MAX; + d >>= CHAR_BIT; + ++spos; + } + + ++dp; + } + + /* Now handle last digit specially, high order zeroes are not written */ + d = *end; + while(d != 0) { + *spos = d & UCHAR_MAX; + d >>= CHAR_BIT; + ++spos; + } + + /* Reverse everything to get digits in the correct order */ + while(--spos > str) { + unsigned char t = *str; + *str = *spos; + *spos = t; + + ++str; + } + + return MP_OKAY; + +} /* end mp_to_unsigned_bin() */ + +/* }}} */ + +/* {{{ mp_count_bits(mp) */ + +int mp_count_bits(mp_int *mp) +{ + int len; + mp_digit d; + + ARGCHK(mp != NULL, MP_BADARG); + + len = DIGIT_BIT * (USED(mp) - 1); + d = DIGIT(mp, USED(mp) - 1); + + while(d != 0) { + ++len; + d >>= 1; + } + + return len; + +} /* end mp_count_bits() */ + +/* }}} */ + +/* {{{ mp_read_radix(mp, str, radix) */ + +/* + mp_read_radix(mp, str, radix) + + Read an integer from the given string, and set mp to the resulting + value. The input is presumed to be in base 10. Leading non-digit + characters are ignored, and the function reads until a non-digit + character or the end of the string. + */ + +mp_err mp_read_radix(mp_int *mp, unsigned char *str, int radix) +{ + int ix = 0, val = 0; + mp_err res; + mp_sign sig = MP_ZPOS; + + ARGCHK(mp != NULL && str != NULL && radix >= 2 && radix <= MAX_RADIX, + MP_BADARG); + + mp_zero(mp); + + /* Skip leading non-digit characters until a digit or '-' or '+' */ + while(str[ix] && + (s_mp_tovalue(str[ix], radix) < 0) && + str[ix] != '-' && + str[ix] != '+') { + ++ix; + } + + if(str[ix] == '-') { + sig = MP_NEG; + ++ix; + } else if(str[ix] == '+') { + sig = MP_ZPOS; /* this is the default anyway... */ + ++ix; + } + + while((val = s_mp_tovalue(str[ix], radix)) >= 0) { + if((res = s_mp_mul_d(mp, radix)) != MP_OKAY) + return res; + if((res = s_mp_add_d(mp, val)) != MP_OKAY) + return res; + ++ix; + } + + if(s_mp_cmp_d(mp, 0) == MP_EQ) + SIGN(mp) = MP_ZPOS; + else + SIGN(mp) = sig; + + return MP_OKAY; + +} /* end mp_read_radix() */ + +/* }}} */ + +/* {{{ mp_radix_size(mp, radix) */ + +int mp_radix_size(mp_int *mp, int radix) +{ + int len; + ARGCHK(mp != NULL, 0); + + len = s_mp_outlen(mp_count_bits(mp), radix) + 1; /* for NUL terminator */ + + if(mp_cmp_z(mp) < 0) + ++len; /* for sign */ + + return len; + +} /* end mp_radix_size() */ + +/* }}} */ + +/* {{{ mp_value_radix_size(num, qty, radix) */ + +/* num = number of digits + qty = number of bits per digit + radix = target base + + Return the number of digits in the specified radix that would be + needed to express 'num' digits of 'qty' bits each. + */ +int mp_value_radix_size(int num, int qty, int radix) +{ + ARGCHK(num >= 0 && qty > 0 && radix >= 2 && radix <= MAX_RADIX, 0); + + return s_mp_outlen(num * qty, radix); + +} /* end mp_value_radix_size() */ + +/* }}} */ + +/* {{{ mp_toradix(mp, str, radix) */ + +mp_err mp_toradix(mp_int *mp, unsigned char *str, int radix) +{ + int ix, pos = 0; + + ARGCHK(mp != NULL && str != NULL, MP_BADARG); + ARGCHK(radix > 1 && radix <= MAX_RADIX, MP_RANGE); + + if(mp_cmp_z(mp) == MP_EQ) { + str[0] = '0'; + str[1] = '\0'; + } else { + mp_err res; + mp_int tmp; + mp_sign sgn; + mp_digit rem, rdx = (mp_digit)radix; + char ch; + + if((res = mp_init_copy(&tmp, mp)) != MP_OKAY) + return res; + + /* Save sign for later, and take absolute value */ + sgn = SIGN(&tmp); SIGN(&tmp) = MP_ZPOS; + + /* Generate output digits in reverse order */ + while(mp_cmp_z(&tmp) != 0) { + if((res = s_mp_div_d(&tmp, rdx, &rem)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + /* Generate digits, use capital letters */ + ch = s_mp_todigit(rem, radix, 0); + + str[pos++] = ch; + } + + /* Add - sign if original value was negative */ + if(sgn == MP_NEG) + str[pos++] = '-'; + + /* Add trailing NUL to end the string */ + str[pos--] = '\0'; + + /* Reverse the digits and sign indicator */ + ix = 0; + while(ix < pos) { + char tmp = str[ix]; + + str[ix] = str[pos]; + str[pos] = tmp; + ++ix; + --pos; + } + + mp_clear(&tmp); + } + + return MP_OKAY; + +} /* end mp_toradix() */ + +/* }}} */ + +/* {{{ mp_char2value(ch, r) */ + +int mp_char2value(char ch, int r) +{ + return s_mp_tovalue(ch, r); + +} /* end mp_tovalue() */ + +/* }}} */ + +/* }}} */ + +/* {{{ mp_strerror(ec) */ + +/* + mp_strerror(ec) + + Return a string describing the meaning of error code 'ec'. The + string returned is allocated in static memory, so the caller should + not attempt to modify or free the memory associated with this + string. + */ +const char *mp_strerror(mp_err ec) +{ + int aec = (ec < 0) ? -ec : ec; + + /* Code values are negative, so the senses of these comparisons + are accurate */ + if(ec < MP_LAST_CODE || ec > MP_OKAY) { + return mp_err_string[0]; /* unknown error code */ + } else { + return mp_err_string[aec + 1]; + } + +} /* end mp_strerror() */ + +/* }}} */ + +/*========================================================================*/ +/*------------------------------------------------------------------------*/ +/* Static function definitions (internal use only) */ + +/* {{{ Memory management */ + +/* {{{ s_mp_grow(mp, min) */ + +/* Make sure there are at least 'min' digits allocated to mp */ +mp_err s_mp_grow(mp_int *mp, mp_size min) +{ + if(min > ALLOC(mp)) { + mp_digit *tmp; + + /* Set min to next nearest default precision block size */ + min = ((min + (s_mp_defprec - 1)) / s_mp_defprec) * s_mp_defprec; + + if((tmp = s_mp_alloc(min, sizeof(mp_digit))) == NULL) + return MP_MEM; + + s_mp_copy(DIGITS(mp), tmp, USED(mp)); + +#if MP_CRYPTO + s_mp_setz(DIGITS(mp), ALLOC(mp)); +#endif + s_mp_free(DIGITS(mp)); + DIGITS(mp) = tmp; + ALLOC(mp) = min; + } + + return MP_OKAY; + +} /* end s_mp_grow() */ + +/* }}} */ + +/* {{{ s_mp_pad(mp, min) */ + +/* Make sure the used size of mp is at least 'min', growing if needed */ +mp_err s_mp_pad(mp_int *mp, mp_size min) +{ + if(min > USED(mp)) { + mp_err res; + + /* Make sure there is room to increase precision */ + if(min > ALLOC(mp) && (res = s_mp_grow(mp, min)) != MP_OKAY) + return res; + + /* Increase precision; should already be 0-filled */ + USED(mp) = min; + } + + return MP_OKAY; + +} /* end s_mp_pad() */ + +/* }}} */ + +/* {{{ s_mp_setz(dp, count) */ + +#if MP_MACRO == 0 +/* Set 'count' digits pointed to by dp to be zeroes */ +void s_mp_setz(mp_digit *dp, mp_size count) +{ +#if MP_MEMSET == 0 + int ix; + + for(ix = 0; ix < count; ix++) + dp[ix] = 0; +#else + memset(dp, 0, count * sizeof(mp_digit)); +#endif + +} /* end s_mp_setz() */ +#endif + +/* }}} */ + +/* {{{ s_mp_copy(sp, dp, count) */ + +#if MP_MACRO == 0 +/* Copy 'count' digits from sp to dp */ +void s_mp_copy(mp_digit *sp, mp_digit *dp, mp_size count) +{ +#if MP_MEMCPY == 0 + int ix; + + for(ix = 0; ix < count; ix++) + dp[ix] = sp[ix]; +#else + memcpy(dp, sp, count * sizeof(mp_digit)); +#endif + +} /* end s_mp_copy() */ +#endif + +/* }}} */ + +/* {{{ s_mp_alloc(nb, ni) */ + +#if MP_MACRO == 0 +/* Allocate ni records of nb bytes each, and return a pointer to that */ +void *s_mp_alloc(size_t nb, size_t ni) +{ + return calloc(nb, ni); + +} /* end s_mp_alloc() */ +#endif + +/* }}} */ + +/* {{{ s_mp_free(ptr) */ + +#if MP_MACRO == 0 +/* Free the memory pointed to by ptr */ +void s_mp_free(void *ptr) +{ + if(ptr) + free(ptr); + +} /* end s_mp_free() */ +#endif + +/* }}} */ + +/* {{{ s_mp_clamp(mp) */ + +/* Remove leading zeroes from the given value */ +void s_mp_clamp(mp_int *mp) +{ + mp_size du = USED(mp); + mp_digit *zp = DIGITS(mp) + du - 1; + + while(du > 1 && !*zp--) + --du; + + USED(mp) = du; + +} /* end s_mp_clamp() */ + + +/* }}} */ + +/* {{{ s_mp_exch(a, b) */ + +/* Exchange the data for a and b; (b, a) = (a, b) */ +void s_mp_exch(mp_int *a, mp_int *b) +{ + mp_int tmp; + + tmp = *a; + *a = *b; + *b = tmp; + +} /* end s_mp_exch() */ + +/* }}} */ + +/* }}} */ + +/* {{{ Arithmetic helpers */ + +/* {{{ s_mp_lshd(mp, p) */ + +/* + Shift mp leftward by p digits, growing if needed, and zero-filling + the in-shifted digits at the right end. This is a convenient + alternative to multiplication by powers of the radix + */ + +mp_err s_mp_lshd(mp_int *mp, mp_size p) +{ + mp_err res; + mp_size pos; + mp_digit *dp; + int ix; + + if(p == 0) + return MP_OKAY; + + if((res = s_mp_pad(mp, USED(mp) + p)) != MP_OKAY) + return res; + + pos = USED(mp) - 1; + dp = DIGITS(mp); + + /* Shift all the significant figures over as needed */ + for(ix = pos - p; ix >= 0; ix--) + dp[ix + p] = dp[ix]; + + /* Fill the bottom digits with zeroes */ + for(ix = 0; ix < p; ix++) + dp[ix] = 0; + + return MP_OKAY; + +} /* end s_mp_lshd() */ + +/* }}} */ + +/* {{{ s_mp_rshd(mp, p) */ + +/* + Shift mp rightward by p digits. Maintains the invariant that + digits above the precision are all zero. Digits shifted off the + end are lost. Cannot fail. + */ + +void s_mp_rshd(mp_int *mp, mp_size p) +{ + mp_size ix; + mp_digit *dp; + + if(p == 0) + return; + + /* Shortcut when all digits are to be shifted off */ + if(p >= USED(mp)) { + s_mp_setz(DIGITS(mp), ALLOC(mp)); + USED(mp) = 1; + SIGN(mp) = MP_ZPOS; + return; + } + + /* Shift all the significant figures over as needed */ + dp = DIGITS(mp); + for(ix = p; ix < USED(mp); ix++) + dp[ix - p] = dp[ix]; + + /* Fill the top digits with zeroes */ + ix -= p; + while(ix < USED(mp)) + dp[ix++] = 0; + + /* Strip off any leading zeroes */ + s_mp_clamp(mp); + +} /* end s_mp_rshd() */ + +/* }}} */ + +/* {{{ s_mp_div_2(mp) */ + +/* Divide by two -- take advantage of radix properties to do it fast */ +void s_mp_div_2(mp_int *mp) +{ + s_mp_div_2d(mp, 1); + +} /* end s_mp_div_2() */ + +/* }}} */ + +/* {{{ s_mp_mul_2(mp) */ + +mp_err s_mp_mul_2(mp_int *mp) +{ + int ix; + mp_digit kin = 0, kout, *dp = DIGITS(mp); + mp_err res; + + /* Shift digits leftward by 1 bit */ + for(ix = 0; ix < USED(mp); ix++) { + kout = (dp[ix] >> (DIGIT_BIT - 1)) & 1; + dp[ix] = (dp[ix] << 1) | kin; + + kin = kout; + } + + /* Deal with rollover from last digit */ + if(kin) { + if(ix >= ALLOC(mp)) { + if((res = s_mp_grow(mp, ALLOC(mp) + 1)) != MP_OKAY) + return res; + dp = DIGITS(mp); + } + + dp[ix] = kin; + USED(mp) += 1; + } + + return MP_OKAY; + +} /* end s_mp_mul_2() */ + +/* }}} */ + +/* {{{ s_mp_mod_2d(mp, d) */ + +/* + Remainder the integer by 2^d, where d is a number of bits. This + amounts to a bitwise AND of the value, and does not require the full + division code + */ +void s_mp_mod_2d(mp_int *mp, mp_digit d) +{ + unsigned int ndig = (d / DIGIT_BIT), nbit = (d % DIGIT_BIT); + unsigned int ix; + mp_digit dmask, *dp = DIGITS(mp); + + if(ndig >= USED(mp)) + return; + + /* Flush all the bits above 2^d in its digit */ + dmask = (1 << nbit) - 1; + dp[ndig] &= dmask; + + /* Flush all digits above the one with 2^d in it */ + for(ix = ndig + 1; ix < USED(mp); ix++) + dp[ix] = 0; + + s_mp_clamp(mp); + +} /* end s_mp_mod_2d() */ + +/* }}} */ + +/* {{{ s_mp_mul_2d(mp, d) */ + +/* + Multiply by the integer 2^d, where d is a number of bits. This + amounts to a bitwise shift of the value, and does not require the + full multiplication code. + */ +mp_err s_mp_mul_2d(mp_int *mp, mp_digit d) +{ + mp_err res; + mp_digit save, next, mask, *dp; + mp_size used; + int ix; + + if((res = s_mp_lshd(mp, d / DIGIT_BIT)) != MP_OKAY) + return res; + + dp = DIGITS(mp); used = USED(mp); + d %= DIGIT_BIT; + + mask = (1 << d) - 1; + + /* If the shift requires another digit, make sure we've got one to + work with */ + if((dp[used - 1] >> (DIGIT_BIT - d)) & mask) { + if((res = s_mp_grow(mp, used + 1)) != MP_OKAY) + return res; + dp = DIGITS(mp); + } + + /* Do the shifting... */ + save = 0; + for(ix = 0; ix < used; ix++) { + next = (dp[ix] >> (DIGIT_BIT - d)) & mask; + dp[ix] = (dp[ix] << d) | save; + save = next; + } + + /* If, at this point, we have a nonzero carryout into the next + digit, we'll increase the size by one digit, and store it... + */ + if(save) { + dp[used] = save; + USED(mp) += 1; + } + + s_mp_clamp(mp); + return MP_OKAY; + +} /* end s_mp_mul_2d() */ + +/* }}} */ + +/* {{{ s_mp_div_2d(mp, d) */ + +/* + Divide the integer by 2^d, where d is a number of bits. This + amounts to a bitwise shift of the value, and does not require the + full division code (used in Barrett reduction, see below) + */ +void s_mp_div_2d(mp_int *mp, mp_digit d) +{ + int ix; + mp_digit save, next, mask, *dp = DIGITS(mp); + + s_mp_rshd(mp, d / DIGIT_BIT); + d %= DIGIT_BIT; + + mask = (1 << d) - 1; + + save = 0; + for(ix = USED(mp) - 1; ix >= 0; ix--) { + next = dp[ix] & mask; + dp[ix] = (dp[ix] >> d) | (save << (DIGIT_BIT - d)); + save = next; + } + + s_mp_clamp(mp); + +} /* end s_mp_div_2d() */ + +/* }}} */ + +/* {{{ s_mp_norm(a, b) */ + +/* + s_mp_norm(a, b) + + Normalize a and b for division, where b is the divisor. In order + that we might make good guesses for quotient digits, we want the + leading digit of b to be at least half the radix, which we + accomplish by multiplying a and b by a constant. This constant is + returned (so that it can be divided back out of the remainder at the + end of the division process). + + We multiply by the smallest power of 2 that gives us a leading digit + at least half the radix. By choosing a power of 2, we simplify the + multiplication and division steps to simple shifts. + */ +mp_digit s_mp_norm(mp_int *a, mp_int *b) +{ + mp_digit t, d = 0; + + t = DIGIT(b, USED(b) - 1); + while(t < (RADIX / 2)) { + t <<= 1; + ++d; + } + + if(d != 0) { + s_mp_mul_2d(a, d); + s_mp_mul_2d(b, d); + } + + return d; + +} /* end s_mp_norm() */ + +/* }}} */ + +/* }}} */ + +/* {{{ Primitive digit arithmetic */ + +/* {{{ s_mp_add_d(mp, d) */ + +/* Add d to |mp| in place */ +mp_err s_mp_add_d(mp_int *mp, mp_digit d) /* unsigned digit addition */ +{ + mp_word w, k = 0; + mp_size ix = 1, used = USED(mp); + mp_digit *dp = DIGITS(mp); + + w = dp[0] + d; + dp[0] = ACCUM(w); + k = CARRYOUT(w); + + while(ix < used && k) { + w = dp[ix] + k; + dp[ix] = ACCUM(w); + k = CARRYOUT(w); + ++ix; + } + + if(k != 0) { + mp_err res; + + if((res = s_mp_pad(mp, USED(mp) + 1)) != MP_OKAY) + return res; + + DIGIT(mp, ix) = k; + } + + return MP_OKAY; + +} /* end s_mp_add_d() */ + +/* }}} */ + +/* {{{ s_mp_sub_d(mp, d) */ + +/* Subtract d from |mp| in place, assumes |mp| > d */ +mp_err s_mp_sub_d(mp_int *mp, mp_digit d) /* unsigned digit subtract */ +{ + mp_word w, b = 0; + mp_size ix = 1, used = USED(mp); + mp_digit *dp = DIGITS(mp); + + /* Compute initial subtraction */ + w = (RADIX + dp[0]) - d; + b = CARRYOUT(w) ? 0 : 1; + dp[0] = ACCUM(w); + + /* Propagate borrows leftward */ + while(b && ix < used) { + w = (RADIX + dp[ix]) - b; + b = CARRYOUT(w) ? 0 : 1; + dp[ix] = ACCUM(w); + ++ix; + } + + /* Remove leading zeroes */ + s_mp_clamp(mp); + + /* If we have a borrow out, it's a violation of the input invariant */ + if(b) + return MP_RANGE; + else + return MP_OKAY; + +} /* end s_mp_sub_d() */ + +/* }}} */ + +/* {{{ s_mp_mul_d(a, d) */ + +/* Compute a = a * d, single digit multiplication */ +mp_err s_mp_mul_d(mp_int *a, mp_digit d) +{ + mp_word w, k = 0; + mp_size ix, max; + mp_err res; + mp_digit *dp = DIGITS(a); + + /* + Single-digit multiplication will increase the precision of the + output by at most one digit. However, we can detect when this + will happen -- if the high-order digit of a, times d, gives a + two-digit result, then the precision of the result will increase; + otherwise it won't. We use this fact to avoid calling s_mp_pad() + unless absolutely necessary. + */ + max = USED(a); + w = dp[max - 1] * d; + if(CARRYOUT(w) != 0) { + if((res = s_mp_pad(a, max + 1)) != MP_OKAY) + return res; + dp = DIGITS(a); + } + + for(ix = 0; ix < max; ix++) { + w = (dp[ix] * d) + k; + dp[ix] = ACCUM(w); + k = CARRYOUT(w); + } + + /* If there is a precision increase, take care of it here; the above + test guarantees we have enough storage to do this safely. + */ + if(k) { + dp[max] = k; + USED(a) = max + 1; + } + + s_mp_clamp(a); + + return MP_OKAY; + +} /* end s_mp_mul_d() */ + +/* }}} */ + +/* {{{ s_mp_div_d(mp, d, r) */ + +/* + s_mp_div_d(mp, d, r) + + Compute the quotient mp = mp / d and remainder r = mp mod d, for a + single digit d. If r is null, the remainder will be discarded. + */ + +mp_err s_mp_div_d(mp_int *mp, mp_digit d, mp_digit *r) +{ + mp_word w = 0, t; + mp_int quot; + mp_err res; + mp_digit *dp = DIGITS(mp), *qp; + int ix; + + if(d == 0) + return MP_RANGE; + + /* Make room for the quotient */ + if((res = mp_init_size(", USED(mp))) != MP_OKAY) + return res; + + USED(") = USED(mp); /* so clamping will work below */ + qp = DIGITS("); + + /* Divide without subtraction */ + for(ix = USED(mp) - 1; ix >= 0; ix--) { + w = (w << DIGIT_BIT) | dp[ix]; + + if(w >= d) { + t = w / d; + w = w % d; + } else { + t = 0; + } + + qp[ix] = t; + } + + /* Deliver the remainder, if desired */ + if(r) + *r = w; + + s_mp_clamp("); + mp_exch(", mp); + mp_clear("); + + return MP_OKAY; + +} /* end s_mp_div_d() */ + +/* }}} */ + +/* }}} */ + +/* {{{ Primitive full arithmetic */ + +/* {{{ s_mp_add(a, b) */ + +/* Compute a = |a| + |b| */ +mp_err s_mp_add(mp_int *a, mp_int *b) /* magnitude addition */ +{ + mp_word w = 0; + mp_digit *pa, *pb; + mp_size ix, used = USED(b); + mp_err res; + + /* Make sure a has enough precision for the output value */ + if((used > USED(a)) && (res = s_mp_pad(a, used)) != MP_OKAY) + return res; + + /* + Add up all digits up to the precision of b. If b had initially + the same precision as a, or greater, we took care of it by the + padding step above, so there is no problem. If b had initially + less precision, we'll have to make sure the carry out is duly + propagated upward among the higher-order digits of the sum. + */ + pa = DIGITS(a); + pb = DIGITS(b); + for(ix = 0; ix < used; ++ix) { + w += *pa + *pb++; + *pa++ = ACCUM(w); + w = CARRYOUT(w); + } + + /* If we run out of 'b' digits before we're actually done, make + sure the carries get propagated upward... + */ + used = USED(a); + while(w && ix < used) { + w += *pa; + *pa++ = ACCUM(w); + w = CARRYOUT(w); + ++ix; + } + + /* If there's an overall carry out, increase precision and include + it. We could have done this initially, but why touch the memory + allocator unless we're sure we have to? + */ + if(w) { + if((res = s_mp_pad(a, used + 1)) != MP_OKAY) + return res; + + DIGIT(a, ix) = w; /* pa may not be valid after s_mp_pad() call */ + } + + return MP_OKAY; + +} /* end s_mp_add() */ + +/* }}} */ + +/* {{{ s_mp_sub(a, b) */ + +/* Compute a = |a| - |b|, assumes |a| >= |b| */ +mp_err s_mp_sub(mp_int *a, mp_int *b) /* magnitude subtract */ +{ + mp_word w = 0; + mp_digit *pa, *pb; + mp_size ix, used = USED(b); + + /* + Subtract and propagate borrow. Up to the precision of b, this + accounts for the digits of b; after that, we just make sure the + carries get to the right place. This saves having to pad b out to + the precision of a just to make the loops work right... + */ + pa = DIGITS(a); + pb = DIGITS(b); + + for(ix = 0; ix < used; ++ix) { + w = (RADIX + *pa) - w - *pb++; + *pa++ = ACCUM(w); + w = CARRYOUT(w) ? 0 : 1; + } + + used = USED(a); + while(ix < used) { + w = RADIX + *pa - w; + *pa++ = ACCUM(w); + w = CARRYOUT(w) ? 0 : 1; + ++ix; + } + + /* Clobber any leading zeroes we created */ + s_mp_clamp(a); + + /* + If there was a borrow out, then |b| > |a| in violation + of our input invariant. We've already done the work, + but we'll at least complain about it... + */ + if(w) + return MP_RANGE; + else + return MP_OKAY; + +} /* end s_mp_sub() */ + +/* }}} */ + +mp_err s_mp_reduce(mp_int *x, mp_int *m, mp_int *mu) +{ + mp_int q; + mp_err res; + mp_size um = USED(m); + + if((res = mp_init_copy(&q, x)) != MP_OKAY) + return res; + + s_mp_rshd(&q, um - 1); /* q1 = x / b^(k-1) */ + s_mp_mul(&q, mu); /* q2 = q1 * mu */ + s_mp_rshd(&q, um + 1); /* q3 = q2 / b^(k+1) */ + + /* x = x mod b^(k+1), quick (no division) */ + s_mp_mod_2d(x, (mp_digit)(DIGIT_BIT * (um + 1))); + + /* q = q * m mod b^(k+1), quick (no division), uses the short multiplier */ +#ifndef SHRT_MUL + s_mp_mul(&q, m); + s_mp_mod_2d(&q, (mp_digit)(DIGIT_BIT * (um + 1))); +#else + s_mp_mul_dig(&q, m, um + 1); +#endif + + /* x = x - q */ + if((res = mp_sub(x, &q, x)) != MP_OKAY) + goto CLEANUP; + + /* If x < 0, add b^(k+1) to it */ + if(mp_cmp_z(x) < 0) { + mp_set(&q, 1); + if((res = s_mp_lshd(&q, um + 1)) != MP_OKAY) + goto CLEANUP; + if((res = mp_add(x, &q, x)) != MP_OKAY) + goto CLEANUP; + } + + /* Back off if it's too big */ + while(mp_cmp(x, m) >= 0) { + if((res = s_mp_sub(x, m)) != MP_OKAY) + break; + } + + CLEANUP: + mp_clear(&q); + + return res; + +} /* end s_mp_reduce() */ + + + +/* {{{ s_mp_mul(a, b) */ + +/* Compute a = |a| * |b| */ +mp_err s_mp_mul(mp_int *a, mp_int *b) +{ + mp_word w, k = 0; + mp_int tmp; + mp_err res; + mp_size ix, jx, ua = USED(a), ub = USED(b); + mp_digit *pa, *pb, *pt, *pbt; + + if((res = mp_init_size(&tmp, ua + ub)) != MP_OKAY) + return res; + + /* This has the effect of left-padding with zeroes... */ + USED(&tmp) = ua + ub; + + /* We're going to need the base value each iteration */ + pbt = DIGITS(&tmp); + + /* Outer loop: Digits of b */ + + pb = DIGITS(b); + for(ix = 0; ix < ub; ++ix, ++pb) { + if(*pb == 0) + continue; + + /* Inner product: Digits of a */ + pa = DIGITS(a); + for(jx = 0; jx < ua; ++jx, ++pa) { + pt = pbt + ix + jx; + w = *pb * *pa + k + *pt; + *pt = ACCUM(w); + k = CARRYOUT(w); + } + + pbt[ix + jx] = k; + k = 0; + } + + s_mp_clamp(&tmp); + s_mp_exch(&tmp, a); + + mp_clear(&tmp); + + return MP_OKAY; + +} /* end s_mp_mul() */ + +/* }}} */ + +/* {{{ s_mp_kmul(a, b, out, len) */ + +#if 0 +void s_mp_kmul(mp_digit *a, mp_digit *b, mp_digit *out, mp_size len) +{ + mp_word w, k = 0; + mp_size ix, jx; + mp_digit *pa, *pt; + + for(ix = 0; ix < len; ++ix, ++b) { + if(*b == 0) + continue; + + pa = a; + for(jx = 0; jx < len; ++jx, ++pa) { + pt = out + ix + jx; + w = *b * *pa + k + *pt; + *pt = ACCUM(w); + k = CARRYOUT(w); + } + + out[ix + jx] = k; + k = 0; + } + +} /* end s_mp_kmul() */ +#endif + +/* }}} */ + +/* {{{ s_mp_sqr(a) */ + +/* + Computes the square of a, in place. This can be done more + efficiently than a general multiplication, because many of the + computation steps are redundant when squaring. The inner product + step is a bit more complicated, but we save a fair number of + iterations of the multiplication loop. + */ +#if MP_SQUARE +mp_err s_mp_sqr(mp_int *a) +{ + mp_word w, k = 0; + mp_int tmp; + mp_err res; + mp_size ix, jx, kx, used = USED(a); + mp_digit *pa1, *pa2, *pt, *pbt; + + if((res = mp_init_size(&tmp, 2 * used)) != MP_OKAY) + return res; + + /* Left-pad with zeroes */ + USED(&tmp) = 2 * used; + + /* We need the base value each time through the loop */ + pbt = DIGITS(&tmp); + + pa1 = DIGITS(a); + for(ix = 0; ix < used; ++ix, ++pa1) { + if(*pa1 == 0) + continue; + + w = DIGIT(&tmp, ix + ix) + (*pa1 * *pa1); + + pbt[ix + ix] = ACCUM(w); + k = CARRYOUT(w); + + /* + The inner product is computed as: + + (C, S) = t[i,j] + 2 a[i] a[j] + C + + This can overflow what can be represented in an mp_word, and + since C arithmetic does not provide any way to check for + overflow, we have to check explicitly for overflow conditions + before they happen. + */ + for(jx = ix + 1, pa2 = DIGITS(a) + jx; jx < used; ++jx, ++pa2) { + mp_word u = 0, v; + + /* Store this in a temporary to avoid indirections later */ + pt = pbt + ix + jx; + + /* Compute the multiplicative step */ + w = *pa1 * *pa2; + + /* If w is more than half MP_WORD_MAX, the doubling will + overflow, and we need to record a carry out into the next + word */ + u = (w >> (MP_WORD_BIT - 1)) & 1; + + /* Double what we've got, overflow will be ignored as defined + for C arithmetic (we've already noted if it is to occur) + */ + w *= 2; + + /* Compute the additive step */ + v = *pt + k; + + /* If we do not already have an overflow carry, check to see + if the addition will cause one, and set the carry out if so + */ + u |= ((MP_WORD_MAX - v) < w); + + /* Add in the rest, again ignoring overflow */ + w += v; + + /* Set the i,j digit of the output */ + *pt = ACCUM(w); + + /* Save carry information for the next iteration of the loop. + This is why k must be an mp_word, instead of an mp_digit */ + k = CARRYOUT(w) | (u << DIGIT_BIT); + + } /* for(jx ...) */ + + /* Set the last digit in the cycle and reset the carry */ + k = DIGIT(&tmp, ix + jx) + k; + pbt[ix + jx] = ACCUM(k); + k = CARRYOUT(k); + + /* If we are carrying out, propagate the carry to the next digit + in the output. This may cascade, so we have to be somewhat + circumspect -- but we will have enough precision in the output + that we won't overflow + */ + kx = 1; + while(k) { + k = pbt[ix + jx + kx] + 1; + pbt[ix + jx + kx] = ACCUM(k); + k = CARRYOUT(k); + ++kx; + } + } /* for(ix ...) */ + + s_mp_clamp(&tmp); + s_mp_exch(&tmp, a); + + mp_clear(&tmp); + + return MP_OKAY; + +} /* end s_mp_sqr() */ +#endif + +/* }}} */ + +/* {{{ s_mp_div(a, b) */ + +/* + s_mp_div(a, b) + + Compute a = a / b and b = a mod b. Assumes b > a. + */ + +mp_err s_mp_div(mp_int *a, mp_int *b) +{ + mp_int quot, rem, t; + mp_word q; + mp_err res; + mp_digit d; + int ix; + + if(mp_cmp_z(b) == 0) + return MP_RANGE; + + /* Shortcut if b is power of two */ + if((ix = s_mp_ispow2(b)) >= 0) { + mp_copy(a, b); /* need this for remainder */ + s_mp_div_2d(a, (mp_digit)ix); + s_mp_mod_2d(b, (mp_digit)ix); + + return MP_OKAY; + } + + /* Allocate space to store the quotient */ + if((res = mp_init_size(", USED(a))) != MP_OKAY) + return res; + + /* A working temporary for division */ + if((res = mp_init_size(&t, USED(a))) != MP_OKAY) + goto T; + + /* Allocate space for the remainder */ + if((res = mp_init_size(&rem, USED(a))) != MP_OKAY) + goto REM; + + /* Normalize to optimize guessing */ + d = s_mp_norm(a, b); + + /* Perform the division itself...woo! */ + ix = USED(a) - 1; + + while(ix >= 0) { + /* Find a partial substring of a which is at least b */ + while(s_mp_cmp(&rem, b) < 0 && ix >= 0) { + if((res = s_mp_lshd(&rem, 1)) != MP_OKAY) + goto CLEANUP; + + if((res = s_mp_lshd(", 1)) != MP_OKAY) + goto CLEANUP; + + DIGIT(&rem, 0) = DIGIT(a, ix); + s_mp_clamp(&rem); + --ix; + } + + /* If we didn't find one, we're finished dividing */ + if(s_mp_cmp(&rem, b) < 0) + break; + + /* Compute a guess for the next quotient digit */ + q = DIGIT(&rem, USED(&rem) - 1); + if(q <= DIGIT(b, USED(b) - 1) && USED(&rem) > 1) + q = (q << DIGIT_BIT) | DIGIT(&rem, USED(&rem) - 2); + + q /= DIGIT(b, USED(b) - 1); + + /* The guess can be as much as RADIX + 1 */ + if(q >= RADIX) + q = RADIX - 1; + + /* See what that multiplies out to */ + mp_copy(b, &t); + if((res = s_mp_mul_d(&t, q)) != MP_OKAY) + goto CLEANUP; + + /* + If it's too big, back it off. We should not have to do this + more than once, or, in rare cases, twice. Knuth describes a + method by which this could be reduced to a maximum of once, but + I didn't implement that here. + */ + while(s_mp_cmp(&t, &rem) > 0) { + --q; + s_mp_sub(&t, b); + } + + /* At this point, q should be the right next digit */ + if((res = s_mp_sub(&rem, &t)) != MP_OKAY) + goto CLEANUP; + + /* + Include the digit in the quotient. We allocated enough memory + for any quotient we could ever possibly get, so we should not + have to check for failures here + */ + DIGIT(", 0) = q; + } + + /* Denormalize remainder */ + if(d != 0) + s_mp_div_2d(&rem, d); + + s_mp_clamp("); + s_mp_clamp(&rem); + + /* Copy quotient back to output */ + s_mp_exch(", a); + + /* Copy remainder back to output */ + s_mp_exch(&rem, b); + +CLEANUP: + mp_clear(&rem); +REM: + mp_clear(&t); +T: + mp_clear("); + + return res; + +} /* end s_mp_div() */ + +/* }}} */ + +/* {{{ s_mp_2expt(a, k) */ + +mp_err s_mp_2expt(mp_int *a, mp_digit k) +{ + mp_err res; + mp_size dig, bit; + + dig = k / DIGIT_BIT; + bit = k % DIGIT_BIT; + + mp_zero(a); + if((res = s_mp_pad(a, dig + 1)) != MP_OKAY) + return res; + + DIGIT(a, dig) |= (1 << bit); + + return MP_OKAY; + +} /* end s_mp_2expt() */ + +/* }}} */ + + +/* }}} */ + +/* }}} */ + +/* {{{ Primitive comparisons */ + +/* {{{ s_mp_cmp(a, b) */ + +/* Compare |a| <=> |b|, return 0 if equal, <0 if a0 if a>b */ +int s_mp_cmp(mp_int *a, mp_int *b) +{ + mp_size ua = USED(a), ub = USED(b); + + if(ua > ub) + return MP_GT; + else if(ua < ub) + return MP_LT; + else { + int ix = ua - 1; + mp_digit *ap = DIGITS(a) + ix, *bp = DIGITS(b) + ix; + + while(ix >= 0) { + if(*ap > *bp) + return MP_GT; + else if(*ap < *bp) + return MP_LT; + + --ap; --bp; --ix; + } + + return MP_EQ; + } + +} /* end s_mp_cmp() */ + +/* }}} */ + +/* {{{ s_mp_cmp_d(a, d) */ + +/* Compare |a| <=> d, return 0 if equal, <0 if a0 if a>d */ +int s_mp_cmp_d(mp_int *a, mp_digit d) +{ + mp_size ua = USED(a); + mp_digit *ap = DIGITS(a); + + if(ua > 1) + return MP_GT; + + if(*ap < d) + return MP_LT; + else if(*ap > d) + return MP_GT; + else + return MP_EQ; + +} /* end s_mp_cmp_d() */ + +/* }}} */ + +/* {{{ s_mp_ispow2(v) */ + +/* + Returns -1 if the value is not a power of two; otherwise, it returns + k such that v = 2^k, i.e. lg(v). + */ +int s_mp_ispow2(mp_int *v) +{ + mp_digit d, *dp; + mp_size uv = USED(v); + int extra = 0, ix; + + d = DIGIT(v, uv - 1); /* most significant digit of v */ + + while(d && ((d & 1) == 0)) { + d >>= 1; + ++extra; + } + + if(d == 1) { + ix = uv - 2; + dp = DIGITS(v) + ix; + + while(ix >= 0) { + if(*dp) + return -1; /* not a power of two */ + + --dp; --ix; + } + + return ((uv - 1) * DIGIT_BIT) + extra; + } + + return -1; + +} /* end s_mp_ispow2() */ + +/* }}} */ + +/* {{{ s_mp_ispow2d(d) */ + +int s_mp_ispow2d(mp_digit d) +{ + int pow = 0; + + while((d & 1) == 0) { + ++pow; d >>= 1; + } + + if(d == 1) + return pow; + + return -1; + +} /* end s_mp_ispow2d() */ + +/* }}} */ + +/* }}} */ + +/* {{{ Primitive I/O helpers */ + +/* {{{ s_mp_tovalue(ch, r) */ + +/* + Convert the given character to its digit value, in the given radix. + If the given character is not understood in the given radix, -1 is + returned. Otherwise the digit's numeric value is returned. + + The results will be odd if you use a radix < 2 or > 62, you are + expected to know what you're up to. + */ +int s_mp_tovalue(char ch, int r) +{ + int val, xch; + + if(r > 36) + xch = ch; + else + xch = toupper(ch); + + if(isdigit(xch)) + val = xch - '0'; + else if(isupper(xch)) + val = xch - 'A' + 10; + else if(islower(xch)) + val = xch - 'a' + 36; + else if(xch == '+') + val = 62; + else if(xch == '/') + val = 63; + else + return -1; + + if(val < 0 || val >= r) + return -1; + + return val; + +} /* end s_mp_tovalue() */ + +/* }}} */ + +/* {{{ s_mp_todigit(val, r, low) */ + +/* + Convert val to a radix-r digit, if possible. If val is out of range + for r, returns zero. Otherwise, returns an ASCII character denoting + the value in the given radix. + + The results may be odd if you use a radix < 2 or > 64, you are + expected to know what you're doing. + */ + +char s_mp_todigit(int val, int r, int low) +{ + char ch; + + if(val < 0 || val >= r) + return 0; + + ch = s_dmap_1[val]; + + if(r <= 36 && low) + ch = tolower(ch); + + return ch; + +} /* end s_mp_todigit() */ + +/* }}} */ + +/* {{{ s_mp_outlen(bits, radix) */ + +/* + Return an estimate for how long a string is needed to hold a radix + r representation of a number with 'bits' significant bits. + + Does not include space for a sign or a NUL terminator. + */ +int s_mp_outlen(int bits, int r) +{ + return (int)((double)bits * LOG_V_2(r)); + +} /* end s_mp_outlen() */ + +/* }}} */ + +/* }}} */ + +/*------------------------------------------------------------------------*/ +/* HERE THERE BE DRAGONS */ +/* crc==4242132123, version==2, Sat Feb 02 06:43:52 2002 */ diff --git a/libtommath/mtest/mpi.h b/libtommath/mtest/mpi.h new file mode 100644 index 0000000..b7a8cb5 --- /dev/null +++ b/libtommath/mtest/mpi.h @@ -0,0 +1,227 @@ +/* + mpi.h + + by Michael J. Fromberger + Copyright (C) 1998 Michael J. Fromberger, All Rights Reserved + + Arbitrary precision integer arithmetic library + + $Id: mpi.h,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ + */ + +#ifndef _H_MPI_ +#define _H_MPI_ + +#include "mpi-config.h" + +#define MP_LT -1 +#define MP_EQ 0 +#define MP_GT 1 + +#if MP_DEBUG +#undef MP_IOFUNC +#define MP_IOFUNC 1 +#endif + +#if MP_IOFUNC +#include +#include +#endif + +#include + +#define MP_NEG 1 +#define MP_ZPOS 0 + +/* Included for compatibility... */ +#define NEG MP_NEG +#define ZPOS MP_ZPOS + +#define MP_OKAY 0 /* no error, all is well */ +#define MP_YES 0 /* yes (boolean result) */ +#define MP_NO -1 /* no (boolean result) */ +#define MP_MEM -2 /* out of memory */ +#define MP_RANGE -3 /* argument out of range */ +#define MP_BADARG -4 /* invalid parameter */ +#define MP_UNDEF -5 /* answer is undefined */ +#define MP_LAST_CODE MP_UNDEF + +#include "mpi-types.h" + +/* Included for compatibility... */ +#define DIGIT_BIT MP_DIGIT_BIT +#define DIGIT_MAX MP_DIGIT_MAX + +/* Macros for accessing the mp_int internals */ +#define SIGN(MP) ((MP)->sign) +#define USED(MP) ((MP)->used) +#define ALLOC(MP) ((MP)->alloc) +#define DIGITS(MP) ((MP)->dp) +#define DIGIT(MP,N) (MP)->dp[(N)] + +#if MP_ARGCHK == 1 +#define ARGCHK(X,Y) {if(!(X)){return (Y);}} +#elif MP_ARGCHK == 2 +#include +#define ARGCHK(X,Y) assert(X) +#else +#define ARGCHK(X,Y) /* */ +#endif + +/* This defines the maximum I/O base (minimum is 2) */ +#define MAX_RADIX 64 + +typedef struct { + mp_sign sign; /* sign of this quantity */ + mp_size alloc; /* how many digits allocated */ + mp_size used; /* how many digits used */ + mp_digit *dp; /* the digits themselves */ +} mp_int; + +/*------------------------------------------------------------------------*/ +/* Default precision */ + +unsigned int mp_get_prec(void); +void mp_set_prec(unsigned int prec); + +/*------------------------------------------------------------------------*/ +/* Memory management */ + +mp_err mp_init(mp_int *mp); +mp_err mp_init_array(mp_int mp[], int count); +mp_err mp_init_size(mp_int *mp, mp_size prec); +mp_err mp_init_copy(mp_int *mp, mp_int *from); +mp_err mp_copy(mp_int *from, mp_int *to); +void mp_exch(mp_int *mp1, mp_int *mp2); +void mp_clear(mp_int *mp); +void mp_clear_array(mp_int mp[], int count); +void mp_zero(mp_int *mp); +void mp_set(mp_int *mp, mp_digit d); +mp_err mp_set_int(mp_int *mp, long z); +mp_err mp_shrink(mp_int *a); + + +/*------------------------------------------------------------------------*/ +/* Single digit arithmetic */ + +mp_err mp_add_d(mp_int *a, mp_digit d, mp_int *b); +mp_err mp_sub_d(mp_int *a, mp_digit d, mp_int *b); +mp_err mp_mul_d(mp_int *a, mp_digit d, mp_int *b); +mp_err mp_mul_2(mp_int *a, mp_int *c); +mp_err mp_div_d(mp_int *a, mp_digit d, mp_int *q, mp_digit *r); +mp_err mp_div_2(mp_int *a, mp_int *c); +mp_err mp_expt_d(mp_int *a, mp_digit d, mp_int *c); + +/*------------------------------------------------------------------------*/ +/* Sign manipulations */ + +mp_err mp_abs(mp_int *a, mp_int *b); +mp_err mp_neg(mp_int *a, mp_int *b); + +/*------------------------------------------------------------------------*/ +/* Full arithmetic */ + +mp_err mp_add(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_sub(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_mul(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_mul_2d(mp_int *a, mp_digit d, mp_int *c); +#if MP_SQUARE +mp_err mp_sqr(mp_int *a, mp_int *b); +#else +#define mp_sqr(a, b) mp_mul(a, a, b) +#endif +mp_err mp_div(mp_int *a, mp_int *b, mp_int *q, mp_int *r); +mp_err mp_div_2d(mp_int *a, mp_digit d, mp_int *q, mp_int *r); +mp_err mp_expt(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_2expt(mp_int *a, mp_digit k); +mp_err mp_sqrt(mp_int *a, mp_int *b); + +/*------------------------------------------------------------------------*/ +/* Modular arithmetic */ + +#if MP_MODARITH +mp_err mp_mod(mp_int *a, mp_int *m, mp_int *c); +mp_err mp_mod_d(mp_int *a, mp_digit d, mp_digit *c); +mp_err mp_addmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c); +mp_err mp_submod(mp_int *a, mp_int *b, mp_int *m, mp_int *c); +mp_err mp_mulmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c); +#if MP_SQUARE +mp_err mp_sqrmod(mp_int *a, mp_int *m, mp_int *c); +#else +#define mp_sqrmod(a, m, c) mp_mulmod(a, a, m, c) +#endif +mp_err mp_exptmod(mp_int *a, mp_int *b, mp_int *m, mp_int *c); +mp_err mp_exptmod_d(mp_int *a, mp_digit d, mp_int *m, mp_int *c); +#endif /* MP_MODARITH */ + +/*------------------------------------------------------------------------*/ +/* Comparisons */ + +int mp_cmp_z(mp_int *a); +int mp_cmp_d(mp_int *a, mp_digit d); +int mp_cmp(mp_int *a, mp_int *b); +int mp_cmp_mag(mp_int *a, mp_int *b); +int mp_cmp_int(mp_int *a, long z); +int mp_isodd(mp_int *a); +int mp_iseven(mp_int *a); + +/*------------------------------------------------------------------------*/ +/* Number theoretic */ + +#if MP_NUMTH +mp_err mp_gcd(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_lcm(mp_int *a, mp_int *b, mp_int *c); +mp_err mp_xgcd(mp_int *a, mp_int *b, mp_int *g, mp_int *x, mp_int *y); +mp_err mp_invmod(mp_int *a, mp_int *m, mp_int *c); +#endif /* end MP_NUMTH */ + +/*------------------------------------------------------------------------*/ +/* Input and output */ + +#if MP_IOFUNC +void mp_print(mp_int *mp, FILE *ofp); +#endif /* end MP_IOFUNC */ + +/*------------------------------------------------------------------------*/ +/* Base conversion */ + +#define BITS 1 +#define BYTES CHAR_BIT + +mp_err mp_read_signed_bin(mp_int *mp, unsigned char *str, int len); +int mp_signed_bin_size(mp_int *mp); +mp_err mp_to_signed_bin(mp_int *mp, unsigned char *str); + +mp_err mp_read_unsigned_bin(mp_int *mp, unsigned char *str, int len); +int mp_unsigned_bin_size(mp_int *mp); +mp_err mp_to_unsigned_bin(mp_int *mp, unsigned char *str); + +int mp_count_bits(mp_int *mp); + +#if MP_COMPAT_MACROS +#define mp_read_raw(mp, str, len) mp_read_signed_bin((mp), (str), (len)) +#define mp_raw_size(mp) mp_signed_bin_size(mp) +#define mp_toraw(mp, str) mp_to_signed_bin((mp), (str)) +#define mp_read_mag(mp, str, len) mp_read_unsigned_bin((mp), (str), (len)) +#define mp_mag_size(mp) mp_unsigned_bin_size(mp) +#define mp_tomag(mp, str) mp_to_unsigned_bin((mp), (str)) +#endif + +mp_err mp_read_radix(mp_int *mp, unsigned char *str, int radix); +int mp_radix_size(mp_int *mp, int radix); +int mp_value_radix_size(int num, int qty, int radix); +mp_err mp_toradix(mp_int *mp, unsigned char *str, int radix); + +int mp_char2value(char ch, int r); + +#define mp_tobinary(M, S) mp_toradix((M), (S), 2) +#define mp_tooctal(M, S) mp_toradix((M), (S), 8) +#define mp_todecimal(M, S) mp_toradix((M), (S), 10) +#define mp_tohex(M, S) mp_toradix((M), (S), 16) + +/*------------------------------------------------------------------------*/ +/* Error strings */ + +const char *mp_strerror(mp_err ec); + +#endif /* end _H_MPI_ */ diff --git a/libtommath/mtest/mtest.c b/libtommath/mtest/mtest.c new file mode 100644 index 0000000..d46f456 --- /dev/null +++ b/libtommath/mtest/mtest.c @@ -0,0 +1,304 @@ +/* makes a bignum test harness with NUM tests per operation + * + * the output is made in the following format [one parameter per line] + +operation +operand1 +operand2 +[... operandN] +result1 +result2 +[... resultN] + +So for example "a * b mod n" would be + +mulmod +a +b +n +a*b mod n + +e.g. if a=3, b=4 n=11 then + +mulmod +3 +4 +11 +1 + + */ + +#ifdef MP_8BIT +#define THE_MASK 127 +#else +#define THE_MASK 32767 +#endif + +#include +#include +#include +#include "mpi.c" + +FILE *rng; + +void rand_num(mp_int *a) +{ + int n, size; + unsigned char buf[2048]; + + size = 1 + ((fgetc(rng)<<8) + fgetc(rng)) % 101; + buf[0] = (fgetc(rng)&1)?1:0; + fread(buf+1, 1, size, rng); + while (buf[1] == 0) buf[1] = fgetc(rng); + mp_read_raw(a, buf, 1+size); +} + +void rand_num2(mp_int *a) +{ + int n, size; + unsigned char buf[2048]; + + size = 10 + ((fgetc(rng)<<8) + fgetc(rng)) % 101; + buf[0] = (fgetc(rng)&1)?1:0; + fread(buf+1, 1, size, rng); + while (buf[1] == 0) buf[1] = fgetc(rng); + mp_read_raw(a, buf, 1+size); +} + +#define mp_to64(a, b) mp_toradix(a, b, 64) + +int main(void) +{ + int n, tmp; + mp_int a, b, c, d, e; + clock_t t1; + char buf[4096]; + + mp_init(&a); + mp_init(&b); + mp_init(&c); + mp_init(&d); + mp_init(&e); + + + /* initial (2^n - 1)^2 testing, makes sure the comba multiplier works [it has the new carry code] */ +/* + mp_set(&a, 1); + for (n = 1; n < 8192; n++) { + mp_mul(&a, &a, &c); + printf("mul\n"); + mp_to64(&a, buf); + printf("%s\n%s\n", buf, buf); + mp_to64(&c, buf); + printf("%s\n", buf); + + mp_add_d(&a, 1, &a); + mp_mul_2(&a, &a); + mp_sub_d(&a, 1, &a); + } +*/ + + rng = fopen("/dev/urandom", "rb"); + if (rng == NULL) { + rng = fopen("/dev/random", "rb"); + if (rng == NULL) { + fprintf(stderr, "\nWarning: stdin used as random source\n\n"); + rng = stdin; + } + } + + t1 = clock(); + for (;;) { +#if 0 + if (clock() - t1 > CLOCKS_PER_SEC) { + sleep(2); + t1 = clock(); + } +#endif + n = fgetc(rng) % 15; + + if (n == 0) { + /* add tests */ + rand_num(&a); + rand_num(&b); + mp_add(&a, &b, &c); + printf("add\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 1) { + /* sub tests */ + rand_num(&a); + rand_num(&b); + mp_sub(&a, &b, &c); + printf("sub\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 2) { + /* mul tests */ + rand_num(&a); + rand_num(&b); + mp_mul(&a, &b, &c); + printf("mul\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 3) { + /* div tests */ + rand_num(&a); + rand_num(&b); + mp_div(&a, &b, &c, &d); + printf("div\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + mp_to64(&d, buf); + printf("%s\n", buf); + } else if (n == 4) { + /* sqr tests */ + rand_num(&a); + mp_sqr(&a, &b); + printf("sqr\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 5) { + /* mul_2d test */ + rand_num(&a); + mp_copy(&a, &b); + n = fgetc(rng) & 63; + mp_mul_2d(&b, n, &b); + mp_to64(&a, buf); + printf("mul2d\n"); + printf("%s\n", buf); + printf("%d\n", n); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 6) { + /* div_2d test */ + rand_num(&a); + mp_copy(&a, &b); + n = fgetc(rng) & 63; + mp_div_2d(&b, n, &b, NULL); + mp_to64(&a, buf); + printf("div2d\n"); + printf("%s\n", buf); + printf("%d\n", n); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 7) { + /* gcd test */ + rand_num(&a); + rand_num(&b); + a.sign = MP_ZPOS; + b.sign = MP_ZPOS; + mp_gcd(&a, &b, &c); + printf("gcd\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 8) { + /* lcm test */ + rand_num(&a); + rand_num(&b); + a.sign = MP_ZPOS; + b.sign = MP_ZPOS; + mp_lcm(&a, &b, &c); + printf("lcm\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 9) { + /* exptmod test */ + rand_num2(&a); + rand_num2(&b); + rand_num2(&c); +// if (c.dp[0]&1) mp_add_d(&c, 1, &c); + a.sign = b.sign = c.sign = 0; + mp_exptmod(&a, &b, &c, &d); + printf("expt\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + mp_to64(&d, buf); + printf("%s\n", buf); + } else if (n == 10) { + /* invmod test */ + rand_num2(&a); + rand_num2(&b); + b.sign = MP_ZPOS; + a.sign = MP_ZPOS; + mp_gcd(&a, &b, &c); + if (mp_cmp_d(&c, 1) != 0) continue; + if (mp_cmp_d(&b, 1) == 0) continue; + mp_invmod(&a, &b, &c); + printf("invmod\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + mp_to64(&c, buf); + printf("%s\n", buf); + } else if (n == 11) { + rand_num(&a); + mp_mul_2(&a, &a); + mp_div_2(&a, &b); + printf("div2\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 12) { + rand_num2(&a); + mp_mul_2(&a, &b); + printf("mul2\n"); + mp_to64(&a, buf); + printf("%s\n", buf); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 13) { + rand_num2(&a); + tmp = abs(rand()) & THE_MASK; + mp_add_d(&a, tmp, &b); + printf("add_d\n"); + mp_to64(&a, buf); + printf("%s\n%d\n", buf, tmp); + mp_to64(&b, buf); + printf("%s\n", buf); + } else if (n == 14) { + rand_num2(&a); + tmp = abs(rand()) & THE_MASK; + mp_sub_d(&a, tmp, &b); + printf("sub_d\n"); + mp_to64(&a, buf); + printf("%s\n%d\n", buf, tmp); + mp_to64(&b, buf); + printf("%s\n", buf); + } + } + fclose(rng); + return 0; +} diff --git a/libtommath/pics/design_process.sxd b/libtommath/pics/design_process.sxd new file mode 100644 index 0000000..7414dbb Binary files /dev/null and b/libtommath/pics/design_process.sxd differ diff --git a/libtommath/pics/design_process.tif b/libtommath/pics/design_process.tif new file mode 100644 index 0000000..4a0c012 Binary files /dev/null and b/libtommath/pics/design_process.tif differ diff --git a/libtommath/pics/expt_state.sxd b/libtommath/pics/expt_state.sxd new file mode 100644 index 0000000..6518404 Binary files /dev/null and b/libtommath/pics/expt_state.sxd differ diff --git a/libtommath/pics/expt_state.tif b/libtommath/pics/expt_state.tif new file mode 100644 index 0000000..cb06e8e Binary files /dev/null and b/libtommath/pics/expt_state.tif differ diff --git a/libtommath/pics/makefile b/libtommath/pics/makefile new file mode 100644 index 0000000..3ecb02f --- /dev/null +++ b/libtommath/pics/makefile @@ -0,0 +1,35 @@ +# makes the images... yeah + +default: pses + +design_process.ps: design_process.tif + tiff2ps -s -e design_process.tif > design_process.ps + +sliding_window.ps: sliding_window.tif + tiff2ps -s -e sliding_window.tif > sliding_window.ps + +expt_state.ps: expt_state.tif + tiff2ps -s -e expt_state.tif > expt_state.ps + +primality.ps: primality.tif + tiff2ps -s -e primality.tif > primality.ps + +design_process.pdf: design_process.ps + epstopdf design_process.ps + +sliding_window.pdf: sliding_window.ps + epstopdf sliding_window.ps + +expt_state.pdf: expt_state.ps + epstopdf expt_state.ps + +primality.pdf: primality.ps + epstopdf primality.ps + + +pses: sliding_window.ps expt_state.ps primality.ps design_process.ps +pdfes: sliding_window.pdf expt_state.pdf primality.pdf design_process.pdf + +clean: + rm -rf *.ps *.pdf .xvpics + \ No newline at end of file diff --git a/libtommath/pics/primality.tif b/libtommath/pics/primality.tif new file mode 100644 index 0000000..76d6be3 Binary files /dev/null and b/libtommath/pics/primality.tif differ diff --git a/libtommath/pics/radix.sxd b/libtommath/pics/radix.sxd new file mode 100644 index 0000000..b9eb9a0 Binary files /dev/null and b/libtommath/pics/radix.sxd differ diff --git a/libtommath/pics/sliding_window.sxd b/libtommath/pics/sliding_window.sxd new file mode 100644 index 0000000..91e7c0d Binary files /dev/null and b/libtommath/pics/sliding_window.sxd differ diff --git a/libtommath/pics/sliding_window.tif b/libtommath/pics/sliding_window.tif new file mode 100644 index 0000000..bb4cb96 Binary files /dev/null and b/libtommath/pics/sliding_window.tif differ diff --git a/libtommath/poster.out b/libtommath/poster.out new file mode 100644 index 0000000..e69de29 diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf new file mode 100644 index 0000000..e0b4f84 Binary files /dev/null and b/libtommath/poster.pdf differ diff --git a/libtommath/poster.tex b/libtommath/poster.tex new file mode 100644 index 0000000..e7388f4 --- /dev/null +++ b/libtommath/poster.tex @@ -0,0 +1,35 @@ +\documentclass[landscape,11pt]{article} +\usepackage{amsmath, amssymb} +\usepackage{hyperref} +\begin{document} +\hspace*{-3in} +\begin{tabular}{llllll} +$c = a + b$ & {\tt mp\_add(\&a, \&b, \&c)} & $b = 2a$ & {\tt mp\_mul\_2(\&a, \&b)} & \\ +$c = a - b$ & {\tt mp\_sub(\&a, \&b, \&c)} & $b = a/2$ & {\tt mp\_div\_2(\&a, \&b)} & \\ +$c = ab $ & {\tt mp\_mul(\&a, \&b, \&c)} & $c = 2^ba$ & {\tt mp\_mul\_2d(\&a, b, \&c)} \\ +$b = a^2 $ & {\tt mp\_sqr(\&a, \&b)} & $c = a/2^b, d = a \mod 2^b$ & {\tt mp\_div\_2d(\&a, b, \&c, \&d)} \\ +$c = \lfloor a/b \rfloor, d = a \mod b$ & {\tt mp\_div(\&a, \&b, \&c, \&d)} & $c = a \mod 2^b $ & {\tt mp\_mod\_2d(\&a, b, \&c)} \\ + && \\ +$a = b $ & {\tt mp\_set\_int(\&a, b)} & $c = a \vee b$ & {\tt mp\_or(\&a, \&b, \&c)} \\ +$b = a $ & {\tt mp\_copy(\&a, \&b)} & $c = a \wedge b$ & {\tt mp\_and(\&a, \&b, \&c)} \\ + && $c = a \oplus b$ & {\tt mp\_xor(\&a, \&b, \&c)} \\ + & \\ +$b = -a $ & {\tt mp\_neg(\&a, \&b)} & $d = a + b \mod c$ & {\tt mp\_addmod(\&a, \&b, \&c, \&d)} \\ +$b = |a| $ & {\tt mp\_abs(\&a, \&b)} & $d = a - b \mod c$ & {\tt mp\_submod(\&a, \&b, \&c, \&d)} \\ + && $d = ab \mod c$ & {\tt mp\_mulmod(\&a, \&b, \&c, \&d)} \\ +Compare $a$ and $b$ & {\tt mp\_cmp(\&a, \&b)} & $c = a^2 \mod b$ & {\tt mp\_sqrmod(\&a, \&b, \&c)} \\ +Is Zero? & {\tt mp\_iszero(\&a)} & $c = a^{-1} \mod b$ & {\tt mp\_invmod(\&a, \&b, \&c)} \\ +Is Even? & {\tt mp\_iseven(\&a)} & $d = a^b \mod c$ & {\tt mp\_exptmod(\&a, \&b, \&c, \&d)} \\ +Is Odd ? & {\tt mp\_isodd(\&a)} \\ +&\\ +$\vert \vert a \vert \vert$ & {\tt mp\_unsigned\_bin\_size(\&a)} & $res$ = 1 if $a$ prime to $t$ rounds? & {\tt mp\_prime\_is\_prime(\&a, t, \&res)} \\ +$buf \leftarrow a$ & {\tt mp\_to\_unsigned\_bin(\&a, buf)} & Next prime after $a$ to $t$ rounds. & {\tt mp\_prime\_next\_prime(\&a, t, bbs\_style)} \\ +$a \leftarrow buf[0..len-1]$ & {\tt mp\_read\_unsigned\_bin(\&a, buf, len)} \\ +&\\ +$b = \sqrt{a}$ & {\tt mp\_sqrt(\&a, \&b)} & $c = \mbox{gcd}(a, b)$ & {\tt mp\_gcd(\&a, \&b, \&c)} \\ +$c = a^{1/b}$ & {\tt mp\_n\_root(\&a, b, \&c)} & $c = \mbox{lcm}(a, b)$ & {\tt mp\_lcm(\&a, \&b, \&c)} \\ +&\\ +Greater Than & MP\_GT & Equal To & MP\_EQ \\ +Less Than & MP\_LT & Bits per digit & DIGIT\_BIT \\ +\end{tabular} +\end{document} diff --git a/libtommath/pre_gen/mpi.c b/libtommath/pre_gen/mpi.c new file mode 100644 index 0000000..7d832e7 --- /dev/null +++ b/libtommath/pre_gen/mpi.c @@ -0,0 +1,8819 @@ +/* Start: bn_error.c */ +#include +#ifdef BN_ERROR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static const struct { + int code; + char *msg; +} msgs[] = { + { MP_OKAY, "Successful" }, + { MP_MEM, "Out of heap" }, + { MP_VAL, "Value out of range" } +}; + +/* return a char * string for a given code */ +char *mp_error_to_string(int code) +{ + int x; + + /* scan the lookup table for the given message */ + for (x = 0; x < (int)(sizeof(msgs) / sizeof(msgs[0])); x++) { + if (msgs[x].code == code) { + return msgs[x].msg; + } + } + + /* generic reply for invalid code */ + return "Invalid error code"; +} + +#endif + +/* End: bn_error.c */ + +/* Start: bn_fast_mp_invmod.c */ +#include +#ifdef BN_FAST_MP_INVMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes the modular inverse via binary extended euclidean algorithm, + * that is c = 1/a mod b + * + * Based on slow invmod except this is optimized for the case where b is + * odd as per HAC Note 14.64 on pp. 610 + */ +int +fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x, y, u, v, B, D; + int res, neg; + + /* 2. [modified] b must be odd */ + if (mp_iseven (b) == 1) { + return MP_VAL; + } + + /* init all our temps */ + if ((res = mp_init_multi(&x, &y, &u, &v, &B, &D, NULL)) != MP_OKAY) { + return res; + } + + /* x == modulus, y == value to invert */ + if ((res = mp_copy (b, &x)) != MP_OKAY) { + goto LBL_ERR; + } + + /* we need y = |a| */ + if ((res = mp_abs (a, &y)) != MP_OKAY) { + goto LBL_ERR; + } + + /* 3. u=x, v=y, A=1, B=0, C=0,D=1 */ + if ((res = mp_copy (&x, &u)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (&y, &v)) != MP_OKAY) { + goto LBL_ERR; + } + mp_set (&D, 1); + +top: + /* 4. while u is even do */ + while (mp_iseven (&u) == 1) { + /* 4.1 u = u/2 */ + if ((res = mp_div_2 (&u, &u)) != MP_OKAY) { + goto LBL_ERR; + } + /* 4.2 if B is odd then */ + if (mp_isodd (&B) == 1) { + if ((res = mp_sub (&B, &x, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* B = B/2 */ + if ((res = mp_div_2 (&B, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 5. while v is even do */ + while (mp_iseven (&v) == 1) { + /* 5.1 v = v/2 */ + if ((res = mp_div_2 (&v, &v)) != MP_OKAY) { + goto LBL_ERR; + } + /* 5.2 if D is odd then */ + if (mp_isodd (&D) == 1) { + /* D = (D-x)/2 */ + if ((res = mp_sub (&D, &x, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* D = D/2 */ + if ((res = mp_div_2 (&D, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 6. if u >= v then */ + if (mp_cmp (&u, &v) != MP_LT) { + /* u = u - v, B = B - D */ + if ((res = mp_sub (&u, &v, &u)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&B, &D, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } else { + /* v - v - u, D = D - B */ + if ((res = mp_sub (&v, &u, &v)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&D, &B, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* if not zero goto step 4 */ + if (mp_iszero (&u) == 0) { + goto top; + } + + /* now a = C, b = D, gcd == g*v */ + + /* if v != 1 then there is no inverse */ + if (mp_cmp_d (&v, 1) != MP_EQ) { + res = MP_VAL; + goto LBL_ERR; + } + + /* b is now the inverse */ + neg = a->sign; + while (D.sign == MP_NEG) { + if ((res = mp_add (&D, b, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + mp_exch (&D, c); + c->sign = neg; + res = MP_OKAY; + +LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); + return res; +} +#endif + +/* End: bn_fast_mp_invmod.c */ + +/* Start: bn_fast_mp_montgomery_reduce.c */ +#include +#ifdef BN_FAST_MP_MONTGOMERY_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes xR**-1 == x (mod N) via Montgomery Reduction + * + * This is an optimized implementation of montgomery_reduce + * which uses the comba method to quickly calculate the columns of the + * reduction. + * + * Based on Algorithm 14.32 on pp.601 of HAC. +*/ +int +fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +{ + int ix, res, olduse; + mp_word W[MP_WARRAY]; + + /* get old used count */ + olduse = x->used; + + /* grow a as required */ + if (x->alloc < n->used + 1) { + if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) { + return res; + } + } + + /* first we have to get the digits of the input into + * an array of double precision words W[...] + */ + { + register mp_word *_W; + register mp_digit *tmpx; + + /* alias for the W[] array */ + _W = W; + + /* alias for the digits of x*/ + tmpx = x->dp; + + /* copy the digits of a into W[0..a->used-1] */ + for (ix = 0; ix < x->used; ix++) { + *_W++ = *tmpx++; + } + + /* zero the high words of W[a->used..m->used*2] */ + for (; ix < n->used * 2 + 1; ix++) { + *_W++ = 0; + } + } + + /* now we proceed to zero successive digits + * from the least significant upwards + */ + for (ix = 0; ix < n->used; ix++) { + /* mu = ai * m' mod b + * + * We avoid a double precision multiplication (which isn't required) + * by casting the value down to a mp_digit. Note this requires + * that W[ix-1] have the carry cleared (see after the inner loop) + */ + register mp_digit mu; + mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); + + /* a = a + mu * m * b**i + * + * This is computed in place and on the fly. The multiplication + * by b**i is handled by offseting which columns the results + * are added to. + * + * Note the comba method normally doesn't handle carries in the + * inner loop In this case we fix the carry from the previous + * column since the Montgomery reduction requires digits of the + * result (so far) [see above] to work. This is + * handled by fixing up one carry after the inner loop. The + * carry fixups are done in order so after these loops the + * first m->used words of W[] have the carries fixed + */ + { + register int iy; + register mp_digit *tmpn; + register mp_word *_W; + + /* alias for the digits of the modulus */ + tmpn = n->dp; + + /* Alias for the columns set by an offset of ix */ + _W = W + ix; + + /* inner loop */ + for (iy = 0; iy < n->used; iy++) { + *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); + } + } + + /* now fix carry for next digit, W[ix+1] */ + W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); + } + + /* now we have to propagate the carries and + * shift the words downward [all those least + * significant digits we zeroed]. + */ + { + register mp_digit *tmpx; + register mp_word *_W, *_W1; + + /* nox fix rest of carries */ + + /* alias for current word */ + _W1 = W + ix; + + /* alias for next word, where the carry goes */ + _W = W + ++ix; + + for (; ix <= n->used * 2 + 1; ix++) { + *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); + } + + /* copy out, A = A/b**n + * + * The result is A/b**n but instead of converting from an + * array of mp_word to mp_digit than calling mp_rshd + * we just copy them in the right order + */ + + /* alias for destination word */ + tmpx = x->dp; + + /* alias for shifted double precision result */ + _W = W + n->used; + + for (ix = 0; ix < n->used + 1; ix++) { + *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); + } + + /* zero oldused digits, if the input a was larger than + * m->used+1 we'll have to clear the digits + */ + for (; ix < olduse; ix++) { + *tmpx++ = 0; + } + } + + /* set the max used and clamp */ + x->used = n->used + 1; + mp_clamp (x); + + /* if A >= m then A = A - m */ + if (mp_cmp_mag (x, n) != MP_LT) { + return s_mp_sub (x, n, x); + } + return MP_OKAY; +} +#endif + +/* End: bn_fast_mp_montgomery_reduce.c */ + +/* Start: bn_fast_s_mp_mul_digs.c */ +#include +#ifdef BN_FAST_S_MP_MUL_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Fast (comba) multiplier + * + * This is the fast column-array [comba] multiplier. It is + * designed to compute the columns of the product first + * then handle the carries afterwards. This has the effect + * of making the nested loops that compute the columns very + * simple and schedulable on super-scalar processors. + * + * This has been modified to produce a variable number of + * digits of output so if say only a half-product is required + * you don't have to compute the upper half (a feature + * required for fast Barrett reduction). + * + * Based on Algorithm 14.12 on pp.595 of HAC. + * + */ +int +fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY]; + register mp_word _W; + + /* grow the destination as required */ + if (c->alloc < digs) { + if ((res = mp_grow (c, digs)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + pa = MIN(digs, a->used + b->used); + + /* clear the carry */ + _W = 0; + for (ix = 0; ix < pa; ix++) { + int tx, ty; + int iy; + mp_digit *tmpx, *tmpy; + + /* get offsets into the two bignums */ + ty = MIN(b->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = b->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* execute loop */ + for (iz = 0; iz < iy; ++iz) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* store term */ + W[ix] = ((mp_digit)_W) & MP_MASK; + + /* make next carry */ + _W = _W >> ((mp_word)DIGIT_BIT); + } + + /* store final carry */ + W[ix] = _W; + + /* setup dest */ + olduse = c->used; + c->used = digs; + + { + register mp_digit *tmpc; + tmpc = c->dp; + for (ix = 0; ix < digs; ix++) { + /* now extract the previous digit [below the carry] */ + *tmpc++ = W[ix]; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpc++ = 0; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif + +/* End: bn_fast_s_mp_mul_digs.c */ + +/* Start: bn_fast_s_mp_mul_high_digs.c */ +#include +#ifdef BN_FAST_S_MP_MUL_HIGH_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* this is a modified version of fast_s_mul_digs that only produces + * output digits *above* digs. See the comments for fast_s_mul_digs + * to see how it works. + * + * This is used in the Barrett reduction since for one of the multiplications + * only the higher digits were needed. This essentially halves the work. + * + * Based on Algorithm 14.12 on pp.595 of HAC. + */ +int +fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY]; + mp_word _W; + + /* grow the destination as required */ + pa = a->used + b->used; + if (c->alloc < pa) { + if ((res = mp_grow (c, pa)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + pa = a->used + b->used; + _W = 0; + for (ix = digs; ix < pa; ix++) { + int tx, ty, iy; + mp_digit *tmpx, *tmpy; + + /* get offsets into the two bignums */ + ty = MIN(b->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = b->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* execute loop */ + for (iz = 0; iz < iy; iz++) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* store term */ + W[ix] = ((mp_digit)_W) & MP_MASK; + + /* make next carry */ + _W = _W >> ((mp_word)DIGIT_BIT); + } + + /* store final carry */ + W[ix] = _W; + + /* setup dest */ + olduse = c->used; + c->used = pa; + + { + register mp_digit *tmpc; + + tmpc = c->dp + digs; + for (ix = digs; ix <= pa; ix++) { + /* now extract the previous digit [below the carry] */ + *tmpc++ = W[ix]; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpc++ = 0; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif + +/* End: bn_fast_s_mp_mul_high_digs.c */ + +/* Start: bn_fast_s_mp_sqr.c */ +#include +#ifdef BN_FAST_S_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* fast squaring + * + * This is the comba method where the columns of the product + * are computed first then the carries are computed. This + * has the effect of making a very simple inner loop that + * is executed the most + * + * W2 represents the outer products and W the inner. + * + * A further optimizations is made because the inner + * products are of the form "A * B * 2". The *2 part does + * not need to be computed until the end which is good + * because 64-bit shifts are slow! + * + * Based on Algorithm 14.16 on pp.597 of HAC. + * + */ +/* the jist of squaring... + +you do like mult except the offset of the tmpx [one that starts closer to zero] +can't equal the offset of tmpy. So basically you set up iy like before then you min it with +(ty-tx) so that it never happens. You double all those you add in the inner loop + +After that loop you do the squares and add them in. + +Remove W2 and don't memset W + +*/ + +int fast_s_mp_sqr (mp_int * a, mp_int * b) +{ + int olduse, res, pa, ix, iz; + mp_digit W[MP_WARRAY], *tmpx; + mp_word W1; + + /* grow the destination as required */ + pa = a->used + a->used; + if (b->alloc < pa) { + if ((res = mp_grow (b, pa)) != MP_OKAY) { + return res; + } + } + + /* number of output digits to produce */ + W1 = 0; + for (ix = 0; ix < pa; ix++) { + int tx, ty, iy; + mp_word _W; + mp_digit *tmpy; + + /* clear counter */ + _W = 0; + + /* get offsets into the two bignums */ + ty = MIN(a->used-1, ix); + tx = ix - ty; + + /* setup temp aliases */ + tmpx = a->dp + tx; + tmpy = a->dp + ty; + + /* this is the number of times the loop will iterrate, essentially its + while (tx++ < a->used && ty-- >= 0) { ... } + */ + iy = MIN(a->used-tx, ty+1); + + /* now for squaring tx can never equal ty + * we halve the distance since they approach at a rate of 2x + * and we have to round because odd cases need to be executed + */ + iy = MIN(iy, (ty-tx+1)>>1); + + /* execute loop */ + for (iz = 0; iz < iy; iz++) { + _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } + + /* double the inner product and add carry */ + _W = _W + _W + W1; + + /* even columns have the square term in them */ + if ((ix&1) == 0) { + _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); + } + + /* store it */ + W[ix] = _W; + + /* make next carry */ + W1 = _W >> ((mp_word)DIGIT_BIT); + } + + /* setup dest */ + olduse = b->used; + b->used = a->used+a->used; + + { + mp_digit *tmpb; + tmpb = b->dp; + for (ix = 0; ix < pa; ix++) { + *tmpb++ = W[ix] & MP_MASK; + } + + /* clear unused digits [that existed in the old copy of c] */ + for (; ix < olduse; ix++) { + *tmpb++ = 0; + } + } + mp_clamp (b); + return MP_OKAY; +} +#endif + +/* End: bn_fast_s_mp_sqr.c */ + +/* Start: bn_mp_2expt.c */ +#include +#ifdef BN_MP_2EXPT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes a = 2**b + * + * Simple algorithm which zeroes the int, grows it then just sets one bit + * as required. + */ +int +mp_2expt (mp_int * a, int b) +{ + int res; + + /* zero a as per default */ + mp_zero (a); + + /* grow a to accomodate the single bit */ + if ((res = mp_grow (a, b / DIGIT_BIT + 1)) != MP_OKAY) { + return res; + } + + /* set the used count of where the bit will go */ + a->used = b / DIGIT_BIT + 1; + + /* put the single bit in its place */ + a->dp[b / DIGIT_BIT] = ((mp_digit)1) << (b % DIGIT_BIT); + + return MP_OKAY; +} +#endif + +/* End: bn_mp_2expt.c */ + +/* Start: bn_mp_abs.c */ +#include +#ifdef BN_MP_ABS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = |a| + * + * Simple function copies the input and fixes the sign to positive + */ +int +mp_abs (mp_int * a, mp_int * b) +{ + int res; + + /* copy a to b */ + if (a != b) { + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } + } + + /* force the sign of b to positive */ + b->sign = MP_ZPOS; + + return MP_OKAY; +} +#endif + +/* End: bn_mp_abs.c */ + +/* Start: bn_mp_add.c */ +#include +#ifdef BN_MP_ADD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level addition (handles signs) */ +int mp_add (mp_int * a, mp_int * b, mp_int * c) +{ + int sa, sb, res; + + /* get sign of both inputs */ + sa = a->sign; + sb = b->sign; + + /* handle two cases, not four */ + if (sa == sb) { + /* both positive or both negative */ + /* add their magnitudes, copy the sign */ + c->sign = sa; + res = s_mp_add (a, b, c); + } else { + /* one positive, the other negative */ + /* subtract the one with the greater magnitude from */ + /* the one of the lesser magnitude. The result gets */ + /* the sign of the one with the greater magnitude. */ + if (mp_cmp_mag (a, b) == MP_LT) { + c->sign = sb; + res = s_mp_sub (b, a, c); + } else { + c->sign = sa; + res = s_mp_sub (a, b, c); + } + } + return res; +} + +#endif + +/* End: bn_mp_add.c */ + +/* Start: bn_mp_add_d.c */ +#include +#ifdef BN_MP_ADD_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* single digit addition */ +int +mp_add_d (mp_int * a, mp_digit b, mp_int * c) +{ + int res, ix, oldused; + mp_digit *tmpa, *tmpc, mu; + + /* grow c as required */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* if a is negative and |a| >= b, call c = |a| - b */ + if (a->sign == MP_NEG && (a->used > 1 || a->dp[0] >= b)) { + /* temporarily fix sign of a */ + a->sign = MP_ZPOS; + + /* c = |a| - b */ + res = mp_sub_d(a, b, c); + + /* fix sign */ + a->sign = c->sign = MP_NEG; + + return res; + } + + /* old number of used digits in c */ + oldused = c->used; + + /* sign always positive */ + c->sign = MP_ZPOS; + + /* source alias */ + tmpa = a->dp; + + /* destination alias */ + tmpc = c->dp; + + /* if a is positive */ + if (a->sign == MP_ZPOS) { + /* add digit, after this we're propagating + * the carry. + */ + *tmpc = *tmpa++ + b; + mu = *tmpc >> DIGIT_BIT; + *tmpc++ &= MP_MASK; + + /* now handle rest of the digits */ + for (ix = 1; ix < a->used; ix++) { + *tmpc = *tmpa++ + mu; + mu = *tmpc >> DIGIT_BIT; + *tmpc++ &= MP_MASK; + } + /* set final carry */ + ix++; + *tmpc++ = mu; + + /* setup size */ + c->used = a->used + 1; + } else { + /* a was negative and |a| < b */ + c->used = 1; + + /* the result is a single digit */ + if (a->used == 1) { + *tmpc++ = b - a->dp[0]; + } else { + *tmpc++ = b; + } + + /* setup count so the clearing of oldused + * can fall through correctly + */ + ix = 1; + } + + /* now zero to oldused */ + while (ix++ < oldused) { + *tmpc++ = 0; + } + mp_clamp(c); + + return MP_OKAY; +} + +#endif + +/* End: bn_mp_add_d.c */ + +/* Start: bn_mp_addmod.c */ +#include +#ifdef BN_MP_ADDMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a + b (mod c) */ +int +mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_add (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif + +/* End: bn_mp_addmod.c */ + +/* Start: bn_mp_and.c */ +#include +#ifdef BN_MP_AND_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* AND two ints together */ +int +mp_and (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + t.dp[ix] &= x->dp[ix]; + } + + /* zero digits above the last from the smallest mp_int */ + for (; ix < t.used; ix++) { + t.dp[ix] = 0; + } + + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_mp_and.c */ + +/* Start: bn_mp_clamp.c */ +#include +#ifdef BN_MP_CLAMP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* trim unused digits + * + * This is used to ensure that leading zero digits are + * trimed and the leading "used" digit will be non-zero + * Typically very fast. Also fixes the sign if there + * are no more leading digits + */ +void +mp_clamp (mp_int * a) +{ + /* decrease used while the most significant digit is + * zero. + */ + while (a->used > 0 && a->dp[a->used - 1] == 0) { + --(a->used); + } + + /* reset the sign flag if used == 0 */ + if (a->used == 0) { + a->sign = MP_ZPOS; + } +} +#endif + +/* End: bn_mp_clamp.c */ + +/* Start: bn_mp_clear.c */ +#include +#ifdef BN_MP_CLEAR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* clear one (frees) */ +void +mp_clear (mp_int * a) +{ + int i; + + /* only do anything if a hasn't been freed previously */ + if (a->dp != NULL) { + /* first zero the digits */ + for (i = 0; i < a->used; i++) { + a->dp[i] = 0; + } + + /* free ram */ + XFREE(a->dp); + + /* reset members to make debugging easier */ + a->dp = NULL; + a->alloc = a->used = 0; + a->sign = MP_ZPOS; + } +} +#endif + +/* End: bn_mp_clear.c */ + +/* Start: bn_mp_clear_multi.c */ +#include +#ifdef BN_MP_CLEAR_MULTI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +#include + +void mp_clear_multi(mp_int *mp, ...) +{ + mp_int* next_mp = mp; + va_list args; + va_start(args, mp); + while (next_mp != NULL) { + mp_clear(next_mp); + next_mp = va_arg(args, mp_int*); + } + va_end(args); +} +#endif + +/* End: bn_mp_clear_multi.c */ + +/* Start: bn_mp_cmp.c */ +#include +#ifdef BN_MP_CMP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare two ints (signed)*/ +int +mp_cmp (mp_int * a, mp_int * b) +{ + /* compare based on sign */ + if (a->sign != b->sign) { + if (a->sign == MP_NEG) { + return MP_LT; + } else { + return MP_GT; + } + } + + /* compare digits */ + if (a->sign == MP_NEG) { + /* if negative compare opposite direction */ + return mp_cmp_mag(b, a); + } else { + return mp_cmp_mag(a, b); + } +} +#endif + +/* End: bn_mp_cmp.c */ + +/* Start: bn_mp_cmp_d.c */ +#include +#ifdef BN_MP_CMP_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare a digit */ +int mp_cmp_d(mp_int * a, mp_digit b) +{ + /* compare based on sign */ + if (a->sign == MP_NEG) { + return MP_LT; + } + + /* compare based on magnitude */ + if (a->used > 1) { + return MP_GT; + } + + /* compare the only digit of a to b */ + if (a->dp[0] > b) { + return MP_GT; + } else if (a->dp[0] < b) { + return MP_LT; + } else { + return MP_EQ; + } +} +#endif + +/* End: bn_mp_cmp_d.c */ + +/* Start: bn_mp_cmp_mag.c */ +#include +#ifdef BN_MP_CMP_MAG_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* compare maginitude of two ints (unsigned) */ +int mp_cmp_mag (mp_int * a, mp_int * b) +{ + int n; + mp_digit *tmpa, *tmpb; + + /* compare based on # of non-zero digits */ + if (a->used > b->used) { + return MP_GT; + } + + if (a->used < b->used) { + return MP_LT; + } + + /* alias for a */ + tmpa = a->dp + (a->used - 1); + + /* alias for b */ + tmpb = b->dp + (a->used - 1); + + /* compare based on digits */ + for (n = 0; n < a->used; ++n, --tmpa, --tmpb) { + if (*tmpa > *tmpb) { + return MP_GT; + } + + if (*tmpa < *tmpb) { + return MP_LT; + } + } + return MP_EQ; +} +#endif + +/* End: bn_mp_cmp_mag.c */ + +/* Start: bn_mp_cnt_lsb.c */ +#include +#ifdef BN_MP_CNT_LSB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static const int lnz[16] = { + 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0 +}; + +/* Counts the number of lsbs which are zero before the first zero bit */ +int mp_cnt_lsb(mp_int *a) +{ + int x; + mp_digit q, qq; + + /* easy out */ + if (mp_iszero(a) == 1) { + return 0; + } + + /* scan lower digits until non-zero */ + for (x = 0; x < a->used && a->dp[x] == 0; x++); + q = a->dp[x]; + x *= DIGIT_BIT; + + /* now scan this digit until a 1 is found */ + if ((q & 1) == 0) { + do { + qq = q & 15; + x += lnz[qq]; + q >>= 4; + } while (qq == 0); + } + return x; +} + +#endif + +/* End: bn_mp_cnt_lsb.c */ + +/* Start: bn_mp_copy.c */ +#include +#ifdef BN_MP_COPY_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* copy, b = a */ +int +mp_copy (mp_int * a, mp_int * b) +{ + int res, n; + + /* if dst == src do nothing */ + if (a == b) { + return MP_OKAY; + } + + /* grow dest */ + if (b->alloc < a->used) { + if ((res = mp_grow (b, a->used)) != MP_OKAY) { + return res; + } + } + + /* zero b and copy the parameters over */ + { + register mp_digit *tmpa, *tmpb; + + /* pointer aliases */ + + /* source */ + tmpa = a->dp; + + /* destination */ + tmpb = b->dp; + + /* copy all the digits */ + for (n = 0; n < a->used; n++) { + *tmpb++ = *tmpa++; + } + + /* clear high digits */ + for (; n < b->used; n++) { + *tmpb++ = 0; + } + } + + /* copy used count and sign */ + b->used = a->used; + b->sign = a->sign; + return MP_OKAY; +} +#endif + +/* End: bn_mp_copy.c */ + +/* Start: bn_mp_count_bits.c */ +#include +#ifdef BN_MP_COUNT_BITS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* returns the number of bits in an int */ +int +mp_count_bits (mp_int * a) +{ + int r; + mp_digit q; + + /* shortcut */ + if (a->used == 0) { + return 0; + } + + /* get number of digits and add that */ + r = (a->used - 1) * DIGIT_BIT; + + /* take the last digit and count the bits in it */ + q = a->dp[a->used - 1]; + while (q > ((mp_digit) 0)) { + ++r; + q >>= ((mp_digit) 1); + } + return r; +} +#endif + +/* End: bn_mp_count_bits.c */ + +/* Start: bn_mp_div.c */ +#include +#ifdef BN_MP_DIV_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +#ifdef BN_MP_DIV_SMALL + +/* slower bit-bang division... also smaller */ +int mp_div(mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + mp_int ta, tb, tq, q; + int res, n, n2; + + /* is divisor zero ? */ + if (mp_iszero (b) == 1) { + return MP_VAL; + } + + /* if a < b then q=0, r = a */ + if (mp_cmp_mag (a, b) == MP_LT) { + if (d != NULL) { + res = mp_copy (a, d); + } else { + res = MP_OKAY; + } + if (c != NULL) { + mp_zero (c); + } + return res; + } + + /* init our temps */ + if ((res = mp_init_multi(&ta, &tb, &tq, &q, NULL) != MP_OKAY)) { + return res; + } + + + mp_set(&tq, 1); + n = mp_count_bits(a) - mp_count_bits(b); + if (((res = mp_abs(a, &ta)) != MP_OKAY) || + ((res = mp_abs(b, &tb)) != MP_OKAY) || + ((res = mp_mul_2d(&tb, n, &tb)) != MP_OKAY) || + ((res = mp_mul_2d(&tq, n, &tq)) != MP_OKAY)) { + goto LBL_ERR; + } + + while (n-- >= 0) { + if (mp_cmp(&tb, &ta) != MP_GT) { + if (((res = mp_sub(&ta, &tb, &ta)) != MP_OKAY) || + ((res = mp_add(&q, &tq, &q)) != MP_OKAY)) { + goto LBL_ERR; + } + } + if (((res = mp_div_2d(&tb, 1, &tb, NULL)) != MP_OKAY) || + ((res = mp_div_2d(&tq, 1, &tq, NULL)) != MP_OKAY)) { + goto LBL_ERR; + } + } + + /* now q == quotient and ta == remainder */ + n = a->sign; + n2 = (a->sign == b->sign ? MP_ZPOS : MP_NEG); + if (c != NULL) { + mp_exch(c, &q); + c->sign = (mp_iszero(c) == MP_YES) ? MP_ZPOS : n2; + } + if (d != NULL) { + mp_exch(d, &ta); + d->sign = (mp_iszero(d) == MP_YES) ? MP_ZPOS : n; + } +LBL_ERR: + mp_clear_multi(&ta, &tb, &tq, &q, NULL); + return res; +} + +#else + +/* integer signed division. + * c*b + d == a [e.g. a/b, c=quotient, d=remainder] + * HAC pp.598 Algorithm 14.20 + * + * Note that the description in HAC is horribly + * incomplete. For example, it doesn't consider + * the case where digits are removed from 'x' in + * the inner loop. It also doesn't consider the + * case that y has fewer than three digits, etc.. + * + * The overall algorithm is as described as + * 14.20 from HAC but fixed to treat these cases. +*/ +int mp_div (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + mp_int q, x, y, t1, t2; + int res, n, t, i, norm, neg; + + /* is divisor zero ? */ + if (mp_iszero (b) == 1) { + return MP_VAL; + } + + /* if a < b then q=0, r = a */ + if (mp_cmp_mag (a, b) == MP_LT) { + if (d != NULL) { + res = mp_copy (a, d); + } else { + res = MP_OKAY; + } + if (c != NULL) { + mp_zero (c); + } + return res; + } + + if ((res = mp_init_size (&q, a->used + 2)) != MP_OKAY) { + return res; + } + q.used = a->used + 2; + + if ((res = mp_init (&t1)) != MP_OKAY) { + goto LBL_Q; + } + + if ((res = mp_init (&t2)) != MP_OKAY) { + goto LBL_T1; + } + + if ((res = mp_init_copy (&x, a)) != MP_OKAY) { + goto LBL_T2; + } + + if ((res = mp_init_copy (&y, b)) != MP_OKAY) { + goto LBL_X; + } + + /* fix the sign */ + neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; + x.sign = y.sign = MP_ZPOS; + + /* normalize both x and y, ensure that y >= b/2, [b == 2**DIGIT_BIT] */ + norm = mp_count_bits(&y) % DIGIT_BIT; + if (norm < (int)(DIGIT_BIT-1)) { + norm = (DIGIT_BIT-1) - norm; + if ((res = mp_mul_2d (&x, norm, &x)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_mul_2d (&y, norm, &y)) != MP_OKAY) { + goto LBL_Y; + } + } else { + norm = 0; + } + + /* note hac does 0 based, so if used==5 then its 0,1,2,3,4, e.g. use 4 */ + n = x.used - 1; + t = y.used - 1; + + /* while (x >= y*b**n-t) do { q[n-t] += 1; x -= y*b**{n-t} } */ + if ((res = mp_lshd (&y, n - t)) != MP_OKAY) { /* y = y*b**{n-t} */ + goto LBL_Y; + } + + while (mp_cmp (&x, &y) != MP_LT) { + ++(q.dp[n - t]); + if ((res = mp_sub (&x, &y, &x)) != MP_OKAY) { + goto LBL_Y; + } + } + + /* reset y by shifting it back down */ + mp_rshd (&y, n - t); + + /* step 3. for i from n down to (t + 1) */ + for (i = n; i >= (t + 1); i--) { + if (i > x.used) { + continue; + } + + /* step 3.1 if xi == yt then set q{i-t-1} to b-1, + * otherwise set q{i-t-1} to (xi*b + x{i-1})/yt */ + if (x.dp[i] == y.dp[t]) { + q.dp[i - t - 1] = ((((mp_digit)1) << DIGIT_BIT) - 1); + } else { + mp_word tmp; + tmp = ((mp_word) x.dp[i]) << ((mp_word) DIGIT_BIT); + tmp |= ((mp_word) x.dp[i - 1]); + tmp /= ((mp_word) y.dp[t]); + if (tmp > (mp_word) MP_MASK) + tmp = MP_MASK; + q.dp[i - t - 1] = (mp_digit) (tmp & (mp_word) (MP_MASK)); + } + + /* while (q{i-t-1} * (yt * b + y{t-1})) > + xi * b**2 + xi-1 * b + xi-2 + + do q{i-t-1} -= 1; + */ + q.dp[i - t - 1] = (q.dp[i - t - 1] + 1) & MP_MASK; + do { + q.dp[i - t - 1] = (q.dp[i - t - 1] - 1) & MP_MASK; + + /* find left hand */ + mp_zero (&t1); + t1.dp[0] = (t - 1 < 0) ? 0 : y.dp[t - 1]; + t1.dp[1] = y.dp[t]; + t1.used = 2; + if ((res = mp_mul_d (&t1, q.dp[i - t - 1], &t1)) != MP_OKAY) { + goto LBL_Y; + } + + /* find right hand */ + t2.dp[0] = (i - 2 < 0) ? 0 : x.dp[i - 2]; + t2.dp[1] = (i - 1 < 0) ? 0 : x.dp[i - 1]; + t2.dp[2] = x.dp[i]; + t2.used = 3; + } while (mp_cmp_mag(&t1, &t2) == MP_GT); + + /* step 3.3 x = x - q{i-t-1} * y * b**{i-t-1} */ + if ((res = mp_mul_d (&y, q.dp[i - t - 1], &t1)) != MP_OKAY) { + goto LBL_Y; + } + + if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) { + goto LBL_Y; + } + + if ((res = mp_sub (&x, &t1, &x)) != MP_OKAY) { + goto LBL_Y; + } + + /* if x < 0 then { x = x + y*b**{i-t-1}; q{i-t-1} -= 1; } */ + if (x.sign == MP_NEG) { + if ((res = mp_copy (&y, &t1)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) { + goto LBL_Y; + } + if ((res = mp_add (&x, &t1, &x)) != MP_OKAY) { + goto LBL_Y; + } + + q.dp[i - t - 1] = (q.dp[i - t - 1] - 1UL) & MP_MASK; + } + } + + /* now q is the quotient and x is the remainder + * [which we have to normalize] + */ + + /* get sign before writing to c */ + x.sign = x.used == 0 ? MP_ZPOS : a->sign; + + if (c != NULL) { + mp_clamp (&q); + mp_exch (&q, c); + c->sign = neg; + } + + if (d != NULL) { + mp_div_2d (&x, norm, &x, NULL); + mp_exch (&x, d); + } + + res = MP_OKAY; + +LBL_Y:mp_clear (&y); +LBL_X:mp_clear (&x); +LBL_T2:mp_clear (&t2); +LBL_T1:mp_clear (&t1); +LBL_Q:mp_clear (&q); + return res; +} + +#endif + +#endif + +/* End: bn_mp_div.c */ + +/* Start: bn_mp_div_2.c */ +#include +#ifdef BN_MP_DIV_2_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = a/2 */ +int mp_div_2(mp_int * a, mp_int * b) +{ + int x, res, oldused; + + /* copy */ + if (b->alloc < a->used) { + if ((res = mp_grow (b, a->used)) != MP_OKAY) { + return res; + } + } + + oldused = b->used; + b->used = a->used; + { + register mp_digit r, rr, *tmpa, *tmpb; + + /* source alias */ + tmpa = a->dp + b->used - 1; + + /* dest alias */ + tmpb = b->dp + b->used - 1; + + /* carry */ + r = 0; + for (x = b->used - 1; x >= 0; x--) { + /* get the carry for the next iteration */ + rr = *tmpa & 1; + + /* shift the current digit, add in carry and store */ + *tmpb-- = (*tmpa-- >> 1) | (r << (DIGIT_BIT - 1)); + + /* forward carry to next iteration */ + r = rr; + } + + /* zero excess digits */ + tmpb = b->dp + b->used; + for (x = b->used; x < oldused; x++) { + *tmpb++ = 0; + } + } + b->sign = a->sign; + mp_clamp (b); + return MP_OKAY; +} +#endif + +/* End: bn_mp_div_2.c */ + +/* Start: bn_mp_div_2d.c */ +#include +#ifdef BN_MP_DIV_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift right by a certain bit count (store quotient in c, optional remainder in d) */ +int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) +{ + mp_digit D, r, rr; + int x, res; + mp_int t; + + + /* if the shift count is <= 0 then we do no work */ + if (b <= 0) { + res = mp_copy (a, c); + if (d != NULL) { + mp_zero (d); + } + return res; + } + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + /* get the remainder */ + if (d != NULL) { + if ((res = mp_mod_2d (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + } + + /* copy */ + if ((res = mp_copy (a, c)) != MP_OKAY) { + mp_clear (&t); + return res; + } + + /* shift by as many digits in the bit count */ + if (b >= (int)DIGIT_BIT) { + mp_rshd (c, b / DIGIT_BIT); + } + + /* shift any bit count < DIGIT_BIT */ + D = (mp_digit) (b % DIGIT_BIT); + if (D != 0) { + register mp_digit *tmpc, mask, shift; + + /* mask */ + mask = (((mp_digit)1) << D) - 1; + + /* shift for lsb */ + shift = DIGIT_BIT - D; + + /* alias */ + tmpc = c->dp + (c->used - 1); + + /* carry */ + r = 0; + for (x = c->used - 1; x >= 0; x--) { + /* get the lower bits of this word in a temp */ + rr = *tmpc & mask; + + /* shift the current word and mix in the carry bits from the previous word */ + *tmpc = (*tmpc >> D) | (r << shift); + --tmpc; + + /* set the carry to the carry bits of the current word found above */ + r = rr; + } + } + mp_clamp (c); + if (d != NULL) { + mp_exch (&t, d); + } + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_mp_div_2d.c */ + +/* Start: bn_mp_div_3.c */ +#include +#ifdef BN_MP_DIV_3_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* divide by three (based on routine from MPI and the GMP manual) */ +int +mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) +{ + mp_int q; + mp_word w, t; + mp_digit b; + int res, ix; + + /* b = 2**DIGIT_BIT / 3 */ + b = (((mp_word)1) << ((mp_word)DIGIT_BIT)) / ((mp_word)3); + + if ((res = mp_init_size(&q, a->used)) != MP_OKAY) { + return res; + } + + q.used = a->used; + q.sign = a->sign; + w = 0; + for (ix = a->used - 1; ix >= 0; ix--) { + w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); + + if (w >= 3) { + /* multiply w by [1/3] */ + t = (w * ((mp_word)b)) >> ((mp_word)DIGIT_BIT); + + /* now subtract 3 * [w/3] from w, to get the remainder */ + w -= t+t+t; + + /* fixup the remainder as required since + * the optimization is not exact. + */ + while (w >= 3) { + t += 1; + w -= 3; + } + } else { + t = 0; + } + q.dp[ix] = (mp_digit)t; + } + + /* [optional] store the remainder */ + if (d != NULL) { + *d = (mp_digit)w; + } + + /* [optional] store the quotient */ + if (c != NULL) { + mp_clamp(&q); + mp_exch(&q, c); + } + mp_clear(&q); + + return res; +} + +#endif + +/* End: bn_mp_div_3.c */ + +/* Start: bn_mp_div_d.c */ +#include +#ifdef BN_MP_DIV_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +static int s_is_power_of_two(mp_digit b, int *p) +{ + int x; + + for (x = 1; x < DIGIT_BIT; x++) { + if (b == (((mp_digit)1)<dp[0] & ((((mp_digit)1)<used)) != MP_OKAY) { + return res; + } + + q.used = a->used; + q.sign = a->sign; + w = 0; + for (ix = a->used - 1; ix >= 0; ix--) { + w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); + + if (w >= b) { + t = (mp_digit)(w / b); + w -= ((mp_word)t) * ((mp_word)b); + } else { + t = 0; + } + q.dp[ix] = (mp_digit)t; + } + + if (d != NULL) { + *d = (mp_digit)w; + } + + if (c != NULL) { + mp_clamp(&q); + mp_exch(&q, c); + } + mp_clear(&q); + + return res; +} + +#endif + +/* End: bn_mp_div_d.c */ + +/* Start: bn_mp_dr_is_modulus.c */ +#include +#ifdef BN_MP_DR_IS_MODULUS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if a number is a valid DR modulus */ +int mp_dr_is_modulus(mp_int *a) +{ + int ix; + + /* must be at least two digits */ + if (a->used < 2) { + return 0; + } + + /* must be of the form b**k - a [a <= b] so all + * but the first digit must be equal to -1 (mod b). + */ + for (ix = 1; ix < a->used; ix++) { + if (a->dp[ix] != MP_MASK) { + return 0; + } + } + return 1; +} + +#endif + +/* End: bn_mp_dr_is_modulus.c */ + +/* Start: bn_mp_dr_reduce.c */ +#include +#ifdef BN_MP_DR_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduce "x" in place modulo "n" using the Diminished Radix algorithm. + * + * Based on algorithm from the paper + * + * "Generating Efficient Primes for Discrete Log Cryptosystems" + * Chae Hoon Lim, Pil Joong Lee, + * POSTECH Information Research Laboratories + * + * The modulus must be of a special format [see manual] + * + * Has been modified to use algorithm 7.10 from the LTM book instead + * + * Input x must be in the range 0 <= x <= (n-1)**2 + */ +int +mp_dr_reduce (mp_int * x, mp_int * n, mp_digit k) +{ + int err, i, m; + mp_word r; + mp_digit mu, *tmpx1, *tmpx2; + + /* m = digits in modulus */ + m = n->used; + + /* ensure that "x" has at least 2m digits */ + if (x->alloc < m + m) { + if ((err = mp_grow (x, m + m)) != MP_OKAY) { + return err; + } + } + +/* top of loop, this is where the code resumes if + * another reduction pass is required. + */ +top: + /* aliases for digits */ + /* alias for lower half of x */ + tmpx1 = x->dp; + + /* alias for upper half of x, or x/B**m */ + tmpx2 = x->dp + m; + + /* set carry to zero */ + mu = 0; + + /* compute (x mod B**m) + k * [x/B**m] inline and inplace */ + for (i = 0; i < m; i++) { + r = ((mp_word)*tmpx2++) * ((mp_word)k) + *tmpx1 + mu; + *tmpx1++ = (mp_digit)(r & MP_MASK); + mu = (mp_digit)(r >> ((mp_word)DIGIT_BIT)); + } + + /* set final carry */ + *tmpx1++ = mu; + + /* zero words above m */ + for (i = m + 1; i < x->used; i++) { + *tmpx1++ = 0; + } + + /* clamp, sub and return */ + mp_clamp (x); + + /* if x >= n then subtract and reduce again + * Each successive "recursion" makes the input smaller and smaller. + */ + if (mp_cmp_mag (x, n) != MP_LT) { + s_mp_sub(x, n, x); + goto top; + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_dr_reduce.c */ + +/* Start: bn_mp_dr_setup.c */ +#include +#ifdef BN_MP_DR_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +void mp_dr_setup(mp_int *a, mp_digit *d) +{ + /* the casts are required if DIGIT_BIT is one less than + * the number of bits in a mp_digit [e.g. DIGIT_BIT==31] + */ + *d = (mp_digit)((((mp_word)1) << ((mp_word)DIGIT_BIT)) - + ((mp_word)a->dp[0])); +} + +#endif + +/* End: bn_mp_dr_setup.c */ + +/* Start: bn_mp_exch.c */ +#include +#ifdef BN_MP_EXCH_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* swap the elements of two integers, for cases where you can't simply swap the + * mp_int pointers around + */ +void +mp_exch (mp_int * a, mp_int * b) +{ + mp_int t; + + t = *a; + *a = *b; + *b = t; +} +#endif + +/* End: bn_mp_exch.c */ + +/* Start: bn_mp_expt_d.c */ +#include +#ifdef BN_MP_EXPT_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* calculate c = a**b using a square-multiply algorithm */ +int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) +{ + int res, x; + mp_int g; + + if ((res = mp_init_copy (&g, a)) != MP_OKAY) { + return res; + } + + /* set initial result */ + mp_set (c, 1); + + for (x = 0; x < (int) DIGIT_BIT; x++) { + /* square */ + if ((res = mp_sqr (c, c)) != MP_OKAY) { + mp_clear (&g); + return res; + } + + /* if the bit is set multiply */ + if ((b & (mp_digit) (((mp_digit)1) << (DIGIT_BIT - 1))) != 0) { + if ((res = mp_mul (c, &g, c)) != MP_OKAY) { + mp_clear (&g); + return res; + } + } + + /* shift to next bit */ + b <<= 1; + } + + mp_clear (&g); + return MP_OKAY; +} +#endif + +/* End: bn_mp_expt_d.c */ + +/* Start: bn_mp_exptmod.c */ +#include +#ifdef BN_MP_EXPTMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + + +/* this is a shell function that calls either the normal or Montgomery + * exptmod functions. Originally the call to the montgomery code was + * embedded in the normal function but that wasted alot of stack space + * for nothing (since 99% of the time the Montgomery code would be called) + */ +int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +{ + int dr; + + /* modulus P must be positive */ + if (P->sign == MP_NEG) { + return MP_VAL; + } + + /* if exponent X is negative we have to recurse */ + if (X->sign == MP_NEG) { +#ifdef BN_MP_INVMOD_C + mp_int tmpG, tmpX; + int err; + + /* first compute 1/G mod P */ + if ((err = mp_init(&tmpG)) != MP_OKAY) { + return err; + } + if ((err = mp_invmod(G, P, &tmpG)) != MP_OKAY) { + mp_clear(&tmpG); + return err; + } + + /* now get |X| */ + if ((err = mp_init(&tmpX)) != MP_OKAY) { + mp_clear(&tmpG); + return err; + } + if ((err = mp_abs(X, &tmpX)) != MP_OKAY) { + mp_clear_multi(&tmpG, &tmpX, NULL); + return err; + } + + /* and now compute (1/G)**|X| instead of G**X [X < 0] */ + err = mp_exptmod(&tmpG, &tmpX, P, Y); + mp_clear_multi(&tmpG, &tmpX, NULL); + return err; +#else + /* no invmod */ + return MP_VAL; +#endif + } + +#ifdef BN_MP_DR_IS_MODULUS_C + /* is it a DR modulus? */ + dr = mp_dr_is_modulus(P); +#else + dr = 0; +#endif + +#ifdef BN_MP_REDUCE_IS_2K_C + /* if not, is it a uDR modulus? */ + if (dr == 0) { + dr = mp_reduce_is_2k(P) << 1; + } +#endif + + /* if the modulus is odd or dr != 0 use the fast method */ +#ifdef BN_MP_EXPTMOD_FAST_C + if (mp_isodd (P) == 1 || dr != 0) { + return mp_exptmod_fast (G, X, P, Y, dr); + } else { +#endif +#ifdef BN_S_MP_EXPTMOD_C + /* otherwise use the generic Barrett reduction technique */ + return s_mp_exptmod (G, X, P, Y); +#else + /* no exptmod for evens */ + return MP_VAL; +#endif +#ifdef BN_MP_EXPTMOD_FAST_C + } +#endif +} + +#endif + +/* End: bn_mp_exptmod.c */ + +/* Start: bn_mp_exptmod_fast.c */ +#include +#ifdef BN_MP_EXPTMOD_FAST_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes Y == G**X mod P, HAC pp.616, Algorithm 14.85 + * + * Uses a left-to-right k-ary sliding window to compute the modular exponentiation. + * The value of k changes based on the size of the exponent. + * + * Uses Montgomery or Diminished Radix reduction [whichever appropriate] + */ + +#ifdef MP_LOW_MEM + #define TAB_SIZE 32 +#else + #define TAB_SIZE 256 +#endif + +int +mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) +{ + mp_int M[TAB_SIZE], res; + mp_digit buf, mp; + int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + + /* use a pointer to the reduction algorithm. This allows us to use + * one of many reduction algorithms without modding the guts of + * the code with if statements everywhere. + */ + int (*redux)(mp_int*,mp_int*,mp_digit); + + /* find window size */ + x = mp_count_bits (X); + if (x <= 7) { + winsize = 2; + } else if (x <= 36) { + winsize = 3; + } else if (x <= 140) { + winsize = 4; + } else if (x <= 450) { + winsize = 5; + } else if (x <= 1303) { + winsize = 6; + } else if (x <= 3529) { + winsize = 7; + } else { + winsize = 8; + } + +#ifdef MP_LOW_MEM + if (winsize > 5) { + winsize = 5; + } +#endif + + /* init M array */ + /* init first cell */ + if ((err = mp_init(&M[1])) != MP_OKAY) { + return err; + } + + /* now init the second half of the array */ + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + if ((err = mp_init(&M[x])) != MP_OKAY) { + for (y = 1<<(winsize-1); y < x; y++) { + mp_clear (&M[y]); + } + mp_clear(&M[1]); + return err; + } + } + + /* determine and setup reduction code */ + if (redmode == 0) { +#ifdef BN_MP_MONTGOMERY_SETUP_C + /* now setup montgomery */ + if ((err = mp_montgomery_setup (P, &mp)) != MP_OKAY) { + goto LBL_M; + } +#else + err = MP_VAL; + goto LBL_M; +#endif + + /* automatically pick the comba one if available (saves quite a few calls/ifs) */ +#ifdef BN_FAST_MP_MONTGOMERY_REDUCE_C + if (((P->used * 2 + 1) < MP_WARRAY) && + P->used < (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + redux = fast_mp_montgomery_reduce; + } else +#endif + { +#ifdef BN_MP_MONTGOMERY_REDUCE_C + /* use slower baseline Montgomery method */ + redux = mp_montgomery_reduce; +#else + err = MP_VAL; + goto LBL_M; +#endif + } + } else if (redmode == 1) { +#if defined(BN_MP_DR_SETUP_C) && defined(BN_MP_DR_REDUCE_C) + /* setup DR reduction for moduli of the form B**k - b */ + mp_dr_setup(P, &mp); + redux = mp_dr_reduce; +#else + err = MP_VAL; + goto LBL_M; +#endif + } else { +#if defined(BN_MP_REDUCE_2K_SETUP_C) && defined(BN_MP_REDUCE_2K_C) + /* setup DR reduction for moduli of the form 2**k - b */ + if ((err = mp_reduce_2k_setup(P, &mp)) != MP_OKAY) { + goto LBL_M; + } + redux = mp_reduce_2k; +#else + err = MP_VAL; + goto LBL_M; +#endif + } + + /* setup result */ + if ((err = mp_init (&res)) != MP_OKAY) { + goto LBL_M; + } + + /* create M table + * + + * + * The first half of the table is not computed though accept for M[0] and M[1] + */ + + if (redmode == 0) { +#ifdef BN_MP_MONTGOMERY_CALC_NORMALIZATION_C + /* now we need R mod m */ + if ((err = mp_montgomery_calc_normalization (&res, P)) != MP_OKAY) { + goto LBL_RES; + } +#else + err = MP_VAL; + goto LBL_RES; +#endif + + /* now set M[1] to G * R mod m */ + if ((err = mp_mulmod (G, &res, P, &M[1])) != MP_OKAY) { + goto LBL_RES; + } + } else { + mp_set(&res, 1); + if ((err = mp_mod(G, P, &M[1])) != MP_OKAY) { + goto LBL_RES; + } + } + + /* compute the value at M[1<<(winsize-1)] by squaring M[1] (winsize-1) times */ + if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_RES; + } + + for (x = 0; x < (winsize - 1); x++) { + if ((err = mp_sqr (&M[1 << (winsize - 1)], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&M[1 << (winsize - 1)], P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* create upper table */ + for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) { + if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&M[x], P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* set initial mode and bit cnt */ + mode = 0; + bitcnt = 1; + buf = 0; + digidx = X->used - 1; + bitcpy = 0; + bitbuf = 0; + + for (;;) { + /* grab next digit as required */ + if (--bitcnt == 0) { + /* if digidx == -1 we are out of digits so break */ + if (digidx == -1) { + break; + } + /* read next digit and reset bitcnt */ + buf = X->dp[digidx--]; + bitcnt = (int)DIGIT_BIT; + } + + /* grab the next msb from the exponent */ + y = (mp_digit)(buf >> (DIGIT_BIT - 1)) & 1; + buf <<= (mp_digit)1; + + /* if the bit is zero and mode == 0 then we ignore it + * These represent the leading zero bits before the first 1 bit + * in the exponent. Technically this opt is not required but it + * does lower the # of trivial squaring/reductions used + */ + if (mode == 0 && y == 0) { + continue; + } + + /* if the bit is zero and mode == 1 then we square */ + if (mode == 1 && y == 0) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + continue; + } + + /* else we add it to the window */ + bitbuf |= (y << (winsize - ++bitcpy)); + mode = 2; + + if (bitcpy == winsize) { + /* ok window is filled so square as required and multiply */ + /* square first */ + for (x = 0; x < winsize; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* then multiply */ + if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + + /* empty window and reset */ + bitcpy = 0; + bitbuf = 0; + mode = 1; + } + } + + /* if bits remain then square/multiply */ + if (mode == 2 && bitcpy > 0) { + /* square then multiply if the bit is set */ + for (x = 0; x < bitcpy; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + + /* get next bit of the window */ + bitbuf <<= 1; + if ((bitbuf & (1 << winsize)) != 0) { + /* then multiply */ + if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = redux (&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + } + } + + if (redmode == 0) { + /* fixup result if Montgomery reduction is used + * recall that any value in a Montgomery system is + * actually multiplied by R mod n. So we have + * to reduce one more time to cancel out the factor + * of R. + */ + if ((err = redux(&res, P, mp)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* swap res with Y */ + mp_exch (&res, Y); + err = MP_OKAY; +LBL_RES:mp_clear (&res); +LBL_M: + mp_clear(&M[1]); + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + mp_clear (&M[x]); + } + return err; +} +#endif + + +/* End: bn_mp_exptmod_fast.c */ + +/* Start: bn_mp_exteuclid.c */ +#include +#ifdef BN_MP_EXTEUCLID_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Extended euclidean algorithm of (a, b) produces + a*u1 + b*u2 = u3 + */ +int mp_exteuclid(mp_int *a, mp_int *b, mp_int *U1, mp_int *U2, mp_int *U3) +{ + mp_int u1,u2,u3,v1,v2,v3,t1,t2,t3,q,tmp; + int err; + + if ((err = mp_init_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL)) != MP_OKAY) { + return err; + } + + /* initialize, (u1,u2,u3) = (1,0,a) */ + mp_set(&u1, 1); + if ((err = mp_copy(a, &u3)) != MP_OKAY) { goto _ERR; } + + /* initialize, (v1,v2,v3) = (0,1,b) */ + mp_set(&v2, 1); + if ((err = mp_copy(b, &v3)) != MP_OKAY) { goto _ERR; } + + /* loop while v3 != 0 */ + while (mp_iszero(&v3) == MP_NO) { + /* q = u3/v3 */ + if ((err = mp_div(&u3, &v3, &q, NULL)) != MP_OKAY) { goto _ERR; } + + /* (t1,t2,t3) = (u1,u2,u3) - (v1,v2,v3)q */ + if ((err = mp_mul(&v1, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u1, &tmp, &t1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_mul(&v2, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u2, &tmp, &t2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_mul(&v3, &q, &tmp)) != MP_OKAY) { goto _ERR; } + if ((err = mp_sub(&u3, &tmp, &t3)) != MP_OKAY) { goto _ERR; } + + /* (u1,u2,u3) = (v1,v2,v3) */ + if ((err = mp_copy(&v1, &u1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&v2, &u2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&v3, &u3)) != MP_OKAY) { goto _ERR; } + + /* (v1,v2,v3) = (t1,t2,t3) */ + if ((err = mp_copy(&t1, &v1)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&t2, &v2)) != MP_OKAY) { goto _ERR; } + if ((err = mp_copy(&t3, &v3)) != MP_OKAY) { goto _ERR; } + } + + /* copy result out */ + if (U1 != NULL) { mp_exch(U1, &u1); } + if (U2 != NULL) { mp_exch(U2, &u2); } + if (U3 != NULL) { mp_exch(U3, &u3); } + + err = MP_OKAY; +_ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL); + return err; +} +#endif + +/* End: bn_mp_exteuclid.c */ + +/* Start: bn_mp_fread.c */ +#include +#ifdef BN_MP_FREAD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read a bigint from a file stream in ASCII */ +int mp_fread(mp_int *a, int radix, FILE *stream) +{ + int err, ch, neg, y; + + /* clear a */ + mp_zero(a); + + /* if first digit is - then set negative */ + ch = fgetc(stream); + if (ch == '-') { + neg = MP_NEG; + ch = fgetc(stream); + } else { + neg = MP_ZPOS; + } + + for (;;) { + /* find y in the radix map */ + for (y = 0; y < radix; y++) { + if (mp_s_rmap[y] == ch) { + break; + } + } + if (y == radix) { + break; + } + + /* shift up and add */ + if ((err = mp_mul_d(a, radix, a)) != MP_OKAY) { + return err; + } + if ((err = mp_add_d(a, y, a)) != MP_OKAY) { + return err; + } + + ch = fgetc(stream); + } + if (mp_cmp_d(a, 0) != MP_EQ) { + a->sign = neg; + } + + return MP_OKAY; +} + +#endif + +/* End: bn_mp_fread.c */ + +/* Start: bn_mp_fwrite.c */ +#include +#ifdef BN_MP_FWRITE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +int mp_fwrite(mp_int *a, int radix, FILE *stream) +{ + char *buf; + int err, len, x; + + if ((err = mp_radix_size(a, radix, &len)) != MP_OKAY) { + return err; + } + + buf = OPT_CAST(char) XMALLOC (len); + if (buf == NULL) { + return MP_MEM; + } + + if ((err = mp_toradix(a, buf, radix)) != MP_OKAY) { + XFREE (buf); + return err; + } + + for (x = 0; x < len; x++) { + if (fputc(buf[x], stream) == EOF) { + XFREE (buf); + return MP_VAL; + } + } + + XFREE (buf); + return MP_OKAY; +} + +#endif + +/* End: bn_mp_fwrite.c */ + +/* Start: bn_mp_gcd.c */ +#include +#ifdef BN_MP_GCD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Greatest Common Divisor using the binary method */ +int mp_gcd (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int u, v; + int k, u_lsb, v_lsb, res; + + /* either zero than gcd is the largest */ + if (mp_iszero (a) == 1 && mp_iszero (b) == 0) { + return mp_abs (b, c); + } + if (mp_iszero (a) == 0 && mp_iszero (b) == 1) { + return mp_abs (a, c); + } + + /* optimized. At this point if a == 0 then + * b must equal zero too + */ + if (mp_iszero (a) == 1) { + mp_zero(c); + return MP_OKAY; + } + + /* get copies of a and b we can modify */ + if ((res = mp_init_copy (&u, a)) != MP_OKAY) { + return res; + } + + if ((res = mp_init_copy (&v, b)) != MP_OKAY) { + goto LBL_U; + } + + /* must be positive for the remainder of the algorithm */ + u.sign = v.sign = MP_ZPOS; + + /* B1. Find the common power of two for u and v */ + u_lsb = mp_cnt_lsb(&u); + v_lsb = mp_cnt_lsb(&v); + k = MIN(u_lsb, v_lsb); + + if (k > 0) { + /* divide the power of two out */ + if ((res = mp_div_2d(&u, k, &u, NULL)) != MP_OKAY) { + goto LBL_V; + } + + if ((res = mp_div_2d(&v, k, &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + /* divide any remaining factors of two out */ + if (u_lsb != k) { + if ((res = mp_div_2d(&u, u_lsb - k, &u, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + if (v_lsb != k) { + if ((res = mp_div_2d(&v, v_lsb - k, &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + while (mp_iszero(&v) == 0) { + /* make sure v is the largest */ + if (mp_cmp_mag(&u, &v) == MP_GT) { + /* swap u and v to make sure v is >= u */ + mp_exch(&u, &v); + } + + /* subtract smallest from largest */ + if ((res = s_mp_sub(&v, &u, &v)) != MP_OKAY) { + goto LBL_V; + } + + /* Divide out all factors of two */ + if ((res = mp_div_2d(&v, mp_cnt_lsb(&v), &v, NULL)) != MP_OKAY) { + goto LBL_V; + } + } + + /* multiply by 2**k which we divided out at the beginning */ + if ((res = mp_mul_2d (&u, k, c)) != MP_OKAY) { + goto LBL_V; + } + c->sign = MP_ZPOS; + res = MP_OKAY; +LBL_V:mp_clear (&u); +LBL_U:mp_clear (&v); + return res; +} +#endif + +/* End: bn_mp_gcd.c */ + +/* Start: bn_mp_get_int.c */ +#include +#ifdef BN_MP_GET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the lower 32-bits of an mp_int */ +unsigned long mp_get_int(mp_int * a) +{ + int i; + unsigned long res; + + if (a->used == 0) { + return 0; + } + + /* get number of digits of the lsb we have to read */ + i = MIN(a->used,(int)((sizeof(unsigned long)*CHAR_BIT+DIGIT_BIT-1)/DIGIT_BIT))-1; + + /* get most significant digit of result */ + res = DIGIT(a,i); + + while (--i >= 0) { + res = (res << DIGIT_BIT) | DIGIT(a,i); + } + + /* force result to 32-bits always so it is consistent on non 32-bit platforms */ + return res & 0xFFFFFFFFUL; +} +#endif + +/* End: bn_mp_get_int.c */ + +/* Start: bn_mp_grow.c */ +#include +#ifdef BN_MP_GROW_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* grow as required */ +int mp_grow (mp_int * a, int size) +{ + int i; + mp_digit *tmp; + + /* if the alloc size is smaller alloc more ram */ + if (a->alloc < size) { + /* ensure there are always at least MP_PREC digits extra on top */ + size += (MP_PREC * 2) - (size % MP_PREC); + + /* reallocate the array a->dp + * + * We store the return in a temporary variable + * in case the operation failed we don't want + * to overwrite the dp member of a. + */ + tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * size); + if (tmp == NULL) { + /* reallocation failed but "a" is still valid [can be freed] */ + return MP_MEM; + } + + /* reallocation succeeded so set a->dp */ + a->dp = tmp; + + /* zero excess digits */ + i = a->alloc; + a->alloc = size; + for (; i < a->alloc; i++) { + a->dp[i] = 0; + } + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_grow.c */ + +/* Start: bn_mp_init.c */ +#include +#ifdef BN_MP_INIT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* init a new mp_int */ +int mp_init (mp_int * a) +{ + int i; + + /* allocate memory required and clear it */ + a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * MP_PREC); + if (a->dp == NULL) { + return MP_MEM; + } + + /* set the digits to zero */ + for (i = 0; i < MP_PREC; i++) { + a->dp[i] = 0; + } + + /* set the used to zero, allocated digits to the default precision + * and sign to positive */ + a->used = 0; + a->alloc = MP_PREC; + a->sign = MP_ZPOS; + + return MP_OKAY; +} +#endif + +/* End: bn_mp_init.c */ + +/* Start: bn_mp_init_copy.c */ +#include +#ifdef BN_MP_INIT_COPY_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* creates "a" then copies b into it */ +int mp_init_copy (mp_int * a, mp_int * b) +{ + int res; + + if ((res = mp_init (a)) != MP_OKAY) { + return res; + } + return mp_copy (b, a); +} +#endif + +/* End: bn_mp_init_copy.c */ + +/* Start: bn_mp_init_multi.c */ +#include +#ifdef BN_MP_INIT_MULTI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +#include + +int mp_init_multi(mp_int *mp, ...) +{ + mp_err res = MP_OKAY; /* Assume ok until proven otherwise */ + int n = 0; /* Number of ok inits */ + mp_int* cur_arg = mp; + va_list args; + + va_start(args, mp); /* init args to next argument from caller */ + while (cur_arg != NULL) { + if (mp_init(cur_arg) != MP_OKAY) { + /* Oops - error! Back-track and mp_clear what we already + succeeded in init-ing, then return error. + */ + va_list clean_args; + + /* end the current list */ + va_end(args); + + /* now start cleaning up */ + cur_arg = mp; + va_start(clean_args, mp); + while (n--) { + mp_clear(cur_arg); + cur_arg = va_arg(clean_args, mp_int*); + } + va_end(clean_args); + res = MP_MEM; + break; + } + n++; + cur_arg = va_arg(args, mp_int*); + } + va_end(args); + return res; /* Assumed ok, if error flagged above. */ +} + +#endif + +/* End: bn_mp_init_multi.c */ + +/* Start: bn_mp_init_set.c */ +#include +#ifdef BN_MP_INIT_SET_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* initialize and set a digit */ +int mp_init_set (mp_int * a, mp_digit b) +{ + int err; + if ((err = mp_init(a)) != MP_OKAY) { + return err; + } + mp_set(a, b); + return err; +} +#endif + +/* End: bn_mp_init_set.c */ + +/* Start: bn_mp_init_set_int.c */ +#include +#ifdef BN_MP_INIT_SET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* initialize and set a digit */ +int mp_init_set_int (mp_int * a, unsigned long b) +{ + int err; + if ((err = mp_init(a)) != MP_OKAY) { + return err; + } + return mp_set_int(a, b); +} +#endif + +/* End: bn_mp_init_set_int.c */ + +/* Start: bn_mp_init_size.c */ +#include +#ifdef BN_MP_INIT_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* init an mp_init for a given size */ +int mp_init_size (mp_int * a, int size) +{ + int x; + + /* pad size so there are always extra digits */ + size += (MP_PREC * 2) - (size % MP_PREC); + + /* alloc mem */ + a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * size); + if (a->dp == NULL) { + return MP_MEM; + } + + /* set the members */ + a->used = 0; + a->alloc = size; + a->sign = MP_ZPOS; + + /* zero the digits */ + for (x = 0; x < size; x++) { + a->dp[x] = 0; + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_init_size.c */ + +/* Start: bn_mp_invmod.c */ +#include +#ifdef BN_MP_INVMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* hac 14.61, pp608 */ +int mp_invmod (mp_int * a, mp_int * b, mp_int * c) +{ + /* b cannot be negative */ + if (b->sign == MP_NEG || mp_iszero(b) == 1) { + return MP_VAL; + } + +#ifdef BN_FAST_MP_INVMOD_C + /* if the modulus is odd we can use a faster routine instead */ + if (mp_isodd (b) == 1) { + return fast_mp_invmod (a, b, c); + } +#endif + +#ifdef BN_MP_INVMOD_SLOW_C + return mp_invmod_slow(a, b, c); +#endif + + return MP_VAL; +} +#endif + +/* End: bn_mp_invmod.c */ + +/* Start: bn_mp_invmod_slow.c */ +#include +#ifdef BN_MP_INVMOD_SLOW_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* hac 14.61, pp608 */ +int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x, y, u, v, A, B, C, D; + int res; + + /* b cannot be negative */ + if (b->sign == MP_NEG || mp_iszero(b) == 1) { + return MP_VAL; + } + + /* init temps */ + if ((res = mp_init_multi(&x, &y, &u, &v, + &A, &B, &C, &D, NULL)) != MP_OKAY) { + return res; + } + + /* x = a, y = b */ + if ((res = mp_copy (a, &x)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (b, &y)) != MP_OKAY) { + goto LBL_ERR; + } + + /* 2. [modified] if x,y are both even then return an error! */ + if (mp_iseven (&x) == 1 && mp_iseven (&y) == 1) { + res = MP_VAL; + goto LBL_ERR; + } + + /* 3. u=x, v=y, A=1, B=0, C=0,D=1 */ + if ((res = mp_copy (&x, &u)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_copy (&y, &v)) != MP_OKAY) { + goto LBL_ERR; + } + mp_set (&A, 1); + mp_set (&D, 1); + +top: + /* 4. while u is even do */ + while (mp_iseven (&u) == 1) { + /* 4.1 u = u/2 */ + if ((res = mp_div_2 (&u, &u)) != MP_OKAY) { + goto LBL_ERR; + } + /* 4.2 if A or B is odd then */ + if (mp_isodd (&A) == 1 || mp_isodd (&B) == 1) { + /* A = (A+y)/2, B = (B-x)/2 */ + if ((res = mp_add (&A, &y, &A)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_sub (&B, &x, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* A = A/2, B = B/2 */ + if ((res = mp_div_2 (&A, &A)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_div_2 (&B, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 5. while v is even do */ + while (mp_iseven (&v) == 1) { + /* 5.1 v = v/2 */ + if ((res = mp_div_2 (&v, &v)) != MP_OKAY) { + goto LBL_ERR; + } + /* 5.2 if C or D is odd then */ + if (mp_isodd (&C) == 1 || mp_isodd (&D) == 1) { + /* C = (C+y)/2, D = (D-x)/2 */ + if ((res = mp_add (&C, &y, &C)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_sub (&D, &x, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + /* C = C/2, D = D/2 */ + if ((res = mp_div_2 (&C, &C)) != MP_OKAY) { + goto LBL_ERR; + } + if ((res = mp_div_2 (&D, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* 6. if u >= v then */ + if (mp_cmp (&u, &v) != MP_LT) { + /* u = u - v, A = A - C, B = B - D */ + if ((res = mp_sub (&u, &v, &u)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&A, &C, &A)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&B, &D, &B)) != MP_OKAY) { + goto LBL_ERR; + } + } else { + /* v - v - u, C = C - A, D = D - B */ + if ((res = mp_sub (&v, &u, &v)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&C, &A, &C)) != MP_OKAY) { + goto LBL_ERR; + } + + if ((res = mp_sub (&D, &B, &D)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* if not zero goto step 4 */ + if (mp_iszero (&u) == 0) + goto top; + + /* now a = C, b = D, gcd == g*v */ + + /* if v != 1 then there is no inverse */ + if (mp_cmp_d (&v, 1) != MP_EQ) { + res = MP_VAL; + goto LBL_ERR; + } + + /* if its too low */ + while (mp_cmp_d(&C, 0) == MP_LT) { + if ((res = mp_add(&C, b, &C)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* too big */ + while (mp_cmp_mag(&C, b) != MP_LT) { + if ((res = mp_sub(&C, b, &C)) != MP_OKAY) { + goto LBL_ERR; + } + } + + /* C is now the inverse */ + mp_exch (&C, c); + res = MP_OKAY; +LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); + return res; +} +#endif + +/* End: bn_mp_invmod_slow.c */ + +/* Start: bn_mp_is_square.c */ +#include +#ifdef BN_MP_IS_SQUARE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Check if remainders are possible squares - fast exclude non-squares */ +static const char rem_128[128] = { + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1 +}; + +static const char rem_105[105] = { + 0, 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, + 0, 0, 1, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 1, + 0, 1, 1, 1, 1, 1, 0, 1, 1, 0, 1, 1, 1, 1, 1, + 1, 0, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, + 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, + 1, 1, 1, 1, 0, 1, 0, 1, 1, 0, 0, 1, 1, 1, 1, + 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1, 1, 1, 1 +}; + +/* Store non-zero to ret if arg is square, and zero if not */ +int mp_is_square(mp_int *arg,int *ret) +{ + int res; + mp_digit c; + mp_int t; + unsigned long r; + + /* Default to Non-square :) */ + *ret = MP_NO; + + if (arg->sign == MP_NEG) { + return MP_VAL; + } + + /* digits used? (TSD) */ + if (arg->used == 0) { + return MP_OKAY; + } + + /* First check mod 128 (suppose that DIGIT_BIT is at least 7) */ + if (rem_128[127 & DIGIT(arg,0)] == 1) { + return MP_OKAY; + } + + /* Next check mod 105 (3*5*7) */ + if ((res = mp_mod_d(arg,105,&c)) != MP_OKAY) { + return res; + } + if (rem_105[c] == 1) { + return MP_OKAY; + } + + + if ((res = mp_init_set_int(&t,11L*13L*17L*19L*23L*29L*31L)) != MP_OKAY) { + return res; + } + if ((res = mp_mod(arg,&t,&t)) != MP_OKAY) { + goto ERR; + } + r = mp_get_int(&t); + /* Check for other prime modules, note it's not an ERROR but we must + * free "t" so the easiest way is to goto ERR. We know that res + * is already equal to MP_OKAY from the mp_mod call + */ + if ( (1L<<(r%11)) & 0x5C4L ) goto ERR; + if ( (1L<<(r%13)) & 0x9E4L ) goto ERR; + if ( (1L<<(r%17)) & 0x5CE8L ) goto ERR; + if ( (1L<<(r%19)) & 0x4F50CL ) goto ERR; + if ( (1L<<(r%23)) & 0x7ACCA0L ) goto ERR; + if ( (1L<<(r%29)) & 0xC2EDD0CL ) goto ERR; + if ( (1L<<(r%31)) & 0x6DE2B848L ) goto ERR; + + /* Final check - is sqr(sqrt(arg)) == arg ? */ + if ((res = mp_sqrt(arg,&t)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sqr(&t,&t)) != MP_OKAY) { + goto ERR; + } + + *ret = (mp_cmp_mag(&t,arg) == MP_EQ) ? MP_YES : MP_NO; +ERR:mp_clear(&t); + return res; +} +#endif + +/* End: bn_mp_is_square.c */ + +/* Start: bn_mp_jacobi.c */ +#include +#ifdef BN_MP_JACOBI_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes the jacobi c = (a | n) (or Legendre if n is prime) + * HAC pp. 73 Algorithm 2.149 + */ +int mp_jacobi (mp_int * a, mp_int * p, int *c) +{ + mp_int a1, p1; + int k, s, r, res; + mp_digit residue; + + /* if p <= 0 return MP_VAL */ + if (mp_cmp_d(p, 0) != MP_GT) { + return MP_VAL; + } + + /* step 1. if a == 0, return 0 */ + if (mp_iszero (a) == 1) { + *c = 0; + return MP_OKAY; + } + + /* step 2. if a == 1, return 1 */ + if (mp_cmp_d (a, 1) == MP_EQ) { + *c = 1; + return MP_OKAY; + } + + /* default */ + s = 0; + + /* step 3. write a = a1 * 2**k */ + if ((res = mp_init_copy (&a1, a)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&p1)) != MP_OKAY) { + goto LBL_A1; + } + + /* divide out larger power of two */ + k = mp_cnt_lsb(&a1); + if ((res = mp_div_2d(&a1, k, &a1, NULL)) != MP_OKAY) { + goto LBL_P1; + } + + /* step 4. if e is even set s=1 */ + if ((k & 1) == 0) { + s = 1; + } else { + /* else set s=1 if p = 1/7 (mod 8) or s=-1 if p = 3/5 (mod 8) */ + residue = p->dp[0] & 7; + + if (residue == 1 || residue == 7) { + s = 1; + } else if (residue == 3 || residue == 5) { + s = -1; + } + } + + /* step 5. if p == 3 (mod 4) *and* a1 == 3 (mod 4) then s = -s */ + if ( ((p->dp[0] & 3) == 3) && ((a1.dp[0] & 3) == 3)) { + s = -s; + } + + /* if a1 == 1 we're done */ + if (mp_cmp_d (&a1, 1) == MP_EQ) { + *c = s; + } else { + /* n1 = n mod a1 */ + if ((res = mp_mod (p, &a1, &p1)) != MP_OKAY) { + goto LBL_P1; + } + if ((res = mp_jacobi (&p1, &a1, &r)) != MP_OKAY) { + goto LBL_P1; + } + *c = s * r; + } + + /* done */ + res = MP_OKAY; +LBL_P1:mp_clear (&p1); +LBL_A1:mp_clear (&a1); + return res; +} +#endif + +/* End: bn_mp_jacobi.c */ + +/* Start: bn_mp_karatsuba_mul.c */ +#include +#ifdef BN_MP_KARATSUBA_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = |a| * |b| using Karatsuba Multiplication using + * three half size multiplications + * + * Let B represent the radix [e.g. 2**DIGIT_BIT] and + * let n represent half of the number of digits in + * the min(a,b) + * + * a = a1 * B**n + a0 + * b = b1 * B**n + b0 + * + * Then, a * b => + a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 + * + * Note that a1b1 and a0b0 are used twice and only need to be + * computed once. So in total three half size (half # of + * digit) multiplications are performed, a0b0, a1b1 and + * (a1-b1)(a0-b0) + * + * Note that a multiplication of half the digits requires + * 1/4th the number of single precision multiplications so in + * total after one call 25% of the single precision multiplications + * are saved. Note also that the call to mp_mul can end up back + * in this function if the a0, a1, b0, or b1 are above the threshold. + * This is known as divide-and-conquer and leads to the famous + * O(N**lg(3)) or O(N**1.584) work which is asymptopically lower than + * the standard O(N**2) that the baseline/comba methods use. + * Generally though the overhead of this method doesn't pay off + * until a certain size (N ~ 80) is reached. + */ +int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int x0, x1, y0, y1, t1, x0y0, x1y1; + int B, err; + + /* default the return code to an error */ + err = MP_MEM; + + /* min # of digits */ + B = MIN (a->used, b->used); + + /* now divide in two */ + B = B >> 1; + + /* init copy all the temps */ + if (mp_init_size (&x0, B) != MP_OKAY) + goto ERR; + if (mp_init_size (&x1, a->used - B) != MP_OKAY) + goto X0; + if (mp_init_size (&y0, B) != MP_OKAY) + goto X1; + if (mp_init_size (&y1, b->used - B) != MP_OKAY) + goto Y0; + + /* init temps */ + if (mp_init_size (&t1, B * 2) != MP_OKAY) + goto Y1; + if (mp_init_size (&x0y0, B * 2) != MP_OKAY) + goto T1; + if (mp_init_size (&x1y1, B * 2) != MP_OKAY) + goto X0Y0; + + /* now shift the digits */ + x0.used = y0.used = B; + x1.used = a->used - B; + y1.used = b->used - B; + + { + register int x; + register mp_digit *tmpa, *tmpb, *tmpx, *tmpy; + + /* we copy the digits directly instead of using higher level functions + * since we also need to shift the digits + */ + tmpa = a->dp; + tmpb = b->dp; + + tmpx = x0.dp; + tmpy = y0.dp; + for (x = 0; x < B; x++) { + *tmpx++ = *tmpa++; + *tmpy++ = *tmpb++; + } + + tmpx = x1.dp; + for (x = B; x < a->used; x++) { + *tmpx++ = *tmpa++; + } + + tmpy = y1.dp; + for (x = B; x < b->used; x++) { + *tmpy++ = *tmpb++; + } + } + + /* only need to clamp the lower words since by definition the + * upper words x1/y1 must have a known number of digits + */ + mp_clamp (&x0); + mp_clamp (&y0); + + /* now calc the products x0y0 and x1y1 */ + /* after this x0 is no longer required, free temp [x0==t2]! */ + if (mp_mul (&x0, &y0, &x0y0) != MP_OKAY) + goto X1Y1; /* x0y0 = x0*y0 */ + if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) + goto X1Y1; /* x1y1 = x1*y1 */ + + /* now calc x1-x0 and y1-y0 */ + if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = x1 - x0 */ + if (mp_sub (&y1, &y0, &x0) != MP_OKAY) + goto X1Y1; /* t2 = y1 - y0 */ + if (mp_mul (&t1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ + + /* add x0y0 */ + if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) + goto X1Y1; /* t2 = x0y0 + x1y1 */ + if (mp_sub (&x0, &t1, &t1) != MP_OKAY) + goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ + + /* shift by B */ + if (mp_lshd (&t1, B) != MP_OKAY) + goto X1Y1; /* t1 = (x0y0 + x1y1 - (x1-x0)*(y1-y0))< +#ifdef BN_MP_KARATSUBA_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Karatsuba squaring, computes b = a*a using three + * half size squarings + * + * See comments of karatsuba_mul for details. It + * is essentially the same algorithm but merely + * tuned to perform recursive squarings. + */ +int mp_karatsuba_sqr (mp_int * a, mp_int * b) +{ + mp_int x0, x1, t1, t2, x0x0, x1x1; + int B, err; + + err = MP_MEM; + + /* min # of digits */ + B = a->used; + + /* now divide in two */ + B = B >> 1; + + /* init copy all the temps */ + if (mp_init_size (&x0, B) != MP_OKAY) + goto ERR; + if (mp_init_size (&x1, a->used - B) != MP_OKAY) + goto X0; + + /* init temps */ + if (mp_init_size (&t1, a->used * 2) != MP_OKAY) + goto X1; + if (mp_init_size (&t2, a->used * 2) != MP_OKAY) + goto T1; + if (mp_init_size (&x0x0, B * 2) != MP_OKAY) + goto T2; + if (mp_init_size (&x1x1, (a->used - B) * 2) != MP_OKAY) + goto X0X0; + + { + register int x; + register mp_digit *dst, *src; + + src = a->dp; + + /* now shift the digits */ + dst = x0.dp; + for (x = 0; x < B; x++) { + *dst++ = *src++; + } + + dst = x1.dp; + for (x = B; x < a->used; x++) { + *dst++ = *src++; + } + } + + x0.used = B; + x1.used = a->used - B; + + mp_clamp (&x0); + + /* now calc the products x0*x0 and x1*x1 */ + if (mp_sqr (&x0, &x0x0) != MP_OKAY) + goto X1X1; /* x0x0 = x0*x0 */ + if (mp_sqr (&x1, &x1x1) != MP_OKAY) + goto X1X1; /* x1x1 = x1*x1 */ + + /* now calc (x1-x0)**2 */ + if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + goto X1X1; /* t1 = x1 - x0 */ + if (mp_sqr (&t1, &t1) != MP_OKAY) + goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ + + /* add x0y0 */ + if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) + goto X1X1; /* t2 = x0x0 + x1x1 */ + if (mp_sub (&t2, &t1, &t1) != MP_OKAY) + goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ + + /* shift by B */ + if (mp_lshd (&t1, B) != MP_OKAY) + goto X1X1; /* t1 = (x0x0 + x1x1 - (x1-x0)*(x1-x0))< +#ifdef BN_MP_LCM_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes least common multiple as |a*b|/(a, b) */ +int mp_lcm (mp_int * a, mp_int * b, mp_int * c) +{ + int res; + mp_int t1, t2; + + + if ((res = mp_init_multi (&t1, &t2, NULL)) != MP_OKAY) { + return res; + } + + /* t1 = get the GCD of the two inputs */ + if ((res = mp_gcd (a, b, &t1)) != MP_OKAY) { + goto LBL_T; + } + + /* divide the smallest by the GCD */ + if (mp_cmp_mag(a, b) == MP_LT) { + /* store quotient in t2 such that t2 * b is the LCM */ + if ((res = mp_div(a, &t1, &t2, NULL)) != MP_OKAY) { + goto LBL_T; + } + res = mp_mul(b, &t2, c); + } else { + /* store quotient in t2 such that t2 * a is the LCM */ + if ((res = mp_div(b, &t1, &t2, NULL)) != MP_OKAY) { + goto LBL_T; + } + res = mp_mul(a, &t2, c); + } + + /* fix the sign to positive */ + c->sign = MP_ZPOS; + +LBL_T: + mp_clear_multi (&t1, &t2, NULL); + return res; +} +#endif + +/* End: bn_mp_lcm.c */ + +/* Start: bn_mp_lshd.c */ +#include +#ifdef BN_MP_LSHD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift left a certain amount of digits */ +int mp_lshd (mp_int * a, int b) +{ + int x, res; + + /* if its less than zero return */ + if (b <= 0) { + return MP_OKAY; + } + + /* grow to fit the new digits */ + if (a->alloc < a->used + b) { + if ((res = mp_grow (a, a->used + b)) != MP_OKAY) { + return res; + } + } + + { + register mp_digit *top, *bottom; + + /* increment the used by the shift amount then copy upwards */ + a->used += b; + + /* top */ + top = a->dp + a->used - 1; + + /* base */ + bottom = a->dp + a->used - 1 - b; + + /* much like mp_rshd this is implemented using a sliding window + * except the window goes the otherway around. Copying from + * the bottom to the top. see bn_mp_rshd.c for more info. + */ + for (x = a->used - 1; x >= b; x--) { + *top-- = *bottom--; + } + + /* zero the lower digits */ + top = a->dp; + for (x = 0; x < b; x++) { + *top++ = 0; + } + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_lshd.c */ + +/* Start: bn_mp_mod.c */ +#include +#ifdef BN_MP_MOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = a mod b, 0 <= c < b */ +int +mp_mod (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int t; + int res; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_div (a, b, NULL, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + + if (t.sign != b->sign) { + res = mp_add (b, &t, c); + } else { + res = MP_OKAY; + mp_exch (&t, c); + } + + mp_clear (&t); + return res; +} +#endif + +/* End: bn_mp_mod.c */ + +/* Start: bn_mp_mod_2d.c */ +#include +#ifdef BN_MP_MOD_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* calc a value mod 2**b */ +int +mp_mod_2d (mp_int * a, int b, mp_int * c) +{ + int x, res; + + /* if b is <= 0 then zero the int */ + if (b <= 0) { + mp_zero (c); + return MP_OKAY; + } + + /* if the modulus is larger than the value than return */ + if (b >= (int) (a->used * DIGIT_BIT)) { + res = mp_copy (a, c); + return res; + } + + /* copy */ + if ((res = mp_copy (a, c)) != MP_OKAY) { + return res; + } + + /* zero digits above the last digit of the modulus */ + for (x = (b / DIGIT_BIT) + ((b % DIGIT_BIT) == 0 ? 0 : 1); x < c->used; x++) { + c->dp[x] = 0; + } + /* clear the digit that is not completely outside/inside the modulus */ + c->dp[b / DIGIT_BIT] &= + (mp_digit) ((((mp_digit) 1) << (((mp_digit) b) % DIGIT_BIT)) - ((mp_digit) 1)); + mp_clamp (c); + return MP_OKAY; +} +#endif + +/* End: bn_mp_mod_2d.c */ + +/* Start: bn_mp_mod_d.c */ +#include +#ifdef BN_MP_MOD_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +int +mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) +{ + return mp_div_d(a, b, NULL, c); +} +#endif + +/* End: bn_mp_mod_d.c */ + +/* Start: bn_mp_montgomery_calc_normalization.c */ +#include +#ifdef BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* + * shifts with subtractions when the result is greater than b. + * + * The method is slightly modified to shift B unconditionally upto just under + * the leading bit of b. This saves alot of multiple precision shifting. + */ +int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) +{ + int x, bits, res; + + /* how many bits of last digit does b use */ + bits = mp_count_bits (b) % DIGIT_BIT; + + + if (b->used > 1) { + if ((res = mp_2expt (a, (b->used - 1) * DIGIT_BIT + bits - 1)) != MP_OKAY) { + return res; + } + } else { + mp_set(a, 1); + bits = 1; + } + + + /* now compute C = A * B mod b */ + for (x = bits - 1; x < (int)DIGIT_BIT; x++) { + if ((res = mp_mul_2 (a, a)) != MP_OKAY) { + return res; + } + if (mp_cmp_mag (a, b) != MP_LT) { + if ((res = s_mp_sub (a, b, a)) != MP_OKAY) { + return res; + } + } + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_montgomery_calc_normalization.c */ + +/* Start: bn_mp_montgomery_reduce.c */ +#include +#ifdef BN_MP_MONTGOMERY_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes xR**-1 == x (mod N) via Montgomery Reduction */ +int +mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +{ + int ix, res, digs; + mp_digit mu; + + /* can the fast reduction [comba] method be used? + * + * Note that unlike in mul you're safely allowed *less* + * than the available columns [255 per default] since carries + * are fixed up in the inner loop. + */ + digs = n->used * 2 + 1; + if ((digs < MP_WARRAY) && + n->used < + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_mp_montgomery_reduce (x, n, rho); + } + + /* grow the input as required */ + if (x->alloc < digs) { + if ((res = mp_grow (x, digs)) != MP_OKAY) { + return res; + } + } + x->used = digs; + + for (ix = 0; ix < n->used; ix++) { + /* mu = ai * rho mod b + * + * The value of rho must be precalculated via + * montgomery_setup() such that + * it equals -1/n0 mod b this allows the + * following inner loop to reduce the + * input one digit at a time + */ + mu = (mp_digit) (((mp_word)x->dp[ix]) * ((mp_word)rho) & MP_MASK); + + /* a = a + mu * m * b**i */ + { + register int iy; + register mp_digit *tmpn, *tmpx, u; + register mp_word r; + + /* alias for digits of the modulus */ + tmpn = n->dp; + + /* alias for the digits of x [the input] */ + tmpx = x->dp + ix; + + /* set the carry to zero */ + u = 0; + + /* Multiply and add in place */ + for (iy = 0; iy < n->used; iy++) { + /* compute product and sum */ + r = ((mp_word)mu) * ((mp_word)*tmpn++) + + ((mp_word) u) + ((mp_word) * tmpx); + + /* get carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + + /* fix digit */ + *tmpx++ = (mp_digit)(r & ((mp_word) MP_MASK)); + } + /* At this point the ix'th digit of x should be zero */ + + + /* propagate carries upwards as required*/ + while (u) { + *tmpx += u; + u = *tmpx >> DIGIT_BIT; + *tmpx++ &= MP_MASK; + } + } + } + + /* at this point the n.used'th least + * significant digits of x are all zero + * which means we can shift x to the + * right by n.used digits and the + * residue is unchanged. + */ + + /* x = x/b**n.used */ + mp_clamp(x); + mp_rshd (x, n->used); + + /* if x >= n then x = x - n */ + if (mp_cmp_mag (x, n) != MP_LT) { + return s_mp_sub (x, n, x); + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_montgomery_reduce.c */ + +/* Start: bn_mp_montgomery_setup.c */ +#include +#ifdef BN_MP_MONTGOMERY_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* setups the montgomery reduction stuff */ +int +mp_montgomery_setup (mp_int * n, mp_digit * rho) +{ + mp_digit x, b; + +/* fast inversion mod 2**k + * + * Based on the fact that + * + * XA = 1 (mod 2**n) => (X(2-XA)) A = 1 (mod 2**2n) + * => 2*X*A - X*X*A*A = 1 + * => 2*(1) - (1) = 1 + */ + b = n->dp[0]; + + if ((b & 1) == 0) { + return MP_VAL; + } + + x = (((b + 2) & 4) << 1) + b; /* here x*a==1 mod 2**4 */ + x *= 2 - b * x; /* here x*a==1 mod 2**8 */ +#if !defined(MP_8BIT) + x *= 2 - b * x; /* here x*a==1 mod 2**16 */ +#endif +#if defined(MP_64BIT) || !(defined(MP_8BIT) || defined(MP_16BIT)) + x *= 2 - b * x; /* here x*a==1 mod 2**32 */ +#endif +#ifdef MP_64BIT + x *= 2 - b * x; /* here x*a==1 mod 2**64 */ +#endif + + /* rho = -1/m mod b */ + *rho = (((mp_word)1 << ((mp_word) DIGIT_BIT)) - x) & MP_MASK; + + return MP_OKAY; +} +#endif + +/* End: bn_mp_montgomery_setup.c */ + +/* Start: bn_mp_mul.c */ +#include +#ifdef BN_MP_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level multiplication (handles sign) */ +int mp_mul (mp_int * a, mp_int * b, mp_int * c) +{ + int res, neg; + neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; + + /* use Toom-Cook? */ +#ifdef BN_MP_TOOM_MUL_C + if (MIN (a->used, b->used) >= TOOM_MUL_CUTOFF) { + res = mp_toom_mul(a, b, c); + } else +#endif +#ifdef BN_MP_KARATSUBA_MUL_C + /* use Karatsuba? */ + if (MIN (a->used, b->used) >= KARATSUBA_MUL_CUTOFF) { + res = mp_karatsuba_mul (a, b, c); + } else +#endif + { + /* can we use the fast multiplier? + * + * The fast multiplier can be used if the output will + * have less than MP_WARRAY digits and the number of + * digits won't affect carry propagation + */ + int digs = a->used + b->used + 1; + +#ifdef BN_FAST_S_MP_MUL_DIGS_C + if ((digs < MP_WARRAY) && + MIN(a->used, b->used) <= + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + res = fast_s_mp_mul_digs (a, b, c, digs); + } else +#endif +#ifdef BN_S_MP_MUL_DIGS_C + res = s_mp_mul (a, b, c); /* uses s_mp_mul_digs */ +#else + res = MP_VAL; +#endif + + } + c->sign = (c->used > 0) ? neg : MP_ZPOS; + return res; +} +#endif + +/* End: bn_mp_mul.c */ + +/* Start: bn_mp_mul_2.c */ +#include +#ifdef BN_MP_MUL_2_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = a*2 */ +int mp_mul_2(mp_int * a, mp_int * b) +{ + int x, res, oldused; + + /* grow to accomodate result */ + if (b->alloc < a->used + 1) { + if ((res = mp_grow (b, a->used + 1)) != MP_OKAY) { + return res; + } + } + + oldused = b->used; + b->used = a->used; + + { + register mp_digit r, rr, *tmpa, *tmpb; + + /* alias for source */ + tmpa = a->dp; + + /* alias for dest */ + tmpb = b->dp; + + /* carry */ + r = 0; + for (x = 0; x < a->used; x++) { + + /* get what will be the *next* carry bit from the + * MSB of the current digit + */ + rr = *tmpa >> ((mp_digit)(DIGIT_BIT - 1)); + + /* now shift up this digit, add in the carry [from the previous] */ + *tmpb++ = ((*tmpa++ << ((mp_digit)1)) | r) & MP_MASK; + + /* copy the carry that would be from the source + * digit into the next iteration + */ + r = rr; + } + + /* new leading digit? */ + if (r != 0) { + /* add a MSB which is always 1 at this point */ + *tmpb = 1; + ++(b->used); + } + + /* now zero any excess digits on the destination + * that we didn't write to + */ + tmpb = b->dp + b->used; + for (x = b->used; x < oldused; x++) { + *tmpb++ = 0; + } + } + b->sign = a->sign; + return MP_OKAY; +} +#endif + +/* End: bn_mp_mul_2.c */ + +/* Start: bn_mp_mul_2d.c */ +#include +#ifdef BN_MP_MUL_2D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift left by a certain bit count */ +int mp_mul_2d (mp_int * a, int b, mp_int * c) +{ + mp_digit d; + int res; + + /* copy */ + if (a != c) { + if ((res = mp_copy (a, c)) != MP_OKAY) { + return res; + } + } + + if (c->alloc < (int)(c->used + b/DIGIT_BIT + 1)) { + if ((res = mp_grow (c, c->used + b / DIGIT_BIT + 1)) != MP_OKAY) { + return res; + } + } + + /* shift by as many digits in the bit count */ + if (b >= (int)DIGIT_BIT) { + if ((res = mp_lshd (c, b / DIGIT_BIT)) != MP_OKAY) { + return res; + } + } + + /* shift any bit count < DIGIT_BIT */ + d = (mp_digit) (b % DIGIT_BIT); + if (d != 0) { + register mp_digit *tmpc, shift, mask, r, rr; + register int x; + + /* bitmask for carries */ + mask = (((mp_digit)1) << d) - 1; + + /* shift for msbs */ + shift = DIGIT_BIT - d; + + /* alias */ + tmpc = c->dp; + + /* carry */ + r = 0; + for (x = 0; x < c->used; x++) { + /* get the higher bits of the current word */ + rr = (*tmpc >> shift) & mask; + + /* shift the current word and OR in the carry */ + *tmpc = ((*tmpc << d) | r) & MP_MASK; + ++tmpc; + + /* set the carry to the carry bits of the current word */ + r = rr; + } + + /* set final carry */ + if (r != 0) { + c->dp[(c->used)++] = r; + } + } + mp_clamp (c); + return MP_OKAY; +} +#endif + +/* End: bn_mp_mul_2d.c */ + +/* Start: bn_mp_mul_d.c */ +#include +#ifdef BN_MP_MUL_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiply by a digit */ +int +mp_mul_d (mp_int * a, mp_digit b, mp_int * c) +{ + mp_digit u, *tmpa, *tmpc; + mp_word r; + int ix, res, olduse; + + /* make sure c is big enough to hold a*b */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow (c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* get the original destinations used count */ + olduse = c->used; + + /* set the sign */ + c->sign = a->sign; + + /* alias for a->dp [source] */ + tmpa = a->dp; + + /* alias for c->dp [dest] */ + tmpc = c->dp; + + /* zero carry */ + u = 0; + + /* compute columns */ + for (ix = 0; ix < a->used; ix++) { + /* compute product and carry sum for this term */ + r = ((mp_word) u) + ((mp_word)*tmpa++) * ((mp_word)b); + + /* mask off higher bits to get a single digit */ + *tmpc++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* send carry into next iteration */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + + /* store final carry [if any] */ + *tmpc++ = u; + + /* now zero digits above the top */ + while (ix++ < olduse) { + *tmpc++ = 0; + } + + /* set used count */ + c->used = a->used + 1; + mp_clamp(c); + + return MP_OKAY; +} +#endif + +/* End: bn_mp_mul_d.c */ + +/* Start: bn_mp_mulmod.c */ +#include +#ifdef BN_MP_MULMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a * b (mod c) */ +int +mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_mul (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif + +/* End: bn_mp_mulmod.c */ + +/* Start: bn_mp_n_root.c */ +#include +#ifdef BN_MP_N_ROOT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* find the n'th root of an integer + * + * Result found such that (c)**b <= a and (c+1)**b > a + * + * This algorithm uses Newton's approximation + * x[i+1] = x[i] - f(x[i])/f'(x[i]) + * which will find the root in log(N) time where + * each step involves a fair bit. This is not meant to + * find huge roots [square and cube, etc]. + */ +int mp_n_root (mp_int * a, mp_digit b, mp_int * c) +{ + mp_int t1, t2, t3; + int res, neg; + + /* input must be positive if b is even */ + if ((b & 1) == 0 && a->sign == MP_NEG) { + return MP_VAL; + } + + if ((res = mp_init (&t1)) != MP_OKAY) { + return res; + } + + if ((res = mp_init (&t2)) != MP_OKAY) { + goto LBL_T1; + } + + if ((res = mp_init (&t3)) != MP_OKAY) { + goto LBL_T2; + } + + /* if a is negative fudge the sign but keep track */ + neg = a->sign; + a->sign = MP_ZPOS; + + /* t2 = 2 */ + mp_set (&t2, 2); + + do { + /* t1 = t2 */ + if ((res = mp_copy (&t2, &t1)) != MP_OKAY) { + goto LBL_T3; + } + + /* t2 = t1 - ((t1**b - a) / (b * t1**(b-1))) */ + + /* t3 = t1**(b-1) */ + if ((res = mp_expt_d (&t1, b - 1, &t3)) != MP_OKAY) { + goto LBL_T3; + } + + /* numerator */ + /* t2 = t1**b */ + if ((res = mp_mul (&t3, &t1, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + /* t2 = t1**b - a */ + if ((res = mp_sub (&t2, a, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + /* denominator */ + /* t3 = t1**(b-1) * b */ + if ((res = mp_mul_d (&t3, b, &t3)) != MP_OKAY) { + goto LBL_T3; + } + + /* t3 = (t1**b - a)/(b * t1**(b-1)) */ + if ((res = mp_div (&t2, &t3, &t3, NULL)) != MP_OKAY) { + goto LBL_T3; + } + + if ((res = mp_sub (&t1, &t3, &t2)) != MP_OKAY) { + goto LBL_T3; + } + } while (mp_cmp (&t1, &t2) != MP_EQ); + + /* result can be off by a few so check */ + for (;;) { + if ((res = mp_expt_d (&t1, b, &t2)) != MP_OKAY) { + goto LBL_T3; + } + + if (mp_cmp (&t2, a) == MP_GT) { + if ((res = mp_sub_d (&t1, 1, &t1)) != MP_OKAY) { + goto LBL_T3; + } + } else { + break; + } + } + + /* reset the sign of a first */ + a->sign = neg; + + /* set the result */ + mp_exch (&t1, c); + + /* set the sign of the result */ + c->sign = neg; + + res = MP_OKAY; + +LBL_T3:mp_clear (&t3); +LBL_T2:mp_clear (&t2); +LBL_T1:mp_clear (&t1); + return res; +} +#endif + +/* End: bn_mp_n_root.c */ + +/* Start: bn_mp_neg.c */ +#include +#ifdef BN_MP_NEG_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* b = -a */ +int mp_neg (mp_int * a, mp_int * b) +{ + int res; + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } + if (mp_iszero(b) != MP_YES) { + b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_neg.c */ + +/* Start: bn_mp_or.c */ +#include +#ifdef BN_MP_OR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* OR two ints together */ +int mp_or (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + t.dp[ix] |= x->dp[ix]; + } + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_mp_or.c */ + +/* Start: bn_mp_prime_fermat.c */ +#include +#ifdef BN_MP_PRIME_FERMAT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* performs one Fermat test. + * + * If "a" were prime then b**a == b (mod a) since the order of + * the multiplicative sub-group would be phi(a) = a-1. That means + * it would be the same as b**(a mod (a-1)) == b**1 == b (mod a). + * + * Sets result to 1 if the congruence holds, or zero otherwise. + */ +int mp_prime_fermat (mp_int * a, mp_int * b, int *result) +{ + mp_int t; + int err; + + /* default to composite */ + *result = MP_NO; + + /* ensure b > 1 */ + if (mp_cmp_d(b, 1) != MP_GT) { + return MP_VAL; + } + + /* init t */ + if ((err = mp_init (&t)) != MP_OKAY) { + return err; + } + + /* compute t = b**a mod a */ + if ((err = mp_exptmod (b, a, a, &t)) != MP_OKAY) { + goto LBL_T; + } + + /* is it equal to b? */ + if (mp_cmp (&t, b) == MP_EQ) { + *result = MP_YES; + } + + err = MP_OKAY; +LBL_T:mp_clear (&t); + return err; +} +#endif + +/* End: bn_mp_prime_fermat.c */ + +/* Start: bn_mp_prime_is_divisible.c */ +#include +#ifdef BN_MP_PRIME_IS_DIVISIBLE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if an integers is divisible by one + * of the first PRIME_SIZE primes or not + * + * sets result to 0 if not, 1 if yes + */ +int mp_prime_is_divisible (mp_int * a, int *result) +{ + int err, ix; + mp_digit res; + + /* default to not */ + *result = MP_NO; + + for (ix = 0; ix < PRIME_SIZE; ix++) { + /* what is a mod LBL_prime_tab[ix] */ + if ((err = mp_mod_d (a, ltm_prime_tab[ix], &res)) != MP_OKAY) { + return err; + } + + /* is the residue zero? */ + if (res == 0) { + *result = MP_YES; + return MP_OKAY; + } + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_prime_is_divisible.c */ + +/* Start: bn_mp_prime_is_prime.c */ +#include +#ifdef BN_MP_PRIME_IS_PRIME_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* performs a variable number of rounds of Miller-Rabin + * + * Probability of error after t rounds is no more than + + * + * Sets result to 1 if probably prime, 0 otherwise + */ +int mp_prime_is_prime (mp_int * a, int t, int *result) +{ + mp_int b; + int ix, err, res; + + /* default to no */ + *result = MP_NO; + + /* valid value of t? */ + if (t <= 0 || t > PRIME_SIZE) { + return MP_VAL; + } + + /* is the input equal to one of the primes in the table? */ + for (ix = 0; ix < PRIME_SIZE; ix++) { + if (mp_cmp_d(a, ltm_prime_tab[ix]) == MP_EQ) { + *result = 1; + return MP_OKAY; + } + } + + /* first perform trial division */ + if ((err = mp_prime_is_divisible (a, &res)) != MP_OKAY) { + return err; + } + + /* return if it was trivially divisible */ + if (res == MP_YES) { + return MP_OKAY; + } + + /* now perform the miller-rabin rounds */ + if ((err = mp_init (&b)) != MP_OKAY) { + return err; + } + + for (ix = 0; ix < t; ix++) { + /* set the prime */ + mp_set (&b, ltm_prime_tab[ix]); + + if ((err = mp_prime_miller_rabin (a, &b, &res)) != MP_OKAY) { + goto LBL_B; + } + + if (res == MP_NO) { + goto LBL_B; + } + } + + /* passed the test */ + *result = MP_YES; +LBL_B:mp_clear (&b); + return err; +} +#endif + +/* End: bn_mp_prime_is_prime.c */ + +/* Start: bn_mp_prime_miller_rabin.c */ +#include +#ifdef BN_MP_PRIME_MILLER_RABIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Miller-Rabin test of "a" to the base of "b" as described in + * HAC pp. 139 Algorithm 4.24 + * + * Sets result to 0 if definitely composite or 1 if probably prime. + * Randomly the chance of error is no more than 1/4 and often + * very much lower. + */ +int mp_prime_miller_rabin (mp_int * a, mp_int * b, int *result) +{ + mp_int n1, y, r; + int s, j, err; + + /* default */ + *result = MP_NO; + + /* ensure b > 1 */ + if (mp_cmp_d(b, 1) != MP_GT) { + return MP_VAL; + } + + /* get n1 = a - 1 */ + if ((err = mp_init_copy (&n1, a)) != MP_OKAY) { + return err; + } + if ((err = mp_sub_d (&n1, 1, &n1)) != MP_OKAY) { + goto LBL_N1; + } + + /* set 2**s * r = n1 */ + if ((err = mp_init_copy (&r, &n1)) != MP_OKAY) { + goto LBL_N1; + } + + /* count the number of least significant bits + * which are zero + */ + s = mp_cnt_lsb(&r); + + /* now divide n - 1 by 2**s */ + if ((err = mp_div_2d (&r, s, &r, NULL)) != MP_OKAY) { + goto LBL_R; + } + + /* compute y = b**r mod a */ + if ((err = mp_init (&y)) != MP_OKAY) { + goto LBL_R; + } + if ((err = mp_exptmod (b, &r, a, &y)) != MP_OKAY) { + goto LBL_Y; + } + + /* if y != 1 and y != n1 do */ + if (mp_cmp_d (&y, 1) != MP_EQ && mp_cmp (&y, &n1) != MP_EQ) { + j = 1; + /* while j <= s-1 and y != n1 */ + while ((j <= (s - 1)) && mp_cmp (&y, &n1) != MP_EQ) { + if ((err = mp_sqrmod (&y, a, &y)) != MP_OKAY) { + goto LBL_Y; + } + + /* if y == 1 then composite */ + if (mp_cmp_d (&y, 1) == MP_EQ) { + goto LBL_Y; + } + + ++j; + } + + /* if y != n1 then composite */ + if (mp_cmp (&y, &n1) != MP_EQ) { + goto LBL_Y; + } + } + + /* probably prime now */ + *result = MP_YES; +LBL_Y:mp_clear (&y); +LBL_R:mp_clear (&r); +LBL_N1:mp_clear (&n1); + return err; +} +#endif + +/* End: bn_mp_prime_miller_rabin.c */ + +/* Start: bn_mp_prime_next_prime.c */ +#include +#ifdef BN_MP_PRIME_NEXT_PRIME_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* finds the next prime after the number "a" using "t" trials + * of Miller-Rabin. + * + * bbs_style = 1 means the prime must be congruent to 3 mod 4 + */ +int mp_prime_next_prime(mp_int *a, int t, int bbs_style) +{ + int err, res, x, y; + mp_digit res_tab[PRIME_SIZE], step, kstep; + mp_int b; + + /* ensure t is valid */ + if (t <= 0 || t > PRIME_SIZE) { + return MP_VAL; + } + + /* force positive */ + a->sign = MP_ZPOS; + + /* simple algo if a is less than the largest prime in the table */ + if (mp_cmp_d(a, ltm_prime_tab[PRIME_SIZE-1]) == MP_LT) { + /* find which prime it is bigger than */ + for (x = PRIME_SIZE - 2; x >= 0; x--) { + if (mp_cmp_d(a, ltm_prime_tab[x]) != MP_LT) { + if (bbs_style == 1) { + /* ok we found a prime smaller or + * equal [so the next is larger] + * + * however, the prime must be + * congruent to 3 mod 4 + */ + if ((ltm_prime_tab[x + 1] & 3) != 3) { + /* scan upwards for a prime congruent to 3 mod 4 */ + for (y = x + 1; y < PRIME_SIZE; y++) { + if ((ltm_prime_tab[y] & 3) == 3) { + mp_set(a, ltm_prime_tab[y]); + return MP_OKAY; + } + } + } + } else { + mp_set(a, ltm_prime_tab[x + 1]); + return MP_OKAY; + } + } + } + /* at this point a maybe 1 */ + if (mp_cmp_d(a, 1) == MP_EQ) { + mp_set(a, 2); + return MP_OKAY; + } + /* fall through to the sieve */ + } + + /* generate a prime congruent to 3 mod 4 or 1/3 mod 4? */ + if (bbs_style == 1) { + kstep = 4; + } else { + kstep = 2; + } + + /* at this point we will use a combination of a sieve and Miller-Rabin */ + + if (bbs_style == 1) { + /* if a mod 4 != 3 subtract the correct value to make it so */ + if ((a->dp[0] & 3) != 3) { + if ((err = mp_sub_d(a, (a->dp[0] & 3) + 1, a)) != MP_OKAY) { return err; }; + } + } else { + if (mp_iseven(a) == 1) { + /* force odd */ + if ((err = mp_sub_d(a, 1, a)) != MP_OKAY) { + return err; + } + } + } + + /* generate the restable */ + for (x = 1; x < PRIME_SIZE; x++) { + if ((err = mp_mod_d(a, ltm_prime_tab[x], res_tab + x)) != MP_OKAY) { + return err; + } + } + + /* init temp used for Miller-Rabin Testing */ + if ((err = mp_init(&b)) != MP_OKAY) { + return err; + } + + for (;;) { + /* skip to the next non-trivially divisible candidate */ + step = 0; + do { + /* y == 1 if any residue was zero [e.g. cannot be prime] */ + y = 0; + + /* increase step to next candidate */ + step += kstep; + + /* compute the new residue without using division */ + for (x = 1; x < PRIME_SIZE; x++) { + /* add the step to each residue */ + res_tab[x] += kstep; + + /* subtract the modulus [instead of using division] */ + if (res_tab[x] >= ltm_prime_tab[x]) { + res_tab[x] -= ltm_prime_tab[x]; + } + + /* set flag if zero */ + if (res_tab[x] == 0) { + y = 1; + } + } + } while (y == 1 && step < ((((mp_digit)1)<= ((((mp_digit)1)< +#ifdef BN_MP_PRIME_RABIN_MILLER_TRIALS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + + +static const struct { + int k, t; +} sizes[] = { +{ 128, 28 }, +{ 256, 16 }, +{ 384, 10 }, +{ 512, 7 }, +{ 640, 6 }, +{ 768, 5 }, +{ 896, 4 }, +{ 1024, 4 } +}; + +/* returns # of RM trials required for a given bit size */ +int mp_prime_rabin_miller_trials(int size) +{ + int x; + + for (x = 0; x < (int)(sizeof(sizes)/(sizeof(sizes[0]))); x++) { + if (sizes[x].k == size) { + return sizes[x].t; + } else if (sizes[x].k > size) { + return (x == 0) ? sizes[0].t : sizes[x - 1].t; + } + } + return sizes[x-1].t + 1; +} + + +#endif + +/* End: bn_mp_prime_rabin_miller_trials.c */ + +/* Start: bn_mp_prime_random_ex.c */ +#include +#ifdef BN_MP_PRIME_RANDOM_EX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* makes a truly random prime of a given size (bits), + * + * Flags are as follows: + * + * LTM_PRIME_BBS - make prime congruent to 3 mod 4 + * LTM_PRIME_SAFE - make sure (p-1)/2 is prime as well (implies LTM_PRIME_BBS) + * LTM_PRIME_2MSB_OFF - make the 2nd highest bit zero + * LTM_PRIME_2MSB_ON - make the 2nd highest bit one + * + * You have to supply a callback which fills in a buffer with random bytes. "dat" is a parameter you can + * have passed to the callback (e.g. a state or something). This function doesn't use "dat" itself + * so it can be NULL + * + */ + +/* This is possibly the mother of all prime generation functions, muahahahahaha! */ +int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback cb, void *dat) +{ + unsigned char *tmp, maskAND, maskOR_msb, maskOR_lsb; + int res, err, bsize, maskOR_msb_offset; + + /* sanity check the input */ + if (size <= 1 || t <= 0) { + return MP_VAL; + } + + /* LTM_PRIME_SAFE implies LTM_PRIME_BBS */ + if (flags & LTM_PRIME_SAFE) { + flags |= LTM_PRIME_BBS; + } + + /* calc the byte size */ + bsize = (size>>3) + ((size&7)?1:0); + + /* we need a buffer of bsize bytes */ + tmp = OPT_CAST(unsigned char) XMALLOC(bsize); + if (tmp == NULL) { + return MP_MEM; + } + + /* calc the maskAND value for the MSbyte*/ + maskAND = ((size&7) == 0) ? 0xFF : (0xFF >> (8 - (size & 7))); + + /* calc the maskOR_msb */ + maskOR_msb = 0; + maskOR_msb_offset = (size - 2) >> 3; + if (flags & LTM_PRIME_2MSB_ON) { + maskOR_msb |= 1 << ((size - 2) & 7); + } else if (flags & LTM_PRIME_2MSB_OFF) { + maskAND &= ~(1 << ((size - 2) & 7)); + } + + /* get the maskOR_lsb */ + maskOR_lsb = 0; + if (flags & LTM_PRIME_BBS) { + maskOR_lsb |= 3; + } + + do { + /* read the bytes */ + if (cb(tmp, bsize, dat) != bsize) { + err = MP_VAL; + goto error; + } + + /* work over the MSbyte */ + tmp[0] &= maskAND; + tmp[0] |= 1 << ((size - 1) & 7); + + /* mix in the maskORs */ + tmp[maskOR_msb_offset] |= maskOR_msb; + tmp[bsize-1] |= maskOR_lsb; + + /* read it in */ + if ((err = mp_read_unsigned_bin(a, tmp, bsize)) != MP_OKAY) { goto error; } + + /* is it prime? */ + if ((err = mp_prime_is_prime(a, t, &res)) != MP_OKAY) { goto error; } + if (res == MP_NO) { + continue; + } + + if (flags & LTM_PRIME_SAFE) { + /* see if (a-1)/2 is prime */ + if ((err = mp_sub_d(a, 1, a)) != MP_OKAY) { goto error; } + if ((err = mp_div_2(a, a)) != MP_OKAY) { goto error; } + + /* is it prime? */ + if ((err = mp_prime_is_prime(a, t, &res)) != MP_OKAY) { goto error; } + } + } while (res == MP_NO); + + if (flags & LTM_PRIME_SAFE) { + /* restore a to the original value */ + if ((err = mp_mul_2(a, a)) != MP_OKAY) { goto error; } + if ((err = mp_add_d(a, 1, a)) != MP_OKAY) { goto error; } + } + + err = MP_OKAY; +error: + XFREE(tmp); + return err; +} + + +#endif + +/* End: bn_mp_prime_random_ex.c */ + +/* Start: bn_mp_radix_size.c */ +#include +#ifdef BN_MP_RADIX_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* returns size of ASCII reprensentation */ +int mp_radix_size (mp_int * a, int radix, int *size) +{ + int res, digs; + mp_int t; + mp_digit d; + + *size = 0; + + /* special case for binary */ + if (radix == 2) { + *size = mp_count_bits (a) + (a->sign == MP_NEG ? 1 : 0) + 1; + return MP_OKAY; + } + + /* make sure the radix is in range */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* init a copy of the input */ + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* digs is the digit count */ + digs = 0; + + /* if it's negative add one for the sign */ + if (t.sign == MP_NEG) { + ++digs; + t.sign = MP_ZPOS; + } + + /* fetch out all of the digits */ + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + ++digs; + } + mp_clear (&t); + + /* return digs + 1, the 1 is for the NULL byte that would be required. */ + *size = digs + 1; + return MP_OKAY; +} + +#endif + +/* End: bn_mp_radix_size.c */ + +/* Start: bn_mp_radix_smap.c */ +#include +#ifdef BN_MP_RADIX_SMAP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* chars used in radix conversions */ +const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz+/"; +#endif + +/* End: bn_mp_radix_smap.c */ + +/* Start: bn_mp_rand.c */ +#include +#ifdef BN_MP_RAND_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* makes a pseudo-random int of a given size */ +int +mp_rand (mp_int * a, int digits) +{ + int res; + mp_digit d; + + mp_zero (a); + if (digits <= 0) { + return MP_OKAY; + } + + /* first place a random non-zero digit */ + do { + d = ((mp_digit) abs (rand ())); + } while (d == 0); + + if ((res = mp_add_d (a, d, a)) != MP_OKAY) { + return res; + } + + while (digits-- > 0) { + if ((res = mp_lshd (a, 1)) != MP_OKAY) { + return res; + } + + if ((res = mp_add_d (a, ((mp_digit) abs (rand ())), a)) != MP_OKAY) { + return res; + } + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_rand.c */ + +/* Start: bn_mp_read_radix.c */ +#include +#ifdef BN_MP_READ_RADIX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read a string [ASCII] in a given radix */ +int mp_read_radix (mp_int * a, char *str, int radix) +{ + int y, res, neg; + char ch; + + /* make sure the radix is ok */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* if the leading digit is a + * minus set the sign to negative. + */ + if (*str == '-') { + ++str; + neg = MP_NEG; + } else { + neg = MP_ZPOS; + } + + /* set the integer to the default of zero */ + mp_zero (a); + + /* process each digit of the string */ + while (*str) { + /* if the radix < 36 the conversion is case insensitive + * this allows numbers like 1AB and 1ab to represent the same value + * [e.g. in hex] + */ + ch = (char) ((radix < 36) ? toupper (*str) : *str); + for (y = 0; y < 64; y++) { + if (ch == mp_s_rmap[y]) { + break; + } + } + + /* if the char was found in the map + * and is less than the given radix add it + * to the number, otherwise exit the loop. + */ + if (y < radix) { + if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) { + return res; + } + if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) { + return res; + } + } else { + break; + } + ++str; + } + + /* set the sign only if a != 0 */ + if (mp_iszero(a) != 1) { + a->sign = neg; + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_read_radix.c */ + +/* Start: bn_mp_read_signed_bin.c */ +#include +#ifdef BN_MP_READ_SIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* read signed bin, big endian, first byte is 0==positive or 1==negative */ +int +mp_read_signed_bin (mp_int * a, unsigned char *b, int c) +{ + int res; + + /* read magnitude */ + if ((res = mp_read_unsigned_bin (a, b + 1, c - 1)) != MP_OKAY) { + return res; + } + + /* first byte is 0 for positive, non-zero for negative */ + if (b[0] == 0) { + a->sign = MP_ZPOS; + } else { + a->sign = MP_NEG; + } + + return MP_OKAY; +} +#endif + +/* End: bn_mp_read_signed_bin.c */ + +/* Start: bn_mp_read_unsigned_bin.c */ +#include +#ifdef BN_MP_READ_UNSIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reads a unsigned char array, assumes the msb is stored first [big endian] */ +int +mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) +{ + int res; + + /* make sure there are at least two digits */ + if (a->alloc < 2) { + if ((res = mp_grow(a, 2)) != MP_OKAY) { + return res; + } + } + + /* zero the int */ + mp_zero (a); + + /* read the bytes in */ + while (c-- > 0) { + if ((res = mp_mul_2d (a, 8, a)) != MP_OKAY) { + return res; + } + +#ifndef MP_8BIT + a->dp[0] |= *b++; + a->used += 1; +#else + a->dp[0] = (*b & MP_MASK); + a->dp[1] |= ((*b++ >> 7U) & 1); + a->used += 2; +#endif + } + mp_clamp (a); + return MP_OKAY; +} +#endif + +/* End: bn_mp_read_unsigned_bin.c */ + +/* Start: bn_mp_reduce.c */ +#include +#ifdef BN_MP_REDUCE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces x mod m, assumes 0 < x < m**2, mu is + * precomputed via mp_reduce_setup. + * From HAC pp.604 Algorithm 14.42 + */ +int +mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +{ + mp_int q; + int res, um = m->used; + + /* q = x */ + if ((res = mp_init_copy (&q, x)) != MP_OKAY) { + return res; + } + + /* q1 = x / b**(k-1) */ + mp_rshd (&q, um - 1); + + /* according to HAC this optimization is ok */ + if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) { + if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) { + goto CLEANUP; + } + } else { +#ifdef BN_S_MP_MUL_HIGH_DIGS_C + if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + goto CLEANUP; + } +#elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) + if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + goto CLEANUP; + } +#else + { + res = MP_VAL; + goto CLEANUP; + } +#endif + } + + /* q3 = q2 / b**(k+1) */ + mp_rshd (&q, um + 1); + + /* x = x mod b**(k+1), quick (no division) */ + if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) { + goto CLEANUP; + } + + /* q = q * m mod b**(k+1), quick (no division) */ + if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) { + goto CLEANUP; + } + + /* x = x - q */ + if ((res = mp_sub (x, &q, x)) != MP_OKAY) { + goto CLEANUP; + } + + /* If x < 0, add b**(k+1) to it */ + if (mp_cmp_d (x, 0) == MP_LT) { + mp_set (&q, 1); + if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) + goto CLEANUP; + if ((res = mp_add (x, &q, x)) != MP_OKAY) + goto CLEANUP; + } + + /* Back off if it's too big */ + while (mp_cmp (x, m) != MP_LT) { + if ((res = s_mp_sub (x, m, x)) != MP_OKAY) { + goto CLEANUP; + } + } + +CLEANUP: + mp_clear (&q); + + return res; +} +#endif + +/* End: bn_mp_reduce.c */ + +/* Start: bn_mp_reduce_2k.c */ +#include +#ifdef BN_MP_REDUCE_2K_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces a modulo n where n is of the form 2**p - d */ +int +mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +{ + mp_int q; + int p, res; + + if ((res = mp_init(&q)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(n); +top: + /* q = a/2**p, a = a mod 2**p */ + if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (d != 1) { + /* q = q * d */ + if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) { + goto ERR; + } + } + + /* a = a + q */ + if ((res = s_mp_add(a, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (mp_cmp_mag(a, n) != MP_LT) { + s_mp_sub(a, n, a); + goto top; + } + +ERR: + mp_clear(&q); + return res; +} + +#endif + +/* End: bn_mp_reduce_2k.c */ + +/* Start: bn_mp_reduce_2k_setup.c */ +#include +#ifdef BN_MP_REDUCE_2K_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +int +mp_reduce_2k_setup(mp_int *a, mp_digit *d) +{ + int res, p; + mp_int tmp; + + if ((res = mp_init(&tmp)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(a); + if ((res = mp_2expt(&tmp, p)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) { + mp_clear(&tmp); + return res; + } + + *d = tmp.dp[0]; + mp_clear(&tmp); + return MP_OKAY; +} +#endif + +/* End: bn_mp_reduce_2k_setup.c */ + +/* Start: bn_mp_reduce_is_2k.c */ +#include +#ifdef BN_MP_REDUCE_IS_2K_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if mp_reduce_2k can be used */ +int mp_reduce_is_2k(mp_int *a) +{ + int ix, iy, iw; + mp_digit iz; + + if (a->used == 0) { + return 0; + } else if (a->used == 1) { + return 1; + } else if (a->used > 1) { + iy = mp_count_bits(a); + iz = 1; + iw = 1; + + /* Test every bit from the second digit up, must be 1 */ + for (ix = DIGIT_BIT; ix < iy; ix++) { + if ((a->dp[iw] & iz) == 0) { + return 0; + } + iz <<= 1; + if (iz > (mp_digit)MP_MASK) { + ++iw; + iz = 1; + } + } + } + return 1; +} + +#endif + +/* End: bn_mp_reduce_is_2k.c */ + +/* Start: bn_mp_reduce_setup.c */ +#include +#ifdef BN_MP_REDUCE_SETUP_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* pre-calculate the value required for Barrett reduction + * For a given modulus "b" it calulates the value required in "a" + */ +int mp_reduce_setup (mp_int * a, mp_int * b) +{ + int res; + + if ((res = mp_2expt (a, b->used * 2 * DIGIT_BIT)) != MP_OKAY) { + return res; + } + return mp_div (a, b, a, NULL); +} +#endif + +/* End: bn_mp_reduce_setup.c */ + +/* Start: bn_mp_rshd.c */ +#include +#ifdef BN_MP_RSHD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shift right a certain amount of digits */ +void mp_rshd (mp_int * a, int b) +{ + int x; + + /* if b <= 0 then ignore it */ + if (b <= 0) { + return; + } + + /* if b > used then simply zero it and return */ + if (a->used <= b) { + mp_zero (a); + return; + } + + { + register mp_digit *bottom, *top; + + /* shift the digits down */ + + /* bottom */ + bottom = a->dp; + + /* top [offset into digits] */ + top = a->dp + b; + + /* this is implemented as a sliding window where + * the window is b-digits long and digits from + * the top of the window are copied to the bottom + * + * e.g. + + b-2 | b-1 | b0 | b1 | b2 | ... | bb | ----> + /\ | ----> + \-------------------/ ----> + */ + for (x = 0; x < (a->used - b); x++) { + *bottom++ = *top++; + } + + /* zero the top digits */ + for (; x < a->used; x++) { + *bottom++ = 0; + } + } + + /* remove excess digits */ + a->used -= b; +} +#endif + +/* End: bn_mp_rshd.c */ + +/* Start: bn_mp_set.c */ +#include +#ifdef BN_MP_SET_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set to a digit */ +void mp_set (mp_int * a, mp_digit b) +{ + mp_zero (a); + a->dp[0] = b & MP_MASK; + a->used = (a->dp[0] != 0) ? 1 : 0; +} +#endif + +/* End: bn_mp_set.c */ + +/* Start: bn_mp_set_int.c */ +#include +#ifdef BN_MP_SET_INT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set a 32-bit const */ +int mp_set_int (mp_int * a, unsigned long b) +{ + int x, res; + + mp_zero (a); + + /* set four bits at a time */ + for (x = 0; x < 8; x++) { + /* shift the number up four bits */ + if ((res = mp_mul_2d (a, 4, a)) != MP_OKAY) { + return res; + } + + /* OR in the top four bits of the source */ + a->dp[0] |= (b >> 28) & 15; + + /* shift the source up to the next four bits */ + b <<= 4; + + /* ensure that digits are not clamped off */ + a->used += 1; + } + mp_clamp (a); + return MP_OKAY; +} +#endif + +/* End: bn_mp_set_int.c */ + +/* Start: bn_mp_shrink.c */ +#include +#ifdef BN_MP_SHRINK_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* shrink a bignum */ +int mp_shrink (mp_int * a) +{ + mp_digit *tmp; + if (a->alloc != a->used && a->used > 0) { + if ((tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * a->used)) == NULL) { + return MP_MEM; + } + a->dp = tmp; + a->alloc = a->used; + } + return MP_OKAY; +} +#endif + +/* End: bn_mp_shrink.c */ + +/* Start: bn_mp_signed_bin_size.c */ +#include +#ifdef BN_MP_SIGNED_BIN_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the size for an signed equivalent */ +int mp_signed_bin_size (mp_int * a) +{ + return 1 + mp_unsigned_bin_size (a); +} +#endif + +/* End: bn_mp_signed_bin_size.c */ + +/* Start: bn_mp_sqr.c */ +#include +#ifdef BN_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* computes b = a*a */ +int +mp_sqr (mp_int * a, mp_int * b) +{ + int res; + +#ifdef BN_MP_TOOM_SQR_C + /* use Toom-Cook? */ + if (a->used >= TOOM_SQR_CUTOFF) { + res = mp_toom_sqr(a, b); + /* Karatsuba? */ + } else +#endif +#ifdef BN_MP_KARATSUBA_SQR_C +if (a->used >= KARATSUBA_SQR_CUTOFF) { + res = mp_karatsuba_sqr (a, b); + } else +#endif + { +#ifdef BN_FAST_S_MP_SQR_C + /* can we use the fast comba multiplier? */ + if ((a->used * 2 + 1) < MP_WARRAY && + a->used < + (1 << (sizeof(mp_word) * CHAR_BIT - 2*DIGIT_BIT - 1))) { + res = fast_s_mp_sqr (a, b); + } else +#endif +#ifdef BN_S_MP_SQR_C + res = s_mp_sqr (a, b); +#else + res = MP_VAL; +#endif + } + b->sign = MP_ZPOS; + return res; +} +#endif + +/* End: bn_mp_sqr.c */ + +/* Start: bn_mp_sqrmod.c */ +#include +#ifdef BN_MP_SQRMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* c = a * a (mod b) */ +int +mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) +{ + int res; + mp_int t; + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_sqr (a, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, b, c); + mp_clear (&t); + return res; +} +#endif + +/* End: bn_mp_sqrmod.c */ + +/* Start: bn_mp_sqrt.c */ +#include +#ifdef BN_MP_SQRT_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* this function is less generic than mp_n_root, simpler and faster */ +int mp_sqrt(mp_int *arg, mp_int *ret) +{ + int res; + mp_int t1,t2; + + /* must be positive */ + if (arg->sign == MP_NEG) { + return MP_VAL; + } + + /* easy out */ + if (mp_iszero(arg) == MP_YES) { + mp_zero(ret); + return MP_OKAY; + } + + if ((res = mp_init_copy(&t1, arg)) != MP_OKAY) { + return res; + } + + if ((res = mp_init(&t2)) != MP_OKAY) { + goto E2; + } + + /* First approx. (not very bad for large arg) */ + mp_rshd (&t1,t1.used/2); + + /* t1 > 0 */ + if ((res = mp_div(arg,&t1,&t2,NULL)) != MP_OKAY) { + goto E1; + } + if ((res = mp_add(&t1,&t2,&t1)) != MP_OKAY) { + goto E1; + } + if ((res = mp_div_2(&t1,&t1)) != MP_OKAY) { + goto E1; + } + /* And now t1 > sqrt(arg) */ + do { + if ((res = mp_div(arg,&t1,&t2,NULL)) != MP_OKAY) { + goto E1; + } + if ((res = mp_add(&t1,&t2,&t1)) != MP_OKAY) { + goto E1; + } + if ((res = mp_div_2(&t1,&t1)) != MP_OKAY) { + goto E1; + } + /* t1 >= sqrt(arg) >= t2 at this point */ + } while (mp_cmp_mag(&t1,&t2) == MP_GT); + + mp_exch(&t1,ret); + +E1: mp_clear(&t2); +E2: mp_clear(&t1); + return res; +} + +#endif + +/* End: bn_mp_sqrt.c */ + +/* Start: bn_mp_sub.c */ +#include +#ifdef BN_MP_SUB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* high level subtraction (handles signs) */ +int +mp_sub (mp_int * a, mp_int * b, mp_int * c) +{ + int sa, sb, res; + + sa = a->sign; + sb = b->sign; + + if (sa != sb) { + /* subtract a negative from a positive, OR */ + /* subtract a positive from a negative. */ + /* In either case, ADD their magnitudes, */ + /* and use the sign of the first number. */ + c->sign = sa; + res = s_mp_add (a, b, c); + } else { + /* subtract a positive from a positive, OR */ + /* subtract a negative from a negative. */ + /* First, take the difference between their */ + /* magnitudes, then... */ + if (mp_cmp_mag (a, b) != MP_LT) { + /* Copy the sign from the first */ + c->sign = sa; + /* The first has a larger or equal magnitude */ + res = s_mp_sub (a, b, c); + } else { + /* The result has the *opposite* sign from */ + /* the first number. */ + c->sign = (sa == MP_ZPOS) ? MP_NEG : MP_ZPOS; + /* The second has a larger magnitude */ + res = s_mp_sub (b, a, c); + } + } + return res; +} + +#endif + +/* End: bn_mp_sub.c */ + +/* Start: bn_mp_sub_d.c */ +#include +#ifdef BN_MP_SUB_D_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* single digit subtraction */ +int +mp_sub_d (mp_int * a, mp_digit b, mp_int * c) +{ + mp_digit *tmpa, *tmpc, mu; + int res, ix, oldused; + + /* grow c as required */ + if (c->alloc < a->used + 1) { + if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) { + return res; + } + } + + /* if a is negative just do an unsigned + * addition [with fudged signs] + */ + if (a->sign == MP_NEG) { + a->sign = MP_ZPOS; + res = mp_add_d(a, b, c); + a->sign = c->sign = MP_NEG; + return res; + } + + /* setup regs */ + oldused = c->used; + tmpa = a->dp; + tmpc = c->dp; + + /* if a <= b simply fix the single digit */ + if ((a->used == 1 && a->dp[0] <= b) || a->used == 0) { + if (a->used == 1) { + *tmpc++ = b - *tmpa; + } else { + *tmpc++ = b; + } + ix = 1; + + /* negative/1digit */ + c->sign = MP_NEG; + c->used = 1; + } else { + /* positive/size */ + c->sign = MP_ZPOS; + c->used = a->used; + + /* subtract first digit */ + *tmpc = *tmpa++ - b; + mu = *tmpc >> (sizeof(mp_digit) * CHAR_BIT - 1); + *tmpc++ &= MP_MASK; + + /* handle rest of the digits */ + for (ix = 1; ix < a->used; ix++) { + *tmpc = *tmpa++ - mu; + mu = *tmpc >> (sizeof(mp_digit) * CHAR_BIT - 1); + *tmpc++ &= MP_MASK; + } + } + + /* zero excess digits */ + while (ix++ < oldused) { + *tmpc++ = 0; + } + mp_clamp(c); + return MP_OKAY; +} + +#endif + +/* End: bn_mp_sub_d.c */ + +/* Start: bn_mp_submod.c */ +#include +#ifdef BN_MP_SUBMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* d = a - b (mod c) */ +int +mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +{ + int res; + mp_int t; + + + if ((res = mp_init (&t)) != MP_OKAY) { + return res; + } + + if ((res = mp_sub (a, b, &t)) != MP_OKAY) { + mp_clear (&t); + return res; + } + res = mp_mod (&t, c, d); + mp_clear (&t); + return res; +} +#endif + +/* End: bn_mp_submod.c */ + +/* Start: bn_mp_to_signed_bin.c */ +#include +#ifdef BN_MP_TO_SIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in signed [big endian] format */ +int +mp_to_signed_bin (mp_int * a, unsigned char *b) +{ + int res; + + if ((res = mp_to_unsigned_bin (a, b + 1)) != MP_OKAY) { + return res; + } + b[0] = (unsigned char) ((a->sign == MP_ZPOS) ? 0 : 1); + return MP_OKAY; +} +#endif + +/* End: bn_mp_to_signed_bin.c */ + +/* Start: bn_mp_to_unsigned_bin.c */ +#include +#ifdef BN_MP_TO_UNSIGNED_BIN_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in unsigned [big endian] format */ +int +mp_to_unsigned_bin (mp_int * a, unsigned char *b) +{ + int x, res; + mp_int t; + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + x = 0; + while (mp_iszero (&t) == 0) { +#ifndef MP_8BIT + b[x++] = (unsigned char) (t.dp[0] & 255); +#else + b[x++] = (unsigned char) (t.dp[0] | ((t.dp[1] & 0x01) << 7)); +#endif + if ((res = mp_div_2d (&t, 8, &t, NULL)) != MP_OKAY) { + mp_clear (&t); + return res; + } + } + bn_reverse (b, x); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_mp_to_unsigned_bin.c */ + +/* Start: bn_mp_toom_mul.c */ +#include +#ifdef BN_MP_TOOM_MUL_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplication using the Toom-Cook 3-way algorithm + * + * Much more complicated than Karatsuba but has a lower asymptotic running time of + * O(N**1.464). This algorithm is only particularly useful on VERY large + * inputs (we're talking 1000s of digits here...). +*/ +int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) +{ + mp_int w0, w1, w2, w3, w4, tmp1, tmp2, a0, a1, a2, b0, b1, b2; + int res, B; + + /* init temps */ + if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, + &a0, &a1, &a2, &b0, &b1, + &b2, &tmp1, &tmp2, NULL)) != MP_OKAY) { + return res; + } + + /* B */ + B = MIN(a->used, b->used) / 3; + + /* a = a2 * B**2 + a1 * B + a0 */ + if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(a, &a1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a1, B); + mp_mod_2d(&a1, DIGIT_BIT * B, &a1); + + if ((res = mp_copy(a, &a2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a2, B*2); + + /* b = b2 * B**2 + b1 * B + b0 */ + if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(b, &b1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&b1, B); + mp_mod_2d(&b1, DIGIT_BIT * B, &b1); + + if ((res = mp_copy(b, &b2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&b2, B*2); + + /* w0 = a0*b0 */ + if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) { + goto ERR; + } + + /* w4 = a2 * b2 */ + if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) { + goto ERR; + } + + /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ + if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) { + goto ERR; + } + + /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ + if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) { + goto ERR; + } + + + /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ + if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) { + goto ERR; + } + + /* now solve the matrix + + 0 0 0 0 1 + 1 2 4 8 16 + 1 1 1 1 1 + 16 8 4 2 1 + 1 0 0 0 0 + + using 12 subtractions, 4 shifts, + 2 small divisions and 1 small multiplication + */ + + /* r1 - r4 */ + if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r0 */ + if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/2 */ + if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3/2 */ + if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) { + goto ERR; + } + /* r2 - r0 - r4 */ + if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1 - 8r0 */ + if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - 8r4 */ + if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + /* 3r2 - r1 - r3 */ + if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/3 */ + if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) { + goto ERR; + } + /* r3/3 */ + if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) { + goto ERR; + } + + /* at this point shift W[n] by B*n */ + if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear_multi(&w0, &w1, &w2, &w3, &w4, + &a0, &a1, &a2, &b0, &b1, + &b2, &tmp1, &tmp2, NULL); + return res; +} + +#endif + +/* End: bn_mp_toom_mul.c */ + +/* Start: bn_mp_toom_sqr.c */ +#include +#ifdef BN_MP_TOOM_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* squaring using Toom-Cook 3-way algorithm */ +int +mp_toom_sqr(mp_int *a, mp_int *b) +{ + mp_int w0, w1, w2, w3, w4, tmp1, a0, a1, a2; + int res, B; + + /* init temps */ + if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, &a0, &a1, &a2, &tmp1, NULL)) != MP_OKAY) { + return res; + } + + /* B */ + B = a->used / 3; + + /* a = a2 * B**2 + a1 * B + a0 */ + if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_copy(a, &a1)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a1, B); + mp_mod_2d(&a1, DIGIT_BIT * B, &a1); + + if ((res = mp_copy(a, &a2)) != MP_OKAY) { + goto ERR; + } + mp_rshd(&a2, B*2); + + /* w0 = a0*a0 */ + if ((res = mp_sqr(&a0, &w0)) != MP_OKAY) { + goto ERR; + } + + /* w4 = a2 * a2 */ + if ((res = mp_sqr(&a2, &w4)) != MP_OKAY) { + goto ERR; + } + + /* w1 = (a2 + 2(a1 + 2a0))**2 */ + if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_sqr(&tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + + /* w3 = (a0 + 2(a1 + 2a2))**2 */ + if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_sqr(&tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + + + /* w2 = (a2 + a1 + a0)**2 */ + if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sqr(&tmp1, &w2)) != MP_OKAY) { + goto ERR; + } + + /* now solve the matrix + + 0 0 0 0 1 + 1 2 4 8 16 + 1 1 1 1 1 + 16 8 4 2 1 + 1 0 0 0 0 + + using 12 subtractions, 4 shifts, 2 small divisions and 1 small multiplication. + */ + + /* r1 - r4 */ + if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r0 */ + if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/2 */ + if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3/2 */ + if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) { + goto ERR; + } + /* r2 - r0 - r4 */ + if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1 - 8r0 */ + if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - 8r4 */ + if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) { + goto ERR; + } + /* 3r2 - r1 - r3 */ + if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) { + goto ERR; + } + /* r1 - r2 */ + if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) { + goto ERR; + } + /* r3 - r2 */ + if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) { + goto ERR; + } + /* r1/3 */ + if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) { + goto ERR; + } + /* r3/3 */ + if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) { + goto ERR; + } + + /* at this point shift W[n] by B*n */ + if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) { + goto ERR; + } + + if ((res = mp_add(&w0, &w1, b)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) { + goto ERR; + } + if ((res = mp_add(&tmp1, b, b)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear_multi(&w0, &w1, &w2, &w3, &w4, &a0, &a1, &a2, &tmp1, NULL); + return res; +} + +#endif + +/* End: bn_mp_toom_sqr.c */ + +/* Start: bn_mp_toradix.c */ +#include +#ifdef BN_MP_TORADIX_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* stores a bignum as a ASCII string in a given radix (2..64) */ +int mp_toradix (mp_int * a, char *str, int radix) +{ + int res, digs; + mp_int t; + mp_digit d; + char *_s = str; + + /* check range of the radix */ + if (radix < 2 || radix > 64) { + return MP_VAL; + } + + /* quick out if its zero */ + if (mp_iszero(a) == 1) { + *str++ = '0'; + *str = '\0'; + return MP_OKAY; + } + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* if it is negative output a - */ + if (t.sign == MP_NEG) { + ++_s; + *str++ = '-'; + t.sign = MP_ZPOS; + } + + digs = 0; + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + *str++ = mp_s_rmap[d]; + ++digs; + } + + /* reverse the digits of the string. In this case _s points + * to the first digit [exluding the sign] of the number] + */ + bn_reverse ((unsigned char *)_s, digs); + + /* append a NULL so the string is properly terminated */ + *str = '\0'; + + mp_clear (&t); + return MP_OKAY; +} + +#endif + +/* End: bn_mp_toradix.c */ + +/* Start: bn_mp_toradix_n.c */ +#include +#ifdef BN_MP_TORADIX_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* stores a bignum as a ASCII string in a given radix (2..64) + * + * Stores upto maxlen-1 chars and always a NULL byte + */ +int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) +{ + int res, digs; + mp_int t; + mp_digit d; + char *_s = str; + + /* check range of the maxlen, radix */ + if (maxlen < 3 || radix < 2 || radix > 64) { + return MP_VAL; + } + + /* quick out if its zero */ + if (mp_iszero(a) == 1) { + *str++ = '0'; + *str = '\0'; + return MP_OKAY; + } + + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* if it is negative output a - */ + if (t.sign == MP_NEG) { + /* we have to reverse our digits later... but not the - sign!! */ + ++_s; + + /* store the flag and mark the number as positive */ + *str++ = '-'; + t.sign = MP_ZPOS; + + /* subtract a char */ + --maxlen; + } + + digs = 0; + while (mp_iszero (&t) == 0) { + if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { + mp_clear (&t); + return res; + } + *str++ = mp_s_rmap[d]; + ++digs; + + if (--maxlen == 1) { + /* no more room */ + break; + } + } + + /* reverse the digits of the string. In this case _s points + * to the first digit [exluding the sign] of the number] + */ + bn_reverse ((unsigned char *)_s, digs); + + /* append a NULL so the string is properly terminated */ + *str = '\0'; + + mp_clear (&t); + return MP_OKAY; +} + +#endif + +/* End: bn_mp_toradix_n.c */ + +/* Start: bn_mp_unsigned_bin_size.c */ +#include +#ifdef BN_MP_UNSIGNED_BIN_SIZE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* get the size for an unsigned equivalent */ +int +mp_unsigned_bin_size (mp_int * a) +{ + int size = mp_count_bits (a); + return (size / 8 + ((size & 7) != 0 ? 1 : 0)); +} +#endif + +/* End: bn_mp_unsigned_bin_size.c */ + +/* Start: bn_mp_xor.c */ +#include +#ifdef BN_MP_XOR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* XOR two ints together */ +int +mp_xor (mp_int * a, mp_int * b, mp_int * c) +{ + int res, ix, px; + mp_int t, *x; + + if (a->used > b->used) { + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + px = b->used; + x = b; + } else { + if ((res = mp_init_copy (&t, b)) != MP_OKAY) { + return res; + } + px = a->used; + x = a; + } + + for (ix = 0; ix < px; ix++) { + + } + mp_clamp (&t); + mp_exch (c, &t); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_mp_xor.c */ + +/* Start: bn_mp_zero.c */ +#include +#ifdef BN_MP_ZERO_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* set to zero */ +void +mp_zero (mp_int * a) +{ + a->sign = MP_ZPOS; + a->used = 0; + memset (a->dp, 0, sizeof (mp_digit) * a->alloc); +} +#endif + +/* End: bn_mp_zero.c */ + +/* Start: bn_prime_tab.c */ +#include +#ifdef BN_PRIME_TAB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +const mp_digit ltm_prime_tab[] = { + 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, + 0x0017, 0x001D, 0x001F, 0x0025, 0x0029, 0x002B, 0x002F, 0x0035, + 0x003B, 0x003D, 0x0043, 0x0047, 0x0049, 0x004F, 0x0053, 0x0059, + 0x0061, 0x0065, 0x0067, 0x006B, 0x006D, 0x0071, 0x007F, +#ifndef MP_8BIT + 0x0083, + 0x0089, 0x008B, 0x0095, 0x0097, 0x009D, 0x00A3, 0x00A7, 0x00AD, + 0x00B3, 0x00B5, 0x00BF, 0x00C1, 0x00C5, 0x00C7, 0x00D3, 0x00DF, + 0x00E3, 0x00E5, 0x00E9, 0x00EF, 0x00F1, 0x00FB, 0x0101, 0x0107, + 0x010D, 0x010F, 0x0115, 0x0119, 0x011B, 0x0125, 0x0133, 0x0137, + + 0x0139, 0x013D, 0x014B, 0x0151, 0x015B, 0x015D, 0x0161, 0x0167, + 0x016F, 0x0175, 0x017B, 0x017F, 0x0185, 0x018D, 0x0191, 0x0199, + 0x01A3, 0x01A5, 0x01AF, 0x01B1, 0x01B7, 0x01BB, 0x01C1, 0x01C9, + 0x01CD, 0x01CF, 0x01D3, 0x01DF, 0x01E7, 0x01EB, 0x01F3, 0x01F7, + 0x01FD, 0x0209, 0x020B, 0x021D, 0x0223, 0x022D, 0x0233, 0x0239, + 0x023B, 0x0241, 0x024B, 0x0251, 0x0257, 0x0259, 0x025F, 0x0265, + 0x0269, 0x026B, 0x0277, 0x0281, 0x0283, 0x0287, 0x028D, 0x0293, + 0x0295, 0x02A1, 0x02A5, 0x02AB, 0x02B3, 0x02BD, 0x02C5, 0x02CF, + + 0x02D7, 0x02DD, 0x02E3, 0x02E7, 0x02EF, 0x02F5, 0x02F9, 0x0301, + 0x0305, 0x0313, 0x031D, 0x0329, 0x032B, 0x0335, 0x0337, 0x033B, + 0x033D, 0x0347, 0x0355, 0x0359, 0x035B, 0x035F, 0x036D, 0x0371, + 0x0373, 0x0377, 0x038B, 0x038F, 0x0397, 0x03A1, 0x03A9, 0x03AD, + 0x03B3, 0x03B9, 0x03C7, 0x03CB, 0x03D1, 0x03D7, 0x03DF, 0x03E5, + 0x03F1, 0x03F5, 0x03FB, 0x03FD, 0x0407, 0x0409, 0x040F, 0x0419, + 0x041B, 0x0425, 0x0427, 0x042D, 0x043F, 0x0443, 0x0445, 0x0449, + 0x044F, 0x0455, 0x045D, 0x0463, 0x0469, 0x047F, 0x0481, 0x048B, + + 0x0493, 0x049D, 0x04A3, 0x04A9, 0x04B1, 0x04BD, 0x04C1, 0x04C7, + 0x04CD, 0x04CF, 0x04D5, 0x04E1, 0x04EB, 0x04FD, 0x04FF, 0x0503, + 0x0509, 0x050B, 0x0511, 0x0515, 0x0517, 0x051B, 0x0527, 0x0529, + 0x052F, 0x0551, 0x0557, 0x055D, 0x0565, 0x0577, 0x0581, 0x058F, + 0x0593, 0x0595, 0x0599, 0x059F, 0x05A7, 0x05AB, 0x05AD, 0x05B3, + 0x05BF, 0x05C9, 0x05CB, 0x05CF, 0x05D1, 0x05D5, 0x05DB, 0x05E7, + 0x05F3, 0x05FB, 0x0607, 0x060D, 0x0611, 0x0617, 0x061F, 0x0623, + 0x062B, 0x062F, 0x063D, 0x0641, 0x0647, 0x0649, 0x064D, 0x0653 +#endif +}; +#endif + +/* End: bn_prime_tab.c */ + +/* Start: bn_reverse.c */ +#include +#ifdef BN_REVERSE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reverse an array, used for radix code */ +void +bn_reverse (unsigned char *s, int len) +{ + int ix, iy; + unsigned char t; + + ix = 0; + iy = len - 1; + while (ix < iy) { + t = s[ix]; + s[ix] = s[iy]; + s[iy] = t; + ++ix; + --iy; + } +} +#endif + +/* End: bn_reverse.c */ + +/* Start: bn_s_mp_add.c */ +#include +#ifdef BN_S_MP_ADD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level addition, based on HAC pp.594, Algorithm 14.7 */ +int +s_mp_add (mp_int * a, mp_int * b, mp_int * c) +{ + mp_int *x; + int olduse, res, min, max; + + /* find sizes, we let |a| <= |b| which means we have to sort + * them. "x" will point to the input with the most digits + */ + if (a->used > b->used) { + min = b->used; + max = a->used; + x = a; + } else { + min = a->used; + max = b->used; + x = b; + } + + /* init result */ + if (c->alloc < max + 1) { + if ((res = mp_grow (c, max + 1)) != MP_OKAY) { + return res; + } + } + + /* get old used digit count and set new one */ + olduse = c->used; + c->used = max + 1; + + { + register mp_digit u, *tmpa, *tmpb, *tmpc; + register int i; + + /* alias for digit pointers */ + + /* first input */ + tmpa = a->dp; + + /* second input */ + tmpb = b->dp; + + /* destination */ + tmpc = c->dp; + + /* zero the carry */ + u = 0; + for (i = 0; i < min; i++) { + /* Compute the sum at one digit, T[i] = A[i] + B[i] + U */ + *tmpc = *tmpa++ + *tmpb++ + u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)DIGIT_BIT); + + /* take away carry bit from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* now copy higher words if any, that is in A+B + * if A or B has more digits add those in + */ + if (min != max) { + for (; i < max; i++) { + /* T[i] = X[i] + U */ + *tmpc = x->dp[i] + u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)DIGIT_BIT); + + /* take away carry bit from T[i] */ + *tmpc++ &= MP_MASK; + } + } + + /* add carry */ + *tmpc++ = u; + + /* clear digits above oldused */ + for (i = c->used; i < olduse; i++) { + *tmpc++ = 0; + } + } + + mp_clamp (c); + return MP_OKAY; +} +#endif + +/* End: bn_s_mp_add.c */ + +/* Start: bn_s_mp_exptmod.c */ +#include +#ifdef BN_S_MP_EXPTMOD_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +#ifdef MP_LOW_MEM + #define TAB_SIZE 32 +#else + #define TAB_SIZE 256 +#endif + +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +{ + mp_int M[TAB_SIZE], res, mu; + mp_digit buf; + int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + + /* find window size */ + x = mp_count_bits (X); + if (x <= 7) { + winsize = 2; + } else if (x <= 36) { + winsize = 3; + } else if (x <= 140) { + winsize = 4; + } else if (x <= 450) { + winsize = 5; + } else if (x <= 1303) { + winsize = 6; + } else if (x <= 3529) { + winsize = 7; + } else { + winsize = 8; + } + +#ifdef MP_LOW_MEM + if (winsize > 5) { + winsize = 5; + } +#endif + + /* init M array */ + /* init first cell */ + if ((err = mp_init(&M[1])) != MP_OKAY) { + return err; + } + + /* now init the second half of the array */ + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + if ((err = mp_init(&M[x])) != MP_OKAY) { + for (y = 1<<(winsize-1); y < x; y++) { + mp_clear (&M[y]); + } + mp_clear(&M[1]); + return err; + } + } + + /* create mu, used for Barrett reduction */ + if ((err = mp_init (&mu)) != MP_OKAY) { + goto LBL_M; + } + if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { + goto LBL_MU; + } + + /* create M table + * + * The M table contains powers of the base, + * e.g. M[x] = G**x mod P + * + * The first half of the table is not + * computed though accept for M[0] and M[1] + */ + if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) { + goto LBL_MU; + } + + /* compute the value at M[1<<(winsize-1)] by squaring + * M[1] (winsize-1) times + */ + if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_MU; + } + + for (x = 0; x < (winsize - 1); x++) { + if ((err = mp_sqr (&M[1 << (winsize - 1)], + &M[1 << (winsize - 1)])) != MP_OKAY) { + goto LBL_MU; + } + if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) + * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) + */ + for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) { + if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { + goto LBL_MU; + } + if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + } + + /* setup result */ + if ((err = mp_init (&res)) != MP_OKAY) { + goto LBL_MU; + } + mp_set (&res, 1); + + /* set initial mode and bit cnt */ + mode = 0; + bitcnt = 1; + buf = 0; + digidx = X->used - 1; + bitcpy = 0; + bitbuf = 0; + + for (;;) { + /* grab next digit as required */ + if (--bitcnt == 0) { + /* if digidx == -1 we are out of digits */ + if (digidx == -1) { + break; + } + /* read next digit and reset the bitcnt */ + buf = X->dp[digidx--]; + bitcnt = (int) DIGIT_BIT; + } + + /* grab the next msb from the exponent */ + y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; + buf <<= (mp_digit)1; + + /* if the bit is zero and mode == 0 then we ignore it + * These represent the leading zero bits before the first 1 bit + * in the exponent. Technically this opt is not required but it + * does lower the # of trivial squaring/reductions used + */ + if (mode == 0 && y == 0) { + continue; + } + + /* if the bit is zero and mode == 1 then we square */ + if (mode == 1 && y == 0) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + continue; + } + + /* else we add it to the window */ + bitbuf |= (y << (winsize - ++bitcpy)); + mode = 2; + + if (bitcpy == winsize) { + /* ok window is filled so square as required and multiply */ + /* square first */ + for (x = 0; x < winsize; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + } + + /* then multiply */ + if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + + /* empty window and reset */ + bitcpy = 0; + bitbuf = 0; + mode = 1; + } + } + + /* if bits remain then square/multiply */ + if (mode == 2 && bitcpy > 0) { + /* square then multiply if the bit is set */ + for (x = 0; x < bitcpy; x++) { + if ((err = mp_sqr (&res, &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + + bitbuf <<= 1; + if ((bitbuf & (1 << winsize)) != 0) { + /* then multiply */ + if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { + goto LBL_RES; + } + if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + goto LBL_RES; + } + } + } + } + + mp_exch (&res, Y); + err = MP_OKAY; +LBL_RES:mp_clear (&res); +LBL_MU:mp_clear (&mu); +LBL_M: + mp_clear(&M[1]); + for (x = 1<<(winsize-1); x < (1 << winsize); x++) { + mp_clear (&M[x]); + } + return err; +} +#endif + +/* End: bn_s_mp_exptmod.c */ + +/* Start: bn_s_mp_mul_digs.c */ +#include +#ifdef BN_S_MP_MUL_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplies |a| * |b| and only computes upto digs digits of result + * HAC pp. 595, Algorithm 14.12 Modified so you can control how + * many digits of output are created. + */ +int +s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + mp_int t; + int res, pa, pb, ix, iy; + mp_digit u; + mp_word r; + mp_digit tmpx, *tmpt, *tmpy; + + /* can we use the fast multiplier? */ + if (((digs) < MP_WARRAY) && + MIN (a->used, b->used) < + (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_s_mp_mul_digs (a, b, c, digs); + } + + if ((res = mp_init_size (&t, digs)) != MP_OKAY) { + return res; + } + t.used = digs; + + /* compute the digits of the product directly */ + pa = a->used; + for (ix = 0; ix < pa; ix++) { + /* set the carry to zero */ + u = 0; + + /* limit ourselves to making digs digits of output */ + pb = MIN (b->used, digs - ix); + + /* setup some aliases */ + /* copy of the digit from a used within the nested loop */ + tmpx = a->dp[ix]; + + /* an alias for the destination shifted ix places */ + tmpt = t.dp + ix; + + /* an alias for the digits of b */ + tmpy = b->dp; + + /* compute the columns of the output and propagate the carry */ + for (iy = 0; iy < pb; iy++) { + /* compute the column as a mp_word */ + r = ((mp_word)*tmpt) + + ((mp_word)tmpx) * ((mp_word)*tmpy++) + + ((mp_word) u); + + /* the new column is the lower part of the result */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get the carry word from the result */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + /* set carry if it is placed below digs */ + if (ix + iy < digs) { + *tmpt = u; + } + } + + mp_clamp (&t); + mp_exch (&t, c); + + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_s_mp_mul_digs.c */ + +/* Start: bn_s_mp_mul_high_digs.c */ +#include +#ifdef BN_S_MP_MUL_HIGH_DIGS_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* multiplies |a| * |b| and does not compute the lower digs digits + * [meant to get the higher part of the product] + */ +int +s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +{ + mp_int t; + int res, pa, pb, ix, iy; + mp_digit u; + mp_word r; + mp_digit tmpx, *tmpt, *tmpy; + + /* can we use the fast multiplier? */ +#ifdef BN_FAST_S_MP_MUL_HIGH_DIGS_C + if (((a->used + b->used + 1) < MP_WARRAY) + && MIN (a->used, b->used) < (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) { + return fast_s_mp_mul_high_digs (a, b, c, digs); + } +#endif + + if ((res = mp_init_size (&t, a->used + b->used + 1)) != MP_OKAY) { + return res; + } + t.used = a->used + b->used + 1; + + pa = a->used; + pb = b->used; + for (ix = 0; ix < pa; ix++) { + /* clear the carry */ + u = 0; + + /* left hand side of A[ix] * B[iy] */ + tmpx = a->dp[ix]; + + /* alias to the address of where the digits will be stored */ + tmpt = &(t.dp[digs]); + + /* alias for where to read the right hand side from */ + tmpy = b->dp + (digs - ix); + + for (iy = digs - ix; iy < pb; iy++) { + /* calculate the double precision result */ + r = ((mp_word)*tmpt) + + ((mp_word)tmpx) * ((mp_word)*tmpy++) + + ((mp_word) u); + + /* get the lower part */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* carry the carry */ + u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); + } + *tmpt = u; + } + mp_clamp (&t); + mp_exch (&t, c); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_s_mp_mul_high_digs.c */ + +/* Start: bn_s_mp_sqr.c */ +#include +#ifdef BN_S_MP_SQR_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ +int +s_mp_sqr (mp_int * a, mp_int * b) +{ + mp_int t; + int res, ix, iy, pa; + mp_word r; + mp_digit u, tmpx, *tmpt; + + pa = a->used; + if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) { + return res; + } + + /* default used is maximum possible size */ + t.used = 2*pa + 1; + + for (ix = 0; ix < pa; ix++) { + /* first calculate the digit at 2*ix */ + /* calculate double precision result */ + r = ((mp_word) t.dp[2*ix]) + + ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); + + /* store lower part in result */ + t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get the carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + + /* left hand side of A[ix] * A[iy] */ + tmpx = a->dp[ix]; + + /* alias for where to store the results */ + tmpt = t.dp + (2*ix + 1); + + for (iy = ix + 1; iy < pa; iy++) { + /* first calculate the product */ + r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); + + /* now calculate the double precision result, note we use + * addition instead of *2 since it's easier to optimize + */ + r = ((mp_word) *tmpt) + r + r + ((mp_word) u); + + /* store lower part */ + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + + /* get carry */ + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + } + /* propagate upwards */ + while (u != ((mp_digit) 0)) { + r = ((mp_word) *tmpt) + ((mp_word) u); + *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); + u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); + } + } + + mp_clamp (&t); + mp_exch (&t, b); + mp_clear (&t); + return MP_OKAY; +} +#endif + +/* End: bn_s_mp_sqr.c */ + +/* Start: bn_s_mp_sub.c */ +#include +#ifdef BN_S_MP_SUB_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ +int +s_mp_sub (mp_int * a, mp_int * b, mp_int * c) +{ + int olduse, res, min, max; + + /* find sizes */ + min = b->used; + max = a->used; + + /* init result */ + if (c->alloc < max) { + if ((res = mp_grow (c, max)) != MP_OKAY) { + return res; + } + } + olduse = c->used; + c->used = max; + + { + register mp_digit u, *tmpa, *tmpb, *tmpc; + register int i; + + /* alias for digit pointers */ + tmpa = a->dp; + tmpb = b->dp; + tmpc = c->dp; + + /* set carry to zero */ + u = 0; + for (i = 0; i < min; i++) { + /* T[i] = A[i] - B[i] - U */ + *tmpc = *tmpa++ - *tmpb++ - u; + + /* U = carry bit of T[i] + * Note this saves performing an AND operation since + * if a carry does occur it will propagate all the way to the + * MSB. As a result a single shift is enough to get the carry + */ + u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); + + /* Clear carry from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* now copy higher words if any, e.g. if A has more digits than B */ + for (; i < max; i++) { + /* T[i] = A[i] - U */ + *tmpc = *tmpa++ - u; + + /* U = carry bit of T[i] */ + u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); + + /* Clear carry from T[i] */ + *tmpc++ &= MP_MASK; + } + + /* clear digits above used (since we may not have grown result above) */ + for (i = c->used; i < olduse; i++) { + *tmpc++ = 0; + } + } + + mp_clamp (c); + return MP_OKAY; +} + +#endif + +/* End: bn_s_mp_sub.c */ + +/* Start: bncore.c */ +#include +#ifdef BNCORE_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* Known optimal configurations + + CPU /Compiler /MUL CUTOFF/SQR CUTOFF +------------------------------------------------------------- + Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) + +*/ + +int KARATSUBA_MUL_CUTOFF = 88, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 128, /* Min. number of digits before Karatsuba squaring is used. */ + + TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ + TOOM_SQR_CUTOFF = 400; +#endif + +/* End: bncore.c */ + + +/* EOF */ diff --git a/libtommath/pretty.build b/libtommath/pretty.build new file mode 100644 index 0000000..a708b8a --- /dev/null +++ b/libtommath/pretty.build @@ -0,0 +1,66 @@ +#!/bin/perl -w +# +# Cute little builder for perl +# Total waste of development time... +# +# This will build all the object files and then the archive .a file +# requires GCC, GNU make and a sense of humour. +# +# Tom St Denis +use strict; + +my $count = 0; +my $starttime = time; +my $rate = 0; +print "Scanning for source files...\n"; +foreach my $filename (glob "*.c") { + ++$count; +} +print "Source files to build: $count\nBuilding...\n"; +my $i = 0; +my $lines = 0; +my $filesbuilt = 0; +foreach my $filename (glob "*.c") { + printf("Building %3.2f%%, ", (++$i/$count)*100.0); + if ($i % 4 == 0) { print "/, "; } + if ($i % 4 == 1) { print "-, "; } + if ($i % 4 == 2) { print "\\, "; } + if ($i % 4 == 3) { print "|, "; } + if ($rate > 0) { + my $tleft = ($count - $i) / $rate; + my $tsec = $tleft%60; + my $tmin = ($tleft/60)%60; + my $thour = ($tleft/3600)%60; + printf("%2d:%02d:%02d left, ", $thour, $tmin, $tsec); + } + my $cnt = ($i/$count)*30.0; + my $x = 0; + print "["; + for (; $x < $cnt; $x++) { print "#"; } + for (; $x < 30; $x++) { print " "; } + print "]\r"; + my $tmp = $filename; + $tmp =~ s/\.c/".o"/ge; + if (open(SRC, "<$tmp")) { + close SRC; + } else { + !system("make $tmp > /dev/null 2>/dev/null") or die "\nERROR: Failed to make $tmp!!!\n"; + open( SRC, "<$filename" ) or die "Couldn't open $filename for reading: $!"; + ++$lines while (); + close SRC or die "Error closing $filename after reading: $!"; + ++$filesbuilt; + } + + # update timer + if (time != $starttime) { + my $delay = time - $starttime; + $rate = $i/$delay; + } +} + +# finish building the library +printf("\nFinished building source (%d seconds, %3.2f files per second).\n", time - $starttime, $rate); +print "Compiled approximately $filesbuilt files and $lines lines of code.\n"; +print "Doing final make (building archive...)\n"; +!system("make > /dev/null 2>/dev/null") or die "\nERROR: Failed to perform last make command!!!\n"; +print "done.\n"; \ No newline at end of file diff --git a/libtommath/tombc/grammar.txt b/libtommath/tombc/grammar.txt new file mode 100644 index 0000000..a780e75 --- /dev/null +++ b/libtommath/tombc/grammar.txt @@ -0,0 +1,35 @@ +program := program statement | statement | empty +statement := { statement } | + identifier = numexpression; | + identifier[numexpression] = numexpression; | + function(expressionlist); | + for (identifer = numexpression; numexpression; identifier = numexpression) { statement } | + while (numexpression) { statement } | + if (numexpresion) { statement } elif | + break; | + continue; + +elif := else statement | empty +function := abs | countbits | exptmod | jacobi | print | isprime | nextprime | issquare | readinteger | exit +expressionlist := expressionlist, expression | expression + +// LR(1) !!!? +expression := string | numexpression +numexpression := cmpexpr && cmpexpr | cmpexpr \|\| cmpexpr | cmpexpr +cmpexpr := boolexpr < boolexpr | boolexpr > boolexpr | boolexpr == boolexpr | + boolexpr <= boolexpr | boolexpr >= boolexpr | boolexpr +boolexpr := shiftexpr & shiftexpr | shiftexpr ^ shiftexpr | shiftexpr \| shiftexpr | shiftexpr +shiftexpr := addsubexpr << addsubexpr | addsubexpr >> addsubexpr | addsubexpr +addsubexpr := mulexpr + mulexpr | mulexpr - mulexpr | mulexpr +mulexpr := expr * expr | expr / expr | expr % expr | expr +expr := -nexpr | nexpr +nexpr := integer | identifier | ( numexpression ) | identifier[numexpression] + +identifier := identifer digits | identifier alpha | alpha +alpha := a ... z | A ... Z +integer := hexnumber | digits +hexnumber := 0xhexdigits +hexdigits := hexdigits hexdigit | hexdigit +hexdigit := 0 ... 9 | a ... f | A ... F +digits := digits digit | digit +digit := 0 ... 9 diff --git a/libtommath/tommath.h b/libtommath/tommath.h new file mode 100644 index 0000000..7cc92c2 --- /dev/null +++ b/libtommath/tommath.h @@ -0,0 +1,567 @@ +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ +#ifndef BN_H_ +#define BN_H_ + +#include +#include +#include +#include +#include + +#include + +#undef MIN +#define MIN(x,y) ((x)<(y)?(x):(y)) +#undef MAX +#define MAX(x,y) ((x)>(y)?(x):(y)) + +#ifdef __cplusplus +extern "C" { + +/* C++ compilers don't like assigning void * to mp_digit * */ +#define OPT_CAST(x) (x *) + +#else + +/* C on the other hand doesn't care */ +#define OPT_CAST(x) + +#endif + + +/* detect 64-bit mode if possible */ +#if defined(__x86_64__) + #if !(defined(MP_64BIT) && defined(MP_16BIT) && defined(MP_8BIT)) + #define MP_64BIT + #endif +#endif + +/* some default configurations. + * + * A "mp_digit" must be able to hold DIGIT_BIT + 1 bits + * A "mp_word" must be able to hold 2*DIGIT_BIT + 1 bits + * + * At the very least a mp_digit must be able to hold 7 bits + * [any size beyond that is ok provided it doesn't overflow the data type] + */ +#ifdef MP_8BIT + typedef unsigned char mp_digit; + typedef unsigned short mp_word; +#elif defined(MP_16BIT) + typedef unsigned short mp_digit; + typedef unsigned long mp_word; +#elif defined(MP_64BIT) + /* for GCC only on supported platforms */ +#ifndef CRYPT + typedef unsigned long long ulong64; + typedef signed long long long64; +#endif + + typedef unsigned long mp_digit; + typedef unsigned long mp_word __attribute__ ((mode(TI))); + + #define DIGIT_BIT 60 +#else + /* this is the default case, 28-bit digits */ + + /* this is to make porting into LibTomCrypt easier :-) */ +#ifndef CRYPT + #if defined(_MSC_VER) || defined(__BORLANDC__) + typedef unsigned __int64 ulong64; + typedef signed __int64 long64; + #else + typedef unsigned long long ulong64; + typedef signed long long long64; + #endif +#endif + + typedef unsigned long mp_digit; + typedef ulong64 mp_word; + +#ifdef MP_31BIT + /* this is an extension that uses 31-bit digits */ + #define DIGIT_BIT 31 +#else + /* default case is 28-bit digits, defines MP_28BIT as a handy macro to test */ + #define DIGIT_BIT 28 + #define MP_28BIT +#endif +#endif + +/* define heap macros */ +#ifndef CRYPT + /* default to libc stuff */ + #ifndef XMALLOC + #define XMALLOC malloc + #define XFREE free + #define XREALLOC realloc + #define XCALLOC calloc + #else + /* prototypes for our heap functions */ + extern void *XMALLOC(size_t n); + extern void *REALLOC(void *p, size_t n); + extern void *XCALLOC(size_t n, size_t s); + extern void XFREE(void *p); + #endif +#endif + + +/* otherwise the bits per digit is calculated automatically from the size of a mp_digit */ +#ifndef DIGIT_BIT + #define DIGIT_BIT ((int)((CHAR_BIT * sizeof(mp_digit) - 1))) /* bits per digit */ +#endif + +#define MP_DIGIT_BIT DIGIT_BIT +#define MP_MASK ((((mp_digit)1)<<((mp_digit)DIGIT_BIT))-((mp_digit)1)) +#define MP_DIGIT_MAX MP_MASK + +/* equalities */ +#define MP_LT -1 /* less than */ +#define MP_EQ 0 /* equal to */ +#define MP_GT 1 /* greater than */ + +#define MP_ZPOS 0 /* positive integer */ +#define MP_NEG 1 /* negative */ + +#define MP_OKAY 0 /* ok result */ +#define MP_MEM -2 /* out of mem */ +#define MP_VAL -3 /* invalid input */ +#define MP_RANGE MP_VAL + +#define MP_YES 1 /* yes response */ +#define MP_NO 0 /* no response */ + +/* Primality generation flags */ +#define LTM_PRIME_BBS 0x0001 /* BBS style prime */ +#define LTM_PRIME_SAFE 0x0002 /* Safe prime (p-1)/2 == prime */ +#define LTM_PRIME_2MSB_OFF 0x0004 /* force 2nd MSB to 0 */ +#define LTM_PRIME_2MSB_ON 0x0008 /* force 2nd MSB to 1 */ + +typedef int mp_err; + +/* you'll have to tune these... */ +extern int KARATSUBA_MUL_CUTOFF, + KARATSUBA_SQR_CUTOFF, + TOOM_MUL_CUTOFF, + TOOM_SQR_CUTOFF; + +/* define this to use lower memory usage routines (exptmods mostly) */ +/* #define MP_LOW_MEM */ + +/* default precision */ +#ifndef MP_PREC + #ifndef MP_LOW_MEM + #define MP_PREC 64 /* default digits of precision */ + #else + #define MP_PREC 8 /* default digits of precision */ + #endif +#endif + +/* size of comba arrays, should be at least 2 * 2**(BITS_PER_WORD - BITS_PER_DIGIT*2) */ +#define MP_WARRAY (1 << (sizeof(mp_word) * CHAR_BIT - 2 * DIGIT_BIT + 1)) + +/* the infamous mp_int structure */ +typedef struct { + int used, alloc, sign; + mp_digit *dp; +} mp_int; + +/* callback for mp_prime_random, should fill dst with random bytes and return how many read [upto len] */ +typedef int ltm_prime_callback(unsigned char *dst, int len, void *dat); + + +#define USED(m) ((m)->used) +#define DIGIT(m,k) ((m)->dp[(k)]) +#define SIGN(m) ((m)->sign) + +/* error code to char* string */ +char *mp_error_to_string(int code); + +/* ---> init and deinit bignum functions <--- */ +/* init a bignum */ +int mp_init(mp_int *a); + +/* free a bignum */ +void mp_clear(mp_int *a); + +/* init a null terminated series of arguments */ +int mp_init_multi(mp_int *mp, ...); + +/* clear a null terminated series of arguments */ +void mp_clear_multi(mp_int *mp, ...); + +/* exchange two ints */ +void mp_exch(mp_int *a, mp_int *b); + +/* shrink ram required for a bignum */ +int mp_shrink(mp_int *a); + +/* grow an int to a given size */ +int mp_grow(mp_int *a, int size); + +/* init to a given number of digits */ +int mp_init_size(mp_int *a, int size); + +/* ---> Basic Manipulations <--- */ +#define mp_iszero(a) (((a)->used == 0) ? MP_YES : MP_NO) +#define mp_iseven(a) (((a)->used > 0 && (((a)->dp[0] & 1) == 0)) ? MP_YES : MP_NO) +#define mp_isodd(a) (((a)->used > 0 && (((a)->dp[0] & 1) == 1)) ? MP_YES : MP_NO) + +/* set to zero */ +void mp_zero(mp_int *a); + +/* set to a digit */ +void mp_set(mp_int *a, mp_digit b); + +/* set a 32-bit const */ +int mp_set_int(mp_int *a, unsigned long b); + +/* get a 32-bit value */ +unsigned long mp_get_int(mp_int * a); + +/* initialize and set a digit */ +int mp_init_set (mp_int * a, mp_digit b); + +/* initialize and set 32-bit value */ +int mp_init_set_int (mp_int * a, unsigned long b); + +/* copy, b = a */ +int mp_copy(mp_int *a, mp_int *b); + +/* inits and copies, a = b */ +int mp_init_copy(mp_int *a, mp_int *b); + +/* trim unused digits */ +void mp_clamp(mp_int *a); + +/* ---> digit manipulation <--- */ + +/* right shift by "b" digits */ +void mp_rshd(mp_int *a, int b); + +/* left shift by "b" digits */ +int mp_lshd(mp_int *a, int b); + +/* c = a / 2**b */ +int mp_div_2d(mp_int *a, int b, mp_int *c, mp_int *d); + +/* b = a/2 */ +int mp_div_2(mp_int *a, mp_int *b); + +/* c = a * 2**b */ +int mp_mul_2d(mp_int *a, int b, mp_int *c); + +/* b = a*2 */ +int mp_mul_2(mp_int *a, mp_int *b); + +/* c = a mod 2**d */ +int mp_mod_2d(mp_int *a, int b, mp_int *c); + +/* computes a = 2**b */ +int mp_2expt(mp_int *a, int b); + +/* Counts the number of lsbs which are zero before the first zero bit */ +int mp_cnt_lsb(mp_int *a); + +/* I Love Earth! */ + +/* makes a pseudo-random int of a given size */ +int mp_rand(mp_int *a, int digits); + +/* ---> binary operations <--- */ +/* c = a XOR b */ +int mp_xor(mp_int *a, mp_int *b, mp_int *c); + +/* c = a OR b */ +int mp_or(mp_int *a, mp_int *b, mp_int *c); + +/* c = a AND b */ +int mp_and(mp_int *a, mp_int *b, mp_int *c); + +/* ---> Basic arithmetic <--- */ + +/* b = -a */ +int mp_neg(mp_int *a, mp_int *b); + +/* b = |a| */ +int mp_abs(mp_int *a, mp_int *b); + +/* compare a to b */ +int mp_cmp(mp_int *a, mp_int *b); + +/* compare |a| to |b| */ +int mp_cmp_mag(mp_int *a, mp_int *b); + +/* c = a + b */ +int mp_add(mp_int *a, mp_int *b, mp_int *c); + +/* c = a - b */ +int mp_sub(mp_int *a, mp_int *b, mp_int *c); + +/* c = a * b */ +int mp_mul(mp_int *a, mp_int *b, mp_int *c); + +/* b = a*a */ +int mp_sqr(mp_int *a, mp_int *b); + +/* a/b => cb + d == a */ +int mp_div(mp_int *a, mp_int *b, mp_int *c, mp_int *d); + +/* c = a mod b, 0 <= c < b */ +int mp_mod(mp_int *a, mp_int *b, mp_int *c); + +/* ---> single digit functions <--- */ + +/* compare against a single digit */ +int mp_cmp_d(mp_int *a, mp_digit b); + +/* c = a + b */ +int mp_add_d(mp_int *a, mp_digit b, mp_int *c); + +/* c = a - b */ +int mp_sub_d(mp_int *a, mp_digit b, mp_int *c); + +/* c = a * b */ +int mp_mul_d(mp_int *a, mp_digit b, mp_int *c); + +/* a/b => cb + d == a */ +int mp_div_d(mp_int *a, mp_digit b, mp_int *c, mp_digit *d); + +/* a/3 => 3c + d == a */ +int mp_div_3(mp_int *a, mp_int *c, mp_digit *d); + +/* c = a**b */ +int mp_expt_d(mp_int *a, mp_digit b, mp_int *c); + +/* c = a mod b, 0 <= c < b */ +int mp_mod_d(mp_int *a, mp_digit b, mp_digit *c); + +/* ---> number theory <--- */ + +/* d = a + b (mod c) */ +int mp_addmod(mp_int *a, mp_int *b, mp_int *c, mp_int *d); + +/* d = a - b (mod c) */ +int mp_submod(mp_int *a, mp_int *b, mp_int *c, mp_int *d); + +/* d = a * b (mod c) */ +int mp_mulmod(mp_int *a, mp_int *b, mp_int *c, mp_int *d); + +/* c = a * a (mod b) */ +int mp_sqrmod(mp_int *a, mp_int *b, mp_int *c); + +/* c = 1/a (mod b) */ +int mp_invmod(mp_int *a, mp_int *b, mp_int *c); + +/* c = (a, b) */ +int mp_gcd(mp_int *a, mp_int *b, mp_int *c); + +/* produces value such that U1*a + U2*b = U3 */ +int mp_exteuclid(mp_int *a, mp_int *b, mp_int *U1, mp_int *U2, mp_int *U3); + +/* c = [a, b] or (a*b)/(a, b) */ +int mp_lcm(mp_int *a, mp_int *b, mp_int *c); + +/* finds one of the b'th root of a, such that |c|**b <= |a| + * + * returns error if a < 0 and b is even + */ +int mp_n_root(mp_int *a, mp_digit b, mp_int *c); + +/* special sqrt algo */ +int mp_sqrt(mp_int *arg, mp_int *ret); + +/* is number a square? */ +int mp_is_square(mp_int *arg, int *ret); + +/* computes the jacobi c = (a | n) (or Legendre if b is prime) */ +int mp_jacobi(mp_int *a, mp_int *n, int *c); + +/* used to setup the Barrett reduction for a given modulus b */ +int mp_reduce_setup(mp_int *a, mp_int *b); + +/* Barrett Reduction, computes a (mod b) with a precomputed value c + * + * Assumes that 0 < a <= b*b, note if 0 > a > -(b*b) then you can merely + * compute the reduction as -1 * mp_reduce(mp_abs(a)) [pseudo code]. + */ +int mp_reduce(mp_int *a, mp_int *b, mp_int *c); + +/* setups the montgomery reduction */ +int mp_montgomery_setup(mp_int *a, mp_digit *mp); + +/* computes a = B**n mod b without division or multiplication useful for + * normalizing numbers in a Montgomery system. + */ +int mp_montgomery_calc_normalization(mp_int *a, mp_int *b); + +/* computes x/R == x (mod N) via Montgomery Reduction */ +int mp_montgomery_reduce(mp_int *a, mp_int *m, mp_digit mp); + +/* returns 1 if a is a valid DR modulus */ +int mp_dr_is_modulus(mp_int *a); + +/* sets the value of "d" required for mp_dr_reduce */ +void mp_dr_setup(mp_int *a, mp_digit *d); + +/* reduces a modulo b using the Diminished Radix method */ +int mp_dr_reduce(mp_int *a, mp_int *b, mp_digit mp); + +/* returns true if a can be reduced with mp_reduce_2k */ +int mp_reduce_is_2k(mp_int *a); + +/* determines k value for 2k reduction */ +int mp_reduce_2k_setup(mp_int *a, mp_digit *d); + +/* reduces a modulo b where b is of the form 2**p - k [0 <= a] */ +int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d); + +/* d = a**b (mod c) */ +int mp_exptmod(mp_int *a, mp_int *b, mp_int *c, mp_int *d); + +/* ---> Primes <--- */ + +/* number of primes */ +#ifdef MP_8BIT + #define PRIME_SIZE 31 +#else + #define PRIME_SIZE 256 +#endif + +/* table of first PRIME_SIZE primes */ +extern const mp_digit ltm_prime_tab[]; + +/* result=1 if a is divisible by one of the first PRIME_SIZE primes */ +int mp_prime_is_divisible(mp_int *a, int *result); + +/* performs one Fermat test of "a" using base "b". + * Sets result to 0 if composite or 1 if probable prime + */ +int mp_prime_fermat(mp_int *a, mp_int *b, int *result); + +/* performs one Miller-Rabin test of "a" using base "b". + * Sets result to 0 if composite or 1 if probable prime + */ +int mp_prime_miller_rabin(mp_int *a, mp_int *b, int *result); + +/* This gives [for a given bit size] the number of trials required + * such that Miller-Rabin gives a prob of failure lower than 2^-96 + */ +int mp_prime_rabin_miller_trials(int size); + +/* performs t rounds of Miller-Rabin on "a" using the first + * t prime bases. Also performs an initial sieve of trial + * division. Determines if "a" is prime with probability + * of error no more than (1/4)**t. + * + * Sets result to 1 if probably prime, 0 otherwise + */ +int mp_prime_is_prime(mp_int *a, int t, int *result); + +/* finds the next prime after the number "a" using "t" trials + * of Miller-Rabin. + * + * bbs_style = 1 means the prime must be congruent to 3 mod 4 + */ +int mp_prime_next_prime(mp_int *a, int t, int bbs_style); + +/* makes a truly random prime of a given size (bytes), + * call with bbs = 1 if you want it to be congruent to 3 mod 4 + * + * You have to supply a callback which fills in a buffer with random bytes. "dat" is a parameter you can + * have passed to the callback (e.g. a state or something). This function doesn't use "dat" itself + * so it can be NULL + * + * The prime generated will be larger than 2^(8*size). + */ +#define mp_prime_random(a, t, size, bbs, cb, dat) mp_prime_random_ex(a, t, ((size) * 8) + 1, (bbs==1)?LTM_PRIME_BBS:0, cb, dat) + +/* makes a truly random prime of a given size (bits), + * + * Flags are as follows: + * + * LTM_PRIME_BBS - make prime congruent to 3 mod 4 + * LTM_PRIME_SAFE - make sure (p-1)/2 is prime as well (implies LTM_PRIME_BBS) + * LTM_PRIME_2MSB_OFF - make the 2nd highest bit zero + * LTM_PRIME_2MSB_ON - make the 2nd highest bit one + * + * You have to supply a callback which fills in a buffer with random bytes. "dat" is a parameter you can + * have passed to the callback (e.g. a state or something). This function doesn't use "dat" itself + * so it can be NULL + * + */ +int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback cb, void *dat); + +/* ---> radix conversion <--- */ +int mp_count_bits(mp_int *a); + +int mp_unsigned_bin_size(mp_int *a); +int mp_read_unsigned_bin(mp_int *a, unsigned char *b, int c); +int mp_to_unsigned_bin(mp_int *a, unsigned char *b); + +int mp_signed_bin_size(mp_int *a); +int mp_read_signed_bin(mp_int *a, unsigned char *b, int c); +int mp_to_signed_bin(mp_int *a, unsigned char *b); + +int mp_read_radix(mp_int *a, char *str, int radix); +int mp_toradix(mp_int *a, char *str, int radix); +int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen); +int mp_radix_size(mp_int *a, int radix, int *size); + +int mp_fread(mp_int *a, int radix, FILE *stream); +int mp_fwrite(mp_int *a, int radix, FILE *stream); + +#define mp_read_raw(mp, str, len) mp_read_signed_bin((mp), (str), (len)) +#define mp_raw_size(mp) mp_signed_bin_size(mp) +#define mp_toraw(mp, str) mp_to_signed_bin((mp), (str)) +#define mp_read_mag(mp, str, len) mp_read_unsigned_bin((mp), (str), (len)) +#define mp_mag_size(mp) mp_unsigned_bin_size(mp) +#define mp_tomag(mp, str) mp_to_unsigned_bin((mp), (str)) + +#define mp_tobinary(M, S) mp_toradix((M), (S), 2) +#define mp_tooctal(M, S) mp_toradix((M), (S), 8) +#define mp_todecimal(M, S) mp_toradix((M), (S), 10) +#define mp_tohex(M, S) mp_toradix((M), (S), 16) + +/* lowlevel functions, do not call! */ +int s_mp_add(mp_int *a, mp_int *b, mp_int *c); +int s_mp_sub(mp_int *a, mp_int *b, mp_int *c); +#define s_mp_mul(a, b, c) s_mp_mul_digs(a, b, c, (a)->used + (b)->used + 1) +int fast_s_mp_mul_digs(mp_int *a, mp_int *b, mp_int *c, int digs); +int s_mp_mul_digs(mp_int *a, mp_int *b, mp_int *c, int digs); +int fast_s_mp_mul_high_digs(mp_int *a, mp_int *b, mp_int *c, int digs); +int s_mp_mul_high_digs(mp_int *a, mp_int *b, mp_int *c, int digs); +int fast_s_mp_sqr(mp_int *a, mp_int *b); +int s_mp_sqr(mp_int *a, mp_int *b); +int mp_karatsuba_mul(mp_int *a, mp_int *b, mp_int *c); +int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c); +int mp_karatsuba_sqr(mp_int *a, mp_int *b); +int mp_toom_sqr(mp_int *a, mp_int *b); +int fast_mp_invmod(mp_int *a, mp_int *b, mp_int *c); +int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c); +int fast_mp_montgomery_reduce(mp_int *a, mp_int *m, mp_digit mp); +int mp_exptmod_fast(mp_int *G, mp_int *X, mp_int *P, mp_int *Y, int mode); +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y); +void bn_reverse(unsigned char *s, int len); + +extern const char *mp_s_rmap; + +#ifdef __cplusplus + } +#endif + +#endif + diff --git a/libtommath/tommath.out b/libtommath/tommath.out new file mode 100644 index 0000000..9f62617 --- /dev/null +++ b/libtommath/tommath.out @@ -0,0 +1,139 @@ +\BOOKMARK [0][-]{chapter.1}{Introduction}{} +\BOOKMARK [1][-]{section.1.1}{Multiple Precision Arithmetic}{chapter.1} +\BOOKMARK [2][-]{subsection.1.1.1}{What is Multiple Precision Arithmetic?}{section.1.1} +\BOOKMARK [2][-]{subsection.1.1.2}{The Need for Multiple Precision Arithmetic}{section.1.1} +\BOOKMARK [2][-]{subsection.1.1.3}{Benefits of Multiple Precision Arithmetic}{section.1.1} +\BOOKMARK [1][-]{section.1.2}{Purpose of This Text}{chapter.1} +\BOOKMARK [1][-]{section.1.3}{Discussion and Notation}{chapter.1} +\BOOKMARK [2][-]{subsection.1.3.1}{Notation}{section.1.3} +\BOOKMARK [2][-]{subsection.1.3.2}{Precision Notation}{section.1.3} +\BOOKMARK [2][-]{subsection.1.3.3}{Algorithm Inputs and Outputs}{section.1.3} +\BOOKMARK [2][-]{subsection.1.3.4}{Mathematical Expressions}{section.1.3} +\BOOKMARK [2][-]{subsection.1.3.5}{Work Effort}{section.1.3} +\BOOKMARK [1][-]{section.1.4}{Exercises}{chapter.1} +\BOOKMARK [1][-]{section.1.5}{Introduction to LibTomMath}{chapter.1} +\BOOKMARK [2][-]{subsection.1.5.1}{What is LibTomMath?}{section.1.5} +\BOOKMARK [2][-]{subsection.1.5.2}{Goals of LibTomMath}{section.1.5} +\BOOKMARK [1][-]{section.1.6}{Choice of LibTomMath}{chapter.1} +\BOOKMARK [2][-]{subsection.1.6.1}{Code Base}{section.1.6} +\BOOKMARK [2][-]{subsection.1.6.2}{API Simplicity}{section.1.6} +\BOOKMARK [2][-]{subsection.1.6.3}{Optimizations}{section.1.6} +\BOOKMARK [2][-]{subsection.1.6.4}{Portability and Stability}{section.1.6} +\BOOKMARK [2][-]{subsection.1.6.5}{Choice}{section.1.6} +\BOOKMARK [0][-]{chapter.2}{Getting Started}{} +\BOOKMARK [1][-]{section.2.1}{Library Basics}{chapter.2} +\BOOKMARK [1][-]{section.2.2}{What is a Multiple Precision Integer?}{chapter.2} +\BOOKMARK [2][-]{subsection.2.2.1}{The mp\137int Structure}{section.2.2} +\BOOKMARK [1][-]{section.2.3}{Argument Passing}{chapter.2} +\BOOKMARK [1][-]{section.2.4}{Return Values}{chapter.2} +\BOOKMARK [1][-]{section.2.5}{Initialization and Clearing}{chapter.2} +\BOOKMARK [2][-]{subsection.2.5.1}{Initializing an mp\137int}{section.2.5} +\BOOKMARK [2][-]{subsection.2.5.2}{Clearing an mp\137int}{section.2.5} +\BOOKMARK [1][-]{section.2.6}{Maintenance Algorithms}{chapter.2} +\BOOKMARK [2][-]{subsection.2.6.1}{Augmenting an mp\137int's Precision}{section.2.6} +\BOOKMARK [2][-]{subsection.2.6.2}{Initializing Variable Precision mp\137ints}{section.2.6} +\BOOKMARK [2][-]{subsection.2.6.3}{Multiple Integer Initializations and Clearings}{section.2.6} +\BOOKMARK [2][-]{subsection.2.6.4}{Clamping Excess Digits}{section.2.6} +\BOOKMARK [0][-]{chapter.3}{Basic Operations}{} +\BOOKMARK [1][-]{section.3.1}{Introduction}{chapter.3} +\BOOKMARK [1][-]{section.3.2}{Assigning Values to mp\137int Structures}{chapter.3} +\BOOKMARK [2][-]{subsection.3.2.1}{Copying an mp\137int}{section.3.2} +\BOOKMARK [2][-]{subsection.3.2.2}{Creating a Clone}{section.3.2} +\BOOKMARK [1][-]{section.3.3}{Zeroing an Integer}{chapter.3} +\BOOKMARK [1][-]{section.3.4}{Sign Manipulation}{chapter.3} +\BOOKMARK [2][-]{subsection.3.4.1}{Absolute Value}{section.3.4} +\BOOKMARK [2][-]{subsection.3.4.2}{Integer Negation}{section.3.4} +\BOOKMARK [1][-]{section.3.5}{Small Constants}{chapter.3} +\BOOKMARK [2][-]{subsection.3.5.1}{Setting Small Constants}{section.3.5} +\BOOKMARK [2][-]{subsection.3.5.2}{Setting Large Constants}{section.3.5} +\BOOKMARK [1][-]{section.3.6}{Comparisons}{chapter.3} +\BOOKMARK [2][-]{subsection.3.6.1}{Unsigned Comparisions}{section.3.6} +\BOOKMARK [2][-]{subsection.3.6.2}{Signed Comparisons}{section.3.6} +\BOOKMARK [0][-]{chapter.4}{Basic Arithmetic}{} +\BOOKMARK [1][-]{section.4.1}{Introduction}{chapter.4} +\BOOKMARK [1][-]{section.4.2}{Addition and Subtraction}{chapter.4} +\BOOKMARK [2][-]{subsection.4.2.1}{Low Level Addition}{section.4.2} +\BOOKMARK [2][-]{subsection.4.2.2}{Low Level Subtraction}{section.4.2} +\BOOKMARK [2][-]{subsection.4.2.3}{High Level Addition}{section.4.2} +\BOOKMARK [2][-]{subsection.4.2.4}{High Level Subtraction}{section.4.2} +\BOOKMARK [1][-]{section.4.3}{Bit and Digit Shifting}{chapter.4} +\BOOKMARK [2][-]{subsection.4.3.1}{Multiplication by Two}{section.4.3} +\BOOKMARK [2][-]{subsection.4.3.2}{Division by Two}{section.4.3} +\BOOKMARK [1][-]{section.4.4}{Polynomial Basis Operations}{chapter.4} +\BOOKMARK [2][-]{subsection.4.4.1}{Multiplication by x}{section.4.4} +\BOOKMARK [2][-]{subsection.4.4.2}{Division by x}{section.4.4} +\BOOKMARK [1][-]{section.4.5}{Powers of Two}{chapter.4} +\BOOKMARK [2][-]{subsection.4.5.1}{Multiplication by Power of Two}{section.4.5} +\BOOKMARK [2][-]{subsection.4.5.2}{Division by Power of Two}{section.4.5} +\BOOKMARK [2][-]{subsection.4.5.3}{Remainder of Division by Power of Two}{section.4.5} +\BOOKMARK [0][-]{chapter.5}{Multiplication and Squaring}{} +\BOOKMARK [1][-]{section.5.1}{The Multipliers}{chapter.5} +\BOOKMARK [1][-]{section.5.2}{Multiplication}{chapter.5} +\BOOKMARK [2][-]{subsection.5.2.1}{The Baseline Multiplication}{section.5.2} +\BOOKMARK [2][-]{subsection.5.2.2}{Faster Multiplication by the ``Comba'' Method}{section.5.2} +\BOOKMARK [2][-]{subsection.5.2.3}{Polynomial Basis Multiplication}{section.5.2} +\BOOKMARK [2][-]{subsection.5.2.4}{Karatsuba Multiplication}{section.5.2} +\BOOKMARK [2][-]{subsection.5.2.5}{Toom-Cook 3-Way Multiplication}{section.5.2} +\BOOKMARK [2][-]{subsection.5.2.6}{Signed Multiplication}{section.5.2} +\BOOKMARK [1][-]{section.5.3}{Squaring}{chapter.5} +\BOOKMARK [2][-]{subsection.5.3.1}{The Baseline Squaring Algorithm}{section.5.3} +\BOOKMARK [2][-]{subsection.5.3.2}{Faster Squaring by the ``Comba'' Method}{section.5.3} +\BOOKMARK [2][-]{subsection.5.3.3}{Polynomial Basis Squaring}{section.5.3} +\BOOKMARK [2][-]{subsection.5.3.4}{Karatsuba Squaring}{section.5.3} +\BOOKMARK [2][-]{subsection.5.3.5}{Toom-Cook Squaring}{section.5.3} +\BOOKMARK [2][-]{subsection.5.3.6}{High Level Squaring}{section.5.3} +\BOOKMARK [0][-]{chapter.6}{Modular Reduction}{} +\BOOKMARK [1][-]{section.6.1}{Basics of Modular Reduction}{chapter.6} +\BOOKMARK [1][-]{section.6.2}{The Barrett Reduction}{chapter.6} +\BOOKMARK [2][-]{subsection.6.2.1}{Fixed Point Arithmetic}{section.6.2} +\BOOKMARK [2][-]{subsection.6.2.2}{Choosing a Radix Point}{section.6.2} +\BOOKMARK [2][-]{subsection.6.2.3}{Trimming the Quotient}{section.6.2} +\BOOKMARK [2][-]{subsection.6.2.4}{Trimming the Residue}{section.6.2} +\BOOKMARK [2][-]{subsection.6.2.5}{The Barrett Algorithm}{section.6.2} +\BOOKMARK [2][-]{subsection.6.2.6}{The Barrett Setup Algorithm}{section.6.2} +\BOOKMARK [1][-]{section.6.3}{The Montgomery Reduction}{chapter.6} +\BOOKMARK [2][-]{subsection.6.3.1}{Digit Based Montgomery Reduction}{section.6.3} +\BOOKMARK [2][-]{subsection.6.3.2}{Baseline Montgomery Reduction}{section.6.3} +\BOOKMARK [2][-]{subsection.6.3.3}{Faster ``Comba'' Montgomery Reduction}{section.6.3} +\BOOKMARK [2][-]{subsection.6.3.4}{Montgomery Setup}{section.6.3} +\BOOKMARK [1][-]{section.6.4}{The Diminished Radix Algorithm}{chapter.6} +\BOOKMARK [2][-]{subsection.6.4.1}{Choice of Moduli}{section.6.4} +\BOOKMARK [2][-]{subsection.6.4.2}{Choice of k}{section.6.4} +\BOOKMARK [2][-]{subsection.6.4.3}{Restricted Diminished Radix Reduction}{section.6.4} +\BOOKMARK [2][-]{subsection.6.4.4}{Unrestricted Diminished Radix Reduction}{section.6.4} +\BOOKMARK [1][-]{section.6.5}{Algorithm Comparison}{chapter.6} +\BOOKMARK [0][-]{chapter.7}{Exponentiation}{} +\BOOKMARK [1][-]{section.7.1}{Exponentiation Basics}{chapter.7} +\BOOKMARK [2][-]{subsection.7.1.1}{Single Digit Exponentiation}{section.7.1} +\BOOKMARK [1][-]{section.7.2}{k-ary Exponentiation}{chapter.7} +\BOOKMARK [2][-]{subsection.7.2.1}{Optimal Values of k}{section.7.2} +\BOOKMARK [2][-]{subsection.7.2.2}{Sliding-Window Exponentiation}{section.7.2} +\BOOKMARK [1][-]{section.7.3}{Modular Exponentiation}{chapter.7} +\BOOKMARK [2][-]{subsection.7.3.1}{Barrett Modular Exponentiation}{section.7.3} +\BOOKMARK [1][-]{section.7.4}{Quick Power of Two}{chapter.7} +\BOOKMARK [0][-]{chapter.8}{Higher Level Algorithms}{} +\BOOKMARK [1][-]{section.8.1}{Integer Division with Remainder}{chapter.8} +\BOOKMARK [2][-]{subsection.8.1.1}{Quotient Estimation}{section.8.1} +\BOOKMARK [2][-]{subsection.8.1.2}{Normalized Integers}{section.8.1} +\BOOKMARK [2][-]{subsection.8.1.3}{Radix- Division with Remainder}{section.8.1} +\BOOKMARK [1][-]{section.8.2}{Single Digit Helpers}{chapter.8} +\BOOKMARK [2][-]{subsection.8.2.1}{Single Digit Addition and Subtraction}{section.8.2} +\BOOKMARK [2][-]{subsection.8.2.2}{Single Digit Multiplication}{section.8.2} +\BOOKMARK [2][-]{subsection.8.2.3}{Single Digit Division}{section.8.2} +\BOOKMARK [2][-]{subsection.8.2.4}{Single Digit Root Extraction}{section.8.2} +\BOOKMARK [1][-]{section.8.3}{Random Number Generation}{chapter.8} +\BOOKMARK [1][-]{section.8.4}{Formatted Representations}{chapter.8} +\BOOKMARK [2][-]{subsection.8.4.1}{Reading Radix-n Input}{section.8.4} +\BOOKMARK [2][-]{subsection.8.4.2}{Generating Radix-n Output}{section.8.4} +\BOOKMARK [0][-]{chapter.9}{Number Theoretic Algorithms}{} +\BOOKMARK [1][-]{section.9.1}{Greatest Common Divisor}{chapter.9} +\BOOKMARK [2][-]{subsection.9.1.1}{Complete Greatest Common Divisor}{section.9.1} +\BOOKMARK [1][-]{section.9.2}{Least Common Multiple}{chapter.9} +\BOOKMARK [1][-]{section.9.3}{Jacobi Symbol Computation}{chapter.9} +\BOOKMARK [2][-]{subsection.9.3.1}{Jacobi Symbol}{section.9.3} +\BOOKMARK [1][-]{section.9.4}{Modular Inverse}{chapter.9} +\BOOKMARK [2][-]{subsection.9.4.1}{General Case}{section.9.4} +\BOOKMARK [1][-]{section.9.5}{Primality Tests}{chapter.9} +\BOOKMARK [2][-]{subsection.9.5.1}{Trial Division}{section.9.5} +\BOOKMARK [2][-]{subsection.9.5.2}{The Fermat Test}{section.9.5} +\BOOKMARK [2][-]{subsection.9.5.3}{The Miller-Rabin Test}{section.9.5} diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf new file mode 100644 index 0000000..88e2dc7 Binary files /dev/null and b/libtommath/tommath.pdf differ diff --git a/libtommath/tommath.src b/libtommath/tommath.src new file mode 100644 index 0000000..6ee842d --- /dev/null +++ b/libtommath/tommath.src @@ -0,0 +1,6314 @@ +\documentclass[b5paper]{book} +\usepackage{hyperref} +\usepackage{makeidx} +\usepackage{amssymb} +\usepackage{color} +\usepackage{alltt} +\usepackage{graphicx} +\usepackage{layout} +\def\union{\cup} +\def\intersect{\cap} +\def\getsrandom{\stackrel{\rm R}{\gets}} +\def\cross{\times} +\def\cat{\hspace{0.5em} \| \hspace{0.5em}} +\def\catn{$\|$} +\def\divides{\hspace{0.3em} | \hspace{0.3em}} +\def\nequiv{\not\equiv} +\def\approx{\raisebox{0.2ex}{\mbox{\small $\sim$}}} +\def\lcm{{\rm lcm}} +\def\gcd{{\rm gcd}} +\def\log{{\rm log}} +\def\ord{{\rm ord}} +\def\abs{{\mathit abs}} +\def\rep{{\mathit rep}} +\def\mod{{\mathit\ mod\ }} +\renewcommand{\pmod}[1]{\ ({\rm mod\ }{#1})} +\newcommand{\floor}[1]{\left\lfloor{#1}\right\rfloor} +\newcommand{\ceil}[1]{\left\lceil{#1}\right\rceil} +\def\Or{{\rm\ or\ }} +\def\And{{\rm\ and\ }} +\def\iff{\hspace{1em}\Longleftrightarrow\hspace{1em}} +\def\implies{\Rightarrow} +\def\undefined{{\rm ``undefined"}} +\def\Proof{\vspace{1ex}\noindent {\bf Proof:}\hspace{1em}} +\let\oldphi\phi +\def\phi{\varphi} +\def\Pr{{\rm Pr}} +\newcommand{\str}[1]{{\mathbf{#1}}} +\def\F{{\mathbb F}} +\def\N{{\mathbb N}} +\def\Z{{\mathbb Z}} +\def\R{{\mathbb R}} +\def\C{{\mathbb C}} +\def\Q{{\mathbb Q}} +\definecolor{DGray}{gray}{0.5} +\newcommand{\emailaddr}[1]{\mbox{$<${#1}$>$}} +\def\twiddle{\raisebox{0.3ex}{\mbox{\tiny $\sim$}}} +\def\gap{\vspace{0.5ex}} +\makeindex +\begin{document} +\frontmatter +\pagestyle{empty} +\title{Implementing Multiple Precision Arithmetic \\ ~ \\ Draft Edition } +\author{\mbox{ +%\begin{small} +\begin{tabular}{c} +Tom St Denis \\ +Algonquin College \\ +\\ +Mads Rasmussen \\ +Open Communications Security \\ +\\ +Greg Rose \\ +QUALCOMM Australia \\ +\end{tabular} +%\end{small} +} +} +\maketitle +This text has been placed in the public domain. This text corresponds to the v0.30 release of the +LibTomMath project. + +\begin{alltt} +Tom St Denis +111 Banning Rd +Ottawa, Ontario +K2L 1C3 +Canada + +Phone: 1-613-836-3160 +Email: tomstdenis@iahu.ca +\end{alltt} + +This text is formatted to the international B5 paper size of 176mm wide by 250mm tall using the \LaTeX{} +{\em book} macro package and the Perl {\em booker} package. + +\tableofcontents +\listoffigures +\chapter*{Prefaces to the Draft Edition} +I started this text in April 2003 to complement my LibTomMath library. That is, explain how to implement the functions +contained in LibTomMath. The goal is to have a textbook that any Computer Science student can use when implementing their +own multiple precision arithmetic. The plan I wanted to follow was flesh out all the +ideas and concepts I had floating around in my head and then work on it afterwards refining a little bit at a time. Chance +would have it that I ended up with my summer off from Algonquin College and I was given four months solid to work on the +text. + +Choosing to not waste any time I dove right into the project even before my spring semester was finished. I wrote a bit +off and on at first. The moment my exams were finished I jumped into long 12 to 16 hour days. The result after only +a couple of months was a ten chapter, three hundred page draft that I quickly had distributed to anyone who wanted +to read it. I had Jean-Luc Cooke print copies for me and I brought them to Crypto'03 in Santa Barbara. So far I have +managed to grab a certain level of attention having people from around the world ask me for copies of the text was certain +rewarding. + +Now we are past December 2003. By this time I had pictured that I would have at least finished my second draft of the text. +Currently I am far off from this goal. I've done partial re-writes of chapters one, two and three but they are not even +finished yet. I haven't given up on the project, only had some setbacks. First O'Reilly declined to publish the text then +Addison-Wesley and Greg is tried another which I don't know the name of. However, at this point I want to focus my energy +onto finishing the book not securing a contract. + +So why am I writing this text? It seems like a lot of work right? Most certainly it is a lot of work writing a textbook. +Even the simplest introductory material has to be lined with references and figures. A lot of the text has to be re-written +from point form to prose form to ensure an easier read. Why am I doing all this work for free then? Simple. My philosophy +is quite simply ``Open Source. Open Academia. Open Minds'' which means that to achieve a goal of open minds, that is, +people willing to accept new ideas and explore the unknown you have to make available material they can access freely +without hinderance. + +I've been writing free software since I was about sixteen but only recently have I hit upon software that people have come +to depend upon. I started LibTomCrypt in December 2001 and now several major companies use it as integral portions of their +software. Several educational institutions use it as a matter of course and many freelance developers use it as +part of their projects. To further my contributions I started the LibTomMath project in December 2002 aimed at providing +multiple precision arithmetic routines that students could learn from. That is write routines that are not only easy +to understand and follow but provide quite impressive performance considering they are all in standard portable ISO C. + +The second leg of my philosophy is ``Open Academia'' which is where this textbook comes in. In the end, when all is +said and done the text will be useable by educational institutions as a reference on multiple precision arithmetic. + +At this time I feel I should share a little information about myself. The most common question I was asked at +Crypto'03, perhaps just out of professional courtesy, was which school I either taught at or attended. The unfortunate +truth is that I neither teach at or attend a school of academic reputation. I'm currently at Algonquin College which +is what I'd like to call ``somewhat academic but mostly vocational'' college. In otherwords, job training. + +I'm a 21 year old computer science student mostly self-taught in the areas I am aware of (which includes a half-dozen +computer science fields, a few fields of mathematics and some English). I look forward to teaching someday but I am +still far off from that goal. + +Now it would be improper for me to not introduce the rest of the texts co-authors. While they are only contributing +corrections and editorial feedback their support has been tremendously helpful in presenting the concepts laid out +in the text so far. Greg has always been there for me. He has tracked my LibTom projects since their inception and even +sent cheques to help pay tuition from time to time. His background has provided a wonderful source to bounce ideas off +of and improve the quality of my writing. Mads is another fellow who has just ``been there''. I don't even recall what +his interest in the LibTom projects is but I'm definitely glad he has been around. His ability to catch logical errors +in my written English have saved me on several occasions to say the least. + +What to expect next? Well this is still a rough draft. I've only had the chance to update a few chapters. However, I've +been getting the feeling that people are starting to use my text and I owe them some updated material. My current tenative +plan is to edit one chapter every two weeks starting January 4th. It seems insane but my lower course load at college +should provide ample time. By Crypto'04 I plan to have a 2nd draft of the text polished and ready to hand out to as many +people who will take it. + +\begin{flushright} Tom St Denis \end{flushright} + +\newpage +I found the opportunity to work with Tom appealing for several reasons, not only could I broaden my own horizons, but also +contribute to educate others facing the problem of having to handle big number mathematical calculations. + +This book is Tom's child and he has been caring and fostering the project ever since the beginning with a clear mind of +how he wanted the project to turn out. I have helped by proofreading the text and we have had several discussions about +the layout and language used. + +I hold a masters degree in cryptography from the University of Southern Denmark and have always been interested in the +practical aspects of cryptography. + +Having worked in the security consultancy business for several years in S\~{a}o Paulo, Brazil, I have been in touch with a +great deal of work in which multiple precision mathematics was needed. Understanding the possibilities for speeding up +multiple precision calculations is often very important since we deal with outdated machine architecture where modular +reductions, for example, become painfully slow. + +This text is for people who stop and wonder when first examining algorithms such as RSA for the first time and asks +themselves, ``You tell me this is only secure for large numbers, fine; but how do you implement these numbers?'' + +\begin{flushright} +Mads Rasmussen + +S\~{a}o Paulo - SP + +Brazil +\end{flushright} + +\newpage +It's all because I broke my leg. That just happened to be at about the same time that Tom asked for someone to review the section of the book about +Karatsuba multiplication. I was laid up, alone and immobile, and thought ``Why not?'' I vaguely knew what Karatsuba multiplication was, but not +really, so I thought I could help, learn, and stop myself from watching daytime cable TV, all at once. + +At the time of writing this, I've still not met Tom or Mads in meatspace. I've been following Tom's progress since his first splash on the +sci.crypt Usenet news group. I watched him go from a clueless newbie, to the cryptographic equivalent of a reformed smoker, to a real +contributor to the field, over a period of about two years. I've been impressed with his obvious intelligence, and astounded by his productivity. +Of course, he's young enough to be my own child, so he doesn't have my problems with staying awake. + +When I reviewed that single section of the book, in its very earliest form, I was very pleasantly surprised. So I decided to collaborate more fully, +and at least review all of it, and perhaps write some bits too. There's still a long way to go with it, and I have watched a number of close +friends go through the mill of publication, so I think that the way to go is longer than Tom thinks it is. Nevertheless, it's a good effort, +and I'm pleased to be involved with it. + +\begin{flushright} +Greg Rose, Sydney, Australia, June 2003. +\end{flushright} + +\mainmatter +\pagestyle{headings} +\chapter{Introduction} +\section{Multiple Precision Arithmetic} + +\subsection{What is Multiple Precision Arithmetic?} +When we think of long-hand arithmetic such as addition or multiplication we rarely consider the fact that we instinctively +raise or lower the precision of the numbers we are dealing with. For example, in decimal we almost immediate can +reason that $7$ times $6$ is $42$. However, $42$ has two digits of precision as opposed to one digit we started with. +Further multiplications of say $3$ result in a larger precision result $126$. In these few examples we have multiple +precisions for the numbers we are working with. Despite the various levels of precision a single subset\footnote{With the occasional optimization.} + of algorithms can be designed to accomodate them. + +By way of comparison a fixed or single precision operation would lose precision on various operations. For example, in +the decimal system with fixed precision $6 \cdot 7 = 2$. + +Essentially at the heart of computer based multiple precision arithmetic are the same long-hand algorithms taught in +schools to manually add, subtract, multiply and divide. + +\subsection{The Need for Multiple Precision Arithmetic} +The most prevalent need for multiple precision arithmetic, often referred to as ``bignum'' math, is within the implementation +of public-key cryptography algorithms. Algorithms such as RSA \cite{RSAREF} and Diffie-Hellman \cite{DHREF} require +integers of significant magnitude to resist known cryptanalytic attacks. For example, at the time of this writing a +typical RSA modulus would be at least greater than $10^{309}$. However, modern programming languages such as ISO C \cite{ISOC} and +Java \cite{JAVA} only provide instrinsic support for integers which are relatively small and single precision. + +\begin{figure}[!here] +\begin{center} +\begin{tabular}{|r|c|} +\hline \textbf{Data Type} & \textbf{Range} \\ +\hline char & $-128 \ldots 127$ \\ +\hline short & $-32768 \ldots 32767$ \\ +\hline long & $-2147483648 \ldots 2147483647$ \\ +\hline long long & $-9223372036854775808 \ldots 9223372036854775807$ \\ +\hline +\end{tabular} +\end{center} +\caption{Typical Data Types for the C Programming Language} +\label{fig:ISOC} +\end{figure} + +The largest data type guaranteed to be provided by the ISO C programming +language\footnote{As per the ISO C standard. However, each compiler vendor is allowed to augment the precision as they +see fit.} can only represent values up to $10^{19}$ as shown in figure \ref{fig:ISOC}. On its own the C language is +insufficient to accomodate the magnitude required for the problem at hand. An RSA modulus of magnitude $10^{19}$ could be +trivially factored\footnote{A Pollard-Rho factoring would take only $2^{16}$ time.} on the average desktop computer, +rendering any protocol based on the algorithm insecure. Multiple precision algorithms solve this very problem by +extending the range of representable integers while using single precision data types. + +Most advancements in fast multiple precision arithmetic stem from the need for faster and more efficient cryptographic +primitives. Faster modular reduction and exponentiation algorithms such as Barrett's algorithm, which have appeared in +various cryptographic journals, can render algorithms such as RSA and Diffie-Hellman more efficient. In fact, several +major companies such as RSA Security, Certicom and Entrust have built entire product lines on the implementation and +deployment of efficient algorithms. + +However, cryptography is not the only field of study that can benefit from fast multiple precision integer routines. +Another auxiliary use of multiple precision integers is high precision floating point data types. +The basic IEEE \cite{IEEE} standard floating point type is made up of an integer mantissa $q$, an exponent $e$ and a sign bit $s$. +Numbers are given in the form $n = q \cdot b^e \cdot -1^s$ where $b = 2$ is the most common base for IEEE. Since IEEE +floating point is meant to be implemented in hardware the precision of the mantissa is often fairly small +(\textit{23, 48 and 64 bits}). The mantissa is merely an integer and a multiple precision integer could be used to create +a mantissa of much larger precision than hardware alone can efficiently support. This approach could be useful where +scientific applications must minimize the total output error over long calculations. + +Yet another use for large integers is within arithmetic on polynomials of large characteristic (i.e. $GF(p)[x]$ for large $p$). +In fact the library discussed within this text has already been used to form a polynomial basis library\footnote{See \url{http://poly.libtomcrypt.org} for more details.}. + +\subsection{Benefits of Multiple Precision Arithmetic} +\index{precision} +The benefit of multiple precision representations over single or fixed precision representations is that +no precision is lost while representing the result of an operation which requires excess precision. For example, +the product of two $n$-bit integers requires at least $2n$ bits of precision to be represented faithfully. A multiple +precision algorithm would augment the precision of the destination to accomodate the result while a single precision system +would truncate excess bits to maintain a fixed level of precision. + +It is possible to implement algorithms which require large integers with fixed precision algorithms. For example, elliptic +curve cryptography (\textit{ECC}) is often implemented on smartcards by fixing the precision of the integers to the maximum +size the system will ever need. Such an approach can lead to vastly simpler algorithms which can accomodate the +integers required even if the host platform cannot natively accomodate them\footnote{For example, the average smartcard +processor has an 8 bit accumulator.}. However, as efficient as such an approach may be, the resulting source code is not +normally very flexible. It cannot, at runtime, accomodate inputs of higher magnitude than the designer anticipated. + +Multiple precision algorithms have the most overhead of any style of arithmetic. For the the most part the +overhead can be kept to a minimum with careful planning, but overall, it is not well suited for most memory starved +platforms. However, multiple precision algorithms do offer the most flexibility in terms of the magnitude of the +inputs. That is, the same algorithms based on multiple precision integers can accomodate any reasonable size input +without the designer's explicit forethought. This leads to lower cost of ownership for the code as it only has to +be written and tested once. + +\section{Purpose of This Text} +The purpose of this text is to instruct the reader regarding how to implement efficient multiple precision algorithms. +That is to not only explain a limited subset of the core theory behind the algorithms but also the various ``house keeping'' +elements that are neglected by authors of other texts on the subject. Several well reknowned texts \cite{TAOCPV2,HAC} +give considerably detailed explanations of the theoretical aspects of algorithms and often very little information +regarding the practical implementation aspects. + +In most cases how an algorithm is explained and how it is actually implemented are two very different concepts. For +example, the Handbook of Applied Cryptography (\textit{HAC}), algorithm 14.7 on page 594, gives a relatively simple +algorithm for performing multiple precision integer addition. However, the description lacks any discussion concerning +the fact that the two integer inputs may be of differing magnitudes. As a result the implementation is not as simple +as the text would lead people to believe. Similarly the division routine (\textit{algorithm 14.20, pp. 598}) does not +discuss how to handle sign or handle the dividend's decreasing magnitude in the main loop (\textit{step \#3}). + +Both texts also do not discuss several key optimal algorithms required such as ``Comba'' and Karatsuba multipliers +and fast modular inversion, which we consider practical oversights. These optimal algorithms are vital to achieve +any form of useful performance in non-trivial applications. + +To solve this problem the focus of this text is on the practical aspects of implementing a multiple precision integer +package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.org}} package is used +to demonstrate algorithms with real implementations\footnote{In the ISO C programming language.} that have been field +tested and work very well. The LibTomMath library is freely available on the Internet for all uses and this text +discusses a very large portion of the inner workings of the library. + +The algorithms that are presented will always include at least one ``pseudo-code'' description followed +by the actual C source code that implements the algorithm. The pseudo-code can be used to implement the same +algorithm in other programming languages as the reader sees fit. + +This text shall also serve as a walkthrough of the creation of multiple precision algorithms from scratch. Showing +the reader how the algorithms fit together as well as where to start on various taskings. + +\section{Discussion and Notation} +\subsection{Notation} +A multiple precision integer of $n$-digits shall be denoted as $x = (x_{n-1}, \ldots, x_1, x_0)_{ \beta }$ and represent +the integer $x \equiv \sum_{i=0}^{n-1} x_i\beta^i$. The elements of the array $x$ are said to be the radix $\beta$ digits +of the integer. For example, $x = (1,2,3)_{10}$ would represent the integer +$1\cdot 10^2 + 2\cdot10^1 + 3\cdot10^0 = 123$. + +\index{mp\_int} +The term ``mp\_int'' shall refer to a composite structure which contains the digits of the integer it represents, as well +as auxilary data required to manipulate the data. These additional members are discussed further in section +\ref{sec:MPINT}. For the purposes of this text a ``multiple precision integer'' and an ``mp\_int'' are assumed to be +synonymous. When an algorithm is specified to accept an mp\_int variable it is assumed the various auxliary data members +are present as well. An expression of the type \textit{variablename.item} implies that it should evaluate to the +member named ``item'' of the variable. For example, a string of characters may have a member ``length'' which would +evaluate to the number of characters in the string. If the string $a$ equals ``hello'' then it follows that +$a.length = 5$. + +For certain discussions more generic algorithms are presented to help the reader understand the final algorithm used +to solve a given problem. When an algorithm is described as accepting an integer input it is assumed the input is +a plain integer with no additional multiple-precision members. That is, algorithms that use integers as opposed to +mp\_ints as inputs do not concern themselves with the housekeeping operations required such as memory management. These +algorithms will be used to establish the relevant theory which will subsequently be used to describe a multiple +precision algorithm to solve the same problem. + +\subsection{Precision Notation} +The variable $\beta$ represents the radix of a single digit of a multiple precision integer and +must be of the form $q^p$ for $q, p \in \Z^+$. A single precision variable must be able to represent integers in +the range $0 \le x < q \beta$ while a double precision variable must be able to represent integers in the range +$0 \le x < q \beta^2$. The extra radix-$q$ factor allows additions and subtractions to proceed without truncation of the +carry. Since all modern computers are binary, it is assumed that $q$ is two. + +\index{mp\_digit} \index{mp\_word} +Within the source code that will be presented for each algorithm, the data type \textbf{mp\_digit} will represent +a single precision integer type, while, the data type \textbf{mp\_word} will represent a double precision integer type. In +several algorithms (notably the Comba routines) temporary results will be stored in arrays of double precision mp\_words. +For the purposes of this text $x_j$ will refer to the $j$'th digit of a single precision array and $\hat x_j$ will refer to +the $j$'th digit of a double precision array. Whenever an expression is to be assigned to a double precision +variable it is assumed that all single precision variables are promoted to double precision during the evaluation. +Expressions that are assigned to a single precision variable are truncated to fit within the precision of a single +precision data type. + +For example, if $\beta = 10^2$ a single precision data type may represent a value in the +range $0 \le x < 10^3$, while a double precision data type may represent a value in the range $0 \le x < 10^5$. Let +$a = 23$ and $b = 49$ represent two single precision variables. The single precision product shall be written +as $c \leftarrow a \cdot b$ while the double precision product shall be written as $\hat c \leftarrow a \cdot b$. +In this particular case, $\hat c = 1127$ and $c = 127$. The most significant digit of the product would not fit +in a single precision data type and as a result $c \ne \hat c$. + +\subsection{Algorithm Inputs and Outputs} +Within the algorithm descriptions all variables are assumed to be scalars of either single or double precision +as indicated. The only exception to this rule is when variables have been indicated to be of type mp\_int. This +distinction is important as scalars are often used as array indicies and various other counters. + +\subsection{Mathematical Expressions} +The $\lfloor \mbox{ } \rfloor$ brackets imply an expression truncated to an integer not greater than the expression +itself. For example, $\lfloor 5.7 \rfloor = 5$. Similarly the $\lceil \mbox{ } \rceil$ brackets imply an expression +rounded to an integer not less than the expression itself. For example, $\lceil 5.1 \rceil = 6$. Typically when +the $/$ division symbol is used the intention is to perform an integer division with truncation. For example, +$5/2 = 2$ which will often be written as $\lfloor 5/2 \rfloor = 2$ for clarity. When an expression is written as a +fraction a real value division is implied, for example ${5 \over 2} = 2.5$. + +The norm of a multiple precision integer, for example $\vert \vert x \vert \vert$, will be used to represent the number of digits in the representation +of the integer. For example, $\vert \vert 123 \vert \vert = 3$ and $\vert \vert 79452 \vert \vert = 5$. + +\subsection{Work Effort} +\index{big-Oh} +To measure the efficiency of the specified algorithms, a modified big-Oh notation is used. In this system all +single precision operations are considered to have the same cost\footnote{Except where explicitly noted.}. +That is a single precision addition, multiplication and division are assumed to take the same time to +complete. While this is generally not true in practice, it will simplify the discussions considerably. + +Some algorithms have slight advantages over others which is why some constants will not be removed in +the notation. For example, a normal baseline multiplication (section \ref{sec:basemult}) requires $O(n^2)$ work while a +baseline squaring (section \ref{sec:basesquare}) requires $O({{n^2 + n}\over 2})$ work. In standard big-Oh notation these +would both be said to be equivalent to $O(n^2)$. However, +in the context of the this text this is not the case as the magnitude of the inputs will typically be rather small. As a +result small constant factors in the work effort will make an observable difference in algorithm efficiency. + +All of the algorithms presented in this text have a polynomial time work level. That is, of the form +$O(n^k)$ for $n, k \in \Z^{+}$. This will help make useful comparisons in terms of the speed of the algorithms and how +various optimizations will help pay off in the long run. + +\section{Exercises} +Within the more advanced chapters a section will be set aside to give the reader some challenging exercises related to +the discussion at hand. These exercises are not designed to be prize winning problems, but instead to be thought +provoking. Wherever possible the problems are forward minded, stating problems that will be answered in subsequent +chapters. The reader is encouraged to finish the exercises as they appear to get a better understanding of the +subject material. + +That being said, the problems are designed to affirm knowledge of a particular subject matter. Students in particular +are encouraged to verify they can answer the problems correctly before moving on. + +Similar to the exercises of \cite[pp. ix]{TAOCPV2} these exercises are given a scoring system based on the difficulty of +the problem. However, unlike \cite{TAOCPV2} the problems do not get nearly as hard. The scoring of these +exercises ranges from one (the easiest) to five (the hardest). The following table sumarizes the +scoring system used. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|l|} +\hline $\left [ 1 \right ]$ & An easy problem that should only take the reader a manner of \\ + & minutes to solve. Usually does not involve much computer time \\ + & to solve. \\ +\hline $\left [ 2 \right ]$ & An easy problem that involves a marginal amount of computer \\ + & time usage. Usually requires a program to be written to \\ + & solve the problem. \\ +\hline $\left [ 3 \right ]$ & A moderately hard problem that requires a non-trivial amount \\ + & of work. Usually involves trivial research and development of \\ + & new theory from the perspective of a student. \\ +\hline $\left [ 4 \right ]$ & A moderately hard problem that involves a non-trivial amount \\ + & of work and research, the solution to which will demonstrate \\ + & a higher mastery of the subject matter. \\ +\hline $\left [ 5 \right ]$ & A hard problem that involves concepts that are difficult for a \\ + & novice to solve. Solutions to these problems will demonstrate a \\ + & complete mastery of the given subject. \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Exercise Scoring System} +\end{figure} + +Problems at the first level are meant to be simple questions that the reader can answer quickly without programming a solution or +devising new theory. These problems are quick tests to see if the material is understood. Problems at the second level +are also designed to be easy but will require a program or algorithm to be implemented to arrive at the answer. These +two levels are essentially entry level questions. + +Problems at the third level are meant to be a bit more difficult than the first two levels. The answer is often +fairly obvious but arriving at an exacting solution requires some thought and skill. These problems will almost always +involve devising a new algorithm or implementing a variation of another algorithm previously presented. Readers who can +answer these questions will feel comfortable with the concepts behind the topic at hand. + +Problems at the fourth level are meant to be similar to those of the level three questions except they will require +additional research to be completed. The reader will most likely not know the answer right away, nor will the text provide +the exact details of the answer until a subsequent chapter. + +Problems at the fifth level are meant to be the hardest +problems relative to all the other problems in the chapter. People who can correctly answer fifth level problems have a +mastery of the subject matter at hand. + +Often problems will be tied together. The purpose of this is to start a chain of thought that will be discussed in future chapters. The reader +is encouraged to answer the follow-up problems and try to draw the relevance of problems. + +\section{Introduction to LibTomMath} + +\subsection{What is LibTomMath?} +LibTomMath is a free and open source multiple precision integer library written entirely in portable ISO C. By portable it +is meant that the library does not contain any code that is computer platform dependent or otherwise problematic to use on +any given platform. + +The library has been successfully tested under numerous operating systems including Unix\footnote{All of these +trademarks belong to their respective rightful owners.}, MacOS, Windows, Linux, PalmOS and on standalone hardware such +as the Gameboy Advance. The library is designed to contain enough functionality to be able to develop applications such +as public key cryptosystems and still maintain a relatively small footprint. + +\subsection{Goals of LibTomMath} + +Libraries which obtain the most efficiency are rarely written in a high level programming language such as C. However, +even though this library is written entirely in ISO C, considerable care has been taken to optimize the algorithm implementations within the +library. Specifically the code has been written to work well with the GNU C Compiler (\textit{GCC}) on both x86 and ARM +processors. Wherever possible, highly efficient algorithms, such as Karatsuba multiplication, sliding window +exponentiation and Montgomery reduction have been provided to make the library more efficient. + +Even with the nearly optimal and specialized algorithms that have been included the Application Programing Interface +(\textit{API}) has been kept as simple as possible. Often generic place holder routines will make use of specialized +algorithms automatically without the developer's specific attention. One such example is the generic multiplication +algorithm \textbf{mp\_mul()} which will automatically use Toom--Cook, Karatsuba, Comba or baseline multiplication +based on the magnitude of the inputs and the configuration of the library. + +Making LibTomMath as efficient as possible is not the only goal of the LibTomMath project. Ideally the library should +be source compatible with another popular library which makes it more attractive for developers to use. In this case the +MPI library was used as a API template for all the basic functions. MPI was chosen because it is another library that fits +in the same niche as LibTomMath. Even though LibTomMath uses MPI as the template for the function names and argument +passing conventions, it has been written from scratch by Tom St Denis. + +The project is also meant to act as a learning tool for students, the logic being that no easy-to-follow ``bignum'' +library exists which can be used to teach computer science students how to perform fast and reliable multiple precision +integer arithmetic. To this end the source code has been given quite a few comments and algorithm discussion points. + +\section{Choice of LibTomMath} +LibTomMath was chosen as the case study of this text not only because the author of both projects is one and the same but +for more worthy reasons. Other libraries such as GMP \cite{GMP}, MPI \cite{MPI}, LIP \cite{LIP} and OpenSSL +\cite{OPENSSL} have multiple precision integer arithmetic routines but would not be ideal for this text for +reasons that will be explained in the following sub-sections. + +\subsection{Code Base} +The LibTomMath code base is all portable ISO C source code. This means that there are no platform dependent conditional +segments of code littered throughout the source. This clean and uncluttered approach to the library means that a +developer can more readily discern the true intent of a given section of source code without trying to keep track of +what conditional code will be used. + +The code base of LibTomMath is well organized. Each function is in its own separate source code file +which allows the reader to find a given function very quickly. On average there are $76$ lines of code per source +file which makes the source very easily to follow. By comparison MPI and LIP are single file projects making code tracing +very hard. GMP has many conditional code segments which also hinder tracing. + +When compiled with GCC for the x86 processor and optimized for speed the entire library is approximately $100$KiB\footnote{The notation ``KiB'' means $2^{10}$ octets, similarly ``MiB'' means $2^{20}$ octets.} + which is fairly small compared to GMP (over $250$KiB). LibTomMath is slightly larger than MPI (which compiles to about +$50$KiB) but LibTomMath is also much faster and more complete than MPI. + +\subsection{API Simplicity} +LibTomMath is designed after the MPI library and shares the API design. Quite often programs that use MPI will build +with LibTomMath without change. The function names correlate directly to the action they perform. Almost all of the +functions share the same parameter passing convention. The learning curve is fairly shallow with the API provided +which is an extremely valuable benefit for the student and developer alike. + +The LIP library is an example of a library with an API that is awkward to work with. LIP uses function names that are often ``compressed'' to +illegible short hand. LibTomMath does not share this characteristic. + +The GMP library also does not return error codes. Instead it uses a POSIX.1 \cite{POSIX1} signal system where errors +are signaled to the host application. This happens to be the fastest approach but definitely not the most versatile. In +effect a math error (i.e. invalid input, heap error, etc) can cause a program to stop functioning which is definitely +undersireable in many situations. + +\subsection{Optimizations} +While LibTomMath is certainly not the fastest library (GMP often beats LibTomMath by a factor of two) it does +feature a set of optimal algorithms for tasks such as modular reduction, exponentiation, multiplication and squaring. GMP +and LIP also feature such optimizations while MPI only uses baseline algorithms with no optimizations. GMP lacks a few +of the additional modular reduction optimizations that LibTomMath features\footnote{At the time of this writing GMP +only had Barrett and Montgomery modular reduction algorithms.}. + +LibTomMath is almost always an order of magnitude faster than the MPI library at computationally expensive tasks such as modular +exponentiation. In the grand scheme of ``bignum'' libraries LibTomMath is faster than the average library and usually +slower than the best libraries such as GMP and OpenSSL by only a small factor. + +\subsection{Portability and Stability} +LibTomMath will build ``out of the box'' on any platform equipped with a modern version of the GNU C Compiler +(\textit{GCC}). This means that without changes the library will build without configuration or setting up any +variables. LIP and MPI will build ``out of the box'' as well but have numerous known bugs. Most notably the author of +MPI has recently stopped working on his library and LIP has long since been discontinued. + +GMP requires a configuration script to run and will not build out of the box. GMP and LibTomMath are still in active +development and are very stable across a variety of platforms. + +\subsection{Choice} +LibTomMath is a relatively compact, well documented, highly optimized and portable library which seems only natural for +the case study of this text. Various source files from the LibTomMath project will be included within the text. However, +the reader is encouraged to download their own copy of the library to actually be able to work with the library. + +\chapter{Getting Started} +\section{Library Basics} +The trick to writing any useful library of source code is to build a solid foundation and work outwards from it. First, +a problem along with allowable solution parameters should be identified and analyzed. In this particular case the +inability to accomodate multiple precision integers is the problem. Futhermore, the solution must be written +as portable source code that is reasonably efficient across several different computer platforms. + +After a foundation is formed the remainder of the library can be designed and implemented in a hierarchical fashion. +That is, to implement the lowest level dependencies first and work towards the most abstract functions last. For example, +before implementing a modular exponentiation algorithm one would implement a modular reduction algorithm. +By building outwards from a base foundation instead of using a parallel design methodology the resulting project is +highly modular. Being highly modular is a desirable property of any project as it often means the resulting product +has a small footprint and updates are easy to perform. + +Usually when I start a project I will begin with the header files. I define the data types I think I will need and +prototype the initial functions that are not dependent on other functions (within the library). After I +implement these base functions I prototype more dependent functions and implement them. The process repeats until +I implement all of the functions I require. For example, in the case of LibTomMath I implemented functions such as +mp\_init() well before I implemented mp\_mul() and even further before I implemented mp\_exptmod(). As an example as to +why this design works note that the Karatsuba and Toom-Cook multipliers were written \textit{after} the +dependent function mp\_exptmod() was written. Adding the new multiplication algorithms did not require changes to the +mp\_exptmod() function itself and lowered the total cost of ownership (\textit{so to speak}) and of development +for new algorithms. This methodology allows new algorithms to be tested in a complete framework with relative ease. + +FIGU,design_process,Design Flow of the First Few Original LibTomMath Functions. + +Only after the majority of the functions were in place did I pursue a less hierarchical approach to auditing and optimizing +the source code. For example, one day I may audit the multipliers and the next day the polynomial basis functions. + +It only makes sense to begin the text with the preliminary data types and support algorithms required as well. +This chapter discusses the core algorithms of the library which are the dependents for every other algorithm. + +\section{What is a Multiple Precision Integer?} +Recall that most programming languages, in particular ISO C \cite{ISOC}, only have fixed precision data types that on their own cannot +be used to represent values larger than their precision will allow. The purpose of multiple precision algorithms is +to use fixed precision data types to create and manipulate multiple precision integers which may represent values +that are very large. + +As a well known analogy, school children are taught how to form numbers larger than nine by prepending more radix ten digits. In the decimal system +the largest single digit value is $9$. However, by concatenating digits together larger numbers may be represented. Newly prepended digits +(\textit{to the left}) are said to be in a different power of ten column. That is, the number $123$ can be described as having a $1$ in the hundreds +column, $2$ in the tens column and $3$ in the ones column. Or more formally $123 = 1 \cdot 10^2 + 2 \cdot 10^1 + 3 \cdot 10^0$. Computer based +multiple precision arithmetic is essentially the same concept. Larger integers are represented by adjoining fixed +precision computer words with the exception that a different radix is used. + +What most people probably do not think about explicitly are the various other attributes that describe a multiple precision +integer. For example, the integer $154_{10}$ has two immediately obvious properties. First, the integer is positive, +that is the sign of this particular integer is positive as opposed to negative. Second, the integer has three digits in +its representation. There is an additional property that the integer posesses that does not concern pencil-and-paper +arithmetic. The third property is how many digits placeholders are available to hold the integer. + +The human analogy of this third property is ensuring there is enough space on the paper to write the integer. For example, +if one starts writing a large number too far to the right on a piece of paper they will have to erase it and move left. +Similarly, computer algorithms must maintain strict control over memory usage to ensure that the digits of an integer +will not exceed the allowed boundaries. These three properties make up what is known as a multiple precision +integer or mp\_int for short. + +\subsection{The mp\_int Structure} +\label{sec:MPINT} +The mp\_int structure is the ISO C based manifestation of what represents a multiple precision integer. The ISO C standard does not provide for +any such data type but it does provide for making composite data types known as structures. The following is the structure definition +used within LibTomMath. + +\index{mp\_int} +\begin{figure}[here] +\begin{center} +\begin{small} +%\begin{verbatim} +\begin{tabular}{|l|} +\hline +typedef struct \{ \\ +\hspace{3mm}int used, alloc, sign;\\ +\hspace{3mm}mp\_digit *dp;\\ +\} \textbf{mp\_int}; \\ +\hline +\end{tabular} +%\end{verbatim} +\end{small} +\caption{The mp\_int Structure} +\label{fig:mpint} +\end{center} +\end{figure} + +The mp\_int structure (fig. \ref{fig:mpint}) can be broken down as follows. + +\begin{enumerate} +\item The \textbf{used} parameter denotes how many digits of the array \textbf{dp} contain the digits used to represent +a given integer. The \textbf{used} count must be positive (or zero) and may not exceed the \textbf{alloc} count. + +\item The \textbf{alloc} parameter denotes how +many digits are available in the array to use by functions before it has to increase in size. When the \textbf{used} count +of a result would exceed the \textbf{alloc} count all of the algorithms will automatically increase the size of the +array to accommodate the precision of the result. + +\item The pointer \textbf{dp} points to a dynamically allocated array of digits that represent the given multiple +precision integer. It is padded with $(\textbf{alloc} - \textbf{used})$ zero digits. The array is maintained in a least +significant digit order. As a pencil and paper analogy the array is organized such that the right most digits are stored +first starting at the location indexed by zero\footnote{In C all arrays begin at zero.} in the array. For example, +if \textbf{dp} contains $\lbrace a, b, c, \ldots \rbrace$ where \textbf{dp}$_0 = a$, \textbf{dp}$_1 = b$, \textbf{dp}$_2 = c$, $\ldots$ then +it would represent the integer $a + b\beta + c\beta^2 + \ldots$ + +\index{MP\_ZPOS} \index{MP\_NEG} +\item The \textbf{sign} parameter denotes the sign as either zero/positive (\textbf{MP\_ZPOS}) or negative (\textbf{MP\_NEG}). +\end{enumerate} + +\subsubsection{Valid mp\_int Structures} +Several rules are placed on the state of an mp\_int structure and are assumed to be followed for reasons of efficiency. +The only exceptions are when the structure is passed to initialization functions such as mp\_init() and mp\_init\_copy(). + +\begin{enumerate} +\item The value of \textbf{alloc} may not be less than one. That is \textbf{dp} always points to a previously allocated +array of digits. +\item The value of \textbf{used} may not exceed \textbf{alloc} and must be greater than or equal to zero. +\item The value of \textbf{used} implies the digit at index $(used - 1)$ of the \textbf{dp} array is non-zero. That is, +leading zero digits in the most significant positions must be trimmed. + \begin{enumerate} + \item Digits in the \textbf{dp} array at and above the \textbf{used} location must be zero. + \end{enumerate} +\item The value of \textbf{sign} must be \textbf{MP\_ZPOS} if \textbf{used} is zero; +this represents the mp\_int value of zero. +\end{enumerate} + +\section{Argument Passing} +A convention of argument passing must be adopted early on in the development of any library. Making the function +prototypes consistent will help eliminate many headaches in the future as the library grows to significant complexity. +In LibTomMath the multiple precision integer functions accept parameters from left to right as pointers to mp\_int +structures. That means that the source (input) operands are placed on the left and the destination (output) on the right. +Consider the following examples. + +\begin{verbatim} + mp_mul(&a, &b, &c); /* c = a * b */ + mp_add(&a, &b, &a); /* a = a + b */ + mp_sqr(&a, &b); /* b = a * a */ +\end{verbatim} + +The left to right order is a fairly natural way to implement the functions since it lets the developer read aloud the +functions and make sense of them. For example, the first function would read ``multiply a and b and store in c''. + +Certain libraries (\textit{LIP by Lenstra for instance}) accept parameters the other way around, to mimic the order +of assignment expressions. That is, the destination (output) is on the left and arguments (inputs) are on the right. In +truth, it is entirely a matter of preference. In the case of LibTomMath the convention from the MPI library has been +adopted. + +Another very useful design consideration, provided for in LibTomMath, is whether to allow argument sources to also be a +destination. For example, the second example (\textit{mp\_add}) adds $a$ to $b$ and stores in $a$. This is an important +feature to implement since it allows the calling functions to cut down on the number of variables it must maintain. +However, to implement this feature specific care has to be given to ensure the destination is not modified before the +source is fully read. + +\section{Return Values} +A well implemented application, no matter what its purpose, should trap as many runtime errors as possible and return them +to the caller. By catching runtime errors a library can be guaranteed to prevent undefined behaviour. However, the end +developer can still manage to cause a library to crash. For example, by passing an invalid pointer an application may +fault by dereferencing memory not owned by the application. + +In the case of LibTomMath the only errors that are checked for are related to inappropriate inputs (division by zero for +instance) and memory allocation errors. It will not check that the mp\_int passed to any function is valid nor +will it check pointers for validity. Any function that can cause a runtime error will return an error code as an +\textbf{int} data type with one of the following values (fig \ref{fig:errcodes}). + +\index{MP\_OKAY} \index{MP\_VAL} \index{MP\_MEM} +\begin{figure}[here] +\begin{center} +\begin{tabular}{|l|l|} +\hline \textbf{Value} & \textbf{Meaning} \\ +\hline \textbf{MP\_OKAY} & The function was successful \\ +\hline \textbf{MP\_VAL} & One of the input value(s) was invalid \\ +\hline \textbf{MP\_MEM} & The function ran out of heap memory \\ +\hline +\end{tabular} +\end{center} +\caption{LibTomMath Error Codes} +\label{fig:errcodes} +\end{figure} + +When an error is detected within a function it should free any memory it allocated, often during the initialization of +temporary mp\_ints, and return as soon as possible. The goal is to leave the system in the same state it was when the +function was called. Error checking with this style of API is fairly simple. + +\begin{verbatim} + int err; + if ((err = mp_add(&a, &b, &c)) != MP_OKAY) { + printf("Error: %s\n", mp_error_to_string(err)); + exit(EXIT_FAILURE); + } +\end{verbatim} + +The GMP \cite{GMP} library uses C style \textit{signals} to flag errors which is of questionable use. Not all errors are fatal +and it was not deemed ideal by the author of LibTomMath to force developers to have signal handlers for such cases. + +\section{Initialization and Clearing} +The logical starting point when actually writing multiple precision integer functions is the initialization and +clearing of the mp\_int structures. These two algorithms will be used by the majority of the higher level algorithms. + +Given the basic mp\_int structure an initialization routine must first allocate memory to hold the digits of +the integer. Often it is optimal to allocate a sufficiently large pre-set number of digits even though +the initial integer will represent zero. If only a single digit were allocated quite a few subsequent re-allocations +would occur when operations are performed on the integers. There is a tradeoff between how many default digits to allocate +and how many re-allocations are tolerable. Obviously allocating an excessive amount of digits initially will waste +memory and become unmanageable. + +If the memory for the digits has been successfully allocated then the rest of the members of the structure must +be initialized. Since the initial state of an mp\_int is to represent the zero integer, the allocated digits must be set +to zero. The \textbf{used} count set to zero and \textbf{sign} set to \textbf{MP\_ZPOS}. + +\subsection{Initializing an mp\_int} +An mp\_int is said to be initialized if it is set to a valid, preferably default, state such that all of the members of the +structure are set to valid values. The mp\_init algorithm will perform such an action. + +\index{mp\_init} +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Allocate memory and initialize $a$ to a known valid mp\_int state. \\ +\hline \\ +1. Allocate memory for \textbf{MP\_PREC} digits. \\ +2. If the allocation failed return(\textit{MP\_MEM}) \\ +3. for $n$ from $0$ to $MP\_PREC - 1$ do \\ +\hspace{3mm}3.1 $a_n \leftarrow 0$\\ +4. $a.sign \leftarrow MP\_ZPOS$\\ +5. $a.used \leftarrow 0$\\ +6. $a.alloc \leftarrow MP\_PREC$\\ +7. Return(\textit{MP\_OKAY})\\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init} +\end{figure} + +\textbf{Algorithm mp\_init.} +The purpose of this function is to initialize an mp\_int structure so that the rest of the library can properly +manipulte it. It is assumed that the input may not have had any of its members previously initialized which is certainly +a valid assumption if the input resides on the stack. + +Before any of the members such as \textbf{sign}, \textbf{used} or \textbf{alloc} are initialized the memory for +the digits is allocated. If this fails the function returns before setting any of the other members. The \textbf{MP\_PREC} +name represents a constant\footnote{Defined in the ``tommath.h'' header file within LibTomMath.} +used to dictate the minimum precision of newly initialized mp\_int integers. Ideally, it is at least equal to the smallest +precision number you'll be working with. + +Allocating a block of digits at first instead of a single digit has the benefit of lowering the number of usually slow +heap operations later functions will have to perform in the future. If \textbf{MP\_PREC} is set correctly the slack +memory and the number of heap operations will be trivial. + +Once the allocation has been made the digits have to be set to zero as well as the \textbf{used}, \textbf{sign} and +\textbf{alloc} members initialized. This ensures that the mp\_int will always represent the default state of zero regardless +of the original condition of the input. + +\textbf{Remark.} +This function introduces the idiosyncrasy that all iterative loops, commonly initiated with the ``for'' keyword, iterate incrementally +when the ``to'' keyword is placed between two expressions. For example, ``for $a$ from $b$ to $c$ do'' means that +a subsequent expression (or body of expressions) are to be evaluated upto $c - b$ times so long as $b \le c$. In each +iteration the variable $a$ is substituted for a new integer that lies inclusively between $b$ and $c$. If $b > c$ occured +the loop would not iterate. By contrast if the ``downto'' keyword were used in place of ``to'' the loop would iterate +decrementally. + +EXAM,bn_mp_init.c + +One immediate observation of this initializtion function is that it does not return a pointer to a mp\_int structure. It +is assumed that the caller has already allocated memory for the mp\_int structure, typically on the application stack. The +call to mp\_init() is used only to initialize the members of the structure to a known default state. + +Here we see (line @23,XMALLOC@) the memory allocation is performed first. This allows us to exit cleanly and quickly +if there is an error. If the allocation fails the routine will return \textbf{MP\_MEM} to the caller to indicate there +was a memory error. The function XMALLOC is what actually allocates the memory. Technically XMALLOC is not a function +but a macro defined in ``tommath.h``. By default, XMALLOC will evaluate to malloc() which is the C library's built--in +memory allocation routine. + +In order to assure the mp\_int is in a known state the digits must be set to zero. On most platforms this could have been +accomplished by using calloc() instead of malloc(). However, to correctly initialize a integer type to a given value in a +portable fashion you have to actually assign the value. The for loop (line @28,for@) performs this required +operation. + +After the memory has been successfully initialized the remainder of the members are initialized +(lines @29,used@ through @31,sign@) to their respective default states. At this point the algorithm has succeeded and +a success code is returned to the calling function. If this function returns \textbf{MP\_OKAY} it is safe to assume the +mp\_int structure has been properly initialized and is safe to use with other functions within the library. + +\subsection{Clearing an mp\_int} +When an mp\_int is no longer required by the application, the memory that has been allocated for its digits must be +returned to the application's memory pool with the mp\_clear algorithm. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_clear}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. The memory for $a$ shall be deallocated. \\ +\hline \\ +1. If $a$ has been previously freed then return(\textit{MP\_OKAY}). \\ +2. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}2.1 $a_n \leftarrow 0$ \\ +3. Free the memory allocated for the digits of $a$. \\ +4. $a.used \leftarrow 0$ \\ +5. $a.alloc \leftarrow 0$ \\ +6. $a.sign \leftarrow MP\_ZPOS$ \\ +7. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_clear} +\end{figure} + +\textbf{Algorithm mp\_clear.} +This algorithm accomplishes two goals. First, it clears the digits and the other mp\_int members. This ensures that +if a developer accidentally re-uses a cleared structure it is less likely to cause problems. The second goal +is to free the allocated memory. + +The logic behind the algorithm is extended by marking cleared mp\_int structures so that subsequent calls to this +algorithm will not try to free the memory multiple times. Cleared mp\_ints are detectable by having a pre-defined invalid +digit pointer \textbf{dp} setting. + +Once an mp\_int has been cleared the mp\_int structure is no longer in a valid state for any other algorithm +with the exception of algorithms mp\_init, mp\_init\_copy, mp\_init\_size and mp\_clear. + +EXAM,bn_mp_clear.c + +The algorithm only operates on the mp\_int if it hasn't been previously cleared. The if statement (line @23,a->dp != NULL@) +checks to see if the \textbf{dp} member is not \textbf{NULL}. If the mp\_int is a valid mp\_int then \textbf{dp} cannot be +\textbf{NULL} in which case the if statement will evaluate to true. + +The digits of the mp\_int are cleared by the for loop (line @25,for@) which assigns a zero to every digit. Similar to mp\_init() +the digits are assigned zero instead of using block memory operations (such as memset()) since this is more portable. + +The digits are deallocated off the heap via the XFREE macro. Similar to XMALLOC the XFREE macro actually evaluates to +a standard C library function. In this case the free() function. Since free() only deallocates the memory the pointer +still has to be reset to \textbf{NULL} manually (line @33,NULL@). + +Now that the digits have been cleared and deallocated the other members are set to their final values (lines @34,= 0@ and @35,ZPOS@). + +\section{Maintenance Algorithms} + +The previous sections describes how to initialize and clear an mp\_int structure. To further support operations +that are to be performed on mp\_int structures (such as addition and multiplication) the dependent algorithms must be +able to augment the precision of an mp\_int and +initialize mp\_ints with differing initial conditions. + +These algorithms complete the set of low level algorithms required to work with mp\_int structures in the higher level +algorithms such as addition, multiplication and modular exponentiation. + +\subsection{Augmenting an mp\_int's Precision} +When storing a value in an mp\_int structure, a sufficient number of digits must be available to accomodate the entire +result of an operation without loss of precision. Quite often the size of the array given by the \textbf{alloc} member +is large enough to simply increase the \textbf{used} digit count. However, when the size of the array is too small it +must be re-sized appropriately to accomodate the result. The mp\_grow algorithm will provide this functionality. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_grow}. \\ +\textbf{Input}. An mp\_int $a$ and an integer $b$. \\ +\textbf{Output}. $a$ is expanded to accomodate $b$ digits. \\ +\hline \\ +1. if $a.alloc \ge b$ then return(\textit{MP\_OKAY}) \\ +2. $u \leftarrow b\mbox{ (mod }MP\_PREC\mbox{)}$ \\ +3. $v \leftarrow b + 2 \cdot MP\_PREC - u$ \\ +4. Re-allocate the array of digits $a$ to size $v$ \\ +5. If the allocation failed then return(\textit{MP\_MEM}). \\ +6. for n from a.alloc to $v - 1$ do \\ +\hspace{+3mm}6.1 $a_n \leftarrow 0$ \\ +7. $a.alloc \leftarrow v$ \\ +8. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_grow} +\end{figure} + +\textbf{Algorithm mp\_grow.} +It is ideal to prevent re-allocations from being performed if they are not required (step one). This is useful to +prevent mp\_ints from growing excessively in code that erroneously calls mp\_grow. + +The requested digit count is padded up to next multiple of \textbf{MP\_PREC} plus an additional \textbf{MP\_PREC} (steps two and three). +This helps prevent many trivial reallocations that would grow an mp\_int by trivially small values. + +It is assumed that the reallocation (step four) leaves the lower $a.alloc$ digits of the mp\_int intact. This is much +akin to how the \textit{realloc} function from the standard C library works. Since the newly allocated digits are +assumed to contain undefined values they are initially set to zero. + +EXAM,bn_mp_grow.c + +A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line @23,if@) checks +if the \textbf{alloc} member of the mp\_int is smaller than the requested digit count. If the count is not larger than \textbf{alloc} +the function skips the re-allocation part thus saving time. + +When a re-allocation is performed it is turned into an optimal request to save time in the future. The requested digit count is +padded upwards to 2nd multiple of \textbf{MP\_PREC} larger than \textbf{alloc} (line @25, size@). The XREALLOC function is used +to re-allocate the memory. As per the other functions XREALLOC is actually a macro which evaluates to realloc by default. The realloc +function leaves the base of the allocation intact which means the first \textbf{alloc} digits of the mp\_int are the same as before +the re-allocation. All that is left is to clear the newly allocated digits and return. + +Note that the re-allocation result is actually stored in a temporary pointer $tmp$. This is to allow this function to return +an error with a valid pointer. Earlier releases of the library stored the result of XREALLOC into the mp\_int $a$. That would +result in a memory leak if XREALLOC ever failed. + +\subsection{Initializing Variable Precision mp\_ints} +Occasionally the number of digits required will be known in advance of an initialization, based on, for example, the size +of input mp\_ints to a given algorithm. The purpose of algorithm mp\_init\_size is similar to mp\_init except that it +will allocate \textit{at least} a specified number of digits. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_size}. \\ +\textbf{Input}. An mp\_int $a$ and the requested number of digits $b$. \\ +\textbf{Output}. $a$ is initialized to hold at least $b$ digits. \\ +\hline \\ +1. $u \leftarrow b \mbox{ (mod }MP\_PREC\mbox{)}$ \\ +2. $v \leftarrow b + 2 \cdot MP\_PREC - u$ \\ +3. Allocate $v$ digits. \\ +4. for $n$ from $0$ to $v - 1$ do \\ +\hspace{3mm}4.1 $a_n \leftarrow 0$ \\ +5. $a.sign \leftarrow MP\_ZPOS$\\ +6. $a.used \leftarrow 0$\\ +7. $a.alloc \leftarrow v$\\ +8. Return(\textit{MP\_OKAY})\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_init\_size} +\end{figure} + +\textbf{Algorithm mp\_init\_size.} +This algorithm will initialize an mp\_int structure $a$ like algorithm mp\_init with the exception that the number of +digits allocated can be controlled by the second input argument $b$. The input size is padded upwards so it is a +multiple of \textbf{MP\_PREC} plus an additional \textbf{MP\_PREC} digits. This padding is used to prevent trivial +allocations from becoming a bottleneck in the rest of the algorithms. + +Like algorithm mp\_init, the mp\_int structure is initialized to a default state representing the integer zero. This +particular algorithm is useful if it is known ahead of time the approximate size of the input. If the approximation is +correct no further memory re-allocations are required to work with the mp\_int. + +EXAM,bn_mp_init_size.c + +The number of digits $b$ requested is padded (line @22,MP_PREC@) by first augmenting it to the next multiple of +\textbf{MP\_PREC} and then adding \textbf{MP\_PREC} to the result. If the memory can be successfully allocated the +mp\_int is placed in a default state representing the integer zero. Otherwise, the error code \textbf{MP\_MEM} will be +returned (line @27,return@). + +The digits are allocated and set to zero at the same time with the calloc() function (line @25,XCALLOC@). The +\textbf{used} count is set to zero, the \textbf{alloc} count set to the padded digit count and the \textbf{sign} flag set +to \textbf{MP\_ZPOS} to achieve a default valid mp\_int state (lines @29,used@, @30,alloc@ and @31,sign@). If the function +returns succesfully then it is correct to assume that the mp\_int structure is in a valid state for the remainder of the +functions to work with. + +\subsection{Multiple Integer Initializations and Clearings} +Occasionally a function will require a series of mp\_int data types to be made available simultaneously. +The purpose of algorithm mp\_init\_multi is to initialize a variable length array of mp\_int structures in a single +statement. It is essentially a shortcut to multiple initializations. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_multi}. \\ +\textbf{Input}. Variable length array $V_k$ of mp\_int variables of length $k$. \\ +\textbf{Output}. The array is initialized such that each mp\_int of $V_k$ is ready to use. \\ +\hline \\ +1. for $n$ from 0 to $k - 1$ do \\ +\hspace{+3mm}1.1. Initialize the mp\_int $V_n$ (\textit{mp\_init}) \\ +\hspace{+3mm}1.2. If initialization failed then do \\ +\hspace{+6mm}1.2.1. for $j$ from $0$ to $n$ do \\ +\hspace{+9mm}1.2.1.1. Free the mp\_int $V_j$ (\textit{mp\_clear}) \\ +\hspace{+6mm}1.2.2. Return(\textit{MP\_MEM}) \\ +2. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init\_multi} +\end{figure} + +\textbf{Algorithm mp\_init\_multi.} +The algorithm will initialize the array of mp\_int variables one at a time. If a runtime error has been detected +(\textit{step 1.2}) all of the previously initialized variables are cleared. The goal is an ``all or nothing'' +initialization which allows for quick recovery from runtime errors. + +EXAM,bn_mp_init_multi.c + +This function intializes a variable length list of mp\_int structure pointers. However, instead of having the mp\_int +structures in an actual C array they are simply passed as arguments to the function. This function makes use of the +``...'' argument syntax of the C programming language. The list is terminated with a final \textbf{NULL} argument +appended on the right. + +The function uses the ``stdarg.h'' \textit{va} functions to step portably through the arguments to the function. A count +$n$ of succesfully initialized mp\_int structures is maintained (line @47,n++@) such that if a failure does occur, +the algorithm can backtrack and free the previously initialized structures (lines @27,if@ to @46,}@). + + +\subsection{Clamping Excess Digits} +When a function anticipates a result will be $n$ digits it is simpler to assume this is true within the body of +the function instead of checking during the computation. For example, a multiplication of a $i$ digit number by a +$j$ digit produces a result of at most $i + j$ digits. It is entirely possible that the result is $i + j - 1$ +though, with no final carry into the last position. However, suppose the destination had to be first expanded +(\textit{via mp\_grow}) to accomodate $i + j - 1$ digits than further expanded to accomodate the final carry. +That would be a considerable waste of time since heap operations are relatively slow. + +The ideal solution is to always assume the result is $i + j$ and fix up the \textbf{used} count after the function +terminates. This way a single heap operation (\textit{at most}) is required. However, if the result was not checked +there would be an excess high order zero digit. + +For example, suppose the product of two integers was $x_n = (0x_{n-1}x_{n-2}...x_0)_{\beta}$. The leading zero digit +will not contribute to the precision of the result. In fact, through subsequent operations more leading zero digits would +accumulate to the point the size of the integer would be prohibitive. As a result even though the precision is very +low the representation is excessively large. + +The mp\_clamp algorithm is designed to solve this very problem. It will trim high-order zeros by decrementing the +\textbf{used} count until a non-zero most significant digit is found. Also in this system, zero is considered to be a +positive number which means that if the \textbf{used} count is decremented to zero, the sign must be set to +\textbf{MP\_ZPOS}. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_clamp}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Any excess leading zero digits of $a$ are removed \\ +\hline \\ +1. while $a.used > 0$ and $a_{a.used - 1} = 0$ do \\ +\hspace{+3mm}1.1 $a.used \leftarrow a.used - 1$ \\ +2. if $a.used = 0$ then do \\ +\hspace{+3mm}2.1 $a.sign \leftarrow MP\_ZPOS$ \\ +\hline \\ +\end{tabular} +\end{center} +\caption{Algorithm mp\_clamp} +\end{figure} + +\textbf{Algorithm mp\_clamp.} +As can be expected this algorithm is very simple. The loop on step one is expected to iterate only once or twice at +the most. For example, this will happen in cases where there is not a carry to fill the last position. Step two fixes the sign for +when all of the digits are zero to ensure that the mp\_int is valid at all times. + +EXAM,bn_mp_clamp.c + +Note on line @27,while@ how to test for the \textbf{used} count is made on the left of the \&\& operator. In the C programming +language the terms to \&\& are evaluated left to right with a boolean short-circuit if any condition fails. This is +important since if the \textbf{used} is zero the test on the right would fetch below the array. That is obviously +undesirable. The parenthesis on line @28,a->used@ is used to make sure the \textbf{used} count is decremented and not +the pointer ``a''. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 1 \right ]$ & Discuss the relevance of the \textbf{used} member of the mp\_int structure. \\ + & \\ +$\left [ 1 \right ]$ & Discuss the consequences of not using padding when performing allocations. \\ + & \\ +$\left [ 2 \right ]$ & Estimate an ideal value for \textbf{MP\_PREC} when performing 1024-bit RSA \\ + & encryption when $\beta = 2^{28}$. \\ + & \\ +$\left [ 1 \right ]$ & Discuss the relevance of the algorithm mp\_clamp. What does it prevent? \\ + & \\ +$\left [ 1 \right ]$ & Give an example of when the algorithm mp\_init\_copy might be useful. \\ + & \\ +\end{tabular} + + +%%% +% CHAPTER FOUR +%%% + +\chapter{Basic Operations} + +\section{Introduction} +In the previous chapter a series of low level algorithms were established that dealt with initializing and maintaining +mp\_int structures. This chapter will discuss another set of seemingly non-algebraic algorithms which will form the low +level basis of the entire library. While these algorithm are relatively trivial it is important to understand how they +work before proceeding since these algorithms will be used almost intrinsically in the following chapters. + +The algorithms in this chapter deal primarily with more ``programmer'' related tasks such as creating copies of +mp\_int structures, assigning small values to mp\_int structures and comparisons of the values mp\_int structures +represent. + +\section{Assigning Values to mp\_int Structures} +\subsection{Copying an mp\_int} +Assigning the value that a given mp\_int structure represents to another mp\_int structure shall be known as making +a copy for the purposes of this text. The copy of the mp\_int will be a separate entity that represents the same +value as the mp\_int it was copied from. The mp\_copy algorithm provides this functionality. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_copy}. \\ +\textbf{Input}. An mp\_int $a$ and $b$. \\ +\textbf{Output}. Store a copy of $a$ in $b$. \\ +\hline \\ +1. If $b.alloc < a.used$ then grow $b$ to $a.used$ digits. (\textit{mp\_grow}) \\ +2. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}2.1 $b_{n} \leftarrow a_{n}$ \\ +3. for $n$ from $a.used$ to $b.used - 1$ do \\ +\hspace{3mm}3.1 $b_{n} \leftarrow 0$ \\ +4. $b.used \leftarrow a.used$ \\ +5. $b.sign \leftarrow a.sign$ \\ +6. return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_copy} +\end{figure} + +\textbf{Algorithm mp\_copy.} +This algorithm copies the mp\_int $a$ such that upon succesful termination of the algorithm the mp\_int $b$ will +represent the same integer as the mp\_int $a$. The mp\_int $b$ shall be a complete and distinct copy of the +mp\_int $a$ meaing that the mp\_int $a$ can be modified and it shall not affect the value of the mp\_int $b$. + +If $b$ does not have enough room for the digits of $a$ it must first have its precision augmented via the mp\_grow +algorithm. The digits of $a$ are copied over the digits of $b$ and any excess digits of $b$ are set to zero (step two +and three). The \textbf{used} and \textbf{sign} members of $a$ are finally copied over the respective members of +$b$. + +\textbf{Remark.} This algorithm also introduces a new idiosyncrasy that will be used throughout the rest of the +text. The error return codes of other algorithms are not explicitly checked in the pseudo-code presented. For example, in +step one of the mp\_copy algorithm the return of mp\_grow is not explicitly checked to ensure it succeeded. Text space is +limited so it is assumed that if a algorithm fails it will clear all temporarily allocated mp\_ints and return +the error code itself. However, the C code presented will demonstrate all of the error handling logic required to +implement the pseudo-code. + +EXAM,bn_mp_copy.c + +Occasionally a dependent algorithm may copy an mp\_int effectively into itself such as when the input and output +mp\_int structures passed to a function are one and the same. For this case it is optimal to return immediately without +copying digits (line @24,a == b@). + +The mp\_int $b$ must have enough digits to accomodate the used digits of the mp\_int $a$. If $b.alloc$ is less than +$a.used$ the algorithm mp\_grow is used to augment the precision of $b$ (lines @29,alloc@ to @33,}@). In order to +simplify the inner loop that copies the digits from $a$ to $b$, two aliases $tmpa$ and $tmpb$ point directly at the digits +of the mp\_ints $a$ and $b$ respectively. These aliases (lines @42,tmpa@ and @45,tmpb@) allow the compiler to access the digits without first dereferencing the +mp\_int pointers and then subsequently the pointer to the digits. + +After the aliases are established the digits from $a$ are copied into $b$ (lines @48,for@ to @50,}@) and then the excess +digits of $b$ are set to zero (lines @53,for@ to @55,}@). Both ``for'' loops make use of the pointer aliases and in +fact the alias for $b$ is carried through into the second ``for'' loop to clear the excess digits. This optimization +allows the alias to stay in a machine register fairly easy between the two loops. + +\textbf{Remarks.} The use of pointer aliases is an implementation methodology first introduced in this function that will +be used considerably in other functions. Technically, a pointer alias is simply a short hand alias used to lower the +number of pointer dereferencing operations required to access data. For example, a for loop may resemble + +\begin{alltt} +for (x = 0; x < 100; x++) \{ + a->num[4]->dp[x] = 0; +\} +\end{alltt} + +This could be re-written using aliases as + +\begin{alltt} +mp_digit *tmpa; +a = a->num[4]->dp; +for (x = 0; x < 100; x++) \{ + *a++ = 0; +\} +\end{alltt} + +In this case an alias is used to access the +array of digits within an mp\_int structure directly. It may seem that a pointer alias is strictly not required +as a compiler may optimize out the redundant pointer operations. However, there are two dominant reasons to use aliases. + +The first reason is that most compilers will not effectively optimize pointer arithmetic. For example, some optimizations +may work for the Microsoft Visual C++ compiler (MSVC) and not for the GNU C Compiler (GCC). Also some optimizations may +work for GCC and not MSVC. As such it is ideal to find a common ground for as many compilers as possible. Pointer +aliases optimize the code considerably before the compiler even reads the source code which means the end compiled code +stands a better chance of being faster. + +The second reason is that pointer aliases often can make an algorithm simpler to read. Consider the first ``for'' +loop of the function mp\_copy() re-written to not use pointer aliases. + +\begin{alltt} + /* copy all the digits */ + for (n = 0; n < a->used; n++) \{ + b->dp[n] = a->dp[n]; + \} +\end{alltt} + +Whether this code is harder to read depends strongly on the individual. However, it is quantifiably slightly more +complicated as there are four variables within the statement instead of just two. + +\subsubsection{Nested Statements} +Another commonly used technique in the source routines is that certain sections of code are nested. This is used in +particular with the pointer aliases to highlight code phases. For example, a Comba multiplier (discussed in chapter six) +will typically have three different phases. First the temporaries are initialized, then the columns calculated and +finally the carries are propagated. In this example the middle column production phase will typically be nested as it +uses temporary variables and aliases the most. + +The nesting also simplies the source code as variables that are nested are only valid for their scope. As a result +the various temporary variables required do not propagate into other sections of code. + + +\subsection{Creating a Clone} +Another common operation is to make a local temporary copy of an mp\_int argument. To initialize an mp\_int +and then copy another existing mp\_int into the newly intialized mp\_int will be known as creating a clone. This is +useful within functions that need to modify an argument but do not wish to actually modify the original copy. The +mp\_init\_copy algorithm has been designed to help perform this task. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_copy}. \\ +\textbf{Input}. An mp\_int $a$ and $b$\\ +\textbf{Output}. $a$ is initialized to be a copy of $b$. \\ +\hline \\ +1. Init $a$. (\textit{mp\_init}) \\ +2. Copy $b$ to $a$. (\textit{mp\_copy}) \\ +3. Return the status of the copy operation. \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init\_copy} +\end{figure} + +\textbf{Algorithm mp\_init\_copy.} +This algorithm will initialize an mp\_int variable and copy another previously initialized mp\_int variable into it. As +such this algorithm will perform two operations in one step. + +EXAM,bn_mp_init_copy.c + +This will initialize \textbf{a} and make it a verbatim copy of the contents of \textbf{b}. Note that +\textbf{a} will have its own memory allocated which means that \textbf{b} may be cleared after the call +and \textbf{a} will be left intact. + +\section{Zeroing an Integer} +Reseting an mp\_int to the default state is a common step in many algorithms. The mp\_zero algorithm will be the algorithm used to +perform this task. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_zero}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Zero the contents of $a$ \\ +\hline \\ +1. $a.used \leftarrow 0$ \\ +2. $a.sign \leftarrow$ MP\_ZPOS \\ +3. for $n$ from 0 to $a.alloc - 1$ do \\ +\hspace{3mm}3.1 $a_n \leftarrow 0$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_zero} +\end{figure} + +\textbf{Algorithm mp\_zero.} +This algorithm simply resets a mp\_int to the default state. + +EXAM,bn_mp_zero.c + +After the function is completed, all of the digits are zeroed, the \textbf{used} count is zeroed and the +\textbf{sign} variable is set to \textbf{MP\_ZPOS}. + +\section{Sign Manipulation} +\subsection{Absolute Value} +With the mp\_int representation of an integer, calculating the absolute value is trivial. The mp\_abs algorithm will compute +the absolute value of an mp\_int. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_abs}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Computes $b = \vert a \vert$ \\ +\hline \\ +1. Copy $a$ to $b$. (\textit{mp\_copy}) \\ +2. If the copy failed return(\textit{MP\_MEM}). \\ +3. $b.sign \leftarrow MP\_ZPOS$ \\ +4. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_abs} +\end{figure} + +\textbf{Algorithm mp\_abs.} +This algorithm computes the absolute of an mp\_int input. First it copies $a$ over $b$. This is an example of an +algorithm where the check in mp\_copy that determines if the source and destination are equal proves useful. This allows, +for instance, the developer to pass the same mp\_int as the source and destination to this function without addition +logic to handle it. + +EXAM,bn_mp_abs.c + +\subsection{Integer Negation} +With the mp\_int representation of an integer, calculating the negation is also trivial. The mp\_neg algorithm will compute +the negative of an mp\_int input. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_neg}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Computes $b = -a$ \\ +\hline \\ +1. Copy $a$ to $b$. (\textit{mp\_copy}) \\ +2. If the copy failed return(\textit{MP\_MEM}). \\ +3. If $a.used = 0$ then return(\textit{MP\_OKAY}). \\ +4. If $a.sign = MP\_ZPOS$ then do \\ +\hspace{3mm}4.1 $b.sign = MP\_NEG$. \\ +5. else do \\ +\hspace{3mm}5.1 $b.sign = MP\_ZPOS$. \\ +6. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_neg} +\end{figure} + +\textbf{Algorithm mp\_neg.} +This algorithm computes the negation of an input. First it copies $a$ over $b$. If $a$ has no used digits then +the algorithm returns immediately. Otherwise it flips the sign flag and stores the result in $b$. Note that if +$a$ had no digits then it must be positive by definition. Had step three been omitted then the algorithm would return +zero as negative. + +EXAM,bn_mp_neg.c + +\section{Small Constants} +\subsection{Setting Small Constants} +Often a mp\_int must be set to a relatively small value such as $1$ or $2$. For these cases the mp\_set algorithm is useful. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_set}. \\ +\textbf{Input}. An mp\_int $a$ and a digit $b$ \\ +\textbf{Output}. Make $a$ equivalent to $b$ \\ +\hline \\ +1. Zero $a$ (\textit{mp\_zero}). \\ +2. $a_0 \leftarrow b \mbox{ (mod }\beta\mbox{)}$ \\ +3. $a.used \leftarrow \left \lbrace \begin{array}{ll} + 1 & \mbox{if }a_0 > 0 \\ + 0 & \mbox{if }a_0 = 0 + \end{array} \right .$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_set} +\end{figure} + +\textbf{Algorithm mp\_set.} +This algorithm sets a mp\_int to a small single digit value. Step number 1 ensures that the integer is reset to the default state. The +single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adjusted accordingly. + +EXAM,bn_mp_set.c + +Line @21,mp_zero@ calls mp\_zero() to clear the mp\_int and reset the sign. Line @22,MP_MASK@ copies the digit +into the least significant location. Note the usage of a new constant \textbf{MP\_MASK}. This constant is used to quickly +reduce an integer modulo $\beta$. Since $\beta$ is of the form $2^k$ for any suitable $k$ it suffices to perform a binary AND with +$MP\_MASK = 2^k - 1$ to perform the reduction. Finally line @23,a->used@ will set the \textbf{used} member with respect to the +digit actually set. This function will always make the integer positive. + +One important limitation of this function is that it will only set one digit. The size of a digit is not fixed, meaning source that uses +this function should take that into account. Only trivially small constants can be set using this function. + +\subsection{Setting Large Constants} +To overcome the limitations of the mp\_set algorithm the mp\_set\_int algorithm is ideal. It accepts a ``long'' +data type as input and will always treat it as a 32-bit integer. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_set\_int}. \\ +\textbf{Input}. An mp\_int $a$ and a ``long'' integer $b$ \\ +\textbf{Output}. Make $a$ equivalent to $b$ \\ +\hline \\ +1. Zero $a$ (\textit{mp\_zero}) \\ +2. for $n$ from 0 to 7 do \\ +\hspace{3mm}2.1 $a \leftarrow a \cdot 16$ (\textit{mp\_mul2d}) \\ +\hspace{3mm}2.2 $u \leftarrow \lfloor b / 2^{4(7 - n)} \rfloor \mbox{ (mod }16\mbox{)}$\\ +\hspace{3mm}2.3 $a_0 \leftarrow a_0 + u$ \\ +\hspace{3mm}2.4 $a.used \leftarrow a.used + 1$ \\ +3. Clamp excess used digits (\textit{mp\_clamp}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_set\_int} +\end{figure} + +\textbf{Algorithm mp\_set\_int.} +The algorithm performs eight iterations of a simple loop where in each iteration four bits from the source are added to the +mp\_int. Step 2.1 will multiply the current result by sixteen making room for four more bits in the less significant positions. In step 2.2 the +next four bits from the source are extracted and are added to the mp\_int. The \textbf{used} digit count is +incremented to reflect the addition. The \textbf{used} digit counter is incremented since if any of the leading digits were zero the mp\_int would have +zero digits used and the newly added four bits would be ignored. + +Excess zero digits are trimmed in steps 2.1 and 3 by using higher level algorithms mp\_mul2d and mp\_clamp. + +EXAM,bn_mp_set_int.c + +This function sets four bits of the number at a time to handle all practical \textbf{DIGIT\_BIT} sizes. The weird +addition on line @38,a->used@ ensures that the newly added in bits are added to the number of digits. While it may not +seem obvious as to why the digit counter does not grow exceedingly large it is because of the shift on line @27,mp_mul_2d@ +as well as the call to mp\_clamp() on line @40,mp_clamp@. Both functions will clamp excess leading digits which keeps +the number of used digits low. + +\section{Comparisons} +\subsection{Unsigned Comparisions} +Comparing a multiple precision integer is performed with the exact same algorithm used to compare two decimal numbers. For example, +to compare $1,234$ to $1,264$ the digits are extracted by their positions. That is we compare $1 \cdot 10^3 + 2 \cdot 10^2 + 3 \cdot 10^1 + 4 \cdot 10^0$ +to $1 \cdot 10^3 + 2 \cdot 10^2 + 6 \cdot 10^1 + 4 \cdot 10^0$ by comparing single digits at a time starting with the highest magnitude +positions. If any leading digit of one integer is greater than a digit in the same position of another integer then obviously it must be greater. + +The first comparision routine that will be developed is the unsigned magnitude compare which will perform a comparison based on the digits of two +mp\_int variables alone. It will ignore the sign of the two inputs. Such a function is useful when an absolute comparison is required or if the +signs are known to agree in advance. + +To facilitate working with the results of the comparison functions three constants are required. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{|r|l|} +\hline \textbf{Constant} & \textbf{Meaning} \\ +\hline \textbf{MP\_GT} & Greater Than \\ +\hline \textbf{MP\_EQ} & Equal To \\ +\hline \textbf{MP\_LT} & Less Than \\ +\hline +\end{tabular} +\end{center} +\caption{Comparison Return Codes} +\end{figure} + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_cmp\_mag}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$. \\ +\textbf{Output}. Unsigned comparison results ($a$ to the left of $b$). \\ +\hline \\ +1. If $a.used > b.used$ then return(\textit{MP\_GT}) \\ +2. If $a.used < b.used$ then return(\textit{MP\_LT}) \\ +3. for n from $a.used - 1$ to 0 do \\ +\hspace{+3mm}3.1 if $a_n > b_n$ then return(\textit{MP\_GT}) \\ +\hspace{+3mm}3.2 if $a_n < b_n$ then return(\textit{MP\_LT}) \\ +4. Return(\textit{MP\_EQ}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_cmp\_mag} +\end{figure} + +\textbf{Algorithm mp\_cmp\_mag.} +By saying ``$a$ to the left of $b$'' it is meant that the comparison is with respect to $a$, that is if $a$ is greater than $b$ it will return +\textbf{MP\_GT} and similar with respect to when $a = b$ and $a < b$. The first two steps compare the number of digits used in both $a$ and $b$. +Obviously if the digit counts differ there would be an imaginary zero digit in the smaller number where the leading digit of the larger number is. +If both have the same number of digits than the actual digits themselves must be compared starting at the leading digit. + +By step three both inputs must have the same number of digits so its safe to start from either $a.used - 1$ or $b.used - 1$ and count down to +the zero'th digit. If after all of the digits have been compared, no difference is found, the algorithm returns \textbf{MP\_EQ}. + +EXAM,bn_mp_cmp_mag.c + +The two if statements on lines @24,if@ and @28,if@ compare the number of digits in the two inputs. These two are performed before all of the digits +are compared since it is a very cheap test to perform and can potentially save considerable time. The implementation given is also not valid +without those two statements. $b.alloc$ may be smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the +array of digits. + +\subsection{Signed Comparisons} +Comparing with sign considerations is also fairly critical in several routines (\textit{division for example}). Based on an unsigned magnitude +comparison a trivial signed comparison algorithm can be written. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_cmp}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. Signed Comparison Results ($a$ to the left of $b$) \\ +\hline \\ +1. if $a.sign = MP\_NEG$ and $b.sign = MP\_ZPOS$ then return(\textit{MP\_LT}) \\ +2. if $a.sign = MP\_ZPOS$ and $b.sign = MP\_NEG$ then return(\textit{MP\_GT}) \\ +3. if $a.sign = MP\_NEG$ then \\ +\hspace{+3mm}3.1 Return the unsigned comparison of $b$ and $a$ (\textit{mp\_cmp\_mag}) \\ +4 Otherwise \\ +\hspace{+3mm}4.1 Return the unsigned comparison of $a$ and $b$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_cmp} +\end{figure} + +\textbf{Algorithm mp\_cmp.} +The first two steps compare the signs of the two inputs. If the signs do not agree then it can return right away with the appropriate +comparison code. When the signs are equal the digits of the inputs must be compared to determine the correct result. In step +three the unsigned comparision flips the order of the arguments since they are both negative. For instance, if $-a > -b$ then +$\vert a \vert < \vert b \vert$. Step number four will compare the two when they are both positive. + +EXAM,bn_mp_cmp.c + +The two if statements on lines @22,if@ and @26,if@ perform the initial sign comparison. If the signs are not the equal then which ever +has the positive sign is larger. At line @30,if@, the inputs are compared based on magnitudes. If the signs were both negative then +the unsigned comparison is performed in the opposite direction (\textit{line @31,mp_cmp_mag@}). Otherwise, the signs are assumed to +be both positive and a forward direction unsigned comparison is performed. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 2 \right ]$ & Modify algorithm mp\_set\_int to accept as input a variable length array of bits. \\ + & \\ +$\left [ 3 \right ]$ & Give the probability that algorithm mp\_cmp\_mag will have to compare $k$ digits \\ + & of two random digits (of equal magnitude) before a difference is found. \\ + & \\ +$\left [ 1 \right ]$ & Suggest a simple method to speed up the implementation of mp\_cmp\_mag based \\ + & on the observations made in the previous problem. \\ + & +\end{tabular} + +\chapter{Basic Arithmetic} +\section{Introduction} +At this point algorithms for initialization, clearing, zeroing, copying, comparing and setting small constants have been +established. The next logical set of algorithms to develop are addition, subtraction and digit shifting algorithms. These +algorithms make use of the lower level algorithms and are the cruicial building block for the multiplication algorithms. It is very important +that these algorithms are highly optimized. On their own they are simple $O(n)$ algorithms but they can be called from higher level algorithms +which easily places them at $O(n^2)$ or even $O(n^3)$ work levels. + +MARK,SHIFTS +All of the algorithms within this chapter make use of the logical bit shift operations denoted by $<<$ and $>>$ for left and right +logical shifts respectively. A logical shift is analogous to sliding the decimal point of radix-10 representations. For example, the real +number $0.9345$ is equivalent to $93.45\%$ which is found by sliding the the decimal two places to the right (\textit{multiplying by $\beta^2 = 10^2$}). +Algebraically a binary logical shift is equivalent to a division or multiplication by a power of two. +For example, $a << k = a \cdot 2^k$ while $a >> k = \lfloor a/2^k \rfloor$. + +One significant difference between a logical shift and the way decimals are shifted is that digits below the zero'th position are removed +from the number. For example, consider $1101_2 >> 1$ using decimal notation this would produce $110.1_2$. However, with a logical shift the +result is $110_2$. + +\section{Addition and Subtraction} +In common twos complement fixed precision arithmetic negative numbers are easily represented by subtraction from the modulus. For example, with 32-bit integers +$a - b\mbox{ (mod }2^{32}\mbox{)}$ is the same as $a + (2^{32} - b) \mbox{ (mod }2^{32}\mbox{)}$ since $2^{32} \equiv 0 \mbox{ (mod }2^{32}\mbox{)}$. +As a result subtraction can be performed with a trivial series of logical operations and an addition. + +However, in multiple precision arithmetic negative numbers are not represented in the same way. Instead a sign flag is used to keep track of the +sign of the integer. As a result signed addition and subtraction are actually implemented as conditional usage of lower level addition or +subtraction algorithms with the sign fixed up appropriately. + +The lower level algorithms will add or subtract integers without regard to the sign flag. That is they will add or subtract the magnitude of +the integers respectively. + +\subsection{Low Level Addition} +An unsigned addition of multiple precision integers is performed with the same long-hand algorithm used to add decimal numbers. That is to add the +trailing digits first and propagate the resulting carry upwards. Since this is a lower level algorithm the name will have a ``s\_'' prefix. +Historically that convention stems from the MPI library where ``s\_'' stood for static functions that were hidden from the developer entirely. + +\newpage +\begin{figure}[!here] +\begin{center} +\begin{small} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_add}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The unsigned addition $c = \vert a \vert + \vert b \vert$. \\ +\hline \\ +1. if $a.used > b.used$ then \\ +\hspace{+3mm}1.1 $min \leftarrow b.used$ \\ +\hspace{+3mm}1.2 $max \leftarrow a.used$ \\ +\hspace{+3mm}1.3 $x \leftarrow a$ \\ +2. else \\ +\hspace{+3mm}2.1 $min \leftarrow a.used$ \\ +\hspace{+3mm}2.2 $max \leftarrow b.used$ \\ +\hspace{+3mm}2.3 $x \leftarrow b$ \\ +3. If $c.alloc < max + 1$ then grow $c$ to hold at least $max + 1$ digits (\textit{mp\_grow}) \\ +4. $oldused \leftarrow c.used$ \\ +5. $c.used \leftarrow max + 1$ \\ +6. $u \leftarrow 0$ \\ +7. for $n$ from $0$ to $min - 1$ do \\ +\hspace{+3mm}7.1 $c_n \leftarrow a_n + b_n + u$ \\ +\hspace{+3mm}7.2 $u \leftarrow c_n >> lg(\beta)$ \\ +\hspace{+3mm}7.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +8. if $min \ne max$ then do \\ +\hspace{+3mm}8.1 for $n$ from $min$ to $max - 1$ do \\ +\hspace{+6mm}8.1.1 $c_n \leftarrow x_n + u$ \\ +\hspace{+6mm}8.1.2 $u \leftarrow c_n >> lg(\beta)$ \\ +\hspace{+6mm}8.1.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +9. $c_{max} \leftarrow u$ \\ +10. if $olduse > max$ then \\ +\hspace{+3mm}10.1 for $n$ from $max + 1$ to $oldused - 1$ do \\ +\hspace{+6mm}10.1.1 $c_n \leftarrow 0$ \\ +11. Clamp excess digits in $c$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Algorithm s\_mp\_add} +\end{figure} + +\textbf{Algorithm s\_mp\_add.} +This algorithm is loosely based on algorithm 14.7 of HAC \cite[pp. 594]{HAC} but has been extended to allow the inputs to have different magnitudes. +Coincidentally the description of algorithm A in Knuth \cite[pp. 266]{TAOCPV2} shares the same deficiency as the algorithm from \cite{HAC}. Even the +MIX pseudo machine code presented by Knuth \cite[pp. 266-267]{TAOCPV2} is incapable of handling inputs which are of different magnitudes. + +The first thing that has to be accomplished is to sort out which of the two inputs is the largest. The addition logic +will simply add all of the smallest input to the largest input and store that first part of the result in the +destination. Then it will apply a simpler addition loop to excess digits of the larger input. + +The first two steps will handle sorting the inputs such that $min$ and $max$ hold the digit counts of the two +inputs. The variable $x$ will be an mp\_int alias for the largest input or the second input $b$ if they have the +same number of digits. After the inputs are sorted the destination $c$ is grown as required to accomodate the sum +of the two inputs. The original \textbf{used} count of $c$ is copied and set to the new used count. + +At this point the first addition loop will go through as many digit positions that both inputs have. The carry +variable $\mu$ is set to zero outside the loop. Inside the loop an ``addition'' step requires three statements to produce +one digit of the summand. First +two digits from $a$ and $b$ are added together along with the carry $\mu$. The carry of this step is extracted and stored +in $\mu$ and finally the digit of the result $c_n$ is truncated within the range $0 \le c_n < \beta$. + +Now all of the digit positions that both inputs have in common have been exhausted. If $min \ne max$ then $x$ is an alias +for one of the inputs that has more digits. A simplified addition loop is then used to essentially copy the remaining digits +and the carry to the destination. + +The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are zeroed which completes the addition. + + +EXAM,bn_s_mp_add.c + +Lines @27,if@ to @35,}@ perform the initial sorting of the inputs and determine the $min$ and $max$ variables. Note that $x$ is a pointer to a +mp\_int assigned to the largest input, in effect it is a local alias. Lines @37,init@ to @42,}@ ensure that the destination is grown to +accomodate the result of the addition. + +Similar to the implementation of mp\_copy this function uses the braced code and local aliases coding style. The three aliases that are on +lines @56,tmpa@, @59,tmpb@ and @62,tmpc@ represent the two inputs and destination variables respectively. These aliases are used to ensure the +compiler does not have to dereference $a$, $b$ or $c$ (respectively) to access the digits of the respective mp\_int. + +The initial carry $u$ is cleared on line @65,u = 0@, note that $u$ is of type mp\_digit which ensures type compatibility within the +implementation. The initial addition loop begins on line @66,for@ and ends on line @75,}@. Similarly the conditional addition loop +begins on line @81,for@ and ends on line @90,}@. The addition is finished with the final carry being stored in $tmpc$ on line @94,tmpc++@. +Note the ``++'' operator on the same line. After line @94,tmpc++@ $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful +for the next loop on lines @97,for@ to @99,}@ which set any old upper digits to zero. + +\subsection{Low Level Subtraction} +The low level unsigned subtraction algorithm is very similar to the low level unsigned addition algorithm. The principle difference is that the +unsigned subtraction algorithm requires the result to be positive. That is when computing $a - b$ the condition $\vert a \vert \ge \vert b\vert$ must +be met for this algorithm to function properly. Keep in mind this low level algorithm is not meant to be used in higher level algorithms directly. +This algorithm as will be shown can be used to create functional signed addition and subtraction algorithms. + +MARK,GAMMA + +For this algorithm a new variable is required to make the description simpler. Recall from section 1.3.1 that a mp\_digit must be able to represent +the range $0 \le x < 2\beta$ for the algorithms to work correctly. However, it is allowable that a mp\_digit represent a larger range of values. For +this algorithm we will assume that the variable $\gamma$ represents the number of bits available in a +mp\_digit (\textit{this implies $2^{\gamma} > \beta$}). + +For example, the default for LibTomMath is to use a ``unsigned long'' for the mp\_digit ``type'' while $\beta = 2^{28}$. In ISO C an ``unsigned long'' +data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma = 32$. + +\newpage\begin{figure}[!here] +\begin{center} +\begin{small} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_sub}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ ($\vert a \vert \ge \vert b \vert$) \\ +\textbf{Output}. The unsigned subtraction $c = \vert a \vert - \vert b \vert$. \\ +\hline \\ +1. $min \leftarrow b.used$ \\ +2. $max \leftarrow a.used$ \\ +3. If $c.alloc < max$ then grow $c$ to hold at least $max$ digits. (\textit{mp\_grow}) \\ +4. $oldused \leftarrow c.used$ \\ +5. $c.used \leftarrow max$ \\ +6. $u \leftarrow 0$ \\ +7. for $n$ from $0$ to $min - 1$ do \\ +\hspace{3mm}7.1 $c_n \leftarrow a_n - b_n - u$ \\ +\hspace{3mm}7.2 $u \leftarrow c_n >> (\gamma - 1)$ \\ +\hspace{3mm}7.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +8. if $min < max$ then do \\ +\hspace{3mm}8.1 for $n$ from $min$ to $max - 1$ do \\ +\hspace{6mm}8.1.1 $c_n \leftarrow a_n - u$ \\ +\hspace{6mm}8.1.2 $u \leftarrow c_n >> (\gamma - 1)$ \\ +\hspace{6mm}8.1.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +9. if $oldused > max$ then do \\ +\hspace{3mm}9.1 for $n$ from $max$ to $oldused - 1$ do \\ +\hspace{6mm}9.1.1 $c_n \leftarrow 0$ \\ +10. Clamp excess digits of $c$. (\textit{mp\_clamp}). \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Algorithm s\_mp\_sub} +\end{figure} + +\textbf{Algorithm s\_mp\_sub.} +This algorithm performs the unsigned subtraction of two mp\_int variables under the restriction that the result must be positive. That is when +passing variables $a$ and $b$ the condition that $\vert a \vert \ge \vert b \vert$ must be met for the algorithm to function correctly. This +algorithm is loosely based on algorithm 14.9 \cite[pp. 595]{HAC} and is similar to algorithm S in \cite[pp. 267]{TAOCPV2} as well. As was the case +of the algorithm s\_mp\_add both other references lack discussion concerning various practical details such as when the inputs differ in magnitude. + +The initial sorting of the inputs is trivial in this algorithm since $a$ is guaranteed to have at least the same magnitude of $b$. Steps 1 and 2 +set the $min$ and $max$ variables. Unlike the addition routine there is guaranteed to be no carry which means that the final result can be at +most $max$ digits in length as opposed to $max + 1$. Similar to the addition algorithm the \textbf{used} count of $c$ is copied locally and +set to the maximal count for the operation. + +The subtraction loop that begins on step seven is essentially the same as the addition loop of algorithm s\_mp\_add except single precision +subtraction is used instead. Note the use of the $\gamma$ variable to extract the carry (\textit{also known as the borrow}) within the subtraction +loops. Under the assumption that two's complement single precision arithmetic is used this will successfully extract the desired carry. + +For example, consider subtracting $0101_2$ from $0100_2$ where $\gamma = 4$ and $\beta = 2$. The least significant bit will force a carry upwards to +the third bit which will be set to zero after the borrow. After the very first bit has been subtracted $4 - 1 \equiv 0011_2$ will remain, When the +third bit of $0101_2$ is subtracted from the result it will cause another carry. In this case though the carry will be forced to propagate all the +way to the most significant bit. + +Recall that $\beta < 2^{\gamma}$. This means that if a carry does occur just before the $lg(\beta)$'th bit it will propagate all the way to the most +significant bit. Thus, the high order bits of the mp\_digit that are not part of the actual digit will either be all zero, or all one. All that +is needed is a single zero or one bit for the carry. Therefore a single logical shift right by $\gamma - 1$ positions is sufficient to extract the +carry. This method of carry extraction may seem awkward but the reason for it becomes apparent when the implementation is discussed. + +If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and copy operation to propagate through the larger input $a$ into $c$. Step +10 will ensure that any leading digits of $c$ above the $max$'th position are zeroed. + +EXAM,bn_s_mp_sub.c + +Line @24,min@ and @25,max@ perform the initial hardcoded sorting of the inputs. In reality the $min$ and $max$ variables are only aliases and are only +used to make the source code easier to read. Again the pointer alias optimization is used within this algorithm. Lines @42,tmpa@, @43,tmpb@ and @44,tmpc@ initialize the aliases for +$a$, $b$ and $c$ respectively. + +The first subtraction loop occurs on lines @47,u = 0@ through @61,}@. The theory behind the subtraction loop is exactly the same as that for +the addition loop. As remarked earlier there is an implementation reason for using the ``awkward'' method of extracting the carry +(\textit{see line @57, >>@}). The traditional method for extracting the carry would be to shift by $lg(\beta)$ positions and logically AND +the least significant bit. The AND operation is required because all of the bits above the $\lg(\beta)$'th bit will be set to one after a carry +occurs from subtraction. This carry extraction requires two relatively cheap operations to extract the carry. The other method is to simply +shift the most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This optimization only works on +twos compliment machines which is a safe assumption to make. + +If $a$ has a larger magnitude than $b$ an additional loop (\textit{see lines @64,for@ through @73,}@}) is required to propagate the carry through +$a$ and copy the result to $c$. + +\subsection{High Level Addition} +Now that both lower level addition and subtraction algorithms have been established an effective high level signed addition algorithm can be +established. This high level addition algorithm will be what other algorithms and developers will use to perform addition of mp\_int data +types. + +Recall from section 5.2 that an mp\_int represents an integer with an unsigned mantissa (\textit{the array of digits}) and a \textbf{sign} +flag. A high level addition is actually performed as a series of eight separate cases which can be optimized down to three unique cases. + +\begin{figure}[!here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_add}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The signed addition $c = a + b$. \\ +\hline \\ +1. if $a.sign = b.sign$ then do \\ +\hspace{3mm}1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{3mm}1.2 $c \leftarrow \vert a \vert + \vert b \vert$ (\textit{s\_mp\_add})\\ +2. else do \\ +\hspace{3mm}2.1 if $\vert a \vert < \vert b \vert$ then do (\textit{mp\_cmp\_mag}) \\ +\hspace{6mm}2.1.1 $c.sign \leftarrow b.sign$ \\ +\hspace{6mm}2.1.2 $c \leftarrow \vert b \vert - \vert a \vert$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c.sign \leftarrow a.sign$ \\ +\hspace{6mm}2.2.2 $c \leftarrow \vert a \vert - \vert b \vert$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_add} +\end{figure} + +\textbf{Algorithm mp\_add.} +This algorithm performs the signed addition of two mp\_int variables. There is no reference algorithm to draw upon from +either \cite{TAOCPV2} or \cite{HAC} since they both only provide unsigned operations. The algorithm is fairly +straightforward but restricted since subtraction can only produce positive results. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|} +\hline \textbf{Sign of $a$} & \textbf{Sign of $b$} & \textbf{$\vert a \vert > \vert b \vert $} & \textbf{Unsigned Operation} & \textbf{Result Sign Flag} \\ +\hline $+$ & $+$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $+$ & $+$ & No & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $-$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $-$ & No & $c = a + b$ & $a.sign$ \\ +\hline &&&&\\ + +\hline $+$ & $-$ & No & $c = b - a$ & $b.sign$ \\ +\hline $-$ & $+$ & No & $c = b - a$ & $b.sign$ \\ + +\hline &&&&\\ + +\hline $+$ & $-$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline $-$ & $+$ & Yes & $c = a - b$ & $a.sign$ \\ + +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Addition Guide Chart} +\label{fig:AddChart} +\end{figure} + +Figure~\ref{fig:AddChart} lists all of the eight possible input combinations and is sorted to show that only three +specific cases need to be handled. The return code of the unsigned operations at step 1.2, 2.1.2 and 2.2.2 are +forwarded to step three to check for errors. This simplifies the description of the algorithm considerably and best +follows how the implementation actually was achieved. + +Also note how the \textbf{sign} is set before the unsigned addition or subtraction is performed. Recall from the descriptions of algorithms +s\_mp\_add and s\_mp\_sub that the mp\_clamp function is used at the end to trim excess digits. The mp\_clamp algorithm will set the \textbf{sign} +to \textbf{MP\_ZPOS} when the \textbf{used} digit count reaches zero. + +For example, consider performing $-a + a$ with algorithm mp\_add. By the description of the algorithm the sign is set to \textbf{MP\_NEG} which would +produce a result of $-0$. However, since the sign is set first then the unsigned addition is performed the subsequent usage of algorithm mp\_clamp +within algorithm s\_mp\_add will force $-0$ to become $0$. + +EXAM,bn_mp_add.c + +The source code follows the algorithm fairly closely. The most notable new source code addition is the usage of the $res$ integer variable which +is used to pass result of the unsigned operations forward. Unlike in the algorithm, the variable $res$ is merely returned as is without +explicitly checking it and returning the constant \textbf{MP\_OKAY}. The observation is this algorithm will succeed or fail only if the lower +level functions do so. Returning their return code is sufficient. + +\subsection{High Level Subtraction} +The high level signed subtraction algorithm is essentially the same as the high level signed addition algorithm. + +\newpage\begin{figure}[!here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_sub}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The signed subtraction $c = a - b$. \\ +\hline \\ +1. if $a.sign \ne b.sign$ then do \\ +\hspace{3mm}1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{3mm}1.2 $c \leftarrow \vert a \vert + \vert b \vert$ (\textit{s\_mp\_add}) \\ +2. else do \\ +\hspace{3mm}2.1 if $\vert a \vert \ge \vert b \vert$ then do (\textit{mp\_cmp\_mag}) \\ +\hspace{6mm}2.1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{6mm}2.1.2 $c \leftarrow \vert a \vert - \vert b \vert$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c.sign \leftarrow \left \lbrace \begin{array}{ll} + MP\_ZPOS & \mbox{if }a.sign = MP\_NEG \\ + MP\_NEG & \mbox{otherwise} \\ + \end{array} \right .$ \\ +\hspace{6mm}2.2.2 $c \leftarrow \vert b \vert - \vert a \vert$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_sub} +\end{figure} + +\textbf{Algorithm mp\_sub.} +This algorithm performs the signed subtraction of two inputs. Similar to algorithm mp\_add there is no reference in either \cite{TAOCPV2} or +\cite{HAC}. Also this algorithm is restricted by algorithm s\_mp\_sub. Chart \ref{fig:SubChart} lists the eight possible inputs and +the operations required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|} +\hline \textbf{Sign of $a$} & \textbf{Sign of $b$} & \textbf{$\vert a \vert \ge \vert b \vert $} & \textbf{Unsigned Operation} & \textbf{Result Sign Flag} \\ +\hline $+$ & $-$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $+$ & $-$ & No & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $+$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $+$ & No & $c = a + b$ & $a.sign$ \\ +\hline &&&& \\ +\hline $+$ & $+$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline $-$ & $-$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline &&&& \\ +\hline $+$ & $+$ & No & $c = b - a$ & $\mbox{opposite of }a.sign$ \\ +\hline $-$ & $-$ & No & $c = b - a$ & $\mbox{opposite of }a.sign$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Subtraction Guide Chart} +\label{fig:SubChart} +\end{figure} + +Similar to the case of algorithm mp\_add the \textbf{sign} is set first before the unsigned addition or subtraction. That is to prevent the +algorithm from producing $-a - -a = -0$ as a result. + +EXAM,bn_mp_sub.c + +Much like the implementation of algorithm mp\_add the variable $res$ is used to catch the return code of the unsigned addition or subtraction operations +and forward it to the end of the function. On line @38, != MP_LT@ the ``not equal to'' \textbf{MP\_LT} expression is used to emulate a +``greater than or equal to'' comparison. + +\section{Bit and Digit Shifting} +MARK,POLY +It is quite common to think of a multiple precision integer as a polynomial in $x$, that is $y = f(\beta)$ where $f(x) = \sum_{i=0}^{n-1} a_i x^i$. +This notation arises within discussion of Montgomery and Diminished Radix Reduction as well as Karatsuba multiplication and squaring. + +In order to facilitate operations on polynomials in $x$ as above a series of simple ``digit'' algorithms have to be established. That is to shift +the digits left or right as well to shift individual bits of the digits left and right. It is important to note that not all ``shift'' operations +are on radix-$\beta$ digits. + +\subsection{Multiplication by Two} + +In a binary system where the radix is a power of two multiplication by two not only arises often in other algorithms it is a fairly efficient +operation to perform. A single precision logical shift left is sufficient to multiply a single digit by two. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_2}. \\ +\textbf{Input}. One mp\_int $a$ \\ +\textbf{Output}. $b = 2a$. \\ +\hline \\ +1. If $b.alloc < a.used + 1$ then grow $b$ to hold $a.used + 1$ digits. (\textit{mp\_grow}) \\ +2. $oldused \leftarrow b.used$ \\ +3. $b.used \leftarrow a.used$ \\ +4. $r \leftarrow 0$ \\ +5. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}5.1 $rr \leftarrow a_n >> (lg(\beta) - 1)$ \\ +\hspace{3mm}5.2 $b_n \leftarrow (a_n << 1) + r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}5.3 $r \leftarrow rr$ \\ +6. If $r \ne 0$ then do \\ +\hspace{3mm}6.1 $b_{n + 1} \leftarrow r$ \\ +\hspace{3mm}6.2 $b.used \leftarrow b.used + 1$ \\ +7. If $b.used < oldused - 1$ then do \\ +\hspace{3mm}7.1 for $n$ from $b.used$ to $oldused - 1$ do \\ +\hspace{6mm}7.1.1 $b_n \leftarrow 0$ \\ +8. $b.sign \leftarrow a.sign$ \\ +9. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_2} +\end{figure} + +\textbf{Algorithm mp\_mul\_2.} +This algorithm will quickly multiply a mp\_int by two provided $\beta$ is a power of two. Neither \cite{TAOCPV2} nor \cite{HAC} describe such +an algorithm despite the fact it arises often in other algorithms. The algorithm is setup much like the lower level algorithm s\_mp\_add since +it is for all intents and purposes equivalent to the operation $b = \vert a \vert + \vert a \vert$. + +Step 1 and 2 grow the input as required to accomodate the maximum number of \textbf{used} digits in the result. The initial \textbf{used} count +is set to $a.used$ at step 4. Only if there is a final carry will the \textbf{used} count require adjustment. + +Step 6 is an optimization implementation of the addition loop for this specific case. That is since the two values being added together +are the same there is no need to perform two reads from the digits of $a$. Step 6.1 performs a single precision shift on the current digit $a_n$ to +obtain what will be the carry for the next iteration. Step 6.2 calculates the $n$'th digit of the result as single precision shift of $a_n$ plus +the previous carry. Recall from ~SHIFTS~ that $a_n << 1$ is equivalent to $a_n \cdot 2$. An iteration of the addition loop is finished with +forwarding the carry to the next iteration. + +Step 7 takes care of any final carry by setting the $a.used$'th digit of the result to the carry and augmenting the \textbf{used} count of $b$. +Step 8 clears any leading digits of $b$ in case it originally had a larger magnitude than $a$. + +EXAM,bn_mp_mul_2.c + +This implementation is essentially an optimized implementation of s\_mp\_add for the case of doubling an input. The only noteworthy difference +is the use of the logical shift operator on line @52,<<@ to perform a single precision doubling. + +\subsection{Division by Two} +A division by two can just as easily be accomplished with a logical shift right as multiplication by two can be with a logical shift left. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_2}. \\ +\textbf{Input}. One mp\_int $a$ \\ +\textbf{Output}. $b = a/2$. \\ +\hline \\ +1. If $b.alloc < a.used$ then grow $b$ to hold $a.used$ digits. (\textit{mp\_grow}) \\ +2. If the reallocation failed return(\textit{MP\_MEM}). \\ +3. $oldused \leftarrow b.used$ \\ +4. $b.used \leftarrow a.used$ \\ +5. $r \leftarrow 0$ \\ +6. for $n$ from $b.used - 1$ to $0$ do \\ +\hspace{3mm}6.1 $rr \leftarrow a_n \mbox{ (mod }2\mbox{)}$\\ +\hspace{3mm}6.2 $b_n \leftarrow (a_n >> 1) + (r << (lg(\beta) - 1)) \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}6.3 $r \leftarrow rr$ \\ +7. If $b.used < oldused - 1$ then do \\ +\hspace{3mm}7.1 for $n$ from $b.used$ to $oldused - 1$ do \\ +\hspace{6mm}7.1.1 $b_n \leftarrow 0$ \\ +8. $b.sign \leftarrow a.sign$ \\ +9. Clamp excess digits of $b$. (\textit{mp\_clamp}) \\ +10. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_2} +\end{figure} + +\textbf{Algorithm mp\_div\_2.} +This algorithm will divide an mp\_int by two using logical shifts to the right. Like mp\_mul\_2 it uses a modified low level addition +core as the basis of the algorithm. Unlike mp\_mul\_2 the shift operations work from the leading digit to the trailing digit. The algorithm +could be written to work from the trailing digit to the leading digit however, it would have to stop one short of $a.used - 1$ digits to prevent +reading past the end of the array of digits. + +Essentially the loop at step 6 is similar to that of mp\_mul\_2 except the logical shifts go in the opposite direction and the carry is at the +least significant bit not the most significant bit. + +EXAM,bn_mp_div_2.c + +\section{Polynomial Basis Operations} +Recall from ~POLY~ that any integer can be represented as a polynomial in $x$ as $y = f(\beta)$. Such a representation is also known as +the polynomial basis \cite[pp. 48]{ROSE}. Given such a notation a multiplication or division by $x$ amounts to shifting whole digits a single +place. The need for such operations arises in several other higher level algorithms such as Barrett and Montgomery reduction, integer +division and Karatsuba multiplication. + +Converting from an array of digits to polynomial basis is very simple. Consider the integer $y \equiv (a_2, a_1, a_0)_{\beta}$ and recall that +$y = \sum_{i=0}^{2} a_i \beta^i$. Simply replace $\beta$ with $x$ and the expression is in polynomial basis. For example, $f(x) = 8x + 9$ is the +polynomial basis representation for $89$ using radix ten. That is, $f(10) = 8(10) + 9 = 89$. + +\subsection{Multiplication by $x$} + +Given a polynomial in $x$ such as $f(x) = a_n x^n + a_{n-1} x^{n-1} + ... + a_0$ multiplying by $x$ amounts to shifting the coefficients up one +degree. In this case $f(x) \cdot x = a_n x^{n+1} + a_{n-1} x^n + ... + a_0 x$. From a scalar basis point of view multiplying by $x$ is equivalent to +multiplying by the integer $\beta$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_lshd}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $a \leftarrow a \cdot \beta^b$ (equivalent to multiplication by $x^b$). \\ +\hline \\ +1. If $b \le 0$ then return(\textit{MP\_OKAY}). \\ +2. If $a.alloc < a.used + b$ then grow $a$ to at least $a.used + b$ digits. (\textit{mp\_grow}). \\ +3. If the reallocation failed return(\textit{MP\_MEM}). \\ +4. $a.used \leftarrow a.used + b$ \\ +5. $i \leftarrow a.used - 1$ \\ +6. $j \leftarrow a.used - 1 - b$ \\ +7. for $n$ from $a.used - 1$ to $b$ do \\ +\hspace{3mm}7.1 $a_{i} \leftarrow a_{j}$ \\ +\hspace{3mm}7.2 $i \leftarrow i - 1$ \\ +\hspace{3mm}7.3 $j \leftarrow j - 1$ \\ +8. for $n$ from 0 to $b - 1$ do \\ +\hspace{3mm}8.1 $a_n \leftarrow 0$ \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_lshd} +\end{figure} + +\textbf{Algorithm mp\_lshd.} +This algorithm multiplies an mp\_int by the $b$'th power of $x$. This is equivalent to multiplying by $\beta^b$. The algorithm differs +from the other algorithms presented so far as it performs the operation in place instead storing the result in a separate location. The +motivation behind this change is due to the way this function is typically used. Algorithms such as mp\_add store the result in an optionally +different third mp\_int because the original inputs are often still required. Algorithm mp\_lshd (\textit{and similarly algorithm mp\_rshd}) is +typically used on values where the original value is no longer required. The algorithm will return success immediately if +$b \le 0$ since the rest of algorithm is only valid when $b > 0$. + +First the destination $a$ is grown as required to accomodate the result. The counters $i$ and $j$ are used to form a \textit{sliding window} over +the digits of $a$ of length $b$. The head of the sliding window is at $i$ (\textit{the leading digit}) and the tail at $j$ (\textit{the trailing digit}). +The loop on step 7 copies the digit from the tail to the head. In each iteration the window is moved down one digit. The last loop on +step 8 sets the lower $b$ digits to zero. + +\newpage +FIGU,sliding_window,Sliding Window Movement + +EXAM,bn_mp_lshd.c + +The if statement on line @24,if@ ensures that the $b$ variable is greater than zero. The \textbf{used} count is incremented by $b$ before +the copy loop begins. This elminates the need for an additional variable in the for loop. The variable $top$ on line @42,top@ is an alias +for the leading digit while $bottom$ on line @45,bottom@ is an alias for the trailing edge. The aliases form a window of exactly $b$ digits +over the input. + +\subsection{Division by $x$} + +Division by powers of $x$ is easily achieved by shifting the digits right and removing any that will end up to the right of the zero'th digit. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_rshd}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $a \leftarrow a / \beta^b$ (Divide by $x^b$). \\ +\hline \\ +1. If $b \le 0$ then return. \\ +2. If $a.used \le b$ then do \\ +\hspace{3mm}2.1 Zero $a$. (\textit{mp\_zero}). \\ +\hspace{3mm}2.2 Return. \\ +3. $i \leftarrow 0$ \\ +4. $j \leftarrow b$ \\ +5. for $n$ from 0 to $a.used - b - 1$ do \\ +\hspace{3mm}5.1 $a_i \leftarrow a_j$ \\ +\hspace{3mm}5.2 $i \leftarrow i + 1$ \\ +\hspace{3mm}5.3 $j \leftarrow j + 1$ \\ +6. for $n$ from $a.used - b$ to $a.used - 1$ do \\ +\hspace{3mm}6.1 $a_n \leftarrow 0$ \\ +7. $a.used \leftarrow a.used - b$ \\ +8. Return. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_rshd} +\end{figure} + +\textbf{Algorithm mp\_rshd.} +This algorithm divides the input in place by the $b$'th power of $x$. It is analogous to dividing by a $\beta^b$ but much quicker since +it does not require single precision division. This algorithm does not actually return an error code as it cannot fail. + +If the input $b$ is less than one the algorithm quickly returns without performing any work. If the \textbf{used} count is less than or equal +to the shift count $b$ then it will simply zero the input and return. + +After the trivial cases of inputs have been handled the sliding window is setup. Much like the case of algorithm mp\_lshd a sliding window that +is $b$ digits wide is used to copy the digits. Unlike mp\_lshd the window slides in the opposite direction from the trailing to the leading digit. +Also the digits are copied from the leading to the trailing edge. + +Once the window copy is complete the upper digits must be zeroed and the \textbf{used} count decremented. + +EXAM,bn_mp_rshd.c + +The only noteworthy element of this routine is the lack of a return type. + +-- Will update later to give it a return type...Tom + +\section{Powers of Two} + +Now that algorithms for moving single bits as well as whole digits exist algorithms for moving the ``in between'' distances are required. For +example, to quickly multiply by $2^k$ for any $k$ without using a full multiplier algorithm would prove useful. Instead of performing single +shifts $k$ times to achieve a multiplication by $2^{\pm k}$ a mixture of whole digit shifting and partial digit shifting is employed. + +\subsection{Multiplication by Power of Two} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot 2^b$. \\ +\hline \\ +1. $c \leftarrow a$. (\textit{mp\_copy}) \\ +2. If $c.alloc < c.used + \lfloor b / lg(\beta) \rfloor + 2$ then grow $c$ accordingly. \\ +3. If the reallocation failed return(\textit{MP\_MEM}). \\ +4. If $b \ge lg(\beta)$ then \\ +\hspace{3mm}4.1 $c \leftarrow c \cdot \beta^{\lfloor b / lg(\beta) \rfloor}$ (\textit{mp\_lshd}). \\ +\hspace{3mm}4.2 If step 4.1 failed return(\textit{MP\_MEM}). \\ +5. $d \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +6. If $d \ne 0$ then do \\ +\hspace{3mm}6.1 $mask \leftarrow 2^d$ \\ +\hspace{3mm}6.2 $r \leftarrow 0$ \\ +\hspace{3mm}6.3 for $n$ from $0$ to $c.used - 1$ do \\ +\hspace{6mm}6.3.1 $rr \leftarrow c_n >> (lg(\beta) - d) \mbox{ (mod }mask\mbox{)}$ \\ +\hspace{6mm}6.3.2 $c_n \leftarrow (c_n << d) + r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}6.3.3 $r \leftarrow rr$ \\ +\hspace{3mm}6.4 If $r > 0$ then do \\ +\hspace{6mm}6.4.1 $c_{c.used} \leftarrow r$ \\ +\hspace{6mm}6.4.2 $c.used \leftarrow c.used + 1$ \\ +7. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_2d} +\end{figure} + +\textbf{Algorithm mp\_mul\_2d.} +This algorithm multiplies $a$ by $2^b$ and stores the result in $c$. The algorithm uses algorithm mp\_lshd and a derivative of algorithm mp\_mul\_2 to +quickly compute the product. + +First the algorithm will multiply $a$ by $x^{\lfloor b / lg(\beta) \rfloor}$ which will ensure that the remainder multiplicand is less than +$\beta$. For example, if $b = 37$ and $\beta = 2^{28}$ then this step will multiply by $x$ leaving a multiplication by $2^{37 - 28} = 2^{9}$ +left. + +After the digits have been shifted appropriately at most $lg(\beta) - 1$ shifts are left to perform. Step 5 calculates the number of remaining shifts +required. If it is non-zero a modified shift loop is used to calculate the remaining product. +Essentially the loop is a generic version of algorith mp\_mul2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ +variable is used to extract the upper $d$ bits to form the carry for the next iteration. + +This algorithm is loosely measured as a $O(2n)$ algorithm which means that if the input is $n$-digits that it takes $2n$ ``time'' to +complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm at a cost of making the algorithm slightly harder to follow. + +EXAM,bn_mp_mul_2d.c + +Notes to be revised when code is updated. -- Tom + +\subsection{Division by Power of Two} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow \lfloor a / 2^b \rfloor, d \leftarrow a \mbox{ (mod }2^b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then do \\ +\hspace{3mm}1.1 $c \leftarrow a$ (\textit{mp\_copy}) \\ +\hspace{3mm}1.2 $d \leftarrow 0$ (\textit{mp\_zero}) \\ +\hspace{3mm}1.3 Return(\textit{MP\_OKAY}). \\ +2. $c \leftarrow a$ \\ +3. $d \leftarrow a \mbox{ (mod }2^b\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +4. If $b \ge lg(\beta)$ then do \\ +\hspace{3mm}4.1 $c \leftarrow \lfloor c/\beta^{\lfloor b/lg(\beta) \rfloor} \rfloor$ (\textit{mp\_rshd}). \\ +5. $k \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +6. If $k \ne 0$ then do \\ +\hspace{3mm}6.1 $mask \leftarrow 2^k$ \\ +\hspace{3mm}6.2 $r \leftarrow 0$ \\ +\hspace{3mm}6.3 for $n$ from $c.used - 1$ to $0$ do \\ +\hspace{6mm}6.3.1 $rr \leftarrow c_n \mbox{ (mod }mask\mbox{)}$ \\ +\hspace{6mm}6.3.2 $c_n \leftarrow (c_n >> k) + (r << (lg(\beta) - k))$ \\ +\hspace{6mm}6.3.3 $r \leftarrow rr$ \\ +7. Clamp excess digits of $c$. (\textit{mp\_clamp}) \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_2d} +\end{figure} + +\textbf{Algorithm mp\_div\_2d.} +This algorithm will divide an input $a$ by $2^b$ and produce the quotient and remainder. The algorithm is designed much like algorithm +mp\_mul\_2d by first using whole digit shifts then single precision shifts. This algorithm will also produce the remainder of the division +by using algorithm mp\_mod\_2d. + +EXAM,bn_mp_div_2d.c + +The implementation of algorithm mp\_div\_2d is slightly different than the algorithm specifies. The remainder $d$ may be optionally +ignored by passing \textbf{NULL} as the pointer to the mp\_int variable. The temporary mp\_int variable $t$ is used to hold the +result of the remainder operation until the end. This allows $d$ and $a$ to represent the same mp\_int without modifying $a$ before +the quotient is obtained. + +The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. (-- Fix this paragraph up later, Tom). + +\subsection{Remainder of Division by Power of Two} + +The last algorithm in the series of polynomial basis power of two algorithms is calculating the remainder of division by $2^b$. This +algorithm benefits from the fact that in twos complement arithmetic $a \mbox{ (mod }2^b\mbox{)}$ is the same as $a$ AND $2^b - 1$. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mod\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow a \mbox{ (mod }2^b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then do \\ +\hspace{3mm}1.1 $c \leftarrow 0$ (\textit{mp\_zero}) \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $b > a.used \cdot lg(\beta)$ then do \\ +\hspace{3mm}2.1 $c \leftarrow a$ (\textit{mp\_copy}) \\ +\hspace{3mm}2.2 Return the result of step 2.1. \\ +3. $c \leftarrow a$ \\ +4. If step 3 failed return(\textit{MP\_MEM}). \\ +5. for $n$ from $\lceil b / lg(\beta) \rceil$ to $c.used$ do \\ +\hspace{3mm}5.1 $c_n \leftarrow 0$ \\ +6. $k \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +7. $c_{\lfloor b / lg(\beta) \rfloor} \leftarrow c_{\lfloor b / lg(\beta) \rfloor} \mbox{ (mod }2^{k}\mbox{)}$. \\ +8. Clamp excess digits of $c$. (\textit{mp\_clamp}) \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mod\_2d} +\end{figure} + +\textbf{Algorithm mp\_mod\_2d.} +This algorithm will quickly calculate the value of $a \mbox{ (mod }2^b\mbox{)}$. First if $b$ is less than or equal to zero the +result is set to zero. If $b$ is greater than the number of bits in $a$ then it simply copies $a$ to $c$ and returns. Otherwise, $a$ +is copied to $b$, leading digits are removed and the remaining leading digit is trimed to the exact bit count. + +EXAM,bn_mp_mod_2d.c + +-- Add comments later, Tom. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ] $ & Devise an algorithm that performs $a \cdot 2^b$ for generic values of $b$ \\ + & in $O(n)$ time. \\ + &\\ +$\left [ 3 \right ] $ & Devise an efficient algorithm to multiply by small low hamming \\ + & weight values such as $3$, $5$ and $9$. Extend it to handle all values \\ + & upto $64$ with a hamming weight less than three. \\ + &\\ +$\left [ 2 \right ] $ & Modify the preceding algorithm to handle values of the form \\ + & $2^k - 1$ as well. \\ + &\\ +$\left [ 3 \right ] $ & Using only algorithms mp\_mul\_2, mp\_div\_2 and mp\_add create an \\ + & algorithm to multiply two integers in roughly $O(2n^2)$ time for \\ + & any $n$-bit input. Note that the time of addition is ignored in the \\ + & calculation. \\ + & \\ +$\left [ 5 \right ] $ & Improve the previous algorithm to have a working time of at most \\ + & $O \left (2^{(k-1)}n + \left ({2n^2 \over k} \right ) \right )$ for an appropriate choice of $k$. Again ignore \\ + & the cost of addition. \\ + & \\ +$\left [ 2 \right ] $ & Devise a chart to find optimal values of $k$ for the previous problem \\ + & for $n = 64 \ldots 1024$ in steps of $64$. \\ + & \\ +$\left [ 2 \right ] $ & Using only algorithms mp\_abs and mp\_sub devise another method for \\ + & calculating the result of a signed comparison. \\ + & +\end{tabular} + +\chapter{Multiplication and Squaring} +\section{The Multipliers} +For most number theoretic problems including certain public key cryptographic algorithms, the ``multipliers'' form the most important subset of +algorithms of any multiple precision integer package. The set of multiplier algorithms include integer multiplication, squaring and modular reduction +where in each of the algorithms single precision multiplication is the dominant operation performed. This chapter will discuss integer multiplication +and squaring, leaving modular reductions for the subsequent chapter. + +The importance of the multiplier algorithms is for the most part driven by the fact that certain popular public key algorithms are based on modular +exponentiation, that is computing $d \equiv a^b \mbox{ (mod }c\mbox{)}$ for some arbitrary choice of $a$, $b$, $c$ and $d$. During a modular +exponentiation the majority\footnote{Roughly speaking a modular exponentiation will spend about 40\% of the time performing modular reductions, +35\% of the time performing squaring and 25\% of the time performing multiplications.} of the processor time is spent performing single precision +multiplications. + +For centuries general purpose multiplication has required a lengthly $O(n^2)$ process, whereby each digit of one multiplicand has to be multiplied +against every digit of the other multiplicand. Traditional long-hand multiplication is based on this process; while the techniques can differ the +overall algorithm used is essentially the same. Only ``recently'' have faster algorithms been studied. First Karatsuba multiplication was discovered in +1962. This algorithm can multiply two numbers with considerably fewer single precision multiplications when compared to the long-hand approach. +This technique led to the discovery of polynomial basis algorithms (\textit{good reference?}) and subquently Fourier Transform based solutions. + +\section{Multiplication} +\subsection{The Baseline Multiplication} +\label{sec:basemult} +\index{baseline multiplication} +Computing the product of two integers in software can be achieved using a trivial adaptation of the standard $O(n^2)$ long-hand multiplication +algorithm that school children are taught. The algorithm is considered an $O(n^2)$ algorithm since for two $n$-digit inputs $n^2$ single precision +multiplications are required. More specifically for a $m$ and $n$ digit input $m \cdot n$ single precision multiplications are required. To +simplify most discussions, it will be assumed that the inputs have comparable number of digits. + +The ``baseline multiplication'' algorithm is designed to act as the ``catch-all'' algorithm, only to be used when the faster algorithms cannot be +used. This algorithm does not use any particularly interesting optimizations and should ideally be avoided if possible. One important +facet of this algorithm, is that it has been modified to only produce a certain amount of output digits as resolution. The importance of this +modification will become evident during the discussion of Barrett modular reduction. Recall that for a $n$ and $m$ digit input the product +will be at most $n + m$ digits. Therefore, this algorithm can be reduced to a full multiplier by having it produce $n + m$ digits of the product. + +Recall from ~GAMMA~ the definition of $\gamma$ as the number of bits in the type \textbf{mp\_digit}. We shall now extend the variable set to +include $\alpha$ which shall represent the number of bits in the type \textbf{mp\_word}. This implies that $2^{\alpha} > 2 \cdot \beta^2$. The +constant $\delta = 2^{\alpha - 2lg(\beta)}$ will represent the maximal weight of any column in a product (\textit{see ~COMBA~ for more information}). + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_mul\_digs}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ +\hline \\ +1. If min$(a.used, b.used) < \delta$ then do \\ +\hspace{3mm}1.1 Calculate $c = \vert a \vert \cdot \vert b \vert$ by the Comba method (\textit{see algorithm~\ref{fig:COMBAMULT}}). \\ +\hspace{3mm}1.2 Return the result of step 1.1 \\ +\\ +Allocate and initialize a temporary mp\_int. \\ +2. Init $t$ to be of size $digs$ \\ +3. If step 2 failed return(\textit{MP\_MEM}). \\ +4. $t.used \leftarrow digs$ \\ +\\ +Compute the product. \\ +5. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}5.1 $u \leftarrow 0$ \\ +\hspace{3mm}5.2 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ +\hspace{3mm}5.3 If $pb < 1$ then goto step 6. \\ +\hspace{3mm}5.4 for $iy$ from $0$ to $pb - 1$ do \\ +\hspace{6mm}5.4.1 $\hat r \leftarrow t_{iy + ix} + a_{ix} \cdot b_{iy} + u$ \\ +\hspace{6mm}5.4.2 $t_{iy + ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}5.4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}5.5 if $ix + pb < digs$ then do \\ +\hspace{6mm}5.5.1 $t_{ix + pb} \leftarrow u$ \\ +6. Clamp excess digits of $t$. \\ +7. Swap $c$ with $t$ \\ +8. Clear $t$ \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_mul\_digs} +\end{figure} + +\textbf{Algorithm s\_mp\_mul\_digs.} +This algorithm computes the unsigned product of two inputs $a$ and $b$, limited to an output precision of $digs$ digits. While it may seem +a bit awkward to modify the function from its simple $O(n^2)$ description, the usefulness of partial multipliers will arise in a subsequent +algorithm. The algorithm is loosely based on algorithm 14.12 from \cite[pp. 595]{HAC} and is similar to Algorithm M of Knuth \cite[pp. 268]{TAOCPV2}. +Algorithm s\_mp\_mul\_digs differs from these cited references since it can produce a variable output precision regardless of the precision of the +inputs. + +The first thing this algorithm checks for is whether a Comba multiplier can be used instead. If the minimum digit count of either +input is less than $\delta$, then the Comba method may be used instead. After the Comba method is ruled out, the baseline algorithm begins. A +temporary mp\_int variable $t$ is used to hold the intermediate result of the product. This allows the algorithm to be used to +compute products when either $a = c$ or $b = c$ without overwriting the inputs. + +All of step 5 is the infamous $O(n^2)$ multiplication loop slightly modified to only produce upto $digs$ digits of output. The $pb$ variable +is given the count of digits to read from $b$ inside the nested loop. If $pb \le 1$ then no more output digits can be produced and the algorithm +will exit the loop. The best way to think of the loops are as a series of $pb \times 1$ multiplications. That is, in each pass of the +innermost loop $a_{ix}$ is multiplied against $b$ and the result is added (\textit{with an appropriate shift}) to $t$. + +For example, consider multiplying $576$ by $241$. That is equivalent to computing $10^0(1)(576) + 10^1(4)(576) + 10^2(2)(576)$ which is best +visualized in the following table. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{|c|c|c|c|c|c|l|} +\hline && & 5 & 7 & 6 & \\ +\hline $\times$&& & 2 & 4 & 1 & \\ +\hline &&&&&&\\ + && & 5 & 7 & 6 & $10^0(1)(576)$ \\ + &2 & 3 & 6 & 1 & 6 & $10^1(4)(576) + 10^0(1)(576)$ \\ + 1 & 3 & 8 & 8 & 1 & 6 & $10^2(2)(576) + 10^1(4)(576) + 10^0(1)(576)$ \\ +\hline +\end{tabular} +\end{center} +\caption{Long-Hand Multiplication Diagram} +\end{figure} + +Each row of the product is added to the result after being shifted to the left (\textit{multiplied by a power of the radix}) by the appropriate +count. That is in pass $ix$ of the inner loop the product is added starting at the $ix$'th digit of the reult. + +Step 5.4.1 introduces the hat symbol (\textit{e.g. $\hat r$}) which represents a double precision variable. The multiplication on that step +is assumed to be a double wide output single precision multiplication. That is, two single precision variables are multiplied to produce a +double precision result. The step is somewhat optimized from a long-hand multiplication algorithm because the carry from the addition in step +5.4.1 is propagated through the nested loop. If the carry was not propagated immediately it would overflow the single precision digit +$t_{ix+iy}$ and the result would be lost. + +At step 5.5 the nested loop is finished and any carry that was left over should be forwarded. The carry does not have to be added to the $ix+pb$'th +digit since that digit is assumed to be zero at this point. However, if $ix + pb \ge digs$ the carry is not set as it would make the result +exceed the precision requested. + +EXAM,bn_s_mp_mul_digs.c + +Lines @31,if@ to @35,}@ determine if the Comba method can be used first. The conditions for using the Comba routine are that min$(a.used, b.used) < \delta$ and +the number of digits of output is less than \textbf{MP\_WARRAY}. This new constant is used to control +the stack usage in the Comba routines. By default it is set to $\delta$ but can be reduced when memory is at a premium. + +Of particular importance is the calculation of the $ix+iy$'th column on lines @64,mp_word@, @65,mp_word@ and @66,mp_word@. Note how all of the +variables are cast to the type \textbf{mp\_word}, which is also the type of variable $\hat r$. That is to ensure that double precision operations +are used instead of single precision. The multiplication on line @65,) * (@ makes use of a specific GCC optimizer behaviour. On the outset it looks like +the compiler will have to use a double precision multiplication to produce the result required. Such an operation would be horribly slow on most +processors and drag this to a crawl. However, GCC is smart enough to realize that double wide output single precision multipliers can be used. For +example, the instruction ``MUL'' on the x86 processor can multiply two 32-bit values and produce a 64-bit result. + +\subsection{Faster Multiplication by the ``Comba'' Method} +MARK,COMBA + +One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be computed and propagated upwards. This +makes the nested loop very sequential and hard to unroll and implement in parallel. The ``Comba'' \cite{COMBA} method is named after little known +(\textit{in cryptographic venues}) Paul G. Comba who described a method of implementing fast multipliers that do not require nested +carry fixup operations. As an interesting aside it seems that Paul Barrett describes a similar technique in +his 1986 paper \cite{BARRETT} written five years before. + +At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight twist is placed on how +the columns of the result are produced. In the standard long-hand algorithm rows of products are produced then added together to form the +final result. In the baseline algorithm the columns are added together after each iteration to get the result instantaneously. + +In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at the $O(n^2)$ level a +simple multiplication and addition step is performed. The carries of the columns are propagated after the nested loop to reduce the amount +of work requiored. Succintly the first step of the algorithm is to compute the product vector $\vec x$ as follows. + +\begin{equation} +\vec x_n = \sum_{i+j = n} a_ib_j, \forall n \in \lbrace 0, 1, 2, \ldots, i + j \rbrace +\end{equation} + +Where $\vec x_n$ is the $n'th$ column of the output vector. Consider the following example which computes the vector $\vec x$ for the multiplication +of $576$ and $241$. + +\newpage\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|c|} + \hline & & 5 & 7 & 6 & First Input\\ + \hline $\times$ & & 2 & 4 & 1 & Second Input\\ +\hline & & $1 \cdot 5 = 5$ & $1 \cdot 7 = 7$ & $1 \cdot 6 = 6$ & First pass \\ + & $4 \cdot 5 = 20$ & $4 \cdot 7+5=33$ & $4 \cdot 6+7=31$ & 6 & Second pass \\ + $2 \cdot 5 = 10$ & $2 \cdot 7 + 20 = 34$ & $2 \cdot 6+33=45$ & 31 & 6 & Third pass \\ +\hline 10 & 34 & 45 & 31 & 6 & Final Result \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Comba Multiplication Diagram} +\end{figure} + +At this point the vector $x = \left < 10, 34, 45, 31, 6 \right >$ is the result of the first step of the Comba multipler. +Now the columns must be fixed by propagating the carry upwards. The resultant vector will have one extra dimension over the input vector which is +congruent to adding a leading zero digit. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Comba Fixup}. \\ +\textbf{Input}. Vector $\vec x$ of dimension $k$ \\ +\textbf{Output}. Vector $\vec x$ such that the carries have been propagated. \\ +\hline \\ +1. for $n$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 $\vec x_{n+1} \leftarrow \vec x_{n+1} + \lfloor \vec x_{n}/\beta \rfloor$ \\ +\hspace{3mm}1.2 $\vec x_{n} \leftarrow \vec x_{n} \mbox{ (mod }\beta\mbox{)}$ \\ +2. Return($\vec x$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Comba Fixup} +\end{figure} + +With that algorithm and $k = 5$ and $\beta = 10$ the following vector is produced $\vec x= \left < 1, 3, 8, 8, 1, 6 \right >$. In this case +$241 \cdot 576$ is in fact $138816$ and the procedure succeeded. If the algorithm is correct and as will be demonstrated shortly more +efficient than the baseline algorithm why not simply always use this algorithm? + +\subsubsection{Column Weight.} +At the nested $O(n^2)$ level the Comba method adds the product of two single precision variables to each column of the output +independently. A serious obstacle is if the carry is lost, due to lack of precision before the algorithm has a chance to fix +the carries. For example, in the multiplication of two three-digit numbers the third column of output will be the sum of +three single precision multiplications. If the precision of the accumulator for the output digits is less then $3 \cdot (\beta - 1)^2$ then +an overflow can occur and the carry information will be lost. For any $m$ and $n$ digit inputs the maximum weight of any column is +min$(m, n)$ which is fairly obvious. + +The maximum number of terms in any column of a product is known as the ``column weight'' and strictly governs when the algorithm can be used. Recall +from earlier that a double precision type has $\alpha$ bits of resolution and a single precision digit has $lg(\beta)$ bits of precision. Given these +two quantities we must not violate the following + +\begin{equation} +k \cdot \left (\beta - 1 \right )^2 < 2^{\alpha} +\end{equation} + +Which reduces to + +\begin{equation} +k \cdot \left ( \beta^2 - 2\beta + 1 \right ) < 2^{\alpha} +\end{equation} + +Let $\rho = lg(\beta)$ represent the number of bits in a single precision digit. By further re-arrangement of the equation the final solution is +found. + +\begin{equation} +k < {{2^{\alpha}} \over {\left (2^{2\rho} - 2^{\rho + 1} + 1 \right )}} +\end{equation} + +The defaults for LibTomMath are $\beta = 2^{28}$ and $\alpha = 2^{64}$ which means that $k$ is bounded by $k < 257$. In this configuration +the smaller input may not have more than $256$ digits if the Comba method is to be used. This is quite satisfactory for most applications since +$256$ digits would allow for numbers in the range of $0 \le x < 2^{7168}$ which, is much larger than most public key cryptographic algorithms require. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_s\_mp\_mul\_digs}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ +\hline \\ +Place an array of \textbf{MP\_WARRAY} double precision digits named $\hat W$ on the stack. \\ +1. If $c.alloc < digs$ then grow $c$ to $digs$ digits. (\textit{mp\_grow}) \\ +2. If step 1 failed return(\textit{MP\_MEM}).\\ +\\ +Zero the temporary array $\hat W$. \\ +3. for $n$ from $0$ to $digs - 1$ do \\ +\hspace{3mm}3.1 $\hat W_n \leftarrow 0$ \\ +\\ +Compute the columns. \\ +4. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}4.1 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ +\hspace{3mm}4.2 If $pb < 1$ then goto step 5. \\ +\hspace{3mm}4.3 for $iy$ from $0$ to $pb - 1$ do \\ +\hspace{6mm}4.3.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}b_{iy}$ \\ +\\ +Propagate the carries upwards. \\ +5. $oldused \leftarrow c.used$ \\ +6. $c.used \leftarrow digs$ \\ +7. If $digs > 1$ then do \\ +\hspace{3mm}7.1. for $ix$ from $1$ to $digs - 1$ do \\ +\hspace{6mm}7.1.1 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix-1} / \beta \rfloor$ \\ +\hspace{6mm}7.1.2 $c_{ix - 1} \leftarrow \hat W_{ix - 1} \mbox{ (mod }\beta\mbox{)}$ \\ +8. else do \\ +\hspace{3mm}8.1 $ix \leftarrow 0$ \\ +9. $c_{ix} \leftarrow \hat W_{ix} \mbox{ (mod }\beta\mbox{)}$ \\ +\\ +Zero excess digits. \\ +10. If $digs < oldused$ then do \\ +\hspace{3mm}10.1 for $n$ from $digs$ to $oldused - 1$ do \\ +\hspace{6mm}10.1.1 $c_n \leftarrow 0$ \\ +11. Clamp excessive digits of $c$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_s\_mp\_mul\_digs} +\label{fig:COMBAMULT} +\end{figure} + +\textbf{Algorithm fast\_s\_mp\_mul\_digs.} +This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. The algorithm +essentially peforms the same calculation as algorithm s\_mp\_mul\_digs, just much faster. + +The array $\hat W$ is meant to be on the stack when the algorithm is used. The size of the array does not change which is ideal. Note also that +unlike algorithm s\_mp\_mul\_digs no temporary mp\_int is required since the result is calculated directly in $\hat W$. + +The $O(n^2)$ loop on step four is where the Comba method's advantages begin to show through in comparison to the baseline algorithm. The lack of +a carry variable or propagation in this loop allows the loop to be performed with only single precision multiplication and additions. Now that each +iteration of the inner loop can be performed independent of the others the inner loop can be performed with a high level of parallelism. + +To measure the benefits of the Comba method over the baseline method consider the number of operations that are required. If the +cost in terms of time of a multiply and addition is $p$ and the cost of a carry propagation is $q$ then a baseline multiplication would require +$O \left ((p + q)n^2 \right )$ time to multiply two $n$-digit numbers. The Comba method requires only $O(pn^2 + qn)$ time, however in practice, +the speed increase is actually much more. With $O(n)$ space the algorithm can be reduced to $O(pn + qn)$ time by implementing the $n$ multiply +and addition operations in the nested loop in parallel. + +EXAM,bn_fast_s_mp_mul_digs.c + +The memset on line @47,memset@ clears the initial $\hat W$ array to zero in a single step. Like the slower baseline multiplication +implementation a series of aliases (\textit{lines @67, tmpx@, @70, tmpy@ and @75,_W@}) are used to simplify the inner $O(n^2)$ loop. +In this case a new alias $\_\hat W$ has been added which refers to the double precision columns offset by $ix$ in each pass. + +The inner loop on lines @83,for@, @84,mp_word@ and @85,}@ is where the algorithm will spend the majority of the time, which is why it has been +stripped to the bones of any extra baggage\footnote{Hence the pointer aliases.}. On x86 processors the multiplication and additions amount to at the +very least five instructions (\textit{two loads, two additions, one multiply}) while on the ARMv4 processors they amount to only three +(\textit{one load, one store, one multiply-add}). For both of the x86 and ARMv4 processors the GCC compiler performs a good job at unrolling the loop +and scheduling the instructions so there are very few dependency stalls. + +In theory the difference between the baseline and comba algorithms is a mere $O(qn)$ time difference. However, in the $O(n^2)$ nested loop of the +baseline method there are dependency stalls as the algorithm must wait for the multiplier to finish before propagating the carry to the next +digit. As a result fewer of the often multiple execution units\footnote{The AMD Athlon has three execution units and the Intel P4 has four.} can +be simultaneously used. + +\subsection{Polynomial Basis Multiplication} +To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms +the use of polynomial basis representation for two integers $a$ and $b$ as $f(x) = \sum_{i=0}^{n} a_i x^i$ and +$g(x) = \sum_{i=0}^{n} b_i x^i$ respectively, is required. In this system both $f(x)$ and $g(x)$ have $n + 1$ terms and are of the $n$'th degree. + +The product $a \cdot b \equiv f(x)g(x)$ is the polynomial $W(x) = \sum_{i=0}^{2n} w_i x^i$. The coefficients $w_i$ will +directly yield the desired product when $\beta$ is substituted for $x$. The direct solution to solve for the $2n + 1$ coefficients +requires $O(n^2)$ time and would in practice be slower than the Comba technique. + +However, numerical analysis theory indicates that only $2n + 1$ distinct points in $W(x)$ are required to determine the values of the $2n + 1$ unknown +coefficients. This means by finding $\zeta_y = W(y)$ for $2n + 1$ small values of $y$ the coefficients of $W(x)$ can be found with +Gaussian elimination. This technique is also occasionally refered to as the \textit{interpolation technique} (\textit{references please...}) since in +effect an interpolation based on $2n + 1$ points will yield a polynomial equivalent to $W(x)$. + +The coefficients of the polynomial $W(x)$ are unknown which makes finding $W(y)$ for any value of $y$ impossible. However, since +$W(x) = f(x)g(x)$ the equivalent $\zeta_y = f(y) g(y)$ can be used in its place. The benefit of this technique stems from the +fact that $f(y)$ and $g(y)$ are much smaller than either $a$ or $b$ respectively. As a result finding the $2n + 1$ relations required +by multiplying $f(y)g(y)$ involves multiplying integers that are much smaller than either of the inputs. + +When picking points to gather relations there are always three obvious points to choose, $y = 0, 1$ and $ \infty$. The $\zeta_0$ term +is simply the product $W(0) = w_0 = a_0 \cdot b_0$. The $\zeta_1$ term is the product +$W(1) = \left (\sum_{i = 0}^{n} a_i \right ) \left (\sum_{i = 0}^{n} b_i \right )$. The third point $\zeta_{\infty}$ is less obvious but rather +simple to explain. The $2n + 1$'th coefficient of $W(x)$ is numerically equivalent to the most significant column in an integer multiplication. +The point at $\infty$ is used symbolically to represent the most significant column, that is $W(\infty) = w_{2n} = a_nb_n$. Note that the +points at $y = 0$ and $\infty$ yield the coefficients $w_0$ and $w_{2n}$ directly. + +If more points are required they should be of small values and powers of two such as $2^q$ and the related \textit{mirror points} +$\left (2^q \right )^{2n} \cdot \zeta_{2^{-q}}$ for small values of $q$. The term ``mirror point'' stems from the fact that +$\left (2^q \right )^{2n} \cdot \zeta_{2^{-q}}$ can be calculated in the exact opposite fashion as $\zeta_{2^q}$. For +example, when $n = 2$ and $q = 1$ then following two equations are equivalent to the point $\zeta_{2}$ and its mirror. + +\begin{eqnarray} +\zeta_{2} = f(2)g(2) = (4a_2 + 2a_1 + a_0)(4b_2 + 2b_1 + b_0) \nonumber \\ +16 \cdot \zeta_{1 \over 2} = 4f({1\over 2}) \cdot 4g({1 \over 2}) = (a_2 + 2a_1 + 4a_0)(b_2 + 2b_1 + 4b_0) +\end{eqnarray} + +Using such points will allow the values of $f(y)$ and $g(y)$ to be independently calculated using only left shifts. For example, when $n = 2$ the +polynomial $f(2^q)$ is equal to $2^q((2^qa_2) + a_1) + a_0$. This technique of polynomial representation is known as Horner's method. + +As a general rule of the algorithm when the inputs are split into $n$ parts each there are $2n - 1$ multiplications. Each multiplication is of +multiplicands that have $n$ times fewer digits than the inputs. The asymptotic running time of this algorithm is +$O \left ( k^{lg_n(2n - 1)} \right )$ for $k$ digit inputs (\textit{assuming they have the same number of digits}). Figure~\ref{fig:exponent} +summarizes the exponents for various values of $n$. + +\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Split into $n$ Parts} & \textbf{Exponent} & \textbf{Notes}\\ +\hline $2$ & $1.584962501$ & This is Karatsuba Multiplication. \\ +\hline $3$ & $1.464973520$ & This is Toom-Cook Multiplication. \\ +\hline $4$ & $1.403677461$ &\\ +\hline $5$ & $1.365212389$ &\\ +\hline $10$ & $1.278753601$ &\\ +\hline $100$ & $1.149426538$ &\\ +\hline $1000$ & $1.100270931$ &\\ +\hline $10000$ & $1.075252070$ &\\ +\hline +\end{tabular} +\end{center} +\caption{Asymptotic Running Time of Polynomial Basis Multiplication} +\label{fig:exponent} +\end{figure} + +At first it may seem like a good idea to choose $n = 1000$ since the exponent is approximately $1.1$. However, the overhead +of solving for the 2001 terms of $W(x)$ will certainly consume any savings the algorithm could offer for all but exceedingly large +numbers. + +\subsubsection{Cutoff Point} +The polynomial basis multiplication algorithms all require fewer single precision multiplications than a straight Comba approach. However, +the algorithms incur an overhead (\textit{at the $O(n)$ work level}) since they require a system of equations to be solved. This makes the +polynomial basis approach more costly to use with small inputs. + +Let $m$ represent the number of digits in the multiplicands (\textit{assume both multiplicands have the same number of digits}). There exists a +point $y$ such that when $m < y$ the polynomial basis algorithms are more costly than Comba, when $m = y$ they are roughly the same cost and +when $m > y$ the Comba methods are slower than the polynomial basis algorithms. + +The exact location of $y$ depends on several key architectural elements of the computer platform in question. + +\begin{enumerate} +\item The ratio of clock cycles for single precision multiplication versus other simpler operations such as addition, shifting, etc. For example +on the AMD Athlon the ratio is roughly $17 : 1$ while on the Intel P4 it is $29 : 1$. The higher the ratio in favour of multiplication the lower +the cutoff point $y$ will be. + +\item The complexity of the linear system of equations (\textit{for the coefficients of $W(x)$}) is. Generally speaking as the number of splits +grows the complexity grows substantially. Ideally solving the system will only involve addition, subtraction and shifting of integers. This +directly reflects on the ratio previous mentioned. + +\item To a lesser extent memory bandwidth and function call overheads. Provided the values are in the processor cache this is less of an +influence over the cutoff point. + +\end{enumerate} + +A clean cutoff point separation occurs when a point $y$ is found such that all of the cutoff point conditions are met. For example, if the point +is too low then there will be values of $m$ such that $m > y$ and the Comba method is still faster. Finding the cutoff points is fairly simple when +a high resolution timer is available. + +\subsection{Karatsuba Multiplication} +Karatsuba \cite{KARA} multiplication when originally proposed in 1962 was among the first set of algorithms to break the $O(n^2)$ barrier for +general purpose multiplication. Given two polynomial basis representations $f(x) = ax + b$ and $g(x) = cx + d$, Karatsuba proved with +light algebra \cite{KARAP} that the following polynomial is equivalent to multiplication of the two integers the polynomials represent. + +\begin{equation} +f(x) \cdot g(x) = acx^2 + ((a - b)(c - d) - (ac + bd))x + bd +\end{equation} + +Using the observation that $ac$ and $bd$ could be re-used only three half sized multiplications would be required to produce the product. Applying +this algorithm recursively, the work factor becomes $O(n^{lg(3)})$ which is substantially better than the work factor $O(n^2)$ of the Comba technique. It turns +out what Karatsuba did not know or at least did not publish was that this is simply polynomial basis multiplication with the points +$\zeta_0$, $\zeta_{\infty}$ and $-\zeta_{-1}$. Consider the resultant system of equations. + +\begin{center} +\begin{tabular}{rcrcrcrc} +$\zeta_{0}$ & $=$ & & & & & $w_0$ \\ +$-\zeta_{-1}$ & $=$ & $-w_2$ & $+$ & $w_1$ & $-$ & $w_0$ \\ +$\zeta_{\infty}$ & $=$ & $w_2$ & & & & \\ +\end{tabular} +\end{center} + +By adding the first and last equation to the equation in the middle the term $w_1$ can be isolated and all three coefficients solved for. The simplicity +of this system of equations has made Karatsuba fairly popular. In fact the cutoff point is often fairly low\footnote{With LibTomMath 0.18 it is 70 and 109 digits for the Intel P4 and AMD Athlon respectively.} +making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. It is worth noting that the point +$\zeta_1$ could be substituted for $-\zeta_{-1}$. In this case the first and third row are subtracted instead of added to the second row. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_karatsuba\_mul}. \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert$ \\ +\hline \\ +1. Init the following mp\_int variables: $x0$, $x1$, $y0$, $y1$, $t1$, $x0y0$, $x1y1$.\\ +2. If step 2 failed then return(\textit{MP\_MEM}). \\ +\\ +Split the input. e.g. $a = x1 \cdot \beta^B + x0$ \\ +3. $B \leftarrow \mbox{min}(a.used, b.used)/2$ \\ +4. $x0 \leftarrow a \mbox{ (mod }\beta^B\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +5. $y0 \leftarrow b \mbox{ (mod }\beta^B\mbox{)}$ \\ +6. $x1 \leftarrow \lfloor a / \beta^B \rfloor$ (\textit{mp\_rshd}) \\ +7. $y1 \leftarrow \lfloor b / \beta^B \rfloor$ \\ +\\ +Calculate the three products. \\ +8. $x0y0 \leftarrow x0 \cdot y0$ (\textit{mp\_mul}) \\ +9. $x1y1 \leftarrow x1 \cdot y1$ \\ +10. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +11. $x0 \leftarrow y1 - y0$ \\ +12. $t1 \leftarrow t1 \cdot x0$ \\ +\\ +Calculate the middle term. \\ +13. $x0 \leftarrow x0y0 + x1y1$ \\ +14. $t1 \leftarrow x0 - t1$ \\ +\\ +Calculate the final product. \\ +15. $t1 \leftarrow t1 \cdot \beta^B$ (\textit{mp\_lshd}) \\ +16. $x1y1 \leftarrow x1y1 \cdot \beta^{2B}$ \\ +17. $t1 \leftarrow x0y0 + t1$ \\ +18. $c \leftarrow t1 + x1y1$ \\ +19. Clear all of the temporary variables. \\ +20. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_karatsuba\_mul} +\end{figure} + +\textbf{Algorithm mp\_karatsuba\_mul.} +This algorithm computes the unsigned product of two inputs using the Karatsuba multiplication algorithm. It is loosely based on the description +from Knuth \cite[pp. 294-295]{TAOCPV2}. + +\index{radix point} +In order to split the two inputs into their respective halves, a suitable \textit{radix point} must be chosen. The radix point chosen must +be used for both of the inputs meaning that it must be smaller than the smallest input. Step 3 chooses the radix point $B$ as half of the +smallest input \textbf{used} count. After the radix point is chosen the inputs are split into lower and upper halves. Step 4 and 5 +compute the lower halves. Step 6 and 7 computer the upper halves. + +After the halves have been computed the three intermediate half-size products must be computed. Step 8 and 9 compute the trivial products +$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 - x0$ has been computed. By using $x0$ instead +of an additional temporary variable, the algorithm can avoid an addition memory allocation operation. + +The remaining steps 13 through 18 compute the Karatsuba polynomial through a variety of digit shifting and addition operations. + +EXAM,bn_mp_karatsuba_mul.c + +The new coding element in this routine, not seen in previous routines, is the usage of goto statements. The conventional +wisdom is that goto statements should be avoided. This is generally true, however when every single function call can fail, it makes sense +to handle error recovery with a single piece of code. Lines @61,if@ to @75,if@ handle initializing all of the temporary variables +required. Note how each of the if statements goes to a different label in case of failure. This allows the routine to correctly free only +the temporaries that have been successfully allocated so far. + +The temporary variables are all initialized using the mp\_init\_size routine since they are expected to be large. This saves the +additional reallocation that would have been necessary. Also $x0$, $x1$, $y0$ and $y1$ have to be able to hold at least their respective +number of digits for the next section of code. + +The first algebraic portion of the algorithm is to split the two inputs into their halves. However, instead of using mp\_mod\_2d and mp\_rshd +to extract the halves, the respective code has been placed inline within the body of the function. To initialize the halves, the \textbf{used} and +\textbf{sign} members are copied first. The first for loop on line @98,for@ copies the lower halves. Since they are both the same magnitude it +is simpler to calculate both lower halves in a single loop. The for loop on lines @104,for@ and @109,for@ calculate the upper halves $x1$ and +$y1$ respectively. + +By inlining the calculation of the halves, the Karatsuba multiplier has a slightly lower overhead and can be used for smaller magnitude inputs. + +When line @152,err@ is reached, the algorithm has completed succesfully. The ``error status'' variable $err$ is set to \textbf{MP\_OKAY} so that +the same code that handles errors can be used to clear the temporary variables and return. + +\subsection{Toom-Cook $3$-Way Multiplication} +Toom-Cook $3$-Way \cite{TOOM} multiplication is essentially the polynomial basis algorithm for $n = 2$ except that the points are +chosen such that $\zeta$ is easy to compute and the resulting system of equations easy to reduce. Here, the points $\zeta_{0}$, +$16 \cdot \zeta_{1 \over 2}$, $\zeta_1$, $\zeta_2$ and $\zeta_{\infty}$ make up the five required points to solve for the coefficients +of the $W(x)$. + +With the five relations that Toom-Cook specifies, the following system of equations is formed. + +\begin{center} +\begin{tabular}{rcrcrcrcrcr} +$\zeta_0$ & $=$ & $0w_4$ & $+$ & $0w_3$ & $+$ & $0w_2$ & $+$ & $0w_1$ & $+$ & $1w_0$ \\ +$16 \cdot \zeta_{1 \over 2}$ & $=$ & $1w_4$ & $+$ & $2w_3$ & $+$ & $4w_2$ & $+$ & $8w_1$ & $+$ & $16w_0$ \\ +$\zeta_1$ & $=$ & $1w_4$ & $+$ & $1w_3$ & $+$ & $1w_2$ & $+$ & $1w_1$ & $+$ & $1w_0$ \\ +$\zeta_2$ & $=$ & $16w_4$ & $+$ & $8w_3$ & $+$ & $4w_2$ & $+$ & $2w_1$ & $+$ & $1w_0$ \\ +$\zeta_{\infty}$ & $=$ & $1w_4$ & $+$ & $0w_3$ & $+$ & $0w_2$ & $+$ & $0w_1$ & $+$ & $0w_0$ \\ +\end{tabular} +\end{center} + +A trivial solution to this matrix requires $12$ subtractions, two multiplications by a small power of two, two divisions by a small power +of two, two divisions by three and one multiplication by three. All of these $19$ sub-operations require less than quadratic time, meaning that +the algorithm can be faster than a baseline multiplication. However, the greater complexity of this algorithm places the cutoff point +(\textbf{TOOM\_MUL\_CUTOFF}) where Toom-Cook becomes more efficient much higher than the Karatsuba cutoff point. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_toom\_mul}. \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot b $ \\ +\hline \\ +Split $a$ and $b$ into three pieces. E.g. $a = a_2 \beta^{2k} + a_1 \beta^{k} + a_0$ \\ +1. $k \leftarrow \lfloor \mbox{min}(a.used, b.used) / 3 \rfloor$ \\ +2. $a_0 \leftarrow a \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +3. $a_1 \leftarrow \lfloor a / \beta^k \rfloor$, $a_1 \leftarrow a_1 \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +4. $a_2 \leftarrow \lfloor a / \beta^{2k} \rfloor$, $a_2 \leftarrow a_2 \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +5. $b_0 \leftarrow a \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +6. $b_1 \leftarrow \lfloor a / \beta^k \rfloor$, $b_1 \leftarrow b_1 \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +7. $b_2 \leftarrow \lfloor a / \beta^{2k} \rfloor$, $b_2 \leftarrow b_2 \mbox{ (mod }\beta^{k}\mbox{)}$ \\ +\\ +Find the five equations for $w_0, w_1, ..., w_4$. \\ +8. $w_0 \leftarrow a_0 \cdot b_0$ \\ +9. $w_4 \leftarrow a_2 \cdot b_2$ \\ +10. $tmp_1 \leftarrow 2 \cdot a_0$, $tmp_1 \leftarrow a_1 + tmp_1$, $tmp_1 \leftarrow 2 \cdot tmp_1$, $tmp_1 \leftarrow tmp_1 + a_2$ \\ +11. $tmp_2 \leftarrow 2 \cdot b_0$, $tmp_2 \leftarrow b_1 + tmp_2$, $tmp_2 \leftarrow 2 \cdot tmp_2$, $tmp_2 \leftarrow tmp_2 + b_2$ \\ +12. $w_1 \leftarrow tmp_1 \cdot tmp_2$ \\ +13. $tmp_1 \leftarrow 2 \cdot a_2$, $tmp_1 \leftarrow a_1 + tmp_1$, $tmp_1 \leftarrow 2 \cdot tmp_1$, $tmp_1 \leftarrow tmp_1 + a_0$ \\ +14. $tmp_2 \leftarrow 2 \cdot b_2$, $tmp_2 \leftarrow b_1 + tmp_2$, $tmp_2 \leftarrow 2 \cdot tmp_2$, $tmp_2 \leftarrow tmp_2 + b_0$ \\ +15. $w_3 \leftarrow tmp_1 \cdot tmp_2$ \\ +16. $tmp_1 \leftarrow a_0 + a_1$, $tmp_1 \leftarrow tmp_1 + a_2$, $tmp_2 \leftarrow b_0 + b_1$, $tmp_2 \leftarrow tmp_2 + b_2$ \\ +17. $w_2 \leftarrow tmp_1 \cdot tmp_2$ \\ +\\ +Continued on the next page.\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_toom\_mul} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_toom\_mul} (continued). \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot b $ \\ +\hline \\ +Now solve the system of equations. \\ +18. $w_1 \leftarrow w_4 - w_1$, $w_3 \leftarrow w_3 - w_0$ \\ +19. $w_1 \leftarrow \lfloor w_1 / 2 \rfloor$, $w_3 \leftarrow \lfloor w_3 / 2 \rfloor$ \\ +20. $w_2 \leftarrow w_2 - w_0$, $w_2 \leftarrow w_2 - w_4$ \\ +21. $w_1 \leftarrow w_1 - w_2$, $w_3 \leftarrow w_3 - w_2$ \\ +22. $tmp_1 \leftarrow 8 \cdot w_0$, $w_1 \leftarrow w_1 - tmp_1$, $tmp_1 \leftarrow 8 \cdot w_4$, $w_3 \leftarrow w_3 - tmp_1$ \\ +23. $w_2 \leftarrow 3 \cdot w_2$, $w_2 \leftarrow w_2 - w_1$, $w_2 \leftarrow w_2 - w_3$ \\ +24. $w_1 \leftarrow w_1 - w_2$, $w_3 \leftarrow w_3 - w_2$ \\ +25. $w_1 \leftarrow \lfloor w_1 / 3 \rfloor, w_3 \leftarrow \lfloor w_3 / 3 \rfloor$ \\ +\\ +Now substitute $\beta^k$ for $x$ by shifting $w_0, w_1, ..., w_4$. \\ +26. for $n$ from $1$ to $4$ do \\ +\hspace{3mm}26.1 $w_n \leftarrow w_n \cdot \beta^{nk}$ \\ +27. $c \leftarrow w_0 + w_1$, $c \leftarrow c + w_2$, $c \leftarrow c + w_3$, $c \leftarrow c + w_4$ \\ +28. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_toom\_mul (continued)} +\end{figure} + +\textbf{Algorithm mp\_toom\_mul.} +This algorithm computes the product of two mp\_int variables $a$ and $b$ using the Toom-Cook approach. Compared to the Karatsuba multiplication, this +algorithm has a lower asymptotic running time of approximately $O(n^{1.464})$ but at an obvious cost in overhead. In this +description, several statements have been compounded to save space. The intention is that the statements are executed from left to right across +any given step. + +The two inputs $a$ and $b$ are first split into three $k$-digit integers $a_0, a_1, a_2$ and $b_0, b_1, b_2$ respectively. From these smaller +integers the coefficients of the polynomial basis representations $f(x)$ and $g(x)$ are known and can be used to find the relations required. + +The first two relations $w_0$ and $w_4$ are the points $\zeta_{0}$ and $\zeta_{\infty}$ respectively. The relation $w_1, w_2$ and $w_3$ correspond +to the points $16 \cdot \zeta_{1 \over 2}, \zeta_{2}$ and $\zeta_{1}$ respectively. These are found using logical shifts to independently find +$f(y)$ and $g(y)$ which significantly speeds up the algorithm. + +After the five relations $w_0, w_1, \ldots, w_4$ have been computed, the system they represent must be solved in order for the unknown coefficients +$w_1, w_2$ and $w_3$ to be isolated. The steps 18 through 25 perform the system reduction required as previously described. Each step of +the reduction represents the comparable matrix operation that would be performed had this been performed by pencil. For example, step 18 indicates +that row $1$ must be subtracted from row $4$ and simultaneously row $0$ subtracted from row $3$. + +Once the coeffients have been isolated, the polynomial $W(x) = \sum_{i=0}^{2n} w_i x^i$ is known. By substituting $\beta^{k}$ for $x$, the integer +result $a \cdot b$ is produced. + +EXAM,bn_mp_toom_mul.c + +-- Comments to be added during editing phase. + +\subsection{Signed Multiplication} +Now that algorithms to handle multiplications of every useful dimensions have been developed, a rather simple finishing touch is required. So far all +of the multiplication algorithms have been unsigned multiplications which leaves only a signed multiplication algorithm to be established. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul}. \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot b$ \\ +\hline \\ +1. If $a.sign = b.sign$ then \\ +\hspace{3mm}1.1 $sign = MP\_ZPOS$ \\ +2. else \\ +\hspace{3mm}2.1 $sign = MP\_ZNEG$ \\ +3. If min$(a.used, b.used) \ge TOOM\_MUL\_CUTOFF$ then \\ +\hspace{3mm}3.1 $c \leftarrow a \cdot b$ using algorithm mp\_toom\_mul \\ +4. else if min$(a.used, b.used) \ge KARATSUBA\_MUL\_CUTOFF$ then \\ +\hspace{3mm}4.1 $c \leftarrow a \cdot b$ using algorithm mp\_karatsuba\_mul \\ +5. else \\ +\hspace{3mm}5.1 $digs \leftarrow a.used + b.used + 1$ \\ +\hspace{3mm}5.2 If $digs < MP\_ARRAY$ and min$(a.used, b.used) \le \delta$ then \\ +\hspace{6mm}5.2.1 $c \leftarrow a \cdot b \mbox{ (mod }\beta^{digs}\mbox{)}$ using algorithm fast\_s\_mp\_mul\_digs. \\ +\hspace{3mm}5.3 else \\ +\hspace{6mm}5.3.1 $c \leftarrow a \cdot b \mbox{ (mod }\beta^{digs}\mbox{)}$ using algorithm s\_mp\_mul\_digs. \\ +6. $c.sign \leftarrow sign$ \\ +7. Return the result of the unsigned multiplication performed. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul} +\end{figure} + +\textbf{Algorithm mp\_mul.} +This algorithm performs the signed multiplication of two inputs. It will make use of any of the three unsigned multiplication algorithms +available when the input is of appropriate size. The \textbf{sign} of the result is not set until the end of the algorithm since algorithm +s\_mp\_mul\_digs will clear it. + +EXAM,bn_mp_mul.c + +The implementation is rather simplistic and is not particularly noteworthy. Line @22,?@ computes the sign of the result using the ``?'' +operator from the C programming language. Line @37,<<@ computes $\delta$ using the fact that $1 << k$ is equal to $2^k$. + +\section{Squaring} +\label{sec:basesquare} + +Squaring is a special case of multiplication where both multiplicands are equal. At first it may seem like there is no significant optimization +available but in fact there is. Consider the multiplication of $576$ against $241$. In total there will be nine single precision multiplications +performed which are $1\cdot 6$, $1 \cdot 7$, $1 \cdot 5$, $4 \cdot 6$, $4 \cdot 7$, $4 \cdot 5$, $2 \cdot 6$, $2 \cdot 7$ and $2 \cdot 5$. Now consider +the multiplication of $123$ against $123$. The nine products are $3 \cdot 3$, $3 \cdot 2$, $3 \cdot 1$, $2 \cdot 3$, $2 \cdot 2$, $2 \cdot 1$, +$1 \cdot 3$, $1 \cdot 2$ and $1 \cdot 1$. On closer inspection some of the products are equivalent. For example, $3 \cdot 2 = 2 \cdot 3$ +and $3 \cdot 1 = 1 \cdot 3$. + +For any $n$-digit input, there are ${{\left (n^2 + n \right)}\over 2}$ possible unique single precision multiplications required compared to the $n^2$ +required for multiplication. The following diagram gives an example of the operations required. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{ccccc|c} +&&1&2&3&\\ +$\times$ &&1&2&3&\\ +\hline && $3 \cdot 1$ & $3 \cdot 2$ & $3 \cdot 3$ & Row 0\\ + & $2 \cdot 1$ & $2 \cdot 2$ & $2 \cdot 3$ && Row 1 \\ + $1 \cdot 1$ & $1 \cdot 2$ & $1 \cdot 3$ &&& Row 2 \\ +\end{tabular} +\end{center} +\caption{Squaring Optimization Diagram} +\end{figure} + +MARK,SQUARE +Starting from zero and numbering the columns from right to left a very simple pattern becomes obvious. For the purposes of this discussion let $x$ +represent the number being squared. The first observation is that in row $k$ the $2k$'th column of the product has a $\left (x_k \right)^2$ term in it. + +The second observation is that every column $j$ in row $k$ where $j \ne 2k$ is part of a double product. Every non-square term of a column will +appear twice hence the name ``double product''. Every odd column is made up entirely of double products. In fact every column is made up of double +products and at most one square (\textit{see the exercise section}). + +The third and final observation is that for row $k$ the first unique non-square term, that is, one that hasn't already appeared in an earlier row, +occurs at column $2k + 1$. For example, on row $1$ of the previous squaring, column one is part of the double product with column one from row zero. +Column two of row one is a square and column three is the first unique column. + +\subsection{The Baseline Squaring Algorithm} +The baseline squaring algorithm is meant to be a catch-all squaring algorithm. It will handle any of the input sizes that the faster routines +will not handle. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +1. Init a temporary mp\_int of at least $2 \cdot a.used +1$ digits. (\textit{mp\_init\_size}) \\ +2. If step 1 failed return(\textit{MP\_MEM}) \\ +3. $t.used \leftarrow 2 \cdot a.used + 1$ \\ +4. For $ix$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}Calculate the square. \\ +\hspace{3mm}4.1 $\hat r \leftarrow t_{2ix} + \left (a_{ix} \right )^2$ \\ +\hspace{3mm}4.2 $t_{2ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}Calculate the double products after the square. \\ +\hspace{3mm}4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}4.4 For $iy$ from $ix + 1$ to $a.used - 1$ do \\ +\hspace{6mm}4.4.1 $\hat r \leftarrow 2 \cdot a_{ix}a_{iy} + t_{ix + iy} + u$ \\ +\hspace{6mm}4.4.2 $t_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}4.4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}Set the last carry. \\ +\hspace{3mm}4.5 While $u > 0$ do \\ +\hspace{6mm}4.5.1 $iy \leftarrow iy + 1$ \\ +\hspace{6mm}4.5.2 $\hat r \leftarrow t_{ix + iy} + u$ \\ +\hspace{6mm}4.5.3 $t_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}4.5.4 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +5. Clamp excess digits of $t$. (\textit{mp\_clamp}) \\ +6. Exchange $b$ and $t$. \\ +7. Clear $t$ (\textit{mp\_clear}) \\ +8. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_sqr} +\end{figure} + +\textbf{Algorithm s\_mp\_sqr.} +This algorithm computes the square of an input using the three observations on squaring. It is based fairly faithfully on algorithm 14.16 of HAC +\cite[pp.596-597]{HAC}. Similar to algorithm s\_mp\_mul\_digs, a temporary mp\_int is allocated to hold the result of the squaring. This allows the +destination mp\_int to be the same as the source mp\_int. + +The outer loop of this algorithm begins on step 4. It is best to think of the outer loop as walking down the rows of the partial results, while +the inner loop computes the columns of the partial result. Step 4.1 and 4.2 compute the square term for each row, and step 4.3 and 4.4 propagate +the carry and compute the double products. + +The requirement that a mp\_word be able to represent the range $0 \le x < 2 \beta^2$ arises from this +very algorithm. The product $a_{ix}a_{iy}$ will lie in the range $0 \le x \le \beta^2 - 2\beta + 1$ which is obviously less than $\beta^2$ meaning that +when it is multiplied by two, it can be properly represented by a mp\_word. + +Similar to algorithm s\_mp\_mul\_digs, after every pass of the inner loop, the destination is correctly set to the sum of all of the partial +results calculated so far. This involves expensive carry propagation which will be eliminated in the next algorithm. + +EXAM,bn_s_mp_sqr.c + +Inside the outer loop (\textit{see line @32,for@}) the square term is calculated on line @35,r =@. Line @42,>>@ extracts the carry from the square +term. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized on lines @45,tmpx@ and @48,tmpt@ respectively. The doubling is performed using two +additions (\textit{see line @57,r + r@}) since it is usually faster than shifting,if not at least as fast. + +\subsection{Faster Squaring by the ``Comba'' Method} +A major drawback to the baseline method is the requirement for single precision shifting inside the $O(n^2)$ nested loop. Squaring has an additional +drawback that it must double the product inside the inner loop as well. As for multiplication, the Comba technique can be used to eliminate these +performance hazards. + +The first obvious solution is to make an array of mp\_words which will hold all of the columns. This will indeed eliminate all of the carry +propagation operations from the inner loop. However, the inner product must still be doubled $O(n^2)$ times. The solution stems from the simple fact +that $2a + 2b + 2c = 2(a + b + c)$. That is the sum of all of the double products is equal to double the sum of all the products. For example, +$ab + ba + ac + ca = 2ab + 2ac = 2(ab + ac)$. + +However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two mp\_word +arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and carry propagation can be +moved to a $O(n)$ work level outside the $O(n^2)$ level. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_s\_mp\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +Place two arrays of \textbf{MP\_WARRAY} mp\_words named $\hat W$ and $\hat {X}$ on the stack. \\ +1. If $b.alloc < 2a.used + 1$ then grow $b$ to $2a.used + 1$ digits. (\textit{mp\_grow}). \\ +2. If step 1 failed return(\textit{MP\_MEM}). \\ +3. for $ix$ from $0$ to $2a.used + 1$ do \\ +\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ +\hspace{3mm}3.2 $\hat {X}_{ix} \leftarrow 0$ \\ +4. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}Compute the square.\\ +\hspace{3mm}4.1 $\hat {X}_{ix+ix} \leftarrow \left ( a_{ix} \right )^2$ \\ +\\ +\hspace{3mm}Compute the double products.\\ +\hspace{3mm}4.2 for $iy$ from $ix + 1$ to $a.used - 1$ do \\ +\hspace{6mm}4.2.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}a_{iy}$ \\ +5. $oldused \leftarrow b.used$ \\ +6. $b.used \leftarrow 2a.used + 1$ \\ +\\ +Double the products and propagate the carries simultaneously. \\ +7. $\hat W_0 \leftarrow 2 \hat W_0 + \hat {X}_0$ \\ +8. for $ix$ from $1$ to $2a.used$ do \\ +\hspace{3mm}8.1 $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ \\ +\hspace{3mm}8.2 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix - 1} / \beta \rfloor$ \\ +\hspace{3mm}8.3 $b_{ix-1} \leftarrow W_{ix-1} \mbox{ (mod }\beta\mbox{)}$ \\ +9. $b_{2a.used} \leftarrow \hat W_{2a.used} \mbox{ (mod }\beta\mbox{)}$ \\ +10. if $2a.used + 1 < oldused$ then do \\ +\hspace{3mm}10.1 for $ix$ from $2a.used + 1$ to $oldused$ do \\ +\hspace{6mm}10.1.1 $b_{ix} \leftarrow 0$ \\ +11. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_s\_mp\_sqr} +\end{figure} + +\textbf{Algorithm fast\_s\_mp\_sqr.} +This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm s\_mp\_sqr when +the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. + +This routine requires two arrays of mp\_words to be placed on the stack. The first array $\hat W$ will hold the double products and the second +array $\hat X$ will hold the squares. Though only at most $MP\_WARRAY \over 2$ words of $\hat X$ are used, it has proven faster on most +processors to simply make it a full size array. + +The loop on step 3 will zero the two arrays to prepare them for the squaring step. Step 4.1 computes the squares of the product. Note how +it simply assigns the value into the $\hat X$ array. The nested loop on step 4.2 computes the doubles of the products. This loop +computes the sum of the products for each column. They are not doubled until later. + +After the squaring loop, the products stored in $\hat W$ musted be doubled and the carries propagated forwards. It makes sense to do both +operations at the same time. The expression $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ computes the sum of the double product and the +squares in place. + +EXAM,bn_fast_s_mp_sqr.c + +-- Write something deep and insightful later, Tom. + +\subsection{Polynomial Basis Squaring} +The same algorithm that performs optimal polynomial basis multiplication can be used to perform polynomial basis squaring. The minor exception +is that $\zeta_y = f(y)g(y)$ is actually equivalent to $\zeta_y = f(y)^2$ since $f(y) = g(y)$. Instead of performing $2n + 1$ +multiplications to find the $\zeta$ relations, squaring operations are performed instead. + +\subsection{Karatsuba Squaring} +Let $f(x) = ax + b$ represent the polynomial basis representation of a number to square. +Let $h(x) = \left ( f(x) \right )^2$ represent the square of the polynomial. The Karatsuba equation can be modified to square a +number with the following equation. + +\begin{equation} +h(x) = a^2x^2 + \left (a^2 + b^2 - (a - b)^2 \right )x + b^2 +\end{equation} + +Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a - b)^2$. As in +Karatsuba multiplication, this algorithm can be applied recursively on the input and will achieve an asymptotic running time of +$O \left ( n^{lg(3)} \right )$. + +If the asymptotic times of Karatsuba squaring and multiplication are the same, why not simply use the multiplication algorithm +instead? The answer to this arises from the cutoff point for squaring. As in multiplication there exists a cutoff point, at which the +time required for a Comba based squaring and a Karatsuba based squaring meet. Due to the overhead inherent in the Karatsuba method, the cutoff +point is fairly high. For example, on an AMD Athlon XP processor with $\beta = 2^{28}$, the cutoff point is around 127 digits. + +Consider squaring a 200 digit number with this technique. It will be split into two 100 digit halves which are subsequently squared. +The 100 digit halves will not be squared using Karatsuba, but instead using the faster Comba based squaring algorithm. If Karatsuba multiplication +were used instead, the 100 digit numbers would be squared with a slower Comba based multiplication. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_karatsuba\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +1. Initialize the following temporary mp\_ints: $x0$, $x1$, $t1$, $t2$, $x0x0$ and $x1x1$. \\ +2. If any of the initializations on step 1 failed return(\textit{MP\_MEM}). \\ +\\ +Split the input. e.g. $a = x1\beta^B + x0$ \\ +3. $B \leftarrow \lfloor a.used / 2 \rfloor$ \\ +4. $x0 \leftarrow a \mbox{ (mod }\beta^B\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +5. $x1 \leftarrow \lfloor a / \beta^B \rfloor$ (\textit{mp\_lshd}) \\ +\\ +Calculate the three squares. \\ +6. $x0x0 \leftarrow x0^2$ (\textit{mp\_sqr}) \\ +7. $x1x1 \leftarrow x1^2$ \\ +8. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +9. $t1 \leftarrow t1^2$ \\ +\\ +Compute the middle term. \\ +10. $t2 \leftarrow x0x0 + x1x1$ (\textit{s\_mp\_add}) \\ +11. $t1 \leftarrow t2 - t1$ \\ +\\ +Compute final product. \\ +12. $t1 \leftarrow t1\beta^B$ (\textit{mp\_lshd}) \\ +13. $x1x1 \leftarrow x1x1\beta^{2B}$ \\ +14. $t1 \leftarrow t1 + x0x0$ \\ +15. $b \leftarrow t1 + x1x1$ \\ +16. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_karatsuba\_sqr} +\end{figure} + +\textbf{Algorithm mp\_karatsuba\_sqr.} +This algorithm computes the square of an input $a$ using the Karatsuba technique. This algorithm is very similar to the Karatsuba based +multiplication algorithm with the exception that the three half-size multiplications have been replaced with three half-size squarings. + +The radix point for squaring is simply placed exactly in the middle of the digits when the input has an odd number of digits, otherwise it is +placed just below the middle. Step 3, 4 and 5 compute the two halves required using $B$ +as the radix point. The first two squares in steps 6 and 7 are rather straightforward while the last square is of a more compact form. + +By expanding $\left (x1 - x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $x1^2 + x0^2 - (x1 - x0)^2 = 2 \cdot x0 \cdot x1$. +Now if $5n$ single precision additions and a squaring of $n$-digits is faster than multiplying two $n$-digit numbers and doubling then +this method is faster. Assuming no further recursions occur, the difference can be estimated with the following inequality. + +Let $p$ represent the cost of a single precision addition and $q$ the cost of a single precision multiplication both in terms of time\footnote{Or +machine clock cycles.}. + +\begin{equation} +5pn +{{q(n^2 + n)} \over 2} \le pn + qn^2 +\end{equation} + +For example, on an AMD Athlon XP processor $p = {1 \over 3}$ and $q = 6$. This implies that the following inequality should hold. +\begin{center} +\begin{tabular}{rcl} +${5n \over 3} + 3n^2 + 3n$ & $<$ & ${n \over 3} + 6n^2$ \\ +${5 \over 3} + 3n + 3$ & $<$ & ${1 \over 3} + 6n$ \\ +${13 \over 9}$ & $<$ & $n$ \\ +\end{tabular} +\end{center} + +This results in a cutoff point around $n = 2$. As a consequence it is actually faster to compute the middle term the ``long way'' on processors +where multiplication is substantially slower\footnote{On the Athlon there is a 1:17 ratio between clock cycles for addition and multiplication. On +the Intel P4 processor this ratio is 1:29 making this method even more beneficial. The only common exception is the ARMv4 processor which has a +ratio of 1:7. } than simpler operations such as addition. + +EXAM,bn_mp_karatsuba_sqr.c + +This implementation is largely based on the implementation of algorithm mp\_karatsuba\_mul. It uses the same inline style to copy and +shift the input into the two halves. The loop from line @54,{@ to line @70,}@ has been modified since only one input exists. The \textbf{used} +count of both $x0$ and $x1$ is fixed up and $x0$ is clamped before the calculations begin. At this point $x1$ and $x0$ are valid equivalents +to the respective halves as if mp\_rshd and mp\_mod\_2d had been used. + +By inlining the copy and shift operations the cutoff point for Karatsuba multiplication can be lowered. On the Athlon the cutoff point +is exactly at the point where Comba squaring can no longer be used (\textit{128 digits}). On slower processors such as the Intel P4 +it is actually below the Comba limit (\textit{at 110 digits}). + +This routine uses the same error trap coding style as mp\_karatsuba\_sqr. As the temporary variables are initialized errors are redirected to +the error trap higher up. If the algorithm completes without error the error code is set to \textbf{MP\_OKAY} and mp\_clears are executed normally. + +\textit{Last paragraph sucks. re-write! -- Tom} + +\subsection{Toom-Cook Squaring} +The Toom-Cook squaring algorithm mp\_toom\_sqr is heavily based on the algorithm mp\_toom\_mul with the exception that squarings are used +instead of multiplication to find the five relations.. The reader is encouraged to read the description of the latter algorithm and try to +derive their own Toom-Cook squaring algorithm. + +\subsection{High Level Squaring} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +1. If $a.used \ge TOOM\_SQR\_CUTOFF$ then \\ +\hspace{3mm}1.1 $b \leftarrow a^2$ using algorithm mp\_toom\_sqr \\ +2. else if $a.used \ge KARATSUBA\_SQR\_CUTOFF$ then \\ +\hspace{3mm}2.1 $b \leftarrow a^2$ using algorithm mp\_karatsuba\_sqr \\ +3. else \\ +\hspace{3mm}3.1 $digs \leftarrow a.used + b.used + 1$ \\ +\hspace{3mm}3.2 If $digs < MP\_ARRAY$ and $a.used \le \delta$ then \\ +\hspace{6mm}3.2.1 $b \leftarrow a^2$ using algorithm fast\_s\_mp\_sqr. \\ +\hspace{3mm}3.3 else \\ +\hspace{6mm}3.3.1 $b \leftarrow a^2$ using algorithm s\_mp\_sqr. \\ +4. $b.sign \leftarrow MP\_ZPOS$ \\ +5. Return the result of the unsigned squaring performed. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_sqr} +\end{figure} + +\textbf{Algorithm mp\_sqr.} +This algorithm computes the square of the input using one of four different algorithms. If the input is very large and has at least +\textbf{TOOM\_SQR\_CUTOFF} or \textbf{KARATSUBA\_SQR\_CUTOFF} digits then either the Toom-Cook or the Karatsuba Squaring algorithm is used. If +neither of the polynomial basis algorithms should be used then either the Comba or baseline algorithm is used. + +EXAM,bn_mp_sqr.c + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ] $ & Devise an efficient algorithm for selection of the radix point to handle inputs \\ + & that have different number of digits in Karatsuba multiplication. \\ + & \\ +$\left [ 3 \right ] $ & In ~SQUARE~ the fact that every column of a squaring is made up \\ + & of double products and at most one square is stated. Prove this statement. \\ + & \\ +$\left [ 2 \right ] $ & In the Comba squaring algorithm half of the $\hat X$ variables are not used. \\ + & Revise algorithm fast\_s\_mp\_sqr to shrink the $\hat X$ array. \\ + & \\ +$\left [ 3 \right ] $ & Prove the equation for Karatsuba squaring. \\ + & \\ +$\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3)} \right )$ time. \\ + & \\ +$\left [ 2 \right ] $ & Determine the minimal ratio between addition and multiplication clock cycles \\ + & required for equation $6.7$ to be true. \\ + & \\ +\end{tabular} + +\chapter{Modular Reduction} +MARK,REDUCTION +\section{Basics of Modular Reduction} +\index{modular residue} +Modular reduction is an operation that arises quite often within public key cryptography algorithms and various number theoretic algorithms, +such as factoring. Modular reduction algorithms are the third class of algorithms of the ``multipliers'' set. A number $a$ is said to be \textit{reduced} +modulo another number $b$ by finding the remainder of the division $a/b$. Full integer division with remainder is a topic to be covered +in~\ref{sec:division}. + +Modular reduction is equivalent to solving for $r$ in the following equation. $a = bq + r$ where $q = \lfloor a/b \rfloor$. The result +$r$ is said to be ``congruent to $a$ modulo $b$'' which is also written as $r \equiv a \mbox{ (mod }b\mbox{)}$. In other vernacular $r$ is known as the +``modular residue'' which leads to ``quadratic residue''\footnote{That's fancy talk for $b \equiv a^2 \mbox{ (mod }p\mbox{)}$.} and +other forms of residues. + +Modular reductions are normally used to create either finite groups, rings or fields. The most common usage for performance driven modular reductions +is in modular exponentiation algorithms. That is to compute $d = a^b \mbox{ (mod }c\mbox{)}$ as fast as possible. This operation is used in the +RSA and Diffie-Hellman public key algorithms, for example. Modular multiplication and squaring also appears as a fundamental operation in +Elliptic Curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular +exponentiations without having to perform (\textit{in this example}) $b - 1$ multiplications. These algorithms will produce partial results in the +range $0 \le x < c^2$ which can be taken advantage of to create several efficient algorithms. They have also been used to create redundancy check +algorithms known as CRCs, error correction codes such as Reed-Solomon and solve a variety of number theoeretic problems. + +\section{The Barrett Reduction} +The Barrett reduction algorithm \cite{BARRETT} was inspired by fast division algorithms which multiply by the reciprocal to emulate +division. Barretts observation was that the residue $c$ of $a$ modulo $b$ is equal to + +\begin{equation} +c = a - b \cdot \lfloor a/b \rfloor +\end{equation} + +Since algorithms such as modular exponentiation would be using the same modulus extensively, typical DSP\footnote{It is worth noting that Barrett's paper +targeted the DSP56K processor.} intuition would indicate the next step would be to replace $a/b$ by a multiplication by the reciprocal. However, +DSP intuition on its own will not work as these numbers are considerably larger than the precision of common DSP floating point data types. +It would take another common optimization to optimize the algorithm. + +\subsection{Fixed Point Arithmetic} +The trick used to optimize the above equation is based on a technique of emulating floating point data types with fixed precision integers. Fixed +point arithmetic would become very popular as it greatly optimize the ``3d-shooter'' genre of games in the mid 1990s when floating point units were +fairly slow if not unavailable. The idea behind fixed point arithmetic is to take a normal $k$-bit integer data type and break it into $p$-bit +integer and a $q$-bit fraction part (\textit{where $p+q = k$}). + +In this system a $k$-bit integer $n$ would actually represent $n/2^q$. For example, with $q = 4$ the integer $n = 37$ would actually represent the +value $2.3125$. To multiply two fixed point numbers the integers are multiplied using traditional arithmetic and subsequently normalized by +moving the implied decimal point back to where it should be. For example, with $q = 4$ to multiply the integers $9$ and $5$ they must be converted +to fixed point first by multiplying by $2^q$. Let $a = 9(2^q)$ represent the fixed point representation of $9$ and $b = 5(2^q)$ represent the +fixed point representation of $5$. The product $ab$ is equal to $45(2^{2q})$ which when normalized by dividing by $2^q$ produces $45(2^q)$. + +This technique became popular since a normal integer multiplication and logical shift right are the only required operations to perform a multiplication +of two fixed point numbers. Using fixed point arithmetic, division can be easily approximated by multiplying by the reciprocal. If $2^q$ is +equivalent to one than $2^q/b$ is equivalent to the fixed point approximation of $1/b$ using real arithmetic. Using this fact dividing an integer +$a$ by another integer $b$ can be achieved with the following expression. + +\begin{equation} +\lfloor a / b \rfloor \mbox{ }\approx\mbox{ } \lfloor (a \cdot \lfloor 2^q / b \rfloor)/2^q \rfloor +\end{equation} + +The precision of the division is proportional to the value of $q$. If the divisor $b$ is used frequently as is the case with +modular exponentiation pre-computing $2^q/b$ will allow a division to be performed with a multiplication and a right shift. Both operations +are considerably faster than division on most processors. + +Consider dividing $19$ by $5$. The correct result is $\lfloor 19/5 \rfloor = 3$. With $q = 3$ the reciprocal is $\lfloor 2^q/5 \rfloor = 1$ which +leads to a product of $19$ which when divided by $2^q$ produces $2$. However, with $q = 4$ the reciprocal is $\lfloor 2^q/5 \rfloor = 3$ and +the result of the emulated division is $\lfloor 3 \cdot 19 / 2^q \rfloor = 3$ which is correct. The value of $2^q$ must be close to or ideally +larger than the dividend. In effect if $a$ is the dividend then $q$ should allow $0 \le \lfloor a/2^q \rfloor \le 1$ in order for this approach +to work correctly. Plugging this form of divison into the original equation the following modular residue equation arises. + +\begin{equation} +c = a - b \cdot \lfloor (a \cdot \lfloor 2^q / b \rfloor)/2^q \rfloor +\end{equation} + +Using the notation from \cite{BARRETT} the value of $\lfloor 2^q / b \rfloor$ will be represented by the $\mu$ symbol. Using the $\mu$ +variable also helps re-inforce the idea that it is meant to be computed once and re-used. + +\begin{equation} +c = a - b \cdot \lfloor (a \cdot \mu)/2^q \rfloor +\end{equation} + +Provided that $2^q \ge a$ this algorithm will produce a quotient that is either exactly correct or off by a value of one. In the context of Barrett +reduction the value of $a$ is bound by $0 \le a \le (b - 1)^2$ meaning that $2^q \ge b^2$ is sufficient to ensure the reciprocal will have enough +precision. + +Let $n$ represent the number of digits in $b$. This algorithm requires approximately $2n^2$ single precision multiplications to produce the quotient and +another $n^2$ single precision multiplications to find the residue. In total $3n^2$ single precision multiplications are required to +reduce the number. + +For example, if $b = 1179677$ and $q = 41$ ($2^q > b^2$), then the reciprocal $\mu$ is equal to $\lfloor 2^q / b \rfloor = 1864089$. Consider reducing +$a = 180388626447$ modulo $b$ using the above reduction equation. The quotient using the new formula is $\lfloor (a \cdot \mu) / 2^q \rfloor = 152913$. +By subtracting $152913b$ from $a$ the correct residue $a \equiv 677346 \mbox{ (mod }b\mbox{)}$ is found. + +\subsection{Choosing a Radix Point} +Using the fixed point representation a modular reduction can be performed with $3n^2$ single precision multiplications. If that were the best +that could be achieved a full division\footnote{A division requires approximately $O(2cn^2)$ single precision multiplications for a small value of $c$. +See~\ref{sec:division} for further details.} might as well be used in its place. The key to optimizing the reduction is to reduce the precision of +the initial multiplication that finds the quotient. + +Let $a$ represent the number of which the residue is sought. Let $b$ represent the modulus used to find the residue. Let $m$ represent +the number of digits in $b$. For the purposes of this discussion we will assume that the number of digits in $a$ is $2m$, which is generally true if +two $m$-digit numbers have been multiplied. Dividing $a$ by $b$ is the same as dividing a $2m$ digit integer by a $m$ digit integer. Digits below the +$m - 1$'th digit of $a$ will contribute at most a value of $1$ to the quotient because $\beta^k < b$ for any $0 \le k \le m - 1$. Another way to +express this is by re-writing $a$ as two parts. If $a' \equiv a \mbox{ (mod }b^m\mbox{)}$ and $a'' = a - a'$ then +${a \over b} \equiv {{a' + a''} \over b}$ which is equivalent to ${a' \over b} + {a'' \over b}$. Since $a'$ is bound to be less than $b$ the quotient +is bound by $0 \le {a' \over b} < 1$. + +Since the digits of $a'$ do not contribute much to the quotient the observation is that they might as well be zero. However, if the digits +``might as well be zero'' they might as well not be there in the first place. Let $q_0 = \lfloor a/\beta^{m-1} \rfloor$ represent the input +with the irrelevant digits trimmed. Now the modular reduction is trimmed to the almost equivalent equation + +\begin{equation} +c = a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor +\end{equation} + +Note that the original divisor $2^q$ has been replaced with $\beta^{m+1}$ where in this case $q$ is a multiple of $lg(\beta)$. Also note that the +exponent on the divisor when added to the amount $q_0$ was shifted by equals $2m$. If the optimization had not been performed the divisor +would have the exponent $2m$ so in the end the exponents do ``add up''. Using the above equation the quotient +$\lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ can be off from the true quotient by at most two. The original fixed point quotient can be off +by as much as one (\textit{provided the radix point is chosen suitably}) and now that the lower irrelevent digits have been trimmed the quotient +can be off by an additional value of one for a total of at most two. This implies that +$0 \le a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor < 3b$. By first subtracting $b$ times the quotient and then conditionally subtracting +$b$ once or twice the residue is found. + +The quotient is now found using $(m + 1)(m) = m^2 + m$ single precision multiplications and the residue with an additional $m^2$ single +precision multiplications, ignoring the subtractions required. In total $2m^2 + m$ single precision multiplications are required to find the residue. +This is considerably faster than the original attempt. + +For example, let $\beta = 10$ represent the radix of the digits. Let $b = 9999$ represent the modulus which implies $m = 4$. Let $a = 99929878$ +represent the value of which the residue is desired. In this case $q = 8$ since $10^7 < 9999^2$ meaning that $\mu = \lfloor \beta^{q}/b \rfloor = 10001$. +With the new observation the multiplicand for the quotient is equal to $q_0 = \lfloor a / \beta^{m - 1} \rfloor = 99929$. The quotient is then +$\lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor = 9993$. Subtracting $9993b$ from $a$ and the correct residue $a \equiv 9871 \mbox{ (mod }b\mbox{)}$ +is found. + +\subsection{Trimming the Quotient} +So far the reduction algorithm has been optimized from $3m^2$ single precision multiplications down to $2m^2 + m$ single precision multiplications. As +it stands now the algorithm is already fairly fast compared to a full integer division algorithm. However, there is still room for +optimization. + +After the first multiplication inside the quotient ($q_0 \cdot \mu$) the value is shifted right by $m + 1$ places effectively nullifying the lower +half of the product. It would be nice to be able to remove those digits from the product to effectively cut down the number of single precision +multiplications. If the number of digits in the modulus $m$ is far less than $\beta$ a full product is not required for the algorithm to work properly. +In fact the lower $m - 2$ digits will not affect the upper half of the product at all and do not need to be computed. + +The value of $\mu$ is a $m$-digit number and $q_0$ is a $m + 1$ digit number. Using a full multiplier $(m + 1)(m) = m^2 + m$ single precision +multiplications would be required. Using a multiplier that will only produce digits at and above the $m - 1$'th digit reduces the number +of single precision multiplications to ${m^2 + m} \over 2$ single precision multiplications. + +\subsection{Trimming the Residue} +After the quotient has been calculated it is used to reduce the input. As previously noted the algorithm is not exact and it can be off by a small +multiple of the modulus, that is $0 \le a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor < 3b$. If $b$ is $m$ digits than the +result of reduction equation is a value of at most $m + 1$ digits (\textit{provided $3 < \beta$}) implying that the upper $m - 1$ digits are +implicitly zero. + +The next optimization arises from this very fact. Instead of computing $b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ using a full +$O(m^2)$ multiplication algorithm only the lower $m+1$ digits of the product have to be computed. Similarly the value of $a$ can +be reduced modulo $\beta^{m+1}$ before the multiple of $b$ is subtracted which simplifes the subtraction as well. A multiplication that produces +only the lower $m+1$ digits requires ${m^2 + 3m - 2} \over 2$ single precision multiplications. + +With both optimizations in place the algorithm is the algorithm Barrett proposed. It requires $m^2 + 2m - 1$ single precision multiplications which +is considerably faster than the straightforward $3m^2$ method. + +\subsection{The Barrett Algorithm} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and $\mu = \lfloor \beta^{2m}/b \rfloor, m = \lceil lg_{\beta}(b) \rceil, (0 \le a < b^2, b > 1)$ \\ +\textbf{Output}. $a \mbox{ (mod }b\mbox{)}$ \\ +\hline \\ +Let $m$ represent the number of digits in $b$. \\ +1. Make a copy of $a$ and store it in $q$. (\textit{mp\_init\_copy}) \\ +2. $q \leftarrow \lfloor q / \beta^{m - 1} \rfloor$ (\textit{mp\_rshd}) \\ +\\ +Produce the quotient. \\ +3. $q \leftarrow q \cdot \mu$ (\textit{note: only produce digits at or above $m-1$}) \\ +4. $q \leftarrow \lfloor q / \beta^{m + 1} \rfloor$ \\ +\\ +Subtract the multiple of modulus from the input. \\ +5. $a \leftarrow a \mbox{ (mod }\beta^{m+1}\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +6. $q \leftarrow q \cdot b \mbox{ (mod }\beta^{m+1}\mbox{)}$ (\textit{s\_mp\_mul\_digs}) \\ +7. $a \leftarrow a - q$ (\textit{mp\_sub}) \\ +\\ +Add $\beta^{m+1}$ if a carry occured. \\ +8. If $a < 0$ then (\textit{mp\_cmp\_d}) \\ +\hspace{3mm}8.1 $q \leftarrow 1$ (\textit{mp\_set}) \\ +\hspace{3mm}8.2 $q \leftarrow q \cdot \beta^{m+1}$ (\textit{mp\_lshd}) \\ +\hspace{3mm}8.3 $a \leftarrow a + q$ \\ +\\ +Now subtract the modulus if the residue is too large (e.g. quotient too small). \\ +9. While $a \ge b$ do (\textit{mp\_cmp}) \\ +\hspace{3mm}9.1 $c \leftarrow a - b$ \\ +10. Clear $q$. \\ +11. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce} +\end{figure} + +\textbf{Algorithm mp\_reduce.} +This algorithm will reduce the input $a$ modulo $b$ in place using the Barrett algorithm. It is loosely based on algorithm 14.42 of HAC +\cite[pp. 602]{HAC} which is based on the paper from Paul Barrett \cite{BARRETT}. The algorithm has several restrictions and assumptions which must +be adhered to for the algorithm to work. + +First the modulus $b$ is assumed to be positive and greater than one. If the modulus were less than or equal to one than subtracting +a multiple of it would either accomplish nothing or actually enlarge the input. The input $a$ must be in the range $0 \le a < b^2$ in order +for the quotient to have enough precision. If $a$ is the product of two numbers that were already reduced modulo $b$, this will not be a problem. +Technically the algorithm will still work if $a \ge b^2$ but it will take much longer to finish. The value of $\mu$ is passed as an argument to this +algorithm and is assumed to be calculated and stored before the algorithm is used. + +Recall that the multiplication for the quotient on step 3 must only produce digits at or above the $m-1$'th position. An algorithm called +$s\_mp\_mul\_high\_digs$ which has not been presented is used to accomplish this task. The algorithm is based on $s\_mp\_mul\_digs$ except that +instead of stopping at a given level of precision it starts at a given level of precision. This optimal algorithm can only be used if the number +of digits in $b$ is very much smaller than $\beta$. + +While it is known that +$a \ge b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ only the lower $m+1$ digits are being used to compute the residue, so an implied +``borrow'' from the higher digits might leave a negative result. After the multiple of the modulus has been subtracted from $a$ the residue must be +fixed up in case it is negative. The invariant $\beta^{m+1}$ must be added to the residue to make it positive again. + +The while loop at step 9 will subtract $b$ until the residue is less than $b$. If the algorithm is performed correctly this step is +performed at most twice, and on average once. However, if $a \ge b^2$ than it will iterate substantially more times than it should. + +EXAM,bn_mp_reduce.c + +The first multiplication that determines the quotient can be performed by only producing the digits from $m - 1$ and up. This essentially halves +the number of single precision multiplications required. However, the optimization is only safe if $\beta$ is much larger than the number of digits +in the modulus. In the source code this is evaluated on lines @36,if@ to @44,}@ where algorithm s\_mp\_mul\_high\_digs is used when it is +safe to do so. + +\subsection{The Barrett Setup Algorithm} +In order to use algorithm mp\_reduce the value of $\mu$ must be calculated in advance. Ideally this value should be computed once and stored for +future use so that the Barrett algorithm can be used without delay. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_setup}. \\ +\textbf{Input}. mp\_int $a$ ($a > 1$) \\ +\textbf{Output}. $\mu \leftarrow \lfloor \beta^{2m}/a \rfloor$ \\ +\hline \\ +1. $\mu \leftarrow 2^{2 \cdot lg(\beta) \cdot m}$ (\textit{mp\_2expt}) \\ +2. $\mu \leftarrow \lfloor \mu / b \rfloor$ (\textit{mp\_div}) \\ +3. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_setup} +\end{figure} + +\textbf{Algorithm mp\_reduce\_setup.} +This algorithm computes the reciprocal $\mu$ required for Barrett reduction. First $\beta^{2m}$ is calculated as $2^{2 \cdot lg(\beta) \cdot m}$ which +is equivalent and much faster. The final value is computed by taking the integer quotient of $\lfloor \mu / b \rfloor$. + +EXAM,bn_mp_reduce_setup.c + +This simple routine calculates the reciprocal $\mu$ required by Barrett reduction. Note the extended usage of algorithm mp\_div where the variable +which would received the remainder is passed as NULL. As will be discussed in~\ref{sec:division} the division routine allows both the quotient and the +remainder to be passed as NULL meaning to ignore the value. + +\section{The Montgomery Reduction} +Montgomery reduction\footnote{Thanks to Niels Ferguson for his insightful explanation of the algorithm.} \cite{MONT} is by far the most interesting +form of reduction in common use. It computes a modular residue which is not actually equal to the residue of the input yet instead equal to a +residue times a constant. However, as perplexing as this may sound the algorithm is relatively simple and very efficient. + +Throughout this entire section the variable $n$ will represent the modulus used to form the residue. As will be discussed shortly the value of +$n$ must be odd. The variable $x$ will represent the quantity of which the residue is sought. Similar to the Barrett algorithm the input +is restricted to $0 \le x < n^2$. To begin the description some simple number theory facts must be established. + +\textbf{Fact 1.} Adding $n$ to $x$ does not change the residue since in effect it adds one to the quotient $\lfloor x / n \rfloor$. Another way +to explain this is that $n$ is (\textit{or multiples of $n$ are}) congruent to zero modulo $n$. Adding zero will not change the value of the residue. + +\textbf{Fact 2.} If $x$ is even then performing a division by two in $\Z$ is congruent to $x \cdot 2^{-1} \mbox{ (mod }n\mbox{)}$. Actually +this is an application of the fact that if $x$ is evenly divisible by any $k \in \Z$ then division in $\Z$ will be congruent to +multiplication by $k^{-1}$ modulo $n$. + +From these two simple facts the following simple algorithm can be derived. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction}. \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $1$ to $k$ do \\ +\hspace{3mm}1.1 If $x$ is odd then \\ +\hspace{6mm}1.1.1 $x \leftarrow x + n$ \\ +\hspace{3mm}1.2 $x \leftarrow x/2$ \\ +2. Return $x$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction} +\end{figure} + +The algorithm reduces the input one bit at a time using the two congruencies stated previously. Inside the loop $n$, which is odd, is +added to $x$ if $x$ is odd. This forces $x$ to be even which allows the division by two in $\Z$ to be congruent to a modular division by two. Since +$x$ is assumed to be initially much larger than $n$ the addition of $n$ will contribute an insignificant magnitude to $x$. Let $r$ represent the +final result of the Montgomery algorithm. If $k > lg(n)$ and $0 \le x < n^2$ then the final result is limited to +$0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction is required to get the residue desired. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|l|} +\hline \textbf{Step number ($t$)} & \textbf{Result ($x$)} \\ +\hline $1$ & $x + n = 5812$, $x/2 = 2906$ \\ +\hline $2$ & $x/2 = 1453$ \\ +\hline $3$ & $x + n = 1710$, $x/2 = 855$ \\ +\hline $4$ & $x + n = 1112$, $x/2 = 556$ \\ +\hline $5$ & $x/2 = 278$ \\ +\hline $6$ & $x/2 = 139$ \\ +\hline $7$ & $x + n = 396$, $x/2 = 198$ \\ +\hline $8$ & $x/2 = 99$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example of Montgomery Reduction (I)} +\label{fig:MONT1} +\end{figure} + +Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 8$. The result of the algorithm $r = 99$ is +congruent to the value of $2^{-8} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^8$ modulo $257$ the correct residue +$r \equiv 158$ is produced. + +Let $k = \lfloor lg(n) \rfloor + 1$ represent the number of bits in $n$. The current algorithm requires $2k^2$ single precision shifts +and $k^2$ single precision additions. At this rate the algorithm is most certainly slower than Barrett reduction and not terribly useful. +Fortunately there exists an alternative representation of the algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction} (modified I). \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 If the $t$'th bit of $x$ is one then \\ +\hspace{6mm}1.1.1 $x \leftarrow x + 2^tn$ \\ +2. Return $x/2^k$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction (modified I)} +\end{figure} + +This algorithm is equivalent since $2^tn$ is a multiple of $n$ and the lower $k$ bits of $x$ are zero by step 2. The number of single +precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a small improvement. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|l|r|} +\hline \textbf{Step number ($t$)} & \textbf{Result ($x$)} & \textbf{Result ($x$) in Binary} \\ +\hline -- & $5555$ & $1010110110011$ \\ +\hline $1$ & $x + 2^{0}n = 5812$ & $1011010110100$ \\ +\hline $2$ & $5812$ & $1011010110100$ \\ +\hline $3$ & $x + 2^{2}n = 6840$ & $1101010111000$ \\ +\hline $4$ & $x + 2^{3}n = 8896$ & $10001011000000$ \\ +\hline $5$ & $8896$ & $10001011000000$ \\ +\hline $6$ & $8896$ & $10001011000000$ \\ +\hline $7$ & $x + 2^{6}n = 25344$ & $110001100000000$ \\ +\hline $8$ & $25344$ & $110001100000000$ \\ +\hline -- & $x/2^k = 99$ & \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example of Montgomery Reduction (II)} +\label{fig:MONT2} +\end{figure} + +Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 8$. +With this algorithm a single shift right at the end is the only right shift required to reduce the input instead of $k$ right shifts inside the +loop. Note that for the iterations $t = 2, 5, 6$ and $8$ where the result $x$ is not changed. In those iterations the $t$'th bit of $x$ is +zero and the appropriate multiple of $n$ does not need to be added to force the $t$'th bit of the result to zero. + +\subsection{Digit Based Montgomery Reduction} +Instead of computing the reduction on a bit-by-bit basis it is actually much faster to compute it on digit-by-digit basis. Consider the +previous algorithm re-written to compute the Montgomery reduction in this new fashion. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction} (modified II). \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 $x \leftarrow x + \mu n \beta^t$ \\ +2. Return $x/\beta^k$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction (modified II)} +\end{figure} + +The value $\mu n \beta^t$ is a multiple of the modulus $n$ meaning that it will not change the residue. If the first digit of +the value $\mu n \beta^t$ equals the negative (modulo $\beta$) of the $t$'th digit of $x$ then the addition will result in a zero digit. This +problem breaks down to solving the following congruency. + +\begin{center} +\begin{tabular}{rcl} +$x_t + \mu n_0$ & $\equiv$ & $0 \mbox{ (mod }\beta\mbox{)}$ \\ +$\mu n_0$ & $\equiv$ & $-x_t \mbox{ (mod }\beta\mbox{)}$ \\ +$\mu$ & $\equiv$ & $-x_t/n_0 \mbox{ (mod }\beta\mbox{)}$ \\ +\end{tabular} +\end{center} + +In each iteration of the loop on step 1 a new value of $\mu$ must be calculated. The value of $-1/n_0 \mbox{ (mod }\beta\mbox{)}$ is used +extensively in this algorithm and should be precomputed. Let $\rho$ represent the negative of the modular inverse of $n_0$ modulo $\beta$. + +For example, let $\beta = 10$ represent the radix. Let $n = 17$ represent the modulus which implies $k = 2$ and $\rho \equiv 7$. Let $x = 33$ +represent the value to reduce. + +\newpage\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Step ($t$)} & \textbf{Value of $x$} & \textbf{Value of $\mu$} \\ +\hline -- & $33$ & --\\ +\hline $0$ & $33 + \mu n = 50$ & $1$ \\ +\hline $1$ & $50 + \mu n \beta = 900$ & $5$ \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Montgomery Reduction} +\end{figure} + +The final result $900$ is then divided by $\beta^k$ to produce the final result $9$. The first observation is that $9 \nequiv x \mbox{ (mod }n\mbox{)}$ +which implies the result is not the modular residue of $x$ modulo $n$. However, recall that the residue is actually multiplied by $\beta^{-k}$ in +the algorithm. To get the true residue the value must be multiplied by $\beta^k$. In this case $\beta^k \equiv 15 \mbox{ (mod }n\mbox{)}$ and +the correct residue is $9 \cdot 15 \equiv 16 \mbox{ (mod }n\mbox{)}$. + +\subsection{Baseline Montgomery Reduction} +The baseline Montgomery reduction algorithm will produce the residue for any size input. It is designed to be a catch-all algororithm for +Montgomery reductions. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_montgomery\_reduce}. \\ +\textbf{Input}. mp\_int $x$, mp\_int $n$ and a digit $\rho \equiv -1/n_0 \mbox{ (mod }n\mbox{)}$. \\ +\hspace{11.5mm}($0 \le x < n^2, n > 1, (n, \beta) = 1, \beta^k > n$) \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. $digs \leftarrow 2n.used + 1$ \\ +2. If $digs < MP\_ARRAY$ and $m.used < \delta$ then \\ +\hspace{3mm}2.1 Use algorithm fast\_mp\_montgomery\_reduce instead. \\ +\\ +Setup $x$ for the reduction. \\ +3. If $x.alloc < digs$ then grow $x$ to $digs$ digits. \\ +4. $x.used \leftarrow digs$ \\ +\\ +Eliminate the lower $k$ digits. \\ +5. For $ix$ from $0$ to $k - 1$ do \\ +\hspace{3mm}5.1 $\mu \leftarrow x_{ix} \cdot \rho \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}5.2 $u \leftarrow 0$ \\ +\hspace{3mm}5.3 For $iy$ from $0$ to $k - 1$ do \\ +\hspace{6mm}5.3.1 $\hat r \leftarrow \mu n_{iy} + x_{ix + iy} + u$ \\ +\hspace{6mm}5.3.2 $x_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}5.3.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}5.4 While $u > 0$ do \\ +\hspace{6mm}5.4.1 $iy \leftarrow iy + 1$ \\ +\hspace{6mm}5.4.2 $x_{ix + iy} \leftarrow x_{ix + iy} + u$ \\ +\hspace{6mm}5.4.3 $u \leftarrow \lfloor x_{ix+iy} / \beta \rfloor$ \\ +\hspace{6mm}5.4.4 $x_{ix + iy} \leftarrow x_{ix+iy} \mbox{ (mod }\beta\mbox{)}$ \\ +\\ +Divide by $\beta^k$ and fix up as required. \\ +6. $x \leftarrow \lfloor x / \beta^k \rfloor$ \\ +7. If $x \ge n$ then \\ +\hspace{3mm}7.1 $x \leftarrow x - n$ \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_montgomery\_reduce} +\end{figure} + +\textbf{Algorithm mp\_montgomery\_reduce.} +This algorithm reduces the input $x$ modulo $n$ in place using the Montgomery reduction algorithm. The algorithm is loosely based +on algorithm 14.32 of \cite[pp.601]{HAC} except it merges the multiplication of $\mu n \beta^t$ with the addition in the inner loop. The +restrictions on this algorithm are fairly easy to adapt to. First $0 \le x < n^2$ bounds the input to numbers in the same range as +for the Barrett algorithm. Additionally if $n > 1$ and $n$ is odd there will exist a modular inverse $\rho$. $\rho$ must be calculated in +advance of this algorithm. Finally the variable $k$ is fixed and a pseudonym for $n.used$. + +Step 2 decides whether a faster Montgomery algorithm can be used. It is based on the Comba technique meaning that there are limits on +the size of the input. This algorithm is discussed in ~COMBARED~. + +Step 5 is the main reduction loop of the algorithm. The value of $\mu$ is calculated once per iteration in the outer loop. The inner loop +calculates $x + \mu n \beta^{ix}$ by multiplying $\mu n$ and adding the result to $x$ shifted by $ix$ digits. Both the addition and +multiplication are performed in the same loop to save time and memory. Step 5.4 will handle any additional carries that escape the inner loop. + +Using a quick inspection this algorithm requires $n$ single precision multiplications for the outer loop and $n^2$ single precision multiplications +in the inner loop. In total $n^2 + n$ single precision multiplications which compares favourably to Barrett at $n^2 + 2n - 1$ single precision +multiplications. + +EXAM,bn_mp_montgomery_reduce.c + +This is the baseline implementation of the Montgomery reduction algorithm. Lines @30,digs@ to @35,}@ determine if the Comba based +routine can be used instead. Line @47,mu@ computes the value of $\mu$ for that particular iteration of the outer loop. + +The multiplication $\mu n \beta^{ix}$ is performed in one step in the inner loop. The alias $tmpx$ refers to the $ix$'th digit of $x$ and +the alias $tmpn$ refers to the modulus $n$. + +\subsection{Faster ``Comba'' Montgomery Reduction} +MARK,COMBARED + +The Montgomery reduction requires fewer single precision multiplications than a Barrett reduction, however it is much slower due to the serial +nature of the inner loop. The Barrett reduction algorithm requires two slightly modified multipliers which can be implemented with the Comba +technique. The Montgomery reduction algorithm cannot directly use the Comba technique to any significant advantage since the inner loop calculates +a $k \times 1$ product $k$ times. + +The biggest obstacle is that at the $ix$'th iteration of the outer loop the value of $x_{ix}$ is required to calculate $\mu$. This means the +carries from $0$ to $ix - 1$ must have been propagated upwards to form a valid $ix$'th digit. The solution as it turns out is very simple. +Perform a Comba like multiplier and inside the outer loop just after the inner loop fix up the $ix + 1$'th digit by forwarding the carry. + +With this change in place the Montgomery reduction algorithm can be performed with a Comba style multiplication loop which substantially increases +the speed of the algorithm. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_mp\_montgomery\_reduce}. \\ +\textbf{Input}. mp\_int $x$, mp\_int $n$ and a digit $\rho \equiv -1/n_0 \mbox{ (mod }n\mbox{)}$. \\ +\hspace{11.5mm}($0 \le x < n^2, n > 1, (n, \beta) = 1, \beta^k > n$) \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +Place an array of \textbf{MP\_WARRAY} mp\_word variables called $\hat W$ on the stack. \\ +1. if $x.alloc < n.used + 1$ then grow $x$ to $n.used + 1$ digits. \\ +Copy the digits of $x$ into the array $\hat W$ \\ +2. For $ix$ from $0$ to $x.used - 1$ do \\ +\hspace{3mm}2.1 $\hat W_{ix} \leftarrow x_{ix}$ \\ +3. For $ix$ from $x.used$ to $2n.used - 1$ do \\ +\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ +Elimiate the lower $k$ digits. \\ +4. for $ix$ from $0$ to $n.used - 1$ do \\ +\hspace{3mm}4.1 $\mu \leftarrow \hat W_{ix} \cdot \rho \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}4.2 For $iy$ from $0$ to $n.used - 1$ do \\ +\hspace{6mm}4.2.1 $\hat W_{iy + ix} \leftarrow \hat W_{iy + ix} + \mu \cdot n_{iy}$ \\ +\hspace{3mm}4.3 $\hat W_{ix + 1} \leftarrow \hat W_{ix + 1} + \lfloor \hat W_{ix} / \beta \rfloor$ \\ +Propagate carries upwards. \\ +5. for $ix$ from $n.used$ to $2n.used + 1$ do \\ +\hspace{3mm}5.1 $\hat W_{ix + 1} \leftarrow \hat W_{ix + 1} + \lfloor \hat W_{ix} / \beta \rfloor$ \\ +Shift right and reduce modulo $\beta$ simultaneously. \\ +6. for $ix$ from $0$ to $n.used + 1$ do \\ +\hspace{3mm}6.1 $x_{ix} \leftarrow \hat W_{ix + n.used} \mbox{ (mod }\beta\mbox{)}$ \\ +Zero excess digits and fixup $x$. \\ +7. if $x.used > n.used + 1$ then do \\ +\hspace{3mm}7.1 for $ix$ from $n.used + 1$ to $x.used - 1$ do \\ +\hspace{6mm}7.1.1 $x_{ix} \leftarrow 0$ \\ +8. $x.used \leftarrow n.used + 1$ \\ +9. Clamp excessive digits of $x$. \\ +10. If $x \ge n$ then \\ +\hspace{3mm}10.1 $x \leftarrow x - n$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_mp\_montgomery\_reduce} +\end{figure} + +\textbf{Algorithm fast\_mp\_montgomery\_reduce.} +This algorithm will compute the Montgomery reduction of $x$ modulo $n$ using the Comba technique. It is on most computer platforms significantly +faster than algorithm mp\_montgomery\_reduce and algorithm mp\_reduce (\textit{Barrett reduction}). The algorithm has the same restrictions +on the input as the baseline reduction algorithm. An additional two restrictions are imposed on this algorithm. The number of digits $k$ in the +the modulus $n$ must not violate $MP\_WARRAY > 2k +1$ and $n < \delta$. When $\beta = 2^{28}$ this algorithm can be used to reduce modulo +a modulus of at most $3,556$ bits in length. + +As in the other Comba reduction algorithms there is a $\hat W$ array which stores the columns of the product. It is initially filled with the +contents of $x$ with the excess digits zeroed. The reduction loop is very similar the to the baseline loop at heart. The multiplication on step +4.1 can be single precision only since $ab \mbox{ (mod }\beta\mbox{)} \equiv (a \mbox{ mod }\beta)(b \mbox{ mod }\beta)$. Some multipliers such +as those on the ARM processors take a variable length time to complete depending on the number of bytes of result it must produce. By performing +a single precision multiplication instead half the amount of time is spent. + +Also note that digit $\hat W_{ix}$ must have the carry from the $ix - 1$'th digit propagated upwards in order for this to work. That is what step +4.3 will do. In effect over the $n.used$ iterations of the outer loop the $n.used$'th lower columns all have the their carries propagated forwards. Note +how the upper bits of those same words are not reduced modulo $\beta$. This is because those values will be discarded shortly and there is no +point. + +Step 5 will propagate the remainder of the carries upwards. On step 6 the columns are reduced modulo $\beta$ and shifted simultaneously as they are +stored in the destination $x$. + +EXAM,bn_fast_mp_montgomery_reduce.c + +The $\hat W$ array is first filled with digits of $x$ on line @49,for@ then the rest of the digits are zeroed on line @54,for@. Both loops share +the same alias variables to make the code easier to read. + +The value of $\mu$ is calculated in an interesting fashion. First the value $\hat W_{ix}$ is reduced modulo $\beta$ and cast to a mp\_digit. This +forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line @101,>>@ fixes the carry +for the next iteration of the loop by propagating the carry from $\hat W_{ix}$ to $\hat W_{ix+1}$. + +The for loop on line @113,for@ propagates the rest of the carries upwards through the columns. The for loop on line @126,for@ reduces the columns +modulo $\beta$ and shifts them $k$ places at the same time. The alias $\_ \hat W$ actually refers to the array $\hat W$ starting at the $n.used$'th +digit, that is $\_ \hat W_{t} = \hat W_{n.used + t}$. + +\subsection{Montgomery Setup} +To calculate the variable $\rho$ a relatively simple algorithm will be required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_montgomery\_setup}. \\ +\textbf{Input}. mp\_int $n$ ($n > 1$ and $(n, 2) = 1$) \\ +\textbf{Output}. $\rho \equiv -1/n_0 \mbox{ (mod }\beta\mbox{)}$ \\ +\hline \\ +1. $b \leftarrow n_0$ \\ +2. If $b$ is even return(\textit{MP\_VAL}) \\ +3. $x \leftarrow ((b + 2) \mbox{ AND } 4) << 1) + b$ \\ +4. for $k$ from 0 to $\lceil lg(lg(\beta)) \rceil - 2$ do \\ +\hspace{3mm}4.1 $x \leftarrow x \cdot (2 - bx)$ \\ +5. $\rho \leftarrow \beta - x \mbox{ (mod }\beta\mbox{)}$ \\ +6. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_montgomery\_setup} +\end{figure} + +\textbf{Algorithm mp\_montgomery\_setup.} +This algorithm will calculate the value of $\rho$ required within the Montgomery reduction algorithms. It uses a very interesting trick +to calculate $1/n_0$ when $\beta$ is a power of two. + +EXAM,bn_mp_montgomery_setup.c + +This source code computes the value of $\rho$ required to perform Montgomery reduction. It has been modified to avoid performing excess +multiplications when $\beta$ is not the default 28-bits. + +\section{The Diminished Radix Algorithm} +The Diminished Radix method of modular reduction \cite{DRMET} is a fairly clever technique which can be more efficient than either the Barrett +or Montgomery methods for certain forms of moduli. The technique is based on the following simple congruence. + +\begin{equation} +(x \mbox{ mod } n) + k \lfloor x / n \rfloor \equiv x \mbox{ (mod }(n - k)\mbox{)} +\end{equation} + +This observation was used in the MMB \cite{MMB} block cipher to create a diffusion primitive. It used the fact that if $n = 2^{31}$ and $k=1$ that +then a x86 multiplier could produce the 62-bit product and use the ``shrd'' instruction to perform a double-precision right shift. The proof +of the above equation is very simple. First write $x$ in the product form. + +\begin{equation} +x = qn + r +\end{equation} + +Now reduce both sides modulo $(n - k)$. + +\begin{equation} +x \equiv qk + r \mbox{ (mod }(n-k)\mbox{)} +\end{equation} + +The variable $n$ reduces modulo $n - k$ to $k$. By putting $q = \lfloor x/n \rfloor$ and $r = x \mbox{ mod } n$ +into the equation the original congruence is reproduced, thus concluding the proof. The following algorithm is based on this observation. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Diminished Radix Reduction}. \\ +\textbf{Input}. Integer $x$, $n$, $k$ \\ +\textbf{Output}. $x \mbox{ mod } (n - k)$ \\ +\hline \\ +1. $q \leftarrow \lfloor x / n \rfloor$ \\ +2. $q \leftarrow k \cdot q$ \\ +3. $x \leftarrow x \mbox{ (mod }n\mbox{)}$ \\ +4. $x \leftarrow x + q$ \\ +5. If $x \ge (n - k)$ then \\ +\hspace{3mm}5.1 $x \leftarrow x - (n - k)$ \\ +\hspace{3mm}5.2 Goto step 1. \\ +6. Return $x$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Diminished Radix Reduction} +\label{fig:DR} +\end{figure} + +This algorithm will reduce $x$ modulo $n - k$ and return the residue. If $0 \le x < (n - k)^2$ then the algorithm will loop almost always +once or twice and occasionally three times. For simplicity sake the value of $x$ is bounded by the following simple polynomial. + +\begin{equation} +0 \le x < n^2 + k^2 - 2nk +\end{equation} + +The true bound is $0 \le x < (n - k - 1)^2$ but this has quite a few more terms. The value of $q$ after step 1 is bounded by the following. + +\begin{equation} +q < n - 2k - k^2/n +\end{equation} + +Since $k^2$ is going to be considerably smaller than $n$ that term will always be zero. The value of $x$ after step 3 is bounded trivially as +$0 \le x < n$. By step four the sum $x + q$ is bounded by + +\begin{equation} +0 \le q + x < (k + 1)n - 2k^2 - 1 +\end{equation} + +With a second pass $q$ will be loosely bounded by $0 \le q < k^2$ after step 2 while $x$ will still be loosely bounded by $0 \le x < n$ after step 3. After the second pass it is highly unlike that the +sum in step 4 will exceed $n - k$. In practice fewer than three passes of the algorithm are required to reduce virtually every input in the +range $0 \le x < (n - k - 1)^2$. + +\begin{figure} +\begin{small} +\begin{center} +\begin{tabular}{|l|} +\hline +$x = 123456789, n = 256, k = 3$ \\ +\hline $q \leftarrow \lfloor x/n \rfloor = 482253$ \\ +$q \leftarrow q*k = 1446759$ \\ +$x \leftarrow x \mbox{ mod } n = 21$ \\ +$x \leftarrow x + q = 1446780$ \\ +$x \leftarrow x - (n - k) = 1446527$ \\ +\hline +$q \leftarrow \lfloor x/n \rfloor = 5650$ \\ +$q \leftarrow q*k = 16950$ \\ +$x \leftarrow x \mbox{ mod } n = 127$ \\ +$x \leftarrow x + q = 17077$ \\ +$x \leftarrow x - (n - k) = 16824$ \\ +\hline +$q \leftarrow \lfloor x/n \rfloor = 65$ \\ +$q \leftarrow q*k = 195$ \\ +$x \leftarrow x \mbox{ mod } n = 184$ \\ +$x \leftarrow x + q = 379$ \\ +$x \leftarrow x - (n - k) = 126$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example Diminished Radix Reduction} +\label{fig:EXDR} +\end{figure} + +Figure~\ref{fig:EXDR} demonstrates the reduction of $x = 123456789$ modulo $n - k = 253$ when $n = 256$ and $k = 3$. Note that even while $x$ +is considerably larger than $(n - k - 1)^2 = 63504$ the algorithm still converges on the modular residue exceedingly fast. In this case only +three passes were required to find the residue $x \equiv 126$. + + +\subsection{Choice of Moduli} +On the surface this algorithm looks like a very expensive algorithm. It requires a couple of subtractions followed by multiplication and other +modular reductions. The usefulness of this algorithm becomes exceedingly clear when an appropriate modulus is chosen. + +Division in general is a very expensive operation to perform. The one exception is when the division is by a power of the radix of representation used. +Division by ten for example is simple for pencil and paper mathematics since it amounts to shifting the decimal place to the right. Similarly division +by two (\textit{or powers of two}) is very simple for binary computers to perform. It would therefore seem logical to choose $n$ of the form $2^p$ +which would imply that $\lfloor x / n \rfloor$ is a simple shift of $x$ right $p$ bits. + +However, there is one operation related to division of power of twos that is even faster than this. If $n = \beta^p$ then the division may be +performed by moving whole digits to the right $p$ places. In practice division by $\beta^p$ is much faster than division by $2^p$ for any $p$. +Also with the choice of $n = \beta^p$ reducing $x$ modulo $n$ merely requires zeroing the digits above the $p-1$'th digit of $x$. + +Throughout the next section the term ``restricted modulus'' will refer to a modulus of the form $\beta^p - k$ whereas the term ``unrestricted +modulus'' will refer to a modulus of the form $2^p - k$. The word ``restricted'' in this case refers to the fact that it is based on the +$2^p$ logic except $p$ must be a multiple of $lg(\beta)$. + +\subsection{Choice of $k$} +Now that division and reduction (\textit{step 1 and 3 of figure~\ref{fig:DR}}) have been optimized to simple digit operations the multiplication by $k$ +in step 2 is the most expensive operation. Fortunately the choice of $k$ is not terribly limited. For all intents and purposes it might +as well be a single digit. The smaller the value of $k$ is the faster the algorithm will be. + +\subsection{Restricted Diminished Radix Reduction} +The restricted Diminished Radix algorithm can quickly reduce an input modulo a modulus of the form $n = \beta^p - k$. This algorithm can reduce +an input $x$ within the range $0 \le x < n^2$ using only a couple passes of the algorithm demonstrated in figure~\ref{fig:DR}. The implementation +of this algorithm has been optimized to avoid additional overhead associated with a division by $\beta^p$, the multiplication by $k$ or the addition +of $x$ and $q$. The resulting algorithm is very efficient and can lead to substantial improvements over Barrett and Montgomery reduction when modular +exponentiations are performed. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_reduce}. \\ +\textbf{Input}. mp\_int $x$, $n$ and a mp\_digit $k = \beta - n_0$ \\ +\hspace{11.5mm}($0 \le x < n^2$, $n > 1$, $0 < k < \beta$) \\ +\textbf{Output}. $x \mbox{ mod } n$ \\ +\hline \\ +1. $m \leftarrow n.used$ \\ +2. If $x.alloc < 2m$ then grow $x$ to $2m$ digits. \\ +3. $\mu \leftarrow 0$ \\ +4. for $i$ from $0$ to $m - 1$ do \\ +\hspace{3mm}4.1 $\hat r \leftarrow k \cdot x_{m+i} + x_{i} + \mu$ \\ +\hspace{3mm}4.2 $x_{i} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}4.3 $\mu \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +5. $x_{m} \leftarrow \mu$ \\ +6. for $i$ from $m + 1$ to $x.used - 1$ do \\ +\hspace{3mm}6.1 $x_{i} \leftarrow 0$ \\ +7. Clamp excess digits of $x$. \\ +8. If $x \ge n$ then \\ +\hspace{3mm}8.1 $x \leftarrow x - n$ \\ +\hspace{3mm}8.2 Goto step 3. \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_reduce} +\end{figure} + +\textbf{Algorithm mp\_dr\_reduce.} +This algorithm will perform the Dimished Radix reduction of $x$ modulo $n$. It has similar restrictions to that of the Barrett reduction +with the addition that $n$ must be of the form $n = \beta^m - k$ where $0 < k <\beta$. + +This algorithm essentially implements the pseudo-code in figure~\ref{fig:DR} except with a slight optimization. The division by $\beta^m$, multiplication by $k$ +and addition of $x \mbox{ mod }\beta^m$ are all performed simultaneously inside the loop on step 4. The division by $\beta^m$ is emulated by accessing +the term at the $m+i$'th position which is subsequently multiplied by $k$ and added to the term at the $i$'th position. After the loop the $m$'th +digit is set to the carry and the upper digits are zeroed. Steps 5 and 6 emulate the reduction modulo $\beta^m$ that should have happend to +$x$ before the addition of the multiple of the upper half. + +At step 8 if $x$ is still larger than $n$ another pass of the algorithm is required. First $n$ is subtracted from $x$ and then the algorithm resumes +at step 3. + +EXAM,bn_mp_dr_reduce.c + +The first step is to grow $x$ as required to $2m$ digits since the reduction is performed in place on $x$. The label on line @49,top:@ is where +the algorithm will resume if further reduction passes are required. In theory it could be placed at the top of the function however, the size of +the modulus and question of whether $x$ is large enough are invariant after the first pass meaning that it would be a waste of time. + +The aliases $tmpx1$ and $tmpx2$ refer to the digits of $x$ where the latter is offset by $m$ digits. By reading digits from $x$ offset by $m$ digits +a division by $\beta^m$ can be simulated virtually for free. The loop on line @61,for@ performs the bulk of the work (\textit{corresponds to step 4 of algorithm 7.11}) +in this algorithm. + +By line @68,mu@ the pointer $tmpx1$ points to the $m$'th digit of $x$ which is where the final carry will be placed. Similarly by line @71,for@ the +same pointer will point to the $m+1$'th digit where the zeroes will be placed. + +Since the algorithm is only valid if both $x$ and $n$ are greater than zero an unsigned comparison suffices to determine if another pass is required. +With the same logic at line @82,sub@ the value of $x$ is known to be greater than or equal to $n$ meaning that an unsigned subtraction can be used +as well. Since the destination of the subtraction is the larger of the inputs the call to algorithm s\_mp\_sub cannot fail and the return code +does not need to be checked. + +\subsubsection{Setup} +To setup the restricted Diminished Radix algorithm the value $k = \beta - n_0$ is required. This algorithm is not really complicated but provided for +completeness. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_setup}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $k = \beta - n_0$ \\ +\hline \\ +1. $k \leftarrow \beta - n_0$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_setup} +\end{figure} + +EXAM,bn_mp_dr_setup.c + +\subsubsection{Modulus Detection} +Another algorithm which will be useful is the ability to detect a restricted Diminished Radix modulus. An integer is said to be +of restricted Diminished Radix form if all of the digits are equal to $\beta - 1$ except the trailing digit which may be any value. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_is\_modulus}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $1$ if $n$ is in D.R form, $0$ otherwise \\ +\hline +1. If $n.used < 2$ then return($0$). \\ +2. for $ix$ from $1$ to $n.used - 1$ do \\ +\hspace{3mm}2.1 If $n_{ix} \ne \beta - 1$ return($0$). \\ +3. Return($1$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_is\_modulus} +\end{figure} + +\textbf{Algorithm mp\_dr\_is\_modulus.} +This algorithm determines if a value is in Diminished Radix form. Step 1 rejects obvious cases where fewer than two digits are +in the mp\_int. Step 2 tests all but the first digit to see if they are equal to $\beta - 1$. If the algorithm manages to get to +step 3 then $n$ must be of Diminished Radix form. + +EXAM,bn_mp_dr_is_modulus.c + +\subsection{Unrestricted Diminished Radix Reduction} +The unrestricted Diminished Radix algorithm allows modular reductions to be performed when the modulus is of the form $2^p - k$. This algorithm +is a straightforward adaptation of algorithm~\ref{fig:DR}. + +In general the restricted Diminished Radix reduction algorithm is much faster since it has considerably lower overhead. However, this new +algorithm is much faster than either Montgomery or Barrett reduction when the moduli are of the appropriate form. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_2k}. \\ +\textbf{Input}. mp\_int $a$ and $n$. mp\_digit $k$ \\ +\hspace{11.5mm}($a \ge 0$, $n > 1$, $0 < k < \beta$, $n + k$ is a power of two) \\ +\textbf{Output}. $a \mbox{ (mod }n\mbox{)}$ \\ +\hline +1. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +2. While $a \ge n$ do \\ +\hspace{3mm}2.1 $q \leftarrow \lfloor a / 2^p \rfloor$ (\textit{mp\_div\_2d}) \\ +\hspace{3mm}2.2 $a \leftarrow a \mbox{ (mod }2^p\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +\hspace{3mm}2.3 $q \leftarrow q \cdot k$ (\textit{mp\_mul\_d}) \\ +\hspace{3mm}2.4 $a \leftarrow a - q$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.5 If $a \ge n$ then do \\ +\hspace{6mm}2.5.1 $a \leftarrow a - n$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_2k} +\end{figure} + +\textbf{Algorithm mp\_reduce\_2k.} +This algorithm quickly reduces an input $a$ modulo an unrestricted Diminished Radix modulus $n$. Division by $2^p$ is emulated with a right +shift which makes the algorithm fairly inexpensive to use. + +EXAM,bn_mp_reduce_2k.c + +The algorithm mp\_count\_bits calculates the number of bits in an mp\_int which is used to find the initial value of $p$. The call to mp\_div\_2d +on line @31,mp_div_2d@ calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size +is kept fairly small. The multiplication by $k$ is only performed if $k > 1$. This allows reductions modulo $2^p - 1$ to be performed without +any multiplications. + +The unsigned s\_mp\_add, mp\_cmp\_mag and s\_mp\_sub are used in place of their full sign counterparts since the inputs are only valid if they are +positive. By using the unsigned versions the overhead is kept to a minimum. + +\subsubsection{Unrestricted Setup} +To setup this reduction algorithm the value of $k = 2^p - n$ is required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_2k\_setup}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $k = 2^p - n$ \\ +\hline +1. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +2. $x \leftarrow 2^p$ (\textit{mp\_2expt}) \\ +3. $x \leftarrow x - n$ (\textit{mp\_sub}) \\ +4. $k \leftarrow x_0$ \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_2k\_setup} +\end{figure} + +\textbf{Algorithm mp\_reduce\_2k\_setup.} +This algorithm computes the value of $k$ required for the algorithm mp\_reduce\_2k. By making a temporary variable $x$ equal to $2^p$ a subtraction +is sufficient to solve for $k$. Alternatively if $n$ has more than one digit the value of $k$ is simply $\beta - n_0$. + +EXAM,bn_mp_reduce_2k_setup.c + +\subsubsection{Unrestricted Detection} +An integer $n$ is a valid unrestricted Diminished Radix modulus if either of the following are true. + +\begin{enumerate} +\item The number has only one digit. +\item The number has more than one digit and every bit from the $\beta$'th to the most significant is one. +\end{enumerate} + +If either condition is true than there is a power of two $2^p$ such that $0 < 2^p - n < \beta$. If the input is only +one digit than it will always be of the correct form. Otherwise all of the bits above the first digit must be one. This arises from the fact +that there will be value of $k$ that when added to the modulus causes a carry in the first digit which propagates all the way to the most +significant bit. The resulting sum will be a power of two. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_is\_2k}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $1$ if of proper form, $0$ otherwise \\ +\hline +1. If $n.used = 0$ then return($0$). \\ +2. If $n.used = 1$ then return($1$). \\ +3. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +4. for $x$ from $lg(\beta)$ to $p$ do \\ +\hspace{3mm}4.1 If the ($x \mbox{ mod }lg(\beta)$)'th bit of the $\lfloor x / lg(\beta) \rfloor$ of $n$ is zero then return($0$). \\ +5. Return($1$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_is\_2k} +\end{figure} + +\textbf{Algorithm mp\_reduce\_is\_2k.} +This algorithm quickly determines if a modulus is of the form required for algorithm mp\_reduce\_2k to function properly. + +EXAM,bn_mp_reduce_is_2k.c + + + +\section{Algorithm Comparison} +So far three very different algorithms for modular reduction have been discussed. Each of the algorithms have their own strengths and weaknesses +that makes having such a selection very useful. The following table sumarizes the three algorithms along with comparisons of work factors. Since +all three algorithms have the restriction that $0 \le x < n^2$ and $n > 1$ those limitations are not included in the table. + +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Method} & \textbf{Work Required} & \textbf{Limitations} & \textbf{$m = 8$} & \textbf{$m = 32$} & \textbf{$m = 64$} \\ +\hline Barrett & $m^2 + 2m - 1$ & None & $79$ & $1087$ & $4223$ \\ +\hline Montgomery & $m^2 + m$ & $n$ must be odd & $72$ & $1056$ & $4160$ \\ +\hline D.R. & $2m$ & $n = \beta^m - k$ & $16$ & $64$ & $128$ \\ +\hline +\end{tabular} +\end{small} +\end{center} + +In theory Montgomery and Barrett reductions would require roughly the same amount of time to complete. However, in practice since Montgomery +reduction can be written as a single function with the Comba technique it is much faster. Barrett reduction suffers from the overhead of +calling the half precision multipliers, addition and division by $\beta$ algorithms. + +For almost every cryptographic algorithm Montgomery reduction is the algorithm of choice. The one set of algorithms where Diminished Radix reduction truly +shines are based on the discrete logarithm problem such as Diffie-Hellman \cite{DH} and ElGamal \cite{ELGAMAL}. In these algorithms +primes of the form $\beta^m - k$ can be found and shared amongst users. These primes will allow the Diminished Radix algorithm to be used in +modular exponentiation to greatly speed up the operation. + + + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ]$ & Prove that the ``trick'' in algorithm mp\_montgomery\_setup actually \\ + & calculates the correct value of $\rho$. \\ + & \\ +$\left [ 2 \right ]$ & Devise an algorithm to reduce modulo $n + k$ for small $k$ quickly. \\ + & \\ +$\left [ 4 \right ]$ & Prove that the pseudo-code algorithm ``Diminished Radix Reduction'' \\ + & (\textit{figure~\ref{fig:DR}}) terminates. Also prove the probability that it will \\ + & terminate within $1 \le k \le 10$ iterations. \\ + & \\ +\end{tabular} + + +\chapter{Exponentiation} +Exponentiation is the operation of raising one variable to the power of another, for example, $a^b$. A variant of exponentiation, computed +in a finite field or ring, is called modular exponentiation. This latter style of operation is typically used in public key +cryptosystems such as RSA and Diffie-Hellman. The ability to quickly compute modular exponentiations is of great benefit to any +such cryptosystem and many methods have been sought to speed it up. + +\section{Exponentiation Basics} +A trivial algorithm would simply multiply $a$ against itself $b - 1$ times to compute the exponentiation desired. However, as $b$ grows in size +the number of multiplications becomes prohibitive. Imagine what would happen if $b$ $\approx$ $2^{1024}$ as is the case when computing an RSA signature +with a $1024$-bit key. Such a calculation could never be completed as it would take simply far too long. + +Fortunately there is a very simple algorithm based on the laws of exponents. Recall that $lg_a(a^b) = b$ and that $lg_a(a^ba^c) = b + c$ which +are two trivial relationships between the base and the exponent. Let $b_i$ represent the $i$'th bit of $b$ starting from the least +significant bit. If $b$ is a $k$-bit integer than the following equation is true. + +\begin{equation} +a^b = \prod_{i=0}^{k-1} a^{2^i \cdot b_i} +\end{equation} + +By taking the base $a$ logarithm of both sides of the equation the following equation is the result. + +\begin{equation} +b = \sum_{i=0}^{k-1}2^i \cdot b_i +\end{equation} + +The term $a^{2^i}$ can be found from the $i - 1$'th term by squaring the term since $\left ( a^{2^i} \right )^2$ is equal to +$a^{2^{i+1}}$. This observation forms the basis of essentially all fast exponentiation algorithms. It requires $k$ squarings and on average +$k \over 2$ multiplications to compute the result. This is indeed quite an improvement over simply multiplying by $a$ a total of $b-1$ times. + +While this current method is a considerable speed up there are further improvements to be made. For example, the $a^{2^i}$ term does not need to +be computed in an auxilary variable. Consider the following equivalent algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Left to Right Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$ and $k$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $k - 1$ to $0$ do \\ +\hspace{3mm}2.1 $c \leftarrow c^2$ \\ +\hspace{3mm}2.2 $c \leftarrow c \cdot a^{b_i}$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Left to Right Exponentiation} +\label{fig:LTOR} +\end{figure} + +This algorithm starts from the most significant bit and works towards the least significant bit. When the $i$'th bit of $b$ is set $a$ is +multiplied against the current product. In each iteration the product is squared which doubles the exponent of the individual terms of the +product. + +For example, let $b = 101100_2 \equiv 44_{10}$. The following chart demonstrates the actions of the algorithm. + +\newpage\begin{figure} +\begin{center} +\begin{tabular}{|c|c|} +\hline \textbf{Value of $i$} & \textbf{Value of $c$} \\ +\hline - & $1$ \\ +\hline $5$ & $a$ \\ +\hline $4$ & $a^2$ \\ +\hline $3$ & $a^4 \cdot a$ \\ +\hline $2$ & $a^8 \cdot a^2 \cdot a$ \\ +\hline $1$ & $a^{16} \cdot a^4 \cdot a^2$ \\ +\hline $0$ & $a^{32} \cdot a^8 \cdot a^4$ \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Left to Right Exponentiation} +\end{figure} + +When the product $a^{32} \cdot a^8 \cdot a^4$ is simplified it is equal $a^{44}$ which is the desired exponentiation. This particular algorithm is +called ``Left to Right'' because it reads the exponent in that order. All of the exponentiation algorithms that will be presented are of this nature. + +\subsection{Single Digit Exponentiation} +The first algorithm in the series of exponentiation algorithms will be an unbounded algorithm where the exponent is a single digit. It is intended +to be used when a small power of an input is required (\textit{e.g. $a^5$}). It is faster than simply multiplying $b - 1$ times for all values of +$b$ that are greater than three. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_expt\_d}. \\ +\textbf{Input}. mp\_int $a$ and mp\_digit $b$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $g \leftarrow a$ (\textit{mp\_init\_copy}) \\ +2. $c \leftarrow 1$ (\textit{mp\_set}) \\ +3. for $x$ from 1 to $lg(\beta)$ do \\ +\hspace{3mm}3.1 $c \leftarrow c^2$ (\textit{mp\_sqr}) \\ +\hspace{3mm}3.2 If $b$ AND $2^{lg(\beta) - 1} \ne 0$ then \\ +\hspace{6mm}3.2.1 $c \leftarrow c \cdot g$ (\textit{mp\_mul}) \\ +\hspace{3mm}3.3 $b \leftarrow b << 1$ \\ +4. Clear $g$. \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_expt\_d} +\end{figure} + +\textbf{Algorithm mp\_expt\_d.} +This algorithm computes the value of $a$ raised to the power of a single digit $b$. It uses the left to right exponentiation algorithm to +quickly compute the exponentiation. It is loosely based on algorithm 14.79 of HAC \cite[pp. 615]{HAC} with the difference that the +exponent is a fixed width. + +A copy of $a$ is made first to allow destination variable $c$ be the same as the source variable $a$. The result is set to the initial value of +$1$ in the subsequent step. + +Inside the loop the exponent is read from the most significant bit first down to the least significant bit. First $c$ is invariably squared +on step 3.1. In the following step if the most significant bit of $b$ is one the copy of $a$ is multiplied against $c$. The value +of $b$ is shifted left one bit to make the next bit down from the most signficant bit the new most significant bit. In effect each +iteration of the loop moves the bits of the exponent $b$ upwards to the most significant location. + +EXAM,bn_mp_expt_d.c + +Line @29,mp_set@ sets the initial value of the result to $1$. Next the loop on line @31,for@ steps through each bit of the exponent starting from +the most significant down towards the least significant. The invariant squaring operation placed on line @333,mp_sqr@ is performed first. After +the squaring the result $c$ is multiplied by the base $g$ if and only if the most significant bit of the exponent is set. The shift on line +@47,<<@ moves all of the bits of the exponent upwards towards the most significant location. + +\section{$k$-ary Exponentiation} +When calculating an exponentiation the most time consuming bottleneck is the multiplications which are in general a small factor +slower than squaring. Recall from the previous algorithm that $b_{i}$ refers to the $i$'th bit of the exponent $b$. Suppose instead it referred to +the $i$'th $k$-bit digit of the exponent of $b$. For $k = 1$ the definitions are synonymous and for $k > 1$ algorithm~\ref{fig:KARY} +computes the same exponentiation. A group of $k$ bits from the exponent is called a \textit{window}. That is it is a small window on only a +portion of the entire exponent. Consider the following modification to the basic left to right exponentiation algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{$k$-ary Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$, $k$ and $t$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $t - 1$ to $0$ do \\ +\hspace{3mm}2.1 $c \leftarrow c^{2^k} $ \\ +\hspace{3mm}2.2 Extract the $i$'th $k$-bit word from $b$ and store it in $g$. \\ +\hspace{3mm}2.3 $c \leftarrow c \cdot a^g$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{$k$-ary Exponentiation} +\label{fig:KARY} +\end{figure} + +The squaring on step 2.1 can be calculated by squaring the value $c$ successively $k$ times. If the values of $a^g$ for $0 < g < 2^k$ have been +precomputed this algorithm requires only $t$ multiplications and $tk$ squarings. The table can be generated with $2^{k - 1} - 1$ squarings and +$2^{k - 1} + 1$ multiplications. This algorithm assumes that the number of bits in the exponent is evenly divisible by $k$. +However, when it is not the remaining $0 < x \le k - 1$ bits can be handled with algorithm~\ref{fig:LTOR}. + +Suppose $k = 4$ and $t = 100$. This modified algorithm will require $109$ multiplications and $408$ squarings to compute the exponentiation. The +original algorithm would on average have required $200$ multiplications and $400$ squrings to compute the same value. The total number of squarings +has increased slightly but the number of multiplications has nearly halved. + +\subsection{Optimal Values of $k$} +An optimal value of $k$ will minimize $2^{k} + \lceil n / k \rceil + n - 1$ for a fixed number of bits in the exponent $n$. The simplest +approach is to brute force search amongst the values $k = 2, 3, \ldots, 8$ for the lowest result. Table~\ref{fig:OPTK} lists optimal values of $k$ +for various exponent sizes and compares the number of multiplication and squarings required against algorithm~\ref{fig:LTOR}. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Exponent (bits)} & \textbf{Optimal $k$} & \textbf{Work at $k$} & \textbf{Work with ~\ref{fig:LTOR}} \\ +\hline $16$ & $2$ & $27$ & $24$ \\ +\hline $32$ & $3$ & $49$ & $48$ \\ +\hline $64$ & $3$ & $92$ & $96$ \\ +\hline $128$ & $4$ & $175$ & $192$ \\ +\hline $256$ & $4$ & $335$ & $384$ \\ +\hline $512$ & $5$ & $645$ & $768$ \\ +\hline $1024$ & $6$ & $1257$ & $1536$ \\ +\hline $2048$ & $6$ & $2452$ & $3072$ \\ +\hline $4096$ & $7$ & $4808$ & $6144$ \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Optimal Values of $k$ for $k$-ary Exponentiation} +\label{fig:OPTK} +\end{figure} + +\subsection{Sliding-Window Exponentiation} +A simple modification to the previous algorithm is only generate the upper half of the table in the range $2^{k-1} \le g < 2^k$. Essentially +this is a table for all values of $g$ where the most significant bit of $g$ is a one. However, in order for this to be allowed in the +algorithm values of $g$ in the range $0 \le g < 2^{k-1}$ must be avoided. + +Table~\ref{fig:OPTK2} lists optimal values of $k$ for various exponent sizes and compares the work required against algorithm~\ref{fig:KARY}. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Exponent (bits)} & \textbf{Optimal $k$} & \textbf{Work at $k$} & \textbf{Work with ~\ref{fig:KARY}} \\ +\hline $16$ & $3$ & $24$ & $27$ \\ +\hline $32$ & $3$ & $45$ & $49$ \\ +\hline $64$ & $4$ & $87$ & $92$ \\ +\hline $128$ & $4$ & $167$ & $175$ \\ +\hline $256$ & $5$ & $322$ & $335$ \\ +\hline $512$ & $6$ & $628$ & $645$ \\ +\hline $1024$ & $6$ & $1225$ & $1257$ \\ +\hline $2048$ & $7$ & $2403$ & $2452$ \\ +\hline $4096$ & $8$ & $4735$ & $4808$ \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Optimal Values of $k$ for Sliding Window Exponentiation} +\label{fig:OPTK2} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Sliding Window $k$-ary Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$, $k$ and $t$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $t - 1$ to $0$ do \\ +\hspace{3mm}2.1 If the $i$'th bit of $b$ is a zero then \\ +\hspace{6mm}2.1.1 $c \leftarrow c^2$ \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c \leftarrow c^{2^k}$ \\ +\hspace{6mm}2.2.2 Extract the $k$ bits from $(b_{i}b_{i-1}\ldots b_{i-(k-1)})$ and store it in $g$. \\ +\hspace{6mm}2.2.3 $c \leftarrow c \cdot a^g$ \\ +\hspace{6mm}2.2.4 $i \leftarrow i - k$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Sliding Window $k$-ary Exponentiation} +\end{figure} + +Similar to the previous algorithm this algorithm must have a special handler when fewer than $k$ bits are left in the exponent. While this +algorithm requires the same number of squarings it can potentially have fewer multiplications. The pre-computed table $a^g$ is also half +the size as the previous table. + +Consider the exponent $b = 111101011001000_2 \equiv 31432_{10}$ with $k = 3$ using both algorithms. The first algorithm will divide the exponent up as +the following five $3$-bit words $b \equiv \left ( 111, 101, 011, 001, 000 \right )_{2}$. The second algorithm will break the +exponent as $b \equiv \left ( 111, 101, 0, 110, 0, 100, 0 \right )_{2}$. The single digit $0$ in the second representation are where +a single squaring took place instead of a squaring and multiplication. In total the first method requires $10$ multiplications and $18$ +squarings. The second method requires $8$ multiplications and $18$ squarings. + +In general the sliding window method is never slower than the generic $k$-ary method and often it is slightly faster. + +\section{Modular Exponentiation} + +Modular exponentiation is essentially computing the power of a base within a finite field or ring. For example, computing +$d \equiv a^b \mbox{ (mod }c\mbox{)}$ is a modular exponentiation. Instead of first computing $a^b$ and then reducing it +modulo $c$ the intermediate result is reduced modulo $c$ after every squaring or multiplication operation. + +This guarantees that any intermediate result is bounded by $0 \le d \le c^2 - 2c + 1$ and can be reduced modulo $c$ quickly using +one of the algorithms presented in ~REDUCTION~. + +Before the actual modular exponentiation algorithm can be written a wrapper algorithm must be written first. This algorithm +will allow the exponent $b$ to be negative which is computed as $c \equiv \left (1 / a \right )^{\vert b \vert} \mbox{(mod }d\mbox{)}$. The +value of $(1/a) \mbox{ mod }c$ is computed using the modular inverse (\textit{see \ref{sec;modinv}}). If no inverse exists the algorithm +terminates with an error. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_exptmod}. \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +1. If $c.sign = MP\_NEG$ return(\textit{MP\_VAL}). \\ +2. If $b.sign = MP\_NEG$ then \\ +\hspace{3mm}2.1 $g' \leftarrow g^{-1} \mbox{ (mod }c\mbox{)}$ \\ +\hspace{3mm}2.2 $x' \leftarrow \vert x \vert$ \\ +\hspace{3mm}2.3 Compute $d \equiv g'^{x'} \mbox{ (mod }c\mbox{)}$ via recursion. \\ +3. if $p$ is odd \textbf{OR} $p$ is a D.R. modulus then \\ +\hspace{3mm}3.1 Compute $y \equiv g^{x} \mbox{ (mod }p\mbox{)}$ via algorithm mp\_exptmod\_fast. \\ +4. else \\ +\hspace{3mm}4.1 Compute $y \equiv g^{x} \mbox{ (mod }p\mbox{)}$ via algorithm s\_mp\_exptmod. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_exptmod} +\end{figure} + +\textbf{Algorithm mp\_exptmod.} +The first algorithm which actually performs modular exponentiation is algorithm s\_mp\_exptmod. It is a sliding window $k$-ary algorithm +which uses Barrett reduction to reduce the product modulo $p$. The second algorithm mp\_exptmod\_fast performs the same operation +except it uses either Montgomery or Diminished Radix reduction. The two latter reduction algorithms are clumped in the same exponentiation +algorithm since their arguments are essentially the same (\textit{two mp\_ints and one mp\_digit}). + +EXAM,bn_mp_exptmod.c + +In order to keep the algorithms in a known state the first step on line @29,if@ is to reject any negative modulus as input. If the exponent is +negative the algorithm tries to perform a modular exponentiation with the modular inverse of the base $G$. The temporary variable $tmpG$ is assigned +the modular inverse of $G$ and $tmpX$ is assigned the absolute value of $X$. The algorithm will recuse with these new values with a positive +exponent. + +If the exponent is positive the algorithm resumes the exponentiation. Line @63,dr_@ determines if the modulus is of the restricted Diminished Radix +form. If it is not line @65,reduce@ attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one +of three values. + +\begin{enumerate} +\item $dr = 0$ means that the modulus is not of either restricted or unrestricted Diminished Radix form. +\item $dr = 1$ means that the modulus is of restricted Diminished Radix form. +\item $dr = 2$ means that the modulus is of unrestricted Diminished Radix form. +\end{enumerate} + +Line @69,if@ determines if the fast modular exponentiation algorithm can be used. It is allowed if $dr \ne 0$ or if the modulus is odd. Otherwise, +the slower s\_mp\_exptmod algorithm is used which uses Barrett reduction. + +\subsection{Barrett Modular Exponentiation} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_exptmod}. \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +1. $k \leftarrow lg(x)$ \\ +2. $winsize \leftarrow \left \lbrace \begin{array}{ll} + 2 & \mbox{if }k \le 7 \\ + 3 & \mbox{if }7 < k \le 36 \\ + 4 & \mbox{if }36 < k \le 140 \\ + 5 & \mbox{if }140 < k \le 450 \\ + 6 & \mbox{if }450 < k \le 1303 \\ + 7 & \mbox{if }1303 < k \le 3529 \\ + 8 & \mbox{if }3529 < k \\ + \end{array} \right .$ \\ +3. Initialize $2^{winsize}$ mp\_ints in an array named $M$ and one mp\_int named $\mu$ \\ +4. Calculate the $\mu$ required for Barrett Reduction (\textit{mp\_reduce\_setup}). \\ +5. $M_1 \leftarrow g \mbox{ (mod }p\mbox{)}$ \\ +\\ +Setup the table of small powers of $g$. First find $g^{2^{winsize}}$ and then all multiples of it. \\ +6. $k \leftarrow 2^{winsize - 1}$ \\ +7. $M_{k} \leftarrow M_1$ \\ +8. for $ix$ from 0 to $winsize - 2$ do \\ +\hspace{3mm}8.1 $M_k \leftarrow \left ( M_k \right )^2$ (\textit{mp\_sqr}) \\ +\hspace{3mm}8.2 $M_k \leftarrow M_k \mbox{ (mod }p\mbox{)}$ (\textit{mp\_reduce}) \\ +9. for $ix$ from $2^{winsize - 1} + 1$ to $2^{winsize} - 1$ do \\ +\hspace{3mm}9.1 $M_{ix} \leftarrow M_{ix - 1} \cdot M_{1}$ (\textit{mp\_mul}) \\ +\hspace{3mm}9.2 $M_{ix} \leftarrow M_{ix} \mbox{ (mod }p\mbox{)}$ (\textit{mp\_reduce}) \\ +10. $res \leftarrow 1$ \\ +\\ +Start Sliding Window. \\ +11. $mode \leftarrow 0, bitcnt \leftarrow 1, buf \leftarrow 0, digidx \leftarrow x.used - 1, bitcpy \leftarrow 0, bitbuf \leftarrow 0$ \\ +12. Loop \\ +\hspace{3mm}12.1 $bitcnt \leftarrow bitcnt - 1$ \\ +\hspace{3mm}12.2 If $bitcnt = 0$ then do \\ +\hspace{6mm}12.2.1 If $digidx = -1$ goto step 13. \\ +\hspace{6mm}12.2.2 $buf \leftarrow x_{digidx}$ \\ +\hspace{6mm}12.2.3 $digidx \leftarrow digidx - 1$ \\ +\hspace{6mm}12.2.4 $bitcnt \leftarrow lg(\beta)$ \\ +Continued on next page. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_exptmod} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_exptmod} (\textit{continued}). \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +\hspace{3mm}12.3 $y \leftarrow (buf >> (lg(\beta) - 1))$ AND $1$ \\ +\hspace{3mm}12.4 $buf \leftarrow buf << 1$ \\ +\hspace{3mm}12.5 if $mode = 0$ and $y = 0$ then goto step 12. \\ +\hspace{3mm}12.6 if $mode = 1$ and $y = 0$ then do \\ +\hspace{6mm}12.6.1 $res \leftarrow res^2$ \\ +\hspace{6mm}12.6.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}12.6.3 Goto step 12. \\ +\hspace{3mm}12.7 $bitcpy \leftarrow bitcpy + 1$ \\ +\hspace{3mm}12.8 $bitbuf \leftarrow bitbuf + (y << (winsize - bitcpy))$ \\ +\hspace{3mm}12.9 $mode \leftarrow 2$ \\ +\hspace{3mm}12.10 If $bitcpy = winsize$ then do \\ +\hspace{6mm}Window is full so perform the squarings and single multiplication. \\ +\hspace{6mm}12.10.1 for $ix$ from $0$ to $winsize -1$ do \\ +\hspace{9mm}12.10.1.1 $res \leftarrow res^2$ \\ +\hspace{9mm}12.10.1.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}12.10.2 $res \leftarrow res \cdot M_{bitbuf}$ \\ +\hspace{6mm}12.10.3 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}Reset the window. \\ +\hspace{6mm}12.10.4 $bitcpy \leftarrow 0, bitbuf \leftarrow 0, mode \leftarrow 1$ \\ +\\ +No more windows left. Check for residual bits of exponent. \\ +13. If $mode = 2$ and $bitcpy > 0$ then do \\ +\hspace{3mm}13.1 for $ix$ form $0$ to $bitcpy - 1$ do \\ +\hspace{6mm}13.1.1 $res \leftarrow res^2$ \\ +\hspace{6mm}13.1.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}13.1.3 $bitbuf \leftarrow bitbuf << 1$ \\ +\hspace{6mm}13.1.4 If $bitbuf$ AND $2^{winsize} \ne 0$ then do \\ +\hspace{9mm}13.1.4.1 $res \leftarrow res \cdot M_{1}$ \\ +\hspace{9mm}13.1.4.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +14. $y \leftarrow res$ \\ +15. Clear $res$, $mu$ and the $M$ array. \\ +16. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_exptmod (continued)} +\end{figure} + +\textbf{Algorithm s\_mp\_exptmod.} +This algorithm computes the $x$'th power of $g$ modulo $p$ and stores the result in $y$. It takes advantage of the Barrett reduction +algorithm to keep the product small throughout the algorithm. + +The first two steps determine the optimal window size based on the number of bits in the exponent. The larger the exponent the +larger the window size becomes. After a window size $winsize$ has been chosen an array of $2^{winsize}$ mp\_int variables is allocated. This +table will hold the values of $g^x \mbox{ (mod }p\mbox{)}$ for $2^{winsize - 1} \le x < 2^{winsize}$. + +After the table is allocated the first power of $g$ is found. Since $g \ge p$ is allowed it must be first reduced modulo $p$ to make +the rest of the algorithm more efficient. The first element of the table at $2^{winsize - 1}$ is found by squaring $M_1$ successively $winsize - 2$ +times. The rest of the table elements are found by multiplying the previous element by $M_1$ modulo $p$. + +Now that the table is available the sliding window may begin. The following list describes the functions of all the variables in the window. +\begin{enumerate} +\item The variable $mode$ dictates how the bits of the exponent are interpreted. +\begin{enumerate} + \item When $mode = 0$ the bits are ignored since no non-zero bit of the exponent has been seen yet. For example, if the exponent were simply + $1$ then there would be $lg(\beta) - 1$ zero bits before the first non-zero bit. In this case bits are ignored until a non-zero bit is found. + \item When $mode = 1$ a non-zero bit has been seen before and a new $winsize$-bit window has not been formed yet. In this mode leading $0$ bits + are read and a single squaring is performed. If a non-zero bit is read a new window is created. + \item When $mode = 2$ the algorithm is in the middle of forming a window and new bits are appended to the window from the most significant bit + downwards. +\end{enumerate} +\item The variable $bitcnt$ indicates how many bits are left in the current digit of the exponent left to be read. When it reaches zero a new digit + is fetched from the exponent. +\item The variable $buf$ holds the currently read digit of the exponent. +\item The variable $digidx$ is an index into the exponents digits. It starts at the leading digit $x.used - 1$ and moves towards the trailing digit. +\item The variable $bitcpy$ indicates how many bits are in the currently formed window. When it reaches $winsize$ the window is flushed and + the appropriate operations performed. +\item The variable $bitbuf$ holds the current bits of the window being formed. +\end{enumerate} + +All of step 12 is the window processing loop. It will iterate while there are digits available form the exponent to read. The first step +inside this loop is to extract a new digit if no more bits are available in the current digit. If there are no bits left a new digit is +read and if there are no digits left than the loop terminates. + +After a digit is made available step 12.3 will extract the most significant bit of the current digit and move all other bits in the digit +upwards. In effect the digit is read from most significant bit to least significant bit and since the digits are read from leading to +trailing edges the entire exponent is read from most significant bit to least significant bit. + +At step 12.5 if the $mode$ and currently extracted bit $y$ are both zero the bit is ignored and the next bit is read. This prevents the +algorithm from having to perform trivial squaring and reduction operations before the first non-zero bit is read. Step 12.6 and 12.7-10 handle +the two cases of $mode = 1$ and $mode = 2$ respectively. + +FIGU,expt_state,Sliding Window State Diagram + +By step 13 there are no more digits left in the exponent. However, there may be partial bits in the window left. If $mode = 2$ then +a Left-to-Right algorithm is used to process the remaining few bits. + +EXAM,bn_s_mp_exptmod.c + +Lines @26,if@ through @40,}@ determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement +on line @32,if@ the value of $x$ is already known to be greater than $140$. + +The conditional piece of code beginning on line @42,ifdef@ allows the window size to be restricted to five bits. This logic is used to ensure +the table of precomputed powers of $G$ remains relatively small. + +The for loop on line @49,for@ initializes the $M$ array while lines @59,mp_init@ and @62,mp_reduce@ compute the value of $\mu$ required for +Barrett reduction. + +-- More later. + +\section{Quick Power of Two} +Calculating $b = 2^a$ can be performed much quicker than with any of the previous algorithms. Recall that a logical shift left $m << k$ is +equivalent to $m \cdot 2^k$. By this logic when $m = 1$ a quick power of two can be achieved. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_2expt}. \\ +\textbf{Input}. integer $b$ \\ +\textbf{Output}. $a \leftarrow 2^b$ \\ +\hline \\ +1. $a \leftarrow 0$ \\ +2. If $a.alloc < \lfloor b / lg(\beta) \rfloor + 1$ then grow $a$ appropriately. \\ +3. $a.used \leftarrow \lfloor b / lg(\beta) \rfloor + 1$ \\ +4. $a_{\lfloor b / lg(\beta) \rfloor} \leftarrow 1 << (b \mbox{ mod } lg(\beta))$ \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_2expt} +\end{figure} + +\textbf{Algorithm mp\_2expt.} + +EXAM,bn_mp_2expt.c + +\chapter{Higher Level Algorithms} + +This chapter discusses the various higher level algorithms that are required to complete a well rounded multiple precision integer package. These +routines are less performance oriented than the algorithms of chapters five, six and seven but are no less important. + +The first section describes a method of integer division with remainder that is universally well known. It provides the signed division logic +for the package. The subsequent section discusses a set of algorithms which allow a single digit to be the 2nd operand for a variety of operations. +These algorithms serve mostly to simplify other algorithms where small constants are required. The last two sections discuss how to manipulate +various representations of integers. For example, converting from an mp\_int to a string of character. + +\section{Integer Division with Remainder} +\label{sec:division} + +Integer division aside from modular exponentiation is the most intensive algorithm to compute. Like addition, subtraction and multiplication +the basis of this algorithm is the long-hand division algorithm taught to school children. Throughout this discussion several common variables +will be used. Let $x$ represent the divisor and $y$ represent the dividend. Let $q$ represent the integer quotient $\lfloor y / x \rfloor$ and +let $r$ represent the remainder $r = y - x \lfloor y / x \rfloor$. The following simple algorithm will be used to start the discussion. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Radix-$\beta$ Integer Division}. \\ +\textbf{Input}. integer $x$ and $y$ \\ +\textbf{Output}. $q = \lfloor y/x\rfloor, r = y - xq$ \\ +\hline \\ +1. $q \leftarrow 0$ \\ +2. $n \leftarrow \vert \vert y \vert \vert - \vert \vert x \vert \vert$ \\ +3. for $t$ from $n$ down to $0$ do \\ +\hspace{3mm}3.1 Maximize $k$ such that $kx\beta^t$ is less than or equal to $y$ and $(k + 1)x\beta^t$ is greater. \\ +\hspace{3mm}3.2 $q \leftarrow q + k\beta^t$ \\ +\hspace{3mm}3.3 $y \leftarrow y - kx\beta^t$ \\ +4. $r \leftarrow y$ \\ +5. Return($q, r$) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Radix-$\beta$ Integer Division} +\label{fig:raddiv} +\end{figure} + +As children we are taught this very simple algorithm for the case of $\beta = 10$. Almost instinctively several optimizations are taught for which +their reason of existing are never explained. For this example let $y = 5471$ represent the dividend and $x = 23$ represent the divisor. + +To find the first digit of the quotient the value of $k$ must be maximized such that $kx\beta^t$ is less than or equal to $y$ and +simultaneously $(k + 1)x\beta^t$ is greater than $y$. Implicitly $k$ is the maximum value the $t$'th digit of the quotient may have. The habitual method +used to find the maximum is to ``eyeball'' the two numbers, typically only the leading digits and quickly estimate a quotient. By only using leading +digits a much simpler division may be used to form an educated guess at what the value must be. In this case $k = \lfloor 54/23\rfloor = 2$ quickly +arises as a possible solution. Indeed $2x\beta^2 = 4600$ is less than $y = 5471$ and simultaneously $(k + 1)x\beta^2 = 6900$ is larger than $y$. +As a result $k\beta^2$ is added to the quotient which now equals $q = 200$ and $4600$ is subtracted from $y$ to give a remainder of $y = 841$. + +Again this process is repeated to produce the quotient digit $k = 3$ which makes the quotient $q = 200 + 3\beta = 230$ and the remainder +$y = 841 - 3x\beta = 181$. Finally the last iteration of the loop produces $k = 7$ which leads to the quotient $q = 230 + 7 = 237$ and the +remainder $y = 181 - 7x = 20$. The final quotient and remainder found are $q = 237$ and $r = y = 20$ which are indeed correct since +$237 \cdot 23 + 20 = 5471$ is true. + +\subsection{Quotient Estimation} +\label{sec:divest} +As alluded to earlier the quotient digit $k$ can be estimated from only the leading digits of both the divisor and dividend. When $p$ leading +digits are used from both the divisor and dividend to form an estimation the accuracy of the estimation rises as $p$ grows. Technically +speaking the estimation is based on assuming the lower $\vert \vert y \vert \vert - p$ and $\vert \vert x \vert \vert - p$ lower digits of the +dividend and divisor are zero. + +The value of the estimation may off by a few values in either direction and in general is fairly correct. A simplification \cite[pp. 271]{TAOCPV2} +of the estimation technique is to use $t + 1$ digits of the dividend and $t$ digits of the divisor, in particularly when $t = 1$. The estimate +using this technique is never too small. For the following proof let $t = \vert \vert y \vert \vert - 1$ and $s = \vert \vert x \vert \vert - 1$ +represent the most significant digits of the dividend and divisor respectively. + +\textbf{Proof.}\textit{ The quotient $\hat k = \lfloor (y_t\beta + y_{t-1}) / x_s \rfloor$ is greater than or equal to +$k = \lfloor y / (x \cdot \beta^{\vert \vert y \vert \vert - \vert \vert x \vert \vert - 1}) \rfloor$. } +The first obvious case is when $\hat k = \beta - 1$ in which case the proof is concluded since the real quotient cannot be larger. For all other +cases $\hat k = \lfloor (y_t\beta + y_{t-1}) / x_s \rfloor$ and $\hat k x_s \ge y_t\beta + y_{t-1} - x_s + 1$. The latter portion of the inequalility +$-x_s + 1$ arises from the fact that a truncated integer division will give the same quotient for at most $x_s - 1$ values. Next a series of +inequalities will prove the hypothesis. + +\begin{equation} +y - \hat k x \le y - \hat k x_s\beta^s +\end{equation} + +This is trivially true since $x \ge x_s\beta^s$. Next we replace $\hat kx_s\beta^s$ by the previous inequality for $\hat kx_s$. + +\begin{equation} +y - \hat k x \le y_t\beta^t + \ldots + y_0 - (y_t\beta^t + y_{t-1}\beta^{t-1} - x_s\beta^t + \beta^s) +\end{equation} + +By simplifying the previous inequality the following inequality is formed. + +\begin{equation} +y - \hat k x \le y_{t-2}\beta^{t-2} + \ldots + y_0 + x_s\beta^s - \beta^s +\end{equation} + +Subsequently, + +\begin{equation} +y_{t-2}\beta^{t-2} + \ldots + y_0 + x_s\beta^s - \beta^s < x_s\beta^s \le x +\end{equation} + +Which proves that $y - \hat kx \le x$ and by consequence $\hat k \ge k$ which concludes the proof. \textbf{QED} + + +\subsection{Normalized Integers} +For the purposes of division a normalized input is when the divisors leading digit $x_n$ is greater than or equal to $\beta / 2$. By multiplying both +$x$ and $y$ by $j = \lfloor (\beta / 2) / x_n \rfloor$ the quotient remains unchanged and the remainder is simply $j$ times the original +remainder. The purpose of normalization is to ensure the leading digit of the divisor is sufficiently large such that the estimated quotient will +lie in the domain of a single digit. Consider the maximum dividend $(\beta - 1) \cdot \beta + (\beta - 1)$ and the minimum divisor $\beta / 2$. + +\begin{equation} +{{\beta^2 - 1} \over { \beta / 2}} \le 2\beta - {2 \over \beta} +\end{equation} + +At most the quotient approaches $2\beta$, however, in practice this will not occur since that would imply the previous quotient digit was too small. + +\subsection{Radix-$\beta$ Division with Remainder} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div}. \\ +\textbf{Input}. mp\_int $a, b$ \\ +\textbf{Output}. $c = \lfloor a/b \rfloor$, $d = a - bc$ \\ +\hline \\ +1. If $b = 0$ return(\textit{MP\_VAL}). \\ +2. If $\vert a \vert < \vert b \vert$ then do \\ +\hspace{3mm}2.1 $d \leftarrow a$ \\ +\hspace{3mm}2.2 $c \leftarrow 0$ \\ +\hspace{3mm}2.3 Return(\textit{MP\_OKAY}). \\ +\\ +Setup the quotient to receive the digits. \\ +3. Grow $q$ to $a.used + 2$ digits. \\ +4. $q \leftarrow 0$ \\ +5. $x \leftarrow \vert a \vert , y \leftarrow \vert b \vert$ \\ +6. $sign \leftarrow \left \lbrace \begin{array}{ll} + MP\_ZPOS & \mbox{if }a.sign = b.sign \\ + MP\_NEG & \mbox{otherwise} \\ + \end{array} \right .$ \\ +\\ +Normalize the inputs such that the leading digit of $y$ is greater than or equal to $\beta / 2$. \\ +7. $norm \leftarrow (lg(\beta) - 1) - (\lceil lg(y) \rceil \mbox{ (mod }lg(\beta)\mbox{)})$ \\ +8. $x \leftarrow x \cdot 2^{norm}, y \leftarrow y \cdot 2^{norm}$ \\ +\\ +Find the leading digit of the quotient. \\ +9. $n \leftarrow x.used - 1, t \leftarrow y.used - 1$ \\ +10. $y \leftarrow y \cdot \beta^{n - t}$ \\ +11. While ($x \ge y$) do \\ +\hspace{3mm}11.1 $q_{n - t} \leftarrow q_{n - t} + 1$ \\ +\hspace{3mm}11.2 $x \leftarrow x - y$ \\ +12. $y \leftarrow \lfloor y / \beta^{n-t} \rfloor$ \\ +\\ +Continued on the next page. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div} (continued). \\ +\textbf{Input}. mp\_int $a, b$ \\ +\textbf{Output}. $c = \lfloor a/b \rfloor$, $d = a - bc$ \\ +\hline \\ +Now find the remainder fo the digits. \\ +13. for $i$ from $n$ down to $(t + 1)$ do \\ +\hspace{3mm}13.1 If $i > x.used$ then jump to the next iteration of this loop. \\ +\hspace{3mm}13.2 If $x_{i} = y_{t}$ then \\ +\hspace{6mm}13.2.1 $q_{i - t - 1} \leftarrow \beta - 1$ \\ +\hspace{3mm}13.3 else \\ +\hspace{6mm}13.3.1 $\hat r \leftarrow x_{i} \cdot \beta + x_{i - 1}$ \\ +\hspace{6mm}13.3.2 $\hat r \leftarrow \lfloor \hat r / y_{t} \rfloor$ \\ +\hspace{6mm}13.3.3 $q_{i - t - 1} \leftarrow \hat r$ \\ +\hspace{3mm}13.4 $q_{i - t - 1} \leftarrow q_{i - t - 1} + 1$ \\ +\\ +Fixup quotient estimation. \\ +\hspace{3mm}13.5 Loop \\ +\hspace{6mm}13.5.1 $q_{i - t - 1} \leftarrow q_{i - t - 1} - 1$ \\ +\hspace{6mm}13.5.2 t$1 \leftarrow 0$ \\ +\hspace{6mm}13.5.3 t$1_0 \leftarrow y_{t - 1}, $ t$1_1 \leftarrow y_t,$ t$1.used \leftarrow 2$ \\ +\hspace{6mm}13.5.4 $t1 \leftarrow t1 \cdot q_{i - t - 1}$ \\ +\hspace{6mm}13.5.5 t$2_0 \leftarrow x_{i - 2}, $ t$2_1 \leftarrow x_{i - 1}, $ t$2_2 \leftarrow x_i, $ t$2.used \leftarrow 3$ \\ +\hspace{6mm}13.5.6 If $\vert t1 \vert > \vert t2 \vert$ then goto step 13.5. \\ +\hspace{3mm}13.6 t$1 \leftarrow y \cdot q_{i - t - 1}$ \\ +\hspace{3mm}13.7 t$1 \leftarrow $ t$1 \cdot \beta^{i - t - 1}$ \\ +\hspace{3mm}13.8 $x \leftarrow x - $ t$1$ \\ +\hspace{3mm}13.9 If $x.sign = MP\_NEG$ then \\ +\hspace{6mm}13.10 t$1 \leftarrow y$ \\ +\hspace{6mm}13.11 t$1 \leftarrow $ t$1 \cdot \beta^{i - t - 1}$ \\ +\hspace{6mm}13.12 $x \leftarrow x + $ t$1$ \\ +\hspace{6mm}13.13 $q_{i - t - 1} \leftarrow q_{i - t - 1} - 1$ \\ +\\ +Finalize the result. \\ +14. Clamp excess digits of $q$ \\ +15. $c \leftarrow q, c.sign \leftarrow sign$ \\ +16. $x.sign \leftarrow a.sign$ \\ +17. $d \leftarrow \lfloor x / 2^{norm} \rfloor$ \\ +18. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div (continued)} +\end{figure} +\textbf{Algorithm mp\_div.} +This algorithm will calculate quotient and remainder from an integer division given a dividend and divisor. The algorithm is a signed +division and will produce a fully qualified quotient and remainder. + +First the divisor $b$ must be non-zero which is enforced in step one. If the divisor is larger than the dividend than the quotient is implicitly +zero and the remainder is the dividend. + +After the first two trivial cases of inputs are handled the variable $q$ is setup to receive the digits of the quotient. Two unsigned copies of the +divisor $y$ and dividend $x$ are made as well. The core of the division algorithm is an unsigned division and will only work if the values are +positive. Now the two values $x$ and $y$ must be normalized such that the leading digit of $y$ is greater than or equal to $\beta / 2$. +This is performed by shifting both to the left by enough bits to get the desired normalization. + +At this point the division algorithm can begin producing digits of the quotient. Recall that maximum value of the estimation used is +$2\beta - {2 \over \beta}$ which means that a digit of the quotient must be first produced by another means. In this case $y$ is shifted +to the left (\textit{step ten}) so that it has the same number of digits as $x$. The loop on step eleven will subtract multiples of the +shifted copy of $y$ until $x$ is smaller. Since the leading digit of $y$ is greater than or equal to $\beta/2$ this loop will iterate at most two +times to produce the desired leading digit of the quotient. + +Now the remainder of the digits can be produced. The equation $\hat q = \lfloor {{x_i \beta + x_{i-1}}\over y_t} \rfloor$ is used to fairly +accurately approximate the true quotient digit. The estimation can in theory produce an estimation as high as $2\beta - {2 \over \beta}$ but by +induction the upper quotient digit is correct (\textit{as established on step eleven}) and the estimate must be less than $\beta$. + +Recall from section~\ref{sec:divest} that the estimation is never too low but may be too high. The next step of the estimation process is +to refine the estimation. The loop on step 13.5 uses $x_i\beta^2 + x_{i-1}\beta + x_{i-2}$ and $q_{i - t - 1}(y_t\beta + y_{t-1})$ as a higher +order approximation to adjust the quotient digit. + +After both phases of estimation the quotient digit may still be off by a value of one\footnote{This is similar to the error introduced +by optimizing Barrett reduction.}. Steps 13.6 and 13.7 subtract the multiple of the divisor from the dividend (\textit{Similar to step 3.3 of +algorithm~\ref{fig:raddiv}} and then subsequently add a multiple of the divisor if the quotient was too large. + +Now that the quotient has been determine finializing the result is a matter of clamping the quotient, fixing the sizes and de-normalizing the +remainder. An important aspect of this algorithm seemingly overlooked in other descriptions such as that of Algorithm 14.20 HAC \cite[pp. 598]{HAC} +is that when the estimations are being made (\textit{inside the loop on step 13.5}) that the digits $y_{t-1}$, $x_{i-2}$ and $x_{i-1}$ may lie +outside their respective boundaries. For example, if $t = 0$ or $i \le 1$ then the digits would be undefined. In those cases the digits should +respectively be replaced with a zero. + +EXAM,bn_mp_div.c + +The implementation of this algorithm differs slightly from the pseudo code presented previously. In this algorithm either of the quotient $c$ or +remainder $d$ may be passed as a \textbf{NULL} pointer which indicates their value is not desired. For example, the C code to call the division +algorithm with only the quotient is + +\begin{verbatim} +mp_div(&a, &b, &c, NULL); /* c = [a/b] */ +\end{verbatim} + +Lines @37,if@ and @42,if@ handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor +respectively. After the two trivial cases all of the temporary variables are initialized. Line @76,neg@ determines the sign of +the quotient and line @77,sign@ ensures that both $x$ and $y$ are positive. + +The number of bits in the leading digit is calculated on line @80,norm@. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits +of precision which when reduced modulo $lg(\beta)$ produces the value of $k$. In this case $k$ is the number of bits in the leading digit which is +exactly what is required. For the algorithm to operate $k$ must equal $lg(\beta) - 1$ and when it does not the inputs must be normalized by shifting +them to the left by $lg(\beta) - 1 - k$ bits. + +Throughout the variables $n$ and $t$ will represent the highest digit of $x$ and $y$ respectively. These are first used to produce the +leading digit of the quotient. The loop beginning on line @113,for@ will produce the remainder of the quotient digits. + +The conditional ``continue'' on line @114,if@ is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the +algorithm eliminates multiple non-zero digits in a single iteration. This ensures that $x_i$ is always non-zero since by definition the digits +above the $i$'th position $x$ must be zero in order for the quotient to be precise\footnote{Precise as far as integer division is concerned.}. + +Lines @142,t1@, @143,t1@ and @150,t2@ through @152,t2@ manually construct the high accuracy estimations by setting the digits of the two mp\_int +variables directly. + +\section{Single Digit Helpers} + +This section briefly describes a series of single digit helper algorithms which come in handy when working with small constants. All of +the helper functions assume the single digit input is positive and will treat them as such. + +\subsection{Single Digit Addition and Subtraction} + +Both addition and subtraction are performed by ``cheating'' and using mp\_set followed by the higher level addition or subtraction +algorithms. As a result these algorithms are subtantially simpler with a slight cost in performance. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_add\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = a + b$ \\ +\hline \\ +1. $t \leftarrow b$ (\textit{mp\_set}) \\ +2. $c \leftarrow a + t$ \\ +3. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_add\_d} +\end{figure} + +\textbf{Algorithm mp\_add\_d.} +This algorithm initiates a temporary mp\_int with the value of the single digit and uses algorithm mp\_add to add the two values together. + +EXAM,bn_mp_add_d.c + +Clever use of the letter 't'. + +\subsubsection{Subtraction} +The single digit subtraction algorithm mp\_sub\_d is essentially the same except it uses mp\_sub to subtract the digit from the mp\_int. + +\subsection{Single Digit Multiplication} +Single digit multiplication arises enough in division and radix conversion that it ought to be implement as a special case of the baseline +multiplication algorithm. Essentially this algorithm is a modified version of algorithm s\_mp\_mul\_digs where one of the multiplicands +only has one digit. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = ab$ \\ +\hline \\ +1. $pa \leftarrow a.used$ \\ +2. Grow $c$ to at least $pa + 1$ digits. \\ +3. $oldused \leftarrow c.used$ \\ +4. $c.used \leftarrow pa + 1$ \\ +5. $c.sign \leftarrow a.sign$ \\ +6. $\mu \leftarrow 0$ \\ +7. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}7.1 $\hat r \leftarrow \mu + a_{ix}b$ \\ +\hspace{3mm}7.2 $c_{ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}7.3 $\mu \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +8. $c_{pa} \leftarrow \mu$ \\ +9. for $ix$ from $pa + 1$ to $oldused$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow 0$ \\ +10. Clamp excess digits of $c$. \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_d} +\end{figure} +\textbf{Algorithm mp\_mul\_d.} +This algorithm quickly multiplies an mp\_int by a small single digit value. It is specially tailored to the job and has a minimal of overhead. +Unlike the full multiplication algorithms this algorithm does not require any significnat temporary storage or memory allocations. + +EXAM,bn_mp_mul_d.c + +In this implementation the destination $c$ may point to the same mp\_int as the source $a$ since the result is written after the digit is +read from the source. This function uses pointer aliases $tmpa$ and $tmpc$ for the digits of $a$ and $c$ respectively. + +\subsection{Single Digit Division} +Like the single digit multiplication algorithm, single digit division is also a fairly common algorithm used in radix conversion. Since the +divisor is only a single digit a specialized variant of the division algorithm can be used to compute the quotient. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = \lfloor a / b \rfloor, d = a - cb$ \\ +\hline \\ +1. If $b = 0$ then return(\textit{MP\_VAL}).\\ +2. If $b = 3$ then use algorithm mp\_div\_3 instead. \\ +3. Init $q$ to $a.used$ digits. \\ +4. $q.used \leftarrow a.used$ \\ +5. $q.sign \leftarrow a.sign$ \\ +6. $\hat w \leftarrow 0$ \\ +7. for $ix$ from $a.used - 1$ down to $0$ do \\ +\hspace{3mm}7.1 $\hat w \leftarrow \hat w \beta + a_{ix}$ \\ +\hspace{3mm}7.2 If $\hat w \ge b$ then \\ +\hspace{6mm}7.2.1 $t \leftarrow \lfloor \hat w / b \rfloor$ \\ +\hspace{6mm}7.2.2 $\hat w \leftarrow \hat w \mbox{ (mod }b\mbox{)}$ \\ +\hspace{3mm}7.3 else\\ +\hspace{6mm}7.3.1 $t \leftarrow 0$ \\ +\hspace{3mm}7.4 $q_{ix} \leftarrow t$ \\ +8. $d \leftarrow \hat w$ \\ +9. Clamp excess digits of $q$. \\ +10. $c \leftarrow q$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_d} +\end{figure} +\textbf{Algorithm mp\_div\_d.} +This algorithm divides the mp\_int $a$ by the single mp\_digit $b$ using an optimized approach. Essentially in every iteration of the +algorithm another digit of the dividend is reduced and another digit of quotient produced. Provided $b < \beta$ the value of $\hat w$ +after step 7.1 will be limited such that $0 \le \lfloor \hat w / b \rfloor < \beta$. + +If the divisor $b$ is equal to three a variant of this algorithm is used which is called mp\_div\_3. It replaces the division by three with +a multiplication by $\lfloor \beta / 3 \rfloor$ and the appropriate shift and residual fixup. In essence it is much like the Barrett reduction +from chapter seven. + +EXAM,bn_mp_div_d.c + +Like the implementation of algorithm mp\_div this algorithm allows either of the quotient or remainder to be passed as a \textbf{NULL} pointer to +indicate the respective value is not required. This allows a trivial single digit modular reduction algorithm, mp\_mod\_d to be created. + +The division and remainder on lines @44,/@ and @45,%@ can be replaced often by a single division on most processors. For example, the 32-bit x86 based +processors can divide a 64-bit quantity by a 32-bit quantity and produce the quotient and remainder simultaneously. Unfortunately the GCC +compiler does not recognize that optimization and will actually produce two function calls to find the quotient and remainder respectively. + +\subsection{Single Digit Root Extraction} + +Finding the $n$'th root of an integer is fairly easy as far as numerical analysis is concerned. Algorithms such as the Newton-Raphson approximation +(\ref{eqn:newton}) series will converge very quickly to a root for any continuous function $f(x)$. + +\begin{equation} +x_{i+1} = x_i - {f(x_i) \over f'(x_i)} +\label{eqn:newton} +\end{equation} + +In this case the $n$'th root is desired and $f(x) = x^n - a$ where $a$ is the integer of which the root is desired. The derivative of $f(x)$ is +simply $f'(x) = nx^{n - 1}$. Of particular importance is that this algorithm will be used over the integers not over the a more continuous domain +such as the real numbers. As a result the root found can be above the true root by few and must be manually adjusted. Ideally at the end of the +algorithm the $n$'th root $b$ of an integer $a$ is desired such that $b^n \le a$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_n\_root}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c^b \le a$ \\ +\hline \\ +1. If $b$ is even and $a.sign = MP\_NEG$ return(\textit{MP\_VAL}). \\ +2. $sign \leftarrow a.sign$ \\ +3. $a.sign \leftarrow MP\_ZPOS$ \\ +4. t$2 \leftarrow 2$ \\ +5. Loop \\ +\hspace{3mm}5.1 t$1 \leftarrow $ t$2$ \\ +\hspace{3mm}5.2 t$3 \leftarrow $ t$1^{b - 1}$ \\ +\hspace{3mm}5.3 t$2 \leftarrow $ t$3 $ $\cdot$ t$1$ \\ +\hspace{3mm}5.4 t$2 \leftarrow $ t$2 - a$ \\ +\hspace{3mm}5.5 t$3 \leftarrow $ t$3 \cdot b$ \\ +\hspace{3mm}5.6 t$3 \leftarrow \lfloor $t$2 / $t$3 \rfloor$ \\ +\hspace{3mm}5.7 t$2 \leftarrow $ t$1 - $ t$3$ \\ +\hspace{3mm}5.8 If t$1 \ne $ t$2$ then goto step 5. \\ +6. Loop \\ +\hspace{3mm}6.1 t$2 \leftarrow $ t$1^b$ \\ +\hspace{3mm}6.2 If t$2 > a$ then \\ +\hspace{6mm}6.2.1 t$1 \leftarrow $ t$1 - 1$ \\ +\hspace{6mm}6.2.2 Goto step 6. \\ +7. $a.sign \leftarrow sign$ \\ +8. $c \leftarrow $ t$1$ \\ +9. $c.sign \leftarrow sign$ \\ +10. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_n\_root} +\end{figure} +\textbf{Algorithm mp\_n\_root.} +This algorithm finds the integer $n$'th root of an input using the Newton-Raphson approach. It is partially optimized based on the observation +that the numerator of ${f(x) \over f'(x)}$ can be derived from a partial denominator. That is at first the denominator is calculated by finding +$x^{b - 1}$. This value can then be multiplied by $x$ and have $a$ subtracted from it to find the numerator. This saves a total of $b - 1$ +multiplications by t$1$ inside the loop. + +The initial value of the approximation is t$2 = 2$ which allows the algorithm to start with very small values and quickly converge on the +root. Ideally this algorithm is meant to find the $n$'th root of an input where $n$ is bounded by $2 \le n \le 5$. + +EXAM,bn_mp_n_root.c + +\section{Random Number Generation} + +Random numbers come up in a variety of activities from public key cryptography to simple simulations and various randomized algorithms. Pollard-Rho +factoring for example, can make use of random values as starting points to find factors of a composite integer. In this case the algorithm presented +is solely for simulations and not intended for cryptographic use. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_rand}. \\ +\textbf{Input}. An integer $b$ \\ +\textbf{Output}. A pseudo-random number of $b$ digits \\ +\hline \\ +1. $a \leftarrow 0$ \\ +2. If $b \le 0$ return(\textit{MP\_OKAY}) \\ +3. Pick a non-zero random digit $d$. \\ +4. $a \leftarrow a + d$ \\ +5. for $ix$ from 1 to $d - 1$ do \\ +\hspace{3mm}5.1 $a \leftarrow a \cdot \beta$ \\ +\hspace{3mm}5.2 Pick a random digit $d$. \\ +\hspace{3mm}5.3 $a \leftarrow a + d$ \\ +6. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_rand} +\end{figure} +\textbf{Algorithm mp\_rand.} +This algorithm produces a pseudo-random integer of $b$ digits. By ensuring that the first digit is non-zero the algorithm also guarantees that the +final result has at least $b$ digits. It relies heavily on a third-part random number generator which should ideally generate uniformly all of +the integers from $0$ to $\beta - 1$. + +EXAM,bn_mp_rand.c + +\section{Formatted Representations} +The ability to emit a radix-$n$ textual representation of an integer is useful for interacting with human parties. For example, the ability to +be given a string of characters such as ``114585'' and turn it into the radix-$\beta$ equivalent would make it easier to enter numbers +into a program. + +\subsection{Reading Radix-n Input} +For the purposes of this text we will assume that a simple lower ASCII map (\ref{fig:ASC}) is used for the values of from $0$ to $63$ to +printable characters. For example, when the character ``N'' is read it represents the integer $23$. The first $16$ characters of the +map are for the common representations up to hexadecimal. After that they match the ``base64'' encoding scheme which are suitable chosen +such that they are printable. While outputting as base64 may not be too helpful for human operators it does allow communication via non binary +mediums. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{cc|cc|cc|cc} +\hline \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} \\ +\hline +0 & 0 & 1 & 1 & 2 & 2 & 3 & 3 \\ +4 & 4 & 5 & 5 & 6 & 6 & 7 & 7 \\ +8 & 8 & 9 & 9 & 10 & A & 11 & B \\ +12 & C & 13 & D & 14 & E & 15 & F \\ +16 & G & 17 & H & 18 & I & 19 & J \\ +20 & K & 21 & L & 22 & M & 23 & N \\ +24 & O & 25 & P & 26 & Q & 27 & R \\ +28 & S & 29 & T & 30 & U & 31 & V \\ +32 & W & 33 & X & 34 & Y & 35 & Z \\ +36 & a & 37 & b & 38 & c & 39 & d \\ +40 & e & 41 & f & 42 & g & 43 & h \\ +44 & i & 45 & j & 46 & k & 47 & l \\ +48 & m & 49 & n & 50 & o & 51 & p \\ +52 & q & 53 & r & 54 & s & 55 & t \\ +56 & u & 57 & v & 58 & w & 59 & x \\ +60 & y & 61 & z & 62 & $+$ & 63 & $/$ \\ +\hline +\end{tabular} +\end{center} +\caption{Lower ASCII Map} +\label{fig:ASC} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_read\_radix}. \\ +\textbf{Input}. A string $str$ of length $sn$ and radix $r$. \\ +\textbf{Output}. The radix-$\beta$ equivalent mp\_int. \\ +\hline \\ +1. If $r < 2$ or $r > 64$ return(\textit{MP\_VAL}). \\ +2. $ix \leftarrow 0$ \\ +3. If $str_0 =$ ``-'' then do \\ +\hspace{3mm}3.1 $ix \leftarrow ix + 1$ \\ +\hspace{3mm}3.2 $sign \leftarrow MP\_NEG$ \\ +4. else \\ +\hspace{3mm}4.1 $sign \leftarrow MP\_ZPOS$ \\ +5. $a \leftarrow 0$ \\ +6. for $iy$ from $ix$ to $sn - 1$ do \\ +\hspace{3mm}6.1 Let $y$ denote the position in the map of $str_{iy}$. \\ +\hspace{3mm}6.2 If $str_{iy}$ is not in the map or $y \ge r$ then goto step 7. \\ +\hspace{3mm}6.3 $a \leftarrow a \cdot r$ \\ +\hspace{3mm}6.4 $a \leftarrow a + y$ \\ +7. If $a \ne 0$ then $a.sign \leftarrow sign$ \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_read\_radix} +\end{figure} +\textbf{Algorithm mp\_read\_radix.} +This algorithm will read an ASCII string and produce the radix-$\beta$ mp\_int representation of the same integer. A minus symbol ``-'' may precede the +string to indicate the value is negative, otherwise it is assumed to be positive. The algorithm will read up to $sn$ characters from the input +and will stop when it reads a character it cannot map the algorithm stops reading characters from the string. This allows numbers to be embedded +as part of larger input without any significant problem. + +EXAM,bn_mp_read_radix.c + +\subsection{Generating Radix-$n$ Output} +Generating radix-$n$ output is fairly trivial with a division and remainder algorithm. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_toradix}. \\ +\textbf{Input}. A mp\_int $a$ and an integer $r$\\ +\textbf{Output}. The radix-$r$ representation of $a$ \\ +\hline \\ +1. If $r < 2$ or $r > 64$ return(\textit{MP\_VAL}). \\ +2. If $a = 0$ then $str = $ ``$0$'' and return(\textit{MP\_OKAY}). \\ +3. $t \leftarrow a$ \\ +4. $str \leftarrow$ ``'' \\ +5. if $t.sign = MP\_NEG$ then \\ +\hspace{3mm}5.1 $str \leftarrow str + $ ``-'' \\ +\hspace{3mm}5.2 $t.sign = MP\_ZPOS$ \\ +6. While ($t \ne 0$) do \\ +\hspace{3mm}6.1 $d \leftarrow t \mbox{ (mod }r\mbox{)}$ \\ +\hspace{3mm}6.2 $t \leftarrow \lfloor t / r \rfloor$ \\ +\hspace{3mm}6.3 Look up $d$ in the map and store the equivalent character in $y$. \\ +\hspace{3mm}6.4 $str \leftarrow str + y$ \\ +7. If $str_0 = $``$-$'' then \\ +\hspace{3mm}7.1 Reverse the digits $str_1, str_2, \ldots str_n$. \\ +8. Otherwise \\ +\hspace{3mm}8.1 Reverse the digits $str_0, str_1, \ldots str_n$. \\ +9. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_toradix} +\end{figure} +\textbf{Algorithm mp\_toradix.} +This algorithm computes the radix-$r$ representation of an mp\_int $a$. The ``digits'' of the representation are extracted by reducing +successive powers of $\lfloor a / r^k \rfloor$ the input modulo $r$ until $r^k > a$. Note that instead of actually dividing by $r^k$ in +each iteration the quotient $\lfloor a / r \rfloor$ is saved for the next iteration. As a result a series of trivial $n \times 1$ divisions +are required instead of a series of $n \times k$ divisions. One design flaw of this approach is that the digits are produced in the reverse order +(see~\ref{fig:mpradix}). To remedy this flaw the digits must be swapped or simply ``reversed''. + +\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Value of $a$} & \textbf{Value of $d$} & \textbf{Value of $str$} \\ +\hline $1234$ & -- & -- \\ +\hline $123$ & $4$ & ``4'' \\ +\hline $12$ & $3$ & ``43'' \\ +\hline $1$ & $2$ & ``432'' \\ +\hline $0$ & $1$ & ``4321'' \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Algorithm mp\_toradix.} +\label{fig:mpradix} +\end{figure} + +EXAM,bn_mp_toradix.c + +\chapter{Number Theoretic Algorithms} +This chapter discusses several fundamental number theoretic algorithms such as the greatest common divisor, least common multiple and Jacobi +symbol computation. These algorithms arise as essential components in several key cryptographic algorithms such as the RSA public key algorithm and +various Sieve based factoring algorithms. + +\section{Greatest Common Divisor} +The greatest common divisor of two integers $a$ and $b$, often denoted as $(a, b)$ is the largest integer $k$ that is a proper divisor of +both $a$ and $b$. That is, $k$ is the largest integer such that $0 \equiv a \mbox{ (mod }k\mbox{)}$ and $0 \equiv b \mbox{ (mod }k\mbox{)}$ occur +simultaneously. + +The most common approach (cite) is to reduce one input modulo another. That is if $a$ and $b$ are divisible by some integer $k$ and if $qa + r = b$ then +$r$ is also divisible by $k$. The reduction pattern follows $\left < a , b \right > \rightarrow \left < b, a \mbox{ mod } b \right >$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (I)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. While ($b > 0$) do \\ +\hspace{3mm}1.1 $r \leftarrow a \mbox{ (mod }b\mbox{)}$ \\ +\hspace{3mm}1.2 $a \leftarrow b$ \\ +\hspace{3mm}1.3 $b \leftarrow r$ \\ +2. Return($a$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (I)} +\label{fig:gcd1} +\end{figure} + +This algorithm will quickly converge on the greatest common divisor since the residue $r$ tends diminish rapidly. However, divisions are +relatively expensive operations to perform and should ideally be avoided. There is another approach based on a similar relationship of +greatest common divisors. The faster approach is based on the observation that if $k$ divides both $a$ and $b$ it will also divide $a - b$. +In particular, we would like $a - b$ to decrease in magnitude which implies that $b \ge a$. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (II)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. While ($b > 0$) do \\ +\hspace{3mm}1.1 Swap $a$ and $b$ such that $a$ is the smallest of the two. \\ +\hspace{3mm}1.2 $b \leftarrow b - a$ \\ +2. Return($a$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (II)} +\label{fig:gcd2} +\end{figure} + +\textbf{Proof} \textit{Algorithm~\ref{fig:gcd2} will return the greatest common divisor of $a$ and $b$.} +The algorithm in figure~\ref{fig:gcd2} will eventually terminate since $b \ge a$ the subtraction in step 1.2 will be a value less than $b$. In other +words in every iteration that tuple $\left < a, b \right >$ decrease in magnitude until eventually $a = b$. Since both $a$ and $b$ are always +divisible by the greatest common divisor (\textit{until the last iteration}) and in the last iteration of the algorithm $b = 0$, therefore, in the +second to last iteration of the algorithm $b = a$ and clearly $(a, a) = a$ which concludes the proof. \textbf{QED}. + +As a matter of practicality algorithm \ref{fig:gcd1} decreases far too slowly to be useful. Specially if $b$ is much larger than $a$ such that +$b - a$ is still very much larger than $a$. A simple addition to the algorithm is to divide $b - a$ by a power of some integer $p$ which does +not divide the greatest common divisor but will divide $b - a$. In this case ${b - a} \over p$ is also an integer and still divisible by +the greatest common divisor. + +However, instead of factoring $b - a$ to find a suitable value of $p$ the powers of $p$ can be removed from $a$ and $b$ that are in common first. +Then inside the loop whenever $b - a$ is divisible by some power of $p$ it can be safely removed. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (III)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. $k \leftarrow 0$ \\ +2. While $a$ and $b$ are both divisible by $p$ do \\ +\hspace{3mm}2.1 $a \leftarrow \lfloor a / p \rfloor$ \\ +\hspace{3mm}2.2 $b \leftarrow \lfloor b / p \rfloor$ \\ +\hspace{3mm}2.3 $k \leftarrow k + 1$ \\ +3. While $a$ is divisible by $p$ do \\ +\hspace{3mm}3.1 $a \leftarrow \lfloor a / p \rfloor$ \\ +4. While $b$ is divisible by $p$ do \\ +\hspace{3mm}4.1 $b \leftarrow \lfloor b / p \rfloor$ \\ +5. While ($b > 0$) do \\ +\hspace{3mm}5.1 Swap $a$ and $b$ such that $a$ is the smallest of the two. \\ +\hspace{3mm}5.2 $b \leftarrow b - a$ \\ +\hspace{3mm}5.3 While $b$ is divisible by $p$ do \\ +\hspace{6mm}5.3.1 $b \leftarrow \lfloor b / p \rfloor$ \\ +6. Return($a \cdot p^k$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (III)} +\label{fig:gcd3} +\end{figure} + +This algorithm is based on the first except it removes powers of $p$ first and inside the main loop to ensure the tuple $\left < a, b \right >$ +decreases more rapidly. The first loop on step two removes powers of $p$ that are in common. A count, $k$, is kept which will present a common +divisor of $p^k$. After step two the remaining common divisor of $a$ and $b$ cannot be divisible by $p$. This means that $p$ can be safely +divided out of the difference $b - a$ so long as the division leaves no remainder. + +In particular the value of $p$ should be chosen such that the division on step 5.3.1 occur often. It also helps that division by $p$ be easy +to compute. The ideal choice of $p$ is two since division by two amounts to a right logical shift. Another important observation is that by +step five both $a$ and $b$ are odd. Therefore, the diffrence $b - a$ must be even which means that each iteration removes one bit from the +largest of the pair. + +\subsection{Complete Greatest Common Divisor} +The algorithms presented so far cannot handle inputs which are zero or negative. The following algorithm can handle all input cases properly +and will produce the greatest common divisor. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_gcd}. \\ +\textbf{Input}. mp\_int $a$ and $b$ \\ +\textbf{Output}. The greatest common divisor $c = (a, b)$. \\ +\hline \\ +1. If $a = 0$ and $b \ne 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow b$ \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $a \ne 0$ and $b = 0$ then \\ +\hspace{3mm}2.1 $c \leftarrow a$ \\ +\hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ +3. If $a = b = 0$ then \\ +\hspace{3mm}3.1 $c \leftarrow 1$ \\ +\hspace{3mm}3.2 Return(\textit{MP\_OKAY}). \\ +4. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ +5. $k \leftarrow 0$ \\ +6. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}6.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}6.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +7. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +8. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}8.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +9. While $v.used > 0$ \\ +\hspace{3mm}9.1 If $\vert u \vert > \vert v \vert$ then \\ +\hspace{6mm}9.1.1 Swap $u$ and $v$. \\ +\hspace{3mm}9.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ +\hspace{3mm}9.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{6mm}9.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +10. $c \leftarrow u \cdot 2^k$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_gcd} +\end{figure} +\textbf{Algorithm mp\_gcd.} +This algorithm will produce the greatest common divisor of two mp\_ints $a$ and $b$. The algorithm was originally based on Algorithm B of +Knuth \cite[pp. 338]{TAOCPV2} but has been modified to be simpler to explain. In theory it achieves the same asymptotic working time as +Algorithm B and in practice this appears to be true. + +The first three steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the +largest input or zero if they are both zero. If the inputs are not trivial than $u$ and $v$ are assigned the absolute values of +$a$ and $b$ respectively and the algorithm will proceed to reduce the pair. + +Step six will divide out any common factors of two and keep track of the count in the variable $k$. After this step two is no longer a +factor of the remaining greatest common divisor between $u$ and $v$ and can be safely evenly divided out of either whenever they are even. Step +seven and eight ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while loops will iterate since +they cannot both be even. + +By step nine both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to +or greater than $u$. This ensures that the subtraction on step 9.2 will always produce a positive and even result. Step 9.3 removes any +factors of two from the difference $u$ to ensure that in the next iteration of the loop both are once again odd. + +After $v = 0$ occurs the variable $u$ has the greatest common divisor of the pair $\left < u, v \right >$ just after step six. The result +must be adjusted by multiplying by the common factors of two ($2^k$) removed earlier. + +EXAM,bn_mp_gcd.c + +This function makes use of the macros mp\_iszero and mp\_iseven. The former evaluates to $1$ if the input mp\_int is equivalent to the +integer zero otherwise it evaluates to $0$. The latter evaluates to $1$ if the input mp\_int represents a non-zero even integer otherwise +it evaluates to $0$. Note that just because mp\_iseven may evaluate to $0$ does not mean the input is odd, it could also be zero. The three +trivial cases of inputs are handled on lines @25,zero@ through @34,}@. After those lines the inputs are assumed to be non-zero. + +Lines @36,if@ and @40,if@ make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two +must be divided out of the two inputs. The while loop on line @49,while@ iterates so long as both are even. The local integer $k$ is used to +keep track of how many factors of $2$ are pulled out of both values. It is assumed that the number of factors will not exceed the maximum +value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than entries than are accessible by an ``int'' so this is not +a limitation.}. + +At this point there are no more common factors of two in the two values. The while loops on lines @60,while@ and @65,while@ remove any independent +factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop +on line @71, while@ performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in +place of the full signed routines since both values are guaranteed to be positive and the result of the subtraction is guaranteed to be non-negative. + +\section{Least Common Multiple} +The least common multiple of a pair of integers is their product divided by their greatest common divisor. For two integers $a$ and $b$ the +least common multiple is normally denoted as $[ a, b ]$ and numerically equivalent to ${ab} \over {(a, b)}$. For example, if $a = 2 \cdot 2 \cdot 3 = 12$ +and $b = 2 \cdot 3 \cdot 3 \cdot 7 = 126$ the least common multiple is ${126 \over {(12, 126)}} = {126 \over 6} = 21$. + +The least common multiple arises often in coding theory as well as number theory. If two functions have periods of $a$ and $b$ respectively they will +collide, that is be in synchronous states, after only $[ a, b ]$ iterations. This is why, for example, random number generators based on +Linear Feedback Shift Registers (LFSR) tend to use registers with periods which are co-prime (\textit{e.g. the greatest common divisor is one.}). +Similarly in number theory if a composite $n$ has two prime factors $p$ and $q$ then maximal order of any unit of $\Z/n\Z$ will be $[ p - 1, q - 1] $. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_lcm}. \\ +\textbf{Input}. mp\_int $a$ and $b$ \\ +\textbf{Output}. The least common multiple $c = [a, b]$. \\ +\hline \\ +1. $c \leftarrow (a, b)$ \\ +2. $t \leftarrow a \cdot b$ \\ +3. $c \leftarrow \lfloor t / c \rfloor$ \\ +4. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_lcm} +\end{figure} +\textbf{Algorithm mp\_lcm.} +This algorithm computes the least common multiple of two mp\_int inputs $a$ and $b$. It computes the least common multiple directly by +dividing the product of the two inputs by their greatest common divisor. + +EXAM,bn_mp_lcm.c + +\section{Jacobi Symbol Computation} +To explain the Jacobi Symbol we shall first discuss the Legendre function\footnote{Arrg. What is the name of this?} off which the Jacobi symbol is +defined. The Legendre function computes whether or not an integer $a$ is a quadratic residue modulo an odd prime $p$. Numerically it is +equivalent to equation \ref{eqn:legendre}. + +\begin{equation} +a^{(p-1)/2} \equiv \begin{array}{rl} + -1 & \mbox{if }a\mbox{ is a quadratic non-residue.} \\ + 0 & \mbox{if }a\mbox{ divides }p\mbox{.} \\ + 1 & \mbox{if }a\mbox{ is a quadratic residue}. + \end{array} \mbox{ (mod }p\mbox{)} +\label{eqn:legendre} +\end{equation} + +\textbf{Proof.} \textit{Equation \ref{eqn:legendre} correctly identifies the residue status of an integer $a$ modulo a prime $p$.} +An integer $a$ is a quadratic residue if the following equation has a solution. + +\begin{equation} +x^2 \equiv a \mbox{ (mod }p\mbox{)} +\label{eqn:root} +\end{equation} + +Consider the following equation. + +\begin{equation} +0 \equiv x^{p-1} - 1 \equiv \left \lbrace \left (x^2 \right )^{(p-1)/2} - a^{(p-1)/2} \right \rbrace + \left ( a^{(p-1)/2} - 1 \right ) \mbox{ (mod }p\mbox{)} +\label{eqn:rooti} +\end{equation} + +Whether equation \ref{eqn:root} has a solution or not equation \ref{eqn:rooti} is always true. If $a^{(p-1)/2} - 1 \equiv 0 \mbox{ (mod }p\mbox{)}$ +then the quantity in the braces must be zero. By reduction, + +\begin{eqnarray} +\left (x^2 \right )^{(p-1)/2} - a^{(p-1)/2} \equiv 0 \nonumber \\ +\left (x^2 \right )^{(p-1)/2} \equiv a^{(p-1)/2} \nonumber \\ +x^2 \equiv a \mbox{ (mod }p\mbox{)} +\end{eqnarray} + +As a result there must be a solution to the quadratic equation and in turn $a$ must be a quadratic residue. If $a$ does not divide $p$ and $a$ +is not a quadratic residue then the only other value $a^{(p-1)/2}$ may be congruent to is $-1$ since +\begin{equation} +0 \equiv a^{p - 1} - 1 \equiv (a^{(p-1)/2} + 1)(a^{(p-1)/2} - 1) \mbox{ (mod }p\mbox{)} +\end{equation} +One of the terms on the right hand side must be zero. \textbf{QED} + +\subsection{Jacobi Symbol} +The Jacobi symbol is a generalization of the Legendre function for any odd non prime moduli $p$ greater than 2. If $p = \prod_{i=0}^n p_i$ then +the Jacobi symbol $\left ( { a \over p } \right )$ is equal to the following equation. + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { a \over p_0} \right ) \left ( { a \over p_1} \right ) \ldots \left ( { a \over p_n} \right ) +\end{equation} + +By inspection if $p$ is prime the Jacobi symbol is equivalent to the Legendre function. The following facts\footnote{See HAC \cite[pp. 72-74]{HAC} for +further details.} will be used to derive an efficient Jacobi symbol algorithm. Where $p$ is an odd integer greater than two and $a, b \in \Z$ the +following are true. + +\begin{enumerate} +\item $\left ( { a \over p} \right )$ equals $-1$, $0$ or $1$. +\item $\left ( { ab \over p} \right ) = \left ( { a \over p} \right )\left ( { b \over p} \right )$. +\item If $a \equiv b$ then $\left ( { a \over p} \right ) = \left ( { b \over p} \right )$. +\item $\left ( { 2 \over p} \right )$ equals $1$ if $p \equiv 1$ or $7 \mbox{ (mod }8\mbox{)}$. Otherwise, it equals $-1$. +\item $\left ( { a \over p} \right ) \equiv \left ( { p \over a} \right ) \cdot (-1)^{(p-1)(a-1)/4}$. More specifically +$\left ( { a \over p} \right ) = \left ( { p \over a} \right )$ if $p \equiv a \equiv 1 \mbox{ (mod }4\mbox{)}$. +\end{enumerate} + +Using these facts if $a = 2^k \cdot a'$ then + +\begin{eqnarray} +\left ( { a \over p } \right ) = \left ( {{2^k} \over p } \right ) \left ( {a' \over p} \right ) \nonumber \\ + = \left ( {2 \over p } \right )^k \left ( {a' \over p} \right ) +\label{eqn:jacobi} +\end{eqnarray} + +By fact five, + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { p \over a } \right ) \cdot (-1)^{(p-1)(a-1)/4} +\end{equation} + +Subsequently by fact three since $p \equiv (p \mbox{ mod }a) \mbox{ (mod }a\mbox{)}$ then + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { {p \mbox{ mod } a} \over a } \right ) \cdot (-1)^{(p-1)(a-1)/4} +\end{equation} + +By putting both observations into equation \ref{eqn:jacobi} the following simplified equation is formed. + +\begin{equation} +\left ( { a \over p } \right ) = \left ( {2 \over p } \right )^k \left ( {{p\mbox{ mod }a'} \over a'} \right ) \cdot (-1)^{(p-1)(a'-1)/4} +\end{equation} + +The value of $\left ( {{p \mbox{ mod }a'} \over a'} \right )$ can be found by using the same equation recursively. The value of +$\left ( {2 \over p } \right )^k$ equals $1$ if $k$ is even otherwise it equals $\left ( {2 \over p } \right )$. Using this approach the +factors of $p$ do not have to be known. Furthermore, if $(a, p) = 1$ then the algorithm will terminate when the recursion requests the +Jacobi symbol computation of $\left ( {1 \over a'} \right )$ which is simply $1$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_jacobi}. \\ +\textbf{Input}. mp\_int $a$ and $p$, $a \ge 0$, $p \ge 3$, $p \equiv 1 \mbox{ (mod }2\mbox{)}$ \\ +\textbf{Output}. The Jacobi symbol $c = \left ( {a \over p } \right )$. \\ +\hline \\ +1. If $a = 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow 0$ \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $a = 1$ then \\ +\hspace{3mm}2.1 $c \leftarrow 1$ \\ +\hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ +3. $a' \leftarrow a$ \\ +4. $k \leftarrow 0$ \\ +5. While $a'.used > 0$ and $a'_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}5.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}5.2 $a' \leftarrow \lfloor a' / 2 \rfloor$ \\ +6. If $k \equiv 0 \mbox{ (mod }2\mbox{)}$ then \\ +\hspace{3mm}6.1 $s \leftarrow 1$ \\ +7. else \\ +\hspace{3mm}7.1 $r \leftarrow p_0 \mbox{ (mod }8\mbox{)}$ \\ +\hspace{3mm}7.2 If $r = 1$ or $r = 7$ then \\ +\hspace{6mm}7.2.1 $s \leftarrow 1$ \\ +\hspace{3mm}7.3 else \\ +\hspace{6mm}7.3.1 $s \leftarrow -1$ \\ +8. If $p_0 \equiv a'_0 \equiv 3 \mbox{ (mod }4\mbox{)}$ then \\ +\hspace{3mm}8.1 $s \leftarrow -s$ \\ +9. If $a' \ne 1$ then \\ +\hspace{3mm}9.1 $p' \leftarrow p \mbox{ (mod }a'\mbox{)}$ \\ +\hspace{3mm}9.2 $s \leftarrow s \cdot \mbox{mp\_jacobi}(p', a')$ \\ +10. $c \leftarrow s$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_jacobi} +\end{figure} +\textbf{Algorithm mp\_jacobi.} +This algorithm computes the Jacobi symbol for an arbitrary positive integer $a$ with respect to an odd integer $p$ greater than three. The algorithm +is based on algorithm 2.149 of HAC \cite[pp. 73]{HAC}. + +Step numbers one and two handle the trivial cases of $a = 0$ and $a = 1$ respectively. Step five determines the number of two factors in the +input $a$. If $k$ is even than the term $\left ( { 2 \over p } \right )^k$ must always evaluate to one. If $k$ is odd than the term evaluates to one +if $p_0$ is congruent to one or seven modulo eight, otherwise it evaluates to $-1$. After the the $\left ( { 2 \over p } \right )^k$ term is handled +the $(-1)^{(p-1)(a'-1)/4}$ is computed and multiplied against the current product $s$. The latter term evaluates to one if both $p$ and $a'$ +are congruent to one modulo four, otherwise it evaluates to negative one. + +By step nine if $a'$ does not equal one a recursion is required. Step 9.1 computes $p' \equiv p \mbox{ (mod }a'\mbox{)}$ and will recurse to compute +$\left ( {p' \over a'} \right )$ which is multiplied against the current Jacobi product. + +EXAM,bn_mp_jacobi.c + +As a matter of practicality the variable $a'$ as per the pseudo-code is reprensented by the variable $a1$ since the $'$ symbol is not valid for a C +variable name character. + +The two simple cases of $a = 0$ and $a = 1$ are handled at the very beginning to simplify the algorithm. If the input is non-trivial the algorithm +has to proceed compute the Jacobi. The variable $s$ is used to hold the current Jacobi product. Note that $s$ is merely a C ``int'' data type since +the values it may obtain are merely $-1$, $0$ and $1$. + +After a local copy of $a$ is made all of the factors of two are divided out and the total stored in $k$. Technically only the least significant +bit of $k$ is required, however, it makes the algorithm simpler to follow to perform an addition. In practice an exclusive-or and addition have the same +processor requirements and neither is faster than the other. + +Line @59, if@ through @70, }@ determines the value of $\left ( { 2 \over p } \right )^k$. If the least significant bit of $k$ is zero than +$k$ is even and the value is one. Otherwise, the value of $s$ depends on which residue class $p$ belongs to modulo eight. The value of +$(-1)^{(p-1)(a'-1)/4}$ is compute and multiplied against $s$ on lines @73, if@ through @75, }@. + +Finally, if $a1$ does not equal one the algorithm must recurse and compute $\left ( {p' \over a'} \right )$. + +\textit{-- Comment about default $s$ and such...} + +\section{Modular Inverse} +\label{sec:modinv} +The modular inverse of a number actually refers to the modular multiplicative inverse. Essentially for any integer $a$ such that $(a, p) = 1$ there +exist another integer $b$ such that $ab \equiv 1 \mbox{ (mod }p\mbox{)}$. The integer $b$ is called the multiplicative inverse of $a$ which is +denoted as $b = a^{-1}$. Technically speaking modular inversion is a well defined operation for any finite ring or field not just for rings and +fields of integers. However, the former will be the matter of discussion. + +The simplest approach is to compute the algebraic inverse of the input. That is to compute $b \equiv a^{\Phi(p) - 1}$. If $\Phi(p)$ is the +order of the multiplicative subgroup modulo $p$ then $b$ must be the multiplicative inverse of $a$. The proof of which is trivial. + +\begin{equation} +ab \equiv a \left (a^{\Phi(p) - 1} \right ) \equiv a^{\Phi(p)} \equiv a^0 \equiv 1 \mbox{ (mod }p\mbox{)} +\end{equation} + +However, as simple as this approach may be it has two serious flaws. It requires that the value of $\Phi(p)$ be known which if $p$ is composite +requires all of the prime factors. This approach also is very slow as the size of $p$ grows. + +A simpler approach is based on the observation that solving for the multiplicative inverse is equivalent to solving the linear +Diophantine\footnote{See LeVeque \cite[pp. 40-43]{LeVeque} for more information.} equation. + +\begin{equation} +ab + pq = 1 +\end{equation} + +Where $a$, $b$, $p$ and $q$ are all integers. If such a pair of integers $ \left < b, q \right >$ exist than $b$ is the multiplicative inverse of +$a$ modulo $p$. The extended Euclidean algorithm (Knuth \cite[pp. 342]{TAOCPV2}) can be used to solve such equations provided $(a, p) = 1$. +However, instead of using that algorithm directly a variant known as the binary Extended Euclidean algorithm will be used in its place. The +binary approach is very similar to the binary greatest common divisor algorithm except it will produce a full solution to the Diophantine +equation. + +\subsection{General Case} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_invmod}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $(a, b) = 1$, $p \ge 2$, $0 < a < p$. \\ +\textbf{Output}. The modular inverse $c \equiv a^{-1} \mbox{ (mod }b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then return(\textit{MP\_VAL}). \\ +2. If $b_0 \equiv 1 \mbox{ (mod }2\mbox{)}$ then use algorithm fast\_mp\_invmod. \\ +3. $x \leftarrow \vert a \vert, y \leftarrow b$ \\ +4. If $x_0 \equiv y_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ then return(\textit{MP\_VAL}). \\ +5. $B \leftarrow 0, C \leftarrow 0, A \leftarrow 1, D \leftarrow 1$ \\ +6. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}6.2 If ($A.used > 0$ and $A_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) or ($B.used > 0$ and $B_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) then \\ +\hspace{6mm}6.2.1 $A \leftarrow A + y$ \\ +\hspace{6mm}6.2.2 $B \leftarrow B - x$ \\ +\hspace{3mm}6.3 $A \leftarrow \lfloor A / 2 \rfloor$ \\ +\hspace{3mm}6.4 $B \leftarrow \lfloor B / 2 \rfloor$ \\ +7. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +\hspace{3mm}7.2 If ($C.used > 0$ and $C_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) or ($D.used > 0$ and $D_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) then \\ +\hspace{6mm}7.2.1 $C \leftarrow C + y$ \\ +\hspace{6mm}7.2.2 $D \leftarrow D - x$ \\ +\hspace{3mm}7.3 $C \leftarrow \lfloor C / 2 \rfloor$ \\ +\hspace{3mm}7.4 $D \leftarrow \lfloor D / 2 \rfloor$ \\ +8. If $u \ge v$ then \\ +\hspace{3mm}8.1 $u \leftarrow u - v$ \\ +\hspace{3mm}8.2 $A \leftarrow A - C$ \\ +\hspace{3mm}8.3 $B \leftarrow B - D$ \\ +9. else \\ +\hspace{3mm}9.1 $v \leftarrow v - u$ \\ +\hspace{3mm}9.2 $C \leftarrow C - A$ \\ +\hspace{3mm}9.3 $D \leftarrow D - B$ \\ +10. If $u \ne 0$ goto step 6. \\ +11. If $v \ne 1$ return(\textit{MP\_VAL}). \\ +12. While $C \le 0$ do \\ +\hspace{3mm}12.1 $C \leftarrow C + b$ \\ +13. While $C \ge b$ do \\ +\hspace{3mm}13.1 $C \leftarrow C - b$ \\ +14. $c \leftarrow C$ \\ +15. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\end{figure} +\textbf{Algorithm mp\_invmod.} +This algorithm computes the modular multiplicative inverse of an integer $a$ modulo an integer $b$. This algorithm is a variation of the +extended binary Euclidean algorithm from HAC \cite[pp. 608]{HAC}. It has been modified to only compute the modular inverse and not a complete +Diophantine solution. + +If $b \le 0$ than the modulus is invalid and MP\_VAL is returned. Similarly if both $a$ and $b$ are even then there cannot be a multiplicative +inverse for $a$ and the error is reported. + +The astute reader will observe that steps seven through nine are very similar to the binary greatest common divisor algorithm mp\_gcd. In this case +the other variables to the Diophantine equation are solved. The algorithm terminates when $u = 0$ in which case the solution is + +\begin{equation} +Ca + Db = v +\end{equation} + +If $v$, the greatest common divisor of $a$ and $b$ is not equal to one then the algorithm will report an error as no inverse exists. Otherwise, $C$ +is the modular inverse of $a$. The actual value of $C$ is congruent to, but not necessarily equal to, the ideal modular inverse which should lie +within $1 \le a^{-1} < b$. Step numbers twelve and thirteen adjust the inverse until it is in range. If the original input $a$ is within $0 < a < p$ +then only a couple of additions or subtractions will be required to adjust the inverse. + +EXAM,bn_mp_invmod.c + +\subsubsection{Odd Moduli} + +When the modulus $b$ is odd the variables $A$ and $C$ are fixed and are not required to compute the inverse. In particular by attempting to solve +the Diophantine $Cb + Da = 1$ only $B$ and $D$ are required to find the inverse of $a$. + +The algorithm fast\_mp\_invmod is a direct adaptation of algorithm mp\_invmod with all all steps involving either $A$ or $C$ removed. This +optimization will halve the time required to compute the modular inverse. + +\section{Primality Tests} + +A non-zero integer $a$ is said to be prime if it is not divisible by any other integer excluding one and itself. For example, $a = 7$ is prime +since the integers $2 \ldots 6$ do not evenly divide $a$. By contrast, $a = 6$ is not prime since $a = 6 = 2 \cdot 3$. + +Prime numbers arise in cryptography considerably as they allow finite fields to be formed. The ability to determine whether an integer is prime or +not quickly has been a viable subject in cryptography and number theory for considerable time. The algorithms that will be presented are all +probablistic algorithms in that when they report an integer is composite it must be composite. However, when the algorithms report an integer is +prime the algorithm may be incorrect. + +As will be discussed it is possible to limit the probability of error so well that for practical purposes the probablity of error might as +well be zero. For the purposes of these discussions let $n$ represent the candidate integer of which the primality is in question. + +\subsection{Trial Division} + +Trial division means to attempt to evenly divide a candidate integer by small prime integers. If the candidate can be evenly divided it obviously +cannot be prime. By dividing by all primes $1 < p \le \sqrt{n}$ this test can actually prove whether an integer is prime. However, such a test +would require a prohibitive amount of time as $n$ grows. + +Instead of dividing by every prime, a smaller, more mangeable set of primes may be used instead. By performing trial division with only a subset +of the primes less than $\sqrt{n} + 1$ the algorithm cannot prove if a candidate is prime. However, often it can prove a candidate is not prime. + +The benefit of this test is that trial division by small values is fairly efficient. Specially compared to the other algorithms that will be +discussed shortly. The probability that this approach correctly identifies a composite candidate when tested with all primes upto $q$ is given by +$1 - {1.12 \over ln(q)}$. The graph (\ref{pic:primality}, will be added later) demonstrates the probability of success for the range +$3 \le q \le 100$. + +At approximately $q = 30$ the gain of performing further tests diminishes fairly quickly. At $q = 90$ further testing is generally not going to +be of any practical use. In the case of LibTomMath the default limit $q = 256$ was chosen since it is not too high and will eliminate +approximately $80\%$ of all candidate integers. The constant \textbf{PRIME\_SIZE} is equal to the number of primes in the test base. The +array \_\_prime\_tab is an array of the first \textbf{PRIME\_SIZE} prime numbers. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_is\_divisible}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $c = 1$ if $n$ is divisible by a small prime, otherwise $c = 0$. \\ +\hline \\ +1. for $ix$ from $0$ to $PRIME\_SIZE$ do \\ +\hspace{3mm}1.1 $d \leftarrow n \mbox{ (mod }\_\_prime\_tab_{ix}\mbox{)}$ \\ +\hspace{3mm}1.2 If $d = 0$ then \\ +\hspace{6mm}1.2.1 $c \leftarrow 1$ \\ +\hspace{6mm}1.2.2 Return(\textit{MP\_OKAY}). \\ +2. $c \leftarrow 0$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_is\_divisible} +\end{figure} +\textbf{Algorithm mp\_prime\_is\_divisible.} +This algorithm attempts to determine if a candidate integer $n$ is composite by performing trial divisions. + +EXAM,bn_mp_prime_is_divisible.c + +The algorithm defaults to a return of $0$ in case an error occurs. The values in the prime table are all specified to be in the range of a +mp\_digit. The table \_\_prime\_tab is defined in the following file. + +EXAM,bn_prime_tab.c + +Note that there are two possible tables. When an mp\_digit is 7-bits long only the primes upto $127$ may be included, otherwise the primes +upto $1619$ are used. Note that the value of \textbf{PRIME\_SIZE} is a constant dependent on the size of a mp\_digit. + +\subsection{The Fermat Test} +The Fermat test is probably one the oldest tests to have a non-trivial probability of success. It is based on the fact that if $n$ is in +fact prime then $a^{n} \equiv a \mbox{ (mod }n\mbox{)}$ for all $0 < a < n$. The reason being that if $n$ is prime than the order of +the multiplicative sub group is $n - 1$. Any base $a$ must have an order which divides $n - 1$ and as such $a^n$ is equivalent to +$a^1 = a$. + +If $n$ is composite then any given base $a$ does not have to have a period which divides $n - 1$. In which case +it is possible that $a^n \nequiv a \mbox{ (mod }n\mbox{)}$. However, this test is not absolute as it is possible that the order +of a base will divide $n - 1$ which would then be reported as prime. Such a base yields what is known as a Fermat pseudo-prime. Several +integers known as Carmichael numbers will be a pseudo-prime to all valid bases. Fortunately such numbers are extremely rare as $n$ grows +in size. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_fermat}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $a \ge 2$, $0 < b < a$. \\ +\textbf{Output}. $c = 1$ if $b^a \equiv b \mbox{ (mod }a\mbox{)}$, otherwise $c = 0$. \\ +\hline \\ +1. $t \leftarrow b^a \mbox{ (mod }a\mbox{)}$ \\ +2. If $t = b$ then \\ +\hspace{3mm}2.1 $c = 1$ \\ +3. else \\ +\hspace{3mm}3.1 $c = 0$ \\ +4. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_fermat} +\end{figure} +\textbf{Algorithm mp\_prime\_fermat.} +This algorithm determines whether an mp\_int $a$ is a Fermat prime to the base $b$ or not. It uses a single modular exponentiation to +determine the result. + +EXAM,bn_mp_prime_fermat.c + +\subsection{The Miller-Rabin Test} +The Miller-Rabin (citation) test is another primality test which has tighter error bounds than the Fermat test specifically with sequentially chosen +candidate integers. The algorithm is based on the observation that if $n - 1 = 2^kr$ and if $b^r \nequiv \pm 1$ then after upto $k - 1$ squarings the +value must be equal to $-1$. The squarings are stopped as soon as $-1$ is observed. If the value of $1$ is observed first it means that +some value not congruent to $\pm 1$ when squared equals one which cannot occur if $n$ is prime. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_miller\_rabin}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $a \ge 2$, $0 < b < a$. \\ +\textbf{Output}. $c = 1$ if $a$ is a Miller-Rabin prime to the base $a$, otherwise $c = 0$. \\ +\hline +1. $a' \leftarrow a - 1$ \\ +2. $r \leftarrow n1$ \\ +3. $c \leftarrow 0, s \leftarrow 0$ \\ +4. While $r.used > 0$ and $r_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}4.1 $s \leftarrow s + 1$ \\ +\hspace{3mm}4.2 $r \leftarrow \lfloor r / 2 \rfloor$ \\ +5. $y \leftarrow b^r \mbox{ (mod }a\mbox{)}$ \\ +6. If $y \nequiv \pm 1$ then \\ +\hspace{3mm}6.1 $j \leftarrow 1$ \\ +\hspace{3mm}6.2 While $j \le (s - 1)$ and $y \nequiv a'$ \\ +\hspace{6mm}6.2.1 $y \leftarrow y^2 \mbox{ (mod }a\mbox{)}$ \\ +\hspace{6mm}6.2.2 If $y = 1$ then goto step 8. \\ +\hspace{6mm}6.2.3 $j \leftarrow j + 1$ \\ +\hspace{3mm}6.3 If $y \nequiv a'$ goto step 8. \\ +7. $c \leftarrow 1$\\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_miller\_rabin} +\end{figure} +\textbf{Algorithm mp\_prime\_miller\_rabin.} +This algorithm performs one trial round of the Miller-Rabin algorithm to the base $b$. It will set $c = 1$ if the algorithm cannot determine +if $b$ is composite or $c = 0$ if $b$ is provably composite. The values of $s$ and $r$ are computed such that $a' = a - 1 = 2^sr$. + +If the value $y \equiv b^r$ is congruent to $\pm 1$ then the algorithm cannot prove if $a$ is composite or not. Otherwise, the algorithm will +square $y$ upto $s - 1$ times stopping only when $y \equiv -1$. If $y^2 \equiv 1$ and $y \nequiv \pm 1$ then the algorithm can report that $a$ +is provably composite. If the algorithm performs $s - 1$ squarings and $y \nequiv -1$ then $a$ is provably composite. If $a$ is not provably +composite then it is \textit{probably} prime. + +EXAM,bn_mp_prime_miller_rabin.c + + + + +\backmatter +\appendix +\begin{thebibliography}{ABCDEF} +\bibitem[1]{TAOCPV2} +Donald Knuth, \textit{The Art of Computer Programming}, Third Edition, Volume Two, Seminumerical Algorithms, Addison-Wesley, 1998 + +\bibitem[2]{HAC} +A. Menezes, P. van Oorschot, S. Vanstone, \textit{Handbook of Applied Cryptography}, CRC Press, 1996 + +\bibitem[3]{ROSE} +Michael Rosing, \textit{Implementing Elliptic Curve Cryptography}, Manning Publications, 1999 + +\bibitem[4]{COMBA} +Paul G. Comba, \textit{Exponentiation Cryptosystems on the IBM PC}. IBM Systems Journal 29(4): 526-538 (1990) + +\bibitem[5]{KARA} +A. Karatsuba, Doklay Akad. Nauk SSSR 145 (1962), pp.293-294 + +\bibitem[6]{KARAP} +Andre Weimerskirch and Christof Paar, \textit{Generalizations of the Karatsuba Algorithm for Polynomial Multiplication}, Submitted to Design, Codes and Cryptography, March 2002 + +\bibitem[7]{BARRETT} +Paul Barrett, \textit{Implementing the Rivest Shamir and Adleman Public Key Encryption Algorithm on a Standard Digital Signal Processor}, Advances in Cryptology, Crypto '86, Springer-Verlag. + +\bibitem[8]{MONT} +P.L.Montgomery. \textit{Modular multiplication without trial division}. Mathematics of Computation, 44(170):519-521, April 1985. + +\bibitem[9]{DRMET} +Chae Hoon Lim and Pil Joong Lee, \textit{Generating Efficient Primes for Discrete Log Cryptosystems}, POSTECH Information Research Laboratories + +\bibitem[10]{MMB} +J. Daemen and R. Govaerts and J. Vandewalle, \textit{Block ciphers based on Modular Arithmetic}, State and {P}rogress in the {R}esearch of {C}ryptography, 1993, pp. 80-89 + +\bibitem[11]{RSAREF} +R.L. Rivest, A. Shamir, L. Adleman, \textit{A Method for Obtaining Digital Signatures and Public-Key Cryptosystems} + +\bibitem[12]{DHREF} +Whitfield Diffie, Martin E. Hellman, \textit{New Directions in Cryptography}, IEEE Transactions on Information Theory, 1976 + +\bibitem[13]{IEEE} +IEEE Standard for Binary Floating-Point Arithmetic (ANSI/IEEE Std 754-1985) + +\bibitem[14]{GMP} +GNU Multiple Precision (GMP), \url{http://www.swox.com/gmp/} + +\bibitem[15]{MPI} +Multiple Precision Integer Library (MPI), Michael Fromberger, \url{http://thayer.dartmouth.edu/~sting/mpi/} + +\bibitem[16]{OPENSSL} +OpenSSL Cryptographic Toolkit, \url{http://openssl.org} + +\bibitem[17]{LIP} +Large Integer Package, \url{http://home.hetnet.nl/~ecstr/LIP.zip} + +\bibitem[18]{ISOC} +JTC1/SC22/WG14, ISO/IEC 9899:1999, ``A draft rationale for the C99 standard.'' + +\bibitem[19]{JAVA} +The Sun Java Website, \url{http://java.sun.com/} + +\end{thebibliography} + +\input{tommath.ind} + +\end{document} diff --git a/libtommath/tommath.tex b/libtommath/tommath.tex new file mode 100644 index 0000000..9c4dc82 --- /dev/null +++ b/libtommath/tommath.tex @@ -0,0 +1,10771 @@ +\documentclass[b5paper]{book} +\usepackage{hyperref} +\usepackage{makeidx} +\usepackage{amssymb} +\usepackage{color} +\usepackage{alltt} +\usepackage{graphicx} +\usepackage{layout} +\def\union{\cup} +\def\intersect{\cap} +\def\getsrandom{\stackrel{\rm R}{\gets}} +\def\cross{\times} +\def\cat{\hspace{0.5em} \| \hspace{0.5em}} +\def\catn{$\|$} +\def\divides{\hspace{0.3em} | \hspace{0.3em}} +\def\nequiv{\not\equiv} +\def\approx{\raisebox{0.2ex}{\mbox{\small $\sim$}}} +\def\lcm{{\rm lcm}} +\def\gcd{{\rm gcd}} +\def\log{{\rm log}} +\def\ord{{\rm ord}} +\def\abs{{\mathit abs}} +\def\rep{{\mathit rep}} +\def\mod{{\mathit\ mod\ }} +\renewcommand{\pmod}[1]{\ ({\rm mod\ }{#1})} +\newcommand{\floor}[1]{\left\lfloor{#1}\right\rfloor} +\newcommand{\ceil}[1]{\left\lceil{#1}\right\rceil} +\def\Or{{\rm\ or\ }} +\def\And{{\rm\ and\ }} +\def\iff{\hspace{1em}\Longleftrightarrow\hspace{1em}} +\def\implies{\Rightarrow} +\def\undefined{{\rm ``undefined"}} +\def\Proof{\vspace{1ex}\noindent {\bf Proof:}\hspace{1em}} +\let\oldphi\phi +\def\phi{\varphi} +\def\Pr{{\rm Pr}} +\newcommand{\str}[1]{{\mathbf{#1}}} +\def\F{{\mathbb F}} +\def\N{{\mathbb N}} +\def\Z{{\mathbb Z}} +\def\R{{\mathbb R}} +\def\C{{\mathbb C}} +\def\Q{{\mathbb Q}} +\definecolor{DGray}{gray}{0.5} +\newcommand{\emailaddr}[1]{\mbox{$<${#1}$>$}} +\def\twiddle{\raisebox{0.3ex}{\mbox{\tiny $\sim$}}} +\def\gap{\vspace{0.5ex}} +\makeindex +\begin{document} +\frontmatter +\pagestyle{empty} +\title{Implementing Multiple Precision Arithmetic \\ ~ \\ Draft Edition } +\author{\mbox{ +%\begin{small} +\begin{tabular}{c} +Tom St Denis \\ +Algonquin College \\ +\\ +Mads Rasmussen \\ +Open Communications Security \\ +\\ +Greg Rose \\ +QUALCOMM Australia \\ +\end{tabular} +%\end{small} +} +} +\maketitle +This text has been placed in the public domain. This text corresponds to the v0.30 release of the +LibTomMath project. + +\begin{alltt} +Tom St Denis +111 Banning Rd +Ottawa, Ontario +K2L 1C3 +Canada + +Phone: 1-613-836-3160 +Email: tomstdenis@iahu.ca +\end{alltt} + +This text is formatted to the international B5 paper size of 176mm wide by 250mm tall using the \LaTeX{} +{\em book} macro package and the Perl {\em booker} package. + +\tableofcontents +\listoffigures +\chapter*{Prefaces to the Draft Edition} +I started this text in April 2003 to complement my LibTomMath library. That is, explain how to implement the functions +contained in LibTomMath. The goal is to have a textbook that any Computer Science student can use when implementing their +own multiple precision arithmetic. The plan I wanted to follow was flesh out all the +ideas and concepts I had floating around in my head and then work on it afterwards refining a little bit at a time. Chance +would have it that I ended up with my summer off from Algonquin College and I was given four months solid to work on the +text. + +Choosing to not waste any time I dove right into the project even before my spring semester was finished. I wrote a bit +off and on at first. The moment my exams were finished I jumped into long 12 to 16 hour days. The result after only +a couple of months was a ten chapter, three hundred page draft that I quickly had distributed to anyone who wanted +to read it. I had Jean-Luc Cooke print copies for me and I brought them to Crypto'03 in Santa Barbara. So far I have +managed to grab a certain level of attention having people from around the world ask me for copies of the text was certain +rewarding. + +Now we are past December 2003. By this time I had pictured that I would have at least finished my second draft of the text. +Currently I am far off from this goal. I've done partial re-writes of chapters one, two and three but they are not even +finished yet. I haven't given up on the project, only had some setbacks. First O'Reilly declined to publish the text then +Addison-Wesley and Greg is tried another which I don't know the name of. However, at this point I want to focus my energy +onto finishing the book not securing a contract. + +So why am I writing this text? It seems like a lot of work right? Most certainly it is a lot of work writing a textbook. +Even the simplest introductory material has to be lined with references and figures. A lot of the text has to be re-written +from point form to prose form to ensure an easier read. Why am I doing all this work for free then? Simple. My philosophy +is quite simply ``Open Source. Open Academia. Open Minds'' which means that to achieve a goal of open minds, that is, +people willing to accept new ideas and explore the unknown you have to make available material they can access freely +without hinderance. + +I've been writing free software since I was about sixteen but only recently have I hit upon software that people have come +to depend upon. I started LibTomCrypt in December 2001 and now several major companies use it as integral portions of their +software. Several educational institutions use it as a matter of course and many freelance developers use it as +part of their projects. To further my contributions I started the LibTomMath project in December 2002 aimed at providing +multiple precision arithmetic routines that students could learn from. That is write routines that are not only easy +to understand and follow but provide quite impressive performance considering they are all in standard portable ISO C. + +The second leg of my philosophy is ``Open Academia'' which is where this textbook comes in. In the end, when all is +said and done the text will be useable by educational institutions as a reference on multiple precision arithmetic. + +At this time I feel I should share a little information about myself. The most common question I was asked at +Crypto'03, perhaps just out of professional courtesy, was which school I either taught at or attended. The unfortunate +truth is that I neither teach at or attend a school of academic reputation. I'm currently at Algonquin College which +is what I'd like to call ``somewhat academic but mostly vocational'' college. In otherwords, job training. + +I'm a 21 year old computer science student mostly self-taught in the areas I am aware of (which includes a half-dozen +computer science fields, a few fields of mathematics and some English). I look forward to teaching someday but I am +still far off from that goal. + +Now it would be improper for me to not introduce the rest of the texts co-authors. While they are only contributing +corrections and editorial feedback their support has been tremendously helpful in presenting the concepts laid out +in the text so far. Greg has always been there for me. He has tracked my LibTom projects since their inception and even +sent cheques to help pay tuition from time to time. His background has provided a wonderful source to bounce ideas off +of and improve the quality of my writing. Mads is another fellow who has just ``been there''. I don't even recall what +his interest in the LibTom projects is but I'm definitely glad he has been around. His ability to catch logical errors +in my written English have saved me on several occasions to say the least. + +What to expect next? Well this is still a rough draft. I've only had the chance to update a few chapters. However, I've +been getting the feeling that people are starting to use my text and I owe them some updated material. My current tenative +plan is to edit one chapter every two weeks starting January 4th. It seems insane but my lower course load at college +should provide ample time. By Crypto'04 I plan to have a 2nd draft of the text polished and ready to hand out to as many +people who will take it. + +\begin{flushright} Tom St Denis \end{flushright} + +\newpage +I found the opportunity to work with Tom appealing for several reasons, not only could I broaden my own horizons, but also +contribute to educate others facing the problem of having to handle big number mathematical calculations. + +This book is Tom's child and he has been caring and fostering the project ever since the beginning with a clear mind of +how he wanted the project to turn out. I have helped by proofreading the text and we have had several discussions about +the layout and language used. + +I hold a masters degree in cryptography from the University of Southern Denmark and have always been interested in the +practical aspects of cryptography. + +Having worked in the security consultancy business for several years in S\~{a}o Paulo, Brazil, I have been in touch with a +great deal of work in which multiple precision mathematics was needed. Understanding the possibilities for speeding up +multiple precision calculations is often very important since we deal with outdated machine architecture where modular +reductions, for example, become painfully slow. + +This text is for people who stop and wonder when first examining algorithms such as RSA for the first time and asks +themselves, ``You tell me this is only secure for large numbers, fine; but how do you implement these numbers?'' + +\begin{flushright} +Mads Rasmussen + +S\~{a}o Paulo - SP + +Brazil +\end{flushright} + +\newpage +It's all because I broke my leg. That just happened to be at about the same time that Tom asked for someone to review the section of the book about +Karatsuba multiplication. I was laid up, alone and immobile, and thought ``Why not?'' I vaguely knew what Karatsuba multiplication was, but not +really, so I thought I could help, learn, and stop myself from watching daytime cable TV, all at once. + +At the time of writing this, I've still not met Tom or Mads in meatspace. I've been following Tom's progress since his first splash on the +sci.crypt Usenet news group. I watched him go from a clueless newbie, to the cryptographic equivalent of a reformed smoker, to a real +contributor to the field, over a period of about two years. I've been impressed with his obvious intelligence, and astounded by his productivity. +Of course, he's young enough to be my own child, so he doesn't have my problems with staying awake. + +When I reviewed that single section of the book, in its very earliest form, I was very pleasantly surprised. So I decided to collaborate more fully, +and at least review all of it, and perhaps write some bits too. There's still a long way to go with it, and I have watched a number of close +friends go through the mill of publication, so I think that the way to go is longer than Tom thinks it is. Nevertheless, it's a good effort, +and I'm pleased to be involved with it. + +\begin{flushright} +Greg Rose, Sydney, Australia, June 2003. +\end{flushright} + +\mainmatter +\pagestyle{headings} +\chapter{Introduction} +\section{Multiple Precision Arithmetic} + +\subsection{What is Multiple Precision Arithmetic?} +When we think of long-hand arithmetic such as addition or multiplication we rarely consider the fact that we instinctively +raise or lower the precision of the numbers we are dealing with. For example, in decimal we almost immediate can +reason that $7$ times $6$ is $42$. However, $42$ has two digits of precision as opposed to one digit we started with. +Further multiplications of say $3$ result in a larger precision result $126$. In these few examples we have multiple +precisions for the numbers we are working with. Despite the various levels of precision a single subset\footnote{With the occasional optimization.} + of algorithms can be designed to accomodate them. + +By way of comparison a fixed or single precision operation would lose precision on various operations. For example, in +the decimal system with fixed precision $6 \cdot 7 = 2$. + +Essentially at the heart of computer based multiple precision arithmetic are the same long-hand algorithms taught in +schools to manually add, subtract, multiply and divide. + +\subsection{The Need for Multiple Precision Arithmetic} +The most prevalent need for multiple precision arithmetic, often referred to as ``bignum'' math, is within the implementation +of public-key cryptography algorithms. Algorithms such as RSA \cite{RSAREF} and Diffie-Hellman \cite{DHREF} require +integers of significant magnitude to resist known cryptanalytic attacks. For example, at the time of this writing a +typical RSA modulus would be at least greater than $10^{309}$. However, modern programming languages such as ISO C \cite{ISOC} and +Java \cite{JAVA} only provide instrinsic support for integers which are relatively small and single precision. + +\begin{figure}[!here] +\begin{center} +\begin{tabular}{|r|c|} +\hline \textbf{Data Type} & \textbf{Range} \\ +\hline char & $-128 \ldots 127$ \\ +\hline short & $-32768 \ldots 32767$ \\ +\hline long & $-2147483648 \ldots 2147483647$ \\ +\hline long long & $-9223372036854775808 \ldots 9223372036854775807$ \\ +\hline +\end{tabular} +\end{center} +\caption{Typical Data Types for the C Programming Language} +\label{fig:ISOC} +\end{figure} + +The largest data type guaranteed to be provided by the ISO C programming +language\footnote{As per the ISO C standard. However, each compiler vendor is allowed to augment the precision as they +see fit.} can only represent values up to $10^{19}$ as shown in figure \ref{fig:ISOC}. On its own the C language is +insufficient to accomodate the magnitude required for the problem at hand. An RSA modulus of magnitude $10^{19}$ could be +trivially factored\footnote{A Pollard-Rho factoring would take only $2^{16}$ time.} on the average desktop computer, +rendering any protocol based on the algorithm insecure. Multiple precision algorithms solve this very problem by +extending the range of representable integers while using single precision data types. + +Most advancements in fast multiple precision arithmetic stem from the need for faster and more efficient cryptographic +primitives. Faster modular reduction and exponentiation algorithms such as Barrett's algorithm, which have appeared in +various cryptographic journals, can render algorithms such as RSA and Diffie-Hellman more efficient. In fact, several +major companies such as RSA Security, Certicom and Entrust have built entire product lines on the implementation and +deployment of efficient algorithms. + +However, cryptography is not the only field of study that can benefit from fast multiple precision integer routines. +Another auxiliary use of multiple precision integers is high precision floating point data types. +The basic IEEE \cite{IEEE} standard floating point type is made up of an integer mantissa $q$, an exponent $e$ and a sign bit $s$. +Numbers are given in the form $n = q \cdot b^e \cdot -1^s$ where $b = 2$ is the most common base for IEEE. Since IEEE +floating point is meant to be implemented in hardware the precision of the mantissa is often fairly small +(\textit{23, 48 and 64 bits}). The mantissa is merely an integer and a multiple precision integer could be used to create +a mantissa of much larger precision than hardware alone can efficiently support. This approach could be useful where +scientific applications must minimize the total output error over long calculations. + +Yet another use for large integers is within arithmetic on polynomials of large characteristic (i.e. $GF(p)[x]$ for large $p$). +In fact the library discussed within this text has already been used to form a polynomial basis library\footnote{See \url{http://poly.libtomcrypt.org} for more details.}. + +\subsection{Benefits of Multiple Precision Arithmetic} +\index{precision} +The benefit of multiple precision representations over single or fixed precision representations is that +no precision is lost while representing the result of an operation which requires excess precision. For example, +the product of two $n$-bit integers requires at least $2n$ bits of precision to be represented faithfully. A multiple +precision algorithm would augment the precision of the destination to accomodate the result while a single precision system +would truncate excess bits to maintain a fixed level of precision. + +It is possible to implement algorithms which require large integers with fixed precision algorithms. For example, elliptic +curve cryptography (\textit{ECC}) is often implemented on smartcards by fixing the precision of the integers to the maximum +size the system will ever need. Such an approach can lead to vastly simpler algorithms which can accomodate the +integers required even if the host platform cannot natively accomodate them\footnote{For example, the average smartcard +processor has an 8 bit accumulator.}. However, as efficient as such an approach may be, the resulting source code is not +normally very flexible. It cannot, at runtime, accomodate inputs of higher magnitude than the designer anticipated. + +Multiple precision algorithms have the most overhead of any style of arithmetic. For the the most part the +overhead can be kept to a minimum with careful planning, but overall, it is not well suited for most memory starved +platforms. However, multiple precision algorithms do offer the most flexibility in terms of the magnitude of the +inputs. That is, the same algorithms based on multiple precision integers can accomodate any reasonable size input +without the designer's explicit forethought. This leads to lower cost of ownership for the code as it only has to +be written and tested once. + +\section{Purpose of This Text} +The purpose of this text is to instruct the reader regarding how to implement efficient multiple precision algorithms. +That is to not only explain a limited subset of the core theory behind the algorithms but also the various ``house keeping'' +elements that are neglected by authors of other texts on the subject. Several well reknowned texts \cite{TAOCPV2,HAC} +give considerably detailed explanations of the theoretical aspects of algorithms and often very little information +regarding the practical implementation aspects. + +In most cases how an algorithm is explained and how it is actually implemented are two very different concepts. For +example, the Handbook of Applied Cryptography (\textit{HAC}), algorithm 14.7 on page 594, gives a relatively simple +algorithm for performing multiple precision integer addition. However, the description lacks any discussion concerning +the fact that the two integer inputs may be of differing magnitudes. As a result the implementation is not as simple +as the text would lead people to believe. Similarly the division routine (\textit{algorithm 14.20, pp. 598}) does not +discuss how to handle sign or handle the dividend's decreasing magnitude in the main loop (\textit{step \#3}). + +Both texts also do not discuss several key optimal algorithms required such as ``Comba'' and Karatsuba multipliers +and fast modular inversion, which we consider practical oversights. These optimal algorithms are vital to achieve +any form of useful performance in non-trivial applications. + +To solve this problem the focus of this text is on the practical aspects of implementing a multiple precision integer +package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.org}} package is used +to demonstrate algorithms with real implementations\footnote{In the ISO C programming language.} that have been field +tested and work very well. The LibTomMath library is freely available on the Internet for all uses and this text +discusses a very large portion of the inner workings of the library. + +The algorithms that are presented will always include at least one ``pseudo-code'' description followed +by the actual C source code that implements the algorithm. The pseudo-code can be used to implement the same +algorithm in other programming languages as the reader sees fit. + +This text shall also serve as a walkthrough of the creation of multiple precision algorithms from scratch. Showing +the reader how the algorithms fit together as well as where to start on various taskings. + +\section{Discussion and Notation} +\subsection{Notation} +A multiple precision integer of $n$-digits shall be denoted as $x = (x_{n-1}, \ldots, x_1, x_0)_{ \beta }$ and represent +the integer $x \equiv \sum_{i=0}^{n-1} x_i\beta^i$. The elements of the array $x$ are said to be the radix $\beta$ digits +of the integer. For example, $x = (1,2,3)_{10}$ would represent the integer +$1\cdot 10^2 + 2\cdot10^1 + 3\cdot10^0 = 123$. + +\index{mp\_int} +The term ``mp\_int'' shall refer to a composite structure which contains the digits of the integer it represents, as well +as auxilary data required to manipulate the data. These additional members are discussed further in section +\ref{sec:MPINT}. For the purposes of this text a ``multiple precision integer'' and an ``mp\_int'' are assumed to be +synonymous. When an algorithm is specified to accept an mp\_int variable it is assumed the various auxliary data members +are present as well. An expression of the type \textit{variablename.item} implies that it should evaluate to the +member named ``item'' of the variable. For example, a string of characters may have a member ``length'' which would +evaluate to the number of characters in the string. If the string $a$ equals ``hello'' then it follows that +$a.length = 5$. + +For certain discussions more generic algorithms are presented to help the reader understand the final algorithm used +to solve a given problem. When an algorithm is described as accepting an integer input it is assumed the input is +a plain integer with no additional multiple-precision members. That is, algorithms that use integers as opposed to +mp\_ints as inputs do not concern themselves with the housekeeping operations required such as memory management. These +algorithms will be used to establish the relevant theory which will subsequently be used to describe a multiple +precision algorithm to solve the same problem. + +\subsection{Precision Notation} +The variable $\beta$ represents the radix of a single digit of a multiple precision integer and +must be of the form $q^p$ for $q, p \in \Z^+$. A single precision variable must be able to represent integers in +the range $0 \le x < q \beta$ while a double precision variable must be able to represent integers in the range +$0 \le x < q \beta^2$. The extra radix-$q$ factor allows additions and subtractions to proceed without truncation of the +carry. Since all modern computers are binary, it is assumed that $q$ is two. + +\index{mp\_digit} \index{mp\_word} +Within the source code that will be presented for each algorithm, the data type \textbf{mp\_digit} will represent +a single precision integer type, while, the data type \textbf{mp\_word} will represent a double precision integer type. In +several algorithms (notably the Comba routines) temporary results will be stored in arrays of double precision mp\_words. +For the purposes of this text $x_j$ will refer to the $j$'th digit of a single precision array and $\hat x_j$ will refer to +the $j$'th digit of a double precision array. Whenever an expression is to be assigned to a double precision +variable it is assumed that all single precision variables are promoted to double precision during the evaluation. +Expressions that are assigned to a single precision variable are truncated to fit within the precision of a single +precision data type. + +For example, if $\beta = 10^2$ a single precision data type may represent a value in the +range $0 \le x < 10^3$, while a double precision data type may represent a value in the range $0 \le x < 10^5$. Let +$a = 23$ and $b = 49$ represent two single precision variables. The single precision product shall be written +as $c \leftarrow a \cdot b$ while the double precision product shall be written as $\hat c \leftarrow a \cdot b$. +In this particular case, $\hat c = 1127$ and $c = 127$. The most significant digit of the product would not fit +in a single precision data type and as a result $c \ne \hat c$. + +\subsection{Algorithm Inputs and Outputs} +Within the algorithm descriptions all variables are assumed to be scalars of either single or double precision +as indicated. The only exception to this rule is when variables have been indicated to be of type mp\_int. This +distinction is important as scalars are often used as array indicies and various other counters. + +\subsection{Mathematical Expressions} +The $\lfloor \mbox{ } \rfloor$ brackets imply an expression truncated to an integer not greater than the expression +itself. For example, $\lfloor 5.7 \rfloor = 5$. Similarly the $\lceil \mbox{ } \rceil$ brackets imply an expression +rounded to an integer not less than the expression itself. For example, $\lceil 5.1 \rceil = 6$. Typically when +the $/$ division symbol is used the intention is to perform an integer division with truncation. For example, +$5/2 = 2$ which will often be written as $\lfloor 5/2 \rfloor = 2$ for clarity. When an expression is written as a +fraction a real value division is implied, for example ${5 \over 2} = 2.5$. + +The norm of a multiple precision integer, for example $\vert \vert x \vert \vert$, will be used to represent the number of digits in the representation +of the integer. For example, $\vert \vert 123 \vert \vert = 3$ and $\vert \vert 79452 \vert \vert = 5$. + +\subsection{Work Effort} +\index{big-Oh} +To measure the efficiency of the specified algorithms, a modified big-Oh notation is used. In this system all +single precision operations are considered to have the same cost\footnote{Except where explicitly noted.}. +That is a single precision addition, multiplication and division are assumed to take the same time to +complete. While this is generally not true in practice, it will simplify the discussions considerably. + +Some algorithms have slight advantages over others which is why some constants will not be removed in +the notation. For example, a normal baseline multiplication (section \ref{sec:basemult}) requires $O(n^2)$ work while a +baseline squaring (section \ref{sec:basesquare}) requires $O({{n^2 + n}\over 2})$ work. In standard big-Oh notation these +would both be said to be equivalent to $O(n^2)$. However, +in the context of the this text this is not the case as the magnitude of the inputs will typically be rather small. As a +result small constant factors in the work effort will make an observable difference in algorithm efficiency. + +All of the algorithms presented in this text have a polynomial time work level. That is, of the form +$O(n^k)$ for $n, k \in \Z^{+}$. This will help make useful comparisons in terms of the speed of the algorithms and how +various optimizations will help pay off in the long run. + +\section{Exercises} +Within the more advanced chapters a section will be set aside to give the reader some challenging exercises related to +the discussion at hand. These exercises are not designed to be prize winning problems, but instead to be thought +provoking. Wherever possible the problems are forward minded, stating problems that will be answered in subsequent +chapters. The reader is encouraged to finish the exercises as they appear to get a better understanding of the +subject material. + +That being said, the problems are designed to affirm knowledge of a particular subject matter. Students in particular +are encouraged to verify they can answer the problems correctly before moving on. + +Similar to the exercises of \cite[pp. ix]{TAOCPV2} these exercises are given a scoring system based on the difficulty of +the problem. However, unlike \cite{TAOCPV2} the problems do not get nearly as hard. The scoring of these +exercises ranges from one (the easiest) to five (the hardest). The following table sumarizes the +scoring system used. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|l|} +\hline $\left [ 1 \right ]$ & An easy problem that should only take the reader a manner of \\ + & minutes to solve. Usually does not involve much computer time \\ + & to solve. \\ +\hline $\left [ 2 \right ]$ & An easy problem that involves a marginal amount of computer \\ + & time usage. Usually requires a program to be written to \\ + & solve the problem. \\ +\hline $\left [ 3 \right ]$ & A moderately hard problem that requires a non-trivial amount \\ + & of work. Usually involves trivial research and development of \\ + & new theory from the perspective of a student. \\ +\hline $\left [ 4 \right ]$ & A moderately hard problem that involves a non-trivial amount \\ + & of work and research, the solution to which will demonstrate \\ + & a higher mastery of the subject matter. \\ +\hline $\left [ 5 \right ]$ & A hard problem that involves concepts that are difficult for a \\ + & novice to solve. Solutions to these problems will demonstrate a \\ + & complete mastery of the given subject. \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Exercise Scoring System} +\end{figure} + +Problems at the first level are meant to be simple questions that the reader can answer quickly without programming a solution or +devising new theory. These problems are quick tests to see if the material is understood. Problems at the second level +are also designed to be easy but will require a program or algorithm to be implemented to arrive at the answer. These +two levels are essentially entry level questions. + +Problems at the third level are meant to be a bit more difficult than the first two levels. The answer is often +fairly obvious but arriving at an exacting solution requires some thought and skill. These problems will almost always +involve devising a new algorithm or implementing a variation of another algorithm previously presented. Readers who can +answer these questions will feel comfortable with the concepts behind the topic at hand. + +Problems at the fourth level are meant to be similar to those of the level three questions except they will require +additional research to be completed. The reader will most likely not know the answer right away, nor will the text provide +the exact details of the answer until a subsequent chapter. + +Problems at the fifth level are meant to be the hardest +problems relative to all the other problems in the chapter. People who can correctly answer fifth level problems have a +mastery of the subject matter at hand. + +Often problems will be tied together. The purpose of this is to start a chain of thought that will be discussed in future chapters. The reader +is encouraged to answer the follow-up problems and try to draw the relevance of problems. + +\section{Introduction to LibTomMath} + +\subsection{What is LibTomMath?} +LibTomMath is a free and open source multiple precision integer library written entirely in portable ISO C. By portable it +is meant that the library does not contain any code that is computer platform dependent or otherwise problematic to use on +any given platform. + +The library has been successfully tested under numerous operating systems including Unix\footnote{All of these +trademarks belong to their respective rightful owners.}, MacOS, Windows, Linux, PalmOS and on standalone hardware such +as the Gameboy Advance. The library is designed to contain enough functionality to be able to develop applications such +as public key cryptosystems and still maintain a relatively small footprint. + +\subsection{Goals of LibTomMath} + +Libraries which obtain the most efficiency are rarely written in a high level programming language such as C. However, +even though this library is written entirely in ISO C, considerable care has been taken to optimize the algorithm implementations within the +library. Specifically the code has been written to work well with the GNU C Compiler (\textit{GCC}) on both x86 and ARM +processors. Wherever possible, highly efficient algorithms, such as Karatsuba multiplication, sliding window +exponentiation and Montgomery reduction have been provided to make the library more efficient. + +Even with the nearly optimal and specialized algorithms that have been included the Application Programing Interface +(\textit{API}) has been kept as simple as possible. Often generic place holder routines will make use of specialized +algorithms automatically without the developer's specific attention. One such example is the generic multiplication +algorithm \textbf{mp\_mul()} which will automatically use Toom--Cook, Karatsuba, Comba or baseline multiplication +based on the magnitude of the inputs and the configuration of the library. + +Making LibTomMath as efficient as possible is not the only goal of the LibTomMath project. Ideally the library should +be source compatible with another popular library which makes it more attractive for developers to use. In this case the +MPI library was used as a API template for all the basic functions. MPI was chosen because it is another library that fits +in the same niche as LibTomMath. Even though LibTomMath uses MPI as the template for the function names and argument +passing conventions, it has been written from scratch by Tom St Denis. + +The project is also meant to act as a learning tool for students, the logic being that no easy-to-follow ``bignum'' +library exists which can be used to teach computer science students how to perform fast and reliable multiple precision +integer arithmetic. To this end the source code has been given quite a few comments and algorithm discussion points. + +\section{Choice of LibTomMath} +LibTomMath was chosen as the case study of this text not only because the author of both projects is one and the same but +for more worthy reasons. Other libraries such as GMP \cite{GMP}, MPI \cite{MPI}, LIP \cite{LIP} and OpenSSL +\cite{OPENSSL} have multiple precision integer arithmetic routines but would not be ideal for this text for +reasons that will be explained in the following sub-sections. + +\subsection{Code Base} +The LibTomMath code base is all portable ISO C source code. This means that there are no platform dependent conditional +segments of code littered throughout the source. This clean and uncluttered approach to the library means that a +developer can more readily discern the true intent of a given section of source code without trying to keep track of +what conditional code will be used. + +The code base of LibTomMath is well organized. Each function is in its own separate source code file +which allows the reader to find a given function very quickly. On average there are $76$ lines of code per source +file which makes the source very easily to follow. By comparison MPI and LIP are single file projects making code tracing +very hard. GMP has many conditional code segments which also hinder tracing. + +When compiled with GCC for the x86 processor and optimized for speed the entire library is approximately $100$KiB\footnote{The notation ``KiB'' means $2^{10}$ octets, similarly ``MiB'' means $2^{20}$ octets.} + which is fairly small compared to GMP (over $250$KiB). LibTomMath is slightly larger than MPI (which compiles to about +$50$KiB) but LibTomMath is also much faster and more complete than MPI. + +\subsection{API Simplicity} +LibTomMath is designed after the MPI library and shares the API design. Quite often programs that use MPI will build +with LibTomMath without change. The function names correlate directly to the action they perform. Almost all of the +functions share the same parameter passing convention. The learning curve is fairly shallow with the API provided +which is an extremely valuable benefit for the student and developer alike. + +The LIP library is an example of a library with an API that is awkward to work with. LIP uses function names that are often ``compressed'' to +illegible short hand. LibTomMath does not share this characteristic. + +The GMP library also does not return error codes. Instead it uses a POSIX.1 \cite{POSIX1} signal system where errors +are signaled to the host application. This happens to be the fastest approach but definitely not the most versatile. In +effect a math error (i.e. invalid input, heap error, etc) can cause a program to stop functioning which is definitely +undersireable in many situations. + +\subsection{Optimizations} +While LibTomMath is certainly not the fastest library (GMP often beats LibTomMath by a factor of two) it does +feature a set of optimal algorithms for tasks such as modular reduction, exponentiation, multiplication and squaring. GMP +and LIP also feature such optimizations while MPI only uses baseline algorithms with no optimizations. GMP lacks a few +of the additional modular reduction optimizations that LibTomMath features\footnote{At the time of this writing GMP +only had Barrett and Montgomery modular reduction algorithms.}. + +LibTomMath is almost always an order of magnitude faster than the MPI library at computationally expensive tasks such as modular +exponentiation. In the grand scheme of ``bignum'' libraries LibTomMath is faster than the average library and usually +slower than the best libraries such as GMP and OpenSSL by only a small factor. + +\subsection{Portability and Stability} +LibTomMath will build ``out of the box'' on any platform equipped with a modern version of the GNU C Compiler +(\textit{GCC}). This means that without changes the library will build without configuration or setting up any +variables. LIP and MPI will build ``out of the box'' as well but have numerous known bugs. Most notably the author of +MPI has recently stopped working on his library and LIP has long since been discontinued. + +GMP requires a configuration script to run and will not build out of the box. GMP and LibTomMath are still in active +development and are very stable across a variety of platforms. + +\subsection{Choice} +LibTomMath is a relatively compact, well documented, highly optimized and portable library which seems only natural for +the case study of this text. Various source files from the LibTomMath project will be included within the text. However, +the reader is encouraged to download their own copy of the library to actually be able to work with the library. + +\chapter{Getting Started} +\section{Library Basics} +The trick to writing any useful library of source code is to build a solid foundation and work outwards from it. First, +a problem along with allowable solution parameters should be identified and analyzed. In this particular case the +inability to accomodate multiple precision integers is the problem. Futhermore, the solution must be written +as portable source code that is reasonably efficient across several different computer platforms. + +After a foundation is formed the remainder of the library can be designed and implemented in a hierarchical fashion. +That is, to implement the lowest level dependencies first and work towards the most abstract functions last. For example, +before implementing a modular exponentiation algorithm one would implement a modular reduction algorithm. +By building outwards from a base foundation instead of using a parallel design methodology the resulting project is +highly modular. Being highly modular is a desirable property of any project as it often means the resulting product +has a small footprint and updates are easy to perform. + +Usually when I start a project I will begin with the header files. I define the data types I think I will need and +prototype the initial functions that are not dependent on other functions (within the library). After I +implement these base functions I prototype more dependent functions and implement them. The process repeats until +I implement all of the functions I require. For example, in the case of LibTomMath I implemented functions such as +mp\_init() well before I implemented mp\_mul() and even further before I implemented mp\_exptmod(). As an example as to +why this design works note that the Karatsuba and Toom-Cook multipliers were written \textit{after} the +dependent function mp\_exptmod() was written. Adding the new multiplication algorithms did not require changes to the +mp\_exptmod() function itself and lowered the total cost of ownership (\textit{so to speak}) and of development +for new algorithms. This methodology allows new algorithms to be tested in a complete framework with relative ease. + +\begin{center} +\begin{figure}[here] +\includegraphics{pics/design_process.ps} +\caption{Design Flow of the First Few Original LibTomMath Functions.} +\label{pic:design_process} +\end{figure} +\end{center} + +Only after the majority of the functions were in place did I pursue a less hierarchical approach to auditing and optimizing +the source code. For example, one day I may audit the multipliers and the next day the polynomial basis functions. + +It only makes sense to begin the text with the preliminary data types and support algorithms required as well. +This chapter discusses the core algorithms of the library which are the dependents for every other algorithm. + +\section{What is a Multiple Precision Integer?} +Recall that most programming languages, in particular ISO C \cite{ISOC}, only have fixed precision data types that on their own cannot +be used to represent values larger than their precision will allow. The purpose of multiple precision algorithms is +to use fixed precision data types to create and manipulate multiple precision integers which may represent values +that are very large. + +As a well known analogy, school children are taught how to form numbers larger than nine by prepending more radix ten digits. In the decimal system +the largest single digit value is $9$. However, by concatenating digits together larger numbers may be represented. Newly prepended digits +(\textit{to the left}) are said to be in a different power of ten column. That is, the number $123$ can be described as having a $1$ in the hundreds +column, $2$ in the tens column and $3$ in the ones column. Or more formally $123 = 1 \cdot 10^2 + 2 \cdot 10^1 + 3 \cdot 10^0$. Computer based +multiple precision arithmetic is essentially the same concept. Larger integers are represented by adjoining fixed +precision computer words with the exception that a different radix is used. + +What most people probably do not think about explicitly are the various other attributes that describe a multiple precision +integer. For example, the integer $154_{10}$ has two immediately obvious properties. First, the integer is positive, +that is the sign of this particular integer is positive as opposed to negative. Second, the integer has three digits in +its representation. There is an additional property that the integer posesses that does not concern pencil-and-paper +arithmetic. The third property is how many digits placeholders are available to hold the integer. + +The human analogy of this third property is ensuring there is enough space on the paper to write the integer. For example, +if one starts writing a large number too far to the right on a piece of paper they will have to erase it and move left. +Similarly, computer algorithms must maintain strict control over memory usage to ensure that the digits of an integer +will not exceed the allowed boundaries. These three properties make up what is known as a multiple precision +integer or mp\_int for short. + +\subsection{The mp\_int Structure} +\label{sec:MPINT} +The mp\_int structure is the ISO C based manifestation of what represents a multiple precision integer. The ISO C standard does not provide for +any such data type but it does provide for making composite data types known as structures. The following is the structure definition +used within LibTomMath. + +\index{mp\_int} +\begin{figure}[here] +\begin{center} +\begin{small} +%\begin{verbatim} +\begin{tabular}{|l|} +\hline +typedef struct \{ \\ +\hspace{3mm}int used, alloc, sign;\\ +\hspace{3mm}mp\_digit *dp;\\ +\} \textbf{mp\_int}; \\ +\hline +\end{tabular} +%\end{verbatim} +\end{small} +\caption{The mp\_int Structure} +\label{fig:mpint} +\end{center} +\end{figure} + +The mp\_int structure (fig. \ref{fig:mpint}) can be broken down as follows. + +\begin{enumerate} +\item The \textbf{used} parameter denotes how many digits of the array \textbf{dp} contain the digits used to represent +a given integer. The \textbf{used} count must be positive (or zero) and may not exceed the \textbf{alloc} count. + +\item The \textbf{alloc} parameter denotes how +many digits are available in the array to use by functions before it has to increase in size. When the \textbf{used} count +of a result would exceed the \textbf{alloc} count all of the algorithms will automatically increase the size of the +array to accommodate the precision of the result. + +\item The pointer \textbf{dp} points to a dynamically allocated array of digits that represent the given multiple +precision integer. It is padded with $(\textbf{alloc} - \textbf{used})$ zero digits. The array is maintained in a least +significant digit order. As a pencil and paper analogy the array is organized such that the right most digits are stored +first starting at the location indexed by zero\footnote{In C all arrays begin at zero.} in the array. For example, +if \textbf{dp} contains $\lbrace a, b, c, \ldots \rbrace$ where \textbf{dp}$_0 = a$, \textbf{dp}$_1 = b$, \textbf{dp}$_2 = c$, $\ldots$ then +it would represent the integer $a + b\beta + c\beta^2 + \ldots$ + +\index{MP\_ZPOS} \index{MP\_NEG} +\item The \textbf{sign} parameter denotes the sign as either zero/positive (\textbf{MP\_ZPOS}) or negative (\textbf{MP\_NEG}). +\end{enumerate} + +\subsubsection{Valid mp\_int Structures} +Several rules are placed on the state of an mp\_int structure and are assumed to be followed for reasons of efficiency. +The only exceptions are when the structure is passed to initialization functions such as mp\_init() and mp\_init\_copy(). + +\begin{enumerate} +\item The value of \textbf{alloc} may not be less than one. That is \textbf{dp} always points to a previously allocated +array of digits. +\item The value of \textbf{used} may not exceed \textbf{alloc} and must be greater than or equal to zero. +\item The value of \textbf{used} implies the digit at index $(used - 1)$ of the \textbf{dp} array is non-zero. That is, +leading zero digits in the most significant positions must be trimmed. + \begin{enumerate} + \item Digits in the \textbf{dp} array at and above the \textbf{used} location must be zero. + \end{enumerate} +\item The value of \textbf{sign} must be \textbf{MP\_ZPOS} if \textbf{used} is zero; +this represents the mp\_int value of zero. +\end{enumerate} + +\section{Argument Passing} +A convention of argument passing must be adopted early on in the development of any library. Making the function +prototypes consistent will help eliminate many headaches in the future as the library grows to significant complexity. +In LibTomMath the multiple precision integer functions accept parameters from left to right as pointers to mp\_int +structures. That means that the source (input) operands are placed on the left and the destination (output) on the right. +Consider the following examples. + +\begin{verbatim} + mp_mul(&a, &b, &c); /* c = a * b */ + mp_add(&a, &b, &a); /* a = a + b */ + mp_sqr(&a, &b); /* b = a * a */ +\end{verbatim} + +The left to right order is a fairly natural way to implement the functions since it lets the developer read aloud the +functions and make sense of them. For example, the first function would read ``multiply a and b and store in c''. + +Certain libraries (\textit{LIP by Lenstra for instance}) accept parameters the other way around, to mimic the order +of assignment expressions. That is, the destination (output) is on the left and arguments (inputs) are on the right. In +truth, it is entirely a matter of preference. In the case of LibTomMath the convention from the MPI library has been +adopted. + +Another very useful design consideration, provided for in LibTomMath, is whether to allow argument sources to also be a +destination. For example, the second example (\textit{mp\_add}) adds $a$ to $b$ and stores in $a$. This is an important +feature to implement since it allows the calling functions to cut down on the number of variables it must maintain. +However, to implement this feature specific care has to be given to ensure the destination is not modified before the +source is fully read. + +\section{Return Values} +A well implemented application, no matter what its purpose, should trap as many runtime errors as possible and return them +to the caller. By catching runtime errors a library can be guaranteed to prevent undefined behaviour. However, the end +developer can still manage to cause a library to crash. For example, by passing an invalid pointer an application may +fault by dereferencing memory not owned by the application. + +In the case of LibTomMath the only errors that are checked for are related to inappropriate inputs (division by zero for +instance) and memory allocation errors. It will not check that the mp\_int passed to any function is valid nor +will it check pointers for validity. Any function that can cause a runtime error will return an error code as an +\textbf{int} data type with one of the following values (fig \ref{fig:errcodes}). + +\index{MP\_OKAY} \index{MP\_VAL} \index{MP\_MEM} +\begin{figure}[here] +\begin{center} +\begin{tabular}{|l|l|} +\hline \textbf{Value} & \textbf{Meaning} \\ +\hline \textbf{MP\_OKAY} & The function was successful \\ +\hline \textbf{MP\_VAL} & One of the input value(s) was invalid \\ +\hline \textbf{MP\_MEM} & The function ran out of heap memory \\ +\hline +\end{tabular} +\end{center} +\caption{LibTomMath Error Codes} +\label{fig:errcodes} +\end{figure} + +When an error is detected within a function it should free any memory it allocated, often during the initialization of +temporary mp\_ints, and return as soon as possible. The goal is to leave the system in the same state it was when the +function was called. Error checking with this style of API is fairly simple. + +\begin{verbatim} + int err; + if ((err = mp_add(&a, &b, &c)) != MP_OKAY) { + printf("Error: %s\n", mp_error_to_string(err)); + exit(EXIT_FAILURE); + } +\end{verbatim} + +The GMP \cite{GMP} library uses C style \textit{signals} to flag errors which is of questionable use. Not all errors are fatal +and it was not deemed ideal by the author of LibTomMath to force developers to have signal handlers for such cases. + +\section{Initialization and Clearing} +The logical starting point when actually writing multiple precision integer functions is the initialization and +clearing of the mp\_int structures. These two algorithms will be used by the majority of the higher level algorithms. + +Given the basic mp\_int structure an initialization routine must first allocate memory to hold the digits of +the integer. Often it is optimal to allocate a sufficiently large pre-set number of digits even though +the initial integer will represent zero. If only a single digit were allocated quite a few subsequent re-allocations +would occur when operations are performed on the integers. There is a tradeoff between how many default digits to allocate +and how many re-allocations are tolerable. Obviously allocating an excessive amount of digits initially will waste +memory and become unmanageable. + +If the memory for the digits has been successfully allocated then the rest of the members of the structure must +be initialized. Since the initial state of an mp\_int is to represent the zero integer, the allocated digits must be set +to zero. The \textbf{used} count set to zero and \textbf{sign} set to \textbf{MP\_ZPOS}. + +\subsection{Initializing an mp\_int} +An mp\_int is said to be initialized if it is set to a valid, preferably default, state such that all of the members of the +structure are set to valid values. The mp\_init algorithm will perform such an action. + +\index{mp\_init} +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Allocate memory and initialize $a$ to a known valid mp\_int state. \\ +\hline \\ +1. Allocate memory for \textbf{MP\_PREC} digits. \\ +2. If the allocation failed return(\textit{MP\_MEM}) \\ +3. for $n$ from $0$ to $MP\_PREC - 1$ do \\ +\hspace{3mm}3.1 $a_n \leftarrow 0$\\ +4. $a.sign \leftarrow MP\_ZPOS$\\ +5. $a.used \leftarrow 0$\\ +6. $a.alloc \leftarrow MP\_PREC$\\ +7. Return(\textit{MP\_OKAY})\\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init} +\end{figure} + +\textbf{Algorithm mp\_init.} +The purpose of this function is to initialize an mp\_int structure so that the rest of the library can properly +manipulte it. It is assumed that the input may not have had any of its members previously initialized which is certainly +a valid assumption if the input resides on the stack. + +Before any of the members such as \textbf{sign}, \textbf{used} or \textbf{alloc} are initialized the memory for +the digits is allocated. If this fails the function returns before setting any of the other members. The \textbf{MP\_PREC} +name represents a constant\footnote{Defined in the ``tommath.h'' header file within LibTomMath.} +used to dictate the minimum precision of newly initialized mp\_int integers. Ideally, it is at least equal to the smallest +precision number you'll be working with. + +Allocating a block of digits at first instead of a single digit has the benefit of lowering the number of usually slow +heap operations later functions will have to perform in the future. If \textbf{MP\_PREC} is set correctly the slack +memory and the number of heap operations will be trivial. + +Once the allocation has been made the digits have to be set to zero as well as the \textbf{used}, \textbf{sign} and +\textbf{alloc} members initialized. This ensures that the mp\_int will always represent the default state of zero regardless +of the original condition of the input. + +\textbf{Remark.} +This function introduces the idiosyncrasy that all iterative loops, commonly initiated with the ``for'' keyword, iterate incrementally +when the ``to'' keyword is placed between two expressions. For example, ``for $a$ from $b$ to $c$ do'' means that +a subsequent expression (or body of expressions) are to be evaluated upto $c - b$ times so long as $b \le c$. In each +iteration the variable $a$ is substituted for a new integer that lies inclusively between $b$ and $c$. If $b > c$ occured +the loop would not iterate. By contrast if the ``downto'' keyword were used in place of ``to'' the loop would iterate +decrementally. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_init.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* init a new mp_int */ +018 int mp_init (mp_int * a) +019 \{ +020 int i; +021 +022 /* allocate memory required and clear it */ +023 a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * MP_PREC); +024 if (a->dp == NULL) \{ +025 return MP_MEM; +026 \} +027 +028 /* set the digits to zero */ +029 for (i = 0; i < MP_PREC; i++) \{ +030 a->dp[i] = 0; +031 \} +032 +033 /* set the used to zero, allocated digits to the default precision +034 * and sign to positive */ +035 a->used = 0; +036 a->alloc = MP_PREC; +037 a->sign = MP_ZPOS; +038 +039 return MP_OKAY; +040 \} +041 #endif +\end{alltt} +\end{small} + +One immediate observation of this initializtion function is that it does not return a pointer to a mp\_int structure. It +is assumed that the caller has already allocated memory for the mp\_int structure, typically on the application stack. The +call to mp\_init() is used only to initialize the members of the structure to a known default state. + +Here we see (line 23) the memory allocation is performed first. This allows us to exit cleanly and quickly +if there is an error. If the allocation fails the routine will return \textbf{MP\_MEM} to the caller to indicate there +was a memory error. The function XMALLOC is what actually allocates the memory. Technically XMALLOC is not a function +but a macro defined in ``tommath.h``. By default, XMALLOC will evaluate to malloc() which is the C library's built--in +memory allocation routine. + +In order to assure the mp\_int is in a known state the digits must be set to zero. On most platforms this could have been +accomplished by using calloc() instead of malloc(). However, to correctly initialize a integer type to a given value in a +portable fashion you have to actually assign the value. The for loop (line 29) performs this required +operation. + +After the memory has been successfully initialized the remainder of the members are initialized +(lines 33 through 34) to their respective default states. At this point the algorithm has succeeded and +a success code is returned to the calling function. If this function returns \textbf{MP\_OKAY} it is safe to assume the +mp\_int structure has been properly initialized and is safe to use with other functions within the library. + +\subsection{Clearing an mp\_int} +When an mp\_int is no longer required by the application, the memory that has been allocated for its digits must be +returned to the application's memory pool with the mp\_clear algorithm. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_clear}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. The memory for $a$ shall be deallocated. \\ +\hline \\ +1. If $a$ has been previously freed then return(\textit{MP\_OKAY}). \\ +2. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}2.1 $a_n \leftarrow 0$ \\ +3. Free the memory allocated for the digits of $a$. \\ +4. $a.used \leftarrow 0$ \\ +5. $a.alloc \leftarrow 0$ \\ +6. $a.sign \leftarrow MP\_ZPOS$ \\ +7. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_clear} +\end{figure} + +\textbf{Algorithm mp\_clear.} +This algorithm accomplishes two goals. First, it clears the digits and the other mp\_int members. This ensures that +if a developer accidentally re-uses a cleared structure it is less likely to cause problems. The second goal +is to free the allocated memory. + +The logic behind the algorithm is extended by marking cleared mp\_int structures so that subsequent calls to this +algorithm will not try to free the memory multiple times. Cleared mp\_ints are detectable by having a pre-defined invalid +digit pointer \textbf{dp} setting. + +Once an mp\_int has been cleared the mp\_int structure is no longer in a valid state for any other algorithm +with the exception of algorithms mp\_init, mp\_init\_copy, mp\_init\_size and mp\_clear. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_clear.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* clear one (frees) */ +018 void +019 mp_clear (mp_int * a) +020 \{ +021 int i; +022 +023 /* only do anything if a hasn't been freed previously */ +024 if (a->dp != NULL) \{ +025 /* first zero the digits */ +026 for (i = 0; i < a->used; i++) \{ +027 a->dp[i] = 0; +028 \} +029 +030 /* free ram */ +031 XFREE(a->dp); +032 +033 /* reset members to make debugging easier */ +034 a->dp = NULL; +035 a->alloc = a->used = 0; +036 a->sign = MP_ZPOS; +037 \} +038 \} +039 #endif +\end{alltt} +\end{small} + +The algorithm only operates on the mp\_int if it hasn't been previously cleared. The if statement (line 24) +checks to see if the \textbf{dp} member is not \textbf{NULL}. If the mp\_int is a valid mp\_int then \textbf{dp} cannot be +\textbf{NULL} in which case the if statement will evaluate to true. + +The digits of the mp\_int are cleared by the for loop (line 26) which assigns a zero to every digit. Similar to mp\_init() +the digits are assigned zero instead of using block memory operations (such as memset()) since this is more portable. + +The digits are deallocated off the heap via the XFREE macro. Similar to XMALLOC the XFREE macro actually evaluates to +a standard C library function. In this case the free() function. Since free() only deallocates the memory the pointer +still has to be reset to \textbf{NULL} manually (line 34). + +Now that the digits have been cleared and deallocated the other members are set to their final values (lines 35 and 36). + +\section{Maintenance Algorithms} + +The previous sections describes how to initialize and clear an mp\_int structure. To further support operations +that are to be performed on mp\_int structures (such as addition and multiplication) the dependent algorithms must be +able to augment the precision of an mp\_int and +initialize mp\_ints with differing initial conditions. + +These algorithms complete the set of low level algorithms required to work with mp\_int structures in the higher level +algorithms such as addition, multiplication and modular exponentiation. + +\subsection{Augmenting an mp\_int's Precision} +When storing a value in an mp\_int structure, a sufficient number of digits must be available to accomodate the entire +result of an operation without loss of precision. Quite often the size of the array given by the \textbf{alloc} member +is large enough to simply increase the \textbf{used} digit count. However, when the size of the array is too small it +must be re-sized appropriately to accomodate the result. The mp\_grow algorithm will provide this functionality. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_grow}. \\ +\textbf{Input}. An mp\_int $a$ and an integer $b$. \\ +\textbf{Output}. $a$ is expanded to accomodate $b$ digits. \\ +\hline \\ +1. if $a.alloc \ge b$ then return(\textit{MP\_OKAY}) \\ +2. $u \leftarrow b\mbox{ (mod }MP\_PREC\mbox{)}$ \\ +3. $v \leftarrow b + 2 \cdot MP\_PREC - u$ \\ +4. Re-allocate the array of digits $a$ to size $v$ \\ +5. If the allocation failed then return(\textit{MP\_MEM}). \\ +6. for n from a.alloc to $v - 1$ do \\ +\hspace{+3mm}6.1 $a_n \leftarrow 0$ \\ +7. $a.alloc \leftarrow v$ \\ +8. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_grow} +\end{figure} + +\textbf{Algorithm mp\_grow.} +It is ideal to prevent re-allocations from being performed if they are not required (step one). This is useful to +prevent mp\_ints from growing excessively in code that erroneously calls mp\_grow. + +The requested digit count is padded up to next multiple of \textbf{MP\_PREC} plus an additional \textbf{MP\_PREC} (steps two and three). +This helps prevent many trivial reallocations that would grow an mp\_int by trivially small values. + +It is assumed that the reallocation (step four) leaves the lower $a.alloc$ digits of the mp\_int intact. This is much +akin to how the \textit{realloc} function from the standard C library works. Since the newly allocated digits are +assumed to contain undefined values they are initially set to zero. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_grow.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* grow as required */ +018 int mp_grow (mp_int * a, int size) +019 \{ +020 int i; +021 mp_digit *tmp; +022 +023 /* if the alloc size is smaller alloc more ram */ +024 if (a->alloc < size) \{ +025 /* ensure there are always at least MP_PREC digits extra on top */ +026 size += (MP_PREC * 2) - (size % MP_PREC); +027 +028 /* reallocate the array a->dp +029 * +030 * We store the return in a temporary variable +031 * in case the operation failed we don't want +032 * to overwrite the dp member of a. +033 */ +034 tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * size); +035 if (tmp == NULL) \{ +036 /* reallocation failed but "a" is still valid [can be freed] */ +037 return MP_MEM; +038 \} +039 +040 /* reallocation succeeded so set a->dp */ +041 a->dp = tmp; +042 +043 /* zero excess digits */ +044 i = a->alloc; +045 a->alloc = size; +046 for (; i < a->alloc; i++) \{ +047 a->dp[i] = 0; +048 \} +049 \} +050 return MP_OKAY; +051 \} +052 #endif +\end{alltt} +\end{small} + +A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line 23) checks +if the \textbf{alloc} member of the mp\_int is smaller than the requested digit count. If the count is not larger than \textbf{alloc} +the function skips the re-allocation part thus saving time. + +When a re-allocation is performed it is turned into an optimal request to save time in the future. The requested digit count is +padded upwards to 2nd multiple of \textbf{MP\_PREC} larger than \textbf{alloc} (line 26). The XREALLOC function is used +to re-allocate the memory. As per the other functions XREALLOC is actually a macro which evaluates to realloc by default. The realloc +function leaves the base of the allocation intact which means the first \textbf{alloc} digits of the mp\_int are the same as before +the re-allocation. All that is left is to clear the newly allocated digits and return. + +Note that the re-allocation result is actually stored in a temporary pointer $tmp$. This is to allow this function to return +an error with a valid pointer. Earlier releases of the library stored the result of XREALLOC into the mp\_int $a$. That would +result in a memory leak if XREALLOC ever failed. + +\subsection{Initializing Variable Precision mp\_ints} +Occasionally the number of digits required will be known in advance of an initialization, based on, for example, the size +of input mp\_ints to a given algorithm. The purpose of algorithm mp\_init\_size is similar to mp\_init except that it +will allocate \textit{at least} a specified number of digits. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_size}. \\ +\textbf{Input}. An mp\_int $a$ and the requested number of digits $b$. \\ +\textbf{Output}. $a$ is initialized to hold at least $b$ digits. \\ +\hline \\ +1. $u \leftarrow b \mbox{ (mod }MP\_PREC\mbox{)}$ \\ +2. $v \leftarrow b + 2 \cdot MP\_PREC - u$ \\ +3. Allocate $v$ digits. \\ +4. for $n$ from $0$ to $v - 1$ do \\ +\hspace{3mm}4.1 $a_n \leftarrow 0$ \\ +5. $a.sign \leftarrow MP\_ZPOS$\\ +6. $a.used \leftarrow 0$\\ +7. $a.alloc \leftarrow v$\\ +8. Return(\textit{MP\_OKAY})\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_init\_size} +\end{figure} + +\textbf{Algorithm mp\_init\_size.} +This algorithm will initialize an mp\_int structure $a$ like algorithm mp\_init with the exception that the number of +digits allocated can be controlled by the second input argument $b$. The input size is padded upwards so it is a +multiple of \textbf{MP\_PREC} plus an additional \textbf{MP\_PREC} digits. This padding is used to prevent trivial +allocations from becoming a bottleneck in the rest of the algorithms. + +Like algorithm mp\_init, the mp\_int structure is initialized to a default state representing the integer zero. This +particular algorithm is useful if it is known ahead of time the approximate size of the input. If the approximation is +correct no further memory re-allocations are required to work with the mp\_int. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_init\_size.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* init an mp_init for a given size */ +018 int mp_init_size (mp_int * a, int size) +019 \{ +020 int x; +021 +022 /* pad size so there are always extra digits */ +023 size += (MP_PREC * 2) - (size % MP_PREC); +024 +025 /* alloc mem */ +026 a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * size); +027 if (a->dp == NULL) \{ +028 return MP_MEM; +029 \} +030 +031 /* set the members */ +032 a->used = 0; +033 a->alloc = size; +034 a->sign = MP_ZPOS; +035 +036 /* zero the digits */ +037 for (x = 0; x < size; x++) \{ +038 a->dp[x] = 0; +039 \} +040 +041 return MP_OKAY; +042 \} +043 #endif +\end{alltt} +\end{small} + +The number of digits $b$ requested is padded (line 23) by first augmenting it to the next multiple of +\textbf{MP\_PREC} and then adding \textbf{MP\_PREC} to the result. If the memory can be successfully allocated the +mp\_int is placed in a default state representing the integer zero. Otherwise, the error code \textbf{MP\_MEM} will be +returned (line 28). + +The digits are allocated and set to zero at the same time with the calloc() function (line @25,XCALLOC@). The +\textbf{used} count is set to zero, the \textbf{alloc} count set to the padded digit count and the \textbf{sign} flag set +to \textbf{MP\_ZPOS} to achieve a default valid mp\_int state (lines 32, 33 and 34). If the function +returns succesfully then it is correct to assume that the mp\_int structure is in a valid state for the remainder of the +functions to work with. + +\subsection{Multiple Integer Initializations and Clearings} +Occasionally a function will require a series of mp\_int data types to be made available simultaneously. +The purpose of algorithm mp\_init\_multi is to initialize a variable length array of mp\_int structures in a single +statement. It is essentially a shortcut to multiple initializations. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_multi}. \\ +\textbf{Input}. Variable length array $V_k$ of mp\_int variables of length $k$. \\ +\textbf{Output}. The array is initialized such that each mp\_int of $V_k$ is ready to use. \\ +\hline \\ +1. for $n$ from 0 to $k - 1$ do \\ +\hspace{+3mm}1.1. Initialize the mp\_int $V_n$ (\textit{mp\_init}) \\ +\hspace{+3mm}1.2. If initialization failed then do \\ +\hspace{+6mm}1.2.1. for $j$ from $0$ to $n$ do \\ +\hspace{+9mm}1.2.1.1. Free the mp\_int $V_j$ (\textit{mp\_clear}) \\ +\hspace{+6mm}1.2.2. Return(\textit{MP\_MEM}) \\ +2. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init\_multi} +\end{figure} + +\textbf{Algorithm mp\_init\_multi.} +The algorithm will initialize the array of mp\_int variables one at a time. If a runtime error has been detected +(\textit{step 1.2}) all of the previously initialized variables are cleared. The goal is an ``all or nothing'' +initialization which allows for quick recovery from runtime errors. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_init\_multi.c +\vspace{-3mm} +\begin{alltt} +016 #include +017 +018 int mp_init_multi(mp_int *mp, ...) +019 \{ +020 mp_err res = MP_OKAY; /* Assume ok until proven otherwise */ +021 int n = 0; /* Number of ok inits */ +022 mp_int* cur_arg = mp; +023 va_list args; +024 +025 va_start(args, mp); /* init args to next argument from caller */ +026 while (cur_arg != NULL) \{ +027 if (mp_init(cur_arg) != MP_OKAY) \{ +028 /* Oops - error! Back-track and mp_clear what we already +029 succeeded in init-ing, then return error. +030 */ +031 va_list clean_args; +032 +033 /* end the current list */ +034 va_end(args); +035 +036 /* now start cleaning up */ +037 cur_arg = mp; +038 va_start(clean_args, mp); +039 while (n--) \{ +040 mp_clear(cur_arg); +041 cur_arg = va_arg(clean_args, mp_int*); +042 \} +043 va_end(clean_args); +044 res = MP_MEM; +045 break; +046 \} +047 n++; +048 cur_arg = va_arg(args, mp_int*); +049 \} +050 va_end(args); +051 return res; /* Assumed ok, if error flagged above. */ +052 \} +053 +054 #endif +\end{alltt} +\end{small} + +This function intializes a variable length list of mp\_int structure pointers. However, instead of having the mp\_int +structures in an actual C array they are simply passed as arguments to the function. This function makes use of the +``...'' argument syntax of the C programming language. The list is terminated with a final \textbf{NULL} argument +appended on the right. + +The function uses the ``stdarg.h'' \textit{va} functions to step portably through the arguments to the function. A count +$n$ of succesfully initialized mp\_int structures is maintained (line 47) such that if a failure does occur, +the algorithm can backtrack and free the previously initialized structures (lines 27 to 46). + + +\subsection{Clamping Excess Digits} +When a function anticipates a result will be $n$ digits it is simpler to assume this is true within the body of +the function instead of checking during the computation. For example, a multiplication of a $i$ digit number by a +$j$ digit produces a result of at most $i + j$ digits. It is entirely possible that the result is $i + j - 1$ +though, with no final carry into the last position. However, suppose the destination had to be first expanded +(\textit{via mp\_grow}) to accomodate $i + j - 1$ digits than further expanded to accomodate the final carry. +That would be a considerable waste of time since heap operations are relatively slow. + +The ideal solution is to always assume the result is $i + j$ and fix up the \textbf{used} count after the function +terminates. This way a single heap operation (\textit{at most}) is required. However, if the result was not checked +there would be an excess high order zero digit. + +For example, suppose the product of two integers was $x_n = (0x_{n-1}x_{n-2}...x_0)_{\beta}$. The leading zero digit +will not contribute to the precision of the result. In fact, through subsequent operations more leading zero digits would +accumulate to the point the size of the integer would be prohibitive. As a result even though the precision is very +low the representation is excessively large. + +The mp\_clamp algorithm is designed to solve this very problem. It will trim high-order zeros by decrementing the +\textbf{used} count until a non-zero most significant digit is found. Also in this system, zero is considered to be a +positive number which means that if the \textbf{used} count is decremented to zero, the sign must be set to +\textbf{MP\_ZPOS}. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_clamp}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Any excess leading zero digits of $a$ are removed \\ +\hline \\ +1. while $a.used > 0$ and $a_{a.used - 1} = 0$ do \\ +\hspace{+3mm}1.1 $a.used \leftarrow a.used - 1$ \\ +2. if $a.used = 0$ then do \\ +\hspace{+3mm}2.1 $a.sign \leftarrow MP\_ZPOS$ \\ +\hline \\ +\end{tabular} +\end{center} +\caption{Algorithm mp\_clamp} +\end{figure} + +\textbf{Algorithm mp\_clamp.} +As can be expected this algorithm is very simple. The loop on step one is expected to iterate only once or twice at +the most. For example, this will happen in cases where there is not a carry to fill the last position. Step two fixes the sign for +when all of the digits are zero to ensure that the mp\_int is valid at all times. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_clamp.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* trim unused digits +018 * +019 * This is used to ensure that leading zero digits are +020 * trimed and the leading "used" digit will be non-zero +021 * Typically very fast. Also fixes the sign if there +022 * are no more leading digits +023 */ +024 void +025 mp_clamp (mp_int * a) +026 \{ +027 /* decrease used while the most significant digit is +028 * zero. +029 */ +030 while (a->used > 0 && a->dp[a->used - 1] == 0) \{ +031 --(a->used); +032 \} +033 +034 /* reset the sign flag if used == 0 */ +035 if (a->used == 0) \{ +036 a->sign = MP_ZPOS; +037 \} +038 \} +039 #endif +\end{alltt} +\end{small} + +Note on line 27 how to test for the \textbf{used} count is made on the left of the \&\& operator. In the C programming +language the terms to \&\& are evaluated left to right with a boolean short-circuit if any condition fails. This is +important since if the \textbf{used} is zero the test on the right would fetch below the array. That is obviously +undesirable. The parenthesis on line 30 is used to make sure the \textbf{used} count is decremented and not +the pointer ``a''. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 1 \right ]$ & Discuss the relevance of the \textbf{used} member of the mp\_int structure. \\ + & \\ +$\left [ 1 \right ]$ & Discuss the consequences of not using padding when performing allocations. \\ + & \\ +$\left [ 2 \right ]$ & Estimate an ideal value for \textbf{MP\_PREC} when performing 1024-bit RSA \\ + & encryption when $\beta = 2^{28}$. \\ + & \\ +$\left [ 1 \right ]$ & Discuss the relevance of the algorithm mp\_clamp. What does it prevent? \\ + & \\ +$\left [ 1 \right ]$ & Give an example of when the algorithm mp\_init\_copy might be useful. \\ + & \\ +\end{tabular} + + +%%% +% CHAPTER FOUR +%%% + +\chapter{Basic Operations} + +\section{Introduction} +In the previous chapter a series of low level algorithms were established that dealt with initializing and maintaining +mp\_int structures. This chapter will discuss another set of seemingly non-algebraic algorithms which will form the low +level basis of the entire library. While these algorithm are relatively trivial it is important to understand how they +work before proceeding since these algorithms will be used almost intrinsically in the following chapters. + +The algorithms in this chapter deal primarily with more ``programmer'' related tasks such as creating copies of +mp\_int structures, assigning small values to mp\_int structures and comparisons of the values mp\_int structures +represent. + +\section{Assigning Values to mp\_int Structures} +\subsection{Copying an mp\_int} +Assigning the value that a given mp\_int structure represents to another mp\_int structure shall be known as making +a copy for the purposes of this text. The copy of the mp\_int will be a separate entity that represents the same +value as the mp\_int it was copied from. The mp\_copy algorithm provides this functionality. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_copy}. \\ +\textbf{Input}. An mp\_int $a$ and $b$. \\ +\textbf{Output}. Store a copy of $a$ in $b$. \\ +\hline \\ +1. If $b.alloc < a.used$ then grow $b$ to $a.used$ digits. (\textit{mp\_grow}) \\ +2. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}2.1 $b_{n} \leftarrow a_{n}$ \\ +3. for $n$ from $a.used$ to $b.used - 1$ do \\ +\hspace{3mm}3.1 $b_{n} \leftarrow 0$ \\ +4. $b.used \leftarrow a.used$ \\ +5. $b.sign \leftarrow a.sign$ \\ +6. return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_copy} +\end{figure} + +\textbf{Algorithm mp\_copy.} +This algorithm copies the mp\_int $a$ such that upon succesful termination of the algorithm the mp\_int $b$ will +represent the same integer as the mp\_int $a$. The mp\_int $b$ shall be a complete and distinct copy of the +mp\_int $a$ meaing that the mp\_int $a$ can be modified and it shall not affect the value of the mp\_int $b$. + +If $b$ does not have enough room for the digits of $a$ it must first have its precision augmented via the mp\_grow +algorithm. The digits of $a$ are copied over the digits of $b$ and any excess digits of $b$ are set to zero (step two +and three). The \textbf{used} and \textbf{sign} members of $a$ are finally copied over the respective members of +$b$. + +\textbf{Remark.} This algorithm also introduces a new idiosyncrasy that will be used throughout the rest of the +text. The error return codes of other algorithms are not explicitly checked in the pseudo-code presented. For example, in +step one of the mp\_copy algorithm the return of mp\_grow is not explicitly checked to ensure it succeeded. Text space is +limited so it is assumed that if a algorithm fails it will clear all temporarily allocated mp\_ints and return +the error code itself. However, the C code presented will demonstrate all of the error handling logic required to +implement the pseudo-code. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_copy.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* copy, b = a */ +018 int +019 mp_copy (mp_int * a, mp_int * b) +020 \{ +021 int res, n; +022 +023 /* if dst == src do nothing */ +024 if (a == b) \{ +025 return MP_OKAY; +026 \} +027 +028 /* grow dest */ +029 if (b->alloc < a->used) \{ +030 if ((res = mp_grow (b, a->used)) != MP_OKAY) \{ +031 return res; +032 \} +033 \} +034 +035 /* zero b and copy the parameters over */ +036 \{ +037 register mp_digit *tmpa, *tmpb; +038 +039 /* pointer aliases */ +040 +041 /* source */ +042 tmpa = a->dp; +043 +044 /* destination */ +045 tmpb = b->dp; +046 +047 /* copy all the digits */ +048 for (n = 0; n < a->used; n++) \{ +049 *tmpb++ = *tmpa++; +050 \} +051 +052 /* clear high digits */ +053 for (; n < b->used; n++) \{ +054 *tmpb++ = 0; +055 \} +056 \} +057 +058 /* copy used count and sign */ +059 b->used = a->used; +060 b->sign = a->sign; +061 return MP_OKAY; +062 \} +063 #endif +\end{alltt} +\end{small} + +Occasionally a dependent algorithm may copy an mp\_int effectively into itself such as when the input and output +mp\_int structures passed to a function are one and the same. For this case it is optimal to return immediately without +copying digits (line 24). + +The mp\_int $b$ must have enough digits to accomodate the used digits of the mp\_int $a$. If $b.alloc$ is less than +$a.used$ the algorithm mp\_grow is used to augment the precision of $b$ (lines 29 to 33). In order to +simplify the inner loop that copies the digits from $a$ to $b$, two aliases $tmpa$ and $tmpb$ point directly at the digits +of the mp\_ints $a$ and $b$ respectively. These aliases (lines 42 and 45) allow the compiler to access the digits without first dereferencing the +mp\_int pointers and then subsequently the pointer to the digits. + +After the aliases are established the digits from $a$ are copied into $b$ (lines 48 to 50) and then the excess +digits of $b$ are set to zero (lines 53 to 55). Both ``for'' loops make use of the pointer aliases and in +fact the alias for $b$ is carried through into the second ``for'' loop to clear the excess digits. This optimization +allows the alias to stay in a machine register fairly easy between the two loops. + +\textbf{Remarks.} The use of pointer aliases is an implementation methodology first introduced in this function that will +be used considerably in other functions. Technically, a pointer alias is simply a short hand alias used to lower the +number of pointer dereferencing operations required to access data. For example, a for loop may resemble + +\begin{alltt} +for (x = 0; x < 100; x++) \{ + a->num[4]->dp[x] = 0; +\} +\end{alltt} + +This could be re-written using aliases as + +\begin{alltt} +mp_digit *tmpa; +a = a->num[4]->dp; +for (x = 0; x < 100; x++) \{ + *a++ = 0; +\} +\end{alltt} + +In this case an alias is used to access the +array of digits within an mp\_int structure directly. It may seem that a pointer alias is strictly not required +as a compiler may optimize out the redundant pointer operations. However, there are two dominant reasons to use aliases. + +The first reason is that most compilers will not effectively optimize pointer arithmetic. For example, some optimizations +may work for the Microsoft Visual C++ compiler (MSVC) and not for the GNU C Compiler (GCC). Also some optimizations may +work for GCC and not MSVC. As such it is ideal to find a common ground for as many compilers as possible. Pointer +aliases optimize the code considerably before the compiler even reads the source code which means the end compiled code +stands a better chance of being faster. + +The second reason is that pointer aliases often can make an algorithm simpler to read. Consider the first ``for'' +loop of the function mp\_copy() re-written to not use pointer aliases. + +\begin{alltt} + /* copy all the digits */ + for (n = 0; n < a->used; n++) \{ + b->dp[n] = a->dp[n]; + \} +\end{alltt} + +Whether this code is harder to read depends strongly on the individual. However, it is quantifiably slightly more +complicated as there are four variables within the statement instead of just two. + +\subsubsection{Nested Statements} +Another commonly used technique in the source routines is that certain sections of code are nested. This is used in +particular with the pointer aliases to highlight code phases. For example, a Comba multiplier (discussed in chapter six) +will typically have three different phases. First the temporaries are initialized, then the columns calculated and +finally the carries are propagated. In this example the middle column production phase will typically be nested as it +uses temporary variables and aliases the most. + +The nesting also simplies the source code as variables that are nested are only valid for their scope. As a result +the various temporary variables required do not propagate into other sections of code. + + +\subsection{Creating a Clone} +Another common operation is to make a local temporary copy of an mp\_int argument. To initialize an mp\_int +and then copy another existing mp\_int into the newly intialized mp\_int will be known as creating a clone. This is +useful within functions that need to modify an argument but do not wish to actually modify the original copy. The +mp\_init\_copy algorithm has been designed to help perform this task. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_init\_copy}. \\ +\textbf{Input}. An mp\_int $a$ and $b$\\ +\textbf{Output}. $a$ is initialized to be a copy of $b$. \\ +\hline \\ +1. Init $a$. (\textit{mp\_init}) \\ +2. Copy $b$ to $a$. (\textit{mp\_copy}) \\ +3. Return the status of the copy operation. \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_init\_copy} +\end{figure} + +\textbf{Algorithm mp\_init\_copy.} +This algorithm will initialize an mp\_int variable and copy another previously initialized mp\_int variable into it. As +such this algorithm will perform two operations in one step. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_init\_copy.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* creates "a" then copies b into it */ +018 int mp_init_copy (mp_int * a, mp_int * b) +019 \{ +020 int res; +021 +022 if ((res = mp_init (a)) != MP_OKAY) \{ +023 return res; +024 \} +025 return mp_copy (b, a); +026 \} +027 #endif +\end{alltt} +\end{small} + +This will initialize \textbf{a} and make it a verbatim copy of the contents of \textbf{b}. Note that +\textbf{a} will have its own memory allocated which means that \textbf{b} may be cleared after the call +and \textbf{a} will be left intact. + +\section{Zeroing an Integer} +Reseting an mp\_int to the default state is a common step in many algorithms. The mp\_zero algorithm will be the algorithm used to +perform this task. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_zero}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Zero the contents of $a$ \\ +\hline \\ +1. $a.used \leftarrow 0$ \\ +2. $a.sign \leftarrow$ MP\_ZPOS \\ +3. for $n$ from 0 to $a.alloc - 1$ do \\ +\hspace{3mm}3.1 $a_n \leftarrow 0$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_zero} +\end{figure} + +\textbf{Algorithm mp\_zero.} +This algorithm simply resets a mp\_int to the default state. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_zero.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* set to zero */ +018 void +019 mp_zero (mp_int * a) +020 \{ +021 a->sign = MP_ZPOS; +022 a->used = 0; +023 memset (a->dp, 0, sizeof (mp_digit) * a->alloc); +024 \} +025 #endif +\end{alltt} +\end{small} + +After the function is completed, all of the digits are zeroed, the \textbf{used} count is zeroed and the +\textbf{sign} variable is set to \textbf{MP\_ZPOS}. + +\section{Sign Manipulation} +\subsection{Absolute Value} +With the mp\_int representation of an integer, calculating the absolute value is trivial. The mp\_abs algorithm will compute +the absolute value of an mp\_int. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_abs}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Computes $b = \vert a \vert$ \\ +\hline \\ +1. Copy $a$ to $b$. (\textit{mp\_copy}) \\ +2. If the copy failed return(\textit{MP\_MEM}). \\ +3. $b.sign \leftarrow MP\_ZPOS$ \\ +4. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_abs} +\end{figure} + +\textbf{Algorithm mp\_abs.} +This algorithm computes the absolute of an mp\_int input. First it copies $a$ over $b$. This is an example of an +algorithm where the check in mp\_copy that determines if the source and destination are equal proves useful. This allows, +for instance, the developer to pass the same mp\_int as the source and destination to this function without addition +logic to handle it. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_abs.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* b = |a| +018 * +019 * Simple function copies the input and fixes the sign to positive +020 */ +021 int +022 mp_abs (mp_int * a, mp_int * b) +023 \{ +024 int res; +025 +026 /* copy a to b */ +027 if (a != b) \{ +028 if ((res = mp_copy (a, b)) != MP_OKAY) \{ +029 return res; +030 \} +031 \} +032 +033 /* force the sign of b to positive */ +034 b->sign = MP_ZPOS; +035 +036 return MP_OKAY; +037 \} +038 #endif +\end{alltt} +\end{small} + +\subsection{Integer Negation} +With the mp\_int representation of an integer, calculating the negation is also trivial. The mp\_neg algorithm will compute +the negative of an mp\_int input. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_neg}. \\ +\textbf{Input}. An mp\_int $a$ \\ +\textbf{Output}. Computes $b = -a$ \\ +\hline \\ +1. Copy $a$ to $b$. (\textit{mp\_copy}) \\ +2. If the copy failed return(\textit{MP\_MEM}). \\ +3. If $a.used = 0$ then return(\textit{MP\_OKAY}). \\ +4. If $a.sign = MP\_ZPOS$ then do \\ +\hspace{3mm}4.1 $b.sign = MP\_NEG$. \\ +5. else do \\ +\hspace{3mm}5.1 $b.sign = MP\_ZPOS$. \\ +6. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_neg} +\end{figure} + +\textbf{Algorithm mp\_neg.} +This algorithm computes the negation of an input. First it copies $a$ over $b$. If $a$ has no used digits then +the algorithm returns immediately. Otherwise it flips the sign flag and stores the result in $b$. Note that if +$a$ had no digits then it must be positive by definition. Had step three been omitted then the algorithm would return +zero as negative. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_neg.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* b = -a */ +018 int mp_neg (mp_int * a, mp_int * b) +019 \{ +020 int res; +021 if ((res = mp_copy (a, b)) != MP_OKAY) \{ +022 return res; +023 \} +024 if (mp_iszero(b) != MP_YES) \{ +025 b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; +026 \} +027 return MP_OKAY; +028 \} +029 #endif +\end{alltt} +\end{small} + +\section{Small Constants} +\subsection{Setting Small Constants} +Often a mp\_int must be set to a relatively small value such as $1$ or $2$. For these cases the mp\_set algorithm is useful. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_set}. \\ +\textbf{Input}. An mp\_int $a$ and a digit $b$ \\ +\textbf{Output}. Make $a$ equivalent to $b$ \\ +\hline \\ +1. Zero $a$ (\textit{mp\_zero}). \\ +2. $a_0 \leftarrow b \mbox{ (mod }\beta\mbox{)}$ \\ +3. $a.used \leftarrow \left \lbrace \begin{array}{ll} + 1 & \mbox{if }a_0 > 0 \\ + 0 & \mbox{if }a_0 = 0 + \end{array} \right .$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_set} +\end{figure} + +\textbf{Algorithm mp\_set.} +This algorithm sets a mp\_int to a small single digit value. Step number 1 ensures that the integer is reset to the default state. The +single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adjusted accordingly. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_set.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* set to a digit */ +018 void mp_set (mp_int * a, mp_digit b) +019 \{ +020 mp_zero (a); +021 a->dp[0] = b & MP_MASK; +022 a->used = (a->dp[0] != 0) ? 1 : 0; +023 \} +024 #endif +\end{alltt} +\end{small} + +Line 20 calls mp\_zero() to clear the mp\_int and reset the sign. Line 21 copies the digit +into the least significant location. Note the usage of a new constant \textbf{MP\_MASK}. This constant is used to quickly +reduce an integer modulo $\beta$. Since $\beta$ is of the form $2^k$ for any suitable $k$ it suffices to perform a binary AND with +$MP\_MASK = 2^k - 1$ to perform the reduction. Finally line 22 will set the \textbf{used} member with respect to the +digit actually set. This function will always make the integer positive. + +One important limitation of this function is that it will only set one digit. The size of a digit is not fixed, meaning source that uses +this function should take that into account. Only trivially small constants can be set using this function. + +\subsection{Setting Large Constants} +To overcome the limitations of the mp\_set algorithm the mp\_set\_int algorithm is ideal. It accepts a ``long'' +data type as input and will always treat it as a 32-bit integer. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_set\_int}. \\ +\textbf{Input}. An mp\_int $a$ and a ``long'' integer $b$ \\ +\textbf{Output}. Make $a$ equivalent to $b$ \\ +\hline \\ +1. Zero $a$ (\textit{mp\_zero}) \\ +2. for $n$ from 0 to 7 do \\ +\hspace{3mm}2.1 $a \leftarrow a \cdot 16$ (\textit{mp\_mul2d}) \\ +\hspace{3mm}2.2 $u \leftarrow \lfloor b / 2^{4(7 - n)} \rfloor \mbox{ (mod }16\mbox{)}$\\ +\hspace{3mm}2.3 $a_0 \leftarrow a_0 + u$ \\ +\hspace{3mm}2.4 $a.used \leftarrow a.used + 1$ \\ +3. Clamp excess used digits (\textit{mp\_clamp}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_set\_int} +\end{figure} + +\textbf{Algorithm mp\_set\_int.} +The algorithm performs eight iterations of a simple loop where in each iteration four bits from the source are added to the +mp\_int. Step 2.1 will multiply the current result by sixteen making room for four more bits in the less significant positions. In step 2.2 the +next four bits from the source are extracted and are added to the mp\_int. The \textbf{used} digit count is +incremented to reflect the addition. The \textbf{used} digit counter is incremented since if any of the leading digits were zero the mp\_int would have +zero digits used and the newly added four bits would be ignored. + +Excess zero digits are trimmed in steps 2.1 and 3 by using higher level algorithms mp\_mul2d and mp\_clamp. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_set\_int.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* set a 32-bit const */ +018 int mp_set_int (mp_int * a, unsigned long b) +019 \{ +020 int x, res; +021 +022 mp_zero (a); +023 +024 /* set four bits at a time */ +025 for (x = 0; x < 8; x++) \{ +026 /* shift the number up four bits */ +027 if ((res = mp_mul_2d (a, 4, a)) != MP_OKAY) \{ +028 return res; +029 \} +030 +031 /* OR in the top four bits of the source */ +032 a->dp[0] |= (b >> 28) & 15; +033 +034 /* shift the source up to the next four bits */ +035 b <<= 4; +036 +037 /* ensure that digits are not clamped off */ +038 a->used += 1; +039 \} +040 mp_clamp (a); +041 return MP_OKAY; +042 \} +043 #endif +\end{alltt} +\end{small} + +This function sets four bits of the number at a time to handle all practical \textbf{DIGIT\_BIT} sizes. The weird +addition on line 38 ensures that the newly added in bits are added to the number of digits. While it may not +seem obvious as to why the digit counter does not grow exceedingly large it is because of the shift on line 27 +as well as the call to mp\_clamp() on line 40. Both functions will clamp excess leading digits which keeps +the number of used digits low. + +\section{Comparisons} +\subsection{Unsigned Comparisions} +Comparing a multiple precision integer is performed with the exact same algorithm used to compare two decimal numbers. For example, +to compare $1,234$ to $1,264$ the digits are extracted by their positions. That is we compare $1 \cdot 10^3 + 2 \cdot 10^2 + 3 \cdot 10^1 + 4 \cdot 10^0$ +to $1 \cdot 10^3 + 2 \cdot 10^2 + 6 \cdot 10^1 + 4 \cdot 10^0$ by comparing single digits at a time starting with the highest magnitude +positions. If any leading digit of one integer is greater than a digit in the same position of another integer then obviously it must be greater. + +The first comparision routine that will be developed is the unsigned magnitude compare which will perform a comparison based on the digits of two +mp\_int variables alone. It will ignore the sign of the two inputs. Such a function is useful when an absolute comparison is required or if the +signs are known to agree in advance. + +To facilitate working with the results of the comparison functions three constants are required. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{|r|l|} +\hline \textbf{Constant} & \textbf{Meaning} \\ +\hline \textbf{MP\_GT} & Greater Than \\ +\hline \textbf{MP\_EQ} & Equal To \\ +\hline \textbf{MP\_LT} & Less Than \\ +\hline +\end{tabular} +\end{center} +\caption{Comparison Return Codes} +\end{figure} + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_cmp\_mag}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$. \\ +\textbf{Output}. Unsigned comparison results ($a$ to the left of $b$). \\ +\hline \\ +1. If $a.used > b.used$ then return(\textit{MP\_GT}) \\ +2. If $a.used < b.used$ then return(\textit{MP\_LT}) \\ +3. for n from $a.used - 1$ to 0 do \\ +\hspace{+3mm}3.1 if $a_n > b_n$ then return(\textit{MP\_GT}) \\ +\hspace{+3mm}3.2 if $a_n < b_n$ then return(\textit{MP\_LT}) \\ +4. Return(\textit{MP\_EQ}) \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_cmp\_mag} +\end{figure} + +\textbf{Algorithm mp\_cmp\_mag.} +By saying ``$a$ to the left of $b$'' it is meant that the comparison is with respect to $a$, that is if $a$ is greater than $b$ it will return +\textbf{MP\_GT} and similar with respect to when $a = b$ and $a < b$. The first two steps compare the number of digits used in both $a$ and $b$. +Obviously if the digit counts differ there would be an imaginary zero digit in the smaller number where the leading digit of the larger number is. +If both have the same number of digits than the actual digits themselves must be compared starting at the leading digit. + +By step three both inputs must have the same number of digits so its safe to start from either $a.used - 1$ or $b.used - 1$ and count down to +the zero'th digit. If after all of the digits have been compared, no difference is found, the algorithm returns \textbf{MP\_EQ}. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_cmp\_mag.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* compare maginitude of two ints (unsigned) */ +018 int mp_cmp_mag (mp_int * a, mp_int * b) +019 \{ +020 int n; +021 mp_digit *tmpa, *tmpb; +022 +023 /* compare based on # of non-zero digits */ +024 if (a->used > b->used) \{ +025 return MP_GT; +026 \} +027 +028 if (a->used < b->used) \{ +029 return MP_LT; +030 \} +031 +032 /* alias for a */ +033 tmpa = a->dp + (a->used - 1); +034 +035 /* alias for b */ +036 tmpb = b->dp + (a->used - 1); +037 +038 /* compare based on digits */ +039 for (n = 0; n < a->used; ++n, --tmpa, --tmpb) \{ +040 if (*tmpa > *tmpb) \{ +041 return MP_GT; +042 \} +043 +044 if (*tmpa < *tmpb) \{ +045 return MP_LT; +046 \} +047 \} +048 return MP_EQ; +049 \} +050 #endif +\end{alltt} +\end{small} + +The two if statements on lines 24 and 28 compare the number of digits in the two inputs. These two are performed before all of the digits +are compared since it is a very cheap test to perform and can potentially save considerable time. The implementation given is also not valid +without those two statements. $b.alloc$ may be smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the +array of digits. + +\subsection{Signed Comparisons} +Comparing with sign considerations is also fairly critical in several routines (\textit{division for example}). Based on an unsigned magnitude +comparison a trivial signed comparison algorithm can be written. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_cmp}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. Signed Comparison Results ($a$ to the left of $b$) \\ +\hline \\ +1. if $a.sign = MP\_NEG$ and $b.sign = MP\_ZPOS$ then return(\textit{MP\_LT}) \\ +2. if $a.sign = MP\_ZPOS$ and $b.sign = MP\_NEG$ then return(\textit{MP\_GT}) \\ +3. if $a.sign = MP\_NEG$ then \\ +\hspace{+3mm}3.1 Return the unsigned comparison of $b$ and $a$ (\textit{mp\_cmp\_mag}) \\ +4 Otherwise \\ +\hspace{+3mm}4.1 Return the unsigned comparison of $a$ and $b$ \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_cmp} +\end{figure} + +\textbf{Algorithm mp\_cmp.} +The first two steps compare the signs of the two inputs. If the signs do not agree then it can return right away with the appropriate +comparison code. When the signs are equal the digits of the inputs must be compared to determine the correct result. In step +three the unsigned comparision flips the order of the arguments since they are both negative. For instance, if $-a > -b$ then +$\vert a \vert < \vert b \vert$. Step number four will compare the two when they are both positive. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_cmp.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* compare two ints (signed)*/ +018 int +019 mp_cmp (mp_int * a, mp_int * b) +020 \{ +021 /* compare based on sign */ +022 if (a->sign != b->sign) \{ +023 if (a->sign == MP_NEG) \{ +024 return MP_LT; +025 \} else \{ +026 return MP_GT; +027 \} +028 \} +029 +030 /* compare digits */ +031 if (a->sign == MP_NEG) \{ +032 /* if negative compare opposite direction */ +033 return mp_cmp_mag(b, a); +034 \} else \{ +035 return mp_cmp_mag(a, b); +036 \} +037 \} +038 #endif +\end{alltt} +\end{small} + +The two if statements on lines 22 and 23 perform the initial sign comparison. If the signs are not the equal then which ever +has the positive sign is larger. At line 31, the inputs are compared based on magnitudes. If the signs were both negative then +the unsigned comparison is performed in the opposite direction (\textit{line 33}). Otherwise, the signs are assumed to +be both positive and a forward direction unsigned comparison is performed. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 2 \right ]$ & Modify algorithm mp\_set\_int to accept as input a variable length array of bits. \\ + & \\ +$\left [ 3 \right ]$ & Give the probability that algorithm mp\_cmp\_mag will have to compare $k$ digits \\ + & of two random digits (of equal magnitude) before a difference is found. \\ + & \\ +$\left [ 1 \right ]$ & Suggest a simple method to speed up the implementation of mp\_cmp\_mag based \\ + & on the observations made in the previous problem. \\ + & +\end{tabular} + +\chapter{Basic Arithmetic} +\section{Introduction} +At this point algorithms for initialization, clearing, zeroing, copying, comparing and setting small constants have been +established. The next logical set of algorithms to develop are addition, subtraction and digit shifting algorithms. These +algorithms make use of the lower level algorithms and are the cruicial building block for the multiplication algorithms. It is very important +that these algorithms are highly optimized. On their own they are simple $O(n)$ algorithms but they can be called from higher level algorithms +which easily places them at $O(n^2)$ or even $O(n^3)$ work levels. + +All of the algorithms within this chapter make use of the logical bit shift operations denoted by $<<$ and $>>$ for left and right +logical shifts respectively. A logical shift is analogous to sliding the decimal point of radix-10 representations. For example, the real +number $0.9345$ is equivalent to $93.45\%$ which is found by sliding the the decimal two places to the right (\textit{multiplying by $\beta^2 = 10^2$}). +Algebraically a binary logical shift is equivalent to a division or multiplication by a power of two. +For example, $a << k = a \cdot 2^k$ while $a >> k = \lfloor a/2^k \rfloor$. + +One significant difference between a logical shift and the way decimals are shifted is that digits below the zero'th position are removed +from the number. For example, consider $1101_2 >> 1$ using decimal notation this would produce $110.1_2$. However, with a logical shift the +result is $110_2$. + +\section{Addition and Subtraction} +In common twos complement fixed precision arithmetic negative numbers are easily represented by subtraction from the modulus. For example, with 32-bit integers +$a - b\mbox{ (mod }2^{32}\mbox{)}$ is the same as $a + (2^{32} - b) \mbox{ (mod }2^{32}\mbox{)}$ since $2^{32} \equiv 0 \mbox{ (mod }2^{32}\mbox{)}$. +As a result subtraction can be performed with a trivial series of logical operations and an addition. + +However, in multiple precision arithmetic negative numbers are not represented in the same way. Instead a sign flag is used to keep track of the +sign of the integer. As a result signed addition and subtraction are actually implemented as conditional usage of lower level addition or +subtraction algorithms with the sign fixed up appropriately. + +The lower level algorithms will add or subtract integers without regard to the sign flag. That is they will add or subtract the magnitude of +the integers respectively. + +\subsection{Low Level Addition} +An unsigned addition of multiple precision integers is performed with the same long-hand algorithm used to add decimal numbers. That is to add the +trailing digits first and propagate the resulting carry upwards. Since this is a lower level algorithm the name will have a ``s\_'' prefix. +Historically that convention stems from the MPI library where ``s\_'' stood for static functions that were hidden from the developer entirely. + +\newpage +\begin{figure}[!here] +\begin{center} +\begin{small} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_add}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The unsigned addition $c = \vert a \vert + \vert b \vert$. \\ +\hline \\ +1. if $a.used > b.used$ then \\ +\hspace{+3mm}1.1 $min \leftarrow b.used$ \\ +\hspace{+3mm}1.2 $max \leftarrow a.used$ \\ +\hspace{+3mm}1.3 $x \leftarrow a$ \\ +2. else \\ +\hspace{+3mm}2.1 $min \leftarrow a.used$ \\ +\hspace{+3mm}2.2 $max \leftarrow b.used$ \\ +\hspace{+3mm}2.3 $x \leftarrow b$ \\ +3. If $c.alloc < max + 1$ then grow $c$ to hold at least $max + 1$ digits (\textit{mp\_grow}) \\ +4. $oldused \leftarrow c.used$ \\ +5. $c.used \leftarrow max + 1$ \\ +6. $u \leftarrow 0$ \\ +7. for $n$ from $0$ to $min - 1$ do \\ +\hspace{+3mm}7.1 $c_n \leftarrow a_n + b_n + u$ \\ +\hspace{+3mm}7.2 $u \leftarrow c_n >> lg(\beta)$ \\ +\hspace{+3mm}7.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +8. if $min \ne max$ then do \\ +\hspace{+3mm}8.1 for $n$ from $min$ to $max - 1$ do \\ +\hspace{+6mm}8.1.1 $c_n \leftarrow x_n + u$ \\ +\hspace{+6mm}8.1.2 $u \leftarrow c_n >> lg(\beta)$ \\ +\hspace{+6mm}8.1.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +9. $c_{max} \leftarrow u$ \\ +10. if $olduse > max$ then \\ +\hspace{+3mm}10.1 for $n$ from $max + 1$ to $oldused - 1$ do \\ +\hspace{+6mm}10.1.1 $c_n \leftarrow 0$ \\ +11. Clamp excess digits in $c$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Algorithm s\_mp\_add} +\end{figure} + +\textbf{Algorithm s\_mp\_add.} +This algorithm is loosely based on algorithm 14.7 of HAC \cite[pp. 594]{HAC} but has been extended to allow the inputs to have different magnitudes. +Coincidentally the description of algorithm A in Knuth \cite[pp. 266]{TAOCPV2} shares the same deficiency as the algorithm from \cite{HAC}. Even the +MIX pseudo machine code presented by Knuth \cite[pp. 266-267]{TAOCPV2} is incapable of handling inputs which are of different magnitudes. + +The first thing that has to be accomplished is to sort out which of the two inputs is the largest. The addition logic +will simply add all of the smallest input to the largest input and store that first part of the result in the +destination. Then it will apply a simpler addition loop to excess digits of the larger input. + +The first two steps will handle sorting the inputs such that $min$ and $max$ hold the digit counts of the two +inputs. The variable $x$ will be an mp\_int alias for the largest input or the second input $b$ if they have the +same number of digits. After the inputs are sorted the destination $c$ is grown as required to accomodate the sum +of the two inputs. The original \textbf{used} count of $c$ is copied and set to the new used count. + +At this point the first addition loop will go through as many digit positions that both inputs have. The carry +variable $\mu$ is set to zero outside the loop. Inside the loop an ``addition'' step requires three statements to produce +one digit of the summand. First +two digits from $a$ and $b$ are added together along with the carry $\mu$. The carry of this step is extracted and stored +in $\mu$ and finally the digit of the result $c_n$ is truncated within the range $0 \le c_n < \beta$. + +Now all of the digit positions that both inputs have in common have been exhausted. If $min \ne max$ then $x$ is an alias +for one of the inputs that has more digits. A simplified addition loop is then used to essentially copy the remaining digits +and the carry to the destination. + +The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are zeroed which completes the addition. + + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_s\_mp\_add.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* low level addition, based on HAC pp.594, Algorithm 14.7 */ +018 int +019 s_mp_add (mp_int * a, mp_int * b, mp_int * c) +020 \{ +021 mp_int *x; +022 int olduse, res, min, max; +023 +024 /* find sizes, we let |a| <= |b| which means we have to sort +025 * them. "x" will point to the input with the most digits +026 */ +027 if (a->used > b->used) \{ +028 min = b->used; +029 max = a->used; +030 x = a; +031 \} else \{ +032 min = a->used; +033 max = b->used; +034 x = b; +035 \} +036 +037 /* init result */ +038 if (c->alloc < max + 1) \{ +039 if ((res = mp_grow (c, max + 1)) != MP_OKAY) \{ +040 return res; +041 \} +042 \} +043 +044 /* get old used digit count and set new one */ +045 olduse = c->used; +046 c->used = max + 1; +047 +048 \{ +049 register mp_digit u, *tmpa, *tmpb, *tmpc; +050 register int i; +051 +052 /* alias for digit pointers */ +053 +054 /* first input */ +055 tmpa = a->dp; +056 +057 /* second input */ +058 tmpb = b->dp; +059 +060 /* destination */ +061 tmpc = c->dp; +062 +063 /* zero the carry */ +064 u = 0; +065 for (i = 0; i < min; i++) \{ +066 /* Compute the sum at one digit, T[i] = A[i] + B[i] + U */ +067 *tmpc = *tmpa++ + *tmpb++ + u; +068 +069 /* U = carry bit of T[i] */ +070 u = *tmpc >> ((mp_digit)DIGIT_BIT); +071 +072 /* take away carry bit from T[i] */ +073 *tmpc++ &= MP_MASK; +074 \} +075 +076 /* now copy higher words if any, that is in A+B +077 * if A or B has more digits add those in +078 */ +079 if (min != max) \{ +080 for (; i < max; i++) \{ +081 /* T[i] = X[i] + U */ +082 *tmpc = x->dp[i] + u; +083 +084 /* U = carry bit of T[i] */ +085 u = *tmpc >> ((mp_digit)DIGIT_BIT); +086 +087 /* take away carry bit from T[i] */ +088 *tmpc++ &= MP_MASK; +089 \} +090 \} +091 +092 /* add carry */ +093 *tmpc++ = u; +094 +095 /* clear digits above oldused */ +096 for (i = c->used; i < olduse; i++) \{ +097 *tmpc++ = 0; +098 \} +099 \} +100 +101 mp_clamp (c); +102 return MP_OKAY; +103 \} +104 #endif +\end{alltt} +\end{small} + +Lines 27 to 35 perform the initial sorting of the inputs and determine the $min$ and $max$ variables. Note that $x$ is a pointer to a +mp\_int assigned to the largest input, in effect it is a local alias. Lines 37 to 42 ensure that the destination is grown to +accomodate the result of the addition. + +Similar to the implementation of mp\_copy this function uses the braced code and local aliases coding style. The three aliases that are on +lines 55, 58 and 61 represent the two inputs and destination variables respectively. These aliases are used to ensure the +compiler does not have to dereference $a$, $b$ or $c$ (respectively) to access the digits of the respective mp\_int. + +The initial carry $u$ is cleared on line 64, note that $u$ is of type mp\_digit which ensures type compatibility within the +implementation. The initial addition loop begins on line 65 and ends on line 74. Similarly the conditional addition loop +begins on line 80 and ends on line 90. The addition is finished with the final carry being stored in $tmpc$ on line 93. +Note the ``++'' operator on the same line. After line 93 $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful +for the next loop on lines 96 to 99 which set any old upper digits to zero. + +\subsection{Low Level Subtraction} +The low level unsigned subtraction algorithm is very similar to the low level unsigned addition algorithm. The principle difference is that the +unsigned subtraction algorithm requires the result to be positive. That is when computing $a - b$ the condition $\vert a \vert \ge \vert b\vert$ must +be met for this algorithm to function properly. Keep in mind this low level algorithm is not meant to be used in higher level algorithms directly. +This algorithm as will be shown can be used to create functional signed addition and subtraction algorithms. + + +For this algorithm a new variable is required to make the description simpler. Recall from section 1.3.1 that a mp\_digit must be able to represent +the range $0 \le x < 2\beta$ for the algorithms to work correctly. However, it is allowable that a mp\_digit represent a larger range of values. For +this algorithm we will assume that the variable $\gamma$ represents the number of bits available in a +mp\_digit (\textit{this implies $2^{\gamma} > \beta$}). + +For example, the default for LibTomMath is to use a ``unsigned long'' for the mp\_digit ``type'' while $\beta = 2^{28}$. In ISO C an ``unsigned long'' +data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma = 32$. + +\newpage\begin{figure}[!here] +\begin{center} +\begin{small} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_sub}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ ($\vert a \vert \ge \vert b \vert$) \\ +\textbf{Output}. The unsigned subtraction $c = \vert a \vert - \vert b \vert$. \\ +\hline \\ +1. $min \leftarrow b.used$ \\ +2. $max \leftarrow a.used$ \\ +3. If $c.alloc < max$ then grow $c$ to hold at least $max$ digits. (\textit{mp\_grow}) \\ +4. $oldused \leftarrow c.used$ \\ +5. $c.used \leftarrow max$ \\ +6. $u \leftarrow 0$ \\ +7. for $n$ from $0$ to $min - 1$ do \\ +\hspace{3mm}7.1 $c_n \leftarrow a_n - b_n - u$ \\ +\hspace{3mm}7.2 $u \leftarrow c_n >> (\gamma - 1)$ \\ +\hspace{3mm}7.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +8. if $min < max$ then do \\ +\hspace{3mm}8.1 for $n$ from $min$ to $max - 1$ do \\ +\hspace{6mm}8.1.1 $c_n \leftarrow a_n - u$ \\ +\hspace{6mm}8.1.2 $u \leftarrow c_n >> (\gamma - 1)$ \\ +\hspace{6mm}8.1.3 $c_n \leftarrow c_n \mbox{ (mod }\beta\mbox{)}$ \\ +9. if $oldused > max$ then do \\ +\hspace{3mm}9.1 for $n$ from $max$ to $oldused - 1$ do \\ +\hspace{6mm}9.1.1 $c_n \leftarrow 0$ \\ +10. Clamp excess digits of $c$. (\textit{mp\_clamp}). \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Algorithm s\_mp\_sub} +\end{figure} + +\textbf{Algorithm s\_mp\_sub.} +This algorithm performs the unsigned subtraction of two mp\_int variables under the restriction that the result must be positive. That is when +passing variables $a$ and $b$ the condition that $\vert a \vert \ge \vert b \vert$ must be met for the algorithm to function correctly. This +algorithm is loosely based on algorithm 14.9 \cite[pp. 595]{HAC} and is similar to algorithm S in \cite[pp. 267]{TAOCPV2} as well. As was the case +of the algorithm s\_mp\_add both other references lack discussion concerning various practical details such as when the inputs differ in magnitude. + +The initial sorting of the inputs is trivial in this algorithm since $a$ is guaranteed to have at least the same magnitude of $b$. Steps 1 and 2 +set the $min$ and $max$ variables. Unlike the addition routine there is guaranteed to be no carry which means that the final result can be at +most $max$ digits in length as opposed to $max + 1$. Similar to the addition algorithm the \textbf{used} count of $c$ is copied locally and +set to the maximal count for the operation. + +The subtraction loop that begins on step seven is essentially the same as the addition loop of algorithm s\_mp\_add except single precision +subtraction is used instead. Note the use of the $\gamma$ variable to extract the carry (\textit{also known as the borrow}) within the subtraction +loops. Under the assumption that two's complement single precision arithmetic is used this will successfully extract the desired carry. + +For example, consider subtracting $0101_2$ from $0100_2$ where $\gamma = 4$ and $\beta = 2$. The least significant bit will force a carry upwards to +the third bit which will be set to zero after the borrow. After the very first bit has been subtracted $4 - 1 \equiv 0011_2$ will remain, When the +third bit of $0101_2$ is subtracted from the result it will cause another carry. In this case though the carry will be forced to propagate all the +way to the most significant bit. + +Recall that $\beta < 2^{\gamma}$. This means that if a carry does occur just before the $lg(\beta)$'th bit it will propagate all the way to the most +significant bit. Thus, the high order bits of the mp\_digit that are not part of the actual digit will either be all zero, or all one. All that +is needed is a single zero or one bit for the carry. Therefore a single logical shift right by $\gamma - 1$ positions is sufficient to extract the +carry. This method of carry extraction may seem awkward but the reason for it becomes apparent when the implementation is discussed. + +If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and copy operation to propagate through the larger input $a$ into $c$. Step +10 will ensure that any leading digits of $c$ above the $max$'th position are zeroed. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_s\_mp\_sub.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ +018 int +019 s_mp_sub (mp_int * a, mp_int * b, mp_int * c) +020 \{ +021 int olduse, res, min, max; +022 +023 /* find sizes */ +024 min = b->used; +025 max = a->used; +026 +027 /* init result */ +028 if (c->alloc < max) \{ +029 if ((res = mp_grow (c, max)) != MP_OKAY) \{ +030 return res; +031 \} +032 \} +033 olduse = c->used; +034 c->used = max; +035 +036 \{ +037 register mp_digit u, *tmpa, *tmpb, *tmpc; +038 register int i; +039 +040 /* alias for digit pointers */ +041 tmpa = a->dp; +042 tmpb = b->dp; +043 tmpc = c->dp; +044 +045 /* set carry to zero */ +046 u = 0; +047 for (i = 0; i < min; i++) \{ +048 /* T[i] = A[i] - B[i] - U */ +049 *tmpc = *tmpa++ - *tmpb++ - u; +050 +051 /* U = carry bit of T[i] +052 * Note this saves performing an AND operation since +053 * if a carry does occur it will propagate all the way to the +054 * MSB. As a result a single shift is enough to get the carry +055 */ +056 u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); +057 +058 /* Clear carry from T[i] */ +059 *tmpc++ &= MP_MASK; +060 \} +061 +062 /* now copy higher words if any, e.g. if A has more digits than B */ +063 for (; i < max; i++) \{ +064 /* T[i] = A[i] - U */ +065 *tmpc = *tmpa++ - u; +066 +067 /* U = carry bit of T[i] */ +068 u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); +069 +070 /* Clear carry from T[i] */ +071 *tmpc++ &= MP_MASK; +072 \} +073 +074 /* clear digits above used (since we may not have grown result above) */ + +075 for (i = c->used; i < olduse; i++) \{ +076 *tmpc++ = 0; +077 \} +078 \} +079 +080 mp_clamp (c); +081 return MP_OKAY; +082 \} +083 +084 #endif +\end{alltt} +\end{small} + +Line 24 and 25 perform the initial hardcoded sorting of the inputs. In reality the $min$ and $max$ variables are only aliases and are only +used to make the source code easier to read. Again the pointer alias optimization is used within this algorithm. Lines 41, 42 and 43 initialize the aliases for +$a$, $b$ and $c$ respectively. + +The first subtraction loop occurs on lines 46 through 60. The theory behind the subtraction loop is exactly the same as that for +the addition loop. As remarked earlier there is an implementation reason for using the ``awkward'' method of extracting the carry +(\textit{see line 56}). The traditional method for extracting the carry would be to shift by $lg(\beta)$ positions and logically AND +the least significant bit. The AND operation is required because all of the bits above the $\lg(\beta)$'th bit will be set to one after a carry +occurs from subtraction. This carry extraction requires two relatively cheap operations to extract the carry. The other method is to simply +shift the most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This optimization only works on +twos compliment machines which is a safe assumption to make. + +If $a$ has a larger magnitude than $b$ an additional loop (\textit{see lines 63 through 72}) is required to propagate the carry through +$a$ and copy the result to $c$. + +\subsection{High Level Addition} +Now that both lower level addition and subtraction algorithms have been established an effective high level signed addition algorithm can be +established. This high level addition algorithm will be what other algorithms and developers will use to perform addition of mp\_int data +types. + +Recall from section 5.2 that an mp\_int represents an integer with an unsigned mantissa (\textit{the array of digits}) and a \textbf{sign} +flag. A high level addition is actually performed as a series of eight separate cases which can be optimized down to three unique cases. + +\begin{figure}[!here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_add}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The signed addition $c = a + b$. \\ +\hline \\ +1. if $a.sign = b.sign$ then do \\ +\hspace{3mm}1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{3mm}1.2 $c \leftarrow \vert a \vert + \vert b \vert$ (\textit{s\_mp\_add})\\ +2. else do \\ +\hspace{3mm}2.1 if $\vert a \vert < \vert b \vert$ then do (\textit{mp\_cmp\_mag}) \\ +\hspace{6mm}2.1.1 $c.sign \leftarrow b.sign$ \\ +\hspace{6mm}2.1.2 $c \leftarrow \vert b \vert - \vert a \vert$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c.sign \leftarrow a.sign$ \\ +\hspace{6mm}2.2.2 $c \leftarrow \vert a \vert - \vert b \vert$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_add} +\end{figure} + +\textbf{Algorithm mp\_add.} +This algorithm performs the signed addition of two mp\_int variables. There is no reference algorithm to draw upon from +either \cite{TAOCPV2} or \cite{HAC} since they both only provide unsigned operations. The algorithm is fairly +straightforward but restricted since subtraction can only produce positive results. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|} +\hline \textbf{Sign of $a$} & \textbf{Sign of $b$} & \textbf{$\vert a \vert > \vert b \vert $} & \textbf{Unsigned Operation} & \textbf{Result Sign Flag} \\ +\hline $+$ & $+$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $+$ & $+$ & No & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $-$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $-$ & No & $c = a + b$ & $a.sign$ \\ +\hline &&&&\\ + +\hline $+$ & $-$ & No & $c = b - a$ & $b.sign$ \\ +\hline $-$ & $+$ & No & $c = b - a$ & $b.sign$ \\ + +\hline &&&&\\ + +\hline $+$ & $-$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline $-$ & $+$ & Yes & $c = a - b$ & $a.sign$ \\ + +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Addition Guide Chart} +\label{fig:AddChart} +\end{figure} + +Figure~\ref{fig:AddChart} lists all of the eight possible input combinations and is sorted to show that only three +specific cases need to be handled. The return code of the unsigned operations at step 1.2, 2.1.2 and 2.2.2 are +forwarded to step three to check for errors. This simplifies the description of the algorithm considerably and best +follows how the implementation actually was achieved. + +Also note how the \textbf{sign} is set before the unsigned addition or subtraction is performed. Recall from the descriptions of algorithms +s\_mp\_add and s\_mp\_sub that the mp\_clamp function is used at the end to trim excess digits. The mp\_clamp algorithm will set the \textbf{sign} +to \textbf{MP\_ZPOS} when the \textbf{used} digit count reaches zero. + +For example, consider performing $-a + a$ with algorithm mp\_add. By the description of the algorithm the sign is set to \textbf{MP\_NEG} which would +produce a result of $-0$. However, since the sign is set first then the unsigned addition is performed the subsequent usage of algorithm mp\_clamp +within algorithm s\_mp\_add will force $-0$ to become $0$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_add.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* high level addition (handles signs) */ +018 int mp_add (mp_int * a, mp_int * b, mp_int * c) +019 \{ +020 int sa, sb, res; +021 +022 /* get sign of both inputs */ +023 sa = a->sign; +024 sb = b->sign; +025 +026 /* handle two cases, not four */ +027 if (sa == sb) \{ +028 /* both positive or both negative */ +029 /* add their magnitudes, copy the sign */ +030 c->sign = sa; +031 res = s_mp_add (a, b, c); +032 \} else \{ +033 /* one positive, the other negative */ +034 /* subtract the one with the greater magnitude from */ +035 /* the one of the lesser magnitude. The result gets */ +036 /* the sign of the one with the greater magnitude. */ +037 if (mp_cmp_mag (a, b) == MP_LT) \{ +038 c->sign = sb; +039 res = s_mp_sub (b, a, c); +040 \} else \{ +041 c->sign = sa; +042 res = s_mp_sub (a, b, c); +043 \} +044 \} +045 return res; +046 \} +047 +048 #endif +\end{alltt} +\end{small} + +The source code follows the algorithm fairly closely. The most notable new source code addition is the usage of the $res$ integer variable which +is used to pass result of the unsigned operations forward. Unlike in the algorithm, the variable $res$ is merely returned as is without +explicitly checking it and returning the constant \textbf{MP\_OKAY}. The observation is this algorithm will succeed or fail only if the lower +level functions do so. Returning their return code is sufficient. + +\subsection{High Level Subtraction} +The high level signed subtraction algorithm is essentially the same as the high level signed addition algorithm. + +\newpage\begin{figure}[!here] +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_sub}. \\ +\textbf{Input}. Two mp\_ints $a$ and $b$ \\ +\textbf{Output}. The signed subtraction $c = a - b$. \\ +\hline \\ +1. if $a.sign \ne b.sign$ then do \\ +\hspace{3mm}1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{3mm}1.2 $c \leftarrow \vert a \vert + \vert b \vert$ (\textit{s\_mp\_add}) \\ +2. else do \\ +\hspace{3mm}2.1 if $\vert a \vert \ge \vert b \vert$ then do (\textit{mp\_cmp\_mag}) \\ +\hspace{6mm}2.1.1 $c.sign \leftarrow a.sign$ \\ +\hspace{6mm}2.1.2 $c \leftarrow \vert a \vert - \vert b \vert$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c.sign \leftarrow \left \lbrace \begin{array}{ll} + MP\_ZPOS & \mbox{if }a.sign = MP\_NEG \\ + MP\_NEG & \mbox{otherwise} \\ + \end{array} \right .$ \\ +\hspace{6mm}2.2.2 $c \leftarrow \vert b \vert - \vert a \vert$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\caption{Algorithm mp\_sub} +\end{figure} + +\textbf{Algorithm mp\_sub.} +This algorithm performs the signed subtraction of two inputs. Similar to algorithm mp\_add there is no reference in either \cite{TAOCPV2} or +\cite{HAC}. Also this algorithm is restricted by algorithm s\_mp\_sub. Chart \ref{fig:SubChart} lists the eight possible inputs and +the operations required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|} +\hline \textbf{Sign of $a$} & \textbf{Sign of $b$} & \textbf{$\vert a \vert \ge \vert b \vert $} & \textbf{Unsigned Operation} & \textbf{Result Sign Flag} \\ +\hline $+$ & $-$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $+$ & $-$ & No & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $+$ & Yes & $c = a + b$ & $a.sign$ \\ +\hline $-$ & $+$ & No & $c = a + b$ & $a.sign$ \\ +\hline &&&& \\ +\hline $+$ & $+$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline $-$ & $-$ & Yes & $c = a - b$ & $a.sign$ \\ +\hline &&&& \\ +\hline $+$ & $+$ & No & $c = b - a$ & $\mbox{opposite of }a.sign$ \\ +\hline $-$ & $-$ & No & $c = b - a$ & $\mbox{opposite of }a.sign$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Subtraction Guide Chart} +\label{fig:SubChart} +\end{figure} + +Similar to the case of algorithm mp\_add the \textbf{sign} is set first before the unsigned addition or subtraction. That is to prevent the +algorithm from producing $-a - -a = -0$ as a result. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_sub.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* high level subtraction (handles signs) */ +018 int +019 mp_sub (mp_int * a, mp_int * b, mp_int * c) +020 \{ +021 int sa, sb, res; +022 +023 sa = a->sign; +024 sb = b->sign; +025 +026 if (sa != sb) \{ +027 /* subtract a negative from a positive, OR */ +028 /* subtract a positive from a negative. */ +029 /* In either case, ADD their magnitudes, */ +030 /* and use the sign of the first number. */ +031 c->sign = sa; +032 res = s_mp_add (a, b, c); +033 \} else \{ +034 /* subtract a positive from a positive, OR */ +035 /* subtract a negative from a negative. */ +036 /* First, take the difference between their */ +037 /* magnitudes, then... */ +038 if (mp_cmp_mag (a, b) != MP_LT) \{ +039 /* Copy the sign from the first */ +040 c->sign = sa; +041 /* The first has a larger or equal magnitude */ +042 res = s_mp_sub (a, b, c); +043 \} else \{ +044 /* The result has the *opposite* sign from */ +045 /* the first number. */ +046 c->sign = (sa == MP_ZPOS) ? MP_NEG : MP_ZPOS; +047 /* The second has a larger magnitude */ +048 res = s_mp_sub (b, a, c); +049 \} +050 \} +051 return res; +052 \} +053 +054 #endif +\end{alltt} +\end{small} + +Much like the implementation of algorithm mp\_add the variable $res$ is used to catch the return code of the unsigned addition or subtraction operations +and forward it to the end of the function. On line 38 the ``not equal to'' \textbf{MP\_LT} expression is used to emulate a +``greater than or equal to'' comparison. + +\section{Bit and Digit Shifting} +It is quite common to think of a multiple precision integer as a polynomial in $x$, that is $y = f(\beta)$ where $f(x) = \sum_{i=0}^{n-1} a_i x^i$. +This notation arises within discussion of Montgomery and Diminished Radix Reduction as well as Karatsuba multiplication and squaring. + +In order to facilitate operations on polynomials in $x$ as above a series of simple ``digit'' algorithms have to be established. That is to shift +the digits left or right as well to shift individual bits of the digits left and right. It is important to note that not all ``shift'' operations +are on radix-$\beta$ digits. + +\subsection{Multiplication by Two} + +In a binary system where the radix is a power of two multiplication by two not only arises often in other algorithms it is a fairly efficient +operation to perform. A single precision logical shift left is sufficient to multiply a single digit by two. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_2}. \\ +\textbf{Input}. One mp\_int $a$ \\ +\textbf{Output}. $b = 2a$. \\ +\hline \\ +1. If $b.alloc < a.used + 1$ then grow $b$ to hold $a.used + 1$ digits. (\textit{mp\_grow}) \\ +2. $oldused \leftarrow b.used$ \\ +3. $b.used \leftarrow a.used$ \\ +4. $r \leftarrow 0$ \\ +5. for $n$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}5.1 $rr \leftarrow a_n >> (lg(\beta) - 1)$ \\ +\hspace{3mm}5.2 $b_n \leftarrow (a_n << 1) + r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}5.3 $r \leftarrow rr$ \\ +6. If $r \ne 0$ then do \\ +\hspace{3mm}6.1 $b_{n + 1} \leftarrow r$ \\ +\hspace{3mm}6.2 $b.used \leftarrow b.used + 1$ \\ +7. If $b.used < oldused - 1$ then do \\ +\hspace{3mm}7.1 for $n$ from $b.used$ to $oldused - 1$ do \\ +\hspace{6mm}7.1.1 $b_n \leftarrow 0$ \\ +8. $b.sign \leftarrow a.sign$ \\ +9. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_2} +\end{figure} + +\textbf{Algorithm mp\_mul\_2.} +This algorithm will quickly multiply a mp\_int by two provided $\beta$ is a power of two. Neither \cite{TAOCPV2} nor \cite{HAC} describe such +an algorithm despite the fact it arises often in other algorithms. The algorithm is setup much like the lower level algorithm s\_mp\_add since +it is for all intents and purposes equivalent to the operation $b = \vert a \vert + \vert a \vert$. + +Step 1 and 2 grow the input as required to accomodate the maximum number of \textbf{used} digits in the result. The initial \textbf{used} count +is set to $a.used$ at step 4. Only if there is a final carry will the \textbf{used} count require adjustment. + +Step 6 is an optimization implementation of the addition loop for this specific case. That is since the two values being added together +are the same there is no need to perform two reads from the digits of $a$. Step 6.1 performs a single precision shift on the current digit $a_n$ to +obtain what will be the carry for the next iteration. Step 6.2 calculates the $n$'th digit of the result as single precision shift of $a_n$ plus +the previous carry. Recall from section 4.1 that $a_n << 1$ is equivalent to $a_n \cdot 2$. An iteration of the addition loop is finished with +forwarding the carry to the next iteration. + +Step 7 takes care of any final carry by setting the $a.used$'th digit of the result to the carry and augmenting the \textbf{used} count of $b$. +Step 8 clears any leading digits of $b$ in case it originally had a larger magnitude than $a$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_2.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* b = a*2 */ +018 int mp_mul_2(mp_int * a, mp_int * b) +019 \{ +020 int x, res, oldused; +021 +022 /* grow to accomodate result */ +023 if (b->alloc < a->used + 1) \{ +024 if ((res = mp_grow (b, a->used + 1)) != MP_OKAY) \{ +025 return res; +026 \} +027 \} +028 +029 oldused = b->used; +030 b->used = a->used; +031 +032 \{ +033 register mp_digit r, rr, *tmpa, *tmpb; +034 +035 /* alias for source */ +036 tmpa = a->dp; +037 +038 /* alias for dest */ +039 tmpb = b->dp; +040 +041 /* carry */ +042 r = 0; +043 for (x = 0; x < a->used; x++) \{ +044 +045 /* get what will be the *next* carry bit from the +046 * MSB of the current digit +047 */ +048 rr = *tmpa >> ((mp_digit)(DIGIT_BIT - 1)); +049 +050 /* now shift up this digit, add in the carry [from the previous] */ +051 *tmpb++ = ((*tmpa++ << ((mp_digit)1)) | r) & MP_MASK; +052 +053 /* copy the carry that would be from the source +054 * digit into the next iteration +055 */ +056 r = rr; +057 \} +058 +059 /* new leading digit? */ +060 if (r != 0) \{ +061 /* add a MSB which is always 1 at this point */ +062 *tmpb = 1; +063 ++(b->used); +064 \} +065 +066 /* now zero any excess digits on the destination +067 * that we didn't write to +068 */ +069 tmpb = b->dp + b->used; +070 for (x = b->used; x < oldused; x++) \{ +071 *tmpb++ = 0; +072 \} +073 \} +074 b->sign = a->sign; +075 return MP_OKAY; +076 \} +077 #endif +\end{alltt} +\end{small} + +This implementation is essentially an optimized implementation of s\_mp\_add for the case of doubling an input. The only noteworthy difference +is the use of the logical shift operator on line 51 to perform a single precision doubling. + +\subsection{Division by Two} +A division by two can just as easily be accomplished with a logical shift right as multiplication by two can be with a logical shift left. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_2}. \\ +\textbf{Input}. One mp\_int $a$ \\ +\textbf{Output}. $b = a/2$. \\ +\hline \\ +1. If $b.alloc < a.used$ then grow $b$ to hold $a.used$ digits. (\textit{mp\_grow}) \\ +2. If the reallocation failed return(\textit{MP\_MEM}). \\ +3. $oldused \leftarrow b.used$ \\ +4. $b.used \leftarrow a.used$ \\ +5. $r \leftarrow 0$ \\ +6. for $n$ from $b.used - 1$ to $0$ do \\ +\hspace{3mm}6.1 $rr \leftarrow a_n \mbox{ (mod }2\mbox{)}$\\ +\hspace{3mm}6.2 $b_n \leftarrow (a_n >> 1) + (r << (lg(\beta) - 1)) \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}6.3 $r \leftarrow rr$ \\ +7. If $b.used < oldused - 1$ then do \\ +\hspace{3mm}7.1 for $n$ from $b.used$ to $oldused - 1$ do \\ +\hspace{6mm}7.1.1 $b_n \leftarrow 0$ \\ +8. $b.sign \leftarrow a.sign$ \\ +9. Clamp excess digits of $b$. (\textit{mp\_clamp}) \\ +10. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_2} +\end{figure} + +\textbf{Algorithm mp\_div\_2.} +This algorithm will divide an mp\_int by two using logical shifts to the right. Like mp\_mul\_2 it uses a modified low level addition +core as the basis of the algorithm. Unlike mp\_mul\_2 the shift operations work from the leading digit to the trailing digit. The algorithm +could be written to work from the trailing digit to the leading digit however, it would have to stop one short of $a.used - 1$ digits to prevent +reading past the end of the array of digits. + +Essentially the loop at step 6 is similar to that of mp\_mul\_2 except the logical shifts go in the opposite direction and the carry is at the +least significant bit not the most significant bit. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_div\_2.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* b = a/2 */ +018 int mp_div_2(mp_int * a, mp_int * b) +019 \{ +020 int x, res, oldused; +021 +022 /* copy */ +023 if (b->alloc < a->used) \{ +024 if ((res = mp_grow (b, a->used)) != MP_OKAY) \{ +025 return res; +026 \} +027 \} +028 +029 oldused = b->used; +030 b->used = a->used; +031 \{ +032 register mp_digit r, rr, *tmpa, *tmpb; +033 +034 /* source alias */ +035 tmpa = a->dp + b->used - 1; +036 +037 /* dest alias */ +038 tmpb = b->dp + b->used - 1; +039 +040 /* carry */ +041 r = 0; +042 for (x = b->used - 1; x >= 0; x--) \{ +043 /* get the carry for the next iteration */ +044 rr = *tmpa & 1; +045 +046 /* shift the current digit, add in carry and store */ +047 *tmpb-- = (*tmpa-- >> 1) | (r << (DIGIT_BIT - 1)); +048 +049 /* forward carry to next iteration */ +050 r = rr; +051 \} +052 +053 /* zero excess digits */ +054 tmpb = b->dp + b->used; +055 for (x = b->used; x < oldused; x++) \{ +056 *tmpb++ = 0; +057 \} +058 \} +059 b->sign = a->sign; +060 mp_clamp (b); +061 return MP_OKAY; +062 \} +063 #endif +\end{alltt} +\end{small} + +\section{Polynomial Basis Operations} +Recall from section 4.3 that any integer can be represented as a polynomial in $x$ as $y = f(\beta)$. Such a representation is also known as +the polynomial basis \cite[pp. 48]{ROSE}. Given such a notation a multiplication or division by $x$ amounts to shifting whole digits a single +place. The need for such operations arises in several other higher level algorithms such as Barrett and Montgomery reduction, integer +division and Karatsuba multiplication. + +Converting from an array of digits to polynomial basis is very simple. Consider the integer $y \equiv (a_2, a_1, a_0)_{\beta}$ and recall that +$y = \sum_{i=0}^{2} a_i \beta^i$. Simply replace $\beta$ with $x$ and the expression is in polynomial basis. For example, $f(x) = 8x + 9$ is the +polynomial basis representation for $89$ using radix ten. That is, $f(10) = 8(10) + 9 = 89$. + +\subsection{Multiplication by $x$} + +Given a polynomial in $x$ such as $f(x) = a_n x^n + a_{n-1} x^{n-1} + ... + a_0$ multiplying by $x$ amounts to shifting the coefficients up one +degree. In this case $f(x) \cdot x = a_n x^{n+1} + a_{n-1} x^n + ... + a_0 x$. From a scalar basis point of view multiplying by $x$ is equivalent to +multiplying by the integer $\beta$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_lshd}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $a \leftarrow a \cdot \beta^b$ (equivalent to multiplication by $x^b$). \\ +\hline \\ +1. If $b \le 0$ then return(\textit{MP\_OKAY}). \\ +2. If $a.alloc < a.used + b$ then grow $a$ to at least $a.used + b$ digits. (\textit{mp\_grow}). \\ +3. If the reallocation failed return(\textit{MP\_MEM}). \\ +4. $a.used \leftarrow a.used + b$ \\ +5. $i \leftarrow a.used - 1$ \\ +6. $j \leftarrow a.used - 1 - b$ \\ +7. for $n$ from $a.used - 1$ to $b$ do \\ +\hspace{3mm}7.1 $a_{i} \leftarrow a_{j}$ \\ +\hspace{3mm}7.2 $i \leftarrow i - 1$ \\ +\hspace{3mm}7.3 $j \leftarrow j - 1$ \\ +8. for $n$ from 0 to $b - 1$ do \\ +\hspace{3mm}8.1 $a_n \leftarrow 0$ \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_lshd} +\end{figure} + +\textbf{Algorithm mp\_lshd.} +This algorithm multiplies an mp\_int by the $b$'th power of $x$. This is equivalent to multiplying by $\beta^b$. The algorithm differs +from the other algorithms presented so far as it performs the operation in place instead storing the result in a separate location. The +motivation behind this change is due to the way this function is typically used. Algorithms such as mp\_add store the result in an optionally +different third mp\_int because the original inputs are often still required. Algorithm mp\_lshd (\textit{and similarly algorithm mp\_rshd}) is +typically used on values where the original value is no longer required. The algorithm will return success immediately if +$b \le 0$ since the rest of algorithm is only valid when $b > 0$. + +First the destination $a$ is grown as required to accomodate the result. The counters $i$ and $j$ are used to form a \textit{sliding window} over +the digits of $a$ of length $b$. The head of the sliding window is at $i$ (\textit{the leading digit}) and the tail at $j$ (\textit{the trailing digit}). +The loop on step 7 copies the digit from the tail to the head. In each iteration the window is moved down one digit. The last loop on +step 8 sets the lower $b$ digits to zero. + +\newpage +\begin{center} +\begin{figure}[here] +\includegraphics{pics/sliding_window.ps} +\caption{Sliding Window Movement} +\label{pic:sliding_window} +\end{figure} +\end{center} + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_lshd.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* shift left a certain amount of digits */ +018 int mp_lshd (mp_int * a, int b) +019 \{ +020 int x, res; +021 +022 /* if its less than zero return */ +023 if (b <= 0) \{ +024 return MP_OKAY; +025 \} +026 +027 /* grow to fit the new digits */ +028 if (a->alloc < a->used + b) \{ +029 if ((res = mp_grow (a, a->used + b)) != MP_OKAY) \{ +030 return res; +031 \} +032 \} +033 +034 \{ +035 register mp_digit *top, *bottom; +036 +037 /* increment the used by the shift amount then copy upwards */ +038 a->used += b; +039 +040 /* top */ +041 top = a->dp + a->used - 1; +042 +043 /* base */ +044 bottom = a->dp + a->used - 1 - b; +045 +046 /* much like mp_rshd this is implemented using a sliding window +047 * except the window goes the otherway around. Copying from +048 * the bottom to the top. see bn_mp_rshd.c for more info. +049 */ +050 for (x = a->used - 1; x >= b; x--) \{ +051 *top-- = *bottom--; +052 \} +053 +054 /* zero the lower digits */ +055 top = a->dp; +056 for (x = 0; x < b; x++) \{ +057 *top++ = 0; +058 \} +059 \} +060 return MP_OKAY; +061 \} +062 #endif +\end{alltt} +\end{small} + +The if statement on line 23 ensures that the $b$ variable is greater than zero. The \textbf{used} count is incremented by $b$ before +the copy loop begins. This elminates the need for an additional variable in the for loop. The variable $top$ on line 41 is an alias +for the leading digit while $bottom$ on line 44 is an alias for the trailing edge. The aliases form a window of exactly $b$ digits +over the input. + +\subsection{Division by $x$} + +Division by powers of $x$ is easily achieved by shifting the digits right and removing any that will end up to the right of the zero'th digit. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_rshd}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $a \leftarrow a / \beta^b$ (Divide by $x^b$). \\ +\hline \\ +1. If $b \le 0$ then return. \\ +2. If $a.used \le b$ then do \\ +\hspace{3mm}2.1 Zero $a$. (\textit{mp\_zero}). \\ +\hspace{3mm}2.2 Return. \\ +3. $i \leftarrow 0$ \\ +4. $j \leftarrow b$ \\ +5. for $n$ from 0 to $a.used - b - 1$ do \\ +\hspace{3mm}5.1 $a_i \leftarrow a_j$ \\ +\hspace{3mm}5.2 $i \leftarrow i + 1$ \\ +\hspace{3mm}5.3 $j \leftarrow j + 1$ \\ +6. for $n$ from $a.used - b$ to $a.used - 1$ do \\ +\hspace{3mm}6.1 $a_n \leftarrow 0$ \\ +7. $a.used \leftarrow a.used - b$ \\ +8. Return. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_rshd} +\end{figure} + +\textbf{Algorithm mp\_rshd.} +This algorithm divides the input in place by the $b$'th power of $x$. It is analogous to dividing by a $\beta^b$ but much quicker since +it does not require single precision division. This algorithm does not actually return an error code as it cannot fail. + +If the input $b$ is less than one the algorithm quickly returns without performing any work. If the \textbf{used} count is less than or equal +to the shift count $b$ then it will simply zero the input and return. + +After the trivial cases of inputs have been handled the sliding window is setup. Much like the case of algorithm mp\_lshd a sliding window that +is $b$ digits wide is used to copy the digits. Unlike mp\_lshd the window slides in the opposite direction from the trailing to the leading digit. +Also the digits are copied from the leading to the trailing edge. + +Once the window copy is complete the upper digits must be zeroed and the \textbf{used} count decremented. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_rshd.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* shift right a certain amount of digits */ +018 void mp_rshd (mp_int * a, int b) +019 \{ +020 int x; +021 +022 /* if b <= 0 then ignore it */ +023 if (b <= 0) \{ +024 return; +025 \} +026 +027 /* if b > used then simply zero it and return */ +028 if (a->used <= b) \{ +029 mp_zero (a); +030 return; +031 \} +032 +033 \{ +034 register mp_digit *bottom, *top; +035 +036 /* shift the digits down */ +037 +038 /* bottom */ +039 bottom = a->dp; +040 +041 /* top [offset into digits] */ +042 top = a->dp + b; +043 +044 /* this is implemented as a sliding window where +045 * the window is b-digits long and digits from +046 * the top of the window are copied to the bottom +047 * +048 * e.g. +049 +050 b-2 | b-1 | b0 | b1 | b2 | ... | bb | ----> +051 /\symbol{92} | ----> +052 \symbol{92}-------------------/ ----> +053 */ +054 for (x = 0; x < (a->used - b); x++) \{ +055 *bottom++ = *top++; +056 \} +057 +058 /* zero the top digits */ +059 for (; x < a->used; x++) \{ +060 *bottom++ = 0; +061 \} +062 \} +063 +064 /* remove excess digits */ +065 a->used -= b; +066 \} +067 #endif +\end{alltt} +\end{small} + +The only noteworthy element of this routine is the lack of a return type. + +-- Will update later to give it a return type...Tom + +\section{Powers of Two} + +Now that algorithms for moving single bits as well as whole digits exist algorithms for moving the ``in between'' distances are required. For +example, to quickly multiply by $2^k$ for any $k$ without using a full multiplier algorithm would prove useful. Instead of performing single +shifts $k$ times to achieve a multiplication by $2^{\pm k}$ a mixture of whole digit shifting and partial digit shifting is employed. + +\subsection{Multiplication by Power of Two} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot 2^b$. \\ +\hline \\ +1. $c \leftarrow a$. (\textit{mp\_copy}) \\ +2. If $c.alloc < c.used + \lfloor b / lg(\beta) \rfloor + 2$ then grow $c$ accordingly. \\ +3. If the reallocation failed return(\textit{MP\_MEM}). \\ +4. If $b \ge lg(\beta)$ then \\ +\hspace{3mm}4.1 $c \leftarrow c \cdot \beta^{\lfloor b / lg(\beta) \rfloor}$ (\textit{mp\_lshd}). \\ +\hspace{3mm}4.2 If step 4.1 failed return(\textit{MP\_MEM}). \\ +5. $d \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +6. If $d \ne 0$ then do \\ +\hspace{3mm}6.1 $mask \leftarrow 2^d$ \\ +\hspace{3mm}6.2 $r \leftarrow 0$ \\ +\hspace{3mm}6.3 for $n$ from $0$ to $c.used - 1$ do \\ +\hspace{6mm}6.3.1 $rr \leftarrow c_n >> (lg(\beta) - d) \mbox{ (mod }mask\mbox{)}$ \\ +\hspace{6mm}6.3.2 $c_n \leftarrow (c_n << d) + r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}6.3.3 $r \leftarrow rr$ \\ +\hspace{3mm}6.4 If $r > 0$ then do \\ +\hspace{6mm}6.4.1 $c_{c.used} \leftarrow r$ \\ +\hspace{6mm}6.4.2 $c.used \leftarrow c.used + 1$ \\ +7. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_2d} +\end{figure} + +\textbf{Algorithm mp\_mul\_2d.} +This algorithm multiplies $a$ by $2^b$ and stores the result in $c$. The algorithm uses algorithm mp\_lshd and a derivative of algorithm mp\_mul\_2 to +quickly compute the product. + +First the algorithm will multiply $a$ by $x^{\lfloor b / lg(\beta) \rfloor}$ which will ensure that the remainder multiplicand is less than +$\beta$. For example, if $b = 37$ and $\beta = 2^{28}$ then this step will multiply by $x$ leaving a multiplication by $2^{37 - 28} = 2^{9}$ +left. + +After the digits have been shifted appropriately at most $lg(\beta) - 1$ shifts are left to perform. Step 5 calculates the number of remaining shifts +required. If it is non-zero a modified shift loop is used to calculate the remaining product. +Essentially the loop is a generic version of algorith mp\_mul2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ +variable is used to extract the upper $d$ bits to form the carry for the next iteration. + +This algorithm is loosely measured as a $O(2n)$ algorithm which means that if the input is $n$-digits that it takes $2n$ ``time'' to +complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm at a cost of making the algorithm slightly harder to follow. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_2d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* shift left by a certain bit count */ +018 int mp_mul_2d (mp_int * a, int b, mp_int * c) +019 \{ +020 mp_digit d; +021 int res; +022 +023 /* copy */ +024 if (a != c) \{ +025 if ((res = mp_copy (a, c)) != MP_OKAY) \{ +026 return res; +027 \} +028 \} +029 +030 if (c->alloc < (int)(c->used + b/DIGIT_BIT + 1)) \{ +031 if ((res = mp_grow (c, c->used + b / DIGIT_BIT + 1)) != MP_OKAY) \{ +032 return res; +033 \} +034 \} +035 +036 /* shift by as many digits in the bit count */ +037 if (b >= (int)DIGIT_BIT) \{ +038 if ((res = mp_lshd (c, b / DIGIT_BIT)) != MP_OKAY) \{ +039 return res; +040 \} +041 \} +042 +043 /* shift any bit count < DIGIT_BIT */ +044 d = (mp_digit) (b % DIGIT_BIT); +045 if (d != 0) \{ +046 register mp_digit *tmpc, shift, mask, r, rr; +047 register int x; +048 +049 /* bitmask for carries */ +050 mask = (((mp_digit)1) << d) - 1; +051 +052 /* shift for msbs */ +053 shift = DIGIT_BIT - d; +054 +055 /* alias */ +056 tmpc = c->dp; +057 +058 /* carry */ +059 r = 0; +060 for (x = 0; x < c->used; x++) \{ +061 /* get the higher bits of the current word */ +062 rr = (*tmpc >> shift) & mask; +063 +064 /* shift the current word and OR in the carry */ +065 *tmpc = ((*tmpc << d) | r) & MP_MASK; +066 ++tmpc; +067 +068 /* set the carry to the carry bits of the current word */ +069 r = rr; +070 \} +071 +072 /* set final carry */ +073 if (r != 0) \{ +074 c->dp[(c->used)++] = r; +075 \} +076 \} +077 mp_clamp (c); +078 return MP_OKAY; +079 \} +080 #endif +\end{alltt} +\end{small} + +Notes to be revised when code is updated. -- Tom + +\subsection{Division by Power of Two} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow \lfloor a / 2^b \rfloor, d \leftarrow a \mbox{ (mod }2^b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then do \\ +\hspace{3mm}1.1 $c \leftarrow a$ (\textit{mp\_copy}) \\ +\hspace{3mm}1.2 $d \leftarrow 0$ (\textit{mp\_zero}) \\ +\hspace{3mm}1.3 Return(\textit{MP\_OKAY}). \\ +2. $c \leftarrow a$ \\ +3. $d \leftarrow a \mbox{ (mod }2^b\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +4. If $b \ge lg(\beta)$ then do \\ +\hspace{3mm}4.1 $c \leftarrow \lfloor c/\beta^{\lfloor b/lg(\beta) \rfloor} \rfloor$ (\textit{mp\_rshd}). \\ +5. $k \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +6. If $k \ne 0$ then do \\ +\hspace{3mm}6.1 $mask \leftarrow 2^k$ \\ +\hspace{3mm}6.2 $r \leftarrow 0$ \\ +\hspace{3mm}6.3 for $n$ from $c.used - 1$ to $0$ do \\ +\hspace{6mm}6.3.1 $rr \leftarrow c_n \mbox{ (mod }mask\mbox{)}$ \\ +\hspace{6mm}6.3.2 $c_n \leftarrow (c_n >> k) + (r << (lg(\beta) - k))$ \\ +\hspace{6mm}6.3.3 $r \leftarrow rr$ \\ +7. Clamp excess digits of $c$. (\textit{mp\_clamp}) \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_2d} +\end{figure} + +\textbf{Algorithm mp\_div\_2d.} +This algorithm will divide an input $a$ by $2^b$ and produce the quotient and remainder. The algorithm is designed much like algorithm +mp\_mul\_2d by first using whole digit shifts then single precision shifts. This algorithm will also produce the remainder of the division +by using algorithm mp\_mod\_2d. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_div\_2d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* shift right by a certain bit count (store quotient in c, optional remaind + er in d) */ +018 int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) +019 \{ +020 mp_digit D, r, rr; +021 int x, res; +022 mp_int t; +023 +024 +025 /* if the shift count is <= 0 then we do no work */ +026 if (b <= 0) \{ +027 res = mp_copy (a, c); +028 if (d != NULL) \{ +029 mp_zero (d); +030 \} +031 return res; +032 \} +033 +034 if ((res = mp_init (&t)) != MP_OKAY) \{ +035 return res; +036 \} +037 +038 /* get the remainder */ +039 if (d != NULL) \{ +040 if ((res = mp_mod_2d (a, b, &t)) != MP_OKAY) \{ +041 mp_clear (&t); +042 return res; +043 \} +044 \} +045 +046 /* copy */ +047 if ((res = mp_copy (a, c)) != MP_OKAY) \{ +048 mp_clear (&t); +049 return res; +050 \} +051 +052 /* shift by as many digits in the bit count */ +053 if (b >= (int)DIGIT_BIT) \{ +054 mp_rshd (c, b / DIGIT_BIT); +055 \} +056 +057 /* shift any bit count < DIGIT_BIT */ +058 D = (mp_digit) (b % DIGIT_BIT); +059 if (D != 0) \{ +060 register mp_digit *tmpc, mask, shift; +061 +062 /* mask */ +063 mask = (((mp_digit)1) << D) - 1; +064 +065 /* shift for lsb */ +066 shift = DIGIT_BIT - D; +067 +068 /* alias */ +069 tmpc = c->dp + (c->used - 1); +070 +071 /* carry */ +072 r = 0; +073 for (x = c->used - 1; x >= 0; x--) \{ +074 /* get the lower bits of this word in a temp */ +075 rr = *tmpc & mask; +076 +077 /* shift the current word and mix in the carry bits from the previous + word */ +078 *tmpc = (*tmpc >> D) | (r << shift); +079 --tmpc; +080 +081 /* set the carry to the carry bits of the current word found above */ +082 r = rr; +083 \} +084 \} +085 mp_clamp (c); +086 if (d != NULL) \{ +087 mp_exch (&t, d); +088 \} +089 mp_clear (&t); +090 return MP_OKAY; +091 \} +092 #endif +\end{alltt} +\end{small} + +The implementation of algorithm mp\_div\_2d is slightly different than the algorithm specifies. The remainder $d$ may be optionally +ignored by passing \textbf{NULL} as the pointer to the mp\_int variable. The temporary mp\_int variable $t$ is used to hold the +result of the remainder operation until the end. This allows $d$ and $a$ to represent the same mp\_int without modifying $a$ before +the quotient is obtained. + +The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. (-- Fix this paragraph up later, Tom). + +\subsection{Remainder of Division by Power of Two} + +The last algorithm in the series of polynomial basis power of two algorithms is calculating the remainder of division by $2^b$. This +algorithm benefits from the fact that in twos complement arithmetic $a \mbox{ (mod }2^b\mbox{)}$ is the same as $a$ AND $2^b - 1$. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mod\_2d}. \\ +\textbf{Input}. One mp\_int $a$ and an integer $b$ \\ +\textbf{Output}. $c \leftarrow a \mbox{ (mod }2^b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then do \\ +\hspace{3mm}1.1 $c \leftarrow 0$ (\textit{mp\_zero}) \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $b > a.used \cdot lg(\beta)$ then do \\ +\hspace{3mm}2.1 $c \leftarrow a$ (\textit{mp\_copy}) \\ +\hspace{3mm}2.2 Return the result of step 2.1. \\ +3. $c \leftarrow a$ \\ +4. If step 3 failed return(\textit{MP\_MEM}). \\ +5. for $n$ from $\lceil b / lg(\beta) \rceil$ to $c.used$ do \\ +\hspace{3mm}5.1 $c_n \leftarrow 0$ \\ +6. $k \leftarrow b \mbox{ (mod }lg(\beta)\mbox{)}$ \\ +7. $c_{\lfloor b / lg(\beta) \rfloor} \leftarrow c_{\lfloor b / lg(\beta) \rfloor} \mbox{ (mod }2^{k}\mbox{)}$. \\ +8. Clamp excess digits of $c$. (\textit{mp\_clamp}) \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mod\_2d} +\end{figure} + +\textbf{Algorithm mp\_mod\_2d.} +This algorithm will quickly calculate the value of $a \mbox{ (mod }2^b\mbox{)}$. First if $b$ is less than or equal to zero the +result is set to zero. If $b$ is greater than the number of bits in $a$ then it simply copies $a$ to $c$ and returns. Otherwise, $a$ +is copied to $b$, leading digits are removed and the remaining leading digit is trimed to the exact bit count. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_mod\_2d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* calc a value mod 2**b */ +018 int +019 mp_mod_2d (mp_int * a, int b, mp_int * c) +020 \{ +021 int x, res; +022 +023 /* if b is <= 0 then zero the int */ +024 if (b <= 0) \{ +025 mp_zero (c); +026 return MP_OKAY; +027 \} +028 +029 /* if the modulus is larger than the value than return */ +030 if (b >= (int) (a->used * DIGIT_BIT)) \{ +031 res = mp_copy (a, c); +032 return res; +033 \} +034 +035 /* copy */ +036 if ((res = mp_copy (a, c)) != MP_OKAY) \{ +037 return res; +038 \} +039 +040 /* zero digits above the last digit of the modulus */ +041 for (x = (b / DIGIT_BIT) + ((b % DIGIT_BIT) == 0 ? 0 : 1); x < c->used; x+ + +) \{ +042 c->dp[x] = 0; +043 \} +044 /* clear the digit that is not completely outside/inside the modulus */ +045 c->dp[b / DIGIT_BIT] &= +046 (mp_digit) ((((mp_digit) 1) << (((mp_digit) b) % DIGIT_BIT)) - ((mp_digi + t) 1)); +047 mp_clamp (c); +048 return MP_OKAY; +049 \} +050 #endif +\end{alltt} +\end{small} + +-- Add comments later, Tom. + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ] $ & Devise an algorithm that performs $a \cdot 2^b$ for generic values of $b$ \\ + & in $O(n)$ time. \\ + &\\ +$\left [ 3 \right ] $ & Devise an efficient algorithm to multiply by small low hamming \\ + & weight values such as $3$, $5$ and $9$. Extend it to handle all values \\ + & upto $64$ with a hamming weight less than three. \\ + &\\ +$\left [ 2 \right ] $ & Modify the preceding algorithm to handle values of the form \\ + & $2^k - 1$ as well. \\ + &\\ +$\left [ 3 \right ] $ & Using only algorithms mp\_mul\_2, mp\_div\_2 and mp\_add create an \\ + & algorithm to multiply two integers in roughly $O(2n^2)$ time for \\ + & any $n$-bit input. Note that the time of addition is ignored in the \\ + & calculation. \\ + & \\ +$\left [ 5 \right ] $ & Improve the previous algorithm to have a working time of at most \\ + & $O \left (2^{(k-1)}n + \left ({2n^2 \over k} \right ) \right )$ for an appropriate choice of $k$. Again ignore \\ + & the cost of addition. \\ + & \\ +$\left [ 2 \right ] $ & Devise a chart to find optimal values of $k$ for the previous problem \\ + & for $n = 64 \ldots 1024$ in steps of $64$. \\ + & \\ +$\left [ 2 \right ] $ & Using only algorithms mp\_abs and mp\_sub devise another method for \\ + & calculating the result of a signed comparison. \\ + & +\end{tabular} + +\chapter{Multiplication and Squaring} +\section{The Multipliers} +For most number theoretic problems including certain public key cryptographic algorithms, the ``multipliers'' form the most important subset of +algorithms of any multiple precision integer package. The set of multiplier algorithms include integer multiplication, squaring and modular reduction +where in each of the algorithms single precision multiplication is the dominant operation performed. This chapter will discuss integer multiplication +and squaring, leaving modular reductions for the subsequent chapter. + +The importance of the multiplier algorithms is for the most part driven by the fact that certain popular public key algorithms are based on modular +exponentiation, that is computing $d \equiv a^b \mbox{ (mod }c\mbox{)}$ for some arbitrary choice of $a$, $b$, $c$ and $d$. During a modular +exponentiation the majority\footnote{Roughly speaking a modular exponentiation will spend about 40\% of the time performing modular reductions, +35\% of the time performing squaring and 25\% of the time performing multiplications.} of the processor time is spent performing single precision +multiplications. + +For centuries general purpose multiplication has required a lengthly $O(n^2)$ process, whereby each digit of one multiplicand has to be multiplied +against every digit of the other multiplicand. Traditional long-hand multiplication is based on this process; while the techniques can differ the +overall algorithm used is essentially the same. Only ``recently'' have faster algorithms been studied. First Karatsuba multiplication was discovered in +1962. This algorithm can multiply two numbers with considerably fewer single precision multiplications when compared to the long-hand approach. +This technique led to the discovery of polynomial basis algorithms (\textit{good reference?}) and subquently Fourier Transform based solutions. + +\section{Multiplication} +\subsection{The Baseline Multiplication} +\label{sec:basemult} +\index{baseline multiplication} +Computing the product of two integers in software can be achieved using a trivial adaptation of the standard $O(n^2)$ long-hand multiplication +algorithm that school children are taught. The algorithm is considered an $O(n^2)$ algorithm since for two $n$-digit inputs $n^2$ single precision +multiplications are required. More specifically for a $m$ and $n$ digit input $m \cdot n$ single precision multiplications are required. To +simplify most discussions, it will be assumed that the inputs have comparable number of digits. + +The ``baseline multiplication'' algorithm is designed to act as the ``catch-all'' algorithm, only to be used when the faster algorithms cannot be +used. This algorithm does not use any particularly interesting optimizations and should ideally be avoided if possible. One important +facet of this algorithm, is that it has been modified to only produce a certain amount of output digits as resolution. The importance of this +modification will become evident during the discussion of Barrett modular reduction. Recall that for a $n$ and $m$ digit input the product +will be at most $n + m$ digits. Therefore, this algorithm can be reduced to a full multiplier by having it produce $n + m$ digits of the product. + +Recall from sub-section 4.2.2 the definition of $\gamma$ as the number of bits in the type \textbf{mp\_digit}. We shall now extend the variable set to +include $\alpha$ which shall represent the number of bits in the type \textbf{mp\_word}. This implies that $2^{\alpha} > 2 \cdot \beta^2$. The +constant $\delta = 2^{\alpha - 2lg(\beta)}$ will represent the maximal weight of any column in a product (\textit{see sub-section 5.2.2 for more information}). + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_mul\_digs}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ +\hline \\ +1. If min$(a.used, b.used) < \delta$ then do \\ +\hspace{3mm}1.1 Calculate $c = \vert a \vert \cdot \vert b \vert$ by the Comba method (\textit{see algorithm~\ref{fig:COMBAMULT}}). \\ +\hspace{3mm}1.2 Return the result of step 1.1 \\ +\\ +Allocate and initialize a temporary mp\_int. \\ +2. Init $t$ to be of size $digs$ \\ +3. If step 2 failed return(\textit{MP\_MEM}). \\ +4. $t.used \leftarrow digs$ \\ +\\ +Compute the product. \\ +5. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}5.1 $u \leftarrow 0$ \\ +\hspace{3mm}5.2 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ +\hspace{3mm}5.3 If $pb < 1$ then goto step 6. \\ +\hspace{3mm}5.4 for $iy$ from $0$ to $pb - 1$ do \\ +\hspace{6mm}5.4.1 $\hat r \leftarrow t_{iy + ix} + a_{ix} \cdot b_{iy} + u$ \\ +\hspace{6mm}5.4.2 $t_{iy + ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}5.4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}5.5 if $ix + pb < digs$ then do \\ +\hspace{6mm}5.5.1 $t_{ix + pb} \leftarrow u$ \\ +6. Clamp excess digits of $t$. \\ +7. Swap $c$ with $t$ \\ +8. Clear $t$ \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_mul\_digs} +\end{figure} + +\textbf{Algorithm s\_mp\_mul\_digs.} +This algorithm computes the unsigned product of two inputs $a$ and $b$, limited to an output precision of $digs$ digits. While it may seem +a bit awkward to modify the function from its simple $O(n^2)$ description, the usefulness of partial multipliers will arise in a subsequent +algorithm. The algorithm is loosely based on algorithm 14.12 from \cite[pp. 595]{HAC} and is similar to Algorithm M of Knuth \cite[pp. 268]{TAOCPV2}. +Algorithm s\_mp\_mul\_digs differs from these cited references since it can produce a variable output precision regardless of the precision of the +inputs. + +The first thing this algorithm checks for is whether a Comba multiplier can be used instead. If the minimum digit count of either +input is less than $\delta$, then the Comba method may be used instead. After the Comba method is ruled out, the baseline algorithm begins. A +temporary mp\_int variable $t$ is used to hold the intermediate result of the product. This allows the algorithm to be used to +compute products when either $a = c$ or $b = c$ without overwriting the inputs. + +All of step 5 is the infamous $O(n^2)$ multiplication loop slightly modified to only produce upto $digs$ digits of output. The $pb$ variable +is given the count of digits to read from $b$ inside the nested loop. If $pb \le 1$ then no more output digits can be produced and the algorithm +will exit the loop. The best way to think of the loops are as a series of $pb \times 1$ multiplications. That is, in each pass of the +innermost loop $a_{ix}$ is multiplied against $b$ and the result is added (\textit{with an appropriate shift}) to $t$. + +For example, consider multiplying $576$ by $241$. That is equivalent to computing $10^0(1)(576) + 10^1(4)(576) + 10^2(2)(576)$ which is best +visualized in the following table. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{|c|c|c|c|c|c|l|} +\hline && & 5 & 7 & 6 & \\ +\hline $\times$&& & 2 & 4 & 1 & \\ +\hline &&&&&&\\ + && & 5 & 7 & 6 & $10^0(1)(576)$ \\ + &2 & 3 & 6 & 1 & 6 & $10^1(4)(576) + 10^0(1)(576)$ \\ + 1 & 3 & 8 & 8 & 1 & 6 & $10^2(2)(576) + 10^1(4)(576) + 10^0(1)(576)$ \\ +\hline +\end{tabular} +\end{center} +\caption{Long-Hand Multiplication Diagram} +\end{figure} + +Each row of the product is added to the result after being shifted to the left (\textit{multiplied by a power of the radix}) by the appropriate +count. That is in pass $ix$ of the inner loop the product is added starting at the $ix$'th digit of the reult. + +Step 5.4.1 introduces the hat symbol (\textit{e.g. $\hat r$}) which represents a double precision variable. The multiplication on that step +is assumed to be a double wide output single precision multiplication. That is, two single precision variables are multiplied to produce a +double precision result. The step is somewhat optimized from a long-hand multiplication algorithm because the carry from the addition in step +5.4.1 is propagated through the nested loop. If the carry was not propagated immediately it would overflow the single precision digit +$t_{ix+iy}$ and the result would be lost. + +At step 5.5 the nested loop is finished and any carry that was left over should be forwarded. The carry does not have to be added to the $ix+pb$'th +digit since that digit is assumed to be zero at this point. However, if $ix + pb \ge digs$ the carry is not set as it would make the result +exceed the precision requested. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_s\_mp\_mul\_digs.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* multiplies |a| * |b| and only computes upto digs digits of result +018 * HAC pp. 595, Algorithm 14.12 Modified so you can control how +019 * many digits of output are created. +020 */ +021 int +022 s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +023 \{ +024 mp_int t; +025 int res, pa, pb, ix, iy; +026 mp_digit u; +027 mp_word r; +028 mp_digit tmpx, *tmpt, *tmpy; +029 +030 /* can we use the fast multiplier? */ +031 if (((digs) < MP_WARRAY) && +032 MIN (a->used, b->used) < +033 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ +034 return fast_s_mp_mul_digs (a, b, c, digs); +035 \} +036 +037 if ((res = mp_init_size (&t, digs)) != MP_OKAY) \{ +038 return res; +039 \} +040 t.used = digs; +041 +042 /* compute the digits of the product directly */ +043 pa = a->used; +044 for (ix = 0; ix < pa; ix++) \{ +045 /* set the carry to zero */ +046 u = 0; +047 +048 /* limit ourselves to making digs digits of output */ +049 pb = MIN (b->used, digs - ix); +050 +051 /* setup some aliases */ +052 /* copy of the digit from a used within the nested loop */ +053 tmpx = a->dp[ix]; +054 +055 /* an alias for the destination shifted ix places */ +056 tmpt = t.dp + ix; +057 +058 /* an alias for the digits of b */ +059 tmpy = b->dp; +060 +061 /* compute the columns of the output and propagate the carry */ +062 for (iy = 0; iy < pb; iy++) \{ +063 /* compute the column as a mp_word */ +064 r = ((mp_word)*tmpt) + +065 ((mp_word)tmpx) * ((mp_word)*tmpy++) + +066 ((mp_word) u); +067 +068 /* the new column is the lower part of the result */ +069 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +070 +071 /* get the carry word from the result */ +072 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); +073 \} +074 /* set carry if it is placed below digs */ +075 if (ix + iy < digs) \{ +076 *tmpt = u; +077 \} +078 \} +079 +080 mp_clamp (&t); +081 mp_exch (&t, c); +082 +083 mp_clear (&t); +084 return MP_OKAY; +085 \} +086 #endif +\end{alltt} +\end{small} + +Lines 31 to 35 determine if the Comba method can be used first. The conditions for using the Comba routine are that min$(a.used, b.used) < \delta$ and +the number of digits of output is less than \textbf{MP\_WARRAY}. This new constant is used to control +the stack usage in the Comba routines. By default it is set to $\delta$ but can be reduced when memory is at a premium. + +Of particular importance is the calculation of the $ix+iy$'th column on lines 64, 65 and 66. Note how all of the +variables are cast to the type \textbf{mp\_word}, which is also the type of variable $\hat r$. That is to ensure that double precision operations +are used instead of single precision. The multiplication on line 65 makes use of a specific GCC optimizer behaviour. On the outset it looks like +the compiler will have to use a double precision multiplication to produce the result required. Such an operation would be horribly slow on most +processors and drag this to a crawl. However, GCC is smart enough to realize that double wide output single precision multipliers can be used. For +example, the instruction ``MUL'' on the x86 processor can multiply two 32-bit values and produce a 64-bit result. + +\subsection{Faster Multiplication by the ``Comba'' Method} + +One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be computed and propagated upwards. This +makes the nested loop very sequential and hard to unroll and implement in parallel. The ``Comba'' \cite{COMBA} method is named after little known +(\textit{in cryptographic venues}) Paul G. Comba who described a method of implementing fast multipliers that do not require nested +carry fixup operations. As an interesting aside it seems that Paul Barrett describes a similar technique in +his 1986 paper \cite{BARRETT} written five years before. + +At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight twist is placed on how +the columns of the result are produced. In the standard long-hand algorithm rows of products are produced then added together to form the +final result. In the baseline algorithm the columns are added together after each iteration to get the result instantaneously. + +In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at the $O(n^2)$ level a +simple multiplication and addition step is performed. The carries of the columns are propagated after the nested loop to reduce the amount +of work requiored. Succintly the first step of the algorithm is to compute the product vector $\vec x$ as follows. + +\begin{equation} +\vec x_n = \sum_{i+j = n} a_ib_j, \forall n \in \lbrace 0, 1, 2, \ldots, i + j \rbrace +\end{equation} + +Where $\vec x_n$ is the $n'th$ column of the output vector. Consider the following example which computes the vector $\vec x$ for the multiplication +of $576$ and $241$. + +\newpage\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|c|c|c|c|c|} + \hline & & 5 & 7 & 6 & First Input\\ + \hline $\times$ & & 2 & 4 & 1 & Second Input\\ +\hline & & $1 \cdot 5 = 5$ & $1 \cdot 7 = 7$ & $1 \cdot 6 = 6$ & First pass \\ + & $4 \cdot 5 = 20$ & $4 \cdot 7+5=33$ & $4 \cdot 6+7=31$ & 6 & Second pass \\ + $2 \cdot 5 = 10$ & $2 \cdot 7 + 20 = 34$ & $2 \cdot 6+33=45$ & 31 & 6 & Third pass \\ +\hline 10 & 34 & 45 & 31 & 6 & Final Result \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Comba Multiplication Diagram} +\end{figure} + +At this point the vector $x = \left < 10, 34, 45, 31, 6 \right >$ is the result of the first step of the Comba multipler. +Now the columns must be fixed by propagating the carry upwards. The resultant vector will have one extra dimension over the input vector which is +congruent to adding a leading zero digit. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Comba Fixup}. \\ +\textbf{Input}. Vector $\vec x$ of dimension $k$ \\ +\textbf{Output}. Vector $\vec x$ such that the carries have been propagated. \\ +\hline \\ +1. for $n$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 $\vec x_{n+1} \leftarrow \vec x_{n+1} + \lfloor \vec x_{n}/\beta \rfloor$ \\ +\hspace{3mm}1.2 $\vec x_{n} \leftarrow \vec x_{n} \mbox{ (mod }\beta\mbox{)}$ \\ +2. Return($\vec x$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Comba Fixup} +\end{figure} + +With that algorithm and $k = 5$ and $\beta = 10$ the following vector is produced $\vec x= \left < 1, 3, 8, 8, 1, 6 \right >$. In this case +$241 \cdot 576$ is in fact $138816$ and the procedure succeeded. If the algorithm is correct and as will be demonstrated shortly more +efficient than the baseline algorithm why not simply always use this algorithm? + +\subsubsection{Column Weight.} +At the nested $O(n^2)$ level the Comba method adds the product of two single precision variables to each column of the output +independently. A serious obstacle is if the carry is lost, due to lack of precision before the algorithm has a chance to fix +the carries. For example, in the multiplication of two three-digit numbers the third column of output will be the sum of +three single precision multiplications. If the precision of the accumulator for the output digits is less then $3 \cdot (\beta - 1)^2$ then +an overflow can occur and the carry information will be lost. For any $m$ and $n$ digit inputs the maximum weight of any column is +min$(m, n)$ which is fairly obvious. + +The maximum number of terms in any column of a product is known as the ``column weight'' and strictly governs when the algorithm can be used. Recall +from earlier that a double precision type has $\alpha$ bits of resolution and a single precision digit has $lg(\beta)$ bits of precision. Given these +two quantities we must not violate the following + +\begin{equation} +k \cdot \left (\beta - 1 \right )^2 < 2^{\alpha} +\end{equation} + +Which reduces to + +\begin{equation} +k \cdot \left ( \beta^2 - 2\beta + 1 \right ) < 2^{\alpha} +\end{equation} + +Let $\rho = lg(\beta)$ represent the number of bits in a single precision digit. By further re-arrangement of the equation the final solution is +found. + +\begin{equation} +k < {{2^{\alpha}} \over {\left (2^{2\rho} - 2^{\rho + 1} + 1 \right )}} +\end{equation} + +The defaults for LibTomMath are $\beta = 2^{28}$ and $\alpha = 2^{64}$ which means that $k$ is bounded by $k < 257$. In this configuration +the smaller input may not have more than $256$ digits if the Comba method is to be used. This is quite satisfactory for most applications since +$256$ digits would allow for numbers in the range of $0 \le x < 2^{7168}$ which, is much larger than most public key cryptographic algorithms require. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_s\_mp\_mul\_digs}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ +\hline \\ +Place an array of \textbf{MP\_WARRAY} double precision digits named $\hat W$ on the stack. \\ +1. If $c.alloc < digs$ then grow $c$ to $digs$ digits. (\textit{mp\_grow}) \\ +2. If step 1 failed return(\textit{MP\_MEM}).\\ +\\ +Zero the temporary array $\hat W$. \\ +3. for $n$ from $0$ to $digs - 1$ do \\ +\hspace{3mm}3.1 $\hat W_n \leftarrow 0$ \\ +\\ +Compute the columns. \\ +4. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}4.1 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ +\hspace{3mm}4.2 If $pb < 1$ then goto step 5. \\ +\hspace{3mm}4.3 for $iy$ from $0$ to $pb - 1$ do \\ +\hspace{6mm}4.3.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}b_{iy}$ \\ +\\ +Propagate the carries upwards. \\ +5. $oldused \leftarrow c.used$ \\ +6. $c.used \leftarrow digs$ \\ +7. If $digs > 1$ then do \\ +\hspace{3mm}7.1. for $ix$ from $1$ to $digs - 1$ do \\ +\hspace{6mm}7.1.1 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix-1} / \beta \rfloor$ \\ +\hspace{6mm}7.1.2 $c_{ix - 1} \leftarrow \hat W_{ix - 1} \mbox{ (mod }\beta\mbox{)}$ \\ +8. else do \\ +\hspace{3mm}8.1 $ix \leftarrow 0$ \\ +9. $c_{ix} \leftarrow \hat W_{ix} \mbox{ (mod }\beta\mbox{)}$ \\ +\\ +Zero excess digits. \\ +10. If $digs < oldused$ then do \\ +\hspace{3mm}10.1 for $n$ from $digs$ to $oldused - 1$ do \\ +\hspace{6mm}10.1.1 $c_n \leftarrow 0$ \\ +11. Clamp excessive digits of $c$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_s\_mp\_mul\_digs} +\label{fig:COMBAMULT} +\end{figure} + +\textbf{Algorithm fast\_s\_mp\_mul\_digs.} +This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. The algorithm +essentially peforms the same calculation as algorithm s\_mp\_mul\_digs, just much faster. + +The array $\hat W$ is meant to be on the stack when the algorithm is used. The size of the array does not change which is ideal. Note also that +unlike algorithm s\_mp\_mul\_digs no temporary mp\_int is required since the result is calculated directly in $\hat W$. + +The $O(n^2)$ loop on step four is where the Comba method's advantages begin to show through in comparison to the baseline algorithm. The lack of +a carry variable or propagation in this loop allows the loop to be performed with only single precision multiplication and additions. Now that each +iteration of the inner loop can be performed independent of the others the inner loop can be performed with a high level of parallelism. + +To measure the benefits of the Comba method over the baseline method consider the number of operations that are required. If the +cost in terms of time of a multiply and addition is $p$ and the cost of a carry propagation is $q$ then a baseline multiplication would require +$O \left ((p + q)n^2 \right )$ time to multiply two $n$-digit numbers. The Comba method requires only $O(pn^2 + qn)$ time, however in practice, +the speed increase is actually much more. With $O(n)$ space the algorithm can be reduced to $O(pn + qn)$ time by implementing the $n$ multiply +and addition operations in the nested loop in parallel. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_fast\_s\_mp\_mul\_digs.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* Fast (comba) multiplier +018 * +019 * This is the fast column-array [comba] multiplier. It is +020 * designed to compute the columns of the product first +021 * then handle the carries afterwards. This has the effect +022 * of making the nested loops that compute the columns very +023 * simple and schedulable on super-scalar processors. +024 * +025 * This has been modified to produce a variable number of +026 * digits of output so if say only a half-product is required +027 * you don't have to compute the upper half (a feature +028 * required for fast Barrett reduction). +029 * +030 * Based on Algorithm 14.12 on pp.595 of HAC. +031 * +032 */ +033 int +034 fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +035 \{ +036 int olduse, res, pa, ix, iz; +037 mp_digit W[MP_WARRAY]; +038 register mp_word _W; +039 +040 /* grow the destination as required */ +041 if (c->alloc < digs) \{ +042 if ((res = mp_grow (c, digs)) != MP_OKAY) \{ +043 return res; +044 \} +045 \} +046 +047 /* number of output digits to produce */ +048 pa = MIN(digs, a->used + b->used); +049 +050 /* clear the carry */ +051 _W = 0; +052 for (ix = 0; ix < pa; ix++) \{ +053 int tx, ty; +054 int iy; +055 mp_digit *tmpx, *tmpy; +056 +057 /* get offsets into the two bignums */ +058 ty = MIN(b->used-1, ix); +059 tx = ix - ty; +060 +061 /* setup temp aliases */ +062 tmpx = a->dp + tx; +063 tmpy = b->dp + ty; +064 +065 /* this is the number of times the loop will iterrate, essentially its + +066 while (tx++ < a->used && ty-- >= 0) \{ ... \} +067 */ +068 iy = MIN(a->used-tx, ty+1); +069 +070 /* execute loop */ +071 for (iz = 0; iz < iy; ++iz) \{ +072 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); +073 \} +074 +075 /* store term */ +076 W[ix] = ((mp_digit)_W) & MP_MASK; +077 +078 /* make next carry */ +079 _W = _W >> ((mp_word)DIGIT_BIT); +080 \} +081 +082 /* store final carry */ +083 W[ix] = _W; +084 +085 /* setup dest */ +086 olduse = c->used; +087 c->used = digs; +088 +089 \{ +090 register mp_digit *tmpc; +091 tmpc = c->dp; +092 for (ix = 0; ix < digs; ix++) \{ +093 /* now extract the previous digit [below the carry] */ +094 *tmpc++ = W[ix]; +095 \} +096 +097 /* clear unused digits [that existed in the old copy of c] */ +098 for (; ix < olduse; ix++) \{ +099 *tmpc++ = 0; +100 \} +101 \} +102 mp_clamp (c); +103 return MP_OKAY; +104 \} +105 #endif +\end{alltt} +\end{small} + +The memset on line @47,memset@ clears the initial $\hat W$ array to zero in a single step. Like the slower baseline multiplication +implementation a series of aliases (\textit{lines 62, 63 and 76}) are used to simplify the inner $O(n^2)$ loop. +In this case a new alias $\_\hat W$ has been added which refers to the double precision columns offset by $ix$ in each pass. + +The inner loop on lines 92, 79 and 80 is where the algorithm will spend the majority of the time, which is why it has been +stripped to the bones of any extra baggage\footnote{Hence the pointer aliases.}. On x86 processors the multiplication and additions amount to at the +very least five instructions (\textit{two loads, two additions, one multiply}) while on the ARMv4 processors they amount to only three +(\textit{one load, one store, one multiply-add}). For both of the x86 and ARMv4 processors the GCC compiler performs a good job at unrolling the loop +and scheduling the instructions so there are very few dependency stalls. + +In theory the difference between the baseline and comba algorithms is a mere $O(qn)$ time difference. However, in the $O(n^2)$ nested loop of the +baseline method there are dependency stalls as the algorithm must wait for the multiplier to finish before propagating the carry to the next +digit. As a result fewer of the often multiple execution units\footnote{The AMD Athlon has three execution units and the Intel P4 has four.} can +be simultaneously used. + +\subsection{Polynomial Basis Multiplication} +To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms +the use of polynomial basis representation for two integers $a$ and $b$ as $f(x) = \sum_{i=0}^{n} a_i x^i$ and +$g(x) = \sum_{i=0}^{n} b_i x^i$ respectively, is required. In this system both $f(x)$ and $g(x)$ have $n + 1$ terms and are of the $n$'th degree. + +The product $a \cdot b \equiv f(x)g(x)$ is the polynomial $W(x) = \sum_{i=0}^{2n} w_i x^i$. The coefficients $w_i$ will +directly yield the desired product when $\beta$ is substituted for $x$. The direct solution to solve for the $2n + 1$ coefficients +requires $O(n^2)$ time and would in practice be slower than the Comba technique. + +However, numerical analysis theory indicates that only $2n + 1$ distinct points in $W(x)$ are required to determine the values of the $2n + 1$ unknown +coefficients. This means by finding $\zeta_y = W(y)$ for $2n + 1$ small values of $y$ the coefficients of $W(x)$ can be found with +Gaussian elimination. This technique is also occasionally refered to as the \textit{interpolation technique} (\textit{references please...}) since in +effect an interpolation based on $2n + 1$ points will yield a polynomial equivalent to $W(x)$. + +The coefficients of the polynomial $W(x)$ are unknown which makes finding $W(y)$ for any value of $y$ impossible. However, since +$W(x) = f(x)g(x)$ the equivalent $\zeta_y = f(y) g(y)$ can be used in its place. The benefit of this technique stems from the +fact that $f(y)$ and $g(y)$ are much smaller than either $a$ or $b$ respectively. As a result finding the $2n + 1$ relations required +by multiplying $f(y)g(y)$ involves multiplying integers that are much smaller than either of the inputs. + +When picking points to gather relations there are always three obvious points to choose, $y = 0, 1$ and $ \infty$. The $\zeta_0$ term +is simply the product $W(0) = w_0 = a_0 \cdot b_0$. The $\zeta_1$ term is the product +$W(1) = \left (\sum_{i = 0}^{n} a_i \right ) \left (\sum_{i = 0}^{n} b_i \right )$. The third point $\zeta_{\infty}$ is less obvious but rather +simple to explain. The $2n + 1$'th coefficient of $W(x)$ is numerically equivalent to the most significant column in an integer multiplication. +The point at $\infty$ is used symbolically to represent the most significant column, that is $W(\infty) = w_{2n} = a_nb_n$. Note that the +points at $y = 0$ and $\infty$ yield the coefficients $w_0$ and $w_{2n}$ directly. + +If more points are required they should be of small values and powers of two such as $2^q$ and the related \textit{mirror points} +$\left (2^q \right )^{2n} \cdot \zeta_{2^{-q}}$ for small values of $q$. The term ``mirror point'' stems from the fact that +$\left (2^q \right )^{2n} \cdot \zeta_{2^{-q}}$ can be calculated in the exact opposite fashion as $\zeta_{2^q}$. For +example, when $n = 2$ and $q = 1$ then following two equations are equivalent to the point $\zeta_{2}$ and its mirror. + +\begin{eqnarray} +\zeta_{2} = f(2)g(2) = (4a_2 + 2a_1 + a_0)(4b_2 + 2b_1 + b_0) \nonumber \\ +16 \cdot \zeta_{1 \over 2} = 4f({1\over 2}) \cdot 4g({1 \over 2}) = (a_2 + 2a_1 + 4a_0)(b_2 + 2b_1 + 4b_0) +\end{eqnarray} + +Using such points will allow the values of $f(y)$ and $g(y)$ to be independently calculated using only left shifts. For example, when $n = 2$ the +polynomial $f(2^q)$ is equal to $2^q((2^qa_2) + a_1) + a_0$. This technique of polynomial representation is known as Horner's method. + +As a general rule of the algorithm when the inputs are split into $n$ parts each there are $2n - 1$ multiplications. Each multiplication is of +multiplicands that have $n$ times fewer digits than the inputs. The asymptotic running time of this algorithm is +$O \left ( k^{lg_n(2n - 1)} \right )$ for $k$ digit inputs (\textit{assuming they have the same number of digits}). Figure~\ref{fig:exponent} +summarizes the exponents for various values of $n$. + +\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Split into $n$ Parts} & \textbf{Exponent} & \textbf{Notes}\\ +\hline $2$ & $1.584962501$ & This is Karatsuba Multiplication. \\ +\hline $3$ & $1.464973520$ & This is Toom-Cook Multiplication. \\ +\hline $4$ & $1.403677461$ &\\ +\hline $5$ & $1.365212389$ &\\ +\hline $10$ & $1.278753601$ &\\ +\hline $100$ & $1.149426538$ &\\ +\hline $1000$ & $1.100270931$ &\\ +\hline $10000$ & $1.075252070$ &\\ +\hline +\end{tabular} +\end{center} +\caption{Asymptotic Running Time of Polynomial Basis Multiplication} +\label{fig:exponent} +\end{figure} + +At first it may seem like a good idea to choose $n = 1000$ since the exponent is approximately $1.1$. However, the overhead +of solving for the 2001 terms of $W(x)$ will certainly consume any savings the algorithm could offer for all but exceedingly large +numbers. + +\subsubsection{Cutoff Point} +The polynomial basis multiplication algorithms all require fewer single precision multiplications than a straight Comba approach. However, +the algorithms incur an overhead (\textit{at the $O(n)$ work level}) since they require a system of equations to be solved. This makes the +polynomial basis approach more costly to use with small inputs. + +Let $m$ represent the number of digits in the multiplicands (\textit{assume both multiplicands have the same number of digits}). There exists a +point $y$ such that when $m < y$ the polynomial basis algorithms are more costly than Comba, when $m = y$ they are roughly the same cost and +when $m > y$ the Comba methods are slower than the polynomial basis algorithms. + +The exact location of $y$ depends on several key architectural elements of the computer platform in question. + +\begin{enumerate} +\item The ratio of clock cycles for single precision multiplication versus other simpler operations such as addition, shifting, etc. For example +on the AMD Athlon the ratio is roughly $17 : 1$ while on the Intel P4 it is $29 : 1$. The higher the ratio in favour of multiplication the lower +the cutoff point $y$ will be. + +\item The complexity of the linear system of equations (\textit{for the coefficients of $W(x)$}) is. Generally speaking as the number of splits +grows the complexity grows substantially. Ideally solving the system will only involve addition, subtraction and shifting of integers. This +directly reflects on the ratio previous mentioned. + +\item To a lesser extent memory bandwidth and function call overheads. Provided the values are in the processor cache this is less of an +influence over the cutoff point. + +\end{enumerate} + +A clean cutoff point separation occurs when a point $y$ is found such that all of the cutoff point conditions are met. For example, if the point +is too low then there will be values of $m$ such that $m > y$ and the Comba method is still faster. Finding the cutoff points is fairly simple when +a high resolution timer is available. + +\subsection{Karatsuba Multiplication} +Karatsuba \cite{KARA} multiplication when originally proposed in 1962 was among the first set of algorithms to break the $O(n^2)$ barrier for +general purpose multiplication. Given two polynomial basis representations $f(x) = ax + b$ and $g(x) = cx + d$, Karatsuba proved with +light algebra \cite{KARAP} that the following polynomial is equivalent to multiplication of the two integers the polynomials represent. + +\begin{equation} +f(x) \cdot g(x) = acx^2 + ((a - b)(c - d) - (ac + bd))x + bd +\end{equation} + +Using the observation that $ac$ and $bd$ could be re-used only three half sized multiplications would be required to produce the product. Applying +this algorithm recursively, the work factor becomes $O(n^{lg(3)})$ which is substantially better than the work factor $O(n^2)$ of the Comba technique. It turns +out what Karatsuba did not know or at least did not publish was that this is simply polynomial basis multiplication with the points +$\zeta_0$, $\zeta_{\infty}$ and $-\zeta_{-1}$. Consider the resultant system of equations. + +\begin{center} +\begin{tabular}{rcrcrcrc} +$\zeta_{0}$ & $=$ & & & & & $w_0$ \\ +$-\zeta_{-1}$ & $=$ & $-w_2$ & $+$ & $w_1$ & $-$ & $w_0$ \\ +$\zeta_{\infty}$ & $=$ & $w_2$ & & & & \\ +\end{tabular} +\end{center} + +By adding the first and last equation to the equation in the middle the term $w_1$ can be isolated and all three coefficients solved for. The simplicity +of this system of equations has made Karatsuba fairly popular. In fact the cutoff point is often fairly low\footnote{With LibTomMath 0.18 it is 70 and 109 digits for the Intel P4 and AMD Athlon respectively.} +making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. It is worth noting that the point +$\zeta_1$ could be substituted for $-\zeta_{-1}$. In this case the first and third row are subtracted instead of added to the second row. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_karatsuba\_mul}. \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert$ \\ +\hline \\ +1. Init the following mp\_int variables: $x0$, $x1$, $y0$, $y1$, $t1$, $x0y0$, $x1y1$.\\ +2. If step 2 failed then return(\textit{MP\_MEM}). \\ +\\ +Split the input. e.g. $a = x1 \cdot \beta^B + x0$ \\ +3. $B \leftarrow \mbox{min}(a.used, b.used)/2$ \\ +4. $x0 \leftarrow a \mbox{ (mod }\beta^B\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +5. $y0 \leftarrow b \mbox{ (mod }\beta^B\mbox{)}$ \\ +6. $x1 \leftarrow \lfloor a / \beta^B \rfloor$ (\textit{mp\_rshd}) \\ +7. $y1 \leftarrow \lfloor b / \beta^B \rfloor$ \\ +\\ +Calculate the three products. \\ +8. $x0y0 \leftarrow x0 \cdot y0$ (\textit{mp\_mul}) \\ +9. $x1y1 \leftarrow x1 \cdot y1$ \\ +10. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +11. $x0 \leftarrow y1 - y0$ \\ +12. $t1 \leftarrow t1 \cdot x0$ \\ +\\ +Calculate the middle term. \\ +13. $x0 \leftarrow x0y0 + x1y1$ \\ +14. $t1 \leftarrow x0 - t1$ \\ +\\ +Calculate the final product. \\ +15. $t1 \leftarrow t1 \cdot \beta^B$ (\textit{mp\_lshd}) \\ +16. $x1y1 \leftarrow x1y1 \cdot \beta^{2B}$ \\ +17. $t1 \leftarrow x0y0 + t1$ \\ +18. $c \leftarrow t1 + x1y1$ \\ +19. Clear all of the temporary variables. \\ +20. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_karatsuba\_mul} +\end{figure} + +\textbf{Algorithm mp\_karatsuba\_mul.} +This algorithm computes the unsigned product of two inputs using the Karatsuba multiplication algorithm. It is loosely based on the description +from Knuth \cite[pp. 294-295]{TAOCPV2}. + +\index{radix point} +In order to split the two inputs into their respective halves, a suitable \textit{radix point} must be chosen. The radix point chosen must +be used for both of the inputs meaning that it must be smaller than the smallest input. Step 3 chooses the radix point $B$ as half of the +smallest input \textbf{used} count. After the radix point is chosen the inputs are split into lower and upper halves. Step 4 and 5 +compute the lower halves. Step 6 and 7 computer the upper halves. + +After the halves have been computed the three intermediate half-size products must be computed. Step 8 and 9 compute the trivial products +$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 - x0$ has been computed. By using $x0$ instead +of an additional temporary variable, the algorithm can avoid an addition memory allocation operation. + +The remaining steps 13 through 18 compute the Karatsuba polynomial through a variety of digit shifting and addition operations. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_karatsuba\_mul.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* c = |a| * |b| using Karatsuba Multiplication using +018 * three half size multiplications +019 * +020 * Let B represent the radix [e.g. 2**DIGIT_BIT] and +021 * let n represent half of the number of digits in +022 * the min(a,b) +023 * +024 * a = a1 * B**n + a0 +025 * b = b1 * B**n + b0 +026 * +027 * Then, a * b => +028 a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 +029 * +030 * Note that a1b1 and a0b0 are used twice and only need to be +031 * computed once. So in total three half size (half # of +032 * digit) multiplications are performed, a0b0, a1b1 and +033 * (a1-b1)(a0-b0) +034 * +035 * Note that a multiplication of half the digits requires +036 * 1/4th the number of single precision multiplications so in +037 * total after one call 25% of the single precision multiplications +038 * are saved. Note also that the call to mp_mul can end up back +039 * in this function if the a0, a1, b0, or b1 are above the threshold. +040 * This is known as divide-and-conquer and leads to the famous +041 * O(N**lg(3)) or O(N**1.584) work which is asymptopically lower than +042 * the standard O(N**2) that the baseline/comba methods use. +043 * Generally though the overhead of this method doesn't pay off +044 * until a certain size (N ~ 80) is reached. +045 */ +046 int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) +047 \{ +048 mp_int x0, x1, y0, y1, t1, x0y0, x1y1; +049 int B, err; +050 +051 /* default the return code to an error */ +052 err = MP_MEM; +053 +054 /* min # of digits */ +055 B = MIN (a->used, b->used); +056 +057 /* now divide in two */ +058 B = B >> 1; +059 +060 /* init copy all the temps */ +061 if (mp_init_size (&x0, B) != MP_OKAY) +062 goto ERR; +063 if (mp_init_size (&x1, a->used - B) != MP_OKAY) +064 goto X0; +065 if (mp_init_size (&y0, B) != MP_OKAY) +066 goto X1; +067 if (mp_init_size (&y1, b->used - B) != MP_OKAY) +068 goto Y0; +069 +070 /* init temps */ +071 if (mp_init_size (&t1, B * 2) != MP_OKAY) +072 goto Y1; +073 if (mp_init_size (&x0y0, B * 2) != MP_OKAY) +074 goto T1; +075 if (mp_init_size (&x1y1, B * 2) != MP_OKAY) +076 goto X0Y0; +077 +078 /* now shift the digits */ +079 x0.used = y0.used = B; +080 x1.used = a->used - B; +081 y1.used = b->used - B; +082 +083 \{ +084 register int x; +085 register mp_digit *tmpa, *tmpb, *tmpx, *tmpy; +086 +087 /* we copy the digits directly instead of using higher level functions +088 * since we also need to shift the digits +089 */ +090 tmpa = a->dp; +091 tmpb = b->dp; +092 +093 tmpx = x0.dp; +094 tmpy = y0.dp; +095 for (x = 0; x < B; x++) \{ +096 *tmpx++ = *tmpa++; +097 *tmpy++ = *tmpb++; +098 \} +099 +100 tmpx = x1.dp; +101 for (x = B; x < a->used; x++) \{ +102 *tmpx++ = *tmpa++; +103 \} +104 +105 tmpy = y1.dp; +106 for (x = B; x < b->used; x++) \{ +107 *tmpy++ = *tmpb++; +108 \} +109 \} +110 +111 /* only need to clamp the lower words since by definition the +112 * upper words x1/y1 must have a known number of digits +113 */ +114 mp_clamp (&x0); +115 mp_clamp (&y0); +116 +117 /* now calc the products x0y0 and x1y1 */ +118 /* after this x0 is no longer required, free temp [x0==t2]! */ +119 if (mp_mul (&x0, &y0, &x0y0) != MP_OKAY) +120 goto X1Y1; /* x0y0 = x0*y0 */ +121 if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) +122 goto X1Y1; /* x1y1 = x1*y1 */ +123 +124 /* now calc x1-x0 and y1-y0 */ +125 if (mp_sub (&x1, &x0, &t1) != MP_OKAY) +126 goto X1Y1; /* t1 = x1 - x0 */ +127 if (mp_sub (&y1, &y0, &x0) != MP_OKAY) +128 goto X1Y1; /* t2 = y1 - y0 */ +129 if (mp_mul (&t1, &x0, &t1) != MP_OKAY) +130 goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ +131 +132 /* add x0y0 */ +133 if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) +134 goto X1Y1; /* t2 = x0y0 + x1y1 */ +135 if (mp_sub (&x0, &t1, &t1) != MP_OKAY) +136 goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ +137 +138 /* shift by B */ +139 if (mp_lshd (&t1, B) != MP_OKAY) +140 goto X1Y1; /* t1 = (x0y0 + x1y1 - (x1-x0)*(y1-y0))<used, b->used) / 3; +037 +038 /* a = a2 * B**2 + a1 * B + a0 */ +039 if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) \{ +040 goto ERR; +041 \} +042 +043 if ((res = mp_copy(a, &a1)) != MP_OKAY) \{ +044 goto ERR; +045 \} +046 mp_rshd(&a1, B); +047 mp_mod_2d(&a1, DIGIT_BIT * B, &a1); +048 +049 if ((res = mp_copy(a, &a2)) != MP_OKAY) \{ +050 goto ERR; +051 \} +052 mp_rshd(&a2, B*2); +053 +054 /* b = b2 * B**2 + b1 * B + b0 */ +055 if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) \{ +056 goto ERR; +057 \} +058 +059 if ((res = mp_copy(b, &b1)) != MP_OKAY) \{ +060 goto ERR; +061 \} +062 mp_rshd(&b1, B); +063 mp_mod_2d(&b1, DIGIT_BIT * B, &b1); +064 +065 if ((res = mp_copy(b, &b2)) != MP_OKAY) \{ +066 goto ERR; +067 \} +068 mp_rshd(&b2, B*2); +069 +070 /* w0 = a0*b0 */ +071 if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) \{ +072 goto ERR; +073 \} +074 +075 /* w4 = a2 * b2 */ +076 if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) \{ +077 goto ERR; +078 \} +079 +080 /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ +081 if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) \{ +082 goto ERR; +083 \} +084 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ +085 goto ERR; +086 \} +087 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ +088 goto ERR; +089 \} +090 if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) \{ +091 goto ERR; +092 \} +093 +094 if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) \{ +095 goto ERR; +096 \} +097 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ +098 goto ERR; +099 \} +100 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ +101 goto ERR; +102 \} +103 if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) \{ +104 goto ERR; +105 \} +106 +107 if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) \{ +108 goto ERR; +109 \} +110 +111 /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ +112 if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) \{ +113 goto ERR; +114 \} +115 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ +116 goto ERR; +117 \} +118 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ +119 goto ERR; +120 \} +121 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ +122 goto ERR; +123 \} +124 +125 if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) \{ +126 goto ERR; +127 \} +128 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ +129 goto ERR; +130 \} +131 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ +132 goto ERR; +133 \} +134 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ +135 goto ERR; +136 \} +137 +138 if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) \{ +139 goto ERR; +140 \} +141 +142 +143 /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ +144 if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) \{ +145 goto ERR; +146 \} +147 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ +148 goto ERR; +149 \} +150 if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) \{ +151 goto ERR; +152 \} +153 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ +154 goto ERR; +155 \} +156 if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) \{ +157 goto ERR; +158 \} +159 +160 /* now solve the matrix +161 +162 0 0 0 0 1 +163 1 2 4 8 16 +164 1 1 1 1 1 +165 16 8 4 2 1 +166 1 0 0 0 0 +167 +168 using 12 subtractions, 4 shifts, +169 2 small divisions and 1 small multiplication +170 */ +171 +172 /* r1 - r4 */ +173 if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) \{ +174 goto ERR; +175 \} +176 /* r3 - r0 */ +177 if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) \{ +178 goto ERR; +179 \} +180 /* r1/2 */ +181 if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) \{ +182 goto ERR; +183 \} +184 /* r3/2 */ +185 if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) \{ +186 goto ERR; +187 \} +188 /* r2 - r0 - r4 */ +189 if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) \{ +190 goto ERR; +191 \} +192 if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) \{ +193 goto ERR; +194 \} +195 /* r1 - r2 */ +196 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ +197 goto ERR; +198 \} +199 /* r3 - r2 */ +200 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ +201 goto ERR; +202 \} +203 /* r1 - 8r0 */ +204 if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) \{ +205 goto ERR; +206 \} +207 if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) \{ +208 goto ERR; +209 \} +210 /* r3 - 8r4 */ +211 if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) \{ +212 goto ERR; +213 \} +214 if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) \{ +215 goto ERR; +216 \} +217 /* 3r2 - r1 - r3 */ +218 if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) \{ +219 goto ERR; +220 \} +221 if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) \{ +222 goto ERR; +223 \} +224 if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) \{ +225 goto ERR; +226 \} +227 /* r1 - r2 */ +228 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ +229 goto ERR; +230 \} +231 /* r3 - r2 */ +232 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ +233 goto ERR; +234 \} +235 /* r1/3 */ +236 if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) \{ +237 goto ERR; +238 \} +239 /* r3/3 */ +240 if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) \{ +241 goto ERR; +242 \} +243 +244 /* at this point shift W[n] by B*n */ +245 if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) \{ +246 goto ERR; +247 \} +248 if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) \{ +249 goto ERR; +250 \} +251 if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) \{ +252 goto ERR; +253 \} +254 if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) \{ +255 goto ERR; +256 \} +257 +258 if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) \{ +259 goto ERR; +260 \} +261 if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) \{ +262 goto ERR; +263 \} +264 if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) \{ +265 goto ERR; +266 \} +267 if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) \{ +268 goto ERR; +269 \} +270 +271 ERR: +272 mp_clear_multi(&w0, &w1, &w2, &w3, &w4, +273 &a0, &a1, &a2, &b0, &b1, +274 &b2, &tmp1, &tmp2, NULL); +275 return res; +276 \} +277 +278 #endif +\end{alltt} +\end{small} + +-- Comments to be added during editing phase. + +\subsection{Signed Multiplication} +Now that algorithms to handle multiplications of every useful dimensions have been developed, a rather simple finishing touch is required. So far all +of the multiplication algorithms have been unsigned multiplications which leaves only a signed multiplication algorithm to be established. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul}. \\ +\textbf{Input}. mp\_int $a$ and mp\_int $b$ \\ +\textbf{Output}. $c \leftarrow a \cdot b$ \\ +\hline \\ +1. If $a.sign = b.sign$ then \\ +\hspace{3mm}1.1 $sign = MP\_ZPOS$ \\ +2. else \\ +\hspace{3mm}2.1 $sign = MP\_ZNEG$ \\ +3. If min$(a.used, b.used) \ge TOOM\_MUL\_CUTOFF$ then \\ +\hspace{3mm}3.1 $c \leftarrow a \cdot b$ using algorithm mp\_toom\_mul \\ +4. else if min$(a.used, b.used) \ge KARATSUBA\_MUL\_CUTOFF$ then \\ +\hspace{3mm}4.1 $c \leftarrow a \cdot b$ using algorithm mp\_karatsuba\_mul \\ +5. else \\ +\hspace{3mm}5.1 $digs \leftarrow a.used + b.used + 1$ \\ +\hspace{3mm}5.2 If $digs < MP\_ARRAY$ and min$(a.used, b.used) \le \delta$ then \\ +\hspace{6mm}5.2.1 $c \leftarrow a \cdot b \mbox{ (mod }\beta^{digs}\mbox{)}$ using algorithm fast\_s\_mp\_mul\_digs. \\ +\hspace{3mm}5.3 else \\ +\hspace{6mm}5.3.1 $c \leftarrow a \cdot b \mbox{ (mod }\beta^{digs}\mbox{)}$ using algorithm s\_mp\_mul\_digs. \\ +6. $c.sign \leftarrow sign$ \\ +7. Return the result of the unsigned multiplication performed. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul} +\end{figure} + +\textbf{Algorithm mp\_mul.} +This algorithm performs the signed multiplication of two inputs. It will make use of any of the three unsigned multiplication algorithms +available when the input is of appropriate size. The \textbf{sign} of the result is not set until the end of the algorithm since algorithm +s\_mp\_mul\_digs will clear it. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_mul.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* high level multiplication (handles sign) */ +018 int mp_mul (mp_int * a, mp_int * b, mp_int * c) +019 \{ +020 int res, neg; +021 neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; +022 +023 /* use Toom-Cook? */ +024 #ifdef BN_MP_TOOM_MUL_C +025 if (MIN (a->used, b->used) >= TOOM_MUL_CUTOFF) \{ +026 res = mp_toom_mul(a, b, c); +027 \} else +028 #endif +029 #ifdef BN_MP_KARATSUBA_MUL_C +030 /* use Karatsuba? */ +031 if (MIN (a->used, b->used) >= KARATSUBA_MUL_CUTOFF) \{ +032 res = mp_karatsuba_mul (a, b, c); +033 \} else +034 #endif +035 \{ +036 /* can we use the fast multiplier? +037 * +038 * The fast multiplier can be used if the output will +039 * have less than MP_WARRAY digits and the number of +040 * digits won't affect carry propagation +041 */ +042 int digs = a->used + b->used + 1; +043 +044 #ifdef BN_FAST_S_MP_MUL_DIGS_C +045 if ((digs < MP_WARRAY) && +046 MIN(a->used, b->used) <= +047 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ +048 res = fast_s_mp_mul_digs (a, b, c, digs); +049 \} else +050 #endif +051 #ifdef BN_S_MP_MUL_DIGS_C +052 res = s_mp_mul (a, b, c); /* uses s_mp_mul_digs */ +053 #else +054 res = MP_VAL; +055 #endif +056 +057 \} +058 c->sign = (c->used > 0) ? neg : MP_ZPOS; +059 return res; +060 \} +061 #endif +\end{alltt} +\end{small} + +The implementation is rather simplistic and is not particularly noteworthy. Line 23 computes the sign of the result using the ``?'' +operator from the C programming language. Line 47 computes $\delta$ using the fact that $1 << k$ is equal to $2^k$. + +\section{Squaring} +\label{sec:basesquare} + +Squaring is a special case of multiplication where both multiplicands are equal. At first it may seem like there is no significant optimization +available but in fact there is. Consider the multiplication of $576$ against $241$. In total there will be nine single precision multiplications +performed which are $1\cdot 6$, $1 \cdot 7$, $1 \cdot 5$, $4 \cdot 6$, $4 \cdot 7$, $4 \cdot 5$, $2 \cdot 6$, $2 \cdot 7$ and $2 \cdot 5$. Now consider +the multiplication of $123$ against $123$. The nine products are $3 \cdot 3$, $3 \cdot 2$, $3 \cdot 1$, $2 \cdot 3$, $2 \cdot 2$, $2 \cdot 1$, +$1 \cdot 3$, $1 \cdot 2$ and $1 \cdot 1$. On closer inspection some of the products are equivalent. For example, $3 \cdot 2 = 2 \cdot 3$ +and $3 \cdot 1 = 1 \cdot 3$. + +For any $n$-digit input, there are ${{\left (n^2 + n \right)}\over 2}$ possible unique single precision multiplications required compared to the $n^2$ +required for multiplication. The following diagram gives an example of the operations required. + +\begin{figure}[here] +\begin{center} +\begin{tabular}{ccccc|c} +&&1&2&3&\\ +$\times$ &&1&2&3&\\ +\hline && $3 \cdot 1$ & $3 \cdot 2$ & $3 \cdot 3$ & Row 0\\ + & $2 \cdot 1$ & $2 \cdot 2$ & $2 \cdot 3$ && Row 1 \\ + $1 \cdot 1$ & $1 \cdot 2$ & $1 \cdot 3$ &&& Row 2 \\ +\end{tabular} +\end{center} +\caption{Squaring Optimization Diagram} +\end{figure} + +Starting from zero and numbering the columns from right to left a very simple pattern becomes obvious. For the purposes of this discussion let $x$ +represent the number being squared. The first observation is that in row $k$ the $2k$'th column of the product has a $\left (x_k \right)^2$ term in it. + +The second observation is that every column $j$ in row $k$ where $j \ne 2k$ is part of a double product. Every non-square term of a column will +appear twice hence the name ``double product''. Every odd column is made up entirely of double products. In fact every column is made up of double +products and at most one square (\textit{see the exercise section}). + +The third and final observation is that for row $k$ the first unique non-square term, that is, one that hasn't already appeared in an earlier row, +occurs at column $2k + 1$. For example, on row $1$ of the previous squaring, column one is part of the double product with column one from row zero. +Column two of row one is a square and column three is the first unique column. + +\subsection{The Baseline Squaring Algorithm} +The baseline squaring algorithm is meant to be a catch-all squaring algorithm. It will handle any of the input sizes that the faster routines +will not handle. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +1. Init a temporary mp\_int of at least $2 \cdot a.used +1$ digits. (\textit{mp\_init\_size}) \\ +2. If step 1 failed return(\textit{MP\_MEM}) \\ +3. $t.used \leftarrow 2 \cdot a.used + 1$ \\ +4. For $ix$ from 0 to $a.used - 1$ do \\ +\hspace{3mm}Calculate the square. \\ +\hspace{3mm}4.1 $\hat r \leftarrow t_{2ix} + \left (a_{ix} \right )^2$ \\ +\hspace{3mm}4.2 $t_{2ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}Calculate the double products after the square. \\ +\hspace{3mm}4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}4.4 For $iy$ from $ix + 1$ to $a.used - 1$ do \\ +\hspace{6mm}4.4.1 $\hat r \leftarrow 2 \cdot a_{ix}a_{iy} + t_{ix + iy} + u$ \\ +\hspace{6mm}4.4.2 $t_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}4.4.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}Set the last carry. \\ +\hspace{3mm}4.5 While $u > 0$ do \\ +\hspace{6mm}4.5.1 $iy \leftarrow iy + 1$ \\ +\hspace{6mm}4.5.2 $\hat r \leftarrow t_{ix + iy} + u$ \\ +\hspace{6mm}4.5.3 $t_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}4.5.4 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +5. Clamp excess digits of $t$. (\textit{mp\_clamp}) \\ +6. Exchange $b$ and $t$. \\ +7. Clear $t$ (\textit{mp\_clear}) \\ +8. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_sqr} +\end{figure} + +\textbf{Algorithm s\_mp\_sqr.} +This algorithm computes the square of an input using the three observations on squaring. It is based fairly faithfully on algorithm 14.16 of HAC +\cite[pp.596-597]{HAC}. Similar to algorithm s\_mp\_mul\_digs, a temporary mp\_int is allocated to hold the result of the squaring. This allows the +destination mp\_int to be the same as the source mp\_int. + +The outer loop of this algorithm begins on step 4. It is best to think of the outer loop as walking down the rows of the partial results, while +the inner loop computes the columns of the partial result. Step 4.1 and 4.2 compute the square term for each row, and step 4.3 and 4.4 propagate +the carry and compute the double products. + +The requirement that a mp\_word be able to represent the range $0 \le x < 2 \beta^2$ arises from this +very algorithm. The product $a_{ix}a_{iy}$ will lie in the range $0 \le x \le \beta^2 - 2\beta + 1$ which is obviously less than $\beta^2$ meaning that +when it is multiplied by two, it can be properly represented by a mp\_word. + +Similar to algorithm s\_mp\_mul\_digs, after every pass of the inner loop, the destination is correctly set to the sum of all of the partial +results calculated so far. This involves expensive carry propagation which will be eliminated in the next algorithm. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_s\_mp\_sqr.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ +018 int +019 s_mp_sqr (mp_int * a, mp_int * b) +020 \{ +021 mp_int t; +022 int res, ix, iy, pa; +023 mp_word r; +024 mp_digit u, tmpx, *tmpt; +025 +026 pa = a->used; +027 if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) \{ +028 return res; +029 \} +030 +031 /* default used is maximum possible size */ +032 t.used = 2*pa + 1; +033 +034 for (ix = 0; ix < pa; ix++) \{ +035 /* first calculate the digit at 2*ix */ +036 /* calculate double precision result */ +037 r = ((mp_word) t.dp[2*ix]) + +038 ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); +039 +040 /* store lower part in result */ +041 t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); +042 +043 /* get the carry */ +044 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +045 +046 /* left hand side of A[ix] * A[iy] */ +047 tmpx = a->dp[ix]; +048 +049 /* alias for where to store the results */ +050 tmpt = t.dp + (2*ix + 1); +051 +052 for (iy = ix + 1; iy < pa; iy++) \{ +053 /* first calculate the product */ +054 r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); +055 +056 /* now calculate the double precision result, note we use +057 * addition instead of *2 since it's easier to optimize +058 */ +059 r = ((mp_word) *tmpt) + r + r + ((mp_word) u); +060 +061 /* store lower part */ +062 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +063 +064 /* get carry */ +065 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +066 \} +067 /* propagate upwards */ +068 while (u != ((mp_digit) 0)) \{ +069 r = ((mp_word) *tmpt) + ((mp_word) u); +070 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +071 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +072 \} +073 \} +074 +075 mp_clamp (&t); +076 mp_exch (&t, b); +077 mp_clear (&t); +078 return MP_OKAY; +079 \} +080 #endif +\end{alltt} +\end{small} + +Inside the outer loop (\textit{see line 34}) the square term is calculated on line 37. Line 44 extracts the carry from the square +term. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized on lines 47 and 50 respectively. The doubling is performed using two +additions (\textit{see line 59}) since it is usually faster than shifting,if not at least as fast. + +\subsection{Faster Squaring by the ``Comba'' Method} +A major drawback to the baseline method is the requirement for single precision shifting inside the $O(n^2)$ nested loop. Squaring has an additional +drawback that it must double the product inside the inner loop as well. As for multiplication, the Comba technique can be used to eliminate these +performance hazards. + +The first obvious solution is to make an array of mp\_words which will hold all of the columns. This will indeed eliminate all of the carry +propagation operations from the inner loop. However, the inner product must still be doubled $O(n^2)$ times. The solution stems from the simple fact +that $2a + 2b + 2c = 2(a + b + c)$. That is the sum of all of the double products is equal to double the sum of all the products. For example, +$ab + ba + ac + ca = 2ab + 2ac = 2(ab + ac)$. + +However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two mp\_word +arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and carry propagation can be +moved to a $O(n)$ work level outside the $O(n^2)$ level. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_s\_mp\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +Place two arrays of \textbf{MP\_WARRAY} mp\_words named $\hat W$ and $\hat {X}$ on the stack. \\ +1. If $b.alloc < 2a.used + 1$ then grow $b$ to $2a.used + 1$ digits. (\textit{mp\_grow}). \\ +2. If step 1 failed return(\textit{MP\_MEM}). \\ +3. for $ix$ from $0$ to $2a.used + 1$ do \\ +\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ +\hspace{3mm}3.2 $\hat {X}_{ix} \leftarrow 0$ \\ +4. for $ix$ from $0$ to $a.used - 1$ do \\ +\hspace{3mm}Compute the square.\\ +\hspace{3mm}4.1 $\hat {X}_{ix+ix} \leftarrow \left ( a_{ix} \right )^2$ \\ +\\ +\hspace{3mm}Compute the double products.\\ +\hspace{3mm}4.2 for $iy$ from $ix + 1$ to $a.used - 1$ do \\ +\hspace{6mm}4.2.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}a_{iy}$ \\ +5. $oldused \leftarrow b.used$ \\ +6. $b.used \leftarrow 2a.used + 1$ \\ +\\ +Double the products and propagate the carries simultaneously. \\ +7. $\hat W_0 \leftarrow 2 \hat W_0 + \hat {X}_0$ \\ +8. for $ix$ from $1$ to $2a.used$ do \\ +\hspace{3mm}8.1 $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ \\ +\hspace{3mm}8.2 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix - 1} / \beta \rfloor$ \\ +\hspace{3mm}8.3 $b_{ix-1} \leftarrow W_{ix-1} \mbox{ (mod }\beta\mbox{)}$ \\ +9. $b_{2a.used} \leftarrow \hat W_{2a.used} \mbox{ (mod }\beta\mbox{)}$ \\ +10. if $2a.used + 1 < oldused$ then do \\ +\hspace{3mm}10.1 for $ix$ from $2a.used + 1$ to $oldused$ do \\ +\hspace{6mm}10.1.1 $b_{ix} \leftarrow 0$ \\ +11. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ +12. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_s\_mp\_sqr} +\end{figure} + +\textbf{Algorithm fast\_s\_mp\_sqr.} +This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm s\_mp\_sqr when +the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. + +This routine requires two arrays of mp\_words to be placed on the stack. The first array $\hat W$ will hold the double products and the second +array $\hat X$ will hold the squares. Though only at most $MP\_WARRAY \over 2$ words of $\hat X$ are used, it has proven faster on most +processors to simply make it a full size array. + +The loop on step 3 will zero the two arrays to prepare them for the squaring step. Step 4.1 computes the squares of the product. Note how +it simply assigns the value into the $\hat X$ array. The nested loop on step 4.2 computes the doubles of the products. This loop +computes the sum of the products for each column. They are not doubled until later. + +After the squaring loop, the products stored in $\hat W$ musted be doubled and the carries propagated forwards. It makes sense to do both +operations at the same time. The expression $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ computes the sum of the double product and the +squares in place. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_fast\_s\_mp\_sqr.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* fast squaring +018 * +019 * This is the comba method where the columns of the product +020 * are computed first then the carries are computed. This +021 * has the effect of making a very simple inner loop that +022 * is executed the most +023 * +024 * W2 represents the outer products and W the inner. +025 * +026 * A further optimizations is made because the inner +027 * products are of the form "A * B * 2". The *2 part does +028 * not need to be computed until the end which is good +029 * because 64-bit shifts are slow! +030 * +031 * Based on Algorithm 14.16 on pp.597 of HAC. +032 * +033 */ +034 /* the jist of squaring... +035 +036 you do like mult except the offset of the tmpx [one that starts closer to ze + ro] +037 can't equal the offset of tmpy. So basically you set up iy like before then + you min it with +038 (ty-tx) so that it never happens. You double all those you add in the inner + loop +039 +040 After that loop you do the squares and add them in. +041 +042 Remove W2 and don't memset W +043 +044 */ +045 +046 int fast_s_mp_sqr (mp_int * a, mp_int * b) +047 \{ +048 int olduse, res, pa, ix, iz; +049 mp_digit W[MP_WARRAY], *tmpx; +050 mp_word W1; +051 +052 /* grow the destination as required */ +053 pa = a->used + a->used; +054 if (b->alloc < pa) \{ +055 if ((res = mp_grow (b, pa)) != MP_OKAY) \{ +056 return res; +057 \} +058 \} +059 +060 /* number of output digits to produce */ +061 W1 = 0; +062 for (ix = 0; ix < pa; ix++) \{ +063 int tx, ty, iy; +064 mp_word _W; +065 mp_digit *tmpy; +066 +067 /* clear counter */ +068 _W = 0; +069 +070 /* get offsets into the two bignums */ +071 ty = MIN(a->used-1, ix); +072 tx = ix - ty; +073 +074 /* setup temp aliases */ +075 tmpx = a->dp + tx; +076 tmpy = a->dp + ty; +077 +078 /* this is the number of times the loop will iterrate, essentially its + +079 while (tx++ < a->used && ty-- >= 0) \{ ... \} +080 */ +081 iy = MIN(a->used-tx, ty+1); +082 +083 /* now for squaring tx can never equal ty +084 * we halve the distance since they approach at a rate of 2x +085 * and we have to round because odd cases need to be executed +086 */ +087 iy = MIN(iy, (ty-tx+1)>>1); +088 +089 /* execute loop */ +090 for (iz = 0; iz < iy; iz++) \{ +091 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); +092 \} +093 +094 /* double the inner product and add carry */ +095 _W = _W + _W + W1; +096 +097 /* even columns have the square term in them */ +098 if ((ix&1) == 0) \{ +099 _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); +100 \} +101 +102 /* store it */ +103 W[ix] = _W; +104 +105 /* make next carry */ +106 W1 = _W >> ((mp_word)DIGIT_BIT); +107 \} +108 +109 /* setup dest */ +110 olduse = b->used; +111 b->used = a->used+a->used; +112 +113 \{ +114 mp_digit *tmpb; +115 tmpb = b->dp; +116 for (ix = 0; ix < pa; ix++) \{ +117 *tmpb++ = W[ix] & MP_MASK; +118 \} +119 +120 /* clear unused digits [that existed in the old copy of c] */ +121 for (; ix < olduse; ix++) \{ +122 *tmpb++ = 0; +123 \} +124 \} +125 mp_clamp (b); +126 return MP_OKAY; +127 \} +128 #endif +\end{alltt} +\end{small} + +-- Write something deep and insightful later, Tom. + +\subsection{Polynomial Basis Squaring} +The same algorithm that performs optimal polynomial basis multiplication can be used to perform polynomial basis squaring. The minor exception +is that $\zeta_y = f(y)g(y)$ is actually equivalent to $\zeta_y = f(y)^2$ since $f(y) = g(y)$. Instead of performing $2n + 1$ +multiplications to find the $\zeta$ relations, squaring operations are performed instead. + +\subsection{Karatsuba Squaring} +Let $f(x) = ax + b$ represent the polynomial basis representation of a number to square. +Let $h(x) = \left ( f(x) \right )^2$ represent the square of the polynomial. The Karatsuba equation can be modified to square a +number with the following equation. + +\begin{equation} +h(x) = a^2x^2 + \left (a^2 + b^2 - (a - b)^2 \right )x + b^2 +\end{equation} + +Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a - b)^2$. As in +Karatsuba multiplication, this algorithm can be applied recursively on the input and will achieve an asymptotic running time of +$O \left ( n^{lg(3)} \right )$. + +If the asymptotic times of Karatsuba squaring and multiplication are the same, why not simply use the multiplication algorithm +instead? The answer to this arises from the cutoff point for squaring. As in multiplication there exists a cutoff point, at which the +time required for a Comba based squaring and a Karatsuba based squaring meet. Due to the overhead inherent in the Karatsuba method, the cutoff +point is fairly high. For example, on an AMD Athlon XP processor with $\beta = 2^{28}$, the cutoff point is around 127 digits. + +Consider squaring a 200 digit number with this technique. It will be split into two 100 digit halves which are subsequently squared. +The 100 digit halves will not be squared using Karatsuba, but instead using the faster Comba based squaring algorithm. If Karatsuba multiplication +were used instead, the 100 digit numbers would be squared with a slower Comba based multiplication. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_karatsuba\_sqr}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $b \leftarrow a^2$ \\ +\hline \\ +1. Initialize the following temporary mp\_ints: $x0$, $x1$, $t1$, $t2$, $x0x0$ and $x1x1$. \\ +2. If any of the initializations on step 1 failed return(\textit{MP\_MEM}). \\ +\\ +Split the input. e.g. $a = x1\beta^B + x0$ \\ +3. $B \leftarrow \lfloor a.used / 2 \rfloor$ \\ +4. $x0 \leftarrow a \mbox{ (mod }\beta^B\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +5. $x1 \leftarrow \lfloor a / \beta^B \rfloor$ (\textit{mp\_lshd}) \\ +\\ +Calculate the three squares. \\ +6. $x0x0 \leftarrow x0^2$ (\textit{mp\_sqr}) \\ +7. $x1x1 \leftarrow x1^2$ \\ +8. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +9. $t1 \leftarrow t1^2$ \\ +\\ +Compute the middle term. \\ +10. $t2 \leftarrow x0x0 + x1x1$ (\textit{s\_mp\_add}) \\ +11. $t1 \leftarrow t2 - t1$ \\ +\\ +Compute final product. \\ +12. $t1 \leftarrow t1\beta^B$ (\textit{mp\_lshd}) \\ +13. $x1x1 \leftarrow x1x1\beta^{2B}$ \\ +14. $t1 \leftarrow t1 + x0x0$ \\ +15. $b \leftarrow t1 + x1x1$ \\ +16. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_karatsuba\_sqr} +\end{figure} + +\textbf{Algorithm mp\_karatsuba\_sqr.} +This algorithm computes the square of an input $a$ using the Karatsuba technique. This algorithm is very similar to the Karatsuba based +multiplication algorithm with the exception that the three half-size multiplications have been replaced with three half-size squarings. + +The radix point for squaring is simply placed exactly in the middle of the digits when the input has an odd number of digits, otherwise it is +placed just below the middle. Step 3, 4 and 5 compute the two halves required using $B$ +as the radix point. The first two squares in steps 6 and 7 are rather straightforward while the last square is of a more compact form. + +By expanding $\left (x1 - x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $x1^2 + x0^2 - (x1 - x0)^2 = 2 \cdot x0 \cdot x1$. +Now if $5n$ single precision additions and a squaring of $n$-digits is faster than multiplying two $n$-digit numbers and doubling then +this method is faster. Assuming no further recursions occur, the difference can be estimated with the following inequality. + +Let $p$ represent the cost of a single precision addition and $q$ the cost of a single precision multiplication both in terms of time\footnote{Or +machine clock cycles.}. + +\begin{equation} +5pn +{{q(n^2 + n)} \over 2} \le pn + qn^2 +\end{equation} + +For example, on an AMD Athlon XP processor $p = {1 \over 3}$ and $q = 6$. This implies that the following inequality should hold. +\begin{center} +\begin{tabular}{rcl} +${5n \over 3} + 3n^2 + 3n$ & $<$ & ${n \over 3} + 6n^2$ \\ +${5 \over 3} + 3n + 3$ & $<$ & ${1 \over 3} + 6n$ \\ +${13 \over 9}$ & $<$ & $n$ \\ +\end{tabular} +\end{center} + +This results in a cutoff point around $n = 2$. As a consequence it is actually faster to compute the middle term the ``long way'' on processors +where multiplication is substantially slower\footnote{On the Athlon there is a 1:17 ratio between clock cycles for addition and multiplication. On +the Intel P4 processor this ratio is 1:29 making this method even more beneficial. The only common exception is the ARMv4 processor which has a +ratio of 1:7. } than simpler operations such as addition. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_karatsuba\_sqr.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* Karatsuba squaring, computes b = a*a using three +018 * half size squarings +019 * +020 * See comments of karatsuba_mul for details. It +021 * is essentially the same algorithm but merely +022 * tuned to perform recursive squarings. +023 */ +024 int mp_karatsuba_sqr (mp_int * a, mp_int * b) +025 \{ +026 mp_int x0, x1, t1, t2, x0x0, x1x1; +027 int B, err; +028 +029 err = MP_MEM; +030 +031 /* min # of digits */ +032 B = a->used; +033 +034 /* now divide in two */ +035 B = B >> 1; +036 +037 /* init copy all the temps */ +038 if (mp_init_size (&x0, B) != MP_OKAY) +039 goto ERR; +040 if (mp_init_size (&x1, a->used - B) != MP_OKAY) +041 goto X0; +042 +043 /* init temps */ +044 if (mp_init_size (&t1, a->used * 2) != MP_OKAY) +045 goto X1; +046 if (mp_init_size (&t2, a->used * 2) != MP_OKAY) +047 goto T1; +048 if (mp_init_size (&x0x0, B * 2) != MP_OKAY) +049 goto T2; +050 if (mp_init_size (&x1x1, (a->used - B) * 2) != MP_OKAY) +051 goto X0X0; +052 +053 \{ +054 register int x; +055 register mp_digit *dst, *src; +056 +057 src = a->dp; +058 +059 /* now shift the digits */ +060 dst = x0.dp; +061 for (x = 0; x < B; x++) \{ +062 *dst++ = *src++; +063 \} +064 +065 dst = x1.dp; +066 for (x = B; x < a->used; x++) \{ +067 *dst++ = *src++; +068 \} +069 \} +070 +071 x0.used = B; +072 x1.used = a->used - B; +073 +074 mp_clamp (&x0); +075 +076 /* now calc the products x0*x0 and x1*x1 */ +077 if (mp_sqr (&x0, &x0x0) != MP_OKAY) +078 goto X1X1; /* x0x0 = x0*x0 */ +079 if (mp_sqr (&x1, &x1x1) != MP_OKAY) +080 goto X1X1; /* x1x1 = x1*x1 */ +081 +082 /* now calc (x1-x0)**2 */ +083 if (mp_sub (&x1, &x0, &t1) != MP_OKAY) +084 goto X1X1; /* t1 = x1 - x0 */ +085 if (mp_sqr (&t1, &t1) != MP_OKAY) +086 goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ +087 +088 /* add x0y0 */ +089 if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) +090 goto X1X1; /* t2 = x0x0 + x1x1 */ +091 if (mp_sub (&t2, &t1, &t1) != MP_OKAY) +092 goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ +093 +094 /* shift by B */ +095 if (mp_lshd (&t1, B) != MP_OKAY) +096 goto X1X1; /* t1 = (x0x0 + x1x1 - (x1-x0)*(x1-x0))<used >= TOOM_SQR_CUTOFF) \{ +026 res = mp_toom_sqr(a, b); +027 /* Karatsuba? */ +028 \} else +029 #endif +030 #ifdef BN_MP_KARATSUBA_SQR_C +031 if (a->used >= KARATSUBA_SQR_CUTOFF) \{ +032 res = mp_karatsuba_sqr (a, b); +033 \} else +034 #endif +035 \{ +036 #ifdef BN_FAST_S_MP_SQR_C +037 /* can we use the fast comba multiplier? */ +038 if ((a->used * 2 + 1) < MP_WARRAY && +039 a->used < +040 (1 << (sizeof(mp_word) * CHAR_BIT - 2*DIGIT_BIT - 1))) \{ +041 res = fast_s_mp_sqr (a, b); +042 \} else +043 #endif +044 #ifdef BN_S_MP_SQR_C +045 res = s_mp_sqr (a, b); +046 #else +047 res = MP_VAL; +048 #endif +049 \} +050 b->sign = MP_ZPOS; +051 return res; +052 \} +053 #endif +\end{alltt} +\end{small} + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ] $ & Devise an efficient algorithm for selection of the radix point to handle inputs \\ + & that have different number of digits in Karatsuba multiplication. \\ + & \\ +$\left [ 3 \right ] $ & In section 5.3 the fact that every column of a squaring is made up \\ + & of double products and at most one square is stated. Prove this statement. \\ + & \\ +$\left [ 2 \right ] $ & In the Comba squaring algorithm half of the $\hat X$ variables are not used. \\ + & Revise algorithm fast\_s\_mp\_sqr to shrink the $\hat X$ array. \\ + & \\ +$\left [ 3 \right ] $ & Prove the equation for Karatsuba squaring. \\ + & \\ +$\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3)} \right )$ time. \\ + & \\ +$\left [ 2 \right ] $ & Determine the minimal ratio between addition and multiplication clock cycles \\ + & required for equation $6.7$ to be true. \\ + & \\ +\end{tabular} + +\chapter{Modular Reduction} +\section{Basics of Modular Reduction} +\index{modular residue} +Modular reduction is an operation that arises quite often within public key cryptography algorithms and various number theoretic algorithms, +such as factoring. Modular reduction algorithms are the third class of algorithms of the ``multipliers'' set. A number $a$ is said to be \textit{reduced} +modulo another number $b$ by finding the remainder of the division $a/b$. Full integer division with remainder is a topic to be covered +in~\ref{sec:division}. + +Modular reduction is equivalent to solving for $r$ in the following equation. $a = bq + r$ where $q = \lfloor a/b \rfloor$. The result +$r$ is said to be ``congruent to $a$ modulo $b$'' which is also written as $r \equiv a \mbox{ (mod }b\mbox{)}$. In other vernacular $r$ is known as the +``modular residue'' which leads to ``quadratic residue''\footnote{That's fancy talk for $b \equiv a^2 \mbox{ (mod }p\mbox{)}$.} and +other forms of residues. + +Modular reductions are normally used to create either finite groups, rings or fields. The most common usage for performance driven modular reductions +is in modular exponentiation algorithms. That is to compute $d = a^b \mbox{ (mod }c\mbox{)}$ as fast as possible. This operation is used in the +RSA and Diffie-Hellman public key algorithms, for example. Modular multiplication and squaring also appears as a fundamental operation in +Elliptic Curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular +exponentiations without having to perform (\textit{in this example}) $b - 1$ multiplications. These algorithms will produce partial results in the +range $0 \le x < c^2$ which can be taken advantage of to create several efficient algorithms. They have also been used to create redundancy check +algorithms known as CRCs, error correction codes such as Reed-Solomon and solve a variety of number theoeretic problems. + +\section{The Barrett Reduction} +The Barrett reduction algorithm \cite{BARRETT} was inspired by fast division algorithms which multiply by the reciprocal to emulate +division. Barretts observation was that the residue $c$ of $a$ modulo $b$ is equal to + +\begin{equation} +c = a - b \cdot \lfloor a/b \rfloor +\end{equation} + +Since algorithms such as modular exponentiation would be using the same modulus extensively, typical DSP\footnote{It is worth noting that Barrett's paper +targeted the DSP56K processor.} intuition would indicate the next step would be to replace $a/b$ by a multiplication by the reciprocal. However, +DSP intuition on its own will not work as these numbers are considerably larger than the precision of common DSP floating point data types. +It would take another common optimization to optimize the algorithm. + +\subsection{Fixed Point Arithmetic} +The trick used to optimize the above equation is based on a technique of emulating floating point data types with fixed precision integers. Fixed +point arithmetic would become very popular as it greatly optimize the ``3d-shooter'' genre of games in the mid 1990s when floating point units were +fairly slow if not unavailable. The idea behind fixed point arithmetic is to take a normal $k$-bit integer data type and break it into $p$-bit +integer and a $q$-bit fraction part (\textit{where $p+q = k$}). + +In this system a $k$-bit integer $n$ would actually represent $n/2^q$. For example, with $q = 4$ the integer $n = 37$ would actually represent the +value $2.3125$. To multiply two fixed point numbers the integers are multiplied using traditional arithmetic and subsequently normalized by +moving the implied decimal point back to where it should be. For example, with $q = 4$ to multiply the integers $9$ and $5$ they must be converted +to fixed point first by multiplying by $2^q$. Let $a = 9(2^q)$ represent the fixed point representation of $9$ and $b = 5(2^q)$ represent the +fixed point representation of $5$. The product $ab$ is equal to $45(2^{2q})$ which when normalized by dividing by $2^q$ produces $45(2^q)$. + +This technique became popular since a normal integer multiplication and logical shift right are the only required operations to perform a multiplication +of two fixed point numbers. Using fixed point arithmetic, division can be easily approximated by multiplying by the reciprocal. If $2^q$ is +equivalent to one than $2^q/b$ is equivalent to the fixed point approximation of $1/b$ using real arithmetic. Using this fact dividing an integer +$a$ by another integer $b$ can be achieved with the following expression. + +\begin{equation} +\lfloor a / b \rfloor \mbox{ }\approx\mbox{ } \lfloor (a \cdot \lfloor 2^q / b \rfloor)/2^q \rfloor +\end{equation} + +The precision of the division is proportional to the value of $q$. If the divisor $b$ is used frequently as is the case with +modular exponentiation pre-computing $2^q/b$ will allow a division to be performed with a multiplication and a right shift. Both operations +are considerably faster than division on most processors. + +Consider dividing $19$ by $5$. The correct result is $\lfloor 19/5 \rfloor = 3$. With $q = 3$ the reciprocal is $\lfloor 2^q/5 \rfloor = 1$ which +leads to a product of $19$ which when divided by $2^q$ produces $2$. However, with $q = 4$ the reciprocal is $\lfloor 2^q/5 \rfloor = 3$ and +the result of the emulated division is $\lfloor 3 \cdot 19 / 2^q \rfloor = 3$ which is correct. The value of $2^q$ must be close to or ideally +larger than the dividend. In effect if $a$ is the dividend then $q$ should allow $0 \le \lfloor a/2^q \rfloor \le 1$ in order for this approach +to work correctly. Plugging this form of divison into the original equation the following modular residue equation arises. + +\begin{equation} +c = a - b \cdot \lfloor (a \cdot \lfloor 2^q / b \rfloor)/2^q \rfloor +\end{equation} + +Using the notation from \cite{BARRETT} the value of $\lfloor 2^q / b \rfloor$ will be represented by the $\mu$ symbol. Using the $\mu$ +variable also helps re-inforce the idea that it is meant to be computed once and re-used. + +\begin{equation} +c = a - b \cdot \lfloor (a \cdot \mu)/2^q \rfloor +\end{equation} + +Provided that $2^q \ge a$ this algorithm will produce a quotient that is either exactly correct or off by a value of one. In the context of Barrett +reduction the value of $a$ is bound by $0 \le a \le (b - 1)^2$ meaning that $2^q \ge b^2$ is sufficient to ensure the reciprocal will have enough +precision. + +Let $n$ represent the number of digits in $b$. This algorithm requires approximately $2n^2$ single precision multiplications to produce the quotient and +another $n^2$ single precision multiplications to find the residue. In total $3n^2$ single precision multiplications are required to +reduce the number. + +For example, if $b = 1179677$ and $q = 41$ ($2^q > b^2$), then the reciprocal $\mu$ is equal to $\lfloor 2^q / b \rfloor = 1864089$. Consider reducing +$a = 180388626447$ modulo $b$ using the above reduction equation. The quotient using the new formula is $\lfloor (a \cdot \mu) / 2^q \rfloor = 152913$. +By subtracting $152913b$ from $a$ the correct residue $a \equiv 677346 \mbox{ (mod }b\mbox{)}$ is found. + +\subsection{Choosing a Radix Point} +Using the fixed point representation a modular reduction can be performed with $3n^2$ single precision multiplications. If that were the best +that could be achieved a full division\footnote{A division requires approximately $O(2cn^2)$ single precision multiplications for a small value of $c$. +See~\ref{sec:division} for further details.} might as well be used in its place. The key to optimizing the reduction is to reduce the precision of +the initial multiplication that finds the quotient. + +Let $a$ represent the number of which the residue is sought. Let $b$ represent the modulus used to find the residue. Let $m$ represent +the number of digits in $b$. For the purposes of this discussion we will assume that the number of digits in $a$ is $2m$, which is generally true if +two $m$-digit numbers have been multiplied. Dividing $a$ by $b$ is the same as dividing a $2m$ digit integer by a $m$ digit integer. Digits below the +$m - 1$'th digit of $a$ will contribute at most a value of $1$ to the quotient because $\beta^k < b$ for any $0 \le k \le m - 1$. Another way to +express this is by re-writing $a$ as two parts. If $a' \equiv a \mbox{ (mod }b^m\mbox{)}$ and $a'' = a - a'$ then +${a \over b} \equiv {{a' + a''} \over b}$ which is equivalent to ${a' \over b} + {a'' \over b}$. Since $a'$ is bound to be less than $b$ the quotient +is bound by $0 \le {a' \over b} < 1$. + +Since the digits of $a'$ do not contribute much to the quotient the observation is that they might as well be zero. However, if the digits +``might as well be zero'' they might as well not be there in the first place. Let $q_0 = \lfloor a/\beta^{m-1} \rfloor$ represent the input +with the irrelevant digits trimmed. Now the modular reduction is trimmed to the almost equivalent equation + +\begin{equation} +c = a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor +\end{equation} + +Note that the original divisor $2^q$ has been replaced with $\beta^{m+1}$ where in this case $q$ is a multiple of $lg(\beta)$. Also note that the +exponent on the divisor when added to the amount $q_0$ was shifted by equals $2m$. If the optimization had not been performed the divisor +would have the exponent $2m$ so in the end the exponents do ``add up''. Using the above equation the quotient +$\lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ can be off from the true quotient by at most two. The original fixed point quotient can be off +by as much as one (\textit{provided the radix point is chosen suitably}) and now that the lower irrelevent digits have been trimmed the quotient +can be off by an additional value of one for a total of at most two. This implies that +$0 \le a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor < 3b$. By first subtracting $b$ times the quotient and then conditionally subtracting +$b$ once or twice the residue is found. + +The quotient is now found using $(m + 1)(m) = m^2 + m$ single precision multiplications and the residue with an additional $m^2$ single +precision multiplications, ignoring the subtractions required. In total $2m^2 + m$ single precision multiplications are required to find the residue. +This is considerably faster than the original attempt. + +For example, let $\beta = 10$ represent the radix of the digits. Let $b = 9999$ represent the modulus which implies $m = 4$. Let $a = 99929878$ +represent the value of which the residue is desired. In this case $q = 8$ since $10^7 < 9999^2$ meaning that $\mu = \lfloor \beta^{q}/b \rfloor = 10001$. +With the new observation the multiplicand for the quotient is equal to $q_0 = \lfloor a / \beta^{m - 1} \rfloor = 99929$. The quotient is then +$\lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor = 9993$. Subtracting $9993b$ from $a$ and the correct residue $a \equiv 9871 \mbox{ (mod }b\mbox{)}$ +is found. + +\subsection{Trimming the Quotient} +So far the reduction algorithm has been optimized from $3m^2$ single precision multiplications down to $2m^2 + m$ single precision multiplications. As +it stands now the algorithm is already fairly fast compared to a full integer division algorithm. However, there is still room for +optimization. + +After the first multiplication inside the quotient ($q_0 \cdot \mu$) the value is shifted right by $m + 1$ places effectively nullifying the lower +half of the product. It would be nice to be able to remove those digits from the product to effectively cut down the number of single precision +multiplications. If the number of digits in the modulus $m$ is far less than $\beta$ a full product is not required for the algorithm to work properly. +In fact the lower $m - 2$ digits will not affect the upper half of the product at all and do not need to be computed. + +The value of $\mu$ is a $m$-digit number and $q_0$ is a $m + 1$ digit number. Using a full multiplier $(m + 1)(m) = m^2 + m$ single precision +multiplications would be required. Using a multiplier that will only produce digits at and above the $m - 1$'th digit reduces the number +of single precision multiplications to ${m^2 + m} \over 2$ single precision multiplications. + +\subsection{Trimming the Residue} +After the quotient has been calculated it is used to reduce the input. As previously noted the algorithm is not exact and it can be off by a small +multiple of the modulus, that is $0 \le a - b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor < 3b$. If $b$ is $m$ digits than the +result of reduction equation is a value of at most $m + 1$ digits (\textit{provided $3 < \beta$}) implying that the upper $m - 1$ digits are +implicitly zero. + +The next optimization arises from this very fact. Instead of computing $b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ using a full +$O(m^2)$ multiplication algorithm only the lower $m+1$ digits of the product have to be computed. Similarly the value of $a$ can +be reduced modulo $\beta^{m+1}$ before the multiple of $b$ is subtracted which simplifes the subtraction as well. A multiplication that produces +only the lower $m+1$ digits requires ${m^2 + 3m - 2} \over 2$ single precision multiplications. + +With both optimizations in place the algorithm is the algorithm Barrett proposed. It requires $m^2 + 2m - 1$ single precision multiplications which +is considerably faster than the straightforward $3m^2$ method. + +\subsection{The Barrett Algorithm} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce}. \\ +\textbf{Input}. mp\_int $a$, mp\_int $b$ and $\mu = \lfloor \beta^{2m}/b \rfloor, m = \lceil lg_{\beta}(b) \rceil, (0 \le a < b^2, b > 1)$ \\ +\textbf{Output}. $a \mbox{ (mod }b\mbox{)}$ \\ +\hline \\ +Let $m$ represent the number of digits in $b$. \\ +1. Make a copy of $a$ and store it in $q$. (\textit{mp\_init\_copy}) \\ +2. $q \leftarrow \lfloor q / \beta^{m - 1} \rfloor$ (\textit{mp\_rshd}) \\ +\\ +Produce the quotient. \\ +3. $q \leftarrow q \cdot \mu$ (\textit{note: only produce digits at or above $m-1$}) \\ +4. $q \leftarrow \lfloor q / \beta^{m + 1} \rfloor$ \\ +\\ +Subtract the multiple of modulus from the input. \\ +5. $a \leftarrow a \mbox{ (mod }\beta^{m+1}\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +6. $q \leftarrow q \cdot b \mbox{ (mod }\beta^{m+1}\mbox{)}$ (\textit{s\_mp\_mul\_digs}) \\ +7. $a \leftarrow a - q$ (\textit{mp\_sub}) \\ +\\ +Add $\beta^{m+1}$ if a carry occured. \\ +8. If $a < 0$ then (\textit{mp\_cmp\_d}) \\ +\hspace{3mm}8.1 $q \leftarrow 1$ (\textit{mp\_set}) \\ +\hspace{3mm}8.2 $q \leftarrow q \cdot \beta^{m+1}$ (\textit{mp\_lshd}) \\ +\hspace{3mm}8.3 $a \leftarrow a + q$ \\ +\\ +Now subtract the modulus if the residue is too large (e.g. quotient too small). \\ +9. While $a \ge b$ do (\textit{mp\_cmp}) \\ +\hspace{3mm}9.1 $c \leftarrow a - b$ \\ +10. Clear $q$. \\ +11. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce} +\end{figure} + +\textbf{Algorithm mp\_reduce.} +This algorithm will reduce the input $a$ modulo $b$ in place using the Barrett algorithm. It is loosely based on algorithm 14.42 of HAC +\cite[pp. 602]{HAC} which is based on the paper from Paul Barrett \cite{BARRETT}. The algorithm has several restrictions and assumptions which must +be adhered to for the algorithm to work. + +First the modulus $b$ is assumed to be positive and greater than one. If the modulus were less than or equal to one than subtracting +a multiple of it would either accomplish nothing or actually enlarge the input. The input $a$ must be in the range $0 \le a < b^2$ in order +for the quotient to have enough precision. If $a$ is the product of two numbers that were already reduced modulo $b$, this will not be a problem. +Technically the algorithm will still work if $a \ge b^2$ but it will take much longer to finish. The value of $\mu$ is passed as an argument to this +algorithm and is assumed to be calculated and stored before the algorithm is used. + +Recall that the multiplication for the quotient on step 3 must only produce digits at or above the $m-1$'th position. An algorithm called +$s\_mp\_mul\_high\_digs$ which has not been presented is used to accomplish this task. The algorithm is based on $s\_mp\_mul\_digs$ except that +instead of stopping at a given level of precision it starts at a given level of precision. This optimal algorithm can only be used if the number +of digits in $b$ is very much smaller than $\beta$. + +While it is known that +$a \ge b \cdot \lfloor (q_0 \cdot \mu) / \beta^{m+1} \rfloor$ only the lower $m+1$ digits are being used to compute the residue, so an implied +``borrow'' from the higher digits might leave a negative result. After the multiple of the modulus has been subtracted from $a$ the residue must be +fixed up in case it is negative. The invariant $\beta^{m+1}$ must be added to the residue to make it positive again. + +The while loop at step 9 will subtract $b$ until the residue is less than $b$. If the algorithm is performed correctly this step is +performed at most twice, and on average once. However, if $a \ge b^2$ than it will iterate substantially more times than it should. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_reduce.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* reduces x mod m, assumes 0 < x < m**2, mu is +018 * precomputed via mp_reduce_setup. +019 * From HAC pp.604 Algorithm 14.42 +020 */ +021 int +022 mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +023 \{ +024 mp_int q; +025 int res, um = m->used; +026 +027 /* q = x */ +028 if ((res = mp_init_copy (&q, x)) != MP_OKAY) \{ +029 return res; +030 \} +031 +032 /* q1 = x / b**(k-1) */ +033 mp_rshd (&q, um - 1); +034 +035 /* according to HAC this optimization is ok */ +036 if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) \{ +037 if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) \{ +038 goto CLEANUP; +039 \} +040 \} else \{ +041 #ifdef BN_S_MP_MUL_HIGH_DIGS_C +042 if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) \{ +043 goto CLEANUP; +044 \} +045 #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) +046 if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) \{ +047 goto CLEANUP; +048 \} +049 #else +050 \{ +051 res = MP_VAL; +052 goto CLEANUP; +053 \} +054 #endif +055 \} +056 +057 /* q3 = q2 / b**(k+1) */ +058 mp_rshd (&q, um + 1); +059 +060 /* x = x mod b**(k+1), quick (no division) */ +061 if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) \{ +062 goto CLEANUP; +063 \} +064 +065 /* q = q * m mod b**(k+1), quick (no division) */ +066 if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) \{ +067 goto CLEANUP; +068 \} +069 +070 /* x = x - q */ +071 if ((res = mp_sub (x, &q, x)) != MP_OKAY) \{ +072 goto CLEANUP; +073 \} +074 +075 /* If x < 0, add b**(k+1) to it */ +076 if (mp_cmp_d (x, 0) == MP_LT) \{ +077 mp_set (&q, 1); +078 if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) +079 goto CLEANUP; +080 if ((res = mp_add (x, &q, x)) != MP_OKAY) +081 goto CLEANUP; +082 \} +083 +084 /* Back off if it's too big */ +085 while (mp_cmp (x, m) != MP_LT) \{ +086 if ((res = s_mp_sub (x, m, x)) != MP_OKAY) \{ +087 goto CLEANUP; +088 \} +089 \} +090 +091 CLEANUP: +092 mp_clear (&q); +093 +094 return res; +095 \} +096 #endif +\end{alltt} +\end{small} + +The first multiplication that determines the quotient can be performed by only producing the digits from $m - 1$ and up. This essentially halves +the number of single precision multiplications required. However, the optimization is only safe if $\beta$ is much larger than the number of digits +in the modulus. In the source code this is evaluated on lines 36 to 44 where algorithm s\_mp\_mul\_high\_digs is used when it is +safe to do so. + +\subsection{The Barrett Setup Algorithm} +In order to use algorithm mp\_reduce the value of $\mu$ must be calculated in advance. Ideally this value should be computed once and stored for +future use so that the Barrett algorithm can be used without delay. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_setup}. \\ +\textbf{Input}. mp\_int $a$ ($a > 1$) \\ +\textbf{Output}. $\mu \leftarrow \lfloor \beta^{2m}/a \rfloor$ \\ +\hline \\ +1. $\mu \leftarrow 2^{2 \cdot lg(\beta) \cdot m}$ (\textit{mp\_2expt}) \\ +2. $\mu \leftarrow \lfloor \mu / b \rfloor$ (\textit{mp\_div}) \\ +3. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_setup} +\end{figure} + +\textbf{Algorithm mp\_reduce\_setup.} +This algorithm computes the reciprocal $\mu$ required for Barrett reduction. First $\beta^{2m}$ is calculated as $2^{2 \cdot lg(\beta) \cdot m}$ which +is equivalent and much faster. The final value is computed by taking the integer quotient of $\lfloor \mu / b \rfloor$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_setup.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* pre-calculate the value required for Barrett reduction +018 * For a given modulus "b" it calulates the value required in "a" +019 */ +020 int mp_reduce_setup (mp_int * a, mp_int * b) +021 \{ +022 int res; +023 +024 if ((res = mp_2expt (a, b->used * 2 * DIGIT_BIT)) != MP_OKAY) \{ +025 return res; +026 \} +027 return mp_div (a, b, a, NULL); +028 \} +029 #endif +\end{alltt} +\end{small} + +This simple routine calculates the reciprocal $\mu$ required by Barrett reduction. Note the extended usage of algorithm mp\_div where the variable +which would received the remainder is passed as NULL. As will be discussed in~\ref{sec:division} the division routine allows both the quotient and the +remainder to be passed as NULL meaning to ignore the value. + +\section{The Montgomery Reduction} +Montgomery reduction\footnote{Thanks to Niels Ferguson for his insightful explanation of the algorithm.} \cite{MONT} is by far the most interesting +form of reduction in common use. It computes a modular residue which is not actually equal to the residue of the input yet instead equal to a +residue times a constant. However, as perplexing as this may sound the algorithm is relatively simple and very efficient. + +Throughout this entire section the variable $n$ will represent the modulus used to form the residue. As will be discussed shortly the value of +$n$ must be odd. The variable $x$ will represent the quantity of which the residue is sought. Similar to the Barrett algorithm the input +is restricted to $0 \le x < n^2$. To begin the description some simple number theory facts must be established. + +\textbf{Fact 1.} Adding $n$ to $x$ does not change the residue since in effect it adds one to the quotient $\lfloor x / n \rfloor$. Another way +to explain this is that $n$ is (\textit{or multiples of $n$ are}) congruent to zero modulo $n$. Adding zero will not change the value of the residue. + +\textbf{Fact 2.} If $x$ is even then performing a division by two in $\Z$ is congruent to $x \cdot 2^{-1} \mbox{ (mod }n\mbox{)}$. Actually +this is an application of the fact that if $x$ is evenly divisible by any $k \in \Z$ then division in $\Z$ will be congruent to +multiplication by $k^{-1}$ modulo $n$. + +From these two simple facts the following simple algorithm can be derived. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction}. \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $1$ to $k$ do \\ +\hspace{3mm}1.1 If $x$ is odd then \\ +\hspace{6mm}1.1.1 $x \leftarrow x + n$ \\ +\hspace{3mm}1.2 $x \leftarrow x/2$ \\ +2. Return $x$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction} +\end{figure} + +The algorithm reduces the input one bit at a time using the two congruencies stated previously. Inside the loop $n$, which is odd, is +added to $x$ if $x$ is odd. This forces $x$ to be even which allows the division by two in $\Z$ to be congruent to a modular division by two. Since +$x$ is assumed to be initially much larger than $n$ the addition of $n$ will contribute an insignificant magnitude to $x$. Let $r$ represent the +final result of the Montgomery algorithm. If $k > lg(n)$ and $0 \le x < n^2$ then the final result is limited to +$0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction is required to get the residue desired. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|l|} +\hline \textbf{Step number ($t$)} & \textbf{Result ($x$)} \\ +\hline $1$ & $x + n = 5812$, $x/2 = 2906$ \\ +\hline $2$ & $x/2 = 1453$ \\ +\hline $3$ & $x + n = 1710$, $x/2 = 855$ \\ +\hline $4$ & $x + n = 1112$, $x/2 = 556$ \\ +\hline $5$ & $x/2 = 278$ \\ +\hline $6$ & $x/2 = 139$ \\ +\hline $7$ & $x + n = 396$, $x/2 = 198$ \\ +\hline $8$ & $x/2 = 99$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example of Montgomery Reduction (I)} +\label{fig:MONT1} +\end{figure} + +Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 8$. The result of the algorithm $r = 99$ is +congruent to the value of $2^{-8} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^8$ modulo $257$ the correct residue +$r \equiv 158$ is produced. + +Let $k = \lfloor lg(n) \rfloor + 1$ represent the number of bits in $n$. The current algorithm requires $2k^2$ single precision shifts +and $k^2$ single precision additions. At this rate the algorithm is most certainly slower than Barrett reduction and not terribly useful. +Fortunately there exists an alternative representation of the algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction} (modified I). \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 If the $t$'th bit of $x$ is one then \\ +\hspace{6mm}1.1.1 $x \leftarrow x + 2^tn$ \\ +2. Return $x/2^k$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction (modified I)} +\end{figure} + +This algorithm is equivalent since $2^tn$ is a multiple of $n$ and the lower $k$ bits of $x$ are zero by step 2. The number of single +precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a small improvement. + +\begin{figure}[here] +\begin{small} +\begin{center} +\begin{tabular}{|c|l|r|} +\hline \textbf{Step number ($t$)} & \textbf{Result ($x$)} & \textbf{Result ($x$) in Binary} \\ +\hline -- & $5555$ & $1010110110011$ \\ +\hline $1$ & $x + 2^{0}n = 5812$ & $1011010110100$ \\ +\hline $2$ & $5812$ & $1011010110100$ \\ +\hline $3$ & $x + 2^{2}n = 6840$ & $1101010111000$ \\ +\hline $4$ & $x + 2^{3}n = 8896$ & $10001011000000$ \\ +\hline $5$ & $8896$ & $10001011000000$ \\ +\hline $6$ & $8896$ & $10001011000000$ \\ +\hline $7$ & $x + 2^{6}n = 25344$ & $110001100000000$ \\ +\hline $8$ & $25344$ & $110001100000000$ \\ +\hline -- & $x/2^k = 99$ & \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example of Montgomery Reduction (II)} +\label{fig:MONT2} +\end{figure} + +Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 8$. +With this algorithm a single shift right at the end is the only right shift required to reduce the input instead of $k$ right shifts inside the +loop. Note that for the iterations $t = 2, 5, 6$ and $8$ where the result $x$ is not changed. In those iterations the $t$'th bit of $x$ is +zero and the appropriate multiple of $n$ does not need to be added to force the $t$'th bit of the result to zero. + +\subsection{Digit Based Montgomery Reduction} +Instead of computing the reduction on a bit-by-bit basis it is actually much faster to compute it on digit-by-digit basis. Consider the +previous algorithm re-written to compute the Montgomery reduction in this new fashion. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Montgomery Reduction} (modified II). \\ +\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. for $t$ from $0$ to $k - 1$ do \\ +\hspace{3mm}1.1 $x \leftarrow x + \mu n \beta^t$ \\ +2. Return $x/\beta^k$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Montgomery Reduction (modified II)} +\end{figure} + +The value $\mu n \beta^t$ is a multiple of the modulus $n$ meaning that it will not change the residue. If the first digit of +the value $\mu n \beta^t$ equals the negative (modulo $\beta$) of the $t$'th digit of $x$ then the addition will result in a zero digit. This +problem breaks down to solving the following congruency. + +\begin{center} +\begin{tabular}{rcl} +$x_t + \mu n_0$ & $\equiv$ & $0 \mbox{ (mod }\beta\mbox{)}$ \\ +$\mu n_0$ & $\equiv$ & $-x_t \mbox{ (mod }\beta\mbox{)}$ \\ +$\mu$ & $\equiv$ & $-x_t/n_0 \mbox{ (mod }\beta\mbox{)}$ \\ +\end{tabular} +\end{center} + +In each iteration of the loop on step 1 a new value of $\mu$ must be calculated. The value of $-1/n_0 \mbox{ (mod }\beta\mbox{)}$ is used +extensively in this algorithm and should be precomputed. Let $\rho$ represent the negative of the modular inverse of $n_0$ modulo $\beta$. + +For example, let $\beta = 10$ represent the radix. Let $n = 17$ represent the modulus which implies $k = 2$ and $\rho \equiv 7$. Let $x = 33$ +represent the value to reduce. + +\newpage\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Step ($t$)} & \textbf{Value of $x$} & \textbf{Value of $\mu$} \\ +\hline -- & $33$ & --\\ +\hline $0$ & $33 + \mu n = 50$ & $1$ \\ +\hline $1$ & $50 + \mu n \beta = 900$ & $5$ \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Montgomery Reduction} +\end{figure} + +The final result $900$ is then divided by $\beta^k$ to produce the final result $9$. The first observation is that $9 \nequiv x \mbox{ (mod }n\mbox{)}$ +which implies the result is not the modular residue of $x$ modulo $n$. However, recall that the residue is actually multiplied by $\beta^{-k}$ in +the algorithm. To get the true residue the value must be multiplied by $\beta^k$. In this case $\beta^k \equiv 15 \mbox{ (mod }n\mbox{)}$ and +the correct residue is $9 \cdot 15 \equiv 16 \mbox{ (mod }n\mbox{)}$. + +\subsection{Baseline Montgomery Reduction} +The baseline Montgomery reduction algorithm will produce the residue for any size input. It is designed to be a catch-all algororithm for +Montgomery reductions. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_montgomery\_reduce}. \\ +\textbf{Input}. mp\_int $x$, mp\_int $n$ and a digit $\rho \equiv -1/n_0 \mbox{ (mod }n\mbox{)}$. \\ +\hspace{11.5mm}($0 \le x < n^2, n > 1, (n, \beta) = 1, \beta^k > n$) \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +1. $digs \leftarrow 2n.used + 1$ \\ +2. If $digs < MP\_ARRAY$ and $m.used < \delta$ then \\ +\hspace{3mm}2.1 Use algorithm fast\_mp\_montgomery\_reduce instead. \\ +\\ +Setup $x$ for the reduction. \\ +3. If $x.alloc < digs$ then grow $x$ to $digs$ digits. \\ +4. $x.used \leftarrow digs$ \\ +\\ +Eliminate the lower $k$ digits. \\ +5. For $ix$ from $0$ to $k - 1$ do \\ +\hspace{3mm}5.1 $\mu \leftarrow x_{ix} \cdot \rho \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}5.2 $u \leftarrow 0$ \\ +\hspace{3mm}5.3 For $iy$ from $0$ to $k - 1$ do \\ +\hspace{6mm}5.3.1 $\hat r \leftarrow \mu n_{iy} + x_{ix + iy} + u$ \\ +\hspace{6mm}5.3.2 $x_{ix + iy} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{6mm}5.3.3 $u \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +\hspace{3mm}5.4 While $u > 0$ do \\ +\hspace{6mm}5.4.1 $iy \leftarrow iy + 1$ \\ +\hspace{6mm}5.4.2 $x_{ix + iy} \leftarrow x_{ix + iy} + u$ \\ +\hspace{6mm}5.4.3 $u \leftarrow \lfloor x_{ix+iy} / \beta \rfloor$ \\ +\hspace{6mm}5.4.4 $x_{ix + iy} \leftarrow x_{ix+iy} \mbox{ (mod }\beta\mbox{)}$ \\ +\\ +Divide by $\beta^k$ and fix up as required. \\ +6. $x \leftarrow \lfloor x / \beta^k \rfloor$ \\ +7. If $x \ge n$ then \\ +\hspace{3mm}7.1 $x \leftarrow x - n$ \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_montgomery\_reduce} +\end{figure} + +\textbf{Algorithm mp\_montgomery\_reduce.} +This algorithm reduces the input $x$ modulo $n$ in place using the Montgomery reduction algorithm. The algorithm is loosely based +on algorithm 14.32 of \cite[pp.601]{HAC} except it merges the multiplication of $\mu n \beta^t$ with the addition in the inner loop. The +restrictions on this algorithm are fairly easy to adapt to. First $0 \le x < n^2$ bounds the input to numbers in the same range as +for the Barrett algorithm. Additionally if $n > 1$ and $n$ is odd there will exist a modular inverse $\rho$. $\rho$ must be calculated in +advance of this algorithm. Finally the variable $k$ is fixed and a pseudonym for $n.used$. + +Step 2 decides whether a faster Montgomery algorithm can be used. It is based on the Comba technique meaning that there are limits on +the size of the input. This algorithm is discussed in sub-section 6.3.3. + +Step 5 is the main reduction loop of the algorithm. The value of $\mu$ is calculated once per iteration in the outer loop. The inner loop +calculates $x + \mu n \beta^{ix}$ by multiplying $\mu n$ and adding the result to $x$ shifted by $ix$ digits. Both the addition and +multiplication are performed in the same loop to save time and memory. Step 5.4 will handle any additional carries that escape the inner loop. + +Using a quick inspection this algorithm requires $n$ single precision multiplications for the outer loop and $n^2$ single precision multiplications +in the inner loop. In total $n^2 + n$ single precision multiplications which compares favourably to Barrett at $n^2 + 2n - 1$ single precision +multiplications. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_montgomery\_reduce.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* computes xR**-1 == x (mod N) via Montgomery Reduction */ +018 int +019 mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +020 \{ +021 int ix, res, digs; +022 mp_digit mu; +023 +024 /* can the fast reduction [comba] method be used? +025 * +026 * Note that unlike in mul you're safely allowed *less* +027 * than the available columns [255 per default] since carries +028 * are fixed up in the inner loop. +029 */ +030 digs = n->used * 2 + 1; +031 if ((digs < MP_WARRAY) && +032 n->used < +033 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ +034 return fast_mp_montgomery_reduce (x, n, rho); +035 \} +036 +037 /* grow the input as required */ +038 if (x->alloc < digs) \{ +039 if ((res = mp_grow (x, digs)) != MP_OKAY) \{ +040 return res; +041 \} +042 \} +043 x->used = digs; +044 +045 for (ix = 0; ix < n->used; ix++) \{ +046 /* mu = ai * rho mod b +047 * +048 * The value of rho must be precalculated via +049 * montgomery_setup() such that +050 * it equals -1/n0 mod b this allows the +051 * following inner loop to reduce the +052 * input one digit at a time +053 */ +054 mu = (mp_digit) (((mp_word)x->dp[ix]) * ((mp_word)rho) & MP_MASK); +055 +056 /* a = a + mu * m * b**i */ +057 \{ +058 register int iy; +059 register mp_digit *tmpn, *tmpx, u; +060 register mp_word r; +061 +062 /* alias for digits of the modulus */ +063 tmpn = n->dp; +064 +065 /* alias for the digits of x [the input] */ +066 tmpx = x->dp + ix; +067 +068 /* set the carry to zero */ +069 u = 0; +070 +071 /* Multiply and add in place */ +072 for (iy = 0; iy < n->used; iy++) \{ +073 /* compute product and sum */ +074 r = ((mp_word)mu) * ((mp_word)*tmpn++) + +075 ((mp_word) u) + ((mp_word) * tmpx); +076 +077 /* get carry */ +078 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +079 +080 /* fix digit */ +081 *tmpx++ = (mp_digit)(r & ((mp_word) MP_MASK)); +082 \} +083 /* At this point the ix'th digit of x should be zero */ +084 +085 +086 /* propagate carries upwards as required*/ +087 while (u) \{ +088 *tmpx += u; +089 u = *tmpx >> DIGIT_BIT; +090 *tmpx++ &= MP_MASK; +091 \} +092 \} +093 \} +094 +095 /* at this point the n.used'th least +096 * significant digits of x are all zero +097 * which means we can shift x to the +098 * right by n.used digits and the +099 * residue is unchanged. +100 */ +101 +102 /* x = x/b**n.used */ +103 mp_clamp(x); +104 mp_rshd (x, n->used); +105 +106 /* if x >= n then x = x - n */ +107 if (mp_cmp_mag (x, n) != MP_LT) \{ +108 return s_mp_sub (x, n, x); +109 \} +110 +111 return MP_OKAY; +112 \} +113 #endif +\end{alltt} +\end{small} + +This is the baseline implementation of the Montgomery reduction algorithm. Lines 30 to 35 determine if the Comba based +routine can be used instead. Line 48 computes the value of $\mu$ for that particular iteration of the outer loop. + +The multiplication $\mu n \beta^{ix}$ is performed in one step in the inner loop. The alias $tmpx$ refers to the $ix$'th digit of $x$ and +the alias $tmpn$ refers to the modulus $n$. + +\subsection{Faster ``Comba'' Montgomery Reduction} + +The Montgomery reduction requires fewer single precision multiplications than a Barrett reduction, however it is much slower due to the serial +nature of the inner loop. The Barrett reduction algorithm requires two slightly modified multipliers which can be implemented with the Comba +technique. The Montgomery reduction algorithm cannot directly use the Comba technique to any significant advantage since the inner loop calculates +a $k \times 1$ product $k$ times. + +The biggest obstacle is that at the $ix$'th iteration of the outer loop the value of $x_{ix}$ is required to calculate $\mu$. This means the +carries from $0$ to $ix - 1$ must have been propagated upwards to form a valid $ix$'th digit. The solution as it turns out is very simple. +Perform a Comba like multiplier and inside the outer loop just after the inner loop fix up the $ix + 1$'th digit by forwarding the carry. + +With this change in place the Montgomery reduction algorithm can be performed with a Comba style multiplication loop which substantially increases +the speed of the algorithm. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{fast\_mp\_montgomery\_reduce}. \\ +\textbf{Input}. mp\_int $x$, mp\_int $n$ and a digit $\rho \equiv -1/n_0 \mbox{ (mod }n\mbox{)}$. \\ +\hspace{11.5mm}($0 \le x < n^2, n > 1, (n, \beta) = 1, \beta^k > n$) \\ +\textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ +\hline \\ +Place an array of \textbf{MP\_WARRAY} mp\_word variables called $\hat W$ on the stack. \\ +1. if $x.alloc < n.used + 1$ then grow $x$ to $n.used + 1$ digits. \\ +Copy the digits of $x$ into the array $\hat W$ \\ +2. For $ix$ from $0$ to $x.used - 1$ do \\ +\hspace{3mm}2.1 $\hat W_{ix} \leftarrow x_{ix}$ \\ +3. For $ix$ from $x.used$ to $2n.used - 1$ do \\ +\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ +Elimiate the lower $k$ digits. \\ +4. for $ix$ from $0$ to $n.used - 1$ do \\ +\hspace{3mm}4.1 $\mu \leftarrow \hat W_{ix} \cdot \rho \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}4.2 For $iy$ from $0$ to $n.used - 1$ do \\ +\hspace{6mm}4.2.1 $\hat W_{iy + ix} \leftarrow \hat W_{iy + ix} + \mu \cdot n_{iy}$ \\ +\hspace{3mm}4.3 $\hat W_{ix + 1} \leftarrow \hat W_{ix + 1} + \lfloor \hat W_{ix} / \beta \rfloor$ \\ +Propagate carries upwards. \\ +5. for $ix$ from $n.used$ to $2n.used + 1$ do \\ +\hspace{3mm}5.1 $\hat W_{ix + 1} \leftarrow \hat W_{ix + 1} + \lfloor \hat W_{ix} / \beta \rfloor$ \\ +Shift right and reduce modulo $\beta$ simultaneously. \\ +6. for $ix$ from $0$ to $n.used + 1$ do \\ +\hspace{3mm}6.1 $x_{ix} \leftarrow \hat W_{ix + n.used} \mbox{ (mod }\beta\mbox{)}$ \\ +Zero excess digits and fixup $x$. \\ +7. if $x.used > n.used + 1$ then do \\ +\hspace{3mm}7.1 for $ix$ from $n.used + 1$ to $x.used - 1$ do \\ +\hspace{6mm}7.1.1 $x_{ix} \leftarrow 0$ \\ +8. $x.used \leftarrow n.used + 1$ \\ +9. Clamp excessive digits of $x$. \\ +10. If $x \ge n$ then \\ +\hspace{3mm}10.1 $x \leftarrow x - n$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm fast\_mp\_montgomery\_reduce} +\end{figure} + +\textbf{Algorithm fast\_mp\_montgomery\_reduce.} +This algorithm will compute the Montgomery reduction of $x$ modulo $n$ using the Comba technique. It is on most computer platforms significantly +faster than algorithm mp\_montgomery\_reduce and algorithm mp\_reduce (\textit{Barrett reduction}). The algorithm has the same restrictions +on the input as the baseline reduction algorithm. An additional two restrictions are imposed on this algorithm. The number of digits $k$ in the +the modulus $n$ must not violate $MP\_WARRAY > 2k +1$ and $n < \delta$. When $\beta = 2^{28}$ this algorithm can be used to reduce modulo +a modulus of at most $3,556$ bits in length. + +As in the other Comba reduction algorithms there is a $\hat W$ array which stores the columns of the product. It is initially filled with the +contents of $x$ with the excess digits zeroed. The reduction loop is very similar the to the baseline loop at heart. The multiplication on step +4.1 can be single precision only since $ab \mbox{ (mod }\beta\mbox{)} \equiv (a \mbox{ mod }\beta)(b \mbox{ mod }\beta)$. Some multipliers such +as those on the ARM processors take a variable length time to complete depending on the number of bytes of result it must produce. By performing +a single precision multiplication instead half the amount of time is spent. + +Also note that digit $\hat W_{ix}$ must have the carry from the $ix - 1$'th digit propagated upwards in order for this to work. That is what step +4.3 will do. In effect over the $n.used$ iterations of the outer loop the $n.used$'th lower columns all have the their carries propagated forwards. Note +how the upper bits of those same words are not reduced modulo $\beta$. This is because those values will be discarded shortly and there is no +point. + +Step 5 will propagate the remainder of the carries upwards. On step 6 the columns are reduced modulo $\beta$ and shifted simultaneously as they are +stored in the destination $x$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_fast\_mp\_montgomery\_reduce.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* computes xR**-1 == x (mod N) via Montgomery Reduction +018 * +019 * This is an optimized implementation of montgomery_reduce +020 * which uses the comba method to quickly calculate the columns of the +021 * reduction. +022 * +023 * Based on Algorithm 14.32 on pp.601 of HAC. +024 */ +025 int +026 fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +027 \{ +028 int ix, res, olduse; +029 mp_word W[MP_WARRAY]; +030 +031 /* get old used count */ +032 olduse = x->used; +033 +034 /* grow a as required */ +035 if (x->alloc < n->used + 1) \{ +036 if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) \{ +037 return res; +038 \} +039 \} +040 +041 /* first we have to get the digits of the input into +042 * an array of double precision words W[...] +043 */ +044 \{ +045 register mp_word *_W; +046 register mp_digit *tmpx; +047 +048 /* alias for the W[] array */ +049 _W = W; +050 +051 /* alias for the digits of x*/ +052 tmpx = x->dp; +053 +054 /* copy the digits of a into W[0..a->used-1] */ +055 for (ix = 0; ix < x->used; ix++) \{ +056 *_W++ = *tmpx++; +057 \} +058 +059 /* zero the high words of W[a->used..m->used*2] */ +060 for (; ix < n->used * 2 + 1; ix++) \{ +061 *_W++ = 0; +062 \} +063 \} +064 +065 /* now we proceed to zero successive digits +066 * from the least significant upwards +067 */ +068 for (ix = 0; ix < n->used; ix++) \{ +069 /* mu = ai * m' mod b +070 * +071 * We avoid a double precision multiplication (which isn't required) +072 * by casting the value down to a mp_digit. Note this requires +073 * that W[ix-1] have the carry cleared (see after the inner loop) +074 */ +075 register mp_digit mu; +076 mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); +077 +078 /* a = a + mu * m * b**i +079 * +080 * This is computed in place and on the fly. The multiplication +081 * by b**i is handled by offseting which columns the results +082 * are added to. +083 * +084 * Note the comba method normally doesn't handle carries in the +085 * inner loop In this case we fix the carry from the previous +086 * column since the Montgomery reduction requires digits of the +087 * result (so far) [see above] to work. This is +088 * handled by fixing up one carry after the inner loop. The +089 * carry fixups are done in order so after these loops the +090 * first m->used words of W[] have the carries fixed +091 */ +092 \{ +093 register int iy; +094 register mp_digit *tmpn; +095 register mp_word *_W; +096 +097 /* alias for the digits of the modulus */ +098 tmpn = n->dp; +099 +100 /* Alias for the columns set by an offset of ix */ +101 _W = W + ix; +102 +103 /* inner loop */ +104 for (iy = 0; iy < n->used; iy++) \{ +105 *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); +106 \} +107 \} +108 +109 /* now fix carry for next digit, W[ix+1] */ +110 W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); +111 \} +112 +113 /* now we have to propagate the carries and +114 * shift the words downward [all those least +115 * significant digits we zeroed]. +116 */ +117 \{ +118 register mp_digit *tmpx; +119 register mp_word *_W, *_W1; +120 +121 /* nox fix rest of carries */ +122 +123 /* alias for current word */ +124 _W1 = W + ix; +125 +126 /* alias for next word, where the carry goes */ +127 _W = W + ++ix; +128 +129 for (; ix <= n->used * 2 + 1; ix++) \{ +130 *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); +131 \} +132 +133 /* copy out, A = A/b**n +134 * +135 * The result is A/b**n but instead of converting from an +136 * array of mp_word to mp_digit than calling mp_rshd +137 * we just copy them in the right order +138 */ +139 +140 /* alias for destination word */ +141 tmpx = x->dp; +142 +143 /* alias for shifted double precision result */ +144 _W = W + n->used; +145 +146 for (ix = 0; ix < n->used + 1; ix++) \{ +147 *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); +148 \} +149 +150 /* zero oldused digits, if the input a was larger than +151 * m->used+1 we'll have to clear the digits +152 */ +153 for (; ix < olduse; ix++) \{ +154 *tmpx++ = 0; +155 \} +156 \} +157 +158 /* set the max used and clamp */ +159 x->used = n->used + 1; +160 mp_clamp (x); +161 +162 /* if A >= m then A = A - m */ +163 if (mp_cmp_mag (x, n) != MP_LT) \{ +164 return s_mp_sub (x, n, x); +165 \} +166 return MP_OKAY; +167 \} +168 #endif +\end{alltt} +\end{small} + +The $\hat W$ array is first filled with digits of $x$ on line 48 then the rest of the digits are zeroed on line 55. Both loops share +the same alias variables to make the code easier to read. + +The value of $\mu$ is calculated in an interesting fashion. First the value $\hat W_{ix}$ is reduced modulo $\beta$ and cast to a mp\_digit. This +forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line 110 fixes the carry +for the next iteration of the loop by propagating the carry from $\hat W_{ix}$ to $\hat W_{ix+1}$. + +The for loop on line 109 propagates the rest of the carries upwards through the columns. The for loop on line 126 reduces the columns +modulo $\beta$ and shifts them $k$ places at the same time. The alias $\_ \hat W$ actually refers to the array $\hat W$ starting at the $n.used$'th +digit, that is $\_ \hat W_{t} = \hat W_{n.used + t}$. + +\subsection{Montgomery Setup} +To calculate the variable $\rho$ a relatively simple algorithm will be required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_montgomery\_setup}. \\ +\textbf{Input}. mp\_int $n$ ($n > 1$ and $(n, 2) = 1$) \\ +\textbf{Output}. $\rho \equiv -1/n_0 \mbox{ (mod }\beta\mbox{)}$ \\ +\hline \\ +1. $b \leftarrow n_0$ \\ +2. If $b$ is even return(\textit{MP\_VAL}) \\ +3. $x \leftarrow ((b + 2) \mbox{ AND } 4) << 1) + b$ \\ +4. for $k$ from 0 to $\lceil lg(lg(\beta)) \rceil - 2$ do \\ +\hspace{3mm}4.1 $x \leftarrow x \cdot (2 - bx)$ \\ +5. $\rho \leftarrow \beta - x \mbox{ (mod }\beta\mbox{)}$ \\ +6. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_montgomery\_setup} +\end{figure} + +\textbf{Algorithm mp\_montgomery\_setup.} +This algorithm will calculate the value of $\rho$ required within the Montgomery reduction algorithms. It uses a very interesting trick +to calculate $1/n_0$ when $\beta$ is a power of two. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_montgomery\_setup.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* setups the montgomery reduction stuff */ +018 int +019 mp_montgomery_setup (mp_int * n, mp_digit * rho) +020 \{ +021 mp_digit x, b; +022 +023 /* fast inversion mod 2**k +024 * +025 * Based on the fact that +026 * +027 * XA = 1 (mod 2**n) => (X(2-XA)) A = 1 (mod 2**2n) +028 * => 2*X*A - X*X*A*A = 1 +029 * => 2*(1) - (1) = 1 +030 */ +031 b = n->dp[0]; +032 +033 if ((b & 1) == 0) \{ +034 return MP_VAL; +035 \} +036 +037 x = (((b + 2) & 4) << 1) + b; /* here x*a==1 mod 2**4 */ +038 x *= 2 - b * x; /* here x*a==1 mod 2**8 */ +039 #if !defined(MP_8BIT) +040 x *= 2 - b * x; /* here x*a==1 mod 2**16 */ +041 #endif +042 #if defined(MP_64BIT) || !(defined(MP_8BIT) || defined(MP_16BIT)) +043 x *= 2 - b * x; /* here x*a==1 mod 2**32 */ +044 #endif +045 #ifdef MP_64BIT +046 x *= 2 - b * x; /* here x*a==1 mod 2**64 */ +047 #endif +048 +049 /* rho = -1/m mod b */ +050 *rho = (((mp_word)1 << ((mp_word) DIGIT_BIT)) - x) & MP_MASK; +051 +052 return MP_OKAY; +053 \} +054 #endif +\end{alltt} +\end{small} + +This source code computes the value of $\rho$ required to perform Montgomery reduction. It has been modified to avoid performing excess +multiplications when $\beta$ is not the default 28-bits. + +\section{The Diminished Radix Algorithm} +The Diminished Radix method of modular reduction \cite{DRMET} is a fairly clever technique which can be more efficient than either the Barrett +or Montgomery methods for certain forms of moduli. The technique is based on the following simple congruence. + +\begin{equation} +(x \mbox{ mod } n) + k \lfloor x / n \rfloor \equiv x \mbox{ (mod }(n - k)\mbox{)} +\end{equation} + +This observation was used in the MMB \cite{MMB} block cipher to create a diffusion primitive. It used the fact that if $n = 2^{31}$ and $k=1$ that +then a x86 multiplier could produce the 62-bit product and use the ``shrd'' instruction to perform a double-precision right shift. The proof +of the above equation is very simple. First write $x$ in the product form. + +\begin{equation} +x = qn + r +\end{equation} + +Now reduce both sides modulo $(n - k)$. + +\begin{equation} +x \equiv qk + r \mbox{ (mod }(n-k)\mbox{)} +\end{equation} + +The variable $n$ reduces modulo $n - k$ to $k$. By putting $q = \lfloor x/n \rfloor$ and $r = x \mbox{ mod } n$ +into the equation the original congruence is reproduced, thus concluding the proof. The following algorithm is based on this observation. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Diminished Radix Reduction}. \\ +\textbf{Input}. Integer $x$, $n$, $k$ \\ +\textbf{Output}. $x \mbox{ mod } (n - k)$ \\ +\hline \\ +1. $q \leftarrow \lfloor x / n \rfloor$ \\ +2. $q \leftarrow k \cdot q$ \\ +3. $x \leftarrow x \mbox{ (mod }n\mbox{)}$ \\ +4. $x \leftarrow x + q$ \\ +5. If $x \ge (n - k)$ then \\ +\hspace{3mm}5.1 $x \leftarrow x - (n - k)$ \\ +\hspace{3mm}5.2 Goto step 1. \\ +6. Return $x$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Diminished Radix Reduction} +\label{fig:DR} +\end{figure} + +This algorithm will reduce $x$ modulo $n - k$ and return the residue. If $0 \le x < (n - k)^2$ then the algorithm will loop almost always +once or twice and occasionally three times. For simplicity sake the value of $x$ is bounded by the following simple polynomial. + +\begin{equation} +0 \le x < n^2 + k^2 - 2nk +\end{equation} + +The true bound is $0 \le x < (n - k - 1)^2$ but this has quite a few more terms. The value of $q$ after step 1 is bounded by the following. + +\begin{equation} +q < n - 2k - k^2/n +\end{equation} + +Since $k^2$ is going to be considerably smaller than $n$ that term will always be zero. The value of $x$ after step 3 is bounded trivially as +$0 \le x < n$. By step four the sum $x + q$ is bounded by + +\begin{equation} +0 \le q + x < (k + 1)n - 2k^2 - 1 +\end{equation} + +With a second pass $q$ will be loosely bounded by $0 \le q < k^2$ after step 2 while $x$ will still be loosely bounded by $0 \le x < n$ after step 3. After the second pass it is highly unlike that the +sum in step 4 will exceed $n - k$. In practice fewer than three passes of the algorithm are required to reduce virtually every input in the +range $0 \le x < (n - k - 1)^2$. + +\begin{figure} +\begin{small} +\begin{center} +\begin{tabular}{|l|} +\hline +$x = 123456789, n = 256, k = 3$ \\ +\hline $q \leftarrow \lfloor x/n \rfloor = 482253$ \\ +$q \leftarrow q*k = 1446759$ \\ +$x \leftarrow x \mbox{ mod } n = 21$ \\ +$x \leftarrow x + q = 1446780$ \\ +$x \leftarrow x - (n - k) = 1446527$ \\ +\hline +$q \leftarrow \lfloor x/n \rfloor = 5650$ \\ +$q \leftarrow q*k = 16950$ \\ +$x \leftarrow x \mbox{ mod } n = 127$ \\ +$x \leftarrow x + q = 17077$ \\ +$x \leftarrow x - (n - k) = 16824$ \\ +\hline +$q \leftarrow \lfloor x/n \rfloor = 65$ \\ +$q \leftarrow q*k = 195$ \\ +$x \leftarrow x \mbox{ mod } n = 184$ \\ +$x \leftarrow x + q = 379$ \\ +$x \leftarrow x - (n - k) = 126$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Example Diminished Radix Reduction} +\label{fig:EXDR} +\end{figure} + +Figure~\ref{fig:EXDR} demonstrates the reduction of $x = 123456789$ modulo $n - k = 253$ when $n = 256$ and $k = 3$. Note that even while $x$ +is considerably larger than $(n - k - 1)^2 = 63504$ the algorithm still converges on the modular residue exceedingly fast. In this case only +three passes were required to find the residue $x \equiv 126$. + + +\subsection{Choice of Moduli} +On the surface this algorithm looks like a very expensive algorithm. It requires a couple of subtractions followed by multiplication and other +modular reductions. The usefulness of this algorithm becomes exceedingly clear when an appropriate modulus is chosen. + +Division in general is a very expensive operation to perform. The one exception is when the division is by a power of the radix of representation used. +Division by ten for example is simple for pencil and paper mathematics since it amounts to shifting the decimal place to the right. Similarly division +by two (\textit{or powers of two}) is very simple for binary computers to perform. It would therefore seem logical to choose $n$ of the form $2^p$ +which would imply that $\lfloor x / n \rfloor$ is a simple shift of $x$ right $p$ bits. + +However, there is one operation related to division of power of twos that is even faster than this. If $n = \beta^p$ then the division may be +performed by moving whole digits to the right $p$ places. In practice division by $\beta^p$ is much faster than division by $2^p$ for any $p$. +Also with the choice of $n = \beta^p$ reducing $x$ modulo $n$ merely requires zeroing the digits above the $p-1$'th digit of $x$. + +Throughout the next section the term ``restricted modulus'' will refer to a modulus of the form $\beta^p - k$ whereas the term ``unrestricted +modulus'' will refer to a modulus of the form $2^p - k$. The word ``restricted'' in this case refers to the fact that it is based on the +$2^p$ logic except $p$ must be a multiple of $lg(\beta)$. + +\subsection{Choice of $k$} +Now that division and reduction (\textit{step 1 and 3 of figure~\ref{fig:DR}}) have been optimized to simple digit operations the multiplication by $k$ +in step 2 is the most expensive operation. Fortunately the choice of $k$ is not terribly limited. For all intents and purposes it might +as well be a single digit. The smaller the value of $k$ is the faster the algorithm will be. + +\subsection{Restricted Diminished Radix Reduction} +The restricted Diminished Radix algorithm can quickly reduce an input modulo a modulus of the form $n = \beta^p - k$. This algorithm can reduce +an input $x$ within the range $0 \le x < n^2$ using only a couple passes of the algorithm demonstrated in figure~\ref{fig:DR}. The implementation +of this algorithm has been optimized to avoid additional overhead associated with a division by $\beta^p$, the multiplication by $k$ or the addition +of $x$ and $q$. The resulting algorithm is very efficient and can lead to substantial improvements over Barrett and Montgomery reduction when modular +exponentiations are performed. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_reduce}. \\ +\textbf{Input}. mp\_int $x$, $n$ and a mp\_digit $k = \beta - n_0$ \\ +\hspace{11.5mm}($0 \le x < n^2$, $n > 1$, $0 < k < \beta$) \\ +\textbf{Output}. $x \mbox{ mod } n$ \\ +\hline \\ +1. $m \leftarrow n.used$ \\ +2. If $x.alloc < 2m$ then grow $x$ to $2m$ digits. \\ +3. $\mu \leftarrow 0$ \\ +4. for $i$ from $0$ to $m - 1$ do \\ +\hspace{3mm}4.1 $\hat r \leftarrow k \cdot x_{m+i} + x_{i} + \mu$ \\ +\hspace{3mm}4.2 $x_{i} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}4.3 $\mu \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +5. $x_{m} \leftarrow \mu$ \\ +6. for $i$ from $m + 1$ to $x.used - 1$ do \\ +\hspace{3mm}6.1 $x_{i} \leftarrow 0$ \\ +7. Clamp excess digits of $x$. \\ +8. If $x \ge n$ then \\ +\hspace{3mm}8.1 $x \leftarrow x - n$ \\ +\hspace{3mm}8.2 Goto step 3. \\ +9. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_reduce} +\end{figure} + +\textbf{Algorithm mp\_dr\_reduce.} +This algorithm will perform the Dimished Radix reduction of $x$ modulo $n$. It has similar restrictions to that of the Barrett reduction +with the addition that $n$ must be of the form $n = \beta^m - k$ where $0 < k <\beta$. + +This algorithm essentially implements the pseudo-code in figure~\ref{fig:DR} except with a slight optimization. The division by $\beta^m$, multiplication by $k$ +and addition of $x \mbox{ mod }\beta^m$ are all performed simultaneously inside the loop on step 4. The division by $\beta^m$ is emulated by accessing +the term at the $m+i$'th position which is subsequently multiplied by $k$ and added to the term at the $i$'th position. After the loop the $m$'th +digit is set to the carry and the upper digits are zeroed. Steps 5 and 6 emulate the reduction modulo $\beta^m$ that should have happend to +$x$ before the addition of the multiple of the upper half. + +At step 8 if $x$ is still larger than $n$ another pass of the algorithm is required. First $n$ is subtracted from $x$ and then the algorithm resumes +at step 3. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_reduce.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* reduce "x" in place modulo "n" using the Diminished Radix algorithm. +018 * +019 * Based on algorithm from the paper +020 * +021 * "Generating Efficient Primes for Discrete Log Cryptosystems" +022 * Chae Hoon Lim, Pil Joong Lee, +023 * POSTECH Information Research Laboratories +024 * +025 * The modulus must be of a special format [see manual] +026 * +027 * Has been modified to use algorithm 7.10 from the LTM book instead +028 * +029 * Input x must be in the range 0 <= x <= (n-1)**2 +030 */ +031 int +032 mp_dr_reduce (mp_int * x, mp_int * n, mp_digit k) +033 \{ +034 int err, i, m; +035 mp_word r; +036 mp_digit mu, *tmpx1, *tmpx2; +037 +038 /* m = digits in modulus */ +039 m = n->used; +040 +041 /* ensure that "x" has at least 2m digits */ +042 if (x->alloc < m + m) \{ +043 if ((err = mp_grow (x, m + m)) != MP_OKAY) \{ +044 return err; +045 \} +046 \} +047 +048 /* top of loop, this is where the code resumes if +049 * another reduction pass is required. +050 */ +051 top: +052 /* aliases for digits */ +053 /* alias for lower half of x */ +054 tmpx1 = x->dp; +055 +056 /* alias for upper half of x, or x/B**m */ +057 tmpx2 = x->dp + m; +058 +059 /* set carry to zero */ +060 mu = 0; +061 +062 /* compute (x mod B**m) + k * [x/B**m] inline and inplace */ +063 for (i = 0; i < m; i++) \{ +064 r = ((mp_word)*tmpx2++) * ((mp_word)k) + *tmpx1 + mu; +065 *tmpx1++ = (mp_digit)(r & MP_MASK); +066 mu = (mp_digit)(r >> ((mp_word)DIGIT_BIT)); +067 \} +068 +069 /* set final carry */ +070 *tmpx1++ = mu; +071 +072 /* zero words above m */ +073 for (i = m + 1; i < x->used; i++) \{ +074 *tmpx1++ = 0; +075 \} +076 +077 /* clamp, sub and return */ +078 mp_clamp (x); +079 +080 /* if x >= n then subtract and reduce again +081 * Each successive "recursion" makes the input smaller and smaller. +082 */ +083 if (mp_cmp_mag (x, n) != MP_LT) \{ +084 s_mp_sub(x, n, x); +085 goto top; +086 \} +087 return MP_OKAY; +088 \} +089 #endif +\end{alltt} +\end{small} + +The first step is to grow $x$ as required to $2m$ digits since the reduction is performed in place on $x$. The label on line 51 is where +the algorithm will resume if further reduction passes are required. In theory it could be placed at the top of the function however, the size of +the modulus and question of whether $x$ is large enough are invariant after the first pass meaning that it would be a waste of time. + +The aliases $tmpx1$ and $tmpx2$ refer to the digits of $x$ where the latter is offset by $m$ digits. By reading digits from $x$ offset by $m$ digits +a division by $\beta^m$ can be simulated virtually for free. The loop on line 63 performs the bulk of the work (\textit{corresponds to step 4 of algorithm 7.11}) +in this algorithm. + +By line 70 the pointer $tmpx1$ points to the $m$'th digit of $x$ which is where the final carry will be placed. Similarly by line 73 the +same pointer will point to the $m+1$'th digit where the zeroes will be placed. + +Since the algorithm is only valid if both $x$ and $n$ are greater than zero an unsigned comparison suffices to determine if another pass is required. +With the same logic at line 84 the value of $x$ is known to be greater than or equal to $n$ meaning that an unsigned subtraction can be used +as well. Since the destination of the subtraction is the larger of the inputs the call to algorithm s\_mp\_sub cannot fail and the return code +does not need to be checked. + +\subsubsection{Setup} +To setup the restricted Diminished Radix algorithm the value $k = \beta - n_0$ is required. This algorithm is not really complicated but provided for +completeness. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_setup}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $k = \beta - n_0$ \\ +\hline \\ +1. $k \leftarrow \beta - n_0$ \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_setup} +\end{figure} + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_setup.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* determines the setup value */ +018 void mp_dr_setup(mp_int *a, mp_digit *d) +019 \{ +020 /* the casts are required if DIGIT_BIT is one less than +021 * the number of bits in a mp_digit [e.g. DIGIT_BIT==31] +022 */ +023 *d = (mp_digit)((((mp_word)1) << ((mp_word)DIGIT_BIT)) - +024 ((mp_word)a->dp[0])); +025 \} +026 +027 #endif +\end{alltt} +\end{small} + +\subsubsection{Modulus Detection} +Another algorithm which will be useful is the ability to detect a restricted Diminished Radix modulus. An integer is said to be +of restricted Diminished Radix form if all of the digits are equal to $\beta - 1$ except the trailing digit which may be any value. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_dr\_is\_modulus}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $1$ if $n$ is in D.R form, $0$ otherwise \\ +\hline +1. If $n.used < 2$ then return($0$). \\ +2. for $ix$ from $1$ to $n.used - 1$ do \\ +\hspace{3mm}2.1 If $n_{ix} \ne \beta - 1$ return($0$). \\ +3. Return($1$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_dr\_is\_modulus} +\end{figure} + +\textbf{Algorithm mp\_dr\_is\_modulus.} +This algorithm determines if a value is in Diminished Radix form. Step 1 rejects obvious cases where fewer than two digits are +in the mp\_int. Step 2 tests all but the first digit to see if they are equal to $\beta - 1$. If the algorithm manages to get to +step 3 then $n$ must be of Diminished Radix form. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_is\_modulus.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* determines if a number is a valid DR modulus */ +018 int mp_dr_is_modulus(mp_int *a) +019 \{ +020 int ix; +021 +022 /* must be at least two digits */ +023 if (a->used < 2) \{ +024 return 0; +025 \} +026 +027 /* must be of the form b**k - a [a <= b] so all +028 * but the first digit must be equal to -1 (mod b). +029 */ +030 for (ix = 1; ix < a->used; ix++) \{ +031 if (a->dp[ix] != MP_MASK) \{ +032 return 0; +033 \} +034 \} +035 return 1; +036 \} +037 +038 #endif +\end{alltt} +\end{small} + +\subsection{Unrestricted Diminished Radix Reduction} +The unrestricted Diminished Radix algorithm allows modular reductions to be performed when the modulus is of the form $2^p - k$. This algorithm +is a straightforward adaptation of algorithm~\ref{fig:DR}. + +In general the restricted Diminished Radix reduction algorithm is much faster since it has considerably lower overhead. However, this new +algorithm is much faster than either Montgomery or Barrett reduction when the moduli are of the appropriate form. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_2k}. \\ +\textbf{Input}. mp\_int $a$ and $n$. mp\_digit $k$ \\ +\hspace{11.5mm}($a \ge 0$, $n > 1$, $0 < k < \beta$, $n + k$ is a power of two) \\ +\textbf{Output}. $a \mbox{ (mod }n\mbox{)}$ \\ +\hline +1. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +2. While $a \ge n$ do \\ +\hspace{3mm}2.1 $q \leftarrow \lfloor a / 2^p \rfloor$ (\textit{mp\_div\_2d}) \\ +\hspace{3mm}2.2 $a \leftarrow a \mbox{ (mod }2^p\mbox{)}$ (\textit{mp\_mod\_2d}) \\ +\hspace{3mm}2.3 $q \leftarrow q \cdot k$ (\textit{mp\_mul\_d}) \\ +\hspace{3mm}2.4 $a \leftarrow a - q$ (\textit{s\_mp\_sub}) \\ +\hspace{3mm}2.5 If $a \ge n$ then do \\ +\hspace{6mm}2.5.1 $a \leftarrow a - n$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_2k} +\end{figure} + +\textbf{Algorithm mp\_reduce\_2k.} +This algorithm quickly reduces an input $a$ modulo an unrestricted Diminished Radix modulus $n$. Division by $2^p$ is emulated with a right +shift which makes the algorithm fairly inexpensive to use. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_2k.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* reduces a modulo n where n is of the form 2**p - d */ +018 int +019 mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +020 \{ +021 mp_int q; +022 int p, res; +023 +024 if ((res = mp_init(&q)) != MP_OKAY) \{ +025 return res; +026 \} +027 +028 p = mp_count_bits(n); +029 top: +030 /* q = a/2**p, a = a mod 2**p */ +031 if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) \{ +032 goto ERR; +033 \} +034 +035 if (d != 1) \{ +036 /* q = q * d */ +037 if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) \{ +038 goto ERR; +039 \} +040 \} +041 +042 /* a = a + q */ +043 if ((res = s_mp_add(a, &q, a)) != MP_OKAY) \{ +044 goto ERR; +045 \} +046 +047 if (mp_cmp_mag(a, n) != MP_LT) \{ +048 s_mp_sub(a, n, a); +049 goto top; +050 \} +051 +052 ERR: +053 mp_clear(&q); +054 return res; +055 \} +056 +057 #endif +\end{alltt} +\end{small} + +The algorithm mp\_count\_bits calculates the number of bits in an mp\_int which is used to find the initial value of $p$. The call to mp\_div\_2d +on line 31 calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size +is kept fairly small. The multiplication by $k$ is only performed if $k > 1$. This allows reductions modulo $2^p - 1$ to be performed without +any multiplications. + +The unsigned s\_mp\_add, mp\_cmp\_mag and s\_mp\_sub are used in place of their full sign counterparts since the inputs are only valid if they are +positive. By using the unsigned versions the overhead is kept to a minimum. + +\subsubsection{Unrestricted Setup} +To setup this reduction algorithm the value of $k = 2^p - n$ is required. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_2k\_setup}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $k = 2^p - n$ \\ +\hline +1. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +2. $x \leftarrow 2^p$ (\textit{mp\_2expt}) \\ +3. $x \leftarrow x - n$ (\textit{mp\_sub}) \\ +4. $k \leftarrow x_0$ \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_2k\_setup} +\end{figure} + +\textbf{Algorithm mp\_reduce\_2k\_setup.} +This algorithm computes the value of $k$ required for the algorithm mp\_reduce\_2k. By making a temporary variable $x$ equal to $2^p$ a subtraction +is sufficient to solve for $k$. Alternatively if $n$ has more than one digit the value of $k$ is simply $\beta - n_0$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_2k\_setup.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* determines the setup value */ +018 int +019 mp_reduce_2k_setup(mp_int *a, mp_digit *d) +020 \{ +021 int res, p; +022 mp_int tmp; +023 +024 if ((res = mp_init(&tmp)) != MP_OKAY) \{ +025 return res; +026 \} +027 +028 p = mp_count_bits(a); +029 if ((res = mp_2expt(&tmp, p)) != MP_OKAY) \{ +030 mp_clear(&tmp); +031 return res; +032 \} +033 +034 if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) \{ +035 mp_clear(&tmp); +036 return res; +037 \} +038 +039 *d = tmp.dp[0]; +040 mp_clear(&tmp); +041 return MP_OKAY; +042 \} +043 #endif +\end{alltt} +\end{small} + +\subsubsection{Unrestricted Detection} +An integer $n$ is a valid unrestricted Diminished Radix modulus if either of the following are true. + +\begin{enumerate} +\item The number has only one digit. +\item The number has more than one digit and every bit from the $\beta$'th to the most significant is one. +\end{enumerate} + +If either condition is true than there is a power of two $2^p$ such that $0 < 2^p - n < \beta$. If the input is only +one digit than it will always be of the correct form. Otherwise all of the bits above the first digit must be one. This arises from the fact +that there will be value of $k$ that when added to the modulus causes a carry in the first digit which propagates all the way to the most +significant bit. The resulting sum will be a power of two. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_reduce\_is\_2k}. \\ +\textbf{Input}. mp\_int $n$ \\ +\textbf{Output}. $1$ if of proper form, $0$ otherwise \\ +\hline +1. If $n.used = 0$ then return($0$). \\ +2. If $n.used = 1$ then return($1$). \\ +3. $p \leftarrow \lceil lg(n) \rceil$ (\textit{mp\_count\_bits}) \\ +4. for $x$ from $lg(\beta)$ to $p$ do \\ +\hspace{3mm}4.1 If the ($x \mbox{ mod }lg(\beta)$)'th bit of the $\lfloor x / lg(\beta) \rfloor$ of $n$ is zero then return($0$). \\ +5. Return($1$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_reduce\_is\_2k} +\end{figure} + +\textbf{Algorithm mp\_reduce\_is\_2k.} +This algorithm quickly determines if a modulus is of the form required for algorithm mp\_reduce\_2k to function properly. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_is\_2k.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* determines if mp_reduce_2k can be used */ +018 int mp_reduce_is_2k(mp_int *a) +019 \{ +020 int ix, iy, iw; +021 mp_digit iz; +022 +023 if (a->used == 0) \{ +024 return 0; +025 \} else if (a->used == 1) \{ +026 return 1; +027 \} else if (a->used > 1) \{ +028 iy = mp_count_bits(a); +029 iz = 1; +030 iw = 1; +031 +032 /* Test every bit from the second digit up, must be 1 */ +033 for (ix = DIGIT_BIT; ix < iy; ix++) \{ +034 if ((a->dp[iw] & iz) == 0) \{ +035 return 0; +036 \} +037 iz <<= 1; +038 if (iz > (mp_digit)MP_MASK) \{ +039 ++iw; +040 iz = 1; +041 \} +042 \} +043 \} +044 return 1; +045 \} +046 +047 #endif +\end{alltt} +\end{small} + + + +\section{Algorithm Comparison} +So far three very different algorithms for modular reduction have been discussed. Each of the algorithms have their own strengths and weaknesses +that makes having such a selection very useful. The following table sumarizes the three algorithms along with comparisons of work factors. Since +all three algorithms have the restriction that $0 \le x < n^2$ and $n > 1$ those limitations are not included in the table. + +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Method} & \textbf{Work Required} & \textbf{Limitations} & \textbf{$m = 8$} & \textbf{$m = 32$} & \textbf{$m = 64$} \\ +\hline Barrett & $m^2 + 2m - 1$ & None & $79$ & $1087$ & $4223$ \\ +\hline Montgomery & $m^2 + m$ & $n$ must be odd & $72$ & $1056$ & $4160$ \\ +\hline D.R. & $2m$ & $n = \beta^m - k$ & $16$ & $64$ & $128$ \\ +\hline +\end{tabular} +\end{small} +\end{center} + +In theory Montgomery and Barrett reductions would require roughly the same amount of time to complete. However, in practice since Montgomery +reduction can be written as a single function with the Comba technique it is much faster. Barrett reduction suffers from the overhead of +calling the half precision multipliers, addition and division by $\beta$ algorithms. + +For almost every cryptographic algorithm Montgomery reduction is the algorithm of choice. The one set of algorithms where Diminished Radix reduction truly +shines are based on the discrete logarithm problem such as Diffie-Hellman \cite{DH} and ElGamal \cite{ELGAMAL}. In these algorithms +primes of the form $\beta^m - k$ can be found and shared amongst users. These primes will allow the Diminished Radix algorithm to be used in +modular exponentiation to greatly speed up the operation. + + + +\section*{Exercises} +\begin{tabular}{cl} +$\left [ 3 \right ]$ & Prove that the ``trick'' in algorithm mp\_montgomery\_setup actually \\ + & calculates the correct value of $\rho$. \\ + & \\ +$\left [ 2 \right ]$ & Devise an algorithm to reduce modulo $n + k$ for small $k$ quickly. \\ + & \\ +$\left [ 4 \right ]$ & Prove that the pseudo-code algorithm ``Diminished Radix Reduction'' \\ + & (\textit{figure~\ref{fig:DR}}) terminates. Also prove the probability that it will \\ + & terminate within $1 \le k \le 10$ iterations. \\ + & \\ +\end{tabular} + + +\chapter{Exponentiation} +Exponentiation is the operation of raising one variable to the power of another, for example, $a^b$. A variant of exponentiation, computed +in a finite field or ring, is called modular exponentiation. This latter style of operation is typically used in public key +cryptosystems such as RSA and Diffie-Hellman. The ability to quickly compute modular exponentiations is of great benefit to any +such cryptosystem and many methods have been sought to speed it up. + +\section{Exponentiation Basics} +A trivial algorithm would simply multiply $a$ against itself $b - 1$ times to compute the exponentiation desired. However, as $b$ grows in size +the number of multiplications becomes prohibitive. Imagine what would happen if $b$ $\approx$ $2^{1024}$ as is the case when computing an RSA signature +with a $1024$-bit key. Such a calculation could never be completed as it would take simply far too long. + +Fortunately there is a very simple algorithm based on the laws of exponents. Recall that $lg_a(a^b) = b$ and that $lg_a(a^ba^c) = b + c$ which +are two trivial relationships between the base and the exponent. Let $b_i$ represent the $i$'th bit of $b$ starting from the least +significant bit. If $b$ is a $k$-bit integer than the following equation is true. + +\begin{equation} +a^b = \prod_{i=0}^{k-1} a^{2^i \cdot b_i} +\end{equation} + +By taking the base $a$ logarithm of both sides of the equation the following equation is the result. + +\begin{equation} +b = \sum_{i=0}^{k-1}2^i \cdot b_i +\end{equation} + +The term $a^{2^i}$ can be found from the $i - 1$'th term by squaring the term since $\left ( a^{2^i} \right )^2$ is equal to +$a^{2^{i+1}}$. This observation forms the basis of essentially all fast exponentiation algorithms. It requires $k$ squarings and on average +$k \over 2$ multiplications to compute the result. This is indeed quite an improvement over simply multiplying by $a$ a total of $b-1$ times. + +While this current method is a considerable speed up there are further improvements to be made. For example, the $a^{2^i}$ term does not need to +be computed in an auxilary variable. Consider the following equivalent algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Left to Right Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$ and $k$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $k - 1$ to $0$ do \\ +\hspace{3mm}2.1 $c \leftarrow c^2$ \\ +\hspace{3mm}2.2 $c \leftarrow c \cdot a^{b_i}$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Left to Right Exponentiation} +\label{fig:LTOR} +\end{figure} + +This algorithm starts from the most significant bit and works towards the least significant bit. When the $i$'th bit of $b$ is set $a$ is +multiplied against the current product. In each iteration the product is squared which doubles the exponent of the individual terms of the +product. + +For example, let $b = 101100_2 \equiv 44_{10}$. The following chart demonstrates the actions of the algorithm. + +\newpage\begin{figure} +\begin{center} +\begin{tabular}{|c|c|} +\hline \textbf{Value of $i$} & \textbf{Value of $c$} \\ +\hline - & $1$ \\ +\hline $5$ & $a$ \\ +\hline $4$ & $a^2$ \\ +\hline $3$ & $a^4 \cdot a$ \\ +\hline $2$ & $a^8 \cdot a^2 \cdot a$ \\ +\hline $1$ & $a^{16} \cdot a^4 \cdot a^2$ \\ +\hline $0$ & $a^{32} \cdot a^8 \cdot a^4$ \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Left to Right Exponentiation} +\end{figure} + +When the product $a^{32} \cdot a^8 \cdot a^4$ is simplified it is equal $a^{44}$ which is the desired exponentiation. This particular algorithm is +called ``Left to Right'' because it reads the exponent in that order. All of the exponentiation algorithms that will be presented are of this nature. + +\subsection{Single Digit Exponentiation} +The first algorithm in the series of exponentiation algorithms will be an unbounded algorithm where the exponent is a single digit. It is intended +to be used when a small power of an input is required (\textit{e.g. $a^5$}). It is faster than simply multiplying $b - 1$ times for all values of +$b$ that are greater than three. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_expt\_d}. \\ +\textbf{Input}. mp\_int $a$ and mp\_digit $b$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $g \leftarrow a$ (\textit{mp\_init\_copy}) \\ +2. $c \leftarrow 1$ (\textit{mp\_set}) \\ +3. for $x$ from 1 to $lg(\beta)$ do \\ +\hspace{3mm}3.1 $c \leftarrow c^2$ (\textit{mp\_sqr}) \\ +\hspace{3mm}3.2 If $b$ AND $2^{lg(\beta) - 1} \ne 0$ then \\ +\hspace{6mm}3.2.1 $c \leftarrow c \cdot g$ (\textit{mp\_mul}) \\ +\hspace{3mm}3.3 $b \leftarrow b << 1$ \\ +4. Clear $g$. \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_expt\_d} +\end{figure} + +\textbf{Algorithm mp\_expt\_d.} +This algorithm computes the value of $a$ raised to the power of a single digit $b$. It uses the left to right exponentiation algorithm to +quickly compute the exponentiation. It is loosely based on algorithm 14.79 of HAC \cite[pp. 615]{HAC} with the difference that the +exponent is a fixed width. + +A copy of $a$ is made first to allow destination variable $c$ be the same as the source variable $a$. The result is set to the initial value of +$1$ in the subsequent step. + +Inside the loop the exponent is read from the most significant bit first down to the least significant bit. First $c$ is invariably squared +on step 3.1. In the following step if the most significant bit of $b$ is one the copy of $a$ is multiplied against $c$. The value +of $b$ is shifted left one bit to make the next bit down from the most signficant bit the new most significant bit. In effect each +iteration of the loop moves the bits of the exponent $b$ upwards to the most significant location. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_expt\_d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* calculate c = a**b using a square-multiply algorithm */ +018 int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) +019 \{ +020 int res, x; +021 mp_int g; +022 +023 if ((res = mp_init_copy (&g, a)) != MP_OKAY) \{ +024 return res; +025 \} +026 +027 /* set initial result */ +028 mp_set (c, 1); +029 +030 for (x = 0; x < (int) DIGIT_BIT; x++) \{ +031 /* square */ +032 if ((res = mp_sqr (c, c)) != MP_OKAY) \{ +033 mp_clear (&g); +034 return res; +035 \} +036 +037 /* if the bit is set multiply */ +038 if ((b & (mp_digit) (((mp_digit)1) << (DIGIT_BIT - 1))) != 0) \{ +039 if ((res = mp_mul (c, &g, c)) != MP_OKAY) \{ +040 mp_clear (&g); +041 return res; +042 \} +043 \} +044 +045 /* shift to next bit */ +046 b <<= 1; +047 \} +048 +049 mp_clear (&g); +050 return MP_OKAY; +051 \} +052 #endif +\end{alltt} +\end{small} + +Line 28 sets the initial value of the result to $1$. Next the loop on line 30 steps through each bit of the exponent starting from +the most significant down towards the least significant. The invariant squaring operation placed on line 32 is performed first. After +the squaring the result $c$ is multiplied by the base $g$ if and only if the most significant bit of the exponent is set. The shift on line +46 moves all of the bits of the exponent upwards towards the most significant location. + +\section{$k$-ary Exponentiation} +When calculating an exponentiation the most time consuming bottleneck is the multiplications which are in general a small factor +slower than squaring. Recall from the previous algorithm that $b_{i}$ refers to the $i$'th bit of the exponent $b$. Suppose instead it referred to +the $i$'th $k$-bit digit of the exponent of $b$. For $k = 1$ the definitions are synonymous and for $k > 1$ algorithm~\ref{fig:KARY} +computes the same exponentiation. A group of $k$ bits from the exponent is called a \textit{window}. That is it is a small window on only a +portion of the entire exponent. Consider the following modification to the basic left to right exponentiation algorithm. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{$k$-ary Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$, $k$ and $t$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $t - 1$ to $0$ do \\ +\hspace{3mm}2.1 $c \leftarrow c^{2^k} $ \\ +\hspace{3mm}2.2 Extract the $i$'th $k$-bit word from $b$ and store it in $g$. \\ +\hspace{3mm}2.3 $c \leftarrow c \cdot a^g$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{$k$-ary Exponentiation} +\label{fig:KARY} +\end{figure} + +The squaring on step 2.1 can be calculated by squaring the value $c$ successively $k$ times. If the values of $a^g$ for $0 < g < 2^k$ have been +precomputed this algorithm requires only $t$ multiplications and $tk$ squarings. The table can be generated with $2^{k - 1} - 1$ squarings and +$2^{k - 1} + 1$ multiplications. This algorithm assumes that the number of bits in the exponent is evenly divisible by $k$. +However, when it is not the remaining $0 < x \le k - 1$ bits can be handled with algorithm~\ref{fig:LTOR}. + +Suppose $k = 4$ and $t = 100$. This modified algorithm will require $109$ multiplications and $408$ squarings to compute the exponentiation. The +original algorithm would on average have required $200$ multiplications and $400$ squrings to compute the same value. The total number of squarings +has increased slightly but the number of multiplications has nearly halved. + +\subsection{Optimal Values of $k$} +An optimal value of $k$ will minimize $2^{k} + \lceil n / k \rceil + n - 1$ for a fixed number of bits in the exponent $n$. The simplest +approach is to brute force search amongst the values $k = 2, 3, \ldots, 8$ for the lowest result. Table~\ref{fig:OPTK} lists optimal values of $k$ +for various exponent sizes and compares the number of multiplication and squarings required against algorithm~\ref{fig:LTOR}. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Exponent (bits)} & \textbf{Optimal $k$} & \textbf{Work at $k$} & \textbf{Work with ~\ref{fig:LTOR}} \\ +\hline $16$ & $2$ & $27$ & $24$ \\ +\hline $32$ & $3$ & $49$ & $48$ \\ +\hline $64$ & $3$ & $92$ & $96$ \\ +\hline $128$ & $4$ & $175$ & $192$ \\ +\hline $256$ & $4$ & $335$ & $384$ \\ +\hline $512$ & $5$ & $645$ & $768$ \\ +\hline $1024$ & $6$ & $1257$ & $1536$ \\ +\hline $2048$ & $6$ & $2452$ & $3072$ \\ +\hline $4096$ & $7$ & $4808$ & $6144$ \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Optimal Values of $k$ for $k$-ary Exponentiation} +\label{fig:OPTK} +\end{figure} + +\subsection{Sliding-Window Exponentiation} +A simple modification to the previous algorithm is only generate the upper half of the table in the range $2^{k-1} \le g < 2^k$. Essentially +this is a table for all values of $g$ where the most significant bit of $g$ is a one. However, in order for this to be allowed in the +algorithm values of $g$ in the range $0 \le g < 2^{k-1}$ must be avoided. + +Table~\ref{fig:OPTK2} lists optimal values of $k$ for various exponent sizes and compares the work required against algorithm~\ref{fig:KARY}. + +\begin{figure}[here] +\begin{center} +\begin{small} +\begin{tabular}{|c|c|c|c|c|c|} +\hline \textbf{Exponent (bits)} & \textbf{Optimal $k$} & \textbf{Work at $k$} & \textbf{Work with ~\ref{fig:KARY}} \\ +\hline $16$ & $3$ & $24$ & $27$ \\ +\hline $32$ & $3$ & $45$ & $49$ \\ +\hline $64$ & $4$ & $87$ & $92$ \\ +\hline $128$ & $4$ & $167$ & $175$ \\ +\hline $256$ & $5$ & $322$ & $335$ \\ +\hline $512$ & $6$ & $628$ & $645$ \\ +\hline $1024$ & $6$ & $1225$ & $1257$ \\ +\hline $2048$ & $7$ & $2403$ & $2452$ \\ +\hline $4096$ & $8$ & $4735$ & $4808$ \\ +\hline +\end{tabular} +\end{small} +\end{center} +\caption{Optimal Values of $k$ for Sliding Window Exponentiation} +\label{fig:OPTK2} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Sliding Window $k$-ary Exponentiation}. \\ +\textbf{Input}. Integer $a$, $b$, $k$ and $t$ \\ +\textbf{Output}. $c = a^b$ \\ +\hline \\ +1. $c \leftarrow 1$ \\ +2. for $i$ from $t - 1$ to $0$ do \\ +\hspace{3mm}2.1 If the $i$'th bit of $b$ is a zero then \\ +\hspace{6mm}2.1.1 $c \leftarrow c^2$ \\ +\hspace{3mm}2.2 else do \\ +\hspace{6mm}2.2.1 $c \leftarrow c^{2^k}$ \\ +\hspace{6mm}2.2.2 Extract the $k$ bits from $(b_{i}b_{i-1}\ldots b_{i-(k-1)})$ and store it in $g$. \\ +\hspace{6mm}2.2.3 $c \leftarrow c \cdot a^g$ \\ +\hspace{6mm}2.2.4 $i \leftarrow i - k$ \\ +3. Return $c$. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Sliding Window $k$-ary Exponentiation} +\end{figure} + +Similar to the previous algorithm this algorithm must have a special handler when fewer than $k$ bits are left in the exponent. While this +algorithm requires the same number of squarings it can potentially have fewer multiplications. The pre-computed table $a^g$ is also half +the size as the previous table. + +Consider the exponent $b = 111101011001000_2 \equiv 31432_{10}$ with $k = 3$ using both algorithms. The first algorithm will divide the exponent up as +the following five $3$-bit words $b \equiv \left ( 111, 101, 011, 001, 000 \right )_{2}$. The second algorithm will break the +exponent as $b \equiv \left ( 111, 101, 0, 110, 0, 100, 0 \right )_{2}$. The single digit $0$ in the second representation are where +a single squaring took place instead of a squaring and multiplication. In total the first method requires $10$ multiplications and $18$ +squarings. The second method requires $8$ multiplications and $18$ squarings. + +In general the sliding window method is never slower than the generic $k$-ary method and often it is slightly faster. + +\section{Modular Exponentiation} + +Modular exponentiation is essentially computing the power of a base within a finite field or ring. For example, computing +$d \equiv a^b \mbox{ (mod }c\mbox{)}$ is a modular exponentiation. Instead of first computing $a^b$ and then reducing it +modulo $c$ the intermediate result is reduced modulo $c$ after every squaring or multiplication operation. + +This guarantees that any intermediate result is bounded by $0 \le d \le c^2 - 2c + 1$ and can be reduced modulo $c$ quickly using +one of the algorithms presented in chapter six. + +Before the actual modular exponentiation algorithm can be written a wrapper algorithm must be written first. This algorithm +will allow the exponent $b$ to be negative which is computed as $c \equiv \left (1 / a \right )^{\vert b \vert} \mbox{(mod }d\mbox{)}$. The +value of $(1/a) \mbox{ mod }c$ is computed using the modular inverse (\textit{see \ref{sec;modinv}}). If no inverse exists the algorithm +terminates with an error. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_exptmod}. \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +1. If $c.sign = MP\_NEG$ return(\textit{MP\_VAL}). \\ +2. If $b.sign = MP\_NEG$ then \\ +\hspace{3mm}2.1 $g' \leftarrow g^{-1} \mbox{ (mod }c\mbox{)}$ \\ +\hspace{3mm}2.2 $x' \leftarrow \vert x \vert$ \\ +\hspace{3mm}2.3 Compute $d \equiv g'^{x'} \mbox{ (mod }c\mbox{)}$ via recursion. \\ +3. if $p$ is odd \textbf{OR} $p$ is a D.R. modulus then \\ +\hspace{3mm}3.1 Compute $y \equiv g^{x} \mbox{ (mod }p\mbox{)}$ via algorithm mp\_exptmod\_fast. \\ +4. else \\ +\hspace{3mm}4.1 Compute $y \equiv g^{x} \mbox{ (mod }p\mbox{)}$ via algorithm s\_mp\_exptmod. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_exptmod} +\end{figure} + +\textbf{Algorithm mp\_exptmod.} +The first algorithm which actually performs modular exponentiation is algorithm s\_mp\_exptmod. It is a sliding window $k$-ary algorithm +which uses Barrett reduction to reduce the product modulo $p$. The second algorithm mp\_exptmod\_fast performs the same operation +except it uses either Montgomery or Diminished Radix reduction. The two latter reduction algorithms are clumped in the same exponentiation +algorithm since their arguments are essentially the same (\textit{two mp\_ints and one mp\_digit}). + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_exptmod.c +\vspace{-3mm} +\begin{alltt} +016 +017 +018 /* this is a shell function that calls either the normal or Montgomery +019 * exptmod functions. Originally the call to the montgomery code was +020 * embedded in the normal function but that wasted alot of stack space +021 * for nothing (since 99% of the time the Montgomery code would be called) +022 */ +023 int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +024 \{ +025 int dr; +026 +027 /* modulus P must be positive */ +028 if (P->sign == MP_NEG) \{ +029 return MP_VAL; +030 \} +031 +032 /* if exponent X is negative we have to recurse */ +033 if (X->sign == MP_NEG) \{ +034 #ifdef BN_MP_INVMOD_C +035 mp_int tmpG, tmpX; +036 int err; +037 +038 /* first compute 1/G mod P */ +039 if ((err = mp_init(&tmpG)) != MP_OKAY) \{ +040 return err; +041 \} +042 if ((err = mp_invmod(G, P, &tmpG)) != MP_OKAY) \{ +043 mp_clear(&tmpG); +044 return err; +045 \} +046 +047 /* now get |X| */ +048 if ((err = mp_init(&tmpX)) != MP_OKAY) \{ +049 mp_clear(&tmpG); +050 return err; +051 \} +052 if ((err = mp_abs(X, &tmpX)) != MP_OKAY) \{ +053 mp_clear_multi(&tmpG, &tmpX, NULL); +054 return err; +055 \} +056 +057 /* and now compute (1/G)**|X| instead of G**X [X < 0] */ +058 err = mp_exptmod(&tmpG, &tmpX, P, Y); +059 mp_clear_multi(&tmpG, &tmpX, NULL); +060 return err; +061 #else +062 /* no invmod */ +063 return MP_VAL; +064 #endif +065 \} +066 +067 #ifdef BN_MP_DR_IS_MODULUS_C +068 /* is it a DR modulus? */ +069 dr = mp_dr_is_modulus(P); +070 #else +071 dr = 0; +072 #endif +073 +074 #ifdef BN_MP_REDUCE_IS_2K_C +075 /* if not, is it a uDR modulus? */ +076 if (dr == 0) \{ +077 dr = mp_reduce_is_2k(P) << 1; +078 \} +079 #endif +080 +081 /* if the modulus is odd or dr != 0 use the fast method */ +082 #ifdef BN_MP_EXPTMOD_FAST_C +083 if (mp_isodd (P) == 1 || dr != 0) \{ +084 return mp_exptmod_fast (G, X, P, Y, dr); +085 \} else \{ +086 #endif +087 #ifdef BN_S_MP_EXPTMOD_C +088 /* otherwise use the generic Barrett reduction technique */ +089 return s_mp_exptmod (G, X, P, Y); +090 #else +091 /* no exptmod for evens */ +092 return MP_VAL; +093 #endif +094 #ifdef BN_MP_EXPTMOD_FAST_C +095 \} +096 #endif +097 \} +098 +099 #endif +\end{alltt} +\end{small} + +In order to keep the algorithms in a known state the first step on line 28 is to reject any negative modulus as input. If the exponent is +negative the algorithm tries to perform a modular exponentiation with the modular inverse of the base $G$. The temporary variable $tmpG$ is assigned +the modular inverse of $G$ and $tmpX$ is assigned the absolute value of $X$. The algorithm will recuse with these new values with a positive +exponent. + +If the exponent is positive the algorithm resumes the exponentiation. Line 69 determines if the modulus is of the restricted Diminished Radix +form. If it is not line 77 attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one +of three values. + +\begin{enumerate} +\item $dr = 0$ means that the modulus is not of either restricted or unrestricted Diminished Radix form. +\item $dr = 1$ means that the modulus is of restricted Diminished Radix form. +\item $dr = 2$ means that the modulus is of unrestricted Diminished Radix form. +\end{enumerate} + +Line 67 determines if the fast modular exponentiation algorithm can be used. It is allowed if $dr \ne 0$ or if the modulus is odd. Otherwise, +the slower s\_mp\_exptmod algorithm is used which uses Barrett reduction. + +\subsection{Barrett Modular Exponentiation} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_exptmod}. \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +1. $k \leftarrow lg(x)$ \\ +2. $winsize \leftarrow \left \lbrace \begin{array}{ll} + 2 & \mbox{if }k \le 7 \\ + 3 & \mbox{if }7 < k \le 36 \\ + 4 & \mbox{if }36 < k \le 140 \\ + 5 & \mbox{if }140 < k \le 450 \\ + 6 & \mbox{if }450 < k \le 1303 \\ + 7 & \mbox{if }1303 < k \le 3529 \\ + 8 & \mbox{if }3529 < k \\ + \end{array} \right .$ \\ +3. Initialize $2^{winsize}$ mp\_ints in an array named $M$ and one mp\_int named $\mu$ \\ +4. Calculate the $\mu$ required for Barrett Reduction (\textit{mp\_reduce\_setup}). \\ +5. $M_1 \leftarrow g \mbox{ (mod }p\mbox{)}$ \\ +\\ +Setup the table of small powers of $g$. First find $g^{2^{winsize}}$ and then all multiples of it. \\ +6. $k \leftarrow 2^{winsize - 1}$ \\ +7. $M_{k} \leftarrow M_1$ \\ +8. for $ix$ from 0 to $winsize - 2$ do \\ +\hspace{3mm}8.1 $M_k \leftarrow \left ( M_k \right )^2$ (\textit{mp\_sqr}) \\ +\hspace{3mm}8.2 $M_k \leftarrow M_k \mbox{ (mod }p\mbox{)}$ (\textit{mp\_reduce}) \\ +9. for $ix$ from $2^{winsize - 1} + 1$ to $2^{winsize} - 1$ do \\ +\hspace{3mm}9.1 $M_{ix} \leftarrow M_{ix - 1} \cdot M_{1}$ (\textit{mp\_mul}) \\ +\hspace{3mm}9.2 $M_{ix} \leftarrow M_{ix} \mbox{ (mod }p\mbox{)}$ (\textit{mp\_reduce}) \\ +10. $res \leftarrow 1$ \\ +\\ +Start Sliding Window. \\ +11. $mode \leftarrow 0, bitcnt \leftarrow 1, buf \leftarrow 0, digidx \leftarrow x.used - 1, bitcpy \leftarrow 0, bitbuf \leftarrow 0$ \\ +12. Loop \\ +\hspace{3mm}12.1 $bitcnt \leftarrow bitcnt - 1$ \\ +\hspace{3mm}12.2 If $bitcnt = 0$ then do \\ +\hspace{6mm}12.2.1 If $digidx = -1$ goto step 13. \\ +\hspace{6mm}12.2.2 $buf \leftarrow x_{digidx}$ \\ +\hspace{6mm}12.2.3 $digidx \leftarrow digidx - 1$ \\ +\hspace{6mm}12.2.4 $bitcnt \leftarrow lg(\beta)$ \\ +Continued on next page. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_exptmod} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{s\_mp\_exptmod} (\textit{continued}). \\ +\textbf{Input}. mp\_int $a$, $b$ and $c$ \\ +\textbf{Output}. $y \equiv g^x \mbox{ (mod }p\mbox{)}$ \\ +\hline \\ +\hspace{3mm}12.3 $y \leftarrow (buf >> (lg(\beta) - 1))$ AND $1$ \\ +\hspace{3mm}12.4 $buf \leftarrow buf << 1$ \\ +\hspace{3mm}12.5 if $mode = 0$ and $y = 0$ then goto step 12. \\ +\hspace{3mm}12.6 if $mode = 1$ and $y = 0$ then do \\ +\hspace{6mm}12.6.1 $res \leftarrow res^2$ \\ +\hspace{6mm}12.6.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}12.6.3 Goto step 12. \\ +\hspace{3mm}12.7 $bitcpy \leftarrow bitcpy + 1$ \\ +\hspace{3mm}12.8 $bitbuf \leftarrow bitbuf + (y << (winsize - bitcpy))$ \\ +\hspace{3mm}12.9 $mode \leftarrow 2$ \\ +\hspace{3mm}12.10 If $bitcpy = winsize$ then do \\ +\hspace{6mm}Window is full so perform the squarings and single multiplication. \\ +\hspace{6mm}12.10.1 for $ix$ from $0$ to $winsize -1$ do \\ +\hspace{9mm}12.10.1.1 $res \leftarrow res^2$ \\ +\hspace{9mm}12.10.1.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}12.10.2 $res \leftarrow res \cdot M_{bitbuf}$ \\ +\hspace{6mm}12.10.3 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}Reset the window. \\ +\hspace{6mm}12.10.4 $bitcpy \leftarrow 0, bitbuf \leftarrow 0, mode \leftarrow 1$ \\ +\\ +No more windows left. Check for residual bits of exponent. \\ +13. If $mode = 2$ and $bitcpy > 0$ then do \\ +\hspace{3mm}13.1 for $ix$ form $0$ to $bitcpy - 1$ do \\ +\hspace{6mm}13.1.1 $res \leftarrow res^2$ \\ +\hspace{6mm}13.1.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +\hspace{6mm}13.1.3 $bitbuf \leftarrow bitbuf << 1$ \\ +\hspace{6mm}13.1.4 If $bitbuf$ AND $2^{winsize} \ne 0$ then do \\ +\hspace{9mm}13.1.4.1 $res \leftarrow res \cdot M_{1}$ \\ +\hspace{9mm}13.1.4.2 $res \leftarrow res \mbox{ (mod }p\mbox{)}$ \\ +14. $y \leftarrow res$ \\ +15. Clear $res$, $mu$ and the $M$ array. \\ +16. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm s\_mp\_exptmod (continued)} +\end{figure} + +\textbf{Algorithm s\_mp\_exptmod.} +This algorithm computes the $x$'th power of $g$ modulo $p$ and stores the result in $y$. It takes advantage of the Barrett reduction +algorithm to keep the product small throughout the algorithm. + +The first two steps determine the optimal window size based on the number of bits in the exponent. The larger the exponent the +larger the window size becomes. After a window size $winsize$ has been chosen an array of $2^{winsize}$ mp\_int variables is allocated. This +table will hold the values of $g^x \mbox{ (mod }p\mbox{)}$ for $2^{winsize - 1} \le x < 2^{winsize}$. + +After the table is allocated the first power of $g$ is found. Since $g \ge p$ is allowed it must be first reduced modulo $p$ to make +the rest of the algorithm more efficient. The first element of the table at $2^{winsize - 1}$ is found by squaring $M_1$ successively $winsize - 2$ +times. The rest of the table elements are found by multiplying the previous element by $M_1$ modulo $p$. + +Now that the table is available the sliding window may begin. The following list describes the functions of all the variables in the window. +\begin{enumerate} +\item The variable $mode$ dictates how the bits of the exponent are interpreted. +\begin{enumerate} + \item When $mode = 0$ the bits are ignored since no non-zero bit of the exponent has been seen yet. For example, if the exponent were simply + $1$ then there would be $lg(\beta) - 1$ zero bits before the first non-zero bit. In this case bits are ignored until a non-zero bit is found. + \item When $mode = 1$ a non-zero bit has been seen before and a new $winsize$-bit window has not been formed yet. In this mode leading $0$ bits + are read and a single squaring is performed. If a non-zero bit is read a new window is created. + \item When $mode = 2$ the algorithm is in the middle of forming a window and new bits are appended to the window from the most significant bit + downwards. +\end{enumerate} +\item The variable $bitcnt$ indicates how many bits are left in the current digit of the exponent left to be read. When it reaches zero a new digit + is fetched from the exponent. +\item The variable $buf$ holds the currently read digit of the exponent. +\item The variable $digidx$ is an index into the exponents digits. It starts at the leading digit $x.used - 1$ and moves towards the trailing digit. +\item The variable $bitcpy$ indicates how many bits are in the currently formed window. When it reaches $winsize$ the window is flushed and + the appropriate operations performed. +\item The variable $bitbuf$ holds the current bits of the window being formed. +\end{enumerate} + +All of step 12 is the window processing loop. It will iterate while there are digits available form the exponent to read. The first step +inside this loop is to extract a new digit if no more bits are available in the current digit. If there are no bits left a new digit is +read and if there are no digits left than the loop terminates. + +After a digit is made available step 12.3 will extract the most significant bit of the current digit and move all other bits in the digit +upwards. In effect the digit is read from most significant bit to least significant bit and since the digits are read from leading to +trailing edges the entire exponent is read from most significant bit to least significant bit. + +At step 12.5 if the $mode$ and currently extracted bit $y$ are both zero the bit is ignored and the next bit is read. This prevents the +algorithm from having to perform trivial squaring and reduction operations before the first non-zero bit is read. Step 12.6 and 12.7-10 handle +the two cases of $mode = 1$ and $mode = 2$ respectively. + +\begin{center} +\begin{figure}[here] +\includegraphics{pics/expt_state.ps} +\caption{Sliding Window State Diagram} +\label{pic:expt_state} +\end{figure} +\end{center} + +By step 13 there are no more digits left in the exponent. However, there may be partial bits in the window left. If $mode = 2$ then +a Left-to-Right algorithm is used to process the remaining few bits. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_s\_mp\_exptmod.c +\vspace{-3mm} +\begin{alltt} +016 +017 #ifdef MP_LOW_MEM +018 #define TAB_SIZE 32 +019 #else +020 #define TAB_SIZE 256 +021 #endif +022 +023 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +024 \{ +025 mp_int M[TAB_SIZE], res, mu; +026 mp_digit buf; +027 int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; +028 +029 /* find window size */ +030 x = mp_count_bits (X); +031 if (x <= 7) \{ +032 winsize = 2; +033 \} else if (x <= 36) \{ +034 winsize = 3; +035 \} else if (x <= 140) \{ +036 winsize = 4; +037 \} else if (x <= 450) \{ +038 winsize = 5; +039 \} else if (x <= 1303) \{ +040 winsize = 6; +041 \} else if (x <= 3529) \{ +042 winsize = 7; +043 \} else \{ +044 winsize = 8; +045 \} +046 +047 #ifdef MP_LOW_MEM +048 if (winsize > 5) \{ +049 winsize = 5; +050 \} +051 #endif +052 +053 /* init M array */ +054 /* init first cell */ +055 if ((err = mp_init(&M[1])) != MP_OKAY) \{ +056 return err; +057 \} +058 +059 /* now init the second half of the array */ +060 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +061 if ((err = mp_init(&M[x])) != MP_OKAY) \{ +062 for (y = 1<<(winsize-1); y < x; y++) \{ +063 mp_clear (&M[y]); +064 \} +065 mp_clear(&M[1]); +066 return err; +067 \} +068 \} +069 +070 /* create mu, used for Barrett reduction */ +071 if ((err = mp_init (&mu)) != MP_OKAY) \{ +072 goto LBL_M; +073 \} +074 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ +075 goto LBL_MU; +076 \} +077 +078 /* create M table +079 * +080 * The M table contains powers of the base, +081 * e.g. M[x] = G**x mod P +082 * +083 * The first half of the table is not +084 * computed though accept for M[0] and M[1] +085 */ +086 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ +087 goto LBL_MU; +088 \} +089 +090 /* compute the value at M[1<<(winsize-1)] by squaring +091 * M[1] (winsize-1) times +092 */ +093 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ +094 goto LBL_MU; +095 \} +096 +097 for (x = 0; x < (winsize - 1); x++) \{ +098 if ((err = mp_sqr (&M[1 << (winsize - 1)], +099 &M[1 << (winsize - 1)])) != MP_OKAY) \{ +100 goto LBL_MU; +101 \} +102 if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ +103 goto LBL_MU; +104 \} +105 \} +106 +107 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) +108 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) +109 */ +110 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ +111 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ +112 goto LBL_MU; +113 \} +114 if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) \{ +115 goto LBL_MU; +116 \} +117 \} +118 +119 /* setup result */ +120 if ((err = mp_init (&res)) != MP_OKAY) \{ +121 goto LBL_MU; +122 \} +123 mp_set (&res, 1); +124 +125 /* set initial mode and bit cnt */ +126 mode = 0; +127 bitcnt = 1; +128 buf = 0; +129 digidx = X->used - 1; +130 bitcpy = 0; +131 bitbuf = 0; +132 +133 for (;;) \{ +134 /* grab next digit as required */ +135 if (--bitcnt == 0) \{ +136 /* if digidx == -1 we are out of digits */ +137 if (digidx == -1) \{ +138 break; +139 \} +140 /* read next digit and reset the bitcnt */ +141 buf = X->dp[digidx--]; +142 bitcnt = (int) DIGIT_BIT; +143 \} +144 +145 /* grab the next msb from the exponent */ +146 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; +147 buf <<= (mp_digit)1; +148 +149 /* if the bit is zero and mode == 0 then we ignore it +150 * These represent the leading zero bits before the first 1 bit +151 * in the exponent. Technically this opt is not required but it +152 * does lower the # of trivial squaring/reductions used +153 */ +154 if (mode == 0 && y == 0) \{ +155 continue; +156 \} +157 +158 /* if the bit is zero and mode == 1 then we square */ +159 if (mode == 1 && y == 0) \{ +160 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +161 goto LBL_RES; +162 \} +163 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ +164 goto LBL_RES; +165 \} +166 continue; +167 \} +168 +169 /* else we add it to the window */ +170 bitbuf |= (y << (winsize - ++bitcpy)); +171 mode = 2; +172 +173 if (bitcpy == winsize) \{ +174 /* ok window is filled so square as required and multiply */ +175 /* square first */ +176 for (x = 0; x < winsize; x++) \{ +177 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +178 goto LBL_RES; +179 \} +180 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ +181 goto LBL_RES; +182 \} +183 \} +184 +185 /* then multiply */ +186 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ +187 goto LBL_RES; +188 \} +189 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ +190 goto LBL_RES; +191 \} +192 +193 /* empty window and reset */ +194 bitcpy = 0; +195 bitbuf = 0; +196 mode = 1; +197 \} +198 \} +199 +200 /* if bits remain then square/multiply */ +201 if (mode == 2 && bitcpy > 0) \{ +202 /* square then multiply if the bit is set */ +203 for (x = 0; x < bitcpy; x++) \{ +204 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +205 goto LBL_RES; +206 \} +207 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ +208 goto LBL_RES; +209 \} +210 +211 bitbuf <<= 1; +212 if ((bitbuf & (1 << winsize)) != 0) \{ +213 /* then multiply */ +214 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ +215 goto LBL_RES; +216 \} +217 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ +218 goto LBL_RES; +219 \} +220 \} +221 \} +222 \} +223 +224 mp_exch (&res, Y); +225 err = MP_OKAY; +226 LBL_RES:mp_clear (&res); +227 LBL_MU:mp_clear (&mu); +228 LBL_M: +229 mp_clear(&M[1]); +230 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +231 mp_clear (&M[x]); +232 \} +233 return err; +234 \} +235 #endif +\end{alltt} +\end{small} + +Lines 31 through 41 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement +on line 33 the value of $x$ is already known to be greater than $140$. + +The conditional piece of code beginning on line 47 allows the window size to be restricted to five bits. This logic is used to ensure +the table of precomputed powers of $G$ remains relatively small. + +The for loop on line 60 initializes the $M$ array while lines 61 and 74 compute the value of $\mu$ required for +Barrett reduction. + +-- More later. + +\section{Quick Power of Two} +Calculating $b = 2^a$ can be performed much quicker than with any of the previous algorithms. Recall that a logical shift left $m << k$ is +equivalent to $m \cdot 2^k$. By this logic when $m = 1$ a quick power of two can be achieved. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_2expt}. \\ +\textbf{Input}. integer $b$ \\ +\textbf{Output}. $a \leftarrow 2^b$ \\ +\hline \\ +1. $a \leftarrow 0$ \\ +2. If $a.alloc < \lfloor b / lg(\beta) \rfloor + 1$ then grow $a$ appropriately. \\ +3. $a.used \leftarrow \lfloor b / lg(\beta) \rfloor + 1$ \\ +4. $a_{\lfloor b / lg(\beta) \rfloor} \leftarrow 1 << (b \mbox{ mod } lg(\beta))$ \\ +5. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_2expt} +\end{figure} + +\textbf{Algorithm mp\_2expt.} + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_2expt.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* computes a = 2**b +018 * +019 * Simple algorithm which zeroes the int, grows it then just sets one bit +020 * as required. +021 */ +022 int +023 mp_2expt (mp_int * a, int b) +024 \{ +025 int res; +026 +027 /* zero a as per default */ +028 mp_zero (a); +029 +030 /* grow a to accomodate the single bit */ +031 if ((res = mp_grow (a, b / DIGIT_BIT + 1)) != MP_OKAY) \{ +032 return res; +033 \} +034 +035 /* set the used count of where the bit will go */ +036 a->used = b / DIGIT_BIT + 1; +037 +038 /* put the single bit in its place */ +039 a->dp[b / DIGIT_BIT] = ((mp_digit)1) << (b % DIGIT_BIT); +040 +041 return MP_OKAY; +042 \} +043 #endif +\end{alltt} +\end{small} + +\chapter{Higher Level Algorithms} + +This chapter discusses the various higher level algorithms that are required to complete a well rounded multiple precision integer package. These +routines are less performance oriented than the algorithms of chapters five, six and seven but are no less important. + +The first section describes a method of integer division with remainder that is universally well known. It provides the signed division logic +for the package. The subsequent section discusses a set of algorithms which allow a single digit to be the 2nd operand for a variety of operations. +These algorithms serve mostly to simplify other algorithms where small constants are required. The last two sections discuss how to manipulate +various representations of integers. For example, converting from an mp\_int to a string of character. + +\section{Integer Division with Remainder} +\label{sec:division} + +Integer division aside from modular exponentiation is the most intensive algorithm to compute. Like addition, subtraction and multiplication +the basis of this algorithm is the long-hand division algorithm taught to school children. Throughout this discussion several common variables +will be used. Let $x$ represent the divisor and $y$ represent the dividend. Let $q$ represent the integer quotient $\lfloor y / x \rfloor$ and +let $r$ represent the remainder $r = y - x \lfloor y / x \rfloor$. The following simple algorithm will be used to start the discussion. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Radix-$\beta$ Integer Division}. \\ +\textbf{Input}. integer $x$ and $y$ \\ +\textbf{Output}. $q = \lfloor y/x\rfloor, r = y - xq$ \\ +\hline \\ +1. $q \leftarrow 0$ \\ +2. $n \leftarrow \vert \vert y \vert \vert - \vert \vert x \vert \vert$ \\ +3. for $t$ from $n$ down to $0$ do \\ +\hspace{3mm}3.1 Maximize $k$ such that $kx\beta^t$ is less than or equal to $y$ and $(k + 1)x\beta^t$ is greater. \\ +\hspace{3mm}3.2 $q \leftarrow q + k\beta^t$ \\ +\hspace{3mm}3.3 $y \leftarrow y - kx\beta^t$ \\ +4. $r \leftarrow y$ \\ +5. Return($q, r$) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Radix-$\beta$ Integer Division} +\label{fig:raddiv} +\end{figure} + +As children we are taught this very simple algorithm for the case of $\beta = 10$. Almost instinctively several optimizations are taught for which +their reason of existing are never explained. For this example let $y = 5471$ represent the dividend and $x = 23$ represent the divisor. + +To find the first digit of the quotient the value of $k$ must be maximized such that $kx\beta^t$ is less than or equal to $y$ and +simultaneously $(k + 1)x\beta^t$ is greater than $y$. Implicitly $k$ is the maximum value the $t$'th digit of the quotient may have. The habitual method +used to find the maximum is to ``eyeball'' the two numbers, typically only the leading digits and quickly estimate a quotient. By only using leading +digits a much simpler division may be used to form an educated guess at what the value must be. In this case $k = \lfloor 54/23\rfloor = 2$ quickly +arises as a possible solution. Indeed $2x\beta^2 = 4600$ is less than $y = 5471$ and simultaneously $(k + 1)x\beta^2 = 6900$ is larger than $y$. +As a result $k\beta^2$ is added to the quotient which now equals $q = 200$ and $4600$ is subtracted from $y$ to give a remainder of $y = 841$. + +Again this process is repeated to produce the quotient digit $k = 3$ which makes the quotient $q = 200 + 3\beta = 230$ and the remainder +$y = 841 - 3x\beta = 181$. Finally the last iteration of the loop produces $k = 7$ which leads to the quotient $q = 230 + 7 = 237$ and the +remainder $y = 181 - 7x = 20$. The final quotient and remainder found are $q = 237$ and $r = y = 20$ which are indeed correct since +$237 \cdot 23 + 20 = 5471$ is true. + +\subsection{Quotient Estimation} +\label{sec:divest} +As alluded to earlier the quotient digit $k$ can be estimated from only the leading digits of both the divisor and dividend. When $p$ leading +digits are used from both the divisor and dividend to form an estimation the accuracy of the estimation rises as $p$ grows. Technically +speaking the estimation is based on assuming the lower $\vert \vert y \vert \vert - p$ and $\vert \vert x \vert \vert - p$ lower digits of the +dividend and divisor are zero. + +The value of the estimation may off by a few values in either direction and in general is fairly correct. A simplification \cite[pp. 271]{TAOCPV2} +of the estimation technique is to use $t + 1$ digits of the dividend and $t$ digits of the divisor, in particularly when $t = 1$. The estimate +using this technique is never too small. For the following proof let $t = \vert \vert y \vert \vert - 1$ and $s = \vert \vert x \vert \vert - 1$ +represent the most significant digits of the dividend and divisor respectively. + +\textbf{Proof.}\textit{ The quotient $\hat k = \lfloor (y_t\beta + y_{t-1}) / x_s \rfloor$ is greater than or equal to +$k = \lfloor y / (x \cdot \beta^{\vert \vert y \vert \vert - \vert \vert x \vert \vert - 1}) \rfloor$. } +The first obvious case is when $\hat k = \beta - 1$ in which case the proof is concluded since the real quotient cannot be larger. For all other +cases $\hat k = \lfloor (y_t\beta + y_{t-1}) / x_s \rfloor$ and $\hat k x_s \ge y_t\beta + y_{t-1} - x_s + 1$. The latter portion of the inequalility +$-x_s + 1$ arises from the fact that a truncated integer division will give the same quotient for at most $x_s - 1$ values. Next a series of +inequalities will prove the hypothesis. + +\begin{equation} +y - \hat k x \le y - \hat k x_s\beta^s +\end{equation} + +This is trivially true since $x \ge x_s\beta^s$. Next we replace $\hat kx_s\beta^s$ by the previous inequality for $\hat kx_s$. + +\begin{equation} +y - \hat k x \le y_t\beta^t + \ldots + y_0 - (y_t\beta^t + y_{t-1}\beta^{t-1} - x_s\beta^t + \beta^s) +\end{equation} + +By simplifying the previous inequality the following inequality is formed. + +\begin{equation} +y - \hat k x \le y_{t-2}\beta^{t-2} + \ldots + y_0 + x_s\beta^s - \beta^s +\end{equation} + +Subsequently, + +\begin{equation} +y_{t-2}\beta^{t-2} + \ldots + y_0 + x_s\beta^s - \beta^s < x_s\beta^s \le x +\end{equation} + +Which proves that $y - \hat kx \le x$ and by consequence $\hat k \ge k$ which concludes the proof. \textbf{QED} + + +\subsection{Normalized Integers} +For the purposes of division a normalized input is when the divisors leading digit $x_n$ is greater than or equal to $\beta / 2$. By multiplying both +$x$ and $y$ by $j = \lfloor (\beta / 2) / x_n \rfloor$ the quotient remains unchanged and the remainder is simply $j$ times the original +remainder. The purpose of normalization is to ensure the leading digit of the divisor is sufficiently large such that the estimated quotient will +lie in the domain of a single digit. Consider the maximum dividend $(\beta - 1) \cdot \beta + (\beta - 1)$ and the minimum divisor $\beta / 2$. + +\begin{equation} +{{\beta^2 - 1} \over { \beta / 2}} \le 2\beta - {2 \over \beta} +\end{equation} + +At most the quotient approaches $2\beta$, however, in practice this will not occur since that would imply the previous quotient digit was too small. + +\subsection{Radix-$\beta$ Division with Remainder} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div}. \\ +\textbf{Input}. mp\_int $a, b$ \\ +\textbf{Output}. $c = \lfloor a/b \rfloor$, $d = a - bc$ \\ +\hline \\ +1. If $b = 0$ return(\textit{MP\_VAL}). \\ +2. If $\vert a \vert < \vert b \vert$ then do \\ +\hspace{3mm}2.1 $d \leftarrow a$ \\ +\hspace{3mm}2.2 $c \leftarrow 0$ \\ +\hspace{3mm}2.3 Return(\textit{MP\_OKAY}). \\ +\\ +Setup the quotient to receive the digits. \\ +3. Grow $q$ to $a.used + 2$ digits. \\ +4. $q \leftarrow 0$ \\ +5. $x \leftarrow \vert a \vert , y \leftarrow \vert b \vert$ \\ +6. $sign \leftarrow \left \lbrace \begin{array}{ll} + MP\_ZPOS & \mbox{if }a.sign = b.sign \\ + MP\_NEG & \mbox{otherwise} \\ + \end{array} \right .$ \\ +\\ +Normalize the inputs such that the leading digit of $y$ is greater than or equal to $\beta / 2$. \\ +7. $norm \leftarrow (lg(\beta) - 1) - (\lceil lg(y) \rceil \mbox{ (mod }lg(\beta)\mbox{)})$ \\ +8. $x \leftarrow x \cdot 2^{norm}, y \leftarrow y \cdot 2^{norm}$ \\ +\\ +Find the leading digit of the quotient. \\ +9. $n \leftarrow x.used - 1, t \leftarrow y.used - 1$ \\ +10. $y \leftarrow y \cdot \beta^{n - t}$ \\ +11. While ($x \ge y$) do \\ +\hspace{3mm}11.1 $q_{n - t} \leftarrow q_{n - t} + 1$ \\ +\hspace{3mm}11.2 $x \leftarrow x - y$ \\ +12. $y \leftarrow \lfloor y / \beta^{n-t} \rfloor$ \\ +\\ +Continued on the next page. \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div} (continued). \\ +\textbf{Input}. mp\_int $a, b$ \\ +\textbf{Output}. $c = \lfloor a/b \rfloor$, $d = a - bc$ \\ +\hline \\ +Now find the remainder fo the digits. \\ +13. for $i$ from $n$ down to $(t + 1)$ do \\ +\hspace{3mm}13.1 If $i > x.used$ then jump to the next iteration of this loop. \\ +\hspace{3mm}13.2 If $x_{i} = y_{t}$ then \\ +\hspace{6mm}13.2.1 $q_{i - t - 1} \leftarrow \beta - 1$ \\ +\hspace{3mm}13.3 else \\ +\hspace{6mm}13.3.1 $\hat r \leftarrow x_{i} \cdot \beta + x_{i - 1}$ \\ +\hspace{6mm}13.3.2 $\hat r \leftarrow \lfloor \hat r / y_{t} \rfloor$ \\ +\hspace{6mm}13.3.3 $q_{i - t - 1} \leftarrow \hat r$ \\ +\hspace{3mm}13.4 $q_{i - t - 1} \leftarrow q_{i - t - 1} + 1$ \\ +\\ +Fixup quotient estimation. \\ +\hspace{3mm}13.5 Loop \\ +\hspace{6mm}13.5.1 $q_{i - t - 1} \leftarrow q_{i - t - 1} - 1$ \\ +\hspace{6mm}13.5.2 t$1 \leftarrow 0$ \\ +\hspace{6mm}13.5.3 t$1_0 \leftarrow y_{t - 1}, $ t$1_1 \leftarrow y_t,$ t$1.used \leftarrow 2$ \\ +\hspace{6mm}13.5.4 $t1 \leftarrow t1 \cdot q_{i - t - 1}$ \\ +\hspace{6mm}13.5.5 t$2_0 \leftarrow x_{i - 2}, $ t$2_1 \leftarrow x_{i - 1}, $ t$2_2 \leftarrow x_i, $ t$2.used \leftarrow 3$ \\ +\hspace{6mm}13.5.6 If $\vert t1 \vert > \vert t2 \vert$ then goto step 13.5. \\ +\hspace{3mm}13.6 t$1 \leftarrow y \cdot q_{i - t - 1}$ \\ +\hspace{3mm}13.7 t$1 \leftarrow $ t$1 \cdot \beta^{i - t - 1}$ \\ +\hspace{3mm}13.8 $x \leftarrow x - $ t$1$ \\ +\hspace{3mm}13.9 If $x.sign = MP\_NEG$ then \\ +\hspace{6mm}13.10 t$1 \leftarrow y$ \\ +\hspace{6mm}13.11 t$1 \leftarrow $ t$1 \cdot \beta^{i - t - 1}$ \\ +\hspace{6mm}13.12 $x \leftarrow x + $ t$1$ \\ +\hspace{6mm}13.13 $q_{i - t - 1} \leftarrow q_{i - t - 1} - 1$ \\ +\\ +Finalize the result. \\ +14. Clamp excess digits of $q$ \\ +15. $c \leftarrow q, c.sign \leftarrow sign$ \\ +16. $x.sign \leftarrow a.sign$ \\ +17. $d \leftarrow \lfloor x / 2^{norm} \rfloor$ \\ +18. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div (continued)} +\end{figure} +\textbf{Algorithm mp\_div.} +This algorithm will calculate quotient and remainder from an integer division given a dividend and divisor. The algorithm is a signed +division and will produce a fully qualified quotient and remainder. + +First the divisor $b$ must be non-zero which is enforced in step one. If the divisor is larger than the dividend than the quotient is implicitly +zero and the remainder is the dividend. + +After the first two trivial cases of inputs are handled the variable $q$ is setup to receive the digits of the quotient. Two unsigned copies of the +divisor $y$ and dividend $x$ are made as well. The core of the division algorithm is an unsigned division and will only work if the values are +positive. Now the two values $x$ and $y$ must be normalized such that the leading digit of $y$ is greater than or equal to $\beta / 2$. +This is performed by shifting both to the left by enough bits to get the desired normalization. + +At this point the division algorithm can begin producing digits of the quotient. Recall that maximum value of the estimation used is +$2\beta - {2 \over \beta}$ which means that a digit of the quotient must be first produced by another means. In this case $y$ is shifted +to the left (\textit{step ten}) so that it has the same number of digits as $x$. The loop on step eleven will subtract multiples of the +shifted copy of $y$ until $x$ is smaller. Since the leading digit of $y$ is greater than or equal to $\beta/2$ this loop will iterate at most two +times to produce the desired leading digit of the quotient. + +Now the remainder of the digits can be produced. The equation $\hat q = \lfloor {{x_i \beta + x_{i-1}}\over y_t} \rfloor$ is used to fairly +accurately approximate the true quotient digit. The estimation can in theory produce an estimation as high as $2\beta - {2 \over \beta}$ but by +induction the upper quotient digit is correct (\textit{as established on step eleven}) and the estimate must be less than $\beta$. + +Recall from section~\ref{sec:divest} that the estimation is never too low but may be too high. The next step of the estimation process is +to refine the estimation. The loop on step 13.5 uses $x_i\beta^2 + x_{i-1}\beta + x_{i-2}$ and $q_{i - t - 1}(y_t\beta + y_{t-1})$ as a higher +order approximation to adjust the quotient digit. + +After both phases of estimation the quotient digit may still be off by a value of one\footnote{This is similar to the error introduced +by optimizing Barrett reduction.}. Steps 13.6 and 13.7 subtract the multiple of the divisor from the dividend (\textit{Similar to step 3.3 of +algorithm~\ref{fig:raddiv}} and then subsequently add a multiple of the divisor if the quotient was too large. + +Now that the quotient has been determine finializing the result is a matter of clamping the quotient, fixing the sizes and de-normalizing the +remainder. An important aspect of this algorithm seemingly overlooked in other descriptions such as that of Algorithm 14.20 HAC \cite[pp. 598]{HAC} +is that when the estimations are being made (\textit{inside the loop on step 13.5}) that the digits $y_{t-1}$, $x_{i-2}$ and $x_{i-1}$ may lie +outside their respective boundaries. For example, if $t = 0$ or $i \le 1$ then the digits would be undefined. In those cases the digits should +respectively be replaced with a zero. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_div.c +\vspace{-3mm} +\begin{alltt} +016 +017 #ifdef BN_MP_DIV_SMALL +018 +019 /* slower bit-bang division... also smaller */ +020 int mp_div(mp_int * a, mp_int * b, mp_int * c, mp_int * d) +021 \{ +022 mp_int ta, tb, tq, q; +023 int res, n, n2; +024 +025 /* is divisor zero ? */ +026 if (mp_iszero (b) == 1) \{ +027 return MP_VAL; +028 \} +029 +030 /* if a < b then q=0, r = a */ +031 if (mp_cmp_mag (a, b) == MP_LT) \{ +032 if (d != NULL) \{ +033 res = mp_copy (a, d); +034 \} else \{ +035 res = MP_OKAY; +036 \} +037 if (c != NULL) \{ +038 mp_zero (c); +039 \} +040 return res; +041 \} +042 +043 /* init our temps */ +044 if ((res = mp_init_multi(&ta, &tb, &tq, &q, NULL) != MP_OKAY)) \{ +045 return res; +046 \} +047 +048 +049 mp_set(&tq, 1); +050 n = mp_count_bits(a) - mp_count_bits(b); +051 if (((res = mp_abs(a, &ta)) != MP_OKAY) || +052 ((res = mp_abs(b, &tb)) != MP_OKAY) || +053 ((res = mp_mul_2d(&tb, n, &tb)) != MP_OKAY) || +054 ((res = mp_mul_2d(&tq, n, &tq)) != MP_OKAY)) \{ +055 goto LBL_ERR; +056 \} +057 +058 while (n-- >= 0) \{ +059 if (mp_cmp(&tb, &ta) != MP_GT) \{ +060 if (((res = mp_sub(&ta, &tb, &ta)) != MP_OKAY) || +061 ((res = mp_add(&q, &tq, &q)) != MP_OKAY)) \{ +062 goto LBL_ERR; +063 \} +064 \} +065 if (((res = mp_div_2d(&tb, 1, &tb, NULL)) != MP_OKAY) || +066 ((res = mp_div_2d(&tq, 1, &tq, NULL)) != MP_OKAY)) \{ +067 goto LBL_ERR; +068 \} +069 \} +070 +071 /* now q == quotient and ta == remainder */ +072 n = a->sign; +073 n2 = (a->sign == b->sign ? MP_ZPOS : MP_NEG); +074 if (c != NULL) \{ +075 mp_exch(c, &q); +076 c->sign = (mp_iszero(c) == MP_YES) ? MP_ZPOS : n2; +077 \} +078 if (d != NULL) \{ +079 mp_exch(d, &ta); +080 d->sign = (mp_iszero(d) == MP_YES) ? MP_ZPOS : n; +081 \} +082 LBL_ERR: +083 mp_clear_multi(&ta, &tb, &tq, &q, NULL); +084 return res; +085 \} +086 +087 #else +088 +089 /* integer signed division. +090 * c*b + d == a [e.g. a/b, c=quotient, d=remainder] +091 * HAC pp.598 Algorithm 14.20 +092 * +093 * Note that the description in HAC is horribly +094 * incomplete. For example, it doesn't consider +095 * the case where digits are removed from 'x' in +096 * the inner loop. It also doesn't consider the +097 * case that y has fewer than three digits, etc.. +098 * +099 * The overall algorithm is as described as +100 * 14.20 from HAC but fixed to treat these cases. +101 */ +102 int mp_div (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +103 \{ +104 mp_int q, x, y, t1, t2; +105 int res, n, t, i, norm, neg; +106 +107 /* is divisor zero ? */ +108 if (mp_iszero (b) == 1) \{ +109 return MP_VAL; +110 \} +111 +112 /* if a < b then q=0, r = a */ +113 if (mp_cmp_mag (a, b) == MP_LT) \{ +114 if (d != NULL) \{ +115 res = mp_copy (a, d); +116 \} else \{ +117 res = MP_OKAY; +118 \} +119 if (c != NULL) \{ +120 mp_zero (c); +121 \} +122 return res; +123 \} +124 +125 if ((res = mp_init_size (&q, a->used + 2)) != MP_OKAY) \{ +126 return res; +127 \} +128 q.used = a->used + 2; +129 +130 if ((res = mp_init (&t1)) != MP_OKAY) \{ +131 goto LBL_Q; +132 \} +133 +134 if ((res = mp_init (&t2)) != MP_OKAY) \{ +135 goto LBL_T1; +136 \} +137 +138 if ((res = mp_init_copy (&x, a)) != MP_OKAY) \{ +139 goto LBL_T2; +140 \} +141 +142 if ((res = mp_init_copy (&y, b)) != MP_OKAY) \{ +143 goto LBL_X; +144 \} +145 +146 /* fix the sign */ +147 neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; +148 x.sign = y.sign = MP_ZPOS; +149 +150 /* normalize both x and y, ensure that y >= b/2, [b == 2**DIGIT_BIT] */ +151 norm = mp_count_bits(&y) % DIGIT_BIT; +152 if (norm < (int)(DIGIT_BIT-1)) \{ +153 norm = (DIGIT_BIT-1) - norm; +154 if ((res = mp_mul_2d (&x, norm, &x)) != MP_OKAY) \{ +155 goto LBL_Y; +156 \} +157 if ((res = mp_mul_2d (&y, norm, &y)) != MP_OKAY) \{ +158 goto LBL_Y; +159 \} +160 \} else \{ +161 norm = 0; +162 \} +163 +164 /* note hac does 0 based, so if used==5 then its 0,1,2,3,4, e.g. use 4 */ +165 n = x.used - 1; +166 t = y.used - 1; +167 +168 /* while (x >= y*b**n-t) do \{ q[n-t] += 1; x -= y*b**\{n-t\} \} */ +169 if ((res = mp_lshd (&y, n - t)) != MP_OKAY) \{ /* y = y*b**\{n-t\} */ +170 goto LBL_Y; +171 \} +172 +173 while (mp_cmp (&x, &y) != MP_LT) \{ +174 ++(q.dp[n - t]); +175 if ((res = mp_sub (&x, &y, &x)) != MP_OKAY) \{ +176 goto LBL_Y; +177 \} +178 \} +179 +180 /* reset y by shifting it back down */ +181 mp_rshd (&y, n - t); +182 +183 /* step 3. for i from n down to (t + 1) */ +184 for (i = n; i >= (t + 1); i--) \{ +185 if (i > x.used) \{ +186 continue; +187 \} +188 +189 /* step 3.1 if xi == yt then set q\{i-t-1\} to b-1, +190 * otherwise set q\{i-t-1\} to (xi*b + x\{i-1\})/yt */ +191 if (x.dp[i] == y.dp[t]) \{ +192 q.dp[i - t - 1] = ((((mp_digit)1) << DIGIT_BIT) - 1); +193 \} else \{ +194 mp_word tmp; +195 tmp = ((mp_word) x.dp[i]) << ((mp_word) DIGIT_BIT); +196 tmp |= ((mp_word) x.dp[i - 1]); +197 tmp /= ((mp_word) y.dp[t]); +198 if (tmp > (mp_word) MP_MASK) +199 tmp = MP_MASK; +200 q.dp[i - t - 1] = (mp_digit) (tmp & (mp_word) (MP_MASK)); +201 \} +202 +203 /* while (q\{i-t-1\} * (yt * b + y\{t-1\})) > +204 xi * b**2 + xi-1 * b + xi-2 +205 +206 do q\{i-t-1\} -= 1; +207 */ +208 q.dp[i - t - 1] = (q.dp[i - t - 1] + 1) & MP_MASK; +209 do \{ +210 q.dp[i - t - 1] = (q.dp[i - t - 1] - 1) & MP_MASK; +211 +212 /* find left hand */ +213 mp_zero (&t1); +214 t1.dp[0] = (t - 1 < 0) ? 0 : y.dp[t - 1]; +215 t1.dp[1] = y.dp[t]; +216 t1.used = 2; +217 if ((res = mp_mul_d (&t1, q.dp[i - t - 1], &t1)) != MP_OKAY) \{ +218 goto LBL_Y; +219 \} +220 +221 /* find right hand */ +222 t2.dp[0] = (i - 2 < 0) ? 0 : x.dp[i - 2]; +223 t2.dp[1] = (i - 1 < 0) ? 0 : x.dp[i - 1]; +224 t2.dp[2] = x.dp[i]; +225 t2.used = 3; +226 \} while (mp_cmp_mag(&t1, &t2) == MP_GT); +227 +228 /* step 3.3 x = x - q\{i-t-1\} * y * b**\{i-t-1\} */ +229 if ((res = mp_mul_d (&y, q.dp[i - t - 1], &t1)) != MP_OKAY) \{ +230 goto LBL_Y; +231 \} +232 +233 if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) \{ +234 goto LBL_Y; +235 \} +236 +237 if ((res = mp_sub (&x, &t1, &x)) != MP_OKAY) \{ +238 goto LBL_Y; +239 \} +240 +241 /* if x < 0 then \{ x = x + y*b**\{i-t-1\}; q\{i-t-1\} -= 1; \} */ +242 if (x.sign == MP_NEG) \{ +243 if ((res = mp_copy (&y, &t1)) != MP_OKAY) \{ +244 goto LBL_Y; +245 \} +246 if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) \{ +247 goto LBL_Y; +248 \} +249 if ((res = mp_add (&x, &t1, &x)) != MP_OKAY) \{ +250 goto LBL_Y; +251 \} +252 +253 q.dp[i - t - 1] = (q.dp[i - t - 1] - 1UL) & MP_MASK; +254 \} +255 \} +256 +257 /* now q is the quotient and x is the remainder +258 * [which we have to normalize] +259 */ +260 +261 /* get sign before writing to c */ +262 x.sign = x.used == 0 ? MP_ZPOS : a->sign; +263 +264 if (c != NULL) \{ +265 mp_clamp (&q); +266 mp_exch (&q, c); +267 c->sign = neg; +268 \} +269 +270 if (d != NULL) \{ +271 mp_div_2d (&x, norm, &x, NULL); +272 mp_exch (&x, d); +273 \} +274 +275 res = MP_OKAY; +276 +277 LBL_Y:mp_clear (&y); +278 LBL_X:mp_clear (&x); +279 LBL_T2:mp_clear (&t2); +280 LBL_T1:mp_clear (&t1); +281 LBL_Q:mp_clear (&q); +282 return res; +283 \} +284 +285 #endif +286 +287 #endif +\end{alltt} +\end{small} + +The implementation of this algorithm differs slightly from the pseudo code presented previously. In this algorithm either of the quotient $c$ or +remainder $d$ may be passed as a \textbf{NULL} pointer which indicates their value is not desired. For example, the C code to call the division +algorithm with only the quotient is + +\begin{verbatim} +mp_div(&a, &b, &c, NULL); /* c = [a/b] */ +\end{verbatim} + +Lines 37 and 44 handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor +respectively. After the two trivial cases all of the temporary variables are initialized. Line 105 determines the sign of +the quotient and line 76 ensures that both $x$ and $y$ are positive. + +The number of bits in the leading digit is calculated on line 105. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits +of precision which when reduced modulo $lg(\beta)$ produces the value of $k$. In this case $k$ is the number of bits in the leading digit which is +exactly what is required. For the algorithm to operate $k$ must equal $lg(\beta) - 1$ and when it does not the inputs must be normalized by shifting +them to the left by $lg(\beta) - 1 - k$ bits. + +Throughout the variables $n$ and $t$ will represent the highest digit of $x$ and $y$ respectively. These are first used to produce the +leading digit of the quotient. The loop beginning on line 183 will produce the remainder of the quotient digits. + +The conditional ``continue'' on line 114 is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the +algorithm eliminates multiple non-zero digits in a single iteration. This ensures that $x_i$ is always non-zero since by definition the digits +above the $i$'th position $x$ must be zero in order for the quotient to be precise\footnote{Precise as far as integer division is concerned.}. + +Lines 130, 130 and 134 through 134 manually construct the high accuracy estimations by setting the digits of the two mp\_int +variables directly. + +\section{Single Digit Helpers} + +This section briefly describes a series of single digit helper algorithms which come in handy when working with small constants. All of +the helper functions assume the single digit input is positive and will treat them as such. + +\subsection{Single Digit Addition and Subtraction} + +Both addition and subtraction are performed by ``cheating'' and using mp\_set followed by the higher level addition or subtraction +algorithms. As a result these algorithms are subtantially simpler with a slight cost in performance. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_add\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = a + b$ \\ +\hline \\ +1. $t \leftarrow b$ (\textit{mp\_set}) \\ +2. $c \leftarrow a + t$ \\ +3. Return(\textit{MP\_OKAY}) \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_add\_d} +\end{figure} + +\textbf{Algorithm mp\_add\_d.} +This algorithm initiates a temporary mp\_int with the value of the single digit and uses algorithm mp\_add to add the two values together. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_add\_d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* single digit addition */ +018 int +019 mp_add_d (mp_int * a, mp_digit b, mp_int * c) +020 \{ +021 int res, ix, oldused; +022 mp_digit *tmpa, *tmpc, mu; +023 +024 /* grow c as required */ +025 if (c->alloc < a->used + 1) \{ +026 if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) \{ +027 return res; +028 \} +029 \} +030 +031 /* if a is negative and |a| >= b, call c = |a| - b */ +032 if (a->sign == MP_NEG && (a->used > 1 || a->dp[0] >= b)) \{ +033 /* temporarily fix sign of a */ +034 a->sign = MP_ZPOS; +035 +036 /* c = |a| - b */ +037 res = mp_sub_d(a, b, c); +038 +039 /* fix sign */ +040 a->sign = c->sign = MP_NEG; +041 +042 return res; +043 \} +044 +045 /* old number of used digits in c */ +046 oldused = c->used; +047 +048 /* sign always positive */ +049 c->sign = MP_ZPOS; +050 +051 /* source alias */ +052 tmpa = a->dp; +053 +054 /* destination alias */ +055 tmpc = c->dp; +056 +057 /* if a is positive */ +058 if (a->sign == MP_ZPOS) \{ +059 /* add digit, after this we're propagating +060 * the carry. +061 */ +062 *tmpc = *tmpa++ + b; +063 mu = *tmpc >> DIGIT_BIT; +064 *tmpc++ &= MP_MASK; +065 +066 /* now handle rest of the digits */ +067 for (ix = 1; ix < a->used; ix++) \{ +068 *tmpc = *tmpa++ + mu; +069 mu = *tmpc >> DIGIT_BIT; +070 *tmpc++ &= MP_MASK; +071 \} +072 /* set final carry */ +073 ix++; +074 *tmpc++ = mu; +075 +076 /* setup size */ +077 c->used = a->used + 1; +078 \} else \{ +079 /* a was negative and |a| < b */ +080 c->used = 1; +081 +082 /* the result is a single digit */ +083 if (a->used == 1) \{ +084 *tmpc++ = b - a->dp[0]; +085 \} else \{ +086 *tmpc++ = b; +087 \} +088 +089 /* setup count so the clearing of oldused +090 * can fall through correctly +091 */ +092 ix = 1; +093 \} +094 +095 /* now zero to oldused */ +096 while (ix++ < oldused) \{ +097 *tmpc++ = 0; +098 \} +099 mp_clamp(c); +100 +101 return MP_OKAY; +102 \} +103 +104 #endif +\end{alltt} +\end{small} + +Clever use of the letter 't'. + +\subsubsection{Subtraction} +The single digit subtraction algorithm mp\_sub\_d is essentially the same except it uses mp\_sub to subtract the digit from the mp\_int. + +\subsection{Single Digit Multiplication} +Single digit multiplication arises enough in division and radix conversion that it ought to be implement as a special case of the baseline +multiplication algorithm. Essentially this algorithm is a modified version of algorithm s\_mp\_mul\_digs where one of the multiplicands +only has one digit. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_mul\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = ab$ \\ +\hline \\ +1. $pa \leftarrow a.used$ \\ +2. Grow $c$ to at least $pa + 1$ digits. \\ +3. $oldused \leftarrow c.used$ \\ +4. $c.used \leftarrow pa + 1$ \\ +5. $c.sign \leftarrow a.sign$ \\ +6. $\mu \leftarrow 0$ \\ +7. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}7.1 $\hat r \leftarrow \mu + a_{ix}b$ \\ +\hspace{3mm}7.2 $c_{ix} \leftarrow \hat r \mbox{ (mod }\beta\mbox{)}$ \\ +\hspace{3mm}7.3 $\mu \leftarrow \lfloor \hat r / \beta \rfloor$ \\ +8. $c_{pa} \leftarrow \mu$ \\ +9. for $ix$ from $pa + 1$ to $oldused$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow 0$ \\ +10. Clamp excess digits of $c$. \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_mul\_d} +\end{figure} +\textbf{Algorithm mp\_mul\_d.} +This algorithm quickly multiplies an mp\_int by a small single digit value. It is specially tailored to the job and has a minimal of overhead. +Unlike the full multiplication algorithms this algorithm does not require any significnat temporary storage or memory allocations. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_d.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* multiply by a digit */ +018 int +019 mp_mul_d (mp_int * a, mp_digit b, mp_int * c) +020 \{ +021 mp_digit u, *tmpa, *tmpc; +022 mp_word r; +023 int ix, res, olduse; +024 +025 /* make sure c is big enough to hold a*b */ +026 if (c->alloc < a->used + 1) \{ +027 if ((res = mp_grow (c, a->used + 1)) != MP_OKAY) \{ +028 return res; +029 \} +030 \} +031 +032 /* get the original destinations used count */ +033 olduse = c->used; +034 +035 /* set the sign */ +036 c->sign = a->sign; +037 +038 /* alias for a->dp [source] */ +039 tmpa = a->dp; +040 +041 /* alias for c->dp [dest] */ +042 tmpc = c->dp; +043 +044 /* zero carry */ +045 u = 0; +046 +047 /* compute columns */ +048 for (ix = 0; ix < a->used; ix++) \{ +049 /* compute product and carry sum for this term */ +050 r = ((mp_word) u) + ((mp_word)*tmpa++) * ((mp_word)b); +051 +052 /* mask off higher bits to get a single digit */ +053 *tmpc++ = (mp_digit) (r & ((mp_word) MP_MASK)); +054 +055 /* send carry into next iteration */ +056 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); +057 \} +058 +059 /* store final carry [if any] */ +060 *tmpc++ = u; +061 +062 /* now zero digits above the top */ +063 while (ix++ < olduse) \{ +064 *tmpc++ = 0; +065 \} +066 +067 /* set used count */ +068 c->used = a->used + 1; +069 mp_clamp(c); +070 +071 return MP_OKAY; +072 \} +073 #endif +\end{alltt} +\end{small} + +In this implementation the destination $c$ may point to the same mp\_int as the source $a$ since the result is written after the digit is +read from the source. This function uses pointer aliases $tmpa$ and $tmpc$ for the digits of $a$ and $c$ respectively. + +\subsection{Single Digit Division} +Like the single digit multiplication algorithm, single digit division is also a fairly common algorithm used in radix conversion. Since the +divisor is only a single digit a specialized variant of the division algorithm can be used to compute the quotient. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_div\_d}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c = \lfloor a / b \rfloor, d = a - cb$ \\ +\hline \\ +1. If $b = 0$ then return(\textit{MP\_VAL}).\\ +2. If $b = 3$ then use algorithm mp\_div\_3 instead. \\ +3. Init $q$ to $a.used$ digits. \\ +4. $q.used \leftarrow a.used$ \\ +5. $q.sign \leftarrow a.sign$ \\ +6. $\hat w \leftarrow 0$ \\ +7. for $ix$ from $a.used - 1$ down to $0$ do \\ +\hspace{3mm}7.1 $\hat w \leftarrow \hat w \beta + a_{ix}$ \\ +\hspace{3mm}7.2 If $\hat w \ge b$ then \\ +\hspace{6mm}7.2.1 $t \leftarrow \lfloor \hat w / b \rfloor$ \\ +\hspace{6mm}7.2.2 $\hat w \leftarrow \hat w \mbox{ (mod }b\mbox{)}$ \\ +\hspace{3mm}7.3 else\\ +\hspace{6mm}7.3.1 $t \leftarrow 0$ \\ +\hspace{3mm}7.4 $q_{ix} \leftarrow t$ \\ +8. $d \leftarrow \hat w$ \\ +9. Clamp excess digits of $q$. \\ +10. $c \leftarrow q$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_div\_d} +\end{figure} +\textbf{Algorithm mp\_div\_d.} +This algorithm divides the mp\_int $a$ by the single mp\_digit $b$ using an optimized approach. Essentially in every iteration of the +algorithm another digit of the dividend is reduced and another digit of quotient produced. Provided $b < \beta$ the value of $\hat w$ +after step 7.1 will be limited such that $0 \le \lfloor \hat w / b \rfloor < \beta$. + +If the divisor $b$ is equal to three a variant of this algorithm is used which is called mp\_div\_3. It replaces the division by three with +a multiplication by $\lfloor \beta / 3 \rfloor$ and the appropriate shift and residual fixup. In essence it is much like the Barrett reduction +from chapter seven. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_div\_d.c +\vspace{-3mm} +\begin{alltt} +016 +017 static int s_is_power_of_two(mp_digit b, int *p) +018 \{ +019 int x; +020 +021 for (x = 1; x < DIGIT_BIT; x++) \{ +022 if (b == (((mp_digit)1)<dp[0] & ((((mp_digit)1)<used)) != MP_OKAY) \{ +074 return res; +075 \} +076 +077 q.used = a->used; +078 q.sign = a->sign; +079 w = 0; +080 for (ix = a->used - 1; ix >= 0; ix--) \{ +081 w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); +082 +083 if (w >= b) \{ +084 t = (mp_digit)(w / b); +085 w -= ((mp_word)t) * ((mp_word)b); +086 \} else \{ +087 t = 0; +088 \} +089 q.dp[ix] = (mp_digit)t; +090 \} +091 +092 if (d != NULL) \{ +093 *d = (mp_digit)w; +094 \} +095 +096 if (c != NULL) \{ +097 mp_clamp(&q); +098 mp_exch(&q, c); +099 \} +100 mp_clear(&q); +101 +102 return res; +103 \} +104 +105 #endif +\end{alltt} +\end{small} + +Like the implementation of algorithm mp\_div this algorithm allows either of the quotient or remainder to be passed as a \textbf{NULL} pointer to +indicate the respective value is not required. This allows a trivial single digit modular reduction algorithm, mp\_mod\_d to be created. + +The division and remainder on lines 43 and @45,%@ can be replaced often by a single division on most processors. For example, the 32-bit x86 based +processors can divide a 64-bit quantity by a 32-bit quantity and produce the quotient and remainder simultaneously. Unfortunately the GCC +compiler does not recognize that optimization and will actually produce two function calls to find the quotient and remainder respectively. + +\subsection{Single Digit Root Extraction} + +Finding the $n$'th root of an integer is fairly easy as far as numerical analysis is concerned. Algorithms such as the Newton-Raphson approximation +(\ref{eqn:newton}) series will converge very quickly to a root for any continuous function $f(x)$. + +\begin{equation} +x_{i+1} = x_i - {f(x_i) \over f'(x_i)} +\label{eqn:newton} +\end{equation} + +In this case the $n$'th root is desired and $f(x) = x^n - a$ where $a$ is the integer of which the root is desired. The derivative of $f(x)$ is +simply $f'(x) = nx^{n - 1}$. Of particular importance is that this algorithm will be used over the integers not over the a more continuous domain +such as the real numbers. As a result the root found can be above the true root by few and must be manually adjusted. Ideally at the end of the +algorithm the $n$'th root $b$ of an integer $a$ is desired such that $b^n \le a$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_n\_root}. \\ +\textbf{Input}. mp\_int $a$ and a mp\_digit $b$ \\ +\textbf{Output}. $c^b \le a$ \\ +\hline \\ +1. If $b$ is even and $a.sign = MP\_NEG$ return(\textit{MP\_VAL}). \\ +2. $sign \leftarrow a.sign$ \\ +3. $a.sign \leftarrow MP\_ZPOS$ \\ +4. t$2 \leftarrow 2$ \\ +5. Loop \\ +\hspace{3mm}5.1 t$1 \leftarrow $ t$2$ \\ +\hspace{3mm}5.2 t$3 \leftarrow $ t$1^{b - 1}$ \\ +\hspace{3mm}5.3 t$2 \leftarrow $ t$3 $ $\cdot$ t$1$ \\ +\hspace{3mm}5.4 t$2 \leftarrow $ t$2 - a$ \\ +\hspace{3mm}5.5 t$3 \leftarrow $ t$3 \cdot b$ \\ +\hspace{3mm}5.6 t$3 \leftarrow \lfloor $t$2 / $t$3 \rfloor$ \\ +\hspace{3mm}5.7 t$2 \leftarrow $ t$1 - $ t$3$ \\ +\hspace{3mm}5.8 If t$1 \ne $ t$2$ then goto step 5. \\ +6. Loop \\ +\hspace{3mm}6.1 t$2 \leftarrow $ t$1^b$ \\ +\hspace{3mm}6.2 If t$2 > a$ then \\ +\hspace{6mm}6.2.1 t$1 \leftarrow $ t$1 - 1$ \\ +\hspace{6mm}6.2.2 Goto step 6. \\ +7. $a.sign \leftarrow sign$ \\ +8. $c \leftarrow $ t$1$ \\ +9. $c.sign \leftarrow sign$ \\ +10. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_n\_root} +\end{figure} +\textbf{Algorithm mp\_n\_root.} +This algorithm finds the integer $n$'th root of an input using the Newton-Raphson approach. It is partially optimized based on the observation +that the numerator of ${f(x) \over f'(x)}$ can be derived from a partial denominator. That is at first the denominator is calculated by finding +$x^{b - 1}$. This value can then be multiplied by $x$ and have $a$ subtracted from it to find the numerator. This saves a total of $b - 1$ +multiplications by t$1$ inside the loop. + +The initial value of the approximation is t$2 = 2$ which allows the algorithm to start with very small values and quickly converge on the +root. Ideally this algorithm is meant to find the $n$'th root of an input where $n$ is bounded by $2 \le n \le 5$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_n\_root.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* find the n'th root of an integer +018 * +019 * Result found such that (c)**b <= a and (c+1)**b > a +020 * +021 * This algorithm uses Newton's approximation +022 * x[i+1] = x[i] - f(x[i])/f'(x[i]) +023 * which will find the root in log(N) time where +024 * each step involves a fair bit. This is not meant to +025 * find huge roots [square and cube, etc]. +026 */ +027 int mp_n_root (mp_int * a, mp_digit b, mp_int * c) +028 \{ +029 mp_int t1, t2, t3; +030 int res, neg; +031 +032 /* input must be positive if b is even */ +033 if ((b & 1) == 0 && a->sign == MP_NEG) \{ +034 return MP_VAL; +035 \} +036 +037 if ((res = mp_init (&t1)) != MP_OKAY) \{ +038 return res; +039 \} +040 +041 if ((res = mp_init (&t2)) != MP_OKAY) \{ +042 goto LBL_T1; +043 \} +044 +045 if ((res = mp_init (&t3)) != MP_OKAY) \{ +046 goto LBL_T2; +047 \} +048 +049 /* if a is negative fudge the sign but keep track */ +050 neg = a->sign; +051 a->sign = MP_ZPOS; +052 +053 /* t2 = 2 */ +054 mp_set (&t2, 2); +055 +056 do \{ +057 /* t1 = t2 */ +058 if ((res = mp_copy (&t2, &t1)) != MP_OKAY) \{ +059 goto LBL_T3; +060 \} +061 +062 /* t2 = t1 - ((t1**b - a) / (b * t1**(b-1))) */ +063 +064 /* t3 = t1**(b-1) */ +065 if ((res = mp_expt_d (&t1, b - 1, &t3)) != MP_OKAY) \{ +066 goto LBL_T3; +067 \} +068 +069 /* numerator */ +070 /* t2 = t1**b */ +071 if ((res = mp_mul (&t3, &t1, &t2)) != MP_OKAY) \{ +072 goto LBL_T3; +073 \} +074 +075 /* t2 = t1**b - a */ +076 if ((res = mp_sub (&t2, a, &t2)) != MP_OKAY) \{ +077 goto LBL_T3; +078 \} +079 +080 /* denominator */ +081 /* t3 = t1**(b-1) * b */ +082 if ((res = mp_mul_d (&t3, b, &t3)) != MP_OKAY) \{ +083 goto LBL_T3; +084 \} +085 +086 /* t3 = (t1**b - a)/(b * t1**(b-1)) */ +087 if ((res = mp_div (&t2, &t3, &t3, NULL)) != MP_OKAY) \{ +088 goto LBL_T3; +089 \} +090 +091 if ((res = mp_sub (&t1, &t3, &t2)) != MP_OKAY) \{ +092 goto LBL_T3; +093 \} +094 \} while (mp_cmp (&t1, &t2) != MP_EQ); +095 +096 /* result can be off by a few so check */ +097 for (;;) \{ +098 if ((res = mp_expt_d (&t1, b, &t2)) != MP_OKAY) \{ +099 goto LBL_T3; +100 \} +101 +102 if (mp_cmp (&t2, a) == MP_GT) \{ +103 if ((res = mp_sub_d (&t1, 1, &t1)) != MP_OKAY) \{ +104 goto LBL_T3; +105 \} +106 \} else \{ +107 break; +108 \} +109 \} +110 +111 /* reset the sign of a first */ +112 a->sign = neg; +113 +114 /* set the result */ +115 mp_exch (&t1, c); +116 +117 /* set the sign of the result */ +118 c->sign = neg; +119 +120 res = MP_OKAY; +121 +122 LBL_T3:mp_clear (&t3); +123 LBL_T2:mp_clear (&t2); +124 LBL_T1:mp_clear (&t1); +125 return res; +126 \} +127 #endif +\end{alltt} +\end{small} + +\section{Random Number Generation} + +Random numbers come up in a variety of activities from public key cryptography to simple simulations and various randomized algorithms. Pollard-Rho +factoring for example, can make use of random values as starting points to find factors of a composite integer. In this case the algorithm presented +is solely for simulations and not intended for cryptographic use. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_rand}. \\ +\textbf{Input}. An integer $b$ \\ +\textbf{Output}. A pseudo-random number of $b$ digits \\ +\hline \\ +1. $a \leftarrow 0$ \\ +2. If $b \le 0$ return(\textit{MP\_OKAY}) \\ +3. Pick a non-zero random digit $d$. \\ +4. $a \leftarrow a + d$ \\ +5. for $ix$ from 1 to $d - 1$ do \\ +\hspace{3mm}5.1 $a \leftarrow a \cdot \beta$ \\ +\hspace{3mm}5.2 Pick a random digit $d$. \\ +\hspace{3mm}5.3 $a \leftarrow a + d$ \\ +6. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_rand} +\end{figure} +\textbf{Algorithm mp\_rand.} +This algorithm produces a pseudo-random integer of $b$ digits. By ensuring that the first digit is non-zero the algorithm also guarantees that the +final result has at least $b$ digits. It relies heavily on a third-part random number generator which should ideally generate uniformly all of +the integers from $0$ to $\beta - 1$. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_rand.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* makes a pseudo-random int of a given size */ +018 int +019 mp_rand (mp_int * a, int digits) +020 \{ +021 int res; +022 mp_digit d; +023 +024 mp_zero (a); +025 if (digits <= 0) \{ +026 return MP_OKAY; +027 \} +028 +029 /* first place a random non-zero digit */ +030 do \{ +031 d = ((mp_digit) abs (rand ())); +032 \} while (d == 0); +033 +034 if ((res = mp_add_d (a, d, a)) != MP_OKAY) \{ +035 return res; +036 \} +037 +038 while (digits-- > 0) \{ +039 if ((res = mp_lshd (a, 1)) != MP_OKAY) \{ +040 return res; +041 \} +042 +043 if ((res = mp_add_d (a, ((mp_digit) abs (rand ())), a)) != MP_OKAY) \{ +044 return res; +045 \} +046 \} +047 +048 return MP_OKAY; +049 \} +050 #endif +\end{alltt} +\end{small} + +\section{Formatted Representations} +The ability to emit a radix-$n$ textual representation of an integer is useful for interacting with human parties. For example, the ability to +be given a string of characters such as ``114585'' and turn it into the radix-$\beta$ equivalent would make it easier to enter numbers +into a program. + +\subsection{Reading Radix-n Input} +For the purposes of this text we will assume that a simple lower ASCII map (\ref{fig:ASC}) is used for the values of from $0$ to $63$ to +printable characters. For example, when the character ``N'' is read it represents the integer $23$. The first $16$ characters of the +map are for the common representations up to hexadecimal. After that they match the ``base64'' encoding scheme which are suitable chosen +such that they are printable. While outputting as base64 may not be too helpful for human operators it does allow communication via non binary +mediums. + +\newpage\begin{figure}[here] +\begin{center} +\begin{tabular}{cc|cc|cc|cc} +\hline \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} & \textbf{Value} & \textbf{Char} \\ +\hline +0 & 0 & 1 & 1 & 2 & 2 & 3 & 3 \\ +4 & 4 & 5 & 5 & 6 & 6 & 7 & 7 \\ +8 & 8 & 9 & 9 & 10 & A & 11 & B \\ +12 & C & 13 & D & 14 & E & 15 & F \\ +16 & G & 17 & H & 18 & I & 19 & J \\ +20 & K & 21 & L & 22 & M & 23 & N \\ +24 & O & 25 & P & 26 & Q & 27 & R \\ +28 & S & 29 & T & 30 & U & 31 & V \\ +32 & W & 33 & X & 34 & Y & 35 & Z \\ +36 & a & 37 & b & 38 & c & 39 & d \\ +40 & e & 41 & f & 42 & g & 43 & h \\ +44 & i & 45 & j & 46 & k & 47 & l \\ +48 & m & 49 & n & 50 & o & 51 & p \\ +52 & q & 53 & r & 54 & s & 55 & t \\ +56 & u & 57 & v & 58 & w & 59 & x \\ +60 & y & 61 & z & 62 & $+$ & 63 & $/$ \\ +\hline +\end{tabular} +\end{center} +\caption{Lower ASCII Map} +\label{fig:ASC} +\end{figure} + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_read\_radix}. \\ +\textbf{Input}. A string $str$ of length $sn$ and radix $r$. \\ +\textbf{Output}. The radix-$\beta$ equivalent mp\_int. \\ +\hline \\ +1. If $r < 2$ or $r > 64$ return(\textit{MP\_VAL}). \\ +2. $ix \leftarrow 0$ \\ +3. If $str_0 =$ ``-'' then do \\ +\hspace{3mm}3.1 $ix \leftarrow ix + 1$ \\ +\hspace{3mm}3.2 $sign \leftarrow MP\_NEG$ \\ +4. else \\ +\hspace{3mm}4.1 $sign \leftarrow MP\_ZPOS$ \\ +5. $a \leftarrow 0$ \\ +6. for $iy$ from $ix$ to $sn - 1$ do \\ +\hspace{3mm}6.1 Let $y$ denote the position in the map of $str_{iy}$. \\ +\hspace{3mm}6.2 If $str_{iy}$ is not in the map or $y \ge r$ then goto step 7. \\ +\hspace{3mm}6.3 $a \leftarrow a \cdot r$ \\ +\hspace{3mm}6.4 $a \leftarrow a + y$ \\ +7. If $a \ne 0$ then $a.sign \leftarrow sign$ \\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_read\_radix} +\end{figure} +\textbf{Algorithm mp\_read\_radix.} +This algorithm will read an ASCII string and produce the radix-$\beta$ mp\_int representation of the same integer. A minus symbol ``-'' may precede the +string to indicate the value is negative, otherwise it is assumed to be positive. The algorithm will read up to $sn$ characters from the input +and will stop when it reads a character it cannot map the algorithm stops reading characters from the string. This allows numbers to be embedded +as part of larger input without any significant problem. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_read\_radix.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* read a string [ASCII] in a given radix */ +018 int mp_read_radix (mp_int * a, char *str, int radix) +019 \{ +020 int y, res, neg; +021 char ch; +022 +023 /* make sure the radix is ok */ +024 if (radix < 2 || radix > 64) \{ +025 return MP_VAL; +026 \} +027 +028 /* if the leading digit is a +029 * minus set the sign to negative. +030 */ +031 if (*str == '-') \{ +032 ++str; +033 neg = MP_NEG; +034 \} else \{ +035 neg = MP_ZPOS; +036 \} +037 +038 /* set the integer to the default of zero */ +039 mp_zero (a); +040 +041 /* process each digit of the string */ +042 while (*str) \{ +043 /* if the radix < 36 the conversion is case insensitive +044 * this allows numbers like 1AB and 1ab to represent the same value +045 * [e.g. in hex] +046 */ +047 ch = (char) ((radix < 36) ? toupper (*str) : *str); +048 for (y = 0; y < 64; y++) \{ +049 if (ch == mp_s_rmap[y]) \{ +050 break; +051 \} +052 \} +053 +054 /* if the char was found in the map +055 * and is less than the given radix add it +056 * to the number, otherwise exit the loop. +057 */ +058 if (y < radix) \{ +059 if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) \{ +060 return res; +061 \} +062 if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) \{ +063 return res; +064 \} +065 \} else \{ +066 break; +067 \} +068 ++str; +069 \} +070 +071 /* set the sign only if a != 0 */ +072 if (mp_iszero(a) != 1) \{ +073 a->sign = neg; +074 \} +075 return MP_OKAY; +076 \} +077 #endif +\end{alltt} +\end{small} + +\subsection{Generating Radix-$n$ Output} +Generating radix-$n$ output is fairly trivial with a division and remainder algorithm. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_toradix}. \\ +\textbf{Input}. A mp\_int $a$ and an integer $r$\\ +\textbf{Output}. The radix-$r$ representation of $a$ \\ +\hline \\ +1. If $r < 2$ or $r > 64$ return(\textit{MP\_VAL}). \\ +2. If $a = 0$ then $str = $ ``$0$'' and return(\textit{MP\_OKAY}). \\ +3. $t \leftarrow a$ \\ +4. $str \leftarrow$ ``'' \\ +5. if $t.sign = MP\_NEG$ then \\ +\hspace{3mm}5.1 $str \leftarrow str + $ ``-'' \\ +\hspace{3mm}5.2 $t.sign = MP\_ZPOS$ \\ +6. While ($t \ne 0$) do \\ +\hspace{3mm}6.1 $d \leftarrow t \mbox{ (mod }r\mbox{)}$ \\ +\hspace{3mm}6.2 $t \leftarrow \lfloor t / r \rfloor$ \\ +\hspace{3mm}6.3 Look up $d$ in the map and store the equivalent character in $y$. \\ +\hspace{3mm}6.4 $str \leftarrow str + y$ \\ +7. If $str_0 = $``$-$'' then \\ +\hspace{3mm}7.1 Reverse the digits $str_1, str_2, \ldots str_n$. \\ +8. Otherwise \\ +\hspace{3mm}8.1 Reverse the digits $str_0, str_1, \ldots str_n$. \\ +9. Return(\textit{MP\_OKAY}).\\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_toradix} +\end{figure} +\textbf{Algorithm mp\_toradix.} +This algorithm computes the radix-$r$ representation of an mp\_int $a$. The ``digits'' of the representation are extracted by reducing +successive powers of $\lfloor a / r^k \rfloor$ the input modulo $r$ until $r^k > a$. Note that instead of actually dividing by $r^k$ in +each iteration the quotient $\lfloor a / r \rfloor$ is saved for the next iteration. As a result a series of trivial $n \times 1$ divisions +are required instead of a series of $n \times k$ divisions. One design flaw of this approach is that the digits are produced in the reverse order +(see~\ref{fig:mpradix}). To remedy this flaw the digits must be swapped or simply ``reversed''. + +\begin{figure} +\begin{center} +\begin{tabular}{|c|c|c|} +\hline \textbf{Value of $a$} & \textbf{Value of $d$} & \textbf{Value of $str$} \\ +\hline $1234$ & -- & -- \\ +\hline $123$ & $4$ & ``4'' \\ +\hline $12$ & $3$ & ``43'' \\ +\hline $1$ & $2$ & ``432'' \\ +\hline $0$ & $1$ & ``4321'' \\ +\hline +\end{tabular} +\end{center} +\caption{Example of Algorithm mp\_toradix.} +\label{fig:mpradix} +\end{figure} + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_toradix.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* stores a bignum as a ASCII string in a given radix (2..64) */ +018 int mp_toradix (mp_int * a, char *str, int radix) +019 \{ +020 int res, digs; +021 mp_int t; +022 mp_digit d; +023 char *_s = str; +024 +025 /* check range of the radix */ +026 if (radix < 2 || radix > 64) \{ +027 return MP_VAL; +028 \} +029 +030 /* quick out if its zero */ +031 if (mp_iszero(a) == 1) \{ +032 *str++ = '0'; +033 *str = '\symbol{92}0'; +034 return MP_OKAY; +035 \} +036 +037 if ((res = mp_init_copy (&t, a)) != MP_OKAY) \{ +038 return res; +039 \} +040 +041 /* if it is negative output a - */ +042 if (t.sign == MP_NEG) \{ +043 ++_s; +044 *str++ = '-'; +045 t.sign = MP_ZPOS; +046 \} +047 +048 digs = 0; +049 while (mp_iszero (&t) == 0) \{ +050 if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) \{ +051 mp_clear (&t); +052 return res; +053 \} +054 *str++ = mp_s_rmap[d]; +055 ++digs; +056 \} +057 +058 /* reverse the digits of the string. In this case _s points +059 * to the first digit [exluding the sign] of the number] +060 */ +061 bn_reverse ((unsigned char *)_s, digs); +062 +063 /* append a NULL so the string is properly terminated */ +064 *str = '\symbol{92}0'; +065 +066 mp_clear (&t); +067 return MP_OKAY; +068 \} +069 +070 #endif +\end{alltt} +\end{small} + +\chapter{Number Theoretic Algorithms} +This chapter discusses several fundamental number theoretic algorithms such as the greatest common divisor, least common multiple and Jacobi +symbol computation. These algorithms arise as essential components in several key cryptographic algorithms such as the RSA public key algorithm and +various Sieve based factoring algorithms. + +\section{Greatest Common Divisor} +The greatest common divisor of two integers $a$ and $b$, often denoted as $(a, b)$ is the largest integer $k$ that is a proper divisor of +both $a$ and $b$. That is, $k$ is the largest integer such that $0 \equiv a \mbox{ (mod }k\mbox{)}$ and $0 \equiv b \mbox{ (mod }k\mbox{)}$ occur +simultaneously. + +The most common approach (cite) is to reduce one input modulo another. That is if $a$ and $b$ are divisible by some integer $k$ and if $qa + r = b$ then +$r$ is also divisible by $k$. The reduction pattern follows $\left < a , b \right > \rightarrow \left < b, a \mbox{ mod } b \right >$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (I)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. While ($b > 0$) do \\ +\hspace{3mm}1.1 $r \leftarrow a \mbox{ (mod }b\mbox{)}$ \\ +\hspace{3mm}1.2 $a \leftarrow b$ \\ +\hspace{3mm}1.3 $b \leftarrow r$ \\ +2. Return($a$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (I)} +\label{fig:gcd1} +\end{figure} + +This algorithm will quickly converge on the greatest common divisor since the residue $r$ tends diminish rapidly. However, divisions are +relatively expensive operations to perform and should ideally be avoided. There is another approach based on a similar relationship of +greatest common divisors. The faster approach is based on the observation that if $k$ divides both $a$ and $b$ it will also divide $a - b$. +In particular, we would like $a - b$ to decrease in magnitude which implies that $b \ge a$. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (II)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. While ($b > 0$) do \\ +\hspace{3mm}1.1 Swap $a$ and $b$ such that $a$ is the smallest of the two. \\ +\hspace{3mm}1.2 $b \leftarrow b - a$ \\ +2. Return($a$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (II)} +\label{fig:gcd2} +\end{figure} + +\textbf{Proof} \textit{Algorithm~\ref{fig:gcd2} will return the greatest common divisor of $a$ and $b$.} +The algorithm in figure~\ref{fig:gcd2} will eventually terminate since $b \ge a$ the subtraction in step 1.2 will be a value less than $b$. In other +words in every iteration that tuple $\left < a, b \right >$ decrease in magnitude until eventually $a = b$. Since both $a$ and $b$ are always +divisible by the greatest common divisor (\textit{until the last iteration}) and in the last iteration of the algorithm $b = 0$, therefore, in the +second to last iteration of the algorithm $b = a$ and clearly $(a, a) = a$ which concludes the proof. \textbf{QED}. + +As a matter of practicality algorithm \ref{fig:gcd1} decreases far too slowly to be useful. Specially if $b$ is much larger than $a$ such that +$b - a$ is still very much larger than $a$. A simple addition to the algorithm is to divide $b - a$ by a power of some integer $p$ which does +not divide the greatest common divisor but will divide $b - a$. In this case ${b - a} \over p$ is also an integer and still divisible by +the greatest common divisor. + +However, instead of factoring $b - a$ to find a suitable value of $p$ the powers of $p$ can be removed from $a$ and $b$ that are in common first. +Then inside the loop whenever $b - a$ is divisible by some power of $p$ it can be safely removed. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{Greatest Common Divisor (III)}. \\ +\textbf{Input}. Two positive integers $a$ and $b$ greater than zero. \\ +\textbf{Output}. The greatest common divisor $(a, b)$. \\ +\hline \\ +1. $k \leftarrow 0$ \\ +2. While $a$ and $b$ are both divisible by $p$ do \\ +\hspace{3mm}2.1 $a \leftarrow \lfloor a / p \rfloor$ \\ +\hspace{3mm}2.2 $b \leftarrow \lfloor b / p \rfloor$ \\ +\hspace{3mm}2.3 $k \leftarrow k + 1$ \\ +3. While $a$ is divisible by $p$ do \\ +\hspace{3mm}3.1 $a \leftarrow \lfloor a / p \rfloor$ \\ +4. While $b$ is divisible by $p$ do \\ +\hspace{3mm}4.1 $b \leftarrow \lfloor b / p \rfloor$ \\ +5. While ($b > 0$) do \\ +\hspace{3mm}5.1 Swap $a$ and $b$ such that $a$ is the smallest of the two. \\ +\hspace{3mm}5.2 $b \leftarrow b - a$ \\ +\hspace{3mm}5.3 While $b$ is divisible by $p$ do \\ +\hspace{6mm}5.3.1 $b \leftarrow \lfloor b / p \rfloor$ \\ +6. Return($a \cdot p^k$). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm Greatest Common Divisor (III)} +\label{fig:gcd3} +\end{figure} + +This algorithm is based on the first except it removes powers of $p$ first and inside the main loop to ensure the tuple $\left < a, b \right >$ +decreases more rapidly. The first loop on step two removes powers of $p$ that are in common. A count, $k$, is kept which will present a common +divisor of $p^k$. After step two the remaining common divisor of $a$ and $b$ cannot be divisible by $p$. This means that $p$ can be safely +divided out of the difference $b - a$ so long as the division leaves no remainder. + +In particular the value of $p$ should be chosen such that the division on step 5.3.1 occur often. It also helps that division by $p$ be easy +to compute. The ideal choice of $p$ is two since division by two amounts to a right logical shift. Another important observation is that by +step five both $a$ and $b$ are odd. Therefore, the diffrence $b - a$ must be even which means that each iteration removes one bit from the +largest of the pair. + +\subsection{Complete Greatest Common Divisor} +The algorithms presented so far cannot handle inputs which are zero or negative. The following algorithm can handle all input cases properly +and will produce the greatest common divisor. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_gcd}. \\ +\textbf{Input}. mp\_int $a$ and $b$ \\ +\textbf{Output}. The greatest common divisor $c = (a, b)$. \\ +\hline \\ +1. If $a = 0$ and $b \ne 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow b$ \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $a \ne 0$ and $b = 0$ then \\ +\hspace{3mm}2.1 $c \leftarrow a$ \\ +\hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ +3. If $a = b = 0$ then \\ +\hspace{3mm}3.1 $c \leftarrow 1$ \\ +\hspace{3mm}3.2 Return(\textit{MP\_OKAY}). \\ +4. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ +5. $k \leftarrow 0$ \\ +6. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}6.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}6.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +7. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +8. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}8.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +9. While $v.used > 0$ \\ +\hspace{3mm}9.1 If $\vert u \vert > \vert v \vert$ then \\ +\hspace{6mm}9.1.1 Swap $u$ and $v$. \\ +\hspace{3mm}9.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ +\hspace{3mm}9.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{6mm}9.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +10. $c \leftarrow u \cdot 2^k$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_gcd} +\end{figure} +\textbf{Algorithm mp\_gcd.} +This algorithm will produce the greatest common divisor of two mp\_ints $a$ and $b$. The algorithm was originally based on Algorithm B of +Knuth \cite[pp. 338]{TAOCPV2} but has been modified to be simpler to explain. In theory it achieves the same asymptotic working time as +Algorithm B and in practice this appears to be true. + +The first three steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the +largest input or zero if they are both zero. If the inputs are not trivial than $u$ and $v$ are assigned the absolute values of +$a$ and $b$ respectively and the algorithm will proceed to reduce the pair. + +Step six will divide out any common factors of two and keep track of the count in the variable $k$. After this step two is no longer a +factor of the remaining greatest common divisor between $u$ and $v$ and can be safely evenly divided out of either whenever they are even. Step +seven and eight ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while loops will iterate since +they cannot both be even. + +By step nine both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to +or greater than $u$. This ensures that the subtraction on step 9.2 will always produce a positive and even result. Step 9.3 removes any +factors of two from the difference $u$ to ensure that in the next iteration of the loop both are once again odd. + +After $v = 0$ occurs the variable $u$ has the greatest common divisor of the pair $\left < u, v \right >$ just after step six. The result +must be adjusted by multiplying by the common factors of two ($2^k$) removed earlier. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_gcd.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* Greatest Common Divisor using the binary method */ +018 int mp_gcd (mp_int * a, mp_int * b, mp_int * c) +019 \{ +020 mp_int u, v; +021 int k, u_lsb, v_lsb, res; +022 +023 /* either zero than gcd is the largest */ +024 if (mp_iszero (a) == 1 && mp_iszero (b) == 0) \{ +025 return mp_abs (b, c); +026 \} +027 if (mp_iszero (a) == 0 && mp_iszero (b) == 1) \{ +028 return mp_abs (a, c); +029 \} +030 +031 /* optimized. At this point if a == 0 then +032 * b must equal zero too +033 */ +034 if (mp_iszero (a) == 1) \{ +035 mp_zero(c); +036 return MP_OKAY; +037 \} +038 +039 /* get copies of a and b we can modify */ +040 if ((res = mp_init_copy (&u, a)) != MP_OKAY) \{ +041 return res; +042 \} +043 +044 if ((res = mp_init_copy (&v, b)) != MP_OKAY) \{ +045 goto LBL_U; +046 \} +047 +048 /* must be positive for the remainder of the algorithm */ +049 u.sign = v.sign = MP_ZPOS; +050 +051 /* B1. Find the common power of two for u and v */ +052 u_lsb = mp_cnt_lsb(&u); +053 v_lsb = mp_cnt_lsb(&v); +054 k = MIN(u_lsb, v_lsb); +055 +056 if (k > 0) \{ +057 /* divide the power of two out */ +058 if ((res = mp_div_2d(&u, k, &u, NULL)) != MP_OKAY) \{ +059 goto LBL_V; +060 \} +061 +062 if ((res = mp_div_2d(&v, k, &v, NULL)) != MP_OKAY) \{ +063 goto LBL_V; +064 \} +065 \} +066 +067 /* divide any remaining factors of two out */ +068 if (u_lsb != k) \{ +069 if ((res = mp_div_2d(&u, u_lsb - k, &u, NULL)) != MP_OKAY) \{ +070 goto LBL_V; +071 \} +072 \} +073 +074 if (v_lsb != k) \{ +075 if ((res = mp_div_2d(&v, v_lsb - k, &v, NULL)) != MP_OKAY) \{ +076 goto LBL_V; +077 \} +078 \} +079 +080 while (mp_iszero(&v) == 0) \{ +081 /* make sure v is the largest */ +082 if (mp_cmp_mag(&u, &v) == MP_GT) \{ +083 /* swap u and v to make sure v is >= u */ +084 mp_exch(&u, &v); +085 \} +086 +087 /* subtract smallest from largest */ +088 if ((res = s_mp_sub(&v, &u, &v)) != MP_OKAY) \{ +089 goto LBL_V; +090 \} +091 +092 /* Divide out all factors of two */ +093 if ((res = mp_div_2d(&v, mp_cnt_lsb(&v), &v, NULL)) != MP_OKAY) \{ +094 goto LBL_V; +095 \} +096 \} +097 +098 /* multiply by 2**k which we divided out at the beginning */ +099 if ((res = mp_mul_2d (&u, k, c)) != MP_OKAY) \{ +100 goto LBL_V; +101 \} +102 c->sign = MP_ZPOS; +103 res = MP_OKAY; +104 LBL_V:mp_clear (&u); +105 LBL_U:mp_clear (&v); +106 return res; +107 \} +108 #endif +\end{alltt} +\end{small} + +This function makes use of the macros mp\_iszero and mp\_iseven. The former evaluates to $1$ if the input mp\_int is equivalent to the +integer zero otherwise it evaluates to $0$. The latter evaluates to $1$ if the input mp\_int represents a non-zero even integer otherwise +it evaluates to $0$. Note that just because mp\_iseven may evaluate to $0$ does not mean the input is odd, it could also be zero. The three +trivial cases of inputs are handled on lines 24 through 37. After those lines the inputs are assumed to be non-zero. + +Lines 34 and 40 make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two +must be divided out of the two inputs. The while loop on line 80 iterates so long as both are even. The local integer $k$ is used to +keep track of how many factors of $2$ are pulled out of both values. It is assumed that the number of factors will not exceed the maximum +value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than entries than are accessible by an ``int'' so this is not +a limitation.}. + +At this point there are no more common factors of two in the two values. The while loops on lines 80 and 80 remove any independent +factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop +on line 80 performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in +place of the full signed routines since both values are guaranteed to be positive and the result of the subtraction is guaranteed to be non-negative. + +\section{Least Common Multiple} +The least common multiple of a pair of integers is their product divided by their greatest common divisor. For two integers $a$ and $b$ the +least common multiple is normally denoted as $[ a, b ]$ and numerically equivalent to ${ab} \over {(a, b)}$. For example, if $a = 2 \cdot 2 \cdot 3 = 12$ +and $b = 2 \cdot 3 \cdot 3 \cdot 7 = 126$ the least common multiple is ${126 \over {(12, 126)}} = {126 \over 6} = 21$. + +The least common multiple arises often in coding theory as well as number theory. If two functions have periods of $a$ and $b$ respectively they will +collide, that is be in synchronous states, after only $[ a, b ]$ iterations. This is why, for example, random number generators based on +Linear Feedback Shift Registers (LFSR) tend to use registers with periods which are co-prime (\textit{e.g. the greatest common divisor is one.}). +Similarly in number theory if a composite $n$ has two prime factors $p$ and $q$ then maximal order of any unit of $\Z/n\Z$ will be $[ p - 1, q - 1] $. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_lcm}. \\ +\textbf{Input}. mp\_int $a$ and $b$ \\ +\textbf{Output}. The least common multiple $c = [a, b]$. \\ +\hline \\ +1. $c \leftarrow (a, b)$ \\ +2. $t \leftarrow a \cdot b$ \\ +3. $c \leftarrow \lfloor t / c \rfloor$ \\ +4. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_lcm} +\end{figure} +\textbf{Algorithm mp\_lcm.} +This algorithm computes the least common multiple of two mp\_int inputs $a$ and $b$. It computes the least common multiple directly by +dividing the product of the two inputs by their greatest common divisor. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_lcm.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* computes least common multiple as |a*b|/(a, b) */ +018 int mp_lcm (mp_int * a, mp_int * b, mp_int * c) +019 \{ +020 int res; +021 mp_int t1, t2; +022 +023 +024 if ((res = mp_init_multi (&t1, &t2, NULL)) != MP_OKAY) \{ +025 return res; +026 \} +027 +028 /* t1 = get the GCD of the two inputs */ +029 if ((res = mp_gcd (a, b, &t1)) != MP_OKAY) \{ +030 goto LBL_T; +031 \} +032 +033 /* divide the smallest by the GCD */ +034 if (mp_cmp_mag(a, b) == MP_LT) \{ +035 /* store quotient in t2 such that t2 * b is the LCM */ +036 if ((res = mp_div(a, &t1, &t2, NULL)) != MP_OKAY) \{ +037 goto LBL_T; +038 \} +039 res = mp_mul(b, &t2, c); +040 \} else \{ +041 /* store quotient in t2 such that t2 * a is the LCM */ +042 if ((res = mp_div(b, &t1, &t2, NULL)) != MP_OKAY) \{ +043 goto LBL_T; +044 \} +045 res = mp_mul(a, &t2, c); +046 \} +047 +048 /* fix the sign to positive */ +049 c->sign = MP_ZPOS; +050 +051 LBL_T: +052 mp_clear_multi (&t1, &t2, NULL); +053 return res; +054 \} +055 #endif +\end{alltt} +\end{small} + +\section{Jacobi Symbol Computation} +To explain the Jacobi Symbol we shall first discuss the Legendre function\footnote{Arrg. What is the name of this?} off which the Jacobi symbol is +defined. The Legendre function computes whether or not an integer $a$ is a quadratic residue modulo an odd prime $p$. Numerically it is +equivalent to equation \ref{eqn:legendre}. + +\begin{equation} +a^{(p-1)/2} \equiv \begin{array}{rl} + -1 & \mbox{if }a\mbox{ is a quadratic non-residue.} \\ + 0 & \mbox{if }a\mbox{ divides }p\mbox{.} \\ + 1 & \mbox{if }a\mbox{ is a quadratic residue}. + \end{array} \mbox{ (mod }p\mbox{)} +\label{eqn:legendre} +\end{equation} + +\textbf{Proof.} \textit{Equation \ref{eqn:legendre} correctly identifies the residue status of an integer $a$ modulo a prime $p$.} +An integer $a$ is a quadratic residue if the following equation has a solution. + +\begin{equation} +x^2 \equiv a \mbox{ (mod }p\mbox{)} +\label{eqn:root} +\end{equation} + +Consider the following equation. + +\begin{equation} +0 \equiv x^{p-1} - 1 \equiv \left \lbrace \left (x^2 \right )^{(p-1)/2} - a^{(p-1)/2} \right \rbrace + \left ( a^{(p-1)/2} - 1 \right ) \mbox{ (mod }p\mbox{)} +\label{eqn:rooti} +\end{equation} + +Whether equation \ref{eqn:root} has a solution or not equation \ref{eqn:rooti} is always true. If $a^{(p-1)/2} - 1 \equiv 0 \mbox{ (mod }p\mbox{)}$ +then the quantity in the braces must be zero. By reduction, + +\begin{eqnarray} +\left (x^2 \right )^{(p-1)/2} - a^{(p-1)/2} \equiv 0 \nonumber \\ +\left (x^2 \right )^{(p-1)/2} \equiv a^{(p-1)/2} \nonumber \\ +x^2 \equiv a \mbox{ (mod }p\mbox{)} +\end{eqnarray} + +As a result there must be a solution to the quadratic equation and in turn $a$ must be a quadratic residue. If $a$ does not divide $p$ and $a$ +is not a quadratic residue then the only other value $a^{(p-1)/2}$ may be congruent to is $-1$ since +\begin{equation} +0 \equiv a^{p - 1} - 1 \equiv (a^{(p-1)/2} + 1)(a^{(p-1)/2} - 1) \mbox{ (mod }p\mbox{)} +\end{equation} +One of the terms on the right hand side must be zero. \textbf{QED} + +\subsection{Jacobi Symbol} +The Jacobi symbol is a generalization of the Legendre function for any odd non prime moduli $p$ greater than 2. If $p = \prod_{i=0}^n p_i$ then +the Jacobi symbol $\left ( { a \over p } \right )$ is equal to the following equation. + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { a \over p_0} \right ) \left ( { a \over p_1} \right ) \ldots \left ( { a \over p_n} \right ) +\end{equation} + +By inspection if $p$ is prime the Jacobi symbol is equivalent to the Legendre function. The following facts\footnote{See HAC \cite[pp. 72-74]{HAC} for +further details.} will be used to derive an efficient Jacobi symbol algorithm. Where $p$ is an odd integer greater than two and $a, b \in \Z$ the +following are true. + +\begin{enumerate} +\item $\left ( { a \over p} \right )$ equals $-1$, $0$ or $1$. +\item $\left ( { ab \over p} \right ) = \left ( { a \over p} \right )\left ( { b \over p} \right )$. +\item If $a \equiv b$ then $\left ( { a \over p} \right ) = \left ( { b \over p} \right )$. +\item $\left ( { 2 \over p} \right )$ equals $1$ if $p \equiv 1$ or $7 \mbox{ (mod }8\mbox{)}$. Otherwise, it equals $-1$. +\item $\left ( { a \over p} \right ) \equiv \left ( { p \over a} \right ) \cdot (-1)^{(p-1)(a-1)/4}$. More specifically +$\left ( { a \over p} \right ) = \left ( { p \over a} \right )$ if $p \equiv a \equiv 1 \mbox{ (mod }4\mbox{)}$. +\end{enumerate} + +Using these facts if $a = 2^k \cdot a'$ then + +\begin{eqnarray} +\left ( { a \over p } \right ) = \left ( {{2^k} \over p } \right ) \left ( {a' \over p} \right ) \nonumber \\ + = \left ( {2 \over p } \right )^k \left ( {a' \over p} \right ) +\label{eqn:jacobi} +\end{eqnarray} + +By fact five, + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { p \over a } \right ) \cdot (-1)^{(p-1)(a-1)/4} +\end{equation} + +Subsequently by fact three since $p \equiv (p \mbox{ mod }a) \mbox{ (mod }a\mbox{)}$ then + +\begin{equation} +\left ( { a \over p } \right ) = \left ( { {p \mbox{ mod } a} \over a } \right ) \cdot (-1)^{(p-1)(a-1)/4} +\end{equation} + +By putting both observations into equation \ref{eqn:jacobi} the following simplified equation is formed. + +\begin{equation} +\left ( { a \over p } \right ) = \left ( {2 \over p } \right )^k \left ( {{p\mbox{ mod }a'} \over a'} \right ) \cdot (-1)^{(p-1)(a'-1)/4} +\end{equation} + +The value of $\left ( {{p \mbox{ mod }a'} \over a'} \right )$ can be found by using the same equation recursively. The value of +$\left ( {2 \over p } \right )^k$ equals $1$ if $k$ is even otherwise it equals $\left ( {2 \over p } \right )$. Using this approach the +factors of $p$ do not have to be known. Furthermore, if $(a, p) = 1$ then the algorithm will terminate when the recursion requests the +Jacobi symbol computation of $\left ( {1 \over a'} \right )$ which is simply $1$. + +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_jacobi}. \\ +\textbf{Input}. mp\_int $a$ and $p$, $a \ge 0$, $p \ge 3$, $p \equiv 1 \mbox{ (mod }2\mbox{)}$ \\ +\textbf{Output}. The Jacobi symbol $c = \left ( {a \over p } \right )$. \\ +\hline \\ +1. If $a = 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow 0$ \\ +\hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ +2. If $a = 1$ then \\ +\hspace{3mm}2.1 $c \leftarrow 1$ \\ +\hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ +3. $a' \leftarrow a$ \\ +4. $k \leftarrow 0$ \\ +5. While $a'.used > 0$ and $a'_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}5.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}5.2 $a' \leftarrow \lfloor a' / 2 \rfloor$ \\ +6. If $k \equiv 0 \mbox{ (mod }2\mbox{)}$ then \\ +\hspace{3mm}6.1 $s \leftarrow 1$ \\ +7. else \\ +\hspace{3mm}7.1 $r \leftarrow p_0 \mbox{ (mod }8\mbox{)}$ \\ +\hspace{3mm}7.2 If $r = 1$ or $r = 7$ then \\ +\hspace{6mm}7.2.1 $s \leftarrow 1$ \\ +\hspace{3mm}7.3 else \\ +\hspace{6mm}7.3.1 $s \leftarrow -1$ \\ +8. If $p_0 \equiv a'_0 \equiv 3 \mbox{ (mod }4\mbox{)}$ then \\ +\hspace{3mm}8.1 $s \leftarrow -s$ \\ +9. If $a' \ne 1$ then \\ +\hspace{3mm}9.1 $p' \leftarrow p \mbox{ (mod }a'\mbox{)}$ \\ +\hspace{3mm}9.2 $s \leftarrow s \cdot \mbox{mp\_jacobi}(p', a')$ \\ +10. $c \leftarrow s$ \\ +11. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_jacobi} +\end{figure} +\textbf{Algorithm mp\_jacobi.} +This algorithm computes the Jacobi symbol for an arbitrary positive integer $a$ with respect to an odd integer $p$ greater than three. The algorithm +is based on algorithm 2.149 of HAC \cite[pp. 73]{HAC}. + +Step numbers one and two handle the trivial cases of $a = 0$ and $a = 1$ respectively. Step five determines the number of two factors in the +input $a$. If $k$ is even than the term $\left ( { 2 \over p } \right )^k$ must always evaluate to one. If $k$ is odd than the term evaluates to one +if $p_0$ is congruent to one or seven modulo eight, otherwise it evaluates to $-1$. After the the $\left ( { 2 \over p } \right )^k$ term is handled +the $(-1)^{(p-1)(a'-1)/4}$ is computed and multiplied against the current product $s$. The latter term evaluates to one if both $p$ and $a'$ +are congruent to one modulo four, otherwise it evaluates to negative one. + +By step nine if $a'$ does not equal one a recursion is required. Step 9.1 computes $p' \equiv p \mbox{ (mod }a'\mbox{)}$ and will recurse to compute +$\left ( {p' \over a'} \right )$ which is multiplied against the current Jacobi product. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_jacobi.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* computes the jacobi c = (a | n) (or Legendre if n is prime) +018 * HAC pp. 73 Algorithm 2.149 +019 */ +020 int mp_jacobi (mp_int * a, mp_int * p, int *c) +021 \{ +022 mp_int a1, p1; +023 int k, s, r, res; +024 mp_digit residue; +025 +026 /* if p <= 0 return MP_VAL */ +027 if (mp_cmp_d(p, 0) != MP_GT) \{ +028 return MP_VAL; +029 \} +030 +031 /* step 1. if a == 0, return 0 */ +032 if (mp_iszero (a) == 1) \{ +033 *c = 0; +034 return MP_OKAY; +035 \} +036 +037 /* step 2. if a == 1, return 1 */ +038 if (mp_cmp_d (a, 1) == MP_EQ) \{ +039 *c = 1; +040 return MP_OKAY; +041 \} +042 +043 /* default */ +044 s = 0; +045 +046 /* step 3. write a = a1 * 2**k */ +047 if ((res = mp_init_copy (&a1, a)) != MP_OKAY) \{ +048 return res; +049 \} +050 +051 if ((res = mp_init (&p1)) != MP_OKAY) \{ +052 goto LBL_A1; +053 \} +054 +055 /* divide out larger power of two */ +056 k = mp_cnt_lsb(&a1); +057 if ((res = mp_div_2d(&a1, k, &a1, NULL)) != MP_OKAY) \{ +058 goto LBL_P1; +059 \} +060 +061 /* step 4. if e is even set s=1 */ +062 if ((k & 1) == 0) \{ +063 s = 1; +064 \} else \{ +065 /* else set s=1 if p = 1/7 (mod 8) or s=-1 if p = 3/5 (mod 8) */ +066 residue = p->dp[0] & 7; +067 +068 if (residue == 1 || residue == 7) \{ +069 s = 1; +070 \} else if (residue == 3 || residue == 5) \{ +071 s = -1; +072 \} +073 \} +074 +075 /* step 5. if p == 3 (mod 4) *and* a1 == 3 (mod 4) then s = -s */ +076 if ( ((p->dp[0] & 3) == 3) && ((a1.dp[0] & 3) == 3)) \{ +077 s = -s; +078 \} +079 +080 /* if a1 == 1 we're done */ +081 if (mp_cmp_d (&a1, 1) == MP_EQ) \{ +082 *c = s; +083 \} else \{ +084 /* n1 = n mod a1 */ +085 if ((res = mp_mod (p, &a1, &p1)) != MP_OKAY) \{ +086 goto LBL_P1; +087 \} +088 if ((res = mp_jacobi (&p1, &a1, &r)) != MP_OKAY) \{ +089 goto LBL_P1; +090 \} +091 *c = s * r; +092 \} +093 +094 /* done */ +095 res = MP_OKAY; +096 LBL_P1:mp_clear (&p1); +097 LBL_A1:mp_clear (&a1); +098 return res; +099 \} +100 #endif +\end{alltt} +\end{small} + +As a matter of practicality the variable $a'$ as per the pseudo-code is reprensented by the variable $a1$ since the $'$ symbol is not valid for a C +variable name character. + +The two simple cases of $a = 0$ and $a = 1$ are handled at the very beginning to simplify the algorithm. If the input is non-trivial the algorithm +has to proceed compute the Jacobi. The variable $s$ is used to hold the current Jacobi product. Note that $s$ is merely a C ``int'' data type since +the values it may obtain are merely $-1$, $0$ and $1$. + +After a local copy of $a$ is made all of the factors of two are divided out and the total stored in $k$. Technically only the least significant +bit of $k$ is required, however, it makes the algorithm simpler to follow to perform an addition. In practice an exclusive-or and addition have the same +processor requirements and neither is faster than the other. + +Line 61 through 70 determines the value of $\left ( { 2 \over p } \right )^k$. If the least significant bit of $k$ is zero than +$k$ is even and the value is one. Otherwise, the value of $s$ depends on which residue class $p$ belongs to modulo eight. The value of +$(-1)^{(p-1)(a'-1)/4}$ is compute and multiplied against $s$ on lines 75 through 73. + +Finally, if $a1$ does not equal one the algorithm must recurse and compute $\left ( {p' \over a'} \right )$. + +\textit{-- Comment about default $s$ and such...} + +\section{Modular Inverse} +\label{sec:modinv} +The modular inverse of a number actually refers to the modular multiplicative inverse. Essentially for any integer $a$ such that $(a, p) = 1$ there +exist another integer $b$ such that $ab \equiv 1 \mbox{ (mod }p\mbox{)}$. The integer $b$ is called the multiplicative inverse of $a$ which is +denoted as $b = a^{-1}$. Technically speaking modular inversion is a well defined operation for any finite ring or field not just for rings and +fields of integers. However, the former will be the matter of discussion. + +The simplest approach is to compute the algebraic inverse of the input. That is to compute $b \equiv a^{\Phi(p) - 1}$. If $\Phi(p)$ is the +order of the multiplicative subgroup modulo $p$ then $b$ must be the multiplicative inverse of $a$. The proof of which is trivial. + +\begin{equation} +ab \equiv a \left (a^{\Phi(p) - 1} \right ) \equiv a^{\Phi(p)} \equiv a^0 \equiv 1 \mbox{ (mod }p\mbox{)} +\end{equation} + +However, as simple as this approach may be it has two serious flaws. It requires that the value of $\Phi(p)$ be known which if $p$ is composite +requires all of the prime factors. This approach also is very slow as the size of $p$ grows. + +A simpler approach is based on the observation that solving for the multiplicative inverse is equivalent to solving the linear +Diophantine\footnote{See LeVeque \cite[pp. 40-43]{LeVeque} for more information.} equation. + +\begin{equation} +ab + pq = 1 +\end{equation} + +Where $a$, $b$, $p$ and $q$ are all integers. If such a pair of integers $ \left < b, q \right >$ exist than $b$ is the multiplicative inverse of +$a$ modulo $p$. The extended Euclidean algorithm (Knuth \cite[pp. 342]{TAOCPV2}) can be used to solve such equations provided $(a, p) = 1$. +However, instead of using that algorithm directly a variant known as the binary Extended Euclidean algorithm will be used in its place. The +binary approach is very similar to the binary greatest common divisor algorithm except it will produce a full solution to the Diophantine +equation. + +\subsection{General Case} +\newpage\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_invmod}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $(a, b) = 1$, $p \ge 2$, $0 < a < p$. \\ +\textbf{Output}. The modular inverse $c \equiv a^{-1} \mbox{ (mod }b\mbox{)}$. \\ +\hline \\ +1. If $b \le 0$ then return(\textit{MP\_VAL}). \\ +2. If $b_0 \equiv 1 \mbox{ (mod }2\mbox{)}$ then use algorithm fast\_mp\_invmod. \\ +3. $x \leftarrow \vert a \vert, y \leftarrow b$ \\ +4. If $x_0 \equiv y_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ then return(\textit{MP\_VAL}). \\ +5. $B \leftarrow 0, C \leftarrow 0, A \leftarrow 1, D \leftarrow 1$ \\ +6. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}6.2 If ($A.used > 0$ and $A_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) or ($B.used > 0$ and $B_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) then \\ +\hspace{6mm}6.2.1 $A \leftarrow A + y$ \\ +\hspace{6mm}6.2.2 $B \leftarrow B - x$ \\ +\hspace{3mm}6.3 $A \leftarrow \lfloor A / 2 \rfloor$ \\ +\hspace{3mm}6.4 $B \leftarrow \lfloor B / 2 \rfloor$ \\ +7. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +\hspace{3mm}7.2 If ($C.used > 0$ and $C_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) or ($D.used > 0$ and $D_0 \equiv 1 \mbox{ (mod }2\mbox{)}$) then \\ +\hspace{6mm}7.2.1 $C \leftarrow C + y$ \\ +\hspace{6mm}7.2.2 $D \leftarrow D - x$ \\ +\hspace{3mm}7.3 $C \leftarrow \lfloor C / 2 \rfloor$ \\ +\hspace{3mm}7.4 $D \leftarrow \lfloor D / 2 \rfloor$ \\ +8. If $u \ge v$ then \\ +\hspace{3mm}8.1 $u \leftarrow u - v$ \\ +\hspace{3mm}8.2 $A \leftarrow A - C$ \\ +\hspace{3mm}8.3 $B \leftarrow B - D$ \\ +9. else \\ +\hspace{3mm}9.1 $v \leftarrow v - u$ \\ +\hspace{3mm}9.2 $C \leftarrow C - A$ \\ +\hspace{3mm}9.3 $D \leftarrow D - B$ \\ +10. If $u \ne 0$ goto step 6. \\ +11. If $v \ne 1$ return(\textit{MP\_VAL}). \\ +12. While $C \le 0$ do \\ +\hspace{3mm}12.1 $C \leftarrow C + b$ \\ +13. While $C \ge b$ do \\ +\hspace{3mm}13.1 $C \leftarrow C - b$ \\ +14. $c \leftarrow C$ \\ +15. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\end{figure} +\textbf{Algorithm mp\_invmod.} +This algorithm computes the modular multiplicative inverse of an integer $a$ modulo an integer $b$. This algorithm is a variation of the +extended binary Euclidean algorithm from HAC \cite[pp. 608]{HAC}. It has been modified to only compute the modular inverse and not a complete +Diophantine solution. + +If $b \le 0$ than the modulus is invalid and MP\_VAL is returned. Similarly if both $a$ and $b$ are even then there cannot be a multiplicative +inverse for $a$ and the error is reported. + +The astute reader will observe that steps seven through nine are very similar to the binary greatest common divisor algorithm mp\_gcd. In this case +the other variables to the Diophantine equation are solved. The algorithm terminates when $u = 0$ in which case the solution is + +\begin{equation} +Ca + Db = v +\end{equation} + +If $v$, the greatest common divisor of $a$ and $b$ is not equal to one then the algorithm will report an error as no inverse exists. Otherwise, $C$ +is the modular inverse of $a$. The actual value of $C$ is congruent to, but not necessarily equal to, the ideal modular inverse which should lie +within $1 \le a^{-1} < b$. Step numbers twelve and thirteen adjust the inverse until it is in range. If the original input $a$ is within $0 < a < p$ +then only a couple of additions or subtractions will be required to adjust the inverse. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_invmod.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* hac 14.61, pp608 */ +018 int mp_invmod (mp_int * a, mp_int * b, mp_int * c) +019 \{ +020 /* b cannot be negative */ +021 if (b->sign == MP_NEG || mp_iszero(b) == 1) \{ +022 return MP_VAL; +023 \} +024 +025 #ifdef BN_FAST_MP_INVMOD_C +026 /* if the modulus is odd we can use a faster routine instead */ +027 if (mp_isodd (b) == 1) \{ +028 return fast_mp_invmod (a, b, c); +029 \} +030 #endif +031 +032 #ifdef BN_MP_INVMOD_SLOW_C +033 return mp_invmod_slow(a, b, c); +034 #endif +035 +036 return MP_VAL; +037 \} +038 #endif +\end{alltt} +\end{small} + +\subsubsection{Odd Moduli} + +When the modulus $b$ is odd the variables $A$ and $C$ are fixed and are not required to compute the inverse. In particular by attempting to solve +the Diophantine $Cb + Da = 1$ only $B$ and $D$ are required to find the inverse of $a$. + +The algorithm fast\_mp\_invmod is a direct adaptation of algorithm mp\_invmod with all all steps involving either $A$ or $C$ removed. This +optimization will halve the time required to compute the modular inverse. + +\section{Primality Tests} + +A non-zero integer $a$ is said to be prime if it is not divisible by any other integer excluding one and itself. For example, $a = 7$ is prime +since the integers $2 \ldots 6$ do not evenly divide $a$. By contrast, $a = 6$ is not prime since $a = 6 = 2 \cdot 3$. + +Prime numbers arise in cryptography considerably as they allow finite fields to be formed. The ability to determine whether an integer is prime or +not quickly has been a viable subject in cryptography and number theory for considerable time. The algorithms that will be presented are all +probablistic algorithms in that when they report an integer is composite it must be composite. However, when the algorithms report an integer is +prime the algorithm may be incorrect. + +As will be discussed it is possible to limit the probability of error so well that for practical purposes the probablity of error might as +well be zero. For the purposes of these discussions let $n$ represent the candidate integer of which the primality is in question. + +\subsection{Trial Division} + +Trial division means to attempt to evenly divide a candidate integer by small prime integers. If the candidate can be evenly divided it obviously +cannot be prime. By dividing by all primes $1 < p \le \sqrt{n}$ this test can actually prove whether an integer is prime. However, such a test +would require a prohibitive amount of time as $n$ grows. + +Instead of dividing by every prime, a smaller, more mangeable set of primes may be used instead. By performing trial division with only a subset +of the primes less than $\sqrt{n} + 1$ the algorithm cannot prove if a candidate is prime. However, often it can prove a candidate is not prime. + +The benefit of this test is that trial division by small values is fairly efficient. Specially compared to the other algorithms that will be +discussed shortly. The probability that this approach correctly identifies a composite candidate when tested with all primes upto $q$ is given by +$1 - {1.12 \over ln(q)}$. The graph (\ref{pic:primality}, will be added later) demonstrates the probability of success for the range +$3 \le q \le 100$. + +At approximately $q = 30$ the gain of performing further tests diminishes fairly quickly. At $q = 90$ further testing is generally not going to +be of any practical use. In the case of LibTomMath the default limit $q = 256$ was chosen since it is not too high and will eliminate +approximately $80\%$ of all candidate integers. The constant \textbf{PRIME\_SIZE} is equal to the number of primes in the test base. The +array \_\_prime\_tab is an array of the first \textbf{PRIME\_SIZE} prime numbers. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_is\_divisible}. \\ +\textbf{Input}. mp\_int $a$ \\ +\textbf{Output}. $c = 1$ if $n$ is divisible by a small prime, otherwise $c = 0$. \\ +\hline \\ +1. for $ix$ from $0$ to $PRIME\_SIZE$ do \\ +\hspace{3mm}1.1 $d \leftarrow n \mbox{ (mod }\_\_prime\_tab_{ix}\mbox{)}$ \\ +\hspace{3mm}1.2 If $d = 0$ then \\ +\hspace{6mm}1.2.1 $c \leftarrow 1$ \\ +\hspace{6mm}1.2.2 Return(\textit{MP\_OKAY}). \\ +2. $c \leftarrow 0$ \\ +3. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_is\_divisible} +\end{figure} +\textbf{Algorithm mp\_prime\_is\_divisible.} +This algorithm attempts to determine if a candidate integer $n$ is composite by performing trial divisions. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_is\_divisible.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* determines if an integers is divisible by one +018 * of the first PRIME_SIZE primes or not +019 * +020 * sets result to 0 if not, 1 if yes +021 */ +022 int mp_prime_is_divisible (mp_int * a, int *result) +023 \{ +024 int err, ix; +025 mp_digit res; +026 +027 /* default to not */ +028 *result = MP_NO; +029 +030 for (ix = 0; ix < PRIME_SIZE; ix++) \{ +031 /* what is a mod LBL_prime_tab[ix] */ +032 if ((err = mp_mod_d (a, ltm_prime_tab[ix], &res)) != MP_OKAY) \{ +033 return err; +034 \} +035 +036 /* is the residue zero? */ +037 if (res == 0) \{ +038 *result = MP_YES; +039 return MP_OKAY; +040 \} +041 \} +042 +043 return MP_OKAY; +044 \} +045 #endif +\end{alltt} +\end{small} + +The algorithm defaults to a return of $0$ in case an error occurs. The values in the prime table are all specified to be in the range of a +mp\_digit. The table \_\_prime\_tab is defined in the following file. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_prime\_tab.c +\vspace{-3mm} +\begin{alltt} +016 const mp_digit ltm_prime_tab[] = \{ +017 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, +018 0x0017, 0x001D, 0x001F, 0x0025, 0x0029, 0x002B, 0x002F, 0x0035, +019 0x003B, 0x003D, 0x0043, 0x0047, 0x0049, 0x004F, 0x0053, 0x0059, +020 0x0061, 0x0065, 0x0067, 0x006B, 0x006D, 0x0071, 0x007F, +021 #ifndef MP_8BIT +022 0x0083, +023 0x0089, 0x008B, 0x0095, 0x0097, 0x009D, 0x00A3, 0x00A7, 0x00AD, +024 0x00B3, 0x00B5, 0x00BF, 0x00C1, 0x00C5, 0x00C7, 0x00D3, 0x00DF, +025 0x00E3, 0x00E5, 0x00E9, 0x00EF, 0x00F1, 0x00FB, 0x0101, 0x0107, +026 0x010D, 0x010F, 0x0115, 0x0119, 0x011B, 0x0125, 0x0133, 0x0137, +027 +028 0x0139, 0x013D, 0x014B, 0x0151, 0x015B, 0x015D, 0x0161, 0x0167, +029 0x016F, 0x0175, 0x017B, 0x017F, 0x0185, 0x018D, 0x0191, 0x0199, +030 0x01A3, 0x01A5, 0x01AF, 0x01B1, 0x01B7, 0x01BB, 0x01C1, 0x01C9, +031 0x01CD, 0x01CF, 0x01D3, 0x01DF, 0x01E7, 0x01EB, 0x01F3, 0x01F7, +032 0x01FD, 0x0209, 0x020B, 0x021D, 0x0223, 0x022D, 0x0233, 0x0239, +033 0x023B, 0x0241, 0x024B, 0x0251, 0x0257, 0x0259, 0x025F, 0x0265, +034 0x0269, 0x026B, 0x0277, 0x0281, 0x0283, 0x0287, 0x028D, 0x0293, +035 0x0295, 0x02A1, 0x02A5, 0x02AB, 0x02B3, 0x02BD, 0x02C5, 0x02CF, +036 +037 0x02D7, 0x02DD, 0x02E3, 0x02E7, 0x02EF, 0x02F5, 0x02F9, 0x0301, +038 0x0305, 0x0313, 0x031D, 0x0329, 0x032B, 0x0335, 0x0337, 0x033B, +039 0x033D, 0x0347, 0x0355, 0x0359, 0x035B, 0x035F, 0x036D, 0x0371, +040 0x0373, 0x0377, 0x038B, 0x038F, 0x0397, 0x03A1, 0x03A9, 0x03AD, +041 0x03B3, 0x03B9, 0x03C7, 0x03CB, 0x03D1, 0x03D7, 0x03DF, 0x03E5, +042 0x03F1, 0x03F5, 0x03FB, 0x03FD, 0x0407, 0x0409, 0x040F, 0x0419, +043 0x041B, 0x0425, 0x0427, 0x042D, 0x043F, 0x0443, 0x0445, 0x0449, +044 0x044F, 0x0455, 0x045D, 0x0463, 0x0469, 0x047F, 0x0481, 0x048B, +045 +046 0x0493, 0x049D, 0x04A3, 0x04A9, 0x04B1, 0x04BD, 0x04C1, 0x04C7, +047 0x04CD, 0x04CF, 0x04D5, 0x04E1, 0x04EB, 0x04FD, 0x04FF, 0x0503, +048 0x0509, 0x050B, 0x0511, 0x0515, 0x0517, 0x051B, 0x0527, 0x0529, +049 0x052F, 0x0551, 0x0557, 0x055D, 0x0565, 0x0577, 0x0581, 0x058F, +050 0x0593, 0x0595, 0x0599, 0x059F, 0x05A7, 0x05AB, 0x05AD, 0x05B3, +051 0x05BF, 0x05C9, 0x05CB, 0x05CF, 0x05D1, 0x05D5, 0x05DB, 0x05E7, +052 0x05F3, 0x05FB, 0x0607, 0x060D, 0x0611, 0x0617, 0x061F, 0x0623, +053 0x062B, 0x062F, 0x063D, 0x0641, 0x0647, 0x0649, 0x064D, 0x0653 +054 #endif +055 \}; +056 #endif +\end{alltt} +\end{small} + +Note that there are two possible tables. When an mp\_digit is 7-bits long only the primes upto $127$ may be included, otherwise the primes +upto $1619$ are used. Note that the value of \textbf{PRIME\_SIZE} is a constant dependent on the size of a mp\_digit. + +\subsection{The Fermat Test} +The Fermat test is probably one the oldest tests to have a non-trivial probability of success. It is based on the fact that if $n$ is in +fact prime then $a^{n} \equiv a \mbox{ (mod }n\mbox{)}$ for all $0 < a < n$. The reason being that if $n$ is prime than the order of +the multiplicative sub group is $n - 1$. Any base $a$ must have an order which divides $n - 1$ and as such $a^n$ is equivalent to +$a^1 = a$. + +If $n$ is composite then any given base $a$ does not have to have a period which divides $n - 1$. In which case +it is possible that $a^n \nequiv a \mbox{ (mod }n\mbox{)}$. However, this test is not absolute as it is possible that the order +of a base will divide $n - 1$ which would then be reported as prime. Such a base yields what is known as a Fermat pseudo-prime. Several +integers known as Carmichael numbers will be a pseudo-prime to all valid bases. Fortunately such numbers are extremely rare as $n$ grows +in size. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_fermat}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $a \ge 2$, $0 < b < a$. \\ +\textbf{Output}. $c = 1$ if $b^a \equiv b \mbox{ (mod }a\mbox{)}$, otherwise $c = 0$. \\ +\hline \\ +1. $t \leftarrow b^a \mbox{ (mod }a\mbox{)}$ \\ +2. If $t = b$ then \\ +\hspace{3mm}2.1 $c = 1$ \\ +3. else \\ +\hspace{3mm}3.1 $c = 0$ \\ +4. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_fermat} +\end{figure} +\textbf{Algorithm mp\_prime\_fermat.} +This algorithm determines whether an mp\_int $a$ is a Fermat prime to the base $b$ or not. It uses a single modular exponentiation to +determine the result. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_fermat.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* performs one Fermat test. +018 * +019 * If "a" were prime then b**a == b (mod a) since the order of +020 * the multiplicative sub-group would be phi(a) = a-1. That means +021 * it would be the same as b**(a mod (a-1)) == b**1 == b (mod a). +022 * +023 * Sets result to 1 if the congruence holds, or zero otherwise. +024 */ +025 int mp_prime_fermat (mp_int * a, mp_int * b, int *result) +026 \{ +027 mp_int t; +028 int err; +029 +030 /* default to composite */ +031 *result = MP_NO; +032 +033 /* ensure b > 1 */ +034 if (mp_cmp_d(b, 1) != MP_GT) \{ +035 return MP_VAL; +036 \} +037 +038 /* init t */ +039 if ((err = mp_init (&t)) != MP_OKAY) \{ +040 return err; +041 \} +042 +043 /* compute t = b**a mod a */ +044 if ((err = mp_exptmod (b, a, a, &t)) != MP_OKAY) \{ +045 goto LBL_T; +046 \} +047 +048 /* is it equal to b? */ +049 if (mp_cmp (&t, b) == MP_EQ) \{ +050 *result = MP_YES; +051 \} +052 +053 err = MP_OKAY; +054 LBL_T:mp_clear (&t); +055 return err; +056 \} +057 #endif +\end{alltt} +\end{small} + +\subsection{The Miller-Rabin Test} +The Miller-Rabin (citation) test is another primality test which has tighter error bounds than the Fermat test specifically with sequentially chosen +candidate integers. The algorithm is based on the observation that if $n - 1 = 2^kr$ and if $b^r \nequiv \pm 1$ then after upto $k - 1$ squarings the +value must be equal to $-1$. The squarings are stopped as soon as $-1$ is observed. If the value of $1$ is observed first it means that +some value not congruent to $\pm 1$ when squared equals one which cannot occur if $n$ is prime. + +\begin{figure}[!here] +\begin{small} +\begin{center} +\begin{tabular}{l} +\hline Algorithm \textbf{mp\_prime\_miller\_rabin}. \\ +\textbf{Input}. mp\_int $a$ and $b$, $a \ge 2$, $0 < b < a$. \\ +\textbf{Output}. $c = 1$ if $a$ is a Miller-Rabin prime to the base $a$, otherwise $c = 0$. \\ +\hline +1. $a' \leftarrow a - 1$ \\ +2. $r \leftarrow n1$ \\ +3. $c \leftarrow 0, s \leftarrow 0$ \\ +4. While $r.used > 0$ and $r_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}4.1 $s \leftarrow s + 1$ \\ +\hspace{3mm}4.2 $r \leftarrow \lfloor r / 2 \rfloor$ \\ +5. $y \leftarrow b^r \mbox{ (mod }a\mbox{)}$ \\ +6. If $y \nequiv \pm 1$ then \\ +\hspace{3mm}6.1 $j \leftarrow 1$ \\ +\hspace{3mm}6.2 While $j \le (s - 1)$ and $y \nequiv a'$ \\ +\hspace{6mm}6.2.1 $y \leftarrow y^2 \mbox{ (mod }a\mbox{)}$ \\ +\hspace{6mm}6.2.2 If $y = 1$ then goto step 8. \\ +\hspace{6mm}6.2.3 $j \leftarrow j + 1$ \\ +\hspace{3mm}6.3 If $y \nequiv a'$ goto step 8. \\ +7. $c \leftarrow 1$\\ +8. Return(\textit{MP\_OKAY}). \\ +\hline +\end{tabular} +\end{center} +\end{small} +\caption{Algorithm mp\_prime\_miller\_rabin} +\end{figure} +\textbf{Algorithm mp\_prime\_miller\_rabin.} +This algorithm performs one trial round of the Miller-Rabin algorithm to the base $b$. It will set $c = 1$ if the algorithm cannot determine +if $b$ is composite or $c = 0$ if $b$ is provably composite. The values of $s$ and $r$ are computed such that $a' = a - 1 = 2^sr$. + +If the value $y \equiv b^r$ is congruent to $\pm 1$ then the algorithm cannot prove if $a$ is composite or not. Otherwise, the algorithm will +square $y$ upto $s - 1$ times stopping only when $y \equiv -1$. If $y^2 \equiv 1$ and $y \nequiv \pm 1$ then the algorithm can report that $a$ +is provably composite. If the algorithm performs $s - 1$ squarings and $y \nequiv -1$ then $a$ is provably composite. If $a$ is not provably +composite then it is \textit{probably} prime. + +\vspace{+3mm}\begin{small} +\hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_miller\_rabin.c +\vspace{-3mm} +\begin{alltt} +016 +017 /* Miller-Rabin test of "a" to the base of "b" as described in +018 * HAC pp. 139 Algorithm 4.24 +019 * +020 * Sets result to 0 if definitely composite or 1 if probably prime. +021 * Randomly the chance of error is no more than 1/4 and often +022 * very much lower. +023 */ +024 int mp_prime_miller_rabin (mp_int * a, mp_int * b, int *result) +025 \{ +026 mp_int n1, y, r; +027 int s, j, err; +028 +029 /* default */ +030 *result = MP_NO; +031 +032 /* ensure b > 1 */ +033 if (mp_cmp_d(b, 1) != MP_GT) \{ +034 return MP_VAL; +035 \} +036 +037 /* get n1 = a - 1 */ +038 if ((err = mp_init_copy (&n1, a)) != MP_OKAY) \{ +039 return err; +040 \} +041 if ((err = mp_sub_d (&n1, 1, &n1)) != MP_OKAY) \{ +042 goto LBL_N1; +043 \} +044 +045 /* set 2**s * r = n1 */ +046 if ((err = mp_init_copy (&r, &n1)) != MP_OKAY) \{ +047 goto LBL_N1; +048 \} +049 +050 /* count the number of least significant bits +051 * which are zero +052 */ +053 s = mp_cnt_lsb(&r); +054 +055 /* now divide n - 1 by 2**s */ +056 if ((err = mp_div_2d (&r, s, &r, NULL)) != MP_OKAY) \{ +057 goto LBL_R; +058 \} +059 +060 /* compute y = b**r mod a */ +061 if ((err = mp_init (&y)) != MP_OKAY) \{ +062 goto LBL_R; +063 \} +064 if ((err = mp_exptmod (b, &r, a, &y)) != MP_OKAY) \{ +065 goto LBL_Y; +066 \} +067 +068 /* if y != 1 and y != n1 do */ +069 if (mp_cmp_d (&y, 1) != MP_EQ && mp_cmp (&y, &n1) != MP_EQ) \{ +070 j = 1; +071 /* while j <= s-1 and y != n1 */ +072 while ((j <= (s - 1)) && mp_cmp (&y, &n1) != MP_EQ) \{ +073 if ((err = mp_sqrmod (&y, a, &y)) != MP_OKAY) \{ +074 goto LBL_Y; +075 \} +076 +077 /* if y == 1 then composite */ +078 if (mp_cmp_d (&y, 1) == MP_EQ) \{ +079 goto LBL_Y; +080 \} +081 +082 ++j; +083 \} +084 +085 /* if y != n1 then composite */ +086 if (mp_cmp (&y, &n1) != MP_EQ) \{ +087 goto LBL_Y; +088 \} +089 \} +090 +091 /* probably prime now */ +092 *result = MP_YES; +093 LBL_Y:mp_clear (&y); +094 LBL_R:mp_clear (&r); +095 LBL_N1:mp_clear (&n1); +096 return err; +097 \} +098 #endif +\end{alltt} +\end{small} + + + + +\backmatter +\appendix +\begin{thebibliography}{ABCDEF} +\bibitem[1]{TAOCPV2} +Donald Knuth, \textit{The Art of Computer Programming}, Third Edition, Volume Two, Seminumerical Algorithms, Addison-Wesley, 1998 + +\bibitem[2]{HAC} +A. Menezes, P. van Oorschot, S. Vanstone, \textit{Handbook of Applied Cryptography}, CRC Press, 1996 + +\bibitem[3]{ROSE} +Michael Rosing, \textit{Implementing Elliptic Curve Cryptography}, Manning Publications, 1999 + +\bibitem[4]{COMBA} +Paul G. Comba, \textit{Exponentiation Cryptosystems on the IBM PC}. IBM Systems Journal 29(4): 526-538 (1990) + +\bibitem[5]{KARA} +A. Karatsuba, Doklay Akad. Nauk SSSR 145 (1962), pp.293-294 + +\bibitem[6]{KARAP} +Andre Weimerskirch and Christof Paar, \textit{Generalizations of the Karatsuba Algorithm for Polynomial Multiplication}, Submitted to Design, Codes and Cryptography, March 2002 + +\bibitem[7]{BARRETT} +Paul Barrett, \textit{Implementing the Rivest Shamir and Adleman Public Key Encryption Algorithm on a Standard Digital Signal Processor}, Advances in Cryptology, Crypto '86, Springer-Verlag. + +\bibitem[8]{MONT} +P.L.Montgomery. \textit{Modular multiplication without trial division}. Mathematics of Computation, 44(170):519-521, April 1985. + +\bibitem[9]{DRMET} +Chae Hoon Lim and Pil Joong Lee, \textit{Generating Efficient Primes for Discrete Log Cryptosystems}, POSTECH Information Research Laboratories + +\bibitem[10]{MMB} +J. Daemen and R. Govaerts and J. Vandewalle, \textit{Block ciphers based on Modular Arithmetic}, State and {P}rogress in the {R}esearch of {C}ryptography, 1993, pp. 80-89 + +\bibitem[11]{RSAREF} +R.L. Rivest, A. Shamir, L. Adleman, \textit{A Method for Obtaining Digital Signatures and Public-Key Cryptosystems} + +\bibitem[12]{DHREF} +Whitfield Diffie, Martin E. Hellman, \textit{New Directions in Cryptography}, IEEE Transactions on Information Theory, 1976 + +\bibitem[13]{IEEE} +IEEE Standard for Binary Floating-Point Arithmetic (ANSI/IEEE Std 754-1985) + +\bibitem[14]{GMP} +GNU Multiple Precision (GMP), \url{http://www.swox.com/gmp/} + +\bibitem[15]{MPI} +Multiple Precision Integer Library (MPI), Michael Fromberger, \url{http://thayer.dartmouth.edu/~sting/mpi/} + +\bibitem[16]{OPENSSL} +OpenSSL Cryptographic Toolkit, \url{http://openssl.org} + +\bibitem[17]{LIP} +Large Integer Package, \url{http://home.hetnet.nl/~ecstr/LIP.zip} + +\bibitem[18]{ISOC} +JTC1/SC22/WG14, ISO/IEC 9899:1999, ``A draft rationale for the C99 standard.'' + +\bibitem[19]{JAVA} +The Sun Java Website, \url{http://java.sun.com/} + +\end{thebibliography} + +\input{tommath.ind} + +\end{document} diff --git a/libtommath/tommath_class.h b/libtommath/tommath_class.h new file mode 100644 index 0000000..53bfa31 --- /dev/null +++ b/libtommath/tommath_class.h @@ -0,0 +1,952 @@ +#if !(defined(LTM1) && defined(LTM2) && defined(LTM3)) +#if defined(LTM2) +#define LTM3 +#endif +#if defined(LTM1) +#define LTM2 +#endif +#define LTM1 + +#if defined(LTM_ALL) +#define BN_ERROR_C +#define BN_FAST_MP_INVMOD_C +#define BN_FAST_MP_MONTGOMERY_REDUCE_C +#define BN_FAST_S_MP_MUL_DIGS_C +#define BN_FAST_S_MP_MUL_HIGH_DIGS_C +#define BN_FAST_S_MP_SQR_C +#define BN_MP_2EXPT_C +#define BN_MP_ABS_C +#define BN_MP_ADD_C +#define BN_MP_ADD_D_C +#define BN_MP_ADDMOD_C +#define BN_MP_AND_C +#define BN_MP_CLAMP_C +#define BN_MP_CLEAR_C +#define BN_MP_CLEAR_MULTI_C +#define BN_MP_CMP_C +#define BN_MP_CMP_D_C +#define BN_MP_CMP_MAG_C +#define BN_MP_CNT_LSB_C +#define BN_MP_COPY_C +#define BN_MP_COUNT_BITS_C +#define BN_MP_DIV_C +#define BN_MP_DIV_2_C +#define BN_MP_DIV_2D_C +#define BN_MP_DIV_3_C +#define BN_MP_DIV_D_C +#define BN_MP_DR_IS_MODULUS_C +#define BN_MP_DR_REDUCE_C +#define BN_MP_DR_SETUP_C +#define BN_MP_EXCH_C +#define BN_MP_EXPT_D_C +#define BN_MP_EXPTMOD_C +#define BN_MP_EXPTMOD_FAST_C +#define BN_MP_EXTEUCLID_C +#define BN_MP_FREAD_C +#define BN_MP_FWRITE_C +#define BN_MP_GCD_C +#define BN_MP_GET_INT_C +#define BN_MP_GROW_C +#define BN_MP_INIT_C +#define BN_MP_INIT_COPY_C +#define BN_MP_INIT_MULTI_C +#define BN_MP_INIT_SET_C +#define BN_MP_INIT_SET_INT_C +#define BN_MP_INIT_SIZE_C +#define BN_MP_INVMOD_C +#define BN_MP_INVMOD_SLOW_C +#define BN_MP_IS_SQUARE_C +#define BN_MP_JACOBI_C +#define BN_MP_KARATSUBA_MUL_C +#define BN_MP_KARATSUBA_SQR_C +#define BN_MP_LCM_C +#define BN_MP_LSHD_C +#define BN_MP_MOD_C +#define BN_MP_MOD_2D_C +#define BN_MP_MOD_D_C +#define BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +#define BN_MP_MONTGOMERY_REDUCE_C +#define BN_MP_MONTGOMERY_SETUP_C +#define BN_MP_MUL_C +#define BN_MP_MUL_2_C +#define BN_MP_MUL_2D_C +#define BN_MP_MUL_D_C +#define BN_MP_MULMOD_C +#define BN_MP_N_ROOT_C +#define BN_MP_NEG_C +#define BN_MP_OR_C +#define BN_MP_PRIME_FERMAT_C +#define BN_MP_PRIME_IS_DIVISIBLE_C +#define BN_MP_PRIME_IS_PRIME_C +#define BN_MP_PRIME_MILLER_RABIN_C +#define BN_MP_PRIME_NEXT_PRIME_C +#define BN_MP_PRIME_RABIN_MILLER_TRIALS_C +#define BN_MP_PRIME_RANDOM_EX_C +#define BN_MP_RADIX_SIZE_C +#define BN_MP_RADIX_SMAP_C +#define BN_MP_RAND_C +#define BN_MP_READ_RADIX_C +#define BN_MP_READ_SIGNED_BIN_C +#define BN_MP_READ_UNSIGNED_BIN_C +#define BN_MP_REDUCE_C +#define BN_MP_REDUCE_2K_C +#define BN_MP_REDUCE_2K_SETUP_C +#define BN_MP_REDUCE_IS_2K_C +#define BN_MP_REDUCE_SETUP_C +#define BN_MP_RSHD_C +#define BN_MP_SET_C +#define BN_MP_SET_INT_C +#define BN_MP_SHRINK_C +#define BN_MP_SIGNED_BIN_SIZE_C +#define BN_MP_SQR_C +#define BN_MP_SQRMOD_C +#define BN_MP_SQRT_C +#define BN_MP_SUB_C +#define BN_MP_SUB_D_C +#define BN_MP_SUBMOD_C +#define BN_MP_TO_SIGNED_BIN_C +#define BN_MP_TO_UNSIGNED_BIN_C +#define BN_MP_TOOM_MUL_C +#define BN_MP_TOOM_SQR_C +#define BN_MP_TORADIX_C +#define BN_MP_TORADIX_N_C +#define BN_MP_UNSIGNED_BIN_SIZE_C +#define BN_MP_XOR_C +#define BN_MP_ZERO_C +#define BN_PRIME_TAB_C +#define BN_REVERSE_C +#define BN_S_MP_ADD_C +#define BN_S_MP_EXPTMOD_C +#define BN_S_MP_MUL_DIGS_C +#define BN_S_MP_MUL_HIGH_DIGS_C +#define BN_S_MP_SQR_C +#define BN_S_MP_SUB_C +#define BNCORE_C +#endif + +#if defined(BN_ERROR_C) + #define BN_MP_ERROR_TO_STRING_C +#endif + +#if defined(BN_FAST_MP_INVMOD_C) + #define BN_MP_ISEVEN_C + #define BN_MP_INIT_MULTI_C + #define BN_MP_COPY_C + #define BN_MP_ABS_C + #define BN_MP_SET_C + #define BN_MP_DIV_2_C + #define BN_MP_ISODD_C + #define BN_MP_SUB_C + #define BN_MP_CMP_C + #define BN_MP_ISZERO_C + #define BN_MP_CMP_D_C + #define BN_MP_ADD_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_FAST_MP_MONTGOMERY_REDUCE_C) + #define BN_MP_GROW_C + #define BN_MP_RSHD_C + #define BN_MP_CLAMP_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_FAST_S_MP_MUL_DIGS_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_FAST_S_MP_SQR_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_2EXPT_C) + #define BN_MP_ZERO_C + #define BN_MP_GROW_C +#endif + +#if defined(BN_MP_ABS_C) + #define BN_MP_COPY_C +#endif + +#if defined(BN_MP_ADD_C) + #define BN_S_MP_ADD_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_ADD_D_C) + #define BN_MP_GROW_C + #define BN_MP_SUB_D_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_ADDMOD_C) + #define BN_MP_INIT_C + #define BN_MP_ADD_C + #define BN_MP_CLEAR_C + #define BN_MP_MOD_C +#endif + +#if defined(BN_MP_AND_C) + #define BN_MP_INIT_COPY_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_CLAMP_C) +#endif + +#if defined(BN_MP_CLEAR_C) +#endif + +#if defined(BN_MP_CLEAR_MULTI_C) + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_CMP_C) + #define BN_MP_CMP_MAG_C +#endif + +#if defined(BN_MP_CMP_D_C) +#endif + +#if defined(BN_MP_CMP_MAG_C) +#endif + +#if defined(BN_MP_CNT_LSB_C) + #define BN_MP_ISZERO_C +#endif + +#if defined(BN_MP_COPY_C) + #define BN_MP_GROW_C +#endif + +#if defined(BN_MP_COUNT_BITS_C) +#endif + +#if defined(BN_MP_DIV_C) + #define BN_MP_ISZERO_C + #define BN_MP_CMP_MAG_C + #define BN_MP_COPY_C + #define BN_MP_ZERO_C + #define BN_MP_INIT_MULTI_C + #define BN_MP_SET_C + #define BN_MP_COUNT_BITS_C + #define BN_MP_ABS_C + #define BN_MP_MUL_2D_C + #define BN_MP_CMP_C + #define BN_MP_SUB_C + #define BN_MP_ADD_C + #define BN_MP_DIV_2D_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_MULTI_C + #define BN_MP_INIT_SIZE_C + #define BN_MP_INIT_C + #define BN_MP_INIT_COPY_C + #define BN_MP_LSHD_C + #define BN_MP_RSHD_C + #define BN_MP_MUL_D_C + #define BN_MP_CLAMP_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_DIV_2_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_DIV_2D_C) + #define BN_MP_COPY_C + #define BN_MP_ZERO_C + #define BN_MP_INIT_C + #define BN_MP_MOD_2D_C + #define BN_MP_CLEAR_C + #define BN_MP_RSHD_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C +#endif + +#if defined(BN_MP_DIV_3_C) + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_DIV_D_C) + #define BN_MP_ISZERO_C + #define BN_MP_COPY_C + #define BN_MP_DIV_2D_C + #define BN_MP_DIV_3_C + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_DR_IS_MODULUS_C) +#endif + +#if defined(BN_MP_DR_REDUCE_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_DR_SETUP_C) +#endif + +#if defined(BN_MP_EXCH_C) +#endif + +#if defined(BN_MP_EXPT_D_C) + #define BN_MP_INIT_COPY_C + #define BN_MP_SET_C + #define BN_MP_SQR_C + #define BN_MP_CLEAR_C + #define BN_MP_MUL_C +#endif + +#if defined(BN_MP_EXPTMOD_C) + #define BN_MP_INIT_C + #define BN_MP_INVMOD_C + #define BN_MP_CLEAR_C + #define BN_MP_ABS_C + #define BN_MP_CLEAR_MULTI_C + #define BN_MP_DR_IS_MODULUS_C + #define BN_MP_REDUCE_IS_2K_C + #define BN_MP_ISODD_C + #define BN_MP_EXPTMOD_FAST_C + #define BN_S_MP_EXPTMOD_C +#endif + +#if defined(BN_MP_EXPTMOD_FAST_C) + #define BN_MP_COUNT_BITS_C + #define BN_MP_INIT_C + #define BN_MP_CLEAR_C + #define BN_MP_MONTGOMERY_SETUP_C + #define BN_FAST_MP_MONTGOMERY_REDUCE_C + #define BN_MP_MONTGOMERY_REDUCE_C + #define BN_MP_DR_SETUP_C + #define BN_MP_DR_REDUCE_C + #define BN_MP_REDUCE_2K_SETUP_C + #define BN_MP_REDUCE_2K_C + #define BN_MP_MONTGOMERY_CALC_NORMALIZATION_C + #define BN_MP_MULMOD_C + #define BN_MP_SET_C + #define BN_MP_MOD_C + #define BN_MP_COPY_C + #define BN_MP_SQR_C + #define BN_MP_MUL_C + #define BN_MP_EXCH_C +#endif + +#if defined(BN_MP_EXTEUCLID_C) + #define BN_MP_INIT_MULTI_C + #define BN_MP_SET_C + #define BN_MP_COPY_C + #define BN_MP_ISZERO_C + #define BN_MP_DIV_C + #define BN_MP_MUL_C + #define BN_MP_SUB_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_MP_FREAD_C) + #define BN_MP_ZERO_C + #define BN_MP_S_RMAP_C + #define BN_MP_MUL_D_C + #define BN_MP_ADD_D_C + #define BN_MP_CMP_D_C +#endif + +#if defined(BN_MP_FWRITE_C) + #define BN_MP_RADIX_SIZE_C + #define BN_MP_TORADIX_C +#endif + +#if defined(BN_MP_GCD_C) + #define BN_MP_ISZERO_C + #define BN_MP_ABS_C + #define BN_MP_ZERO_C + #define BN_MP_INIT_COPY_C + #define BN_MP_CNT_LSB_C + #define BN_MP_DIV_2D_C + #define BN_MP_CMP_MAG_C + #define BN_MP_EXCH_C + #define BN_S_MP_SUB_C + #define BN_MP_MUL_2D_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_GET_INT_C) +#endif + +#if defined(BN_MP_GROW_C) +#endif + +#if defined(BN_MP_INIT_C) +#endif + +#if defined(BN_MP_INIT_COPY_C) + #define BN_MP_COPY_C +#endif + +#if defined(BN_MP_INIT_MULTI_C) + #define BN_MP_ERR_C + #define BN_MP_INIT_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_INIT_SET_C) + #define BN_MP_INIT_C + #define BN_MP_SET_C +#endif + +#if defined(BN_MP_INIT_SET_INT_C) + #define BN_MP_INIT_C + #define BN_MP_SET_INT_C +#endif + +#if defined(BN_MP_INIT_SIZE_C) + #define BN_MP_INIT_C +#endif + +#if defined(BN_MP_INVMOD_C) + #define BN_MP_ISZERO_C + #define BN_MP_ISODD_C + #define BN_FAST_MP_INVMOD_C + #define BN_MP_INVMOD_SLOW_C +#endif + +#if defined(BN_MP_INVMOD_SLOW_C) + #define BN_MP_ISZERO_C + #define BN_MP_INIT_MULTI_C + #define BN_MP_COPY_C + #define BN_MP_ISEVEN_C + #define BN_MP_SET_C + #define BN_MP_DIV_2_C + #define BN_MP_ISODD_C + #define BN_MP_ADD_C + #define BN_MP_SUB_C + #define BN_MP_CMP_C + #define BN_MP_CMP_D_C + #define BN_MP_CMP_MAG_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_MP_IS_SQUARE_C) + #define BN_MP_MOD_D_C + #define BN_MP_INIT_SET_INT_C + #define BN_MP_MOD_C + #define BN_MP_GET_INT_C + #define BN_MP_SQRT_C + #define BN_MP_SQR_C + #define BN_MP_CMP_MAG_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_JACOBI_C) + #define BN_MP_CMP_D_C + #define BN_MP_ISZERO_C + #define BN_MP_INIT_COPY_C + #define BN_MP_CNT_LSB_C + #define BN_MP_DIV_2D_C + #define BN_MP_MOD_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_KARATSUBA_MUL_C) + #define BN_MP_MUL_C + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_SUB_C + #define BN_MP_ADD_C + #define BN_MP_LSHD_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_KARATSUBA_SQR_C) + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_SQR_C + #define BN_MP_SUB_C + #define BN_S_MP_ADD_C + #define BN_MP_LSHD_C + #define BN_MP_ADD_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_LCM_C) + #define BN_MP_INIT_MULTI_C + #define BN_MP_GCD_C + #define BN_MP_CMP_MAG_C + #define BN_MP_DIV_C + #define BN_MP_MUL_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_MP_LSHD_C) + #define BN_MP_GROW_C + #define BN_MP_RSHD_C +#endif + +#if defined(BN_MP_MOD_C) + #define BN_MP_INIT_C + #define BN_MP_DIV_C + #define BN_MP_CLEAR_C + #define BN_MP_ADD_C + #define BN_MP_EXCH_C +#endif + +#if defined(BN_MP_MOD_2D_C) + #define BN_MP_ZERO_C + #define BN_MP_COPY_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_MOD_D_C) + #define BN_MP_DIV_D_C +#endif + +#if defined(BN_MP_MONTGOMERY_CALC_NORMALIZATION_C) + #define BN_MP_COUNT_BITS_C + #define BN_MP_2EXPT_C + #define BN_MP_SET_C + #define BN_MP_MUL_2_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_MONTGOMERY_REDUCE_C) + #define BN_FAST_MP_MONTGOMERY_REDUCE_C + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C + #define BN_MP_RSHD_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_MONTGOMERY_SETUP_C) +#endif + +#if defined(BN_MP_MUL_C) + #define BN_MP_TOOM_MUL_C + #define BN_MP_KARATSUBA_MUL_C + #define BN_FAST_S_MP_MUL_DIGS_C + #define BN_S_MP_MUL_C + #define BN_S_MP_MUL_DIGS_C +#endif + +#if defined(BN_MP_MUL_2_C) + #define BN_MP_GROW_C +#endif + +#if defined(BN_MP_MUL_2D_C) + #define BN_MP_COPY_C + #define BN_MP_GROW_C + #define BN_MP_LSHD_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_MUL_D_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_MULMOD_C) + #define BN_MP_INIT_C + #define BN_MP_MUL_C + #define BN_MP_CLEAR_C + #define BN_MP_MOD_C +#endif + +#if defined(BN_MP_N_ROOT_C) + #define BN_MP_INIT_C + #define BN_MP_SET_C + #define BN_MP_COPY_C + #define BN_MP_EXPT_D_C + #define BN_MP_MUL_C + #define BN_MP_SUB_C + #define BN_MP_MUL_D_C + #define BN_MP_DIV_C + #define BN_MP_CMP_C + #define BN_MP_SUB_D_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_NEG_C) + #define BN_MP_COPY_C + #define BN_MP_ISZERO_C +#endif + +#if defined(BN_MP_OR_C) + #define BN_MP_INIT_COPY_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_PRIME_FERMAT_C) + #define BN_MP_CMP_D_C + #define BN_MP_INIT_C + #define BN_MP_EXPTMOD_C + #define BN_MP_CMP_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_PRIME_IS_DIVISIBLE_C) + #define BN_MP_MOD_D_C +#endif + +#if defined(BN_MP_PRIME_IS_PRIME_C) + #define BN_MP_CMP_D_C + #define BN_MP_PRIME_IS_DIVISIBLE_C + #define BN_MP_INIT_C + #define BN_MP_SET_C + #define BN_MP_PRIME_MILLER_RABIN_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_PRIME_MILLER_RABIN_C) + #define BN_MP_CMP_D_C + #define BN_MP_INIT_COPY_C + #define BN_MP_SUB_D_C + #define BN_MP_CNT_LSB_C + #define BN_MP_DIV_2D_C + #define BN_MP_EXPTMOD_C + #define BN_MP_CMP_C + #define BN_MP_SQRMOD_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_PRIME_NEXT_PRIME_C) + #define BN_MP_CMP_D_C + #define BN_MP_SET_C + #define BN_MP_SUB_D_C + #define BN_MP_ISEVEN_C + #define BN_MP_MOD_D_C + #define BN_MP_INIT_C + #define BN_MP_ADD_D_C + #define BN_MP_PRIME_MILLER_RABIN_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_PRIME_RABIN_MILLER_TRIALS_C) +#endif + +#if defined(BN_MP_PRIME_RANDOM_EX_C) + #define BN_MP_READ_UNSIGNED_BIN_C + #define BN_MP_PRIME_IS_PRIME_C + #define BN_MP_SUB_D_C + #define BN_MP_DIV_2_C + #define BN_MP_MUL_2_C + #define BN_MP_ADD_D_C +#endif + +#if defined(BN_MP_RADIX_SIZE_C) + #define BN_MP_COUNT_BITS_C + #define BN_MP_INIT_COPY_C + #define BN_MP_ISZERO_C + #define BN_MP_DIV_D_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_RADIX_SMAP_C) + #define BN_MP_S_RMAP_C +#endif + +#if defined(BN_MP_RAND_C) + #define BN_MP_ZERO_C + #define BN_MP_ADD_D_C + #define BN_MP_LSHD_C +#endif + +#if defined(BN_MP_READ_RADIX_C) + #define BN_MP_ZERO_C + #define BN_MP_S_RMAP_C + #define BN_MP_MUL_D_C + #define BN_MP_ADD_D_C + #define BN_MP_ISZERO_C +#endif + +#if defined(BN_MP_READ_SIGNED_BIN_C) + #define BN_MP_READ_UNSIGNED_BIN_C +#endif + +#if defined(BN_MP_READ_UNSIGNED_BIN_C) + #define BN_MP_GROW_C + #define BN_MP_ZERO_C + #define BN_MP_MUL_2D_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_REDUCE_C) + #define BN_MP_REDUCE_SETUP_C + #define BN_MP_INIT_COPY_C + #define BN_MP_RSHD_C + #define BN_MP_MUL_C + #define BN_S_MP_MUL_HIGH_DIGS_C + #define BN_FAST_S_MP_MUL_HIGH_DIGS_C + #define BN_MP_MOD_2D_C + #define BN_S_MP_MUL_DIGS_C + #define BN_MP_SUB_C + #define BN_MP_CMP_D_C + #define BN_MP_SET_C + #define BN_MP_LSHD_C + #define BN_MP_ADD_C + #define BN_MP_CMP_C + #define BN_S_MP_SUB_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_REDUCE_2K_C) + #define BN_MP_INIT_C + #define BN_MP_COUNT_BITS_C + #define BN_MP_DIV_2D_C + #define BN_MP_MUL_D_C + #define BN_S_MP_ADD_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_REDUCE_2K_SETUP_C) + #define BN_MP_INIT_C + #define BN_MP_COUNT_BITS_C + #define BN_MP_2EXPT_C + #define BN_MP_CLEAR_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_REDUCE_IS_2K_C) + #define BN_MP_REDUCE_2K_C + #define BN_MP_COUNT_BITS_C +#endif + +#if defined(BN_MP_REDUCE_SETUP_C) + #define BN_MP_2EXPT_C + #define BN_MP_DIV_C +#endif + +#if defined(BN_MP_RSHD_C) + #define BN_MP_ZERO_C +#endif + +#if defined(BN_MP_SET_C) + #define BN_MP_ZERO_C +#endif + +#if defined(BN_MP_SET_INT_C) + #define BN_MP_ZERO_C + #define BN_MP_MUL_2D_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_SHRINK_C) +#endif + +#if defined(BN_MP_SIGNED_BIN_SIZE_C) + #define BN_MP_UNSIGNED_BIN_SIZE_C +#endif + +#if defined(BN_MP_SQR_C) + #define BN_MP_TOOM_SQR_C + #define BN_MP_KARATSUBA_SQR_C + #define BN_FAST_S_MP_SQR_C + #define BN_S_MP_SQR_C +#endif + +#if defined(BN_MP_SQRMOD_C) + #define BN_MP_INIT_C + #define BN_MP_SQR_C + #define BN_MP_CLEAR_C + #define BN_MP_MOD_C +#endif + +#if defined(BN_MP_SQRT_C) + #define BN_MP_N_ROOT_C + #define BN_MP_ISZERO_C + #define BN_MP_ZERO_C + #define BN_MP_INIT_COPY_C + #define BN_MP_RSHD_C + #define BN_MP_DIV_C + #define BN_MP_ADD_C + #define BN_MP_DIV_2_C + #define BN_MP_CMP_MAG_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_SUB_C) + #define BN_S_MP_ADD_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C +#endif + +#if defined(BN_MP_SUB_D_C) + #define BN_MP_GROW_C + #define BN_MP_ADD_D_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_MP_SUBMOD_C) + #define BN_MP_INIT_C + #define BN_MP_SUB_C + #define BN_MP_CLEAR_C + #define BN_MP_MOD_C +#endif + +#if defined(BN_MP_TO_SIGNED_BIN_C) + #define BN_MP_TO_UNSIGNED_BIN_C +#endif + +#if defined(BN_MP_TO_UNSIGNED_BIN_C) + #define BN_MP_INIT_COPY_C + #define BN_MP_ISZERO_C + #define BN_MP_DIV_2D_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_TOOM_MUL_C) + #define BN_MP_INIT_MULTI_C + #define BN_MP_MOD_2D_C + #define BN_MP_COPY_C + #define BN_MP_RSHD_C + #define BN_MP_MUL_C + #define BN_MP_MUL_2_C + #define BN_MP_ADD_C + #define BN_MP_SUB_C + #define BN_MP_DIV_2_C + #define BN_MP_MUL_2D_C + #define BN_MP_MUL_D_C + #define BN_MP_DIV_3_C + #define BN_MP_LSHD_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_MP_TOOM_SQR_C) + #define BN_MP_INIT_MULTI_C + #define BN_MP_MOD_2D_C + #define BN_MP_COPY_C + #define BN_MP_RSHD_C + #define BN_MP_SQR_C + #define BN_MP_MUL_2_C + #define BN_MP_ADD_C + #define BN_MP_SUB_C + #define BN_MP_DIV_2_C + #define BN_MP_MUL_2D_C + #define BN_MP_MUL_D_C + #define BN_MP_DIV_3_C + #define BN_MP_LSHD_C + #define BN_MP_CLEAR_MULTI_C +#endif + +#if defined(BN_MP_TORADIX_C) + #define BN_MP_ISZERO_C + #define BN_MP_INIT_COPY_C + #define BN_MP_DIV_D_C + #define BN_MP_CLEAR_C + #define BN_MP_S_RMAP_C +#endif + +#if defined(BN_MP_TORADIX_N_C) + #define BN_MP_ISZERO_C + #define BN_MP_INIT_COPY_C + #define BN_MP_DIV_D_C + #define BN_MP_CLEAR_C + #define BN_MP_S_RMAP_C +#endif + +#if defined(BN_MP_UNSIGNED_BIN_SIZE_C) + #define BN_MP_COUNT_BITS_C +#endif + +#if defined(BN_MP_XOR_C) + #define BN_MP_INIT_COPY_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_MP_ZERO_C) +#endif + +#if defined(BN_PRIME_TAB_C) +#endif + +#if defined(BN_REVERSE_C) +#endif + +#if defined(BN_S_MP_ADD_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BN_S_MP_EXPTMOD_C) + #define BN_MP_COUNT_BITS_C + #define BN_MP_INIT_C + #define BN_MP_CLEAR_C + #define BN_MP_REDUCE_SETUP_C + #define BN_MP_MOD_C + #define BN_MP_COPY_C + #define BN_MP_SQR_C + #define BN_MP_REDUCE_C + #define BN_MP_MUL_C + #define BN_MP_SET_C + #define BN_MP_EXCH_C +#endif + +#if defined(BN_S_MP_MUL_DIGS_C) + #define BN_FAST_S_MP_MUL_DIGS_C + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_S_MP_MUL_HIGH_DIGS_C) + #define BN_FAST_S_MP_MUL_HIGH_DIGS_C + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_S_MP_SQR_C) + #define BN_MP_INIT_SIZE_C + #define BN_MP_CLAMP_C + #define BN_MP_EXCH_C + #define BN_MP_CLEAR_C +#endif + +#if defined(BN_S_MP_SUB_C) + #define BN_MP_GROW_C + #define BN_MP_CLAMP_C +#endif + +#if defined(BNCORE_C) +#endif + +#ifdef LTM3 +#define LTM_LAST +#endif +#include +#include +#else +#define LTM_LAST +#endif diff --git a/libtommath/tommath_superclass.h b/libtommath/tommath_superclass.h new file mode 100644 index 0000000..b50ecb0 --- /dev/null +++ b/libtommath/tommath_superclass.h @@ -0,0 +1,72 @@ +/* super class file for PK algos */ + +/* default ... include all MPI */ +#define LTM_ALL + +/* RSA only (does not support DH/DSA/ECC) */ +// #define SC_RSA_1 + +/* For reference.... On an Athlon64 optimizing for speed... + + LTM's mpi.o with all functions [striped] is 142KiB in size. + +*/ + +/* Works for RSA only, mpi.o is 68KiB */ +#ifdef SC_RSA_1 + #define BN_MP_SHRINK_C + #define BN_MP_LCM_C + #define BN_MP_PRIME_RANDOM_EX_C + #define BN_MP_INVMOD_C + #define BN_MP_GCD_C + #define BN_MP_MOD_C + #define BN_MP_MULMOD_C + #define BN_MP_ADDMOD_C + #define BN_MP_EXPTMOD_C + #define BN_MP_SET_INT_C + #define BN_MP_INIT_MULTI_C + #define BN_MP_CLEAR_MULTI_C + #define BN_MP_UNSIGNED_BIN_SIZE_C + #define BN_MP_TO_UNSIGNED_BIN_C + #define BN_MP_MOD_D_C + #define BN_MP_PRIME_RABIN_MILLER_TRIALS_C + #define BN_REVERSE_C + #define BN_PRIME_TAB_C + + /* other modifiers */ + #define BN_MP_DIV_SMALL /* Slower division, not critical */ + + /* here we are on the last pass so we turn things off. The functions classes are still there + * but we remove them specifically from the build. This also invokes tweaks in functions + * like removing support for even moduli, etc... + */ +#ifdef LTM_LAST + #undef BN_MP_TOOM_MUL_C + #undef BN_MP_TOOM_SQR_C + #undef BN_MP_KARATSUBA_MUL_C + #undef BN_MP_KARATSUBA_SQR_C + #undef BN_MP_REDUCE_C + #undef BN_MP_REDUCE_SETUP_C + #undef BN_MP_DR_IS_MODULUS_C + #undef BN_MP_DR_SETUP_C + #undef BN_MP_DR_REDUCE_C + #undef BN_MP_REDUCE_IS_2K_C + #undef BN_MP_REDUCE_2K_SETUP_C + #undef BN_MP_REDUCE_2K_C + #undef BN_S_MP_EXPTMOD_C + #undef BN_MP_DIV_3_C + #undef BN_S_MP_MUL_HIGH_DIGS_C + #undef BN_FAST_S_MP_MUL_HIGH_DIGS_C + #undef BN_FAST_MP_INVMOD_C + + /* To safely undefine these you have to make sure your RSA key won't exceed the Comba threshold + * which is roughly 255 digits [7140 bits for 32-bit machines, 15300 bits for 64-bit machines] + * which means roughly speaking you can handle upto 2536-bit RSA keys with these defined without + * trouble. + */ + #undef BN_S_MP_MUL_DIGS_C + #undef BN_S_MP_SQR_C + #undef BN_MP_MONTGOMERY_REDUCE_C +#endif + +#endif -- cgit v0.12 From d2b645df1ab7b43093f7553808c64fedaa3b3a49 Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Sun, 10 Apr 2005 23:54:55 +0000 Subject: Import of tommath 0.35 --- libtommath/bn.pdf | Bin 335112 -> 337204 bytes libtommath/bn.tex | 29 +- libtommath/bn_fast_mp_invmod.c | 5 +- libtommath/bn_fast_mp_montgomery_reduce.c | 3 +- libtommath/bn_fast_s_mp_mul_digs.c | 11 +- libtommath/bn_fast_s_mp_mul_high_digs.c | 5 +- libtommath/bn_fast_s_mp_sqr.c | 33 +- libtommath/bn_mp_exptmod.c | 14 +- libtommath/bn_mp_exptmod_fast.c | 3 +- libtommath/bn_mp_exteuclid.c | 7 + libtommath/bn_mp_invmod_slow.c | 4 +- libtommath/bn_mp_montgomery_calc_normalization.c | 1 - libtommath/bn_mp_mul_d.c | 3 +- libtommath/bn_mp_neg.c | 10 +- libtommath/bn_mp_prime_random_ex.c | 4 +- libtommath/bn_mp_radix_size.c | 19 +- libtommath/bn_mp_rand.c | 4 +- libtommath/bn_mp_read_radix.c | 2 +- libtommath/bn_mp_reduce.c | 7 +- libtommath/bn_mp_reduce_2k.c | 3 +- libtommath/bn_mp_reduce_2k_setup.c | 3 +- libtommath/bn_mp_reduce_is_2k.c | 8 +- libtommath/bn_mp_to_signed_bin.c | 3 +- libtommath/bn_mp_to_unsigned_bin.c | 3 +- libtommath/bn_mp_toom_mul.c | 7 +- libtommath/bn_mp_unsigned_bin_size.c | 3 +- libtommath/bn_mp_xor.c | 2 +- libtommath/bn_mp_zero.c | 12 +- libtommath/bn_s_mp_exptmod.c | 35 +- libtommath/bn_s_mp_mul_digs.c | 3 +- libtommath/bn_s_mp_sqr.c | 3 +- libtommath/bncore.c | 5 +- libtommath/callgraph.txt | 5504 ++++++++++++++-------- libtommath/changes.txt | 23 + libtommath/demo/demo.c | 975 ++-- libtommath/demo/timing.c | 398 +- libtommath/dep.pl | 2 + libtommath/etc/timer.asm | 72 +- libtommath/etc/tune.c | 35 +- libtommath/logs/README | 24 +- libtommath/logs/add.log | 14 +- libtommath/logs/addsub.png | Bin 6254 -> 6253 bytes libtommath/logs/expt.log | 14 +- libtommath/logs/expt.png | Bin 6605 -> 6604 bytes libtommath/logs/expt_2k.log | 11 +- libtommath/logs/expt_dr.log | 14 +- libtommath/logs/invmod.png | Bin 4918 -> 4917 bytes libtommath/logs/mult.log | 227 +- libtommath/logs/mult.png | Bin 6770 -> 6769 bytes libtommath/logs/mult_kara.log | 117 +- libtommath/logs/sqr.log | 227 +- libtommath/logs/sqr_kara.log | 117 +- libtommath/logs/sub.log | 30 +- libtommath/makefile | 6 +- libtommath/makefile.bcc | 4 +- libtommath/makefile.cygwin_dll | 4 +- libtommath/makefile.icc | 4 +- libtommath/makefile.msvc | 4 +- libtommath/makefile.shared | 7 +- libtommath/pics/expt_state.tif | Bin 87542 -> 87540 bytes libtommath/pics/primality.tif | Bin 85514 -> 85512 bytes libtommath/poster.pdf | Bin 40821 -> 40821 bytes libtommath/pre_gen/mpi.c | 437 +- libtommath/tommath.h | 15 +- libtommath/tommath.pdf | Bin 1159120 -> 1160406 bytes libtommath/tommath.src | 499 +- libtommath/tommath.tex | 2797 +++++------ libtommath/tommath_class.h | 48 +- 68 files changed, 7145 insertions(+), 4738 deletions(-) diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf index 9b873e1..615ff4e 100644 Binary files a/libtommath/bn.pdf and b/libtommath/bn.pdf differ diff --git a/libtommath/bn.tex b/libtommath/bn.tex index 962d6ea..244bd6f 100644 --- a/libtommath/bn.tex +++ b/libtommath/bn.tex @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{LibTomMath User Manual \\ v0.33} +\title{LibTomMath User Manual \\ v0.35} \author{Tom St Denis \\ tomstdenis@iahu.ca} \maketitle This text, the library and the accompanying textbook are all hereby placed in the public domain. This book has been @@ -263,12 +263,12 @@ are the pros and cons of LibTomMath by comparing it to the math routines from Gn \begin{center} \begin{tabular}{|l|c|c|l|} \hline \textbf{Criteria} & \textbf{Pro} & \textbf{Con} & \textbf{Notes} \\ -\hline Few lines of code per file & X & & GnuPG $ = 300.9$, LibTomMath $ = 76.04$ \\ +\hline Few lines of code per file & X & & GnuPG $ = 300.9$, LibTomMath $ = 71.97$ \\ \hline Commented function prototypes & X && GnuPG function names are cryptic. \\ \hline Speed && X & LibTomMath is slower. \\ \hline Totally free & X & & GPL has unfavourable restrictions.\\ \hline Large function base & X & & GnuPG is barebones. \\ -\hline Four modular reduction algorithms & X & & Faster modular exponentiation. \\ +\hline Five modular reduction algorithms & X & & Faster modular exponentiation for a variety of moduli. \\ \hline Portable & X & & GnuPG requires configuration to build. \\ \hline \end{tabular} @@ -284,9 +284,12 @@ would require when working with large integers. So it may feel tempting to just rip the math code out of GnuPG (or GnuMP where it was taken from originally) in your own application but I think there are reasons not to. While LibTomMath is slower than libraries such as GnuMP it is not normally significantly slower. On x86 machines the difference is normally a factor of two when performing modular -exponentiations. +exponentiations. It depends largely on the processor, compiler and the moduli being used. -Essentially the only time you wouldn't use LibTomMath is when blazing speed is the primary concern. +Essentially the only time you wouldn't use LibTomMath is when blazing speed is the primary concern. However, +on the other side of the coin LibTomMath offers you a totally free (public domain) well structured math library +that is very flexible, complete and performs well in resource contrained environments. Fast RSA for example can +be performed with as little as 8KB of ram for data (again depending on build options). \chapter{Getting Started with LibTomMath} \section{Building Programs} @@ -809,7 +812,7 @@ mp\_int variables based on their digits only. \index{mp\_cmp\_mag} \begin{alltt} -int mp_cmp(mp_int * a, mp_int * b); +int mp_cmp_mag(mp_int * a, mp_int * b); \end{alltt} This will compare $a$ to $b$ placing $a$ to the left of $b$. This function cannot fail and will return one of the three compare codes listed in figure \ref{fig:CMP}. @@ -1220,12 +1223,13 @@ int mp_sqr (mp_int * a, mp_int * b); \end{alltt} Will square $a$ and store it in $b$. Like the case of multiplication there are four different squaring -algorithms all which can be called from mp\_sqr(). It is ideal to use mp\_sqr over mp\_mul when squaring terms. +algorithms all which can be called from mp\_sqr(). It is ideal to use mp\_sqr over mp\_mul when squaring terms because +of the speed difference. \section{Tuning Polynomial Basis Routines} Both of the Toom-Cook and Karatsuba multiplication algorithms are faster than the traditional $O(n^2)$ approach that -the Comba and baseline algorithms use. At $O(n^{1.464973})$ and $O(n^{1.584962})$ running times respectfully they require +the Comba and baseline algorithms use. At $O(n^{1.464973})$ and $O(n^{1.584962})$ running times respectively they require considerably less work. For example, a 10000-digit multiplication would take roughly 724,000 single precision multiplications with Toom-Cook or 100,000,000 single precision multiplications with the standard Comba (a factor of 138). @@ -1297,14 +1301,14 @@ of $b$. This algorithm accepts an input $a$ of any range and is not limited by \section{Barrett Reduction} Barrett reduction is a generic optimized reduction algorithm that requires pre--computation to achieve -a decent speedup over straight division. First a $mu$ value must be precomputed with the following function. +a decent speedup over straight division. First a $\mu$ value must be precomputed with the following function. \index{mp\_reduce\_setup} \begin{alltt} int mp_reduce_setup(mp_int *a, mp_int *b); \end{alltt} -Given a modulus in $b$ this produces the required $mu$ value in $a$. For any given modulus this only has to +Given a modulus in $b$ this produces the required $\mu$ value in $a$. For any given modulus this only has to be computed once. Modular reduction can now be performed with the following. \index{mp\_reduce} @@ -1312,7 +1316,7 @@ be computed once. Modular reduction can now be performed with the following. int mp_reduce(mp_int *a, mp_int *b, mp_int *c); \end{alltt} -This will reduce $a$ in place modulo $b$ with the precomputed $mu$ value in $c$. $a$ must be in the range +This will reduce $a$ in place modulo $b$ with the precomputed $\mu$ value in $c$. $a$ must be in the range $0 \le a < b^2$. \begin{alltt} @@ -1578,7 +1582,8 @@ will return $-2$. This algorithm uses the ``Newton Approximation'' method and will converge on the correct root fairly quickly. Since the algorithm requires raising $a$ to the power of $b$ it is not ideal to attempt to find roots for large values of $b$. If particularly large roots are required then a factor method could be used instead. For example, -$a^{1/16}$ is equivalent to $\left (a^{1/4} \right)^{1/4}$. +$a^{1/16}$ is equivalent to $\left (a^{1/4} \right)^{1/4}$ or simply +$\left ( \left ( \left ( a^{1/2} \right )^{1/2} \right )^{1/2} \right )^{1/2}$ \chapter{Prime Numbers} \section{Trial Division} diff --git a/libtommath/bn_fast_mp_invmod.c b/libtommath/bn_fast_mp_invmod.c index b5b9f10..acc8364 100644 --- a/libtommath/bn_fast_mp_invmod.c +++ b/libtommath/bn_fast_mp_invmod.c @@ -21,8 +21,7 @@ * Based on slow invmod except this is optimized for the case where b is * odd as per HAC Note 14.64 on pp. 610 */ -int -fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) +int fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) { mp_int x, y, u, v, B, D; int res, neg; @@ -43,7 +42,7 @@ fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) } /* we need y = |a| */ - if ((res = mp_abs (a, &y)) != MP_OKAY) { + if ((res = mp_mod (a, b, &y)) != MP_OKAY) { goto LBL_ERR; } diff --git a/libtommath/bn_fast_mp_montgomery_reduce.c b/libtommath/bn_fast_mp_montgomery_reduce.c index 7373ae6..14f307f 100644 --- a/libtommath/bn_fast_mp_montgomery_reduce.c +++ b/libtommath/bn_fast_mp_montgomery_reduce.c @@ -23,8 +23,7 @@ * * Based on Algorithm 14.32 on pp.601 of HAC. */ -int -fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) { int ix, res, olduse; mp_word W[MP_WARRAY]; diff --git a/libtommath/bn_fast_s_mp_mul_digs.c b/libtommath/bn_fast_s_mp_mul_digs.c index e1ff5f3..df3da26 100644 --- a/libtommath/bn_fast_s_mp_mul_digs.c +++ b/libtommath/bn_fast_s_mp_mul_digs.c @@ -31,8 +31,7 @@ * Based on Algorithm 14.12 on pp.595 of HAC. * */ -int -fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { int olduse, res, pa, ix, iz; mp_digit W[MP_WARRAY]; @@ -63,7 +62,7 @@ fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) tmpx = a->dp + tx; tmpy = b->dp + ty; - /* this is the number of times the loop will iterrate, essentially its + /* this is the number of times the loop will iterrate, essentially while (tx++ < a->used && ty-- >= 0) { ... } */ iy = MIN(a->used-tx, ty+1); @@ -81,16 +80,16 @@ fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } /* store final carry */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* setup dest */ olduse = c->used; - c->used = digs; + c->used = pa; { register mp_digit *tmpc; tmpc = c->dp; - for (ix = 0; ix < digs; ix++) { + for (ix = 0; ix < pa+1; ix++) { /* now extract the previous digit [below the carry] */ *tmpc++ = W[ix]; } diff --git a/libtommath/bn_fast_s_mp_mul_high_digs.c b/libtommath/bn_fast_s_mp_mul_high_digs.c index 064a9dd..ee657f9 100644 --- a/libtommath/bn_fast_s_mp_mul_high_digs.c +++ b/libtommath/bn_fast_s_mp_mul_high_digs.c @@ -24,8 +24,7 @@ * * Based on Algorithm 14.12 on pp.595 of HAC. */ -int -fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { int olduse, res, pa, ix, iz; mp_digit W[MP_WARRAY]; @@ -72,7 +71,7 @@ fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } /* store final carry */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* setup dest */ olduse = c->used; diff --git a/libtommath/bn_fast_s_mp_sqr.c b/libtommath/bn_fast_s_mp_sqr.c index d6014ab..66a2942 100644 --- a/libtommath/bn_fast_s_mp_sqr.c +++ b/libtommath/bn_fast_s_mp_sqr.c @@ -15,33 +15,14 @@ * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org */ -/* fast squaring - * - * This is the comba method where the columns of the product - * are computed first then the carries are computed. This - * has the effect of making a very simple inner loop that - * is executed the most - * - * W2 represents the outer products and W the inner. - * - * A further optimizations is made because the inner - * products are of the form "A * B * 2". The *2 part does - * not need to be computed until the end which is good - * because 64-bit shifts are slow! - * - * Based on Algorithm 14.16 on pp.597 of HAC. - * - */ /* the jist of squaring... - -you do like mult except the offset of the tmpx [one that starts closer to zero] -can't equal the offset of tmpy. So basically you set up iy like before then you min it with -(ty-tx) so that it never happens. You double all those you add in the inner loop + * you do like mult except the offset of the tmpx [one that + * starts closer to zero] can't equal the offset of tmpy. + * So basically you set up iy like before then you min it with + * (ty-tx) so that it never happens. You double all those + * you add in the inner loop After that loop you do the squares and add them in. - -Remove W2 and don't memset W - */ int fast_s_mp_sqr (mp_int * a, mp_int * b) @@ -76,7 +57,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) tmpx = a->dp + tx; tmpy = a->dp + ty; - /* this is the number of times the loop will iterrate, essentially its + /* this is the number of times the loop will iterrate, essentially while (tx++ < a->used && ty-- >= 0) { ... } */ iy = MIN(a->used-tx, ty+1); @@ -101,7 +82,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) } /* store it */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* make next carry */ W1 = _W >> ((mp_word)DIGIT_BIT); diff --git a/libtommath/bn_mp_exptmod.c b/libtommath/bn_mp_exptmod.c index 7309170..7c4e2f8 100644 --- a/libtommath/bn_mp_exptmod.c +++ b/libtommath/bn_mp_exptmod.c @@ -65,21 +65,29 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif } +/* modified diminished radix reduction */ +#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) + if (mp_reduce_is_2k_l(P) == MP_YES) { + return s_mp_exptmod(G, X, P, Y, 1); + } +#endif + #ifdef BN_MP_DR_IS_MODULUS_C /* is it a DR modulus? */ dr = mp_dr_is_modulus(P); #else + /* default to no */ dr = 0; #endif #ifdef BN_MP_REDUCE_IS_2K_C - /* if not, is it a uDR modulus? */ + /* if not, is it a unrestricted DR modulus? */ if (dr == 0) { dr = mp_reduce_is_2k(P) << 1; } #endif - /* if the modulus is odd or dr != 0 use the fast method */ + /* if the modulus is odd or dr != 0 use the montgomery method */ #ifdef BN_MP_EXPTMOD_FAST_C if (mp_isodd (P) == 1 || dr != 0) { return mp_exptmod_fast (G, X, P, Y, dr); @@ -87,7 +95,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif #ifdef BN_S_MP_EXPTMOD_C /* otherwise use the generic Barrett reduction technique */ - return s_mp_exptmod (G, X, P, Y); + return s_mp_exptmod (G, X, P, Y, 0); #else /* no exptmod for evens */ return MP_VAL; diff --git a/libtommath/bn_mp_exptmod_fast.c b/libtommath/bn_mp_exptmod_fast.c index 255e9d9..82be9ac 100644 --- a/libtommath/bn_mp_exptmod_fast.c +++ b/libtommath/bn_mp_exptmod_fast.c @@ -29,8 +29,7 @@ #define TAB_SIZE 256 #endif -int -mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) +int mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) { mp_int M[TAB_SIZE], res; mp_digit buf, mp; diff --git a/libtommath/bn_mp_exteuclid.c b/libtommath/bn_mp_exteuclid.c index 545450b..c4ebab4 100644 --- a/libtommath/bn_mp_exteuclid.c +++ b/libtommath/bn_mp_exteuclid.c @@ -59,6 +59,13 @@ int mp_exteuclid(mp_int *a, mp_int *b, mp_int *U1, mp_int *U2, mp_int *U3) if ((err = mp_copy(&t3, &v3)) != MP_OKAY) { goto _ERR; } } + /* make sure U3 >= 0 */ + if (u3.sign == MP_NEG) { + mp_neg(&u1, &u1); + mp_neg(&u2, &u2); + mp_neg(&u3, &u3); + } + /* copy result out */ if (U1 != NULL) { mp_exch(U1, &u1); } if (U2 != NULL) { mp_exch(U2, &u2); } diff --git a/libtommath/bn_mp_invmod_slow.c b/libtommath/bn_mp_invmod_slow.c index c1884c0..c048655 100644 --- a/libtommath/bn_mp_invmod_slow.c +++ b/libtommath/bn_mp_invmod_slow.c @@ -33,8 +33,8 @@ int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c) } /* x = a, y = b */ - if ((res = mp_copy (a, &x)) != MP_OKAY) { - goto LBL_ERR; + if ((res = mp_mod(a, b, &x)) != MP_OKAY) { + goto LBL_ERR; } if ((res = mp_copy (b, &y)) != MP_OKAY) { goto LBL_ERR; diff --git a/libtommath/bn_mp_montgomery_calc_normalization.c b/libtommath/bn_mp_montgomery_calc_normalization.c index 0a760cf..e2efc34 100644 --- a/libtommath/bn_mp_montgomery_calc_normalization.c +++ b/libtommath/bn_mp_montgomery_calc_normalization.c @@ -28,7 +28,6 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) /* how many bits of last digit does b use */ bits = mp_count_bits (b) % DIGIT_BIT; - if (b->used > 1) { if ((res = mp_2expt (a, (b->used - 1) * DIGIT_BIT + bits - 1)) != MP_OKAY) { return res; diff --git a/libtommath/bn_mp_mul_d.c b/libtommath/bn_mp_mul_d.c index f936361..9e11eef 100644 --- a/libtommath/bn_mp_mul_d.c +++ b/libtommath/bn_mp_mul_d.c @@ -57,8 +57,9 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); } - /* store final carry [if any] */ + /* store final carry [if any] and increment ix offset */ *tmpc++ = u; + ++ix; /* now zero digits above the top */ while (ix++ < olduse) { diff --git a/libtommath/bn_mp_neg.c b/libtommath/bn_mp_neg.c index 3a991db..159cd74 100644 --- a/libtommath/bn_mp_neg.c +++ b/libtommath/bn_mp_neg.c @@ -19,12 +19,18 @@ int mp_neg (mp_int * a, mp_int * b) { int res; - if ((res = mp_copy (a, b)) != MP_OKAY) { - return res; + if (a != b) { + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } } + if (mp_iszero(b) != MP_YES) { b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; + } else { + b->sign = MP_ZPOS; } + return MP_OKAY; } #endif diff --git a/libtommath/bn_mp_prime_random_ex.c b/libtommath/bn_mp_prime_random_ex.c index 2010ebe..78c0583 100644 --- a/libtommath/bn_mp_prime_random_ex.c +++ b/libtommath/bn_mp_prime_random_ex.c @@ -60,7 +60,7 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback /* calc the maskOR_msb */ maskOR_msb = 0; - maskOR_msb_offset = (size - 2) >> 3; + maskOR_msb_offset = ((size & 7) == 1) ? 1 : 0; if (flags & LTM_PRIME_2MSB_ON) { maskOR_msb |= 1 << ((size - 2) & 7); } else if (flags & LTM_PRIME_2MSB_OFF) { @@ -68,7 +68,7 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback } /* get the maskOR_lsb */ - maskOR_lsb = 0; + maskOR_lsb = 1; if (flags & LTM_PRIME_BBS) { maskOR_lsb |= 3; } diff --git a/libtommath/bn_mp_radix_size.c b/libtommath/bn_mp_radix_size.c index 30b78d9..3d423ba 100644 --- a/libtommath/bn_mp_radix_size.c +++ b/libtommath/bn_mp_radix_size.c @@ -35,22 +35,29 @@ int mp_radix_size (mp_int * a, int radix, int *size) return MP_VAL; } - /* init a copy of the input */ - if ((res = mp_init_copy (&t, a)) != MP_OKAY) { - return res; + if (mp_iszero(a) == MP_YES) { + *size = 2; + return MP_OKAY; } /* digs is the digit count */ digs = 0; /* if it's negative add one for the sign */ - if (t.sign == MP_NEG) { + if (a->sign == MP_NEG) { ++digs; - t.sign = MP_ZPOS; } + /* init a copy of the input */ + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* force temp to positive */ + t.sign = MP_ZPOS; + /* fetch out all of the digits */ - while (mp_iszero (&t) == 0) { + while (mp_iszero (&t) == MP_NO) { if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { mp_clear (&t); return res; diff --git a/libtommath/bn_mp_rand.c b/libtommath/bn_mp_rand.c index 1cc47f1..0dc7019 100644 --- a/libtommath/bn_mp_rand.c +++ b/libtommath/bn_mp_rand.c @@ -29,14 +29,14 @@ mp_rand (mp_int * a, int digits) /* first place a random non-zero digit */ do { - d = ((mp_digit) abs (rand ())); + d = ((mp_digit) abs (rand ())) & MP_MASK; } while (d == 0); if ((res = mp_add_d (a, d, a)) != MP_OKAY) { return res; } - while (digits-- > 0) { + while (--digits > 0) { if ((res = mp_lshd (a, 1)) != MP_OKAY) { return res; } diff --git a/libtommath/bn_mp_read_radix.c b/libtommath/bn_mp_read_radix.c index 704bd0f..1ec3937 100644 --- a/libtommath/bn_mp_read_radix.c +++ b/libtommath/bn_mp_read_radix.c @@ -16,7 +16,7 @@ */ /* read a string [ASCII] in a given radix */ -int mp_read_radix (mp_int * a, char *str, int radix) +int mp_read_radix (mp_int * a, const char *str, int radix) { int y, res, neg; char ch; diff --git a/libtommath/bn_mp_reduce.c b/libtommath/bn_mp_reduce.c index cfcb55a..d746445 100644 --- a/libtommath/bn_mp_reduce.c +++ b/libtommath/bn_mp_reduce.c @@ -19,8 +19,7 @@ * precomputed via mp_reduce_setup. * From HAC pp.604 Algorithm 14.42 */ -int -mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +int mp_reduce (mp_int * x, mp_int * m, mp_int * mu) { mp_int q; int res, um = m->used; @@ -40,11 +39,11 @@ mp_reduce (mp_int * x, mp_int * m, mp_int * mu) } } else { #ifdef BN_S_MP_MUL_HIGH_DIGS_C - if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + if ((res = s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) { goto CLEANUP; } #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) - if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) { goto CLEANUP; } #else diff --git a/libtommath/bn_mp_reduce_2k.c b/libtommath/bn_mp_reduce_2k.c index a5a9c74..28c3a00 100644 --- a/libtommath/bn_mp_reduce_2k.c +++ b/libtommath/bn_mp_reduce_2k.c @@ -16,8 +16,7 @@ */ /* reduces a modulo n where n is of the form 2**p - d */ -int -mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) { mp_int q; int p, res; diff --git a/libtommath/bn_mp_reduce_2k_setup.c b/libtommath/bn_mp_reduce_2k_setup.c index 5e1fb6e..585e1b7 100644 --- a/libtommath/bn_mp_reduce_2k_setup.c +++ b/libtommath/bn_mp_reduce_2k_setup.c @@ -16,8 +16,7 @@ */ /* determines the setup value */ -int -mp_reduce_2k_setup(mp_int *a, mp_digit *d) +int mp_reduce_2k_setup(mp_int *a, mp_digit *d) { int res, p; mp_int tmp; diff --git a/libtommath/bn_mp_reduce_is_2k.c b/libtommath/bn_mp_reduce_is_2k.c index fc81397..0fb8384 100644 --- a/libtommath/bn_mp_reduce_is_2k.c +++ b/libtommath/bn_mp_reduce_is_2k.c @@ -22,9 +22,9 @@ int mp_reduce_is_2k(mp_int *a) mp_digit iz; if (a->used == 0) { - return 0; + return MP_NO; } else if (a->used == 1) { - return 1; + return MP_YES; } else if (a->used > 1) { iy = mp_count_bits(a); iz = 1; @@ -33,7 +33,7 @@ int mp_reduce_is_2k(mp_int *a) /* Test every bit from the second digit up, must be 1 */ for (ix = DIGIT_BIT; ix < iy; ix++) { if ((a->dp[iw] & iz) == 0) { - return 0; + return MP_NO; } iz <<= 1; if (iz > (mp_digit)MP_MASK) { @@ -42,7 +42,7 @@ int mp_reduce_is_2k(mp_int *a) } } } - return 1; + return MP_YES; } #endif diff --git a/libtommath/bn_mp_to_signed_bin.c b/libtommath/bn_mp_to_signed_bin.c index 0e40d0f..b0a597e 100644 --- a/libtommath/bn_mp_to_signed_bin.c +++ b/libtommath/bn_mp_to_signed_bin.c @@ -16,8 +16,7 @@ */ /* store in signed [big endian] format */ -int -mp_to_signed_bin (mp_int * a, unsigned char *b) +int mp_to_signed_bin (mp_int * a, unsigned char *b) { int res; diff --git a/libtommath/bn_mp_to_unsigned_bin.c b/libtommath/bn_mp_to_unsigned_bin.c index 763e346..000967e 100644 --- a/libtommath/bn_mp_to_unsigned_bin.c +++ b/libtommath/bn_mp_to_unsigned_bin.c @@ -16,8 +16,7 @@ */ /* store in unsigned [big endian] format */ -int -mp_to_unsigned_bin (mp_int * a, unsigned char *b) +int mp_to_unsigned_bin (mp_int * a, unsigned char *b) { int x, res; mp_int t; diff --git a/libtommath/bn_mp_toom_mul.c b/libtommath/bn_mp_toom_mul.c index 2d66779..125331b 100644 --- a/libtommath/bn_mp_toom_mul.c +++ b/libtommath/bn_mp_toom_mul.c @@ -17,9 +17,10 @@ /* multiplication using the Toom-Cook 3-way algorithm * - * Much more complicated than Karatsuba but has a lower asymptotic running time of - * O(N**1.464). This algorithm is only particularly useful on VERY large - * inputs (we're talking 1000s of digits here...). + * Much more complicated than Karatsuba but has a lower + * asymptotic running time of O(N**1.464). This algorithm is + * only particularly useful on VERY large inputs + * (we're talking 1000s of digits here...). */ int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) { diff --git a/libtommath/bn_mp_unsigned_bin_size.c b/libtommath/bn_mp_unsigned_bin_size.c index 80da415..091f406 100644 --- a/libtommath/bn_mp_unsigned_bin_size.c +++ b/libtommath/bn_mp_unsigned_bin_size.c @@ -16,8 +16,7 @@ */ /* get the size for an unsigned equivalent */ -int -mp_unsigned_bin_size (mp_int * a) +int mp_unsigned_bin_size (mp_int * a) { int size = mp_count_bits (a); return (size / 8 + ((size & 7) != 0 ? 1 : 0)); diff --git a/libtommath/bn_mp_xor.c b/libtommath/bn_mp_xor.c index 192aacc..de7e62c 100644 --- a/libtommath/bn_mp_xor.c +++ b/libtommath/bn_mp_xor.c @@ -37,7 +37,7 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) } for (ix = 0; ix < px; ix++) { - + t.dp[ix] ^= x->dp[ix]; } mp_clamp (&t); mp_exch (c, &t); diff --git a/libtommath/bn_mp_zero.c b/libtommath/bn_mp_zero.c index 0097598..c8d8907 100644 --- a/libtommath/bn_mp_zero.c +++ b/libtommath/bn_mp_zero.c @@ -16,11 +16,17 @@ */ /* set to zero */ -void -mp_zero (mp_int * a) +void mp_zero (mp_int * a) { + int n; + mp_digit *tmp; + a->sign = MP_ZPOS; a->used = 0; - memset (a->dp, 0, sizeof (mp_digit) * a->alloc); + + tmp = a->dp; + for (n = 0; n < a->alloc; n++) { + *tmp++ = 0; + } } #endif diff --git a/libtommath/bn_s_mp_exptmod.c b/libtommath/bn_s_mp_exptmod.c index 01a766f..597e877 100644 --- a/libtommath/bn_s_mp_exptmod.c +++ b/libtommath/bn_s_mp_exptmod.c @@ -21,11 +21,12 @@ #define TAB_SIZE 256 #endif -int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) { mp_int M[TAB_SIZE], res, mu; mp_digit buf; int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + int (*redux)(mp_int*,mp_int*,mp_int*); /* find window size */ x = mp_count_bits (X); @@ -72,9 +73,18 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_init (&mu)) != MP_OKAY) { goto LBL_M; } - if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { - goto LBL_MU; - } + + if (redmode == 0) { + if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { + goto LBL_MU; + } + redux = mp_reduce; + } else { + if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + redux = mp_reduce_2k_l; + } /* create M table * @@ -96,11 +106,14 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) } for (x = 0; x < (winsize - 1); x++) { + /* square it */ if ((err = mp_sqr (&M[1 << (winsize - 1)], &M[1 << (winsize - 1)])) != MP_OKAY) { goto LBL_MU; } - if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { + + /* reduce modulo P */ + if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { goto LBL_MU; } } @@ -112,7 +125,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { goto LBL_MU; } - if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) { + if ((err = redux (&M[x], P, &mu)) != MP_OKAY) { goto LBL_MU; } } @@ -161,7 +174,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } continue; @@ -178,7 +191,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } } @@ -187,7 +200,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } @@ -205,7 +218,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } @@ -215,7 +228,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } } diff --git a/libtommath/bn_s_mp_mul_digs.c b/libtommath/bn_s_mp_mul_digs.c index d9f0a56..b40ae2e 100644 --- a/libtommath/bn_s_mp_mul_digs.c +++ b/libtommath/bn_s_mp_mul_digs.c @@ -19,8 +19,7 @@ * HAC pp. 595, Algorithm 14.12 Modified so you can control how * many digits of output are created. */ -int -s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { mp_int t; int res, pa, pb, ix, iy; diff --git a/libtommath/bn_s_mp_sqr.c b/libtommath/bn_s_mp_sqr.c index 4d12804..9cdb563 100644 --- a/libtommath/bn_s_mp_sqr.c +++ b/libtommath/bn_s_mp_sqr.c @@ -16,8 +16,7 @@ */ /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ -int -s_mp_sqr (mp_int * a, mp_int * b) +int s_mp_sqr (mp_int * a, mp_int * b) { mp_int t; int res, ix, iy, pa; diff --git a/libtommath/bncore.c b/libtommath/bncore.c index cf8a15a..82e3132 100644 --- a/libtommath/bncore.c +++ b/libtommath/bncore.c @@ -20,11 +20,12 @@ CPU /Compiler /MUL CUTOFF/SQR CUTOFF ------------------------------------------------------------- Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) + AMD Athlon64 /GCC v3.4.4 / 74/ 124/LTM 0.34 */ -int KARATSUBA_MUL_CUTOFF = 88, /* Min. number of digits before Karatsuba multiplication is used. */ - KARATSUBA_SQR_CUTOFF = 128, /* Min. number of digits before Karatsuba squaring is used. */ +int KARATSUBA_MUL_CUTOFF = 74, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 124, /* Min. number of digits before Karatsuba squaring is used. */ TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ TOOM_SQR_CUTOFF = 400; diff --git a/libtommath/callgraph.txt b/libtommath/callgraph.txt index 4dc4cba..2efcf24 100644 --- a/libtommath/callgraph.txt +++ b/libtommath/callgraph.txt @@ -907,7 +907,64 @@ BN_MP_EXPTMOD_C | | | +--->BN_MP_CLEAR_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C -| | +--->BN_MP_ABS_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C | | +--->BN_MP_SET_C | | | +--->BN_MP_ZERO_C | | +--->BN_MP_DIV_2_C @@ -938,6 +995,66 @@ BN_MP_EXPTMOD_C | +--->BN_MP_INVMOD_SLOW_C | | +--->BN_MP_INIT_MULTI_C | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C | | +--->BN_MP_SET_C @@ -973,93 +1090,63 @@ BN_MP_EXPTMOD_C | +--->BN_MP_COPY_C | | +--->BN_MP_GROW_C +--->BN_MP_CLEAR_MULTI_C -+--->BN_MP_DR_IS_MODULUS_C -+--->BN_MP_REDUCE_IS_2K_C -| +--->BN_MP_REDUCE_2K_C -| | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_DIV_2D_C -| | | +--->BN_MP_COPY_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MOD_2D_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| | +--->BN_MP_MUL_D_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_COUNT_BITS_C -+--->BN_MP_EXPTMOD_FAST_C ++--->BN_MP_REDUCE_IS_2K_L_C ++--->BN_S_MP_EXPTMOD_C | +--->BN_MP_COUNT_BITS_C -| +--->BN_MP_MONTGOMERY_SETUP_C -| +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_RSHD_C -| | | +--->BN_MP_ZERO_C -| | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| +--->BN_MP_MONTGOMERY_REDUCE_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -| | +--->BN_MP_RSHD_C -| | | +--->BN_MP_ZERO_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| +--->BN_MP_DR_SETUP_C -| +--->BN_MP_DR_REDUCE_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| +--->BN_MP_REDUCE_2K_SETUP_C +| +--->BN_MP_REDUCE_SETUP_C | | +--->BN_MP_2EXPT_C | | | +--->BN_MP_ZERO_C | | | +--->BN_MP_GROW_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_REDUCE_2K_C -| | +--->BN_MP_DIV_2D_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C -| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_MUL_D_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_CLAMP_C -| +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C -| | +--->BN_MP_2EXPT_C -| | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_GROW_C -| | +--->BN_MP_SET_C +| +--->BN_MP_REDUCE_C +| | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C | | | +--->BN_MP_ZERO_C -| | +--->BN_MP_MUL_2_C -| | | +--->BN_MP_GROW_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_MULMOD_C | | +--->BN_MP_MUL_C | | | +--->BN_MP_TOOM_MUL_C | | | | +--->BN_MP_INIT_MULTI_C @@ -1070,8 +1157,6 @@ BN_MP_EXPTMOD_C | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_MUL_2_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ADD_C @@ -1123,8 +1208,6 @@ BN_MP_EXPTMOD_C | | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_LSHD_C | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C @@ -1132,62 +1215,150 @@ BN_MP_EXPTMOD_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_MOD_C -| | | +--->BN_MP_DIV_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_MP_COPY_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_SET_C -| | | | +--->BN_MP_MUL_2D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_RSHD_C +| | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_D_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_REDUCE_2K_SETUP_L_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_REDUCE_2K_L_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | +--->BN_MP_SUB_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C | | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C | | | | | +--->BN_S_MP_SUB_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_ADD_C +| | | | +--->BN_MP_SUB_C | | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C | | | | | +--->BN_S_MP_SUB_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_2D_C -| | | | | +--->BN_MP_MOD_2D_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_INIT_COPY_C -| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_MUL_2D_C | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_MUL_D_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| +--->BN_MP_SET_C -| | +--->BN_MP_ZERO_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C | +--->BN_MP_MOD_C | | +--->BN_MP_DIV_C | | | +--->BN_MP_CMP_MAG_C @@ -1195,6 +1366,7 @@ BN_MP_EXPTMOD_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_ZERO_C | | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_SET_C | | | +--->BN_MP_MUL_2D_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_LSHD_C @@ -1379,73 +1551,239 @@ BN_MP_EXPTMOD_C | | | +--->BN_MP_INIT_SIZE_C | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_EXCH_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C | +--->BN_MP_EXCH_C -+--->BN_S_MP_EXPTMOD_C -| +--->BN_MP_COUNT_BITS_C -| +--->BN_MP_REDUCE_SETUP_C -| | +--->BN_MP_2EXPT_C -| | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_GROW_C -| | +--->BN_MP_DIV_C -| | | +--->BN_MP_CMP_MAG_C ++--->BN_MP_DR_IS_MODULUS_C ++--->BN_MP_REDUCE_IS_2K_C +| +--->BN_MP_REDUCE_2K_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_DIV_2D_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_INIT_MULTI_C -| | | +--->BN_MP_SET_C -| | | +--->BN_MP_MUL_2D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_DIV_2D_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MOD_2D_C | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_INIT_COPY_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_RSHD_C | | | +--->BN_MP_RSHD_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_CLAMP_C -| +--->BN_MP_MOD_C -| | +--->BN_MP_DIV_C -| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_COUNT_BITS_C ++--->BN_MP_EXPTMOD_FAST_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_MONTGOMERY_SETUP_C +| +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_MONTGOMERY_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_DR_SETUP_C +| +--->BN_MP_DR_REDUCE_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| +--->BN_MP_REDUCE_2K_SETUP_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_REDUCE_2K_C +| | +--->BN_MP_DIV_2D_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_INIT_MULTI_C -| | | +--->BN_MP_SET_C -| | | +--->BN_MP_MUL_2D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MOD_2D_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | +--->BN_MP_2EXPT_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_MULMOD_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_MOD_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_S_MP_SUB_C @@ -1554,163 +1892,49 @@ BN_MP_EXPTMOD_C | | | +--->BN_MP_INIT_SIZE_C | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_EXCH_C -| +--->BN_MP_REDUCE_C -| | +--->BN_MP_INIT_COPY_C -| | +--->BN_MP_RSHD_C -| | | +--->BN_MP_ZERO_C -| | +--->BN_MP_MUL_C -| | | +--->BN_MP_TOOM_MUL_C -| | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MUL_2_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_2_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_3_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C | | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_KARATSUBA_MUL_C -| | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_DIV_3_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_MP_LSHD_C | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MOD_2D_C -| | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_MUL_DIGS_C -| | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| | +--->BN_MP_SUB_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_D_C -| | +--->BN_MP_SET_C -| | | +--->BN_MP_ZERO_C -| | +--->BN_MP_LSHD_C -| | | +--->BN_MP_GROW_C -| | +--->BN_MP_ADD_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_C -| | | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_MUL_C -| | +--->BN_MP_TOOM_MUL_C -| | | +--->BN_MP_INIT_MULTI_C -| | | +--->BN_MP_MOD_2D_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MUL_2_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_DIV_2_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MUL_2D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_DIV_3_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_KARATSUBA_MUL_C | | | +--->BN_MP_INIT_SIZE_C | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_SUB_C @@ -1736,8 +1960,6 @@ BN_MP_EXPTMOD_C | | | +--->BN_MP_INIT_SIZE_C | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_EXCH_C -| +--->BN_MP_SET_C -| | +--->BN_MP_ZERO_C | +--->BN_MP_EXCH_C @@ -1769,7 +1991,64 @@ BN_MP_PRIME_FERMAT_C | | | | +--->BN_MP_CLEAR_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2D_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_COPY_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_SET_C | | | | +--->BN_MP_ZERO_C | | | +--->BN_MP_DIV_2_C @@ -1799,6 +2078,66 @@ BN_MP_PRIME_FERMAT_C | | +--->BN_MP_INVMOD_SLOW_C | | | +--->BN_MP_INIT_MULTI_C | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2D_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_COPY_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_SET_C @@ -1833,93 +2172,63 @@ BN_MP_PRIME_FERMAT_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C | +--->BN_MP_CLEAR_MULTI_C -| +--->BN_MP_DR_IS_MODULUS_C -| +--->BN_MP_REDUCE_IS_2K_C -| | +--->BN_MP_REDUCE_2K_C -| | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_DIV_2D_C +| +--->BN_MP_REDUCE_IS_2K_L_C +| +--->BN_S_MP_EXPTMOD_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_REDUCE_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2D_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_COPY_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_COUNT_BITS_C -| +--->BN_MP_EXPTMOD_FAST_C -| | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_MONTGOMERY_SETUP_C -| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_MONTGOMERY_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_DR_SETUP_C -| | +--->BN_MP_DR_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_REDUCE_2K_SETUP_C -| | | +--->BN_MP_2EXPT_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_REDUCE_2K_C -| | | +--->BN_MP_DIV_2D_C +| | +--->BN_MP_REDUCE_C +| | | +--->BN_MP_INIT_COPY_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C -| | | +--->BN_MP_2EXPT_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_SET_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MUL_2_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MULMOD_C | | | +--->BN_MP_MUL_C | | | | +--->BN_MP_TOOM_MUL_C | | | | | +--->BN_MP_INIT_MULTI_C @@ -1930,8 +2239,6 @@ BN_MP_PRIME_FERMAT_C | | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_MUL_2_C | | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_ADD_C @@ -1983,8 +2290,6 @@ BN_MP_PRIME_FERMAT_C | | | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_ZERO_C | | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C @@ -1992,62 +2297,149 @@ BN_MP_PRIME_FERMAT_C | | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_MOD_C -| | | | +--->BN_MP_DIV_C -| | | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_SETUP_L_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_L_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_SET_C -| | | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_SUB_C +| | | | | +--->BN_MP_ADD_C | | | | | | +--->BN_S_MP_ADD_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C | | | | | | +--->BN_S_MP_SUB_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_SUB_C | | | | | | +--->BN_S_MP_ADD_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C | | | | | | +--->BN_S_MP_SUB_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_2D_C -| | | | | | +--->BN_MP_MOD_2D_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_INIT_COPY_C -| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_MUL_2D_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_MUL_D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_SET_C -| | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C | | +--->BN_MP_MOD_C | | | +--->BN_MP_DIV_C | | | | +--->BN_MP_CMP_MAG_C @@ -2055,6 +2447,7 @@ BN_MP_PRIME_FERMAT_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C | | | | +--->BN_MP_MUL_2D_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_LSHD_C @@ -2239,57 +2632,224 @@ BN_MP_PRIME_FERMAT_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C | | +--->BN_MP_EXCH_C -| +--->BN_S_MP_EXPTMOD_C -| | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_REDUCE_SETUP_C -| | | +--->BN_MP_2EXPT_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_DIV_C -| | | | +--->BN_MP_CMP_MAG_C +| +--->BN_MP_DR_IS_MODULUS_C +| +--->BN_MP_REDUCE_IS_2K_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_DIV_2D_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_SET_C -| | | | +--->BN_MP_MUL_2D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MOD_2D_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_EXPTMOD_FAST_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_MONTGOMERY_SETUP_C +| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_DR_SETUP_C +| | +--->BN_MP_DR_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_REDUCE_2K_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_MUL_2D_C | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_MUL_D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_2D_C -| | | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_INIT_COPY_C -| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2D_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_INIT_COPY_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C | | | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C | | +--->BN_MP_MOD_C | | | +--->BN_MP_DIV_C | | | | +--->BN_MP_CMP_MAG_C @@ -2297,7 +2857,6 @@ BN_MP_PRIME_FERMAT_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_SET_C | | | | +--->BN_MP_MUL_2D_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_LSHD_C @@ -2414,135 +2973,22 @@ BN_MP_PRIME_FERMAT_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_REDUCE_C -| | | +--->BN_MP_INIT_COPY_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MUL_C -| | | | +--->BN_MP_TOOM_MUL_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_MOD_2D_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_2_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_2_C +| | +--->BN_MP_MUL_C +| | | +--->BN_MP_TOOM_MUL_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_3_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_KARATSUBA_MUL_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MOD_2D_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_MUL_DIGS_C -| | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_SET_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MUL_C -| | | +--->BN_MP_TOOM_MUL_C -| | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_MUL_2_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_SUB_C @@ -2595,8 +3041,6 @@ BN_MP_PRIME_FERMAT_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_SET_C -| | | +--->BN_MP_ZERO_C | | +--->BN_MP_EXCH_C +--->BN_MP_CMP_C | +--->BN_MP_CMP_MAG_C @@ -2901,7 +3345,65 @@ BN_MP_INVMOD_C | | +--->BN_MP_CLEAR_C | +--->BN_MP_COPY_C | | +--->BN_MP_GROW_C -| +--->BN_MP_ABS_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C | +--->BN_MP_SET_C | | +--->BN_MP_ZERO_C | +--->BN_MP_DIV_2_C @@ -2933,6 +3435,67 @@ BN_MP_INVMOD_C | +--->BN_MP_INIT_MULTI_C | | +--->BN_MP_INIT_C | | +--->BN_MP_CLEAR_C +| +--->BN_MP_MOD_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_DIV_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_SET_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2D_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C | +--->BN_MP_COPY_C | | +--->BN_MP_GROW_C | +--->BN_MP_SET_C @@ -2985,43 +3548,101 @@ BN_FAST_MP_INVMOD_C | +--->BN_MP_CLEAR_C +--->BN_MP_COPY_C | +--->BN_MP_GROW_C -+--->BN_MP_ABS_C -+--->BN_MP_SET_C -| +--->BN_MP_ZERO_C -+--->BN_MP_DIV_2_C -| +--->BN_MP_GROW_C -| +--->BN_MP_CLAMP_C -+--->BN_MP_SUB_C -| +--->BN_S_MP_ADD_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -| +--->BN_MP_CMP_MAG_C -| +--->BN_S_MP_SUB_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -+--->BN_MP_CMP_C -| +--->BN_MP_CMP_MAG_C -+--->BN_MP_CMP_D_C -+--->BN_MP_ADD_C -| +--->BN_S_MP_ADD_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -| +--->BN_MP_CMP_MAG_C -| +--->BN_S_MP_SUB_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -+--->BN_MP_EXCH_C -+--->BN_MP_CLEAR_MULTI_C -| +--->BN_MP_CLEAR_C - - -BN_MP_FWRITE_C -+--->BN_MP_RADIX_SIZE_C -| +--->BN_MP_COUNT_BITS_C -| +--->BN_MP_INIT_COPY_C -| | +--->BN_MP_COPY_C -| | | +--->BN_MP_GROW_C -| +--->BN_MP_DIV_D_C ++--->BN_MP_MOD_C +| +--->BN_MP_INIT_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C ++--->BN_MP_SET_C +| +--->BN_MP_ZERO_C ++--->BN_MP_DIV_2_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_SUB_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_C +| +--->BN_MP_CMP_MAG_C ++--->BN_MP_CMP_D_C ++--->BN_MP_ADD_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_EXCH_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_FWRITE_C ++--->BN_MP_RADIX_SIZE_C +| +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_D_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C | | +--->BN_MP_DIV_2D_C @@ -3473,7 +4094,55 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | +--->BN_MP_CLEAR_C | | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MOD_C +| | | | | | +--->BN_MP_DIV_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | | +--->BN_MP_ABS_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | | +--->BN_MP_CLEAR_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C | | | | | +--->BN_MP_DIV_2_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C @@ -3501,6 +4170,57 @@ BN_MP_PRIME_RANDOM_EX_C | | | | +--->BN_MP_INVMOD_SLOW_C | | | | | +--->BN_MP_INIT_MULTI_C | | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_MOD_C +| | | | | | +--->BN_MP_DIV_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | | +--->BN_MP_ABS_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | | +--->BN_MP_CLEAR_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C | | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_DIV_2_C @@ -3533,75 +4253,54 @@ BN_MP_PRIME_RANDOM_EX_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_CLEAR_MULTI_C -| | | +--->BN_MP_DR_IS_MODULUS_C -| | | +--->BN_MP_REDUCE_IS_2K_C -| | | | +--->BN_MP_REDUCE_2K_C -| | | | | +--->BN_MP_COUNT_BITS_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_EXPTMOD_FAST_C +| | | +--->BN_MP_REDUCE_IS_2K_L_C +| | | +--->BN_S_MP_EXPTMOD_C | | | | +--->BN_MP_COUNT_BITS_C -| | | | +--->BN_MP_MONTGOMERY_SETUP_C -| | | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_MONTGOMERY_REDUCE_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_DR_SETUP_C -| | | | +--->BN_MP_DR_REDUCE_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_REDUCE_2K_SETUP_C +| | | | +--->BN_MP_REDUCE_SETUP_C | | | | | +--->BN_MP_2EXPT_C | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_REDUCE_2K_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C -| | | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_MUL_2_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MULMOD_C -| | | | | +--->BN_MP_MUL_C -| | | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_REDUCE_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_C +| | | | | | +--->BN_MP_TOOM_MUL_C | | | | | | | +--->BN_MP_INIT_MULTI_C | | | | | | | +--->BN_MP_MOD_2D_C | | | | | | | | +--->BN_MP_ZERO_C @@ -3610,8 +4309,6 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | | | +--->BN_MP_CLAMP_C | | | | | | | +--->BN_MP_COPY_C | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | | | +--->BN_MP_ZERO_C | | | | | | | +--->BN_MP_MUL_2_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_ADD_C @@ -3663,8 +4360,6 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_LSHD_C | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C @@ -3672,52 +4367,138 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | | +--->BN_MP_CLAMP_C | | | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_MOD_C -| | | | | | +--->BN_MP_DIV_C -| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_REDUCE_2K_SETUP_L_C +| | | | | +--->BN_MP_2EXPT_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_REDUCE_2K_L_C +| | | | | +--->BN_MP_MUL_C +| | | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | | +--->BN_MP_COPY_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C | | | | | | | +--->BN_MP_COPY_C | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_ZERO_C -| | | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_MUL_2_C | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_C -| | | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_MP_ADD_C | | | | | | | | +--->BN_S_MP_ADD_C | | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C | | | | | | | | +--->BN_S_MP_SUB_C | | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_MP_SUB_C | | | | | | | | +--->BN_S_MP_ADD_C | | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C | | | | | | | | +--->BN_S_MP_SUB_C | | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_EXCH_C -| | | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_DIV_2_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_MUL_2D_C | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_MUL_D_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_DIV_3_C +| | | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_MOD_C | | | | | +--->BN_MP_DIV_C | | | | | | +--->BN_MP_CMP_MAG_C @@ -3903,53 +4684,196 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_EXCH_C | | | | +--->BN_MP_EXCH_C -| | | +--->BN_S_MP_EXPTMOD_C +| | | +--->BN_MP_DR_IS_MODULUS_C +| | | +--->BN_MP_REDUCE_IS_2K_C +| | | | +--->BN_MP_REDUCE_2K_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_COUNT_BITS_C -| | | | +--->BN_MP_REDUCE_SETUP_C +| | | +--->BN_MP_EXPTMOD_FAST_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_DR_SETUP_C +| | | | +--->BN_MP_DR_REDUCE_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_REDUCE_2K_SETUP_C | | | | | +--->BN_MP_2EXPT_C | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_DIV_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_MP_COPY_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | +--->BN_MP_MUL_2D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_MUL_D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MOD_C -| | | | | +--->BN_MP_DIV_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_MP_COPY_C -| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_REDUCE_2K_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | | +--->BN_MP_2EXPT_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MULMOD_C +| | | | | +--->BN_MP_MUL_C +| | | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | | +--->BN_MP_COPY_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_MUL_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_2_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_DIV_3_C +| | | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_MOD_C +| | | | | | +--->BN_MP_DIV_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_C +| | | | | | | +--->BN_MP_SUB_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_ADD_C +| | | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_MUL_D_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_MP_INIT_MULTI_C | | | | | | +--->BN_MP_MUL_2D_C @@ -4061,116 +4985,6 @@ BN_MP_PRIME_RANDOM_EX_C | | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_REDUCE_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_MUL_C -| | | | | | +--->BN_MP_TOOM_MUL_C -| | | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | | +--->BN_MP_MOD_2D_C -| | | | | | | | +--->BN_MP_ZERO_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_MUL_2_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_ADD_C -| | | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_SUB_C -| | | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_DIV_2_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_MUL_2D_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_MUL_D_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_DIV_3_C -| | | | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | | +--->BN_MP_EXCH_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_KARATSUBA_MUL_C -| | | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_SUB_C -| | | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_ADD_C -| | | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MOD_2D_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_MUL_C | | | | | +--->BN_MP_TOOM_MUL_C | | | | | | +--->BN_MP_INIT_MULTI_C @@ -4753,7 +5567,55 @@ BN_MP_PRIME_IS_PRIME_C | | | | | +--->BN_MP_CLEAR_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | +--->BN_MP_ABS_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C | | | | +--->BN_MP_DIV_2_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C @@ -4781,6 +5643,57 @@ BN_MP_PRIME_IS_PRIME_C | | | +--->BN_MP_INVMOD_SLOW_C | | | | +--->BN_MP_INIT_MULTI_C | | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | +--->BN_MP_ABS_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_DIV_2_C @@ -4813,73 +5726,52 @@ BN_MP_PRIME_IS_PRIME_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | +--->BN_MP_CLEAR_MULTI_C -| | +--->BN_MP_DR_IS_MODULUS_C -| | +--->BN_MP_REDUCE_IS_2K_C -| | | +--->BN_MP_REDUCE_2K_C -| | | | +--->BN_MP_COUNT_BITS_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_EXPTMOD_FAST_C +| | +--->BN_MP_REDUCE_IS_2K_L_C +| | +--->BN_S_MP_EXPTMOD_C | | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_MONTGOMERY_SETUP_C -| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_MONTGOMERY_REDUCE_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_DR_SETUP_C -| | | +--->BN_MP_DR_REDUCE_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_REDUCE_2K_SETUP_C +| | | +--->BN_MP_REDUCE_SETUP_C | | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_REDUCE_2K_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C -| | | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_MUL_2_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_REDUCE_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_MUL_C | | | | | +--->BN_MP_TOOM_MUL_C | | | | | | +--->BN_MP_INIT_MULTI_C @@ -4890,8 +5782,6 @@ BN_MP_PRIME_IS_PRIME_C | | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_COPY_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_MP_MUL_2_C | | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_ADD_C @@ -4943,8 +5833,6 @@ BN_MP_PRIME_IS_PRIME_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_LSHD_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C @@ -4952,60 +5840,146 @@ BN_MP_PRIME_IS_PRIME_C | | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_MOD_C -| | | | | +--->BN_MP_DIV_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_MP_COPY_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | +--->BN_MP_MUL_2D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_MUL_D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_MOD_C -| | | | +--->BN_MP_DIV_C -| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_SETUP_L_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_L_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_LSHD_C | | | | | | | +--->BN_MP_RSHD_C @@ -5183,48 +6157,191 @@ BN_MP_PRIME_IS_PRIME_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_EXCH_C -| | +--->BN_S_MP_EXPTMOD_C +| | +--->BN_MP_DR_IS_MODULUS_C +| | +--->BN_MP_REDUCE_IS_2K_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_REDUCE_SETUP_C +| | +--->BN_MP_EXPTMOD_FAST_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_DR_SETUP_C +| | | +--->BN_MP_DR_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_REDUCE_2K_SETUP_C | | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_DIV_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_MP_COPY_C -| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MULMOD_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_MUL_2D_C | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_MUL_D_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_MOD_C | | | | +--->BN_MP_DIV_C | | | | | +--->BN_MP_CMP_MAG_C @@ -5341,116 +6458,6 @@ BN_MP_PRIME_IS_PRIME_C | | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_REDUCE_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_MUL_C -| | | | | +--->BN_MP_TOOM_MUL_C -| | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | +--->BN_MP_MOD_2D_C -| | | | | | | +--->BN_MP_ZERO_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_2_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_DIV_2_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_2D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_DIV_3_C -| | | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_EXCH_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_KARATSUBA_MUL_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_MUL_C | | | | +--->BN_MP_TOOM_MUL_C | | | | | +--->BN_MP_INIT_MULTI_C @@ -6496,7 +7503,55 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | +--->BN_MP_CLEAR_C | | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ABS_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | +--->BN_MP_ABS_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C | | | | +--->BN_MP_DIV_2_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C @@ -6524,105 +7579,135 @@ BN_MP_PRIME_NEXT_PRIME_C | | | +--->BN_MP_INVMOD_SLOW_C | | | | +--->BN_MP_INIT_MULTI_C | | | | | +--->BN_MP_CLEAR_C -| | | | +--->BN_MP_COPY_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_DIV_2_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_CLEAR_MULTI_C -| | | | | +--->BN_MP_CLEAR_C -| | +--->BN_MP_CLEAR_C -| | +--->BN_MP_ABS_C -| | | +--->BN_MP_COPY_C -| | | | +--->BN_MP_GROW_C -| | +--->BN_MP_CLEAR_MULTI_C -| | +--->BN_MP_DR_IS_MODULUS_C -| | +--->BN_MP_REDUCE_IS_2K_C -| | | +--->BN_MP_REDUCE_2K_C -| | | | +--->BN_MP_COUNT_BITS_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COUNT_BITS_C +| | | | | | +--->BN_MP_ABS_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | | +--->BN_MP_CLEAR_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_COPY_C | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_DIV_2_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_EXPTMOD_FAST_C -| | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_MONTGOMERY_SETUP_C -| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_MONTGOMERY_REDUCE_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C | | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_DR_SETUP_C -| | | +--->BN_MP_DR_REDUCE_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_ABS_C +| | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_REDUCE_2K_SETUP_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_REDUCE_IS_2K_L_C +| | +--->BN_S_MP_EXPTMOD_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_REDUCE_SETUP_C | | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_REDUCE_2K_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C -| | | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_MUL_2_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_REDUCE_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_MUL_C | | | | | +--->BN_MP_TOOM_MUL_C | | | | | | +--->BN_MP_INIT_MULTI_C @@ -6633,8 +7718,6 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_COPY_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_ZERO_C | | | | | | +--->BN_MP_MUL_2_C | | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_ADD_C @@ -6686,8 +7769,6 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_LSHD_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C @@ -6695,52 +7776,138 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_MOD_C -| | | | | +--->BN_MP_DIV_C -| | | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MOD_2D_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_SETUP_L_C +| | | | +--->BN_MP_2EXPT_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_L_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_COPY_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_C -| | | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_MP_ADD_C | | | | | | | +--->BN_S_MP_ADD_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C | | | | | | | +--->BN_S_MP_SUB_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_SUB_C | | | | | | | +--->BN_S_MP_ADD_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C | | | | | | | +--->BN_S_MP_SUB_C | | | | | | | | +--->BN_MP_GROW_C | | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_DIV_2_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_MUL_2D_C | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_MUL_D_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_MOD_C | | | | +--->BN_MP_DIV_C | | | | | +--->BN_MP_CMP_MAG_C @@ -6926,48 +8093,191 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_EXCH_C -| | +--->BN_S_MP_EXPTMOD_C +| | +--->BN_MP_DR_IS_MODULUS_C +| | +--->BN_MP_REDUCE_IS_2K_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_COUNT_BITS_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_REDUCE_SETUP_C +| | +--->BN_MP_EXPTMOD_FAST_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MONTGOMERY_SETUP_C +| | | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_DR_SETUP_C +| | | +--->BN_MP_DR_REDUCE_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_REDUCE_2K_SETUP_C | | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_DIV_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_MP_COPY_C -| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_REDUCE_2K_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | | +--->BN_MP_2EXPT_C | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_MUL_2_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MULMOD_C +| | | | +--->BN_MP_MUL_C +| | | | | +--->BN_MP_TOOM_MUL_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MOD_2D_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | | +--->BN_MP_COPY_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_MUL_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_2_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_2D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_MUL_D_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_DIV_3_C +| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_MP_EXCH_C | | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_RSHD_C +| | | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_MOD_C +| | | | | +--->BN_MP_DIV_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_INIT_MULTI_C +| | | | | | +--->BN_MP_MUL_2D_C | | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_LSHD_C +| | | | | | | | +--->BN_MP_RSHD_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_CMP_C +| | | | | | +--->BN_MP_SUB_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_ADD_C +| | | | | | | +--->BN_S_MP_ADD_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | | +--->BN_S_MP_SUB_C +| | | | | | | | +--->BN_MP_GROW_C +| | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_MUL_D_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_ADD_C | | | | | | +--->BN_S_MP_ADD_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C | | | | | | +--->BN_S_MP_SUB_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_MOD_C | | | | +--->BN_MP_DIV_C | | | | | +--->BN_MP_CMP_MAG_C @@ -7030,170 +8340,60 @@ BN_MP_PRIME_NEXT_PRIME_C | | | | | | +--->BN_S_MP_ADD_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_2_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_3_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_KARATSUBA_SQR_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_FAST_S_MP_SQR_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_SQR_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_REDUCE_C -| | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_MUL_C -| | | | | +--->BN_MP_TOOM_MUL_C -| | | | | | +--->BN_MP_INIT_MULTI_C -| | | | | | +--->BN_MP_MOD_2D_C -| | | | | | | +--->BN_MP_ZERO_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_2_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_DIV_2_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_2D_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C | | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_DIV_3_C -| | | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C | | | | | | | +--->BN_MP_CLAMP_C -| | | | | | | +--->BN_MP_EXCH_C -| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C | | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_KARATSUBA_MUL_C -| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_SUB_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_ADD_C -| | | | | | | +--->BN_S_MP_ADD_C -| | | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | | +--->BN_S_MP_SUB_C -| | | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_DIV_3_C | | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C | | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MOD_2D_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_KARATSUBA_SQR_C | | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_SQR_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_SQR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_MUL_C | | | | +--->BN_MP_TOOM_MUL_C | | | | | +--->BN_MP_INIT_MULTI_C @@ -7406,6 +8606,67 @@ BN_MP_INVMOD_SLOW_C +--->BN_MP_INIT_MULTI_C | +--->BN_MP_INIT_C | +--->BN_MP_CLEAR_C ++--->BN_MP_MOD_C +| +--->BN_MP_INIT_C +| +--->BN_MP_DIV_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_CLEAR_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +--->BN_MP_COPY_C | +--->BN_MP_GROW_C +--->BN_MP_SET_C @@ -7484,49 +8745,143 @@ BN_MP_LCM_C | +--->BN_MP_MUL_2D_C | | +--->BN_MP_GROW_C | | +--->BN_MP_LSHD_C -| | | +--->BN_MP_RSHD_C -| | +--->BN_MP_CLAMP_C -| +--->BN_MP_CMP_C -| +--->BN_MP_SUB_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_ADD_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_INIT_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_CLEAR_C +| +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_C +| +--->BN_MP_INIT_C +| +--->BN_MP_INIT_COPY_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_MUL_D_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_CLEAR_C ++--->BN_MP_MUL_C +| +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_MUL_2_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_3_C +| | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_INIT_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_CLEAR_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLEAR_MULTI_C +| | | +--->BN_MP_CLEAR_C +| +--->BN_MP_KARATSUBA_MUL_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_LSHD_C | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_DIV_2D_C -| | +--->BN_MP_INIT_C -| | +--->BN_MP_MOD_2D_C -| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C | | +--->BN_MP_CLEAR_C -| | +--->BN_MP_RSHD_C +| +--->BN_FAST_S_MP_MUL_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_INIT_C | | +--->BN_MP_CLAMP_C | | +--->BN_MP_EXCH_C -| +--->BN_MP_EXCH_C -| +--->BN_MP_CLEAR_MULTI_C | | +--->BN_MP_CLEAR_C -| +--->BN_MP_INIT_SIZE_C -| | +--->BN_MP_INIT_C -| +--->BN_MP_INIT_C -| +--->BN_MP_INIT_COPY_C -| +--->BN_MP_LSHD_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_RSHD_C -| +--->BN_MP_RSHD_C -| +--->BN_MP_MUL_D_C ++--->BN_MP_CLEAR_MULTI_C +| +--->BN_MP_CLEAR_C + + +BN_MP_REDUCE_2K_L_C ++--->BN_MP_INIT_C ++--->BN_MP_COUNT_BITS_C ++--->BN_MP_DIV_2D_C +| +--->BN_MP_COPY_C | | +--->BN_MP_GROW_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_MOD_2D_C | | +--->BN_MP_CLAMP_C -| +--->BN_MP_CLAMP_C | +--->BN_MP_CLEAR_C +| +--->BN_MP_RSHD_C +| +--->BN_MP_CLAMP_C +| +--->BN_MP_EXCH_C +--->BN_MP_MUL_C | +--->BN_MP_TOOM_MUL_C +| | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_CLEAR_C | | +--->BN_MP_MOD_2D_C | | | +--->BN_MP_ZERO_C | | | +--->BN_MP_COPY_C @@ -7542,6 +8897,7 @@ BN_MP_LCM_C | | | +--->BN_S_MP_ADD_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C @@ -7549,6 +8905,7 @@ BN_MP_LCM_C | | | +--->BN_S_MP_ADD_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C @@ -7564,7 +8921,6 @@ BN_MP_LCM_C | | | +--->BN_MP_CLAMP_C | | +--->BN_MP_DIV_3_C | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_INIT_C | | | +--->BN_MP_CLAMP_C | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_CLEAR_C @@ -7574,16 +8930,17 @@ BN_MP_LCM_C | | | +--->BN_MP_CLEAR_C | +--->BN_MP_KARATSUBA_MUL_C | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_INIT_C | | +--->BN_MP_CLAMP_C | | +--->BN_MP_SUB_C | | | +--->BN_S_MP_ADD_C | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | +--->BN_MP_ADD_C | | | +--->BN_S_MP_ADD_C | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | +--->BN_MP_LSHD_C @@ -7596,12 +8953,17 @@ BN_MP_LCM_C | | +--->BN_MP_CLAMP_C | +--->BN_S_MP_MUL_DIGS_C | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_INIT_C | | +--->BN_MP_CLAMP_C | | +--->BN_MP_EXCH_C | | +--->BN_MP_CLEAR_C -+--->BN_MP_CLEAR_MULTI_C -| +--->BN_MP_CLEAR_C ++--->BN_S_MP_ADD_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CMP_MAG_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C BN_REVERSE_C @@ -7671,6 +9033,18 @@ BN_MP_GCD_C +--->BN_MP_CLEAR_C +BN_MP_REDUCE_2K_SETUP_L_C ++--->BN_MP_INIT_C ++--->BN_MP_2EXPT_C +| +--->BN_MP_ZERO_C +| +--->BN_MP_GROW_C ++--->BN_MP_COUNT_BITS_C ++--->BN_S_MP_SUB_C +| +--->BN_MP_GROW_C +| +--->BN_MP_CLAMP_C ++--->BN_MP_CLEAR_C + + BN_MP_READ_RADIX_C +--->BN_MP_ZERO_C +--->BN_MP_MUL_D_C @@ -7942,46 +9316,266 @@ BN_S_MP_EXPTMOD_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C | | +--->BN_MP_ZERO_C -| | +--->BN_MP_INIT_MULTI_C -| | +--->BN_MP_SET_C -| | +--->BN_MP_ABS_C -| | +--->BN_MP_MUL_2D_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_RSHD_C +| | +--->BN_MP_INIT_MULTI_C +| | +--->BN_MP_SET_C +| | +--->BN_MP_ABS_C +| | +--->BN_MP_MUL_2D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_C +| | +--->BN_MP_SUB_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_ADD_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_LSHD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_REDUCE_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_RSHD_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_2D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_S_MP_MUL_HIGH_DIGS_C +| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_MOD_2D_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_S_MP_MUL_DIGS_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_INIT_SIZE_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_SUB_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_D_C +| +--->BN_MP_SET_C +| | +--->BN_MP_ZERO_C +| +--->BN_MP_LSHD_C +| | +--->BN_MP_GROW_C +| +--->BN_MP_ADD_C +| | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CMP_MAG_C +| | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_C +| | +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_REDUCE_2K_SETUP_L_C +| +--->BN_MP_2EXPT_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_GROW_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C ++--->BN_MP_REDUCE_2K_L_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_C -| | +--->BN_MP_SUB_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_MUL_C +| | +--->BN_MP_TOOM_MUL_C +| | | +--->BN_MP_INIT_MULTI_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_DIV_2_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_ADD_C -| | | +--->BN_S_MP_ADD_C +| | | +--->BN_MP_MUL_2D_C | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_SUB_C +| | | +--->BN_MP_MUL_D_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_DIV_2D_C -| | | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_DIV_3_C +| | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLEAR_MULTI_C +| | +--->BN_MP_KARATSUBA_MUL_C +| | | +--->BN_MP_INIT_SIZE_C | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| | +--->BN_MP_EXCH_C -| | +--->BN_MP_CLEAR_MULTI_C -| | +--->BN_MP_INIT_SIZE_C -| | +--->BN_MP_INIT_COPY_C -| | +--->BN_MP_LSHD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_RSHD_C -| | +--->BN_MP_RSHD_C -| | +--->BN_MP_MUL_D_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_ZERO_C +| | +--->BN_FAST_S_MP_MUL_DIGS_C | | | +--->BN_MP_GROW_C | | | +--->BN_MP_CLAMP_C +| | +--->BN_S_MP_MUL_DIGS_C +| | | +--->BN_MP_INIT_SIZE_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| +--->BN_S_MP_ADD_C +| | +--->BN_MP_GROW_C +| | +--->BN_MP_CLAMP_C +| +--->BN_MP_CMP_MAG_C +| +--->BN_S_MP_SUB_C +| | +--->BN_MP_GROW_C | | +--->BN_MP_CLAMP_C +--->BN_MP_MOD_C | +--->BN_MP_DIV_C @@ -8110,121 +9704,6 @@ BN_S_MP_EXPTMOD_C | | +--->BN_MP_INIT_SIZE_C | | +--->BN_MP_CLAMP_C | | +--->BN_MP_EXCH_C -+--->BN_MP_REDUCE_C -| +--->BN_MP_INIT_COPY_C -| +--->BN_MP_RSHD_C -| | +--->BN_MP_ZERO_C -| +--->BN_MP_MUL_C -| | +--->BN_MP_TOOM_MUL_C -| | | +--->BN_MP_INIT_MULTI_C -| | | +--->BN_MP_MOD_2D_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MUL_2_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_DIV_2_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MUL_2D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_DIV_3_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLEAR_MULTI_C -| | +--->BN_MP_KARATSUBA_MUL_C -| | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_S_MP_MUL_DIGS_C -| | | +--->BN_MP_INIT_SIZE_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_EXCH_C -| +--->BN_S_MP_MUL_HIGH_DIGS_C -| | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_INIT_SIZE_C -| | +--->BN_MP_CLAMP_C -| | +--->BN_MP_EXCH_C -| +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C -| +--->BN_MP_MOD_2D_C -| | +--->BN_MP_ZERO_C -| | +--->BN_MP_CLAMP_C -| +--->BN_S_MP_MUL_DIGS_C -| | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_INIT_SIZE_C -| | +--->BN_MP_CLAMP_C -| | +--->BN_MP_EXCH_C -| +--->BN_MP_SUB_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_CMP_D_C -| +--->BN_MP_SET_C -| | +--->BN_MP_ZERO_C -| +--->BN_MP_LSHD_C -| | +--->BN_MP_GROW_C -| +--->BN_MP_ADD_C -| | +--->BN_S_MP_ADD_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_CMP_MAG_C -| | +--->BN_S_MP_SUB_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| +--->BN_MP_CMP_C -| | +--->BN_MP_CMP_MAG_C -| +--->BN_S_MP_SUB_C -| | +--->BN_MP_GROW_C -| | +--->BN_MP_CLAMP_C +--->BN_MP_MUL_C | +--->BN_MP_TOOM_MUL_C | | +--->BN_MP_INIT_MULTI_C @@ -8529,6 +10008,31 @@ BN_MP_ADD_C | +--->BN_MP_CLAMP_C +BN_MP_TO_SIGNED_BIN_N_C ++--->BN_MP_SIGNED_BIN_SIZE_C +| +--->BN_MP_UNSIGNED_BIN_SIZE_C +| | +--->BN_MP_COUNT_BITS_C ++--->BN_MP_TO_SIGNED_BIN_C +| +--->BN_MP_TO_UNSIGNED_BIN_C +| | +--->BN_MP_INIT_COPY_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | +--->BN_MP_DIV_2D_C +| | | +--->BN_MP_COPY_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_RSHD_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_EXCH_C +| | +--->BN_MP_CLEAR_C + + +BN_MP_REDUCE_IS_2K_L_C + + BN_MP_RAND_C +--->BN_MP_ZERO_C +--->BN_MP_ADD_D_C @@ -8556,6 +10060,26 @@ BN_MP_RSHD_C BN_MP_SHRINK_C +BN_MP_TO_UNSIGNED_BIN_N_C ++--->BN_MP_UNSIGNED_BIN_SIZE_C +| +--->BN_MP_COUNT_BITS_C ++--->BN_MP_TO_UNSIGNED_BIN_C +| +--->BN_MP_INIT_COPY_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| +--->BN_MP_DIV_2D_C +| | +--->BN_MP_COPY_C +| | | +--->BN_MP_GROW_C +| | +--->BN_MP_ZERO_C +| | +--->BN_MP_MOD_2D_C +| | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_CLEAR_C +| | +--->BN_MP_RSHD_C +| | +--->BN_MP_CLAMP_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_CLEAR_C + + BN_MP_REDUCE_C +--->BN_MP_REDUCE_SETUP_C | +--->BN_MP_2EXPT_C @@ -9062,6 +10586,7 @@ BN_MP_EXTEUCLID_C | +--->BN_S_MP_SUB_C | | +--->BN_MP_GROW_C | | +--->BN_MP_CLAMP_C ++--->BN_MP_NEG_C +--->BN_MP_EXCH_C +--->BN_MP_CLEAR_MULTI_C | +--->BN_MP_CLEAR_C @@ -9269,7 +10794,56 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | +--->BN_MP_CLEAR_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ABS_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_SET_C | | | | +--->BN_MP_ZERO_C | | | +--->BN_MP_DIV_2_C @@ -9299,6 +10873,58 @@ BN_MP_PRIME_MILLER_RABIN_C | | +--->BN_MP_INVMOD_SLOW_C | | | +--->BN_MP_INIT_MULTI_C | | | | +--->BN_MP_CLEAR_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_COUNT_BITS_C +| | | | | +--->BN_MP_ABS_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_CLEAR_MULTI_C +| | | | | | +--->BN_MP_CLEAR_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_CLEAR_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C | | | +--->BN_MP_COPY_C | | | | +--->BN_MP_GROW_C | | | +--->BN_MP_SET_C @@ -9333,75 +10959,176 @@ BN_MP_PRIME_MILLER_RABIN_C | | +--->BN_MP_COPY_C | | | +--->BN_MP_GROW_C | +--->BN_MP_CLEAR_MULTI_C -| +--->BN_MP_DR_IS_MODULUS_C -| +--->BN_MP_REDUCE_IS_2K_C -| | +--->BN_MP_REDUCE_2K_C -| | | +--->BN_MP_COUNT_BITS_C -| | | +--->BN_MP_MUL_D_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_COUNT_BITS_C -| +--->BN_MP_EXPTMOD_FAST_C +| +--->BN_MP_REDUCE_IS_2K_L_C +| +--->BN_S_MP_EXPTMOD_C | | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_MONTGOMERY_SETUP_C -| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_MONTGOMERY_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_DR_SETUP_C -| | +--->BN_MP_DR_REDUCE_C -| | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | +--->BN_MP_REDUCE_2K_SETUP_C +| | +--->BN_MP_REDUCE_SETUP_C | | | +--->BN_MP_2EXPT_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_GROW_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_DIV_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_D_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | +--->BN_S_MP_MUL_HIGH_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_REDUCE_2K_C -| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_ADD_C -| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_MOD_2D_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_COPY_C +| | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | | +--->BN_MP_SUB_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_LSHD_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_ADD_C +| | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_CMP_MAG_C +| | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_C +| | | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | +--->BN_MP_REDUCE_2K_SETUP_L_C | | | +--->BN_MP_2EXPT_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_SET_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MUL_2_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_CMP_MAG_C | | | +--->BN_S_MP_SUB_C | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_CLAMP_C -| | +--->BN_MP_MULMOD_C +| | +--->BN_MP_REDUCE_2K_L_C | | | +--->BN_MP_MUL_C | | | | +--->BN_MP_TOOM_MUL_C | | | | | +--->BN_MP_INIT_MULTI_C @@ -9474,55 +11201,13 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_MOD_C -| | | | +--->BN_MP_DIV_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_MP_COPY_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ZERO_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_SET_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_SET_C -| | | +--->BN_MP_ZERO_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C | | +--->BN_MP_MOD_C | | | +--->BN_MP_DIV_C | | | | +--->BN_MP_CMP_MAG_C @@ -9530,6 +11215,7 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_INIT_MULTI_C +| | | | +--->BN_MP_SET_C | | | | +--->BN_MP_MUL_2D_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_LSHD_C @@ -9653,104 +11339,253 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_2_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_2D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_DIV_3_C +| | | | | +--->BN_MP_INIT_SIZE_C +| | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_KARATSUBA_MUL_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_SUB_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_ADD_C +| | | | | +--->BN_S_MP_ADD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_CMP_MAG_C +| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_LSHD_C +| | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | +--->BN_FAST_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_MUL_DIGS_C +| | | | +--->BN_MP_INIT_SIZE_C +| | | | +--->BN_MP_CLAMP_C +| | | | +--->BN_MP_EXCH_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C +| | +--->BN_MP_EXCH_C +| +--->BN_MP_DR_IS_MODULUS_C +| +--->BN_MP_REDUCE_IS_2K_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_COUNT_BITS_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_COUNT_BITS_C +| +--->BN_MP_EXPTMOD_FAST_C +| | +--->BN_MP_COUNT_BITS_C +| | +--->BN_MP_MONTGOMERY_SETUP_C +| | +--->BN_FAST_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_MONTGOMERY_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_RSHD_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_DR_SETUP_C +| | +--->BN_MP_DR_REDUCE_C +| | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | +--->BN_MP_REDUCE_2K_SETUP_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_REDUCE_2K_C +| | | +--->BN_MP_MUL_D_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_S_MP_ADD_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MONTGOMERY_CALC_NORMALIZATION_C +| | | +--->BN_MP_2EXPT_C +| | | | +--->BN_MP_ZERO_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_SET_C +| | | | +--->BN_MP_ZERO_C +| | | +--->BN_MP_MUL_2_C +| | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_CMP_MAG_C +| | | +--->BN_S_MP_SUB_C +| | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_MULMOD_C +| | | +--->BN_MP_MUL_C +| | | | +--->BN_MP_TOOM_MUL_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_MOD_2D_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | | +--->BN_MP_COPY_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_COPY_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_MUL_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_DIV_2_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_MUL_2D_C | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_MUL_D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_DIV_3_C +| | | | | | +--->BN_MP_INIT_SIZE_C | | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_2_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MUL_2D_C -| | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_EXCH_C | | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | +--->BN_MP_KARATSUBA_MUL_C +| | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_MUL_D_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_CMP_MAG_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | +--->BN_MP_LSHD_C +| | | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | | | +--->BN_MP_ZERO_C +| | | | +--->BN_FAST_S_MP_MUL_DIGS_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_DIV_3_C +| | | | +--->BN_S_MP_MUL_DIGS_C | | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_CLAMP_C | | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_KARATSUBA_MUL_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C -| | | | | | +--->BN_MP_GROW_C +| | | +--->BN_MP_MOD_C +| | | | +--->BN_MP_DIV_C | | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ADD_C -| | | | | +--->BN_S_MP_ADD_C +| | | | | +--->BN_MP_COPY_C | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CMP_MAG_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | +--->BN_MP_ZERO_C +| | | | | +--->BN_MP_INIT_MULTI_C +| | | | | +--->BN_MP_SET_C +| | | | | +--->BN_MP_MUL_2D_C | | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | | | +--->BN_MP_ZERO_C -| | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_MUL_DIGS_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_EXCH_C -| +--->BN_S_MP_EXPTMOD_C -| | +--->BN_MP_COUNT_BITS_C -| | +--->BN_MP_REDUCE_SETUP_C -| | | +--->BN_MP_2EXPT_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_DIV_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_MP_COPY_C -| | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_SET_C -| | | | +--->BN_MP_MUL_2D_C -| | | | | +--->BN_MP_GROW_C +| | | | | | +--->BN_MP_LSHD_C +| | | | | | | +--->BN_MP_RSHD_C +| | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_C +| | | | | +--->BN_MP_SUB_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_ADD_C +| | | | | | +--->BN_S_MP_ADD_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | | +--->BN_S_MP_SUB_C +| | | | | | | +--->BN_MP_GROW_C +| | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_EXCH_C +| | | | | +--->BN_MP_INIT_SIZE_C | | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_RSHD_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_C -| | | | +--->BN_MP_SUB_C -| | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_S_MP_SUB_C +| | | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_RSHD_C +| | | | | +--->BN_MP_MUL_D_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_ADD_C | | | | | +--->BN_S_MP_ADD_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C +| | | | | +--->BN_MP_CMP_MAG_C | | | | | +--->BN_S_MP_SUB_C | | | | | | +--->BN_MP_GROW_C | | | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_LSHD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_MUL_D_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CLAMP_C +| | +--->BN_MP_SET_C +| | | +--->BN_MP_ZERO_C | | +--->BN_MP_MOD_C | | | +--->BN_MP_DIV_C | | | | +--->BN_MP_CMP_MAG_C @@ -9758,7 +11593,6 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | | +--->BN_MP_GROW_C | | | | +--->BN_MP_ZERO_C | | | | +--->BN_MP_INIT_MULTI_C -| | | | +--->BN_MP_SET_C | | | | +--->BN_MP_MUL_2D_C | | | | | +--->BN_MP_GROW_C | | | | | +--->BN_MP_LSHD_C @@ -9868,118 +11702,6 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_REDUCE_C -| | | +--->BN_MP_RSHD_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_MUL_C -| | | | +--->BN_MP_TOOM_MUL_C -| | | | | +--->BN_MP_INIT_MULTI_C -| | | | | +--->BN_MP_MOD_2D_C -| | | | | | +--->BN_MP_ZERO_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_2_C -| | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_2_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_2D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_MUL_D_C -| | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_DIV_3_C -| | | | | | +--->BN_MP_INIT_SIZE_C -| | | | | | +--->BN_MP_CLAMP_C -| | | | | | +--->BN_MP_EXCH_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_KARATSUBA_MUL_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_SUB_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_ADD_C -| | | | | | +--->BN_S_MP_ADD_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | | +--->BN_MP_CMP_MAG_C -| | | | | | +--->BN_S_MP_SUB_C -| | | | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_LSHD_C -| | | | | | +--->BN_MP_GROW_C -| | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_INIT_SIZE_C -| | | | | +--->BN_MP_CLAMP_C -| | | | | +--->BN_MP_EXCH_C -| | | +--->BN_S_MP_MUL_HIGH_DIGS_C -| | | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_FAST_S_MP_MUL_HIGH_DIGS_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_MOD_2D_C -| | | | +--->BN_MP_ZERO_C -| | | | +--->BN_MP_CLAMP_C -| | | +--->BN_S_MP_MUL_DIGS_C -| | | | +--->BN_FAST_S_MP_MUL_DIGS_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_INIT_SIZE_C -| | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_EXCH_C -| | | +--->BN_MP_SUB_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_SET_C -| | | | +--->BN_MP_ZERO_C -| | | +--->BN_MP_LSHD_C -| | | | +--->BN_MP_GROW_C -| | | +--->BN_MP_ADD_C -| | | | +--->BN_S_MP_ADD_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | | +--->BN_S_MP_SUB_C -| | | | | +--->BN_MP_GROW_C -| | | | | +--->BN_MP_CLAMP_C -| | | +--->BN_MP_CMP_C -| | | | +--->BN_MP_CMP_MAG_C -| | | +--->BN_S_MP_SUB_C -| | | | +--->BN_MP_GROW_C -| | | | +--->BN_MP_CLAMP_C | | +--->BN_MP_MUL_C | | | +--->BN_MP_TOOM_MUL_C | | | | +--->BN_MP_INIT_MULTI_C @@ -10048,8 +11770,6 @@ BN_MP_PRIME_MILLER_RABIN_C | | | | +--->BN_MP_INIT_SIZE_C | | | | +--->BN_MP_CLAMP_C | | | | +--->BN_MP_EXCH_C -| | +--->BN_MP_SET_C -| | | +--->BN_MP_ZERO_C | | +--->BN_MP_EXCH_C +--->BN_MP_CMP_C | +--->BN_MP_CMP_MAG_C diff --git a/libtommath/changes.txt b/libtommath/changes.txt index 0d1ec2e..99e40c1 100644 --- a/libtommath/changes.txt +++ b/libtommath/changes.txt @@ -1,3 +1,26 @@ +March 12th, 2005 +v0.35 -- Stupid XOR function missing line again... oops. + -- Fixed bug in invmod not handling negative inputs correctly [Wolfgang Ehrhardt] + -- Made exteuclid always give positive u3 output...[ Wolfgang Ehrhardt ] + -- [Wolfgang Ehrhardt] Suggested a fix for mp_reduce() which avoided underruns. ;-) + -- mp_rand() would emit one too many digits and it was possible to get a 0 out of it ... oops + -- Added montgomery to the testing to make sure it handles 1..10 digit moduli correctly + -- Fixed bug in comba that would lead to possible erroneous outputs when "pa < digs" + -- Fixed bug in mp_toradix_size for "0" [Kevin Kenny] + -- Updated chapters 1-5 of the textbook ;-) It now talks about the new comba code! + +February 12th, 2005 +v0.34 -- Fixed two more small errors in mp_prime_random_ex() + -- Fixed overflow in mp_mul_d() [Kevin Kenny] + -- Added mp_to_(un)signed_bin_n() functions which do bounds checking for ya [and report the size] + -- Added "large" diminished radix support. Speeds up things like DSA where the moduli is of the form 2^k - P for some P < 2^(k/2) or so + Actually is faster than Montgomery on my AMD64 (and probably much faster on a P4) + -- Updated the manual a bit + -- Ok so I haven't done the textbook work yet... My current freelance gig has landed me in France till the + end of Feb/05. Once I get back I'll have tons of free time and I plan to go to town on the book. + As of this release the API will freeze. At least until the book catches up with all the changes. I welcome + bug reports but new algorithms will have to wait. + December 23rd, 2004 v0.33 -- Fixed "small" variant for mp_div() which would munge with negative dividends... -- Fixed bug in mp_prime_random_ex() which would set the most significant byte to zero when diff --git a/libtommath/demo/demo.c b/libtommath/demo/demo.c index 62615cd..0a6115a 100644 --- a/libtommath/demo/demo.c +++ b/libtommath/demo/demo.c @@ -9,15 +9,16 @@ #include "tommath.h" -void ndraw(mp_int *a, char *name) +void ndraw(mp_int * a, char *name) { char buf[16000]; + printf("%s: ", name); mp_toradix(a, buf, 10); printf("%s\n", buf); } -static void draw(mp_int *a) +static void draw(mp_int * a) { ndraw(a, ""); } @@ -39,20 +40,23 @@ int lbit(void) int myrng(unsigned char *dst, int len, void *dat) { int x; - for (x = 0; x < len; x++) dst[x] = rand() & 0xFF; + + for (x = 0; x < len; x++) + dst[x] = rand() & 0xFF; return len; } - char cmd[4096], buf[4096]; +char cmd[4096], buf[4096]; int main(void) { mp_int a, b, c, d, e, f; - unsigned long expt_n, add_n, sub_n, mul_n, div_n, sqr_n, mul2d_n, div2d_n, gcd_n, lcm_n, inv_n, - div2_n, mul2_n, add_d_n, sub_d_n, t; + unsigned long expt_n, add_n, sub_n, mul_n, div_n, sqr_n, mul2d_n, div2d_n, + gcd_n, lcm_n, inv_n, div2_n, mul2_n, add_d_n, sub_d_n, t; unsigned rr; int i, n, err, cnt, ix, old_kara_m, old_kara_s; + mp_digit mp; mp_init(&a); @@ -65,108 +69,152 @@ int main(void) srand(time(NULL)); #if 0 - // test mp_get_int - printf("Testing: mp_get_int\n"); - for(i=0;i<1000;++i) { - t = ((unsigned long)rand()*rand()+1)&0xFFFFFFFF; - mp_set_int(&a,t); - if (t!=mp_get_int(&a)) { + // test montgomery + printf("Testing montgomery...\n"); + for (i = 1; i < 10; i++) { + printf("Testing digit size: %d\n", i); + for (n = 0; n < 1000; n++) { + mp_rand(&a, i); + a.dp[0] |= 1; + + // let's see if R is right + mp_montgomery_calc_normalization(&b, &a); + mp_montgomery_setup(&a, &mp); + + // now test a random reduction + for (ix = 0; ix < 100; ix++) { + mp_rand(&c, 1 + abs(rand()) % (2*i)); + mp_copy(&c, &d); + mp_copy(&c, &e); + + mp_mod(&d, &a, &d); + mp_montgomery_reduce(&c, &a, mp); + mp_mulmod(&c, &b, &a, &c); + + if (mp_cmp(&c, &d) != MP_EQ) { +printf("d = e mod a, c = e MOD a\n"); +mp_todecimal(&a, buf); printf("a = %s\n", buf); +mp_todecimal(&e, buf); printf("e = %s\n", buf); +mp_todecimal(&d, buf); printf("d = %s\n", buf); +mp_todecimal(&c, buf); printf("c = %s\n", buf); +printf("compare no compare!\n"); exit(EXIT_FAILURE); } + } + } + } + printf("done\n"); + + // test mp_get_int + printf("Testing: mp_get_int\n"); + for (i = 0; i < 1000; ++i) { + t = ((unsigned long) rand() * rand() + 1) & 0xFFFFFFFF; + mp_set_int(&a, t); + if (t != mp_get_int(&a)) { + printf("mp_get_int() bad result!\n"); + return 1; + } + } + mp_set_int(&a, 0); + if (mp_get_int(&a) != 0) { printf("mp_get_int() bad result!\n"); return 1; - } - } - mp_set_int(&a,0); - if (mp_get_int(&a)!=0) - { printf("mp_get_int() bad result!\n"); - return 1; - } - mp_set_int(&a,0xffffffff); - if (mp_get_int(&a)!=0xffffffff) - { printf("mp_get_int() bad result!\n"); - return 1; - } - - // test mp_sqrt - printf("Testing: mp_sqrt\n"); - for (i=0;i<1000;++i) { - printf("%6d\r", i); fflush(stdout); - n = (rand()&15)+1; - mp_rand(&a,n); - if (mp_sqrt(&a,&b) != MP_OKAY) - { printf("mp_sqrt() error!\n"); - return 1; - } - mp_n_root(&a,2,&a); - if (mp_cmp_mag(&b,&a) != MP_EQ) - { printf("mp_sqrt() bad result!\n"); - return 1; - } - } - - printf("\nTesting: mp_is_square\n"); - for (i=0;i<1000;++i) { - printf("%6d\r", i); fflush(stdout); - - /* test mp_is_square false negatives */ - n = (rand()&7)+1; - mp_rand(&a,n); - mp_sqr(&a,&a); - if (mp_is_square(&a,&n)!=MP_OKAY) { - printf("fn:mp_is_square() error!\n"); - return 1; - } - if (n==0) { - printf("fn:mp_is_square() bad result!\n"); + } + mp_set_int(&a, 0xffffffff); + if (mp_get_int(&a) != 0xffffffff) { + printf("mp_get_int() bad result!\n"); return 1; - } + } + // test mp_sqrt + printf("Testing: mp_sqrt\n"); + for (i = 0; i < 1000; ++i) { + printf("%6d\r", i); + fflush(stdout); + n = (rand() & 15) + 1; + mp_rand(&a, n); + if (mp_sqrt(&a, &b) != MP_OKAY) { + printf("mp_sqrt() error!\n"); + return 1; + } + mp_n_root(&a, 2, &a); + if (mp_cmp_mag(&b, &a) != MP_EQ) { + printf("mp_sqrt() bad result!\n"); + return 1; + } + } - /* test for false positives */ - mp_add_d(&a, 1, &a); - if (mp_is_square(&a,&n)!=MP_OKAY) { - printf("fp:mp_is_square() error!\n"); - return 1; - } - if (n==1) { - printf("fp:mp_is_square() bad result!\n"); - return 1; - } + printf("\nTesting: mp_is_square\n"); + for (i = 0; i < 1000; ++i) { + printf("%6d\r", i); + fflush(stdout); + + /* test mp_is_square false negatives */ + n = (rand() & 7) + 1; + mp_rand(&a, n); + mp_sqr(&a, &a); + if (mp_is_square(&a, &n) != MP_OKAY) { + printf("fn:mp_is_square() error!\n"); + return 1; + } + if (n == 0) { + printf("fn:mp_is_square() bad result!\n"); + return 1; + } - } - printf("\n\n"); + /* test for false positives */ + mp_add_d(&a, 1, &a); + if (mp_is_square(&a, &n) != MP_OKAY) { + printf("fp:mp_is_square() error!\n"); + return 1; + } + if (n == 1) { + printf("fp:mp_is_square() bad result!\n"); + return 1; + } + + } + printf("\n\n"); /* test for size */ - for (ix = 10; ix < 256; ix++) { - printf("Testing (not safe-prime): %9d bits \r", ix); fflush(stdout); - err = mp_prime_random_ex(&a, 8, ix, (rand()&1)?LTM_PRIME_2MSB_OFF:LTM_PRIME_2MSB_ON, myrng, NULL); - if (err != MP_OKAY) { - printf("failed with err code %d\n", err); - return EXIT_FAILURE; - } - if (mp_count_bits(&a) != ix) { - printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); - return EXIT_FAILURE; - } + for (ix = 10; ix < 128; ix++) { + printf("Testing (not safe-prime): %9d bits \r", ix); + fflush(stdout); + err = + mp_prime_random_ex(&a, 8, ix, + (rand() & 1) ? LTM_PRIME_2MSB_OFF : + LTM_PRIME_2MSB_ON, myrng, NULL); + if (err != MP_OKAY) { + printf("failed with err code %d\n", err); + return EXIT_FAILURE; + } + if (mp_count_bits(&a) != ix) { + printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); + return EXIT_FAILURE; + } } - for (ix = 16; ix < 256; ix++) { - printf("Testing ( safe-prime): %9d bits \r", ix); fflush(stdout); - err = mp_prime_random_ex(&a, 8, ix, ((rand()&1)?LTM_PRIME_2MSB_OFF:LTM_PRIME_2MSB_ON)|LTM_PRIME_SAFE, myrng, NULL); - if (err != MP_OKAY) { - printf("failed with err code %d\n", err); - return EXIT_FAILURE; - } - if (mp_count_bits(&a) != ix) { - printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); - return EXIT_FAILURE; - } - /* let's see if it's really a safe prime */ - mp_sub_d(&a, 1, &a); - mp_div_2(&a, &a); - mp_prime_is_prime(&a, 8, &cnt); - if (cnt != MP_YES) { - printf("sub is not prime!\n"); - return EXIT_FAILURE; - } + for (ix = 16; ix < 128; ix++) { + printf("Testing ( safe-prime): %9d bits \r", ix); + fflush(stdout); + err = + mp_prime_random_ex(&a, 8, ix, + ((rand() & 1) ? LTM_PRIME_2MSB_OFF : + LTM_PRIME_2MSB_ON) | LTM_PRIME_SAFE, myrng, + NULL); + if (err != MP_OKAY) { + printf("failed with err code %d\n", err); + return EXIT_FAILURE; + } + if (mp_count_bits(&a) != ix) { + printf("Prime is %d not %d bits!!!\n", mp_count_bits(&a), ix); + return EXIT_FAILURE; + } + /* let's see if it's really a safe prime */ + mp_sub_d(&a, 1, &a); + mp_div_2(&a, &a); + mp_prime_is_prime(&a, 8, &cnt); + if (cnt != MP_YES) { + printf("sub is not prime!\n"); + return EXIT_FAILURE; + } } printf("\n\n"); @@ -194,51 +242,56 @@ int main(void) printf("testing mp_cnt_lsb...\n"); mp_set(&a, 1); for (ix = 0; ix < 1024; ix++) { - if (mp_cnt_lsb(&a) != ix) { - printf("Failed at %d, %d\n", ix, mp_cnt_lsb(&a)); - return 0; - } - mp_mul_2(&a, &a); + if (mp_cnt_lsb(&a) != ix) { + printf("Failed at %d, %d\n", ix, mp_cnt_lsb(&a)); + return 0; + } + mp_mul_2(&a, &a); } /* test mp_reduce_2k */ printf("Testing mp_reduce_2k...\n"); for (cnt = 3; cnt <= 128; ++cnt) { - mp_digit tmp; - mp_2expt(&a, cnt); - mp_sub_d(&a, 2, &a); /* a = 2**cnt - 2 */ - - - printf("\nTesting %4d bits", cnt); - printf("(%d)", mp_reduce_is_2k(&a)); - mp_reduce_2k_setup(&a, &tmp); - printf("(%d)", tmp); - for (ix = 0; ix < 1000; ix++) { - if (!(ix & 127)) {printf("."); fflush(stdout); } - mp_rand(&b, (cnt/DIGIT_BIT + 1) * 2); - mp_copy(&c, &b); - mp_mod(&c, &a, &c); - mp_reduce_2k(&b, &a, 1); - if (mp_cmp(&c, &b)) { - printf("FAILED\n"); - exit(0); - } - } - } + mp_digit tmp; + + mp_2expt(&a, cnt); + mp_sub_d(&a, 2, &a); /* a = 2**cnt - 2 */ + + + printf("\nTesting %4d bits", cnt); + printf("(%d)", mp_reduce_is_2k(&a)); + mp_reduce_2k_setup(&a, &tmp); + printf("(%d)", tmp); + for (ix = 0; ix < 1000; ix++) { + if (!(ix & 127)) { + printf("."); + fflush(stdout); + } + mp_rand(&b, (cnt / DIGIT_BIT + 1) * 2); + mp_copy(&c, &b); + mp_mod(&c, &a, &c); + mp_reduce_2k(&b, &a, 2); + if (mp_cmp(&c, &b)) { + printf("FAILED\n"); + exit(0); + } + } + } /* test mp_div_3 */ printf("Testing mp_div_3...\n"); mp_set(&d, 3); - for (cnt = 0; cnt < 10000; ) { + for (cnt = 0; cnt < 10000;) { mp_digit r1, r2; - if (!(++cnt & 127)) printf("%9d\r", cnt); + if (!(++cnt & 127)) + printf("%9d\r", cnt); mp_rand(&a, abs(rand()) % 128 + 1); mp_div(&a, &d, &b, &e); mp_div_3(&a, &c, &r2); if (mp_cmp(&b, &c) || mp_cmp_d(&e, r2)) { - printf("\n\nmp_div_3 => Failure\n"); + printf("\n\nmp_div_3 => Failure\n"); } } printf("\n\nPassed div_3 testing\n"); @@ -246,270 +299,438 @@ int main(void) /* test the DR reduction */ printf("testing mp_dr_reduce...\n"); for (cnt = 2; cnt < 32; cnt++) { - printf("%d digit modulus\n", cnt); - mp_grow(&a, cnt); - mp_zero(&a); - for (ix = 1; ix < cnt; ix++) { - a.dp[ix] = MP_MASK; - } - a.used = cnt; - a.dp[0] = 3; - - mp_rand(&b, cnt - 1); - mp_copy(&b, &c); + printf("%d digit modulus\n", cnt); + mp_grow(&a, cnt); + mp_zero(&a); + for (ix = 1; ix < cnt; ix++) { + a.dp[ix] = MP_MASK; + } + a.used = cnt; + a.dp[0] = 3; + + mp_rand(&b, cnt - 1); + mp_copy(&b, &c); rr = 0; do { - if (!(rr & 127)) { printf("%9lu\r", rr); fflush(stdout); } - mp_sqr(&b, &b); mp_add_d(&b, 1, &b); - mp_copy(&b, &c); - - mp_mod(&b, &a, &b); - mp_dr_reduce(&c, &a, (((mp_digit)1)< - #endif - return __getReg (3116); - #else - #error need rdtsc function for this build - #endif - } +#elif defined _M_IX86 + __asm rdtsc +#elif defined _M_AMD64 + return __rdtsc(); +#elif defined _M_IA64 +#if defined __INTEL_COMPILER +#include +#endif + return __getReg(3116); +#else +#error need rdtsc function for this build +#endif +} #define DO(x) x; x; //#define DO4(x) DO2(x); DO2(x); @@ -77,7 +81,7 @@ static ulong64 TIMFUNC (void) int main(void) { ulong64 tt, gg, CLK_PER_SEC; - FILE *log, *logb, *logc; + FILE *log, *logb, *logc, *logd; mp_int a, b, c, d, e, f; int n, cnt, ix, old_kara_m, old_kara_s; unsigned rr; @@ -90,168 +94,191 @@ int main(void) mp_init(&f); srand(time(NULL)); - - - /* temp. turn off TOOM */ - TOOM_MUL_CUTOFF = TOOM_SQR_CUTOFF = 100000; - - CLK_PER_SEC = TIMFUNC(); - sleep(1); - CLK_PER_SEC = TIMFUNC() - CLK_PER_SEC; - - printf("CLK_PER_SEC == %llu\n", CLK_PER_SEC); - - log = fopen("logs/add.log", "w"); - for (cnt = 8; cnt <= 128; cnt += 8) { - SLEEP; - mp_rand(&a, cnt); - mp_rand(&b, cnt); - rr = 0; - tt = -1; - do { - gg = TIMFUNC(); - DO(mp_add(&a,&b,&c)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; - } while (++rr < 100000); - printf("Adding\t\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); fflush(log); - } - fclose(log); - log = fopen("logs/sub.log", "w"); - for (cnt = 8; cnt <= 128; cnt += 8) { - SLEEP; - mp_rand(&a, cnt); - mp_rand(&b, cnt); - rr = 0; - tt = -1; - do { - gg = TIMFUNC(); - DO(mp_sub(&a,&b,&c)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; - } while (++rr < 100000); - - printf("Subtracting\t\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); fflush(log); - } - fclose(log); + + /* temp. turn off TOOM */ + TOOM_MUL_CUTOFF = TOOM_SQR_CUTOFF = 100000; + + CLK_PER_SEC = TIMFUNC(); + sleep(1); + CLK_PER_SEC = TIMFUNC() - CLK_PER_SEC; + + printf("CLK_PER_SEC == %llu\n", CLK_PER_SEC); + goto exptmod; + log = fopen("logs/add.log", "w"); + for (cnt = 8; cnt <= 128; cnt += 8) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_add(&a, &b, &c)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; + } while (++rr < 100000); + printf("Adding\t\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(log, "%d %9llu\n", cnt * DIGIT_BIT, tt); + fflush(log); + } + fclose(log); + + log = fopen("logs/sub.log", "w"); + for (cnt = 8; cnt <= 128; cnt += 8) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_sub(&a, &b, &c)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; + } while (++rr < 100000); + + printf("Subtracting\t\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(log, "%d %9llu\n", cnt * DIGIT_BIT, tt); + fflush(log); + } + fclose(log); /* do mult/square twice, first without karatsuba and second with */ + multtest: old_kara_m = KARATSUBA_MUL_CUTOFF; old_kara_s = KARATSUBA_SQR_CUTOFF; - for (ix = 0; ix < 1; ix++) { - printf("With%s Karatsuba\n", (ix==0)?"out":""); - - KARATSUBA_MUL_CUTOFF = (ix==0)?9999:old_kara_m; - KARATSUBA_SQR_CUTOFF = (ix==0)?9999:old_kara_s; - - log = fopen((ix==0)?"logs/mult.log":"logs/mult_kara.log", "w"); - for (cnt = 4; cnt <= 288; cnt += 2) { - SLEEP; - mp_rand(&a, cnt); - mp_rand(&b, cnt); - rr = 0; - tt = -1; - do { - gg = TIMFUNC(); - DO(mp_mul(&a, &b, &c)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; - } while (++rr < 100); - printf("Multiplying\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); fflush(log); + for (ix = 0; ix < 2; ix++) { + printf("With%s Karatsuba\n", (ix == 0) ? "out" : ""); + + KARATSUBA_MUL_CUTOFF = (ix == 0) ? 9999 : old_kara_m; + KARATSUBA_SQR_CUTOFF = (ix == 0) ? 9999 : old_kara_s; + + log = fopen((ix == 0) ? "logs/mult.log" : "logs/mult_kara.log", "w"); + for (cnt = 4; cnt <= 10240 / DIGIT_BIT; cnt += 2) { + SLEEP; + mp_rand(&a, cnt); + mp_rand(&b, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_mul(&a, &b, &c)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; + } while (++rr < 100); + printf("Multiplying\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); + fflush(log); } fclose(log); - log = fopen((ix==0)?"logs/sqr.log":"logs/sqr_kara.log", "w"); - for (cnt = 4; cnt <= 288; cnt += 2) { - SLEEP; - mp_rand(&a, cnt); - rr = 0; - tt = -1; - do { - gg = TIMFUNC(); - DO(mp_sqr(&a, &b)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; - } while (++rr < 100); - printf("Squaring\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); fflush(log); + log = fopen((ix == 0) ? "logs/sqr.log" : "logs/sqr_kara.log", "w"); + for (cnt = 4; cnt <= 10240 / DIGIT_BIT; cnt += 2) { + SLEEP; + mp_rand(&a, cnt); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_sqr(&a, &b)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; + } while (++rr < 100); + printf("Squaring\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(log, "%d %9llu\n", mp_count_bits(&a), tt); + fflush(log); } fclose(log); } + exptmod: - { + { char *primes[] = { - /* 2K moduli mersenne primes */ - "6864797660130609714981900799081393217269435300143305409394463459185543183397656052122559640661454554977296311391480858037121987999716643812574028291115057151", - "531137992816767098689588206552468627329593117727031923199444138200403559860852242739162502265229285668889329486246501015346579337652707239409519978766587351943831270835393219031728127", - "10407932194664399081925240327364085538615262247266704805319112350403608059673360298012239441732324184842421613954281007791383566248323464908139906605677320762924129509389220345773183349661583550472959420547689811211693677147548478866962501384438260291732348885311160828538416585028255604666224831890918801847068222203140521026698435488732958028878050869736186900714720710555703168729087", - "1475979915214180235084898622737381736312066145333169775147771216478570297878078949377407337049389289382748507531496480477281264838760259191814463365330269540496961201113430156902396093989090226259326935025281409614983499388222831448598601834318536230923772641390209490231836446899608210795482963763094236630945410832793769905399982457186322944729636418890623372171723742105636440368218459649632948538696905872650486914434637457507280441823676813517852099348660847172579408422316678097670224011990280170474894487426924742108823536808485072502240519452587542875349976558572670229633962575212637477897785501552646522609988869914013540483809865681250419497686697771007", - "259117086013202627776246767922441530941818887553125427303974923161874019266586362086201209516800483406550695241733194177441689509238807017410377709597512042313066624082916353517952311186154862265604547691127595848775610568757931191017711408826252153849035830401185072116424747461823031471398340229288074545677907941037288235820705892351068433882986888616658650280927692080339605869308790500409503709875902119018371991620994002568935113136548829739112656797303241986517250116412703509705427773477972349821676443446668383119322540099648994051790241624056519054483690809616061625743042361721863339415852426431208737266591962061753535748892894599629195183082621860853400937932839420261866586142503251450773096274235376822938649407127700846077124211823080804139298087057504713825264571448379371125032081826126566649084251699453951887789613650248405739378594599444335231188280123660406262468609212150349937584782292237144339628858485938215738821232393687046160677362909315071", - "190797007524439073807468042969529173669356994749940177394741882673528979787005053706368049835514900244303495954950709725762186311224148828811920216904542206960744666169364221195289538436845390250168663932838805192055137154390912666527533007309292687539092257043362517857366624699975402375462954490293259233303137330643531556539739921926201438606439020075174723029056838272505051571967594608350063404495977660656269020823960825567012344189908927956646011998057988548630107637380993519826582389781888135705408653045219655801758081251164080554609057468028203308718724654081055323215860189611391296030471108443146745671967766308925858547271507311563765171008318248647110097614890313562856541784154881743146033909602737947385055355960331855614540900081456378659068370317267696980001187750995491090350108417050917991562167972281070161305972518044872048331306383715094854938415738549894606070722584737978176686422134354526989443028353644037187375385397838259511833166416134323695660367676897722287918773420968982326089026150031515424165462111337527431154890666327374921446276833564519776797633875503548665093914556482031482248883127023777039667707976559857333357013727342079099064400455741830654320379350833236245819348824064783585692924881021978332974949906122664421376034687815350484991", - - /* DR moduli */ - "14059105607947488696282932836518693308967803494693489478439861164411992439598399594747002144074658928593502845729752797260025831423419686528151609940203368612079", - "101745825697019260773923519755878567461315282017759829107608914364075275235254395622580447400994175578963163918967182013639660669771108475957692810857098847138903161308502419410142185759152435680068435915159402496058513611411688900243039", - "736335108039604595805923406147184530889923370574768772191969612422073040099331944991573923112581267542507986451953227192970402893063850485730703075899286013451337291468249027691733891486704001513279827771740183629161065194874727962517148100775228363421083691764065477590823919364012917984605619526140821797602431", - "38564998830736521417281865696453025806593491967131023221754800625044118265468851210705360385717536794615180260494208076605798671660719333199513807806252394423283413430106003596332513246682903994829528690198205120921557533726473585751382193953592127439965050261476810842071573684505878854588706623484573925925903505747545471088867712185004135201289273405614415899438276535626346098904241020877974002916168099951885406379295536200413493190419727789712076165162175783", - "542189391331696172661670440619180536749994166415993334151601745392193484590296600979602378676624808129613777993466242203025054573692562689251250471628358318743978285860720148446448885701001277560572526947619392551574490839286458454994488665744991822837769918095117129546414124448777033941223565831420390846864429504774477949153794689948747680362212954278693335653935890352619041936727463717926744868338358149568368643403037768649616778526013610493696186055899318268339432671541328195724261329606699831016666359440874843103020666106568222401047720269951530296879490444224546654729111504346660859907296364097126834834235287147", - "1487259134814709264092032648525971038895865645148901180585340454985524155135260217788758027400478312256339496385275012465661575576202252063145698732079880294664220579764848767704076761853197216563262660046602703973050798218246170835962005598561669706844469447435461092542265792444947706769615695252256130901271870341005768912974433684521436211263358097522726462083917939091760026658925757076733484173202927141441492573799914240222628795405623953109131594523623353044898339481494120112723445689647986475279242446083151413667587008191682564376412347964146113898565886683139407005941383669325997475076910488086663256335689181157957571445067490187939553165903773554290260531009121879044170766615232300936675369451260747671432073394867530820527479172464106442450727640226503746586340279816318821395210726268291535648506190714616083163403189943334431056876038286530365757187367147446004855912033137386225053275419626102417236133948503", - "1095121115716677802856811290392395128588168592409109494900178008967955253005183831872715423151551999734857184538199864469605657805519106717529655044054833197687459782636297255219742994736751541815269727940751860670268774903340296040006114013971309257028332849679096824800250742691718610670812374272414086863715763724622797509437062518082383056050144624962776302147890521249477060215148275163688301275847155316042279405557632639366066847442861422164832655874655824221577849928863023018366835675399949740429332468186340518172487073360822220449055340582568461568645259954873303616953776393853174845132081121976327462740354930744487429617202585015510744298530101547706821590188733515880733527449780963163909830077616357506845523215289297624086914545378511082534229620116563260168494523906566709418166011112754529766183554579321224940951177394088465596712620076240067370589036924024728375076210477267488679008016579588696191194060127319035195370137160936882402244399699172017835144537488486396906144217720028992863941288217185353914991583400421682751000603596655790990815525126154394344641336397793791497068253936771017031980867706707490224041075826337383538651825493679503771934836094655802776331664261631740148281763487765852746577808019633679", - - /* generic unrestricted moduli */ - "17933601194860113372237070562165128350027320072176844226673287945873370751245439587792371960615073855669274087805055507977323024886880985062002853331424203", - "2893527720709661239493896562339544088620375736490408468011883030469939904368086092336458298221245707898933583190713188177399401852627749210994595974791782790253946539043962213027074922559572312141181787434278708783207966459019479487", - "347743159439876626079252796797422223177535447388206607607181663903045907591201940478223621722118173270898487582987137708656414344685816179420855160986340457973820182883508387588163122354089264395604796675278966117567294812714812796820596564876450716066283126720010859041484786529056457896367683122960411136319", - "47266428956356393164697365098120418976400602706072312735924071745438532218237979333351774907308168340693326687317443721193266215155735814510792148768576498491199122744351399489453533553203833318691678263241941706256996197460424029012419012634671862283532342656309677173602509498417976091509154360039893165037637034737020327399910409885798185771003505320583967737293415979917317338985837385734747478364242020380416892056650841470869294527543597349250299539682430605173321029026555546832473048600327036845781970289288898317888427517364945316709081173840186150794397479045034008257793436817683392375274635794835245695887", - "436463808505957768574894870394349739623346440601945961161254440072143298152040105676491048248110146278752857839930515766167441407021501229924721335644557342265864606569000117714935185566842453630868849121480179691838399545644365571106757731317371758557990781880691336695584799313313687287468894148823761785582982549586183756806449017542622267874275103877481475534991201849912222670102069951687572917937634467778042874315463238062009202992087620963771759666448266532858079402669920025224220613419441069718482837399612644978839925207109870840278194042158748845445131729137117098529028886770063736487420613144045836803985635654192482395882603511950547826439092832800532152534003936926017612446606135655146445620623395788978726744728503058670046885876251527122350275750995227", - "11424167473351836398078306042624362277956429440521137061889702611766348760692206243140413411077394583180726863277012016602279290144126785129569474909173584789822341986742719230331946072730319555984484911716797058875905400999504305877245849119687509023232790273637466821052576859232452982061831009770786031785669030271542286603956118755585683996118896215213488875253101894663403069677745948305893849505434201763745232895780711972432011344857521691017896316861403206449421332243658855453435784006517202894181640562433575390821384210960117518650374602256601091379644034244332285065935413233557998331562749140202965844219336298970011513882564935538704289446968322281451907487362046511461221329799897350993370560697505809686438782036235372137015731304779072430260986460269894522159103008260495503005267165927542949439526272736586626709581721032189532726389643625590680105784844246152702670169304203783072275089194754889511973916207", - "1214855636816562637502584060163403830270705000634713483015101384881871978446801224798536155406895823305035467591632531067547890948695117172076954220727075688048751022421198712032848890056357845974246560748347918630050853933697792254955890439720297560693579400297062396904306270145886830719309296352765295712183040773146419022875165382778007040109957609739589875590885701126197906063620133954893216612678838507540777138437797705602453719559017633986486649523611975865005712371194067612263330335590526176087004421363598470302731349138773205901447704682181517904064735636518462452242791676541725292378925568296858010151852326316777511935037531017413910506921922450666933202278489024521263798482237150056835746454842662048692127173834433089016107854491097456725016327709663199738238442164843147132789153725513257167915555162094970853584447993125488607696008169807374736711297007473812256272245489405898470297178738029484459690836250560495461579533254473316340608217876781986188705928270735695752830825527963838355419762516246028680280988020401914551825487349990306976304093109384451438813251211051597392127491464898797406789175453067960072008590614886532333015881171367104445044718144312416815712216611576221546455968770801413440778423979", - NULL + /* 2K large moduli */ + "179769313486231590772930519078902473361797697894230657273430081157732675805500963132708477322407536021120113879871393357658789768814416622492847430639474124377767893424865485276302219601246094119453082952085005768838150682342462881473913110540827237163350510684586239334100047359817950870678242457666208137217", + "32317006071311007300714876688669951960444102669715484032130345427524655138867890893197201411522913463688717960921898019494119559150490921095088152386448283120630877367300996091750197750389652106796057638384067568276792218642619756161838094338476170470581645852036305042887575891541065808607552399123930385521914333389668342420684974786564569494856176035326322058077805659331026192708460314150258592864177116725943603718461857357598351152301645904403697613233287231227125684710820209725157101726931323469678542580656697935045997268352998638099733077152121140120031150424541696791951097529546801429027668869927491725169", + "1044388881413152506691752710716624382579964249047383780384233483283953907971557456848826811934997558340890106714439262837987573438185793607263236087851365277945956976543709998340361590134383718314428070011855946226376318839397712745672334684344586617496807908705803704071284048740118609114467977783598029006686938976881787785946905630190260940599579453432823469303026696443059025015972399867714215541693835559885291486318237914434496734087811872639496475100189041349008417061675093668333850551032972088269550769983616369411933015213796825837188091833656751221318492846368125550225998300412344784862595674492194617023806505913245610825731835380087608622102834270197698202313169017678006675195485079921636419370285375124784014907159135459982790513399611551794271106831134090584272884279791554849782954323534517065223269061394905987693002122963395687782878948440616007412945674919823050571642377154816321380631045902916136926708342856440730447899971901781465763473223850267253059899795996090799469201774624817718449867455659250178329070473119433165550807568221846571746373296884912819520317457002440926616910874148385078411929804522981857338977648103126085902995208257421855249796721729039744118165938433694823325696642096892124547425283", + /* 2K moduli mersenne primes */ + "6864797660130609714981900799081393217269435300143305409394463459185543183397656052122559640661454554977296311391480858037121987999716643812574028291115057151", + "531137992816767098689588206552468627329593117727031923199444138200403559860852242739162502265229285668889329486246501015346579337652707239409519978766587351943831270835393219031728127", + "10407932194664399081925240327364085538615262247266704805319112350403608059673360298012239441732324184842421613954281007791383566248323464908139906605677320762924129509389220345773183349661583550472959420547689811211693677147548478866962501384438260291732348885311160828538416585028255604666224831890918801847068222203140521026698435488732958028878050869736186900714720710555703168729087", + "1475979915214180235084898622737381736312066145333169775147771216478570297878078949377407337049389289382748507531496480477281264838760259191814463365330269540496961201113430156902396093989090226259326935025281409614983499388222831448598601834318536230923772641390209490231836446899608210795482963763094236630945410832793769905399982457186322944729636418890623372171723742105636440368218459649632948538696905872650486914434637457507280441823676813517852099348660847172579408422316678097670224011990280170474894487426924742108823536808485072502240519452587542875349976558572670229633962575212637477897785501552646522609988869914013540483809865681250419497686697771007", + "259117086013202627776246767922441530941818887553125427303974923161874019266586362086201209516800483406550695241733194177441689509238807017410377709597512042313066624082916353517952311186154862265604547691127595848775610568757931191017711408826252153849035830401185072116424747461823031471398340229288074545677907941037288235820705892351068433882986888616658650280927692080339605869308790500409503709875902119018371991620994002568935113136548829739112656797303241986517250116412703509705427773477972349821676443446668383119322540099648994051790241624056519054483690809616061625743042361721863339415852426431208737266591962061753535748892894599629195183082621860853400937932839420261866586142503251450773096274235376822938649407127700846077124211823080804139298087057504713825264571448379371125032081826126566649084251699453951887789613650248405739378594599444335231188280123660406262468609212150349937584782292237144339628858485938215738821232393687046160677362909315071", + "190797007524439073807468042969529173669356994749940177394741882673528979787005053706368049835514900244303495954950709725762186311224148828811920216904542206960744666169364221195289538436845390250168663932838805192055137154390912666527533007309292687539092257043362517857366624699975402375462954490293259233303137330643531556539739921926201438606439020075174723029056838272505051571967594608350063404495977660656269020823960825567012344189908927956646011998057988548630107637380993519826582389781888135705408653045219655801758081251164080554609057468028203308718724654081055323215860189611391296030471108443146745671967766308925858547271507311563765171008318248647110097614890313562856541784154881743146033909602737947385055355960331855614540900081456378659068370317267696980001187750995491090350108417050917991562167972281070161305972518044872048331306383715094854938415738549894606070722584737978176686422134354526989443028353644037187375385397838259511833166416134323695660367676897722287918773420968982326089026150031515424165462111337527431154890666327374921446276833564519776797633875503548665093914556482031482248883127023777039667707976559857333357013727342079099064400455741830654320379350833236245819348824064783585692924881021978332974949906122664421376034687815350484991", + + /* DR moduli */ + "14059105607947488696282932836518693308967803494693489478439861164411992439598399594747002144074658928593502845729752797260025831423419686528151609940203368612079", + "101745825697019260773923519755878567461315282017759829107608914364075275235254395622580447400994175578963163918967182013639660669771108475957692810857098847138903161308502419410142185759152435680068435915159402496058513611411688900243039", + "736335108039604595805923406147184530889923370574768772191969612422073040099331944991573923112581267542507986451953227192970402893063850485730703075899286013451337291468249027691733891486704001513279827771740183629161065194874727962517148100775228363421083691764065477590823919364012917984605619526140821797602431", + "38564998830736521417281865696453025806593491967131023221754800625044118265468851210705360385717536794615180260494208076605798671660719333199513807806252394423283413430106003596332513246682903994829528690198205120921557533726473585751382193953592127439965050261476810842071573684505878854588706623484573925925903505747545471088867712185004135201289273405614415899438276535626346098904241020877974002916168099951885406379295536200413493190419727789712076165162175783", + "542189391331696172661670440619180536749994166415993334151601745392193484590296600979602378676624808129613777993466242203025054573692562689251250471628358318743978285860720148446448885701001277560572526947619392551574490839286458454994488665744991822837769918095117129546414124448777033941223565831420390846864429504774477949153794689948747680362212954278693335653935890352619041936727463717926744868338358149568368643403037768649616778526013610493696186055899318268339432671541328195724261329606699831016666359440874843103020666106568222401047720269951530296879490444224546654729111504346660859907296364097126834834235287147", + "1487259134814709264092032648525971038895865645148901180585340454985524155135260217788758027400478312256339496385275012465661575576202252063145698732079880294664220579764848767704076761853197216563262660046602703973050798218246170835962005598561669706844469447435461092542265792444947706769615695252256130901271870341005768912974433684521436211263358097522726462083917939091760026658925757076733484173202927141441492573799914240222628795405623953109131594523623353044898339481494120112723445689647986475279242446083151413667587008191682564376412347964146113898565886683139407005941383669325997475076910488086663256335689181157957571445067490187939553165903773554290260531009121879044170766615232300936675369451260747671432073394867530820527479172464106442450727640226503746586340279816318821395210726268291535648506190714616083163403189943334431056876038286530365757187367147446004855912033137386225053275419626102417236133948503", + "1095121115716677802856811290392395128588168592409109494900178008967955253005183831872715423151551999734857184538199864469605657805519106717529655044054833197687459782636297255219742994736751541815269727940751860670268774903340296040006114013971309257028332849679096824800250742691718610670812374272414086863715763724622797509437062518082383056050144624962776302147890521249477060215148275163688301275847155316042279405557632639366066847442861422164832655874655824221577849928863023018366835675399949740429332468186340518172487073360822220449055340582568461568645259954873303616953776393853174845132081121976327462740354930744487429617202585015510744298530101547706821590188733515880733527449780963163909830077616357506845523215289297624086914545378511082534229620116563260168494523906566709418166011112754529766183554579321224940951177394088465596712620076240067370589036924024728375076210477267488679008016579588696191194060127319035195370137160936882402244399699172017835144537488486396906144217720028992863941288217185353914991583400421682751000603596655790990815525126154394344641336397793791497068253936771017031980867706707490224041075826337383538651825493679503771934836094655802776331664261631740148281763487765852746577808019633679", + + /* generic unrestricted moduli */ + "17933601194860113372237070562165128350027320072176844226673287945873370751245439587792371960615073855669274087805055507977323024886880985062002853331424203", + "2893527720709661239493896562339544088620375736490408468011883030469939904368086092336458298221245707898933583190713188177399401852627749210994595974791782790253946539043962213027074922559572312141181787434278708783207966459019479487", + "347743159439876626079252796797422223177535447388206607607181663903045907591201940478223621722118173270898487582987137708656414344685816179420855160986340457973820182883508387588163122354089264395604796675278966117567294812714812796820596564876450716066283126720010859041484786529056457896367683122960411136319", + "47266428956356393164697365098120418976400602706072312735924071745438532218237979333351774907308168340693326687317443721193266215155735814510792148768576498491199122744351399489453533553203833318691678263241941706256996197460424029012419012634671862283532342656309677173602509498417976091509154360039893165037637034737020327399910409885798185771003505320583967737293415979917317338985837385734747478364242020380416892056650841470869294527543597349250299539682430605173321029026555546832473048600327036845781970289288898317888427517364945316709081173840186150794397479045034008257793436817683392375274635794835245695887", + "436463808505957768574894870394349739623346440601945961161254440072143298152040105676491048248110146278752857839930515766167441407021501229924721335644557342265864606569000117714935185566842453630868849121480179691838399545644365571106757731317371758557990781880691336695584799313313687287468894148823761785582982549586183756806449017542622267874275103877481475534991201849912222670102069951687572917937634467778042874315463238062009202992087620963771759666448266532858079402669920025224220613419441069718482837399612644978839925207109870840278194042158748845445131729137117098529028886770063736487420613144045836803985635654192482395882603511950547826439092832800532152534003936926017612446606135655146445620623395788978726744728503058670046885876251527122350275750995227", + "11424167473351836398078306042624362277956429440521137061889702611766348760692206243140413411077394583180726863277012016602279290144126785129569474909173584789822341986742719230331946072730319555984484911716797058875905400999504305877245849119687509023232790273637466821052576859232452982061831009770786031785669030271542286603956118755585683996118896215213488875253101894663403069677745948305893849505434201763745232895780711972432011344857521691017896316861403206449421332243658855453435784006517202894181640562433575390821384210960117518650374602256601091379644034244332285065935413233557998331562749140202965844219336298970011513882564935538704289446968322281451907487362046511461221329799897350993370560697505809686438782036235372137015731304779072430260986460269894522159103008260495503005267165927542949439526272736586626709581721032189532726389643625590680105784844246152702670169304203783072275089194754889511973916207", + "1214855636816562637502584060163403830270705000634713483015101384881871978446801224798536155406895823305035467591632531067547890948695117172076954220727075688048751022421198712032848890056357845974246560748347918630050853933697792254955890439720297560693579400297062396904306270145886830719309296352765295712183040773146419022875165382778007040109957609739589875590885701126197906063620133954893216612678838507540777138437797705602453719559017633986486649523611975865005712371194067612263330335590526176087004421363598470302731349138773205901447704682181517904064735636518462452242791676541725292378925568296858010151852326316777511935037531017413910506921922450666933202278489024521263798482237150056835746454842662048692127173834433089016107854491097456725016327709663199738238442164843147132789153725513257167915555162094970853584447993125488607696008169807374736711297007473812256272245489405898470297178738029484459690836250560495461579533254473316340608217876781986188705928270735695752830825527963838355419762516246028680280988020401914551825487349990306976304093109384451438813251211051597392127491464898797406789175453067960072008590614886532333015881171367104445044718144312416815712216611576221546455968770801413440778423979", + NULL }; - log = fopen("logs/expt.log", "w"); - logb = fopen("logs/expt_dr.log", "w"); - logc = fopen("logs/expt_2k.log", "w"); - for (n = 0; primes[n]; n++) { - SLEEP; - mp_read_radix(&a, primes[n], 10); - mp_zero(&b); - for (rr = 0; rr < (unsigned)mp_count_bits(&a); rr++) { - mp_mul_2(&b, &b); - b.dp[0] |= lbit(); - b.used += 1; - } - mp_sub_d(&a, 1, &c); - mp_mod(&b, &c, &b); - mp_set(&c, 3); - rr = 0; - tt = -1; - do { - gg = TIMFUNC(); - DO(mp_exptmod(&c, &b, &a, &d)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; - } while (++rr < 10); - mp_sub_d(&a, 1, &e); - mp_sub(&e, &b, &b); - mp_exptmod(&c, &b, &a, &e); /* c^(p-1-b) mod a */ - mp_mulmod(&e, &d, &a, &d); /* c^b * c^(p-1-b) == c^p-1 == 1 */ - if (mp_cmp_d(&d, 1)) { - printf("Different (%d)!!!\n", mp_count_bits(&a)); - draw(&d); - exit(0); + log = fopen("logs/expt.log", "w"); + logb = fopen("logs/expt_dr.log", "w"); + logc = fopen("logs/expt_2k.log", "w"); + logd = fopen("logs/expt_2kl.log", "w"); + for (n = 0; primes[n]; n++) { + SLEEP; + mp_read_radix(&a, primes[n], 10); + mp_zero(&b); + for (rr = 0; rr < (unsigned) mp_count_bits(&a); rr++) { + mp_mul_2(&b, &b); + b.dp[0] |= lbit(); + b.used += 1; + } + mp_sub_d(&a, 1, &c); + mp_mod(&b, &c, &b); + mp_set(&c, 3); + rr = 0; + tt = -1; + do { + gg = TIMFUNC(); + DO(mp_exptmod(&c, &b, &a, &d)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; + } while (++rr < 10); + mp_sub_d(&a, 1, &e); + mp_sub(&e, &b, &b); + mp_exptmod(&c, &b, &a, &e); /* c^(p-1-b) mod a */ + mp_mulmod(&e, &d, &a, &d); /* c^b * c^(p-1-b) == c^p-1 == 1 */ + if (mp_cmp_d(&d, 1)) { + printf("Different (%d)!!!\n", mp_count_bits(&a)); + draw(&d); + exit(0); + } + printf("Exponentiating\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(n < 4 ? logd : (n < 9) ? logc : (n < 16) ? logb : log, + "%d %9llu\n", mp_count_bits(&a), tt); } - printf("Exponentiating\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf((n < 6) ? logc : (n < 13) ? logb : log, "%d %9llu\n", mp_count_bits(&a), tt); - } } fclose(log); fclose(logb); fclose(logc); + fclose(logd); log = fopen("logs/invmod.log", "w"); for (cnt = 4; cnt <= 128; cnt += 4) { @@ -260,28 +287,29 @@ int main(void) mp_rand(&b, cnt); do { - mp_add_d(&b, 1, &b); - mp_gcd(&a, &b, &c); + mp_add_d(&b, 1, &b); + mp_gcd(&a, &b, &c); } while (mp_cmp_d(&c, 1) != MP_EQ); - rr = 0; - tt = -1; + rr = 0; + tt = -1; do { - gg = TIMFUNC(); - DO(mp_invmod(&b, &a, &c)); - gg = (TIMFUNC() - gg)>>1; - if (tt > gg) tt = gg; + gg = TIMFUNC(); + DO(mp_invmod(&b, &a, &c)); + gg = (TIMFUNC() - gg) >> 1; + if (tt > gg) + tt = gg; } while (++rr < 1000); mp_mulmod(&b, &c, &a, &d); if (mp_cmp_d(&d, 1) != MP_EQ) { - printf("Failed to invert\n"); - return 0; + printf("Failed to invert\n"); + return 0; } - printf("Inverting mod\t%4d-bit => %9llu/sec, %9llu cycles\n", mp_count_bits(&a), CLK_PER_SEC/tt, tt); - fprintf(log, "%d %9llu\n", cnt*DIGIT_BIT, tt); + printf("Inverting mod\t%4d-bit => %9llu/sec, %9llu cycles\n", + mp_count_bits(&a), CLK_PER_SEC / tt, tt); + fprintf(log, "%d %9llu\n", cnt * DIGIT_BIT, tt); } fclose(log); return 0; } - diff --git a/libtommath/dep.pl b/libtommath/dep.pl index 22266e3..c39e27e 100644 --- a/libtommath/dep.pl +++ b/libtommath/dep.pl @@ -13,6 +13,8 @@ print CLASS "#if !(defined(LTM1) && defined(LTM2) && defined(LTM3))\n#if defined foreach my $filename (glob "bn*.c") { my $define = $filename; +print "Processing $filename\n"; + # convert filename to upper case so we can use it as a define $define =~ tr/[a-z]/[A-Z]/; $define =~ tr/\./_/; diff --git a/libtommath/etc/timer.asm b/libtommath/etc/timer.asm index 35890d9..326a947 100644 --- a/libtommath/etc/timer.asm +++ b/libtommath/etc/timer.asm @@ -1,37 +1,37 @@ -; x86 timer in NASM -; -; Tom St Denis, tomstdenis@iahu.ca -[bits 32] -[section .data] -time dd 0, 0 - -[section .text] - -%ifdef USE_ELF -[global t_start] -t_start: -%else -[global _t_start] -_t_start: -%endif - push edx - push eax - rdtsc - mov [time+0],edx - mov [time+4],eax - pop eax - pop edx - ret - -%ifdef USE_ELF -[global t_read] -t_read: -%else -[global _t_read] -_t_read: -%endif - rdtsc - sub eax,[time+4] - sbb edx,[time+0] - ret +; x86 timer in NASM +; +; Tom St Denis, tomstdenis@iahu.ca +[bits 32] +[section .data] +time dd 0, 0 + +[section .text] + +%ifdef USE_ELF +[global t_start] +t_start: +%else +[global _t_start] +_t_start: +%endif + push edx + push eax + rdtsc + mov [time+0],edx + mov [time+4],eax + pop eax + pop edx + ret + +%ifdef USE_ELF +[global t_read] +t_read: +%else +[global _t_read] +_t_read: +%endif + rdtsc + sub eax,[time+4] + sbb edx,[time+0] + ret \ No newline at end of file diff --git a/libtommath/etc/tune.c b/libtommath/etc/tune.c index 14aace2..d054d10 100644 --- a/libtommath/etc/tune.c +++ b/libtommath/etc/tune.c @@ -10,13 +10,44 @@ */ #define TIMES (1UL<<14UL) +/* RDTSC from Scott Duplichan */ +static ulong64 TIMFUNC (void) + { + #if defined __GNUC__ + #if defined(__i386__) || defined(__x86_64__) + unsigned long long a; + __asm__ __volatile__ ("rdtsc\nmovl %%eax,%0\nmovl %%edx,4+%0\n"::"m"(a):"%eax","%edx"); + return a; + #else /* gcc-IA64 version */ + unsigned long result; + __asm__ __volatile__("mov %0=ar.itc" : "=r"(result) :: "memory"); + while (__builtin_expect ((int) result == -1, 0)) + __asm__ __volatile__("mov %0=ar.itc" : "=r"(result) :: "memory"); + return result; + #endif + + // Microsoft and Intel Windows compilers + #elif defined _M_IX86 + __asm rdtsc + #elif defined _M_AMD64 + return __rdtsc (); + #elif defined _M_IA64 + #if defined __INTEL_COMPILER + #include + #endif + return __getReg (3116); + #else + #error need rdtsc function for this build + #endif + } + #ifndef X86_TIMER /* generic ISO C timer */ ulong64 LBL_T; -void t_start(void) { LBL_T = clock(); } -ulong64 t_read(void) { return clock() - LBL_T; } +void t_start(void) { LBL_T = TIMFUNC(); } +ulong64 t_read(void) { return TIMFUNC() - LBL_T; } #else extern void t_start(void); diff --git a/libtommath/logs/README b/libtommath/logs/README index ea20c81..965e7c8 100644 --- a/libtommath/logs/README +++ b/libtommath/logs/README @@ -1,13 +1,13 @@ -To use the pretty graphs you have to first build/run the ltmtest from the root directory of the package. -Todo this type - -make timing ; ltmtest - -in the root. It will run for a while [about ten minutes on most PCs] and produce a series of .log files in logs/. - -After doing that run "gnuplot graphs.dem" to make the PNGs. If you managed todo that all so far just open index.html to view -them all :-) - -Have fun - +To use the pretty graphs you have to first build/run the ltmtest from the root directory of the package. +Todo this type + +make timing ; ltmtest + +in the root. It will run for a while [about ten minutes on most PCs] and produce a series of .log files in logs/. + +After doing that run "gnuplot graphs.dem" to make the PNGs. If you managed todo that all so far just open index.html to view +them all :-) + +Have fun + Tom \ No newline at end of file diff --git a/libtommath/logs/add.log b/libtommath/logs/add.log index fa11039..43503ac 100644 --- a/libtommath/logs/add.log +++ b/libtommath/logs/add.log @@ -1,10 +1,10 @@ -480 88 -960 113 -1440 138 -1920 163 -2400 202 -2880 226 -3360 251 +480 87 +960 111 +1440 135 +1920 159 +2400 200 +2880 224 +3360 248 3840 272 4320 296 4800 320 diff --git a/libtommath/logs/addsub.png b/libtommath/logs/addsub.png index a5679ac..441c7b2 100644 Binary files a/libtommath/logs/addsub.png and b/libtommath/logs/addsub.png differ diff --git a/libtommath/logs/expt.log b/libtommath/logs/expt.log index e65e927..920ba55 100644 --- a/libtommath/logs/expt.log +++ b/libtommath/logs/expt.log @@ -1,7 +1,7 @@ -513 1499509 -769 3682671 -1025 8098887 -2049 49332743 -2561 89647783 -3073 149440713 -4097 326135364 +513 1489160 +769 3688476 +1025 8162061 +2049 49260015 +2561 89579052 +3073 148797060 +4097 324449263 diff --git a/libtommath/logs/expt.png b/libtommath/logs/expt.png index 9ee8bb7..d779cc5 100644 Binary files a/libtommath/logs/expt.png and b/libtommath/logs/expt.png differ diff --git a/libtommath/logs/expt_2k.log b/libtommath/logs/expt_2k.log index d106280..56b50db 100644 --- a/libtommath/logs/expt_2k.log +++ b/libtommath/logs/expt_2k.log @@ -1,6 +1,5 @@ -521 1423346 -607 1841305 -1279 8375656 -2203 34104708 -3217 83830729 -4253 167916804 +607 2272809 +1279 9557382 +2203 36250309 +3217 87666486 +4253 174168369 diff --git a/libtommath/logs/expt_dr.log b/libtommath/logs/expt_dr.log index 6cfc874..eb93fc9 100644 --- a/libtommath/logs/expt_dr.log +++ b/libtommath/logs/expt_dr.log @@ -1,7 +1,7 @@ -532 1803110 -784 3607375 -1036 6089790 -1540 14739797 -2072 33251589 -3080 82794331 -4116 165212734 +532 1989592 +784 3898697 +1036 6519700 +1540 15676650 +2072 33128187 +3080 82963362 +4116 168358337 diff --git a/libtommath/logs/invmod.png b/libtommath/logs/invmod.png index 0a8a4ad..9dcd7d8 100644 Binary files a/libtommath/logs/invmod.png and b/libtommath/logs/invmod.png differ diff --git a/libtommath/logs/mult.log b/libtommath/logs/mult.log index 864de46..33563fc 100644 --- a/libtommath/logs/mult.log +++ b/libtommath/logs/mult.log @@ -1,143 +1,84 @@ -271 580 -390 861 -511 1177 -630 1598 -749 2115 -871 2670 -991 3276 -1111 3987 -1231 4722 -1351 5474 -1471 6281 -1589 7126 -1710 8114 -1831 8988 -1946 10038 -2071 10995 -2188 12286 -2310 13152 -2430 14480 -2549 15521 -2671 17171 -2790 18081 -2911 19754 -3031 20809 -3150 22849 -3269 23757 -3391 25772 -3508 26832 -3631 29304 -3750 30149 -3865 32581 -3988 33644 -4111 36565 -4231 37309 -4351 40152 -4471 41188 -4590 44658 -4710 45256 -4827 48538 -4951 49490 -5070 53472 -5190 53902 -5308 57619 -5431 58509 -5550 63044 -5664 63333 -5791 67542 -5911 68279 -6028 73477 -6150 73475 -6271 78189 -6390 78842 -6510 84691 -6631 84444 -6751 89721 -6871 90186 -6991 96665 -7111 96119 -7231 101937 -7350 102212 -7471 109439 -7591 108491 -7709 114965 -7829 115025 -7951 123002 -8071 121630 -8190 128725 -8311 128536 -8430 137298 -8550 135568 -8671 143265 -8791 142793 -8911 152432 -9030 150202 -9151 158616 -9271 157848 -9391 168374 -9511 165651 -9627 174775 -9750 173375 -9871 185067 -9985 181845 -10111 191708 -10229 190239 -10351 202585 -10467 198704 -10591 209193 -10711 207322 -10831 220842 -10950 215882 -11071 227761 -11191 225501 -11311 239669 -11430 234809 -11550 243511 -11671 255947 -11791 255243 -11906 267828 -12029 263437 -12149 276571 -12270 275579 -12390 288963 -12510 284001 -12631 298196 -12751 297018 -12869 310848 -12990 305369 -13111 319086 -13230 318940 -13349 333685 -13471 327495 -13588 343678 -13711 341817 -13831 357181 -13948 350440 -14071 367526 -14189 365330 -14311 381551 -14429 374149 -14549 392203 -14670 389764 -14791 406761 -14910 398652 -15026 417718 -15150 414733 -15269 432759 -15390 1037071 -15511 1053454 -15631 1069198 -15748 1086164 -15871 1112820 -15991 1129676 -16111 1145924 -16230 1163016 -16345 1179911 -16471 1197048 -16586 1214352 -16711 1232095 -16829 1249338 -16947 1266987 -17071 1284181 -17188 1302521 -17311 1320539 +271 555 +390 855 +508 1161 +631 1605 +749 2117 +871 2687 +991 3329 +1108 4084 +1231 4786 +1351 5624 +1470 6392 +1586 7364 +1710 8218 +1830 9255 +1951 10217 +2067 11461 +2191 12463 +2308 13677 +2430 14800 +2551 16232 +2671 17460 +2791 18899 +2902 20247 +3028 21902 +3151 23240 +3267 24927 +3391 26441 +3511 28277 +3631 29838 +3749 31751 +3869 33673 +3989 35431 +4111 37518 +4231 39426 +4349 41504 +4471 43567 +4591 45786 +4711 47876 +4831 50299 +4951 52427 +5071 54785 +5189 57241 +5307 59730 +5431 62194 +5551 64761 +5670 67322 +5789 70073 +5907 72663 +6030 75437 +6151 78242 +6268 81202 +6389 83948 +6509 86985 +6631 89903 +6747 93184 +6869 96044 +6991 99286 +7109 102395 +7229 105917 +7351 108940 +7470 112490 +7589 115702 +7711 119508 +7831 122632 +7951 126410 +8071 129808 +8190 133895 +8311 137146 +8431 141218 +8549 144732 +8667 149131 +8790 152462 +8911 156754 +9030 160479 +9149 165138 +9271 168601 +9391 173185 +9511 176988 +9627 181976 +9751 185539 +9870 190388 +9991 194335 +10110 199605 +10228 203298 diff --git a/libtommath/logs/mult.png b/libtommath/logs/mult.png index 4f7a4ee..d22e8c8 100644 Binary files a/libtommath/logs/mult.png and b/libtommath/logs/mult.png differ diff --git a/libtommath/logs/mult_kara.log b/libtommath/logs/mult_kara.log index 086feaf..7136c79 100644 --- a/libtommath/logs/mult_kara.log +++ b/libtommath/logs/mult_kara.log @@ -1,33 +1,84 @@ -924 16686 -1146 25334 -1371 35304 -1591 47122 -1820 61500 -2044 75254 -2266 91732 -2492 111656 -2716 129428 -2937 147508 -3164 167758 -3388 188248 -3612 210826 -3836 233814 -4059 256898 -4284 280210 -4508 310372 -4731 333902 -4955 376502 -5179 402854 -5404 432004 -5626 459010 -5849 491868 -6076 520550 -6300 547400 -6524 575968 -6747 608482 -6971 642850 -7196 673670 -7419 710680 -7644 743942 -7868 780394 -8092 817342 +271 560 +391 870 +511 1159 +631 1605 +750 2111 +871 2737 +991 3361 +1111 4054 +1231 4778 +1351 5600 +1471 6404 +1591 7323 +1710 8255 +1831 9239 +1948 10257 +2070 11397 +2190 12531 +2308 13665 +2429 14870 +2550 16175 +2671 17539 +2787 18879 +2911 20350 +3031 21807 +3150 23415 +3270 24897 +3388 26567 +3511 28205 +3627 30076 +3751 31744 +3869 33657 +3991 35425 +4111 37522 +4229 39363 +4351 41503 +4470 43491 +4590 45827 +4711 47795 +4828 50166 +4951 52318 +5070 54911 +5191 57036 +5308 58237 +5431 60248 +5551 62678 +5671 64786 +5791 67294 +5908 69343 +6031 71607 +6151 74166 +6271 76590 +6391 78734 +6511 81175 +6631 83742 +6750 86403 +6868 88873 +6990 91150 +7110 94211 +7228 96922 +7351 99445 +7469 102216 +7589 104968 +7711 108113 +7827 110758 +7950 113714 +8071 116511 +8186 119643 +8310 122679 +8425 125581 +8551 128715 +8669 131778 +8788 135116 +8910 138138 +9031 141628 +9148 144754 +9268 148367 +9391 151551 +9511 155033 +9631 158652 +9751 162125 +9871 165248 +9988 168627 +10111 172427 +10231 176412 diff --git a/libtommath/logs/sqr.log b/libtommath/logs/sqr.log index 0898342..cd29fc5 100644 --- a/libtommath/logs/sqr.log +++ b/libtommath/logs/sqr.log @@ -1,143 +1,84 @@ -271 552 -389 883 -510 1191 -629 1572 -750 1996 -863 2428 -991 2891 -1108 3539 -1231 4182 -1351 4980 -1471 5771 -1590 6551 -1711 7313 -1830 8240 -1951 9184 -2070 10087 -2191 11140 -2311 12111 -2431 13219 -2550 14247 -2669 15353 -2791 16446 -2911 17692 -3029 18848 -3151 20028 -3268 21282 -3391 22696 -3511 23971 -3631 25303 -3751 26675 -3871 28245 -3990 29736 -4111 31124 -4229 32714 -4347 34397 -4471 35877 -4587 37269 -4710 39011 -4831 40884 -4950 42501 -5070 44005 -5191 46026 -5310 48168 -5431 49801 -5551 51385 -5671 53604 -5787 55942 -5910 57757 -6031 59391 -6151 61754 -6271 64234 -6390 66110 -6511 67845 -6627 70474 -6751 73113 -6871 75064 -6990 76940 -7111 79681 -7230 82548 -7351 84597 -7471 86507 -7591 89497 -7711 225216 -7831 232192 -7951 239583 -8071 247302 -8191 255497 -8308 261587 -8431 271490 -8550 279492 -8671 286927 -8790 294680 -8910 302974 -9030 311300 -9150 318635 -9271 326740 -9390 335304 -9511 344297 -9630 352056 -9748 358652 -9870 369723 -9991 379119 -10111 386982 -10231 396075 -10349 404396 -10470 415375 -10590 424146 -10711 433390 -10829 442662 -10950 453238 -11071 462178 -11186 469811 -11311 482529 -11431 493214 -11550 503210 -11671 513486 -11791 524244 -11911 535277 -12031 544872 -12151 555695 -12271 566893 -12391 578385 -12510 588658 -12628 596914 -12751 611324 -12871 623437 -12991 633907 -13110 645605 -13231 657684 -13351 670037 -13471 680939 -13591 693047 -13710 705363 -13829 718178 -13949 727930 -14069 739641 -14190 754817 -14310 768192 -14431 779875 -14551 792655 -14667 802847 -14791 819806 -14911 831684 -15031 844936 -15151 858813 -15270 873037 -15387 882123 -15510 899117 -15631 913465 -15750 927989 -15870 940790 -15991 954948 -16110 969483 -16231 984544 -16350 997837 -16470 1012445 -16590 1027834 -16710 1043032 -16831 1056394 -16951 1071408 -17069 1097263 -17191 1113364 -17306 1123650 +265 562 +389 882 +509 1207 +631 1572 +750 1990 +859 2433 +991 2894 +1109 3555 +1230 4228 +1350 5018 +1471 5805 +1591 6579 +1709 7415 +1829 8329 +1949 9225 +2071 10139 +2188 11239 +2309 12178 +2431 13212 +2551 14294 +2671 15551 +2791 16512 +2911 17718 +3030 18876 +3150 20259 +3270 21374 +3391 22650 +3511 23948 +3631 25493 +3750 26756 +3870 28225 +3989 29705 +4110 31409 +4230 32834 +4351 34327 +4471 35818 +4591 37636 +4711 39228 +4830 40868 +4949 42393 +5070 44541 +5191 46269 +5310 48162 +5429 49728 +5548 51985 +5671 53948 +5791 55885 +5910 57584 +6031 60082 +6150 62239 +6270 64309 +6390 66014 +6511 68766 +6631 71012 +6750 73172 +6871 74952 +6991 77909 +7111 80371 +7231 82666 +7351 84531 +7469 87698 +7589 90318 +7711 225384 +7830 232428 +7950 240009 +8070 246522 +8190 253662 +8310 260961 +8431 269253 +8549 275743 +8671 283769 +8789 290811 +8911 300034 +9030 306873 +9149 315085 +9270 323944 +9390 332390 +9508 337519 +9631 348986 +9749 356904 +9871 367013 +9989 373831 +10108 381033 +10230 393475 diff --git a/libtommath/logs/sqr_kara.log b/libtommath/logs/sqr_kara.log index cafe458..06355a7 100644 --- a/libtommath/logs/sqr_kara.log +++ b/libtommath/logs/sqr_kara.log @@ -1,33 +1,84 @@ -922 11272 -1148 16004 -1370 21958 -1596 28684 -1817 37832 -2044 46386 -2262 56218 -2492 66388 -2716 77478 -2940 89380 -3163 103680 -3385 116274 -3612 135334 -3836 151332 -4057 164938 -4284 183178 -4508 198864 -4731 215222 -4954 231986 -5180 251660 -5404 269414 -5626 288454 -5850 307806 -6076 329458 -6299 347726 -6523 369864 -6748 387832 -6971 413010 -7194 453310 -7415 476936 -7643 497118 -7867 521394 -8091 540224 +271 560 +388 878 +511 1179 +629 1625 +751 1988 +871 2423 +989 2896 +1111 3561 +1231 4209 +1350 5015 +1470 5804 +1591 6556 +1709 7420 +1831 8263 +1951 9173 +2070 10153 +2191 11229 +2310 12167 +2431 13211 +2550 14309 +2671 15524 +2788 16525 +2910 17712 +3028 18822 +3148 20220 +3271 21343 +3391 22652 +3511 23944 +3630 25485 +3750 26778 +3868 28201 +3990 29653 +4111 31393 +4225 32841 +4350 34328 +4471 35786 +4590 37652 +4711 39245 +4830 40876 +4951 42433 +5068 44547 +5191 46321 +5311 48140 +5430 49727 +5550 52034 +5671 53954 +5791 55921 +5908 57597 +6031 60084 +6148 62226 +6270 64295 +6390 66045 +6511 68779 +6629 71003 +6751 73169 +6871 74992 +6991 77895 +7110 80376 +7231 82628 +7351 84468 +7470 87664 +7591 90284 +7711 91352 +7828 93995 +7950 96276 +8071 98691 +8190 101256 +8308 103631 +8431 105222 +8550 108343 +8671 110281 +8787 112764 +8911 115397 +9031 117690 +9151 120266 +9271 122715 +9391 124624 +9510 127937 +9630 130313 +9750 132914 +9871 136129 +9991 138517 +10108 141525 +10231 144225 diff --git a/libtommath/logs/sub.log b/libtommath/logs/sub.log index a42d91e..9f84fa2 100644 --- a/libtommath/logs/sub.log +++ b/libtommath/logs/sub.log @@ -1,16 +1,16 @@ -480 87 -960 114 -1440 139 -1920 159 -2400 204 -2880 228 -3360 250 -3840 273 -4320 300 +480 94 +960 116 +1440 140 +1920 164 +2400 205 +2880 229 +3360 253 +3840 277 +4320 299 4800 321 -5280 348 -5760 370 -6240 393 -6720 420 -7200 444 -7680 466 +5280 345 +5760 371 +6240 395 +6720 419 +7200 441 +7680 465 diff --git a/libtommath/makefile b/libtommath/makefile index 164a0ab..17873ee 100644 --- a/libtommath/makefile +++ b/libtommath/makefile @@ -3,7 +3,7 @@ #Tom St Denis #version of library -VERSION=0.33 +VERSION=0.35 CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare @@ -57,11 +57,13 @@ bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_reduce_2k_l.o bn_mp_reduce_is_2k_l.o bn_mp_reduce_2k_setup_l.o \ bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ -bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ +bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o libtommath.a: $(OBJECTS) $(AR) $(ARFLAGS) libtommath.a $(OBJECTS) diff --git a/libtommath/makefile.bcc b/libtommath/makefile.bcc index 775e9ff..647c69a 100644 --- a/libtommath/makefile.bcc +++ b/libtommath/makefile.bcc @@ -27,11 +27,13 @@ bn_mp_prime_is_prime.obj bn_mp_prime_next_prime.obj bn_mp_dr_reduce.obj \ bn_mp_dr_is_modulus.obj bn_mp_dr_setup.obj bn_mp_reduce_setup.obj \ bn_mp_toom_mul.obj bn_mp_toom_sqr.obj bn_mp_div_3.obj bn_s_mp_exptmod.obj \ bn_mp_reduce_2k.obj bn_mp_reduce_is_2k.obj bn_mp_reduce_2k_setup.obj \ +bn_mp_reduce_2k_l.obj bn_mp_reduce_is_2k_l.obj bn_mp_reduce_2k_setup_l.obj \ bn_mp_radix_smap.obj bn_mp_read_radix.obj bn_mp_toradix.obj bn_mp_radix_size.obj \ bn_mp_fread.obj bn_mp_fwrite.obj bn_mp_cnt_lsb.obj bn_error.obj \ bn_mp_init_multi.obj bn_mp_clear_multi.obj bn_mp_exteuclid.obj bn_mp_toradix_n.obj \ bn_mp_prime_random_ex.obj bn_mp_get_int.obj bn_mp_sqrt.obj bn_mp_is_square.obj \ -bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj +bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj \ +bn_mp_to_signed_bin_n.obj bn_mp_to_unsigned_bin_n.obj TARGET = libtommath.lib diff --git a/libtommath/makefile.cygwin_dll b/libtommath/makefile.cygwin_dll index c90e5d9..85b10c7 100644 --- a/libtommath/makefile.cygwin_dll +++ b/libtommath/makefile.cygwin_dll @@ -32,11 +32,13 @@ bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_reduce_2k_l.o bn_mp_reduce_is_2k_l.o bn_mp_reduce_2k_setup_l.o \ bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ -bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ +bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o # make a Windows DLL via Cygwin windll: $(OBJECTS) diff --git a/libtommath/makefile.icc b/libtommath/makefile.icc index 3775b20..e764253 100644 --- a/libtommath/makefile.icc +++ b/libtommath/makefile.icc @@ -59,11 +59,13 @@ bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_reduce_2k_l.o bn_mp_reduce_is_2k_l.o bn_mp_reduce_2k_setup_l.o \ bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ -bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ +bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o libtommath.a: $(OBJECTS) $(AR) $(ARFLAGS) libtommath.a $(OBJECTS) diff --git a/libtommath/makefile.msvc b/libtommath/makefile.msvc index cf59943..dbbf9f3 100644 --- a/libtommath/makefile.msvc +++ b/libtommath/makefile.msvc @@ -26,11 +26,13 @@ bn_mp_prime_is_prime.obj bn_mp_prime_next_prime.obj bn_mp_dr_reduce.obj \ bn_mp_dr_is_modulus.obj bn_mp_dr_setup.obj bn_mp_reduce_setup.obj \ bn_mp_toom_mul.obj bn_mp_toom_sqr.obj bn_mp_div_3.obj bn_s_mp_exptmod.obj \ bn_mp_reduce_2k.obj bn_mp_reduce_is_2k.obj bn_mp_reduce_2k_setup.obj \ +bn_mp_reduce_2k_l.obj bn_mp_reduce_is_2k_l.obj bn_mp_reduce_2k_setup_l.obj \ bn_mp_radix_smap.obj bn_mp_read_radix.obj bn_mp_toradix.obj bn_mp_radix_size.obj \ bn_mp_fread.obj bn_mp_fwrite.obj bn_mp_cnt_lsb.obj bn_error.obj \ bn_mp_init_multi.obj bn_mp_clear_multi.obj bn_mp_exteuclid.obj bn_mp_toradix_n.obj \ bn_mp_prime_random_ex.obj bn_mp_get_int.obj bn_mp_sqrt.obj bn_mp_is_square.obj \ -bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj +bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj \ +bn_mp_to_signed_bin_n.obj bn_mp_to_unsigned_bin_n.obj library: $(OBJECTS) lib /out:tommath.lib $(OBJECTS) diff --git a/libtommath/makefile.shared b/libtommath/makefile.shared index 86a3786..7c35881 100644 --- a/libtommath/makefile.shared +++ b/libtommath/makefile.shared @@ -1,7 +1,7 @@ #Makefile for GCC # #Tom St Denis -VERSION=0:33 +VERSION=0:35 CC = libtool --mode=compile gcc CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare @@ -53,11 +53,14 @@ bn_mp_prime_is_prime.o bn_mp_prime_next_prime.o bn_mp_dr_reduce.o \ bn_mp_dr_is_modulus.o bn_mp_dr_setup.o bn_mp_reduce_setup.o \ bn_mp_toom_mul.o bn_mp_toom_sqr.o bn_mp_div_3.o bn_s_mp_exptmod.o \ bn_mp_reduce_2k.o bn_mp_reduce_is_2k.o bn_mp_reduce_2k_setup.o \ +bn_mp_reduce_2k_l.o bn_mp_reduce_is_2k_l.o bn_mp_reduce_2k_setup_l.o \ bn_mp_radix_smap.o bn_mp_read_radix.o bn_mp_toradix.o bn_mp_radix_size.o \ bn_mp_fread.o bn_mp_fwrite.o bn_mp_cnt_lsb.o bn_error.o \ bn_mp_init_multi.o bn_mp_clear_multi.o bn_mp_exteuclid.o bn_mp_toradix_n.o \ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_init_set.o \ -bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o +bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ +bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o + libtommath.la: $(OBJECTS) libtool --mode=link gcc *.lo -o libtommath.la -rpath $(LIBPATH) -version-info $(VERSION) diff --git a/libtommath/pics/expt_state.tif b/libtommath/pics/expt_state.tif index cb06e8e..0aaee39 100644 Binary files a/libtommath/pics/expt_state.tif and b/libtommath/pics/expt_state.tif differ diff --git a/libtommath/pics/primality.tif b/libtommath/pics/primality.tif index 76d6be3..83aafe0 100644 Binary files a/libtommath/pics/primality.tif and b/libtommath/pics/primality.tif differ diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf index e0b4f84..4c3e365 100644 Binary files a/libtommath/poster.pdf and b/libtommath/poster.pdf differ diff --git a/libtommath/pre_gen/mpi.c b/libtommath/pre_gen/mpi.c index 7d832e7..8ec8a10 100644 --- a/libtommath/pre_gen/mpi.c +++ b/libtommath/pre_gen/mpi.c @@ -69,8 +69,7 @@ char *mp_error_to_string(int code) * Based on slow invmod except this is optimized for the case where b is * odd as per HAC Note 14.64 on pp. 610 */ -int -fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) +int fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) { mp_int x, y, u, v, B, D; int res, neg; @@ -91,7 +90,7 @@ fast_mp_invmod (mp_int * a, mp_int * b, mp_int * c) } /* we need y = |a| */ - if ((res = mp_abs (a, &y)) != MP_OKAY) { + if ((res = mp_mod (a, b, &y)) != MP_OKAY) { goto LBL_ERR; } @@ -220,8 +219,7 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); * * Based on Algorithm 14.32 on pp.601 of HAC. */ -int -fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) { int ix, res, olduse; mp_word W[MP_WARRAY]; @@ -401,8 +399,7 @@ fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) * Based on Algorithm 14.12 on pp.595 of HAC. * */ -int -fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { int olduse, res, pa, ix, iz; mp_digit W[MP_WARRAY]; @@ -433,7 +430,7 @@ fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) tmpx = a->dp + tx; tmpy = b->dp + ty; - /* this is the number of times the loop will iterrate, essentially its + /* this is the number of times the loop will iterrate, essentially while (tx++ < a->used && ty-- >= 0) { ... } */ iy = MIN(a->used-tx, ty+1); @@ -451,16 +448,16 @@ fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } /* store final carry */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* setup dest */ olduse = c->used; - c->used = digs; + c->used = pa; { register mp_digit *tmpc; tmpc = c->dp; - for (ix = 0; ix < digs; ix++) { + for (ix = 0; ix < pa+1; ix++) { /* now extract the previous digit [below the carry] */ *tmpc++ = W[ix]; } @@ -504,8 +501,7 @@ fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * * Based on Algorithm 14.12 on pp.595 of HAC. */ -int -fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { int olduse, res, pa, ix, iz; mp_digit W[MP_WARRAY]; @@ -552,7 +548,7 @@ fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } /* store final carry */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* setup dest */ olduse = c->used; @@ -597,33 +593,14 @@ fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org */ -/* fast squaring - * - * This is the comba method where the columns of the product - * are computed first then the carries are computed. This - * has the effect of making a very simple inner loop that - * is executed the most - * - * W2 represents the outer products and W the inner. - * - * A further optimizations is made because the inner - * products are of the form "A * B * 2". The *2 part does - * not need to be computed until the end which is good - * because 64-bit shifts are slow! - * - * Based on Algorithm 14.16 on pp.597 of HAC. - * - */ /* the jist of squaring... - -you do like mult except the offset of the tmpx [one that starts closer to zero] -can't equal the offset of tmpy. So basically you set up iy like before then you min it with -(ty-tx) so that it never happens. You double all those you add in the inner loop + * you do like mult except the offset of the tmpx [one that + * starts closer to zero] can't equal the offset of tmpy. + * So basically you set up iy like before then you min it with + * (ty-tx) so that it never happens. You double all those + * you add in the inner loop After that loop you do the squares and add them in. - -Remove W2 and don't memset W - */ int fast_s_mp_sqr (mp_int * a, mp_int * b) @@ -658,7 +635,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) tmpx = a->dp + tx; tmpy = a->dp + ty; - /* this is the number of times the loop will iterrate, essentially its + /* this is the number of times the loop will iterrate, essentially while (tx++ < a->used && ty-- >= 0) { ... } */ iy = MIN(a->used-tx, ty+1); @@ -683,7 +660,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) } /* store it */ - W[ix] = _W; + W[ix] = (mp_digit)(_W & MP_MASK); /* make next carry */ W1 = _W >> ((mp_word)DIGIT_BIT); @@ -2467,21 +2444,29 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif } +/* modified diminished radix reduction */ +#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) + if (mp_reduce_is_2k_l(P) == MP_YES) { + return s_mp_exptmod(G, X, P, Y, 1); + } +#endif + #ifdef BN_MP_DR_IS_MODULUS_C /* is it a DR modulus? */ dr = mp_dr_is_modulus(P); #else + /* default to no */ dr = 0; #endif #ifdef BN_MP_REDUCE_IS_2K_C - /* if not, is it a uDR modulus? */ + /* if not, is it a unrestricted DR modulus? */ if (dr == 0) { dr = mp_reduce_is_2k(P) << 1; } #endif - /* if the modulus is odd or dr != 0 use the fast method */ + /* if the modulus is odd or dr != 0 use the montgomery method */ #ifdef BN_MP_EXPTMOD_FAST_C if (mp_isodd (P) == 1 || dr != 0) { return mp_exptmod_fast (G, X, P, Y, dr); @@ -2489,7 +2474,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif #ifdef BN_S_MP_EXPTMOD_C /* otherwise use the generic Barrett reduction technique */ - return s_mp_exptmod (G, X, P, Y); + return s_mp_exptmod (G, X, P, Y, 0); #else /* no exptmod for evens */ return MP_VAL; @@ -2535,8 +2520,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #define TAB_SIZE 256 #endif -int -mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) +int mp_exptmod_fast (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) { mp_int M[TAB_SIZE], res; mp_digit buf, mp; @@ -2887,6 +2871,13 @@ int mp_exteuclid(mp_int *a, mp_int *b, mp_int *U1, mp_int *U2, mp_int *U3) if ((err = mp_copy(&t3, &v3)) != MP_OKAY) { goto _ERR; } } + /* make sure U3 >= 0 */ + if (u3.sign == MP_NEG) { + mp_neg(&u1, &u1); + mp_neg(&u2, &u2); + mp_neg(&u3, &u3); + } + /* copy result out */ if (U1 != NULL) { mp_exch(U1, &u1); } if (U2 != NULL) { mp_exch(U2, &u2); } @@ -3561,8 +3552,8 @@ int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c) } /* x = a, y = b */ - if ((res = mp_copy (a, &x)) != MP_OKAY) { - goto LBL_ERR; + if ((res = mp_mod(a, b, &x)) != MP_OKAY) { + goto LBL_ERR; } if ((res = mp_copy (b, &y)) != MP_OKAY) { goto LBL_ERR; @@ -4490,7 +4481,6 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) /* how many bits of last digit does b use */ bits = mp_count_bits (b) % DIGIT_BIT; - if (b->used > 1) { if ((res = mp_2expt (a, (b->used - 1) * DIGIT_BIT + bits - 1)) != MP_OKAY) { return res; @@ -4989,8 +4979,9 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); } - /* store final carry [if any] */ + /* store final carry [if any] and increment ix offset */ *tmpc++ = u; + ++ix; /* now zero digits above the top */ while (ix++ < olduse) { @@ -5202,12 +5193,18 @@ LBL_T1:mp_clear (&t1); int mp_neg (mp_int * a, mp_int * b) { int res; - if ((res = mp_copy (a, b)) != MP_OKAY) { - return res; + if (a != b) { + if ((res = mp_copy (a, b)) != MP_OKAY) { + return res; + } } + if (mp_iszero(b) != MP_YES) { b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; + } else { + b->sign = MP_ZPOS; } + return MP_OKAY; } #endif @@ -5847,7 +5844,7 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback /* calc the maskOR_msb */ maskOR_msb = 0; - maskOR_msb_offset = (size - 2) >> 3; + maskOR_msb_offset = ((size & 7) == 1) ? 1 : 0; if (flags & LTM_PRIME_2MSB_ON) { maskOR_msb |= 1 << ((size - 2) & 7); } else if (flags & LTM_PRIME_2MSB_OFF) { @@ -5855,7 +5852,7 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback } /* get the maskOR_lsb */ - maskOR_lsb = 0; + maskOR_lsb = 1; if (flags & LTM_PRIME_BBS) { maskOR_lsb |= 3; } @@ -5949,22 +5946,29 @@ int mp_radix_size (mp_int * a, int radix, int *size) return MP_VAL; } - /* init a copy of the input */ - if ((res = mp_init_copy (&t, a)) != MP_OKAY) { - return res; + if (mp_iszero(a) == MP_YES) { + *size = 2; + return MP_OKAY; } /* digs is the digit count */ digs = 0; /* if it's negative add one for the sign */ - if (t.sign == MP_NEG) { + if (a->sign == MP_NEG) { ++digs; - t.sign = MP_ZPOS; } + /* init a copy of the input */ + if ((res = mp_init_copy (&t, a)) != MP_OKAY) { + return res; + } + + /* force temp to positive */ + t.sign = MP_ZPOS; + /* fetch out all of the digits */ - while (mp_iszero (&t) == 0) { + while (mp_iszero (&t) == MP_NO) { if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { mp_clear (&t); return res; @@ -6038,14 +6042,14 @@ mp_rand (mp_int * a, int digits) /* first place a random non-zero digit */ do { - d = ((mp_digit) abs (rand ())); + d = ((mp_digit) abs (rand ())) & MP_MASK; } while (d == 0); if ((res = mp_add_d (a, d, a)) != MP_OKAY) { return res; } - while (digits-- > 0) { + while (--digits > 0) { if ((res = mp_lshd (a, 1)) != MP_OKAY) { return res; } @@ -6080,7 +6084,7 @@ mp_rand (mp_int * a, int digits) */ /* read a string [ASCII] in a given radix */ -int mp_read_radix (mp_int * a, char *str, int radix) +int mp_read_radix (mp_int * a, const char *str, int radix) { int y, res, neg; char ch; @@ -6263,8 +6267,7 @@ mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) * precomputed via mp_reduce_setup. * From HAC pp.604 Algorithm 14.42 */ -int -mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +int mp_reduce (mp_int * x, mp_int * m, mp_int * mu) { mp_int q; int res, um = m->used; @@ -6284,11 +6287,11 @@ mp_reduce (mp_int * x, mp_int * m, mp_int * mu) } } else { #ifdef BN_S_MP_MUL_HIGH_DIGS_C - if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + if ((res = s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) { goto CLEANUP; } #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) - if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) { + if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) { goto CLEANUP; } #else @@ -6361,8 +6364,7 @@ CLEANUP: */ /* reduces a modulo n where n is of the form 2**p - d */ -int -mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) { mp_int q; int p, res; @@ -6404,6 +6406,68 @@ ERR: /* End: bn_mp_reduce_2k.c */ +/* Start: bn_mp_reduce_2k_l.c */ +#include +#ifdef BN_MP_REDUCE_2K_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* reduces a modulo n where n is of the form 2**p - d + This differs from reduce_2k since "d" can be larger + than a single digit. +*/ +int mp_reduce_2k_l(mp_int *a, mp_int *n, mp_int *d) +{ + mp_int q; + int p, res; + + if ((res = mp_init(&q)) != MP_OKAY) { + return res; + } + + p = mp_count_bits(n); +top: + /* q = a/2**p, a = a mod 2**p */ + if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) { + goto ERR; + } + + /* q = q * d */ + if ((res = mp_mul(&q, d, &q)) != MP_OKAY) { + goto ERR; + } + + /* a = a + q */ + if ((res = s_mp_add(a, &q, a)) != MP_OKAY) { + goto ERR; + } + + if (mp_cmp_mag(a, n) != MP_LT) { + s_mp_sub(a, n, a); + goto top; + } + +ERR: + mp_clear(&q); + return res; +} + +#endif + +/* End: bn_mp_reduce_2k_l.c */ + /* Start: bn_mp_reduce_2k_setup.c */ #include #ifdef BN_MP_REDUCE_2K_SETUP_C @@ -6423,8 +6487,7 @@ ERR: */ /* determines the setup value */ -int -mp_reduce_2k_setup(mp_int *a, mp_digit *d) +int mp_reduce_2k_setup(mp_int *a, mp_digit *d) { int res, p; mp_int tmp; @@ -6452,6 +6515,50 @@ mp_reduce_2k_setup(mp_int *a, mp_digit *d) /* End: bn_mp_reduce_2k_setup.c */ +/* Start: bn_mp_reduce_2k_setup_l.c */ +#include +#ifdef BN_MP_REDUCE_2K_SETUP_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines the setup value */ +int mp_reduce_2k_setup_l(mp_int *a, mp_int *d) +{ + int res; + mp_int tmp; + + if ((res = mp_init(&tmp)) != MP_OKAY) { + return res; + } + + if ((res = mp_2expt(&tmp, mp_count_bits(a))) != MP_OKAY) { + goto ERR; + } + + if ((res = s_mp_sub(&tmp, a, d)) != MP_OKAY) { + goto ERR; + } + +ERR: + mp_clear(&tmp); + return res; +} +#endif + +/* End: bn_mp_reduce_2k_setup_l.c */ + /* Start: bn_mp_reduce_is_2k.c */ #include #ifdef BN_MP_REDUCE_IS_2K_C @@ -6477,9 +6584,9 @@ int mp_reduce_is_2k(mp_int *a) mp_digit iz; if (a->used == 0) { - return 0; + return MP_NO; } else if (a->used == 1) { - return 1; + return MP_YES; } else if (a->used > 1) { iy = mp_count_bits(a); iz = 1; @@ -6488,7 +6595,7 @@ int mp_reduce_is_2k(mp_int *a) /* Test every bit from the second digit up, must be 1 */ for (ix = DIGIT_BIT; ix < iy; ix++) { if ((a->dp[iw] & iz) == 0) { - return 0; + return MP_NO; } iz <<= 1; if (iz > (mp_digit)MP_MASK) { @@ -6497,13 +6604,57 @@ int mp_reduce_is_2k(mp_int *a) } } } - return 1; + return MP_YES; } #endif /* End: bn_mp_reduce_is_2k.c */ +/* Start: bn_mp_reduce_is_2k_l.c */ +#include +#ifdef BN_MP_REDUCE_IS_2K_L_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* determines if reduce_2k_l can be used */ +int mp_reduce_is_2k_l(mp_int *a) +{ + int ix, iy; + + if (a->used == 0) { + return MP_NO; + } else if (a->used == 1) { + return MP_YES; + } else if (a->used > 1) { + /* if more than half of the digits are -1 we're sold */ + for (iy = ix = 0; ix < a->used; ix++) { + if (a->dp[ix] == MP_MASK) { + ++iy; + } + } + return (iy >= (a->used/2)) ? MP_YES : MP_NO; + + } + return MP_NO; +} + +#endif + +/* End: bn_mp_reduce_is_2k_l.c */ + /* Start: bn_mp_reduce_setup.c */ #include #ifdef BN_MP_REDUCE_SETUP_C @@ -7138,8 +7289,7 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) */ /* store in signed [big endian] format */ -int -mp_to_signed_bin (mp_int * a, unsigned char *b) +int mp_to_signed_bin (mp_int * a, unsigned char *b) { int res; @@ -7153,6 +7303,37 @@ mp_to_signed_bin (mp_int * a, unsigned char *b) /* End: bn_mp_to_signed_bin.c */ +/* Start: bn_mp_to_signed_bin_n.c */ +#include +#ifdef BN_MP_TO_SIGNED_BIN_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in signed [big endian] format */ +int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) +{ + if (*outlen < (unsigned long)mp_signed_bin_size(a)) { + return MP_VAL; + } + *outlen = mp_signed_bin_size(a); + return mp_to_signed_bin(a, b); +} +#endif + +/* End: bn_mp_to_signed_bin_n.c */ + /* Start: bn_mp_to_unsigned_bin.c */ #include #ifdef BN_MP_TO_UNSIGNED_BIN_C @@ -7172,8 +7353,7 @@ mp_to_signed_bin (mp_int * a, unsigned char *b) */ /* store in unsigned [big endian] format */ -int -mp_to_unsigned_bin (mp_int * a, unsigned char *b) +int mp_to_unsigned_bin (mp_int * a, unsigned char *b) { int x, res; mp_int t; @@ -7202,6 +7382,37 @@ mp_to_unsigned_bin (mp_int * a, unsigned char *b) /* End: bn_mp_to_unsigned_bin.c */ +/* Start: bn_mp_to_unsigned_bin_n.c */ +#include +#ifdef BN_MP_TO_UNSIGNED_BIN_N_C +/* LibTomMath, multiple-precision integer library -- Tom St Denis + * + * LibTomMath is a library that provides multiple-precision + * integer arithmetic as well as number theoretic functionality. + * + * The library was designed directly after the MPI library by + * Michael Fromberger but has been written from scratch with + * additional optimizations in place. + * + * The library is free for all purposes without any express + * guarantee it works. + * + * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + */ + +/* store in unsigned [big endian] format */ +int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) +{ + if (*outlen < (unsigned long)mp_unsigned_bin_size(a)) { + return MP_VAL; + } + *outlen = mp_unsigned_bin_size(a); + return mp_to_unsigned_bin(a, b); +} +#endif + +/* End: bn_mp_to_unsigned_bin_n.c */ + /* Start: bn_mp_toom_mul.c */ #include #ifdef BN_MP_TOOM_MUL_C @@ -7222,9 +7433,10 @@ mp_to_unsigned_bin (mp_int * a, unsigned char *b) /* multiplication using the Toom-Cook 3-way algorithm * - * Much more complicated than Karatsuba but has a lower asymptotic running time of - * O(N**1.464). This algorithm is only particularly useful on VERY large - * inputs (we're talking 1000s of digits here...). + * Much more complicated than Karatsuba but has a lower + * asymptotic running time of O(N**1.464). This algorithm is + * only particularly useful on VERY large inputs + * (we're talking 1000s of digits here...). */ int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) { @@ -7894,8 +8106,7 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) */ /* get the size for an unsigned equivalent */ -int -mp_unsigned_bin_size (mp_int * a) +int mp_unsigned_bin_size (mp_int * a) { int size = mp_count_bits (a); return (size / 8 + ((size & 7) != 0 ? 1 : 0)); @@ -7944,7 +8155,7 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) } for (ix = 0; ix < px; ix++) { - + t.dp[ix] ^= x->dp[ix]; } mp_clamp (&t); mp_exch (c, &t); @@ -7974,12 +8185,18 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) */ /* set to zero */ -void -mp_zero (mp_int * a) +void mp_zero (mp_int * a) { + int n; + mp_digit *tmp; + a->sign = MP_ZPOS; a->used = 0; - memset (a->dp, 0, sizeof (mp_digit) * a->alloc); + + tmp = a->dp; + for (n = 0; n < a->alloc; n++) { + *tmp++ = 0; + } } #endif @@ -8218,11 +8435,12 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) #define TAB_SIZE 256 #endif -int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmode) { mp_int M[TAB_SIZE], res, mu; mp_digit buf; int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; + int (*redux)(mp_int*,mp_int*,mp_int*); /* find window size */ x = mp_count_bits (X); @@ -8269,9 +8487,18 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_init (&mu)) != MP_OKAY) { goto LBL_M; } - if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { - goto LBL_MU; - } + + if (redmode == 0) { + if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) { + goto LBL_MU; + } + redux = mp_reduce; + } else { + if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) { + goto LBL_MU; + } + redux = mp_reduce_2k_l; + } /* create M table * @@ -8293,11 +8520,14 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) } for (x = 0; x < (winsize - 1); x++) { + /* square it */ if ((err = mp_sqr (&M[1 << (winsize - 1)], &M[1 << (winsize - 1)])) != MP_OKAY) { goto LBL_MU; } - if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { + + /* reduce modulo P */ + if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) { goto LBL_MU; } } @@ -8309,7 +8539,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) { goto LBL_MU; } - if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) { + if ((err = redux (&M[x], P, &mu)) != MP_OKAY) { goto LBL_MU; } } @@ -8358,7 +8588,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } continue; @@ -8375,7 +8605,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } } @@ -8384,7 +8614,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } @@ -8402,7 +8632,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_sqr (&res, &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } @@ -8412,7 +8642,7 @@ int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) { goto LBL_RES; } - if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) { + if ((err = redux (&res, P, &mu)) != MP_OKAY) { goto LBL_RES; } } @@ -8456,8 +8686,7 @@ LBL_M: * HAC pp. 595, Algorithm 14.12 Modified so you can control how * many digits of output are created. */ -int -s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) { mp_int t; int res, pa, pb, ix, iy; @@ -8625,8 +8854,7 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) */ /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ -int -s_mp_sqr (mp_int * a, mp_int * b) +int s_mp_sqr (mp_int * a, mp_int * b) { mp_int t; int res, ix, iy, pa; @@ -8803,11 +9031,12 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) CPU /Compiler /MUL CUTOFF/SQR CUTOFF ------------------------------------------------------------- Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) + AMD Athlon64 /GCC v3.4.4 / 74/ 124/LTM 0.34 */ -int KARATSUBA_MUL_CUTOFF = 88, /* Min. number of digits before Karatsuba multiplication is used. */ - KARATSUBA_SQR_CUTOFF = 128, /* Min. number of digits before Karatsuba squaring is used. */ +int KARATSUBA_MUL_CUTOFF = 74, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 124, /* Min. number of digits before Karatsuba squaring is used. */ TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ TOOM_SQR_CUTOFF = 400; diff --git a/libtommath/tommath.h b/libtommath/tommath.h index 7cc92c2..bcb9d86 100644 --- a/libtommath/tommath.h +++ b/libtommath/tommath.h @@ -429,6 +429,15 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d); /* reduces a modulo b where b is of the form 2**p - k [0 <= a] */ int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d); +/* returns true if a can be reduced with mp_reduce_2k_l */ +int mp_reduce_is_2k_l(mp_int *a); + +/* determines k value for 2k reduction */ +int mp_reduce_2k_setup_l(mp_int *a, mp_int *d); + +/* reduces a modulo b where b is of the form 2**p - k [0 <= a] */ +int mp_reduce_2k_l(mp_int *a, mp_int *n, mp_int *d); + /* d = a**b (mod c) */ int mp_exptmod(mp_int *a, mp_int *b, mp_int *c, mp_int *d); @@ -511,12 +520,14 @@ int mp_count_bits(mp_int *a); int mp_unsigned_bin_size(mp_int *a); int mp_read_unsigned_bin(mp_int *a, unsigned char *b, int c); int mp_to_unsigned_bin(mp_int *a, unsigned char *b); +int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen); int mp_signed_bin_size(mp_int *a); int mp_read_signed_bin(mp_int *a, unsigned char *b, int c); int mp_to_signed_bin(mp_int *a, unsigned char *b); +int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen); -int mp_read_radix(mp_int *a, char *str, int radix); +int mp_read_radix(mp_int *a, const char *str, int radix); int mp_toradix(mp_int *a, char *str, int radix); int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen); int mp_radix_size(mp_int *a, int radix, int *size); @@ -554,7 +565,7 @@ int fast_mp_invmod(mp_int *a, mp_int *b, mp_int *c); int mp_invmod_slow (mp_int * a, mp_int * b, mp_int * c); int fast_mp_montgomery_reduce(mp_int *a, mp_int *m, mp_digit mp); int mp_exptmod_fast(mp_int *G, mp_int *X, mp_int *P, mp_int *Y, int mode); -int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y); +int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int mode); void bn_reverse(unsigned char *s, int len); extern const char *mp_s_rmap; diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf index 88e2dc7..c486d29 100644 Binary files a/libtommath/tommath.pdf and b/libtommath/tommath.pdf differ diff --git a/libtommath/tommath.src b/libtommath/tommath.src index 6ee842d..7a53860 100644 --- a/libtommath/tommath.src +++ b/libtommath/tommath.src @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{Implementing Multiple Precision Arithmetic \\ ~ \\ Draft Edition } +\title{Multi--Precision Math} \author{\mbox{ %\begin{small} \begin{tabular}{c} @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.30 release of the +This text has been placed in the public domain. This text corresponds to the v0.35 release of the LibTomMath project. \begin{alltt} @@ -85,66 +85,32 @@ This text is formatted to the international B5 paper size of 176mm wide by 250mm \tableofcontents \listoffigures -\chapter*{Prefaces to the Draft Edition} -I started this text in April 2003 to complement my LibTomMath library. That is, explain how to implement the functions -contained in LibTomMath. The goal is to have a textbook that any Computer Science student can use when implementing their -own multiple precision arithmetic. The plan I wanted to follow was flesh out all the -ideas and concepts I had floating around in my head and then work on it afterwards refining a little bit at a time. Chance -would have it that I ended up with my summer off from Algonquin College and I was given four months solid to work on the -text. - -Choosing to not waste any time I dove right into the project even before my spring semester was finished. I wrote a bit -off and on at first. The moment my exams were finished I jumped into long 12 to 16 hour days. The result after only -a couple of months was a ten chapter, three hundred page draft that I quickly had distributed to anyone who wanted -to read it. I had Jean-Luc Cooke print copies for me and I brought them to Crypto'03 in Santa Barbara. So far I have -managed to grab a certain level of attention having people from around the world ask me for copies of the text was certain -rewarding. - -Now we are past December 2003. By this time I had pictured that I would have at least finished my second draft of the text. -Currently I am far off from this goal. I've done partial re-writes of chapters one, two and three but they are not even -finished yet. I haven't given up on the project, only had some setbacks. First O'Reilly declined to publish the text then -Addison-Wesley and Greg is tried another which I don't know the name of. However, at this point I want to focus my energy -onto finishing the book not securing a contract. - -So why am I writing this text? It seems like a lot of work right? Most certainly it is a lot of work writing a textbook. -Even the simplest introductory material has to be lined with references and figures. A lot of the text has to be re-written -from point form to prose form to ensure an easier read. Why am I doing all this work for free then? Simple. My philosophy -is quite simply ``Open Source. Open Academia. Open Minds'' which means that to achieve a goal of open minds, that is, -people willing to accept new ideas and explore the unknown you have to make available material they can access freely -without hinderance. - -I've been writing free software since I was about sixteen but only recently have I hit upon software that people have come -to depend upon. I started LibTomCrypt in December 2001 and now several major companies use it as integral portions of their -software. Several educational institutions use it as a matter of course and many freelance developers use it as -part of their projects. To further my contributions I started the LibTomMath project in December 2002 aimed at providing -multiple precision arithmetic routines that students could learn from. That is write routines that are not only easy -to understand and follow but provide quite impressive performance considering they are all in standard portable ISO C. - -The second leg of my philosophy is ``Open Academia'' which is where this textbook comes in. In the end, when all is -said and done the text will be useable by educational institutions as a reference on multiple precision arithmetic. - -At this time I feel I should share a little information about myself. The most common question I was asked at -Crypto'03, perhaps just out of professional courtesy, was which school I either taught at or attended. The unfortunate -truth is that I neither teach at or attend a school of academic reputation. I'm currently at Algonquin College which -is what I'd like to call ``somewhat academic but mostly vocational'' college. In otherwords, job training. - -I'm a 21 year old computer science student mostly self-taught in the areas I am aware of (which includes a half-dozen -computer science fields, a few fields of mathematics and some English). I look forward to teaching someday but I am -still far off from that goal. - -Now it would be improper for me to not introduce the rest of the texts co-authors. While they are only contributing -corrections and editorial feedback their support has been tremendously helpful in presenting the concepts laid out -in the text so far. Greg has always been there for me. He has tracked my LibTom projects since their inception and even -sent cheques to help pay tuition from time to time. His background has provided a wonderful source to bounce ideas off -of and improve the quality of my writing. Mads is another fellow who has just ``been there''. I don't even recall what -his interest in the LibTom projects is but I'm definitely glad he has been around. His ability to catch logical errors -in my written English have saved me on several occasions to say the least. - -What to expect next? Well this is still a rough draft. I've only had the chance to update a few chapters. However, I've -been getting the feeling that people are starting to use my text and I owe them some updated material. My current tenative -plan is to edit one chapter every two weeks starting January 4th. It seems insane but my lower course load at college -should provide ample time. By Crypto'04 I plan to have a 2nd draft of the text polished and ready to hand out to as many -people who will take it. +\chapter*{Prefaces} +When I tell people about my LibTom projects and that I release them as public domain they are often puzzled. +They ask why I did it and especially why I continue to work on them for free. The best I can explain it is ``Because I can.'' +Which seems odd and perhaps too terse for adult conversation. I often qualify it with ``I am able, I am willing.'' which +perhaps explains it better. I am the first to admit there is not anything that special with what I have done. Perhaps +others can see that too and then we would have a society to be proud of. My LibTom projects are what I am doing to give +back to society in the form of tools and knowledge that can help others in their endeavours. + +I started writing this book because it was the most logical task to further my goal of open academia. The LibTomMath source +code itself was written to be easy to follow and learn from. There are times, however, where pure C source code does not +explain the algorithms properly. Hence this book. The book literally starts with the foundation of the library and works +itself outwards to the more complicated algorithms. The use of both pseudo--code and verbatim source code provides a duality +of ``theory'' and ``practice'' that the computer science students of the world shall appreciate. I never deviate too far +from relatively straightforward algebra and I hope that this book can be a valuable learning asset. + +This book and indeed much of the LibTom projects would not exist in their current form if it was not for a plethora +of kind people donating their time, resources and kind words to help support my work. Writing a text of significant +length (along with the source code) is a tiresome and lengthy process. Currently the LibTom project is four years old, +comprises of literally thousands of users and over 100,000 lines of source code, TeX and other material. People like Mads and Greg +were there at the beginning to encourage me to work well. It is amazing how timely validation from others can boost morale to +continue the project. Definitely my parents were there for me by providing room and board during the many months of work in 2003. + +To my many friends whom I have met through the years I thank you for the good times and the words of encouragement. I hope I +honour your kind gestures with this project. + +Open Source. Open Academia. Open Minds. \begin{flushright} Tom St Denis \end{flushright} @@ -937,7 +903,7 @@ assumed to contain undefined values they are initially set to zero. EXAM,bn_mp_grow.c -A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line @23,if@) checks +A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line @24,alloc@) checks if the \textbf{alloc} member of the mp\_int is smaller than the requested digit count. If the count is not larger than \textbf{alloc} the function skips the re-allocation part thus saving time. @@ -1310,7 +1276,7 @@ After the function is completed, all of the digits are zeroed, the \textbf{used} With the mp\_int representation of an integer, calculating the absolute value is trivial. The mp\_abs algorithm will compute the absolute value of an mp\_int. -\newpage\begin{figure}[here] +\begin{figure}[here] \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{mp\_abs}. \\ @@ -1335,6 +1301,9 @@ logic to handle it. EXAM,bn_mp_abs.c +This fairly trivial algorithm first eliminates non--required duplications (line @27,a != b@) and then sets the +\textbf{sign} flag to \textbf{MP\_ZPOS}. + \subsection{Integer Negation} With the mp\_int representation of an integer, calculating the negation is also trivial. The mp\_neg algorithm will compute the negative of an mp\_int input. @@ -1368,11 +1337,15 @@ zero as negative. EXAM,bn_mp_neg.c +Like mp\_abs() this function avoids non--required duplications (line @21,a != b@) and then sets the sign. We +have to make sure that only non--zero values get a \textbf{sign} of \textbf{MP\_NEG}. If the mp\_int is zero +than the \textbf{sign} is hard--coded to \textbf{MP\_ZPOS}. + \section{Small Constants} \subsection{Setting Small Constants} Often a mp\_int must be set to a relatively small value such as $1$ or $2$. For these cases the mp\_set algorithm is useful. -\begin{figure}[here] +\newpage\begin{figure}[here] \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{mp\_set}. \\ @@ -1397,11 +1370,14 @@ single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adj EXAM,bn_mp_set.c -Line @21,mp_zero@ calls mp\_zero() to clear the mp\_int and reset the sign. Line @22,MP_MASK@ copies the digit -into the least significant location. Note the usage of a new constant \textbf{MP\_MASK}. This constant is used to quickly -reduce an integer modulo $\beta$. Since $\beta$ is of the form $2^k$ for any suitable $k$ it suffices to perform a binary AND with -$MP\_MASK = 2^k - 1$ to perform the reduction. Finally line @23,a->used@ will set the \textbf{used} member with respect to the -digit actually set. This function will always make the integer positive. +First we zero (line @21,mp_zero@) the mp\_int to make sure that the other members are initialized for a +small positive constant. mp\_zero() ensures that the \textbf{sign} is positive and the \textbf{used} count +is zero. Next we set the digit and reduce it modulo $\beta$ (line @22,MP_MASK@). After this step we have to +check if the resulting digit is zero or not. If it is not then we set the \textbf{used} count to one, otherwise +to zero. + +We can quickly reduce modulo $\beta$ since it is of the form $2^k$ and a quick binary AND operation with +$2^k - 1$ will perform the same operation. One important limitation of this function is that it will only set one digit. The size of a digit is not fixed, meaning source that uses this function should take that into account. Only trivially small constants can be set using this function. @@ -1503,10 +1479,12 @@ the zero'th digit. If after all of the digits have been compared, no difference EXAM,bn_mp_cmp_mag.c -The two if statements on lines @24,if@ and @28,if@ compare the number of digits in the two inputs. These two are performed before all of the digits -are compared since it is a very cheap test to perform and can potentially save considerable time. The implementation given is also not valid -without those two statements. $b.alloc$ may be smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the -array of digits. +The two if statements (lines @24,if@ and @28,if@) compare the number of digits in the two inputs. These two are +performed before all of the digits are compared since it is a very cheap test to perform and can potentially save +considerable time. The implementation given is also not valid without those two statements. $b.alloc$ may be +smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the array of digits. + + \subsection{Signed Comparisons} Comparing with sign considerations is also fairly critical in several routines (\textit{division for example}). Based on an unsigned magnitude @@ -1539,9 +1517,9 @@ $\vert a \vert < \vert b \vert$. Step number four will compare the two when the EXAM,bn_mp_cmp.c -The two if statements on lines @22,if@ and @26,if@ perform the initial sign comparison. If the signs are not the equal then which ever -has the positive sign is larger. At line @30,if@, the inputs are compared based on magnitudes. If the signs were both negative then -the unsigned comparison is performed in the opposite direction (\textit{line @31,mp_cmp_mag@}). Otherwise, the signs are assumed to +The two if statements (lines @22,if@ and @26,if@) perform the initial sign comparison. If the signs are not the equal then which ever +has the positive sign is larger. The inputs are compared (line @30,if@) based on magnitudes. If the signs were both +negative then the unsigned comparison is performed in the opposite direction (line @31,mp_cmp_mag@). Otherwise, the signs are assumed to be both positive and a forward direction unsigned comparison is performed. \section*{Exercises} @@ -1664,19 +1642,21 @@ The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are EXAM,bn_s_mp_add.c -Lines @27,if@ to @35,}@ perform the initial sorting of the inputs and determine the $min$ and $max$ variables. Note that $x$ is a pointer to a -mp\_int assigned to the largest input, in effect it is a local alias. Lines @37,init@ to @42,}@ ensure that the destination is grown to -accomodate the result of the addition. +We first sort (lines @27,if@ to @35,}@) the inputs based on magnitude and determine the $min$ and $max$ variables. +Note that $x$ is a pointer to an mp\_int assigned to the largest input, in effect it is a local alias. Next we +grow the destination (@37,init@ to @42,}@) ensure that it can accomodate the result of the addition. Similar to the implementation of mp\_copy this function uses the braced code and local aliases coding style. The three aliases that are on lines @56,tmpa@, @59,tmpb@ and @62,tmpc@ represent the two inputs and destination variables respectively. These aliases are used to ensure the compiler does not have to dereference $a$, $b$ or $c$ (respectively) to access the digits of the respective mp\_int. -The initial carry $u$ is cleared on line @65,u = 0@, note that $u$ is of type mp\_digit which ensures type compatibility within the -implementation. The initial addition loop begins on line @66,for@ and ends on line @75,}@. Similarly the conditional addition loop -begins on line @81,for@ and ends on line @90,}@. The addition is finished with the final carry being stored in $tmpc$ on line @94,tmpc++@. -Note the ``++'' operator on the same line. After line @94,tmpc++@ $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful -for the next loop on lines @97,for@ to @99,}@ which set any old upper digits to zero. +The initial carry $u$ will be cleared (line @65,u = 0@), note that $u$ is of type mp\_digit which ensures type +compatibility within the implementation. The initial addition (line @66,for@ to @75,}@) adds digits from +both inputs until the smallest input runs out of digits. Similarly the conditional addition loop +(line @81,for@ to @90,}@) adds the remaining digits from the larger of the two inputs. The addition is finished +with the final carry being stored in $tmpc$ (line @94,tmpc++@). Note the ``++'' operator within the same expression. +After line @94,tmpc++@, $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful +for the next loop (line @97,for@ to @99,}@) which set any old upper digits to zero. \subsection{Low Level Subtraction} The low level unsigned subtraction algorithm is very similar to the low level unsigned addition algorithm. The principle difference is that the @@ -1692,7 +1672,7 @@ this algorithm we will assume that the variable $\gamma$ represents the number o mp\_digit (\textit{this implies $2^{\gamma} > \beta$}). For example, the default for LibTomMath is to use a ``unsigned long'' for the mp\_digit ``type'' while $\beta = 2^{28}$. In ISO C an ``unsigned long'' -data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma = 32$. +data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma \ge 32$. \newpage\begin{figure}[!here] \begin{center} @@ -1759,20 +1739,23 @@ If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and cop EXAM,bn_s_mp_sub.c -Line @24,min@ and @25,max@ perform the initial hardcoded sorting of the inputs. In reality the $min$ and $max$ variables are only aliases and are only -used to make the source code easier to read. Again the pointer alias optimization is used within this algorithm. Lines @42,tmpa@, @43,tmpb@ and @44,tmpc@ initialize the aliases for -$a$, $b$ and $c$ respectively. +Like low level addition we ``sort'' the inputs. Except in this case the sorting is hardcoded +(lines @24,min@ and @25,max@). In reality the $min$ and $max$ variables are only aliases and are only +used to make the source code easier to read. Again the pointer alias optimization is used +within this algorithm. The aliases $tmpa$, $tmpb$ and $tmpc$ are initialized +(lines @42,tmpa@, @43,tmpb@ and @44,tmpc@) for $a$, $b$ and $c$ respectively. -The first subtraction loop occurs on lines @47,u = 0@ through @61,}@. The theory behind the subtraction loop is exactly the same as that for -the addition loop. As remarked earlier there is an implementation reason for using the ``awkward'' method of extracting the carry -(\textit{see line @57, >>@}). The traditional method for extracting the carry would be to shift by $lg(\beta)$ positions and logically AND -the least significant bit. The AND operation is required because all of the bits above the $\lg(\beta)$'th bit will be set to one after a carry -occurs from subtraction. This carry extraction requires two relatively cheap operations to extract the carry. The other method is to simply -shift the most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This optimization only works on -twos compliment machines which is a safe assumption to make. +The first subtraction loop (lines @47,u = 0@ through @61,}@) subtract digits from both inputs until the smaller of +the two inputs has been exhausted. As remarked earlier there is an implementation reason for using the ``awkward'' +method of extracting the carry (line @57, >>@). The traditional method for extracting the carry would be to shift +by $lg(\beta)$ positions and logically AND the least significant bit. The AND operation is required because all of +the bits above the $\lg(\beta)$'th bit will be set to one after a carry occurs from subtraction. This carry +extraction requires two relatively cheap operations to extract the carry. The other method is to simply shift the +most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This +optimization only works on twos compliment machines which is a safe assumption to make. -If $a$ has a larger magnitude than $b$ an additional loop (\textit{see lines @64,for@ through @73,}@}) is required to propagate the carry through -$a$ and copy the result to $c$. +If $a$ has a larger magnitude than $b$ an additional loop (lines @64,for@ through @73,}@) is required to propagate +the carry through $a$ and copy the result to $c$. \subsection{High Level Addition} Now that both lower level addition and subtraction algorithms have been established an effective high level signed addition algorithm can be @@ -2098,10 +2081,11 @@ FIGU,sliding_window,Sliding Window Movement EXAM,bn_mp_lshd.c -The if statement on line @24,if@ ensures that the $b$ variable is greater than zero. The \textbf{used} count is incremented by $b$ before -the copy loop begins. This elminates the need for an additional variable in the for loop. The variable $top$ on line @42,top@ is an alias -for the leading digit while $bottom$ on line @45,bottom@ is an alias for the trailing edge. The aliases form a window of exactly $b$ digits -over the input. +The if statement (line @24,if@) ensures that the $b$ variable is greater than zero since we do not interpret negative +shift counts properly. The \textbf{used} count is incremented by $b$ before the copy loop begins. This elminates +the need for an additional variable in the for loop. The variable $top$ (line @42,top@) is an alias +for the leading digit while $bottom$ (line @45,bottom@) is an alias for the trailing edge. The aliases form a +window of exactly $b$ digits over the input. \subsection{Division by $x$} @@ -2151,9 +2135,9 @@ Once the window copy is complete the upper digits must be zeroed and the \textbf EXAM,bn_mp_rshd.c -The only noteworthy element of this routine is the lack of a return type. - --- Will update later to give it a return type...Tom +The only noteworthy element of this routine is the lack of a return type since it cannot fail. Like mp\_lshd() we +form a sliding window except we copy in the other direction. After the window (line @59,for (;@) we then zero +the upper digits of the input to make sure the result is correct. \section{Powers of Two} @@ -2214,7 +2198,15 @@ complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm EXAM,bn_mp_mul_2d.c -Notes to be revised when code is updated. -- Tom +The shifting is performed in--place which means the first step (line @24,a != c@) is to copy the input to the +destination. We avoid calling mp\_copy() by making sure the mp\_ints are different. The destination then +has to be grown (line @31,grow@) to accomodate the result. + +If the shift count $b$ is larger than $lg(\beta)$ then a call to mp\_lshd() is used to handle all of the multiples +of $lg(\beta)$. Leaving only a remaining shift of $lg(\beta) - 1$ or fewer bits left. Inside the actual shift +loop (lines @45,if@ to @76,}@) we make use of pre--computed values $shift$ and $mask$. These are used to +extract the carry bit(s) to pass into the next iteration of the loop. The $r$ and $rr$ variables form a +chain between consecutive iterations to propagate the carry. \subsection{Division by Power of Two} @@ -2263,7 +2255,8 @@ ignored by passing \textbf{NULL} as the pointer to the mp\_int variable. The result of the remainder operation until the end. This allows $d$ and $a$ to represent the same mp\_int without modifying $a$ before the quotient is obtained. -The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. (-- Fix this paragraph up later, Tom). +The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. The only significant difference is +the direction of the shifts. \subsection{Remainder of Division by Power of Two} @@ -2306,7 +2299,13 @@ is copied to $b$, leading digits are removed and the remaining leading digit is EXAM,bn_mp_mod_2d.c --- Add comments later, Tom. +We first avoid cases of $b \le 0$ by simply mp\_zero()'ing the destination in such cases. Next if $2^b$ is larger +than the input we just mp\_copy() the input and return right away. After this point we know we must actually +perform some work to produce the remainder. + +Recalling that reducing modulo $2^k$ and a binary ``and'' with $2^k - 1$ are numerically equivalent we can quickly reduce +the number. First we zero any digits above the last digit in $2^b$ (line @41,for@). Next we reduce the +leading digit of both (line @45,&=@) and then mp\_clamp(). \section*{Exercises} \begin{tabular}{cl} @@ -2464,33 +2463,46 @@ exceed the precision requested. EXAM,bn_s_mp_mul_digs.c -Lines @31,if@ to @35,}@ determine if the Comba method can be used first. The conditions for using the Comba routine are that min$(a.used, b.used) < \delta$ and -the number of digits of output is less than \textbf{MP\_WARRAY}. This new constant is used to control -the stack usage in the Comba routines. By default it is set to $\delta$ but can be reduced when memory is at a premium. +First we determine (line @30,if@) if the Comba method can be used first since it's faster. The conditions for +sing the Comba routine are that min$(a.used, b.used) < \delta$ and the number of digits of output is less than +\textbf{MP\_WARRAY}. This new constant is used to control the stack usage in the Comba routines. By default it is +set to $\delta$ but can be reduced when memory is at a premium. + +If we cannot use the Comba method we proceed to setup the baseline routine. We allocate the the destination mp\_int +$t$ (line @36,init@) to the exact size of the output to avoid further re--allocations. At this point we now +begin the $O(n^2)$ loop. -Of particular importance is the calculation of the $ix+iy$'th column on lines @64,mp_word@, @65,mp_word@ and @66,mp_word@. Note how all of the -variables are cast to the type \textbf{mp\_word}, which is also the type of variable $\hat r$. That is to ensure that double precision operations -are used instead of single precision. The multiplication on line @65,) * (@ makes use of a specific GCC optimizer behaviour. On the outset it looks like -the compiler will have to use a double precision multiplication to produce the result required. Such an operation would be horribly slow on most -processors and drag this to a crawl. However, GCC is smart enough to realize that double wide output single precision multipliers can be used. For -example, the instruction ``MUL'' on the x86 processor can multiply two 32-bit values and produce a 64-bit result. +This implementation of multiplication has the caveat that it can be trimmed to only produce a variable number of +digits as output. In each iteration of the outer loop the $pb$ variable is set (line @48,MIN@) to the maximum +number of inner loop iterations. + +Inside the inner loop we calculate $\hat r$ as the mp\_word product of the two mp\_digits and the addition of the +carry from the previous iteration. A particularly important observation is that most modern optimizing +C compilers (GCC for instance) can recognize that a $N \times N \rightarrow 2N$ multiplication is all that +is required for the product. In x86 terms for example, this means using the MUL instruction. + +Each digit of the product is stored in turn (line @68,tmpt@) and the carry propagated (line @71,>>@) to the +next iteration. \subsection{Faster Multiplication by the ``Comba'' Method} MARK,COMBA -One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be computed and propagated upwards. This -makes the nested loop very sequential and hard to unroll and implement in parallel. The ``Comba'' \cite{COMBA} method is named after little known -(\textit{in cryptographic venues}) Paul G. Comba who described a method of implementing fast multipliers that do not require nested -carry fixup operations. As an interesting aside it seems that Paul Barrett describes a similar technique in -his 1986 paper \cite{BARRETT} written five years before. +One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be +computed and propagated upwards. This makes the nested loop very sequential and hard to unroll and implement +in parallel. The ``Comba'' \cite{COMBA} method is named after little known (\textit{in cryptographic venues}) Paul G. +Comba who described a method of implementing fast multipliers that do not require nested carry fixup operations. As an +interesting aside it seems that Paul Barrett describes a similar technique in his 1986 paper \cite{BARRETT} written +five years before. -At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight twist is placed on how -the columns of the result are produced. In the standard long-hand algorithm rows of products are produced then added together to form the -final result. In the baseline algorithm the columns are added together after each iteration to get the result instantaneously. +At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight +twist is placed on how the columns of the result are produced. In the standard long-hand algorithm rows of products +are produced then added together to form the final result. In the baseline algorithm the columns are added together +after each iteration to get the result instantaneously. -In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at the $O(n^2)$ level a -simple multiplication and addition step is performed. The carries of the columns are propagated after the nested loop to reduce the amount -of work requiored. Succintly the first step of the algorithm is to compute the product vector $\vec x$ as follows. +In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at +the $O(n^2)$ level a simple multiplication and addition step is performed. The carries of the columns are propagated +after the nested loop to reduce the amount of work requiored. Succintly the first step of the algorithm is to compute +the product vector $\vec x$ as follows. \begin{equation} \vec x_n = \sum_{i+j = n} a_ib_j, \forall n \in \lbrace 0, 1, 2, \ldots, i + j \rbrace @@ -2584,38 +2596,32 @@ $256$ digits would allow for numbers in the range of $0 \le x < 2^{7168}$ which, \textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ \textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ \hline \\ -Place an array of \textbf{MP\_WARRAY} double precision digits named $\hat W$ on the stack. \\ +Place an array of \textbf{MP\_WARRAY} single precision digits named $W$ on the stack. \\ 1. If $c.alloc < digs$ then grow $c$ to $digs$ digits. (\textit{mp\_grow}) \\ 2. If step 1 failed return(\textit{MP\_MEM}).\\ \\ -Zero the temporary array $\hat W$. \\ -3. for $n$ from $0$ to $digs - 1$ do \\ -\hspace{3mm}3.1 $\hat W_n \leftarrow 0$ \\ +3. $pa \leftarrow \mbox{MIN}(digs, a.used + b.used)$ \\ \\ -Compute the columns. \\ -4. for $ix$ from $0$ to $a.used - 1$ do \\ -\hspace{3mm}4.1 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ -\hspace{3mm}4.2 If $pb < 1$ then goto step 5. \\ -\hspace{3mm}4.3 for $iy$ from $0$ to $pb - 1$ do \\ -\hspace{6mm}4.3.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}b_{iy}$ \\ +4. $\_ \hat W \leftarrow 0$ \\ +5. for $ix$ from 0 to $pa - 1$ do \\ +\hspace{3mm}5.1 $ty \leftarrow \mbox{MIN}(b.used - 1, ix)$ \\ +\hspace{3mm}5.2 $tx \leftarrow ix - ty$ \\ +\hspace{3mm}5.3 $iy \leftarrow \mbox{MIN}(a.used - tx, ty + 1)$ \\ +\hspace{3mm}5.4 for $iz$ from 0 to $iy - 1$ do \\ +\hspace{6mm}5.4.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx+iy}b_{ty-iy}$ \\ +\hspace{3mm}5.5 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$\\ +\hspace{3mm}5.6 $\_ \hat W \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ +6. $W_{pa} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ \\ -Propagate the carries upwards. \\ -5. $oldused \leftarrow c.used$ \\ -6. $c.used \leftarrow digs$ \\ -7. If $digs > 1$ then do \\ -\hspace{3mm}7.1. for $ix$ from $1$ to $digs - 1$ do \\ -\hspace{6mm}7.1.1 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix-1} / \beta \rfloor$ \\ -\hspace{6mm}7.1.2 $c_{ix - 1} \leftarrow \hat W_{ix - 1} \mbox{ (mod }\beta\mbox{)}$ \\ -8. else do \\ -\hspace{3mm}8.1 $ix \leftarrow 0$ \\ -9. $c_{ix} \leftarrow \hat W_{ix} \mbox{ (mod }\beta\mbox{)}$ \\ +7. $oldused \leftarrow c.used$ \\ +8. $c.used \leftarrow digs$ \\ +9. for $ix$ from $0$ to $pa$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow W_{ix}$ \\ +10. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ +\hspace{3mm}10.1 $c_{ix} \leftarrow 0$ \\ \\ -Zero excess digits. \\ -10. If $digs < oldused$ then do \\ -\hspace{3mm}10.1 for $n$ from $digs$ to $oldused - 1$ do \\ -\hspace{6mm}10.1.1 $c_n \leftarrow 0$ \\ -11. Clamp excessive digits of $c$. (\textit{mp\_clamp}) \\ -12. Return(\textit{MP\_OKAY}). \\ +11. Clamp $c$. \\ +12. Return MP\_OKAY. \\ \hline \end{tabular} \end{center} @@ -2625,15 +2631,24 @@ Zero excess digits. \\ \end{figure} \textbf{Algorithm fast\_s\_mp\_mul\_digs.} -This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. The algorithm -essentially peforms the same calculation as algorithm s\_mp\_mul\_digs, just much faster. +This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. + +The outer loop of this algorithm is more complicated than that of the baseline multiplier. This is because on the inside of the +loop we want to produce one column per pass. This allows the accumulator $\_ \hat W$ to be placed in CPU registers and +reduce the memory bandwidth to two \textbf{mp\_digit} reads per iteration. + +The $ty$ variable is set to the minimum count of $ix$ or the number of digits in $b$. That way if $a$ has more digits than +$b$ this will be limited to $b.used - 1$. The $tx$ variable is set to the to the distance past $b.used$ the variable +$ix$ is. This is used for the immediately subsequent statement where we find $iy$. -The array $\hat W$ is meant to be on the stack when the algorithm is used. The size of the array does not change which is ideal. Note also that -unlike algorithm s\_mp\_mul\_digs no temporary mp\_int is required since the result is calculated directly in $\hat W$. +The variable $iy$ is the minimum digits we can read from either $a$ or $b$ before running out. Computing one column at a time +means we have to scan one integer upwards and the other downwards. $a$ starts at $tx$ and $b$ starts at $ty$. In each +pass we are producing the $ix$'th output column and we note that $tx + ty = ix$. As we move $tx$ upwards we have to +move $ty$ downards so the equality remains valid. The $iy$ variable is the number of iterations until +$tx \ge a.used$ or $ty < 0$ occurs. -The $O(n^2)$ loop on step four is where the Comba method's advantages begin to show through in comparison to the baseline algorithm. The lack of -a carry variable or propagation in this loop allows the loop to be performed with only single precision multiplication and additions. Now that each -iteration of the inner loop can be performed independent of the others the inner loop can be performed with a high level of parallelism. +After every inner pass we store the lower half of the accumulator into $W_{ix}$ and then propagate the carry of the accumulator +into the next round by dividing $\_ \hat W$ by $\beta$. To measure the benefits of the Comba method over the baseline method consider the number of operations that are required. If the cost in terms of time of a multiply and addition is $p$ and the cost of a carry propagation is $q$ then a baseline multiplication would require @@ -2643,20 +2658,20 @@ and addition operations in the nested loop in parallel. EXAM,bn_fast_s_mp_mul_digs.c -The memset on line @47,memset@ clears the initial $\hat W$ array to zero in a single step. Like the slower baseline multiplication -implementation a series of aliases (\textit{lines @67, tmpx@, @70, tmpy@ and @75,_W@}) are used to simplify the inner $O(n^2)$ loop. -In this case a new alias $\_\hat W$ has been added which refers to the double precision columns offset by $ix$ in each pass. +As per the pseudo--code we first calculate $pa$ (line @47,MIN@) as the number of digits to output. Next we begin the outer loop +to produce the individual columns of the product. We use the two aliases $tmpx$ and $tmpy$ (lines @61,tmpx@, @62,tmpy@) to point +inside the two multiplicands quickly. -The inner loop on lines @83,for@, @84,mp_word@ and @85,}@ is where the algorithm will spend the majority of the time, which is why it has been -stripped to the bones of any extra baggage\footnote{Hence the pointer aliases.}. On x86 processors the multiplication and additions amount to at the -very least five instructions (\textit{two loads, two additions, one multiply}) while on the ARMv4 processors they amount to only three -(\textit{one load, one store, one multiply-add}). For both of the x86 and ARMv4 processors the GCC compiler performs a good job at unrolling the loop -and scheduling the instructions so there are very few dependency stalls. +The inner loop (lines @70,for@ to @72,}@) of this implementation is where the tradeoff come into play. Originally this comba +implementation was ``row--major'' which means it adds to each of the columns in each pass. After the outer loop it would then fix +the carries. This was very fast except it had an annoying drawback. You had to read a mp\_word and two mp\_digits and write +one mp\_word per iteration. On processors such as the Athlon XP and P4 this did not matter much since the cache bandwidth +is very high and it can keep the ALU fed with data. It did, however, matter on older and embedded cpus where cache is often +slower and also often doesn't exist. This new algorithm only performs two reads per iteration under the assumption that the +compiler has aliased $\_ \hat W$ to a CPU register. -In theory the difference between the baseline and comba algorithms is a mere $O(qn)$ time difference. However, in the $O(n^2)$ nested loop of the -baseline method there are dependency stalls as the algorithm must wait for the multiplier to finish before propagating the carry to the next -digit. As a result fewer of the often multiple execution units\footnote{The AMD Athlon has three execution units and the Intel P4 has four.} can -be simultaneously used. +After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines @75,W[ix]@, @78,>>@) to forward it as +a carry for the next pass. After the outer loop we use the final carry (line @82,W[ix]@) as the last digit of the product. \subsection{Polynomial Basis Multiplication} To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms @@ -2976,13 +2991,26 @@ result $a \cdot b$ is produced. EXAM,bn_mp_toom_mul.c --- Comments to be added during editing phase. +The first obvious thing to note is that this algorithm is complicated. The complexity is worth it if you are multiplying very +large numbers. For example, a 10,000 digit multiplication takes approximaly 99,282,205 fewer single precision multiplications with +Toom--Cook than a Comba or baseline approach (this is a savings of more than 99$\%$). For most ``crypto'' sized numbers this +algorithm is not practical as Karatsuba has a much lower cutoff point. + +First we split $a$ and $b$ into three roughly equal portions. This has been accomplished (lines @40,mod@ to @69,rshd@) with +combinations of mp\_rshd() and mp\_mod\_2d() function calls. At this point $a = a2 \cdot \beta^2 + a1 \cdot \beta + a0$ and similiarly +for $b$. + +Next we compute the five points $w0, w1, w2, w3$ and $w4$. Recall that $w0$ and $w4$ can be computed directly from the portions so +we get those out of the way first (lines @72,mul@ and @77,mul@). Next we compute $w1, w2$ and $w3$ using Horners method. + +After this point we solve for the actual values of $w1, w2$ and $w3$ by reducing the $5 \times 5$ system which is relatively +straight forward. \subsection{Signed Multiplication} Now that algorithms to handle multiplications of every useful dimensions have been developed, a rather simple finishing touch is required. So far all of the multiplication algorithms have been unsigned multiplications which leaves only a signed multiplication algorithm to be established. -\newpage\begin{figure}[!here] +\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -3065,7 +3093,7 @@ Column two of row one is a square and column three is the first unique column. The baseline squaring algorithm is meant to be a catch-all squaring algorithm. It will handle any of the input sizes that the faster routines will not handle. -\newpage\begin{figure}[!here] +\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -3121,9 +3149,14 @@ results calculated so far. This involves expensive carry propagation which will EXAM,bn_s_mp_sqr.c -Inside the outer loop (\textit{see line @32,for@}) the square term is calculated on line @35,r =@. Line @42,>>@ extracts the carry from the square -term. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized on lines @45,tmpx@ and @48,tmpt@ respectively. The doubling is performed using two -additions (\textit{see line @57,r + r@}) since it is usually faster than shifting,if not at least as fast. +Inside the outer loop (line @32,for@) the square term is calculated on line @35,r =@. The carry (line @42,>>@) has been +extracted from the mp\_word accumulator using a right shift. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized +(lines @45,tmpx@ and @48,tmpt@) to simplify the inner loop. The doubling is performed using two +additions (line @57,r + r@) since it is usually faster than shifting, if not at least as fast. + +The important observation is that the inner loop does not begin at $iy = 0$ like for multiplication. As such the inner loops +get progressively shorter as the algorithm proceeds. This is what leads to the savings compared to using a multiplication to +square a number. \subsection{Faster Squaring by the ``Comba'' Method} A major drawback to the baseline method is the requirement for single precision shifting inside the $O(n^2)$ nested loop. Squaring has an additional @@ -3135,9 +3168,9 @@ propagation operations from the inner loop. However, the inner product must sti that $2a + 2b + 2c = 2(a + b + c)$. That is the sum of all of the double products is equal to double the sum of all the products. For example, $ab + ba + ac + ca = 2ab + 2ac = 2(ab + ac)$. -However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two mp\_word -arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and carry propagation can be -moved to a $O(n)$ work level outside the $O(n^2)$ level. +However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two +mp\_word arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and +carry propagation can be moved to a $O(n)$ work level outside the $O(n^2)$ level. In this case, we have an even simpler solution in mind. \newpage\begin{figure}[!here] \begin{small} @@ -3147,34 +3180,34 @@ moved to a $O(n)$ work level outside the $O(n^2)$ level. \textbf{Input}. mp\_int $a$ \\ \textbf{Output}. $b \leftarrow a^2$ \\ \hline \\ -Place two arrays of \textbf{MP\_WARRAY} mp\_words named $\hat W$ and $\hat {X}$ on the stack. \\ +Place an array of \textbf{MP\_WARRAY} mp\_digits named $W$ on the stack. \\ 1. If $b.alloc < 2a.used + 1$ then grow $b$ to $2a.used + 1$ digits. (\textit{mp\_grow}). \\ 2. If step 1 failed return(\textit{MP\_MEM}). \\ -3. for $ix$ from $0$ to $2a.used + 1$ do \\ -\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ -\hspace{3mm}3.2 $\hat {X}_{ix} \leftarrow 0$ \\ -4. for $ix$ from $0$ to $a.used - 1$ do \\ -\hspace{3mm}Compute the square.\\ -\hspace{3mm}4.1 $\hat {X}_{ix+ix} \leftarrow \left ( a_{ix} \right )^2$ \\ \\ -\hspace{3mm}Compute the double products.\\ -\hspace{3mm}4.2 for $iy$ from $ix + 1$ to $a.used - 1$ do \\ -\hspace{6mm}4.2.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}a_{iy}$ \\ -5. $oldused \leftarrow b.used$ \\ -6. $b.used \leftarrow 2a.used + 1$ \\ +3. $pa \leftarrow 2 \cdot a.used$ \\ +4. $\hat W1 \leftarrow 0$ \\ +5. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}5.1 $\_ \hat W \leftarrow 0$ \\ +\hspace{3mm}5.2 $ty \leftarrow \mbox{MIN}(a.used - 1, ix)$ \\ +\hspace{3mm}5.3 $tx \leftarrow ix - ty$ \\ +\hspace{3mm}5.4 $iy \leftarrow \mbox{MIN}(a.used - tx, ty + 1)$ \\ +\hspace{3mm}5.5 $iy \leftarrow \mbox{MIN}(iy, \lfloor \left (ty - tx + 1 \right )/2 \rfloor)$ \\ +\hspace{3mm}5.6 for $iz$ from $0$ to $iz - 1$ do \\ +\hspace{6mm}5.6.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx + iz}a_{ty - iz}$ \\ +\hspace{3mm}5.7 $\_ \hat W \leftarrow 2 \cdot \_ \hat W + \hat W1$ \\ +\hspace{3mm}5.8 if $ix$ is even then \\ +\hspace{6mm}5.8.1 $\_ \hat W \leftarrow \_ \hat W + \left ( a_{\lfloor ix/2 \rfloor}\right )^2$ \\ +\hspace{3mm}5.9 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ +\hspace{3mm}5.10 $\hat W1 \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ \\ -Double the products and propagate the carries simultaneously. \\ -7. $\hat W_0 \leftarrow 2 \hat W_0 + \hat {X}_0$ \\ -8. for $ix$ from $1$ to $2a.used$ do \\ -\hspace{3mm}8.1 $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ \\ -\hspace{3mm}8.2 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix - 1} / \beta \rfloor$ \\ -\hspace{3mm}8.3 $b_{ix-1} \leftarrow W_{ix-1} \mbox{ (mod }\beta\mbox{)}$ \\ -9. $b_{2a.used} \leftarrow \hat W_{2a.used} \mbox{ (mod }\beta\mbox{)}$ \\ -10. if $2a.used + 1 < oldused$ then do \\ -\hspace{3mm}10.1 for $ix$ from $2a.used + 1$ to $oldused$ do \\ -\hspace{6mm}10.1.1 $b_{ix} \leftarrow 0$ \\ -11. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ -12. Return(\textit{MP\_OKAY}). \\ +6. $oldused \leftarrow b.used$ \\ +7. $b.used \leftarrow 2 \cdot a.used$ \\ +8. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}8.1 $b_{ix} \leftarrow W_{ix}$ \\ +9. for $ix$ from $pa$ to $oldused - 1$ do \\ +\hspace{3mm}9.1 $b_{ix} \leftarrow 0$ \\ +10. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ +11. Return(\textit{MP\_OKAY}). \\ \hline \end{tabular} \end{center} @@ -3183,24 +3216,24 @@ Double the products and propagate the carries simultaneously. \\ \end{figure} \textbf{Algorithm fast\_s\_mp\_sqr.} -This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm s\_mp\_sqr when -the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. +This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm +s\_mp\_sqr when the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. +This algorithm is very similar to the Comba multiplier except with a few key differences we shall make note of. -This routine requires two arrays of mp\_words to be placed on the stack. The first array $\hat W$ will hold the double products and the second -array $\hat X$ will hold the squares. Though only at most $MP\_WARRAY \over 2$ words of $\hat X$ are used, it has proven faster on most -processors to simply make it a full size array. +First, we have an accumulator and carry variables $\_ \hat W$ and $\hat W1$ respectively. This is because the inner loop +products are to be doubled. If we had added the previous carry in we would be doubling too much. Next we perform an +addition MIN condition on $iy$ (step 5.5) to prevent overlapping digits. For example, $a_3 \cdot a_5$ is equal +$a_5 \cdot a_3$. Whereas in the multiplication case we would have $5 < a.used$ and $3 \ge 0$ is maintained since we double the sum +of the products just outside the inner loop we have to avoid doing this. This is also a good thing since we perform +fewer multiplications and the routine ends up being faster. -The loop on step 3 will zero the two arrays to prepare them for the squaring step. Step 4.1 computes the squares of the product. Note how -it simply assigns the value into the $\hat X$ array. The nested loop on step 4.2 computes the doubles of the products. This loop -computes the sum of the products for each column. They are not doubled until later. - -After the squaring loop, the products stored in $\hat W$ musted be doubled and the carries propagated forwards. It makes sense to do both -operations at the same time. The expression $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ computes the sum of the double product and the -squares in place. +Finally the last difference is the addition of the ``square'' term outside the inner loop (step 5.8). We add in the square +only to even outputs and it is the square of the term at the $\lfloor ix / 2 \rfloor$ position. EXAM,bn_fast_s_mp_sqr.c --- Write something deep and insightful later, Tom. +This implementation is essentially a copy of Comba multiplication with the appropriate changes added to make it faster for +the special case of squaring. \subsection{Polynomial Basis Squaring} The same algorithm that performs optimal polynomial basis multiplication can be used to perform polynomial basis squaring. The minor exception @@ -3312,14 +3345,13 @@ By inlining the copy and shift operations the cutoff point for Karatsuba multipl is exactly at the point where Comba squaring can no longer be used (\textit{128 digits}). On slower processors such as the Intel P4 it is actually below the Comba limit (\textit{at 110 digits}). -This routine uses the same error trap coding style as mp\_karatsuba\_sqr. As the temporary variables are initialized errors are redirected to -the error trap higher up. If the algorithm completes without error the error code is set to \textbf{MP\_OKAY} and mp\_clears are executed normally. - -\textit{Last paragraph sucks. re-write! -- Tom} +This routine uses the same error trap coding style as mp\_karatsuba\_sqr. As the temporary variables are initialized errors are +redirected to the error trap higher up. If the algorithm completes without error the error code is set to \textbf{MP\_OKAY} and +mp\_clears are executed normally. \subsection{Toom-Cook Squaring} The Toom-Cook squaring algorithm mp\_toom\_sqr is heavily based on the algorithm mp\_toom\_mul with the exception that squarings are used -instead of multiplication to find the five relations.. The reader is encouraged to read the description of the latter algorithm and try to +instead of multiplication to find the five relations. The reader is encouraged to read the description of the latter algorithm and try to derive their own Toom-Cook squaring algorithm. \subsection{High Level Squaring} @@ -3362,12 +3394,9 @@ EXAM,bn_mp_sqr.c $\left [ 3 \right ] $ & Devise an efficient algorithm for selection of the radix point to handle inputs \\ & that have different number of digits in Karatsuba multiplication. \\ & \\ -$\left [ 3 \right ] $ & In ~SQUARE~ the fact that every column of a squaring is made up \\ +$\left [ 2 \right ] $ & In ~SQUARE~ the fact that every column of a squaring is made up \\ & of double products and at most one square is stated. Prove this statement. \\ & \\ -$\left [ 2 \right ] $ & In the Comba squaring algorithm half of the $\hat X$ variables are not used. \\ - & Revise algorithm fast\_s\_mp\_sqr to shrink the $\hat X$ array. \\ - & \\ $\left [ 3 \right ] $ & Prove the equation for Karatsuba squaring. \\ & \\ $\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3)} \right )$ time. \\ @@ -3375,6 +3404,14 @@ $\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3 $\left [ 2 \right ] $ & Determine the minimal ratio between addition and multiplication clock cycles \\ & required for equation $6.7$ to be true. \\ & \\ +$\left [ 3 \right ] $ & Implement a threaded version of Comba multiplication (and squaring) where you \\ + & compute subsets of the columns in each thread. Determine a cutoff point where \\ + & it is effective and add the logic to mp\_mul() and mp\_sqr(). \\ + &\\ +$\left [ 4 \right ] $ & Same as the previous but also modify the Karatsuba and Toom-Cook. You must \\ + & increase the throughput of mp\_exptmod() for random odd moduli in the range \\ + & $512 \ldots 4096$ bits significantly ($> 2x$) to complete this challenge. \\ + & \\ \end{tabular} \chapter{Modular Reduction} @@ -3394,7 +3431,7 @@ other forms of residues. Modular reductions are normally used to create either finite groups, rings or fields. The most common usage for performance driven modular reductions is in modular exponentiation algorithms. That is to compute $d = a^b \mbox{ (mod }c\mbox{)}$ as fast as possible. This operation is used in the RSA and Diffie-Hellman public key algorithms, for example. Modular multiplication and squaring also appears as a fundamental operation in -Elliptic Curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular +elliptic curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular exponentiations without having to perform (\textit{in this example}) $b - 1$ multiplications. These algorithms will produce partial results in the range $0 \le x < c^2$ which can be taken advantage of to create several efficient algorithms. They have also been used to create redundancy check algorithms known as CRCs, error correction codes such as Reed-Solomon and solve a variety of number theoeretic problems. @@ -3610,7 +3647,7 @@ safe to do so. In order to use algorithm mp\_reduce the value of $\mu$ must be calculated in advance. Ideally this value should be computed once and stored for future use so that the Barrett algorithm can be used without delay. -\begin{figure}[!here] +\newpage\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -5818,6 +5855,8 @@ To explain the Jacobi Symbol we shall first discuss the Legendre function\footno defined. The Legendre function computes whether or not an integer $a$ is a quadratic residue modulo an odd prime $p$. Numerically it is equivalent to equation \ref{eqn:legendre}. +\textit{-- Tom, don't be an ass, cite your source here...!} + \begin{equation} a^{(p-1)/2} \equiv \begin{array}{rl} -1 & \mbox{if }a\mbox{ is a quadratic non-residue.} \\ diff --git a/libtommath/tommath.tex b/libtommath/tommath.tex index 9c4dc82..b016010 100644 --- a/libtommath/tommath.tex +++ b/libtommath/tommath.tex @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{Implementing Multiple Precision Arithmetic \\ ~ \\ Draft Edition } +\title{Multi--Precision Math} \author{\mbox{ %\begin{small} \begin{tabular}{c} @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.30 release of the +This text has been placed in the public domain. This text corresponds to the v0.35 release of the LibTomMath project. \begin{alltt} @@ -85,66 +85,32 @@ This text is formatted to the international B5 paper size of 176mm wide by 250mm \tableofcontents \listoffigures -\chapter*{Prefaces to the Draft Edition} -I started this text in April 2003 to complement my LibTomMath library. That is, explain how to implement the functions -contained in LibTomMath. The goal is to have a textbook that any Computer Science student can use when implementing their -own multiple precision arithmetic. The plan I wanted to follow was flesh out all the -ideas and concepts I had floating around in my head and then work on it afterwards refining a little bit at a time. Chance -would have it that I ended up with my summer off from Algonquin College and I was given four months solid to work on the -text. - -Choosing to not waste any time I dove right into the project even before my spring semester was finished. I wrote a bit -off and on at first. The moment my exams were finished I jumped into long 12 to 16 hour days. The result after only -a couple of months was a ten chapter, three hundred page draft that I quickly had distributed to anyone who wanted -to read it. I had Jean-Luc Cooke print copies for me and I brought them to Crypto'03 in Santa Barbara. So far I have -managed to grab a certain level of attention having people from around the world ask me for copies of the text was certain -rewarding. - -Now we are past December 2003. By this time I had pictured that I would have at least finished my second draft of the text. -Currently I am far off from this goal. I've done partial re-writes of chapters one, two and three but they are not even -finished yet. I haven't given up on the project, only had some setbacks. First O'Reilly declined to publish the text then -Addison-Wesley and Greg is tried another which I don't know the name of. However, at this point I want to focus my energy -onto finishing the book not securing a contract. - -So why am I writing this text? It seems like a lot of work right? Most certainly it is a lot of work writing a textbook. -Even the simplest introductory material has to be lined with references and figures. A lot of the text has to be re-written -from point form to prose form to ensure an easier read. Why am I doing all this work for free then? Simple. My philosophy -is quite simply ``Open Source. Open Academia. Open Minds'' which means that to achieve a goal of open minds, that is, -people willing to accept new ideas and explore the unknown you have to make available material they can access freely -without hinderance. - -I've been writing free software since I was about sixteen but only recently have I hit upon software that people have come -to depend upon. I started LibTomCrypt in December 2001 and now several major companies use it as integral portions of their -software. Several educational institutions use it as a matter of course and many freelance developers use it as -part of their projects. To further my contributions I started the LibTomMath project in December 2002 aimed at providing -multiple precision arithmetic routines that students could learn from. That is write routines that are not only easy -to understand and follow but provide quite impressive performance considering they are all in standard portable ISO C. - -The second leg of my philosophy is ``Open Academia'' which is where this textbook comes in. In the end, when all is -said and done the text will be useable by educational institutions as a reference on multiple precision arithmetic. - -At this time I feel I should share a little information about myself. The most common question I was asked at -Crypto'03, perhaps just out of professional courtesy, was which school I either taught at or attended. The unfortunate -truth is that I neither teach at or attend a school of academic reputation. I'm currently at Algonquin College which -is what I'd like to call ``somewhat academic but mostly vocational'' college. In otherwords, job training. - -I'm a 21 year old computer science student mostly self-taught in the areas I am aware of (which includes a half-dozen -computer science fields, a few fields of mathematics and some English). I look forward to teaching someday but I am -still far off from that goal. - -Now it would be improper for me to not introduce the rest of the texts co-authors. While they are only contributing -corrections and editorial feedback their support has been tremendously helpful in presenting the concepts laid out -in the text so far. Greg has always been there for me. He has tracked my LibTom projects since their inception and even -sent cheques to help pay tuition from time to time. His background has provided a wonderful source to bounce ideas off -of and improve the quality of my writing. Mads is another fellow who has just ``been there''. I don't even recall what -his interest in the LibTom projects is but I'm definitely glad he has been around. His ability to catch logical errors -in my written English have saved me on several occasions to say the least. - -What to expect next? Well this is still a rough draft. I've only had the chance to update a few chapters. However, I've -been getting the feeling that people are starting to use my text and I owe them some updated material. My current tenative -plan is to edit one chapter every two weeks starting January 4th. It seems insane but my lower course load at college -should provide ample time. By Crypto'04 I plan to have a 2nd draft of the text polished and ready to hand out to as many -people who will take it. +\chapter*{Prefaces} +When I tell people about my LibTom projects and that I release them as public domain they are often puzzled. +They ask why I did it and especially why I continue to work on them for free. The best I can explain it is ``Because I can.'' +Which seems odd and perhaps too terse for adult conversation. I often qualify it with ``I am able, I am willing.'' which +perhaps explains it better. I am the first to admit there is not anything that special with what I have done. Perhaps +others can see that too and then we would have a society to be proud of. My LibTom projects are what I am doing to give +back to society in the form of tools and knowledge that can help others in their endeavours. + +I started writing this book because it was the most logical task to further my goal of open academia. The LibTomMath source +code itself was written to be easy to follow and learn from. There are times, however, where pure C source code does not +explain the algorithms properly. Hence this book. The book literally starts with the foundation of the library and works +itself outwards to the more complicated algorithms. The use of both pseudo--code and verbatim source code provides a duality +of ``theory'' and ``practice'' that the computer science students of the world shall appreciate. I never deviate too far +from relatively straightforward algebra and I hope that this book can be a valuable learning asset. + +This book and indeed much of the LibTom projects would not exist in their current form if it was not for a plethora +of kind people donating their time, resources and kind words to help support my work. Writing a text of significant +length (along with the source code) is a tiresome and lengthy process. Currently the LibTom project is four years old, +comprises of literally thousands of users and over 100,000 lines of source code, TeX and other material. People like Mads and Greg +were there at the beginning to encourage me to work well. It is amazing how timely validation from others can boost morale to +continue the project. Definitely my parents were there for me by providing room and board during the many months of work in 2003. + +To my many friends whom I have met through the years I thank you for the good times and the words of encouragement. I hope I +honour your kind gestures with this project. + +Open Source. Open Academia. Open Minds. \begin{flushright} Tom St Denis \end{flushright} @@ -1045,7 +1011,7 @@ assumed to contain undefined values they are initially set to zero. \end{alltt} \end{small} -A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line 23) checks +A quick optimization is to first determine if a memory re-allocation is required at all. The if statement (line 24) checks if the \textbf{alloc} member of the mp\_int is smaller than the requested digit count. If the count is not larger than \textbf{alloc} the function skips the re-allocation part thus saving time. @@ -1590,14 +1556,20 @@ This algorithm simply resets a mp\_int to the default state. \begin{alltt} 016 017 /* set to zero */ -018 void -019 mp_zero (mp_int * a) -020 \{ -021 a->sign = MP_ZPOS; -022 a->used = 0; -023 memset (a->dp, 0, sizeof (mp_digit) * a->alloc); -024 \} -025 #endif +018 void mp_zero (mp_int * a) +019 \{ +020 int n; +021 mp_digit *tmp; +022 +023 a->sign = MP_ZPOS; +024 a->used = 0; +025 +026 tmp = a->dp; +027 for (n = 0; n < a->alloc; n++) \{ +028 *tmp++ = 0; +029 \} +030 \} +031 #endif \end{alltt} \end{small} @@ -1609,7 +1581,7 @@ After the function is completed, all of the digits are zeroed, the \textbf{used} With the mp\_int representation of an integer, calculating the absolute value is trivial. The mp\_abs algorithm will compute the absolute value of an mp\_int. -\newpage\begin{figure}[here] +\begin{figure}[here] \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{mp\_abs}. \\ @@ -1662,6 +1634,9 @@ logic to handle it. \end{alltt} \end{small} +This fairly trivial algorithm first eliminates non--required duplications (line 27) and then sets the +\textbf{sign} flag to \textbf{MP\_ZPOS}. + \subsection{Integer Negation} With the mp\_int representation of an integer, calculating the negation is also trivial. The mp\_neg algorithm will compute the negative of an mp\_int input. @@ -1702,23 +1677,33 @@ zero as negative. 018 int mp_neg (mp_int * a, mp_int * b) 019 \{ 020 int res; -021 if ((res = mp_copy (a, b)) != MP_OKAY) \{ -022 return res; -023 \} -024 if (mp_iszero(b) != MP_YES) \{ -025 b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; -026 \} -027 return MP_OKAY; -028 \} -029 #endif +021 if (a != b) \{ +022 if ((res = mp_copy (a, b)) != MP_OKAY) \{ +023 return res; +024 \} +025 \} +026 +027 if (mp_iszero(b) != MP_YES) \{ +028 b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; +029 \} else \{ +030 b->sign = MP_ZPOS; +031 \} +032 +033 return MP_OKAY; +034 \} +035 #endif \end{alltt} \end{small} +Like mp\_abs() this function avoids non--required duplications (line 21) and then sets the sign. We +have to make sure that only non--zero values get a \textbf{sign} of \textbf{MP\_NEG}. If the mp\_int is zero +than the \textbf{sign} is hard--coded to \textbf{MP\_ZPOS}. + \section{Small Constants} \subsection{Setting Small Constants} Often a mp\_int must be set to a relatively small value such as $1$ or $2$. For these cases the mp\_set algorithm is useful. -\begin{figure}[here] +\newpage\begin{figure}[here] \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{mp\_set}. \\ @@ -1757,11 +1742,14 @@ single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adj \end{alltt} \end{small} -Line 20 calls mp\_zero() to clear the mp\_int and reset the sign. Line 21 copies the digit -into the least significant location. Note the usage of a new constant \textbf{MP\_MASK}. This constant is used to quickly -reduce an integer modulo $\beta$. Since $\beta$ is of the form $2^k$ for any suitable $k$ it suffices to perform a binary AND with -$MP\_MASK = 2^k - 1$ to perform the reduction. Finally line 22 will set the \textbf{used} member with respect to the -digit actually set. This function will always make the integer positive. +First we zero (line 20) the mp\_int to make sure that the other members are initialized for a +small positive constant. mp\_zero() ensures that the \textbf{sign} is positive and the \textbf{used} count +is zero. Next we set the digit and reduce it modulo $\beta$ (line 21). After this step we have to +check if the resulting digit is zero or not. If it is not then we set the \textbf{used} count to one, otherwise +to zero. + +We can quickly reduce modulo $\beta$ since it is of the form $2^k$ and a quick binary AND operation with +$2^k - 1$ will perform the same operation. One important limitation of this function is that it will only set one digit. The size of a digit is not fixed, meaning source that uses this function should take that into account. Only trivially small constants can be set using this function. @@ -1936,10 +1924,12 @@ the zero'th digit. If after all of the digits have been compared, no difference \end{alltt} \end{small} -The two if statements on lines 24 and 28 compare the number of digits in the two inputs. These two are performed before all of the digits -are compared since it is a very cheap test to perform and can potentially save considerable time. The implementation given is also not valid -without those two statements. $b.alloc$ may be smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the -array of digits. +The two if statements (lines 24 and 28) compare the number of digits in the two inputs. These two are +performed before all of the digits are compared since it is a very cheap test to perform and can potentially save +considerable time. The implementation given is also not valid without those two statements. $b.alloc$ may be +smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the array of digits. + + \subsection{Signed Comparisons} Comparing with sign considerations is also fairly critical in several routines (\textit{division for example}). Based on an unsigned magnitude @@ -2000,9 +1990,9 @@ $\vert a \vert < \vert b \vert$. Step number four will compare the two when the \end{alltt} \end{small} -The two if statements on lines 22 and 23 perform the initial sign comparison. If the signs are not the equal then which ever -has the positive sign is larger. At line 31, the inputs are compared based on magnitudes. If the signs were both negative then -the unsigned comparison is performed in the opposite direction (\textit{line 33}). Otherwise, the signs are assumed to +The two if statements (lines 22 and 23) perform the initial sign comparison. If the signs are not the equal then which ever +has the positive sign is larger. The inputs are compared (line 31) based on magnitudes. If the signs were both +negative then the unsigned comparison is performed in the opposite direction (line 33). Otherwise, the signs are assumed to be both positive and a forward direction unsigned comparison is performed. \section*{Exercises} @@ -2218,19 +2208,21 @@ The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are \end{alltt} \end{small} -Lines 27 to 35 perform the initial sorting of the inputs and determine the $min$ and $max$ variables. Note that $x$ is a pointer to a -mp\_int assigned to the largest input, in effect it is a local alias. Lines 37 to 42 ensure that the destination is grown to -accomodate the result of the addition. +We first sort (lines 27 to 35) the inputs based on magnitude and determine the $min$ and $max$ variables. +Note that $x$ is a pointer to an mp\_int assigned to the largest input, in effect it is a local alias. Next we +grow the destination (37 to 42) ensure that it can accomodate the result of the addition. Similar to the implementation of mp\_copy this function uses the braced code and local aliases coding style. The three aliases that are on lines 55, 58 and 61 represent the two inputs and destination variables respectively. These aliases are used to ensure the compiler does not have to dereference $a$, $b$ or $c$ (respectively) to access the digits of the respective mp\_int. -The initial carry $u$ is cleared on line 64, note that $u$ is of type mp\_digit which ensures type compatibility within the -implementation. The initial addition loop begins on line 65 and ends on line 74. Similarly the conditional addition loop -begins on line 80 and ends on line 90. The addition is finished with the final carry being stored in $tmpc$ on line 93. -Note the ``++'' operator on the same line. After line 93 $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful -for the next loop on lines 96 to 99 which set any old upper digits to zero. +The initial carry $u$ will be cleared (line 64), note that $u$ is of type mp\_digit which ensures type +compatibility within the implementation. The initial addition (line 65 to 74) adds digits from +both inputs until the smallest input runs out of digits. Similarly the conditional addition loop +(line 80 to 90) adds the remaining digits from the larger of the two inputs. The addition is finished +with the final carry being stored in $tmpc$ (line 93). Note the ``++'' operator within the same expression. +After line 93, $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful +for the next loop (line 96 to 99) which set any old upper digits to zero. \subsection{Low Level Subtraction} The low level unsigned subtraction algorithm is very similar to the low level unsigned addition algorithm. The principle difference is that the @@ -2245,7 +2237,7 @@ this algorithm we will assume that the variable $\gamma$ represents the number o mp\_digit (\textit{this implies $2^{\gamma} > \beta$}). For example, the default for LibTomMath is to use a ``unsigned long'' for the mp\_digit ``type'' while $\beta = 2^{28}$. In ISO C an ``unsigned long'' -data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma = 32$. +data type must be able to represent $0 \le x < 2^{32}$ meaning that in this case $\gamma \ge 32$. \newpage\begin{figure}[!here] \begin{center} @@ -2387,20 +2379,23 @@ If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and cop \end{alltt} \end{small} -Line 24 and 25 perform the initial hardcoded sorting of the inputs. In reality the $min$ and $max$ variables are only aliases and are only -used to make the source code easier to read. Again the pointer alias optimization is used within this algorithm. Lines 41, 42 and 43 initialize the aliases for -$a$, $b$ and $c$ respectively. +Like low level addition we ``sort'' the inputs. Except in this case the sorting is hardcoded +(lines 24 and 25). In reality the $min$ and $max$ variables are only aliases and are only +used to make the source code easier to read. Again the pointer alias optimization is used +within this algorithm. The aliases $tmpa$, $tmpb$ and $tmpc$ are initialized +(lines 41, 42 and 43) for $a$, $b$ and $c$ respectively. -The first subtraction loop occurs on lines 46 through 60. The theory behind the subtraction loop is exactly the same as that for -the addition loop. As remarked earlier there is an implementation reason for using the ``awkward'' method of extracting the carry -(\textit{see line 56}). The traditional method for extracting the carry would be to shift by $lg(\beta)$ positions and logically AND -the least significant bit. The AND operation is required because all of the bits above the $\lg(\beta)$'th bit will be set to one after a carry -occurs from subtraction. This carry extraction requires two relatively cheap operations to extract the carry. The other method is to simply -shift the most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This optimization only works on -twos compliment machines which is a safe assumption to make. +The first subtraction loop (lines 46 through 60) subtract digits from both inputs until the smaller of +the two inputs has been exhausted. As remarked earlier there is an implementation reason for using the ``awkward'' +method of extracting the carry (line 56). The traditional method for extracting the carry would be to shift +by $lg(\beta)$ positions and logically AND the least significant bit. The AND operation is required because all of +the bits above the $\lg(\beta)$'th bit will be set to one after a carry occurs from subtraction. This carry +extraction requires two relatively cheap operations to extract the carry. The other method is to simply shift the +most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This +optimization only works on twos compliment machines which is a safe assumption to make. -If $a$ has a larger magnitude than $b$ an additional loop (\textit{see lines 63 through 72}) is required to propagate the carry through -$a$ and copy the result to $c$. +If $a$ has a larger magnitude than $b$ an additional loop (lines 63 through 72) is required to propagate +the carry through $a$ and copy the result to $c$. \subsection{High Level Addition} Now that both lower level addition and subtraction algorithms have been established an effective high level signed addition algorithm can be @@ -2985,10 +2980,11 @@ step 8 sets the lower $b$ digits to zero. \end{alltt} \end{small} -The if statement on line 23 ensures that the $b$ variable is greater than zero. The \textbf{used} count is incremented by $b$ before -the copy loop begins. This elminates the need for an additional variable in the for loop. The variable $top$ on line 41 is an alias -for the leading digit while $bottom$ on line 44 is an alias for the trailing edge. The aliases form a window of exactly $b$ digits -over the input. +The if statement (line 23) ensures that the $b$ variable is greater than zero since we do not interpret negative +shift counts properly. The \textbf{used} count is incremented by $b$ before the copy loop begins. This elminates +the need for an additional variable in the for loop. The variable $top$ (line 41) is an alias +for the leading digit while $bottom$ (line 44) is an alias for the trailing edge. The aliases form a +window of exactly $b$ digits over the input. \subsection{Division by $x$} @@ -3095,9 +3091,9 @@ Once the window copy is complete the upper digits must be zeroed and the \textbf \end{alltt} \end{small} -The only noteworthy element of this routine is the lack of a return type. - --- Will update later to give it a return type...Tom +The only noteworthy element of this routine is the lack of a return type since it cannot fail. Like mp\_lshd() we +form a sliding window except we copy in the other direction. After the window (line 59) we then zero +the upper digits of the input to make sure the result is correct. \section{Powers of Two} @@ -3228,7 +3224,15 @@ complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm \end{alltt} \end{small} -Notes to be revised when code is updated. -- Tom +The shifting is performed in--place which means the first step (line 24) is to copy the input to the +destination. We avoid calling mp\_copy() by making sure the mp\_ints are different. The destination then +has to be grown (line 31) to accomodate the result. + +If the shift count $b$ is larger than $lg(\beta)$ then a call to mp\_lshd() is used to handle all of the multiples +of $lg(\beta)$. Leaving only a remaining shift of $lg(\beta) - 1$ or fewer bits left. Inside the actual shift +loop (lines 45 to 76) we make use of pre--computed values $shift$ and $mask$. These are used to +extract the carry bit(s) to pass into the next iteration of the loop. The $r$ and $rr$ variables form a +chain between consecutive iterations to propagate the carry. \subsection{Division by Power of Two} @@ -3361,7 +3365,8 @@ ignored by passing \textbf{NULL} as the pointer to the mp\_int variable. The result of the remainder operation until the end. This allows $d$ and $a$ to represent the same mp\_int without modifying $a$ before the quotient is obtained. -The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. (-- Fix this paragraph up later, Tom). +The remainder of the source code is essentially the same as the source code for mp\_mul\_2d. The only significant difference is +the direction of the shifts. \subsection{Remainder of Division by Power of Two} @@ -3446,7 +3451,13 @@ is copied to $b$, leading digits are removed and the remaining leading digit is \end{alltt} \end{small} --- Add comments later, Tom. +We first avoid cases of $b \le 0$ by simply mp\_zero()'ing the destination in such cases. Next if $2^b$ is larger +than the input we just mp\_copy() the input and return right away. After this point we know we must actually +perform some work to produce the remainder. + +Recalling that reducing modulo $2^k$ and a binary ``and'' with $2^k - 1$ are numerically equivalent we can quickly reduce +the number. First we zero any digits above the last digit in $2^b$ (line 41). Next we reduce the +leading digit of both (line 45) and then mp\_clamp(). \section*{Exercises} \begin{tabular}{cl} @@ -3611,101 +3622,113 @@ exceed the precision requested. 018 * HAC pp. 595, Algorithm 14.12 Modified so you can control how 019 * many digits of output are created. 020 */ -021 int -022 s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) -023 \{ -024 mp_int t; -025 int res, pa, pb, ix, iy; -026 mp_digit u; -027 mp_word r; -028 mp_digit tmpx, *tmpt, *tmpy; -029 -030 /* can we use the fast multiplier? */ -031 if (((digs) < MP_WARRAY) && -032 MIN (a->used, b->used) < -033 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ -034 return fast_s_mp_mul_digs (a, b, c, digs); -035 \} -036 -037 if ((res = mp_init_size (&t, digs)) != MP_OKAY) \{ -038 return res; -039 \} -040 t.used = digs; -041 -042 /* compute the digits of the product directly */ -043 pa = a->used; -044 for (ix = 0; ix < pa; ix++) \{ -045 /* set the carry to zero */ -046 u = 0; -047 -048 /* limit ourselves to making digs digits of output */ -049 pb = MIN (b->used, digs - ix); -050 -051 /* setup some aliases */ -052 /* copy of the digit from a used within the nested loop */ -053 tmpx = a->dp[ix]; -054 -055 /* an alias for the destination shifted ix places */ -056 tmpt = t.dp + ix; -057 -058 /* an alias for the digits of b */ -059 tmpy = b->dp; -060 -061 /* compute the columns of the output and propagate the carry */ -062 for (iy = 0; iy < pb; iy++) \{ -063 /* compute the column as a mp_word */ -064 r = ((mp_word)*tmpt) + -065 ((mp_word)tmpx) * ((mp_word)*tmpy++) + -066 ((mp_word) u); -067 -068 /* the new column is the lower part of the result */ -069 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -070 -071 /* get the carry word from the result */ -072 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); -073 \} -074 /* set carry if it is placed below digs */ -075 if (ix + iy < digs) \{ -076 *tmpt = u; -077 \} -078 \} -079 -080 mp_clamp (&t); -081 mp_exch (&t, c); -082 -083 mp_clear (&t); -084 return MP_OKAY; -085 \} -086 #endif +021 int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +022 \{ +023 mp_int t; +024 int res, pa, pb, ix, iy; +025 mp_digit u; +026 mp_word r; +027 mp_digit tmpx, *tmpt, *tmpy; +028 +029 /* can we use the fast multiplier? */ +030 if (((digs) < MP_WARRAY) && +031 MIN (a->used, b->used) < +032 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ +033 return fast_s_mp_mul_digs (a, b, c, digs); +034 \} +035 +036 if ((res = mp_init_size (&t, digs)) != MP_OKAY) \{ +037 return res; +038 \} +039 t.used = digs; +040 +041 /* compute the digits of the product directly */ +042 pa = a->used; +043 for (ix = 0; ix < pa; ix++) \{ +044 /* set the carry to zero */ +045 u = 0; +046 +047 /* limit ourselves to making digs digits of output */ +048 pb = MIN (b->used, digs - ix); +049 +050 /* setup some aliases */ +051 /* copy of the digit from a used within the nested loop */ +052 tmpx = a->dp[ix]; +053 +054 /* an alias for the destination shifted ix places */ +055 tmpt = t.dp + ix; +056 +057 /* an alias for the digits of b */ +058 tmpy = b->dp; +059 +060 /* compute the columns of the output and propagate the carry */ +061 for (iy = 0; iy < pb; iy++) \{ +062 /* compute the column as a mp_word */ +063 r = ((mp_word)*tmpt) + +064 ((mp_word)tmpx) * ((mp_word)*tmpy++) + +065 ((mp_word) u); +066 +067 /* the new column is the lower part of the result */ +068 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +069 +070 /* get the carry word from the result */ +071 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); +072 \} +073 /* set carry if it is placed below digs */ +074 if (ix + iy < digs) \{ +075 *tmpt = u; +076 \} +077 \} +078 +079 mp_clamp (&t); +080 mp_exch (&t, c); +081 +082 mp_clear (&t); +083 return MP_OKAY; +084 \} +085 #endif \end{alltt} \end{small} -Lines 31 to 35 determine if the Comba method can be used first. The conditions for using the Comba routine are that min$(a.used, b.used) < \delta$ and -the number of digits of output is less than \textbf{MP\_WARRAY}. This new constant is used to control -the stack usage in the Comba routines. By default it is set to $\delta$ but can be reduced when memory is at a premium. +First we determine (line 30) if the Comba method can be used first since it's faster. The conditions for +sing the Comba routine are that min$(a.used, b.used) < \delta$ and the number of digits of output is less than +\textbf{MP\_WARRAY}. This new constant is used to control the stack usage in the Comba routines. By default it is +set to $\delta$ but can be reduced when memory is at a premium. + +If we cannot use the Comba method we proceed to setup the baseline routine. We allocate the the destination mp\_int +$t$ (line 36) to the exact size of the output to avoid further re--allocations. At this point we now +begin the $O(n^2)$ loop. -Of particular importance is the calculation of the $ix+iy$'th column on lines 64, 65 and 66. Note how all of the -variables are cast to the type \textbf{mp\_word}, which is also the type of variable $\hat r$. That is to ensure that double precision operations -are used instead of single precision. The multiplication on line 65 makes use of a specific GCC optimizer behaviour. On the outset it looks like -the compiler will have to use a double precision multiplication to produce the result required. Such an operation would be horribly slow on most -processors and drag this to a crawl. However, GCC is smart enough to realize that double wide output single precision multipliers can be used. For -example, the instruction ``MUL'' on the x86 processor can multiply two 32-bit values and produce a 64-bit result. +This implementation of multiplication has the caveat that it can be trimmed to only produce a variable number of +digits as output. In each iteration of the outer loop the $pb$ variable is set (line 48) to the maximum +number of inner loop iterations. + +Inside the inner loop we calculate $\hat r$ as the mp\_word product of the two mp\_digits and the addition of the +carry from the previous iteration. A particularly important observation is that most modern optimizing +C compilers (GCC for instance) can recognize that a $N \times N \rightarrow 2N$ multiplication is all that +is required for the product. In x86 terms for example, this means using the MUL instruction. + +Each digit of the product is stored in turn (line 68) and the carry propagated (line 71) to the +next iteration. \subsection{Faster Multiplication by the ``Comba'' Method} -One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be computed and propagated upwards. This -makes the nested loop very sequential and hard to unroll and implement in parallel. The ``Comba'' \cite{COMBA} method is named after little known -(\textit{in cryptographic venues}) Paul G. Comba who described a method of implementing fast multipliers that do not require nested -carry fixup operations. As an interesting aside it seems that Paul Barrett describes a similar technique in -his 1986 paper \cite{BARRETT} written five years before. +One of the huge drawbacks of the ``baseline'' algorithms is that at the $O(n^2)$ level the carry must be +computed and propagated upwards. This makes the nested loop very sequential and hard to unroll and implement +in parallel. The ``Comba'' \cite{COMBA} method is named after little known (\textit{in cryptographic venues}) Paul G. +Comba who described a method of implementing fast multipliers that do not require nested carry fixup operations. As an +interesting aside it seems that Paul Barrett describes a similar technique in his 1986 paper \cite{BARRETT} written +five years before. -At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight twist is placed on how -the columns of the result are produced. In the standard long-hand algorithm rows of products are produced then added together to form the -final result. In the baseline algorithm the columns are added together after each iteration to get the result instantaneously. +At the heart of the Comba technique is once again the long-hand algorithm. Except in this case a slight +twist is placed on how the columns of the result are produced. In the standard long-hand algorithm rows of products +are produced then added together to form the final result. In the baseline algorithm the columns are added together +after each iteration to get the result instantaneously. -In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at the $O(n^2)$ level a -simple multiplication and addition step is performed. The carries of the columns are propagated after the nested loop to reduce the amount -of work requiored. Succintly the first step of the algorithm is to compute the product vector $\vec x$ as follows. +In the Comba algorithm the columns of the result are produced entirely independently of each other. That is at +the $O(n^2)$ level a simple multiplication and addition step is performed. The carries of the columns are propagated +after the nested loop to reduce the amount of work requiored. Succintly the first step of the algorithm is to compute +the product vector $\vec x$ as follows. \begin{equation} \vec x_n = \sum_{i+j = n} a_ib_j, \forall n \in \lbrace 0, 1, 2, \ldots, i + j \rbrace @@ -3799,38 +3822,32 @@ $256$ digits would allow for numbers in the range of $0 \le x < 2^{7168}$ which, \textbf{Input}. mp\_int $a$, mp\_int $b$ and an integer $digs$ \\ \textbf{Output}. $c \leftarrow \vert a \vert \cdot \vert b \vert \mbox{ (mod }\beta^{digs}\mbox{)}$. \\ \hline \\ -Place an array of \textbf{MP\_WARRAY} double precision digits named $\hat W$ on the stack. \\ +Place an array of \textbf{MP\_WARRAY} single precision digits named $W$ on the stack. \\ 1. If $c.alloc < digs$ then grow $c$ to $digs$ digits. (\textit{mp\_grow}) \\ 2. If step 1 failed return(\textit{MP\_MEM}).\\ \\ -Zero the temporary array $\hat W$. \\ -3. for $n$ from $0$ to $digs - 1$ do \\ -\hspace{3mm}3.1 $\hat W_n \leftarrow 0$ \\ +3. $pa \leftarrow \mbox{MIN}(digs, a.used + b.used)$ \\ \\ -Compute the columns. \\ -4. for $ix$ from $0$ to $a.used - 1$ do \\ -\hspace{3mm}4.1 $pb \leftarrow \mbox{min}(b.used, digs - ix)$ \\ -\hspace{3mm}4.2 If $pb < 1$ then goto step 5. \\ -\hspace{3mm}4.3 for $iy$ from $0$ to $pb - 1$ do \\ -\hspace{6mm}4.3.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}b_{iy}$ \\ +4. $\_ \hat W \leftarrow 0$ \\ +5. for $ix$ from 0 to $pa - 1$ do \\ +\hspace{3mm}5.1 $ty \leftarrow \mbox{MIN}(b.used - 1, ix)$ \\ +\hspace{3mm}5.2 $tx \leftarrow ix - ty$ \\ +\hspace{3mm}5.3 $iy \leftarrow \mbox{MIN}(a.used - tx, ty + 1)$ \\ +\hspace{3mm}5.4 for $iz$ from 0 to $iy - 1$ do \\ +\hspace{6mm}5.4.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx+iy}b_{ty-iy}$ \\ +\hspace{3mm}5.5 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$\\ +\hspace{3mm}5.6 $\_ \hat W \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ +6. $W_{pa} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ \\ -Propagate the carries upwards. \\ -5. $oldused \leftarrow c.used$ \\ -6. $c.used \leftarrow digs$ \\ -7. If $digs > 1$ then do \\ -\hspace{3mm}7.1. for $ix$ from $1$ to $digs - 1$ do \\ -\hspace{6mm}7.1.1 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix-1} / \beta \rfloor$ \\ -\hspace{6mm}7.1.2 $c_{ix - 1} \leftarrow \hat W_{ix - 1} \mbox{ (mod }\beta\mbox{)}$ \\ -8. else do \\ -\hspace{3mm}8.1 $ix \leftarrow 0$ \\ -9. $c_{ix} \leftarrow \hat W_{ix} \mbox{ (mod }\beta\mbox{)}$ \\ +7. $oldused \leftarrow c.used$ \\ +8. $c.used \leftarrow digs$ \\ +9. for $ix$ from $0$ to $pa$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow W_{ix}$ \\ +10. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ +\hspace{3mm}10.1 $c_{ix} \leftarrow 0$ \\ \\ -Zero excess digits. \\ -10. If $digs < oldused$ then do \\ -\hspace{3mm}10.1 for $n$ from $digs$ to $oldused - 1$ do \\ -\hspace{6mm}10.1.1 $c_n \leftarrow 0$ \\ -11. Clamp excessive digits of $c$. (\textit{mp\_clamp}) \\ -12. Return(\textit{MP\_OKAY}). \\ +11. Clamp $c$. \\ +12. Return MP\_OKAY. \\ \hline \end{tabular} \end{center} @@ -3840,15 +3857,24 @@ Zero excess digits. \\ \end{figure} \textbf{Algorithm fast\_s\_mp\_mul\_digs.} -This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. The algorithm -essentially peforms the same calculation as algorithm s\_mp\_mul\_digs, just much faster. +This algorithm performs the unsigned multiplication of $a$ and $b$ using the Comba method limited to $digs$ digits of precision. + +The outer loop of this algorithm is more complicated than that of the baseline multiplier. This is because on the inside of the +loop we want to produce one column per pass. This allows the accumulator $\_ \hat W$ to be placed in CPU registers and +reduce the memory bandwidth to two \textbf{mp\_digit} reads per iteration. -The array $\hat W$ is meant to be on the stack when the algorithm is used. The size of the array does not change which is ideal. Note also that -unlike algorithm s\_mp\_mul\_digs no temporary mp\_int is required since the result is calculated directly in $\hat W$. +The $ty$ variable is set to the minimum count of $ix$ or the number of digits in $b$. That way if $a$ has more digits than +$b$ this will be limited to $b.used - 1$. The $tx$ variable is set to the to the distance past $b.used$ the variable +$ix$ is. This is used for the immediately subsequent statement where we find $iy$. -The $O(n^2)$ loop on step four is where the Comba method's advantages begin to show through in comparison to the baseline algorithm. The lack of -a carry variable or propagation in this loop allows the loop to be performed with only single precision multiplication and additions. Now that each -iteration of the inner loop can be performed independent of the others the inner loop can be performed with a high level of parallelism. +The variable $iy$ is the minimum digits we can read from either $a$ or $b$ before running out. Computing one column at a time +means we have to scan one integer upwards and the other downwards. $a$ starts at $tx$ and $b$ starts at $ty$. In each +pass we are producing the $ix$'th output column and we note that $tx + ty = ix$. As we move $tx$ upwards we have to +move $ty$ downards so the equality remains valid. The $iy$ variable is the number of iterations until +$tx \ge a.used$ or $ty < 0$ occurs. + +After every inner pass we store the lower half of the accumulator into $W_{ix}$ and then propagate the carry of the accumulator +into the next round by dividing $\_ \hat W$ by $\beta$. To measure the benefits of the Comba method over the baseline method consider the number of operations that are required. If the cost in terms of time of a multiply and addition is $p$ and the cost of a carry propagation is $q$ then a baseline multiplication would require @@ -3877,97 +3903,95 @@ and addition operations in the nested loop in parallel. 030 * Based on Algorithm 14.12 on pp.595 of HAC. 031 * 032 */ -033 int -034 fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) -035 \{ -036 int olduse, res, pa, ix, iz; -037 mp_digit W[MP_WARRAY]; -038 register mp_word _W; -039 -040 /* grow the destination as required */ -041 if (c->alloc < digs) \{ -042 if ((res = mp_grow (c, digs)) != MP_OKAY) \{ -043 return res; -044 \} -045 \} -046 -047 /* number of output digits to produce */ -048 pa = MIN(digs, a->used + b->used); -049 -050 /* clear the carry */ -051 _W = 0; -052 for (ix = 0; ix < pa; ix++) \{ -053 int tx, ty; -054 int iy; -055 mp_digit *tmpx, *tmpy; -056 -057 /* get offsets into the two bignums */ -058 ty = MIN(b->used-1, ix); -059 tx = ix - ty; -060 -061 /* setup temp aliases */ -062 tmpx = a->dp + tx; -063 tmpy = b->dp + ty; -064 -065 /* this is the number of times the loop will iterrate, essentially its - -066 while (tx++ < a->used && ty-- >= 0) \{ ... \} -067 */ -068 iy = MIN(a->used-tx, ty+1); -069 -070 /* execute loop */ -071 for (iz = 0; iz < iy; ++iz) \{ -072 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); -073 \} -074 -075 /* store term */ -076 W[ix] = ((mp_digit)_W) & MP_MASK; -077 -078 /* make next carry */ -079 _W = _W >> ((mp_word)DIGIT_BIT); -080 \} -081 -082 /* store final carry */ -083 W[ix] = _W; -084 -085 /* setup dest */ -086 olduse = c->used; -087 c->used = digs; -088 -089 \{ -090 register mp_digit *tmpc; -091 tmpc = c->dp; -092 for (ix = 0; ix < digs; ix++) \{ -093 /* now extract the previous digit [below the carry] */ -094 *tmpc++ = W[ix]; -095 \} -096 -097 /* clear unused digits [that existed in the old copy of c] */ -098 for (; ix < olduse; ix++) \{ -099 *tmpc++ = 0; -100 \} -101 \} -102 mp_clamp (c); -103 return MP_OKAY; -104 \} -105 #endif +033 int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) +034 \{ +035 int olduse, res, pa, ix, iz; +036 mp_digit W[MP_WARRAY]; +037 register mp_word _W; +038 +039 /* grow the destination as required */ +040 if (c->alloc < digs) \{ +041 if ((res = mp_grow (c, digs)) != MP_OKAY) \{ +042 return res; +043 \} +044 \} +045 +046 /* number of output digits to produce */ +047 pa = MIN(digs, a->used + b->used); +048 +049 /* clear the carry */ +050 _W = 0; +051 for (ix = 0; ix < pa; ix++) \{ +052 int tx, ty; +053 int iy; +054 mp_digit *tmpx, *tmpy; +055 +056 /* get offsets into the two bignums */ +057 ty = MIN(b->used-1, ix); +058 tx = ix - ty; +059 +060 /* setup temp aliases */ +061 tmpx = a->dp + tx; +062 tmpy = b->dp + ty; +063 +064 /* this is the number of times the loop will iterrate, essentially +065 while (tx++ < a->used && ty-- >= 0) \{ ... \} +066 */ +067 iy = MIN(a->used-tx, ty+1); +068 +069 /* execute loop */ +070 for (iz = 0; iz < iy; ++iz) \{ +071 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); +072 \} +073 +074 /* store term */ +075 W[ix] = ((mp_digit)_W) & MP_MASK; +076 +077 /* make next carry */ +078 _W = _W >> ((mp_word)DIGIT_BIT); +079 \} +080 +081 /* store final carry */ +082 W[ix] = (mp_digit)(_W & MP_MASK); +083 +084 /* setup dest */ +085 olduse = c->used; +086 c->used = pa; +087 +088 \{ +089 register mp_digit *tmpc; +090 tmpc = c->dp; +091 for (ix = 0; ix < pa+1; ix++) \{ +092 /* now extract the previous digit [below the carry] */ +093 *tmpc++ = W[ix]; +094 \} +095 +096 /* clear unused digits [that existed in the old copy of c] */ +097 for (; ix < olduse; ix++) \{ +098 *tmpc++ = 0; +099 \} +100 \} +101 mp_clamp (c); +102 return MP_OKAY; +103 \} +104 #endif \end{alltt} \end{small} -The memset on line @47,memset@ clears the initial $\hat W$ array to zero in a single step. Like the slower baseline multiplication -implementation a series of aliases (\textit{lines 62, 63 and 76}) are used to simplify the inner $O(n^2)$ loop. -In this case a new alias $\_\hat W$ has been added which refers to the double precision columns offset by $ix$ in each pass. +As per the pseudo--code we first calculate $pa$ (line 47) as the number of digits to output. Next we begin the outer loop +to produce the individual columns of the product. We use the two aliases $tmpx$ and $tmpy$ (lines 61, 62) to point +inside the two multiplicands quickly. -The inner loop on lines 92, 79 and 80 is where the algorithm will spend the majority of the time, which is why it has been -stripped to the bones of any extra baggage\footnote{Hence the pointer aliases.}. On x86 processors the multiplication and additions amount to at the -very least five instructions (\textit{two loads, two additions, one multiply}) while on the ARMv4 processors they amount to only three -(\textit{one load, one store, one multiply-add}). For both of the x86 and ARMv4 processors the GCC compiler performs a good job at unrolling the loop -and scheduling the instructions so there are very few dependency stalls. +The inner loop (lines 70 to 72) of this implementation is where the tradeoff come into play. Originally this comba +implementation was ``row--major'' which means it adds to each of the columns in each pass. After the outer loop it would then fix +the carries. This was very fast except it had an annoying drawback. You had to read a mp\_word and two mp\_digits and write +one mp\_word per iteration. On processors such as the Athlon XP and P4 this did not matter much since the cache bandwidth +is very high and it can keep the ALU fed with data. It did, however, matter on older and embedded cpus where cache is often +slower and also often doesn't exist. This new algorithm only performs two reads per iteration under the assumption that the +compiler has aliased $\_ \hat W$ to a CPU register. -In theory the difference between the baseline and comba algorithms is a mere $O(qn)$ time difference. However, in the $O(n^2)$ nested loop of the -baseline method there are dependency stalls as the algorithm must wait for the multiplier to finish before propagating the carry to the next -digit. As a result fewer of the often multiple execution units\footnote{The AMD Athlon has three execution units and the Intel P4 has four.} can -be simultaneously used. +After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines 75, 78) to forward it as +a carry for the next pass. After the outer loop we use the final carry (line 82) as the last digit of the product. \subsection{Polynomial Basis Multiplication} To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms @@ -4444,277 +4468,290 @@ result $a \cdot b$ is produced. 016 017 /* multiplication using the Toom-Cook 3-way algorithm 018 * -019 * Much more complicated than Karatsuba but has a lower asymptotic running t - ime of -020 * O(N**1.464). This algorithm is only particularly useful on VERY large -021 * inputs (we're talking 1000s of digits here...). -022 */ -023 int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) -024 \{ -025 mp_int w0, w1, w2, w3, w4, tmp1, tmp2, a0, a1, a2, b0, b1, b2; -026 int res, B; -027 -028 /* init temps */ -029 if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, -030 &a0, &a1, &a2, &b0, &b1, -031 &b2, &tmp1, &tmp2, NULL)) != MP_OKAY) \{ -032 return res; -033 \} -034 -035 /* B */ -036 B = MIN(a->used, b->used) / 3; -037 -038 /* a = a2 * B**2 + a1 * B + a0 */ -039 if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) \{ -040 goto ERR; -041 \} -042 -043 if ((res = mp_copy(a, &a1)) != MP_OKAY) \{ -044 goto ERR; -045 \} -046 mp_rshd(&a1, B); -047 mp_mod_2d(&a1, DIGIT_BIT * B, &a1); -048 -049 if ((res = mp_copy(a, &a2)) != MP_OKAY) \{ -050 goto ERR; -051 \} -052 mp_rshd(&a2, B*2); -053 -054 /* b = b2 * B**2 + b1 * B + b0 */ -055 if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) \{ -056 goto ERR; -057 \} -058 -059 if ((res = mp_copy(b, &b1)) != MP_OKAY) \{ -060 goto ERR; -061 \} -062 mp_rshd(&b1, B); -063 mp_mod_2d(&b1, DIGIT_BIT * B, &b1); -064 -065 if ((res = mp_copy(b, &b2)) != MP_OKAY) \{ -066 goto ERR; -067 \} -068 mp_rshd(&b2, B*2); -069 -070 /* w0 = a0*b0 */ -071 if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) \{ -072 goto ERR; -073 \} -074 -075 /* w4 = a2 * b2 */ -076 if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) \{ -077 goto ERR; -078 \} -079 -080 /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ -081 if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) \{ -082 goto ERR; -083 \} -084 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ -085 goto ERR; -086 \} -087 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ -088 goto ERR; -089 \} -090 if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) \{ -091 goto ERR; -092 \} -093 -094 if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) \{ -095 goto ERR; -096 \} -097 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ -098 goto ERR; -099 \} -100 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ -101 goto ERR; -102 \} -103 if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) \{ -104 goto ERR; -105 \} -106 -107 if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) \{ -108 goto ERR; -109 \} -110 -111 /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ -112 if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) \{ -113 goto ERR; -114 \} -115 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ -116 goto ERR; -117 \} -118 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ -119 goto ERR; -120 \} -121 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ -122 goto ERR; -123 \} -124 -125 if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) \{ -126 goto ERR; -127 \} -128 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ -129 goto ERR; -130 \} -131 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ -132 goto ERR; -133 \} -134 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ -135 goto ERR; -136 \} -137 -138 if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) \{ -139 goto ERR; -140 \} -141 -142 -143 /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ -144 if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) \{ -145 goto ERR; -146 \} -147 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ -148 goto ERR; -149 \} -150 if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) \{ -151 goto ERR; -152 \} -153 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ -154 goto ERR; -155 \} -156 if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) \{ -157 goto ERR; -158 \} -159 -160 /* now solve the matrix -161 -162 0 0 0 0 1 -163 1 2 4 8 16 -164 1 1 1 1 1 -165 16 8 4 2 1 -166 1 0 0 0 0 -167 -168 using 12 subtractions, 4 shifts, -169 2 small divisions and 1 small multiplication -170 */ -171 -172 /* r1 - r4 */ -173 if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) \{ -174 goto ERR; -175 \} -176 /* r3 - r0 */ -177 if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) \{ -178 goto ERR; -179 \} -180 /* r1/2 */ -181 if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) \{ -182 goto ERR; -183 \} -184 /* r3/2 */ -185 if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) \{ -186 goto ERR; -187 \} -188 /* r2 - r0 - r4 */ -189 if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) \{ -190 goto ERR; -191 \} -192 if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) \{ -193 goto ERR; -194 \} -195 /* r1 - r2 */ -196 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ -197 goto ERR; -198 \} -199 /* r3 - r2 */ -200 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ -201 goto ERR; -202 \} -203 /* r1 - 8r0 */ -204 if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) \{ -205 goto ERR; -206 \} -207 if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) \{ -208 goto ERR; -209 \} -210 /* r3 - 8r4 */ -211 if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) \{ -212 goto ERR; -213 \} -214 if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) \{ -215 goto ERR; -216 \} -217 /* 3r2 - r1 - r3 */ -218 if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) \{ -219 goto ERR; -220 \} -221 if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) \{ -222 goto ERR; -223 \} -224 if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) \{ -225 goto ERR; -226 \} -227 /* r1 - r2 */ -228 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ -229 goto ERR; -230 \} -231 /* r3 - r2 */ -232 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ -233 goto ERR; -234 \} -235 /* r1/3 */ -236 if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) \{ -237 goto ERR; -238 \} -239 /* r3/3 */ -240 if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) \{ -241 goto ERR; -242 \} -243 -244 /* at this point shift W[n] by B*n */ -245 if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) \{ -246 goto ERR; -247 \} -248 if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) \{ -249 goto ERR; -250 \} -251 if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) \{ -252 goto ERR; -253 \} -254 if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) \{ -255 goto ERR; -256 \} -257 -258 if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) \{ -259 goto ERR; -260 \} -261 if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) \{ -262 goto ERR; -263 \} -264 if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) \{ -265 goto ERR; -266 \} -267 if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) \{ -268 goto ERR; -269 \} -270 -271 ERR: -272 mp_clear_multi(&w0, &w1, &w2, &w3, &w4, -273 &a0, &a1, &a2, &b0, &b1, -274 &b2, &tmp1, &tmp2, NULL); -275 return res; -276 \} -277 -278 #endif +019 * Much more complicated than Karatsuba but has a lower +020 * asymptotic running time of O(N**1.464). This algorithm is +021 * only particularly useful on VERY large inputs +022 * (we're talking 1000s of digits here...). +023 */ +024 int mp_toom_mul(mp_int *a, mp_int *b, mp_int *c) +025 \{ +026 mp_int w0, w1, w2, w3, w4, tmp1, tmp2, a0, a1, a2, b0, b1, b2; +027 int res, B; +028 +029 /* init temps */ +030 if ((res = mp_init_multi(&w0, &w1, &w2, &w3, &w4, +031 &a0, &a1, &a2, &b0, &b1, +032 &b2, &tmp1, &tmp2, NULL)) != MP_OKAY) \{ +033 return res; +034 \} +035 +036 /* B */ +037 B = MIN(a->used, b->used) / 3; +038 +039 /* a = a2 * B**2 + a1 * B + a0 */ +040 if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) \{ +041 goto ERR; +042 \} +043 +044 if ((res = mp_copy(a, &a1)) != MP_OKAY) \{ +045 goto ERR; +046 \} +047 mp_rshd(&a1, B); +048 mp_mod_2d(&a1, DIGIT_BIT * B, &a1); +049 +050 if ((res = mp_copy(a, &a2)) != MP_OKAY) \{ +051 goto ERR; +052 \} +053 mp_rshd(&a2, B*2); +054 +055 /* b = b2 * B**2 + b1 * B + b0 */ +056 if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) \{ +057 goto ERR; +058 \} +059 +060 if ((res = mp_copy(b, &b1)) != MP_OKAY) \{ +061 goto ERR; +062 \} +063 mp_rshd(&b1, B); +064 mp_mod_2d(&b1, DIGIT_BIT * B, &b1); +065 +066 if ((res = mp_copy(b, &b2)) != MP_OKAY) \{ +067 goto ERR; +068 \} +069 mp_rshd(&b2, B*2); +070 +071 /* w0 = a0*b0 */ +072 if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) \{ +073 goto ERR; +074 \} +075 +076 /* w4 = a2 * b2 */ +077 if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) \{ +078 goto ERR; +079 \} +080 +081 /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ +082 if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) \{ +083 goto ERR; +084 \} +085 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ +086 goto ERR; +087 \} +088 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ +089 goto ERR; +090 \} +091 if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) \{ +092 goto ERR; +093 \} +094 +095 if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) \{ +096 goto ERR; +097 \} +098 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ +099 goto ERR; +100 \} +101 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ +102 goto ERR; +103 \} +104 if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) \{ +105 goto ERR; +106 \} +107 +108 if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) \{ +109 goto ERR; +110 \} +111 +112 /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ +113 if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) \{ +114 goto ERR; +115 \} +116 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ +117 goto ERR; +118 \} +119 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ +120 goto ERR; +121 \} +122 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ +123 goto ERR; +124 \} +125 +126 if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) \{ +127 goto ERR; +128 \} +129 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ +130 goto ERR; +131 \} +132 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ +133 goto ERR; +134 \} +135 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ +136 goto ERR; +137 \} +138 +139 if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) \{ +140 goto ERR; +141 \} +142 +143 +144 /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ +145 if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) \{ +146 goto ERR; +147 \} +148 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ +149 goto ERR; +150 \} +151 if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) \{ +152 goto ERR; +153 \} +154 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ +155 goto ERR; +156 \} +157 if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) \{ +158 goto ERR; +159 \} +160 +161 /* now solve the matrix +162 +163 0 0 0 0 1 +164 1 2 4 8 16 +165 1 1 1 1 1 +166 16 8 4 2 1 +167 1 0 0 0 0 +168 +169 using 12 subtractions, 4 shifts, +170 2 small divisions and 1 small multiplication +171 */ +172 +173 /* r1 - r4 */ +174 if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) \{ +175 goto ERR; +176 \} +177 /* r3 - r0 */ +178 if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) \{ +179 goto ERR; +180 \} +181 /* r1/2 */ +182 if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) \{ +183 goto ERR; +184 \} +185 /* r3/2 */ +186 if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) \{ +187 goto ERR; +188 \} +189 /* r2 - r0 - r4 */ +190 if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) \{ +191 goto ERR; +192 \} +193 if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) \{ +194 goto ERR; +195 \} +196 /* r1 - r2 */ +197 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ +198 goto ERR; +199 \} +200 /* r3 - r2 */ +201 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ +202 goto ERR; +203 \} +204 /* r1 - 8r0 */ +205 if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) \{ +206 goto ERR; +207 \} +208 if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) \{ +209 goto ERR; +210 \} +211 /* r3 - 8r4 */ +212 if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) \{ +213 goto ERR; +214 \} +215 if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) \{ +216 goto ERR; +217 \} +218 /* 3r2 - r1 - r3 */ +219 if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) \{ +220 goto ERR; +221 \} +222 if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) \{ +223 goto ERR; +224 \} +225 if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) \{ +226 goto ERR; +227 \} +228 /* r1 - r2 */ +229 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ +230 goto ERR; +231 \} +232 /* r3 - r2 */ +233 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ +234 goto ERR; +235 \} +236 /* r1/3 */ +237 if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) \{ +238 goto ERR; +239 \} +240 /* r3/3 */ +241 if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) \{ +242 goto ERR; +243 \} +244 +245 /* at this point shift W[n] by B*n */ +246 if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) \{ +247 goto ERR; +248 \} +249 if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) \{ +250 goto ERR; +251 \} +252 if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) \{ +253 goto ERR; +254 \} +255 if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) \{ +256 goto ERR; +257 \} +258 +259 if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) \{ +260 goto ERR; +261 \} +262 if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) \{ +263 goto ERR; +264 \} +265 if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) \{ +266 goto ERR; +267 \} +268 if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) \{ +269 goto ERR; +270 \} +271 +272 ERR: +273 mp_clear_multi(&w0, &w1, &w2, &w3, &w4, +274 &a0, &a1, &a2, &b0, &b1, +275 &b2, &tmp1, &tmp2, NULL); +276 return res; +277 \} +278 +279 #endif \end{alltt} \end{small} --- Comments to be added during editing phase. +The first obvious thing to note is that this algorithm is complicated. The complexity is worth it if you are multiplying very +large numbers. For example, a 10,000 digit multiplication takes approximaly 99,282,205 fewer single precision multiplications with +Toom--Cook than a Comba or baseline approach (this is a savings of more than 99$\%$). For most ``crypto'' sized numbers this +algorithm is not practical as Karatsuba has a much lower cutoff point. + +First we split $a$ and $b$ into three roughly equal portions. This has been accomplished (lines 40 to 69) with +combinations of mp\_rshd() and mp\_mod\_2d() function calls. At this point $a = a2 \cdot \beta^2 + a1 \cdot \beta + a0$ and similiarly +for $b$. + +Next we compute the five points $w0, w1, w2, w3$ and $w4$. Recall that $w0$ and $w4$ can be computed directly from the portions so +we get those out of the way first (lines 72 and 77). Next we compute $w1, w2$ and $w3$ using Horners method. + +After this point we solve for the actual values of $w1, w2$ and $w3$ by reducing the $5 \times 5$ system which is relatively +straight forward. \subsection{Signed Multiplication} Now that algorithms to handle multiplications of every useful dimensions have been developed, a rather simple finishing touch is required. So far all of the multiplication algorithms have been unsigned multiplications which leaves only a signed multiplication algorithm to be established. -\newpage\begin{figure}[!here] +\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -4847,7 +4884,7 @@ Column two of row one is a square and column three is the first unique column. The baseline squaring algorithm is meant to be a catch-all squaring algorithm. It will handle any of the input sizes that the faster routines will not handle. -\newpage\begin{figure}[!here] +\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -4907,75 +4944,79 @@ results calculated so far. This involves expensive carry propagation which will \begin{alltt} 016 017 /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ -018 int -019 s_mp_sqr (mp_int * a, mp_int * b) -020 \{ -021 mp_int t; -022 int res, ix, iy, pa; -023 mp_word r; -024 mp_digit u, tmpx, *tmpt; -025 -026 pa = a->used; -027 if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) \{ -028 return res; -029 \} -030 -031 /* default used is maximum possible size */ -032 t.used = 2*pa + 1; -033 -034 for (ix = 0; ix < pa; ix++) \{ -035 /* first calculate the digit at 2*ix */ -036 /* calculate double precision result */ -037 r = ((mp_word) t.dp[2*ix]) + -038 ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); -039 -040 /* store lower part in result */ -041 t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); -042 -043 /* get the carry */ -044 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -045 -046 /* left hand side of A[ix] * A[iy] */ -047 tmpx = a->dp[ix]; -048 -049 /* alias for where to store the results */ -050 tmpt = t.dp + (2*ix + 1); -051 -052 for (iy = ix + 1; iy < pa; iy++) \{ -053 /* first calculate the product */ -054 r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); -055 -056 /* now calculate the double precision result, note we use -057 * addition instead of *2 since it's easier to optimize -058 */ -059 r = ((mp_word) *tmpt) + r + r + ((mp_word) u); -060 -061 /* store lower part */ -062 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -063 -064 /* get carry */ -065 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -066 \} -067 /* propagate upwards */ -068 while (u != ((mp_digit) 0)) \{ -069 r = ((mp_word) *tmpt) + ((mp_word) u); -070 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -071 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -072 \} -073 \} -074 -075 mp_clamp (&t); -076 mp_exch (&t, b); -077 mp_clear (&t); -078 return MP_OKAY; -079 \} -080 #endif +018 int s_mp_sqr (mp_int * a, mp_int * b) +019 \{ +020 mp_int t; +021 int res, ix, iy, pa; +022 mp_word r; +023 mp_digit u, tmpx, *tmpt; +024 +025 pa = a->used; +026 if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) \{ +027 return res; +028 \} +029 +030 /* default used is maximum possible size */ +031 t.used = 2*pa + 1; +032 +033 for (ix = 0; ix < pa; ix++) \{ +034 /* first calculate the digit at 2*ix */ +035 /* calculate double precision result */ +036 r = ((mp_word) t.dp[2*ix]) + +037 ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); +038 +039 /* store lower part in result */ +040 t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); +041 +042 /* get the carry */ +043 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +044 +045 /* left hand side of A[ix] * A[iy] */ +046 tmpx = a->dp[ix]; +047 +048 /* alias for where to store the results */ +049 tmpt = t.dp + (2*ix + 1); +050 +051 for (iy = ix + 1; iy < pa; iy++) \{ +052 /* first calculate the product */ +053 r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); +054 +055 /* now calculate the double precision result, note we use +056 * addition instead of *2 since it's easier to optimize +057 */ +058 r = ((mp_word) *tmpt) + r + r + ((mp_word) u); +059 +060 /* store lower part */ +061 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +062 +063 /* get carry */ +064 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +065 \} +066 /* propagate upwards */ +067 while (u != ((mp_digit) 0)) \{ +068 r = ((mp_word) *tmpt) + ((mp_word) u); +069 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); +070 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); +071 \} +072 \} +073 +074 mp_clamp (&t); +075 mp_exch (&t, b); +076 mp_clear (&t); +077 return MP_OKAY; +078 \} +079 #endif \end{alltt} \end{small} -Inside the outer loop (\textit{see line 34}) the square term is calculated on line 37. Line 44 extracts the carry from the square -term. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized on lines 47 and 50 respectively. The doubling is performed using two -additions (\textit{see line 59}) since it is usually faster than shifting,if not at least as fast. +Inside the outer loop (line 33) the square term is calculated on line 36. The carry (line 43) has been +extracted from the mp\_word accumulator using a right shift. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized +(lines 46 and 49) to simplify the inner loop. The doubling is performed using two +additions (line 58) since it is usually faster than shifting, if not at least as fast. + +The important observation is that the inner loop does not begin at $iy = 0$ like for multiplication. As such the inner loops +get progressively shorter as the algorithm proceeds. This is what leads to the savings compared to using a multiplication to +square a number. \subsection{Faster Squaring by the ``Comba'' Method} A major drawback to the baseline method is the requirement for single precision shifting inside the $O(n^2)$ nested loop. Squaring has an additional @@ -4987,9 +5028,9 @@ propagation operations from the inner loop. However, the inner product must sti that $2a + 2b + 2c = 2(a + b + c)$. That is the sum of all of the double products is equal to double the sum of all the products. For example, $ab + ba + ac + ca = 2ab + 2ac = 2(ab + ac)$. -However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two mp\_word -arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and carry propagation can be -moved to a $O(n)$ work level outside the $O(n^2)$ level. +However, we cannot simply double all of the columns, since the squares appear only once per row. The most practical solution is to have two +mp\_word arrays. One array will hold the squares and the other array will hold the double products. With both arrays the doubling and +carry propagation can be moved to a $O(n)$ work level outside the $O(n^2)$ level. In this case, we have an even simpler solution in mind. \newpage\begin{figure}[!here] \begin{small} @@ -4999,34 +5040,34 @@ moved to a $O(n)$ work level outside the $O(n^2)$ level. \textbf{Input}. mp\_int $a$ \\ \textbf{Output}. $b \leftarrow a^2$ \\ \hline \\ -Place two arrays of \textbf{MP\_WARRAY} mp\_words named $\hat W$ and $\hat {X}$ on the stack. \\ +Place an array of \textbf{MP\_WARRAY} mp\_digits named $W$ on the stack. \\ 1. If $b.alloc < 2a.used + 1$ then grow $b$ to $2a.used + 1$ digits. (\textit{mp\_grow}). \\ 2. If step 1 failed return(\textit{MP\_MEM}). \\ -3. for $ix$ from $0$ to $2a.used + 1$ do \\ -\hspace{3mm}3.1 $\hat W_{ix} \leftarrow 0$ \\ -\hspace{3mm}3.2 $\hat {X}_{ix} \leftarrow 0$ \\ -4. for $ix$ from $0$ to $a.used - 1$ do \\ -\hspace{3mm}Compute the square.\\ -\hspace{3mm}4.1 $\hat {X}_{ix+ix} \leftarrow \left ( a_{ix} \right )^2$ \\ \\ -\hspace{3mm}Compute the double products.\\ -\hspace{3mm}4.2 for $iy$ from $ix + 1$ to $a.used - 1$ do \\ -\hspace{6mm}4.2.1 $\hat W_{ix+iy} \leftarrow \hat W_{ix+iy} + a_{ix}a_{iy}$ \\ -5. $oldused \leftarrow b.used$ \\ -6. $b.used \leftarrow 2a.used + 1$ \\ +3. $pa \leftarrow 2 \cdot a.used$ \\ +4. $\hat W1 \leftarrow 0$ \\ +5. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}5.1 $\_ \hat W \leftarrow 0$ \\ +\hspace{3mm}5.2 $ty \leftarrow \mbox{MIN}(a.used - 1, ix)$ \\ +\hspace{3mm}5.3 $tx \leftarrow ix - ty$ \\ +\hspace{3mm}5.4 $iy \leftarrow \mbox{MIN}(a.used - tx, ty + 1)$ \\ +\hspace{3mm}5.5 $iy \leftarrow \mbox{MIN}(iy, \lfloor \left (ty - tx + 1 \right )/2 \rfloor)$ \\ +\hspace{3mm}5.6 for $iz$ from $0$ to $iz - 1$ do \\ +\hspace{6mm}5.6.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx + iz}a_{ty - iz}$ \\ +\hspace{3mm}5.7 $\_ \hat W \leftarrow 2 \cdot \_ \hat W + \hat W1$ \\ +\hspace{3mm}5.8 if $ix$ is even then \\ +\hspace{6mm}5.8.1 $\_ \hat W \leftarrow \_ \hat W + \left ( a_{\lfloor ix/2 \rfloor}\right )^2$ \\ +\hspace{3mm}5.9 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ +\hspace{3mm}5.10 $\hat W1 \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ \\ -Double the products and propagate the carries simultaneously. \\ -7. $\hat W_0 \leftarrow 2 \hat W_0 + \hat {X}_0$ \\ -8. for $ix$ from $1$ to $2a.used$ do \\ -\hspace{3mm}8.1 $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ \\ -\hspace{3mm}8.2 $\hat W_{ix} \leftarrow \hat W_{ix} + \lfloor \hat W_{ix - 1} / \beta \rfloor$ \\ -\hspace{3mm}8.3 $b_{ix-1} \leftarrow W_{ix-1} \mbox{ (mod }\beta\mbox{)}$ \\ -9. $b_{2a.used} \leftarrow \hat W_{2a.used} \mbox{ (mod }\beta\mbox{)}$ \\ -10. if $2a.used + 1 < oldused$ then do \\ -\hspace{3mm}10.1 for $ix$ from $2a.used + 1$ to $oldused$ do \\ -\hspace{6mm}10.1.1 $b_{ix} \leftarrow 0$ \\ -11. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ -12. Return(\textit{MP\_OKAY}). \\ +6. $oldused \leftarrow b.used$ \\ +7. $b.used \leftarrow 2 \cdot a.used$ \\ +8. for $ix$ from $0$ to $pa - 1$ do \\ +\hspace{3mm}8.1 $b_{ix} \leftarrow W_{ix}$ \\ +9. for $ix$ from $pa$ to $oldused - 1$ do \\ +\hspace{3mm}9.1 $b_{ix} \leftarrow 0$ \\ +10. Clamp excess digits from $b$. (\textit{mp\_clamp}) \\ +11. Return(\textit{MP\_OKAY}). \\ \hline \end{tabular} \end{center} @@ -5035,146 +5076,123 @@ Double the products and propagate the carries simultaneously. \\ \end{figure} \textbf{Algorithm fast\_s\_mp\_sqr.} -This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm s\_mp\_sqr when -the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. +This algorithm computes the square of an input using the Comba technique. It is designed to be a replacement for algorithm +s\_mp\_sqr when the number of input digits is less than \textbf{MP\_WARRAY} and less than $\delta \over 2$. +This algorithm is very similar to the Comba multiplier except with a few key differences we shall make note of. -This routine requires two arrays of mp\_words to be placed on the stack. The first array $\hat W$ will hold the double products and the second -array $\hat X$ will hold the squares. Though only at most $MP\_WARRAY \over 2$ words of $\hat X$ are used, it has proven faster on most -processors to simply make it a full size array. +First, we have an accumulator and carry variables $\_ \hat W$ and $\hat W1$ respectively. This is because the inner loop +products are to be doubled. If we had added the previous carry in we would be doubling too much. Next we perform an +addition MIN condition on $iy$ (step 5.5) to prevent overlapping digits. For example, $a_3 \cdot a_5$ is equal +$a_5 \cdot a_3$. Whereas in the multiplication case we would have $5 < a.used$ and $3 \ge 0$ is maintained since we double the sum +of the products just outside the inner loop we have to avoid doing this. This is also a good thing since we perform +fewer multiplications and the routine ends up being faster. -The loop on step 3 will zero the two arrays to prepare them for the squaring step. Step 4.1 computes the squares of the product. Note how -it simply assigns the value into the $\hat X$ array. The nested loop on step 4.2 computes the doubles of the products. This loop -computes the sum of the products for each column. They are not doubled until later. - -After the squaring loop, the products stored in $\hat W$ musted be doubled and the carries propagated forwards. It makes sense to do both -operations at the same time. The expression $\hat W_{ix} \leftarrow 2 \hat W_{ix} + \hat {X}_{ix}$ computes the sum of the double product and the -squares in place. +Finally the last difference is the addition of the ``square'' term outside the inner loop (step 5.8). We add in the square +only to even outputs and it is the square of the term at the $\lfloor ix / 2 \rfloor$ position. \vspace{+3mm}\begin{small} \hspace{-5.1mm}{\bf File}: bn\_fast\_s\_mp\_sqr.c \vspace{-3mm} \begin{alltt} 016 -017 /* fast squaring -018 * -019 * This is the comba method where the columns of the product -020 * are computed first then the carries are computed. This -021 * has the effect of making a very simple inner loop that -022 * is executed the most -023 * -024 * W2 represents the outer products and W the inner. -025 * -026 * A further optimizations is made because the inner -027 * products are of the form "A * B * 2". The *2 part does -028 * not need to be computed until the end which is good -029 * because 64-bit shifts are slow! -030 * -031 * Based on Algorithm 14.16 on pp.597 of HAC. -032 * -033 */ -034 /* the jist of squaring... -035 -036 you do like mult except the offset of the tmpx [one that starts closer to ze - ro] -037 can't equal the offset of tmpy. So basically you set up iy like before then - you min it with -038 (ty-tx) so that it never happens. You double all those you add in the inner - loop -039 -040 After that loop you do the squares and add them in. -041 -042 Remove W2 and don't memset W -043 -044 */ -045 -046 int fast_s_mp_sqr (mp_int * a, mp_int * b) -047 \{ -048 int olduse, res, pa, ix, iz; -049 mp_digit W[MP_WARRAY], *tmpx; -050 mp_word W1; -051 -052 /* grow the destination as required */ -053 pa = a->used + a->used; -054 if (b->alloc < pa) \{ -055 if ((res = mp_grow (b, pa)) != MP_OKAY) \{ -056 return res; -057 \} -058 \} -059 -060 /* number of output digits to produce */ -061 W1 = 0; -062 for (ix = 0; ix < pa; ix++) \{ -063 int tx, ty, iy; -064 mp_word _W; -065 mp_digit *tmpy; -066 -067 /* clear counter */ -068 _W = 0; +017 /* the jist of squaring... +018 * you do like mult except the offset of the tmpx [one that +019 * starts closer to zero] can't equal the offset of tmpy. +020 * So basically you set up iy like before then you min it with +021 * (ty-tx) so that it never happens. You double all those +022 * you add in the inner loop +023 +024 After that loop you do the squares and add them in. +025 */ +026 +027 int fast_s_mp_sqr (mp_int * a, mp_int * b) +028 \{ +029 int olduse, res, pa, ix, iz; +030 mp_digit W[MP_WARRAY], *tmpx; +031 mp_word W1; +032 +033 /* grow the destination as required */ +034 pa = a->used + a->used; +035 if (b->alloc < pa) \{ +036 if ((res = mp_grow (b, pa)) != MP_OKAY) \{ +037 return res; +038 \} +039 \} +040 +041 /* number of output digits to produce */ +042 W1 = 0; +043 for (ix = 0; ix < pa; ix++) \{ +044 int tx, ty, iy; +045 mp_word _W; +046 mp_digit *tmpy; +047 +048 /* clear counter */ +049 _W = 0; +050 +051 /* get offsets into the two bignums */ +052 ty = MIN(a->used-1, ix); +053 tx = ix - ty; +054 +055 /* setup temp aliases */ +056 tmpx = a->dp + tx; +057 tmpy = a->dp + ty; +058 +059 /* this is the number of times the loop will iterrate, essentially +060 while (tx++ < a->used && ty-- >= 0) \{ ... \} +061 */ +062 iy = MIN(a->used-tx, ty+1); +063 +064 /* now for squaring tx can never equal ty +065 * we halve the distance since they approach at a rate of 2x +066 * and we have to round because odd cases need to be executed +067 */ +068 iy = MIN(iy, (ty-tx+1)>>1); 069 -070 /* get offsets into the two bignums */ -071 ty = MIN(a->used-1, ix); -072 tx = ix - ty; -073 -074 /* setup temp aliases */ -075 tmpx = a->dp + tx; -076 tmpy = a->dp + ty; +070 /* execute loop */ +071 for (iz = 0; iz < iy; iz++) \{ +072 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); +073 \} +074 +075 /* double the inner product and add carry */ +076 _W = _W + _W + W1; 077 -078 /* this is the number of times the loop will iterrate, essentially its - -079 while (tx++ < a->used && ty-- >= 0) \{ ... \} -080 */ -081 iy = MIN(a->used-tx, ty+1); +078 /* even columns have the square term in them */ +079 if ((ix&1) == 0) \{ +080 _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); +081 \} 082 -083 /* now for squaring tx can never equal ty -084 * we halve the distance since they approach at a rate of 2x -085 * and we have to round because odd cases need to be executed -086 */ -087 iy = MIN(iy, (ty-tx+1)>>1); -088 -089 /* execute loop */ -090 for (iz = 0; iz < iy; iz++) \{ -091 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); -092 \} +083 /* store it */ +084 W[ix] = (mp_digit)(_W & MP_MASK); +085 +086 /* make next carry */ +087 W1 = _W >> ((mp_word)DIGIT_BIT); +088 \} +089 +090 /* setup dest */ +091 olduse = b->used; +092 b->used = a->used+a->used; 093 -094 /* double the inner product and add carry */ -095 _W = _W + _W + W1; -096 -097 /* even columns have the square term in them */ -098 if ((ix&1) == 0) \{ -099 _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); -100 \} -101 -102 /* store it */ -103 W[ix] = _W; -104 -105 /* make next carry */ -106 W1 = _W >> ((mp_word)DIGIT_BIT); -107 \} -108 -109 /* setup dest */ -110 olduse = b->used; -111 b->used = a->used+a->used; -112 -113 \{ -114 mp_digit *tmpb; -115 tmpb = b->dp; -116 for (ix = 0; ix < pa; ix++) \{ -117 *tmpb++ = W[ix] & MP_MASK; -118 \} -119 -120 /* clear unused digits [that existed in the old copy of c] */ -121 for (; ix < olduse; ix++) \{ -122 *tmpb++ = 0; -123 \} -124 \} -125 mp_clamp (b); -126 return MP_OKAY; -127 \} -128 #endif +094 \{ +095 mp_digit *tmpb; +096 tmpb = b->dp; +097 for (ix = 0; ix < pa; ix++) \{ +098 *tmpb++ = W[ix] & MP_MASK; +099 \} +100 +101 /* clear unused digits [that existed in the old copy of c] */ +102 for (; ix < olduse; ix++) \{ +103 *tmpb++ = 0; +104 \} +105 \} +106 mp_clamp (b); +107 return MP_OKAY; +108 \} +109 #endif \end{alltt} \end{small} --- Write something deep and insightful later, Tom. +This implementation is essentially a copy of Comba multiplication with the appropriate changes added to make it faster for +the special case of squaring. \subsection{Polynomial Basis Squaring} The same algorithm that performs optimal polynomial basis multiplication can be used to perform polynomial basis squaring. The minor exception @@ -5392,14 +5410,13 @@ By inlining the copy and shift operations the cutoff point for Karatsuba multipl is exactly at the point where Comba squaring can no longer be used (\textit{128 digits}). On slower processors such as the Intel P4 it is actually below the Comba limit (\textit{at 110 digits}). -This routine uses the same error trap coding style as mp\_karatsuba\_sqr. As the temporary variables are initialized errors are redirected to -the error trap higher up. If the algorithm completes without error the error code is set to \textbf{MP\_OKAY} and mp\_clears are executed normally. - -\textit{Last paragraph sucks. re-write! -- Tom} +This routine uses the same error trap coding style as mp\_karatsuba\_sqr. As the temporary variables are initialized errors are +redirected to the error trap higher up. If the algorithm completes without error the error code is set to \textbf{MP\_OKAY} and +mp\_clears are executed normally. \subsection{Toom-Cook Squaring} The Toom-Cook squaring algorithm mp\_toom\_sqr is heavily based on the algorithm mp\_toom\_mul with the exception that squarings are used -instead of multiplication to find the five relations.. The reader is encouraged to read the description of the latter algorithm and try to +instead of multiplication to find the five relations. The reader is encouraged to read the description of the latter algorithm and try to derive their own Toom-Cook squaring algorithm. \subsection{High Level Squaring} @@ -5485,12 +5502,9 @@ neither of the polynomial basis algorithms should be used then either the Comba $\left [ 3 \right ] $ & Devise an efficient algorithm for selection of the radix point to handle inputs \\ & that have different number of digits in Karatsuba multiplication. \\ & \\ -$\left [ 3 \right ] $ & In section 5.3 the fact that every column of a squaring is made up \\ +$\left [ 2 \right ] $ & In section 5.3 the fact that every column of a squaring is made up \\ & of double products and at most one square is stated. Prove this statement. \\ & \\ -$\left [ 2 \right ] $ & In the Comba squaring algorithm half of the $\hat X$ variables are not used. \\ - & Revise algorithm fast\_s\_mp\_sqr to shrink the $\hat X$ array. \\ - & \\ $\left [ 3 \right ] $ & Prove the equation for Karatsuba squaring. \\ & \\ $\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3)} \right )$ time. \\ @@ -5498,6 +5512,14 @@ $\left [ 1 \right ] $ & Prove that Karatsuba squaring requires $O \left (n^{lg(3 $\left [ 2 \right ] $ & Determine the minimal ratio between addition and multiplication clock cycles \\ & required for equation $6.7$ to be true. \\ & \\ +$\left [ 3 \right ] $ & Implement a threaded version of Comba multiplication (and squaring) where you \\ + & compute subsets of the columns in each thread. Determine a cutoff point where \\ + & it is effective and add the logic to mp\_mul() and mp\_sqr(). \\ + &\\ +$\left [ 4 \right ] $ & Same as the previous but also modify the Karatsuba and Toom-Cook. You must \\ + & increase the throughput of mp\_exptmod() for random odd moduli in the range \\ + & $512 \ldots 4096$ bits significantly ($> 2x$) to complete this challenge. \\ + & \\ \end{tabular} \chapter{Modular Reduction} @@ -5516,7 +5538,7 @@ other forms of residues. Modular reductions are normally used to create either finite groups, rings or fields. The most common usage for performance driven modular reductions is in modular exponentiation algorithms. That is to compute $d = a^b \mbox{ (mod }c\mbox{)}$ as fast as possible. This operation is used in the RSA and Diffie-Hellman public key algorithms, for example. Modular multiplication and squaring also appears as a fundamental operation in -Elliptic Curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular +elliptic curve cryptographic algorithms. As will be discussed in the subsequent chapter there exist fast algorithms for computing modular exponentiations without having to perform (\textit{in this example}) $b - 1$ multiplications. These algorithms will produce partial results in the range $0 \le x < c^2$ which can be taken advantage of to create several efficient algorithms. They have also been used to create redundancy check algorithms known as CRCs, error correction codes such as Reed-Solomon and solve a variety of number theoeretic problems. @@ -5730,95 +5752,94 @@ performed at most twice, and on average once. However, if $a \ge b^2$ than it wi 018 * precomputed via mp_reduce_setup. 019 * From HAC pp.604 Algorithm 14.42 020 */ -021 int -022 mp_reduce (mp_int * x, mp_int * m, mp_int * mu) -023 \{ -024 mp_int q; -025 int res, um = m->used; -026 -027 /* q = x */ -028 if ((res = mp_init_copy (&q, x)) != MP_OKAY) \{ -029 return res; -030 \} -031 -032 /* q1 = x / b**(k-1) */ -033 mp_rshd (&q, um - 1); -034 -035 /* according to HAC this optimization is ok */ -036 if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) \{ -037 if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) \{ -038 goto CLEANUP; -039 \} -040 \} else \{ -041 #ifdef BN_S_MP_MUL_HIGH_DIGS_C -042 if ((res = s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) \{ -043 goto CLEANUP; -044 \} -045 #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) -046 if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um - 1)) != MP_OKAY) \{ -047 goto CLEANUP; -048 \} -049 #else -050 \{ -051 res = MP_VAL; -052 goto CLEANUP; -053 \} -054 #endif -055 \} -056 -057 /* q3 = q2 / b**(k+1) */ -058 mp_rshd (&q, um + 1); -059 -060 /* x = x mod b**(k+1), quick (no division) */ -061 if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) \{ -062 goto CLEANUP; -063 \} -064 -065 /* q = q * m mod b**(k+1), quick (no division) */ -066 if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) \{ -067 goto CLEANUP; -068 \} -069 -070 /* x = x - q */ -071 if ((res = mp_sub (x, &q, x)) != MP_OKAY) \{ -072 goto CLEANUP; -073 \} -074 -075 /* If x < 0, add b**(k+1) to it */ -076 if (mp_cmp_d (x, 0) == MP_LT) \{ -077 mp_set (&q, 1); -078 if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) -079 goto CLEANUP; -080 if ((res = mp_add (x, &q, x)) != MP_OKAY) -081 goto CLEANUP; -082 \} -083 -084 /* Back off if it's too big */ -085 while (mp_cmp (x, m) != MP_LT) \{ -086 if ((res = s_mp_sub (x, m, x)) != MP_OKAY) \{ -087 goto CLEANUP; -088 \} -089 \} -090 -091 CLEANUP: -092 mp_clear (&q); -093 -094 return res; -095 \} -096 #endif +021 int mp_reduce (mp_int * x, mp_int * m, mp_int * mu) +022 \{ +023 mp_int q; +024 int res, um = m->used; +025 +026 /* q = x */ +027 if ((res = mp_init_copy (&q, x)) != MP_OKAY) \{ +028 return res; +029 \} +030 +031 /* q1 = x / b**(k-1) */ +032 mp_rshd (&q, um - 1); +033 +034 /* according to HAC this optimization is ok */ +035 if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) \{ +036 if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) \{ +037 goto CLEANUP; +038 \} +039 \} else \{ +040 #ifdef BN_S_MP_MUL_HIGH_DIGS_C +041 if ((res = s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) \{ +042 goto CLEANUP; +043 \} +044 #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) +045 if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) \{ +046 goto CLEANUP; +047 \} +048 #else +049 \{ +050 res = MP_VAL; +051 goto CLEANUP; +052 \} +053 #endif +054 \} +055 +056 /* q3 = q2 / b**(k+1) */ +057 mp_rshd (&q, um + 1); +058 +059 /* x = x mod b**(k+1), quick (no division) */ +060 if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) \{ +061 goto CLEANUP; +062 \} +063 +064 /* q = q * m mod b**(k+1), quick (no division) */ +065 if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) \{ +066 goto CLEANUP; +067 \} +068 +069 /* x = x - q */ +070 if ((res = mp_sub (x, &q, x)) != MP_OKAY) \{ +071 goto CLEANUP; +072 \} +073 +074 /* If x < 0, add b**(k+1) to it */ +075 if (mp_cmp_d (x, 0) == MP_LT) \{ +076 mp_set (&q, 1); +077 if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) +078 goto CLEANUP; +079 if ((res = mp_add (x, &q, x)) != MP_OKAY) +080 goto CLEANUP; +081 \} +082 +083 /* Back off if it's too big */ +084 while (mp_cmp (x, m) != MP_LT) \{ +085 if ((res = s_mp_sub (x, m, x)) != MP_OKAY) \{ +086 goto CLEANUP; +087 \} +088 \} +089 +090 CLEANUP: +091 mp_clear (&q); +092 +093 return res; +094 \} +095 #endif \end{alltt} \end{small} The first multiplication that determines the quotient can be performed by only producing the digits from $m - 1$ and up. This essentially halves the number of single precision multiplications required. However, the optimization is only safe if $\beta$ is much larger than the number of digits -in the modulus. In the source code this is evaluated on lines 36 to 44 where algorithm s\_mp\_mul\_high\_digs is used when it is +in the modulus. In the source code this is evaluated on lines 36 to 43 where algorithm s\_mp\_mul\_high\_digs is used when it is safe to do so. \subsection{The Barrett Setup Algorithm} In order to use algorithm mp\_reduce the value of $\mu$ must be calculated in advance. Ideally this value should be computed once and stored for future use so that the Barrett algorithm can be used without delay. -\begin{figure}[!here] +\newpage\begin{figure}[!here] \begin{small} \begin{center} \begin{tabular}{l} @@ -6314,161 +6335,160 @@ stored in the destination $x$. 022 * 023 * Based on Algorithm 14.32 on pp.601 of HAC. 024 */ -025 int -026 fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) -027 \{ -028 int ix, res, olduse; -029 mp_word W[MP_WARRAY]; -030 -031 /* get old used count */ -032 olduse = x->used; -033 -034 /* grow a as required */ -035 if (x->alloc < n->used + 1) \{ -036 if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) \{ -037 return res; -038 \} -039 \} -040 -041 /* first we have to get the digits of the input into -042 * an array of double precision words W[...] -043 */ -044 \{ -045 register mp_word *_W; -046 register mp_digit *tmpx; -047 -048 /* alias for the W[] array */ -049 _W = W; -050 -051 /* alias for the digits of x*/ -052 tmpx = x->dp; -053 -054 /* copy the digits of a into W[0..a->used-1] */ -055 for (ix = 0; ix < x->used; ix++) \{ -056 *_W++ = *tmpx++; -057 \} -058 -059 /* zero the high words of W[a->used..m->used*2] */ -060 for (; ix < n->used * 2 + 1; ix++) \{ -061 *_W++ = 0; -062 \} -063 \} -064 -065 /* now we proceed to zero successive digits -066 * from the least significant upwards -067 */ -068 for (ix = 0; ix < n->used; ix++) \{ -069 /* mu = ai * m' mod b -070 * -071 * We avoid a double precision multiplication (which isn't required) -072 * by casting the value down to a mp_digit. Note this requires -073 * that W[ix-1] have the carry cleared (see after the inner loop) -074 */ -075 register mp_digit mu; -076 mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); -077 -078 /* a = a + mu * m * b**i -079 * -080 * This is computed in place and on the fly. The multiplication -081 * by b**i is handled by offseting which columns the results -082 * are added to. -083 * -084 * Note the comba method normally doesn't handle carries in the -085 * inner loop In this case we fix the carry from the previous -086 * column since the Montgomery reduction requires digits of the -087 * result (so far) [see above] to work. This is -088 * handled by fixing up one carry after the inner loop. The -089 * carry fixups are done in order so after these loops the -090 * first m->used words of W[] have the carries fixed -091 */ -092 \{ -093 register int iy; -094 register mp_digit *tmpn; -095 register mp_word *_W; -096 -097 /* alias for the digits of the modulus */ -098 tmpn = n->dp; -099 -100 /* Alias for the columns set by an offset of ix */ -101 _W = W + ix; -102 -103 /* inner loop */ -104 for (iy = 0; iy < n->used; iy++) \{ -105 *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); -106 \} -107 \} -108 -109 /* now fix carry for next digit, W[ix+1] */ -110 W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); -111 \} -112 -113 /* now we have to propagate the carries and -114 * shift the words downward [all those least -115 * significant digits we zeroed]. -116 */ -117 \{ -118 register mp_digit *tmpx; -119 register mp_word *_W, *_W1; -120 -121 /* nox fix rest of carries */ -122 -123 /* alias for current word */ -124 _W1 = W + ix; -125 -126 /* alias for next word, where the carry goes */ -127 _W = W + ++ix; -128 -129 for (; ix <= n->used * 2 + 1; ix++) \{ -130 *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); -131 \} -132 -133 /* copy out, A = A/b**n -134 * -135 * The result is A/b**n but instead of converting from an -136 * array of mp_word to mp_digit than calling mp_rshd -137 * we just copy them in the right order -138 */ -139 -140 /* alias for destination word */ -141 tmpx = x->dp; -142 -143 /* alias for shifted double precision result */ -144 _W = W + n->used; -145 -146 for (ix = 0; ix < n->used + 1; ix++) \{ -147 *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); -148 \} -149 -150 /* zero oldused digits, if the input a was larger than -151 * m->used+1 we'll have to clear the digits -152 */ -153 for (; ix < olduse; ix++) \{ -154 *tmpx++ = 0; -155 \} -156 \} -157 -158 /* set the max used and clamp */ -159 x->used = n->used + 1; -160 mp_clamp (x); -161 -162 /* if A >= m then A = A - m */ -163 if (mp_cmp_mag (x, n) != MP_LT) \{ -164 return s_mp_sub (x, n, x); -165 \} -166 return MP_OKAY; -167 \} -168 #endif +025 int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) +026 \{ +027 int ix, res, olduse; +028 mp_word W[MP_WARRAY]; +029 +030 /* get old used count */ +031 olduse = x->used; +032 +033 /* grow a as required */ +034 if (x->alloc < n->used + 1) \{ +035 if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) \{ +036 return res; +037 \} +038 \} +039 +040 /* first we have to get the digits of the input into +041 * an array of double precision words W[...] +042 */ +043 \{ +044 register mp_word *_W; +045 register mp_digit *tmpx; +046 +047 /* alias for the W[] array */ +048 _W = W; +049 +050 /* alias for the digits of x*/ +051 tmpx = x->dp; +052 +053 /* copy the digits of a into W[0..a->used-1] */ +054 for (ix = 0; ix < x->used; ix++) \{ +055 *_W++ = *tmpx++; +056 \} +057 +058 /* zero the high words of W[a->used..m->used*2] */ +059 for (; ix < n->used * 2 + 1; ix++) \{ +060 *_W++ = 0; +061 \} +062 \} +063 +064 /* now we proceed to zero successive digits +065 * from the least significant upwards +066 */ +067 for (ix = 0; ix < n->used; ix++) \{ +068 /* mu = ai * m' mod b +069 * +070 * We avoid a double precision multiplication (which isn't required) +071 * by casting the value down to a mp_digit. Note this requires +072 * that W[ix-1] have the carry cleared (see after the inner loop) +073 */ +074 register mp_digit mu; +075 mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); +076 +077 /* a = a + mu * m * b**i +078 * +079 * This is computed in place and on the fly. The multiplication +080 * by b**i is handled by offseting which columns the results +081 * are added to. +082 * +083 * Note the comba method normally doesn't handle carries in the +084 * inner loop In this case we fix the carry from the previous +085 * column since the Montgomery reduction requires digits of the +086 * result (so far) [see above] to work. This is +087 * handled by fixing up one carry after the inner loop. The +088 * carry fixups are done in order so after these loops the +089 * first m->used words of W[] have the carries fixed +090 */ +091 \{ +092 register int iy; +093 register mp_digit *tmpn; +094 register mp_word *_W; +095 +096 /* alias for the digits of the modulus */ +097 tmpn = n->dp; +098 +099 /* Alias for the columns set by an offset of ix */ +100 _W = W + ix; +101 +102 /* inner loop */ +103 for (iy = 0; iy < n->used; iy++) \{ +104 *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); +105 \} +106 \} +107 +108 /* now fix carry for next digit, W[ix+1] */ +109 W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); +110 \} +111 +112 /* now we have to propagate the carries and +113 * shift the words downward [all those least +114 * significant digits we zeroed]. +115 */ +116 \{ +117 register mp_digit *tmpx; +118 register mp_word *_W, *_W1; +119 +120 /* nox fix rest of carries */ +121 +122 /* alias for current word */ +123 _W1 = W + ix; +124 +125 /* alias for next word, where the carry goes */ +126 _W = W + ++ix; +127 +128 for (; ix <= n->used * 2 + 1; ix++) \{ +129 *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); +130 \} +131 +132 /* copy out, A = A/b**n +133 * +134 * The result is A/b**n but instead of converting from an +135 * array of mp_word to mp_digit than calling mp_rshd +136 * we just copy them in the right order +137 */ +138 +139 /* alias for destination word */ +140 tmpx = x->dp; +141 +142 /* alias for shifted double precision result */ +143 _W = W + n->used; +144 +145 for (ix = 0; ix < n->used + 1; ix++) \{ +146 *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); +147 \} +148 +149 /* zero oldused digits, if the input a was larger than +150 * m->used+1 we'll have to clear the digits +151 */ +152 for (; ix < olduse; ix++) \{ +153 *tmpx++ = 0; +154 \} +155 \} +156 +157 /* set the max used and clamp */ +158 x->used = n->used + 1; +159 mp_clamp (x); +160 +161 /* if A >= m then A = A - m */ +162 if (mp_cmp_mag (x, n) != MP_LT) \{ +163 return s_mp_sub (x, n, x); +164 \} +165 return MP_OKAY; +166 \} +167 #endif \end{alltt} \end{small} -The $\hat W$ array is first filled with digits of $x$ on line 48 then the rest of the digits are zeroed on line 55. Both loops share +The $\hat W$ array is first filled with digits of $x$ on line 50 then the rest of the digits are zeroed on line 54. Both loops share the same alias variables to make the code easier to read. The value of $\mu$ is calculated in an interesting fashion. First the value $\hat W_{ix}$ is reduced modulo $\beta$ and cast to a mp\_digit. This -forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line 110 fixes the carry +forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line 109 fixes the carry for the next iteration of the loop by propagating the carry from $\hat W_{ix}$ to $\hat W_{ix+1}$. -The for loop on line 109 propagates the rest of the carries upwards through the columns. The for loop on line 126 reduces the columns +The for loop on line 108 propagates the rest of the carries upwards through the columns. The for loop on line 125 reduces the columns modulo $\beta$ and shifts them $k$ places at the same time. The alias $\_ \hat W$ actually refers to the array $\hat W$ starting at the $n.used$'th digit, that is $\_ \hat W_{t} = \hat W_{n.used + t}$. @@ -6968,51 +6988,50 @@ shift which makes the algorithm fairly inexpensive to use. \begin{alltt} 016 017 /* reduces a modulo n where n is of the form 2**p - d */ -018 int -019 mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) -020 \{ -021 mp_int q; -022 int p, res; -023 -024 if ((res = mp_init(&q)) != MP_OKAY) \{ -025 return res; -026 \} -027 -028 p = mp_count_bits(n); -029 top: -030 /* q = a/2**p, a = a mod 2**p */ -031 if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) \{ -032 goto ERR; -033 \} -034 -035 if (d != 1) \{ -036 /* q = q * d */ -037 if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) \{ -038 goto ERR; -039 \} -040 \} -041 -042 /* a = a + q */ -043 if ((res = s_mp_add(a, &q, a)) != MP_OKAY) \{ -044 goto ERR; -045 \} -046 -047 if (mp_cmp_mag(a, n) != MP_LT) \{ -048 s_mp_sub(a, n, a); -049 goto top; -050 \} -051 -052 ERR: -053 mp_clear(&q); -054 return res; -055 \} -056 -057 #endif +018 int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) +019 \{ +020 mp_int q; +021 int p, res; +022 +023 if ((res = mp_init(&q)) != MP_OKAY) \{ +024 return res; +025 \} +026 +027 p = mp_count_bits(n); +028 top: +029 /* q = a/2**p, a = a mod 2**p */ +030 if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) \{ +031 goto ERR; +032 \} +033 +034 if (d != 1) \{ +035 /* q = q * d */ +036 if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) \{ +037 goto ERR; +038 \} +039 \} +040 +041 /* a = a + q */ +042 if ((res = s_mp_add(a, &q, a)) != MP_OKAY) \{ +043 goto ERR; +044 \} +045 +046 if (mp_cmp_mag(a, n) != MP_LT) \{ +047 s_mp_sub(a, n, a); +048 goto top; +049 \} +050 +051 ERR: +052 mp_clear(&q); +053 return res; +054 \} +055 +056 #endif \end{alltt} \end{small} The algorithm mp\_count\_bits calculates the number of bits in an mp\_int which is used to find the initial value of $p$. The call to mp\_div\_2d -on line 31 calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size +on line 30 calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size is kept fairly small. The multiplication by $k$ is only performed if $k > 1$. This allows reductions modulo $2^p - 1$ to be performed without any multiplications. @@ -7052,32 +7071,31 @@ is sufficient to solve for $k$. Alternatively if $n$ has more than one digit th \begin{alltt} 016 017 /* determines the setup value */ -018 int -019 mp_reduce_2k_setup(mp_int *a, mp_digit *d) -020 \{ -021 int res, p; -022 mp_int tmp; -023 -024 if ((res = mp_init(&tmp)) != MP_OKAY) \{ -025 return res; -026 \} -027 -028 p = mp_count_bits(a); -029 if ((res = mp_2expt(&tmp, p)) != MP_OKAY) \{ -030 mp_clear(&tmp); -031 return res; -032 \} -033 -034 if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) \{ -035 mp_clear(&tmp); -036 return res; -037 \} -038 -039 *d = tmp.dp[0]; -040 mp_clear(&tmp); -041 return MP_OKAY; -042 \} -043 #endif +018 int mp_reduce_2k_setup(mp_int *a, mp_digit *d) +019 \{ +020 int res, p; +021 mp_int tmp; +022 +023 if ((res = mp_init(&tmp)) != MP_OKAY) \{ +024 return res; +025 \} +026 +027 p = mp_count_bits(a); +028 if ((res = mp_2expt(&tmp, p)) != MP_OKAY) \{ +029 mp_clear(&tmp); +030 return res; +031 \} +032 +033 if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) \{ +034 mp_clear(&tmp); +035 return res; +036 \} +037 +038 *d = tmp.dp[0]; +039 mp_clear(&tmp); +040 return MP_OKAY; +041 \} +042 #endif \end{alltt} \end{small} @@ -7130,9 +7148,9 @@ This algorithm quickly determines if a modulus is of the form required for algor 021 mp_digit iz; 022 023 if (a->used == 0) \{ -024 return 0; +024 return MP_NO; 025 \} else if (a->used == 1) \{ -026 return 1; +026 return MP_YES; 027 \} else if (a->used > 1) \{ 028 iy = mp_count_bits(a); 029 iz = 1; @@ -7141,7 +7159,7 @@ This algorithm quickly determines if a modulus is of the form required for algor 032 /* Test every bit from the second digit up, must be 1 */ 033 for (ix = DIGIT_BIT; ix < iy; ix++) \{ 034 if ((a->dp[iw] & iz) == 0) \{ -035 return 0; +035 return MP_NO; 036 \} 037 iz <<= 1; 038 if (iz > (mp_digit)MP_MASK) \{ @@ -7150,7 +7168,7 @@ This algorithm quickly determines if a modulus is of the form required for algor 041 \} 042 \} 043 \} -044 return 1; +044 return MP_YES; 045 \} 046 047 #endif @@ -7601,39 +7619,47 @@ algorithm since their arguments are essentially the same (\textit{two mp\_ints a 064 #endif 065 \} 066 -067 #ifdef BN_MP_DR_IS_MODULUS_C -068 /* is it a DR modulus? */ -069 dr = mp_dr_is_modulus(P); -070 #else -071 dr = 0; +067 /* modified diminished radix reduction */ +068 #if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) +069 if (mp_reduce_is_2k_l(P) == MP_YES) \{ +070 return s_mp_exptmod(G, X, P, Y, 1); +071 \} 072 #endif 073 -074 #ifdef BN_MP_REDUCE_IS_2K_C -075 /* if not, is it a uDR modulus? */ -076 if (dr == 0) \{ -077 dr = mp_reduce_is_2k(P) << 1; -078 \} -079 #endif -080 -081 /* if the modulus is odd or dr != 0 use the fast method */ -082 #ifdef BN_MP_EXPTMOD_FAST_C -083 if (mp_isodd (P) == 1 || dr != 0) \{ -084 return mp_exptmod_fast (G, X, P, Y, dr); -085 \} else \{ -086 #endif -087 #ifdef BN_S_MP_EXPTMOD_C -088 /* otherwise use the generic Barrett reduction technique */ -089 return s_mp_exptmod (G, X, P, Y); -090 #else -091 /* no exptmod for evens */ -092 return MP_VAL; -093 #endif -094 #ifdef BN_MP_EXPTMOD_FAST_C -095 \} -096 #endif -097 \} -098 -099 #endif +074 #ifdef BN_MP_DR_IS_MODULUS_C +075 /* is it a DR modulus? */ +076 dr = mp_dr_is_modulus(P); +077 #else +078 /* default to no */ +079 dr = 0; +080 #endif +081 +082 #ifdef BN_MP_REDUCE_IS_2K_C +083 /* if not, is it a unrestricted DR modulus? */ +084 if (dr == 0) \{ +085 dr = mp_reduce_is_2k(P) << 1; +086 \} +087 #endif +088 +089 /* if the modulus is odd or dr != 0 use the montgomery method */ +090 #ifdef BN_MP_EXPTMOD_FAST_C +091 if (mp_isodd (P) == 1 || dr != 0) \{ +092 return mp_exptmod_fast (G, X, P, Y, dr); +093 \} else \{ +094 #endif +095 #ifdef BN_S_MP_EXPTMOD_C +096 /* otherwise use the generic Barrett reduction technique */ +097 return s_mp_exptmod (G, X, P, Y, 0); +098 #else +099 /* no exptmod for evens */ +100 return MP_VAL; +101 #endif +102 #ifdef BN_MP_EXPTMOD_FAST_C +103 \} +104 #endif +105 \} +106 +107 #endif \end{alltt} \end{small} @@ -7642,8 +7668,8 @@ negative the algorithm tries to perform a modular exponentiation with the modula the modular inverse of $G$ and $tmpX$ is assigned the absolute value of $X$. The algorithm will recuse with these new values with a positive exponent. -If the exponent is positive the algorithm resumes the exponentiation. Line 69 determines if the modulus is of the restricted Diminished Radix -form. If it is not line 77 attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one +If the exponent is positive the algorithm resumes the exponentiation. Line 76 determines if the modulus is of the restricted Diminished Radix +form. If it is not line 69 attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one of three values. \begin{enumerate} @@ -7652,7 +7678,7 @@ of three values. \item $dr = 2$ means that the modulus is of unrestricted Diminished Radix form. \end{enumerate} -Line 67 determines if the fast modular exponentiation algorithm can be used. It is allowed if $dr \ne 0$ or if the modulus is odd. Otherwise, +Line 69 determines if the fast modular exponentiation algorithm can be used. It is allowed if $dr \ne 0$ or if the modulus is odd. Otherwise, the slower s\_mp\_exptmod algorithm is used which uses Barrett reduction. \subsection{Barrett Modular Exponentiation} @@ -7820,230 +7846,244 @@ a Left-to-Right algorithm is used to process the remaining few bits. 020 #define TAB_SIZE 256 021 #endif 022 -023 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) +023 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmod + e) 024 \{ 025 mp_int M[TAB_SIZE], res, mu; 026 mp_digit buf; 027 int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; -028 -029 /* find window size */ -030 x = mp_count_bits (X); -031 if (x <= 7) \{ -032 winsize = 2; -033 \} else if (x <= 36) \{ -034 winsize = 3; -035 \} else if (x <= 140) \{ -036 winsize = 4; -037 \} else if (x <= 450) \{ -038 winsize = 5; -039 \} else if (x <= 1303) \{ -040 winsize = 6; -041 \} else if (x <= 3529) \{ -042 winsize = 7; -043 \} else \{ -044 winsize = 8; -045 \} -046 -047 #ifdef MP_LOW_MEM -048 if (winsize > 5) \{ -049 winsize = 5; -050 \} -051 #endif -052 -053 /* init M array */ -054 /* init first cell */ -055 if ((err = mp_init(&M[1])) != MP_OKAY) \{ -056 return err; -057 \} -058 -059 /* now init the second half of the array */ -060 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -061 if ((err = mp_init(&M[x])) != MP_OKAY) \{ -062 for (y = 1<<(winsize-1); y < x; y++) \{ -063 mp_clear (&M[y]); -064 \} -065 mp_clear(&M[1]); -066 return err; -067 \} -068 \} -069 -070 /* create mu, used for Barrett reduction */ -071 if ((err = mp_init (&mu)) != MP_OKAY) \{ -072 goto LBL_M; -073 \} -074 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ -075 goto LBL_MU; -076 \} -077 -078 /* create M table -079 * -080 * The M table contains powers of the base, -081 * e.g. M[x] = G**x mod P -082 * -083 * The first half of the table is not -084 * computed though accept for M[0] and M[1] -085 */ -086 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ -087 goto LBL_MU; -088 \} -089 -090 /* compute the value at M[1<<(winsize-1)] by squaring -091 * M[1] (winsize-1) times -092 */ -093 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ -094 goto LBL_MU; -095 \} -096 -097 for (x = 0; x < (winsize - 1); x++) \{ -098 if ((err = mp_sqr (&M[1 << (winsize - 1)], -099 &M[1 << (winsize - 1)])) != MP_OKAY) \{ -100 goto LBL_MU; -101 \} -102 if ((err = mp_reduce (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ -103 goto LBL_MU; -104 \} +028 int (*redux)(mp_int*,mp_int*,mp_int*); +029 +030 /* find window size */ +031 x = mp_count_bits (X); +032 if (x <= 7) \{ +033 winsize = 2; +034 \} else if (x <= 36) \{ +035 winsize = 3; +036 \} else if (x <= 140) \{ +037 winsize = 4; +038 \} else if (x <= 450) \{ +039 winsize = 5; +040 \} else if (x <= 1303) \{ +041 winsize = 6; +042 \} else if (x <= 3529) \{ +043 winsize = 7; +044 \} else \{ +045 winsize = 8; +046 \} +047 +048 #ifdef MP_LOW_MEM +049 if (winsize > 5) \{ +050 winsize = 5; +051 \} +052 #endif +053 +054 /* init M array */ +055 /* init first cell */ +056 if ((err = mp_init(&M[1])) != MP_OKAY) \{ +057 return err; +058 \} +059 +060 /* now init the second half of the array */ +061 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +062 if ((err = mp_init(&M[x])) != MP_OKAY) \{ +063 for (y = 1<<(winsize-1); y < x; y++) \{ +064 mp_clear (&M[y]); +065 \} +066 mp_clear(&M[1]); +067 return err; +068 \} +069 \} +070 +071 /* create mu, used for Barrett reduction */ +072 if ((err = mp_init (&mu)) != MP_OKAY) \{ +073 goto LBL_M; +074 \} +075 +076 if (redmode == 0) \{ +077 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ +078 goto LBL_MU; +079 \} +080 redux = mp_reduce; +081 \} else \{ +082 if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) \{ +083 goto LBL_MU; +084 \} +085 redux = mp_reduce_2k_l; +086 \} +087 +088 /* create M table +089 * +090 * The M table contains powers of the base, +091 * e.g. M[x] = G**x mod P +092 * +093 * The first half of the table is not +094 * computed though accept for M[0] and M[1] +095 */ +096 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ +097 goto LBL_MU; +098 \} +099 +100 /* compute the value at M[1<<(winsize-1)] by squaring +101 * M[1] (winsize-1) times +102 */ +103 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ +104 goto LBL_MU; 105 \} 106 -107 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) -108 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) -109 */ -110 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ -111 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ -112 goto LBL_MU; -113 \} -114 if ((err = mp_reduce (&M[x], P, &mu)) != MP_OKAY) \{ -115 goto LBL_MU; -116 \} -117 \} -118 -119 /* setup result */ -120 if ((err = mp_init (&res)) != MP_OKAY) \{ -121 goto LBL_MU; -122 \} -123 mp_set (&res, 1); -124 -125 /* set initial mode and bit cnt */ -126 mode = 0; -127 bitcnt = 1; -128 buf = 0; -129 digidx = X->used - 1; -130 bitcpy = 0; -131 bitbuf = 0; -132 -133 for (;;) \{ -134 /* grab next digit as required */ -135 if (--bitcnt == 0) \{ -136 /* if digidx == -1 we are out of digits */ -137 if (digidx == -1) \{ -138 break; -139 \} -140 /* read next digit and reset the bitcnt */ -141 buf = X->dp[digidx--]; -142 bitcnt = (int) DIGIT_BIT; -143 \} -144 -145 /* grab the next msb from the exponent */ -146 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; -147 buf <<= (mp_digit)1; -148 -149 /* if the bit is zero and mode == 0 then we ignore it -150 * These represent the leading zero bits before the first 1 bit -151 * in the exponent. Technically this opt is not required but it -152 * does lower the # of trivial squaring/reductions used -153 */ -154 if (mode == 0 && y == 0) \{ -155 continue; +107 for (x = 0; x < (winsize - 1); x++) \{ +108 /* square it */ +109 if ((err = mp_sqr (&M[1 << (winsize - 1)], +110 &M[1 << (winsize - 1)])) != MP_OKAY) \{ +111 goto LBL_MU; +112 \} +113 +114 /* reduce modulo P */ +115 if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ +116 goto LBL_MU; +117 \} +118 \} +119 +120 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) +121 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) +122 */ +123 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ +124 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ +125 goto LBL_MU; +126 \} +127 if ((err = redux (&M[x], P, &mu)) != MP_OKAY) \{ +128 goto LBL_MU; +129 \} +130 \} +131 +132 /* setup result */ +133 if ((err = mp_init (&res)) != MP_OKAY) \{ +134 goto LBL_MU; +135 \} +136 mp_set (&res, 1); +137 +138 /* set initial mode and bit cnt */ +139 mode = 0; +140 bitcnt = 1; +141 buf = 0; +142 digidx = X->used - 1; +143 bitcpy = 0; +144 bitbuf = 0; +145 +146 for (;;) \{ +147 /* grab next digit as required */ +148 if (--bitcnt == 0) \{ +149 /* if digidx == -1 we are out of digits */ +150 if (digidx == -1) \{ +151 break; +152 \} +153 /* read next digit and reset the bitcnt */ +154 buf = X->dp[digidx--]; +155 bitcnt = (int) DIGIT_BIT; 156 \} 157 -158 /* if the bit is zero and mode == 1 then we square */ -159 if (mode == 1 && y == 0) \{ -160 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -161 goto LBL_RES; -162 \} -163 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ -164 goto LBL_RES; -165 \} -166 continue; -167 \} -168 -169 /* else we add it to the window */ -170 bitbuf |= (y << (winsize - ++bitcpy)); -171 mode = 2; -172 -173 if (bitcpy == winsize) \{ -174 /* ok window is filled so square as required and multiply */ -175 /* square first */ -176 for (x = 0; x < winsize; x++) \{ -177 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -178 goto LBL_RES; -179 \} -180 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ -181 goto LBL_RES; -182 \} -183 \} -184 -185 /* then multiply */ -186 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ -187 goto LBL_RES; -188 \} -189 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ -190 goto LBL_RES; -191 \} -192 -193 /* empty window and reset */ -194 bitcpy = 0; -195 bitbuf = 0; -196 mode = 1; -197 \} -198 \} -199 -200 /* if bits remain then square/multiply */ -201 if (mode == 2 && bitcpy > 0) \{ -202 /* square then multiply if the bit is set */ -203 for (x = 0; x < bitcpy; x++) \{ -204 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -205 goto LBL_RES; -206 \} -207 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ -208 goto LBL_RES; -209 \} -210 -211 bitbuf <<= 1; -212 if ((bitbuf & (1 << winsize)) != 0) \{ -213 /* then multiply */ -214 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ -215 goto LBL_RES; -216 \} -217 if ((err = mp_reduce (&res, P, &mu)) != MP_OKAY) \{ -218 goto LBL_RES; -219 \} -220 \} -221 \} -222 \} +158 /* grab the next msb from the exponent */ +159 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; +160 buf <<= (mp_digit)1; +161 +162 /* if the bit is zero and mode == 0 then we ignore it +163 * These represent the leading zero bits before the first 1 bit +164 * in the exponent. Technically this opt is not required but it +165 * does lower the # of trivial squaring/reductions used +166 */ +167 if (mode == 0 && y == 0) \{ +168 continue; +169 \} +170 +171 /* if the bit is zero and mode == 1 then we square */ +172 if (mode == 1 && y == 0) \{ +173 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +174 goto LBL_RES; +175 \} +176 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +177 goto LBL_RES; +178 \} +179 continue; +180 \} +181 +182 /* else we add it to the window */ +183 bitbuf |= (y << (winsize - ++bitcpy)); +184 mode = 2; +185 +186 if (bitcpy == winsize) \{ +187 /* ok window is filled so square as required and multiply */ +188 /* square first */ +189 for (x = 0; x < winsize; x++) \{ +190 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +191 goto LBL_RES; +192 \} +193 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +194 goto LBL_RES; +195 \} +196 \} +197 +198 /* then multiply */ +199 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ +200 goto LBL_RES; +201 \} +202 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +203 goto LBL_RES; +204 \} +205 +206 /* empty window and reset */ +207 bitcpy = 0; +208 bitbuf = 0; +209 mode = 1; +210 \} +211 \} +212 +213 /* if bits remain then square/multiply */ +214 if (mode == 2 && bitcpy > 0) \{ +215 /* square then multiply if the bit is set */ +216 for (x = 0; x < bitcpy; x++) \{ +217 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +218 goto LBL_RES; +219 \} +220 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +221 goto LBL_RES; +222 \} 223 -224 mp_exch (&res, Y); -225 err = MP_OKAY; -226 LBL_RES:mp_clear (&res); -227 LBL_MU:mp_clear (&mu); -228 LBL_M: -229 mp_clear(&M[1]); -230 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -231 mp_clear (&M[x]); -232 \} -233 return err; -234 \} -235 #endif +224 bitbuf <<= 1; +225 if ((bitbuf & (1 << winsize)) != 0) \{ +226 /* then multiply */ +227 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ +228 goto LBL_RES; +229 \} +230 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +231 goto LBL_RES; +232 \} +233 \} +234 \} +235 \} +236 +237 mp_exch (&res, Y); +238 err = MP_OKAY; +239 LBL_RES:mp_clear (&res); +240 LBL_MU:mp_clear (&mu); +241 LBL_M: +242 mp_clear(&M[1]); +243 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +244 mp_clear (&M[x]); +245 \} +246 return err; +247 \} +248 #endif \end{alltt} \end{small} -Lines 31 through 41 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +Lines 21 through 40 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement -on line 33 the value of $x$ is already known to be greater than $140$. +on line 32 the value of $x$ is already known to be greater than $140$. -The conditional piece of code beginning on line 47 allows the window size to be restricted to five bits. This logic is used to ensure +The conditional piece of code beginning on line 48 allows the window size to be restricted to five bits. This logic is used to ensure the table of precomputed powers of $G$ remains relatively small. -The for loop on line 60 initializes the $M$ array while lines 61 and 74 compute the value of $\mu$ required for +The for loop on line 61 initializes the $M$ array while lines 62 and 77 compute the value of $\mu$ required for Barrett reduction. -- More later. @@ -8873,21 +8913,22 @@ Unlike the full multiplication algorithms this algorithm does not require any si 056 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); 057 \} 058 -059 /* store final carry [if any] */ +059 /* store final carry [if any] and increment ix offset */ 060 *tmpc++ = u; -061 -062 /* now zero digits above the top */ -063 while (ix++ < olduse) \{ -064 *tmpc++ = 0; -065 \} -066 -067 /* set used count */ -068 c->used = a->used + 1; -069 mp_clamp(c); -070 -071 return MP_OKAY; -072 \} -073 #endif +061 ++ix; +062 +063 /* now zero digits above the top */ +064 while (ix++ < olduse) \{ +065 *tmpc++ = 0; +066 \} +067 +068 /* set used count */ +069 c->used = a->used + 1; +070 mp_clamp(c); +071 +072 return MP_OKAY; +073 \} +074 #endif \end{alltt} \end{small} @@ -9275,14 +9316,14 @@ the integers from $0$ to $\beta - 1$. 028 029 /* first place a random non-zero digit */ 030 do \{ -031 d = ((mp_digit) abs (rand ())); +031 d = ((mp_digit) abs (rand ())) & MP_MASK; 032 \} while (d == 0); 033 034 if ((res = mp_add_d (a, d, a)) != MP_OKAY) \{ 035 return res; 036 \} 037 -038 while (digits-- > 0) \{ +038 while (--digits > 0) \{ 039 if ((res = mp_lshd (a, 1)) != MP_OKAY) \{ 040 return res; 041 \} @@ -9379,7 +9420,7 @@ as part of larger input without any significant problem. \begin{alltt} 016 017 /* read a string [ASCII] in a given radix */ -018 int mp_read_radix (mp_int * a, char *str, int radix) +018 int mp_read_radix (mp_int * a, const char *str, int radix) 019 \{ 020 int y, res, neg; 021 char ch; @@ -9941,6 +9982,8 @@ To explain the Jacobi Symbol we shall first discuss the Legendre function\footno defined. The Legendre function computes whether or not an integer $a$ is a quadratic residue modulo an odd prime $p$. Numerically it is equivalent to equation \ref{eqn:legendre}. +\textit{-- Tom, don't be an ass, cite your source here...!} + \begin{equation} a^{(p-1)/2} \equiv \begin{array}{rl} -1 & \mbox{if }a\mbox{ is a quadratic non-residue.} \\ diff --git a/libtommath/tommath_class.h b/libtommath/tommath_class.h index 53bfa31..6d05b7b 100644 --- a/libtommath/tommath_class.h +++ b/libtommath/tommath_class.h @@ -90,8 +90,11 @@ #define BN_MP_READ_UNSIGNED_BIN_C #define BN_MP_REDUCE_C #define BN_MP_REDUCE_2K_C +#define BN_MP_REDUCE_2K_L_C #define BN_MP_REDUCE_2K_SETUP_C +#define BN_MP_REDUCE_2K_SETUP_L_C #define BN_MP_REDUCE_IS_2K_C +#define BN_MP_REDUCE_IS_2K_L_C #define BN_MP_REDUCE_SETUP_C #define BN_MP_RSHD_C #define BN_MP_SET_C @@ -105,7 +108,9 @@ #define BN_MP_SUB_D_C #define BN_MP_SUBMOD_C #define BN_MP_TO_SIGNED_BIN_C +#define BN_MP_TO_SIGNED_BIN_N_C #define BN_MP_TO_UNSIGNED_BIN_C +#define BN_MP_TO_UNSIGNED_BIN_N_C #define BN_MP_TOOM_MUL_C #define BN_MP_TOOM_SQR_C #define BN_MP_TORADIX_C @@ -132,7 +137,7 @@ #define BN_MP_ISEVEN_C #define BN_MP_INIT_MULTI_C #define BN_MP_COPY_C - #define BN_MP_ABS_C + #define BN_MP_MOD_C #define BN_MP_SET_C #define BN_MP_DIV_2_C #define BN_MP_ISODD_C @@ -324,11 +329,12 @@ #define BN_MP_CLEAR_C #define BN_MP_ABS_C #define BN_MP_CLEAR_MULTI_C + #define BN_MP_REDUCE_IS_2K_L_C + #define BN_S_MP_EXPTMOD_C #define BN_MP_DR_IS_MODULUS_C #define BN_MP_REDUCE_IS_2K_C #define BN_MP_ISODD_C #define BN_MP_EXPTMOD_FAST_C - #define BN_S_MP_EXPTMOD_C #endif #if defined(BN_MP_EXPTMOD_FAST_C) @@ -360,6 +366,7 @@ #define BN_MP_DIV_C #define BN_MP_MUL_C #define BN_MP_SUB_C + #define BN_MP_NEG_C #define BN_MP_EXCH_C #define BN_MP_CLEAR_MULTI_C #endif @@ -434,6 +441,7 @@ #if defined(BN_MP_INVMOD_SLOW_C) #define BN_MP_ISZERO_C #define BN_MP_INIT_MULTI_C + #define BN_MP_MOD_C #define BN_MP_COPY_C #define BN_MP_ISEVEN_C #define BN_MP_SET_C @@ -725,6 +733,17 @@ #define BN_MP_CLEAR_C #endif +#if defined(BN_MP_REDUCE_2K_L_C) + #define BN_MP_INIT_C + #define BN_MP_COUNT_BITS_C + #define BN_MP_DIV_2D_C + #define BN_MP_MUL_C + #define BN_S_MP_ADD_C + #define BN_MP_CMP_MAG_C + #define BN_S_MP_SUB_C + #define BN_MP_CLEAR_C +#endif + #if defined(BN_MP_REDUCE_2K_SETUP_C) #define BN_MP_INIT_C #define BN_MP_COUNT_BITS_C @@ -733,11 +752,22 @@ #define BN_S_MP_SUB_C #endif +#if defined(BN_MP_REDUCE_2K_SETUP_L_C) + #define BN_MP_INIT_C + #define BN_MP_2EXPT_C + #define BN_MP_COUNT_BITS_C + #define BN_S_MP_SUB_C + #define BN_MP_CLEAR_C +#endif + #if defined(BN_MP_REDUCE_IS_2K_C) #define BN_MP_REDUCE_2K_C #define BN_MP_COUNT_BITS_C #endif +#if defined(BN_MP_REDUCE_IS_2K_L_C) +#endif + #if defined(BN_MP_REDUCE_SETUP_C) #define BN_MP_2EXPT_C #define BN_MP_DIV_C @@ -815,6 +845,11 @@ #define BN_MP_TO_UNSIGNED_BIN_C #endif +#if defined(BN_MP_TO_SIGNED_BIN_N_C) + #define BN_MP_SIGNED_BIN_SIZE_C + #define BN_MP_TO_SIGNED_BIN_C +#endif + #if defined(BN_MP_TO_UNSIGNED_BIN_C) #define BN_MP_INIT_COPY_C #define BN_MP_ISZERO_C @@ -822,6 +857,11 @@ #define BN_MP_CLEAR_C #endif +#if defined(BN_MP_TO_UNSIGNED_BIN_N_C) + #define BN_MP_UNSIGNED_BIN_SIZE_C + #define BN_MP_TO_UNSIGNED_BIN_C +#endif + #if defined(BN_MP_TOOM_MUL_C) #define BN_MP_INIT_MULTI_C #define BN_MP_MOD_2D_C @@ -902,10 +942,12 @@ #define BN_MP_INIT_C #define BN_MP_CLEAR_C #define BN_MP_REDUCE_SETUP_C + #define BN_MP_REDUCE_C + #define BN_MP_REDUCE_2K_SETUP_L_C + #define BN_MP_REDUCE_2K_L_C #define BN_MP_MOD_C #define BN_MP_COPY_C #define BN_MP_SQR_C - #define BN_MP_REDUCE_C #define BN_MP_MUL_C #define BN_MP_SET_C #define BN_MP_EXCH_C -- cgit v0.12 From 36537913f69228c5a11335a42637feba36c96677 Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Mon, 26 Sep 2005 16:31:55 +0000 Subject: Import of libtommath 0.36 --- libtommath/bn.pdf | Bin 337204 -> 340684 bytes libtommath/bn.tex | 2 +- libtommath/bn_error.c | 4 + libtommath/bn_fast_mp_invmod.c | 4 + libtommath/bn_fast_mp_montgomery_reduce.c | 4 + libtommath/bn_fast_s_mp_mul_digs.c | 5 + libtommath/bn_fast_s_mp_mul_high_digs.c | 4 + libtommath/bn_fast_s_mp_sqr.c | 4 + libtommath/bn_mp_2expt.c | 4 + libtommath/bn_mp_abs.c | 4 + libtommath/bn_mp_add.c | 4 + libtommath/bn_mp_add_d.c | 4 + libtommath/bn_mp_addmod.c | 4 + libtommath/bn_mp_and.c | 4 + libtommath/bn_mp_clamp.c | 4 + libtommath/bn_mp_clear.c | 4 + libtommath/bn_mp_clear_multi.c | 4 + libtommath/bn_mp_cmp.c | 4 + libtommath/bn_mp_cmp_d.c | 4 + libtommath/bn_mp_cmp_mag.c | 4 + libtommath/bn_mp_cnt_lsb.c | 4 + libtommath/bn_mp_copy.c | 4 + libtommath/bn_mp_count_bits.c | 4 + libtommath/bn_mp_div.c | 4 + libtommath/bn_mp_div_2.c | 4 + libtommath/bn_mp_div_2d.c | 4 + libtommath/bn_mp_div_3.c | 4 + libtommath/bn_mp_div_d.c | 4 + libtommath/bn_mp_dr_is_modulus.c | 4 + libtommath/bn_mp_dr_reduce.c | 4 + libtommath/bn_mp_dr_setup.c | 4 + libtommath/bn_mp_exch.c | 4 + libtommath/bn_mp_expt_d.c | 4 + libtommath/bn_mp_exptmod.c | 6 +- libtommath/bn_mp_exptmod_fast.c | 4 + libtommath/bn_mp_exteuclid.c | 4 + libtommath/bn_mp_fread.c | 4 + libtommath/bn_mp_fwrite.c | 4 + libtommath/bn_mp_gcd.c | 4 + libtommath/bn_mp_get_int.c | 4 + libtommath/bn_mp_grow.c | 4 + libtommath/bn_mp_init.c | 4 + libtommath/bn_mp_init_copy.c | 4 + libtommath/bn_mp_init_multi.c | 4 + libtommath/bn_mp_init_set.c | 4 + libtommath/bn_mp_init_set_int.c | 4 + libtommath/bn_mp_init_size.c | 4 + libtommath/bn_mp_invmod.c | 4 + libtommath/bn_mp_invmod_slow.c | 4 + libtommath/bn_mp_is_square.c | 4 + libtommath/bn_mp_jacobi.c | 4 + libtommath/bn_mp_karatsuba_mul.c | 20 +- libtommath/bn_mp_karatsuba_sqr.c | 12 +- libtommath/bn_mp_lcm.c | 4 + libtommath/bn_mp_lshd.c | 4 + libtommath/bn_mp_mod.c | 4 + libtommath/bn_mp_mod_2d.c | 4 + libtommath/bn_mp_mod_d.c | 4 + libtommath/bn_mp_montgomery_calc_normalization.c | 4 + libtommath/bn_mp_montgomery_reduce.c | 4 + libtommath/bn_mp_montgomery_setup.c | 4 + libtommath/bn_mp_mul.c | 4 + libtommath/bn_mp_mul_2.c | 4 + libtommath/bn_mp_mul_2d.c | 4 + libtommath/bn_mp_mul_d.c | 4 + libtommath/bn_mp_mulmod.c | 7 +- libtommath/bn_mp_n_root.c | 4 + libtommath/bn_mp_neg.c | 4 + libtommath/bn_mp_or.c | 4 + libtommath/bn_mp_prime_fermat.c | 4 + libtommath/bn_mp_prime_is_divisible.c | 4 + libtommath/bn_mp_prime_is_prime.c | 4 + libtommath/bn_mp_prime_miller_rabin.c | 4 + libtommath/bn_mp_prime_next_prime.c | 4 + libtommath/bn_mp_prime_rabin_miller_trials.c | 4 + libtommath/bn_mp_prime_random_ex.c | 10 +- libtommath/bn_mp_radix_size.c | 4 + libtommath/bn_mp_radix_smap.c | 4 + libtommath/bn_mp_rand.c | 4 + libtommath/bn_mp_read_radix.c | 4 + libtommath/bn_mp_read_signed_bin.c | 7 +- libtommath/bn_mp_read_unsigned_bin.c | 7 +- libtommath/bn_mp_reduce.c | 4 + libtommath/bn_mp_reduce_2k.c | 4 + libtommath/bn_mp_reduce_2k_l.c | 4 + libtommath/bn_mp_reduce_2k_setup.c | 4 + libtommath/bn_mp_reduce_2k_setup_l.c | 4 + libtommath/bn_mp_reduce_is_2k.c | 4 + libtommath/bn_mp_reduce_is_2k_l.c | 4 + libtommath/bn_mp_reduce_setup.c | 4 + libtommath/bn_mp_rshd.c | 4 + libtommath/bn_mp_set.c | 4 + libtommath/bn_mp_set_int.c | 4 + libtommath/bn_mp_shrink.c | 4 + libtommath/bn_mp_signed_bin_size.c | 4 + libtommath/bn_mp_sqr.c | 4 + libtommath/bn_mp_sqrmod.c | 4 + libtommath/bn_mp_sqrt.c | 4 + libtommath/bn_mp_sub.c | 4 + libtommath/bn_mp_sub_d.c | 4 + libtommath/bn_mp_submod.c | 4 + libtommath/bn_mp_to_signed_bin.c | 4 + libtommath/bn_mp_to_signed_bin_n.c | 4 + libtommath/bn_mp_to_unsigned_bin.c | 4 + libtommath/bn_mp_to_unsigned_bin_n.c | 4 + libtommath/bn_mp_toom_mul.c | 4 + libtommath/bn_mp_toom_sqr.c | 4 + libtommath/bn_mp_toradix.c | 4 + libtommath/bn_mp_toradix_n.c | 4 + libtommath/bn_mp_unsigned_bin_size.c | 4 + libtommath/bn_mp_xor.c | 4 + libtommath/bn_mp_zero.c | 4 + libtommath/bn_prime_tab.c | 4 + libtommath/bn_reverse.c | 4 + libtommath/bn_s_mp_add.c | 4 + libtommath/bn_s_mp_exptmod.c | 5 +- libtommath/bn_s_mp_mul_digs.c | 4 + libtommath/bn_s_mp_mul_high_digs.c | 4 + libtommath/bn_s_mp_sqr.c | 4 + libtommath/bn_s_mp_sub.c | 4 + libtommath/bncore.c | 10 +- libtommath/booker.pl | 3 + libtommath/changes.txt | 12 + libtommath/demo/demo.c | 8 +- libtommath/demo/timing.c | 4 + libtommath/etc/2kprime.c | 4 + libtommath/etc/drprime.c | 4 + libtommath/etc/makefile.icc | 2 +- libtommath/etc/mersenne.c | 4 + libtommath/etc/mont.c | 4 + libtommath/etc/pprime.c | 4 + libtommath/etc/tune.c | 4 + libtommath/logs/expt.log | 14 +- libtommath/logs/expt_2k.log | 10 +- libtommath/logs/expt_2kl.log | 8 +- libtommath/logs/expt_dr.log | 14 +- libtommath/logs/index.html | 5 +- libtommath/makefile | 51 +- libtommath/makefile.cygwin_dll | 4 + libtommath/makefile.icc | 2 +- libtommath/makefile.msvc | 4 +- libtommath/makefile.shared | 47 +- libtommath/mtest/logtab.h | 4 + libtommath/mtest/mpi-config.h | 6 +- libtommath/mtest/mpi-types.h | 4 + libtommath/mtest/mpi.c | 6 +- libtommath/mtest/mpi.h | 6 +- libtommath/mtest/mtest.c | 4 + libtommath/poster.pdf | Bin 40821 -> 37806 bytes libtommath/pre_gen/mpi.c | 525 +++++++++++++++++- libtommath/tommath.h | 26 +- libtommath/tommath.pdf | Bin 1160406 -> 1159839 bytes libtommath/tommath.src | 31 +- libtommath/tommath.tex | 670 +++++++++++++---------- libtommath/tommath_class.h | 5 + libtommath/tommath_superclass.h | 6 +- 156 files changed, 1587 insertions(+), 445 deletions(-) diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf index 615ff4e..b8b8f8e 100644 Binary files a/libtommath/bn.pdf and b/libtommath/bn.pdf differ diff --git a/libtommath/bn.tex b/libtommath/bn.tex index 244bd6f..8b37766 100644 --- a/libtommath/bn.tex +++ b/libtommath/bn.tex @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{LibTomMath User Manual \\ v0.35} +\title{LibTomMath User Manual \\ v0.36} \author{Tom St Denis \\ tomstdenis@iahu.ca} \maketitle This text, the library and the accompanying textbook are all hereby placed in the public domain. This book has been diff --git a/libtommath/bn_error.c b/libtommath/bn_error.c index 1546784..e260763 100644 --- a/libtommath/bn_error.c +++ b/libtommath/bn_error.c @@ -41,3 +41,7 @@ char *mp_error_to_string(int code) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_error.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_fast_mp_invmod.c b/libtommath/bn_fast_mp_invmod.c index acc8364..9f4a4da 100644 --- a/libtommath/bn_fast_mp_invmod.c +++ b/libtommath/bn_fast_mp_invmod.c @@ -142,3 +142,7 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_mp_invmod.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_fast_mp_montgomery_reduce.c b/libtommath/bn_fast_mp_montgomery_reduce.c index 14f307f..e676c6e 100644 --- a/libtommath/bn_fast_mp_montgomery_reduce.c +++ b/libtommath/bn_fast_mp_montgomery_reduce.c @@ -166,3 +166,7 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_mp_montgomery_reduce.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_fast_s_mp_mul_digs.c b/libtommath/bn_fast_s_mp_mul_digs.c index df3da26..0c715be 100644 --- a/libtommath/bn_fast_s_mp_mul_digs.c +++ b/libtommath/bn_fast_s_mp_mul_digs.c @@ -70,6 +70,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) /* execute loop */ for (iz = 0; iz < iy; ++iz) { _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } /* store term */ @@ -103,3 +104,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_mul_digs.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_fast_s_mp_mul_high_digs.c b/libtommath/bn_fast_s_mp_mul_high_digs.c index ee657f9..7c10ce4 100644 --- a/libtommath/bn_fast_s_mp_mul_high_digs.c +++ b/libtommath/bn_fast_s_mp_mul_high_digs.c @@ -95,3 +95,7 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_mul_high_digs.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_fast_s_mp_sqr.c b/libtommath/bn_fast_s_mp_sqr.c index 66a2942..c8f0dc6 100644 --- a/libtommath/bn_fast_s_mp_sqr.c +++ b/libtommath/bn_fast_s_mp_sqr.c @@ -108,3 +108,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_sqr.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_2expt.c b/libtommath/bn_mp_2expt.c index 45a6818..d859623 100644 --- a/libtommath/bn_mp_2expt.c +++ b/libtommath/bn_mp_2expt.c @@ -42,3 +42,7 @@ mp_2expt (mp_int * a, int b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_2expt.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_abs.c b/libtommath/bn_mp_abs.c index 34f810f..7231a27 100644 --- a/libtommath/bn_mp_abs.c +++ b/libtommath/bn_mp_abs.c @@ -37,3 +37,7 @@ mp_abs (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_abs.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_add.c b/libtommath/bn_mp_add.c index 554b7f7..74dcb48 100644 --- a/libtommath/bn_mp_add.c +++ b/libtommath/bn_mp_add.c @@ -47,3 +47,7 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_add.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_add_d.c b/libtommath/bn_mp_add_d.c index bdd0280..fde3cee 100644 --- a/libtommath/bn_mp_add_d.c +++ b/libtommath/bn_mp_add_d.c @@ -103,3 +103,7 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_add_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_addmod.c b/libtommath/bn_mp_addmod.c index 13eb33f..5cf1604 100644 --- a/libtommath/bn_mp_addmod.c +++ b/libtommath/bn_mp_addmod.c @@ -35,3 +35,7 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_addmod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_and.c b/libtommath/bn_mp_and.c index 61dc386..9715308 100644 --- a/libtommath/bn_mp_and.c +++ b/libtommath/bn_mp_and.c @@ -51,3 +51,7 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_and.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_clamp.c b/libtommath/bn_mp_clamp.c index c172611..56a6362 100644 --- a/libtommath/bn_mp_clamp.c +++ b/libtommath/bn_mp_clamp.c @@ -38,3 +38,7 @@ mp_clamp (mp_int * a) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clamp.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_clear.c b/libtommath/bn_mp_clear.c index 5342648..7564fff 100644 --- a/libtommath/bn_mp_clear.c +++ b/libtommath/bn_mp_clear.c @@ -38,3 +38,7 @@ mp_clear (mp_int * a) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clear.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_clear_multi.c b/libtommath/bn_mp_clear_multi.c index 24cbe73..2766907 100644 --- a/libtommath/bn_mp_clear_multi.c +++ b/libtommath/bn_mp_clear_multi.c @@ -28,3 +28,7 @@ void mp_clear_multi(mp_int *mp, ...) va_end(args); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clear_multi.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_cmp.c b/libtommath/bn_mp_cmp.c index 583b5f8..ce82baf 100644 --- a/libtommath/bn_mp_cmp.c +++ b/libtommath/bn_mp_cmp.c @@ -37,3 +37,7 @@ mp_cmp (mp_int * a, mp_int * b) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_cmp_d.c b/libtommath/bn_mp_cmp_d.c index 882b1c9..2d98647 100644 --- a/libtommath/bn_mp_cmp_d.c +++ b/libtommath/bn_mp_cmp_d.c @@ -38,3 +38,7 @@ int mp_cmp_d(mp_int * a, mp_digit b) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_cmp_mag.c b/libtommath/bn_mp_cmp_mag.c index a0f351c..3ade54f 100644 --- a/libtommath/bn_mp_cmp_mag.c +++ b/libtommath/bn_mp_cmp_mag.c @@ -49,3 +49,7 @@ int mp_cmp_mag (mp_int * a, mp_int * b) return MP_EQ; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp_mag.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_cnt_lsb.c b/libtommath/bn_mp_cnt_lsb.c index 571f03f..6ff212d 100644 --- a/libtommath/bn_mp_cnt_lsb.c +++ b/libtommath/bn_mp_cnt_lsb.c @@ -47,3 +47,7 @@ int mp_cnt_lsb(mp_int *a) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cnt_lsb.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_copy.c b/libtommath/bn_mp_copy.c index 183ec9b..f2de108 100644 --- a/libtommath/bn_mp_copy.c +++ b/libtommath/bn_mp_copy.c @@ -62,3 +62,7 @@ mp_copy (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_copy.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_count_bits.c b/libtommath/bn_mp_count_bits.c index f3f85ac..cfab837 100644 --- a/libtommath/bn_mp_count_bits.c +++ b/libtommath/bn_mp_count_bits.c @@ -39,3 +39,7 @@ mp_count_bits (mp_int * a) return r; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_count_bits.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_div.c b/libtommath/bn_mp_div.c index 6b2b8f0..a0a9d7c 100644 --- a/libtommath/bn_mp_div.c +++ b/libtommath/bn_mp_div.c @@ -286,3 +286,7 @@ LBL_Q:mp_clear (&q); #endif #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_div_2.c b/libtommath/bn_mp_div_2.c index 5777997..23cd43a 100644 --- a/libtommath/bn_mp_div_2.c +++ b/libtommath/bn_mp_div_2.c @@ -62,3 +62,7 @@ int mp_div_2(mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_2.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_div_2d.c b/libtommath/bn_mp_div_2d.c index cf103f2..305eeaa 100644 --- a/libtommath/bn_mp_div_2d.c +++ b/libtommath/bn_mp_div_2d.c @@ -91,3 +91,7 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_2d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_div_3.c b/libtommath/bn_mp_div_3.c index 7cbafc1..69d25cf 100644 --- a/libtommath/bn_mp_div_3.c +++ b/libtommath/bn_mp_div_3.c @@ -73,3 +73,7 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_3.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_div_d.c b/libtommath/bn_mp_div_d.c index 9b58aa6..c3afceb 100644 --- a/libtommath/bn_mp_div_d.c +++ b/libtommath/bn_mp_div_d.c @@ -104,3 +104,7 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_dr_is_modulus.c b/libtommath/bn_mp_dr_is_modulus.c index 5ef78a3..b11bc0c 100644 --- a/libtommath/bn_mp_dr_is_modulus.c +++ b/libtommath/bn_mp_dr_is_modulus.c @@ -37,3 +37,7 @@ int mp_dr_is_modulus(mp_int *a) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_is_modulus.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_dr_reduce.c b/libtommath/bn_mp_dr_reduce.c index 9bb7ad7..c7119a1 100644 --- a/libtommath/bn_mp_dr_reduce.c +++ b/libtommath/bn_mp_dr_reduce.c @@ -88,3 +88,7 @@ top: return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_reduce.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_dr_setup.c b/libtommath/bn_mp_dr_setup.c index 029d310..c177199 100644 --- a/libtommath/bn_mp_dr_setup.c +++ b/libtommath/bn_mp_dr_setup.c @@ -26,3 +26,7 @@ void mp_dr_setup(mp_int *a, mp_digit *d) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_setup.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_exch.c b/libtommath/bn_mp_exch.c index 0ef485a..7bb1169 100644 --- a/libtommath/bn_mp_exch.c +++ b/libtommath/bn_mp_exch.c @@ -28,3 +28,7 @@ mp_exch (mp_int * a, mp_int * b) *b = t; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exch.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_expt_d.c b/libtommath/bn_mp_expt_d.c index fdb8bd9..d5067ab 100644 --- a/libtommath/bn_mp_expt_d.c +++ b/libtommath/bn_mp_expt_d.c @@ -51,3 +51,7 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_expt_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_exptmod.c b/libtommath/bn_mp_exptmod.c index 7c4e2f8..f0b205b 100644 --- a/libtommath/bn_mp_exptmod.c +++ b/libtommath/bn_mp_exptmod.c @@ -66,7 +66,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) } /* modified diminished radix reduction */ -#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) +#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) && defined(BN_S_MP_EXPTMOD_C) if (mp_reduce_is_2k_l(P) == MP_YES) { return s_mp_exptmod(G, X, P, Y, 1); } @@ -106,3 +106,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exptmod.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_exptmod_fast.c b/libtommath/bn_mp_exptmod_fast.c index 82be9ac..e4f25df 100644 --- a/libtommath/bn_mp_exptmod_fast.c +++ b/libtommath/bn_mp_exptmod_fast.c @@ -315,3 +315,7 @@ LBL_M: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exptmod_fast.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_exteuclid.c b/libtommath/bn_mp_exteuclid.c index c4ebab4..f0ae8e5 100644 --- a/libtommath/bn_mp_exteuclid.c +++ b/libtommath/bn_mp_exteuclid.c @@ -76,3 +76,7 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exteuclid.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_fread.c b/libtommath/bn_mp_fread.c index 293df3f..f1c72fd 100644 --- a/libtommath/bn_mp_fread.c +++ b/libtommath/bn_mp_fread.c @@ -61,3 +61,7 @@ int mp_fread(mp_int *a, int radix, FILE *stream) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_fread.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_fwrite.c b/libtommath/bn_mp_fwrite.c index 8fa3129..29c0a2b 100644 --- a/libtommath/bn_mp_fwrite.c +++ b/libtommath/bn_mp_fwrite.c @@ -46,3 +46,7 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_fwrite.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_gcd.c b/libtommath/bn_mp_gcd.c index 6265df1..f0141ac 100644 --- a/libtommath/bn_mp_gcd.c +++ b/libtommath/bn_mp_gcd.c @@ -107,3 +107,7 @@ LBL_U:mp_clear (&v); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_gcd.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_get_int.c b/libtommath/bn_mp_get_int.c index 034467b..e9282aa 100644 --- a/libtommath/bn_mp_get_int.c +++ b/libtommath/bn_mp_get_int.c @@ -39,3 +39,7 @@ unsigned long mp_get_int(mp_int * a) return res & 0xFFFFFFFFUL; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_get_int.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_grow.c b/libtommath/bn_mp_grow.c index 12a78a8..047c6af 100644 --- a/libtommath/bn_mp_grow.c +++ b/libtommath/bn_mp_grow.c @@ -51,3 +51,7 @@ int mp_grow (mp_int * a, int size) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_grow.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init.c b/libtommath/bn_mp_init.c index 9d70554..7a59a39 100644 --- a/libtommath/bn_mp_init.c +++ b/libtommath/bn_mp_init.c @@ -40,3 +40,7 @@ int mp_init (mp_int * a) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init_copy.c b/libtommath/bn_mp_init_copy.c index b1b0fa2..2b3248d 100644 --- a/libtommath/bn_mp_init_copy.c +++ b/libtommath/bn_mp_init_copy.c @@ -26,3 +26,7 @@ int mp_init_copy (mp_int * a, mp_int * b) return mp_copy (b, a); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_copy.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init_multi.c b/libtommath/bn_mp_init_multi.c index 8cb123a..5af771f 100644 --- a/libtommath/bn_mp_init_multi.c +++ b/libtommath/bn_mp_init_multi.c @@ -53,3 +53,7 @@ int mp_init_multi(mp_int *mp, ...) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_multi.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init_set.c b/libtommath/bn_mp_init_set.c index 0251e61..ded8617 100644 --- a/libtommath/bn_mp_init_set.c +++ b/libtommath/bn_mp_init_set.c @@ -26,3 +26,7 @@ int mp_init_set (mp_int * a, mp_digit b) return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_set.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init_set_int.c b/libtommath/bn_mp_init_set_int.c index f59fd19..45341fe 100644 --- a/libtommath/bn_mp_init_set_int.c +++ b/libtommath/bn_mp_init_set_int.c @@ -25,3 +25,7 @@ int mp_init_set_int (mp_int * a, unsigned long b) return mp_set_int(a, b); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_set_int.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_init_size.c b/libtommath/bn_mp_init_size.c index 845ce2c..74afbf9 100644 --- a/libtommath/bn_mp_init_size.c +++ b/libtommath/bn_mp_init_size.c @@ -42,3 +42,7 @@ int mp_init_size (mp_int * a, int size) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_size.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_invmod.c b/libtommath/bn_mp_invmod.c index 46118ad..bf35b0a 100644 --- a/libtommath/bn_mp_invmod.c +++ b/libtommath/bn_mp_invmod.c @@ -37,3 +37,7 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) return MP_VAL; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_invmod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_invmod_slow.c b/libtommath/bn_mp_invmod_slow.c index c048655..50a9b6f 100644 --- a/libtommath/bn_mp_invmod_slow.c +++ b/libtommath/bn_mp_invmod_slow.c @@ -169,3 +169,7 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_invmod_slow.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_is_square.c b/libtommath/bn_mp_is_square.c index 969d237..8ee84c7 100644 --- a/libtommath/bn_mp_is_square.c +++ b/libtommath/bn_mp_is_square.c @@ -103,3 +103,7 @@ ERR:mp_clear(&t); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_is_square.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_jacobi.c b/libtommath/bn_mp_jacobi.c index 74cbbf3..8178454 100644 --- a/libtommath/bn_mp_jacobi.c +++ b/libtommath/bn_mp_jacobi.c @@ -99,3 +99,7 @@ LBL_A1:mp_clear (&a1); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_jacobi.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_karatsuba_mul.c b/libtommath/bn_mp_karatsuba_mul.c index daa78c7..a1ff713 100644 --- a/libtommath/bn_mp_karatsuba_mul.c +++ b/libtommath/bn_mp_karatsuba_mul.c @@ -26,12 +26,12 @@ * b = b1 * B**n + b0 * * Then, a * b => - a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 + a1b1 * B**2n + ((a1 + a0)(b1 + b0) - (a0b0 + a1b1)) * B + a0b0 * * Note that a1b1 and a0b0 are used twice and only need to be * computed once. So in total three half size (half # of * digit) multiplications are performed, a0b0, a1b1 and - * (a1-b1)(a0-b0) + * (a1+b1)(a0+b0) * * Note that a multiplication of half the digits requires * 1/4th the number of single precision multiplications so in @@ -122,19 +122,19 @@ int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) goto X1Y1; /* x1y1 = x1*y1 */ - /* now calc x1-x0 and y1-y0 */ - if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + /* now calc x1+x0 and y1+y0 */ + if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) goto X1Y1; /* t1 = x1 - x0 */ - if (mp_sub (&y1, &y0, &x0) != MP_OKAY) + if (s_mp_add (&y1, &y0, &x0) != MP_OKAY) goto X1Y1; /* t2 = y1 - y0 */ if (mp_mul (&t1, &x0, &t1) != MP_OKAY) - goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ + goto X1Y1; /* t1 = (x1 + x0) * (y1 + y0) */ /* add x0y0 */ if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) goto X1Y1; /* t2 = x0y0 + x1y1 */ - if (mp_sub (&x0, &t1, &t1) != MP_OKAY) - goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ + if (s_mp_sub (&t1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = (x1+x0)*(y1+y0) - (x1y1 + x0y0) */ /* shift by B */ if (mp_lshd (&t1, B) != MP_OKAY) @@ -161,3 +161,7 @@ ERR: return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_karatsuba_mul.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_karatsuba_sqr.c b/libtommath/bn_mp_karatsuba_sqr.c index 315ceab..3bfe157 100644 --- a/libtommath/bn_mp_karatsuba_sqr.c +++ b/libtommath/bn_mp_karatsuba_sqr.c @@ -80,8 +80,8 @@ int mp_karatsuba_sqr (mp_int * a, mp_int * b) if (mp_sqr (&x1, &x1x1) != MP_OKAY) goto X1X1; /* x1x1 = x1*x1 */ - /* now calc (x1-x0)**2 */ - if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + /* now calc (x1+x0)**2 */ + if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) goto X1X1; /* t1 = x1 - x0 */ if (mp_sqr (&t1, &t1) != MP_OKAY) goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ @@ -89,8 +89,8 @@ int mp_karatsuba_sqr (mp_int * a, mp_int * b) /* add x0y0 */ if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) goto X1X1; /* t2 = x0x0 + x1x1 */ - if (mp_sub (&t2, &t1, &t1) != MP_OKAY) - goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ + if (s_mp_sub (&t1, &t2, &t1) != MP_OKAY) + goto X1X1; /* t1 = (x1+x0)**2 - (x0x0 + x1x1) */ /* shift by B */ if (mp_lshd (&t1, B) != MP_OKAY) @@ -115,3 +115,7 @@ ERR: return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_karatsuba_sqr.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_lcm.c b/libtommath/bn_mp_lcm.c index 8e3a759..7bdaa43 100644 --- a/libtommath/bn_mp_lcm.c +++ b/libtommath/bn_mp_lcm.c @@ -54,3 +54,7 @@ LBL_T: return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_lcm.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_lshd.c b/libtommath/bn_mp_lshd.c index 398b648..5ddeb62 100644 --- a/libtommath/bn_mp_lshd.c +++ b/libtommath/bn_mp_lshd.c @@ -61,3 +61,7 @@ int mp_lshd (mp_int * a, int b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_lshd.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mod.c b/libtommath/bn_mp_mod.c index 75779bb..22cb069 100644 --- a/libtommath/bn_mp_mod.c +++ b/libtommath/bn_mp_mod.c @@ -42,3 +42,7 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mod_2d.c b/libtommath/bn_mp_mod_2d.c index 589e4ba..935d97d 100644 --- a/libtommath/bn_mp_mod_2d.c +++ b/libtommath/bn_mp_mod_2d.c @@ -49,3 +49,7 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod_2d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mod_d.c b/libtommath/bn_mp_mod_d.c index 8a2ad24..329594a 100644 --- a/libtommath/bn_mp_mod_d.c +++ b/libtommath/bn_mp_mod_d.c @@ -21,3 +21,7 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) return mp_div_d(a, b, NULL, c); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_montgomery_calc_normalization.c b/libtommath/bn_mp_montgomery_calc_normalization.c index e2efc34..0da933f 100644 --- a/libtommath/bn_mp_montgomery_calc_normalization.c +++ b/libtommath/bn_mp_montgomery_calc_normalization.c @@ -53,3 +53,7 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_calc_normalization.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_montgomery_reduce.c b/libtommath/bn_mp_montgomery_reduce.c index 3095fa7..d556332 100644 --- a/libtommath/bn_mp_montgomery_reduce.c +++ b/libtommath/bn_mp_montgomery_reduce.c @@ -112,3 +112,7 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_reduce.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_montgomery_setup.c b/libtommath/bn_mp_montgomery_setup.c index 9dfc087..e55e974 100644 --- a/libtommath/bn_mp_montgomery_setup.c +++ b/libtommath/bn_mp_montgomery_setup.c @@ -53,3 +53,7 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_setup.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mul.c b/libtommath/bn_mp_mul.c index f9cfa09..8fd3872 100644 --- a/libtommath/bn_mp_mul.c +++ b/libtommath/bn_mp_mul.c @@ -60,3 +60,7 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mul_2.c b/libtommath/bn_mp_mul_2.c index 6936681..7409f1c 100644 --- a/libtommath/bn_mp_mul_2.c +++ b/libtommath/bn_mp_mul_2.c @@ -76,3 +76,7 @@ int mp_mul_2(mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_2.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mul_2d.c b/libtommath/bn_mp_mul_2d.c index 04cb8dd..800646d 100644 --- a/libtommath/bn_mp_mul_2d.c +++ b/libtommath/bn_mp_mul_2d.c @@ -79,3 +79,7 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_2d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mul_d.c b/libtommath/bn_mp_mul_d.c index 9e11eef..061199f 100644 --- a/libtommath/bn_mp_mul_d.c +++ b/libtommath/bn_mp_mul_d.c @@ -73,3 +73,7 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_d.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_mulmod.c b/libtommath/bn_mp_mulmod.c index d34e90a..cb605ed 100644 --- a/libtommath/bn_mp_mulmod.c +++ b/libtommath/bn_mp_mulmod.c @@ -16,8 +16,7 @@ */ /* d = a * b (mod c) */ -int -mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) { int res; mp_int t; @@ -35,3 +34,7 @@ mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mulmod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_n_root.c b/libtommath/bn_mp_n_root.c index 7b11aa2..2fadc6c 100644 --- a/libtommath/bn_mp_n_root.c +++ b/libtommath/bn_mp_n_root.c @@ -126,3 +126,7 @@ LBL_T1:mp_clear (&t1); return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_n_root.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_neg.c b/libtommath/bn_mp_neg.c index 159cd74..9cc654a 100644 --- a/libtommath/bn_mp_neg.c +++ b/libtommath/bn_mp_neg.c @@ -34,3 +34,7 @@ int mp_neg (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_neg.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_or.c b/libtommath/bn_mp_or.c index dccee7e..14c0f19 100644 --- a/libtommath/bn_mp_or.c +++ b/libtommath/bn_mp_or.c @@ -44,3 +44,7 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_or.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_fermat.c b/libtommath/bn_mp_prime_fermat.c index fd74dbe..9b647cb 100644 --- a/libtommath/bn_mp_prime_fermat.c +++ b/libtommath/bn_mp_prime_fermat.c @@ -56,3 +56,7 @@ LBL_T:mp_clear (&t); return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_fermat.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_is_divisible.c b/libtommath/bn_mp_prime_is_divisible.c index f85fe7c..11a2f27 100644 --- a/libtommath/bn_mp_prime_is_divisible.c +++ b/libtommath/bn_mp_prime_is_divisible.c @@ -44,3 +44,7 @@ int mp_prime_is_divisible (mp_int * a, int *result) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_is_divisible.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_is_prime.c b/libtommath/bn_mp_prime_is_prime.c index 188053a..3e0e36b 100644 --- a/libtommath/bn_mp_prime_is_prime.c +++ b/libtommath/bn_mp_prime_is_prime.c @@ -77,3 +77,7 @@ LBL_B:mp_clear (&b); return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_is_prime.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_miller_rabin.c b/libtommath/bn_mp_prime_miller_rabin.c index 758a2c3..712f20d 100644 --- a/libtommath/bn_mp_prime_miller_rabin.c +++ b/libtommath/bn_mp_prime_miller_rabin.c @@ -97,3 +97,7 @@ LBL_N1:mp_clear (&n1); return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_miller_rabin.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_next_prime.c b/libtommath/bn_mp_prime_next_prime.c index 24f93c4..48b8f02 100644 --- a/libtommath/bn_mp_prime_next_prime.c +++ b/libtommath/bn_mp_prime_next_prime.c @@ -164,3 +164,7 @@ LBL_ERR: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_next_prime.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_rabin_miller_trials.c b/libtommath/bn_mp_prime_rabin_miller_trials.c index d1d0867..c4c9f5e 100644 --- a/libtommath/bn_mp_prime_rabin_miller_trials.c +++ b/libtommath/bn_mp_prime_rabin_miller_trials.c @@ -46,3 +46,7 @@ int mp_prime_rabin_miller_trials(int size) #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_rabin_miller_trials.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_prime_random_ex.c b/libtommath/bn_mp_prime_random_ex.c index 78c0583..daca61c 100644 --- a/libtommath/bn_mp_prime_random_ex.c +++ b/libtommath/bn_mp_prime_random_ex.c @@ -62,10 +62,8 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback maskOR_msb = 0; maskOR_msb_offset = ((size & 7) == 1) ? 1 : 0; if (flags & LTM_PRIME_2MSB_ON) { - maskOR_msb |= 1 << ((size - 2) & 7); - } else if (flags & LTM_PRIME_2MSB_OFF) { - maskAND &= ~(1 << ((size - 2) & 7)); - } + maskOR_msb |= 0x80 >> ((9 - size) & 7); + } /* get the maskOR_lsb */ maskOR_lsb = 1; @@ -121,3 +119,7 @@ error: #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_random_ex.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_radix_size.c b/libtommath/bn_mp_radix_size.c index 3d423ba..7c5d8b5 100644 --- a/libtommath/bn_mp_radix_size.c +++ b/libtommath/bn_mp_radix_size.c @@ -72,3 +72,7 @@ int mp_radix_size (mp_int * a, int radix, int *size) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_radix_size.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_radix_smap.c b/libtommath/bn_mp_radix_smap.c index bc7517d..b9b88f9 100644 --- a/libtommath/bn_mp_radix_smap.c +++ b/libtommath/bn_mp_radix_smap.c @@ -18,3 +18,7 @@ /* chars used in radix conversions */ const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz+/"; #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_radix_smap.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_rand.c b/libtommath/bn_mp_rand.c index 0dc7019..94b0e7f 100644 --- a/libtommath/bn_mp_rand.c +++ b/libtommath/bn_mp_rand.c @@ -49,3 +49,7 @@ mp_rand (mp_int * a, int digits) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_rand.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_read_radix.c b/libtommath/bn_mp_read_radix.c index 1ec3937..ca2bde5 100644 --- a/libtommath/bn_mp_read_radix.c +++ b/libtommath/bn_mp_read_radix.c @@ -76,3 +76,7 @@ int mp_read_radix (mp_int * a, const char *str, int radix) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_radix.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_read_signed_bin.c b/libtommath/bn_mp_read_signed_bin.c index 814d6c1..05b1c9c 100644 --- a/libtommath/bn_mp_read_signed_bin.c +++ b/libtommath/bn_mp_read_signed_bin.c @@ -16,8 +16,7 @@ */ /* read signed bin, big endian, first byte is 0==positive or 1==negative */ -int -mp_read_signed_bin (mp_int * a, unsigned char *b, int c) +int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) { int res; @@ -36,3 +35,7 @@ mp_read_signed_bin (mp_int * a, unsigned char *b, int c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_signed_bin.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_read_unsigned_bin.c b/libtommath/bn_mp_read_unsigned_bin.c index 946457d..655415a 100644 --- a/libtommath/bn_mp_read_unsigned_bin.c +++ b/libtommath/bn_mp_read_unsigned_bin.c @@ -16,8 +16,7 @@ */ /* reads a unsigned char array, assumes the msb is stored first [big endian] */ -int -mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) +int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) { int res; @@ -50,3 +49,7 @@ mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_unsigned_bin.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce.c b/libtommath/bn_mp_reduce.c index d746445..dbc38c8 100644 --- a/libtommath/bn_mp_reduce.c +++ b/libtommath/bn_mp_reduce.c @@ -94,3 +94,7 @@ CLEANUP: return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_2k.c b/libtommath/bn_mp_reduce_2k.c index 28c3a00..790ac3c 100644 --- a/libtommath/bn_mp_reduce_2k.c +++ b/libtommath/bn_mp_reduce_2k.c @@ -55,3 +55,7 @@ ERR: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_2k_l.c b/libtommath/bn_mp_reduce_2k_l.c index 1d7e1f0..6a013cf 100644 --- a/libtommath/bn_mp_reduce_2k_l.c +++ b/libtommath/bn_mp_reduce_2k_l.c @@ -56,3 +56,7 @@ ERR: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_l.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_2k_setup.c b/libtommath/bn_mp_reduce_2k_setup.c index 585e1b7..17c54c5 100644 --- a/libtommath/bn_mp_reduce_2k_setup.c +++ b/libtommath/bn_mp_reduce_2k_setup.c @@ -41,3 +41,7 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_setup.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_2k_setup_l.c b/libtommath/bn_mp_reduce_2k_setup_l.c index 810a456..2913162 100644 --- a/libtommath/bn_mp_reduce_2k_setup_l.c +++ b/libtommath/bn_mp_reduce_2k_setup_l.c @@ -38,3 +38,7 @@ ERR: return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_setup_l.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_is_2k.c b/libtommath/bn_mp_reduce_is_2k.c index 0fb8384..ad14107 100644 --- a/libtommath/bn_mp_reduce_is_2k.c +++ b/libtommath/bn_mp_reduce_is_2k.c @@ -46,3 +46,7 @@ int mp_reduce_is_2k(mp_int *a) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_is_2k.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_is_2k_l.c b/libtommath/bn_mp_reduce_is_2k_l.c index ceba0ed..160b2ce 100644 --- a/libtommath/bn_mp_reduce_is_2k_l.c +++ b/libtommath/bn_mp_reduce_is_2k_l.c @@ -38,3 +38,7 @@ int mp_reduce_is_2k_l(mp_int *a) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_is_2k_l.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_reduce_setup.c b/libtommath/bn_mp_reduce_setup.c index 99f158a..4d2d99f 100644 --- a/libtommath/bn_mp_reduce_setup.c +++ b/libtommath/bn_mp_reduce_setup.c @@ -28,3 +28,7 @@ int mp_reduce_setup (mp_int * a, mp_int * b) return mp_div (a, b, a, NULL); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_setup.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_rshd.c b/libtommath/bn_mp_rshd.c index 913dda6..d5a75c6 100644 --- a/libtommath/bn_mp_rshd.c +++ b/libtommath/bn_mp_rshd.c @@ -66,3 +66,7 @@ void mp_rshd (mp_int * a, int b) a->used -= b; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_rshd.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_set.c b/libtommath/bn_mp_set.c index 078fd5f..af01b3c 100644 --- a/libtommath/bn_mp_set.c +++ b/libtommath/bn_mp_set.c @@ -23,3 +23,7 @@ void mp_set (mp_int * a, mp_digit b) a->used = (a->dp[0] != 0) ? 1 : 0; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_set.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_set_int.c b/libtommath/bn_mp_set_int.c index bd47136..c7ddb79 100644 --- a/libtommath/bn_mp_set_int.c +++ b/libtommath/bn_mp_set_int.c @@ -42,3 +42,7 @@ int mp_set_int (mp_int * a, unsigned long b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_set_int.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_shrink.c b/libtommath/bn_mp_shrink.c index b31f9d2..a40b65c 100644 --- a/libtommath/bn_mp_shrink.c +++ b/libtommath/bn_mp_shrink.c @@ -29,3 +29,7 @@ int mp_shrink (mp_int * a) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_shrink.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_signed_bin_size.c b/libtommath/bn_mp_signed_bin_size.c index 30048cb..4dbbeb8 100644 --- a/libtommath/bn_mp_signed_bin_size.c +++ b/libtommath/bn_mp_signed_bin_size.c @@ -21,3 +21,7 @@ int mp_signed_bin_size (mp_int * a) return 1 + mp_unsigned_bin_size (a); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_signed_bin_size.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_sqr.c b/libtommath/bn_mp_sqr.c index b1fdb57..ac926e9 100644 --- a/libtommath/bn_mp_sqr.c +++ b/libtommath/bn_mp_sqr.c @@ -52,3 +52,7 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqr.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_sqrmod.c b/libtommath/bn_mp_sqrmod.c index 1923be4..fe5f4bb 100644 --- a/libtommath/bn_mp_sqrmod.c +++ b/libtommath/bn_mp_sqrmod.c @@ -35,3 +35,7 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqrmod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_sqrt.c b/libtommath/bn_mp_sqrt.c index 76cec87..ac8c2b8 100644 --- a/libtommath/bn_mp_sqrt.c +++ b/libtommath/bn_mp_sqrt.c @@ -75,3 +75,7 @@ E2: mp_clear(&t1); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqrt.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_sub.c b/libtommath/bn_mp_sub.c index 97495f4..52e1e43 100644 --- a/libtommath/bn_mp_sub.c +++ b/libtommath/bn_mp_sub.c @@ -53,3 +53,7 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sub.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_sub_d.c b/libtommath/bn_mp_sub_d.c index 4923dde..0b31cbe 100644 --- a/libtommath/bn_mp_sub_d.c +++ b/libtommath/bn_mp_sub_d.c @@ -83,3 +83,7 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sub_d.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_submod.c b/libtommath/bn_mp_submod.c index b999c85..f735e9e 100644 --- a/libtommath/bn_mp_submod.c +++ b/libtommath/bn_mp_submod.c @@ -36,3 +36,7 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) return res; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_submod.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_to_signed_bin.c b/libtommath/bn_mp_to_signed_bin.c index b0a597e..bc07d1e 100644 --- a/libtommath/bn_mp_to_signed_bin.c +++ b/libtommath/bn_mp_to_signed_bin.c @@ -27,3 +27,7 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_signed_bin.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_to_signed_bin_n.c b/libtommath/bn_mp_to_signed_bin_n.c index 0f765ee..ff2a768 100644 --- a/libtommath/bn_mp_to_signed_bin_n.c +++ b/libtommath/bn_mp_to_signed_bin_n.c @@ -25,3 +25,7 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) return mp_to_signed_bin(a, b); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_signed_bin_n.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_to_unsigned_bin.c b/libtommath/bn_mp_to_unsigned_bin.c index 000967e..29b8d36 100644 --- a/libtommath/bn_mp_to_unsigned_bin.c +++ b/libtommath/bn_mp_to_unsigned_bin.c @@ -42,3 +42,7 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_unsigned_bin.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_to_unsigned_bin_n.c b/libtommath/bn_mp_to_unsigned_bin_n.c index d0256b4..415e87d 100644 --- a/libtommath/bn_mp_to_unsigned_bin_n.c +++ b/libtommath/bn_mp_to_unsigned_bin_n.c @@ -25,3 +25,7 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) return mp_to_unsigned_bin(a, b); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_unsigned_bin_n.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_toom_mul.c b/libtommath/bn_mp_toom_mul.c index 125331b..e6fb523 100644 --- a/libtommath/bn_mp_toom_mul.c +++ b/libtommath/bn_mp_toom_mul.c @@ -278,3 +278,7 @@ ERR: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toom_mul.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_toom_sqr.c b/libtommath/bn_mp_toom_sqr.c index 8c46fea..ba800a0 100644 --- a/libtommath/bn_mp_toom_sqr.c +++ b/libtommath/bn_mp_toom_sqr.c @@ -220,3 +220,7 @@ ERR: } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toom_sqr.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_toradix.c b/libtommath/bn_mp_toradix.c index a206d5e..96ac736 100644 --- a/libtommath/bn_mp_toradix.c +++ b/libtommath/bn_mp_toradix.c @@ -69,3 +69,7 @@ int mp_toradix (mp_int * a, char *str, int radix) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toradix.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_toradix_n.c b/libtommath/bn_mp_toradix_n.c index 7d43558..d07ba95 100644 --- a/libtommath/bn_mp_toradix_n.c +++ b/libtommath/bn_mp_toradix_n.c @@ -83,3 +83,7 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toradix_n.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_unsigned_bin_size.c b/libtommath/bn_mp_unsigned_bin_size.c index 091f406..9622dbf 100644 --- a/libtommath/bn_mp_unsigned_bin_size.c +++ b/libtommath/bn_mp_unsigned_bin_size.c @@ -22,3 +22,7 @@ int mp_unsigned_bin_size (mp_int * a) return (size / 8 + ((size & 7) != 0 ? 1 : 0)); } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_unsigned_bin_size.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_xor.c b/libtommath/bn_mp_xor.c index de7e62c..ae9f29b 100644 --- a/libtommath/bn_mp_xor.c +++ b/libtommath/bn_mp_xor.c @@ -45,3 +45,7 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_xor.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_mp_zero.c b/libtommath/bn_mp_zero.c index c8d8907..6f7469c 100644 --- a/libtommath/bn_mp_zero.c +++ b/libtommath/bn_mp_zero.c @@ -30,3 +30,7 @@ void mp_zero (mp_int * a) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_zero.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_prime_tab.c b/libtommath/bn_prime_tab.c index 14306c2..9ec6d7a 100644 --- a/libtommath/bn_prime_tab.c +++ b/libtommath/bn_prime_tab.c @@ -55,3 +55,7 @@ const mp_digit ltm_prime_tab[] = { #endif }; #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_prime_tab.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_reverse.c b/libtommath/bn_reverse.c index 851a6e8..ad119ff 100644 --- a/libtommath/bn_reverse.c +++ b/libtommath/bn_reverse.c @@ -33,3 +33,7 @@ bn_reverse (unsigned char *s, int len) } } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_reverse.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_add.c b/libtommath/bn_s_mp_add.c index 2b378ae..f196f3e 100644 --- a/libtommath/bn_s_mp_add.c +++ b/libtommath/bn_s_mp_add.c @@ -103,3 +103,7 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_add.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_exptmod.c b/libtommath/bn_s_mp_exptmod.c index 597e877..d33558a 100644 --- a/libtommath/bn_s_mp_exptmod.c +++ b/libtommath/bn_s_mp_exptmod.c @@ -14,7 +14,6 @@ * * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org */ - #ifdef MP_LOW_MEM #define TAB_SIZE 32 #else @@ -247,3 +246,7 @@ LBL_M: return err; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_exptmod.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_mul_digs.c b/libtommath/bn_s_mp_mul_digs.c index b40ae2e..e296640 100644 --- a/libtommath/bn_s_mp_mul_digs.c +++ b/libtommath/bn_s_mp_mul_digs.c @@ -84,3 +84,7 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_mul_digs.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_mul_high_digs.c b/libtommath/bn_s_mp_mul_high_digs.c index a060248..972918f 100644 --- a/libtommath/bn_s_mp_mul_high_digs.c +++ b/libtommath/bn_s_mp_mul_high_digs.c @@ -75,3 +75,7 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_mul_high_digs.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_sqr.c b/libtommath/bn_s_mp_sqr.c index 9cdb563..1b1e0b4 100644 --- a/libtommath/bn_s_mp_sqr.c +++ b/libtommath/bn_s_mp_sqr.c @@ -78,3 +78,7 @@ int s_mp_sqr (mp_int * a, mp_int * b) return MP_OKAY; } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_sqr.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bn_s_mp_sub.c b/libtommath/bn_s_mp_sub.c index 5b7aef9..fb2ea21 100644 --- a/libtommath/bn_s_mp_sub.c +++ b/libtommath/bn_s_mp_sub.c @@ -83,3 +83,7 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) } #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_sub.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/bncore.c b/libtommath/bncore.c index 82e3132..fad10d2 100644 --- a/libtommath/bncore.c +++ b/libtommath/bncore.c @@ -20,13 +20,17 @@ CPU /Compiler /MUL CUTOFF/SQR CUTOFF ------------------------------------------------------------- Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) - AMD Athlon64 /GCC v3.4.4 / 74/ 124/LTM 0.34 + AMD Athlon64 /GCC v3.4.4 / 80/ 120/LTM 0.35 */ -int KARATSUBA_MUL_CUTOFF = 74, /* Min. number of digits before Karatsuba multiplication is used. */ - KARATSUBA_SQR_CUTOFF = 124, /* Min. number of digits before Karatsuba squaring is used. */ +int KARATSUBA_MUL_CUTOFF = 80, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 120, /* Min. number of digits before Karatsuba squaring is used. */ TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ TOOM_SQR_CUTOFF = 400; #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bncore.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:56 $ */ diff --git a/libtommath/booker.pl b/libtommath/booker.pl index 5c77e53..f419ab4 100644 --- a/libtommath/booker.pl +++ b/libtommath/booker.pl @@ -89,6 +89,9 @@ while () { $inline = 0; while () { + next if ($_ =~ /\$Source/); + next if ($_ =~ /\$Revision/); + next if ($_ =~ /\$Date/); $text[$line++] = $_; ++$inline; chomp($_); diff --git a/libtommath/changes.txt b/libtommath/changes.txt index 99e40c1..4f27d63 100644 --- a/libtommath/changes.txt +++ b/libtommath/changes.txt @@ -1,3 +1,15 @@ +August 1st, 2005 +v0.36 -- LTM_PRIME_2MSB_ON was fixed and the "OFF" flag was removed. + -- [Peter LaDow] found a typo in the XREALLOC macro + -- [Peter LaDow] pointed out that mp_read_(un)signed_bin should have "const" on the input + -- Ported LTC patch to fix the prime_random_ex() function to get the bitsize correct [and the maskOR flags] + -- Kevin Kenny pointed out a stray // + -- David Hulton pointed out a typo in the textbook [mp_montgomery_setup() pseudo-code] + -- Neal Hamilton (Elliptic Semiconductor) pointed out that my Karatsuba notation was backwards and that I could use + unsigned operations in the routine. + -- Paul Schmidt pointed out a linking error in mp_exptmod() when BN_S_MP_EXPTMOD_C is undefined (and another for read_radix) + -- Updated makefiles to be way more flexible + March 12th, 2005 v0.35 -- Stupid XOR function missing line again... oops. -- Fixed bug in invmod not handling negative inputs correctly [Wolfgang Ehrhardt] diff --git a/libtommath/demo/demo.c b/libtommath/demo/demo.c index 0a6115a..0555366 100644 --- a/libtommath/demo/demo.c +++ b/libtommath/demo/demo.c @@ -389,8 +389,8 @@ printf("compare no compare!\n"); exit(EXIT_FAILURE); } sub_d_n = 0; /* force KARA and TOOM to enable despite cutoffs */ - KARATSUBA_SQR_CUTOFF = KARATSUBA_MUL_CUTOFF = 110; - TOOM_SQR_CUTOFF = TOOM_MUL_CUTOFF = 150; + KARATSUBA_SQR_CUTOFF = KARATSUBA_MUL_CUTOFF = 8; + TOOM_SQR_CUTOFF = TOOM_MUL_CUTOFF = 16; for (;;) { /* randomly clear and re-init one variable, this has the affect of triming the alloc space */ @@ -734,3 +734,7 @@ printf("compare no compare!\n"); exit(EXIT_FAILURE); } } return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/demo/demo.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/demo/timing.c b/libtommath/demo/timing.c index bb3be52..cf0f39c 100644 --- a/libtommath/demo/timing.c +++ b/libtommath/demo/timing.c @@ -313,3 +313,7 @@ int main(void) return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/demo/timing.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/2kprime.c b/libtommath/etc/2kprime.c index d48b83e..d8ea97c 100644 --- a/libtommath/etc/2kprime.c +++ b/libtommath/etc/2kprime.c @@ -78,3 +78,7 @@ int main(void) + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/2kprime.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/drprime.c b/libtommath/etc/drprime.c index 0ab8ea6..eec89ed 100644 --- a/libtommath/etc/drprime.c +++ b/libtommath/etc/drprime.c @@ -58,3 +58,7 @@ int main(void) return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/drprime.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/makefile.icc b/libtommath/etc/makefile.icc index 0a50728..8a1ffff 100644 --- a/libtommath/etc/makefile.icc +++ b/libtommath/etc/makefile.icc @@ -16,7 +16,7 @@ CFLAGS += -I../ # B - Blend of P4 and PM [mobile] # # Default to just generic max opts -CFLAGS += -O3 -xN -ip +CFLAGS += -O3 -xP -ip # default lib name (requires install with root) # LIBNAME=-ltommath diff --git a/libtommath/etc/mersenne.c b/libtommath/etc/mersenne.c index 1cd5b50..939616f 100644 --- a/libtommath/etc/mersenne.c +++ b/libtommath/etc/mersenne.c @@ -138,3 +138,7 @@ main (void) } return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/mersenne.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/mont.c b/libtommath/etc/mont.c index dbf1735..c6a8e32 100644 --- a/libtommath/etc/mont.c +++ b/libtommath/etc/mont.c @@ -44,3 +44,7 @@ int main(void) + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/mont.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/pprime.c b/libtommath/etc/pprime.c index 26e0d84..a922b64 100644 --- a/libtommath/etc/pprime.c +++ b/libtommath/etc/pprime.c @@ -394,3 +394,7 @@ main (void) return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/pprime.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/etc/tune.c b/libtommath/etc/tune.c index d054d10..b09c7d9 100644 --- a/libtommath/etc/tune.c +++ b/libtommath/etc/tune.c @@ -136,3 +136,7 @@ main (void) return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/tune.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/logs/expt.log b/libtommath/logs/expt.log index 920ba55..70932ab 100644 --- a/libtommath/logs/expt.log +++ b/libtommath/logs/expt.log @@ -1,7 +1,7 @@ -513 1489160 -769 3688476 -1025 8162061 -2049 49260015 -2561 89579052 -3073 148797060 -4097 324449263 +513 1435869 +769 3544970 +1025 7791638 +2049 46902238 +2561 85334899 +3073 141451412 +4097 308770310 diff --git a/libtommath/logs/expt_2k.log b/libtommath/logs/expt_2k.log index 56b50db..97d325f 100644 --- a/libtommath/logs/expt_2k.log +++ b/libtommath/logs/expt_2k.log @@ -1,5 +1,5 @@ -607 2272809 -1279 9557382 -2203 36250309 -3217 87666486 -4253 174168369 +607 2109225 +1279 10148314 +2203 34126877 +3217 82716424 +4253 161569606 diff --git a/libtommath/logs/expt_2kl.log b/libtommath/logs/expt_2kl.log index b2eb8c2..d9ad4be 100644 --- a/libtommath/logs/expt_2kl.log +++ b/libtommath/logs/expt_2kl.log @@ -1,4 +1,4 @@ -1024 6954080 -2048 35993987 -4096 176068521 -521 1683720 +1024 7705271 +2048 34286851 +4096 165207491 +521 1618631 diff --git a/libtommath/logs/expt_dr.log b/libtommath/logs/expt_dr.log index eb93fc9..c6bbe07 100644 --- a/libtommath/logs/expt_dr.log +++ b/libtommath/logs/expt_dr.log @@ -1,7 +1,7 @@ -532 1989592 -784 3898697 -1036 6519700 -1540 15676650 -2072 33128187 -3080 82963362 -4116 168358337 +532 1928550 +784 3763908 +1036 7564221 +1540 16566059 +2072 32283784 +3080 79851565 +4116 157843530 diff --git a/libtommath/logs/index.html b/libtommath/logs/index.html index 19fe403..2b65a0b 100644 --- a/libtommath/logs/index.html +++ b/libtommath/logs/index.html @@ -21,4 +21,7 @@
- \ No newline at end of file + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/logs/index.html,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/makefile b/libtommath/makefile index 17873ee..a4697d4 100644 --- a/libtommath/makefile +++ b/libtommath/makefile @@ -3,12 +3,14 @@ #Tom St Denis #version of library -VERSION=0.35 +VERSION=0.36 CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare +ifndef IGNORE_SPEED + #for speed -CFLAGS += -O3 -funroll-all-loops +CFLAGS += -O3 -funroll-loops #for size #CFLAGS += -Os @@ -19,14 +21,27 @@ CFLAGS += -fomit-frame-pointer #debug #CFLAGS += -g3 +endif + #install as this user -USER=root -GROUP=root +ifndef INSTALL_GROUP + GROUP=wheel +else + GROUP=$(INSTALL_GROUP) +endif + +ifndef INSTALL_USER + USER=root +else + USER=$(INSTALL_USER) +endif default: libtommath.a #default files to install -LIBNAME=libtommath.a +ifndef LIBNAME + LIBNAME=libtommath.a +endif HEADERS=tommath.h tommath_class.h tommath_superclass.h #LIBPATH-The directory for libtommath to be installed to. @@ -65,9 +80,9 @@ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_ini bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o -libtommath.a: $(OBJECTS) - $(AR) $(ARFLAGS) libtommath.a $(OBJECTS) - ranlib libtommath.a +$(LIBNAME): $(OBJECTS) + $(AR) $(ARFLAGS) $@ $(OBJECTS) + ranlib $@ #make a profiled library (takes a while!!!) # @@ -89,23 +104,23 @@ profiled_single: ./ltmtest rm -f *.o ltmtest $(CC) $(CFLAGS) -fbranch-probabilities -DTESTING -c mpi.c -o mpi.o - $(AR) $(ARFLAGS) libtommath.a mpi.o - ranlib libtommath.a + $(AR) $(ARFLAGS) $(LIBNAME) mpi.o + ranlib $(LIBNAME) -install: libtommath.a +install: $(LIBNAME) install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(LIBPATH) install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) install -g $(GROUP) -o $(USER) $(LIBNAME) $(DESTDIR)$(LIBPATH) install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) -test: libtommath.a demo/demo.o - $(CC) $(CFLAGS) demo/demo.o libtommath.a -o test +test: $(LIBNAME) demo/demo.o + $(CC) $(CFLAGS) demo/demo.o $(LIBNAME) -o test mtest: test cd mtest ; $(CC) $(CFLAGS) mtest.c -o mtest -timing: libtommath.a - $(CC) $(CFLAGS) -DTIMER demo/timing.c libtommath.a -o ltmtest +timing: $(LIBNAME) + $(CC) $(CFLAGS) -DTIMER demo/timing.c $(LIBNAME) -o ltmtest # makes the LTM book DVI file, requires tetex, perl and makeindex [part of tetex I think] docdvi: tommath.src @@ -151,6 +166,12 @@ clean: cd etc ; make clean cd pics ; make clean +#zipup the project (take that!) +no_oops: clean + cd .. ; cvs commit + echo Scanning for scratch/dirty files + find . -type f | grep -v CVS | xargs -n 1 bash mess.sh + zipup: clean manual poster docs perl gen.pl ; mv mpi.c pre_gen/ ; \ cd .. ; rm -rf ltm* libtommath-$(VERSION) ; mkdir libtommath-$(VERSION) ; \ diff --git a/libtommath/makefile.cygwin_dll b/libtommath/makefile.cygwin_dll index 85b10c7..dae65ae 100644 --- a/libtommath/makefile.cygwin_dll +++ b/libtommath/makefile.cygwin_dll @@ -49,3 +49,7 @@ windll: $(OBJECTS) test: $(OBJECTS) windll gcc $(CFLAGS) demo/demo.c libtommath.dll.a -Wl,--enable-auto-import -o test -s cd mtest ; $(CC) -O3 -fomit-frame-pointer -funroll-loops mtest.c -o mtest -s + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/makefile.cygwin_dll,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:57 $ */ diff --git a/libtommath/makefile.icc b/libtommath/makefile.icc index e764253..cf70ab0 100644 --- a/libtommath/makefile.icc +++ b/libtommath/makefile.icc @@ -19,7 +19,7 @@ CFLAGS += -I./ # B - Blend of P4 and PM [mobile] # # Default to just generic max opts -CFLAGS += -O3 -xN +CFLAGS += -O3 -xP -ip #install as this user USER=root diff --git a/libtommath/makefile.msvc b/libtommath/makefile.msvc index dbbf9f3..5edebec 100644 --- a/libtommath/makefile.msvc +++ b/libtommath/makefile.msvc @@ -2,7 +2,7 @@ # #Tom St Denis -CFLAGS = /I. /Ox /DWIN32 /W4 +CFLAGS = /I. /Ox /DWIN32 /W3 /Fo$@ default: library @@ -34,5 +34,7 @@ bn_mp_prime_random_ex.obj bn_mp_get_int.obj bn_mp_sqrt.obj bn_mp_is_square.obj \ bn_mp_init_set.obj bn_mp_init_set_int.obj bn_mp_invmod_slow.obj bn_mp_prime_rabin_miller_trials.obj \ bn_mp_to_signed_bin_n.obj bn_mp_to_unsigned_bin_n.obj +HEADERS=tommath.h tommath_class.h tommath_superclass.h + library: $(OBJECTS) lib /out:tommath.lib $(OBJECTS) diff --git a/libtommath/makefile.shared b/libtommath/makefile.shared index 7c35881..821558c 100644 --- a/libtommath/makefile.shared +++ b/libtommath/makefile.shared @@ -1,11 +1,14 @@ #Makefile for GCC # #Tom St Denis -VERSION=0:35 +VERSION=0:36 CC = libtool --mode=compile gcc + CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare +ifndef IGNORE_SPEED + #for speed CFLAGS += -O3 -funroll-loops @@ -15,14 +18,30 @@ CFLAGS += -O3 -funroll-loops #x86 optimizations [should be valid for any GCC install though] CFLAGS += -fomit-frame-pointer +endif + #install as this user -USER=root -GROUP=root +ifndef INSTALL_GROUP + GROUP=wheel +else + GROUP=$(INSTALL_GROUP) +endif + +ifndef INSTALL_USER + USER=root +else + USER=$(INSTALL_USER) +endif default: libtommath.la #default files to install -LIBNAME=libtommath.la +ifndef LIBNAME + LIBNAME=libtommath.la +endif +ifndef LIBNAME_S + LIBNAME_S=libtommath.a +endif HEADERS=tommath.h tommath_class.h tommath_superclass.h #LIBPATH-The directory for libtommath to be installed to. @@ -61,20 +80,20 @@ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_ini bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o - -libtommath.la: $(OBJECTS) - libtool --mode=link gcc *.lo -o libtommath.la -rpath $(LIBPATH) -version-info $(VERSION) - libtool --mode=link gcc *.o -o libtommath.a - libtool --mode=install install -c libtommath.la $(LIBPATH)/libtommath.la +$(LIBNAME): $(OBJECTS) + libtool --mode=link gcc *.lo -o $(LIBNAME) -rpath $(LIBPATH) -version-info $(VERSION) + libtool --mode=link gcc *.o -o $(LIBNAME_S) + ranlib $(LIBNAME_S) + libtool --mode=install install -c $(LIBNAME) $(LIBPATH)/$@ install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) -test: libtommath.a demo/demo.o +test: $(LIBNAME) demo/demo.o gcc $(CFLAGS) -c demo/demo.c -o demo/demo.o - libtool --mode=link gcc -o test demo/demo.o libtommath.la + libtool --mode=link gcc -o test demo/demo.o $(LIBNAME_S) mtest: test - cd mtest ; gcc $(CFLAGS) mtest.c -o mtest -s + cd mtest ; gcc $(CFLAGS) mtest.c -o mtest -timing: libtommath.la - gcc $(CFLAGS) -DTIMER demo/timing.c libtommath.a -o ltmtest -s +timing: $(LIBNAME) + gcc $(CFLAGS) -DTIMER demo/timing.c $(LIBNAME_S) -o ltmtest diff --git a/libtommath/mtest/logtab.h b/libtommath/mtest/logtab.h index 68462bd..4c8774c 100644 --- a/libtommath/mtest/logtab.h +++ b/libtommath/mtest/logtab.h @@ -18,3 +18,7 @@ const float s_logv_2[] = { 0.166666667 }; + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/logtab.h,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/mtest/mpi-config.h b/libtommath/mtest/mpi-config.h index dcdbd35..e6ffbc4 100644 --- a/libtommath/mtest/mpi-config.h +++ b/libtommath/mtest/mpi-config.h @@ -1,5 +1,5 @@ /* Default configuration for MPI library */ -/* $Id: mpi-config.h,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ */ +/* $Id: mpi-config.h,v 1.1.1.2 2005/09/26 16:32:17 kennykb Exp $ */ #ifndef MPI_CONFIG_H_ #define MPI_CONFIG_H_ @@ -84,3 +84,7 @@ /* crc==3287762869, version==2, Sat Feb 02 06:43:53 2002 */ + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/mpi-config.h,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/mtest/mpi-types.h b/libtommath/mtest/mpi-types.h index e097188..96d5967 100644 --- a/libtommath/mtest/mpi-types.h +++ b/libtommath/mtest/mpi-types.h @@ -14,3 +14,7 @@ typedef int mp_err; #define DIGIT_FMT "%04X" #define RADIX (MP_DIGIT_MAX+1) + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/mpi-types.h,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/mtest/mpi.c b/libtommath/mtest/mpi.c index 0517602..1b6f114 100644 --- a/libtommath/mtest/mpi.c +++ b/libtommath/mtest/mpi.c @@ -6,7 +6,7 @@ Arbitrary precision integer arithmetic library - $Id: mpi.c,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ + $Id: mpi.c,v 1.1.1.2 2005/09/26 16:32:17 kennykb Exp $ */ #include "mpi.h" @@ -3979,3 +3979,7 @@ int s_mp_outlen(int bits, int r) /*------------------------------------------------------------------------*/ /* HERE THERE BE DRAGONS */ /* crc==4242132123, version==2, Sat Feb 02 06:43:52 2002 */ + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/mpi.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/mtest/mpi.h b/libtommath/mtest/mpi.h index b7a8cb5..1bd0680 100644 --- a/libtommath/mtest/mpi.h +++ b/libtommath/mtest/mpi.h @@ -6,7 +6,7 @@ Arbitrary precision integer arithmetic library - $Id: mpi.h,v 1.1.1.1 2005/01/19 22:41:29 kennykb Exp $ + $Id: mpi.h,v 1.1.1.2 2005/09/26 16:32:17 kennykb Exp $ */ #ifndef _H_MPI_ @@ -225,3 +225,7 @@ int mp_char2value(char ch, int r); const char *mp_strerror(mp_err ec); #endif /* end _H_MPI_ */ + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/mpi.h,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/mtest/mtest.c b/libtommath/mtest/mtest.c index d46f456..f18dc00 100644 --- a/libtommath/mtest/mtest.c +++ b/libtommath/mtest/mtest.c @@ -302,3 +302,7 @@ int main(void) fclose(rng); return 0; } + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/mtest/mtest.c,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:17 $ */ diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf index 4c3e365..faceef1 100644 Binary files a/libtommath/poster.pdf and b/libtommath/poster.pdf differ diff --git a/libtommath/pre_gen/mpi.c b/libtommath/pre_gen/mpi.c index 8ec8a10..78945ac 100644 --- a/libtommath/pre_gen/mpi.c +++ b/libtommath/pre_gen/mpi.c @@ -43,6 +43,10 @@ char *mp_error_to_string(int code) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_error.c */ /* Start: bn_fast_mp_invmod.c */ @@ -191,6 +195,10 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_fast_mp_invmod.c */ /* Start: bn_fast_mp_montgomery_reduce.c */ @@ -363,6 +371,10 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_fast_mp_montgomery_reduce.c */ /* Start: bn_fast_s_mp_mul_digs.c */ @@ -438,6 +450,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) /* execute loop */ for (iz = 0; iz < iy; ++iz) { _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); + } /* store term */ @@ -472,6 +485,10 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_fast_s_mp_mul_digs.c */ /* Start: bn_fast_s_mp_mul_high_digs.c */ @@ -573,6 +590,10 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_fast_s_mp_mul_high_digs.c */ /* Start: bn_fast_s_mp_sqr.c */ @@ -687,6 +708,10 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_fast_s_mp_sqr.c */ /* Start: bn_mp_2expt.c */ @@ -735,6 +760,10 @@ mp_2expt (mp_int * a, int b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_2expt.c */ /* Start: bn_mp_abs.c */ @@ -778,6 +807,10 @@ mp_abs (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_abs.c */ /* Start: bn_mp_add.c */ @@ -831,6 +864,10 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_add.c */ /* Start: bn_mp_add_d.c */ @@ -940,6 +977,10 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_add_d.c */ /* Start: bn_mp_addmod.c */ @@ -981,6 +1022,10 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_addmod.c */ /* Start: bn_mp_and.c */ @@ -1038,6 +1083,10 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_and.c */ /* Start: bn_mp_clamp.c */ @@ -1082,6 +1131,10 @@ mp_clamp (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_clamp.c */ /* Start: bn_mp_clear.c */ @@ -1126,6 +1179,10 @@ mp_clear (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_clear.c */ /* Start: bn_mp_clear_multi.c */ @@ -1160,6 +1217,10 @@ void mp_clear_multi(mp_int *mp, ...) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_clear_multi.c */ /* Start: bn_mp_cmp.c */ @@ -1203,6 +1264,10 @@ mp_cmp (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_cmp.c */ /* Start: bn_mp_cmp_d.c */ @@ -1247,6 +1312,10 @@ int mp_cmp_d(mp_int * a, mp_digit b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_cmp_d.c */ /* Start: bn_mp_cmp_mag.c */ @@ -1302,6 +1371,10 @@ int mp_cmp_mag (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_cmp_mag.c */ /* Start: bn_mp_cnt_lsb.c */ @@ -1355,6 +1428,10 @@ int mp_cnt_lsb(mp_int *a) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_cnt_lsb.c */ /* Start: bn_mp_copy.c */ @@ -1423,6 +1500,10 @@ mp_copy (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_copy.c */ /* Start: bn_mp_count_bits.c */ @@ -1468,6 +1549,10 @@ mp_count_bits (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_count_bits.c */ /* Start: bn_mp_div.c */ @@ -1760,6 +1845,10 @@ LBL_Q:mp_clear (&q); #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_div.c */ /* Start: bn_mp_div_2.c */ @@ -1828,6 +1917,10 @@ int mp_div_2(mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_div_2.c */ /* Start: bn_mp_div_2d.c */ @@ -1925,6 +2018,10 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_div_2d.c */ /* Start: bn_mp_div_3.c */ @@ -2004,6 +2101,10 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_div_3.c */ /* Start: bn_mp_div_d.c */ @@ -2114,6 +2215,10 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_div_d.c */ /* Start: bn_mp_dr_is_modulus.c */ @@ -2157,6 +2262,10 @@ int mp_dr_is_modulus(mp_int *a) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_dr_is_modulus.c */ /* Start: bn_mp_dr_reduce.c */ @@ -2251,6 +2360,10 @@ top: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_dr_reduce.c */ /* Start: bn_mp_dr_setup.c */ @@ -2283,6 +2396,10 @@ void mp_dr_setup(mp_int *a, mp_digit *d) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_dr_setup.c */ /* Start: bn_mp_exch.c */ @@ -2317,6 +2434,10 @@ mp_exch (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_exch.c */ /* Start: bn_mp_expt_d.c */ @@ -2374,6 +2495,10 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_expt_d.c */ /* Start: bn_mp_exptmod.c */ @@ -2445,7 +2570,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) } /* modified diminished radix reduction */ -#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) +#if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) && defined(BN_S_MP_EXPTMOD_C) if (mp_reduce_is_2k_l(P) == MP_YES) { return s_mp_exptmod(G, X, P, Y, 1); } @@ -2486,6 +2611,10 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_exptmod.c */ /* Start: bn_mp_exptmod_fast.c */ @@ -2807,6 +2936,10 @@ LBL_M: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_exptmod_fast.c */ /* Start: bn_mp_exteuclid.c */ @@ -2889,6 +3022,10 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_exteuclid.c */ /* Start: bn_mp_fread.c */ @@ -2956,6 +3093,10 @@ int mp_fread(mp_int *a, int radix, FILE *stream) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_fread.c */ /* Start: bn_mp_fwrite.c */ @@ -3008,6 +3149,10 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_fwrite.c */ /* Start: bn_mp_gcd.c */ @@ -3121,6 +3266,10 @@ LBL_U:mp_clear (&v); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_gcd.c */ /* Start: bn_mp_get_int.c */ @@ -3166,6 +3315,10 @@ unsigned long mp_get_int(mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_get_int.c */ /* Start: bn_mp_grow.c */ @@ -3223,6 +3376,10 @@ int mp_grow (mp_int * a, int size) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_grow.c */ /* Start: bn_mp_init.c */ @@ -3269,6 +3426,10 @@ int mp_init (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init.c */ /* Start: bn_mp_init_copy.c */ @@ -3301,6 +3462,10 @@ int mp_init_copy (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init_copy.c */ /* Start: bn_mp_init_multi.c */ @@ -3360,6 +3525,10 @@ int mp_init_multi(mp_int *mp, ...) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init_multi.c */ /* Start: bn_mp_init_set.c */ @@ -3392,6 +3561,10 @@ int mp_init_set (mp_int * a, mp_digit b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init_set.c */ /* Start: bn_mp_init_set_int.c */ @@ -3423,6 +3596,10 @@ int mp_init_set_int (mp_int * a, unsigned long b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init_set_int.c */ /* Start: bn_mp_init_size.c */ @@ -3471,6 +3648,10 @@ int mp_init_size (mp_int * a, int size) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_init_size.c */ /* Start: bn_mp_invmod.c */ @@ -3514,6 +3695,10 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_invmod.c */ /* Start: bn_mp_invmod_slow.c */ @@ -3689,6 +3874,10 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_invmod_slow.c */ /* Start: bn_mp_is_square.c */ @@ -3798,6 +3987,10 @@ ERR:mp_clear(&t); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_is_square.c */ /* Start: bn_mp_jacobi.c */ @@ -3903,6 +4096,10 @@ LBL_A1:mp_clear (&a1); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_jacobi.c */ /* Start: bn_mp_karatsuba_mul.c */ @@ -3934,12 +4131,12 @@ LBL_A1:mp_clear (&a1); * b = b1 * B**n + b0 * * Then, a * b => - a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 + a1b1 * B**2n + ((a1 + a0)(b1 + b0) - (a0b0 + a1b1)) * B + a0b0 * * Note that a1b1 and a0b0 are used twice and only need to be * computed once. So in total three half size (half # of * digit) multiplications are performed, a0b0, a1b1 and - * (a1-b1)(a0-b0) + * (a1+b1)(a0+b0) * * Note that a multiplication of half the digits requires * 1/4th the number of single precision multiplications so in @@ -4030,19 +4227,19 @@ int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) goto X1Y1; /* x1y1 = x1*y1 */ - /* now calc x1-x0 and y1-y0 */ - if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + /* now calc x1+x0 and y1+y0 */ + if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) goto X1Y1; /* t1 = x1 - x0 */ - if (mp_sub (&y1, &y0, &x0) != MP_OKAY) + if (s_mp_add (&y1, &y0, &x0) != MP_OKAY) goto X1Y1; /* t2 = y1 - y0 */ if (mp_mul (&t1, &x0, &t1) != MP_OKAY) - goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ + goto X1Y1; /* t1 = (x1 + x0) * (y1 + y0) */ /* add x0y0 */ if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) goto X1Y1; /* t2 = x0y0 + x1y1 */ - if (mp_sub (&x0, &t1, &t1) != MP_OKAY) - goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ + if (s_mp_sub (&t1, &x0, &t1) != MP_OKAY) + goto X1Y1; /* t1 = (x1+x0)*(y1+y0) - (x1y1 + x0y0) */ /* shift by B */ if (mp_lshd (&t1, B) != MP_OKAY) @@ -4070,6 +4267,10 @@ ERR: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_karatsuba_mul.c */ /* Start: bn_mp_karatsuba_sqr.c */ @@ -4155,8 +4356,8 @@ int mp_karatsuba_sqr (mp_int * a, mp_int * b) if (mp_sqr (&x1, &x1x1) != MP_OKAY) goto X1X1; /* x1x1 = x1*x1 */ - /* now calc (x1-x0)**2 */ - if (mp_sub (&x1, &x0, &t1) != MP_OKAY) + /* now calc (x1+x0)**2 */ + if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) goto X1X1; /* t1 = x1 - x0 */ if (mp_sqr (&t1, &t1) != MP_OKAY) goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ @@ -4164,8 +4365,8 @@ int mp_karatsuba_sqr (mp_int * a, mp_int * b) /* add x0y0 */ if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) goto X1X1; /* t2 = x0x0 + x1x1 */ - if (mp_sub (&t2, &t1, &t1) != MP_OKAY) - goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ + if (s_mp_sub (&t1, &t2, &t1) != MP_OKAY) + goto X1X1; /* t1 = (x1+x0)**2 - (x0x0 + x1x1) */ /* shift by B */ if (mp_lshd (&t1, B) != MP_OKAY) @@ -4191,6 +4392,10 @@ ERR: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_karatsuba_sqr.c */ /* Start: bn_mp_lcm.c */ @@ -4251,6 +4456,10 @@ LBL_T: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_lcm.c */ /* Start: bn_mp_lshd.c */ @@ -4318,6 +4527,10 @@ int mp_lshd (mp_int * a, int b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_lshd.c */ /* Start: bn_mp_mod.c */ @@ -4366,6 +4579,10 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mod.c */ /* Start: bn_mp_mod_2d.c */ @@ -4421,6 +4638,10 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mod_2d.c */ /* Start: bn_mp_mod_d.c */ @@ -4448,6 +4669,10 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mod_d.c */ /* Start: bn_mp_montgomery_calc_normalization.c */ @@ -4507,6 +4732,10 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_montgomery_calc_normalization.c */ /* Start: bn_mp_montgomery_reduce.c */ @@ -4625,6 +4854,10 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_montgomery_reduce.c */ /* Start: bn_mp_montgomery_setup.c */ @@ -4684,6 +4917,10 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_montgomery_setup.c */ /* Start: bn_mp_mul.c */ @@ -4750,6 +4987,10 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mul.c */ /* Start: bn_mp_mul_2.c */ @@ -4832,6 +5073,10 @@ int mp_mul_2(mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mul_2.c */ /* Start: bn_mp_mul_2d.c */ @@ -4917,6 +5162,10 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mul_2d.c */ /* Start: bn_mp_mul_d.c */ @@ -4996,6 +5245,10 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mul_d.c */ /* Start: bn_mp_mulmod.c */ @@ -5017,8 +5270,7 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) */ /* d = a * b (mod c) */ -int -mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) +int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) { int res; mp_int t; @@ -5037,6 +5289,10 @@ mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_mulmod.c */ /* Start: bn_mp_n_root.c */ @@ -5169,6 +5425,10 @@ LBL_T1:mp_clear (&t1); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_n_root.c */ /* Start: bn_mp_neg.c */ @@ -5209,6 +5469,10 @@ int mp_neg (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_neg.c */ /* Start: bn_mp_or.c */ @@ -5259,6 +5523,10 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_or.c */ /* Start: bn_mp_prime_fermat.c */ @@ -5321,6 +5589,10 @@ LBL_T:mp_clear (&t); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_fermat.c */ /* Start: bn_mp_prime_is_divisible.c */ @@ -5371,6 +5643,10 @@ int mp_prime_is_divisible (mp_int * a, int *result) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_is_divisible.c */ /* Start: bn_mp_prime_is_prime.c */ @@ -5454,6 +5730,10 @@ LBL_B:mp_clear (&b); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_is_prime.c */ /* Start: bn_mp_prime_miller_rabin.c */ @@ -5557,6 +5837,10 @@ LBL_N1:mp_clear (&n1); } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_miller_rabin.c */ /* Start: bn_mp_prime_next_prime.c */ @@ -5727,6 +6011,10 @@ LBL_ERR: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_next_prime.c */ /* Start: bn_mp_prime_rabin_miller_trials.c */ @@ -5779,6 +6067,10 @@ int mp_prime_rabin_miller_trials(int size) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_rabin_miller_trials.c */ /* Start: bn_mp_prime_random_ex.c */ @@ -5846,10 +6138,8 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback maskOR_msb = 0; maskOR_msb_offset = ((size & 7) == 1) ? 1 : 0; if (flags & LTM_PRIME_2MSB_ON) { - maskOR_msb |= 1 << ((size - 2) & 7); - } else if (flags & LTM_PRIME_2MSB_OFF) { - maskAND &= ~(1 << ((size - 2) & 7)); - } + maskOR_msb |= 0x80 >> ((9 - size) & 7); + } /* get the maskOR_lsb */ maskOR_lsb = 1; @@ -5906,6 +6196,10 @@ error: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_prime_random_ex.c */ /* Start: bn_mp_radix_size.c */ @@ -5984,6 +6278,10 @@ int mp_radix_size (mp_int * a, int radix, int *size) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_radix_size.c */ /* Start: bn_mp_radix_smap.c */ @@ -6008,6 +6306,10 @@ int mp_radix_size (mp_int * a, int radix, int *size) const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz+/"; #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_radix_smap.c */ /* Start: bn_mp_rand.c */ @@ -6063,6 +6365,10 @@ mp_rand (mp_int * a, int digits) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_rand.c */ /* Start: bn_mp_read_radix.c */ @@ -6145,6 +6451,10 @@ int mp_read_radix (mp_int * a, const char *str, int radix) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_read_radix.c */ /* Start: bn_mp_read_signed_bin.c */ @@ -6166,8 +6476,7 @@ int mp_read_radix (mp_int * a, const char *str, int radix) */ /* read signed bin, big endian, first byte is 0==positive or 1==negative */ -int -mp_read_signed_bin (mp_int * a, unsigned char *b, int c) +int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) { int res; @@ -6187,6 +6496,10 @@ mp_read_signed_bin (mp_int * a, unsigned char *b, int c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_read_signed_bin.c */ /* Start: bn_mp_read_unsigned_bin.c */ @@ -6208,8 +6521,7 @@ mp_read_signed_bin (mp_int * a, unsigned char *b, int c) */ /* reads a unsigned char array, assumes the msb is stored first [big endian] */ -int -mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) +int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) { int res; @@ -6243,6 +6555,10 @@ mp_read_unsigned_bin (mp_int * a, unsigned char *b, int c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_read_unsigned_bin.c */ /* Start: bn_mp_reduce.c */ @@ -6343,6 +6659,10 @@ CLEANUP: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce.c */ /* Start: bn_mp_reduce_2k.c */ @@ -6404,6 +6724,10 @@ ERR: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_2k.c */ /* Start: bn_mp_reduce_2k_l.c */ @@ -6466,6 +6790,10 @@ ERR: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_2k_l.c */ /* Start: bn_mp_reduce_2k_setup.c */ @@ -6513,6 +6841,10 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_2k_setup.c */ /* Start: bn_mp_reduce_2k_setup_l.c */ @@ -6557,6 +6889,10 @@ ERR: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_2k_setup_l.c */ /* Start: bn_mp_reduce_is_2k.c */ @@ -6609,6 +6945,10 @@ int mp_reduce_is_2k(mp_int *a) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_is_2k.c */ /* Start: bn_mp_reduce_is_2k_l.c */ @@ -6653,6 +6993,10 @@ int mp_reduce_is_2k_l(mp_int *a) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_is_2k_l.c */ /* Start: bn_mp_reduce_setup.c */ @@ -6687,6 +7031,10 @@ int mp_reduce_setup (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_reduce_setup.c */ /* Start: bn_mp_rshd.c */ @@ -6759,6 +7107,10 @@ void mp_rshd (mp_int * a, int b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_rshd.c */ /* Start: bn_mp_set.c */ @@ -6788,6 +7140,10 @@ void mp_set (mp_int * a, mp_digit b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_set.c */ /* Start: bn_mp_set_int.c */ @@ -6836,6 +7192,10 @@ int mp_set_int (mp_int * a, unsigned long b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_set_int.c */ /* Start: bn_mp_shrink.c */ @@ -6871,6 +7231,10 @@ int mp_shrink (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_shrink.c */ /* Start: bn_mp_signed_bin_size.c */ @@ -6898,6 +7262,10 @@ int mp_signed_bin_size (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_signed_bin_size.c */ /* Start: bn_mp_sqr.c */ @@ -6956,6 +7324,10 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_sqr.c */ /* Start: bn_mp_sqrmod.c */ @@ -6997,6 +7369,10 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_sqrmod.c */ /* Start: bn_mp_sqrt.c */ @@ -7078,6 +7454,10 @@ E2: mp_clear(&t1); #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_sqrt.c */ /* Start: bn_mp_sub.c */ @@ -7137,6 +7517,10 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_sub.c */ /* Start: bn_mp_sub_d.c */ @@ -7226,6 +7610,10 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_sub_d.c */ /* Start: bn_mp_submod.c */ @@ -7268,6 +7656,10 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_submod.c */ /* Start: bn_mp_to_signed_bin.c */ @@ -7301,6 +7693,10 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_to_signed_bin.c */ /* Start: bn_mp_to_signed_bin_n.c */ @@ -7332,6 +7728,10 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_to_signed_bin_n.c */ /* Start: bn_mp_to_unsigned_bin.c */ @@ -7380,6 +7780,10 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_to_unsigned_bin.c */ /* Start: bn_mp_to_unsigned_bin_n.c */ @@ -7411,6 +7815,10 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_to_unsigned_bin_n.c */ /* Start: bn_mp_toom_mul.c */ @@ -7695,6 +8103,10 @@ ERR: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_toom_mul.c */ /* Start: bn_mp_toom_sqr.c */ @@ -7921,6 +8333,10 @@ ERR: #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_toom_sqr.c */ /* Start: bn_mp_toradix.c */ @@ -7996,6 +8412,10 @@ int mp_toradix (mp_int * a, char *str, int radix) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_toradix.c */ /* Start: bn_mp_toradix_n.c */ @@ -8085,6 +8505,10 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_toradix_n.c */ /* Start: bn_mp_unsigned_bin_size.c */ @@ -8113,6 +8537,10 @@ int mp_unsigned_bin_size (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_unsigned_bin_size.c */ /* Start: bn_mp_xor.c */ @@ -8164,6 +8592,10 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_xor.c */ /* Start: bn_mp_zero.c */ @@ -8200,6 +8632,10 @@ void mp_zero (mp_int * a) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_mp_zero.c */ /* Start: bn_prime_tab.c */ @@ -8261,6 +8697,10 @@ const mp_digit ltm_prime_tab[] = { }; #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_prime_tab.c */ /* Start: bn_reverse.c */ @@ -8300,6 +8740,10 @@ bn_reverse (unsigned char *s, int len) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_reverse.c */ /* Start: bn_s_mp_add.c */ @@ -8409,6 +8853,10 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_add.c */ /* Start: bn_s_mp_exptmod.c */ @@ -8428,7 +8876,6 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) * * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org */ - #ifdef MP_LOW_MEM #define TAB_SIZE 32 #else @@ -8662,6 +9109,10 @@ LBL_M: } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_exptmod.c */ /* Start: bn_s_mp_mul_digs.c */ @@ -8752,6 +9203,10 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_mul_digs.c */ /* Start: bn_s_mp_mul_high_digs.c */ @@ -8833,6 +9288,10 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_mul_high_digs.c */ /* Start: bn_s_mp_sqr.c */ @@ -8917,6 +9376,10 @@ int s_mp_sqr (mp_int * a, mp_int * b) } #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_sqr.c */ /* Start: bn_s_mp_sub.c */ @@ -9006,6 +9469,10 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bn_s_mp_sub.c */ /* Start: bncore.c */ @@ -9031,17 +9498,21 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) CPU /Compiler /MUL CUTOFF/SQR CUTOFF ------------------------------------------------------------- Intel P4 Northwood /GCC v3.4.1 / 88/ 128/LTM 0.32 ;-) - AMD Athlon64 /GCC v3.4.4 / 74/ 124/LTM 0.34 + AMD Athlon64 /GCC v3.4.4 / 80/ 120/LTM 0.35 */ -int KARATSUBA_MUL_CUTOFF = 74, /* Min. number of digits before Karatsuba multiplication is used. */ - KARATSUBA_SQR_CUTOFF = 124, /* Min. number of digits before Karatsuba squaring is used. */ +int KARATSUBA_MUL_CUTOFF = 80, /* Min. number of digits before Karatsuba multiplication is used. */ + KARATSUBA_SQR_CUTOFF = 120, /* Min. number of digits before Karatsuba squaring is used. */ TOOM_MUL_CUTOFF = 350, /* no optimal values of these are known yet so set em high */ TOOM_SQR_CUTOFF = 400; #endif +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:22 $ */ + /* End: bncore.c */ diff --git a/libtommath/tommath.h b/libtommath/tommath.h index bcb9d86..43517b4 100644 --- a/libtommath/tommath.h +++ b/libtommath/tommath.h @@ -23,10 +23,13 @@ #include -#undef MIN -#define MIN(x,y) ((x)<(y)?(x):(y)) -#undef MAX -#define MAX(x,y) ((x)>(y)?(x):(y)) +#ifndef MIN + #define MIN(x,y) ((x)<(y)?(x):(y)) +#endif + +#ifndef MAX + #define MAX(x,y) ((x)>(y)?(x):(y)) +#endif #ifdef __cplusplus extern "C" { @@ -112,7 +115,7 @@ extern "C" { #else /* prototypes for our heap functions */ extern void *XMALLOC(size_t n); - extern void *REALLOC(void *p, size_t n); + extern void *XREALLOC(void *p, size_t n); extern void *XCALLOC(size_t n, size_t s); extern void XFREE(void *p); #endif @@ -147,7 +150,6 @@ extern "C" { /* Primality generation flags */ #define LTM_PRIME_BBS 0x0001 /* BBS style prime */ #define LTM_PRIME_SAFE 0x0002 /* Safe prime (p-1)/2 == prime */ -#define LTM_PRIME_2MSB_OFF 0x0004 /* force 2nd MSB to 0 */ #define LTM_PRIME_2MSB_ON 0x0008 /* force 2nd MSB to 1 */ typedef int mp_err; @@ -164,7 +166,7 @@ extern int KARATSUBA_MUL_CUTOFF, /* default precision */ #ifndef MP_PREC #ifndef MP_LOW_MEM - #define MP_PREC 64 /* default digits of precision */ + #define MP_PREC 32 /* default digits of precision */ #else #define MP_PREC 8 /* default digits of precision */ #endif @@ -518,13 +520,13 @@ int mp_prime_random_ex(mp_int *a, int t, int size, int flags, ltm_prime_callback int mp_count_bits(mp_int *a); int mp_unsigned_bin_size(mp_int *a); -int mp_read_unsigned_bin(mp_int *a, unsigned char *b, int c); +int mp_read_unsigned_bin(mp_int *a, const unsigned char *b, int c); int mp_to_unsigned_bin(mp_int *a, unsigned char *b); int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen); int mp_signed_bin_size(mp_int *a); -int mp_read_signed_bin(mp_int *a, unsigned char *b, int c); -int mp_to_signed_bin(mp_int *a, unsigned char *b); +int mp_read_signed_bin(mp_int *a, const unsigned char *b, int c); +int mp_to_signed_bin(mp_int *a, unsigned char *b); int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen); int mp_read_radix(mp_int *a, const char *str, int radix); @@ -576,3 +578,7 @@ extern const char *mp_s_rmap; #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/tommath.h,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:31:58 $ */ diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf index c486d29..08f6a1e 100644 Binary files a/libtommath/tommath.pdf and b/libtommath/tommath.pdf differ diff --git a/libtommath/tommath.src b/libtommath/tommath.src index 7a53860..b392ead 100644 --- a/libtommath/tommath.src +++ b/libtommath/tommath.src @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.35 release of the +This text has been placed in the public domain. This text corresponds to the v0.36 release of the LibTomMath project. \begin{alltt} @@ -2775,26 +2775,25 @@ general purpose multiplication. Given two polynomial basis representations $f(x light algebra \cite{KARAP} that the following polynomial is equivalent to multiplication of the two integers the polynomials represent. \begin{equation} -f(x) \cdot g(x) = acx^2 + ((a - b)(c - d) - (ac + bd))x + bd +f(x) \cdot g(x) = acx^2 + ((a + b)(c + d) - (ac + bd))x + bd \end{equation} Using the observation that $ac$ and $bd$ could be re-used only three half sized multiplications would be required to produce the product. Applying this algorithm recursively, the work factor becomes $O(n^{lg(3)})$ which is substantially better than the work factor $O(n^2)$ of the Comba technique. It turns out what Karatsuba did not know or at least did not publish was that this is simply polynomial basis multiplication with the points -$\zeta_0$, $\zeta_{\infty}$ and $-\zeta_{-1}$. Consider the resultant system of equations. +$\zeta_0$, $\zeta_{\infty}$ and $\zeta_{1}$. Consider the resultant system of equations. \begin{center} \begin{tabular}{rcrcrcrc} $\zeta_{0}$ & $=$ & & & & & $w_0$ \\ -$-\zeta_{-1}$ & $=$ & $-w_2$ & $+$ & $w_1$ & $-$ & $w_0$ \\ +$\zeta_{1}$ & $=$ & $w_2$ & $+$ & $w_1$ & $+$ & $w_0$ \\ $\zeta_{\infty}$ & $=$ & $w_2$ & & & & \\ \end{tabular} \end{center} By adding the first and last equation to the equation in the middle the term $w_1$ can be isolated and all three coefficients solved for. The simplicity of this system of equations has made Karatsuba fairly popular. In fact the cutoff point is often fairly low\footnote{With LibTomMath 0.18 it is 70 and 109 digits for the Intel P4 and AMD Athlon respectively.} -making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. It is worth noting that the point -$\zeta_1$ could be substituted for $-\zeta_{-1}$. In this case the first and third row are subtracted instead of added to the second row. +making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. \newpage\begin{figure}[!here] \begin{small} @@ -2817,13 +2816,13 @@ Split the input. e.g. $a = x1 \cdot \beta^B + x0$ \\ Calculate the three products. \\ 8. $x0y0 \leftarrow x0 \cdot y0$ (\textit{mp\_mul}) \\ 9. $x1y1 \leftarrow x1 \cdot y1$ \\ -10. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ -11. $x0 \leftarrow y1 - y0$ \\ +10. $t1 \leftarrow x1 + x0$ (\textit{mp\_add}) \\ +11. $x0 \leftarrow y1 + y0$ \\ 12. $t1 \leftarrow t1 \cdot x0$ \\ \\ Calculate the middle term. \\ 13. $x0 \leftarrow x0y0 + x1y1$ \\ -14. $t1 \leftarrow x0 - t1$ \\ +14. $t1 \leftarrow t1 - x0$ (\textit{s\_mp\_sub}) \\ \\ Calculate the final product. \\ 15. $t1 \leftarrow t1 \cdot \beta^B$ (\textit{mp\_lshd}) \\ @@ -2850,7 +2849,7 @@ smallest input \textbf{used} count. After the radix point is chosen the inputs compute the lower halves. Step 6 and 7 computer the upper halves. After the halves have been computed the three intermediate half-size products must be computed. Step 8 and 9 compute the trivial products -$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 - x0$ has been computed. By using $x0$ instead +$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 + x0$ has been computed. By using $x0$ instead of an additional temporary variable, the algorithm can avoid an addition memory allocation operation. The remaining steps 13 through 18 compute the Karatsuba polynomial through a variety of digit shifting and addition operations. @@ -3246,10 +3245,10 @@ Let $h(x) = \left ( f(x) \right )^2$ represent the square of the polynomial. Th number with the following equation. \begin{equation} -h(x) = a^2x^2 + \left (a^2 + b^2 - (a - b)^2 \right )x + b^2 +h(x) = a^2x^2 + \left ((a + b)^2 - (a^2 + b^2) \right )x + b^2 \end{equation} -Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a - b)^2$. As in +Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a + b)^2$. As in Karatsuba multiplication, this algorithm can be applied recursively on the input and will achieve an asymptotic running time of $O \left ( n^{lg(3)} \right )$. @@ -3281,12 +3280,12 @@ Split the input. e.g. $a = x1\beta^B + x0$ \\ Calculate the three squares. \\ 6. $x0x0 \leftarrow x0^2$ (\textit{mp\_sqr}) \\ 7. $x1x1 \leftarrow x1^2$ \\ -8. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +8. $t1 \leftarrow x1 + x0$ (\textit{s\_mp\_add}) \\ 9. $t1 \leftarrow t1^2$ \\ \\ Compute the middle term. \\ 10. $t2 \leftarrow x0x0 + x1x1$ (\textit{s\_mp\_add}) \\ -11. $t1 \leftarrow t2 - t1$ \\ +11. $t1 \leftarrow t1 - t2$ \\ \\ Compute final product. \\ 12. $t1 \leftarrow t1\beta^B$ (\textit{mp\_lshd}) \\ @@ -3309,7 +3308,7 @@ The radix point for squaring is simply placed exactly in the middle of the digit placed just below the middle. Step 3, 4 and 5 compute the two halves required using $B$ as the radix point. The first two squares in steps 6 and 7 are rather straightforward while the last square is of a more compact form. -By expanding $\left (x1 - x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $x1^2 + x0^2 - (x1 - x0)^2 = 2 \cdot x0 \cdot x1$. +By expanding $\left (x1 + x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $(x0 - x1)^2 - (x1^2 + x0^2) = 2 \cdot x0 \cdot x1$. Now if $5n$ single precision additions and a squaring of $n$-digits is faster than multiplying two $n$-digit numbers and doubling then this method is faster. Assuming no further recursions occur, the difference can be estimated with the following inequality. @@ -4035,7 +4034,7 @@ To calculate the variable $\rho$ a relatively simple algorithm will be required. \hline \\ 1. $b \leftarrow n_0$ \\ 2. If $b$ is even return(\textit{MP\_VAL}) \\ -3. $x \leftarrow ((b + 2) \mbox{ AND } 4) << 1) + b$ \\ +3. $x \leftarrow (((b + 2) \mbox{ AND } 4) << 1) + b$ \\ 4. for $k$ from 0 to $\lceil lg(lg(\beta)) \rceil - 2$ do \\ \hspace{3mm}4.1 $x \leftarrow x \cdot (2 - bx)$ \\ 5. $\rho \leftarrow \beta - x \mbox{ (mod }\beta\mbox{)}$ \\ diff --git a/libtommath/tommath.tex b/libtommath/tommath.tex index b016010..b69421b 100644 --- a/libtommath/tommath.tex +++ b/libtommath/tommath.tex @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.35 release of the +This text has been placed in the public domain. This text corresponds to the v0.36 release of the LibTomMath project. \begin{alltt} @@ -814,6 +814,7 @@ decrementally. 039 return MP_OKAY; 040 \} 041 #endif +042 \end{alltt} \end{small} @@ -902,6 +903,7 @@ with the exception of algorithms mp\_init, mp\_init\_copy, mp\_init\_size and mp 037 \} 038 \} 039 #endif +040 \end{alltt} \end{small} @@ -1008,6 +1010,7 @@ assumed to contain undefined values they are initially set to zero. 050 return MP_OKAY; 051 \} 052 #endif +053 \end{alltt} \end{small} @@ -1096,6 +1099,7 @@ correct no further memory re-allocations are required to work with the mp\_int. 041 return MP_OKAY; 042 \} 043 #endif +044 \end{alltt} \end{small} @@ -1183,6 +1187,7 @@ initialization which allows for quick recovery from runtime errors. 052 \} 053 054 #endif +055 \end{alltt} \end{small} @@ -1268,6 +1273,7 @@ when all of the digits are zero to ensure that the mp\_int is valid at all times 037 \} 038 \} 039 #endif +040 \end{alltt} \end{small} @@ -1405,6 +1411,7 @@ implement the pseudo-code. 061 return MP_OKAY; 062 \} 063 #endif +064 \end{alltt} \end{small} @@ -1519,6 +1526,7 @@ such this algorithm will perform two operations in one step. 025 return mp_copy (b, a); 026 \} 027 #endif +028 \end{alltt} \end{small} @@ -1570,6 +1578,7 @@ This algorithm simply resets a mp\_int to the default state. 029 \} 030 \} 031 #endif +032 \end{alltt} \end{small} @@ -1631,6 +1640,7 @@ logic to handle it. 036 return MP_OKAY; 037 \} 038 #endif +039 \end{alltt} \end{small} @@ -1692,6 +1702,7 @@ zero as negative. 033 return MP_OKAY; 034 \} 035 #endif +036 \end{alltt} \end{small} @@ -1739,6 +1750,7 @@ single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adj 022 a->used = (a->dp[0] != 0) ? 1 : 0; 023 \} 024 #endif +025 \end{alltt} \end{small} @@ -1819,6 +1831,7 @@ Excess zero digits are trimmed in steps 2.1 and 3 by using higher level algorith 041 return MP_OKAY; 042 \} 043 #endif +044 \end{alltt} \end{small} @@ -1921,6 +1934,7 @@ the zero'th digit. If after all of the digits have been compared, no difference 048 return MP_EQ; 049 \} 050 #endif +051 \end{alltt} \end{small} @@ -1987,6 +2001,7 @@ $\vert a \vert < \vert b \vert$. Step number four will compare the two when the 036 \} 037 \} 038 #endif +039 \end{alltt} \end{small} @@ -2205,6 +2220,7 @@ The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are 102 return MP_OKAY; 103 \} 104 #endif +105 \end{alltt} \end{small} @@ -2376,6 +2392,7 @@ If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and cop 082 \} 083 084 #endif +085 \end{alltt} \end{small} @@ -2511,6 +2528,7 @@ within algorithm s\_mp\_add will force $-0$ to become $0$. 046 \} 047 048 #endif +049 \end{alltt} \end{small} @@ -2623,6 +2641,7 @@ algorithm from producing $-a - -a = -0$ as a result. 052 \} 053 054 #endif +055 \end{alltt} \end{small} @@ -2757,6 +2776,7 @@ Step 8 clears any leading digits of $b$ in case it originally had a larger magni 075 return MP_OKAY; 076 \} 077 #endif +078 \end{alltt} \end{small} @@ -2857,6 +2877,7 @@ least significant bit not the most significant bit. 061 return MP_OKAY; 062 \} 063 #endif +064 \end{alltt} \end{small} @@ -2977,6 +2998,7 @@ step 8 sets the lower $b$ digits to zero. 060 return MP_OKAY; 061 \} 062 #endif +063 \end{alltt} \end{small} @@ -3088,6 +3110,7 @@ Once the window copy is complete the upper digits must be zeroed and the \textbf 065 a->used -= b; 066 \} 067 #endif +068 \end{alltt} \end{small} @@ -3221,6 +3244,7 @@ complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm 078 return MP_OKAY; 079 \} 080 #endif +081 \end{alltt} \end{small} @@ -3357,6 +3381,7 @@ by using algorithm mp\_mod\_2d. 090 return MP_OKAY; 091 \} 092 #endif +093 \end{alltt} \end{small} @@ -3448,6 +3473,7 @@ is copied to $b$, leading digits are removed and the remaining leading digit is 048 return MP_OKAY; 049 \} 050 #endif +051 \end{alltt} \end{small} @@ -3687,6 +3713,7 @@ exceed the precision requested. 083 return MP_OKAY; 084 \} 085 #endif +086 \end{alltt} \end{small} @@ -3942,39 +3969,41 @@ and addition operations in the nested loop in parallel. 069 /* execute loop */ 070 for (iz = 0; iz < iy; ++iz) \{ 071 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); -072 \} -073 -074 /* store term */ -075 W[ix] = ((mp_digit)_W) & MP_MASK; -076 -077 /* make next carry */ -078 _W = _W >> ((mp_word)DIGIT_BIT); -079 \} -080 -081 /* store final carry */ -082 W[ix] = (mp_digit)(_W & MP_MASK); -083 -084 /* setup dest */ -085 olduse = c->used; -086 c->used = pa; -087 -088 \{ -089 register mp_digit *tmpc; -090 tmpc = c->dp; -091 for (ix = 0; ix < pa+1; ix++) \{ -092 /* now extract the previous digit [below the carry] */ -093 *tmpc++ = W[ix]; -094 \} -095 -096 /* clear unused digits [that existed in the old copy of c] */ -097 for (; ix < olduse; ix++) \{ -098 *tmpc++ = 0; -099 \} -100 \} -101 mp_clamp (c); -102 return MP_OKAY; -103 \} -104 #endif +072 +073 \} +074 +075 /* store term */ +076 W[ix] = ((mp_digit)_W) & MP_MASK; +077 +078 /* make next carry */ +079 _W = _W >> ((mp_word)DIGIT_BIT); +080 \} +081 +082 /* store final carry */ +083 W[ix] = (mp_digit)(_W & MP_MASK); +084 +085 /* setup dest */ +086 olduse = c->used; +087 c->used = pa; +088 +089 \{ +090 register mp_digit *tmpc; +091 tmpc = c->dp; +092 for (ix = 0; ix < pa+1; ix++) \{ +093 /* now extract the previous digit [below the carry] */ +094 *tmpc++ = W[ix]; +095 \} +096 +097 /* clear unused digits [that existed in the old copy of c] */ +098 for (; ix < olduse; ix++) \{ +099 *tmpc++ = 0; +100 \} +101 \} +102 mp_clamp (c); +103 return MP_OKAY; +104 \} +105 #endif +106 \end{alltt} \end{small} @@ -3982,7 +4011,7 @@ As per the pseudo--code we first calculate $pa$ (line 47) as the number of digit to produce the individual columns of the product. We use the two aliases $tmpx$ and $tmpy$ (lines 61, 62) to point inside the two multiplicands quickly. -The inner loop (lines 70 to 72) of this implementation is where the tradeoff come into play. Originally this comba +The inner loop (lines 70 to 73) of this implementation is where the tradeoff come into play. Originally this comba implementation was ``row--major'' which means it adds to each of the columns in each pass. After the outer loop it would then fix the carries. This was very fast except it had an annoying drawback. You had to read a mp\_word and two mp\_digits and write one mp\_word per iteration. On processors such as the Athlon XP and P4 this did not matter much since the cache bandwidth @@ -3990,8 +4019,8 @@ is very high and it can keep the ALU fed with data. It did, however, matter on slower and also often doesn't exist. This new algorithm only performs two reads per iteration under the assumption that the compiler has aliased $\_ \hat W$ to a CPU register. -After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines 75, 78) to forward it as -a carry for the next pass. After the outer loop we use the final carry (line 82) as the last digit of the product. +After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines 76, 79) to forward it as +a carry for the next pass. After the outer loop we use the final carry (line 83) as the last digit of the product. \subsection{Polynomial Basis Multiplication} To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms @@ -4095,26 +4124,25 @@ general purpose multiplication. Given two polynomial basis representations $f(x light algebra \cite{KARAP} that the following polynomial is equivalent to multiplication of the two integers the polynomials represent. \begin{equation} -f(x) \cdot g(x) = acx^2 + ((a - b)(c - d) - (ac + bd))x + bd +f(x) \cdot g(x) = acx^2 + ((a + b)(c + d) - (ac + bd))x + bd \end{equation} Using the observation that $ac$ and $bd$ could be re-used only three half sized multiplications would be required to produce the product. Applying this algorithm recursively, the work factor becomes $O(n^{lg(3)})$ which is substantially better than the work factor $O(n^2)$ of the Comba technique. It turns out what Karatsuba did not know or at least did not publish was that this is simply polynomial basis multiplication with the points -$\zeta_0$, $\zeta_{\infty}$ and $-\zeta_{-1}$. Consider the resultant system of equations. +$\zeta_0$, $\zeta_{\infty}$ and $\zeta_{1}$. Consider the resultant system of equations. \begin{center} \begin{tabular}{rcrcrcrc} $\zeta_{0}$ & $=$ & & & & & $w_0$ \\ -$-\zeta_{-1}$ & $=$ & $-w_2$ & $+$ & $w_1$ & $-$ & $w_0$ \\ +$\zeta_{1}$ & $=$ & $w_2$ & $+$ & $w_1$ & $+$ & $w_0$ \\ $\zeta_{\infty}$ & $=$ & $w_2$ & & & & \\ \end{tabular} \end{center} By adding the first and last equation to the equation in the middle the term $w_1$ can be isolated and all three coefficients solved for. The simplicity of this system of equations has made Karatsuba fairly popular. In fact the cutoff point is often fairly low\footnote{With LibTomMath 0.18 it is 70 and 109 digits for the Intel P4 and AMD Athlon respectively.} -making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. It is worth noting that the point -$\zeta_1$ could be substituted for $-\zeta_{-1}$. In this case the first and third row are subtracted instead of added to the second row. +making it an ideal algorithm to speed up certain public key cryptosystems such as RSA and Diffie-Hellman. \newpage\begin{figure}[!here] \begin{small} @@ -4137,13 +4165,13 @@ Split the input. e.g. $a = x1 \cdot \beta^B + x0$ \\ Calculate the three products. \\ 8. $x0y0 \leftarrow x0 \cdot y0$ (\textit{mp\_mul}) \\ 9. $x1y1 \leftarrow x1 \cdot y1$ \\ -10. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ -11. $x0 \leftarrow y1 - y0$ \\ +10. $t1 \leftarrow x1 + x0$ (\textit{mp\_add}) \\ +11. $x0 \leftarrow y1 + y0$ \\ 12. $t1 \leftarrow t1 \cdot x0$ \\ \\ Calculate the middle term. \\ 13. $x0 \leftarrow x0y0 + x1y1$ \\ -14. $t1 \leftarrow x0 - t1$ \\ +14. $t1 \leftarrow t1 - x0$ (\textit{s\_mp\_sub}) \\ \\ Calculate the final product. \\ 15. $t1 \leftarrow t1 \cdot \beta^B$ (\textit{mp\_lshd}) \\ @@ -4170,7 +4198,7 @@ smallest input \textbf{used} count. After the radix point is chosen the inputs compute the lower halves. Step 6 and 7 computer the upper halves. After the halves have been computed the three intermediate half-size products must be computed. Step 8 and 9 compute the trivial products -$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 - x0$ has been computed. By using $x0$ instead +$x0 \cdot y0$ and $x1 \cdot y1$. The mp\_int $x0$ is used as a temporary variable after $x1 + x0$ has been computed. By using $x0$ instead of an additional temporary variable, the algorithm can avoid an addition memory allocation operation. The remaining steps 13 through 18 compute the Karatsuba polynomial through a variety of digit shifting and addition operations. @@ -4191,12 +4219,12 @@ The remaining steps 13 through 18 compute the Karatsuba polynomial through a var 025 * b = b1 * B**n + b0 026 * 027 * Then, a * b => -028 a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 +028 a1b1 * B**2n + ((a1 + a0)(b1 + b0) - (a0b0 + a1b1)) * B + a0b0 029 * 030 * Note that a1b1 and a0b0 are used twice and only need to be 031 * computed once. So in total three half size (half # of 032 * digit) multiplications are performed, a0b0, a1b1 and -033 * (a1-b1)(a0-b0) +033 * (a1+b1)(a0+b0) 034 * 035 * Note that a multiplication of half the digits requires 036 * 1/4th the number of single precision multiplications so in @@ -4287,19 +4315,19 @@ The remaining steps 13 through 18 compute the Karatsuba polynomial through a var 121 if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) 122 goto X1Y1; /* x1y1 = x1*y1 */ 123 -124 /* now calc x1-x0 and y1-y0 */ -125 if (mp_sub (&x1, &x0, &t1) != MP_OKAY) +124 /* now calc x1+x0 and y1+y0 */ +125 if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) 126 goto X1Y1; /* t1 = x1 - x0 */ -127 if (mp_sub (&y1, &y0, &x0) != MP_OKAY) +127 if (s_mp_add (&y1, &y0, &x0) != MP_OKAY) 128 goto X1Y1; /* t2 = y1 - y0 */ 129 if (mp_mul (&t1, &x0, &t1) != MP_OKAY) -130 goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ +130 goto X1Y1; /* t1 = (x1 + x0) * (y1 + y0) */ 131 132 /* add x0y0 */ 133 if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) 134 goto X1Y1; /* t2 = x0y0 + x1y1 */ -135 if (mp_sub (&x0, &t1, &t1) != MP_OKAY) -136 goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ +135 if (s_mp_sub (&t1, &x0, &t1) != MP_OKAY) +136 goto X1Y1; /* t1 = (x1+x0)*(y1+y0) - (x1y1 + x0y0) */ 137 138 /* shift by B */ 139 if (mp_lshd (&t1, B) != MP_OKAY) @@ -4326,6 +4354,7 @@ The remaining steps 13 through 18 compute the Karatsuba polynomial through a var 160 return err; 161 \} 162 #endif +163 \end{alltt} \end{small} @@ -4729,6 +4758,7 @@ result $a \cdot b$ is produced. 277 \} 278 279 #endif +280 \end{alltt} \end{small} @@ -4837,6 +4867,7 @@ s\_mp\_mul\_digs will clear it. 059 return res; 060 \} 061 #endif +062 \end{alltt} \end{small} @@ -5006,6 +5037,7 @@ results calculated so far. This involves expensive carry propagation which will 077 return MP_OKAY; 078 \} 079 #endif +080 \end{alltt} \end{small} @@ -5188,6 +5220,7 @@ only to even outputs and it is the square of the term at the $\lfloor ix / 2 \rf 107 return MP_OKAY; 108 \} 109 #endif +110 \end{alltt} \end{small} @@ -5205,10 +5238,10 @@ Let $h(x) = \left ( f(x) \right )^2$ represent the square of the polynomial. Th number with the following equation. \begin{equation} -h(x) = a^2x^2 + \left (a^2 + b^2 - (a - b)^2 \right )x + b^2 +h(x) = a^2x^2 + \left ((a + b)^2 - (a^2 + b^2) \right )x + b^2 \end{equation} -Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a - b)^2$. As in +Upon closer inspection this equation only requires the calculation of three half-sized squares: $a^2$, $b^2$ and $(a + b)^2$. As in Karatsuba multiplication, this algorithm can be applied recursively on the input and will achieve an asymptotic running time of $O \left ( n^{lg(3)} \right )$. @@ -5240,12 +5273,12 @@ Split the input. e.g. $a = x1\beta^B + x0$ \\ Calculate the three squares. \\ 6. $x0x0 \leftarrow x0^2$ (\textit{mp\_sqr}) \\ 7. $x1x1 \leftarrow x1^2$ \\ -8. $t1 \leftarrow x1 - x0$ (\textit{mp\_sub}) \\ +8. $t1 \leftarrow x1 + x0$ (\textit{s\_mp\_add}) \\ 9. $t1 \leftarrow t1^2$ \\ \\ Compute the middle term. \\ 10. $t2 \leftarrow x0x0 + x1x1$ (\textit{s\_mp\_add}) \\ -11. $t1 \leftarrow t2 - t1$ \\ +11. $t1 \leftarrow t1 - t2$ \\ \\ Compute final product. \\ 12. $t1 \leftarrow t1\beta^B$ (\textit{mp\_lshd}) \\ @@ -5268,7 +5301,7 @@ The radix point for squaring is simply placed exactly in the middle of the digit placed just below the middle. Step 3, 4 and 5 compute the two halves required using $B$ as the radix point. The first two squares in steps 6 and 7 are rather straightforward while the last square is of a more compact form. -By expanding $\left (x1 - x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $x1^2 + x0^2 - (x1 - x0)^2 = 2 \cdot x0 \cdot x1$. +By expanding $\left (x1 + x0 \right )^2$, the $x1^2$ and $x0^2$ terms in the middle disappear, that is $(x0 - x1)^2 - (x1^2 + x0^2) = 2 \cdot x0 \cdot x1$. Now if $5n$ single precision additions and a squaring of $n$-digits is faster than multiplying two $n$-digit numbers and doubling then this method is faster. Assuming no further recursions occur, the difference can be estimated with the following inequality. @@ -5363,8 +5396,8 @@ ratio of 1:7. } than simpler operations such as addition. 079 if (mp_sqr (&x1, &x1x1) != MP_OKAY) 080 goto X1X1; /* x1x1 = x1*x1 */ 081 -082 /* now calc (x1-x0)**2 */ -083 if (mp_sub (&x1, &x0, &t1) != MP_OKAY) +082 /* now calc (x1+x0)**2 */ +083 if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) 084 goto X1X1; /* t1 = x1 - x0 */ 085 if (mp_sqr (&t1, &t1) != MP_OKAY) 086 goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ @@ -5372,8 +5405,8 @@ ratio of 1:7. } than simpler operations such as addition. 088 /* add x0y0 */ 089 if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) 090 goto X1X1; /* t2 = x0x0 + x1x1 */ -091 if (mp_sub (&t2, &t1, &t1) != MP_OKAY) -092 goto X1X1; /* t1 = x0x0 + x1x1 - (x1-x0)*(x1-x0) */ +091 if (s_mp_sub (&t1, &t2, &t1) != MP_OKAY) +092 goto X1X1; /* t1 = (x1+x0)**2 - (x0x0 + x1x1) */ 093 094 /* shift by B */ 095 if (mp_lshd (&t1, B) != MP_OKAY) @@ -5398,6 +5431,7 @@ ratio of 1:7. } than simpler operations such as addition. 114 return err; 115 \} 116 #endif +117 \end{alltt} \end{small} @@ -5494,6 +5528,7 @@ neither of the polynomial basis algorithms should be used then either the Comba 051 return res; 052 \} 053 #endif +054 \end{alltt} \end{small} @@ -5827,6 +5862,7 @@ performed at most twice, and on average once. However, if $a \ge b^2$ than it wi 093 return res; 094 \} 095 #endif +096 \end{alltt} \end{small} @@ -5879,6 +5915,7 @@ is equivalent and much faster. The final value is computed by taking the intege 027 return mp_div (a, b, a, NULL); 028 \} 029 #endif +030 \end{alltt} \end{small} @@ -6234,6 +6271,7 @@ multiplications. 111 return MP_OKAY; 112 \} 113 #endif +114 \end{alltt} \end{small} @@ -6478,6 +6516,7 @@ stored in the destination $x$. 165 return MP_OKAY; 166 \} 167 #endif +168 \end{alltt} \end{small} @@ -6505,7 +6544,7 @@ To calculate the variable $\rho$ a relatively simple algorithm will be required. \hline \\ 1. $b \leftarrow n_0$ \\ 2. If $b$ is even return(\textit{MP\_VAL}) \\ -3. $x \leftarrow ((b + 2) \mbox{ AND } 4) << 1) + b$ \\ +3. $x \leftarrow (((b + 2) \mbox{ AND } 4) << 1) + b$ \\ 4. for $k$ from 0 to $\lceil lg(lg(\beta)) \rceil - 2$ do \\ \hspace{3mm}4.1 $x \leftarrow x \cdot (2 - bx)$ \\ 5. $\rho \leftarrow \beta - x \mbox{ (mod }\beta\mbox{)}$ \\ @@ -6564,6 +6603,7 @@ to calculate $1/n_0$ when $\beta$ is a power of two. 052 return MP_OKAY; 053 \} 054 #endif +055 \end{alltt} \end{small} @@ -6830,6 +6870,7 @@ at step 3. 087 return MP_OKAY; 088 \} 089 #endif +090 \end{alltt} \end{small} @@ -6885,6 +6926,7 @@ completeness. 025 \} 026 027 #endif +028 \end{alltt} \end{small} @@ -6943,6 +6985,7 @@ step 3 then $n$ must be of Diminished Radix form. 036 \} 037 038 #endif +039 \end{alltt} \end{small} @@ -7027,6 +7070,7 @@ shift which makes the algorithm fairly inexpensive to use. 054 \} 055 056 #endif +057 \end{alltt} \end{small} @@ -7096,6 +7140,7 @@ is sufficient to solve for $k$. Alternatively if $n$ has more than one digit th 040 return MP_OKAY; 041 \} 042 #endif +043 \end{alltt} \end{small} @@ -7172,6 +7217,7 @@ This algorithm quickly determines if a modulus is of the form required for algor 045 \} 046 047 #endif +048 \end{alltt} \end{small} @@ -7381,6 +7427,7 @@ iteration of the loop moves the bits of the exponent $b$ upwards to the most sig 050 return MP_OKAY; 051 \} 052 #endif +053 \end{alltt} \end{small} @@ -7620,7 +7667,8 @@ algorithm since their arguments are essentially the same (\textit{two mp\_ints a 065 \} 066 067 /* modified diminished radix reduction */ -068 #if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) +068 #if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) && defin + ed(BN_S_MP_EXPTMOD_C) 069 if (mp_reduce_is_2k_l(P) == MP_YES) \{ 070 return s_mp_exptmod(G, X, P, Y, 1); 071 \} @@ -7660,6 +7708,7 @@ algorithm since their arguments are essentially the same (\textit{two mp\_ints a 105 \} 106 107 #endif +108 \end{alltt} \end{small} @@ -7839,251 +7888,251 @@ a Left-to-Right algorithm is used to process the remaining few bits. \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_exptmod.c \vspace{-3mm} \begin{alltt} -016 -017 #ifdef MP_LOW_MEM -018 #define TAB_SIZE 32 -019 #else -020 #define TAB_SIZE 256 -021 #endif -022 -023 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmod +016 #ifdef MP_LOW_MEM +017 #define TAB_SIZE 32 +018 #else +019 #define TAB_SIZE 256 +020 #endif +021 +022 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmod e) -024 \{ -025 mp_int M[TAB_SIZE], res, mu; -026 mp_digit buf; -027 int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; -028 int (*redux)(mp_int*,mp_int*,mp_int*); -029 -030 /* find window size */ -031 x = mp_count_bits (X); -032 if (x <= 7) \{ -033 winsize = 2; -034 \} else if (x <= 36) \{ -035 winsize = 3; -036 \} else if (x <= 140) \{ -037 winsize = 4; -038 \} else if (x <= 450) \{ -039 winsize = 5; -040 \} else if (x <= 1303) \{ -041 winsize = 6; -042 \} else if (x <= 3529) \{ -043 winsize = 7; -044 \} else \{ -045 winsize = 8; -046 \} -047 -048 #ifdef MP_LOW_MEM -049 if (winsize > 5) \{ -050 winsize = 5; -051 \} -052 #endif -053 -054 /* init M array */ -055 /* init first cell */ -056 if ((err = mp_init(&M[1])) != MP_OKAY) \{ -057 return err; -058 \} -059 -060 /* now init the second half of the array */ -061 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -062 if ((err = mp_init(&M[x])) != MP_OKAY) \{ -063 for (y = 1<<(winsize-1); y < x; y++) \{ -064 mp_clear (&M[y]); -065 \} -066 mp_clear(&M[1]); -067 return err; -068 \} -069 \} -070 -071 /* create mu, used for Barrett reduction */ -072 if ((err = mp_init (&mu)) != MP_OKAY) \{ -073 goto LBL_M; -074 \} -075 -076 if (redmode == 0) \{ -077 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ -078 goto LBL_MU; -079 \} -080 redux = mp_reduce; -081 \} else \{ -082 if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) \{ -083 goto LBL_MU; -084 \} -085 redux = mp_reduce_2k_l; -086 \} -087 -088 /* create M table -089 * -090 * The M table contains powers of the base, -091 * e.g. M[x] = G**x mod P -092 * -093 * The first half of the table is not -094 * computed though accept for M[0] and M[1] -095 */ -096 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ -097 goto LBL_MU; -098 \} -099 -100 /* compute the value at M[1<<(winsize-1)] by squaring -101 * M[1] (winsize-1) times -102 */ -103 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ -104 goto LBL_MU; -105 \} -106 -107 for (x = 0; x < (winsize - 1); x++) \{ -108 /* square it */ -109 if ((err = mp_sqr (&M[1 << (winsize - 1)], -110 &M[1 << (winsize - 1)])) != MP_OKAY) \{ -111 goto LBL_MU; -112 \} -113 -114 /* reduce modulo P */ -115 if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ -116 goto LBL_MU; -117 \} -118 \} -119 -120 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) -121 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) -122 */ -123 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ -124 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ -125 goto LBL_MU; -126 \} -127 if ((err = redux (&M[x], P, &mu)) != MP_OKAY) \{ -128 goto LBL_MU; -129 \} -130 \} -131 -132 /* setup result */ -133 if ((err = mp_init (&res)) != MP_OKAY) \{ -134 goto LBL_MU; -135 \} -136 mp_set (&res, 1); -137 -138 /* set initial mode and bit cnt */ -139 mode = 0; -140 bitcnt = 1; -141 buf = 0; -142 digidx = X->used - 1; -143 bitcpy = 0; -144 bitbuf = 0; -145 -146 for (;;) \{ -147 /* grab next digit as required */ -148 if (--bitcnt == 0) \{ -149 /* if digidx == -1 we are out of digits */ -150 if (digidx == -1) \{ -151 break; -152 \} -153 /* read next digit and reset the bitcnt */ -154 buf = X->dp[digidx--]; -155 bitcnt = (int) DIGIT_BIT; -156 \} -157 -158 /* grab the next msb from the exponent */ -159 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; -160 buf <<= (mp_digit)1; -161 -162 /* if the bit is zero and mode == 0 then we ignore it -163 * These represent the leading zero bits before the first 1 bit -164 * in the exponent. Technically this opt is not required but it -165 * does lower the # of trivial squaring/reductions used -166 */ -167 if (mode == 0 && y == 0) \{ -168 continue; -169 \} -170 -171 /* if the bit is zero and mode == 1 then we square */ -172 if (mode == 1 && y == 0) \{ -173 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -174 goto LBL_RES; -175 \} -176 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -177 goto LBL_RES; -178 \} -179 continue; -180 \} -181 -182 /* else we add it to the window */ -183 bitbuf |= (y << (winsize - ++bitcpy)); -184 mode = 2; -185 -186 if (bitcpy == winsize) \{ -187 /* ok window is filled so square as required and multiply */ -188 /* square first */ -189 for (x = 0; x < winsize; x++) \{ -190 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -191 goto LBL_RES; -192 \} -193 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -194 goto LBL_RES; -195 \} -196 \} -197 -198 /* then multiply */ -199 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ -200 goto LBL_RES; -201 \} -202 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -203 goto LBL_RES; -204 \} -205 -206 /* empty window and reset */ -207 bitcpy = 0; -208 bitbuf = 0; -209 mode = 1; -210 \} -211 \} -212 -213 /* if bits remain then square/multiply */ -214 if (mode == 2 && bitcpy > 0) \{ -215 /* square then multiply if the bit is set */ -216 for (x = 0; x < bitcpy; x++) \{ -217 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -218 goto LBL_RES; -219 \} -220 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -221 goto LBL_RES; -222 \} -223 -224 bitbuf <<= 1; -225 if ((bitbuf & (1 << winsize)) != 0) \{ -226 /* then multiply */ -227 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ -228 goto LBL_RES; -229 \} -230 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -231 goto LBL_RES; -232 \} -233 \} -234 \} -235 \} -236 -237 mp_exch (&res, Y); -238 err = MP_OKAY; -239 LBL_RES:mp_clear (&res); -240 LBL_MU:mp_clear (&mu); -241 LBL_M: -242 mp_clear(&M[1]); -243 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -244 mp_clear (&M[x]); -245 \} -246 return err; -247 \} -248 #endif +023 \{ +024 mp_int M[TAB_SIZE], res, mu; +025 mp_digit buf; +026 int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; +027 int (*redux)(mp_int*,mp_int*,mp_int*); +028 +029 /* find window size */ +030 x = mp_count_bits (X); +031 if (x <= 7) \{ +032 winsize = 2; +033 \} else if (x <= 36) \{ +034 winsize = 3; +035 \} else if (x <= 140) \{ +036 winsize = 4; +037 \} else if (x <= 450) \{ +038 winsize = 5; +039 \} else if (x <= 1303) \{ +040 winsize = 6; +041 \} else if (x <= 3529) \{ +042 winsize = 7; +043 \} else \{ +044 winsize = 8; +045 \} +046 +047 #ifdef MP_LOW_MEM +048 if (winsize > 5) \{ +049 winsize = 5; +050 \} +051 #endif +052 +053 /* init M array */ +054 /* init first cell */ +055 if ((err = mp_init(&M[1])) != MP_OKAY) \{ +056 return err; +057 \} +058 +059 /* now init the second half of the array */ +060 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +061 if ((err = mp_init(&M[x])) != MP_OKAY) \{ +062 for (y = 1<<(winsize-1); y < x; y++) \{ +063 mp_clear (&M[y]); +064 \} +065 mp_clear(&M[1]); +066 return err; +067 \} +068 \} +069 +070 /* create mu, used for Barrett reduction */ +071 if ((err = mp_init (&mu)) != MP_OKAY) \{ +072 goto LBL_M; +073 \} +074 +075 if (redmode == 0) \{ +076 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ +077 goto LBL_MU; +078 \} +079 redux = mp_reduce; +080 \} else \{ +081 if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) \{ +082 goto LBL_MU; +083 \} +084 redux = mp_reduce_2k_l; +085 \} +086 +087 /* create M table +088 * +089 * The M table contains powers of the base, +090 * e.g. M[x] = G**x mod P +091 * +092 * The first half of the table is not +093 * computed though accept for M[0] and M[1] +094 */ +095 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ +096 goto LBL_MU; +097 \} +098 +099 /* compute the value at M[1<<(winsize-1)] by squaring +100 * M[1] (winsize-1) times +101 */ +102 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ +103 goto LBL_MU; +104 \} +105 +106 for (x = 0; x < (winsize - 1); x++) \{ +107 /* square it */ +108 if ((err = mp_sqr (&M[1 << (winsize - 1)], +109 &M[1 << (winsize - 1)])) != MP_OKAY) \{ +110 goto LBL_MU; +111 \} +112 +113 /* reduce modulo P */ +114 if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ +115 goto LBL_MU; +116 \} +117 \} +118 +119 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) +120 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) +121 */ +122 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ +123 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ +124 goto LBL_MU; +125 \} +126 if ((err = redux (&M[x], P, &mu)) != MP_OKAY) \{ +127 goto LBL_MU; +128 \} +129 \} +130 +131 /* setup result */ +132 if ((err = mp_init (&res)) != MP_OKAY) \{ +133 goto LBL_MU; +134 \} +135 mp_set (&res, 1); +136 +137 /* set initial mode and bit cnt */ +138 mode = 0; +139 bitcnt = 1; +140 buf = 0; +141 digidx = X->used - 1; +142 bitcpy = 0; +143 bitbuf = 0; +144 +145 for (;;) \{ +146 /* grab next digit as required */ +147 if (--bitcnt == 0) \{ +148 /* if digidx == -1 we are out of digits */ +149 if (digidx == -1) \{ +150 break; +151 \} +152 /* read next digit and reset the bitcnt */ +153 buf = X->dp[digidx--]; +154 bitcnt = (int) DIGIT_BIT; +155 \} +156 +157 /* grab the next msb from the exponent */ +158 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; +159 buf <<= (mp_digit)1; +160 +161 /* if the bit is zero and mode == 0 then we ignore it +162 * These represent the leading zero bits before the first 1 bit +163 * in the exponent. Technically this opt is not required but it +164 * does lower the # of trivial squaring/reductions used +165 */ +166 if (mode == 0 && y == 0) \{ +167 continue; +168 \} +169 +170 /* if the bit is zero and mode == 1 then we square */ +171 if (mode == 1 && y == 0) \{ +172 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +173 goto LBL_RES; +174 \} +175 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +176 goto LBL_RES; +177 \} +178 continue; +179 \} +180 +181 /* else we add it to the window */ +182 bitbuf |= (y << (winsize - ++bitcpy)); +183 mode = 2; +184 +185 if (bitcpy == winsize) \{ +186 /* ok window is filled so square as required and multiply */ +187 /* square first */ +188 for (x = 0; x < winsize; x++) \{ +189 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +190 goto LBL_RES; +191 \} +192 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +193 goto LBL_RES; +194 \} +195 \} +196 +197 /* then multiply */ +198 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ +199 goto LBL_RES; +200 \} +201 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +202 goto LBL_RES; +203 \} +204 +205 /* empty window and reset */ +206 bitcpy = 0; +207 bitbuf = 0; +208 mode = 1; +209 \} +210 \} +211 +212 /* if bits remain then square/multiply */ +213 if (mode == 2 && bitcpy > 0) \{ +214 /* square then multiply if the bit is set */ +215 for (x = 0; x < bitcpy; x++) \{ +216 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ +217 goto LBL_RES; +218 \} +219 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +220 goto LBL_RES; +221 \} +222 +223 bitbuf <<= 1; +224 if ((bitbuf & (1 << winsize)) != 0) \{ +225 /* then multiply */ +226 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ +227 goto LBL_RES; +228 \} +229 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ +230 goto LBL_RES; +231 \} +232 \} +233 \} +234 \} +235 +236 mp_exch (&res, Y); +237 err = MP_OKAY; +238 LBL_RES:mp_clear (&res); +239 LBL_MU:mp_clear (&mu); +240 LBL_M: +241 mp_clear(&M[1]); +242 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ +243 mp_clear (&M[x]); +244 \} +245 return err; +246 \} +247 #endif +248 \end{alltt} \end{small} -Lines 21 through 40 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +Lines 31 through 41 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement -on line 32 the value of $x$ is already known to be greater than $140$. +on line 33 the value of $x$ is already known to be greater than $140$. -The conditional piece of code beginning on line 48 allows the window size to be restricted to five bits. This logic is used to ensure +The conditional piece of code beginning on line 47 allows the window size to be restricted to five bits. This logic is used to ensure the table of precomputed powers of $G$ remains relatively small. -The for loop on line 61 initializes the $M$ array while lines 62 and 77 compute the value of $\mu$ required for +The for loop on line 60 initializes the $M$ array while lines 61 and 76 compute the value of $\mu$ required for Barrett reduction. -- More later. @@ -8146,6 +8195,7 @@ equivalent to $m \cdot 2^k$. By this logic when $m = 1$ a quick power of two ca 041 return MP_OKAY; 042 \} 043 #endif +044 \end{alltt} \end{small} @@ -8666,6 +8716,7 @@ respectively be replaced with a zero. 285 #endif 286 287 #endif +288 \end{alltt} \end{small} @@ -8820,6 +8871,7 @@ This algorithm initiates a temporary mp\_int with the value of the single digit 102 \} 103 104 #endif +105 \end{alltt} \end{small} @@ -8929,6 +8981,7 @@ Unlike the full multiplication algorithms this algorithm does not require any si 072 return MP_OKAY; 073 \} 074 #endif +075 \end{alltt} \end{small} @@ -9074,6 +9127,7 @@ from chapter seven. 103 \} 104 105 #endif +106 \end{alltt} \end{small} @@ -9260,6 +9314,7 @@ root. Ideally this algorithm is meant to find the $n$'th root of an input where 125 return res; 126 \} 127 #endif +128 \end{alltt} \end{small} @@ -9336,6 +9391,7 @@ the integers from $0$ to $\beta - 1$. 048 return MP_OKAY; 049 \} 050 #endif +051 \end{alltt} \end{small} @@ -9480,6 +9536,7 @@ as part of larger input without any significant problem. 075 return MP_OKAY; 076 \} 077 #endif +078 \end{alltt} \end{small} @@ -9599,6 +9656,7 @@ are required instead of a series of $n \times k$ divisions. One design flaw of 068 \} 069 070 #endif +071 \end{alltt} \end{small} @@ -9879,6 +9937,7 @@ must be adjusted by multiplying by the common factors of two ($2^k$) removed ear 106 return res; 107 \} 108 #endif +109 \end{alltt} \end{small} @@ -9974,6 +10033,7 @@ dividing the product of the two inputs by their greatest common divisor. 053 return res; 054 \} 055 #endif +056 \end{alltt} \end{small} @@ -10218,6 +10278,7 @@ $\left ( {p' \over a'} \right )$ which is multiplied against the current Jacobi 098 return res; 099 \} 100 #endif +101 \end{alltt} \end{small} @@ -10366,6 +10427,7 @@ then only a couple of additions or subtractions will be required to adjust the i 036 return MP_VAL; 037 \} 038 #endif +039 \end{alltt} \end{small} @@ -10467,6 +10529,7 @@ This algorithm attempts to determine if a candidate integer $n$ is composite by 043 return MP_OKAY; 044 \} 045 #endif +046 \end{alltt} \end{small} @@ -10518,6 +10581,7 @@ mp\_digit. The table \_\_prime\_tab is defined in the following file. 054 #endif 055 \}; 056 #endif +057 \end{alltt} \end{small} @@ -10606,6 +10670,7 @@ determine the result. 055 return err; 056 \} 057 #endif +058 \end{alltt} \end{small} @@ -10741,6 +10806,7 @@ composite then it is \textit{probably} prime. 096 return err; 097 \} 098 #endif +099 \end{alltt} \end{small} diff --git a/libtommath/tommath_class.h b/libtommath/tommath_class.h index 6d05b7b..29e36fc 100644 --- a/libtommath/tommath_class.h +++ b/libtommath/tommath_class.h @@ -687,6 +687,7 @@ #if defined(BN_MP_READ_RADIX_C) #define BN_MP_ZERO_C #define BN_MP_S_RMAP_C + #define BN_MP_RADIX_SMAP_C #define BN_MP_MUL_D_C #define BN_MP_ADD_D_C #define BN_MP_ISZERO_C @@ -992,3 +993,7 @@ #else #define LTM_LAST #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/tommath_class.h,v $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ diff --git a/libtommath/tommath_superclass.h b/libtommath/tommath_superclass.h index b50ecb0..6722510 100644 --- a/libtommath/tommath_superclass.h +++ b/libtommath/tommath_superclass.h @@ -4,7 +4,7 @@ #define LTM_ALL /* RSA only (does not support DH/DSA/ECC) */ -// #define SC_RSA_1 +/* #define SC_RSA_1 */ /* For reference.... On an Athlon64 optimizing for speed... @@ -70,3 +70,7 @@ #endif #endif + +/* $Source: /root/tcl/repos-to-convert/tcl/libtommath/tommath_superclass.h,v $ */ +/* $Revision: 1.1.1.2 $ */ +/* $Date: 2005/09/26 16:32:16 $ */ -- cgit v0.12 From 23d966feecf52e4d2f8ffb358c375bf4ecee8d8a Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Mon, 26 Sep 2005 16:53:54 +0000 Subject: re-import of three damaged PDF's --- libtommath/bn.pdf | Bin 340684 -> 340681 bytes libtommath/poster.pdf | Bin 37806 -> 37805 bytes libtommath/tommath.pdf | Bin 1159839 -> 1159821 bytes 3 files changed, 0 insertions(+), 0 deletions(-) diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf index b8b8f8e..0124c71 100644 Binary files a/libtommath/bn.pdf and b/libtommath/bn.pdf differ diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf index faceef1..5a39a04 100644 Binary files a/libtommath/poster.pdf and b/libtommath/poster.pdf differ diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf index 08f6a1e..71ddffe 100644 Binary files a/libtommath/tommath.pdf and b/libtommath/tommath.pdf differ -- cgit v0.12 From 32dabb168bc76e93bb522c8de30e3023df038a0f Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Tue, 27 Dec 2005 17:59:37 +0000 Subject: Import of libtommath 0.37 --- libtommath/bn.pdf | Bin 340681 -> 341050 bytes libtommath/bn.tex | 2 +- libtommath/bn_mp_add_d.c | 7 +- libtommath/bn_mp_radix_size.c | 6 +- libtommath/bn_mp_read_radix.c | 7 +- libtommath/bn_mp_sub_d.c | 8 +- libtommath/bn_mp_toradix_n.c | 19 +- libtommath/booker.pl | 2 +- libtommath/changes.txt | 6 + libtommath/makefile | 19 +- libtommath/makefile.bcc | 2 +- libtommath/makefile.shared | 10 +- libtommath/poster.pdf | Bin 37805 -> 37800 bytes libtommath/pre_gen/mpi.c | 503 +++++++++++++++++++++--------------------- libtommath/tommath.pdf | Bin 1159821 -> 1160280 bytes libtommath/tommath.src | 2 +- libtommath/tommath.tex | 232 +++++++++---------- 17 files changed, 431 insertions(+), 394 deletions(-) diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf index 0124c71..b54b602 100644 Binary files a/libtommath/bn.pdf and b/libtommath/bn.pdf differ diff --git a/libtommath/bn.tex b/libtommath/bn.tex index 8b37766..f89e200 100644 --- a/libtommath/bn.tex +++ b/libtommath/bn.tex @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{LibTomMath User Manual \\ v0.36} +\title{LibTomMath User Manual \\ v0.37} \author{Tom St Denis \\ tomstdenis@iahu.ca} \maketitle This text, the library and the accompanying textbook are all hereby placed in the public domain. This book has been diff --git a/libtommath/bn_mp_add_d.c b/libtommath/bn_mp_add_d.c index fde3cee..3dba671 100644 --- a/libtommath/bn_mp_add_d.c +++ b/libtommath/bn_mp_add_d.c @@ -40,6 +40,9 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) /* fix sign */ a->sign = c->sign = MP_NEG; + /* clamp */ + mp_clamp(c); + return res; } @@ -105,5 +108,5 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_add_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/12/27 17:59:37 $ */ diff --git a/libtommath/bn_mp_radix_size.c b/libtommath/bn_mp_radix_size.c index 7c5d8b5..7e01577 100644 --- a/libtommath/bn_mp_radix_size.c +++ b/libtommath/bn_mp_radix_size.c @@ -36,7 +36,7 @@ int mp_radix_size (mp_int * a, int radix, int *size) } if (mp_iszero(a) == MP_YES) { - *size = 2; + *size = 2; return MP_OKAY; } @@ -74,5 +74,5 @@ int mp_radix_size (mp_int * a, int radix, int *size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_radix_size.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 17:59:38 $ */ diff --git a/libtommath/bn_mp_read_radix.c b/libtommath/bn_mp_read_radix.c index ca2bde5..1aea788 100644 --- a/libtommath/bn_mp_read_radix.c +++ b/libtommath/bn_mp_read_radix.c @@ -21,6 +21,9 @@ int mp_read_radix (mp_int * a, const char *str, int radix) int y, res, neg; char ch; + /* zero the digit bignum */ + mp_zero(a); + /* make sure the radix is ok */ if (radix < 2 || radix > 64) { return MP_VAL; @@ -78,5 +81,5 @@ int mp_read_radix (mp_int * a, const char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_radix.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 17:59:38 $ */ diff --git a/libtommath/bn_mp_sub_d.c b/libtommath/bn_mp_sub_d.c index 0b31cbe..ffeea09 100644 --- a/libtommath/bn_mp_sub_d.c +++ b/libtommath/bn_mp_sub_d.c @@ -36,6 +36,10 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) a->sign = MP_ZPOS; res = mp_add_d(a, b, c); a->sign = c->sign = MP_NEG; + + /* clamp */ + mp_clamp(c); + return res; } @@ -85,5 +89,5 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sub_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/12/27 17:59:38 $ */ diff --git a/libtommath/bn_mp_toradix_n.c b/libtommath/bn_mp_toradix_n.c index d07ba95..607a4be 100644 --- a/libtommath/bn_mp_toradix_n.c +++ b/libtommath/bn_mp_toradix_n.c @@ -27,12 +27,12 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) char *_s = str; /* check range of the maxlen, radix */ - if (maxlen < 3 || radix < 2 || radix > 64) { + if (maxlen < 2 || radix < 2 || radix > 64) { return MP_VAL; } /* quick out if its zero */ - if (mp_iszero(a) == 1) { + if (mp_iszero(a) == MP_YES) { *str++ = '0'; *str = '\0'; return MP_OKAY; @@ -57,21 +57,20 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) digs = 0; while (mp_iszero (&t) == 0) { + if (--maxlen < 1) { + /* no more room */ + break; + } if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { mp_clear (&t); return res; } *str++ = mp_s_rmap[d]; ++digs; - - if (--maxlen == 1) { - /* no more room */ - break; - } } /* reverse the digits of the string. In this case _s points - * to the first digit [exluding the sign] of the number] + * to the first digit [exluding the sign] of the number */ bn_reverse ((unsigned char *)_s, digs); @@ -85,5 +84,5 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toradix_n.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2005/12/27 17:59:38 $ */ diff --git a/libtommath/booker.pl b/libtommath/booker.pl index f419ab4..df8b30d 100644 --- a/libtommath/booker.pl +++ b/libtommath/booker.pl @@ -221,7 +221,7 @@ while () { $str = "chapter eight"; } elsif ($a == 9) { $str = "chapter nine"; - } elsif ($a == 2) { + } elsif ($a == 10) { $str = "chapter ten"; } } else { diff --git a/libtommath/changes.txt b/libtommath/changes.txt index 4f27d63..1322d14 100644 --- a/libtommath/changes.txt +++ b/libtommath/changes.txt @@ -1,3 +1,9 @@ +November 18th, 2005 +v0.37 -- [Don Porter] reported on a TCL list [HEY SEND ME BUGREPORTS ALREADY!!!] that mp_add_d() would compute -0 with some inputs. Fixed. + -- [rinick@gmail.com] reported the makefile.bcc was messed up. Fixed. + -- [Kevin Kenny] reported some issues with mp_toradix_n(). Now it doesn't require a min of 3 chars of output. + -- Made the make command renamable. Wee + August 1st, 2005 v0.36 -- LTM_PRIME_2MSB_ON was fixed and the "OFF" flag was removed. -- [Peter LaDow] found a typo in the XREALLOC macro diff --git a/libtommath/makefile b/libtommath/makefile index a4697d4..192e842 100644 --- a/libtommath/makefile +++ b/libtommath/makefile @@ -3,10 +3,14 @@ #Tom St Denis #version of library -VERSION=0.36 +VERSION=0.37 CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare +ifndef MAKE + MAKE=make +endif + ifndef IGNORE_SPEED #for speed @@ -124,7 +128,7 @@ timing: $(LIBNAME) # makes the LTM book DVI file, requires tetex, perl and makeindex [part of tetex I think] docdvi: tommath.src - cd pics ; make + cd pics ; MAKE=${MAKE} ${MAKE} echo "hello" > tommath.ind perl booker.pl latex tommath > /dev/null @@ -141,7 +145,7 @@ poster: poster.tex docs: docdvi dvipdf tommath rm -f tommath.log tommath.aux tommath.dvi tommath.idx tommath.toc tommath.lof tommath.ind tommath.ilg - cd pics ; make clean + cd pics ; MAKE=${MAKE} ${MAKE} clean #LTM user manual mandvi: bn.tex @@ -161,10 +165,10 @@ pretty: clean: rm -f *.bat *.pdf *.o *.a *.obj *.lib *.exe *.dll etclib/*.o demo/demo.o test ltmtest mpitest mtest/mtest mtest/mtest.exe \ - *.idx *.toc *.log *.aux *.dvi *.lof *.ind *.ilg *.ps *.log *.s mpi.c *.da *.dyn *.dpi tommath.tex `find -type f | grep [~] | xargs` *.lo *.la + *.idx *.toc *.log *.aux *.dvi *.lof *.ind *.ilg *.ps *.log *.s mpi.c *.da *.dyn *.dpi tommath.tex `find . -type f | grep [~] | xargs` *.lo *.la rm -rf .libs - cd etc ; make clean - cd pics ; make clean + cd etc ; MAKE=${MAKE} ${MAKE} clean + cd pics ; MAKE=${MAKE} ${MAKE} clean #zipup the project (take that!) no_oops: clean @@ -177,4 +181,5 @@ zipup: clean manual poster docs cd .. ; rm -rf ltm* libtommath-$(VERSION) ; mkdir libtommath-$(VERSION) ; \ cp -R ./libtommath/* ./libtommath-$(VERSION)/ ; \ tar -c libtommath-$(VERSION)/* | bzip2 -9vvc > ltm-$(VERSION).tar.bz2 ; \ - zip -9 -r ltm-$(VERSION).zip libtommath-$(VERSION)/* + zip -9 -r ltm-$(VERSION).zip libtommath-$(VERSION)/* ; \ + mv -f ltm* ~ ; rm -rf libtommath-$(VERSION) diff --git a/libtommath/makefile.bcc b/libtommath/makefile.bcc index 647c69a..67743d9 100644 --- a/libtommath/makefile.bcc +++ b/libtommath/makefile.bcc @@ -39,6 +39,6 @@ TARGET = libtommath.lib $(TARGET): $(OBJECTS) -.c.objbjbjbj: +.c.obj: $(CC) $(CFLAGS) $< $(LIB) $(TARGET) -+$@ diff --git a/libtommath/makefile.shared b/libtommath/makefile.shared index 821558c..9d2c20a 100644 --- a/libtommath/makefile.shared +++ b/libtommath/makefile.shared @@ -1,7 +1,7 @@ #Makefile for GCC # #Tom St Denis -VERSION=0:36 +VERSION=0:37 CC = libtool --mode=compile gcc @@ -80,11 +80,13 @@ bn_mp_prime_random_ex.o bn_mp_get_int.o bn_mp_sqrt.o bn_mp_is_square.o bn_mp_ini bn_mp_init_set_int.o bn_mp_invmod_slow.o bn_mp_prime_rabin_miller_trials.o \ bn_mp_to_signed_bin_n.o bn_mp_to_unsigned_bin_n.o +objs: $(OBJECTS) + $(LIBNAME): $(OBJECTS) libtool --mode=link gcc *.lo -o $(LIBNAME) -rpath $(LIBPATH) -version-info $(VERSION) - libtool --mode=link gcc *.o -o $(LIBNAME_S) - ranlib $(LIBNAME_S) - libtool --mode=install install -c $(LIBNAME) $(LIBPATH)/$@ + +install: $(LIBNAME) + libtool --mode=install install -c $(LIBNAME) $(LIBPATH)/$(LIBNAME) install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf index 5a39a04..95bf4b3 100644 Binary files a/libtommath/poster.pdf and b/libtommath/poster.pdf differ diff --git a/libtommath/pre_gen/mpi.c b/libtommath/pre_gen/mpi.c index 78945ac..d915a58 100644 --- a/libtommath/pre_gen/mpi.c +++ b/libtommath/pre_gen/mpi.c @@ -44,8 +44,8 @@ char *mp_error_to_string(int code) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_error.c */ @@ -196,8 +196,8 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_fast_mp_invmod.c */ @@ -372,8 +372,8 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_fast_mp_montgomery_reduce.c */ @@ -486,8 +486,8 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_fast_s_mp_mul_digs.c */ @@ -591,8 +591,8 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_fast_s_mp_mul_high_digs.c */ @@ -709,8 +709,8 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_fast_s_mp_sqr.c */ @@ -761,8 +761,8 @@ mp_2expt (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_2expt.c */ @@ -808,8 +808,8 @@ mp_abs (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_abs.c */ @@ -865,8 +865,8 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_add.c */ @@ -913,6 +913,9 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) /* fix sign */ a->sign = c->sign = MP_NEG; + /* clamp */ + mp_clamp(c); + return res; } @@ -978,8 +981,8 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_add_d.c */ @@ -1023,8 +1026,8 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_addmod.c */ @@ -1084,8 +1087,8 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_and.c */ @@ -1132,8 +1135,8 @@ mp_clamp (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_clamp.c */ @@ -1180,8 +1183,8 @@ mp_clear (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_clear.c */ @@ -1218,8 +1221,8 @@ void mp_clear_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_clear_multi.c */ @@ -1265,8 +1268,8 @@ mp_cmp (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_cmp.c */ @@ -1313,8 +1316,8 @@ int mp_cmp_d(mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_cmp_d.c */ @@ -1372,8 +1375,8 @@ int mp_cmp_mag (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_cmp_mag.c */ @@ -1429,8 +1432,8 @@ int mp_cnt_lsb(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_cnt_lsb.c */ @@ -1501,8 +1504,8 @@ mp_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_copy.c */ @@ -1550,8 +1553,8 @@ mp_count_bits (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_count_bits.c */ @@ -1846,8 +1849,8 @@ LBL_Q:mp_clear (&q); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_div.c */ @@ -1918,8 +1921,8 @@ int mp_div_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_div_2.c */ @@ -2019,8 +2022,8 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_div_2d.c */ @@ -2102,8 +2105,8 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_div_3.c */ @@ -2216,8 +2219,8 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_div_d.c */ @@ -2263,8 +2266,8 @@ int mp_dr_is_modulus(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_dr_is_modulus.c */ @@ -2361,8 +2364,8 @@ top: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_dr_reduce.c */ @@ -2397,8 +2400,8 @@ void mp_dr_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_dr_setup.c */ @@ -2435,8 +2438,8 @@ mp_exch (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_exch.c */ @@ -2496,8 +2499,8 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_expt_d.c */ @@ -2612,8 +2615,8 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_exptmod.c */ @@ -2937,8 +2940,8 @@ LBL_M: /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_exptmod_fast.c */ @@ -3023,8 +3026,8 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_exteuclid.c */ @@ -3094,8 +3097,8 @@ int mp_fread(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_fread.c */ @@ -3150,8 +3153,8 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_fwrite.c */ @@ -3267,8 +3270,8 @@ LBL_U:mp_clear (&v); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_gcd.c */ @@ -3316,8 +3319,8 @@ unsigned long mp_get_int(mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_get_int.c */ @@ -3377,8 +3380,8 @@ int mp_grow (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_grow.c */ @@ -3427,8 +3430,8 @@ int mp_init (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init.c */ @@ -3463,8 +3466,8 @@ int mp_init_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init_copy.c */ @@ -3526,8 +3529,8 @@ int mp_init_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init_multi.c */ @@ -3562,8 +3565,8 @@ int mp_init_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init_set.c */ @@ -3597,8 +3600,8 @@ int mp_init_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init_set_int.c */ @@ -3649,8 +3652,8 @@ int mp_init_size (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_init_size.c */ @@ -3696,8 +3699,8 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_invmod.c */ @@ -3875,8 +3878,8 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_invmod_slow.c */ @@ -3988,8 +3991,8 @@ ERR:mp_clear(&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_is_square.c */ @@ -4097,8 +4100,8 @@ LBL_A1:mp_clear (&a1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_jacobi.c */ @@ -4268,8 +4271,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_karatsuba_mul.c */ @@ -4393,8 +4396,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_karatsuba_sqr.c */ @@ -4457,8 +4460,8 @@ LBL_T: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_lcm.c */ @@ -4528,8 +4531,8 @@ int mp_lshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_lshd.c */ @@ -4580,8 +4583,8 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mod.c */ @@ -4639,8 +4642,8 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mod_2d.c */ @@ -4670,8 +4673,8 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mod_d.c */ @@ -4733,8 +4736,8 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_montgomery_calc_normalization.c */ @@ -4855,8 +4858,8 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_montgomery_reduce.c */ @@ -4918,8 +4921,8 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_montgomery_setup.c */ @@ -4988,8 +4991,8 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mul.c */ @@ -5074,8 +5077,8 @@ int mp_mul_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mul_2.c */ @@ -5163,8 +5166,8 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mul_2d.c */ @@ -5246,8 +5249,8 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mul_d.c */ @@ -5290,8 +5293,8 @@ int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_mulmod.c */ @@ -5426,8 +5429,8 @@ LBL_T1:mp_clear (&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_n_root.c */ @@ -5470,8 +5473,8 @@ int mp_neg (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_neg.c */ @@ -5524,8 +5527,8 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_or.c */ @@ -5590,8 +5593,8 @@ LBL_T:mp_clear (&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_fermat.c */ @@ -5644,8 +5647,8 @@ int mp_prime_is_divisible (mp_int * a, int *result) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_is_divisible.c */ @@ -5731,8 +5734,8 @@ LBL_B:mp_clear (&b); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_is_prime.c */ @@ -5838,8 +5841,8 @@ LBL_N1:mp_clear (&n1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_miller_rabin.c */ @@ -6012,8 +6015,8 @@ LBL_ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_next_prime.c */ @@ -6068,8 +6071,8 @@ int mp_prime_rabin_miller_trials(int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_rabin_miller_trials.c */ @@ -6197,8 +6200,8 @@ error: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_prime_random_ex.c */ @@ -6241,7 +6244,7 @@ int mp_radix_size (mp_int * a, int radix, int *size) } if (mp_iszero(a) == MP_YES) { - *size = 2; + *size = 2; return MP_OKAY; } @@ -6279,8 +6282,8 @@ int mp_radix_size (mp_int * a, int radix, int *size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_radix_size.c */ @@ -6307,8 +6310,8 @@ const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrs #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_radix_smap.c */ @@ -6366,8 +6369,8 @@ mp_rand (mp_int * a, int digits) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_rand.c */ @@ -6395,6 +6398,9 @@ int mp_read_radix (mp_int * a, const char *str, int radix) int y, res, neg; char ch; + /* zero the digit bignum */ + mp_zero(a); + /* make sure the radix is ok */ if (radix < 2 || radix > 64) { return MP_VAL; @@ -6452,8 +6458,8 @@ int mp_read_radix (mp_int * a, const char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_read_radix.c */ @@ -6497,8 +6503,8 @@ int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_read_signed_bin.c */ @@ -6556,8 +6562,8 @@ int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_read_unsigned_bin.c */ @@ -6660,8 +6666,8 @@ CLEANUP: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce.c */ @@ -6725,8 +6731,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_2k.c */ @@ -6791,8 +6797,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_2k_l.c */ @@ -6842,8 +6848,8 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_2k_setup.c */ @@ -6890,8 +6896,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_2k_setup_l.c */ @@ -6946,8 +6952,8 @@ int mp_reduce_is_2k(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_is_2k.c */ @@ -6994,8 +7000,8 @@ int mp_reduce_is_2k_l(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_is_2k_l.c */ @@ -7032,8 +7038,8 @@ int mp_reduce_setup (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_reduce_setup.c */ @@ -7108,8 +7114,8 @@ void mp_rshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_rshd.c */ @@ -7141,8 +7147,8 @@ void mp_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_set.c */ @@ -7193,8 +7199,8 @@ int mp_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_set_int.c */ @@ -7232,8 +7238,8 @@ int mp_shrink (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_shrink.c */ @@ -7263,8 +7269,8 @@ int mp_signed_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_signed_bin_size.c */ @@ -7325,8 +7331,8 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_sqr.c */ @@ -7370,8 +7376,8 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_sqrmod.c */ @@ -7455,8 +7461,8 @@ E2: mp_clear(&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_sqrt.c */ @@ -7518,8 +7524,8 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_sub.c */ @@ -7562,6 +7568,10 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) a->sign = MP_ZPOS; res = mp_add_d(a, b, c); a->sign = c->sign = MP_NEG; + + /* clamp */ + mp_clamp(c); + return res; } @@ -7611,8 +7621,8 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_sub_d.c */ @@ -7657,8 +7667,8 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_submod.c */ @@ -7694,8 +7704,8 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_to_signed_bin.c */ @@ -7729,8 +7739,8 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_to_signed_bin_n.c */ @@ -7781,8 +7791,8 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_to_unsigned_bin.c */ @@ -7816,8 +7826,8 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_to_unsigned_bin_n.c */ @@ -8104,8 +8114,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_toom_mul.c */ @@ -8334,8 +8344,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_toom_sqr.c */ @@ -8413,8 +8423,8 @@ int mp_toradix (mp_int * a, char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_toradix.c */ @@ -8448,12 +8458,12 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) char *_s = str; /* check range of the maxlen, radix */ - if (maxlen < 3 || radix < 2 || radix > 64) { + if (maxlen < 2 || radix < 2 || radix > 64) { return MP_VAL; } /* quick out if its zero */ - if (mp_iszero(a) == 1) { + if (mp_iszero(a) == MP_YES) { *str++ = '0'; *str = '\0'; return MP_OKAY; @@ -8478,21 +8488,20 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) digs = 0; while (mp_iszero (&t) == 0) { + if (--maxlen < 1) { + /* no more room */ + break; + } if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) { mp_clear (&t); return res; } *str++ = mp_s_rmap[d]; ++digs; - - if (--maxlen == 1) { - /* no more room */ - break; - } } /* reverse the digits of the string. In this case _s points - * to the first digit [exluding the sign] of the number] + * to the first digit [exluding the sign] of the number */ bn_reverse ((unsigned char *)_s, digs); @@ -8506,8 +8515,8 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_toradix_n.c */ @@ -8538,8 +8547,8 @@ int mp_unsigned_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_unsigned_bin_size.c */ @@ -8593,8 +8602,8 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_xor.c */ @@ -8633,8 +8642,8 @@ void mp_zero (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_mp_zero.c */ @@ -8698,8 +8707,8 @@ const mp_digit ltm_prime_tab[] = { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_prime_tab.c */ @@ -8741,8 +8750,8 @@ bn_reverse (unsigned char *s, int len) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_reverse.c */ @@ -8854,8 +8863,8 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_add.c */ @@ -9110,8 +9119,8 @@ LBL_M: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_exptmod.c */ @@ -9204,8 +9213,8 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_mul_digs.c */ @@ -9289,8 +9298,8 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_mul_high_digs.c */ @@ -9377,8 +9386,8 @@ int s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_sqr.c */ @@ -9470,8 +9479,8 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bn_s_mp_sub.c */ @@ -9510,8 +9519,8 @@ int KARATSUBA_MUL_CUTOFF = 80, /* Min. number of digits before Karatsub #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:22 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2005/12/27 18:00:26 $ */ /* End: bncore.c */ diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf index 71ddffe..5c314f5 100644 Binary files a/libtommath/tommath.pdf and b/libtommath/tommath.pdf differ diff --git a/libtommath/tommath.src b/libtommath/tommath.src index b392ead..8e03635 100644 --- a/libtommath/tommath.src +++ b/libtommath/tommath.src @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.36 release of the +This text has been placed in the public domain. This text corresponds to the v0.37 release of the LibTomMath project. \begin{alltt} diff --git a/libtommath/tommath.tex b/libtommath/tommath.tex index b69421b..a852a8d 100644 --- a/libtommath/tommath.tex +++ b/libtommath/tommath.tex @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.36 release of the +This text has been placed in the public domain. This text corresponds to the v0.37 release of the LibTomMath project. \begin{alltt} @@ -8808,70 +8808,73 @@ This algorithm initiates a temporary mp\_int with the value of the single digit 039 /* fix sign */ 040 a->sign = c->sign = MP_NEG; 041 -042 return res; -043 \} +042 /* clamp */ +043 mp_clamp(c); 044 -045 /* old number of used digits in c */ -046 oldused = c->used; +045 return res; +046 \} 047 -048 /* sign always positive */ -049 c->sign = MP_ZPOS; +048 /* old number of used digits in c */ +049 oldused = c->used; 050 -051 /* source alias */ -052 tmpa = a->dp; +051 /* sign always positive */ +052 c->sign = MP_ZPOS; 053 -054 /* destination alias */ -055 tmpc = c->dp; +054 /* source alias */ +055 tmpa = a->dp; 056 -057 /* if a is positive */ -058 if (a->sign == MP_ZPOS) \{ -059 /* add digit, after this we're propagating -060 * the carry. -061 */ -062 *tmpc = *tmpa++ + b; -063 mu = *tmpc >> DIGIT_BIT; -064 *tmpc++ &= MP_MASK; -065 -066 /* now handle rest of the digits */ -067 for (ix = 1; ix < a->used; ix++) \{ -068 *tmpc = *tmpa++ + mu; -069 mu = *tmpc >> DIGIT_BIT; -070 *tmpc++ &= MP_MASK; -071 \} -072 /* set final carry */ -073 ix++; -074 *tmpc++ = mu; -075 -076 /* setup size */ -077 c->used = a->used + 1; -078 \} else \{ -079 /* a was negative and |a| < b */ -080 c->used = 1; -081 -082 /* the result is a single digit */ -083 if (a->used == 1) \{ -084 *tmpc++ = b - a->dp[0]; -085 \} else \{ -086 *tmpc++ = b; -087 \} -088 -089 /* setup count so the clearing of oldused -090 * can fall through correctly -091 */ -092 ix = 1; -093 \} -094 -095 /* now zero to oldused */ -096 while (ix++ < oldused) \{ -097 *tmpc++ = 0; -098 \} -099 mp_clamp(c); -100 -101 return MP_OKAY; -102 \} +057 /* destination alias */ +058 tmpc = c->dp; +059 +060 /* if a is positive */ +061 if (a->sign == MP_ZPOS) \{ +062 /* add digit, after this we're propagating +063 * the carry. +064 */ +065 *tmpc = *tmpa++ + b; +066 mu = *tmpc >> DIGIT_BIT; +067 *tmpc++ &= MP_MASK; +068 +069 /* now handle rest of the digits */ +070 for (ix = 1; ix < a->used; ix++) \{ +071 *tmpc = *tmpa++ + mu; +072 mu = *tmpc >> DIGIT_BIT; +073 *tmpc++ &= MP_MASK; +074 \} +075 /* set final carry */ +076 ix++; +077 *tmpc++ = mu; +078 +079 /* setup size */ +080 c->used = a->used + 1; +081 \} else \{ +082 /* a was negative and |a| < b */ +083 c->used = 1; +084 +085 /* the result is a single digit */ +086 if (a->used == 1) \{ +087 *tmpc++ = b - a->dp[0]; +088 \} else \{ +089 *tmpc++ = b; +090 \} +091 +092 /* setup count so the clearing of oldused +093 * can fall through correctly +094 */ +095 ix = 1; +096 \} +097 +098 /* now zero to oldused */ +099 while (ix++ < oldused) \{ +100 *tmpc++ = 0; +101 \} +102 mp_clamp(c); 103 -104 #endif -105 +104 return MP_OKAY; +105 \} +106 +107 #endif +108 \end{alltt} \end{small} @@ -9481,62 +9484,65 @@ as part of larger input without any significant problem. 020 int y, res, neg; 021 char ch; 022 -023 /* make sure the radix is ok */ -024 if (radix < 2 || radix > 64) \{ -025 return MP_VAL; -026 \} -027 -028 /* if the leading digit is a -029 * minus set the sign to negative. -030 */ -031 if (*str == '-') \{ -032 ++str; -033 neg = MP_NEG; -034 \} else \{ -035 neg = MP_ZPOS; -036 \} -037 -038 /* set the integer to the default of zero */ -039 mp_zero (a); -040 -041 /* process each digit of the string */ -042 while (*str) \{ -043 /* if the radix < 36 the conversion is case insensitive -044 * this allows numbers like 1AB and 1ab to represent the same value -045 * [e.g. in hex] -046 */ -047 ch = (char) ((radix < 36) ? toupper (*str) : *str); -048 for (y = 0; y < 64; y++) \{ -049 if (ch == mp_s_rmap[y]) \{ -050 break; -051 \} -052 \} -053 -054 /* if the char was found in the map -055 * and is less than the given radix add it -056 * to the number, otherwise exit the loop. -057 */ -058 if (y < radix) \{ -059 if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) \{ -060 return res; -061 \} -062 if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) \{ +023 /* zero the digit bignum */ +024 mp_zero(a); +025 +026 /* make sure the radix is ok */ +027 if (radix < 2 || radix > 64) \{ +028 return MP_VAL; +029 \} +030 +031 /* if the leading digit is a +032 * minus set the sign to negative. +033 */ +034 if (*str == '-') \{ +035 ++str; +036 neg = MP_NEG; +037 \} else \{ +038 neg = MP_ZPOS; +039 \} +040 +041 /* set the integer to the default of zero */ +042 mp_zero (a); +043 +044 /* process each digit of the string */ +045 while (*str) \{ +046 /* if the radix < 36 the conversion is case insensitive +047 * this allows numbers like 1AB and 1ab to represent the same value +048 * [e.g. in hex] +049 */ +050 ch = (char) ((radix < 36) ? toupper (*str) : *str); +051 for (y = 0; y < 64; y++) \{ +052 if (ch == mp_s_rmap[y]) \{ +053 break; +054 \} +055 \} +056 +057 /* if the char was found in the map +058 * and is less than the given radix add it +059 * to the number, otherwise exit the loop. +060 */ +061 if (y < radix) \{ +062 if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) \{ 063 return res; 064 \} -065 \} else \{ -066 break; -067 \} -068 ++str; -069 \} -070 -071 /* set the sign only if a != 0 */ -072 if (mp_iszero(a) != 1) \{ -073 a->sign = neg; -074 \} -075 return MP_OKAY; -076 \} -077 #endif -078 +065 if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) \{ +066 return res; +067 \} +068 \} else \{ +069 break; +070 \} +071 ++str; +072 \} +073 +074 /* set the sign only if a != 0 */ +075 if (mp_iszero(a) != 1) \{ +076 a->sign = neg; +077 \} +078 return MP_OKAY; +079 \} +080 #endif +081 \end{alltt} \end{small} -- cgit v0.12 From b62b2d6ee4170b8d2cff9e546d67cc24e0c782c6 Mon Sep 17 00:00:00 2001 From: Kevin B Kenny Date: Fri, 1 Dec 2006 00:08:10 +0000 Subject: Import of libtommath 0.39+ --- libtommath/bn.pdf | Bin 341050 -> 340921 bytes libtommath/bn.tex | 2 +- libtommath/bn_error.c | 6 +- libtommath/bn_fast_mp_invmod.c | 6 +- libtommath/bn_fast_mp_montgomery_reduce.c | 6 +- libtommath/bn_fast_s_mp_mul_digs.c | 11 +- libtommath/bn_fast_s_mp_mul_high_digs.c | 11 +- libtommath/bn_fast_s_mp_sqr.c | 6 +- libtommath/bn_mp_2expt.c | 6 +- libtommath/bn_mp_abs.c | 6 +- libtommath/bn_mp_add.c | 6 +- libtommath/bn_mp_add_d.c | 6 +- libtommath/bn_mp_addmod.c | 6 +- libtommath/bn_mp_and.c | 6 +- libtommath/bn_mp_clamp.c | 6 +- libtommath/bn_mp_clear.c | 6 +- libtommath/bn_mp_clear_multi.c | 6 +- libtommath/bn_mp_cmp.c | 6 +- libtommath/bn_mp_cmp_d.c | 6 +- libtommath/bn_mp_cmp_mag.c | 6 +- libtommath/bn_mp_cnt_lsb.c | 6 +- libtommath/bn_mp_copy.c | 6 +- libtommath/bn_mp_count_bits.c | 6 +- libtommath/bn_mp_div.c | 6 +- libtommath/bn_mp_div_2.c | 6 +- libtommath/bn_mp_div_2d.c | 6 +- libtommath/bn_mp_div_3.c | 6 +- libtommath/bn_mp_div_d.c | 6 +- libtommath/bn_mp_dr_is_modulus.c | 6 +- libtommath/bn_mp_dr_reduce.c | 6 +- libtommath/bn_mp_dr_setup.c | 6 +- libtommath/bn_mp_exch.c | 6 +- libtommath/bn_mp_expt_d.c | 6 +- libtommath/bn_mp_exptmod.c | 6 +- libtommath/bn_mp_exptmod_fast.c | 6 +- libtommath/bn_mp_exteuclid.c | 6 +- libtommath/bn_mp_fread.c | 6 +- libtommath/bn_mp_fwrite.c | 6 +- libtommath/bn_mp_gcd.c | 18 +- libtommath/bn_mp_get_int.c | 6 +- libtommath/bn_mp_grow.c | 6 +- libtommath/bn_mp_init.c | 6 +- libtommath/bn_mp_init_copy.c | 6 +- libtommath/bn_mp_init_multi.c | 6 +- libtommath/bn_mp_init_set.c | 6 +- libtommath/bn_mp_init_set_int.c | 6 +- libtommath/bn_mp_init_size.c | 6 +- libtommath/bn_mp_invmod.c | 6 +- libtommath/bn_mp_invmod_slow.c | 6 +- libtommath/bn_mp_is_square.c | 6 +- libtommath/bn_mp_jacobi.c | 6 +- libtommath/bn_mp_karatsuba_mul.c | 6 +- libtommath/bn_mp_karatsuba_sqr.c | 6 +- libtommath/bn_mp_lcm.c | 6 +- libtommath/bn_mp_lshd.c | 6 +- libtommath/bn_mp_mod.c | 6 +- libtommath/bn_mp_mod_2d.c | 6 +- libtommath/bn_mp_mod_d.c | 6 +- libtommath/bn_mp_montgomery_calc_normalization.c | 6 +- libtommath/bn_mp_montgomery_reduce.c | 6 +- libtommath/bn_mp_montgomery_setup.c | 6 +- libtommath/bn_mp_mul.c | 6 +- libtommath/bn_mp_mul_2.c | 6 +- libtommath/bn_mp_mul_2d.c | 6 +- libtommath/bn_mp_mul_d.c | 6 +- libtommath/bn_mp_mulmod.c | 6 +- libtommath/bn_mp_n_root.c | 6 +- libtommath/bn_mp_neg.c | 6 +- libtommath/bn_mp_or.c | 6 +- libtommath/bn_mp_prime_fermat.c | 6 +- libtommath/bn_mp_prime_is_divisible.c | 6 +- libtommath/bn_mp_prime_is_prime.c | 6 +- libtommath/bn_mp_prime_miller_rabin.c | 6 +- libtommath/bn_mp_prime_next_prime.c | 6 +- libtommath/bn_mp_prime_rabin_miller_trials.c | 6 +- libtommath/bn_mp_prime_random_ex.c | 6 +- libtommath/bn_mp_radix_size.c | 6 +- libtommath/bn_mp_radix_smap.c | 6 +- libtommath/bn_mp_rand.c | 6 +- libtommath/bn_mp_read_radix.c | 6 +- libtommath/bn_mp_read_signed_bin.c | 6 +- libtommath/bn_mp_read_unsigned_bin.c | 6 +- libtommath/bn_mp_reduce.c | 6 +- libtommath/bn_mp_reduce_2k.c | 6 +- libtommath/bn_mp_reduce_2k_l.c | 6 +- libtommath/bn_mp_reduce_2k_setup.c | 6 +- libtommath/bn_mp_reduce_2k_setup_l.c | 6 +- libtommath/bn_mp_reduce_is_2k.c | 6 +- libtommath/bn_mp_reduce_is_2k_l.c | 6 +- libtommath/bn_mp_reduce_setup.c | 6 +- libtommath/bn_mp_rshd.c | 6 +- libtommath/bn_mp_set.c | 6 +- libtommath/bn_mp_set_int.c | 6 +- libtommath/bn_mp_shrink.c | 6 +- libtommath/bn_mp_signed_bin_size.c | 6 +- libtommath/bn_mp_sqr.c | 6 +- libtommath/bn_mp_sqrmod.c | 6 +- libtommath/bn_mp_sqrt.c | 6 +- libtommath/bn_mp_sub.c | 6 +- libtommath/bn_mp_sub_d.c | 6 +- libtommath/bn_mp_submod.c | 6 +- libtommath/bn_mp_to_signed_bin.c | 6 +- libtommath/bn_mp_to_signed_bin_n.c | 6 +- libtommath/bn_mp_to_unsigned_bin.c | 6 +- libtommath/bn_mp_to_unsigned_bin_n.c | 6 +- libtommath/bn_mp_toom_mul.c | 6 +- libtommath/bn_mp_toom_sqr.c | 6 +- libtommath/bn_mp_toradix.c | 6 +- libtommath/bn_mp_toradix_n.c | 6 +- libtommath/bn_mp_unsigned_bin_size.c | 6 +- libtommath/bn_mp_xor.c | 6 +- libtommath/bn_mp_zero.c | 6 +- libtommath/bn_prime_tab.c | 6 +- libtommath/bn_reverse.c | 6 +- libtommath/bn_s_mp_add.c | 6 +- libtommath/bn_s_mp_exptmod.c | 6 +- libtommath/bn_s_mp_mul_digs.c | 6 +- libtommath/bn_s_mp_mul_high_digs.c | 6 +- libtommath/bn_s_mp_sqr.c | 6 +- libtommath/bn_s_mp_sub.c | 6 +- libtommath/bncore.c | 6 +- libtommath/changes.txt | 11 + libtommath/etc/mersenne.c | 6 +- libtommath/etc/pprime.c | 8 +- libtommath/etc/tune.c | 6 +- libtommath/makefile | 2 +- libtommath/makefile.shared | 7 +- libtommath/poster.pdf | Bin 37800 -> 37822 bytes libtommath/pre_gen/mpi.c | 734 ++-- libtommath/tommath.h | 6 +- libtommath/tommath.pdf | Bin 1160280 -> 1194158 bytes libtommath/tommath.src | 138 +- libtommath/tommath.tex | 4527 +--------------------- 133 files changed, 985 insertions(+), 5198 deletions(-) diff --git a/libtommath/bn.pdf b/libtommath/bn.pdf index b54b602..392b649 100644 Binary files a/libtommath/bn.pdf and b/libtommath/bn.pdf differ diff --git a/libtommath/bn.tex b/libtommath/bn.tex index f89e200..e8eb994 100644 --- a/libtommath/bn.tex +++ b/libtommath/bn.tex @@ -49,7 +49,7 @@ \begin{document} \frontmatter \pagestyle{empty} -\title{LibTomMath User Manual \\ v0.37} +\title{LibTomMath User Manual \\ v0.39} \author{Tom St Denis \\ tomstdenis@iahu.ca} \maketitle This text, the library and the accompanying textbook are all hereby placed in the public domain. This book has been diff --git a/libtommath/bn_error.c b/libtommath/bn_error.c index e260763..d96ea2a 100644 --- a/libtommath/bn_error.c +++ b/libtommath/bn_error.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static const struct { @@ -43,5 +43,5 @@ char *mp_error_to_string(int code) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_error.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_fast_mp_invmod.c b/libtommath/bn_fast_mp_invmod.c index 9f4a4da..744ae4f 100644 --- a/libtommath/bn_fast_mp_invmod.c +++ b/libtommath/bn_fast_mp_invmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes the modular inverse via binary extended euclidean algorithm, @@ -144,5 +144,5 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_mp_invmod.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_fast_mp_montgomery_reduce.c b/libtommath/bn_fast_mp_montgomery_reduce.c index e676c6e..45a4089 100644 --- a/libtommath/bn_fast_mp_montgomery_reduce.c +++ b/libtommath/bn_fast_mp_montgomery_reduce.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes xR**-1 == x (mod N) via Montgomery Reduction @@ -168,5 +168,5 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_mp_montgomery_reduce.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_fast_s_mp_mul_digs.c b/libtommath/bn_fast_s_mp_mul_digs.c index 0c715be..86b78b4 100644 --- a/libtommath/bn_fast_s_mp_mul_digs.c +++ b/libtommath/bn_fast_s_mp_mul_digs.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Fast (comba) multiplier @@ -78,10 +78,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) /* make next carry */ _W = _W >> ((mp_word)DIGIT_BIT); - } - - /* store final carry */ - W[ix] = (mp_digit)(_W & MP_MASK); + } /* setup dest */ olduse = c->used; @@ -106,5 +103,5 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_mul_digs.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_fast_s_mp_mul_high_digs.c b/libtommath/bn_fast_s_mp_mul_high_digs.c index 7c10ce4..607630a 100644 --- a/libtommath/bn_fast_s_mp_mul_high_digs.c +++ b/libtommath/bn_fast_s_mp_mul_high_digs.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* this is a modified version of fast_s_mul_digs that only produces @@ -70,9 +70,6 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) _W = _W >> ((mp_word)DIGIT_BIT); } - /* store final carry */ - W[ix] = (mp_digit)(_W & MP_MASK); - /* setup dest */ olduse = c->used; c->used = pa; @@ -81,7 +78,7 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) register mp_digit *tmpc; tmpc = c->dp + digs; - for (ix = digs; ix <= pa; ix++) { + for (ix = digs; ix < pa; ix++) { /* now extract the previous digit [below the carry] */ *tmpc++ = W[ix]; } @@ -97,5 +94,5 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_mul_high_digs.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_fast_s_mp_sqr.c b/libtommath/bn_fast_s_mp_sqr.c index c8f0dc6..50adf00 100644 --- a/libtommath/bn_fast_s_mp_sqr.c +++ b/libtommath/bn_fast_s_mp_sqr.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* the jist of squaring... @@ -110,5 +110,5 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_fast_s_mp_sqr.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_2expt.c b/libtommath/bn_mp_2expt.c index d859623..a9d3e9c 100644 --- a/libtommath/bn_mp_2expt.c +++ b/libtommath/bn_mp_2expt.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes a = 2**b @@ -44,5 +44,5 @@ mp_2expt (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_2expt.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_abs.c b/libtommath/bn_mp_abs.c index 7231a27..2a7f02c 100644 --- a/libtommath/bn_mp_abs.c +++ b/libtommath/bn_mp_abs.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = |a| @@ -39,5 +39,5 @@ mp_abs (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_abs.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_add.c b/libtommath/bn_mp_add.c index 74dcb48..b7effdb 100644 --- a/libtommath/bn_mp_add.c +++ b/libtommath/bn_mp_add.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level addition (handles signs) */ @@ -49,5 +49,5 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_add.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_add_d.c b/libtommath/bn_mp_add_d.c index 3dba671..598acab 100644 --- a/libtommath/bn_mp_add_d.c +++ b/libtommath/bn_mp_add_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* single digit addition */ @@ -108,5 +108,5 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_add_d.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/12/27 17:59:37 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_addmod.c b/libtommath/bn_mp_addmod.c index 5cf1604..b0b4d8b 100644 --- a/libtommath/bn_mp_addmod.c +++ b/libtommath/bn_mp_addmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a + b (mod c) */ @@ -37,5 +37,5 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_addmod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_and.c b/libtommath/bn_mp_and.c index 9715308..ff61017 100644 --- a/libtommath/bn_mp_and.c +++ b/libtommath/bn_mp_and.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* AND two ints together */ @@ -53,5 +53,5 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_and.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_clamp.c b/libtommath/bn_mp_clamp.c index 56a6362..4f2f8ba 100644 --- a/libtommath/bn_mp_clamp.c +++ b/libtommath/bn_mp_clamp.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* trim unused digits @@ -40,5 +40,5 @@ mp_clamp (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clamp.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_clear.c b/libtommath/bn_mp_clear.c index 7564fff..e1fe10d 100644 --- a/libtommath/bn_mp_clear.c +++ b/libtommath/bn_mp_clear.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* clear one (frees) */ @@ -40,5 +40,5 @@ mp_clear (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clear.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_clear_multi.c b/libtommath/bn_mp_clear_multi.c index 2766907..e9910e8 100644 --- a/libtommath/bn_mp_clear_multi.c +++ b/libtommath/bn_mp_clear_multi.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #include @@ -30,5 +30,5 @@ void mp_clear_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_clear_multi.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_cmp.c b/libtommath/bn_mp_cmp.c index ce82baf..6361730 100644 --- a/libtommath/bn_mp_cmp.c +++ b/libtommath/bn_mp_cmp.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare two ints (signed)*/ @@ -39,5 +39,5 @@ mp_cmp (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_cmp_d.c b/libtommath/bn_mp_cmp_d.c index 2d98647..92c3567 100644 --- a/libtommath/bn_mp_cmp_d.c +++ b/libtommath/bn_mp_cmp_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare a digit */ @@ -40,5 +40,5 @@ int mp_cmp_d(mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_cmp_mag.c b/libtommath/bn_mp_cmp_mag.c index 3ade54f..31c8221 100644 --- a/libtommath/bn_mp_cmp_mag.c +++ b/libtommath/bn_mp_cmp_mag.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare maginitude of two ints (unsigned) */ @@ -51,5 +51,5 @@ int mp_cmp_mag (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cmp_mag.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_cnt_lsb.c b/libtommath/bn_mp_cnt_lsb.c index 6ff212d..4aa68b5 100644 --- a/libtommath/bn_mp_cnt_lsb.c +++ b/libtommath/bn_mp_cnt_lsb.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static const int lnz[16] = { @@ -49,5 +49,5 @@ int mp_cnt_lsb(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_cnt_lsb.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_copy.c b/libtommath/bn_mp_copy.c index f2de108..a5d5e6f 100644 --- a/libtommath/bn_mp_copy.c +++ b/libtommath/bn_mp_copy.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* copy, b = a */ @@ -64,5 +64,5 @@ mp_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_copy.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_count_bits.c b/libtommath/bn_mp_count_bits.c index cfab837..44c0cff 100644 --- a/libtommath/bn_mp_count_bits.c +++ b/libtommath/bn_mp_count_bits.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* returns the number of bits in an int */ @@ -41,5 +41,5 @@ mp_count_bits (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_count_bits.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_div.c b/libtommath/bn_mp_div.c index a0a9d7c..4a94172 100644 --- a/libtommath/bn_mp_div.c +++ b/libtommath/bn_mp_div.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #ifdef BN_MP_DIV_SMALL @@ -288,5 +288,5 @@ LBL_Q:mp_clear (&q); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_div_2.c b/libtommath/bn_mp_div_2.c index 23cd43a..bcb17c1 100644 --- a/libtommath/bn_mp_div_2.c +++ b/libtommath/bn_mp_div_2.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = a/2 */ @@ -64,5 +64,5 @@ int mp_div_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_2.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_div_2d.c b/libtommath/bn_mp_div_2d.c index 305eeaa..12a7c99 100644 --- a/libtommath/bn_mp_div_2d.c +++ b/libtommath/bn_mp_div_2d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift right by a certain bit count (store quotient in c, optional remainder in d) */ @@ -93,5 +93,5 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_2d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_div_3.c b/libtommath/bn_mp_div_3.c index 69d25cf..571991a 100644 --- a/libtommath/bn_mp_div_3.c +++ b/libtommath/bn_mp_div_3.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* divide by three (based on routine from MPI and the GMP manual) */ @@ -75,5 +75,5 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_3.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_div_d.c b/libtommath/bn_mp_div_d.c index c3afceb..4f210e6 100644 --- a/libtommath/bn_mp_div_d.c +++ b/libtommath/bn_mp_div_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static int s_is_power_of_two(mp_digit b, int *p) @@ -106,5 +106,5 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_div_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_dr_is_modulus.c b/libtommath/bn_mp_dr_is_modulus.c index b11bc0c..9532df1 100644 --- a/libtommath/bn_mp_dr_is_modulus.c +++ b/libtommath/bn_mp_dr_is_modulus.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if a number is a valid DR modulus */ @@ -39,5 +39,5 @@ int mp_dr_is_modulus(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_is_modulus.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_dr_reduce.c b/libtommath/bn_mp_dr_reduce.c index c7119a1..6d63462 100644 --- a/libtommath/bn_mp_dr_reduce.c +++ b/libtommath/bn_mp_dr_reduce.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduce "x" in place modulo "n" using the Diminished Radix algorithm. @@ -90,5 +90,5 @@ top: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_reduce.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_dr_setup.c b/libtommath/bn_mp_dr_setup.c index c177199..c6f4b2f 100644 --- a/libtommath/bn_mp_dr_setup.c +++ b/libtommath/bn_mp_dr_setup.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -28,5 +28,5 @@ void mp_dr_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_dr_setup.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_exch.c b/libtommath/bn_mp_exch.c index 7bb1169..691d9f6 100644 --- a/libtommath/bn_mp_exch.c +++ b/libtommath/bn_mp_exch.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* swap the elements of two integers, for cases where you can't simply swap the @@ -30,5 +30,5 @@ mp_exch (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exch.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_expt_d.c b/libtommath/bn_mp_expt_d.c index d5067ab..dfd04eb 100644 --- a/libtommath/bn_mp_expt_d.c +++ b/libtommath/bn_mp_expt_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* calculate c = a**b using a square-multiply algorithm */ @@ -53,5 +53,5 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_expt_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_exptmod.c b/libtommath/bn_mp_exptmod.c index f0b205b..714a96f 100644 --- a/libtommath/bn_mp_exptmod.c +++ b/libtommath/bn_mp_exptmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ @@ -108,5 +108,5 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exptmod.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_exptmod_fast.c b/libtommath/bn_mp_exptmod_fast.c index e4f25df..cb8d94a 100644 --- a/libtommath/bn_mp_exptmod_fast.c +++ b/libtommath/bn_mp_exptmod_fast.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes Y == G**X mod P, HAC pp.616, Algorithm 14.85 @@ -317,5 +317,5 @@ LBL_M: /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exptmod_fast.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_exteuclid.c b/libtommath/bn_mp_exteuclid.c index f0ae8e5..9730fa0 100644 --- a/libtommath/bn_mp_exteuclid.c +++ b/libtommath/bn_mp_exteuclid.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Extended euclidean algorithm of (a, b) produces @@ -78,5 +78,5 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_exteuclid.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_fread.c b/libtommath/bn_mp_fread.c index f1c72fd..c1b0128 100644 --- a/libtommath/bn_mp_fread.c +++ b/libtommath/bn_mp_fread.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read a bigint from a file stream in ASCII */ @@ -63,5 +63,5 @@ int mp_fread(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_fread.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_fwrite.c b/libtommath/bn_mp_fwrite.c index 29c0a2b..5785c02 100644 --- a/libtommath/bn_mp_fwrite.c +++ b/libtommath/bn_mp_fwrite.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ int mp_fwrite(mp_int *a, int radix, FILE *stream) @@ -48,5 +48,5 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_fwrite.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_gcd.c b/libtommath/bn_mp_gcd.c index f0141ac..bbc5421 100644 --- a/libtommath/bn_mp_gcd.c +++ b/libtommath/bn_mp_gcd.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Greatest Common Divisor using the binary method */ @@ -22,21 +22,13 @@ int mp_gcd (mp_int * a, mp_int * b, mp_int * c) int k, u_lsb, v_lsb, res; /* either zero than gcd is the largest */ - if (mp_iszero (a) == 1 && mp_iszero (b) == 0) { + if (mp_iszero (a) == MP_YES) { return mp_abs (b, c); } - if (mp_iszero (a) == 0 && mp_iszero (b) == 1) { + if (mp_iszero (b) == MP_YES) { return mp_abs (a, c); } - /* optimized. At this point if a == 0 then - * b must equal zero too - */ - if (mp_iszero (a) == 1) { - mp_zero(c); - return MP_OKAY; - } - /* get copies of a and b we can modify */ if ((res = mp_init_copy (&u, a)) != MP_OKAY) { return res; @@ -109,5 +101,5 @@ LBL_U:mp_clear (&v); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_gcd.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_get_int.c b/libtommath/bn_mp_get_int.c index e9282aa..269be79 100644 --- a/libtommath/bn_mp_get_int.c +++ b/libtommath/bn_mp_get_int.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the lower 32-bits of an mp_int */ @@ -41,5 +41,5 @@ unsigned long mp_get_int(mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_get_int.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_grow.c b/libtommath/bn_mp_grow.c index 047c6af..e77c774 100644 --- a/libtommath/bn_mp_grow.c +++ b/libtommath/bn_mp_grow.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* grow as required */ @@ -53,5 +53,5 @@ int mp_grow (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_grow.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init.c b/libtommath/bn_mp_init.c index 7a59a39..c866e89 100644 --- a/libtommath/bn_mp_init.c +++ b/libtommath/bn_mp_init.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* init a new mp_int */ @@ -42,5 +42,5 @@ int mp_init (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init_copy.c b/libtommath/bn_mp_init_copy.c index 2b3248d..2e1c207 100644 --- a/libtommath/bn_mp_init_copy.c +++ b/libtommath/bn_mp_init_copy.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* creates "a" then copies b into it */ @@ -28,5 +28,5 @@ int mp_init_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_copy.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init_multi.c b/libtommath/bn_mp_init_multi.c index 5af771f..70148b8 100644 --- a/libtommath/bn_mp_init_multi.c +++ b/libtommath/bn_mp_init_multi.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #include @@ -55,5 +55,5 @@ int mp_init_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_multi.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init_set.c b/libtommath/bn_mp_init_set.c index ded8617..cdf1249 100644 --- a/libtommath/bn_mp_init_set.c +++ b/libtommath/bn_mp_init_set.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* initialize and set a digit */ @@ -28,5 +28,5 @@ int mp_init_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_set.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init_set_int.c b/libtommath/bn_mp_init_set_int.c index 45341fe..a4e87d5 100644 --- a/libtommath/bn_mp_init_set_int.c +++ b/libtommath/bn_mp_init_set_int.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* initialize and set a digit */ @@ -27,5 +27,5 @@ int mp_init_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_set_int.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_init_size.c b/libtommath/bn_mp_init_size.c index 74afbf9..4433b16 100644 --- a/libtommath/bn_mp_init_size.c +++ b/libtommath/bn_mp_init_size.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* init an mp_init for a given size */ @@ -44,5 +44,5 @@ int mp_init_size (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_init_size.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_invmod.c b/libtommath/bn_mp_invmod.c index bf35b0a..09e71cd 100644 --- a/libtommath/bn_mp_invmod.c +++ b/libtommath/bn_mp_invmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* hac 14.61, pp608 */ @@ -39,5 +39,5 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_invmod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_invmod_slow.c b/libtommath/bn_mp_invmod_slow.c index 50a9b6f..ff9cc96 100644 --- a/libtommath/bn_mp_invmod_slow.c +++ b/libtommath/bn_mp_invmod_slow.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* hac 14.61, pp608 */ @@ -171,5 +171,5 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_invmod_slow.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_is_square.c b/libtommath/bn_mp_is_square.c index 8ee84c7..01f07b3 100644 --- a/libtommath/bn_mp_is_square.c +++ b/libtommath/bn_mp_is_square.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Check if remainders are possible squares - fast exclude non-squares */ @@ -105,5 +105,5 @@ ERR:mp_clear(&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_is_square.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_jacobi.c b/libtommath/bn_mp_jacobi.c index 8178454..cb7713d 100644 --- a/libtommath/bn_mp_jacobi.c +++ b/libtommath/bn_mp_jacobi.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes the jacobi c = (a | n) (or Legendre if n is prime) @@ -101,5 +101,5 @@ LBL_A1:mp_clear (&a1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_jacobi.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_karatsuba_mul.c b/libtommath/bn_mp_karatsuba_mul.c index a1ff713..53187dd 100644 --- a/libtommath/bn_mp_karatsuba_mul.c +++ b/libtommath/bn_mp_karatsuba_mul.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = |a| * |b| using Karatsuba Multiplication using @@ -163,5 +163,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_karatsuba_mul.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_karatsuba_sqr.c b/libtommath/bn_mp_karatsuba_sqr.c index 3bfe157..7f1f253 100644 --- a/libtommath/bn_mp_karatsuba_sqr.c +++ b/libtommath/bn_mp_karatsuba_sqr.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Karatsuba squaring, computes b = a*a using three @@ -117,5 +117,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_karatsuba_sqr.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_lcm.c b/libtommath/bn_mp_lcm.c index 7bdaa43..72a5beb 100644 --- a/libtommath/bn_mp_lcm.c +++ b/libtommath/bn_mp_lcm.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes least common multiple as |a*b|/(a, b) */ @@ -56,5 +56,5 @@ LBL_T: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_lcm.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_lshd.c b/libtommath/bn_mp_lshd.c index 5ddeb62..84dfa81 100644 --- a/libtommath/bn_mp_lshd.c +++ b/libtommath/bn_mp_lshd.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift left a certain amount of digits */ @@ -63,5 +63,5 @@ int mp_lshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_lshd.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mod.c b/libtommath/bn_mp_mod.c index 22cb069..16d9d76 100644 --- a/libtommath/bn_mp_mod.c +++ b/libtommath/bn_mp_mod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = a mod b, 0 <= c < b */ @@ -44,5 +44,5 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mod_2d.c b/libtommath/bn_mp_mod_2d.c index 935d97d..2ab7e33 100644 --- a/libtommath/bn_mp_mod_2d.c +++ b/libtommath/bn_mp_mod_2d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* calc a value mod 2**b */ @@ -51,5 +51,5 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod_2d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mod_d.c b/libtommath/bn_mp_mod_d.c index 329594a..91dcbe1 100644 --- a/libtommath/bn_mp_mod_d.c +++ b/libtommath/bn_mp_mod_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ int @@ -23,5 +23,5 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mod_d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_montgomery_calc_normalization.c b/libtommath/bn_mp_montgomery_calc_normalization.c index 0da933f..59dd8ea 100644 --- a/libtommath/bn_mp_montgomery_calc_normalization.c +++ b/libtommath/bn_mp_montgomery_calc_normalization.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* @@ -55,5 +55,5 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_calc_normalization.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_montgomery_reduce.c b/libtommath/bn_mp_montgomery_reduce.c index d556332..f9305d8 100644 --- a/libtommath/bn_mp_montgomery_reduce.c +++ b/libtommath/bn_mp_montgomery_reduce.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes xR**-1 == x (mod N) via Montgomery Reduction */ @@ -114,5 +114,5 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_reduce.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_montgomery_setup.c b/libtommath/bn_mp_montgomery_setup.c index e55e974..cea6778 100644 --- a/libtommath/bn_mp_montgomery_setup.c +++ b/libtommath/bn_mp_montgomery_setup.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* setups the montgomery reduction stuff */ @@ -55,5 +55,5 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_montgomery_setup.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mul.c b/libtommath/bn_mp_mul.c index 8fd3872..6506635 100644 --- a/libtommath/bn_mp_mul.c +++ b/libtommath/bn_mp_mul.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level multiplication (handles sign) */ @@ -62,5 +62,5 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mul_2.c b/libtommath/bn_mp_mul_2.c index 7409f1c..96d5710 100644 --- a/libtommath/bn_mp_mul_2.c +++ b/libtommath/bn_mp_mul_2.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = a*2 */ @@ -78,5 +78,5 @@ int mp_mul_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_2.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mul_2d.c b/libtommath/bn_mp_mul_2d.c index 800646d..88fa080 100644 --- a/libtommath/bn_mp_mul_2d.c +++ b/libtommath/bn_mp_mul_2d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift left by a certain bit count */ @@ -81,5 +81,5 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_2d.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mul_d.c b/libtommath/bn_mp_mul_d.c index 061199f..e86d6ab 100644 --- a/libtommath/bn_mp_mul_d.c +++ b/libtommath/bn_mp_mul_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiply by a digit */ @@ -75,5 +75,5 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mul_d.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_mulmod.c b/libtommath/bn_mp_mulmod.c index cb605ed..d84c555 100644 --- a/libtommath/bn_mp_mulmod.c +++ b/libtommath/bn_mp_mulmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a * b (mod c) */ @@ -36,5 +36,5 @@ int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_mulmod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_n_root.c b/libtommath/bn_mp_n_root.c index 2fadc6c..734d5ea 100644 --- a/libtommath/bn_mp_n_root.c +++ b/libtommath/bn_mp_n_root.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* find the n'th root of an integer @@ -128,5 +128,5 @@ LBL_T1:mp_clear (&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_n_root.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_neg.c b/libtommath/bn_mp_neg.c index 9cc654a..17e851a 100644 --- a/libtommath/bn_mp_neg.c +++ b/libtommath/bn_mp_neg.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = -a */ @@ -36,5 +36,5 @@ int mp_neg (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_neg.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_or.c b/libtommath/bn_mp_or.c index 14c0f19..09df58c 100644 --- a/libtommath/bn_mp_or.c +++ b/libtommath/bn_mp_or.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* OR two ints together */ @@ -46,5 +46,5 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_or.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_fermat.c b/libtommath/bn_mp_prime_fermat.c index 9b647cb..f6edf9e 100644 --- a/libtommath/bn_mp_prime_fermat.c +++ b/libtommath/bn_mp_prime_fermat.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* performs one Fermat test. @@ -58,5 +58,5 @@ LBL_T:mp_clear (&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_fermat.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_is_divisible.c b/libtommath/bn_mp_prime_is_divisible.c index 11a2f27..897c11b 100644 --- a/libtommath/bn_mp_prime_is_divisible.c +++ b/libtommath/bn_mp_prime_is_divisible.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if an integers is divisible by one @@ -46,5 +46,5 @@ int mp_prime_is_divisible (mp_int * a, int *result) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_is_divisible.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_is_prime.c b/libtommath/bn_mp_prime_is_prime.c index 3e0e36b..135f1d9 100644 --- a/libtommath/bn_mp_prime_is_prime.c +++ b/libtommath/bn_mp_prime_is_prime.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* performs a variable number of rounds of Miller-Rabin @@ -79,5 +79,5 @@ LBL_B:mp_clear (&b); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_is_prime.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_miller_rabin.c b/libtommath/bn_mp_prime_miller_rabin.c index 712f20d..f2d6c7f 100644 --- a/libtommath/bn_mp_prime_miller_rabin.c +++ b/libtommath/bn_mp_prime_miller_rabin.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Miller-Rabin test of "a" to the base of "b" as described in @@ -99,5 +99,5 @@ LBL_N1:mp_clear (&n1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_miller_rabin.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_next_prime.c b/libtommath/bn_mp_prime_next_prime.c index 48b8f02..a875260 100644 --- a/libtommath/bn_mp_prime_next_prime.c +++ b/libtommath/bn_mp_prime_next_prime.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* finds the next prime after the number "a" using "t" trials @@ -166,5 +166,5 @@ LBL_ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_next_prime.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_rabin_miller_trials.c b/libtommath/bn_mp_prime_rabin_miller_trials.c index c4c9f5e..30825a3 100644 --- a/libtommath/bn_mp_prime_rabin_miller_trials.c +++ b/libtommath/bn_mp_prime_rabin_miller_trials.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ @@ -48,5 +48,5 @@ int mp_prime_rabin_miller_trials(int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_rabin_miller_trials.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_prime_random_ex.c b/libtommath/bn_mp_prime_random_ex.c index daca61c..baddd10 100644 --- a/libtommath/bn_mp_prime_random_ex.c +++ b/libtommath/bn_mp_prime_random_ex.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* makes a truly random prime of a given size (bits), @@ -121,5 +121,5 @@ error: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_prime_random_ex.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_radix_size.c b/libtommath/bn_mp_radix_size.c index 7e01577..cf0a093 100644 --- a/libtommath/bn_mp_radix_size.c +++ b/libtommath/bn_mp_radix_size.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* returns size of ASCII reprensentation */ @@ -74,5 +74,5 @@ int mp_radix_size (mp_int * a, int radix, int *size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_radix_size.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 17:59:38 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_radix_smap.c b/libtommath/bn_mp_radix_smap.c index b9b88f9..913acad 100644 --- a/libtommath/bn_mp_radix_smap.c +++ b/libtommath/bn_mp_radix_smap.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* chars used in radix conversions */ @@ -20,5 +20,5 @@ const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrs #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_radix_smap.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_rand.c b/libtommath/bn_mp_rand.c index 94b0e7f..6de7447 100644 --- a/libtommath/bn_mp_rand.c +++ b/libtommath/bn_mp_rand.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* makes a pseudo-random int of a given size */ @@ -51,5 +51,5 @@ mp_rand (mp_int * a, int digits) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_rand.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_read_radix.c b/libtommath/bn_mp_read_radix.c index 1aea788..9a6dd9b 100644 --- a/libtommath/bn_mp_read_radix.c +++ b/libtommath/bn_mp_read_radix.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read a string [ASCII] in a given radix */ @@ -81,5 +81,5 @@ int mp_read_radix (mp_int * a, const char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_radix.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 17:59:38 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_read_signed_bin.c b/libtommath/bn_mp_read_signed_bin.c index 05b1c9c..ae9e6a8 100644 --- a/libtommath/bn_mp_read_signed_bin.c +++ b/libtommath/bn_mp_read_signed_bin.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read signed bin, big endian, first byte is 0==positive or 1==negative */ @@ -37,5 +37,5 @@ int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_signed_bin.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_read_unsigned_bin.c b/libtommath/bn_mp_read_unsigned_bin.c index 655415a..b94265f 100644 --- a/libtommath/bn_mp_read_unsigned_bin.c +++ b/libtommath/bn_mp_read_unsigned_bin.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reads a unsigned char array, assumes the msb is stored first [big endian] */ @@ -51,5 +51,5 @@ int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_read_unsigned_bin.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce.c b/libtommath/bn_mp_reduce.c index dbc38c8..e4c8842 100644 --- a/libtommath/bn_mp_reduce.c +++ b/libtommath/bn_mp_reduce.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces x mod m, assumes 0 < x < m**2, mu is @@ -96,5 +96,5 @@ CLEANUP: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_2k.c b/libtommath/bn_mp_reduce_2k.c index 790ac3c..0bc9f36 100644 --- a/libtommath/bn_mp_reduce_2k.c +++ b/libtommath/bn_mp_reduce_2k.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces a modulo n where n is of the form 2**p - d */ @@ -57,5 +57,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_2k_l.c b/libtommath/bn_mp_reduce_2k_l.c index 6a013cf..ff50948 100644 --- a/libtommath/bn_mp_reduce_2k_l.c +++ b/libtommath/bn_mp_reduce_2k_l.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces a modulo n where n is of the form 2**p - d @@ -58,5 +58,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_l.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_2k_setup.c b/libtommath/bn_mp_reduce_2k_setup.c index 17c54c5..2a97cd0 100644 --- a/libtommath/bn_mp_reduce_2k_setup.c +++ b/libtommath/bn_mp_reduce_2k_setup.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -43,5 +43,5 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_setup.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_2k_setup_l.c b/libtommath/bn_mp_reduce_2k_setup_l.c index 2913162..acff733 100644 --- a/libtommath/bn_mp_reduce_2k_setup_l.c +++ b/libtommath/bn_mp_reduce_2k_setup_l.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -40,5 +40,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_2k_setup_l.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_is_2k.c b/libtommath/bn_mp_reduce_is_2k.c index ad14107..e398e19 100644 --- a/libtommath/bn_mp_reduce_is_2k.c +++ b/libtommath/bn_mp_reduce_is_2k.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if mp_reduce_2k can be used */ @@ -48,5 +48,5 @@ int mp_reduce_is_2k(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_is_2k.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_is_2k_l.c b/libtommath/bn_mp_reduce_is_2k_l.c index 160b2ce..82e972d 100644 --- a/libtommath/bn_mp_reduce_is_2k_l.c +++ b/libtommath/bn_mp_reduce_is_2k_l.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if reduce_2k_l can be used */ @@ -40,5 +40,5 @@ int mp_reduce_is_2k_l(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_is_2k_l.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_reduce_setup.c b/libtommath/bn_mp_reduce_setup.c index 4d2d99f..94bd26f 100644 --- a/libtommath/bn_mp_reduce_setup.c +++ b/libtommath/bn_mp_reduce_setup.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* pre-calculate the value required for Barrett reduction @@ -30,5 +30,5 @@ int mp_reduce_setup (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_reduce_setup.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_rshd.c b/libtommath/bn_mp_rshd.c index d5a75c6..ebc8d5f 100644 --- a/libtommath/bn_mp_rshd.c +++ b/libtommath/bn_mp_rshd.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift right a certain amount of digits */ @@ -68,5 +68,5 @@ void mp_rshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_rshd.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_set.c b/libtommath/bn_mp_set.c index af01b3c..9cb64c7 100644 --- a/libtommath/bn_mp_set.c +++ b/libtommath/bn_mp_set.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set to a digit */ @@ -25,5 +25,5 @@ void mp_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_set.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_set_int.c b/libtommath/bn_mp_set_int.c index c7ddb79..106c4e2 100644 --- a/libtommath/bn_mp_set_int.c +++ b/libtommath/bn_mp_set_int.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set a 32-bit const */ @@ -44,5 +44,5 @@ int mp_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_set_int.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_shrink.c b/libtommath/bn_mp_shrink.c index a40b65c..ddd72e3 100644 --- a/libtommath/bn_mp_shrink.c +++ b/libtommath/bn_mp_shrink.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shrink a bignum */ @@ -31,5 +31,5 @@ int mp_shrink (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_shrink.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_signed_bin_size.c b/libtommath/bn_mp_signed_bin_size.c index 4dbbeb8..97fdb96 100644 --- a/libtommath/bn_mp_signed_bin_size.c +++ b/libtommath/bn_mp_signed_bin_size.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the size for an signed equivalent */ @@ -23,5 +23,5 @@ int mp_signed_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_signed_bin_size.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_sqr.c b/libtommath/bn_mp_sqr.c index ac926e9..4e75bdb 100644 --- a/libtommath/bn_mp_sqr.c +++ b/libtommath/bn_mp_sqr.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes b = a*a */ @@ -54,5 +54,5 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqr.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_sqrmod.c b/libtommath/bn_mp_sqrmod.c index fe5f4bb..d0f0a79 100644 --- a/libtommath/bn_mp_sqrmod.c +++ b/libtommath/bn_mp_sqrmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = a * a (mod b) */ @@ -37,5 +37,5 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqrmod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_sqrt.c b/libtommath/bn_mp_sqrt.c index ac8c2b8..086801d 100644 --- a/libtommath/bn_mp_sqrt.c +++ b/libtommath/bn_mp_sqrt.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* this function is less generic than mp_n_root, simpler and faster */ @@ -77,5 +77,5 @@ E2: mp_clear(&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sqrt.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_sub.c b/libtommath/bn_mp_sub.c index 52e1e43..c0e2def 100644 --- a/libtommath/bn_mp_sub.c +++ b/libtommath/bn_mp_sub.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level subtraction (handles signs) */ @@ -55,5 +55,5 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sub.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_sub_d.c b/libtommath/bn_mp_sub_d.c index ffeea09..d979f35 100644 --- a/libtommath/bn_mp_sub_d.c +++ b/libtommath/bn_mp_sub_d.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* single digit subtraction */ @@ -89,5 +89,5 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_sub_d.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/12/27 17:59:38 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_submod.c b/libtommath/bn_mp_submod.c index f735e9e..046e844 100644 --- a/libtommath/bn_mp_submod.c +++ b/libtommath/bn_mp_submod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a - b (mod c) */ @@ -38,5 +38,5 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_submod.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_to_signed_bin.c b/libtommath/bn_mp_to_signed_bin.c index bc07d1e..066eb51 100644 --- a/libtommath/bn_mp_to_signed_bin.c +++ b/libtommath/bn_mp_to_signed_bin.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in signed [big endian] format */ @@ -29,5 +29,5 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_signed_bin.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_to_signed_bin_n.c b/libtommath/bn_mp_to_signed_bin_n.c index ff2a768..b1df632 100644 --- a/libtommath/bn_mp_to_signed_bin_n.c +++ b/libtommath/bn_mp_to_signed_bin_n.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in signed [big endian] format */ @@ -27,5 +27,5 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_signed_bin_n.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_to_unsigned_bin.c b/libtommath/bn_mp_to_unsigned_bin.c index 29b8d36..d69de35 100644 --- a/libtommath/bn_mp_to_unsigned_bin.c +++ b/libtommath/bn_mp_to_unsigned_bin.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in unsigned [big endian] format */ @@ -44,5 +44,5 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_unsigned_bin.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_to_unsigned_bin_n.c b/libtommath/bn_mp_to_unsigned_bin_n.c index 415e87d..5621960 100644 --- a/libtommath/bn_mp_to_unsigned_bin_n.c +++ b/libtommath/bn_mp_to_unsigned_bin_n.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in unsigned [big endian] format */ @@ -27,5 +27,5 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_to_unsigned_bin_n.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_toom_mul.c b/libtommath/bn_mp_toom_mul.c index e6fb523..14d0705 100644 --- a/libtommath/bn_mp_toom_mul.c +++ b/libtommath/bn_mp_toom_mul.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplication using the Toom-Cook 3-way algorithm @@ -280,5 +280,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toom_mul.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_toom_sqr.c b/libtommath/bn_mp_toom_sqr.c index ba800a0..14a235a 100644 --- a/libtommath/bn_mp_toom_sqr.c +++ b/libtommath/bn_mp_toom_sqr.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* squaring using Toom-Cook 3-way algorithm */ @@ -222,5 +222,5 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toom_sqr.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_toradix.c b/libtommath/bn_mp_toradix.c index 96ac736..1bd8819 100644 --- a/libtommath/bn_mp_toradix.c +++ b/libtommath/bn_mp_toradix.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* stores a bignum as a ASCII string in a given radix (2..64) */ @@ -71,5 +71,5 @@ int mp_toradix (mp_int * a, char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toradix.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_toradix_n.c b/libtommath/bn_mp_toradix_n.c index 607a4be..39d5101 100644 --- a/libtommath/bn_mp_toradix_n.c +++ b/libtommath/bn_mp_toradix_n.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* stores a bignum as a ASCII string in a given radix (2..64) @@ -84,5 +84,5 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_toradix_n.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/12/27 17:59:38 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_unsigned_bin_size.c b/libtommath/bn_mp_unsigned_bin_size.c index 9622dbf..e79b91a 100644 --- a/libtommath/bn_mp_unsigned_bin_size.c +++ b/libtommath/bn_mp_unsigned_bin_size.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the size for an unsigned equivalent */ @@ -24,5 +24,5 @@ int mp_unsigned_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_unsigned_bin_size.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_xor.c b/libtommath/bn_mp_xor.c index ae9f29b..bf40408 100644 --- a/libtommath/bn_mp_xor.c +++ b/libtommath/bn_mp_xor.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* XOR two ints together */ @@ -47,5 +47,5 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_xor.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_mp_zero.c b/libtommath/bn_mp_zero.c index 6f7469c..3cbd933 100644 --- a/libtommath/bn_mp_zero.c +++ b/libtommath/bn_mp_zero.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set to zero */ @@ -32,5 +32,5 @@ void mp_zero (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_mp_zero.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_prime_tab.c b/libtommath/bn_prime_tab.c index 9ec6d7a..38cb592 100644 --- a/libtommath/bn_prime_tab.c +++ b/libtommath/bn_prime_tab.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ const mp_digit ltm_prime_tab[] = { 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, @@ -57,5 +57,5 @@ const mp_digit ltm_prime_tab[] = { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_prime_tab.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_reverse.c b/libtommath/bn_reverse.c index ad119ff..3132f93 100644 --- a/libtommath/bn_reverse.c +++ b/libtommath/bn_reverse.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reverse an array, used for radix code */ @@ -35,5 +35,5 @@ bn_reverse (unsigned char *s, int len) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_reverse.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_add.c b/libtommath/bn_s_mp_add.c index f196f3e..7023300 100644 --- a/libtommath/bn_s_mp_add.c +++ b/libtommath/bn_s_mp_add.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level addition, based on HAC pp.594, Algorithm 14.7 */ @@ -105,5 +105,5 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_add.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_exptmod.c b/libtommath/bn_s_mp_exptmod.c index d33558a..7c6e304 100644 --- a/libtommath/bn_s_mp_exptmod.c +++ b/libtommath/bn_s_mp_exptmod.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #ifdef MP_LOW_MEM #define TAB_SIZE 32 @@ -248,5 +248,5 @@ LBL_M: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_exptmod.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_mul_digs.c b/libtommath/bn_s_mp_mul_digs.c index e296640..eb99e33 100644 --- a/libtommath/bn_s_mp_mul_digs.c +++ b/libtommath/bn_s_mp_mul_digs.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplies |a| * |b| and only computes upto digs digits of result @@ -86,5 +86,5 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_mul_digs.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_mul_high_digs.c b/libtommath/bn_s_mp_mul_high_digs.c index 972918f..2ae9ee1 100644 --- a/libtommath/bn_s_mp_mul_high_digs.c +++ b/libtommath/bn_s_mp_mul_high_digs.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplies |a| * |b| and does not compute the lower digs digits @@ -77,5 +77,5 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_mul_high_digs.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_sqr.c b/libtommath/bn_s_mp_sqr.c index 1b1e0b4..0ae2869 100644 --- a/libtommath/bn_s_mp_sqr.c +++ b/libtommath/bn_s_mp_sqr.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ @@ -80,5 +80,5 @@ int s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_sqr.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bn_s_mp_sub.c b/libtommath/bn_s_mp_sub.c index fb2ea21..94375a0 100644 --- a/libtommath/bn_s_mp_sub.c +++ b/libtommath/bn_s_mp_sub.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ @@ -85,5 +85,5 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bn_s_mp_sub.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/bncore.c b/libtommath/bncore.c index fad10d2..e53fdee 100644 --- a/libtommath/bncore.c +++ b/libtommath/bncore.c @@ -12,7 +12,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Known optimal configurations @@ -32,5 +32,5 @@ int KARATSUBA_MUL_CUTOFF = 80, /* Min. number of digits before Karatsub #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/bncore.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:56 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:11 $ */ diff --git a/libtommath/changes.txt b/libtommath/changes.txt index 1322d14..9498d36 100644 --- a/libtommath/changes.txt +++ b/libtommath/changes.txt @@ -1,3 +1,14 @@ +April 4th, 2006 +v0.39 -- Jim Wigginton pointed out my Montgomery examples in figures 6.4 and 6.6 were off by one, k should be 9 not 8 + -- Bruce Guenter suggested I use --tag=CC for libtool builds where the compiler may think it's C++. + -- "mm" from sci.crypt pointed out that my mp_gcd was sub-optimal (I also updated and corrected the book) + -- updated some of the @@ tags in tommath.src to reflect source changes. + -- updated email and url info in all source files + +Jan 26th, 2006 +v0.38 -- broken makefile.shared fixed + -- removed some carry stores that were not required [updated text] + November 18th, 2005 v0.37 -- [Don Porter] reported on a TCL list [HEY SEND ME BUGREPORTS ALREADY!!!] that mp_add_d() would compute -0 with some inputs. Fixed. -- [rinick@gmail.com] reported the makefile.bcc was messed up. Fixed. diff --git a/libtommath/etc/mersenne.c b/libtommath/etc/mersenne.c index 939616f..e4891c8 100644 --- a/libtommath/etc/mersenne.c +++ b/libtommath/etc/mersenne.c @@ -1,6 +1,6 @@ /* Finds Mersenne primes using the Lucas-Lehmer test * - * Tom St Denis, tomstdenis@iahu.ca + * Tom St Denis, tomstdenis@gmail.com */ #include #include @@ -140,5 +140,5 @@ main (void) } /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/mersenne.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:32:16 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:28 $ */ diff --git a/libtommath/etc/pprime.c b/libtommath/etc/pprime.c index a922b64..abb3c5a 100644 --- a/libtommath/etc/pprime.c +++ b/libtommath/etc/pprime.c @@ -1,8 +1,8 @@ /* Generates provable primes * - * See http://iahu.ca:8080/papers/pp.pdf for more info. + * See http://gmail.com:8080/papers/pp.pdf for more info. * - * Tom St Denis, tomstdenis@iahu.ca, http://tom.iahu.ca + * Tom St Denis, tomstdenis@gmail.com, http://tom.gmail.com */ #include #include "tommath.h" @@ -396,5 +396,5 @@ main (void) } /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/pprime.c,v $ */ -/* $Revision: 1.1.1.2 $ */ -/* $Date: 2005/09/26 16:32:16 $ */ +/* $Revision: 1.1.1.3 $ */ +/* $Date: 2006/12/01 00:08:28 $ */ diff --git a/libtommath/etc/tune.c b/libtommath/etc/tune.c index b09c7d9..3088bdb 100644 --- a/libtommath/etc/tune.c +++ b/libtommath/etc/tune.c @@ -1,6 +1,6 @@ /* Tune the Karatsuba parameters * - * Tom St Denis, tomstdenis@iahu.ca + * Tom St Denis, tomstdenis@gmail.com */ #include #include @@ -138,5 +138,5 @@ main (void) } /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/etc/tune.c,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:32:16 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:29 $ */ diff --git a/libtommath/makefile b/libtommath/makefile index 192e842..e08a888 100644 --- a/libtommath/makefile +++ b/libtommath/makefile @@ -3,7 +3,7 @@ #Tom St Denis #version of library -VERSION=0.37 +VERSION=0.39 CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare diff --git a/libtommath/makefile.shared b/libtommath/makefile.shared index 9d2c20a..8522d44 100644 --- a/libtommath/makefile.shared +++ b/libtommath/makefile.shared @@ -1,9 +1,9 @@ #Makefile for GCC # #Tom St Denis -VERSION=0:37 +VERSION=0:39 -CC = libtool --mode=compile gcc +CC = libtool --mode=compile --tag=CC gcc CFLAGS += -I./ -Wall -W -Wshadow -Wsign-compare @@ -86,7 +86,8 @@ $(LIBNAME): $(OBJECTS) libtool --mode=link gcc *.lo -o $(LIBNAME) -rpath $(LIBPATH) -version-info $(VERSION) install: $(LIBNAME) - libtool --mode=install install -c $(LIBNAME) $(LIBPATH)/$(LIBNAME) + install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(LIBPATH) + libtool --mode=install install -c $(LIBNAME) $(DESTDIR)$(LIBPATH)/$(LIBNAME) install -d -g $(GROUP) -o $(USER) $(DESTDIR)$(INCPATH) install -g $(GROUP) -o $(USER) $(HEADERS) $(DESTDIR)$(INCPATH) diff --git a/libtommath/poster.pdf b/libtommath/poster.pdf index 95bf4b3..1f705cf 100644 Binary files a/libtommath/poster.pdf and b/libtommath/poster.pdf differ diff --git a/libtommath/pre_gen/mpi.c b/libtommath/pre_gen/mpi.c index d915a58..62ec029 100644 --- a/libtommath/pre_gen/mpi.c +++ b/libtommath/pre_gen/mpi.c @@ -13,7 +13,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static const struct { @@ -44,8 +44,8 @@ char *mp_error_to_string(int code) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_error.c */ @@ -64,7 +64,7 @@ char *mp_error_to_string(int code) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes the modular inverse via binary extended euclidean algorithm, @@ -196,8 +196,8 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_fast_mp_invmod.c */ @@ -216,7 +216,7 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &B, &D, NULL); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes xR**-1 == x (mod N) via Montgomery Reduction @@ -372,8 +372,8 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_fast_mp_montgomery_reduce.c */ @@ -392,7 +392,7 @@ int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Fast (comba) multiplier @@ -458,10 +458,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) /* make next carry */ _W = _W >> ((mp_word)DIGIT_BIT); - } - - /* store final carry */ - W[ix] = (mp_digit)(_W & MP_MASK); + } /* setup dest */ olduse = c->used; @@ -486,8 +483,8 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_fast_s_mp_mul_digs.c */ @@ -506,7 +503,7 @@ int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* this is a modified version of fast_s_mul_digs that only produces @@ -564,9 +561,6 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) _W = _W >> ((mp_word)DIGIT_BIT); } - /* store final carry */ - W[ix] = (mp_digit)(_W & MP_MASK); - /* setup dest */ olduse = c->used; c->used = pa; @@ -591,8 +585,8 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_fast_s_mp_mul_high_digs.c */ @@ -611,7 +605,7 @@ int fast_s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* the jist of squaring... @@ -709,8 +703,8 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_fast_s_mp_sqr.c */ @@ -729,7 +723,7 @@ int fast_s_mp_sqr (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes a = 2**b @@ -761,8 +755,8 @@ mp_2expt (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_2expt.c */ @@ -781,7 +775,7 @@ mp_2expt (mp_int * a, int b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = |a| @@ -808,8 +802,8 @@ mp_abs (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_abs.c */ @@ -828,7 +822,7 @@ mp_abs (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level addition (handles signs) */ @@ -865,8 +859,8 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_add.c */ @@ -885,7 +879,7 @@ int mp_add (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* single digit addition */ @@ -981,8 +975,8 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_add_d.c */ @@ -1001,7 +995,7 @@ mp_add_d (mp_int * a, mp_digit b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a + b (mod c) */ @@ -1026,8 +1020,8 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_addmod.c */ @@ -1046,7 +1040,7 @@ mp_addmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* AND two ints together */ @@ -1087,8 +1081,8 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_and.c */ @@ -1107,7 +1101,7 @@ mp_and (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* trim unused digits @@ -1135,8 +1129,8 @@ mp_clamp (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_clamp.c */ @@ -1155,7 +1149,7 @@ mp_clamp (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* clear one (frees) */ @@ -1183,8 +1177,8 @@ mp_clear (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_clear.c */ @@ -1203,7 +1197,7 @@ mp_clear (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #include @@ -1221,8 +1215,8 @@ void mp_clear_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_clear_multi.c */ @@ -1241,7 +1235,7 @@ void mp_clear_multi(mp_int *mp, ...) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare two ints (signed)*/ @@ -1268,8 +1262,8 @@ mp_cmp (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_cmp.c */ @@ -1288,7 +1282,7 @@ mp_cmp (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare a digit */ @@ -1316,8 +1310,8 @@ int mp_cmp_d(mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_cmp_d.c */ @@ -1336,7 +1330,7 @@ int mp_cmp_d(mp_int * a, mp_digit b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* compare maginitude of two ints (unsigned) */ @@ -1375,8 +1369,8 @@ int mp_cmp_mag (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_cmp_mag.c */ @@ -1395,7 +1389,7 @@ int mp_cmp_mag (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static const int lnz[16] = { @@ -1432,8 +1426,8 @@ int mp_cnt_lsb(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_cnt_lsb.c */ @@ -1452,7 +1446,7 @@ int mp_cnt_lsb(mp_int *a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* copy, b = a */ @@ -1504,8 +1498,8 @@ mp_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_copy.c */ @@ -1524,7 +1518,7 @@ mp_copy (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* returns the number of bits in an int */ @@ -1553,8 +1547,8 @@ mp_count_bits (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_count_bits.c */ @@ -1573,7 +1567,7 @@ mp_count_bits (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #ifdef BN_MP_DIV_SMALL @@ -1849,8 +1843,8 @@ LBL_Q:mp_clear (&q); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_div.c */ @@ -1869,7 +1863,7 @@ LBL_Q:mp_clear (&q); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = a/2 */ @@ -1921,8 +1915,8 @@ int mp_div_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_div_2.c */ @@ -1941,7 +1935,7 @@ int mp_div_2(mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift right by a certain bit count (store quotient in c, optional remainder in d) */ @@ -2022,8 +2016,8 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_div_2d.c */ @@ -2042,7 +2036,7 @@ int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* divide by three (based on routine from MPI and the GMP manual) */ @@ -2105,8 +2099,8 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_div_3.c */ @@ -2125,7 +2119,7 @@ mp_div_3 (mp_int * a, mp_int *c, mp_digit * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ static int s_is_power_of_two(mp_digit b, int *p) @@ -2219,8 +2213,8 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_div_d.c */ @@ -2239,7 +2233,7 @@ int mp_div_d (mp_int * a, mp_digit b, mp_int * c, mp_digit * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if a number is a valid DR modulus */ @@ -2266,8 +2260,8 @@ int mp_dr_is_modulus(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_dr_is_modulus.c */ @@ -2286,7 +2280,7 @@ int mp_dr_is_modulus(mp_int *a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduce "x" in place modulo "n" using the Diminished Radix algorithm. @@ -2364,8 +2358,8 @@ top: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_dr_reduce.c */ @@ -2384,7 +2378,7 @@ top: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -2400,8 +2394,8 @@ void mp_dr_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_dr_setup.c */ @@ -2420,7 +2414,7 @@ void mp_dr_setup(mp_int *a, mp_digit *d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* swap the elements of two integers, for cases where you can't simply swap the @@ -2438,8 +2432,8 @@ mp_exch (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_exch.c */ @@ -2458,7 +2452,7 @@ mp_exch (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* calculate c = a**b using a square-multiply algorithm */ @@ -2499,8 +2493,8 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_expt_d.c */ @@ -2519,7 +2513,7 @@ int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ @@ -2615,8 +2609,8 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_exptmod.c */ @@ -2635,7 +2629,7 @@ int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes Y == G**X mod P, HAC pp.616, Algorithm 14.85 @@ -2940,8 +2934,8 @@ LBL_M: /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_exptmod_fast.c */ @@ -2960,7 +2954,7 @@ LBL_M: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Extended euclidean algorithm of (a, b) produces @@ -3026,8 +3020,8 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_exteuclid.c */ @@ -3046,7 +3040,7 @@ _ERR: mp_clear_multi(&u1, &u2, &u3, &v1, &v2, &v3, &t1, &t2, &t3, &q, &tmp, NULL * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read a bigint from a file stream in ASCII */ @@ -3097,8 +3091,8 @@ int mp_fread(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_fread.c */ @@ -3117,7 +3111,7 @@ int mp_fread(mp_int *a, int radix, FILE *stream) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ int mp_fwrite(mp_int *a, int radix, FILE *stream) @@ -3153,8 +3147,8 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_fwrite.c */ @@ -3173,7 +3167,7 @@ int mp_fwrite(mp_int *a, int radix, FILE *stream) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Greatest Common Divisor using the binary method */ @@ -3183,21 +3177,13 @@ int mp_gcd (mp_int * a, mp_int * b, mp_int * c) int k, u_lsb, v_lsb, res; /* either zero than gcd is the largest */ - if (mp_iszero (a) == 1 && mp_iszero (b) == 0) { + if (mp_iszero (a) == MP_YES) { return mp_abs (b, c); } - if (mp_iszero (a) == 0 && mp_iszero (b) == 1) { + if (mp_iszero (b) == MP_YES) { return mp_abs (a, c); } - /* optimized. At this point if a == 0 then - * b must equal zero too - */ - if (mp_iszero (a) == 1) { - mp_zero(c); - return MP_OKAY; - } - /* get copies of a and b we can modify */ if ((res = mp_init_copy (&u, a)) != MP_OKAY) { return res; @@ -3270,8 +3256,8 @@ LBL_U:mp_clear (&v); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_gcd.c */ @@ -3290,7 +3276,7 @@ LBL_U:mp_clear (&v); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the lower 32-bits of an mp_int */ @@ -3319,8 +3305,8 @@ unsigned long mp_get_int(mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_get_int.c */ @@ -3339,7 +3325,7 @@ unsigned long mp_get_int(mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* grow as required */ @@ -3380,8 +3366,8 @@ int mp_grow (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_grow.c */ @@ -3400,7 +3386,7 @@ int mp_grow (mp_int * a, int size) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* init a new mp_int */ @@ -3430,8 +3416,8 @@ int mp_init (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init.c */ @@ -3450,7 +3436,7 @@ int mp_init (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* creates "a" then copies b into it */ @@ -3466,8 +3452,8 @@ int mp_init_copy (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init_copy.c */ @@ -3486,7 +3472,7 @@ int mp_init_copy (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #include @@ -3529,8 +3515,8 @@ int mp_init_multi(mp_int *mp, ...) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init_multi.c */ @@ -3549,7 +3535,7 @@ int mp_init_multi(mp_int *mp, ...) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* initialize and set a digit */ @@ -3565,8 +3551,8 @@ int mp_init_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init_set.c */ @@ -3585,7 +3571,7 @@ int mp_init_set (mp_int * a, mp_digit b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* initialize and set a digit */ @@ -3600,8 +3586,8 @@ int mp_init_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init_set_int.c */ @@ -3620,7 +3606,7 @@ int mp_init_set_int (mp_int * a, unsigned long b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* init an mp_init for a given size */ @@ -3652,8 +3638,8 @@ int mp_init_size (mp_int * a, int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_init_size.c */ @@ -3672,7 +3658,7 @@ int mp_init_size (mp_int * a, int size) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* hac 14.61, pp608 */ @@ -3699,8 +3685,8 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_invmod.c */ @@ -3719,7 +3705,7 @@ int mp_invmod (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* hac 14.61, pp608 */ @@ -3878,8 +3864,8 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_invmod_slow.c */ @@ -3898,7 +3884,7 @@ LBL_ERR:mp_clear_multi (&x, &y, &u, &v, &A, &B, &C, &D, NULL); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Check if remainders are possible squares - fast exclude non-squares */ @@ -3991,8 +3977,8 @@ ERR:mp_clear(&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_is_square.c */ @@ -4011,7 +3997,7 @@ ERR:mp_clear(&t); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes the jacobi c = (a | n) (or Legendre if n is prime) @@ -4100,8 +4086,8 @@ LBL_A1:mp_clear (&a1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_jacobi.c */ @@ -4120,7 +4106,7 @@ LBL_A1:mp_clear (&a1); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = |a| * |b| using Karatsuba Multiplication using @@ -4271,8 +4257,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_karatsuba_mul.c */ @@ -4291,7 +4277,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Karatsuba squaring, computes b = a*a using three @@ -4396,8 +4382,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_karatsuba_sqr.c */ @@ -4416,7 +4402,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes least common multiple as |a*b|/(a, b) */ @@ -4460,8 +4446,8 @@ LBL_T: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_lcm.c */ @@ -4480,7 +4466,7 @@ LBL_T: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift left a certain amount of digits */ @@ -4531,8 +4517,8 @@ int mp_lshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_lshd.c */ @@ -4551,7 +4537,7 @@ int mp_lshd (mp_int * a, int b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = a mod b, 0 <= c < b */ @@ -4583,8 +4569,8 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mod.c */ @@ -4603,7 +4589,7 @@ mp_mod (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* calc a value mod 2**b */ @@ -4642,8 +4628,8 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mod_2d.c */ @@ -4662,7 +4648,7 @@ mp_mod_2d (mp_int * a, int b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ int @@ -4673,8 +4659,8 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mod_d.c */ @@ -4693,7 +4679,7 @@ mp_mod_d (mp_int * a, mp_digit b, mp_digit * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* @@ -4736,8 +4722,8 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_montgomery_calc_normalization.c */ @@ -4756,7 +4742,7 @@ int mp_montgomery_calc_normalization (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes xR**-1 == x (mod N) via Montgomery Reduction */ @@ -4858,8 +4844,8 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_montgomery_reduce.c */ @@ -4878,7 +4864,7 @@ mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* setups the montgomery reduction stuff */ @@ -4921,8 +4907,8 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_montgomery_setup.c */ @@ -4941,7 +4927,7 @@ mp_montgomery_setup (mp_int * n, mp_digit * rho) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level multiplication (handles sign) */ @@ -4991,8 +4977,8 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mul.c */ @@ -5011,7 +4997,7 @@ int mp_mul (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = a*2 */ @@ -5077,8 +5063,8 @@ int mp_mul_2(mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mul_2.c */ @@ -5097,7 +5083,7 @@ int mp_mul_2(mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift left by a certain bit count */ @@ -5166,8 +5152,8 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mul_2d.c */ @@ -5186,7 +5172,7 @@ int mp_mul_2d (mp_int * a, int b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiply by a digit */ @@ -5249,8 +5235,8 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mul_d.c */ @@ -5269,7 +5255,7 @@ mp_mul_d (mp_int * a, mp_digit b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a * b (mod c) */ @@ -5293,8 +5279,8 @@ int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_mulmod.c */ @@ -5313,7 +5299,7 @@ int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* find the n'th root of an integer @@ -5429,8 +5415,8 @@ LBL_T1:mp_clear (&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_n_root.c */ @@ -5449,7 +5435,7 @@ LBL_T1:mp_clear (&t1); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* b = -a */ @@ -5473,8 +5459,8 @@ int mp_neg (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_neg.c */ @@ -5493,7 +5479,7 @@ int mp_neg (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* OR two ints together */ @@ -5527,8 +5513,8 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_or.c */ @@ -5547,7 +5533,7 @@ int mp_or (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* performs one Fermat test. @@ -5593,8 +5579,8 @@ LBL_T:mp_clear (&t); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_fermat.c */ @@ -5613,7 +5599,7 @@ LBL_T:mp_clear (&t); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if an integers is divisible by one @@ -5647,8 +5633,8 @@ int mp_prime_is_divisible (mp_int * a, int *result) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_is_divisible.c */ @@ -5667,7 +5653,7 @@ int mp_prime_is_divisible (mp_int * a, int *result) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* performs a variable number of rounds of Miller-Rabin @@ -5734,8 +5720,8 @@ LBL_B:mp_clear (&b); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_is_prime.c */ @@ -5754,7 +5740,7 @@ LBL_B:mp_clear (&b); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Miller-Rabin test of "a" to the base of "b" as described in @@ -5841,8 +5827,8 @@ LBL_N1:mp_clear (&n1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_miller_rabin.c */ @@ -5861,7 +5847,7 @@ LBL_N1:mp_clear (&n1); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* finds the next prime after the number "a" using "t" trials @@ -6015,8 +6001,8 @@ LBL_ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_next_prime.c */ @@ -6035,7 +6021,7 @@ LBL_ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ @@ -6071,8 +6057,8 @@ int mp_prime_rabin_miller_trials(int size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_rabin_miller_trials.c */ @@ -6091,7 +6077,7 @@ int mp_prime_rabin_miller_trials(int size) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* makes a truly random prime of a given size (bits), @@ -6200,8 +6186,8 @@ error: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_prime_random_ex.c */ @@ -6220,7 +6206,7 @@ error: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* returns size of ASCII reprensentation */ @@ -6282,8 +6268,8 @@ int mp_radix_size (mp_int * a, int radix, int *size) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_radix_size.c */ @@ -6302,7 +6288,7 @@ int mp_radix_size (mp_int * a, int radix, int *size) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* chars used in radix conversions */ @@ -6310,8 +6296,8 @@ const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrs #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_radix_smap.c */ @@ -6330,7 +6316,7 @@ const char *mp_s_rmap = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrs * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* makes a pseudo-random int of a given size */ @@ -6369,8 +6355,8 @@ mp_rand (mp_int * a, int digits) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_rand.c */ @@ -6389,7 +6375,7 @@ mp_rand (mp_int * a, int digits) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read a string [ASCII] in a given radix */ @@ -6458,8 +6444,8 @@ int mp_read_radix (mp_int * a, const char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_read_radix.c */ @@ -6478,7 +6464,7 @@ int mp_read_radix (mp_int * a, const char *str, int radix) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* read signed bin, big endian, first byte is 0==positive or 1==negative */ @@ -6503,8 +6489,8 @@ int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_read_signed_bin.c */ @@ -6523,7 +6509,7 @@ int mp_read_signed_bin (mp_int * a, const unsigned char *b, int c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reads a unsigned char array, assumes the msb is stored first [big endian] */ @@ -6562,8 +6548,8 @@ int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_read_unsigned_bin.c */ @@ -6582,7 +6568,7 @@ int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces x mod m, assumes 0 < x < m**2, mu is @@ -6666,8 +6652,8 @@ CLEANUP: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce.c */ @@ -6686,7 +6672,7 @@ CLEANUP: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces a modulo n where n is of the form 2**p - d */ @@ -6731,8 +6717,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_2k.c */ @@ -6751,7 +6737,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reduces a modulo n where n is of the form 2**p - d @@ -6797,8 +6783,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_2k_l.c */ @@ -6817,7 +6803,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -6848,8 +6834,8 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_2k_setup.c */ @@ -6868,7 +6854,7 @@ int mp_reduce_2k_setup(mp_int *a, mp_digit *d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines the setup value */ @@ -6896,8 +6882,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_2k_setup_l.c */ @@ -6916,7 +6902,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if mp_reduce_2k can be used */ @@ -6952,8 +6938,8 @@ int mp_reduce_is_2k(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_is_2k.c */ @@ -6972,7 +6958,7 @@ int mp_reduce_is_2k(mp_int *a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* determines if reduce_2k_l can be used */ @@ -7000,8 +6986,8 @@ int mp_reduce_is_2k_l(mp_int *a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_is_2k_l.c */ @@ -7020,7 +7006,7 @@ int mp_reduce_is_2k_l(mp_int *a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* pre-calculate the value required for Barrett reduction @@ -7038,8 +7024,8 @@ int mp_reduce_setup (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_reduce_setup.c */ @@ -7058,7 +7044,7 @@ int mp_reduce_setup (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shift right a certain amount of digits */ @@ -7114,8 +7100,8 @@ void mp_rshd (mp_int * a, int b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_rshd.c */ @@ -7134,7 +7120,7 @@ void mp_rshd (mp_int * a, int b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set to a digit */ @@ -7147,8 +7133,8 @@ void mp_set (mp_int * a, mp_digit b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_set.c */ @@ -7167,7 +7153,7 @@ void mp_set (mp_int * a, mp_digit b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set a 32-bit const */ @@ -7199,8 +7185,8 @@ int mp_set_int (mp_int * a, unsigned long b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_set_int.c */ @@ -7219,7 +7205,7 @@ int mp_set_int (mp_int * a, unsigned long b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* shrink a bignum */ @@ -7238,8 +7224,8 @@ int mp_shrink (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_shrink.c */ @@ -7258,7 +7244,7 @@ int mp_shrink (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the size for an signed equivalent */ @@ -7269,8 +7255,8 @@ int mp_signed_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_signed_bin_size.c */ @@ -7289,7 +7275,7 @@ int mp_signed_bin_size (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* computes b = a*a */ @@ -7331,8 +7317,8 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_sqr.c */ @@ -7351,7 +7337,7 @@ if (a->used >= KARATSUBA_SQR_CUTOFF) { * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* c = a * a (mod b) */ @@ -7376,8 +7362,8 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_sqrmod.c */ @@ -7396,7 +7382,7 @@ mp_sqrmod (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* this function is less generic than mp_n_root, simpler and faster */ @@ -7461,8 +7447,8 @@ E2: mp_clear(&t1); #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_sqrt.c */ @@ -7481,7 +7467,7 @@ E2: mp_clear(&t1); * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* high level subtraction (handles signs) */ @@ -7524,8 +7510,8 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_sub.c */ @@ -7544,7 +7530,7 @@ mp_sub (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* single digit subtraction */ @@ -7621,8 +7607,8 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_sub_d.c */ @@ -7641,7 +7627,7 @@ mp_sub_d (mp_int * a, mp_digit b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* d = a - b (mod c) */ @@ -7667,8 +7653,8 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_submod.c */ @@ -7687,7 +7673,7 @@ mp_submod (mp_int * a, mp_int * b, mp_int * c, mp_int * d) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in signed [big endian] format */ @@ -7704,8 +7690,8 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_to_signed_bin.c */ @@ -7724,7 +7710,7 @@ int mp_to_signed_bin (mp_int * a, unsigned char *b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in signed [big endian] format */ @@ -7739,8 +7725,8 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_to_signed_bin_n.c */ @@ -7759,7 +7745,7 @@ int mp_to_signed_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in unsigned [big endian] format */ @@ -7791,8 +7777,8 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_to_unsigned_bin.c */ @@ -7811,7 +7797,7 @@ int mp_to_unsigned_bin (mp_int * a, unsigned char *b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* store in unsigned [big endian] format */ @@ -7826,8 +7812,8 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_to_unsigned_bin_n.c */ @@ -7846,7 +7832,7 @@ int mp_to_unsigned_bin_n (mp_int * a, unsigned char *b, unsigned long *outlen) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplication using the Toom-Cook 3-way algorithm @@ -8114,8 +8100,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_toom_mul.c */ @@ -8134,7 +8120,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* squaring using Toom-Cook 3-way algorithm */ @@ -8344,8 +8330,8 @@ ERR: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_toom_sqr.c */ @@ -8364,7 +8350,7 @@ ERR: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* stores a bignum as a ASCII string in a given radix (2..64) */ @@ -8423,8 +8409,8 @@ int mp_toradix (mp_int * a, char *str, int radix) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_toradix.c */ @@ -8443,7 +8429,7 @@ int mp_toradix (mp_int * a, char *str, int radix) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* stores a bignum as a ASCII string in a given radix (2..64) @@ -8515,8 +8501,8 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_toradix_n.c */ @@ -8535,7 +8521,7 @@ int mp_toradix_n(mp_int * a, char *str, int radix, int maxlen) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* get the size for an unsigned equivalent */ @@ -8547,8 +8533,8 @@ int mp_unsigned_bin_size (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_unsigned_bin_size.c */ @@ -8567,7 +8553,7 @@ int mp_unsigned_bin_size (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* XOR two ints together */ @@ -8602,8 +8588,8 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_xor.c */ @@ -8622,7 +8608,7 @@ mp_xor (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* set to zero */ @@ -8642,8 +8628,8 @@ void mp_zero (mp_int * a) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_mp_zero.c */ @@ -8662,7 +8648,7 @@ void mp_zero (mp_int * a) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ const mp_digit ltm_prime_tab[] = { 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, @@ -8707,8 +8693,8 @@ const mp_digit ltm_prime_tab[] = { #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_prime_tab.c */ @@ -8727,7 +8713,7 @@ const mp_digit ltm_prime_tab[] = { * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* reverse an array, used for radix code */ @@ -8750,8 +8736,8 @@ bn_reverse (unsigned char *s, int len) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_reverse.c */ @@ -8770,7 +8756,7 @@ bn_reverse (unsigned char *s, int len) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level addition, based on HAC pp.594, Algorithm 14.7 */ @@ -8863,8 +8849,8 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_add.c */ @@ -8883,7 +8869,7 @@ s_mp_add (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #ifdef MP_LOW_MEM #define TAB_SIZE 32 @@ -9119,8 +9105,8 @@ LBL_M: #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_exptmod.c */ @@ -9139,7 +9125,7 @@ LBL_M: * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplies |a| * |b| and only computes upto digs digits of result @@ -9213,8 +9199,8 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_mul_digs.c */ @@ -9233,7 +9219,7 @@ int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* multiplies |a| * |b| and does not compute the lower digs digits @@ -9298,8 +9284,8 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_mul_high_digs.c */ @@ -9318,7 +9304,7 @@ s_mp_mul_high_digs (mp_int * a, mp_int * b, mp_int * c, int digs) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ @@ -9386,8 +9372,8 @@ int s_mp_sqr (mp_int * a, mp_int * b) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_sqr.c */ @@ -9406,7 +9392,7 @@ int s_mp_sqr (mp_int * a, mp_int * b) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ @@ -9479,8 +9465,8 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bn_s_mp_sub.c */ @@ -9499,7 +9485,7 @@ s_mp_sub (mp_int * a, mp_int * b, mp_int * c) * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ /* Known optimal configurations @@ -9519,8 +9505,8 @@ int KARATSUBA_MUL_CUTOFF = 80, /* Min. number of digits before Karatsub #endif /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/pre_gen/mpi.c,v $ */ -/* $Revision: 1.1.1.4 $ */ -/* $Date: 2005/12/27 18:00:26 $ */ +/* $Revision: 1.1.1.5 $ */ +/* $Date: 2006/12/01 00:08:34 $ */ /* End: bncore.c */ diff --git a/libtommath/tommath.h b/libtommath/tommath.h index 43517b4..f9b2d11 100644 --- a/libtommath/tommath.h +++ b/libtommath/tommath.h @@ -10,7 +10,7 @@ * The library is free for all purposes without any express * guarantee it works. * - * Tom St Denis, tomstdenis@iahu.ca, http://math.libtomcrypt.org + * Tom St Denis, tomstdenis@gmail.com, http://math.libtomcrypt.com */ #ifndef BN_H_ #define BN_H_ @@ -580,5 +580,5 @@ extern const char *mp_s_rmap; /* $Source: /root/tcl/repos-to-convert/tcl/libtommath/tommath.h,v $ */ -/* $Revision: 1.1.1.3 $ */ -/* $Date: 2005/09/26 16:31:58 $ */ +/* $Revision: 1.1.1.4 $ */ +/* $Date: 2006/12/01 00:08:12 $ */ diff --git a/libtommath/tommath.pdf b/libtommath/tommath.pdf index 5c314f5..c9571d8 100644 Binary files a/libtommath/tommath.pdf and b/libtommath/tommath.pdf differ diff --git a/libtommath/tommath.src b/libtommath/tommath.src index 8e03635..4065822 100644 --- a/libtommath/tommath.src +++ b/libtommath/tommath.src @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.37 release of the +This text has been placed in the public domain. This text corresponds to the v0.39 release of the LibTomMath project. \begin{alltt} @@ -77,7 +77,7 @@ K2L 1C3 Canada Phone: 1-613-836-3160 -Email: tomstdenis@iahu.ca +Email: tomstdenis@gmail.com \end{alltt} This text is formatted to the international B5 paper size of 176mm wide by 250mm tall using the \LaTeX{} @@ -268,7 +268,7 @@ and fast modular inversion, which we consider practical oversights. These optim any form of useful performance in non-trivial applications. To solve this problem the focus of this text is on the practical aspects of implementing a multiple precision integer -package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.org}} package is used +package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.com}} package is used to demonstrate algorithms with real implementations\footnote{In the ISO C programming language.} that have been field tested and work very well. The LibTomMath library is freely available on the Internet for all uses and this text discusses a very large portion of the inner workings of the library. @@ -2190,7 +2190,7 @@ left. After the digits have been shifted appropriately at most $lg(\beta) - 1$ shifts are left to perform. Step 5 calculates the number of remaining shifts required. If it is non-zero a modified shift loop is used to calculate the remaining product. -Essentially the loop is a generic version of algorith mp\_mul2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ +Essentially the loop is a generic version of algorithm mp\_mul\_2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ variable is used to extract the upper $d$ bits to form the carry for the next iteration. This algorithm is loosely measured as a $O(2n)$ algorithm which means that if the input is $n$-digits that it takes $2n$ ``time'' to @@ -2611,17 +2611,16 @@ Place an array of \textbf{MP\_WARRAY} single precision digits named $W$ on the s \hspace{6mm}5.4.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx+iy}b_{ty-iy}$ \\ \hspace{3mm}5.5 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$\\ \hspace{3mm}5.6 $\_ \hat W \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ -6. $W_{pa} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ \\ -7. $oldused \leftarrow c.used$ \\ -8. $c.used \leftarrow digs$ \\ -9. for $ix$ from $0$ to $pa$ do \\ -\hspace{3mm}9.1 $c_{ix} \leftarrow W_{ix}$ \\ -10. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ -\hspace{3mm}10.1 $c_{ix} \leftarrow 0$ \\ +6. $oldused \leftarrow c.used$ \\ +7. $c.used \leftarrow digs$ \\ +8. for $ix$ from $0$ to $pa$ do \\ +\hspace{3mm}8.1 $c_{ix} \leftarrow W_{ix}$ \\ +9. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow 0$ \\ \\ -11. Clamp $c$. \\ -12. Return MP\_OKAY. \\ +10. Clamp $c$. \\ +11. Return MP\_OKAY. \\ \hline \end{tabular} \end{center} @@ -3731,6 +3730,7 @@ $0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction \hline $6$ & $x/2 = 139$ \\ \hline $7$ & $x + n = 396$, $x/2 = 198$ \\ \hline $8$ & $x/2 = 99$ \\ +\hline $9$ & $x + n = 356$, $x/2 = 178$ \\ \hline \end{tabular} \end{center} @@ -3739,8 +3739,8 @@ $0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction \label{fig:MONT1} \end{figure} -Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 8$. The result of the algorithm $r = 99$ is -congruent to the value of $2^{-8} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^8$ modulo $257$ the correct residue +Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 9$ (note $\beta^k = 512$ which is larger than $n$). The result of +the algorithm $r = 178$ is congruent to the value of $2^{-9} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^9$ modulo $257$ the correct residue $r \equiv 158$ is produced. Let $k = \lfloor lg(n) \rfloor + 1$ represent the number of bits in $n$. The current algorithm requires $2k^2$ single precision shifts @@ -3752,10 +3752,10 @@ Fortunately there exists an alternative representation of the algorithm. \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{Montgomery Reduction} (modified I). \\ -\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Input}. Integer $x$, $n$ and $k$ ($2^k > n$) \\ \textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ \hline \\ -1. for $t$ from $0$ to $k - 1$ do \\ +1. for $t$ from $1$ to $k$ do \\ \hspace{3mm}1.1 If the $t$'th bit of $x$ is one then \\ \hspace{6mm}1.1.1 $x \leftarrow x + 2^tn$ \\ 2. Return $x/2^k$. \\ @@ -3783,7 +3783,8 @@ precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a s \hline $6$ & $8896$ & $10001011000000$ \\ \hline $7$ & $x + 2^{6}n = 25344$ & $110001100000000$ \\ \hline $8$ & $25344$ & $110001100000000$ \\ -\hline -- & $x/2^k = 99$ & \\ +\hline $9$ & $x + 2^{7}n = 91136$ & $10110010000000000$ \\ +\hline -- & $x/2^k = 178$ & \\ \hline \end{tabular} \end{center} @@ -3792,7 +3793,7 @@ precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a s \label{fig:MONT2} \end{figure} -Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 8$. +Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 9$. With this algorithm a single shift right at the end is the only right shift required to reduce the input instead of $k$ right shifts inside the loop. Note that for the iterations $t = 2, 5, 6$ and $8$ where the result $x$ is not changed. In those iterations the $t$'th bit of $x$ is zero and the appropriate multiple of $n$ does not need to be added to force the $t$'th bit of the result to zero. @@ -3806,7 +3807,7 @@ previous algorithm re-written to compute the Montgomery reduction in this new fa \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{Montgomery Reduction} (modified II). \\ -\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Input}. Integer $x$, $n$ and $k$ ($\beta^k > n$) \\ \textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ \hline \\ 1. for $t$ from $0$ to $k - 1$ do \\ @@ -4938,15 +4939,15 @@ a Left-to-Right algorithm is used to process the remaining few bits. EXAM,bn_s_mp_exptmod.c -Lines @26,if@ through @40,}@ determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +Lines @31,if@ through @45,}@ determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement -on line @32,if@ the value of $x$ is already known to be greater than $140$. +on line @37,if@ the value of $x$ is already known to be greater than $140$. The conditional piece of code beginning on line @42,ifdef@ allows the window size to be restricted to five bits. This logic is used to ensure the table of precomputed powers of $G$ remains relatively small. -The for loop on line @49,for@ initializes the $M$ array while lines @59,mp_init@ and @62,mp_reduce@ compute the value of $\mu$ required for -Barrett reduction. +The for loop on line @60,for@ initializes the $M$ array while lines @71,mp_init@ and @75,mp_reduce@ through @85,}@ initialize the reduction +function that will be used for this modulus. -- More later. @@ -5229,23 +5230,23 @@ algorithm with only the quotient is mp_div(&a, &b, &c, NULL); /* c = [a/b] */ \end{verbatim} -Lines @37,if@ and @42,if@ handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor -respectively. After the two trivial cases all of the temporary variables are initialized. Line @76,neg@ determines the sign of -the quotient and line @77,sign@ ensures that both $x$ and $y$ are positive. +Lines @108,if@ and @113,if@ handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor +respectively. After the two trivial cases all of the temporary variables are initialized. Line @147,neg@ determines the sign of +the quotient and line @148,sign@ ensures that both $x$ and $y$ are positive. -The number of bits in the leading digit is calculated on line @80,norm@. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits +The number of bits in the leading digit is calculated on line @151,norm@. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits of precision which when reduced modulo $lg(\beta)$ produces the value of $k$. In this case $k$ is the number of bits in the leading digit which is exactly what is required. For the algorithm to operate $k$ must equal $lg(\beta) - 1$ and when it does not the inputs must be normalized by shifting them to the left by $lg(\beta) - 1 - k$ bits. Throughout the variables $n$ and $t$ will represent the highest digit of $x$ and $y$ respectively. These are first used to produce the -leading digit of the quotient. The loop beginning on line @113,for@ will produce the remainder of the quotient digits. +leading digit of the quotient. The loop beginning on line @184,for@ will produce the remainder of the quotient digits. -The conditional ``continue'' on line @114,if@ is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the +The conditional ``continue'' on line @186,continue@ is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the algorithm eliminates multiple non-zero digits in a single iteration. This ensures that $x_i$ is always non-zero since by definition the digits above the $i$'th position $x$ must be zero in order for the quotient to be precise\footnote{Precise as far as integer division is concerned.}. -Lines @142,t1@, @143,t1@ and @150,t2@ through @152,t2@ manually construct the high accuracy estimations by setting the digits of the two mp\_int +Lines @214,t1@, @216,t1@ and @222,t2@ through @225,t2@ manually construct the high accuracy estimations by setting the digits of the two mp\_int variables directly. \section{Single Digit Helpers} @@ -5743,33 +5744,30 @@ and will produce the greatest common divisor. \textbf{Input}. mp\_int $a$ and $b$ \\ \textbf{Output}. The greatest common divisor $c = (a, b)$. \\ \hline \\ -1. If $a = 0$ and $b \ne 0$ then \\ -\hspace{3mm}1.1 $c \leftarrow b$ \\ +1. If $a = 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow \vert b \vert $ \\ \hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ -2. If $a \ne 0$ and $b = 0$ then \\ -\hspace{3mm}2.1 $c \leftarrow a$ \\ +2. If $b = 0$ then \\ +\hspace{3mm}2.1 $c \leftarrow \vert a \vert $ \\ \hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ -3. If $a = b = 0$ then \\ -\hspace{3mm}3.1 $c \leftarrow 1$ \\ -\hspace{3mm}3.2 Return(\textit{MP\_OKAY}). \\ -4. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ -5. $k \leftarrow 0$ \\ -6. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}6.1 $k \leftarrow k + 1$ \\ -\hspace{3mm}6.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ -\hspace{3mm}6.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -7. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}7.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ -8. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}8.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -9. While $v.used > 0$ \\ -\hspace{3mm}9.1 If $\vert u \vert > \vert v \vert$ then \\ -\hspace{6mm}9.1.1 Swap $u$ and $v$. \\ -\hspace{3mm}9.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ -\hspace{3mm}9.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{6mm}9.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -10. $c \leftarrow u \cdot 2^k$ \\ -11. Return(\textit{MP\_OKAY}). \\ +3. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ +4. $k \leftarrow 0$ \\ +5. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}5.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}5.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}5.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +6. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +7. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +8. While $v.used > 0$ \\ +\hspace{3mm}8.1 If $\vert u \vert > \vert v \vert$ then \\ +\hspace{6mm}8.1.1 Swap $u$ and $v$. \\ +\hspace{3mm}8.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ +\hspace{3mm}8.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{6mm}8.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +9. $c \leftarrow u \cdot 2^k$ \\ +10. Return(\textit{MP\_OKAY}). \\ \hline \end{tabular} \end{center} @@ -5781,17 +5779,17 @@ This algorithm will produce the greatest common divisor of two mp\_ints $a$ and Knuth \cite[pp. 338]{TAOCPV2} but has been modified to be simpler to explain. In theory it achieves the same asymptotic working time as Algorithm B and in practice this appears to be true. -The first three steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the +The first two steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the largest input or zero if they are both zero. If the inputs are not trivial than $u$ and $v$ are assigned the absolute values of $a$ and $b$ respectively and the algorithm will proceed to reduce the pair. -Step six will divide out any common factors of two and keep track of the count in the variable $k$. After this step two is no longer a +Step five will divide out any common factors of two and keep track of the count in the variable $k$. After this step, two is no longer a factor of the remaining greatest common divisor between $u$ and $v$ and can be safely evenly divided out of either whenever they are even. Step -seven and eight ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while loops will iterate since +six and seven ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while--loops will iterate since they cannot both be even. -By step nine both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to -or greater than $u$. This ensures that the subtraction on step 9.2 will always produce a positive and even result. Step 9.3 removes any +By step eight both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to +or greater than $u$. This ensures that the subtraction on step 8.2 will always produce a positive and even result. Step 8.3 removes any factors of two from the difference $u$ to ensure that in the next iteration of the loop both are once again odd. After $v = 0$ occurs the variable $u$ has the greatest common divisor of the pair $\left < u, v \right >$ just after step six. The result @@ -5802,17 +5800,17 @@ EXAM,bn_mp_gcd.c This function makes use of the macros mp\_iszero and mp\_iseven. The former evaluates to $1$ if the input mp\_int is equivalent to the integer zero otherwise it evaluates to $0$. The latter evaluates to $1$ if the input mp\_int represents a non-zero even integer otherwise it evaluates to $0$. Note that just because mp\_iseven may evaluate to $0$ does not mean the input is odd, it could also be zero. The three -trivial cases of inputs are handled on lines @25,zero@ through @34,}@. After those lines the inputs are assumed to be non-zero. +trivial cases of inputs are handled on lines @23,zero@ through @29,}@. After those lines the inputs are assumed to be non-zero. -Lines @36,if@ and @40,if@ make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two -must be divided out of the two inputs. The while loop on line @49,while@ iterates so long as both are even. The local integer $k$ is used to -keep track of how many factors of $2$ are pulled out of both values. It is assumed that the number of factors will not exceed the maximum -value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than entries than are accessible by an ``int'' so this is not -a limitation.}. +Lines @32,if@ and @36,if@ make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two +must be divided out of the two inputs. The block starting at line @43,common@ removes common factors of two by first counting the number of trailing +zero bits in both. The local integer $k$ is used to keep track of how many factors of $2$ are pulled out of both values. It is assumed that +the number of factors will not exceed the maximum value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than +entries than are accessible by an ``int'' so this is not a limitation.}. -At this point there are no more common factors of two in the two values. The while loops on lines @60,while@ and @65,while@ remove any independent -factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop -on line @71, while@ performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in +At this point there are no more common factors of two in the two values. The divisions by a power of two on lines @60,div_2d@ and @67,div_2d@ remove +any independent factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop +on line @72, while@ performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in place of the full signed routines since both values are guaranteed to be positive and the result of the subtraction is guaranteed to be non-negative. \section{Least Common Multiple} diff --git a/libtommath/tommath.tex b/libtommath/tommath.tex index a852a8d..c79a537 100644 --- a/libtommath/tommath.tex +++ b/libtommath/tommath.tex @@ -66,7 +66,7 @@ QUALCOMM Australia \\ } } \maketitle -This text has been placed in the public domain. This text corresponds to the v0.37 release of the +This text has been placed in the public domain. This text corresponds to the v0.39 release of the LibTomMath project. \begin{alltt} @@ -77,7 +77,7 @@ K2L 1C3 Canada Phone: 1-613-836-3160 -Email: tomstdenis@iahu.ca +Email: tomstdenis@gmail.com \end{alltt} This text is formatted to the international B5 paper size of 176mm wide by 250mm tall using the \LaTeX{} @@ -268,7 +268,7 @@ and fast modular inversion, which we consider practical oversights. These optim any form of useful performance in non-trivial applications. To solve this problem the focus of this text is on the practical aspects of implementing a multiple precision integer -package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.org}} package is used +package. As a case study the ``LibTomMath''\footnote{Available at \url{http://math.libtomcrypt.com}} package is used to demonstrate algorithms with real implementations\footnote{In the ISO C programming language.} that have been field tested and work very well. The LibTomMath library is freely available on the Internet for all uses and this text discusses a very large portion of the inner workings of the library. @@ -788,33 +788,6 @@ decrementally. \hspace{-5.1mm}{\bf File}: bn\_mp\_init.c \vspace{-3mm} \begin{alltt} -016 -017 /* init a new mp_int */ -018 int mp_init (mp_int * a) -019 \{ -020 int i; -021 -022 /* allocate memory required and clear it */ -023 a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * MP_PREC); -024 if (a->dp == NULL) \{ -025 return MP_MEM; -026 \} -027 -028 /* set the digits to zero */ -029 for (i = 0; i < MP_PREC; i++) \{ -030 a->dp[i] = 0; -031 \} -032 -033 /* set the used to zero, allocated digits to the default precision -034 * and sign to positive */ -035 a->used = 0; -036 a->alloc = MP_PREC; -037 a->sign = MP_ZPOS; -038 -039 return MP_OKAY; -040 \} -041 #endif -042 \end{alltt} \end{small} @@ -822,7 +795,7 @@ One immediate observation of this initializtion function is that it does not ret is assumed that the caller has already allocated memory for the mp\_int structure, typically on the application stack. The call to mp\_init() is used only to initialize the members of the structure to a known default state. -Here we see (line 23) the memory allocation is performed first. This allows us to exit cleanly and quickly +Here we see (line 24) the memory allocation is performed first. This allows us to exit cleanly and quickly if there is an error. If the allocation fails the routine will return \textbf{MP\_MEM} to the caller to indicate there was a memory error. The function XMALLOC is what actually allocates the memory. Technically XMALLOC is not a function but a macro defined in ``tommath.h``. By default, XMALLOC will evaluate to malloc() which is the C library's built--in @@ -830,11 +803,11 @@ memory allocation routine. In order to assure the mp\_int is in a known state the digits must be set to zero. On most platforms this could have been accomplished by using calloc() instead of malloc(). However, to correctly initialize a integer type to a given value in a -portable fashion you have to actually assign the value. The for loop (line 29) performs this required +portable fashion you have to actually assign the value. The for loop (line 30) performs this required operation. After the memory has been successfully initialized the remainder of the members are initialized -(lines 33 through 34) to their respective default states. At this point the algorithm has succeeded and +(lines 34 through 35) to their respective default states. At this point the algorithm has succeeded and a success code is returned to the calling function. If this function returns \textbf{MP\_OKAY} it is safe to assume the mp\_int structure has been properly initialized and is safe to use with other functions within the library. @@ -879,46 +852,21 @@ with the exception of algorithms mp\_init, mp\_init\_copy, mp\_init\_size and mp \hspace{-5.1mm}{\bf File}: bn\_mp\_clear.c \vspace{-3mm} \begin{alltt} -016 -017 /* clear one (frees) */ -018 void -019 mp_clear (mp_int * a) -020 \{ -021 int i; -022 -023 /* only do anything if a hasn't been freed previously */ -024 if (a->dp != NULL) \{ -025 /* first zero the digits */ -026 for (i = 0; i < a->used; i++) \{ -027 a->dp[i] = 0; -028 \} -029 -030 /* free ram */ -031 XFREE(a->dp); -032 -033 /* reset members to make debugging easier */ -034 a->dp = NULL; -035 a->alloc = a->used = 0; -036 a->sign = MP_ZPOS; -037 \} -038 \} -039 #endif -040 \end{alltt} \end{small} -The algorithm only operates on the mp\_int if it hasn't been previously cleared. The if statement (line 24) +The algorithm only operates on the mp\_int if it hasn't been previously cleared. The if statement (line 25) checks to see if the \textbf{dp} member is not \textbf{NULL}. If the mp\_int is a valid mp\_int then \textbf{dp} cannot be \textbf{NULL} in which case the if statement will evaluate to true. -The digits of the mp\_int are cleared by the for loop (line 26) which assigns a zero to every digit. Similar to mp\_init() +The digits of the mp\_int are cleared by the for loop (line 27) which assigns a zero to every digit. Similar to mp\_init() the digits are assigned zero instead of using block memory operations (such as memset()) since this is more portable. The digits are deallocated off the heap via the XFREE macro. Similar to XMALLOC the XFREE macro actually evaluates to a standard C library function. In this case the free() function. Since free() only deallocates the memory the pointer -still has to be reset to \textbf{NULL} manually (line 34). +still has to be reset to \textbf{NULL} manually (line 35). -Now that the digits have been cleared and deallocated the other members are set to their final values (lines 35 and 36). +Now that the digits have been cleared and deallocated the other members are set to their final values (lines 36 and 37). \section{Maintenance Algorithms} @@ -973,44 +921,6 @@ assumed to contain undefined values they are initially set to zero. \hspace{-5.1mm}{\bf File}: bn\_mp\_grow.c \vspace{-3mm} \begin{alltt} -016 -017 /* grow as required */ -018 int mp_grow (mp_int * a, int size) -019 \{ -020 int i; -021 mp_digit *tmp; -022 -023 /* if the alloc size is smaller alloc more ram */ -024 if (a->alloc < size) \{ -025 /* ensure there are always at least MP_PREC digits extra on top */ -026 size += (MP_PREC * 2) - (size % MP_PREC); -027 -028 /* reallocate the array a->dp -029 * -030 * We store the return in a temporary variable -031 * in case the operation failed we don't want -032 * to overwrite the dp member of a. -033 */ -034 tmp = OPT_CAST(mp_digit) XREALLOC (a->dp, sizeof (mp_digit) * size); -035 if (tmp == NULL) \{ -036 /* reallocation failed but "a" is still valid [can be freed] */ -037 return MP_MEM; -038 \} -039 -040 /* reallocation succeeded so set a->dp */ -041 a->dp = tmp; -042 -043 /* zero excess digits */ -044 i = a->alloc; -045 a->alloc = size; -046 for (; i < a->alloc; i++) \{ -047 a->dp[i] = 0; -048 \} -049 \} -050 return MP_OKAY; -051 \} -052 #endif -053 \end{alltt} \end{small} @@ -1019,7 +929,7 @@ if the \textbf{alloc} member of the mp\_int is smaller than the requested digit the function skips the re-allocation part thus saving time. When a re-allocation is performed it is turned into an optimal request to save time in the future. The requested digit count is -padded upwards to 2nd multiple of \textbf{MP\_PREC} larger than \textbf{alloc} (line 26). The XREALLOC function is used +padded upwards to 2nd multiple of \textbf{MP\_PREC} larger than \textbf{alloc} (line 25). The XREALLOC function is used to re-allocate the memory. As per the other functions XREALLOC is actually a macro which evaluates to realloc by default. The realloc function leaves the base of the allocation intact which means the first \textbf{alloc} digits of the mp\_int are the same as before the re-allocation. All that is left is to clear the newly allocated digits and return. @@ -1071,46 +981,17 @@ correct no further memory re-allocations are required to work with the mp\_int. \hspace{-5.1mm}{\bf File}: bn\_mp\_init\_size.c \vspace{-3mm} \begin{alltt} -016 -017 /* init an mp_init for a given size */ -018 int mp_init_size (mp_int * a, int size) -019 \{ -020 int x; -021 -022 /* pad size so there are always extra digits */ -023 size += (MP_PREC * 2) - (size % MP_PREC); -024 -025 /* alloc mem */ -026 a->dp = OPT_CAST(mp_digit) XMALLOC (sizeof (mp_digit) * size); -027 if (a->dp == NULL) \{ -028 return MP_MEM; -029 \} -030 -031 /* set the members */ -032 a->used = 0; -033 a->alloc = size; -034 a->sign = MP_ZPOS; -035 -036 /* zero the digits */ -037 for (x = 0; x < size; x++) \{ -038 a->dp[x] = 0; -039 \} -040 -041 return MP_OKAY; -042 \} -043 #endif -044 \end{alltt} \end{small} -The number of digits $b$ requested is padded (line 23) by first augmenting it to the next multiple of +The number of digits $b$ requested is padded (line 24) by first augmenting it to the next multiple of \textbf{MP\_PREC} and then adding \textbf{MP\_PREC} to the result. If the memory can be successfully allocated the mp\_int is placed in a default state representing the integer zero. Otherwise, the error code \textbf{MP\_MEM} will be -returned (line 28). +returned (line 29). The digits are allocated and set to zero at the same time with the calloc() function (line @25,XCALLOC@). The \textbf{used} count is set to zero, the \textbf{alloc} count set to the padded digit count and the \textbf{sign} flag set -to \textbf{MP\_ZPOS} to achieve a default valid mp\_int state (lines 32, 33 and 34). If the function +to \textbf{MP\_ZPOS} to achieve a default valid mp\_int state (lines 33, 34 and 35). If the function returns succesfully then it is correct to assume that the mp\_int structure is in a valid state for the remainder of the functions to work with. @@ -1148,46 +1029,6 @@ initialization which allows for quick recovery from runtime errors. \hspace{-5.1mm}{\bf File}: bn\_mp\_init\_multi.c \vspace{-3mm} \begin{alltt} -016 #include -017 -018 int mp_init_multi(mp_int *mp, ...) -019 \{ -020 mp_err res = MP_OKAY; /* Assume ok until proven otherwise */ -021 int n = 0; /* Number of ok inits */ -022 mp_int* cur_arg = mp; -023 va_list args; -024 -025 va_start(args, mp); /* init args to next argument from caller */ -026 while (cur_arg != NULL) \{ -027 if (mp_init(cur_arg) != MP_OKAY) \{ -028 /* Oops - error! Back-track and mp_clear what we already -029 succeeded in init-ing, then return error. -030 */ -031 va_list clean_args; -032 -033 /* end the current list */ -034 va_end(args); -035 -036 /* now start cleaning up */ -037 cur_arg = mp; -038 va_start(clean_args, mp); -039 while (n--) \{ -040 mp_clear(cur_arg); -041 cur_arg = va_arg(clean_args, mp_int*); -042 \} -043 va_end(clean_args); -044 res = MP_MEM; -045 break; -046 \} -047 n++; -048 cur_arg = va_arg(args, mp_int*); -049 \} -050 va_end(args); -051 return res; /* Assumed ok, if error flagged above. */ -052 \} -053 -054 #endif -055 \end{alltt} \end{small} @@ -1197,8 +1038,8 @@ structures in an actual C array they are simply passed as arguments to the funct appended on the right. The function uses the ``stdarg.h'' \textit{va} functions to step portably through the arguments to the function. A count -$n$ of succesfully initialized mp\_int structures is maintained (line 47) such that if a failure does occur, -the algorithm can backtrack and free the previously initialized structures (lines 27 to 46). +$n$ of succesfully initialized mp\_int structures is maintained (line 48) such that if a failure does occur, +the algorithm can backtrack and free the previously initialized structures (lines 28 to 47). \subsection{Clamping Excess Digits} @@ -1249,38 +1090,13 @@ when all of the digits are zero to ensure that the mp\_int is valid at all times \hspace{-5.1mm}{\bf File}: bn\_mp\_clamp.c \vspace{-3mm} \begin{alltt} -016 -017 /* trim unused digits -018 * -019 * This is used to ensure that leading zero digits are -020 * trimed and the leading "used" digit will be non-zero -021 * Typically very fast. Also fixes the sign if there -022 * are no more leading digits -023 */ -024 void -025 mp_clamp (mp_int * a) -026 \{ -027 /* decrease used while the most significant digit is -028 * zero. -029 */ -030 while (a->used > 0 && a->dp[a->used - 1] == 0) \{ -031 --(a->used); -032 \} -033 -034 /* reset the sign flag if used == 0 */ -035 if (a->used == 0) \{ -036 a->sign = MP_ZPOS; -037 \} -038 \} -039 #endif -040 \end{alltt} \end{small} -Note on line 27 how to test for the \textbf{used} count is made on the left of the \&\& operator. In the C programming +Note on line 28 how to test for the \textbf{used} count is made on the left of the \&\& operator. In the C programming language the terms to \&\& are evaluated left to right with a boolean short-circuit if any condition fails. This is important since if the \textbf{used} is zero the test on the right would fetch below the array. That is obviously -undesirable. The parenthesis on line 30 is used to make sure the \textbf{used} count is decremented and not +undesirable. The parenthesis on line 31 is used to make sure the \textbf{used} count is decremented and not the pointer ``a''. \section*{Exercises} @@ -1363,70 +1179,21 @@ implement the pseudo-code. \hspace{-5.1mm}{\bf File}: bn\_mp\_copy.c \vspace{-3mm} \begin{alltt} -016 -017 /* copy, b = a */ -018 int -019 mp_copy (mp_int * a, mp_int * b) -020 \{ -021 int res, n; -022 -023 /* if dst == src do nothing */ -024 if (a == b) \{ -025 return MP_OKAY; -026 \} -027 -028 /* grow dest */ -029 if (b->alloc < a->used) \{ -030 if ((res = mp_grow (b, a->used)) != MP_OKAY) \{ -031 return res; -032 \} -033 \} -034 -035 /* zero b and copy the parameters over */ -036 \{ -037 register mp_digit *tmpa, *tmpb; -038 -039 /* pointer aliases */ -040 -041 /* source */ -042 tmpa = a->dp; -043 -044 /* destination */ -045 tmpb = b->dp; -046 -047 /* copy all the digits */ -048 for (n = 0; n < a->used; n++) \{ -049 *tmpb++ = *tmpa++; -050 \} -051 -052 /* clear high digits */ -053 for (; n < b->used; n++) \{ -054 *tmpb++ = 0; -055 \} -056 \} -057 -058 /* copy used count and sign */ -059 b->used = a->used; -060 b->sign = a->sign; -061 return MP_OKAY; -062 \} -063 #endif -064 \end{alltt} \end{small} Occasionally a dependent algorithm may copy an mp\_int effectively into itself such as when the input and output mp\_int structures passed to a function are one and the same. For this case it is optimal to return immediately without -copying digits (line 24). +copying digits (line 25). The mp\_int $b$ must have enough digits to accomodate the used digits of the mp\_int $a$. If $b.alloc$ is less than -$a.used$ the algorithm mp\_grow is used to augment the precision of $b$ (lines 29 to 33). In order to +$a.used$ the algorithm mp\_grow is used to augment the precision of $b$ (lines 30 to 33). In order to simplify the inner loop that copies the digits from $a$ to $b$, two aliases $tmpa$ and $tmpb$ point directly at the digits -of the mp\_ints $a$ and $b$ respectively. These aliases (lines 42 and 45) allow the compiler to access the digits without first dereferencing the +of the mp\_ints $a$ and $b$ respectively. These aliases (lines 43 and 46) allow the compiler to access the digits without first dereferencing the mp\_int pointers and then subsequently the pointer to the digits. -After the aliases are established the digits from $a$ are copied into $b$ (lines 48 to 50) and then the excess -digits of $b$ are set to zero (lines 53 to 55). Both ``for'' loops make use of the pointer aliases and in +After the aliases are established the digits from $a$ are copied into $b$ (lines 49 to 51) and then the excess +digits of $b$ are set to zero (lines 54 to 56). Both ``for'' loops make use of the pointer aliases and in fact the alias for $b$ is carried through into the second ``for'' loop to clear the excess digits. This optimization allows the alias to stay in a machine register fairly easy between the two loops. @@ -1514,19 +1281,6 @@ such this algorithm will perform two operations in one step. \hspace{-5.1mm}{\bf File}: bn\_mp\_init\_copy.c \vspace{-3mm} \begin{alltt} -016 -017 /* creates "a" then copies b into it */ -018 int mp_init_copy (mp_int * a, mp_int * b) -019 \{ -020 int res; -021 -022 if ((res = mp_init (a)) != MP_OKAY) \{ -023 return res; -024 \} -025 return mp_copy (b, a); -026 \} -027 #endif -028 \end{alltt} \end{small} @@ -1562,23 +1316,6 @@ This algorithm simply resets a mp\_int to the default state. \hspace{-5.1mm}{\bf File}: bn\_mp\_zero.c \vspace{-3mm} \begin{alltt} -016 -017 /* set to zero */ -018 void mp_zero (mp_int * a) -019 \{ -020 int n; -021 mp_digit *tmp; -022 -023 a->sign = MP_ZPOS; -024 a->used = 0; -025 -026 tmp = a->dp; -027 for (n = 0; n < a->alloc; n++) \{ -028 *tmp++ = 0; -029 \} -030 \} -031 #endif -032 \end{alltt} \end{small} @@ -1617,34 +1354,10 @@ logic to handle it. \hspace{-5.1mm}{\bf File}: bn\_mp\_abs.c \vspace{-3mm} \begin{alltt} -016 -017 /* b = |a| -018 * -019 * Simple function copies the input and fixes the sign to positive -020 */ -021 int -022 mp_abs (mp_int * a, mp_int * b) -023 \{ -024 int res; -025 -026 /* copy a to b */ -027 if (a != b) \{ -028 if ((res = mp_copy (a, b)) != MP_OKAY) \{ -029 return res; -030 \} -031 \} -032 -033 /* force the sign of b to positive */ -034 b->sign = MP_ZPOS; -035 -036 return MP_OKAY; -037 \} -038 #endif -039 \end{alltt} \end{small} -This fairly trivial algorithm first eliminates non--required duplications (line 27) and then sets the +This fairly trivial algorithm first eliminates non--required duplications (line 28) and then sets the \textbf{sign} flag to \textbf{MP\_ZPOS}. \subsection{Integer Negation} @@ -1682,31 +1395,10 @@ zero as negative. \hspace{-5.1mm}{\bf File}: bn\_mp\_neg.c \vspace{-3mm} \begin{alltt} -016 -017 /* b = -a */ -018 int mp_neg (mp_int * a, mp_int * b) -019 \{ -020 int res; -021 if (a != b) \{ -022 if ((res = mp_copy (a, b)) != MP_OKAY) \{ -023 return res; -024 \} -025 \} -026 -027 if (mp_iszero(b) != MP_YES) \{ -028 b->sign = (a->sign == MP_ZPOS) ? MP_NEG : MP_ZPOS; -029 \} else \{ -030 b->sign = MP_ZPOS; -031 \} -032 -033 return MP_OKAY; -034 \} -035 #endif -036 \end{alltt} \end{small} -Like mp\_abs() this function avoids non--required duplications (line 21) and then sets the sign. We +Like mp\_abs() this function avoids non--required duplications (line 22) and then sets the sign. We have to make sure that only non--zero values get a \textbf{sign} of \textbf{MP\_NEG}. If the mp\_int is zero than the \textbf{sign} is hard--coded to \textbf{MP\_ZPOS}. @@ -1741,22 +1433,12 @@ single digit is set (\textit{modulo $\beta$}) and the \textbf{used} count is adj \hspace{-5.1mm}{\bf File}: bn\_mp\_set.c \vspace{-3mm} \begin{alltt} -016 -017 /* set to a digit */ -018 void mp_set (mp_int * a, mp_digit b) -019 \{ -020 mp_zero (a); -021 a->dp[0] = b & MP_MASK; -022 a->used = (a->dp[0] != 0) ? 1 : 0; -023 \} -024 #endif -025 \end{alltt} \end{small} -First we zero (line 20) the mp\_int to make sure that the other members are initialized for a +First we zero (line 21) the mp\_int to make sure that the other members are initialized for a small positive constant. mp\_zero() ensures that the \textbf{sign} is positive and the \textbf{used} count -is zero. Next we set the digit and reduce it modulo $\beta$ (line 21). After this step we have to +is zero. Next we set the digit and reduce it modulo $\beta$ (line 22). After this step we have to check if the resulting digit is zero or not. If it is not then we set the \textbf{used} count to one, otherwise to zero. @@ -1803,42 +1485,13 @@ Excess zero digits are trimmed in steps 2.1 and 3 by using higher level algorith \hspace{-5.1mm}{\bf File}: bn\_mp\_set\_int.c \vspace{-3mm} \begin{alltt} -016 -017 /* set a 32-bit const */ -018 int mp_set_int (mp_int * a, unsigned long b) -019 \{ -020 int x, res; -021 -022 mp_zero (a); -023 -024 /* set four bits at a time */ -025 for (x = 0; x < 8; x++) \{ -026 /* shift the number up four bits */ -027 if ((res = mp_mul_2d (a, 4, a)) != MP_OKAY) \{ -028 return res; -029 \} -030 -031 /* OR in the top four bits of the source */ -032 a->dp[0] |= (b >> 28) & 15; -033 -034 /* shift the source up to the next four bits */ -035 b <<= 4; -036 -037 /* ensure that digits are not clamped off */ -038 a->used += 1; -039 \} -040 mp_clamp (a); -041 return MP_OKAY; -042 \} -043 #endif -044 \end{alltt} \end{small} This function sets four bits of the number at a time to handle all practical \textbf{DIGIT\_BIT} sizes. The weird -addition on line 38 ensures that the newly added in bits are added to the number of digits. While it may not -seem obvious as to why the digit counter does not grow exceedingly large it is because of the shift on line 27 -as well as the call to mp\_clamp() on line 40. Both functions will clamp excess leading digits which keeps +addition on line 39 ensures that the newly added in bits are added to the number of digits. While it may not +seem obvious as to why the digit counter does not grow exceedingly large it is because of the shift on line 28 +as well as the call to mp\_clamp() on line 41. Both functions will clamp excess leading digits which keeps the number of used digits low. \section{Comparisons} @@ -1899,46 +1552,10 @@ the zero'th digit. If after all of the digits have been compared, no difference \hspace{-5.1mm}{\bf File}: bn\_mp\_cmp\_mag.c \vspace{-3mm} \begin{alltt} -016 -017 /* compare maginitude of two ints (unsigned) */ -018 int mp_cmp_mag (mp_int * a, mp_int * b) -019 \{ -020 int n; -021 mp_digit *tmpa, *tmpb; -022 -023 /* compare based on # of non-zero digits */ -024 if (a->used > b->used) \{ -025 return MP_GT; -026 \} -027 -028 if (a->used < b->used) \{ -029 return MP_LT; -030 \} -031 -032 /* alias for a */ -033 tmpa = a->dp + (a->used - 1); -034 -035 /* alias for b */ -036 tmpb = b->dp + (a->used - 1); -037 -038 /* compare based on digits */ -039 for (n = 0; n < a->used; ++n, --tmpa, --tmpb) \{ -040 if (*tmpa > *tmpb) \{ -041 return MP_GT; -042 \} -043 -044 if (*tmpa < *tmpb) \{ -045 return MP_LT; -046 \} -047 \} -048 return MP_EQ; -049 \} -050 #endif -051 \end{alltt} \end{small} -The two if statements (lines 24 and 28) compare the number of digits in the two inputs. These two are +The two if statements (lines 25 and 29) compare the number of digits in the two inputs. These two are performed before all of the digits are compared since it is a very cheap test to perform and can potentially save considerable time. The implementation given is also not valid without those two statements. $b.alloc$ may be smaller than $a.used$, meaning that undefined values will be read from $b$ past the end of the array of digits. @@ -1978,36 +1595,12 @@ $\vert a \vert < \vert b \vert$. Step number four will compare the two when the \hspace{-5.1mm}{\bf File}: bn\_mp\_cmp.c \vspace{-3mm} \begin{alltt} -016 -017 /* compare two ints (signed)*/ -018 int -019 mp_cmp (mp_int * a, mp_int * b) -020 \{ -021 /* compare based on sign */ -022 if (a->sign != b->sign) \{ -023 if (a->sign == MP_NEG) \{ -024 return MP_LT; -025 \} else \{ -026 return MP_GT; -027 \} -028 \} -029 -030 /* compare digits */ -031 if (a->sign == MP_NEG) \{ -032 /* if negative compare opposite direction */ -033 return mp_cmp_mag(b, a); -034 \} else \{ -035 return mp_cmp_mag(a, b); -036 \} -037 \} -038 #endif -039 \end{alltt} \end{small} -The two if statements (lines 22 and 23) perform the initial sign comparison. If the signs are not the equal then which ever -has the positive sign is larger. The inputs are compared (line 31) based on magnitudes. If the signs were both -negative then the unsigned comparison is performed in the opposite direction (line 33). Otherwise, the signs are assumed to +The two if statements (lines 23 and 24) perform the initial sign comparison. If the signs are not the equal then which ever +has the positive sign is larger. The inputs are compared (line 32) based on magnitudes. If the signs were both +negative then the unsigned comparison is performed in the opposite direction (line 34). Otherwise, the signs are assumed to be both positive and a forward direction unsigned comparison is performed. \section*{Exercises} @@ -2131,114 +1724,24 @@ The final carry is stored in $c_{max}$ and digits above $max$ upto $oldused$ are \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_add.c \vspace{-3mm} \begin{alltt} -016 -017 /* low level addition, based on HAC pp.594, Algorithm 14.7 */ -018 int -019 s_mp_add (mp_int * a, mp_int * b, mp_int * c) -020 \{ -021 mp_int *x; -022 int olduse, res, min, max; -023 -024 /* find sizes, we let |a| <= |b| which means we have to sort -025 * them. "x" will point to the input with the most digits -026 */ -027 if (a->used > b->used) \{ -028 min = b->used; -029 max = a->used; -030 x = a; -031 \} else \{ -032 min = a->used; -033 max = b->used; -034 x = b; -035 \} -036 -037 /* init result */ -038 if (c->alloc < max + 1) \{ -039 if ((res = mp_grow (c, max + 1)) != MP_OKAY) \{ -040 return res; -041 \} -042 \} -043 -044 /* get old used digit count and set new one */ -045 olduse = c->used; -046 c->used = max + 1; -047 -048 \{ -049 register mp_digit u, *tmpa, *tmpb, *tmpc; -050 register int i; -051 -052 /* alias for digit pointers */ -053 -054 /* first input */ -055 tmpa = a->dp; -056 -057 /* second input */ -058 tmpb = b->dp; -059 -060 /* destination */ -061 tmpc = c->dp; -062 -063 /* zero the carry */ -064 u = 0; -065 for (i = 0; i < min; i++) \{ -066 /* Compute the sum at one digit, T[i] = A[i] + B[i] + U */ -067 *tmpc = *tmpa++ + *tmpb++ + u; -068 -069 /* U = carry bit of T[i] */ -070 u = *tmpc >> ((mp_digit)DIGIT_BIT); -071 -072 /* take away carry bit from T[i] */ -073 *tmpc++ &= MP_MASK; -074 \} -075 -076 /* now copy higher words if any, that is in A+B -077 * if A or B has more digits add those in -078 */ -079 if (min != max) \{ -080 for (; i < max; i++) \{ -081 /* T[i] = X[i] + U */ -082 *tmpc = x->dp[i] + u; -083 -084 /* U = carry bit of T[i] */ -085 u = *tmpc >> ((mp_digit)DIGIT_BIT); -086 -087 /* take away carry bit from T[i] */ -088 *tmpc++ &= MP_MASK; -089 \} -090 \} -091 -092 /* add carry */ -093 *tmpc++ = u; -094 -095 /* clear digits above oldused */ -096 for (i = c->used; i < olduse; i++) \{ -097 *tmpc++ = 0; -098 \} -099 \} -100 -101 mp_clamp (c); -102 return MP_OKAY; -103 \} -104 #endif -105 \end{alltt} \end{small} -We first sort (lines 27 to 35) the inputs based on magnitude and determine the $min$ and $max$ variables. +We first sort (lines 28 to 36) the inputs based on magnitude and determine the $min$ and $max$ variables. Note that $x$ is a pointer to an mp\_int assigned to the largest input, in effect it is a local alias. Next we -grow the destination (37 to 42) ensure that it can accomodate the result of the addition. +grow the destination (38 to 42) ensure that it can accomodate the result of the addition. Similar to the implementation of mp\_copy this function uses the braced code and local aliases coding style. The three aliases that are on -lines 55, 58 and 61 represent the two inputs and destination variables respectively. These aliases are used to ensure the +lines 56, 59 and 62 represent the two inputs and destination variables respectively. These aliases are used to ensure the compiler does not have to dereference $a$, $b$ or $c$ (respectively) to access the digits of the respective mp\_int. -The initial carry $u$ will be cleared (line 64), note that $u$ is of type mp\_digit which ensures type -compatibility within the implementation. The initial addition (line 65 to 74) adds digits from +The initial carry $u$ will be cleared (line 65), note that $u$ is of type mp\_digit which ensures type +compatibility within the implementation. The initial addition (line 66 to 75) adds digits from both inputs until the smallest input runs out of digits. Similarly the conditional addition loop -(line 80 to 90) adds the remaining digits from the larger of the two inputs. The addition is finished -with the final carry being stored in $tmpc$ (line 93). Note the ``++'' operator within the same expression. -After line 93, $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful -for the next loop (line 96 to 99) which set any old upper digits to zero. +(line 81 to 90) adds the remaining digits from the larger of the two inputs. The addition is finished +with the final carry being stored in $tmpc$ (line 94). Note the ``++'' operator within the same expression. +After line 94, $tmpc$ will point to the $c.used$'th digit of the mp\_int $c$. This is useful +for the next loop (line 97 to 99) which set any old upper digits to zero. \subsection{Low Level Subtraction} The low level unsigned subtraction algorithm is very similar to the low level unsigned addition algorithm. The principle difference is that the @@ -2322,96 +1825,25 @@ If $b$ has a smaller magnitude than $a$ then step 9 will force the carry and cop \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_sub.c \vspace{-3mm} \begin{alltt} -016 -017 /* low level subtraction (assumes |a| > |b|), HAC pp.595 Algorithm 14.9 */ -018 int -019 s_mp_sub (mp_int * a, mp_int * b, mp_int * c) -020 \{ -021 int olduse, res, min, max; -022 -023 /* find sizes */ -024 min = b->used; -025 max = a->used; -026 -027 /* init result */ -028 if (c->alloc < max) \{ -029 if ((res = mp_grow (c, max)) != MP_OKAY) \{ -030 return res; -031 \} -032 \} -033 olduse = c->used; -034 c->used = max; -035 -036 \{ -037 register mp_digit u, *tmpa, *tmpb, *tmpc; -038 register int i; -039 -040 /* alias for digit pointers */ -041 tmpa = a->dp; -042 tmpb = b->dp; -043 tmpc = c->dp; -044 -045 /* set carry to zero */ -046 u = 0; -047 for (i = 0; i < min; i++) \{ -048 /* T[i] = A[i] - B[i] - U */ -049 *tmpc = *tmpa++ - *tmpb++ - u; -050 -051 /* U = carry bit of T[i] -052 * Note this saves performing an AND operation since -053 * if a carry does occur it will propagate all the way to the -054 * MSB. As a result a single shift is enough to get the carry -055 */ -056 u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); -057 -058 /* Clear carry from T[i] */ -059 *tmpc++ &= MP_MASK; -060 \} -061 -062 /* now copy higher words if any, e.g. if A has more digits than B */ -063 for (; i < max; i++) \{ -064 /* T[i] = A[i] - U */ -065 *tmpc = *tmpa++ - u; -066 -067 /* U = carry bit of T[i] */ -068 u = *tmpc >> ((mp_digit)(CHAR_BIT * sizeof (mp_digit) - 1)); -069 -070 /* Clear carry from T[i] */ -071 *tmpc++ &= MP_MASK; -072 \} -073 -074 /* clear digits above used (since we may not have grown result above) */ - -075 for (i = c->used; i < olduse; i++) \{ -076 *tmpc++ = 0; -077 \} -078 \} -079 -080 mp_clamp (c); -081 return MP_OKAY; -082 \} -083 -084 #endif -085 \end{alltt} \end{small} Like low level addition we ``sort'' the inputs. Except in this case the sorting is hardcoded -(lines 24 and 25). In reality the $min$ and $max$ variables are only aliases and are only +(lines 25 and 26). In reality the $min$ and $max$ variables are only aliases and are only used to make the source code easier to read. Again the pointer alias optimization is used within this algorithm. The aliases $tmpa$, $tmpb$ and $tmpc$ are initialized -(lines 41, 42 and 43) for $a$, $b$ and $c$ respectively. +(lines 42, 43 and 44) for $a$, $b$ and $c$ respectively. -The first subtraction loop (lines 46 through 60) subtract digits from both inputs until the smaller of +The first subtraction loop (lines 47 through 61) subtract digits from both inputs until the smaller of the two inputs has been exhausted. As remarked earlier there is an implementation reason for using the ``awkward'' -method of extracting the carry (line 56). The traditional method for extracting the carry would be to shift +method of extracting the carry (line 57). The traditional method for extracting the carry would be to shift by $lg(\beta)$ positions and logically AND the least significant bit. The AND operation is required because all of the bits above the $\lg(\beta)$'th bit will be set to one after a carry occurs from subtraction. This carry extraction requires two relatively cheap operations to extract the carry. The other method is to simply shift the most significant bit to the least significant bit thus extracting the carry with a single cheap operation. This optimization only works on twos compliment machines which is a safe assumption to make. -If $a$ has a larger magnitude than $b$ an additional loop (lines 63 through 72) is required to propagate +If $a$ has a larger magnitude than $b$ an additional loop (lines 64 through 73) is required to propagate the carry through $a$ and copy the result to $c$. \subsection{High Level Addition} @@ -2495,40 +1927,6 @@ within algorithm s\_mp\_add will force $-0$ to become $0$. \hspace{-5.1mm}{\bf File}: bn\_mp\_add.c \vspace{-3mm} \begin{alltt} -016 -017 /* high level addition (handles signs) */ -018 int mp_add (mp_int * a, mp_int * b, mp_int * c) -019 \{ -020 int sa, sb, res; -021 -022 /* get sign of both inputs */ -023 sa = a->sign; -024 sb = b->sign; -025 -026 /* handle two cases, not four */ -027 if (sa == sb) \{ -028 /* both positive or both negative */ -029 /* add their magnitudes, copy the sign */ -030 c->sign = sa; -031 res = s_mp_add (a, b, c); -032 \} else \{ -033 /* one positive, the other negative */ -034 /* subtract the one with the greater magnitude from */ -035 /* the one of the lesser magnitude. The result gets */ -036 /* the sign of the one with the greater magnitude. */ -037 if (mp_cmp_mag (a, b) == MP_LT) \{ -038 c->sign = sb; -039 res = s_mp_sub (b, a, c); -040 \} else \{ -041 c->sign = sa; -042 res = s_mp_sub (a, b, c); -043 \} -044 \} -045 return res; -046 \} -047 -048 #endif -049 \end{alltt} \end{small} @@ -2602,51 +2000,11 @@ algorithm from producing $-a - -a = -0$ as a result. \hspace{-5.1mm}{\bf File}: bn\_mp\_sub.c \vspace{-3mm} \begin{alltt} -016 -017 /* high level subtraction (handles signs) */ -018 int -019 mp_sub (mp_int * a, mp_int * b, mp_int * c) -020 \{ -021 int sa, sb, res; -022 -023 sa = a->sign; -024 sb = b->sign; -025 -026 if (sa != sb) \{ -027 /* subtract a negative from a positive, OR */ -028 /* subtract a positive from a negative. */ -029 /* In either case, ADD their magnitudes, */ -030 /* and use the sign of the first number. */ -031 c->sign = sa; -032 res = s_mp_add (a, b, c); -033 \} else \{ -034 /* subtract a positive from a positive, OR */ -035 /* subtract a negative from a negative. */ -036 /* First, take the difference between their */ -037 /* magnitudes, then... */ -038 if (mp_cmp_mag (a, b) != MP_LT) \{ -039 /* Copy the sign from the first */ -040 c->sign = sa; -041 /* The first has a larger or equal magnitude */ -042 res = s_mp_sub (a, b, c); -043 \} else \{ -044 /* The result has the *opposite* sign from */ -045 /* the first number. */ -046 c->sign = (sa == MP_ZPOS) ? MP_NEG : MP_ZPOS; -047 /* The second has a larger magnitude */ -048 res = s_mp_sub (b, a, c); -049 \} -050 \} -051 return res; -052 \} -053 -054 #endif -055 \end{alltt} \end{small} Much like the implementation of algorithm mp\_add the variable $res$ is used to catch the return code of the unsigned addition or subtraction operations -and forward it to the end of the function. On line 38 the ``not equal to'' \textbf{MP\_LT} expression is used to emulate a +and forward it to the end of the function. On line 39 the ``not equal to'' \textbf{MP\_LT} expression is used to emulate a ``greater than or equal to'' comparison. \section{Bit and Digit Shifting} @@ -2714,74 +2072,11 @@ Step 8 clears any leading digits of $b$ in case it originally had a larger magni \hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_2.c \vspace{-3mm} \begin{alltt} -016 -017 /* b = a*2 */ -018 int mp_mul_2(mp_int * a, mp_int * b) -019 \{ -020 int x, res, oldused; -021 -022 /* grow to accomodate result */ -023 if (b->alloc < a->used + 1) \{ -024 if ((res = mp_grow (b, a->used + 1)) != MP_OKAY) \{ -025 return res; -026 \} -027 \} -028 -029 oldused = b->used; -030 b->used = a->used; -031 -032 \{ -033 register mp_digit r, rr, *tmpa, *tmpb; -034 -035 /* alias for source */ -036 tmpa = a->dp; -037 -038 /* alias for dest */ -039 tmpb = b->dp; -040 -041 /* carry */ -042 r = 0; -043 for (x = 0; x < a->used; x++) \{ -044 -045 /* get what will be the *next* carry bit from the -046 * MSB of the current digit -047 */ -048 rr = *tmpa >> ((mp_digit)(DIGIT_BIT - 1)); -049 -050 /* now shift up this digit, add in the carry [from the previous] */ -051 *tmpb++ = ((*tmpa++ << ((mp_digit)1)) | r) & MP_MASK; -052 -053 /* copy the carry that would be from the source -054 * digit into the next iteration -055 */ -056 r = rr; -057 \} -058 -059 /* new leading digit? */ -060 if (r != 0) \{ -061 /* add a MSB which is always 1 at this point */ -062 *tmpb = 1; -063 ++(b->used); -064 \} -065 -066 /* now zero any excess digits on the destination -067 * that we didn't write to -068 */ -069 tmpb = b->dp + b->used; -070 for (x = b->used; x < oldused; x++) \{ -071 *tmpb++ = 0; -072 \} -073 \} -074 b->sign = a->sign; -075 return MP_OKAY; -076 \} -077 #endif -078 \end{alltt} \end{small} This implementation is essentially an optimized implementation of s\_mp\_add for the case of doubling an input. The only noteworthy difference -is the use of the logical shift operator on line 51 to perform a single precision doubling. +is the use of the logical shift operator on line 52 to perform a single precision doubling. \subsection{Division by Two} A division by two can just as easily be accomplished with a logical shift right as multiplication by two can be with a logical shift left. @@ -2829,55 +2124,6 @@ least significant bit not the most significant bit. \hspace{-5.1mm}{\bf File}: bn\_mp\_div\_2.c \vspace{-3mm} \begin{alltt} -016 -017 /* b = a/2 */ -018 int mp_div_2(mp_int * a, mp_int * b) -019 \{ -020 int x, res, oldused; -021 -022 /* copy */ -023 if (b->alloc < a->used) \{ -024 if ((res = mp_grow (b, a->used)) != MP_OKAY) \{ -025 return res; -026 \} -027 \} -028 -029 oldused = b->used; -030 b->used = a->used; -031 \{ -032 register mp_digit r, rr, *tmpa, *tmpb; -033 -034 /* source alias */ -035 tmpa = a->dp + b->used - 1; -036 -037 /* dest alias */ -038 tmpb = b->dp + b->used - 1; -039 -040 /* carry */ -041 r = 0; -042 for (x = b->used - 1; x >= 0; x--) \{ -043 /* get the carry for the next iteration */ -044 rr = *tmpa & 1; -045 -046 /* shift the current digit, add in carry and store */ -047 *tmpb-- = (*tmpa-- >> 1) | (r << (DIGIT_BIT - 1)); -048 -049 /* forward carry to next iteration */ -050 r = rr; -051 \} -052 -053 /* zero excess digits */ -054 tmpb = b->dp + b->used; -055 for (x = b->used; x < oldused; x++) \{ -056 *tmpb++ = 0; -057 \} -058 \} -059 b->sign = a->sign; -060 mp_clamp (b); -061 return MP_OKAY; -062 \} -063 #endif -064 \end{alltt} \end{small} @@ -2951,61 +2197,13 @@ step 8 sets the lower $b$ digits to zero. \hspace{-5.1mm}{\bf File}: bn\_mp\_lshd.c \vspace{-3mm} \begin{alltt} -016 -017 /* shift left a certain amount of digits */ -018 int mp_lshd (mp_int * a, int b) -019 \{ -020 int x, res; -021 -022 /* if its less than zero return */ -023 if (b <= 0) \{ -024 return MP_OKAY; -025 \} -026 -027 /* grow to fit the new digits */ -028 if (a->alloc < a->used + b) \{ -029 if ((res = mp_grow (a, a->used + b)) != MP_OKAY) \{ -030 return res; -031 \} -032 \} -033 -034 \{ -035 register mp_digit *top, *bottom; -036 -037 /* increment the used by the shift amount then copy upwards */ -038 a->used += b; -039 -040 /* top */ -041 top = a->dp + a->used - 1; -042 -043 /* base */ -044 bottom = a->dp + a->used - 1 - b; -045 -046 /* much like mp_rshd this is implemented using a sliding window -047 * except the window goes the otherway around. Copying from -048 * the bottom to the top. see bn_mp_rshd.c for more info. -049 */ -050 for (x = a->used - 1; x >= b; x--) \{ -051 *top-- = *bottom--; -052 \} -053 -054 /* zero the lower digits */ -055 top = a->dp; -056 for (x = 0; x < b; x++) \{ -057 *top++ = 0; -058 \} -059 \} -060 return MP_OKAY; -061 \} -062 #endif -063 \end{alltt} \end{small} -The if statement (line 23) ensures that the $b$ variable is greater than zero since we do not interpret negative +The if statement (line 24) ensures that the $b$ variable is greater than zero since we do not interpret negative shift counts properly. The \textbf{used} count is incremented by $b$ before the copy loop begins. This elminates -the need for an additional variable in the for loop. The variable $top$ (line 41) is an alias -for the leading digit while $bottom$ (line 44) is an alias for the trailing edge. The aliases form a +the need for an additional variable in the for loop. The variable $top$ (line 42) is an alias +for the leading digit while $bottom$ (line 45) is an alias for the trailing edge. The aliases form a window of exactly $b$ digits over the input. \subsection{Division by $x$} @@ -3058,64 +2256,11 @@ Once the window copy is complete the upper digits must be zeroed and the \textbf \hspace{-5.1mm}{\bf File}: bn\_mp\_rshd.c \vspace{-3mm} \begin{alltt} -016 -017 /* shift right a certain amount of digits */ -018 void mp_rshd (mp_int * a, int b) -019 \{ -020 int x; -021 -022 /* if b <= 0 then ignore it */ -023 if (b <= 0) \{ -024 return; -025 \} -026 -027 /* if b > used then simply zero it and return */ -028 if (a->used <= b) \{ -029 mp_zero (a); -030 return; -031 \} -032 -033 \{ -034 register mp_digit *bottom, *top; -035 -036 /* shift the digits down */ -037 -038 /* bottom */ -039 bottom = a->dp; -040 -041 /* top [offset into digits] */ -042 top = a->dp + b; -043 -044 /* this is implemented as a sliding window where -045 * the window is b-digits long and digits from -046 * the top of the window are copied to the bottom -047 * -048 * e.g. -049 -050 b-2 | b-1 | b0 | b1 | b2 | ... | bb | ----> -051 /\symbol{92} | ----> -052 \symbol{92}-------------------/ ----> -053 */ -054 for (x = 0; x < (a->used - b); x++) \{ -055 *bottom++ = *top++; -056 \} -057 -058 /* zero the top digits */ -059 for (; x < a->used; x++) \{ -060 *bottom++ = 0; -061 \} -062 \} -063 -064 /* remove excess digits */ -065 a->used -= b; -066 \} -067 #endif -068 \end{alltt} \end{small} The only noteworthy element of this routine is the lack of a return type since it cannot fail. Like mp\_lshd() we -form a sliding window except we copy in the other direction. After the window (line 59) we then zero +form a sliding window except we copy in the other direction. After the window (line 60) we then zero the upper digits of the input to make sure the result is correct. \section{Powers of Two} @@ -3169,7 +2314,7 @@ left. After the digits have been shifted appropriately at most $lg(\beta) - 1$ shifts are left to perform. Step 5 calculates the number of remaining shifts required. If it is non-zero a modified shift loop is used to calculate the remaining product. -Essentially the loop is a generic version of algorith mp\_mul2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ +Essentially the loop is a generic version of algorithm mp\_mul\_2 designed to handle any shift count in the range $1 \le x < lg(\beta)$. The $mask$ variable is used to extract the upper $d$ bits to form the carry for the next iteration. This algorithm is loosely measured as a $O(2n)$ algorithm which means that if the input is $n$-digits that it takes $2n$ ``time'' to @@ -3179,82 +2324,16 @@ complete. It is possible to optimize this algorithm down to a $O(n)$ algorithm \hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_2d.c \vspace{-3mm} \begin{alltt} -016 -017 /* shift left by a certain bit count */ -018 int mp_mul_2d (mp_int * a, int b, mp_int * c) -019 \{ -020 mp_digit d; -021 int res; -022 -023 /* copy */ -024 if (a != c) \{ -025 if ((res = mp_copy (a, c)) != MP_OKAY) \{ -026 return res; -027 \} -028 \} -029 -030 if (c->alloc < (int)(c->used + b/DIGIT_BIT + 1)) \{ -031 if ((res = mp_grow (c, c->used + b / DIGIT_BIT + 1)) != MP_OKAY) \{ -032 return res; -033 \} -034 \} -035 -036 /* shift by as many digits in the bit count */ -037 if (b >= (int)DIGIT_BIT) \{ -038 if ((res = mp_lshd (c, b / DIGIT_BIT)) != MP_OKAY) \{ -039 return res; -040 \} -041 \} -042 -043 /* shift any bit count < DIGIT_BIT */ -044 d = (mp_digit) (b % DIGIT_BIT); -045 if (d != 0) \{ -046 register mp_digit *tmpc, shift, mask, r, rr; -047 register int x; -048 -049 /* bitmask for carries */ -050 mask = (((mp_digit)1) << d) - 1; -051 -052 /* shift for msbs */ -053 shift = DIGIT_BIT - d; -054 -055 /* alias */ -056 tmpc = c->dp; -057 -058 /* carry */ -059 r = 0; -060 for (x = 0; x < c->used; x++) \{ -061 /* get the higher bits of the current word */ -062 rr = (*tmpc >> shift) & mask; -063 -064 /* shift the current word and OR in the carry */ -065 *tmpc = ((*tmpc << d) | r) & MP_MASK; -066 ++tmpc; -067 -068 /* set the carry to the carry bits of the current word */ -069 r = rr; -070 \} -071 -072 /* set final carry */ -073 if (r != 0) \{ -074 c->dp[(c->used)++] = r; -075 \} -076 \} -077 mp_clamp (c); -078 return MP_OKAY; -079 \} -080 #endif -081 \end{alltt} \end{small} -The shifting is performed in--place which means the first step (line 24) is to copy the input to the +The shifting is performed in--place which means the first step (line 25) is to copy the input to the destination. We avoid calling mp\_copy() by making sure the mp\_ints are different. The destination then -has to be grown (line 31) to accomodate the result. +has to be grown (line 32) to accomodate the result. If the shift count $b$ is larger than $lg(\beta)$ then a call to mp\_lshd() is used to handle all of the multiples of $lg(\beta)$. Leaving only a remaining shift of $lg(\beta) - 1$ or fewer bits left. Inside the actual shift -loop (lines 45 to 76) we make use of pre--computed values $shift$ and $mask$. These are used to +loop (lines 46 to 76) we make use of pre--computed values $shift$ and $mask$. These are used to extract the carry bit(s) to pass into the next iteration of the loop. The $r$ and $rr$ variables form a chain between consecutive iterations to propagate the carry. @@ -3302,86 +2381,6 @@ by using algorithm mp\_mod\_2d. \hspace{-5.1mm}{\bf File}: bn\_mp\_div\_2d.c \vspace{-3mm} \begin{alltt} -016 -017 /* shift right by a certain bit count (store quotient in c, optional remaind - er in d) */ -018 int mp_div_2d (mp_int * a, int b, mp_int * c, mp_int * d) -019 \{ -020 mp_digit D, r, rr; -021 int x, res; -022 mp_int t; -023 -024 -025 /* if the shift count is <= 0 then we do no work */ -026 if (b <= 0) \{ -027 res = mp_copy (a, c); -028 if (d != NULL) \{ -029 mp_zero (d); -030 \} -031 return res; -032 \} -033 -034 if ((res = mp_init (&t)) != MP_OKAY) \{ -035 return res; -036 \} -037 -038 /* get the remainder */ -039 if (d != NULL) \{ -040 if ((res = mp_mod_2d (a, b, &t)) != MP_OKAY) \{ -041 mp_clear (&t); -042 return res; -043 \} -044 \} -045 -046 /* copy */ -047 if ((res = mp_copy (a, c)) != MP_OKAY) \{ -048 mp_clear (&t); -049 return res; -050 \} -051 -052 /* shift by as many digits in the bit count */ -053 if (b >= (int)DIGIT_BIT) \{ -054 mp_rshd (c, b / DIGIT_BIT); -055 \} -056 -057 /* shift any bit count < DIGIT_BIT */ -058 D = (mp_digit) (b % DIGIT_BIT); -059 if (D != 0) \{ -060 register mp_digit *tmpc, mask, shift; -061 -062 /* mask */ -063 mask = (((mp_digit)1) << D) - 1; -064 -065 /* shift for lsb */ -066 shift = DIGIT_BIT - D; -067 -068 /* alias */ -069 tmpc = c->dp + (c->used - 1); -070 -071 /* carry */ -072 r = 0; -073 for (x = c->used - 1; x >= 0; x--) \{ -074 /* get the lower bits of this word in a temp */ -075 rr = *tmpc & mask; -076 -077 /* shift the current word and mix in the carry bits from the previous - word */ -078 *tmpc = (*tmpc >> D) | (r << shift); -079 --tmpc; -080 -081 /* set the carry to the carry bits of the current word found above */ -082 r = rr; -083 \} -084 \} -085 mp_clamp (c); -086 if (d != NULL) \{ -087 mp_exch (&t, d); -088 \} -089 mp_clear (&t); -090 return MP_OKAY; -091 \} -092 #endif -093 \end{alltt} \end{small} @@ -3436,44 +2435,6 @@ is copied to $b$, leading digits are removed and the remaining leading digit is \hspace{-5.1mm}{\bf File}: bn\_mp\_mod\_2d.c \vspace{-3mm} \begin{alltt} -016 -017 /* calc a value mod 2**b */ -018 int -019 mp_mod_2d (mp_int * a, int b, mp_int * c) -020 \{ -021 int x, res; -022 -023 /* if b is <= 0 then zero the int */ -024 if (b <= 0) \{ -025 mp_zero (c); -026 return MP_OKAY; -027 \} -028 -029 /* if the modulus is larger than the value than return */ -030 if (b >= (int) (a->used * DIGIT_BIT)) \{ -031 res = mp_copy (a, c); -032 return res; -033 \} -034 -035 /* copy */ -036 if ((res = mp_copy (a, c)) != MP_OKAY) \{ -037 return res; -038 \} -039 -040 /* zero digits above the last digit of the modulus */ -041 for (x = (b / DIGIT_BIT) + ((b % DIGIT_BIT) == 0 ? 0 : 1); x < c->used; x+ - +) \{ -042 c->dp[x] = 0; -043 \} -044 /* clear the digit that is not completely outside/inside the modulus */ -045 c->dp[b / DIGIT_BIT] &= -046 (mp_digit) ((((mp_digit) 1) << (((mp_digit) b) % DIGIT_BIT)) - ((mp_digi - t) 1)); -047 mp_clamp (c); -048 return MP_OKAY; -049 \} -050 #endif -051 \end{alltt} \end{small} @@ -3482,8 +2443,8 @@ than the input we just mp\_copy() the input and return right away. After this p perform some work to produce the remainder. Recalling that reducing modulo $2^k$ and a binary ``and'' with $2^k - 1$ are numerically equivalent we can quickly reduce -the number. First we zero any digits above the last digit in $2^b$ (line 41). Next we reduce the -leading digit of both (line 45) and then mp\_clamp(). +the number. First we zero any digits above the last digit in $2^b$ (line 42). Next we reduce the +leading digit of both (line 46) and then mp\_clamp(). \section*{Exercises} \begin{tabular}{cl} @@ -3643,91 +2604,20 @@ exceed the precision requested. \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_mul\_digs.c \vspace{-3mm} \begin{alltt} -016 -017 /* multiplies |a| * |b| and only computes upto digs digits of result -018 * HAC pp. 595, Algorithm 14.12 Modified so you can control how -019 * many digits of output are created. -020 */ -021 int s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) -022 \{ -023 mp_int t; -024 int res, pa, pb, ix, iy; -025 mp_digit u; -026 mp_word r; -027 mp_digit tmpx, *tmpt, *tmpy; -028 -029 /* can we use the fast multiplier? */ -030 if (((digs) < MP_WARRAY) && -031 MIN (a->used, b->used) < -032 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ -033 return fast_s_mp_mul_digs (a, b, c, digs); -034 \} -035 -036 if ((res = mp_init_size (&t, digs)) != MP_OKAY) \{ -037 return res; -038 \} -039 t.used = digs; -040 -041 /* compute the digits of the product directly */ -042 pa = a->used; -043 for (ix = 0; ix < pa; ix++) \{ -044 /* set the carry to zero */ -045 u = 0; -046 -047 /* limit ourselves to making digs digits of output */ -048 pb = MIN (b->used, digs - ix); -049 -050 /* setup some aliases */ -051 /* copy of the digit from a used within the nested loop */ -052 tmpx = a->dp[ix]; -053 -054 /* an alias for the destination shifted ix places */ -055 tmpt = t.dp + ix; -056 -057 /* an alias for the digits of b */ -058 tmpy = b->dp; -059 -060 /* compute the columns of the output and propagate the carry */ -061 for (iy = 0; iy < pb; iy++) \{ -062 /* compute the column as a mp_word */ -063 r = ((mp_word)*tmpt) + -064 ((mp_word)tmpx) * ((mp_word)*tmpy++) + -065 ((mp_word) u); -066 -067 /* the new column is the lower part of the result */ -068 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -069 -070 /* get the carry word from the result */ -071 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); -072 \} -073 /* set carry if it is placed below digs */ -074 if (ix + iy < digs) \{ -075 *tmpt = u; -076 \} -077 \} -078 -079 mp_clamp (&t); -080 mp_exch (&t, c); -081 -082 mp_clear (&t); -083 return MP_OKAY; -084 \} -085 #endif -086 \end{alltt} \end{small} -First we determine (line 30) if the Comba method can be used first since it's faster. The conditions for +First we determine (line 31) if the Comba method can be used first since it's faster. The conditions for sing the Comba routine are that min$(a.used, b.used) < \delta$ and the number of digits of output is less than \textbf{MP\_WARRAY}. This new constant is used to control the stack usage in the Comba routines. By default it is set to $\delta$ but can be reduced when memory is at a premium. If we cannot use the Comba method we proceed to setup the baseline routine. We allocate the the destination mp\_int -$t$ (line 36) to the exact size of the output to avoid further re--allocations. At this point we now +$t$ (line 37) to the exact size of the output to avoid further re--allocations. At this point we now begin the $O(n^2)$ loop. This implementation of multiplication has the caveat that it can be trimmed to only produce a variable number of -digits as output. In each iteration of the outer loop the $pb$ variable is set (line 48) to the maximum +digits as output. In each iteration of the outer loop the $pb$ variable is set (line 49) to the maximum number of inner loop iterations. Inside the inner loop we calculate $\hat r$ as the mp\_word product of the two mp\_digits and the addition of the @@ -3735,7 +2625,7 @@ carry from the previous iteration. A particularly important observation is that C compilers (GCC for instance) can recognize that a $N \times N \rightarrow 2N$ multiplication is all that is required for the product. In x86 terms for example, this means using the MUL instruction. -Each digit of the product is stored in turn (line 68) and the carry propagated (line 71) to the +Each digit of the product is stored in turn (line 69) and the carry propagated (line 72) to the next iteration. \subsection{Faster Multiplication by the ``Comba'' Method} @@ -3864,17 +2754,16 @@ Place an array of \textbf{MP\_WARRAY} single precision digits named $W$ on the s \hspace{6mm}5.4.1 $\_ \hat W \leftarrow \_ \hat W + a_{tx+iy}b_{ty-iy}$ \\ \hspace{3mm}5.5 $W_{ix} \leftarrow \_ \hat W (\mbox{mod }\beta)$\\ \hspace{3mm}5.6 $\_ \hat W \leftarrow \lfloor \_ \hat W / \beta \rfloor$ \\ -6. $W_{pa} \leftarrow \_ \hat W (\mbox{mod }\beta)$ \\ \\ -7. $oldused \leftarrow c.used$ \\ -8. $c.used \leftarrow digs$ \\ -9. for $ix$ from $0$ to $pa$ do \\ -\hspace{3mm}9.1 $c_{ix} \leftarrow W_{ix}$ \\ -10. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ -\hspace{3mm}10.1 $c_{ix} \leftarrow 0$ \\ +6. $oldused \leftarrow c.used$ \\ +7. $c.used \leftarrow digs$ \\ +8. for $ix$ from $0$ to $pa$ do \\ +\hspace{3mm}8.1 $c_{ix} \leftarrow W_{ix}$ \\ +9. for $ix$ from $pa + 1$ to $oldused - 1$ do \\ +\hspace{3mm}9.1 $c_{ix} \leftarrow 0$ \\ \\ -11. Clamp $c$. \\ -12. Return MP\_OKAY. \\ +10. Clamp $c$. \\ +11. Return MP\_OKAY. \\ \hline \end{tabular} \end{center} @@ -3913,105 +2802,14 @@ and addition operations in the nested loop in parallel. \hspace{-5.1mm}{\bf File}: bn\_fast\_s\_mp\_mul\_digs.c \vspace{-3mm} \begin{alltt} -016 -017 /* Fast (comba) multiplier -018 * -019 * This is the fast column-array [comba] multiplier. It is -020 * designed to compute the columns of the product first -021 * then handle the carries afterwards. This has the effect -022 * of making the nested loops that compute the columns very -023 * simple and schedulable on super-scalar processors. -024 * -025 * This has been modified to produce a variable number of -026 * digits of output so if say only a half-product is required -027 * you don't have to compute the upper half (a feature -028 * required for fast Barrett reduction). -029 * -030 * Based on Algorithm 14.12 on pp.595 of HAC. -031 * -032 */ -033 int fast_s_mp_mul_digs (mp_int * a, mp_int * b, mp_int * c, int digs) -034 \{ -035 int olduse, res, pa, ix, iz; -036 mp_digit W[MP_WARRAY]; -037 register mp_word _W; -038 -039 /* grow the destination as required */ -040 if (c->alloc < digs) \{ -041 if ((res = mp_grow (c, digs)) != MP_OKAY) \{ -042 return res; -043 \} -044 \} -045 -046 /* number of output digits to produce */ -047 pa = MIN(digs, a->used + b->used); -048 -049 /* clear the carry */ -050 _W = 0; -051 for (ix = 0; ix < pa; ix++) \{ -052 int tx, ty; -053 int iy; -054 mp_digit *tmpx, *tmpy; -055 -056 /* get offsets into the two bignums */ -057 ty = MIN(b->used-1, ix); -058 tx = ix - ty; -059 -060 /* setup temp aliases */ -061 tmpx = a->dp + tx; -062 tmpy = b->dp + ty; -063 -064 /* this is the number of times the loop will iterrate, essentially -065 while (tx++ < a->used && ty-- >= 0) \{ ... \} -066 */ -067 iy = MIN(a->used-tx, ty+1); -068 -069 /* execute loop */ -070 for (iz = 0; iz < iy; ++iz) \{ -071 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); -072 -073 \} -074 -075 /* store term */ -076 W[ix] = ((mp_digit)_W) & MP_MASK; -077 -078 /* make next carry */ -079 _W = _W >> ((mp_word)DIGIT_BIT); -080 \} -081 -082 /* store final carry */ -083 W[ix] = (mp_digit)(_W & MP_MASK); -084 -085 /* setup dest */ -086 olduse = c->used; -087 c->used = pa; -088 -089 \{ -090 register mp_digit *tmpc; -091 tmpc = c->dp; -092 for (ix = 0; ix < pa+1; ix++) \{ -093 /* now extract the previous digit [below the carry] */ -094 *tmpc++ = W[ix]; -095 \} -096 -097 /* clear unused digits [that existed in the old copy of c] */ -098 for (; ix < olduse; ix++) \{ -099 *tmpc++ = 0; -100 \} -101 \} -102 mp_clamp (c); -103 return MP_OKAY; -104 \} -105 #endif -106 \end{alltt} \end{small} -As per the pseudo--code we first calculate $pa$ (line 47) as the number of digits to output. Next we begin the outer loop -to produce the individual columns of the product. We use the two aliases $tmpx$ and $tmpy$ (lines 61, 62) to point +As per the pseudo--code we first calculate $pa$ (line 48) as the number of digits to output. Next we begin the outer loop +to produce the individual columns of the product. We use the two aliases $tmpx$ and $tmpy$ (lines 62, 63) to point inside the two multiplicands quickly. -The inner loop (lines 70 to 73) of this implementation is where the tradeoff come into play. Originally this comba +The inner loop (lines 71 to 74) of this implementation is where the tradeoff come into play. Originally this comba implementation was ``row--major'' which means it adds to each of the columns in each pass. After the outer loop it would then fix the carries. This was very fast except it had an annoying drawback. You had to read a mp\_word and two mp\_digits and write one mp\_word per iteration. On processors such as the Athlon XP and P4 this did not matter much since the cache bandwidth @@ -4019,8 +2817,8 @@ is very high and it can keep the ALU fed with data. It did, however, matter on slower and also often doesn't exist. This new algorithm only performs two reads per iteration under the assumption that the compiler has aliased $\_ \hat W$ to a CPU register. -After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines 76, 79) to forward it as -a carry for the next pass. After the outer loop we use the final carry (line 83) as the last digit of the product. +After the inner loop we store the current accumulator in $W$ and shift $\_ \hat W$ (lines 77, 80) to forward it as +a carry for the next pass. After the outer loop we use the final carry (line 77) as the last digit of the product. \subsection{Polynomial Basis Multiplication} To break the $O(n^2)$ barrier in multiplication requires a completely different look at integer multiplication. In the following algorithms @@ -4207,160 +3005,12 @@ The remaining steps 13 through 18 compute the Karatsuba polynomial through a var \hspace{-5.1mm}{\bf File}: bn\_mp\_karatsuba\_mul.c \vspace{-3mm} \begin{alltt} -016 -017 /* c = |a| * |b| using Karatsuba Multiplication using -018 * three half size multiplications -019 * -020 * Let B represent the radix [e.g. 2**DIGIT_BIT] and -021 * let n represent half of the number of digits in -022 * the min(a,b) -023 * -024 * a = a1 * B**n + a0 -025 * b = b1 * B**n + b0 -026 * -027 * Then, a * b => -028 a1b1 * B**2n + ((a1 + a0)(b1 + b0) - (a0b0 + a1b1)) * B + a0b0 -029 * -030 * Note that a1b1 and a0b0 are used twice and only need to be -031 * computed once. So in total three half size (half # of -032 * digit) multiplications are performed, a0b0, a1b1 and -033 * (a1+b1)(a0+b0) -034 * -035 * Note that a multiplication of half the digits requires -036 * 1/4th the number of single precision multiplications so in -037 * total after one call 25% of the single precision multiplications -038 * are saved. Note also that the call to mp_mul can end up back -039 * in this function if the a0, a1, b0, or b1 are above the threshold. -040 * This is known as divide-and-conquer and leads to the famous -041 * O(N**lg(3)) or O(N**1.584) work which is asymptopically lower than -042 * the standard O(N**2) that the baseline/comba methods use. -043 * Generally though the overhead of this method doesn't pay off -044 * until a certain size (N ~ 80) is reached. -045 */ -046 int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) -047 \{ -048 mp_int x0, x1, y0, y1, t1, x0y0, x1y1; -049 int B, err; -050 -051 /* default the return code to an error */ -052 err = MP_MEM; -053 -054 /* min # of digits */ -055 B = MIN (a->used, b->used); -056 -057 /* now divide in two */ -058 B = B >> 1; -059 -060 /* init copy all the temps */ -061 if (mp_init_size (&x0, B) != MP_OKAY) -062 goto ERR; -063 if (mp_init_size (&x1, a->used - B) != MP_OKAY) -064 goto X0; -065 if (mp_init_size (&y0, B) != MP_OKAY) -066 goto X1; -067 if (mp_init_size (&y1, b->used - B) != MP_OKAY) -068 goto Y0; -069 -070 /* init temps */ -071 if (mp_init_size (&t1, B * 2) != MP_OKAY) -072 goto Y1; -073 if (mp_init_size (&x0y0, B * 2) != MP_OKAY) -074 goto T1; -075 if (mp_init_size (&x1y1, B * 2) != MP_OKAY) -076 goto X0Y0; -077 -078 /* now shift the digits */ -079 x0.used = y0.used = B; -080 x1.used = a->used - B; -081 y1.used = b->used - B; -082 -083 \{ -084 register int x; -085 register mp_digit *tmpa, *tmpb, *tmpx, *tmpy; -086 -087 /* we copy the digits directly instead of using higher level functions -088 * since we also need to shift the digits -089 */ -090 tmpa = a->dp; -091 tmpb = b->dp; -092 -093 tmpx = x0.dp; -094 tmpy = y0.dp; -095 for (x = 0; x < B; x++) \{ -096 *tmpx++ = *tmpa++; -097 *tmpy++ = *tmpb++; -098 \} -099 -100 tmpx = x1.dp; -101 for (x = B; x < a->used; x++) \{ -102 *tmpx++ = *tmpa++; -103 \} -104 -105 tmpy = y1.dp; -106 for (x = B; x < b->used; x++) \{ -107 *tmpy++ = *tmpb++; -108 \} -109 \} -110 -111 /* only need to clamp the lower words since by definition the -112 * upper words x1/y1 must have a known number of digits -113 */ -114 mp_clamp (&x0); -115 mp_clamp (&y0); -116 -117 /* now calc the products x0y0 and x1y1 */ -118 /* after this x0 is no longer required, free temp [x0==t2]! */ -119 if (mp_mul (&x0, &y0, &x0y0) != MP_OKAY) -120 goto X1Y1; /* x0y0 = x0*y0 */ -121 if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) -122 goto X1Y1; /* x1y1 = x1*y1 */ -123 -124 /* now calc x1+x0 and y1+y0 */ -125 if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) -126 goto X1Y1; /* t1 = x1 - x0 */ -127 if (s_mp_add (&y1, &y0, &x0) != MP_OKAY) -128 goto X1Y1; /* t2 = y1 - y0 */ -129 if (mp_mul (&t1, &x0, &t1) != MP_OKAY) -130 goto X1Y1; /* t1 = (x1 + x0) * (y1 + y0) */ -131 -132 /* add x0y0 */ -133 if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) -134 goto X1Y1; /* t2 = x0y0 + x1y1 */ -135 if (s_mp_sub (&t1, &x0, &t1) != MP_OKAY) -136 goto X1Y1; /* t1 = (x1+x0)*(y1+y0) - (x1y1 + x0y0) */ -137 -138 /* shift by B */ -139 if (mp_lshd (&t1, B) != MP_OKAY) -140 goto X1Y1; /* t1 = (x0y0 + x1y1 - (x1-x0)*(y1-y0))<used, b->used) / 3; -038 -039 /* a = a2 * B**2 + a1 * B + a0 */ -040 if ((res = mp_mod_2d(a, DIGIT_BIT * B, &a0)) != MP_OKAY) \{ -041 goto ERR; -042 \} -043 -044 if ((res = mp_copy(a, &a1)) != MP_OKAY) \{ -045 goto ERR; -046 \} -047 mp_rshd(&a1, B); -048 mp_mod_2d(&a1, DIGIT_BIT * B, &a1); -049 -050 if ((res = mp_copy(a, &a2)) != MP_OKAY) \{ -051 goto ERR; -052 \} -053 mp_rshd(&a2, B*2); -054 -055 /* b = b2 * B**2 + b1 * B + b0 */ -056 if ((res = mp_mod_2d(b, DIGIT_BIT * B, &b0)) != MP_OKAY) \{ -057 goto ERR; -058 \} -059 -060 if ((res = mp_copy(b, &b1)) != MP_OKAY) \{ -061 goto ERR; -062 \} -063 mp_rshd(&b1, B); -064 mp_mod_2d(&b1, DIGIT_BIT * B, &b1); -065 -066 if ((res = mp_copy(b, &b2)) != MP_OKAY) \{ -067 goto ERR; -068 \} -069 mp_rshd(&b2, B*2); -070 -071 /* w0 = a0*b0 */ -072 if ((res = mp_mul(&a0, &b0, &w0)) != MP_OKAY) \{ -073 goto ERR; -074 \} -075 -076 /* w4 = a2 * b2 */ -077 if ((res = mp_mul(&a2, &b2, &w4)) != MP_OKAY) \{ -078 goto ERR; -079 \} -080 -081 /* w1 = (a2 + 2(a1 + 2a0))(b2 + 2(b1 + 2b0)) */ -082 if ((res = mp_mul_2(&a0, &tmp1)) != MP_OKAY) \{ -083 goto ERR; -084 \} -085 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ -086 goto ERR; -087 \} -088 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ -089 goto ERR; -090 \} -091 if ((res = mp_add(&tmp1, &a2, &tmp1)) != MP_OKAY) \{ -092 goto ERR; -093 \} -094 -095 if ((res = mp_mul_2(&b0, &tmp2)) != MP_OKAY) \{ -096 goto ERR; -097 \} -098 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ -099 goto ERR; -100 \} -101 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ -102 goto ERR; -103 \} -104 if ((res = mp_add(&tmp2, &b2, &tmp2)) != MP_OKAY) \{ -105 goto ERR; -106 \} -107 -108 if ((res = mp_mul(&tmp1, &tmp2, &w1)) != MP_OKAY) \{ -109 goto ERR; -110 \} -111 -112 /* w3 = (a0 + 2(a1 + 2a2))(b0 + 2(b1 + 2b2)) */ -113 if ((res = mp_mul_2(&a2, &tmp1)) != MP_OKAY) \{ -114 goto ERR; -115 \} -116 if ((res = mp_add(&tmp1, &a1, &tmp1)) != MP_OKAY) \{ -117 goto ERR; -118 \} -119 if ((res = mp_mul_2(&tmp1, &tmp1)) != MP_OKAY) \{ -120 goto ERR; -121 \} -122 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ -123 goto ERR; -124 \} -125 -126 if ((res = mp_mul_2(&b2, &tmp2)) != MP_OKAY) \{ -127 goto ERR; -128 \} -129 if ((res = mp_add(&tmp2, &b1, &tmp2)) != MP_OKAY) \{ -130 goto ERR; -131 \} -132 if ((res = mp_mul_2(&tmp2, &tmp2)) != MP_OKAY) \{ -133 goto ERR; -134 \} -135 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ -136 goto ERR; -137 \} -138 -139 if ((res = mp_mul(&tmp1, &tmp2, &w3)) != MP_OKAY) \{ -140 goto ERR; -141 \} -142 -143 -144 /* w2 = (a2 + a1 + a0)(b2 + b1 + b0) */ -145 if ((res = mp_add(&a2, &a1, &tmp1)) != MP_OKAY) \{ -146 goto ERR; -147 \} -148 if ((res = mp_add(&tmp1, &a0, &tmp1)) != MP_OKAY) \{ -149 goto ERR; -150 \} -151 if ((res = mp_add(&b2, &b1, &tmp2)) != MP_OKAY) \{ -152 goto ERR; -153 \} -154 if ((res = mp_add(&tmp2, &b0, &tmp2)) != MP_OKAY) \{ -155 goto ERR; -156 \} -157 if ((res = mp_mul(&tmp1, &tmp2, &w2)) != MP_OKAY) \{ -158 goto ERR; -159 \} -160 -161 /* now solve the matrix -162 -163 0 0 0 0 1 -164 1 2 4 8 16 -165 1 1 1 1 1 -166 16 8 4 2 1 -167 1 0 0 0 0 -168 -169 using 12 subtractions, 4 shifts, -170 2 small divisions and 1 small multiplication -171 */ -172 -173 /* r1 - r4 */ -174 if ((res = mp_sub(&w1, &w4, &w1)) != MP_OKAY) \{ -175 goto ERR; -176 \} -177 /* r3 - r0 */ -178 if ((res = mp_sub(&w3, &w0, &w3)) != MP_OKAY) \{ -179 goto ERR; -180 \} -181 /* r1/2 */ -182 if ((res = mp_div_2(&w1, &w1)) != MP_OKAY) \{ -183 goto ERR; -184 \} -185 /* r3/2 */ -186 if ((res = mp_div_2(&w3, &w3)) != MP_OKAY) \{ -187 goto ERR; -188 \} -189 /* r2 - r0 - r4 */ -190 if ((res = mp_sub(&w2, &w0, &w2)) != MP_OKAY) \{ -191 goto ERR; -192 \} -193 if ((res = mp_sub(&w2, &w4, &w2)) != MP_OKAY) \{ -194 goto ERR; -195 \} -196 /* r1 - r2 */ -197 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ -198 goto ERR; -199 \} -200 /* r3 - r2 */ -201 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ -202 goto ERR; -203 \} -204 /* r1 - 8r0 */ -205 if ((res = mp_mul_2d(&w0, 3, &tmp1)) != MP_OKAY) \{ -206 goto ERR; -207 \} -208 if ((res = mp_sub(&w1, &tmp1, &w1)) != MP_OKAY) \{ -209 goto ERR; -210 \} -211 /* r3 - 8r4 */ -212 if ((res = mp_mul_2d(&w4, 3, &tmp1)) != MP_OKAY) \{ -213 goto ERR; -214 \} -215 if ((res = mp_sub(&w3, &tmp1, &w3)) != MP_OKAY) \{ -216 goto ERR; -217 \} -218 /* 3r2 - r1 - r3 */ -219 if ((res = mp_mul_d(&w2, 3, &w2)) != MP_OKAY) \{ -220 goto ERR; -221 \} -222 if ((res = mp_sub(&w2, &w1, &w2)) != MP_OKAY) \{ -223 goto ERR; -224 \} -225 if ((res = mp_sub(&w2, &w3, &w2)) != MP_OKAY) \{ -226 goto ERR; -227 \} -228 /* r1 - r2 */ -229 if ((res = mp_sub(&w1, &w2, &w1)) != MP_OKAY) \{ -230 goto ERR; -231 \} -232 /* r3 - r2 */ -233 if ((res = mp_sub(&w3, &w2, &w3)) != MP_OKAY) \{ -234 goto ERR; -235 \} -236 /* r1/3 */ -237 if ((res = mp_div_3(&w1, &w1, NULL)) != MP_OKAY) \{ -238 goto ERR; -239 \} -240 /* r3/3 */ -241 if ((res = mp_div_3(&w3, &w3, NULL)) != MP_OKAY) \{ -242 goto ERR; -243 \} -244 -245 /* at this point shift W[n] by B*n */ -246 if ((res = mp_lshd(&w1, 1*B)) != MP_OKAY) \{ -247 goto ERR; -248 \} -249 if ((res = mp_lshd(&w2, 2*B)) != MP_OKAY) \{ -250 goto ERR; -251 \} -252 if ((res = mp_lshd(&w3, 3*B)) != MP_OKAY) \{ -253 goto ERR; -254 \} -255 if ((res = mp_lshd(&w4, 4*B)) != MP_OKAY) \{ -256 goto ERR; -257 \} -258 -259 if ((res = mp_add(&w0, &w1, c)) != MP_OKAY) \{ -260 goto ERR; -261 \} -262 if ((res = mp_add(&w2, &w3, &tmp1)) != MP_OKAY) \{ -263 goto ERR; -264 \} -265 if ((res = mp_add(&w4, &tmp1, &tmp1)) != MP_OKAY) \{ -266 goto ERR; -267 \} -268 if ((res = mp_add(&tmp1, c, c)) != MP_OKAY) \{ -269 goto ERR; -270 \} -271 -272 ERR: -273 mp_clear_multi(&w0, &w1, &w2, &w3, &w4, -274 &a0, &a1, &a2, &b0, &b1, -275 &b2, &tmp1, &tmp2, NULL); -276 return res; -277 \} -278 -279 #endif -280 \end{alltt} \end{small} @@ -4767,12 +3152,12 @@ large numbers. For example, a 10,000 digit multiplication takes approximaly 99, Toom--Cook than a Comba or baseline approach (this is a savings of more than 99$\%$). For most ``crypto'' sized numbers this algorithm is not practical as Karatsuba has a much lower cutoff point. -First we split $a$ and $b$ into three roughly equal portions. This has been accomplished (lines 40 to 69) with +First we split $a$ and $b$ into three roughly equal portions. This has been accomplished (lines 41 to 70) with combinations of mp\_rshd() and mp\_mod\_2d() function calls. At this point $a = a2 \cdot \beta^2 + a1 \cdot \beta + a0$ and similiarly for $b$. Next we compute the five points $w0, w1, w2, w3$ and $w4$. Recall that $w0$ and $w4$ can be computed directly from the portions so -we get those out of the way first (lines 72 and 77). Next we compute $w1, w2$ and $w3$ using Horners method. +we get those out of the way first (lines 73 and 78). Next we compute $w1, w2$ and $w3$ using Horners method. After this point we solve for the actual values of $w1, w2$ and $w3$ by reducing the $5 \times 5$ system which is relatively straight forward. @@ -4821,58 +3206,11 @@ s\_mp\_mul\_digs will clear it. \hspace{-5.1mm}{\bf File}: bn\_mp\_mul.c \vspace{-3mm} \begin{alltt} -016 -017 /* high level multiplication (handles sign) */ -018 int mp_mul (mp_int * a, mp_int * b, mp_int * c) -019 \{ -020 int res, neg; -021 neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; -022 -023 /* use Toom-Cook? */ -024 #ifdef BN_MP_TOOM_MUL_C -025 if (MIN (a->used, b->used) >= TOOM_MUL_CUTOFF) \{ -026 res = mp_toom_mul(a, b, c); -027 \} else -028 #endif -029 #ifdef BN_MP_KARATSUBA_MUL_C -030 /* use Karatsuba? */ -031 if (MIN (a->used, b->used) >= KARATSUBA_MUL_CUTOFF) \{ -032 res = mp_karatsuba_mul (a, b, c); -033 \} else -034 #endif -035 \{ -036 /* can we use the fast multiplier? -037 * -038 * The fast multiplier can be used if the output will -039 * have less than MP_WARRAY digits and the number of -040 * digits won't affect carry propagation -041 */ -042 int digs = a->used + b->used + 1; -043 -044 #ifdef BN_FAST_S_MP_MUL_DIGS_C -045 if ((digs < MP_WARRAY) && -046 MIN(a->used, b->used) <= -047 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ -048 res = fast_s_mp_mul_digs (a, b, c, digs); -049 \} else -050 #endif -051 #ifdef BN_S_MP_MUL_DIGS_C -052 res = s_mp_mul (a, b, c); /* uses s_mp_mul_digs */ -053 #else -054 res = MP_VAL; -055 #endif -056 -057 \} -058 c->sign = (c->used > 0) ? neg : MP_ZPOS; -059 return res; -060 \} -061 #endif -062 \end{alltt} \end{small} -The implementation is rather simplistic and is not particularly noteworthy. Line 23 computes the sign of the result using the ``?'' -operator from the C programming language. Line 47 computes $\delta$ using the fact that $1 << k$ is equal to $2^k$. +The implementation is rather simplistic and is not particularly noteworthy. Line 22 computes the sign of the result using the ``?'' +operator from the C programming language. Line 48 computes $\delta$ using the fact that $1 << k$ is equal to $2^k$. \section{Squaring} \label{sec:basesquare} @@ -4973,78 +3311,13 @@ results calculated so far. This involves expensive carry propagation which will \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_sqr.c \vspace{-3mm} \begin{alltt} -016 -017 /* low level squaring, b = a*a, HAC pp.596-597, Algorithm 14.16 */ -018 int s_mp_sqr (mp_int * a, mp_int * b) -019 \{ -020 mp_int t; -021 int res, ix, iy, pa; -022 mp_word r; -023 mp_digit u, tmpx, *tmpt; -024 -025 pa = a->used; -026 if ((res = mp_init_size (&t, 2*pa + 1)) != MP_OKAY) \{ -027 return res; -028 \} -029 -030 /* default used is maximum possible size */ -031 t.used = 2*pa + 1; -032 -033 for (ix = 0; ix < pa; ix++) \{ -034 /* first calculate the digit at 2*ix */ -035 /* calculate double precision result */ -036 r = ((mp_word) t.dp[2*ix]) + -037 ((mp_word)a->dp[ix])*((mp_word)a->dp[ix]); -038 -039 /* store lower part in result */ -040 t.dp[ix+ix] = (mp_digit) (r & ((mp_word) MP_MASK)); -041 -042 /* get the carry */ -043 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -044 -045 /* left hand side of A[ix] * A[iy] */ -046 tmpx = a->dp[ix]; -047 -048 /* alias for where to store the results */ -049 tmpt = t.dp + (2*ix + 1); -050 -051 for (iy = ix + 1; iy < pa; iy++) \{ -052 /* first calculate the product */ -053 r = ((mp_word)tmpx) * ((mp_word)a->dp[iy]); -054 -055 /* now calculate the double precision result, note we use -056 * addition instead of *2 since it's easier to optimize -057 */ -058 r = ((mp_word) *tmpt) + r + r + ((mp_word) u); -059 -060 /* store lower part */ -061 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -062 -063 /* get carry */ -064 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -065 \} -066 /* propagate upwards */ -067 while (u != ((mp_digit) 0)) \{ -068 r = ((mp_word) *tmpt) + ((mp_word) u); -069 *tmpt++ = (mp_digit) (r & ((mp_word) MP_MASK)); -070 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -071 \} -072 \} -073 -074 mp_clamp (&t); -075 mp_exch (&t, b); -076 mp_clear (&t); -077 return MP_OKAY; -078 \} -079 #endif -080 \end{alltt} \end{small} -Inside the outer loop (line 33) the square term is calculated on line 36. The carry (line 43) has been +Inside the outer loop (line 34) the square term is calculated on line 37. The carry (line 44) has been extracted from the mp\_word accumulator using a right shift. Aliases for $a_{ix}$ and $t_{ix+iy}$ are initialized -(lines 46 and 49) to simplify the inner loop. The doubling is performed using two -additions (line 58) since it is usually faster than shifting, if not at least as fast. +(lines 47 and 50) to simplify the inner loop. The doubling is performed using two +additions (line 59) since it is usually faster than shifting, if not at least as fast. The important observation is that the inner loop does not begin at $iy = 0$ like for multiplication. As such the inner loops get progressively shorter as the algorithm proceeds. This is what leads to the savings compared to using a multiplication to @@ -5126,101 +3399,6 @@ only to even outputs and it is the square of the term at the $\lfloor ix / 2 \rf \hspace{-5.1mm}{\bf File}: bn\_fast\_s\_mp\_sqr.c \vspace{-3mm} \begin{alltt} -016 -017 /* the jist of squaring... -018 * you do like mult except the offset of the tmpx [one that -019 * starts closer to zero] can't equal the offset of tmpy. -020 * So basically you set up iy like before then you min it with -021 * (ty-tx) so that it never happens. You double all those -022 * you add in the inner loop -023 -024 After that loop you do the squares and add them in. -025 */ -026 -027 int fast_s_mp_sqr (mp_int * a, mp_int * b) -028 \{ -029 int olduse, res, pa, ix, iz; -030 mp_digit W[MP_WARRAY], *tmpx; -031 mp_word W1; -032 -033 /* grow the destination as required */ -034 pa = a->used + a->used; -035 if (b->alloc < pa) \{ -036 if ((res = mp_grow (b, pa)) != MP_OKAY) \{ -037 return res; -038 \} -039 \} -040 -041 /* number of output digits to produce */ -042 W1 = 0; -043 for (ix = 0; ix < pa; ix++) \{ -044 int tx, ty, iy; -045 mp_word _W; -046 mp_digit *tmpy; -047 -048 /* clear counter */ -049 _W = 0; -050 -051 /* get offsets into the two bignums */ -052 ty = MIN(a->used-1, ix); -053 tx = ix - ty; -054 -055 /* setup temp aliases */ -056 tmpx = a->dp + tx; -057 tmpy = a->dp + ty; -058 -059 /* this is the number of times the loop will iterrate, essentially -060 while (tx++ < a->used && ty-- >= 0) \{ ... \} -061 */ -062 iy = MIN(a->used-tx, ty+1); -063 -064 /* now for squaring tx can never equal ty -065 * we halve the distance since they approach at a rate of 2x -066 * and we have to round because odd cases need to be executed -067 */ -068 iy = MIN(iy, (ty-tx+1)>>1); -069 -070 /* execute loop */ -071 for (iz = 0; iz < iy; iz++) \{ -072 _W += ((mp_word)*tmpx++)*((mp_word)*tmpy--); -073 \} -074 -075 /* double the inner product and add carry */ -076 _W = _W + _W + W1; -077 -078 /* even columns have the square term in them */ -079 if ((ix&1) == 0) \{ -080 _W += ((mp_word)a->dp[ix>>1])*((mp_word)a->dp[ix>>1]); -081 \} -082 -083 /* store it */ -084 W[ix] = (mp_digit)(_W & MP_MASK); -085 -086 /* make next carry */ -087 W1 = _W >> ((mp_word)DIGIT_BIT); -088 \} -089 -090 /* setup dest */ -091 olduse = b->used; -092 b->used = a->used+a->used; -093 -094 \{ -095 mp_digit *tmpb; -096 tmpb = b->dp; -097 for (ix = 0; ix < pa; ix++) \{ -098 *tmpb++ = W[ix] & MP_MASK; -099 \} -100 -101 /* clear unused digits [that existed in the old copy of c] */ -102 for (; ix < olduse; ix++) \{ -103 *tmpb++ = 0; -104 \} -105 \} -106 mp_clamp (b); -107 return MP_OKAY; -108 \} -109 #endif -110 \end{alltt} \end{small} @@ -5330,113 +3508,11 @@ ratio of 1:7. } than simpler operations such as addition. \hspace{-5.1mm}{\bf File}: bn\_mp\_karatsuba\_sqr.c \vspace{-3mm} \begin{alltt} -016 -017 /* Karatsuba squaring, computes b = a*a using three -018 * half size squarings -019 * -020 * See comments of karatsuba_mul for details. It -021 * is essentially the same algorithm but merely -022 * tuned to perform recursive squarings. -023 */ -024 int mp_karatsuba_sqr (mp_int * a, mp_int * b) -025 \{ -026 mp_int x0, x1, t1, t2, x0x0, x1x1; -027 int B, err; -028 -029 err = MP_MEM; -030 -031 /* min # of digits */ -032 B = a->used; -033 -034 /* now divide in two */ -035 B = B >> 1; -036 -037 /* init copy all the temps */ -038 if (mp_init_size (&x0, B) != MP_OKAY) -039 goto ERR; -040 if (mp_init_size (&x1, a->used - B) != MP_OKAY) -041 goto X0; -042 -043 /* init temps */ -044 if (mp_init_size (&t1, a->used * 2) != MP_OKAY) -045 goto X1; -046 if (mp_init_size (&t2, a->used * 2) != MP_OKAY) -047 goto T1; -048 if (mp_init_size (&x0x0, B * 2) != MP_OKAY) -049 goto T2; -050 if (mp_init_size (&x1x1, (a->used - B) * 2) != MP_OKAY) -051 goto X0X0; -052 -053 \{ -054 register int x; -055 register mp_digit *dst, *src; -056 -057 src = a->dp; -058 -059 /* now shift the digits */ -060 dst = x0.dp; -061 for (x = 0; x < B; x++) \{ -062 *dst++ = *src++; -063 \} -064 -065 dst = x1.dp; -066 for (x = B; x < a->used; x++) \{ -067 *dst++ = *src++; -068 \} -069 \} -070 -071 x0.used = B; -072 x1.used = a->used - B; -073 -074 mp_clamp (&x0); -075 -076 /* now calc the products x0*x0 and x1*x1 */ -077 if (mp_sqr (&x0, &x0x0) != MP_OKAY) -078 goto X1X1; /* x0x0 = x0*x0 */ -079 if (mp_sqr (&x1, &x1x1) != MP_OKAY) -080 goto X1X1; /* x1x1 = x1*x1 */ -081 -082 /* now calc (x1+x0)**2 */ -083 if (s_mp_add (&x1, &x0, &t1) != MP_OKAY) -084 goto X1X1; /* t1 = x1 - x0 */ -085 if (mp_sqr (&t1, &t1) != MP_OKAY) -086 goto X1X1; /* t1 = (x1 - x0) * (x1 - x0) */ -087 -088 /* add x0y0 */ -089 if (s_mp_add (&x0x0, &x1x1, &t2) != MP_OKAY) -090 goto X1X1; /* t2 = x0x0 + x1x1 */ -091 if (s_mp_sub (&t1, &t2, &t1) != MP_OKAY) -092 goto X1X1; /* t1 = (x1+x0)**2 - (x0x0 + x1x1) */ -093 -094 /* shift by B */ -095 if (mp_lshd (&t1, B) != MP_OKAY) -096 goto X1X1; /* t1 = (x0x0 + x1x1 - (x1-x0)*(x1-x0))<used >= TOOM_SQR_CUTOFF) \{ -026 res = mp_toom_sqr(a, b); -027 /* Karatsuba? */ -028 \} else -029 #endif -030 #ifdef BN_MP_KARATSUBA_SQR_C -031 if (a->used >= KARATSUBA_SQR_CUTOFF) \{ -032 res = mp_karatsuba_sqr (a, b); -033 \} else -034 #endif -035 \{ -036 #ifdef BN_FAST_S_MP_SQR_C -037 /* can we use the fast comba multiplier? */ -038 if ((a->used * 2 + 1) < MP_WARRAY && -039 a->used < -040 (1 << (sizeof(mp_word) * CHAR_BIT - 2*DIGIT_BIT - 1))) \{ -041 res = fast_s_mp_sqr (a, b); -042 \} else -043 #endif -044 #ifdef BN_S_MP_SQR_C -045 res = s_mp_sqr (a, b); -046 #else -047 res = MP_VAL; -048 #endif -049 \} -050 b->sign = MP_ZPOS; -051 return res; -052 \} -053 #endif -054 \end{alltt} \end{small} @@ -5782,93 +3819,12 @@ performed at most twice, and on average once. However, if $a \ge b^2$ than it wi \hspace{-5.1mm}{\bf File}: bn\_mp\_reduce.c \vspace{-3mm} \begin{alltt} -016 -017 /* reduces x mod m, assumes 0 < x < m**2, mu is -018 * precomputed via mp_reduce_setup. -019 * From HAC pp.604 Algorithm 14.42 -020 */ -021 int mp_reduce (mp_int * x, mp_int * m, mp_int * mu) -022 \{ -023 mp_int q; -024 int res, um = m->used; -025 -026 /* q = x */ -027 if ((res = mp_init_copy (&q, x)) != MP_OKAY) \{ -028 return res; -029 \} -030 -031 /* q1 = x / b**(k-1) */ -032 mp_rshd (&q, um - 1); -033 -034 /* according to HAC this optimization is ok */ -035 if (((unsigned long) um) > (((mp_digit)1) << (DIGIT_BIT - 1))) \{ -036 if ((res = mp_mul (&q, mu, &q)) != MP_OKAY) \{ -037 goto CLEANUP; -038 \} -039 \} else \{ -040 #ifdef BN_S_MP_MUL_HIGH_DIGS_C -041 if ((res = s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) \{ -042 goto CLEANUP; -043 \} -044 #elif defined(BN_FAST_S_MP_MUL_HIGH_DIGS_C) -045 if ((res = fast_s_mp_mul_high_digs (&q, mu, &q, um)) != MP_OKAY) \{ -046 goto CLEANUP; -047 \} -048 #else -049 \{ -050 res = MP_VAL; -051 goto CLEANUP; -052 \} -053 #endif -054 \} -055 -056 /* q3 = q2 / b**(k+1) */ -057 mp_rshd (&q, um + 1); -058 -059 /* x = x mod b**(k+1), quick (no division) */ -060 if ((res = mp_mod_2d (x, DIGIT_BIT * (um + 1), x)) != MP_OKAY) \{ -061 goto CLEANUP; -062 \} -063 -064 /* q = q * m mod b**(k+1), quick (no division) */ -065 if ((res = s_mp_mul_digs (&q, m, &q, um + 1)) != MP_OKAY) \{ -066 goto CLEANUP; -067 \} -068 -069 /* x = x - q */ -070 if ((res = mp_sub (x, &q, x)) != MP_OKAY) \{ -071 goto CLEANUP; -072 \} -073 -074 /* If x < 0, add b**(k+1) to it */ -075 if (mp_cmp_d (x, 0) == MP_LT) \{ -076 mp_set (&q, 1); -077 if ((res = mp_lshd (&q, um + 1)) != MP_OKAY) -078 goto CLEANUP; -079 if ((res = mp_add (x, &q, x)) != MP_OKAY) -080 goto CLEANUP; -081 \} -082 -083 /* Back off if it's too big */ -084 while (mp_cmp (x, m) != MP_LT) \{ -085 if ((res = s_mp_sub (x, m, x)) != MP_OKAY) \{ -086 goto CLEANUP; -087 \} -088 \} -089 -090 CLEANUP: -091 mp_clear (&q); -092 -093 return res; -094 \} -095 #endif -096 \end{alltt} \end{small} The first multiplication that determines the quotient can be performed by only producing the digits from $m - 1$ and up. This essentially halves the number of single precision multiplications required. However, the optimization is only safe if $\beta$ is much larger than the number of digits -in the modulus. In the source code this is evaluated on lines 36 to 43 where algorithm s\_mp\_mul\_high\_digs is used when it is +in the modulus. In the source code this is evaluated on lines 36 to 44 where algorithm s\_mp\_mul\_high\_digs is used when it is safe to do so. \subsection{The Barrett Setup Algorithm} @@ -5901,21 +3857,6 @@ is equivalent and much faster. The final value is computed by taking the intege \hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_setup.c \vspace{-3mm} \begin{alltt} -016 -017 /* pre-calculate the value required for Barrett reduction -018 * For a given modulus "b" it calulates the value required in "a" -019 */ -020 int mp_reduce_setup (mp_int * a, mp_int * b) -021 \{ -022 int res; -023 -024 if ((res = mp_2expt (a, b->used * 2 * DIGIT_BIT)) != MP_OKAY) \{ -025 return res; -026 \} -027 return mp_div (a, b, a, NULL); -028 \} -029 #endif -030 \end{alltt} \end{small} @@ -5980,6 +3921,7 @@ $0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction \hline $6$ & $x/2 = 139$ \\ \hline $7$ & $x + n = 396$, $x/2 = 198$ \\ \hline $8$ & $x/2 = 99$ \\ +\hline $9$ & $x + n = 356$, $x/2 = 178$ \\ \hline \end{tabular} \end{center} @@ -5988,8 +3930,8 @@ $0 \le r < \lfloor x/2^k \rfloor + n$. As a result at most a single subtraction \label{fig:MONT1} \end{figure} -Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 8$. The result of the algorithm $r = 99$ is -congruent to the value of $2^{-8} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^8$ modulo $257$ the correct residue +Consider the example in figure~\ref{fig:MONT1} which reduces $x = 5555$ modulo $n = 257$ when $k = 9$ (note $\beta^k = 512$ which is larger than $n$). The result of +the algorithm $r = 178$ is congruent to the value of $2^{-9} \cdot 5555 \mbox{ (mod }257\mbox{)}$. When $r$ is multiplied by $2^9$ modulo $257$ the correct residue $r \equiv 158$ is produced. Let $k = \lfloor lg(n) \rfloor + 1$ represent the number of bits in $n$. The current algorithm requires $2k^2$ single precision shifts @@ -6001,10 +3943,10 @@ Fortunately there exists an alternative representation of the algorithm. \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{Montgomery Reduction} (modified I). \\ -\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Input}. Integer $x$, $n$ and $k$ ($2^k > n$) \\ \textbf{Output}. $2^{-k}x \mbox{ (mod }n\mbox{)}$ \\ \hline \\ -1. for $t$ from $0$ to $k - 1$ do \\ +1. for $t$ from $1$ to $k$ do \\ \hspace{3mm}1.1 If the $t$'th bit of $x$ is one then \\ \hspace{6mm}1.1.1 $x \leftarrow x + 2^tn$ \\ 2. Return $x/2^k$. \\ @@ -6032,7 +3974,8 @@ precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a s \hline $6$ & $8896$ & $10001011000000$ \\ \hline $7$ & $x + 2^{6}n = 25344$ & $110001100000000$ \\ \hline $8$ & $25344$ & $110001100000000$ \\ -\hline -- & $x/2^k = 99$ & \\ +\hline $9$ & $x + 2^{7}n = 91136$ & $10110010000000000$ \\ +\hline -- & $x/2^k = 178$ & \\ \hline \end{tabular} \end{center} @@ -6041,7 +3984,7 @@ precision shifts has now been reduced from $2k^2$ to $k^2 + k$ which is only a s \label{fig:MONT2} \end{figure} -Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 8$. +Figure~\ref{fig:MONT2} demonstrates the modified algorithm reducing $x = 5555$ modulo $n = 257$ with $k = 9$. With this algorithm a single shift right at the end is the only right shift required to reduce the input instead of $k$ right shifts inside the loop. Note that for the iterations $t = 2, 5, 6$ and $8$ where the result $x$ is not changed. In those iterations the $t$'th bit of $x$ is zero and the appropriate multiple of $n$ does not need to be added to force the $t$'th bit of the result to zero. @@ -6055,7 +3998,7 @@ previous algorithm re-written to compute the Montgomery reduction in this new fa \begin{center} \begin{tabular}{l} \hline Algorithm \textbf{Montgomery Reduction} (modified II). \\ -\textbf{Input}. Integer $x$, $n$ and $k$ \\ +\textbf{Input}. Integer $x$, $n$ and $k$ ($\beta^k > n$) \\ \textbf{Output}. $\beta^{-k}x \mbox{ (mod }n\mbox{)}$ \\ \hline \\ 1. for $t$ from $0$ to $k - 1$ do \\ @@ -6173,110 +4116,11 @@ multiplications. \hspace{-5.1mm}{\bf File}: bn\_mp\_montgomery\_reduce.c \vspace{-3mm} \begin{alltt} -016 -017 /* computes xR**-1 == x (mod N) via Montgomery Reduction */ -018 int -019 mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) -020 \{ -021 int ix, res, digs; -022 mp_digit mu; -023 -024 /* can the fast reduction [comba] method be used? -025 * -026 * Note that unlike in mul you're safely allowed *less* -027 * than the available columns [255 per default] since carries -028 * are fixed up in the inner loop. -029 */ -030 digs = n->used * 2 + 1; -031 if ((digs < MP_WARRAY) && -032 n->used < -033 (1 << ((CHAR_BIT * sizeof (mp_word)) - (2 * DIGIT_BIT)))) \{ -034 return fast_mp_montgomery_reduce (x, n, rho); -035 \} -036 -037 /* grow the input as required */ -038 if (x->alloc < digs) \{ -039 if ((res = mp_grow (x, digs)) != MP_OKAY) \{ -040 return res; -041 \} -042 \} -043 x->used = digs; -044 -045 for (ix = 0; ix < n->used; ix++) \{ -046 /* mu = ai * rho mod b -047 * -048 * The value of rho must be precalculated via -049 * montgomery_setup() such that -050 * it equals -1/n0 mod b this allows the -051 * following inner loop to reduce the -052 * input one digit at a time -053 */ -054 mu = (mp_digit) (((mp_word)x->dp[ix]) * ((mp_word)rho) & MP_MASK); -055 -056 /* a = a + mu * m * b**i */ -057 \{ -058 register int iy; -059 register mp_digit *tmpn, *tmpx, u; -060 register mp_word r; -061 -062 /* alias for digits of the modulus */ -063 tmpn = n->dp; -064 -065 /* alias for the digits of x [the input] */ -066 tmpx = x->dp + ix; -067 -068 /* set the carry to zero */ -069 u = 0; -070 -071 /* Multiply and add in place */ -072 for (iy = 0; iy < n->used; iy++) \{ -073 /* compute product and sum */ -074 r = ((mp_word)mu) * ((mp_word)*tmpn++) + -075 ((mp_word) u) + ((mp_word) * tmpx); -076 -077 /* get carry */ -078 u = (mp_digit)(r >> ((mp_word) DIGIT_BIT)); -079 -080 /* fix digit */ -081 *tmpx++ = (mp_digit)(r & ((mp_word) MP_MASK)); -082 \} -083 /* At this point the ix'th digit of x should be zero */ -084 -085 -086 /* propagate carries upwards as required*/ -087 while (u) \{ -088 *tmpx += u; -089 u = *tmpx >> DIGIT_BIT; -090 *tmpx++ &= MP_MASK; -091 \} -092 \} -093 \} -094 -095 /* at this point the n.used'th least -096 * significant digits of x are all zero -097 * which means we can shift x to the -098 * right by n.used digits and the -099 * residue is unchanged. -100 */ -101 -102 /* x = x/b**n.used */ -103 mp_clamp(x); -104 mp_rshd (x, n->used); -105 -106 /* if x >= n then x = x - n */ -107 if (mp_cmp_mag (x, n) != MP_LT) \{ -108 return s_mp_sub (x, n, x); -109 \} -110 -111 return MP_OKAY; -112 \} -113 #endif -114 \end{alltt} \end{small} -This is the baseline implementation of the Montgomery reduction algorithm. Lines 30 to 35 determine if the Comba based -routine can be used instead. Line 48 computes the value of $\mu$ for that particular iteration of the outer loop. +This is the baseline implementation of the Montgomery reduction algorithm. Lines 31 to 36 determine if the Comba based +routine can be used instead. Line 47 computes the value of $\mu$ for that particular iteration of the outer loop. The multiplication $\mu n \beta^{ix}$ is performed in one step in the inner loop. The alias $tmpx$ refers to the $ix$'th digit of $x$ and the alias $tmpn$ refers to the modulus $n$. @@ -6364,170 +4208,17 @@ stored in the destination $x$. \hspace{-5.1mm}{\bf File}: bn\_fast\_mp\_montgomery\_reduce.c \vspace{-3mm} \begin{alltt} -016 -017 /* computes xR**-1 == x (mod N) via Montgomery Reduction -018 * -019 * This is an optimized implementation of montgomery_reduce -020 * which uses the comba method to quickly calculate the columns of the -021 * reduction. -022 * -023 * Based on Algorithm 14.32 on pp.601 of HAC. -024 */ -025 int fast_mp_montgomery_reduce (mp_int * x, mp_int * n, mp_digit rho) -026 \{ -027 int ix, res, olduse; -028 mp_word W[MP_WARRAY]; -029 -030 /* get old used count */ -031 olduse = x->used; -032 -033 /* grow a as required */ -034 if (x->alloc < n->used + 1) \{ -035 if ((res = mp_grow (x, n->used + 1)) != MP_OKAY) \{ -036 return res; -037 \} -038 \} -039 -040 /* first we have to get the digits of the input into -041 * an array of double precision words W[...] -042 */ -043 \{ -044 register mp_word *_W; -045 register mp_digit *tmpx; -046 -047 /* alias for the W[] array */ -048 _W = W; -049 -050 /* alias for the digits of x*/ -051 tmpx = x->dp; -052 -053 /* copy the digits of a into W[0..a->used-1] */ -054 for (ix = 0; ix < x->used; ix++) \{ -055 *_W++ = *tmpx++; -056 \} -057 -058 /* zero the high words of W[a->used..m->used*2] */ -059 for (; ix < n->used * 2 + 1; ix++) \{ -060 *_W++ = 0; -061 \} -062 \} -063 -064 /* now we proceed to zero successive digits -065 * from the least significant upwards -066 */ -067 for (ix = 0; ix < n->used; ix++) \{ -068 /* mu = ai * m' mod b -069 * -070 * We avoid a double precision multiplication (which isn't required) -071 * by casting the value down to a mp_digit. Note this requires -072 * that W[ix-1] have the carry cleared (see after the inner loop) -073 */ -074 register mp_digit mu; -075 mu = (mp_digit) (((W[ix] & MP_MASK) * rho) & MP_MASK); -076 -077 /* a = a + mu * m * b**i -078 * -079 * This is computed in place and on the fly. The multiplication -080 * by b**i is handled by offseting which columns the results -081 * are added to. -082 * -083 * Note the comba method normally doesn't handle carries in the -084 * inner loop In this case we fix the carry from the previous -085 * column since the Montgomery reduction requires digits of the -086 * result (so far) [see above] to work. This is -087 * handled by fixing up one carry after the inner loop. The -088 * carry fixups are done in order so after these loops the -089 * first m->used words of W[] have the carries fixed -090 */ -091 \{ -092 register int iy; -093 register mp_digit *tmpn; -094 register mp_word *_W; -095 -096 /* alias for the digits of the modulus */ -097 tmpn = n->dp; -098 -099 /* Alias for the columns set by an offset of ix */ -100 _W = W + ix; -101 -102 /* inner loop */ -103 for (iy = 0; iy < n->used; iy++) \{ -104 *_W++ += ((mp_word)mu) * ((mp_word)*tmpn++); -105 \} -106 \} -107 -108 /* now fix carry for next digit, W[ix+1] */ -109 W[ix + 1] += W[ix] >> ((mp_word) DIGIT_BIT); -110 \} -111 -112 /* now we have to propagate the carries and -113 * shift the words downward [all those least -114 * significant digits we zeroed]. -115 */ -116 \{ -117 register mp_digit *tmpx; -118 register mp_word *_W, *_W1; -119 -120 /* nox fix rest of carries */ -121 -122 /* alias for current word */ -123 _W1 = W + ix; -124 -125 /* alias for next word, where the carry goes */ -126 _W = W + ++ix; -127 -128 for (; ix <= n->used * 2 + 1; ix++) \{ -129 *_W++ += *_W1++ >> ((mp_word) DIGIT_BIT); -130 \} -131 -132 /* copy out, A = A/b**n -133 * -134 * The result is A/b**n but instead of converting from an -135 * array of mp_word to mp_digit than calling mp_rshd -136 * we just copy them in the right order -137 */ -138 -139 /* alias for destination word */ -140 tmpx = x->dp; -141 -142 /* alias for shifted double precision result */ -143 _W = W + n->used; -144 -145 for (ix = 0; ix < n->used + 1; ix++) \{ -146 *tmpx++ = (mp_digit)(*_W++ & ((mp_word) MP_MASK)); -147 \} -148 -149 /* zero oldused digits, if the input a was larger than -150 * m->used+1 we'll have to clear the digits -151 */ -152 for (; ix < olduse; ix++) \{ -153 *tmpx++ = 0; -154 \} -155 \} -156 -157 /* set the max used and clamp */ -158 x->used = n->used + 1; -159 mp_clamp (x); -160 -161 /* if A >= m then A = A - m */ -162 if (mp_cmp_mag (x, n) != MP_LT) \{ -163 return s_mp_sub (x, n, x); -164 \} -165 return MP_OKAY; -166 \} -167 #endif -168 \end{alltt} \end{small} -The $\hat W$ array is first filled with digits of $x$ on line 50 then the rest of the digits are zeroed on line 54. Both loops share +The $\hat W$ array is first filled with digits of $x$ on line 48 then the rest of the digits are zeroed on line 55. Both loops share the same alias variables to make the code easier to read. The value of $\mu$ is calculated in an interesting fashion. First the value $\hat W_{ix}$ is reduced modulo $\beta$ and cast to a mp\_digit. This -forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line 109 fixes the carry +forces the compiler to use a single precision multiplication and prevents any concerns about loss of precision. Line 110 fixes the carry for the next iteration of the loop by propagating the carry from $\hat W_{ix}$ to $\hat W_{ix+1}$. -The for loop on line 108 propagates the rest of the carries upwards through the columns. The for loop on line 125 reduces the columns +The for loop on line 109 propagates the rest of the carries upwards through the columns. The for loop on line 126 reduces the columns modulo $\beta$ and shifts them $k$ places at the same time. The alias $\_ \hat W$ actually refers to the array $\hat W$ starting at the $n.used$'th digit, that is $\_ \hat W_{t} = \hat W_{n.used + t}$. @@ -6564,46 +4255,6 @@ to calculate $1/n_0$ when $\beta$ is a power of two. \hspace{-5.1mm}{\bf File}: bn\_mp\_montgomery\_setup.c \vspace{-3mm} \begin{alltt} -016 -017 /* setups the montgomery reduction stuff */ -018 int -019 mp_montgomery_setup (mp_int * n, mp_digit * rho) -020 \{ -021 mp_digit x, b; -022 -023 /* fast inversion mod 2**k -024 * -025 * Based on the fact that -026 * -027 * XA = 1 (mod 2**n) => (X(2-XA)) A = 1 (mod 2**2n) -028 * => 2*X*A - X*X*A*A = 1 -029 * => 2*(1) - (1) = 1 -030 */ -031 b = n->dp[0]; -032 -033 if ((b & 1) == 0) \{ -034 return MP_VAL; -035 \} -036 -037 x = (((b + 2) & 4) << 1) + b; /* here x*a==1 mod 2**4 */ -038 x *= 2 - b * x; /* here x*a==1 mod 2**8 */ -039 #if !defined(MP_8BIT) -040 x *= 2 - b * x; /* here x*a==1 mod 2**16 */ -041 #endif -042 #if defined(MP_64BIT) || !(defined(MP_8BIT) || defined(MP_16BIT)) -043 x *= 2 - b * x; /* here x*a==1 mod 2**32 */ -044 #endif -045 #ifdef MP_64BIT -046 x *= 2 - b * x; /* here x*a==1 mod 2**64 */ -047 #endif -048 -049 /* rho = -1/m mod b */ -050 *rho = (((mp_word)1 << ((mp_word) DIGIT_BIT)) - x) & MP_MASK; -051 -052 return MP_OKAY; -053 \} -054 #endif -055 \end{alltt} \end{small} @@ -6796,97 +4447,22 @@ at step 3. \hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_reduce.c \vspace{-3mm} \begin{alltt} -016 -017 /* reduce "x" in place modulo "n" using the Diminished Radix algorithm. -018 * -019 * Based on algorithm from the paper -020 * -021 * "Generating Efficient Primes for Discrete Log Cryptosystems" -022 * Chae Hoon Lim, Pil Joong Lee, -023 * POSTECH Information Research Laboratories -024 * -025 * The modulus must be of a special format [see manual] -026 * -027 * Has been modified to use algorithm 7.10 from the LTM book instead -028 * -029 * Input x must be in the range 0 <= x <= (n-1)**2 -030 */ -031 int -032 mp_dr_reduce (mp_int * x, mp_int * n, mp_digit k) -033 \{ -034 int err, i, m; -035 mp_word r; -036 mp_digit mu, *tmpx1, *tmpx2; -037 -038 /* m = digits in modulus */ -039 m = n->used; -040 -041 /* ensure that "x" has at least 2m digits */ -042 if (x->alloc < m + m) \{ -043 if ((err = mp_grow (x, m + m)) != MP_OKAY) \{ -044 return err; -045 \} -046 \} -047 -048 /* top of loop, this is where the code resumes if -049 * another reduction pass is required. -050 */ -051 top: -052 /* aliases for digits */ -053 /* alias for lower half of x */ -054 tmpx1 = x->dp; -055 -056 /* alias for upper half of x, or x/B**m */ -057 tmpx2 = x->dp + m; -058 -059 /* set carry to zero */ -060 mu = 0; -061 -062 /* compute (x mod B**m) + k * [x/B**m] inline and inplace */ -063 for (i = 0; i < m; i++) \{ -064 r = ((mp_word)*tmpx2++) * ((mp_word)k) + *tmpx1 + mu; -065 *tmpx1++ = (mp_digit)(r & MP_MASK); -066 mu = (mp_digit)(r >> ((mp_word)DIGIT_BIT)); -067 \} -068 -069 /* set final carry */ -070 *tmpx1++ = mu; -071 -072 /* zero words above m */ -073 for (i = m + 1; i < x->used; i++) \{ -074 *tmpx1++ = 0; -075 \} -076 -077 /* clamp, sub and return */ -078 mp_clamp (x); -079 -080 /* if x >= n then subtract and reduce again -081 * Each successive "recursion" makes the input smaller and smaller. -082 */ -083 if (mp_cmp_mag (x, n) != MP_LT) \{ -084 s_mp_sub(x, n, x); -085 goto top; -086 \} -087 return MP_OKAY; -088 \} -089 #endif -090 \end{alltt} \end{small} -The first step is to grow $x$ as required to $2m$ digits since the reduction is performed in place on $x$. The label on line 51 is where +The first step is to grow $x$ as required to $2m$ digits since the reduction is performed in place on $x$. The label on line 52 is where the algorithm will resume if further reduction passes are required. In theory it could be placed at the top of the function however, the size of the modulus and question of whether $x$ is large enough are invariant after the first pass meaning that it would be a waste of time. The aliases $tmpx1$ and $tmpx2$ refer to the digits of $x$ where the latter is offset by $m$ digits. By reading digits from $x$ offset by $m$ digits -a division by $\beta^m$ can be simulated virtually for free. The loop on line 63 performs the bulk of the work (\textit{corresponds to step 4 of algorithm 7.11}) +a division by $\beta^m$ can be simulated virtually for free. The loop on line 64 performs the bulk of the work (\textit{corresponds to step 4 of algorithm 7.11}) in this algorithm. -By line 70 the pointer $tmpx1$ points to the $m$'th digit of $x$ which is where the final carry will be placed. Similarly by line 73 the +By line 67 the pointer $tmpx1$ points to the $m$'th digit of $x$ which is where the final carry will be placed. Similarly by line 74 the same pointer will point to the $m+1$'th digit where the zeroes will be placed. Since the algorithm is only valid if both $x$ and $n$ are greater than zero an unsigned comparison suffices to determine if another pass is required. -With the same logic at line 84 the value of $x$ is known to be greater than or equal to $n$ meaning that an unsigned subtraction can be used +With the same logic at line 81 the value of $x$ is known to be greater than or equal to $n$ meaning that an unsigned subtraction can be used as well. Since the destination of the subtraction is the larger of the inputs the call to algorithm s\_mp\_sub cannot fail and the return code does not need to be checked. @@ -6914,19 +4490,6 @@ completeness. \hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_setup.c \vspace{-3mm} \begin{alltt} -016 -017 /* determines the setup value */ -018 void mp_dr_setup(mp_int *a, mp_digit *d) -019 \{ -020 /* the casts are required if DIGIT_BIT is one less than -021 * the number of bits in a mp_digit [e.g. DIGIT_BIT==31] -022 */ -023 *d = (mp_digit)((((mp_word)1) << ((mp_word)DIGIT_BIT)) - -024 ((mp_word)a->dp[0])); -025 \} -026 -027 #endif -028 \end{alltt} \end{small} @@ -6962,30 +4525,6 @@ step 3 then $n$ must be of Diminished Radix form. \hspace{-5.1mm}{\bf File}: bn\_mp\_dr\_is\_modulus.c \vspace{-3mm} \begin{alltt} -016 -017 /* determines if a number is a valid DR modulus */ -018 int mp_dr_is_modulus(mp_int *a) -019 \{ -020 int ix; -021 -022 /* must be at least two digits */ -023 if (a->used < 2) \{ -024 return 0; -025 \} -026 -027 /* must be of the form b**k - a [a <= b] so all -028 * but the first digit must be equal to -1 (mod b). -029 */ -030 for (ix = 1; ix < a->used; ix++) \{ -031 if (a->dp[ix] != MP_MASK) \{ -032 return 0; -033 \} -034 \} -035 return 1; -036 \} -037 -038 #endif -039 \end{alltt} \end{small} @@ -7029,53 +4568,11 @@ shift which makes the algorithm fairly inexpensive to use. \hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_2k.c \vspace{-3mm} \begin{alltt} -016 -017 /* reduces a modulo n where n is of the form 2**p - d */ -018 int mp_reduce_2k(mp_int *a, mp_int *n, mp_digit d) -019 \{ -020 mp_int q; -021 int p, res; -022 -023 if ((res = mp_init(&q)) != MP_OKAY) \{ -024 return res; -025 \} -026 -027 p = mp_count_bits(n); -028 top: -029 /* q = a/2**p, a = a mod 2**p */ -030 if ((res = mp_div_2d(a, p, &q, a)) != MP_OKAY) \{ -031 goto ERR; -032 \} -033 -034 if (d != 1) \{ -035 /* q = q * d */ -036 if ((res = mp_mul_d(&q, d, &q)) != MP_OKAY) \{ -037 goto ERR; -038 \} -039 \} -040 -041 /* a = a + q */ -042 if ((res = s_mp_add(a, &q, a)) != MP_OKAY) \{ -043 goto ERR; -044 \} -045 -046 if (mp_cmp_mag(a, n) != MP_LT) \{ -047 s_mp_sub(a, n, a); -048 goto top; -049 \} -050 -051 ERR: -052 mp_clear(&q); -053 return res; -054 \} -055 -056 #endif -057 \end{alltt} \end{small} The algorithm mp\_count\_bits calculates the number of bits in an mp\_int which is used to find the initial value of $p$. The call to mp\_div\_2d -on line 30 calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size +on line 31 calculates both the quotient $q$ and the remainder $a$ required. By doing both in a single function call the code size is kept fairly small. The multiplication by $k$ is only performed if $k > 1$. This allows reductions modulo $2^p - 1$ to be performed without any multiplications. @@ -7113,34 +4610,6 @@ is sufficient to solve for $k$. Alternatively if $n$ has more than one digit th \hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_2k\_setup.c \vspace{-3mm} \begin{alltt} -016 -017 /* determines the setup value */ -018 int mp_reduce_2k_setup(mp_int *a, mp_digit *d) -019 \{ -020 int res, p; -021 mp_int tmp; -022 -023 if ((res = mp_init(&tmp)) != MP_OKAY) \{ -024 return res; -025 \} -026 -027 p = mp_count_bits(a); -028 if ((res = mp_2expt(&tmp, p)) != MP_OKAY) \{ -029 mp_clear(&tmp); -030 return res; -031 \} -032 -033 if ((res = s_mp_sub(&tmp, a, &tmp)) != MP_OKAY) \{ -034 mp_clear(&tmp); -035 return res; -036 \} -037 -038 *d = tmp.dp[0]; -039 mp_clear(&tmp); -040 return MP_OKAY; -041 \} -042 #endif -043 \end{alltt} \end{small} @@ -7185,39 +4654,6 @@ This algorithm quickly determines if a modulus is of the form required for algor \hspace{-5.1mm}{\bf File}: bn\_mp\_reduce\_is\_2k.c \vspace{-3mm} \begin{alltt} -016 -017 /* determines if mp_reduce_2k can be used */ -018 int mp_reduce_is_2k(mp_int *a) -019 \{ -020 int ix, iy, iw; -021 mp_digit iz; -022 -023 if (a->used == 0) \{ -024 return MP_NO; -025 \} else if (a->used == 1) \{ -026 return MP_YES; -027 \} else if (a->used > 1) \{ -028 iy = mp_count_bits(a); -029 iz = 1; -030 iw = 1; -031 -032 /* Test every bit from the second digit up, must be 1 */ -033 for (ix = DIGIT_BIT; ix < iy; ix++) \{ -034 if ((a->dp[iw] & iz) == 0) \{ -035 return MP_NO; -036 \} -037 iz <<= 1; -038 if (iz > (mp_digit)MP_MASK) \{ -039 ++iw; -040 iz = 1; -041 \} -042 \} -043 \} -044 return MP_YES; -045 \} -046 -047 #endif -048 \end{alltt} \end{small} @@ -7390,51 +4826,13 @@ iteration of the loop moves the bits of the exponent $b$ upwards to the most sig \hspace{-5.1mm}{\bf File}: bn\_mp\_expt\_d.c \vspace{-3mm} \begin{alltt} -016 -017 /* calculate c = a**b using a square-multiply algorithm */ -018 int mp_expt_d (mp_int * a, mp_digit b, mp_int * c) -019 \{ -020 int res, x; -021 mp_int g; -022 -023 if ((res = mp_init_copy (&g, a)) != MP_OKAY) \{ -024 return res; -025 \} -026 -027 /* set initial result */ -028 mp_set (c, 1); -029 -030 for (x = 0; x < (int) DIGIT_BIT; x++) \{ -031 /* square */ -032 if ((res = mp_sqr (c, c)) != MP_OKAY) \{ -033 mp_clear (&g); -034 return res; -035 \} -036 -037 /* if the bit is set multiply */ -038 if ((b & (mp_digit) (((mp_digit)1) << (DIGIT_BIT - 1))) != 0) \{ -039 if ((res = mp_mul (c, &g, c)) != MP_OKAY) \{ -040 mp_clear (&g); -041 return res; -042 \} -043 \} -044 -045 /* shift to next bit */ -046 b <<= 1; -047 \} -048 -049 mp_clear (&g); -050 return MP_OKAY; -051 \} -052 #endif -053 \end{alltt} \end{small} -Line 28 sets the initial value of the result to $1$. Next the loop on line 30 steps through each bit of the exponent starting from -the most significant down towards the least significant. The invariant squaring operation placed on line 32 is performed first. After +Line 29 sets the initial value of the result to $1$. Next the loop on line 31 steps through each bit of the exponent starting from +the most significant down towards the least significant. The invariant squaring operation placed on line 33 is performed first. After the squaring the result $c$ is multiplied by the base $g$ if and only if the most significant bit of the exponent is set. The shift on line -46 moves all of the bits of the exponent upwards towards the most significant location. +47 moves all of the bits of the exponent upwards towards the most significant location. \section{$k$-ary Exponentiation} When calculating an exponentiation the most time consuming bottleneck is the multiplications which are in general a small factor @@ -7615,110 +5013,16 @@ algorithm since their arguments are essentially the same (\textit{two mp\_ints a \hspace{-5.1mm}{\bf File}: bn\_mp\_exptmod.c \vspace{-3mm} \begin{alltt} -016 -017 -018 /* this is a shell function that calls either the normal or Montgomery -019 * exptmod functions. Originally the call to the montgomery code was -020 * embedded in the normal function but that wasted alot of stack space -021 * for nothing (since 99% of the time the Montgomery code would be called) -022 */ -023 int mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y) -024 \{ -025 int dr; -026 -027 /* modulus P must be positive */ -028 if (P->sign == MP_NEG) \{ -029 return MP_VAL; -030 \} -031 -032 /* if exponent X is negative we have to recurse */ -033 if (X->sign == MP_NEG) \{ -034 #ifdef BN_MP_INVMOD_C -035 mp_int tmpG, tmpX; -036 int err; -037 -038 /* first compute 1/G mod P */ -039 if ((err = mp_init(&tmpG)) != MP_OKAY) \{ -040 return err; -041 \} -042 if ((err = mp_invmod(G, P, &tmpG)) != MP_OKAY) \{ -043 mp_clear(&tmpG); -044 return err; -045 \} -046 -047 /* now get |X| */ -048 if ((err = mp_init(&tmpX)) != MP_OKAY) \{ -049 mp_clear(&tmpG); -050 return err; -051 \} -052 if ((err = mp_abs(X, &tmpX)) != MP_OKAY) \{ -053 mp_clear_multi(&tmpG, &tmpX, NULL); -054 return err; -055 \} -056 -057 /* and now compute (1/G)**|X| instead of G**X [X < 0] */ -058 err = mp_exptmod(&tmpG, &tmpX, P, Y); -059 mp_clear_multi(&tmpG, &tmpX, NULL); -060 return err; -061 #else -062 /* no invmod */ -063 return MP_VAL; -064 #endif -065 \} -066 -067 /* modified diminished radix reduction */ -068 #if defined(BN_MP_REDUCE_IS_2K_L_C) && defined(BN_MP_REDUCE_2K_L_C) && defin - ed(BN_S_MP_EXPTMOD_C) -069 if (mp_reduce_is_2k_l(P) == MP_YES) \{ -070 return s_mp_exptmod(G, X, P, Y, 1); -071 \} -072 #endif -073 -074 #ifdef BN_MP_DR_IS_MODULUS_C -075 /* is it a DR modulus? */ -076 dr = mp_dr_is_modulus(P); -077 #else -078 /* default to no */ -079 dr = 0; -080 #endif -081 -082 #ifdef BN_MP_REDUCE_IS_2K_C -083 /* if not, is it a unrestricted DR modulus? */ -084 if (dr == 0) \{ -085 dr = mp_reduce_is_2k(P) << 1; -086 \} -087 #endif -088 -089 /* if the modulus is odd or dr != 0 use the montgomery method */ -090 #ifdef BN_MP_EXPTMOD_FAST_C -091 if (mp_isodd (P) == 1 || dr != 0) \{ -092 return mp_exptmod_fast (G, X, P, Y, dr); -093 \} else \{ -094 #endif -095 #ifdef BN_S_MP_EXPTMOD_C -096 /* otherwise use the generic Barrett reduction technique */ -097 return s_mp_exptmod (G, X, P, Y, 0); -098 #else -099 /* no exptmod for evens */ -100 return MP_VAL; -101 #endif -102 #ifdef BN_MP_EXPTMOD_FAST_C -103 \} -104 #endif -105 \} -106 -107 #endif -108 \end{alltt} \end{small} -In order to keep the algorithms in a known state the first step on line 28 is to reject any negative modulus as input. If the exponent is +In order to keep the algorithms in a known state the first step on line 29 is to reject any negative modulus as input. If the exponent is negative the algorithm tries to perform a modular exponentiation with the modular inverse of the base $G$. The temporary variable $tmpG$ is assigned the modular inverse of $G$ and $tmpX$ is assigned the absolute value of $X$. The algorithm will recuse with these new values with a positive exponent. -If the exponent is positive the algorithm resumes the exponentiation. Line 76 determines if the modulus is of the restricted Diminished Radix -form. If it is not line 69 attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one +If the exponent is positive the algorithm resumes the exponentiation. Line 77 determines if the modulus is of the restricted Diminished Radix +form. If it is not line 70 attempts to determine if it is of a unrestricted Diminished Radix form. The integer $dr$ will take on one of three values. \begin{enumerate} @@ -7888,252 +5192,18 @@ a Left-to-Right algorithm is used to process the remaining few bits. \hspace{-5.1mm}{\bf File}: bn\_s\_mp\_exptmod.c \vspace{-3mm} \begin{alltt} -016 #ifdef MP_LOW_MEM -017 #define TAB_SIZE 32 -018 #else -019 #define TAB_SIZE 256 -020 #endif -021 -022 int s_mp_exptmod (mp_int * G, mp_int * X, mp_int * P, mp_int * Y, int redmod - e) -023 \{ -024 mp_int M[TAB_SIZE], res, mu; -025 mp_digit buf; -026 int err, bitbuf, bitcpy, bitcnt, mode, digidx, x, y, winsize; -027 int (*redux)(mp_int*,mp_int*,mp_int*); -028 -029 /* find window size */ -030 x = mp_count_bits (X); -031 if (x <= 7) \{ -032 winsize = 2; -033 \} else if (x <= 36) \{ -034 winsize = 3; -035 \} else if (x <= 140) \{ -036 winsize = 4; -037 \} else if (x <= 450) \{ -038 winsize = 5; -039 \} else if (x <= 1303) \{ -040 winsize = 6; -041 \} else if (x <= 3529) \{ -042 winsize = 7; -043 \} else \{ -044 winsize = 8; -045 \} -046 -047 #ifdef MP_LOW_MEM -048 if (winsize > 5) \{ -049 winsize = 5; -050 \} -051 #endif -052 -053 /* init M array */ -054 /* init first cell */ -055 if ((err = mp_init(&M[1])) != MP_OKAY) \{ -056 return err; -057 \} -058 -059 /* now init the second half of the array */ -060 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -061 if ((err = mp_init(&M[x])) != MP_OKAY) \{ -062 for (y = 1<<(winsize-1); y < x; y++) \{ -063 mp_clear (&M[y]); -064 \} -065 mp_clear(&M[1]); -066 return err; -067 \} -068 \} -069 -070 /* create mu, used for Barrett reduction */ -071 if ((err = mp_init (&mu)) != MP_OKAY) \{ -072 goto LBL_M; -073 \} -074 -075 if (redmode == 0) \{ -076 if ((err = mp_reduce_setup (&mu, P)) != MP_OKAY) \{ -077 goto LBL_MU; -078 \} -079 redux = mp_reduce; -080 \} else \{ -081 if ((err = mp_reduce_2k_setup_l (P, &mu)) != MP_OKAY) \{ -082 goto LBL_MU; -083 \} -084 redux = mp_reduce_2k_l; -085 \} -086 -087 /* create M table -088 * -089 * The M table contains powers of the base, -090 * e.g. M[x] = G**x mod P -091 * -092 * The first half of the table is not -093 * computed though accept for M[0] and M[1] -094 */ -095 if ((err = mp_mod (G, P, &M[1])) != MP_OKAY) \{ -096 goto LBL_MU; -097 \} -098 -099 /* compute the value at M[1<<(winsize-1)] by squaring -100 * M[1] (winsize-1) times -101 */ -102 if ((err = mp_copy (&M[1], &M[1 << (winsize - 1)])) != MP_OKAY) \{ -103 goto LBL_MU; -104 \} -105 -106 for (x = 0; x < (winsize - 1); x++) \{ -107 /* square it */ -108 if ((err = mp_sqr (&M[1 << (winsize - 1)], -109 &M[1 << (winsize - 1)])) != MP_OKAY) \{ -110 goto LBL_MU; -111 \} -112 -113 /* reduce modulo P */ -114 if ((err = redux (&M[1 << (winsize - 1)], P, &mu)) != MP_OKAY) \{ -115 goto LBL_MU; -116 \} -117 \} -118 -119 /* create upper table, that is M[x] = M[x-1] * M[1] (mod P) -120 * for x = (2**(winsize - 1) + 1) to (2**winsize - 1) -121 */ -122 for (x = (1 << (winsize - 1)) + 1; x < (1 << winsize); x++) \{ -123 if ((err = mp_mul (&M[x - 1], &M[1], &M[x])) != MP_OKAY) \{ -124 goto LBL_MU; -125 \} -126 if ((err = redux (&M[x], P, &mu)) != MP_OKAY) \{ -127 goto LBL_MU; -128 \} -129 \} -130 -131 /* setup result */ -132 if ((err = mp_init (&res)) != MP_OKAY) \{ -133 goto LBL_MU; -134 \} -135 mp_set (&res, 1); -136 -137 /* set initial mode and bit cnt */ -138 mode = 0; -139 bitcnt = 1; -140 buf = 0; -141 digidx = X->used - 1; -142 bitcpy = 0; -143 bitbuf = 0; -144 -145 for (;;) \{ -146 /* grab next digit as required */ -147 if (--bitcnt == 0) \{ -148 /* if digidx == -1 we are out of digits */ -149 if (digidx == -1) \{ -150 break; -151 \} -152 /* read next digit and reset the bitcnt */ -153 buf = X->dp[digidx--]; -154 bitcnt = (int) DIGIT_BIT; -155 \} -156 -157 /* grab the next msb from the exponent */ -158 y = (buf >> (mp_digit)(DIGIT_BIT - 1)) & 1; -159 buf <<= (mp_digit)1; -160 -161 /* if the bit is zero and mode == 0 then we ignore it -162 * These represent the leading zero bits before the first 1 bit -163 * in the exponent. Technically this opt is not required but it -164 * does lower the # of trivial squaring/reductions used -165 */ -166 if (mode == 0 && y == 0) \{ -167 continue; -168 \} -169 -170 /* if the bit is zero and mode == 1 then we square */ -171 if (mode == 1 && y == 0) \{ -172 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -173 goto LBL_RES; -174 \} -175 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -176 goto LBL_RES; -177 \} -178 continue; -179 \} -180 -181 /* else we add it to the window */ -182 bitbuf |= (y << (winsize - ++bitcpy)); -183 mode = 2; -184 -185 if (bitcpy == winsize) \{ -186 /* ok window is filled so square as required and multiply */ -187 /* square first */ -188 for (x = 0; x < winsize; x++) \{ -189 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -190 goto LBL_RES; -191 \} -192 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -193 goto LBL_RES; -194 \} -195 \} -196 -197 /* then multiply */ -198 if ((err = mp_mul (&res, &M[bitbuf], &res)) != MP_OKAY) \{ -199 goto LBL_RES; -200 \} -201 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -202 goto LBL_RES; -203 \} -204 -205 /* empty window and reset */ -206 bitcpy = 0; -207 bitbuf = 0; -208 mode = 1; -209 \} -210 \} -211 -212 /* if bits remain then square/multiply */ -213 if (mode == 2 && bitcpy > 0) \{ -214 /* square then multiply if the bit is set */ -215 for (x = 0; x < bitcpy; x++) \{ -216 if ((err = mp_sqr (&res, &res)) != MP_OKAY) \{ -217 goto LBL_RES; -218 \} -219 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -220 goto LBL_RES; -221 \} -222 -223 bitbuf <<= 1; -224 if ((bitbuf & (1 << winsize)) != 0) \{ -225 /* then multiply */ -226 if ((err = mp_mul (&res, &M[1], &res)) != MP_OKAY) \{ -227 goto LBL_RES; -228 \} -229 if ((err = redux (&res, P, &mu)) != MP_OKAY) \{ -230 goto LBL_RES; -231 \} -232 \} -233 \} -234 \} -235 -236 mp_exch (&res, Y); -237 err = MP_OKAY; -238 LBL_RES:mp_clear (&res); -239 LBL_MU:mp_clear (&mu); -240 LBL_M: -241 mp_clear(&M[1]); -242 for (x = 1<<(winsize-1); x < (1 << winsize); x++) \{ -243 mp_clear (&M[x]); -244 \} -245 return err; -246 \} -247 #endif -248 \end{alltt} \end{small} -Lines 31 through 41 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted +Lines 32 through 46 determine the optimal window size based on the length of the exponent in bits. The window divisions are sorted from smallest to greatest so that in each \textbf{if} statement only one condition must be tested. For example, by the \textbf{if} statement -on line 33 the value of $x$ is already known to be greater than $140$. +on line 38 the value of $x$ is already known to be greater than $140$. -The conditional piece of code beginning on line 47 allows the window size to be restricted to five bits. This logic is used to ensure +The conditional piece of code beginning on line 48 allows the window size to be restricted to five bits. This logic is used to ensure the table of precomputed powers of $G$ remains relatively small. -The for loop on line 60 initializes the $M$ array while lines 61 and 76 compute the value of $\mu$ required for -Barrett reduction. +The for loop on line 61 initializes the $M$ array while lines 72 and 77 through 86 initialize the reduction +function that will be used for this modulus. -- More later. @@ -8167,35 +5237,6 @@ equivalent to $m \cdot 2^k$. By this logic when $m = 1$ a quick power of two ca \hspace{-5.1mm}{\bf File}: bn\_mp\_2expt.c \vspace{-3mm} \begin{alltt} -016 -017 /* computes a = 2**b -018 * -019 * Simple algorithm which zeroes the int, grows it then just sets one bit -020 * as required. -021 */ -022 int -023 mp_2expt (mp_int * a, int b) -024 \{ -025 int res; -026 -027 /* zero a as per default */ -028 mp_zero (a); -029 -030 /* grow a to accomodate the single bit */ -031 if ((res = mp_grow (a, b / DIGIT_BIT + 1)) != MP_OKAY) \{ -032 return res; -033 \} -034 -035 /* set the used count of where the bit will go */ -036 a->used = b / DIGIT_BIT + 1; -037 -038 /* put the single bit in its place */ -039 a->dp[b / DIGIT_BIT] = ((mp_digit)1) << (b % DIGIT_BIT); -040 -041 return MP_OKAY; -042 \} -043 #endif -044 \end{alltt} \end{small} @@ -8444,279 +5485,6 @@ respectively be replaced with a zero. \hspace{-5.1mm}{\bf File}: bn\_mp\_div.c \vspace{-3mm} \begin{alltt} -016 -017 #ifdef BN_MP_DIV_SMALL -018 -019 /* slower bit-bang division... also smaller */ -020 int mp_div(mp_int * a, mp_int * b, mp_int * c, mp_int * d) -021 \{ -022 mp_int ta, tb, tq, q; -023 int res, n, n2; -024 -025 /* is divisor zero ? */ -026 if (mp_iszero (b) == 1) \{ -027 return MP_VAL; -028 \} -029 -030 /* if a < b then q=0, r = a */ -031 if (mp_cmp_mag (a, b) == MP_LT) \{ -032 if (d != NULL) \{ -033 res = mp_copy (a, d); -034 \} else \{ -035 res = MP_OKAY; -036 \} -037 if (c != NULL) \{ -038 mp_zero (c); -039 \} -040 return res; -041 \} -042 -043 /* init our temps */ -044 if ((res = mp_init_multi(&ta, &tb, &tq, &q, NULL) != MP_OKAY)) \{ -045 return res; -046 \} -047 -048 -049 mp_set(&tq, 1); -050 n = mp_count_bits(a) - mp_count_bits(b); -051 if (((res = mp_abs(a, &ta)) != MP_OKAY) || -052 ((res = mp_abs(b, &tb)) != MP_OKAY) || -053 ((res = mp_mul_2d(&tb, n, &tb)) != MP_OKAY) || -054 ((res = mp_mul_2d(&tq, n, &tq)) != MP_OKAY)) \{ -055 goto LBL_ERR; -056 \} -057 -058 while (n-- >= 0) \{ -059 if (mp_cmp(&tb, &ta) != MP_GT) \{ -060 if (((res = mp_sub(&ta, &tb, &ta)) != MP_OKAY) || -061 ((res = mp_add(&q, &tq, &q)) != MP_OKAY)) \{ -062 goto LBL_ERR; -063 \} -064 \} -065 if (((res = mp_div_2d(&tb, 1, &tb, NULL)) != MP_OKAY) || -066 ((res = mp_div_2d(&tq, 1, &tq, NULL)) != MP_OKAY)) \{ -067 goto LBL_ERR; -068 \} -069 \} -070 -071 /* now q == quotient and ta == remainder */ -072 n = a->sign; -073 n2 = (a->sign == b->sign ? MP_ZPOS : MP_NEG); -074 if (c != NULL) \{ -075 mp_exch(c, &q); -076 c->sign = (mp_iszero(c) == MP_YES) ? MP_ZPOS : n2; -077 \} -078 if (d != NULL) \{ -079 mp_exch(d, &ta); -080 d->sign = (mp_iszero(d) == MP_YES) ? MP_ZPOS : n; -081 \} -082 LBL_ERR: -083 mp_clear_multi(&ta, &tb, &tq, &q, NULL); -084 return res; -085 \} -086 -087 #else -088 -089 /* integer signed division. -090 * c*b + d == a [e.g. a/b, c=quotient, d=remainder] -091 * HAC pp.598 Algorithm 14.20 -092 * -093 * Note that the description in HAC is horribly -094 * incomplete. For example, it doesn't consider -095 * the case where digits are removed from 'x' in -096 * the inner loop. It also doesn't consider the -097 * case that y has fewer than three digits, etc.. -098 * -099 * The overall algorithm is as described as -100 * 14.20 from HAC but fixed to treat these cases. -101 */ -102 int mp_div (mp_int * a, mp_int * b, mp_int * c, mp_int * d) -103 \{ -104 mp_int q, x, y, t1, t2; -105 int res, n, t, i, norm, neg; -106 -107 /* is divisor zero ? */ -108 if (mp_iszero (b) == 1) \{ -109 return MP_VAL; -110 \} -111 -112 /* if a < b then q=0, r = a */ -113 if (mp_cmp_mag (a, b) == MP_LT) \{ -114 if (d != NULL) \{ -115 res = mp_copy (a, d); -116 \} else \{ -117 res = MP_OKAY; -118 \} -119 if (c != NULL) \{ -120 mp_zero (c); -121 \} -122 return res; -123 \} -124 -125 if ((res = mp_init_size (&q, a->used + 2)) != MP_OKAY) \{ -126 return res; -127 \} -128 q.used = a->used + 2; -129 -130 if ((res = mp_init (&t1)) != MP_OKAY) \{ -131 goto LBL_Q; -132 \} -133 -134 if ((res = mp_init (&t2)) != MP_OKAY) \{ -135 goto LBL_T1; -136 \} -137 -138 if ((res = mp_init_copy (&x, a)) != MP_OKAY) \{ -139 goto LBL_T2; -140 \} -141 -142 if ((res = mp_init_copy (&y, b)) != MP_OKAY) \{ -143 goto LBL_X; -144 \} -145 -146 /* fix the sign */ -147 neg = (a->sign == b->sign) ? MP_ZPOS : MP_NEG; -148 x.sign = y.sign = MP_ZPOS; -149 -150 /* normalize both x and y, ensure that y >= b/2, [b == 2**DIGIT_BIT] */ -151 norm = mp_count_bits(&y) % DIGIT_BIT; -152 if (norm < (int)(DIGIT_BIT-1)) \{ -153 norm = (DIGIT_BIT-1) - norm; -154 if ((res = mp_mul_2d (&x, norm, &x)) != MP_OKAY) \{ -155 goto LBL_Y; -156 \} -157 if ((res = mp_mul_2d (&y, norm, &y)) != MP_OKAY) \{ -158 goto LBL_Y; -159 \} -160 \} else \{ -161 norm = 0; -162 \} -163 -164 /* note hac does 0 based, so if used==5 then its 0,1,2,3,4, e.g. use 4 */ -165 n = x.used - 1; -166 t = y.used - 1; -167 -168 /* while (x >= y*b**n-t) do \{ q[n-t] += 1; x -= y*b**\{n-t\} \} */ -169 if ((res = mp_lshd (&y, n - t)) != MP_OKAY) \{ /* y = y*b**\{n-t\} */ -170 goto LBL_Y; -171 \} -172 -173 while (mp_cmp (&x, &y) != MP_LT) \{ -174 ++(q.dp[n - t]); -175 if ((res = mp_sub (&x, &y, &x)) != MP_OKAY) \{ -176 goto LBL_Y; -177 \} -178 \} -179 -180 /* reset y by shifting it back down */ -181 mp_rshd (&y, n - t); -182 -183 /* step 3. for i from n down to (t + 1) */ -184 for (i = n; i >= (t + 1); i--) \{ -185 if (i > x.used) \{ -186 continue; -187 \} -188 -189 /* step 3.1 if xi == yt then set q\{i-t-1\} to b-1, -190 * otherwise set q\{i-t-1\} to (xi*b + x\{i-1\})/yt */ -191 if (x.dp[i] == y.dp[t]) \{ -192 q.dp[i - t - 1] = ((((mp_digit)1) << DIGIT_BIT) - 1); -193 \} else \{ -194 mp_word tmp; -195 tmp = ((mp_word) x.dp[i]) << ((mp_word) DIGIT_BIT); -196 tmp |= ((mp_word) x.dp[i - 1]); -197 tmp /= ((mp_word) y.dp[t]); -198 if (tmp > (mp_word) MP_MASK) -199 tmp = MP_MASK; -200 q.dp[i - t - 1] = (mp_digit) (tmp & (mp_word) (MP_MASK)); -201 \} -202 -203 /* while (q\{i-t-1\} * (yt * b + y\{t-1\})) > -204 xi * b**2 + xi-1 * b + xi-2 -205 -206 do q\{i-t-1\} -= 1; -207 */ -208 q.dp[i - t - 1] = (q.dp[i - t - 1] + 1) & MP_MASK; -209 do \{ -210 q.dp[i - t - 1] = (q.dp[i - t - 1] - 1) & MP_MASK; -211 -212 /* find left hand */ -213 mp_zero (&t1); -214 t1.dp[0] = (t - 1 < 0) ? 0 : y.dp[t - 1]; -215 t1.dp[1] = y.dp[t]; -216 t1.used = 2; -217 if ((res = mp_mul_d (&t1, q.dp[i - t - 1], &t1)) != MP_OKAY) \{ -218 goto LBL_Y; -219 \} -220 -221 /* find right hand */ -222 t2.dp[0] = (i - 2 < 0) ? 0 : x.dp[i - 2]; -223 t2.dp[1] = (i - 1 < 0) ? 0 : x.dp[i - 1]; -224 t2.dp[2] = x.dp[i]; -225 t2.used = 3; -226 \} while (mp_cmp_mag(&t1, &t2) == MP_GT); -227 -228 /* step 3.3 x = x - q\{i-t-1\} * y * b**\{i-t-1\} */ -229 if ((res = mp_mul_d (&y, q.dp[i - t - 1], &t1)) != MP_OKAY) \{ -230 goto LBL_Y; -231 \} -232 -233 if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) \{ -234 goto LBL_Y; -235 \} -236 -237 if ((res = mp_sub (&x, &t1, &x)) != MP_OKAY) \{ -238 goto LBL_Y; -239 \} -240 -241 /* if x < 0 then \{ x = x + y*b**\{i-t-1\}; q\{i-t-1\} -= 1; \} */ -242 if (x.sign == MP_NEG) \{ -243 if ((res = mp_copy (&y, &t1)) != MP_OKAY) \{ -244 goto LBL_Y; -245 \} -246 if ((res = mp_lshd (&t1, i - t - 1)) != MP_OKAY) \{ -247 goto LBL_Y; -248 \} -249 if ((res = mp_add (&x, &t1, &x)) != MP_OKAY) \{ -250 goto LBL_Y; -251 \} -252 -253 q.dp[i - t - 1] = (q.dp[i - t - 1] - 1UL) & MP_MASK; -254 \} -255 \} -256 -257 /* now q is the quotient and x is the remainder -258 * [which we have to normalize] -259 */ -260 -261 /* get sign before writing to c */ -262 x.sign = x.used == 0 ? MP_ZPOS : a->sign; -263 -264 if (c != NULL) \{ -265 mp_clamp (&q); -266 mp_exch (&q, c); -267 c->sign = neg; -268 \} -269 -270 if (d != NULL) \{ -271 mp_div_2d (&x, norm, &x, NULL); -272 mp_exch (&x, d); -273 \} -274 -275 res = MP_OKAY; -276 -277 LBL_Y:mp_clear (&y); -278 LBL_X:mp_clear (&x); -279 LBL_T2:mp_clear (&t2); -280 LBL_T1:mp_clear (&t1); -281 LBL_Q:mp_clear (&q); -282 return res; -283 \} -284 -285 #endif -286 -287 #endif -288 \end{alltt} \end{small} @@ -8728,23 +5496,23 @@ algorithm with only the quotient is mp_div(&a, &b, &c, NULL); /* c = [a/b] */ \end{verbatim} -Lines 37 and 44 handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor -respectively. After the two trivial cases all of the temporary variables are initialized. Line 105 determines the sign of -the quotient and line 76 ensures that both $x$ and $y$ are positive. +Lines 109 and 113 handle the two trivial cases of inputs which are division by zero and dividend smaller than the divisor +respectively. After the two trivial cases all of the temporary variables are initialized. Line 148 determines the sign of +the quotient and line 148 ensures that both $x$ and $y$ are positive. -The number of bits in the leading digit is calculated on line 105. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits +The number of bits in the leading digit is calculated on line 151. Implictly an mp\_int with $r$ digits will require $lg(\beta)(r-1) + k$ bits of precision which when reduced modulo $lg(\beta)$ produces the value of $k$. In this case $k$ is the number of bits in the leading digit which is exactly what is required. For the algorithm to operate $k$ must equal $lg(\beta) - 1$ and when it does not the inputs must be normalized by shifting them to the left by $lg(\beta) - 1 - k$ bits. Throughout the variables $n$ and $t$ will represent the highest digit of $x$ and $y$ respectively. These are first used to produce the -leading digit of the quotient. The loop beginning on line 183 will produce the remainder of the quotient digits. +leading digit of the quotient. The loop beginning on line 184 will produce the remainder of the quotient digits. -The conditional ``continue'' on line 114 is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the +The conditional ``continue'' on line 187 is used to prevent the algorithm from reading past the leading edge of $x$ which can occur when the algorithm eliminates multiple non-zero digits in a single iteration. This ensures that $x_i$ is always non-zero since by definition the digits above the $i$'th position $x$ must be zero in order for the quotient to be precise\footnote{Precise as far as integer division is concerned.}. -Lines 130, 130 and 134 through 134 manually construct the high accuracy estimations by setting the digits of the two mp\_int +Lines 214, 216 and 223 through 225 manually construct the high accuracy estimations by setting the digits of the two mp\_int variables directly. \section{Single Digit Helpers} @@ -8782,99 +5550,6 @@ This algorithm initiates a temporary mp\_int with the value of the single digit \hspace{-5.1mm}{\bf File}: bn\_mp\_add\_d.c \vspace{-3mm} \begin{alltt} -016 -017 /* single digit addition */ -018 int -019 mp_add_d (mp_int * a, mp_digit b, mp_int * c) -020 \{ -021 int res, ix, oldused; -022 mp_digit *tmpa, *tmpc, mu; -023 -024 /* grow c as required */ -025 if (c->alloc < a->used + 1) \{ -026 if ((res = mp_grow(c, a->used + 1)) != MP_OKAY) \{ -027 return res; -028 \} -029 \} -030 -031 /* if a is negative and |a| >= b, call c = |a| - b */ -032 if (a->sign == MP_NEG && (a->used > 1 || a->dp[0] >= b)) \{ -033 /* temporarily fix sign of a */ -034 a->sign = MP_ZPOS; -035 -036 /* c = |a| - b */ -037 res = mp_sub_d(a, b, c); -038 -039 /* fix sign */ -040 a->sign = c->sign = MP_NEG; -041 -042 /* clamp */ -043 mp_clamp(c); -044 -045 return res; -046 \} -047 -048 /* old number of used digits in c */ -049 oldused = c->used; -050 -051 /* sign always positive */ -052 c->sign = MP_ZPOS; -053 -054 /* source alias */ -055 tmpa = a->dp; -056 -057 /* destination alias */ -058 tmpc = c->dp; -059 -060 /* if a is positive */ -061 if (a->sign == MP_ZPOS) \{ -062 /* add digit, after this we're propagating -063 * the carry. -064 */ -065 *tmpc = *tmpa++ + b; -066 mu = *tmpc >> DIGIT_BIT; -067 *tmpc++ &= MP_MASK; -068 -069 /* now handle rest of the digits */ -070 for (ix = 1; ix < a->used; ix++) \{ -071 *tmpc = *tmpa++ + mu; -072 mu = *tmpc >> DIGIT_BIT; -073 *tmpc++ &= MP_MASK; -074 \} -075 /* set final carry */ -076 ix++; -077 *tmpc++ = mu; -078 -079 /* setup size */ -080 c->used = a->used + 1; -081 \} else \{ -082 /* a was negative and |a| < b */ -083 c->used = 1; -084 -085 /* the result is a single digit */ -086 if (a->used == 1) \{ -087 *tmpc++ = b - a->dp[0]; -088 \} else \{ -089 *tmpc++ = b; -090 \} -091 -092 /* setup count so the clearing of oldused -093 * can fall through correctly -094 */ -095 ix = 1; -096 \} -097 -098 /* now zero to oldused */ -099 while (ix++ < oldused) \{ -100 *tmpc++ = 0; -101 \} -102 mp_clamp(c); -103 -104 return MP_OKAY; -105 \} -106 -107 #endif -108 \end{alltt} \end{small} @@ -8925,66 +5600,6 @@ Unlike the full multiplication algorithms this algorithm does not require any si \hspace{-5.1mm}{\bf File}: bn\_mp\_mul\_d.c \vspace{-3mm} \begin{alltt} -016 -017 /* multiply by a digit */ -018 int -019 mp_mul_d (mp_int * a, mp_digit b, mp_int * c) -020 \{ -021 mp_digit u, *tmpa, *tmpc; -022 mp_word r; -023 int ix, res, olduse; -024 -025 /* make sure c is big enough to hold a*b */ -026 if (c->alloc < a->used + 1) \{ -027 if ((res = mp_grow (c, a->used + 1)) != MP_OKAY) \{ -028 return res; -029 \} -030 \} -031 -032 /* get the original destinations used count */ -033 olduse = c->used; -034 -035 /* set the sign */ -036 c->sign = a->sign; -037 -038 /* alias for a->dp [source] */ -039 tmpa = a->dp; -040 -041 /* alias for c->dp [dest] */ -042 tmpc = c->dp; -043 -044 /* zero carry */ -045 u = 0; -046 -047 /* compute columns */ -048 for (ix = 0; ix < a->used; ix++) \{ -049 /* compute product and carry sum for this term */ -050 r = ((mp_word) u) + ((mp_word)*tmpa++) * ((mp_word)b); -051 -052 /* mask off higher bits to get a single digit */ -053 *tmpc++ = (mp_digit) (r & ((mp_word) MP_MASK)); -054 -055 /* send carry into next iteration */ -056 u = (mp_digit) (r >> ((mp_word) DIGIT_BIT)); -057 \} -058 -059 /* store final carry [if any] and increment ix offset */ -060 *tmpc++ = u; -061 ++ix; -062 -063 /* now zero digits above the top */ -064 while (ix++ < olduse) \{ -065 *tmpc++ = 0; -066 \} -067 -068 /* set used count */ -069 c->used = a->used + 1; -070 mp_clamp(c); -071 -072 return MP_OKAY; -073 \} -074 #endif -075 \end{alltt} \end{small} @@ -9040,104 +5655,13 @@ from chapter seven. \hspace{-5.1mm}{\bf File}: bn\_mp\_div\_d.c \vspace{-3mm} \begin{alltt} -016 -017 static int s_is_power_of_two(mp_digit b, int *p) -018 \{ -019 int x; -020 -021 for (x = 1; x < DIGIT_BIT; x++) \{ -022 if (b == (((mp_digit)1)<dp[0] & ((((mp_digit)1)<used)) != MP_OKAY) \{ -074 return res; -075 \} -076 -077 q.used = a->used; -078 q.sign = a->sign; -079 w = 0; -080 for (ix = a->used - 1; ix >= 0; ix--) \{ -081 w = (w << ((mp_word)DIGIT_BIT)) | ((mp_word)a->dp[ix]); -082 -083 if (w >= b) \{ -084 t = (mp_digit)(w / b); -085 w -= ((mp_word)t) * ((mp_word)b); -086 \} else \{ -087 t = 0; -088 \} -089 q.dp[ix] = (mp_digit)t; -090 \} -091 -092 if (d != NULL) \{ -093 *d = (mp_digit)w; -094 \} -095 -096 if (c != NULL) \{ -097 mp_clamp(&q); -098 mp_exch(&q, c); -099 \} -100 mp_clear(&q); -101 -102 return res; -103 \} -104 -105 #endif -106 \end{alltt} \end{small} Like the implementation of algorithm mp\_div this algorithm allows either of the quotient or remainder to be passed as a \textbf{NULL} pointer to indicate the respective value is not required. This allows a trivial single digit modular reduction algorithm, mp\_mod\_d to be created. -The division and remainder on lines 43 and @45,%@ can be replaced often by a single division on most processors. For example, the 32-bit x86 based +The division and remainder on lines 44 and @45,%@ can be replaced often by a single division on most processors. For example, the 32-bit x86 based processors can divide a 64-bit quantity by a 32-bit quantity and produce the quotient and remainder simultaneously. Unfortunately the GCC compiler does not recognize that optimization and will actually produce two function calls to find the quotient and remainder respectively. @@ -9205,119 +5729,6 @@ root. Ideally this algorithm is meant to find the $n$'th root of an input where \hspace{-5.1mm}{\bf File}: bn\_mp\_n\_root.c \vspace{-3mm} \begin{alltt} -016 -017 /* find the n'th root of an integer -018 * -019 * Result found such that (c)**b <= a and (c+1)**b > a -020 * -021 * This algorithm uses Newton's approximation -022 * x[i+1] = x[i] - f(x[i])/f'(x[i]) -023 * which will find the root in log(N) time where -024 * each step involves a fair bit. This is not meant to -025 * find huge roots [square and cube, etc]. -026 */ -027 int mp_n_root (mp_int * a, mp_digit b, mp_int * c) -028 \{ -029 mp_int t1, t2, t3; -030 int res, neg; -031 -032 /* input must be positive if b is even */ -033 if ((b & 1) == 0 && a->sign == MP_NEG) \{ -034 return MP_VAL; -035 \} -036 -037 if ((res = mp_init (&t1)) != MP_OKAY) \{ -038 return res; -039 \} -040 -041 if ((res = mp_init (&t2)) != MP_OKAY) \{ -042 goto LBL_T1; -043 \} -044 -045 if ((res = mp_init (&t3)) != MP_OKAY) \{ -046 goto LBL_T2; -047 \} -048 -049 /* if a is negative fudge the sign but keep track */ -050 neg = a->sign; -051 a->sign = MP_ZPOS; -052 -053 /* t2 = 2 */ -054 mp_set (&t2, 2); -055 -056 do \{ -057 /* t1 = t2 */ -058 if ((res = mp_copy (&t2, &t1)) != MP_OKAY) \{ -059 goto LBL_T3; -060 \} -061 -062 /* t2 = t1 - ((t1**b - a) / (b * t1**(b-1))) */ -063 -064 /* t3 = t1**(b-1) */ -065 if ((res = mp_expt_d (&t1, b - 1, &t3)) != MP_OKAY) \{ -066 goto LBL_T3; -067 \} -068 -069 /* numerator */ -070 /* t2 = t1**b */ -071 if ((res = mp_mul (&t3, &t1, &t2)) != MP_OKAY) \{ -072 goto LBL_T3; -073 \} -074 -075 /* t2 = t1**b - a */ -076 if ((res = mp_sub (&t2, a, &t2)) != MP_OKAY) \{ -077 goto LBL_T3; -078 \} -079 -080 /* denominator */ -081 /* t3 = t1**(b-1) * b */ -082 if ((res = mp_mul_d (&t3, b, &t3)) != MP_OKAY) \{ -083 goto LBL_T3; -084 \} -085 -086 /* t3 = (t1**b - a)/(b * t1**(b-1)) */ -087 if ((res = mp_div (&t2, &t3, &t3, NULL)) != MP_OKAY) \{ -088 goto LBL_T3; -089 \} -090 -091 if ((res = mp_sub (&t1, &t3, &t2)) != MP_OKAY) \{ -092 goto LBL_T3; -093 \} -094 \} while (mp_cmp (&t1, &t2) != MP_EQ); -095 -096 /* result can be off by a few so check */ -097 for (;;) \{ -098 if ((res = mp_expt_d (&t1, b, &t2)) != MP_OKAY) \{ -099 goto LBL_T3; -100 \} -101 -102 if (mp_cmp (&t2, a) == MP_GT) \{ -103 if ((res = mp_sub_d (&t1, 1, &t1)) != MP_OKAY) \{ -104 goto LBL_T3; -105 \} -106 \} else \{ -107 break; -108 \} -109 \} -110 -111 /* reset the sign of a first */ -112 a->sign = neg; -113 -114 /* set the result */ -115 mp_exch (&t1, c); -116 -117 /* set the sign of the result */ -118 c->sign = neg; -119 -120 res = MP_OKAY; -121 -122 LBL_T3:mp_clear (&t3); -123 LBL_T2:mp_clear (&t2); -124 LBL_T1:mp_clear (&t1); -125 return res; -126 \} -127 #endif -128 \end{alltt} \end{small} @@ -9359,42 +5770,6 @@ the integers from $0$ to $\beta - 1$. \hspace{-5.1mm}{\bf File}: bn\_mp\_rand.c \vspace{-3mm} \begin{alltt} -016 -017 /* makes a pseudo-random int of a given size */ -018 int -019 mp_rand (mp_int * a, int digits) -020 \{ -021 int res; -022 mp_digit d; -023 -024 mp_zero (a); -025 if (digits <= 0) \{ -026 return MP_OKAY; -027 \} -028 -029 /* first place a random non-zero digit */ -030 do \{ -031 d = ((mp_digit) abs (rand ())) & MP_MASK; -032 \} while (d == 0); -033 -034 if ((res = mp_add_d (a, d, a)) != MP_OKAY) \{ -035 return res; -036 \} -037 -038 while (--digits > 0) \{ -039 if ((res = mp_lshd (a, 1)) != MP_OKAY) \{ -040 return res; -041 \} -042 -043 if ((res = mp_add_d (a, ((mp_digit) abs (rand ())), a)) != MP_OKAY) \{ -044 return res; -045 \} -046 \} -047 -048 return MP_OKAY; -049 \} -050 #endif -051 \end{alltt} \end{small} @@ -9477,72 +5852,6 @@ as part of larger input without any significant problem. \hspace{-5.1mm}{\bf File}: bn\_mp\_read\_radix.c \vspace{-3mm} \begin{alltt} -016 -017 /* read a string [ASCII] in a given radix */ -018 int mp_read_radix (mp_int * a, const char *str, int radix) -019 \{ -020 int y, res, neg; -021 char ch; -022 -023 /* zero the digit bignum */ -024 mp_zero(a); -025 -026 /* make sure the radix is ok */ -027 if (radix < 2 || radix > 64) \{ -028 return MP_VAL; -029 \} -030 -031 /* if the leading digit is a -032 * minus set the sign to negative. -033 */ -034 if (*str == '-') \{ -035 ++str; -036 neg = MP_NEG; -037 \} else \{ -038 neg = MP_ZPOS; -039 \} -040 -041 /* set the integer to the default of zero */ -042 mp_zero (a); -043 -044 /* process each digit of the string */ -045 while (*str) \{ -046 /* if the radix < 36 the conversion is case insensitive -047 * this allows numbers like 1AB and 1ab to represent the same value -048 * [e.g. in hex] -049 */ -050 ch = (char) ((radix < 36) ? toupper (*str) : *str); -051 for (y = 0; y < 64; y++) \{ -052 if (ch == mp_s_rmap[y]) \{ -053 break; -054 \} -055 \} -056 -057 /* if the char was found in the map -058 * and is less than the given radix add it -059 * to the number, otherwise exit the loop. -060 */ -061 if (y < radix) \{ -062 if ((res = mp_mul_d (a, (mp_digit) radix, a)) != MP_OKAY) \{ -063 return res; -064 \} -065 if ((res = mp_add_d (a, (mp_digit) y, a)) != MP_OKAY) \{ -066 return res; -067 \} -068 \} else \{ -069 break; -070 \} -071 ++str; -072 \} -073 -074 /* set the sign only if a != 0 */ -075 if (mp_iszero(a) != 1) \{ -076 a->sign = neg; -077 \} -078 return MP_OKAY; -079 \} -080 #endif -081 \end{alltt} \end{small} @@ -9607,62 +5916,6 @@ are required instead of a series of $n \times k$ divisions. One design flaw of \hspace{-5.1mm}{\bf File}: bn\_mp\_toradix.c \vspace{-3mm} \begin{alltt} -016 -017 /* stores a bignum as a ASCII string in a given radix (2..64) */ -018 int mp_toradix (mp_int * a, char *str, int radix) -019 \{ -020 int res, digs; -021 mp_int t; -022 mp_digit d; -023 char *_s = str; -024 -025 /* check range of the radix */ -026 if (radix < 2 || radix > 64) \{ -027 return MP_VAL; -028 \} -029 -030 /* quick out if its zero */ -031 if (mp_iszero(a) == 1) \{ -032 *str++ = '0'; -033 *str = '\symbol{92}0'; -034 return MP_OKAY; -035 \} -036 -037 if ((res = mp_init_copy (&t, a)) != MP_OKAY) \{ -038 return res; -039 \} -040 -041 /* if it is negative output a - */ -042 if (t.sign == MP_NEG) \{ -043 ++_s; -044 *str++ = '-'; -045 t.sign = MP_ZPOS; -046 \} -047 -048 digs = 0; -049 while (mp_iszero (&t) == 0) \{ -050 if ((res = mp_div_d (&t, (mp_digit) radix, &t, &d)) != MP_OKAY) \{ -051 mp_clear (&t); -052 return res; -053 \} -054 *str++ = mp_s_rmap[d]; -055 ++digs; -056 \} -057 -058 /* reverse the digits of the string. In this case _s points -059 * to the first digit [exluding the sign] of the number] -060 */ -061 bn_reverse ((unsigned char *)_s, digs); -062 -063 /* append a NULL so the string is properly terminated */ -064 *str = '\symbol{92}0'; -065 -066 mp_clear (&t); -067 return MP_OKAY; -068 \} -069 -070 #endif -071 \end{alltt} \end{small} @@ -9792,33 +6045,30 @@ and will produce the greatest common divisor. \textbf{Input}. mp\_int $a$ and $b$ \\ \textbf{Output}. The greatest common divisor $c = (a, b)$. \\ \hline \\ -1. If $a = 0$ and $b \ne 0$ then \\ -\hspace{3mm}1.1 $c \leftarrow b$ \\ +1. If $a = 0$ then \\ +\hspace{3mm}1.1 $c \leftarrow \vert b \vert $ \\ \hspace{3mm}1.2 Return(\textit{MP\_OKAY}). \\ -2. If $a \ne 0$ and $b = 0$ then \\ -\hspace{3mm}2.1 $c \leftarrow a$ \\ +2. If $b = 0$ then \\ +\hspace{3mm}2.1 $c \leftarrow \vert a \vert $ \\ \hspace{3mm}2.2 Return(\textit{MP\_OKAY}). \\ -3. If $a = b = 0$ then \\ -\hspace{3mm}3.1 $c \leftarrow 1$ \\ -\hspace{3mm}3.2 Return(\textit{MP\_OKAY}). \\ -4. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ -5. $k \leftarrow 0$ \\ -6. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}6.1 $k \leftarrow k + 1$ \\ -\hspace{3mm}6.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ -\hspace{3mm}6.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -7. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}7.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ -8. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{3mm}8.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -9. While $v.used > 0$ \\ -\hspace{3mm}9.1 If $\vert u \vert > \vert v \vert$ then \\ -\hspace{6mm}9.1.1 Swap $u$ and $v$. \\ -\hspace{3mm}9.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ -\hspace{3mm}9.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ -\hspace{6mm}9.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ -10. $c \leftarrow u \cdot 2^k$ \\ -11. Return(\textit{MP\_OKAY}). \\ +3. $u \leftarrow \vert a \vert, v \leftarrow \vert b \vert$ \\ +4. $k \leftarrow 0$ \\ +5. While $u.used > 0$ and $v.used > 0$ and $u_0 \equiv v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}5.1 $k \leftarrow k + 1$ \\ +\hspace{3mm}5.2 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +\hspace{3mm}5.3 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +6. While $u.used > 0$ and $u_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}6.1 $u \leftarrow \lfloor u / 2 \rfloor$ \\ +7. While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{3mm}7.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +8. While $v.used > 0$ \\ +\hspace{3mm}8.1 If $\vert u \vert > \vert v \vert$ then \\ +\hspace{6mm}8.1.1 Swap $u$ and $v$. \\ +\hspace{3mm}8.2 $v \leftarrow \vert v \vert - \vert u \vert$ \\ +\hspace{3mm}8.3 While $v.used > 0$ and $v_0 \equiv 0 \mbox{ (mod }2\mbox{)}$ \\ +\hspace{6mm}8.3.1 $v \leftarrow \lfloor v / 2 \rfloor$ \\ +9. $c \leftarrow u \cdot 2^k$ \\ +10. Return(\textit{MP\_OKAY}). \\ \hline \end{tabular} \end{center} @@ -9830,17 +6080,17 @@ This algorithm will produce the greatest common divisor of two mp\_ints $a$ and Knuth \cite[pp. 338]{TAOCPV2} but has been modified to be simpler to explain. In theory it achieves the same asymptotic working time as Algorithm B and in practice this appears to be true. -The first three steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the +The first two steps handle the cases where either one of or both inputs are zero. If either input is zero the greatest common divisor is the largest input or zero if they are both zero. If the inputs are not trivial than $u$ and $v$ are assigned the absolute values of $a$ and $b$ respectively and the algorithm will proceed to reduce the pair. -Step six will divide out any common factors of two and keep track of the count in the variable $k$. After this step two is no longer a +Step five will divide out any common factors of two and keep track of the count in the variable $k$. After this step, two is no longer a factor of the remaining greatest common divisor between $u$ and $v$ and can be safely evenly divided out of either whenever they are even. Step -seven and eight ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while loops will iterate since +six and seven ensure that the $u$ and $v$ respectively have no more factors of two. At most only one of the while--loops will iterate since they cannot both be even. -By step nine both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to -or greater than $u$. This ensures that the subtraction on step 9.2 will always produce a positive and even result. Step 9.3 removes any +By step eight both of $u$ and $v$ are odd which is required for the inner logic. First the pair are swapped such that $v$ is equal to +or greater than $u$. This ensures that the subtraction on step 8.2 will always produce a positive and even result. Step 8.3 removes any factors of two from the difference $u$ to ensure that in the next iteration of the loop both are once again odd. After $v = 0$ occurs the variable $u$ has the greatest common divisor of the pair $\left < u, v \right >$ just after step six. The result @@ -9850,117 +6100,23 @@ must be adjusted by multiplying by the common factors of two ($2^k$) removed ear \hspace{-5.1mm}{\bf File}: bn\_mp\_gcd.c \vspace{-3mm} \begin{alltt} -016 -017 /* Greatest Common Divisor using the binary method */ -018 int mp_gcd (mp_int * a, mp_int * b, mp_int * c) -019 \{ -020 mp_int u, v; -021 int k, u_lsb, v_lsb, res; -022 -023 /* either zero than gcd is the largest */ -024 if (mp_iszero (a) == 1 && mp_iszero (b) == 0) \{ -025 return mp_abs (b, c); -026 \} -027 if (mp_iszero (a) == 0 && mp_iszero (b) == 1) \{ -028 return mp_abs (a, c); -029 \} -030 -031 /* optimized. At this point if a == 0 then -032 * b must equal zero too -033 */ -034 if (mp_iszero (a) == 1) \{ -035 mp_zero(c); -036 return MP_OKAY; -037 \} -038 -039 /* get copies of a and b we can modify */ -040 if ((res = mp_init_copy (&u, a)) != MP_OKAY) \{ -041 return res; -042 \} -043 -044 if ((res = mp_init_copy (&v, b)) != MP_OKAY) \{ -045 goto LBL_U; -046 \} -047 -048 /* must be positive for the remainder of the algorithm */ -049 u.sign = v.sign = MP_ZPOS; -050 -051 /* B1. Find the common power of two for u and v */ -052 u_lsb = mp_cnt_lsb(&u); -053 v_lsb = mp_cnt_lsb(&v); -054 k = MIN(u_lsb, v_lsb); -055 -056 if (k > 0) \{ -057 /* divide the power of two out */ -058 if ((res = mp_div_2d(&u, k, &u, NULL)) != MP_OKAY) \{ -059 goto LBL_V; -060 \} -061 -062 if ((res = mp_div_2d(&v, k, &v, NULL)) != MP_OKAY) \{ -063 goto LBL_V; -064 \} -065 \} -066 -067 /* divide any remaining factors of two out */ -068 if (u_lsb != k) \{ -069 if ((res = mp_div_2d(&u, u_lsb - k, &u, NULL)) != MP_OKAY) \{ -070 goto LBL_V; -071 \} -072 \} -073 -074 if (v_lsb != k) \{ -075 if ((res = mp_div_2d(&v, v_lsb - k, &v, NULL)) != MP_OKAY) \{ -076 goto LBL_V; -077 \} -078 \} -079 -080 while (mp_iszero(&v) == 0) \{ -081 /* make sure v is the largest */ -082 if (mp_cmp_mag(&u, &v) == MP_GT) \{ -083 /* swap u and v to make sure v is >= u */ -084 mp_exch(&u, &v); -085 \} -086 -087 /* subtract smallest from largest */ -088 if ((res = s_mp_sub(&v, &u, &v)) != MP_OKAY) \{ -089 goto LBL_V; -090 \} -091 -092 /* Divide out all factors of two */ -093 if ((res = mp_div_2d(&v, mp_cnt_lsb(&v), &v, NULL)) != MP_OKAY) \{ -094 goto LBL_V; -095 \} -096 \} -097 -098 /* multiply by 2**k which we divided out at the beginning */ -099 if ((res = mp_mul_2d (&u, k, c)) != MP_OKAY) \{ -100 goto LBL_V; -101 \} -102 c->sign = MP_ZPOS; -103 res = MP_OKAY; -104 LBL_V:mp_clear (&u); -105 LBL_U:mp_clear (&v); -106 return res; -107 \} -108 #endif -109 \end{alltt} \end{small} This function makes use of the macros mp\_iszero and mp\_iseven. The former evaluates to $1$ if the input mp\_int is equivalent to the integer zero otherwise it evaluates to $0$. The latter evaluates to $1$ if the input mp\_int represents a non-zero even integer otherwise it evaluates to $0$. Note that just because mp\_iseven may evaluate to $0$ does not mean the input is odd, it could also be zero. The three -trivial cases of inputs are handled on lines 24 through 37. After those lines the inputs are assumed to be non-zero. +trivial cases of inputs are handled on lines 24 through 30. After those lines the inputs are assumed to be non-zero. -Lines 34 and 40 make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two -must be divided out of the two inputs. The while loop on line 80 iterates so long as both are even. The local integer $k$ is used to -keep track of how many factors of $2$ are pulled out of both values. It is assumed that the number of factors will not exceed the maximum -value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than entries than are accessible by an ``int'' so this is not -a limitation.}. +Lines 32 and 37 make local copies $u$ and $v$ of the inputs $a$ and $b$ respectively. At this point the common factors of two +must be divided out of the two inputs. The block starting at line 44 removes common factors of two by first counting the number of trailing +zero bits in both. The local integer $k$ is used to keep track of how many factors of $2$ are pulled out of both values. It is assumed that +the number of factors will not exceed the maximum value of a C ``int'' data type\footnote{Strictly speaking no array in C may have more than +entries than are accessible by an ``int'' so this is not a limitation.}. -At this point there are no more common factors of two in the two values. The while loops on lines 80 and 80 remove any independent -factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop -on line 80 performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in +At this point there are no more common factors of two in the two values. The divisions by a power of two on lines 62 and 68 remove +any independent factors of two such that both $u$ and $v$ are guaranteed to be an odd integer before hitting the main body of the algorithm. The while loop +on line 73 performs the reduction of the pair until $v$ is equal to zero. The unsigned comparison and subtraction algorithms are used in place of the full signed routines since both values are guaranteed to be positive and the result of the subtraction is guaranteed to be non-negative. \section{Least Common Multiple} @@ -9999,47 +6155,6 @@ dividing the product of the two inputs by their greatest common divisor. \hspace{-5.1mm}{\bf File}: bn\_mp\_lcm.c \vspace{-3mm} \begin{alltt} -016 -017 /* computes least common multiple as |a*b|/(a, b) */ -018 int mp_lcm (mp_int * a, mp_int * b, mp_int * c) -019 \{ -020 int res; -021 mp_int t1, t2; -022 -023 -024 if ((res = mp_init_multi (&t1, &t2, NULL)) != MP_OKAY) \{ -025 return res; -026 \} -027 -028 /* t1 = get the GCD of the two inputs */ -029 if ((res = mp_gcd (a, b, &t1)) != MP_OKAY) \{ -030 goto LBL_T; -031 \} -032 -033 /* divide the smallest by the GCD */ -034 if (mp_cmp_mag(a, b) == MP_LT) \{ -035 /* store quotient in t2 such that t2 * b is the LCM */ -036 if ((res = mp_div(a, &t1, &t2, NULL)) != MP_OKAY) \{ -037 goto LBL_T; -038 \} -039 res = mp_mul(b, &t2, c); -040 \} else \{ -041 /* store quotient in t2 such that t2 * a is the LCM */ -042 if ((res = mp_div(b, &t1, &t2, NULL)) != MP_OKAY) \{ -043 goto LBL_T; -044 \} -045 res = mp_mul(a, &t2, c); -046 \} -047 -048 /* fix the sign to positive */ -049 c->sign = MP_ZPOS; -050 -051 LBL_T: -052 mp_clear_multi (&t1, &t2, NULL); -053 return res; -054 \} -055 #endif -056 \end{alltt} \end{small} @@ -10199,92 +6314,6 @@ $\left ( {p' \over a'} \right )$ which is multiplied against the current Jacobi \hspace{-5.1mm}{\bf File}: bn\_mp\_jacobi.c \vspace{-3mm} \begin{alltt} -016 -017 /* computes the jacobi c = (a | n) (or Legendre if n is prime) -018 * HAC pp. 73 Algorithm 2.149 -019 */ -020 int mp_jacobi (mp_int * a, mp_int * p, int *c) -021 \{ -022 mp_int a1, p1; -023 int k, s, r, res; -024 mp_digit residue; -025 -026 /* if p <= 0 return MP_VAL */ -027 if (mp_cmp_d(p, 0) != MP_GT) \{ -028 return MP_VAL; -029 \} -030 -031 /* step 1. if a == 0, return 0 */ -032 if (mp_iszero (a) == 1) \{ -033 *c = 0; -034 return MP_OKAY; -035 \} -036 -037 /* step 2. if a == 1, return 1 */ -038 if (mp_cmp_d (a, 1) == MP_EQ) \{ -039 *c = 1; -040 return MP_OKAY; -041 \} -042 -043 /* default */ -044 s = 0; -045 -046 /* step 3. write a = a1 * 2**k */ -047 if ((res = mp_init_copy (&a1, a)) != MP_OKAY) \{ -048 return res; -049 \} -050 -051 if ((res = mp_init (&p1)) != MP_OKAY) \{ -052 goto LBL_A1; -053 \} -054 -055 /* divide out larger power of two */ -056 k = mp_cnt_lsb(&a1); -057 if ((res = mp_div_2d(&a1, k, &a1, NULL)) != MP_OKAY) \{ -058 goto LBL_P1; -059 \} -060 -061 /* step 4. if e is even set s=1 */ -062 if ((k & 1) == 0) \{ -063 s = 1; -064 \} else \{ -065 /* else set s=1 if p = 1/7 (mod 8) or s=-1 if p = 3/5 (mod 8) */ -066 residue = p->dp[0] & 7; -067 -068 if (residue == 1 || residue == 7) \{ -069 s = 1; -070 \} else if (residue == 3 || residue == 5) \{ -071 s = -1; -072 \} -073 \} -074 -075 /* step 5. if p == 3 (mod 4) *and* a1 == 3 (mod 4) then s = -s */ -076 if ( ((p->dp[0] & 3) == 3) && ((a1.dp[0] & 3) == 3)) \{ -077 s = -s; -078 \} -079 -080 /* if a1 == 1 we're done */ -081 if (mp_cmp_d (&a1, 1) == MP_EQ) \{ -082 *c = s; -083 \} else \{ -084 /* n1 = n mod a1 */ -085 if ((res = mp_mod (p, &a1, &p1)) != MP_OKAY) \{ -086 goto LBL_P1; -087 \} -088 if ((res = mp_jacobi (&p1, &a1, &r)) != MP_OKAY) \{ -089 goto LBL_P1; -090 \} -091 *c = s * r; -092 \} -093 -094 /* done */ -095 res = MP_OKAY; -096 LBL_P1:mp_clear (&p1); -097 LBL_A1:mp_clear (&a1); -098 return res; -099 \} -100 #endif -101 \end{alltt} \end{small} @@ -10299,9 +6328,9 @@ After a local copy of $a$ is made all of the factors of two are divided out and bit of $k$ is required, however, it makes the algorithm simpler to follow to perform an addition. In practice an exclusive-or and addition have the same processor requirements and neither is faster than the other. -Line 61 through 70 determines the value of $\left ( { 2 \over p } \right )^k$. If the least significant bit of $k$ is zero than +Line 58 through 71 determines the value of $\left ( { 2 \over p } \right )^k$. If the least significant bit of $k$ is zero than $k$ is even and the value is one. Otherwise, the value of $s$ depends on which residue class $p$ belongs to modulo eight. The value of -$(-1)^{(p-1)(a'-1)/4}$ is compute and multiplied against $s$ on lines 75 through 73. +$(-1)^{(p-1)(a'-1)/4}$ is compute and multiplied against $s$ on lines 71 through 74. Finally, if $a1$ does not equal one the algorithm must recurse and compute $\left ( {p' \over a'} \right )$. @@ -10410,30 +6439,6 @@ then only a couple of additions or subtractions will be required to adjust the i \hspace{-5.1mm}{\bf File}: bn\_mp\_invmod.c \vspace{-3mm} \begin{alltt} -016 -017 /* hac 14.61, pp608 */ -018 int mp_invmod (mp_int * a, mp_int * b, mp_int * c) -019 \{ -020 /* b cannot be negative */ -021 if (b->sign == MP_NEG || mp_iszero(b) == 1) \{ -022 return MP_VAL; -023 \} -024 -025 #ifdef BN_FAST_MP_INVMOD_C -026 /* if the modulus is odd we can use a faster routine instead */ -027 if (mp_isodd (b) == 1) \{ -028 return fast_mp_invmod (a, b, c); -029 \} -030 #endif -031 -032 #ifdef BN_MP_INVMOD_SLOW_C -033 return mp_invmod_slow(a, b, c); -034 #endif -035 -036 return MP_VAL; -037 \} -038 #endif -039 \end{alltt} \end{small} @@ -10505,37 +6510,6 @@ This algorithm attempts to determine if a candidate integer $n$ is composite by \hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_is\_divisible.c \vspace{-3mm} \begin{alltt} -016 -017 /* determines if an integers is divisible by one -018 * of the first PRIME_SIZE primes or not -019 * -020 * sets result to 0 if not, 1 if yes -021 */ -022 int mp_prime_is_divisible (mp_int * a, int *result) -023 \{ -024 int err, ix; -025 mp_digit res; -026 -027 /* default to not */ -028 *result = MP_NO; -029 -030 for (ix = 0; ix < PRIME_SIZE; ix++) \{ -031 /* what is a mod LBL_prime_tab[ix] */ -032 if ((err = mp_mod_d (a, ltm_prime_tab[ix], &res)) != MP_OKAY) \{ -033 return err; -034 \} -035 -036 /* is the residue zero? */ -037 if (res == 0) \{ -038 *result = MP_YES; -039 return MP_OKAY; -040 \} -041 \} -042 -043 return MP_OKAY; -044 \} -045 #endif -046 \end{alltt} \end{small} @@ -10546,48 +6520,6 @@ mp\_digit. The table \_\_prime\_tab is defined in the following file. \hspace{-5.1mm}{\bf File}: bn\_prime\_tab.c \vspace{-3mm} \begin{alltt} -016 const mp_digit ltm_prime_tab[] = \{ -017 0x0002, 0x0003, 0x0005, 0x0007, 0x000B, 0x000D, 0x0011, 0x0013, -018 0x0017, 0x001D, 0x001F, 0x0025, 0x0029, 0x002B, 0x002F, 0x0035, -019 0x003B, 0x003D, 0x0043, 0x0047, 0x0049, 0x004F, 0x0053, 0x0059, -020 0x0061, 0x0065, 0x0067, 0x006B, 0x006D, 0x0071, 0x007F, -021 #ifndef MP_8BIT -022 0x0083, -023 0x0089, 0x008B, 0x0095, 0x0097, 0x009D, 0x00A3, 0x00A7, 0x00AD, -024 0x00B3, 0x00B5, 0x00BF, 0x00C1, 0x00C5, 0x00C7, 0x00D3, 0x00DF, -025 0x00E3, 0x00E5, 0x00E9, 0x00EF, 0x00F1, 0x00FB, 0x0101, 0x0107, -026 0x010D, 0x010F, 0x0115, 0x0119, 0x011B, 0x0125, 0x0133, 0x0137, -027 -028 0x0139, 0x013D, 0x014B, 0x0151, 0x015B, 0x015D, 0x0161, 0x0167, -029 0x016F, 0x0175, 0x017B, 0x017F, 0x0185, 0x018D, 0x0191, 0x0199, -030 0x01A3, 0x01A5, 0x01AF, 0x01B1, 0x01B7, 0x01BB, 0x01C1, 0x01C9, -031 0x01CD, 0x01CF, 0x01D3, 0x01DF, 0x01E7, 0x01EB, 0x01F3, 0x01F7, -032 0x01FD, 0x0209, 0x020B, 0x021D, 0x0223, 0x022D, 0x0233, 0x0239, -033 0x023B, 0x0241, 0x024B, 0x0251, 0x0257, 0x0259, 0x025F, 0x0265, -034 0x0269, 0x026B, 0x0277, 0x0281, 0x0283, 0x0287, 0x028D, 0x0293, -035 0x0295, 0x02A1, 0x02A5, 0x02AB, 0x02B3, 0x02BD, 0x02C5, 0x02CF, -036 -037 0x02D7, 0x02DD, 0x02E3, 0x02E7, 0x02EF, 0x02F5, 0x02F9, 0x0301, -038 0x0305, 0x0313, 0x031D, 0x0329, 0x032B, 0x0335, 0x0337, 0x033B, -039 0x033D, 0x0347, 0x0355, 0x0359, 0x035B, 0x035F, 0x036D, 0x0371, -040 0x0373, 0x0377, 0x038B, 0x038F, 0x0397, 0x03A1, 0x03A9, 0x03AD, -041 0x03B3, 0x03B9, 0x03C7, 0x03CB, 0x03D1, 0x03D7, 0x03DF, 0x03E5, -042 0x03F1, 0x03F5, 0x03FB, 0x03FD, 0x0407, 0x0409, 0x040F, 0x0419, -043 0x041B, 0x0425, 0x0427, 0x042D, 0x043F, 0x0443, 0x0445, 0x0449, -044 0x044F, 0x0455, 0x045D, 0x0463, 0x0469, 0x047F, 0x0481, 0x048B, -045 -046 0x0493, 0x049D, 0x04A3, 0x04A9, 0x04B1, 0x04BD, 0x04C1, 0x04C7, -047 0x04CD, 0x04CF, 0x04D5, 0x04E1, 0x04EB, 0x04FD, 0x04FF, 0x0503, -048 0x0509, 0x050B, 0x0511, 0x0515, 0x0517, 0x051B, 0x0527, 0x0529, -049 0x052F, 0x0551, 0x0557, 0x055D, 0x0565, 0x0577, 0x0581, 0x058F, -050 0x0593, 0x0595, 0x0599, 0x059F, 0x05A7, 0x05AB, 0x05AD, 0x05B3, -051 0x05BF, 0x05C9, 0x05CB, 0x05CF, 0x05D1, 0x05D5, 0x05DB, 0x05E7, -052 0x05F3, 0x05FB, 0x0607, 0x060D, 0x0611, 0x0617, 0x061F, 0x0623, -053 0x062B, 0x062F, 0x063D, 0x0641, 0x0647, 0x0649, 0x064D, 0x0653 -054 #endif -055 \}; -056 #endif -057 \end{alltt} \end{small} @@ -10634,49 +6566,6 @@ determine the result. \hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_fermat.c \vspace{-3mm} \begin{alltt} -016 -017 /* performs one Fermat test. -018 * -019 * If "a" were prime then b**a == b (mod a) since the order of -020 * the multiplicative sub-group would be phi(a) = a-1. That means -021 * it would be the same as b**(a mod (a-1)) == b**1 == b (mod a). -022 * -023 * Sets result to 1 if the congruence holds, or zero otherwise. -024 */ -025 int mp_prime_fermat (mp_int * a, mp_int * b, int *result) -026 \{ -027 mp_int t; -028 int err; -029 -030 /* default to composite */ -031 *result = MP_NO; -032 -033 /* ensure b > 1 */ -034 if (mp_cmp_d(b, 1) != MP_GT) \{ -035 return MP_VAL; -036 \} -037 -038 /* init t */ -039 if ((err = mp_init (&t)) != MP_OKAY) \{ -040 return err; -041 \} -042 -043 /* compute t = b**a mod a */ -044 if ((err = mp_exptmod (b, a, a, &t)) != MP_OKAY) \{ -045 goto LBL_T; -046 \} -047 -048 /* is it equal to b? */ -049 if (mp_cmp (&t, b) == MP_EQ) \{ -050 *result = MP_YES; -051 \} -052 -053 err = MP_OKAY; -054 LBL_T:mp_clear (&t); -055 return err; -056 \} -057 #endif -058 \end{alltt} \end{small} @@ -10729,90 +6618,6 @@ composite then it is \textit{probably} prime. \hspace{-5.1mm}{\bf File}: bn\_mp\_prime\_miller\_rabin.c \vspace{-3mm} \begin{alltt} -016 -017 /* Miller-Rabin test of "a" to the base of "b" as described in -018 * HAC pp. 139 Algorithm 4.24 -019 * -020 * Sets result to 0 if definitely composite or 1 if probably prime. -021 * Randomly the chance of error is no more than 1/4 and often -022 * very much lower. -023 */ -024 int mp_prime_miller_rabin (mp_int * a, mp_int * b, int *result) -025 \{ -026 mp_int n1, y, r; -027 int s, j, err; -028 -029 /* default */ -030 *result = MP_NO; -031 -032 /* ensure b > 1 */ -033 if (mp_cmp_d(b, 1) != MP_GT) \{ -034 return MP_VAL; -035 \} -036 -037 /* get n1 = a - 1 */ -038 if ((err = mp_init_copy (&n1, a)) != MP_OKAY) \{ -039 return err; -040 \} -041 if ((err = mp_sub_d (&n1, 1, &n1)) != MP_OKAY) \{ -042 goto LBL_N1; -043 \} -044 -045 /* set 2**s * r = n1 */ -046 if ((err = mp_init_copy (&r, &n1)) != MP_OKAY) \{ -047 goto LBL_N1; -048 \} -049 -050 /* count the number of least significant bits -051 * which are zero -052 */ -053 s = mp_cnt_lsb(&r); -054 -055 /* now divide n - 1 by 2**s */ -056 if ((err = mp_div_2d (&r, s, &r, NULL)) != MP_OKAY) \{ -057 goto LBL_R; -058 \} -059 -060 /* compute y = b**r mod a */ -061 if ((err = mp_init (&y)) != MP_OKAY) \{ -062 goto LBL_R; -063 \} -064 if ((err = mp_exptmod (b, &r, a, &y)) != MP_OKAY) \{ -065 goto LBL_Y; -066 \} -067 -068 /* if y != 1 and y != n1 do */ -069 if (mp_cmp_d (&y, 1) != MP_EQ && mp_cmp (&y, &n1) != MP_EQ) \{ -070 j = 1; -071 /* while j <= s-1 and y != n1 */ -072 while ((j <= (s - 1)) && mp_cmp (&y, &n1) != MP_EQ) \{ -073 if ((err = mp_sqrmod (&y, a, &y)) != MP_OKAY) \{ -074 goto LBL_Y; -075 \} -076 -077 /* if y == 1 then composite */ -078 if (mp_cmp_d (&y, 1) == MP_EQ) \{ -079 goto LBL_Y; -080 \} -081 -082 ++j; -083 \} -084 -085 /* if y != n1 then composite */ -086 if (mp_cmp (&y, &n1) != MP_EQ) \{ -087 goto LBL_Y; -088 \} -089 \} -090 -091 /* probably prime now */ -092 *result = MP_YES; -093 LBL_Y:mp_clear (&y); -094 LBL_R:mp_clear (&r); -095 LBL_N1:mp_clear (&n1); -096 return err; -097 \} -098 #endif -099 \end{alltt} \end{small} -- cgit v0.12