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-rw-r--r--generic/tclStrToD.c2209
1 files changed, 1118 insertions, 1091 deletions
diff --git a/generic/tclStrToD.c b/generic/tclStrToD.c
index b89ce45..67b6482 100644
--- a/generic/tclStrToD.c
+++ b/generic/tclStrToD.c
@@ -1,6 +1,4 @@
/*
- *----------------------------------------------------------------------
- *
* tclStrToD.c --
*
* This file contains a collection of procedures for managing conversions
@@ -13,7 +11,6 @@
*
* See the file "license.terms" for information on usage and redistribution of
* this file, and for a DISCLAIMER OF ALL WARRANTIES.
- *----------------------------------------------------------------------
*/
#include "tclInt.h"
@@ -38,6 +35,11 @@
#endif
/*
+ * Rounding controls. (Thanks a lot, Intel!)
+ */
+
+#ifdef __i386
+/*
* gcc on x86 needs access to rounding controls, because of a questionable
* feature where it retains intermediate results as IEEE 'long double' values
* somewhat unpredictably. It is tempting to include fpu_control.h, but that
@@ -45,41 +47,65 @@
* and ix86-isms are factored out here.
*/
-#if defined(__GNUC__) && defined(__i386)
-typedef unsigned int fpu_control_t __attribute__ ((__mode__ (__HI__)));
-#define _FPU_GETCW(cw) __asm__ __volatile__ ("fnstcw %0" : "=m" (*&cw))
-#define _FPU_SETCW(cw) __asm__ __volatile__ ("fldcw %0" : : "m" (*&cw))
+#if defined(__GNUC__)
+typedef unsigned int fpu_control_t __attribute__ ((__mode__ (__HI__)));
+
+#define _FPU_GETCW(cw) __asm__ __volatile__ ("fnstcw %0" : "=m" (*&cw))
+#define _FPU_SETCW(cw) __asm__ __volatile__ ("fldcw %0" : : "m" (*&cw))
# define FPU_IEEE_ROUNDING 0x027f
# define ADJUST_FPU_CONTROL_WORD
-#endif
+#define TCL_IEEE_DOUBLE_ROUNDING \
+ fpu_control_t roundTo53Bits = FPU_IEEE_ROUNDING; \
+ fpu_control_t oldRoundingMode; \
+ _FPU_GETCW(oldRoundingMode); \
+ _FPU_SETCW(roundTo53Bits)
+#define TCL_DEFAULT_DOUBLE_ROUNDING \
+ _FPU_SETCW(oldRoundingMode)
-/* Sun ProC needs sunmath for rounding control on x86 like gcc above.
- *
- *
+/*
+ * Sun ProC needs sunmath for rounding control on x86 like gcc above.
*/
-#if defined(__sun) && defined(__i386) && !defined(__GNUC__)
+#elif defined(__sun)
#include <sunmath.h>
+#define TCL_IEEE_DOUBLE_ROUNDING \
+ ieee_flags("set","precision","double",NULL)
+#define TCL_DEFAULT_DOUBLE_ROUNDING \
+ ieee_flags("clear","precision",NULL,NULL)
+
+/*
+ * Other platforms are assumed to always operate in full IEEE mode, so we make
+ * the macros to go in and out of that mode do nothing.
+ */
+
+#else /* !__GNUC__ && !__sun */
+#define TCL_IEEE_DOUBLE_ROUNDING ((void) 0)
+#define TCL_DEFAULT_DOUBLE_ROUNDING ((void) 0)
+#endif
+#else /* !__i386 */
+#define TCL_IEEE_DOUBLE_ROUNDING ((void) 0)
+#define TCL_DEFAULT_DOUBLE_ROUNDING ((void) 0)
#endif
/*
- * MIPS floating-point units need special settings in control registers
- * to use gradual underflow as we expect. This fix is for the MIPSpro
- * compiler.
+ * MIPS floating-point units need special settings in control registers to use
+ * gradual underflow as we expect. This fix is for the MIPSpro compiler.
*/
+
#if defined(__sgi) && defined(_COMPILER_VERSION)
#include <sys/fpu.h>
#endif
+
/*
* HP's PA_RISC architecture uses 7ff4000000000000 to represent a quiet NaN.
* Everyone else uses 7ff8000000000000. (Why, HP, why?)
*/
#ifdef __hppa
-# define NAN_START 0x7ff4
-# define NAN_MASK (((Tcl_WideUInt) 1) << 50)
+# define NAN_START 0x7ff4
+# define NAN_MASK (((Tcl_WideUInt) 1) << 50)
#else
-# define NAN_START 0x7ff8
-# define NAN_MASK (((Tcl_WideUInt) 1) << 51)
+# define NAN_START 0x7ff8
+# define NAN_MASK (((Tcl_WideUInt) 1) << 51)
#endif
/*
@@ -93,45 +119,44 @@ typedef unsigned int fpu_control_t __attribute__ ((__mode__ (__HI__)));
#define TWO_OVER_3LOG10 0.28952965460216784
#define LOG10_3HALVES_PLUS_FUDGE 0.1760912590558
-/* Definitions of the parts of an IEEE754-format floating point number */
-
-#define SIGN_BIT 0x80000000
- /* Mask for the sign bit in the first
- * word of a double */
-#define EXP_MASK 0x7ff00000
- /* Mask for the exponent field in the
- * first word of a double */
-#define EXP_SHIFT 20
- /* Shift count to make the exponent an
- * integer */
-#define HIDDEN_BIT (((Tcl_WideUInt) 0x00100000) << 32)
- /* Hidden 1 bit for the significand */
-#define HI_ORDER_SIG_MASK 0x000fffff
+/*
+ * Definitions of the parts of an IEEE754-format floating point number.
+ */
+
+#define SIGN_BIT 0x80000000
+ /* Mask for the sign bit in the first word of
+ * a double. */
+#define EXP_MASK 0x7ff00000
+ /* Mask for the exponent field in the first
+ * word of a double. */
+#define EXP_SHIFT 20 /* Shift count to make the exponent an
+ * integer. */
+#define HIDDEN_BIT (((Tcl_WideUInt) 0x00100000) << 32)
+ /* Hidden 1 bit for the significand. */
+#define HI_ORDER_SIG_MASK 0x000fffff
/* Mask for the high-order part of the
* significand in the first word of a
- * double */
-#define SIG_MASK (((Tcl_WideUInt) HI_ORDER_SIG_MASK << 32) \
- | 0xffffffff)
+ * double. */
+#define SIG_MASK (((Tcl_WideUInt) HI_ORDER_SIG_MASK << 32) \
+ | 0xffffffff)
/* Mask for the 52-bit significand. */
-#define FP_PRECISION 53
- /* Number of bits of significand plus the
- * hidden bit */
-#define EXPONENT_BIAS 0x3ff
- /* Bias of the exponent 0 */
-
-/* Derived quantities */
-
-#define TEN_PMAX 22
- /* floor(FP_PRECISION*log(2)/log(5)) */
-#define QUICK_MAX 14
- /* floor((FP_PRECISION-1)*log(2)/log(10)) - 1 */
-#define BLETCH 0x10
- /* Highest power of two that is greater than
- * DBL_MAX_10_EXP, divided by 16 */
-#define DIGIT_GROUP 8
- /* floor(DIGIT_BIT*log(2)/log(10)) */
-
-/* Union used to dismantle floating point numbers. */
+#define FP_PRECISION 53 /* Number of bits of significand plus the
+ * hidden bit. */
+#define EXPONENT_BIAS 0x3ff /* Bias of the exponent 0. */
+
+/*
+ * Derived quantities.
+ */
+
+#define TEN_PMAX 22 /* floor(FP_PRECISION*log(2)/log(5)) */
+#define QUICK_MAX 14 /* floor((FP_PRECISION-1)*log(2)/log(10))-1 */
+#define BLETCH 0x10 /* Highest power of two that is greater than
+ * DBL_MAX_10_EXP, divided by 16. */
+#define DIGIT_GROUP 8 /* floor(DIGIT_BIT*log(2)/log(10)) */
+
+/*
+ * Union used to dismantle floating point numbers.
+ */
typedef union Double {
struct {
@@ -162,7 +187,7 @@ static int log2FLT_RADIX; /* Logarithm of the floating point radix. */
static int mantBits; /* Number of bits in a double's significand */
static mp_int pow5[9]; /* Table of powers of 5**(2**n), up to
* 5**256 */
-static double tiny = 0.0; /* The smallest representable double */
+static double tiny = 0.0; /* The smallest representable double. */
static int maxDigits; /* The maximum number of digits to the left of
* the decimal point of a double. */
static int minDigits; /* The maximum number of digits to the right
@@ -184,10 +209,12 @@ static int n770_fp; /* Flag is 1 on Nokia N770 floating point.
* reversed: if big-endian is 7654 3210,
* and little-endian is 0123 4567,
* then Nokia's FP is 4567 0123;
- * little-endian within the 32-bit words
- * but big-endian between them. */
+ * little-endian within the 32-bit words but
+ * big-endian between them. */
-/* Table of powers of 5 that are small enough to fit in an mp_digit. */
+/*
+ * Table of powers of 5 that are small enough to fit in an mp_digit.
+ */
static const mp_digit dpow5[13] = {
1, 5, 25, 125,
@@ -196,7 +223,10 @@ static const mp_digit dpow5[13] = {
244140625
};
-/* Table of powers: pow5_13[n] = 5**(13*2**(n+1)) */
+/*
+ * Table of powers: pow5_13[n] = 5**(13*2**(n+1))
+ */
+
static mp_int pow5_13[5]; /* Table of powers: 5**13, 5**26, 5**52,
* 5**104, 5**208 */
static const double tens[] = {
@@ -270,68 +300,74 @@ static double MakeHighPrecisionDouble(int signum,
static double MakeLowPrecisionDouble(int signum,
Tcl_WideUInt significand, int nSigDigs,
int exponent);
+#ifdef IEEE_FLOATING_POINT
static double MakeNaN(int signum, Tcl_WideUInt tag);
+#endif
static double RefineApproximation(double approx,
mp_int *exactSignificand, int exponent);
-static void MulPow5(mp_int*, unsigned, mp_int*);
-static int NormalizeRightward(Tcl_WideUInt*);
+static void MulPow5(mp_int *, unsigned, mp_int *);
+static int NormalizeRightward(Tcl_WideUInt *);
static int RequiredPrecision(Tcl_WideUInt);
-static void DoubleToExpAndSig(double, Tcl_WideUInt*, int*, int*);
-static void TakeAbsoluteValue(Double*, int*);
-static char* FormatInfAndNaN(Double*, int*, char**);
-static char* FormatZero(int*, char**);
+static void DoubleToExpAndSig(double, Tcl_WideUInt *, int *,
+ int *);
+static void TakeAbsoluteValue(Double *, int *);
+static char * FormatInfAndNaN(Double *, int *, char **);
+static char * FormatZero(int *, char **);
static int ApproximateLog10(Tcl_WideUInt, int, int);
-static int BetterLog10(double, int, int*);
-static void ComputeScale(int, int, int*, int*, int*, int*);
-static void SetPrecisionLimits(int, int, int*, int*, int*, int*);
-static char* BumpUp(char*, char*, int*);
-static int AdjustRange(double*, int);
-static char* ShorteningQuickFormat(double, int, int, double,
- char*, int*);
-static char* StrictQuickFormat(double, int, int, double,
- char*, int*);
-static char* QuickConversion(double, int, int, int, int, int, int,
- int*, char**);
-static void CastOutPowersOf2(int*, int*, int*);
-static char* ShorteningInt64Conversion(Double*, int, Tcl_WideUInt,
+static int BetterLog10(double, int, int *);
+static void ComputeScale(int, int, int *, int *, int *, int *);
+static void SetPrecisionLimits(int, int, int *, int *, int *,
+ int *);
+static char * BumpUp(char *, char *, int *);
+static int AdjustRange(double *, int);
+static char * ShorteningQuickFormat(double, int, int, double,
+ char *, int *);
+static char * StrictQuickFormat(double, int, int, double,
+ char *, int *);
+static char * QuickConversion(double, int, int, int, int, int, int,
+ int *, char **);
+static void CastOutPowersOf2(int *, int *, int *);
+static char * ShorteningInt64Conversion(Double *, int, Tcl_WideUInt,
int, int, int, int, int, int, int, int, int,
- int, int, int*, char**);
-static char* StrictInt64Conversion(Double*, int, Tcl_WideUInt,
+ int, int, int *, char **);
+static char * StrictInt64Conversion(Double *, int, Tcl_WideUInt,
int, int, int, int, int, int,
- int, int, int*, char**);
-static int ShouldBankerRoundUpPowD(mp_int*, int, int);
-static int ShouldBankerRoundUpToNextPowD(mp_int*, mp_int*,
- int, int, int, mp_int*);
-static char* ShorteningBignumConversionPowD(Double* dPtr,
+ int, int, int *, char **);
+static int ShouldBankerRoundUpPowD(mp_int *, int, int);
+static int ShouldBankerRoundUpToNextPowD(mp_int *, mp_int *,
+ int, int, int, mp_int *);
+static char * ShorteningBignumConversionPowD(Double *dPtr,
int convType, Tcl_WideUInt bw, int b2, int b5,
int m2plus, int m2minus, int m5,
int sd, int k, int len,
- int ilim, int ilim1, int* decpt,
- char** endPtr);
-static char* StrictBignumConversionPowD(Double* dPtr, int convType,
+ int ilim, int ilim1, int *decpt,
+ char **endPtr);
+static char * StrictBignumConversionPowD(Double *dPtr, int convType,
Tcl_WideUInt bw, int b2, int b5,
int sd, int k, int len,
- int ilim, int ilim1, int* decpt,
- char** endPtr);
-static int ShouldBankerRoundUp(mp_int*, mp_int*, int);
-static int ShouldBankerRoundUpToNext(mp_int*, mp_int*, mp_int*,
- int, int, mp_int*);
-static char* ShorteningBignumConversion(Double* dPtr, int convType,
+ int ilim, int ilim1, int *decpt,
+ char **endPtr);
+static int ShouldBankerRoundUp(mp_int *, mp_int *, int);
+static int ShouldBankerRoundUpToNext(mp_int *, mp_int *,
+ mp_int *, int, int, mp_int *);
+static char * ShorteningBignumConversion(Double *dPtr, int convType,
Tcl_WideUInt bw, int b2,
int m2plus, int m2minus,
int s2, int s5, int k, int len,
- int ilim, int ilim1, int* decpt,
- char** endPtr);
-static char* StrictBignumConversion(Double* dPtr, int convType,
+ int ilim, int ilim1, int *decpt,
+ char **endPtr);
+static char * StrictBignumConversion(Double *dPtr, int convType,
Tcl_WideUInt bw, int b2,
int s2, int s5, int k, int len,
- int ilim, int ilim1, int* decpt,
- char** endPtr);
-static double BignumToBiasedFrExp(mp_int *big, int *machexp);
+ int ilim, int ilim1, int *decpt,
+ char **endPtr);
+static double BignumToBiasedFrExp(const mp_int *big, int *machexp);
static double Pow10TimesFrExp(int exponent, double fraction,
int *machexp);
static double SafeLdExp(double fraction, int exponent);
+#ifdef IEEE_FLOATING_POINT
static Tcl_WideUInt Nokia770Twiddle(Tcl_WideUInt w);
+#endif
/*
*----------------------------------------------------------------------
@@ -360,14 +396,17 @@ static Tcl_WideUInt Nokia770Twiddle(Tcl_WideUInt w);
* - TCL_PARSE_SCAN_PREFIXES: ignore the prefixes 0b and 0o that are
* not part of the [scan] command's vocabulary. Use only in
* combination with TCL_PARSE_INTEGER_ONLY.
- * - TCL_PARSE_OCTAL_ONLY: parse only in the octal format, whether
+ * - TCL_PARSE_BINARY_ONLY: parse only in the binary format, whether
+ * or not a prefix is present that would lead to binary parsing.
+ * Use only in combination with TCL_PARSE_INTEGER_ONLY.
+ * - TCL_PARSE_OCTAL_ONLY: parse only in the octal format, whether
* or not a prefix is present that would lead to octal parsing.
* Use only in combination with TCL_PARSE_INTEGER_ONLY.
- * - TCL_PARSE_HEXADECIMAL_ONLY: parse only in the hexadecimal format,
+ * - TCL_PARSE_HEXADECIMAL_ONLY: parse only in the hexadecimal format,
* whether or not a prefix is present that would lead to
* hexadecimal parsing. Use only in combination with
* TCL_PARSE_INTEGER_ONLY.
- * - TCL_PARSE_DECIMAL_ONLY: parse only in the decimal format, no
+ * - TCL_PARSE_DECIMAL_ONLY: parse only in the decimal format, no
* matter whether a 0 prefix would normally force a different
* base.
* - TCL_PARSE_NO_WHITESPACE: reject any leading/trailing whitespace
@@ -461,38 +500,38 @@ TclParseNumber(
} state = INITIAL;
enum State acceptState = INITIAL;
- int signum = 0; /* Sign of the number being parsed */
+ int signum = 0; /* Sign of the number being parsed. */
Tcl_WideUInt significandWide = 0;
/* Significand of the number being parsed (if
- * no overflow) */
+ * no overflow). */
mp_int significandBig; /* Significand of the number being parsed (if
- * it overflows significandWide) */
- int significandOverflow = 0;/* Flag==1 iff significandBig is used */
+ * it overflows significandWide). */
+ int significandOverflow = 0;/* Flag==1 iff significandBig is used. */
Tcl_WideUInt octalSignificandWide = 0;
/* Significand of an octal number; needed
* because we don't know whether a number with
* a leading zero is octal or decimal until
- * we've scanned forward to a '.' or 'e' */
+ * we've scanned forward to a '.' or 'e'. */
mp_int octalSignificandBig; /* Significand of octal number once
- * octalSignificandWide overflows */
+ * octalSignificandWide overflows. */
int octalSignificandOverflow = 0;
- /* Flag==1 if octalSignificandBig is used */
+ /* Flag==1 if octalSignificandBig is used. */
int numSigDigs = 0; /* Number of significant digits in the decimal
- * significand */
+ * significand. */
int numTrailZeros = 0; /* Number of trailing zeroes at the current
* point in the parse. */
int numDigitsAfterDp = 0; /* Number of digits scanned after the decimal
- * point */
+ * point. */
int exponentSignum = 0; /* Signum of the exponent of a floating point
- * number */
- long exponent = 0; /* Exponent of a floating point number */
- const char *p; /* Pointer to next character to scan */
- size_t len; /* Number of characters remaining after p */
+ * number. */
+ long exponent = 0; /* Exponent of a floating point number. */
+ const char *p; /* Pointer to next character to scan. */
+ size_t len; /* Number of characters remaining after p. */
const char *acceptPoint; /* Pointer to position after last character in
- * an acceptable number */
+ * an acceptable number. */
size_t acceptLen; /* Number of characters following that
* point. */
- int status = TCL_OK; /* Status to return to caller */
+ int status = TCL_OK; /* Status to return to caller. */
char d = 0; /* Last hexadecimal digit scanned; initialized
* to avoid a compiler warning. */
int shift = 0; /* Amount to shift when accumulating binary */
@@ -554,6 +593,8 @@ TclParseNumber(
break;
} else if (flags & TCL_PARSE_HEXADECIMAL_ONLY) {
goto zerox;
+ } else if (flags & TCL_PARSE_BINARY_ONLY) {
+ goto zerob;
} else if (flags & TCL_PARSE_OCTAL_ONLY) {
goto zeroo;
} else if (isdigit(UCHAR(c))) {
@@ -580,16 +621,16 @@ TclParseNumber(
case ZERO:
/*
* Scanned a leading zero (perhaps with a + or -). Acceptable
- * inputs are digits, period, X, b, and E. If 8 or 9 is encountered,
- * the number can't be octal. This state and the OCTAL state
- * differ only in whether they recognize 'X' and 'b'.
+ * inputs are digits, period, X, b, and E. If 8 or 9 is
+ * encountered, the number can't be octal. This state and the
+ * OCTAL state differ only in whether they recognize 'X' and 'b'.
*/
acceptState = state;
acceptPoint = p;
acceptLen = len;
if (c == 'x' || c == 'X') {
- if (flags & TCL_PARSE_OCTAL_ONLY) {
+ if (flags & (TCL_PARSE_OCTAL_ONLY|TCL_PARSE_BINARY_ONLY)) {
goto endgame;
}
state = ZERO_X;
@@ -608,6 +649,9 @@ TclParseNumber(
state = ZERO_B;
break;
}
+ if (flags & TCL_PARSE_BINARY_ONLY) {
+ goto zerob;
+ }
if (c == 'o' || c == 'O') {
explicitOctal = 1;
state = ZERO_O;
@@ -793,6 +837,7 @@ TclParseNumber(
acceptPoint = p;
acceptLen = len;
case ZERO_B:
+ zerob:
if (c == '0') {
numTrailZeros++;
state = BINARY;
@@ -1181,7 +1226,7 @@ TclParseNumber(
case OCTAL:
/*
- * Returning an octal integer. Final scaling step
+ * Returning an octal integer. Final scaling step.
*/
shift = 3 * numTrailZeros;
@@ -1203,7 +1248,7 @@ TclParseNumber(
if (!octalSignificandOverflow) {
if (octalSignificandWide >
(Tcl_WideUInt)(((~(unsigned long)0) >> 1) + signum)) {
-#ifndef NO_WIDE_TYPE
+#ifndef TCL_WIDE_INT_IS_LONG
if (octalSignificandWide <= (MOST_BITS + signum)) {
objPtr->typePtr = &tclWideIntType;
if (signum) {
@@ -1242,7 +1287,7 @@ TclParseNumber(
case DECIMAL:
significandOverflow = AccumulateDecimalDigit(0, numTrailZeros-1,
&significandWide, &significandBig, significandOverflow);
- if (!significandOverflow && (significandWide > MOST_BITS+signum)) {
+ if (!significandOverflow && (significandWide > MOST_BITS+signum)){
significandOverflow = 1;
TclBNInitBignumFromWideUInt(&significandBig, significandWide);
}
@@ -1250,7 +1295,7 @@ TclParseNumber(
if (!significandOverflow) {
if (significandWide >
(Tcl_WideUInt)(((~(unsigned long)0) >> 1) + signum)) {
-#ifndef NO_WIDE_TYPE
+#ifndef TCL_WIDE_INT_IS_LONG
if (significandWide <= MOST_BITS+signum) {
objPtr->typePtr = &tclWideIntType;
if (signum) {
@@ -1298,16 +1343,16 @@ TclParseNumber(
objPtr->typePtr = &tclDoubleType;
if (exponentSignum) {
- exponent = - exponent;
+ exponent = -exponent;
}
if (!significandOverflow) {
objPtr->internalRep.doubleValue = MakeLowPrecisionDouble(
signum, significandWide, numSigDigs,
- (numTrailZeros + exponent - numDigitsAfterDp));
+ numTrailZeros + exponent - numDigitsAfterDp);
} else {
objPtr->internalRep.doubleValue = MakeHighPrecisionDouble(
signum, &significandBig, numSigDigs,
- (numTrailZeros + exponent - numDigitsAfterDp));
+ numTrailZeros + exponent - numDigitsAfterDp);
}
break;
@@ -1324,12 +1369,12 @@ TclParseNumber(
#ifdef IEEE_FLOATING_POINT
case sNAN:
case sNANFINISH:
- objPtr->internalRep.doubleValue = MakeNaN(signum, significandWide);
+ objPtr->internalRep.doubleValue = MakeNaN(signum,significandWide);
objPtr->typePtr = &tclDoubleType;
break;
#endif
case INITIAL:
- /* This case only to silence compiler warning */
+ /* This case only to silence compiler warning. */
Tcl_Panic("TclParseNumber: state INITIAL can't happen here");
}
}
@@ -1340,11 +1385,9 @@ TclParseNumber(
if (status != TCL_OK) {
if (interp != NULL) {
- Tcl_Obj *msg;
+ Tcl_Obj *msg = Tcl_ObjPrintf("expected %s but got \"",
+ expected);
- TclNewLiteralStringObj(msg, "expected ");
- Tcl_AppendToObj(msg, expected, -1);
- Tcl_AppendToObj(msg, " but got \"", -1);
Tcl_AppendLimitedToObj(msg, bytes, numBytes, 50, "");
Tcl_AppendToObj(msg, "\"", -1);
if (state == BAD_OCTAL) {
@@ -1401,7 +1444,7 @@ AccumulateDecimalDigit(
Tcl_WideUInt w;
/*
- * Try wide multiplication first
+ * Try wide multiplication first.
*/
if (!bignumFlag) {
@@ -1414,10 +1457,10 @@ AccumulateDecimalDigit(
*wideRepPtr = digit;
return 0;
} else if (numZeros >= maxpow10_wide
- || w > ((~(Tcl_WideUInt)0)-digit)/pow10_wide[numZeros+1]) {
+ || w > ((~(Tcl_WideUInt)0)-digit)/pow10_wide[numZeros+1]) {
/*
- * Wide multiplication will overflow. Expand the
- * number to a bignum and fall through into the bignum case.
+ * Wide multiplication will overflow. Expand the number to a
+ * bignum and fall through into the bignum case.
*/
TclBNInitBignumFromWideUInt(bignumRepPtr, w);
@@ -1425,6 +1468,7 @@ AccumulateDecimalDigit(
/*
* Wide multiplication.
*/
+
*wideRepPtr = w * pow10_wide[numZeros+1] + digit;
return 0;
}
@@ -1492,12 +1536,12 @@ AccumulateDecimalDigit(
static double
MakeLowPrecisionDouble(
int signum, /* 1 if the number is negative, 0 otherwise */
- Tcl_WideUInt significand, /* Significand of the number */
- int numSigDigs, /* Number of digits in the significand */
- int exponent) /* Power of ten */
+ Tcl_WideUInt significand, /* Significand of the number. */
+ int numSigDigs, /* Number of digits in the significand. */
+ int exponent) /* Power of ten. */
{
- double retval; /* Value of the number */
- mp_int significandBig; /* Significand expressed as a bignum */
+ double retval; /* Value of the number. */
+ mp_int significandBig; /* Significand expressed as a bignum. */
/*
* With gcc on x86, the floating point rounding mode is double-extended.
@@ -1507,15 +1551,7 @@ MakeLowPrecisionDouble(
* ulp, so we need to change rounding mode to 53-bits.
*/
-#if defined(__GNUC__) && defined(__i386)
- fpu_control_t roundTo53Bits = 0x027f;
- fpu_control_t oldRoundingMode;
- _FPU_GETCW(oldRoundingMode);
- _FPU_SETCW(roundTo53Bits);
-#endif
-#if defined(__sun) && defined(__i386) && !defined(__GNUC__)
- ieee_flags("set","precision","double",NULL);
-#endif
+ TCL_IEEE_DOUBLE_ROUNDING;
/*
* Test for the easy cases.
@@ -1530,10 +1566,12 @@ MakeLowPrecisionDouble(
* without special handling.
*/
- retval = (double)(Tcl_WideInt)significand * pow10vals[exponent];
+ retval = (double)
+ ((Tcl_WideInt)significand * pow10vals[exponent]);
goto returnValue;
} else {
int diff = QUICK_MAX - numSigDigs;
+
if (exponent-diff <= mmaxpow) {
/*
* 10**exponent is not an exact integer, but
@@ -1542,8 +1580,8 @@ MakeLowPrecisionDouble(
* with only one roundoff.
*/
- volatile double factor =
- (double)(Tcl_WideInt)significand * pow10vals[diff];
+ volatile double factor = (double)
+ ((Tcl_WideInt)significand * pow10vals[diff]);
retval = factor * pow10vals[exponent-diff];
goto returnValue;
}
@@ -1556,7 +1594,8 @@ MakeLowPrecisionDouble(
* only one rounding.
*/
- retval = (double)(Tcl_WideInt)significand / pow10vals[-exponent];
+ retval = (double)
+ ((Tcl_WideInt)significand / pow10vals[-exponent]);
goto returnValue;
}
}
@@ -1585,12 +1624,7 @@ MakeLowPrecisionDouble(
* On gcc on x86, restore the floating point mode word.
*/
-#if defined(__GNUC__) && defined(__i386)
- _FPU_SETCW(oldRoundingMode);
-#endif
-#if defined(__sun) && defined(__i386) && !defined(__GNUC__)
- ieee_flags("clear","precision",NULL,NULL);
-#endif
+ TCL_DEFAULT_DOUBLE_ROUNDING;
return retval;
}
@@ -1615,13 +1649,13 @@ MakeLowPrecisionDouble(
static double
MakeHighPrecisionDouble(
- int signum, /* 1=negative, 0=nonnegative */
- mp_int *significand, /* Exact significand of the number */
- int numSigDigs, /* Number of significant digits */
- int exponent) /* Power of 10 by which to multiply */
+ int signum, /* 1=negative, 0=nonnegative. */
+ mp_int *significand, /* Exact significand of the number. */
+ int numSigDigs, /* Number of significant digits. */
+ int exponent) /* Power of 10 by which to multiply. */
{
double retval;
- int machexp; /* Machine exponent of a power of 10 */
+ int machexp; /* Machine exponent of a power of 10. */
/*
* With gcc on x86, the floating point rounding mode is double-extended.
@@ -1631,15 +1665,7 @@ MakeHighPrecisionDouble(
* ulp, so we need to change rounding mode to 53-bits.
*/
-#if defined(__GNUC__) && defined(__i386)
- fpu_control_t roundTo53Bits = 0x027f;
- fpu_control_t oldRoundingMode;
- _FPU_GETCW(oldRoundingMode);
- _FPU_SETCW(roundTo53Bits);
-#endif
-#if defined(__sun) && defined(__i386) && !defined(__GNUC__)
- ieee_flags("set","precision","double",NULL);
-#endif
+ TCL_IEEE_DOUBLE_ROUNDING;
/*
* Quick checks for over/underflow.
@@ -1670,9 +1696,9 @@ MakeHighPrecisionDouble(
goto returnValue;
}
retval = SafeLdExp(retval, machexp);
- if (tiny == 0.0) {
- tiny = SafeLdExp(1.0, DBL_MIN_EXP * log2FLT_RADIX - mantBits);
- }
+ if (tiny == 0.0) {
+ tiny = SafeLdExp(1.0, DBL_MIN_EXP * log2FLT_RADIX - mantBits);
+ }
if (retval < tiny) {
retval = tiny;
}
@@ -1698,12 +1724,8 @@ MakeHighPrecisionDouble(
* On gcc on x86, restore the floating point mode word.
*/
-#if defined(__GNUC__) && defined(__i386)
- _FPU_SETCW(oldRoundingMode);
-#endif
-#if defined(__sun) && defined(__i386) && !defined(__GNUC__)
- ieee_flags("clear","precision",NULL,NULL);
-#endif
+ TCL_DEFAULT_DOUBLE_ROUNDING;
+
return retval;
}
@@ -1722,8 +1744,8 @@ MakeHighPrecisionDouble(
#ifdef IEEE_FLOATING_POINT
static double
MakeNaN(
- int signum, /* Sign bit (1=negative, 0=nonnegative */
- Tcl_WideUInt tags) /* Tag bits to put in the NaN */
+ int signum, /* Sign bit (1=negative, 0=nonnegative. */
+ Tcl_WideUInt tags) /* Tag bits to put in the NaN. */
{
union {
Tcl_WideUInt iv;
@@ -1761,28 +1783,28 @@ MakeNaN(
static double
RefineApproximation(
- double approxResult, /* Approximate result of conversion */
- mp_int *exactSignificand, /* Integer significand */
- int exponent) /* Power of 10 to multiply by significand */
+ double approxResult, /* Approximate result of conversion. */
+ mp_int *exactSignificand, /* Integer significand. */
+ int exponent) /* Power of 10 to multiply by significand. */
{
int M2, M5; /* Powers of 2 and of 5 needed to put the
* decimal and binary numbers over a common
* denominator. */
- double significand; /* Sigificand of the binary number */
- int binExponent; /* Exponent of the binary number */
+ double significand; /* Sigificand of the binary number. */
+ int binExponent; /* Exponent of the binary number. */
int msb; /* Most significant bit position of an
- * intermediate result */
+ * intermediate result. */
int nDigits; /* Number of mp_digit's in an intermediate
- * result */
+ * result. */
mp_int twoMv; /* Approx binary value expressed as an exact
- * integer scaled by the multiplier 2M */
+ * integer scaled by the multiplier 2M. */
mp_int twoMd; /* Exact decimal value expressed as an exact
- * integer scaled by the multiplier 2M */
- int scale; /* Scale factor for M */
- int multiplier; /* Power of two to scale M */
+ * integer scaled by the multiplier 2M. */
+ int scale; /* Scale factor for M. */
+ int multiplier; /* Power of two to scale M. */
double num, den; /* Numerator and denominator of the correction
- * term */
- double quot; /* Correction term */
+ * term. */
+ double quot; /* Correction term. */
double minincr; /* Lower bound on the absolute value of the
* correction term. */
int roundToEven = 0; /* Flag == TRUE if we need to invoke
@@ -1818,8 +1840,8 @@ RefineApproximation(
M5 = 0;
} else {
M5 = -exponent;
- if ((M5-1) > M2) {
- M2 = M5-1;
+ if (M5 - 1 > M2) {
+ M2 = M5 - 1;
}
}
@@ -1858,7 +1880,7 @@ RefineApproximation(
mp_init_copy(&twoMd, exactSignificand);
for (i=0; i<=8; ++i) {
- if ((M5+exponent) & (1 << i)) {
+ if ((M5 + exponent) & (1 << i)) {
mp_mul(&twoMd, pow5+i, &twoMd);
}
}
@@ -1868,7 +1890,7 @@ RefineApproximation(
/*
* The result, 2Mv-2Md, needs to be divided by 2M to yield a correction
* term. Because 2M may well overflow a double, we need to scale the
- * denominator by a factor of 2**binExponent-mantBits
+ * denominator by a factor of 2**binExponent-mantBits.
*/
scale = binExponent - mantBits - 1;
@@ -1892,8 +1914,8 @@ RefineApproximation(
* If the result is less than unity, the error is less than 1/2 unit in
* the last place, so there's no correction to make.
*/
- mp_clear(&twoMd);
- mp_clear(&twoMv);
+ mp_clear(&twoMd);
+ mp_clear(&twoMv);
return approxResult;
case MP_EQ:
/*
@@ -1909,8 +1931,8 @@ RefineApproximation(
rteSignificand = frexp(approxResult, &rteExponent);
rteSigWide = (Tcl_WideInt) ldexp(rteSignificand, FP_PRECISION);
if ((rteSigWide & 1) == 0) {
- mp_clear(&twoMd);
- mp_clear(&twoMv);
+ mp_clear(&twoMd);
+ mp_clear(&twoMv);
return approxResult;
}
}
@@ -1939,26 +1961,28 @@ RefineApproximation(
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* MultPow5 --
*
* Multiply a bignum by a power of 5.
*
* Side effects:
- * Stores base*5**n in result
+ * Stores base*5**n in result.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-MulPow5(mp_int* base, /* Number to multiply */
- unsigned n, /* Power of 5 to multiply by */
- mp_int* result) /* Place to store the result */
+MulPow5(
+ mp_int *base, /* Number to multiply. */
+ unsigned n, /* Power of 5 to multiply by. */
+ mp_int *result) /* Place to store the result. */
{
- mp_int* p = base;
+ mp_int *p = base;
int n13 = n / 13;
int r = n % 13;
+
if (r != 0) {
mp_mul_d(p, dpow5[r], result);
p = result;
@@ -1976,14 +2000,14 @@ MulPow5(mp_int* base, /* Number to multiply */
mp_copy(p, result);
}
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* NormalizeRightward --
*
- * Shifts a number rightward until it is odd (that is, until the
- * least significant bit is nonzero.
+ * Shifts a number rightward until it is odd (that is, until the least
+ * significant bit is nonzero.
*
* Results:
* Returns the number of bit positions by which the number was shifted.
@@ -1991,15 +2015,16 @@ MulPow5(mp_int* base, /* Number to multiply */
* Side effects:
* Shifts the number in place; *wPtr is replaced by the shifted number.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-NormalizeRightward(Tcl_WideUInt* wPtr)
- /* INOUT: Number to shift */
+NormalizeRightward(
+ Tcl_WideUInt *wPtr) /* INOUT: Number to shift. */
{
int rv = 0;
Tcl_WideUInt w = *wPtr;
+
if (!(w & (Tcl_WideUInt) 0xffffffff)) {
w >>= 32; rv += 32;
}
@@ -2021,27 +2046,28 @@ NormalizeRightward(Tcl_WideUInt* wPtr)
*wPtr = w;
return rv;
}
-
+
/*
- *-----------------------------------------------------------------------------0
+ *----------------------------------------------------------------------
*
* RequiredPrecision --
*
* Determines the number of bits needed to hold an intger.
*
* Results:
- * Returns the position of the most significant bit (0 - 63).
- * Returns 0 if the number is zero.
+ * Returns the position of the most significant bit (0 - 63). Returns 0
+ * if the number is zero.
*
- *----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
static int
-RequiredPrecision(Tcl_WideUInt w)
- /* Number to interrogate */
+RequiredPrecision(
+ Tcl_WideUInt w) /* Number to interrogate. */
{
int rv;
unsigned long wi;
+
if (w & ((Tcl_WideUInt) 0xffffffff << 32)) {
wi = (unsigned long) (w >> 32); rv = 32;
} else {
@@ -2067,38 +2093,40 @@ RequiredPrecision(Tcl_WideUInt w)
}
return rv;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* DoubleToExpAndSig --
*
* Separates a 'double' into exponent and significand.
*
* Side effects:
- * Stores the significand in '*significand' and the exponent in
- * '*expon' so that dv == significand * 2.0**expon, and significand
- * is odd. Also stores the position of the leftmost 1-bit in 'significand'
- * in 'bits'.
+ * Stores the significand in '*significand' and the exponent in '*expon'
+ * so that dv == significand * 2.0**expon, and significand is odd. Also
+ * stores the position of the leftmost 1-bit in 'significand' in 'bits'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-DoubleToExpAndSig(double dv, /* Number to convert */
- Tcl_WideUInt* significand,
- /* OUTPUT: Significand of the number */
- int* expon, /* OUTPUT: Exponent to multiply the number by */
- int* bits) /* OUTPUT: Number of significant bits */
+DoubleToExpAndSig(
+ double dv, /* Number to convert. */
+ Tcl_WideUInt *significand, /* OUTPUT: Significand of the number. */
+ int *expon, /* OUTPUT: Exponent to multiply the number
+ * by. */
+ int *bits) /* OUTPUT: Number of significant bits. */
{
- Double d; /* Number being converted */
- Tcl_WideUInt z; /* Significand under construction */
- int de; /* Exponent of the number */
- int k; /* Bit count */
+ Double d; /* Number being converted. */
+ Tcl_WideUInt z; /* Significand under construction. */
+ int de; /* Exponent of the number. */
+ int k; /* Bit count. */
d.d = dv;
- /* Extract exponent and significand */
+ /*
+ * Extract exponent and significand.
+ */
de = (d.w.word0 & EXP_MASK) >> EXP_SHIFT;
z = d.q & SIG_MASK;
@@ -2114,24 +2142,25 @@ DoubleToExpAndSig(double dv, /* Number to convert */
}
*significand = z;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* TakeAbsoluteValue --
*
* Takes the absolute value of a 'double' including 0, Inf and NaN
*
* Side effects:
- * The 'double' in *d is replaced with its absolute value. The
- * signum is stored in 'sign': 1 for negative, 0 for nonnegative.
+ * The 'double' in *d is replaced with its absolute value. The signum is
+ * stored in 'sign': 1 for negative, 0 for nonnegative.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-TakeAbsoluteValue(Double* d, /* Number to replace with absolute value */
- int* sign) /* Place to put the signum */
+TakeAbsoluteValue(
+ Double *d, /* Number to replace with absolute value. */
+ int *sign) /* Place to put the signum. */
{
if (d->w.word0 & SIGN_BIT) {
*sign = 1;
@@ -2140,32 +2169,33 @@ TakeAbsoluteValue(Double* d, /* Number to replace with absolute value */
*sign = 0;
}
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* FormatInfAndNaN --
*
* Bailout for formatting infinities and Not-A-Number.
*
* Results:
- * Returns one of the strings 'Infinity' and 'NaN'.
+ * Returns one of the strings 'Infinity' and 'NaN'. The string returned
+ * must be freed by the caller using 'ckfree'.
*
* Side effects:
- * Stores 9999 in *decpt, and sets '*endPtr' to designate the
- * terminating NUL byte of the string if 'endPtr' is not NULL.
+ * Stores 9999 in *decpt, and sets '*endPtr' to designate the terminating
+ * NUL byte of the string if 'endPtr' is not NULL.
*
- * The string returned must be freed by the caller using 'ckfree'.
- *
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-FormatInfAndNaN(Double* d, /* Exceptional number to format */
- int* decpt, /* Decimal point to set to a bogus value */
- char** endPtr) /* Pointer to the end of the formatted data */
+inline static char *
+FormatInfAndNaN(
+ Double *d, /* Exceptional number to format. */
+ int *decpt, /* Decimal point to set to a bogus value. */
+ char **endPtr) /* Pointer to the end of the formatted data */
{
- char* retval;
+ char *retval;
+
*decpt = 9999;
if (!(d->w.word1) && !(d->w.word0 & HI_ORDER_SIG_MASK)) {
retval = ckalloc(9);
@@ -2182,9 +2212,9 @@ FormatInfAndNaN(Double* d, /* Exceptional number to format */
}
return retval;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* FormatZero --
*
@@ -2197,14 +2227,16 @@ FormatInfAndNaN(Double* d, /* Exceptional number to format */
* Stores 1 in '*decpt' and puts a pointer to the NUL byte terminating
* the string in '*endPtr' if 'endPtr' is not NULL.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-FormatZero(int* decpt, /* Location of the decimal point */
- char** endPtr) /* Pointer to the end of the formatted data */
+inline static char *
+FormatZero(
+ int *decpt, /* Location of the decimal point. */
+ char **endPtr) /* Pointer to the end of the formatted data */
{
- char* retval = ckalloc(2);
+ char *retval = ckalloc(2);
+
strcpy(retval, "0");
if (endPtr) {
*endPtr = retval+1;
@@ -2212,31 +2244,31 @@ FormatZero(int* decpt, /* Location of the decimal point */
*decpt = 0;
return retval;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ApproximateLog10 --
*
- * Computes a two-term Taylor series approximation to the common
- * log of a number, and computes the number's binary log.
+ * Computes a two-term Taylor series approximation to the common log of a
+ * number, and computes the number's binary log.
*
* Results:
- * Return an approximation to floor(log10(bw*2**be)) that is either
- * exact or 1 too high.
+ * Return an approximation to floor(log10(bw*2**be)) that is either exact
+ * or 1 too high.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-ApproximateLog10(Tcl_WideUInt bw,
- /* Integer significand of the number */
- int be, /* Power of two to scale bw */
- int bbits) /* Number of bits of precision in bw */
+ApproximateLog10(
+ Tcl_WideUInt bw, /* Integer significand of the number. */
+ int be, /* Power of two to scale bw. */
+ int bbits) /* Number of bits of precision in bw. */
{
- int i; /* Log base 2 of the number */
+ int i; /* Log base 2 of the number. */
int k; /* Floor(Log base 10 of the number) */
- double ds; /* Mantissa of the number */
+ double ds; /* Mantissa of the number. */
Double d2;
/*
@@ -2250,17 +2282,16 @@ ApproximateLog10(Tcl_WideUInt bw,
d2.w.word0 |= (EXPONENT_BIAS) << EXP_SHIFT;
i = be + bbits - 1;
ds = (d2.d - 1.5) * TWO_OVER_3LOG10
- + LOG10_3HALVES_PLUS_FUDGE
- + LOG10_2 * i;
+ + LOG10_3HALVES_PLUS_FUDGE + LOG10_2 * i;
k = (int) ds;
if (k > ds) {
--k;
}
return k;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* BetterLog10 --
*
@@ -2268,24 +2299,27 @@ ApproximateLog10(Tcl_WideUInt bw,
* 1 .. 10**(TEN_PMAX)-1
*
* Side effects:
- * Sets k_check to 0 if the new result is known to be exact, and to
- * 1 if it may still be one too high.
+ * Sets k_check to 0 if the new result is known to be exact, and to 1 if
+ * it may still be one too high.
*
* Results:
- * Returns the improved approximation to log10(d)
+ * Returns the improved approximation to log10(d).
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-BetterLog10(double d, /* Original number to format */
- int k, /* Characteristic(Log base 10) of the number */
- int* k_check) /* Flag == 1 if k is inexact */
+BetterLog10(
+ double d, /* Original number to format. */
+ int k, /* Characteristic(Log base 10) of the
+ * number. */
+ int *k_check) /* Flag == 1 if k is inexact. */
{
/*
- * Performance hack. If k is in the range 0..TEN_PMAX, then we can
- * use a powers-of-ten table to check it.
+ * Performance hack. If k is in the range 0..TEN_PMAX, then we can use a
+ * powers-of-ten table to check it.
*/
+
if (k >= 0 && k <= TEN_PMAX) {
if (d < tens[k]) {
k--;
@@ -2296,40 +2330,41 @@ BetterLog10(double d, /* Original number to format */
}
return k;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ComputeScale --
*
* Prepares to format a floating-point number as decimal.
*
* Parameters:
- * floor(log10*x) is k (or possibly k-1). floor(log2(x) is i.
- * The significand of x requires bbits bits to represent.
+ * floor(log10*x) is k (or possibly k-1). floor(log2(x) is i. The
+ * significand of x requires bbits bits to represent.
*
* Results:
* Determines integers b2, b5, s2, s5 so that sig*2**b2*5**b5/2**s2*2**s5
- * exactly represents the value of the x/10**k. This value will lie
- * in the range [1 .. 10), and allows for computing successive digits
- * by multiplying sig%10 by 10.
+ * exactly represents the value of the x/10**k. This value will lie in
+ * the range [1 .. 10), and allows for computing successive digits by
+ * multiplying sig%10 by 10.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-ComputeScale(int be, /* Exponent part of number: d = bw * 2**be */
- int k, /* Characteristic of log10(number) */
- int* b2, /* OUTPUT: Power of 2 in the numerator */
- int* b5, /* OUTPUT: Power of 5 in the numerator */
- int* s2, /* OUTPUT: Power of 2 in the denominator */
- int* s5) /* OUTPUT: Power of 5 in the denominator */
+ComputeScale(
+ int be, /* Exponent part of number: d = bw * 2**be. */
+ int k, /* Characteristic of log10(number). */
+ int *b2, /* OUTPUT: Power of 2 in the numerator. */
+ int *b5, /* OUTPUT: Power of 5 in the numerator. */
+ int *s2, /* OUTPUT: Power of 2 in the denominator. */
+ int *s5) /* OUTPUT: Power of 5 in the denominator. */
{
-
/*
- * Scale numerator and denominator powers of 2 so that the
- * input binary number is the ratio of integers
+ * Scale numerator and denominator powers of 2 so that the input binary
+ * number is the ratio of integers.
*/
+
if (be <= 0) {
*b2 = 0;
*s2 = -be;
@@ -2339,9 +2374,10 @@ ComputeScale(int be, /* Exponent part of number: d = bw * 2**be */
}
/*
- * Scale numerator and denominator so that the output decimal number
- * is the ratio of integers
+ * Scale numerator and denominator so that the output decimal number is
+ * the ratio of integers.
*/
+
if (k >= 0) {
*b5 = 0;
*s5 = k;
@@ -2354,49 +2390,45 @@ ComputeScale(int be, /* Exponent part of number: d = bw * 2**be */
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* SetPrecisionLimits --
*
- * Determines how many digits of significance should be computed
- * (and, hence, how much memory need be allocated) for formatting a
- * floating point number.
+ * Determines how many digits of significance should be computed (and,
+ * hence, how much memory need be allocated) for formatting a floating
+ * point number.
*
* Given that 'k' is floor(log10(x)):
- * if 'shortest' format is used, there will be at most 18 digits in the result.
+ * if 'shortest' format is used, there will be at most 18 digits in the
+ * result.
* if 'F' format is used, there will be at most 'ndigits' + k + 1 digits
* if 'E' format is used, there will be exactly 'ndigits' digits.
*
* Side effects:
- * Adjusts '*ndigitsPtr' to have a valid value.
- * Stores the maximum memory allocation needed in *iPtr.
- * Sets '*iLimPtr' to the limiting number of digits to convert if k
- * has been guessed correctly, and '*iLim1Ptr' to the limiting number
- * of digits to convert if k has been guessed to be one too high.
+ * Adjusts '*ndigitsPtr' to have a valid value. Stores the maximum memory
+ * allocation needed in *iPtr. Sets '*iLimPtr' to the limiting number of
+ * digits to convert if k has been guessed correctly, and '*iLim1Ptr' to
+ * the limiting number of digits to convert if k has been guessed to be
+ * one too high.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-SetPrecisionLimits(int convType,
- /* Type of conversion:
- * TCL_DD_SHORTEST
- * TCL_DD_STEELE0
- * TCL_DD_E_FMT
- * TCL_DD_F_FMT */
- int k, /* Floor(log10(number to convert)) */
- int* ndigitsPtr,
- /* IN/OUT: Number of digits requested
- * (Will be adjusted if needed) */
- int* iPtr, /* OUT: Maximum number of digits
- * to return */
- int *iLimPtr,/* OUT: Number of digits of significance
- * if the bignum method is used.*/
- int *iLim1Ptr)
- /* OUT: Number of digits of significance
- * if the quick method is used. */
+SetPrecisionLimits(
+ int convType, /* Type of conversion: TCL_DD_SHORTEST,
+ * TCL_DD_STEELE0, TCL_DD_E_FMT,
+ * TCL_DD_F_FMT. */
+ int k, /* Floor(log10(number to convert)) */
+ int *ndigitsPtr, /* IN/OUT: Number of digits requested (will be
+ * adjusted if needed). */
+ int *iPtr, /* OUT: Maximum number of digits to return. */
+ int *iLimPtr, /* OUT: Number of digits of significance if
+ * the bignum method is used.*/
+ int *iLim1Ptr) /* OUT: Number of digits of significance if
+ * the quick method is used. */
{
- switch(convType) {
+ switch (convType) {
case TCL_DD_SHORTEST0:
case TCL_DD_STEELE0:
*iLimPtr = *iLim1Ptr = -1;
@@ -2424,31 +2456,31 @@ SetPrecisionLimits(int convType,
Tcl_Panic("impossible conversion type in TclDoubleDigits");
}
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* BumpUp --
*
- * Increases a string of digits ending in a series of nines to
- * designate the next higher number. xxxxb9999... -> xxxx(b+1)0000...
+ * Increases a string of digits ending in a series of nines to designate
+ * the next higher number. xxxxb9999... -> xxxx(b+1)0000...
*
* Results:
* Returns a pointer to the end of the adjusted string.
*
* Side effects:
- * In the case that the string consists solely of '999999', sets it
- * to "1" and moves the decimal point (*kPtr) one place to the right.
+ * In the case that the string consists solely of '999999', sets it to
+ * "1" and moves the decimal point (*kPtr) one place to the right.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-
-inline static char*
-BumpUp(char* s, /* Cursor pointing one past the end of the
- * string */
- char* retval, /* Start of the string of digits */
- int* kPtr) /* Position of the decimal point */
+inline static char *
+BumpUp(
+ char *s, /* Cursor pointing one past the end of the
+ * string. */
+ char *retval, /* Start of the string of digits. */
+ int *kPtr) /* Position of the decimal point. */
{
while (*--s == '9') {
if (s == retval) {
@@ -2463,27 +2495,28 @@ BumpUp(char* s, /* Cursor pointing one past the end of the
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* AdjustRange --
*
- * Rescales a 'double' in preparation for formatting it using the
- * 'quick' double-to-string method.
+ * Rescales a 'double' in preparation for formatting it using the 'quick'
+ * double-to-string method.
*
* Results:
- * Returns the precision that has been lost in the prescaling as
- * a count of units in the least significant place.
+ * Returns the precision that has been lost in the prescaling as a count
+ * of units in the least significant place.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-AdjustRange(double* dPtr, /* INOUT: Number to adjust */
- int k) /* IN: floor(log10(d)) */
+AdjustRange(
+ double *dPtr, /* INOUT: Number to adjust. */
+ int k) /* IN: floor(log10(d)) */
{
int ieps; /* Number of roundoff errors that have
- * accumulated */
- double d = *dPtr; /* Number to adjust */
+ * accumulated. */
+ double d = *dPtr; /* Number to adjust. */
double ds;
int i, j, j1;
@@ -2493,6 +2526,7 @@ AdjustRange(double* dPtr, /* INOUT: Number to adjust */
/*
* The number must be reduced to bring it into range.
*/
+
ds = tens[k & 0xf];
j = k >> 4;
if (j & BLETCH) {
@@ -2511,8 +2545,9 @@ AdjustRange(double* dPtr, /* INOUT: Number to adjust */
d /= ds;
} else if ((j1 = -k) != 0) {
/*
- * The number must be increased to bring it into range
+ * The number must be increased to bring it into range.
*/
+
d *= tens[j1 & 0xf];
i = 0;
for (j = j1>>4; j; j>>=1) {
@@ -2529,52 +2564,52 @@ AdjustRange(double* dPtr, /* INOUT: Number to adjust */
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShorteningQuickFormat --
*
- * Returns a 'quick' format of a double precision number to a string
- * of digits, preferring a shorter string of digits if the shorter
- * string is still within 1/2 ulp of the number.
+ * Returns a 'quick' format of a double precision number to a string of
+ * digits, preferring a shorter string of digits if the shorter string is
+ * still within 1/2 ulp of the number.
*
* Results:
- * Returns the string of digits. Returns NULL if the 'quick' method
- * fails and the bignum method must be used.
+ * Returns the string of digits. Returns NULL if the 'quick' method fails
+ * and the bignum method must be used.
*
* Side effects:
* Stores the position of the decimal point at '*kPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-ShorteningQuickFormat(double d, /* Number to convert */
- int k, /* floor(log10(d)) */
- int ilim, /* Number of significant digits to return */
- double eps,
- /* Estimated roundoff error */
- char* retval,
- /* Buffer to receive the digit string */
- int* kPtr)
- /* Pointer to stash the position of
- * the decimal point */
+inline static char *
+ShorteningQuickFormat(
+ double d, /* Number to convert. */
+ int k, /* floor(log10(d)) */
+ int ilim, /* Number of significant digits to return. */
+ double eps, /* Estimated roundoff error. */
+ char *retval, /* Buffer to receive the digit string. */
+ int *kPtr) /* Pointer to stash the position of the
+ * decimal point. */
{
- char* s = retval; /* Cursor in the return value */
- int digit; /* Current digit */
+ char *s = retval; /* Cursor in the return value. */
+ int digit; /* Current digit. */
int i;
eps = 0.5 / tens[ilim-1] - eps;
i = 0;
for (;;) {
- /* Convert a digit */
+ /*
+ * Convert a digit.
+ */
digit = (int) d;
d -= digit;
*s++ = '0' + digit;
/*
- * Truncate the conversion if the string of digits is within
- * 1/2 ulp of the actual value.
+ * Truncate the conversion if the string of digits is within 1/2 ulp
+ * of the actual value.
*/
if (d < eps) {
@@ -2588,7 +2623,7 @@ ShorteningQuickFormat(double d, /* Number to convert */
/*
* Bail out if the conversion fails to converge to a sufficiently
- * precise value
+ * precise value.
*/
if (++i >= ilim) {
@@ -2605,40 +2640,44 @@ ShorteningQuickFormat(double d, /* Number to convert */
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* StrictQuickFormat --
*
- * Convert a double precision number of a string of a precise number
- * of digits, using the 'quick' double precision method.
+ * Convert a double precision number of a string of a precise number of
+ * digits, using the 'quick' double precision method.
*
* Results:
- * Returns the digit string, or NULL if the bignum method must be
- * used to do the formatting.
+ * Returns the digit string, or NULL if the bignum method must be used to
+ * do the formatting.
*
* Side effects:
* Stores the position of the decimal point in '*kPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-StrictQuickFormat(double d, /* Number to convert */
- int k, /* floor(log10(d)) */
- int ilim, /* Number of significant digits to return */
- double eps, /* Estimated roundoff error */
- char* retval, /* Start of the digit string */
- int* kPtr) /* Pointer to stash the position of
- * the decimal point */
+inline static char *
+StrictQuickFormat(
+ double d, /* Number to convert. */
+ int k, /* floor(log10(d)) */
+ int ilim, /* Number of significant digits to return. */
+ double eps, /* Estimated roundoff error. */
+ char *retval, /* Start of the digit string. */
+ int *kPtr) /* Pointer to stash the position of the
+ * decimal point. */
{
- char* s = retval; /* Cursor in the return value */
- int digit; /* Current digit of the answer */
+ char *s = retval; /* Cursor in the return value. */
+ int digit; /* Current digit of the answer. */
int i;
eps *= tens[ilim-1];
i = 1;
for (;;) {
- /* Extract a digit */
+ /*
+ * Extract a digit.
+ */
+
digit = (int) d;
d -= digit;
if (d == 0.0) {
@@ -2647,9 +2686,10 @@ StrictQuickFormat(double d, /* Number to convert */
*s++ = '0' + digit;
/*
- * When the given digit count is reached, handle trailing strings
- * of 0 and 9.
+ * When the given digit count is reached, handle trailing strings of 0
+ * and 9.
*/
+
if (i == ilim) {
if (d > 0.5 + eps) {
*kPtr = k;
@@ -2666,14 +2706,17 @@ StrictQuickFormat(double d, /* Number to convert */
}
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
+
++i;
d *= 10.0;
}
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* QuickConversion --
*
@@ -2682,44 +2725,48 @@ StrictQuickFormat(double d, /* Number to convert */
* therefore be used for the intermediate results.
*
* Results:
- * Returns the converted string, or NULL if the bignum method must
- * be used.
+ * Returns the converted string, or NULL if the bignum method must be
+ * used.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-QuickConversion(double e, /* Number to format */
- int k, /* floor(log10(d)), approximately */
- int k_check, /* 0 if k is exact, 1 if it may be too high */
- int flags, /* Flags passed to dtoa:
+inline static char *
+QuickConversion(
+ double e, /* Number to format. */
+ int k, /* floor(log10(d)), approximately. */
+ int k_check, /* 0 if k is exact, 1 if it may be too high */
+ int flags, /* Flags passed to dtoa:
* TCL_DD_SHORTEN_FLAG */
- int len, /* Length of the return value */
- int ilim, /* Number of digits to store */
- int ilim1, /* Number of digits to store if we
- * musguessed k */
- int* decpt, /* OUTPUT: Location of the decimal point */
- char** endPtr) /* OUTPUT: Pointer to the terminal null byte */
+ int len, /* Length of the return value. */
+ int ilim, /* Number of digits to store. */
+ int ilim1, /* Number of digits to store if we misguessed
+ * k. */
+ int *decpt, /* OUTPUT: Location of the decimal point. */
+ char **endPtr) /* OUTPUT: Pointer to the terminal null
+ * byte. */
{
int ieps; /* Number of 1-ulp roundoff errors that have
- * accumulated in the calculation*/
- Double eps; /* Estimated roundoff error */
- char* retval; /* Returned string */
- char* end; /* Pointer to the terminal null byte in the
- * returned string */
+ * accumulated in the calculation. */
+ Double eps; /* Estimated roundoff error. */
+ char *retval; /* Returned string. */
+ char *end; /* Pointer to the terminal null byte in the
+ * returned string. */
volatile double d; /* Workaround for a bug in mingw gcc 3.4.5 */
/*
- * Bring d into the range [1 .. 10)
+ * Bring d into the range [1 .. 10).
*/
+
ieps = AdjustRange(&e, k);
d = e;
/*
- * If the guessed value of k didn't get d into range, adjust it
- * by one. If that leaves us outside the range in which quick format
- * is accurate, bail out.
+ * If the guessed value of k didn't get d into range, adjust it by one. If
+ * that leaves us outside the range in which quick format is accurate,
+ * bail out.
*/
+
if (k_check && d < 1. && ilim > 0) {
if (ilim1 < 0) {
return NULL;
@@ -2731,15 +2778,16 @@ QuickConversion(double e, /* Number to format */
}
/*
- * Compute estimated roundoff error
+ * Compute estimated roundoff error.
*/
+
eps.d = ieps * d + 7.;
eps.w.word0 -= (FP_PRECISION-1) << EXP_SHIFT;
/*
- * Handle the peculiar case where the result has no significant
- * digits.
+ * Handle the peculiar case where the result has no significant digits.
*/
+
retval = ckalloc(len + 1);
if (ilim == 0) {
d -= 5.;
@@ -2756,7 +2804,9 @@ QuickConversion(double e, /* Number to format */
}
}
- /* Format the digit string */
+ /*
+ * Format the digit string.
+ */
if (flags & TCL_DD_SHORTEN_FLAG) {
end = ShorteningQuickFormat(d, k, ilim, eps.d, retval, decpt);
@@ -2775,106 +2825,99 @@ QuickConversion(double e, /* Number to format */
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* CastOutPowersOf2 --
*
- * Adjust the factors 'b2', 'm2', and 's2' to cast out common powers
- * of 2 from numerator and denominator in preparation for the 'bignum'
- * method of floating point conversion.
+ * Adjust the factors 'b2', 'm2', and 's2' to cast out common powers of 2
+ * from numerator and denominator in preparation for the 'bignum' method
+ * of floating point conversion.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static void
-CastOutPowersOf2(int* b2, /* Power of 2 to multiply the significand */
- int* m2, /* Power of 2 to multiply 1/2 ulp */
- int* s2) /* Power of 2 to multiply the common
- * denominator */
+CastOutPowersOf2(
+ int *b2, /* Power of 2 to multiply the significand. */
+ int *m2, /* Power of 2 to multiply 1/2 ulp. */
+ int *s2) /* Power of 2 to multiply the common
+ * denominator. */
{
int i;
+
if (*m2 > 0 && *s2 > 0) { /* Find the smallest power of 2 in the
- * numerator */
- if (*m2 < *s2) { /* Find the lowest common denominatorr */
+ * numerator. */
+ if (*m2 < *s2) { /* Find the lowest common denominator. */
i = *m2;
} else {
i = *s2;
}
- *b2 -= i; /* Reduce to lowest terms */
+ *b2 -= i; /* Reduce to lowest terms. */
*m2 -= i;
*s2 -= i;
}
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShorteningInt64Conversion --
*
- * Converts a double-precision number to the shortest string of
- * digits that reconverts exactly to the given number, or to
- * 'ilim' digits if that will yield a shorter result. The numerator and
- * denominator in David Gay's conversion algorithm are known to fit
- * in Tcl_WideUInt, giving considerably faster arithmetic than mp_int's.
+ * Converts a double-precision number to the shortest string of digits
+ * that reconverts exactly to the given number, or to 'ilim' digits if
+ * that will yield a shorter result. The numerator and denominator in
+ * David Gay's conversion algorithm are known to fit in Tcl_WideUInt,
+ * giving considerably faster arithmetic than mp_int's.
*
* Results:
- * Returns the string of significant decimal digits, in newly
- * allocated memory
+ * Returns the string of significant decimal digits, in newly allocated
+ * memory
*
* Side effects:
- * Stores the location of the decimal point in '*decpt' and the
- * location of the terminal null byte in '*endPtr'.
+ * Stores the location of the decimal point in '*decpt' and the location
+ * of the terminal null byte in '*endPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-ShorteningInt64Conversion(Double* dPtr,
- /* Original number to convert */
- int convType,
- /* Type of conversion (shortest, Steele,
- E format, F format) */
- Tcl_WideUInt bw,
- /* Integer significand */
- int b2, int b5,
- /* Scale factor for the significand
- * in the numerator */
- int m2plus, int m2minus, int m5,
- /* Scale factors for 1/2 ulp in
- * the numerator (will be different if
- * bw == 1 */
- int s2, int s5,
- /* Scale factors for the denominator */
- int k,
- /* Number of output digits before the decimal
- * point */
- int len,
- /* Number of digits to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Position of the terminal '\0'
- * at the end of the returned string */
+inline static char *
+ShorteningInt64Conversion(
+ Double *dPtr, /* Original number to convert. */
+ int convType, /* Type of conversion (shortest, Steele,
+ * E format, F format). */
+ Tcl_WideUInt bw, /* Integer significand. */
+ int b2, int b5, /* Scale factor for the significand in the
+ * numerator. */
+ int m2plus, int m2minus, int m5,
+ /* Scale factors for 1/2 ulp in the numerator
+ * (will be different if bw == 1. */
+ int s2, int s5, /* Scale factors for the denominator. */
+ int k, /* Number of output digits before the decimal
+ * point. */
+ int len, /* Number of digits to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Position of the terminal '\0' at
+ * the end of the returned string. */
{
-
- char* retval = ckalloc(len + 1);
- /* Output buffer */
+ char *retval = ckalloc(len + 1);
+ /* Output buffer. */
Tcl_WideUInt b = (bw * wuipow5[b5]) << b2;
- /* Numerator of the fraction being converted */
+ /* Numerator of the fraction being
+ * converted. */
Tcl_WideUInt S = wuipow5[s5] << s2;
/* Denominator of the fraction being
- * converted */
- Tcl_WideUInt mplus, mminus; /* Ranges for testing whether the result
- * is within roundoff of being exact */
- int digit; /* Current output digit */
- char* s = retval; /* Cursor in the output buffer */
- int i; /* Current position in the output buffer */
+ * converted. */
+ Tcl_WideUInt mplus, mminus; /* Ranges for testing whether the result is
+ * within roundoff of being exact. */
+ int digit; /* Current output digit. */
+ char *s = retval; /* Cursor in the output buffer. */
+ int i; /* Current position in the output buffer. */
- /* Adjust if the logarithm was guessed wrong */
+ /*
+ * Adjust if the logarithm was guessed wrong.
+ */
if (b < S) {
b = 10 * b;
@@ -2883,12 +2926,16 @@ ShorteningInt64Conversion(Double* dPtr,
--k;
}
- /* Compute roundoff ranges */
+ /*
+ * Compute roundoff ranges.
+ */
mplus = wuipow5[m5] << m2plus;
mminus = wuipow5[m5] << m2minus;
- /* Loop through the digits */
+ /*
+ * Loop through the digits.
+ */
i = 1;
for (;;) {
@@ -2902,17 +2949,15 @@ ShorteningInt64Conversion(Double* dPtr,
* Does the current digit put us on the low side of the exact value
* but within within roundoff of being exact?
*/
- if (b < mplus
- || (b == mplus
- && convType != TCL_DD_STEELE0
- && (dPtr->w.word1 & 1) == 0)) {
+
+ if (b < mplus || (b == mplus
+ && convType != TCL_DD_STEELE0 && (dPtr->w.word1 & 1) == 0)) {
/*
- * Make sure we shouldn't be rounding *up* instead,
- * in case the next number above is closer
+ * Make sure we shouldn't be rounding *up* instead, in case the
+ * next number above is closer.
*/
- if (2 * b > S
- || (2 * b == S
- && (digit & 1) != 0)) {
+
+ if (2 * b > S || (2 * b == S && (digit & 1) != 0)) {
++digit;
if (digit == 10) {
*s++ = '9';
@@ -2921,7 +2966,9 @@ ShorteningInt64Conversion(Double* dPtr,
}
}
- /* Stash the current digit */
+ /*
+ * Stash the current digit.
+ */
*s++ = '0' + digit;
break;
@@ -2931,10 +2978,9 @@ ShorteningInt64Conversion(Double* dPtr,
* Does one plus the current digit put us within roundoff of the
* number?
*/
- if (b > S - mminus
- || (b == S - mminus
- && convType != TCL_DD_STEELE0
- && (dPtr->w.word1 & 1) == 0)) {
+
+ if (b > S - mminus || (b == S - mminus
+ && convType != TCL_DD_STEELE0 && (dPtr->w.word1 & 1) == 0)) {
if (digit == 9) {
*s++ = '9';
s = BumpUp(s, retval, &k);
@@ -2948,16 +2994,18 @@ ShorteningInt64Conversion(Double* dPtr,
/*
* Have we converted all the requested digits?
*/
+
*s++ = '0' + digit;
if (i == ilim) {
- if (2*b > S
- || (2*b == S && (digit & 1) != 0)) {
+ if (2*b > S || (2*b == S && (digit & 1) != 0)) {
s = BumpUp(s, retval, &k);
}
break;
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
b = 10 * b;
mplus = 10 * mplus;
@@ -2969,6 +3017,7 @@ ShorteningInt64Conversion(Double* dPtr,
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
*s = '\0';
*decpt = k;
if (endPtr) {
@@ -2978,69 +3027,61 @@ ShorteningInt64Conversion(Double* dPtr,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* StrictInt64Conversion --
*
- * Converts a double-precision number to a fixed-length string of
- * 'ilim' digits that reconverts exactly to the given number.
- * ('ilim' should be replaced with 'ilim1' in the case where
- * log10(d) has been overestimated). The numerator and
- * denominator in David Gay's conversion algorithm are known to fit
- * in Tcl_WideUInt, giving considerably faster arithmetic than mp_int's.
+ * Converts a double-precision number to a fixed-length string of 'ilim'
+ * digits that reconverts exactly to the given number. ('ilim' should be
+ * replaced with 'ilim1' in the case where log10(d) has been
+ * overestimated). The numerator and denominator in David Gay's
+ * conversion algorithm are known to fit in Tcl_WideUInt, giving
+ * considerably faster arithmetic than mp_int's.
*
* Results:
- * Returns the string of significant decimal digits, in newly
- * allocated memory
+ * Returns the string of significant decimal digits, in newly allocated
+ * memory
*
* Side effects:
- * Stores the location of the decimal point in '*decpt' and the
- * location of the terminal null byte in '*endPtr'.
+ * Stores the location of the decimal point in '*decpt' and the location
+ * of the terminal null byte in '*endPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-StrictInt64Conversion(Double* dPtr,
- /* Original number to convert */
- int convType,
- /* Type of conversion (shortest, Steele,
- E format, F format) */
- Tcl_WideUInt bw,
- /* Integer significand */
- int b2, int b5,
- /* Scale factor for the significand
- * in the numerator */
- int s2, int s5,
- /* Scale factors for the denominator */
- int k,
- /* Number of output digits before the decimal
- * point */
- int len,
- /* Number of digits to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Position of the terminal '\0'
- * at the end of the returned string */
+inline static char *
+StrictInt64Conversion(
+ Double *dPtr, /* Original number to convert. */
+ int convType, /* Type of conversion (shortest, Steele,
+ * E format, F format). */
+ Tcl_WideUInt bw, /* Integer significand. */
+ int b2, int b5, /* Scale factor for the significand in the
+ * numerator. */
+ int s2, int s5, /* Scale factors for the denominator. */
+ int k, /* Number of output digits before the decimal
+ * point. */
+ int len, /* Number of digits to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Position of the terminal '\0' at
+ * the end of the returned string. */
{
-
- char* retval = ckalloc(len + 1);
- /* Output buffer */
+ char *retval = ckalloc(len + 1);
+ /* Output buffer. */
Tcl_WideUInt b = (bw * wuipow5[b5]) << b2;
- /* Numerator of the fraction being converted */
+ /* Numerator of the fraction being
+ * converted. */
Tcl_WideUInt S = wuipow5[s5] << s2;
/* Denominator of the fraction being
- * converted */
- int digit; /* Current output digit */
- char* s = retval; /* Cursor in the output buffer */
- int i; /* Current position in the output buffer */
+ * converted. */
+ int digit; /* Current output digit. */
+ char *s = retval; /* Cursor in the output buffer. */
+ int i; /* Current position in the output buffer. */
- /* Adjust if the logarithm was guessed wrong */
+ /*
+ * Adjust if the logarithm was guessed wrong.
+ */
if (b < S) {
b = 10 * b;
@@ -3048,7 +3089,9 @@ StrictInt64Conversion(Double* dPtr,
--k;
}
- /* Loop through the digits */
+ /*
+ * Loop through the digits.
+ */
i = 1;
for (;;) {
@@ -3061,10 +3104,10 @@ StrictInt64Conversion(Double* dPtr,
/*
* Have we converted all the requested digits?
*/
+
*s++ = '0' + digit;
if (i == ilim) {
- if (2*b > S
- || (2*b == S && (digit & 1) != 0)) {
+ if (2*b > S || (2*b == S && (digit & 1) != 0)) {
s = BumpUp(s, retval, &k);
} else {
while (*--s == '0') {
@@ -3075,7 +3118,9 @@ StrictInt64Conversion(Double* dPtr,
break;
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
b = 10 * b;
++i;
@@ -3085,6 +3130,7 @@ StrictInt64Conversion(Double* dPtr,
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
*s = '\0';
*decpt = k;
if (endPtr) {
@@ -3094,30 +3140,30 @@ StrictInt64Conversion(Double* dPtr,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShouldBankerRoundUpPowD --
*
- * Test whether bankers' rounding should round a digit up. Assumption
- * is made that the denominator of the fraction being tested is
- * a power of 2**DIGIT_BIT.
+ * Test whether bankers' rounding should round a digit up. Assumption is
+ * made that the denominator of the fraction being tested is a power of
+ * 2**DIGIT_BIT.
*
* Results:
- * Returns 1 iff the fraction is more than 1/2, or if the fraction
- * is exactly 1/2 and the digit is odd.
+ * Returns 1 iff the fraction is more than 1/2, or if the fraction is
+ * exactly 1/2 and the digit is odd.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-ShouldBankerRoundUpPowD(mp_int* b,
- /* Numerator of the fraction */
- int sd, /* Denominator is 2**(sd*DIGIT_BIT) */
- int isodd)
- /* 1 if the digit is odd, 0 if even */
+ShouldBankerRoundUpPowD(
+ mp_int *b, /* Numerator of the fraction. */
+ int sd, /* Denominator is 2**(sd*DIGIT_BIT). */
+ int isodd) /* 1 if the digit is odd, 0 if even. */
{
int i;
- static const mp_digit topbit = (1<<(DIGIT_BIT-1));
+ static const mp_digit topbit = 1 << (DIGIT_BIT - 1);
+
if (b->used < sd || (b->dp[sd-1] & topbit) == 0) {
return 0;
}
@@ -3133,45 +3179,41 @@ ShouldBankerRoundUpPowD(mp_int* b,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShouldBankerRoundUpToNextPowD --
*
- * Tests whether bankers' rounding will round down in the
- * "denominator is a power of 2**MP_DIGIT" case.
+ * Tests whether bankers' rounding will round down in the "denominator is
+ * a power of 2**MP_DIGIT" case.
*
* Results:
* Returns 1 if the rounding will be performed - which increases the
* digit by one - and 0 otherwise.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-ShouldBankerRoundUpToNextPowD(mp_int* b,
- /* Numerator of the fraction */
- mp_int* m,
- /* Numerator of the rounding tolerance */
- int sd,
- /* Common denominator is 2**(sd*DIGIT_BIT) */
- int convType,
- /* Conversion type: STEELE defeats
- * round-to-even (Not sure why one wants to
- * do this; I copied it from Gay) FIXME */
- int isodd,
- /* 1 if the integer significand is odd */
- mp_int* temp)
- /* Work area for the calculation */
+ShouldBankerRoundUpToNextPowD(
+ mp_int *b, /* Numerator of the fraction. */
+ mp_int *m, /* Numerator of the rounding tolerance. */
+ int sd, /* Common denominator is 2**(sd*DIGIT_BIT). */
+ int convType, /* Conversion type: STEELE defeats
+ * round-to-even (not sure why one wants to do
+ * this; I copied it from Gay). FIXME */
+ int isodd, /* 1 if the integer significand is odd. */
+ mp_int *temp) /* Work area for the calculation. */
{
int i;
/*
- * Compare B and S-m -- which is the same as comparing B+m and S --
- * which we do by computing b+m and doing a bitwhack compare against
+ * Compare B and S-m - which is the same as comparing B+m and S - which we
+ * do by computing b+m and doing a bitwhack compare against
* 2**(DIGIT_BIT*sd)
*/
+
mp_add(b, m, temp);
- if (temp->used <= sd) { /* too few digits to be > S */
+ if (temp->used <= sd) { /* Too few digits to be > s */
return 0;
}
if (temp->used > sd+1 || temp->dp[sd] > 1) {
@@ -3179,81 +3221,70 @@ ShouldBankerRoundUpToNextPowD(mp_int* b,
return 1;
}
for (i = sd-1; i >= 0; --i) {
- /* check for ==s */
+ /* Check for ==s */
if (temp->dp[i] != 0) { /* > s */
return 1;
}
}
if (convType == TCL_DD_STEELE0) {
- /* biased rounding */
+ /* Biased rounding. */
return 0;
}
return isodd;
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShorteningBignumConversionPowD --
*
- * Converts a double-precision number to the shortest string of
- * digits that reconverts exactly to the given number, or to
- * 'ilim' digits if that will yield a shorter result. The denominator
- * in David Gay's conversion algorithm is known to be a power of
- * 2**DIGIT_BIT, and hence the division in the main loop may be replaced
- * by a digit shift and mask.
+ * Converts a double-precision number to the shortest string of digits
+ * that reconverts exactly to the given number, or to 'ilim' digits if
+ * that will yield a shorter result. The denominator in David Gay's
+ * conversion algorithm is known to be a power of 2**DIGIT_BIT, and hence
+ * the division in the main loop may be replaced by a digit shift and
+ * mask.
*
* Results:
- * Returns the string of significant decimal digits, in newly
- * allocated memory
+ * Returns the string of significant decimal digits, in newly allocated
+ * memory
*
* Side effects:
- * Stores the location of the decimal point in '*decpt' and the
- * location of the terminal null byte in '*endPtr'.
+ * Stores the location of the decimal point in '*decpt' and the location
+ * of the terminal null byte in '*endPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-ShorteningBignumConversionPowD(Double* dPtr,
- /* Original number to convert */
- int convType,
- /* Type of conversion (shortest, Steele,
- E format, F format) */
- Tcl_WideUInt bw,
- /* Integer significand */
- int b2, int b5,
- /* Scale factor for the significand
- * in the numerator */
- int m2plus, int m2minus, int m5,
- /* Scale factors for 1/2 ulp in
- * the numerator (will be different if
- * bw == 1 */
- int sd,
- /* Scale factor for the denominator */
- int k,
- /* Number of output digits before the decimal
- * point */
- int len,
- /* Number of digits to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Position of the terminal '\0'
- * at the end of the returned string */
+inline static char *
+ShorteningBignumConversionPowD(
+ Double *dPtr, /* Original number to convert. */
+ int convType, /* Type of conversion (shortest, Steele,
+ * E format, F format). */
+ Tcl_WideUInt bw, /* Integer significand. */
+ int b2, int b5, /* Scale factor for the significand in the
+ * numerator. */
+ int m2plus, int m2minus, int m5,
+ /* Scale factors for 1/2 ulp in the numerator
+ * (will be different if bw == 1). */
+ int sd, /* Scale factor for the denominator. */
+ int k, /* Number of output digits before the decimal
+ * point. */
+ int len, /* Number of digits to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Position of the terminal '\0' at
+ * the end of the returned string. */
{
-
- char* retval = ckalloc(len + 1);
- /* Output buffer */
- mp_int b; /* Numerator of the fraction being converted */
- mp_int mplus, mminus; /* Bounds for roundoff */
- mp_digit digit; /* Current output digit */
- char* s = retval; /* Cursor in the output buffer */
- int i; /* Index in the output buffer */
+ char *retval = ckalloc(len + 1);
+ /* Output buffer. */
+ mp_int b; /* Numerator of the fraction being
+ * converted. */
+ mp_int mplus, mminus; /* Bounds for roundoff. */
+ mp_digit digit; /* Current output digit. */
+ char *s = retval; /* Cursor in the output buffer. */
+ int i; /* Index in the output buffer. */
mp_int temp;
int r1;
@@ -3267,7 +3298,9 @@ ShorteningBignumConversionPowD(Double* dPtr,
MulPow5(&b, b5, &b);
mp_mul_2d(&b, b2, &b);
- /* Adjust if the logarithm was guessed wrong */
+ /*
+ * Adjust if the logarithm was guessed wrong.
+ */
if (b.used <= sd) {
mp_mul_d(&b, 10, &b);
@@ -3289,8 +3322,10 @@ ShorteningBignumConversionPowD(Double* dPtr,
}
mp_init(&temp);
- /* Loop through the digits. Do division and mod by s == 2**(sd*DIGIT_BIT)
- * by mp_digit extraction */
+ /*
+ * Loop through the digits. Do division and mod by s == 2**(sd*DIGIT_BIT)
+ * by mp_digit extraction.
+ */
i = 0;
for (;;) {
@@ -3310,14 +3345,13 @@ ShorteningBignumConversionPowD(Double* dPtr,
*/
r1 = mp_cmp_mag(&b, (m2plus > m2minus)? &mplus : &mminus);
- if (r1 == MP_LT
- || (r1 == MP_EQ
- && convType != TCL_DD_STEELE0
- && (dPtr->w.word1 & 1) == 0)) {
+ if (r1 == MP_LT || (r1 == MP_EQ
+ && convType != TCL_DD_STEELE0 && (dPtr->w.word1 & 1) == 0)) {
/*
- * Make sure we shouldn't be rounding *up* instead,
- * in case the next number above is closer
+ * Make sure we shouldn't be rounding *up* instead, in case the
+ * next number above is closer.
*/
+
if (ShouldBankerRoundUpPowD(&b, sd, digit&1)) {
++digit;
if (digit == 10) {
@@ -3327,7 +3361,9 @@ ShorteningBignumConversionPowD(Double* dPtr,
}
}
- /* Stash the last digit */
+ /*
+ * Stash the last digit.
+ */
*s++ = '0' + digit;
break;
@@ -3338,9 +3374,8 @@ ShorteningBignumConversionPowD(Double* dPtr,
* number?
*/
- if (ShouldBankerRoundUpToNextPowD(&b, &mminus, sd,
- convType, dPtr->w.word1 & 1,
- &temp)) {
+ if (ShouldBankerRoundUpToNextPowD(&b, &mminus, sd, convType,
+ dPtr->w.word1 & 1, &temp)) {
if (digit == 9) {
*s++ = '9';
s = BumpUp(s, retval, &k);
@@ -3354,6 +3389,7 @@ ShorteningBignumConversionPowD(Double* dPtr,
/*
* Have we converted all the requested digits?
*/
+
*s++ = '0' + digit;
if (i == ilim) {
if (ShouldBankerRoundUpPowD(&b, sd, digit&1)) {
@@ -3362,7 +3398,9 @@ ShorteningBignumConversionPowD(Double* dPtr,
break;
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
mp_mul_d(&b, 10, &b);
mp_mul_d(&mminus, 10, &mminus);
@@ -3376,6 +3414,7 @@ ShorteningBignumConversionPowD(Double* dPtr,
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
if (m2plus > m2minus) {
mp_clear(&mplus);
}
@@ -3389,62 +3428,52 @@ ShorteningBignumConversionPowD(Double* dPtr,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* StrictBignumConversionPowD --
*
- * Converts a double-precision number to a fixed-lengt string of
- * 'ilim' digits (or 'ilim1' if log10(d) has been overestimated.)
- * The denominator in David Gay's conversion algorithm is known to
- * be a power of 2**DIGIT_BIT, and hence the division in the main
- * loop may be replaced by a digit shift and mask.
+ * Converts a double-precision number to a fixed-lengt string of 'ilim'
+ * digits (or 'ilim1' if log10(d) has been overestimated). The
+ * denominator in David Gay's conversion algorithm is known to be a power
+ * of 2**DIGIT_BIT, and hence the division in the main loop may be
+ * replaced by a digit shift and mask.
*
* Results:
- * Returns the string of significant decimal digits, in newly
- * allocated memory.
+ * Returns the string of significant decimal digits, in newly allocated
+ * memory.
*
* Side effects:
- * Stores the location of the decimal point in '*decpt' and the
- * location of the terminal null byte in '*endPtr'.
+ * Stores the location of the decimal point in '*decpt' and the location
+ * of the terminal null byte in '*endPtr'.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-StrictBignumConversionPowD(Double* dPtr,
- /* Original number to convert */
- int convType,
- /* Type of conversion (shortest, Steele,
- E format, F format) */
- Tcl_WideUInt bw,
- /* Integer significand */
- int b2, int b5,
- /* Scale factor for the significand
- * in the numerator */
- int sd,
- /* Scale factor for the denominator */
- int k,
- /* Number of output digits before the decimal
- * point */
- int len,
- /* Number of digits to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Position of the terminal '\0'
- * at the end of the returned string */
+inline static char *
+StrictBignumConversionPowD(
+ Double *dPtr, /* Original number to convert. */
+ int convType, /* Type of conversion (shortest, Steele,
+ * E format, F format). */
+ Tcl_WideUInt bw, /* Integer significand. */
+ int b2, int b5, /* Scale factor for the significand in the
+ * numerator. */
+ int sd, /* Scale factor for the denominator. */
+ int k, /* Number of output digits before the decimal
+ * point. */
+ int len, /* Number of digits to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Position of the terminal '\0' at
+ * the end of the returned string. */
{
-
- char* retval = ckalloc(len + 1);
- /* Output buffer */
- mp_int b; /* Numerator of the fraction being converted */
- mp_digit digit; /* Current output digit */
- char* s = retval; /* Cursor in the output buffer */
- int i; /* Index in the output buffer */
+ char *retval = ckalloc(len + 1);
+ /* Output buffer. */
+ mp_int b; /* Numerator of the fraction being
+ * converted. */
+ mp_digit digit; /* Current output digit. */
+ char *s = retval; /* Cursor in the output buffer. */
+ int i; /* Index in the output buffer. */
mp_int temp;
/*
@@ -3455,7 +3484,9 @@ StrictBignumConversionPowD(Double* dPtr,
MulPow5(&b, b5, &b);
mp_mul_2d(&b, b2, &b);
- /* Adjust if the logarithm was guessed wrong */
+ /*
+ * Adjust if the logarithm was guessed wrong.
+ */
if (b.used <= sd) {
mp_mul_d(&b, 10, &b);
@@ -3466,7 +3497,7 @@ StrictBignumConversionPowD(Double* dPtr,
/*
* Loop through the digits. Do division and mod by s == 2**(sd*DIGIT_BIT)
- * by mp_digit extraction
+ * by mp_digit extraction.
*/
i = 1;
@@ -3478,26 +3509,29 @@ StrictBignumConversionPowD(Double* dPtr,
if (b.used > sd+1 || digit >= 10) {
Tcl_Panic("wrong digit!");
}
- --b.used; mp_clamp(&b);
+ --b.used;
+ mp_clamp(&b);
}
/*
* Have we converted all the requested digits?
*/
+
*s++ = '0' + digit;
if (i == ilim) {
if (ShouldBankerRoundUpPowD(&b, sd, digit&1)) {
s = BumpUp(s, retval, &k);
- } else {
- while (*--s == '0') {
- /* do nothing */
- }
- ++s;
}
+ while (*--s == '0') {
+ /* do nothing */
+ }
+ ++s;
break;
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
mp_mul_d(&b, 10, &b);
++i;
@@ -3507,6 +3541,7 @@ StrictBignumConversionPowD(Double* dPtr,
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
mp_clear_multi(&b, &temp, NULL);
*s = '\0';
*decpt = k;
@@ -3517,7 +3552,7 @@ StrictBignumConversionPowD(Double* dPtr,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShouldBankerRoundUp --
*
@@ -3527,17 +3562,18 @@ StrictBignumConversionPowD(Double* dPtr,
* Results:
* Returns 1 if the number needs to be rounded up, 0 otherwise.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-ShouldBankerRoundUp(mp_int* twor,
- /* 2x the remainder from thd division that
- * produced the last digit */
- mp_int* S, /* Denominator */
- int isodd) /* Flag == 1 if the last digit is odd */
+ShouldBankerRoundUp(
+ mp_int *twor, /* 2x the remainder from thd division that
+ * produced the last digit. */
+ mp_int *S, /* Denominator. */
+ int isodd) /* Flag == 1 if the last digit is odd. */
{
int r = mp_cmp_mag(twor, S);
+
switch (r) {
case MP_LT:
return 0;
@@ -3551,38 +3587,37 @@ ShouldBankerRoundUp(mp_int* twor,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShouldBankerRoundUpToNext --
*
- * Tests whether the remainder is great enough to force rounding
- * to the next higher digit.
+ * Tests whether the remainder is great enough to force rounding to the
+ * next higher digit.
*
* Results:
* Returns 1 if the number should be rounded up, 0 otherwise.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
inline static int
-ShouldBankerRoundUpToNext(mp_int* b,
- /* Remainder from the division that produced
+ShouldBankerRoundUpToNext(
+ mp_int *b, /* Remainder from the division that produced
* the last digit. */
- mp_int* m,
- /* Numerator of the rounding tolerance */
- mp_int* S,
- /* Denominator */
- int convType,
- /* Conversion type: STEELE0 defeats
- * round-to-even. (Not sure why one would
- * want this; I coped it from Gay. FIXME */
- int isodd,
- /* 1 if the integer significand is odd */
- mp_int* temp)
- /* Work area needed for the calculation */
+ mp_int *m, /* Numerator of the rounding tolerance. */
+ mp_int *S, /* Denominator. */
+ int convType, /* Conversion type: STEELE0 defeats
+ * round-to-even. (Not sure why one would want
+ * this; I coped it from Gay). FIXME */
+ int isodd, /* 1 if the integer significand is odd. */
+ mp_int *temp) /* Work area needed for the calculation. */
{
int r;
- /* Compare b and S-m: this is the same as comparing B+m and S. */
+
+ /*
+ * Compare b and S-m: this is the same as comparing B+m and S.
+ */
+
mp_add(b, m, temp);
r = mp_cmp_mag(temp, S);
switch(r) {
@@ -3602,7 +3637,7 @@ ShouldBankerRoundUpToNext(mp_int* b,
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* ShorteningBignumConversion --
*
@@ -3613,49 +3648,38 @@ ShouldBankerRoundUpToNext(mp_int* b,
* Returns the string of digits.
*
* Side effects:
- * Stores the position of the decimal point in *decpt.
- * Stores a pointer to the end of the number in *endPtr.
+ * Stores the position of the decimal point in *decpt. Stores a pointer
+ * to the end of the number in *endPtr.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-ShorteningBignumConversion(Double* dPtr,
- /* Original number being converted */
- int convType,
- /* Conversion type */
- Tcl_WideUInt bw,
- /* Integer significand and exponent */
- int b2,
- /* Scale factor for the significand */
- int m2plus, int m2minus,
- /* Scale factors for 1/2 ulp in numerator */
- int s2, int s5,
- /* Scale factors for denominator */
- int k,
- /* Guessed position of the decimal point */
- int len,
- /* Size of the digit buffer to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Pointer to the end of the number */
+inline static char *
+ShorteningBignumConversion(
+ Double *dPtr, /* Original number being converted. */
+ int convType, /* Conversion type. */
+ Tcl_WideUInt bw, /* Integer significand and exponent. */
+ int b2, /* Scale factor for the significand. */
+ int m2plus, int m2minus, /* Scale factors for 1/2 ulp in numerator. */
+ int s2, int s5, /* Scale factors for denominator. */
+ int k, /* Guessed position of the decimal point. */
+ int len, /* Size of the digit buffer to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Pointer to the end of the number */
{
- char* retval = ckalloc(len+1);
- /* Buffer of digits to return */
- char* s = retval; /* Cursor in the return value */
- mp_int b; /* Numerator of the result */
- mp_int mminus; /* 1/2 ulp below the result */
- mp_int mplus; /* 1/2 ulp above the result */
- mp_int S; /* Denominator of the result */
- mp_int dig; /* Current digit of the result */
- int digit; /* Current digit of the result */
- mp_int temp; /* Work area */
- int minit = 1; /* Fudge factor for when we misguess k */
+ char *retval = ckalloc(len+1);
+ /* Buffer of digits to return. */
+ char *s = retval; /* Cursor in the return value. */
+ mp_int b; /* Numerator of the result. */
+ mp_int mminus; /* 1/2 ulp below the result. */
+ mp_int mplus; /* 1/2 ulp above the result. */
+ mp_int S; /* Denominator of the result. */
+ mp_int dig; /* Current digit of the result. */
+ int digit; /* Current digit of the result. */
+ mp_int temp; /* Work area. */
+ int minit = 1; /* Fudge factor for when we misguess k. */
int i;
int r1;
@@ -3670,8 +3694,7 @@ ShorteningBignumConversion(Double* dPtr,
MulPow5(&S, s5, &S); mp_mul_2d(&S, s2, &S);
/*
- * Handle the case where we guess the position of the decimal point
- * wrong.
+ * Handle the case where we guess the position of the decimal point wrong.
*/
if (mp_cmp_mag(&b, &S) == MP_LT) {
@@ -3681,7 +3704,9 @@ ShorteningBignumConversion(Double* dPtr,
--k;
}
- /* mminus = 2**m2minus * 5**m5 */
+ /*
+ * mminus = 2**m2minus * 5**m5
+ */
mp_init_set_int(&mminus, minit);
mp_mul_2d(&mminus, m2minus, &mminus);
@@ -3691,7 +3716,9 @@ ShorteningBignumConversion(Double* dPtr,
}
mp_init(&temp);
- /* Loop through the digits */
+ /*
+ * Loop through the digits.
+ */
mp_init(&dig);
i = 1;
@@ -3708,10 +3735,8 @@ ShorteningBignumConversion(Double* dPtr,
*/
r1 = mp_cmp_mag(&b, (m2plus > m2minus)? &mplus : &mminus);
- if (r1 == MP_LT
- || (r1 == MP_EQ
- && convType != TCL_DD_STEELE0
- && (dPtr->w.word1 & 1) == 0)) {
+ if (r1 == MP_LT || (r1 == MP_EQ
+ && convType != TCL_DD_STEELE0 && (dPtr->w.word1 & 1) == 0)) {
mp_mul_2d(&b, 1, &b);
if (ShouldBankerRoundUp(&b, &S, digit&1)) {
++digit;
@@ -3726,12 +3751,12 @@ ShorteningBignumConversion(Double* dPtr,
}
/*
- * Does the current digit leave us with a remainder large enough
- * to commit to rounding up to the next higher digit?
+ * Does the current digit leave us with a remainder large enough to
+ * commit to rounding up to the next higher digit?
*/
if (ShouldBankerRoundUpToNext(&b, &mminus, &S, convType,
- dPtr->w.word1 & 1, &temp)) {
+ dPtr->w.word1 & 1, &temp)) {
++digit;
if (digit == 10) {
*s++ = '9';
@@ -3742,7 +3767,9 @@ ShorteningBignumConversion(Double* dPtr,
break;
}
- /* Have we converted all the requested digits? */
+ /*
+ * Have we converted all the requested digits?
+ */
*s++ = '0' + digit;
if (i == ilim) {
@@ -3753,11 +3780,15 @@ ShorteningBignumConversion(Double* dPtr,
break;
}
- /* Advance to the next digit */
+ /*
+ * Advance to the next digit.
+ */
if (s5 > 0) {
+ /*
+ * Can possibly shorten the denominator.
+ */
- /* Can possibly shorten the denominator */
mp_mul_2d(&b, 1, &b);
mp_mul_2d(&mminus, 1, &mminus);
if (m2plus > m2minus) {
@@ -3765,13 +3796,14 @@ ShorteningBignumConversion(Double* dPtr,
}
mp_div_d(&S, 5, &S, NULL);
--s5;
+
/*
- * IDEA: It might possibly be a win to fall back to
- * int64 arithmetic here if S < 2**64/10. But it's
- * a win only for a fairly narrow range of magnitudes
- * so perhaps not worth bothering. We already know that
- * we shorten the denominator by at least 1 mp_digit, perhaps
- * 2. as we do the conversion for 17 digits of significance.
+ * IDEA: It might possibly be a win to fall back to int64_t
+ * arithmetic here if S < 2**64/10. But it's a win only for
+ * a fairly narrow range of magnitudes so perhaps not worth
+ * bothering. We already know that we shorten the
+ * denominator by at least 1 mp_digit, perhaps 2, as we do
+ * the conversion for 17 digits of significance.
* Possible savings:
* 10**26 1 trip through loop before fallback possible
* 10**27 1 trip
@@ -3790,7 +3822,7 @@ ShorteningBignumConversion(Double* dPtr,
* 10**40 14 trips
* 10**41 15 trips
* 10**42 16 trips
- * thereafter no gain.
+ * thereafter no gain.
*/
} else {
mp_mul_d(&b, 10, &b);
@@ -3803,11 +3835,11 @@ ShorteningBignumConversion(Double* dPtr,
++i;
}
-
/*
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
if (m2plus > m2minus) {
mp_clear(&mplus);
}
@@ -3818,57 +3850,49 @@ ShorteningBignumConversion(Double* dPtr,
*endPtr = s;
}
return retval;
-
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* StrictBignumConversion --
*
- * Convert a floating point number to a fixed-length digit string
- * using the multiprecision method.
+ * Convert a floating point number to a fixed-length digit string using
+ * the multiprecision method.
*
* Results:
* Returns the string of digits.
*
* Side effects:
- * Stores the position of the decimal point in *decpt.
- * Stores a pointer to the end of the number in *endPtr.
+ * Stores the position of the decimal point in *decpt. Stores a pointer
+ * to the end of the number in *endPtr.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-inline static char*
-StrictBignumConversion(Double* dPtr,
- /* Original number being converted */
- int convType,
- /* Conversion type */
- Tcl_WideUInt bw,
- /* Integer significand and exponent */
- int b2, /* Scale factor for the significand */
- int s2, int s5,
- /* Scale factors for denominator */
- int k, /* Guessed position of the decimal point */
- int len, /* Size of the digit buffer to allocate */
- int ilim,
- /* Number of digits to convert if b >= s */
- int ilim1,
- /* Number of digits to convert if b < s */
- int* decpt,
- /* OUTPUT: Position of the decimal point */
- char** endPtr)
- /* OUTPUT: Pointer to the end of the number */
+inline static char *
+StrictBignumConversion(
+ Double *dPtr, /* Original number being converted. */
+ int convType, /* Conversion type. */
+ Tcl_WideUInt bw, /* Integer significand and exponent. */
+ int b2, /* Scale factor for the significand. */
+ int s2, int s5, /* Scale factors for denominator. */
+ int k, /* Guessed position of the decimal point. */
+ int len, /* Size of the digit buffer to allocate. */
+ int ilim, /* Number of digits to convert if b >= s */
+ int ilim1, /* Number of digits to convert if b < s */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ char **endPtr) /* OUTPUT: Pointer to the end of the number */
{
- char* retval = ckalloc(len+1);
- /* Buffer of digits to return */
- char* s = retval; /* Cursor in the return value */
- mp_int b; /* Numerator of the result */
- mp_int S; /* Denominator of the result */
- mp_int dig; /* Current digit of the result */
- int digit; /* Current digit of the result */
- mp_int temp; /* Work area */
- int g; /* Size of the current digit groun */
+ char *retval = ckalloc(len+1);
+ /* Buffer of digits to return. */
+ char *s = retval; /* Cursor in the return value. */
+ mp_int b; /* Numerator of the result. */
+ mp_int S; /* Denominator of the result. */
+ mp_int dig; /* Current digit of the result. */
+ int digit; /* Current digit of the result. */
+ mp_int temp; /* Work area. */
+ int g; /* Size of the current digit ground. */
int i, j;
/*
@@ -3883,8 +3907,7 @@ StrictBignumConversion(Double* dPtr,
MulPow5(&S, s5, &S); mp_mul_2d(&S, s2, &S);
/*
- * Handle the case where we guess the position of the decimal point
- * wrong.
+ * Handle the case where we guess the position of the decimal point wrong.
*/
if (mp_cmp_mag(&b, &S) == MP_LT) {
@@ -3893,7 +3916,9 @@ StrictBignumConversion(Double* dPtr,
--k;
}
- /* Convert the leading digit */
+ /*
+ * Convert the leading digit.
+ */
i = 0;
mp_div(&b, &S, &dig, &b);
@@ -3902,7 +3927,9 @@ StrictBignumConversion(Double* dPtr,
}
digit = dig.dp[0];
- /* Is a single digit all that was requested? */
+ /*
+ * Is a single digit all that was requested?
+ */
*s++ = '0' + digit;
if (++i >= ilim) {
@@ -3911,10 +3938,10 @@ StrictBignumConversion(Double* dPtr,
s = BumpUp(s, retval, &k);
}
} else {
-
for (;;) {
-
- /* Shift by a group of digits. */
+ /*
+ * Shift by a group of digits.
+ */
g = ilim - i;
if (g > DIGIT_GROUP) {
@@ -3933,18 +3960,17 @@ StrictBignumConversion(Double* dPtr,
mp_mul_2d(&b, g, &b);
/*
- * As with the shortening bignum conversion, it's possible at
- * this point that we will have reduced the denominator to
- * less than 2**64/10, at which point it would be possible to
- * fall back to to int64 arithmetic. But the potential payoff
- * is tremendously less - unless we're working in F format -
- * because we know that three groups of digits will always
- * suffice for %#.17e, the longest format that doesn't introduce
- * empty precision.
+ * As with the shortening bignum conversion, it's possible at this
+ * point that we will have reduced the denominator to less than
+ * 2**64/10, at which point it would be possible to fall back to
+ * to int64_t arithmetic. But the potential payoff is tremendously
+ * less - unless we're working in F format - because we know that
+ * three groups of digits will always suffice for %#.17e, the
+ * longest format that doesn't introduce empty precision.
+ *
+ * Extract the next group of digits.
*/
- /* Extract the next group of digits */
-
mp_div(&b, &S, &dig, &b);
if (dig.used > 1) {
Tcl_Panic("wrong digit!");
@@ -3952,31 +3978,35 @@ StrictBignumConversion(Double* dPtr,
digit = dig.dp[0];
for (j = g-1; j >= 0; --j) {
int t = itens[j];
+
*s++ = digit / t + '0';
digit %= t;
}
i += g;
- /* Have we converted all the requested digits? */
+ /*
+ * Have we converted all the requested digits?
+ */
if (i == ilim) {
mp_mul_2d(&b, 1, &b);
if (ShouldBankerRoundUp(&b, &S, digit&1)) {
s = BumpUp(s, retval, &k);
- } else {
- while (*--s == '0') {
- /* do nothing */
- }
- ++s;
}
- break;
+ break;
}
}
}
+ while (*--s == '0') {
+ /* do nothing */
+ }
+ ++s;
+
/*
* Endgame - store the location of the decimal point and the end of the
* string.
*/
+
mp_clear_multi(&b, &S, &temp, &dig, NULL);
*s = '\0';
*decpt = k;
@@ -3984,117 +4014,118 @@ StrictBignumConversion(Double* dPtr,
*endPtr = s;
}
return retval;
-
}
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* TclDoubleDigits --
*
- * Core of Tcl's conversion of double-precision floating point numbers
- * to decimal.
+ * Core of Tcl's conversion of double-precision floating point numbers to
+ * decimal.
*
* Results:
* Returns a newly-allocated string of digits.
*
* Side effects:
* Sets *decpt to the index of the character in the string before the
- * place that the decimal point should go. If 'endPtr' is not NULL,
- * sets endPtr to point to the terminating '\0' byte of the string.
- * Sets *sign to 1 if a minus sign should be printed with the number,
- * or 0 if a plus sign (or no sign) should appear.
+ * place that the decimal point should go. If 'endPtr' is not NULL, sets
+ * endPtr to point to the terminating '\0' byte of the string. Sets *sign
+ * to 1 if a minus sign should be printed with the number, or 0 if a plus
+ * sign (or no sign) should appear.
*
- * This function is a service routine that produces the string of digits
- * for floating-point-to-decimal conversion. It can do a number of things
+ * This function is a service routine that produces the string of digits for
+ * floating-point-to-decimal conversion. It can do a number of things
* according to the 'flags' argument. Valid values for 'flags' include:
- * TCL_DD_SHORTEST - This is the default for floating point conversion
- * if ::tcl_precision is 0. It constructs the shortest string
- * of digits that will reconvert to the given number when scanned.
+ * TCL_DD_SHORTEST - This is the default for floating point conversion if
+ * ::tcl_precision is 0. It constructs the shortest string of
+ * digits that will reconvert to the given number when scanned.
* For floating point numbers that are exactly between two
* decimal numbers, it resolves using the 'round to even' rule.
* With this value, the 'ndigits' parameter is ignored.
- * TCL_DD_STEELE - This value is not recommended and may be removed
- * in the future. It follows the conversion algorithm outlined
- * in "How to Print Floating-Point Numbers Accurately" by
- * Guy L. Steele, Jr. and Jon L. White [Proc. ACM SIGPLAN '90,
- * pp. 112-126]. This rule has the effect of rendering 1e23
- * as 9.9999999999999999e22 - which is a 'better' approximation
- * in the sense that it will reconvert correctly even if
- * a subsequent input conversion is 'round up' or 'round down'
+ * TCL_DD_STEELE - This value is not recommended and may be removed in
+ * the future. It follows the conversion algorithm outlined in
+ * "How to Print Floating-Point Numbers Accurately" by Guy
+ * L. Steele, Jr. and Jon L. White [Proc. ACM SIGPLAN '90,
+ * pp. 112-126]. This rule has the effect of rendering 1e23 as
+ * 9.9999999999999999e22 - which is a 'better' approximation in
+ * the sense that it will reconvert correctly even if a
+ * subsequent input conversion is 'round up' or 'round down'
* rather than 'round to nearest', but is surprising otherwise.
- * TCL_DD_E_FORMAT - This value is used to prepare numbers for %e
- * format conversion (or for default floating->string if
- * tcl_precision is not 0). It constructs a string of at most
- * 'ndigits' digits, choosing the one that is closest to the
- * given number (and resolving ties with 'round to even').
- * It is allowed to return fewer than 'ndigits' if the number
- * converts exactly; if the TCL_DD_E_FORMAT|TCL_DD_SHORTEN_FLAG
- * is supplied instead, it also returns fewer digits if the
- * shorter string will still reconvert to the given input number.
- * In any case, strings of trailing zeroes are suppressed.
- * TCL_DD_F_FORMAT - This value is used to prepare numbers for %f
- * format conversion. It requests that conversion proceed until
+ * TCL_DD_E_FORMAT - This value is used to prepare numbers for %e format
+ * conversion (or for default floating->string if tcl_precision
+ * is not 0). It constructs a string of at most 'ndigits' digits,
+ * choosing the one that is closest to the given number (and
+ * resolving ties with 'round to even'). It is allowed to return
+ * fewer than 'ndigits' if the number converts exactly; if the
+ * TCL_DD_E_FORMAT|TCL_DD_SHORTEN_FLAG is supplied instead, it
+ * also returns fewer digits if the shorter string will still
+ * reconvert without loss to the given input number. In any case,
+ * strings of trailing zeroes are suppressed.
+ * TCL_DD_F_FORMAT - This value is used to prepare numbers for %f format
+ * conversion. It requests that conversion proceed until
* 'ndigits' digits after the decimal point have been converted.
* It is possible for this format to result in a zero-length
- * string if the number is sufficiently small. Again, it
- * is permissible for TCL_DD_F_FORMAT to return fewer digits
- * for a number that converts exactly, and changing the
- * argument to TCL_DD_F_FORMAT|TCL_DD_SHORTEN_FLAG will allow
- * the routine also to return fewer digits if the shorter string
- * will still reconvert without loss to the given input number.
- * Strings of trailing zeroes are suppressed.
- *
- * To any of these flags may be OR'ed TCL_DD_NO_QUICK; this flag
- * requires all calculations to be done in exact arithmetic. Normally,
- * E and F format with fewer than about 14 digits will be done with
- * a quick floating point approximation and fall back on the exact
- * arithmetic only if the input number is close enough to the
- * midpoint between two decimal strings that more precision is needed
- * to resolve which string is correct.
+ * string if the number is sufficiently small. Again, it is
+ * permissible for TCL_DD_F_FORMAT to return fewer digits for a
+ * number that converts exactly, and changing the argument to
+ * TCL_DD_F_FORMAT|TCL_DD_SHORTEN_FLAG will allow the routine
+ * also to return fewer digits if the shorter string will still
+ * reconvert without loss to the given input number. Strings of
+ * trailing zeroes are suppressed.
+ *
+ * To any of these flags may be OR'ed TCL_DD_NO_QUICK; this flag requires
+ * all calculations to be done in exact arithmetic. Normally, E and F
+ * format with fewer than about 14 digits will be done with a quick
+ * floating point approximation and fall back on the exact arithmetic
+ * only if the input number is close enough to the midpoint between two
+ * decimal strings that more precision is needed to resolve which string
+ * is correct.
*
* The value stored in the 'decpt' argument on return may be negative
- * (indicating that the decimal point falls to the left of the string)
- * or greater than the length of the string. In addition, the value -9999
- * is used as a sentinel to indicate that the string is one of the special
- * values "Infinity" and "NaN", and that no decimal point should be inserted.
+ * (indicating that the decimal point falls to the left of the string) or
+ * greater than the length of the string. In addition, the value -9999 is used
+ * as a sentinel to indicate that the string is one of the special values
+ * "Infinity" and "NaN", and that no decimal point should be inserted.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
-char*
-TclDoubleDigits(double dv, /* Number to convert */
- int ndigits, /* Number of digits requested */
- int flags, /* Conversion flags */
- int* decpt, /* OUTPUT: Position of the decimal point */
- int* sign, /* OUTPUT: 1 if the result is negative */
- char** endPtr) /* OUTPUT: If not NULL, receives a pointer
- * to one character beyond the end
- * of the returned string */
+
+char *
+TclDoubleDigits(
+ double dv, /* Number to convert. */
+ int ndigits, /* Number of digits requested. */
+ int flags, /* Conversion flags. */
+ int *decpt, /* OUTPUT: Position of the decimal point. */
+ int *sign, /* OUTPUT: 1 if the result is negative. */
+ char **endPtr) /* OUTPUT: If not NULL, receives a pointer to
+ * one character beyond the end of the
+ * returned string. */
{
int convType = (flags & TCL_DD_CONVERSION_TYPE_MASK);
- /* Type of conversion being performed
- * TCL_DD_SHORTEST0
- * TCL_DD_STEELE0
- * TCL_DD_E_FORMAT
- * TCL_DD_F_FORMAT */
- Double d; /* Union for deconstructing doubles */
- Tcl_WideUInt bw; /* Integer significand */
+ /* Type of conversion being performed:
+ * TCL_DD_SHORTEST0, TCL_DD_STEELE0,
+ * TCL_DD_E_FORMAT, or TCL_DD_F_FORMAT. */
+ Double d; /* Union for deconstructing doubles. */
+ Tcl_WideUInt bw; /* Integer significand. */
int be; /* Power of 2 by which b must be multiplied */
- int bbits; /* Number of bits needed to represent b */
+ int bbits; /* Number of bits needed to represent b. */
int denorm; /* Flag == 1 iff the input number was
- * denormalized */
- int k; /* Estimate of floor(log10(d)) */
- int k_check; /* Flag == 1 if d is near enough to a
- * power of ten that k must be checked */
+ * denormalized. */
+ int k; /* Estimate of floor(log10(d)). */
+ int k_check; /* Flag == 1 if d is near enough to a power of
+ * ten that k must be checked. */
int b2, b5, s2, s5; /* Powers of 2 and 5 in the numerator and
- * denominator of intermediate results */
- int ilim = -1, ilim1 = -1; /* Number of digits to convert, and number
- * to convert if log10(d) has been
- * overestimated */
- char* retval; /* Return value from this function */
+ * denominator of intermediate results. */
+ int ilim = -1, ilim1 = -1; /* Number of digits to convert, and number to
+ * convert if log10(d) has been
+ * overestimated. */
+ char *retval; /* Return value from this function. */
int i = -1;
- /* Put the input number into a union for bit-whacking */
+ /*
+ * Put the input number into a union for bit-whacking.
+ */
d.d = dv;
@@ -4113,10 +4144,10 @@ TclDoubleDigits(double dv, /* Number to convert */
/*
* Unpack the floating point into a wide integer and an exponent.
- * Determine the number of bits that the big integer requires, and
- * compute a quick approximation (which may be one too high) of
- * ceil(log10(d.d)).
+ * Determine the number of bits that the big integer requires, and compute
+ * a quick approximation (which may be one too high) of ceil(log10(d.d)).
*/
+
denorm = ((d.w.word0 & EXP_MASK) == 0);
DoubleToExpAndSig(d.d, &bw, &be, &bbits);
k = ApproximateLog10(bw, be, bbits);
@@ -4126,58 +4157,57 @@ TclDoubleDigits(double dv, /* Number to convert */
* d is the number to convert.
* bw are significand and exponent: d == bw*2**be,
* bbits is the length of bw: 2**bbits-1 <= bw < 2**bbits
- * k is either ceil(log10(d)) or ceil(log10(d))+1. k_check is 0
- * if we know that k is exactly ceil(log10(d)) and 1 if we need to
- * check.
+ * k is either ceil(log10(d)) or ceil(log10(d))+1. k_check is 0 if we
+ * know that k is exactly ceil(log10(d)) and 1 if we need to check.
* We want a rational number
* r = b * 10**(1-k) = bw * 2**b2 * 5**b5 / (2**s2 / 5**s5),
* with b2, b5, s2, s5 >= 0. Note that the most significant decimal
- * digit is floor(r) and that successive digits can be obtained
- * by setting r <- 10*floor(r) (or b <= 10 * (b % S)).
- * Find appropriate b2, b5, s2, s5.
+ * digit is floor(r) and that successive digits can be obtained by
+ * setting r <- 10*floor(r) (or b <= 10 * (b % S)). Find appropriate
+ * b2, b5, s2, s5.
*/
ComputeScale(be, k, &b2, &b5, &s2, &s5);
/*
- * Correct an incorrect caller-supplied 'ndigits'.
- * Also determine:
+ * Correct an incorrect caller-supplied 'ndigits'. Also determine:
* i = The maximum number of decimal digits that will be returned in the
* formatted string. This is k + 1 + ndigits for F format, 18 for
- * shortest and Steele, and ndigits for E format.
- * ilim = The number of significant digits to convert if
- * k has been guessed correctly. This is -1 for shortest and Steele
- * (which stop when all significance has been lost), 'ndigits'
- * for E format, and 'k + 1 + ndigits' for F format.
- * ilim1 = The minimum number of significant digits to convert if
- * k has been guessed 1 too high. This, too, is -1 for shortest
- * and Steele, and 'ndigits' for E format, but it's 'ndigits-1'
- * for F format.
+ * shortest and Steele, and ndigits for E format.
+ * ilim = The number of significant digits to convert if k has been
+ * guessed correctly. This is -1 for shortest and Steele (which
+ * stop when all significance has been lost), 'ndigits' for E
+ * format, and 'k + 1 + ndigits' for F format.
+ * ilim1 = The minimum number of significant digits to convert if k has
+ * been guessed 1 too high. This, too, is -1 for shortest and
+ * Steele, and 'ndigits' for E format, but it's 'ndigits-1' for F
+ * format.
*/
SetPrecisionLimits(convType, k, &ndigits, &i, &ilim, &ilim1);
/*
- * Try to do low-precision conversion in floating point rather
- * than resorting to expensive multiprecision arithmetic
+ * Try to do low-precision conversion in floating point rather than
+ * resorting to expensive multiprecision arithmetic.
*/
+
if (ilim >= 0 && ilim <= QUICK_MAX && !(flags & TCL_DD_NO_QUICK)) {
- if ((retval = QuickConversion(d.d, k, k_check, flags,
- i, ilim, ilim1,
- decpt, endPtr)) != NULL) {
+ retval = QuickConversion(d.d, k, k_check, flags, i, ilim, ilim1,
+ decpt, endPtr);
+ if (retval != NULL) {
return retval;
}
}
/*
- * For shortening conversions, determine the upper and lower bounds
- * for the remainder at which we can stop.
- * m+ = (2**m2plus * 5**m5) / (2**s2 * 5**s5) is the limit on the
- * high side, and
- * m- = (2**m2minus * 5**m5) / (2**s2 * 5**s5) is the limit on the
- * low side.
- * We may need to increase s2 to put m2plus, m2minus, b2 over a
- * common denominator.
+ * For shortening conversions, determine the upper and lower bounds for
+ * the remainder at which we can stop.
+ * m+ = (2**m2plus * 5**m5) / (2**s2 * 5**s5) is the limit on the high
+ * side, and
+ * m- = (2**m2minus * 5**m5) / (2**s2 * 5**s5) is the limit on the low
+ * side.
+ * We may need to increase s2 to put m2plus, m2minus, b2 over a common
+ * denominator.
*/
if (flags & TCL_DD_SHORTEN_FLAG) {
@@ -4187,10 +4217,10 @@ TclDoubleDigits(double dv, /* Number to convert */
int len = i;
/*
- * Find the quantity i so that (2**i*5**b5)/(2**s2*5**s5)
- * is 1/2 unit in the least significant place of the floating
- * point number.
+ * Find the quantity i so that (2**i*5**b5)/(2**s2*5**s5) is 1/2 unit
+ * in the least significant place of the floating point number.
*/
+
if (denorm) {
i = be + EXPONENT_BIAS + (FP_PRECISION-1);
} else {
@@ -4201,14 +4231,16 @@ TclDoubleDigits(double dv, /* Number to convert */
/*
* Reduce the fractions to lowest terms, since the above calculation
- * may have left excess powers of 2 in numerator and denominator
+ * may have left excess powers of 2 in numerator and denominator.
*/
+
CastOutPowersOf2(&b2, &m2minus, &s2);
/*
* In the special case where bw==1, the nearest floating point number
* to it on the low side is 1/4 ulp below it. Adjust accordingly.
*/
+
m2plus = m2minus;
if (!denorm && bw == 1) {
++b2;
@@ -4216,60 +4248,56 @@ TclDoubleDigits(double dv, /* Number to convert */
++m2plus;
}
- if (s5+1 < N_LOG2POW5
- && s2+1 + log2pow5[s5+1] <= 64) {
+ if (s5+1 < N_LOG2POW5 && s2+1 + log2pow5[s5+1] <= 64) {
/*
- * If 10*2**s2*5**s5 == 2**(s2+1)+5**(s5+1) fits in a 64-bit
- * word, then all our intermediate calculations can be done
- * using exact 64-bit arithmetic with no need for expensive
- * multiprecision operations. (This will be true for all numbers
- * in the range [1.0e-3 .. 1.0e+24]).
+ * If 10*2**s2*5**s5 == 2**(s2+1)+5**(s5+1) fits in a 64-bit word,
+ * then all our intermediate calculations can be done using exact
+ * 64-bit arithmetic with no need for expensive multiprecision
+ * operations. (This will be true for all numbers in the range
+ * [1.0e-3 .. 1.0e+24]).
*/
- return ShorteningInt64Conversion(&d, convType, bw, b2, b5,
- m2plus, m2minus, m5,
- s2, s5, k, len, ilim, ilim1,
- decpt, endPtr);
+ return ShorteningInt64Conversion(&d, convType, bw, b2, b5, m2plus,
+ m2minus, m5, s2, s5, k, len, ilim, ilim1, decpt, endPtr);
} else if (s5 == 0) {
/*
- * The denominator is a power of 2, so we can replace division
- * by digit shifts. First we round up s2 to a multiple of
- * DIGIT_BIT, and adjust m2 and b2 accordingly. Then we launch
- * into a version of the comparison that's specialized for
- * the 'power of mp_digit in the denominator' case.
+ * The denominator is a power of 2, so we can replace division by
+ * digit shifts. First we round up s2 to a multiple of DIGIT_BIT,
+ * and adjust m2 and b2 accordingly. Then we launch into a version
+ * of the comparison that's specialized for the 'power of mp_digit
+ * in the denominator' case.
*/
+
if (s2 % DIGIT_BIT != 0) {
int delta = DIGIT_BIT - (s2 % DIGIT_BIT);
+
b2 += delta;
m2plus += delta;
m2minus += delta;
s2 += delta;
}
return ShorteningBignumConversionPowD(&d, convType, bw, b2, b5,
- m2plus, m2minus, m5,
- s2/DIGIT_BIT, k, len,
- ilim, ilim1, decpt, endPtr);
+ m2plus, m2minus, m5, s2/DIGIT_BIT, k, len, ilim, ilim1,
+ decpt, endPtr);
} else {
-
/*
- * Alas, there's no helpful special case; use full-up
- * bignum arithmetic for the conversion
+ * Alas, there's no helpful special case; use full-up bignum
+ * arithmetic for the conversion.
*/
- return ShorteningBignumConversion(&d, convType, bw,
- b2, m2plus, m2minus,
- s2, s5, k, len,
- ilim, ilim1, decpt, endPtr);
-
+ return ShorteningBignumConversion(&d, convType, bw, b2, m2plus,
+ m2minus, s2, s5, k, len, ilim, ilim1, decpt, endPtr);
}
-
} else {
-
- /* Non-shortening conversion */
+ /*
+ * Non-shortening conversion.
+ */
int len = i;
- /* Reduce numerator and denominator to lowest terms */
+ /*
+ * Reduce numerator and denominator to lowest terms.
+ */
if (b2 >= s2 && s2 > 0) {
b2 -= s2; s2 = 0;
@@ -4277,48 +4305,46 @@ TclDoubleDigits(double dv, /* Number to convert */
s2 -= b2; b2 = 0;
}
- if (s5+1 < N_LOG2POW5
- && s2+1 + log2pow5[s5+1] <= 64) {
+ if (s5+1 < N_LOG2POW5 && s2+1 + log2pow5[s5+1] <= 64) {
/*
- * If 10*2**s2*5**s5 == 2**(s2+1)+5**(s5+1) fits in a 64-bit
- * word, then all our intermediate calculations can be done
- * using exact 64-bit arithmetic with no need for expensive
- * multiprecision operations.
+ * If 10*2**s2*5**s5 == 2**(s2+1)+5**(s5+1) fits in a 64-bit word,
+ * then all our intermediate calculations can be done using exact
+ * 64-bit arithmetic with no need for expensive multiprecision
+ * operations.
*/
- return StrictInt64Conversion(&d, convType, bw, b2, b5,
- s2, s5, k, len, ilim, ilim1,
- decpt, endPtr);
-
+ return StrictInt64Conversion(&d, convType, bw, b2, b5, s2, s5, k,
+ len, ilim, ilim1, decpt, endPtr);
} else if (s5 == 0) {
/*
- * The denominator is a power of 2, so we can replace division
- * by digit shifts. First we round up s2 to a multiple of
- * DIGIT_BIT, and adjust m2 and b2 accordingly. Then we launch
- * into a version of the comparison that's specialized for
- * the 'power of mp_digit in the denominator' case.
+ * The denominator is a power of 2, so we can replace division by
+ * digit shifts. First we round up s2 to a multiple of DIGIT_BIT,
+ * and adjust m2 and b2 accordingly. Then we launch into a version
+ * of the comparison that's specialized for the 'power of mp_digit
+ * in the denominator' case.
*/
+
if (s2 % DIGIT_BIT != 0) {
int delta = DIGIT_BIT - (s2 % DIGIT_BIT);
+
b2 += delta;
s2 += delta;
}
return StrictBignumConversionPowD(&d, convType, bw, b2, b5,
- s2/DIGIT_BIT, k, len,
- ilim, ilim1, decpt, endPtr);
+ s2/DIGIT_BIT, k, len, ilim, ilim1, decpt, endPtr);
} else {
/*
- * There are no helpful special cases, but at least we know
- * in advance how many digits we will convert. We can run the
- * conversion in steps of DIGIT_GROUP digits, so as to
- * have many fewer mp_int divisions.
+ * There are no helpful special cases, but at least we know in
+ * advance how many digits we will convert. We can run the
+ * conversion in steps of DIGIT_GROUP digits, so as to have many
+ * fewer mp_int divisions.
*/
- return StrictBignumConversion(&d, convType, bw, b2, s2, s5,
- k, len, ilim, ilim1, decpt, endPtr);
+
+ return StrictBignumConversion(&d, convType, bw, b2, s2, s5, k,
+ len, ilim, ilim1, decpt, endPtr);
}
}
}
-
/*
*----------------------------------------------------------------------
@@ -4346,14 +4372,12 @@ TclInitDoubleConversion(void)
int x;
Tcl_WideUInt u;
double d;
-
#ifdef IEEE_FLOATING_POINT
union {
double dv;
Tcl_WideUInt iv;
} bitwhack;
#endif
-
#if defined(__sgi) && defined(_COMPILER_VERSION)
union fpc_csr mipsCR;
@@ -4368,8 +4392,7 @@ TclInitDoubleConversion(void)
maxpow10_wide = (int)
floor(sizeof(Tcl_WideUInt) * CHAR_BIT * log(2.) / log(10.));
- pow10_wide = (Tcl_WideUInt *)
- ckalloc((maxpow10_wide + 1) * sizeof(Tcl_WideUInt));
+ pow10_wide = ckalloc((maxpow10_wide + 1) * sizeof(Tcl_WideUInt));
u = 1;
for (i = 0; i < maxpow10_wide; ++i) {
pow10_wide[i] = u;
@@ -4378,8 +4401,8 @@ TclInitDoubleConversion(void)
pow10_wide[i] = u;
/*
- * Determine how many bits of precision a double has, and how many
- * decimal digits that represents.
+ * Determine how many bits of precision a double has, and how many decimal
+ * digits that represents.
*/
if (frexp((double) FLT_RADIX, &log2FLT_RADIX) != 0.5) {
@@ -4390,8 +4413,8 @@ TclInitDoubleConversion(void)
d = 1.0;
/*
- * Initialize a table of powers of ten that can be exactly represented
- * in a double.
+ * Initialize a table of powers of ten that can be exactly represented in
+ * a double.
*/
x = (int) (DBL_MANT_DIG * log((double) FLT_RADIX) / log(5.0));
@@ -4476,10 +4499,13 @@ TclFinalizeDoubleConversion(void)
{
int i;
- ckfree((char *) pow10_wide);
+ ckfree(pow10_wide);
for (i=0; i<9; ++i) {
mp_clear(pow5 + i);
}
+ for (i=0; i < 5; ++i) {
+ mp_clear(pow5_13 + i);
+ }
}
/*
@@ -4502,9 +4528,9 @@ TclFinalizeDoubleConversion(void)
int
Tcl_InitBignumFromDouble(
- Tcl_Interp *interp, /* For error message */
- double d, /* Number to convert */
- mp_int *b) /* Place to store the result */
+ Tcl_Interp *interp, /* For error message. */
+ double d, /* Number to convert. */
+ mp_int *b) /* Place to store the result. */
{
double fract;
int expt;
@@ -4558,7 +4584,7 @@ Tcl_InitBignumFromDouble(
double
TclBignumToDouble(
- mp_int *a) /* Integer to convert. */
+ const mp_int *a) /* Integer to convert. */
{
mp_int b;
int bits, shift, i, lsb;
@@ -4654,9 +4680,9 @@ TclBignumToDouble(
return -r;
}
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* TclCeil --
*
@@ -4666,12 +4692,12 @@ TclBignumToDouble(
* Results:
* Returns the floating point number.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
double
TclCeil(
- mp_int *a) /* Integer to convert. */
+ const mp_int *a) /* Integer to convert. */
{
double r = 0.0;
mp_int b;
@@ -4711,24 +4737,24 @@ TclCeil(
mp_clear(&b);
return r;
}
-
+
/*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*
* TclFloor --
*
- * Computes the largest floating point number less than or equal to
- * the mp_int argument.
+ * Computes the largest floating point number less than or equal to the
+ * mp_int argument.
*
* Results:
* Returns the floating point value.
*
- *-----------------------------------------------------------------------------
+ *----------------------------------------------------------------------
*/
double
TclFloor(
- mp_int *a) /* Integer to convert. */
+ const mp_int *a) /* Integer to convert. */
{
double r = 0.0;
mp_int b;
@@ -4784,8 +4810,8 @@ TclFloor(
static double
BignumToBiasedFrExp(
- mp_int *a, /* Integer to convert */
- int *machexp) /* Power of two */
+ const mp_int *a, /* Integer to convert. */
+ int *machexp) /* Power of two. */
{
mp_int b;
int bits;
@@ -4849,8 +4875,8 @@ BignumToBiasedFrExp(
static double
Pow10TimesFrExp(
- int exponent, /* Power of 10 to multiply by */
- double fraction, /* Significand of multiplicand */
+ int exponent, /* Power of 10 to multiply by. */
+ double fraction, /* Significand of multiplicand. */
int *machexp) /* On input, exponent of multiplicand. On
* output, exponent of result. */
{
@@ -4860,7 +4886,7 @@ Pow10TimesFrExp(
if (exponent > 0) {
/*
- * Multiply by 10**exponent
+ * Multiply by 10**exponent.
*/
retval = frexp(retval * pow10vals[exponent&0xf], &j);
@@ -4873,7 +4899,7 @@ Pow10TimesFrExp(
}
} else if (exponent < 0) {
/*
- * Divide by 10**-exponent
+ * Divide by 10**-exponent.
*/
retval = frexp(retval / pow10vals[(-exponent) & 0xf], &j);
@@ -4982,26 +5008,27 @@ TclFormatNaN(
*
* Nokia770Twiddle --
*
- * Transpose the two words of a number for Nokia 770 floating
- * point handling.
+ * Transpose the two words of a number for Nokia 770 floating point
+ * handling.
*
*----------------------------------------------------------------------
*/
-
+#ifdef IEEE_FLOATING_POINT
static Tcl_WideUInt
Nokia770Twiddle(
- Tcl_WideUInt w) /* Number to transpose */
+ Tcl_WideUInt w) /* Number to transpose. */
{
return (((w >> 32) & 0xffffffff) | (w << 32));
}
+#endif
/*
*----------------------------------------------------------------------
*
* TclNokia770Doubles --
*
- * Transpose the two words of a number for Nokia 770 floating
- * point handling.
+ * Transpose the two words of a number for Nokia 770 floating point
+ * handling.
*
*----------------------------------------------------------------------
*/