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authorRobb Matzke <matzke@llnl.gov>1998-06-30 21:30:28 (GMT)
committerRobb Matzke <matzke@llnl.gov>1998-06-30 21:30:28 (GMT)
commit1b3a1f8014b630208013c7a18cfe8e7c0539e161 (patch)
tree442600fb6f75f8dbde490f48d2a8ccba7c823164 /src/H5Tconv.c
parent030d46c078b7ef61468703dabb4861212ecb13ca (diff)
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[svn-r437] Changes since 19980612
---------------------- ./src/H5Tbit.c ./src/H5Tpkg.h Fixed a bug in H5T_bit_copy(). Added H5T_bit_get_d() and H5T_bit_set_d() which treat portions of a bit vector as an unsigned integer. Added H5T_bit_inc() that increments part of a bit vector and returns an indication of overflow. ./src/H5Tconv.c ./src/H5Tpkg.h ./test/dtypes.c Added a slow general floating point conversion which works so far on Intel, MIPS, and DEC but the test is turned off because a cast from double to float will cause a SIGFPE on some systems if an overflow occurs. Added fast hardware conversions between native floating point types. This function is also subject to the SIGFPE problem. ./src/H5detect.c Removed the exponent bias adjustment when the significand isn't normalized. This is now handled in the conversion functions instead. ./src/H5T.c Register new conversion functions. Plugged a memory leak in the library termination code. ./RELEASE Added a list of major changes since the first alpha. ./src/H5.c ./src/H5private.h ./src/H5A.c ./src/H5AC.c ./src/H5D.c ./src/H5Ffamily.c ./src/H5Fistore.c ./src/H5G.c ./src/H5Gprivate.h ./src/H5HG.c ./src/H5O.c ./src/H5T.c ./src/H5Tbit.c ./src/H5Tconv.c Fixed various compiler warnings on Irix64. ./src/H5MM.c Added PABLO_MASK to this file. ./test/chunk.c Removed a warning about memcpy().
Diffstat (limited to 'src/H5Tconv.c')
-rw-r--r--src/H5Tconv.c500
1 files changed, 496 insertions, 4 deletions
diff --git a/src/H5Tconv.c b/src/H5Tconv.c
index f994345..930b330 100644
--- a/src/H5Tconv.c
+++ b/src/H5Tconv.c
@@ -620,12 +620,14 @@ H5T_conv_i_i (hid_t src_id, hid_t dst_id, H5T_cdata_t *cdata,
} else if (src->size>=dst->size) {
sp = dp = (uint8*)buf;
direction = 1;
- olap = ceil((double)(src->size)/(src->size-dst->size))-1;
+ olap = (size_t)(ceil((double)(src->size)/
+ (double)(src->size-dst->size))-1);
} else {
sp = (uint8*)buf + (nelmts-1) * src->size;
dp = (uint8*)buf + (nelmts-1) * dst->size;
direction = -1;
- olap = ceil((double)(dst->size)/(dst->size-src->size))-1;
+ olap = (size_t)(ceil((double)(dst->size)/
+ (double)(dst->size-src->size))-1);
}
/* The conversion loop */
@@ -871,6 +873,497 @@ H5T_conv_i_i (hid_t src_id, hid_t dst_id, H5T_cdata_t *cdata,
/*-------------------------------------------------------------------------
+ * Function: H5T_conv_f_f
+ *
+ * Purpose: Convert one floating point type to another. This is a catch
+ * all for floating point conversions and is probably not
+ * particularly fast!
+ *
+ * Return: Success: SUCCEED
+ *
+ * Failure: FAIL
+ *
+ * Programmer: Robb Matzke
+ * Tuesday, June 23, 1998
+ *
+ * Modifications:
+ *
+ *-------------------------------------------------------------------------
+ */
+herr_t
+H5T_conv_f_f (hid_t src_id, hid_t dst_id, H5T_cdata_t *cdata,
+ size_t nelmts, void *buf, void __unused__ *bkg)
+{
+ /* Traversal-related variables */
+ H5T_t *src_p; /*source data type */
+ H5T_t *dst_p; /*destination data type */
+ H5T_atomic_t src; /*atomic source info */
+ H5T_atomic_t dst; /*atomic destination info */
+ intn direction; /*forward or backward traversal */
+ size_t elmtno; /*element number */
+ size_t half_size; /*half the type size */
+ size_t olap; /*num overlapping elements */
+ ssize_t bitno; /*bit number */
+ uint8 *s, *sp, *d, *dp; /*source and dest traversal ptrs*/
+ uint8 dbuf[64]; /*temp destination buffer */
+
+ /* Conversion-related variables */
+ hssize_t expo; /*exponent */
+ hssize_t expo_max; /*maximum possible dst exponent */
+ size_t msize; /*useful size of mantissa in src*/
+ size_t mpos; /*offset to useful mant is src */
+ size_t mrsh; /*amount to right shift mantissa*/
+ hbool_t carry; /*carry after rounding mantissa */
+ size_t i; /*miscellaneous counters */
+ size_t implied; /*destination implied bits */
+
+ FUNC_ENTER (H5T_conv_f_f, FAIL);
+
+ switch (cdata->command) {
+ case H5T_CONV_INIT:
+ if (H5_DATATYPE!=H5I_group (src_id) ||
+ NULL==(src_p=H5I_object (src_id)) ||
+ H5_DATATYPE!=H5I_group (dst_id) ||
+ NULL==(dst_p=H5I_object (dst_id))) {
+ HRETURN_ERROR (H5E_ARGS, H5E_BADTYPE, FAIL, "not a data type");
+ }
+ src = src_p->u.atomic;
+ dst = dst_p->u.atomic;
+ if (H5T_ORDER_LE!=src.order &&
+ H5T_ORDER_BE!=src.order) {
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "unsupported byte order");
+ }
+ if (H5T_ORDER_LE!=dst.order &&
+ H5T_ORDER_BE!=dst.order) {
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "unsupported byte order");
+ }
+ if (dst_p->size>sizeof(dbuf)) {
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "destination size is too large");
+ }
+ if (8*sizeof(expo)-1<src.u.f.esize ||
+ 8*sizeof(expo)-1<dst.u.f.esize) {
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "exponent field is too large");
+ }
+ cdata->need_bkg = H5T_BKG_NO;
+ break;
+
+ case H5T_CONV_FREE:
+ break;
+
+ case H5T_CONV_CONV:
+ /* Get the data types */
+ if (H5_DATATYPE!=H5I_group (src_id) ||
+ NULL==(src_p=H5I_object (src_id)) ||
+ H5_DATATYPE!=H5I_group (dst_id) ||
+ NULL==(dst_p=H5I_object (dst_id))) {
+ HRETURN_ERROR (H5E_ARGS, H5E_BADTYPE, FAIL, "not a data type");
+ }
+ src = src_p->u.atomic;
+ dst = dst_p->u.atomic;
+ expo_max = ((hssize_t)1 << dst.u.f.esize) - 1;
+
+ /*
+ * Do we process the values from beginning to end or vice versa? Also,
+ * how many of the elements have the source and destination areas
+ * overlapping?
+ */
+ if (src_p->size==dst_p->size) {
+ sp = dp = (uint8*)buf;
+ direction = 1;
+ olap = nelmts;
+ } else if (src_p->size>=dst_p->size) {
+ sp = dp = (uint8*)buf;
+ direction = 1;
+ olap = (size_t)(ceil((double)(src_p->size)/
+ (double)(src_p->size-dst_p->size))-1);
+ } else {
+ sp = (uint8*)buf + (nelmts-1) * src_p->size;
+ dp = (uint8*)buf + (nelmts-1) * dst_p->size;
+ direction = -1;
+ olap = (size_t)(ceil((double)(dst_p->size)/
+ (double)(dst_p->size-src_p->size))-1);
+ }
+
+ /* The conversion loop */
+ for (elmtno=0; elmtno<nelmts; elmtno++) {
+ /*
+ * If the source and destination buffers overlap then use a
+ * temporary buffer for the destination.
+ */
+ if (direction>0) {
+ s = sp;
+ d = elmtno<olap ? dbuf : dp;
+ } else {
+ s = sp;
+ d = elmtno >= nelmts-olap ? dbuf : dp;
+ }
+#ifndef NDEBUG
+ /* I don't quite trust the overlap calculations yet --rpm */
+ if (d==dbuf) {
+ assert ((dp>=sp && dp<sp+src_p->size) ||
+ (sp>=dp && sp<dp+dst_p->size));
+ } else {
+ assert ((dp<sp && dp+dst_p->size<=sp) ||
+ (sp<dp && sp+src_p->size<=dp));
+ }
+#endif
+
+ /*
+ * Put the data in little endian order so our loops aren't so
+ * complicated. We'll do all the conversion stuff assuming
+ * little endian and then we'll fix the order at the end.
+ */
+ if (H5T_ORDER_BE==src.order) {
+ half_size = src_p->size/2;
+ for (i=0; i<half_size; i++) {
+ uint8 tmp = s[src_p->size-(i+1)];
+ s[src_p->size-(i+1)] = s[i];
+ s[i] = tmp;
+ }
+ }
+
+ /*
+ * Check for special cases: +0, -0, +Inf, -Inf, NaN
+ */
+ if (H5T_bit_find (s, src.u.f.mpos, src.u.f.msize,
+ H5T_BIT_LSB, TRUE)<0) {
+ if (H5T_bit_find (s, src.u.f.epos, src.u.f.esize,
+ H5T_BIT_LSB, TRUE)<0) {
+ /* +0 or -0 */
+ H5T_bit_copy (d, dst.u.f.sign, s, src.u.f.sign, 1);
+ H5T_bit_set (d, dst.u.f.epos, dst.u.f.esize, FALSE);
+ H5T_bit_set (d, dst.u.f.mpos, dst.u.f.esize, FALSE);
+ goto padding;
+ } else if (H5T_bit_find (s, src.u.f.epos, src.u.f.esize,
+ H5T_BIT_LSB, FALSE)<0) {
+ /* +Inf or -Inf */
+ H5T_bit_copy (d, dst.u.f.sign, s, src.u.f.sign, 1);
+ H5T_bit_set (d, dst.u.f.epos, dst.u.f.esize, TRUE);
+ H5T_bit_set (d, dst.u.f.mpos, dst.u.f.msize, FALSE);
+ goto padding;
+ }
+ } else if (H5T_bit_find (s, src.u.f.epos, src.u.f.esize,
+ H5T_BIT_LSB, FALSE)<0) {
+ /*
+ * NaN. There are many NaN values, so we just set all bits of
+ * the significand.
+ */
+ H5T_bit_copy (d, dst.u.f.sign, s, src.u.f.sign, 1);
+ H5T_bit_set (d, dst.u.f.epos, dst.u.f.esize, TRUE);
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize, TRUE);
+ goto padding;
+ }
+
+ /*
+ * Get the exponent as an unsigned quantity from the section of
+ * the source bit field where it's located. Don't worry about
+ * the exponent bias yet.
+ */
+ expo = H5T_bit_get_d(s, src.u.f.epos, src.u.f.esize);
+
+ /*
+ * Set markers for the source mantissa, excluding the leading `1'
+ * (might be implied).
+ */
+ implied = 1;
+ mpos = src.u.f.mpos;
+ mrsh = 0;
+ if (0==expo || H5T_NORM_NONE==src.u.f.norm) {
+ if ((bitno=H5T_bit_find(s, src.u.f.mpos, src.u.f.msize,
+ H5T_BIT_MSB, TRUE))>0) {
+ msize = bitno;
+ } else if (0==bitno) {
+ msize = 1;
+ H5T_bit_set(s, src.u.f.mpos, 1, FALSE);
+ }
+ } else if (H5T_NORM_IMPLIED==src.u.f.norm) {
+ msize = src.u.f.msize;
+ } else {
+ assert("normalization method not implemented yet" && 0);
+ abort();
+ }
+
+ /*
+ * The sign for the destination is the same as the sign for the
+ * source in all cases.
+ */
+ H5T_bit_copy (d, dst.u.f.sign, s, src.u.f.sign, 1);
+
+ /*
+ * Calculate the true source exponent by adjusting according to
+ * the source exponent bias.
+ */
+ if (0==expo || H5T_NORM_NONE==src.u.f.norm) {
+ bitno = H5T_bit_find(s, src.u.f.mpos, src.u.f.msize,
+ H5T_BIT_MSB, TRUE);
+ assert(bitno>=0);
+ expo -= (src.u.f.ebias-1) + (src.u.f.msize-bitno);
+ } else if (H5T_NORM_IMPLIED==src.u.f.norm) {
+ expo -= src.u.f.ebias;
+ } else {
+ assert("normalization method not implemented yet" && 0);
+ abort();
+ }
+
+ /*
+ * If the destination is not normalized then right shift the
+ * mantissa by one.
+ */
+ if (H5T_NORM_NONE==dst.u.f.norm) {
+ mrsh++;
+ }
+
+ /*
+ * Calculate the destination exponent by adding the destination
+ * bias and clipping by the minimum and maximum possible
+ * destination exponent values.
+ */
+ expo += dst.u.f.ebias;
+ if (expo < -(hssize_t)(dst.u.f.msize)) {
+ /* The exponent is way too small. Result is zero. */
+ expo = 0;
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize, FALSE);
+ msize = 0;
+
+ } else if (expo<=0) {
+ /*
+ * The exponent is too small to fit in the exponent field,
+ * but by shifting the mantissa to the right we can
+ * accomodate that value. The mantissa of course is no
+ * longer normalized.
+ */
+ mrsh += 1-expo;
+ expo = 0;
+
+ } else if (expo>=expo_max) {
+ /*
+ * The exponent is too large to fit in the available region
+ * or it results in the maximum possible value. Use positive
+ * or negative infinity instead.
+ */
+ expo = expo_max;
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize, FALSE);
+ msize = 0;
+
+ }
+
+ /*
+ * If the destination mantissa is smaller than the source
+ * mantissa then round the source mantissa. Rounding may cause a
+ * carry in which case the exponent has to be re-evaluated for
+ * overflow. That is, if `carry' is clear then the implied
+ * mantissa bit is `1', else it is `10' binary.
+ */
+ if (msize>0 && mrsh<=dst.u.f.msize && mrsh+msize>dst.u.f.msize) {
+ bitno = (ssize_t)(mrsh+msize - dst.u.f.msize);
+ assert(bitno>=0 && (size_t)bitno<=msize);
+ carry = H5T_bit_inc(s, mpos+bitno-1, 1+msize-bitno);
+ if (carry) implied = 2;
+ }
+
+ /*
+ * Write the mantissa to the destination
+ */
+ if (mrsh>dst.u.f.msize+1) {
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize, FALSE);
+ } else if (mrsh==dst.u.f.msize+1) {
+ H5T_bit_set(d, dst.u.f.mpos+1, dst.u.f.msize-1, FALSE);
+ H5T_bit_set(d, dst.u.f.mpos, 1, TRUE);
+ } else if (mrsh==dst.u.f.msize) {
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize, FALSE);
+ H5T_bit_set_d(d, dst.u.f.mpos, MIN(2, dst.u.f.msize), implied);
+ } else {
+ if (mrsh>0) {
+ H5T_bit_set(d, dst.u.f.mpos+dst.u.f.msize-mrsh, mrsh,
+ FALSE);
+ H5T_bit_set_d(d, dst.u.f.mpos+dst.u.f.msize-mrsh, 2,
+ implied);
+ }
+ if (mrsh+msize>=dst.u.f.msize) {
+ H5T_bit_copy(d, dst.u.f.mpos,
+ s, (mpos+msize+mrsh-dst.u.f.msize),
+ dst.u.f.msize-mrsh);
+ } else {
+ H5T_bit_copy(d, dst.u.f.mpos+dst.u.f.msize-(mrsh+msize),
+ s, mpos, msize);
+ H5T_bit_set(d, dst.u.f.mpos, dst.u.f.msize-(mrsh+msize),
+ FALSE);
+ }
+ }
+
+ /* Write the exponent */
+ H5T_bit_set_d(d, dst.u.f.epos, dst.u.f.esize, expo);
+
+ padding:
+#ifndef LATER
+ /*
+ * Set internal padding areas
+ */
+#endif
+
+ /*
+ * Set external padding areas
+ */
+ if (dst.offset>0) {
+ assert (H5T_PAD_ZERO==dst.lsb_pad ||
+ H5T_PAD_ONE==dst.lsb_pad);
+ H5T_bit_set (d, 0, dst.offset,
+ H5T_PAD_ONE==dst.lsb_pad);
+ }
+ if (dst.offset+dst.prec!=8*dst_p->size) {
+ assert (H5T_PAD_ZERO==dst.msb_pad ||
+ H5T_PAD_ONE==dst.msb_pad);
+ H5T_bit_set (d, dst.offset+dst.prec,
+ 8*dst_p->size - (dst.offset+dst.prec),
+ H5T_PAD_ONE==dst.msb_pad);
+ }
+
+ /*
+ * Put the destination in the correct byte order. See note at
+ * beginning of loop.
+ */
+ if (H5T_ORDER_BE==dst.order) {
+ half_size = dst_p->size/2;
+ for (i=0; i<half_size; i++) {
+ uint8 tmp = d[dst_p->size-(i+1)];
+ d[dst_p->size-(i+1)] = d[i];
+ d[i] = tmp;
+ }
+ }
+
+ /*
+ * If we had used a temporary buffer for the destination then we
+ * should copy the value to the true destination buffer.
+ */
+ if (d==dbuf) HDmemcpy (dp, d, dst_p->size);
+ sp += direction * src_p->size;
+ dp += direction * dst_p->size;
+ }
+
+ break;
+
+ default:
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "unknown conversion command");
+ }
+
+ FUNC_LEAVE (SUCCEED);
+}
+
+
+/*-------------------------------------------------------------------------
+ * Function: H5T_conv_float_double
+ *
+ * Purpose: Convert native `float' to native `double' using hardware.
+ * This is a fast special case.
+ *
+ * Return: Success: SUCCEED
+ *
+ * Failure: FAIL
+ *
+ * Programmer: Robb Matzke
+ * Tuesday, June 23, 1998
+ *
+ * Modifications:
+ *
+ *-------------------------------------------------------------------------
+ */
+herr_t
+H5T_conv_float_double (hid_t __unused__ src_id, hid_t __unused__ dst_id,
+ H5T_cdata_t *cdata, size_t nelmts, void *buf,
+ void __unused__ *bkg)
+{
+ size_t elmtno; /*element number */
+ float *s; /*source buffer */
+ double *d; /*destination buffer */
+
+ FUNC_ENTER (H5T_conv_float_double, FAIL);
+
+ switch (cdata->command) {
+ case H5T_CONV_INIT:
+ cdata->need_bkg = H5T_BKG_NO;
+ break;
+
+ case H5T_CONV_FREE:
+ break;
+
+ case H5T_CONV_CONV:
+ s = (float*)buf + nelmts;
+ d = (double*)buf + nelmts;
+
+ for (elmtno=0; elmtno<nelmts; elmtno++) {
+ *--d = *--s;
+ }
+ break;
+
+ default:
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "unknown conversion command");
+ }
+
+ FUNC_LEAVE (SUCCEED);
+}
+
+
+/*-------------------------------------------------------------------------
+ * Function: H5T_conv_double_float
+ *
+ * Purpose: Convert native `double' to native `float' using hardware.
+ * This is a fast special case.
+ *
+ * Return: Success: SUCCEED
+ *
+ * Failure: FAIL
+ *
+ * Programmer: Robb Matzke
+ * Tuesday, June 23, 1998
+ *
+ * Modifications:
+ *
+ *-------------------------------------------------------------------------
+ */
+herr_t
+H5T_conv_double_float (hid_t __unused__ src_id, hid_t __unused__ dst_id,
+ H5T_cdata_t *cdata, size_t nelmts, void *buf,
+ void __unused__ *bkg)
+{
+ size_t elmtno; /*element number */
+ double *s; /*source buffer */
+ float *d; /*destination buffer */
+
+ FUNC_ENTER (H5T_conv_double_float, FAIL);
+
+ switch (cdata->command) {
+ case H5T_CONV_INIT:
+ cdata->need_bkg = H5T_BKG_NO;
+ break;
+
+ case H5T_CONV_FREE:
+ break;
+
+ case H5T_CONV_CONV:
+ s = (double*)buf;
+ d = (float*)buf;
+
+ for (elmtno=0; elmtno<nelmts; elmtno++) {
+ *d++ = *s++;
+ }
+ break;
+
+ default:
+ HRETURN_ERROR (H5E_DATATYPE, H5E_UNSUPPORTED, FAIL,
+ "unknown conversion command");
+ }
+
+ FUNC_LEAVE (SUCCEED);
+}
+
+
+/*-------------------------------------------------------------------------
* Function: H5T_conv_i32le_f64le
*
* Purpose: Converts 4-byte little-endian integers (signed or unsigned)
@@ -894,7 +1387,6 @@ H5T_conv_i32le_f64le (hid_t src_id, hid_t dst_id, H5T_cdata_t *cdata,
uint8 *s=NULL, *d=NULL; /*src and dst buf pointers */
uint8 tmp[8]; /*temporary destination buffer */
H5T_t *src = NULL; /*source data type */
- H5T_t *dst = NULL; /*destination data type */
size_t elmtno; /*element counter */
uintn sign; /*sign bit */
uintn cin, cout; /*carry in/out */
@@ -919,7 +1411,7 @@ H5T_conv_i32le_f64le (hid_t src_id, hid_t dst_id, H5T_cdata_t *cdata,
if (H5_DATATYPE!=H5I_group (src_id) ||
NULL==(src=H5I_object (src_id)) ||
H5_DATATYPE!=H5I_group (dst_id) ||
- NULL==(dst=H5I_object (dst_id))) {
+ NULL==H5I_object (dst_id)) {
HRETURN_ERROR (H5E_ARGS, H5E_BADTYPE, FAIL, "not a data type");
}