e606fb399e
* intrinsics/pack_generic.c (pack): Remove unneeded calculation. * m4/matmull.m4 (matmul_): Remove unneeded calculations, fix pointer cast to avoid warning. * generated/matmul_l4.c: Regenerated. * generated/matmul_l8.c: Regenerated. * Makefile.am: Remove AM_CFLAGS here. * configure.ac: Define AM_CFLAGS and AM_FCFLAGS so that warnings are set. Set additionally -Wstrict-prototypes for CFLAGS. * Makefile.in: Regenerated * configure: Regenerated. From-SVN: r99723
429 lines
12 KiB
C
429 lines
12 KiB
C
/* Generic implementation of the PACK intrinsic
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Copyright (C) 2002, 2004, 2005 Free Software Foundation, Inc.
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Contributed by Paul Brook <paul@nowt.org>
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This file is part of the GNU Fortran 95 runtime library (libgfortran).
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Libgfortran is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public
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License as published by the Free Software Foundation; either
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version 2 of the License, or (at your option) any later version.
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In addition to the permissions in the GNU General Public License, the
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Free Software Foundation gives you unlimited permission to link the
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compiled version of this file into combinations with other programs,
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and to distribute those combinations without any restriction coming
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from the use of this file. (The General Public License restrictions
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do apply in other respects; for example, they cover modification of
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the file, and distribution when not linked into a combine
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executable.)
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Ligbfortran is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public
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License along with libgfortran; see the file COPYING. If not,
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write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
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Boston, MA 02111-1307, USA. */
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#include "config.h"
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#include <stdlib.h>
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#include <assert.h>
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#include <string.h>
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#include "libgfortran.h"
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/* PACK is specified as follows:
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13.14.80 PACK (ARRAY, MASK, [VECTOR])
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Description: Pack an array into an array of rank one under the
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control of a mask.
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Class: Transformational fucntion.
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Arguments:
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ARRAY may be of any type. It shall not be scalar.
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MASK shall be of type LOGICAL. It shall be conformable with ARRAY.
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VECTOR (optional) shall be of the same type and type parameters
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as ARRAY. VECTOR shall have at least as many elements as
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there are true elements in MASK. If MASK is a scalar
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with the value true, VECTOR shall have at least as many
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elements as there are in ARRAY.
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Result Characteristics: The result is an array of rank one with the
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same type and type parameters as ARRAY. If VECTOR is present, the
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result size is that of VECTOR; otherwise, the result size is the
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number /t/ of true elements in MASK unless MASK is scalar with the
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value true, in which case the result size is the size of ARRAY.
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Result Value: Element /i/ of the result is the element of ARRAY
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that corresponds to the /i/th true element of MASK, taking elements
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in array element order, for /i/ = 1, 2, ..., /t/. If VECTOR is
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present and has size /n/ > /t/, element /i/ of the result has the
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value VECTOR(/i/), for /i/ = /t/ + 1, ..., /n/.
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Examples: The nonzero elements of an array M with the value
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| 0 0 0 |
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| 9 0 0 | may be "gathered" by the function PACK. The result of
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| 0 0 7 |
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PACK (M, MASK = M.NE.0) is [9,7] and the result of PACK (M, M.NE.0,
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VECTOR = (/ 2,4,6,8,10,12 /)) is [9,7,6,8,10,12].
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There are two variants of the PACK intrinsic: one, where MASK is
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array valued, and the other one where MASK is scalar. */
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extern void pack (gfc_array_char *, const gfc_array_char *,
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const gfc_array_l4 *, const gfc_array_char *);
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export_proto(pack);
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void
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pack (gfc_array_char *ret, const gfc_array_char *array,
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const gfc_array_l4 *mask, const gfc_array_char *vector)
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{
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/* r.* indicates the return array. */
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index_type rstride0;
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char *rptr;
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/* s.* indicates the source array. */
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index_type sstride[GFC_MAX_DIMENSIONS];
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index_type sstride0;
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const char *sptr;
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/* m.* indicates the mask array. */
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index_type mstride[GFC_MAX_DIMENSIONS];
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index_type mstride0;
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const GFC_LOGICAL_4 *mptr;
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index_type count[GFC_MAX_DIMENSIONS];
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index_type extent[GFC_MAX_DIMENSIONS];
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index_type n;
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index_type dim;
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index_type size;
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index_type nelem;
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size = GFC_DESCRIPTOR_SIZE (array);
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dim = GFC_DESCRIPTOR_RANK (array);
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for (n = 0; n < dim; n++)
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{
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count[n] = 0;
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extent[n] = array->dim[n].ubound + 1 - array->dim[n].lbound;
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sstride[n] = array->dim[n].stride * size;
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mstride[n] = mask->dim[n].stride;
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}
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if (sstride[0] == 0)
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sstride[0] = size;
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if (mstride[0] == 0)
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mstride[0] = 1;
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sptr = array->data;
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mptr = mask->data;
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/* Use the same loop for both logical types. */
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if (GFC_DESCRIPTOR_SIZE (mask) != 4)
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{
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if (GFC_DESCRIPTOR_SIZE (mask) != 8)
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runtime_error ("Funny sized logical array");
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for (n = 0; n < dim; n++)
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mstride[n] <<= 1;
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mptr = GFOR_POINTER_L8_TO_L4 (mptr);
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}
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if (ret->data == NULL)
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{
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/* Allocate the memory for the result. */
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int total;
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if (vector != NULL)
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{
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/* The return array will have as many
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elements as there are in VECTOR. */
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total = vector->dim[0].ubound + 1 - vector->dim[0].lbound;
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}
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else
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{
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/* We have to count the true elements in MASK. */
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/* TODO: We could speed up pack easily in the case of only
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few .TRUE. entries in MASK, by keeping track of where we
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would be in the source array during the initial traversal
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of MASK, and caching the pointers to those elements. Then,
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supposed the number of elements is small enough, we would
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only have to traverse the list, and copy those elements
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into the result array. In the case of datatypes which fit
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in one of the integer types we could also cache the
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value instead of a pointer to it.
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This approach might be bad from the point of view of
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cache behavior in the case where our cache is not big
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enough to hold all elements that have to be copied. */
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const GFC_LOGICAL_4 *m = mptr;
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total = 0;
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while (m)
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{
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/* Test this element. */
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if (*m)
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total++;
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/* Advance to the next element. */
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m += mstride[0];
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count[0]++;
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n = 0;
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while (count[n] == extent[n])
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{
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/* When we get to the end of a dimension, reset it
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and increment the next dimension. */
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count[n] = 0;
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/* We could precalculate this product, but this is a
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less frequently used path so proabably not worth
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it. */
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m -= mstride[n] * extent[n];
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n++;
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if (n >= dim)
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{
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/* Break out of the loop. */
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m = NULL;
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break;
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}
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else
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{
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count[n]++;
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mptr += mstride[n];
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}
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}
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}
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}
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/* Setup the array descriptor. */
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ret->dim[0].lbound = 0;
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ret->dim[0].ubound = total - 1;
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ret->dim[0].stride = 1;
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ret->data = internal_malloc_size (size * total);
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ret->base = 0;
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if (total == 0)
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/* In this case, nothing remains to be done. */
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return;
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}
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rstride0 = ret->dim[0].stride * size;
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if (rstride0 == 0)
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rstride0 = size;
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sstride0 = sstride[0];
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mstride0 = mstride[0];
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rptr = ret->data;
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while (sptr)
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{
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/* Test this element. */
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if (*mptr)
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{
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/* Add it. */
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memcpy (rptr, sptr, size);
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rptr += rstride0;
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}
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/* Advance to the next element. */
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sptr += sstride0;
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mptr += mstride0;
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count[0]++;
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n = 0;
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while (count[n] == extent[n])
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{
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/* When we get to the end of a dimension, reset it and increment
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the next dimension. */
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count[n] = 0;
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/* We could precalculate these products, but this is a less
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frequently used path so proabably not worth it. */
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sptr -= sstride[n] * extent[n];
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mptr -= mstride[n] * extent[n];
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n++;
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if (n >= dim)
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{
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/* Break out of the loop. */
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sptr = NULL;
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break;
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}
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else
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{
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count[n]++;
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sptr += sstride[n];
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mptr += mstride[n];
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}
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}
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}
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/* Add any remaining elements from VECTOR. */
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if (vector)
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{
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n = vector->dim[0].ubound + 1 - vector->dim[0].lbound;
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nelem = ((rptr - ret->data) / rstride0);
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if (n > nelem)
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{
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sstride0 = vector->dim[0].stride * size;
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if (sstride0 == 0)
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sstride0 = size;
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sptr = vector->data + sstride0 * nelem;
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n -= nelem;
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while (n--)
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{
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memcpy (rptr, sptr, size);
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rptr += rstride0;
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sptr += sstride0;
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}
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}
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}
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}
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extern void pack_s (gfc_array_char *ret, const gfc_array_char *array,
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const GFC_LOGICAL_4 *, const gfc_array_char *);
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export_proto(pack_s);
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void
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pack_s (gfc_array_char *ret, const gfc_array_char *array,
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const GFC_LOGICAL_4 *mask, const gfc_array_char *vector)
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{
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/* r.* indicates the return array. */
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index_type rstride0;
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char *rptr;
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/* s.* indicates the source array. */
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index_type sstride[GFC_MAX_DIMENSIONS];
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index_type sstride0;
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const char *sptr;
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index_type count[GFC_MAX_DIMENSIONS];
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index_type extent[GFC_MAX_DIMENSIONS];
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index_type n;
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index_type dim;
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index_type size;
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index_type nelem;
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size = GFC_DESCRIPTOR_SIZE (array);
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dim = GFC_DESCRIPTOR_RANK (array);
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for (n = 0; n < dim; n++)
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{
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count[n] = 0;
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extent[n] = array->dim[n].ubound + 1 - array->dim[n].lbound;
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sstride[n] = array->dim[n].stride * size;
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}
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if (sstride[0] == 0)
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sstride[0] = size;
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sstride0 = sstride[0];
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sptr = array->data;
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if (ret->data == NULL)
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{
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/* Allocate the memory for the result. */
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int total;
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if (vector != NULL)
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{
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/* The return array will have as many elements as there are
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in vector. */
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total = vector->dim[0].ubound + 1 - vector->dim[0].lbound;
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}
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else
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{
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if (*mask)
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{
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/* The result array will have as many elements as the input
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array. */
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total = extent[0];
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for (n = 1; n < dim; n++)
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total *= extent[n];
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}
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else
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{
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/* The result array will be empty. */
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ret->dim[0].lbound = 0;
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ret->dim[0].ubound = -1;
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ret->dim[0].stride = 1;
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ret->data = internal_malloc_size (0);
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ret->base = 0;
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return;
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}
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}
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/* Setup the array descriptor. */
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ret->dim[0].lbound = 0;
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ret->dim[0].ubound = total - 1;
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ret->dim[0].stride = 1;
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ret->data = internal_malloc_size (size * total);
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ret->base = 0;
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}
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rstride0 = ret->dim[0].stride * size;
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if (rstride0 == 0)
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rstride0 = size;
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rptr = ret->data;
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/* The remaining possibilities are now:
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If MASK is .TRUE., we have to copy the source array into the
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result array. We then have to fill it up with elements from VECTOR.
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If MASK is .FALSE., we have to copy VECTOR into the result
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array. If VECTOR were not present we would have already returned. */
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if (*mask)
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{
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while (sptr)
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{
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/* Add this element. */
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memcpy (rptr, sptr, size);
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rptr += rstride0;
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/* Advance to the next element. */
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sptr += sstride0;
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count[0]++;
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n = 0;
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while (count[n] == extent[n])
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{
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/* When we get to the end of a dimension, reset it and
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increment the next dimension. */
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count[n] = 0;
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/* We could precalculate these products, but this is a
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less frequently used path so proabably not worth it. */
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sptr -= sstride[n] * extent[n];
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n++;
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if (n >= dim)
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{
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/* Break out of the loop. */
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sptr = NULL;
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break;
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}
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else
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{
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count[n]++;
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sptr += sstride[n];
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}
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}
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}
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}
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/* Add any remaining elements from VECTOR. */
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if (vector)
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{
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n = vector->dim[0].ubound + 1 - vector->dim[0].lbound;
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nelem = ((rptr - ret->data) / rstride0);
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if (n > nelem)
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{
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sstride0 = vector->dim[0].stride * size;
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if (sstride0 == 0)
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sstride0 = size;
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sptr = vector->data + sstride0 * nelem;
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n -= nelem;
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while (n--)
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{
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memcpy (rptr, sptr, size);
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rptr += rstride0;
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sptr += sstride0;
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}
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}
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}
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}
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