sv-dependency-builds: src/fftw-3.3.3/kernel/cpy2d.c annotate

annotate src/fftw-3.3.3/kernel/cpy2d.c @ 23:619f715526df sv_v2.1

Update Vamp plugin SDK to 2.5

author	Chris Cannam
date	Thu, 09 May 2013 10:52:46 +0100
parents	37bf6b4a2645
children

rev	line source
Chris@10	1 /*
Chris@10	2 * Copyright (c) 2003, 2007-11 Matteo Frigo
Chris@10	3 * Copyright (c) 2003, 2007-11 Massachusetts Institute of Technology
Chris@10	4 *
Chris@10	5 * This program is free software; you can redistribute it and/or modify
Chris@10	6 * it under the terms of the GNU General Public License as published by
Chris@10	7 * the Free Software Foundation; either version 2 of the License, or
Chris@10	8 * (at your option) any later version.
Chris@10	9 *
Chris@10	10 * This program is distributed in the hope that it will be useful,
Chris@10	11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
Chris@10	12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
Chris@10	13 * GNU General Public License for more details.
Chris@10	14 *
Chris@10	15 * You should have received a copy of the GNU General Public License
Chris@10	16 * along with this program; if not, write to the Free Software
Chris@10	17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
Chris@10	18 *
Chris@10	19 */
Chris@10	20
Chris@10	21 /* out of place 2D copy routines */
Chris@10	22 #include "ifftw.h"
Chris@10	23
Chris@10	24 #if defined(__x86_64__) \|\| defined(_M_X64) \|\| defined(_M_AMD64)
Chris@10	25 # ifdef HAVE_XMMINTRIN_H
Chris@10	26 # include <xmmintrin.h>
Chris@10	27 # define WIDE_TYPE __m128
Chris@10	28 # endif
Chris@10	29 #endif
Chris@10	30
Chris@10	31 #ifndef WIDE_TYPE
Chris@10	32 /* fall back to double, which means that WIDE_TYPE will be unused */
Chris@10	33 # define WIDE_TYPE double
Chris@10	34 #endif
Chris@10	35
Chris@10	36 void X(cpy2d)(R I, R O,
Chris@10	37 INT n0, INT is0, INT os0,
Chris@10	38 INT n1, INT is1, INT os1,
Chris@10	39 INT vl)
Chris@10	40 {
Chris@10	41 INT i0, i1, v;
Chris@10	42
Chris@10	43 switch (vl) {
Chris@10	44 case 1:
Chris@10	45 for (i1 = 0; i1 < n1; ++i1)
Chris@10	46 for (i0 = 0; i0 < n0; ++i0) {
Chris@10	47 R x0 = I[i0 * is0 + i1 * is1];
Chris@10	48 O[i0 * os0 + i1 * os1] = x0;
Chris@10	49 }
Chris@10	50 break;
Chris@10	51 case 2:
Chris@10	52 if (1
Chris@10	53 && (2 * sizeof(R) == sizeof(WIDE_TYPE))
Chris@10	54 && (sizeof(WIDE_TYPE) > sizeof(double))
Chris@10	55 && (((size_t)I) % sizeof(WIDE_TYPE) == 0)
Chris@10	56 && (((size_t)O) % sizeof(WIDE_TYPE) == 0)
Chris@10	57 && ((is0 & 1) == 0)
Chris@10	58 && ((is1 & 1) == 0)
Chris@10	59 && ((os0 & 1) == 0)
Chris@10	60 && ((os1 & 1) == 0)) {
Chris@10	61 /* copy R[2] as WIDE_TYPE if WIDE_TYPE is large
Chris@10	62 enough to hold R[2], and if the input is
Chris@10	63 properly aligned. This is a win when R==double
Chris@10	64 and WIDE_TYPE is 128 bits. */
Chris@10	65 for (i1 = 0; i1 < n1; ++i1)
Chris@10	66 for (i0 = 0; i0 < n0; ++i0) {
Chris@10	67 (WIDE_TYPE )&O[i0 * os0 + i1 * os1] =
Chris@10	68 (WIDE_TYPE )&I[i0 * is0 + i1 * is1];
Chris@10	69 }
Chris@10	70 } else if (1
Chris@10	71 && (2 * sizeof(R) == sizeof(double))
Chris@10	72 && (((size_t)I) % sizeof(double) == 0)
Chris@10	73 && (((size_t)O) % sizeof(double) == 0)
Chris@10	74 && ((is0 & 1) == 0)
Chris@10	75 && ((is1 & 1) == 0)
Chris@10	76 && ((os0 & 1) == 0)
Chris@10	77 && ((os1 & 1) == 0)) {
Chris@10	78 /* copy R[2] as double if double is large enough to
Chris@10	79 hold R[2], and if the input is properly aligned.
Chris@10	80 This case applies when R==float */
Chris@10	81 for (i1 = 0; i1 < n1; ++i1)
Chris@10	82 for (i0 = 0; i0 < n0; ++i0) {
Chris@10	83 (double )&O[i0 * os0 + i1 * os1] =
Chris@10	84 (double )&I[i0 * is0 + i1 * is1];
Chris@10	85 }
Chris@10	86 } else {
Chris@10	87 for (i1 = 0; i1 < n1; ++i1)
Chris@10	88 for (i0 = 0; i0 < n0; ++i0) {
Chris@10	89 R x0 = I[i0 * is0 + i1 * is1];
Chris@10	90 R x1 = I[i0 * is0 + i1 * is1 + 1];
Chris@10	91 O[i0 * os0 + i1 * os1] = x0;
Chris@10	92 O[i0 * os0 + i1 * os1 + 1] = x1;
Chris@10	93 }
Chris@10	94 }
Chris@10	95 break;
Chris@10	96 default:
Chris@10	97 for (i1 = 0; i1 < n1; ++i1)
Chris@10	98 for (i0 = 0; i0 < n0; ++i0)
Chris@10	99 for (v = 0; v < vl; ++v) {
Chris@10	100 R x0 = I[i0 * is0 + i1 * is1 + v];
Chris@10	101 O[i0 * os0 + i1 * os1 + v] = x0;
Chris@10	102 }
Chris@10	103 break;
Chris@10	104 }
Chris@10	105 }
Chris@10	106
Chris@10	107 /* like cpy2d, but read input contiguously if possible */
Chris@10	108 void X(cpy2d_ci)(R I, R O,
Chris@10	109 INT n0, INT is0, INT os0,
Chris@10	110 INT n1, INT is1, INT os1,
Chris@10	111 INT vl)
Chris@10	112 {
Chris@10	113 if (IABS(is0) < IABS(is1)) /* inner loop is for n0 */
Chris@10	114 X(cpy2d) (I, O, n0, is0, os0, n1, is1, os1, vl);
Chris@10	115 else
Chris@10	116 X(cpy2d) (I, O, n1, is1, os1, n0, is0, os0, vl);
Chris@10	117 }
Chris@10	118
Chris@10	119 /* like cpy2d, but write output contiguously if possible */
Chris@10	120 void X(cpy2d_co)(R I, R O,
Chris@10	121 INT n0, INT is0, INT os0,
Chris@10	122 INT n1, INT is1, INT os1,
Chris@10	123 INT vl)
Chris@10	124 {
Chris@10	125 if (IABS(os0) < IABS(os1)) /* inner loop is for n0 */
Chris@10	126 X(cpy2d) (I, O, n0, is0, os0, n1, is1, os1, vl);
Chris@10	127 else
Chris@10	128 X(cpy2d) (I, O, n1, is1, os1, n0, is0, os0, vl);
Chris@10	129 }
Chris@10	130
Chris@10	131
Chris@10	132 /* tiled copy routines */
Chris@10	133 struct cpy2d_closure {
Chris@10	134 R I, O;
Chris@10	135 INT is0, os0, is1, os1, vl;
Chris@10	136 R *buf;
Chris@10	137 };
Chris@10	138
Chris@10	139 static void dotile(INT n0l, INT n0u, INT n1l, INT n1u, void *args)
Chris@10	140 {
Chris@10	141 struct cpy2d_closure k = (struct cpy2d_closure )args;
Chris@10	142 X(cpy2d)(k->I + n0l * k->is0 + n1l * k->is1,
Chris@10	143 k->O + n0l * k->os0 + n1l * k->os1,
Chris@10	144 n0u - n0l, k->is0, k->os0,
Chris@10	145 n1u - n1l, k->is1, k->os1,
Chris@10	146 k->vl);
Chris@10	147 }
Chris@10	148
Chris@10	149 static void dotile_buf(INT n0l, INT n0u, INT n1l, INT n1u, void *args)
Chris@10	150 {
Chris@10	151 struct cpy2d_closure k = (struct cpy2d_closure )args;
Chris@10	152
Chris@10	153 /* copy from I to buf */
Chris@10	154 X(cpy2d_ci)(k->I + n0l * k->is0 + n1l * k->is1,
Chris@10	155 k->buf,
Chris@10	156 n0u - n0l, k->is0, k->vl,
Chris@10	157 n1u - n1l, k->is1, k->vl * (n0u - n0l),
Chris@10	158 k->vl);
Chris@10	159
Chris@10	160 /* copy from buf to O */
Chris@10	161 X(cpy2d_co)(k->buf,
Chris@10	162 k->O + n0l * k->os0 + n1l * k->os1,
Chris@10	163 n0u - n0l, k->vl, k->os0,
Chris@10	164 n1u - n1l, k->vl * (n0u - n0l), k->os1,
Chris@10	165 k->vl);
Chris@10	166 }
Chris@10	167
Chris@10	168
Chris@10	169 void X(cpy2d_tiled)(R I, R O,
Chris@10	170 INT n0, INT is0, INT os0,
Chris@10	171 INT n1, INT is1, INT os1, INT vl)
Chris@10	172 {
Chris@10	173 INT tilesz = X(compute_tilesz)(vl,
Chris@10	174 1 /* input array */
Chris@10	175 + 1 /* ouput array */);
Chris@10	176 struct cpy2d_closure k;
Chris@10	177 k.I = I;
Chris@10	178 k.O = O;
Chris@10	179 k.is0 = is0;
Chris@10	180 k.os0 = os0;
Chris@10	181 k.is1 = is1;
Chris@10	182 k.os1 = os1;
Chris@10	183 k.vl = vl;
Chris@10	184 k.buf = 0; /* unused */
Chris@10	185 X(tile2d)(0, n0, 0, n1, tilesz, dotile, &k);
Chris@10	186 }
Chris@10	187
Chris@10	188 void X(cpy2d_tiledbuf)(R I, R O,
Chris@10	189 INT n0, INT is0, INT os0,
Chris@10	190 INT n1, INT is1, INT os1, INT vl)
Chris@10	191 {
Chris@10	192 R buf[CACHESIZE / (2 * sizeof(R))];
Chris@10	193 /* input and buffer in cache, or
Chris@10	194 output and buffer in cache */
Chris@10	195 INT tilesz = X(compute_tilesz)(vl, 2);
Chris@10	196 struct cpy2d_closure k;
Chris@10	197 k.I = I;
Chris@10	198 k.O = O;
Chris@10	199 k.is0 = is0;
Chris@10	200 k.os0 = os0;
Chris@10	201 k.is1 = is1;
Chris@10	202 k.os1 = os1;
Chris@10	203 k.vl = vl;
Chris@10	204 k.buf = buf;
Chris@10	205 A(tilesz * tilesz * vl * sizeof(R) <= sizeof(buf));
Chris@10	206 X(tile2d)(0, n0, 0, n1, tilesz, dotile_buf, &k);
Chris@10	207 }

Mercurial > hg > sv-dependency-builds

annotate src/fftw-3.3.3/kernel/cpy2d.c @ 23:619f715526df sv_v2.1