sv-dependency-builds: src/fftw-3.3.5/libbench2/verify-rdft2.c annotate

annotate src/fftw-3.3.5/libbench2/verify-rdft2.c @ 168:ceec0dd9ec9c

Replace these with versions built using an older toolset (so as to avoid ABI compatibilities when linking on Ubuntu 14.04 for packaging purposes)

author	Chris Cannam <cannam@all-day-breakfast.com>
date	Fri, 07 Feb 2020 11:51:13 +0000
parents	7867fa7e1b6b
children

rev	line source
cannam@127	1 /*
cannam@127	2 * Copyright (c) 2003, 2007-14 Matteo Frigo
cannam@127	3 * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
cannam@127	4 *
cannam@127	5 * This program is free software; you can redistribute it and/or modify
cannam@127	6 * it under the terms of the GNU General Public License as published by
cannam@127	7 * the Free Software Foundation; either version 2 of the License, or
cannam@127	8 * (at your option) any later version.
cannam@127	9 *
cannam@127	10 * This program is distributed in the hope that it will be useful,
cannam@127	11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
cannam@127	12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
cannam@127	13 * GNU General Public License for more details.
cannam@127	14 *
cannam@127	15 * You should have received a copy of the GNU General Public License
cannam@127	16 * along with this program; if not, write to the Free Software
cannam@127	17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
cannam@127	18 *
cannam@127	19 */
cannam@127	20
cannam@127	21
cannam@127	22 #include "verify.h"
cannam@127	23
cannam@127	24 /* copy real A into real B, using output stride of A and input stride of B */
cannam@127	25 typedef struct {
cannam@127	26 dotens2_closure k;
cannam@127	27 R *ra;
cannam@127	28 R *rb;
cannam@127	29 } cpyr_closure;
cannam@127	30
cannam@127	31 static void cpyr0(dotens2_closure *k_,
cannam@127	32 int indxa, int ondxa, int indxb, int ondxb)
cannam@127	33 {
cannam@127	34 cpyr_closure k = (cpyr_closure )k_;
cannam@127	35 k->rb[indxb] = k->ra[ondxa];
cannam@127	36 UNUSED(indxa); UNUSED(ondxb);
cannam@127	37 }
cannam@127	38
cannam@127	39 static void cpyr(R ra, const bench_tensor sza,
cannam@127	40 R rb, const bench_tensor szb)
cannam@127	41 {
cannam@127	42 cpyr_closure k;
cannam@127	43 k.k.apply = cpyr0;
cannam@127	44 k.ra = ra; k.rb = rb;
cannam@127	45 bench_dotens2(sza, szb, &k.k);
cannam@127	46 }
cannam@127	47
cannam@127	48 /* copy unpacked halfcomplex A[n] into packed-complex B[n], using output stride
cannam@127	49 of A and input stride of B. Only copies non-redundant half; other
cannam@127	50 half must be copied via mkhermitian. */
cannam@127	51 typedef struct {
cannam@127	52 dotens2_closure k;
cannam@127	53 int n;
cannam@127	54 int as;
cannam@127	55 int scalea;
cannam@127	56 R ra, ia;
cannam@127	57 R rb, ib;
cannam@127	58 } cpyhc2_closure;
cannam@127	59
cannam@127	60 static void cpyhc20(dotens2_closure *k_,
cannam@127	61 int indxa, int ondxa, int indxb, int ondxb)
cannam@127	62 {
cannam@127	63 cpyhc2_closure k = (cpyhc2_closure )k_;
cannam@127	64 int i, n = k->n;
cannam@127	65 int scalea = k->scalea;
cannam@127	66 int as = k->as * scalea;
cannam@127	67 R ra = k->ra + ondxa scalea, ia = k->ia + ondxa scalea;
cannam@127	68 R rb = k->rb + indxb, ib = k->ib + indxb;
cannam@127	69 UNUSED(indxa); UNUSED(ondxb);
cannam@127	70
cannam@127	71 for (i = 0; i < n/2 + 1; ++i) {
cannam@127	72 rb[2i] = ra[asi];
cannam@127	73 ib[2i] = ia[asi];
cannam@127	74 }
cannam@127	75 }
cannam@127	76
cannam@127	77 static void cpyhc2(R ra, R ia,
cannam@127	78 const bench_tensor sza, const bench_tensor vecsza,
cannam@127	79 int scalea,
cannam@127	80 R rb, R ib, const bench_tensor *szb)
cannam@127	81 {
cannam@127	82 cpyhc2_closure k;
cannam@127	83 BENCH_ASSERT(sza->rnk <= 1);
cannam@127	84 k.k.apply = cpyhc20;
cannam@127	85 k.n = tensor_sz(sza);
cannam@127	86 k.scalea = scalea;
cannam@127	87 if (!BENCH_FINITE_RNK(sza->rnk) \|\| sza->rnk == 0)
cannam@127	88 k.as = 0;
cannam@127	89 else
cannam@127	90 k.as = sza->dims[0].os;
cannam@127	91 k.ra = ra; k.ia = ia; k.rb = rb; k.ib = ib;
cannam@127	92 bench_dotens2(vecsza, szb, &k.k);
cannam@127	93 }
cannam@127	94
cannam@127	95 /* icpyhc2 is the inverse of cpyhc2 */
cannam@127	96
cannam@127	97 static void icpyhc20(dotens2_closure *k_,
cannam@127	98 int indxa, int ondxa, int indxb, int ondxb)
cannam@127	99 {
cannam@127	100 cpyhc2_closure k = (cpyhc2_closure )k_;
cannam@127	101 int i, n = k->n;
cannam@127	102 int scalea = k->scalea;
cannam@127	103 int as = k->as * scalea;
cannam@127	104 R ra = k->ra + indxa scalea, ia = k->ia + indxa scalea;
cannam@127	105 R rb = k->rb + ondxb, ib = k->ib + ondxb;
cannam@127	106 UNUSED(ondxa); UNUSED(indxb);
cannam@127	107
cannam@127	108 for (i = 0; i < n/2 + 1; ++i) {
cannam@127	109 ra[asi] = rb[2i];
cannam@127	110 ia[asi] = ib[2i];
cannam@127	111 }
cannam@127	112 }
cannam@127	113
cannam@127	114 static void icpyhc2(R ra, R ia,
cannam@127	115 const bench_tensor sza, const bench_tensor vecsza,
cannam@127	116 int scalea,
cannam@127	117 R rb, R ib, const bench_tensor *szb)
cannam@127	118 {
cannam@127	119 cpyhc2_closure k;
cannam@127	120 BENCH_ASSERT(sza->rnk <= 1);
cannam@127	121 k.k.apply = icpyhc20;
cannam@127	122 k.n = tensor_sz(sza);
cannam@127	123 k.scalea = scalea;
cannam@127	124 if (!BENCH_FINITE_RNK(sza->rnk) \|\| sza->rnk == 0)
cannam@127	125 k.as = 0;
cannam@127	126 else
cannam@127	127 k.as = sza->dims[0].is;
cannam@127	128 k.ra = ra; k.ia = ia; k.rb = rb; k.ib = ib;
cannam@127	129 bench_dotens2(vecsza, szb, &k.k);
cannam@127	130 }
cannam@127	131
cannam@127	132 typedef struct {
cannam@127	133 dofft_closure k;
cannam@127	134 bench_problem *p;
cannam@127	135 } dofft_rdft2_closure;
cannam@127	136
cannam@127	137 static void rdft2_apply(dofft_closure *k_,
cannam@127	138 bench_complex in, bench_complex out)
cannam@127	139 {
cannam@127	140 dofft_rdft2_closure k = (dofft_rdft2_closure )k_;
cannam@127	141 bench_problem *p = k->p;
cannam@127	142 bench_tensor totalsz, pckdsz, totalsz_swap, pckdsz_swap;
cannam@127	143 bench_tensor probsz2, totalsz2, *pckdsz2;
cannam@127	144 bench_tensor probsz2_swap, totalsz2_swap, *pckdsz2_swap;
cannam@127	145 bench_real ri, ii, ro, io;
cannam@127	146 int n2, totalscale;
cannam@127	147
cannam@127	148 totalsz = tensor_append(p->vecsz, p->sz);
cannam@127	149 pckdsz = verify_pack(totalsz, 2);
cannam@127	150 n2 = tensor_sz(totalsz);
cannam@127	151 if (BENCH_FINITE_RNK(p->sz->rnk) && p->sz->rnk > 0)
cannam@127	152 n2 = (n2 / p->sz->dims[p->sz->rnk - 1].n) *
cannam@127	153 (p->sz->dims[p->sz->rnk - 1].n / 2 + 1);
cannam@127	154 ri = (bench_real *) p->in;
cannam@127	155 ro = (bench_real *) p->out;
cannam@127	156
cannam@127	157 if (BENCH_FINITE_RNK(p->sz->rnk) && p->sz->rnk > 0 && n2 > 0) {
cannam@127	158 probsz2 = tensor_copy_sub(p->sz, p->sz->rnk - 1, 1);
cannam@127	159 totalsz2 = tensor_copy_sub(totalsz, 0, totalsz->rnk - 1);
cannam@127	160 pckdsz2 = tensor_copy_sub(pckdsz, 0, pckdsz->rnk - 1);
cannam@127	161 }
cannam@127	162 else {
cannam@127	163 probsz2 = mktensor(0);
cannam@127	164 totalsz2 = tensor_copy(totalsz);
cannam@127	165 pckdsz2 = tensor_copy(pckdsz);
cannam@127	166 }
cannam@127	167
cannam@127	168 totalsz_swap = tensor_copy_swapio(totalsz);
cannam@127	169 pckdsz_swap = tensor_copy_swapio(pckdsz);
cannam@127	170 totalsz2_swap = tensor_copy_swapio(totalsz2);
cannam@127	171 pckdsz2_swap = tensor_copy_swapio(pckdsz2);
cannam@127	172 probsz2_swap = tensor_copy_swapio(probsz2);
cannam@127	173
cannam@127	174 /* confusion: the stride is the distance between complex elements
cannam@127	175 when using interleaved format, but it is the distance between
cannam@127	176 real elements when using split format */
cannam@127	177 if (p->split) {
cannam@127	178 ii = p->ini ? (bench_real *) p->ini : ri + n2;
cannam@127	179 io = p->outi ? (bench_real *) p->outi : ro + n2;
cannam@127	180 totalscale = 1;
cannam@127	181 } else {
cannam@127	182 ii = p->ini ? (bench_real *) p->ini : ri + 1;
cannam@127	183 io = p->outi ? (bench_real *) p->outi : ro + 1;
cannam@127	184 totalscale = 2;
cannam@127	185 }
cannam@127	186
cannam@127	187 if (p->sign < 0) { /* R2HC */
cannam@127	188 int N, vN, i;
cannam@127	189 cpyr(&c_re(in[0]), pckdsz, ri, totalsz);
cannam@127	190 after_problem_rcopy_from(p, ri);
cannam@127	191 doit(1, p);
cannam@127	192 after_problem_hccopy_to(p, ro, io);
cannam@127	193 if (k->k.recopy_input)
cannam@127	194 cpyr(ri, totalsz_swap, &c_re(in[0]), pckdsz_swap);
cannam@127	195 cpyhc2(ro, io, probsz2, totalsz2, totalscale,
cannam@127	196 &c_re(out[0]), &c_im(out[0]), pckdsz2);
cannam@127	197 N = tensor_sz(p->sz);
cannam@127	198 vN = tensor_sz(p->vecsz);
cannam@127	199 for (i = 0; i < vN; ++i)
cannam@127	200 mkhermitian(out + i*N, p->sz->rnk, p->sz->dims, 1);
cannam@127	201 }
cannam@127	202 else { /* HC2R */
cannam@127	203 icpyhc2(ri, ii, probsz2, totalsz2, totalscale,
cannam@127	204 &c_re(in[0]), &c_im(in[0]), pckdsz2);
cannam@127	205 after_problem_hccopy_from(p, ri, ii);
cannam@127	206 doit(1, p);
cannam@127	207 after_problem_rcopy_to(p, ro);
cannam@127	208 if (k->k.recopy_input)
cannam@127	209 cpyhc2(ri, ii, probsz2_swap, totalsz2_swap, totalscale,
cannam@127	210 &c_re(in[0]), &c_im(in[0]), pckdsz2_swap);
cannam@127	211 mkreal(out, tensor_sz(pckdsz));
cannam@127	212 cpyr(ro, totalsz, &c_re(out[0]), pckdsz);
cannam@127	213 }
cannam@127	214
cannam@127	215 tensor_destroy(totalsz);
cannam@127	216 tensor_destroy(pckdsz);
cannam@127	217 tensor_destroy(totalsz_swap);
cannam@127	218 tensor_destroy(pckdsz_swap);
cannam@127	219 tensor_destroy(probsz2);
cannam@127	220 tensor_destroy(totalsz2);
cannam@127	221 tensor_destroy(pckdsz2);
cannam@127	222 tensor_destroy(probsz2_swap);
cannam@127	223 tensor_destroy(totalsz2_swap);
cannam@127	224 tensor_destroy(pckdsz2_swap);
cannam@127	225 }
cannam@127	226
cannam@127	227 void verify_rdft2(bench_problem p, int rounds, double tol, errors e)
cannam@127	228 {
cannam@127	229 C inA, inB, inC, outA, outB, outC, *tmp;
cannam@127	230 int n, vecn, N;
cannam@127	231 dofft_rdft2_closure k;
cannam@127	232
cannam@127	233 BENCH_ASSERT(p->kind == PROBLEM_REAL);
cannam@127	234
cannam@127	235 if (!BENCH_FINITE_RNK(p->sz->rnk) \|\| !BENCH_FINITE_RNK(p->vecsz->rnk))
cannam@127	236 return; /* give up */
cannam@127	237
cannam@127	238 k.k.apply = rdft2_apply;
cannam@127	239 k.k.recopy_input = 0;
cannam@127	240 k.p = p;
cannam@127	241
cannam@127	242 if (rounds == 0)
cannam@127	243 rounds = 20; /* default value */
cannam@127	244
cannam@127	245 n = tensor_sz(p->sz);
cannam@127	246 vecn = tensor_sz(p->vecsz);
cannam@127	247 N = n * vecn;
cannam@127	248
cannam@127	249 inA = (C ) bench_malloc(N sizeof(C));
cannam@127	250 inB = (C ) bench_malloc(N sizeof(C));
cannam@127	251 inC = (C ) bench_malloc(N sizeof(C));
cannam@127	252 outA = (C ) bench_malloc(N sizeof(C));
cannam@127	253 outB = (C ) bench_malloc(N sizeof(C));
cannam@127	254 outC = (C ) bench_malloc(N sizeof(C));
cannam@127	255 tmp = (C ) bench_malloc(N sizeof(C));
cannam@127	256
cannam@127	257 e->i = impulse(&k.k, n, vecn, inA, inB, inC, outA, outB, outC,
cannam@127	258 tmp, rounds, tol);
cannam@127	259 e->l = linear(&k.k, 1, N, inA, inB, inC, outA, outB, outC,
cannam@127	260 tmp, rounds, tol);
cannam@127	261
cannam@127	262 e->s = 0.0;
cannam@127	263 if (p->sign < 0)
cannam@127	264 e->s = dmax(e->s, tf_shift(&k.k, 1, p->sz, n, vecn, p->sign,
cannam@127	265 inA, inB, outA, outB,
cannam@127	266 tmp, rounds, tol, TIME_SHIFT));
cannam@127	267 else
cannam@127	268 e->s = dmax(e->s, tf_shift(&k.k, 1, p->sz, n, vecn, p->sign,
cannam@127	269 inA, inB, outA, outB,
cannam@127	270 tmp, rounds, tol, FREQ_SHIFT));
cannam@127	271
cannam@127	272 if (!p->in_place && !p->destroy_input)
cannam@127	273 preserves_input(&k.k, p->sign < 0 ? mkreal : mkhermitian1,
cannam@127	274 N, inA, inB, outB, rounds);
cannam@127	275
cannam@127	276 bench_free(tmp);
cannam@127	277 bench_free(outC);
cannam@127	278 bench_free(outB);
cannam@127	279 bench_free(outA);
cannam@127	280 bench_free(inC);
cannam@127	281 bench_free(inB);
cannam@127	282 bench_free(inA);
cannam@127	283 }
cannam@127	284
cannam@127	285 void accuracy_rdft2(bench_problem *p, int rounds, int impulse_rounds,
cannam@127	286 double t[6])
cannam@127	287 {
cannam@127	288 dofft_rdft2_closure k;
cannam@127	289 int n;
cannam@127	290 C a, b;
cannam@127	291
cannam@127	292 BENCH_ASSERT(p->kind == PROBLEM_REAL);
cannam@127	293 BENCH_ASSERT(p->sz->rnk == 1);
cannam@127	294 BENCH_ASSERT(p->vecsz->rnk == 0);
cannam@127	295
cannam@127	296 k.k.apply = rdft2_apply;
cannam@127	297 k.k.recopy_input = 0;
cannam@127	298 k.p = p;
cannam@127	299 n = tensor_sz(p->sz);
cannam@127	300
cannam@127	301 a = (C ) bench_malloc(n sizeof(C));
cannam@127	302 b = (C ) bench_malloc(n sizeof(C));
cannam@127	303 accuracy_test(&k.k, p->sign < 0 ? mkreal : mkhermitian1, p->sign,
cannam@127	304 n, a, b, rounds, impulse_rounds, t);
cannam@127	305 bench_free(b);
cannam@127	306 bench_free(a);
cannam@127	307 }

Mercurial > hg > sv-dependency-builds

annotate src/fftw-3.3.5/libbench2/verify-rdft2.c @ 168:ceec0dd9ec9c