mirror of
https://github.com/tildearrow/furnace.git
synced 2024-12-18 22:40:20 +00:00
54e93db207
not reliable yet
177 lines
5.2 KiB
C
177 lines
5.2 KiB
C
/*
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* Copyright (c) 2003, 2007-14 Matteo Frigo
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* Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program 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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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*
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*/
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#include "verify.h"
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/* copy A into B, using output stride of A and input stride of B */
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typedef struct {
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dotens2_closure k;
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R *ra; R *ia;
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R *rb; R *ib;
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int scalea, scaleb;
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} cpy_closure;
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static void cpy0(dotens2_closure *k_,
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int indxa, int ondxa, int indxb, int ondxb)
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{
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cpy_closure *k = (cpy_closure *)k_;
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k->rb[indxb * k->scaleb] = k->ra[ondxa * k->scalea];
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k->ib[indxb * k->scaleb] = k->ia[ondxa * k->scalea];
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UNUSED(indxa); UNUSED(ondxb);
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}
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static void cpy(R *ra, R *ia, const bench_tensor *sza, int scalea,
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R *rb, R *ib, const bench_tensor *szb, int scaleb)
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{
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cpy_closure k;
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k.k.apply = cpy0;
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k.ra = ra; k.ia = ia; k.rb = rb; k.ib = ib;
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k.scalea = scalea; k.scaleb = scaleb;
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bench_dotens2(sza, szb, &k.k);
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}
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typedef struct {
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dofft_closure k;
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bench_problem *p;
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} dofft_dft_closure;
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static void dft_apply(dofft_closure *k_, bench_complex *in, bench_complex *out)
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{
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dofft_dft_closure *k = (dofft_dft_closure *)k_;
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bench_problem *p = k->p;
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bench_tensor *totalsz, *pckdsz;
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bench_tensor *totalsz_swap, *pckdsz_swap;
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bench_real *ri, *ii, *ro, *io;
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int totalscale;
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totalsz = tensor_append(p->vecsz, p->sz);
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pckdsz = verify_pack(totalsz, 2);
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ri = (bench_real *) p->in;
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ro = (bench_real *) p->out;
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totalsz_swap = tensor_copy_swapio(totalsz);
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pckdsz_swap = tensor_copy_swapio(pckdsz);
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/* confusion: the stride is the distance between complex elements
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when using interleaved format, but it is the distance between
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real elements when using split format */
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if (p->split) {
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ii = p->ini ? (bench_real *) p->ini : ri + p->iphyssz;
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io = p->outi ? (bench_real *) p->outi : ro + p->ophyssz;
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totalscale = 1;
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} else {
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ii = p->ini ? (bench_real *) p->ini : ri + 1;
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io = p->outi ? (bench_real *) p->outi : ro + 1;
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totalscale = 2;
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}
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cpy(&c_re(in[0]), &c_im(in[0]), pckdsz, 1,
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ri, ii, totalsz, totalscale);
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after_problem_ccopy_from(p, ri, ii);
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doit(1, p);
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after_problem_ccopy_to(p, ro, io);
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if (k->k.recopy_input)
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cpy(ri, ii, totalsz_swap, totalscale,
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&c_re(in[0]), &c_im(in[0]), pckdsz_swap, 1);
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cpy(ro, io, totalsz, totalscale,
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&c_re(out[0]), &c_im(out[0]), pckdsz, 1);
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tensor_destroy(totalsz);
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tensor_destroy(pckdsz);
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tensor_destroy(totalsz_swap);
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tensor_destroy(pckdsz_swap);
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}
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void verify_dft(bench_problem *p, int rounds, double tol, errors *e)
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{
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C *inA, *inB, *inC, *outA, *outB, *outC, *tmp;
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int n, vecn, N;
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dofft_dft_closure k;
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BENCH_ASSERT(p->kind == PROBLEM_COMPLEX);
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k.k.apply = dft_apply;
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k.k.recopy_input = 0;
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k.p = p;
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if (rounds == 0)
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rounds = 20; /* default value */
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n = tensor_sz(p->sz);
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vecn = tensor_sz(p->vecsz);
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N = n * vecn;
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inA = (C *) bench_malloc(N * sizeof(C));
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inB = (C *) bench_malloc(N * sizeof(C));
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inC = (C *) bench_malloc(N * sizeof(C));
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outA = (C *) bench_malloc(N * sizeof(C));
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outB = (C *) bench_malloc(N * sizeof(C));
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outC = (C *) bench_malloc(N * sizeof(C));
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tmp = (C *) bench_malloc(N * sizeof(C));
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e->i = impulse(&k.k, n, vecn, inA, inB, inC, outA, outB, outC,
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tmp, rounds, tol);
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e->l = linear(&k.k, 0, N, inA, inB, inC, outA, outB, outC,
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tmp, rounds, tol);
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e->s = 0.0;
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e->s = dmax(e->s, tf_shift(&k.k, 0, p->sz, n, vecn, p->sign,
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inA, inB, outA, outB,
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tmp, rounds, tol, TIME_SHIFT));
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e->s = dmax(e->s, tf_shift(&k.k, 0, p->sz, n, vecn, p->sign,
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inA, inB, outA, outB,
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tmp, rounds, tol, FREQ_SHIFT));
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if (!p->in_place && !p->destroy_input)
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preserves_input(&k.k, 0, N, inA, inB, outB, rounds);
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bench_free(tmp);
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bench_free(outC);
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bench_free(outB);
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bench_free(outA);
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bench_free(inC);
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bench_free(inB);
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bench_free(inA);
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}
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void accuracy_dft(bench_problem *p, int rounds, int impulse_rounds,
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double t[6])
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{
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dofft_dft_closure k;
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int n;
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C *a, *b;
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BENCH_ASSERT(p->kind == PROBLEM_COMPLEX);
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BENCH_ASSERT(p->sz->rnk == 1);
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BENCH_ASSERT(p->vecsz->rnk == 0);
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k.k.apply = dft_apply;
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k.k.recopy_input = 0;
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k.p = p;
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n = tensor_sz(p->sz);
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a = (C *) bench_malloc(n * sizeof(C));
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b = (C *) bench_malloc(n * sizeof(C));
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accuracy_test(&k.k, 0, p->sign, n, a, b, rounds, impulse_rounds, t);
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bench_free(b);
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bench_free(a);
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}
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