Chris@10: /*
Chris@10: * Copyright (c) 2003, 2007-11 Matteo Frigo
Chris@10: * Copyright (c) 2003, 2007-11 Massachusetts Institute of Technology
Chris@10: *
Chris@10: * This program is free software; you can redistribute it and/or modify
Chris@10: * it under the terms of the GNU General Public License as published by
Chris@10: * the Free Software Foundation; either version 2 of the License, or
Chris@10: * (at your option) any later version.
Chris@10: *
Chris@10: * This program is distributed in the hope that it will be useful,
Chris@10: * but WITHOUT ANY WARRANTY; without even the implied warranty of
Chris@10: * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
Chris@10: * GNU General Public License for more details.
Chris@10: *
Chris@10: * You should have received a copy of the GNU General Public License
Chris@10: * along with this program; if not, write to the Free Software
Chris@10: * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
Chris@10: *
Chris@10: */
Chris@10:
Chris@10:
Chris@10: /* plans for rank-0 RDFTs (copy operations) */
Chris@10:
Chris@10: #include "rdft.h"
Chris@10:
Chris@10: #ifdef HAVE_STRING_H
Chris@10: #include <string.h> /* for memcpy() */
Chris@10: #endif
Chris@10:
Chris@10: #define MAXRNK 32 /* FIXME: should malloc() */
Chris@10:
Chris@10: typedef struct {
Chris@10: plan_rdft super;
Chris@10: INT vl;
Chris@10: int rnk;
Chris@10: iodim d[MAXRNK];
Chris@10: const char *nam;
Chris@10: } P;
Chris@10:
Chris@10: typedef struct {
Chris@10: solver super;
Chris@10: rdftapply apply;
Chris@10: int (*applicable)(const P *pln, const problem_rdft *p);
Chris@10: const char *nam;
Chris@10: } S;
Chris@10:
Chris@10: /* copy up to MAXRNK dimensions from problem into plan. If a
Chris@10: contiguous dimension exists, save its length in pln->vl */
Chris@10: static int fill_iodim(P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: int i;
Chris@10: const tensor *vecsz = p->vecsz;
Chris@10:
Chris@10: pln->vl = 1;
Chris@10: pln->rnk = 0;
Chris@10: for (i = 0; i < vecsz->rnk; ++i) {
Chris@10: /* extract contiguous dimensions */
Chris@10: if (pln->vl == 1 &&
Chris@10: vecsz->dims[i].is == 1 && vecsz->dims[i].os == 1)
Chris@10: pln->vl = vecsz->dims[i].n;
Chris@10: else if (pln->rnk == MAXRNK)
Chris@10: return 0;
Chris@10: else
Chris@10: pln->d[pln->rnk++] = vecsz->dims[i];
Chris@10: }
Chris@10:
Chris@10: return 1;
Chris@10: }
Chris@10:
Chris@10: /* generic higher-rank copy routine, calls cpy2d() to do the real work */
Chris@10: static void copy(const iodim *d, int rnk, INT vl,
Chris@10: R *I, R *O,
Chris@10: cpy2d_func cpy2d)
Chris@10: {
Chris@10: A(rnk >= 2);
Chris@10: if (rnk == 2)
Chris@10: cpy2d(I, O, d[0].n, d[0].is, d[0].os, d[1].n, d[1].is, d[1].os, vl);
Chris@10: else {
Chris@10: INT i;
Chris@10: for (i = 0; i < d[0].n; ++i, I += d[0].is, O += d[0].os)
Chris@10: copy(d + 1, rnk - 1, vl, I, O, cpy2d);
Chris@10: }
Chris@10: }
Chris@10:
Chris@10: /* FIXME: should be more general */
Chris@10: static int transposep(const P *pln)
Chris@10: {
Chris@10: int i;
Chris@10:
Chris@10: for (i = 0; i < pln->rnk - 2; ++i)
Chris@10: if (pln->d[i].is != pln->d[i].os)
Chris@10: return 0;
Chris@10:
Chris@10: return (pln->d[i].n == pln->d[i+1].n &&
Chris@10: pln->d[i].is == pln->d[i+1].os &&
Chris@10: pln->d[i].os == pln->d[i+1].is);
Chris@10: }
Chris@10:
Chris@10: /* generic higher-rank transpose routine, calls transpose2d() to do
Chris@10: * the real work */
Chris@10: static void transpose(const iodim *d, int rnk, INT vl,
Chris@10: R *I,
Chris@10: transpose_func transpose2d)
Chris@10: {
Chris@10: A(rnk >= 2);
Chris@10: if (rnk == 2)
Chris@10: transpose2d(I, d[0].n, d[0].is, d[0].os, vl);
Chris@10: else {
Chris@10: INT i;
Chris@10: for (i = 0; i < d[0].n; ++i, I += d[0].is)
Chris@10: transpose(d + 1, rnk - 1, vl, I, transpose2d);
Chris@10: }
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank 0,1,2, out of place, iterative */
Chris@10: static void apply_iter(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10:
Chris@10: switch (ego->rnk) {
Chris@10: case 0:
Chris@10: X(cpy1d)(I, O, ego->vl, 1, 1, 1);
Chris@10: break;
Chris@10: case 1:
Chris@10: X(cpy1d)(I, O,
Chris@10: ego->d[0].n, ego->d[0].is, ego->d[0].os,
Chris@10: ego->vl);
Chris@10: break;
Chris@10: default:
Chris@10: copy(ego->d, ego->rnk, ego->vl, I, O, X(cpy2d_ci));
Chris@10: break;
Chris@10: }
Chris@10: }
Chris@10:
Chris@10: static int applicable_iter(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: UNUSED(pln);
Chris@10: return (p->I != p->O);
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* out of place, write contiguous output */
Chris@10: static void apply_cpy2dco(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: copy(ego->d, ego->rnk, ego->vl, I, O, X(cpy2d_co));
Chris@10: }
Chris@10:
Chris@10: static int applicable_cpy2dco(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: int rnk = pln->rnk;
Chris@10: return (1
Chris@10: && p->I != p->O
Chris@10: && rnk >= 2
Chris@10:
Chris@10: /* must not duplicate apply_iter */
Chris@10: && (X(iabs)(pln->d[rnk - 2].is) <= X(iabs)(pln->d[rnk - 1].is)
Chris@10: ||
Chris@10: X(iabs)(pln->d[rnk - 2].os) <= X(iabs)(pln->d[rnk - 1].os))
Chris@10: );
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* out of place, tiled, no buffering */
Chris@10: static void apply_tiled(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: copy(ego->d, ego->rnk, ego->vl, I, O, X(cpy2d_tiled));
Chris@10: }
Chris@10:
Chris@10: static int applicable_tiled(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: return (1
Chris@10: && p->I != p->O
Chris@10: && pln->rnk >= 2
Chris@10:
Chris@10: /* somewhat arbitrary */
Chris@10: && X(compute_tilesz)(pln->vl, 1) > 4
Chris@10: );
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* out of place, tiled, with buffer */
Chris@10: static void apply_tiledbuf(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: copy(ego->d, ego->rnk, ego->vl, I, O, X(cpy2d_tiledbuf));
Chris@10: }
Chris@10:
Chris@10: #define applicable_tiledbuf applicable_tiled
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank 0, out of place, using memcpy */
Chris@10: static void apply_memcpy(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10:
Chris@10: A(ego->rnk == 0);
Chris@10: memcpy(O, I, ego->vl * sizeof(R));
Chris@10: }
Chris@10:
Chris@10: static int applicable_memcpy(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: return (1
Chris@10: && p->I != p->O
Chris@10: && pln->rnk == 0
Chris@10: && pln->vl > 2 /* do not bother memcpy-ing complex numbers */
Chris@10: );
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank > 0 vecloop, out of place, using memcpy (e.g. out-of-place
Chris@10: transposes of vl-tuples ... for large vl it should be more
Chris@10: efficient to use memcpy than the tiled stuff). */
Chris@10:
Chris@10: static void memcpy_loop(INT cpysz, int rnk, const iodim *d, R *I, R *O)
Chris@10: {
Chris@10: INT i, n = d->n, is = d->is, os = d->os;
Chris@10: if (rnk == 1)
Chris@10: for (i = 0; i < n; ++i, I += is, O += os)
Chris@10: memcpy(O, I, cpysz);
Chris@10: else {
Chris@10: --rnk; ++d;
Chris@10: for (i = 0; i < n; ++i, I += is, O += os)
Chris@10: memcpy_loop(cpysz, rnk, d, I, O);
Chris@10: }
Chris@10: }
Chris@10:
Chris@10: static void apply_memcpy_loop(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: memcpy_loop(ego->vl * sizeof(R), ego->rnk, ego->d, I, O);
Chris@10: }
Chris@10:
Chris@10: static int applicable_memcpy_loop(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: return (p->I != p->O
Chris@10: && pln->rnk > 0
Chris@10: && pln->vl > 2 /* do not bother memcpy-ing complex numbers */);
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank 2, in place, square transpose, iterative */
Chris@10: static void apply_ip_sq(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: UNUSED(O);
Chris@10: transpose(ego->d, ego->rnk, ego->vl, I, X(transpose));
Chris@10: }
Chris@10:
Chris@10:
Chris@10: static int applicable_ip_sq(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: return (1
Chris@10: && p->I == p->O
Chris@10: && pln->rnk >= 2
Chris@10: && transposep(pln));
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank 2, in place, square transpose, tiled */
Chris@10: static void apply_ip_sq_tiled(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: UNUSED(O);
Chris@10: transpose(ego->d, ego->rnk, ego->vl, I, X(transpose_tiled));
Chris@10: }
Chris@10:
Chris@10: static int applicable_ip_sq_tiled(const P *pln, const problem_rdft *p)
Chris@10: {
Chris@10: return (1
Chris@10: && applicable_ip_sq(pln, p)
Chris@10:
Chris@10: /* somewhat arbitrary */
Chris@10: && X(compute_tilesz)(pln->vl, 2) > 4
Chris@10: );
Chris@10: }
Chris@10:
Chris@10: /**************************************************************/
Chris@10: /* rank 2, in place, square transpose, tiled, buffered */
Chris@10: static void apply_ip_sq_tiledbuf(const plan *ego_, R *I, R *O)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: UNUSED(O);
Chris@10: transpose(ego->d, ego->rnk, ego->vl, I, X(transpose_tiledbuf));
Chris@10: }
Chris@10:
Chris@10: #define applicable_ip_sq_tiledbuf applicable_ip_sq_tiled
Chris@10:
Chris@10: /**************************************************************/
Chris@10: static int applicable(const S *ego, const problem *p_)
Chris@10: {
Chris@10: const problem_rdft *p = (const problem_rdft *) p_;
Chris@10: P pln;
Chris@10: return (1
Chris@10: && p->sz->rnk == 0
Chris@10: && FINITE_RNK(p->vecsz->rnk)
Chris@10: && fill_iodim(&pln, p)
Chris@10: && ego->applicable(&pln, p)
Chris@10: );
Chris@10: }
Chris@10:
Chris@10: static void print(const plan *ego_, printer *p)
Chris@10: {
Chris@10: const P *ego = (const P *) ego_;
Chris@10: int i;
Chris@10: p->print(p, "(%s/%D", ego->nam, ego->vl);
Chris@10: for (i = 0; i < ego->rnk; ++i)
Chris@10: p->print(p, "%v", ego->d[i].n);
Chris@10: p->print(p, ")");
Chris@10: }
Chris@10:
Chris@10: static plan *mkplan(const solver *ego_, const problem *p_, planner *plnr)
Chris@10: {
Chris@10: const problem_rdft *p;
Chris@10: const S *ego = (const S *) ego_;
Chris@10: P *pln;
Chris@10: int retval;
Chris@10:
Chris@10: static const plan_adt padt = {
Chris@10: X(rdft_solve), X(null_awake), print, X(plan_null_destroy)
Chris@10: };
Chris@10:
Chris@10: UNUSED(plnr);
Chris@10:
Chris@10: if (!applicable(ego, p_))
Chris@10: return (plan *) 0;
Chris@10:
Chris@10: p = (const problem_rdft *) p_;
Chris@10: pln = MKPLAN_RDFT(P, &padt, ego->apply);
Chris@10:
Chris@10: retval = fill_iodim(pln, p);
Chris@10: (void)retval; /* UNUSED unless DEBUG */
Chris@10: A(retval);
Chris@10: A(pln->vl > 0); /* because FINITE_RNK(p->vecsz->rnk) holds */
Chris@10: pln->nam = ego->nam;
Chris@10:
Chris@10: /* X(tensor_sz)(p->vecsz) loads, X(tensor_sz)(p->vecsz) stores */
Chris@10: X(ops_other)(2 * X(tensor_sz)(p->vecsz), &pln->super.super.ops);
Chris@10: return &(pln->super.super);
Chris@10: }
Chris@10:
Chris@10:
Chris@10: void X(rdft_rank0_register)(planner *p)
Chris@10: {
Chris@10: unsigned i;
Chris@10: static struct {
Chris@10: rdftapply apply;
Chris@10: int (*applicable)(const P *, const problem_rdft *);
Chris@10: const char *nam;
Chris@10: } tab[] = {
Chris@10: { apply_memcpy, applicable_memcpy, "rdft-rank0-memcpy" },
Chris@10: { apply_memcpy_loop, applicable_memcpy_loop,
Chris@10: "rdft-rank0-memcpy-loop" },
Chris@10: { apply_iter, applicable_iter, "rdft-rank0-iter-ci" },
Chris@10: { apply_cpy2dco, applicable_cpy2dco, "rdft-rank0-iter-co" },
Chris@10: { apply_tiled, applicable_tiled, "rdft-rank0-tiled" },
Chris@10: { apply_tiledbuf, applicable_tiledbuf, "rdft-rank0-tiledbuf" },
Chris@10: { apply_ip_sq, applicable_ip_sq, "rdft-rank0-ip-sq" },
Chris@10: {
Chris@10: apply_ip_sq_tiled,
Chris@10: applicable_ip_sq_tiled,
Chris@10: "rdft-rank0-ip-sq-tiled"
Chris@10: },
Chris@10: {
Chris@10: apply_ip_sq_tiledbuf,
Chris@10: applicable_ip_sq_tiledbuf,
Chris@10: "rdft-rank0-ip-sq-tiledbuf"
Chris@10: },
Chris@10: };
Chris@10:
Chris@10: for (i = 0; i < sizeof(tab) / sizeof(tab[0]); ++i) {
Chris@10: static const solver_adt sadt = { PROBLEM_RDFT, mkplan, 0 };
Chris@10: S *slv = MKSOLVER(S, &sadt);
Chris@10: slv->apply = tab[i].apply;
Chris@10: slv->applicable = tab[i].applicable;
Chris@10: slv->nam = tab[i].nam;
Chris@10: REGISTER_SOLVER(p, &(slv->super));
Chris@10: }
Chris@10: }