sv-dependency-builds: src/fftw-3.3.8/mpi/transpose-pairwise.c annotate

annotate src/fftw-3.3.8/mpi/transpose-pairwise.c @ 169:223a55898ab9 tip default

Add null config files

author	Chris Cannam <cannam@all-day-breakfast.com>
date	Mon, 02 Mar 2020 14:03:47 +0000
parents	bd3cc4d1df30
children

rev	line source
cannam@167	1 /*
cannam@167	2 * Copyright (c) 2003, 2007-14 Matteo Frigo
cannam@167	3 * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
cannam@167	4 *
cannam@167	5 * This program is free software; you can redistribute it and/or modify
cannam@167	6 * it under the terms of the GNU General Public License as published by
cannam@167	7 * the Free Software Foundation; either version 2 of the License, or
cannam@167	8 * (at your option) any later version.
cannam@167	9 *
cannam@167	10 * This program is distributed in the hope that it will be useful,
cannam@167	11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
cannam@167	12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
cannam@167	13 * GNU General Public License for more details.
cannam@167	14 *
cannam@167	15 * You should have received a copy of the GNU General Public License
cannam@167	16 * along with this program; if not, write to the Free Software
cannam@167	17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
cannam@167	18 *
cannam@167	19 */
cannam@167	20
cannam@167	21 /* Distributed transposes using a sequence of carefully scheduled
cannam@167	22 pairwise exchanges. This has the advantage that it can be done
cannam@167	23 in-place, or out-of-place while preserving the input, using buffer
cannam@167	24 space proportional to the local size divided by the number of
cannam@167	25 processes (i.e. to the total array size divided by the number of
cannam@167	26 processes squared). */
cannam@167	27
cannam@167	28 #include "mpi-transpose.h"
cannam@167	29 #include <string.h>
cannam@167	30
cannam@167	31 typedef struct {
cannam@167	32 solver super;
cannam@167	33 int preserve_input; /* preserve input even if DESTROY_INPUT was passed */
cannam@167	34 } S;
cannam@167	35
cannam@167	36 typedef struct {
cannam@167	37 plan_mpi_transpose super;
cannam@167	38
cannam@167	39 plan cld1, cld2, cld2rest, cld3;
cannam@167	40 INT rest_Ioff, rest_Ooff;
cannam@167	41
cannam@167	42 int n_pes, my_pe, *sched;
cannam@167	43 INT send_block_sizes, send_block_offsets;
cannam@167	44 INT recv_block_sizes, recv_block_offsets;
cannam@167	45 MPI_Comm comm;
cannam@167	46 int preserve_input;
cannam@167	47 } P;
cannam@167	48
cannam@167	49 static void transpose_chunks(int *sched, int n_pes, int my_pe,
cannam@167	50 INT sbs, INT sbo, INT rbs, INT rbo,
cannam@167	51 MPI_Comm comm,
cannam@167	52 R I, R O)
cannam@167	53 {
cannam@167	54 if (sched) {
cannam@167	55 int i;
cannam@167	56 MPI_Status status;
cannam@167	57
cannam@167	58 /* TODO: explore non-synchronous send/recv? */
cannam@167	59
cannam@167	60 if (I == O) {
cannam@167	61 R buf = (R) MALLOC(sizeof(R) * sbs[0], BUFFERS);
cannam@167	62
cannam@167	63 for (i = 0; i < n_pes; ++i) {
cannam@167	64 int pe = sched[i];
cannam@167	65 if (my_pe == pe) {
cannam@167	66 if (rbo[pe] != sbo[pe])
cannam@167	67 memmove(O + rbo[pe], O + sbo[pe],
cannam@167	68 sbs[pe] * sizeof(R));
cannam@167	69 }
cannam@167	70 else {
cannam@167	71 memcpy(buf, O + sbo[pe], sbs[pe] * sizeof(R));
cannam@167	72 MPI_Sendrecv(buf, (int) (sbs[pe]), FFTW_MPI_TYPE,
cannam@167	73 pe, (my_pe * n_pes + pe) & 0xffff,
cannam@167	74 O + rbo[pe], (int) (rbs[pe]),
cannam@167	75 FFTW_MPI_TYPE,
cannam@167	76 pe, (pe * n_pes + my_pe) & 0xffff,
cannam@167	77 comm, &status);
cannam@167	78 }
cannam@167	79 }
cannam@167	80
cannam@167	81 X(ifree)(buf);
cannam@167	82 }
cannam@167	83 else { /* I != O */
cannam@167	84 for (i = 0; i < n_pes; ++i) {
cannam@167	85 int pe = sched[i];
cannam@167	86 if (my_pe == pe)
cannam@167	87 memcpy(O + rbo[pe], I + sbo[pe], sbs[pe] * sizeof(R));
cannam@167	88 else
cannam@167	89 MPI_Sendrecv(I + sbo[pe], (int) (sbs[pe]),
cannam@167	90 FFTW_MPI_TYPE,
cannam@167	91 pe, (my_pe * n_pes + pe) & 0xffff,
cannam@167	92 O + rbo[pe], (int) (rbs[pe]),
cannam@167	93 FFTW_MPI_TYPE,
cannam@167	94 pe, (pe * n_pes + my_pe) & 0xffff,
cannam@167	95 comm, &status);
cannam@167	96 }
cannam@167	97 }
cannam@167	98 }
cannam@167	99 }
cannam@167	100
cannam@167	101 static void apply(const plan ego_, R I, R *O)
cannam@167	102 {
cannam@167	103 const P ego = (const P ) ego_;
cannam@167	104 plan_rdft cld1, cld2, cld2rest, cld3;
cannam@167	105
cannam@167	106 /* transpose locally to get contiguous chunks */
cannam@167	107 cld1 = (plan_rdft *) ego->cld1;
cannam@167	108 if (cld1) {
cannam@167	109 cld1->apply(ego->cld1, I, O);
cannam@167	110
cannam@167	111 if (ego->preserve_input) I = O;
cannam@167	112
cannam@167	113 /* transpose chunks globally */
cannam@167	114 transpose_chunks(ego->sched, ego->n_pes, ego->my_pe,
cannam@167	115 ego->send_block_sizes, ego->send_block_offsets,
cannam@167	116 ego->recv_block_sizes, ego->recv_block_offsets,
cannam@167	117 ego->comm, O, I);
cannam@167	118 }
cannam@167	119 else if (ego->preserve_input) {
cannam@167	120 /* transpose chunks globally */
cannam@167	121 transpose_chunks(ego->sched, ego->n_pes, ego->my_pe,
cannam@167	122 ego->send_block_sizes, ego->send_block_offsets,
cannam@167	123 ego->recv_block_sizes, ego->recv_block_offsets,
cannam@167	124 ego->comm, I, O);
cannam@167	125
cannam@167	126 I = O;
cannam@167	127 }
cannam@167	128 else {
cannam@167	129 /* transpose chunks globally */
cannam@167	130 transpose_chunks(ego->sched, ego->n_pes, ego->my_pe,
cannam@167	131 ego->send_block_sizes, ego->send_block_offsets,
cannam@167	132 ego->recv_block_sizes, ego->recv_block_offsets,
cannam@167	133 ego->comm, I, I);
cannam@167	134 }
cannam@167	135
cannam@167	136 /* transpose locally, again, to get ordinary row-major;
cannam@167	137 this may take two transposes if the block sizes are unequal
cannam@167	138 (3 subplans, two of which operate on disjoint data) */
cannam@167	139 cld2 = (plan_rdft *) ego->cld2;
cannam@167	140 cld2->apply(ego->cld2, I, O);
cannam@167	141 cld2rest = (plan_rdft *) ego->cld2rest;
cannam@167	142 if (cld2rest) {
cannam@167	143 cld2rest->apply(ego->cld2rest,
cannam@167	144 I + ego->rest_Ioff, O + ego->rest_Ooff);
cannam@167	145 cld3 = (plan_rdft *) ego->cld3;
cannam@167	146 if (cld3)
cannam@167	147 cld3->apply(ego->cld3, O, O);
cannam@167	148 /* else TRANSPOSED_OUT is true and user wants O transposed */
cannam@167	149 }
cannam@167	150 }
cannam@167	151
cannam@167	152 static int applicable(const S ego, const problem p_,
cannam@167	153 const planner *plnr)
cannam@167	154 {
cannam@167	155 const problem_mpi_transpose p = (const problem_mpi_transpose ) p_;
cannam@167	156 /* Note: this is not UGLY for out-of-place, destroy-input plans;
cannam@167	157 the planner often prefers transpose-pairwise to transpose-alltoall,
cannam@167	158 at least with LAM MPI on my machine. */
cannam@167	159 return (1
cannam@167	160 && (!ego->preserve_input \|\| (!NO_DESTROY_INPUTP(plnr)
cannam@167	161 && p->I != p->O))
cannam@167	162 && ONLY_TRANSPOSEDP(p->flags));
cannam@167	163 }
cannam@167	164
cannam@167	165 static void awake(plan *ego_, enum wakefulness wakefulness)
cannam@167	166 {
cannam@167	167 P ego = (P ) ego_;
cannam@167	168 X(plan_awake)(ego->cld1, wakefulness);
cannam@167	169 X(plan_awake)(ego->cld2, wakefulness);
cannam@167	170 X(plan_awake)(ego->cld2rest, wakefulness);
cannam@167	171 X(plan_awake)(ego->cld3, wakefulness);
cannam@167	172 }
cannam@167	173
cannam@167	174 static void destroy(plan *ego_)
cannam@167	175 {
cannam@167	176 P ego = (P ) ego_;
cannam@167	177 X(ifree0)(ego->sched);
cannam@167	178 X(ifree0)(ego->send_block_sizes);
cannam@167	179 MPI_Comm_free(&ego->comm);
cannam@167	180 X(plan_destroy_internal)(ego->cld3);
cannam@167	181 X(plan_destroy_internal)(ego->cld2rest);
cannam@167	182 X(plan_destroy_internal)(ego->cld2);
cannam@167	183 X(plan_destroy_internal)(ego->cld1);
cannam@167	184 }
cannam@167	185
cannam@167	186 static void print(const plan ego_, printer p)
cannam@167	187 {
cannam@167	188 const P ego = (const P ) ego_;
cannam@167	189 p->print(p, "(mpi-transpose-pairwise%s%(%p%)%(%p%)%(%p%)%(%p%))",
cannam@167	190 ego->preserve_input==2 ?"/p":"",
cannam@167	191 ego->cld1, ego->cld2, ego->cld2rest, ego->cld3);
cannam@167	192 }
cannam@167	193
cannam@167	194 /* Given a process which_pe and a number of processes npes, fills
cannam@167	195 the array sched[npes] with a sequence of processes to communicate
cannam@167	196 with for a deadlock-free, optimum-overlap all-to-all communication.
cannam@167	197 (All processes must call this routine to get their own schedules.)
cannam@167	198 The schedule can be re-ordered arbitrarily as long as all processes
cannam@167	199 apply the same permutation to their schedules.
cannam@167	200
cannam@167	201 The algorithm here is based upon the one described in:
cannam@167	202 J. A. M. Schreuder, "Constructing timetables for sport
cannam@167	203 competitions," Mathematical Programming Study 13, pp. 58-67 (1980).
cannam@167	204 In a sport competition, you have N teams and want every team to
cannam@167	205 play every other team in as short a time as possible (maximum overlap
cannam@167	206 between games). This timetabling problem is therefore identical
cannam@167	207 to that of an all-to-all communications problem. In our case, there
cannam@167	208 is one wrinkle: as part of the schedule, the process must do
cannam@167	209 some data transfer with itself (local data movement), analogous
cannam@167	210 to a requirement that each team "play itself" in addition to other
cannam@167	211 teams. With this wrinkle, it turns out that an optimal timetable
cannam@167	212 (N parallel games) can be constructed for any N, not just for even
cannam@167	213 N as in the original problem described by Schreuder.
cannam@167	214 */
cannam@167	215 static void fill1_comm_sched(int *sched, int which_pe, int npes)
cannam@167	216 {
cannam@167	217 int pe, i, n, s = 0;
cannam@167	218 A(which_pe >= 0 && which_pe < npes);
cannam@167	219 if (npes % 2 == 0) {
cannam@167	220 n = npes;
cannam@167	221 sched[s++] = which_pe;
cannam@167	222 }
cannam@167	223 else
cannam@167	224 n = npes + 1;
cannam@167	225 for (pe = 0; pe < n - 1; ++pe) {
cannam@167	226 if (npes % 2 == 0) {
cannam@167	227 if (pe == which_pe) sched[s++] = npes - 1;
cannam@167	228 else if (npes - 1 == which_pe) sched[s++] = pe;
cannam@167	229 }
cannam@167	230 else if (pe == which_pe) sched[s++] = pe;
cannam@167	231
cannam@167	232 if (pe != which_pe && which_pe < n - 1) {
cannam@167	233 i = (pe - which_pe + (n - 1)) % (n - 1);
cannam@167	234 if (i < n/2)
cannam@167	235 sched[s++] = (pe + i) % (n - 1);
cannam@167	236
cannam@167	237 i = (which_pe - pe + (n - 1)) % (n - 1);
cannam@167	238 if (i < n/2)
cannam@167	239 sched[s++] = (pe - i + (n - 1)) % (n - 1);
cannam@167	240 }
cannam@167	241 }
cannam@167	242 A(s == npes);
cannam@167	243 }
cannam@167	244
cannam@167	245 /* Sort the communication schedule sched for npes so that the schedule
cannam@167	246 on process sortpe is ascending or descending (!ascending). This is
cannam@167	247 necessary to allow in-place transposes when the problem does not
cannam@167	248 divide equally among the processes. In this case there is one
cannam@167	249 process where the incoming blocks are bigger/smaller than the
cannam@167	250 outgoing blocks and thus have to be received in
cannam@167	251 descending/ascending order, respectively, to avoid overwriting data
cannam@167	252 before it is sent. */
cannam@167	253 static void sort1_comm_sched(int *sched, int npes, int sortpe, int ascending)
cannam@167	254 {
cannam@167	255 int *sortsched, i;
cannam@167	256 sortsched = (int ) MALLOC(npes sizeof(int) * 2, OTHER);
cannam@167	257 fill1_comm_sched(sortsched, sortpe, npes);
cannam@167	258 if (ascending)
cannam@167	259 for (i = 0; i < npes; ++i)
cannam@167	260 sortsched[npes + sortsched[i]] = sched[i];
cannam@167	261 else
cannam@167	262 for (i = 0; i < npes; ++i)
cannam@167	263 sortsched[2*npes - 1 - sortsched[i]] = sched[i];
cannam@167	264 for (i = 0; i < npes; ++i)
cannam@167	265 sched[i] = sortsched[npes + i];
cannam@167	266 X(ifree)(sortsched);
cannam@167	267 }
cannam@167	268
cannam@167	269 /* make the plans to do the post-MPI transpositions (shared with
cannam@167	270 transpose-alltoall) */
cannam@167	271 int XM(mkplans_posttranspose)(const problem_mpi_transpose p, planner plnr,
cannam@167	272 R I, R O, int my_pe,
cannam@167	273 plan cld2, plan cld2rest, plan **cld3,
cannam@167	274 INT rest_Ioff, INT rest_Ooff)
cannam@167	275 {
cannam@167	276 INT vn = p->vn;
cannam@167	277 INT b = p->block;
cannam@167	278 INT bt = XM(block)(p->ny, p->tblock, my_pe);
cannam@167	279 INT nxb = p->nx / b; /* number of equal-sized blocks */
cannam@167	280 INT nxr = p->nx - nxb * b; /* leftover rows after equal blocks */
cannam@167	281
cannam@167	282 cld2 = cld2rest = *cld3 = NULL;
cannam@167	283 rest_Ioff = rest_Ooff = 0;
cannam@167	284
cannam@167	285 if (!(p->flags & TRANSPOSED_OUT) && (nxr == 0 \|\| I != O)) {
cannam@167	286 INT nx = p->nx * vn;
cannam@167	287 b *= vn;
cannam@167	288 *cld2 = X(mkplan_f_d)(plnr,
cannam@167	289 X(mkproblem_rdft_0_d)(X(mktensor_3d)
cannam@167	290 (nxb, bt * b, b,
cannam@167	291 bt, b, nx,
cannam@167	292 b, 1, 1),
cannam@167	293 I, O),
cannam@167	294 0, 0, NO_SLOW);
cannam@167	295 if (!*cld2) goto nada;
cannam@167	296
cannam@167	297 if (nxr > 0) {
cannam@167	298 rest_Ioff = nxb bt * b;
cannam@167	299 rest_Ooff = nxb b;
cannam@167	300 b = nxr * vn;
cannam@167	301 *cld2rest = X(mkplan_f_d)(plnr,
cannam@167	302 X(mkproblem_rdft_0_d)(X(mktensor_2d)
cannam@167	303 (bt, b, nx,
cannam@167	304 b, 1, 1),
cannam@167	305 I + *rest_Ioff,
cannam@167	306 O + *rest_Ooff),
cannam@167	307 0, 0, NO_SLOW);
cannam@167	308 if (!*cld2rest) goto nada;
cannam@167	309 }
cannam@167	310 }
cannam@167	311 else {
cannam@167	312 *cld2 = X(mkplan_f_d)(plnr,
cannam@167	313 X(mkproblem_rdft_0_d)(
cannam@167	314 X(mktensor_4d)
cannam@167	315 (nxb, bt * b * vn, bt * b * vn,
cannam@167	316 bt, b * vn, vn,
cannam@167	317 b, vn, bt * vn,
cannam@167	318 vn, 1, 1),
cannam@167	319 I, O),
cannam@167	320 0, 0, NO_SLOW);
cannam@167	321 if (!*cld2) goto nada;
cannam@167	322
cannam@167	323 rest_Ioff = rest_Ooff = nxb * bt * b * vn;
cannam@167	324 *cld2rest = X(mkplan_f_d)(plnr,
cannam@167	325 X(mkproblem_rdft_0_d)(
cannam@167	326 X(mktensor_3d)
cannam@167	327 (bt, nxr * vn, vn,
cannam@167	328 nxr, vn, bt * vn,
cannam@167	329 vn, 1, 1),
cannam@167	330 I + rest_Ioff, O + rest_Ooff),
cannam@167	331 0, 0, NO_SLOW);
cannam@167	332 if (!*cld2rest) goto nada;
cannam@167	333
cannam@167	334 if (!(p->flags & TRANSPOSED_OUT)) {
cannam@167	335 *cld3 = X(mkplan_f_d)(plnr,
cannam@167	336 X(mkproblem_rdft_0_d)(
cannam@167	337 X(mktensor_3d)
cannam@167	338 (p->nx, bt * vn, vn,
cannam@167	339 bt, vn, p->nx * vn,
cannam@167	340 vn, 1, 1),
cannam@167	341 O, O),
cannam@167	342 0, 0, NO_SLOW);
cannam@167	343 if (!*cld3) goto nada;
cannam@167	344 }
cannam@167	345 }
cannam@167	346
cannam@167	347 return 1;
cannam@167	348
cannam@167	349 nada:
cannam@167	350 X(plan_destroy_internal)(*cld3);
cannam@167	351 X(plan_destroy_internal)(*cld2rest);
cannam@167	352 X(plan_destroy_internal)(*cld2);
cannam@167	353 cld2 = cld2rest = *cld3 = NULL;
cannam@167	354 return 0;
cannam@167	355 }
cannam@167	356
cannam@167	357 static plan mkplan(const solver ego_, const problem p_, planner plnr)
cannam@167	358 {
cannam@167	359 const S ego = (const S ) ego_;
cannam@167	360 const problem_mpi_transpose *p;
cannam@167	361 P *pln;
cannam@167	362 plan cld1 = 0, cld2 = 0, cld2rest = 0, cld3 = 0;
cannam@167	363 INT b, bt, vn, rest_Ioff, rest_Ooff;
cannam@167	364 INT sbs, sbo, rbs, rbo;
cannam@167	365 int pe, my_pe, n_pes, sort_pe = -1, ascending = 1;
cannam@167	366 R I, O;
cannam@167	367 static const plan_adt padt = {
cannam@167	368 XM(transpose_solve), awake, print, destroy
cannam@167	369 };
cannam@167	370
cannam@167	371 UNUSED(ego);
cannam@167	372
cannam@167	373 if (!applicable(ego, p_, plnr))
cannam@167	374 return (plan *) 0;
cannam@167	375
cannam@167	376 p = (const problem_mpi_transpose *) p_;
cannam@167	377 vn = p->vn;
cannam@167	378 I = p->I; O = p->O;
cannam@167	379
cannam@167	380 MPI_Comm_rank(p->comm, &my_pe);
cannam@167	381 MPI_Comm_size(p->comm, &n_pes);
cannam@167	382
cannam@167	383 b = XM(block)(p->nx, p->block, my_pe);
cannam@167	384
cannam@167	385 if (!(p->flags & TRANSPOSED_IN)) { /* b x ny x vn -> ny x b x vn */
cannam@167	386 cld1 = X(mkplan_f_d)(plnr,
cannam@167	387 X(mkproblem_rdft_0_d)(X(mktensor_3d)
cannam@167	388 (b, p->ny * vn, vn,
cannam@167	389 p->ny, vn, b * vn,
cannam@167	390 vn, 1, 1),
cannam@167	391 I, O),
cannam@167	392 0, 0, NO_SLOW);
cannam@167	393 if (XM(any_true)(!cld1, p->comm)) goto nada;
cannam@167	394 }
cannam@167	395 if (ego->preserve_input \|\| NO_DESTROY_INPUTP(plnr)) I = O;
cannam@167	396
cannam@167	397 if (XM(any_true)(!XM(mkplans_posttranspose)(p, plnr, I, O, my_pe,
cannam@167	398 &cld2, &cld2rest, &cld3,
cannam@167	399 &rest_Ioff, &rest_Ooff),
cannam@167	400 p->comm)) goto nada;
cannam@167	401
cannam@167	402 pln = MKPLAN_MPI_TRANSPOSE(P, &padt, apply);
cannam@167	403
cannam@167	404 pln->cld1 = cld1;
cannam@167	405 pln->cld2 = cld2;
cannam@167	406 pln->cld2rest = cld2rest;
cannam@167	407 pln->rest_Ioff = rest_Ioff;
cannam@167	408 pln->rest_Ooff = rest_Ooff;
cannam@167	409 pln->cld3 = cld3;
cannam@167	410 pln->preserve_input = ego->preserve_input ? 2 : NO_DESTROY_INPUTP(plnr);
cannam@167	411
cannam@167	412 MPI_Comm_dup(p->comm, &pln->comm);
cannam@167	413
cannam@167	414 n_pes = (int) X(imax)(XM(num_blocks)(p->nx, p->block),
cannam@167	415 XM(num_blocks)(p->ny, p->tblock));
cannam@167	416
cannam@167	417 /* Compute sizes/offsets of blocks to exchange between processors */
cannam@167	418 sbs = (INT ) MALLOC(4 n_pes * sizeof(INT), PLANS);
cannam@167	419 sbo = sbs + n_pes;
cannam@167	420 rbs = sbo + n_pes;
cannam@167	421 rbo = rbs + n_pes;
cannam@167	422 b = XM(block)(p->nx, p->block, my_pe);
cannam@167	423 bt = XM(block)(p->ny, p->tblock, my_pe);
cannam@167	424 for (pe = 0; pe < n_pes; ++pe) {
cannam@167	425 INT db, dbt; /* destination block sizes */
cannam@167	426 db = XM(block)(p->nx, p->block, pe);
cannam@167	427 dbt = XM(block)(p->ny, p->tblock, pe);
cannam@167	428
cannam@167	429 sbs[pe] = b * dbt * vn;
cannam@167	430 sbo[pe] = pe * (b * p->tblock) * vn;
cannam@167	431 rbs[pe] = db * bt * vn;
cannam@167	432 rbo[pe] = pe * (p->block * bt) * vn;
cannam@167	433
cannam@167	434 if (db * dbt > 0 && db * p->tblock != p->block * dbt) {
cannam@167	435 A(sort_pe == -1); /* only one process should need sorting */
cannam@167	436 sort_pe = pe;
cannam@167	437 ascending = db * p->tblock > p->block * dbt;
cannam@167	438 }
cannam@167	439 }
cannam@167	440 pln->n_pes = n_pes;
cannam@167	441 pln->my_pe = my_pe;
cannam@167	442 pln->send_block_sizes = sbs;
cannam@167	443 pln->send_block_offsets = sbo;
cannam@167	444 pln->recv_block_sizes = rbs;
cannam@167	445 pln->recv_block_offsets = rbo;
cannam@167	446
cannam@167	447 if (my_pe >= n_pes) {
cannam@167	448 pln->sched = 0; /* this process is not doing anything */
cannam@167	449 }
cannam@167	450 else {
cannam@167	451 pln->sched = (int ) MALLOC(n_pes sizeof(int), PLANS);
cannam@167	452 fill1_comm_sched(pln->sched, my_pe, n_pes);
cannam@167	453 if (sort_pe >= 0)
cannam@167	454 sort1_comm_sched(pln->sched, n_pes, sort_pe, ascending);
cannam@167	455 }
cannam@167	456
cannam@167	457 X(ops_zero)(&pln->super.super.ops);
cannam@167	458 if (cld1) X(ops_add2)(&cld1->ops, &pln->super.super.ops);
cannam@167	459 if (cld2) X(ops_add2)(&cld2->ops, &pln->super.super.ops);
cannam@167	460 if (cld2rest) X(ops_add2)(&cld2rest->ops, &pln->super.super.ops);
cannam@167	461 if (cld3) X(ops_add2)(&cld3->ops, &pln->super.super.ops);
cannam@167	462 /* FIXME: should MPI operations be counted in "other" somehow? */
cannam@167	463
cannam@167	464 return &(pln->super.super);
cannam@167	465
cannam@167	466 nada:
cannam@167	467 X(plan_destroy_internal)(cld3);
cannam@167	468 X(plan_destroy_internal)(cld2rest);
cannam@167	469 X(plan_destroy_internal)(cld2);
cannam@167	470 X(plan_destroy_internal)(cld1);
cannam@167	471 return (plan *) 0;
cannam@167	472 }
cannam@167	473
cannam@167	474 static solver *mksolver(int preserve_input)
cannam@167	475 {
cannam@167	476 static const solver_adt sadt = { PROBLEM_MPI_TRANSPOSE, mkplan, 0 };
cannam@167	477 S *slv = MKSOLVER(S, &sadt);
cannam@167	478 slv->preserve_input = preserve_input;
cannam@167	479 return &(slv->super);
cannam@167	480 }
cannam@167	481
cannam@167	482 void XM(transpose_pairwise_register)(planner *p)
cannam@167	483 {
cannam@167	484 int preserve_input;
cannam@167	485 for (preserve_input = 0; preserve_input <= 1; ++preserve_input)
cannam@167	486 REGISTER_SOLVER(p, mksolver(preserve_input));
cannam@167	487 }

Mercurial > hg > sv-dependency-builds

annotate src/fftw-3.3.8/mpi/transpose-pairwise.c @ 169:223a55898ab9 tip default