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annotate src/fftw-3.3.3/mpi/mpi-bench.c @ 23:619f715526df sv_v2.1

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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 /* NOTE to users: this is the FFTW-MPI self-test and benchmark program.
Chris@10 3 It is probably NOT a good place to learn FFTW usage, since it has a
Chris@10 4 lot of added complexity in order to exercise and test the full API,
Chris@10 5 etcetera. We suggest reading the manual. */
Chris@10 6 /**************************************************************************/
Chris@10 7
Chris@10 8 #include <math.h>
Chris@10 9 #include <stdio.h>
Chris@10 10 #include <string.h>
Chris@10 11 #include "fftw3-mpi.h"
Chris@10 12 #include "fftw-bench.h"
Chris@10 13
Chris@10 14 #if defined(BENCHFFT_SINGLE)
Chris@10 15 # define BENCH_MPI_TYPE MPI_FLOAT
Chris@10 16 #elif defined(BENCHFFT_LDOUBLE)
Chris@10 17 # define BENCH_MPI_TYPE MPI_LONG_DOUBLE
Chris@10 18 #elif defined(BENCHFFT_QUAD)
Chris@10 19 # error MPI quad-precision type is unknown
Chris@10 20 #else
Chris@10 21 # define BENCH_MPI_TYPE MPI_DOUBLE
Chris@10 22 #endif
Chris@10 23
Chris@10 24 #if SIZEOF_PTRDIFF_T == SIZEOF_INT
Chris@10 25 # define FFTW_MPI_PTRDIFF_T MPI_INT
Chris@10 26 #elif SIZEOF_PTRDIFF_T == SIZEOF_LONG
Chris@10 27 # define FFTW_MPI_PTRDIFF_T MPI_LONG
Chris@10 28 #elif SIZEOF_PTRDIFF_T == SIZEOF_LONG_LONG
Chris@10 29 # define FFTW_MPI_PTRDIFF_T MPI_LONG_LONG
Chris@10 30 #else
Chris@10 31 # error MPI type for ptrdiff_t is unknown
Chris@10 32 # define FFTW_MPI_PTRDIFF_T MPI_LONG
Chris@10 33 #endif
Chris@10 34
Chris@10 35 static const char *mkversion(void) { return FFTW(version); }
Chris@10 36 static const char *mkcc(void) { return FFTW(cc); }
Chris@10 37 static const char *mkcodelet_optim(void) { return FFTW(codelet_optim); }
Chris@10 38 static const char *mknproc(void) {
Chris@10 39 static char buf[32];
Chris@10 40 int ncpus;
Chris@10 41 MPI_Comm_size(MPI_COMM_WORLD, &ncpus);
Chris@10 42 #ifdef HAVE_SNPRINTF
Chris@10 43 snprintf(buf, 32, "%d", ncpus);
Chris@10 44 #else
Chris@10 45 sprintf(buf, "%d", ncpus);
Chris@10 46 #endif
Chris@10 47 return buf;
Chris@10 48 }
Chris@10 49
Chris@10 50 BEGIN_BENCH_DOC
Chris@10 51 BENCH_DOC("name", "fftw3_mpi")
Chris@10 52 BENCH_DOCF("version", mkversion)
Chris@10 53 BENCH_DOCF("cc", mkcc)
Chris@10 54 BENCH_DOCF("codelet-optim", mkcodelet_optim)
Chris@10 55 BENCH_DOCF("nproc", mknproc)
Chris@10 56 END_BENCH_DOC
Chris@10 57
Chris@10 58 static int n_pes = 1, my_pe = 0;
Chris@10 59
Chris@10 60 /* global variables describing the shape of the data and its distribution */
Chris@10 61 static int rnk;
Chris@10 62 static ptrdiff_t vn, iNtot, oNtot;
Chris@10 63 static ptrdiff_t *local_ni=0, *local_starti=0;
Chris@10 64 static ptrdiff_t *local_no=0, *local_starto=0;
Chris@10 65 static ptrdiff_t *all_local_ni=0, *all_local_starti=0; /* n_pes x rnk arrays */
Chris@10 66 static ptrdiff_t *all_local_no=0, *all_local_starto=0; /* n_pes x rnk arrays */
Chris@10 67 static ptrdiff_t *istrides = 0, *ostrides = 0;
Chris@10 68 static ptrdiff_t *total_ni=0, *total_no=0;
Chris@10 69 static int *isend_cnt = 0, *isend_off = 0; /* for MPI_Scatterv */
Chris@10 70 static int *orecv_cnt = 0, *orecv_off = 0; /* for MPI_Gatherv */
Chris@10 71
Chris@10 72 static bench_real *local_in = 0, *local_out = 0;
Chris@10 73 static bench_real *all_local_in = 0, *all_local_out = 0;
Chris@10 74 static int all_local_in_alloc = 0, all_local_out_alloc = 0;
Chris@10 75 static FFTW(plan) plan_scramble_in = 0, plan_unscramble_out = 0;
Chris@10 76
Chris@10 77 static void alloc_rnk(int rnk_) {
Chris@10 78 rnk = rnk_;
Chris@10 79 bench_free(local_ni);
Chris@10 80 if (rnk == 0)
Chris@10 81 local_ni = 0;
Chris@10 82 else
Chris@10 83 local_ni = (ptrdiff_t *) bench_malloc(sizeof(ptrdiff_t) * rnk
Chris@10 84 * (8 + n_pes * 4));
Chris@10 85
Chris@10 86 local_starti = local_ni + rnk;
Chris@10 87 local_no = local_ni + 2 * rnk;
Chris@10 88 local_starto = local_ni + 3 * rnk;
Chris@10 89 istrides = local_ni + 4 * rnk;
Chris@10 90 ostrides = local_ni + 5 * rnk;
Chris@10 91 total_ni = local_ni + 6 * rnk;
Chris@10 92 total_no = local_ni + 7 * rnk;
Chris@10 93 all_local_ni = local_ni + 8 * rnk;
Chris@10 94 all_local_starti = local_ni + (8 + n_pes) * rnk;
Chris@10 95 all_local_no = local_ni + (8 + 2 * n_pes) * rnk;
Chris@10 96 all_local_starto = local_ni + (8 + 3 * n_pes) * rnk;
Chris@10 97 }
Chris@10 98
Chris@10 99 static void setup_gather_scatter(void)
Chris@10 100 {
Chris@10 101 int i, j;
Chris@10 102 ptrdiff_t off;
Chris@10 103
Chris@10 104 MPI_Gather(local_ni, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 105 all_local_ni, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 106 0, MPI_COMM_WORLD);
Chris@10 107 MPI_Bcast(all_local_ni, rnk*n_pes, FFTW_MPI_PTRDIFF_T, 0, MPI_COMM_WORLD);
Chris@10 108 MPI_Gather(local_starti, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 109 all_local_starti, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 110 0, MPI_COMM_WORLD);
Chris@10 111 MPI_Bcast(all_local_starti, rnk*n_pes, FFTW_MPI_PTRDIFF_T, 0, MPI_COMM_WORLD);
Chris@10 112
Chris@10 113 MPI_Gather(local_no, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 114 all_local_no, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 115 0, MPI_COMM_WORLD);
Chris@10 116 MPI_Bcast(all_local_no, rnk*n_pes, FFTW_MPI_PTRDIFF_T, 0, MPI_COMM_WORLD);
Chris@10 117 MPI_Gather(local_starto, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 118 all_local_starto, rnk, FFTW_MPI_PTRDIFF_T,
Chris@10 119 0, MPI_COMM_WORLD);
Chris@10 120 MPI_Bcast(all_local_starto, rnk*n_pes, FFTW_MPI_PTRDIFF_T, 0, MPI_COMM_WORLD);
Chris@10 121
Chris@10 122 off = 0;
Chris@10 123 for (i = 0; i < n_pes; ++i) {
Chris@10 124 ptrdiff_t N = vn;
Chris@10 125 for (j = 0; j < rnk; ++j)
Chris@10 126 N *= all_local_ni[i * rnk + j];
Chris@10 127 isend_cnt[i] = N;
Chris@10 128 isend_off[i] = off;
Chris@10 129 off += N;
Chris@10 130 }
Chris@10 131 iNtot = off;
Chris@10 132 all_local_in_alloc = 1;
Chris@10 133
Chris@10 134 istrides[rnk - 1] = vn;
Chris@10 135 for (j = rnk - 2; j >= 0; --j)
Chris@10 136 istrides[j] = total_ni[j + 1] * istrides[j + 1];
Chris@10 137
Chris@10 138 off = 0;
Chris@10 139 for (i = 0; i < n_pes; ++i) {
Chris@10 140 ptrdiff_t N = vn;
Chris@10 141 for (j = 0; j < rnk; ++j)
Chris@10 142 N *= all_local_no[i * rnk + j];
Chris@10 143 orecv_cnt[i] = N;
Chris@10 144 orecv_off[i] = off;
Chris@10 145 off += N;
Chris@10 146 }
Chris@10 147 oNtot = off;
Chris@10 148 all_local_out_alloc = 1;
Chris@10 149
Chris@10 150 ostrides[rnk - 1] = vn;
Chris@10 151 for (j = rnk - 2; j >= 0; --j)
Chris@10 152 ostrides[j] = total_no[j + 1] * ostrides[j + 1];
Chris@10 153 }
Chris@10 154
Chris@10 155 static void copy_block_out(const bench_real *in,
Chris@10 156 int rnk, ptrdiff_t *n, ptrdiff_t *start,
Chris@10 157 ptrdiff_t is, ptrdiff_t *os, ptrdiff_t vn,
Chris@10 158 bench_real *out)
Chris@10 159 {
Chris@10 160 ptrdiff_t i;
Chris@10 161 if (rnk == 0) {
Chris@10 162 for (i = 0; i < vn; ++i)
Chris@10 163 out[i] = in[i];
Chris@10 164 }
Chris@10 165 else if (rnk == 1) { /* this case is just an optimization */
Chris@10 166 ptrdiff_t j;
Chris@10 167 out += start[0] * os[0];
Chris@10 168 for (j = 0; j < n[0]; ++j) {
Chris@10 169 for (i = 0; i < vn; ++i)
Chris@10 170 out[i] = in[i];
Chris@10 171 in += is;
Chris@10 172 out += os[0];
Chris@10 173 }
Chris@10 174 }
Chris@10 175 else {
Chris@10 176 /* we should do n[0] for locality, but this way is simpler to code */
Chris@10 177 for (i = 0; i < n[rnk - 1]; ++i)
Chris@10 178 copy_block_out(in + i * is,
Chris@10 179 rnk - 1, n, start, is * n[rnk - 1], os, vn,
Chris@10 180 out + (start[rnk - 1] + i) * os[rnk - 1]);
Chris@10 181 }
Chris@10 182 }
Chris@10 183
Chris@10 184 static void copy_block_in(bench_real *in,
Chris@10 185 int rnk, ptrdiff_t *n, ptrdiff_t *start,
Chris@10 186 ptrdiff_t is, ptrdiff_t *os, ptrdiff_t vn,
Chris@10 187 const bench_real *out)
Chris@10 188 {
Chris@10 189 ptrdiff_t i;
Chris@10 190 if (rnk == 0) {
Chris@10 191 for (i = 0; i < vn; ++i)
Chris@10 192 in[i] = out[i];
Chris@10 193 }
Chris@10 194 else if (rnk == 1) { /* this case is just an optimization */
Chris@10 195 ptrdiff_t j;
Chris@10 196 out += start[0] * os[0];
Chris@10 197 for (j = 0; j < n[0]; ++j) {
Chris@10 198 for (i = 0; i < vn; ++i)
Chris@10 199 in[i] = out[i];
Chris@10 200 in += is;
Chris@10 201 out += os[0];
Chris@10 202 }
Chris@10 203 }
Chris@10 204 else {
Chris@10 205 /* we should do n[0] for locality, but this way is simpler to code */
Chris@10 206 for (i = 0; i < n[rnk - 1]; ++i)
Chris@10 207 copy_block_in(in + i * is,
Chris@10 208 rnk - 1, n, start, is * n[rnk - 1], os, vn,
Chris@10 209 out + (start[rnk - 1] + i) * os[rnk - 1]);
Chris@10 210 }
Chris@10 211 }
Chris@10 212
Chris@10 213 static void do_scatter_in(bench_real *in)
Chris@10 214 {
Chris@10 215 bench_real *ali;
Chris@10 216 int i;
Chris@10 217 if (all_local_in_alloc) {
Chris@10 218 bench_free(all_local_in);
Chris@10 219 all_local_in = (bench_real*) bench_malloc(iNtot*sizeof(bench_real));
Chris@10 220 all_local_in_alloc = 0;
Chris@10 221 }
Chris@10 222 ali = all_local_in;
Chris@10 223 for (i = 0; i < n_pes; ++i) {
Chris@10 224 copy_block_in(ali,
Chris@10 225 rnk, all_local_ni + i * rnk,
Chris@10 226 all_local_starti + i * rnk,
Chris@10 227 vn, istrides, vn,
Chris@10 228 in);
Chris@10 229 ali += isend_cnt[i];
Chris@10 230 }
Chris@10 231 MPI_Scatterv(all_local_in, isend_cnt, isend_off, BENCH_MPI_TYPE,
Chris@10 232 local_in, isend_cnt[my_pe], BENCH_MPI_TYPE,
Chris@10 233 0, MPI_COMM_WORLD);
Chris@10 234 }
Chris@10 235
Chris@10 236 static void do_gather_out(bench_real *out)
Chris@10 237 {
Chris@10 238 bench_real *alo;
Chris@10 239 int i;
Chris@10 240
Chris@10 241 if (all_local_out_alloc) {
Chris@10 242 bench_free(all_local_out);
Chris@10 243 all_local_out = (bench_real*) bench_malloc(oNtot*sizeof(bench_real));
Chris@10 244 all_local_out_alloc = 0;
Chris@10 245 }
Chris@10 246 MPI_Gatherv(local_out, orecv_cnt[my_pe], BENCH_MPI_TYPE,
Chris@10 247 all_local_out, orecv_cnt, orecv_off, BENCH_MPI_TYPE,
Chris@10 248 0, MPI_COMM_WORLD);
Chris@10 249 MPI_Bcast(all_local_out, oNtot, BENCH_MPI_TYPE, 0, MPI_COMM_WORLD);
Chris@10 250 alo = all_local_out;
Chris@10 251 for (i = 0; i < n_pes; ++i) {
Chris@10 252 copy_block_out(alo,
Chris@10 253 rnk, all_local_no + i * rnk,
Chris@10 254 all_local_starto + i * rnk,
Chris@10 255 vn, ostrides, vn,
Chris@10 256 out);
Chris@10 257 alo += orecv_cnt[i];
Chris@10 258 }
Chris@10 259 }
Chris@10 260
Chris@10 261 static void alloc_local(ptrdiff_t nreal, int inplace)
Chris@10 262 {
Chris@10 263 bench_free(local_in);
Chris@10 264 if (local_out != local_in) bench_free(local_out);
Chris@10 265 local_in = local_out = 0;
Chris@10 266 if (nreal > 0) {
Chris@10 267 ptrdiff_t i;
Chris@10 268 local_in = (bench_real*) bench_malloc(nreal * sizeof(bench_real));
Chris@10 269 if (inplace)
Chris@10 270 local_out = local_in;
Chris@10 271 else
Chris@10 272 local_out = (bench_real*) bench_malloc(nreal * sizeof(bench_real));
Chris@10 273 for (i = 0; i < nreal; ++i) local_in[i] = local_out[i] = 0.0;
Chris@10 274 }
Chris@10 275 }
Chris@10 276
Chris@10 277 void after_problem_rcopy_from(bench_problem *p, bench_real *ri)
Chris@10 278 {
Chris@10 279 UNUSED(p);
Chris@10 280 do_scatter_in(ri);
Chris@10 281 if (plan_scramble_in) FFTW(execute)(plan_scramble_in);
Chris@10 282 }
Chris@10 283
Chris@10 284 void after_problem_rcopy_to(bench_problem *p, bench_real *ro)
Chris@10 285 {
Chris@10 286 UNUSED(p);
Chris@10 287 if (plan_unscramble_out) FFTW(execute)(plan_unscramble_out);
Chris@10 288 do_gather_out(ro);
Chris@10 289 }
Chris@10 290
Chris@10 291 void after_problem_ccopy_from(bench_problem *p, bench_real *ri, bench_real *ii)
Chris@10 292 {
Chris@10 293 UNUSED(ii);
Chris@10 294 after_problem_rcopy_from(p, ri);
Chris@10 295 }
Chris@10 296
Chris@10 297 void after_problem_ccopy_to(bench_problem *p, bench_real *ro, bench_real *io)
Chris@10 298 {
Chris@10 299 UNUSED(io);
Chris@10 300 after_problem_rcopy_to(p, ro);
Chris@10 301 }
Chris@10 302
Chris@10 303 void after_problem_hccopy_from(bench_problem *p, bench_real *ri, bench_real *ii)
Chris@10 304 {
Chris@10 305 UNUSED(ii);
Chris@10 306 after_problem_rcopy_from(p, ri);
Chris@10 307 }
Chris@10 308
Chris@10 309 void after_problem_hccopy_to(bench_problem *p, bench_real *ro, bench_real *io)
Chris@10 310 {
Chris@10 311 UNUSED(io);
Chris@10 312 after_problem_rcopy_to(p, ro);
Chris@10 313 }
Chris@10 314
Chris@10 315 static FFTW(plan) mkplan_transpose_local(ptrdiff_t nx, ptrdiff_t ny,
Chris@10 316 ptrdiff_t vn,
Chris@10 317 bench_real *in, bench_real *out)
Chris@10 318 {
Chris@10 319 FFTW(iodim64) hdims[3];
Chris@10 320 FFTW(r2r_kind) k[3];
Chris@10 321 FFTW(plan) pln;
Chris@10 322
Chris@10 323 hdims[0].n = nx;
Chris@10 324 hdims[0].is = ny * vn;
Chris@10 325 hdims[0].os = vn;
Chris@10 326 hdims[1].n = ny;
Chris@10 327 hdims[1].is = vn;
Chris@10 328 hdims[1].os = nx * vn;
Chris@10 329 hdims[2].n = vn;
Chris@10 330 hdims[2].is = 1;
Chris@10 331 hdims[2].os = 1;
Chris@10 332 k[0] = k[1] = k[2] = FFTW_R2HC;
Chris@10 333 pln = FFTW(plan_guru64_r2r)(0, 0, 3, hdims, in, out, k, FFTW_ESTIMATE);
Chris@10 334 BENCH_ASSERT(pln != 0);
Chris@10 335 return pln;
Chris@10 336 }
Chris@10 337
Chris@10 338 static int tensor_rowmajor_transposedp(bench_tensor *t)
Chris@10 339 {
Chris@10 340 bench_iodim *d;
Chris@10 341 int i;
Chris@10 342
Chris@10 343 BENCH_ASSERT(FINITE_RNK(t->rnk));
Chris@10 344 if (t->rnk < 2)
Chris@10 345 return 0;
Chris@10 346
Chris@10 347 d = t->dims;
Chris@10 348 if (d[0].is != d[1].is * d[1].n
Chris@10 349 || d[0].os != d[1].is
Chris@10 350 || d[1].os != d[0].os * d[0].n)
Chris@10 351 return 0;
Chris@10 352 if (t->rnk > 2 && d[1].is != d[2].is * d[2].n)
Chris@10 353 return 0;
Chris@10 354 for (i = 2; i + 1 < t->rnk; ++i) {
Chris@10 355 d = t->dims + i;
Chris@10 356 if (d[0].is != d[1].is * d[1].n
Chris@10 357 || d[0].os != d[1].os * d[1].n)
Chris@10 358 return 0;
Chris@10 359 }
Chris@10 360
Chris@10 361 if (t->rnk > 2 && t->dims[t->rnk-1].is != t->dims[t->rnk-1].os)
Chris@10 362 return 0;
Chris@10 363 return 1;
Chris@10 364 }
Chris@10 365
Chris@10 366 static int tensor_contiguousp(bench_tensor *t, int s)
Chris@10 367 {
Chris@10 368 return (t->dims[t->rnk-1].is == s
Chris@10 369 && ((tensor_rowmajorp(t) &&
Chris@10 370 t->dims[t->rnk-1].is == t->dims[t->rnk-1].os)
Chris@10 371 || tensor_rowmajor_transposedp(t)));
Chris@10 372 }
Chris@10 373
Chris@10 374 static FFTW(plan) mkplan_complex(bench_problem *p, unsigned flags)
Chris@10 375 {
Chris@10 376 FFTW(plan) pln = 0;
Chris@10 377 int i;
Chris@10 378 ptrdiff_t ntot;
Chris@10 379
Chris@10 380 vn = p->vecsz->rnk == 1 ? p->vecsz->dims[0].n : 1;
Chris@10 381
Chris@10 382 if (p->sz->rnk < 1
Chris@10 383 || p->split
Chris@10 384 || !tensor_contiguousp(p->sz, vn)
Chris@10 385 || tensor_rowmajor_transposedp(p->sz)
Chris@10 386 || p->vecsz->rnk > 1
Chris@10 387 || (p->vecsz->rnk == 1 && (p->vecsz->dims[0].is != 1
Chris@10 388 || p->vecsz->dims[0].os != 1)))
Chris@10 389 return 0;
Chris@10 390
Chris@10 391 alloc_rnk(p->sz->rnk);
Chris@10 392 for (i = 0; i < rnk; ++i) {
Chris@10 393 total_ni[i] = total_no[i] = p->sz->dims[i].n;
Chris@10 394 local_ni[i] = local_no[i] = total_ni[i];
Chris@10 395 local_starti[i] = local_starto[i] = 0;
Chris@10 396 }
Chris@10 397 if (rnk > 1) {
Chris@10 398 ptrdiff_t n, start, nT, startT;
Chris@10 399 ntot = FFTW(mpi_local_size_many_transposed)
Chris@10 400 (p->sz->rnk, total_ni, vn,
Chris@10 401 FFTW_MPI_DEFAULT_BLOCK, FFTW_MPI_DEFAULT_BLOCK,
Chris@10 402 MPI_COMM_WORLD,
Chris@10 403 &n, &start, &nT, &startT);
Chris@10 404 if (flags & FFTW_MPI_TRANSPOSED_IN) {
Chris@10 405 local_ni[1] = nT;
Chris@10 406 local_starti[1] = startT;
Chris@10 407 }
Chris@10 408 else {
Chris@10 409 local_ni[0] = n;
Chris@10 410 local_starti[0] = start;
Chris@10 411 }
Chris@10 412 if (flags & FFTW_MPI_TRANSPOSED_OUT) {
Chris@10 413 local_no[1] = nT;
Chris@10 414 local_starto[1] = startT;
Chris@10 415 }
Chris@10 416 else {
Chris@10 417 local_no[0] = n;
Chris@10 418 local_starto[0] = start;
Chris@10 419 }
Chris@10 420 }
Chris@10 421 else if (rnk == 1) {
Chris@10 422 ntot = FFTW(mpi_local_size_many_1d)
Chris@10 423 (total_ni[0], vn, MPI_COMM_WORLD, p->sign, flags,
Chris@10 424 local_ni, local_starti, local_no, local_starto);
Chris@10 425 }
Chris@10 426 alloc_local(ntot * 2, p->in == p->out);
Chris@10 427
Chris@10 428 pln = FFTW(mpi_plan_many_dft)(p->sz->rnk, total_ni, vn,
Chris@10 429 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 430 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 431 (FFTW(complex) *) local_in,
Chris@10 432 (FFTW(complex) *) local_out,
Chris@10 433 MPI_COMM_WORLD, p->sign, flags);
Chris@10 434
Chris@10 435 vn *= 2;
Chris@10 436
Chris@10 437 if (rnk > 1) {
Chris@10 438 ptrdiff_t nrest = 1;
Chris@10 439 for (i = 2; i < rnk; ++i) nrest *= p->sz->dims[i].n;
Chris@10 440 if (flags & FFTW_MPI_TRANSPOSED_IN)
Chris@10 441 plan_scramble_in = mkplan_transpose_local(
Chris@10 442 p->sz->dims[0].n, local_ni[1], vn * nrest,
Chris@10 443 local_in, local_in);
Chris@10 444 if (flags & FFTW_MPI_TRANSPOSED_OUT)
Chris@10 445 plan_unscramble_out = mkplan_transpose_local(
Chris@10 446 local_no[1], p->sz->dims[0].n, vn * nrest,
Chris@10 447 local_out, local_out);
Chris@10 448 }
Chris@10 449
Chris@10 450 return pln;
Chris@10 451 }
Chris@10 452
Chris@10 453 static int tensor_real_contiguousp(bench_tensor *t, int sign, int s)
Chris@10 454 {
Chris@10 455 return (t->dims[t->rnk-1].is == s
Chris@10 456 && ((tensor_real_rowmajorp(t, sign, 1) &&
Chris@10 457 t->dims[t->rnk-1].is == t->dims[t->rnk-1].os)));
Chris@10 458 }
Chris@10 459
Chris@10 460 static FFTW(plan) mkplan_real(bench_problem *p, unsigned flags)
Chris@10 461 {
Chris@10 462 FFTW(plan) pln = 0;
Chris@10 463 int i;
Chris@10 464 ptrdiff_t ntot;
Chris@10 465
Chris@10 466 vn = p->vecsz->rnk == 1 ? p->vecsz->dims[0].n : 1;
Chris@10 467
Chris@10 468 if (p->sz->rnk < 2
Chris@10 469 || p->split
Chris@10 470 || !tensor_real_contiguousp(p->sz, p->sign, vn)
Chris@10 471 || tensor_rowmajor_transposedp(p->sz)
Chris@10 472 || p->vecsz->rnk > 1
Chris@10 473 || (p->vecsz->rnk == 1 && (p->vecsz->dims[0].is != 1
Chris@10 474 || p->vecsz->dims[0].os != 1)))
Chris@10 475 return 0;
Chris@10 476
Chris@10 477 alloc_rnk(p->sz->rnk);
Chris@10 478 for (i = 0; i < rnk; ++i) {
Chris@10 479 total_ni[i] = total_no[i] = p->sz->dims[i].n;
Chris@10 480 local_ni[i] = local_no[i] = total_ni[i];
Chris@10 481 local_starti[i] = local_starto[i] = 0;
Chris@10 482 }
Chris@10 483 local_ni[rnk-1] = local_no[rnk-1] = total_ni[rnk-1] = total_no[rnk-1]
Chris@10 484 = p->sz->dims[rnk-1].n / 2 + 1;
Chris@10 485 {
Chris@10 486 ptrdiff_t n, start, nT, startT;
Chris@10 487 ntot = FFTW(mpi_local_size_many_transposed)
Chris@10 488 (p->sz->rnk, total_ni, vn,
Chris@10 489 FFTW_MPI_DEFAULT_BLOCK, FFTW_MPI_DEFAULT_BLOCK,
Chris@10 490 MPI_COMM_WORLD,
Chris@10 491 &n, &start, &nT, &startT);
Chris@10 492 if (flags & FFTW_MPI_TRANSPOSED_IN) {
Chris@10 493 local_ni[1] = nT;
Chris@10 494 local_starti[1] = startT;
Chris@10 495 }
Chris@10 496 else {
Chris@10 497 local_ni[0] = n;
Chris@10 498 local_starti[0] = start;
Chris@10 499 }
Chris@10 500 if (flags & FFTW_MPI_TRANSPOSED_OUT) {
Chris@10 501 local_no[1] = nT;
Chris@10 502 local_starto[1] = startT;
Chris@10 503 }
Chris@10 504 else {
Chris@10 505 local_no[0] = n;
Chris@10 506 local_starto[0] = start;
Chris@10 507 }
Chris@10 508 }
Chris@10 509 alloc_local(ntot * 2, p->in == p->out);
Chris@10 510
Chris@10 511 total_ni[rnk - 1] = p->sz->dims[rnk - 1].n;
Chris@10 512 if (p->sign < 0)
Chris@10 513 pln = FFTW(mpi_plan_many_dft_r2c)(p->sz->rnk, total_ni, vn,
Chris@10 514 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 515 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 516 local_in,
Chris@10 517 (FFTW(complex) *) local_out,
Chris@10 518 MPI_COMM_WORLD, flags);
Chris@10 519 else
Chris@10 520 pln = FFTW(mpi_plan_many_dft_c2r)(p->sz->rnk, total_ni, vn,
Chris@10 521 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 522 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 523 (FFTW(complex) *) local_in,
Chris@10 524 local_out,
Chris@10 525 MPI_COMM_WORLD, flags);
Chris@10 526
Chris@10 527 total_ni[rnk - 1] = p->sz->dims[rnk - 1].n / 2 + 1;
Chris@10 528 vn *= 2;
Chris@10 529
Chris@10 530 {
Chris@10 531 ptrdiff_t nrest = 1;
Chris@10 532 for (i = 2; i < rnk; ++i) nrest *= total_ni[i];
Chris@10 533 if (flags & FFTW_MPI_TRANSPOSED_IN)
Chris@10 534 plan_scramble_in = mkplan_transpose_local(
Chris@10 535 total_ni[0], local_ni[1], vn * nrest,
Chris@10 536 local_in, local_in);
Chris@10 537 if (flags & FFTW_MPI_TRANSPOSED_OUT)
Chris@10 538 plan_unscramble_out = mkplan_transpose_local(
Chris@10 539 local_no[1], total_ni[0], vn * nrest,
Chris@10 540 local_out, local_out);
Chris@10 541 }
Chris@10 542
Chris@10 543 return pln;
Chris@10 544 }
Chris@10 545
Chris@10 546 static FFTW(plan) mkplan_transpose(bench_problem *p, unsigned flags)
Chris@10 547 {
Chris@10 548 ptrdiff_t ntot, nx, ny;
Chris@10 549 int ix=0, iy=1, i;
Chris@10 550 const bench_iodim *d = p->vecsz->dims;
Chris@10 551 FFTW(plan) pln;
Chris@10 552
Chris@10 553 if (p->vecsz->rnk == 3) {
Chris@10 554 for (i = 0; i < 3; ++i)
Chris@10 555 if (d[i].is == 1 && d[i].os == 1) {
Chris@10 556 vn = d[i].n;
Chris@10 557 ix = (i + 1) % 3;
Chris@10 558 iy = (i + 2) % 3;
Chris@10 559 break;
Chris@10 560 }
Chris@10 561 if (i == 3) return 0;
Chris@10 562 }
Chris@10 563 else {
Chris@10 564 vn = 1;
Chris@10 565 ix = 0;
Chris@10 566 iy = 1;
Chris@10 567 }
Chris@10 568
Chris@10 569 if (d[ix].is == d[iy].n * vn && d[ix].os == vn
Chris@10 570 && d[iy].os == d[ix].n * vn && d[iy].is == vn) {
Chris@10 571 nx = d[ix].n;
Chris@10 572 ny = d[iy].n;
Chris@10 573 }
Chris@10 574 else if (d[iy].is == d[ix].n * vn && d[iy].os == vn
Chris@10 575 && d[ix].os == d[iy].n * vn && d[ix].is == vn) {
Chris@10 576 nx = d[iy].n;
Chris@10 577 ny = d[ix].n;
Chris@10 578 }
Chris@10 579 else
Chris@10 580 return 0;
Chris@10 581
Chris@10 582 alloc_rnk(2);
Chris@10 583 ntot = vn * FFTW(mpi_local_size_2d_transposed)(nx, ny, MPI_COMM_WORLD,
Chris@10 584 &local_ni[0],
Chris@10 585 &local_starti[0],
Chris@10 586 &local_no[0],
Chris@10 587 &local_starto[0]);
Chris@10 588 local_ni[1] = ny;
Chris@10 589 local_starti[1] = 0;
Chris@10 590 local_no[1] = nx;
Chris@10 591 local_starto[1] = 0;
Chris@10 592 total_ni[0] = nx; total_ni[1] = ny;
Chris@10 593 total_no[1] = nx; total_no[0] = ny;
Chris@10 594 alloc_local(ntot, p->in == p->out);
Chris@10 595
Chris@10 596 pln = FFTW(mpi_plan_many_transpose)(nx, ny, vn,
Chris@10 597 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 598 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 599 local_in, local_out,
Chris@10 600 MPI_COMM_WORLD, flags);
Chris@10 601
Chris@10 602 if (flags & FFTW_MPI_TRANSPOSED_IN)
Chris@10 603 plan_scramble_in = mkplan_transpose_local(local_ni[0], ny, vn,
Chris@10 604 local_in, local_in);
Chris@10 605 if (flags & FFTW_MPI_TRANSPOSED_OUT)
Chris@10 606 plan_unscramble_out = mkplan_transpose_local
Chris@10 607 (nx, local_no[0], vn, local_out, local_out);
Chris@10 608
Chris@10 609 #if 0
Chris@10 610 if (pln && vn == 1) {
Chris@10 611 int i, j;
Chris@10 612 bench_real *ri = (bench_real *) p->in;
Chris@10 613 bench_real *ro = (bench_real *) p->out;
Chris@10 614 if (!ri || !ro) return pln;
Chris@10 615 setup_gather_scatter();
Chris@10 616 for (i = 0; i < nx * ny; ++i)
Chris@10 617 ri[i] = i;
Chris@10 618 after_problem_rcopy_from(p, ri);
Chris@10 619 FFTW(execute)(pln);
Chris@10 620 after_problem_rcopy_to(p, ro);
Chris@10 621 if (my_pe == 0) {
Chris@10 622 for (i = 0; i < nx; ++i) {
Chris@10 623 for (j = 0; j < ny; ++j)
Chris@10 624 printf(" %3g", ro[j * nx + i]);
Chris@10 625 printf("\n");
Chris@10 626 }
Chris@10 627 }
Chris@10 628 }
Chris@10 629 #endif
Chris@10 630
Chris@10 631 return pln;
Chris@10 632 }
Chris@10 633
Chris@10 634 static FFTW(plan) mkplan_r2r(bench_problem *p, unsigned flags)
Chris@10 635 {
Chris@10 636 FFTW(plan) pln = 0;
Chris@10 637 int i;
Chris@10 638 ptrdiff_t ntot;
Chris@10 639 FFTW(r2r_kind) *k;
Chris@10 640
Chris@10 641 if ((p->sz->rnk == 0 || (p->sz->rnk == 1 && p->sz->dims[0].n == 1))
Chris@10 642 && p->vecsz->rnk >= 2 && p->vecsz->rnk <= 3)
Chris@10 643 return mkplan_transpose(p, flags);
Chris@10 644
Chris@10 645 vn = p->vecsz->rnk == 1 ? p->vecsz->dims[0].n : 1;
Chris@10 646
Chris@10 647 if (p->sz->rnk < 1
Chris@10 648 || p->split
Chris@10 649 || !tensor_contiguousp(p->sz, vn)
Chris@10 650 || tensor_rowmajor_transposedp(p->sz)
Chris@10 651 || p->vecsz->rnk > 1
Chris@10 652 || (p->vecsz->rnk == 1 && (p->vecsz->dims[0].is != 1
Chris@10 653 || p->vecsz->dims[0].os != 1)))
Chris@10 654 return 0;
Chris@10 655
Chris@10 656 alloc_rnk(p->sz->rnk);
Chris@10 657 for (i = 0; i < rnk; ++i) {
Chris@10 658 total_ni[i] = total_no[i] = p->sz->dims[i].n;
Chris@10 659 local_ni[i] = local_no[i] = total_ni[i];
Chris@10 660 local_starti[i] = local_starto[i] = 0;
Chris@10 661 }
Chris@10 662 if (rnk > 1) {
Chris@10 663 ptrdiff_t n, start, nT, startT;
Chris@10 664 ntot = FFTW(mpi_local_size_many_transposed)
Chris@10 665 (p->sz->rnk, total_ni, vn,
Chris@10 666 FFTW_MPI_DEFAULT_BLOCK, FFTW_MPI_DEFAULT_BLOCK,
Chris@10 667 MPI_COMM_WORLD,
Chris@10 668 &n, &start, &nT, &startT);
Chris@10 669 if (flags & FFTW_MPI_TRANSPOSED_IN) {
Chris@10 670 local_ni[1] = nT;
Chris@10 671 local_starti[1] = startT;
Chris@10 672 }
Chris@10 673 else {
Chris@10 674 local_ni[0] = n;
Chris@10 675 local_starti[0] = start;
Chris@10 676 }
Chris@10 677 if (flags & FFTW_MPI_TRANSPOSED_OUT) {
Chris@10 678 local_no[1] = nT;
Chris@10 679 local_starto[1] = startT;
Chris@10 680 }
Chris@10 681 else {
Chris@10 682 local_no[0] = n;
Chris@10 683 local_starto[0] = start;
Chris@10 684 }
Chris@10 685 }
Chris@10 686 else if (rnk == 1) {
Chris@10 687 ntot = FFTW(mpi_local_size_many_1d)
Chris@10 688 (total_ni[0], vn, MPI_COMM_WORLD, p->sign, flags,
Chris@10 689 local_ni, local_starti, local_no, local_starto);
Chris@10 690 }
Chris@10 691 alloc_local(ntot, p->in == p->out);
Chris@10 692
Chris@10 693 k = (FFTW(r2r_kind) *) bench_malloc(sizeof(FFTW(r2r_kind)) * p->sz->rnk);
Chris@10 694 for (i = 0; i < p->sz->rnk; ++i)
Chris@10 695 switch (p->k[i]) {
Chris@10 696 case R2R_R2HC: k[i] = FFTW_R2HC; break;
Chris@10 697 case R2R_HC2R: k[i] = FFTW_HC2R; break;
Chris@10 698 case R2R_DHT: k[i] = FFTW_DHT; break;
Chris@10 699 case R2R_REDFT00: k[i] = FFTW_REDFT00; break;
Chris@10 700 case R2R_REDFT01: k[i] = FFTW_REDFT01; break;
Chris@10 701 case R2R_REDFT10: k[i] = FFTW_REDFT10; break;
Chris@10 702 case R2R_REDFT11: k[i] = FFTW_REDFT11; break;
Chris@10 703 case R2R_RODFT00: k[i] = FFTW_RODFT00; break;
Chris@10 704 case R2R_RODFT01: k[i] = FFTW_RODFT01; break;
Chris@10 705 case R2R_RODFT10: k[i] = FFTW_RODFT10; break;
Chris@10 706 case R2R_RODFT11: k[i] = FFTW_RODFT11; break;
Chris@10 707 default: BENCH_ASSERT(0);
Chris@10 708 }
Chris@10 709
Chris@10 710 pln = FFTW(mpi_plan_many_r2r)(p->sz->rnk, total_ni, vn,
Chris@10 711 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 712 FFTW_MPI_DEFAULT_BLOCK,
Chris@10 713 local_in, local_out,
Chris@10 714 MPI_COMM_WORLD, k, flags);
Chris@10 715 bench_free(k);
Chris@10 716
Chris@10 717 if (rnk > 1) {
Chris@10 718 ptrdiff_t nrest = 1;
Chris@10 719 for (i = 2; i < rnk; ++i) nrest *= p->sz->dims[i].n;
Chris@10 720 if (flags & FFTW_MPI_TRANSPOSED_IN)
Chris@10 721 plan_scramble_in = mkplan_transpose_local(
Chris@10 722 p->sz->dims[0].n, local_ni[1], vn * nrest,
Chris@10 723 local_in, local_in);
Chris@10 724 if (flags & FFTW_MPI_TRANSPOSED_OUT)
Chris@10 725 plan_unscramble_out = mkplan_transpose_local(
Chris@10 726 local_no[1], p->sz->dims[0].n, vn * nrest,
Chris@10 727 local_out, local_out);
Chris@10 728 }
Chris@10 729
Chris@10 730 return pln;
Chris@10 731 }
Chris@10 732
Chris@10 733 FFTW(plan) mkplan(bench_problem *p, unsigned flags)
Chris@10 734 {
Chris@10 735 FFTW(plan) pln = 0;
Chris@10 736 FFTW(destroy_plan)(plan_scramble_in); plan_scramble_in = 0;
Chris@10 737 FFTW(destroy_plan)(plan_unscramble_out); plan_unscramble_out = 0;
Chris@10 738 if (p->scrambled_in) {
Chris@10 739 if (p->sz->rnk == 1 && p->sz->dims[0].n != 1)
Chris@10 740 flags |= FFTW_MPI_SCRAMBLED_IN;
Chris@10 741 else
Chris@10 742 flags |= FFTW_MPI_TRANSPOSED_IN;
Chris@10 743 }
Chris@10 744 if (p->scrambled_out) {
Chris@10 745 if (p->sz->rnk == 1 && p->sz->dims[0].n != 1)
Chris@10 746 flags |= FFTW_MPI_SCRAMBLED_OUT;
Chris@10 747 else
Chris@10 748 flags |= FFTW_MPI_TRANSPOSED_OUT;
Chris@10 749 }
Chris@10 750 switch (p->kind) {
Chris@10 751 case PROBLEM_COMPLEX:
Chris@10 752 pln =mkplan_complex(p, flags);
Chris@10 753 break;
Chris@10 754 case PROBLEM_REAL:
Chris@10 755 pln = mkplan_real(p, flags);
Chris@10 756 break;
Chris@10 757 case PROBLEM_R2R:
Chris@10 758 pln = mkplan_r2r(p, flags);
Chris@10 759 break;
Chris@10 760 default: BENCH_ASSERT(0);
Chris@10 761 }
Chris@10 762 if (pln) setup_gather_scatter();
Chris@10 763 return pln;
Chris@10 764 }
Chris@10 765
Chris@10 766 void main_init(int *argc, char ***argv)
Chris@10 767 {
Chris@10 768 #ifdef HAVE_SMP
Chris@10 769 # if MPI_VERSION >= 2 /* for MPI_Init_thread */
Chris@10 770 int provided;
Chris@10 771 MPI_Init_thread(argc, argv, MPI_THREAD_FUNNELED, &provided);
Chris@10 772 threads_ok = provided >= MPI_THREAD_FUNNELED;
Chris@10 773 # else
Chris@10 774 MPI_Init(argc, argv);
Chris@10 775 threads_ok = 0;
Chris@10 776 # endif
Chris@10 777 #else
Chris@10 778 MPI_Init(argc, argv);
Chris@10 779 #endif
Chris@10 780 MPI_Comm_rank(MPI_COMM_WORLD, &my_pe);
Chris@10 781 MPI_Comm_size(MPI_COMM_WORLD, &n_pes);
Chris@10 782 if (my_pe != 0) verbose = -999;
Chris@10 783 no_speed_allocation = 1; /* so we can benchmark transforms > memory */
Chris@10 784 always_pad_real = 1; /* out-of-place real transforms are padded */
Chris@10 785 isend_cnt = (int *) bench_malloc(sizeof(int) * n_pes);
Chris@10 786 isend_off = (int *) bench_malloc(sizeof(int) * n_pes);
Chris@10 787 orecv_cnt = (int *) bench_malloc(sizeof(int) * n_pes);
Chris@10 788 orecv_off = (int *) bench_malloc(sizeof(int) * n_pes);
Chris@10 789
Chris@10 790 /* init_threads must be called before any other FFTW function,
Chris@10 791 including mpi_init, because it has to register the threads hooks
Chris@10 792 before the planner is initalized */
Chris@10 793 #ifdef HAVE_SMP
Chris@10 794 if (threads_ok) { BENCH_ASSERT(FFTW(init_threads)()); }
Chris@10 795 #endif
Chris@10 796 FFTW(mpi_init)();
Chris@10 797 }
Chris@10 798
Chris@10 799 void initial_cleanup(void)
Chris@10 800 {
Chris@10 801 alloc_rnk(0);
Chris@10 802 alloc_local(0, 0);
Chris@10 803 bench_free(all_local_in); all_local_in = 0;
Chris@10 804 bench_free(all_local_out); all_local_out = 0;
Chris@10 805 bench_free(isend_off); isend_off = 0;
Chris@10 806 bench_free(isend_cnt); isend_cnt = 0;
Chris@10 807 bench_free(orecv_off); orecv_off = 0;
Chris@10 808 bench_free(orecv_cnt); orecv_cnt = 0;
Chris@10 809 FFTW(destroy_plan)(plan_scramble_in); plan_scramble_in = 0;
Chris@10 810 FFTW(destroy_plan)(plan_unscramble_out); plan_unscramble_out = 0;
Chris@10 811 }
Chris@10 812
Chris@10 813 void final_cleanup(void)
Chris@10 814 {
Chris@10 815 MPI_Finalize();
Chris@10 816 }
Chris@10 817
Chris@10 818 void bench_exit(int status)
Chris@10 819 {
Chris@10 820 MPI_Abort(MPI_COMM_WORLD, status);
Chris@10 821 }
Chris@10 822
Chris@10 823 double bench_cost_postprocess(double cost)
Chris@10 824 {
Chris@10 825 double cost_max;
Chris@10 826 MPI_Allreduce(&cost, &cost_max, 1, MPI_DOUBLE, MPI_MAX, MPI_COMM_WORLD);
Chris@10 827 return cost_max;
Chris@10 828 }
Chris@10 829
Chris@10 830
Chris@10 831 int import_wisdom(FILE *f)
Chris@10 832 {
Chris@10 833 int success = 1, sall;
Chris@10 834 if (my_pe == 0) success = FFTW(import_wisdom_from_file)(f);
Chris@10 835 FFTW(mpi_broadcast_wisdom)(MPI_COMM_WORLD);
Chris@10 836 MPI_Allreduce(&success, &sall, 1, MPI_INT, MPI_LAND, MPI_COMM_WORLD);
Chris@10 837 return sall;
Chris@10 838 }
Chris@10 839
Chris@10 840 void export_wisdom(FILE *f)
Chris@10 841 {
Chris@10 842 FFTW(mpi_gather_wisdom)(MPI_COMM_WORLD);
Chris@10 843 if (my_pe == 0) FFTW(export_wisdom_to_file)(f);
Chris@10 844 }