/* * Copyright (c) 1997-1999, 2003 Massachusetts Institute of Technology * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * */ /* * fftw_test.c : test program for complex-complex transforms */ /* $Id: fftw_test.c,v 1.103 2003/03/16 23:43:46 stevenj Exp $ */ #include "fftw-int.h" #include #include #include #include #include #include "test_main.h" char fftw_prefix[] = "fftw"; void test_ergun(int n, fftw_direction dir, fftw_plan plan); /************************************************* * Speed tests *************************************************/ void zero_arr(int n, fftw_complex *a) { int i; for (i = 0; i < n; ++i) c_re(a[i]) = c_im(a[i]) = 0.0; } void test_speed_aux(int n, fftw_direction dir, int flags, int specific) { fftw_complex *in, *out; fftw_plan plan; double t; fftw_time begin, end; in = (fftw_complex *) fftw_malloc(n * howmany_fields * sizeof(fftw_complex)); out = (fftw_complex *) fftw_malloc(n * howmany_fields * sizeof(fftw_complex)); if (specific) { begin = fftw_get_time(); plan = fftw_create_plan_specific(n, dir, speed_flag | flags | wisdom_flag | no_vector_flag, in, howmany_fields, out, howmany_fields); end = fftw_get_time(); } else { begin = fftw_get_time(); plan = fftw_create_plan(n, dir, speed_flag | flags | wisdom_flag | no_vector_flag); end = fftw_get_time(); } CHECK(plan != NULL, "can't create plan"); t = fftw_time_to_sec(fftw_time_diff(end, begin)); WHEN_VERBOSE(2, printf("time for planner: %f s\n", t)); WHEN_VERBOSE(2, fftw_print_plan(plan)); if (paranoid && !(flags & FFTW_IN_PLACE)) { begin = fftw_get_time(); test_ergun(n, dir, plan); end = fftw_get_time(); t = fftw_time_to_sec(fftw_time_diff(end, begin)); WHEN_VERBOSE(2, printf("time for validation: %f s\n", t)); } FFTW_TIME_FFT(fftw(plan, howmany_fields, in, howmany_fields, 1, out, howmany_fields, 1), in, n * howmany_fields, t); fftw_destroy_plan(plan); WHEN_VERBOSE(1, printf("time for one fft: %s", smart_sprint_time(t))); WHEN_VERBOSE(1, printf(" (%s/point)\n", smart_sprint_time(t / n))); WHEN_VERBOSE(1, printf("\"mflops\" = 5 (n log2 n) / (t in microseconds)" " = %f\n", howmany_fields * mflops(t, n))); fftw_free(in); fftw_free(out); WHEN_VERBOSE(1, printf("\n")); } void test_speed_nd_aux(struct size sz, fftw_direction dir, int flags, int specific) { fftw_complex *in; fftwnd_plan plan; double t; fftw_time begin, end; int i, N; /* only bench in-place multi-dim transforms */ flags |= FFTW_IN_PLACE; N = 1; for (i = 0; i < sz.rank; ++i) N *= (sz.narray[i]); in = (fftw_complex *) fftw_malloc(N * howmany_fields * sizeof(fftw_complex)); if (specific) { begin = fftw_get_time(); plan = fftwnd_create_plan_specific(sz.rank, sz.narray, dir, speed_flag | flags | wisdom_flag | no_vector_flag, in, howmany_fields, 0, 1); } else { begin = fftw_get_time(); plan = fftwnd_create_plan(sz.rank, sz.narray, dir, speed_flag | flags | wisdom_flag | no_vector_flag); } end = fftw_get_time(); CHECK(plan != NULL, "can't create plan"); t = fftw_time_to_sec(fftw_time_diff(end, begin)); WHEN_VERBOSE(2, printf("time for planner: %f s\n", t)); WHEN_VERBOSE(2, printf("\n")); WHEN_VERBOSE(2, (fftwnd_print_plan(plan))); WHEN_VERBOSE(2, printf("\n")); FFTW_TIME_FFT(fftwnd(plan, howmany_fields, in, howmany_fields, 1, 0, 0, 0), in, N * howmany_fields, t); fftwnd_destroy_plan(plan); WHEN_VERBOSE(1, printf("time for one fft: %s", smart_sprint_time(t))); WHEN_VERBOSE(1, printf(" (%s/point)\n", smart_sprint_time(t / N))); WHEN_VERBOSE(1, printf("\"mflops\" = 5 (N log2 N) / (t in microseconds)" " = %f\n", howmany_fields * mflops(t, N))); fftw_free(in); WHEN_VERBOSE(1, printf("\n")); } /************************************************* * correctness tests *************************************************/ void fill_random(fftw_complex *a, int n) { int i; /* generate random inputs */ for (i = 0; i < n; ++i) { c_re(a[i]) = DRAND(); c_im(a[i]) = DRAND(); } } void array_copy(fftw_complex *out, fftw_complex *in, int n) { int i; for (i = 0; i < n; ++i) out[i] = in[i]; } /* C = A + B */ void array_add(fftw_complex *C, fftw_complex *A, fftw_complex *B, int n) { int i; for (i = 0; i < n; ++i) { c_re(C[i]) = c_re(A[i]) + c_re(B[i]); c_im(C[i]) = c_im(A[i]) + c_im(B[i]); } } /* C = A - B */ void array_sub(fftw_complex *C, fftw_complex *A, fftw_complex *B, int n) { int i; for (i = 0; i < n; ++i) { c_re(C[i]) = c_re(A[i]) - c_re(B[i]); c_im(C[i]) = c_im(A[i]) - c_im(B[i]); } } /* B = rotate left A */ void array_rol(fftw_complex *B, fftw_complex *A, int n, int n_before, int n_after) { int i, ib, ia; for (ib = 0; ib < n_before; ++ib) { for (i = 0; i < n - 1; ++i) for (ia = 0; ia < n_after; ++ia) B[(ib * n + i) * n_after + ia] = A[(ib * n + i + 1) * n_after + ia]; for (ia = 0; ia < n_after; ++ia) B[(ib * n + n - 1) * n_after + ia] = A[ib * n * n_after + ia]; } } /* A = alpha * A (in place) */ void array_scale(fftw_complex *A, fftw_complex alpha, int n) { int i; for (i = 0; i < n; ++i) { fftw_complex a = A[i]; c_re(A[i]) = c_re(a) * c_re(alpha) - c_im(a) * c_im(alpha); c_im(A[i]) = c_re(a) * c_im(alpha) + c_im(a) * c_re(alpha); } } void array_compare(fftw_complex *A, fftw_complex *B, int n) { double d = compute_error_complex(A, 1, B, 1, n); if (d > TOLERANCE) { fflush(stdout); fprintf(stderr, "Found relative error %e\n", d); fftw_die("failure in Ergun's verification procedure\n"); } } /* * guaranteed out-of-place transform. Does the necessary * copying if the plan is in-place. */ static void fftw_out_of_place(fftw_plan plan, int n, fftw_complex *in, fftw_complex *out) { if (plan->flags & FFTW_IN_PLACE) { array_copy(out, in, n); fftw(plan, 1, out, 1, n, (fftw_complex *)0, 1, n); } else { fftw(plan, 1, in, 1, n, out, 1, n); } } /* * Implementation of the FFT tester described in * * Funda Ergün. Testing multivariate linear functions: Overcoming the * generator bottleneck. In Proceedings of the Twenty-Seventh Annual * ACM Symposium on the Theory of Computing, pages 407-416, Las Vegas, * Nevada, 29 May--1 June 1995. */ void test_ergun(int n, fftw_direction dir, fftw_plan plan) { fftw_complex *inA, *inB, *inC, *outA, *outB, *outC; fftw_complex *tmp; fftw_complex impulse; int i; int rounds = 20; FFTW_TRIG_REAL twopin = FFTW_K2PI / (FFTW_TRIG_REAL) n; inA = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); inB = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); inC = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); outA = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); outB = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); outC = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); tmp = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex)); WHEN_VERBOSE(2, printf("Validating plan, n = %d, dir = %s\n", n, dir == FFTW_FORWARD ? "FORWARD" : "BACKWARD")); /* test 1: check linearity */ for (i = 0; i < rounds; ++i) { fftw_complex alpha, beta; c_re(alpha) = DRAND(); c_im(alpha) = DRAND(); c_re(beta) = DRAND(); c_im(beta) = DRAND(); fill_random(inA, n); fill_random(inB, n); fftw_out_of_place(plan, n, inA, outA); fftw_out_of_place(plan, n, inB, outB); array_scale(outA, alpha, n); array_scale(outB, beta, n); array_add(tmp, outA, outB, n); array_scale(inA, alpha, n); array_scale(inB, beta, n); array_add(inC, inA, inB, n); fftw_out_of_place(plan, n, inC, outC); array_compare(outC, tmp, n); } /* test 2: check that the unit impulse is transformed properly */ c_re(impulse) = 1.0; c_im(impulse) = 0.0; for (i = 0; i < n; ++i) { /* impulse */ c_re(inA[i]) = 0.0; c_im(inA[i]) = 0.0; /* transform of the impulse */ outA[i] = impulse; } inA[0] = impulse; for (i = 0; i < rounds; ++i) { fill_random(inB, n); array_sub(inC, inA, inB, n); fftw_out_of_place(plan, n, inB, outB); fftw_out_of_place(plan, n, inC, outC); array_add(tmp, outB, outC, n); array_compare(tmp, outA, n); } /* test 3: check the time-shift property */ /* the paper performs more tests, but this code should be fine too */ for (i = 0; i < rounds; ++i) { int j; fill_random(inA, n); array_rol(inB, inA, n, 1, 1); fftw_out_of_place(plan, n, inA, outA); fftw_out_of_place(plan, n, inB, outB); for (j = 0; j < n; ++j) { FFTW_TRIG_REAL s = dir * FFTW_TRIG_SIN(j * twopin); FFTW_TRIG_REAL c = FFTW_TRIG_COS(j * twopin); c_re(tmp[j]) = c_re(outB[j]) * c - c_im(outB[j]) * s; c_im(tmp[j]) = c_re(outB[j]) * s + c_im(outB[j]) * c; } array_compare(tmp, outA, n); } WHEN_VERBOSE(2, printf("Validation done\n")); fftw_free(tmp); fftw_free(outC); fftw_free(outB); fftw_free(outA); fftw_free(inC); fftw_free(inB); fftw_free(inA); } static void fftw_plan_hook_function(fftw_plan p) { WHEN_VERBOSE(3, printf("Validating tentative plan\n")); WHEN_VERBOSE(3, fftw_print_plan(p)); test_ergun(p->n, p->dir, p); } /* Same as test_ergun, but for multi-dimensional transforms: */ void testnd_ergun(int rank, int *n, fftw_direction dir, fftwnd_plan plan) { fftw_complex *inA, *inB, *inC, *outA, *outB, *outC; fftw_complex *tmp; fftw_complex impulse; int N, n_before, n_after, dim; int i, which_impulse; int rounds = 20; FFTW_TRIG_REAL twopin; N = 1; for (dim = 0; dim < rank; ++dim) N *= n[dim]; inA = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); inB = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); inC = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); outA = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); outB = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); outC = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); tmp = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); WHEN_VERBOSE(2, printf("Validating plan, N = %d, dir = %s\n", N, dir == FFTW_FORWARD ? "FORWARD" : "BACKWARD")); /* test 1: check linearity */ for (i = 0; i < rounds; ++i) { fftw_complex alpha, beta; c_re(alpha) = DRAND(); c_im(alpha) = DRAND(); c_re(beta) = DRAND(); c_im(beta) = DRAND(); fill_random(inA, N); fill_random(inB, N); fftwnd(plan, 1, inA, 1, N, outA, 1, N); fftwnd(plan, 1, inB, 1, N, outB, 1, N); array_scale(outA, alpha, N); array_scale(outB, beta, N); array_add(tmp, outA, outB, N); array_scale(inA, alpha, N); array_scale(inB, beta, N); array_add(inC, inA, inB, N); fftwnd(plan, 1, inC, 1, N, outC, 1, N); array_compare(outC, tmp, N); } /* * test 2: check that the unit impulse is transformed properly -- we * need to test both the real and imaginary impulses */ for (which_impulse = 0; which_impulse < 2; ++which_impulse) { if (which_impulse == 0) { /* real impulse */ c_re(impulse) = 1.0; c_im(impulse) = 0.0; } else { /* imaginary impulse */ c_re(impulse) = 0.0; c_im(impulse) = 1.0; } for (i = 0; i < N; ++i) { /* impulse */ c_re(inA[i]) = 0.0; c_im(inA[i]) = 0.0; /* transform of the impulse */ outA[i] = impulse; } inA[0] = impulse; for (i = 0; i < rounds; ++i) { fill_random(inB, N); array_sub(inC, inA, inB, N); fftwnd(plan, 1, inB, 1, N, outB, 1, N); fftwnd(plan, 1, inC, 1, N, outC, 1, N); array_add(tmp, outB, outC, N); array_compare(tmp, outA, N); } } /* test 3: check the time-shift property */ /* the paper performs more tests, but this code should be fine too */ /* -- we have to check shifts in each dimension */ n_before = 1; n_after = N; for (dim = 0; dim < rank; ++dim) { int n_cur = n[dim]; n_after /= n_cur; twopin = FFTW_K2PI / (FFTW_TRIG_REAL) n_cur; for (i = 0; i < rounds; ++i) { int j, jb, ja; fill_random(inA, N); array_rol(inB, inA, n_cur, n_before, n_after); fftwnd(plan, 1, inA, 1, N, outA, 1, N); fftwnd(plan, 1, inB, 1, N, outB, 1, N); for (jb = 0; jb < n_before; ++jb) for (j = 0; j < n_cur; ++j) { FFTW_TRIG_REAL s = dir * FFTW_TRIG_SIN(j * twopin); FFTW_TRIG_REAL c = FFTW_TRIG_COS(j * twopin); for (ja = 0; ja < n_after; ++ja) { c_re(tmp[(jb * n_cur + j) * n_after + ja]) = c_re(outB[(jb * n_cur + j) * n_after + ja]) * c - c_im(outB[(jb * n_cur + j) * n_after + ja]) * s; c_im(tmp[(jb * n_cur + j) * n_after + ja]) = c_re(outB[(jb * n_cur + j) * n_after + ja]) * s + c_im(outB[(jb * n_cur + j) * n_after + ja]) * c; } } array_compare(tmp, outA, N); } n_before *= n_cur; } WHEN_VERBOSE(2, printf("Validation done\n")); fftw_free(tmp); fftw_free(outC); fftw_free(outB); fftw_free(outA); fftw_free(inC); fftw_free(inB); fftw_free(inA); } void test_out_of_place(int n, int istride, int ostride, int howmany, fftw_direction dir, fftw_plan validated_plan, int specific) { fftw_complex *in1, *in2, *out1, *out2; fftw_plan plan; int i, j; int flags = measure_flag | wisdom_flag | FFTW_OUT_OF_PLACE; if (coinflip()) flags |= FFTW_THREADSAFE; in1 = (fftw_complex *) fftw_malloc(istride * n * sizeof(fftw_complex) * howmany); in2 = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex) * howmany); out1 = (fftw_complex *) fftw_malloc(ostride * n * sizeof(fftw_complex) * howmany); out2 = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex) * howmany); if (!specific) plan = fftw_create_plan(n, dir, flags); else plan = fftw_create_plan_specific(n, dir, flags, in1, istride, out1, ostride); /* generate random inputs */ for (i = 0; i < n * howmany; ++i) { c_re(in1[i * istride]) = c_re(in2[i]) = DRAND(); c_im(in1[i * istride]) = c_im(in2[i]) = DRAND(); } /* * fill in other positions of the array, to make sure that * fftw doesn't overwrite them */ for (j = 1; j < istride; ++j) for (i = 0; i < n * howmany; ++i) { c_re(in1[i * istride + j]) = i * istride + j; c_im(in1[i * istride + j]) = i * istride - j; } for (j = 1; j < ostride; ++j) for (i = 0; i < n * howmany; ++i) { c_re(out1[i * ostride + j]) = -i * ostride + j; c_im(out1[i * ostride + j]) = -i * ostride - j; } CHECK(plan != NULL, "can't create plan"); WHEN_VERBOSE(2, fftw_print_plan(plan)); /* fft-ize */ if (howmany != 1 || istride != 1 || ostride != 1 || coinflip()) fftw(plan, howmany, in1, istride, n * istride, out1, ostride, n * ostride); else fftw_one(plan, in1, out1); fftw_destroy_plan(plan); /* check for overwriting */ for (j = 1; j < istride; ++j) for (i = 0; i < n * howmany; ++i) CHECK(c_re(in1[i * istride + j]) == i * istride + j && c_im(in1[i * istride + j]) == i * istride - j, "input has been overwritten"); for (j = 1; j < ostride; ++j) for (i = 0; i < n * howmany; ++i) CHECK(c_re(out1[i * ostride + j]) == -i * ostride + j && c_im(out1[i * ostride + j]) == -i * ostride - j, "output has been overwritten"); for (i = 0; i < howmany; ++i) { fftw(validated_plan, 1, in2 + n * i, 1, n, out2 + n * i, 1, n); } CHECK(compute_error_complex(out1, ostride, out2, 1, n * howmany) < TOLERANCE, "test_out_of_place: wrong answer"); WHEN_VERBOSE(2, printf("OK\n")); fftw_free(in1); fftw_free(in2); fftw_free(out1); fftw_free(out2); } void test_in_place(int n, int istride, int howmany, fftw_direction dir, fftw_plan validated_plan, int specific) { fftw_complex *in1, *in2, *out2; fftw_plan plan; int i, j; int flags = measure_flag | wisdom_flag | FFTW_IN_PLACE; if (coinflip()) flags |= FFTW_THREADSAFE; in1 = (fftw_complex *) fftw_malloc(istride * n * sizeof(fftw_complex) * howmany); in2 = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex) * howmany); out2 = (fftw_complex *) fftw_malloc(n * sizeof(fftw_complex) * howmany); if (!specific) plan = fftw_create_plan(n, dir, flags); else plan = fftw_create_plan_specific(n, dir, flags, in1, istride, (fftw_complex *) NULL, 0); /* generate random inputs */ for (i = 0; i < n * howmany; ++i) { c_re(in1[i * istride]) = c_re(in2[i]) = DRAND(); c_im(in1[i * istride]) = c_im(in2[i]) = DRAND(); } /* * fill in other positions of the array, to make sure that * fftw doesn't overwrite them */ for (j = 1; j < istride; ++j) for (i = 0; i < n * howmany; ++i) { c_re(in1[i * istride + j]) = i * istride + j; c_im(in1[i * istride + j]) = i * istride - j; } CHECK(plan != NULL, "can't create plan"); WHEN_VERBOSE(2, fftw_print_plan(plan)); /* fft-ize */ if (howmany != 1 || istride != 1 || coinflip()) fftw(plan, howmany, in1, istride, n * istride, (fftw_complex *) NULL, 0, 0); else fftw_one(plan, in1, NULL); fftw_destroy_plan(plan); /* check for overwriting */ for (j = 1; j < istride; ++j) for (i = 0; i < n * howmany; ++i) CHECK(c_re(in1[i * istride + j]) == i * istride + j && c_im(in1[i * istride + j]) == i * istride - j, "input has been overwritten"); for (i = 0; i < howmany; ++i) { fftw(validated_plan, 1, in2 + n * i, 1, n, out2 + n * i, 1, n); } CHECK(compute_error_complex(in1, istride, out2, 1, n * howmany) < TOLERANCE, "test_in_place: wrong answer"); WHEN_VERBOSE(2, printf("OK\n")); fftw_free(in1); fftw_free(in2); fftw_free(out2); } void test_out_of_place_both(int n, int istride, int ostride, int howmany, fftw_plan validated_plan_forward, fftw_plan validated_plan_backward) { int specific; for (specific = 0; specific <= 1; ++specific) { WHEN_VERBOSE(2, printf("TEST CORRECTNESS (out of place, FFTW_FORWARD, %s)" " n = %d istride = %d ostride = %d howmany = %d\n", SPECIFICP(specific), n, istride, ostride, howmany)); test_out_of_place(n, istride, ostride, howmany, FFTW_FORWARD, validated_plan_forward, specific); WHEN_VERBOSE(2, printf("TEST CORRECTNESS (out of place, FFTW_BACKWARD, %s)" " n = %d istride = %d ostride = %d howmany = %d\n", SPECIFICP(specific), n, istride, ostride, howmany)); test_out_of_place(n, istride, ostride, howmany, FFTW_BACKWARD, validated_plan_backward, specific); } } void test_in_place_both(int n, int istride, int howmany, fftw_plan validated_plan_forward, fftw_plan validated_plan_backward) { int specific; for (specific = 0; specific <= 1; ++specific) { WHEN_VERBOSE(2, printf("TEST CORRECTNESS (in place, FFTW_FORWARD, %s) " "n = %d istride = %d howmany = %d\n", SPECIFICP(specific), n, istride, howmany)); test_in_place(n, istride, howmany, FFTW_FORWARD, validated_plan_forward, specific); WHEN_VERBOSE(2, printf("TEST CORRECTNESS (in place, FFTW_BACKWARD, %s) " "n = %d istride = %d howmany = %d\n", SPECIFICP(specific), n, istride, howmany)); test_in_place(n, istride, howmany, FFTW_BACKWARD, validated_plan_backward, specific); } } void test_correctness(int n) { int istride, ostride, howmany; fftw_plan validated_plan_forward, validated_plan_backward; WHEN_VERBOSE(1, printf("Testing correctness for n = %d...", n); fflush(stdout)); /* produce a *good* plan (validated by Ergun's test procedure) */ validated_plan_forward = fftw_create_plan(n, FFTW_FORWARD, measure_flag | wisdom_flag); test_ergun(n, FFTW_FORWARD, validated_plan_forward); validated_plan_backward = fftw_create_plan(n, FFTW_BACKWARD, measure_flag | wisdom_flag); test_ergun(n, FFTW_BACKWARD, validated_plan_backward); for (istride = 1; istride <= MAX_STRIDE; ++istride) for (ostride = 1; ostride <= MAX_STRIDE; ++ostride) for (howmany = 1; howmany <= MAX_HOWMANY; ++howmany) test_out_of_place_both(n, istride, ostride, howmany, validated_plan_forward, validated_plan_backward); for (istride = 1; istride <= MAX_STRIDE; ++istride) for (howmany = 1; howmany <= MAX_HOWMANY; ++howmany) test_in_place_both(n, istride, howmany, validated_plan_forward, validated_plan_backward); fftw_destroy_plan(validated_plan_forward); fftw_destroy_plan(validated_plan_backward); if (!(wisdom_flag & FFTW_USE_WISDOM) && chk_mem_leak) fftw_check_memory_leaks(); WHEN_VERBOSE(1, printf("OK\n")); } /************************************************* * multi-dimensional correctness tests *************************************************/ void testnd_out_of_place(int rank, int *n, fftw_direction dir, fftwnd_plan validated_plan) { int istride, ostride; int N, dim, i; fftw_complex *in1, *in2, *out1, *out2; fftwnd_plan p; int flags = measure_flag | wisdom_flag; if (coinflip()) flags |= FFTW_THREADSAFE; N = 1; for (dim = 0; dim < rank; ++dim) N *= n[dim]; in1 = (fftw_complex *) fftw_malloc(N * MAX_STRIDE * sizeof(fftw_complex)); out1 = (fftw_complex *) fftw_malloc(N * MAX_STRIDE * sizeof(fftw_complex)); in2 = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); out2 = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); p = fftwnd_create_plan(rank, n, dir, flags); for (istride = 1; istride <= MAX_STRIDE; ++istride) { /* generate random inputs */ for (i = 0; i < N; ++i) { int j; c_re(in2[i]) = DRAND(); c_im(in2[i]) = DRAND(); for (j = 0; j < istride; ++j) { c_re(in1[i * istride + j]) = c_re(in2[i]); c_im(in1[i * istride + j]) = c_im(in2[i]); } } for (ostride = 1; ostride <= MAX_STRIDE; ++ostride) { int howmany = (istride < ostride) ? istride : ostride; if (howmany != 1 || istride != 1 || ostride != 1 || coinflip()) fftwnd(p, howmany, in1, istride, 1, out1, ostride, 1); else fftwnd_one(p, in1, out1); fftwnd(validated_plan, 1, in2, 1, 1, out2, 1, 1); for (i = 0; i < howmany; ++i) CHECK(compute_error_complex(out1 + i, ostride, out2, 1, N) < TOLERANCE, "testnd_out_of_place: wrong answer"); } } fftwnd_destroy_plan(p); fftw_free(out2); fftw_free(in2); fftw_free(out1); fftw_free(in1); } void testnd_in_place(int rank, int *n, fftw_direction dir, fftwnd_plan validated_plan, int alternate_api, int specific, int force_buffered) { int istride; int N, dim, i; fftw_complex *in1, *in2, *out2; fftwnd_plan p; int flags = measure_flag | wisdom_flag | FFTW_IN_PLACE; if (coinflip()) flags |= FFTW_THREADSAFE; if (force_buffered) flags |= FFTWND_FORCE_BUFFERED; N = 1; for (dim = 0; dim < rank; ++dim) N *= n[dim]; in1 = (fftw_complex *) fftw_malloc(N * MAX_STRIDE * sizeof(fftw_complex)); in2 = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); out2 = (fftw_complex *) fftw_malloc(N * sizeof(fftw_complex)); if (!specific) { if (alternate_api && (rank == 2 || rank == 3)) { if (rank == 2) p = fftw2d_create_plan(n[0], n[1], dir, flags); else p = fftw3d_create_plan(n[0], n[1], n[2], dir, flags); } else /* standard api */ p = fftwnd_create_plan(rank, n, dir, flags); } else { /* specific plan creation */ if (alternate_api && (rank == 2 || rank == 3)) { if (rank == 2) p = fftw2d_create_plan_specific(n[0], n[1], dir, flags, in1, 1, (fftw_complex *) NULL, 1); else p = fftw3d_create_plan_specific(n[0], n[1], n[2], dir, flags, in1, 1, (fftw_complex *) NULL, 1); } else /* standard api */ p = fftwnd_create_plan_specific(rank, n, dir, flags, in1, 1, (fftw_complex *) NULL, 1); } for (istride = 1; istride <= MAX_STRIDE; ++istride) { /* * generate random inputs */ for (i = 0; i < N; ++i) { int j; c_re(in2[i]) = DRAND(); c_im(in2[i]) = DRAND(); for (j = 0; j < istride; ++j) { c_re(in1[i * istride + j]) = c_re(in2[i]); c_im(in1[i * istride + j]) = c_im(in2[i]); } } if (istride != 1 || istride != 1 || coinflip()) fftwnd(p, istride, in1, istride, 1, (fftw_complex *) NULL, 1, 1); else fftwnd_one(p, in1, NULL); fftwnd(validated_plan, 1, in2, 1, 1, out2, 1, 1); for (i = 0; i < istride; ++i) CHECK(compute_error_complex(in1 + i, istride, out2, 1, N) < TOLERANCE, "testnd_in_place: wrong answer"); } fftwnd_destroy_plan(p); fftw_free(out2); fftw_free(in2); fftw_free(in1); } void testnd_correctness(struct size sz, fftw_direction dir, int alt_api, int specific, int force_buf) { fftwnd_plan validated_plan; validated_plan = fftwnd_create_plan(sz.rank, sz.narray, dir, measure_flag | wisdom_flag); testnd_ergun(sz.rank, sz.narray, dir, validated_plan); testnd_out_of_place(sz.rank, sz.narray, dir, validated_plan); testnd_in_place(sz.rank, sz.narray, dir, validated_plan, alt_api, specific, force_buf); fftwnd_destroy_plan(validated_plan); } /************************************************* * planner tests *************************************************/ void test_planner(int rank) { /* * create and destroy many plans, at random. Check the * garbage-collecting allocator of twiddle factors */ int i, dim; int r, s; fftw_plan p[PLANNER_TEST_SIZE]; fftwnd_plan pnd[PLANNER_TEST_SIZE]; int *narr, maxdim; chk_mem_leak = 0; verbose--; please_wait(); if (rank < 1) rank = 1; narr = (int *) fftw_malloc(rank * sizeof(int)); maxdim = (int) pow(8192.0, 1.0/rank); for (i = 0; i < PLANNER_TEST_SIZE; ++i) { p[i] = (fftw_plan) 0; pnd[i] = (fftwnd_plan) 0; } for (i = 0; i < PLANNER_TEST_SIZE * PLANNER_TEST_SIZE; ++i) { r = rand(); if (r < 0) r = -r; r = r % PLANNER_TEST_SIZE; for (dim = 0; dim < rank; ++dim) { do { s = rand(); if (s < 0) s = -s; s = s % maxdim + 1; } while (s == 0); narr[dim] = s; } if (rank == 1) { if (p[r]) fftw_destroy_plan(p[r]); p[r] = fftw_create_plan(narr[0], random_dir(), measure_flag | wisdom_flag); if (paranoid && narr[0] < 200) test_correctness(narr[0]); } if (pnd[r]) fftwnd_destroy_plan(pnd[r]); pnd[r] = fftwnd_create_plan(rank, narr, random_dir(), measure_flag | wisdom_flag); if (i % (PLANNER_TEST_SIZE * PLANNER_TEST_SIZE / 20) == 0) { WHEN_VERBOSE(0, printf("test planner: so far so good\n")); WHEN_VERBOSE(0, printf("test planner: iteration %d out of %d\n", i, PLANNER_TEST_SIZE * PLANNER_TEST_SIZE)); } } for (i = 0; i < PLANNER_TEST_SIZE; ++i) { if (p[i]) fftw_destroy_plan(p[i]); if (pnd[i]) fftwnd_destroy_plan(pnd[i]); } fftw_free(narr); verbose++; chk_mem_leak = 1; } /************************************************* * test initialization *************************************************/ void test_init(int *argc, char ***argv) { } void test_finish(void) { } void enter_paranoid_mode(void) { fftw_plan_hook = fftw_plan_hook_function; } int get_option(int argc, char **argv, char *argval, int argval_maxlen) { return default_get_option(argc,argv,argval,argval_maxlen); }