/* Copyright (C) 2016 Arb authors This file is part of Arb. Arb is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. See . */ #include "arb_mat.h" static void _fmpq_mat_sum_of_squares(fmpq_t res, const fmpq_mat_t Q) { slong i, j; fmpq_zero(res); for (i = 0; i < fmpq_mat_nrows(Q); i++) { for (j = 0; j < fmpq_mat_ncols(Q); j++) { fmpq_addmul(res, fmpq_mat_entry(Q, i, j), fmpq_mat_entry(Q, i, j)); } } } int main() { slong iter; flint_rand_t state; flint_printf("frobenius_norm...."); fflush(stdout); flint_randinit(state); /* compare to the exact rational norm */ for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { fmpq_mat_t Q; fmpq_t q; arb_mat_t A; slong n, qbits, prec; n = n_randint(state, 8); qbits = 1 + n_randint(state, 100); prec = 2 + n_randint(state, 200); fmpq_mat_init(Q, n, n); fmpq_init(q); arb_mat_init(A, n, n); fmpq_mat_randtest(Q, state, qbits); _fmpq_mat_sum_of_squares(q, Q); arb_mat_set_fmpq_mat(A, Q, prec); /* check that the arb interval contains the exact value */ { arb_t a; arb_init(a); arb_mat_frobenius_norm(a, A, prec); arb_mul(a, a, a, prec); if (!arb_contains_fmpq(a, q)) { flint_printf("FAIL (containment, iter = %wd)\n", iter); flint_printf("n = %wd, prec = %wd\n", n, prec); flint_printf("\n"); flint_printf("Q = \n"); fmpq_mat_print(Q); flint_printf("\n\n"); flint_printf("frobenius_norm(Q)^2 = \n"); fmpq_print(q); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("frobenius_norm(A)^2 = \n"); arb_printd(a, 15); flint_printf("\n\n"); flint_printf("frobenius_norm(A)^2 = \n"); arb_print(a); flint_printf("\n\n"); flint_abort(); } arb_clear(a); } /* check that the upper bound is not less than the exact value */ { mag_t b; fmpq_t y; mag_init(b); fmpq_init(y); arb_mat_bound_frobenius_norm(b, A); mag_mul(b, b, b); mag_get_fmpq(y, b); if (fmpq_cmp(q, y) > 0) { flint_printf("FAIL (bound, iter = %wd)\n", iter); flint_printf("n = %wd, prec = %wd\n", n, prec); flint_printf("\n"); flint_printf("Q = \n"); fmpq_mat_print(Q); flint_printf("\n\n"); flint_printf("frobenius_norm(Q)^2 = \n"); fmpq_print(q); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("bound_frobenius_norm(A)^2 = \n"); mag_printd(b, 15); flint_printf("\n\n"); flint_printf("bound_frobenius_norm(A)^2 = \n"); mag_print(b); flint_printf("\n\n"); flint_abort(); } mag_clear(b); fmpq_clear(y); } fmpq_mat_clear(Q); fmpq_clear(q); arb_mat_clear(A); } /* check trace(A^T A) = frobenius_norm(A)^2 */ for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { slong m, n, prec; arb_mat_t A, AT, ATA; arb_t t; prec = 2 + n_randint(state, 200); m = n_randint(state, 10); n = n_randint(state, 10); arb_mat_init(A, m, n); arb_mat_init(AT, n, m); arb_mat_init(ATA, n, n); arb_init(t); arb_mat_randtest(A, state, 2 + n_randint(state, 100), 10); arb_mat_transpose(AT, A); arb_mat_mul(ATA, AT, A, prec); arb_mat_trace(t, ATA, prec); arb_sqrt(t, t, prec); /* check the norm bound */ { mag_t low, frobenius; mag_init(low); arb_get_mag_lower(low, t); mag_init(frobenius); arb_mat_bound_frobenius_norm(frobenius, A); if (mag_cmp(low, frobenius) > 0) { flint_printf("FAIL (bound)\n", iter); flint_printf("m = %wd, n = %wd, prec = %wd\n", m, n, prec); flint_printf("\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("lower(sqrt(trace(A^T A))) = \n"); mag_printd(low, 15); flint_printf("\n\n"); flint_printf("bound_frobenius_norm(A) = \n"); mag_printd(frobenius, 15); flint_printf("\n\n"); flint_abort(); } mag_clear(low); mag_clear(frobenius); } /* check the norm interval */ { arb_t frobenius; arb_init(frobenius); arb_mat_frobenius_norm(frobenius, A, prec); if (!arb_overlaps(t, frobenius)) { flint_printf("FAIL (overlap)\n", iter); flint_printf("m = %wd, n = %wd, prec = %wd\n", m, n, prec); flint_printf("\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("sqrt(trace(A^T A)) = \n"); arb_printd(t, 15); flint_printf("\n\n"); flint_printf("frobenius_norm(A) = \n"); arb_printd(frobenius, 15); flint_printf("\n\n"); flint_abort(); } arb_clear(frobenius); } arb_mat_clear(A); arb_mat_clear(AT); arb_mat_clear(ATA); arb_clear(t); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }