int main(void) { int i, result; FLINT_TEST_INIT(state); flint_printf("one...."); fflush(stdout); /* 1 * A == A * 1 == A */ for (i = 0; i < 100 * flint_test_multiplier(); i++) { fmpq_mat_t A, B, C, I; slong n, bits; n = n_randint(state, 10); bits = 1 + n_randint(state, 100); fmpq_mat_init(A, n, n); fmpq_mat_init(B, n, n); fmpq_mat_init(C, n, n); fmpq_mat_init(I, n, n); fmpq_mat_randtest(A, state, bits); fmpq_mat_one(I); fmpq_mat_mul(B, I, A); fmpq_mat_mul(C, A, I); result = fmpq_mat_equal(A, B) && fmpq_mat_equal(A, C); if (!result) { flint_printf("FAIL:\n"); flint_printf("A:\n"); fmpq_mat_print(A); flint_printf("B:\n"); fmpq_mat_print(B); flint_printf("C:\n"); fmpq_mat_print(C); flint_printf("I:\n"); fmpq_mat_print(I); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(C); fmpq_mat_clear(I); } FLINT_TEST_CLEANUP(state); flint_printf("PASS\n"); return EXIT_SUCCESS; }
void _fmpq_mat_randtest_positive_semidefinite(fmpq_mat_t mat, flint_rand_t state, mp_bitcnt_t bits) { slong n; fmpq_mat_t R, RT; if (!fmpq_mat_is_square(mat)) abort(); /* assert */ n = fmpq_mat_nrows(mat); fmpq_mat_init(R, n, n); fmpq_mat_init(RT, n, n); fmpq_mat_randtest(R, state, bits); fmpq_mat_transpose(RT, R); fmpq_mat_mul(mat, R, RT); fmpq_mat_clear(R); fmpq_mat_clear(RT); }
int main() { slong iter; flint_rand_t state; flint_printf("lu...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000; iter++) { fmpq_mat_t Q; acb_mat_t A, LU, P, L, U, T; slong i, j, n, qbits, prec, *perm; int q_invertible, r_invertible; n = n_randint(state, 8); qbits = 1 + n_randint(state, 100); prec = 2 + n_randint(state, 202); fmpq_mat_init(Q, n, n); acb_mat_init(A, n, n); acb_mat_init(LU, n, n); acb_mat_init(P, n, n); acb_mat_init(L, n, n); acb_mat_init(U, n, n); acb_mat_init(T, n, n); perm = _perm_init(n); fmpq_mat_randtest(Q, state, qbits); q_invertible = fmpq_mat_is_invertible(Q); if (!q_invertible) { acb_mat_set_fmpq_mat(A, Q, prec); r_invertible = acb_mat_lu(perm, LU, A, prec); if (r_invertible) { flint_printf("FAIL: matrix is singular over Q but not over R\n"); 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("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("LU = \n"); acb_mat_printd(LU, 15); flint_printf("\n\n"); } } else { /* now this must converge */ while (1) { acb_mat_set_fmpq_mat(A, Q, prec); r_invertible = acb_mat_lu(perm, LU, A, prec); if (r_invertible) { break; } else { if (prec > 10000) { flint_printf("FAIL: failed to converge at 10000 bits\n"); abort(); } prec *= 2; } } acb_mat_one(L); for (i = 0; i < n; i++) for (j = 0; j < i; j++) acb_set(acb_mat_entry(L, i, j), acb_mat_entry(LU, i, j)); for (i = 0; i < n; i++) for (j = i; j < n; j++) acb_set(acb_mat_entry(U, i, j), acb_mat_entry(LU, i, j)); for (i = 0; i < n; i++) acb_one(acb_mat_entry(P, perm[i], i)); acb_mat_mul(T, P, L, prec); acb_mat_mul(T, T, U, prec); if (!acb_mat_contains_fmpq_mat(T, 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("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("LU = \n"); acb_mat_printd(LU, 15); flint_printf("\n\n"); flint_printf("L = \n"); acb_mat_printd(L, 15); flint_printf("\n\n"); flint_printf("U = \n"); acb_mat_printd(U, 15); flint_printf("\n\n"); flint_printf("P*L*U = \n"); acb_mat_printd(T, 15); flint_printf("\n\n"); abort(); } } fmpq_mat_clear(Q); acb_mat_clear(A); acb_mat_clear(LU); acb_mat_clear(P); acb_mat_clear(L); acb_mat_clear(U); acb_mat_clear(T); _perm_clear(perm); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("solve_cho_precomp...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { fmpq_mat_t Q, QX, QB; arb_mat_t A, X, B; slong n, m, qbits, prec; int q_invertible, r_invertible, r_invertible2; n = n_randint(state, 8); m = n_randint(state, 8); qbits = 1 + n_randint(state, 30); prec = 2 + n_randint(state, 200); fmpq_mat_init(Q, n, n); fmpq_mat_init(QX, n, m); fmpq_mat_init(QB, n, m); arb_mat_init(A, n, n); arb_mat_init(X, n, m); arb_mat_init(B, n, m); _fmpq_mat_randtest_positive_semidefinite(Q, state, qbits); fmpq_mat_randtest(QB, state, qbits); q_invertible = fmpq_mat_solve_fraction_free(QX, Q, QB); if (!q_invertible) { arb_mat_set_fmpq_mat(A, Q, prec); r_invertible = _spd_solve(X, A, B, prec); if (r_invertible) { flint_printf("FAIL: matrix is singular over Q but not over R\n"); 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("QX = \n"); fmpq_mat_print(QX); flint_printf("\n\n"); flint_printf("QB = \n"); fmpq_mat_print(QB); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_abort(); } } else { /* now this must converge */ while (1) { arb_mat_set_fmpq_mat(A, Q, prec); arb_mat_set_fmpq_mat(B, QB, prec); r_invertible = _spd_solve(X, A, B, prec); if (r_invertible) { break; } else { if (prec > 10000) { flint_printf("FAIL: failed to converge at 10000 bits\n"); flint_printf("Q = \n"); fmpq_mat_print(Q); flint_printf("\n\n"); flint_printf("QX = \n"); fmpq_mat_print(QX); flint_printf("\n\n"); flint_printf("QB = \n"); fmpq_mat_print(QB); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_abort(); } prec *= 2; } } if (!arb_mat_contains_fmpq_mat(X, QX)) { 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("QB = \n"); fmpq_mat_print(QB); flint_printf("\n\n"); flint_printf("QX = \n"); fmpq_mat_print(QX); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("B = \n"); arb_mat_printd(B, 15); flint_printf("\n\n"); flint_printf("X = \n"); arb_mat_printd(X, 15); flint_printf("\n\n"); flint_abort(); } /* test aliasing */ r_invertible2 = _spd_solve(B, A, B, prec); if (!arb_mat_equal(X, B) || r_invertible != r_invertible2) { flint_printf("FAIL (aliasing)\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("B = \n"); arb_mat_printd(B, 15); flint_printf("\n\n"); flint_printf("X = \n"); arb_mat_printd(X, 15); flint_printf("\n\n"); flint_abort(); } } fmpq_mat_clear(Q); fmpq_mat_clear(QB); fmpq_mat_clear(QX); arb_mat_clear(A); arb_mat_clear(B); arb_mat_clear(X); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("inv...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000; iter++) { fmpq_mat_t Q, Qinv; acb_mat_t A, Ainv; slong n, qbits, prec; int q_invertible, r_invertible, r_invertible2; n = n_randint(state, 8); qbits = 1 + n_randint(state, 30); prec = 2 + n_randint(state, 200); fmpq_mat_init(Q, n, n); fmpq_mat_init(Qinv, n, n); acb_mat_init(A, n, n); acb_mat_init(Ainv, n, n); fmpq_mat_randtest(Q, state, qbits); q_invertible = fmpq_mat_inv(Qinv, Q); if (!q_invertible) { acb_mat_set_fmpq_mat(A, Q, prec); r_invertible = acb_mat_inv(Ainv, A, prec); if (r_invertible) { flint_printf("FAIL: matrix is singular over Q but not over R\n"); 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("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("Ainv = \n"); acb_mat_printd(Ainv, 15); flint_printf("\n\n"); abort(); } } else { /* now this must converge */ while (1) { acb_mat_set_fmpq_mat(A, Q, prec); r_invertible = acb_mat_inv(Ainv, A, prec); if (r_invertible) { break; } else { if (prec > 10000) { flint_printf("FAIL: failed to converge at 10000 bits\n"); flint_printf("Q = \n"); fmpq_mat_print(Q); flint_printf("\n\n"); flint_printf("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); abort(); } prec *= 2; } } if (!acb_mat_contains_fmpq_mat(Ainv, Qinv)) { 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("Qinv = \n"); fmpq_mat_print(Qinv); flint_printf("\n\n"); flint_printf("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("Ainv = \n"); acb_mat_printd(Ainv, 15); flint_printf("\n\n"); abort(); } /* test aliasing */ r_invertible2 = acb_mat_inv(A, A, prec); if (!acb_mat_equal(A, Ainv) || r_invertible != r_invertible2) { flint_printf("FAIL (aliasing)\n"); flint_printf("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("Ainv = \n"); acb_mat_printd(Ainv, 15); flint_printf("\n\n"); abort(); } } fmpq_mat_clear(Q); fmpq_mat_clear(Qinv); acb_mat_clear(A); acb_mat_clear(Ainv); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("mul...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { slong m, n, k, qbits1, qbits2, rbits1, rbits2, rbits3; fmpq_mat_t A, B, C; acb_mat_t a, b, c, d; qbits1 = 2 + n_randint(state, 200); qbits2 = 2 + n_randint(state, 200); rbits1 = 2 + n_randint(state, 200); rbits2 = 2 + n_randint(state, 200); rbits3 = 2 + n_randint(state, 200); m = n_randint(state, 10); n = n_randint(state, 10); k = n_randint(state, 10); fmpq_mat_init(A, m, n); fmpq_mat_init(B, n, k); fmpq_mat_init(C, m, k); acb_mat_init(a, m, n); acb_mat_init(b, n, k); acb_mat_init(c, m, k); acb_mat_init(d, m, k); fmpq_mat_randtest(A, state, qbits1); fmpq_mat_randtest(B, state, qbits2); fmpq_mat_mul(C, A, B); acb_mat_set_fmpq_mat(a, A, rbits1); acb_mat_set_fmpq_mat(b, B, rbits2); acb_mat_mul(c, a, b, rbits3); if (!acb_mat_contains_fmpq_mat(c, C)) { flint_printf("FAIL\n\n"); flint_printf("m = %wd, n = %wd, k = %wd, bits3 = %wd\n", m, n, k, rbits3); flint_printf("A = "); fmpq_mat_print(A); flint_printf("\n\n"); flint_printf("B = "); fmpq_mat_print(B); flint_printf("\n\n"); flint_printf("C = "); fmpq_mat_print(C); flint_printf("\n\n"); flint_printf("a = "); acb_mat_printd(a, 15); flint_printf("\n\n"); flint_printf("b = "); acb_mat_printd(b, 15); flint_printf("\n\n"); flint_printf("c = "); acb_mat_printd(c, 15); flint_printf("\n\n"); abort(); } /* test aliasing with a */ if (acb_mat_nrows(a) == acb_mat_nrows(c) && acb_mat_ncols(a) == acb_mat_ncols(c)) { acb_mat_set(d, a); acb_mat_mul(d, d, b, rbits3); if (!acb_mat_equal(d, c)) { flint_printf("FAIL (aliasing 1)\n\n"); abort(); } } /* test aliasing with b */ if (acb_mat_nrows(b) == acb_mat_nrows(c) && acb_mat_ncols(b) == acb_mat_ncols(c)) { acb_mat_set(d, b); acb_mat_mul(d, a, d, rbits3); if (!acb_mat_equal(d, c)) { flint_printf("FAIL (aliasing 2)\n\n"); abort(); } } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(C); acb_mat_clear(a); acb_mat_clear(b); acb_mat_clear(c); acb_mat_clear(d); } /* check algebraic properties like associativity and distributivity */ for (iter = 0; iter < 1000 * arb_test_multiplier(); iter++) { slong m, n, k, l; slong rbits; acb_mat_t a, b, c, d, ab, ac, bd, cd, s; rbits = 2 + n_randint(state, 200); m = n_randint(state, 10); n = n_randint(state, 10); k = n_randint(state, 10); l = n_randint(state, 10); _acb_mat_init_randtest(a, m, n, state); _acb_mat_init_randtest(b, n, k, state); _acb_mat_init_randtest(c, n, k, state); _acb_mat_init_randtest(d, k, l, state); acb_mat_init(ab, m, k); acb_mat_init(ac, m, k); acb_mat_init(bd, n, l); acb_mat_init(cd, n, l); acb_mat_init(s, n, k); acb_mat_mul(ab, a, b, rbits); acb_mat_mul(ac, a, c, rbits); acb_mat_mul(bd, b, d, rbits); acb_mat_mul(cd, c, d, rbits); acb_mat_add(s, b, c, rbits); /* check associativity of multiplication */ /* (A*B)*D = A*(B*D) */ { acb_mat_t lhs, rhs; acb_mat_init(lhs, m, l); acb_mat_init(rhs, m, l); acb_mat_mul(lhs, ab, d, rbits); acb_mat_mul(rhs, a, bd, rbits); if (!acb_mat_overlaps(lhs, rhs)) { flint_printf("FAIL\n\n"); flint_printf("m, n, k, l = %wd, %wd, %wd, %wd\n", m, n, k, l); flint_printf("rbits = %wd\n", rbits); _acb_mat_nprintd("a", a); _acb_mat_nprintd("b", b); _acb_mat_nprintd("d", d); _acb_mat_nprintd("(a*b)*d", lhs); _acb_mat_nprintd("a*(b*d)", rhs); abort(); } acb_mat_clear(lhs); acb_mat_clear(rhs); } /* check left distributivity of multiplication over addition */ /* A*(B + C) = A*B + A*C */ { acb_mat_t lhs, rhs; acb_mat_init(lhs, m, k); acb_mat_init(rhs, m, k); acb_mat_mul(lhs, a, s, rbits); acb_mat_add(rhs, ab, ac, rbits); if (!acb_mat_overlaps(lhs, rhs)) { flint_printf("FAIL\n\n"); flint_printf("m, n, k, l = %wd, %wd, %wd, %wd\n", m, n, k, l); flint_printf("rbits = %wd\n", rbits); _acb_mat_nprintd("a", a); _acb_mat_nprintd("b", b); _acb_mat_nprintd("c", c); _acb_mat_nprintd("a*(b + c)", lhs); _acb_mat_nprintd("a*b + b*c", rhs); abort(); } acb_mat_clear(lhs); acb_mat_clear(rhs); } /* check right distributivity of multiplication over addition */ /* (B + C)*D = B*D + C*D */ { acb_mat_t lhs, rhs; acb_mat_init(lhs, n, l); acb_mat_init(rhs, n, l); acb_mat_mul(lhs, s, d, rbits); acb_mat_add(rhs, bd, cd, rbits); if (!acb_mat_overlaps(lhs, rhs)) { flint_printf("FAIL\n\n"); flint_printf("m, n, k, l = %wd, %wd, %wd, %wd\n", m, n, k, l); flint_printf("rbits = %wd\n", rbits); _acb_mat_nprintd("b", b); _acb_mat_nprintd("c", c); _acb_mat_nprintd("d", d); _acb_mat_nprintd("(b + c)*d", lhs); _acb_mat_nprintd("b*d + c*d", rhs); abort(); } acb_mat_clear(lhs); acb_mat_clear(rhs); } /* check left multiplicative identity I*D = D */ { acb_mat_t one, lhs; acb_mat_init(one, k, k); acb_mat_init(lhs, k, l); acb_mat_one(one); acb_mat_mul(lhs, one, d, rbits); if (!acb_mat_contains(lhs, d)) { flint_printf("FAIL\n\n"); flint_printf("k = %wd, l = %wd\n", k, l); flint_printf("rbits = %wd\n", rbits); _acb_mat_nprintd("identity * d", lhs); _acb_mat_nprintd("d", d); abort(); } acb_mat_clear(one); acb_mat_clear(lhs); } /* check right multiplicative identity A*I = A */ { acb_mat_t one, lhs; acb_mat_init(one, n, n); acb_mat_init(lhs, m, n); acb_mat_one(one); acb_mat_mul(lhs, a, one, rbits); if (!acb_mat_contains(lhs, a)) { flint_printf("FAIL\n\n"); flint_printf("m = %wd, n = %wd\n", m, n); flint_printf("rbits = %wd\n", rbits); _acb_mat_nprintd("a * identity", lhs); _acb_mat_nprintd("a", a); abort(); } acb_mat_clear(one); acb_mat_clear(lhs); } acb_mat_clear(a); acb_mat_clear(b); acb_mat_clear(c); acb_mat_clear(d); acb_mat_clear(ab); acb_mat_clear(ac); acb_mat_clear(bd); acb_mat_clear(cd); acb_mat_clear(s); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("det...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 100000; iter++) { fmpq_mat_t Q; fmpq_t Qdet; arb_mat_t A; arb_t Adet; 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(Qdet); arb_mat_init(A, n, n); arb_init(Adet); fmpq_mat_randtest(Q, state, qbits); fmpq_mat_det(Qdet, Q); arb_mat_set_fmpq_mat(A, Q, prec); arb_mat_det(Adet, A, prec); if (!arb_contains_fmpq(Adet, Qdet)) { 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("Qdet = \n"); fmpq_print(Qdet); flint_printf("\n\n"); flint_printf("A = \n"); arb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("Adet = \n"); arb_printd(Adet, 15); flint_printf("\n\n"); flint_printf("Adet = \n"); arb_print(Adet); flint_printf("\n\n"); abort(); } fmpq_mat_clear(Q); fmpq_clear(Qdet); arb_mat_clear(A); arb_clear(Adet); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { long iter; flint_rand_t state; printf("exp...."); fflush(stdout); flint_randinit(state); /* check exp(A)*exp(c*A) = exp((1+c)*A) */ for (iter = 0; iter < 1000; iter++) { arb_mat_t A, E, F, EF, G; fmpq_mat_t Q; arb_t c, d; long n, qbits, prec; n = n_randint(state, 5); qbits = 2 + n_randint(state, 300); prec = 2 + n_randint(state, 300); arb_init(c); arb_init(d); fmpq_mat_init(Q, n, n); arb_mat_init(A, n, n); arb_mat_init(E, n, n); arb_mat_init(F, n, n); arb_mat_init(EF, n, n); arb_mat_init(G, n, n); fmpq_mat_randtest(Q, state, qbits); arb_mat_set_fmpq_mat(A, Q, prec); arb_mat_exp(E, A, prec); arb_randtest(c, state, prec, 10); arb_mat_scalar_mul_arb(F, A, c, prec); arb_mat_exp(F, F, prec); arb_add_ui(d, c, 1, prec); arb_mat_scalar_mul_arb(G, A, d, prec); arb_mat_exp(G, G, prec); arb_mat_mul(EF, E, F, prec); if (!arb_mat_overlaps(EF, G)) { printf("FAIL\n\n"); printf("n = %ld, prec = %ld\n", n, prec); printf("c = \n"); arb_printd(c, 15); printf("\n\n"); printf("A = \n"); arb_mat_printd(A, 15); printf("\n\n"); printf("E = \n"); arb_mat_printd(E, 15); printf("\n\n"); printf("F = \n"); arb_mat_printd(F, 15); printf("\n\n"); printf("E*F = \n"); arb_mat_printd(EF, 15); printf("\n\n"); printf("G = \n"); arb_mat_printd(G, 15); printf("\n\n"); abort(); } arb_clear(c); arb_clear(d); fmpq_mat_clear(Q); arb_mat_clear(A); arb_mat_clear(E); arb_mat_clear(F); arb_mat_clear(EF); arb_mat_clear(G); } flint_randclear(state); flint_cleanup(); printf("PASS\n"); return EXIT_SUCCESS; }
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"); 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"); 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"); 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"); 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; }
int main() { slong iter; flint_rand_t state; flint_printf("mul_threaded...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 5000 * arb_test_multiplier(); iter++) { slong m, n, k, qbits1, qbits2, rbits1, rbits2, rbits3; fmpq_mat_t A, B, C; acb_mat_t a, b, c, d; flint_set_num_threads(1 + n_randint(state, 5)); qbits1 = 2 + n_randint(state, 200); qbits2 = 2 + n_randint(state, 200); rbits1 = 2 + n_randint(state, 200); rbits2 = 2 + n_randint(state, 200); rbits3 = 2 + n_randint(state, 200); m = n_randint(state, 10); n = n_randint(state, 10); k = n_randint(state, 10); fmpq_mat_init(A, m, n); fmpq_mat_init(B, n, k); fmpq_mat_init(C, m, k); acb_mat_init(a, m, n); acb_mat_init(b, n, k); acb_mat_init(c, m, k); acb_mat_init(d, m, k); fmpq_mat_randtest(A, state, qbits1); fmpq_mat_randtest(B, state, qbits2); fmpq_mat_mul(C, A, B); acb_mat_set_fmpq_mat(a, A, rbits1); acb_mat_set_fmpq_mat(b, B, rbits2); acb_mat_mul_threaded(c, a, b, rbits3); if (!acb_mat_contains_fmpq_mat(c, C)) { flint_printf("FAIL\n\n"); flint_printf("threads = %d, m = %wd, n = %wd, k = %wd, bits3 = %wd\n", flint_get_num_threads(), m, n, k, rbits3); flint_printf("A = "); fmpq_mat_print(A); flint_printf("\n\n"); flint_printf("B = "); fmpq_mat_print(B); flint_printf("\n\n"); flint_printf("C = "); fmpq_mat_print(C); flint_printf("\n\n"); flint_printf("a = "); acb_mat_printd(a, 15); flint_printf("\n\n"); flint_printf("b = "); acb_mat_printd(b, 15); flint_printf("\n\n"); flint_printf("c = "); acb_mat_printd(c, 15); flint_printf("\n\n"); flint_abort(); } /* test aliasing with a */ if (acb_mat_nrows(a) == acb_mat_nrows(c) && acb_mat_ncols(a) == acb_mat_ncols(c)) { acb_mat_set(d, a); acb_mat_mul_threaded(d, d, b, rbits3); if (!acb_mat_equal(d, c)) { flint_printf("FAIL (aliasing 1)\n\n"); flint_abort(); } } /* test aliasing with b */ if (acb_mat_nrows(b) == acb_mat_nrows(c) && acb_mat_ncols(b) == acb_mat_ncols(c)) { acb_mat_set(d, b); acb_mat_mul_threaded(d, a, d, rbits3); if (!acb_mat_equal(d, c)) { flint_printf("FAIL (aliasing 2)\n\n"); flint_abort(); } } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(C); acb_mat_clear(a); acb_mat_clear(b); acb_mat_clear(c); acb_mat_clear(d); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { long iter; flint_rand_t state; printf("det...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000; iter++) { fmpq_mat_t Q; fmpq_t Qdet; acb_mat_t A; acb_t Adet, imagunit; long n, qbits, prec; int imaginary; n = n_randint(state, 8); qbits = 1 + n_randint(state, 100); prec = 2 + n_randint(state, 200); imaginary = n_randint(state, 2); fmpq_mat_init(Q, n, n); fmpq_init(Qdet); acb_mat_init(A, n, n); acb_init(Adet); acb_init(imagunit); fmpq_mat_randtest(Q, state, qbits); fmpq_mat_det(Qdet, Q); acb_mat_set_fmpq_mat(A, Q, prec); if (imaginary) { acb_onei(imagunit); acb_mat_scalar_mul_acb(A, A, imagunit, prec); } acb_mat_det(Adet, A, prec); if (imaginary) { acb_onei(imagunit); acb_inv(imagunit, imagunit, prec); acb_pow_ui(imagunit, imagunit, n, prec); acb_mul(Adet, Adet, imagunit, prec); } if (!acb_contains_fmpq(Adet, Qdet)) { printf("FAIL (containment, iter = %ld)\n", iter); printf("n = %ld, prec = %ld\n", n, prec); printf("\n"); printf("Q = \n"); fmpq_mat_print(Q); printf("\n\n"); printf("Qdet = \n"); fmpq_print(Qdet); printf("\n\n"); printf("A = \n"); acb_mat_printd(A, 15); printf("\n\n"); printf("Adet = \n"); acb_printd(Adet, 15); printf("\n\n"); printf("Adet = \n"); acb_print(Adet); printf("\n\n"); abort(); } fmpq_mat_clear(Q); fmpq_clear(Qdet); acb_mat_clear(A); acb_clear(Adet); acb_clear(imagunit); } flint_randclear(state); flint_cleanup(); printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("sqr...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { slong n, qbits1, rbits1, rbits2; fmpq_mat_t A, B; acb_mat_t a, b, c; qbits1 = 2 + n_randint(state, 200); rbits1 = 2 + n_randint(state, 200); rbits2 = 2 + n_randint(state, 200); n = n_randint(state, 10); fmpq_mat_init(A, n, n); fmpq_mat_init(B, n, n); acb_mat_init(a, n, n); acb_mat_init(b, n, n); acb_mat_init(c, n, n); fmpq_mat_randtest(A, state, qbits1); fmpq_mat_mul(B, A, A); acb_mat_set_fmpq_mat(a, A, rbits1); acb_mat_sqr(b, a, rbits2); if (!acb_mat_contains_fmpq_mat(b, B)) { flint_printf("FAIL\n\n"); flint_printf("n = %wd, bits2 = %wd\n", n, rbits2); flint_printf("A = "); fmpq_mat_print(A); flint_printf("\n\n"); flint_printf("B = "); fmpq_mat_print(B); flint_printf("\n\n"); flint_printf("a = "); acb_mat_printd(a, 15); flint_printf("\n\n"); flint_printf("b = "); acb_mat_printd(b, 15); flint_printf("\n\n"); abort(); } /* test aliasing */ acb_mat_set(c, a); acb_mat_sqr(c, c, rbits2); if (!acb_mat_equal(c, b)) { flint_printf("FAIL (aliasing)\n\n"); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); acb_mat_clear(a); acb_mat_clear(b); acb_mat_clear(c); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main() { slong iter; flint_rand_t state; flint_printf("trace...."); fflush(stdout); flint_randinit(state); /* check that the acb trace contains the fmpq trace */ for (iter = 0; iter < 10000; iter++) { fmpq_mat_t Q; fmpq_t Qtrace; acb_mat_t A; acb_t Atrace; 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(Qtrace); acb_mat_init(A, n, n); acb_init(Atrace); fmpq_mat_randtest(Q, state, qbits); fmpq_mat_trace(Qtrace, Q); acb_mat_set_fmpq_mat(A, Q, prec); acb_mat_trace(Atrace, A, prec); if (!acb_contains_fmpq(Atrace, Qtrace)) { 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("Qtrace = \n"); fmpq_print(Qtrace); flint_printf("\n\n"); flint_printf("A = \n"); acb_mat_printd(A, 15); flint_printf("\n\n"); flint_printf("Atrace = \n"); acb_printd(Atrace, 15); flint_printf("\n\n"); flint_printf("Atrace = \n"); acb_print(Atrace); flint_printf("\n\n"); abort(); } fmpq_mat_clear(Q); fmpq_clear(Qtrace); acb_mat_clear(A); acb_clear(Atrace); } /* check trace(A*B) = trace(B*A) */ for (iter = 0; iter < 10000; iter++) { slong m, n, prec; acb_mat_t a, b, ab, ba; acb_t trab, trba; prec = 2 + n_randint(state, 200); m = n_randint(state, 10); n = n_randint(state, 10); acb_mat_init(a, m, n); acb_mat_init(b, n, m); acb_mat_init(ab, m, m); acb_mat_init(ba, n, n); acb_init(trab); acb_init(trba); acb_mat_randtest(a, state, 2 + n_randint(state, 100), 10); acb_mat_randtest(b, state, 2 + n_randint(state, 100), 10); acb_mat_mul(ab, a, b, prec); acb_mat_mul(ba, b, a, prec); acb_mat_trace(trab, ab, prec); acb_mat_trace(trba, ba, prec); if (!acb_overlaps(trab, trba)) { flint_printf("FAIL (overlap, iter = %wd)\n", iter); flint_printf("m = %wd, n = %wd, prec = %wd\n", m, n, prec); flint_printf("\n"); flint_printf("a = \n"); acb_mat_printd(a, 15); flint_printf("\n\n"); flint_printf("b = \n"); acb_mat_printd(b, 15); flint_printf("\n\n"); flint_printf("ab = \n"); acb_mat_printd(ab, 15); flint_printf("\n\n"); flint_printf("ba = \n"); acb_mat_printd(ba, 15); flint_printf("\n\n"); flint_printf("trace(ab) = \n"); acb_printd(trab, 15); flint_printf("\n\n"); flint_printf("trace(ba) = \n"); acb_printd(trba, 15); flint_printf("\n\n"); } acb_clear(trab); acb_clear(trba); acb_mat_clear(a); acb_mat_clear(b); acb_mat_clear(ab); acb_mat_clear(ba); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }
int main(void) { int i; FLINT_TEST_INIT(state); flint_printf("solve_dixon...."); fflush(stdout); /* Solve nonsingular systems */ for (i = 0; i < 100 * flint_test_multiplier(); i++) { fmpq_mat_t A, B, X, AX; fmpq_t d; int success; slong n, m, bits; n = n_randint(state, 10); m = n_randint(state, 10); bits = 1 + n_randint(state, 100); fmpq_mat_init(A, n, n); fmpq_mat_init(B, n, m); fmpq_mat_init(X, n, m); fmpq_mat_init(AX, n, m); fmpq_init(d); /* XXX: replace with a randtest function */ do { fmpq_mat_randtest(A, state, bits); fmpq_mat_det(d, A); } while (fmpq_is_zero(d)); fmpq_clear(d); fmpq_mat_randtest(B, state, bits); success = fmpq_mat_solve_dixon(X, A, B); fmpq_mat_mul(AX, A, X); if (!fmpq_mat_equal(AX, B) || !success) { flint_printf("FAIL!\n"); flint_printf("success: %d\n", success); flint_printf("A:\n"); fmpq_mat_print(A); flint_printf("B:\n"); fmpq_mat_print(B); flint_printf("X:\n"); fmpq_mat_print(X); flint_printf("AX:\n"); fmpq_mat_print(AX); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(X); fmpq_mat_clear(AX); } /* Check singular systems */ for (i = 0; i < 100 * flint_test_multiplier(); i++) { fmpq_mat_t A, B, X; fmpz_mat_t M; fmpz_t den; slong n, m, bits; int success; n = 1 + n_randint(state, 10); m = 1 + n_randint(state, 10); bits = 1 + n_randint(state, 100); fmpz_init(den); fmpz_mat_init(M, n, n); fmpz_mat_randrank(M, state, n_randint(state, n), bits); if (i % 2) fmpz_mat_randops(M, state, n_randint(state, 2*m*n + 1)); fmpz_randtest_not_zero(den, state, bits); fmpq_mat_init(A, n, n); fmpq_mat_set_fmpz_mat_div_fmpz(A, M, den); fmpq_mat_init(B, n, m); fmpq_mat_randtest(B, state, bits); fmpq_mat_init(X, n, m); success = fmpq_mat_solve_dixon(X, A, B); if (success != 0) { flint_printf("FAIL!\n"); flint_printf("Expected success = 0\n"); fmpq_mat_print(A); flint_printf("\n"); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(X); fmpz_mat_clear(M); fmpz_clear(den); } FLINT_TEST_CLEANUP(state); flint_printf("PASS\n"); return 0; }
int main(void) { long i; flint_rand_t state; printf("trace...."); fflush(stdout); flint_randinit(state); /* Test trace(AB) = trace(BA) */ for (i = 0; i < 1000; i++) { fmpq_mat_t A, B, AB, BA; fmpq_t trab, trba; long m, n; m = n_randint(state, 10); n = n_randint(state, 10); fmpq_mat_init(A, m, n); fmpq_mat_init(B, n, m); fmpq_mat_init(AB, m, m); fmpq_mat_init(BA, n, n); fmpq_init(trab); fmpq_init(trba); fmpq_mat_randtest(A, state, 1 + n_randint(state, 100)); fmpq_mat_randtest(B, state, 1 + n_randint(state, 100)); fmpq_mat_mul(AB, A, B); fmpq_mat_mul(BA, B, A); fmpq_mat_trace(trab, AB); fmpq_mat_trace(trba, BA); if (!fmpq_equal(trab, trba)) { printf("FAIL:\n"); fmpq_mat_print(A), printf("\n"); fmpq_mat_print(B), printf("\n"); fmpq_mat_print(AB), printf("\n"); fmpq_mat_print(BA), printf("\n"); printf("tr(AB): "), fmpq_print(trab), printf("\n"); printf("tr(BA): "), fmpq_print(trba), printf("\n"); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(AB); fmpq_mat_clear(BA); fmpq_clear(trab); fmpq_clear(trba); } flint_randclear(state); _fmpz_cleanup(); printf("PASS\n"); return 0; }
int main(void) { int i, result; FLINT_TEST_INIT(state); flint_printf("scalar_div_fmpz...."); fflush(stdout); /* Aliasing */ for (i = 0; i < 100 * flint_test_multiplier(); i++) { fmpq_mat_t A, B; fmpz_t x; slong m, n, bits; m = n_randint(state, 10); n = n_randint(state, 10); bits = 1 + n_randint(state, 100); fmpq_mat_init(A, m, n); fmpq_mat_init(B, m, n); fmpz_init(x); fmpq_mat_randtest(B, state, bits); fmpz_randtest_not_zero(x, state, bits); fmpq_mat_scalar_div_fmpz(A, B, x); fmpq_mat_scalar_div_fmpz(B, B, x); result = fmpq_mat_equal(A, B); if (!result) { flint_printf("FAIL:\n"); flint_printf("A:\n"), fmpq_mat_print(A); flint_printf("B:\n"), fmpq_mat_print(B); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpz_clear(x); } /* (A + B) / x == A / x + B / x */ for (i = 0; i < 100 * flint_test_multiplier(); i++) { fmpq_mat_t A, B, C, D; fmpz_t x; slong m, n, bits; m = n_randint(state, 10); n = n_randint(state, 10); bits = 1 + n_randint(state, 100); fmpq_mat_init(A, m, n); fmpq_mat_init(B, m, n); fmpq_mat_init(C, m, n); fmpq_mat_init(D, m, n); fmpz_init(x); fmpq_mat_randtest(A, state, bits); fmpq_mat_randtest(B, state, bits); fmpz_randtest_not_zero(x, state, bits); fmpq_mat_scalar_div_fmpz(C, A, x); fmpq_mat_scalar_div_fmpz(D, B, x); fmpq_mat_add(D, C, D); fmpq_mat_add(C, A, B); fmpq_mat_scalar_div_fmpz(C, C, x); result = fmpq_mat_equal(C, D); if (!result) { flint_printf("FAIL:\n"); flint_printf("A:\n"), fmpq_mat_print(A); flint_printf("B:\n"), fmpq_mat_print(B); abort(); } fmpq_mat_clear(A); fmpq_mat_clear(B); fmpq_mat_clear(C); fmpq_mat_clear(D); fmpz_clear(x); } FLINT_TEST_CLEANUP(state); flint_printf("PASS\n"); return EXIT_SUCCESS; }