/* Copyright (C) 2021 Fredrik Johansson 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 "acb_hypgeom.h" int main() { slong iter; flint_rand_t state; flint_printf("gamma_taylor...."); fflush(stdout); flint_randinit(state); for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++) { acb_t x, s1, s2, a, b; slong prec, ebits, prec2; int success, success2, alias, reciprocal; if (n_randint(state, 10) == 0) prec = 2 + n_randint(state, 4000); else prec = 2 + n_randint(state, 300); if (n_randint(state, 10) == 0) ebits = 100; else ebits = 10; prec2 = prec + 1 + n_randint(state, 30); acb_init(x); acb_init(s1); acb_init(s2); acb_init(a); acb_init(b); acb_randtest(x, state, prec, ebits); acb_randtest(s1, state, prec, 10); acb_randtest(s2, state, prec, 10); alias = n_randint(state, 2); reciprocal = n_randint(state, 2); if (alias) { success = acb_hypgeom_gamma_taylor(s1, x, reciprocal, prec); } else { acb_set(s1, x); success = acb_hypgeom_gamma_taylor(s1, s1, reciprocal, prec); } if (success) { /* printf("%ld\n", iter); */ /* Compare with Stirling series algorithm. */ acb_hypgeom_gamma_stirling(s2, x, reciprocal, prec); if (!acb_overlaps(s1, s2)) { flint_printf("FAIL\n\n"); flint_printf("prec = %wd\n\n", prec); flint_printf("x = "); acb_printn(x, 1000, 0); flint_printf("\n\n"); flint_printf("s1 = "); acb_printn(s1, 1000, 0); flint_printf("\n\n"); flint_printf("s2 = "); acb_printn(s2, 1000, 0); flint_printf("\n\n"); acb_sub(s1, s1, s2, prec2); flint_printf("s1 - s2 = "); acb_printd(s1, 1000); flint_printf("\n\n"); flint_abort(); } /* Compare with different level of precision. */ success2 = acb_hypgeom_gamma_taylor(s2, x, reciprocal, prec2); if (success2 && !acb_overlaps(s1, s2)) { flint_printf("FAIL (2)\n\n"); flint_printf("prec = %wd\n\n", prec); flint_printf("x = "); acb_printn(x, 1000, 0); flint_printf("\n\n"); flint_printf("s1 = "); acb_printn(s1, 1000, 0); flint_printf("\n\n"); flint_printf("s2 = "); acb_printn(s2, 1000, 0); flint_printf("\n\n"); acb_sub(s1, s1, s2, prec2); flint_printf("s1 - s2 = "); acb_printn(s1, 1000, 0); flint_printf("\n\n"); flint_abort(); } acb_get_mid(a, x); if (n_randint(state, 2)) { arf_set_mag(arb_midref(acb_realref(b)), arb_radref(acb_realref(x))); arf_set_mag(arb_midref(acb_imagref(b)), arb_radref(acb_imagref(x))); if (n_randint(state, 2)) acb_neg(b, b); if (n_randint(state, 2)) acb_conj(b, b); acb_add(a, a, b, prec2); } success2 = acb_hypgeom_gamma_taylor(s2, a, reciprocal, prec2); if (success2 && !acb_overlaps(s1, s2)) { flint_printf("FAIL (3)\n\n"); flint_printf("prec = %wd\n\n", prec); flint_printf("x = "); acb_printn(x, 1000, 0); flint_printf("\n\n"); flint_printf("s1 = "); acb_printn(s1, 1000, 0); flint_printf("\n\n"); flint_printf("s2 = "); acb_printn(s2, 1000, 0); flint_printf("\n\n"); acb_sub(s1, s1, s2, prec2); flint_printf("s1 - s2 = "); acb_printn(s1, 1000, 0); flint_printf("\n\n"); flint_abort(); } } acb_clear(x); acb_clear(s1); acb_clear(s2); acb_clear(a); acb_clear(b); } flint_randclear(state); flint_cleanup(); flint_printf("PASS\n"); return EXIT_SUCCESS; }