/*============================================================================= This file is part of ARB. ARB 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. ARB 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 ARB; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =============================================================================*/ /****************************************************************************** Copyright (C) 2016 Pascal Molin ******************************************************************************/ #include "acb_dirichlet.h" #include "acb_poly.h" /* x = Pi / q * t^2 */ static void acb_dirichlet_arb_theta_argt(arb_t x, ulong q, const arb_t t, slong prec) { arb_const_pi(x, prec); arb_div_ui(x, x, q, prec); arb_mul(x, x, t, prec); arb_mul(x, x, t, prec); arb_neg(x, x); arb_exp(x, x, prec); } /* small order, multiply by chi at the end */ void acb_dirichlet_arb_theta_smallorder(acb_t res, const arb_t x, int parity, const ulong *a, const acb_dirichlet_powers_t z, slong len, slong prec) { slong k; ulong order = z->order; arb_t xk2, kxk2, dx, x2; acb_ptr t; arb_init(xk2); arb_init(dx); arb_init(x2); arb_init(kxk2); arb_set(dx, x); arb_set(xk2, x); arb_mul(x2, x, x, prec); t = _acb_vec_init(order); _acb_vec_zero(t, order); arb_set(acb_realref(t + 0), xk2); /* TODO: reduce precision at each step */ for (k = 2; k < len; k++) { arb_mul(dx, dx, x2, prec); arb_mul(xk2, xk2, dx, prec); if (a[k] != ACB_DIRICHLET_CHI_NULL) { if (parity) { arb_mul_si(kxk2, xk2, k, prec); arb_add(acb_realref(t + a[k]), acb_realref(t + a[k]), kxk2, prec); } else { arb_add(acb_realref(t + a[k]), acb_realref(t + a[k]), xk2, prec); } } } /* now Hörner */ _acb_poly_evaluate(res, t, order, z->z + 1, prec); _acb_vec_clear(t, order); arb_clear(xk2); arb_clear(x2); arb_clear(dx); } void acb_dirichlet_arb_theta_naive(acb_t res, const arb_t x, int parity, const ulong *a, const acb_dirichlet_powers_t z, slong len, slong prec) { slong k; arb_t xk2, dx, x2; acb_t zk; arb_init(xk2); arb_init(dx); arb_init(x2); acb_init(zk); arb_set(dx, x); arb_set(xk2, dx); arb_mul(x2, dx, dx, prec); acb_set_arb(res, xk2); /* TODO: reduce prec */ for (k = 2; k < len; k++) { arb_mul(dx, dx, x2, prec); arb_mul(xk2, xk2, dx, prec); if (a[k] != ACB_DIRICHLET_CHI_NULL) { acb_dirichlet_power(zk, z, a[k], prec); if (parity) acb_mul_si(zk, zk, k, prec); acb_addmul_arb(res, zk, xk2, prec); } } arb_clear(xk2); arb_clear(x2); arb_clear(dx); acb_clear(zk); } void acb_dirichlet_chi_theta(acb_t res, const acb_dirichlet_group_t G, const acb_dirichlet_char_t chi, const arb_t t, slong prec) { slong len; ulong * a; arb_t x; acb_dirichlet_powers_t z; len = acb_dirichlet_theta_length(G->q, t, prec); a = flint_malloc(len * sizeof(ulong)); acb_dirichlet_ui_chi_vec(a, G, chi, len); acb_dirichlet_powers_init(z, chi->order, len, prec); arb_init(x); acb_dirichlet_arb_theta_argt(x, G->q, t, prec); acb_dirichlet_arb_theta_naive(res, x, chi->parity, a, z, len, prec); arb_clear(x); flint_free(a); acb_dirichlet_powers_clear(z); }