/*============================================================================= This file is part of FLINT. FLINT 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. FLINT 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 copy1 of the GNU General Public License along with FLINT; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =============================================================================*/ /****************************************************************************** Copyright (C) 2011 Sebastian Pancratz ******************************************************************************/ #include #include "flint.h" #include "fmpz_mod_poly.h" /* Let i be such that 2^{i} < len1 <= 2^{i+1}. Note that the jth step of the recursion requires temporary space of size no more than (len2 - 1)(2^j - 1) + 1. Note the smallest step j=0 doesn't require any temporary space and the largest step has j = i, and hence the sum is sum_{j=1}^i [(len2 - 1) (2^j - 1) + 1] = (len2 - 1)(2^{i+1} - 2) - (len2 - 2) i */ void _fmpz_mod_poly_compose_divconquer_recursive(fmpz *res, const fmpz *poly1, slong len1, fmpz **pow2, slong len2, fmpz *v, const fmpz_t p) { if (len1 == 1) { fmpz_set(res, poly1); } else if (len1 == 2) { _fmpz_mod_poly_scalar_mul_fmpz(res, pow2[0], len2, poly1 + 1, p); fmpz_add(res, res, poly1); if (fmpz_cmpabs(res, p) >= 0) fmpz_sub(res, res, p); } else { const slong i = FLINT_BIT_COUNT(len1 - 1) - 1; fmpz *w = v + ((WORD(1) << i) - 1) * (len2 - 1) + 1; _fmpz_mod_poly_compose_divconquer_recursive(v, poly1 + (WORD(1) << i), len1 - (WORD(1) << i), pow2, len2, w, p); _fmpz_mod_poly_mul(res, pow2[i], (len2 - 1) * (WORD(1) << i) + 1, v, (len2 - 1) * (len1 - (WORD(1) << i) - 1) + 1, p); _fmpz_mod_poly_compose_divconquer_recursive(v, poly1, WORD(1) << i, pow2, len2, w, p); _fmpz_mod_poly_add(res, res, (len2 - 1) * ((WORD(1) << i) - 1) + 1, v, (len2 - 1) * ((WORD(1) << i) - 1) + 1, p); } } void _fmpz_mod_poly_compose_divconquer(fmpz *res, const fmpz *poly1, slong len1, const fmpz *poly2, slong len2, const fmpz_t p) { if (len1 == 1 || len2 == 0) { fmpz_set(res, poly1); } else { const slong k = FLINT_BIT_COUNT(len1 - 1); const slong lenV = len2 * ((WORD(1) << k) - 1) + k; const slong lenW = (len2 - 1) * ((WORD(1) << k) - 2) - (len2 - 2) * (k-1); slong i; fmpz *v, *w, **pow2; v = _fmpz_vec_init(lenV + lenW); w = v + lenV; pow2 = flint_malloc(k * sizeof(fmpz *)); for (i = 0; i < k; i++) { pow2[i] = v + (len2 * ((WORD(1) << i) - 1) + i); } _fmpz_vec_set(pow2[0], poly2, len2); for (i = 1; i < k; i++) { _fmpz_mod_poly_sqr(pow2[i], pow2[i-1], (len2 - 1) * (WORD(1) << (i - 1)) + 1, p); } _fmpz_mod_poly_compose_divconquer_recursive(res, poly1, len1, pow2, len2, w, p); _fmpz_vec_clear(v, lenV + lenW); flint_free(pow2); } } void fmpz_mod_poly_compose_divconquer(fmpz_mod_poly_t res, const fmpz_mod_poly_t poly1, const fmpz_mod_poly_t poly2) { const slong len1 = poly1->length; const slong len2 = poly2->length; if (len1 == 0) { fmpz_mod_poly_zero(res); } else if (len1 == 1 || len2 == 0) { fmpz_mod_poly_set_fmpz(res, poly1->coeffs); } else { const slong lenr = (len1 - 1) * (len2 - 1) + 1; if ((res != poly1) && (res != poly2)) { fmpz_mod_poly_fit_length(res, lenr); _fmpz_mod_poly_compose_divconquer(res->coeffs, poly1->coeffs, len1, poly2->coeffs, len2, &(res->p)); } else { fmpz *t = _fmpz_vec_init(lenr); _fmpz_mod_poly_compose_divconquer(t, poly1->coeffs, len1, poly2->coeffs, len2, &(res->p)); _fmpz_vec_clear(res->coeffs, res->alloc); res->coeffs = t; res->alloc = lenr; res->length = lenr; } _fmpz_mod_poly_set_length(res, lenr); _fmpz_mod_poly_normalise(res); } }