/*============================================================================= 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 copy 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) 2010, 2011 Sebastian Pancratz Copyright (C) 2010 William Hart ******************************************************************************/ #include #include #include "flint.h" #include "nmod_vec.h" #include "nmod_poly.h" /* See fmpz_poly/compose_divconquer.c */ void _nmod_poly_compose_series_divconquer(mp_ptr res, mp_srcptr poly1, slong len1, mp_srcptr poly2, slong len2, slong N, nmod_t mod) { slong i, j, k, n; slong *hlen, alloc, powlen; mp_ptr v, *h, pow, temp; if (len1 == 1) { res[0] = poly1[0]; return; } if (len2 == 1) { res[0] = _nmod_poly_evaluate_nmod(poly1, len1, poly2[0], mod); return; } if (len1 == 2) { mp_limb_t t = poly1[0]; _nmod_vec_scalar_mul_nmod(res, poly2, len2, poly1[1], mod); res[0] = n_addmod(res[0], t, mod.n); return; } /* Initialisation */ hlen = (slong *) flint_malloc(((len1 + 1) / 2) * sizeof(slong)); for (k = 1; (2 << k) < len1; k++) ; hlen[0] = hlen[1] = FLINT_MIN(N, ((1 << k) - 1) * (len2 - 1) + 1); for (i = k - 1; i > 0; i--) { slong hi = (len1 + (1 << i) - 1) / (1 << i); slong t = FLINT_MIN(N, ((1 << i) - 1) * (len2 - 1) + 1); for (n = (hi + 1) / 2; n < hi; n++) hlen[n] = t; } powlen = FLINT_MIN(N, (1 << k) * (len2 - 1) + 1); alloc = 0; for (i = 0; i < (len1 + 1) / 2; i++) alloc += hlen[i]; v = _nmod_vec_init(alloc + 2 * powlen); h = (mp_ptr *) flint_malloc(((len1 + 1) / 2) * sizeof(mp_ptr)); h[0] = v; for (i = 0; i < (len1 - 1) / 2; i++) { h[i + 1] = h[i] + hlen[i]; hlen[i] = 0; } hlen[(len1 - 1) / 2] = 0; pow = v + alloc; temp = pow + powlen; /* Let's start the actual work */ for (i = 0, j = 0; i < len1 / 2; i++, j += 2) { if (poly1[j + 1] != WORD(0)) { _nmod_vec_scalar_mul_nmod(h[i], poly2, len2, poly1[j + 1], mod); h[i][0] = n_addmod(h[i][0], poly1[j], mod.n); hlen[i] = len2; } else if (poly1[j] != WORD(0)) { h[i][0] = poly1[j]; hlen[i] = 1; } } if ((len1 & WORD(1))) { if (poly1[j] != WORD(0)) { h[i][0] = poly1[j]; hlen[i] = 1; } } powlen = FLINT_MIN(N, 2 * len2 - 1); _nmod_poly_mullow(pow, poly2, len2, poly2, len2, powlen, mod); for (n = (len1 + 1) / 2; n > 2; n = (n + 1) / 2) { if (hlen[1] > 0) { slong templen = FLINT_MIN(N, powlen + hlen[1] - 1); _nmod_poly_mullow(temp, pow, powlen, h[1], hlen[1], templen, mod); _nmod_poly_add(h[0], temp, templen, h[0], hlen[0], mod); hlen[0] = FLINT_MAX(hlen[0], templen); } for (i = 1; i < n / 2; i++) { if (hlen[2*i + 1] > 0) { hlen[i] = FLINT_MIN(N, hlen[2*i + 1] + powlen - 1); _nmod_poly_mullow(h[i], pow, powlen, h[2*i + 1], hlen[2*i + 1], hlen[i], mod); } else { hlen[i] = 0; } _nmod_poly_add(h[i], h[i], hlen[i], h[2*i], hlen[2*i], mod); hlen[i] = FLINT_MAX(hlen[i], hlen[2*i]); } if ((n & WORD(1))) { hlen[i] = FLINT_MIN(N, hlen[2*i]); flint_mpn_copyi(h[i], h[2*i], hlen[i]); } _nmod_poly_mullow(temp, pow, powlen, pow, powlen, FLINT_MIN(N, 2 * powlen - 1), mod); powlen = FLINT_MIN(N, 2 * powlen - 1); { mp_ptr t = pow; pow = temp; temp = t; } } _nmod_poly_mullow(res, pow, powlen, h[1], hlen[1], FLINT_MIN(N, powlen + hlen[1] - 1), mod); _nmod_vec_add(res, res, h[0], hlen[0], mod); _nmod_vec_clear(v); flint_free(h); flint_free(hlen); } void nmod_poly_compose_series_divconquer(nmod_poly_t res, const nmod_poly_t poly1, const nmod_poly_t poly2, slong N) { const slong len1 = poly1->length; const slong len2 = FLINT_MIN(N, poly2->length); slong lenr; if (len1 == 0 || N == 0) { nmod_poly_zero(res); return; } if (len1 == 1 || len2 == 0) { nmod_poly_set_coeff_ui(res, 0, poly1->coeffs[0]); nmod_poly_truncate(res, 1); return; } lenr = FLINT_MIN(N, (len1 - 1) * (len2 - 1) + 1); if (res != poly1 && res != poly2) { nmod_poly_fit_length(res, lenr); _nmod_poly_compose_series_divconquer(res->coeffs, poly1->coeffs, len1, poly2->coeffs, len2, N, poly1->mod); } else { nmod_poly_t t; nmod_poly_init2(t, poly1->mod.n, lenr); _nmod_poly_compose_series_divconquer(t->coeffs, poly1->coeffs, len1, poly2->coeffs, len2, N, poly1->mod); nmod_poly_swap(res, t); nmod_poly_clear(t); } res->length = lenr; _nmod_poly_normalise(res); }