/*============================================================================= 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) 2011 William Hart Copyright (C) 2012 Sebastian Pancratz ******************************************************************************/ #include #include "nmod_poly.h" #include "mpn_extras.h" slong _nmod_poly_xgcd(mp_ptr G, mp_ptr S, mp_ptr T, mp_srcptr A, slong lenA, mp_srcptr B, slong lenB, nmod_t mod) { const slong cutoff = FLINT_BIT_COUNT(mod.n) <= 8 ? NMOD_POLY_SMALL_GCD_CUTOFF : NMOD_POLY_GCD_CUTOFF; if (lenA < cutoff) return _nmod_poly_xgcd_euclidean(G, S, T, A, lenA, B, lenB, mod); else return _nmod_poly_xgcd_hgcd(G, S, T, A, lenA, B, lenB, mod); } void nmod_poly_xgcd(nmod_poly_t G, nmod_poly_t S, nmod_poly_t T, const nmod_poly_t A, const nmod_poly_t B) { if (A->length < B->length) { nmod_poly_xgcd(G, T, S, B, A); } else /* lenA >= lenB >= 0 */ { const slong lenA = A->length, lenB = B->length; mp_limb_t inv; if (lenA == 0) /* lenA = lenB = 0 */ { nmod_poly_zero(G); nmod_poly_zero(S); nmod_poly_zero(T); } else if (lenB == 0) /* lenA > lenB = 0 */ { inv = n_invmod(A->coeffs[lenA - 1], A->mod.n); nmod_poly_scalar_mul_nmod(G, A, inv); nmod_poly_zero(T); nmod_poly_set_coeff_ui(S, 0, inv); S->length = 1; } else if (lenB == 1) /* lenA >= lenB = 1 */ { nmod_poly_fit_length(T, 1); T->length = 1; T->coeffs[0] = n_invmod(B->coeffs[0], A->mod.n); nmod_poly_one(G); nmod_poly_zero(S); } else /* lenA >= lenB >= 2 */ { mp_ptr g, s, t; slong lenG; if (G == A || G == B) { g = _nmod_vec_init(FLINT_MIN(lenA, lenB)); } else { nmod_poly_fit_length(G, FLINT_MIN(lenA, lenB)); g = G->coeffs; } if (S == A || S == B) { s = _nmod_vec_init(lenB - 1); } else { nmod_poly_fit_length(S, lenB - 1); s = S->coeffs; } if (T == A || T == B) { t = _nmod_vec_init(lenA - 1); } else { nmod_poly_fit_length(T, lenA - 1); t = T->coeffs; } if (lenA >= lenB) lenG = _nmod_poly_xgcd(g, s, t, A->coeffs, lenA, B->coeffs, lenB, A->mod); else lenG = _nmod_poly_xgcd(g, t, s, B->coeffs, lenB, A->coeffs, lenA, A->mod); if (G == A || G == B) { flint_free(G->coeffs); G->coeffs = g; G->alloc = FLINT_MIN(lenA, lenB); } if (S == A || S == B) { flint_free(S->coeffs); S->coeffs = s; S->alloc = lenB - 1; } if (T == A || T == B) { flint_free(T->coeffs); T->coeffs = t; T->alloc = lenA - 1; } G->length = lenG; S->length = FLINT_MAX(lenB - lenG, 1); T->length = FLINT_MAX(lenA - lenG, 1); MPN_NORM(S->coeffs, S->length); MPN_NORM(T->coeffs, T->length); if (G->coeffs[lenG - 1] != 1) { inv = n_invmod(G->coeffs[lenG - 1], A->mod.n); nmod_poly_scalar_mul_nmod(G, G, inv); nmod_poly_scalar_mul_nmod(S, S, inv); nmod_poly_scalar_mul_nmod(T, T, inv); } } } }