197 lines
5.2 KiB
C
197 lines
5.2 KiB
C
/*=============================================================================
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This file is part of FLINT.
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FLINT is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2 of the License, or
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(at your option) any later version.
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FLINT is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with FLINT; if not, write to the Free Software
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Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
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=============================================================================*/
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/******************************************************************************
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Copyright (C) 2008, 2009 William Hart
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Copyright (C) 2010, 2011 Sebastian Pancratz
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******************************************************************************/
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#include <stdlib.h>
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#include <gmp.h>
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#include "flint.h"
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#include "fmpz.h"
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#include "fmpz_vec.h"
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#include "fmpz_mod_poly.h"
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static void
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__fmpz_mod_poly_divrem_divconquer(fmpz * Q, fmpz * R,
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const fmpz * A, slong lenA, const fmpz * B, slong lenB,
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const fmpz_t invB, const fmpz_t p)
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{
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if (lenA < 2 * lenB - 1)
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{
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/*
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Convert unbalanced division into a 2 n1 - 1 by n1 division
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*/
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const slong n1 = lenA - lenB + 1;
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const slong n2 = lenB - n1;
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const fmpz * p1 = A + n2;
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const fmpz * d1 = B + n2;
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const fmpz * d2 = B;
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fmpz * W = _fmpz_vec_init((2 * n1 - 1) + lenB - 1);
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fmpz * d1q1 = R + n2;
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fmpz * d2q1 = W + (2 * n1 - 1);
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_fmpz_mod_poly_divrem_divconquer_recursive(Q, d1q1, W, p1, d1, n1,
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invB, p);
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/*
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Compute d2q1 = Q d2, of length lenB - 1
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*/
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if (n1 >= n2)
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_fmpz_mod_poly_mul(d2q1, Q, n1, d2, n2, p);
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else
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_fmpz_mod_poly_mul(d2q1, d2, n2, Q, n1, p);
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/*
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Compute BQ = d1q1 * x^n1 + d2q1, of length lenB - 1;
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then compute R = A - BQ
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*/
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_fmpz_vec_swap(R, d2q1, n2);
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_fmpz_mod_poly_add(R + n2, R + n2, n1 - 1, d2q1 + n2, n1 - 1, p);
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_fmpz_mod_poly_sub(R, A, lenA, R, lenA, p);
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_fmpz_vec_clear(W, (2 * n1 - 1) + lenB - 1);
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}
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else /* lenA = 2 * lenB - 1 */
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{
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fmpz * W = _fmpz_vec_init(lenA);
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_fmpz_mod_poly_divrem_divconquer_recursive(Q, R, W,
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A, B, lenB, invB, p);
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_fmpz_mod_poly_sub(R, A, lenB - 1, R, lenB - 1, p);
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_fmpz_vec_clear(W, lenA);
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}
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}
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void _fmpz_mod_poly_divrem_divconquer(fmpz *Q, fmpz *R,
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const fmpz *A, slong lenA, const fmpz *B, slong lenB,
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const fmpz_t invB, const fmpz_t p)
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{
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if (lenA <= 2 * lenB - 1)
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{
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__fmpz_mod_poly_divrem_divconquer(Q, R, A, lenA, B, lenB, invB, p);
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}
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else /* lenA > 2 * lenB - 1 */
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{
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slong shift, n = 2 * lenB - 1;
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fmpz *QB, *W;
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_fmpz_vec_set(R, A, lenA);
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W = _fmpz_vec_init(2 * n);
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QB = W + n;
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while (lenA >= n)
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{
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shift = lenA - n;
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_fmpz_mod_poly_divrem_divconquer_recursive(Q + shift, QB,
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W, R + shift, B, lenB, invB, p);
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_fmpz_mod_poly_sub(R + shift, R + shift, n, QB, n, p);
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lenA -= lenB;
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}
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if (lenA >= lenB)
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{
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__fmpz_mod_poly_divrem_divconquer(Q, W, R, lenA, B, lenB, invB, p);
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_fmpz_vec_swap(W, R, lenA);
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}
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_fmpz_vec_clear(W, 2 * n);
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}
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}
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void
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fmpz_mod_poly_divrem_divconquer(fmpz_mod_poly_t Q, fmpz_mod_poly_t R,
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const fmpz_mod_poly_t A, const fmpz_mod_poly_t B)
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{
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const slong lenA = A->length;
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const slong lenB = B->length;
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const slong lenQ = lenA - lenB + 1;
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fmpz *q, *r;
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fmpz_t invB;
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if (lenA < lenB)
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{
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fmpz_mod_poly_set(R, A);
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fmpz_mod_poly_zero(Q);
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return;
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}
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fmpz_init(invB);
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fmpz_invmod(invB, fmpz_mod_poly_lead(B), &(B->p));
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if (Q == A || Q == B)
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{
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q = _fmpz_vec_init(lenQ);
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}
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else
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{
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fmpz_mod_poly_fit_length(Q, lenQ);
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q = Q->coeffs;
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}
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if (R == A || R == B)
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{
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r = _fmpz_vec_init(lenA);
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}
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else
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{
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fmpz_mod_poly_fit_length(R, lenA);
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r = R->coeffs;
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}
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_fmpz_mod_poly_divrem_divconquer(q, r, A->coeffs, lenA,
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B->coeffs, lenB, invB, &(B->p));
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if (Q == A || Q == B)
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{
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_fmpz_vec_clear(Q->coeffs, Q->alloc);
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Q->coeffs = q;
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Q->alloc = lenQ;
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Q->length = lenQ;
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}
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else
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{
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_fmpz_mod_poly_set_length(Q, lenQ);
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}
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if (R == A || R == B)
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{
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_fmpz_vec_clear(R->coeffs, R->alloc);
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R->coeffs = r;
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R->alloc = lenA;
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R->length = lenA;
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}
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_fmpz_mod_poly_set_length(R, lenB - 1);
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_fmpz_mod_poly_normalise(R);
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fmpz_clear(invB);
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}
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