548 lines
12 KiB
C
548 lines
12 KiB
C
/* mpn_gcdext -- Extended Greatest Common Divisor.
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Copyright 1996, 1998, 2000, 2001, 2002, 2003, 2004, 2005, 2008, 2009 Free Software
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Foundation, Inc.
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This file is part of the GNU MP Library.
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The GNU MP Library is free software; you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License as published by
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the Free Software Foundation; either version 3 of the License, or (at your
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option) any later version.
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The GNU MP Library is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
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License for more details.
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You should have received a copy of the GNU Lesser General Public License
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along with the GNU MP Library. If not, see http://www.gnu.org/licenses/. */
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#include "mpir.h"
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#include "gmp-impl.h"
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#include "longlong.h"
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/* Computes (r;b) = (a; b) M. Result is of size n + M->n +/- 1, and
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the size is returned (if inputs are non-normalized, result may be
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non-normalized too). Temporary space needed is M->n + n.
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*/
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static size_t
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hgcd_mul_matrix_vector (struct hgcd_matrix *M,
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mp_ptr rp, mp_srcptr ap, mp_ptr bp, mp_size_t n, mp_ptr tp)
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{
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mp_limb_t ah, bh;
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/* Compute (r,b) <-- (u00 a + u10 b, u01 a + u11 b) as
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t = u00 * a
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r = u10 * b
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r += t;
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t = u11 * b
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b = u01 * a
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b += t;
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*/
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if (M->n >= n)
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{
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mpn_mul (tp, M->p[0][0], M->n, ap, n);
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mpn_mul (rp, M->p[1][0], M->n, bp, n);
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}
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else
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{
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mpn_mul (tp, ap, n, M->p[0][0], M->n);
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mpn_mul (rp, bp, n, M->p[1][0], M->n);
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}
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ah = mpn_add_n (rp, rp, tp, n + M->n);
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if (M->n >= n)
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{
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mpn_mul (tp, M->p[1][1], M->n, bp, n);
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mpn_mul (bp, M->p[0][1], M->n, ap, n);
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}
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else
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{
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mpn_mul (tp, bp, n, M->p[1][1], M->n);
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mpn_mul (bp, ap, n, M->p[0][1], M->n);
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}
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bh = mpn_add_n (bp, bp, tp, n + M->n);
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n += M->n;
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if ( (ah | bh) > 0)
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{
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rp[n] = ah;
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bp[n] = bh;
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n++;
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}
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else
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{
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/* Normalize */
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while ( (rp[n-1] | bp[n-1]) == 0)
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n--;
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}
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return n;
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}
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#define COMPUTE_V_ITCH(n) (2*(n) + 1)
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/* Computes |v| = |(g - u a)| / b, where u may be positive or
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negative, and v is of the opposite sign. a, b are of size n, u and
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v at most size n, and v must have space for n+1 limbs. */
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static mp_size_t
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compute_v (mp_ptr vp,
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mp_srcptr ap, mp_srcptr bp, mp_size_t n,
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mp_srcptr gp, mp_size_t gn,
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mp_srcptr up, mp_size_t usize,
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mp_ptr tp)
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{
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mp_size_t size;
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mp_size_t an;
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mp_size_t bn;
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mp_size_t vn;
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ASSERT (n > 0);
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ASSERT (gn > 0);
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ASSERT (usize != 0);
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size = ABS (usize);
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ASSERT (size <= n);
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an = n;
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MPN_NORMALIZE (ap, an);
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if (an >= size)
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mpn_mul (tp, ap, an, up, size);
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else
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mpn_mul (tp, up, size, ap, an);
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size += an;
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size -= tp[size - 1] == 0;
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ASSERT (gn <= size);
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if (usize > 0)
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{
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/* |v| = -v = (u a - g) / b */
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ASSERT_NOCARRY (mpn_sub (tp, tp, size, gp, gn));
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MPN_NORMALIZE (tp, size);
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if (size == 0)
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return 0;
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}
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else
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{ /* usize < 0 */
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/* |v| = v = (c - u a) / b = (c + |u| a) / b */
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mp_limb_t cy = mpn_add (tp, tp, size, gp, gn);
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if (cy)
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tp[size++] = cy;
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}
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/* Now divide t / b. There must be no remainder */
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bn = n;
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MPN_NORMALIZE (bp, bn);
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ASSERT (size >= bn);
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vn = size + 1 - bn;
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ASSERT (vn <= n + 1);
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mpn_divexact (vp, tp, size, bp, bn);
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vn -= (vp[vn-1] == 0);
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return vn;
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}
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/* Temporary storage:
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Initial division: Quotient of at most an - n + 1 <= an limbs.
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Storage for u0 and u1: 2(n+1).
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Storage for hgcd matrix M, with input ceil(n/2): 5 * ceil(n/4)
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Storage for hgcd, input (n + 1)/2: 9 n/4 plus some.
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When hgcd succeeds: 1 + floor(3n/2) for adjusting a and b, and 2(n+1) for the cofactors.
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When hgcd fails: 2n + 1 for mpn_gcdext_subdiv_step, which is less.
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For the lehmer call after the loop, Let T denote
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GCDEXT_DC_THRESHOLD. For the gcdext_lehmer call, we need T each for
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u, a and b, and 4T+3 scratch space. Next, for compute_v, we need T
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for u, T+1 for v and 2T + 1 scratch space. In all, 7T + 3 is
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sufficient for both operations.
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*/
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/* Optimal choice of p seems difficult. In each iteration the division
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* of work between hgcd and the updates of u0 and u1 depends on the
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* current size of the u. It may be desirable to use a different
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* choice of p in each iteration. Also the input size seems to matter;
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* choosing p = n / 3 in the first iteration seems to improve
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* performance slightly for input size just above the threshold, but
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* degrade performance for larger inputs. */
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#define CHOOSE_P_1(n) ((n) / 2)
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#define CHOOSE_P_2(n) ((n) / 3)
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mp_size_t
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mpn_gcdext (mp_ptr gp, mp_ptr up, mp_size_t *usizep,
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mp_ptr ap, mp_size_t an, mp_ptr bp, mp_size_t n)
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{
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mp_size_t talloc;
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mp_size_t scratch;
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mp_size_t matrix_scratch;
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mp_size_t ualloc = n + 1;
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mp_size_t un;
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mp_ptr u0;
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mp_ptr u1;
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mp_ptr tp;
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TMP_DECL;
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ASSERT (an >= n);
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ASSERT (n > 0);
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TMP_MARK;
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/* FIXME: Check for small sizes first, before setting up temporary
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storage etc. */
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talloc = MPN_GCDEXT_LEHMER_N_ITCH(n);
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/* For initial division */
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scratch = an - n + 1;
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if (scratch > talloc)
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talloc = scratch;
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if (ABOVE_THRESHOLD (n, GCDEXT_DC_THRESHOLD))
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{
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/* For hgcd loop. */
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mp_size_t hgcd_scratch;
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mp_size_t update_scratch;
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mp_size_t p1 = CHOOSE_P_1 (n);
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mp_size_t p2 = CHOOSE_P_2 (n);
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mp_size_t min_p = MIN(p1, p2);
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mp_size_t max_p = MAX(p1, p2);
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matrix_scratch = MPN_HGCD_MATRIX_INIT_ITCH (n - min_p);
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hgcd_scratch = mpn_hgcd_itch (n - min_p);
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update_scratch = max_p + n - 1;
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scratch = matrix_scratch + MAX(hgcd_scratch, update_scratch);
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if (scratch > talloc)
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talloc = scratch;
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/* Final mpn_gcdext_lehmer_n call. Need space for u and for
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copies of a and b. */
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scratch = MPN_GCDEXT_LEHMER_N_ITCH (GCDEXT_DC_THRESHOLD)
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+ 3*GCDEXT_DC_THRESHOLD;
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if (scratch > talloc)
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talloc = scratch;
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/* Cofactors u0 and u1 */
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talloc += 2*(n+1);
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}
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tp = TMP_ALLOC_LIMBS(talloc);
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if (an > n)
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{
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mpn_tdiv_qr (tp, ap, 0, ap, an, bp, n);
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if (mpn_zero_p (ap, n))
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{
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MPN_COPY (gp, bp, n);
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*usizep = 0;
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TMP_FREE;
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return n;
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}
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}
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if (BELOW_THRESHOLD (n, GCDEXT_DC_THRESHOLD))
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{
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mp_size_t gn = mpn_gcdext_lehmer_n(gp, up, usizep, ap, bp, n, tp);
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TMP_FREE;
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return gn;
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}
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MPN_ZERO (tp, 2*ualloc);
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u0 = tp; tp += ualloc;
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u1 = tp; tp += ualloc;
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{
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/* For the first hgcd call, there are no u updates, and it makes
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some sense to use a different choice for p. */
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/* FIXME: We could trim use of temporary storage, since u0 and u1
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are not used yet. For the hgcd call, we could swap in the u0
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and u1 pointers for the relevant matrix elements. */
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struct hgcd_matrix M;
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mp_size_t p = CHOOSE_P_1 (n);
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mp_size_t nn;
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mpn_hgcd_matrix_init (&M, n - p, tp);
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nn = mpn_hgcd (ap + p, bp + p, n - p, &M, tp + matrix_scratch);
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if (nn > 0)
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{
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ASSERT (M.n <= (n - p - 1)/2);
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ASSERT (M.n + p <= (p + n - 1) / 2);
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/* Temporary storage 2 (p + M->n) <= p + n - 1 */
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n = mpn_hgcd_matrix_adjust (&M, p + nn, ap, bp, p, tp + matrix_scratch);
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MPN_COPY (u0, M.p[1][0], M.n);
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MPN_COPY (u1, M.p[1][1], M.n);
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un = M.n;
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while ( (u0[un-1] | u1[un-1] ) == 0)
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un--;
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}
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else
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{
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/* mpn_hgcd has failed. Then either one of a or b is very
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small, or the difference is very small. Perform one
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subtraction followed by one division. */
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mp_size_t gn;
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mp_size_t updated_un = 1;
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u1[0] = 1;
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/* Temporary storage 2n + 1 */
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n = mpn_gcdext_subdiv_step (gp, &gn, up, usizep, ap, bp, n,
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u0, u1, &updated_un, tp, tp + n);
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if (n == 0)
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{
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TMP_FREE;
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return gn;
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}
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un = updated_un;
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ASSERT (un < ualloc);
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}
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}
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while (ABOVE_THRESHOLD (n, GCDEXT_DC_THRESHOLD))
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{
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struct hgcd_matrix M;
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mp_size_t p = CHOOSE_P_2 (n);
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mp_size_t nn;
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mpn_hgcd_matrix_init (&M, n - p, tp);
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nn = mpn_hgcd (ap + p, bp + p, n - p, &M, tp + matrix_scratch);
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if (nn > 0)
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{
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mp_ptr t0;
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t0 = tp + matrix_scratch;
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ASSERT (M.n <= (n - p - 1)/2);
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ASSERT (M.n + p <= (p + n - 1) / 2);
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/* Temporary storage 2 (p + M->n) <= p + n - 1 */
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n = mpn_hgcd_matrix_adjust (&M, p + nn, ap, bp, p, t0);
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/* By the same analysis as for mpn_hgcd_matrix_mul */
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ASSERT (M.n + un <= ualloc);
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/* FIXME: This copying could be avoided by some swapping of
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* pointers. May need more temporary storage, though. */
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MPN_COPY (t0, u0, un);
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/* Temporary storage ualloc */
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un = hgcd_mul_matrix_vector (&M, u0, t0, u1, un, t0 + un);
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ASSERT (un < ualloc);
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ASSERT ( (u0[un-1] | u1[un-1]) > 0);
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}
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else
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{
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/* mpn_hgcd has failed. Then either one of a or b is very
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small, or the difference is very small. Perform one
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subtraction followed by one division. */
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mp_size_t gn;
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mp_size_t updated_un = un;
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/* Temporary storage 2n + 1 */
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n = mpn_gcdext_subdiv_step (gp, &gn, up, usizep, ap, bp, n,
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u0, u1, &updated_un, tp, tp + n);
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if (n == 0)
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{
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TMP_FREE;
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return gn;
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}
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un = updated_un;
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ASSERT (un < ualloc);
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}
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}
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if (UNLIKELY (mpn_cmp (ap, bp, n) == 0))
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{
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/* Must return the smallest cofactor, +u1 or -u0 */
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int c;
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MPN_COPY (gp, ap, n);
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MPN_CMP (c, u0, u1, un);
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/* c == 0 can happen only when A = (2k+1) G, B = 2 G. And in
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this case we choose the cofactor + 1, corresponding to G = A
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- k B, rather than -1, corresponding to G = - A + (k+1) B. */
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ASSERT (c != 0 || (un == 1 && u0[0] == 1 && u1[0] == 1));
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if (c < 0)
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{
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MPN_NORMALIZE (u0, un);
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MPN_COPY (up, u0, un);
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*usizep = -un;
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}
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else
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{
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MPN_NORMALIZE_NOT_ZERO (u1, un);
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MPN_COPY (up, u1, un);
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*usizep = un;
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}
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TMP_FREE;
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return n;
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}
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else if (mpn_zero_p (u0, un))
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{
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mp_size_t gn;
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ASSERT (un == 1);
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ASSERT (u1[0] == 1);
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/* g = u a + v b = (u u1 - v u0) A + (...) B = u A + (...) B */
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gn = mpn_gcdext_lehmer_n (gp, up, usizep, ap, bp, n, tp);
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TMP_FREE;
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return gn;
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}
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else
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{
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/* We have A = ... a + ... b
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B = u0 a + u1 b
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a = u1 A + ... B
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b = -u0 A + ... B
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with bounds
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|u0|, |u1| <= B / min(a, b)
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Compute g = u a + v b = (u u1 - v u0) A + (...) B
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Here, u, v are bounded by
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|u| <= b,
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|v| <= a
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*/
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mp_size_t u0n;
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mp_size_t u1n;
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mp_size_t lehmer_un;
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mp_size_t lehmer_vn;
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mp_size_t gn;
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mp_ptr lehmer_up;
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mp_ptr lehmer_vp;
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int negate;
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lehmer_up = tp; tp += n;
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/* Call mpn_gcdext_lehmer_n with copies of a and b. */
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MPN_COPY (tp, ap, n);
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MPN_COPY (tp + n, bp, n);
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gn = mpn_gcdext_lehmer_n (gp, lehmer_up, &lehmer_un, tp, tp + n, n, tp + 2*n);
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u0n = un;
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MPN_NORMALIZE (u0, u0n);
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if (lehmer_un == 0)
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{
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/* u == 0 ==> v = g / b == 1 ==> g = - u0 A + (...) B */
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MPN_COPY (up, u0, u0n);
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*usizep = -u0n;
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TMP_FREE;
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return gn;
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}
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lehmer_vp = tp;
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/* Compute v = (g - u a) / b */
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lehmer_vn = compute_v (lehmer_vp,
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ap, bp, n, gp, gn, lehmer_up, lehmer_un, tp + n + 1);
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if (lehmer_un > 0)
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negate = 0;
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else
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{
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lehmer_un = -lehmer_un;
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negate = 1;
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}
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u1n = un;
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MPN_NORMALIZE (u1, u1n);
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/* It's possible that u0 = 1, u1 = 0 */
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if (u1n == 0)
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{
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ASSERT (un == 1);
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ASSERT (u0[0] == 1);
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/* u1 == 0 ==> u u1 + v u0 = v */
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MPN_COPY (up, lehmer_vp, lehmer_vn);
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*usizep = negate ? lehmer_vn : - lehmer_vn;
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TMP_FREE;
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return gn;
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}
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ASSERT (lehmer_un + u1n <= ualloc);
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ASSERT (lehmer_vn + u0n <= ualloc);
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/* Now u0, u1, u are non-zero. We may still have v == 0 */
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/* Compute u u0 */
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if (lehmer_un <= u1n)
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/* Should be the common case */
|
|
mpn_mul (up, u1, u1n, lehmer_up, lehmer_un);
|
|
else
|
|
mpn_mul (up, lehmer_up, lehmer_un, u1, u1n);
|
|
|
|
un = u1n + lehmer_un;
|
|
un -= (up[un - 1] == 0);
|
|
|
|
if (lehmer_vn > 0)
|
|
{
|
|
mp_limb_t cy;
|
|
|
|
/* Overwrites old u1 value */
|
|
if (lehmer_vn <= u0n)
|
|
/* Should be the common case */
|
|
mpn_mul (u1, u0, u0n, lehmer_vp, lehmer_vn);
|
|
else
|
|
mpn_mul (u1, lehmer_vp, lehmer_vn, u0, u0n);
|
|
|
|
u1n = u0n + lehmer_vn;
|
|
u1n -= (u1[u1n - 1] == 0);
|
|
|
|
if (u1n <= un)
|
|
{
|
|
cy = mpn_add (up, up, un, u1, u1n);
|
|
}
|
|
else
|
|
{
|
|
cy = mpn_add (up, u1, u1n, up, un);
|
|
un = u1n;
|
|
}
|
|
up[un] = cy;
|
|
un += (cy != 0);
|
|
|
|
ASSERT (un < ualloc);
|
|
}
|
|
*usizep = negate ? -un : un;
|
|
|
|
TMP_FREE;
|
|
return gn;
|
|
}
|
|
}
|