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361 lines
10 KiB
C
361 lines
10 KiB
C
/* mpn_mul_n -- Multiply two natural numbers of length n.
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Copyright (C) 1991-2024 Free Software 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 2.1 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; see the file COPYING.LIB. If not, see
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<https://www.gnu.org/licenses/>. */
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#include <gmp.h>
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#include "gmp-impl.h"
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/* Multiply the natural numbers u (pointed to by UP) and v (pointed to by VP),
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both with SIZE limbs, and store the result at PRODP. 2 * SIZE limbs are
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always stored. Return the most significant limb.
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Argument constraints:
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1. PRODP != UP and PRODP != VP, i.e. the destination
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must be distinct from the multiplier and the multiplicand. */
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/* If KARATSUBA_THRESHOLD is not already defined, define it to a
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value which is good on most machines. */
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#ifndef KARATSUBA_THRESHOLD
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#define KARATSUBA_THRESHOLD 32
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#endif
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/* The code can't handle KARATSUBA_THRESHOLD smaller than 2. */
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#if KARATSUBA_THRESHOLD < 2
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#undef KARATSUBA_THRESHOLD
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#define KARATSUBA_THRESHOLD 2
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#endif
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/* Handle simple cases with traditional multiplication.
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This is the most critical code of multiplication. All multiplies rely
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on this, both small and huge. Small ones arrive here immediately. Huge
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ones arrive here as this is the base case for Karatsuba's recursive
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algorithm below. */
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void
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impn_mul_n_basecase (mp_ptr prodp, mp_srcptr up, mp_srcptr vp, mp_size_t size)
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{
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mp_size_t i;
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mp_limb_t cy_limb;
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mp_limb_t v_limb;
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/* Multiply by the first limb in V separately, as the result can be
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stored (not added) to PROD. We also avoid a loop for zeroing. */
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v_limb = vp[0];
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if (v_limb <= 1)
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{
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if (v_limb == 1)
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MPN_COPY (prodp, up, size);
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else
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MPN_ZERO (prodp, size);
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cy_limb = 0;
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}
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else
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cy_limb = mpn_mul_1 (prodp, up, size, v_limb);
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prodp[size] = cy_limb;
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prodp++;
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/* For each iteration in the outer loop, multiply one limb from
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U with one limb from V, and add it to PROD. */
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for (i = 1; i < size; i++)
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{
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v_limb = vp[i];
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if (v_limb <= 1)
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{
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cy_limb = 0;
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if (v_limb == 1)
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cy_limb = mpn_add_n (prodp, prodp, up, size);
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}
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else
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cy_limb = mpn_addmul_1 (prodp, up, size, v_limb);
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prodp[size] = cy_limb;
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prodp++;
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}
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}
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void
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impn_mul_n (mp_ptr prodp,
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mp_srcptr up, mp_srcptr vp, mp_size_t size, mp_ptr tspace)
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{
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if ((size & 1) != 0)
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{
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/* The size is odd, the code code below doesn't handle that.
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Multiply the least significant (size - 1) limbs with a recursive
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call, and handle the most significant limb of S1 and S2
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separately. */
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/* A slightly faster way to do this would be to make the Karatsuba
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code below behave as if the size were even, and let it check for
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odd size in the end. I.e., in essence move this code to the end.
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Doing so would save us a recursive call, and potentially make the
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stack grow a lot less. */
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mp_size_t esize = size - 1; /* even size */
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mp_limb_t cy_limb;
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MPN_MUL_N_RECURSE (prodp, up, vp, esize, tspace);
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cy_limb = mpn_addmul_1 (prodp + esize, up, esize, vp[esize]);
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prodp[esize + esize] = cy_limb;
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cy_limb = mpn_addmul_1 (prodp + esize, vp, size, up[esize]);
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prodp[esize + size] = cy_limb;
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}
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else
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{
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/* Anatolij Alekseevich Karatsuba's divide-and-conquer algorithm.
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Split U in two pieces, U1 and U0, such that
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U = U0 + U1*(B**n),
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and V in V1 and V0, such that
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V = V0 + V1*(B**n).
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UV is then computed recursively using the identity
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2n n n n
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UV = (B + B )U V + B (U -U )(V -V ) + (B + 1)U V
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1 1 1 0 0 1 0 0
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Where B = 2**BITS_PER_MP_LIMB. */
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mp_size_t hsize = size >> 1;
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mp_limb_t cy;
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int negflg;
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/*** Product H. ________________ ________________
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|_____U1 x V1____||____U0 x V0_____| */
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/* Put result in upper part of PROD and pass low part of TSPACE
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as new TSPACE. */
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MPN_MUL_N_RECURSE (prodp + size, up + hsize, vp + hsize, hsize, tspace);
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/*** Product M. ________________
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|_(U1-U0)(V0-V1)_| */
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if (mpn_cmp (up + hsize, up, hsize) >= 0)
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{
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mpn_sub_n (prodp, up + hsize, up, hsize);
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negflg = 0;
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}
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else
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{
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mpn_sub_n (prodp, up, up + hsize, hsize);
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negflg = 1;
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}
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if (mpn_cmp (vp + hsize, vp, hsize) >= 0)
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{
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mpn_sub_n (prodp + hsize, vp + hsize, vp, hsize);
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negflg ^= 1;
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}
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else
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{
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mpn_sub_n (prodp + hsize, vp, vp + hsize, hsize);
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/* No change of NEGFLG. */
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}
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/* Read temporary operands from low part of PROD.
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Put result in low part of TSPACE using upper part of TSPACE
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as new TSPACE. */
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MPN_MUL_N_RECURSE (tspace, prodp, prodp + hsize, hsize, tspace + size);
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/*** Add/copy product H. */
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MPN_COPY (prodp + hsize, prodp + size, hsize);
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cy = mpn_add_n (prodp + size, prodp + size, prodp + size + hsize, hsize);
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/*** Add product M (if NEGFLG M is a negative number). */
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if (negflg)
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cy -= mpn_sub_n (prodp + hsize, prodp + hsize, tspace, size);
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else
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cy += mpn_add_n (prodp + hsize, prodp + hsize, tspace, size);
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/*** Product L. ________________ ________________
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|________________||____U0 x V0_____| */
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/* Read temporary operands from low part of PROD.
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Put result in low part of TSPACE using upper part of TSPACE
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as new TSPACE. */
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MPN_MUL_N_RECURSE (tspace, up, vp, hsize, tspace + size);
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/*** Add/copy Product L (twice). */
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cy += mpn_add_n (prodp + hsize, prodp + hsize, tspace, size);
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if (cy)
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mpn_add_1 (prodp + hsize + size, prodp + hsize + size, hsize, cy);
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MPN_COPY (prodp, tspace, hsize);
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cy = mpn_add_n (prodp + hsize, prodp + hsize, tspace + hsize, hsize);
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if (cy)
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mpn_add_1 (prodp + size, prodp + size, size, 1);
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}
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}
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void
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impn_sqr_n_basecase (mp_ptr prodp, mp_srcptr up, mp_size_t size)
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{
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mp_size_t i;
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mp_limb_t cy_limb;
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mp_limb_t v_limb;
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/* Multiply by the first limb in V separately, as the result can be
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stored (not added) to PROD. We also avoid a loop for zeroing. */
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v_limb = up[0];
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if (v_limb <= 1)
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{
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if (v_limb == 1)
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MPN_COPY (prodp, up, size);
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else
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MPN_ZERO (prodp, size);
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cy_limb = 0;
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}
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else
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cy_limb = mpn_mul_1 (prodp, up, size, v_limb);
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prodp[size] = cy_limb;
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prodp++;
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/* For each iteration in the outer loop, multiply one limb from
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U with one limb from V, and add it to PROD. */
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for (i = 1; i < size; i++)
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{
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v_limb = up[i];
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if (v_limb <= 1)
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{
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cy_limb = 0;
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if (v_limb == 1)
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cy_limb = mpn_add_n (prodp, prodp, up, size);
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}
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else
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cy_limb = mpn_addmul_1 (prodp, up, size, v_limb);
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prodp[size] = cy_limb;
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prodp++;
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}
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}
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void
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impn_sqr_n (mp_ptr prodp,
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mp_srcptr up, mp_size_t size, mp_ptr tspace)
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{
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if ((size & 1) != 0)
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{
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/* The size is odd, the code code below doesn't handle that.
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Multiply the least significant (size - 1) limbs with a recursive
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call, and handle the most significant limb of S1 and S2
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separately. */
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/* A slightly faster way to do this would be to make the Karatsuba
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code below behave as if the size were even, and let it check for
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odd size in the end. I.e., in essence move this code to the end.
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Doing so would save us a recursive call, and potentially make the
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stack grow a lot less. */
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mp_size_t esize = size - 1; /* even size */
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mp_limb_t cy_limb;
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MPN_SQR_N_RECURSE (prodp, up, esize, tspace);
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cy_limb = mpn_addmul_1 (prodp + esize, up, esize, up[esize]);
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prodp[esize + esize] = cy_limb;
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cy_limb = mpn_addmul_1 (prodp + esize, up, size, up[esize]);
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prodp[esize + size] = cy_limb;
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}
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else
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{
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mp_size_t hsize = size >> 1;
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mp_limb_t cy;
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/*** Product H. ________________ ________________
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|_____U1 x U1____||____U0 x U0_____| */
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/* Put result in upper part of PROD and pass low part of TSPACE
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as new TSPACE. */
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MPN_SQR_N_RECURSE (prodp + size, up + hsize, hsize, tspace);
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/*** Product M. ________________
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|_(U1-U0)(U0-U1)_| */
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if (mpn_cmp (up + hsize, up, hsize) >= 0)
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{
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mpn_sub_n (prodp, up + hsize, up, hsize);
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}
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else
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{
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mpn_sub_n (prodp, up, up + hsize, hsize);
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}
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/* Read temporary operands from low part of PROD.
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Put result in low part of TSPACE using upper part of TSPACE
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as new TSPACE. */
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MPN_SQR_N_RECURSE (tspace, prodp, hsize, tspace + size);
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/*** Add/copy product H. */
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MPN_COPY (prodp + hsize, prodp + size, hsize);
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cy = mpn_add_n (prodp + size, prodp + size, prodp + size + hsize, hsize);
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/*** Add product M (if NEGFLG M is a negative number). */
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cy -= mpn_sub_n (prodp + hsize, prodp + hsize, tspace, size);
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/*** Product L. ________________ ________________
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|________________||____U0 x U0_____| */
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/* Read temporary operands from low part of PROD.
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Put result in low part of TSPACE using upper part of TSPACE
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as new TSPACE. */
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MPN_SQR_N_RECURSE (tspace, up, hsize, tspace + size);
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/*** Add/copy Product L (twice). */
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cy += mpn_add_n (prodp + hsize, prodp + hsize, tspace, size);
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if (cy)
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mpn_add_1 (prodp + hsize + size, prodp + hsize + size, hsize, cy);
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MPN_COPY (prodp, tspace, hsize);
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cy = mpn_add_n (prodp + hsize, prodp + hsize, tspace + hsize, hsize);
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if (cy)
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mpn_add_1 (prodp + size, prodp + size, size, 1);
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}
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}
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/* This should be made into an inline function in gmp.h. */
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void
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mpn_mul_n (mp_ptr prodp, mp_srcptr up, mp_srcptr vp, mp_size_t size)
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{
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TMP_DECL (marker);
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TMP_MARK (marker);
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if (up == vp)
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{
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if (size < KARATSUBA_THRESHOLD)
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{
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impn_sqr_n_basecase (prodp, up, size);
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}
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else
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{
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mp_ptr tspace;
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tspace = (mp_ptr) TMP_ALLOC (2 * size * BYTES_PER_MP_LIMB);
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impn_sqr_n (prodp, up, size, tspace);
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}
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}
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else
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{
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if (size < KARATSUBA_THRESHOLD)
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{
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impn_mul_n_basecase (prodp, up, vp, size);
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}
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else
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{
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mp_ptr tspace;
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tspace = (mp_ptr) TMP_ALLOC (2 * size * BYTES_PER_MP_LIMB);
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impn_mul_n (prodp, up, vp, size, tspace);
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}
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}
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TMP_FREE (marker);
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}
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