ff4ff35918
Red Bear OS is a full fork. All sources must be available from git clone with zero network access. Removed gitignore rules that excluded fetched source trees under recipes/*/source/, local/recipes/kde/*/source/, local/recipes/qt/*/source/, and vendor source trees. Build artifacts (target/, build/, source.tar, *.o, *.so) remain excluded. 127291 files added — kernel, relibc, base, bootloader, pkgar, all KDE/Qt frameworks, mesa, wayland, DRM drivers, and every other recipe source.
442 lines
15 KiB
C
442 lines
15 KiB
C
/* mpn_mul -- Multiply two natural numbers.
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Contributed to the GNU project by Torbjorn Granlund.
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Copyright 1991, 1993, 1994, 1996, 1997, 1999-2003, 2005-2007, 2009, 2010, 2012,
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2014, 2019 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 either:
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* the GNU Lesser General Public License as published by the Free
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Software Foundation; either version 3 of the License, or (at your
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option) any later version.
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or
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* the GNU General Public License as published by the Free Software
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Foundation; either version 2 of the License, or (at your option) any
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later version.
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or both in parallel, as here.
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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 General Public License
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for more details.
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You should have received copies of the GNU General Public License and the
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GNU Lesser General Public License along with the GNU MP Library. If not,
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see https://www.gnu.org/licenses/. */
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#include "gmp-impl.h"
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#ifndef MUL_BASECASE_MAX_UN
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#define MUL_BASECASE_MAX_UN 500
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#endif
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/* Areas where the different toom algorithms can be called (extracted
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from the t-toom*.c files, and ignoring small constant offsets):
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1/6 1/5 1/4 4/13 1/3 3/8 2/5 5/11 1/2 3/5 2/3 3/4 4/5 1 vn/un
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4/7 6/7
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6/11
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|--------------------| toom22 (small)
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|| toom22 (large)
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|xxxx| toom22 called
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|-------------------------------------| toom32
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|xxxxxxxxxxxxxxxx| | toom32 called
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|------------| toom33
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|x| toom33 called
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|---------------------------------| | toom42
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|xxxxxxxxxxxxxxxxxxxxxxxx| | toom42 called
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|--------------------| toom43
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|xxxxxxxxxx| toom43 called
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|-----------------------------| toom52 (unused)
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|--------| toom44
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|xxxxxxxx| toom44 called
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|--------------------| | toom53
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|xxxxxx| toom53 called
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|-------------------------| toom62 (unused)
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|----------------| toom54 (unused)
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|--------------------| toom63
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|xxxxxxxxx| | toom63 called
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|---------------------------------| toom6h
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|xxxxxxxx| toom6h called
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|-------------------------| toom8h (32 bit)
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|------------------------------------------| toom8h (64 bit)
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|xxxxxxxx| toom8h called
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*/
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#define TOOM33_OK(an,bn) (6 + 2 * an < 3 * bn)
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#define TOOM44_OK(an,bn) (12 + 3 * an < 4 * bn)
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/* Multiply the natural numbers u (pointed to by UP, with UN limbs) and v
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(pointed to by VP, with VN limbs), and store the result at PRODP. The
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result is UN + VN limbs. Return the most significant limb of the result.
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NOTE: The space pointed to by PRODP is overwritten before finished with U
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and V, so overlap is an error.
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Argument constraints:
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1. UN >= VN.
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2. PRODP != UP and PRODP != VP, i.e. the destination must be distinct from
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the multiplier and the multiplicand. */
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/*
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* The cutoff lines in the toomX2 and toomX3 code are now exactly between the
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ideal lines of the surrounding algorithms. Is that optimal?
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* The toomX3 code now uses a structure similar to the one of toomX2, except
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that it loops longer in the unbalanced case. The result is that the
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remaining area might have un < vn. Should we fix the toomX2 code in a
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similar way?
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* The toomX3 code is used for the largest non-FFT unbalanced operands. It
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therefore calls mpn_mul recursively for certain cases.
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* Allocate static temp space using THRESHOLD variables (except for toom44
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when !WANT_FFT). That way, we can typically have no TMP_ALLOC at all.
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* We sort ToomX2 algorithms together, assuming the toom22, toom32, toom42
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have the same vn threshold. This is not true, we should actually use
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mul_basecase for slightly larger operands for toom32 than for toom22, and
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even larger for toom42.
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* That problem is even more prevalent for toomX3. We therefore use special
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THRESHOLD variables there.
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*/
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mp_limb_t
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mpn_mul (mp_ptr prodp,
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mp_srcptr up, mp_size_t un,
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mp_srcptr vp, mp_size_t vn)
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{
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ASSERT (un >= vn);
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ASSERT (vn >= 1);
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ASSERT (! MPN_OVERLAP_P (prodp, un+vn, up, un));
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ASSERT (! MPN_OVERLAP_P (prodp, un+vn, vp, vn));
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if (BELOW_THRESHOLD (un, MUL_TOOM22_THRESHOLD))
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{
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/* When un (and thus vn) is below the toom22 range, do mul_basecase.
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Test un and not vn here not to thwart the un >> vn code below.
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This special case is not necessary, but cuts the overhead for the
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smallest operands. */
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mpn_mul_basecase (prodp, up, un, vp, vn);
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}
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else if (un == vn)
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{
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mpn_mul_n (prodp, up, vp, un);
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}
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else if (vn < MUL_TOOM22_THRESHOLD)
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{ /* plain schoolbook multiplication */
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/* Unless un is very large, or else if have an applicable mpn_mul_N,
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perform basecase multiply directly. */
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if (un <= MUL_BASECASE_MAX_UN
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#if HAVE_NATIVE_mpn_mul_2
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|| vn <= 2
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#else
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|| vn == 1
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#endif
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)
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mpn_mul_basecase (prodp, up, un, vp, vn);
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else
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{
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/* We have un >> MUL_BASECASE_MAX_UN > vn. For better memory
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locality, split up[] into MUL_BASECASE_MAX_UN pieces and multiply
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these pieces with the vp[] operand. After each such partial
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multiplication (but the last) we copy the most significant vn
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limbs into a temporary buffer since that part would otherwise be
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overwritten by the next multiplication. After the next
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multiplication, we add it back. This illustrates the situation:
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-->vn<--
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_____________________|
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X /|
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/XX__________________/ |
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_____________________ |
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X / |
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/XX__________________/ |
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_____________________ |
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/ / |
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/____________________/ |
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==================================================================
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The parts marked with X are the parts whose sums are copied into
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the temporary buffer. */
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mp_limb_t tp[MUL_TOOM22_THRESHOLD_LIMIT];
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mp_limb_t cy;
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ASSERT (MUL_TOOM22_THRESHOLD <= MUL_TOOM22_THRESHOLD_LIMIT);
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mpn_mul_basecase (prodp, up, MUL_BASECASE_MAX_UN, vp, vn);
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prodp += MUL_BASECASE_MAX_UN;
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MPN_COPY (tp, prodp, vn); /* preserve high triangle */
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up += MUL_BASECASE_MAX_UN;
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un -= MUL_BASECASE_MAX_UN;
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while (un > MUL_BASECASE_MAX_UN)
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{
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mpn_mul_basecase (prodp, up, MUL_BASECASE_MAX_UN, vp, vn);
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cy = mpn_add_n (prodp, prodp, tp, vn); /* add back preserved triangle */
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mpn_incr_u (prodp + vn, cy);
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prodp += MUL_BASECASE_MAX_UN;
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MPN_COPY (tp, prodp, vn); /* preserve high triangle */
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up += MUL_BASECASE_MAX_UN;
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un -= MUL_BASECASE_MAX_UN;
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}
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if (un > vn)
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{
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mpn_mul_basecase (prodp, up, un, vp, vn);
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}
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else
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{
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ASSERT (un > 0);
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mpn_mul_basecase (prodp, vp, vn, up, un);
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}
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cy = mpn_add_n (prodp, prodp, tp, vn); /* add back preserved triangle */
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mpn_incr_u (prodp + vn, cy);
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}
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}
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else if (BELOW_THRESHOLD (vn, MUL_TOOM33_THRESHOLD))
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{
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/* Use ToomX2 variants */
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mp_ptr scratch;
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TMP_SDECL; TMP_SMARK;
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#define ITCH_TOOMX2 (9 * vn / 2 + GMP_NUMB_BITS * 2)
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scratch = TMP_SALLOC_LIMBS (ITCH_TOOMX2);
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ASSERT (mpn_toom22_mul_itch ((5*vn-1)/4, vn) <= ITCH_TOOMX2); /* 5vn/2+ */
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ASSERT (mpn_toom32_mul_itch ((7*vn-1)/4, vn) <= ITCH_TOOMX2); /* 7vn/6+ */
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ASSERT (mpn_toom42_mul_itch (3 * vn - 1, vn) <= ITCH_TOOMX2); /* 9vn/2+ */
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#undef ITCH_TOOMX2
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/* FIXME: This condition (repeated in the loop below) leaves from a vn*vn
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square to a (3vn-1)*vn rectangle. Leaving such a rectangle is hardly
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wise; we would get better balance by slightly moving the bound. We
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will sometimes end up with un < vn, like in the X3 arm below. */
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if (un >= 3 * vn)
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{
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mp_limb_t cy;
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mp_ptr ws;
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/* The maximum ws usage is for the mpn_mul result. */
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ws = TMP_SALLOC_LIMBS (4 * vn);
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mpn_toom42_mul (prodp, up, 2 * vn, vp, vn, scratch);
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un -= 2 * vn;
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up += 2 * vn;
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prodp += 2 * vn;
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while (un >= 3 * vn)
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{
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mpn_toom42_mul (ws, up, 2 * vn, vp, vn, scratch);
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un -= 2 * vn;
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up += 2 * vn;
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, 2 * vn);
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mpn_incr_u (prodp + vn, cy);
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prodp += 2 * vn;
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}
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/* vn <= un < 3vn */
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if (4 * un < 5 * vn)
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mpn_toom22_mul (ws, up, un, vp, vn, scratch);
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else if (4 * un < 7 * vn)
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mpn_toom32_mul (ws, up, un, vp, vn, scratch);
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else
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mpn_toom42_mul (ws, up, un, vp, vn, scratch);
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, un);
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mpn_incr_u (prodp + vn, cy);
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}
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else
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{
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if (4 * un < 5 * vn)
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mpn_toom22_mul (prodp, up, un, vp, vn, scratch);
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else if (4 * un < 7 * vn)
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mpn_toom32_mul (prodp, up, un, vp, vn, scratch);
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else
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mpn_toom42_mul (prodp, up, un, vp, vn, scratch);
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}
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TMP_SFREE;
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}
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else if (BELOW_THRESHOLD ((un + vn) >> 1, MUL_FFT_THRESHOLD) ||
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BELOW_THRESHOLD (3 * vn, MUL_FFT_THRESHOLD))
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{
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/* Handle the largest operands that are not in the FFT range. The 2nd
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condition makes very unbalanced operands avoid the FFT code (except
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perhaps as coefficient products of the Toom code. */
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if (BELOW_THRESHOLD (vn, MUL_TOOM44_THRESHOLD) || !TOOM44_OK (un, vn))
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{
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/* Use ToomX3 variants */
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mp_ptr scratch;
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TMP_DECL; TMP_MARK;
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#define ITCH_TOOMX3 (4 * vn + GMP_NUMB_BITS)
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scratch = TMP_ALLOC_LIMBS (ITCH_TOOMX3);
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ASSERT (mpn_toom33_mul_itch ((7*vn-1)/6, vn) <= ITCH_TOOMX3); /* 7vn/2+ */
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ASSERT (mpn_toom43_mul_itch ((3*vn-1)/2, vn) <= ITCH_TOOMX3); /* 9vn/4+ */
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ASSERT (mpn_toom32_mul_itch ((7*vn-1)/4, vn) <= ITCH_TOOMX3); /* 7vn/6+ */
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ASSERT (mpn_toom53_mul_itch ((11*vn-1)/6, vn) <= ITCH_TOOMX3); /* 11vn/3+ */
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ASSERT (mpn_toom42_mul_itch ((5*vn-1)/2, vn) <= ITCH_TOOMX3); /* 15vn/4+ */
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ASSERT (mpn_toom63_mul_itch ((5*vn-1)/2, vn) <= ITCH_TOOMX3); /* 15vn/4+ */
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#undef ITCH_TOOMX3
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if (2 * un >= 5 * vn)
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{
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mp_limb_t cy;
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mp_ptr ws;
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/* The maximum ws usage is for the mpn_mul result. */
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ws = TMP_ALLOC_LIMBS (7 * vn >> 1);
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if (BELOW_THRESHOLD (vn, MUL_TOOM42_TO_TOOM63_THRESHOLD))
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mpn_toom42_mul (prodp, up, 2 * vn, vp, vn, scratch);
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else
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mpn_toom63_mul (prodp, up, 2 * vn, vp, vn, scratch);
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un -= 2 * vn;
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up += 2 * vn;
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prodp += 2 * vn;
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while (2 * un >= 5 * vn) /* un >= 2.5vn */
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{
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if (BELOW_THRESHOLD (vn, MUL_TOOM42_TO_TOOM63_THRESHOLD))
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mpn_toom42_mul (ws, up, 2 * vn, vp, vn, scratch);
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else
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mpn_toom63_mul (ws, up, 2 * vn, vp, vn, scratch);
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un -= 2 * vn;
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up += 2 * vn;
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, 2 * vn);
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mpn_incr_u (prodp + vn, cy);
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prodp += 2 * vn;
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}
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/* vn / 2 <= un < 2.5vn */
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if (un < vn)
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mpn_mul (ws, vp, vn, up, un);
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else
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mpn_mul (ws, up, un, vp, vn);
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, un);
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mpn_incr_u (prodp + vn, cy);
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}
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else
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{
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if (6 * un < 7 * vn)
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mpn_toom33_mul (prodp, up, un, vp, vn, scratch);
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else if (2 * un < 3 * vn)
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{
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if (BELOW_THRESHOLD (vn, MUL_TOOM32_TO_TOOM43_THRESHOLD))
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mpn_toom32_mul (prodp, up, un, vp, vn, scratch);
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else
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mpn_toom43_mul (prodp, up, un, vp, vn, scratch);
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}
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else if (6 * un < 11 * vn)
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{
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if (4 * un < 7 * vn)
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{
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if (BELOW_THRESHOLD (vn, MUL_TOOM32_TO_TOOM53_THRESHOLD))
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mpn_toom32_mul (prodp, up, un, vp, vn, scratch);
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else
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mpn_toom53_mul (prodp, up, un, vp, vn, scratch);
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}
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else
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{
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if (BELOW_THRESHOLD (vn, MUL_TOOM42_TO_TOOM53_THRESHOLD))
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mpn_toom42_mul (prodp, up, un, vp, vn, scratch);
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else
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mpn_toom53_mul (prodp, up, un, vp, vn, scratch);
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}
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}
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else
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{
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if (BELOW_THRESHOLD (vn, MUL_TOOM42_TO_TOOM63_THRESHOLD))
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mpn_toom42_mul (prodp, up, un, vp, vn, scratch);
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else
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mpn_toom63_mul (prodp, up, un, vp, vn, scratch);
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}
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}
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TMP_FREE;
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}
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else
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{
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mp_ptr scratch;
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TMP_DECL; TMP_MARK;
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if (BELOW_THRESHOLD (vn, MUL_TOOM6H_THRESHOLD))
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{
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scratch = TMP_SALLOC_LIMBS (mpn_toom44_mul_itch (un, vn));
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mpn_toom44_mul (prodp, up, un, vp, vn, scratch);
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}
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else if (BELOW_THRESHOLD (vn, MUL_TOOM8H_THRESHOLD))
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{
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scratch = TMP_SALLOC_LIMBS (mpn_toom6h_mul_itch (un, vn));
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mpn_toom6h_mul (prodp, up, un, vp, vn, scratch);
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}
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else
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{
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scratch = TMP_ALLOC_LIMBS (mpn_toom8h_mul_itch (un, vn));
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mpn_toom8h_mul (prodp, up, un, vp, vn, scratch);
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}
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TMP_FREE;
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}
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}
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else
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{
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if (un >= 8 * vn)
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{
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mp_limb_t cy;
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mp_ptr ws;
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TMP_DECL; TMP_MARK;
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/* The maximum ws usage is for the mpn_mul result. */
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ws = TMP_BALLOC_LIMBS (9 * vn >> 1);
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mpn_fft_mul (prodp, up, 3 * vn, vp, vn);
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un -= 3 * vn;
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up += 3 * vn;
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prodp += 3 * vn;
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while (2 * un >= 7 * vn) /* un >= 3.5vn */
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{
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mpn_fft_mul (ws, up, 3 * vn, vp, vn);
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un -= 3 * vn;
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up += 3 * vn;
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, 3 * vn);
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mpn_incr_u (prodp + vn, cy);
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prodp += 3 * vn;
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}
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/* vn / 2 <= un < 3.5vn */
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if (un < vn)
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mpn_mul (ws, vp, vn, up, un);
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else
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mpn_mul (ws, up, un, vp, vn);
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cy = mpn_add_n (prodp, prodp, ws, vn);
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MPN_COPY (prodp + vn, ws + vn, un);
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mpn_incr_u (prodp + vn, cy);
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TMP_FREE;
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}
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else
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mpn_fft_mul (prodp, up, un, vp, vn);
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|
}
|
|
|
|
return prodp[un + vn - 1]; /* historic */
|
|
}
|