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dnl AMD64 mpn_addlsh_n -- rp[] = up[] + (vp[] << k)
dnl AMD64 mpn_rsblsh_n -- rp[] = (vp[] << k) - up[]
dnl Optimised for Nehalem.
dnl Contributed to the GNU project by Torbjorn Granlund.
dnl Copyright 2011 Free Software Foundation, Inc.
dnl This file is part of the GNU MP Library.
dnl The GNU MP Library is free software; you can redistribute it and/or modify
dnl it under the terms of the GNU Lesser General Public License as published
dnl by the Free Software Foundation; either version 3 of the License, or (at
dnl your option) any later version.
dnl The GNU MP Library is distributed in the hope that it will be useful, but
dnl WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
dnl or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
dnl License for more details.
dnl You should have received a copy of the GNU Lesser General Public License
dnl along with the GNU MP Library. If not, see http://www.gnu.org/licenses/.
include(`../config.m4')
C cycles/limb
C AMD K8,K9 ?
C AMD K10 4.75
C Intel P4 ?
C Intel core2 2.8-3
C Intel NHM 2.8
C Intel SBR 3.55
C Intel atom ?
C VIA nano ?
C The inner-loop probably runs close to optimally on Nehalem (using 4-way
C unrolling). The rest of the code is quite crude, and could perhaps be made
C both smaller and faster.
C INPUT PARAMETERS
define(`rp', `%rdi')
define(`up', `%rsi')
define(`vp', `%rdx')
define(`n', `%rcx')
define(`cnt', `%r8')
define(`cy', `%r9') C for _nc variant
ifdef(`OPERATION_addlsh_n', `
define(ADDSUB, add)
define(ADCSBB, adc)
define(IFRSB, )
define(func_n, mpn_addlsh_n)
define(func_nc, mpn_addlsh_nc)')
ifdef(`OPERATION_rsblsh_n', `
define(ADDSUB, sub)
define(ADCSBB, sbb)
define(IFRSB, `$1')
define(func_n, mpn_rsblsh_n)
define(func_nc, mpn_rsblsh_nc)')
C mpn_rsblsh_nc removed below, its idea of carry-in is inconsistent with
C refmpn_rsblsh_nc
MULFUNC_PROLOGUE(mpn_addlsh_n mpn_addlsh_nc mpn_rsblsh_n)
ASM_START()
TEXT
ALIGN(32)
PROLOGUE(func_n)
push %rbx
xor R32(%rbx), R32(%rbx) C clear CF save register
L(ent): push %rbp
mov R32(n), R32(%rbp)
mov n, %rax
mov R32(cnt), R32(%rcx)
neg R32(%rcx)
lea -8(up,%rax,8), up
lea -8(vp,%rax,8), vp
lea -40(rp,%rax,8), rp
neg %rax
and $3, R32(%rbp)
jz L(b0)
cmp $2, R32(%rbp)
jc L(b1)
jz L(b2)
L(b3): xor R32(%r9), R32(%r9)
mov 8(vp,%rax,8), %r10
mov 16(vp,%rax,8), %r11
shrd %cl, %r10, %r9
shrd %cl, %r11, %r10
add R32(%rbx), R32(%rbx)
ADCSBB 8(up,%rax,8), %r9
mov 24(vp,%rax,8), %r8
ADCSBB 16(up,%rax,8), %r10
sbb R32(%rbx), R32(%rbx)
add $3, %rax
jmp L(lo3)
L(b0): mov 8(vp,%rax,8), %r9
xor R32(%r8), R32(%r8)
shrd %cl, %r9, %r8
mov 16(vp,%rax,8), %r10
mov 24(vp,%rax,8), %r11
shrd %cl, %r10, %r9
shrd %cl, %r11, %r10
add R32(%rbx), R32(%rbx)
ADCSBB 8(up,%rax,8), %r8
mov %r8, 40(rp,%rax,8) C offset 40
ADCSBB 16(up,%rax,8), %r9
mov 32(vp,%rax,8), %r8
ADCSBB 24(up,%rax,8), %r10
sbb R32(%rbx), R32(%rbx)
add $4, %rax
jmp L(lo0)
L(b1): mov 8(vp,%rax,8), %r8
add $1, %rax
jz L(1)
mov 8(vp,%rax,8), %r9
xor R32(%rbp), R32(%rbp)
jmp L(lo1)
L(1): xor R32(%r11), R32(%r11)
jmp L(wd1)
L(b2): xor %r10, %r10
mov 8(vp,%rax,8), %r11
shrd %cl, %r11, %r10
add R32(%rbx), R32(%rbx)
mov 16(vp,%rax,8), %r8
ADCSBB 8(up,%rax,8), %r10
sbb R32(%rbx), R32(%rbx)
add $2, %rax
jz L(end)
ALIGN(16)
L(top): mov 8(vp,%rax,8), %r9
mov %r11, %rbp
L(lo2): mov %r10, 24(rp,%rax,8) C offset 24
L(lo1): shrd %cl, %r8, %rbp
shrd %cl, %r9, %r8
mov 16(vp,%rax,8), %r10
mov 24(vp,%rax,8), %r11
shrd %cl, %r10, %r9
shrd %cl, %r11, %r10
add R32(%rbx), R32(%rbx)
ADCSBB (up,%rax,8), %rbp
ADCSBB 8(up,%rax,8), %r8
mov %r8, 40(rp,%rax,8) C offset 40
ADCSBB 16(up,%rax,8), %r9
mov 32(vp,%rax,8), %r8
ADCSBB 24(up,%rax,8), %r10
sbb R32(%rbx), R32(%rbx)
add $4, %rax
mov %rbp, (rp,%rax,8) C offset 32
L(lo0):
L(lo3): mov %r9, 16(rp,%rax,8) C offset 48
jnz L(top)
L(end): mov %r10, 24(rp,%rax,8)
L(wd1): shrd %cl, %r8, %r11
add R32(%rbx), R32(%rbx)
ADCSBB (up,%rax,8), %r11
mov %r11, 32(rp,%rax,8) C offset 32
adc R32(%rax), R32(%rax) C rax is zero after loop
shr R8(%rcx), %r8
ADDSUB %r8, %rax
IFRSB( neg %rax)
pop %rbp
pop %rbx
ret
EPILOGUE()
PROLOGUE(func_nc)
push %rbx
neg cy
sbb R32(%rbx), R32(%rbx) C initialise CF save register
jmp L(ent)
EPILOGUE()
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