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|
C x86_64/memxor3.asm
ifelse(`
Copyright (C) 2010, 2014 Niels Möller
This file is part of GNU Nettle.
GNU Nettle is free software: you can redistribute it and/or
modify it under the terms of either:
* the GNU Lesser General Public License as published by the Free
Software Foundation; either version 3 of the License, or (at your
option) any later version.
or
* the GNU General Public License as published by the Free
Software Foundation; either version 2 of the License, or (at your
option) any later version.
or both in parallel, as here.
GNU Nettle is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received copies of the GNU General Public License and
the GNU Lesser General Public License along with this program. If
not, see http://www.gnu.org/licenses/.
')
C Register usage:
define(`DST', `%rax') C Originally in %rdi
define(`AP', `%rsi')
define(`BP', `%rdx')
define(`N', `%r10')
define(`TMP', `%r8')
define(`TMP2', `%r9')
define(`CNT', `%rdi')
define(`S0', `%r11')
define(`S1', `%rdi') C Overlaps with CNT
define(`USE_SSE2', `no')
.file "memxor3.asm"
.text
C memxor3(void *dst, const void *a, const void *b, size_t n)
C %rdi %rsi %rdx %rcx
ALIGN(16)
PROLOGUE(nettle_memxor3)
W64_ENTRY(4, 0)
C %cl needed for shift count, so move away N
mov %rcx, N
.Lmemxor3_entry:
test N, N
C Get number of unaligned bytes at the end
C %rdi is used as CNT, %rax as DST and as return value
mov %rdi, %rax
jz .Ldone
add N, CNT
and $7, CNT
jz .Laligned
cmp $8, N
jc .Lfinal_next
C FIXME: Instead of this loop, could try cmov with memory
C destination, as a sequence of one 8-bit, one 16-bit and one
C 32-bit operations. (Except that cmov can't do 8-bit ops, so
C that step has to use a conditional).
.Lalign_loop:
sub $1, N
movb (AP, N), LREG(TMP)
xorb (BP, N), LREG(TMP)
movb LREG(TMP), (DST, N)
sub $1, CNT
jnz .Lalign_loop
.Laligned:
ifelse(USE_SSE2, yes, `
cmp $16, N
jnc .Lsse2_case
')
C Check for the case that AP and BP have the same alignment,
C but different from DST.
mov AP, TMP
sub BP, TMP
test $7, TMP
jnz .Lno_shift_case
mov AP, %rcx
sub DST, %rcx
and $7, %rcx
jz .Lno_shift_case
sub %rcx, AP
sub %rcx, BP
shl $3, %rcx
C Unrolling, with aligned values alternating in S0 and S1
test $8, N
jnz .Lshift_odd
mov (AP, N), S1
xor (BP, N), S1
jmp .Lshift_next
.Lshift_odd:
mov -8(AP, N), S1
mov (AP, N), S0
xor -8(BP, N), S1
xor (BP, N), S0
mov S1, TMP
shr %cl, TMP
neg %cl
shl %cl, S0
neg %cl
or S0, TMP
mov TMP, -8(DST, N)
sub $8, N
jz .Ldone
jmp .Lshift_next
ALIGN(16)
.Lshift_loop:
mov 8(AP, N), S0
xor 8(BP, N), S0
mov S0, TMP
shr %cl, TMP
neg %cl
shl %cl, S1
neg %cl
or S1, TMP
mov TMP, 8(DST, N)
mov (AP, N), S1
xor (BP, N), S1
mov S1, TMP
shr %cl, TMP
neg %cl
shl %cl, S0
neg %cl
or S0, TMP
mov TMP, (DST, N)
.Lshift_next:
sub $16, N
C FIXME: Handle the case N == 16 specially,
C like in the non-shifted case?
C ja .Lshift_loop
C jz .Ldone
jnc .Lshift_loop
add $15, N
jnc .Ldone
shr $3, %rcx
add %rcx, AP
add %rcx, BP
jmp .Lfinal_loop
.Lno_shift_case:
C Next destination word is -8(DST, N)
C Setup for unrolling
test $8, N
jz .Lword_next
sub $8, N
jz .Lone_word
mov (AP, N), TMP
xor (BP, N), TMP
mov TMP, (DST, N)
jmp .Lword_next
ALIGN(16)
.Lword_loop:
mov 8(AP, N), TMP
mov (AP, N), TMP2
xor 8(BP, N), TMP
xor (BP, N), TMP2
mov TMP, 8(DST, N)
mov TMP2, (DST, N)
.Lword_next:
sub $16, N
ja .Lword_loop C Not zero and no carry
jnz .Lfinal
C Final operation is word aligned
mov 8(AP, N), TMP
xor 8(BP, N), TMP
mov TMP, 8(DST, N)
.Lone_word:
mov (AP, N), TMP
xor (BP, N), TMP
mov TMP, (DST, N)
C ENTRY might have been 3 args, too, but it doesn't matter for the exit
W64_EXIT(4, 0)
ret
.Lfinal:
add $15, N
.Lfinal_loop:
movb (AP, N), LREG(TMP)
xorb (BP, N), LREG(TMP)
movb LREG(TMP), (DST, N)
.Lfinal_next:
sub $1, N
jnc .Lfinal_loop
.Ldone:
C ENTRY might have been 3 args, too, but it doesn't matter for the exit
W64_EXIT(4, 0)
ret
ifelse(USE_SSE2, yes, `
.Lsse2_case:
lea (DST, N), TMP
test $8, TMP
jz .Lsse2_next
sub $8, N
mov (AP, N), TMP
xor (BP, N), TMP
mov TMP, (DST, N)
jmp .Lsse2_next
ALIGN(16)
.Lsse2_loop:
movdqu (AP, N), %xmm0
movdqu (BP, N), %xmm1
pxor %xmm0, %xmm1
movdqa %xmm1, (DST, N)
.Lsse2_next:
sub $16, N
ja .Lsse2_loop
C FIXME: See if we can do a full word first, before the
C byte-wise final loop.
jnz .Lfinal
C Final operation is aligned
movdqu (AP), %xmm0
movdqu (BP), %xmm1
pxor %xmm0, %xmm1
movdqa %xmm1, (DST)
C ENTRY might have been 3 args, too, but it doesn't matter for the exit
W64_EXIT(4, 0)
ret
')
EPILOGUE(nettle_memxor3)
|
