dnl AMD64 mpn_copyd optimised for CPUs with fast SSE.
dnl Copyright 2003, 2005, 2007, 2011, 2012, 2015 Free Software Foundation,
dnl Inc.
dnl Contributed to the GNU project by Torbjörn Granlund.
dnl This file is part of the GNU MP Library.
dnl
dnl The GNU MP Library is free software; you can redistribute it and/or modify
dnl it under the terms of either:
dnl
dnl * the GNU Lesser General Public License as published by the Free
dnl Software Foundation; either version 3 of the License, or (at your
dnl option) any later version.
dnl
dnl or
dnl
dnl * the GNU General Public License as published by the Free Software
dnl Foundation; either version 2 of the License, or (at your option) any
dnl later version.
dnl
dnl or both in parallel, as here.
dnl
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 General Public License
dnl for more details.
dnl
dnl You should have received copies of the GNU General Public License and the
dnl GNU Lesser General Public License along with the GNU MP Library. If not,
dnl see https://www.gnu.org/licenses/.
include(`../config.m4')
C cycles/limb cycles/limb cycles/limb good
C aligned unaligned best seen for cpu?
C AMD K8,K9
C AMD K10 0.85 1.64 Y/N
C AMD bull 1.4 1.4 Y
C AMD pile 0.68 0.98 Y/N
C AMD steam
C AMD excavator
C AMD bobcat
C AMD jaguar 0.65 1.02 opt/0.93 Y/N
C Intel P4 2.3 2.3 Y
C Intel core 1.0 1.0 0.52/0.80 N
C Intel NHM 0.5 0.67 Y
C Intel SBR 0.51 0.75 opt/0.54 Y/N
C Intel IBR 0.50 0.57 opt/0.50 Y
C Intel HWL 0.50 0.57 opt/0.51 Y
C Intel BWL 0.55 0.62 opt/0.55 Y
C Intel atom
C Intel SLM 1.02 1.27 opt/1.04 Y/N
C VIA nano 1.16 5.16 Y/N
C We try to do as many 16-byte operations as possible. The top-most and
C bottom-most writes might need 8-byte operations. We can always write using
C aligned 16-byte operations, we read with both aligned and unaligned 16-byte
C operations.
C Instead of having separate loops for reading aligned and unaligned, we read
C using MOVDQU. This seems to work great except for core2; there performance
C doubles when reading using MOVDQA (for aligned source). It is unclear how to
C best handle the unaligned case there.
C INPUT PARAMETERS
define(`rp', `%rdi')
define(`up', `%rsi')
define(`n', `%rdx')
ABI_SUPPORT(DOS64)
ABI_SUPPORT(STD64)
dnl define(`movdqu', lddqu)
ASM_START()
TEXT
ALIGN(16)
PROLOGUE(mpn_copyd)
FUNC_ENTRY(3)
test n, n
jz L(don)
lea -16(rp,n,8), rp
lea -16(up,n,8), up
test $8, R8(rp) C is rp 16-byte aligned?
jz L(ali) C jump if rp aligned
mov 8(up), %rax
lea -8(up), up
mov %rax, 8(rp)
lea -8(rp), rp
dec n
sub $16, n
jc L(sma)
ALIGN(16)
L(top): movdqu (up), %xmm0
movdqu -16(up), %xmm1
movdqu -32(up), %xmm2
movdqu -48(up), %xmm3
movdqu -64(up), %xmm4
movdqu -80(up), %xmm5
movdqu -96(up), %xmm6
movdqu -112(up), %xmm7
lea -128(up), up
movdqa %xmm0, (rp)
movdqa %xmm1, -16(rp)
movdqa %xmm2, -32(rp)
movdqa %xmm3, -48(rp)
movdqa %xmm4, -64(rp)
movdqa %xmm5, -80(rp)
movdqa %xmm6, -96(rp)
movdqa %xmm7, -112(rp)
lea -128(rp), rp
L(ali): sub $16, n
jnc L(top)
L(sma): test $8, R8(n)
jz 1f
movdqu (up), %xmm0
movdqu -16(up), %xmm1
movdqu -32(up), %xmm2
movdqu -48(up), %xmm3
lea -64(up), up
movdqa %xmm0, (rp)
movdqa %xmm1, -16(rp)
movdqa %xmm2, -32(rp)
movdqa %xmm3, -48(rp)
lea -64(rp), rp
1:
test $4, R8(n)
jz 1f
movdqu (up), %xmm0
movdqu -16(up), %xmm1
lea -32(up), up
movdqa %xmm0, (rp)
movdqa %xmm1, -16(rp)
lea -32(rp), rp
1:
test $2, R8(n)
jz 1f
movdqu (up), %xmm0
lea -16(up), up
movdqa %xmm0, (rp)
lea -16(rp), rp
1:
test $1, R8(n)
jz 1f
mov 8(up), %r8
mov %r8, 8(rp)
1:
L(don): FUNC_EXIT()
ret
EPILOGUE()