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#! /usr/bin/env perl
# Copyright 2010-2016 The OpenSSL Project Authors. All Rights Reserved.
#
# Licensed under the OpenSSL license (the "License"). You may not use
# this file except in compliance with the License. You can obtain a copy
# in the file LICENSE in the source distribution or at
# https://www.openssl.org/source/license.html
#
# ====================================================================
# Written by Andy Polyakov <appro@openssl.org> for the OpenSSL
# project. The module is, however, dual licensed under OpenSSL and
# CRYPTOGAMS licenses depending on where you obtain it. For further
# details see http://www.openssl.org/~appro/cryptogams/.
# ====================================================================
#
# March, June 2010
#
# The module implements "4-bit" GCM GHASH function and underlying
# single multiplication operation in GF(2^128). "4-bit" means that
# it uses 256 bytes per-key table [+128 bytes shared table]. GHASH
# function features so called "528B" variant utilizing additional
# 256+16 bytes of per-key storage [+512 bytes shared table].
# Performance results are for this streamed GHASH subroutine and are
# expressed in cycles per processed byte, less is better:
#
# gcc 3.4.x(*) assembler
#
# P4 28.6 14.0 +100%
# Opteron 19.3 7.7 +150%
# Core2 17.8 8.1(**) +120%
# Atom 31.6 16.8 +88%
# VIA Nano 21.8 10.1 +115%
#
# (*) comparison is not completely fair, because C results are
# for vanilla "256B" implementation, while assembler results
# are for "528B";-)
# (**) it's mystery [to me] why Core2 result is not same as for
# Opteron;
# May 2010
#
# Add PCLMULQDQ version performing at 2.02 cycles per processed byte.
# See ghash-x86.pl for background information and details about coding
# techniques.
#
# Special thanks to David Woodhouse for providing access to a
# Westmere-based system on behalf of Intel Open Source Technology Centre.
# December 2012
#
# Overhaul: aggregate Karatsuba post-processing, improve ILP in
# reduction_alg9, increase reduction aggregate factor to 4x. As for
# the latter. ghash-x86.pl discusses that it makes lesser sense to
# increase aggregate factor. Then why increase here? Critical path
# consists of 3 independent pclmulqdq instructions, Karatsuba post-
# processing and reduction. "On top" of this we lay down aggregated
# multiplication operations, triplets of independent pclmulqdq's. As
# issue rate for pclmulqdq is limited, it makes lesser sense to
# aggregate more multiplications than it takes to perform remaining
# non-multiplication operations. 2x is near-optimal coefficient for
# contemporary Intel CPUs (therefore modest improvement coefficient),
# but not for Bulldozer. Latter is because logical SIMD operations
# are twice as slow in comparison to Intel, so that critical path is
# longer. A CPU with higher pclmulqdq issue rate would also benefit
# from higher aggregate factor...
#
# Westmere 1.78(+13%)
# Sandy Bridge 1.80(+8%)
# Ivy Bridge 1.80(+7%)
# Haswell 0.55(+93%) (if system doesn't support AVX)
# Broadwell 0.45(+110%)(if system doesn't support AVX)
# Skylake 0.44(+110%)(if system doesn't support AVX)
# Bulldozer 1.49(+27%)
# Silvermont 2.88(+13%)
# Knights L 2.12(-) (if system doesn't support AVX)
# Goldmont 1.08(+24%)
# March 2013
#
# ... 8x aggregate factor AVX code path is using reduction algorithm
# suggested by Shay Gueron[1]. Even though contemporary AVX-capable
# CPUs such as Sandy and Ivy Bridge can execute it, the code performs
# sub-optimally in comparison to above mentioned version. But thanks
# to Ilya Albrekht and Max Locktyukhin of Intel Corp. we knew that
# it performs in 0.41 cycles per byte on Haswell processor, in
# 0.29 on Broadwell, and in 0.36 on Skylake.
#
# Knights Landing achieves 1.09 cpb.
#
# [1] http://rt.openssl.org/Ticket/Display.html?id=2900&user=guest&pass=guest
# This file was patched in BoringSSL to remove the variable-time 4-bit
# implementation.
$flavour = shift;
$output = shift;
if ($flavour =~ /\./) { $output = $flavour; undef $flavour; }
$win64=0; $win64=1 if ($flavour =~ /[nm]asm|mingw64/ || $output =~ /\.asm$/);
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
( $xlate="${dir}x86_64-xlate.pl" and -f $xlate ) or
( $xlate="${dir}../../../perlasm/x86_64-xlate.pl" and -f $xlate) or
die "can't locate x86_64-xlate.pl";
# See the notes about |$avx| in aesni-gcm-x86_64.pl; otherwise tags will be
# computed incorrectly.
#
# In upstream, this is controlled by shelling out to the compiler to check
# versions, but BoringSSL is intended to be used with pre-generated perlasm
# output, so this isn't useful anyway.
$avx = 1;
open OUT,"| \"$^X\" \"$xlate\" $flavour \"$output\"";
*STDOUT=*OUT;
$do4xaggr=1;
$code=<<___;
.text
.extern OPENSSL_ia32cap_P
___
######################################################################
# PCLMULQDQ version.
@_4args=$win64? ("%rcx","%rdx","%r8", "%r9") : # Win64 order
("%rdi","%rsi","%rdx","%rcx"); # Unix order
($Xi,$Xhi)=("%xmm0","%xmm1"); $Hkey="%xmm2";
($T1,$T2,$T3)=("%xmm3","%xmm4","%xmm5");
sub clmul64x64_T2 { # minimal register pressure
my ($Xhi,$Xi,$Hkey,$HK)=@_;
if (!defined($HK)) { $HK = $T2;
$code.=<<___;
movdqa $Xi,$Xhi #
pshufd \$0b01001110,$Xi,$T1
pshufd \$0b01001110,$Hkey,$T2
pxor $Xi,$T1 #
pxor $Hkey,$T2
___
} else {
$code.=<<___;
movdqa $Xi,$Xhi #
pshufd \$0b01001110,$Xi,$T1
pxor $Xi,$T1 #
___
}
$code.=<<___;
pclmulqdq \$0x00,$Hkey,$Xi #######
pclmulqdq \$0x11,$Hkey,$Xhi #######
pclmulqdq \$0x00,$HK,$T1 #######
pxor $Xi,$T1 #
pxor $Xhi,$T1 #
movdqa $T1,$T2 #
psrldq \$8,$T1
pslldq \$8,$T2 #
pxor $T1,$Xhi
pxor $T2,$Xi #
___
}
sub reduction_alg9 { # 17/11 times faster than Intel version
my ($Xhi,$Xi) = @_;
$code.=<<___;
# 1st phase
movdqa $Xi,$T2 #
movdqa $Xi,$T1
psllq \$5,$Xi
pxor $Xi,$T1 #
psllq \$1,$Xi
pxor $T1,$Xi #
psllq \$57,$Xi #
movdqa $Xi,$T1 #
pslldq \$8,$Xi
psrldq \$8,$T1 #
pxor $T2,$Xi
pxor $T1,$Xhi #
# 2nd phase
movdqa $Xi,$T2
psrlq \$1,$Xi
pxor $T2,$Xhi #
pxor $Xi,$T2
psrlq \$5,$Xi
pxor $T2,$Xi #
psrlq \$1,$Xi #
pxor $Xhi,$Xi #
___
}
{ my ($Htbl,$Xip)=@_4args;
my $HK="%xmm6";
$code.=<<___;
.globl gcm_init_clmul
.type gcm_init_clmul,\@abi-omnipotent
.align 16
gcm_init_clmul:
.cfi_startproc
.L_init_clmul:
___
$code.=<<___ if ($win64);
.LSEH_begin_gcm_init_clmul:
# I can't trust assembler to use specific encoding:-(
.byte 0x48,0x83,0xec,0x18 #sub $0x18,%rsp
.byte 0x0f,0x29,0x34,0x24 #movaps %xmm6,(%rsp)
___
$code.=<<___;
movdqu ($Xip),$Hkey
pshufd \$0b01001110,$Hkey,$Hkey # dword swap
# <<1 twist
pshufd \$0b11111111,$Hkey,$T2 # broadcast uppermost dword
movdqa $Hkey,$T1
psllq \$1,$Hkey
pxor $T3,$T3 #
psrlq \$63,$T1
pcmpgtd $T2,$T3 # broadcast carry bit
pslldq \$8,$T1
por $T1,$Hkey # H<<=1
# magic reduction
pand .L0x1c2_polynomial(%rip),$T3
pxor $T3,$Hkey # if(carry) H^=0x1c2_polynomial
# calculate H^2
pshufd \$0b01001110,$Hkey,$HK
movdqa $Hkey,$Xi
pxor $Hkey,$HK
___
&clmul64x64_T2 ($Xhi,$Xi,$Hkey,$HK);
&reduction_alg9 ($Xhi,$Xi);
$code.=<<___;
pshufd \$0b01001110,$Hkey,$T1
pshufd \$0b01001110,$Xi,$T2
pxor $Hkey,$T1 # Karatsuba pre-processing
movdqu $Hkey,0x00($Htbl) # save H
pxor $Xi,$T2 # Karatsuba pre-processing
movdqu $Xi,0x10($Htbl) # save H^2
palignr \$8,$T1,$T2 # low part is H.lo^H.hi...
movdqu $T2,0x20($Htbl) # save Karatsuba "salt"
___
if ($do4xaggr) {
&clmul64x64_T2 ($Xhi,$Xi,$Hkey,$HK); # H^3
&reduction_alg9 ($Xhi,$Xi);
$code.=<<___;
movdqa $Xi,$T3
___
&clmul64x64_T2 ($Xhi,$Xi,$Hkey,$HK); # H^4
&reduction_alg9 ($Xhi,$Xi);
$code.=<<___;
pshufd \$0b01001110,$T3,$T1
pshufd \$0b01001110,$Xi,$T2
pxor $T3,$T1 # Karatsuba pre-processing
movdqu $T3,0x30($Htbl) # save H^3
pxor $Xi,$T2 # Karatsuba pre-processing
movdqu $Xi,0x40($Htbl) # save H^4
palignr \$8,$T1,$T2 # low part is H^3.lo^H^3.hi...
movdqu $T2,0x50($Htbl) # save Karatsuba "salt"
___
}
$code.=<<___ if ($win64);
movaps (%rsp),%xmm6
lea 0x18(%rsp),%rsp
.LSEH_end_gcm_init_clmul:
___
$code.=<<___;
ret
.cfi_endproc
.size gcm_init_clmul,.-gcm_init_clmul
___
}
{ my ($Xip,$Htbl)=@_4args;
$code.=<<___;
.globl gcm_gmult_clmul
.type gcm_gmult_clmul,\@abi-omnipotent
.align 16
gcm_gmult_clmul:
.cfi_startproc
.L_gmult_clmul:
movdqu ($Xip),$Xi
movdqa .Lbswap_mask(%rip),$T3
movdqu ($Htbl),$Hkey
movdqu 0x20($Htbl),$T2
pshufb $T3,$Xi
___
&clmul64x64_T2 ($Xhi,$Xi,$Hkey,$T2);
$code.=<<___ if (0 || (&reduction_alg9($Xhi,$Xi)&&0));
# experimental alternative. special thing about is that there
# no dependency between the two multiplications...
mov \$`0xE1<<1`,%eax
mov \$0xA040608020C0E000,%r10 # ((7..0)·0xE0)&0xff
mov \$0x07,%r11d
movq %rax,$T1
movq %r10,$T2
movq %r11,$T3 # borrow $T3
pand $Xi,$T3
pshufb $T3,$T2 # ($Xi&7)·0xE0
movq %rax,$T3
pclmulqdq \$0x00,$Xi,$T1 # ·(0xE1<<1)
pxor $Xi,$T2
pslldq \$15,$T2
paddd $T2,$T2 # <<(64+56+1)
pxor $T2,$Xi
pclmulqdq \$0x01,$T3,$Xi
movdqa .Lbswap_mask(%rip),$T3 # reload $T3
psrldq \$1,$T1
pxor $T1,$Xhi
pslldq \$7,$Xi
pxor $Xhi,$Xi
___
$code.=<<___;
pshufb $T3,$Xi
movdqu $Xi,($Xip)
ret
.cfi_endproc
.size gcm_gmult_clmul,.-gcm_gmult_clmul
___
}
{ my ($Xip,$Htbl,$inp,$len)=@_4args;
my ($Xln,$Xmn,$Xhn,$Hkey2,$HK) = map("%xmm$_",(3..7));
my ($T1,$T2,$T3)=map("%xmm$_",(8..10));
$code.=<<___;
.globl gcm_ghash_clmul
.type gcm_ghash_clmul,\@abi-omnipotent
.align 32
gcm_ghash_clmul:
.cfi_startproc
.L_ghash_clmul:
___
$code.=<<___ if ($win64);
lea -0x88(%rsp),%rax
.LSEH_begin_gcm_ghash_clmul:
# I can't trust assembler to use specific encoding:-(
.byte 0x48,0x8d,0x60,0xe0 #lea -0x20(%rax),%rsp
.byte 0x0f,0x29,0x70,0xe0 #movaps %xmm6,-0x20(%rax)
.byte 0x0f,0x29,0x78,0xf0 #movaps %xmm7,-0x10(%rax)
.byte 0x44,0x0f,0x29,0x00 #movaps %xmm8,0(%rax)
.byte 0x44,0x0f,0x29,0x48,0x10 #movaps %xmm9,0x10(%rax)
.byte 0x44,0x0f,0x29,0x50,0x20 #movaps %xmm10,0x20(%rax)
.byte 0x44,0x0f,0x29,0x58,0x30 #movaps %xmm11,0x30(%rax)
.byte 0x44,0x0f,0x29,0x60,0x40 #movaps %xmm12,0x40(%rax)
.byte 0x44,0x0f,0x29,0x68,0x50 #movaps %xmm13,0x50(%rax)
.byte 0x44,0x0f,0x29,0x70,0x60 #movaps %xmm14,0x60(%rax)
.byte 0x44,0x0f,0x29,0x78,0x70 #movaps %xmm15,0x70(%rax)
___
$code.=<<___;
movdqa .Lbswap_mask(%rip),$T3
movdqu ($Xip),$Xi
movdqu ($Htbl),$Hkey
movdqu 0x20($Htbl),$HK
pshufb $T3,$Xi
sub \$0x10,$len
jz .Lodd_tail
movdqu 0x10($Htbl),$Hkey2
___
if ($do4xaggr) {
my ($Xl,$Xm,$Xh,$Hkey3,$Hkey4)=map("%xmm$_",(11..15));
$code.=<<___;
leaq OPENSSL_ia32cap_P(%rip),%rax
mov 4(%rax),%eax
cmp \$0x30,$len
jb .Lskip4x
and \$`1<<26|1<<22`,%eax # isolate MOVBE+XSAVE
cmp \$`1<<22`,%eax # check for MOVBE without XSAVE
je .Lskip4x
sub \$0x30,$len
mov \$0xA040608020C0E000,%rax # ((7..0)·0xE0)&0xff
movdqu 0x30($Htbl),$Hkey3
movdqu 0x40($Htbl),$Hkey4
#######
# Xi+4 =[(H*Ii+3) + (H^2*Ii+2) + (H^3*Ii+1) + H^4*(Ii+Xi)] mod P
#
movdqu 0x30($inp),$Xln
movdqu 0x20($inp),$Xl
pshufb $T3,$Xln
pshufb $T3,$Xl
movdqa $Xln,$Xhn
pshufd \$0b01001110,$Xln,$Xmn
pxor $Xln,$Xmn
pclmulqdq \$0x00,$Hkey,$Xln
pclmulqdq \$0x11,$Hkey,$Xhn
pclmulqdq \$0x00,$HK,$Xmn
movdqa $Xl,$Xh
pshufd \$0b01001110,$Xl,$Xm
pxor $Xl,$Xm
pclmulqdq \$0x00,$Hkey2,$Xl
pclmulqdq \$0x11,$Hkey2,$Xh
pclmulqdq \$0x10,$HK,$Xm
xorps $Xl,$Xln
xorps $Xh,$Xhn
movups 0x50($Htbl),$HK
xorps $Xm,$Xmn
movdqu 0x10($inp),$Xl
movdqu 0($inp),$T1
pshufb $T3,$Xl
pshufb $T3,$T1
movdqa $Xl,$Xh
pshufd \$0b01001110,$Xl,$Xm
pxor $T1,$Xi
pxor $Xl,$Xm
pclmulqdq \$0x00,$Hkey3,$Xl
movdqa $Xi,$Xhi
pshufd \$0b01001110,$Xi,$T1
pxor $Xi,$T1
pclmulqdq \$0x11,$Hkey3,$Xh
pclmulqdq \$0x00,$HK,$Xm
xorps $Xl,$Xln
xorps $Xh,$Xhn
lea 0x40($inp),$inp
sub \$0x40,$len
jc .Ltail4x
jmp .Lmod4_loop
.align 32
.Lmod4_loop:
pclmulqdq \$0x00,$Hkey4,$Xi
xorps $Xm,$Xmn
movdqu 0x30($inp),$Xl
pshufb $T3,$Xl
pclmulqdq \$0x11,$Hkey4,$Xhi
xorps $Xln,$Xi
movdqu 0x20($inp),$Xln
movdqa $Xl,$Xh
pclmulqdq \$0x10,$HK,$T1
pshufd \$0b01001110,$Xl,$Xm
xorps $Xhn,$Xhi
pxor $Xl,$Xm
pshufb $T3,$Xln
movups 0x20($Htbl),$HK
xorps $Xmn,$T1
pclmulqdq \$0x00,$Hkey,$Xl
pshufd \$0b01001110,$Xln,$Xmn
pxor $Xi,$T1 # aggregated Karatsuba post-processing
movdqa $Xln,$Xhn
pxor $Xhi,$T1 #
pxor $Xln,$Xmn
movdqa $T1,$T2 #
pclmulqdq \$0x11,$Hkey,$Xh
pslldq \$8,$T1
psrldq \$8,$T2 #
pxor $T1,$Xi
movdqa .L7_mask(%rip),$T1
pxor $T2,$Xhi #
movq %rax,$T2
pand $Xi,$T1 # 1st phase
pshufb $T1,$T2 #
pxor $Xi,$T2 #
pclmulqdq \$0x00,$HK,$Xm
psllq \$57,$T2 #
movdqa $T2,$T1 #
pslldq \$8,$T2
pclmulqdq \$0x00,$Hkey2,$Xln
psrldq \$8,$T1 #
pxor $T2,$Xi
pxor $T1,$Xhi #
movdqu 0($inp),$T1
movdqa $Xi,$T2 # 2nd phase
psrlq \$1,$Xi
pclmulqdq \$0x11,$Hkey2,$Xhn
xorps $Xl,$Xln
movdqu 0x10($inp),$Xl
pshufb $T3,$Xl
pclmulqdq \$0x10,$HK,$Xmn
xorps $Xh,$Xhn
movups 0x50($Htbl),$HK
pshufb $T3,$T1
pxor $T2,$Xhi #
pxor $Xi,$T2
psrlq \$5,$Xi
movdqa $Xl,$Xh
pxor $Xm,$Xmn
pshufd \$0b01001110,$Xl,$Xm
pxor $T2,$Xi #
pxor $T1,$Xhi
pxor $Xl,$Xm
pclmulqdq \$0x00,$Hkey3,$Xl
psrlq \$1,$Xi #
pxor $Xhi,$Xi #
movdqa $Xi,$Xhi
pclmulqdq \$0x11,$Hkey3,$Xh
xorps $Xl,$Xln
pshufd \$0b01001110,$Xi,$T1
pxor $Xi,$T1
pclmulqdq \$0x00,$HK,$Xm
xorps $Xh,$Xhn
lea 0x40($inp),$inp
sub \$0x40,$len
jnc .Lmod4_loop
.Ltail4x:
pclmulqdq \$0x00,$Hkey4,$Xi
pclmulqdq \$0x11,$Hkey4,$Xhi
pclmulqdq \$0x10,$HK,$T1
xorps $Xm,$Xmn
xorps $Xln,$Xi
xorps $Xhn,$Xhi
pxor $Xi,$Xhi # aggregated Karatsuba post-processing
pxor $Xmn,$T1
pxor $Xhi,$T1 #
pxor $Xi,$Xhi
movdqa $T1,$T2 #
psrldq \$8,$T1
pslldq \$8,$T2 #
pxor $T1,$Xhi
pxor $T2,$Xi #
___
&reduction_alg9($Xhi,$Xi);
$code.=<<___;
add \$0x40,$len
jz .Ldone
movdqu 0x20($Htbl),$HK
sub \$0x10,$len
jz .Lodd_tail
.Lskip4x:
___
}
$code.=<<___;
#######
# Xi+2 =[H*(Ii+1 + Xi+1)] mod P =
# [(H*Ii+1) + (H*Xi+1)] mod P =
# [(H*Ii+1) + H^2*(Ii+Xi)] mod P
#
movdqu ($inp),$T1 # Ii
movdqu 16($inp),$Xln # Ii+1
pshufb $T3,$T1
pshufb $T3,$Xln
pxor $T1,$Xi # Ii+Xi
movdqa $Xln,$Xhn
pshufd \$0b01001110,$Xln,$Xmn
pxor $Xln,$Xmn
pclmulqdq \$0x00,$Hkey,$Xln
pclmulqdq \$0x11,$Hkey,$Xhn
pclmulqdq \$0x00,$HK,$Xmn
lea 32($inp),$inp # i+=2
nop
sub \$0x20,$len
jbe .Leven_tail
nop
jmp .Lmod_loop
.align 32
.Lmod_loop:
movdqa $Xi,$Xhi
movdqa $Xmn,$T1
pshufd \$0b01001110,$Xi,$Xmn #
pxor $Xi,$Xmn #
pclmulqdq \$0x00,$Hkey2,$Xi
pclmulqdq \$0x11,$Hkey2,$Xhi
pclmulqdq \$0x10,$HK,$Xmn
pxor $Xln,$Xi # (H*Ii+1) + H^2*(Ii+Xi)
pxor $Xhn,$Xhi
movdqu ($inp),$T2 # Ii
pxor $Xi,$T1 # aggregated Karatsuba post-processing
pshufb $T3,$T2
movdqu 16($inp),$Xln # Ii+1
pxor $Xhi,$T1
pxor $T2,$Xhi # "Ii+Xi", consume early
pxor $T1,$Xmn
pshufb $T3,$Xln
movdqa $Xmn,$T1 #
psrldq \$8,$T1
pslldq \$8,$Xmn #
pxor $T1,$Xhi
pxor $Xmn,$Xi #
movdqa $Xln,$Xhn #
movdqa $Xi,$T2 # 1st phase
movdqa $Xi,$T1
psllq \$5,$Xi
pxor $Xi,$T1 #
pclmulqdq \$0x00,$Hkey,$Xln #######
psllq \$1,$Xi
pxor $T1,$Xi #
psllq \$57,$Xi #
movdqa $Xi,$T1 #
pslldq \$8,$Xi
psrldq \$8,$T1 #
pxor $T2,$Xi
pshufd \$0b01001110,$Xhn,$Xmn
pxor $T1,$Xhi #
pxor $Xhn,$Xmn #
movdqa $Xi,$T2 # 2nd phase
psrlq \$1,$Xi
pclmulqdq \$0x11,$Hkey,$Xhn #######
pxor $T2,$Xhi #
pxor $Xi,$T2
psrlq \$5,$Xi
pxor $T2,$Xi #
lea 32($inp),$inp
psrlq \$1,$Xi #
pclmulqdq \$0x00,$HK,$Xmn #######
pxor $Xhi,$Xi #
sub \$0x20,$len
ja .Lmod_loop
.Leven_tail:
movdqa $Xi,$Xhi
movdqa $Xmn,$T1
pshufd \$0b01001110,$Xi,$Xmn #
pxor $Xi,$Xmn #
pclmulqdq \$0x00,$Hkey2,$Xi
pclmulqdq \$0x11,$Hkey2,$Xhi
pclmulqdq \$0x10,$HK,$Xmn
pxor $Xln,$Xi # (H*Ii+1) + H^2*(Ii+Xi)
pxor $Xhn,$Xhi
pxor $Xi,$T1
pxor $Xhi,$T1
pxor $T1,$Xmn
movdqa $Xmn,$T1 #
psrldq \$8,$T1
pslldq \$8,$Xmn #
pxor $T1,$Xhi
pxor $Xmn,$Xi #
___
&reduction_alg9 ($Xhi,$Xi);
$code.=<<___;
test $len,$len
jnz .Ldone
.Lodd_tail:
movdqu ($inp),$T1 # Ii
pshufb $T3,$T1
pxor $T1,$Xi # Ii+Xi
___
&clmul64x64_T2 ($Xhi,$Xi,$Hkey,$HK); # H*(Ii+Xi)
&reduction_alg9 ($Xhi,$Xi);
$code.=<<___;
.Ldone:
pshufb $T3,$Xi
movdqu $Xi,($Xip)
___
$code.=<<___ if ($win64);
movaps (%rsp),%xmm6
movaps 0x10(%rsp),%xmm7
movaps 0x20(%rsp),%xmm8
movaps 0x30(%rsp),%xmm9
movaps 0x40(%rsp),%xmm10
movaps 0x50(%rsp),%xmm11
movaps 0x60(%rsp),%xmm12
movaps 0x70(%rsp),%xmm13
movaps 0x80(%rsp),%xmm14
movaps 0x90(%rsp),%xmm15
lea 0xa8(%rsp),%rsp
.LSEH_end_gcm_ghash_clmul:
___
$code.=<<___;
ret
.cfi_endproc
.size gcm_ghash_clmul,.-gcm_ghash_clmul
___
}
$code.=<<___;
.globl gcm_init_avx
.type gcm_init_avx,\@abi-omnipotent
.align 32
gcm_init_avx:
.cfi_startproc
___
if ($avx) {
my ($Htbl,$Xip)=@_4args;
my $HK="%xmm6";
$code.=<<___ if ($win64);
.LSEH_begin_gcm_init_avx:
# I can't trust assembler to use specific encoding:-(
.byte 0x48,0x83,0xec,0x18 #sub $0x18,%rsp
.byte 0x0f,0x29,0x34,0x24 #movaps %xmm6,(%rsp)
___
$code.=<<___;
vzeroupper
vmovdqu ($Xip),$Hkey
vpshufd \$0b01001110,$Hkey,$Hkey # dword swap
# <<1 twist
vpshufd \$0b11111111,$Hkey,$T2 # broadcast uppermost dword
vpsrlq \$63,$Hkey,$T1
vpsllq \$1,$Hkey,$Hkey
vpxor $T3,$T3,$T3 #
vpcmpgtd $T2,$T3,$T3 # broadcast carry bit
vpslldq \$8,$T1,$T1
vpor $T1,$Hkey,$Hkey # H<<=1
# magic reduction
vpand .L0x1c2_polynomial(%rip),$T3,$T3
vpxor $T3,$Hkey,$Hkey # if(carry) H^=0x1c2_polynomial
vpunpckhqdq $Hkey,$Hkey,$HK
vmovdqa $Hkey,$Xi
vpxor $Hkey,$HK,$HK
mov \$4,%r10 # up to H^8
jmp .Linit_start_avx
___
sub clmul64x64_avx {
my ($Xhi,$Xi,$Hkey,$HK)=@_;
if (!defined($HK)) { $HK = $T2;
$code.=<<___;
vpunpckhqdq $Xi,$Xi,$T1
vpunpckhqdq $Hkey,$Hkey,$T2
vpxor $Xi,$T1,$T1 #
vpxor $Hkey,$T2,$T2
___
} else {
$code.=<<___;
vpunpckhqdq $Xi,$Xi,$T1
vpxor $Xi,$T1,$T1 #
___
}
$code.=<<___;
vpclmulqdq \$0x11,$Hkey,$Xi,$Xhi #######
vpclmulqdq \$0x00,$Hkey,$Xi,$Xi #######
vpclmulqdq \$0x00,$HK,$T1,$T1 #######
vpxor $Xi,$Xhi,$T2 #
vpxor $T2,$T1,$T1 #
vpslldq \$8,$T1,$T2 #
vpsrldq \$8,$T1,$T1
vpxor $T2,$Xi,$Xi #
vpxor $T1,$Xhi,$Xhi
___
}
sub reduction_avx {
my ($Xhi,$Xi) = @_;
$code.=<<___;
vpsllq \$57,$Xi,$T1 # 1st phase
vpsllq \$62,$Xi,$T2
vpxor $T1,$T2,$T2 #
vpsllq \$63,$Xi,$T1
vpxor $T1,$T2,$T2 #
vpslldq \$8,$T2,$T1 #
vpsrldq \$8,$T2,$T2
vpxor $T1,$Xi,$Xi #
vpxor $T2,$Xhi,$Xhi
vpsrlq \$1,$Xi,$T2 # 2nd phase
vpxor $Xi,$Xhi,$Xhi
vpxor $T2,$Xi,$Xi #
vpsrlq \$5,$T2,$T2
vpxor $T2,$Xi,$Xi #
vpsrlq \$1,$Xi,$Xi #
vpxor $Xhi,$Xi,$Xi #
___
}
$code.=<<___;
.align 32
.Linit_loop_avx:
vpalignr \$8,$T1,$T2,$T3 # low part is H.lo^H.hi...
vmovdqu $T3,-0x10($Htbl) # save Karatsuba "salt"
___
&clmul64x64_avx ($Xhi,$Xi,$Hkey,$HK); # calculate H^3,5,7
&reduction_avx ($Xhi,$Xi);
$code.=<<___;
.Linit_start_avx:
vmovdqa $Xi,$T3
___
&clmul64x64_avx ($Xhi,$Xi,$Hkey,$HK); # calculate H^2,4,6,8
&reduction_avx ($Xhi,$Xi);
$code.=<<___;
vpshufd \$0b01001110,$T3,$T1
vpshufd \$0b01001110,$Xi,$T2
vpxor $T3,$T1,$T1 # Karatsuba pre-processing
vmovdqu $T3,0x00($Htbl) # save H^1,3,5,7
vpxor $Xi,$T2,$T2 # Karatsuba pre-processing
vmovdqu $Xi,0x10($Htbl) # save H^2,4,6,8
lea 0x30($Htbl),$Htbl
sub \$1,%r10
jnz .Linit_loop_avx
vpalignr \$8,$T2,$T1,$T3 # last "salt" is flipped
vmovdqu $T3,-0x10($Htbl)
vzeroupper
___
$code.=<<___ if ($win64);
movaps (%rsp),%xmm6
lea 0x18(%rsp),%rsp
.LSEH_end_gcm_init_avx:
___
$code.=<<___;
ret
.cfi_endproc
.size gcm_init_avx,.-gcm_init_avx
___
} else {
$code.=<<___;
jmp .L_init_clmul
.size gcm_init_avx,.-gcm_init_avx
___
}
$code.=<<___;
.globl gcm_gmult_avx
.type gcm_gmult_avx,\@abi-omnipotent
.align 32
gcm_gmult_avx:
.cfi_startproc
jmp .L_gmult_clmul
.cfi_endproc
.size gcm_gmult_avx,.-gcm_gmult_avx
___
$code.=<<___;
.globl gcm_ghash_avx
.type gcm_ghash_avx,\@abi-omnipotent
.align 32
gcm_ghash_avx:
.cfi_startproc
___
if ($avx) {
my ($Xip,$Htbl,$inp,$len)=@_4args;
my ($Xlo,$Xhi,$Xmi,
$Zlo,$Zhi,$Zmi,
$Hkey,$HK,$T1,$T2,
$Xi,$Xo,$Tred,$bswap,$Ii,$Ij) = map("%xmm$_",(0..15));
$code.=<<___ if ($win64);
lea -0x88(%rsp),%rax
.LSEH_begin_gcm_ghash_avx:
# I can't trust assembler to use specific encoding:-(
.byte 0x48,0x8d,0x60,0xe0 #lea -0x20(%rax),%rsp
.byte 0x0f,0x29,0x70,0xe0 #movaps %xmm6,-0x20(%rax)
.byte 0x0f,0x29,0x78,0xf0 #movaps %xmm7,-0x10(%rax)
.byte 0x44,0x0f,0x29,0x00 #movaps %xmm8,0(%rax)
.byte 0x44,0x0f,0x29,0x48,0x10 #movaps %xmm9,0x10(%rax)
.byte 0x44,0x0f,0x29,0x50,0x20 #movaps %xmm10,0x20(%rax)
.byte 0x44,0x0f,0x29,0x58,0x30 #movaps %xmm11,0x30(%rax)
.byte 0x44,0x0f,0x29,0x60,0x40 #movaps %xmm12,0x40(%rax)
.byte 0x44,0x0f,0x29,0x68,0x50 #movaps %xmm13,0x50(%rax)
.byte 0x44,0x0f,0x29,0x70,0x60 #movaps %xmm14,0x60(%rax)
.byte 0x44,0x0f,0x29,0x78,0x70 #movaps %xmm15,0x70(%rax)
___
$code.=<<___;
vzeroupper
vmovdqu ($Xip),$Xi # load $Xi
lea .L0x1c2_polynomial(%rip),%r10
lea 0x40($Htbl),$Htbl # size optimization
vmovdqu .Lbswap_mask(%rip),$bswap
vpshufb $bswap,$Xi,$Xi
cmp \$0x80,$len
jb .Lshort_avx
sub \$0x80,$len
vmovdqu 0x70($inp),$Ii # I[7]
vmovdqu 0x00-0x40($Htbl),$Hkey # $Hkey^1
vpshufb $bswap,$Ii,$Ii
vmovdqu 0x20-0x40($Htbl),$HK
vpunpckhqdq $Ii,$Ii,$T2
vmovdqu 0x60($inp),$Ij # I[6]
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpxor $Ii,$T2,$T2
vpshufb $bswap,$Ij,$Ij
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0x10-0x40($Htbl),$Hkey # $Hkey^2
vpunpckhqdq $Ij,$Ij,$T1
vmovdqu 0x50($inp),$Ii # I[5]
vpclmulqdq \$0x00,$HK,$T2,$Xmi
vpxor $Ij,$T1,$T1
vpshufb $bswap,$Ii,$Ii
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpunpckhqdq $Ii,$Ii,$T2
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vmovdqu 0x30-0x40($Htbl),$Hkey # $Hkey^3
vpxor $Ii,$T2,$T2
vmovdqu 0x40($inp),$Ij # I[4]
vpclmulqdq \$0x10,$HK,$T1,$Zmi
vmovdqu 0x50-0x40($Htbl),$HK
vpshufb $bswap,$Ij,$Ij
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpxor $Xhi,$Zhi,$Zhi
vpunpckhqdq $Ij,$Ij,$T1
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0x40-0x40($Htbl),$Hkey # $Hkey^4
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T2,$Xmi
vpxor $Ij,$T1,$T1
vmovdqu 0x30($inp),$Ii # I[3]
vpxor $Zlo,$Xlo,$Xlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpxor $Zhi,$Xhi,$Xhi
vpshufb $bswap,$Ii,$Ii
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vmovdqu 0x60-0x40($Htbl),$Hkey # $Hkey^5
vpxor $Zmi,$Xmi,$Xmi
vpunpckhqdq $Ii,$Ii,$T2
vpclmulqdq \$0x10,$HK,$T1,$Zmi
vmovdqu 0x80-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vmovdqu 0x20($inp),$Ij # I[2]
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpxor $Xhi,$Zhi,$Zhi
vpshufb $bswap,$Ij,$Ij
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0x70-0x40($Htbl),$Hkey # $Hkey^6
vpxor $Xmi,$Zmi,$Zmi
vpunpckhqdq $Ij,$Ij,$T1
vpclmulqdq \$0x00,$HK,$T2,$Xmi
vpxor $Ij,$T1,$T1
vmovdqu 0x10($inp),$Ii # I[1]
vpxor $Zlo,$Xlo,$Xlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpxor $Zhi,$Xhi,$Xhi
vpshufb $bswap,$Ii,$Ii
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vmovdqu 0x90-0x40($Htbl),$Hkey # $Hkey^7
vpxor $Zmi,$Xmi,$Xmi
vpunpckhqdq $Ii,$Ii,$T2
vpclmulqdq \$0x10,$HK,$T1,$Zmi
vmovdqu 0xb0-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vmovdqu ($inp),$Ij # I[0]
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpxor $Xhi,$Zhi,$Zhi
vpshufb $bswap,$Ij,$Ij
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0xa0-0x40($Htbl),$Hkey # $Hkey^8
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x10,$HK,$T2,$Xmi
lea 0x80($inp),$inp
cmp \$0x80,$len
jb .Ltail_avx
vpxor $Xi,$Ij,$Ij # accumulate $Xi
sub \$0x80,$len
jmp .Loop8x_avx
.align 32
.Loop8x_avx:
vpunpckhqdq $Ij,$Ij,$T1
vmovdqu 0x70($inp),$Ii # I[7]
vpxor $Xlo,$Zlo,$Zlo
vpxor $Ij,$T1,$T1
vpclmulqdq \$0x00,$Hkey,$Ij,$Xi
vpshufb $bswap,$Ii,$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xo
vmovdqu 0x00-0x40($Htbl),$Hkey # $Hkey^1
vpunpckhqdq $Ii,$Ii,$T2
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Tred
vmovdqu 0x20-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vmovdqu 0x60($inp),$Ij # I[6]
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpxor $Zlo,$Xi,$Xi # collect result
vpshufb $bswap,$Ij,$Ij
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vxorps $Zhi,$Xo,$Xo
vmovdqu 0x10-0x40($Htbl),$Hkey # $Hkey^2
vpunpckhqdq $Ij,$Ij,$T1
vpclmulqdq \$0x00,$HK, $T2,$Xmi
vpxor $Zmi,$Tred,$Tred
vxorps $Ij,$T1,$T1
vmovdqu 0x50($inp),$Ii # I[5]
vpxor $Xi,$Tred,$Tred # aggregated Karatsuba post-processing
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpxor $Xo,$Tred,$Tred
vpslldq \$8,$Tred,$T2
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vpsrldq \$8,$Tred,$Tred
vpxor $T2, $Xi, $Xi
vmovdqu 0x30-0x40($Htbl),$Hkey # $Hkey^3
vpshufb $bswap,$Ii,$Ii
vxorps $Tred,$Xo, $Xo
vpxor $Xhi,$Zhi,$Zhi
vpunpckhqdq $Ii,$Ii,$T2
vpclmulqdq \$0x10,$HK, $T1,$Zmi
vmovdqu 0x50-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vpxor $Xmi,$Zmi,$Zmi
vmovdqu 0x40($inp),$Ij # I[4]
vpalignr \$8,$Xi,$Xi,$Tred # 1st phase
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpshufb $bswap,$Ij,$Ij
vpxor $Zlo,$Xlo,$Xlo
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0x40-0x40($Htbl),$Hkey # $Hkey^4
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Zhi,$Xhi,$Xhi
vpclmulqdq \$0x00,$HK, $T2,$Xmi
vxorps $Ij,$T1,$T1
vpxor $Zmi,$Xmi,$Xmi
vmovdqu 0x30($inp),$Ii # I[3]
vpclmulqdq \$0x10,(%r10),$Xi,$Xi
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpshufb $bswap,$Ii,$Ii
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vmovdqu 0x60-0x40($Htbl),$Hkey # $Hkey^5
vpunpckhqdq $Ii,$Ii,$T2
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x10,$HK, $T1,$Zmi
vmovdqu 0x80-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vpxor $Xmi,$Zmi,$Zmi
vmovdqu 0x20($inp),$Ij # I[2]
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpshufb $bswap,$Ij,$Ij
vpxor $Zlo,$Xlo,$Xlo
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0x70-0x40($Htbl),$Hkey # $Hkey^6
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Zhi,$Xhi,$Xhi
vpclmulqdq \$0x00,$HK, $T2,$Xmi
vpxor $Ij,$T1,$T1
vpxor $Zmi,$Xmi,$Xmi
vxorps $Tred,$Xi,$Xi
vmovdqu 0x10($inp),$Ii # I[1]
vpalignr \$8,$Xi,$Xi,$Tred # 2nd phase
vpclmulqdq \$0x00,$Hkey,$Ij,$Zlo
vpshufb $bswap,$Ii,$Ii
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x11,$Hkey,$Ij,$Zhi
vmovdqu 0x90-0x40($Htbl),$Hkey # $Hkey^7
vpclmulqdq \$0x10,(%r10),$Xi,$Xi
vxorps $Xo,$Tred,$Tred
vpunpckhqdq $Ii,$Ii,$T2
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x10,$HK, $T1,$Zmi
vmovdqu 0xb0-0x40($Htbl),$HK
vpxor $Ii,$T2,$T2
vpxor $Xmi,$Zmi,$Zmi
vmovdqu ($inp),$Ij # I[0]
vpclmulqdq \$0x00,$Hkey,$Ii,$Xlo
vpshufb $bswap,$Ij,$Ij
vpclmulqdq \$0x11,$Hkey,$Ii,$Xhi
vmovdqu 0xa0-0x40($Htbl),$Hkey # $Hkey^8
vpxor $Tred,$Ij,$Ij
vpclmulqdq \$0x10,$HK, $T2,$Xmi
vpxor $Xi,$Ij,$Ij # accumulate $Xi
lea 0x80($inp),$inp
sub \$0x80,$len
jnc .Loop8x_avx
add \$0x80,$len
jmp .Ltail_no_xor_avx
.align 32
.Lshort_avx:
vmovdqu -0x10($inp,$len),$Ii # very last word
lea ($inp,$len),$inp
vmovdqu 0x00-0x40($Htbl),$Hkey # $Hkey^1
vmovdqu 0x20-0x40($Htbl),$HK
vpshufb $bswap,$Ii,$Ij
vmovdqa $Xlo,$Zlo # subtle way to zero $Zlo,
vmovdqa $Xhi,$Zhi # $Zhi and
vmovdqa $Xmi,$Zmi # $Zmi
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x20($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x10-0x40($Htbl),$Hkey # $Hkey^2
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vpsrldq \$8,$HK,$HK
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x30($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x30-0x40($Htbl),$Hkey # $Hkey^3
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vmovdqu 0x50-0x40($Htbl),$HK
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x40($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x40-0x40($Htbl),$Hkey # $Hkey^4
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vpsrldq \$8,$HK,$HK
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x50($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x60-0x40($Htbl),$Hkey # $Hkey^5
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vmovdqu 0x80-0x40($Htbl),$HK
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x60($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x70-0x40($Htbl),$Hkey # $Hkey^6
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vpsrldq \$8,$HK,$HK
sub \$0x10,$len
jz .Ltail_avx
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vmovdqu -0x70($inp),$Ii
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vmovdqu 0x90-0x40($Htbl),$Hkey # $Hkey^7
vpshufb $bswap,$Ii,$Ij
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vmovq 0xb8-0x40($Htbl),$HK
sub \$0x10,$len
jmp .Ltail_avx
.align 32
.Ltail_avx:
vpxor $Xi,$Ij,$Ij # accumulate $Xi
.Ltail_no_xor_avx:
vpunpckhqdq $Ij,$Ij,$T1
vpxor $Xlo,$Zlo,$Zlo
vpclmulqdq \$0x00,$Hkey,$Ij,$Xlo
vpxor $Ij,$T1,$T1
vpxor $Xhi,$Zhi,$Zhi
vpclmulqdq \$0x11,$Hkey,$Ij,$Xhi
vpxor $Xmi,$Zmi,$Zmi
vpclmulqdq \$0x00,$HK,$T1,$Xmi
vmovdqu (%r10),$Tred
vpxor $Xlo,$Zlo,$Xi
vpxor $Xhi,$Zhi,$Xo
vpxor $Xmi,$Zmi,$Zmi
vpxor $Xi, $Zmi,$Zmi # aggregated Karatsuba post-processing
vpxor $Xo, $Zmi,$Zmi
vpslldq \$8, $Zmi,$T2
vpsrldq \$8, $Zmi,$Zmi
vpxor $T2, $Xi, $Xi
vpxor $Zmi,$Xo, $Xo
vpclmulqdq \$0x10,$Tred,$Xi,$T2 # 1st phase
vpalignr \$8,$Xi,$Xi,$Xi
vpxor $T2,$Xi,$Xi
vpclmulqdq \$0x10,$Tred,$Xi,$T2 # 2nd phase
vpalignr \$8,$Xi,$Xi,$Xi
vpxor $Xo,$Xi,$Xi
vpxor $T2,$Xi,$Xi
cmp \$0,$len
jne .Lshort_avx
vpshufb $bswap,$Xi,$Xi
vmovdqu $Xi,($Xip)
vzeroupper
___
$code.=<<___ if ($win64);
movaps (%rsp),%xmm6
movaps 0x10(%rsp),%xmm7
movaps 0x20(%rsp),%xmm8
movaps 0x30(%rsp),%xmm9
movaps 0x40(%rsp),%xmm10
movaps 0x50(%rsp),%xmm11
movaps 0x60(%rsp),%xmm12
movaps 0x70(%rsp),%xmm13
movaps 0x80(%rsp),%xmm14
movaps 0x90(%rsp),%xmm15
lea 0xa8(%rsp),%rsp
.LSEH_end_gcm_ghash_avx:
___
$code.=<<___;
ret
.cfi_endproc
.size gcm_ghash_avx,.-gcm_ghash_avx
___
} else {
$code.=<<___;
jmp .L_ghash_clmul
.size gcm_ghash_avx,.-gcm_ghash_avx
___
}
$code.=<<___;
.align 64
.Lbswap_mask:
.byte 15,14,13,12,11,10,9,8,7,6,5,4,3,2,1,0
.L0x1c2_polynomial:
.byte 1,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0xc2
.L7_mask:
.long 7,0,7,0
.align 64
.asciz "GHASH for x86_64, CRYPTOGAMS by <appro\@openssl.org>"
.align 64
___
if ($win64) {
$code.=<<___;
.section .pdata
.align 4
.rva .LSEH_begin_gcm_init_clmul
.rva .LSEH_end_gcm_init_clmul
.rva .LSEH_info_gcm_init_clmul
.rva .LSEH_begin_gcm_ghash_clmul
.rva .LSEH_end_gcm_ghash_clmul
.rva .LSEH_info_gcm_ghash_clmul
___
$code.=<<___ if ($avx);
.rva .LSEH_begin_gcm_init_avx
.rva .LSEH_end_gcm_init_avx
.rva .LSEH_info_gcm_init_clmul
.rva .LSEH_begin_gcm_ghash_avx
.rva .LSEH_end_gcm_ghash_avx
.rva .LSEH_info_gcm_ghash_clmul
___
$code.=<<___;
.section .xdata
.align 8
.LSEH_info_gcm_init_clmul:
.byte 0x01,0x08,0x03,0x00
.byte 0x08,0x68,0x00,0x00 #movaps 0x00(rsp),xmm6
.byte 0x04,0x22,0x00,0x00 #sub rsp,0x18
.LSEH_info_gcm_ghash_clmul:
.byte 0x01,0x33,0x16,0x00
.byte 0x33,0xf8,0x09,0x00 #movaps 0x90(rsp),xmm15
.byte 0x2e,0xe8,0x08,0x00 #movaps 0x80(rsp),xmm14
.byte 0x29,0xd8,0x07,0x00 #movaps 0x70(rsp),xmm13
.byte 0x24,0xc8,0x06,0x00 #movaps 0x60(rsp),xmm12
.byte 0x1f,0xb8,0x05,0x00 #movaps 0x50(rsp),xmm11
.byte 0x1a,0xa8,0x04,0x00 #movaps 0x40(rsp),xmm10
.byte 0x15,0x98,0x03,0x00 #movaps 0x30(rsp),xmm9
.byte 0x10,0x88,0x02,0x00 #movaps 0x20(rsp),xmm8
.byte 0x0c,0x78,0x01,0x00 #movaps 0x10(rsp),xmm7
.byte 0x08,0x68,0x00,0x00 #movaps 0x00(rsp),xmm6
.byte 0x04,0x01,0x15,0x00 #sub rsp,0xa8
___
}
$code =~ s/\`([^\`]*)\`/eval($1)/gem;
print $code;
close STDOUT or die "error closing STDOUT: $!";