openssl1.0/crypto/modes/asm/ghash-x86_64.pl
2019-08-09 10:00:55 +02:00

1754 lines
42 KiB
Perl
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#!/usr/bin/env perl
#
# ====================================================================
# 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 <dwmw2@infradead.org> 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)
# Bulldozer 1.49(+27%)
# Silvermont 2.88(+13%)
# 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, and in
# 0.29 on Broadwell.
#
# [1] http://rt.openssl.org/Ticket/Display.html?id=2900&user=guest&pass=guest
$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 $xlate) or
die "can't locate x86_64-xlate.pl";
if (`$ENV{CC} -Wa,-v -c -o /dev/null -x assembler /dev/null 2>&1`
=~ /GNU assembler version ([2-9]\.[0-9]+)/) {
$avx = ($1>=2.20) + ($1>=2.22);
}
if (!$avx && $win64 && ($flavour =~ /nasm/ || $ENV{ASM} =~ /nasm/) &&
`nasm -v 2>&1` =~ /NASM version ([2-9]\.[0-9]+)/) {
$avx = ($1>=2.09) + ($1>=2.10);
}
if (!$avx && $win64 && ($flavour =~ /masm/ || $ENV{ASM} =~ /ml64/) &&
`ml64 2>&1` =~ /Version ([0-9]+)\./) {
$avx = ($1>=10) + ($1>=11);
}
if (!$avx && `$ENV{CC} -v 2>&1` =~ /((?:^clang|LLVM) version|.*based on LLVM) ([3-9]\.[0-9]+)/) {
$avx = ($2>=3.0) + ($2>3.0);
}
open OUT,"| \"$^X\" $xlate $flavour $output";
*STDOUT=*OUT;
$do4xaggr=1;
# common register layout
$nlo="%rax";
$nhi="%rbx";
$Zlo="%r8";
$Zhi="%r9";
$tmp="%r10";
$rem_4bit = "%r11";
$Xi="%rdi";
$Htbl="%rsi";
# per-function register layout
$cnt="%rcx";
$rem="%rdx";
sub LB() { my $r=shift; $r =~ s/%[er]([a-d])x/%\1l/ or
$r =~ s/%[er]([sd]i)/%\1l/ or
$r =~ s/%[er](bp)/%\1l/ or
$r =~ s/%(r[0-9]+)[d]?/%\1b/; $r; }
sub AUTOLOAD() # thunk [simplified] 32-bit style perlasm
{ my $opcode = $AUTOLOAD; $opcode =~ s/.*:://;
my $arg = pop;
$arg = "\$$arg" if ($arg*1 eq $arg);
$code .= "\t$opcode\t".join(',',$arg,reverse @_)."\n";
}
{ my $N;
sub loop() {
my $inp = shift;
$N++;
$code.=<<___;
xor $nlo,$nlo
xor $nhi,$nhi
mov `&LB("$Zlo")`,`&LB("$nlo")`
mov `&LB("$Zlo")`,`&LB("$nhi")`
shl \$4,`&LB("$nlo")`
mov \$14,$cnt
mov 8($Htbl,$nlo),$Zlo
mov ($Htbl,$nlo),$Zhi
and \$0xf0,`&LB("$nhi")`
mov $Zlo,$rem
jmp .Loop$N
.align 16
.Loop$N:
shr \$4,$Zlo
and \$0xf,$rem
mov $Zhi,$tmp
mov ($inp,$cnt),`&LB("$nlo")`
shr \$4,$Zhi
xor 8($Htbl,$nhi),$Zlo
shl \$60,$tmp
xor ($Htbl,$nhi),$Zhi
mov `&LB("$nlo")`,`&LB("$nhi")`
xor ($rem_4bit,$rem,8),$Zhi
mov $Zlo,$rem
shl \$4,`&LB("$nlo")`
xor $tmp,$Zlo
dec $cnt
js .Lbreak$N
shr \$4,$Zlo
and \$0xf,$rem
mov $Zhi,$tmp
shr \$4,$Zhi
xor 8($Htbl,$nlo),$Zlo
shl \$60,$tmp
xor ($Htbl,$nlo),$Zhi
and \$0xf0,`&LB("$nhi")`
xor ($rem_4bit,$rem,8),$Zhi
mov $Zlo,$rem
xor $tmp,$Zlo
jmp .Loop$N
.align 16
.Lbreak$N:
shr \$4,$Zlo
and \$0xf,$rem
mov $Zhi,$tmp
shr \$4,$Zhi
xor 8($Htbl,$nlo),$Zlo
shl \$60,$tmp
xor ($Htbl,$nlo),$Zhi
and \$0xf0,`&LB("$nhi")`
xor ($rem_4bit,$rem,8),$Zhi
mov $Zlo,$rem
xor $tmp,$Zlo
shr \$4,$Zlo
and \$0xf,$rem
mov $Zhi,$tmp
shr \$4,$Zhi
xor 8($Htbl,$nhi),$Zlo
shl \$60,$tmp
xor ($Htbl,$nhi),$Zhi
xor $tmp,$Zlo
xor ($rem_4bit,$rem,8),$Zhi
bswap $Zlo
bswap $Zhi
___
}}
$code=<<___;
.text
.extern OPENSSL_ia32cap_P
.globl gcm_gmult_4bit
.type gcm_gmult_4bit,\@function,2
.align 16
gcm_gmult_4bit:
push %rbx
push %rbp # %rbp and %r12 are pushed exclusively in
push %r12 # order to reuse Win64 exception handler...
.Lgmult_prologue:
movzb 15($Xi),$Zlo
lea .Lrem_4bit(%rip),$rem_4bit
___
&loop ($Xi);
$code.=<<___;
mov $Zlo,8($Xi)
mov $Zhi,($Xi)
mov 16(%rsp),%rbx
lea 24(%rsp),%rsp
.Lgmult_epilogue:
ret
.size gcm_gmult_4bit,.-gcm_gmult_4bit
___
# per-function register layout
$inp="%rdx";
$len="%rcx";
$rem_8bit=$rem_4bit;
$code.=<<___;
.globl gcm_ghash_4bit
.type gcm_ghash_4bit,\@function,4
.align 16
gcm_ghash_4bit:
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
sub \$280,%rsp
.Lghash_prologue:
mov $inp,%r14 # reassign couple of args
mov $len,%r15
___
{ my $inp="%r14";
my $dat="%edx";
my $len="%r15";
my @nhi=("%ebx","%ecx");
my @rem=("%r12","%r13");
my $Hshr4="%rbp";
&sub ($Htbl,-128); # size optimization
&lea ($Hshr4,"16+128(%rsp)");
{ my @lo =($nlo,$nhi);
my @hi =($Zlo,$Zhi);
&xor ($dat,$dat);
for ($i=0,$j=-2;$i<18;$i++,$j++) {
&mov ("$j(%rsp)",&LB($dat)) if ($i>1);
&or ($lo[0],$tmp) if ($i>1);
&mov (&LB($dat),&LB($lo[1])) if ($i>0 && $i<17);
&shr ($lo[1],4) if ($i>0 && $i<17);
&mov ($tmp,$hi[1]) if ($i>0 && $i<17);
&shr ($hi[1],4) if ($i>0 && $i<17);
&mov ("8*$j($Hshr4)",$hi[0]) if ($i>1);
&mov ($hi[0],"16*$i+0-128($Htbl)") if ($i<16);
&shl (&LB($dat),4) if ($i>0 && $i<17);
&mov ("8*$j-128($Hshr4)",$lo[0]) if ($i>1);
&mov ($lo[0],"16*$i+8-128($Htbl)") if ($i<16);
&shl ($tmp,60) if ($i>0 && $i<17);
push (@lo,shift(@lo));
push (@hi,shift(@hi));
}
}
&add ($Htbl,-128);
&mov ($Zlo,"8($Xi)");
&mov ($Zhi,"0($Xi)");
&add ($len,$inp); # pointer to the end of data
&lea ($rem_8bit,".Lrem_8bit(%rip)");
&jmp (".Louter_loop");
$code.=".align 16\n.Louter_loop:\n";
&xor ($Zhi,"($inp)");
&mov ("%rdx","8($inp)");
&lea ($inp,"16($inp)");
&xor ("%rdx",$Zlo);
&mov ("($Xi)",$Zhi);
&mov ("8($Xi)","%rdx");
&shr ("%rdx",32);
&xor ($nlo,$nlo);
&rol ($dat,8);
&mov (&LB($nlo),&LB($dat));
&movz ($nhi[0],&LB($dat));
&shl (&LB($nlo),4);
&shr ($nhi[0],4);
for ($j=11,$i=0;$i<15;$i++) {
&rol ($dat,8);
&xor ($Zlo,"8($Htbl,$nlo)") if ($i>0);
&xor ($Zhi,"($Htbl,$nlo)") if ($i>0);
&mov ($Zlo,"8($Htbl,$nlo)") if ($i==0);
&mov ($Zhi,"($Htbl,$nlo)") if ($i==0);
&mov (&LB($nlo),&LB($dat));
&xor ($Zlo,$tmp) if ($i>0);
&movzw ($rem[1],"($rem_8bit,$rem[1],2)") if ($i>0);
&movz ($nhi[1],&LB($dat));
&shl (&LB($nlo),4);
&movzb ($rem[0],"(%rsp,$nhi[0])");
&shr ($nhi[1],4) if ($i<14);
&and ($nhi[1],0xf0) if ($i==14);
&shl ($rem[1],48) if ($i>0);
&xor ($rem[0],$Zlo);
&mov ($tmp,$Zhi);
&xor ($Zhi,$rem[1]) if ($i>0);
&shr ($Zlo,8);
&movz ($rem[0],&LB($rem[0]));
&mov ($dat,"$j($Xi)") if (--$j%4==0);
&shr ($Zhi,8);
&xor ($Zlo,"-128($Hshr4,$nhi[0],8)");
&shl ($tmp,56);
&xor ($Zhi,"($Hshr4,$nhi[0],8)");
unshift (@nhi,pop(@nhi)); # "rotate" registers
unshift (@rem,pop(@rem));
}
&movzw ($rem[1],"($rem_8bit,$rem[1],2)");
&xor ($Zlo,"8($Htbl,$nlo)");
&xor ($Zhi,"($Htbl,$nlo)");
&shl ($rem[1],48);
&xor ($Zlo,$tmp);
&xor ($Zhi,$rem[1]);
&movz ($rem[0],&LB($Zlo));
&shr ($Zlo,4);
&mov ($tmp,$Zhi);
&shl (&LB($rem[0]),4);
&shr ($Zhi,4);
&xor ($Zlo,"8($Htbl,$nhi[0])");
&movzw ($rem[0],"($rem_8bit,$rem[0],2)");
&shl ($tmp,60);
&xor ($Zhi,"($Htbl,$nhi[0])");
&xor ($Zlo,$tmp);
&shl ($rem[0],48);
&bswap ($Zlo);
&xor ($Zhi,$rem[0]);
&bswap ($Zhi);
&cmp ($inp,$len);
&jb (".Louter_loop");
}
$code.=<<___;
mov $Zlo,8($Xi)
mov $Zhi,($Xi)
lea 280(%rsp),%rsi
mov 0(%rsi),%r15
mov 8(%rsi),%r14
mov 16(%rsi),%r13
mov 24(%rsi),%r12
mov 32(%rsi),%rbp
mov 40(%rsi),%rbx
lea 48(%rsi),%rsp
.Lghash_epilogue:
ret
.size gcm_ghash_4bit,.-gcm_ghash_4bit
___
######################################################################
# 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:
.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:
___
$code.=<<___;
ret
.size gcm_init_clmul,.-gcm_init_clmul
___
}
{ my ($Xip,$Htbl)=@_4args;
$code.=<<___;
.globl gcm_gmult_clmul
.type gcm_gmult_clmul,\@abi-omnipotent
.align 16
gcm_gmult_clmul:
.L_gmult_clmul:
movdqu ($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
.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:
.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));
$code.=<<___;
mov OPENSSL_ia32cap_P+4(%rip),%eax
cmp \$0x30,$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
.size gcm_ghash_clmul,.-gcm_ghash_clmul
___
}
$code.=<<___;
.globl gcm_init_avx
.type gcm_init_avx,\@abi-omnipotent
.align 32
gcm_init_avx:
___
if ($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
.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:
jmp .L_gmult_clmul
.size gcm_gmult_avx,.-gcm_gmult_avx
___
$code.=<<___;
.globl gcm_ghash_avx
.type gcm_ghash_avx,\@abi-omnipotent
.align 32
gcm_ghash_avx:
___
if ($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
.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
.L7_mask_poly:
.long 7,0,`0xE1<<1`,0
.align 64
.type .Lrem_4bit,\@object
.Lrem_4bit:
.long 0,`0x0000<<16`,0,`0x1C20<<16`,0,`0x3840<<16`,0,`0x2460<<16`
.long 0,`0x7080<<16`,0,`0x6CA0<<16`,0,`0x48C0<<16`,0,`0x54E0<<16`
.long 0,`0xE100<<16`,0,`0xFD20<<16`,0,`0xD940<<16`,0,`0xC560<<16`
.long 0,`0x9180<<16`,0,`0x8DA0<<16`,0,`0xA9C0<<16`,0,`0xB5E0<<16`
.type .Lrem_8bit,\@object
.Lrem_8bit:
.value 0x0000,0x01C2,0x0384,0x0246,0x0708,0x06CA,0x048C,0x054E
.value 0x0E10,0x0FD2,0x0D94,0x0C56,0x0918,0x08DA,0x0A9C,0x0B5E
.value 0x1C20,0x1DE2,0x1FA4,0x1E66,0x1B28,0x1AEA,0x18AC,0x196E
.value 0x1230,0x13F2,0x11B4,0x1076,0x1538,0x14FA,0x16BC,0x177E
.value 0x3840,0x3982,0x3BC4,0x3A06,0x3F48,0x3E8A,0x3CCC,0x3D0E
.value 0x3650,0x3792,0x35D4,0x3416,0x3158,0x309A,0x32DC,0x331E
.value 0x2460,0x25A2,0x27E4,0x2626,0x2368,0x22AA,0x20EC,0x212E
.value 0x2A70,0x2BB2,0x29F4,0x2836,0x2D78,0x2CBA,0x2EFC,0x2F3E
.value 0x7080,0x7142,0x7304,0x72C6,0x7788,0x764A,0x740C,0x75CE
.value 0x7E90,0x7F52,0x7D14,0x7CD6,0x7998,0x785A,0x7A1C,0x7BDE
.value 0x6CA0,0x6D62,0x6F24,0x6EE6,0x6BA8,0x6A6A,0x682C,0x69EE
.value 0x62B0,0x6372,0x6134,0x60F6,0x65B8,0x647A,0x663C,0x67FE
.value 0x48C0,0x4902,0x4B44,0x4A86,0x4FC8,0x4E0A,0x4C4C,0x4D8E
.value 0x46D0,0x4712,0x4554,0x4496,0x41D8,0x401A,0x425C,0x439E
.value 0x54E0,0x5522,0x5764,0x56A6,0x53E8,0x522A,0x506C,0x51AE
.value 0x5AF0,0x5B32,0x5974,0x58B6,0x5DF8,0x5C3A,0x5E7C,0x5FBE
.value 0xE100,0xE0C2,0xE284,0xE346,0xE608,0xE7CA,0xE58C,0xE44E
.value 0xEF10,0xEED2,0xEC94,0xED56,0xE818,0xE9DA,0xEB9C,0xEA5E
.value 0xFD20,0xFCE2,0xFEA4,0xFF66,0xFA28,0xFBEA,0xF9AC,0xF86E
.value 0xF330,0xF2F2,0xF0B4,0xF176,0xF438,0xF5FA,0xF7BC,0xF67E
.value 0xD940,0xD882,0xDAC4,0xDB06,0xDE48,0xDF8A,0xDDCC,0xDC0E
.value 0xD750,0xD692,0xD4D4,0xD516,0xD058,0xD19A,0xD3DC,0xD21E
.value 0xC560,0xC4A2,0xC6E4,0xC726,0xC268,0xC3AA,0xC1EC,0xC02E
.value 0xCB70,0xCAB2,0xC8F4,0xC936,0xCC78,0xCDBA,0xCFFC,0xCE3E
.value 0x9180,0x9042,0x9204,0x93C6,0x9688,0x974A,0x950C,0x94CE
.value 0x9F90,0x9E52,0x9C14,0x9DD6,0x9898,0x995A,0x9B1C,0x9ADE
.value 0x8DA0,0x8C62,0x8E24,0x8FE6,0x8AA8,0x8B6A,0x892C,0x88EE
.value 0x83B0,0x8272,0x8034,0x81F6,0x84B8,0x857A,0x873C,0x86FE
.value 0xA9C0,0xA802,0xAA44,0xAB86,0xAEC8,0xAF0A,0xAD4C,0xAC8E
.value 0xA7D0,0xA612,0xA454,0xA596,0xA0D8,0xA11A,0xA35C,0xA29E
.value 0xB5E0,0xB422,0xB664,0xB7A6,0xB2E8,0xB32A,0xB16C,0xB0AE
.value 0xBBF0,0xBA32,0xB874,0xB9B6,0xBCF8,0xBD3A,0xBF7C,0xBEBE
.asciz "GHASH for x86_64, CRYPTOGAMS by <appro\@openssl.org>"
.align 64
___
# EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
# CONTEXT *context,DISPATCHER_CONTEXT *disp)
if ($win64) {
$rec="%rcx";
$frame="%rdx";
$context="%r8";
$disp="%r9";
$code.=<<___;
.extern __imp_RtlVirtualUnwind
.type se_handler,\@abi-omnipotent
.align 16
se_handler:
push %rsi
push %rdi
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
pushfq
sub \$64,%rsp
mov 120($context),%rax # pull context->Rax
mov 248($context),%rbx # pull context->Rip
mov 8($disp),%rsi # disp->ImageBase
mov 56($disp),%r11 # disp->HandlerData
mov 0(%r11),%r10d # HandlerData[0]
lea (%rsi,%r10),%r10 # prologue label
cmp %r10,%rbx # context->Rip<prologue label
jb .Lin_prologue
mov 152($context),%rax # pull context->Rsp
mov 4(%r11),%r10d # HandlerData[1]
lea (%rsi,%r10),%r10 # epilogue label
cmp %r10,%rbx # context->Rip>=epilogue label
jae .Lin_prologue
lea 24(%rax),%rax # adjust "rsp"
mov -8(%rax),%rbx
mov -16(%rax),%rbp
mov -24(%rax),%r12
mov %rbx,144($context) # restore context->Rbx
mov %rbp,160($context) # restore context->Rbp
mov %r12,216($context) # restore context->R12
.Lin_prologue:
mov 8(%rax),%rdi
mov 16(%rax),%rsi
mov %rax,152($context) # restore context->Rsp
mov %rsi,168($context) # restore context->Rsi
mov %rdi,176($context) # restore context->Rdi
mov 40($disp),%rdi # disp->ContextRecord
mov $context,%rsi # context
mov \$`1232/8`,%ecx # sizeof(CONTEXT)
.long 0xa548f3fc # cld; rep movsq
mov $disp,%rsi
xor %rcx,%rcx # arg1, UNW_FLAG_NHANDLER
mov 8(%rsi),%rdx # arg2, disp->ImageBase
mov 0(%rsi),%r8 # arg3, disp->ControlPc
mov 16(%rsi),%r9 # arg4, disp->FunctionEntry
mov 40(%rsi),%r10 # disp->ContextRecord
lea 56(%rsi),%r11 # &disp->HandlerData
lea 24(%rsi),%r12 # &disp->EstablisherFrame
mov %r10,32(%rsp) # arg5
mov %r11,40(%rsp) # arg6
mov %r12,48(%rsp) # arg7
mov %rcx,56(%rsp) # arg8, (NULL)
call *__imp_RtlVirtualUnwind(%rip)
mov \$1,%eax # ExceptionContinueSearch
add \$64,%rsp
popfq
pop %r15
pop %r14
pop %r13
pop %r12
pop %rbp
pop %rbx
pop %rdi
pop %rsi
ret
.size se_handler,.-se_handler
.section .pdata
.align 4
.rva .LSEH_begin_gcm_gmult_4bit
.rva .LSEH_end_gcm_gmult_4bit
.rva .LSEH_info_gcm_gmult_4bit
.rva .LSEH_begin_gcm_ghash_4bit
.rva .LSEH_end_gcm_ghash_4bit
.rva .LSEH_info_gcm_ghash_4bit
.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_gmult_4bit:
.byte 9,0,0,0
.rva se_handler
.rva .Lgmult_prologue,.Lgmult_epilogue # HandlerData
.LSEH_info_gcm_ghash_4bit:
.byte 9,0,0,0
.rva se_handler
.rva .Lghash_prologue,.Lghash_epilogue # HandlerData
.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;