generic-library/openssl
1
0
Fork 0
Code Issues Pull Requests Releases Wiki Activity
openssl/crypto/bn/asm/x86_64-mont5.pl

1498 lines
31 KiB
Perl
Raw Normal View History

This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
#!/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/.
# ====================================================================
# August 2011.
#
# Companion to x86_64-mont.pl that optimizes cache-timing attack
# countermeasures. The subroutines are produced by replacing bp[i]
# references in their x86_64-mont.pl counterparts with cache-neutral
# references to powers table computed in BN_mod_exp_mont_consttime.
# In addition subroutine that scatters elements of the powers table
# is implemented, so that scatter-/gathering can be tuned without
# bn_exp.c modifications.
$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 $xlate) or
die "can't locate x86_64-xlate.pl";
x86_64 assembly pack: keep making Windows build more robust. PR: 2963 and a number of others
2013-02-02 19:52:43 +01:00
open OUT,"| \"$^X\" $xlate $flavour $output";
*STDOUT=*OUT;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
if (`$ENV{CC} -Wa,-v -c -o /dev/null -x assembler /dev/null 2>&1`
=~ /GNU assembler version ([2-9]\.[0-9]+)/) {
bn/asm/*x86_64*.pl: correct assembler requirement for ad*x.
2013-10-14 22:41:00 +02:00
$addx = ($1>=2.23);
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
}
if (!$addx && $win64 && ($flavour =~ /nasm/ || $ENV{ASM} =~ /nasm/) &&
`nasm -v 2>&1` =~ /NASM version ([2-9]\.[0-9]+)/) {
$addx = ($1>=2.10);
}
if (!$addx && $win64 && ($flavour =~ /masm/ || $ENV{ASM} =~ /ml64/) &&
`ml64 2>&1` =~ /Version ([0-9]+)\./) {
$addx = ($1>=11);
}
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
# int bn_mul_mont_gather5(
$rp="%rdi"; # BN_ULONG *rp,
$ap="%rsi"; # const BN_ULONG *ap,
$bp="%rdx"; # const BN_ULONG *bp,
$np="%rcx"; # const BN_ULONG *np,
$n0="%r8"; # const BN_ULONG *n0,
$num="%r9"; # int num,
# int idx); # 0 to 2^5-1, "index" in $bp holding
# pre-computed powers of a', interlaced
# in such manner that b[0] is $bp[idx],
# b[1] is [2^5+idx], etc.
$lo0="%r10";
$hi0="%r11";
$hi1="%r13";
$i="%r14";
$j="%r15";
$m0="%rbx";
$m1="%rbp";
$code=<<___;
.text
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
.extern OPENSSL_ia32cap_P
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
.globl bn_mul_mont_gather5
.type bn_mul_mont_gather5,\@function,6
.align 64
bn_mul_mont_gather5:
test \$3,${num}d
jnz .Lmul_enter
cmp \$8,${num}d
jb .Lmul_enter
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
___
$code.=<<___ if ($addx);
mov OPENSSL_ia32cap_P+8(%rip),%r11d
___
$code.=<<___;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
jmp .Lmul4x_enter
.align 16
.Lmul_enter:
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
mov ${num}d,${num}d
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov `($win64?56:8)`(%rsp),%r10d # load 7th argument
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
___
$code.=<<___ if ($win64);
lea -0x28(%rsp),%rsp
movaps %xmm6,(%rsp)
movaps %xmm7,0x10(%rsp)
.Lmul_alloca:
___
$code.=<<___;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rsp,%rax
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
lea 2($num),%r11
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
neg %r11
lea (%rsp,%r11,8),%rsp # tp=alloca(8*(num+2))
and \$-1024,%rsp # minimize TLB usage
mov %rax,8(%rsp,$num,8) # tp[num+1]=%rsp
.Lmul_body:
mov $bp,%r12 # reassign $bp
___
$bp="%r12";
$STRIDE=2**5*8; # 5 is "window size"
$N=$STRIDE/4; # should match cache line size
$code.=<<___;
mov %r10,%r11
shr \$`log($N/8)/log(2)`,%r10
and \$`$N/8-1`,%r11
not %r10
lea .Lmagic_masks(%rip),%rax
and \$`2**5/($N/8)-1`,%r10 # 5 is "window size"
lea 96($bp,%r11,8),$bp # pointer within 1st cache line
movq 0(%rax,%r10,8),%xmm4 # set of masks denoting which
movq 8(%rax,%r10,8),%xmm5 # cache line contains element
movq 16(%rax,%r10,8),%xmm6 # denoted by 7th argument
movq 24(%rax,%r10,8),%xmm7
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
movq %xmm0,$m0 # m0=bp[0]
mov ($n0),$n0 # pull n0[0] value
mov ($ap),%rax
xor $i,$i # i=0
xor $j,$j # j=0
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
mov $n0,$m1
mulq $m0 # ap[0]*bp[0]
mov %rax,$lo0
mov ($np),%rax
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
imulq $lo0,$m1 # "tp[0]"*n0
mov %rdx,$hi0
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
mulq $m1 # np[0]*m1
add %rax,$lo0 # discarded
mov 8($ap),%rax
adc \$0,%rdx
mov %rdx,$hi1
lea 1($j),$j # j++
jmp .L1st_enter
.align 16
.L1st:
add %rax,$hi1
mov ($ap,$j,8),%rax
adc \$0,%rdx
add $hi0,$hi1 # np[j]*m1+ap[j]*bp[0]
mov $lo0,$hi0
adc \$0,%rdx
mov $hi1,-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$hi1
.L1st_enter:
mulq $m0 # ap[j]*bp[0]
add %rax,$hi0
mov ($np,$j,8),%rax
adc \$0,%rdx
lea 1($j),$j # j++
mov %rdx,$lo0
mulq $m1 # np[j]*m1
cmp $num,$j
jne .L1st
movq %xmm0,$m0 # bp[1]
add %rax,$hi1
mov ($ap),%rax # ap[0]
adc \$0,%rdx
add $hi0,$hi1 # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $hi1,-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$hi1
mov $lo0,$hi0
xor %rdx,%rdx
add $hi0,$hi1
adc \$0,%rdx
mov $hi1,-8(%rsp,$num,8)
mov %rdx,(%rsp,$num,8) # store upmost overflow bit
lea 1($i),$i # i++
jmp .Louter
.align 16
.Louter:
xor $j,$j # j=0
mov $n0,$m1
mov (%rsp),$lo0
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
mulq $m0 # ap[0]*bp[i]
add %rax,$lo0 # ap[0]*bp[i]+tp[0]
mov ($np),%rax
adc \$0,%rdx
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
imulq $lo0,$m1 # tp[0]*n0
mov %rdx,$hi0
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
mulq $m1 # np[0]*m1
add %rax,$lo0 # discarded
mov 8($ap),%rax
adc \$0,%rdx
mov 8(%rsp),$lo0 # tp[1]
mov %rdx,$hi1
lea 1($j),$j # j++
jmp .Linner_enter
.align 16
.Linner:
add %rax,$hi1
mov ($ap,$j,8),%rax
adc \$0,%rdx
add $lo0,$hi1 # np[j]*m1+ap[j]*bp[i]+tp[j]
mov (%rsp,$j,8),$lo0
adc \$0,%rdx
mov $hi1,-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$hi1
.Linner_enter:
mulq $m0 # ap[j]*bp[i]
add %rax,$hi0
mov ($np,$j,8),%rax
adc \$0,%rdx
add $hi0,$lo0 # ap[j]*bp[i]+tp[j]
mov %rdx,$hi0
adc \$0,$hi0
lea 1($j),$j # j++
mulq $m1 # np[j]*m1
cmp $num,$j
jne .Linner
movq %xmm0,$m0 # bp[i+1]
add %rax,$hi1
mov ($ap),%rax # ap[0]
adc \$0,%rdx
add $lo0,$hi1 # np[j]*m1+ap[j]*bp[i]+tp[j]
mov (%rsp,$j,8),$lo0
adc \$0,%rdx
mov $hi1,-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$hi1
xor %rdx,%rdx
add $hi0,$hi1
adc \$0,%rdx
add $lo0,$hi1 # pull upmost overflow bit
adc \$0,%rdx
mov $hi1,-8(%rsp,$num,8)
mov %rdx,(%rsp,$num,8) # store upmost overflow bit
lea 1($i),$i # i++
cmp $num,$i
jl .Louter
xor $i,$i # i=0 and clear CF!
mov (%rsp),%rax # tp[0]
lea (%rsp),$ap # borrow ap for tp
mov $num,$j # j=num
jmp .Lsub
.align 16
.Lsub: sbb ($np,$i,8),%rax
mov %rax,($rp,$i,8) # rp[i]=tp[i]-np[i]
mov 8($ap,$i,8),%rax # tp[i+1]
lea 1($i),$i # i++
dec $j # doesnn't affect CF!
jnz .Lsub
sbb \$0,%rax # handle upmost overflow bit
xor $i,$i
and %rax,$ap
not %rax
mov $rp,$np
and %rax,$np
mov $num,$j # j=num
or $np,$ap # ap=borrow?tp:rp
.align 16
.Lcopy: # copy or in-place refresh
mov ($ap,$i,8),%rax
mov $i,(%rsp,$i,8) # zap temporary vector
mov %rax,($rp,$i,8) # rp[i]=tp[i]
lea 1($i),$i
sub \$1,$j
jnz .Lcopy
mov 8(%rsp,$num,8),%rsi # restore %rsp
mov \$1,%rax
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
___
$code.=<<___ if ($win64);
movaps (%rsi),%xmm6
movaps 0x10(%rsi),%xmm7
lea 0x28(%rsi),%rsi
___
$code.=<<___;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov (%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
.Lmul_epilogue:
ret
.size bn_mul_mont_gather5,.-bn_mul_mont_gather5
___
{{{
my @A=("%r10","%r11");
my @N=("%r13","%rdi");
$code.=<<___;
.type bn_mul4x_mont_gather5,\@function,6
.align 16
bn_mul4x_mont_gather5:
.Lmul4x_enter:
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
___
$code.=<<___ if ($addx);
and \$0x80100,%r11d
cmp \$0x80100,%r11d
je .Lmulx4x_enter
___
$code.=<<___;
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
mov ${num}d,${num}d
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov `($win64?56:8)`(%rsp),%r10d # load 7th argument
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
___
$code.=<<___ if ($win64);
lea -0x28(%rsp),%rsp
movaps %xmm6,(%rsp)
movaps %xmm7,0x10(%rsp)
.Lmul4x_alloca:
___
$code.=<<___;
mov %rsp,%rax
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
lea 4($num),%r11
neg %r11
lea (%rsp,%r11,8),%rsp # tp=alloca(8*(num+4))
and \$-1024,%rsp # minimize TLB usage
mov %rax,8(%rsp,$num,8) # tp[num+1]=%rsp
.Lmul4x_body:
mov $rp,16(%rsp,$num,8) # tp[num+2]=$rp
mov %rdx,%r12 # reassign $bp
___
$bp="%r12";
$STRIDE=2**5*8; # 5 is "window size"
$N=$STRIDE/4; # should match cache line size
$code.=<<___;
mov %r10,%r11
shr \$`log($N/8)/log(2)`,%r10
and \$`$N/8-1`,%r11
not %r10
lea .Lmagic_masks(%rip),%rax
and \$`2**5/($N/8)-1`,%r10 # 5 is "window size"
lea 96($bp,%r11,8),$bp # pointer within 1st cache line
movq 0(%rax,%r10,8),%xmm4 # set of masks denoting which
movq 8(%rax,%r10,8),%xmm5 # cache line contains element
movq 16(%rax,%r10,8),%xmm6 # denoted by 7th argument
movq 24(%rax,%r10,8),%xmm7
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
movq %xmm0,$m0 # m0=bp[0]
mov ($n0),$n0 # pull n0[0] value
mov ($ap),%rax
xor $i,$i # i=0
xor $j,$j # j=0
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
mov $n0,$m1
mulq $m0 # ap[0]*bp[0]
mov %rax,$A[0]
mov ($np),%rax
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
imulq $A[0],$m1 # "tp[0]"*n0
mov %rdx,$A[1]
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
mulq $m1 # np[0]*m1
add %rax,$A[0] # discarded
mov 8($ap),%rax
adc \$0,%rdx
mov %rdx,$N[1]
mulq $m0
add %rax,$A[1]
mov 8($np),%rax
adc \$0,%rdx
mov %rdx,$A[0]
mulq $m1
add %rax,$N[1]
mov 16($ap),%rax
adc \$0,%rdx
add $A[1],$N[1]
lea 4($j),$j # j++
adc \$0,%rdx
mov $N[1],(%rsp)
mov %rdx,$N[0]
jmp .L1st4x
.align 16
.L1st4x:
mulq $m0 # ap[j]*bp[0]
add %rax,$A[0]
mov -16($np,$j,8),%rax
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov -8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[0],-24(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[0]
add %rax,$A[1]
mov -8($np,$j,8),%rax
adc \$0,%rdx
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov ($ap,$j,8),%rax
adc \$0,%rdx
add $A[1],$N[1] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[1],-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[0]
mulq $m0 # ap[j]*bp[0]
add %rax,$A[0]
mov ($np,$j,8),%rax
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov 8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[0],-8(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[0]
add %rax,$A[1]
mov 8($np,$j,8),%rax
adc \$0,%rdx
lea 4($j),$j # j++
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov -16($ap,$j,8),%rax
adc \$0,%rdx
add $A[1],$N[1] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[1],-32(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[0]
cmp $num,$j
jl .L1st4x
mulq $m0 # ap[j]*bp[0]
add %rax,$A[0]
mov -16($np,$j,8),%rax
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov -8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[0],-24(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[0]
add %rax,$A[1]
mov -8($np,$j,8),%rax
adc \$0,%rdx
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov ($ap),%rax # ap[0]
adc \$0,%rdx
add $A[1],$N[1] # np[j]*m1+ap[j]*bp[0]
adc \$0,%rdx
mov $N[1],-16(%rsp,$j,8) # tp[j-1]
mov %rdx,$N[0]
movq %xmm0,$m0 # bp[1]
xor $N[1],$N[1]
add $A[0],$N[0]
adc \$0,$N[1]
mov $N[0],-8(%rsp,$j,8)
mov $N[1],(%rsp,$j,8) # store upmost overflow bit
lea 1($i),$i # i++
.align 4
.Louter4x:
xor $j,$j # j=0
movq `0*$STRIDE/4-96`($bp),%xmm0
movq `1*$STRIDE/4-96`($bp),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bp),%xmm2
pand %xmm5,%xmm1
mov (%rsp),$A[0]
mov $n0,$m1
mulq $m0 # ap[0]*bp[i]
add %rax,$A[0] # ap[0]*bp[i]+tp[0]
mov ($np),%rax
adc \$0,%rdx
movq `3*$STRIDE/4-96`($bp),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
imulq $A[0],$m1 # tp[0]*n0
mov %rdx,$A[1]
por %xmm2,%xmm0
lea $STRIDE($bp),$bp
por %xmm3,%xmm0
mulq $m1 # np[0]*m1
add %rax,$A[0] # "$N[0]", discarded
mov 8($ap),%rax
adc \$0,%rdx
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[i]
add %rax,$A[1]
mov 8($np),%rax
adc \$0,%rdx
add 8(%rsp),$A[1] # +tp[1]
adc \$0,%rdx
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov 16($ap),%rax
adc \$0,%rdx
add $A[1],$N[1] # np[j]*m1+ap[j]*bp[i]+tp[j]
lea 4($j),$j # j+=2
adc \$0,%rdx
mov %rdx,$N[0]
jmp .Linner4x
.align 16
.Linner4x:
mulq $m0 # ap[j]*bp[i]
add %rax,$A[0]
mov -16($np,$j,8),%rax
adc \$0,%rdx
add -16(%rsp,$j,8),$A[0] # ap[j]*bp[i]+tp[j]
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov -8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[1],-32(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[i]
add %rax,$A[1]
mov -8($np,$j,8),%rax
adc \$0,%rdx
add -8(%rsp,$j,8),$A[1]
adc \$0,%rdx
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov ($ap,$j,8),%rax
adc \$0,%rdx
add $A[1],$N[1]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[0],-24(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[0]
mulq $m0 # ap[j]*bp[i]
add %rax,$A[0]
mov ($np,$j,8),%rax
adc \$0,%rdx
add (%rsp,$j,8),$A[0] # ap[j]*bp[i]+tp[j]
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov 8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[1],-16(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[i]
add %rax,$A[1]
mov 8($np,$j,8),%rax
adc \$0,%rdx
add 8(%rsp,$j,8),$A[1]
adc \$0,%rdx
lea 4($j),$j # j++
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov -16($ap,$j,8),%rax
adc \$0,%rdx
add $A[1],$N[1]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[0],-40(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[0]
cmp $num,$j
jl .Linner4x
mulq $m0 # ap[j]*bp[i]
add %rax,$A[0]
mov -16($np,$j,8),%rax
adc \$0,%rdx
add -16(%rsp,$j,8),$A[0] # ap[j]*bp[i]+tp[j]
adc \$0,%rdx
mov %rdx,$A[1]
mulq $m1 # np[j]*m1
add %rax,$N[0]
mov -8($ap,$j,8),%rax
adc \$0,%rdx
add $A[0],$N[0]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[1],-32(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[1]
mulq $m0 # ap[j]*bp[i]
add %rax,$A[1]
mov -8($np,$j,8),%rax
adc \$0,%rdx
add -8(%rsp,$j,8),$A[1]
adc \$0,%rdx
lea 1($i),$i # i++
mov %rdx,$A[0]
mulq $m1 # np[j]*m1
add %rax,$N[1]
mov ($ap),%rax # ap[0]
adc \$0,%rdx
add $A[1],$N[1]
adc \$0,%rdx
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[0],-24(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov %rdx,$N[0]
movq %xmm0,$m0 # bp[i+1]
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
mov $N[1],-16(%rsp,$j,8) # tp[j-1]
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
xor $N[1],$N[1]
add $A[0],$N[0]
adc \$0,$N[1]
add (%rsp,$num,8),$N[0] # pull upmost overflow bit
adc \$0,$N[1]
mov $N[0],-8(%rsp,$j,8)
mov $N[1],(%rsp,$j,8) # store upmost overflow bit
cmp $num,$i
jl .Louter4x
___
{
my @ri=("%rax","%rdx",$m0,$m1);
$code.=<<___;
mov 16(%rsp,$num,8),$rp # restore $rp
mov 0(%rsp),@ri[0] # tp[0]
pxor %xmm0,%xmm0
mov 8(%rsp),@ri[1] # tp[1]
shr \$2,$num # num/=4
lea (%rsp),$ap # borrow ap for tp
xor $i,$i # i=0 and clear CF!
sub 0($np),@ri[0]
mov 16($ap),@ri[2] # tp[2]
mov 24($ap),@ri[3] # tp[3]
sbb 8($np),@ri[1]
lea -1($num),$j # j=num/4-1
jmp .Lsub4x
.align 16
.Lsub4x:
mov @ri[0],0($rp,$i,8) # rp[i]=tp[i]-np[i]
mov @ri[1],8($rp,$i,8) # rp[i]=tp[i]-np[i]
sbb 16($np,$i,8),@ri[2]
mov 32($ap,$i,8),@ri[0] # tp[i+1]
mov 40($ap,$i,8),@ri[1]
sbb 24($np,$i,8),@ri[3]
mov @ri[2],16($rp,$i,8) # rp[i]=tp[i]-np[i]
mov @ri[3],24($rp,$i,8) # rp[i]=tp[i]-np[i]
sbb 32($np,$i,8),@ri[0]
mov 48($ap,$i,8),@ri[2]
mov 56($ap,$i,8),@ri[3]
sbb 40($np,$i,8),@ri[1]
lea 4($i),$i # i++
dec $j # doesnn't affect CF!
jnz .Lsub4x
mov @ri[0],0($rp,$i,8) # rp[i]=tp[i]-np[i]
mov 32($ap,$i,8),@ri[0] # load overflow bit
sbb 16($np,$i,8),@ri[2]
mov @ri[1],8($rp,$i,8) # rp[i]=tp[i]-np[i]
sbb 24($np,$i,8),@ri[3]
mov @ri[2],16($rp,$i,8) # rp[i]=tp[i]-np[i]
sbb \$0,@ri[0] # handle upmost overflow bit
mov @ri[3],24($rp,$i,8) # rp[i]=tp[i]-np[i]
xor $i,$i # i=0
and @ri[0],$ap
not @ri[0]
mov $rp,$np
and @ri[0],$np
lea -1($num),$j
or $np,$ap # ap=borrow?tp:rp
movdqu ($ap),%xmm1
movdqa %xmm0,(%rsp)
movdqu %xmm1,($rp)
jmp .Lcopy4x
.align 16
.Lcopy4x: # copy or in-place refresh
movdqu 16($ap,$i),%xmm2
movdqu 32($ap,$i),%xmm1
movdqa %xmm0,16(%rsp,$i)
movdqu %xmm2,16($rp,$i)
movdqa %xmm0,32(%rsp,$i)
movdqu %xmm1,32($rp,$i)
lea 32($i),$i
dec $j
jnz .Lcopy4x
shl \$2,$num
movdqu 16($ap,$i),%xmm2
movdqa %xmm0,16(%rsp,$i)
movdqu %xmm2,16($rp,$i)
___
}
$code.=<<___;
mov 8(%rsp,$num,8),%rsi # restore %rsp
mov \$1,%rax
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
___
$code.=<<___ if ($win64);
movaps (%rsi),%xmm6
movaps 0x10(%rsi),%xmm7
lea 0x28(%rsi),%rsi
___
$code.=<<___;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
mov (%rsi),%r15
mov 8(%rsi),%r14
mov 16(%rsi),%r13
mov 24(%rsi),%r12
mov 32(%rsi),%rbp
mov 40(%rsi),%rbx
lea 48(%rsi),%rsp
.Lmul4x_epilogue:
ret
.size bn_mul4x_mont_gather5,.-bn_mul4x_mont_gather5
___
}}}
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
if ($addx) {{{
my $bp="%rdx"; # original value
$code.=<<___;
.type bn_mulx4x_mont_gather5,\@function,6
.align 32
bn_mulx4x_mont_gather5:
.Lmulx4x_enter:
mov %rsp,%rax
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
___
$code.=<<___ if ($win64);
lea -0x28(%rsp),%rsp
movaps %xmm6,(%rsp)
movaps %xmm7,0x10(%rsp)
___
$code.=<<___;
shl \$3,${num}d # convert $num to bytes
xor %r10,%r10
mov %rsp,%r11 # put aside %rsp
sub $num,%r10 # -$num
mov ($n0),$n0 # *n0
lea -72(%rsp,%r10),%rsp # alloca(frame+$num+8)
and \$-128,%rsp
##############################################################
# Stack layout
# +0 num
# +8 off-loaded &b[i]
# +16 end of b[num]
# +24 saved n0
# +32 saved rp
# +40
# +48 inner counter
# +56 saved %rsp
# +64 tmp[num+1]
#
mov $num,0(%rsp) # save $num
shl \$5,$num
lea 256($bp,$num),%r10
shr \$5+5,$num
mov %r10,16(%rsp) # end of b[num]
sub \$1,$num
mov $n0, 24(%rsp) # save *n0
mov $rp, 32(%rsp) # save $rp
mov $num,48(%rsp) # inner counter
mov %r11,56(%rsp) # save original %rsp
jmp .Lmulx4x_body
.align 32
.Lmulx4x_body:
___
my ($aptr, $bptr, $nptr, $tptr, $mi, $bi, $zero, $num)=
("%rsi","%rdi","%rcx","%rbx","%r8","%r9","%rbp","%rax");
my $rptr=$bptr;
my $STRIDE=2**5*8; # 5 is "window size"
my $N=$STRIDE/4; # should match cache line size
$code.=<<___;
mov `($win64?56:8)`(%rax),%r10d # load 7th argument
mov %r10,%r11
shr \$`log($N/8)/log(2)`,%r10
and \$`$N/8-1`,%r11
not %r10
lea .Lmagic_masks(%rip),%rax
and \$`2**5/($N/8)-1`,%r10 # 5 is "window size"
lea 96($bp,%r11,8),$bptr # pointer within 1st cache line
movq 0(%rax,%r10,8),%xmm4 # set of masks denoting which
movq 8(%rax,%r10,8),%xmm5 # cache line contains element
movq 16(%rax,%r10,8),%xmm6 # denoted by 7th argument
movq 24(%rax,%r10,8),%xmm7
movq `0*$STRIDE/4-96`($bptr),%xmm0
movq `1*$STRIDE/4-96`($bptr),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bptr),%xmm2
pand %xmm5,%xmm1
movq `3*$STRIDE/4-96`($bptr),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
por %xmm2,%xmm0
lea $STRIDE($bptr),$bptr
por %xmm3,%xmm0
movq %xmm0,%rdx # bp[0]
movq `0*$STRIDE/4-96`($bptr),%xmm0
movq `1*$STRIDE/4-96`($bptr),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bptr),%xmm2
pand %xmm5,%xmm1
lea 64+32(%rsp),$tptr
mov %rdx,$bi
xor $zero,$zero # of=0,cf=0
mulx 0*8($aptr),$mi,%rax # a[0]*b[0]
mulx 1*8($aptr),%r11,%r14 # a[1]*b[0]
adcx %rax,%r11
mulx 2*8($aptr),%r12,%r13 # ...
adcx %r14,%r12
adcx $zero,%r13
movq `3*$STRIDE/4-96`($bptr),%xmm3
lea $STRIDE($bptr),%r10 # next &b[i]
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
bn/asm/x86_64-mont*.pl: add MULX/ADCX/ADOX code path.
2013-10-03 00:45:04 +02:00
mov $mi,$bptr # borrow $bptr
imulq 24(%rsp),$mi # "t[0]"*n0
xor $zero,$zero # cf=0, of=0
por %xmm2,%xmm0
por %xmm3,%xmm0
mov %r10,8(%rsp) # off-load &b[i]
mulx 3*8($aptr),%rax,%r14
mov $mi,%rdx
lea 4*8($aptr),$aptr
adcx %rax,%r13
adcx $zero,%r14 # cf=0
mulx 0*8($nptr),%rax,%r10
adcx %rax,$bptr # discarded
adox %r11,%r10
mulx 1*8($nptr),%rax,%r11
adcx %rax,%r10
adox %r12,%r11
mulx 2*8($nptr),%rax,%r12
mov 48(%rsp),$bptr # counter value
mov %r10,-4*8($tptr)
adcx %rax,%r11
adox %r13,%r12
mulx 3*8($nptr),%rax,%r15
mov $bi,%rdx
mov %r11,-3*8($tptr)
adcx %rax,%r12
adox $zero,%r15 # of=0
lea 4*8($nptr),$nptr
mov %r12,-2*8($tptr)
jmp .Lmulx4x_1st
.align 32
.Lmulx4x_1st:
adcx $zero,%r15 # cf=0, modulo-scheduled
mulx 0*8($aptr),%r10,%rax # a[4]*b[0]
adcx %r14,%r10
mulx 1*8($aptr),%r11,%r14 # a[5]*b[0]
adcx %rax,%r11
mulx 2*8($aptr),%r12,%rax # ...
adcx %r14,%r12
mulx 3*8($aptr),%r13,%r14
.byte 0x66,0x66
mov $mi,%rdx
adcx %rax,%r13
adcx $zero,%r14 # cf=0
lea 4*8($aptr),$aptr
lea 4*8($tptr),$tptr
adox %r15,%r10
mulx 0*8($nptr),%rax,%r15
adcx %rax,%r10
adox %r15,%r11
mulx 1*8($nptr),%rax,%r15
adcx %rax,%r11
adox %r15,%r12
.byte 0x3e
mulx 2*8($nptr),%rax,%r15
mov %r10,-5*8($tptr)
mov %r11,-4*8($tptr)
adcx %rax,%r12
adox %r15,%r13
mulx 3*8($nptr),%rax,%r15
mov $bi,%rdx
mov %r12,-3*8($tptr)
adcx %rax,%r13
adox $zero,%r15
lea 4*8($nptr),$nptr
mov %r13,-2*8($tptr)
dec $bptr # of=0, pass cf
jnz .Lmulx4x_1st
mov 0(%rsp),$num # load num
mov 8(%rsp),$bptr # re-load &b[i]
movq %xmm0,%rdx # bp[1]
adc $zero,%r15 # modulo-scheduled
add %r15,%r14
sbb %r15,%r15 # top-most carry
mov %r14,-1*8($tptr)
jmp .Lmulx4x_outer
.align 32
.Lmulx4x_outer:
sub $num,$aptr # rewind $aptr
mov %r15,($tptr) # save top-most carry
mov 64(%rsp),%r10
lea 64(%rsp),$tptr
sub $num,$nptr # rewind $nptr
xor $zero,$zero # cf=0, of=0
mov %rdx,$bi
movq `0*$STRIDE/4-96`($bptr),%xmm0
movq `1*$STRIDE/4-96`($bptr),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($bptr),%xmm2
pand %xmm5,%xmm1
mulx 0*8($aptr),$mi,%rax # a[0]*b[i]
adox %r10,$mi
mov 1*8($tptr),%r10
mulx 1*8($aptr),%r11,%r14 # a[1]*b[i]
adcx %rax,%r11
mulx 2*8($aptr),%r12,%r13 # ...
adox %r10,%r11
adcx %r14,%r12
adox $zero,%r12
adcx $zero,%r13
movq `3*$STRIDE/4-96`($bptr),%xmm3
lea $STRIDE($bptr),%r10 # next &b[i]
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
mov $mi,$bptr # borrow $bptr
imulq 24(%rsp),$mi # "t[0]"*n0
xor $zero,$zero # cf=0, of=0
por %xmm2,%xmm0
por %xmm3,%xmm0
mov %r10,8(%rsp) # off-load &b[i]
mov 2*8($tptr),%r10
mulx 3*8($aptr),%rax,%r14
mov $mi,%rdx
adox %r10,%r12
adcx %rax,%r13
adox 3*8($tptr),%r13
adcx $zero,%r14
lea 4*8($aptr),$aptr
lea 4*8($tptr),$tptr
adox $zero,%r14
mulx 0*8($nptr),%rax,%r10
adcx %rax,$bptr # discarded
adox %r11,%r10
mulx 1*8($nptr),%rax,%r11
adcx %rax,%r10
adox %r12,%r11
mulx 2*8($nptr),%rax,%r12
.byte 0x3e
mov %r10,-4*8($tptr)
.byte 0x3e
mov 0*8($tptr),%r10
adcx %rax,%r11
adox %r13,%r12
mulx 3*8($nptr),%rax,%r15
mov $bi,%rdx
mov %r11,-3*8($tptr)
adcx %rax,%r12
adox $zero,%r15 # of=0
mov 48(%rsp),$bptr # counter value
mov %r12,-2*8($tptr)
lea 4*8($nptr),$nptr
jmp .Lmulx4x_inner
.align 32
.Lmulx4x_inner:
adcx $zero,%r15 # cf=0, modulo-scheduled
adox %r10,%r14
mulx 0*8($aptr),%r10,%rax # a[4]*b[i]
mov 1*8($tptr),%r13
adcx %r14,%r10
mulx 1*8($aptr),%r11,%r14 # a[5]*b[i]
adox %rax,%r11
mulx 2*8($aptr),%r12,%rax # ...
adcx %r13,%r11
adox %r14,%r12
mulx 3*8($aptr),%r13,%r14
mov $mi,%rdx
adcx 2*8($tptr),%r12
adox %rax,%r13
adcx 3*8($tptr),%r13
adox $zero,%r14 # of=0
lea 4*8($aptr),$aptr
.byte 0x48,0x8d,0x9b,0x20,0x00,0x00,0x00 # lea 4*8($tptr),$tptr
adcx $zero,%r14 # cf=0
adox %r15,%r10
.byte 0x3e,0xc4,0x62,0xfb,0xf6,0x79,0x00 # mulx 0*8($nptr),%rax,%r15
adcx %rax,%r10
adox %r15,%r11
mulx 1*8($nptr),%rax,%r15
adcx %rax,%r11
adox %r15,%r12
mulx 2*8($nptr),%rax,%r15
mov %r10,-5*8($tptr)
mov 0*8($tptr),%r10
adcx %rax,%r12
adox %r15,%r13
mulx 3*8($nptr),%rax,%r15
mov $bi,%rdx
mov %r11,-4*8($tptr)
mov %r12,-3*8($tptr)
adcx %rax,%r13
adox $zero,%r15
lea 4*8($nptr),$nptr
mov %r13,-2*8($tptr)
dec $bptr # of=0, pass cf
jnz .Lmulx4x_inner
mov 0(%rsp),$num # load num
mov 8(%rsp),$bptr # re-load &b[i]
movq %xmm0,%rdx # bp[i+1]
adc $zero,%r15 # modulo-scheduled
sub %r10,$zero # pull top-most carry
adc %r15,%r14
sbb %r15,%r15 # top-most carry
mov %r14,-1*8($tptr)
cmp 16(%rsp),$bptr
jb .Lmulx4x_outer
neg $num
mov 32(%rsp),$rptr # restore rp
lea 64(%rsp),$tptr
xor %rdx,%rdx
pxor %xmm0,%xmm0
mov 0*8($nptr,$num),%r8
mov 1*8($nptr,$num),%r9
neg %r8
jmp .Lmulx4x_sub_entry
.align 32
.Lmulx4x_sub:
mov 0*8($nptr,$num),%r8
mov 1*8($nptr,$num),%r9
not %r8
.Lmulx4x_sub_entry:
mov 2*8($nptr,$num),%r10
not %r9
and %r15,%r8
mov 3*8($nptr,$num),%r11
not %r10
and %r15,%r9
not %r11
and %r15,%r10
and %r15,%r11
neg %rdx # mov %rdx,%cf
adc 0*8($tptr),%r8
adc 1*8($tptr),%r9
movdqa %xmm0,($tptr)
adc 2*8($tptr),%r10
adc 3*8($tptr),%r11
movdqa %xmm0,16($tptr)
lea 4*8($tptr),$tptr
sbb %rdx,%rdx # mov %cf,%rdx
mov %r8,0*8($rptr)
mov %r9,1*8($rptr)
mov %r10,2*8($rptr)
mov %r11,3*8($rptr)
lea 4*8($rptr),$rptr
add \$32,$num
jnz .Lmulx4x_sub
mov 56(%rsp),%rsi # restore %rsp
mov \$1,%rax
___
$code.=<<___ if ($win64);
movaps (%rsi),%xmm6
movaps 0x10(%rsi),%xmm7
lea 0x28(%rsi),%rsi
___
$code.=<<___;
mov (%rsi),%r15
mov 8(%rsi),%r14
mov 16(%rsi),%r13
mov 24(%rsi),%r12
mov 32(%rsi),%rbp
mov 40(%rsi),%rbx
lea 48(%rsi),%rsp
.Lmulx4x_epilogue:
ret
.size bn_mulx4x_mont_gather5,.-bn_mulx4x_mont_gather5
___
}}}
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
{
my ($inp,$num,$tbl,$idx)=$win64?("%rcx","%rdx","%r8", "%r9") : # Win64 order
("%rdi","%rsi","%rdx","%rcx"); # Unix order
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
my $out=$inp;
my $STRIDE=2**5*8;
my $N=$STRIDE/4;
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
$code.=<<___;
.globl bn_scatter5
.type bn_scatter5,\@abi-omnipotent
.align 16
bn_scatter5:
Fix OPENSSL_BN_ASM_MONT5 for corner cases; add a test. Submitted by: Emilia Kasper
2011-10-13 12:35:10 +00:00
cmp \$0, $num
jz .Lscatter_epilogue
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
lea ($tbl,$idx,8),$tbl
.Lscatter:
mov ($inp),%rax
lea 8($inp),$inp
mov %rax,($tbl)
lea 32*8($tbl),$tbl
sub \$1,$num
jnz .Lscatter
Fix OPENSSL_BN_ASM_MONT5 for corner cases; add a test. Submitted by: Emilia Kasper
2011-10-13 12:35:10 +00:00
.Lscatter_epilogue:
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
ret
.size bn_scatter5,.-bn_scatter5
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
.globl bn_gather5
.type bn_gather5,\@abi-omnipotent
.align 16
bn_gather5:
___
$code.=<<___ if ($win64);
.LSEH_begin_bn_gather5:
# I can't trust assembler to use specific encoding:-(
.byte 0x48,0x83,0xec,0x28 #sub \$0x28,%rsp
.byte 0x0f,0x29,0x34,0x24 #movaps %xmm6,(%rsp)
.byte 0x0f,0x29,0x7c,0x24,0x10 #movdqa %xmm7,0x10(%rsp)
___
$code.=<<___;
mov $idx,%r11
shr \$`log($N/8)/log(2)`,$idx
and \$`$N/8-1`,%r11
not $idx
lea .Lmagic_masks(%rip),%rax
and \$`2**5/($N/8)-1`,$idx # 5 is "window size"
lea 96($tbl,%r11,8),$tbl # pointer within 1st cache line
movq 0(%rax,$idx,8),%xmm4 # set of masks denoting which
movq 8(%rax,$idx,8),%xmm5 # cache line contains element
movq 16(%rax,$idx,8),%xmm6 # denoted by 7th argument
movq 24(%rax,$idx,8),%xmm7
jmp .Lgather
.align 16
.Lgather:
movq `0*$STRIDE/4-96`($tbl),%xmm0
movq `1*$STRIDE/4-96`($tbl),%xmm1
pand %xmm4,%xmm0
movq `2*$STRIDE/4-96`($tbl),%xmm2
pand %xmm5,%xmm1
movq `3*$STRIDE/4-96`($tbl),%xmm3
pand %xmm6,%xmm2
por %xmm1,%xmm0
pand %xmm7,%xmm3
por %xmm2,%xmm0
lea $STRIDE($tbl),$tbl
por %xmm3,%xmm0
movq %xmm0,($out) # m0=bp[0]
lea 8($out),$out
sub \$1,$num
jnz .Lgather
___
$code.=<<___ if ($win64);
movaps %xmm6,(%rsp)
movaps %xmm7,0x10(%rsp)
lea 0x28(%rsp),%rsp
___
$code.=<<___;
ret
.LSEH_end_bn_gather5:
.size bn_gather5,.-bn_gather5
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
___
}
$code.=<<___;
.align 64
.Lmagic_masks:
.long 0,0, 0,0, 0,0, -1,-1
.long 0,0, 0,0, 0,0, 0,0
.asciz "Montgomery Multiplication with scatter/gather for x86_64, CRYPTOGAMS by <appro\@openssl.org>"
___
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
# EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
# CONTEXT *context,DISPATCHER_CONTEXT *disp)
if ($win64) {
$rec="%rcx";
$frame="%rdx";
$context="%r8";
$disp="%r9";
$code.=<<___;
.extern __imp_RtlVirtualUnwind
.type mul_handler,\@abi-omnipotent
.align 16
mul_handler:
push %rsi
push %rdi
push %rbx
push %rbp
push %r12
push %r13
push %r14
push %r15
pushfq
sub \$64,%rsp
mov 120($context),%rax # pull context->Rax
mov 248($context),%rbx # pull context->Rip
mov 8($disp),%rsi # disp->ImageBase
mov 56($disp),%r11 # disp->HandlerData
mov 0(%r11),%r10d # HandlerData[0]
lea (%rsi,%r10),%r10 # end of prologue label
cmp %r10,%rbx # context->Rip<end of prologue label
jb .Lcommon_seh_tail
lea `40+48`(%rax),%rax
mov 4(%r11),%r10d # HandlerData[1]
lea (%rsi,%r10),%r10 # end of alloca label
cmp %r10,%rbx # context->Rip<end of alloca label
jb .Lcommon_seh_tail
mov 152($context),%rax # pull context->Rsp
mov 8(%r11),%r10d # HandlerData[2]
lea (%rsi,%r10),%r10 # epilogue label
cmp %r10,%rbx # context->Rip>=epilogue label
jae .Lcommon_seh_tail
mov 192($context),%r10 # pull $num
mov 8(%rax,%r10,8),%rax # pull saved stack pointer
movaps (%rax),%xmm0
movaps 16(%rax),%xmm1
lea `40+48`(%rax),%rax
mov -8(%rax),%rbx
mov -16(%rax),%rbp
mov -24(%rax),%r12
mov -32(%rax),%r13
mov -40(%rax),%r14
mov -48(%rax),%r15
mov %rbx,144($context) # restore context->Rbx
mov %rbp,160($context) # restore context->Rbp
mov %r12,216($context) # restore context->R12
mov %r13,224($context) # restore context->R13
mov %r14,232($context) # restore context->R14
mov %r15,240($context) # restore context->R15
movups %xmm0,512($context) # restore context->Xmm6
movups %xmm1,528($context) # restore context->Xmm7
.Lcommon_seh_tail:
mov 8(%rax),%rdi
mov 16(%rax),%rsi
mov %rax,152($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 \$154,%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 mul_handler,.-mul_handler
.section .pdata
.align 4
.rva .LSEH_begin_bn_mul_mont_gather5
.rva .LSEH_end_bn_mul_mont_gather5
.rva .LSEH_info_bn_mul_mont_gather5
.rva .LSEH_begin_bn_mul4x_mont_gather5
.rva .LSEH_end_bn_mul4x_mont_gather5
.rva .LSEH_info_bn_mul4x_mont_gather5
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
.rva .LSEH_begin_bn_gather5
.rva .LSEH_end_bn_gather5
.rva .LSEH_info_bn_gather5
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
.section .xdata
.align 8
.LSEH_info_bn_mul_mont_gather5:
.byte 9,0,0,0
.rva mul_handler
.rva .Lmul_alloca,.Lmul_body,.Lmul_epilogue # HandlerData[]
.align 8
.LSEH_info_bn_mul4x_mont_gather5:
.byte 9,0,0,0
.rva mul_handler
.rva .Lmul4x_alloca,.Lmul4x_body,.Lmul4x_epilogue # HandlerData[]
.align 8
bn_exp.c: further optimizations using more ideas from http://eprint.iacr.org/2011/239.
2011-10-17 17:41:49 +00:00
.LSEH_info_bn_gather5:
.byte 0x01,0x0d,0x05,0x00
.byte 0x0d,0x78,0x01,0x00 #movaps 0x10(rsp),xmm7
.byte 0x08,0x68,0x00,0x00 #movaps (rsp),xmm6
.byte 0x04,0x42,0x00,0x00 #sub rsp,0x28
.align 8
x86_64-mont5.pl: add missing Win64 support.
2011-08-14 09:06:06 +00:00
___
}
This commit completes recent modular exponentiation optimizations on x86_64 platform. It targets specifically RSA1024 sign (using ideas from http://eprint.iacr.org/2011/239) and adds more than 10% on most platforms. Overall performance improvement relative to 1.0.0 is ~40% in average, with best result of 54% on Westmere. Incidentally ~40% is average improvement even for longer key lengths.
2011-08-12 16:44:32 +00:00
$code =~ s/\`([^\`]*)\`/eval($1)/gem;
print $code;
close STDOUT;
Reference in New Issue Copy Permalink