Import OpenSSL 1.0.1q.

[dragonfly.git] / crypto / openssl / crypto / bn / asm / x86_64-gf2m.pl

#!/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/.
# ====================================================================
#
# May 2011
#
# The module implements bn_GF2m_mul_2x2 polynomial multiplication used
# in bn_gf2m.c. It's kind of low-hanging mechanical port from C for
# the time being... Except that it has two code paths: code suitable
# for any x86_64 CPU and PCLMULQDQ one suitable for Westmere and
# later. Improvement varies from one benchmark and µ-arch to another.
# Vanilla code path is at most 20% faster than compiler-generated code
# [not very impressive], while PCLMULQDQ - whole 85%-160% better on
# 163- and 571-bit ECDH benchmarks on Intel CPUs. Keep in mind that
# these coefficients are not ones for bn_GF2m_mul_2x2 itself, as not
# all CPU time is burnt in it...

$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";

open OUT,"| \"$^X\" $xlate $flavour $output";
*STDOUT=*OUT;

($lo,$hi)=("%rax","%rdx");      $a=$lo;
($i0,$i1)=("%rsi","%rdi");
($t0,$t1)=("%rbx","%rcx");
($b,$mask)=("%rbp","%r8");
($a1,$a2,$a4,$a8,$a12,$a48)=map("%r$_",(9..15));
($R,$Tx)=("%xmm0","%xmm1");

$code.=<<___;
.text

.type   _mul_1x1,\@abi-omnipotent
.align  16
_mul_1x1:
        sub     \$128+8,%rsp
        mov     \$-1,$a1
        lea     ($a,$a),$i0
        shr     \$3,$a1
        lea     (,$a,4),$i1
        and     $a,$a1                  # a1=a&0x1fffffffffffffff
        lea     (,$a,8),$a8
        sar     \$63,$a                 # broadcast 63rd bit
        lea     ($a1,$a1),$a2
        sar     \$63,$i0                # broadcast 62nd bit
        lea     (,$a1,4),$a4
        and     $b,$a
        sar     \$63,$i1                # boardcast 61st bit
        mov     $a,$hi                  # $a is $lo
        shl     \$63,$lo
        and     $b,$i0
        shr     \$1,$hi
        mov     $i0,$t1
        shl     \$62,$i0
        and     $b,$i1
        shr     \$2,$t1
        xor     $i0,$lo
        mov     $i1,$t0
        shl     \$61,$i1
        xor     $t1,$hi
        shr     \$3,$t0
        xor     $i1,$lo
        xor     $t0,$hi

        mov     $a1,$a12
        movq    \$0,0(%rsp)             # tab[0]=0
        xor     $a2,$a12                # a1^a2
        mov     $a1,8(%rsp)             # tab[1]=a1
         mov    $a4,$a48
        mov     $a2,16(%rsp)            # tab[2]=a2
         xor    $a8,$a48                # a4^a8
        mov     $a12,24(%rsp)           # tab[3]=a1^a2

        xor     $a4,$a1
        mov     $a4,32(%rsp)            # tab[4]=a4
        xor     $a4,$a2
        mov     $a1,40(%rsp)            # tab[5]=a1^a4
        xor     $a4,$a12
        mov     $a2,48(%rsp)            # tab[6]=a2^a4
         xor    $a48,$a1                # a1^a4^a4^a8=a1^a8
        mov     $a12,56(%rsp)           # tab[7]=a1^a2^a4
         xor    $a48,$a2                # a2^a4^a4^a8=a1^a8

        mov     $a8,64(%rsp)            # tab[8]=a8
        xor     $a48,$a12               # a1^a2^a4^a4^a8=a1^a2^a8
        mov     $a1,72(%rsp)            # tab[9]=a1^a8
         xor    $a4,$a1                 # a1^a8^a4
        mov     $a2,80(%rsp)            # tab[10]=a2^a8
         xor    $a4,$a2                 # a2^a8^a4
        mov     $a12,88(%rsp)           # tab[11]=a1^a2^a8

        xor     $a4,$a12                # a1^a2^a8^a4
        mov     $a48,96(%rsp)           # tab[12]=a4^a8
         mov    $mask,$i0
        mov     $a1,104(%rsp)           # tab[13]=a1^a4^a8
         and    $b,$i0
        mov     $a2,112(%rsp)           # tab[14]=a2^a4^a8
         shr    \$4,$b
        mov     $a12,120(%rsp)          # tab[15]=a1^a2^a4^a8
         mov    $mask,$i1
         and    $b,$i1
         shr    \$4,$b

        movq    (%rsp,$i0,8),$R         # half of calculations is done in SSE2
        mov     $mask,$i0
        and     $b,$i0
        shr     \$4,$b
___
    for ($n=1;$n<8;$n++) {
        $code.=<<___;
        mov     (%rsp,$i1,8),$t1
        mov     $mask,$i1
        mov     $t1,$t0
        shl     \$`8*$n-4`,$t1
        and     $b,$i1
         movq   (%rsp,$i0,8),$Tx
        shr     \$`64-(8*$n-4)`,$t0
        xor     $t1,$lo
         pslldq \$$n,$Tx
         mov    $mask,$i0
        shr     \$4,$b
        xor     $t0,$hi
         and    $b,$i0
         shr    \$4,$b
         pxor   $Tx,$R
___
    }
$code.=<<___;
        mov     (%rsp,$i1,8),$t1
        mov     $t1,$t0
        shl     \$`8*$n-4`,$t1
        movq    $R,$i0
        shr     \$`64-(8*$n-4)`,$t0
        xor     $t1,$lo
        psrldq  \$8,$R
        xor     $t0,$hi
        movq    $R,$i1
        xor     $i0,$lo
        xor     $i1,$hi

        add     \$128+8,%rsp
        ret
.Lend_mul_1x1:
.size   _mul_1x1,.-_mul_1x1
___

($rp,$a1,$a0,$b1,$b0) = $win64? ("%rcx","%rdx","%r8", "%r9","%r10") :   # Win64 order
                                ("%rdi","%rsi","%rdx","%rcx","%r8");    # Unix order

$code.=<<___;
.extern OPENSSL_ia32cap_P
.globl  bn_GF2m_mul_2x2
.type   bn_GF2m_mul_2x2,\@abi-omnipotent
.align  16
bn_GF2m_mul_2x2:
        mov     OPENSSL_ia32cap_P(%rip),%rax
        bt      \$33,%rax
        jnc     .Lvanilla_mul_2x2

        movq            $a1,%xmm0
        movq            $b1,%xmm1
        movq            $a0,%xmm2
___
$code.=<<___ if ($win64);
        movq            40(%rsp),%xmm3
___
$code.=<<___ if (!$win64);
        movq            $b0,%xmm3
___
$code.=<<___;
        movdqa          %xmm0,%xmm4
        movdqa          %xmm1,%xmm5
        pclmulqdq       \$0,%xmm1,%xmm0 # a1·b1
        pxor            %xmm2,%xmm4
        pxor            %xmm3,%xmm5
        pclmulqdq       \$0,%xmm3,%xmm2 # a0·b0
        pclmulqdq       \$0,%xmm5,%xmm4 # (a0+a1)·(b0+b1)
        xorps           %xmm0,%xmm4
        xorps           %xmm2,%xmm4     # (a0+a1)·(b0+b1)-a0·b0-a1·b1
        movdqa          %xmm4,%xmm5
        pslldq          \$8,%xmm4
        psrldq          \$8,%xmm5
        pxor            %xmm4,%xmm2
        pxor            %xmm5,%xmm0
        movdqu          %xmm2,0($rp)
        movdqu          %xmm0,16($rp)
        ret

.align  16
.Lvanilla_mul_2x2:
        lea     -8*17(%rsp),%rsp
___
$code.=<<___ if ($win64);
        mov     `8*17+40`(%rsp),$b0
        mov     %rdi,8*15(%rsp)
        mov     %rsi,8*16(%rsp)
___
$code.=<<___;
        mov     %r14,8*10(%rsp)
        mov     %r13,8*11(%rsp)
        mov     %r12,8*12(%rsp)
        mov     %rbp,8*13(%rsp)
        mov     %rbx,8*14(%rsp)
.Lbody_mul_2x2:
        mov     $rp,32(%rsp)            # save the arguments
        mov     $a1,40(%rsp)
        mov     $a0,48(%rsp)
        mov     $b1,56(%rsp)
        mov     $b0,64(%rsp)

        mov     \$0xf,$mask
        mov     $a1,$a
        mov     $b1,$b
        call    _mul_1x1                # a1·b1
        mov     $lo,16(%rsp)
        mov     $hi,24(%rsp)

        mov     48(%rsp),$a
        mov     64(%rsp),$b
        call    _mul_1x1                # a0·b0
        mov     $lo,0(%rsp)
        mov     $hi,8(%rsp)

        mov     40(%rsp),$a
        mov     56(%rsp),$b
        xor     48(%rsp),$a
        xor     64(%rsp),$b
        call    _mul_1x1                # (a0+a1)·(b0+b1)
___
        @r=("%rbx","%rcx","%rdi","%rsi");
$code.=<<___;
        mov     0(%rsp),@r[0]
        mov     8(%rsp),@r[1]
        mov     16(%rsp),@r[2]
        mov     24(%rsp),@r[3]
        mov     32(%rsp),%rbp

        xor     $hi,$lo
        xor     @r[1],$hi
        xor     @r[0],$lo
        mov     @r[0],0(%rbp)
        xor     @r[2],$hi
        mov     @r[3],24(%rbp)
        xor     @r[3],$lo
        xor     @r[3],$hi
        xor     $hi,$lo
        mov     $hi,16(%rbp)
        mov     $lo,8(%rbp)

        mov     8*10(%rsp),%r14
        mov     8*11(%rsp),%r13
        mov     8*12(%rsp),%r12
        mov     8*13(%rsp),%rbp
        mov     8*14(%rsp),%rbx
___
$code.=<<___ if ($win64);
        mov     8*15(%rsp),%rdi
        mov     8*16(%rsp),%rsi
___
$code.=<<___;
        lea     8*17(%rsp),%rsp
        ret
.Lend_mul_2x2:
.size   bn_GF2m_mul_2x2,.-bn_GF2m_mul_2x2
.asciz  "GF(2^m) Multiplication for x86_64, CRYPTOGAMS by <appro\@openssl.org>"
.align  16
___

# 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     152($context),%rax      # pull context->Rsp
        mov     248($context),%rbx      # pull context->Rip

        lea     .Lbody_mul_2x2(%rip),%r10
        cmp     %r10,%rbx               # context->Rip<"prologue" label
        jb      .Lin_prologue

        mov     8*10(%rax),%r14         # mimic epilogue
        mov     8*11(%rax),%r13
        mov     8*12(%rax),%r12
        mov     8*13(%rax),%rbp
        mov     8*14(%rax),%rbx
        mov     8*15(%rax),%rdi
        mov     8*16(%rax),%rsi

        mov     %rbx,144($context)      # restore context->Rbx
        mov     %rbp,160($context)      # restore context->Rbp
        mov     %rsi,168($context)      # restore context->Rsi
        mov     %rdi,176($context)      # restore context->Rdi
        mov     %r12,216($context)      # restore context->R12
        mov     %r13,224($context)      # restore context->R13
        mov     %r14,232($context)      # restore context->R14

.Lin_prologue:
        lea     8*17(%rax),%rax
        mov     %rax,152($context)      # restore context->Rsp

        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   se_handler,.-se_handler

.section        .pdata
.align  4
        .rva    _mul_1x1
        .rva    .Lend_mul_1x1
        .rva    .LSEH_info_1x1

        .rva    .Lvanilla_mul_2x2
        .rva    .Lend_mul_2x2
        .rva    .LSEH_info_2x2
.section        .xdata
.align  8
.LSEH_info_1x1:
        .byte   0x01,0x07,0x02,0x00
        .byte   0x07,0x01,0x11,0x00     # sub rsp,128+8
.LSEH_info_2x2:
        .byte   9,0,0,0
        .rva    se_handler
___
}

$code =~ s/\`([^\`]*)\`/eval($1)/gem;
print $code;
close STDOUT;