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- #! /usr/bin/env perl
- # Copyright 2005-2018 The OpenSSL Project Authors. All Rights Reserved.
- #
- # Licensed under the OpenSSL license (the "License"). You may not use
- # this file except in compliance with the License. You can obtain a copy
- # in the file LICENSE in the source distribution or at
- # https://www.openssl.org/source/license.html
- # ====================================================================
- # Written by Andy Polyakov <appro@openssl.org> for the OpenSSL
- # project. The module is, however, dual licensed under OpenSSL and
- # CRYPTOGAMS licenses depending on where you obtain it. For further
- # details see http://www.openssl.org/~appro/cryptogams/.
- # ====================================================================
- # October 2005
- #
- # This is a "teaser" code, as it can be improved in several ways...
- # First of all non-SSE2 path should be implemented (yes, for now it
- # performs Montgomery multiplication/convolution only on SSE2-capable
- # CPUs such as P4, others fall down to original code). Then inner loop
- # can be unrolled and modulo-scheduled to improve ILP and possibly
- # moved to 128-bit XMM register bank (though it would require input
- # rearrangement and/or increase bus bandwidth utilization). Dedicated
- # squaring procedure should give further performance improvement...
- # Yet, for being draft, the code improves rsa512 *sign* benchmark by
- # 110%(!), rsa1024 one - by 70% and rsa4096 - by 20%:-)
- # December 2006
- #
- # Modulo-scheduling SSE2 loops results in further 15-20% improvement.
- # Integer-only code [being equipped with dedicated squaring procedure]
- # gives ~40% on rsa512 sign benchmark...
- $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
- push(@INC,"${dir}","${dir}../../perlasm");
- require "x86asm.pl";
- $output = pop;
- open STDOUT,">$output";
- &asm_init($ARGV[0]);
- $sse2=0;
- for (@ARGV) { $sse2=1 if (/-DOPENSSL_IA32_SSE2/); }
- &external_label("OPENSSL_ia32cap_P") if ($sse2);
- &function_begin("bn_mul_mont");
- $i="edx";
- $j="ecx";
- $ap="esi"; $tp="esi"; # overlapping variables!!!
- $rp="edi"; $bp="edi"; # overlapping variables!!!
- $np="ebp";
- $num="ebx";
- $_num=&DWP(4*0,"esp"); # stack top layout
- $_rp=&DWP(4*1,"esp");
- $_ap=&DWP(4*2,"esp");
- $_bp=&DWP(4*3,"esp");
- $_np=&DWP(4*4,"esp");
- $_n0=&DWP(4*5,"esp"); $_n0q=&QWP(4*5,"esp");
- $_sp=&DWP(4*6,"esp");
- $_bpend=&DWP(4*7,"esp");
- $frame=32; # size of above frame rounded up to 16n
- &xor ("eax","eax");
- &mov ("edi",&wparam(5)); # int num
- &cmp ("edi",4);
- &jl (&label("just_leave"));
- &lea ("esi",&wparam(0)); # put aside pointer to argument block
- &lea ("edx",&wparam(1)); # load ap
- &add ("edi",2); # extra two words on top of tp
- &neg ("edi");
- &lea ("ebp",&DWP(-$frame,"esp","edi",4)); # future alloca($frame+4*(num+2))
- &neg ("edi");
- # minimize cache contention by arranging 2K window between stack
- # pointer and ap argument [np is also position sensitive vector,
- # but it's assumed to be near ap, as it's allocated at ~same
- # time].
- &mov ("eax","ebp");
- &sub ("eax","edx");
- &and ("eax",2047);
- &sub ("ebp","eax"); # this aligns sp and ap modulo 2048
- &xor ("edx","ebp");
- &and ("edx",2048);
- &xor ("edx",2048);
- &sub ("ebp","edx"); # this splits them apart modulo 4096
- &and ("ebp",-64); # align to cache line
- # An OS-agnostic version of __chkstk.
- #
- # Some OSes (Windows) insist on stack being "wired" to
- # physical memory in strictly sequential manner, i.e. if stack
- # allocation spans two pages, then reference to farmost one can
- # be punishable by SEGV. But page walking can do good even on
- # other OSes, because it guarantees that villain thread hits
- # the guard page before it can make damage to innocent one...
- &mov ("eax","esp");
- &sub ("eax","ebp");
- &and ("eax",-4096);
- &mov ("edx","esp"); # saved stack pointer!
- &lea ("esp",&DWP(0,"ebp","eax"));
- &mov ("eax",&DWP(0,"esp"));
- &cmp ("esp","ebp");
- &ja (&label("page_walk"));
- &jmp (&label("page_walk_done"));
- &set_label("page_walk",16);
- &lea ("esp",&DWP(-4096,"esp"));
- &mov ("eax",&DWP(0,"esp"));
- &cmp ("esp","ebp");
- &ja (&label("page_walk"));
- &set_label("page_walk_done");
- ################################# load argument block...
- &mov ("eax",&DWP(0*4,"esi"));# BN_ULONG *rp
- &mov ("ebx",&DWP(1*4,"esi"));# const BN_ULONG *ap
- &mov ("ecx",&DWP(2*4,"esi"));# const BN_ULONG *bp
- &mov ("ebp",&DWP(3*4,"esi"));# const BN_ULONG *np
- &mov ("esi",&DWP(4*4,"esi"));# const BN_ULONG *n0
- #&mov ("edi",&DWP(5*4,"esi"));# int num
- &mov ("esi",&DWP(0,"esi")); # pull n0[0]
- &mov ($_rp,"eax"); # ... save a copy of argument block
- &mov ($_ap,"ebx");
- &mov ($_bp,"ecx");
- &mov ($_np,"ebp");
- &mov ($_n0,"esi");
- &lea ($num,&DWP(-3,"edi")); # num=num-1 to assist modulo-scheduling
- #&mov ($_num,$num); # redundant as $num is not reused
- &mov ($_sp,"edx"); # saved stack pointer!
- if($sse2) {
- $acc0="mm0"; # mmx register bank layout
- $acc1="mm1";
- $car0="mm2";
- $car1="mm3";
- $mul0="mm4";
- $mul1="mm5";
- $temp="mm6";
- $mask="mm7";
- &picmeup("eax","OPENSSL_ia32cap_P");
- &bt (&DWP(0,"eax"),26);
- &jnc (&label("non_sse2"));
- &mov ("eax",-1);
- &movd ($mask,"eax"); # mask 32 lower bits
- &mov ($ap,$_ap); # load input pointers
- &mov ($bp,$_bp);
- &mov ($np,$_np);
- &xor ($i,$i); # i=0
- &xor ($j,$j); # j=0
- &movd ($mul0,&DWP(0,$bp)); # bp[0]
- &movd ($mul1,&DWP(0,$ap)); # ap[0]
- &movd ($car1,&DWP(0,$np)); # np[0]
- &pmuludq($mul1,$mul0); # ap[0]*bp[0]
- &movq ($car0,$mul1);
- &movq ($acc0,$mul1); # I wish movd worked for
- &pand ($acc0,$mask); # inter-register transfers
- &pmuludq($mul1,$_n0q); # *=n0
- &pmuludq($car1,$mul1); # "t[0]"*np[0]*n0
- &paddq ($car1,$acc0);
- &movd ($acc1,&DWP(4,$np)); # np[1]
- &movd ($acc0,&DWP(4,$ap)); # ap[1]
- &psrlq ($car0,32);
- &psrlq ($car1,32);
- &inc ($j); # j++
- &set_label("1st",16);
- &pmuludq($acc0,$mul0); # ap[j]*bp[0]
- &pmuludq($acc1,$mul1); # np[j]*m1
- &paddq ($car0,$acc0); # +=c0
- &paddq ($car1,$acc1); # +=c1
- &movq ($acc0,$car0);
- &pand ($acc0,$mask);
- &movd ($acc1,&DWP(4,$np,$j,4)); # np[j+1]
- &paddq ($car1,$acc0); # +=ap[j]*bp[0];
- &movd ($acc0,&DWP(4,$ap,$j,4)); # ap[j+1]
- &psrlq ($car0,32);
- &movd (&DWP($frame-4,"esp",$j,4),$car1); # tp[j-1]=
- &psrlq ($car1,32);
- &lea ($j,&DWP(1,$j));
- &cmp ($j,$num);
- &jl (&label("1st"));
- &pmuludq($acc0,$mul0); # ap[num-1]*bp[0]
- &pmuludq($acc1,$mul1); # np[num-1]*m1
- &paddq ($car0,$acc0); # +=c0
- &paddq ($car1,$acc1); # +=c1
- &movq ($acc0,$car0);
- &pand ($acc0,$mask);
- &paddq ($car1,$acc0); # +=ap[num-1]*bp[0];
- &movd (&DWP($frame-4,"esp",$j,4),$car1); # tp[num-2]=
- &psrlq ($car0,32);
- &psrlq ($car1,32);
- &paddq ($car1,$car0);
- &movq (&QWP($frame,"esp",$num,4),$car1); # tp[num].tp[num-1]
- &inc ($i); # i++
- &set_label("outer");
- &xor ($j,$j); # j=0
- &movd ($mul0,&DWP(0,$bp,$i,4)); # bp[i]
- &movd ($mul1,&DWP(0,$ap)); # ap[0]
- &movd ($temp,&DWP($frame,"esp")); # tp[0]
- &movd ($car1,&DWP(0,$np)); # np[0]
- &pmuludq($mul1,$mul0); # ap[0]*bp[i]
- &paddq ($mul1,$temp); # +=tp[0]
- &movq ($acc0,$mul1);
- &movq ($car0,$mul1);
- &pand ($acc0,$mask);
- &pmuludq($mul1,$_n0q); # *=n0
- &pmuludq($car1,$mul1);
- &paddq ($car1,$acc0);
- &movd ($temp,&DWP($frame+4,"esp")); # tp[1]
- &movd ($acc1,&DWP(4,$np)); # np[1]
- &movd ($acc0,&DWP(4,$ap)); # ap[1]
- &psrlq ($car0,32);
- &psrlq ($car1,32);
- &paddq ($car0,$temp); # +=tp[1]
- &inc ($j); # j++
- &dec ($num);
- &set_label("inner");
- &pmuludq($acc0,$mul0); # ap[j]*bp[i]
- &pmuludq($acc1,$mul1); # np[j]*m1
- &paddq ($car0,$acc0); # +=c0
- &paddq ($car1,$acc1); # +=c1
- &movq ($acc0,$car0);
- &movd ($temp,&DWP($frame+4,"esp",$j,4));# tp[j+1]
- &pand ($acc0,$mask);
- &movd ($acc1,&DWP(4,$np,$j,4)); # np[j+1]
- &paddq ($car1,$acc0); # +=ap[j]*bp[i]+tp[j]
- &movd ($acc0,&DWP(4,$ap,$j,4)); # ap[j+1]
- &psrlq ($car0,32);
- &movd (&DWP($frame-4,"esp",$j,4),$car1);# tp[j-1]=
- &psrlq ($car1,32);
- &paddq ($car0,$temp); # +=tp[j+1]
- &dec ($num);
- &lea ($j,&DWP(1,$j)); # j++
- &jnz (&label("inner"));
- &mov ($num,$j);
- &pmuludq($acc0,$mul0); # ap[num-1]*bp[i]
- &pmuludq($acc1,$mul1); # np[num-1]*m1
- &paddq ($car0,$acc0); # +=c0
- &paddq ($car1,$acc1); # +=c1
- &movq ($acc0,$car0);
- &pand ($acc0,$mask);
- &paddq ($car1,$acc0); # +=ap[num-1]*bp[i]+tp[num-1]
- &movd (&DWP($frame-4,"esp",$j,4),$car1); # tp[num-2]=
- &psrlq ($car0,32);
- &psrlq ($car1,32);
- &movd ($temp,&DWP($frame+4,"esp",$num,4)); # += tp[num]
- &paddq ($car1,$car0);
- &paddq ($car1,$temp);
- &movq (&QWP($frame,"esp",$num,4),$car1); # tp[num].tp[num-1]
- &lea ($i,&DWP(1,$i)); # i++
- &cmp ($i,$num);
- &jle (&label("outer"));
- &emms (); # done with mmx bank
- &jmp (&label("common_tail"));
- &set_label("non_sse2",16);
- }
- if (0) {
- &mov ("esp",$_sp);
- &xor ("eax","eax"); # signal "not fast enough [yet]"
- &jmp (&label("just_leave"));
- # While the below code provides competitive performance for
- # all key lengths on modern Intel cores, it's still more
- # than 10% slower for 4096-bit key elsewhere:-( "Competitive"
- # means compared to the original integer-only assembler.
- # 512-bit RSA sign is better by ~40%, but that's about all
- # one can say about all CPUs...
- } else {
- $inp="esi"; # integer path uses these registers differently
- $word="edi";
- $carry="ebp";
- &mov ($inp,$_ap);
- &lea ($carry,&DWP(1,$num));
- &mov ($word,$_bp);
- &xor ($j,$j); # j=0
- &mov ("edx",$inp);
- &and ($carry,1); # see if num is even
- &sub ("edx",$word); # see if ap==bp
- &lea ("eax",&DWP(4,$word,$num,4)); # &bp[num]
- &or ($carry,"edx");
- &mov ($word,&DWP(0,$word)); # bp[0]
- &jz (&label("bn_sqr_mont"));
- &mov ($_bpend,"eax");
- &mov ("eax",&DWP(0,$inp));
- &xor ("edx","edx");
- &set_label("mull",16);
- &mov ($carry,"edx");
- &mul ($word); # ap[j]*bp[0]
- &add ($carry,"eax");
- &lea ($j,&DWP(1,$j));
- &adc ("edx",0);
- &mov ("eax",&DWP(0,$inp,$j,4)); # ap[j+1]
- &cmp ($j,$num);
- &mov (&DWP($frame-4,"esp",$j,4),$carry); # tp[j]=
- &jl (&label("mull"));
- &mov ($carry,"edx");
- &mul ($word); # ap[num-1]*bp[0]
- &mov ($word,$_n0);
- &add ("eax",$carry);
- &mov ($inp,$_np);
- &adc ("edx",0);
- &imul ($word,&DWP($frame,"esp")); # n0*tp[0]
- &mov (&DWP($frame,"esp",$num,4),"eax"); # tp[num-1]=
- &xor ($j,$j);
- &mov (&DWP($frame+4,"esp",$num,4),"edx"); # tp[num]=
- &mov (&DWP($frame+8,"esp",$num,4),$j); # tp[num+1]=
- &mov ("eax",&DWP(0,$inp)); # np[0]
- &mul ($word); # np[0]*m
- &add ("eax",&DWP($frame,"esp")); # +=tp[0]
- &mov ("eax",&DWP(4,$inp)); # np[1]
- &adc ("edx",0);
- &inc ($j);
- &jmp (&label("2ndmadd"));
- &set_label("1stmadd",16);
- &mov ($carry,"edx");
- &mul ($word); # ap[j]*bp[i]
- &add ($carry,&DWP($frame,"esp",$j,4)); # +=tp[j]
- &lea ($j,&DWP(1,$j));
- &adc ("edx",0);
- &add ($carry,"eax");
- &mov ("eax",&DWP(0,$inp,$j,4)); # ap[j+1]
- &adc ("edx",0);
- &cmp ($j,$num);
- &mov (&DWP($frame-4,"esp",$j,4),$carry); # tp[j]=
- &jl (&label("1stmadd"));
- &mov ($carry,"edx");
- &mul ($word); # ap[num-1]*bp[i]
- &add ("eax",&DWP($frame,"esp",$num,4)); # +=tp[num-1]
- &mov ($word,$_n0);
- &adc ("edx",0);
- &mov ($inp,$_np);
- &add ($carry,"eax");
- &adc ("edx",0);
- &imul ($word,&DWP($frame,"esp")); # n0*tp[0]
- &xor ($j,$j);
- &add ("edx",&DWP($frame+4,"esp",$num,4)); # carry+=tp[num]
- &mov (&DWP($frame,"esp",$num,4),$carry); # tp[num-1]=
- &adc ($j,0);
- &mov ("eax",&DWP(0,$inp)); # np[0]
- &mov (&DWP($frame+4,"esp",$num,4),"edx"); # tp[num]=
- &mov (&DWP($frame+8,"esp",$num,4),$j); # tp[num+1]=
- &mul ($word); # np[0]*m
- &add ("eax",&DWP($frame,"esp")); # +=tp[0]
- &mov ("eax",&DWP(4,$inp)); # np[1]
- &adc ("edx",0);
- &mov ($j,1);
- &set_label("2ndmadd",16);
- &mov ($carry,"edx");
- &mul ($word); # np[j]*m
- &add ($carry,&DWP($frame,"esp",$j,4)); # +=tp[j]
- &lea ($j,&DWP(1,$j));
- &adc ("edx",0);
- &add ($carry,"eax");
- &mov ("eax",&DWP(0,$inp,$j,4)); # np[j+1]
- &adc ("edx",0);
- &cmp ($j,$num);
- &mov (&DWP($frame-8,"esp",$j,4),$carry); # tp[j-1]=
- &jl (&label("2ndmadd"));
- &mov ($carry,"edx");
- &mul ($word); # np[j]*m
- &add ($carry,&DWP($frame,"esp",$num,4)); # +=tp[num-1]
- &adc ("edx",0);
- &add ($carry,"eax");
- &adc ("edx",0);
- &mov (&DWP($frame-4,"esp",$num,4),$carry); # tp[num-2]=
- &xor ("eax","eax");
- &mov ($j,$_bp); # &bp[i]
- &add ("edx",&DWP($frame+4,"esp",$num,4)); # carry+=tp[num]
- &adc ("eax",&DWP($frame+8,"esp",$num,4)); # +=tp[num+1]
- &lea ($j,&DWP(4,$j));
- &mov (&DWP($frame,"esp",$num,4),"edx"); # tp[num-1]=
- &cmp ($j,$_bpend);
- &mov (&DWP($frame+4,"esp",$num,4),"eax"); # tp[num]=
- &je (&label("common_tail"));
- &mov ($word,&DWP(0,$j)); # bp[i+1]
- &mov ($inp,$_ap);
- &mov ($_bp,$j); # &bp[++i]
- &xor ($j,$j);
- &xor ("edx","edx");
- &mov ("eax",&DWP(0,$inp));
- &jmp (&label("1stmadd"));
- &set_label("bn_sqr_mont",16);
- $sbit=$num;
- &mov ($_num,$num);
- &mov ($_bp,$j); # i=0
- &mov ("eax",$word); # ap[0]
- &mul ($word); # ap[0]*ap[0]
- &mov (&DWP($frame,"esp"),"eax"); # tp[0]=
- &mov ($sbit,"edx");
- &shr ("edx",1);
- &and ($sbit,1);
- &inc ($j);
- &set_label("sqr",16);
- &mov ("eax",&DWP(0,$inp,$j,4)); # ap[j]
- &mov ($carry,"edx");
- &mul ($word); # ap[j]*ap[0]
- &add ("eax",$carry);
- &lea ($j,&DWP(1,$j));
- &adc ("edx",0);
- &lea ($carry,&DWP(0,$sbit,"eax",2));
- &shr ("eax",31);
- &cmp ($j,$_num);
- &mov ($sbit,"eax");
- &mov (&DWP($frame-4,"esp",$j,4),$carry); # tp[j]=
- &jl (&label("sqr"));
- &mov ("eax",&DWP(0,$inp,$j,4)); # ap[num-1]
- &mov ($carry,"edx");
- &mul ($word); # ap[num-1]*ap[0]
- &add ("eax",$carry);
- &mov ($word,$_n0);
- &adc ("edx",0);
- &mov ($inp,$_np);
- &lea ($carry,&DWP(0,$sbit,"eax",2));
- &imul ($word,&DWP($frame,"esp")); # n0*tp[0]
- &shr ("eax",31);
- &mov (&DWP($frame,"esp",$j,4),$carry); # tp[num-1]=
- &lea ($carry,&DWP(0,"eax","edx",2));
- &mov ("eax",&DWP(0,$inp)); # np[0]
- &shr ("edx",31);
- &mov (&DWP($frame+4,"esp",$j,4),$carry); # tp[num]=
- &mov (&DWP($frame+8,"esp",$j,4),"edx"); # tp[num+1]=
- &mul ($word); # np[0]*m
- &add ("eax",&DWP($frame,"esp")); # +=tp[0]
- &mov ($num,$j);
- &adc ("edx",0);
- &mov ("eax",&DWP(4,$inp)); # np[1]
- &mov ($j,1);
- &set_label("3rdmadd",16);
- &mov ($carry,"edx");
- &mul ($word); # np[j]*m
- &add ($carry,&DWP($frame,"esp",$j,4)); # +=tp[j]
- &adc ("edx",0);
- &add ($carry,"eax");
- &mov ("eax",&DWP(4,$inp,$j,4)); # np[j+1]
- &adc ("edx",0);
- &mov (&DWP($frame-4,"esp",$j,4),$carry); # tp[j-1]=
- &mov ($carry,"edx");
- &mul ($word); # np[j+1]*m
- &add ($carry,&DWP($frame+4,"esp",$j,4)); # +=tp[j+1]
- &lea ($j,&DWP(2,$j));
- &adc ("edx",0);
- &add ($carry,"eax");
- &mov ("eax",&DWP(0,$inp,$j,4)); # np[j+2]
- &adc ("edx",0);
- &cmp ($j,$num);
- &mov (&DWP($frame-8,"esp",$j,4),$carry); # tp[j]=
- &jl (&label("3rdmadd"));
- &mov ($carry,"edx");
- &mul ($word); # np[j]*m
- &add ($carry,&DWP($frame,"esp",$num,4)); # +=tp[num-1]
- &adc ("edx",0);
- &add ($carry,"eax");
- &adc ("edx",0);
- &mov (&DWP($frame-4,"esp",$num,4),$carry); # tp[num-2]=
- &mov ($j,$_bp); # i
- &xor ("eax","eax");
- &mov ($inp,$_ap);
- &add ("edx",&DWP($frame+4,"esp",$num,4)); # carry+=tp[num]
- &adc ("eax",&DWP($frame+8,"esp",$num,4)); # +=tp[num+1]
- &mov (&DWP($frame,"esp",$num,4),"edx"); # tp[num-1]=
- &cmp ($j,$num);
- &mov (&DWP($frame+4,"esp",$num,4),"eax"); # tp[num]=
- &je (&label("common_tail"));
- &mov ($word,&DWP(4,$inp,$j,4)); # ap[i]
- &lea ($j,&DWP(1,$j));
- &mov ("eax",$word);
- &mov ($_bp,$j); # ++i
- &mul ($word); # ap[i]*ap[i]
- &add ("eax",&DWP($frame,"esp",$j,4)); # +=tp[i]
- &adc ("edx",0);
- &mov (&DWP($frame,"esp",$j,4),"eax"); # tp[i]=
- &xor ($carry,$carry);
- &cmp ($j,$num);
- &lea ($j,&DWP(1,$j));
- &je (&label("sqrlast"));
- &mov ($sbit,"edx"); # zaps $num
- &shr ("edx",1);
- &and ($sbit,1);
- &set_label("sqradd",16);
- &mov ("eax",&DWP(0,$inp,$j,4)); # ap[j]
- &mov ($carry,"edx");
- &mul ($word); # ap[j]*ap[i]
- &add ("eax",$carry);
- &lea ($carry,&DWP(0,"eax","eax"));
- &adc ("edx",0);
- &shr ("eax",31);
- &add ($carry,&DWP($frame,"esp",$j,4)); # +=tp[j]
- &lea ($j,&DWP(1,$j));
- &adc ("eax",0);
- &add ($carry,$sbit);
- &adc ("eax",0);
- &cmp ($j,$_num);
- &mov (&DWP($frame-4,"esp",$j,4),$carry); # tp[j]=
- &mov ($sbit,"eax");
- &jle (&label("sqradd"));
- &mov ($carry,"edx");
- &add ("edx","edx");
- &shr ($carry,31);
- &add ("edx",$sbit);
- &adc ($carry,0);
- &set_label("sqrlast");
- &mov ($word,$_n0);
- &mov ($inp,$_np);
- &imul ($word,&DWP($frame,"esp")); # n0*tp[0]
- &add ("edx",&DWP($frame,"esp",$j,4)); # +=tp[num]
- &mov ("eax",&DWP(0,$inp)); # np[0]
- &adc ($carry,0);
- &mov (&DWP($frame,"esp",$j,4),"edx"); # tp[num]=
- &mov (&DWP($frame+4,"esp",$j,4),$carry); # tp[num+1]=
- &mul ($word); # np[0]*m
- &add ("eax",&DWP($frame,"esp")); # +=tp[0]
- &lea ($num,&DWP(-1,$j));
- &adc ("edx",0);
- &mov ($j,1);
- &mov ("eax",&DWP(4,$inp)); # np[1]
- &jmp (&label("3rdmadd"));
- }
- &set_label("common_tail",16);
- &mov ($np,$_np); # load modulus pointer
- &mov ($rp,$_rp); # load result pointer
- &lea ($tp,&DWP($frame,"esp")); # [$ap and $bp are zapped]
- &mov ("eax",&DWP(0,$tp)); # tp[0]
- &mov ($j,$num); # j=num-1
- &xor ($i,$i); # i=0 and clear CF!
- &set_label("sub",16);
- &sbb ("eax",&DWP(0,$np,$i,4));
- &mov (&DWP(0,$rp,$i,4),"eax"); # rp[i]=tp[i]-np[i]
- &dec ($j); # doesn't affect CF!
- &mov ("eax",&DWP(4,$tp,$i,4)); # tp[i+1]
- &lea ($i,&DWP(1,$i)); # i++
- &jge (&label("sub"));
- &sbb ("eax",0); # handle upmost overflow bit
- &mov ("edx",-1);
- &xor ("edx","eax");
- &jmp (&label("copy"));
- &set_label("copy",16); # conditional copy
- &mov ($tp,&DWP($frame,"esp",$num,4));
- &mov ($np,&DWP(0,$rp,$num,4));
- &mov (&DWP($frame,"esp",$num,4),$j); # zap temporary vector
- &and ($tp,"eax");
- &and ($np,"edx");
- &or ($np,$tp);
- &mov (&DWP(0,$rp,$num,4),$np);
- &dec ($num);
- &jge (&label("copy"));
- &mov ("esp",$_sp); # pull saved stack pointer
- &mov ("eax",1);
- &set_label("just_leave");
- &function_end("bn_mul_mont");
- &asciz("Montgomery Multiplication for x86, CRYPTOGAMS by <appro\@openssl.org>");
- &asm_finish();
- close STDOUT;
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