6aa36e8e5a
Reviewed-by: Richard Levitte <levitte@openssl.org>
342 lines
7.8 KiB
Raku
342 lines
7.8 KiB
Raku
#! /usr/bin/env perl
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# Copyright 2006-2016 The OpenSSL Project Authors. All Rights Reserved.
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#
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# Licensed under the OpenSSL license (the "License"). You may not use
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# this file except in compliance with the License. You can obtain a copy
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# in the file LICENSE in the source distribution or at
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# https://www.openssl.org/source/license.html
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# ====================================================================
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# Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
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# project. The module is, however, dual licensed under OpenSSL and
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# CRYPTOGAMS licenses depending on where you obtain it. For further
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# details see http://www.openssl.org/~appro/cryptogams/.
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# ====================================================================
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# April 2006
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# "Teaser" Montgomery multiplication module for PowerPC. It's possible
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# to gain a bit more by modulo-scheduling outer loop, then dedicated
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# squaring procedure should give further 20% and code can be adapted
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# for 32-bit application running on 64-bit CPU. As for the latter.
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# It won't be able to achieve "native" 64-bit performance, because in
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# 32-bit application context every addc instruction will have to be
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# expanded as addc, twice right shift by 32 and finally adde, etc.
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# So far RSA *sign* performance improvement over pre-bn_mul_mont asm
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# for 64-bit application running on PPC970/G5 is:
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#
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# 512-bit +65%
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# 1024-bit +35%
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# 2048-bit +18%
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# 4096-bit +4%
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$flavour = shift;
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if ($flavour =~ /32/) {
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$BITS= 32;
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$BNSZ= $BITS/8;
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$SIZE_T=4;
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$RZONE= 224;
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$LD= "lwz"; # load
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$LDU= "lwzu"; # load and update
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$LDX= "lwzx"; # load indexed
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$ST= "stw"; # store
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$STU= "stwu"; # store and update
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$STX= "stwx"; # store indexed
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$STUX= "stwux"; # store indexed and update
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$UMULL= "mullw"; # unsigned multiply low
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$UMULH= "mulhwu"; # unsigned multiply high
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$UCMP= "cmplw"; # unsigned compare
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$SHRI= "srwi"; # unsigned shift right by immediate
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$PUSH= $ST;
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$POP= $LD;
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} elsif ($flavour =~ /64/) {
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$BITS= 64;
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$BNSZ= $BITS/8;
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$SIZE_T=8;
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$RZONE= 288;
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# same as above, but 64-bit mnemonics...
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$LD= "ld"; # load
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$LDU= "ldu"; # load and update
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$LDX= "ldx"; # load indexed
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$ST= "std"; # store
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$STU= "stdu"; # store and update
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$STX= "stdx"; # store indexed
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$STUX= "stdux"; # store indexed and update
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$UMULL= "mulld"; # unsigned multiply low
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$UMULH= "mulhdu"; # unsigned multiply high
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$UCMP= "cmpld"; # unsigned compare
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$SHRI= "srdi"; # unsigned shift right by immediate
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$PUSH= $ST;
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$POP= $LD;
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} else { die "nonsense $flavour"; }
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$FRAME=8*$SIZE_T+$RZONE;
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$LOCALS=8*$SIZE_T;
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$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
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( $xlate="${dir}ppc-xlate.pl" and -f $xlate ) or
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( $xlate="${dir}../../perlasm/ppc-xlate.pl" and -f $xlate) or
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die "can't locate ppc-xlate.pl";
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open STDOUT,"| $^X $xlate $flavour ".shift || die "can't call $xlate: $!";
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$sp="r1";
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$toc="r2";
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$rp="r3"; $ovf="r3";
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$ap="r4";
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$bp="r5";
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$np="r6";
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$n0="r7";
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$num="r8";
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$rp="r9"; # $rp is reassigned
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$aj="r10";
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$nj="r11";
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$tj="r12";
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# non-volatile registers
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$i="r20";
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$j="r21";
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$tp="r22";
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$m0="r23";
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$m1="r24";
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$lo0="r25";
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$hi0="r26";
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$lo1="r27";
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$hi1="r28";
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$alo="r29";
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$ahi="r30";
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$nlo="r31";
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#
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$nhi="r0";
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$code=<<___;
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.machine "any"
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.text
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.globl .bn_mul_mont_int
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.align 4
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.bn_mul_mont_int:
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cmpwi $num,4
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mr $rp,r3 ; $rp is reassigned
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li r3,0
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bltlr
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___
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$code.=<<___ if ($BNSZ==4);
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cmpwi $num,32 ; longer key performance is not better
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bgelr
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___
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$code.=<<___;
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slwi $num,$num,`log($BNSZ)/log(2)`
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li $tj,-4096
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addi $ovf,$num,$FRAME
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subf $ovf,$ovf,$sp ; $sp-$ovf
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and $ovf,$ovf,$tj ; minimize TLB usage
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subf $ovf,$sp,$ovf ; $ovf-$sp
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mr $tj,$sp
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srwi $num,$num,`log($BNSZ)/log(2)`
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$STUX $sp,$sp,$ovf
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$PUSH r20,`-12*$SIZE_T`($tj)
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$PUSH r21,`-11*$SIZE_T`($tj)
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$PUSH r22,`-10*$SIZE_T`($tj)
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$PUSH r23,`-9*$SIZE_T`($tj)
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$PUSH r24,`-8*$SIZE_T`($tj)
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$PUSH r25,`-7*$SIZE_T`($tj)
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$PUSH r26,`-6*$SIZE_T`($tj)
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$PUSH r27,`-5*$SIZE_T`($tj)
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$PUSH r28,`-4*$SIZE_T`($tj)
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$PUSH r29,`-3*$SIZE_T`($tj)
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$PUSH r30,`-2*$SIZE_T`($tj)
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$PUSH r31,`-1*$SIZE_T`($tj)
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$LD $n0,0($n0) ; pull n0[0] value
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addi $num,$num,-2 ; adjust $num for counter register
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$LD $m0,0($bp) ; m0=bp[0]
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$LD $aj,0($ap) ; ap[0]
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addi $tp,$sp,$LOCALS
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$UMULL $lo0,$aj,$m0 ; ap[0]*bp[0]
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$UMULH $hi0,$aj,$m0
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$LD $aj,$BNSZ($ap) ; ap[1]
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$LD $nj,0($np) ; np[0]
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$UMULL $m1,$lo0,$n0 ; "tp[0]"*n0
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$UMULL $alo,$aj,$m0 ; ap[1]*bp[0]
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$UMULH $ahi,$aj,$m0
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$UMULL $lo1,$nj,$m1 ; np[0]*m1
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$UMULH $hi1,$nj,$m1
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$LD $nj,$BNSZ($np) ; np[1]
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addc $lo1,$lo1,$lo0
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addze $hi1,$hi1
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$UMULL $nlo,$nj,$m1 ; np[1]*m1
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$UMULH $nhi,$nj,$m1
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mtctr $num
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li $j,`2*$BNSZ`
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.align 4
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L1st:
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$LDX $aj,$ap,$j ; ap[j]
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addc $lo0,$alo,$hi0
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$LDX $nj,$np,$j ; np[j]
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addze $hi0,$ahi
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$UMULL $alo,$aj,$m0 ; ap[j]*bp[0]
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addc $lo1,$nlo,$hi1
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$UMULH $ahi,$aj,$m0
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addze $hi1,$nhi
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$UMULL $nlo,$nj,$m1 ; np[j]*m1
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addc $lo1,$lo1,$lo0 ; np[j]*m1+ap[j]*bp[0]
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$UMULH $nhi,$nj,$m1
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addze $hi1,$hi1
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$ST $lo1,0($tp) ; tp[j-1]
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addi $j,$j,$BNSZ ; j++
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addi $tp,$tp,$BNSZ ; tp++
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bdnz L1st
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;L1st
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addc $lo0,$alo,$hi0
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addze $hi0,$ahi
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addc $lo1,$nlo,$hi1
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addze $hi1,$nhi
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addc $lo1,$lo1,$lo0 ; np[j]*m1+ap[j]*bp[0]
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addze $hi1,$hi1
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$ST $lo1,0($tp) ; tp[j-1]
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li $ovf,0
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addc $hi1,$hi1,$hi0
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addze $ovf,$ovf ; upmost overflow bit
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$ST $hi1,$BNSZ($tp)
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li $i,$BNSZ
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.align 4
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Louter:
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$LDX $m0,$bp,$i ; m0=bp[i]
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$LD $aj,0($ap) ; ap[0]
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addi $tp,$sp,$LOCALS
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$LD $tj,$LOCALS($sp); tp[0]
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$UMULL $lo0,$aj,$m0 ; ap[0]*bp[i]
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$UMULH $hi0,$aj,$m0
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$LD $aj,$BNSZ($ap) ; ap[1]
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$LD $nj,0($np) ; np[0]
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addc $lo0,$lo0,$tj ; ap[0]*bp[i]+tp[0]
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$UMULL $alo,$aj,$m0 ; ap[j]*bp[i]
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addze $hi0,$hi0
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$UMULL $m1,$lo0,$n0 ; tp[0]*n0
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$UMULH $ahi,$aj,$m0
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$UMULL $lo1,$nj,$m1 ; np[0]*m1
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$UMULH $hi1,$nj,$m1
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$LD $nj,$BNSZ($np) ; np[1]
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addc $lo1,$lo1,$lo0
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$UMULL $nlo,$nj,$m1 ; np[1]*m1
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addze $hi1,$hi1
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$UMULH $nhi,$nj,$m1
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mtctr $num
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li $j,`2*$BNSZ`
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.align 4
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Linner:
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$LDX $aj,$ap,$j ; ap[j]
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addc $lo0,$alo,$hi0
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$LD $tj,$BNSZ($tp) ; tp[j]
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addze $hi0,$ahi
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$LDX $nj,$np,$j ; np[j]
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addc $lo1,$nlo,$hi1
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$UMULL $alo,$aj,$m0 ; ap[j]*bp[i]
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addze $hi1,$nhi
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$UMULH $ahi,$aj,$m0
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addc $lo0,$lo0,$tj ; ap[j]*bp[i]+tp[j]
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$UMULL $nlo,$nj,$m1 ; np[j]*m1
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addze $hi0,$hi0
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$UMULH $nhi,$nj,$m1
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addc $lo1,$lo1,$lo0 ; np[j]*m1+ap[j]*bp[i]+tp[j]
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addi $j,$j,$BNSZ ; j++
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addze $hi1,$hi1
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$ST $lo1,0($tp) ; tp[j-1]
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addi $tp,$tp,$BNSZ ; tp++
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bdnz Linner
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;Linner
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$LD $tj,$BNSZ($tp) ; tp[j]
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addc $lo0,$alo,$hi0
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addze $hi0,$ahi
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addc $lo0,$lo0,$tj ; ap[j]*bp[i]+tp[j]
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addze $hi0,$hi0
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addc $lo1,$nlo,$hi1
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addze $hi1,$nhi
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addc $lo1,$lo1,$lo0 ; np[j]*m1+ap[j]*bp[i]+tp[j]
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addze $hi1,$hi1
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$ST $lo1,0($tp) ; tp[j-1]
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addic $ovf,$ovf,-1 ; move upmost overflow to XER[CA]
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li $ovf,0
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adde $hi1,$hi1,$hi0
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addze $ovf,$ovf
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$ST $hi1,$BNSZ($tp)
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;
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slwi $tj,$num,`log($BNSZ)/log(2)`
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$UCMP $i,$tj
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addi $i,$i,$BNSZ
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ble Louter
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addi $num,$num,2 ; restore $num
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subfc $j,$j,$j ; j=0 and "clear" XER[CA]
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addi $tp,$sp,$LOCALS
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mtctr $num
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.align 4
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Lsub: $LDX $tj,$tp,$j
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$LDX $nj,$np,$j
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subfe $aj,$nj,$tj ; tp[j]-np[j]
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$STX $aj,$rp,$j
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addi $j,$j,$BNSZ
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bdnz Lsub
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li $j,0
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mtctr $num
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subfe $ovf,$j,$ovf ; handle upmost overflow bit
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and $ap,$tp,$ovf
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andc $np,$rp,$ovf
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or $ap,$ap,$np ; ap=borrow?tp:rp
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.align 4
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Lcopy: ; copy or in-place refresh
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$LDX $tj,$ap,$j
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$STX $tj,$rp,$j
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$STX $j,$tp,$j ; zap at once
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addi $j,$j,$BNSZ
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bdnz Lcopy
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$POP $tj,0($sp)
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li r3,1
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$POP r20,`-12*$SIZE_T`($tj)
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$POP r21,`-11*$SIZE_T`($tj)
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$POP r22,`-10*$SIZE_T`($tj)
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$POP r23,`-9*$SIZE_T`($tj)
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$POP r24,`-8*$SIZE_T`($tj)
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$POP r25,`-7*$SIZE_T`($tj)
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$POP r26,`-6*$SIZE_T`($tj)
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$POP r27,`-5*$SIZE_T`($tj)
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$POP r28,`-4*$SIZE_T`($tj)
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$POP r29,`-3*$SIZE_T`($tj)
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$POP r30,`-2*$SIZE_T`($tj)
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$POP r31,`-1*$SIZE_T`($tj)
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mr $sp,$tj
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blr
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.long 0
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.byte 0,12,4,0,0x80,12,6,0
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.long 0
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.size .bn_mul_mont_int,.-.bn_mul_mont_int
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.asciz "Montgomery Multiplication for PPC, CRYPTOGAMS by <appro\@openssl.org>"
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___
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$code =~ s/\`([^\`]*)\`/eval $1/gem;
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print $code;
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close STDOUT;
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