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path: root/openssl/crypto/bn/asm/ppc-mont.pl
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#!/usr/bin/env perl

# ====================================================================
# Written by Andy Polyakov <appro@fy.chalmers.se> 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/.
# ====================================================================

# April 2006

# "Teaser" Montgomery multiplication module for PowerPC. It's possible
# to gain a bit more by modulo-scheduling outer loop, then dedicated
# squaring procedure should give further 20% and code can be adapted
# for 32-bit application running on 64-bit CPU. As for the latter.
# It won't be able to achieve "native" 64-bit performance, because in
# 32-bit application context every addc instruction will have to be
# expanded as addc, twice right shift by 32 and finally adde, etc.
# So far RSA *sign* performance improvement over pre-bn_mul_mont asm
# for 64-bit application running on PPC970/G5 is:
#
# 512-bit	+65%	
# 1024-bit	+35%
# 2048-bit	+18%
# 4096-bit	+4%

$flavour = shift;

if ($flavour =~ /32/) {
	$BITS=	32;
	$BNSZ=	$BITS/8;
	$SIZE_T=4;
	$RZONE=	224;

	$LD=	"lwz";		# load
	$LDU=	"lwzu";		# load and update
	$LDX=	"lwzx";		# load indexed
	$ST=	"stw";		# store
	$STU=	"stwu";		# store and update
	$STX=	"stwx";		# store indexed
	$STUX=	"stwux";	# store indexed and update
	$UMULL=	"mullw";	# unsigned multiply low
	$UMULH=	"mulhwu";	# unsigned multiply high
	$UCMP=	"cmplw";	# unsigned compare
	$SHRI=	"srwi";		# unsigned shift right by immediate	
	$PUSH=	$ST;
	$POP=	$LD;
} elsif ($flavour =~ /64/) {
	$BITS=	64;
	$BNSZ=	$BITS/8;
	$SIZE_T=8;
	$RZONE=	288;

	# same as above, but 64-bit mnemonics...
	$LD=	"ld";		# load
	$LDU=	"ldu";		# load and update
	$LDX=	"ldx";		# load indexed
	$ST=	"std";		# store
	$STU=	"stdu";		# store and update
	$STX=	"stdx";		# store indexed
	$STUX=	"stdux";	# store indexed and update
	$UMULL=	"mulld";	# unsigned multiply low
	$UMULH=	"mulhdu";	# unsigned multiply high
	$UCMP=	"cmpld";	# unsigned compare
	$SHRI=	"srdi";		# unsigned shift right by immediate	
	$PUSH=	$ST;
	$POP=	$LD;
} else { die "nonsense $flavour"; }

$FRAME=8*$SIZE_T+$RZONE;
$LOCALS=8*$SIZE_T;

$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
( $xlate="${dir}ppc-xlate.pl" and -f $xlate ) or
( $xlate="${dir}../../perlasm/ppc-xlate.pl" and -f $xlate) or
die "can't locate ppc-xlate.pl";

open STDOUT,"| $^X $xlate $flavour ".shift || die "can't call $xlate: $!";

$sp="r1";
$toc="r2";
$rp="r3";	$ovf="r3";
$ap="r4";
$bp="r5";
$np="r6";
$n0="r7";
$num="r8";
$rp="r9";	# $rp is reassigned
$aj="r10";
$nj="r11";
$tj="r12";
# non-volatile registers
$i="r20";
$j="r21";
$tp="r22";
$m0="r23";
$m1="r24";
$lo0="r25";
$hi0="r26";
$lo1="r27";
$hi1="r28";
$alo="r29";
$ahi="r30";
$nlo="r31";
#
$nhi="r0";

$code=<<___;
.machine "any"
.text

.globl	.bn_mul_mont_int
.align	4
.bn_mul_mont_int:
	cmpwi	$num,4
	mr	$rp,r3		; $rp is reassigned
	li	r3,0
	bltlr
___
$code.=<<___ if ($BNSZ==4);
	cmpwi	$num,32		; longer key performance is not better
	bgelr
___
$code.=<<___;
	slwi	$num,$num,`log($BNSZ)/log(2)`
	li	$tj,-4096
	addi	$ovf,$num,$FRAME
	subf	$ovf,$ovf,$sp	; $sp-$ovf
	and	$ovf,$ovf,$tj	; minimize TLB usage
	subf	$ovf,$sp,$ovf	; $ovf-$sp
	mr	$tj,$sp
	srwi	$num,$num,`log($BNSZ)/log(2)`
	$STUX	$sp,$sp,$ovf

	$PUSH	r20,`-12*$SIZE_T`($tj)
	$PUSH	r21,`-11*$SIZE_T`($tj)
	$PUSH	r22,`-10*$SIZE_T`($tj)
	$PUSH	r23,`-9*$SIZE_T`($tj)
	$PUSH	r24,`-8*$SIZE_T`($tj)
	$PUSH	r25,`-7*$SIZE_T`($tj)
	$PUSH	r26,`-6*$SIZE_T`($tj)
	$PUSH	r27,`-5*$SIZE_T`($tj)
	$PUSH	r28,`-4*$SIZE_T`($tj)
	$PUSH	r29,`-3*$SIZE_T`($tj)
	$PUSH	r30,`-2*$SIZE_T`($tj)
	$PUSH	r31,`-1*$SIZE_T`($tj)

	$LD	$n0,0($n0)	; pull n0[0] value
	addi	$num,$num,-2	; adjust $num for counter register

	$LD	$m0,0($bp)	; m0=bp[0]
	$LD	$aj,0($ap)	; ap[0]
	addi	$tp,$sp,$LOCALS
	$UMULL	$lo0,$aj,$m0	; ap[0]*bp[0]
	$UMULH	$hi0,$aj,$m0

	$LD	$aj,$BNSZ($ap)	; ap[1]
	$LD	$nj,0($np)	; np[0]

	$UMULL	$m1,$lo0,$n0	; "tp[0]"*n0

	$UMULL	$alo,$aj,$m0	; ap[1]*bp[0]
	$UMULH	$ahi,$aj,$m0

	$UMULL	$lo1,$nj,$m1	; np[0]*m1
	$UMULH	$hi1,$nj,$m1
	$LD	$nj,$BNSZ($np)	; np[1]
	addc	$lo1,$lo1,$lo0
	addze	$hi1,$hi1

	$UMULL	$nlo,$nj,$m1	; np[1]*m1
	$UMULH	$nhi,$nj,$m1

	mtctr	$num
	li	$j,`2*$BNSZ`
.align	4
L1st:
	$LDX	$aj,$ap,$j	; ap[j]
	addc	$lo0,$alo,$hi0
	$LDX	$nj,$np,$j	; np[j]
	addze	$hi0,$ahi
	$UMULL	$alo,$aj,$m0	; ap[j]*bp[0]
	addc	$lo1,$nlo,$hi1
	$UMULH	$ahi,$aj,$m0
	addze	$hi1,$nhi
	$UMULL	$nlo,$nj,$m1	; np[j]*m1
	addc	$lo1,$lo1,$lo0	; np[j]*m1+ap[j]*bp[0]
	$UMULH	$nhi,$nj,$m1
	addze	$hi1,$hi1
	$ST	$lo1,0($tp)	; tp[j-1]

	addi	$j,$j,$BNSZ	; j++
	addi	$tp,$tp,$BNSZ	; tp++
	bdnz-	L1st
;L1st
	addc	$lo0,$alo,$hi0
	addze	$hi0,$ahi

	addc	$lo1,$nlo,$hi1
	addze	$hi1,$nhi
	addc	$lo1,$lo1,$lo0	; np[j]*m1+ap[j]*bp[0]
	addze	$hi1,$hi1
	$ST	$lo1,0($tp)	; tp[j-1]

	li	$ovf,0
	addc	$hi1,$hi1,$hi0
	addze	$ovf,$ovf	; upmost overflow bit
	$ST	$hi1,$BNSZ($tp)

	li	$i,$BNSZ
.align	4
Louter:
	$LDX	$m0,$bp,$i	; m0=bp[i]
	$LD	$aj,0($ap)	; ap[0]
	addi	$tp,$sp,$LOCALS
	$LD	$tj,$LOCALS($sp); tp[0]
	$UMULL	$lo0,$aj,$m0	; ap[0]*bp[i]
	$UMULH	$hi0,$aj,$m0
	$LD	$aj,$BNSZ($ap)	; ap[1]
	$LD	$nj,0($np)	; np[0]
	addc	$lo0,$lo0,$tj	; ap[0]*bp[i]+tp[0]
	$UMULL	$alo,$aj,$m0	; ap[j]*bp[i]
	addze	$hi0,$hi0
	$UMULL	$m1,$lo0,$n0	; tp[0]*n0
	$UMULH	$ahi,$aj,$m0
	$UMULL	$lo1,$nj,$m1	; np[0]*m1
	$UMULH	$hi1,$nj,$m1
	$LD	$nj,$BNSZ($np)	; np[1]
	addc	$lo1,$lo1,$lo0
	$UMULL	$nlo,$nj,$m1	; np[1]*m1
	addze	$hi1,$hi1
	$UMULH	$nhi,$nj,$m1

	mtctr	$num
	li	$j,`2*$BNSZ`
.align	4
Linner:
	$LDX	$aj,$ap,$j	; ap[j]
	addc	$lo0,$alo,$hi0
	$LD	$tj,$BNSZ($tp)	; tp[j]
	addze	$hi0,$ahi
	$LDX	$nj,$np,$j	; np[j]
	addc	$lo1,$nlo,$hi1
	$UMULL	$alo,$aj,$m0	; ap[j]*bp[i]
	addze	$hi1,$nhi
	$UMULH	$ahi,$aj,$m0
	addc	$lo0,$lo0,$tj	; ap[j]*bp[i]+tp[j]
	$UMULL	$nlo,$nj,$m1	; np[j]*m1
	addze	$hi0,$hi0
	$UMULH	$nhi,$nj,$m1
	addc	$lo1,$lo1,$lo0	; np[j]*m1+ap[j]*bp[i]+tp[j]
	addi	$j,$j,$BNSZ	; j++
	addze	$hi1,$hi1
	$ST	$lo1,0($tp)	; tp[j-1]
	addi	$tp,$tp,$BNSZ	; tp++
	bdnz-	Linner
;Linner
	$LD	$tj,$BNSZ($tp)	; tp[j]
	addc	$lo0,$alo,$hi0
	addze	$hi0,$ahi
	addc	$lo0,$lo0,$tj	; ap[j]*bp[i]+tp[j]
	addze	$hi0,$hi0

	addc	$lo1,$nlo,$hi1
	addze	$hi1,$nhi
	addc	$lo1,$lo1,$lo0	; np[j]*m1+ap[j]*bp[i]+tp[j]
	addze	$hi1,$hi1
	$ST	$lo1,0($tp)	; tp[j-1]

	addic	$ovf,$ovf,-1	; move upmost overflow to XER[CA]
	li	$ovf,0
	adde	$hi1,$hi1,$hi0
	addze	$ovf,$ovf
	$ST	$hi1,$BNSZ($tp)
;
	slwi	$tj,$num,`log($BNSZ)/log(2)`
	$UCMP	$i,$tj
	addi	$i,$i,$BNSZ
	ble-	Louter

	addi	$num,$num,2	; restore $num
	subfc	$j,$j,$j	; j=0 and "clear" XER[CA]
	addi	$tp,$sp,$LOCALS
	mtctr	$num

.align	4
Lsub:	$LDX	$tj,$tp,$j
	$LDX	$nj,$np,$j
	subfe	$aj,$nj,$tj	; tp[j]-np[j]
	$STX	$aj,$rp,$j
	addi	$j,$j,$BNSZ
	bdnz-	Lsub

	li	$j,0
	mtctr	$num
	subfe	$ovf,$j,$ovf	; handle upmost overflow bit
	and	$ap,$tp,$ovf
	andc	$np,$rp,$ovf
	or	$ap,$ap,$np	; ap=borrow?tp:rp

.align	4
Lcopy:				; copy or in-place refresh
	$LDX	$tj,$ap,$j
	$STX	$tj,$rp,$j
	$STX	$j,$tp,$j	; zap at once
	addi	$j,$j,$BNSZ
	bdnz-	Lcopy

	$POP	$tj,0($sp)
	li	r3,1
	$POP	r20,`-12*$SIZE_T`($tj)
	$POP	r21,`-11*$SIZE_T`($tj)
	$POP	r22,`-10*$SIZE_T`($tj)
	$POP	r23,`-9*$SIZE_T`($tj)
	$POP	r24,`-8*$SIZE_T`($tj)
	$POP	r25,`-7*$SIZE_T`($tj)
	$POP	r26,`-6*$SIZE_T`($tj)
	$POP	r27,`-5*$SIZE_T`($tj)
	$POP	r28,`-4*$SIZE_T`($tj)
	$POP	r29,`-3*$SIZE_T`($tj)
	$POP	r30,`-2*$SIZE_T`($tj)
	$POP	r31,`-1*$SIZE_T`($tj)
	mr	$sp,$tj
	blr
	.long	0
	.byte	0,12,4,0,0x80,12,6,0
	.long	0
.size	.bn_mul_mont_int,.-.bn_mul_mont_int

.asciz  "Montgomery Multiplication for PPC, CRYPTOGAMS by <appro\@openssl.org>"
___

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