src/third_party/openssl/openssl/crypto/bn/asm/s390x-gf2m.pl - cobalt - Git at Google

 #!/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... gcc 4.3 appeared to generate poor code, therefore
 # the effort. And indeed, the module delivers 55%-90%(*) improvement
 # on haviest ECDSA verify and ECDH benchmarks for 163- and 571-bit
 # key lengths on z990, 30%-55%(*) - on z10, and 70%-110%(*) - on z196.
 # This is for 64-bit build. In 32-bit "highgprs" case improvement is
 # even higher, for example on z990 it was measured 80%-150%. ECDSA
 # sign is modest 9%-12% faster. Keep in mind that these coefficients
 # are not ones for bn_GF2m_mul_2x2 itself, as not all CPU time is
 # burnt in it...
 #
 # (*)	gcc 4.1 was observed to deliver better results than gcc 4.3,
 #	so that improvement coefficients can vary from one specific
 #	setup to another.

 $flavour = shift;

 if ($flavour =~ /3[12]/) {
         $SIZE_T=4;
         $g="";
 } else {
         $SIZE_T=8;
         $g="g";
 }

 while (($output=shift) && ($output!~/^\w[\w\-]*\.\w+$/)) {}
 open STDOUT,">$output";

 $stdframe=16*$SIZE_T+4*8;

 $rp="%r2";
 $a1="%r3";
 $a0="%r4";
 $b1="%r5";
 $b0="%r6";

 $ra="%r14";
 $sp="%r15";

 @T=("%r0","%r1");
 @i=("%r12","%r13");

 ($a1,$a2,$a4,$a8,$a12,$a48)=map("%r$_",(6..11));
 ($lo,$hi,$b)=map("%r$_",(3..5)); $a=$lo; $mask=$a8;

 $code.=<<___;
 .text

 .type	_mul_1x1,\@function
 .align	16
 _mul_1x1:
 	lgr	$a1,$a
 	sllg	$a2,$a,1
 	sllg	$a4,$a,2
 	sllg	$a8,$a,3

 	srag	$lo,$a1,63			# broadcast 63rd bit
 	nihh	$a1,0x1fff
 	srag	@i[0],$a2,63			# broadcast 62nd bit
 	nihh	$a2,0x3fff
 	srag	@i[1],$a4,63			# broadcast 61st bit
 	nihh	$a4,0x7fff
 	ngr	$lo,$b
 	ngr	@i[0],$b
 	ngr	@i[1],$b

 	lghi	@T[0],0
 	lgr	$a12,$a1
 	stg	@T[0],`$stdframe+0*8`($sp)	# tab[0]=0
 	xgr	$a12,$a2
 	stg	$a1,`$stdframe+1*8`($sp)	# tab[1]=a1
 	 lgr	$a48,$a4
 	stg	$a2,`$stdframe+2*8`($sp)	# tab[2]=a2
 	 xgr	$a48,$a8
 	stg	$a12,`$stdframe+3*8`($sp)	# tab[3]=a1^a2
 	 xgr	$a1,$a4

 	stg	$a4,`$stdframe+4*8`($sp)	# tab[4]=a4
 	xgr	$a2,$a4
 	stg	$a1,`$stdframe+5*8`($sp)	# tab[5]=a1^a4
 	xgr	$a12,$a4
 	stg	$a2,`$stdframe+6*8`($sp)	# tab[6]=a2^a4
 	 xgr	$a1,$a48
 	stg	$a12,`$stdframe+7*8`($sp)	# tab[7]=a1^a2^a4
 	 xgr	$a2,$a48

 	stg	$a8,`$stdframe+8*8`($sp)	# tab[8]=a8
 	xgr	$a12,$a48
 	stg	$a1,`$stdframe+9*8`($sp)	# tab[9]=a1^a8
 	 xgr	$a1,$a4
 	stg	$a2,`$stdframe+10*8`($sp)	# tab[10]=a2^a8
 	 xgr	$a2,$a4
 	stg	$a12,`$stdframe+11*8`($sp)	# tab[11]=a1^a2^a8

 	xgr	$a12,$a4
 	stg	$a48,`$stdframe+12*8`($sp)	# tab[12]=a4^a8
 	 srlg	$hi,$lo,1
 	stg	$a1,`$stdframe+13*8`($sp)	# tab[13]=a1^a4^a8
 	 sllg	$lo,$lo,63
 	stg	$a2,`$stdframe+14*8`($sp)	# tab[14]=a2^a4^a8
 	 srlg	@T[0],@i[0],2
 	stg	$a12,`$stdframe+15*8`($sp)	# tab[15]=a1^a2^a4^a8

 	lghi	$mask,`0xf<<3`
 	sllg	$a1,@i[0],62
 	 sllg	@i[0],$b,3
 	srlg	@T[1],@i[1],3
 	 ngr	@i[0],$mask
 	sllg	$a2,@i[1],61
 	 srlg	@i[1],$b,4-3
 	xgr	$hi,@T[0]
 	 ngr	@i[1],$mask
 	xgr	$lo,$a1
 	xgr	$hi,@T[1]
 	xgr	$lo,$a2

 	xg	$lo,$stdframe(@i[0],$sp)
 	srlg	@i[0],$b,8-3
 	ngr	@i[0],$mask
 ___
 for($n=1;$n<14;$n++) {
 $code.=<<___;
 	lg	@T[1],$stdframe(@i[1],$sp)
 	srlg	@i[1],$b,`($n+2)*4`-3
 	sllg	@T[0],@T[1],`$n*4`
 	ngr	@i[1],$mask
 	srlg	@T[1],@T[1],`64-$n*4`
 	xgr	$lo,@T[0]
 	xgr	$hi,@T[1]
 ___
 	push(@i,shift(@i)); push(@T,shift(@T));
 }
 $code.=<<___;
 	lg	@T[1],$stdframe(@i[1],$sp)
 	sllg	@T[0],@T[1],`$n*4`
 	srlg	@T[1],@T[1],`64-$n*4`
 	xgr	$lo,@T[0]
 	xgr	$hi,@T[1]

 	lg	@T[0],$stdframe(@i[0],$sp)
 	sllg	@T[1],@T[0],`($n+1)*4`
 	srlg	@T[0],@T[0],`64-($n+1)*4`
 	xgr	$lo,@T[1]
 	xgr	$hi,@T[0]

 	br	$ra
 .size	_mul_1x1,.-_mul_1x1

 .globl	bn_GF2m_mul_2x2
 .type	bn_GF2m_mul_2x2,\@function
 .align	16
 bn_GF2m_mul_2x2:
 	stm${g}	%r3,%r15,3*$SIZE_T($sp)

 	lghi	%r1,-$stdframe-128
 	la	%r0,0($sp)
 	la	$sp,0(%r1,$sp)			# alloca
 	st${g}	%r0,0($sp)			# back chain
 ___
 if ($SIZE_T==8) {
 my @r=map("%r$_",(6..9));
 $code.=<<___;
 	bras	$ra,_mul_1x1			# a1·b1
 	stmg	$lo,$hi,16($rp)

 	lg	$a,`$stdframe+128+4*$SIZE_T`($sp)
 	lg	$b,`$stdframe+128+6*$SIZE_T`($sp)
 	bras	$ra,_mul_1x1			# a0·b0
 	stmg	$lo,$hi,0($rp)

 	lg	$a,`$stdframe+128+3*$SIZE_T`($sp)
 	lg	$b,`$stdframe+128+5*$SIZE_T`($sp)
 	xg	$a,`$stdframe+128+4*$SIZE_T`($sp)
 	xg	$b,`$stdframe+128+6*$SIZE_T`($sp)
 	bras	$ra,_mul_1x1			# (a0+a1)·(b0+b1)
 	lmg	@r[0],@r[3],0($rp)

 	xgr	$lo,$hi
 	xgr	$hi,@r[1]
 	xgr	$lo,@r[0]
 	xgr	$hi,@r[2]
 	xgr	$lo,@r[3]
 	xgr	$hi,@r[3]
 	xgr	$lo,$hi
 	stg	$hi,16($rp)
 	stg	$lo,8($rp)
 ___
 } else {
 $code.=<<___;
 	sllg	%r3,%r3,32
 	sllg	%r5,%r5,32
 	or	%r3,%r4
 	or	%r5,%r6
 	bras	$ra,_mul_1x1
 	rllg	$lo,$lo,32
 	rllg	$hi,$hi,32
 	stmg	$lo,$hi,0($rp)
 ___
 }
 $code.=<<___;
 	lm${g}	%r6,%r15,`$stdframe+128+6*$SIZE_T`($sp)
 	br	$ra
 .size	bn_GF2m_mul_2x2,.-bn_GF2m_mul_2x2
 .string	"GF(2^m) Multiplication for s390x, CRYPTOGAMS by <appro\@openssl.org>"
 ___

 $code =~ s/\`([^\`]*)\`/eval($1)/gem;
 print $code;
 close STDOUT;
	#!/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... gcc 4.3 appeared to generate poor code, therefore
	# the effort. And indeed, the module delivers 55%-90%(*) improvement
	# on haviest ECDSA verify and ECDH benchmarks for 163- and 571-bit
	# key lengths on z990, 30%-55%() - on z10, and 70%-110%() - on z196.
	# This is for 64-bit build. In 32-bit "highgprs" case improvement is
	# even higher, for example on z990 it was measured 80%-150%. ECDSA
	# sign is modest 9%-12% faster. Keep in mind that these coefficients
	# are not ones for bn_GF2m_mul_2x2 itself, as not all CPU time is
	# burnt in it...
	#
	# (*) gcc 4.1 was observed to deliver better results than gcc 4.3,
	# so that improvement coefficients can vary from one specific
	# setup to another.

	$flavour = shift;

	if ($flavour =~ /3[12]/) {
	$SIZE_T=4;
	$g="";
	} else {
	$SIZE_T=8;
	$g="g";
	}

	while (($output=shift) && ($output!~/^\w[\w\-]*\.\w+$/)) {}
	open STDOUT,">$output";

	$stdframe=16$SIZE_T+48;

	$rp="%r2";
	$a1="%r3";
	$a0="%r4";
	$b1="%r5";
	$b0="%r6";

	$ra="%r14";
	$sp="%r15";

	@T=("%r0","%r1");
	@i=("%r12","%r13");

	($a1,$a2,$a4,$a8,$a12,$a48)=map("%r$_",(6..11));
	($lo,$hi,$b)=map("%r$_",(3..5)); $a=$lo; $mask=$a8;

	$code.=<<___;
	.text

	.type _mul_1x1,\@function
	.align 16
	_mul_1x1:
	lgr $a1,$a
	sllg $a2,$a,1
	sllg $a4,$a,2
	sllg $a8,$a,3

	srag $lo,$a1,63 # broadcast 63rd bit
	nihh $a1,0x1fff
	srag @i[0],$a2,63 # broadcast 62nd bit
	nihh $a2,0x3fff
	srag @i[1],$a4,63 # broadcast 61st bit
	nihh $a4,0x7fff
	ngr $lo,$b
	ngr @i[0],$b
	ngr @i[1],$b

	lghi @T[0],0
	lgr $a12,$a1
	stg @T[0],`$stdframe+0*8`($sp) # tab[0]=0
	xgr $a12,$a2
	stg $a1,`$stdframe+1*8`($sp) # tab[1]=a1
	lgr $a48,$a4
	stg $a2,`$stdframe+2*8`($sp) # tab[2]=a2
	xgr $a48,$a8
	stg $a12,`$stdframe+3*8`($sp) # tab[3]=a1^a2
	xgr $a1,$a4

	stg $a4,`$stdframe+4*8`($sp) # tab[4]=a4
	xgr $a2,$a4
	stg $a1,`$stdframe+5*8`($sp) # tab[5]=a1^a4
	xgr $a12,$a4
	stg $a2,`$stdframe+6*8`($sp) # tab[6]=a2^a4
	xgr $a1,$a48
	stg $a12,`$stdframe+7*8`($sp) # tab[7]=a1^a2^a4
	xgr $a2,$a48

	stg $a8,`$stdframe+8*8`($sp) # tab[8]=a8
	xgr $a12,$a48
	stg $a1,`$stdframe+9*8`($sp) # tab[9]=a1^a8
	xgr $a1,$a4
	stg $a2,`$stdframe+10*8`($sp) # tab[10]=a2^a8
	xgr $a2,$a4
	stg $a12,`$stdframe+11*8`($sp) # tab[11]=a1^a2^a8

	xgr $a12,$a4
	stg $a48,`$stdframe+12*8`($sp) # tab[12]=a4^a8
	srlg $hi,$lo,1
	stg $a1,`$stdframe+13*8`($sp) # tab[13]=a1^a4^a8
	sllg $lo,$lo,63
	stg $a2,`$stdframe+14*8`($sp) # tab[14]=a2^a4^a8
	srlg @T[0],@i[0],2
	stg $a12,`$stdframe+15*8`($sp) # tab[15]=a1^a2^a4^a8

	lghi $mask,`0xf<<3`
	sllg $a1,@i[0],62
	sllg @i[0],$b,3
	srlg @T[1],@i[1],3
	ngr @i[0],$mask
	sllg $a2,@i[1],61
	srlg @i[1],$b,4-3
	xgr $hi,@T[0]
	ngr @i[1],$mask
	xgr $lo,$a1
	xgr $hi,@T[1]
	xgr $lo,$a2

	xg $lo,$stdframe(@i[0],$sp)
	srlg @i[0],$b,8-3
	ngr @i[0],$mask
	___
	for($n=1;$n<14;$n++) {
	$code.=<<___;
	lg @T[1],$stdframe(@i[1],$sp)
	srlg @i[1],$b,`($n+2)*4`-3
	sllg @T[0],@T[1],`$n*4`
	ngr @i[1],$mask
	srlg @T[1],@T[1],`64-$n*4`
	xgr $lo,@T[0]
	xgr $hi,@T[1]
	___
	push(@i,shift(@i)); push(@T,shift(@T));
	}
	$code.=<<___;
	lg @T[1],$stdframe(@i[1],$sp)
	sllg @T[0],@T[1],`$n*4`
	srlg @T[1],@T[1],`64-$n*4`
	xgr $lo,@T[0]
	xgr $hi,@T[1]

	lg @T[0],$stdframe(@i[0],$sp)
	sllg @T[1],@T[0],`($n+1)*4`
	srlg @T[0],@T[0],`64-($n+1)*4`
	xgr $lo,@T[1]
	xgr $hi,@T[0]

	br $ra
	.size _mul_1x1,.-_mul_1x1

	.globl bn_GF2m_mul_2x2
	.type bn_GF2m_mul_2x2,\@function
	.align 16
	bn_GF2m_mul_2x2:
	stm${g} %r3,%r15,3*$SIZE_T($sp)

	lghi %r1,-$stdframe-128
	la %r0,0($sp)
	la $sp,0(%r1,$sp) # alloca
	st${g} %r0,0($sp) # back chain
	___
	if ($SIZE_T==8) {
	my @r=map("%r$_",(6..9));
	$code.=<<___;
	bras $ra,_mul_1x1 # a1·b1
	stmg $lo,$hi,16($rp)

	lg $a,`$stdframe+128+4*$SIZE_T`($sp)
	lg $b,`$stdframe+128+6*$SIZE_T`($sp)
	bras $ra,_mul_1x1 # a0·b0
	stmg $lo,$hi,0($rp)

	lg $a,`$stdframe+128+3*$SIZE_T`($sp)
	lg $b,`$stdframe+128+5*$SIZE_T`($sp)
	xg $a,`$stdframe+128+4*$SIZE_T`($sp)
	xg $b,`$stdframe+128+6*$SIZE_T`($sp)
	bras $ra,_mul_1x1 # (a0+a1)·(b0+b1)
	lmg @r[0],@r[3],0($rp)

	xgr $lo,$hi
	xgr $hi,@r[1]
	xgr $lo,@r[0]
	xgr $hi,@r[2]
	xgr $lo,@r[3]
	xgr $hi,@r[3]
	xgr $lo,$hi
	stg $hi,16($rp)
	stg $lo,8($rp)
	___
	} else {
	$code.=<<___;
	sllg %r3,%r3,32
	sllg %r5,%r5,32
	or %r3,%r4
	or %r5,%r6
	bras $ra,_mul_1x1
	rllg $lo,$lo,32
	rllg $hi,$hi,32
	stmg $lo,$hi,0($rp)
	___
	}
	$code.=<<___;
	lm${g} %r6,%r15,`$stdframe+128+6*$SIZE_T`($sp)
	br $ra
	.size bn_GF2m_mul_2x2,.-bn_GF2m_mul_2x2
	.string "GF(2^m) Multiplication for s390x, CRYPTOGAMS by <appro\@openssl.org>"
	___

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