source-engine/thirdparty/openssl/crypto/modes/asm/ghash-s390x.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/.
# ====================================================================

# September 2010.
#
# The module implements "4-bit" GCM GHASH function and underlying
# single multiplication operation in GF(2^128). "4-bit" means that it
# uses 256 bytes per-key table [+128 bytes shared table]. Performance
# was measured to be ~18 cycles per processed byte on z10, which is
# almost 40% better than gcc-generated code. It should be noted that
# 18 cycles is worse result than expected: loop is scheduled for 12
# and the result should be close to 12. In the lack of instruction-
# level profiling data it's impossible to tell why...

# November 2010.
#
# Adapt for -m31 build. If kernel supports what's called "highgprs"
# feature on Linux [see /proc/cpuinfo], it's possible to use 64-bit
# instructions and achieve "64-bit" performance even in 31-bit legacy
# application context. The feature is not specific to any particular
# processor, as long as it's "z-CPU". Latter implies that the code
# remains z/Architecture specific. On z990 it was measured to perform
# 2.8x better than 32-bit code generated by gcc 4.3.

# March 2011.
#
# Support for hardware KIMD-GHASH is verified to produce correct
# result and therefore is engaged. On z196 it was measured to process
# 8KB buffer ~7 faster than software implementation. It's not as
# impressive for smaller buffer sizes and for smallest 16-bytes buffer
# it's actually almost 2 times slower. Which is the reason why
# KIMD-GHASH is not used in gcm_gmult_4bit.

$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";

$softonly=0;

$Zhi="%r0";
$Zlo="%r1";

$Xi="%r2";	# argument block
$Htbl="%r3";
$inp="%r4";
$len="%r5";

$rem0="%r6";	# variables
$rem1="%r7";
$nlo="%r8";
$nhi="%r9";
$xi="%r10";
$cnt="%r11";
$tmp="%r12";
$x78="%r13";
$rem_4bit="%r14";

$sp="%r15";

$code.=<<___;
.text

.globl	gcm_gmult_4bit
.align	32
gcm_gmult_4bit:
___
$code.=<<___ if(!$softonly && 0);	# hardware is slow for single block...
	larl	%r1,OPENSSL_s390xcap_P
	lg	%r0,0(%r1)
	tmhl	%r0,0x4000	# check for message-security-assist
	jz	.Lsoft_gmult
	lghi	%r0,0
	la	%r1,16($sp)
	.long	0xb93e0004	# kimd %r0,%r4
	lg	%r1,24($sp)
	tmhh	%r1,0x4000	# check for function 65
	jz	.Lsoft_gmult
	stg	%r0,16($sp)	# arrange 16 bytes of zero input
	stg	%r0,24($sp)
	lghi	%r0,65		# function 65
	la	%r1,0($Xi)	# H lies right after Xi in gcm128_context
	la	$inp,16($sp)
	lghi	$len,16
	.long	0xb93e0004	# kimd %r0,$inp
	brc	1,.-4		# pay attention to "partial completion"
	br	%r14
.align	32
.Lsoft_gmult:
___
$code.=<<___;
	stm${g}	%r6,%r14,6*$SIZE_T($sp)

	aghi	$Xi,-1
	lghi	$len,1
	lghi	$x78,`0xf<<3`
	larl	$rem_4bit,rem_4bit

	lg	$Zlo,8+1($Xi)		# Xi
	j	.Lgmult_shortcut
.type	gcm_gmult_4bit,\@function
.size	gcm_gmult_4bit,(.-gcm_gmult_4bit)

.globl	gcm_ghash_4bit
.align	32
gcm_ghash_4bit:
___
$code.=<<___ if(!$softonly);
	larl	%r1,OPENSSL_s390xcap_P
	lg	%r0,0(%r1)
	tmhl	%r0,0x4000	# check for message-security-assist
	jz	.Lsoft_ghash
	lghi	%r0,0
	la	%r1,16($sp)
	.long	0xb93e0004	# kimd %r0,%r4
	lg	%r1,24($sp)
	tmhh	%r1,0x4000	# check for function 65
	jz	.Lsoft_ghash
	lghi	%r0,65		# function 65
	la	%r1,0($Xi)	# H lies right after Xi in gcm128_context
	.long	0xb93e0004	# kimd %r0,$inp
	brc	1,.-4		# pay attention to "partial completion"
	br	%r14
.align	32
.Lsoft_ghash:
___
$code.=<<___ if ($flavour =~ /3[12]/);
	llgfr	$len,$len
___
$code.=<<___;
	stm${g}	%r6,%r14,6*$SIZE_T($sp)

	aghi	$Xi,-1
	srlg	$len,$len,4
	lghi	$x78,`0xf<<3`
	larl	$rem_4bit,rem_4bit

	lg	$Zlo,8+1($Xi)		# Xi
	lg	$Zhi,0+1($Xi)
	lghi	$tmp,0
.Louter:
	xg	$Zhi,0($inp)		# Xi ^= inp 
	xg	$Zlo,8($inp)
	xgr	$Zhi,$tmp
	stg	$Zlo,8+1($Xi)
	stg	$Zhi,0+1($Xi)

.Lgmult_shortcut:
	lghi	$tmp,0xf0
	sllg	$nlo,$Zlo,4
	srlg	$xi,$Zlo,8		# extract second byte
	ngr	$nlo,$tmp
	lgr	$nhi,$Zlo
	lghi	$cnt,14
	ngr	$nhi,$tmp

	lg	$Zlo,8($nlo,$Htbl)
	lg	$Zhi,0($nlo,$Htbl)

	sllg	$nlo,$xi,4
	sllg	$rem0,$Zlo,3
	ngr	$nlo,$tmp
	ngr	$rem0,$x78
	ngr	$xi,$tmp

	sllg	$tmp,$Zhi,60
	srlg	$Zlo,$Zlo,4
	srlg	$Zhi,$Zhi,4
	xg	$Zlo,8($nhi,$Htbl)
	xg	$Zhi,0($nhi,$Htbl)
	lgr	$nhi,$xi
	sllg	$rem1,$Zlo,3
	xgr	$Zlo,$tmp
	ngr	$rem1,$x78
	j	.Lghash_inner
.align	16
.Lghash_inner:
	srlg	$Zlo,$Zlo,4
	sllg	$tmp,$Zhi,60
	xg	$Zlo,8($nlo,$Htbl)
	srlg	$Zhi,$Zhi,4
	llgc	$xi,0($cnt,$Xi)
	xg	$Zhi,0($nlo,$Htbl)
	sllg	$nlo,$xi,4
	xg	$Zhi,0($rem0,$rem_4bit)
	nill	$nlo,0xf0
	sllg	$rem0,$Zlo,3
	xgr	$Zlo,$tmp
	ngr	$rem0,$x78
	nill	$xi,0xf0

	sllg	$tmp,$Zhi,60
	srlg	$Zlo,$Zlo,4
	srlg	$Zhi,$Zhi,4
	xg	$Zlo,8($nhi,$Htbl)
	xg	$Zhi,0($nhi,$Htbl)
	lgr	$nhi,$xi
	xg	$Zhi,0($rem1,$rem_4bit)
	sllg	$rem1,$Zlo,3
	xgr	$Zlo,$tmp
	ngr	$rem1,$x78
	brct	$cnt,.Lghash_inner

	sllg	$tmp,$Zhi,60
	srlg	$Zlo,$Zlo,4
	srlg	$Zhi,$Zhi,4
	xg	$Zlo,8($nlo,$Htbl)
	xg	$Zhi,0($nlo,$Htbl)
	sllg	$xi,$Zlo,3
	xg	$Zhi,0($rem0,$rem_4bit)
	xgr	$Zlo,$tmp
	ngr	$xi,$x78

	sllg	$tmp,$Zhi,60
	srlg	$Zlo,$Zlo,4
	srlg	$Zhi,$Zhi,4
	xg	$Zlo,8($nhi,$Htbl)
	xg	$Zhi,0($nhi,$Htbl)
	xgr	$Zlo,$tmp
	xg	$Zhi,0($rem1,$rem_4bit)

	lg	$tmp,0($xi,$rem_4bit)
	la	$inp,16($inp)
	sllg	$tmp,$tmp,4		# correct last rem_4bit[rem]
	brctg	$len,.Louter

	xgr	$Zhi,$tmp
	stg	$Zlo,8+1($Xi)
	stg	$Zhi,0+1($Xi)
	lm${g}	%r6,%r14,6*$SIZE_T($sp)
	br	%r14
.type	gcm_ghash_4bit,\@function
.size	gcm_ghash_4bit,(.-gcm_ghash_4bit)

.align	64
rem_4bit:
	.long	`0x0000<<12`,0,`0x1C20<<12`,0,`0x3840<<12`,0,`0x2460<<12`,0
	.long	`0x7080<<12`,0,`0x6CA0<<12`,0,`0x48C0<<12`,0,`0x54E0<<12`,0
	.long	`0xE100<<12`,0,`0xFD20<<12`,0,`0xD940<<12`,0,`0xC560<<12`,0
	.long	`0x9180<<12`,0,`0x8DA0<<12`,0,`0xA9C0<<12`,0,`0xB5E0<<12`,0
.type	rem_4bit,\@object
.size	rem_4bit,(.-rem_4bit)
.string	"GHASH for s390x, CRYPTOGAMS by <appro\@openssl.org>"
___

$code =~ s/\`([^\`]*)\`/eval $1/gem;
print $code;
close STDOUT;
Add thirdparty libs 4 years ago			`#!/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/.`
			`# ====================================================================`

			`# September 2010.`
			`#`
			`# The module implements "4-bit" GCM GHASH function and underlying`
			`# single multiplication operation in GF(2^128). "4-bit" means that it`
			`# uses 256 bytes per-key table [+128 bytes shared table]. Performance`
			`# was measured to be ~18 cycles per processed byte on z10, which is`
			`# almost 40% better than gcc-generated code. It should be noted that`
			`# 18 cycles is worse result than expected: loop is scheduled for 12`
			`# and the result should be close to 12. In the lack of instruction-`
			`# level profiling data it's impossible to tell why...`

			`# November 2010.`
			`#`
			`# Adapt for -m31 build. If kernel supports what's called "highgprs"`
			`# feature on Linux [see /proc/cpuinfo], it's possible to use 64-bit`
			`# instructions and achieve "64-bit" performance even in 31-bit legacy`
			`# application context. The feature is not specific to any particular`
			`# processor, as long as it's "z-CPU". Latter implies that the code`
			`# remains z/Architecture specific. On z990 it was measured to perform`
			`# 2.8x better than 32-bit code generated by gcc 4.3.`

			`# March 2011.`
			`#`
			`# Support for hardware KIMD-GHASH is verified to produce correct`
			`# result and therefore is engaged. On z196 it was measured to process`
			`# 8KB buffer ~7 faster than software implementation. It's not as`
			`# impressive for smaller buffer sizes and for smallest 16-bytes buffer`
			`# it's actually almost 2 times slower. Which is the reason why`
			`# KIMD-GHASH is not used in gcm_gmult_4bit.`

			`$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";`

			`$softonly=0;`

			`$Zhi="%r0";`
			`$Zlo="%r1";`

			`$Xi="%r2"; # argument block`
			`$Htbl="%r3";`
			`$inp="%r4";`
			`$len="%r5";`

			`$rem0="%r6"; # variables`
			`$rem1="%r7";`
			`$nlo="%r8";`
			`$nhi="%r9";`
			`$xi="%r10";`
			`$cnt="%r11";`
			`$tmp="%r12";`
			`$x78="%r13";`
			`$rem_4bit="%r14";`

			`$sp="%r15";`

			`$code.=<<___;`
			`.text`

			`.globl gcm_gmult_4bit`
			`.align 32`
			`gcm_gmult_4bit:`
			`___`
			`$code.=<<___ if(!$softonly && 0); # hardware is slow for single block...`
			`larl %r1,OPENSSL_s390xcap_P`
			`lg %r0,0(%r1)`
			`tmhl %r0,0x4000 # check for message-security-assist`
			`jz .Lsoft_gmult`
			`lghi %r0,0`
			`la %r1,16($sp)`
			`.long 0xb93e0004 # kimd %r0,%r4`
			`lg %r1,24($sp)`
			`tmhh %r1,0x4000 # check for function 65`
			`jz .Lsoft_gmult`
			`stg %r0,16($sp) # arrange 16 bytes of zero input`
			`stg %r0,24($sp)`
			`lghi %r0,65 # function 65`
			`la %r1,0($Xi) # H lies right after Xi in gcm128_context`
			`la $inp,16($sp)`
			`lghi $len,16`
			`.long 0xb93e0004 # kimd %r0,$inp`
			`brc 1,.-4 # pay attention to "partial completion"`
			`br %r14`
			`.align 32`
			`.Lsoft_gmult:`
			`___`
			`$code.=<<___;`
			`stm${g} %r6,%r14,6*$SIZE_T($sp)`

			`aghi $Xi,-1`
			`lghi $len,1`
			lghi $x78,`0xf<<3`
			`larl $rem_4bit,rem_4bit`

			`lg $Zlo,8+1($Xi) # Xi`
			`j .Lgmult_shortcut`
			`.type gcm_gmult_4bit,\@function`
			`.size gcm_gmult_4bit,(.-gcm_gmult_4bit)`

			`.globl gcm_ghash_4bit`
			`.align 32`
			`gcm_ghash_4bit:`
			`___`
			`$code.=<<___ if(!$softonly);`
			`larl %r1,OPENSSL_s390xcap_P`
			`lg %r0,0(%r1)`
			`tmhl %r0,0x4000 # check for message-security-assist`
			`jz .Lsoft_ghash`
			`lghi %r0,0`
			`la %r1,16($sp)`
			`.long 0xb93e0004 # kimd %r0,%r4`
			`lg %r1,24($sp)`
			`tmhh %r1,0x4000 # check for function 65`
			`jz .Lsoft_ghash`
			`lghi %r0,65 # function 65`
			`la %r1,0($Xi) # H lies right after Xi in gcm128_context`
			`.long 0xb93e0004 # kimd %r0,$inp`
			`brc 1,.-4 # pay attention to "partial completion"`
			`br %r14`
			`.align 32`
			`.Lsoft_ghash:`
			`___`
			`$code.=<<___ if ($flavour =~ /3[12]/);`
			`llgfr $len,$len`
			`___`
			`$code.=<<___;`
			`stm${g} %r6,%r14,6*$SIZE_T($sp)`

			`aghi $Xi,-1`
			`srlg $len,$len,4`
			lghi $x78,`0xf<<3`
			`larl $rem_4bit,rem_4bit`

			`lg $Zlo,8+1($Xi) # Xi`
			`lg $Zhi,0+1($Xi)`
			`lghi $tmp,0`
			`.Louter:`
			`xg $Zhi,0($inp) # Xi ^= inp`
			`xg $Zlo,8($inp)`
			`xgr $Zhi,$tmp`
			`stg $Zlo,8+1($Xi)`
			`stg $Zhi,0+1($Xi)`

			`.Lgmult_shortcut:`
			`lghi $tmp,0xf0`
			`sllg $nlo,$Zlo,4`
			`srlg $xi,$Zlo,8 # extract second byte`
			`ngr $nlo,$tmp`
			`lgr $nhi,$Zlo`
			`lghi $cnt,14`
			`ngr $nhi,$tmp`

			`lg $Zlo,8($nlo,$Htbl)`
			`lg $Zhi,0($nlo,$Htbl)`

			`sllg $nlo,$xi,4`
			`sllg $rem0,$Zlo,3`
			`ngr $nlo,$tmp`
			`ngr $rem0,$x78`
			`ngr $xi,$tmp`

			`sllg $tmp,$Zhi,60`
			`srlg $Zlo,$Zlo,4`
			`srlg $Zhi,$Zhi,4`
			`xg $Zlo,8($nhi,$Htbl)`
			`xg $Zhi,0($nhi,$Htbl)`
			`lgr $nhi,$xi`
			`sllg $rem1,$Zlo,3`
			`xgr $Zlo,$tmp`
			`ngr $rem1,$x78`
			`j .Lghash_inner`
			`.align 16`
			`.Lghash_inner:`
			`srlg $Zlo,$Zlo,4`
			`sllg $tmp,$Zhi,60`
			`xg $Zlo,8($nlo,$Htbl)`
			`srlg $Zhi,$Zhi,4`
			`llgc $xi,0($cnt,$Xi)`
			`xg $Zhi,0($nlo,$Htbl)`
			`sllg $nlo,$xi,4`
			`xg $Zhi,0($rem0,$rem_4bit)`
			`nill $nlo,0xf0`
			`sllg $rem0,$Zlo,3`
			`xgr $Zlo,$tmp`
			`ngr $rem0,$x78`
			`nill $xi,0xf0`

			`sllg $tmp,$Zhi,60`
			`srlg $Zlo,$Zlo,4`
			`srlg $Zhi,$Zhi,4`
			`xg $Zlo,8($nhi,$Htbl)`
			`xg $Zhi,0($nhi,$Htbl)`
			`lgr $nhi,$xi`
			`xg $Zhi,0($rem1,$rem_4bit)`
			`sllg $rem1,$Zlo,3`
			`xgr $Zlo,$tmp`
			`ngr $rem1,$x78`
			`brct $cnt,.Lghash_inner`

			`sllg $tmp,$Zhi,60`
			`srlg $Zlo,$Zlo,4`
			`srlg $Zhi,$Zhi,4`
			`xg $Zlo,8($nlo,$Htbl)`
			`xg $Zhi,0($nlo,$Htbl)`
			`sllg $xi,$Zlo,3`
			`xg $Zhi,0($rem0,$rem_4bit)`
			`xgr $Zlo,$tmp`
			`ngr $xi,$x78`

			`sllg $tmp,$Zhi,60`
			`srlg $Zlo,$Zlo,4`
			`srlg $Zhi,$Zhi,4`
			`xg $Zlo,8($nhi,$Htbl)`
			`xg $Zhi,0($nhi,$Htbl)`
			`xgr $Zlo,$tmp`
			`xg $Zhi,0($rem1,$rem_4bit)`

			`lg $tmp,0($xi,$rem_4bit)`
			`la $inp,16($inp)`
			`sllg $tmp,$tmp,4 # correct last rem_4bit[rem]`
			`brctg $len,.Louter`

			`xgr $Zhi,$tmp`
			`stg $Zlo,8+1($Xi)`
			`stg $Zhi,0+1($Xi)`
			`lm${g} %r6,%r14,6*$SIZE_T($sp)`
			`br %r14`
			`.type gcm_ghash_4bit,\@function`
			`.size gcm_ghash_4bit,(.-gcm_ghash_4bit)`

			`.align 64`
			`rem_4bit:`
			.long `0x0000<<12`,0,`0x1C20<<12`,0,`0x3840<<12`,0,`0x2460<<12`,0
			.long `0x7080<<12`,0,`0x6CA0<<12`,0,`0x48C0<<12`,0,`0x54E0<<12`,0
			.long `0xE100<<12`,0,`0xFD20<<12`,0,`0xD940<<12`,0,`0xC560<<12`,0
			.long `0x9180<<12`,0,`0x8DA0<<12`,0,`0xA9C0<<12`,0,`0xB5E0<<12`,0
			`.type rem_4bit,\@object`
			`.size rem_4bit,(.-rem_4bit)`
			`.string "GHASH for s390x, CRYPTOGAMS by <appro\@openssl.org>"`
			`___`

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