openssl/crypto/modes/asm/ghash-x86.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/.
# ====================================================================
#
# March 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 [+64/128 bytes fixed table]. It has two
# code paths: vanilla x86 and vanilla MMX. Former will be executed on
# 486 and Pentium, latter on all others. Performance results are for
# streamed GHASH subroutine and are expressed in cycles per processed
# byte, less is better:
#
#		gcc 2.95.3(*)	MMX assembler	x86 assembler
#
# Pentium	100/112(**)	-		50
# PIII		63 /77		16		24
# P4		96 /122		30		84(***)
# Opteron	50 /71		21		30
# Core2		63 /102		19		28
#
# (*)	gcc 3.4.x was observed to generate few percent slower code,
#	which is one of reasons why 2.95.3 results were chosen,
#	another reason is lack of 3.4.x results for older CPUs;
# (**)	second number is result for code compiled with -fPIC flag,
#	which is actually more relevant, because assembler code is
#	position-independent;
# (***)	see comment in non-MMX routine for further details;
#
# To summarize, it's 2-3 times faster than gcc-generated code. To
# anchor it to something else SHA1 assembler processes one byte in
# 11-13 cycles on contemporary x86 cores.

$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
push(@INC,"${dir}","${dir}../../perlasm");
require "x86asm.pl";

&asm_init($ARGV[0],"gcm-x86.pl",$x86only = $ARGV[$#ARGV] eq "386");

&static_label("rem_4bit") if (!$x86only);

$Zhh  = "ebp";
$Zhl  = "edx";
$Zlh  = "ecx";
$Zll  = "ebx";
$inp  = "edi";
$Htbl = "esi";

$unroll = 0;	# Affects x86 loop. Folded loop performs ~7% worse
		# than unrolled, which has to be weighted against
		# 1.7x code size reduction. Well, *overall* 1.7x,
		# x86-specific code itself shrinks by 2.5x...

sub mmx_loop() {
# MMX version performs 2.8 times better on P4 (see comment in non-MMX
# routine for further details), 40% better on Opteron, 50% better
# on PIII and Core2... In other words effort is considered to be well
# spent...
    my $inp = shift;
    my $rem_4bit = shift;
    my $cnt = $Zhh;
    my $nhi = $Zhl;
    my $nlo = $Zlh;
    my $rem = $Zll;

    my $Zlo = "mm0";
    my $Zhi = "mm1";
    my $tmp = "mm2";

	&xor	($nlo,$nlo);	# avoid partial register stalls on PIII
	&mov	($nhi,$Zll);
	&mov	(&LB($nlo),&LB($nhi));
	&mov	($cnt,14);
	&shl	(&LB($nlo),4);
	&and	($nhi,0xf0);
	&movq	($Zlo,&QWP(8,$Htbl,$nlo));
	&movq	($Zhi,&QWP(0,$Htbl,$nlo));
	&movd	($rem,$Zlo);
	&jmp	(&label("mmx_loop"));

    &set_label("mmx_loop",16);
	&psrlq	($Zlo,4);
	&and	($rem,0xf);
	&pxor	($Zlo,&QWP(8,$Htbl,$nhi));
	&movq	($tmp,$Zhi);
	&psrlq	($Zhi,4);
	&mov	(&LB($nlo),&BP(0,$inp,$cnt));
	&dec	($cnt);
	&psllq	($tmp,60);
	&pxor	($Zhi,&QWP(0,$rem_4bit,$rem,8));
	&movd	($rem,$Zlo);
	&pxor	($Zhi,&QWP(0,$Htbl,$nhi));
	&mov	($nhi,$nlo);
	&pxor	($Zlo,$tmp);
	&js	(&label("mmx_break"));

	&shl	(&LB($nlo),4);
	&and	($rem,0xf);
	&psrlq	($Zlo,4);
	&and	($nhi,0xf0);
	&movq	($tmp,$Zhi);
	&psrlq	($Zhi,4);
	&pxor	($Zlo,&QWP(8,$Htbl,$nlo));
	&psllq	($tmp,60);
	&pxor	($Zhi,&QWP(0,$rem_4bit,$rem,8));
	&movd	($rem,$Zlo);
	&pxor	($Zhi,&QWP(0,$Htbl,$nlo));
	&pxor	($Zlo,$tmp);
	&jmp	(&label("mmx_loop"));

    &set_label("mmx_break",16);
	&shl	(&LB($nlo),4);
	&and	($rem,0xf);
	&psrlq	($Zlo,4);
	&and	($nhi,0xf0);
	&movq	($tmp,$Zhi);
	&psrlq	($Zhi,4);
	&pxor	($Zlo,&QWP(8,$Htbl,$nlo));
	&psllq	($tmp,60);
	&pxor	($Zhi,&QWP(0,$rem_4bit,$rem,8));
	&movd	($rem,$Zlo);
	&pxor	($Zhi,&QWP(0,$Htbl,$nlo));
	&pxor	($Zlo,$tmp);

	&psrlq	($Zlo,4);
	&and	($rem,0xf);
	&pxor	($Zlo,&QWP(8,$Htbl,$nhi));
	&movq	($tmp,$Zhi);
	&psrlq	($Zhi,4);
	&psllq	($tmp,60);
	&pxor	($Zhi,&QWP(0,$rem_4bit,$rem,8));
	&movd	($rem,$Zlo);
	&pxor	($Zhi,&QWP(0,$Htbl,$nhi));
	&mov	($nhi,$nlo);
	&pxor	($Zlo,$tmp);

	&psrlq	($Zlo,32);	# lower part of Zlo is already there
	&movd	($Zhl,$Zhi);
	&psrlq	($Zhi,32);
	&movd	($Zlh,$Zlo);
	&movd	($Zhh,$Zhi);

	&bswap	($Zll);
	&bswap	($Zhl);
	&bswap	($Zlh);
	&bswap	($Zhh);
}

sub x86_loop {
    my $off = shift;
    my $rem = "eax";

	&mov	($Zhh,&DWP(4,$Htbl,$Zll));
	&mov	($Zhl,&DWP(0,$Htbl,$Zll));
	&mov	($Zlh,&DWP(12,$Htbl,$Zll));
	&mov	($Zll,&DWP(8,$Htbl,$Zll));
	&xor	($rem,$rem);	# avoid partial register stalls on PIII

	# shrd practically kills P4, 2.5x deterioration, but P4 has
	# MMX code-path to execute. shrd runs tad faster [than twice
	# the shifts, move's and or's] on pre-MMX Pentium (as well as
	# PIII and Core2), *but* minimizes code size, spares register
	# and thus allows to fold the loop...
	if (!$unroll) {
	my $cnt = $inp;
	&mov	($cnt,15);
	&jmp	(&label("x86_loop"));
	&set_label("x86_loop",16);
	    for($i=1;$i<=2;$i++) {
		&mov	(&LB($rem),&LB($Zll));
		&shrd	($Zll,$Zlh,4);
		&and	(&LB($rem),0xf);
		&shrd	($Zlh,$Zhl,4);
		&shrd	($Zhl,$Zhh,4);
		&shr	($Zhh,4);
		&xor	($Zhh,&DWP($off+16,"esp",$rem,4));

		&mov	(&LB($rem),&BP($off,"esp",$cnt));
		if ($i&1) {
			&and	(&LB($rem),0xf0);
		} else {
			&shl	(&LB($rem),4);
		}

		&xor	($Zll,&DWP(8,$Htbl,$rem));
		&xor	($Zlh,&DWP(12,$Htbl,$rem));
		&xor	($Zhl,&DWP(0,$Htbl,$rem));
		&xor	($Zhh,&DWP(4,$Htbl,$rem));

		if ($i&1) {
			&dec	($cnt);
			&js	(&label("x86_break"));
		} else {
			&jmp	(&label("x86_loop"));
		}
	    }
	&set_label("x86_break",16);
	} else {
	    for($i=1;$i<32;$i++) {
		&comment($i);
		&mov	(&LB($rem),&LB($Zll));
		&shrd	($Zll,$Zlh,4);
		&and	(&LB($rem),0xf);
		&shrd	($Zlh,$Zhl,4);
		&shrd	($Zhl,$Zhh,4);
		&shr	($Zhh,4);
		&xor	($Zhh,&DWP($off+16,"esp",$rem,4));

		if ($i&1) {
			&mov	(&LB($rem),&BP($off+15-($i>>1),"esp"));
			&and	(&LB($rem),0xf0);
		} else {
			&mov	(&LB($rem),&BP($off+15-($i>>1),"esp"));
			&shl	(&LB($rem),4);
		}

		&xor	($Zll,&DWP(8,$Htbl,$rem));
		&xor	($Zlh,&DWP(12,$Htbl,$rem));
		&xor	($Zhl,&DWP(0,$Htbl,$rem));
		&xor	($Zhh,&DWP(4,$Htbl,$rem));
	    }
	}
	&bswap	($Zll);
	&bswap	($Zlh);
	&bswap	($Zhl);
	if (!$x86only) {
		&bswap	($Zhh);
	} else {
		&mov	("eax",$Zhh);
		&bswap	("eax");
		&mov	($Zhh,"eax");
	}
}

if ($unroll) {
    &function_begin_B("_x86_gmult_4bit_inner");
	&x86_loop(4);
	&ret	();
    &function_end_B("_x86_gmult_4bit_inner");
}

&function_begin("gcm_gmult_4bit");
    if (!$x86only) {
	&call	(&label("pic_point"));
	&set_label("pic_point");
	&blindpop("eax");
	&picmeup("ebp","OPENSSL_ia32cap_P","eax",&label("pic_point"));
	&bt	(&DWP(0,"ebp"),23);	# check for MMX bit
	&jnc	(&label("x86"));

	&lea	("eax",&DWP(&label("rem_4bit")."-".&label("pic_point"),"eax"));

	&mov	($inp,&wparam(0));	# load Xi
	&mov	($Htbl,&wparam(1));	# load Htable

	&movz	($Zll,&BP(15,$inp));

	&mmx_loop($inp,"eax");

	&emms	();
	&mov	(&DWP(12,$inp),$Zll);
	&mov	(&DWP(4,$inp),$Zhl);
	&mov	(&DWP(8,$inp),$Zlh);
	&mov	(&DWP(0,$inp),$Zhh);

	&function_end_A();
    &set_label("x86",16);
    }
	&stack_push(16+4+1);			# +1 for stack alignment
	&mov	($inp,&wparam(0));		# load Xi
	&mov	($Htbl,&wparam(1));		# load Htable

	&mov	($Zhh,&DWP(0,$inp));		# load Xi[16]
	&mov	($Zhl,&DWP(4,$inp));
	&mov	($Zlh,&DWP(8,$inp));
	&mov	($Zll,&DWP(12,$inp));

	&deposit_rem_4bit(16);

	&mov	(&DWP(0,"esp"),$Zhh);		# copy Xi[16] on stack
	&mov	(&DWP(4,"esp"),$Zhl);
	&mov	(&DWP(8,"esp"),$Zlh);
	&mov	(&DWP(12,"esp"),$Zll);
	&shr	($Zll,20);
	&and	($Zll,0xf0);

	if ($unroll) {
		&call	("_x86_gmult_4bit_inner");
	} else {
		&x86_loop(0);
		&mov	($inp,&wparam(0));
	}

	&mov	(&DWP(12,$inp),$Zll);
	&mov	(&DWP(8,$inp),$Zlh);
	&mov	(&DWP(4,$inp),$Zhl);
	&mov	(&DWP(0,$inp),$Zhh);
	&stack_pop(16+4+1);
&function_end("gcm_gmult_4bit");

# Streamed version performs 20% better on P4, 7% on Opteron,
# 10% on Core2 and PIII...
&function_begin("gcm_ghash_4bit");
    if (!$x86only) {
	&call	(&label("pic_point"));
	&set_label("pic_point");
	&blindpop("eax");
	&picmeup("ebp","OPENSSL_ia32cap_P","eax",&label("pic_point"));
	&bt	(&DWP(0,"ebp"),23);	# check for MMX bit
	&jnc	(&label("x86"));

	&lea	("eax",&DWP(&label("rem_4bit")."-".&label("pic_point"),"eax"));

	&mov	($inp,&wparam(0));	# load in
	&mov	($Zlh,&wparam(1));	# load len
	&mov	($Zhh,&wparam(2));	# load Xi
	&mov	($Htbl,&wparam(3));	# load Htable
	&add	($Zlh,$inp);
	&mov	(&wparam(1),$Zlh);	# len to point at the end of input
	&stack_push(4+1);		# +1 for stack alignment
	&mov	($Zll,&DWP(12,$Zhh));	# load Xi[16]
	&mov	($Zhl,&DWP(4,$Zhh));
	&mov	($Zlh,&DWP(8,$Zhh));
	&mov	($Zhh,&DWP(0,$Zhh));

    &set_label("mmx_outer_loop",16);
	&xor	($Zll,&DWP(12,$inp));
	&xor	($Zhl,&DWP(4,$inp));
	&xor	($Zlh,&DWP(8,$inp));
	&xor	($Zhh,&DWP(0,$inp));
	&mov	(&DWP(12,"esp"),$Zll);
	&mov	(&DWP(4,"esp"),$Zhl);
	&mov	(&DWP(8,"esp"),$Zlh);
	&mov	(&DWP(0,"esp"),$Zhh);

	&shr	($Zll,24);

	&mmx_loop("esp","eax");

	&lea	($inp,&DWP(16,$inp));
	&cmp	($inp,&wparam(1));
	&jb	(&label("mmx_outer_loop"));

	&mov	($inp,&wparam(2));	# load Xi
	&emms	();
	&mov	(&DWP(12,$inp),$Zll);
	&mov	(&DWP(4,$inp),$Zhl);
	&mov	(&DWP(8,$inp),$Zlh);
	&mov	(&DWP(0,$inp),$Zhh);

	&stack_pop(4+1);
	&function_end_A();
    &set_label("x86",16);
    }
	&stack_push(16+4+1);			# +1 for 64-bit alignment
	&mov	($inp,&wparam(0));		# load in
	&mov	("ecx",&wparam(1));		# load len
	&mov	($Zll,&wparam(2));		# load Xi
	&mov	($Htbl,&wparam(3));		# load Htable
	&add	("ecx",$inp);
	&mov	(&wparam(1),"ecx");

	&mov	($Zhh,&DWP(0,$Zll));		# load Xi[16]
	&mov	($Zhl,&DWP(4,$Zll));
	&mov	($Zlh,&DWP(8,$Zll));
	&mov	($Zll,&DWP(12,$Zll));

	&deposit_rem_4bit(16);

    &set_label("x86_outer_loop",16);
	&xor	($Zll,&DWP(12,$inp));		# xor with input
	&xor	($Zlh,&DWP(8,$inp));
	&xor	($Zhl,&DWP(4,$inp));
	&xor	($Zhh,&DWP(0,$inp));
	&mov	(&DWP(12,"esp"),$Zll);		# dump it on stack
	&mov	(&DWP(8,"esp"),$Zlh);
	&mov	(&DWP(4,"esp"),$Zhl);
	&mov	(&DWP(0,"esp"),$Zhh);

	&shr	($Zll,20);
	&and	($Zll,0xf0);

	if ($unroll) {
		&call	("_x86_gmult_4bit_inner");
	} else {
		&x86_loop(0);
		&mov	($inp,&wparam(0));
	}
	&lea	($inp,&DWP(16,$inp));
	&cmp	($inp,&wparam(1));
	&mov	(&wparam(0),$inp)	if (!$unroll);
	&jb	(&label("x86_outer_loop"));

	&mov	($inp,&wparam(2));	# load Xi
	&mov	(&DWP(12,$inp),$Zll);
	&mov	(&DWP(8,$inp),$Zlh);
	&mov	(&DWP(4,$inp),$Zhl);
	&mov	(&DWP(0,$inp),$Zhh);
	&stack_pop(16+4+1);
&function_end("gcm_ghash_4bit");

sub deposit_rem_4bit {
    my $bias = shift;

	&mov	(&DWP($bias+0, "esp"),0x0000<<16);
	&mov	(&DWP($bias+4, "esp"),0x1C20<<16);
	&mov	(&DWP($bias+8, "esp"),0x3840<<16);
	&mov	(&DWP($bias+12,"esp"),0x2460<<16);
	&mov	(&DWP($bias+16,"esp"),0x7080<<16);
	&mov	(&DWP($bias+20,"esp"),0x6CA0<<16);
	&mov	(&DWP($bias+24,"esp"),0x48C0<<16);
	&mov	(&DWP($bias+28,"esp"),0x54E0<<16);
	&mov	(&DWP($bias+32,"esp"),0xE100<<16);
	&mov	(&DWP($bias+36,"esp"),0xFD20<<16);
	&mov	(&DWP($bias+40,"esp"),0xD940<<16);
	&mov	(&DWP($bias+44,"esp"),0xC560<<16);
	&mov	(&DWP($bias+48,"esp"),0x9180<<16);
	&mov	(&DWP($bias+52,"esp"),0x8DA0<<16);
	&mov	(&DWP($bias+56,"esp"),0xA9C0<<16);
	&mov	(&DWP($bias+60,"esp"),0xB5E0<<16);
}

if (!$x86only) {
&set_label("rem_4bit",64);
	&data_word(0,0x0000<<16,0,0x1C20<<16,0,0x3840<<16,0,0x2460<<16);
	&data_word(0,0x7080<<16,0,0x6CA0<<16,0,0x48C0<<16,0,0x54E0<<16);
	&data_word(0,0xE100<<16,0,0xFD20<<16,0,0xD940<<16,0,0xC560<<16);
	&data_word(0,0x9180<<16,0,0x8DA0<<16,0,0xA9C0<<16,0,0xB5E0<<16);
}
&asciz("GHASH for x86, CRYPTOGAMS by <appro\@openssl.org>");
&asm_finish();
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`#!/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/.`
			`# ====================================================================`
			`#`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# March 2010`
			`#`
GHASH assembler: new ghash-sparcv9.pl module and saner descriptions. 2010-03-22 17:24:18 +00:00			`# 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 [+64/128 bytes fixed table]. It has two`
			`# code paths: vanilla x86 and vanilla MMX. Former will be executed on`
			`# 486 and Pentium, latter on all others. Performance results are for`
			`# streamed GHASH subroutine and are expressed in cycles per processed`
			`# byte, less is better:`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`#`
			`# gcc 2.95.3(*) MMX assembler x86 assembler`
			`#`
			`# Pentium 100/112(**) - 50`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# PIII 63 /77 16 24`
			`# P4 96 /122 30 84(***)`
			`# Opteron 50 /71 21 30`
			`# Core2 63 /102 19 28`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`#`
			`# (*) gcc 3.4.x was observed to generate few percent slower code,`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# which is one of reasons why 2.95.3 results were chosen,`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`# another reason is lack of 3.4.x results for older CPUs;`
			`# (**) second number is result for code compiled with -fPIC flag,`
			`# which is actually more relevant, because assembler code is`
			`# position-independent;`
			`# (***) see comment in non-MMX routine for further details;`
			`#`
			`# To summarize, it's 2-3 times faster than gcc-generated code. To`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# anchor it to something else SHA1 assembler processes one byte in`
			`# 11-13 cycles on contemporary x86 cores.`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00
			`$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;`
			`push(@INC,"${dir}","${dir}../../perlasm");`
			`require "x86asm.pl";`

			`&asm_init($ARGV[0],"gcm-x86.pl",$x86only = $ARGV[$#ARGV] eq "386");`

			`&static_label("rem_4bit") if (!$x86only);`

			`$Zhh = "ebp";`
			`$Zhl = "edx";`
			`$Zlh = "ecx";`
			`$Zll = "ebx";`
			`$inp = "edi";`
			`$Htbl = "esi";`

			`$unroll = 0; # Affects x86 loop. Folded loop performs ~7% worse`
			`# than unrolled, which has to be weighted against`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# 1.7x code size reduction. Well, overall 1.7x,`
			`# x86-specific code itself shrinks by 2.5x...`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00
			`sub mmx_loop() {`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`# MMX version performs 2.8 times better on P4 (see comment in non-MMX`
			`# routine for further details), 40% better on Opteron, 50% better`
			`# on PIII and Core2... In other words effort is considered to be well`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`# spent...`
			`my $inp = shift;`
			`my $rem_4bit = shift;`
			`my $cnt = $Zhh;`
			`my $nhi = $Zhl;`
			`my $nlo = $Zlh;`
			`my $rem = $Zll;`

			`my $Zlo = "mm0";`
			`my $Zhi = "mm1";`
			`my $tmp = "mm2";`

			`&xor ($nlo,$nlo); # avoid partial register stalls on PIII`
			`&mov ($nhi,$Zll);`
			`&mov (&LB($nlo),&LB($nhi));`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&mov ($cnt,14);`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&shl (&LB($nlo),4);`
			`&and ($nhi,0xf0);`
			`&movq ($Zlo,&QWP(8,$Htbl,$nlo));`
			`&movq ($Zhi,&QWP(0,$Htbl,$nlo));`
			`&movd ($rem,$Zlo);`
			`&jmp (&label("mmx_loop"));`

			`&set_label("mmx_loop",16);`
			`&psrlq ($Zlo,4);`
			`&and ($rem,0xf);`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&pxor ($Zlo,&QWP(8,$Htbl,$nhi));`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&movq ($tmp,$Zhi);`
			`&psrlq ($Zhi,4);`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&mov (&LB($nlo),&BP(0,$inp,$cnt));`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&dec ($cnt);`
			`&psllq ($tmp,60);`
			`&pxor ($Zhi,&QWP(0,$rem_4bit,$rem,8));`
			`&movd ($rem,$Zlo);`
			`&pxor ($Zhi,&QWP(0,$Htbl,$nhi));`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&mov ($nhi,$nlo);`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&pxor ($Zlo,$tmp);`
			`&js (&label("mmx_break"));`

ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&shl (&LB($nlo),4);`
			`&and ($rem,0xf);`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&psrlq ($Zlo,4);`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&and ($nhi,0xf0);`
Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&movq ($tmp,$Zhi);`
			`&psrlq ($Zhi,4);`
			`&pxor ($Zlo,&QWP(8,$Htbl,$nlo));`
			`&psllq ($tmp,60);`
			`&pxor ($Zhi,&QWP(0,$rem_4bit,$rem,8));`
			`&movd ($rem,$Zlo);`
			`&pxor ($Zhi,&QWP(0,$Htbl,$nlo));`
			`&pxor ($Zlo,$tmp);`
			`&jmp (&label("mmx_loop"));`

			`&set_label("mmx_break",16);`
ghash-ia64.pl: new file, GHASH for Itanium. ghash-x86_64.pl: minimize stack frame usage. ghash-x86.pl: modulo-scheduling MMX loop in respect to input vector results in up to 10% performance improvement. 2010-03-15 19:07:52 +00:00			`&shl (&LB($nlo),4);`
			`&and ($rem,0xf);`
			`&psrlq ($Zlo,4);`
			`&and ($nhi,0xf0);`
			`&movq ($tmp,$Zhi);`
			`&psrlq ($Zhi,4);`
			`&pxor ($Zlo,&QWP(8,$Htbl,$nlo));`
			`&psllq ($tmp,60);`
			`&pxor ($Zhi,&QWP(0,$rem_4bit,$rem,8));`
			`&movd ($rem,$Zlo);`
			`&pxor ($Zhi,&QWP(0,$Htbl,$nlo));`
			`&pxor ($Zlo,$tmp);`

			`&psrlq ($Zlo,4);`
			`&and ($rem,0xf);`
			`&pxor ($Zlo,&QWP(8,$Htbl,$nhi));`
			`&movq ($tmp,$Zhi);`
			`&psrlq ($Zhi,4);`
			`&psllq ($tmp,60);`
			`&pxor ($Zhi,&QWP(0,$rem_4bit,$rem,8));`
			`&movd ($rem,$Zlo);`
			`&pxor ($Zhi,&QWP(0,$Htbl,$nhi));`
			`&mov ($nhi,$nlo);`
			`&pxor ($Zlo,$tmp);`

Add GHASH x86 assembler. 2010-03-09 23:03:33 +00:00			`&psrlq ($Zlo,32); # lower part of Zlo is already there`
			`&movd ($Zhl,$Zhi);`
			`&psrlq ($Zhi,32);`
			`&movd ($Zlh,$Zlo);`
			`&movd ($Zhh,$Zhi);`

			`&bswap ($Zll);`
			`&bswap ($Zhl);`
			`&bswap ($Zlh);`
			`&bswap ($Zhh);`
			`}`

			`sub x86_loop {`
			`my $off = shift;`
			`my $rem = "eax";`

			`&mov ($Zhh,&DWP(4,$Htbl,$Zll));`
			`&mov ($Zhl,&DWP(0,$Htbl,$Zll));`
			`&mov ($Zlh,&DWP(12,$Htbl,$Zll));`
			`&mov ($Zll,&DWP(8,$Htbl,$Zll));`
			`&xor ($rem,$rem); # avoid partial register stalls on PIII`

			`# shrd practically kills P4, 2.5x deterioration, but P4 has`
			`# MMX code-path to execute. shrd runs tad faster [than twice`
			`# the shifts, move's and or's] on pre-MMX Pentium (as well as`
			`# PIII and Core2), but minimizes code size, spares register`
			`# and thus allows to fold the loop...`
			`if (!$unroll) {`
			`my $cnt = $inp;`
			`&mov ($cnt,15);`
			`&jmp (&label("x86_loop"));`
			`&set_label("x86_loop",16);`
			`for($i=1;$i<=2;$i++) {`
			`&mov (&LB($rem),&LB($Zll));`
			`&shrd ($Zll,$Zlh,4);`
			`&and (&LB($rem),0xf);`
			`&shrd ($Zlh,$Zhl,4);`
			`&shrd ($Zhl,$Zhh,4);`
			`&shr ($Zhh,4);`
			`&xor ($Zhh,&DWP($off+16,"esp",$rem,4));`

			`&mov (&LB($rem),&BP($off,"esp",$cnt));`
			`if ($i&1) {`
			`&and (&LB($rem),0xf0);`
			`} else {`
			`&shl (&LB($rem),4);`
			`}`

			`&xor ($Zll,&DWP(8,$Htbl,$rem));`
			`&xor ($Zlh,&DWP(12,$Htbl,$rem));`
			`&xor ($Zhl,&DWP(0,$Htbl,$rem));`
			`&xor ($Zhh,&DWP(4,$Htbl,$rem));`

			`if ($i&1) {`
			`&dec ($cnt);`
			`&js (&label("x86_break"));`
			`} else {`
			`&jmp (&label("x86_loop"));`
			`}`
			`}`
			`&set_label("x86_break",16);`
			`} else {`
			`for($i=1;$i<32;$i++) {`
			`&comment($i);`
			`&mov (&LB($rem),&LB($Zll));`
			`&shrd ($Zll,$Zlh,4);`
			`&and (&LB($rem),0xf);`
			`&shrd ($Zlh,$Zhl,4);`
			`&shrd ($Zhl,$Zhh,4);`
			`&shr ($Zhh,4);`
			`&xor ($Zhh,&DWP($off+16,"esp",$rem,4));`

			`if ($i&1) {`
			`&mov (&LB($rem),&BP($off+15-($i>>1),"esp"));`
			`&and (&LB($rem),0xf0);`
			`} else {`
			`&mov (&LB($rem),&BP($off+15-($i>>1),"esp"));`
			`&shl (&LB($rem),4);`
			`}`

			`&xor ($Zll,&DWP(8,$Htbl,$rem));`
			`&xor ($Zlh,&DWP(12,$Htbl,$rem));`
			`&xor ($Zhl,&DWP(0,$Htbl,$rem));`
			`&xor ($Zhh,&DWP(4,$Htbl,$rem));`
			`}`
			`}`
			`&bswap ($Zll);`
			`&bswap ($Zlh);`
			`&bswap ($Zhl);`
			`if (!$x86only) {`
			`&bswap ($Zhh);`
			`} else {`
			`&mov ("eax",$Zhh);`
			`&bswap ("eax");`
			`&mov ($Zhh,"eax");`
			`}`
			`}`

			`if ($unroll) {`
			`&function_begin_B("_x86_gmult_4bit_inner");`
			`&x86_loop(4);`
			`&ret ();`
			`&function_end_B("_x86_gmult_4bit_inner");`
			`}`

			`&function_begin("gcm_gmult_4bit");`
			`if (!$x86only) {`
			`&call (&label("pic_point"));`
			`&set_label("pic_point");`
			`&blindpop("eax");`
			`&picmeup("ebp","OPENSSL_ia32cap_P","eax",&label("pic_point"));`
			`&bt (&DWP(0,"ebp"),23); # check for MMX bit`
			`&jnc (&label("x86"));`

			`&lea ("eax",&DWP(&label("rem_4bit")."-".&label("pic_point"),"eax"));`

			`&mov ($inp,&wparam(0)); # load Xi`
			`&mov ($Htbl,&wparam(1)); # load Htable`

			`&movz ($Zll,&BP(15,$inp));`

			`&mmx_loop($inp,"eax");`

			`&emms ();`
			`&mov (&DWP(12,$inp),$Zll);`
			`&mov (&DWP(4,$inp),$Zhl);`
			`&mov (&DWP(8,$inp),$Zlh);`
			`&mov (&DWP(0,$inp),$Zhh);`

			`&function_end_A();`
			`&set_label("x86",16);`
			`}`
			`&stack_push(16+4+1); # +1 for stack alignment`
			`&mov ($inp,&wparam(0)); # load Xi`
			`&mov ($Htbl,&wparam(1)); # load Htable`

			`&mov ($Zhh,&DWP(0,$inp)); # load Xi[16]`
			`&mov ($Zhl,&DWP(4,$inp));`
			`&mov ($Zlh,&DWP(8,$inp));`
			`&mov ($Zll,&DWP(12,$inp));`

			`&deposit_rem_4bit(16);`

			`&mov (&DWP(0,"esp"),$Zhh); # copy Xi[16] on stack`
			`&mov (&DWP(4,"esp"),$Zhl);`
			`&mov (&DWP(8,"esp"),$Zlh);`
			`&mov (&DWP(12,"esp"),$Zll);`
			`&shr ($Zll,20);`
			`&and ($Zll,0xf0);`

			`if ($unroll) {`
			`&call ("_x86_gmult_4bit_inner");`
			`} else {`
			`&x86_loop(0);`
			`&mov ($inp,&wparam(0));`
			`}`

			`&mov (&DWP(12,$inp),$Zll);`
			`&mov (&DWP(8,$inp),$Zlh);`
			`&mov (&DWP(4,$inp),$Zhl);`
			`&mov (&DWP(0,$inp),$Zhh);`
			`&stack_pop(16+4+1);`
			`&function_end("gcm_gmult_4bit");`

			`# Streamed version performs 20% better on P4, 7% on Opteron,`
			`# 10% on Core2 and PIII...`
			`&function_begin("gcm_ghash_4bit");`
			`if (!$x86only) {`
			`&call (&label("pic_point"));`
			`&set_label("pic_point");`
			`&blindpop("eax");`
			`&picmeup("ebp","OPENSSL_ia32cap_P","eax",&label("pic_point"));`
			`&bt (&DWP(0,"ebp"),23); # check for MMX bit`
			`&jnc (&label("x86"));`

			`&lea ("eax",&DWP(&label("rem_4bit")."-".&label("pic_point"),"eax"));`

			`&mov ($inp,&wparam(0)); # load in`
			`&mov ($Zlh,&wparam(1)); # load len`
			`&mov ($Zhh,&wparam(2)); # load Xi`
			`&mov ($Htbl,&wparam(3)); # load Htable`
			`&add ($Zlh,$inp);`
			`&mov (&wparam(1),$Zlh); # len to point at the end of input`
			`&stack_push(4+1); # +1 for stack alignment`
			`&mov ($Zll,&DWP(12,$Zhh)); # load Xi[16]`
			`&mov ($Zhl,&DWP(4,$Zhh));`
			`&mov ($Zlh,&DWP(8,$Zhh));`
			`&mov ($Zhh,&DWP(0,$Zhh));`

			`&set_label("mmx_outer_loop",16);`
			`&xor ($Zll,&DWP(12,$inp));`
			`&xor ($Zhl,&DWP(4,$inp));`
			`&xor ($Zlh,&DWP(8,$inp));`
			`&xor ($Zhh,&DWP(0,$inp));`
			`&mov (&DWP(12,"esp"),$Zll);`
			`&mov (&DWP(4,"esp"),$Zhl);`
			`&mov (&DWP(8,"esp"),$Zlh);`
			`&mov (&DWP(0,"esp"),$Zhh);`

			`&shr ($Zll,24);`

			`&mmx_loop("esp","eax");`

			`&lea ($inp,&DWP(16,$inp));`
			`&cmp ($inp,&wparam(1));`
			`&jb (&label("mmx_outer_loop"));`

			`&mov ($inp,&wparam(2)); # load Xi`
			`&emms ();`
			`&mov (&DWP(12,$inp),$Zll);`
			`&mov (&DWP(4,$inp),$Zhl);`
			`&mov (&DWP(8,$inp),$Zlh);`
			`&mov (&DWP(0,$inp),$Zhh);`

			`&stack_pop(4+1);`
			`&function_end_A();`
			`&set_label("x86",16);`
			`}`
			`&stack_push(16+4+1); # +1 for 64-bit alignment`
			`&mov ($inp,&wparam(0)); # load in`
			`&mov ("ecx",&wparam(1)); # load len`
			`&mov ($Zll,&wparam(2)); # load Xi`
			`&mov ($Htbl,&wparam(3)); # load Htable`
			`&add ("ecx",$inp);`
			`&mov (&wparam(1),"ecx");`

			`&mov ($Zhh,&DWP(0,$Zll)); # load Xi[16]`
			`&mov ($Zhl,&DWP(4,$Zll));`
			`&mov ($Zlh,&DWP(8,$Zll));`
			`&mov ($Zll,&DWP(12,$Zll));`

			`&deposit_rem_4bit(16);`

			`&set_label("x86_outer_loop",16);`
			`&xor ($Zll,&DWP(12,$inp)); # xor with input`
			`&xor ($Zlh,&DWP(8,$inp));`
			`&xor ($Zhl,&DWP(4,$inp));`
			`&xor ($Zhh,&DWP(0,$inp));`
			`&mov (&DWP(12,"esp"),$Zll); # dump it on stack`
			`&mov (&DWP(8,"esp"),$Zlh);`
			`&mov (&DWP(4,"esp"),$Zhl);`
			`&mov (&DWP(0,"esp"),$Zhh);`

			`&shr ($Zll,20);`
			`&and ($Zll,0xf0);`

			`if ($unroll) {`
			`&call ("_x86_gmult_4bit_inner");`
			`} else {`
			`&x86_loop(0);`
			`&mov ($inp,&wparam(0));`
			`}`
			`&lea ($inp,&DWP(16,$inp));`
			`&cmp ($inp,&wparam(1));`
			`&mov (&wparam(0),$inp) if (!$unroll);`
			`&jb (&label("x86_outer_loop"));`

			`&mov ($inp,&wparam(2)); # load Xi`
			`&mov (&DWP(12,$inp),$Zll);`
			`&mov (&DWP(8,$inp),$Zlh);`
			`&mov (&DWP(4,$inp),$Zhl);`
			`&mov (&DWP(0,$inp),$Zhh);`
			`&stack_pop(16+4+1);`
			`&function_end("gcm_ghash_4bit");`

			`sub deposit_rem_4bit {`
			`my $bias = shift;`

			`&mov (&DWP($bias+0, "esp"),0x0000<<16);`
			`&mov (&DWP($bias+4, "esp"),0x1C20<<16);`
			`&mov (&DWP($bias+8, "esp"),0x3840<<16);`
			`&mov (&DWP($bias+12,"esp"),0x2460<<16);`
			`&mov (&DWP($bias+16,"esp"),0x7080<<16);`
			`&mov (&DWP($bias+20,"esp"),0x6CA0<<16);`
			`&mov (&DWP($bias+24,"esp"),0x48C0<<16);`
			`&mov (&DWP($bias+28,"esp"),0x54E0<<16);`
			`&mov (&DWP($bias+32,"esp"),0xE100<<16);`
			`&mov (&DWP($bias+36,"esp"),0xFD20<<16);`
			`&mov (&DWP($bias+40,"esp"),0xD940<<16);`
			`&mov (&DWP($bias+44,"esp"),0xC560<<16);`
			`&mov (&DWP($bias+48,"esp"),0x9180<<16);`
			`&mov (&DWP($bias+52,"esp"),0x8DA0<<16);`
			`&mov (&DWP($bias+56,"esp"),0xA9C0<<16);`
			`&mov (&DWP($bias+60,"esp"),0xB5E0<<16);`
			`}`

			`if (!$x86only) {`
			`&set_label("rem_4bit",64);`
			`&data_word(0,0x0000<<16,0,0x1C20<<16,0,0x3840<<16,0,0x2460<<16);`
			`&data_word(0,0x7080<<16,0,0x6CA0<<16,0,0x48C0<<16,0,0x54E0<<16);`
			`&data_word(0,0xE100<<16,0,0xFD20<<16,0,0xD940<<16,0,0xC560<<16);`
			`&data_word(0,0x9180<<16,0,0x8DA0<<16,0,0xA9C0<<16,0,0xB5E0<<16);`
			`}`
			`&asciz("GHASH for x86, CRYPTOGAMS by <appro\@openssl.org>");`
			`&asm_finish();`