PPC assembly pack: add ChaCha20 and Poly1305 modules.

Reviewed-by: Richard Levitte <levitte@openssl.org>
This commit is contained in:
Andy Polyakov 2016-02-10 11:51:23 +01:00
parent af093bf485
commit 9e58d1192d
7 changed files with 2322 additions and 0 deletions

View File

@ -40,6 +40,8 @@ chacha-x86.s: asm/chacha-x86.pl
$(PERL) asm/chacha-x86.pl $(PERLASM_SCHEME) $(CFLAGS) $(PROCESSOR) > $@
chacha-x86_64.s: asm/chacha-x86_64.pl
$(PERL) asm/chacha-x86_64.pl $(PERLASM_SCHEME) > $@
chacha-ppc.s: asm/chacha-ppc.pl
$(PERL) asm/chacha-ppc.pl $(PERLASM_SCHEME) $@
chacha-%.S: asm/chacha-%.pl; $(PERL) $< $(PERLASM_SCHEME) $@

942
crypto/chacha/asm/chacha-ppc.pl Executable file
View File

@ -0,0 +1,942 @@
#!/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/.
# ====================================================================
#
# October 2015
#
# ChaCha20 for PowerPC/AltiVec.
#
# Performance in cycles per byte out of large buffer.
#
# IALU/gcc-4.x 3xAltiVec+1xIALU
#
# Freescale e300 13.6/+115% -
# PPC74x0 6.81/+310% 4.66
# POWER7 8.62/+61% 4.27
# POWER8 8.70/+51% 3.96
$flavour = shift;
if ($flavour =~ /64/) {
$SIZE_T =8;
$LRSAVE =2*$SIZE_T;
$STU ="stdu";
$POP ="ld";
$PUSH ="std";
$UCMP ="cmpld";
} elsif ($flavour =~ /32/) {
$SIZE_T =4;
$LRSAVE =$SIZE_T;
$STU ="stwu";
$POP ="lwz";
$PUSH ="stw";
$UCMP ="cmplw";
} else { die "nonsense $flavour"; }
$LITTLE_ENDIAN = ($flavour=~/le$/) ? 1 : 0;
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $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: $!";
$LOCALS=6*$SIZE_T;
$FRAME=$LOCALS+64+18*$SIZE_T; # 64 is for local variables
sub AUTOLOAD() # thunk [simplified] x86-style perlasm
{ my $opcode = $AUTOLOAD; $opcode =~ s/.*:://; $opcode =~ s/_/\./;
$code .= "\t$opcode\t".join(',',@_)."\n";
}
my $sp = "r1";
my ($out,$inp,$len,$key,$ctr) = map("r$_",(3..7));
my @x=map("r$_",(16..31));
my @d=map("r$_",(11,12,14,15));
my @t=map("r$_",(7..10));
sub ROUND {
my ($a0,$b0,$c0,$d0)=@_;
my ($a1,$b1,$c1,$d1)=map(($_&~3)+(($_+1)&3),($a0,$b0,$c0,$d0));
my ($a2,$b2,$c2,$d2)=map(($_&~3)+(($_+1)&3),($a1,$b1,$c1,$d1));
my ($a3,$b3,$c3,$d3)=map(($_&~3)+(($_+1)&3),($a2,$b2,$c2,$d2));
(
"&add (@x[$a0],@x[$a0],@x[$b0])",
"&add (@x[$a1],@x[$a1],@x[$b1])",
"&add (@x[$a2],@x[$a2],@x[$b2])",
"&add (@x[$a3],@x[$a3],@x[$b3])",
"&xor (@x[$d0],@x[$d0],@x[$a0])",
"&xor (@x[$d1],@x[$d1],@x[$a1])",
"&xor (@x[$d2],@x[$d2],@x[$a2])",
"&xor (@x[$d3],@x[$d3],@x[$a3])",
"&rotlwi (@x[$d0],@x[$d0],16)",
"&rotlwi (@x[$d1],@x[$d1],16)",
"&rotlwi (@x[$d2],@x[$d2],16)",
"&rotlwi (@x[$d3],@x[$d3],16)",
"&add (@x[$c0],@x[$c0],@x[$d0])",
"&add (@x[$c1],@x[$c1],@x[$d1])",
"&add (@x[$c2],@x[$c2],@x[$d2])",
"&add (@x[$c3],@x[$c3],@x[$d3])",
"&xor (@x[$b0],@x[$b0],@x[$c0])",
"&xor (@x[$b1],@x[$b1],@x[$c1])",
"&xor (@x[$b2],@x[$b2],@x[$c2])",
"&xor (@x[$b3],@x[$b3],@x[$c3])",
"&rotlwi (@x[$b0],@x[$b0],12)",
"&rotlwi (@x[$b1],@x[$b1],12)",
"&rotlwi (@x[$b2],@x[$b2],12)",
"&rotlwi (@x[$b3],@x[$b3],12)",
"&add (@x[$a0],@x[$a0],@x[$b0])",
"&add (@x[$a1],@x[$a1],@x[$b1])",
"&add (@x[$a2],@x[$a2],@x[$b2])",
"&add (@x[$a3],@x[$a3],@x[$b3])",
"&xor (@x[$d0],@x[$d0],@x[$a0])",
"&xor (@x[$d1],@x[$d1],@x[$a1])",
"&xor (@x[$d2],@x[$d2],@x[$a2])",
"&xor (@x[$d3],@x[$d3],@x[$a3])",
"&rotlwi (@x[$d0],@x[$d0],8)",
"&rotlwi (@x[$d1],@x[$d1],8)",
"&rotlwi (@x[$d2],@x[$d2],8)",
"&rotlwi (@x[$d3],@x[$d3],8)",
"&add (@x[$c0],@x[$c0],@x[$d0])",
"&add (@x[$c1],@x[$c1],@x[$d1])",
"&add (@x[$c2],@x[$c2],@x[$d2])",
"&add (@x[$c3],@x[$c3],@x[$d3])",
"&xor (@x[$b0],@x[$b0],@x[$c0])",
"&xor (@x[$b1],@x[$b1],@x[$c1])",
"&xor (@x[$b2],@x[$b2],@x[$c2])",
"&xor (@x[$b3],@x[$b3],@x[$c3])",
"&rotlwi (@x[$b0],@x[$b0],7)",
"&rotlwi (@x[$b1],@x[$b1],7)",
"&rotlwi (@x[$b2],@x[$b2],7)",
"&rotlwi (@x[$b3],@x[$b3],7)"
);
}
$code.=<<___;
.machine "any"
.globl .ChaCha20_ctr32_int
.align 5
.ChaCha20_ctr32_int:
__ChaCha20_ctr32_int:
${UCMP}i $len,0
beqlr-
$STU $sp,-$FRAME($sp)
mflr r0
$PUSH r14,`$FRAME-$SIZE_T*18`($sp)
$PUSH r15,`$FRAME-$SIZE_T*17`($sp)
$PUSH r16,`$FRAME-$SIZE_T*16`($sp)
$PUSH r17,`$FRAME-$SIZE_T*15`($sp)
$PUSH r18,`$FRAME-$SIZE_T*14`($sp)
$PUSH r19,`$FRAME-$SIZE_T*13`($sp)
$PUSH r20,`$FRAME-$SIZE_T*12`($sp)
$PUSH r21,`$FRAME-$SIZE_T*11`($sp)
$PUSH r22,`$FRAME-$SIZE_T*10`($sp)
$PUSH r23,`$FRAME-$SIZE_T*9`($sp)
$PUSH r24,`$FRAME-$SIZE_T*8`($sp)
$PUSH r25,`$FRAME-$SIZE_T*7`($sp)
$PUSH r26,`$FRAME-$SIZE_T*6`($sp)
$PUSH r27,`$FRAME-$SIZE_T*5`($sp)
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
lwz @d[0],0($ctr) # load counter
lwz @d[1],4($ctr)
lwz @d[2],8($ctr)
lwz @d[3],12($ctr)
bl __ChaCha20_1x
$POP r0,`$FRAME+$LRSAVE`($sp)
$POP r14,`$FRAME-$SIZE_T*18`($sp)
$POP r15,`$FRAME-$SIZE_T*17`($sp)
$POP r16,`$FRAME-$SIZE_T*16`($sp)
$POP r17,`$FRAME-$SIZE_T*15`($sp)
$POP r18,`$FRAME-$SIZE_T*14`($sp)
$POP r19,`$FRAME-$SIZE_T*13`($sp)
$POP r20,`$FRAME-$SIZE_T*12`($sp)
$POP r21,`$FRAME-$SIZE_T*11`($sp)
$POP r22,`$FRAME-$SIZE_T*10`($sp)
$POP r23,`$FRAME-$SIZE_T*9`($sp)
$POP r24,`$FRAME-$SIZE_T*8`($sp)
$POP r25,`$FRAME-$SIZE_T*7`($sp)
$POP r26,`$FRAME-$SIZE_T*6`($sp)
$POP r27,`$FRAME-$SIZE_T*5`($sp)
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
mtlr r0
addi $sp,$sp,$FRAME
blr
.long 0
.byte 0,12,4,1,0x80,18,5,0
.long 0
.size .ChaCha20_ctr32_int,.-.ChaCha20_ctr32_int
.align 5
__ChaCha20_1x:
Loop_outer:
lis @x[0],0x6170 # synthesize sigma
lis @x[1],0x3320
lis @x[2],0x7962
lis @x[3],0x6b20
ori @x[0],@x[0],0x7865
ori @x[1],@x[1],0x646e
ori @x[2],@x[2],0x2d32
ori @x[3],@x[3],0x6574
li r0,10 # inner loop counter
lwz @x[4],0($key) # load key
lwz @x[5],4($key)
lwz @x[6],8($key)
lwz @x[7],12($key)
lwz @x[8],16($key)
mr @x[12],@d[0] # copy counter
lwz @x[9],20($key)
mr @x[13],@d[1]
lwz @x[10],24($key)
mr @x[14],@d[2]
lwz @x[11],28($key)
mr @x[15],@d[3]
mr @t[0],@x[4]
mr @t[1],@x[5]
mr @t[2],@x[6]
mr @t[3],@x[7]
mtctr r0
Loop:
___
foreach (&ROUND(0, 4, 8,12)) { eval; }
foreach (&ROUND(0, 5,10,15)) { eval; }
$code.=<<___;
bdnz Loop
subic $len,$len,64 # $len-=64
addi @x[0],@x[0],0x7865 # accumulate key block
addi @x[1],@x[1],0x646e
addi @x[2],@x[2],0x2d32
addi @x[3],@x[3],0x6574
addis @x[0],@x[0],0x6170
addis @x[1],@x[1],0x3320
addis @x[2],@x[2],0x7962
addis @x[3],@x[3],0x6b20
subfe. r0,r0,r0 # borrow?-1:0
add @x[4],@x[4],@t[0]
lwz @t[0],16($key)
add @x[5],@x[5],@t[1]
lwz @t[1],20($key)
add @x[6],@x[6],@t[2]
lwz @t[2],24($key)
add @x[7],@x[7],@t[3]
lwz @t[3],28($key)
add @x[8],@x[8],@t[0]
add @x[9],@x[9],@t[1]
add @x[10],@x[10],@t[2]
add @x[11],@x[11],@t[3]
add @x[12],@x[12],@d[0]
add @x[13],@x[13],@d[1]
add @x[14],@x[14],@d[2]
add @x[15],@x[15],@d[3]
addi @d[0],@d[0],1 # increment counter
___
if (!$LITTLE_ENDIAN) { for($i=0;$i<16;$i++) { # flip byte order
$code.=<<___;
mr @t[$i&3],@x[$i]
rotlwi @x[$i],@x[$i],8
rlwimi @x[$i],@t[$i&3],24,0,7
rlwimi @x[$i],@t[$i&3],24,16,23
___
} }
$code.=<<___;
bne Ltail # $len-=64 borrowed
lwz @t[0],0($inp) # load input, aligned or not
lwz @t[1],4($inp)
${UCMP}i $len,0 # done already?
lwz @t[2],8($inp)
lwz @t[3],12($inp)
xor @x[0],@x[0],@t[0] # xor with input
lwz @t[0],16($inp)
xor @x[1],@x[1],@t[1]
lwz @t[1],20($inp)
xor @x[2],@x[2],@t[2]
lwz @t[2],24($inp)
xor @x[3],@x[3],@t[3]
lwz @t[3],28($inp)
xor @x[4],@x[4],@t[0]
lwz @t[0],32($inp)
xor @x[5],@x[5],@t[1]
lwz @t[1],36($inp)
xor @x[6],@x[6],@t[2]
lwz @t[2],40($inp)
xor @x[7],@x[7],@t[3]
lwz @t[3],44($inp)
xor @x[8],@x[8],@t[0]
lwz @t[0],48($inp)
xor @x[9],@x[9],@t[1]
lwz @t[1],52($inp)
xor @x[10],@x[10],@t[2]
lwz @t[2],56($inp)
xor @x[11],@x[11],@t[3]
lwz @t[3],60($inp)
xor @x[12],@x[12],@t[0]
stw @x[0],0($out) # store output, aligned or not
xor @x[13],@x[13],@t[1]
stw @x[1],4($out)
xor @x[14],@x[14],@t[2]
stw @x[2],8($out)
xor @x[15],@x[15],@t[3]
stw @x[3],12($out)
stw @x[4],16($out)
stw @x[5],20($out)
stw @x[6],24($out)
stw @x[7],28($out)
stw @x[8],32($out)
stw @x[9],36($out)
stw @x[10],40($out)
stw @x[11],44($out)
stw @x[12],48($out)
stw @x[13],52($out)
stw @x[14],56($out)
addi $inp,$inp,64
stw @x[15],60($out)
addi $out,$out,64
bne Loop_outer
blr
.align 4
Ltail:
addi $len,$len,64 # restore tail length
subi $inp,$inp,1 # prepare for *++ptr
subi $out,$out,1
addi @t[0],$sp,$LOCALS-1
mtctr $len
stw @x[0],`$LOCALS+0`($sp) # save whole block to stack
stw @x[1],`$LOCALS+4`($sp)
stw @x[2],`$LOCALS+8`($sp)
stw @x[3],`$LOCALS+12`($sp)
stw @x[4],`$LOCALS+16`($sp)
stw @x[5],`$LOCALS+20`($sp)
stw @x[6],`$LOCALS+24`($sp)
stw @x[7],`$LOCALS+28`($sp)
stw @x[8],`$LOCALS+32`($sp)
stw @x[9],`$LOCALS+36`($sp)
stw @x[10],`$LOCALS+40`($sp)
stw @x[11],`$LOCALS+44`($sp)
stw @x[12],`$LOCALS+48`($sp)
stw @x[13],`$LOCALS+52`($sp)
stw @x[14],`$LOCALS+56`($sp)
stw @x[15],`$LOCALS+60`($sp)
Loop_tail: # byte-by-byte loop
lbzu @d[0],1($inp)
lbzu @x[0],1(@t[0])
xor @d[1],@d[0],@x[0]
stbu @d[1],1($out)
bdnz Loop_tail
stw $sp,`$LOCALS+0`($sp) # wipe block on stack
stw $sp,`$LOCALS+4`($sp)
stw $sp,`$LOCALS+8`($sp)
stw $sp,`$LOCALS+12`($sp)
stw $sp,`$LOCALS+16`($sp)
stw $sp,`$LOCALS+20`($sp)
stw $sp,`$LOCALS+24`($sp)
stw $sp,`$LOCALS+28`($sp)
stw $sp,`$LOCALS+32`($sp)
stw $sp,`$LOCALS+36`($sp)
stw $sp,`$LOCALS+40`($sp)
stw $sp,`$LOCALS+44`($sp)
stw $sp,`$LOCALS+48`($sp)
stw $sp,`$LOCALS+52`($sp)
stw $sp,`$LOCALS+56`($sp)
stw $sp,`$LOCALS+60`($sp)
blr
.long 0
.byte 0,12,0x14,0,0,0,0,0
___
{{{
my ($A0,$B0,$C0,$D0,$A1,$B1,$C1,$D1,$A2,$B2,$C2,$D2,$T0,$T1,$T2) =
map("v$_",(0..14));
my (@K)=map("v$_",(15..20));
my ($FOUR,$sixteen,$twenty4,$twenty,$twelve,$twenty5,$seven) =
map("v$_",(21..27));
my ($inpperm,$outperm,$outmask) = map("v$_",(28..30));
my @D=("v31",$seven,$T0,$T1,$T2);
my $FRAME=$LOCALS+64+13*16+18*$SIZE_T; # 13*16 is for v20-v31 offload
sub VMXROUND {
my $odd = pop;
my ($a,$b,$c,$d,$t)=@_;
(
"&vadduwm ('$a','$a','$b')",
"&vxor ('$d','$d','$a')",
"&vperm ('$d','$d','$d','$sixteen')",
"&vadduwm ('$c','$c','$d')",
"&vxor ('$t','$b','$c')",
"&vsrw ('$b','$t','$twenty')",
"&vslw ('$t','$t','$twelve')",
"&vor ('$b','$b','$t')",
"&vadduwm ('$a','$a','$b')",
"&vxor ('$d','$d','$a')",
"&vperm ('$d','$d','$d','$twenty4')",
"&vadduwm ('$c','$c','$d')",
"&vxor ('$t','$b','$c')",
"&vsrw ('$b','$t','$twenty5')",
"&vslw ('$t','$t','$seven')",
"&vor ('$b','$b','$t')",
"&vsldoi ('$c','$c','$c',8)",
"&vsldoi ('$b','$b','$b',$odd?4:12)",
"&vsldoi ('$d','$d','$d',$odd?12:4)"
);
}
$code.=<<___;
.globl .ChaCha20_ctr32_vmx
.align 5
.ChaCha20_ctr32_vmx:
${UCMP}i $len,256
blt __ChaCha20_ctr32_int
$STU $sp,-$FRAME($sp)
mflr r0
li r10,`15+$LOCALS+64`
li r11,`31+$LOCALS+64`
mfspr r12,256
stvx v20,r10,$sp
addi r10,r10,32
stvx v21,r11,$sp
addi r11,r11,32
stvx v22,r10,$sp
addi r10,r10,32
stvx v23,r11,$sp
addi r11,r11,32
stvx v24,r10,$sp
addi r10,r10,32
stvx v25,r11,$sp
addi r11,r11,32
stvx v26,r10,$sp
addi r10,r10,32
stvx v27,r11,$sp
addi r11,r11,32
stvx v28,r10,$sp
addi r10,r10,32
stvx v29,r11,$sp
addi r11,r11,32
stvx v30,r10,$sp
stvx v31,r11,$sp
stw r12,`$FRAME-$SIZE_T*18-4`($sp) # save vrsave
$PUSH r14,`$FRAME-$SIZE_T*18`($sp)
$PUSH r15,`$FRAME-$SIZE_T*17`($sp)
$PUSH r16,`$FRAME-$SIZE_T*16`($sp)
$PUSH r17,`$FRAME-$SIZE_T*15`($sp)
$PUSH r18,`$FRAME-$SIZE_T*14`($sp)
$PUSH r19,`$FRAME-$SIZE_T*13`($sp)
$PUSH r20,`$FRAME-$SIZE_T*12`($sp)
$PUSH r21,`$FRAME-$SIZE_T*11`($sp)
$PUSH r22,`$FRAME-$SIZE_T*10`($sp)
$PUSH r23,`$FRAME-$SIZE_T*9`($sp)
$PUSH r24,`$FRAME-$SIZE_T*8`($sp)
$PUSH r25,`$FRAME-$SIZE_T*7`($sp)
$PUSH r26,`$FRAME-$SIZE_T*6`($sp)
$PUSH r27,`$FRAME-$SIZE_T*5`($sp)
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
li 12,-1
$PUSH r0, `$FRAME+$LRSAVE`($sp)
mtspr 256,r12 # preserve all AltiVec registers
bl Lconsts # returns pointer Lsigma in r12
li @x[0],16
li @x[1],32
li @x[2],48
li @x[3],64
li @x[4],31 # 31 is not a typo
li @x[5],15 # nor is 15
lvx @K[1],0,$key # load key
?lvsr $T0,0,$key # prepare unaligned load
lvx @K[2],@x[0],$key
lvx @D[0],@x[4],$key
lvx @K[3],0,$ctr # load counter
?lvsr $T1,0,$ctr # prepare unaligned load
lvx @D[1],@x[5],$ctr
lvx @K[0],0,r12 # load constants
lvx @K[5],@x[0],r12 # one
lvx $FOUR,@x[1],r12
lvx $sixteen,@x[2],r12
lvx $twenty4,@x[3],r12
?vperm @K[1],@K[2],@K[1],$T0 # align key
?vperm @K[2],@D[0],@K[2],$T0
?vperm @K[3],@D[1],@K[3],$T1 # align counter
lwz @d[0],0($ctr) # load counter to GPR
lwz @d[1],4($ctr)
vadduwm @K[3],@K[3],@K[5] # adjust AltiVec counter
lwz @d[2],8($ctr)
vadduwm @K[4],@K[3],@K[5]
lwz @d[3],12($ctr)
vadduwm @K[5],@K[4],@K[5]
vspltisw $twenty,-12 # synthesize constants
vspltisw $twelve,12
vspltisw $twenty5,-7
#vspltisw $seven,7 # synthesized in the loop
vxor $T0,$T0,$T0 # 0x00..00
vspltisw $outmask,-1 # 0xff..ff
?lvsr $inpperm,0,$inp # prepare for unaligned load
?lvsl $outperm,0,$out # prepare for unaligned store
?vperm $outmask,$outmask,$T0,$outperm
be?vspltisb $T1,3 # 0x03..03
be?vxor $inpperm,$inpperm,$T1 # swap bytes within words
be?vxor $outperm,$outperm,$T1
b Loop_outer_vmx
.align 4
Loop_outer_vmx:
lis @x[0],0x6170 # synthesize sigma
lis @x[1],0x3320
vmr $A0,@K[0]
lis @x[2],0x7962
lis @x[3],0x6b20
vmr $A1,@K[0]
ori @x[0],@x[0],0x7865
ori @x[1],@x[1],0x646e
vmr $A2,@K[0]
ori @x[2],@x[2],0x2d32
ori @x[3],@x[3],0x6574
vmr $B0,@K[1]
li r0,10 # inner loop counter
lwz @x[4],0($key) # load key to GPR
vmr $B1,@K[1]
lwz @x[5],4($key)
vmr $B2,@K[1]
lwz @x[6],8($key)
vmr $C0,@K[2]
lwz @x[7],12($key)
vmr $C1,@K[2]
lwz @x[8],16($key)
vmr $C2,@K[2]
mr @x[12],@d[0] # copy GPR counter
lwz @x[9],20($key)
vmr $D0,@K[3]
mr @x[13],@d[1]
lwz @x[10],24($key)
vmr $D1,@K[4]
mr @x[14],@d[2]
lwz @x[11],28($key)
vmr $D2,@K[5]
mr @x[15],@d[3]
mr @t[0],@x[4]
mr @t[1],@x[5]
mr @t[2],@x[6]
mr @t[3],@x[7]
vspltisw $seven,7
mtctr r0
nop
Loop_vmx:
___
my @thread0=&VMXROUND($A0,$B0,$C0,$D0,$T0,0);
my @thread1=&VMXROUND($A1,$B1,$C1,$D1,$T1,0);
my @thread2=&VMXROUND($A2,$B2,$C2,$D2,$T2,0);
my @thread3=&ROUND(0,4,8,12);
foreach (@thread0) {
eval; eval(shift(@thread3));
eval(shift(@thread1)); eval(shift(@thread3));
eval(shift(@thread2)); eval(shift(@thread3));
}
@thread0=&VMXROUND($A0,$B0,$C0,$D0,$T0,1);
@thread1=&VMXROUND($A1,$B1,$C1,$D1,$T1,1);
@thread2=&VMXROUND($A2,$B2,$C2,$D2,$T2,1);
@thread3=&ROUND(0,5,10,15);
foreach (@thread0) {
eval; eval(shift(@thread3));
eval(shift(@thread1)); eval(shift(@thread3));
eval(shift(@thread2)); eval(shift(@thread3));
}
$code.=<<___;
bdnz Loop_vmx
subi $len,$len,256 # $len-=256
addi @x[0],@x[0],0x7865 # accumulate key block
addi @x[1],@x[1],0x646e
addi @x[2],@x[2],0x2d32
addi @x[3],@x[3],0x6574
addis @x[0],@x[0],0x6170
addis @x[1],@x[1],0x3320
addis @x[2],@x[2],0x7962
addis @x[3],@x[3],0x6b20
add @x[4],@x[4],@t[0]
lwz @t[0],16($key)
add @x[5],@x[5],@t[1]
lwz @t[1],20($key)
add @x[6],@x[6],@t[2]
lwz @t[2],24($key)
add @x[7],@x[7],@t[3]
lwz @t[3],28($key)
add @x[8],@x[8],@t[0]
add @x[9],@x[9],@t[1]
add @x[10],@x[10],@t[2]
add @x[11],@x[11],@t[3]
add @x[12],@x[12],@d[0]
add @x[13],@x[13],@d[1]
add @x[14],@x[14],@d[2]
add @x[15],@x[15],@d[3]
vadduwm $A0,$A0,@K[0] # accumulate key block
vadduwm $A1,$A1,@K[0]
vadduwm $A2,$A2,@K[0]
vadduwm $B0,$B0,@K[1]
vadduwm $B1,$B1,@K[1]
vadduwm $B2,$B2,@K[1]
vadduwm $C0,$C0,@K[2]
vadduwm $C1,$C1,@K[2]
vadduwm $C2,$C2,@K[2]
vadduwm $D0,$D0,@K[3]
vadduwm $D1,$D1,@K[4]
vadduwm $D2,$D2,@K[5]
addi @d[0],@d[0],4 # increment counter
vadduwm @K[3],@K[3],$FOUR
vadduwm @K[4],@K[4],$FOUR
vadduwm @K[5],@K[5],$FOUR
___
if (!$LITTLE_ENDIAN) { for($i=0;$i<16;$i++) { # flip byte order
$code.=<<___;
mr @t[$i&3],@x[$i]
rotlwi @x[$i],@x[$i],8
rlwimi @x[$i],@t[$i&3],24,0,7
rlwimi @x[$i],@t[$i&3],24,16,23
___
} }
$code.=<<___;
lwz @t[0],0($inp) # load input, aligned or not
lwz @t[1],4($inp)
lwz @t[2],8($inp)
lwz @t[3],12($inp)
xor @x[0],@x[0],@t[0] # xor with input
lwz @t[0],16($inp)
xor @x[1],@x[1],@t[1]
lwz @t[1],20($inp)
xor @x[2],@x[2],@t[2]
lwz @t[2],24($inp)
xor @x[3],@x[3],@t[3]
lwz @t[3],28($inp)
xor @x[4],@x[4],@t[0]
lwz @t[0],32($inp)
xor @x[5],@x[5],@t[1]
lwz @t[1],36($inp)
xor @x[6],@x[6],@t[2]
lwz @t[2],40($inp)
xor @x[7],@x[7],@t[3]
lwz @t[3],44($inp)
xor @x[8],@x[8],@t[0]
lwz @t[0],48($inp)
xor @x[9],@x[9],@t[1]
lwz @t[1],52($inp)
xor @x[10],@x[10],@t[2]
lwz @t[2],56($inp)
xor @x[11],@x[11],@t[3]
lwz @t[3],60($inp)
xor @x[12],@x[12],@t[0]
stw @x[0],0($out) # store output, aligned or not
xor @x[13],@x[13],@t[1]
stw @x[1],4($out)
xor @x[14],@x[14],@t[2]
stw @x[2],8($out)
xor @x[15],@x[15],@t[3]
stw @x[3],12($out)
addi $inp,$inp,64
stw @x[4],16($out)
li @t[0],16
stw @x[5],20($out)
li @t[1],32
stw @x[6],24($out)
li @t[2],48
stw @x[7],28($out)
li @t[3],64
stw @x[8],32($out)
stw @x[9],36($out)
stw @x[10],40($out)
stw @x[11],44($out)
stw @x[12],48($out)
stw @x[13],52($out)
stw @x[14],56($out)
stw @x[15],60($out)
addi $out,$out,64
lvx @D[0],0,$inp # load input
lvx @D[1],@t[0],$inp
lvx @D[2],@t[1],$inp
lvx @D[3],@t[2],$inp
lvx @D[4],@t[3],$inp
addi $inp,$inp,64
?vperm @D[0],@D[1],@D[0],$inpperm # align input
?vperm @D[1],@D[2],@D[1],$inpperm
?vperm @D[2],@D[3],@D[2],$inpperm
?vperm @D[3],@D[4],@D[3],$inpperm
vxor $A0,$A0,@D[0] # xor with input
vxor $B0,$B0,@D[1]
lvx @D[1],@t[0],$inp # keep loading input
vxor $C0,$C0,@D[2]
lvx @D[2],@t[1],$inp
vxor $D0,$D0,@D[3]
lvx @D[3],@t[2],$inp
lvx @D[0],@t[3],$inp
addi $inp,$inp,64
li @t[3],63 # 63 is not a typo
vperm $A0,$A0,$A0,$outperm # pre-misalign output
vperm $B0,$B0,$B0,$outperm
vperm $C0,$C0,$C0,$outperm
vperm $D0,$D0,$D0,$outperm
?vperm @D[4],@D[1],@D[4],$inpperm # align input
?vperm @D[1],@D[2],@D[1],$inpperm
?vperm @D[2],@D[3],@D[2],$inpperm
?vperm @D[3],@D[0],@D[3],$inpperm
vxor $A1,$A1,@D[4]
vxor $B1,$B1,@D[1]
lvx @D[1],@t[0],$inp # keep loading input
vxor $C1,$C1,@D[2]
lvx @D[2],@t[1],$inp
vxor $D1,$D1,@D[3]
lvx @D[3],@t[2],$inp
lvx @D[4],@t[3],$inp # redundant in aligned case
addi $inp,$inp,64
vperm $A1,$A1,$A1,$outperm # pre-misalign output
vperm $B1,$B1,$B1,$outperm
vperm $C1,$C1,$C1,$outperm
vperm $D1,$D1,$D1,$outperm
?vperm @D[0],@D[1],@D[0],$inpperm # align input
?vperm @D[1],@D[2],@D[1],$inpperm
?vperm @D[2],@D[3],@D[2],$inpperm
?vperm @D[3],@D[4],@D[3],$inpperm
vxor $A2,$A2,@D[0]
vxor $B2,$B2,@D[1]
vxor $C2,$C2,@D[2]
vxor $D2,$D2,@D[3]
vperm $A2,$A2,$A2,$outperm # pre-misalign output
vperm $B2,$B2,$B2,$outperm
vperm $C2,$C2,$C2,$outperm
vperm $D2,$D2,$D2,$outperm
andi. @x[1],$out,15 # is $out aligned?
mr @x[0],$out
vsel @D[0],$A0,$B0,$outmask # collect pre-misaligned output
vsel @D[1],$B0,$C0,$outmask
vsel @D[2],$C0,$D0,$outmask
vsel @D[3],$D0,$A1,$outmask
vsel $B0,$A1,$B1,$outmask
vsel $C0,$B1,$C1,$outmask
vsel $D0,$C1,$D1,$outmask
vsel $A1,$D1,$A2,$outmask
vsel $B1,$A2,$B2,$outmask
vsel $C1,$B2,$C2,$outmask
vsel $D1,$C2,$D2,$outmask
#stvx $A0,0,$out # take it easy on the edges
stvx @D[0],@t[0],$out # store output
stvx @D[1],@t[1],$out
stvx @D[2],@t[2],$out
addi $out,$out,64
stvx @D[3],0,$out
stvx $B0,@t[0],$out
stvx $C0,@t[1],$out
stvx $D0,@t[2],$out
addi $out,$out,64
stvx $A1,0,$out
stvx $B1,@t[0],$out
stvx $C1,@t[1],$out
stvx $D1,@t[2],$out
addi $out,$out,64
beq Laligned_vmx
sub @x[2],$out,@x[1] # in misaligned case edges
li @x[3],0 # are written byte-by-byte
Lunaligned_tail_vmx:
stvebx $D2,@x[3],@x[2]
addi @x[3],@x[3],1
cmpw @x[3],@x[1]
bne Lunaligned_tail_vmx
sub @x[2],@x[0],@x[1]
Lunaligned_head_vmx:
stvebx $A0,@x[1],@x[2]
cmpwi @x[1],15
addi @x[1],@x[1],1
bne Lunaligned_head_vmx
${UCMP}i $len,255 # done with 256-byte blocks yet?
bgt Loop_outer_vmx
b Ldone_vmx
.align 4
Laligned_vmx:
stvx $A0,0,@x[0] # head hexaword was not stored
${UCMP}i $len,255 # done with 256-byte blocks yet?
bgt Loop_outer_vmx
nop
Ldone_vmx:
${UCMP}i $len,0 # done yet?
bnel __ChaCha20_1x
lwz r12,`$FRAME-$SIZE_T*18-4`($sp) # pull vrsave
li r10,`15+$LOCALS+64`
li r11,`31+$LOCALS+64`
mtspr 256,r12 # restore vrsave
lvx v20,r10,$sp
addi r10,r10,32
lvx v21,r11,$sp
addi r11,r11,32
lvx v22,r10,$sp
addi r10,r10,32
lvx v23,r11,$sp
addi r11,r11,32
lvx v24,r10,$sp
addi r10,r10,32
lvx v25,r11,$sp
addi r11,r11,32
lvx v26,r10,$sp
addi r10,r10,32
lvx v27,r11,$sp
addi r11,r11,32
lvx v28,r10,$sp
addi r10,r10,32
lvx v29,r11,$sp
addi r11,r11,32
lvx v30,r10,$sp
lvx v31,r11,$sp
$POP r0, `$FRAME+$LRSAVE`($sp)
$POP r14,`$FRAME-$SIZE_T*18`($sp)
$POP r15,`$FRAME-$SIZE_T*17`($sp)
$POP r16,`$FRAME-$SIZE_T*16`($sp)
$POP r17,`$FRAME-$SIZE_T*15`($sp)
$POP r18,`$FRAME-$SIZE_T*14`($sp)
$POP r19,`$FRAME-$SIZE_T*13`($sp)
$POP r20,`$FRAME-$SIZE_T*12`($sp)
$POP r21,`$FRAME-$SIZE_T*11`($sp)
$POP r22,`$FRAME-$SIZE_T*10`($sp)
$POP r23,`$FRAME-$SIZE_T*9`($sp)
$POP r24,`$FRAME-$SIZE_T*8`($sp)
$POP r25,`$FRAME-$SIZE_T*7`($sp)
$POP r26,`$FRAME-$SIZE_T*6`($sp)
$POP r27,`$FRAME-$SIZE_T*5`($sp)
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
mtlr r0
addi $sp,$sp,$FRAME
blr
.long 0
.byte 0,12,0x04,1,0x80,18,5,0
.long 0
.size .ChaCha20_ctr32_vmx,.-.ChaCha20_ctr32_vmx
.align 5
Lconsts:
mflr r0
bcl 20,31,\$+4
mflr r12 #vvvvv "distance between . and _vpaes_consts
addi r12,r12,`64-8`
mtlr r0
blr
.long 0
.byte 0,12,0x14,0,0,0,0,0
.space `64-9*4`
Lsigma:
.long 0x61707865,0x3320646e,0x79622d32,0x6b206574
.long 1,0,0,0
.long 4,0,0,0
___
$code.=<<___ if ($LITTLE_ENDIAN);
.long 0x0e0f0c0d,0x0a0b0809,0x06070405,0x02030001
.long 0x0d0e0f0c,0x090a0b08,0x05060704,0x01020300
___
$code.=<<___ if (!$LITTLE_ENDIAN); # flipped words
.long 0x02030001,0x06070405,0x0a0b0809,0x0e0f0c0d
.long 0x01020300,0x05060704,0x090a0b08,0x0d0e0f0c
___
$code.=<<___;
.asciz "ChaCha20 for PowerPC/AltiVec, CRYPTOGAMS by <appro\@openssl.org>"
.align 2
___
}}}
foreach (split("\n",$code)) {
s/\`([^\`]*)\`/eval $1/ge;
# instructions prefixed with '?' are endian-specific and need
# to be adjusted accordingly...
if ($flavour !~ /le$/) { # big-endian
s/be\?// or
s/le\?/#le#/ or
s/\?lvsr/lvsl/ or
s/\?lvsl/lvsr/ or
s/\?(vperm\s+v[0-9]+,\s*)(v[0-9]+,\s*)(v[0-9]+,\s*)(v[0-9]+)/$1$3$2$4/ or
s/(vsldoi\s+v[0-9]+,\s*)(v[0-9]+,)\s*(v[0-9]+,\s*)([0-9]+)/$1$3$2 16-$4/;
} else { # little-endian
s/le\?// or
s/be\?/#be#/ or
s/\?([a-z]+)/$1/;
}
print $_,"\n";
}
close STDOUT;

View File

@ -8,6 +8,8 @@ BEGINRAW[Makefile(unix)]
$(PERL) {- $sourcedir -}/asm/chacha-x86.pl $(PERLASM_SCHEME) $(CFLAGS) $(PROCESSOR) > $@
{- $builddir -}/chacha-x86_64.s: {- $sourcedir -}/asm/chacha-x86_64.pl
$(PERL) {- $sourcedir -}/asm/chacha-x86_64.pl $(PERLASM_SCHEME) > $@
{- $builddir -}/chacha-ppc.s: {- $sourcedir -}/asm/chacha-ppc.pl
$(PERL) {- $sourcedir -}/asm/chacha-ppc.pl $(PERLASM_SCHEME) $@
{- $builddir -}/chacha-%.S: {- $sourcedir -}/asm/chacha-%.pl
$(PERL) $< $(PERLASM_SCHEME) $@

View File

@ -42,6 +42,10 @@ poly1305-x86.s: asm/poly1305-x86.pl
$(PERL) asm/poly1305-x86.pl $(PERLASM_SCHEME) $(CFLAGS) $(PROCESSOR) > $@
poly1305-x86_64.s: asm/poly1305-x86_64.pl
$(PERL) asm/poly1305-x86_64.pl $(PERLASM_SCHEME) > $@
poly1305-ppc.s: asm/poly1305-ppc.pl
$(PERL) asm/poly1305-ppc.pl $(PERLASM_SCHEME) $@
poly1305-ppcfp.s: asm/poly1305-ppcfp.pl
$(PERL) asm/poly1305-ppcfp.pl $(PERLASM_SCHEME) $@
poly1305-%.S: asm/poly1305-%.pl; $(PERL) $< $(PERLASM_SCHEME) $@

View File

@ -0,0 +1,636 @@
#!/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/.
# ====================================================================
#
# This module implements Poly1305 hash for PowerPC.
#
# June 2015
#
# Numbers are cycles per processed byte with poly1305_blocks alone,
# and improvement coefficients relative to gcc-generated code.
#
# -m32 -m64
#
# Freescale e300 14.8/+80% -
# PPC74x0 7.40/+60% -
# PPC970 7.20/+114% 3.51/+205%
# POWER6 3.96/+250% 2.02/+170%
# POWER7 3.67/+260% 1.87/+100%
# POWER8 - 2.13/+200%
#
# Do we need floating-point implementation for PPC? Results presented
# in poly1305_ieee754.c are tricky to compare to, because they are for
# compiler-generated code. On the other hand it's known that floating-
# point performance can be dominated by FPU latency, which means that
# there is limit even for ideally optimized (and even vectorized) code.
# And this limit is estimated to be higher than above -m64 results. Or
# in other words floating-point implementation can be meaningful to
# consider only in 32-bit application context. We probably have to
# recognize that 32-bit builds are getting less popular on high-end
# systems and therefore tend to target embedded ones, which might not
# even have FPU...
#
# On side note, Power ISA 2.07 enables vector base 2^26 implementation,
# and POWER8 might have capacity to break 1.0 cycle per byte barrier...
$flavour = shift;
if ($flavour =~ /64/) {
$SIZE_T =8;
$LRSAVE =2*$SIZE_T;
$UCMP ="cmpld";
$STU ="stdu";
$POP ="ld";
$PUSH ="std";
} elsif ($flavour =~ /32/) {
$SIZE_T =4;
$LRSAVE =$SIZE_T;
$UCMP ="cmplw";
$STU ="stwu";
$POP ="lwz";
$PUSH ="stw";
} else { die "nonsense $flavour"; }
# Define endianess based on flavour
# i.e.: linux64le
$LITTLE_ENDIAN = ($flavour=~/le$/) ? $SIZE_T : 0;
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $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: $!";
$FRAME=24*$SIZE_T;
$sp="r1";
my ($ctx,$inp,$len,$padbit) = map("r$_",(3..6));
my ($mac,$nonce)=($inp,$len);
my $mask = "r0";
$code=<<___;
.machine "any"
.text
___
if ($flavour =~ /64/) {
###############################################################################
# base 2^64 implementation
my ($h0,$h1,$h2,$d0,$d1,$d2, $r0,$r1,$s1, $t0,$t1) = map("r$_",(7..12,27..31));
$code.=<<___;
.globl .poly1305_init_int
.align 4
.poly1305_init_int:
xor r0,r0,r0
std r0,0($ctx) # zero hash value
std r0,8($ctx)
std r0,16($ctx)
$UCMP $inp,r0
beq- Lno_key
___
$code.=<<___ if ($LITTLE_ENDIAN);
ld $d0,0($inp) # load key material
ld $d1,8($inp)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $h0,4
lwbrx $d0,0,$inp # load key material
li $d1,8
lwbrx $h0,$h0,$inp
li $h1,12
lwbrx $d1,$d1,$inp
lwbrx $h1,$h1,$inp
insrdi $d0,$h0,32,0
insrdi $d1,$h1,32,0
___
$code.=<<___;
lis $h1,0xfff # 0x0fff0000
ori $h1,$h1,0xfffc # 0x0ffffffc
insrdi $h1,$h1,32,0 # 0x0ffffffc0ffffffc
ori $h0,$h1,3 # 0x0ffffffc0fffffff
and $d0,$d0,$h0
and $d1,$d1,$h1
std $d0,32($ctx) # store key
std $d1,40($ctx)
Lno_key:
xor r3,r3,r3
blr
.long 0
.byte 0,12,0x14,0,0,0,2,0
.size .poly1305_init_int,.-.poly1305_init_int
.globl .poly1305_blocks
.align 4
.poly1305_blocks:
srdi. $len,$len,4
beq- Labort
$STU $sp,-$FRAME($sp)
mflr r0
$PUSH r27,`$FRAME-$SIZE_T*5`($sp)
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
ld $r0,32($ctx) # load key
ld $r1,40($ctx)
ld $h0,0($ctx) # load hash value
ld $h1,8($ctx)
ld $h2,16($ctx)
srdi $s1,$r1,2
mtctr $len
add $s1,$s1,$r1 # s1 = r1 + r1>>2
li $mask,3
b Loop
.align 4
Loop:
___
$code.=<<___ if ($LITTLE_ENDIAN);
ld $t0,0($inp) # load input
ld $t1,8($inp)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $d0,4
lwbrx $t0,0,$inp # load input
li $t1,8
lwbrx $d0,$d0,$inp
li $d1,12
lwbrx $t1,$t1,$inp
lwbrx $d1,$d1,$inp
insrdi $t0,$d0,32,0
insrdi $t1,$d1,32,0
___
$code.=<<___;
addi $inp,$inp,16
addc $h0,$h0,$t0 # accumulate input
adde $h1,$h1,$t1
mulld $d0,$h0,$r0 # h0*r0
mulhdu $d1,$h0,$r0
adde $h2,$h2,$padbit
mulld $t0,$h1,$s1 # h1*5*r1
mulhdu $t1,$h1,$s1
addc $d0,$d0,$t0
adde $d1,$d1,$t1
mulld $t0,$h0,$r1 # h0*r1
mulhdu $d2,$h0,$r1
addc $d1,$d1,$t0
addze $d2,$d2
mulld $t0,$h1,$r0 # h1*r0
mulhdu $t1,$h1,$r0
addc $d1,$d1,$t0
adde $d2,$d2,$t1
mulld $t0,$h2,$s1 # h2*5*r1
mulld $t1,$h2,$r0 # h2*r0
addc $d1,$d1,$t0
adde $d2,$d2,$t1
andc $t0,$d2,$mask # final reduction step
and $h2,$d2,$mask
srdi $t1,$t0,2
add $t0,$t0,$t1
addc $h0,$d0,$t0
addze $h1,$d1
bdnz Loop
std $h0,0($ctx) # store hash value
std $h1,8($ctx)
std $h2,16($ctx)
$POP r27,`$FRAME-$SIZE_T*5`($sp)
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
addi $sp,$sp,$FRAME
Labort:
blr
.long 0
.byte 0,12,4,1,0x80,5,4,0
.size .poly1305_blocks,.-.poly1305_blocks
.globl .poly1305_emit
.align 4
.poly1305_emit:
ld $h0,0($ctx) # load hash
ld $h1,8($ctx)
ld $h2,16($ctx)
ld $padbit,0($nonce) # load nonce
ld $nonce,8($nonce)
addic $d0,$h0,5 # compare to modulus
addze $d1,$h1
addze $d2,$h2
srdi $mask,$d2,2 # did it carry/borrow?
neg $mask,$mask
andc $h0,$h0,$mask
and $d0,$d0,$mask
andc $h1,$h1,$mask
and $d1,$d1,$mask
or $h0,$h0,$d0
or $h1,$h1,$d1
___
$code.=<<___ if (!$LITTLE_ENDIAN);
rotldi $padbit,$padbit,32 # flip nonce words
rotldi $nonce,$nonce,32
___
$code.=<<___;
addc $h0,$h0,$padbit # accumulate nonce
adde $h1,$h1,$nonce
___
$code.=<<___ if ($LITTLE_ENDIAN);
std $h0,0($mac) # write result
std $h1,8($mac)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
extrdi r0,$h0,32,0
li $d0,4
stwbrx $h0,0,$mac # write result
extrdi $h0,$h1,32,0
li $d1,8
stwbrx r0,$d0,$mac
li $d2,12
stwbrx $h1,$d1,$mac
stwbrx $h0,$d2,$mac
___
$code.=<<___;
blr
.long 0
.byte 0,12,0x14,0,0,0,3,0
.size .poly1305_emit,.-.poly1305_emit
___
} else {
###############################################################################
# base 2^32 implementation
my ($h0,$h1,$h2,$h3,$h4, $r0,$r1,$r2,$r3, $s1,$s2,$s3,
$t0,$t1,$t2,$t3, $D0,$D1,$D2,$D3, $d0,$d1,$d2,$d3
) = map("r$_",(7..12,14..31));
$code.=<<___;
.globl .poly1305_init_int
.align 4
.poly1305_init_int:
xor r0,r0,r0
stw r0,0($ctx) # zero hash value
stw r0,4($ctx)
stw r0,8($ctx)
stw r0,12($ctx)
stw r0,16($ctx)
$UCMP $inp,r0
beq- Lno_key
___
$code.=<<___ if ($LITTLE_ENDIAN);
lw $h0,0($inp) # load key material
lw $h1,4($inp)
lw $h2,8($inp)
lw $h3,12($inp)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $h1,4
lwbrx $h0,0,$inp # load key material
li $h2,8
lwbrx $h1,$h1,$inp
li $h3,12
lwbrx $h2,$h2,$inp
lwbrx $h3,$h3,$inp
___
$code.=<<___;
lis $mask,0xf000 # 0xf0000000
li $r0,-4
andc $r0,$r0,$mask # 0x0ffffffc
andc $h0,$h0,$mask
and $h1,$h1,$r0
and $h2,$h2,$r0
and $h3,$h3,$r0
stw $h0,32($ctx) # store key
stw $h1,36($ctx)
stw $h2,40($ctx)
stw $h3,44($ctx)
Lno_key:
xor r3,r3,r3
blr
.long 0
.byte 0,12,0x14,0,0,0,2,0
.size .poly1305_init_int,.-.poly1305_init_int
.globl .poly1305_blocks
.align 4
.poly1305_blocks:
srwi. $len,$len,4
beq- Labort
$STU $sp,-$FRAME($sp)
mflr r0
$PUSH r14,`$FRAME-$SIZE_T*18`($sp)
$PUSH r15,`$FRAME-$SIZE_T*17`($sp)
$PUSH r16,`$FRAME-$SIZE_T*16`($sp)
$PUSH r17,`$FRAME-$SIZE_T*15`($sp)
$PUSH r18,`$FRAME-$SIZE_T*14`($sp)
$PUSH r19,`$FRAME-$SIZE_T*13`($sp)
$PUSH r20,`$FRAME-$SIZE_T*12`($sp)
$PUSH r21,`$FRAME-$SIZE_T*11`($sp)
$PUSH r22,`$FRAME-$SIZE_T*10`($sp)
$PUSH r23,`$FRAME-$SIZE_T*9`($sp)
$PUSH r24,`$FRAME-$SIZE_T*8`($sp)
$PUSH r25,`$FRAME-$SIZE_T*7`($sp)
$PUSH r26,`$FRAME-$SIZE_T*6`($sp)
$PUSH r27,`$FRAME-$SIZE_T*5`($sp)
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
lwz $r0,32($ctx) # load key
lwz $r1,36($ctx)
lwz $r2,40($ctx)
lwz $r3,44($ctx)
lwz $h0,0($ctx) # load hash value
lwz $h1,4($ctx)
lwz $h2,8($ctx)
lwz $h3,12($ctx)
lwz $h4,16($ctx)
srwi $s1,$r1,2
srwi $s2,$r2,2
srwi $s3,$r3,2
add $s1,$s1,$r1 # si = ri + ri>>2
add $s2,$s2,$r2
add $s3,$s3,$r3
mtctr $len
li $mask,3
b Loop
.align 4
Loop:
___
$code.=<<___ if ($LITTLE_ENDIAN);
lwz $d0,0($inp) # load input
lwz $d1,4($inp)
lwz $d2,8($inp)
lwz $d3,12($inp)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $d1,4
lwbrx $d0,0,$inp # load input
li $d2,8
lwbrx $d1,$d1,$inp
li $d3,12
lwbrx $d2,$d2,$inp
lwbrx $d3,$d3,$inp
___
$code.=<<___;
addi $inp,$inp,16
addc $h0,$h0,$d0 # accumulate input
adde $h1,$h1,$d1
adde $h2,$h2,$d2
mullw $d0,$h0,$r0 # h0*r0
mulhwu $D0,$h0,$r0
mullw $d1,$h0,$r1 # h0*r1
mulhwu $D1,$h0,$r1
mullw $d2,$h0,$r2 # h0*r2
mulhwu $D2,$h0,$r2
adde $h3,$h3,$d3
adde $h4,$h4,$padbit
mullw $d3,$h0,$r3 # h0*r3
mulhwu $D3,$h0,$r3
mullw $t0,$h1,$s3 # h1*s3
mulhwu $t1,$h1,$s3
mullw $t2,$h1,$r0 # h1*r0
mulhwu $t3,$h1,$r0
addc $d0,$d0,$t0
adde $D0,$D0,$t1
mullw $t0,$h1,$r1 # h1*r1
mulhwu $t1,$h1,$r1
addc $d1,$d1,$t2
adde $D1,$D1,$t3
mullw $t2,$h1,$r2 # h1*r2
mulhwu $t3,$h1,$r2
addc $d2,$d2,$t0
adde $D2,$D2,$t1
mullw $t0,$h2,$s2 # h2*s2
mulhwu $t1,$h2,$s2
addc $d3,$d3,$t2
adde $D3,$D3,$t3
mullw $t2,$h2,$s3 # h2*s3
mulhwu $t3,$h2,$s3
addc $d0,$d0,$t0
adde $D0,$D0,$t1
mullw $t0,$h2,$r0 # h2*r0
mulhwu $t1,$h2,$r0
addc $d1,$d1,$t2
adde $D1,$D1,$t3
mullw $t2,$h2,$r1 # h2*r1
mulhwu $t3,$h2,$r1
addc $d2,$d2,$t0
adde $D2,$D2,$t1
mullw $t0,$h3,$s1 # h3*s1
mulhwu $t1,$h3,$s1
addc $d3,$d3,$t2
adde $D3,$D3,$t3
mullw $t2,$h3,$s2 # h3*s2
mulhwu $t3,$h3,$s2
addc $d0,$d0,$t0
adde $D0,$D0,$t1
mullw $t0,$h3,$s3 # h3*s3
mulhwu $t1,$h3,$s3
addc $d1,$d1,$t2
adde $D1,$D1,$t3
mullw $t2,$h3,$r0 # h3*r0
mulhwu $t3,$h3,$r0
addc $d2,$d2,$t0
adde $D2,$D2,$t1
mullw $t0,$h4,$s1 # h4*s1
addc $d3,$d3,$t2
adde $D3,$D3,$t3
addc $d1,$d1,$t0
mullw $t1,$h4,$s2 # h4*s2
addze $D1,$D1
addc $d2,$d2,$t1
addze $D2,$D2
mullw $t2,$h4,$s3 # h4*s3
addc $d3,$d3,$t2
addze $D3,$D3
mullw $h4,$h4,$r0 # h4*r0
addc $h1,$d1,$D0
adde $h2,$d2,$D1
adde $h3,$d3,$D2
adde $h4,$h4,$D3
andc $D0,$h4,$mask # final reduction step
and $h4,$h4,$mask
srwi $D1,$D0,2
add $D0,$D0,$D1
addc $h0,$d0,$D0
addze $h1,$h1
addze $h2,$h2
addze $h3,$h3
bdnz Loop
stw $h0,0($ctx) # store hash value
stw $h1,4($ctx)
stw $h2,8($ctx)
stw $h3,12($ctx)
stw $h4,16($ctx)
$POP r14,`$FRAME-$SIZE_T*18`($sp)
$POP r15,`$FRAME-$SIZE_T*17`($sp)
$POP r16,`$FRAME-$SIZE_T*16`($sp)
$POP r17,`$FRAME-$SIZE_T*15`($sp)
$POP r18,`$FRAME-$SIZE_T*14`($sp)
$POP r19,`$FRAME-$SIZE_T*13`($sp)
$POP r20,`$FRAME-$SIZE_T*12`($sp)
$POP r21,`$FRAME-$SIZE_T*11`($sp)
$POP r22,`$FRAME-$SIZE_T*10`($sp)
$POP r23,`$FRAME-$SIZE_T*9`($sp)
$POP r24,`$FRAME-$SIZE_T*8`($sp)
$POP r25,`$FRAME-$SIZE_T*7`($sp)
$POP r26,`$FRAME-$SIZE_T*6`($sp)
$POP r27,`$FRAME-$SIZE_T*5`($sp)
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
addi $sp,$sp,$FRAME
Labort:
blr
.long 0
.byte 0,12,4,1,0x80,18,4,0
.size .poly1305_blocks,.-.poly1305_blocks
.globl .poly1305_emit
.align 4
.poly1305_emit:
$STU $sp,-$FRAME($sp)
mflr r0
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
lwz $h0,0($ctx) # load hash
lwz $h1,4($ctx)
lwz $h2,8($ctx)
lwz $h3,12($ctx)
lwz $h4,16($ctx)
addic $d0,$h0,5 # compare to modulus
addze $d1,$h1
addze $d2,$h2
addze $d3,$h3
addze $mask,$h4
srwi $mask,$mask,2 # did it carry/borrow?
neg $mask,$mask
andc $h0,$h0,$mask
and $d0,$d0,$mask
andc $h1,$h1,$mask
and $d1,$d1,$mask
or $h0,$h0,$d0
lwz $d0,0($nonce) # load nonce
andc $h2,$h2,$mask
and $d2,$d2,$mask
or $h1,$h1,$d1
lwz $d1,4($nonce)
andc $h3,$h3,$mask
and $d3,$d3,$mask
or $h2,$h2,$d2
lwz $d2,8($nonce)
or $h3,$h3,$d3
lwz $d3,12($nonce)
addc $h0,$h0,$d0 # accumulate nonce
adde $h1,$h1,$d1
adde $h2,$h2,$d2
adde $h3,$h3,$d3
___
$code.=<<___ if ($LITTLE_ENDIAN);
stw $h0,0($mac) # write result
stw $h1,4($mac)
stw $h2,8($mac)
stw $h3,12($mac)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $d1,4
stwbrx $h0,0,$mac # write result
li $d2,8
stwbrx $h1,$d1,$mac
li $d3,12
stwbrx $h2,$d2,$mac
stwbrx $h3,$d3,$mac
___
$code.=<<___;
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
addi $sp,$sp,$FRAME
blr
.long 0
.byte 0,12,4,1,0x80,4,3,0
.size .poly1305_emit,.-.poly1305_emit
___
}
$code.=<<___;
.asciz "Poly1305 for PPC, CRYPTOGAMS by <appro\@openssl.org>"
___
$code =~ s/\`([^\`]*)\`/eval $1/gem;
print $code;
close STDOUT;

View File

@ -0,0 +1,732 @@
#!/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/.
# ====================================================================
#
# This module implements Poly1305 hash for PowerPC FPU.
#
# June 2015
#
# Numbers are cycles per processed byte with poly1305_blocks alone,
# and improvement coefficients relative to gcc-generated code.
#
# Freescale e300 9.78/+30%
# PPC74x0 7.08/+50%
# PPC970 6.24/+80%
# POWER7 3.50/+30%
# POWER8 3.75/+10%
$flavour = shift;
if ($flavour =~ /64/) {
$SIZE_T =8;
$LRSAVE =2*$SIZE_T;
$UCMP ="cmpld";
$STU ="stdu";
$POP ="ld";
$PUSH ="std";
} elsif ($flavour =~ /32/) {
$SIZE_T =4;
$LRSAVE =$SIZE_T;
$UCMP ="cmplw";
$STU ="stwu";
$POP ="lwz";
$PUSH ="stw";
} else { die "nonsense $flavour"; }
$LITTLE_ENDIAN = ($flavour=~/le$/) ? 4 : 0;
$LWXLE = $LITTLE_ENDIAN ? "lwzx" : "lwbrx";
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $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: $!";
$LOCALS=6*$SIZE_T;
$FRAME=$LOCALS+6*8+18*8;
my $sp="r1";
my ($ctx,$inp,$len,$padbit) = map("r$_",(3..6));
my ($in0,$in1,$in2,$in3,$i1,$i2,$i3) = map("r$_",(7..12,6));
my ($h0lo,$h0hi,$h1lo,$h1hi,$h2lo,$h2hi,$h3lo,$h3hi,
$two0,$two32,$two64,$two96,$two130,$five_two130,
$r0lo,$r0hi,$r1lo,$r1hi,$r2lo,$r2hi,
$s2lo,$s2hi,$s3lo,$s3hi,
$c0lo,$c0hi,$c1lo,$c1hi,$c2lo,$c2hi,$c3lo,$c3hi) = map("f$_",(0..31));
# borrowings
my ($r3lo,$r3hi,$s1lo,$s1hi) = ($c0lo,$c0hi,$c1lo,$c1hi);
my ($x0,$x1,$x2,$x3) = ($c2lo,$c2hi,$c3lo,$c3hi);
my ($y0,$y1,$y2,$y3) = ($c3lo,$c3hi,$c1lo,$c1hi);
$code.=<<___;
.machine "any"
.text
.globl .poly1305_init_fpu
.align 6
.poly1305_init_fpu:
$STU $sp,-$LOCALS($sp) # minimal frame
mflr $padbit
$PUSH $padbit,`$LOCALS+$LRSAVE`($sp)
bl LPICmeup
xor r0,r0,r0
mtlr $padbit # restore lr
lfd $two0,8*0($len) # load constants
lfd $two32,8*1($len)
lfd $two64,8*2($len)
lfd $two96,8*3($len)
lfd $two130,8*4($len)
lfd $five_two130,8*5($len)
stfd $two0,8*0($ctx) # initial hash value, biased 0
stfd $two32,8*1($ctx)
stfd $two64,8*2($ctx)
stfd $two96,8*3($ctx)
$UCMP $inp,r0
beq- Lno_key
lfd $h3lo,8*13($len) # new fpscr
mffs $h3hi # old fpscr
stfd $two0,8*4($ctx) # key "template"
stfd $two32,8*5($ctx)
stfd $two64,8*6($ctx)
stfd $two96,8*7($ctx)
li $in1,4
li $in2,8
li $in3,12
$LWXLE $in0,0,$inp # load key
$LWXLE $in1,$in1,$inp
$LWXLE $in2,$in2,$inp
$LWXLE $in3,$in3,$inp
lis $i1,0xf000 # 0xf0000000
ori $i2,$i1,3 # 0xf0000003
andc $in0,$in0,$i1 # &=0x0fffffff
andc $in1,$in1,$i2 # &=0x0ffffffc
andc $in2,$in2,$i2
andc $in3,$in3,$i2
stw $in0,`8*4+(4^$LITTLE_ENDIAN)`($ctx) # fill "template"
stw $in1,`8*5+(4^$LITTLE_ENDIAN)`($ctx)
stw $in2,`8*6+(4^$LITTLE_ENDIAN)`($ctx)
stw $in3,`8*7+(4^$LITTLE_ENDIAN)`($ctx)
mtfsf 255,$h3lo # fpscr
stfd $two0,8*18($ctx) # copy constants to context
stfd $two32,8*19($ctx)
stfd $two64,8*20($ctx)
stfd $two96,8*21($ctx)
stfd $two130,8*22($ctx)
stfd $five_two130,8*23($ctx)
lfd $h0lo,8*4($ctx) # load [biased] key
lfd $h1lo,8*5($ctx)
lfd $h2lo,8*6($ctx)
lfd $h3lo,8*7($ctx)
fsub $h0lo,$h0lo,$two0 # r0
fsub $h1lo,$h1lo,$two32 # r1
fsub $h2lo,$h2lo,$two64 # r2
fsub $h3lo,$h3lo,$two96 # r3
lfd $two0,8*6($len) # more constants
lfd $two32,8*7($len)
lfd $two64,8*8($len)
lfd $two96,8*9($len)
fmul $h1hi,$h1lo,$five_two130 # s1
fmul $h2hi,$h2lo,$five_two130 # s2
stfd $h3hi,8*15($ctx) # borrow slot for original fpscr
fmul $h3hi,$h3lo,$five_two130 # s3
fadd $h0hi,$h0lo,$two0
stfd $h1hi,8*12($ctx) # put aside for now
fadd $h1hi,$h1lo,$two32
stfd $h2hi,8*13($ctx)
fadd $h2hi,$h2lo,$two64
stfd $h3hi,8*14($ctx)
fadd $h3hi,$h3lo,$two96
fsub $h0hi,$h0hi,$two0
fsub $h1hi,$h1hi,$two32
fsub $h2hi,$h2hi,$two64
fsub $h3hi,$h3hi,$two96
lfd $two0,8*10($len) # more constants
lfd $two32,8*11($len)
lfd $two64,8*12($len)
fsub $h0lo,$h0lo,$h0hi
fsub $h1lo,$h1lo,$h1hi
fsub $h2lo,$h2lo,$h2hi
fsub $h3lo,$h3lo,$h3hi
stfd $h0hi,8*5($ctx) # r0hi
stfd $h1hi,8*7($ctx) # r1hi
stfd $h2hi,8*9($ctx) # r2hi
stfd $h3hi,8*11($ctx) # r3hi
stfd $h0lo,8*4($ctx) # r0lo
stfd $h1lo,8*6($ctx) # r1lo
stfd $h2lo,8*8($ctx) # r2lo
stfd $h3lo,8*10($ctx) # r3lo
lfd $h1lo,8*12($ctx) # s1
lfd $h2lo,8*13($ctx) # s2
lfd $h3lo,8*14($ctx) # s3
lfd $h0lo,8*15($ctx) # pull original fpscr
fadd $h1hi,$h1lo,$two0
fadd $h2hi,$h2lo,$two32
fadd $h3hi,$h3lo,$two64
fsub $h1hi,$h1hi,$two0
fsub $h2hi,$h2hi,$two32
fsub $h3hi,$h3hi,$two64
fsub $h1lo,$h1lo,$h1hi
fsub $h2lo,$h2lo,$h2hi
fsub $h3lo,$h3lo,$h3hi
stfd $h1hi,8*13($ctx) # s1hi
stfd $h2hi,8*15($ctx) # s2hi
stfd $h3hi,8*17($ctx) # s3hi
stfd $h1lo,8*12($ctx) # s1lo
stfd $h2lo,8*14($ctx) # s2lo
stfd $h3lo,8*16($ctx) # s3lo
mtfsf 255,$h0lo # restore fpscr
Lno_key:
xor r3,r3,r3
addi $sp,$sp,$LOCALS
blr
.long 0
.byte 0,12,4,1,0x80,0,2,0
.size .poly1305_init_fpu,.-.poly1305_init_fpu
.globl .poly1305_blocks_fpu
.align 4
.poly1305_blocks_fpu:
srwi. $len,$len,4
beq- Labort
$STU $sp,-$FRAME($sp)
mflr r0
stfd f14,`$FRAME-8*18`($sp)
stfd f15,`$FRAME-8*17`($sp)
stfd f16,`$FRAME-8*16`($sp)
stfd f17,`$FRAME-8*15`($sp)
stfd f18,`$FRAME-8*14`($sp)
stfd f19,`$FRAME-8*13`($sp)
stfd f20,`$FRAME-8*12`($sp)
stfd f21,`$FRAME-8*11`($sp)
stfd f22,`$FRAME-8*10`($sp)
stfd f23,`$FRAME-8*9`($sp)
stfd f24,`$FRAME-8*8`($sp)
stfd f25,`$FRAME-8*7`($sp)
stfd f26,`$FRAME-8*6`($sp)
stfd f27,`$FRAME-8*5`($sp)
stfd f28,`$FRAME-8*4`($sp)
stfd f29,`$FRAME-8*3`($sp)
stfd f30,`$FRAME-8*2`($sp)
stfd f31,`$FRAME-8*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
xor r0,r0,r0
li $in3,1
mtctr $len
neg $len,$len
stw r0,`$LOCALS+8*4+(0^$LITTLE_ENDIAN)`($sp)
stw $in3,`$LOCALS+8*4+(4^$LITTLE_ENDIAN)`($sp)
lfd $two0,8*18($ctx) # load constants
lfd $two32,8*19($ctx)
lfd $two64,8*20($ctx)
lfd $two96,8*21($ctx)
lfd $two130,8*22($ctx)
lfd $five_two130,8*23($ctx)
lfd $h0lo,8*0($ctx) # load [biased] hash value
lfd $h1lo,8*1($ctx)
lfd $h2lo,8*2($ctx)
lfd $h3lo,8*3($ctx)
stfd $two0,`$LOCALS+8*0`($sp) # input "template"
oris $in3,$padbit,`(1023+52+96)<<4`
stfd $two32,`$LOCALS+8*1`($sp)
stfd $two64,`$LOCALS+8*2`($sp)
stw $in3,`$LOCALS+8*3+(0^$LITTLE_ENDIAN)`($sp)
li $i1,4
li $i2,8
li $i3,12
$LWXLE $in0,0,$inp # load input
$LWXLE $in1,$i1,$inp
$LWXLE $in2,$i2,$inp
$LWXLE $in3,$i3,$inp
addi $inp,$inp,16
stw $in0,`$LOCALS+8*0+(4^$LITTLE_ENDIAN)`($sp) # fill "template"
stw $in1,`$LOCALS+8*1+(4^$LITTLE_ENDIAN)`($sp)
stw $in2,`$LOCALS+8*2+(4^$LITTLE_ENDIAN)`($sp)
stw $in3,`$LOCALS+8*3+(4^$LITTLE_ENDIAN)`($sp)
mffs $x0 # original fpscr
lfd $x1,`$LOCALS+8*4`($sp) # new fpscr
lfd $r0lo,8*4($ctx) # load key
lfd $r0hi,8*5($ctx)
lfd $r1lo,8*6($ctx)
lfd $r1hi,8*7($ctx)
lfd $r2lo,8*8($ctx)
lfd $r2hi,8*9($ctx)
lfd $r3lo,8*10($ctx)
lfd $r3hi,8*11($ctx)
lfd $s1lo,8*12($ctx)
lfd $s1hi,8*13($ctx)
lfd $s2lo,8*14($ctx)
lfd $s2hi,8*15($ctx)
lfd $s3lo,8*16($ctx)
lfd $s3hi,8*17($ctx)
stfd $x0,`$LOCALS+8*4`($sp) # save original fpscr
mtfsf 255,$x1
addic $len,$len,1
addze r0,r0
slwi. r0,r0,4
sub $inp,$inp,r0 # conditional rewind
lfd $x0,`$LOCALS+8*0`($sp)
lfd $x1,`$LOCALS+8*1`($sp)
lfd $x2,`$LOCALS+8*2`($sp)
lfd $x3,`$LOCALS+8*3`($sp)
fsub $h0lo,$h0lo,$two0 # de-bias hash value
$LWXLE $in0,0,$inp # modulo-scheduled input load
fsub $h1lo,$h1lo,$two32
$LWXLE $in1,$i1,$inp
fsub $h2lo,$h2lo,$two64
$LWXLE $in2,$i2,$inp
fsub $h3lo,$h3lo,$two96
$LWXLE $in3,$i3,$inp
fsub $x0,$x0,$two0 # de-bias input
addi $inp,$inp,16
fsub $x1,$x1,$two32
fsub $x2,$x2,$two64
fsub $x3,$x3,$two96
fadd $x0,$x0,$h0lo # accumulate input
stw $in0,`$LOCALS+8*0+(4^$LITTLE_ENDIAN)`($sp)
fadd $x1,$x1,$h1lo
stw $in1,`$LOCALS+8*1+(4^$LITTLE_ENDIAN)`($sp)
fadd $x2,$x2,$h2lo
stw $in2,`$LOCALS+8*2+(4^$LITTLE_ENDIAN)`($sp)
fadd $x3,$x3,$h3lo
stw $in3,`$LOCALS+8*3+(4^$LITTLE_ENDIAN)`($sp)
b Lentry
.align 4
Loop:
fsub $y0,$y0,$two0 # de-bias input
addic $len,$len,1
fsub $y1,$y1,$two32
addze r0,r0
fsub $y2,$y2,$two64
slwi. r0,r0,4
fsub $y3,$y3,$two96
sub $inp,$inp,r0 # conditional rewind
fadd $h0lo,$h0lo,$y0 # accumulate input
fadd $h0hi,$h0hi,$y1
fadd $h2lo,$h2lo,$y2
fadd $h2hi,$h2hi,$y3
######################################### base 2^48 -> base 2^32
fadd $c1lo,$h1lo,$two64
$LWXLE $in0,0,$inp # modulo-scheduled input load
fadd $c1hi,$h1hi,$two64
$LWXLE $in1,$i1,$inp
fadd $c3lo,$h3lo,$two130
$LWXLE $in2,$i2,$inp
fadd $c3hi,$h3hi,$two130
$LWXLE $in3,$i3,$inp
fadd $c0lo,$h0lo,$two32
addi $inp,$inp,16
fadd $c0hi,$h0hi,$two32
fadd $c2lo,$h2lo,$two96
fadd $c2hi,$h2hi,$two96
fsub $c1lo,$c1lo,$two64
stw $in0,`$LOCALS+8*0+(4^$LITTLE_ENDIAN)`($sp) # fill "template"
fsub $c1hi,$c1hi,$two64
stw $in1,`$LOCALS+8*1+(4^$LITTLE_ENDIAN)`($sp)
fsub $c3lo,$c3lo,$two130
stw $in2,`$LOCALS+8*2+(4^$LITTLE_ENDIAN)`($sp)
fsub $c3hi,$c3hi,$two130
stw $in3,`$LOCALS+8*3+(4^$LITTLE_ENDIAN)`($sp)
fsub $c0lo,$c0lo,$two32
fsub $c0hi,$c0hi,$two32
fsub $c2lo,$c2lo,$two96
fsub $c2hi,$c2hi,$two96
fsub $h1lo,$h1lo,$c1lo
fsub $h1hi,$h1hi,$c1hi
fsub $h3lo,$h3lo,$c3lo
fsub $h3hi,$h3hi,$c3hi
fsub $h2lo,$h2lo,$c2lo
fsub $h2hi,$h2hi,$c2hi
fsub $h0lo,$h0lo,$c0lo
fsub $h0hi,$h0hi,$c0hi
fadd $h1lo,$h1lo,$c0lo
fadd $h1hi,$h1hi,$c0hi
fadd $h3lo,$h3lo,$c2lo
fadd $h3hi,$h3hi,$c2hi
fadd $h2lo,$h2lo,$c1lo
fadd $h2hi,$h2hi,$c1hi
fmadd $h0lo,$c3lo,$five_two130,$h0lo
fmadd $h0hi,$c3hi,$five_two130,$h0hi
fadd $x1,$h1lo,$h1hi
lfd $s1lo,8*12($ctx) # reload constants
fadd $x3,$h3lo,$h3hi
lfd $s1hi,8*13($ctx)
fadd $x2,$h2lo,$h2hi
lfd $r3lo,8*10($ctx)
fadd $x0,$h0lo,$h0hi
lfd $r3hi,8*11($ctx)
Lentry:
fmul $h0lo,$s3lo,$x1
fmul $h0hi,$s3hi,$x1
fmul $h2lo,$r1lo,$x1
fmul $h2hi,$r1hi,$x1
fmul $h1lo,$r0lo,$x1
fmul $h1hi,$r0hi,$x1
fmul $h3lo,$r2lo,$x1
fmul $h3hi,$r2hi,$x1
fmadd $h0lo,$s1lo,$x3,$h0lo
fmadd $h0hi,$s1hi,$x3,$h0hi
fmadd $h2lo,$s3lo,$x3,$h2lo
fmadd $h2hi,$s3hi,$x3,$h2hi
fmadd $h1lo,$s2lo,$x3,$h1lo
fmadd $h1hi,$s2hi,$x3,$h1hi
fmadd $h3lo,$r0lo,$x3,$h3lo
fmadd $h3hi,$r0hi,$x3,$h3hi
fmadd $h0lo,$s2lo,$x2,$h0lo
fmadd $h0hi,$s2hi,$x2,$h0hi
fmadd $h2lo,$r0lo,$x2,$h2lo
fmadd $h2hi,$r0hi,$x2,$h2hi
fmadd $h1lo,$s3lo,$x2,$h1lo
fmadd $h1hi,$s3hi,$x2,$h1hi
fmadd $h3lo,$r1lo,$x2,$h3lo
fmadd $h3hi,$r1hi,$x2,$h3hi
fmadd $h0lo,$r0lo,$x0,$h0lo
lfd $y0,`$LOCALS+8*0`($sp) # load [biased] input
fmadd $h0hi,$r0hi,$x0,$h0hi
lfd $y1,`$LOCALS+8*1`($sp)
fmadd $h2lo,$r2lo,$x0,$h2lo
lfd $y2,`$LOCALS+8*2`($sp)
fmadd $h2hi,$r2hi,$x0,$h2hi
lfd $y3,`$LOCALS+8*3`($sp)
fmadd $h1lo,$r1lo,$x0,$h1lo
fmadd $h1hi,$r1hi,$x0,$h1hi
fmadd $h3lo,$r3lo,$x0,$h3lo
fmadd $h3hi,$r3hi,$x0,$h3hi
bdnz Loop
######################################### base 2^48 -> base 2^32
fadd $c0lo,$h0lo,$two32
fadd $c0hi,$h0hi,$two32
fadd $c2lo,$h2lo,$two96
fadd $c2hi,$h2hi,$two96
fadd $c1lo,$h1lo,$two64
fadd $c1hi,$h1hi,$two64
fadd $c3lo,$h3lo,$two130
fadd $c3hi,$h3hi,$two130
fsub $c0lo,$c0lo,$two32
fsub $c0hi,$c0hi,$two32
fsub $c2lo,$c2lo,$two96
fsub $c2hi,$c2hi,$two96
fsub $c1lo,$c1lo,$two64
fsub $c1hi,$c1hi,$two64
fsub $c3lo,$c3lo,$two130
fsub $c3hi,$c3hi,$two130
fsub $h1lo,$h1lo,$c1lo
fsub $h1hi,$h1hi,$c1hi
fsub $h3lo,$h3lo,$c3lo
fsub $h3hi,$h3hi,$c3hi
fsub $h2lo,$h2lo,$c2lo
fsub $h2hi,$h2hi,$c2hi
fsub $h0lo,$h0lo,$c0lo
fsub $h0hi,$h0hi,$c0hi
fadd $h1lo,$h1lo,$c0lo
fadd $h1hi,$h1hi,$c0hi
fadd $h3lo,$h3lo,$c2lo
fadd $h3hi,$h3hi,$c2hi
fadd $h2lo,$h2lo,$c1lo
fadd $h2hi,$h2hi,$c1hi
fmadd $h0lo,$c3lo,$five_two130,$h0lo
fmadd $h0hi,$c3hi,$five_two130,$h0hi
fadd $x1,$h1lo,$h1hi
fadd $x3,$h3lo,$h3hi
fadd $x2,$h2lo,$h2hi
fadd $x0,$h0lo,$h0hi
lfd $h0lo,`$LOCALS+8*4`($sp) # pull saved fpscr
fadd $x1,$x1,$two32 # bias
fadd $x3,$x3,$two96
fadd $x2,$x2,$two64
fadd $x0,$x0,$two0
stfd $x1,8*1($ctx) # store [biased] hash value
stfd $x3,8*3($ctx)
stfd $x2,8*2($ctx)
stfd $x0,8*0($ctx)
mtfsf 255,$h0lo # restore original fpscr
lfd f14,`$FRAME-8*18`($sp)
lfd f15,`$FRAME-8*17`($sp)
lfd f16,`$FRAME-8*16`($sp)
lfd f17,`$FRAME-8*15`($sp)
lfd f18,`$FRAME-8*14`($sp)
lfd f19,`$FRAME-8*13`($sp)
lfd f20,`$FRAME-8*12`($sp)
lfd f21,`$FRAME-8*11`($sp)
lfd f22,`$FRAME-8*10`($sp)
lfd f23,`$FRAME-8*9`($sp)
lfd f24,`$FRAME-8*8`($sp)
lfd f25,`$FRAME-8*7`($sp)
lfd f26,`$FRAME-8*6`($sp)
lfd f27,`$FRAME-8*5`($sp)
lfd f28,`$FRAME-8*4`($sp)
lfd f29,`$FRAME-8*3`($sp)
lfd f30,`$FRAME-8*2`($sp)
lfd f31,`$FRAME-8*1`($sp)
addi $sp,$sp,$FRAME
Labort:
blr
.long 0
.byte 0,12,4,1,0x80,0,4,0
.size .poly1305_blocks_fpu,.-.poly1305_blocks_fpu
___
{
my ($mac,$nonce)=($inp,$len);
my ($h0,$h1,$h2,$h3,$h4, $d0,$d1,$d2,$d3
) = map("r$_",(7..11,28..31));
my $mask = "r0";
my $FRAME = (6+4)*$SIZE_T;
$code.=<<___;
.globl .poly1305_emit_fpu
.align 4
.poly1305_emit_fpu:
$STU $sp,-$FRAME($sp)
mflr r0
$PUSH r28,`$FRAME-$SIZE_T*4`($sp)
$PUSH r29,`$FRAME-$SIZE_T*3`($sp)
$PUSH r30,`$FRAME-$SIZE_T*2`($sp)
$PUSH r31,`$FRAME-$SIZE_T*1`($sp)
$PUSH r0,`$FRAME+$LRSAVE`($sp)
lwz $d0,`8*0+(0^$LITTLE_ENDIAN)`($ctx) # load hash
lwz $h0,`8*0+(4^$LITTLE_ENDIAN)`($ctx)
lwz $d1,`8*1+(0^$LITTLE_ENDIAN)`($ctx)
lwz $h1,`8*1+(4^$LITTLE_ENDIAN)`($ctx)
lwz $d2,`8*2+(0^$LITTLE_ENDIAN)`($ctx)
lwz $h2,`8*2+(4^$LITTLE_ENDIAN)`($ctx)
lwz $d3,`8*3+(0^$LITTLE_ENDIAN)`($ctx)
lwz $h3,`8*3+(4^$LITTLE_ENDIAN)`($ctx)
lis $mask,0xfff0
andc $d0,$d0,$mask # mask exponent
andc $d1,$d1,$mask
andc $d2,$d2,$mask
andc $d3,$d3,$mask # can be partially reduced...
li $mask,3
srwi $padbit,$d3,2 # ... so reduce
and $h4,$d3,$mask
andc $d3,$d3,$mask
add $d3,$d3,$padbit
___
if ($SIZE_T==4) {
$code.=<<___;
addc $h0,$h0,$d3
adde $h1,$h1,$d0
adde $h2,$h2,$d1
adde $h3,$h3,$d2
addze $h4,$h4
addic $d0,$h0,5 # compare to modulus
addze $d1,$h1
addze $d2,$h2
addze $d3,$h3
addze $mask,$h4
srwi $mask,$mask,2 # did it carry/borrow?
neg $mask,$mask
srawi $mask,$mask,31 # mask
andc $h0,$h0,$mask
and $d0,$d0,$mask
andc $h1,$h1,$mask
and $d1,$d1,$mask
or $h0,$h0,$d0
lwz $d0,0($nonce) # load nonce
andc $h2,$h2,$mask
and $d2,$d2,$mask
or $h1,$h1,$d1
lwz $d1,4($nonce)
andc $h3,$h3,$mask
and $d3,$d3,$mask
or $h2,$h2,$d2
lwz $d2,8($nonce)
or $h3,$h3,$d3
lwz $d3,12($nonce)
addc $h0,$h0,$d0 # accumulate nonce
adde $h1,$h1,$d1
adde $h2,$h2,$d2
adde $h3,$h3,$d3
___
} else {
$code.=<<___;
add $h0,$h0,$d3
add $h1,$h1,$d0
add $h2,$h2,$d1
add $h3,$h3,$d2
srdi $d0,$h0,32
add $h1,$h1,$d0
srdi $d1,$h1,32
add $h2,$h2,$d1
srdi $d2,$h2,32
add $h3,$h3,$d2
srdi $d3,$h3,32
add $h4,$h4,$d3
insrdi $h0,$h1,32,0
insrdi $h2,$h3,32,0
addic $d0,$h0,5 # compare to modulus
addze $d1,$h2
addze $d2,$h4
srdi $mask,$d2,2 # did it carry/borrow?
neg $mask,$mask
sradi $mask,$mask,63 # mask
ld $d2,0($nonce) # load nonce
ld $d3,8($nonce)
andc $h0,$h0,$mask
and $d0,$d0,$mask
andc $h2,$h2,$mask
and $d1,$d1,$mask
or $h0,$h0,$d0
or $h2,$h2,$d1
___
$code.=<<___ if (!$LITTLE_ENDIAN);
rotldi $d2,$d2,32 # flip nonce words
rotldi $d3,$d3,32
___
$code.=<<___;
addc $h0,$h0,$d2 # accumulate nonce
adde $h2,$h2,$d3
srdi $h1,$h0,32
srdi $h3,$h2,32
___
}
$code.=<<___ if ($LITTLE_ENDIAN);
stw $h0,0($mac) # write result
stw $h1,4($mac)
stw $h2,8($mac)
stw $h3,12($mac)
___
$code.=<<___ if (!$LITTLE_ENDIAN);
li $d1,4
stwbrx $h0,0,$mac # write result
li $d2,8
stwbrx $h1,$d1,$mac
li $d3,12
stwbrx $h2,$d2,$mac
stwbrx $h3,$d3,$mac
___
$code.=<<___;
$POP r28,`$FRAME-$SIZE_T*4`($sp)
$POP r29,`$FRAME-$SIZE_T*3`($sp)
$POP r30,`$FRAME-$SIZE_T*2`($sp)
$POP r31,`$FRAME-$SIZE_T*1`($sp)
addi $sp,$sp,$FRAME
blr
.long 0
.byte 0,12,4,1,0x80,4,3,0
.size .poly1305_emit_fpu,.-.poly1305_emit_fpu
___
}
# Ugly hack here, because PPC assembler syntax seem to vary too
# much from platforms to platform...
$code.=<<___;
.align 6
LPICmeup:
mflr r0
bcl 20,31,\$+4
mflr $len # vvvvvv "distance" between . and 1st data entry
addi $len,$len,`64-8` # borrow $len
mtlr r0
blr
.long 0
.byte 0,12,0x14,0,0,0,0,0
.space `64-9*4`
.quad 0x4330000000000000 # 2^(52+0)
.quad 0x4530000000000000 # 2^(52+32)
.quad 0x4730000000000000 # 2^(52+64)
.quad 0x4930000000000000 # 2^(52+96)
.quad 0x4b50000000000000 # 2^(52+130)
.quad 0x37f4000000000000 # 5/2^130
.quad 0x4430000000000000 # 2^(52+16+0)
.quad 0x4630000000000000 # 2^(52+16+32)
.quad 0x4830000000000000 # 2^(52+16+64)
.quad 0x4a30000000000000 # 2^(52+16+96)
.quad 0x3e30000000000000 # 2^(52+16+0-96)
.quad 0x4030000000000000 # 2^(52+16+32-96)
.quad 0x4230000000000000 # 2^(52+16+64-96)
.quad 0x0000000000000001 # fpscr: truncate, no exceptions
.asciz "Poly1305 for PPC FPU, CRYPTOGAMS by <appro\@openssl.org>"
.align 4
___
$code =~ s/\`([^\`]*)\`/eval $1/gem;
print $code;
close STDOUT;

View File

@ -9,6 +9,10 @@ BEGINRAW[Makefile(unix)]
$(PERL) {- $sourcedir -}/asm/poly1305-x86.pl $(PERLASM_SCHEME) $(CFLAGS) $(PROCESSOR) > $@
{- $builddir -}/poly1305-x86_64.s: {- $sourcedir -}/asm/poly1305-x86_64.pl
$(PERL) {- $sourcedir -}/asm/poly1305-x86_64.pl $(PERLASM_SCHEME) > $@
{- $builddir -}/poly1305-ppc.s: {- $sourcedir -}/asm/poly1305-ppc.pl
$(PERL) {- $sourcedir -}/asm/poly1305-ppc.pl $(PERLASM_SCHEME) $@
{- $builddir -}/poly1305-ppcfp.s: {- $sourcedir -}/asm/poly1305-ppcfp.pl
$(PERL) {- $sourcedir -}/asm/poly1305-ppcfp.pl $(PERLASM_SCHEME) $@
{- $builddir -}/poly1305-%.S: {- $sourcedir -}/asm/poly1305-%.pl
$(PERL) $< $(PERLASM_SCHEME) $@