virtualx-engine/drivers/builtin_openssl/crypto/bn/asm/ppc64-mont.pl
Juan Linietsky 87f37bc5a3 -Added OpenSSL and HTTPS support
-Built-in version of the library for Windows, Android and iOS (other OSs use system one)
-Small fixes all around
2014-04-28 21:56:43 -03:00

1088 lines
26 KiB
Raku
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#!/usr/bin/env perl
# ====================================================================
# Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
# project. The module is, however, dual licensed under OpenSSL and
# CRYPTOGAMS licenses depending on where you obtain it. For further
# details see http://www.openssl.org/~appro/cryptogams/.
# ====================================================================
# December 2007
# The reason for undertaken effort is basically following. Even though
# Power 6 CPU operates at incredible 4.7GHz clock frequency, its PKI
# performance was observed to be less than impressive, essentially as
# fast as 1.8GHz PPC970, or 2.6 times(!) slower than one would hope.
# Well, it's not surprising that IBM had to make some sacrifices to
# boost the clock frequency that much, but no overall improvement?
# Having observed how much difference did switching to FPU make on
# UltraSPARC, playing same stunt on Power 6 appeared appropriate...
# Unfortunately the resulting performance improvement is not as
# impressive, ~30%, and in absolute terms is still very far from what
# one would expect from 4.7GHz CPU. There is a chance that I'm doing
# something wrong, but in the lack of assembler level micro-profiling
# data or at least decent platform guide I can't tell... Or better
# results might be achieved with VMX... Anyway, this module provides
# *worse* performance on other PowerPC implementations, ~40-15% slower
# on PPC970 depending on key length and ~40% slower on Power 5 for all
# key lengths. As it's obviously inappropriate as "best all-round"
# alternative, it has to be complemented with run-time CPU family
# detection. Oh! It should also be noted that unlike other PowerPC
# implementation IALU ppc-mont.pl module performs *suboptimaly* on
# >=1024-bit key lengths on Power 6. It should also be noted that
# *everything* said so far applies to 64-bit builds! As far as 32-bit
# application executed on 64-bit CPU goes, this module is likely to
# become preferred choice, because it's easy to adapt it for such
# case and *is* faster than 32-bit ppc-mont.pl on *all* processors.
# February 2008
# Micro-profiling assisted optimization results in ~15% improvement
# over original ppc64-mont.pl version, or overall ~50% improvement
# over ppc.pl module on Power 6. If compared to ppc-mont.pl on same
# Power 6 CPU, this module is 5-150% faster depending on key length,
# [hereafter] more for longer keys. But if compared to ppc-mont.pl
# on 1.8GHz PPC970, it's only 5-55% faster. Still far from impressive
# in absolute terms, but it's apparently the way Power 6 is...
# December 2009
# Adapted for 32-bit build this module delivers 25-120%, yes, more
# than *twice* for longer keys, performance improvement over 32-bit
# ppc-mont.pl on 1.8GHz PPC970. However! This implementation utilizes
# even 64-bit integer operations and the trouble is that most PPC
# operating systems don't preserve upper halves of general purpose
# registers upon 32-bit signal delivery. They do preserve them upon
# context switch, but not signalling:-( This means that asynchronous
# signals have to be blocked upon entry to this subroutine. Signal
# masking (and of course complementary unmasking) has quite an impact
# on performance, naturally larger for shorter keys. It's so severe
# that 512-bit key performance can be as low as 1/3 of expected one.
# This is why this routine can be engaged for longer key operations
# only on these OSes, see crypto/ppccap.c for further details. MacOS X
# is an exception from this and doesn't require signal masking, and
# that's where above improvement coefficients were collected. For
# others alternative would be to break dependence on upper halves of
# GPRs by sticking to 32-bit integer operations...
$flavour = shift;
if ($flavour =~ /32/) {
$SIZE_T=4;
$RZONE= 224;
$fname= "bn_mul_mont_fpu64";
$STUX= "stwux"; # store indexed and update
$PUSH= "stw";
$POP= "lwz";
} elsif ($flavour =~ /64/) {
$SIZE_T=8;
$RZONE= 288;
$fname= "bn_mul_mont_fpu64";
# same as above, but 64-bit mnemonics...
$STUX= "stdux"; # store indexed and update
$PUSH= "std";
$POP= "ld";
} else { die "nonsense $flavour"; }
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $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=64; # padded frame header
$TRANSFER=16*8;
$carry="r0";
$sp="r1";
$toc="r2";
$rp="r3"; $ovf="r3";
$ap="r4";
$bp="r5";
$np="r6";
$n0="r7";
$num="r8";
$rp="r9"; # $rp is reassigned
$tp="r10";
$j="r11";
$i="r12";
# non-volatile registers
$nap_d="r22"; # interleaved ap and np in double format
$a0="r23"; # ap[0]
$t0="r24"; # temporary registers
$t1="r25";
$t2="r26";
$t3="r27";
$t4="r28";
$t5="r29";
$t6="r30";
$t7="r31";
# PPC offers enough register bank capacity to unroll inner loops twice
#
# ..A3A2A1A0
# dcba
# -----------
# A0a
# A0b
# A0c
# A0d
# A1a
# A1b
# A1c
# A1d
# A2a
# A2b
# A2c
# A2d
# A3a
# A3b
# A3c
# A3d
# ..a
# ..b
#
$ba="f0"; $bb="f1"; $bc="f2"; $bd="f3";
$na="f4"; $nb="f5"; $nc="f6"; $nd="f7";
$dota="f8"; $dotb="f9";
$A0="f10"; $A1="f11"; $A2="f12"; $A3="f13";
$N0="f20"; $N1="f21"; $N2="f22"; $N3="f23";
$T0a="f24"; $T0b="f25";
$T1a="f26"; $T1b="f27";
$T2a="f28"; $T2b="f29";
$T3a="f30"; $T3b="f31";
# sp----------->+-------------------------------+
# | saved sp |
# +-------------------------------+
# . .
# +64 +-------------------------------+
# | 16 gpr<->fpr transfer zone |
# . .
# . .
# +16*8 +-------------------------------+
# | __int64 tmp[-1] |
# +-------------------------------+
# | __int64 tmp[num] |
# . .
# . .
# . .
# +(num+1)*8 +-------------------------------+
# | padding to 64 byte boundary |
# . .
# +X +-------------------------------+
# | double nap_d[4*num] |
# . .
# . .
# . .
# +-------------------------------+
# . .
# -12*size_t +-------------------------------+
# | 10 saved gpr, r22-r31 |
# . .
# . .
# -12*8 +-------------------------------+
# | 12 saved fpr, f20-f31 |
# . .
# . .
# +-------------------------------+
$code=<<___;
.machine "any"
.text
.globl .$fname
.align 5
.$fname:
cmpwi $num,`3*8/$SIZE_T`
mr $rp,r3 ; $rp is reassigned
li r3,0 ; possible "not handled" return code
bltlr-
andi. r0,$num,`16/$SIZE_T-1` ; $num has to be "even"
bnelr-
slwi $num,$num,`log($SIZE_T)/log(2)` ; num*=sizeof(BN_LONG)
li $i,-4096
slwi $tp,$num,2 ; place for {an}p_{lh}[num], i.e. 4*num
add $tp,$tp,$num ; place for tp[num+1]
addi $tp,$tp,`$FRAME+$TRANSFER+8+64+$RZONE`
subf $tp,$tp,$sp ; $sp-$tp
and $tp,$tp,$i ; minimize TLB usage
subf $tp,$sp,$tp ; $tp-$sp
mr $i,$sp
$STUX $sp,$sp,$tp ; alloca
$PUSH r22,`-12*8-10*$SIZE_T`($i)
$PUSH r23,`-12*8-9*$SIZE_T`($i)
$PUSH r24,`-12*8-8*$SIZE_T`($i)
$PUSH r25,`-12*8-7*$SIZE_T`($i)
$PUSH r26,`-12*8-6*$SIZE_T`($i)
$PUSH r27,`-12*8-5*$SIZE_T`($i)
$PUSH r28,`-12*8-4*$SIZE_T`($i)
$PUSH r29,`-12*8-3*$SIZE_T`($i)
$PUSH r30,`-12*8-2*$SIZE_T`($i)
$PUSH r31,`-12*8-1*$SIZE_T`($i)
stfd f20,`-12*8`($i)
stfd f21,`-11*8`($i)
stfd f22,`-10*8`($i)
stfd f23,`-9*8`($i)
stfd f24,`-8*8`($i)
stfd f25,`-7*8`($i)
stfd f26,`-6*8`($i)
stfd f27,`-5*8`($i)
stfd f28,`-4*8`($i)
stfd f29,`-3*8`($i)
stfd f30,`-2*8`($i)
stfd f31,`-1*8`($i)
___
$code.=<<___ if ($SIZE_T==8);
ld $a0,0($ap) ; pull ap[0] value
ld $n0,0($n0) ; pull n0[0] value
ld $t3,0($bp) ; bp[0]
___
$code.=<<___ if ($SIZE_T==4);
mr $t1,$n0
lwz $a0,0($ap) ; pull ap[0,1] value
lwz $t0,4($ap)
lwz $n0,0($t1) ; pull n0[0,1] value
lwz $t1,4($t1)
lwz $t3,0($bp) ; bp[0,1]
lwz $t2,4($bp)
insrdi $a0,$t0,32,0
insrdi $n0,$t1,32,0
insrdi $t3,$t2,32,0
___
$code.=<<___;
addi $tp,$sp,`$FRAME+$TRANSFER+8+64`
li $i,-64
add $nap_d,$tp,$num
and $nap_d,$nap_d,$i ; align to 64 bytes
mulld $t7,$a0,$t3 ; ap[0]*bp[0]
; nap_d is off by 1, because it's used with stfdu/lfdu
addi $nap_d,$nap_d,-8
srwi $j,$num,`3+1` ; counter register, num/2
mulld $t7,$t7,$n0 ; tp[0]*n0
addi $j,$j,-1
addi $tp,$sp,`$FRAME+$TRANSFER-8`
li $carry,0
mtctr $j
; transfer bp[0] to FPU as 4x16-bit values
extrdi $t0,$t3,16,48
extrdi $t1,$t3,16,32
extrdi $t2,$t3,16,16
extrdi $t3,$t3,16,0
std $t0,`$FRAME+0`($sp)
std $t1,`$FRAME+8`($sp)
std $t2,`$FRAME+16`($sp)
std $t3,`$FRAME+24`($sp)
; transfer (ap[0]*bp[0])*n0 to FPU as 4x16-bit values
extrdi $t4,$t7,16,48
extrdi $t5,$t7,16,32
extrdi $t6,$t7,16,16
extrdi $t7,$t7,16,0
std $t4,`$FRAME+32`($sp)
std $t5,`$FRAME+40`($sp)
std $t6,`$FRAME+48`($sp)
std $t7,`$FRAME+56`($sp)
___
$code.=<<___ if ($SIZE_T==8);
lwz $t0,4($ap) ; load a[j] as 32-bit word pair
lwz $t1,0($ap)
lwz $t2,12($ap) ; load a[j+1] as 32-bit word pair
lwz $t3,8($ap)
lwz $t4,4($np) ; load n[j] as 32-bit word pair
lwz $t5,0($np)
lwz $t6,12($np) ; load n[j+1] as 32-bit word pair
lwz $t7,8($np)
___
$code.=<<___ if ($SIZE_T==4);
lwz $t0,0($ap) ; load a[j..j+3] as 32-bit word pairs
lwz $t1,4($ap)
lwz $t2,8($ap)
lwz $t3,12($ap)
lwz $t4,0($np) ; load n[j..j+3] as 32-bit word pairs
lwz $t5,4($np)
lwz $t6,8($np)
lwz $t7,12($np)
___
$code.=<<___;
lfd $ba,`$FRAME+0`($sp)
lfd $bb,`$FRAME+8`($sp)
lfd $bc,`$FRAME+16`($sp)
lfd $bd,`$FRAME+24`($sp)
lfd $na,`$FRAME+32`($sp)
lfd $nb,`$FRAME+40`($sp)
lfd $nc,`$FRAME+48`($sp)
lfd $nd,`$FRAME+56`($sp)
std $t0,`$FRAME+64`($sp)
std $t1,`$FRAME+72`($sp)
std $t2,`$FRAME+80`($sp)
std $t3,`$FRAME+88`($sp)
std $t4,`$FRAME+96`($sp)
std $t5,`$FRAME+104`($sp)
std $t6,`$FRAME+112`($sp)
std $t7,`$FRAME+120`($sp)
fcfid $ba,$ba
fcfid $bb,$bb
fcfid $bc,$bc
fcfid $bd,$bd
fcfid $na,$na
fcfid $nb,$nb
fcfid $nc,$nc
fcfid $nd,$nd
lfd $A0,`$FRAME+64`($sp)
lfd $A1,`$FRAME+72`($sp)
lfd $A2,`$FRAME+80`($sp)
lfd $A3,`$FRAME+88`($sp)
lfd $N0,`$FRAME+96`($sp)
lfd $N1,`$FRAME+104`($sp)
lfd $N2,`$FRAME+112`($sp)
lfd $N3,`$FRAME+120`($sp)
fcfid $A0,$A0
fcfid $A1,$A1
fcfid $A2,$A2
fcfid $A3,$A3
fcfid $N0,$N0
fcfid $N1,$N1
fcfid $N2,$N2
fcfid $N3,$N3
addi $ap,$ap,16
addi $np,$np,16
fmul $T1a,$A1,$ba
fmul $T1b,$A1,$bb
stfd $A0,8($nap_d) ; save a[j] in double format
stfd $A1,16($nap_d)
fmul $T2a,$A2,$ba
fmul $T2b,$A2,$bb
stfd $A2,24($nap_d) ; save a[j+1] in double format
stfd $A3,32($nap_d)
fmul $T3a,$A3,$ba
fmul $T3b,$A3,$bb
stfd $N0,40($nap_d) ; save n[j] in double format
stfd $N1,48($nap_d)
fmul $T0a,$A0,$ba
fmul $T0b,$A0,$bb
stfd $N2,56($nap_d) ; save n[j+1] in double format
stfdu $N3,64($nap_d)
fmadd $T1a,$A0,$bc,$T1a
fmadd $T1b,$A0,$bd,$T1b
fmadd $T2a,$A1,$bc,$T2a
fmadd $T2b,$A1,$bd,$T2b
fmadd $T3a,$A2,$bc,$T3a
fmadd $T3b,$A2,$bd,$T3b
fmul $dota,$A3,$bc
fmul $dotb,$A3,$bd
fmadd $T1a,$N1,$na,$T1a
fmadd $T1b,$N1,$nb,$T1b
fmadd $T2a,$N2,$na,$T2a
fmadd $T2b,$N2,$nb,$T2b
fmadd $T3a,$N3,$na,$T3a
fmadd $T3b,$N3,$nb,$T3b
fmadd $T0a,$N0,$na,$T0a
fmadd $T0b,$N0,$nb,$T0b
fmadd $T1a,$N0,$nc,$T1a
fmadd $T1b,$N0,$nd,$T1b
fmadd $T2a,$N1,$nc,$T2a
fmadd $T2b,$N1,$nd,$T2b
fmadd $T3a,$N2,$nc,$T3a
fmadd $T3b,$N2,$nd,$T3b
fmadd $dota,$N3,$nc,$dota
fmadd $dotb,$N3,$nd,$dotb
fctid $T0a,$T0a
fctid $T0b,$T0b
fctid $T1a,$T1a
fctid $T1b,$T1b
fctid $T2a,$T2a
fctid $T2b,$T2b
fctid $T3a,$T3a
fctid $T3b,$T3b
stfd $T0a,`$FRAME+0`($sp)
stfd $T0b,`$FRAME+8`($sp)
stfd $T1a,`$FRAME+16`($sp)
stfd $T1b,`$FRAME+24`($sp)
stfd $T2a,`$FRAME+32`($sp)
stfd $T2b,`$FRAME+40`($sp)
stfd $T3a,`$FRAME+48`($sp)
stfd $T3b,`$FRAME+56`($sp)
.align 5
L1st:
___
$code.=<<___ if ($SIZE_T==8);
lwz $t0,4($ap) ; load a[j] as 32-bit word pair
lwz $t1,0($ap)
lwz $t2,12($ap) ; load a[j+1] as 32-bit word pair
lwz $t3,8($ap)
lwz $t4,4($np) ; load n[j] as 32-bit word pair
lwz $t5,0($np)
lwz $t6,12($np) ; load n[j+1] as 32-bit word pair
lwz $t7,8($np)
___
$code.=<<___ if ($SIZE_T==4);
lwz $t0,0($ap) ; load a[j..j+3] as 32-bit word pairs
lwz $t1,4($ap)
lwz $t2,8($ap)
lwz $t3,12($ap)
lwz $t4,0($np) ; load n[j..j+3] as 32-bit word pairs
lwz $t5,4($np)
lwz $t6,8($np)
lwz $t7,12($np)
___
$code.=<<___;
std $t0,`$FRAME+64`($sp)
std $t1,`$FRAME+72`($sp)
std $t2,`$FRAME+80`($sp)
std $t3,`$FRAME+88`($sp)
std $t4,`$FRAME+96`($sp)
std $t5,`$FRAME+104`($sp)
std $t6,`$FRAME+112`($sp)
std $t7,`$FRAME+120`($sp)
ld $t0,`$FRAME+0`($sp)
ld $t1,`$FRAME+8`($sp)
ld $t2,`$FRAME+16`($sp)
ld $t3,`$FRAME+24`($sp)
ld $t4,`$FRAME+32`($sp)
ld $t5,`$FRAME+40`($sp)
ld $t6,`$FRAME+48`($sp)
ld $t7,`$FRAME+56`($sp)
lfd $A0,`$FRAME+64`($sp)
lfd $A1,`$FRAME+72`($sp)
lfd $A2,`$FRAME+80`($sp)
lfd $A3,`$FRAME+88`($sp)
lfd $N0,`$FRAME+96`($sp)
lfd $N1,`$FRAME+104`($sp)
lfd $N2,`$FRAME+112`($sp)
lfd $N3,`$FRAME+120`($sp)
fcfid $A0,$A0
fcfid $A1,$A1
fcfid $A2,$A2
fcfid $A3,$A3
fcfid $N0,$N0
fcfid $N1,$N1
fcfid $N2,$N2
fcfid $N3,$N3
addi $ap,$ap,16
addi $np,$np,16
fmul $T1a,$A1,$ba
fmul $T1b,$A1,$bb
fmul $T2a,$A2,$ba
fmul $T2b,$A2,$bb
stfd $A0,8($nap_d) ; save a[j] in double format
stfd $A1,16($nap_d)
fmul $T3a,$A3,$ba
fmul $T3b,$A3,$bb
fmadd $T0a,$A0,$ba,$dota
fmadd $T0b,$A0,$bb,$dotb
stfd $A2,24($nap_d) ; save a[j+1] in double format
stfd $A3,32($nap_d)
fmadd $T1a,$A0,$bc,$T1a
fmadd $T1b,$A0,$bd,$T1b
fmadd $T2a,$A1,$bc,$T2a
fmadd $T2b,$A1,$bd,$T2b
stfd $N0,40($nap_d) ; save n[j] in double format
stfd $N1,48($nap_d)
fmadd $T3a,$A2,$bc,$T3a
fmadd $T3b,$A2,$bd,$T3b
add $t0,$t0,$carry ; can not overflow
fmul $dota,$A3,$bc
fmul $dotb,$A3,$bd
stfd $N2,56($nap_d) ; save n[j+1] in double format
stfdu $N3,64($nap_d)
srdi $carry,$t0,16
add $t1,$t1,$carry
srdi $carry,$t1,16
fmadd $T1a,$N1,$na,$T1a
fmadd $T1b,$N1,$nb,$T1b
insrdi $t0,$t1,16,32
fmadd $T2a,$N2,$na,$T2a
fmadd $T2b,$N2,$nb,$T2b
add $t2,$t2,$carry
fmadd $T3a,$N3,$na,$T3a
fmadd $T3b,$N3,$nb,$T3b
srdi $carry,$t2,16
fmadd $T0a,$N0,$na,$T0a
fmadd $T0b,$N0,$nb,$T0b
insrdi $t0,$t2,16,16
add $t3,$t3,$carry
srdi $carry,$t3,16
fmadd $T1a,$N0,$nc,$T1a
fmadd $T1b,$N0,$nd,$T1b
insrdi $t0,$t3,16,0 ; 0..63 bits
fmadd $T2a,$N1,$nc,$T2a
fmadd $T2b,$N1,$nd,$T2b
add $t4,$t4,$carry
fmadd $T3a,$N2,$nc,$T3a
fmadd $T3b,$N2,$nd,$T3b
srdi $carry,$t4,16
fmadd $dota,$N3,$nc,$dota
fmadd $dotb,$N3,$nd,$dotb
add $t5,$t5,$carry
srdi $carry,$t5,16
insrdi $t4,$t5,16,32
fctid $T0a,$T0a
fctid $T0b,$T0b
add $t6,$t6,$carry
fctid $T1a,$T1a
fctid $T1b,$T1b
srdi $carry,$t6,16
fctid $T2a,$T2a
fctid $T2b,$T2b
insrdi $t4,$t6,16,16
fctid $T3a,$T3a
fctid $T3b,$T3b
add $t7,$t7,$carry
insrdi $t4,$t7,16,0 ; 64..127 bits
srdi $carry,$t7,16 ; upper 33 bits
stfd $T0a,`$FRAME+0`($sp)
stfd $T0b,`$FRAME+8`($sp)
stfd $T1a,`$FRAME+16`($sp)
stfd $T1b,`$FRAME+24`($sp)
stfd $T2a,`$FRAME+32`($sp)
stfd $T2b,`$FRAME+40`($sp)
stfd $T3a,`$FRAME+48`($sp)
stfd $T3b,`$FRAME+56`($sp)
std $t0,8($tp) ; tp[j-1]
stdu $t4,16($tp) ; tp[j]
bdnz- L1st
fctid $dota,$dota
fctid $dotb,$dotb
ld $t0,`$FRAME+0`($sp)
ld $t1,`$FRAME+8`($sp)
ld $t2,`$FRAME+16`($sp)
ld $t3,`$FRAME+24`($sp)
ld $t4,`$FRAME+32`($sp)
ld $t5,`$FRAME+40`($sp)
ld $t6,`$FRAME+48`($sp)
ld $t7,`$FRAME+56`($sp)
stfd $dota,`$FRAME+64`($sp)
stfd $dotb,`$FRAME+72`($sp)
add $t0,$t0,$carry ; can not overflow
srdi $carry,$t0,16
add $t1,$t1,$carry
srdi $carry,$t1,16
insrdi $t0,$t1,16,32
add $t2,$t2,$carry
srdi $carry,$t2,16
insrdi $t0,$t2,16,16
add $t3,$t3,$carry
srdi $carry,$t3,16
insrdi $t0,$t3,16,0 ; 0..63 bits
add $t4,$t4,$carry
srdi $carry,$t4,16
add $t5,$t5,$carry
srdi $carry,$t5,16
insrdi $t4,$t5,16,32
add $t6,$t6,$carry
srdi $carry,$t6,16
insrdi $t4,$t6,16,16
add $t7,$t7,$carry
insrdi $t4,$t7,16,0 ; 64..127 bits
srdi $carry,$t7,16 ; upper 33 bits
ld $t6,`$FRAME+64`($sp)
ld $t7,`$FRAME+72`($sp)
std $t0,8($tp) ; tp[j-1]
stdu $t4,16($tp) ; tp[j]
add $t6,$t6,$carry ; can not overflow
srdi $carry,$t6,16
add $t7,$t7,$carry
insrdi $t6,$t7,48,0
srdi $ovf,$t7,48
std $t6,8($tp) ; tp[num-1]
slwi $t7,$num,2
subf $nap_d,$t7,$nap_d ; rewind pointer
li $i,8 ; i=1
.align 5
Louter:
___
$code.=<<___ if ($SIZE_T==8);
ldx $t3,$bp,$i ; bp[i]
___
$code.=<<___ if ($SIZE_T==4);
add $t0,$bp,$i
lwz $t3,0($t0) ; bp[i,i+1]
lwz $t0,4($t0)
insrdi $t3,$t0,32,0
___
$code.=<<___;
ld $t6,`$FRAME+$TRANSFER+8`($sp) ; tp[0]
mulld $t7,$a0,$t3 ; ap[0]*bp[i]
addi $tp,$sp,`$FRAME+$TRANSFER`
add $t7,$t7,$t6 ; ap[0]*bp[i]+tp[0]
li $carry,0
mulld $t7,$t7,$n0 ; tp[0]*n0
mtctr $j
; transfer bp[i] to FPU as 4x16-bit values
extrdi $t0,$t3,16,48
extrdi $t1,$t3,16,32
extrdi $t2,$t3,16,16
extrdi $t3,$t3,16,0
std $t0,`$FRAME+0`($sp)
std $t1,`$FRAME+8`($sp)
std $t2,`$FRAME+16`($sp)
std $t3,`$FRAME+24`($sp)
; transfer (ap[0]*bp[i]+tp[0])*n0 to FPU as 4x16-bit values
extrdi $t4,$t7,16,48
extrdi $t5,$t7,16,32
extrdi $t6,$t7,16,16
extrdi $t7,$t7,16,0
std $t4,`$FRAME+32`($sp)
std $t5,`$FRAME+40`($sp)
std $t6,`$FRAME+48`($sp)
std $t7,`$FRAME+56`($sp)
lfd $A0,8($nap_d) ; load a[j] in double format
lfd $A1,16($nap_d)
lfd $A2,24($nap_d) ; load a[j+1] in double format
lfd $A3,32($nap_d)
lfd $N0,40($nap_d) ; load n[j] in double format
lfd $N1,48($nap_d)
lfd $N2,56($nap_d) ; load n[j+1] in double format
lfdu $N3,64($nap_d)
lfd $ba,`$FRAME+0`($sp)
lfd $bb,`$FRAME+8`($sp)
lfd $bc,`$FRAME+16`($sp)
lfd $bd,`$FRAME+24`($sp)
lfd $na,`$FRAME+32`($sp)
lfd $nb,`$FRAME+40`($sp)
lfd $nc,`$FRAME+48`($sp)
lfd $nd,`$FRAME+56`($sp)
fcfid $ba,$ba
fcfid $bb,$bb
fcfid $bc,$bc
fcfid $bd,$bd
fcfid $na,$na
fcfid $nb,$nb
fcfid $nc,$nc
fcfid $nd,$nd
fmul $T1a,$A1,$ba
fmul $T1b,$A1,$bb
fmul $T2a,$A2,$ba
fmul $T2b,$A2,$bb
fmul $T3a,$A3,$ba
fmul $T3b,$A3,$bb
fmul $T0a,$A0,$ba
fmul $T0b,$A0,$bb
fmadd $T1a,$A0,$bc,$T1a
fmadd $T1b,$A0,$bd,$T1b
fmadd $T2a,$A1,$bc,$T2a
fmadd $T2b,$A1,$bd,$T2b
fmadd $T3a,$A2,$bc,$T3a
fmadd $T3b,$A2,$bd,$T3b
fmul $dota,$A3,$bc
fmul $dotb,$A3,$bd
fmadd $T1a,$N1,$na,$T1a
fmadd $T1b,$N1,$nb,$T1b
lfd $A0,8($nap_d) ; load a[j] in double format
lfd $A1,16($nap_d)
fmadd $T2a,$N2,$na,$T2a
fmadd $T2b,$N2,$nb,$T2b
lfd $A2,24($nap_d) ; load a[j+1] in double format
lfd $A3,32($nap_d)
fmadd $T3a,$N3,$na,$T3a
fmadd $T3b,$N3,$nb,$T3b
fmadd $T0a,$N0,$na,$T0a
fmadd $T0b,$N0,$nb,$T0b
fmadd $T1a,$N0,$nc,$T1a
fmadd $T1b,$N0,$nd,$T1b
fmadd $T2a,$N1,$nc,$T2a
fmadd $T2b,$N1,$nd,$T2b
fmadd $T3a,$N2,$nc,$T3a
fmadd $T3b,$N2,$nd,$T3b
fmadd $dota,$N3,$nc,$dota
fmadd $dotb,$N3,$nd,$dotb
fctid $T0a,$T0a
fctid $T0b,$T0b
fctid $T1a,$T1a
fctid $T1b,$T1b
fctid $T2a,$T2a
fctid $T2b,$T2b
fctid $T3a,$T3a
fctid $T3b,$T3b
stfd $T0a,`$FRAME+0`($sp)
stfd $T0b,`$FRAME+8`($sp)
stfd $T1a,`$FRAME+16`($sp)
stfd $T1b,`$FRAME+24`($sp)
stfd $T2a,`$FRAME+32`($sp)
stfd $T2b,`$FRAME+40`($sp)
stfd $T3a,`$FRAME+48`($sp)
stfd $T3b,`$FRAME+56`($sp)
.align 5
Linner:
fmul $T1a,$A1,$ba
fmul $T1b,$A1,$bb
fmul $T2a,$A2,$ba
fmul $T2b,$A2,$bb
lfd $N0,40($nap_d) ; load n[j] in double format
lfd $N1,48($nap_d)
fmul $T3a,$A3,$ba
fmul $T3b,$A3,$bb
fmadd $T0a,$A0,$ba,$dota
fmadd $T0b,$A0,$bb,$dotb
lfd $N2,56($nap_d) ; load n[j+1] in double format
lfdu $N3,64($nap_d)
fmadd $T1a,$A0,$bc,$T1a
fmadd $T1b,$A0,$bd,$T1b
fmadd $T2a,$A1,$bc,$T2a
fmadd $T2b,$A1,$bd,$T2b
lfd $A0,8($nap_d) ; load a[j] in double format
lfd $A1,16($nap_d)
fmadd $T3a,$A2,$bc,$T3a
fmadd $T3b,$A2,$bd,$T3b
fmul $dota,$A3,$bc
fmul $dotb,$A3,$bd
lfd $A2,24($nap_d) ; load a[j+1] in double format
lfd $A3,32($nap_d)
fmadd $T1a,$N1,$na,$T1a
fmadd $T1b,$N1,$nb,$T1b
ld $t0,`$FRAME+0`($sp)
ld $t1,`$FRAME+8`($sp)
fmadd $T2a,$N2,$na,$T2a
fmadd $T2b,$N2,$nb,$T2b
ld $t2,`$FRAME+16`($sp)
ld $t3,`$FRAME+24`($sp)
fmadd $T3a,$N3,$na,$T3a
fmadd $T3b,$N3,$nb,$T3b
add $t0,$t0,$carry ; can not overflow
ld $t4,`$FRAME+32`($sp)
ld $t5,`$FRAME+40`($sp)
fmadd $T0a,$N0,$na,$T0a
fmadd $T0b,$N0,$nb,$T0b
srdi $carry,$t0,16
add $t1,$t1,$carry
srdi $carry,$t1,16
ld $t6,`$FRAME+48`($sp)
ld $t7,`$FRAME+56`($sp)
fmadd $T1a,$N0,$nc,$T1a
fmadd $T1b,$N0,$nd,$T1b
insrdi $t0,$t1,16,32
ld $t1,8($tp) ; tp[j]
fmadd $T2a,$N1,$nc,$T2a
fmadd $T2b,$N1,$nd,$T2b
add $t2,$t2,$carry
fmadd $T3a,$N2,$nc,$T3a
fmadd $T3b,$N2,$nd,$T3b
srdi $carry,$t2,16
insrdi $t0,$t2,16,16
fmadd $dota,$N3,$nc,$dota
fmadd $dotb,$N3,$nd,$dotb
add $t3,$t3,$carry
ldu $t2,16($tp) ; tp[j+1]
srdi $carry,$t3,16
insrdi $t0,$t3,16,0 ; 0..63 bits
add $t4,$t4,$carry
fctid $T0a,$T0a
fctid $T0b,$T0b
srdi $carry,$t4,16
fctid $T1a,$T1a
fctid $T1b,$T1b
add $t5,$t5,$carry
fctid $T2a,$T2a
fctid $T2b,$T2b
srdi $carry,$t5,16
insrdi $t4,$t5,16,32
fctid $T3a,$T3a
fctid $T3b,$T3b
add $t6,$t6,$carry
srdi $carry,$t6,16
insrdi $t4,$t6,16,16
stfd $T0a,`$FRAME+0`($sp)
stfd $T0b,`$FRAME+8`($sp)
add $t7,$t7,$carry
addc $t3,$t0,$t1
___
$code.=<<___ if ($SIZE_T==4); # adjust XER[CA]
extrdi $t0,$t0,32,0
extrdi $t1,$t1,32,0
adde $t0,$t0,$t1
___
$code.=<<___;
stfd $T1a,`$FRAME+16`($sp)
stfd $T1b,`$FRAME+24`($sp)
insrdi $t4,$t7,16,0 ; 64..127 bits
srdi $carry,$t7,16 ; upper 33 bits
stfd $T2a,`$FRAME+32`($sp)
stfd $T2b,`$FRAME+40`($sp)
adde $t5,$t4,$t2
___
$code.=<<___ if ($SIZE_T==4); # adjust XER[CA]
extrdi $t4,$t4,32,0
extrdi $t2,$t2,32,0
adde $t4,$t4,$t2
___
$code.=<<___;
stfd $T3a,`$FRAME+48`($sp)
stfd $T3b,`$FRAME+56`($sp)
addze $carry,$carry
std $t3,-16($tp) ; tp[j-1]
std $t5,-8($tp) ; tp[j]
bdnz- Linner
fctid $dota,$dota
fctid $dotb,$dotb
ld $t0,`$FRAME+0`($sp)
ld $t1,`$FRAME+8`($sp)
ld $t2,`$FRAME+16`($sp)
ld $t3,`$FRAME+24`($sp)
ld $t4,`$FRAME+32`($sp)
ld $t5,`$FRAME+40`($sp)
ld $t6,`$FRAME+48`($sp)
ld $t7,`$FRAME+56`($sp)
stfd $dota,`$FRAME+64`($sp)
stfd $dotb,`$FRAME+72`($sp)
add $t0,$t0,$carry ; can not overflow
srdi $carry,$t0,16
add $t1,$t1,$carry
srdi $carry,$t1,16
insrdi $t0,$t1,16,32
add $t2,$t2,$carry
ld $t1,8($tp) ; tp[j]
srdi $carry,$t2,16
insrdi $t0,$t2,16,16
add $t3,$t3,$carry
ldu $t2,16($tp) ; tp[j+1]
srdi $carry,$t3,16
insrdi $t0,$t3,16,0 ; 0..63 bits
add $t4,$t4,$carry
srdi $carry,$t4,16
add $t5,$t5,$carry
srdi $carry,$t5,16
insrdi $t4,$t5,16,32
add $t6,$t6,$carry
srdi $carry,$t6,16
insrdi $t4,$t6,16,16
add $t7,$t7,$carry
insrdi $t4,$t7,16,0 ; 64..127 bits
srdi $carry,$t7,16 ; upper 33 bits
ld $t6,`$FRAME+64`($sp)
ld $t7,`$FRAME+72`($sp)
addc $t3,$t0,$t1
___
$code.=<<___ if ($SIZE_T==4); # adjust XER[CA]
extrdi $t0,$t0,32,0
extrdi $t1,$t1,32,0
adde $t0,$t0,$t1
___
$code.=<<___;
adde $t5,$t4,$t2
___
$code.=<<___ if ($SIZE_T==4); # adjust XER[CA]
extrdi $t4,$t4,32,0
extrdi $t2,$t2,32,0
adde $t4,$t4,$t2
___
$code.=<<___;
addze $carry,$carry
std $t3,-16($tp) ; tp[j-1]
std $t5,-8($tp) ; tp[j]
add $carry,$carry,$ovf ; comsume upmost overflow
add $t6,$t6,$carry ; can not overflow
srdi $carry,$t6,16
add $t7,$t7,$carry
insrdi $t6,$t7,48,0
srdi $ovf,$t7,48
std $t6,0($tp) ; tp[num-1]
slwi $t7,$num,2
addi $i,$i,8
subf $nap_d,$t7,$nap_d ; rewind pointer
cmpw $i,$num
blt- Louter
___
$code.=<<___ if ($SIZE_T==8);
subf $np,$num,$np ; rewind np
addi $j,$j,1 ; restore counter
subfc $i,$i,$i ; j=0 and "clear" XER[CA]
addi $tp,$sp,`$FRAME+$TRANSFER+8`
addi $t4,$sp,`$FRAME+$TRANSFER+16`
addi $t5,$np,8
addi $t6,$rp,8
mtctr $j
.align 4
Lsub: ldx $t0,$tp,$i
ldx $t1,$np,$i
ldx $t2,$t4,$i
ldx $t3,$t5,$i
subfe $t0,$t1,$t0 ; tp[j]-np[j]
subfe $t2,$t3,$t2 ; tp[j+1]-np[j+1]
stdx $t0,$rp,$i
stdx $t2,$t6,$i
addi $i,$i,16
bdnz- Lsub
li $i,0
subfe $ovf,$i,$ovf ; handle upmost overflow bit
and $ap,$tp,$ovf
andc $np,$rp,$ovf
or $ap,$ap,$np ; ap=borrow?tp:rp
addi $t7,$ap,8
mtctr $j
.align 4
Lcopy: ; copy or in-place refresh
ldx $t0,$ap,$i
ldx $t1,$t7,$i
std $i,8($nap_d) ; zap nap_d
std $i,16($nap_d)
std $i,24($nap_d)
std $i,32($nap_d)
std $i,40($nap_d)
std $i,48($nap_d)
std $i,56($nap_d)
stdu $i,64($nap_d)
stdx $t0,$rp,$i
stdx $t1,$t6,$i
stdx $i,$tp,$i ; zap tp at once
stdx $i,$t4,$i
addi $i,$i,16
bdnz- Lcopy
___
$code.=<<___ if ($SIZE_T==4);
subf $np,$num,$np ; rewind np
addi $j,$j,1 ; restore counter
subfc $i,$i,$i ; j=0 and "clear" XER[CA]
addi $tp,$sp,`$FRAME+$TRANSFER`
addi $np,$np,-4
addi $rp,$rp,-4
addi $ap,$sp,`$FRAME+$TRANSFER+4`
mtctr $j
.align 4
Lsub: ld $t0,8($tp) ; load tp[j..j+3] in 64-bit word order
ldu $t2,16($tp)
lwz $t4,4($np) ; load np[j..j+3] in 32-bit word order
lwz $t5,8($np)
lwz $t6,12($np)
lwzu $t7,16($np)
extrdi $t1,$t0,32,0
extrdi $t3,$t2,32,0
subfe $t4,$t4,$t0 ; tp[j]-np[j]
stw $t0,4($ap) ; save tp[j..j+3] in 32-bit word order
subfe $t5,$t5,$t1 ; tp[j+1]-np[j+1]
stw $t1,8($ap)
subfe $t6,$t6,$t2 ; tp[j+2]-np[j+2]
stw $t2,12($ap)
subfe $t7,$t7,$t3 ; tp[j+3]-np[j+3]
stwu $t3,16($ap)
stw $t4,4($rp)
stw $t5,8($rp)
stw $t6,12($rp)
stwu $t7,16($rp)
bdnz- Lsub
li $i,0
subfe $ovf,$i,$ovf ; handle upmost overflow bit
addi $tp,$sp,`$FRAME+$TRANSFER+4`
subf $rp,$num,$rp ; rewind rp
and $ap,$tp,$ovf
andc $np,$rp,$ovf
or $ap,$ap,$np ; ap=borrow?tp:rp
addi $tp,$sp,`$FRAME+$TRANSFER`
mtctr $j
.align 4
Lcopy: ; copy or in-place refresh
lwz $t0,4($ap)
lwz $t1,8($ap)
lwz $t2,12($ap)
lwzu $t3,16($ap)
std $i,8($nap_d) ; zap nap_d
std $i,16($nap_d)
std $i,24($nap_d)
std $i,32($nap_d)
std $i,40($nap_d)
std $i,48($nap_d)
std $i,56($nap_d)
stdu $i,64($nap_d)
stw $t0,4($rp)
stw $t1,8($rp)
stw $t2,12($rp)
stwu $t3,16($rp)
std $i,8($tp) ; zap tp at once
stdu $i,16($tp)
bdnz- Lcopy
___
$code.=<<___;
$POP $i,0($sp)
li r3,1 ; signal "handled"
$POP r22,`-12*8-10*$SIZE_T`($i)
$POP r23,`-12*8-9*$SIZE_T`($i)
$POP r24,`-12*8-8*$SIZE_T`($i)
$POP r25,`-12*8-7*$SIZE_T`($i)
$POP r26,`-12*8-6*$SIZE_T`($i)
$POP r27,`-12*8-5*$SIZE_T`($i)
$POP r28,`-12*8-4*$SIZE_T`($i)
$POP r29,`-12*8-3*$SIZE_T`($i)
$POP r30,`-12*8-2*$SIZE_T`($i)
$POP r31,`-12*8-1*$SIZE_T`($i)
lfd f20,`-12*8`($i)
lfd f21,`-11*8`($i)
lfd f22,`-10*8`($i)
lfd f23,`-9*8`($i)
lfd f24,`-8*8`($i)
lfd f25,`-7*8`($i)
lfd f26,`-6*8`($i)
lfd f27,`-5*8`($i)
lfd f28,`-4*8`($i)
lfd f29,`-3*8`($i)
lfd f30,`-2*8`($i)
lfd f31,`-1*8`($i)
mr $sp,$i
blr
.long 0
.byte 0,12,4,0,0x8c,10,6,0
.long 0
.asciz "Montgomery Multiplication for PPC64, CRYPTOGAMS by <appro\@openssl.org>"
___
$code =~ s/\`([^\`]*)\`/eval $1/gem;
print $code;
close STDOUT;