CloverBootloader/Library/OpensslLib/openssl/crypto/poly1305/asm/poly1305-sparcv9.pl

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#! /usr/bin/env perl
# Copyright 2016-2021 The OpenSSL Project Authors. All Rights Reserved.
#
# Licensed under the Apache License 2.0 (the "License"). You may not use
# this file except in compliance with the License. You can obtain a copy
# in the file LICENSE in the source distribution or at
# https://www.openssl.org/source/license.html
#
# ====================================================================
# 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 SPARCv9, vanilla, as well
# as VIS3 and FMA extensions.
#
# May, August 2015
#
# Numbers are cycles per processed byte with poly1305_blocks alone.
#
# IALU(*) FMA
#
# UltraSPARC III 12.3(**)
# SPARC T3 7.92
# SPARC T4 1.70(***) 6.55
# SPARC64 X 5.60 3.64
#
# (*) Comparison to compiler-generated code is really problematic,
# because latter's performance varies too much depending on too
# many variables. For example, one can measure from 5x to 15x
# improvement on T4 for gcc-4.6. Well, in T4 case it's a bit
# unfair comparison, because compiler doesn't use VIS3, but
# given same initial conditions coefficient varies from 3x to 9x.
# (**) Pre-III performance should be even worse; floating-point
# performance for UltraSPARC I-IV on the other hand is reported
# to be 4.25 for hand-coded assembly, but they are just too old
# to care about.
# (***) Multi-process benchmark saturates at ~12.5x single-process
# result on 8-core processor, or ~21GBps per 2.85GHz socket.
# $output is the last argument if it looks like a file (it has an extension)
my $output = $#ARGV >= 0 && $ARGV[$#ARGV] =~ m|\.\w+$| ? pop : undef;
open STDOUT,">$output" if $output;
my ($ctx,$inp,$len,$padbit,$shl,$shr) = map("%i$_",(0..5));
my ($r0,$r1,$r2,$r3,$s1,$s2,$s3,$h4) = map("%l$_",(0..7));
my ($h0,$h1,$h2,$h3, $t0,$t1,$t2) = map("%o$_",(0..5,7));
my ($d0,$d1,$d2,$d3) = map("%g$_",(1..4));
$code.=<<___;
#ifndef __ASSEMBLER__
# define __ASSEMBLER__ 1
#endif
#include "crypto/sparc_arch.h"
#ifdef __arch64__
.register %g2,#scratch
.register %g3,#scratch
# define STPTR stx
# define SIZE_T 8
#else
# define STPTR st
# define SIZE_T 4
#endif
#define LOCALS (STACK_BIAS+STACK_FRAME)
.section ".text",#alloc,#execinstr
#ifdef __PIC__
SPARC_PIC_THUNK(%g1)
#endif
.globl poly1305_init
.align 32
poly1305_init:
save %sp,-STACK_FRAME-16,%sp
nop
SPARC_LOAD_ADDRESS(OPENSSL_sparcv9cap_P,%g1)
ld [%g1],%g1
and %g1,SPARCV9_FMADD|SPARCV9_VIS3,%g1
cmp %g1,SPARCV9_FMADD
be .Lpoly1305_init_fma
nop
stx %g0,[$ctx+0]
stx %g0,[$ctx+8] ! zero hash value
brz,pn $inp,.Lno_key
stx %g0,[$ctx+16]
and $inp,7,$shr ! alignment factor
andn $inp,7,$inp
sll $shr,3,$shr ! *8
neg $shr,$shl
sethi %hi(0x0ffffffc),$t0
set 8,$h1
or $t0,%lo(0x0ffffffc),$t0
set 16,$h2
sllx $t0,32,$t1
or $t0,$t1,$t1 ! 0x0ffffffc0ffffffc
or $t1,3,$t0 ! 0x0ffffffc0fffffff
ldxa [$inp+%g0]0x88,$h0 ! load little-endian key
brz,pt $shr,.Lkey_aligned
ldxa [$inp+$h1]0x88,$h1
ldxa [$inp+$h2]0x88,$h2
srlx $h0,$shr,$h0
sllx $h1,$shl,$t2
srlx $h1,$shr,$h1
or $t2,$h0,$h0
sllx $h2,$shl,$h2
or $h2,$h1,$h1
.Lkey_aligned:
and $t0,$h0,$h0
and $t1,$h1,$h1
stx $h0,[$ctx+32+0] ! store key
stx $h1,[$ctx+32+8]
andcc %g1,SPARCV9_VIS3,%g0
be .Lno_key
nop
1: call .+8
add %o7,poly1305_blocks_vis3-1b,%o7
add %o7,poly1305_emit-poly1305_blocks_vis3,%o5
STPTR %o7,[%i2]
STPTR %o5,[%i2+SIZE_T]
ret
restore %g0,1,%o0 ! return 1
.Lno_key:
ret
restore %g0,%g0,%o0 ! return 0
.type poly1305_init,#function
.size poly1305_init,.-poly1305_init
.globl poly1305_blocks
.align 32
poly1305_blocks:
save %sp,-STACK_FRAME,%sp
srln $len,4,$len
brz,pn $len,.Lno_data
nop
ld [$ctx+32+0],$r1 ! load key
ld [$ctx+32+4],$r0
ld [$ctx+32+8],$r3
ld [$ctx+32+12],$r2
ld [$ctx+0],$h1 ! load hash value
ld [$ctx+4],$h0
ld [$ctx+8],$h3
ld [$ctx+12],$h2
ld [$ctx+16],$h4
and $inp,7,$shr ! alignment factor
andn $inp,7,$inp
set 8,$d1
sll $shr,3,$shr ! *8
set 16,$d2
neg $shr,$shl
srl $r1,2,$s1
srl $r2,2,$s2
add $r1,$s1,$s1
srl $r3,2,$s3
add $r2,$s2,$s2
add $r3,$s3,$s3
.Loop:
ldxa [$inp+%g0]0x88,$d0 ! load little-endian input
brz,pt $shr,.Linp_aligned
ldxa [$inp+$d1]0x88,$d1
ldxa [$inp+$d2]0x88,$d2
srlx $d0,$shr,$d0
sllx $d1,$shl,$t1
srlx $d1,$shr,$d1
or $t1,$d0,$d0
sllx $d2,$shl,$d2
or $d2,$d1,$d1
.Linp_aligned:
srlx $d0,32,$t0
addcc $d0,$h0,$h0 ! accumulate input
srlx $d1,32,$t1
addccc $t0,$h1,$h1
addccc $d1,$h2,$h2
addccc $t1,$h3,$h3
addc $padbit,$h4,$h4
umul $r0,$h0,$d0
umul $r1,$h0,$d1
umul $r2,$h0,$d2
umul $r3,$h0,$d3
sub $len,1,$len
add $inp,16,$inp
umul $s3,$h1,$t0
umul $r0,$h1,$t1
umul $r1,$h1,$t2
add $t0,$d0,$d0
add $t1,$d1,$d1
umul $r2,$h1,$t0
add $t2,$d2,$d2
add $t0,$d3,$d3
umul $s2,$h2,$t1
umul $s3,$h2,$t2
umul $r0,$h2,$t0
add $t1,$d0,$d0
add $t2,$d1,$d1
umul $r1,$h2,$t1
add $t0,$d2,$d2
add $t1,$d3,$d3
umul $s1,$h3,$t2
umul $s2,$h3,$t0
umul $s3,$h3,$t1
add $t2,$d0,$d0
add $t0,$d1,$d1
umul $r0,$h3,$t2
add $t1,$d2,$d2
add $t2,$d3,$d3
umul $s1,$h4,$t0
umul $s2,$h4,$t1
umul $s3,$h4,$t2
umul $r0,$h4,$h4
add $t0,$d1,$d1
add $t1,$d2,$d2
srlx $d0,32,$h1
add $t2,$d3,$d3
srlx $d1,32,$h2
addcc $d1,$h1,$h1
srlx $d2,32,$h3
set 8,$d1
addccc $d2,$h2,$h2
srlx $d3,32,$t0
set 16,$d2
addccc $d3,$h3,$h3
addc $t0,$h4,$h4
srl $h4,2,$t0 ! final reduction step
andn $h4,3,$t1
and $h4,3,$h4
add $t1,$t0,$t0
addcc $t0,$d0,$h0
addccc %g0,$h1,$h1
addccc %g0,$h2,$h2
addccc %g0,$h3,$h3
brnz,pt $len,.Loop
addc %g0,$h4,$h4
st $h1,[$ctx+0] ! store hash value
st $h0,[$ctx+4]
st $h3,[$ctx+8]
st $h2,[$ctx+12]
st $h4,[$ctx+16]
.Lno_data:
ret
restore
.type poly1305_blocks,#function
.size poly1305_blocks,.-poly1305_blocks
___
########################################################################
# VIS3 has umulxhi and addxc...
{
my ($H0,$H1,$H2,$R0,$R1,$S1,$T1) = map("%o$_",(0..5,7));
my ($D0,$D1,$D2,$T0) = map("%g$_",(1..4));
$code.=<<___;
.align 32
poly1305_blocks_vis3:
save %sp,-STACK_FRAME,%sp
srln $len,4,$len
brz,pn $len,.Lno_data
nop
ldx [$ctx+32+0],$R0 ! load key
ldx [$ctx+32+8],$R1
ldx [$ctx+0],$H0 ! load hash value
ldx [$ctx+8],$H1
ld [$ctx+16],$H2
and $inp,7,$shr ! alignment factor
andn $inp,7,$inp
set 8,$r1
sll $shr,3,$shr ! *8
set 16,$r2
neg $shr,$shl
srlx $R1,2,$S1
b .Loop_vis3
add $R1,$S1,$S1
.Loop_vis3:
ldxa [$inp+%g0]0x88,$D0 ! load little-endian input
brz,pt $shr,.Linp_aligned_vis3
ldxa [$inp+$r1]0x88,$D1
ldxa [$inp+$r2]0x88,$D2
srlx $D0,$shr,$D0
sllx $D1,$shl,$T1
srlx $D1,$shr,$D1
or $T1,$D0,$D0
sllx $D2,$shl,$D2
or $D2,$D1,$D1
.Linp_aligned_vis3:
addcc $D0,$H0,$H0 ! accumulate input
sub $len,1,$len
addxccc $D1,$H1,$H1
add $inp,16,$inp
mulx $R0,$H0,$D0 ! r0*h0
addxc $padbit,$H2,$H2
umulxhi $R0,$H0,$D1
mulx $S1,$H1,$T0 ! s1*h1
umulxhi $S1,$H1,$T1
addcc $T0,$D0,$D0
mulx $R1,$H0,$T0 ! r1*h0
addxc $T1,$D1,$D1
umulxhi $R1,$H0,$D2
addcc $T0,$D1,$D1
mulx $R0,$H1,$T0 ! r0*h1
addxc %g0,$D2,$D2
umulxhi $R0,$H1,$T1
addcc $T0,$D1,$D1
mulx $S1,$H2,$T0 ! s1*h2
addxc $T1,$D2,$D2
mulx $R0,$H2,$T1 ! r0*h2
addcc $T0,$D1,$D1
addxc $T1,$D2,$D2
srlx $D2,2,$T0 ! final reduction step
andn $D2,3,$T1
and $D2,3,$H2
add $T1,$T0,$T0
addcc $T0,$D0,$H0
addxccc %g0,$D1,$H1
brnz,pt $len,.Loop_vis3
addxc %g0,$H2,$H2
stx $H0,[$ctx+0] ! store hash value
stx $H1,[$ctx+8]
st $H2,[$ctx+16]
ret
restore
.type poly1305_blocks_vis3,#function
.size poly1305_blocks_vis3,.-poly1305_blocks_vis3
___
}
my ($mac,$nonce) = ($inp,$len);
$code.=<<___;
.globl poly1305_emit
.align 32
poly1305_emit:
save %sp,-STACK_FRAME,%sp
ld [$ctx+0],$h1 ! load hash value
ld [$ctx+4],$h0
ld [$ctx+8],$h3
ld [$ctx+12],$h2
ld [$ctx+16],$h4
addcc $h0,5,$r0 ! compare to modulus
addccc $h1,0,$r1
addccc $h2,0,$r2
addccc $h3,0,$r3
addc $h4,0,$h4
andcc $h4,4,%g0 ! did it carry/borrow?
movnz %icc,$r0,$h0
ld [$nonce+0],$r0 ! load nonce
movnz %icc,$r1,$h1
ld [$nonce+4],$r1
movnz %icc,$r2,$h2
ld [$nonce+8],$r2
movnz %icc,$r3,$h3
ld [$nonce+12],$r3
addcc $r0,$h0,$h0 ! accumulate nonce
addccc $r1,$h1,$h1
addccc $r2,$h2,$h2
addc $r3,$h3,$h3
srl $h0,8,$r0
stb $h0,[$mac+0] ! store little-endian result
srl $h0,16,$r1
stb $r0,[$mac+1]
srl $h0,24,$r2
stb $r1,[$mac+2]
stb $r2,[$mac+3]
srl $h1,8,$r0
stb $h1,[$mac+4]
srl $h1,16,$r1
stb $r0,[$mac+5]
srl $h1,24,$r2
stb $r1,[$mac+6]
stb $r2,[$mac+7]
srl $h2,8,$r0
stb $h2,[$mac+8]
srl $h2,16,$r1
stb $r0,[$mac+9]
srl $h2,24,$r2
stb $r1,[$mac+10]
stb $r2,[$mac+11]
srl $h3,8,$r0
stb $h3,[$mac+12]
srl $h3,16,$r1
stb $r0,[$mac+13]
srl $h3,24,$r2
stb $r1,[$mac+14]
stb $r2,[$mac+15]
ret
restore
.type poly1305_emit,#function
.size poly1305_emit,.-poly1305_emit
___
{
my ($ctx,$inp,$len,$padbit) = map("%i$_",(0..3));
my ($in0,$in1,$in2,$in3,$in4) = map("%o$_",(0..4));
my ($i1,$step,$shr,$shl) = map("%l$_",(0..7));
my $i2=$step;
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".2*$_,(0..31));
# borrowings
my ($r3lo,$r3hi,$s1lo,$s1hi) = ($c0lo,$c0hi,$c1lo,$c1hi);
my ($x0,$x1,$x2,$x3) = ($c2lo,$c2hi,$c3lo,$c3hi);
my ($y0,$y1,$y2,$y3) = ($c1lo,$c1hi,$c3hi,$c3lo);
$code.=<<___;
.align 32
poly1305_init_fma:
save %sp,-STACK_FRAME-16,%sp
nop
.Lpoly1305_init_fma:
1: call .+8
add %o7,.Lconsts_fma-1b,%o7
ldd [%o7+8*0],$two0 ! load constants
ldd [%o7+8*1],$two32
ldd [%o7+8*2],$two64
ldd [%o7+8*3],$two96
ldd [%o7+8*5],$five_two130
std $two0,[$ctx+8*0] ! initial hash value, biased 0
std $two32,[$ctx+8*1]
std $two64,[$ctx+8*2]
std $two96,[$ctx+8*3]
brz,pn $inp,.Lno_key_fma
nop
stx %fsr,[%sp+LOCALS] ! save original %fsr
ldx [%o7+8*6],%fsr ! load new %fsr
std $two0,[$ctx+8*4] ! key "template"
std $two32,[$ctx+8*5]
std $two64,[$ctx+8*6]
std $two96,[$ctx+8*7]
and $inp,7,$shr
andn $inp,7,$inp ! align pointer
mov 8,$i1
sll $shr,3,$shr
mov 16,$i2
neg $shr,$shl
ldxa [$inp+%g0]0x88,$in0 ! load little-endian key
ldxa [$inp+$i1]0x88,$in2
brz $shr,.Lkey_aligned_fma
sethi %hi(0xf0000000),$i1 ! 0xf0000000
ldxa [$inp+$i2]0x88,$in4
srlx $in0,$shr,$in0 ! align data
sllx $in2,$shl,$in1
srlx $in2,$shr,$in2
or $in1,$in0,$in0
sllx $in4,$shl,$in3
or $in3,$in2,$in2
.Lkey_aligned_fma:
or $i1,3,$i2 ! 0xf0000003
srlx $in0,32,$in1
andn $in0,$i1,$in0 ! &=0x0fffffff
andn $in1,$i2,$in1 ! &=0x0ffffffc
srlx $in2,32,$in3
andn $in2,$i2,$in2
andn $in3,$i2,$in3
st $in0,[$ctx+`8*4+4`] ! fill "template"
st $in1,[$ctx+`8*5+4`]
st $in2,[$ctx+`8*6+4`]
st $in3,[$ctx+`8*7+4`]
ldd [$ctx+8*4],$h0lo ! load [biased] key
ldd [$ctx+8*5],$h1lo
ldd [$ctx+8*6],$h2lo
ldd [$ctx+8*7],$h3lo
fsubd $h0lo,$two0, $h0lo ! r0
ldd [%o7+8*7],$two0 ! more constants
fsubd $h1lo,$two32,$h1lo ! r1
ldd [%o7+8*8],$two32
fsubd $h2lo,$two64,$h2lo ! r2
ldd [%o7+8*9],$two64
fsubd $h3lo,$two96,$h3lo ! r3
ldd [%o7+8*10],$two96
fmuld $five_two130,$h1lo,$s1lo ! s1
fmuld $five_two130,$h2lo,$s2lo ! s2
fmuld $five_two130,$h3lo,$s3lo ! s3
faddd $h0lo,$two0, $h0hi
faddd $h1lo,$two32,$h1hi
faddd $h2lo,$two64,$h2hi
faddd $h3lo,$two96,$h3hi
fsubd $h0hi,$two0, $h0hi
ldd [%o7+8*11],$two0 ! more constants
fsubd $h1hi,$two32,$h1hi
ldd [%o7+8*12],$two32
fsubd $h2hi,$two64,$h2hi
ldd [%o7+8*13],$two64
fsubd $h3hi,$two96,$h3hi
fsubd $h0lo,$h0hi,$h0lo
std $h0hi,[$ctx+8*5] ! r0hi
fsubd $h1lo,$h1hi,$h1lo
std $h1hi,[$ctx+8*7] ! r1hi
fsubd $h2lo,$h2hi,$h2lo
std $h2hi,[$ctx+8*9] ! r2hi
fsubd $h3lo,$h3hi,$h3lo
std $h3hi,[$ctx+8*11] ! r3hi
faddd $s1lo,$two0, $s1hi
faddd $s2lo,$two32,$s2hi
faddd $s3lo,$two64,$s3hi
fsubd $s1hi,$two0, $s1hi
fsubd $s2hi,$two32,$s2hi
fsubd $s3hi,$two64,$s3hi
fsubd $s1lo,$s1hi,$s1lo
fsubd $s2lo,$s2hi,$s2lo
fsubd $s3lo,$s3hi,$s3lo
ldx [%sp+LOCALS],%fsr ! restore %fsr
std $h0lo,[$ctx+8*4] ! r0lo
std $h1lo,[$ctx+8*6] ! r1lo
std $h2lo,[$ctx+8*8] ! r2lo
std $h3lo,[$ctx+8*10] ! r3lo
std $s1hi,[$ctx+8*13]
std $s2hi,[$ctx+8*15]
std $s3hi,[$ctx+8*17]
std $s1lo,[$ctx+8*12]
std $s2lo,[$ctx+8*14]
std $s3lo,[$ctx+8*16]
add %o7,poly1305_blocks_fma-.Lconsts_fma,%o0
add %o7,poly1305_emit_fma-.Lconsts_fma,%o1
STPTR %o0,[%i2]
STPTR %o1,[%i2+SIZE_T]
ret
restore %g0,1,%o0 ! return 1
.Lno_key_fma:
ret
restore %g0,%g0,%o0 ! return 0
.type poly1305_init_fma,#function
.size poly1305_init_fma,.-poly1305_init_fma
.align 32
poly1305_blocks_fma:
save %sp,-STACK_FRAME-48,%sp
srln $len,4,$len
brz,pn $len,.Labort
sub $len,1,$len
1: call .+8
add %o7,.Lconsts_fma-1b,%o7
ldd [%o7+8*0],$two0 ! load constants
ldd [%o7+8*1],$two32
ldd [%o7+8*2],$two64
ldd [%o7+8*3],$two96
ldd [%o7+8*4],$two130
ldd [%o7+8*5],$five_two130
ldd [$ctx+8*0],$h0lo ! load [biased] hash value
ldd [$ctx+8*1],$h1lo
ldd [$ctx+8*2],$h2lo
ldd [$ctx+8*3],$h3lo
std $two0,[%sp+LOCALS+8*0] ! input "template"
sethi %hi((1023+52+96)<<20),$in3
std $two32,[%sp+LOCALS+8*1]
or $padbit,$in3,$in3
std $two64,[%sp+LOCALS+8*2]
st $in3,[%sp+LOCALS+8*3]
and $inp,7,$shr
andn $inp,7,$inp ! align pointer
mov 8,$i1
sll $shr,3,$shr
mov 16,$step
neg $shr,$shl
ldxa [$inp+%g0]0x88,$in0 ! load little-endian input
brz $shr,.Linp_aligned_fma
ldxa [$inp+$i1]0x88,$in2
ldxa [$inp+$step]0x88,$in4
add $inp,8,$inp
srlx $in0,$shr,$in0 ! align data
sllx $in2,$shl,$in1
srlx $in2,$shr,$in2
or $in1,$in0,$in0
sllx $in4,$shl,$in3
srlx $in4,$shr,$in4 ! pre-shift
or $in3,$in2,$in2
.Linp_aligned_fma:
srlx $in0,32,$in1
movrz $len,0,$step
srlx $in2,32,$in3
add $step,$inp,$inp ! conditional advance
st $in0,[%sp+LOCALS+8*0+4] ! fill "template"
st $in1,[%sp+LOCALS+8*1+4]
st $in2,[%sp+LOCALS+8*2+4]
st $in3,[%sp+LOCALS+8*3+4]
ldd [$ctx+8*4],$r0lo ! load key
ldd [$ctx+8*5],$r0hi
ldd [$ctx+8*6],$r1lo
ldd [$ctx+8*7],$r1hi
ldd [$ctx+8*8],$r2lo
ldd [$ctx+8*9],$r2hi
ldd [$ctx+8*10],$r3lo
ldd [$ctx+8*11],$r3hi
ldd [$ctx+8*12],$s1lo
ldd [$ctx+8*13],$s1hi
ldd [$ctx+8*14],$s2lo
ldd [$ctx+8*15],$s2hi
ldd [$ctx+8*16],$s3lo
ldd [$ctx+8*17],$s3hi
stx %fsr,[%sp+LOCALS+8*4] ! save original %fsr
ldx [%o7+8*6],%fsr ! load new %fsr
subcc $len,1,$len
movrz $len,0,$step
ldd [%sp+LOCALS+8*0],$x0 ! load biased input
ldd [%sp+LOCALS+8*1],$x1
ldd [%sp+LOCALS+8*2],$x2
ldd [%sp+LOCALS+8*3],$x3
fsubd $h0lo,$two0, $h0lo ! de-bias hash value
fsubd $h1lo,$two32,$h1lo
ldxa [$inp+%g0]0x88,$in0 ! modulo-scheduled input load
fsubd $h2lo,$two64,$h2lo
fsubd $h3lo,$two96,$h3lo
ldxa [$inp+$i1]0x88,$in2
fsubd $x0,$two0, $x0 ! de-bias input
fsubd $x1,$two32,$x1
fsubd $x2,$two64,$x2
fsubd $x3,$two96,$x3
brz $shr,.Linp_aligned_fma2
add $step,$inp,$inp ! conditional advance
sllx $in0,$shl,$in1 ! align data
srlx $in0,$shr,$in3
or $in1,$in4,$in0
sllx $in2,$shl,$in1
srlx $in2,$shr,$in4 ! pre-shift
or $in3,$in1,$in2
.Linp_aligned_fma2:
srlx $in0,32,$in1
srlx $in2,32,$in3
faddd $h0lo,$x0,$x0 ! accumulate input
stw $in0,[%sp+LOCALS+8*0+4]
faddd $h1lo,$x1,$x1
stw $in1,[%sp+LOCALS+8*1+4]
faddd $h2lo,$x2,$x2
stw $in2,[%sp+LOCALS+8*2+4]
faddd $h3lo,$x3,$x3
stw $in3,[%sp+LOCALS+8*3+4]
b .Lentry_fma
nop
.align 16
.Loop_fma:
ldxa [$inp+%g0]0x88,$in0 ! modulo-scheduled input load
ldxa [$inp+$i1]0x88,$in2
movrz $len,0,$step
faddd $y0,$h0lo,$h0lo ! accumulate input
faddd $y1,$h0hi,$h0hi
faddd $y2,$h2lo,$h2lo
faddd $y3,$h2hi,$h2hi
brz,pn $shr,.Linp_aligned_fma3
add $step,$inp,$inp ! conditional advance
sllx $in0,$shl,$in1 ! align data
srlx $in0,$shr,$in3
or $in1,$in4,$in0
sllx $in2,$shl,$in1
srlx $in2,$shr,$in4 ! pre-shift
or $in3,$in1,$in2
.Linp_aligned_fma3:
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! base 2^48 -> base 2^32
faddd $two64,$h1lo,$c1lo
srlx $in0,32,$in1
faddd $two64,$h1hi,$c1hi
srlx $in2,32,$in3
faddd $two130,$h3lo,$c3lo
st $in0,[%sp+LOCALS+8*0+4] ! fill "template"
faddd $two130,$h3hi,$c3hi
st $in1,[%sp+LOCALS+8*1+4]
faddd $two32,$h0lo,$c0lo
st $in2,[%sp+LOCALS+8*2+4]
faddd $two32,$h0hi,$c0hi
st $in3,[%sp+LOCALS+8*3+4]
faddd $two96,$h2lo,$c2lo
faddd $two96,$h2hi,$c2hi
fsubd $c1lo,$two64,$c1lo
fsubd $c1hi,$two64,$c1hi
fsubd $c3lo,$two130,$c3lo
fsubd $c3hi,$two130,$c3hi
fsubd $c0lo,$two32,$c0lo
fsubd $c0hi,$two32,$c0hi
fsubd $c2lo,$two96,$c2lo
fsubd $c2hi,$two96,$c2hi
fsubd $h1lo,$c1lo,$h1lo
fsubd $h1hi,$c1hi,$h1hi
fsubd $h3lo,$c3lo,$h3lo
fsubd $h3hi,$c3hi,$h3hi
fsubd $h2lo,$c2lo,$h2lo
fsubd $h2hi,$c2hi,$h2hi
fsubd $h0lo,$c0lo,$h0lo
fsubd $h0hi,$c0hi,$h0hi
faddd $h1lo,$c0lo,$h1lo
faddd $h1hi,$c0hi,$h1hi
faddd $h3lo,$c2lo,$h3lo
faddd $h3hi,$c2hi,$h3hi
faddd $h2lo,$c1lo,$h2lo
faddd $h2hi,$c1hi,$h2hi
fmaddd $five_two130,$c3lo,$h0lo,$h0lo
fmaddd $five_two130,$c3hi,$h0hi,$h0hi
faddd $h1lo,$h1hi,$x1
ldd [$ctx+8*12],$s1lo ! reload constants
faddd $h3lo,$h3hi,$x3
ldd [$ctx+8*13],$s1hi
faddd $h2lo,$h2hi,$x2
ldd [$ctx+8*10],$r3lo
faddd $h0lo,$h0hi,$x0
ldd [$ctx+8*11],$r3hi
.Lentry_fma:
fmuld $x1,$s3lo,$h0lo
fmuld $x1,$s3hi,$h0hi
fmuld $x1,$r1lo,$h2lo
fmuld $x1,$r1hi,$h2hi
fmuld $x1,$r0lo,$h1lo
fmuld $x1,$r0hi,$h1hi
fmuld $x1,$r2lo,$h3lo
fmuld $x1,$r2hi,$h3hi
fmaddd $x3,$s1lo,$h0lo,$h0lo
fmaddd $x3,$s1hi,$h0hi,$h0hi
fmaddd $x3,$s3lo,$h2lo,$h2lo
fmaddd $x3,$s3hi,$h2hi,$h2hi
fmaddd $x3,$s2lo,$h1lo,$h1lo
fmaddd $x3,$s2hi,$h1hi,$h1hi
fmaddd $x3,$r0lo,$h3lo,$h3lo
fmaddd $x3,$r0hi,$h3hi,$h3hi
fmaddd $x2,$s2lo,$h0lo,$h0lo
fmaddd $x2,$s2hi,$h0hi,$h0hi
fmaddd $x2,$r0lo,$h2lo,$h2lo
fmaddd $x2,$r0hi,$h2hi,$h2hi
fmaddd $x2,$s3lo,$h1lo,$h1lo
ldd [%sp+LOCALS+8*0],$y0 ! load [biased] input
fmaddd $x2,$s3hi,$h1hi,$h1hi
ldd [%sp+LOCALS+8*1],$y1
fmaddd $x2,$r1lo,$h3lo,$h3lo
ldd [%sp+LOCALS+8*2],$y2
fmaddd $x2,$r1hi,$h3hi,$h3hi
ldd [%sp+LOCALS+8*3],$y3
fmaddd $x0,$r0lo,$h0lo,$h0lo
fsubd $y0,$two0, $y0 ! de-bias input
fmaddd $x0,$r0hi,$h0hi,$h0hi
fsubd $y1,$two32,$y1
fmaddd $x0,$r2lo,$h2lo,$h2lo
fsubd $y2,$two64,$y2
fmaddd $x0,$r2hi,$h2hi,$h2hi
fsubd $y3,$two96,$y3
fmaddd $x0,$r1lo,$h1lo,$h1lo
fmaddd $x0,$r1hi,$h1hi,$h1hi
fmaddd $x0,$r3lo,$h3lo,$h3lo
fmaddd $x0,$r3hi,$h3hi,$h3hi
bcc SIZE_T_CC,.Loop_fma
subcc $len,1,$len
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! base 2^48 -> base 2^32
faddd $h0lo,$two32,$c0lo
faddd $h0hi,$two32,$c0hi
faddd $h2lo,$two96,$c2lo
faddd $h2hi,$two96,$c2hi
faddd $h1lo,$two64,$c1lo
faddd $h1hi,$two64,$c1hi
faddd $h3lo,$two130,$c3lo
faddd $h3hi,$two130,$c3hi
fsubd $c0lo,$two32,$c0lo
fsubd $c0hi,$two32,$c0hi
fsubd $c2lo,$two96,$c2lo
fsubd $c2hi,$two96,$c2hi
fsubd $c1lo,$two64,$c1lo
fsubd $c1hi,$two64,$c1hi
fsubd $c3lo,$two130,$c3lo
fsubd $c3hi,$two130,$c3hi
fsubd $h1lo,$c1lo,$h1lo
fsubd $h1hi,$c1hi,$h1hi
fsubd $h3lo,$c3lo,$h3lo
fsubd $h3hi,$c3hi,$h3hi
fsubd $h2lo,$c2lo,$h2lo
fsubd $h2hi,$c2hi,$h2hi
fsubd $h0lo,$c0lo,$h0lo
fsubd $h0hi,$c0hi,$h0hi
faddd $h1lo,$c0lo,$h1lo
faddd $h1hi,$c0hi,$h1hi
faddd $h3lo,$c2lo,$h3lo
faddd $h3hi,$c2hi,$h3hi
faddd $h2lo,$c1lo,$h2lo
faddd $h2hi,$c1hi,$h2hi
fmaddd $five_two130,$c3lo,$h0lo,$h0lo
fmaddd $five_two130,$c3hi,$h0hi,$h0hi
faddd $h1lo,$h1hi,$x1
faddd $h3lo,$h3hi,$x3
faddd $h2lo,$h2hi,$x2
faddd $h0lo,$h0hi,$x0
faddd $x1,$two32,$x1 ! bias
faddd $x3,$two96,$x3
faddd $x2,$two64,$x2
faddd $x0,$two0, $x0
ldx [%sp+LOCALS+8*4],%fsr ! restore saved %fsr
std $x1,[$ctx+8*1] ! store [biased] hash value
std $x3,[$ctx+8*3]
std $x2,[$ctx+8*2]
std $x0,[$ctx+8*0]
.Labort:
ret
restore
.type poly1305_blocks_fma,#function
.size poly1305_blocks_fma,.-poly1305_blocks_fma
___
{
my ($mac,$nonce)=($inp,$len);
my ($h0,$h1,$h2,$h3,$h4, $d0,$d1,$d2,$d3, $mask
) = (map("%l$_",(0..5)),map("%o$_",(0..4)));
$code.=<<___;
.align 32
poly1305_emit_fma:
save %sp,-STACK_FRAME,%sp
ld [$ctx+8*0+0],$d0 ! load hash
ld [$ctx+8*0+4],$h0
ld [$ctx+8*1+0],$d1
ld [$ctx+8*1+4],$h1
ld [$ctx+8*2+0],$d2
ld [$ctx+8*2+4],$h2
ld [$ctx+8*3+0],$d3
ld [$ctx+8*3+4],$h3
sethi %hi(0xfff00000),$mask
andn $d0,$mask,$d0 ! mask exponent
andn $d1,$mask,$d1
andn $d2,$mask,$d2
andn $d3,$mask,$d3 ! can be partially reduced...
mov 3,$mask
srl $d3,2,$padbit ! ... so reduce
and $d3,$mask,$h4
andn $d3,$mask,$d3
add $padbit,$d3,$d3
addcc $d3,$h0,$h0
addccc $d0,$h1,$h1
addccc $d1,$h2,$h2
addccc $d2,$h3,$h3
addc %g0,$h4,$h4
addcc $h0,5,$d0 ! compare to modulus
addccc $h1,0,$d1
addccc $h2,0,$d2
addccc $h3,0,$d3
addc $h4,0,$mask
srl $mask,2,$mask ! did it carry/borrow?
neg $mask,$mask
sra $mask,31,$mask ! mask
andn $h0,$mask,$h0
and $d0,$mask,$d0
andn $h1,$mask,$h1
and $d1,$mask,$d1
or $d0,$h0,$h0
ld [$nonce+0],$d0 ! load nonce
andn $h2,$mask,$h2
and $d2,$mask,$d2
or $d1,$h1,$h1
ld [$nonce+4],$d1
andn $h3,$mask,$h3
and $d3,$mask,$d3
or $d2,$h2,$h2
ld [$nonce+8],$d2
or $d3,$h3,$h3
ld [$nonce+12],$d3
addcc $d0,$h0,$h0 ! accumulate nonce
addccc $d1,$h1,$h1
addccc $d2,$h2,$h2
addc $d3,$h3,$h3
stb $h0,[$mac+0] ! write little-endian result
srl $h0,8,$h0
stb $h1,[$mac+4]
srl $h1,8,$h1
stb $h2,[$mac+8]
srl $h2,8,$h2
stb $h3,[$mac+12]
srl $h3,8,$h3
stb $h0,[$mac+1]
srl $h0,8,$h0
stb $h1,[$mac+5]
srl $h1,8,$h1
stb $h2,[$mac+9]
srl $h2,8,$h2
stb $h3,[$mac+13]
srl $h3,8,$h3
stb $h0,[$mac+2]
srl $h0,8,$h0
stb $h1,[$mac+6]
srl $h1,8,$h1
stb $h2,[$mac+10]
srl $h2,8,$h2
stb $h3,[$mac+14]
srl $h3,8,$h3
stb $h0,[$mac+3]
stb $h1,[$mac+7]
stb $h2,[$mac+11]
stb $h3,[$mac+15]
ret
restore
.type poly1305_emit_fma,#function
.size poly1305_emit_fma,.-poly1305_emit_fma
___
}
$code.=<<___;
.align 64
.Lconsts_fma:
.word 0x43300000,0x00000000 ! 2^(52+0)
.word 0x45300000,0x00000000 ! 2^(52+32)
.word 0x47300000,0x00000000 ! 2^(52+64)
.word 0x49300000,0x00000000 ! 2^(52+96)
.word 0x4b500000,0x00000000 ! 2^(52+130)
.word 0x37f40000,0x00000000 ! 5/2^130
.word 0,1<<30 ! fsr: truncate, no exceptions
.word 0x44300000,0x00000000 ! 2^(52+16+0)
.word 0x46300000,0x00000000 ! 2^(52+16+32)
.word 0x48300000,0x00000000 ! 2^(52+16+64)
.word 0x4a300000,0x00000000 ! 2^(52+16+96)
.word 0x3e300000,0x00000000 ! 2^(52+16+0-96)
.word 0x40300000,0x00000000 ! 2^(52+16+32-96)
.word 0x42300000,0x00000000 ! 2^(52+16+64-96)
.asciz "Poly1305 for SPARCv9/VIS3/FMA, CRYPTOGAMS by <appro\@openssl.org>"
.align 4
___
}
# Purpose of these subroutines is to explicitly encode VIS instructions,
# so that one can compile the module without having to specify VIS
# extensions on compiler command line, e.g. -xarch=v9 vs. -xarch=v9a.
# Idea is to reserve for option to produce "universal" binary and let
# programmer detect if current CPU is VIS capable at run-time.
sub unvis3 {
my ($mnemonic,$rs1,$rs2,$rd)=@_;
my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24 );
my ($ref,$opf);
my %visopf = ( "addxc" => 0x011,
"addxccc" => 0x013,
"umulxhi" => 0x016 );
$ref = "$mnemonic\t$rs1,$rs2,$rd";
if ($opf=$visopf{$mnemonic}) {
foreach ($rs1,$rs2,$rd) {
return $ref if (!/%([goli])([0-9])/);
$_=$bias{$1}+$2;
}
return sprintf ".word\t0x%08x !%s",
0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub unfma {
my ($mnemonic,$rs1,$rs2,$rs3,$rd)=@_;
my ($ref,$opf);
my %fmaopf = ( "fmadds" => 0x1,
"fmaddd" => 0x2,
"fmsubs" => 0x5,
"fmsubd" => 0x6 );
$ref = "$mnemonic\t$rs1,$rs2,$rs3,$rd";
if ($opf=$fmaopf{$mnemonic}) {
foreach ($rs1,$rs2,$rs3,$rd) {
return $ref if (!/%f([0-9]{1,2})/);
$_=$1;
if ($1>=32) {
return $ref if ($1&1);
# re-encode for upper double register addressing
$_=($1|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
0x81b80000|$rd<<25|$rs1<<14|$rs3<<9|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
foreach (split("\n",$code)) {
s/\`([^\`]*)\`/eval $1/ge;
s/\b(umulxhi|addxc[c]{0,2})\s+(%[goli][0-7]),\s*(%[goli][0-7]),\s*(%[goli][0-7])/
&unvis3($1,$2,$3,$4)
/ge or
s/\b(fmadd[sd])\s+(%f[0-9]+),\s*(%f[0-9]+),\s*(%f[0-9]+),\s*(%f[0-9]+)/
&unfma($1,$2,$3,$4,$5)
/ge;
print $_,"\n";
}
close STDOUT or die "error closing STDOUT: $!";