boringssl/crypto/fipsmodule/aes/asm/aesv8-armx.pl
David Benjamin f03cdc3a93 Sync ARM assembly up to 609b0852e4d50251857dbbac3141ba042e35a9ae.
This change was made by copying over the files as of that commit and
then discarding the parts of the diff which corresponding to our own
changes.

Change-Id: I28c5d711f7a8cec30749b8174687434129af5209
Reviewed-on: https://boringssl-review.googlesource.com/17111
Reviewed-by: Adam Langley <agl@google.com>
2017-06-13 17:47:20 +00:00

1010 lines
22 KiB
Perl

#! /usr/bin/env perl
# Copyright 2014-2016 The OpenSSL Project Authors. All Rights Reserved.
#
# Licensed under the OpenSSL license (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 support for ARMv8 AES instructions. The
# module is endian-agnostic in sense that it supports both big- and
# little-endian cases. As does it support both 32- and 64-bit modes
# of operation. Latter is achieved by limiting amount of utilized
# registers to 16, which implies additional NEON load and integer
# instructions. This has no effect on mighty Apple A7, where results
# are literally equal to the theoretical estimates based on AES
# instruction latencies and issue rates. On Cortex-A53, an in-order
# execution core, this costs up to 10-15%, which is partially
# compensated by implementing dedicated code path for 128-bit
# CBC encrypt case. On Cortex-A57 parallelizable mode performance
# seems to be limited by sheer amount of NEON instructions...
#
# Performance in cycles per byte processed with 128-bit key:
#
# CBC enc CBC dec CTR
# Apple A7 2.39 1.20 1.20
# Cortex-A53 1.32 1.29 1.46
# Cortex-A57(*) 1.95 0.85 0.93
# Denver 1.96 0.86 0.80
# Mongoose 1.33 1.20 1.20
#
# (*) original 3.64/1.34/1.32 results were for r0p0 revision
# and are still same even for updated module;
$flavour = shift;
$output = shift;
$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
( $xlate="${dir}arm-xlate.pl" and -f $xlate ) or
( $xlate="${dir}../../../perlasm/arm-xlate.pl" and -f $xlate) or
die "can't locate arm-xlate.pl";
open OUT,"| \"$^X\" $xlate $flavour $output";
*STDOUT=*OUT;
$prefix="aes_hw";
$code=<<___;
#include <openssl/arm_arch.h>
#if __ARM_MAX_ARCH__>=7
.text
___
$code.=<<___ if ($flavour =~ /64/);
#if !defined(__clang__) || defined(BORINGSSL_CLANG_SUPPORTS_DOT_ARCH)
.arch armv8-a+crypto
#endif
___
$code.=".arch armv7-a\n.fpu neon\n.code 32\n" if ($flavour !~ /64/);
#^^^^^^ this is done to simplify adoption by not depending
# on latest binutils.
# Assembler mnemonics are an eclectic mix of 32- and 64-bit syntax,
# NEON is mostly 32-bit mnemonics, integer - mostly 64. Goal is to
# maintain both 32- and 64-bit codes within single module and
# transliterate common code to either flavour with regex vodoo.
#
{{{
my ($inp,$bits,$out,$ptr,$rounds)=("x0","w1","x2","x3","w12");
my ($zero,$rcon,$mask,$in0,$in1,$tmp,$key)=
$flavour=~/64/? map("q$_",(0..6)) : map("q$_",(0..3,8..10));
$code.=<<___;
.align 5
.Lrcon:
.long 0x01,0x01,0x01,0x01
.long 0x0c0f0e0d,0x0c0f0e0d,0x0c0f0e0d,0x0c0f0e0d // rotate-n-splat
.long 0x1b,0x1b,0x1b,0x1b
.globl ${prefix}_set_encrypt_key
.type ${prefix}_set_encrypt_key,%function
.align 5
${prefix}_set_encrypt_key:
.Lenc_key:
___
$code.=<<___ if ($flavour =~ /64/);
stp x29,x30,[sp,#-16]!
add x29,sp,#0
___
$code.=<<___;
mov $ptr,#-1
cmp $inp,#0
b.eq .Lenc_key_abort
cmp $out,#0
b.eq .Lenc_key_abort
mov $ptr,#-2
cmp $bits,#128
b.lt .Lenc_key_abort
cmp $bits,#256
b.gt .Lenc_key_abort
tst $bits,#0x3f
b.ne .Lenc_key_abort
adr $ptr,.Lrcon
cmp $bits,#192
veor $zero,$zero,$zero
vld1.8 {$in0},[$inp],#16
mov $bits,#8 // reuse $bits
vld1.32 {$rcon,$mask},[$ptr],#32
b.lt .Loop128
b.eq .L192
b .L256
.align 4
.Loop128:
vtbl.8 $key,{$in0},$mask
vext.8 $tmp,$zero,$in0,#12
vst1.32 {$in0},[$out],#16
aese $key,$zero
subs $bits,$bits,#1
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $key,$key,$rcon
veor $in0,$in0,$tmp
vshl.u8 $rcon,$rcon,#1
veor $in0,$in0,$key
b.ne .Loop128
vld1.32 {$rcon},[$ptr]
vtbl.8 $key,{$in0},$mask
vext.8 $tmp,$zero,$in0,#12
vst1.32 {$in0},[$out],#16
aese $key,$zero
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $key,$key,$rcon
veor $in0,$in0,$tmp
vshl.u8 $rcon,$rcon,#1
veor $in0,$in0,$key
vtbl.8 $key,{$in0},$mask
vext.8 $tmp,$zero,$in0,#12
vst1.32 {$in0},[$out],#16
aese $key,$zero
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $key,$key,$rcon
veor $in0,$in0,$tmp
veor $in0,$in0,$key
vst1.32 {$in0},[$out]
add $out,$out,#0x50
mov $rounds,#10
b .Ldone
.align 4
.L192:
vld1.8 {$in1},[$inp],#8
vmov.i8 $key,#8 // borrow $key
vst1.32 {$in0},[$out],#16
vsub.i8 $mask,$mask,$key // adjust the mask
.Loop192:
vtbl.8 $key,{$in1},$mask
vext.8 $tmp,$zero,$in0,#12
vst1.32 {$in1},[$out],#8
aese $key,$zero
subs $bits,$bits,#1
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vdup.32 $tmp,${in0}[3]
veor $tmp,$tmp,$in1
veor $key,$key,$rcon
vext.8 $in1,$zero,$in1,#12
vshl.u8 $rcon,$rcon,#1
veor $in1,$in1,$tmp
veor $in0,$in0,$key
veor $in1,$in1,$key
vst1.32 {$in0},[$out],#16
b.ne .Loop192
mov $rounds,#12
add $out,$out,#0x20
b .Ldone
.align 4
.L256:
vld1.8 {$in1},[$inp]
mov $bits,#7
mov $rounds,#14
vst1.32 {$in0},[$out],#16
.Loop256:
vtbl.8 $key,{$in1},$mask
vext.8 $tmp,$zero,$in0,#12
vst1.32 {$in1},[$out],#16
aese $key,$zero
subs $bits,$bits,#1
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in0,$in0,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $key,$key,$rcon
veor $in0,$in0,$tmp
vshl.u8 $rcon,$rcon,#1
veor $in0,$in0,$key
vst1.32 {$in0},[$out],#16
b.eq .Ldone
vdup.32 $key,${in0}[3] // just splat
vext.8 $tmp,$zero,$in1,#12
aese $key,$zero
veor $in1,$in1,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in1,$in1,$tmp
vext.8 $tmp,$zero,$tmp,#12
veor $in1,$in1,$tmp
veor $in1,$in1,$key
b .Loop256
.Ldone:
str $rounds,[$out]
mov $ptr,#0
.Lenc_key_abort:
mov x0,$ptr // return value
`"ldr x29,[sp],#16" if ($flavour =~ /64/)`
ret
.size ${prefix}_set_encrypt_key,.-${prefix}_set_encrypt_key
.globl ${prefix}_set_decrypt_key
.type ${prefix}_set_decrypt_key,%function
.align 5
${prefix}_set_decrypt_key:
___
$code.=<<___ if ($flavour =~ /64/);
stp x29,x30,[sp,#-16]!
add x29,sp,#0
___
$code.=<<___ if ($flavour !~ /64/);
stmdb sp!,{r4,lr}
___
$code.=<<___;
bl .Lenc_key
cmp x0,#0
b.ne .Ldec_key_abort
sub $out,$out,#240 // restore original $out
mov x4,#-16
add $inp,$out,x12,lsl#4 // end of key schedule
vld1.32 {v0.16b},[$out]
vld1.32 {v1.16b},[$inp]
vst1.32 {v0.16b},[$inp],x4
vst1.32 {v1.16b},[$out],#16
.Loop_imc:
vld1.32 {v0.16b},[$out]
vld1.32 {v1.16b},[$inp]
aesimc v0.16b,v0.16b
aesimc v1.16b,v1.16b
vst1.32 {v0.16b},[$inp],x4
vst1.32 {v1.16b},[$out],#16
cmp $inp,$out
b.hi .Loop_imc
vld1.32 {v0.16b},[$out]
aesimc v0.16b,v0.16b
vst1.32 {v0.16b},[$inp]
eor x0,x0,x0 // return value
.Ldec_key_abort:
___
$code.=<<___ if ($flavour !~ /64/);
ldmia sp!,{r4,pc}
___
$code.=<<___ if ($flavour =~ /64/);
ldp x29,x30,[sp],#16
ret
___
$code.=<<___;
.size ${prefix}_set_decrypt_key,.-${prefix}_set_decrypt_key
___
}}}
{{{
sub gen_block () {
my $dir = shift;
my ($e,$mc) = $dir eq "en" ? ("e","mc") : ("d","imc");
my ($inp,$out,$key)=map("x$_",(0..2));
my $rounds="w3";
my ($rndkey0,$rndkey1,$inout)=map("q$_",(0..3));
$code.=<<___;
.globl ${prefix}_${dir}crypt
.type ${prefix}_${dir}crypt,%function
.align 5
${prefix}_${dir}crypt:
ldr $rounds,[$key,#240]
vld1.32 {$rndkey0},[$key],#16
vld1.8 {$inout},[$inp]
sub $rounds,$rounds,#2
vld1.32 {$rndkey1},[$key],#16
.Loop_${dir}c:
aes$e $inout,$rndkey0
aes$mc $inout,$inout
vld1.32 {$rndkey0},[$key],#16
subs $rounds,$rounds,#2
aes$e $inout,$rndkey1
aes$mc $inout,$inout
vld1.32 {$rndkey1},[$key],#16
b.gt .Loop_${dir}c
aes$e $inout,$rndkey0
aes$mc $inout,$inout
vld1.32 {$rndkey0},[$key]
aes$e $inout,$rndkey1
veor $inout,$inout,$rndkey0
vst1.8 {$inout},[$out]
ret
.size ${prefix}_${dir}crypt,.-${prefix}_${dir}crypt
___
}
&gen_block("en");
&gen_block("de");
}}}
{{{
my ($inp,$out,$len,$key,$ivp)=map("x$_",(0..4)); my $enc="w5";
my ($rounds,$cnt,$key_,$step,$step1)=($enc,"w6","x7","x8","x12");
my ($dat0,$dat1,$in0,$in1,$tmp0,$tmp1,$ivec,$rndlast)=map("q$_",(0..7));
my ($dat,$tmp,$rndzero_n_last)=($dat0,$tmp0,$tmp1);
my ($key4,$key5,$key6,$key7)=("x6","x12","x14",$key);
### q8-q15 preloaded key schedule
$code.=<<___;
.globl ${prefix}_cbc_encrypt
.type ${prefix}_cbc_encrypt,%function
.align 5
${prefix}_cbc_encrypt:
___
$code.=<<___ if ($flavour =~ /64/);
stp x29,x30,[sp,#-16]!
add x29,sp,#0
___
$code.=<<___ if ($flavour !~ /64/);
mov ip,sp
stmdb sp!,{r4-r8,lr}
vstmdb sp!,{d8-d15} @ ABI specification says so
ldmia ip,{r4-r5} @ load remaining args
___
$code.=<<___;
subs $len,$len,#16
mov $step,#16
b.lo .Lcbc_abort
cclr $step,eq
cmp $enc,#0 // en- or decrypting?
ldr $rounds,[$key,#240]
and $len,$len,#-16
vld1.8 {$ivec},[$ivp]
vld1.8 {$dat},[$inp],$step
vld1.32 {q8-q9},[$key] // load key schedule...
sub $rounds,$rounds,#6
add $key_,$key,x5,lsl#4 // pointer to last 7 round keys
sub $rounds,$rounds,#2
vld1.32 {q10-q11},[$key_],#32
vld1.32 {q12-q13},[$key_],#32
vld1.32 {q14-q15},[$key_],#32
vld1.32 {$rndlast},[$key_]
add $key_,$key,#32
mov $cnt,$rounds
b.eq .Lcbc_dec
cmp $rounds,#2
veor $dat,$dat,$ivec
veor $rndzero_n_last,q8,$rndlast
b.eq .Lcbc_enc128
vld1.32 {$in0-$in1},[$key_]
add $key_,$key,#16
add $key4,$key,#16*4
add $key5,$key,#16*5
aese $dat,q8
aesmc $dat,$dat
add $key6,$key,#16*6
add $key7,$key,#16*7
b .Lenter_cbc_enc
.align 4
.Loop_cbc_enc:
aese $dat,q8
aesmc $dat,$dat
vst1.8 {$ivec},[$out],#16
.Lenter_cbc_enc:
aese $dat,q9
aesmc $dat,$dat
aese $dat,$in0
aesmc $dat,$dat
vld1.32 {q8},[$key4]
cmp $rounds,#4
aese $dat,$in1
aesmc $dat,$dat
vld1.32 {q9},[$key5]
b.eq .Lcbc_enc192
aese $dat,q8
aesmc $dat,$dat
vld1.32 {q8},[$key6]
aese $dat,q9
aesmc $dat,$dat
vld1.32 {q9},[$key7]
nop
.Lcbc_enc192:
aese $dat,q8
aesmc $dat,$dat
subs $len,$len,#16
aese $dat,q9
aesmc $dat,$dat
cclr $step,eq
aese $dat,q10
aesmc $dat,$dat
aese $dat,q11
aesmc $dat,$dat
vld1.8 {q8},[$inp],$step
aese $dat,q12
aesmc $dat,$dat
veor q8,q8,$rndzero_n_last
aese $dat,q13
aesmc $dat,$dat
vld1.32 {q9},[$key_] // re-pre-load rndkey[1]
aese $dat,q14
aesmc $dat,$dat
aese $dat,q15
veor $ivec,$dat,$rndlast
b.hs .Loop_cbc_enc
vst1.8 {$ivec},[$out],#16
b .Lcbc_done
.align 5
.Lcbc_enc128:
vld1.32 {$in0-$in1},[$key_]
aese $dat,q8
aesmc $dat,$dat
b .Lenter_cbc_enc128
.Loop_cbc_enc128:
aese $dat,q8
aesmc $dat,$dat
vst1.8 {$ivec},[$out],#16
.Lenter_cbc_enc128:
aese $dat,q9
aesmc $dat,$dat
subs $len,$len,#16
aese $dat,$in0
aesmc $dat,$dat
cclr $step,eq
aese $dat,$in1
aesmc $dat,$dat
aese $dat,q10
aesmc $dat,$dat
aese $dat,q11
aesmc $dat,$dat
vld1.8 {q8},[$inp],$step
aese $dat,q12
aesmc $dat,$dat
aese $dat,q13
aesmc $dat,$dat
aese $dat,q14
aesmc $dat,$dat
veor q8,q8,$rndzero_n_last
aese $dat,q15
veor $ivec,$dat,$rndlast
b.hs .Loop_cbc_enc128
vst1.8 {$ivec},[$out],#16
b .Lcbc_done
___
{
my ($dat2,$in2,$tmp2)=map("q$_",(10,11,9));
$code.=<<___;
.align 5
.Lcbc_dec:
vld1.8 {$dat2},[$inp],#16
subs $len,$len,#32 // bias
add $cnt,$rounds,#2
vorr $in1,$dat,$dat
vorr $dat1,$dat,$dat
vorr $in2,$dat2,$dat2
b.lo .Lcbc_dec_tail
vorr $dat1,$dat2,$dat2
vld1.8 {$dat2},[$inp],#16
vorr $in0,$dat,$dat
vorr $in1,$dat1,$dat1
vorr $in2,$dat2,$dat2
.Loop3x_cbc_dec:
aesd $dat0,q8
aesimc $dat0,$dat0
aesd $dat1,q8
aesimc $dat1,$dat1
aesd $dat2,q8
aesimc $dat2,$dat2
vld1.32 {q8},[$key_],#16
subs $cnt,$cnt,#2
aesd $dat0,q9
aesimc $dat0,$dat0
aesd $dat1,q9
aesimc $dat1,$dat1
aesd $dat2,q9
aesimc $dat2,$dat2
vld1.32 {q9},[$key_],#16
b.gt .Loop3x_cbc_dec
aesd $dat0,q8
aesimc $dat0,$dat0
aesd $dat1,q8
aesimc $dat1,$dat1
aesd $dat2,q8
aesimc $dat2,$dat2
veor $tmp0,$ivec,$rndlast
subs $len,$len,#0x30
veor $tmp1,$in0,$rndlast
mov.lo x6,$len // x6, $cnt, is zero at this point
aesd $dat0,q9
aesimc $dat0,$dat0
aesd $dat1,q9
aesimc $dat1,$dat1
aesd $dat2,q9
aesimc $dat2,$dat2
veor $tmp2,$in1,$rndlast
add $inp,$inp,x6 // $inp is adjusted in such way that
// at exit from the loop $dat1-$dat2
// are loaded with last "words"
vorr $ivec,$in2,$in2
mov $key_,$key
aesd $dat0,q12
aesimc $dat0,$dat0
aesd $dat1,q12
aesimc $dat1,$dat1
aesd $dat2,q12
aesimc $dat2,$dat2
vld1.8 {$in0},[$inp],#16
aesd $dat0,q13
aesimc $dat0,$dat0
aesd $dat1,q13
aesimc $dat1,$dat1
aesd $dat2,q13
aesimc $dat2,$dat2
vld1.8 {$in1},[$inp],#16
aesd $dat0,q14
aesimc $dat0,$dat0
aesd $dat1,q14
aesimc $dat1,$dat1
aesd $dat2,q14
aesimc $dat2,$dat2
vld1.8 {$in2},[$inp],#16
aesd $dat0,q15
aesd $dat1,q15
aesd $dat2,q15
vld1.32 {q8},[$key_],#16 // re-pre-load rndkey[0]
add $cnt,$rounds,#2
veor $tmp0,$tmp0,$dat0
veor $tmp1,$tmp1,$dat1
veor $dat2,$dat2,$tmp2
vld1.32 {q9},[$key_],#16 // re-pre-load rndkey[1]
vst1.8 {$tmp0},[$out],#16
vorr $dat0,$in0,$in0
vst1.8 {$tmp1},[$out],#16
vorr $dat1,$in1,$in1
vst1.8 {$dat2},[$out],#16
vorr $dat2,$in2,$in2
b.hs .Loop3x_cbc_dec
cmn $len,#0x30
b.eq .Lcbc_done
nop
.Lcbc_dec_tail:
aesd $dat1,q8
aesimc $dat1,$dat1
aesd $dat2,q8
aesimc $dat2,$dat2
vld1.32 {q8},[$key_],#16
subs $cnt,$cnt,#2
aesd $dat1,q9
aesimc $dat1,$dat1
aesd $dat2,q9
aesimc $dat2,$dat2
vld1.32 {q9},[$key_],#16
b.gt .Lcbc_dec_tail
aesd $dat1,q8
aesimc $dat1,$dat1
aesd $dat2,q8
aesimc $dat2,$dat2
aesd $dat1,q9
aesimc $dat1,$dat1
aesd $dat2,q9
aesimc $dat2,$dat2
aesd $dat1,q12
aesimc $dat1,$dat1
aesd $dat2,q12
aesimc $dat2,$dat2
cmn $len,#0x20
aesd $dat1,q13
aesimc $dat1,$dat1
aesd $dat2,q13
aesimc $dat2,$dat2
veor $tmp1,$ivec,$rndlast
aesd $dat1,q14
aesimc $dat1,$dat1
aesd $dat2,q14
aesimc $dat2,$dat2
veor $tmp2,$in1,$rndlast
aesd $dat1,q15
aesd $dat2,q15
b.eq .Lcbc_dec_one
veor $tmp1,$tmp1,$dat1
veor $tmp2,$tmp2,$dat2
vorr $ivec,$in2,$in2
vst1.8 {$tmp1},[$out],#16
vst1.8 {$tmp2},[$out],#16
b .Lcbc_done
.Lcbc_dec_one:
veor $tmp1,$tmp1,$dat2
vorr $ivec,$in2,$in2
vst1.8 {$tmp1},[$out],#16
.Lcbc_done:
vst1.8 {$ivec},[$ivp]
.Lcbc_abort:
___
}
$code.=<<___ if ($flavour !~ /64/);
vldmia sp!,{d8-d15}
ldmia sp!,{r4-r8,pc}
___
$code.=<<___ if ($flavour =~ /64/);
ldr x29,[sp],#16
ret
___
$code.=<<___;
.size ${prefix}_cbc_encrypt,.-${prefix}_cbc_encrypt
___
}}}
{{{
my ($inp,$out,$len,$key,$ivp)=map("x$_",(0..4));
my ($rounds,$cnt,$key_)=("w5","w6","x7");
my ($ctr,$tctr0,$tctr1,$tctr2)=map("w$_",(8..10,12));
my $step="x12"; # aliases with $tctr2
my ($dat0,$dat1,$in0,$in1,$tmp0,$tmp1,$ivec,$rndlast)=map("q$_",(0..7));
my ($dat2,$in2,$tmp2)=map("q$_",(10,11,9));
my ($dat,$tmp)=($dat0,$tmp0);
### q8-q15 preloaded key schedule
$code.=<<___;
.globl ${prefix}_ctr32_encrypt_blocks
.type ${prefix}_ctr32_encrypt_blocks,%function
.align 5
${prefix}_ctr32_encrypt_blocks:
___
$code.=<<___ if ($flavour =~ /64/);
stp x29,x30,[sp,#-16]!
add x29,sp,#0
___
$code.=<<___ if ($flavour !~ /64/);
mov ip,sp
stmdb sp!,{r4-r10,lr}
vstmdb sp!,{d8-d15} @ ABI specification says so
ldr r4, [ip] @ load remaining arg
___
$code.=<<___;
ldr $rounds,[$key,#240]
ldr $ctr, [$ivp, #12]
vld1.32 {$dat0},[$ivp]
vld1.32 {q8-q9},[$key] // load key schedule...
sub $rounds,$rounds,#4
mov $step,#16
cmp $len,#2
add $key_,$key,x5,lsl#4 // pointer to last 5 round keys
sub $rounds,$rounds,#2
vld1.32 {q12-q13},[$key_],#32
vld1.32 {q14-q15},[$key_],#32
vld1.32 {$rndlast},[$key_]
add $key_,$key,#32
mov $cnt,$rounds
cclr $step,lo
#ifndef __ARMEB__
rev $ctr, $ctr
#endif
vorr $dat1,$dat0,$dat0
add $tctr1, $ctr, #1
vorr $dat2,$dat0,$dat0
add $ctr, $ctr, #2
vorr $ivec,$dat0,$dat0
rev $tctr1, $tctr1
vmov.32 ${dat1}[3],$tctr1
b.ls .Lctr32_tail
rev $tctr2, $ctr
sub $len,$len,#3 // bias
vmov.32 ${dat2}[3],$tctr2
b .Loop3x_ctr32
.align 4
.Loop3x_ctr32:
aese $dat0,q8
aesmc $dat0,$dat0
aese $dat1,q8
aesmc $dat1,$dat1
aese $dat2,q8
aesmc $dat2,$dat2
vld1.32 {q8},[$key_],#16
subs $cnt,$cnt,#2
aese $dat0,q9
aesmc $dat0,$dat0
aese $dat1,q9
aesmc $dat1,$dat1
aese $dat2,q9
aesmc $dat2,$dat2
vld1.32 {q9},[$key_],#16
b.gt .Loop3x_ctr32
aese $dat0,q8
aesmc $tmp0,$dat0
aese $dat1,q8
aesmc $tmp1,$dat1
vld1.8 {$in0},[$inp],#16
vorr $dat0,$ivec,$ivec
aese $dat2,q8
aesmc $dat2,$dat2
vld1.8 {$in1},[$inp],#16
vorr $dat1,$ivec,$ivec
aese $tmp0,q9
aesmc $tmp0,$tmp0
aese $tmp1,q9
aesmc $tmp1,$tmp1
vld1.8 {$in2},[$inp],#16
mov $key_,$key
aese $dat2,q9
aesmc $tmp2,$dat2
vorr $dat2,$ivec,$ivec
add $tctr0,$ctr,#1
aese $tmp0,q12
aesmc $tmp0,$tmp0
aese $tmp1,q12
aesmc $tmp1,$tmp1
veor $in0,$in0,$rndlast
add $tctr1,$ctr,#2
aese $tmp2,q12
aesmc $tmp2,$tmp2
veor $in1,$in1,$rndlast
add $ctr,$ctr,#3
aese $tmp0,q13
aesmc $tmp0,$tmp0
aese $tmp1,q13
aesmc $tmp1,$tmp1
veor $in2,$in2,$rndlast
rev $tctr0,$tctr0
aese $tmp2,q13
aesmc $tmp2,$tmp2
vmov.32 ${dat0}[3], $tctr0
rev $tctr1,$tctr1
aese $tmp0,q14
aesmc $tmp0,$tmp0
aese $tmp1,q14
aesmc $tmp1,$tmp1
vmov.32 ${dat1}[3], $tctr1
rev $tctr2,$ctr
aese $tmp2,q14
aesmc $tmp2,$tmp2
vmov.32 ${dat2}[3], $tctr2
subs $len,$len,#3
aese $tmp0,q15
aese $tmp1,q15
aese $tmp2,q15
veor $in0,$in0,$tmp0
vld1.32 {q8},[$key_],#16 // re-pre-load rndkey[0]
vst1.8 {$in0},[$out],#16
veor $in1,$in1,$tmp1
mov $cnt,$rounds
vst1.8 {$in1},[$out],#16
veor $in2,$in2,$tmp2
vld1.32 {q9},[$key_],#16 // re-pre-load rndkey[1]
vst1.8 {$in2},[$out],#16
b.hs .Loop3x_ctr32
adds $len,$len,#3
b.eq .Lctr32_done
cmp $len,#1
mov $step,#16
cclr $step,eq
.Lctr32_tail:
aese $dat0,q8
aesmc $dat0,$dat0
aese $dat1,q8
aesmc $dat1,$dat1
vld1.32 {q8},[$key_],#16
subs $cnt,$cnt,#2
aese $dat0,q9
aesmc $dat0,$dat0
aese $dat1,q9
aesmc $dat1,$dat1
vld1.32 {q9},[$key_],#16
b.gt .Lctr32_tail
aese $dat0,q8
aesmc $dat0,$dat0
aese $dat1,q8
aesmc $dat1,$dat1
aese $dat0,q9
aesmc $dat0,$dat0
aese $dat1,q9
aesmc $dat1,$dat1
vld1.8 {$in0},[$inp],$step
aese $dat0,q12
aesmc $dat0,$dat0
aese $dat1,q12
aesmc $dat1,$dat1
vld1.8 {$in1},[$inp]
aese $dat0,q13
aesmc $dat0,$dat0
aese $dat1,q13
aesmc $dat1,$dat1
veor $in0,$in0,$rndlast
aese $dat0,q14
aesmc $dat0,$dat0
aese $dat1,q14
aesmc $dat1,$dat1
veor $in1,$in1,$rndlast
aese $dat0,q15
aese $dat1,q15
cmp $len,#1
veor $in0,$in0,$dat0
veor $in1,$in1,$dat1
vst1.8 {$in0},[$out],#16
b.eq .Lctr32_done
vst1.8 {$in1},[$out]
.Lctr32_done:
___
$code.=<<___ if ($flavour !~ /64/);
vldmia sp!,{d8-d15}
ldmia sp!,{r4-r10,pc}
___
$code.=<<___ if ($flavour =~ /64/);
ldr x29,[sp],#16
ret
___
$code.=<<___;
.size ${prefix}_ctr32_encrypt_blocks,.-${prefix}_ctr32_encrypt_blocks
___
}}}
$code.=<<___;
#endif
___
########################################
if ($flavour =~ /64/) { ######## 64-bit code
my %opcode = (
"aesd" => 0x4e285800, "aese" => 0x4e284800,
"aesimc"=> 0x4e287800, "aesmc" => 0x4e286800 );
local *unaes = sub {
my ($mnemonic,$arg)=@_;
$arg =~ m/[qv]([0-9]+)[^,]*,\s*[qv]([0-9]+)/o &&
sprintf ".inst\t0x%08x\t//%s %s",
$opcode{$mnemonic}|$1|($2<<5),
$mnemonic,$arg;
};
foreach(split("\n",$code)) {
s/\`([^\`]*)\`/eval($1)/geo;
s/\bq([0-9]+)\b/"v".($1<8?$1:$1+8).".16b"/geo; # old->new registers
s/@\s/\/\//o; # old->new style commentary
#s/[v]?(aes\w+)\s+([qv].*)/unaes($1,$2)/geo or
s/cclr\s+([wx])([^,]+),\s*([a-z]+)/csel $1$2,$1zr,$1$2,$3/o or
s/mov\.([a-z]+)\s+([wx][0-9]+),\s*([wx][0-9]+)/csel $2,$3,$2,$1/o or
s/vmov\.i8/movi/o or # fix up legacy mnemonics
s/vext\.8/ext/o or
s/vrev32\.8/rev32/o or
s/vtst\.8/cmtst/o or
s/vshr/ushr/o or
s/^(\s+)v/$1/o or # strip off v prefix
s/\bbx\s+lr\b/ret/o;
# fix up remainig legacy suffixes
s/\.[ui]?8//o;
m/\],#8/o and s/\.16b/\.8b/go;
s/\.[ui]?32//o and s/\.16b/\.4s/go;
s/\.[ui]?64//o and s/\.16b/\.2d/go;
s/\.[42]([sd])\[([0-3])\]/\.$1\[$2\]/o;
print $_,"\n";
}
} else { ######## 32-bit code
my %opcode = (
"aesd" => 0xf3b00340, "aese" => 0xf3b00300,
"aesimc"=> 0xf3b003c0, "aesmc" => 0xf3b00380 );
local *unaes = sub {
my ($mnemonic,$arg)=@_;
if ($arg =~ m/[qv]([0-9]+)[^,]*,\s*[qv]([0-9]+)/o) {
my $word = $opcode{$mnemonic}|(($1&7)<<13)|(($1&8)<<19)
|(($2&7)<<1) |(($2&8)<<2);
# since ARMv7 instructions are always encoded little-endian.
# correct solution is to use .inst directive, but older
# assemblers don't implement it:-(
sprintf ".byte\t0x%02x,0x%02x,0x%02x,0x%02x\t@ %s %s",
$word&0xff,($word>>8)&0xff,
($word>>16)&0xff,($word>>24)&0xff,
$mnemonic,$arg;
}
};
sub unvtbl {
my $arg=shift;
$arg =~ m/q([0-9]+),\s*\{q([0-9]+)\},\s*q([0-9]+)/o &&
sprintf "vtbl.8 d%d,{q%d},d%d\n\t".
"vtbl.8 d%d,{q%d},d%d", 2*$1,$2,2*$3, 2*$1+1,$2,2*$3+1;
}
sub unvdup32 {
my $arg=shift;
$arg =~ m/q([0-9]+),\s*q([0-9]+)\[([0-3])\]/o &&
sprintf "vdup.32 q%d,d%d[%d]",$1,2*$2+($3>>1),$3&1;
}
sub unvmov32 {
my $arg=shift;
$arg =~ m/q([0-9]+)\[([0-3])\],(.*)/o &&
sprintf "vmov.32 d%d[%d],%s",2*$1+($2>>1),$2&1,$3;
}
foreach(split("\n",$code)) {
s/\`([^\`]*)\`/eval($1)/geo;
s/\b[wx]([0-9]+)\b/r$1/go; # new->old registers
s/\bv([0-9])\.[12468]+[bsd]\b/q$1/go; # new->old registers
s/\/\/\s?/@ /o; # new->old style commentary
# fix up remainig new-style suffixes
s/\{q([0-9]+)\},\s*\[(.+)\],#8/sprintf "{d%d},[$2]!",2*$1/eo or
s/\],#[0-9]+/]!/o;
s/[v]?(aes\w+)\s+([qv].*)/unaes($1,$2)/geo or
s/cclr\s+([^,]+),\s*([a-z]+)/mov$2 $1,#0/o or
s/vtbl\.8\s+(.*)/unvtbl($1)/geo or
s/vdup\.32\s+(.*)/unvdup32($1)/geo or
s/vmov\.32\s+(.*)/unvmov32($1)/geo or
s/^(\s+)b\./$1b/o or
s/^(\s+)mov\./$1mov/o or
s/^(\s+)ret/$1bx\tlr/o;
print $_,"\n";
}
}
close STDOUT;