openssl/crypto/perlasm/sparcv9_modes.pl
Richard Levitte a5d9549d6e Following the license change, modify the boilerplates in crypto/perlasm/
[skip ci]

Reviewed-by: Matt Caswell <matt@openssl.org>
(Merged from https://github.com/openssl/openssl/pull/7807)
2018-12-06 15:10:05 +01:00

1703 lines
38 KiB
Perl

#! /usr/bin/env perl
# Copyright 2012-2016 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
# Specific modes implementations for SPARC Architecture 2011. There
# is T4 dependency though, an ASI value that is not specified in the
# Architecture Manual. But as SPARC universe is rather monocultural,
# we imply that processor capable of executing crypto instructions
# can handle the ASI in question as well. This means that we ought to
# keep eyes open when new processors emerge...
#
# As for above mentioned ASI. It's so called "block initializing
# store" which cancels "read" in "read-update-write" on cache lines.
# This is "cooperative" optimization, as it reduces overall pressure
# on memory interface. Benefits can't be observed/quantified with
# usual benchmarks, on the contrary you can notice that single-thread
# performance for parallelizable modes is ~1.5% worse for largest
# block sizes [though few percent better for not so long ones]. All
# this based on suggestions from David Miller.
$::bias="STACK_BIAS";
$::frame="STACK_FRAME";
$::size_t_cc="SIZE_T_CC";
sub asm_init { # to be called with @ARGV as argument
for (@_) { $::abibits=64 if (/\-m64/ || /\-xarch\=v9/); }
if ($::abibits==64) { $::bias=2047; $::frame=192; $::size_t_cc="%xcc"; }
else { $::bias=0; $::frame=112; $::size_t_cc="%icc"; }
}
# unified interface
my ($inp,$out,$len,$key,$ivec)=map("%i$_",(0..5));
# local variables
my ($ileft,$iright,$ooff,$omask,$ivoff,$blk_init)=map("%l$_",(0..7));
sub alg_cbc_encrypt_implement {
my ($alg,$bits) = @_;
$::code.=<<___;
.globl ${alg}${bits}_t4_cbc_encrypt
.align 32
${alg}${bits}_t4_cbc_encrypt:
save %sp, -$::frame, %sp
cmp $len, 0
be,pn $::size_t_cc, .L${bits}_cbc_enc_abort
srln $len, 0, $len ! needed on v8+, "nop" on v9
sub $inp, $out, $blk_init ! $inp!=$out
___
$::code.=<<___ if (!$::evp);
andcc $ivec, 7, $ivoff
alignaddr $ivec, %g0, $ivec
ldd [$ivec + 0], %f0 ! load ivec
bz,pt %icc, 1f
ldd [$ivec + 8], %f2
ldd [$ivec + 16], %f4
faligndata %f0, %f2, %f0
faligndata %f2, %f4, %f2
1:
___
$::code.=<<___ if ($::evp);
ld [$ivec + 0], %f0
ld [$ivec + 4], %f1
ld [$ivec + 8], %f2
ld [$ivec + 12], %f3
___
$::code.=<<___;
prefetch [$inp], 20
prefetch [$inp + 63], 20
call _${alg}${bits}_load_enckey
and $inp, 7, $ileft
andn $inp, 7, $inp
sll $ileft, 3, $ileft
mov 64, $iright
mov 0xff, $omask
sub $iright, $ileft, $iright
and $out, 7, $ooff
cmp $len, 127
movrnz $ooff, 0, $blk_init ! if ( $out&7 ||
movleu $::size_t_cc, 0, $blk_init ! $len<128 ||
brnz,pn $blk_init, .L${bits}cbc_enc_blk ! $inp==$out)
srl $omask, $ooff, $omask
alignaddrl $out, %g0, $out
srlx $len, 4, $len
prefetch [$out], 22
.L${bits}_cbc_enc_loop:
ldx [$inp + 0], %o0
brz,pt $ileft, 4f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
4:
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
movxtod %o0, %f12
movxtod %o1, %f14
fxor %f12, %f0, %f0 ! ^= ivec
fxor %f14, %f2, %f2
prefetch [$out + 63], 22
prefetch [$inp + 16+63], 20
call _${alg}${bits}_encrypt_1x
add $inp, 16, $inp
brnz,pn $ooff, 2f
sub $len, 1, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
brnz,pt $len, .L${bits}_cbc_enc_loop
add $out, 16, $out
___
$::code.=<<___ if ($::evp);
st %f0, [$ivec + 0]
st %f1, [$ivec + 4]
st %f2, [$ivec + 8]
st %f3, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, 3f
nop
std %f0, [$ivec + 0] ! write out ivec
std %f2, [$ivec + 8]
___
$::code.=<<___;
.L${bits}_cbc_enc_abort:
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f4 ! handle unaligned output
faligndata %f0, %f2, %f6
faligndata %f2, %f2, %f8
stda %f4, [$out + $omask]0xc0 ! partial store
std %f6, [$out + 8]
add $out, 16, $out
orn %g0, $omask, $omask
stda %f8, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_cbc_enc_loop+4
orn %g0, $omask, $omask
___
$::code.=<<___ if ($::evp);
st %f0, [$ivec + 0]
st %f1, [$ivec + 4]
st %f2, [$ivec + 8]
st %f3, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, 3f
nop
std %f0, [$ivec + 0] ! write out ivec
std %f2, [$ivec + 8]
ret
restore
.align 16
3: alignaddrl $ivec, $ivoff, %g0 ! handle unaligned ivec
mov 0xff, $omask
srl $omask, $ivoff, $omask
faligndata %f0, %f0, %f4
faligndata %f0, %f2, %f6
faligndata %f2, %f2, %f8
stda %f4, [$ivec + $omask]0xc0
std %f6, [$ivec + 8]
add $ivec, 16, $ivec
orn %g0, $omask, $omask
stda %f8, [$ivec + $omask]0xc0
___
$::code.=<<___;
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}cbc_enc_blk:
add $out, $len, $blk_init
and $blk_init, 63, $blk_init ! tail
sub $len, $blk_init, $len
add $blk_init, 15, $blk_init ! round up to 16n
srlx $len, 4, $len
srl $blk_init, 4, $blk_init
.L${bits}_cbc_enc_blk_loop:
ldx [$inp + 0], %o0
brz,pt $ileft, 5f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
5:
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
movxtod %o0, %f12
movxtod %o1, %f14
fxor %f12, %f0, %f0 ! ^= ivec
fxor %f14, %f2, %f2
prefetch [$inp + 16+63], 20
call _${alg}${bits}_encrypt_1x
add $inp, 16, $inp
sub $len, 1, $len
stda %f0, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f2, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
brnz,pt $len, .L${bits}_cbc_enc_blk_loop
add $out, 8, $out
membar #StoreLoad|#StoreStore
brnz,pt $blk_init, .L${bits}_cbc_enc_loop
mov $blk_init, $len
___
$::code.=<<___ if ($::evp);
st %f0, [$ivec + 0]
st %f1, [$ivec + 4]
st %f2, [$ivec + 8]
st %f3, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, 3b
nop
std %f0, [$ivec + 0] ! write out ivec
std %f2, [$ivec + 8]
___
$::code.=<<___;
ret
restore
.type ${alg}${bits}_t4_cbc_encrypt,#function
.size ${alg}${bits}_t4_cbc_encrypt,.-${alg}${bits}_t4_cbc_encrypt
___
}
sub alg_cbc_decrypt_implement {
my ($alg,$bits) = @_;
$::code.=<<___;
.globl ${alg}${bits}_t4_cbc_decrypt
.align 32
${alg}${bits}_t4_cbc_decrypt:
save %sp, -$::frame, %sp
cmp $len, 0
be,pn $::size_t_cc, .L${bits}_cbc_dec_abort
srln $len, 0, $len ! needed on v8+, "nop" on v9
sub $inp, $out, $blk_init ! $inp!=$out
___
$::code.=<<___ if (!$::evp);
andcc $ivec, 7, $ivoff
alignaddr $ivec, %g0, $ivec
ldd [$ivec + 0], %f12 ! load ivec
bz,pt %icc, 1f
ldd [$ivec + 8], %f14
ldd [$ivec + 16], %f0
faligndata %f12, %f14, %f12
faligndata %f14, %f0, %f14
1:
___
$::code.=<<___ if ($::evp);
ld [$ivec + 0], %f12 ! load ivec
ld [$ivec + 4], %f13
ld [$ivec + 8], %f14
ld [$ivec + 12], %f15
___
$::code.=<<___;
prefetch [$inp], 20
prefetch [$inp + 63], 20
call _${alg}${bits}_load_deckey
and $inp, 7, $ileft
andn $inp, 7, $inp
sll $ileft, 3, $ileft
mov 64, $iright
mov 0xff, $omask
sub $iright, $ileft, $iright
and $out, 7, $ooff
cmp $len, 255
movrnz $ooff, 0, $blk_init ! if ( $out&7 ||
movleu $::size_t_cc, 0, $blk_init ! $len<256 ||
brnz,pn $blk_init, .L${bits}cbc_dec_blk ! $inp==$out)
srl $omask, $ooff, $omask
andcc $len, 16, %g0 ! is number of blocks even?
srlx $len, 4, $len
alignaddrl $out, %g0, $out
bz %icc, .L${bits}_cbc_dec_loop2x
prefetch [$out], 22
.L${bits}_cbc_dec_loop:
ldx [$inp + 0], %o0
brz,pt $ileft, 4f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
4:
xor %g4, %o0, %o2 ! ^= rk[0]
xor %g5, %o1, %o3
movxtod %o2, %f0
movxtod %o3, %f2
prefetch [$out + 63], 22
prefetch [$inp + 16+63], 20
call _${alg}${bits}_decrypt_1x
add $inp, 16, $inp
fxor %f12, %f0, %f0 ! ^= ivec
fxor %f14, %f2, %f2
movxtod %o0, %f12
movxtod %o1, %f14
brnz,pn $ooff, 2f
sub $len, 1, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
brnz,pt $len, .L${bits}_cbc_dec_loop2x
add $out, 16, $out
___
$::code.=<<___ if ($::evp);
st %f12, [$ivec + 0]
st %f13, [$ivec + 4]
st %f14, [$ivec + 8]
st %f15, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec
nop
std %f12, [$ivec + 0] ! write out ivec
std %f14, [$ivec + 8]
___
$::code.=<<___;
.L${bits}_cbc_dec_abort:
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f4 ! handle unaligned output
faligndata %f0, %f2, %f6
faligndata %f2, %f2, %f8
stda %f4, [$out + $omask]0xc0 ! partial store
std %f6, [$out + 8]
add $out, 16, $out
orn %g0, $omask, $omask
stda %f8, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_cbc_dec_loop2x+4
orn %g0, $omask, $omask
___
$::code.=<<___ if ($::evp);
st %f12, [$ivec + 0]
st %f13, [$ivec + 4]
st %f14, [$ivec + 8]
st %f15, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec
nop
std %f12, [$ivec + 0] ! write out ivec
std %f14, [$ivec + 8]
___
$::code.=<<___;
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}_cbc_dec_loop2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 4f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
4:
xor %g4, %o0, %o4 ! ^= rk[0]
xor %g5, %o1, %o5
movxtod %o4, %f0
movxtod %o5, %f2
xor %g4, %o2, %o4
xor %g5, %o3, %o5
movxtod %o4, %f4
movxtod %o5, %f6
prefetch [$out + 63], 22
prefetch [$inp + 32+63], 20
call _${alg}${bits}_decrypt_2x
add $inp, 32, $inp
movxtod %o0, %f8
movxtod %o1, %f10
fxor %f12, %f0, %f0 ! ^= ivec
fxor %f14, %f2, %f2
movxtod %o2, %f12
movxtod %o3, %f14
fxor %f8, %f4, %f4
fxor %f10, %f6, %f6
brnz,pn $ooff, 2f
sub $len, 2, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
std %f4, [$out + 16]
std %f6, [$out + 24]
brnz,pt $len, .L${bits}_cbc_dec_loop2x
add $out, 32, $out
___
$::code.=<<___ if ($::evp);
st %f12, [$ivec + 0]
st %f13, [$ivec + 4]
st %f14, [$ivec + 8]
st %f15, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec
nop
std %f12, [$ivec + 0] ! write out ivec
std %f14, [$ivec + 8]
___
$::code.=<<___;
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f8 ! handle unaligned output
faligndata %f0, %f2, %f0
faligndata %f2, %f4, %f2
faligndata %f4, %f6, %f4
faligndata %f6, %f6, %f6
stda %f8, [$out + $omask]0xc0 ! partial store
std %f0, [$out + 8]
std %f2, [$out + 16]
std %f4, [$out + 24]
add $out, 32, $out
orn %g0, $omask, $omask
stda %f6, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_cbc_dec_loop2x+4
orn %g0, $omask, $omask
___
$::code.=<<___ if ($::evp);
st %f12, [$ivec + 0]
st %f13, [$ivec + 4]
st %f14, [$ivec + 8]
st %f15, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec
nop
std %f12, [$ivec + 0] ! write out ivec
std %f14, [$ivec + 8]
ret
restore
.align 16
.L${bits}_cbc_dec_unaligned_ivec:
alignaddrl $ivec, $ivoff, %g0 ! handle unaligned ivec
mov 0xff, $omask
srl $omask, $ivoff, $omask
faligndata %f12, %f12, %f0
faligndata %f12, %f14, %f2
faligndata %f14, %f14, %f4
stda %f0, [$ivec + $omask]0xc0
std %f2, [$ivec + 8]
add $ivec, 16, $ivec
orn %g0, $omask, $omask
stda %f4, [$ivec + $omask]0xc0
___
$::code.=<<___;
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}cbc_dec_blk:
add $out, $len, $blk_init
and $blk_init, 63, $blk_init ! tail
sub $len, $blk_init, $len
add $blk_init, 15, $blk_init ! round up to 16n
srlx $len, 4, $len
srl $blk_init, 4, $blk_init
sub $len, 1, $len
add $blk_init, 1, $blk_init
.L${bits}_cbc_dec_blk_loop2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 5f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
5:
xor %g4, %o0, %o4 ! ^= rk[0]
xor %g5, %o1, %o5
movxtod %o4, %f0
movxtod %o5, %f2
xor %g4, %o2, %o4
xor %g5, %o3, %o5
movxtod %o4, %f4
movxtod %o5, %f6
prefetch [$inp + 32+63], 20
call _${alg}${bits}_decrypt_2x
add $inp, 32, $inp
subcc $len, 2, $len
movxtod %o0, %f8
movxtod %o1, %f10
fxor %f12, %f0, %f0 ! ^= ivec
fxor %f14, %f2, %f2
movxtod %o2, %f12
movxtod %o3, %f14
fxor %f8, %f4, %f4
fxor %f10, %f6, %f6
stda %f0, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f2, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f4, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f6, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
bgu,pt $::size_t_cc, .L${bits}_cbc_dec_blk_loop2x
add $out, 8, $out
add $blk_init, $len, $len
andcc $len, 1, %g0 ! is number of blocks even?
membar #StoreLoad|#StoreStore
bnz,pt %icc, .L${bits}_cbc_dec_loop
srl $len, 0, $len
brnz,pn $len, .L${bits}_cbc_dec_loop2x
nop
___
$::code.=<<___ if ($::evp);
st %f12, [$ivec + 0] ! write out ivec
st %f13, [$ivec + 4]
st %f14, [$ivec + 8]
st %f15, [$ivec + 12]
___
$::code.=<<___ if (!$::evp);
brnz,pn $ivoff, 3b
nop
std %f12, [$ivec + 0] ! write out ivec
std %f14, [$ivec + 8]
___
$::code.=<<___;
ret
restore
.type ${alg}${bits}_t4_cbc_decrypt,#function
.size ${alg}${bits}_t4_cbc_decrypt,.-${alg}${bits}_t4_cbc_decrypt
___
}
sub alg_ctr32_implement {
my ($alg,$bits) = @_;
$::code.=<<___;
.globl ${alg}${bits}_t4_ctr32_encrypt
.align 32
${alg}${bits}_t4_ctr32_encrypt:
save %sp, -$::frame, %sp
srln $len, 0, $len ! needed on v8+, "nop" on v9
prefetch [$inp], 20
prefetch [$inp + 63], 20
call _${alg}${bits}_load_enckey
sllx $len, 4, $len
ld [$ivec + 0], %l4 ! counter
ld [$ivec + 4], %l5
ld [$ivec + 8], %l6
ld [$ivec + 12], %l7
sllx %l4, 32, %o5
or %l5, %o5, %o5
sllx %l6, 32, %g1
xor %o5, %g4, %g4 ! ^= rk[0]
xor %g1, %g5, %g5
movxtod %g4, %f14 ! most significant 64 bits
sub $inp, $out, $blk_init ! $inp!=$out
and $inp, 7, $ileft
andn $inp, 7, $inp
sll $ileft, 3, $ileft
mov 64, $iright
mov 0xff, $omask
sub $iright, $ileft, $iright
and $out, 7, $ooff
cmp $len, 255
movrnz $ooff, 0, $blk_init ! if ( $out&7 ||
movleu $::size_t_cc, 0, $blk_init ! $len<256 ||
brnz,pn $blk_init, .L${bits}_ctr32_blk ! $inp==$out)
srl $omask, $ooff, $omask
andcc $len, 16, %g0 ! is number of blocks even?
alignaddrl $out, %g0, $out
bz %icc, .L${bits}_ctr32_loop2x
srlx $len, 4, $len
.L${bits}_ctr32_loop:
ldx [$inp + 0], %o0
brz,pt $ileft, 4f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
4:
xor %g5, %l7, %g1 ! ^= rk[0]
add %l7, 1, %l7
movxtod %g1, %f2
srl %l7, 0, %l7 ! clruw
prefetch [$out + 63], 22
prefetch [$inp + 16+63], 20
___
$::code.=<<___ if ($alg eq "aes");
aes_eround01 %f16, %f14, %f2, %f4
aes_eround23 %f18, %f14, %f2, %f2
___
$::code.=<<___ if ($alg eq "cmll");
camellia_f %f16, %f2, %f14, %f2
camellia_f %f18, %f14, %f2, %f0
___
$::code.=<<___;
call _${alg}${bits}_encrypt_1x+8
add $inp, 16, $inp
movxtod %o0, %f10
movxtod %o1, %f12
fxor %f10, %f0, %f0 ! ^= inp
fxor %f12, %f2, %f2
brnz,pn $ooff, 2f
sub $len, 1, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
brnz,pt $len, .L${bits}_ctr32_loop2x
add $out, 16, $out
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f4 ! handle unaligned output
faligndata %f0, %f2, %f6
faligndata %f2, %f2, %f8
stda %f4, [$out + $omask]0xc0 ! partial store
std %f6, [$out + 8]
add $out, 16, $out
orn %g0, $omask, $omask
stda %f8, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_ctr32_loop2x+4
orn %g0, $omask, $omask
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}_ctr32_loop2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 4f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
4:
xor %g5, %l7, %g1 ! ^= rk[0]
add %l7, 1, %l7
movxtod %g1, %f2
srl %l7, 0, %l7 ! clruw
xor %g5, %l7, %g1
add %l7, 1, %l7
movxtod %g1, %f6
srl %l7, 0, %l7 ! clruw
prefetch [$out + 63], 22
prefetch [$inp + 32+63], 20
___
$::code.=<<___ if ($alg eq "aes");
aes_eround01 %f16, %f14, %f2, %f8
aes_eround23 %f18, %f14, %f2, %f2
aes_eround01 %f16, %f14, %f6, %f10
aes_eround23 %f18, %f14, %f6, %f6
___
$::code.=<<___ if ($alg eq "cmll");
camellia_f %f16, %f2, %f14, %f2
camellia_f %f16, %f6, %f14, %f6
camellia_f %f18, %f14, %f2, %f0
camellia_f %f18, %f14, %f6, %f4
___
$::code.=<<___;
call _${alg}${bits}_encrypt_2x+16
add $inp, 32, $inp
movxtod %o0, %f8
movxtod %o1, %f10
movxtod %o2, %f12
fxor %f8, %f0, %f0 ! ^= inp
movxtod %o3, %f8
fxor %f10, %f2, %f2
fxor %f12, %f4, %f4
fxor %f8, %f6, %f6
brnz,pn $ooff, 2f
sub $len, 2, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
std %f4, [$out + 16]
std %f6, [$out + 24]
brnz,pt $len, .L${bits}_ctr32_loop2x
add $out, 32, $out
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f8 ! handle unaligned output
faligndata %f0, %f2, %f0
faligndata %f2, %f4, %f2
faligndata %f4, %f6, %f4
faligndata %f6, %f6, %f6
stda %f8, [$out + $omask]0xc0 ! partial store
std %f0, [$out + 8]
std %f2, [$out + 16]
std %f4, [$out + 24]
add $out, 32, $out
orn %g0, $omask, $omask
stda %f6, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_ctr32_loop2x+4
orn %g0, $omask, $omask
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}_ctr32_blk:
add $out, $len, $blk_init
and $blk_init, 63, $blk_init ! tail
sub $len, $blk_init, $len
add $blk_init, 15, $blk_init ! round up to 16n
srlx $len, 4, $len
srl $blk_init, 4, $blk_init
sub $len, 1, $len
add $blk_init, 1, $blk_init
.L${bits}_ctr32_blk_loop2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 5f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
5:
xor %g5, %l7, %g1 ! ^= rk[0]
add %l7, 1, %l7
movxtod %g1, %f2
srl %l7, 0, %l7 ! clruw
xor %g5, %l7, %g1
add %l7, 1, %l7
movxtod %g1, %f6
srl %l7, 0, %l7 ! clruw
prefetch [$inp + 32+63], 20
___
$::code.=<<___ if ($alg eq "aes");
aes_eround01 %f16, %f14, %f2, %f8
aes_eround23 %f18, %f14, %f2, %f2
aes_eround01 %f16, %f14, %f6, %f10
aes_eround23 %f18, %f14, %f6, %f6
___
$::code.=<<___ if ($alg eq "cmll");
camellia_f %f16, %f2, %f14, %f2
camellia_f %f16, %f6, %f14, %f6
camellia_f %f18, %f14, %f2, %f0
camellia_f %f18, %f14, %f6, %f4
___
$::code.=<<___;
call _${alg}${bits}_encrypt_2x+16
add $inp, 32, $inp
subcc $len, 2, $len
movxtod %o0, %f8
movxtod %o1, %f10
movxtod %o2, %f12
fxor %f8, %f0, %f0 ! ^= inp
movxtod %o3, %f8
fxor %f10, %f2, %f2
fxor %f12, %f4, %f4
fxor %f8, %f6, %f6
stda %f0, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f2, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f4, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f6, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
bgu,pt $::size_t_cc, .L${bits}_ctr32_blk_loop2x
add $out, 8, $out
add $blk_init, $len, $len
andcc $len, 1, %g0 ! is number of blocks even?
membar #StoreLoad|#StoreStore
bnz,pt %icc, .L${bits}_ctr32_loop
srl $len, 0, $len
brnz,pn $len, .L${bits}_ctr32_loop2x
nop
ret
restore
.type ${alg}${bits}_t4_ctr32_encrypt,#function
.size ${alg}${bits}_t4_ctr32_encrypt,.-${alg}${bits}_t4_ctr32_encrypt
___
}
sub alg_xts_implement {
my ($alg,$bits,$dir) = @_;
my ($inp,$out,$len,$key1,$key2,$ivec)=map("%i$_",(0..5));
my $rem=$ivec;
$::code.=<<___;
.globl ${alg}${bits}_t4_xts_${dir}crypt
.align 32
${alg}${bits}_t4_xts_${dir}crypt:
save %sp, -$::frame-16, %sp
srln $len, 0, $len ! needed on v8+, "nop" on v9
mov $ivec, %o0
add %fp, $::bias-16, %o1
call ${alg}_t4_encrypt
mov $key2, %o2
add %fp, $::bias-16, %l7
ldxa [%l7]0x88, %g2
add %fp, $::bias-8, %l7
ldxa [%l7]0x88, %g3 ! %g3:%g2 is tweak
sethi %hi(0x76543210), %l7
or %l7, %lo(0x76543210), %l7
bmask %l7, %g0, %g0 ! byte swap mask
prefetch [$inp], 20
prefetch [$inp + 63], 20
call _${alg}${bits}_load_${dir}ckey
and $len, 15, $rem
and $len, -16, $len
___
$code.=<<___ if ($dir eq "de");
mov 0, %l7
movrnz $rem, 16, %l7
sub $len, %l7, $len
___
$code.=<<___;
sub $inp, $out, $blk_init ! $inp!=$out
and $inp, 7, $ileft
andn $inp, 7, $inp
sll $ileft, 3, $ileft
mov 64, $iright
mov 0xff, $omask
sub $iright, $ileft, $iright
and $out, 7, $ooff
cmp $len, 255
movrnz $ooff, 0, $blk_init ! if ( $out&7 ||
movleu $::size_t_cc, 0, $blk_init ! $len<256 ||
brnz,pn $blk_init, .L${bits}_xts_${dir}blk ! $inp==$out)
srl $omask, $ooff, $omask
andcc $len, 16, %g0 ! is number of blocks even?
___
$code.=<<___ if ($dir eq "de");
brz,pn $len, .L${bits}_xts_${dir}steal
___
$code.=<<___;
alignaddrl $out, %g0, $out
bz %icc, .L${bits}_xts_${dir}loop2x
srlx $len, 4, $len
.L${bits}_xts_${dir}loop:
ldx [$inp + 0], %o0
brz,pt $ileft, 4f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
4:
movxtod %g2, %f12
movxtod %g3, %f14
bshuffle %f12, %f12, %f12
bshuffle %f14, %f14, %f14
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
movxtod %o0, %f0
movxtod %o1, %f2
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
prefetch [$out + 63], 22
prefetch [$inp + 16+63], 20
call _${alg}${bits}_${dir}crypt_1x
add $inp, 16, $inp
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %g2
and %l7, 0x87, %l7
addxc %g3, %g3, %g3
xor %l7, %g2, %g2
brnz,pn $ooff, 2f
sub $len, 1, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
brnz,pt $len, .L${bits}_xts_${dir}loop2x
add $out, 16, $out
brnz,pn $rem, .L${bits}_xts_${dir}steal
nop
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f4 ! handle unaligned output
faligndata %f0, %f2, %f6
faligndata %f2, %f2, %f8
stda %f4, [$out + $omask]0xc0 ! partial store
std %f6, [$out + 8]
add $out, 16, $out
orn %g0, $omask, $omask
stda %f8, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_xts_${dir}loop2x+4
orn %g0, $omask, $omask
brnz,pn $rem, .L${bits}_xts_${dir}steal
nop
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}_xts_${dir}loop2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 4f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
4:
movxtod %g2, %f12
movxtod %g3, %f14
bshuffle %f12, %f12, %f12
bshuffle %f14, %f14, %f14
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %g2
and %l7, 0x87, %l7
addxc %g3, %g3, %g3
xor %l7, %g2, %g2
movxtod %g2, %f8
movxtod %g3, %f10
bshuffle %f8, %f8, %f8
bshuffle %f10, %f10, %f10
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
xor %g4, %o2, %o2 ! ^= rk[0]
xor %g5, %o3, %o3
movxtod %o0, %f0
movxtod %o1, %f2
movxtod %o2, %f4
movxtod %o3, %f6
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
fxor %f8, %f4, %f4 ! ^= tweak[0]
fxor %f10, %f6, %f6
prefetch [$out + 63], 22
prefetch [$inp + 32+63], 20
call _${alg}${bits}_${dir}crypt_2x
add $inp, 32, $inp
movxtod %g2, %f8
movxtod %g3, %f10
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %g2
and %l7, 0x87, %l7
addxc %g3, %g3, %g3
xor %l7, %g2, %g2
bshuffle %f8, %f8, %f8
bshuffle %f10, %f10, %f10
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
fxor %f8, %f4, %f4
fxor %f10, %f6, %f6
brnz,pn $ooff, 2f
sub $len, 2, $len
std %f0, [$out + 0]
std %f2, [$out + 8]
std %f4, [$out + 16]
std %f6, [$out + 24]
brnz,pt $len, .L${bits}_xts_${dir}loop2x
add $out, 32, $out
fsrc2 %f4, %f0
fsrc2 %f6, %f2
brnz,pn $rem, .L${bits}_xts_${dir}steal
nop
ret
restore
.align 16
2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard
! and ~3x deterioration
! in inp==out case
faligndata %f0, %f0, %f8 ! handle unaligned output
faligndata %f0, %f2, %f10
faligndata %f2, %f4, %f12
faligndata %f4, %f6, %f14
faligndata %f6, %f6, %f0
stda %f8, [$out + $omask]0xc0 ! partial store
std %f10, [$out + 8]
std %f12, [$out + 16]
std %f14, [$out + 24]
add $out, 32, $out
orn %g0, $omask, $omask
stda %f0, [$out + $omask]0xc0 ! partial store
brnz,pt $len, .L${bits}_xts_${dir}loop2x+4
orn %g0, $omask, $omask
fsrc2 %f4, %f0
fsrc2 %f6, %f2
brnz,pn $rem, .L${bits}_xts_${dir}steal
nop
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
.align 32
.L${bits}_xts_${dir}blk:
add $out, $len, $blk_init
and $blk_init, 63, $blk_init ! tail
sub $len, $blk_init, $len
add $blk_init, 15, $blk_init ! round up to 16n
srlx $len, 4, $len
srl $blk_init, 4, $blk_init
sub $len, 1, $len
add $blk_init, 1, $blk_init
.L${bits}_xts_${dir}blk2x:
ldx [$inp + 0], %o0
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
brz,pt $ileft, 5f
ldx [$inp + 24], %o3
ldx [$inp + 32], %o4
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
or %g1, %o0, %o0
sllx %o1, $ileft, %o1
srlx %o2, $iright, %g1
or %g1, %o1, %o1
sllx %o2, $ileft, %o2
srlx %o3, $iright, %g1
or %g1, %o2, %o2
sllx %o3, $ileft, %o3
srlx %o4, $iright, %o4
or %o4, %o3, %o3
5:
movxtod %g2, %f12
movxtod %g3, %f14
bshuffle %f12, %f12, %f12
bshuffle %f14, %f14, %f14
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %g2
and %l7, 0x87, %l7
addxc %g3, %g3, %g3
xor %l7, %g2, %g2
movxtod %g2, %f8
movxtod %g3, %f10
bshuffle %f8, %f8, %f8
bshuffle %f10, %f10, %f10
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
xor %g4, %o2, %o2 ! ^= rk[0]
xor %g5, %o3, %o3
movxtod %o0, %f0
movxtod %o1, %f2
movxtod %o2, %f4
movxtod %o3, %f6
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
fxor %f8, %f4, %f4 ! ^= tweak[0]
fxor %f10, %f6, %f6
prefetch [$inp + 32+63], 20
call _${alg}${bits}_${dir}crypt_2x
add $inp, 32, $inp
movxtod %g2, %f8
movxtod %g3, %f10
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %g2
and %l7, 0x87, %l7
addxc %g3, %g3, %g3
xor %l7, %g2, %g2
bshuffle %f8, %f8, %f8
bshuffle %f10, %f10, %f10
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
fxor %f8, %f4, %f4
fxor %f10, %f6, %f6
subcc $len, 2, $len
stda %f0, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f2, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f4, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
add $out, 8, $out
stda %f6, [$out]0xe2 ! ASI_BLK_INIT, T4-specific
bgu,pt $::size_t_cc, .L${bits}_xts_${dir}blk2x
add $out, 8, $out
add $blk_init, $len, $len
andcc $len, 1, %g0 ! is number of blocks even?
membar #StoreLoad|#StoreStore
bnz,pt %icc, .L${bits}_xts_${dir}loop
srl $len, 0, $len
brnz,pn $len, .L${bits}_xts_${dir}loop2x
nop
fsrc2 %f4, %f0
fsrc2 %f6, %f2
brnz,pn $rem, .L${bits}_xts_${dir}steal
nop
ret
restore
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
___
$code.=<<___ if ($dir eq "en");
.align 32
.L${bits}_xts_${dir}steal:
std %f0, [%fp + $::bias-16] ! copy of output
std %f2, [%fp + $::bias-8]
srl $ileft, 3, $ileft
add %fp, $::bias-16, %l7
add $inp, $ileft, $inp ! original $inp+$len&-15
add $out, $ooff, $out ! original $out+$len&-15
mov 0, $ileft
nop ! align
.L${bits}_xts_${dir}stealing:
ldub [$inp + $ileft], %o0
ldub [%l7 + $ileft], %o1
dec $rem
stb %o0, [%l7 + $ileft]
stb %o1, [$out + $ileft]
brnz $rem, .L${bits}_xts_${dir}stealing
inc $ileft
mov %l7, $inp
sub $out, 16, $out
mov 0, $ileft
sub $out, $ooff, $out
ba .L${bits}_xts_${dir}loop ! one more time
mov 1, $len ! $rem is 0
___
$code.=<<___ if ($dir eq "de");
.align 32
.L${bits}_xts_${dir}steal:
ldx [$inp + 0], %o0
brz,pt $ileft, 8f
ldx [$inp + 8], %o1
ldx [$inp + 16], %o2
sllx %o0, $ileft, %o0
srlx %o1, $iright, %g1
sllx %o1, $ileft, %o1
or %g1, %o0, %o0
srlx %o2, $iright, %o2
or %o2, %o1, %o1
8:
srax %g3, 63, %l7 ! next tweak value
addcc %g2, %g2, %o2
and %l7, 0x87, %l7
addxc %g3, %g3, %o3
xor %l7, %o2, %o2
movxtod %o2, %f12
movxtod %o3, %f14
bshuffle %f12, %f12, %f12
bshuffle %f14, %f14, %f14
xor %g4, %o0, %o0 ! ^= rk[0]
xor %g5, %o1, %o1
movxtod %o0, %f0
movxtod %o1, %f2
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
call _${alg}${bits}_${dir}crypt_1x
add $inp, 16, $inp
fxor %f12, %f0, %f0 ! ^= tweak[0]
fxor %f14, %f2, %f2
std %f0, [%fp + $::bias-16]
std %f2, [%fp + $::bias-8]
srl $ileft, 3, $ileft
add %fp, $::bias-16, %l7
add $inp, $ileft, $inp ! original $inp+$len&-15
add $out, $ooff, $out ! original $out+$len&-15
mov 0, $ileft
add $out, 16, $out
nop ! align
.L${bits}_xts_${dir}stealing:
ldub [$inp + $ileft], %o0
ldub [%l7 + $ileft], %o1
dec $rem
stb %o0, [%l7 + $ileft]
stb %o1, [$out + $ileft]
brnz $rem, .L${bits}_xts_${dir}stealing
inc $ileft
mov %l7, $inp
sub $out, 16, $out
mov 0, $ileft
sub $out, $ooff, $out
ba .L${bits}_xts_${dir}loop ! one more time
mov 1, $len ! $rem is 0
___
$code.=<<___;
ret
restore
.type ${alg}${bits}_t4_xts_${dir}crypt,#function
.size ${alg}${bits}_t4_xts_${dir}crypt,.-${alg}${bits}_t4_xts_${dir}crypt
___
}
# 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 unvis {
my ($mnemonic,$rs1,$rs2,$rd)=@_;
my ($ref,$opf);
my %visopf = ( "faligndata" => 0x048,
"bshuffle" => 0x04c,
"fnot2" => 0x066,
"fxor" => 0x06c,
"fsrc2" => 0x078 );
$ref = "$mnemonic\t$rs1,$rs2,$rd";
if ($opf=$visopf{$mnemonic}) {
foreach ($rs1,$rs2,$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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub unvis3 {
my ($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,
"alignaddr" => 0x018,
"bmask" => 0x019,
"alignaddrl" => 0x01a );
$ref = "$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 $ref;
}
}
sub unaes_round { # 4-argument instructions
my ($mnemonic,$rs1,$rs2,$rs3,$rd)=@_;
my ($ref,$opf);
my %aesopf = ( "aes_eround01" => 0,
"aes_eround23" => 1,
"aes_dround01" => 2,
"aes_dround23" => 3,
"aes_eround01_l"=> 4,
"aes_eround23_l"=> 5,
"aes_dround01_l"=> 6,
"aes_dround23_l"=> 7,
"aes_kexpand1" => 8 );
$ref = "$mnemonic\t$rs1,$rs2,$rs3,$rd";
if (defined($opf=$aesopf{$mnemonic})) {
$rs3 = ($rs3 =~ /%f([0-6]*[02468])/) ? (($1|$1>>5)&31) : $rs3;
foreach ($rs1,$rs2,$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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|$rd<<25|0x19<<19|$rs1<<14|$rs3<<9|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub unaes_kexpand { # 3-argument instructions
my ($mnemonic,$rs1,$rs2,$rd)=@_;
my ($ref,$opf);
my %aesopf = ( "aes_kexpand0" => 0x130,
"aes_kexpand2" => 0x131 );
$ref = "$mnemonic\t$rs1,$rs2,$rd";
if (defined($opf=$aesopf{$mnemonic})) {
foreach ($rs1,$rs2,$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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|$rd<<25|0x36<<19|$rs1<<14|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub uncamellia_f { # 4-argument instructions
my ($mnemonic,$rs1,$rs2,$rs3,$rd)=@_;
my ($ref,$opf);
$ref = "$mnemonic\t$rs1,$rs2,$rs3,$rd";
if (1) {
$rs3 = ($rs3 =~ /%f([0-6]*[02468])/) ? (($1|$1>>5)&31) : $rs3;
foreach ($rs1,$rs2,$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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|$rd<<25|0x19<<19|$rs1<<14|$rs3<<9|0xc<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub uncamellia3 { # 3-argument instructions
my ($mnemonic,$rs1,$rs2,$rd)=@_;
my ($ref,$opf);
my %cmllopf = ( "camellia_fl" => 0x13c,
"camellia_fli" => 0x13d );
$ref = "$mnemonic\t$rs1,$rs2,$rd";
if (defined($opf=$cmllopf{$mnemonic})) {
foreach ($rs1,$rs2,$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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|$rd<<25|0x36<<19|$rs1<<14|$opf<<5|$rs2,
$ref;
} else {
return $ref;
}
}
sub unmovxtox { # 2-argument instructions
my ($mnemonic,$rs,$rd)=@_;
my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24, "f" => 0 );
my ($ref,$opf);
my %movxopf = ( "movdtox" => 0x110,
"movstouw" => 0x111,
"movstosw" => 0x113,
"movxtod" => 0x118,
"movwtos" => 0x119 );
$ref = "$mnemonic\t$rs,$rd";
if (defined($opf=$movxopf{$mnemonic})) {
foreach ($rs,$rd) {
return $ref if (!/%([fgoli])([0-9]{1,2})/);
$_=$bias{$1}+$2;
if ($2>=32) {
return $ref if ($2&1);
# re-encode for upper double register addressing
$_=($2|$2>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|$rd<<25|0x36<<19|$opf<<5|$rs,
$ref;
} else {
return $ref;
}
}
sub undes {
my ($mnemonic)=shift;
my @args=@_;
my ($ref,$opf);
my %desopf = ( "des_round" => 0b1001,
"des_ip" => 0b100110100,
"des_iip" => 0b100110101,
"des_kexpand" => 0b100110110 );
$ref = "$mnemonic\t".join(",",@_);
if (defined($opf=$desopf{$mnemonic})) { # 4-arg
if ($mnemonic eq "des_round") {
foreach (@args[0..3]) {
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|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|0b011001<<19|$opf<<5|$args[0]<<14|$args[1]|$args[2]<<9|$args[3]<<25,
$ref;
} elsif ($mnemonic eq "des_kexpand") { # 3-arg
foreach (@args[0..2]) {
return $ref if (!/(%f)?([0-9]{1,2})/);
$_=$2;
if ($2>=32) {
return $ref if ($2&1);
# re-encode for upper double register addressing
$_=($2|$2>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|0b110110<<19|$opf<<5|$args[0]<<14|$args[1]|$args[2]<<25,
$ref;
} else { # 2-arg
foreach (@args[0..1]) {
return $ref if (!/%f([0-9]{1,2})/);
$_=$1;
if ($1>=32) {
return $ref if ($2&1);
# re-encode for upper double register addressing
$_=($1|$1>>5)&31;
}
}
return sprintf ".word\t0x%08x !%s",
2<<30|0b110110<<19|$opf<<5|$args[0]<<14|$args[1]<<25,
$ref;
}
} else {
return $ref;
}
}
sub emit_assembler {
foreach (split("\n",$::code)) {
s/\`([^\`]*)\`/eval $1/ge;
s/\b(f[a-z]+2[sd]*)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})\s*$/$1\t%f0,$2,$3/go;
s/\b(aes_[edk][^\s]*)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*([%fx0-9]+),\s*(%f[0-9]{1,2})/
&unaes_round($1,$2,$3,$4,$5)
/geo or
s/\b(aes_kexpand[02])\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})/
&unaes_kexpand($1,$2,$3,$4)
/geo or
s/\b(camellia_f)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*([%fx0-9]+),\s*(%f[0-9]{1,2})/
&uncamellia_f($1,$2,$3,$4,$5)
/geo or
s/\b(camellia_[^s]+)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})/
&uncamellia3($1,$2,$3,$4)
/geo or
s/\b(des_\w+)\s+(%f[0-9]{1,2}),\s*([%fx0-9]+)(?:,\s*(%f[0-9]{1,2})(?:,\s*(%f[0-9]{1,2}))?)?/
&undes($1,$2,$3,$4,$5)
/geo or
s/\b(mov[ds]to\w+)\s+(%f[0-9]{1,2}),\s*(%[goli][0-7])/
&unmovxtox($1,$2,$3)
/geo or
s/\b(mov[xw]to[ds])\s+(%[goli][0-7]),\s*(%f[0-9]{1,2})/
&unmovxtox($1,$2,$3)
/geo or
s/\b([fb][^\s]*)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})/
&unvis($1,$2,$3,$4)
/geo or
s/\b(umulxhi|bmask|addxc[c]{0,2}|alignaddr[l]*)\s+(%[goli][0-7]),\s*(%[goli][0-7]),\s*(%[goli][0-7])/
&unvis3($1,$2,$3,$4)
/geo;
print $_,"\n";
}
}
1;