782 lines
19 KiB
Perl
782 lines
19 KiB
Perl
#! /usr/bin/env perl
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# Copyright 2014-2020 The OpenSSL Project Authors. All Rights Reserved.
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#
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# Licensed under the OpenSSL license (the "License"). You may not use
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# this file except in compliance with the License. You can obtain a copy
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# in the file LICENSE in the source distribution or at
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# https://www.openssl.org/source/license.html
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#
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# ====================================================================
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# Written by Andy Polyakov <appro@openssl.org> for the OpenSSL
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# project. The module is, however, dual licensed under OpenSSL and
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# CRYPTOGAMS licenses depending on where you obtain it. For further
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# details see http://www.openssl.org/~appro/cryptogams/.
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# ====================================================================
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#
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# GHASH for ARMv8 Crypto Extension, 64-bit polynomial multiplication.
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#
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# June 2014
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#
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# Initial version was developed in tight cooperation with Ard
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# Biesheuvel of Linaro from bits-n-pieces from other assembly modules.
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# Just like aesv8-armx.pl this module supports both AArch32 and
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# AArch64 execution modes.
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#
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# July 2014
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#
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# Implement 2x aggregated reduction [see ghash-x86.pl for background
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# information].
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#
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# November 2017
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#
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# AArch64 register bank to "accommodate" 4x aggregated reduction and
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# improve performance by 20-70% depending on processor.
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#
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# Current performance in cycles per processed byte:
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#
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# 64-bit PMULL 32-bit PMULL 32-bit NEON(*)
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# Apple A7 0.58 0.92 5.62
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# Cortex-A53 0.85 1.01 8.39
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# Cortex-A57 0.73 1.17 7.61
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# Denver 0.51 0.65 6.02
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# Mongoose 0.65 1.10 8.06
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# Kryo 0.76 1.16 8.00
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#
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# (*) presented for reference/comparison purposes;
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$flavour = shift;
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$output = shift;
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$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
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( $xlate="${dir}arm-xlate.pl" and -f $xlate ) or
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( $xlate="${dir}../../perlasm/arm-xlate.pl" and -f $xlate) or
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die "can't locate arm-xlate.pl";
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open OUT,"| \"$^X\" $xlate $flavour $output";
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*STDOUT=*OUT;
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$Xi="x0"; # argument block
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$Htbl="x1";
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$inp="x2";
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$len="x3";
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$inc="x12";
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{
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my ($Xl,$Xm,$Xh,$IN)=map("q$_",(0..3));
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my ($t0,$t1,$t2,$xC2,$H,$Hhl,$H2)=map("q$_",(8..14));
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$code=<<___;
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#include "arm_arch.h"
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#if __ARM_MAX_ARCH__>=7
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.text
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___
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$code.=".arch armv8-a+crypto\n" if ($flavour =~ /64/);
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$code.=<<___ if ($flavour !~ /64/);
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.fpu neon
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.code 32
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#undef __thumb2__
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___
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################################################################################
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# void gcm_init_v8(u128 Htable[16],const u64 H[2]);
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#
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# input: 128-bit H - secret parameter E(K,0^128)
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# output: precomputed table filled with degrees of twisted H;
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# H is twisted to handle reverse bitness of GHASH;
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# only few of 16 slots of Htable[16] are used;
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# data is opaque to outside world (which allows to
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# optimize the code independently);
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#
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$code.=<<___;
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.global gcm_init_v8
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.type gcm_init_v8,%function
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.align 4
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gcm_init_v8:
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vld1.64 {$t1},[x1] @ load input H
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vmov.i8 $xC2,#0xe1
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vshl.i64 $xC2,$xC2,#57 @ 0xc2.0
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vext.8 $IN,$t1,$t1,#8
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vshr.u64 $t2,$xC2,#63
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vdup.32 $t1,${t1}[1]
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vext.8 $t0,$t2,$xC2,#8 @ t0=0xc2....01
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vshr.u64 $t2,$IN,#63
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vshr.s32 $t1,$t1,#31 @ broadcast carry bit
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vand $t2,$t2,$t0
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vshl.i64 $IN,$IN,#1
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vext.8 $t2,$t2,$t2,#8
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vand $t0,$t0,$t1
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vorr $IN,$IN,$t2 @ H<<<=1
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veor $H,$IN,$t0 @ twisted H
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vst1.64 {$H},[x0],#16 @ store Htable[0]
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@ calculate H^2
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vext.8 $t0,$H,$H,#8 @ Karatsuba pre-processing
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vpmull.p64 $Xl,$H,$H
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veor $t0,$t0,$H
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vpmull2.p64 $Xh,$H,$H
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vpmull.p64 $Xm,$t0,$t0
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vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
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veor $t2,$Xl,$Xh
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veor $Xm,$Xm,$t1
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veor $Xm,$Xm,$t2
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vpmull.p64 $t2,$Xl,$xC2 @ 1st phase
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vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
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vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
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veor $Xl,$Xm,$t2
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vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase
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vpmull.p64 $Xl,$Xl,$xC2
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veor $t2,$t2,$Xh
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veor $H2,$Xl,$t2
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vext.8 $t1,$H2,$H2,#8 @ Karatsuba pre-processing
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veor $t1,$t1,$H2
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vext.8 $Hhl,$t0,$t1,#8 @ pack Karatsuba pre-processed
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vst1.64 {$Hhl-$H2},[x0],#32 @ store Htable[1..2]
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___
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if ($flavour =~ /64/) {
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my ($t3,$Yl,$Ym,$Yh) = map("q$_",(4..7));
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$code.=<<___;
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@ calculate H^3 and H^4
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vpmull.p64 $Xl,$H, $H2
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vpmull.p64 $Yl,$H2,$H2
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vpmull2.p64 $Xh,$H, $H2
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vpmull2.p64 $Yh,$H2,$H2
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vpmull.p64 $Xm,$t0,$t1
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vpmull.p64 $Ym,$t1,$t1
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vext.8 $t0,$Xl,$Xh,#8 @ Karatsuba post-processing
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vext.8 $t1,$Yl,$Yh,#8
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veor $t2,$Xl,$Xh
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veor $Xm,$Xm,$t0
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veor $t3,$Yl,$Yh
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veor $Ym,$Ym,$t1
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veor $Xm,$Xm,$t2
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vpmull.p64 $t2,$Xl,$xC2 @ 1st phase
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veor $Ym,$Ym,$t3
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vpmull.p64 $t3,$Yl,$xC2
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vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
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vmov $Yh#lo,$Ym#hi
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vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
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vmov $Ym#hi,$Yl#lo
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veor $Xl,$Xm,$t2
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veor $Yl,$Ym,$t3
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vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase
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vext.8 $t3,$Yl,$Yl,#8
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vpmull.p64 $Xl,$Xl,$xC2
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vpmull.p64 $Yl,$Yl,$xC2
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veor $t2,$t2,$Xh
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veor $t3,$t3,$Yh
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veor $H, $Xl,$t2 @ H^3
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veor $H2,$Yl,$t3 @ H^4
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vext.8 $t0,$H, $H,#8 @ Karatsuba pre-processing
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vext.8 $t1,$H2,$H2,#8
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veor $t0,$t0,$H
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veor $t1,$t1,$H2
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vext.8 $Hhl,$t0,$t1,#8 @ pack Karatsuba pre-processed
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vst1.64 {$H-$H2},[x0] @ store Htable[3..5]
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___
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}
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$code.=<<___;
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ret
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.size gcm_init_v8,.-gcm_init_v8
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___
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################################################################################
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# void gcm_gmult_v8(u64 Xi[2],const u128 Htable[16]);
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#
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# input: Xi - current hash value;
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# Htable - table precomputed in gcm_init_v8;
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# output: Xi - next hash value Xi;
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#
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$code.=<<___;
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.global gcm_gmult_v8
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.type gcm_gmult_v8,%function
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.align 4
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gcm_gmult_v8:
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vld1.64 {$t1},[$Xi] @ load Xi
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vmov.i8 $xC2,#0xe1
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vld1.64 {$H-$Hhl},[$Htbl] @ load twisted H, ...
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vshl.u64 $xC2,$xC2,#57
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#ifndef __ARMEB__
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vrev64.8 $t1,$t1
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#endif
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vext.8 $IN,$t1,$t1,#8
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vpmull.p64 $Xl,$H,$IN @ H.lo·Xi.lo
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veor $t1,$t1,$IN @ Karatsuba pre-processing
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vpmull2.p64 $Xh,$H,$IN @ H.hi·Xi.hi
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vpmull.p64 $Xm,$Hhl,$t1 @ (H.lo+H.hi)·(Xi.lo+Xi.hi)
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vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
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veor $t2,$Xl,$Xh
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veor $Xm,$Xm,$t1
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veor $Xm,$Xm,$t2
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vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
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vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
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vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
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veor $Xl,$Xm,$t2
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vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
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vpmull.p64 $Xl,$Xl,$xC2
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veor $t2,$t2,$Xh
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veor $Xl,$Xl,$t2
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#ifndef __ARMEB__
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vrev64.8 $Xl,$Xl
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#endif
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vext.8 $Xl,$Xl,$Xl,#8
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vst1.64 {$Xl},[$Xi] @ write out Xi
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ret
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.size gcm_gmult_v8,.-gcm_gmult_v8
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___
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################################################################################
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# void gcm_ghash_v8(u64 Xi[2],const u128 Htable[16],const u8 *inp,size_t len);
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#
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# input: table precomputed in gcm_init_v8;
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# current hash value Xi;
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# pointer to input data;
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# length of input data in bytes, but divisible by block size;
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# output: next hash value Xi;
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#
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$code.=<<___;
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.global gcm_ghash_v8
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.type gcm_ghash_v8,%function
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.align 4
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gcm_ghash_v8:
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___
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$code.=<<___ if ($flavour =~ /64/);
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cmp $len,#64
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b.hs .Lgcm_ghash_v8_4x
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___
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$code.=<<___ if ($flavour !~ /64/);
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vstmdb sp!,{d8-d15} @ 32-bit ABI says so
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___
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$code.=<<___;
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vld1.64 {$Xl},[$Xi] @ load [rotated] Xi
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@ "[rotated]" means that
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@ loaded value would have
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@ to be rotated in order to
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@ make it appear as in
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@ algorithm specification
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subs $len,$len,#32 @ see if $len is 32 or larger
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mov $inc,#16 @ $inc is used as post-
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@ increment for input pointer;
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@ as loop is modulo-scheduled
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@ $inc is zeroed just in time
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@ to preclude overstepping
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@ inp[len], which means that
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@ last block[s] are actually
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@ loaded twice, but last
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@ copy is not processed
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vld1.64 {$H-$Hhl},[$Htbl],#32 @ load twisted H, ..., H^2
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vmov.i8 $xC2,#0xe1
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vld1.64 {$H2},[$Htbl]
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cclr $inc,eq @ is it time to zero $inc?
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vext.8 $Xl,$Xl,$Xl,#8 @ rotate Xi
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vld1.64 {$t0},[$inp],#16 @ load [rotated] I[0]
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vshl.u64 $xC2,$xC2,#57 @ compose 0xc2.0 constant
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#ifndef __ARMEB__
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vrev64.8 $t0,$t0
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vrev64.8 $Xl,$Xl
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#endif
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vext.8 $IN,$t0,$t0,#8 @ rotate I[0]
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b.lo .Lodd_tail_v8 @ $len was less than 32
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___
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{ my ($Xln,$Xmn,$Xhn,$In) = map("q$_",(4..7));
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#######
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# Xi+2 =[H*(Ii+1 + Xi+1)] mod P =
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# [(H*Ii+1) + (H*Xi+1)] mod P =
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# [(H*Ii+1) + H^2*(Ii+Xi)] mod P
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#
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$code.=<<___;
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vld1.64 {$t1},[$inp],$inc @ load [rotated] I[1]
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#ifndef __ARMEB__
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vrev64.8 $t1,$t1
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#endif
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vext.8 $In,$t1,$t1,#8
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veor $IN,$IN,$Xl @ I[i]^=Xi
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vpmull.p64 $Xln,$H,$In @ H·Ii+1
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veor $t1,$t1,$In @ Karatsuba pre-processing
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vpmull2.p64 $Xhn,$H,$In
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b .Loop_mod2x_v8
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.align 4
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.Loop_mod2x_v8:
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vext.8 $t2,$IN,$IN,#8
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subs $len,$len,#32 @ is there more data?
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vpmull.p64 $Xl,$H2,$IN @ H^2.lo·Xi.lo
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cclr $inc,lo @ is it time to zero $inc?
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vpmull.p64 $Xmn,$Hhl,$t1
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veor $t2,$t2,$IN @ Karatsuba pre-processing
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vpmull2.p64 $Xh,$H2,$IN @ H^2.hi·Xi.hi
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veor $Xl,$Xl,$Xln @ accumulate
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vpmull2.p64 $Xm,$Hhl,$t2 @ (H^2.lo+H^2.hi)·(Xi.lo+Xi.hi)
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vld1.64 {$t0},[$inp],$inc @ load [rotated] I[i+2]
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veor $Xh,$Xh,$Xhn
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cclr $inc,eq @ is it time to zero $inc?
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veor $Xm,$Xm,$Xmn
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vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
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veor $t2,$Xl,$Xh
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veor $Xm,$Xm,$t1
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vld1.64 {$t1},[$inp],$inc @ load [rotated] I[i+3]
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#ifndef __ARMEB__
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vrev64.8 $t0,$t0
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#endif
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veor $Xm,$Xm,$t2
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vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
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#ifndef __ARMEB__
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vrev64.8 $t1,$t1
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#endif
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vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
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vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
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vext.8 $In,$t1,$t1,#8
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vext.8 $IN,$t0,$t0,#8
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veor $Xl,$Xm,$t2
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vpmull.p64 $Xln,$H,$In @ H·Ii+1
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veor $IN,$IN,$Xh @ accumulate $IN early
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vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
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vpmull.p64 $Xl,$Xl,$xC2
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veor $IN,$IN,$t2
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veor $t1,$t1,$In @ Karatsuba pre-processing
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veor $IN,$IN,$Xl
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vpmull2.p64 $Xhn,$H,$In
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b.hs .Loop_mod2x_v8 @ there was at least 32 more bytes
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veor $Xh,$Xh,$t2
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vext.8 $IN,$t0,$t0,#8 @ re-construct $IN
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adds $len,$len,#32 @ re-construct $len
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veor $Xl,$Xl,$Xh @ re-construct $Xl
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b.eq .Ldone_v8 @ is $len zero?
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___
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}
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$code.=<<___;
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.Lodd_tail_v8:
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vext.8 $t2,$Xl,$Xl,#8
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veor $IN,$IN,$Xl @ inp^=Xi
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veor $t1,$t0,$t2 @ $t1 is rotated inp^Xi
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vpmull.p64 $Xl,$H,$IN @ H.lo·Xi.lo
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veor $t1,$t1,$IN @ Karatsuba pre-processing
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vpmull2.p64 $Xh,$H,$IN @ H.hi·Xi.hi
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vpmull.p64 $Xm,$Hhl,$t1 @ (H.lo+H.hi)·(Xi.lo+Xi.hi)
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vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
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veor $t2,$Xl,$Xh
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veor $Xm,$Xm,$t1
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veor $Xm,$Xm,$t2
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vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
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vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
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vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
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veor $Xl,$Xm,$t2
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vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
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vpmull.p64 $Xl,$Xl,$xC2
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veor $t2,$t2,$Xh
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veor $Xl,$Xl,$t2
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.Ldone_v8:
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#ifndef __ARMEB__
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vrev64.8 $Xl,$Xl
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#endif
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vext.8 $Xl,$Xl,$Xl,#8
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vst1.64 {$Xl},[$Xi] @ write out Xi
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___
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$code.=<<___ if ($flavour !~ /64/);
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vldmia sp!,{d8-d15} @ 32-bit ABI says so
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___
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$code.=<<___;
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ret
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.size gcm_ghash_v8,.-gcm_ghash_v8
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___
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if ($flavour =~ /64/) { # 4x subroutine
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my ($I0,$j1,$j2,$j3,
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$I1,$I2,$I3,$H3,$H34,$H4,$Yl,$Ym,$Yh) = map("q$_",(4..7,15..23));
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$code.=<<___;
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.type gcm_ghash_v8_4x,%function
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.align 4
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gcm_ghash_v8_4x:
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.Lgcm_ghash_v8_4x:
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vld1.64 {$Xl},[$Xi] @ load [rotated] Xi
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vld1.64 {$H-$H2},[$Htbl],#48 @ load twisted H, ..., H^2
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vmov.i8 $xC2,#0xe1
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vld1.64 {$H3-$H4},[$Htbl] @ load twisted H^3, ..., H^4
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vshl.u64 $xC2,$xC2,#57 @ compose 0xc2.0 constant
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vld1.64 {$I0-$j3},[$inp],#64
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#ifndef __ARMEB__
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vrev64.8 $Xl,$Xl
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vrev64.8 $j1,$j1
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|
vrev64.8 $j2,$j2
|
|
vrev64.8 $j3,$j3
|
|
vrev64.8 $I0,$I0
|
|
#endif
|
|
vext.8 $I3,$j3,$j3,#8
|
|
vext.8 $I2,$j2,$j2,#8
|
|
vext.8 $I1,$j1,$j1,#8
|
|
|
|
vpmull.p64 $Yl,$H,$I3 @ H·Ii+3
|
|
veor $j3,$j3,$I3
|
|
vpmull2.p64 $Yh,$H,$I3
|
|
vpmull.p64 $Ym,$Hhl,$j3
|
|
|
|
vpmull.p64 $t0,$H2,$I2 @ H^2·Ii+2
|
|
veor $j2,$j2,$I2
|
|
vpmull2.p64 $I2,$H2,$I2
|
|
vpmull2.p64 $j2,$Hhl,$j2
|
|
|
|
veor $Yl,$Yl,$t0
|
|
veor $Yh,$Yh,$I2
|
|
veor $Ym,$Ym,$j2
|
|
|
|
vpmull.p64 $j3,$H3,$I1 @ H^3·Ii+1
|
|
veor $j1,$j1,$I1
|
|
vpmull2.p64 $I1,$H3,$I1
|
|
vpmull.p64 $j1,$H34,$j1
|
|
|
|
veor $Yl,$Yl,$j3
|
|
veor $Yh,$Yh,$I1
|
|
veor $Ym,$Ym,$j1
|
|
|
|
subs $len,$len,#128
|
|
b.lo .Ltail4x
|
|
|
|
b .Loop4x
|
|
|
|
.align 4
|
|
.Loop4x:
|
|
veor $t0,$I0,$Xl
|
|
vld1.64 {$I0-$j3},[$inp],#64
|
|
vext.8 $IN,$t0,$t0,#8
|
|
#ifndef __ARMEB__
|
|
vrev64.8 $j1,$j1
|
|
vrev64.8 $j2,$j2
|
|
vrev64.8 $j3,$j3
|
|
vrev64.8 $I0,$I0
|
|
#endif
|
|
|
|
vpmull.p64 $Xl,$H4,$IN @ H^4·(Xi+Ii)
|
|
veor $t0,$t0,$IN
|
|
vpmull2.p64 $Xh,$H4,$IN
|
|
vext.8 $I3,$j3,$j3,#8
|
|
vpmull2.p64 $Xm,$H34,$t0
|
|
|
|
veor $Xl,$Xl,$Yl
|
|
veor $Xh,$Xh,$Yh
|
|
vext.8 $I2,$j2,$j2,#8
|
|
veor $Xm,$Xm,$Ym
|
|
vext.8 $I1,$j1,$j1,#8
|
|
|
|
vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
|
|
veor $t2,$Xl,$Xh
|
|
vpmull.p64 $Yl,$H,$I3 @ H·Ii+3
|
|
veor $j3,$j3,$I3
|
|
veor $Xm,$Xm,$t1
|
|
vpmull2.p64 $Yh,$H,$I3
|
|
veor $Xm,$Xm,$t2
|
|
vpmull.p64 $Ym,$Hhl,$j3
|
|
|
|
vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
|
|
vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
|
|
vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
|
|
vpmull.p64 $t0,$H2,$I2 @ H^2·Ii+2
|
|
veor $j2,$j2,$I2
|
|
vpmull2.p64 $I2,$H2,$I2
|
|
veor $Xl,$Xm,$t2
|
|
vpmull2.p64 $j2,$Hhl,$j2
|
|
|
|
veor $Yl,$Yl,$t0
|
|
veor $Yh,$Yh,$I2
|
|
veor $Ym,$Ym,$j2
|
|
|
|
vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
|
|
vpmull.p64 $Xl,$Xl,$xC2
|
|
vpmull.p64 $j3,$H3,$I1 @ H^3·Ii+1
|
|
veor $j1,$j1,$I1
|
|
veor $t2,$t2,$Xh
|
|
vpmull2.p64 $I1,$H3,$I1
|
|
vpmull.p64 $j1,$H34,$j1
|
|
|
|
veor $Xl,$Xl,$t2
|
|
veor $Yl,$Yl,$j3
|
|
veor $Yh,$Yh,$I1
|
|
vext.8 $Xl,$Xl,$Xl,#8
|
|
veor $Ym,$Ym,$j1
|
|
|
|
subs $len,$len,#64
|
|
b.hs .Loop4x
|
|
|
|
.Ltail4x:
|
|
veor $t0,$I0,$Xl
|
|
vext.8 $IN,$t0,$t0,#8
|
|
|
|
vpmull.p64 $Xl,$H4,$IN @ H^4·(Xi+Ii)
|
|
veor $t0,$t0,$IN
|
|
vpmull2.p64 $Xh,$H4,$IN
|
|
vpmull2.p64 $Xm,$H34,$t0
|
|
|
|
veor $Xl,$Xl,$Yl
|
|
veor $Xh,$Xh,$Yh
|
|
veor $Xm,$Xm,$Ym
|
|
|
|
adds $len,$len,#64
|
|
b.eq .Ldone4x
|
|
|
|
cmp $len,#32
|
|
b.lo .Lone
|
|
b.eq .Ltwo
|
|
.Lthree:
|
|
vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
|
|
veor $t2,$Xl,$Xh
|
|
veor $Xm,$Xm,$t1
|
|
vld1.64 {$I0-$j2},[$inp]
|
|
veor $Xm,$Xm,$t2
|
|
#ifndef __ARMEB__
|
|
vrev64.8 $j1,$j1
|
|
vrev64.8 $j2,$j2
|
|
vrev64.8 $I0,$I0
|
|
#endif
|
|
|
|
vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
|
|
vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
|
|
vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
|
|
vext.8 $I2,$j2,$j2,#8
|
|
vext.8 $I1,$j1,$j1,#8
|
|
veor $Xl,$Xm,$t2
|
|
|
|
vpmull.p64 $Yl,$H,$I2 @ H·Ii+2
|
|
veor $j2,$j2,$I2
|
|
|
|
vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
|
|
vpmull.p64 $Xl,$Xl,$xC2
|
|
veor $t2,$t2,$Xh
|
|
vpmull2.p64 $Yh,$H,$I2
|
|
vpmull.p64 $Ym,$Hhl,$j2
|
|
veor $Xl,$Xl,$t2
|
|
vpmull.p64 $j3,$H2,$I1 @ H^2·Ii+1
|
|
veor $j1,$j1,$I1
|
|
vext.8 $Xl,$Xl,$Xl,#8
|
|
|
|
vpmull2.p64 $I1,$H2,$I1
|
|
veor $t0,$I0,$Xl
|
|
vpmull2.p64 $j1,$Hhl,$j1
|
|
vext.8 $IN,$t0,$t0,#8
|
|
|
|
veor $Yl,$Yl,$j3
|
|
veor $Yh,$Yh,$I1
|
|
veor $Ym,$Ym,$j1
|
|
|
|
vpmull.p64 $Xl,$H3,$IN @ H^3·(Xi+Ii)
|
|
veor $t0,$t0,$IN
|
|
vpmull2.p64 $Xh,$H3,$IN
|
|
vpmull.p64 $Xm,$H34,$t0
|
|
|
|
veor $Xl,$Xl,$Yl
|
|
veor $Xh,$Xh,$Yh
|
|
veor $Xm,$Xm,$Ym
|
|
b .Ldone4x
|
|
|
|
.align 4
|
|
.Ltwo:
|
|
vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
|
|
veor $t2,$Xl,$Xh
|
|
veor $Xm,$Xm,$t1
|
|
vld1.64 {$I0-$j1},[$inp]
|
|
veor $Xm,$Xm,$t2
|
|
#ifndef __ARMEB__
|
|
vrev64.8 $j1,$j1
|
|
vrev64.8 $I0,$I0
|
|
#endif
|
|
|
|
vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
|
|
vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
|
|
vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
|
|
vext.8 $I1,$j1,$j1,#8
|
|
veor $Xl,$Xm,$t2
|
|
|
|
vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
|
|
vpmull.p64 $Xl,$Xl,$xC2
|
|
veor $t2,$t2,$Xh
|
|
veor $Xl,$Xl,$t2
|
|
vext.8 $Xl,$Xl,$Xl,#8
|
|
|
|
vpmull.p64 $Yl,$H,$I1 @ H·Ii+1
|
|
veor $j1,$j1,$I1
|
|
|
|
veor $t0,$I0,$Xl
|
|
vext.8 $IN,$t0,$t0,#8
|
|
|
|
vpmull2.p64 $Yh,$H,$I1
|
|
vpmull.p64 $Ym,$Hhl,$j1
|
|
|
|
vpmull.p64 $Xl,$H2,$IN @ H^2·(Xi+Ii)
|
|
veor $t0,$t0,$IN
|
|
vpmull2.p64 $Xh,$H2,$IN
|
|
vpmull2.p64 $Xm,$Hhl,$t0
|
|
|
|
veor $Xl,$Xl,$Yl
|
|
veor $Xh,$Xh,$Yh
|
|
veor $Xm,$Xm,$Ym
|
|
b .Ldone4x
|
|
|
|
.align 4
|
|
.Lone:
|
|
vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
|
|
veor $t2,$Xl,$Xh
|
|
veor $Xm,$Xm,$t1
|
|
vld1.64 {$I0},[$inp]
|
|
veor $Xm,$Xm,$t2
|
|
#ifndef __ARMEB__
|
|
vrev64.8 $I0,$I0
|
|
#endif
|
|
|
|
vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
|
|
vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
|
|
vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
|
|
veor $Xl,$Xm,$t2
|
|
|
|
vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
|
|
vpmull.p64 $Xl,$Xl,$xC2
|
|
veor $t2,$t2,$Xh
|
|
veor $Xl,$Xl,$t2
|
|
vext.8 $Xl,$Xl,$Xl,#8
|
|
|
|
veor $t0,$I0,$Xl
|
|
vext.8 $IN,$t0,$t0,#8
|
|
|
|
vpmull.p64 $Xl,$H,$IN
|
|
veor $t0,$t0,$IN
|
|
vpmull2.p64 $Xh,$H,$IN
|
|
vpmull.p64 $Xm,$Hhl,$t0
|
|
|
|
.Ldone4x:
|
|
vext.8 $t1,$Xl,$Xh,#8 @ Karatsuba post-processing
|
|
veor $t2,$Xl,$Xh
|
|
veor $Xm,$Xm,$t1
|
|
veor $Xm,$Xm,$t2
|
|
|
|
vpmull.p64 $t2,$Xl,$xC2 @ 1st phase of reduction
|
|
vmov $Xh#lo,$Xm#hi @ Xh|Xm - 256-bit result
|
|
vmov $Xm#hi,$Xl#lo @ Xm is rotated Xl
|
|
veor $Xl,$Xm,$t2
|
|
|
|
vext.8 $t2,$Xl,$Xl,#8 @ 2nd phase of reduction
|
|
vpmull.p64 $Xl,$Xl,$xC2
|
|
veor $t2,$t2,$Xh
|
|
veor $Xl,$Xl,$t2
|
|
vext.8 $Xl,$Xl,$Xl,#8
|
|
|
|
#ifndef __ARMEB__
|
|
vrev64.8 $Xl,$Xl
|
|
#endif
|
|
vst1.64 {$Xl},[$Xi] @ write out Xi
|
|
|
|
ret
|
|
.size gcm_ghash_v8_4x,.-gcm_ghash_v8_4x
|
|
___
|
|
|
|
}
|
|
}
|
|
|
|
$code.=<<___;
|
|
.asciz "GHASH for ARMv8, CRYPTOGAMS by <appro\@openssl.org>"
|
|
.align 2
|
|
#endif
|
|
___
|
|
|
|
if ($flavour =~ /64/) { ######## 64-bit code
|
|
sub unvmov {
|
|
my $arg=shift;
|
|
|
|
$arg =~ m/q([0-9]+)#(lo|hi),\s*q([0-9]+)#(lo|hi)/o &&
|
|
sprintf "ins v%d.d[%d],v%d.d[%d]",$1<8?$1:$1+8,($2 eq "lo")?0:1,
|
|
$3<8?$3:$3+8,($4 eq "lo")?0:1;
|
|
}
|
|
foreach(split("\n",$code)) {
|
|
s/cclr\s+([wx])([^,]+),\s*([a-z]+)/csel $1$2,$1zr,$1$2,$3/o or
|
|
s/vmov\.i8/movi/o or # fix up legacy mnemonics
|
|
s/vmov\s+(.*)/unvmov($1)/geo or
|
|
s/vext\.8/ext/o or
|
|
s/vshr\.s/sshr\.s/o or
|
|
s/vshr/ushr/o or
|
|
s/^(\s+)v/$1/o or # strip off v prefix
|
|
s/\bbx\s+lr\b/ret/o;
|
|
|
|
s/\bq([0-9]+)\b/"v".($1<8?$1:$1+8).".16b"/geo; # old->new registers
|
|
s/@\s/\/\//o; # old->new style commentary
|
|
|
|
# fix up remaining legacy suffixes
|
|
s/\.[ui]?8(\s)/$1/o;
|
|
s/\.[uis]?32//o and s/\.16b/\.4s/go;
|
|
m/\.p64/o and s/\.16b/\.1q/o; # 1st pmull argument
|
|
m/l\.p64/o and s/\.16b/\.1d/go; # 2nd and 3rd pmull arguments
|
|
s/\.[uisp]?64//o and s/\.16b/\.2d/go;
|
|
s/\.[42]([sd])\[([0-3])\]/\.$1\[$2\]/o;
|
|
|
|
print $_,"\n";
|
|
}
|
|
} else { ######## 32-bit code
|
|
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),$3&1;
|
|
}
|
|
sub unvpmullp64 {
|
|
my ($mnemonic,$arg)=@_;
|
|
|
|
if ($arg =~ m/q([0-9]+),\s*q([0-9]+),\s*q([0-9]+)/o) {
|
|
my $word = 0xf2a00e00|(($1&7)<<13)|(($1&8)<<19)
|
|
|(($2&7)<<17)|(($2&8)<<4)
|
|
|(($3&7)<<1) |(($3&8)<<2);
|
|
$word |= 0x00010001 if ($mnemonic =~ "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;
|
|
}
|
|
}
|
|
|
|
foreach(split("\n",$code)) {
|
|
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 remaining new-style suffixes
|
|
s/\],#[0-9]+/]!/o;
|
|
|
|
s/cclr\s+([^,]+),\s*([a-z]+)/mov$2 $1,#0/o or
|
|
s/vdup\.32\s+(.*)/unvdup32($1)/geo or
|
|
s/v?(pmull2?)\.p64\s+(.*)/unvpmullp64($1,$2)/geo or
|
|
s/\bq([0-9]+)#(lo|hi)/sprintf "d%d",2*$1+($2 eq "hi")/geo or
|
|
s/^(\s+)b\./$1b/o or
|
|
s/^(\s+)ret/$1bx\tlr/o;
|
|
|
|
print $_,"\n";
|
|
}
|
|
}
|
|
|
|
close STDOUT or die "error closing STDOUT: $!"; # enforce flush
|