552 lines
16 KiB
Raku
Executable File
552 lines
16 KiB
Raku
Executable File
#!/usr/bin/env perl
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# Copyright 2017-2020 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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# Keccak-1600 for AVX-512F.
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#
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# July 2017.
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#
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# Below code is KECCAK_1X_ALT implementation (see sha/keccak1600.c).
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# Pretty straightforward, the only "magic" is data layout in registers.
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# It's impossible to have one that is optimal for every step, hence
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# it's changing as algorithm progresses. Data is saved in linear order,
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# but in-register order morphs between rounds. Even rounds take in
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# linear layout, and odd rounds - transposed, or "verticaly-shaped"...
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#
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########################################################################
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# Numbers are cycles per processed byte out of large message.
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#
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# r=1088(*)
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#
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# Knights Landing 7.6
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# Skylake-X 5.7
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#
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# (*) Corresponds to SHA3-256.
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########################################################################
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# Below code is combination of two ideas. One is taken from Keccak Code
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# Package, hereafter KCP, and another one from initial version of this
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# module. What is common is observation that Pi's input and output are
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# "mostly transposed", i.e. if input is aligned by x coordinate, then
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# output is [mostly] aligned by y. Both versions, KCP and predecessor,
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# were trying to use one of them from round to round, which resulted in
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# some kind of transposition in each round. This version still does
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# transpose data, but only every second round. Another essential factor
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# is that KCP transposition has to be performed with instructions that
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# turned to be rather expensive on Knights Landing, both latency- and
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# throughput-wise. Not to mention that some of them have to depend on
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# each other. On the other hand initial version of this module was
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# relying heavily on blend instructions. There were lots of them,
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# resulting in higher instruction count, yet it performed better on
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# Knights Landing, because processor can execute pair of them each
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# cycle and they have minimal latency. This module is an attempt to
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# bring best parts together:-)
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#
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# Coordinates below correspond to those in sha/keccak1600.c. Input
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# layout is straight linear:
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#
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# [0][4] [0][3] [0][2] [0][1] [0][0]
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# [1][4] [1][3] [1][2] [1][1] [1][0]
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# [2][4] [2][3] [2][2] [2][1] [2][0]
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# [3][4] [3][3] [3][2] [3][1] [3][0]
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# [4][4] [4][3] [4][2] [4][1] [4][0]
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#
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# It's perfect for Theta, while Pi is reduced to intra-register
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# permutations which yield layout perfect for Chi:
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#
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# [4][0] [3][0] [2][0] [1][0] [0][0]
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# [4][1] [3][1] [2][1] [1][1] [0][1]
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# [4][2] [3][2] [2][2] [1][2] [0][2]
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# [4][3] [3][3] [2][3] [1][3] [0][3]
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# [4][4] [3][4] [2][4] [1][4] [0][4]
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#
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# Now instead of performing full transposition and feeding it to next
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# identical round, we perform kind of diagonal transposition to layout
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# from initial version of this module, and make it suitable for Theta:
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#
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# [4][4] [3][3] [2][2] [1][1] [0][0]>4.3.2.1.0>[4][4] [3][3] [2][2] [1][1] [0][0]
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# [4][0] [3][4] [2][3] [1][2] [0][1]>3.2.1.0.4>[3][4] [2][3] [1][2] [0][1] [4][0]
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# [4][1] [3][0] [2][4] [1][3] [0][2]>2.1.0.4.3>[2][4] [1][3] [0][2] [4][1] [3][0]
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# [4][2] [3][1] [2][0] [1][4] [0][3]>1.0.4.3.2>[1][4] [0][3] [4][2] [3][1] [2][0]
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# [4][3] [3][2] [2][1] [1][0] [0][4]>0.4.3.2.1>[0][4] [4][3] [3][2] [2][1] [1][0]
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#
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# Now intra-register permutations yield initial [almost] straight
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# linear layout:
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#
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# [4][4] [3][3] [2][2] [1][1] [0][0]
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##[0][4] [0][3] [0][2] [0][1] [0][0]
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# [3][4] [2][3] [1][2] [0][1] [4][0]
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##[2][3] [2][2] [2][1] [2][0] [2][4]
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# [2][4] [1][3] [0][2] [4][1] [3][0]
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##[4][2] [4][1] [4][0] [4][4] [4][3]
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# [1][4] [0][3] [4][2] [3][1] [2][0]
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##[1][1] [1][0] [1][4] [1][3] [1][2]
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# [0][4] [4][3] [3][2] [2][1] [1][0]
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##[3][0] [3][4] [3][3] [3][2] [3][1]
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#
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# This means that odd round Chi is performed in less suitable layout,
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# with a number of additional permutations. But overall it turned to be
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# a win. Permutations are fastest possible on Knights Landing and they
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# are laid down to be independent of each other. In the essence I traded
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# 20 blend instructions for 3 permutations. The result is 13% faster
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# than KCP on Skylake-X, and >40% on Knights Landing.
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#
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# As implied, data is loaded in straight linear order. Digits in
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# variables' names represent coordinates of right-most element of
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# loaded data chunk:
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my ($A00, # [0][4] [0][3] [0][2] [0][1] [0][0]
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$A10, # [1][4] [1][3] [1][2] [1][1] [1][0]
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$A20, # [2][4] [2][3] [2][2] [2][1] [2][0]
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$A30, # [3][4] [3][3] [3][2] [3][1] [3][0]
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$A40) = # [4][4] [4][3] [4][2] [4][1] [4][0]
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map("%zmm$_",(0..4));
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# We also need to map the magic order into offsets within structure:
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my @A_jagged = ([0,0], [0,1], [0,2], [0,3], [0,4],
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[1,0], [1,1], [1,2], [1,3], [1,4],
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[2,0], [2,1], [2,2], [2,3], [2,4],
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[3,0], [3,1], [3,2], [3,3], [3,4],
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[4,0], [4,1], [4,2], [4,3], [4,4]);
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@A_jagged = map(8*($$_[0]*8+$$_[1]), @A_jagged); # ... and now linear
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my @T = map("%zmm$_",(5..12));
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my @Theta = map("%zmm$_",(33,13..16)); # invalid @Theta[0] is not typo
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my @Pi0 = map("%zmm$_",(17..21));
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my @Rhotate0 = map("%zmm$_",(22..26));
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my @Rhotate1 = map("%zmm$_",(27..31));
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my ($C00,$D00) = @T[0..1];
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my ($k00001,$k00010,$k00100,$k01000,$k10000,$k11111) = map("%k$_",(1..6));
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$code.=<<___;
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.text
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.type __KeccakF1600,\@function
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.align 32
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__KeccakF1600:
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lea iotas(%rip),%r10
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mov \$12,%eax
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jmp .Loop_avx512
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.align 32
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.Loop_avx512:
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######################################### Theta, even round
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vmovdqa64 $A00,@T[0] # put aside original A00
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vpternlogq \$0x96,$A20,$A10,$A00 # and use it as "C00"
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vpternlogq \$0x96,$A40,$A30,$A00
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vprolq \$1,$A00,$D00
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vpermq $A00,@Theta[1],$A00
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vpermq $D00,@Theta[4],$D00
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vpternlogq \$0x96,$A00,$D00,@T[0] # T[0] is original A00
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vpternlogq \$0x96,$A00,$D00,$A10
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vpternlogq \$0x96,$A00,$D00,$A20
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vpternlogq \$0x96,$A00,$D00,$A30
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vpternlogq \$0x96,$A00,$D00,$A40
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######################################### Rho
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vprolvq @Rhotate0[0],@T[0],$A00 # T[0] is original A00
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vprolvq @Rhotate0[1],$A10,$A10
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vprolvq @Rhotate0[2],$A20,$A20
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vprolvq @Rhotate0[3],$A30,$A30
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vprolvq @Rhotate0[4],$A40,$A40
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######################################### Pi
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vpermq $A00,@Pi0[0],$A00
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vpermq $A10,@Pi0[1],$A10
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vpermq $A20,@Pi0[2],$A20
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vpermq $A30,@Pi0[3],$A30
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vpermq $A40,@Pi0[4],$A40
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######################################### Chi
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vmovdqa64 $A00,@T[0]
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vmovdqa64 $A10,@T[1]
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vpternlogq \$0xD2,$A20,$A10,$A00
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vpternlogq \$0xD2,$A30,$A20,$A10
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vpternlogq \$0xD2,$A40,$A30,$A20
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vpternlogq \$0xD2,@T[0],$A40,$A30
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vpternlogq \$0xD2,@T[1],@T[0],$A40
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######################################### Iota
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vpxorq (%r10),$A00,${A00}{$k00001}
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lea 16(%r10),%r10
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######################################### Harmonize rounds
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vpblendmq $A20,$A10,@{T[1]}{$k00010}
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vpblendmq $A30,$A20,@{T[2]}{$k00010}
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vpblendmq $A40,$A30,@{T[3]}{$k00010}
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vpblendmq $A10,$A00,@{T[0]}{$k00010}
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vpblendmq $A00,$A40,@{T[4]}{$k00010}
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vpblendmq $A30,@T[1],@{T[1]}{$k00100}
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vpblendmq $A40,@T[2],@{T[2]}{$k00100}
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vpblendmq $A20,@T[0],@{T[0]}{$k00100}
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vpblendmq $A00,@T[3],@{T[3]}{$k00100}
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vpblendmq $A10,@T[4],@{T[4]}{$k00100}
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vpblendmq $A40,@T[1],@{T[1]}{$k01000}
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vpblendmq $A30,@T[0],@{T[0]}{$k01000}
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vpblendmq $A00,@T[2],@{T[2]}{$k01000}
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vpblendmq $A10,@T[3],@{T[3]}{$k01000}
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vpblendmq $A20,@T[4],@{T[4]}{$k01000}
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vpblendmq $A40,@T[0],@{T[0]}{$k10000}
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vpblendmq $A00,@T[1],@{T[1]}{$k10000}
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vpblendmq $A10,@T[2],@{T[2]}{$k10000}
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vpblendmq $A20,@T[3],@{T[3]}{$k10000}
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vpblendmq $A30,@T[4],@{T[4]}{$k10000}
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#vpermq @T[0],@Theta[0],$A00 # doesn't actually change order
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vpermq @T[1],@Theta[1],$A10
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vpermq @T[2],@Theta[2],$A20
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vpermq @T[3],@Theta[3],$A30
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vpermq @T[4],@Theta[4],$A40
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######################################### Theta, odd round
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vmovdqa64 $T[0],$A00 # real A00
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vpternlogq \$0x96,$A20,$A10,$C00 # C00 is @T[0]'s alias
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vpternlogq \$0x96,$A40,$A30,$C00
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vprolq \$1,$C00,$D00
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vpermq $C00,@Theta[1],$C00
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vpermq $D00,@Theta[4],$D00
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vpternlogq \$0x96,$C00,$D00,$A00
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vpternlogq \$0x96,$C00,$D00,$A30
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vpternlogq \$0x96,$C00,$D00,$A10
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vpternlogq \$0x96,$C00,$D00,$A40
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vpternlogq \$0x96,$C00,$D00,$A20
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######################################### Rho
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vprolvq @Rhotate1[0],$A00,$A00
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vprolvq @Rhotate1[3],$A30,@T[1]
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vprolvq @Rhotate1[1],$A10,@T[2]
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vprolvq @Rhotate1[4],$A40,@T[3]
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vprolvq @Rhotate1[2],$A20,@T[4]
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vpermq $A00,@Theta[4],@T[5]
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vpermq $A00,@Theta[3],@T[6]
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######################################### Iota
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vpxorq -8(%r10),$A00,${A00}{$k00001}
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######################################### Pi
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vpermq @T[1],@Theta[2],$A10
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vpermq @T[2],@Theta[4],$A20
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vpermq @T[3],@Theta[1],$A30
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vpermq @T[4],@Theta[3],$A40
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######################################### Chi
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vpternlogq \$0xD2,@T[6],@T[5],$A00
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vpermq @T[1],@Theta[1],@T[7]
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#vpermq @T[1],@Theta[0],@T[1]
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vpternlogq \$0xD2,@T[1],@T[7],$A10
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vpermq @T[2],@Theta[3],@T[0]
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vpermq @T[2],@Theta[2],@T[2]
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vpternlogq \$0xD2,@T[2],@T[0],$A20
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#vpermq @T[3],@Theta[0],@T[3]
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vpermq @T[3],@Theta[4],@T[1]
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vpternlogq \$0xD2,@T[1],@T[3],$A30
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vpermq @T[4],@Theta[2],@T[0]
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vpermq @T[4],@Theta[1],@T[4]
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vpternlogq \$0xD2,@T[4],@T[0],$A40
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dec %eax
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jnz .Loop_avx512
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ret
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.size __KeccakF1600,.-__KeccakF1600
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___
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my ($A_flat,$inp,$len,$bsz) = ("%rdi","%rsi","%rdx","%rcx");
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my $out = $inp; # in squeeze
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$code.=<<___;
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.globl SHA3_absorb
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.type SHA3_absorb,\@function
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.align 32
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SHA3_absorb:
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mov %rsp,%r11
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lea -320(%rsp),%rsp
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and \$-64,%rsp
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lea 96($A_flat),$A_flat
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lea 96($inp),$inp
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lea 128(%rsp),%r9
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lea theta_perm(%rip),%r8
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kxnorw $k11111,$k11111,$k11111
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kshiftrw \$15,$k11111,$k00001
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kshiftrw \$11,$k11111,$k11111
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kshiftlw \$1,$k00001,$k00010
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kshiftlw \$2,$k00001,$k00100
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kshiftlw \$3,$k00001,$k01000
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kshiftlw \$4,$k00001,$k10000
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#vmovdqa64 64*0(%r8),@Theta[0]
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vmovdqa64 64*1(%r8),@Theta[1]
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vmovdqa64 64*2(%r8),@Theta[2]
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vmovdqa64 64*3(%r8),@Theta[3]
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vmovdqa64 64*4(%r8),@Theta[4]
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vmovdqa64 64*5(%r8),@Rhotate1[0]
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vmovdqa64 64*6(%r8),@Rhotate1[1]
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vmovdqa64 64*7(%r8),@Rhotate1[2]
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vmovdqa64 64*8(%r8),@Rhotate1[3]
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vmovdqa64 64*9(%r8),@Rhotate1[4]
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vmovdqa64 64*10(%r8),@Rhotate0[0]
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vmovdqa64 64*11(%r8),@Rhotate0[1]
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vmovdqa64 64*12(%r8),@Rhotate0[2]
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vmovdqa64 64*13(%r8),@Rhotate0[3]
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vmovdqa64 64*14(%r8),@Rhotate0[4]
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vmovdqa64 64*15(%r8),@Pi0[0]
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vmovdqa64 64*16(%r8),@Pi0[1]
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vmovdqa64 64*17(%r8),@Pi0[2]
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vmovdqa64 64*18(%r8),@Pi0[3]
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vmovdqa64 64*19(%r8),@Pi0[4]
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vmovdqu64 40*0-96($A_flat),${A00}{$k11111}{z}
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vpxorq @T[0],@T[0],@T[0]
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vmovdqu64 40*1-96($A_flat),${A10}{$k11111}{z}
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vmovdqu64 40*2-96($A_flat),${A20}{$k11111}{z}
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vmovdqu64 40*3-96($A_flat),${A30}{$k11111}{z}
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vmovdqu64 40*4-96($A_flat),${A40}{$k11111}{z}
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vmovdqa64 @T[0],0*64-128(%r9) # zero transfer area on stack
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vmovdqa64 @T[0],1*64-128(%r9)
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vmovdqa64 @T[0],2*64-128(%r9)
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vmovdqa64 @T[0],3*64-128(%r9)
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vmovdqa64 @T[0],4*64-128(%r9)
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jmp .Loop_absorb_avx512
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.align 32
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.Loop_absorb_avx512:
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mov $bsz,%rax
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sub $bsz,$len
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jc .Ldone_absorb_avx512
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shr \$3,%eax
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___
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for(my $i=0; $i<25; $i++) {
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$code.=<<___
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mov 8*$i-96($inp),%r8
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mov %r8,$A_jagged[$i]-128(%r9)
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dec %eax
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jz .Labsorved_avx512
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___
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}
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$code.=<<___;
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.Labsorved_avx512:
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lea ($inp,$bsz),$inp
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vpxorq 64*0-128(%r9),$A00,$A00
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vpxorq 64*1-128(%r9),$A10,$A10
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vpxorq 64*2-128(%r9),$A20,$A20
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vpxorq 64*3-128(%r9),$A30,$A30
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vpxorq 64*4-128(%r9),$A40,$A40
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call __KeccakF1600
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jmp .Loop_absorb_avx512
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.align 32
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.Ldone_absorb_avx512:
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vmovdqu64 $A00,40*0-96($A_flat){$k11111}
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vmovdqu64 $A10,40*1-96($A_flat){$k11111}
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vmovdqu64 $A20,40*2-96($A_flat){$k11111}
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vmovdqu64 $A30,40*3-96($A_flat){$k11111}
|
|
vmovdqu64 $A40,40*4-96($A_flat){$k11111}
|
|
|
|
vzeroupper
|
|
|
|
lea (%r11),%rsp
|
|
lea ($len,$bsz),%rax # return value
|
|
ret
|
|
.size SHA3_absorb,.-SHA3_absorb
|
|
|
|
.globl SHA3_squeeze
|
|
.type SHA3_squeeze,\@function
|
|
.align 32
|
|
SHA3_squeeze:
|
|
mov %rsp,%r11
|
|
|
|
lea 96($A_flat),$A_flat
|
|
cmp $bsz,$len
|
|
jbe .Lno_output_extension_avx512
|
|
|
|
lea theta_perm(%rip),%r8
|
|
|
|
kxnorw $k11111,$k11111,$k11111
|
|
kshiftrw \$15,$k11111,$k00001
|
|
kshiftrw \$11,$k11111,$k11111
|
|
kshiftlw \$1,$k00001,$k00010
|
|
kshiftlw \$2,$k00001,$k00100
|
|
kshiftlw \$3,$k00001,$k01000
|
|
kshiftlw \$4,$k00001,$k10000
|
|
|
|
#vmovdqa64 64*0(%r8),@Theta[0]
|
|
vmovdqa64 64*1(%r8),@Theta[1]
|
|
vmovdqa64 64*2(%r8),@Theta[2]
|
|
vmovdqa64 64*3(%r8),@Theta[3]
|
|
vmovdqa64 64*4(%r8),@Theta[4]
|
|
|
|
vmovdqa64 64*5(%r8),@Rhotate1[0]
|
|
vmovdqa64 64*6(%r8),@Rhotate1[1]
|
|
vmovdqa64 64*7(%r8),@Rhotate1[2]
|
|
vmovdqa64 64*8(%r8),@Rhotate1[3]
|
|
vmovdqa64 64*9(%r8),@Rhotate1[4]
|
|
|
|
vmovdqa64 64*10(%r8),@Rhotate0[0]
|
|
vmovdqa64 64*11(%r8),@Rhotate0[1]
|
|
vmovdqa64 64*12(%r8),@Rhotate0[2]
|
|
vmovdqa64 64*13(%r8),@Rhotate0[3]
|
|
vmovdqa64 64*14(%r8),@Rhotate0[4]
|
|
|
|
vmovdqa64 64*15(%r8),@Pi0[0]
|
|
vmovdqa64 64*16(%r8),@Pi0[1]
|
|
vmovdqa64 64*17(%r8),@Pi0[2]
|
|
vmovdqa64 64*18(%r8),@Pi0[3]
|
|
vmovdqa64 64*19(%r8),@Pi0[4]
|
|
|
|
vmovdqu64 40*0-96($A_flat),${A00}{$k11111}{z}
|
|
vmovdqu64 40*1-96($A_flat),${A10}{$k11111}{z}
|
|
vmovdqu64 40*2-96($A_flat),${A20}{$k11111}{z}
|
|
vmovdqu64 40*3-96($A_flat),${A30}{$k11111}{z}
|
|
vmovdqu64 40*4-96($A_flat),${A40}{$k11111}{z}
|
|
|
|
.Lno_output_extension_avx512:
|
|
shr \$3,$bsz
|
|
lea -96($A_flat),%r9
|
|
mov $bsz,%rax
|
|
jmp .Loop_squeeze_avx512
|
|
|
|
.align 32
|
|
.Loop_squeeze_avx512:
|
|
cmp \$8,$len
|
|
jb .Ltail_squeeze_avx512
|
|
|
|
mov (%r9),%r8
|
|
lea 8(%r9),%r9
|
|
mov %r8,($out)
|
|
lea 8($out),$out
|
|
sub \$8,$len # len -= 8
|
|
jz .Ldone_squeeze_avx512
|
|
|
|
sub \$1,%rax # bsz--
|
|
jnz .Loop_squeeze_avx512
|
|
|
|
#vpermq @Theta[4],@Theta[4],@Theta[3]
|
|
#vpermq @Theta[3],@Theta[4],@Theta[2]
|
|
#vpermq @Theta[3],@Theta[3],@Theta[1]
|
|
|
|
call __KeccakF1600
|
|
|
|
vmovdqu64 $A00,40*0-96($A_flat){$k11111}
|
|
vmovdqu64 $A10,40*1-96($A_flat){$k11111}
|
|
vmovdqu64 $A20,40*2-96($A_flat){$k11111}
|
|
vmovdqu64 $A30,40*3-96($A_flat){$k11111}
|
|
vmovdqu64 $A40,40*4-96($A_flat){$k11111}
|
|
|
|
lea -96($A_flat),%r9
|
|
mov $bsz,%rax
|
|
jmp .Loop_squeeze_avx512
|
|
|
|
.Ltail_squeeze_avx512:
|
|
mov $out,%rdi
|
|
mov %r9,%rsi
|
|
mov $len,%rcx
|
|
.byte 0xf3,0xa4 # rep movsb
|
|
|
|
.Ldone_squeeze_avx512:
|
|
vzeroupper
|
|
|
|
lea (%r11),%rsp
|
|
ret
|
|
.size SHA3_squeeze,.-SHA3_squeeze
|
|
|
|
.align 64
|
|
theta_perm:
|
|
.quad 0, 1, 2, 3, 4, 5, 6, 7 # [not used]
|
|
.quad 4, 0, 1, 2, 3, 5, 6, 7
|
|
.quad 3, 4, 0, 1, 2, 5, 6, 7
|
|
.quad 2, 3, 4, 0, 1, 5, 6, 7
|
|
.quad 1, 2, 3, 4, 0, 5, 6, 7
|
|
|
|
rhotates1:
|
|
.quad 0, 44, 43, 21, 14, 0, 0, 0 # [0][0] [1][1] [2][2] [3][3] [4][4]
|
|
.quad 18, 1, 6, 25, 8, 0, 0, 0 # [4][0] [0][1] [1][2] [2][3] [3][4]
|
|
.quad 41, 2, 62, 55, 39, 0, 0, 0 # [3][0] [4][1] [0][2] [1][3] [2][4]
|
|
.quad 3, 45, 61, 28, 20, 0, 0, 0 # [2][0] [3][1] [4][2] [0][3] [1][4]
|
|
.quad 36, 10, 15, 56, 27, 0, 0, 0 # [1][0] [2][1] [3][2] [4][3] [0][4]
|
|
|
|
rhotates0:
|
|
.quad 0, 1, 62, 28, 27, 0, 0, 0
|
|
.quad 36, 44, 6, 55, 20, 0, 0, 0
|
|
.quad 3, 10, 43, 25, 39, 0, 0, 0
|
|
.quad 41, 45, 15, 21, 8, 0, 0, 0
|
|
.quad 18, 2, 61, 56, 14, 0, 0, 0
|
|
|
|
pi0_perm:
|
|
.quad 0, 3, 1, 4, 2, 5, 6, 7
|
|
.quad 1, 4, 2, 0, 3, 5, 6, 7
|
|
.quad 2, 0, 3, 1, 4, 5, 6, 7
|
|
.quad 3, 1, 4, 2, 0, 5, 6, 7
|
|
.quad 4, 2, 0, 3, 1, 5, 6, 7
|
|
|
|
|
|
iotas:
|
|
.quad 0x0000000000000001
|
|
.quad 0x0000000000008082
|
|
.quad 0x800000000000808a
|
|
.quad 0x8000000080008000
|
|
.quad 0x000000000000808b
|
|
.quad 0x0000000080000001
|
|
.quad 0x8000000080008081
|
|
.quad 0x8000000000008009
|
|
.quad 0x000000000000008a
|
|
.quad 0x0000000000000088
|
|
.quad 0x0000000080008009
|
|
.quad 0x000000008000000a
|
|
.quad 0x000000008000808b
|
|
.quad 0x800000000000008b
|
|
.quad 0x8000000000008089
|
|
.quad 0x8000000000008003
|
|
.quad 0x8000000000008002
|
|
.quad 0x8000000000000080
|
|
.quad 0x000000000000800a
|
|
.quad 0x800000008000000a
|
|
.quad 0x8000000080008081
|
|
.quad 0x8000000000008080
|
|
.quad 0x0000000080000001
|
|
.quad 0x8000000080008008
|
|
|
|
.asciz "Keccak-1600 absorb and squeeze for AVX-512F, CRYPTOGAMS by <appro\@openssl.org>"
|
|
___
|
|
|
|
$output=pop;
|
|
open STDOUT,">$output";
|
|
print $code;
|
|
close STDOUT or die "error closing STDOUT: $!";
|