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1aa89a7a3a
They now generally conform to the following argument sequence: script.pl "$(PERLASM_SCHEME)" [ C preprocessor arguments ... ] \ $(PROCESSOR) <output file> However, in the spirit of being able to use these scripts manually, they also allow for no argument, or for only the flavour, or for only the output file. This is done by only using the last argument as output file if it's a file (it has an extension), and only using the first argument as flavour if it isn't a file (it doesn't have an extension). While we're at it, we make all $xlate calls the same, i.e. the $output argument is always quoted, and we always die on error when trying to start $xlate. There's a perl lesson in this, regarding operator priority... This will always succeed, even when it fails: open FOO, "something" || die "ERR: $!"; The reason is that '||' has higher priority than list operators (a function is essentially a list operator and gobbles up everything following it that isn't lower priority), and since a non-empty string is always true, so that ends up being exactly the same as: open FOO, "something"; This, however, will fail if "something" can't be opened: open FOO, "something" or die "ERR: $!"; The reason is that 'or' has lower priority that list operators, i.e. it's performed after the 'open' call. Reviewed-by: Matt Caswell <matt@openssl.org> (Merged from https://github.com/openssl/openssl/pull/9884)
551 lines
16 KiB
Raku
Executable File
551 lines
16 KiB
Raku
Executable File
#!/usr/bin/env perl
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# Copyright 2017-2018 The OpenSSL Project Authors. All Rights Reserved.
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#
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# Licensed under the Apache License 2.0 (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
|
|
___
|
|
}
|
|
$code.=<<___;
|
|
.Labsorved_avx512:
|
|
lea ($inp,$bsz),$inp
|
|
|
|
vpxorq 64*0-128(%r9),$A00,$A00
|
|
vpxorq 64*1-128(%r9),$A10,$A10
|
|
vpxorq 64*2-128(%r9),$A20,$A20
|
|
vpxorq 64*3-128(%r9),$A30,$A30
|
|
vpxorq 64*4-128(%r9),$A40,$A40
|
|
|
|
call __KeccakF1600
|
|
|
|
jmp .Loop_absorb_avx512
|
|
|
|
.align 32
|
|
.Ldone_absorb_avx512:
|
|
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){$k11111}
|
|
|
|
vzeroupper
|
|
|
|
lea (%r11),%rsp
|
|
lea ($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>"
|
|
___
|
|
|
|
$output=pop and open STDOUT,">$output";
|
|
print $code;
|
|
close STDOUT;
|