#!/usr/bin/env perl # # ==================================================================== # Written by Andy Polyakov for the OpenSSL # project. The module is, however, dual licensed under OpenSSL and # CRYPTOGAMS licenses depending on where you obtain it. For further # details see http://www.openssl.org/~appro/cryptogams/. # ==================================================================== # # Keccak-1600 for AVX512VL. # # December 2017. # # This is an adaptation of AVX2 module that reuses register data # layout, but utilizes new 256-bit AVX512VL instructions. See AVX2 # module for further information on layout. # ######################################################################## # Numbers are cycles per processed byte out of large message. # # r=1088(*) # # Skylake-X 6.4/+47% # Ice Lake 6.4/+34% # Rocket Lake 6.6/+30% # Zen 4 7.0/+8% # # (*) Corresponds to SHA3-256. Percentage after slash is improvement # coefficient in comparison to scalar keccak1600-x86_64.pl. # Digits in variables' names denote right-most coordinates: my ($A00, # [0][0] [0][0] [0][0] [0][0] # %ymm0 $A01, # [0][4] [0][3] [0][2] [0][1] # %ymm1 $A20, # [3][0] [1][0] [4][0] [2][0] # %ymm2 $A31, # [2][4] [4][3] [1][2] [3][1] # %ymm3 $A21, # [3][4] [1][3] [4][2] [2][1] # %ymm4 $A41, # [1][4] [2][3] [3][2] [4][1] # %ymm5 $A11) = # [4][4] [3][3] [2][2] [1][1] # %ymm6 map("%ymm$_",(0..6)); # We also need to map the magic order into offsets within structure: my @A_jagged = ([0,0], [1,0], [1,1], [1,2], [1,3], # [0][0..4] [2,2], [6,0], [3,1], [4,2], [5,3], # [1][0..4] [2,0], [4,0], [6,1], [5,2], [3,3], # [2][0..4] [2,3], [3,0], [5,1], [6,2], [4,3], # [3][0..4] [2,1], [5,0], [4,1], [3,2], [6,3]); # [4][0..4] @A_jagged = map(8*($$_[0]*4+$$_[1]), @A_jagged); # ... and now linear my @T = map("%ymm$_",(7..15)); my ($C14,$C00,$D00,$D14) = @T[5..8]; my ($R20,$R01,$R31,$R21,$R41,$R11) = map("%ymm$_",(16..21)); $code.=<<___; .text .type __KeccakF1600,\@function .align 32 __KeccakF1600: lea iotas(%rip),%r10 mov \$24,%eax jmp .Loop_avx512vl .align 32 .Loop_avx512vl: ######################################### Theta vpshufd \$0b01001110,$A20,$C00 vpxor $A31,$A41,$C14 vpxor $A11,$A21,@T[2] vpternlogq \$0x96,$A01,$T[2],$C14 # C[1..4] vpxor $A20,$C00,$C00 vpermq \$0b01001110,$C00,@T[0] vpermq \$0b10010011,$C14,@T[4] vprolq \$1,$C14,@T[1] # ROL64(C[1..4],1) vpermq \$0b00111001,@T[1],$D14 vpxor @T[4],@T[1],$D00 vpermq \$0b00000000,$D00,$D00 # D[0..0] = ROL64(C[1],1) ^ C[4] vpternlogq \$0x96,@T[0],$A00,$C00 # C[0..0] vprolq \$1,$C00,@T[1] # ROL64(C[0..0],1) vpxor $D00,$A00,$A00 # ^= D[0..0] vpblendd \$0b11000000,@T[1],$D14,$D14 vpblendd \$0b00000011,$C00,@T[4],@T[0] ######################################### Rho + Pi + pre-Chi shuffle vpxor $D00,$A20,$A20 # ^= D[0..0] from Theta vprolvq $R20,$A20,$A20 vpternlogq \$0x96,@T[0],$D14,$A31 # ^= D[1..4] from Theta vprolvq $R31,$A31,$A31 vpternlogq \$0x96,@T[0],$D14,$A21 # ^= D[1..4] from Theta vprolvq $R21,$A21,$A21 vpternlogq \$0x96,@T[0],$D14,$A41 # ^= D[1..4] from Theta vprolvq $R41,$A41,$A41 vpermq \$0b10001101,$A20,@T[3] # $A20 -> future $A31 vpermq \$0b10001101,$A31,@T[4] # $A31 -> future $A21 vpternlogq \$0x96,@T[0],$D14,$A11 # ^= D[1..4] from Theta vprolvq $R11,$A11,@T[1] # $A11 -> future $A01 vpermq \$0b00011011,$A21,@T[5] # $A21 -> future $A41 vpermq \$0b01110010,$A41,@T[6] # $A41 -> future $A11 vpternlogq \$0x96,@T[0],$D14,$A01 # ^= D[1..4] from Theta vprolvq $R01,$A01,@T[2] # $A01 -> future $A20 ######################################### Chi vpblendd \$0b00001100,@T[6],@T[2],$A31 # [4][4] [2][0] vpblendd \$0b00001100,@T[2],@T[4],@T[8] # [4][0] [2][1] vpblendd \$0b00001100,@T[4],@T[3],$A41 # [4][2] [2][4] vpblendd \$0b00001100,@T[3],@T[2],@T[7] # [4][3] [2][0] vpblendd \$0b00110000,@T[4],$A31,$A31 # [1][3] [4][4] [2][0] vpblendd \$0b00110000,@T[5],@T[8],@T[8] # [1][4] [4][0] [2][1] vpblendd \$0b00110000,@T[2],$A41,$A41 # [1][0] [4][2] [2][4] vpblendd \$0b00110000,@T[6],@T[7],@T[7] # [1][1] [4][3] [2][0] vpblendd \$0b11000000,@T[5],$A31,$A31 # [3][2] [1][3] [4][4] [2][0] vpblendd \$0b11000000,@T[6],@T[8],@T[8] # [3][3] [1][4] [4][0] [2][1] vpblendd \$0b11000000,@T[6],$A41,$A41 # [3][3] [1][0] [4][2] [2][4] vpblendd \$0b11000000,@T[4],@T[7],@T[7] # [3][4] [1][1] [4][3] [2][0] vpternlogq \$0xC6,@T[8],@T[3],$A31 # [3][1] [1][2] [4][3] [2][4] vpternlogq \$0xC6,@T[7],@T[5],$A41 # [3][2] [1][4] [4][1] [2][3] vpsrldq \$8,@T[1],@T[0] vpandn @T[0],@T[1],@T[0] # tgting [0][0] [0][0] [0][0] [0][0] vpblendd \$0b00001100,@T[2],@T[5],$A11 # [4][0] [2][3] vpblendd \$0b00001100,@T[5],@T[3],@T[8] # [4][1] [2][4] vpblendd \$0b00110000,@T[3],$A11,$A11 # [1][2] [4][0] [2][3] vpblendd \$0b00110000,@T[4],@T[8],@T[8] # [1][3] [4][1] [2][4] vpblendd \$0b11000000,@T[4],$A11,$A11 # [3][4] [1][2] [4][0] [2][3] vpblendd \$0b11000000,@T[2],@T[8],@T[8] # [3][0] [1][3] [4][1] [2][4] vpternlogq \$0xC6,@T[8],@T[6],$A11 # [3][3] [1][1] [4][4] [2][2] vpermq \$0b00011110,@T[1],$A21 # [0][1] [0][2] [0][4] [0][3] vpblendd \$0b00110000,$A00,$A21,@T[8] # [0][1] [0][0] [0][4] [0][3] vpermq \$0b00111001,@T[1],$A01 # [0][1] [0][4] [0][3] [0][2] vpblendd \$0b11000000,$A00,$A01,$A01 # [0][0] [0][4] [0][3] [0][2] vpblendd \$0b00001100,@T[5],@T[4],$A20 # [4][1] [2][1] vpblendd \$0b00001100,@T[4],@T[6],@T[7] # [4][2] [2][2] vpblendd \$0b00110000,@T[6],$A20,$A20 # [1][1] [4][1] [2][1] vpblendd \$0b00110000,@T[3],@T[7],@T[7] # [1][2] [4][2] [2][2] vpblendd \$0b11000000,@T[3],$A20,$A20 # [3][1] [1][1] [4][1] [2][1] vpblendd \$0b11000000,@T[5],@T[7],@T[7] # [3][2] [1][2] [4][2] [2][2] vpternlogq \$0xC6,@T[7],@T[2],$A20 # [3][0] [1][0] [4][0] [2][0] vpermq \$0b00000000,@T[0],@T[0] # [0][0] [0][0] [0][0] [0][0] vpermq \$0b00011011,$A31,$A31 # post-Chi shuffle vpermq \$0b10001101,$A41,$A41 vpermq \$0b01110010,$A11,$A11 vpblendd \$0b00001100,@T[3],@T[6],$A21 # [4][3] [2][2] vpblendd \$0b00001100,@T[6],@T[5],@T[7] # [4][4] [2][3] vpblendd \$0b00110000,@T[5],$A21,$A21 # [1][4] [4][3] [2][2] vpblendd \$0b00110000,@T[2],@T[7],@T[7] # [1][0] [4][4] [2][3] vpblendd \$0b11000000,@T[2],$A21,$A21 # [3][0] [1][4] [4][3] [2][2] vpblendd \$0b11000000,@T[3],@T[7],@T[7] # [3][1] [1][0] [4][4] [2][3] vpternlogq \$0xC6,@T[8],@T[1],$A01 # [0][4] [0][3] [0][2] [0][1] vpternlogq \$0xC6,@T[7],@T[4],$A21 # [3][4] [1][3] [4][2] [2][1] ######################################### Iota vpternlogq \$0x96,(%r10),@T[0],$A00 lea 32(%r10),%r10 dec %eax jnz .Loop_avx512vl ret .size __KeccakF1600,.-__KeccakF1600 ___ my ($A_flat,$inp,$len,$bsz) = ("%rdi","%rsi","%rdx","%rcx"); my $out = $inp; # in squeeze $code.=<<___; .globl SHA3_absorb .type SHA3_absorb,\@function .align 32 SHA3_absorb: mov %rsp,%r11 lea -240(%rsp),%rsp and \$-32,%rsp lea 96($A_flat),$A_flat lea 96($inp),$inp lea 96(%rsp),%r10 lea rhotates_left(%rip),%r8 vzeroupper vpbroadcastq -96($A_flat),$A00 # load A[5][5] vmovdqu 8+32*0-96($A_flat),$A01 vmovdqu 8+32*1-96($A_flat),$A20 vmovdqu 8+32*2-96($A_flat),$A31 vmovdqu 8+32*3-96($A_flat),$A21 vmovdqu 8+32*4-96($A_flat),$A41 vmovdqu 8+32*5-96($A_flat),$A11 vmovdqa64 0*32(%r8),$R20 # load "rhotate" indices vmovdqa64 1*32(%r8),$R01 vmovdqa64 2*32(%r8),$R31 vmovdqa64 3*32(%r8),$R21 vmovdqa64 4*32(%r8),$R41 vmovdqa64 5*32(%r8),$R11 vpxor @T[0],@T[0],@T[0] vmovdqa @T[0],32*2-96(%r10) # zero transfer area on stack vmovdqa @T[0],32*3-96(%r10) vmovdqa @T[0],32*4-96(%r10) vmovdqa @T[0],32*5-96(%r10) vmovdqa @T[0],32*6-96(%r10) .Loop_absorb_avx512vl: mov $bsz,%rax sub $bsz,$len jc .Ldone_absorb_avx512vl shr \$3,%eax vpbroadcastq 0-96($inp),@T[0] vmovdqu 8-96($inp),@T[1] sub \$4,%eax ___ for(my $i=5; $i<25; $i++) { $code.=<<___ dec %eax jz .Labsorved_avx512vl mov 8*$i-96($inp),%r8 mov %r8,$A_jagged[$i]-96(%r10) ___ } $code.=<<___; .Labsorved_avx512vl: lea ($inp,$bsz),$inp vpxor @T[0],$A00,$A00 vpxor @T[1],$A01,$A01 vpxor 32*2-96(%r10),$A20,$A20 vpxor 32*3-96(%r10),$A31,$A31 vpxor 32*4-96(%r10),$A21,$A21 vpxor 32*5-96(%r10),$A41,$A41 vpxor 32*6-96(%r10),$A11,$A11 call __KeccakF1600 lea 96(%rsp),%r10 jmp .Loop_absorb_avx512vl .Ldone_absorb_avx512vl: vmovq %xmm0,-96($A_flat) vmovdqu $A01,8+32*0-96($A_flat) vmovdqu $A20,8+32*1-96($A_flat) vmovdqu $A31,8+32*2-96($A_flat) vmovdqu $A21,8+32*3-96($A_flat) vmovdqu $A41,8+32*4-96($A_flat) vmovdqu $A11,8+32*5-96($A_flat) 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 lea rhotates_left(%rip),%r8 shr \$3,$bsz vzeroupper vpbroadcastq -96($A_flat),$A00 vpxor @T[0],@T[0],@T[0] vmovdqu 8+32*0-96($A_flat),$A01 vmovdqu 8+32*1-96($A_flat),$A20 vmovdqu 8+32*2-96($A_flat),$A31 vmovdqu 8+32*3-96($A_flat),$A21 vmovdqu 8+32*4-96($A_flat),$A41 vmovdqu 8+32*5-96($A_flat),$A11 vmovdqa64 0*32(%r8),$R20 # load "rhotate" indices vmovdqa64 1*32(%r8),$R01 vmovdqa64 2*32(%r8),$R31 vmovdqa64 3*32(%r8),$R21 vmovdqa64 4*32(%r8),$R41 vmovdqa64 5*32(%r8),$R11 mov $bsz,%rax .Loop_squeeze_avx512vl: mov @A_jagged[$i]-96($A_flat),%r8 ___ for (my $i=0; $i<25; $i++) { $code.=<<___; sub \$8,$len jc .Ltail_squeeze_avx512vl mov %r8,($out) lea 8($out),$out je .Ldone_squeeze_avx512vl dec %eax je .Lextend_output_avx512vl mov @A_jagged[$i+1]-120($A_flat),%r8 ___ } $code.=<<___; .Lextend_output_avx512vl: call __KeccakF1600 vmovq %xmm0,-96($A_flat) vmovdqu $A01,8+32*0-96($A_flat) vmovdqu $A20,8+32*1-96($A_flat) vmovdqu $A31,8+32*2-96($A_flat) vmovdqu $A21,8+32*3-96($A_flat) vmovdqu $A41,8+32*4-96($A_flat) vmovdqu $A11,8+32*5-96($A_flat) mov $bsz,%rax jmp .Loop_squeeze_avx512vl .Ltail_squeeze_avx512vl: add \$8,$len .Loop_tail_avx512vl: mov %r8b,($out) lea 1($out),$out shr \$8,%r8 dec $len jnz .Loop_tail_avx512vl .Ldone_squeeze_avx512vl: vzeroupper lea (%r11),%rsp ret .size SHA3_squeeze,.-SHA3_squeeze .align 64 rhotates_left: .quad 3, 18, 36, 41 # [2][0] [4][0] [1][0] [3][0] .quad 1, 62, 28, 27 # [0][1] [0][2] [0][3] [0][4] .quad 45, 6, 56, 39 # [3][1] [1][2] [4][3] [2][4] .quad 10, 61, 55, 8 # [2][1] [4][2] [1][3] [3][4] .quad 2, 15, 25, 20 # [4][1] [3][2] [2][3] [1][4] .quad 44, 43, 21, 14 # [1][1] [2][2] [3][3] [4][4] iotas: .quad 0x0000000000000001, 0x0000000000000001, 0x0000000000000001, 0x0000000000000001 .quad 0x0000000000008082, 0x0000000000008082, 0x0000000000008082, 0x0000000000008082 .quad 0x800000000000808a, 0x800000000000808a, 0x800000000000808a, 0x800000000000808a .quad 0x8000000080008000, 0x8000000080008000, 0x8000000080008000, 0x8000000080008000 .quad 0x000000000000808b, 0x000000000000808b, 0x000000000000808b, 0x000000000000808b .quad 0x0000000080000001, 0x0000000080000001, 0x0000000080000001, 0x0000000080000001 .quad 0x8000000080008081, 0x8000000080008081, 0x8000000080008081, 0x8000000080008081 .quad 0x8000000000008009, 0x8000000000008009, 0x8000000000008009, 0x8000000000008009 .quad 0x000000000000008a, 0x000000000000008a, 0x000000000000008a, 0x000000000000008a .quad 0x0000000000000088, 0x0000000000000088, 0x0000000000000088, 0x0000000000000088 .quad 0x0000000080008009, 0x0000000080008009, 0x0000000080008009, 0x0000000080008009 .quad 0x000000008000000a, 0x000000008000000a, 0x000000008000000a, 0x000000008000000a .quad 0x000000008000808b, 0x000000008000808b, 0x000000008000808b, 0x000000008000808b .quad 0x800000000000008b, 0x800000000000008b, 0x800000000000008b, 0x800000000000008b .quad 0x8000000000008089, 0x8000000000008089, 0x8000000000008089, 0x8000000000008089 .quad 0x8000000000008003, 0x8000000000008003, 0x8000000000008003, 0x8000000000008003 .quad 0x8000000000008002, 0x8000000000008002, 0x8000000000008002, 0x8000000000008002 .quad 0x8000000000000080, 0x8000000000000080, 0x8000000000000080, 0x8000000000000080 .quad 0x000000000000800a, 0x000000000000800a, 0x000000000000800a, 0x000000000000800a .quad 0x800000008000000a, 0x800000008000000a, 0x800000008000000a, 0x800000008000000a .quad 0x8000000080008081, 0x8000000080008081, 0x8000000080008081, 0x8000000080008081 .quad 0x8000000000008080, 0x8000000000008080, 0x8000000000008080, 0x8000000000008080 .quad 0x0000000080000001, 0x0000000080000001, 0x0000000080000001, 0x0000000080000001 .quad 0x8000000080008008, 0x8000000080008008, 0x8000000080008008, 0x8000000080008008 .asciz "Keccak-1600 absorb and squeeze for AVX512VL, CRYPTOGAMS by " ___ print $code; close STDOUT;