#!/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/. # ==================================================================== # # This module implements Poly1305 hash for x86_64. # # March 2015 # # Numbers are cycles per processed byte with poly1305_blocks alone, # measured with rdtsc at fixed clock frequency. # # IALU/gcc-4.8(*) AVX(**) AVX2 # P4 4.90/+120% - # Core 2 2.39/+90% - # Westmere 1.86/+120% - # Sandy Bridge 1.39/+140% 1.10 # Haswell 1.10/+175% 1.11 0.65 # Skylake 1.12/+120% 0.96 0.51 # Silvermont 2.83/+95% - # VIA Nano 1.82/+150% - # Sledgehammer 1.38/+160% - # Bulldozer 2.21/+130% 0.97 # # (*) improvement coefficients relative to clang are more modest and # are ~50% on most processors, in both cases we are comparing to # __int128 code; # (**) SSE2 implementation was attempted, but among non-AVX processors # it was faster than integer-only code only on older Intel P4 and # Core processors, 50-30%, less newer processor is, but slower on # contemporary ones, for example almost 2x slower on Atom, and as # former are naturally disappearing, SSE2 is deemed unnecessary; $flavour = shift; $output = shift; if ($flavour =~ /\./) { $output = $flavour; undef $flavour; } $win64=0; $win64=1 if ($flavour =~ /[nm]asm|mingw64/ || $output =~ /\.asm$/); $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1; ( $xlate="${dir}x86_64-xlate.pl" and -f $xlate ) or ( $xlate="${dir}../../perlasm/x86_64-xlate.pl" and -f $xlate) or die "can't locate x86_64-xlate.pl"; if (`$ENV{CC} -Wa,-v -c -o /dev/null -x assembler /dev/null 2>&1` =~ /GNU assembler version ([2-9]\.[0-9]+)/) { $avx = ($1>=2.19) + ($1>=2.22); } if (!$avx && $win64 && ($flavour =~ /nasm/ || $ENV{ASM} =~ /nasm/) && `nasm -v 2>&1` =~ /NASM version ([2-9]\.[0-9]+)/) { $avx = ($1>=2.09) + ($1>=2.10); } if (!$avx && $win64 && ($flavour =~ /masm/ || $ENV{ASM} =~ /ml64/) && `ml64 2>&1` =~ /Version ([0-9]+)\./) { $avx = ($1>=10) + ($1>=12); } if (!$avx && `$ENV{CC} -v 2>&1` =~ /((?:^clang|LLVM) version|.*based on LLVM) ([3-9]\.[0-9]+)/) { $avx = ($2>=3.0) + ($2>3.0); } open OUT,"| \"$^X\" $xlate $flavour $output"; *STDOUT=*OUT; my ($ctx,$inp,$len,$padbit)=("%rdi","%rsi","%rdx","%rcx"); my ($mac,$nonce)=($inp,$len); # *_emit arguments my ($d1,$d2,$d3, $r0,$r1,$s1)=map("%r$_",(8..13)); my ($h0,$h1,$h2)=("%r14","%rbx","%rbp"); sub poly1305_iteration { # input: copy of $r1 in %rax, $h0-$h2, $r0-$r1 # output: $h0-$h2 *= $r0-$r1 $code.=<<___; mulq $h0 # h0*r1 mov %rax,$d2 mov $r0,%rax mov %rdx,$d3 mulq $h0 # h0*r0 mov %rax,$h0 # future $h0 mov $r0,%rax mov %rdx,$d1 mulq $h1 # h1*r0 add %rax,$d2 mov $s1,%rax adc %rdx,$d3 mulq $h1 # h1*s1 mov $h2,$h1 # borrow $h1 add %rax,$h0 adc %rdx,$d1 imulq $s1,$h1 # h2*s1 add $h1,$d2 mov $d1,$h1 adc \$0,$d3 imulq $r0,$h2 # h2*r0 add $d2,$h1 mov \$-4,%rax # mask value adc $h2,$d3 and $d3,%rax # last reduction step mov $d3,$h2 shr \$2,$d3 and \$3,$h2 add $d3,%rax add %rax,$h0 adc \$0,$h1 ___ } ######################################################################## # Layout of opaque area is following. # # unsigned __int64 h[3]; # current hash value base 2^64 # unsigned __int64 r[2]; # key value base 2^64 $code.=<<___; .text .extern OPENSSL_ia32cap_P .globl poly1305_init .type poly1305_init,\@function,3 .align 32 poly1305_init: xor %rax,%rax mov %rax,0($ctx) # initialize hash value mov %rax,8($ctx) mov %rax,16($ctx) cmp \$0,$inp je .Lno_key lea poly1305_blocks(%rip),%r10 lea poly1305_emit(%rip),%r11 ___ $code.=<<___ if ($avx); mov OPENSSL_ia32cap_P+4(%rip),%r9 lea poly1305_blocks_avx(%rip),%rax lea poly1305_emit_avx(%rip),%rcx bt \$`60-32`,%r9 # AVX? cmovc %rax,%r10 cmovc %rcx,%r11 ___ $code.=<<___ if ($avx>1); lea poly1305_blocks_avx2(%rip),%rax bt \$`5+32`,%r9 # AVX2? cmovc %rax,%r10 ___ $code.=<<___; mov \$0x0ffffffc0fffffff,%rax mov \$0x0ffffffc0ffffffc,%rcx and 0($inp),%rax and 8($inp),%rcx mov %rax,24($ctx) mov %rcx,32($ctx) mov %r10,0(%rdx) mov %r11,8(%rdx) mov \$1,%eax .Lno_key: ret .size poly1305_init,.-poly1305_init .globl poly1305_blocks .type poly1305_blocks,\@function,4 .align 32 poly1305_blocks: .Lblocks: sub \$16,$len # too short? jc .Lno_data push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 .Lblocks_body: mov $len,%r15 # reassign $len mov 24($ctx),$r0 # load r mov 32($ctx),$s1 mov 0($ctx),$h0 # load hash value mov 8($ctx),$h1 mov 16($ctx),$h2 mov $s1,$r1 shr \$2,$s1 mov $r1,%rax add $r1,$s1 # s1 = r1 + (r1 >> 2) jmp .Loop .align 32 .Loop: add 0($inp),$h0 # accumulate input adc 8($inp),$h1 lea 16($inp),$inp adc $padbit,$h2 ___ &poly1305_iteration(); $code.=<<___; mov $r1,%rax sub \$16,%r15 # len-=16 jnc .Loop mov $h0,0($ctx) # store hash value mov $h1,8($ctx) mov $h2,16($ctx) mov 0(%rsp),%r15 mov 8(%rsp),%r14 mov 16(%rsp),%r13 mov 24(%rsp),%r12 mov 32(%rsp),%rbp mov 40(%rsp),%rbx lea 48(%rsp),%rsp .Lno_data: .Lblocks_epilogue: ret .size poly1305_blocks,.-poly1305_blocks .globl poly1305_emit .type poly1305_emit,\@function,3 .align 32 poly1305_emit: .Lemit: mov 0($ctx),%r8 # load hash value mov 8($ctx),%r9 mov 16($ctx),%r10 mov %r8,%rax add \$5,%r8 # compare to modulus mov %r9,%rcx adc \$0,%r9 adc \$0,%r10 shr \$2,%r10 # did 130-bit value overfow? cmovnz %r8,%rax cmovnz %r9,%rcx add 0($nonce),%rax # accumulate nonce adc 8($nonce),%rcx mov %rax,0($mac) # write result mov %rcx,8($mac) ret .size poly1305_emit,.-poly1305_emit ___ if ($avx) { ######################################################################## # Layout of opaque area is following. # # unsigned __int32 h[5]; # current hash value base 2^26 # unsigned __int32 is_base2_26; # unsigned __int64 r[2]; # key value base 2^64 # unsigned __int64 pad; # struct { unsigned __int32 r^2, r^1, r^4, r^3; } r[9]; # # where r^n are base 2^26 digits of degrees of multiplier key. There are # 5 digits, but last four are interleaved with multiples of 5, totalling # in 9 elements: r0, r1, 5*r1, r2, 5*r2, r3, 5*r3, r4, 5*r4. my ($H0,$H1,$H2,$H3,$H4, $T0,$T1,$T2,$T3,$T4, $D0,$D1,$D2,$D3,$D4, $MASK) = map("%xmm$_",(0..15)); $code.=<<___; .type __poly1305_block,\@abi-omnipotent .align 32 __poly1305_block: ___ &poly1305_iteration(); $code.=<<___; ret .size __poly1305_block,.-__poly1305_block .type __poly1305_init_avx,\@abi-omnipotent .align 32 __poly1305_init_avx: mov $r0,$h0 mov $r1,$h1 xor $h2,$h2 lea 48+64($ctx),$ctx # size optimization mov $r1,%rax call __poly1305_block # r^2 mov \$0x3ffffff,%eax # save interleaved r^2 and r base 2^26 mov \$0x3ffffff,%edx mov $h0,$d1 and $h0#d,%eax mov $r0,$d2 and $r0#d,%edx mov %eax,`16*0+0-64`($ctx) shr \$26,$d1 mov %edx,`16*0+4-64`($ctx) shr \$26,$d2 mov \$0x3ffffff,%eax mov \$0x3ffffff,%edx and $d1#d,%eax and $d2#d,%edx mov %eax,`16*1+0-64`($ctx) lea (%rax,%rax,4),%eax # *5 mov %edx,`16*1+4-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 mov %eax,`16*2+0-64`($ctx) shr \$26,$d1 mov %edx,`16*2+4-64`($ctx) shr \$26,$d2 mov $h1,%rax mov $r1,%rdx shl \$12,%rax shl \$12,%rdx or $d1,%rax or $d2,%rdx and \$0x3ffffff,%eax and \$0x3ffffff,%edx mov %eax,`16*3+0-64`($ctx) lea (%rax,%rax,4),%eax # *5 mov %edx,`16*3+4-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 mov %eax,`16*4+0-64`($ctx) mov $h1,$d1 mov %edx,`16*4+4-64`($ctx) mov $r1,$d2 mov \$0x3ffffff,%eax mov \$0x3ffffff,%edx shr \$14,$d1 shr \$14,$d2 and $d1#d,%eax and $d2#d,%edx mov %eax,`16*5+0-64`($ctx) lea (%rax,%rax,4),%eax # *5 mov %edx,`16*5+4-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 mov %eax,`16*6+0-64`($ctx) shr \$26,$d1 mov %edx,`16*6+4-64`($ctx) shr \$26,$d2 mov $h2,%rax shl \$24,%rax or %rax,$d1 mov $d1#d,`16*7+0-64`($ctx) lea ($d1,$d1,4),$d1 # *5 mov $d2#d,`16*7+4-64`($ctx) lea ($d2,$d2,4),$d2 # *5 mov $d1#d,`16*8+0-64`($ctx) mov $d2#d,`16*8+4-64`($ctx) mov $r1,%rax call __poly1305_block # r^3 mov \$0x3ffffff,%eax # save r^3 base 2^26 mov $h0,$d1 and $h0#d,%eax shr \$26,$d1 mov %eax,`16*0+12-64`($ctx) mov \$0x3ffffff,%edx and $d1#d,%edx mov %edx,`16*1+12-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 shr \$26,$d1 mov %edx,`16*2+12-64`($ctx) mov $h1,%rax shl \$12,%rax or $d1,%rax and \$0x3ffffff,%eax mov %eax,`16*3+12-64`($ctx) lea (%rax,%rax,4),%eax # *5 mov $h1,$d1 mov %eax,`16*4+12-64`($ctx) mov \$0x3ffffff,%edx shr \$14,$d1 and $d1#d,%edx mov %edx,`16*5+12-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 shr \$26,$d1 mov %edx,`16*6+12-64`($ctx) mov $h2,%rax shl \$24,%rax or %rax,$d1 mov $d1#d,`16*7+12-64`($ctx) lea ($d1,$d1,4),$d1 # *5 mov $d1#d,`16*8+12-64`($ctx) mov $r1,%rax call __poly1305_block # r^4 mov \$0x3ffffff,%eax # save r^4 base 2^26 mov $h0,$d1 and $h0#d,%eax shr \$26,$d1 mov %eax,`16*0+8-64`($ctx) mov \$0x3ffffff,%edx and $d1#d,%edx mov %edx,`16*1+8-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 shr \$26,$d1 mov %edx,`16*2+8-64`($ctx) mov $h1,%rax shl \$12,%rax or $d1,%rax and \$0x3ffffff,%eax mov %eax,`16*3+8-64`($ctx) lea (%rax,%rax,4),%eax # *5 mov $h1,$d1 mov %eax,`16*4+8-64`($ctx) mov \$0x3ffffff,%edx shr \$14,$d1 and $d1#d,%edx mov %edx,`16*5+8-64`($ctx) lea (%rdx,%rdx,4),%edx # *5 shr \$26,$d1 mov %edx,`16*6+8-64`($ctx) mov $h2,%rax shl \$24,%rax or %rax,$d1 mov $d1#d,`16*7+8-64`($ctx) lea ($d1,$d1,4),$d1 # *5 mov $d1#d,`16*8+8-64`($ctx) lea -48-64($ctx),$ctx # size [de-]optimization ret .size __poly1305_init_avx,.-__poly1305_init_avx .type poly1305_blocks_avx,\@function,4 .align 32 poly1305_blocks_avx: mov 20($ctx),%r8d # is_base2_26 cmp \$128,$len jae .Lblocks_avx test %r8d,%r8d jz .Lblocks .Lblocks_avx: and \$-16,$len jz .Lno_data_avx vzeroupper test %r8d,%r8d jz .Lbase2_64_avx test \$31,$len jz .Leven_avx push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 .Lblocks_avx_body: mov $len,%r15 # reassign $len mov 0($ctx),$d1 # load hash value mov 8($ctx),$d2 mov 16($ctx),$h2#d mov 24($ctx),$r0 # load r mov 32($ctx),$s1 ################################# base 2^26 -> base 2^64 mov $d1#d,$h0#d and \$-1<<31,$d1 mov $d2,$r1 # borrow $r1 mov $d2#d,$h1#d and \$-1<<31,$d2 shr \$6,$d1 shl \$52,$r1 add $d1,$h0 shr \$12,$h1 shr \$18,$d2 add $r1,$h0 adc $d2,$h1 mov $h2,$d1 shl \$40,$d1 shr \$24,$h2 add $d1,$h1 adc \$0,$h2 # can be partially reduced... mov \$-4,$d2 # ... so reduce mov $h2,$d1 and $h2,$d2 shr \$2,$d1 and \$3,$h2 add $d2,$d1 # =*5 add $d1,$h0 adc \$0,$h1 mov $s1,$r1 mov $s1,%rax shr \$2,$s1 add $r1,$s1 # s1 = r1 + (r1 >> 2) add 0($inp),$h0 # accumulate input adc 8($inp),$h1 lea 16($inp),$inp adc $padbit,$h2 call __poly1305_block test $padbit,$padbit # if $padbit is zero, jz .Lstore_base2_64_avx # store hash in base 2^64 format ################################# base 2^64 -> base 2^26 mov $h0,%rax mov $h0,%rdx shr \$52,$h0 mov $h1,$r0 mov $h1,$r1 shr \$26,%rdx and \$0x3ffffff,%rax # h[0] shl \$12,$r0 and \$0x3ffffff,%rdx # h[1] shr \$14,$h1 or $r0,$h0 shl \$24,$h2 and \$0x3ffffff,$h0 # h[2] shr \$40,$r1 and \$0x3ffffff,$h1 # h[3] or $r1,$h2 # h[4] sub \$16,%r15 jz .Lstore_base2_26_avx vmovd %rax#d,$H0 vmovd %rdx#d,$H1 vmovd $h0#d,$H2 vmovd $h1#d,$H3 vmovd $h2#d,$H4 jmp .Lproceed_avx .align 32 .Lstore_base2_64_avx: mov $h0,0($ctx) mov $h1,8($ctx) mov $h2,16($ctx) # note that is_base2_26 is zeroed jmp .Ldone_avx .align 16 .Lstore_base2_26_avx: mov %rax#d,0($ctx) # store hash value base 2^26 mov %rdx#d,4($ctx) mov $h0#d,8($ctx) mov $h1#d,12($ctx) mov $h2#d,16($ctx) .align 16 .Ldone_avx: mov 0(%rsp),%r15 mov 8(%rsp),%r14 mov 16(%rsp),%r13 mov 24(%rsp),%r12 mov 32(%rsp),%rbp mov 40(%rsp),%rbx lea 48(%rsp),%rsp .Lno_data_avx: .Lblocks_avx_epilogue: ret .align 32 .Lbase2_64_avx: push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 .Lbase2_64_avx_body: mov $len,%r15 # reassign $len mov 24($ctx),$r0 # load r mov 32($ctx),$s1 mov 0($ctx),$h0 # load hash value mov 8($ctx),$h1 mov 16($ctx),$h2#d mov $s1,$r1 mov $s1,%rax shr \$2,$s1 add $r1,$s1 # s1 = r1 + (r1 >> 2) test \$31,$len jz .Linit_avx add 0($inp),$h0 # accumulate input adc 8($inp),$h1 lea 16($inp),$inp adc $padbit,$h2 sub \$16,%r15 call __poly1305_block .Linit_avx: ################################# base 2^64 -> base 2^26 mov $h0,%rax mov $h0,%rdx shr \$52,$h0 mov $h1,$d1 mov $h1,$d2 shr \$26,%rdx and \$0x3ffffff,%rax # h[0] shl \$12,$d1 and \$0x3ffffff,%rdx # h[1] shr \$14,$h1 or $d1,$h0 shl \$24,$h2 and \$0x3ffffff,$h0 # h[2] shr \$40,$d2 and \$0x3ffffff,$h1 # h[3] or $d2,$h2 # h[4] vmovd %rax#d,$H0 vmovd %rdx#d,$H1 vmovd $h0#d,$H2 vmovd $h1#d,$H3 vmovd $h2#d,$H4 movl \$1,20($ctx) # set is_base2_26 call __poly1305_init_avx .Lproceed_avx: mov %r15,$len mov 0(%rsp),%r15 mov 8(%rsp),%r14 mov 16(%rsp),%r13 mov 24(%rsp),%r12 mov 32(%rsp),%rbp mov 40(%rsp),%rbx lea 48(%rsp),%rax lea 48(%rsp),%rsp .Lbase2_64_avx_epilogue: jmp .Ldo_avx .align 32 .Leven_avx: vmovd 4*0($ctx),$H0 # load hash value vmovd 4*1($ctx),$H1 vmovd 4*2($ctx),$H2 vmovd 4*3($ctx),$H3 vmovd 4*4($ctx),$H4 .Ldo_avx: ___ $code.=<<___ if (!$win64); lea -0x58(%rsp),%r11 sub \$0x178,%rsp ___ $code.=<<___ if ($win64); lea -0xf8(%rsp),%r11 sub \$0x218,%rsp vmovdqa %xmm6,0x50(%r11) vmovdqa %xmm7,0x60(%r11) vmovdqa %xmm8,0x70(%r11) vmovdqa %xmm9,0x80(%r11) vmovdqa %xmm10,0x90(%r11) vmovdqa %xmm11,0xa0(%r11) vmovdqa %xmm12,0xb0(%r11) vmovdqa %xmm13,0xc0(%r11) vmovdqa %xmm14,0xd0(%r11) vmovdqa %xmm15,0xe0(%r11) .Ldo_avx_body: ___ $code.=<<___; sub \$64,$len lea -32($inp),%rax cmovc %rax,$inp vmovdqu `16*3`($ctx),$D4 # preload r0^2 lea `16*3+64`($ctx),$ctx # size optimization lea .Lconst(%rip),%rcx ################################################################ # load input vmovdqu 16*2($inp),$T0 vmovdqu 16*3($inp),$T1 vmovdqa 64(%rcx),$MASK # .Lmask26 vpsrldq \$6,$T0,$T2 # splat input vpsrldq \$6,$T1,$T3 vpunpckhqdq $T1,$T0,$T4 # 4 vpunpcklqdq $T1,$T0,$T0 # 0:1 vpunpcklqdq $T3,$T2,$T3 # 2:3 vpsrlq \$40,$T4,$T4 # 4 vpsrlq \$26,$T0,$T1 vpand $MASK,$T0,$T0 # 0 vpsrlq \$4,$T3,$T2 vpand $MASK,$T1,$T1 # 1 vpsrlq \$30,$T3,$T3 vpand $MASK,$T2,$T2 # 2 vpand $MASK,$T3,$T3 # 3 vpor 32(%rcx),$T4,$T4 # padbit, yes, always jbe .Lskip_loop_avx # expand and copy pre-calculated table to stack vmovdqu `16*1-64`($ctx),$D1 vmovdqu `16*2-64`($ctx),$D2 vpshufd \$0xEE,$D4,$D3 # 34xx -> 3434 vpshufd \$0x44,$D4,$D0 # xx12 -> 1212 vmovdqa $D3,-0x90(%r11) vmovdqa $D0,0x00(%rsp) vpshufd \$0xEE,$D1,$D4 vmovdqu `16*3-64`($ctx),$D0 vpshufd \$0x44,$D1,$D1 vmovdqa $D4,-0x80(%r11) vmovdqa $D1,0x10(%rsp) vpshufd \$0xEE,$D2,$D3 vmovdqu `16*4-64`($ctx),$D1 vpshufd \$0x44,$D2,$D2 vmovdqa $D3,-0x70(%r11) vmovdqa $D2,0x20(%rsp) vpshufd \$0xEE,$D0,$D4 vmovdqu `16*5-64`($ctx),$D2 vpshufd \$0x44,$D0,$D0 vmovdqa $D4,-0x60(%r11) vmovdqa $D0,0x30(%rsp) vpshufd \$0xEE,$D1,$D3 vmovdqu `16*6-64`($ctx),$D0 vpshufd \$0x44,$D1,$D1 vmovdqa $D3,-0x50(%r11) vmovdqa $D1,0x40(%rsp) vpshufd \$0xEE,$D2,$D4 vmovdqu `16*7-64`($ctx),$D1 vpshufd \$0x44,$D2,$D2 vmovdqa $D4,-0x40(%r11) vmovdqa $D2,0x50(%rsp) vpshufd \$0xEE,$D0,$D3 vmovdqu `16*8-64`($ctx),$D2 vpshufd \$0x44,$D0,$D0 vmovdqa $D3,-0x30(%r11) vmovdqa $D0,0x60(%rsp) vpshufd \$0xEE,$D1,$D4 vpshufd \$0x44,$D1,$D1 vmovdqa $D4,-0x20(%r11) vmovdqa $D1,0x70(%rsp) vpshufd \$0xEE,$D2,$D3 vmovdqa 0x00(%rsp),$D4 # preload r0^2 vpshufd \$0x44,$D2,$D2 vmovdqa $D3,-0x10(%r11) vmovdqa $D2,0x80(%rsp) jmp .Loop_avx .align 32 .Loop_avx: ################################################################ # ((inp[0]*r^4+inp[2]*r^2+inp[4])*r^4+inp[6]*r^2 # ((inp[1]*r^4+inp[3]*r^2+inp[5])*r^3+inp[7]*r # \___________________/ # ((inp[0]*r^4+inp[2]*r^2+inp[4])*r^4+inp[6]*r^2+inp[8])*r^2 # ((inp[1]*r^4+inp[3]*r^2+inp[5])*r^4+inp[7]*r^2+inp[9])*r # \___________________/ \____________________/ # # Note that we start with inp[2:3]*r^2. This is because it # doesn't depend on reduction in previous iteration. ################################################################ # d4 = h4*r0 + h3*r1 + h2*r2 + h1*r3 + h0*r4 # d3 = h3*r0 + h2*r1 + h1*r2 + h0*r3 + h4*5*r4 # d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 # d1 = h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 + h2*5*r4 # d0 = h0*r0 + h4*5*r1 + h3*5*r2 + h2*5*r3 + h1*5*r4 # # though note that $Tx and $Hx are "reversed" in this section, # and $D4 is preloaded with r0^2... vpmuludq $T0,$D4,$D0 # d0 = h0*r0 vpmuludq $T1,$D4,$D1 # d1 = h1*r0 vmovdqa $H2,0x20(%r11) # offload hash vpmuludq $T2,$D4,$D2 # d3 = h2*r0 vmovdqa 0x10(%rsp),$H2 # r1^2 vpmuludq $T3,$D4,$D3 # d3 = h3*r0 vpmuludq $T4,$D4,$D4 # d4 = h4*r0 vmovdqa $H0,0x00(%r11) # vpmuludq 0x20(%rsp),$T4,$H0 # h4*s1 vmovdqa $H1,0x10(%r11) # vpmuludq $T3,$H2,$H1 # h3*r1 vpaddq $H0,$D0,$D0 # d0 += h4*s1 vpaddq $H1,$D4,$D4 # d4 += h3*r1 vmovdqa $H3,0x30(%r11) # vpmuludq $T2,$H2,$H0 # h2*r1 vpmuludq $T1,$H2,$H1 # h1*r1 vpaddq $H0,$D3,$D3 # d3 += h2*r1 vmovdqa 0x30(%rsp),$H3 # r2^2 vpaddq $H1,$D2,$D2 # d2 += h1*r1 vmovdqa $H4,0x40(%r11) # vpmuludq $T0,$H2,$H2 # h0*r1 vpmuludq $T2,$H3,$H0 # h2*r2 vpaddq $H2,$D1,$D1 # d1 += h0*r1 vmovdqa 0x40(%rsp),$H4 # s2^2 vpaddq $H0,$D4,$D4 # d4 += h2*r2 vpmuludq $T1,$H3,$H1 # h1*r2 vpmuludq $T0,$H3,$H3 # h0*r2 vpaddq $H1,$D3,$D3 # d3 += h1*r2 vmovdqa 0x50(%rsp),$H2 # r3^2 vpaddq $H3,$D2,$D2 # d2 += h0*r2 vpmuludq $T4,$H4,$H0 # h4*s2 vpmuludq $T3,$H4,$H4 # h3*s2 vpaddq $H0,$D1,$D1 # d1 += h4*s2 vmovdqa 0x60(%rsp),$H3 # s3^2 vpaddq $H4,$D0,$D0 # d0 += h3*s2 vmovdqa 0x80(%rsp),$H4 # s4^2 vpmuludq $T1,$H2,$H1 # h1*r3 vpmuludq $T0,$H2,$H2 # h0*r3 vpaddq $H1,$D4,$D4 # d4 += h1*r3 vpaddq $H2,$D3,$D3 # d3 += h0*r3 vpmuludq $T4,$H3,$H0 # h4*s3 vpmuludq $T3,$H3,$H1 # h3*s3 vpaddq $H0,$D2,$D2 # d2 += h4*s3 vmovdqu 16*0($inp),$H0 # load input vpaddq $H1,$D1,$D1 # d1 += h3*s3 vpmuludq $T2,$H3,$H3 # h2*s3 vpmuludq $T2,$H4,$T2 # h2*s4 vpaddq $H3,$D0,$D0 # d0 += h2*s3 vmovdqu 16*1($inp),$H1 # vpaddq $T2,$D1,$D1 # d1 += h2*s4 vpmuludq $T3,$H4,$T3 # h3*s4 vpmuludq $T4,$H4,$T4 # h4*s4 vpsrldq \$6,$H0,$H2 # splat input vpaddq $T3,$D2,$D2 # d2 += h3*s4 vpaddq $T4,$D3,$D3 # d3 += h4*s4 vpsrldq \$6,$H1,$H3 # vpmuludq 0x70(%rsp),$T0,$T4 # h0*r4 vpmuludq $T1,$H4,$T0 # h1*s4 vpunpckhqdq $H1,$H0,$H4 # 4 vpaddq $T4,$D4,$D4 # d4 += h0*r4 vmovdqa -0x90(%r11),$T4 # r0^4 vpaddq $T0,$D0,$D0 # d0 += h1*s4 vpunpcklqdq $H1,$H0,$H0 # 0:1 vpunpcklqdq $H3,$H2,$H3 # 2:3 #vpsrlq \$40,$H4,$H4 # 4 vpsrldq \$`40/8`,$H4,$H4 # 4 vpsrlq \$26,$H0,$H1 vpand $MASK,$H0,$H0 # 0 vpsrlq \$4,$H3,$H2 vpand $MASK,$H1,$H1 # 1 vpand 0(%rcx),$H4,$H4 # .Lmask24 vpsrlq \$30,$H3,$H3 vpand $MASK,$H2,$H2 # 2 vpand $MASK,$H3,$H3 # 3 vpor 32(%rcx),$H4,$H4 # padbit, yes, always vpaddq 0x00(%r11),$H0,$H0 # add hash value vpaddq 0x10(%r11),$H1,$H1 vpaddq 0x20(%r11),$H2,$H2 vpaddq 0x30(%r11),$H3,$H3 vpaddq 0x40(%r11),$H4,$H4 lea 16*2($inp),%rax lea 16*4($inp),$inp sub \$64,$len cmovc %rax,$inp ################################################################ # Now we accumulate (inp[0:1]+hash)*r^4 ################################################################ # d4 = h4*r0 + h3*r1 + h2*r2 + h1*r3 + h0*r4 # d3 = h3*r0 + h2*r1 + h1*r2 + h0*r3 + h4*5*r4 # d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 # d1 = h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 + h2*5*r4 # d0 = h0*r0 + h4*5*r1 + h3*5*r2 + h2*5*r3 + h1*5*r4 vpmuludq $H0,$T4,$T0 # h0*r0 vpmuludq $H1,$T4,$T1 # h1*r0 vpaddq $T0,$D0,$D0 vpaddq $T1,$D1,$D1 vmovdqa -0x80(%r11),$T2 # r1^4 vpmuludq $H2,$T4,$T0 # h2*r0 vpmuludq $H3,$T4,$T1 # h3*r0 vpaddq $T0,$D2,$D2 vpaddq $T1,$D3,$D3 vpmuludq $H4,$T4,$T4 # h4*r0 vpmuludq -0x70(%r11),$H4,$T0 # h4*s1 vpaddq $T4,$D4,$D4 vpaddq $T0,$D0,$D0 # d0 += h4*s1 vpmuludq $H2,$T2,$T1 # h2*r1 vpmuludq $H3,$T2,$T0 # h3*r1 vpaddq $T1,$D3,$D3 # d3 += h2*r1 vmovdqa -0x60(%r11),$T3 # r2^4 vpaddq $T0,$D4,$D4 # d4 += h3*r1 vpmuludq $H1,$T2,$T1 # h1*r1 vpmuludq $H0,$T2,$T2 # h0*r1 vpaddq $T1,$D2,$D2 # d2 += h1*r1 vpaddq $T2,$D1,$D1 # d1 += h0*r1 vmovdqa -0x50(%r11),$T4 # s2^4 vpmuludq $H2,$T3,$T0 # h2*r2 vpmuludq $H1,$T3,$T1 # h1*r2 vpaddq $T0,$D4,$D4 # d4 += h2*r2 vpaddq $T1,$D3,$D3 # d3 += h1*r2 vmovdqa -0x40(%r11),$T2 # r3^4 vpmuludq $H0,$T3,$T3 # h0*r2 vpmuludq $H4,$T4,$T0 # h4*s2 vpaddq $T3,$D2,$D2 # d2 += h0*r2 vpaddq $T0,$D1,$D1 # d1 += h4*s2 vmovdqa -0x30(%r11),$T3 # s3^4 vpmuludq $H3,$T4,$T4 # h3*s2 vpmuludq $H1,$T2,$T1 # h1*r3 vpaddq $T4,$D0,$D0 # d0 += h3*s2 vmovdqa -0x10(%r11),$T4 # s4^4 vpaddq $T1,$D4,$D4 # d4 += h1*r3 vpmuludq $H0,$T2,$T2 # h0*r3 vpmuludq $H4,$T3,$T0 # h4*s3 vpaddq $T2,$D3,$D3 # d3 += h0*r3 vpaddq $T0,$D2,$D2 # d2 += h4*s3 vmovdqu 16*2($inp),$T0 # load input vpmuludq $H3,$T3,$T2 # h3*s3 vpmuludq $H2,$T3,$T3 # h2*s3 vpaddq $T2,$D1,$D1 # d1 += h3*s3 vmovdqu 16*3($inp),$T1 # vpaddq $T3,$D0,$D0 # d0 += h2*s3 vpmuludq $H2,$T4,$H2 # h2*s4 vpmuludq $H3,$T4,$H3 # h3*s4 vpsrldq \$6,$T0,$T2 # splat input vpaddq $H2,$D1,$D1 # d1 += h2*s4 vpmuludq $H4,$T4,$H4 # h4*s4 vpsrldq \$6,$T1,$T3 # vpaddq $H3,$D2,$H2 # h2 = d2 + h3*s4 vpaddq $H4,$D3,$H3 # h3 = d3 + h4*s4 vpmuludq -0x20(%r11),$H0,$H4 # h0*r4 vpmuludq $H1,$T4,$H0 vpunpckhqdq $T1,$T0,$T4 # 4 vpaddq $H4,$D4,$H4 # h4 = d4 + h0*r4 vpaddq $H0,$D0,$H0 # h0 = d0 + h1*s4 vpunpcklqdq $T1,$T0,$T0 # 0:1 vpunpcklqdq $T3,$T2,$T3 # 2:3 #vpsrlq \$40,$T4,$T4 # 4 vpsrldq \$`40/8`,$T4,$T4 # 4 vpsrlq \$26,$T0,$T1 vmovdqa 0x00(%rsp),$D4 # preload r0^2 vpand $MASK,$T0,$T0 # 0 vpsrlq \$4,$T3,$T2 vpand $MASK,$T1,$T1 # 1 vpand 0(%rcx),$T4,$T4 # .Lmask24 vpsrlq \$30,$T3,$T3 vpand $MASK,$T2,$T2 # 2 vpand $MASK,$T3,$T3 # 3 vpor 32(%rcx),$T4,$T4 # padbit, yes, always ################################################################ # lazy reduction as discussed in "NEON crypto" by D.J. Bernstein # and P. Schwabe vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$D1,$H1 # h0 -> h1 vpsrlq \$26,$H4,$D0 vpand $MASK,$H4,$H4 vpsrlq \$26,$H1,$D1 vpand $MASK,$H1,$H1 vpaddq $D1,$H2,$H2 # h1 -> h2 vpaddq $D0,$H0,$H0 vpsllq \$2,$D0,$D0 vpaddq $D0,$H0,$H0 # h4 -> h0 vpsrlq \$26,$H2,$D2 vpand $MASK,$H2,$H2 vpaddq $D2,$H3,$H3 # h2 -> h3 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$H1,$H1 # h0 -> h1 vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 ja .Loop_avx .Lskip_loop_avx: ################################################################ # multiply (inp[0:1]+hash) or inp[2:3] by r^2:r^1 vpshufd \$0x10,$D4,$D4 # r0^n, xx12 -> x1x2 add \$32,$len jnz .Long_tail_avx vpaddq $H2,$T2,$T2 vpaddq $H0,$T0,$T0 vpaddq $H1,$T1,$T1 vpaddq $H3,$T3,$T3 vpaddq $H4,$T4,$T4 .Long_tail_avx: vmovdqa $H2,0x20(%r11) vmovdqa $H0,0x00(%r11) vmovdqa $H1,0x10(%r11) vmovdqa $H3,0x30(%r11) vmovdqa $H4,0x40(%r11) # d4 = h4*r0 + h3*r1 + h2*r2 + h1*r3 + h0*r4 # d3 = h3*r0 + h2*r1 + h1*r2 + h0*r3 + h4*5*r4 # d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 # d1 = h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 + h2*5*r4 # d0 = h0*r0 + h4*5*r1 + h3*5*r2 + h2*5*r3 + h1*5*r4 vpmuludq $T2,$D4,$D2 # d2 = h2*r0 vpmuludq $T0,$D4,$D0 # d0 = h0*r0 vpshufd \$0x10,`16*1-64`($ctx),$H2 # r1^n vpmuludq $T1,$D4,$D1 # d1 = h1*r0 vpmuludq $T3,$D4,$D3 # d3 = h3*r0 vpmuludq $T4,$D4,$D4 # d4 = h4*r0 vpmuludq $T3,$H2,$H0 # h3*r1 vpaddq $H0,$D4,$D4 # d4 += h3*r1 vpshufd \$0x10,`16*2-64`($ctx),$H3 # s1^n vpmuludq $T2,$H2,$H1 # h2*r1 vpaddq $H1,$D3,$D3 # d3 += h2*r1 vpshufd \$0x10,`16*3-64`($ctx),$H4 # r2^n vpmuludq $T1,$H2,$H0 # h1*r1 vpaddq $H0,$D2,$D2 # d2 += h1*r1 vpmuludq $T0,$H2,$H2 # h0*r1 vpaddq $H2,$D1,$D1 # d1 += h0*r1 vpmuludq $T4,$H3,$H3 # h4*s1 vpaddq $H3,$D0,$D0 # d0 += h4*s1 vpshufd \$0x10,`16*4-64`($ctx),$H2 # s2^n vpmuludq $T2,$H4,$H1 # h2*r2 vpaddq $H1,$D4,$D4 # d4 += h2*r2 vpmuludq $T1,$H4,$H0 # h1*r2 vpaddq $H0,$D3,$D3 # d3 += h1*r2 vpshufd \$0x10,`16*5-64`($ctx),$H3 # r3^n vpmuludq $T0,$H4,$H4 # h0*r2 vpaddq $H4,$D2,$D2 # d2 += h0*r2 vpmuludq $T4,$H2,$H1 # h4*s2 vpaddq $H1,$D1,$D1 # d1 += h4*s2 vpshufd \$0x10,`16*6-64`($ctx),$H4 # s3^n vpmuludq $T3,$H2,$H2 # h3*s2 vpaddq $H2,$D0,$D0 # d0 += h3*s2 vpmuludq $T1,$H3,$H0 # h1*r3 vpaddq $H0,$D4,$D4 # d4 += h1*r3 vpmuludq $T0,$H3,$H3 # h0*r3 vpaddq $H3,$D3,$D3 # d3 += h0*r3 vpshufd \$0x10,`16*7-64`($ctx),$H2 # r4^n vpmuludq $T4,$H4,$H1 # h4*s3 vpaddq $H1,$D2,$D2 # d2 += h4*s3 vpshufd \$0x10,`16*8-64`($ctx),$H3 # s4^n vpmuludq $T3,$H4,$H0 # h3*s3 vpaddq $H0,$D1,$D1 # d1 += h3*s3 vpmuludq $T2,$H4,$H4 # h2*s3 vpaddq $H4,$D0,$D0 # d0 += h2*s3 vpmuludq $T0,$H2,$H2 # h0*r4 vpaddq $H2,$D4,$D4 # h4 = d4 + h0*r4 vpmuludq $T4,$H3,$H1 # h4*s4 vpaddq $H1,$D3,$D3 # h3 = d3 + h4*s4 vpmuludq $T3,$H3,$H0 # h3*s4 vpaddq $H0,$D2,$D2 # h2 = d2 + h3*s4 vpmuludq $T2,$H3,$H1 # h2*s4 vpaddq $H1,$D1,$D1 # h1 = d1 + h2*s4 vpmuludq $T1,$H3,$H3 # h1*s4 vpaddq $H3,$D0,$D0 # h0 = d0 + h1*s4 jz .Lshort_tail_avx vmovdqu 16*0($inp),$H0 # load input vmovdqu 16*1($inp),$H1 vpsrldq \$6,$H0,$H2 # splat input vpsrldq \$6,$H1,$H3 vpunpckhqdq $H1,$H0,$H4 # 4 vpunpcklqdq $H1,$H0,$H0 # 0:1 vpunpcklqdq $H3,$H2,$H3 # 2:3 vpsrlq \$40,$H4,$H4 # 4 vpsrlq \$26,$H0,$H1 vpand $MASK,$H0,$H0 # 0 vpsrlq \$4,$H3,$H2 vpand $MASK,$H1,$H1 # 1 vpsrlq \$30,$H3,$H3 vpand $MASK,$H2,$H2 # 2 vpand $MASK,$H3,$H3 # 3 vpor 32(%rcx),$H4,$H4 # padbit, yes, always vpshufd \$0x32,`16*0-64`($ctx),$T4 # r0^n, 34xx -> x3x4 vpaddq 0x00(%r11),$H0,$H0 vpaddq 0x10(%r11),$H1,$H1 vpaddq 0x20(%r11),$H2,$H2 vpaddq 0x30(%r11),$H3,$H3 vpaddq 0x40(%r11),$H4,$H4 ################################################################ # multiply (inp[0:1]+hash) by r^4:r^3 and accumulate vpmuludq $H0,$T4,$T0 # h0*r0 vpaddq $T0,$D0,$D0 # d0 += h0*r0 vpmuludq $H1,$T4,$T1 # h1*r0 vpaddq $T1,$D1,$D1 # d1 += h1*r0 vpmuludq $H2,$T4,$T0 # h2*r0 vpaddq $T0,$D2,$D2 # d2 += h2*r0 vpshufd \$0x32,`16*1-64`($ctx),$T2 # r1^n vpmuludq $H3,$T4,$T1 # h3*r0 vpaddq $T1,$D3,$D3 # d3 += h3*r0 vpmuludq $H4,$T4,$T4 # h4*r0 vpaddq $T4,$D4,$D4 # d4 += h4*r0 vpmuludq $H3,$T2,$T0 # h3*r1 vpaddq $T0,$D4,$D4 # d4 += h3*r1 vpshufd \$0x32,`16*2-64`($ctx),$T3 # s1 vpmuludq $H2,$T2,$T1 # h2*r1 vpaddq $T1,$D3,$D3 # d3 += h2*r1 vpshufd \$0x32,`16*3-64`($ctx),$T4 # r2 vpmuludq $H1,$T2,$T0 # h1*r1 vpaddq $T0,$D2,$D2 # d2 += h1*r1 vpmuludq $H0,$T2,$T2 # h0*r1 vpaddq $T2,$D1,$D1 # d1 += h0*r1 vpmuludq $H4,$T3,$T3 # h4*s1 vpaddq $T3,$D0,$D0 # d0 += h4*s1 vpshufd \$0x32,`16*4-64`($ctx),$T2 # s2 vpmuludq $H2,$T4,$T1 # h2*r2 vpaddq $T1,$D4,$D4 # d4 += h2*r2 vpmuludq $H1,$T4,$T0 # h1*r2 vpaddq $T0,$D3,$D3 # d3 += h1*r2 vpshufd \$0x32,`16*5-64`($ctx),$T3 # r3 vpmuludq $H0,$T4,$T4 # h0*r2 vpaddq $T4,$D2,$D2 # d2 += h0*r2 vpmuludq $H4,$T2,$T1 # h4*s2 vpaddq $T1,$D1,$D1 # d1 += h4*s2 vpshufd \$0x32,`16*6-64`($ctx),$T4 # s3 vpmuludq $H3,$T2,$T2 # h3*s2 vpaddq $T2,$D0,$D0 # d0 += h3*s2 vpmuludq $H1,$T3,$T0 # h1*r3 vpaddq $T0,$D4,$D4 # d4 += h1*r3 vpmuludq $H0,$T3,$T3 # h0*r3 vpaddq $T3,$D3,$D3 # d3 += h0*r3 vpshufd \$0x32,`16*7-64`($ctx),$T2 # r4 vpmuludq $H4,$T4,$T1 # h4*s3 vpaddq $T1,$D2,$D2 # d2 += h4*s3 vpshufd \$0x32,`16*8-64`($ctx),$T3 # s4 vpmuludq $H3,$T4,$T0 # h3*s3 vpaddq $T0,$D1,$D1 # d1 += h3*s3 vpmuludq $H2,$T4,$T4 # h2*s3 vpaddq $T4,$D0,$D0 # d0 += h2*s3 vpmuludq $H0,$T2,$T2 # h0*r4 vpaddq $T2,$D4,$D4 # d4 += h0*r4 vpmuludq $H4,$T3,$T1 # h4*s4 vpaddq $T1,$D3,$D3 # d3 += h4*s4 vpmuludq $H3,$T3,$T0 # h3*s4 vpaddq $T0,$D2,$D2 # d2 += h3*s4 vpmuludq $H2,$T3,$T1 # h2*s4 vpaddq $T1,$D1,$D1 # d1 += h2*s4 vpmuludq $H1,$T3,$T3 # h1*s4 vpaddq $T3,$D0,$D0 # d0 += h1*s4 .Lshort_tail_avx: ################################################################ # lazy reduction vpsrlq \$26,$D3,$H3 vpand $MASK,$D3,$D3 vpaddq $H3,$D4,$D4 # h3 -> h4 vpsrlq \$26,$D0,$H0 vpand $MASK,$D0,$D0 vpaddq $H0,$D1,$D1 # h0 -> h1 vpsrlq \$26,$D4,$H4 vpand $MASK,$D4,$D4 vpsrlq \$26,$D1,$H1 vpand $MASK,$D1,$D1 vpaddq $H1,$D2,$D2 # h1 -> h2 vpaddq $H4,$D0,$D0 vpsllq \$2,$H4,$H4 vpaddq $H4,$D0,$D0 # h4 -> h0 vpsrlq \$26,$D2,$H2 vpand $MASK,$D2,$D2 vpaddq $H2,$D3,$D3 # h2 -> h3 vpsrlq \$26,$D0,$H0 vpand $MASK,$D0,$D0 vpaddq $H0,$D1,$D1 # h0 -> h1 vpsrlq \$26,$D3,$H3 vpand $MASK,$D3,$D3 vpaddq $H3,$D4,$D4 # h3 -> h4 ################################################################ # horizontal addition vpsrldq \$8,$D2,$T2 vpsrldq \$8,$D0,$T0 vpsrldq \$8,$D1,$T1 vpsrldq \$8,$D3,$T3 vpsrldq \$8,$D4,$T4 vpaddq $T2,$D2,$H2 vpaddq $T0,$D0,$H0 vpaddq $T1,$D1,$H1 vpaddq $T3,$D3,$H3 vpaddq $T4,$D4,$H4 vmovd $H0,`4*0-48-64`($ctx) # save partially reduced vmovd $H1,`4*1-48-64`($ctx) vmovd $H2,`4*2-48-64`($ctx) vmovd $H3,`4*3-48-64`($ctx) vmovd $H4,`4*4-48-64`($ctx) ___ $code.=<<___ if ($win64); vmovdqa 0x50(%r11),%xmm6 vmovdqa 0x60(%r11),%xmm7 vmovdqa 0x70(%r11),%xmm8 vmovdqa 0x80(%r11),%xmm9 vmovdqa 0x90(%r11),%xmm10 vmovdqa 0xa0(%r11),%xmm11 vmovdqa 0xb0(%r11),%xmm12 vmovdqa 0xc0(%r11),%xmm13 vmovdqa 0xd0(%r11),%xmm14 vmovdqa 0xe0(%r11),%xmm15 lea 0xf8(%r11),%rsp .Ldo_avx_epilogue: ___ $code.=<<___ if (!$win64); lea 0x58(%r11),%rsp ___ $code.=<<___; vzeroupper ret .size poly1305_blocks_avx,.-poly1305_blocks_avx .type poly1305_emit_avx,\@function,3 .align 32 poly1305_emit_avx: cmpl \$0,20($ctx) # is_base2_26? je .Lemit mov 0($ctx),%eax # load hash value base 2^26 mov 4($ctx),%ecx mov 8($ctx),%r8d mov 12($ctx),%r11d mov 16($ctx),%r10d shl \$26,%rcx # base 2^26 -> base 2^64 mov %r8,%r9 shl \$52,%r8 add %rcx,%rax shr \$12,%r9 add %rax,%r8 # h0 adc \$0,%r9 shl \$14,%r11 mov %r10,%rax shr \$24,%r10 add %r11,%r9 shl \$40,%rax add %rax,%r9 # h1 adc \$0,%r10 # h2 mov %r10,%rax # could be partially reduced, so reduce mov %r10,%rcx and \$3,%r10 shr \$2,%rax and \$-4,%rcx add %rcx,%rax add %rax,%r8 adc \$0,%r9 mov %r8,%rax add \$5,%r8 # compare to modulus mov %r9,%rcx adc \$0,%r9 adc \$0,%r10 shr \$2,%r10 # did 130-bit value overfow? cmovnz %r8,%rax cmovnz %r9,%rcx add 0($nonce),%rax # accumulate nonce adc 8($nonce),%rcx mov %rax,0($mac) # write result mov %rcx,8($mac) ret .size poly1305_emit_avx,.-poly1305_emit_avx ___ if ($avx>1) { my ($H0,$H1,$H2,$H3,$H4, $MASK, $T4,$T0,$T1,$T2,$T3, $D0,$D1,$D2,$D3,$D4) = map("%ymm$_",(0..15)); my $S4=$MASK; $code.=<<___; .type poly1305_blocks_avx2,\@function,4 .align 32 poly1305_blocks_avx2: mov 20($ctx),%r8d # is_base2_26 cmp \$128,$len jae .Lblocks_avx2 test %r8d,%r8d jz .Lblocks .Lblocks_avx2: and \$-16,$len jz .Lno_data_avx2 vzeroupper test %r8d,%r8d jz .Lbase2_64_avx2 test \$63,$len jz .Leven_avx2 push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 .Lblocks_avx2_body: mov $len,%r15 # reassign $len mov 0($ctx),$d1 # load hash value mov 8($ctx),$d2 mov 16($ctx),$h2#d mov 24($ctx),$r0 # load r mov 32($ctx),$s1 ################################# base 2^26 -> base 2^64 mov $d1#d,$h0#d and \$-1<<31,$d1 mov $d2,$r1 # borrow $r1 mov $d2#d,$h1#d and \$-1<<31,$d2 shr \$6,$d1 shl \$52,$r1 add $d1,$h0 shr \$12,$h1 shr \$18,$d2 add $r1,$h0 adc $d2,$h1 mov $h2,$d1 shl \$40,$d1 shr \$24,$h2 add $d1,$h1 adc \$0,$h2 # can be partially reduced... mov \$-4,$d2 # ... so reduce mov $h2,$d1 and $h2,$d2 shr \$2,$d1 and \$3,$h2 add $d2,$d1 # =*5 add $d1,$h0 adc \$0,$h1 mov $s1,$r1 mov $s1,%rax shr \$2,$s1 add $r1,$s1 # s1 = r1 + (r1 >> 2) .Lbase2_26_pre_avx2: add 0($inp),$h0 # accumulate input adc 8($inp),$h1 lea 16($inp),$inp adc $padbit,$h2 sub \$16,%r15 call __poly1305_block mov $r1,%rax test \$63,%r15 jnz .Lbase2_26_pre_avx2 test $padbit,$padbit # if $padbit is zero, jz .Lstore_base2_64_avx2 # store hash in base 2^64 format ################################# base 2^64 -> base 2^26 mov $h0,%rax mov $h0,%rdx shr \$52,$h0 mov $h1,$r0 mov $h1,$r1 shr \$26,%rdx and \$0x3ffffff,%rax # h[0] shl \$12,$r0 and \$0x3ffffff,%rdx # h[1] shr \$14,$h1 or $r0,$h0 shl \$24,$h2 and \$0x3ffffff,$h0 # h[2] shr \$40,$r1 and \$0x3ffffff,$h1 # h[3] or $r1,$h2 # h[4] test %r15,%r15 jz .Lstore_base2_26_avx2 vmovd %rax#d,%x#$H0 vmovd %rdx#d,%x#$H1 vmovd $h0#d,%x#$H2 vmovd $h1#d,%x#$H3 vmovd $h2#d,%x#$H4 jmp .Lproceed_avx2 .align 32 .Lstore_base2_64_avx2: mov $h0,0($ctx) mov $h1,8($ctx) mov $h2,16($ctx) # note that is_base2_26 is zeroed jmp .Ldone_avx2 .align 16 .Lstore_base2_26_avx2: mov %rax#d,0($ctx) # store hash value base 2^26 mov %rdx#d,4($ctx) mov $h0#d,8($ctx) mov $h1#d,12($ctx) mov $h2#d,16($ctx) .align 16 .Ldone_avx2: mov 0(%rsp),%r15 mov 8(%rsp),%r14 mov 16(%rsp),%r13 mov 24(%rsp),%r12 mov 32(%rsp),%rbp mov 40(%rsp),%rbx lea 48(%rsp),%rsp .Lno_data_avx2: .Lblocks_avx2_epilogue: ret .align 32 .Lbase2_64_avx2: push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 .Lbase2_64_avx2_body: mov $len,%r15 # reassign $len mov 24($ctx),$r0 # load r mov 32($ctx),$s1 mov 0($ctx),$h0 # load hash value mov 8($ctx),$h1 mov 16($ctx),$h2#d mov $s1,$r1 mov $s1,%rax shr \$2,$s1 add $r1,$s1 # s1 = r1 + (r1 >> 2) test \$63,$len jz .Linit_avx2 .Lbase2_64_pre_avx2: add 0($inp),$h0 # accumulate input adc 8($inp),$h1 lea 16($inp),$inp adc $padbit,$h2 sub \$16,%r15 call __poly1305_block mov $r1,%rax test \$63,%r15 jnz .Lbase2_64_pre_avx2 .Linit_avx2: ################################# base 2^64 -> base 2^26 mov $h0,%rax mov $h0,%rdx shr \$52,$h0 mov $h1,$d1 mov $h1,$d2 shr \$26,%rdx and \$0x3ffffff,%rax # h[0] shl \$12,$d1 and \$0x3ffffff,%rdx # h[1] shr \$14,$h1 or $d1,$h0 shl \$24,$h2 and \$0x3ffffff,$h0 # h[2] shr \$40,$d2 and \$0x3ffffff,$h1 # h[3] or $d2,$h2 # h[4] vmovd %rax#d,%x#$H0 vmovd %rdx#d,%x#$H1 vmovd $h0#d,%x#$H2 vmovd $h1#d,%x#$H3 vmovd $h2#d,%x#$H4 movl \$1,20($ctx) # set is_base2_26 call __poly1305_init_avx .Lproceed_avx2: mov %r15,$len mov 0(%rsp),%r15 mov 8(%rsp),%r14 mov 16(%rsp),%r13 mov 24(%rsp),%r12 mov 32(%rsp),%rbp mov 40(%rsp),%rbx lea 48(%rsp),%rax lea 48(%rsp),%rsp .Lbase2_64_avx2_epilogue: jmp .Ldo_avx2 .align 32 .Leven_avx2: vmovd 4*0($ctx),%x#$H0 # load hash value base 2^26 vmovd 4*1($ctx),%x#$H1 vmovd 4*2($ctx),%x#$H2 vmovd 4*3($ctx),%x#$H3 vmovd 4*4($ctx),%x#$H4 .Ldo_avx2: ___ $code.=<<___ if (!$win64); lea -8(%rsp),%r11 sub \$0x128,%rsp ___ $code.=<<___ if ($win64); lea -0xf8(%rsp),%r11 sub \$0x1c8,%rsp vmovdqa %xmm6,0x50(%r11) vmovdqa %xmm7,0x60(%r11) vmovdqa %xmm8,0x70(%r11) vmovdqa %xmm9,0x80(%r11) vmovdqa %xmm10,0x90(%r11) vmovdqa %xmm11,0xa0(%r11) vmovdqa %xmm12,0xb0(%r11) vmovdqa %xmm13,0xc0(%r11) vmovdqa %xmm14,0xd0(%r11) vmovdqa %xmm15,0xe0(%r11) .Ldo_avx2_body: ___ $code.=<<___; lea 48+64($ctx),$ctx # size optimization lea .Lconst(%rip),%rcx # expand and copy pre-calculated table to stack vmovdqu `16*0-64`($ctx),%x#$T2 and \$-512,%rsp vmovdqu `16*1-64`($ctx),%x#$T3 vmovdqu `16*2-64`($ctx),%x#$T4 vmovdqu `16*3-64`($ctx),%x#$D0 vmovdqu `16*4-64`($ctx),%x#$D1 vmovdqu `16*5-64`($ctx),%x#$D2 vmovdqu `16*6-64`($ctx),%x#$D3 vpermq \$0x15,$T2,$T2 # 00003412 -> 12343434 vmovdqu `16*7-64`($ctx),%x#$D4 vpermq \$0x15,$T3,$T3 vpshufd \$0xc8,$T2,$T2 # 12343434 -> 14243444 vmovdqu `16*8-64`($ctx),%x#$MASK vpermq \$0x15,$T4,$T4 vpshufd \$0xc8,$T3,$T3 vmovdqa $T2,0x00(%rsp) vpermq \$0x15,$D0,$D0 vpshufd \$0xc8,$T4,$T4 vmovdqa $T3,0x20(%rsp) vpermq \$0x15,$D1,$D1 vpshufd \$0xc8,$D0,$D0 vmovdqa $T4,0x40(%rsp) vpermq \$0x15,$D2,$D2 vpshufd \$0xc8,$D1,$D1 vmovdqa $D0,0x60(%rsp) vpermq \$0x15,$D3,$D3 vpshufd \$0xc8,$D2,$D2 vmovdqa $D1,0x80(%rsp) vpermq \$0x15,$D4,$D4 vpshufd \$0xc8,$D3,$D3 vmovdqa $D2,0xa0(%rsp) vpermq \$0x15,$MASK,$MASK vpshufd \$0xc8,$D4,$D4 vmovdqa $D3,0xc0(%rsp) vpshufd \$0xc8,$MASK,$MASK vmovdqa $D4,0xe0(%rsp) vmovdqa $MASK,0x100(%rsp) vmovdqa 64(%rcx),$MASK # .Lmask26 ################################################################ # load input vmovdqu 16*0($inp),%x#$T0 vmovdqu 16*1($inp),%x#$T1 vinserti128 \$1,16*2($inp),$T0,$T0 vinserti128 \$1,16*3($inp),$T1,$T1 lea 16*4($inp),$inp vpsrldq \$6,$T0,$T2 # splat input vpsrldq \$6,$T1,$T3 vpunpckhqdq $T1,$T0,$T4 # 4 vpunpcklqdq $T3,$T2,$T2 # 2:3 vpunpcklqdq $T1,$T0,$T0 # 0:1 vpsrlq \$30,$T2,$T3 vpsrlq \$4,$T2,$T2 vpsrlq \$26,$T0,$T1 vpsrlq \$40,$T4,$T4 # 4 vpand $MASK,$T2,$T2 # 2 vpand $MASK,$T0,$T0 # 0 vpand $MASK,$T1,$T1 # 1 vpand $MASK,$T3,$T3 # 3 vpor 32(%rcx),$T4,$T4 # padbit, yes, always lea 0x90(%rsp),%rax # size optimization vpaddq $H2,$T2,$H2 # accumulate input sub \$64,$len jz .Ltail_avx2 jmp .Loop_avx2 .align 32 .Loop_avx2: ################################################################ # ((inp[0]*r^4+r[4])*r^4+r[8])*r^4 # ((inp[1]*r^4+r[5])*r^4+r[9])*r^3 # ((inp[2]*r^4+r[6])*r^4+r[10])*r^2 # ((inp[3]*r^4+r[7])*r^4+r[11])*r^1 # \________/\________/ ################################################################ #vpaddq $H2,$T2,$H2 # accumulate input vpaddq $H0,$T0,$H0 vmovdqa `32*0`(%rsp),$T0 # r0^4 vpaddq $H1,$T1,$H1 vmovdqa `32*1`(%rsp),$T1 # r1^4 vpaddq $H3,$T3,$H3 vmovdqa `32*3`(%rsp),$T2 # r2^4 vpaddq $H4,$T4,$H4 vmovdqa `32*6-0x90`(%rax),$T3 # s3^4 vmovdqa `32*8-0x90`(%rax),$S4 # s4^4 # d4 = h4*r0 + h3*r1 + h2*r2 + h1*r3 + h0*r4 # d3 = h3*r0 + h2*r1 + h1*r2 + h0*r3 + h4*5*r4 # d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 # d1 = h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 + h2*5*r4 # d0 = h0*r0 + h4*5*r1 + h3*5*r2 + h2*5*r3 + h1*5*r4 # # however, as h2 is "chronologically" first one available pull # corresponding operations up, so it's # # d4 = h2*r2 + h4*r0 + h3*r1 + h1*r3 + h0*r4 # d3 = h2*r1 + h3*r0 + h1*r2 + h0*r3 + h4*5*r4 # d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 # d1 = h2*5*r4 + h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 # d0 = h2*5*r3 + h0*r0 + h4*5*r1 + h3*5*r2 + h1*5*r4 vpmuludq $H2,$T0,$D2 # d2 = h2*r0 vpmuludq $H2,$T1,$D3 # d3 = h2*r1 vpmuludq $H2,$T2,$D4 # d4 = h2*r2 vpmuludq $H2,$T3,$D0 # d0 = h2*s3 vpmuludq $H2,$S4,$D1 # d1 = h2*s4 vpmuludq $H0,$T1,$T4 # h0*r1 vpmuludq $H1,$T1,$H2 # h1*r1, borrow $H2 as temp vpaddq $T4,$D1,$D1 # d1 += h0*r1 vpaddq $H2,$D2,$D2 # d2 += h1*r1 vpmuludq $H3,$T1,$T4 # h3*r1 vpmuludq `32*2`(%rsp),$H4,$H2 # h4*s1 vpaddq $T4,$D4,$D4 # d4 += h3*r1 vpaddq $H2,$D0,$D0 # d0 += h4*s1 vmovdqa `32*4-0x90`(%rax),$T1 # s2 vpmuludq $H0,$T0,$T4 # h0*r0 vpmuludq $H1,$T0,$H2 # h1*r0 vpaddq $T4,$D0,$D0 # d0 += h0*r0 vpaddq $H2,$D1,$D1 # d1 += h1*r0 vpmuludq $H3,$T0,$T4 # h3*r0 vpmuludq $H4,$T0,$H2 # h4*r0 vmovdqu 16*0($inp),%x#$T0 # load input vpaddq $T4,$D3,$D3 # d3 += h3*r0 vpaddq $H2,$D4,$D4 # d4 += h4*r0 vinserti128 \$1,16*2($inp),$T0,$T0 vpmuludq $H3,$T1,$T4 # h3*s2 vpmuludq $H4,$T1,$H2 # h4*s2 vmovdqu 16*1($inp),%x#$T1 vpaddq $T4,$D0,$D0 # d0 += h3*s2 vpaddq $H2,$D1,$D1 # d1 += h4*s2 vmovdqa `32*5-0x90`(%rax),$H2 # r3 vpmuludq $H1,$T2,$T4 # h1*r2 vpmuludq $H0,$T2,$T2 # h0*r2 vpaddq $T4,$D3,$D3 # d3 += h1*r2 vpaddq $T2,$D2,$D2 # d2 += h0*r2 vinserti128 \$1,16*3($inp),$T1,$T1 lea 16*4($inp),$inp vpmuludq $H1,$H2,$T4 # h1*r3 vpmuludq $H0,$H2,$H2 # h0*r3 vpsrldq \$6,$T0,$T2 # splat input vpaddq $T4,$D4,$D4 # d4 += h1*r3 vpaddq $H2,$D3,$D3 # d3 += h0*r3 vpmuludq $H3,$T3,$T4 # h3*s3 vpmuludq $H4,$T3,$H2 # h4*s3 vpsrldq \$6,$T1,$T3 vpaddq $T4,$D1,$D1 # d1 += h3*s3 vpaddq $H2,$D2,$D2 # d2 += h4*s3 vpunpckhqdq $T1,$T0,$T4 # 4 vpmuludq $H3,$S4,$H3 # h3*s4 vpmuludq $H4,$S4,$H4 # h4*s4 vpunpcklqdq $T1,$T0,$T0 # 0:1 vpaddq $H3,$D2,$H2 # h2 = d2 + h3*r4 vpaddq $H4,$D3,$H3 # h3 = d3 + h4*r4 vpunpcklqdq $T3,$T2,$T3 # 2:3 vpmuludq `32*7-0x90`(%rax),$H0,$H4 # h0*r4 vpmuludq $H1,$S4,$H0 # h1*s4 vmovdqa 64(%rcx),$MASK # .Lmask26 vpaddq $H4,$D4,$H4 # h4 = d4 + h0*r4 vpaddq $H0,$D0,$H0 # h0 = d0 + h1*s4 ################################################################ # lazy reduction (interleaved with tail of input splat) vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$D1,$H1 # h0 -> h1 vpsrlq \$26,$H4,$D4 vpand $MASK,$H4,$H4 vpsrlq \$4,$T3,$T2 vpsrlq \$26,$H1,$D1 vpand $MASK,$H1,$H1 vpaddq $D1,$H2,$H2 # h1 -> h2 vpaddq $D4,$H0,$H0 vpsllq \$2,$D4,$D4 vpaddq $D4,$H0,$H0 # h4 -> h0 vpand $MASK,$T2,$T2 # 2 vpsrlq \$26,$T0,$T1 vpsrlq \$26,$H2,$D2 vpand $MASK,$H2,$H2 vpaddq $D2,$H3,$H3 # h2 -> h3 vpaddq $T2,$H2,$H2 # modulo-scheduled vpsrlq \$30,$T3,$T3 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$H1,$H1 # h0 -> h1 vpsrlq \$40,$T4,$T4 # 4 vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 vpand $MASK,$T0,$T0 # 0 vpand $MASK,$T1,$T1 # 1 vpand $MASK,$T3,$T3 # 3 vpor 32(%rcx),$T4,$T4 # padbit, yes, always sub \$64,$len jnz .Loop_avx2 .byte 0x66,0x90 .Ltail_avx2: ################################################################ # while above multiplications were by r^4 in all lanes, in last # iteration we multiply least significant lane by r^4 and most # significant one by r, so copy of above except that references # to the precomputed table are displaced by 4... #vpaddq $H2,$T2,$H2 # accumulate input vpaddq $H0,$T0,$H0 vmovdqu `32*0+4`(%rsp),$T0 # r0^4 vpaddq $H1,$T1,$H1 vmovdqu `32*1+4`(%rsp),$T1 # r1^4 vpaddq $H3,$T3,$H3 vmovdqu `32*3+4`(%rsp),$T2 # r2^4 vpaddq $H4,$T4,$H4 vmovdqu `32*6+4-0x90`(%rax),$T3 # s3^4 vmovdqu `32*8+4-0x90`(%rax),$S4 # s4^4 vpmuludq $H2,$T0,$D2 # d2 = h2*r0 vpmuludq $H2,$T1,$D3 # d3 = h2*r1 vpmuludq $H2,$T2,$D4 # d4 = h2*r2 vpmuludq $H2,$T3,$D0 # d0 = h2*s3 vpmuludq $H2,$S4,$D1 # d1 = h2*s4 vpmuludq $H0,$T1,$T4 # h0*r1 vpmuludq $H1,$T1,$H2 # h1*r1 vpaddq $T4,$D1,$D1 # d1 += h0*r1 vpaddq $H2,$D2,$D2 # d2 += h1*r1 vpmuludq $H3,$T1,$T4 # h3*r1 vpmuludq `32*2+4`(%rsp),$H4,$H2 # h4*s1 vpaddq $T4,$D4,$D4 # d4 += h3*r1 vpaddq $H2,$D0,$D0 # d0 += h4*s1 vpmuludq $H0,$T0,$T4 # h0*r0 vpmuludq $H1,$T0,$H2 # h1*r0 vpaddq $T4,$D0,$D0 # d0 += h0*r0 vmovdqu `32*4+4-0x90`(%rax),$T1 # s2 vpaddq $H2,$D1,$D1 # d1 += h1*r0 vpmuludq $H3,$T0,$T4 # h3*r0 vpmuludq $H4,$T0,$H2 # h4*r0 vpaddq $T4,$D3,$D3 # d3 += h3*r0 vpaddq $H2,$D4,$D4 # d4 += h4*r0 vpmuludq $H3,$T1,$T4 # h3*s2 vpmuludq $H4,$T1,$H2 # h4*s2 vpaddq $T4,$D0,$D0 # d0 += h3*s2 vpaddq $H2,$D1,$D1 # d1 += h4*s2 vmovdqu `32*5+4-0x90`(%rax),$H2 # r3 vpmuludq $H1,$T2,$T4 # h1*r2 vpmuludq $H0,$T2,$T2 # h0*r2 vpaddq $T4,$D3,$D3 # d3 += h1*r2 vpaddq $T2,$D2,$D2 # d2 += h0*r2 vpmuludq $H1,$H2,$T4 # h1*r3 vpmuludq $H0,$H2,$H2 # h0*r3 vpaddq $T4,$D4,$D4 # d4 += h1*r3 vpaddq $H2,$D3,$D3 # d3 += h0*r3 vpmuludq $H3,$T3,$T4 # h3*s3 vpmuludq $H4,$T3,$H2 # h4*s3 vpaddq $T4,$D1,$D1 # d1 += h3*s3 vpaddq $H2,$D2,$D2 # d2 += h4*s3 vpmuludq $H3,$S4,$H3 # h3*s4 vpmuludq $H4,$S4,$H4 # h4*s4 vpaddq $H3,$D2,$H2 # h2 = d2 + h3*r4 vpaddq $H4,$D3,$H3 # h3 = d3 + h4*r4 vpmuludq `32*7+4-0x90`(%rax),$H0,$H4 # h0*r4 vpmuludq $H1,$S4,$H0 # h1*s4 vmovdqa 64(%rcx),$MASK # .Lmask26 vpaddq $H4,$D4,$H4 # h4 = d4 + h0*r4 vpaddq $H0,$D0,$H0 # h0 = d0 + h1*s4 ################################################################ # lazy reduction vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$D1,$H1 # h0 -> h1 vpsrlq \$26,$H4,$D4 vpand $MASK,$H4,$H4 vpsrlq \$26,$H1,$D1 vpand $MASK,$H1,$H1 vpaddq $D1,$H2,$H2 # h1 -> h2 vpaddq $D4,$H0,$H0 vpsllq \$2,$D4,$D4 vpaddq $D4,$H0,$H0 # h4 -> h0 vpsrlq \$26,$H2,$D2 vpand $MASK,$H2,$H2 vpaddq $D2,$H3,$H3 # h2 -> h3 vpsrlq \$26,$H0,$D0 vpand $MASK,$H0,$H0 vpaddq $D0,$H1,$H1 # h0 -> h1 vpsrlq \$26,$H3,$D3 vpand $MASK,$H3,$H3 vpaddq $D3,$H4,$H4 # h3 -> h4 ################################################################ # horizontal addition vpsrldq \$8,$H2,$T2 vpsrldq \$8,$H0,$T0 vpsrldq \$8,$H1,$T1 vpsrldq \$8,$H3,$T3 vpsrldq \$8,$H4,$T4 vpaddq $T2,$H2,$H2 vpaddq $T0,$H0,$H0 vpaddq $T1,$H1,$H1 vpaddq $T3,$H3,$H3 vpaddq $T4,$H4,$H4 vpermq \$0x2,$H2,$T2 vpermq \$0x2,$H0,$T0 vpermq \$0x2,$H1,$T1 vpermq \$0x2,$H3,$T3 vpermq \$0x2,$H4,$T4 vpaddq $T2,$H2,$H2 vpaddq $T0,$H0,$H0 vpaddq $T1,$H1,$H1 vpaddq $T3,$H3,$H3 vpaddq $T4,$H4,$H4 vmovd %x#$H0,`4*0-48-64`($ctx)# save partially reduced vmovd %x#$H1,`4*1-48-64`($ctx) vmovd %x#$H2,`4*2-48-64`($ctx) vmovd %x#$H3,`4*3-48-64`($ctx) vmovd %x#$H4,`4*4-48-64`($ctx) ___ $code.=<<___ if ($win64); vmovdqa 0x50(%r11),%xmm6 vmovdqa 0x60(%r11),%xmm7 vmovdqa 0x70(%r11),%xmm8 vmovdqa 0x80(%r11),%xmm9 vmovdqa 0x90(%r11),%xmm10 vmovdqa 0xa0(%r11),%xmm11 vmovdqa 0xb0(%r11),%xmm12 vmovdqa 0xc0(%r11),%xmm13 vmovdqa 0xd0(%r11),%xmm14 vmovdqa 0xe0(%r11),%xmm15 lea 0xf8(%r11),%rsp .Ldo_avx2_epilogue: ___ $code.=<<___ if (!$win64); lea 8(%r11),%rsp ___ $code.=<<___; vzeroupper ret .size poly1305_blocks_avx2,.-poly1305_blocks_avx2 ___ } $code.=<<___; .align 64 .Lconst: .Lmask24: .long 0x0ffffff,0,0x0ffffff,0,0x0ffffff,0,0x0ffffff,0 .L129: .long 1<<24,0,1<<24,0,1<<24,0,1<<24,0 .Lmask26: .long 0x3ffffff,0,0x3ffffff,0,0x3ffffff,0,0x3ffffff,0 .Lfive: .long 5,0,5,0,5,0,5,0 ___ } $code.=<<___; .asciz "Poly1305 for x86_64, CRYPTOGAMS by " .align 16 ___ # EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame, # CONTEXT *context,DISPATCHER_CONTEXT *disp) if ($win64) { $rec="%rcx"; $frame="%rdx"; $context="%r8"; $disp="%r9"; $code.=<<___; .extern __imp_RtlVirtualUnwind .type se_handler,\@abi-omnipotent .align 16 se_handler: push %rsi push %rdi push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 pushfq sub \$64,%rsp mov 120($context),%rax # pull context->Rax mov 248($context),%rbx # pull context->Rip mov 8($disp),%rsi # disp->ImageBase mov 56($disp),%r11 # disp->HandlerData mov 0(%r11),%r10d # HandlerData[0] lea (%rsi,%r10),%r10 # prologue label cmp %r10,%rbx # context->Rip<.Lprologue jb .Lcommon_seh_tail mov 152($context),%rax # pull context->Rsp mov 4(%r11),%r10d # HandlerData[1] lea (%rsi,%r10),%r10 # epilogue label cmp %r10,%rbx # context->Rip>=.Lepilogue jae .Lcommon_seh_tail lea 48(%rax),%rax mov -8(%rax),%rbx mov -16(%rax),%rbp mov -24(%rax),%r12 mov -32(%rax),%r13 mov -40(%rax),%r14 mov -48(%rax),%r15 mov %rbx,144($context) # restore context->Rbx mov %rbp,160($context) # restore context->Rbp mov %r12,216($context) # restore context->R12 mov %r13,224($context) # restore context->R13 mov %r14,232($context) # restore context->R14 mov %r15,240($context) # restore context->R14 jmp .Lcommon_seh_tail .size se_handler,.-se_handler .type avx_handler,\@abi-omnipotent .align 16 avx_handler: push %rsi push %rdi push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 pushfq sub \$64,%rsp mov 120($context),%rax # pull context->Rax mov 248($context),%rbx # pull context->Rip mov 8($disp),%rsi # disp->ImageBase mov 56($disp),%r11 # disp->HandlerData mov 0(%r11),%r10d # HandlerData[0] lea (%rsi,%r10),%r10 # prologue label cmp %r10,%rbx # context->RipRsp mov 4(%r11),%r10d # HandlerData[1] lea (%rsi,%r10),%r10 # epilogue label cmp %r10,%rbx # context->Rip>=epilogue label jae .Lcommon_seh_tail mov 208($context),%rax # pull context->R11 lea 0x50(%rax),%rsi lea 0xf8(%rax),%rax lea 512($context),%rdi # &context.Xmm6 mov \$20,%ecx .long 0xa548f3fc # cld; rep movsq .Lcommon_seh_tail: mov 8(%rax),%rdi mov 16(%rax),%rsi mov %rax,152($context) # restore context->Rsp mov %rsi,168($context) # restore context->Rsi mov %rdi,176($context) # restore context->Rdi mov 40($disp),%rdi # disp->ContextRecord mov $context,%rsi # context mov \$154,%ecx # sizeof(CONTEXT) .long 0xa548f3fc # cld; rep movsq mov $disp,%rsi xor %rcx,%rcx # arg1, UNW_FLAG_NHANDLER mov 8(%rsi),%rdx # arg2, disp->ImageBase mov 0(%rsi),%r8 # arg3, disp->ControlPc mov 16(%rsi),%r9 # arg4, disp->FunctionEntry mov 40(%rsi),%r10 # disp->ContextRecord lea 56(%rsi),%r11 # &disp->HandlerData lea 24(%rsi),%r12 # &disp->EstablisherFrame mov %r10,32(%rsp) # arg5 mov %r11,40(%rsp) # arg6 mov %r12,48(%rsp) # arg7 mov %rcx,56(%rsp) # arg8, (NULL) call *__imp_RtlVirtualUnwind(%rip) mov \$1,%eax # ExceptionContinueSearch add \$64,%rsp popfq pop %r15 pop %r14 pop %r13 pop %r12 pop %rbp pop %rbx pop %rdi pop %rsi ret .size avx_handler,.-avx_handler .section .pdata .align 4 .rva .LSEH_begin_poly1305_init .rva .LSEH_end_poly1305_init .rva .LSEH_info_poly1305_init .rva .LSEH_begin_poly1305_blocks .rva .LSEH_end_poly1305_blocks .rva .LSEH_info_poly1305_blocks .rva .LSEH_begin_poly1305_emit .rva .LSEH_end_poly1305_emit .rva .LSEH_info_poly1305_emit ___ $code.=<<___ if ($avx); .rva .LSEH_begin_poly1305_blocks_avx .rva .Lbase2_64_avx .rva .LSEH_info_poly1305_blocks_avx_1 .rva .Lbase2_64_avx .rva .Leven_avx .rva .LSEH_info_poly1305_blocks_avx_2 .rva .Leven_avx .rva .LSEH_end_poly1305_blocks_avx .rva .LSEH_info_poly1305_blocks_avx_3 .rva .LSEH_begin_poly1305_emit_avx .rva .LSEH_end_poly1305_emit_avx .rva .LSEH_info_poly1305_emit_avx ___ $code.=<<___ if ($avx>1); .rva .LSEH_begin_poly1305_blocks_avx2 .rva .Lbase2_64_avx2 .rva .LSEH_info_poly1305_blocks_avx2_1 .rva .Lbase2_64_avx2 .rva .Leven_avx2 .rva .LSEH_info_poly1305_blocks_avx2_2 .rva .Leven_avx2 .rva .LSEH_end_poly1305_blocks_avx2 .rva .LSEH_info_poly1305_blocks_avx2_3 ___ $code.=<<___; .section .xdata .align 8 .LSEH_info_poly1305_init: .byte 9,0,0,0 .rva se_handler .rva .LSEH_begin_poly1305_init,.LSEH_begin_poly1305_init .LSEH_info_poly1305_blocks: .byte 9,0,0,0 .rva se_handler .rva .Lblocks_body,.Lblocks_epilogue .LSEH_info_poly1305_emit: .byte 9,0,0,0 .rva se_handler .rva .LSEH_begin_poly1305_emit,.LSEH_begin_poly1305_emit ___ $code.=<<___ if ($avx); .LSEH_info_poly1305_blocks_avx_1: .byte 9,0,0,0 .rva se_handler .rva .Lblocks_avx_body,.Lblocks_avx_epilogue # HandlerData[] .LSEH_info_poly1305_blocks_avx_2: .byte 9,0,0,0 .rva se_handler .rva .Lbase2_64_avx_body,.Lbase2_64_avx_epilogue # HandlerData[] .LSEH_info_poly1305_blocks_avx_3: .byte 9,0,0,0 .rva avx_handler .rva .Ldo_avx_body,.Ldo_avx_epilogue # HandlerData[] .LSEH_info_poly1305_emit_avx: .byte 9,0,0,0 .rva se_handler .rva .LSEH_begin_poly1305_emit_avx,.LSEH_begin_poly1305_emit_avx ___ $code.=<<___ if ($avx>1); .LSEH_info_poly1305_blocks_avx2_1: .byte 9,0,0,0 .rva se_handler .rva .Lblocks_avx2_body,.Lblocks_avx2_epilogue # HandlerData[] .LSEH_info_poly1305_blocks_avx2_2: .byte 9,0,0,0 .rva se_handler .rva .Lbase2_64_avx2_body,.Lbase2_64_avx2_epilogue # HandlerData[] .LSEH_info_poly1305_blocks_avx2_3: .byte 9,0,0,0 .rva avx_handler .rva .Ldo_avx2_body,.Ldo_avx2_epilogue # HandlerData[] ___ } foreach (split('\n',$code)) { s/\`([^\`]*)\`/eval($1)/ge; s/%r([a-z]+)#d/%e$1/g; s/%r([0-9]+)#d/%r$1d/g; s/%x#%y/%x/g; print $_,"\n"; } close STDOUT;