#!/usr/bin/env perl # SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause # # This code is taken from the OpenSSL project but the author, Andy Polyakov, # has relicensed it under the licenses specified in the SPDX header above. # The original headers, including the original license headers, are # included below for completeness. # # ==================================================================== # 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/. # ==================================================================== # # IALU(*)/gcc-4.4 NEON # # ARM11xx(ARMv6) 7.78/+100% - # Cortex-A5 6.35/+130% 3.00 # Cortex-A8 6.25/+115% 2.36 # Cortex-A9 5.10/+95% 2.55 # Cortex-A15 3.85/+85% 1.25(**) # Snapdragon S4 5.70/+100% 1.48(**) # # (*) this is for -march=armv6, i.e. with bunch of ldrb loading data; # (**) these are trade-off results, they can be improved by ~8% but at # the cost of 15/12% regression on Cortex-A5/A7, it's even possible # to improve Cortex-A9 result, but then A5/A7 loose more than 20%; $flavour = shift; if ($flavour=~/\w[\w\-]*\.\w+$/) { $output=$flavour; undef $flavour; } else { while (($output=shift) && ($output!~/\w[\w\-]*\.\w+$/)) {} } if ($flavour && $flavour ne "void") { $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1; ( $xlate="${dir}arm-xlate.pl" and -f $xlate ) or ( $xlate="${dir}../../perlasm/arm-xlate.pl" and -f $xlate) or die "can't locate arm-xlate.pl"; open STDOUT,"| \"$^X\" $xlate $flavour $output"; } else { open STDOUT,">$output"; } ($ctx,$inp,$len,$padbit)=map("r$_",(0..3)); $code.=<<___; #ifndef __KERNEL__ # include "arm_arch.h" #else # define __ARM_ARCH__ __LINUX_ARM_ARCH__ # define __ARM_MAX_ARCH__ __LINUX_ARM_ARCH__ # define poly1305_init poly1305_init_arm # define poly1305_blocks poly1305_blocks_arm # define poly1305_emit poly1305_emit_arm #endif .text #if defined(__thumb2__) .syntax unified .thumb #else .code 32 #endif .globl poly1305_emit .globl poly1305_blocks .globl poly1305_init .type poly1305_init,%function .align 5 poly1305_init: .Lpoly1305_init: stmdb sp!,{r4-r11} eor r3,r3,r3 cmp $inp,#0 str r3,[$ctx,#0] @ zero hash value str r3,[$ctx,#4] str r3,[$ctx,#8] str r3,[$ctx,#12] str r3,[$ctx,#16] str r3,[$ctx,#36] @ is_base2_26 add $ctx,$ctx,#20 #ifdef __thumb2__ it eq #endif moveq r0,#0 beq .Lno_key #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__) adr r11,.Lpoly1305_init ldr r12,.LOPENSSL_armcap #endif ldrb r4,[$inp,#0] mov r10,#0x0fffffff ldrb r5,[$inp,#1] and r3,r10,#-4 @ 0x0ffffffc ldrb r6,[$inp,#2] ldrb r7,[$inp,#3] orr r4,r4,r5,lsl#8 ldrb r5,[$inp,#4] orr r4,r4,r6,lsl#16 ldrb r6,[$inp,#5] orr r4,r4,r7,lsl#24 ldrb r7,[$inp,#6] and r4,r4,r10 #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__) ldr r12,[r11,r12] @ OPENSSL_armcap_P # ifdef __APPLE__ ldr r12,[r12] # endif #endif ldrb r8,[$inp,#7] orr r5,r5,r6,lsl#8 ldrb r6,[$inp,#8] orr r5,r5,r7,lsl#16 ldrb r7,[$inp,#9] orr r5,r5,r8,lsl#24 ldrb r8,[$inp,#10] and r5,r5,r3 #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__) tst r12,#ARMV7_NEON @ check for NEON # ifdef __APPLE__ adr r9,poly1305_blocks_neon adr r11,poly1305_blocks # ifdef __thumb2__ it ne # endif movne r11,r9 adr r12,poly1305_emit adr r10,poly1305_emit_neon # ifdef __thumb2__ it ne # endif movne r12,r10 # else # ifdef __thumb2__ itete eq # endif addeq r12,r11,#(poly1305_emit-.Lpoly1305_init) addne r12,r11,#(poly1305_emit_neon-.Lpoly1305_init) addeq r11,r11,#(poly1305_blocks-.Lpoly1305_init) addne r11,r11,#(poly1305_blocks_neon-.Lpoly1305_init) # endif # ifdef __thumb2__ orr r12,r12,#1 @ thumb-ify address orr r11,r11,#1 # endif #endif ldrb r9,[$inp,#11] orr r6,r6,r7,lsl#8 ldrb r7,[$inp,#12] orr r6,r6,r8,lsl#16 ldrb r8,[$inp,#13] orr r6,r6,r9,lsl#24 ldrb r9,[$inp,#14] and r6,r6,r3 ldrb r10,[$inp,#15] orr r7,r7,r8,lsl#8 str r4,[$ctx,#0] orr r7,r7,r9,lsl#16 str r5,[$ctx,#4] orr r7,r7,r10,lsl#24 str r6,[$ctx,#8] and r7,r7,r3 str r7,[$ctx,#12] #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__) stmia r2,{r11,r12} @ fill functions table mov r0,#1 #else mov r0,#0 #endif .Lno_key: ldmia sp!,{r4-r11} #if __ARM_ARCH__>=5 ret @ bx lr #else tst lr,#1 moveq pc,lr @ be binary compatible with V4, yet bx lr @ interoperable with Thumb ISA:-) #endif .size poly1305_init,.-poly1305_init ___ { my ($h0,$h1,$h2,$h3,$h4,$r0,$r1,$r2,$r3)=map("r$_",(4..12)); my ($s1,$s2,$s3)=($r1,$r2,$r3); $code.=<<___; .type poly1305_blocks,%function .align 5 poly1305_blocks: .Lpoly1305_blocks: stmdb sp!,{r3-r11,lr} ands $len,$len,#-16 beq .Lno_data cmp $padbit,#0 add $len,$len,$inp @ end pointer sub sp,sp,#32 ldmia $ctx,{$h0-$r3} @ load context str $ctx,[sp,#12] @ offload stuff mov lr,$inp str $len,[sp,#16] str $r1,[sp,#20] str $r2,[sp,#24] str $r3,[sp,#28] b .Loop .Loop: #if __ARM_ARCH__<7 ldrb r0,[lr],#16 @ load input # ifdef __thumb2__ it hi # endif addhi $h4,$h4,#1 @ 1<<128 ldrb r1,[lr,#-15] ldrb r2,[lr,#-14] ldrb r3,[lr,#-13] orr r1,r0,r1,lsl#8 ldrb r0,[lr,#-12] orr r2,r1,r2,lsl#16 ldrb r1,[lr,#-11] orr r3,r2,r3,lsl#24 ldrb r2,[lr,#-10] adds $h0,$h0,r3 @ accumulate input ldrb r3,[lr,#-9] orr r1,r0,r1,lsl#8 ldrb r0,[lr,#-8] orr r2,r1,r2,lsl#16 ldrb r1,[lr,#-7] orr r3,r2,r3,lsl#24 ldrb r2,[lr,#-6] adcs $h1,$h1,r3 ldrb r3,[lr,#-5] orr r1,r0,r1,lsl#8 ldrb r0,[lr,#-4] orr r2,r1,r2,lsl#16 ldrb r1,[lr,#-3] orr r3,r2,r3,lsl#24 ldrb r2,[lr,#-2] adcs $h2,$h2,r3 ldrb r3,[lr,#-1] orr r1,r0,r1,lsl#8 str lr,[sp,#8] @ offload input pointer orr r2,r1,r2,lsl#16 add $s1,$r1,$r1,lsr#2 orr r3,r2,r3,lsl#24 #else ldr r0,[lr],#16 @ load input # ifdef __thumb2__ it hi # endif addhi $h4,$h4,#1 @ padbit ldr r1,[lr,#-12] ldr r2,[lr,#-8] ldr r3,[lr,#-4] # ifdef __ARMEB__ rev r0,r0 rev r1,r1 rev r2,r2 rev r3,r3 # endif adds $h0,$h0,r0 @ accumulate input str lr,[sp,#8] @ offload input pointer adcs $h1,$h1,r1 add $s1,$r1,$r1,lsr#2 adcs $h2,$h2,r2 #endif add $s2,$r2,$r2,lsr#2 adcs $h3,$h3,r3 add $s3,$r3,$r3,lsr#2 umull r2,r3,$h1,$r0 adc $h4,$h4,#0 umull r0,r1,$h0,$r0 umlal r2,r3,$h4,$s1 umlal r0,r1,$h3,$s1 ldr $r1,[sp,#20] @ reload $r1 umlal r2,r3,$h2,$s3 umlal r0,r1,$h1,$s3 umlal r2,r3,$h3,$s2 umlal r0,r1,$h2,$s2 umlal r2,r3,$h0,$r1 str r0,[sp,#0] @ future $h0 mul r0,$s2,$h4 ldr $r2,[sp,#24] @ reload $r2 adds r2,r2,r1 @ d1+=d0>>32 eor r1,r1,r1 adc lr,r3,#0 @ future $h2 str r2,[sp,#4] @ future $h1 mul r2,$s3,$h4 eor r3,r3,r3 umlal r0,r1,$h3,$s3 ldr $r3,[sp,#28] @ reload $r3 umlal r2,r3,$h3,$r0 umlal r0,r1,$h2,$r0 umlal r2,r3,$h2,$r1 umlal r0,r1,$h1,$r1 umlal r2,r3,$h1,$r2 umlal r0,r1,$h0,$r2 umlal r2,r3,$h0,$r3 ldr $h0,[sp,#0] mul $h4,$r0,$h4 ldr $h1,[sp,#4] adds $h2,lr,r0 @ d2+=d1>>32 ldr lr,[sp,#8] @ reload input pointer adc r1,r1,#0 adds $h3,r2,r1 @ d3+=d2>>32 ldr r0,[sp,#16] @ reload end pointer adc r3,r3,#0 add $h4,$h4,r3 @ h4+=d3>>32 and r1,$h4,#-4 and $h4,$h4,#3 add r1,r1,r1,lsr#2 @ *=5 adds $h0,$h0,r1 adcs $h1,$h1,#0 adcs $h2,$h2,#0 adcs $h3,$h3,#0 adc $h4,$h4,#0 cmp r0,lr @ done yet? bhi .Loop ldr $ctx,[sp,#12] add sp,sp,#32 stmia $ctx,{$h0-$h4} @ store the result .Lno_data: #if __ARM_ARCH__>=5 ldmia sp!,{r3-r11,pc} #else ldmia sp!,{r3-r11,lr} tst lr,#1 moveq pc,lr @ be binary compatible with V4, yet bx lr @ interoperable with Thumb ISA:-) #endif .size poly1305_blocks,.-poly1305_blocks ___ } { my ($ctx,$mac,$nonce)=map("r$_",(0..2)); my ($h0,$h1,$h2,$h3,$h4,$g0,$g1,$g2,$g3)=map("r$_",(3..11)); my $g4=$h4; $code.=<<___; .type poly1305_emit,%function .align 5 poly1305_emit: stmdb sp!,{r4-r11} .Lpoly1305_emit_enter: ldmia $ctx,{$h0-$h4} adds $g0,$h0,#5 @ compare to modulus adcs $g1,$h1,#0 adcs $g2,$h2,#0 adcs $g3,$h3,#0 adc $g4,$h4,#0 tst $g4,#4 @ did it carry/borrow? #ifdef __thumb2__ it ne #endif movne $h0,$g0 ldr $g0,[$nonce,#0] #ifdef __thumb2__ it ne #endif movne $h1,$g1 ldr $g1,[$nonce,#4] #ifdef __thumb2__ it ne #endif movne $h2,$g2 ldr $g2,[$nonce,#8] #ifdef __thumb2__ it ne #endif movne $h3,$g3 ldr $g3,[$nonce,#12] adds $h0,$h0,$g0 adcs $h1,$h1,$g1 adcs $h2,$h2,$g2 adc $h3,$h3,$g3 #if __ARM_ARCH__>=7 # ifdef __ARMEB__ rev $h0,$h0 rev $h1,$h1 rev $h2,$h2 rev $h3,$h3 # endif str $h0,[$mac,#0] str $h1,[$mac,#4] str $h2,[$mac,#8] str $h3,[$mac,#12] #else strb $h0,[$mac,#0] mov $h0,$h0,lsr#8 strb $h1,[$mac,#4] mov $h1,$h1,lsr#8 strb $h2,[$mac,#8] mov $h2,$h2,lsr#8 strb $h3,[$mac,#12] mov $h3,$h3,lsr#8 strb $h0,[$mac,#1] mov $h0,$h0,lsr#8 strb $h1,[$mac,#5] mov $h1,$h1,lsr#8 strb $h2,[$mac,#9] mov $h2,$h2,lsr#8 strb $h3,[$mac,#13] mov $h3,$h3,lsr#8 strb $h0,[$mac,#2] mov $h0,$h0,lsr#8 strb $h1,[$mac,#6] mov $h1,$h1,lsr#8 strb $h2,[$mac,#10] mov $h2,$h2,lsr#8 strb $h3,[$mac,#14] mov $h3,$h3,lsr#8 strb $h0,[$mac,#3] strb $h1,[$mac,#7] strb $h2,[$mac,#11] strb $h3,[$mac,#15] #endif ldmia sp!,{r4-r11} #if __ARM_ARCH__>=5 ret @ bx lr #else tst lr,#1 moveq pc,lr @ be binary compatible with V4, yet bx lr @ interoperable with Thumb ISA:-) #endif .size poly1305_emit,.-poly1305_emit ___ { my ($R0,$R1,$S1,$R2,$S2,$R3,$S3,$R4,$S4) = map("d$_",(0..9)); my ($D0,$D1,$D2,$D3,$D4, $H0,$H1,$H2,$H3,$H4) = map("q$_",(5..14)); my ($T0,$T1,$MASK) = map("q$_",(15,4,0)); my ($in2,$zeros,$tbl0,$tbl1) = map("r$_",(4..7)); $code.=<<___; #if (defined(__KERNEL__) && defined(CONFIG_KERNEL_MODE_NEON)) || (!defined(__KERNEL__) && __ARM_MAX_ARCH__>=7) .fpu neon .type poly1305_init_neon,%function .align 5 poly1305_init_neon: .Lpoly1305_init_neon: ldr r4,[$ctx,#20] @ load key base 2^32 ldr r5,[$ctx,#24] ldr r6,[$ctx,#28] ldr r7,[$ctx,#32] and r2,r4,#0x03ffffff @ base 2^32 -> base 2^26 mov r3,r4,lsr#26 mov r4,r5,lsr#20 orr r3,r3,r5,lsl#6 mov r5,r6,lsr#14 orr r4,r4,r6,lsl#12 mov r6,r7,lsr#8 orr r5,r5,r7,lsl#18 and r3,r3,#0x03ffffff and r4,r4,#0x03ffffff and r5,r5,#0x03ffffff vdup.32 $R0,r2 @ r^1 in both lanes add r2,r3,r3,lsl#2 @ *5 vdup.32 $R1,r3 add r3,r4,r4,lsl#2 vdup.32 $S1,r2 vdup.32 $R2,r4 add r4,r5,r5,lsl#2 vdup.32 $S2,r3 vdup.32 $R3,r5 add r5,r6,r6,lsl#2 vdup.32 $S3,r4 vdup.32 $R4,r6 vdup.32 $S4,r5 mov $zeros,#2 @ counter .Lsquare_neon: @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ d0 = h0*r0 + h4*5*r1 + h3*5*r2 + h2*5*r3 + h1*5*r4 @ d1 = h1*r0 + h0*r1 + h4*5*r2 + h3*5*r3 + h2*5*r4 @ d2 = h2*r0 + h1*r1 + h0*r2 + h4*5*r3 + h3*5*r4 @ d3 = h3*r0 + h2*r1 + h1*r2 + h0*r3 + h4*5*r4 @ d4 = h4*r0 + h3*r1 + h2*r2 + h1*r3 + h0*r4 vmull.u32 $D0,$R0,${R0}[1] vmull.u32 $D1,$R1,${R0}[1] vmull.u32 $D2,$R2,${R0}[1] vmull.u32 $D3,$R3,${R0}[1] vmull.u32 $D4,$R4,${R0}[1] vmlal.u32 $D0,$R4,${S1}[1] vmlal.u32 $D1,$R0,${R1}[1] vmlal.u32 $D2,$R1,${R1}[1] vmlal.u32 $D3,$R2,${R1}[1] vmlal.u32 $D4,$R3,${R1}[1] vmlal.u32 $D0,$R3,${S2}[1] vmlal.u32 $D1,$R4,${S2}[1] vmlal.u32 $D3,$R1,${R2}[1] vmlal.u32 $D2,$R0,${R2}[1] vmlal.u32 $D4,$R2,${R2}[1] vmlal.u32 $D0,$R2,${S3}[1] vmlal.u32 $D3,$R0,${R3}[1] vmlal.u32 $D1,$R3,${S3}[1] vmlal.u32 $D2,$R4,${S3}[1] vmlal.u32 $D4,$R1,${R3}[1] vmlal.u32 $D3,$R4,${S4}[1] vmlal.u32 $D0,$R1,${S4}[1] vmlal.u32 $D1,$R2,${S4}[1] vmlal.u32 $D2,$R3,${S4}[1] vmlal.u32 $D4,$R0,${R4}[1] @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ lazy reduction as discussed in "NEON crypto" by D.J. Bernstein @ and P. Schwabe @ @ H0>>+H1>>+H2>>+H3>>+H4 @ H3>>+H4>>*5+H0>>+H1 @ @ Trivia. @ @ Result of multiplication of n-bit number by m-bit number is @ n+m bits wide. However! Even though 2^n is a n+1-bit number, @ m-bit number multiplied by 2^n is still n+m bits wide. @ @ Sum of two n-bit numbers is n+1 bits wide, sum of three - n+2, @ and so is sum of four. Sum of 2^m n-m-bit numbers and n-bit @ one is n+1 bits wide. @ @ >>+ denotes Hnext += Hn>>26, Hn &= 0x3ffffff. This means that @ H0, H2, H3 are guaranteed to be 26 bits wide, while H1 and H4 @ can be 27. However! In cases when their width exceeds 26 bits @ they are limited by 2^26+2^6. This in turn means that *sum* @ of the products with these values can still be viewed as sum @ of 52-bit numbers as long as the amount of addends is not a @ power of 2. For example, @ @ H4 = H4*R0 + H3*R1 + H2*R2 + H1*R3 + H0 * R4, @ @ which can't be larger than 5 * (2^26 + 2^6) * (2^26 + 2^6), or @ 5 * (2^52 + 2*2^32 + 2^12), which in turn is smaller than @ 8 * (2^52) or 2^55. However, the value is then multiplied by @ by 5, so we should be looking at 5 * 5 * (2^52 + 2^33 + 2^12), @ which is less than 32 * (2^52) or 2^57. And when processing @ data we are looking at triple as many addends... @ @ In key setup procedure pre-reduced H0 is limited by 5*4+1 and @ 5*H4 - by 5*5 52-bit addends, or 57 bits. But when hashing the @ input H0 is limited by (5*4+1)*3 addends, or 58 bits, while @ 5*H4 by 5*5*3, or 59[!] bits. How is this relevant? vmlal.u32 @ instruction accepts 2x32-bit input and writes 2x64-bit result. @ This means that result of reduction have to be compressed upon @ loop wrap-around. This can be done in the process of reduction @ to minimize amount of instructions [as well as amount of @ 128-bit instructions, which benefits low-end processors], but @ one has to watch for H2 (which is narrower than H0) and 5*H4 @ not being wider than 58 bits, so that result of right shift @ by 26 bits fits in 32 bits. This is also useful on x86, @ because it allows to use paddd in place for paddq, which @ benefits Atom, where paddq is ridiculously slow. vshr.u64 $T0,$D3,#26 vmovn.i64 $D3#lo,$D3 vshr.u64 $T1,$D0,#26 vmovn.i64 $D0#lo,$D0 vadd.i64 $D4,$D4,$T0 @ h3 -> h4 vbic.i32 $D3#lo,#0xfc000000 @ &=0x03ffffff vadd.i64 $D1,$D1,$T1 @ h0 -> h1 vbic.i32 $D0#lo,#0xfc000000 vshrn.u64 $T0#lo,$D4,#26 vmovn.i64 $D4#lo,$D4 vshr.u64 $T1,$D1,#26 vmovn.i64 $D1#lo,$D1 vadd.i64 $D2,$D2,$T1 @ h1 -> h2 vbic.i32 $D4#lo,#0xfc000000 vbic.i32 $D1#lo,#0xfc000000 vadd.i32 $D0#lo,$D0#lo,$T0#lo vshl.u32 $T0#lo,$T0#lo,#2 vshrn.u64 $T1#lo,$D2,#26 vmovn.i64 $D2#lo,$D2 vadd.i32 $D0#lo,$D0#lo,$T0#lo @ h4 -> h0 vadd.i32 $D3#lo,$D3#lo,$T1#lo @ h2 -> h3 vbic.i32 $D2#lo,#0xfc000000 vshr.u32 $T0#lo,$D0#lo,#26 vbic.i32 $D0#lo,#0xfc000000 vshr.u32 $T1#lo,$D3#lo,#26 vbic.i32 $D3#lo,#0xfc000000 vadd.i32 $D1#lo,$D1#lo,$T0#lo @ h0 -> h1 vadd.i32 $D4#lo,$D4#lo,$T1#lo @ h3 -> h4 subs $zeros,$zeros,#1 beq .Lsquare_break_neon add $tbl0,$ctx,#(48+0*9*4) add $tbl1,$ctx,#(48+1*9*4) vtrn.32 $R0,$D0#lo @ r^2:r^1 vtrn.32 $R2,$D2#lo vtrn.32 $R3,$D3#lo vtrn.32 $R1,$D1#lo vtrn.32 $R4,$D4#lo vshl.u32 $S2,$R2,#2 @ *5 vshl.u32 $S3,$R3,#2 vshl.u32 $S1,$R1,#2 vshl.u32 $S4,$R4,#2 vadd.i32 $S2,$S2,$R2 vadd.i32 $S1,$S1,$R1 vadd.i32 $S3,$S3,$R3 vadd.i32 $S4,$S4,$R4 vst4.32 {${R0}[0],${R1}[0],${S1}[0],${R2}[0]},[$tbl0]! vst4.32 {${R0}[1],${R1}[1],${S1}[1],${R2}[1]},[$tbl1]! vst4.32 {${S2}[0],${R3}[0],${S3}[0],${R4}[0]},[$tbl0]! vst4.32 {${S2}[1],${R3}[1],${S3}[1],${R4}[1]},[$tbl1]! vst1.32 {${S4}[0]},[$tbl0,:32] vst1.32 {${S4}[1]},[$tbl1,:32] b .Lsquare_neon .align 4 .Lsquare_break_neon: add $tbl0,$ctx,#(48+2*4*9) add $tbl1,$ctx,#(48+3*4*9) vmov $R0,$D0#lo @ r^4:r^3 vshl.u32 $S1,$D1#lo,#2 @ *5 vmov $R1,$D1#lo vshl.u32 $S2,$D2#lo,#2 vmov $R2,$D2#lo vshl.u32 $S3,$D3#lo,#2 vmov $R3,$D3#lo vshl.u32 $S4,$D4#lo,#2 vmov $R4,$D4#lo vadd.i32 $S1,$S1,$D1#lo vadd.i32 $S2,$S2,$D2#lo vadd.i32 $S3,$S3,$D3#lo vadd.i32 $S4,$S4,$D4#lo vst4.32 {${R0}[0],${R1}[0],${S1}[0],${R2}[0]},[$tbl0]! vst4.32 {${R0}[1],${R1}[1],${S1}[1],${R2}[1]},[$tbl1]! vst4.32 {${S2}[0],${R3}[0],${S3}[0],${R4}[0]},[$tbl0]! vst4.32 {${S2}[1],${R3}[1],${S3}[1],${R4}[1]},[$tbl1]! vst1.32 {${S4}[0]},[$tbl0] vst1.32 {${S4}[1]},[$tbl1] ret @ bx lr .size poly1305_init_neon,.-poly1305_init_neon #ifdef __KERNEL__ .globl poly1305_blocks_neon #endif .type poly1305_blocks_neon,%function .align 5 poly1305_blocks_neon: ldr ip,[$ctx,#36] @ is_base2_26 ands $len,$len,#-16 beq .Lno_data_neon cmp $len,#64 bhs .Lenter_neon tst ip,ip @ is_base2_26? beq .Lpoly1305_blocks .Lenter_neon: stmdb sp!,{r4-r7} vstmdb sp!,{d8-d15} @ ABI specification says so tst ip,ip @ is_base2_26? bne .Lbase2_26_neon stmdb sp!,{r1-r3,lr} bl .Lpoly1305_init_neon ldr r4,[$ctx,#0] @ load hash value base 2^32 ldr r5,[$ctx,#4] ldr r6,[$ctx,#8] ldr r7,[$ctx,#12] ldr ip,[$ctx,#16] and r2,r4,#0x03ffffff @ base 2^32 -> base 2^26 mov r3,r4,lsr#26 veor $D0#lo,$D0#lo,$D0#lo mov r4,r5,lsr#20 orr r3,r3,r5,lsl#6 veor $D1#lo,$D1#lo,$D1#lo mov r5,r6,lsr#14 orr r4,r4,r6,lsl#12 veor $D2#lo,$D2#lo,$D2#lo mov r6,r7,lsr#8 orr r5,r5,r7,lsl#18 veor $D3#lo,$D3#lo,$D3#lo and r3,r3,#0x03ffffff orr r6,r6,ip,lsl#24 veor $D4#lo,$D4#lo,$D4#lo and r4,r4,#0x03ffffff mov r1,#1 and r5,r5,#0x03ffffff str r1,[$ctx,#36] @ is_base2_26 vmov.32 $D0#lo[0],r2 vmov.32 $D1#lo[0],r3 vmov.32 $D2#lo[0],r4 vmov.32 $D3#lo[0],r5 vmov.32 $D4#lo[0],r6 adr $zeros,.Lzeros ldmia sp!,{r1-r3,lr} b .Lbase2_32_neon .align 4 .Lbase2_26_neon: @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ load hash value veor $D0#lo,$D0#lo,$D0#lo veor $D1#lo,$D1#lo,$D1#lo veor $D2#lo,$D2#lo,$D2#lo veor $D3#lo,$D3#lo,$D3#lo veor $D4#lo,$D4#lo,$D4#lo vld4.32 {$D0#lo[0],$D1#lo[0],$D2#lo[0],$D3#lo[0]},[$ctx]! adr $zeros,.Lzeros vld1.32 {$D4#lo[0]},[$ctx] sub $ctx,$ctx,#16 @ rewind .Lbase2_32_neon: add $in2,$inp,#32 mov $padbit,$padbit,lsl#24 tst $len,#31 beq .Leven vld4.32 {$H0#lo[0],$H1#lo[0],$H2#lo[0],$H3#lo[0]},[$inp]! vmov.32 $H4#lo[0],$padbit sub $len,$len,#16 add $in2,$inp,#32 # ifdef __ARMEB__ vrev32.8 $H0,$H0 vrev32.8 $H3,$H3 vrev32.8 $H1,$H1 vrev32.8 $H2,$H2 # endif vsri.u32 $H4#lo,$H3#lo,#8 @ base 2^32 -> base 2^26 vshl.u32 $H3#lo,$H3#lo,#18 vsri.u32 $H3#lo,$H2#lo,#14 vshl.u32 $H2#lo,$H2#lo,#12 vadd.i32 $H4#hi,$H4#lo,$D4#lo @ add hash value and move to #hi vbic.i32 $H3#lo,#0xfc000000 vsri.u32 $H2#lo,$H1#lo,#20 vshl.u32 $H1#lo,$H1#lo,#6 vbic.i32 $H2#lo,#0xfc000000 vsri.u32 $H1#lo,$H0#lo,#26 vadd.i32 $H3#hi,$H3#lo,$D3#lo vbic.i32 $H0#lo,#0xfc000000 vbic.i32 $H1#lo,#0xfc000000 vadd.i32 $H2#hi,$H2#lo,$D2#lo vadd.i32 $H0#hi,$H0#lo,$D0#lo vadd.i32 $H1#hi,$H1#lo,$D1#lo mov $tbl1,$zeros add $tbl0,$ctx,#48 cmp $len,$len b .Long_tail .align 4 .Leven: subs $len,$len,#64 it lo movlo $in2,$zeros vmov.i32 $H4,#1<<24 @ padbit, yes, always vld4.32 {$H0#lo,$H1#lo,$H2#lo,$H3#lo},[$inp] @ inp[0:1] add $inp,$inp,#64 vld4.32 {$H0#hi,$H1#hi,$H2#hi,$H3#hi},[$in2] @ inp[2:3] (or 0) add $in2,$in2,#64 itt hi addhi $tbl1,$ctx,#(48+1*9*4) addhi $tbl0,$ctx,#(48+3*9*4) # ifdef __ARMEB__ vrev32.8 $H0,$H0 vrev32.8 $H3,$H3 vrev32.8 $H1,$H1 vrev32.8 $H2,$H2 # endif vsri.u32 $H4,$H3,#8 @ base 2^32 -> base 2^26 vshl.u32 $H3,$H3,#18 vsri.u32 $H3,$H2,#14 vshl.u32 $H2,$H2,#12 vbic.i32 $H3,#0xfc000000 vsri.u32 $H2,$H1,#20 vshl.u32 $H1,$H1,#6 vbic.i32 $H2,#0xfc000000 vsri.u32 $H1,$H0,#26 vbic.i32 $H0,#0xfc000000 vbic.i32 $H1,#0xfc000000 bls .Lskip_loop vld4.32 {${R0}[1],${R1}[1],${S1}[1],${R2}[1]},[$tbl1]! @ load r^2 vld4.32 {${R0}[0],${R1}[0],${S1}[0],${R2}[0]},[$tbl0]! @ load r^4 vld4.32 {${S2}[1],${R3}[1],${S3}[1],${R4}[1]},[$tbl1]! vld4.32 {${S2}[0],${R3}[0],${S3}[0],${R4}[0]},[$tbl0]! b .Loop_neon .align 5 .Loop_neon: @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ ((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 @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ inp[2:3]*r^2 vadd.i32 $H2#lo,$H2#lo,$D2#lo @ accumulate inp[0:1] vmull.u32 $D2,$H2#hi,${R0}[1] vadd.i32 $H0#lo,$H0#lo,$D0#lo vmull.u32 $D0,$H0#hi,${R0}[1] vadd.i32 $H3#lo,$H3#lo,$D3#lo vmull.u32 $D3,$H3#hi,${R0}[1] vmlal.u32 $D2,$H1#hi,${R1}[1] vadd.i32 $H1#lo,$H1#lo,$D1#lo vmull.u32 $D1,$H1#hi,${R0}[1] vadd.i32 $H4#lo,$H4#lo,$D4#lo vmull.u32 $D4,$H4#hi,${R0}[1] subs $len,$len,#64 vmlal.u32 $D0,$H4#hi,${S1}[1] it lo movlo $in2,$zeros vmlal.u32 $D3,$H2#hi,${R1}[1] vld1.32 ${S4}[1],[$tbl1,:32] vmlal.u32 $D1,$H0#hi,${R1}[1] vmlal.u32 $D4,$H3#hi,${R1}[1] vmlal.u32 $D0,$H3#hi,${S2}[1] vmlal.u32 $D3,$H1#hi,${R2}[1] vmlal.u32 $D4,$H2#hi,${R2}[1] vmlal.u32 $D1,$H4#hi,${S2}[1] vmlal.u32 $D2,$H0#hi,${R2}[1] vmlal.u32 $D3,$H0#hi,${R3}[1] vmlal.u32 $D0,$H2#hi,${S3}[1] vmlal.u32 $D4,$H1#hi,${R3}[1] vmlal.u32 $D1,$H3#hi,${S3}[1] vmlal.u32 $D2,$H4#hi,${S3}[1] vmlal.u32 $D3,$H4#hi,${S4}[1] vmlal.u32 $D0,$H1#hi,${S4}[1] vmlal.u32 $D4,$H0#hi,${R4}[1] vmlal.u32 $D1,$H2#hi,${S4}[1] vmlal.u32 $D2,$H3#hi,${S4}[1] vld4.32 {$H0#hi,$H1#hi,$H2#hi,$H3#hi},[$in2] @ inp[2:3] (or 0) add $in2,$in2,#64 @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ (hash+inp[0:1])*r^4 and accumulate vmlal.u32 $D3,$H3#lo,${R0}[0] vmlal.u32 $D0,$H0#lo,${R0}[0] vmlal.u32 $D4,$H4#lo,${R0}[0] vmlal.u32 $D1,$H1#lo,${R0}[0] vmlal.u32 $D2,$H2#lo,${R0}[0] vld1.32 ${S4}[0],[$tbl0,:32] vmlal.u32 $D3,$H2#lo,${R1}[0] vmlal.u32 $D0,$H4#lo,${S1}[0] vmlal.u32 $D4,$H3#lo,${R1}[0] vmlal.u32 $D1,$H0#lo,${R1}[0] vmlal.u32 $D2,$H1#lo,${R1}[0] vmlal.u32 $D3,$H1#lo,${R2}[0] vmlal.u32 $D0,$H3#lo,${S2}[0] vmlal.u32 $D4,$H2#lo,${R2}[0] vmlal.u32 $D1,$H4#lo,${S2}[0] vmlal.u32 $D2,$H0#lo,${R2}[0] vmlal.u32 $D3,$H0#lo,${R3}[0] vmlal.u32 $D0,$H2#lo,${S3}[0] vmlal.u32 $D4,$H1#lo,${R3}[0] vmlal.u32 $D1,$H3#lo,${S3}[0] vmlal.u32 $D3,$H4#lo,${S4}[0] vmlal.u32 $D2,$H4#lo,${S3}[0] vmlal.u32 $D0,$H1#lo,${S4}[0] vmlal.u32 $D4,$H0#lo,${R4}[0] vmov.i32 $H4,#1<<24 @ padbit, yes, always vmlal.u32 $D1,$H2#lo,${S4}[0] vmlal.u32 $D2,$H3#lo,${S4}[0] vld4.32 {$H0#lo,$H1#lo,$H2#lo,$H3#lo},[$inp] @ inp[0:1] add $inp,$inp,#64 # ifdef __ARMEB__ vrev32.8 $H0,$H0 vrev32.8 $H1,$H1 vrev32.8 $H2,$H2 vrev32.8 $H3,$H3 # endif @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ lazy reduction interleaved with base 2^32 -> base 2^26 of @ inp[0:3] previously loaded to $H0-$H3 and smashed to $H0-$H4. vshr.u64 $T0,$D3,#26 vmovn.i64 $D3#lo,$D3 vshr.u64 $T1,$D0,#26 vmovn.i64 $D0#lo,$D0 vadd.i64 $D4,$D4,$T0 @ h3 -> h4 vbic.i32 $D3#lo,#0xfc000000 vsri.u32 $H4,$H3,#8 @ base 2^32 -> base 2^26 vadd.i64 $D1,$D1,$T1 @ h0 -> h1 vshl.u32 $H3,$H3,#18 vbic.i32 $D0#lo,#0xfc000000 vshrn.u64 $T0#lo,$D4,#26 vmovn.i64 $D4#lo,$D4 vshr.u64 $T1,$D1,#26 vmovn.i64 $D1#lo,$D1 vadd.i64 $D2,$D2,$T1 @ h1 -> h2 vsri.u32 $H3,$H2,#14 vbic.i32 $D4#lo,#0xfc000000 vshl.u32 $H2,$H2,#12 vbic.i32 $D1#lo,#0xfc000000 vadd.i32 $D0#lo,$D0#lo,$T0#lo vshl.u32 $T0#lo,$T0#lo,#2 vbic.i32 $H3,#0xfc000000 vshrn.u64 $T1#lo,$D2,#26 vmovn.i64 $D2#lo,$D2 vaddl.u32 $D0,$D0#lo,$T0#lo @ h4 -> h0 [widen for a sec] vsri.u32 $H2,$H1,#20 vadd.i32 $D3#lo,$D3#lo,$T1#lo @ h2 -> h3 vshl.u32 $H1,$H1,#6 vbic.i32 $D2#lo,#0xfc000000 vbic.i32 $H2,#0xfc000000 vshrn.u64 $T0#lo,$D0,#26 @ re-narrow vmovn.i64 $D0#lo,$D0 vsri.u32 $H1,$H0,#26 vbic.i32 $H0,#0xfc000000 vshr.u32 $T1#lo,$D3#lo,#26 vbic.i32 $D3#lo,#0xfc000000 vbic.i32 $D0#lo,#0xfc000000 vadd.i32 $D1#lo,$D1#lo,$T0#lo @ h0 -> h1 vadd.i32 $D4#lo,$D4#lo,$T1#lo @ h3 -> h4 vbic.i32 $H1,#0xfc000000 bhi .Loop_neon .Lskip_loop: @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ multiply (inp[0:1]+hash) or inp[2:3] by r^2:r^1 add $tbl1,$ctx,#(48+0*9*4) add $tbl0,$ctx,#(48+1*9*4) adds $len,$len,#32 it ne movne $len,#0 bne .Long_tail vadd.i32 $H2#hi,$H2#lo,$D2#lo @ add hash value and move to #hi vadd.i32 $H0#hi,$H0#lo,$D0#lo vadd.i32 $H3#hi,$H3#lo,$D3#lo vadd.i32 $H1#hi,$H1#lo,$D1#lo vadd.i32 $H4#hi,$H4#lo,$D4#lo .Long_tail: vld4.32 {${R0}[1],${R1}[1],${S1}[1],${R2}[1]},[$tbl1]! @ load r^1 vld4.32 {${R0}[0],${R1}[0],${S1}[0],${R2}[0]},[$tbl0]! @ load r^2 vadd.i32 $H2#lo,$H2#lo,$D2#lo @ can be redundant vmull.u32 $D2,$H2#hi,$R0 vadd.i32 $H0#lo,$H0#lo,$D0#lo vmull.u32 $D0,$H0#hi,$R0 vadd.i32 $H3#lo,$H3#lo,$D3#lo vmull.u32 $D3,$H3#hi,$R0 vadd.i32 $H1#lo,$H1#lo,$D1#lo vmull.u32 $D1,$H1#hi,$R0 vadd.i32 $H4#lo,$H4#lo,$D4#lo vmull.u32 $D4,$H4#hi,$R0 vmlal.u32 $D0,$H4#hi,$S1 vld4.32 {${S2}[1],${R3}[1],${S3}[1],${R4}[1]},[$tbl1]! vmlal.u32 $D3,$H2#hi,$R1 vld4.32 {${S2}[0],${R3}[0],${S3}[0],${R4}[0]},[$tbl0]! vmlal.u32 $D1,$H0#hi,$R1 vmlal.u32 $D4,$H3#hi,$R1 vmlal.u32 $D2,$H1#hi,$R1 vmlal.u32 $D3,$H1#hi,$R2 vld1.32 ${S4}[1],[$tbl1,:32] vmlal.u32 $D0,$H3#hi,$S2 vld1.32 ${S4}[0],[$tbl0,:32] vmlal.u32 $D4,$H2#hi,$R2 vmlal.u32 $D1,$H4#hi,$S2 vmlal.u32 $D2,$H0#hi,$R2 vmlal.u32 $D3,$H0#hi,$R3 it ne addne $tbl1,$ctx,#(48+2*9*4) vmlal.u32 $D0,$H2#hi,$S3 it ne addne $tbl0,$ctx,#(48+3*9*4) vmlal.u32 $D4,$H1#hi,$R3 vmlal.u32 $D1,$H3#hi,$S3 vmlal.u32 $D2,$H4#hi,$S3 vmlal.u32 $D3,$H4#hi,$S4 vorn $MASK,$MASK,$MASK @ all-ones, can be redundant vmlal.u32 $D0,$H1#hi,$S4 vshr.u64 $MASK,$MASK,#38 vmlal.u32 $D4,$H0#hi,$R4 vmlal.u32 $D1,$H2#hi,$S4 vmlal.u32 $D2,$H3#hi,$S4 beq .Lshort_tail @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ (hash+inp[0:1])*r^4:r^3 and accumulate vld4.32 {${R0}[1],${R1}[1],${S1}[1],${R2}[1]},[$tbl1]! @ load r^3 vld4.32 {${R0}[0],${R1}[0],${S1}[0],${R2}[0]},[$tbl0]! @ load r^4 vmlal.u32 $D2,$H2#lo,$R0 vmlal.u32 $D0,$H0#lo,$R0 vmlal.u32 $D3,$H3#lo,$R0 vmlal.u32 $D1,$H1#lo,$R0 vmlal.u32 $D4,$H4#lo,$R0 vmlal.u32 $D0,$H4#lo,$S1 vld4.32 {${S2}[1],${R3}[1],${S3}[1],${R4}[1]},[$tbl1]! vmlal.u32 $D3,$H2#lo,$R1 vld4.32 {${S2}[0],${R3}[0],${S3}[0],${R4}[0]},[$tbl0]! vmlal.u32 $D1,$H0#lo,$R1 vmlal.u32 $D4,$H3#lo,$R1 vmlal.u32 $D2,$H1#lo,$R1 vmlal.u32 $D3,$H1#lo,$R2 vld1.32 ${S4}[1],[$tbl1,:32] vmlal.u32 $D0,$H3#lo,$S2 vld1.32 ${S4}[0],[$tbl0,:32] vmlal.u32 $D4,$H2#lo,$R2 vmlal.u32 $D1,$H4#lo,$S2 vmlal.u32 $D2,$H0#lo,$R2 vmlal.u32 $D3,$H0#lo,$R3 vmlal.u32 $D0,$H2#lo,$S3 vmlal.u32 $D4,$H1#lo,$R3 vmlal.u32 $D1,$H3#lo,$S3 vmlal.u32 $D2,$H4#lo,$S3 vmlal.u32 $D3,$H4#lo,$S4 vorn $MASK,$MASK,$MASK @ all-ones vmlal.u32 $D0,$H1#lo,$S4 vshr.u64 $MASK,$MASK,#38 vmlal.u32 $D4,$H0#lo,$R4 vmlal.u32 $D1,$H2#lo,$S4 vmlal.u32 $D2,$H3#lo,$S4 .Lshort_tail: @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ horizontal addition vadd.i64 $D3#lo,$D3#lo,$D3#hi vadd.i64 $D0#lo,$D0#lo,$D0#hi vadd.i64 $D4#lo,$D4#lo,$D4#hi vadd.i64 $D1#lo,$D1#lo,$D1#hi vadd.i64 $D2#lo,$D2#lo,$D2#hi @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ lazy reduction, but without narrowing vshr.u64 $T0,$D3,#26 vand.i64 $D3,$D3,$MASK vshr.u64 $T1,$D0,#26 vand.i64 $D0,$D0,$MASK vadd.i64 $D4,$D4,$T0 @ h3 -> h4 vadd.i64 $D1,$D1,$T1 @ h0 -> h1 vshr.u64 $T0,$D4,#26 vand.i64 $D4,$D4,$MASK vshr.u64 $T1,$D1,#26 vand.i64 $D1,$D1,$MASK vadd.i64 $D2,$D2,$T1 @ h1 -> h2 vadd.i64 $D0,$D0,$T0 vshl.u64 $T0,$T0,#2 vshr.u64 $T1,$D2,#26 vand.i64 $D2,$D2,$MASK vadd.i64 $D0,$D0,$T0 @ h4 -> h0 vadd.i64 $D3,$D3,$T1 @ h2 -> h3 vshr.u64 $T0,$D0,#26 vand.i64 $D0,$D0,$MASK vshr.u64 $T1,$D3,#26 vand.i64 $D3,$D3,$MASK vadd.i64 $D1,$D1,$T0 @ h0 -> h1 vadd.i64 $D4,$D4,$T1 @ h3 -> h4 cmp $len,#0 bne .Leven @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ @ store hash value vst4.32 {$D0#lo[0],$D1#lo[0],$D2#lo[0],$D3#lo[0]},[$ctx]! vst1.32 {$D4#lo[0]},[$ctx] vldmia sp!,{d8-d15} @ epilogue ldmia sp!,{r4-r7} .Lno_data_neon: ret @ bx lr .size poly1305_blocks_neon,.-poly1305_blocks_neon #ifdef __KERNEL__ .globl poly1305_emit_neon #endif .type poly1305_emit_neon,%function .align 5 poly1305_emit_neon: ldr ip,[$ctx,#36] @ is_base2_26 stmdb sp!,{r4-r11} tst ip,ip beq .Lpoly1305_emit_enter ldmia $ctx,{$h0-$h4} eor $g0,$g0,$g0 adds $h0,$h0,$h1,lsl#26 @ base 2^26 -> base 2^32 mov $h1,$h1,lsr#6 adcs $h1,$h1,$h2,lsl#20 mov $h2,$h2,lsr#12 adcs $h2,$h2,$h3,lsl#14 mov $h3,$h3,lsr#18 adcs $h3,$h3,$h4,lsl#8 adc $h4,$g0,$h4,lsr#24 @ can be partially reduced ... and $g0,$h4,#-4 @ ... so reduce and $h4,$h3,#3 add $g0,$g0,$g0,lsr#2 @ *= 5 adds $h0,$h0,$g0 adcs $h1,$h1,#0 adcs $h2,$h2,#0 adcs $h3,$h3,#0 adc $h4,$h4,#0 adds $g0,$h0,#5 @ compare to modulus adcs $g1,$h1,#0 adcs $g2,$h2,#0 adcs $g3,$h3,#0 adc $g4,$h4,#0 tst $g4,#4 @ did it carry/borrow? it ne movne $h0,$g0 ldr $g0,[$nonce,#0] it ne movne $h1,$g1 ldr $g1,[$nonce,#4] it ne movne $h2,$g2 ldr $g2,[$nonce,#8] it ne movne $h3,$g3 ldr $g3,[$nonce,#12] adds $h0,$h0,$g0 @ accumulate nonce adcs $h1,$h1,$g1 adcs $h2,$h2,$g2 adc $h3,$h3,$g3 # ifdef __ARMEB__ rev $h0,$h0 rev $h1,$h1 rev $h2,$h2 rev $h3,$h3 # endif str $h0,[$mac,#0] @ store the result str $h1,[$mac,#4] str $h2,[$mac,#8] str $h3,[$mac,#12] ldmia sp!,{r4-r11} ret @ bx lr .size poly1305_emit_neon,.-poly1305_emit_neon .align 5 .Lzeros: .long 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 # ifndef __KERNEL__ .LOPENSSL_armcap: .word OPENSSL_armcap_P-.Lpoly1305_init # endif #endif ___ } } $code.=<<___; .align 2 #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__) .comm OPENSSL_armcap_P,4,4 #endif ___ open SELF,$0; while() { next if (/^#!/); last if (!s/^#/@/ and !/^$/); print; } close SELF; foreach (split("\n",$code)) { s/\`([^\`]*)\`/eval $1/geo; s/\bq([0-9]+)#(lo|hi)/sprintf "d%d",2*$1+($2 eq "hi")/geo or s/\bret\b/bx lr/go or s/\bbx\s+lr\b/.word\t0xe12fff1e/go; # make it possible to compile with -march=armv4 print $_,"\n"; } close STDOUT; # enforce flush