| #! /usr/bin/env perl |
| # Copyright 2015-2021 The OpenSSL Project Authors. All Rights Reserved. |
| # |
| # Licensed under the Apache License 2.0 (the "License"). You may not use |
| # this file except in compliance with the License. You can obtain a copy |
| # in the file LICENSE in the source distribution or at |
| # https://www.openssl.org/source/license.html |
| |
| |
| # ==================================================================== |
| # Written by Andy Polyakov <appro@openssl.org> 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/. |
| # ==================================================================== |
| # |
| # ECP_NISTZ256 module for SPARCv9. |
| # |
| # February 2015. |
| # |
| # Original ECP_NISTZ256 submission targeting x86_64 is detailed in |
| # http://eprint.iacr.org/2013/816. In the process of adaptation |
| # original .c module was made 32-bit savvy in order to make this |
| # implementation possible. |
| # |
| # with/without -DECP_NISTZ256_ASM |
| # UltraSPARC III +12-18% |
| # SPARC T4 +99-550% (+66-150% on 32-bit Solaris) |
| # |
| # Ranges denote minimum and maximum improvement coefficients depending |
| # on benchmark. Lower coefficients are for ECDSA sign, server-side |
| # operation. Keep in mind that +200% means 3x improvement. |
| |
| $output = pop and open STDOUT,">$output"; |
| |
| $code.=<<___; |
| #ifndef __ASSEMBLER__ |
| # define __ASSEMBLER__ 1 |
| #endif |
| #include "crypto/sparc_arch.h" |
| |
| #define LOCALS (STACK_BIAS+STACK_FRAME) |
| #ifdef __arch64__ |
| .register %g2,#scratch |
| .register %g3,#scratch |
| # define STACK64_FRAME STACK_FRAME |
| # define LOCALS64 LOCALS |
| #else |
| # define STACK64_FRAME (2047+192) |
| # define LOCALS64 STACK64_FRAME |
| #endif |
| |
| .section ".text",#alloc,#execinstr |
| ___ |
| ######################################################################## |
| # Convert ecp_nistz256_table.c to layout expected by ecp_nistz_gather_w7 |
| # |
| $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1; |
| open TABLE,"<ecp_nistz256_table.c" or |
| open TABLE,"<${dir}../ecp_nistz256_table.c" or |
| die "failed to open ecp_nistz256_table.c:",$!; |
| |
| use integer; |
| |
| foreach(<TABLE>) { |
| s/TOBN\(\s*(0x[0-9a-f]+),\s*(0x[0-9a-f]+)\s*\)/push @arr,hex($2),hex($1)/geo; |
| } |
| close TABLE; |
| |
| # See ecp_nistz256_table.c for explanation for why it's 64*16*37. |
| # 64*16*37-1 is because $#arr returns last valid index or @arr, not |
| # amount of elements. |
| die "insane number of elements" if ($#arr != 64*16*37-1); |
| |
| $code.=<<___; |
| .globl ecp_nistz256_precomputed |
| .align 4096 |
| ecp_nistz256_precomputed: |
| ___ |
| ######################################################################## |
| # this conversion smashes P256_POINT_AFFINE by individual bytes with |
| # 64 byte interval, similar to |
| # 1111222233334444 |
| # 1234123412341234 |
| for(1..37) { |
| @tbl = splice(@arr,0,64*16); |
| for($i=0;$i<64;$i++) { |
| undef @line; |
| for($j=0;$j<64;$j++) { |
| push @line,(@tbl[$j*16+$i/4]>>(($i%4)*8))&0xff; |
| } |
| $code.=".byte\t"; |
| $code.=join(',',map { sprintf "0x%02x",$_} @line); |
| $code.="\n"; |
| } |
| } |
| |
| {{{ |
| my ($rp,$ap,$bp)=map("%i$_",(0..2)); |
| my @acc=map("%l$_",(0..7)); |
| my ($t0,$t1,$t2,$t3,$t4,$t5,$t6,$t7)=(map("%o$_",(0..5)),"%g4","%g5"); |
| my ($bi,$a0,$mask,$carry)=(map("%i$_",(3..5)),"%g1"); |
| my ($rp_real,$ap_real)=("%g2","%g3"); |
| |
| $code.=<<___; |
| .type ecp_nistz256_precomputed,#object |
| .size ecp_nistz256_precomputed,.-ecp_nistz256_precomputed |
| .align 64 |
| .LRR: ! 2^512 mod P precomputed for NIST P256 polynomial |
| .long 0x00000003, 0x00000000, 0xffffffff, 0xfffffffb |
| .long 0xfffffffe, 0xffffffff, 0xfffffffd, 0x00000004 |
| .Lone: |
| .long 1,0,0,0,0,0,0,0 |
| .asciz "ECP_NISTZ256 for SPARCv9, CRYPTOGAMS by <appro\@openssl.org>" |
| |
| ! void ecp_nistz256_to_mont(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_to_mont |
| .align 64 |
| ecp_nistz256_to_mont: |
| save %sp,-STACK_FRAME,%sp |
| nop |
| 1: call .+8 |
| add %o7,.LRR-1b,$bp |
| call __ecp_nistz256_mul_mont |
| nop |
| ret |
| restore |
| .type ecp_nistz256_to_mont,#function |
| .size ecp_nistz256_to_mont,.-ecp_nistz256_to_mont |
| |
| ! void ecp_nistz256_from_mont(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_from_mont |
| .align 32 |
| ecp_nistz256_from_mont: |
| save %sp,-STACK_FRAME,%sp |
| nop |
| 1: call .+8 |
| add %o7,.Lone-1b,$bp |
| call __ecp_nistz256_mul_mont |
| nop |
| ret |
| restore |
| .type ecp_nistz256_from_mont,#function |
| .size ecp_nistz256_from_mont,.-ecp_nistz256_from_mont |
| |
| ! void ecp_nistz256_mul_mont(BN_ULONG %i0[8],const BN_ULONG %i1[8], |
| ! const BN_ULONG %i2[8]); |
| .globl ecp_nistz256_mul_mont |
| .align 32 |
| ecp_nistz256_mul_mont: |
| save %sp,-STACK_FRAME,%sp |
| nop |
| call __ecp_nistz256_mul_mont |
| nop |
| ret |
| restore |
| .type ecp_nistz256_mul_mont,#function |
| .size ecp_nistz256_mul_mont,.-ecp_nistz256_mul_mont |
| |
| ! void ecp_nistz256_sqr_mont(BN_ULONG %i0[8],const BN_ULONG %i2[8]); |
| .globl ecp_nistz256_sqr_mont |
| .align 32 |
| ecp_nistz256_sqr_mont: |
| save %sp,-STACK_FRAME,%sp |
| mov $ap,$bp |
| call __ecp_nistz256_mul_mont |
| nop |
| ret |
| restore |
| .type ecp_nistz256_sqr_mont,#function |
| .size ecp_nistz256_sqr_mont,.-ecp_nistz256_sqr_mont |
| ___ |
| |
| ######################################################################## |
| # Special thing to keep in mind is that $t0-$t7 hold 64-bit values, |
| # while all others are meant to keep 32. "Meant to" means that additions |
| # to @acc[0-7] do "contaminate" upper bits, but they are cleared before |
| # they can affect outcome (follow 'and' with $mask). Also keep in mind |
| # that addition with carry is addition with 32-bit carry, even though |
| # CPU is 64-bit. [Addition with 64-bit carry was introduced in T3, see |
| # below for VIS3 code paths.] |
| |
| $code.=<<___; |
| .align 32 |
| __ecp_nistz256_mul_mont: |
| ld [$bp+0],$bi ! b[0] |
| mov -1,$mask |
| ld [$ap+0],$a0 |
| srl $mask,0,$mask ! 0xffffffff |
| ld [$ap+4],$t1 |
| ld [$ap+8],$t2 |
| ld [$ap+12],$t3 |
| ld [$ap+16],$t4 |
| ld [$ap+20],$t5 |
| ld [$ap+24],$t6 |
| ld [$ap+28],$t7 |
| mulx $a0,$bi,$t0 ! a[0-7]*b[0], 64-bit results |
| mulx $t1,$bi,$t1 |
| mulx $t2,$bi,$t2 |
| mulx $t3,$bi,$t3 |
| mulx $t4,$bi,$t4 |
| mulx $t5,$bi,$t5 |
| mulx $t6,$bi,$t6 |
| mulx $t7,$bi,$t7 |
| srlx $t0,32,@acc[1] ! extract high parts |
| srlx $t1,32,@acc[2] |
| srlx $t2,32,@acc[3] |
| srlx $t3,32,@acc[4] |
| srlx $t4,32,@acc[5] |
| srlx $t5,32,@acc[6] |
| srlx $t6,32,@acc[7] |
| srlx $t7,32,@acc[0] ! "@acc[8]" |
| mov 0,$carry |
| ___ |
| for($i=1;$i<8;$i++) { |
| $code.=<<___; |
| addcc @acc[1],$t1,@acc[1] ! accumulate high parts |
| ld [$bp+4*$i],$bi ! b[$i] |
| ld [$ap+4],$t1 ! re-load a[1-7] |
| addccc @acc[2],$t2,@acc[2] |
| addccc @acc[3],$t3,@acc[3] |
| ld [$ap+8],$t2 |
| ld [$ap+12],$t3 |
| addccc @acc[4],$t4,@acc[4] |
| addccc @acc[5],$t5,@acc[5] |
| ld [$ap+16],$t4 |
| ld [$ap+20],$t5 |
| addccc @acc[6],$t6,@acc[6] |
| addccc @acc[7],$t7,@acc[7] |
| ld [$ap+24],$t6 |
| ld [$ap+28],$t7 |
| addccc @acc[0],$carry,@acc[0] ! "@acc[8]" |
| addc %g0,%g0,$carry |
| ___ |
| # Reduction iteration is normally performed by accumulating |
| # result of multiplication of modulus by "magic" digit [and |
| # omitting least significant word, which is guaranteed to |
| # be 0], but thanks to special form of modulus and "magic" |
| # digit being equal to least significant word, it can be |
| # performed with additions and subtractions alone. Indeed: |
| # |
| # ffff.0001.0000.0000.0000.ffff.ffff.ffff |
| # * abcd |
| # + xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.abcd |
| # |
| # Now observing that ff..ff*x = (2^n-1)*x = 2^n*x-x, we |
| # rewrite above as: |
| # |
| # xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.abcd |
| # + abcd.0000.abcd.0000.0000.abcd.0000.0000.0000 |
| # - abcd.0000.0000.0000.0000.0000.0000.abcd |
| # |
| # or marking redundant operations: |
| # |
| # xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.xxxx.---- |
| # + abcd.0000.abcd.0000.0000.abcd.----.----.---- |
| # - abcd.----.----.----.----.----.----.---- |
| |
| $code.=<<___; |
| ! multiplication-less reduction |
| addcc @acc[3],$t0,@acc[3] ! r[3]+=r[0] |
| addccc @acc[4],%g0,@acc[4] ! r[4]+=0 |
| and @acc[1],$mask,@acc[1] |
| and @acc[2],$mask,@acc[2] |
| addccc @acc[5],%g0,@acc[5] ! r[5]+=0 |
| addccc @acc[6],$t0,@acc[6] ! r[6]+=r[0] |
| and @acc[3],$mask,@acc[3] |
| and @acc[4],$mask,@acc[4] |
| addccc @acc[7],%g0,@acc[7] ! r[7]+=0 |
| addccc @acc[0],$t0,@acc[0] ! r[8]+=r[0] "@acc[8]" |
| and @acc[5],$mask,@acc[5] |
| and @acc[6],$mask,@acc[6] |
| addc $carry,%g0,$carry ! top-most carry |
| subcc @acc[7],$t0,@acc[7] ! r[7]-=r[0] |
| subccc @acc[0],%g0,@acc[0] ! r[8]-=0 "@acc[8]" |
| subc $carry,%g0,$carry ! top-most carry |
| and @acc[7],$mask,@acc[7] |
| and @acc[0],$mask,@acc[0] ! "@acc[8]" |
| ___ |
| push(@acc,shift(@acc)); # rotate registers to "omit" acc[0] |
| $code.=<<___; |
| mulx $a0,$bi,$t0 ! a[0-7]*b[$i], 64-bit results |
| mulx $t1,$bi,$t1 |
| mulx $t2,$bi,$t2 |
| mulx $t3,$bi,$t3 |
| mulx $t4,$bi,$t4 |
| mulx $t5,$bi,$t5 |
| mulx $t6,$bi,$t6 |
| mulx $t7,$bi,$t7 |
| add @acc[0],$t0,$t0 ! accumulate low parts, can't overflow |
| add @acc[1],$t1,$t1 |
| srlx $t0,32,@acc[1] ! extract high parts |
| add @acc[2],$t2,$t2 |
| srlx $t1,32,@acc[2] |
| add @acc[3],$t3,$t3 |
| srlx $t2,32,@acc[3] |
| add @acc[4],$t4,$t4 |
| srlx $t3,32,@acc[4] |
| add @acc[5],$t5,$t5 |
| srlx $t4,32,@acc[5] |
| add @acc[6],$t6,$t6 |
| srlx $t5,32,@acc[6] |
| add @acc[7],$t7,$t7 |
| srlx $t6,32,@acc[7] |
| srlx $t7,32,@acc[0] ! "@acc[8]" |
| ___ |
| } |
| $code.=<<___; |
| addcc @acc[1],$t1,@acc[1] ! accumulate high parts |
| addccc @acc[2],$t2,@acc[2] |
| addccc @acc[3],$t3,@acc[3] |
| addccc @acc[4],$t4,@acc[4] |
| addccc @acc[5],$t5,@acc[5] |
| addccc @acc[6],$t6,@acc[6] |
| addccc @acc[7],$t7,@acc[7] |
| addccc @acc[0],$carry,@acc[0] ! "@acc[8]" |
| addc %g0,%g0,$carry |
| |
| addcc @acc[3],$t0,@acc[3] ! multiplication-less reduction |
| addccc @acc[4],%g0,@acc[4] |
| addccc @acc[5],%g0,@acc[5] |
| addccc @acc[6],$t0,@acc[6] |
| addccc @acc[7],%g0,@acc[7] |
| addccc @acc[0],$t0,@acc[0] ! "@acc[8]" |
| addc $carry,%g0,$carry |
| subcc @acc[7],$t0,@acc[7] |
| subccc @acc[0],%g0,@acc[0] ! "@acc[8]" |
| subc $carry,%g0,$carry ! top-most carry |
| ___ |
| push(@acc,shift(@acc)); # rotate registers to omit acc[0] |
| $code.=<<___; |
| ! Final step is "if result > mod, subtract mod", but we do it |
| ! "other way around", namely subtract modulus from result |
| ! and if it borrowed, add modulus back. |
| |
| subcc @acc[0],-1,@acc[0] ! subtract modulus |
| subccc @acc[1],-1,@acc[1] |
| subccc @acc[2],-1,@acc[2] |
| subccc @acc[3],0,@acc[3] |
| subccc @acc[4],0,@acc[4] |
| subccc @acc[5],0,@acc[5] |
| subccc @acc[6],1,@acc[6] |
| subccc @acc[7],-1,@acc[7] |
| subc $carry,0,$carry ! broadcast borrow bit |
| |
| ! Note that because mod has special form, i.e. consists of |
| ! 0xffffffff, 1 and 0s, we can conditionally synthesize it by |
| ! using value of broadcasted borrow and the borrow bit itself. |
| ! To minimize dependency chain we first broadcast and then |
| ! extract the bit by negating (follow $bi). |
| |
| addcc @acc[0],$carry,@acc[0] ! add modulus or zero |
| addccc @acc[1],$carry,@acc[1] |
| neg $carry,$bi |
| st @acc[0],[$rp] |
| addccc @acc[2],$carry,@acc[2] |
| st @acc[1],[$rp+4] |
| addccc @acc[3],0,@acc[3] |
| st @acc[2],[$rp+8] |
| addccc @acc[4],0,@acc[4] |
| st @acc[3],[$rp+12] |
| addccc @acc[5],0,@acc[5] |
| st @acc[4],[$rp+16] |
| addccc @acc[6],$bi,@acc[6] |
| st @acc[5],[$rp+20] |
| addc @acc[7],$carry,@acc[7] |
| st @acc[6],[$rp+24] |
| retl |
| st @acc[7],[$rp+28] |
| .type __ecp_nistz256_mul_mont,#function |
| .size __ecp_nistz256_mul_mont,.-__ecp_nistz256_mul_mont |
| |
| ! void ecp_nistz256_add(BN_ULONG %i0[8],const BN_ULONG %i1[8], |
| ! const BN_ULONG %i2[8]); |
| .globl ecp_nistz256_add |
| .align 32 |
| ecp_nistz256_add: |
| save %sp,-STACK_FRAME,%sp |
| ld [$ap],@acc[0] |
| ld [$ap+4],@acc[1] |
| ld [$ap+8],@acc[2] |
| ld [$ap+12],@acc[3] |
| ld [$ap+16],@acc[4] |
| ld [$ap+20],@acc[5] |
| ld [$ap+24],@acc[6] |
| call __ecp_nistz256_add |
| ld [$ap+28],@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_add,#function |
| .size ecp_nistz256_add,.-ecp_nistz256_add |
| |
| .align 32 |
| __ecp_nistz256_add: |
| ld [$bp+0],$t0 ! b[0] |
| ld [$bp+4],$t1 |
| ld [$bp+8],$t2 |
| ld [$bp+12],$t3 |
| addcc @acc[0],$t0,@acc[0] |
| ld [$bp+16],$t4 |
| ld [$bp+20],$t5 |
| addccc @acc[1],$t1,@acc[1] |
| ld [$bp+24],$t6 |
| ld [$bp+28],$t7 |
| addccc @acc[2],$t2,@acc[2] |
| addccc @acc[3],$t3,@acc[3] |
| addccc @acc[4],$t4,@acc[4] |
| addccc @acc[5],$t5,@acc[5] |
| addccc @acc[6],$t6,@acc[6] |
| addccc @acc[7],$t7,@acc[7] |
| addc %g0,%g0,$carry |
| |
| .Lreduce_by_sub: |
| |
| ! if a+b >= modulus, subtract modulus. |
| ! |
| ! But since comparison implies subtraction, we subtract |
| ! modulus and then add it back if subtraction borrowed. |
| |
| subcc @acc[0],-1,@acc[0] |
| subccc @acc[1],-1,@acc[1] |
| subccc @acc[2],-1,@acc[2] |
| subccc @acc[3], 0,@acc[3] |
| subccc @acc[4], 0,@acc[4] |
| subccc @acc[5], 0,@acc[5] |
| subccc @acc[6], 1,@acc[6] |
| subccc @acc[7],-1,@acc[7] |
| subc $carry,0,$carry |
| |
| ! Note that because mod has special form, i.e. consists of |
| ! 0xffffffff, 1 and 0s, we can conditionally synthesize it by |
| ! using value of borrow and its negative. |
| |
| addcc @acc[0],$carry,@acc[0] ! add synthesized modulus |
| addccc @acc[1],$carry,@acc[1] |
| neg $carry,$bi |
| st @acc[0],[$rp] |
| addccc @acc[2],$carry,@acc[2] |
| st @acc[1],[$rp+4] |
| addccc @acc[3],0,@acc[3] |
| st @acc[2],[$rp+8] |
| addccc @acc[4],0,@acc[4] |
| st @acc[3],[$rp+12] |
| addccc @acc[5],0,@acc[5] |
| st @acc[4],[$rp+16] |
| addccc @acc[6],$bi,@acc[6] |
| st @acc[5],[$rp+20] |
| addc @acc[7],$carry,@acc[7] |
| st @acc[6],[$rp+24] |
| retl |
| st @acc[7],[$rp+28] |
| .type __ecp_nistz256_add,#function |
| .size __ecp_nistz256_add,.-__ecp_nistz256_add |
| |
| ! void ecp_nistz256_mul_by_2(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_mul_by_2 |
| .align 32 |
| ecp_nistz256_mul_by_2: |
| save %sp,-STACK_FRAME,%sp |
| ld [$ap],@acc[0] |
| ld [$ap+4],@acc[1] |
| ld [$ap+8],@acc[2] |
| ld [$ap+12],@acc[3] |
| ld [$ap+16],@acc[4] |
| ld [$ap+20],@acc[5] |
| ld [$ap+24],@acc[6] |
| call __ecp_nistz256_mul_by_2 |
| ld [$ap+28],@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_mul_by_2,#function |
| .size ecp_nistz256_mul_by_2,.-ecp_nistz256_mul_by_2 |
| |
| .align 32 |
| __ecp_nistz256_mul_by_2: |
| addcc @acc[0],@acc[0],@acc[0] ! a+a=2*a |
| addccc @acc[1],@acc[1],@acc[1] |
| addccc @acc[2],@acc[2],@acc[2] |
| addccc @acc[3],@acc[3],@acc[3] |
| addccc @acc[4],@acc[4],@acc[4] |
| addccc @acc[5],@acc[5],@acc[5] |
| addccc @acc[6],@acc[6],@acc[6] |
| addccc @acc[7],@acc[7],@acc[7] |
| b .Lreduce_by_sub |
| addc %g0,%g0,$carry |
| .type __ecp_nistz256_mul_by_2,#function |
| .size __ecp_nistz256_mul_by_2,.-__ecp_nistz256_mul_by_2 |
| |
| ! void ecp_nistz256_mul_by_3(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_mul_by_3 |
| .align 32 |
| ecp_nistz256_mul_by_3: |
| save %sp,-STACK_FRAME,%sp |
| ld [$ap],@acc[0] |
| ld [$ap+4],@acc[1] |
| ld [$ap+8],@acc[2] |
| ld [$ap+12],@acc[3] |
| ld [$ap+16],@acc[4] |
| ld [$ap+20],@acc[5] |
| ld [$ap+24],@acc[6] |
| call __ecp_nistz256_mul_by_3 |
| ld [$ap+28],@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_mul_by_3,#function |
| .size ecp_nistz256_mul_by_3,.-ecp_nistz256_mul_by_3 |
| |
| .align 32 |
| __ecp_nistz256_mul_by_3: |
| addcc @acc[0],@acc[0],$t0 ! a+a=2*a |
| addccc @acc[1],@acc[1],$t1 |
| addccc @acc[2],@acc[2],$t2 |
| addccc @acc[3],@acc[3],$t3 |
| addccc @acc[4],@acc[4],$t4 |
| addccc @acc[5],@acc[5],$t5 |
| addccc @acc[6],@acc[6],$t6 |
| addccc @acc[7],@acc[7],$t7 |
| addc %g0,%g0,$carry |
| |
| subcc $t0,-1,$t0 ! .Lreduce_by_sub but without stores |
| subccc $t1,-1,$t1 |
| subccc $t2,-1,$t2 |
| subccc $t3, 0,$t3 |
| subccc $t4, 0,$t4 |
| subccc $t5, 0,$t5 |
| subccc $t6, 1,$t6 |
| subccc $t7,-1,$t7 |
| subc $carry,0,$carry |
| |
| addcc $t0,$carry,$t0 ! add synthesized modulus |
| addccc $t1,$carry,$t1 |
| neg $carry,$bi |
| addccc $t2,$carry,$t2 |
| addccc $t3,0,$t3 |
| addccc $t4,0,$t4 |
| addccc $t5,0,$t5 |
| addccc $t6,$bi,$t6 |
| addc $t7,$carry,$t7 |
| |
| addcc $t0,@acc[0],@acc[0] ! 2*a+a=3*a |
| addccc $t1,@acc[1],@acc[1] |
| addccc $t2,@acc[2],@acc[2] |
| addccc $t3,@acc[3],@acc[3] |
| addccc $t4,@acc[4],@acc[4] |
| addccc $t5,@acc[5],@acc[5] |
| addccc $t6,@acc[6],@acc[6] |
| addccc $t7,@acc[7],@acc[7] |
| b .Lreduce_by_sub |
| addc %g0,%g0,$carry |
| .type __ecp_nistz256_mul_by_3,#function |
| .size __ecp_nistz256_mul_by_3,.-__ecp_nistz256_mul_by_3 |
| |
| ! void ecp_nistz256_sub(BN_ULONG %i0[8],const BN_ULONG %i1[8], |
| ! const BN_ULONG %i2[8]); |
| .globl ecp_nistz256_sub |
| .align 32 |
| ecp_nistz256_sub: |
| save %sp,-STACK_FRAME,%sp |
| ld [$ap],@acc[0] |
| ld [$ap+4],@acc[1] |
| ld [$ap+8],@acc[2] |
| ld [$ap+12],@acc[3] |
| ld [$ap+16],@acc[4] |
| ld [$ap+20],@acc[5] |
| ld [$ap+24],@acc[6] |
| call __ecp_nistz256_sub_from |
| ld [$ap+28],@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_sub,#function |
| .size ecp_nistz256_sub,.-ecp_nistz256_sub |
| |
| ! void ecp_nistz256_neg(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_neg |
| .align 32 |
| ecp_nistz256_neg: |
| save %sp,-STACK_FRAME,%sp |
| mov $ap,$bp |
| mov 0,@acc[0] |
| mov 0,@acc[1] |
| mov 0,@acc[2] |
| mov 0,@acc[3] |
| mov 0,@acc[4] |
| mov 0,@acc[5] |
| mov 0,@acc[6] |
| call __ecp_nistz256_sub_from |
| mov 0,@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_neg,#function |
| .size ecp_nistz256_neg,.-ecp_nistz256_neg |
| |
| .align 32 |
| __ecp_nistz256_sub_from: |
| ld [$bp+0],$t0 ! b[0] |
| ld [$bp+4],$t1 |
| ld [$bp+8],$t2 |
| ld [$bp+12],$t3 |
| subcc @acc[0],$t0,@acc[0] |
| ld [$bp+16],$t4 |
| ld [$bp+20],$t5 |
| subccc @acc[1],$t1,@acc[1] |
| subccc @acc[2],$t2,@acc[2] |
| ld [$bp+24],$t6 |
| ld [$bp+28],$t7 |
| subccc @acc[3],$t3,@acc[3] |
| subccc @acc[4],$t4,@acc[4] |
| subccc @acc[5],$t5,@acc[5] |
| subccc @acc[6],$t6,@acc[6] |
| subccc @acc[7],$t7,@acc[7] |
| subc %g0,%g0,$carry ! broadcast borrow bit |
| |
| .Lreduce_by_add: |
| |
| ! if a-b borrows, add modulus. |
| ! |
| ! Note that because mod has special form, i.e. consists of |
| ! 0xffffffff, 1 and 0s, we can conditionally synthesize it by |
| ! using value of broadcasted borrow and the borrow bit itself. |
| ! To minimize dependency chain we first broadcast and then |
| ! extract the bit by negating (follow $bi). |
| |
| addcc @acc[0],$carry,@acc[0] ! add synthesized modulus |
| addccc @acc[1],$carry,@acc[1] |
| neg $carry,$bi |
| st @acc[0],[$rp] |
| addccc @acc[2],$carry,@acc[2] |
| st @acc[1],[$rp+4] |
| addccc @acc[3],0,@acc[3] |
| st @acc[2],[$rp+8] |
| addccc @acc[4],0,@acc[4] |
| st @acc[3],[$rp+12] |
| addccc @acc[5],0,@acc[5] |
| st @acc[4],[$rp+16] |
| addccc @acc[6],$bi,@acc[6] |
| st @acc[5],[$rp+20] |
| addc @acc[7],$carry,@acc[7] |
| st @acc[6],[$rp+24] |
| retl |
| st @acc[7],[$rp+28] |
| .type __ecp_nistz256_sub_from,#function |
| .size __ecp_nistz256_sub_from,.-__ecp_nistz256_sub_from |
| |
| .align 32 |
| __ecp_nistz256_sub_morf: |
| ld [$bp+0],$t0 ! b[0] |
| ld [$bp+4],$t1 |
| ld [$bp+8],$t2 |
| ld [$bp+12],$t3 |
| subcc $t0,@acc[0],@acc[0] |
| ld [$bp+16],$t4 |
| ld [$bp+20],$t5 |
| subccc $t1,@acc[1],@acc[1] |
| subccc $t2,@acc[2],@acc[2] |
| ld [$bp+24],$t6 |
| ld [$bp+28],$t7 |
| subccc $t3,@acc[3],@acc[3] |
| subccc $t4,@acc[4],@acc[4] |
| subccc $t5,@acc[5],@acc[5] |
| subccc $t6,@acc[6],@acc[6] |
| subccc $t7,@acc[7],@acc[7] |
| b .Lreduce_by_add |
| subc %g0,%g0,$carry ! broadcast borrow bit |
| .type __ecp_nistz256_sub_morf,#function |
| .size __ecp_nistz256_sub_morf,.-__ecp_nistz256_sub_morf |
| |
| ! void ecp_nistz256_div_by_2(BN_ULONG %i0[8],const BN_ULONG %i1[8]); |
| .globl ecp_nistz256_div_by_2 |
| .align 32 |
| ecp_nistz256_div_by_2: |
| save %sp,-STACK_FRAME,%sp |
| ld [$ap],@acc[0] |
| ld [$ap+4],@acc[1] |
| ld [$ap+8],@acc[2] |
| ld [$ap+12],@acc[3] |
| ld [$ap+16],@acc[4] |
| ld [$ap+20],@acc[5] |
| ld [$ap+24],@acc[6] |
| call __ecp_nistz256_div_by_2 |
| ld [$ap+28],@acc[7] |
| ret |
| restore |
| .type ecp_nistz256_div_by_2,#function |
| .size ecp_nistz256_div_by_2,.-ecp_nistz256_div_by_2 |
| |
| .align 32 |
| __ecp_nistz256_div_by_2: |
| ! ret = (a is odd ? a+mod : a) >> 1 |
| |
| and @acc[0],1,$bi |
| neg $bi,$carry |
| addcc @acc[0],$carry,@acc[0] |
| addccc @acc[1],$carry,@acc[1] |
| addccc @acc[2],$carry,@acc[2] |
| addccc @acc[3],0,@acc[3] |
| addccc @acc[4],0,@acc[4] |
| addccc @acc[5],0,@acc[5] |
| addccc @acc[6],$bi,@acc[6] |
| addccc @acc[7],$carry,@acc[7] |
| addc %g0,%g0,$carry |
| |
| ! ret >>= 1 |
| |
| srl @acc[0],1,@acc[0] |
| sll @acc[1],31,$t0 |
| srl @acc[1],1,@acc[1] |
| or @acc[0],$t0,@acc[0] |
| sll @acc[2],31,$t1 |
| srl @acc[2],1,@acc[2] |
| or @acc[1],$t1,@acc[1] |
| sll @acc[3],31,$t2 |
| st @acc[0],[$rp] |
| srl @acc[3],1,@acc[3] |
| or @acc[2],$t2,@acc[2] |
| sll @acc[4],31,$t3 |
| st @acc[1],[$rp+4] |
| srl @acc[4],1,@acc[4] |
| or @acc[3],$t3,@acc[3] |
| sll @acc[5],31,$t4 |
| st @acc[2],[$rp+8] |
| srl @acc[5],1,@acc[5] |
| or @acc[4],$t4,@acc[4] |
| sll @acc[6],31,$t5 |
| st @acc[3],[$rp+12] |
| srl @acc[6],1,@acc[6] |
| or @acc[5],$t5,@acc[5] |
| sll @acc[7],31,$t6 |
| st @acc[4],[$rp+16] |
| srl @acc[7],1,@acc[7] |
| or @acc[6],$t6,@acc[6] |
| sll $carry,31,$t7 |
| st @acc[5],[$rp+20] |
| or @acc[7],$t7,@acc[7] |
| st @acc[6],[$rp+24] |
| retl |
| st @acc[7],[$rp+28] |
| .type __ecp_nistz256_div_by_2,#function |
| .size __ecp_nistz256_div_by_2,.-__ecp_nistz256_div_by_2 |
| ___ |
| |
| ######################################################################## |
| # following subroutines are "literal" implementation of those found in |
| # ecp_nistz256.c |
| # |
| ######################################################################## |
| # void ecp_nistz256_point_double(P256_POINT *out,const P256_POINT *inp); |
| # |
| { |
| my ($S,$M,$Zsqr,$tmp0)=map(32*$_,(0..3)); |
| # above map() describes stack layout with 4 temporary |
| # 256-bit vectors on top. |
| |
| $code.=<<___; |
| #ifdef __PIC__ |
| SPARC_PIC_THUNK(%g1) |
| #endif |
| |
| .globl ecp_nistz256_point_double |
| .align 32 |
| ecp_nistz256_point_double: |
| SPARC_LOAD_ADDRESS_LEAF(OPENSSL_sparcv9cap_P,%g1,%g5) |
| ld [%g1],%g1 ! OPENSSL_sparcv9cap_P[0] |
| and %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK),%g1 |
| cmp %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK) |
| be ecp_nistz256_point_double_vis3 |
| nop |
| |
| save %sp,-STACK_FRAME-32*4,%sp |
| |
| mov $rp,$rp_real |
| mov $ap,$ap_real |
| |
| .Lpoint_double_shortcut: |
| ld [$ap+32],@acc[0] |
| ld [$ap+32+4],@acc[1] |
| ld [$ap+32+8],@acc[2] |
| ld [$ap+32+12],@acc[3] |
| ld [$ap+32+16],@acc[4] |
| ld [$ap+32+20],@acc[5] |
| ld [$ap+32+24],@acc[6] |
| ld [$ap+32+28],@acc[7] |
| call __ecp_nistz256_mul_by_2 ! p256_mul_by_2(S, in_y); |
| add %sp,LOCALS+$S,$rp |
| |
| add $ap_real,64,$bp |
| add $ap_real,64,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Zsqr, in_z); |
| add %sp,LOCALS+$Zsqr,$rp |
| |
| add $ap_real,0,$bp |
| call __ecp_nistz256_add ! p256_add(M, Zsqr, in_x); |
| add %sp,LOCALS+$M,$rp |
| |
| add %sp,LOCALS+$S,$bp |
| add %sp,LOCALS+$S,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(S, S); |
| add %sp,LOCALS+$S,$rp |
| |
| ld [$ap_real],@acc[0] |
| add %sp,LOCALS+$Zsqr,$bp |
| ld [$ap_real+4],@acc[1] |
| ld [$ap_real+8],@acc[2] |
| ld [$ap_real+12],@acc[3] |
| ld [$ap_real+16],@acc[4] |
| ld [$ap_real+20],@acc[5] |
| ld [$ap_real+24],@acc[6] |
| ld [$ap_real+28],@acc[7] |
| call __ecp_nistz256_sub_from ! p256_sub(Zsqr, in_x, Zsqr); |
| add %sp,LOCALS+$Zsqr,$rp |
| |
| add $ap_real,32,$bp |
| add $ap_real,64,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(tmp0, in_z, in_y); |
| add %sp,LOCALS+$tmp0,$rp |
| |
| call __ecp_nistz256_mul_by_2 ! p256_mul_by_2(res_z, tmp0); |
| add $rp_real,64,$rp |
| |
| add %sp,LOCALS+$Zsqr,$bp |
| add %sp,LOCALS+$M,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(M, M, Zsqr); |
| add %sp,LOCALS+$M,$rp |
| |
| call __ecp_nistz256_mul_by_3 ! p256_mul_by_3(M, M); |
| add %sp,LOCALS+$M,$rp |
| |
| add %sp,LOCALS+$S,$bp |
| add %sp,LOCALS+$S,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(tmp0, S); |
| add %sp,LOCALS+$tmp0,$rp |
| |
| call __ecp_nistz256_div_by_2 ! p256_div_by_2(res_y, tmp0); |
| add $rp_real,32,$rp |
| |
| add $ap_real,0,$bp |
| add %sp,LOCALS+$S,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S, S, in_x); |
| add %sp,LOCALS+$S,$rp |
| |
| call __ecp_nistz256_mul_by_2 ! p256_mul_by_2(tmp0, S); |
| add %sp,LOCALS+$tmp0,$rp |
| |
| add %sp,LOCALS+$M,$bp |
| add %sp,LOCALS+$M,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(res_x, M); |
| add $rp_real,0,$rp |
| |
| add %sp,LOCALS+$tmp0,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_x, res_x, tmp0); |
| add $rp_real,0,$rp |
| |
| add %sp,LOCALS+$S,$bp |
| call __ecp_nistz256_sub_morf ! p256_sub(S, S, res_x); |
| add %sp,LOCALS+$S,$rp |
| |
| add %sp,LOCALS+$M,$bp |
| add %sp,LOCALS+$S,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S, S, M); |
| add %sp,LOCALS+$S,$rp |
| |
| add $rp_real,32,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_y, S, res_y); |
| add $rp_real,32,$rp |
| |
| ret |
| restore |
| .type ecp_nistz256_point_double,#function |
| .size ecp_nistz256_point_double,.-ecp_nistz256_point_double |
| ___ |
| } |
| |
| ######################################################################## |
| # void ecp_nistz256_point_add(P256_POINT *out,const P256_POINT *in1, |
| # const P256_POINT *in2); |
| { |
| my ($res_x,$res_y,$res_z, |
| $H,$Hsqr,$R,$Rsqr,$Hcub, |
| $U1,$U2,$S1,$S2)=map(32*$_,(0..11)); |
| my ($Z1sqr, $Z2sqr) = ($Hsqr, $Rsqr); |
| |
| # above map() describes stack layout with 12 temporary |
| # 256-bit vectors on top. Then we reserve some space for |
| # !in1infty, !in2infty, result of check for zero and return pointer. |
| |
| my $bp_real=$rp_real; |
| |
| $code.=<<___; |
| .globl ecp_nistz256_point_add |
| .align 32 |
| ecp_nistz256_point_add: |
| SPARC_LOAD_ADDRESS_LEAF(OPENSSL_sparcv9cap_P,%g1,%g5) |
| ld [%g1],%g1 ! OPENSSL_sparcv9cap_P[0] |
| and %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK),%g1 |
| cmp %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK) |
| be ecp_nistz256_point_add_vis3 |
| nop |
| |
| save %sp,-STACK_FRAME-32*12-32,%sp |
| |
| stx $rp,[%fp+STACK_BIAS-8] ! off-load $rp |
| mov $ap,$ap_real |
| mov $bp,$bp_real |
| |
| ld [$bp+64],$t0 ! in2_z |
| ld [$bp+64+4],$t1 |
| ld [$bp+64+8],$t2 |
| ld [$bp+64+12],$t3 |
| ld [$bp+64+16],$t4 |
| ld [$bp+64+20],$t5 |
| ld [$bp+64+24],$t6 |
| ld [$bp+64+28],$t7 |
| or $t1,$t0,$t0 |
| or $t3,$t2,$t2 |
| or $t5,$t4,$t4 |
| or $t7,$t6,$t6 |
| or $t2,$t0,$t0 |
| or $t6,$t4,$t4 |
| or $t4,$t0,$t0 ! !in2infty |
| movrnz $t0,-1,$t0 |
| st $t0,[%fp+STACK_BIAS-12] |
| |
| ld [$ap+64],$t0 ! in1_z |
| ld [$ap+64+4],$t1 |
| ld [$ap+64+8],$t2 |
| ld [$ap+64+12],$t3 |
| ld [$ap+64+16],$t4 |
| ld [$ap+64+20],$t5 |
| ld [$ap+64+24],$t6 |
| ld [$ap+64+28],$t7 |
| or $t1,$t0,$t0 |
| or $t3,$t2,$t2 |
| or $t5,$t4,$t4 |
| or $t7,$t6,$t6 |
| or $t2,$t0,$t0 |
| or $t6,$t4,$t4 |
| or $t4,$t0,$t0 ! !in1infty |
| movrnz $t0,-1,$t0 |
| st $t0,[%fp+STACK_BIAS-16] |
| |
| add $bp_real,64,$bp |
| add $bp_real,64,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Z2sqr, in2_z); |
| add %sp,LOCALS+$Z2sqr,$rp |
| |
| add $ap_real,64,$bp |
| add $ap_real,64,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Z1sqr, in1_z); |
| add %sp,LOCALS+$Z1sqr,$rp |
| |
| add $bp_real,64,$bp |
| add %sp,LOCALS+$Z2sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S1, Z2sqr, in2_z); |
| add %sp,LOCALS+$S1,$rp |
| |
| add $ap_real,64,$bp |
| add %sp,LOCALS+$Z1sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, Z1sqr, in1_z); |
| add %sp,LOCALS+$S2,$rp |
| |
| add $ap_real,32,$bp |
| add %sp,LOCALS+$S1,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S1, S1, in1_y); |
| add %sp,LOCALS+$S1,$rp |
| |
| add $bp_real,32,$bp |
| add %sp,LOCALS+$S2,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, S2, in2_y); |
| add %sp,LOCALS+$S2,$rp |
| |
| add %sp,LOCALS+$S1,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(R, S2, S1); |
| add %sp,LOCALS+$R,$rp |
| |
| or @acc[1],@acc[0],@acc[0] ! see if result is zero |
| or @acc[3],@acc[2],@acc[2] |
| or @acc[5],@acc[4],@acc[4] |
| or @acc[7],@acc[6],@acc[6] |
| or @acc[2],@acc[0],@acc[0] |
| or @acc[6],@acc[4],@acc[4] |
| or @acc[4],@acc[0],@acc[0] |
| st @acc[0],[%fp+STACK_BIAS-20] |
| |
| add $ap_real,0,$bp |
| add %sp,LOCALS+$Z2sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(U1, in1_x, Z2sqr); |
| add %sp,LOCALS+$U1,$rp |
| |
| add $bp_real,0,$bp |
| add %sp,LOCALS+$Z1sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(U2, in2_x, Z1sqr); |
| add %sp,LOCALS+$U2,$rp |
| |
| add %sp,LOCALS+$U1,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(H, U2, U1); |
| add %sp,LOCALS+$H,$rp |
| |
| or @acc[1],@acc[0],@acc[0] ! see if result is zero |
| or @acc[3],@acc[2],@acc[2] |
| or @acc[5],@acc[4],@acc[4] |
| or @acc[7],@acc[6],@acc[6] |
| or @acc[2],@acc[0],@acc[0] |
| or @acc[6],@acc[4],@acc[4] |
| orcc @acc[4],@acc[0],@acc[0] |
| |
| bne,pt %icc,.Ladd_proceed ! is_equal(U1,U2)? |
| nop |
| |
| ld [%fp+STACK_BIAS-12],$t0 |
| ld [%fp+STACK_BIAS-16],$t1 |
| ld [%fp+STACK_BIAS-20],$t2 |
| andcc $t0,$t1,%g0 |
| be,pt %icc,.Ladd_proceed ! (in1infty || in2infty)? |
| nop |
| andcc $t2,$t2,%g0 |
| be,pt %icc,.Ladd_double ! is_equal(S1,S2)? |
| nop |
| |
| ldx [%fp+STACK_BIAS-8],$rp |
| st %g0,[$rp] |
| st %g0,[$rp+4] |
| st %g0,[$rp+8] |
| st %g0,[$rp+12] |
| st %g0,[$rp+16] |
| st %g0,[$rp+20] |
| st %g0,[$rp+24] |
| st %g0,[$rp+28] |
| st %g0,[$rp+32] |
| st %g0,[$rp+32+4] |
| st %g0,[$rp+32+8] |
| st %g0,[$rp+32+12] |
| st %g0,[$rp+32+16] |
| st %g0,[$rp+32+20] |
| st %g0,[$rp+32+24] |
| st %g0,[$rp+32+28] |
| st %g0,[$rp+64] |
| st %g0,[$rp+64+4] |
| st %g0,[$rp+64+8] |
| st %g0,[$rp+64+12] |
| st %g0,[$rp+64+16] |
| st %g0,[$rp+64+20] |
| st %g0,[$rp+64+24] |
| st %g0,[$rp+64+28] |
| b .Ladd_done |
| nop |
| |
| .align 16 |
| .Ladd_double: |
| ldx [%fp+STACK_BIAS-8],$rp_real |
| mov $ap_real,$ap |
| b .Lpoint_double_shortcut |
| add %sp,32*(12-4)+32,%sp ! difference in frame sizes |
| |
| .align 16 |
| .Ladd_proceed: |
| add %sp,LOCALS+$R,$bp |
| add %sp,LOCALS+$R,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Rsqr, R); |
| add %sp,LOCALS+$Rsqr,$rp |
| |
| add $ap_real,64,$bp |
| add %sp,LOCALS+$H,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(res_z, H, in1_z); |
| add %sp,LOCALS+$res_z,$rp |
| |
| add %sp,LOCALS+$H,$bp |
| add %sp,LOCALS+$H,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Hsqr, H); |
| add %sp,LOCALS+$Hsqr,$rp |
| |
| add $bp_real,64,$bp |
| add %sp,LOCALS+$res_z,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(res_z, res_z, in2_z); |
| add %sp,LOCALS+$res_z,$rp |
| |
| add %sp,LOCALS+$H,$bp |
| add %sp,LOCALS+$Hsqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(Hcub, Hsqr, H); |
| add %sp,LOCALS+$Hcub,$rp |
| |
| add %sp,LOCALS+$U1,$bp |
| add %sp,LOCALS+$Hsqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(U2, U1, Hsqr); |
| add %sp,LOCALS+$U2,$rp |
| |
| call __ecp_nistz256_mul_by_2 ! p256_mul_by_2(Hsqr, U2); |
| add %sp,LOCALS+$Hsqr,$rp |
| |
| add %sp,LOCALS+$Rsqr,$bp |
| call __ecp_nistz256_sub_morf ! p256_sub(res_x, Rsqr, Hsqr); |
| add %sp,LOCALS+$res_x,$rp |
| |
| add %sp,LOCALS+$Hcub,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_x, res_x, Hcub); |
| add %sp,LOCALS+$res_x,$rp |
| |
| add %sp,LOCALS+$U2,$bp |
| call __ecp_nistz256_sub_morf ! p256_sub(res_y, U2, res_x); |
| add %sp,LOCALS+$res_y,$rp |
| |
| add %sp,LOCALS+$Hcub,$bp |
| add %sp,LOCALS+$S1,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, S1, Hcub); |
| add %sp,LOCALS+$S2,$rp |
| |
| add %sp,LOCALS+$R,$bp |
| add %sp,LOCALS+$res_y,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(res_y, res_y, R); |
| add %sp,LOCALS+$res_y,$rp |
| |
| add %sp,LOCALS+$S2,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_y, res_y, S2); |
| add %sp,LOCALS+$res_y,$rp |
| |
| ld [%fp+STACK_BIAS-16],$t1 ! !in1infty |
| ld [%fp+STACK_BIAS-12],$t2 ! !in2infty |
| ldx [%fp+STACK_BIAS-8],$rp |
| ___ |
| for($i=0;$i<96;$i+=8) { # conditional moves |
| $code.=<<___; |
| ld [%sp+LOCALS+$i],@acc[0] ! res |
| ld [%sp+LOCALS+$i+4],@acc[1] |
| ld [$bp_real+$i],@acc[2] ! in2 |
| ld [$bp_real+$i+4],@acc[3] |
| ld [$ap_real+$i],@acc[4] ! in1 |
| ld [$ap_real+$i+4],@acc[5] |
| movrz $t1,@acc[2],@acc[0] |
| movrz $t1,@acc[3],@acc[1] |
| movrz $t2,@acc[4],@acc[0] |
| movrz $t2,@acc[5],@acc[1] |
| st @acc[0],[$rp+$i] |
| st @acc[1],[$rp+$i+4] |
| ___ |
| } |
| $code.=<<___; |
| .Ladd_done: |
| ret |
| restore |
| .type ecp_nistz256_point_add,#function |
| .size ecp_nistz256_point_add,.-ecp_nistz256_point_add |
| ___ |
| } |
| |
| ######################################################################## |
| # void ecp_nistz256_point_add_affine(P256_POINT *out,const P256_POINT *in1, |
| # const P256_POINT_AFFINE *in2); |
| { |
| my ($res_x,$res_y,$res_z, |
| $U2,$S2,$H,$R,$Hsqr,$Hcub,$Rsqr)=map(32*$_,(0..9)); |
| my $Z1sqr = $S2; |
| # above map() describes stack layout with 10 temporary |
| # 256-bit vectors on top. Then we reserve some space for |
| # !in1infty, !in2infty, result of check for zero and return pointer. |
| |
| my @ONE_mont=(1,0,0,-1,-1,-1,-2,0); |
| my $bp_real=$rp_real; |
| |
| $code.=<<___; |
| .globl ecp_nistz256_point_add_affine |
| .align 32 |
| ecp_nistz256_point_add_affine: |
| SPARC_LOAD_ADDRESS_LEAF(OPENSSL_sparcv9cap_P,%g1,%g5) |
| ld [%g1],%g1 ! OPENSSL_sparcv9cap_P[0] |
| and %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK),%g1 |
| cmp %g1,(SPARCV9_VIS3|SPARCV9_64BIT_STACK) |
| be ecp_nistz256_point_add_affine_vis3 |
| nop |
| |
| save %sp,-STACK_FRAME-32*10-32,%sp |
| |
| stx $rp,[%fp+STACK_BIAS-8] ! off-load $rp |
| mov $ap,$ap_real |
| mov $bp,$bp_real |
| |
| ld [$ap+64],$t0 ! in1_z |
| ld [$ap+64+4],$t1 |
| ld [$ap+64+8],$t2 |
| ld [$ap+64+12],$t3 |
| ld [$ap+64+16],$t4 |
| ld [$ap+64+20],$t5 |
| ld [$ap+64+24],$t6 |
| ld [$ap+64+28],$t7 |
| or $t1,$t0,$t0 |
| or $t3,$t2,$t2 |
| or $t5,$t4,$t4 |
| or $t7,$t6,$t6 |
| or $t2,$t0,$t0 |
| or $t6,$t4,$t4 |
| or $t4,$t0,$t0 ! !in1infty |
| movrnz $t0,-1,$t0 |
| st $t0,[%fp+STACK_BIAS-16] |
| |
| ld [$bp],@acc[0] ! in2_x |
| ld [$bp+4],@acc[1] |
| ld [$bp+8],@acc[2] |
| ld [$bp+12],@acc[3] |
| ld [$bp+16],@acc[4] |
| ld [$bp+20],@acc[5] |
| ld [$bp+24],@acc[6] |
| ld [$bp+28],@acc[7] |
| ld [$bp+32],$t0 ! in2_y |
| ld [$bp+32+4],$t1 |
| ld [$bp+32+8],$t2 |
| ld [$bp+32+12],$t3 |
| ld [$bp+32+16],$t4 |
| ld [$bp+32+20],$t5 |
| ld [$bp+32+24],$t6 |
| ld [$bp+32+28],$t7 |
| or @acc[1],@acc[0],@acc[0] |
| or @acc[3],@acc[2],@acc[2] |
| or @acc[5],@acc[4],@acc[4] |
| or @acc[7],@acc[6],@acc[6] |
| or @acc[2],@acc[0],@acc[0] |
| or @acc[6],@acc[4],@acc[4] |
| or @acc[4],@acc[0],@acc[0] |
| or $t1,$t0,$t0 |
| or $t3,$t2,$t2 |
| or $t5,$t4,$t4 |
| or $t7,$t6,$t6 |
| or $t2,$t0,$t0 |
| or $t6,$t4,$t4 |
| or $t4,$t0,$t0 |
| or @acc[0],$t0,$t0 ! !in2infty |
| movrnz $t0,-1,$t0 |
| st $t0,[%fp+STACK_BIAS-12] |
| |
| add $ap_real,64,$bp |
| add $ap_real,64,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Z1sqr, in1_z); |
| add %sp,LOCALS+$Z1sqr,$rp |
| |
| add $bp_real,0,$bp |
| add %sp,LOCALS+$Z1sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(U2, Z1sqr, in2_x); |
| add %sp,LOCALS+$U2,$rp |
| |
| add $ap_real,0,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(H, U2, in1_x); |
| add %sp,LOCALS+$H,$rp |
| |
| add $ap_real,64,$bp |
| add %sp,LOCALS+$Z1sqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, Z1sqr, in1_z); |
| add %sp,LOCALS+$S2,$rp |
| |
| add $ap_real,64,$bp |
| add %sp,LOCALS+$H,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(res_z, H, in1_z); |
| add %sp,LOCALS+$res_z,$rp |
| |
| add $bp_real,32,$bp |
| add %sp,LOCALS+$S2,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, S2, in2_y); |
| add %sp,LOCALS+$S2,$rp |
| |
| add $ap_real,32,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(R, S2, in1_y); |
| add %sp,LOCALS+$R,$rp |
| |
| add %sp,LOCALS+$H,$bp |
| add %sp,LOCALS+$H,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Hsqr, H); |
| add %sp,LOCALS+$Hsqr,$rp |
| |
| add %sp,LOCALS+$R,$bp |
| add %sp,LOCALS+$R,$ap |
| call __ecp_nistz256_mul_mont ! p256_sqr_mont(Rsqr, R); |
| add %sp,LOCALS+$Rsqr,$rp |
| |
| add %sp,LOCALS+$H,$bp |
| add %sp,LOCALS+$Hsqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(Hcub, Hsqr, H); |
| add %sp,LOCALS+$Hcub,$rp |
| |
| add $ap_real,0,$bp |
| add %sp,LOCALS+$Hsqr,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(U2, in1_x, Hsqr); |
| add %sp,LOCALS+$U2,$rp |
| |
| call __ecp_nistz256_mul_by_2 ! p256_mul_by_2(Hsqr, U2); |
| add %sp,LOCALS+$Hsqr,$rp |
| |
| add %sp,LOCALS+$Rsqr,$bp |
| call __ecp_nistz256_sub_morf ! p256_sub(res_x, Rsqr, Hsqr); |
| add %sp,LOCALS+$res_x,$rp |
| |
| add %sp,LOCALS+$Hcub,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_x, res_x, Hcub); |
| add %sp,LOCALS+$res_x,$rp |
| |
| add %sp,LOCALS+$U2,$bp |
| call __ecp_nistz256_sub_morf ! p256_sub(res_y, U2, res_x); |
| add %sp,LOCALS+$res_y,$rp |
| |
| add $ap_real,32,$bp |
| add %sp,LOCALS+$Hcub,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(S2, in1_y, Hcub); |
| add %sp,LOCALS+$S2,$rp |
| |
| add %sp,LOCALS+$R,$bp |
| add %sp,LOCALS+$res_y,$ap |
| call __ecp_nistz256_mul_mont ! p256_mul_mont(res_y, res_y, R); |
| add %sp,LOCALS+$res_y,$rp |
| |
| add %sp,LOCALS+$S2,$bp |
| call __ecp_nistz256_sub_from ! p256_sub(res_y, res_y, S2); |
| add %sp,LOCALS+$res_y,$rp |
| |
| ld [%fp+STACK_BIAS-16],$t1 ! !in1infty |
| ld [%fp+STACK_BIAS-12],$t2 ! !in2infty |
| ldx [%fp+STACK_BIAS-8],$rp |
| ___ |
| for($i=0;$i<64;$i+=8) { # conditional moves |
| $code.=<<___; |
| ld [%sp+LOCALS+$i],@acc[0] ! res |
| ld [%sp+LOCALS+$i+4],@acc[1] |
| ld [$bp_real+$i],@acc[2] ! in2 |
| ld [$bp_real+$i+4],@acc[3] |
| ld [$ap_real+$i],@acc[4] ! in1 |
| ld [$ap_real+$i+4],@acc[5] |
| movrz $t1,@acc[2],@acc[0] |
| movrz $t1,@acc[3],@acc[1] |
| movrz $t2,@acc[4],@acc[0] |
| movrz $t2,@acc[5],@acc[1] |
| st @acc[0],[$rp+$i] |
| st @acc[1],[$rp+$i+4] |
| ___ |
| } |
| for(;$i<96;$i+=8) { |
| my $j=($i-64)/4; |
| $code.=<<___; |
| ld [%sp+LOCALS+$i],@acc[0] ! res |
| ld [%sp+LOCALS+$i+4],@acc[1] |
| ld [$ap_real+$i],@acc[4] ! in1 |
| ld [$ap_real+$i+4],@acc[5] |
| movrz $t1,@ONE_mont[$j],@acc[0] |
| movrz $t1,@ONE_mont[$j+1],@acc[1] |
| movrz $t2,@acc[4],@acc[0] |
| movrz $t2,@acc[5],@acc[1] |
| st @acc[0],[$rp+$i] |
| st @acc[1],[$rp+$i+4] |
| ___ |
| } |
| $code.=<<___; |
| ret |
| restore |
| .type ecp_nistz256_point_add_affine,#function |
| .size ecp_nistz256_point_add_affine,.-ecp_nistz256_point_add_affine |
| ___ |
| } }}} |
| {{{ |
| my ($out,$inp,$index)=map("%i$_",(0..2)); |
| my $mask="%o0"; |
| |
| $code.=<<___; |
| ! void ecp_nistz256_scatter_w5(void *%i0,const P256_POINT *%i1, |
| ! int %i2); |
| .globl ecp_nistz256_scatter_w5 |
| .align 32 |
| ecp_nistz256_scatter_w5: |
| save %sp,-STACK_FRAME,%sp |
| |
| sll $index,2,$index |
| add $out,$index,$out |
| |
| ld [$inp],%l0 ! X |
| ld [$inp+4],%l1 |
| ld [$inp+8],%l2 |
| ld [$inp+12],%l3 |
| ld [$inp+16],%l4 |
| ld [$inp+20],%l5 |
| ld [$inp+24],%l6 |
| ld [$inp+28],%l7 |
| add $inp,32,$inp |
| st %l0,[$out+64*0-4] |
| st %l1,[$out+64*1-4] |
| st %l2,[$out+64*2-4] |
| st %l3,[$out+64*3-4] |
| st %l4,[$out+64*4-4] |
| st %l5,[$out+64*5-4] |
| st %l6,[$out+64*6-4] |
| st %l7,[$out+64*7-4] |
| add $out,64*8,$out |
| |
| ld [$inp],%l0 ! Y |
| ld [$inp+4],%l1 |
| ld [$inp+8],%l2 |
| ld [$inp+12],%l3 |
| ld [$inp+16],%l4 |
| ld [$inp+20],%l5 |
| ld [$inp+24],%l6 |
| ld [$inp+28],%l7 |
| add $inp,32,$inp |
| st %l0,[$out+64*0-4] |
| st %l1,[$out+64*1-4] |
| st %l2,[$out+64*2-4] |
| st %l3,[$out+64*3-4] |
| st %l4,[$out+64*4-4] |
| st %l5,[$out+64*5-4] |
| st %l6,[$out+64*6-4] |
| st %l7,[$out+64*7-4] |
| add $out,64*8,$out |
| |
| ld [$inp],%l0 ! Z |
| ld [$inp+4],%l1 |
| ld [$inp+8],%l2 |
| ld [$inp+12],%l3 |
| ld [$inp+16],%l4 |
| ld [$inp+20],%l5 |
| ld [$inp+24],%l6 |
| ld [$inp+28],%l7 |
| st %l0,[$out+64*0-4] |
| st %l1,[$out+64*1-4] |
| st %l2,[$out+64*2-4] |
| st %l3,[$out+64*3-4] |
| st %l4,[$out+64*4-4] |
| st %l5,[$out+64*5-4] |
| st %l6,[$out+64*6-4] |
| st %l7,[$out+64*7-4] |
| |
| ret |
| restore |
| .type ecp_nistz256_scatter_w5,#function |
| .size ecp_nistz256_scatter_w5,.-ecp_nistz256_scatter_w5 |
| |
| ! void ecp_nistz256_gather_w5(P256_POINT *%i0,const void *%i1, |
| ! int %i2); |
| .globl ecp_nistz256_gather_w5 |
| .align 32 |
| ecp_nistz256_gather_w5: |
| save %sp,-STACK_FRAME,%sp |
| |
| neg $index,$mask |
| srax $mask,63,$mask |
| |
| add $index,$mask,$index |
| sll $index,2,$index |
| add $inp,$index,$inp |
| |
| ld [$inp+64*0],%l0 |
| ld [$inp+64*1],%l1 |
| ld [$inp+64*2],%l2 |
| ld [$inp+64*3],%l3 |
| ld [$inp+64*4],%l4 |
| ld [$inp+64*5],%l5 |
| ld [$inp+64*6],%l6 |
| ld [$inp+64*7],%l7 |
| add $inp,64*8,$inp |
| and %l0,$mask,%l0 |
| and %l1,$mask,%l1 |
| st %l0,[$out] ! X |
| and %l2,$mask,%l2 |
| st %l1,[$out+4] |
| and %l3,$mask,%l3 |
| st %l2,[$out+8] |
| and %l4,$mask,%l4 |
| st %l3,[$out+12] |
| and %l5,$mask,%l5 |
| st %l4,[$out+16] |
| and %l6,$mask,%l6 |
| st %l5,[$out+20] |
| and %l7,$mask,%l7 |
| st %l6,[$out+24] |
| st %l7,[$out+28] |
| add $out,32,$out |
| |
| ld [$inp+64*0],%l0 |
| ld [$inp+64*1],%l1 |
| ld [$inp+64*2],%l2 |
| ld [$inp+64*3],%l3 |
| ld [$inp+64*4],%l4 |
| ld [$inp+64*5],%l5 |
| ld [$inp+64*6],%l6 |
| ld [$inp+64*7],%l7 |
| add $inp,64*8,$inp |
| and %l0,$mask,%l0 |
| and %l1,$mask,%l1 |
| st %l0,[$out] ! Y |
| and %l2,$mask,%l2 |
| st %l1,[$out+4] |
| and %l3,$mask,%l3 |
| st %l2,[$out+8] |
| and %l4,$mask,%l4 |
| st %l3,[$out+12] |
| and %l5,$mask,%l5 |
| st %l4,[$out+16] |
| and %l6,$mask,%l6 |
| st %l5,[$out+20] |
| and %l7,$mask,%l7 |
| st %l6,[$out+24] |
| st %l7,[$out+28] |
| add $out,32,$out |
| |
| ld [$inp+64*0],%l0 |
| ld [$inp+64*1],%l1 |
| ld [$inp+64*2],%l2 |
| ld [$inp+64*3],%l3 |
| ld [$inp+64*4],%l4 |
| ld [$inp+64*5],%l5 |
| ld [$inp+64*6],%l6 |
| ld [$inp+64*7],%l7 |
| and %l0,$mask,%l0 |
| and %l1,$mask,%l1 |
| st %l0,[$out] ! Z |
| and %l2,$mask,%l2 |
| st %l1,[$out+4] |
| and %l3,$mask,%l3 |
| st %l2,[$out+8] |
| and %l4,$mask,%l4 |
| st %l3,[$out+12] |
| and %l5,$mask,%l5 |
| st %l4,[$out+16] |
| and %l6,$mask,%l6 |
| st %l5,[$out+20] |
| and %l7,$mask,%l7 |
| st %l6,[$out+24] |
| st %l7,[$out+28] |
| |
| ret |
| restore |
| .type ecp_nistz256_gather_w5,#function |
| .size ecp_nistz256_gather_w5,.-ecp_nistz256_gather_w5 |
| |
| ! void ecp_nistz256_scatter_w7(void *%i0,const P256_POINT_AFFINE *%i1, |
| ! int %i2); |
| .globl ecp_nistz256_scatter_w7 |
| .align 32 |
| ecp_nistz256_scatter_w7: |
| save %sp,-STACK_FRAME,%sp |
| nop |
| add $out,$index,$out |
| mov 64/4,$index |
| .Loop_scatter_w7: |
| ld [$inp],%l0 |
| add $inp,4,$inp |
| subcc $index,1,$index |
| stb %l0,[$out+64*0] |
| srl %l0,8,%l1 |
| stb %l1,[$out+64*1] |
| srl %l0,16,%l2 |
| stb %l2,[$out+64*2] |
| srl %l0,24,%l3 |
| stb %l3,[$out+64*3] |
| bne .Loop_scatter_w7 |
| add $out,64*4,$out |
| |
| ret |
| restore |
| .type ecp_nistz256_scatter_w7,#function |
| .size ecp_nistz256_scatter_w7,.-ecp_nistz256_scatter_w7 |
| |
| ! void ecp_nistz256_gather_w7(P256_POINT_AFFINE *%i0,const void *%i1, |
| ! int %i2); |
| .globl ecp_nistz256_gather_w7 |
| .align 32 |
| ecp_nistz256_gather_w7: |
| save %sp,-STACK_FRAME,%sp |
| |
| neg $index,$mask |
| srax $mask,63,$mask |
| |
| add $index,$mask,$index |
| add $inp,$index,$inp |
| mov 64/4,$index |
| |
| .Loop_gather_w7: |
| ldub [$inp+64*0],%l0 |
| prefetch [$inp+3840+64*0],1 |
| subcc $index,1,$index |
| ldub [$inp+64*1],%l1 |
| prefetch [$inp+3840+64*1],1 |
| ldub [$inp+64*2],%l2 |
| prefetch [$inp+3840+64*2],1 |
| ldub [$inp+64*3],%l3 |
| prefetch [$inp+3840+64*3],1 |
| add $inp,64*4,$inp |
| sll %l1,8,%l1 |
| sll %l2,16,%l2 |
| or %l0,%l1,%l0 |
| sll %l3,24,%l3 |
| or %l0,%l2,%l0 |
| or %l0,%l3,%l0 |
| and %l0,$mask,%l0 |
| st %l0,[$out] |
| bne .Loop_gather_w7 |
| add $out,4,$out |
| |
| ret |
| restore |
| .type ecp_nistz256_gather_w7,#function |
| .size ecp_nistz256_gather_w7,.-ecp_nistz256_gather_w7 |
| ___ |
| }}} |
| {{{ |
| ######################################################################## |
| # Following subroutines are VIS3 counterparts of those above that |
| # implement ones found in ecp_nistz256.c. Key difference is that they |
| # use 128-bit multiplication and addition with 64-bit carry, and in order |
| # to do that they perform conversion from uin32_t[8] to uint64_t[4] upon |
| # entry and vice versa on return. |
| # |
| my ($rp,$ap,$bp)=map("%i$_",(0..2)); |
| my ($t0,$t1,$t2,$t3,$a0,$a1,$a2,$a3)=map("%l$_",(0..7)); |
| my ($acc0,$acc1,$acc2,$acc3,$acc4,$acc5)=map("%o$_",(0..5)); |
| my ($bi,$poly1,$poly3,$minus1)=(map("%i$_",(3..5)),"%g1"); |
| my ($rp_real,$ap_real)=("%g2","%g3"); |
| my ($acc6,$acc7)=($bp,$bi); # used in squaring |
| |
| $code.=<<___; |
| .align 32 |
| __ecp_nistz256_mul_by_2_vis3: |
| addcc $acc0,$acc0,$acc0 |
| addxccc $acc1,$acc1,$acc1 |
| addxccc $acc2,$acc2,$acc2 |
| addxccc $acc3,$acc3,$acc3 |
| b .Lreduce_by_sub_vis3 |
| addxc %g0,%g0,$acc4 ! did it carry? |
| .type __ecp_nistz256_mul_by_2_vis3,#function |
| .size __ecp_nistz256_mul_by_2_vis3,.-__ecp_nistz256_mul_by_2_vis3 |
| |
| .align 32 |
| __ecp_nistz256_add_vis3: |
| ldx [$bp+0],$t0 |
| ldx [$bp+8],$t1 |
| ldx [$bp+16],$t2 |
| ldx [$bp+24],$t3 |
| |
| __ecp_nistz256_add_noload_vis3: |
| |
| addcc $t0,$acc0,$acc0 |
| addxccc $t1,$acc1,$acc1 |
| addxccc $t2,$acc2,$acc2 |
| addxccc $t3,$acc3,$acc3 |
| addxc %g0,%g0,$acc4 ! did it carry? |
| |
| .Lreduce_by_sub_vis3: |
| |
| addcc $acc0,1,$t0 ! add -modulus, i.e. subtract |
| addxccc $acc1,$poly1,$t1 |
| addxccc $acc2,$minus1,$t2 |
| addxccc $acc3,$poly3,$t3 |
| addxc $acc4,$minus1,$acc4 |
| |
| movrz $acc4,$t0,$acc0 ! ret = borrow ? ret : ret-modulus |
| movrz $acc4,$t1,$acc1 |
| stx $acc0,[$rp] |
| movrz $acc4,$t2,$acc2 |
| stx $acc1,[$rp+8] |
| movrz $acc4,$t3,$acc3 |
| stx $acc2,[$rp+16] |
| retl |
| stx $acc3,[$rp+24] |
| .type __ecp_nistz256_add_vis3,#function |
| .size __ecp_nistz256_add_vis3,.-__ecp_nistz256_add_vis3 |
| |
| ! Trouble with subtraction is that there is no subtraction with 64-bit |
| ! borrow, only with 32-bit one. For this reason we "decompose" 64-bit |
| ! $acc0-$acc3 to 32-bit values and pick b[4] in 32-bit pieces. But |
| ! recall that SPARC is big-endian, which is why you'll observe that |
| ! b[4] is accessed as 4-0-12-8-20-16-28-24. And prior reduction we |
| ! "collect" result back to 64-bit $acc0-$acc3. |
| .align 32 |
| __ecp_nistz256_sub_from_vis3: |
| ld [$bp+4],$t0 |
| ld [$bp+0],$t1 |
| ld [$bp+12],$t2 |
| ld [$bp+8],$t3 |
| |
| srlx $acc0,32,$acc4 |
| not $poly1,$poly1 |
| srlx $acc1,32,$acc5 |
| subcc $acc0,$t0,$acc0 |
| ld [$bp+20],$t0 |
| subccc $acc4,$t1,$acc4 |
| ld [$bp+16],$t1 |
| subccc $acc1,$t2,$acc1 |
| ld [$bp+28],$t2 |
| and $acc0,$poly1,$acc0 |
| subccc $acc5,$t3,$acc5 |
| ld [$bp+24],$t3 |
| sllx $acc4,32,$acc4 |
| and $acc1,$poly1,$acc1 |
| sllx $acc5,32,$acc5 |
| or $acc0,$acc4,$acc0 |
| srlx $acc2,32,$acc4 |
| or $acc1,$acc5,$acc1 |
| srlx $acc3,32,$acc5 |
| subccc $acc2,$t0,$acc2 |
| subccc $acc4,$t1,$acc4 |
| subccc $acc3,$t2,$acc3 |
| and $acc2,$poly1,$acc2 |
| subccc $acc5,$t3,$acc5 |
| sllx $acc4,32,$acc4 |
| and $acc3,$poly1,$acc3 |
| sllx $acc5,32,$acc5 |
| or $acc2,$acc4,$acc2 |
| subc %g0,%g0,$acc4 ! did it borrow? |
| b .Lreduce_by_add_vis3 |
| or $acc3,$acc5,$acc3 |
| .type __ecp_nistz256_sub_from_vis3,#function |
| .size __ecp_nistz256_sub_from_vis3,.-__ecp_nistz256_sub_from_vis3 |
| |
| .align 32 |
| __ecp_nistz256_sub_morf_vis3: |
| ld [$bp+4],$t0 |
| ld [$bp+0],$t1 |
| ld [$bp+12],$t2 |
| ld [$bp+8],$t3 |
| |
| srlx $acc0,32,$acc4 |
| not $poly1,$poly1 |
| srlx $acc1,32,$acc5 |
| subcc $t0,$acc0,$acc0 |
| ld [$bp+20],$t0 |
| subccc $t1,$acc4,$acc4 |
| ld [$bp+16],$t1 |
| subccc $t2,$acc1,$acc1 |
| ld [$bp+28],$t2 |
| and $acc0,$poly1,$acc0 |
| subccc $t3,$acc5,$acc5 |
| ld [$bp+24],$t3 |
| sllx $acc4,32,$acc4 |
| and $acc1,$poly1,$acc1 |
| sllx $acc5,32,$acc5 |
| or $acc0,$acc4,$acc0 |
| srlx $acc2,32,$acc4 |
| or $acc1,$acc5,$acc1 |
| srlx $acc3,32,$acc5 |
| subccc $t0,$acc2,$acc2 |
| subccc $t1,$acc4,$acc4 |
| subccc $t2,$acc3,$acc3 |
| and $acc2,$poly1,$acc2 |
| subccc $t3,$acc5,$acc5 |
| sllx $acc4,32,$acc4 |
| and $acc3,$poly1,$acc3 |
| sllx $acc5,32,$acc5 |
| or $acc2,$acc4,$acc2 |
| subc %g0,%g0,$acc4 ! did it borrow? |
| or $acc3,$acc5,$acc3 |
| |
| .Lreduce_by_add_vis3: |
| |
| addcc $acc0,-1,$t0 ! add modulus |
| not $poly3,$t3 |
| addxccc $acc1,$poly1,$t1 |
| not $poly1,$poly1 ! restore $poly1 |
| addxccc $acc2,%g0,$t2 |
| addxc $acc3,$t3,$t3 |
| |
| movrnz $acc4,$t0,$acc0 ! if a-b borrowed, ret = ret+mod |
| movrnz $acc4,$t1,$acc1 |
| stx $acc0,[$rp] |
| movrnz $acc4,$t2,$acc2 |
| stx $acc1,[$rp+8] |
| movrnz $acc4,$t3,$acc3 |
| stx $acc2,[$rp+16] |
| retl |
| stx $acc3,[$rp+24] |
| .type __ecp_nistz256_sub_morf_vis3,#function |
| .size __ecp_nistz256_sub_morf_vis3,.-__ecp_nistz256_sub_morf_vis3 |
| |
| .align 32 |
| __ecp_nistz256_div_by_2_vis3: |
| ! ret = (a is odd ? a+mod : a) >> 1 |
| |
| not $poly1,$t1 |
| not $poly3,$t3 |
| and $acc0,1,$acc5 |
| addcc $acc0,-1,$t0 ! add modulus |
| addxccc $acc1,$t1,$t1 |
| addxccc $acc2,%g0,$t2 |
| addxccc $acc3,$t3,$t3 |
| addxc %g0,%g0,$acc4 ! carry bit |
| |
| movrnz $acc5,$t0,$acc0 |
| movrnz $acc5,$t1,$acc1 |
| movrnz $acc5,$t2,$acc2 |
| movrnz $acc5,$t3,$acc3 |
| movrz $acc5,%g0,$acc4 |
| |
| ! ret >>= 1 |
| |
| srlx $acc0,1,$acc0 |
| sllx $acc1,63,$t0 |
| srlx $acc1,1,$acc1 |
| or $acc0,$t0,$acc0 |
| sllx $acc2,63,$t1 |
| srlx $acc2,1,$acc2 |
| or $acc1,$t1,$acc1 |
| sllx $acc3,63,$t2 |
| stx $acc0,[$rp] |
| srlx $acc3,1,$acc3 |
| or $acc2,$t2,$acc2 |
| sllx $acc4,63,$t3 ! don't forget carry bit |
| stx $acc1,[$rp+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[$rp+16] |
| retl |
| stx $acc3,[$rp+24] |
| .type __ecp_nistz256_div_by_2_vis3,#function |
| .size __ecp_nistz256_div_by_2_vis3,.-__ecp_nistz256_div_by_2_vis3 |
| |
| ! compared to __ecp_nistz256_mul_mont it's almost 4x smaller and |
| ! 4x faster [on T4]... |
| .align 32 |
| __ecp_nistz256_mul_mont_vis3: |
| mulx $a0,$bi,$acc0 |
| not $poly3,$poly3 ! 0xFFFFFFFF00000001 |
| umulxhi $a0,$bi,$t0 |
| mulx $a1,$bi,$acc1 |
| umulxhi $a1,$bi,$t1 |
| mulx $a2,$bi,$acc2 |
| umulxhi $a2,$bi,$t2 |
| mulx $a3,$bi,$acc3 |
| umulxhi $a3,$bi,$t3 |
| ldx [$bp+8],$bi ! b[1] |
| |
| addcc $acc1,$t0,$acc1 ! accumulate high parts of multiplication |
| sllx $acc0,32,$t0 |
| addxccc $acc2,$t1,$acc2 |
| srlx $acc0,32,$t1 |
| addxccc $acc3,$t2,$acc3 |
| addxc %g0,$t3,$acc4 |
| mov 0,$acc5 |
| ___ |
| for($i=1;$i<4;$i++) { |
| # Reduction iteration is normally performed by accumulating |
| # result of multiplication of modulus by "magic" digit [and |
| # omitting least significant word, which is guaranteed to |
| # be 0], but thanks to special form of modulus and "magic" |
| # digit being equal to least significant word, it can be |
| # performed with additions and subtractions alone. Indeed: |
| # |
| # ffff0001.00000000.0000ffff.ffffffff |
| # * abcdefgh |
| # + xxxxxxxx.xxxxxxxx.xxxxxxxx.xxxxxxxx.abcdefgh |
| # |
| # Now observing that ff..ff*x = (2^n-1)*x = 2^n*x-x, we |
| # rewrite above as: |
| # |
| # xxxxxxxx.xxxxxxxx.xxxxxxxx.xxxxxxxx.abcdefgh |
| # + abcdefgh.abcdefgh.0000abcd.efgh0000.00000000 |
| # - 0000abcd.efgh0000.00000000.00000000.abcdefgh |
| # |
| # or marking redundant operations: |
| # |
| # xxxxxxxx.xxxxxxxx.xxxxxxxx.xxxxxxxx.-------- |
| # + abcdefgh.abcdefgh.0000abcd.efgh0000.-------- |
| # - 0000abcd.efgh0000.--------.--------.-------- |
| # ^^^^^^^^ but this word is calculated with umulxhi, because |
| # there is no subtract with 64-bit borrow:-( |
| |
| $code.=<<___; |
| sub $acc0,$t0,$t2 ! acc0*0xFFFFFFFF00000001, low part |
| umulxhi $acc0,$poly3,$t3 ! acc0*0xFFFFFFFF00000001, high part |
| addcc $acc1,$t0,$acc0 ! +=acc[0]<<96 and omit acc[0] |
| mulx $a0,$bi,$t0 |
| addxccc $acc2,$t1,$acc1 |
| mulx $a1,$bi,$t1 |
| addxccc $acc3,$t2,$acc2 ! +=acc[0]*0xFFFFFFFF00000001 |
| mulx $a2,$bi,$t2 |
| addxccc $acc4,$t3,$acc3 |
| mulx $a3,$bi,$t3 |
| addxc $acc5,%g0,$acc4 |
| |
| addcc $acc0,$t0,$acc0 ! accumulate low parts of multiplication |
| umulxhi $a0,$bi,$t0 |
| addxccc $acc1,$t1,$acc1 |
| umulxhi $a1,$bi,$t1 |
| addxccc $acc2,$t2,$acc2 |
| umulxhi $a2,$bi,$t2 |
| addxccc $acc3,$t3,$acc3 |
| umulxhi $a3,$bi,$t3 |
| addxc $acc4,%g0,$acc4 |
| ___ |
| $code.=<<___ if ($i<3); |
| ldx [$bp+8*($i+1)],$bi ! bp[$i+1] |
| ___ |
| $code.=<<___; |
| addcc $acc1,$t0,$acc1 ! accumulate high parts of multiplication |
| sllx $acc0,32,$t0 |
| addxccc $acc2,$t1,$acc2 |
| srlx $acc0,32,$t1 |
| addxccc $acc3,$t2,$acc3 |
| addxccc $acc4,$t3,$acc4 |
| addxc %g0,%g0,$acc5 |
| ___ |
| } |
| $code.=<<___; |
| sub $acc0,$t0,$t2 ! acc0*0xFFFFFFFF00000001, low part |
| umulxhi $acc0,$poly3,$t3 ! acc0*0xFFFFFFFF00000001, high part |
| addcc $acc1,$t0,$acc0 ! +=acc[0]<<96 and omit acc[0] |
| addxccc $acc2,$t1,$acc1 |
| addxccc $acc3,$t2,$acc2 ! +=acc[0]*0xFFFFFFFF00000001 |
| addxccc $acc4,$t3,$acc3 |
| b .Lmul_final_vis3 ! see below |
| addxc $acc5,%g0,$acc4 |
| .type __ecp_nistz256_mul_mont_vis3,#function |
| .size __ecp_nistz256_mul_mont_vis3,.-__ecp_nistz256_mul_mont_vis3 |
| |
| ! compared to above __ecp_nistz256_mul_mont_vis3 it's 21% less |
| ! instructions, but only 14% faster [on T4]... |
| .align 32 |
| __ecp_nistz256_sqr_mont_vis3: |
| ! | | | | | |a1*a0| | |
| ! | | | | |a2*a0| | | |
| ! | |a3*a2|a3*a0| | | | |
| ! | | | |a2*a1| | | | |
| ! | | |a3*a1| | | | | |
| ! *| | | | | | | | 2| |
| ! +|a3*a3|a2*a2|a1*a1|a0*a0| |
| ! |--+--+--+--+--+--+--+--| |
| ! |A7|A6|A5|A4|A3|A2|A1|A0|, where Ax is $accx, i.e. follow $accx |
| ! |
| ! "can't overflow" below mark carrying into high part of |
| ! multiplication result, which can't overflow, because it |
| ! can never be all ones. |
| |
| mulx $a1,$a0,$acc1 ! a[1]*a[0] |
| umulxhi $a1,$a0,$t1 |
| mulx $a2,$a0,$acc2 ! a[2]*a[0] |
| umulxhi $a2,$a0,$t2 |
| mulx $a3,$a0,$acc3 ! a[3]*a[0] |
| umulxhi $a3,$a0,$acc4 |
| |
| addcc $acc2,$t1,$acc2 ! accumulate high parts of multiplication |
| mulx $a2,$a1,$t0 ! a[2]*a[1] |
| umulxhi $a2,$a1,$t1 |
| addxccc $acc3,$t2,$acc3 |
| mulx $a3,$a1,$t2 ! a[3]*a[1] |
| umulxhi $a3,$a1,$t3 |
| addxc $acc4,%g0,$acc4 ! can't overflow |
| |
| mulx $a3,$a2,$acc5 ! a[3]*a[2] |
| not $poly3,$poly3 ! 0xFFFFFFFF00000001 |
| umulxhi $a3,$a2,$acc6 |
| |
| addcc $t2,$t1,$t1 ! accumulate high parts of multiplication |
| mulx $a0,$a0,$acc0 ! a[0]*a[0] |
| addxc $t3,%g0,$t2 ! can't overflow |
| |
| addcc $acc3,$t0,$acc3 ! accumulate low parts of multiplication |
| umulxhi $a0,$a0,$a0 |
| addxccc $acc4,$t1,$acc4 |
| mulx $a1,$a1,$t1 ! a[1]*a[1] |
| addxccc $acc5,$t2,$acc5 |
| umulxhi $a1,$a1,$a1 |
| addxc $acc6,%g0,$acc6 ! can't overflow |
| |
| addcc $acc1,$acc1,$acc1 ! acc[1-6]*=2 |
| mulx $a2,$a2,$t2 ! a[2]*a[2] |
| addxccc $acc2,$acc2,$acc2 |
| umulxhi $a2,$a2,$a2 |
| addxccc $acc3,$acc3,$acc3 |
| mulx $a3,$a3,$t3 ! a[3]*a[3] |
| addxccc $acc4,$acc4,$acc4 |
| umulxhi $a3,$a3,$a3 |
| addxccc $acc5,$acc5,$acc5 |
| addxccc $acc6,$acc6,$acc6 |
| addxc %g0,%g0,$acc7 |
| |
| addcc $acc1,$a0,$acc1 ! +a[i]*a[i] |
| addxccc $acc2,$t1,$acc2 |
| addxccc $acc3,$a1,$acc3 |
| addxccc $acc4,$t2,$acc4 |
| sllx $acc0,32,$t0 |
| addxccc $acc5,$a2,$acc5 |
| srlx $acc0,32,$t1 |
| addxccc $acc6,$t3,$acc6 |
| sub $acc0,$t0,$t2 ! acc0*0xFFFFFFFF00000001, low part |
| addxc $acc7,$a3,$acc7 |
| ___ |
| for($i=0;$i<3;$i++) { # reductions, see commentary |
| # in multiplication for details |
| $code.=<<___; |
| umulxhi $acc0,$poly3,$t3 ! acc0*0xFFFFFFFF00000001, high part |
| addcc $acc1,$t0,$acc0 ! +=acc[0]<<96 and omit acc[0] |
| sllx $acc0,32,$t0 |
| addxccc $acc2,$t1,$acc1 |
| srlx $acc0,32,$t1 |
| addxccc $acc3,$t2,$acc2 ! +=acc[0]*0xFFFFFFFF00000001 |
| sub $acc0,$t0,$t2 ! acc0*0xFFFFFFFF00000001, low part |
| addxc %g0,$t3,$acc3 ! can't overflow |
| ___ |
| } |
| $code.=<<___; |
| umulxhi $acc0,$poly3,$t3 ! acc0*0xFFFFFFFF00000001, high part |
| addcc $acc1,$t0,$acc0 ! +=acc[0]<<96 and omit acc[0] |
| addxccc $acc2,$t1,$acc1 |
| addxccc $acc3,$t2,$acc2 ! +=acc[0]*0xFFFFFFFF00000001 |
| addxc %g0,$t3,$acc3 ! can't overflow |
| |
| addcc $acc0,$acc4,$acc0 ! accumulate upper half |
| addxccc $acc1,$acc5,$acc1 |
| addxccc $acc2,$acc6,$acc2 |
| addxccc $acc3,$acc7,$acc3 |
| addxc %g0,%g0,$acc4 |
| |
| .Lmul_final_vis3: |
| |
| ! Final step is "if result > mod, subtract mod", but as comparison |
| ! means subtraction, we do the subtraction and then copy outcome |
| ! if it didn't borrow. But note that as we [have to] replace |
| ! subtraction with addition with negative, carry/borrow logic is |
| ! inverse. |
| |
| addcc $acc0,1,$t0 ! add -modulus, i.e. subtract |
| not $poly3,$poly3 ! restore 0x00000000FFFFFFFE |
| addxccc $acc1,$poly1,$t1 |
| addxccc $acc2,$minus1,$t2 |
| addxccc $acc3,$poly3,$t3 |
| addxccc $acc4,$minus1,%g0 ! did it carry? |
| |
| movcs %xcc,$t0,$acc0 |
| movcs %xcc,$t1,$acc1 |
| stx $acc0,[$rp] |
| movcs %xcc,$t2,$acc2 |
| stx $acc1,[$rp+8] |
| movcs %xcc,$t3,$acc3 |
| stx $acc2,[$rp+16] |
| retl |
| stx $acc3,[$rp+24] |
| .type __ecp_nistz256_sqr_mont_vis3,#function |
| .size __ecp_nistz256_sqr_mont_vis3,.-__ecp_nistz256_sqr_mont_vis3 |
| ___ |
| |
| ######################################################################## |
| # void ecp_nistz256_point_double(P256_POINT *out,const P256_POINT *inp); |
| # |
| { |
| my ($res_x,$res_y,$res_z, |
| $in_x,$in_y,$in_z, |
| $S,$M,$Zsqr,$tmp0)=map(32*$_,(0..9)); |
| # above map() describes stack layout with 10 temporary |
| # 256-bit vectors on top. |
| |
| $code.=<<___; |
| .align 32 |
| ecp_nistz256_point_double_vis3: |
| save %sp,-STACK64_FRAME-32*10,%sp |
| |
| mov $rp,$rp_real |
| .Ldouble_shortcut_vis3: |
| mov -1,$minus1 |
| mov -2,$poly3 |
| sllx $minus1,32,$poly1 ! 0xFFFFFFFF00000000 |
| srl $poly3,0,$poly3 ! 0x00000000FFFFFFFE |
| |
| ! convert input to uint64_t[4] |
| ld [$ap],$a0 ! in_x |
| ld [$ap+4],$t0 |
| ld [$ap+8],$a1 |
| ld [$ap+12],$t1 |
| ld [$ap+16],$a2 |
| ld [$ap+20],$t2 |
| ld [$ap+24],$a3 |
| ld [$ap+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| ld [$ap+32],$acc0 ! in_y |
| or $a0,$t0,$a0 |
| ld [$ap+32+4],$t0 |
| sllx $t2,32,$t2 |
| ld [$ap+32+8],$acc1 |
| or $a1,$t1,$a1 |
| ld [$ap+32+12],$t1 |
| sllx $t3,32,$t3 |
| ld [$ap+32+16],$acc2 |
| or $a2,$t2,$a2 |
| ld [$ap+32+20],$t2 |
| or $a3,$t3,$a3 |
| ld [$ap+32+24],$acc3 |
| sllx $t0,32,$t0 |
| ld [$ap+32+28],$t3 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in_x] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in_x+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in_x+16] |
| or $acc0,$t0,$acc0 |
| stx $a3,[%sp+LOCALS64+$in_x+24] |
| or $acc1,$t1,$acc1 |
| stx $acc0,[%sp+LOCALS64+$in_y] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in_y+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in_y+16] |
| stx $acc3,[%sp+LOCALS64+$in_y+24] |
| |
| ld [$ap+64],$a0 ! in_z |
| ld [$ap+64+4],$t0 |
| ld [$ap+64+8],$a1 |
| ld [$ap+64+12],$t1 |
| ld [$ap+64+16],$a2 |
| ld [$ap+64+20],$t2 |
| ld [$ap+64+24],$a3 |
| ld [$ap+64+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| or $a0,$t0,$a0 |
| sllx $t2,32,$t2 |
| or $a1,$t1,$a1 |
| sllx $t3,32,$t3 |
| or $a2,$t2,$a2 |
| or $a3,$t3,$a3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in_z] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in_z+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in_z+16] |
| stx $a3,[%sp+LOCALS64+$in_z+24] |
| |
| ! in_y is still in $acc0-$acc3 |
| call __ecp_nistz256_mul_by_2_vis3 ! p256_mul_by_2(S, in_y); |
| add %sp,LOCALS64+$S,$rp |
| |
| ! in_z is still in $a0-$a3 |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Zsqr, in_z); |
| add %sp,LOCALS64+$Zsqr,$rp |
| |
| mov $acc0,$a0 ! put Zsqr aside |
| mov $acc1,$a1 |
| mov $acc2,$a2 |
| mov $acc3,$a3 |
| |
| add %sp,LOCALS64+$in_x,$bp |
| call __ecp_nistz256_add_vis3 ! p256_add(M, Zsqr, in_x); |
| add %sp,LOCALS64+$M,$rp |
| |
| mov $a0,$acc0 ! restore Zsqr |
| ldx [%sp+LOCALS64+$S],$a0 ! forward load |
| mov $a1,$acc1 |
| ldx [%sp+LOCALS64+$S+8],$a1 |
| mov $a2,$acc2 |
| ldx [%sp+LOCALS64+$S+16],$a2 |
| mov $a3,$acc3 |
| ldx [%sp+LOCALS64+$S+24],$a3 |
| |
| add %sp,LOCALS64+$in_x,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(Zsqr, in_x, Zsqr); |
| add %sp,LOCALS64+$Zsqr,$rp |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(S, S); |
| add %sp,LOCALS64+$S,$rp |
| |
| ldx [%sp+LOCALS64+$in_z],$bi |
| ldx [%sp+LOCALS64+$in_y],$a0 |
| ldx [%sp+LOCALS64+$in_y+8],$a1 |
| ldx [%sp+LOCALS64+$in_y+16],$a2 |
| ldx [%sp+LOCALS64+$in_y+24],$a3 |
| add %sp,LOCALS64+$in_z,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(tmp0, in_z, in_y); |
| add %sp,LOCALS64+$tmp0,$rp |
| |
| ldx [%sp+LOCALS64+$M],$bi ! forward load |
| ldx [%sp+LOCALS64+$Zsqr],$a0 |
| ldx [%sp+LOCALS64+$Zsqr+8],$a1 |
| ldx [%sp+LOCALS64+$Zsqr+16],$a2 |
| ldx [%sp+LOCALS64+$Zsqr+24],$a3 |
| |
| call __ecp_nistz256_mul_by_2_vis3 ! p256_mul_by_2(res_z, tmp0); |
| add %sp,LOCALS64+$res_z,$rp |
| |
| add %sp,LOCALS64+$M,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(M, M, Zsqr); |
| add %sp,LOCALS64+$M,$rp |
| |
| mov $acc0,$a0 ! put aside M |
| mov $acc1,$a1 |
| mov $acc2,$a2 |
| mov $acc3,$a3 |
| call __ecp_nistz256_mul_by_2_vis3 |
| add %sp,LOCALS64+$M,$rp |
| mov $a0,$t0 ! copy M |
| ldx [%sp+LOCALS64+$S],$a0 ! forward load |
| mov $a1,$t1 |
| ldx [%sp+LOCALS64+$S+8],$a1 |
| mov $a2,$t2 |
| ldx [%sp+LOCALS64+$S+16],$a2 |
| mov $a3,$t3 |
| ldx [%sp+LOCALS64+$S+24],$a3 |
| call __ecp_nistz256_add_noload_vis3 ! p256_mul_by_3(M, M); |
| add %sp,LOCALS64+$M,$rp |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(tmp0, S); |
| add %sp,LOCALS64+$tmp0,$rp |
| |
| ldx [%sp+LOCALS64+$S],$bi ! forward load |
| ldx [%sp+LOCALS64+$in_x],$a0 |
| ldx [%sp+LOCALS64+$in_x+8],$a1 |
| ldx [%sp+LOCALS64+$in_x+16],$a2 |
| ldx [%sp+LOCALS64+$in_x+24],$a3 |
| |
| call __ecp_nistz256_div_by_2_vis3 ! p256_div_by_2(res_y, tmp0); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| add %sp,LOCALS64+$S,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S, S, in_x); |
| add %sp,LOCALS64+$S,$rp |
| |
| ldx [%sp+LOCALS64+$M],$a0 ! forward load |
| ldx [%sp+LOCALS64+$M+8],$a1 |
| ldx [%sp+LOCALS64+$M+16],$a2 |
| ldx [%sp+LOCALS64+$M+24],$a3 |
| |
| call __ecp_nistz256_mul_by_2_vis3 ! p256_mul_by_2(tmp0, S); |
| add %sp,LOCALS64+$tmp0,$rp |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(res_x, M); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| add %sp,LOCALS64+$tmp0,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_x, res_x, tmp0); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| ldx [%sp+LOCALS64+$M],$a0 ! forward load |
| ldx [%sp+LOCALS64+$M+8],$a1 |
| ldx [%sp+LOCALS64+$M+16],$a2 |
| ldx [%sp+LOCALS64+$M+24],$a3 |
| |
| add %sp,LOCALS64+$S,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(S, S, res_x); |
| add %sp,LOCALS64+$S,$rp |
| |
| mov $acc0,$bi |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S, S, M); |
| add %sp,LOCALS64+$S,$rp |
| |
| ldx [%sp+LOCALS64+$res_x],$a0 ! forward load |
| ldx [%sp+LOCALS64+$res_x+8],$a1 |
| ldx [%sp+LOCALS64+$res_x+16],$a2 |
| ldx [%sp+LOCALS64+$res_x+24],$a3 |
| |
| add %sp,LOCALS64+$res_y,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_y, S, res_y); |
| add %sp,LOCALS64+$res_y,$bp |
| |
| ! convert output to uint_32[8] |
| srlx $a0,32,$t0 |
| srlx $a1,32,$t1 |
| st $a0,[$rp_real] ! res_x |
| srlx $a2,32,$t2 |
| st $t0,[$rp_real+4] |
| srlx $a3,32,$t3 |
| st $a1,[$rp_real+8] |
| st $t1,[$rp_real+12] |
| st $a2,[$rp_real+16] |
| st $t2,[$rp_real+20] |
| st $a3,[$rp_real+24] |
| st $t3,[$rp_real+28] |
| |
| ldx [%sp+LOCALS64+$res_z],$a0 ! forward load |
| srlx $acc0,32,$t0 |
| ldx [%sp+LOCALS64+$res_z+8],$a1 |
| srlx $acc1,32,$t1 |
| ldx [%sp+LOCALS64+$res_z+16],$a2 |
| srlx $acc2,32,$t2 |
| ldx [%sp+LOCALS64+$res_z+24],$a3 |
| srlx $acc3,32,$t3 |
| st $acc0,[$rp_real+32] ! res_y |
| st $t0, [$rp_real+32+4] |
| st $acc1,[$rp_real+32+8] |
| st $t1, [$rp_real+32+12] |
| st $acc2,[$rp_real+32+16] |
| st $t2, [$rp_real+32+20] |
| st $acc3,[$rp_real+32+24] |
| st $t3, [$rp_real+32+28] |
| |
| srlx $a0,32,$t0 |
| srlx $a1,32,$t1 |
| st $a0,[$rp_real+64] ! res_z |
| srlx $a2,32,$t2 |
| st $t0,[$rp_real+64+4] |
| srlx $a3,32,$t3 |
| st $a1,[$rp_real+64+8] |
| st $t1,[$rp_real+64+12] |
| st $a2,[$rp_real+64+16] |
| st $t2,[$rp_real+64+20] |
| st $a3,[$rp_real+64+24] |
| st $t3,[$rp_real+64+28] |
| |
| ret |
| restore |
| .type ecp_nistz256_point_double_vis3,#function |
| .size ecp_nistz256_point_double_vis3,.-ecp_nistz256_point_double_vis3 |
| ___ |
| } |
| ######################################################################## |
| # void ecp_nistz256_point_add(P256_POINT *out,const P256_POINT *in1, |
| # const P256_POINT *in2); |
| { |
| my ($res_x,$res_y,$res_z, |
| $in1_x,$in1_y,$in1_z, |
| $in2_x,$in2_y,$in2_z, |
| $H,$Hsqr,$R,$Rsqr,$Hcub, |
| $U1,$U2,$S1,$S2)=map(32*$_,(0..17)); |
| my ($Z1sqr, $Z2sqr) = ($Hsqr, $Rsqr); |
| |
| # above map() describes stack layout with 18 temporary |
| # 256-bit vectors on top. Then we reserve some space for |
| # !in1infty, !in2infty and result of check for zero. |
| |
| $code.=<<___; |
| .align 32 |
| ecp_nistz256_point_add_vis3: |
| save %sp,-STACK64_FRAME-32*18-32,%sp |
| |
| mov $rp,$rp_real |
| mov -1,$minus1 |
| mov -2,$poly3 |
| sllx $minus1,32,$poly1 ! 0xFFFFFFFF00000000 |
| srl $poly3,0,$poly3 ! 0x00000000FFFFFFFE |
| |
| ! convert input to uint64_t[4] |
| ld [$bp],$a0 ! in2_x |
| ld [$bp+4],$t0 |
| ld [$bp+8],$a1 |
| ld [$bp+12],$t1 |
| ld [$bp+16],$a2 |
| ld [$bp+20],$t2 |
| ld [$bp+24],$a3 |
| ld [$bp+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| ld [$bp+32],$acc0 ! in2_y |
| or $a0,$t0,$a0 |
| ld [$bp+32+4],$t0 |
| sllx $t2,32,$t2 |
| ld [$bp+32+8],$acc1 |
| or $a1,$t1,$a1 |
| ld [$bp+32+12],$t1 |
| sllx $t3,32,$t3 |
| ld [$bp+32+16],$acc2 |
| or $a2,$t2,$a2 |
| ld [$bp+32+20],$t2 |
| or $a3,$t3,$a3 |
| ld [$bp+32+24],$acc3 |
| sllx $t0,32,$t0 |
| ld [$bp+32+28],$t3 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in2_x] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in2_x+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in2_x+16] |
| or $acc0,$t0,$acc0 |
| stx $a3,[%sp+LOCALS64+$in2_x+24] |
| or $acc1,$t1,$acc1 |
| stx $acc0,[%sp+LOCALS64+$in2_y] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in2_y+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in2_y+16] |
| stx $acc3,[%sp+LOCALS64+$in2_y+24] |
| |
| ld [$bp+64],$acc0 ! in2_z |
| ld [$bp+64+4],$t0 |
| ld [$bp+64+8],$acc1 |
| ld [$bp+64+12],$t1 |
| ld [$bp+64+16],$acc2 |
| ld [$bp+64+20],$t2 |
| ld [$bp+64+24],$acc3 |
| ld [$bp+64+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| ld [$ap],$a0 ! in1_x |
| or $acc0,$t0,$acc0 |
| ld [$ap+4],$t0 |
| sllx $t2,32,$t2 |
| ld [$ap+8],$a1 |
| or $acc1,$t1,$acc1 |
| ld [$ap+12],$t1 |
| sllx $t3,32,$t3 |
| ld [$ap+16],$a2 |
| or $acc2,$t2,$acc2 |
| ld [$ap+20],$t2 |
| or $acc3,$t3,$acc3 |
| ld [$ap+24],$a3 |
| sllx $t0,32,$t0 |
| ld [$ap+28],$t3 |
| sllx $t1,32,$t1 |
| stx $acc0,[%sp+LOCALS64+$in2_z] |
| sllx $t2,32,$t2 |
| stx $acc1,[%sp+LOCALS64+$in2_z+8] |
| sllx $t3,32,$t3 |
| stx $acc2,[%sp+LOCALS64+$in2_z+16] |
| stx $acc3,[%sp+LOCALS64+$in2_z+24] |
| |
| or $acc1,$acc0,$acc0 |
| or $acc3,$acc2,$acc2 |
| or $acc2,$acc0,$acc0 |
| movrnz $acc0,-1,$acc0 ! !in2infty |
| stx $acc0,[%fp+STACK_BIAS-8] |
| |
| or $a0,$t0,$a0 |
| ld [$ap+32],$acc0 ! in1_y |
| or $a1,$t1,$a1 |
| ld [$ap+32+4],$t0 |
| or $a2,$t2,$a2 |
| ld [$ap+32+8],$acc1 |
| or $a3,$t3,$a3 |
| ld [$ap+32+12],$t1 |
| ld [$ap+32+16],$acc2 |
| ld [$ap+32+20],$t2 |
| ld [$ap+32+24],$acc3 |
| sllx $t0,32,$t0 |
| ld [$ap+32+28],$t3 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in1_x] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in1_x+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in1_x+16] |
| or $acc0,$t0,$acc0 |
| stx $a3,[%sp+LOCALS64+$in1_x+24] |
| or $acc1,$t1,$acc1 |
| stx $acc0,[%sp+LOCALS64+$in1_y] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in1_y+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in1_y+16] |
| stx $acc3,[%sp+LOCALS64+$in1_y+24] |
| |
| ldx [%sp+LOCALS64+$in2_z],$a0 ! forward load |
| ldx [%sp+LOCALS64+$in2_z+8],$a1 |
| ldx [%sp+LOCALS64+$in2_z+16],$a2 |
| ldx [%sp+LOCALS64+$in2_z+24],$a3 |
| |
| ld [$ap+64],$acc0 ! in1_z |
| ld [$ap+64+4],$t0 |
| ld [$ap+64+8],$acc1 |
| ld [$ap+64+12],$t1 |
| ld [$ap+64+16],$acc2 |
| ld [$ap+64+20],$t2 |
| ld [$ap+64+24],$acc3 |
| ld [$ap+64+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| or $acc0,$t0,$acc0 |
| sllx $t2,32,$t2 |
| or $acc1,$t1,$acc1 |
| sllx $t3,32,$t3 |
| stx $acc0,[%sp+LOCALS64+$in1_z] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in1_z+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in1_z+16] |
| stx $acc3,[%sp+LOCALS64+$in1_z+24] |
| |
| or $acc1,$acc0,$acc0 |
| or $acc3,$acc2,$acc2 |
| or $acc2,$acc0,$acc0 |
| movrnz $acc0,-1,$acc0 ! !in1infty |
| stx $acc0,[%fp+STACK_BIAS-16] |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Z2sqr, in2_z); |
| add %sp,LOCALS64+$Z2sqr,$rp |
| |
| ldx [%sp+LOCALS64+$in1_z],$a0 |
| ldx [%sp+LOCALS64+$in1_z+8],$a1 |
| ldx [%sp+LOCALS64+$in1_z+16],$a2 |
| ldx [%sp+LOCALS64+$in1_z+24],$a3 |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Z1sqr, in1_z); |
| add %sp,LOCALS64+$Z1sqr,$rp |
| |
| ldx [%sp+LOCALS64+$Z2sqr],$bi |
| ldx [%sp+LOCALS64+$in2_z],$a0 |
| ldx [%sp+LOCALS64+$in2_z+8],$a1 |
| ldx [%sp+LOCALS64+$in2_z+16],$a2 |
| ldx [%sp+LOCALS64+$in2_z+24],$a3 |
| add %sp,LOCALS64+$Z2sqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S1, Z2sqr, in2_z); |
| add %sp,LOCALS64+$S1,$rp |
| |
| ldx [%sp+LOCALS64+$Z1sqr],$bi |
| ldx [%sp+LOCALS64+$in1_z],$a0 |
| ldx [%sp+LOCALS64+$in1_z+8],$a1 |
| ldx [%sp+LOCALS64+$in1_z+16],$a2 |
| ldx [%sp+LOCALS64+$in1_z+24],$a3 |
| add %sp,LOCALS64+$Z1sqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, Z1sqr, in1_z); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$S1],$bi |
| ldx [%sp+LOCALS64+$in1_y],$a0 |
| ldx [%sp+LOCALS64+$in1_y+8],$a1 |
| ldx [%sp+LOCALS64+$in1_y+16],$a2 |
| ldx [%sp+LOCALS64+$in1_y+24],$a3 |
| add %sp,LOCALS64+$S1,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S1, S1, in1_y); |
| add %sp,LOCALS64+$S1,$rp |
| |
| ldx [%sp+LOCALS64+$S2],$bi |
| ldx [%sp+LOCALS64+$in2_y],$a0 |
| ldx [%sp+LOCALS64+$in2_y+8],$a1 |
| ldx [%sp+LOCALS64+$in2_y+16],$a2 |
| ldx [%sp+LOCALS64+$in2_y+24],$a3 |
| add %sp,LOCALS64+$S2,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, S2, in2_y); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$Z2sqr],$bi ! forward load |
| ldx [%sp+LOCALS64+$in1_x],$a0 |
| ldx [%sp+LOCALS64+$in1_x+8],$a1 |
| ldx [%sp+LOCALS64+$in1_x+16],$a2 |
| ldx [%sp+LOCALS64+$in1_x+24],$a3 |
| |
| add %sp,LOCALS64+$S1,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(R, S2, S1); |
| add %sp,LOCALS64+$R,$rp |
| |
| or $acc1,$acc0,$acc0 ! see if result is zero |
| or $acc3,$acc2,$acc2 |
| or $acc2,$acc0,$acc0 |
| stx $acc0,[%fp+STACK_BIAS-24] |
| |
| add %sp,LOCALS64+$Z2sqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(U1, in1_x, Z2sqr); |
| add %sp,LOCALS64+$U1,$rp |
| |
| ldx [%sp+LOCALS64+$Z1sqr],$bi |
| ldx [%sp+LOCALS64+$in2_x],$a0 |
| ldx [%sp+LOCALS64+$in2_x+8],$a1 |
| ldx [%sp+LOCALS64+$in2_x+16],$a2 |
| ldx [%sp+LOCALS64+$in2_x+24],$a3 |
| add %sp,LOCALS64+$Z1sqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(U2, in2_x, Z1sqr); |
| add %sp,LOCALS64+$U2,$rp |
| |
| ldx [%sp+LOCALS64+$R],$a0 ! forward load |
| ldx [%sp+LOCALS64+$R+8],$a1 |
| ldx [%sp+LOCALS64+$R+16],$a2 |
| ldx [%sp+LOCALS64+$R+24],$a3 |
| |
| add %sp,LOCALS64+$U1,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(H, U2, U1); |
| add %sp,LOCALS64+$H,$rp |
| |
| or $acc1,$acc0,$acc0 ! see if result is zero |
| or $acc3,$acc2,$acc2 |
| orcc $acc2,$acc0,$acc0 |
| |
| bne,pt %xcc,.Ladd_proceed_vis3 ! is_equal(U1,U2)? |
| nop |
| |
| ldx [%fp+STACK_BIAS-8],$t0 |
| ldx [%fp+STACK_BIAS-16],$t1 |
| ldx [%fp+STACK_BIAS-24],$t2 |
| andcc $t0,$t1,%g0 |
| be,pt %xcc,.Ladd_proceed_vis3 ! (in1infty || in2infty)? |
| nop |
| andcc $t2,$t2,%g0 |
| be,a,pt %xcc,.Ldouble_shortcut_vis3 ! is_equal(S1,S2)? |
| add %sp,32*(12-10)+32,%sp ! difference in frame sizes |
| |
| st %g0,[$rp_real] |
| st %g0,[$rp_real+4] |
| st %g0,[$rp_real+8] |
| st %g0,[$rp_real+12] |
| st %g0,[$rp_real+16] |
| st %g0,[$rp_real+20] |
| st %g0,[$rp_real+24] |
| st %g0,[$rp_real+28] |
| st %g0,[$rp_real+32] |
| st %g0,[$rp_real+32+4] |
| st %g0,[$rp_real+32+8] |
| st %g0,[$rp_real+32+12] |
| st %g0,[$rp_real+32+16] |
| st %g0,[$rp_real+32+20] |
| st %g0,[$rp_real+32+24] |
| st %g0,[$rp_real+32+28] |
| st %g0,[$rp_real+64] |
| st %g0,[$rp_real+64+4] |
| st %g0,[$rp_real+64+8] |
| st %g0,[$rp_real+64+12] |
| st %g0,[$rp_real+64+16] |
| st %g0,[$rp_real+64+20] |
| st %g0,[$rp_real+64+24] |
| st %g0,[$rp_real+64+28] |
| b .Ladd_done_vis3 |
| nop |
| |
| .align 16 |
| .Ladd_proceed_vis3: |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Rsqr, R); |
| add %sp,LOCALS64+$Rsqr,$rp |
| |
| ldx [%sp+LOCALS64+$H],$bi |
| ldx [%sp+LOCALS64+$in1_z],$a0 |
| ldx [%sp+LOCALS64+$in1_z+8],$a1 |
| ldx [%sp+LOCALS64+$in1_z+16],$a2 |
| ldx [%sp+LOCALS64+$in1_z+24],$a3 |
| add %sp,LOCALS64+$H,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(res_z, H, in1_z); |
| add %sp,LOCALS64+$res_z,$rp |
| |
| ldx [%sp+LOCALS64+$H],$a0 |
| ldx [%sp+LOCALS64+$H+8],$a1 |
| ldx [%sp+LOCALS64+$H+16],$a2 |
| ldx [%sp+LOCALS64+$H+24],$a3 |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Hsqr, H); |
| add %sp,LOCALS64+$Hsqr,$rp |
| |
| ldx [%sp+LOCALS64+$res_z],$bi |
| ldx [%sp+LOCALS64+$in2_z],$a0 |
| ldx [%sp+LOCALS64+$in2_z+8],$a1 |
| ldx [%sp+LOCALS64+$in2_z+16],$a2 |
| ldx [%sp+LOCALS64+$in2_z+24],$a3 |
| add %sp,LOCALS64+$res_z,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(res_z, res_z, in2_z); |
| add %sp,LOCALS64+$res_z,$rp |
| |
| ldx [%sp+LOCALS64+$H],$bi |
| ldx [%sp+LOCALS64+$Hsqr],$a0 |
| ldx [%sp+LOCALS64+$Hsqr+8],$a1 |
| ldx [%sp+LOCALS64+$Hsqr+16],$a2 |
| ldx [%sp+LOCALS64+$Hsqr+24],$a3 |
| add %sp,LOCALS64+$H,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(Hcub, Hsqr, H); |
| add %sp,LOCALS64+$Hcub,$rp |
| |
| ldx [%sp+LOCALS64+$U1],$bi |
| ldx [%sp+LOCALS64+$Hsqr],$a0 |
| ldx [%sp+LOCALS64+$Hsqr+8],$a1 |
| ldx [%sp+LOCALS64+$Hsqr+16],$a2 |
| ldx [%sp+LOCALS64+$Hsqr+24],$a3 |
| add %sp,LOCALS64+$U1,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(U2, U1, Hsqr); |
| add %sp,LOCALS64+$U2,$rp |
| |
| call __ecp_nistz256_mul_by_2_vis3 ! p256_mul_by_2(Hsqr, U2); |
| add %sp,LOCALS64+$Hsqr,$rp |
| |
| add %sp,LOCALS64+$Rsqr,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(res_x, Rsqr, Hsqr); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| add %sp,LOCALS64+$Hcub,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_x, res_x, Hcub); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| ldx [%sp+LOCALS64+$S1],$bi ! forward load |
| ldx [%sp+LOCALS64+$Hcub],$a0 |
| ldx [%sp+LOCALS64+$Hcub+8],$a1 |
| ldx [%sp+LOCALS64+$Hcub+16],$a2 |
| ldx [%sp+LOCALS64+$Hcub+24],$a3 |
| |
| add %sp,LOCALS64+$U2,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(res_y, U2, res_x); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| add %sp,LOCALS64+$S1,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, S1, Hcub); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$R],$bi |
| ldx [%sp+LOCALS64+$res_y],$a0 |
| ldx [%sp+LOCALS64+$res_y+8],$a1 |
| ldx [%sp+LOCALS64+$res_y+16],$a2 |
| ldx [%sp+LOCALS64+$res_y+24],$a3 |
| add %sp,LOCALS64+$R,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(res_y, res_y, R); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| add %sp,LOCALS64+$S2,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_y, res_y, S2); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| ldx [%fp+STACK_BIAS-16],$t1 ! !in1infty |
| ldx [%fp+STACK_BIAS-8],$t2 ! !in2infty |
| ___ |
| for($i=0;$i<96;$i+=16) { # conditional moves |
| $code.=<<___; |
| ldx [%sp+LOCALS64+$res_x+$i],$acc0 ! res |
| ldx [%sp+LOCALS64+$res_x+$i+8],$acc1 |
| ldx [%sp+LOCALS64+$in2_x+$i],$acc2 ! in2 |
| ldx [%sp+LOCALS64+$in2_x+$i+8],$acc3 |
| ldx [%sp+LOCALS64+$in1_x+$i],$acc4 ! in1 |
| ldx [%sp+LOCALS64+$in1_x+$i+8],$acc5 |
| movrz $t1,$acc2,$acc0 |
| movrz $t1,$acc3,$acc1 |
| movrz $t2,$acc4,$acc0 |
| movrz $t2,$acc5,$acc1 |
| srlx $acc0,32,$acc2 |
| srlx $acc1,32,$acc3 |
| st $acc0,[$rp_real+$i] |
| st $acc2,[$rp_real+$i+4] |
| st $acc1,[$rp_real+$i+8] |
| st $acc3,[$rp_real+$i+12] |
| ___ |
| } |
| $code.=<<___; |
| .Ladd_done_vis3: |
| ret |
| restore |
| .type ecp_nistz256_point_add_vis3,#function |
| .size ecp_nistz256_point_add_vis3,.-ecp_nistz256_point_add_vis3 |
| ___ |
| } |
| ######################################################################## |
| # void ecp_nistz256_point_add_affine(P256_POINT *out,const P256_POINT *in1, |
| # const P256_POINT_AFFINE *in2); |
| { |
| my ($res_x,$res_y,$res_z, |
| $in1_x,$in1_y,$in1_z, |
| $in2_x,$in2_y, |
| $U2,$S2,$H,$R,$Hsqr,$Hcub,$Rsqr)=map(32*$_,(0..14)); |
| my $Z1sqr = $S2; |
| # above map() describes stack layout with 15 temporary |
| # 256-bit vectors on top. Then we reserve some space for |
| # !in1infty and !in2infty. |
| |
| $code.=<<___; |
| .align 32 |
| ecp_nistz256_point_add_affine_vis3: |
| save %sp,-STACK64_FRAME-32*15-32,%sp |
| |
| mov $rp,$rp_real |
| mov -1,$minus1 |
| mov -2,$poly3 |
| sllx $minus1,32,$poly1 ! 0xFFFFFFFF00000000 |
| srl $poly3,0,$poly3 ! 0x00000000FFFFFFFE |
| |
| ! convert input to uint64_t[4] |
| ld [$bp],$a0 ! in2_x |
| ld [$bp+4],$t0 |
| ld [$bp+8],$a1 |
| ld [$bp+12],$t1 |
| ld [$bp+16],$a2 |
| ld [$bp+20],$t2 |
| ld [$bp+24],$a3 |
| ld [$bp+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| ld [$bp+32],$acc0 ! in2_y |
| or $a0,$t0,$a0 |
| ld [$bp+32+4],$t0 |
| sllx $t2,32,$t2 |
| ld [$bp+32+8],$acc1 |
| or $a1,$t1,$a1 |
| ld [$bp+32+12],$t1 |
| sllx $t3,32,$t3 |
| ld [$bp+32+16],$acc2 |
| or $a2,$t2,$a2 |
| ld [$bp+32+20],$t2 |
| or $a3,$t3,$a3 |
| ld [$bp+32+24],$acc3 |
| sllx $t0,32,$t0 |
| ld [$bp+32+28],$t3 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in2_x] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in2_x+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in2_x+16] |
| or $acc0,$t0,$acc0 |
| stx $a3,[%sp+LOCALS64+$in2_x+24] |
| or $acc1,$t1,$acc1 |
| stx $acc0,[%sp+LOCALS64+$in2_y] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in2_y+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in2_y+16] |
| stx $acc3,[%sp+LOCALS64+$in2_y+24] |
| |
| or $a1,$a0,$a0 |
| or $a3,$a2,$a2 |
| or $acc1,$acc0,$acc0 |
| or $acc3,$acc2,$acc2 |
| or $a2,$a0,$a0 |
| or $acc2,$acc0,$acc0 |
| or $acc0,$a0,$a0 |
| movrnz $a0,-1,$a0 ! !in2infty |
| stx $a0,[%fp+STACK_BIAS-8] |
| |
| ld [$ap],$a0 ! in1_x |
| ld [$ap+4],$t0 |
| ld [$ap+8],$a1 |
| ld [$ap+12],$t1 |
| ld [$ap+16],$a2 |
| ld [$ap+20],$t2 |
| ld [$ap+24],$a3 |
| ld [$ap+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| ld [$ap+32],$acc0 ! in1_y |
| or $a0,$t0,$a0 |
| ld [$ap+32+4],$t0 |
| sllx $t2,32,$t2 |
| ld [$ap+32+8],$acc1 |
| or $a1,$t1,$a1 |
| ld [$ap+32+12],$t1 |
| sllx $t3,32,$t3 |
| ld [$ap+32+16],$acc2 |
| or $a2,$t2,$a2 |
| ld [$ap+32+20],$t2 |
| or $a3,$t3,$a3 |
| ld [$ap+32+24],$acc3 |
| sllx $t0,32,$t0 |
| ld [$ap+32+28],$t3 |
| sllx $t1,32,$t1 |
| stx $a0,[%sp+LOCALS64+$in1_x] |
| sllx $t2,32,$t2 |
| stx $a1,[%sp+LOCALS64+$in1_x+8] |
| sllx $t3,32,$t3 |
| stx $a2,[%sp+LOCALS64+$in1_x+16] |
| or $acc0,$t0,$acc0 |
| stx $a3,[%sp+LOCALS64+$in1_x+24] |
| or $acc1,$t1,$acc1 |
| stx $acc0,[%sp+LOCALS64+$in1_y] |
| or $acc2,$t2,$acc2 |
| stx $acc1,[%sp+LOCALS64+$in1_y+8] |
| or $acc3,$t3,$acc3 |
| stx $acc2,[%sp+LOCALS64+$in1_y+16] |
| stx $acc3,[%sp+LOCALS64+$in1_y+24] |
| |
| ld [$ap+64],$a0 ! in1_z |
| ld [$ap+64+4],$t0 |
| ld [$ap+64+8],$a1 |
| ld [$ap+64+12],$t1 |
| ld [$ap+64+16],$a2 |
| ld [$ap+64+20],$t2 |
| ld [$ap+64+24],$a3 |
| ld [$ap+64+28],$t3 |
| sllx $t0,32,$t0 |
| sllx $t1,32,$t1 |
| or $a0,$t0,$a0 |
| sllx $t2,32,$t2 |
| or $a1,$t1,$a1 |
| sllx $t3,32,$t3 |
| stx $a0,[%sp+LOCALS64+$in1_z] |
| or $a2,$t2,$a2 |
| stx $a1,[%sp+LOCALS64+$in1_z+8] |
| or $a3,$t3,$a3 |
| stx $a2,[%sp+LOCALS64+$in1_z+16] |
| stx $a3,[%sp+LOCALS64+$in1_z+24] |
| |
| or $a1,$a0,$t0 |
| or $a3,$a2,$t2 |
| or $t2,$t0,$t0 |
| movrnz $t0,-1,$t0 ! !in1infty |
| stx $t0,[%fp+STACK_BIAS-16] |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Z1sqr, in1_z); |
| add %sp,LOCALS64+$Z1sqr,$rp |
| |
| ldx [%sp+LOCALS64+$in2_x],$bi |
| mov $acc0,$a0 |
| mov $acc1,$a1 |
| mov $acc2,$a2 |
| mov $acc3,$a3 |
| add %sp,LOCALS64+$in2_x,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(U2, Z1sqr, in2_x); |
| add %sp,LOCALS64+$U2,$rp |
| |
| ldx [%sp+LOCALS64+$Z1sqr],$bi ! forward load |
| ldx [%sp+LOCALS64+$in1_z],$a0 |
| ldx [%sp+LOCALS64+$in1_z+8],$a1 |
| ldx [%sp+LOCALS64+$in1_z+16],$a2 |
| ldx [%sp+LOCALS64+$in1_z+24],$a3 |
| |
| add %sp,LOCALS64+$in1_x,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(H, U2, in1_x); |
| add %sp,LOCALS64+$H,$rp |
| |
| add %sp,LOCALS64+$Z1sqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, Z1sqr, in1_z); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$H],$bi |
| ldx [%sp+LOCALS64+$in1_z],$a0 |
| ldx [%sp+LOCALS64+$in1_z+8],$a1 |
| ldx [%sp+LOCALS64+$in1_z+16],$a2 |
| ldx [%sp+LOCALS64+$in1_z+24],$a3 |
| add %sp,LOCALS64+$H,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(res_z, H, in1_z); |
| add %sp,LOCALS64+$res_z,$rp |
| |
| ldx [%sp+LOCALS64+$S2],$bi |
| ldx [%sp+LOCALS64+$in2_y],$a0 |
| ldx [%sp+LOCALS64+$in2_y+8],$a1 |
| ldx [%sp+LOCALS64+$in2_y+16],$a2 |
| ldx [%sp+LOCALS64+$in2_y+24],$a3 |
| add %sp,LOCALS64+$S2,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, S2, in2_y); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$H],$a0 ! forward load |
| ldx [%sp+LOCALS64+$H+8],$a1 |
| ldx [%sp+LOCALS64+$H+16],$a2 |
| ldx [%sp+LOCALS64+$H+24],$a3 |
| |
| add %sp,LOCALS64+$in1_y,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(R, S2, in1_y); |
| add %sp,LOCALS64+$R,$rp |
| |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Hsqr, H); |
| add %sp,LOCALS64+$Hsqr,$rp |
| |
| ldx [%sp+LOCALS64+$R],$a0 |
| ldx [%sp+LOCALS64+$R+8],$a1 |
| ldx [%sp+LOCALS64+$R+16],$a2 |
| ldx [%sp+LOCALS64+$R+24],$a3 |
| call __ecp_nistz256_sqr_mont_vis3 ! p256_sqr_mont(Rsqr, R); |
| add %sp,LOCALS64+$Rsqr,$rp |
| |
| ldx [%sp+LOCALS64+$H],$bi |
| ldx [%sp+LOCALS64+$Hsqr],$a0 |
| ldx [%sp+LOCALS64+$Hsqr+8],$a1 |
| ldx [%sp+LOCALS64+$Hsqr+16],$a2 |
| ldx [%sp+LOCALS64+$Hsqr+24],$a3 |
| add %sp,LOCALS64+$H,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(Hcub, Hsqr, H); |
| add %sp,LOCALS64+$Hcub,$rp |
| |
| ldx [%sp+LOCALS64+$Hsqr],$bi |
| ldx [%sp+LOCALS64+$in1_x],$a0 |
| ldx [%sp+LOCALS64+$in1_x+8],$a1 |
| ldx [%sp+LOCALS64+$in1_x+16],$a2 |
| ldx [%sp+LOCALS64+$in1_x+24],$a3 |
| add %sp,LOCALS64+$Hsqr,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(U2, in1_x, Hsqr); |
| add %sp,LOCALS64+$U2,$rp |
| |
| call __ecp_nistz256_mul_by_2_vis3 ! p256_mul_by_2(Hsqr, U2); |
| add %sp,LOCALS64+$Hsqr,$rp |
| |
| add %sp,LOCALS64+$Rsqr,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(res_x, Rsqr, Hsqr); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| add %sp,LOCALS64+$Hcub,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_x, res_x, Hcub); |
| add %sp,LOCALS64+$res_x,$rp |
| |
| ldx [%sp+LOCALS64+$Hcub],$bi ! forward load |
| ldx [%sp+LOCALS64+$in1_y],$a0 |
| ldx [%sp+LOCALS64+$in1_y+8],$a1 |
| ldx [%sp+LOCALS64+$in1_y+16],$a2 |
| ldx [%sp+LOCALS64+$in1_y+24],$a3 |
| |
| add %sp,LOCALS64+$U2,$bp |
| call __ecp_nistz256_sub_morf_vis3 ! p256_sub(res_y, U2, res_x); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| add %sp,LOCALS64+$Hcub,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(S2, in1_y, Hcub); |
| add %sp,LOCALS64+$S2,$rp |
| |
| ldx [%sp+LOCALS64+$R],$bi |
| ldx [%sp+LOCALS64+$res_y],$a0 |
| ldx [%sp+LOCALS64+$res_y+8],$a1 |
| ldx [%sp+LOCALS64+$res_y+16],$a2 |
| ldx [%sp+LOCALS64+$res_y+24],$a3 |
| add %sp,LOCALS64+$R,$bp |
| call __ecp_nistz256_mul_mont_vis3 ! p256_mul_mont(res_y, res_y, R); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| add %sp,LOCALS64+$S2,$bp |
| call __ecp_nistz256_sub_from_vis3 ! p256_sub(res_y, res_y, S2); |
| add %sp,LOCALS64+$res_y,$rp |
| |
| ldx [%fp+STACK_BIAS-16],$t1 ! !in1infty |
| ldx [%fp+STACK_BIAS-8],$t2 ! !in2infty |
| 1: call .+8 |
| add %o7,.Lone_mont_vis3-1b,$bp |
| ___ |
| for($i=0;$i<64;$i+=16) { # conditional moves |
| $code.=<<___; |
| ldx [%sp+LOCALS64+$res_x+$i],$acc0 ! res |
| ldx [%sp+LOCALS64+$res_x+$i+8],$acc1 |
| ldx [%sp+LOCALS64+$in2_x+$i],$acc2 ! in2 |
| ldx [%sp+LOCALS64+$in2_x+$i+8],$acc3 |
| ldx [%sp+LOCALS64+$in1_x+$i],$acc4 ! in1 |
| ldx [%sp+LOCALS64+$in1_x+$i+8],$acc5 |
| movrz $t1,$acc2,$acc0 |
| movrz $t1,$acc3,$acc1 |
| movrz $t2,$acc4,$acc0 |
| movrz $t2,$acc5,$acc1 |
| srlx $acc0,32,$acc2 |
| srlx $acc1,32,$acc3 |
| st $acc0,[$rp_real+$i] |
| st $acc2,[$rp_real+$i+4] |
| st $acc1,[$rp_real+$i+8] |
| st $acc3,[$rp_real+$i+12] |
| ___ |
| } |
| for(;$i<96;$i+=16) { |
| $code.=<<___; |
| ldx [%sp+LOCALS64+$res_x+$i],$acc0 ! res |
| ldx [%sp+LOCALS64+$res_x+$i+8],$acc1 |
| ldx [$bp+$i-64],$acc2 ! "in2" |
| ldx [$bp+$i-64+8],$acc3 |
| ldx [%sp+LOCALS64+$in1_x+$i],$acc4 ! in1 |
| ldx [%sp+LOCALS64+$in1_x+$i+8],$acc5 |
| movrz $t1,$acc2,$acc0 |
| movrz $t1,$acc3,$acc1 |
| movrz $t2,$acc4,$acc0 |
| movrz $t2,$acc5,$acc1 |
| srlx $acc0,32,$acc2 |
| srlx $acc1,32,$acc3 |
| st $acc0,[$rp_real+$i] |
| st $acc2,[$rp_real+$i+4] |
| st $acc1,[$rp_real+$i+8] |
| st $acc3,[$rp_real+$i+12] |
| ___ |
| } |
| $code.=<<___; |
| ret |
| restore |
| .type ecp_nistz256_point_add_affine_vis3,#function |
| .size ecp_nistz256_point_add_affine_vis3,.-ecp_nistz256_point_add_affine_vis3 |
| .align 64 |
| .Lone_mont_vis3: |
| .long 0x00000000,0x00000001, 0xffffffff,0x00000000 |
| .long 0xffffffff,0xffffffff, 0x00000000,0xfffffffe |
| .align 64 |
| ___ |
| } }}} |
| |
| # Purpose of these subroutines is to explicitly encode VIS instructions, |
| # so that one can compile the module without having to specify VIS |
| # extensions on compiler command line, e.g. -xarch=v9 vs. -xarch=v9a. |
| # Idea is to reserve for option to produce "universal" binary and let |
| # programmer detect if current CPU is VIS capable at run-time. |
| sub unvis3 { |
| my ($mnemonic,$rs1,$rs2,$rd)=@_; |
| my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24 ); |
| my ($ref,$opf); |
| my %visopf = ( "addxc" => 0x011, |
| "addxccc" => 0x013, |
| "umulxhi" => 0x016 ); |
| |
| $ref = "$mnemonic\t$rs1,$rs2,$rd"; |
| |
| if ($opf=$visopf{$mnemonic}) { |
| foreach ($rs1,$rs2,$rd) { |
| return $ref if (!/%([goli])([0-9])/); |
| $_=$bias{$1}+$2; |
| } |
| |
| return sprintf ".word\t0x%08x !%s", |
| 0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2, |
| $ref; |
| } else { |
| return $ref; |
| } |
| } |
| |
| foreach (split("\n",$code)) { |
| s/\`([^\`]*)\`/eval $1/ge; |
| |
| s/\b(umulxhi|addxc[c]{0,2})\s+(%[goli][0-7]),\s*(%[goli][0-7]),\s*(%[goli][0-7])/ |
| &unvis3($1,$2,$3,$4) |
| /ge; |
| |
| print $_,"\n"; |
| } |
| |
| close STDOUT or die "error closing STDOUT: $!"; |