#!/usr/bin/env perl # ==================================================================== # Written by David S. Miller and Andy Polyakov # . The module is licensed under 2-clause BSD # license. October 2012. All rights reserved. # ==================================================================== ###################################################################### # AES round instructions complete in 3 cycles and can be issued every # cycle. It means that round calculations should take 4*rounds cycles, # because any given round instruction depends on result of *both* # previous instructions: # # |0 |1 |2 |3 |4 # |01|01|01| # |23|23|23| # |01|01|... # |23|... # # Provided that fxor [with IV] takes 3 cycles to complete, critical # path length for CBC encrypt would be 3+4*rounds, or in other words # it should process one byte in at least (3+4*rounds)/16 cycles. This # estimate doesn't account for "collateral" instructions, such as # fetching input from memory, xor-ing it with zero-round key and # storing the result. Yet, *measured* performance [for data aligned # at 64-bit boundary!] deviates from this equation by less than 0.5%: # # 128-bit key 192- 256- # CBC encrypt 2.70/2.90(*) 3.20/3.40 3.70/3.90 # (*) numbers after slash are for # misaligned data. # # Out-of-order execution logic managed to fully overlap "collateral" # instructions with those on critical path. Amazing! # # As with Intel AES-NI, question is if it's possible to improve # performance of parallelizeable modes by interleaving round # instructions. Provided round instruction latency and throughput # optimal interleave factor is 2. But can we expect 2x performance # improvement? Well, as round instructions can be issued one per # cycle, they don't saturate the 2-way issue pipeline and therefore # there is room for "collateral" calculations... Yet, 2x speed-up # over CBC encrypt remains unattaintable: # # 128-bit key 192- 256- # CBC decrypt 1.64/2.11 1.89/2.37 2.23/2.61 # CTR 1.64/2.08(*) 1.89/2.33 2.23/2.61 # (*) numbers after slash are for # misaligned data. # # Estimates based on amount of instructions under assumption that # round instructions are not pairable with any other instruction # suggest that latter is the actual case and pipeline runs # underutilized. It should be noted that T4 out-of-order execution # logic is so capable that performance gain from 2x interleave is # not even impressive, ~7-13% over non-interleaved code, largest # for 256-bit keys. # To anchor to something else, software implementation processes # one byte in 29 cycles with 128-bit key on same processor. Intel # Sandy Bridge encrypts byte in 5.07 cycles in CBC mode and decrypts # in 0.93, naturally with AES-NI. $bits=32; for (@ARGV) { $bits=64 if (/\-m64/ || /\-xarch\=v9/); } if ($bits==64) { $bias=2047; $frame=192; } else { $bias=0; $frame=112; } $evp=1; # if $evp is set to 0, script generates module with # AES_[en|de]crypt, AES_set_[en|de]crypt_key and AES_cbc_encrypt entry # points. These however are not fully compatible with openssl/aes.h, # because they expect AES_KEY to be aligned at 64-bit boundary. When # used through EVP, alignment is arranged at EVP layer. Second thing # that is arranged by EVP is at least 32-bit alignment of IV. ###################################################################### # single-round subroutines # { my ($inp,$out,$key,$rounds,$tmp,$mask)=map("%o$_",(0..5)); $code=<<___; .text .globl aes_t4_encrypt .align 32 aes_t4_encrypt: andcc $inp, 7, %g1 ! is input aligned? andn $inp, 7, $inp ldx [$key + 0], %g4 ldx [$key + 8], %g5 ldx [$inp + 0], %o4 bz,pt %icc, 1f ldx [$inp + 8], %o5 ldx [$inp + 16], $inp sll %g1, 3, %g1 sub %g0, %g1, %o3 sllx %o4, %g1, %o4 sllx %o5, %g1, %g1 srlx %o5, %o3, %o5 srlx $inp, %o3, %o3 or %o5, %o4, %o4 or %o3, %g1, %o5 1: ld [$key + 240], $rounds ldd [$key + 16], %f12 ldd [$key + 24], %f14 xor %g4, %o4, %o4 xor %g5, %o5, %o5 movxtod %o4, %f0 movxtod %o5, %f2 srl $rounds, 1, $rounds ldd [$key + 32], %f16 sub $rounds, 1, $rounds ldd [$key + 40], %f18 add $key, 48, $key .Lenc: aes_eround01 %f12, %f0, %f2, %f4 aes_eround23 %f14, %f0, %f2, %f2 ldd [$key + 0], %f12 ldd [$key + 8], %f14 sub $rounds,1,$rounds aes_eround01 %f16, %f4, %f2, %f0 aes_eround23 %f18, %f4, %f2, %f2 ldd [$key + 16], %f16 ldd [$key + 24], %f18 brnz,pt $rounds, .Lenc add $key, 32, $key andcc $out, 7, $tmp ! is output aligned? aes_eround01 %f12, %f0, %f2, %f4 aes_eround23 %f14, %f0, %f2, %f2 aes_eround01_l %f16, %f4, %f2, %f0 aes_eround23_l %f18, %f4, %f2, %f2 bnz,pn %icc, 2f nop std %f0, [$out + 0] retl std %f2, [$out + 8] 2: alignaddrl $out, %g0, $out mov 0xff, $mask srl $mask, $tmp, $mask faligndata %f0, %f0, %f4 faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$out + $mask]0xc0 ! partial store std %f6, [$out + 8] add $out, 16, $out orn %g0, $mask, $mask retl stda %f8, [$out + $mask]0xc0 ! partial store .type aes_t4_encrypt,#function .size aes_t4_encrypt,.-aes_t4_encrypt .globl aes_t4_decrypt .align 32 aes_t4_decrypt: andcc $inp, 7, %g1 ! is input aligned? andn $inp, 7, $inp ldx [$key + 0], %g4 ldx [$key + 8], %g5 ldx [$inp + 0], %o4 bz,pt %icc, 1f ldx [$inp + 8], %o5 ldx [$inp + 16], $inp sll %g1, 3, %g1 sub %g0, %g1, %o3 sllx %o4, %g1, %o4 sllx %o5, %g1, %g1 srlx %o5, %o3, %o5 srlx $inp, %o3, %o3 or %o5, %o4, %o4 or %o3, %g1, %o5 1: ld [$key + 240], $rounds ldd [$key + 16], %f12 ldd [$key + 24], %f14 xor %g4, %o4, %o4 xor %g5, %o5, %o5 movxtod %o4, %f0 movxtod %o5, %f2 srl $rounds, 1, $rounds ldd [$key + 32], %f16 sub $rounds, 1, $rounds ldd [$key + 40], %f18 add $key, 48, $key .Ldec: aes_dround01 %f12, %f0, %f2, %f4 aes_dround23 %f14, %f0, %f2, %f2 ldd [$key + 0], %f12 ldd [$key + 8], %f14 sub $rounds,1,$rounds aes_dround01 %f16, %f4, %f2, %f0 aes_dround23 %f18, %f4, %f2, %f2 ldd [$key + 16], %f16 ldd [$key + 24], %f18 brnz,pt $rounds, .Ldec add $key, 32, $key andcc $out, 7, $tmp ! is output aligned? aes_dround01 %f12, %f0, %f2, %f4 aes_dround23 %f14, %f0, %f2, %f2 aes_dround01_l %f16, %f4, %f2, %f0 aes_dround23_l %f18, %f4, %f2, %f2 bnz,pn %icc, 2f nop std %f0, [$out + 0] retl std %f2, [$out + 8] 2: alignaddrl $out, %g0, $out mov 0xff, $mask srl $mask, $tmp, $mask faligndata %f0, %f0, %f4 faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$out + $mask]0xc0 ! partial store std %f6, [$out + 8] add $out, 16, $out orn %g0, $mask, $mask retl stda %f8, [$out + $mask]0xc0 ! partial store .type aes_t4_decrypt,#function .size aes_t4_decrypt,.-aes_t4_decrypt ___ } ###################################################################### # key setup subroutines # { my ($inp,$bits,$out,$tmp)=map("%o$_",(0..5)); $code.=<<___; .globl aes_t4_set_encrypt_key .align 32 aes_t4_set_encrypt_key: .Lset_encrypt_key: and $inp, 7, $tmp alignaddr $inp, %g0, $inp cmp $bits, 192 ldd [$inp + 0], %f0 bl,pt %icc,.L128 ldd [$inp + 8], %f2 be,pt %icc,.L192 ldd [$inp + 16], %f4 brz,pt $tmp, .L256aligned ldd [$inp + 24], %f6 ldd [$inp + 32], %f8 faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 faligndata %f4, %f6, %f4 faligndata %f6, %f8, %f6 .L256aligned: ___ for ($i=0; $i<6; $i++) { $code.=<<___; std %f0, [$out + `32*$i+0`] aes_kexpand1 %f0, %f6, $i, %f0 std %f2, [$out + `32*$i+8`] aes_kexpand2 %f2, %f0, %f2 std %f4, [$out + `32*$i+16`] aes_kexpand0 %f4, %f2, %f4 std %f6, [$out + `32*$i+24`] aes_kexpand2 %f6, %f4, %f6 ___ } $code.=<<___; std %f0, [$out + `32*$i+0`] aes_kexpand1 %f0, %f6, $i, %f0 std %f2, [$out + `32*$i+8`] aes_kexpand2 %f2, %f0, %f2 std %f4, [$out + `32*$i+16`] std %f6, [$out + `32*$i+24`] std %f0, [$out + `32*$i+32`] std %f2, [$out + `32*$i+40`] mov 14, $tmp st $tmp, [$out + 240] retl xor %o0, %o0, %o0 .align 16 .L192: brz,pt $tmp, .L192aligned nop ldd [$inp + 24], %f6 faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 faligndata %f4, %f6, %f4 .L192aligned: ___ for ($i=0; $i<7; $i++) { $code.=<<___; std %f0, [$out + `24*$i+0`] aes_kexpand1 %f0, %f4, $i, %f0 std %f2, [$out + `24*$i+8`] aes_kexpand2 %f2, %f0, %f2 std %f4, [$out + `24*$i+16`] aes_kexpand2 %f4, %f2, %f4 ___ } $code.=<<___; std %f0, [$out + `24*$i+0`] aes_kexpand1 %f0, %f4, $i, %f0 std %f2, [$out + `24*$i+8`] aes_kexpand2 %f2, %f0, %f2 std %f4, [$out + `24*$i+16`] std %f0, [$out + `24*$i+24`] std %f2, [$out + `24*$i+32`] mov 12, $tmp st $tmp, [$out + 240] retl xor %o0, %o0, %o0 .align 16 .L128: brz,pt $tmp, .L128aligned nop ldd [$inp + 16], %f4 faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 .L128aligned: ___ for ($i=0; $i<10; $i++) { $code.=<<___; std %f0, [$out + `16*$i+0`] aes_kexpand1 %f0, %f2, $i, %f0 std %f2, [$out + `16*$i+8`] aes_kexpand2 %f2, %f0, %f2 ___ } $code.=<<___; std %f0, [$out + `16*$i+0`] std %f2, [$out + `16*$i+8`] mov 10, $tmp st $tmp, [$out + 240] retl xor %o0, %o0, %o0 .type aes_t4_set_encrypt_key,#function .size aes_t4_set_encrypt_key,.-aes_t4_set_encrypt_key .globl aes_t4_set_decrypt_key .align 32 aes_t4_set_decrypt_key: mov %o7, %o5 call .Lset_encrypt_key nop mov %o5, %o7 sll $tmp, 4, $inp ! $tmp is number of rounds add $tmp, 2, $tmp add $out, $inp, $inp ! $inp=$out+16*rounds srl $tmp, 2, $tmp ! $tmp=(rounds+2)/4 .Lkey_flip: ldd [$out + 0], %f0 ldd [$out + 8], %f2 ldd [$out + 16], %f4 ldd [$out + 24], %f6 ldd [$inp + 0], %f8 ldd [$inp + 8], %f10 ldd [$inp - 16], %f12 ldd [$inp - 8], %f14 sub $tmp, 1, $tmp std %f0, [$inp + 0] std %f2, [$inp + 8] std %f4, [$inp - 16] std %f6, [$inp - 8] std %f8, [$out + 0] std %f10, [$out + 8] std %f12, [$out + 16] std %f14, [$out + 24] add $out, 32, $out brnz $tmp, .Lkey_flip sub $inp, 32, $inp retl xor %o0, %o0, %o0 .type aes_t4_set_decrypt_key,#function .size aes_t4_set_decrypt_key,.-aes_t4_set_decrypt_key ___ } {{{ my ($inp,$out,$len,$key,$ivec,$enc)=map("%i$_",(0..5)); my ($ileft,$iright,$ooff,$omask,$ivoff)=map("%l$_",(1..7)); $code.=<<___; .align 32 _aes128_loadkey: ldx [$key + 0], %g4 ldx [$key + 8], %g5 ___ for ($i=2; $i<22;$i++) { # load key schedule $code.=<<___; ldd [$key + `8*$i`], %f`12+2*$i` ___ } $code.=<<___; retl nop .type _aes128_loadkey,#function .size _aes128_loadkey,.-_aes128_loadkey .align 32 _aes128_encrypt_1x: ___ for ($i=0; $i<4; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_eround01 %f48, %f0, %f2, %f4 aes_eround23 %f50, %f0, %f2, %f2 aes_eround01_l %f52, %f4, %f2, %f0 retl aes_eround23_l %f54, %f4, %f2, %f2 .type _aes128_encrypt_1x,#function .size _aes128_encrypt_1x,.-_aes128_encrypt_1x .align 32 _aes128_encrypt_2x: ___ for ($i=0; $i<4; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_eround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_eround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_eround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_eround01 %f48, %f0, %f2, %f8 aes_eround23 %f50, %f0, %f2, %f2 aes_eround01 %f48, %f4, %f6, %f10 aes_eround23 %f50, %f4, %f6, %f6 aes_eround01_l %f52, %f8, %f2, %f0 aes_eround23_l %f54, %f8, %f2, %f2 aes_eround01_l %f52, %f10, %f6, %f4 retl aes_eround23_l %f54, %f10, %f6, %f6 .type _aes128_encrypt_2x,#function .size _aes128_encrypt_2x,.-_aes128_encrypt_2x .align 32 _aes128_decrypt_1x: ___ for ($i=0; $i<4; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_dround01 %f48, %f0, %f2, %f4 aes_dround23 %f50, %f0, %f2, %f2 aes_dround01_l %f52, %f4, %f2, %f0 retl aes_dround23_l %f54, %f4, %f2, %f2 .type _aes128_decrypt_1x,#function .size _aes128_decrypt_1x,.-_aes128_decrypt_1x .align 32 _aes128_decrypt_2x: ___ for ($i=0; $i<4; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_dround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_dround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_dround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_dround01 %f48, %f0, %f2, %f8 aes_dround23 %f50, %f0, %f2, %f2 aes_dround01 %f48, %f4, %f6, %f10 aes_dround23 %f50, %f4, %f6, %f6 aes_dround01_l %f52, %f8, %f2, %f0 aes_dround23_l %f54, %f8, %f2, %f2 aes_dround01_l %f52, %f10, %f6, %f4 retl aes_dround23_l %f54, %f10, %f6, %f6 .type _aes128_decrypt_2x,#function .size _aes128_decrypt_2x,.-_aes128_decrypt_2x .align 32 _aes192_loadkey: _aes256_loadkey: ldx [$key + 0], %g4 ldx [$key + 8], %g5 ___ for ($i=2; $i<26;$i++) { # load key schedule $code.=<<___; ldd [$key + `8*$i`], %f`12+2*$i` ___ } $code.=<<___; retl nop .type _aes192_loadkey,#function .size _aes192_loadkey,.-_aes192_loadkey .align 32 _aes192_encrypt_1x: ___ for ($i=0; $i<5; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_eround01 %f56, %f0, %f2, %f4 aes_eround23 %f58, %f0, %f2, %f2 aes_eround01_l %f60, %f4, %f2, %f0 retl aes_eround23_l %f62, %f4, %f2, %f2 .type _aes192_encrypt_1x,#function .size _aes192_encrypt_1x,.-_aes192_encrypt_1x .align 32 _aes192_encrypt_2x: ___ for ($i=0; $i<5; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_eround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_eround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_eround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_eround01 %f56, %f0, %f2, %f8 aes_eround23 %f58, %f0, %f2, %f2 aes_eround01 %f56, %f4, %f6, %f10 aes_eround23 %f58, %f4, %f6, %f6 aes_eround01_l %f60, %f8, %f2, %f0 aes_eround23_l %f62, %f8, %f2, %f2 aes_eround01_l %f60, %f10, %f6, %f4 retl aes_eround23_l %f62, %f10, %f6, %f6 .type _aes192_encrypt_2x,#function .size _aes192_encrypt_2x,.-_aes192_encrypt_2x .align 32 _aes192_decrypt_1x: ___ for ($i=0; $i<5; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_dround01 %f56, %f0, %f2, %f4 aes_dround23 %f58, %f0, %f2, %f2 aes_dround01_l %f60, %f4, %f2, %f0 retl aes_dround23_l %f62, %f4, %f2, %f2 .type _aes192_decrypt_1x,#function .size _aes192_decrypt_1x,.-_aes192_decrypt_1x .align 32 _aes192_decrypt_2x: ___ for ($i=0; $i<5; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_dround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_dround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_dround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_dround01 %f56, %f0, %f2, %f8 aes_dround23 %f58, %f0, %f2, %f2 aes_dround01 %f56, %f4, %f6, %f10 aes_dround23 %f58, %f4, %f6, %f6 aes_dround01_l %f60, %f8, %f2, %f0 aes_dround23_l %f62, %f8, %f2, %f2 aes_dround01_l %f60, %f10, %f6, %f4 retl aes_dround23_l %f62, %f10, %f6, %f6 .type _aes192_decrypt_2x,#function .size _aes192_decrypt_2x,.-_aes192_decrypt_2x .align 32 _aes256_encrypt_1x: aes_eround01 %f16, %f0, %f2, %f4 aes_eround23 %f18, %f0, %f2, %f2 ldd [$key + 208], %f16 ldd [$key + 216], %f18 aes_eround01 %f20, %f4, %f2, %f0 aes_eround23 %f22, %f4, %f2, %f2 ldd [$key + 224], %f20 ldd [$key + 232], %f22 ___ for ($i=1; $i<6; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_eround01 %f16, %f0, %f2, %f4 aes_eround23 %f18, %f0, %f2, %f2 ldd [$key + 16], %f16 ldd [$key + 24], %f18 aes_eround01_l %f20, %f4, %f2, %f0 aes_eround23_l %f22, %f4, %f2, %f2 ldd [$key + 32], %f20 retl ldd [$key + 40], %f22 .type _aes256_encrypt_1x,#function .size _aes256_encrypt_1x,.-_aes256_encrypt_1x .align 32 _aes256_encrypt_2x: aes_eround01 %f16, %f0, %f2, %f8 aes_eround23 %f18, %f0, %f2, %f2 aes_eround01 %f16, %f4, %f6, %f10 aes_eround23 %f18, %f4, %f6, %f6 ldd [$key + 208], %f16 ldd [$key + 216], %f18 aes_eround01 %f20, %f8, %f2, %f0 aes_eround23 %f22, %f8, %f2, %f2 aes_eround01 %f20, %f10, %f6, %f4 aes_eround23 %f22, %f10, %f6, %f6 ldd [$key + 224], %f20 ldd [$key + 232], %f22 ___ for ($i=1; $i<6; $i++) { $code.=<<___; aes_eround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_eround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_eround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_eround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_eround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_eround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_eround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_eround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_eround01 %f16, %f0, %f2, %f8 aes_eround23 %f18, %f0, %f2, %f2 aes_eround01 %f16, %f4, %f6, %f10 aes_eround23 %f18, %f4, %f6, %f6 ldd [$key + 16], %f16 ldd [$key + 24], %f18 aes_eround01_l %f20, %f8, %f2, %f0 aes_eround23_l %f22, %f8, %f2, %f2 aes_eround01_l %f20, %f10, %f6, %f4 aes_eround23_l %f22, %f10, %f6, %f6 ldd [$key + 32], %f20 retl ldd [$key + 40], %f22 .type _aes256_encrypt_2x,#function .size _aes256_encrypt_2x,.-_aes256_encrypt_2x .align 32 _aes256_decrypt_1x: aes_dround01 %f16, %f0, %f2, %f4 aes_dround23 %f18, %f0, %f2, %f2 ldd [$key + 208], %f16 ldd [$key + 216], %f18 aes_dround01 %f20, %f4, %f2, %f0 aes_dround23 %f22, %f4, %f2, %f2 ldd [$key + 224], %f20 ldd [$key + 232], %f22 ___ for ($i=1; $i<6; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f4 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f4, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f4, %f2, %f2 ___ } $code.=<<___; aes_dround01 %f16, %f0, %f2, %f4 aes_dround23 %f18, %f0, %f2, %f2 ldd [$key + 16], %f16 ldd [$key + 24], %f18 aes_dround01_l %f20, %f4, %f2, %f0 aes_dround23_l %f22, %f4, %f2, %f2 ldd [$key + 32], %f20 retl ldd [$key + 40], %f22 .type _aes256_decrypt_1x,#function .size _aes256_decrypt_1x,.-_aes256_decrypt_1x .align 32 _aes256_decrypt_2x: aes_dround01 %f16, %f0, %f2, %f8 aes_dround23 %f18, %f0, %f2, %f2 aes_dround01 %f16, %f4, %f6, %f10 aes_dround23 %f18, %f4, %f6, %f6 ldd [$key + 208], %f16 ldd [$key + 216], %f18 aes_dround01 %f20, %f8, %f2, %f0 aes_dround23 %f22, %f8, %f2, %f2 aes_dround01 %f20, %f10, %f6, %f4 aes_dround23 %f22, %f10, %f6, %f6 ldd [$key + 224], %f20 ldd [$key + 232], %f22 ___ for ($i=1; $i<6; $i++) { $code.=<<___; aes_dround01 %f`16+8*$i+0`, %f0, %f2, %f8 aes_dround23 %f`16+8*$i+2`, %f0, %f2, %f2 aes_dround01 %f`16+8*$i+0`, %f4, %f6, %f10 aes_dround23 %f`16+8*$i+2`, %f4, %f6, %f6 aes_dround01 %f`16+8*$i+4`, %f8, %f2, %f0 aes_dround23 %f`16+8*$i+6`, %f8, %f2, %f2 aes_dround01 %f`16+8*$i+4`, %f10, %f6, %f4 aes_dround23 %f`16+8*$i+6`, %f10, %f6, %f6 ___ } $code.=<<___; aes_dround01 %f16, %f0, %f2, %f8 aes_dround23 %f18, %f0, %f2, %f2 aes_dround01 %f16, %f4, %f6, %f10 aes_dround23 %f18, %f4, %f6, %f6 ldd [$key + 16], %f16 ldd [$key + 24], %f18 aes_dround01_l %f20, %f8, %f2, %f0 aes_dround23_l %f22, %f8, %f2, %f2 aes_dround01_l %f20, %f10, %f6, %f4 aes_dround23_l %f22, %f10, %f6, %f6 ldd [$key + 32], %f20 retl ldd [$key + 40], %f22 .type _aes256_decrypt_2x,#function .size _aes256_decrypt_2x,.-_aes256_decrypt_2x ___ sub aes_cbc_encrypt_implement { my $bits = shift; $code.=<<___; .globl aes${bits}_t4_cbc_encrypt .align 32 aes${bits}_t4_cbc_encrypt: save %sp, -$frame, %sp ___ $code.=<<___ if (!$evp); andcc $ivec, 7, $ivoff alignaddr $ivec, %g0, $ivec ldd [$ivec + 0], %f0 ! load ivec bz,pt %icc, 1f ldd [$ivec + 8], %f2 ldd [$ivec + 16], %f4 faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 1: ___ $code.=<<___ if ($evp); ld [$ivec + 0], %f0 ld [$ivec + 4], %f1 ld [$ivec + 8], %f2 ld [$ivec + 12], %f3 ___ $code.=<<___; call _aes${bits}_loadkey srlx $len, 4, $len and $inp, 7, $ileft andn $inp, 7, $inp sll $ileft, 3, $ileft mov 64, $iright mov 0xff, $omask sub $iright, $ileft, $iright and $out, 7, $ooff alignaddrl $out, %g0, $out srl $omask, $ooff, $omask .L${bits}_cbc_enc_loop: ldx [$inp + 0], %o0 brz,pt $ileft, 4f ldx [$inp + 8], %o1 ldx [$inp + 16], %o2 sllx %o0, $ileft, %o0 srlx %o1, $iright, %g1 sllx %o1, $ileft, %o1 or %g1, %o0, %o0 srlx %o2, $iright, %o2 or %o2, %o1, %o1 4: xor %g4, %o0, %o0 ! ^= rk[0] xor %g5, %o1, %o1 movxtod %o0, %f12 movxtod %o1, %f14 fxor %f12, %f0, %f0 ! ^= ivec fxor %f14, %f2, %f2 call _aes${bits}_encrypt_1x add $inp, 16, $inp brnz,pn $ooff, 2f sub $len, 1, $len std %f0, [$out + 0] std %f2, [$out + 8] brnz,pt $len, .L${bits}_cbc_enc_loop add $out, 16, $out ___ $code.=<<___ if ($evp); st %f0, [$ivec + 0] st %f1, [$ivec + 4] st %f2, [$ivec + 8] st %f3, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, 3f nop std %f0, [$ivec + 0] ! write out ivec std %f2, [$ivec + 8] ___ $code.=<<___; ret restore .align 16 2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard ! and ~3x deterioration ! in inp==out case faligndata %f0, %f0, %f4 ! handle unaligned output faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$out + $omask]0xc0 ! partial store std %f6, [$out + 8] add $out, 16, $out orn %g0, $omask, $omask stda %f8, [$out + $omask]0xc0 ! partial store brnz,pt $len, .L${bits}_cbc_enc_loop+4 orn %g0, $omask, $omask ___ $code.=<<___ if ($evp); st %f0, [$ivec + 0] st %f1, [$ivec + 4] st %f2, [$ivec + 8] st %f3, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, 3f nop std %f0, [$ivec + 0] ! write out ivec std %f2, [$ivec + 8] ret restore .align 16 3: alignaddrl $ivec, $ivoff, %g0 ! handle unaligned ivec mov 0xff, $omask srl $omask, $ivoff, $omask faligndata %f0, %f0, %f4 faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$ivec + $omask]0xc0 std %f6, [$ivec + 8] add $ivec, 16, $ivec orn %g0, $omask, $omask stda %f8, [$ivec + $omask]0xc0 ___ $code.=<<___; ret restore .type aes${bits}_t4_cbc_encrypt,#function .size aes${bits}_t4_cbc_encrypt,.-aes${bits}_t4_cbc_encrypt ___ } &aes_cbc_encrypt_implement(128); &aes_cbc_encrypt_implement(192); &aes_cbc_encrypt_implement(256); sub aes_cbc_decrypt_implement { my $bits = shift; $code.=<<___; .globl aes${bits}_t4_cbc_decrypt .align 32 aes${bits}_t4_cbc_decrypt: save %sp, -$frame, %sp ___ $code.=<<___ if (!$evp); andcc $ivec, 7, $ivoff alignaddr $ivec, %g0, $ivec ldd [$ivec + 0], %f12 ! load ivec bz,pt %icc, 1f ldd [$ivec + 8], %f14 ldd [$ivec + 16], %f0 faligndata %f12, %f14, %f12 faligndata %f14, %f0, %f14 1: ___ $code.=<<___ if ($evp); ld [$ivec + 0], %f12 ! load ivec ld [$ivec + 4], %f13 ld [$ivec + 8], %f14 ld [$ivec + 12], %f15 ___ $code.=<<___; call _aes${bits}_loadkey srlx $len, 4, $len andcc $len, 1, %g0 ! is number of blocks even? and $inp, 7, $ileft andn $inp, 7, $inp sll $ileft, 3, $ileft mov 64, $iright mov 0xff, $omask sub $iright, $ileft, $iright and $out, 7, $ooff alignaddrl $out, %g0, $out bz %icc, .L${bits}_cbc_dec_loop2x srl $omask, $ooff, $omask .L${bits}_cbc_dec_loop: ldx [$inp + 0], %o0 brz,pt $ileft, 4f ldx [$inp + 8], %o1 ldx [$inp + 16], %o2 sllx %o0, $ileft, %o0 srlx %o1, $iright, %g1 sllx %o1, $ileft, %o1 or %g1, %o0, %o0 srlx %o2, $iright, %o2 or %o2, %o1, %o1 4: xor %g4, %o0, %o2 ! ^= rk[0] xor %g5, %o1, %o3 movxtod %o2, %f0 movxtod %o3, %f2 call _aes${bits}_decrypt_1x add $inp, 16, $inp fxor %f12, %f0, %f0 ! ^= ivec fxor %f14, %f2, %f2 movxtod %o0, %f12 movxtod %o1, %f14 brnz,pn $ooff, 2f sub $len, 1, $len std %f0, [$out + 0] std %f2, [$out + 8] brnz,pt $len, .L${bits}_cbc_dec_loop2x add $out, 16, $out ___ $code.=<<___ if ($evp); st %f12, [$ivec + 0] st %f13, [$ivec + 4] st %f14, [$ivec + 8] st %f15, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec nop std %f12, [$ivec + 0] ! write out ivec std %f14, [$ivec + 8] ___ $code.=<<___; ret restore .align 16 2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard ! and ~3x deterioration ! in inp==out case faligndata %f0, %f0, %f4 ! handle unaligned output faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$out + $omask]0xc0 ! partial store std %f6, [$out + 8] add $out, 16, $out orn %g0, $omask, $omask stda %f8, [$out + $omask]0xc0 ! partial store brnz,pt $len, .L${bits}_cbc_dec_loop2x+4 orn %g0, $omask, $omask ___ $code.=<<___ if ($evp); st %f12, [$ivec + 0] st %f13, [$ivec + 4] st %f14, [$ivec + 8] st %f15, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec nop std %f12, [$ivec + 0] ! write out ivec std %f14, [$ivec + 8] ___ $code.=<<___; ret restore !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! .align 32 .L${bits}_cbc_dec_loop2x: ldx [$inp + 0], %o0 ldx [$inp + 8], %o1 ldx [$inp + 16], %o2 brz,pt $ileft, 4f ldx [$inp + 24], %o3 ldx [$inp + 32], %o4 sllx %o0, $ileft, %o0 srlx %o1, $iright, %g1 or %g1, %o0, %o0 sllx %o1, $ileft, %o1 srlx %o2, $iright, %g1 or %g1, %o1, %o1 sllx %o2, $ileft, %o2 srlx %o3, $iright, %g1 or %g1, %o2, %o2 sllx %o3, $ileft, %o3 srlx %o4, $iright, %o4 or %o4, %o3, %o3 4: xor %g4, %o0, %o4 ! ^= rk[0] xor %g5, %o1, %o5 movxtod %o4, %f0 movxtod %o5, %f2 xor %g4, %o2, %o4 xor %g5, %o3, %o5 movxtod %o4, %f4 movxtod %o5, %f6 call _aes${bits}_decrypt_2x add $inp, 32, $inp movxtod %o0, %f8 movxtod %o1, %f10 fxor %f12, %f0, %f0 ! ^= ivec fxor %f14, %f2, %f2 movxtod %o2, %f12 movxtod %o3, %f14 fxor %f8, %f4, %f4 fxor %f10, %f6, %f6 brnz,pn $ooff, 2f sub $len, 2, $len std %f0, [$out + 0] std %f2, [$out + 8] std %f4, [$out + 16] std %f6, [$out + 24] brnz,pt $len, .L${bits}_cbc_dec_loop2x add $out, 32, $out ___ $code.=<<___ if ($evp); st %f12, [$ivec + 0] st %f13, [$ivec + 4] st %f14, [$ivec + 8] st %f15, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec nop std %f12, [$ivec + 0] ! write out ivec std %f14, [$ivec + 8] ___ $code.=<<___; ret restore .align 16 2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard ! and ~3x deterioration ! in inp==out case faligndata %f0, %f0, %f8 ! handle unaligned output faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 faligndata %f4, %f6, %f4 faligndata %f6, %f6, %f6 stda %f8, [$out + $omask]0xc0 ! partial store std %f0, [$out + 8] std %f2, [$out + 16] std %f4, [$out + 24] add $out, 32, $out orn %g0, $omask, $omask stda %f6, [$out + $omask]0xc0 ! partial store brnz,pt $len, .L${bits}_cbc_dec_loop2x+4 orn %g0, $omask, $omask ___ $code.=<<___ if ($evp); st %f12, [$ivec + 0] st %f13, [$ivec + 4] st %f14, [$ivec + 8] st %f15, [$ivec + 12] ___ $code.=<<___ if (!$evp); brnz,pn $ivoff, .L${bits}_cbc_dec_unaligned_ivec nop std %f12, [$ivec + 0] ! write out ivec std %f14, [$ivec + 8] ret restore .align 16 .L${bits}_cbc_dec_unaligned_ivec: alignaddrl $ivec, $ivoff, %g0 ! handle unaligned ivec mov 0xff, $omask srl $omask, $ivoff, $omask faligndata %f12, %f12, %f0 faligndata %f12, %f14, %f2 faligndata %f14, %f14, %f4 stda %f0, [$ivec + $omask]0xc0 std %f2, [$ivec + 8] add $ivec, 16, $ivec orn %g0, $omask, $omask stda %f4, [$ivec + $omask]0xc0 ___ $code.=<<___; ret restore .type aes${bits}_t4_cbc_decrypt,#function .size aes${bits}_t4_cbc_decrypt,.-aes${bits}_t4_cbc_decrypt ___ } &aes_cbc_decrypt_implement(128); &aes_cbc_decrypt_implement(192); &aes_cbc_decrypt_implement(256); sub aes_ctr32_implement { my $bits = shift; $code.=<<___; .globl aes${bits}_t4_ctr32_encrypt .align 32 aes${bits}_t4_ctr32_encrypt: save %sp, -$frame, %sp call _aes${bits}_loadkey nop ld [$ivec + 0], %l4 ! counter ld [$ivec + 4], %l5 ld [$ivec + 8], %l6 ld [$ivec + 12], %l7 sllx %l4, 32, %o5 or %l5, %o5, %o5 sllx %l6, 32, %g1 xor %o5, %g4, %g4 ! ^= rk[0] xor %g1, %g5, %g5 movxtod %g4, %f14 ! most significant 64 bits andcc $len, 1, %g0 ! is number of blocks even? and $inp, 7, $ileft andn $inp, 7, $inp sll $ileft, 3, $ileft mov 64, $iright mov 0xff, $omask sub $iright, $ileft, $iright and $out, 7, $ooff alignaddrl $out, %g0, $out bz %icc, .L${bits}_ctr32_loop2x srl $omask, $ooff, $omask .L${bits}_ctr32_loop: ldx [$inp + 0], %o0 brz,pt $ileft, 4f ldx [$inp + 8], %o1 ldx [$inp + 16], %o2 sllx %o0, $ileft, %o0 srlx %o1, $iright, %g1 sllx %o1, $ileft, %o1 or %g1, %o0, %o0 srlx %o2, $iright, %o2 or %o2, %o1, %o1 4: xor %g5, %l7, %g1 ! ^= rk[0] add %l7, 1, %l7 movxtod %g1, %f2 srl %l7, 0, %l7 ! clruw aes_eround01 %f16, %f14, %f2, %f4 aes_eround23 %f18, %f14, %f2, %f2 call _aes${bits}_encrypt_1x+8 add $inp, 16, $inp movxtod %o0, %f10 movxtod %o1, %f12 fxor %f10, %f0, %f0 ! ^= inp fxor %f12, %f2, %f2 brnz,pn $ooff, 2f sub $len, 1, $len std %f0, [$out + 0] std %f2, [$out + 8] brnz,pt $len, .L${bits}_ctr32_loop2x add $out, 16, $out ret restore .align 16 2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard ! and ~3x deterioration ! in inp==out case faligndata %f0, %f0, %f4 ! handle unaligned output faligndata %f0, %f2, %f6 faligndata %f2, %f2, %f8 stda %f4, [$out + $omask]0xc0 ! partial store std %f6, [$out + 8] add $out, 16, $out orn %g0, $omask, $omask stda %f8, [$out + $omask]0xc0 ! partial store brnz,pt $len, .L${bits}_ctr32_loop2x+4 orn %g0, $omask, $omask ret restore !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! .align 32 .L${bits}_ctr32_loop2x: ldx [$inp + 0], %o0 ldx [$inp + 8], %o1 ldx [$inp + 16], %o2 brz,pt $ileft, 4f ldx [$inp + 24], %o3 ldx [$inp + 32], %o4 sllx %o0, $ileft, %o0 srlx %o1, $iright, %g1 or %g1, %o0, %o0 sllx %o1, $ileft, %o1 srlx %o2, $iright, %g1 or %g1, %o1, %o1 sllx %o2, $ileft, %o2 srlx %o3, $iright, %g1 or %g1, %o2, %o2 sllx %o3, $ileft, %o3 srlx %o4, $iright, %o4 or %o4, %o3, %o3 4: xor %g5, %l7, %g1 ! ^= rk[0] add %l7, 1, %l7 movxtod %g1, %f2 srl %l7, 0, %l7 ! clruw xor %g5, %l7, %g1 add %l7, 1, %l7 movxtod %g1, %f6 srl %l7, 0, %l7 ! clruw aes_eround01 %f16, %f14, %f2, %f8 aes_eround23 %f18, %f14, %f2, %f2 aes_eround01 %f16, %f14, %f6, %f10 aes_eround23 %f18, %f14, %f6, %f6 call _aes${bits}_encrypt_2x+16 add $inp, 32, $inp movxtod %o0, %f8 movxtod %o1, %f10 movxtod %o2, %f12 fxor %f8, %f0, %f0 ! ^= inp movxtod %o3, %f8 fxor %f10, %f2, %f2 fxor %f12, %f4, %f4 fxor %f8, %f6, %f6 brnz,pn $ooff, 2f sub $len, 2, $len std %f0, [$out + 0] std %f2, [$out + 8] std %f4, [$out + 16] std %f6, [$out + 24] brnz,pt $len, .L${bits}_ctr32_loop2x add $out, 32, $out ret restore .align 16 2: ldxa [$inp]0x82, %o0 ! avoid read-after-write hazard ! and ~3x deterioration ! in inp==out case faligndata %f0, %f0, %f8 ! handle unaligned output faligndata %f0, %f2, %f0 faligndata %f2, %f4, %f2 faligndata %f4, %f6, %f4 faligndata %f6, %f6, %f6 stda %f8, [$out + $omask]0xc0 ! partial store std %f0, [$out + 8] std %f2, [$out + 16] std %f4, [$out + 24] add $out, 32, $out orn %g0, $omask, $omask stda %f6, [$out + $omask]0xc0 ! partial store brnz,pt $len, .L${bits}_ctr32_loop2x+4 orn %g0, $omask, $omask ret restore .type aes${bits}_t4_ctr32_encrypt,#function .size aes${bits}_t4_ctr32_encrypt,.-aes${bits}_t4_ctr32_encrypt ___ } if ($evp) { &aes_ctr32_implement(128); &aes_ctr32_implement(192); &aes_ctr32_implement(256); } }}} if (!$evp) { $code.=<<___; .global AES_encrypt AES_encrypt=aes_t4_encrypt .global AES_decrypt AES_decrypt=aes_t4_decrypt .global AES_set_encrypt_key AES_set_encrypt_key=aes_t4_set_encrypt_key .global AES_set_decrypt_key AES_set_decrypt_key=aes_t4_set_decrypt_key ___ my ($inp,$out,$len,$key,$ivec,$enc)=map("%o$_",(0..5)); $code.=<<___; .globl AES_cbc_encrypt .align 32 AES_cbc_encrypt: ld [$key + 240], %g1 nop brz $enc, .Lcbc_decrypt cmp %g1, 12 bl,pt %icc, aes128_t4_cbc_encrypt nop be,pn %icc, aes192_t4_cbc_encrypt nop ba aes256_t4_cbc_encrypt nop .Lcbc_decrypt: bl,pt %icc, aes128_t4_cbc_decrypt nop be,pn %icc, aes192_t4_cbc_decrypt nop ba aes256_t4_cbc_decrypt nop .type AES_cbc_encrypt,#function .size AES_cbc_encrypt,.-AES_cbc_encrypt ___ } $code.=<<___; .asciz "AES for SPARC T4, David S. Miller, Andy Polyakov" .align 4 ___ # Purpose of these subroutines is to explicitly encode VIS instructions, # so that one can compile the module without having to specify VIS # extentions on compiler command line, e.g. -xarch=v9 vs. -xarch=v9a. # Idea is to reserve for option to produce "universal" binary and let # programmer detect if current CPU is VIS capable at run-time. sub unvis { my ($mnemonic,$rs1,$rs2,$rd)=@_; my ($ref,$opf); my %visopf = ( "faligndata" => 0x048, "fxor" => 0x06c ); $ref = "$mnemonic\t$rs1,$rs2,$rd"; if ($opf=$visopf{$mnemonic}) { foreach ($rs1,$rs2,$rd) { return $ref if (!/%f([0-9]{1,2})/); $_=$1; if ($1>=32) { return $ref if ($1&1); # re-encode for upper double register addressing $_=($1|$1>>5)&31; } } return sprintf ".word\t0x%08x !%s", 0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2, $ref; } else { return $ref; } } sub unalignaddr { my ($mnemonic,$rs1,$rs2,$rd)=@_; my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24 ); my $ref = "$mnemonic\t$rs1,$rs2,$rd"; my $opf = $mnemonic =~ /l$/ ? 0x01a :0x18; foreach ($rs1,$rs2,$rd) { if (/%([goli])([0-7])/) { $_=$bias{$1}+$2; } else { return $ref; } } return sprintf ".word\t0x%08x !%s", 0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2, $ref; } sub unaes_round { # 4-argument instructions my ($mnemonic,$rs1,$rs2,$rs3,$rd)=@_; my ($ref,$opf); my %aesopf = ( "aes_eround01" => 0, "aes_eround23" => 1, "aes_dround01" => 2, "aes_dround23" => 3, "aes_eround01_l"=> 4, "aes_eround23_l"=> 5, "aes_dround01_l"=> 6, "aes_dround23_l"=> 7, "aes_kexpand1" => 8 ); $ref = "$mnemonic\t$rs1,$rs2,$rs3,$rd"; if (defined($opf=$aesopf{$mnemonic})) { $rs3 = ($rs3 =~ /%f([0-6]*[02468])/) ? (($1|$1>>5)&31) : $rs3; foreach ($rs1,$rs2,$rd) { return $ref if (!/%f([0-9]{1,2})/); $_=$1; if ($1>=32) { return $ref if ($1&1); # re-encode for upper double register addressing $_=($1|$1>>5)&31; } } return sprintf ".word\t0x%08x !%s", 2<<30|$rd<<25|0x19<<19|$rs1<<14|$rs3<<9|$opf<<5|$rs2, $ref; } else { return $ref; } } sub unaes_kexpand { # 3-argument instructions my ($mnemonic,$rs1,$rs2,$rd)=@_; my ($ref,$opf); my %aesopf = ( "aes_kexpand0" => 0x130, "aes_kexpand2" => 0x131 ); $ref = "$mnemonic\t$rs1,$rs2,$rd"; if (defined($opf=$aesopf{$mnemonic})) { foreach ($rs1,$rs2,$rd) { return $ref if (!/%f([0-9]{1,2})/); $_=$1; if ($1>=32) { return $ref if ($1&1); # re-encode for upper double register addressing $_=($1|$1>>5)&31; } } return sprintf ".word\t0x%08x !%s", 2<<30|$rd<<25|0x36<<19|$rs1<<14|$opf<<5|$rs2, $ref; } else { return $ref; } } sub unmovxtox { # 2-argument instructions my ($mnemonic,$rs,$rd)=@_; my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24, "f" => 0 ); my ($ref,$opf); my %movxopf = ( "movdtox" => 0x110, "movstouw" => 0x111, "movstosw" => 0x113, "movxtod" => 0x118, "movwtos" => 0x119 ); $ref = "$mnemonic\t$rs,$rd"; if (defined($opf=$movxopf{$mnemonic})) { foreach ($rs,$rd) { return $ref if (!/%([fgoli])([0-9]{1,2})/); $_=$bias{$1}+$2; if ($2>=32) { return $ref if ($2&1); # re-encode for upper double register addressing $_=($2|$2>>5)&31; } } return sprintf ".word\t0x%08x !%s", 2<<30|$rd<<25|0x36<<19|$opf<<5|$rs, $ref; } else { return $ref; } } foreach (split("\n",$code)) { s/\`([^\`]*)\`/eval $1/ge; s/\b(aes_[edk][^\s]*)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*([%fx0-9]+),\s*(%f[0-9]{1,2})/ &unaes_round($1,$2,$3,$4,$5) /ge or s/\b(aes_kexpand[02])\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})/ &unaes_kexpand($1,$2,$3,$4) /ge or s/\b(mov[ds]to\w+)\s+(%f[0-9]{1,2}),\s*(%[goli][0-7])/ &unmovxtox($1,$2,$3) /ge or s/\b(mov[xw]to[ds])\s+(%[goli][0-7]),\s*(%f[0-9]{1,2})/ &unmovxtox($1,$2,$3) /ge or s/\b(f[^\s]*)\s+(%f[0-9]{1,2}),\s*(%f[0-9]{1,2}),\s*(%f[0-9]{1,2})/ &unvis($1,$2,$3,$4) /ge or s/\b(alignaddr[l]*)\s+(%[goli][0-7]),\s*(%[goli][0-7]),\s*(%[goli][0-7])/ &unalignaddr($1,$2,$3,$4) /ge; print $_,"\n"; } close STDOUT;