ref: 2cdc6577ef8a251bf1740439cf5bfc47050dab41
dir: /third_party/boringssl/src/crypto/fipsmodule/aes/asm/vpaes-x86.pl/
#! /usr/bin/env perl # Copyright 2011-2016 The OpenSSL Project Authors. All Rights Reserved. # # Licensed under the OpenSSL license (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 ###################################################################### ## Constant-time SSSE3 AES core implementation. ## version 0.1 ## ## By Mike Hamburg (Stanford University), 2009 ## Public domain. ## ## For details see http://shiftleft.org/papers/vector_aes/ and ## http://crypto.stanford.edu/vpaes/. ###################################################################### # September 2011. # # Port vpaes-x86_64.pl as 32-bit "almost" drop-in replacement for # aes-586.pl. "Almost" refers to the fact that AES_cbc_encrypt # doesn't handle partial vectors (doesn't have to if called from # EVP only). "Drop-in" implies that this module doesn't share key # schedule structure with the original nor does it make assumption # about its alignment... # # Performance summary. aes-586.pl column lists large-block CBC # encrypt/decrypt/with-hyper-threading-off(*) results in cycles per # byte processed with 128-bit key, and vpaes-x86.pl column - [also # large-block CBC] encrypt/decrypt. # # aes-586.pl vpaes-x86.pl # # Core 2(**) 28.1/41.4/18.3 21.9/25.2(***) # Nehalem 27.9/40.4/18.1 10.2/11.9 # Atom 70.7/92.1/60.1 61.1/75.4(***) # Silvermont 45.4/62.9/24.1 49.2/61.1(***) # # (*) "Hyper-threading" in the context refers rather to cache shared # among multiple cores, than to specifically Intel HTT. As vast # majority of contemporary cores share cache, slower code path # is common place. In other words "with-hyper-threading-off" # results are presented mostly for reference purposes. # # (**) "Core 2" refers to initial 65nm design, a.k.a. Conroe. # # (***) Less impressive improvement on Core 2 and Atom is due to slow # pshufb, yet it's respectable +28%/64% improvement on Core 2 # and +15% on Atom (as implied, over "hyper-threading-safe" # code path). # # <appro@openssl.org> $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1; push(@INC,"${dir}","${dir}../../../perlasm"); require "x86asm.pl"; $output = pop; open OUT,">$output"; *STDOUT=*OUT; &asm_init($ARGV[0],$x86only = $ARGV[$#ARGV] eq "386"); $PREFIX="vpaes"; my ($round, $base, $magic, $key, $const, $inp, $out)= ("eax", "ebx", "ecx", "edx","ebp", "esi","edi"); &preprocessor_ifdef("BORINGSSL_DISPATCH_TEST") &external_label("BORINGSSL_function_hit"); &preprocessor_endif(); &static_label("_vpaes_consts"); &static_label("_vpaes_schedule_low_round"); &set_label("_vpaes_consts",64); $k_inv=-0x30; # inv, inva &data_word(0x0D080180,0x0E05060F,0x0A0B0C02,0x04070309); &data_word(0x0F0B0780,0x01040A06,0x02050809,0x030D0E0C); $k_s0F=-0x10; # s0F &data_word(0x0F0F0F0F,0x0F0F0F0F,0x0F0F0F0F,0x0F0F0F0F); $k_ipt=0x00; # input transform (lo, hi) &data_word(0x5A2A7000,0xC2B2E898,0x52227808,0xCABAE090); &data_word(0x317C4D00,0x4C01307D,0xB0FDCC81,0xCD80B1FC); $k_sb1=0x20; # sb1u, sb1t &data_word(0xCB503E00,0xB19BE18F,0x142AF544,0xA5DF7A6E); &data_word(0xFAE22300,0x3618D415,0x0D2ED9EF,0x3BF7CCC1); $k_sb2=0x40; # sb2u, sb2t &data_word(0x0B712400,0xE27A93C6,0xBC982FCD,0x5EB7E955); &data_word(0x0AE12900,0x69EB8840,0xAB82234A,0xC2A163C8); $k_sbo=0x60; # sbou, sbot &data_word(0x6FBDC700,0xD0D26D17,0xC502A878,0x15AABF7A); &data_word(0x5FBB6A00,0xCFE474A5,0x412B35FA,0x8E1E90D1); $k_mc_forward=0x80; # mc_forward &data_word(0x00030201,0x04070605,0x080B0A09,0x0C0F0E0D); &data_word(0x04070605,0x080B0A09,0x0C0F0E0D,0x00030201); &data_word(0x080B0A09,0x0C0F0E0D,0x00030201,0x04070605); &data_word(0x0C0F0E0D,0x00030201,0x04070605,0x080B0A09); $k_mc_backward=0xc0; # mc_backward &data_word(0x02010003,0x06050407,0x0A09080B,0x0E0D0C0F); &data_word(0x0E0D0C0F,0x02010003,0x06050407,0x0A09080B); &data_word(0x0A09080B,0x0E0D0C0F,0x02010003,0x06050407); &data_word(0x06050407,0x0A09080B,0x0E0D0C0F,0x02010003); $k_sr=0x100; # sr &data_word(0x03020100,0x07060504,0x0B0A0908,0x0F0E0D0C); &data_word(0x0F0A0500,0x030E0904,0x07020D08,0x0B06010C); &data_word(0x0B020900,0x0F060D04,0x030A0108,0x070E050C); &data_word(0x070A0D00,0x0B0E0104,0x0F020508,0x0306090C); $k_rcon=0x140; # rcon &data_word(0xAF9DEEB6,0x1F8391B9,0x4D7C7D81,0x702A9808); $k_s63=0x150; # s63: all equal to 0x63 transformed &data_word(0x5B5B5B5B,0x5B5B5B5B,0x5B5B5B5B,0x5B5B5B5B); $k_opt=0x160; # output transform &data_word(0xD6B66000,0xFF9F4929,0xDEBE6808,0xF7974121); &data_word(0x50BCEC00,0x01EDBD51,0xB05C0CE0,0xE10D5DB1); $k_deskew=0x180; # deskew tables: inverts the sbox's "skew" &data_word(0x47A4E300,0x07E4A340,0x5DBEF91A,0x1DFEB95A); &data_word(0x83EA6900,0x5F36B5DC,0xF49D1E77,0x2841C2AB); ## ## Decryption stuff ## Key schedule constants ## $k_dksd=0x1a0; # decryption key schedule: invskew x*D &data_word(0xA3E44700,0xFEB91A5D,0x5A1DBEF9,0x0740E3A4); &data_word(0xB5368300,0x41C277F4,0xAB289D1E,0x5FDC69EA); $k_dksb=0x1c0; # decryption key schedule: invskew x*B &data_word(0x8550D500,0x9A4FCA1F,0x1CC94C99,0x03D65386); &data_word(0xB6FC4A00,0x115BEDA7,0x7E3482C8,0xD993256F); $k_dkse=0x1e0; # decryption key schedule: invskew x*E + 0x63 &data_word(0x1FC9D600,0xD5031CCA,0x994F5086,0x53859A4C); &data_word(0x4FDC7BE8,0xA2319605,0x20B31487,0xCD5EF96A); $k_dks9=0x200; # decryption key schedule: invskew x*9 &data_word(0x7ED9A700,0xB6116FC8,0x82255BFC,0x4AED9334); &data_word(0x27143300,0x45765162,0xE9DAFDCE,0x8BB89FAC); ## ## Decryption stuff ## Round function constants ## $k_dipt=0x220; # decryption input transform &data_word(0x0B545F00,0x0F505B04,0x114E451A,0x154A411E); &data_word(0x60056500,0x86E383E6,0xF491F194,0x12771772); $k_dsb9=0x240; # decryption sbox output *9*u, *9*t &data_word(0x9A86D600,0x851C0353,0x4F994CC9,0xCAD51F50); &data_word(0xECD74900,0xC03B1789,0xB2FBA565,0x725E2C9E); $k_dsbd=0x260; # decryption sbox output *D*u, *D*t &data_word(0xE6B1A200,0x7D57CCDF,0x882A4439,0xF56E9B13); &data_word(0x24C6CB00,0x3CE2FAF7,0x15DEEFD3,0x2931180D); $k_dsbb=0x280; # decryption sbox output *B*u, *B*t &data_word(0x96B44200,0xD0226492,0xB0F2D404,0x602646F6); &data_word(0xCD596700,0xC19498A6,0x3255AA6B,0xF3FF0C3E); $k_dsbe=0x2a0; # decryption sbox output *E*u, *E*t &data_word(0x26D4D000,0x46F29296,0x64B4F6B0,0x22426004); &data_word(0xFFAAC100,0x0C55A6CD,0x98593E32,0x9467F36B); $k_dsbo=0x2c0; # decryption sbox final output &data_word(0x7EF94000,0x1387EA53,0xD4943E2D,0xC7AA6DB9); &data_word(0x93441D00,0x12D7560F,0xD8C58E9C,0xCA4B8159); &asciz ("Vector Permutation AES for x86/SSSE3, Mike Hamburg (Stanford University)"); &align (64); &function_begin_B("_vpaes_preheat"); &add ($const,&DWP(0,"esp")); &movdqa ("xmm7",&QWP($k_inv,$const)); &movdqa ("xmm6",&QWP($k_s0F,$const)); &ret (); &function_end_B("_vpaes_preheat"); ## ## _aes_encrypt_core ## ## AES-encrypt %xmm0. ## ## Inputs: ## %xmm0 = input ## %xmm6-%xmm7 as in _vpaes_preheat ## (%edx) = scheduled keys ## ## Output in %xmm0 ## Clobbers %xmm1-%xmm5, %eax, %ebx, %ecx, %edx ## ## &function_begin_B("_vpaes_encrypt_core"); &mov ($magic,16); &mov ($round,&DWP(240,$key)); &movdqa ("xmm1","xmm6") &movdqa ("xmm2",&QWP($k_ipt,$const)); &pandn ("xmm1","xmm0"); &pand ("xmm0","xmm6"); &movdqu ("xmm5",&QWP(0,$key)); &pshufb ("xmm2","xmm0"); &movdqa ("xmm0",&QWP($k_ipt+16,$const)); &pxor ("xmm2","xmm5"); &psrld ("xmm1",4); &add ($key,16); &pshufb ("xmm0","xmm1"); &lea ($base,&DWP($k_mc_backward,$const)); &pxor ("xmm0","xmm2"); &jmp (&label("enc_entry")); &set_label("enc_loop",16); # middle of middle round &movdqa ("xmm4",&QWP($k_sb1,$const)); # 4 : sb1u &movdqa ("xmm0",&QWP($k_sb1+16,$const));# 0 : sb1t &pshufb ("xmm4","xmm2"); # 4 = sb1u &pshufb ("xmm0","xmm3"); # 0 = sb1t &pxor ("xmm4","xmm5"); # 4 = sb1u + k &movdqa ("xmm5",&QWP($k_sb2,$const)); # 4 : sb2u &pxor ("xmm0","xmm4"); # 0 = A &movdqa ("xmm1",&QWP(-0x40,$base,$magic));# .Lk_mc_forward[] &pshufb ("xmm5","xmm2"); # 4 = sb2u &movdqa ("xmm2",&QWP($k_sb2+16,$const));# 2 : sb2t &movdqa ("xmm4",&QWP(0,$base,$magic)); # .Lk_mc_backward[] &pshufb ("xmm2","xmm3"); # 2 = sb2t &movdqa ("xmm3","xmm0"); # 3 = A &pxor ("xmm2","xmm5"); # 2 = 2A &pshufb ("xmm0","xmm1"); # 0 = B &add ($key,16); # next key &pxor ("xmm0","xmm2"); # 0 = 2A+B &pshufb ("xmm3","xmm4"); # 3 = D &add ($magic,16); # next mc &pxor ("xmm3","xmm0"); # 3 = 2A+B+D &pshufb ("xmm0","xmm1"); # 0 = 2B+C &and ($magic,0x30); # ... mod 4 &sub ($round,1); # nr-- &pxor ("xmm0","xmm3"); # 0 = 2A+3B+C+D &set_label("enc_entry"); # top of round &movdqa ("xmm1","xmm6"); # 1 : i &movdqa ("xmm5",&QWP($k_inv+16,$const));# 2 : a/k &pandn ("xmm1","xmm0"); # 1 = i<<4 &psrld ("xmm1",4); # 1 = i &pand ("xmm0","xmm6"); # 0 = k &pshufb ("xmm5","xmm0"); # 2 = a/k &movdqa ("xmm3","xmm7"); # 3 : 1/i &pxor ("xmm0","xmm1"); # 0 = j &pshufb ("xmm3","xmm1"); # 3 = 1/i &movdqa ("xmm4","xmm7"); # 4 : 1/j &pxor ("xmm3","xmm5"); # 3 = iak = 1/i + a/k &pshufb ("xmm4","xmm0"); # 4 = 1/j &movdqa ("xmm2","xmm7"); # 2 : 1/iak &pxor ("xmm4","xmm5"); # 4 = jak = 1/j + a/k &pshufb ("xmm2","xmm3"); # 2 = 1/iak &movdqa ("xmm3","xmm7"); # 3 : 1/jak &pxor ("xmm2","xmm0"); # 2 = io &pshufb ("xmm3","xmm4"); # 3 = 1/jak &movdqu ("xmm5",&QWP(0,$key)); &pxor ("xmm3","xmm1"); # 3 = jo &jnz (&label("enc_loop")); # middle of last round &movdqa ("xmm4",&QWP($k_sbo,$const)); # 3 : sbou .Lk_sbo &movdqa ("xmm0",&QWP($k_sbo+16,$const));# 3 : sbot .Lk_sbo+16 &pshufb ("xmm4","xmm2"); # 4 = sbou &pxor ("xmm4","xmm5"); # 4 = sb1u + k &pshufb ("xmm0","xmm3"); # 0 = sb1t &movdqa ("xmm1",&QWP(0x40,$base,$magic));# .Lk_sr[] &pxor ("xmm0","xmm4"); # 0 = A &pshufb ("xmm0","xmm1"); &ret (); &function_end_B("_vpaes_encrypt_core"); ## ## Decryption core ## ## Same API as encryption core. ## &function_begin_B("_vpaes_decrypt_core"); &lea ($base,&DWP($k_dsbd,$const)); &mov ($round,&DWP(240,$key)); &movdqa ("xmm1","xmm6"); &movdqa ("xmm2",&QWP($k_dipt-$k_dsbd,$base)); &pandn ("xmm1","xmm0"); &mov ($magic,$round); &psrld ("xmm1",4) &movdqu ("xmm5",&QWP(0,$key)); &shl ($magic,4); &pand ("xmm0","xmm6"); &pshufb ("xmm2","xmm0"); &movdqa ("xmm0",&QWP($k_dipt-$k_dsbd+16,$base)); &xor ($magic,0x30); &pshufb ("xmm0","xmm1"); &and ($magic,0x30); &pxor ("xmm2","xmm5"); &movdqa ("xmm5",&QWP($k_mc_forward+48,$const)); &pxor ("xmm0","xmm2"); &add ($key,16); &lea ($magic,&DWP($k_sr-$k_dsbd,$base,$magic)); &jmp (&label("dec_entry")); &set_label("dec_loop",16); ## ## Inverse mix columns ## &movdqa ("xmm4",&QWP(-0x20,$base)); # 4 : sb9u &movdqa ("xmm1",&QWP(-0x10,$base)); # 0 : sb9t &pshufb ("xmm4","xmm2"); # 4 = sb9u &pshufb ("xmm1","xmm3"); # 0 = sb9t &pxor ("xmm0","xmm4"); &movdqa ("xmm4",&QWP(0,$base)); # 4 : sbdu &pxor ("xmm0","xmm1"); # 0 = ch &movdqa ("xmm1",&QWP(0x10,$base)); # 0 : sbdt &pshufb ("xmm4","xmm2"); # 4 = sbdu &pshufb ("xmm0","xmm5"); # MC ch &pshufb ("xmm1","xmm3"); # 0 = sbdt &pxor ("xmm0","xmm4"); # 4 = ch &movdqa ("xmm4",&QWP(0x20,$base)); # 4 : sbbu &pxor ("xmm0","xmm1"); # 0 = ch &movdqa ("xmm1",&QWP(0x30,$base)); # 0 : sbbt &pshufb ("xmm4","xmm2"); # 4 = sbbu &pshufb ("xmm0","xmm5"); # MC ch &pshufb ("xmm1","xmm3"); # 0 = sbbt &pxor ("xmm0","xmm4"); # 4 = ch &movdqa ("xmm4",&QWP(0x40,$base)); # 4 : sbeu &pxor ("xmm0","xmm1"); # 0 = ch &movdqa ("xmm1",&QWP(0x50,$base)); # 0 : sbet &pshufb ("xmm4","xmm2"); # 4 = sbeu &pshufb ("xmm0","xmm5"); # MC ch &pshufb ("xmm1","xmm3"); # 0 = sbet &pxor ("xmm0","xmm4"); # 4 = ch &add ($key,16); # next round key &palignr("xmm5","xmm5",12); &pxor ("xmm0","xmm1"); # 0 = ch &sub ($round,1); # nr-- &set_label("dec_entry"); # top of round &movdqa ("xmm1","xmm6"); # 1 : i &movdqa ("xmm2",&QWP($k_inv+16,$const));# 2 : a/k &pandn ("xmm1","xmm0"); # 1 = i<<4 &pand ("xmm0","xmm6"); # 0 = k &psrld ("xmm1",4); # 1 = i &pshufb ("xmm2","xmm0"); # 2 = a/k &movdqa ("xmm3","xmm7"); # 3 : 1/i &pxor ("xmm0","xmm1"); # 0 = j &pshufb ("xmm3","xmm1"); # 3 = 1/i &movdqa ("xmm4","xmm7"); # 4 : 1/j &pxor ("xmm3","xmm2"); # 3 = iak = 1/i + a/k &pshufb ("xmm4","xmm0"); # 4 = 1/j &pxor ("xmm4","xmm2"); # 4 = jak = 1/j + a/k &movdqa ("xmm2","xmm7"); # 2 : 1/iak &pshufb ("xmm2","xmm3"); # 2 = 1/iak &movdqa ("xmm3","xmm7"); # 3 : 1/jak &pxor ("xmm2","xmm0"); # 2 = io &pshufb ("xmm3","xmm4"); # 3 = 1/jak &movdqu ("xmm0",&QWP(0,$key)); &pxor ("xmm3","xmm1"); # 3 = jo &jnz (&label("dec_loop")); # middle of last round &movdqa ("xmm4",&QWP(0x60,$base)); # 3 : sbou &pshufb ("xmm4","xmm2"); # 4 = sbou &pxor ("xmm4","xmm0"); # 4 = sb1u + k &movdqa ("xmm0",&QWP(0x70,$base)); # 0 : sbot &movdqa ("xmm2",&QWP(0,$magic)); &pshufb ("xmm0","xmm3"); # 0 = sb1t &pxor ("xmm0","xmm4"); # 0 = A &pshufb ("xmm0","xmm2"); &ret (); &function_end_B("_vpaes_decrypt_core"); ######################################################## ## ## ## AES key schedule ## ## ## ######################################################## &function_begin_B("_vpaes_schedule_core"); &add ($const,&DWP(0,"esp")); &movdqu ("xmm0",&QWP(0,$inp)); # load key (unaligned) &movdqa ("xmm2",&QWP($k_rcon,$const)); # load rcon # input transform &movdqa ("xmm3","xmm0"); &lea ($base,&DWP($k_ipt,$const)); &movdqa (&QWP(4,"esp"),"xmm2"); # xmm8 &call ("_vpaes_schedule_transform"); &movdqa ("xmm7","xmm0"); &test ($out,$out); &jnz (&label("schedule_am_decrypting")); # encrypting, output zeroth round key after transform &movdqu (&QWP(0,$key),"xmm0"); &jmp (&label("schedule_go")); &set_label("schedule_am_decrypting"); # decrypting, output zeroth round key after shiftrows &movdqa ("xmm1",&QWP($k_sr,$const,$magic)); &pshufb ("xmm3","xmm1"); &movdqu (&QWP(0,$key),"xmm3"); &xor ($magic,0x30); &set_label("schedule_go"); &cmp ($round,192); &ja (&label("schedule_256")); &je (&label("schedule_192")); # 128: fall though ## ## .schedule_128 ## ## 128-bit specific part of key schedule. ## ## This schedule is really simple, because all its parts ## are accomplished by the subroutines. ## &set_label("schedule_128"); &mov ($round,10); &set_label("loop_schedule_128"); &call ("_vpaes_schedule_round"); &dec ($round); &jz (&label("schedule_mangle_last")); &call ("_vpaes_schedule_mangle"); # write output &jmp (&label("loop_schedule_128")); ## ## .aes_schedule_192 ## ## 192-bit specific part of key schedule. ## ## The main body of this schedule is the same as the 128-bit ## schedule, but with more smearing. The long, high side is ## stored in %xmm7 as before, and the short, low side is in ## the high bits of %xmm6. ## ## This schedule is somewhat nastier, however, because each ## round produces 192 bits of key material, or 1.5 round keys. ## Therefore, on each cycle we do 2 rounds and produce 3 round ## keys. ## &set_label("schedule_192",16); &movdqu ("xmm0",&QWP(8,$inp)); # load key part 2 (very unaligned) &call ("_vpaes_schedule_transform"); # input transform &movdqa ("xmm6","xmm0"); # save short part &pxor ("xmm4","xmm4"); # clear 4 &movhlps("xmm6","xmm4"); # clobber low side with zeros &mov ($round,4); &set_label("loop_schedule_192"); &call ("_vpaes_schedule_round"); &palignr("xmm0","xmm6",8); &call ("_vpaes_schedule_mangle"); # save key n &call ("_vpaes_schedule_192_smear"); &call ("_vpaes_schedule_mangle"); # save key n+1 &call ("_vpaes_schedule_round"); &dec ($round); &jz (&label("schedule_mangle_last")); &call ("_vpaes_schedule_mangle"); # save key n+2 &call ("_vpaes_schedule_192_smear"); &jmp (&label("loop_schedule_192")); ## ## .aes_schedule_256 ## ## 256-bit specific part of key schedule. ## ## The structure here is very similar to the 128-bit ## schedule, but with an additional "low side" in ## %xmm6. The low side's rounds are the same as the ## high side's, except no rcon and no rotation. ## &set_label("schedule_256",16); &movdqu ("xmm0",&QWP(16,$inp)); # load key part 2 (unaligned) &call ("_vpaes_schedule_transform"); # input transform &mov ($round,7); &set_label("loop_schedule_256"); &call ("_vpaes_schedule_mangle"); # output low result &movdqa ("xmm6","xmm0"); # save cur_lo in xmm6 # high round &call ("_vpaes_schedule_round"); &dec ($round); &jz (&label("schedule_mangle_last")); &call ("_vpaes_schedule_mangle"); # low round. swap xmm7 and xmm6 &pshufd ("xmm0","xmm0",0xFF); &movdqa (&QWP(20,"esp"),"xmm7"); &movdqa ("xmm7","xmm6"); &call ("_vpaes_schedule_low_round"); &movdqa ("xmm7",&QWP(20,"esp")); &jmp (&label("loop_schedule_256")); ## ## .aes_schedule_mangle_last ## ## Mangler for last round of key schedule ## Mangles %xmm0 ## when encrypting, outputs out(%xmm0) ^ 63 ## when decrypting, outputs unskew(%xmm0) ## ## Always called right before return... jumps to cleanup and exits ## &set_label("schedule_mangle_last",16); # schedule last round key from xmm0 &lea ($base,&DWP($k_deskew,$const)); &test ($out,$out); &jnz (&label("schedule_mangle_last_dec")); # encrypting &movdqa ("xmm1",&QWP($k_sr,$const,$magic)); &pshufb ("xmm0","xmm1"); # output permute &lea ($base,&DWP($k_opt,$const)); # prepare to output transform &add ($key,32); &set_label("schedule_mangle_last_dec"); &add ($key,-16); &pxor ("xmm0",&QWP($k_s63,$const)); &call ("_vpaes_schedule_transform"); # output transform &movdqu (&QWP(0,$key),"xmm0"); # save last key # cleanup &pxor ("xmm0","xmm0"); &pxor ("xmm1","xmm1"); &pxor ("xmm2","xmm2"); &pxor ("xmm3","xmm3"); &pxor ("xmm4","xmm4"); &pxor ("xmm5","xmm5"); &pxor ("xmm6","xmm6"); &pxor ("xmm7","xmm7"); &ret (); &function_end_B("_vpaes_schedule_core"); ## ## .aes_schedule_192_smear ## ## Smear the short, low side in the 192-bit key schedule. ## ## Inputs: ## %xmm7: high side, b a x y ## %xmm6: low side, d c 0 0 ## %xmm13: 0 ## ## Outputs: ## %xmm6: b+c+d b+c 0 0 ## %xmm0: b+c+d b+c b a ## &function_begin_B("_vpaes_schedule_192_smear"); &pshufd ("xmm1","xmm6",0x80); # d c 0 0 -> c 0 0 0 &pshufd ("xmm0","xmm7",0xFE); # b a _ _ -> b b b a &pxor ("xmm6","xmm1"); # -> c+d c 0 0 &pxor ("xmm1","xmm1"); &pxor ("xmm6","xmm0"); # -> b+c+d b+c b a &movdqa ("xmm0","xmm6"); &movhlps("xmm6","xmm1"); # clobber low side with zeros &ret (); &function_end_B("_vpaes_schedule_192_smear"); ## ## .aes_schedule_round ## ## Runs one main round of the key schedule on %xmm0, %xmm7 ## ## Specifically, runs subbytes on the high dword of %xmm0 ## then rotates it by one byte and xors into the low dword of ## %xmm7. ## ## Adds rcon from low byte of %xmm8, then rotates %xmm8 for ## next rcon. ## ## Smears the dwords of %xmm7 by xoring the low into the ## second low, result into third, result into highest. ## ## Returns results in %xmm7 = %xmm0. ## Clobbers %xmm1-%xmm5. ## &function_begin_B("_vpaes_schedule_round"); # extract rcon from xmm8 &movdqa ("xmm2",&QWP(8,"esp")); # xmm8 &pxor ("xmm1","xmm1"); &palignr("xmm1","xmm2",15); &palignr("xmm2","xmm2",15); &pxor ("xmm7","xmm1"); # rotate &pshufd ("xmm0","xmm0",0xFF); &palignr("xmm0","xmm0",1); # fall through... &movdqa (&QWP(8,"esp"),"xmm2"); # xmm8 # low round: same as high round, but no rotation and no rcon. &set_label("_vpaes_schedule_low_round"); # smear xmm7 &movdqa ("xmm1","xmm7"); &pslldq ("xmm7",4); &pxor ("xmm7","xmm1"); &movdqa ("xmm1","xmm7"); &pslldq ("xmm7",8); &pxor ("xmm7","xmm1"); &pxor ("xmm7",&QWP($k_s63,$const)); # subbyte &movdqa ("xmm4",&QWP($k_s0F,$const)); &movdqa ("xmm5",&QWP($k_inv,$const)); # 4 : 1/j &movdqa ("xmm1","xmm4"); &pandn ("xmm1","xmm0"); &psrld ("xmm1",4); # 1 = i &pand ("xmm0","xmm4"); # 0 = k &movdqa ("xmm2",&QWP($k_inv+16,$const));# 2 : a/k &pshufb ("xmm2","xmm0"); # 2 = a/k &pxor ("xmm0","xmm1"); # 0 = j &movdqa ("xmm3","xmm5"); # 3 : 1/i &pshufb ("xmm3","xmm1"); # 3 = 1/i &pxor ("xmm3","xmm2"); # 3 = iak = 1/i + a/k &movdqa ("xmm4","xmm5"); # 4 : 1/j &pshufb ("xmm4","xmm0"); # 4 = 1/j &pxor ("xmm4","xmm2"); # 4 = jak = 1/j + a/k &movdqa ("xmm2","xmm5"); # 2 : 1/iak &pshufb ("xmm2","xmm3"); # 2 = 1/iak &pxor ("xmm2","xmm0"); # 2 = io &movdqa ("xmm3","xmm5"); # 3 : 1/jak &pshufb ("xmm3","xmm4"); # 3 = 1/jak &pxor ("xmm3","xmm1"); # 3 = jo &movdqa ("xmm4",&QWP($k_sb1,$const)); # 4 : sbou &pshufb ("xmm4","xmm2"); # 4 = sbou &movdqa ("xmm0",&QWP($k_sb1+16,$const));# 0 : sbot &pshufb ("xmm0","xmm3"); # 0 = sb1t &pxor ("xmm0","xmm4"); # 0 = sbox output # add in smeared stuff &pxor ("xmm0","xmm7"); &movdqa ("xmm7","xmm0"); &ret (); &function_end_B("_vpaes_schedule_round"); ## ## .aes_schedule_transform ## ## Linear-transform %xmm0 according to tables at (%ebx) ## ## Output in %xmm0 ## Clobbers %xmm1, %xmm2 ## &function_begin_B("_vpaes_schedule_transform"); &movdqa ("xmm2",&QWP($k_s0F,$const)); &movdqa ("xmm1","xmm2"); &pandn ("xmm1","xmm0"); &psrld ("xmm1",4); &pand ("xmm0","xmm2"); &movdqa ("xmm2",&QWP(0,$base)); &pshufb ("xmm2","xmm0"); &movdqa ("xmm0",&QWP(16,$base)); &pshufb ("xmm0","xmm1"); &pxor ("xmm0","xmm2"); &ret (); &function_end_B("_vpaes_schedule_transform"); ## ## .aes_schedule_mangle ## ## Mangle xmm0 from (basis-transformed) standard version ## to our version. ## ## On encrypt, ## xor with 0x63 ## multiply by circulant 0,1,1,1 ## apply shiftrows transform ## ## On decrypt, ## xor with 0x63 ## multiply by "inverse mixcolumns" circulant E,B,D,9 ## deskew ## apply shiftrows transform ## ## ## Writes out to (%edx), and increments or decrements it ## Keeps track of round number mod 4 in %ecx ## Preserves xmm0 ## Clobbers xmm1-xmm5 ## &function_begin_B("_vpaes_schedule_mangle"); &movdqa ("xmm4","xmm0"); # save xmm0 for later &movdqa ("xmm5",&QWP($k_mc_forward,$const)); &test ($out,$out); &jnz (&label("schedule_mangle_dec")); # encrypting &add ($key,16); &pxor ("xmm4",&QWP($k_s63,$const)); &pshufb ("xmm4","xmm5"); &movdqa ("xmm3","xmm4"); &pshufb ("xmm4","xmm5"); &pxor ("xmm3","xmm4"); &pshufb ("xmm4","xmm5"); &pxor ("xmm3","xmm4"); &jmp (&label("schedule_mangle_both")); &set_label("schedule_mangle_dec",16); # inverse mix columns &movdqa ("xmm2",&QWP($k_s0F,$const)); &lea ($inp,&DWP($k_dksd,$const)); &movdqa ("xmm1","xmm2"); &pandn ("xmm1","xmm4"); &psrld ("xmm1",4); # 1 = hi &pand ("xmm4","xmm2"); # 4 = lo &movdqa ("xmm2",&QWP(0,$inp)); &pshufb ("xmm2","xmm4"); &movdqa ("xmm3",&QWP(0x10,$inp)); &pshufb ("xmm3","xmm1"); &pxor ("xmm3","xmm2"); &pshufb ("xmm3","xmm5"); &movdqa ("xmm2",&QWP(0x20,$inp)); &pshufb ("xmm2","xmm4"); &pxor ("xmm2","xmm3"); &movdqa ("xmm3",&QWP(0x30,$inp)); &pshufb ("xmm3","xmm1"); &pxor ("xmm3","xmm2"); &pshufb ("xmm3","xmm5"); &movdqa ("xmm2",&QWP(0x40,$inp)); &pshufb ("xmm2","xmm4"); &pxor ("xmm2","xmm3"); &movdqa ("xmm3",&QWP(0x50,$inp)); &pshufb ("xmm3","xmm1"); &pxor ("xmm3","xmm2"); &pshufb ("xmm3","xmm5"); &movdqa ("xmm2",&QWP(0x60,$inp)); &pshufb ("xmm2","xmm4"); &pxor ("xmm2","xmm3"); &movdqa ("xmm3",&QWP(0x70,$inp)); &pshufb ("xmm3","xmm1"); &pxor ("xmm3","xmm2"); &add ($key,-16); &set_label("schedule_mangle_both"); &movdqa ("xmm1",&QWP($k_sr,$const,$magic)); &pshufb ("xmm3","xmm1"); &add ($magic,-16); &and ($magic,0x30); &movdqu (&QWP(0,$key),"xmm3"); &ret (); &function_end_B("_vpaes_schedule_mangle"); # # Interface to OpenSSL # &function_begin("${PREFIX}_set_encrypt_key"); record_function_hit(5); &mov ($inp,&wparam(0)); # inp &lea ($base,&DWP(-56,"esp")); &mov ($round,&wparam(1)); # bits &and ($base,-16); &mov ($key,&wparam(2)); # key &xchg ($base,"esp"); # alloca &mov (&DWP(48,"esp"),$base); &mov ($base,$round); &shr ($base,5); &add ($base,5); &mov (&DWP(240,$key),$base); # AES_KEY->rounds = nbits/32+5; &mov ($magic,0x30); &mov ($out,0); &lea ($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point"))); &call ("_vpaes_schedule_core"); &set_label("pic_point"); &mov ("esp",&DWP(48,"esp")); &xor ("eax","eax"); &function_end("${PREFIX}_set_encrypt_key"); &function_begin("${PREFIX}_set_decrypt_key"); &mov ($inp,&wparam(0)); # inp &lea ($base,&DWP(-56,"esp")); &mov ($round,&wparam(1)); # bits &and ($base,-16); &mov ($key,&wparam(2)); # key &xchg ($base,"esp"); # alloca &mov (&DWP(48,"esp"),$base); &mov ($base,$round); &shr ($base,5); &add ($base,5); &mov (&DWP(240,$key),$base); # AES_KEY->rounds = nbits/32+5; &shl ($base,4); &lea ($key,&DWP(16,$key,$base)); &mov ($out,1); &mov ($magic,$round); &shr ($magic,1); &and ($magic,32); &xor ($magic,32); # nbist==192?0:32; &lea ($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point"))); &call ("_vpaes_schedule_core"); &set_label("pic_point"); &mov ("esp",&DWP(48,"esp")); &xor ("eax","eax"); &function_end("${PREFIX}_set_decrypt_key"); &function_begin("${PREFIX}_encrypt"); record_function_hit(4); &lea ($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point"))); &call ("_vpaes_preheat"); &set_label("pic_point"); &mov ($inp,&wparam(0)); # inp &lea ($base,&DWP(-56,"esp")); &mov ($out,&wparam(1)); # out &and ($base,-16); &mov ($key,&wparam(2)); # key &xchg ($base,"esp"); # alloca &mov (&DWP(48,"esp"),$base); &movdqu ("xmm0",&QWP(0,$inp)); &call ("_vpaes_encrypt_core"); &movdqu (&QWP(0,$out),"xmm0"); &mov ("esp",&DWP(48,"esp")); &function_end("${PREFIX}_encrypt"); &function_begin("${PREFIX}_decrypt"); &lea ($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point"))); &call ("_vpaes_preheat"); &set_label("pic_point"); &mov ($inp,&wparam(0)); # inp &lea ($base,&DWP(-56,"esp")); &mov ($out,&wparam(1)); # out &and ($base,-16); &mov ($key,&wparam(2)); # key &xchg ($base,"esp"); # alloca &mov (&DWP(48,"esp"),$base); &movdqu ("xmm0",&QWP(0,$inp)); &call ("_vpaes_decrypt_core"); &movdqu (&QWP(0,$out),"xmm0"); &mov ("esp",&DWP(48,"esp")); &function_end("${PREFIX}_decrypt"); &function_begin("${PREFIX}_cbc_encrypt"); &mov ($inp,&wparam(0)); # inp &mov ($out,&wparam(1)); # out &mov ($round,&wparam(2)); # len &mov ($key,&wparam(3)); # key &sub ($round,16); &jc (&label("cbc_abort")); &lea ($base,&DWP(-56,"esp")); &mov ($const,&wparam(4)); # ivp &and ($base,-16); &mov ($magic,&wparam(5)); # enc &xchg ($base,"esp"); # alloca &movdqu ("xmm1",&QWP(0,$const)); # load IV &sub ($out,$inp); &mov (&DWP(48,"esp"),$base); &mov (&DWP(0,"esp"),$out); # save out &mov (&DWP(4,"esp"),$key) # save key &mov (&DWP(8,"esp"),$const); # save ivp &mov ($out,$round); # $out works as $len &lea ($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point"))); &call ("_vpaes_preheat"); &set_label("pic_point"); &cmp ($magic,0); &je (&label("cbc_dec_loop")); &jmp (&label("cbc_enc_loop")); &set_label("cbc_enc_loop",16); &movdqu ("xmm0",&QWP(0,$inp)); # load input &pxor ("xmm0","xmm1"); # inp^=iv &call ("_vpaes_encrypt_core"); &mov ($base,&DWP(0,"esp")); # restore out &mov ($key,&DWP(4,"esp")); # restore key &movdqa ("xmm1","xmm0"); &movdqu (&QWP(0,$base,$inp),"xmm0"); # write output &lea ($inp,&DWP(16,$inp)); &sub ($out,16); &jnc (&label("cbc_enc_loop")); &jmp (&label("cbc_done")); &set_label("cbc_dec_loop",16); &movdqu ("xmm0",&QWP(0,$inp)); # load input &movdqa (&QWP(16,"esp"),"xmm1"); # save IV &movdqa (&QWP(32,"esp"),"xmm0"); # save future IV &call ("_vpaes_decrypt_core"); &mov ($base,&DWP(0,"esp")); # restore out &mov ($key,&DWP(4,"esp")); # restore key &pxor ("xmm0",&QWP(16,"esp")); # out^=iv &movdqa ("xmm1",&QWP(32,"esp")); # load next IV &movdqu (&QWP(0,$base,$inp),"xmm0"); # write output &lea ($inp,&DWP(16,$inp)); &sub ($out,16); &jnc (&label("cbc_dec_loop")); &set_label("cbc_done"); &mov ($base,&DWP(8,"esp")); # restore ivp &mov ("esp",&DWP(48,"esp")); &movdqu (&QWP(0,$base),"xmm1"); # write IV &set_label("cbc_abort"); &function_end("${PREFIX}_cbc_encrypt"); &asm_finish(); close STDOUT or die "error closing STDOUT: $!";