#! /usr/bin/env perl # Copyright 2007-2016 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 # ==================================================================== # Written by Andy Polyakov for the OpenSSL # project. The module is, however, dual licensed under OpenSSL and # CRYPTOGAMS licenses depending on where you obtain it. For further # details see http://www.openssl.org/~appro/cryptogams/. # ==================================================================== # AES for s390x. # April 2007. # # Software performance improvement over gcc-generated code is ~70% and # in absolute terms is ~73 cycles per byte processed with 128-bit key. # You're likely to exclaim "why so slow?" Keep in mind that z-CPUs are # *strictly* in-order execution and issued instruction [in this case # load value from memory is critical] has to complete before execution # flow proceeds. S-boxes are compressed to 2KB[+256B]. # # As for hardware acceleration support. It's basically a "teaser," as # it can and should be improved in several ways. Most notably support # for CBC is not utilized, nor multiple blocks are ever processed. # Then software key schedule can be postponed till hardware support # detection... Performance improvement over assembler is reportedly # ~2.5x, but can reach >8x [naturally on larger chunks] if proper # support is implemented. # May 2007. # # Implement AES_set_[en|de]crypt_key. Key schedule setup is avoided # for 128-bit keys, if hardware support is detected. # Januray 2009. # # Add support for hardware AES192/256 and reschedule instructions to # minimize/avoid Address Generation Interlock hazard and to favour # dual-issue z10 pipeline. This gave ~25% improvement on z10 and # almost 50% on z9. The gain is smaller on z10, because being dual- # issue z10 makes it improssible to eliminate the interlock condition: # critial path is not long enough. Yet it spends ~24 cycles per byte # processed with 128-bit key. # # Unlike previous version hardware support detection takes place only # at the moment of key schedule setup, which is denoted in key->rounds. # This is done, because deferred key setup can't be made MT-safe, not # for keys longer than 128 bits. # # Add AES_cbc_encrypt, which gives incredible performance improvement, # it was measured to be ~6.6x. It's less than previously mentioned 8x, # because software implementation was optimized. # May 2010. # # Add AES_ctr32_encrypt. If hardware-assisted, it provides up to 4.3x # performance improvement over "generic" counter mode routine relying # on single-block, also hardware-assisted, AES_encrypt. "Up to" refers # to the fact that exact throughput value depends on current stack # frame alignment within 4KB page. In worst case you get ~75% of the # maximum, but *on average* it would be as much as ~98%. Meaning that # worst case is unlike, it's like hitting ravine on plateau. # November 2010. # # Adapt for -m31 build. If kernel supports what's called "highgprs" # feature on Linux [see /proc/cpuinfo], it's possible to use 64-bit # instructions and achieve "64-bit" performance even in 31-bit legacy # application context. The feature is not specific to any particular # processor, as long as it's "z-CPU". Latter implies that the code # remains z/Architecture specific. On z990 it was measured to perform # 2x better than code generated by gcc 4.3. # December 2010. # # Add support for z196 "cipher message with counter" instruction. # Note however that it's disengaged, because it was measured to # perform ~12% worse than vanilla km-based code... # February 2011. # # Add AES_xts_[en|de]crypt. This includes support for z196 km-xts-aes # instructions, which deliver ~70% improvement at 8KB block size over # vanilla km-based code, 37% - at most like 512-bytes block size. $flavour = shift; if ($flavour =~ /3[12]/) { $SIZE_T=4; $g=""; } else { $SIZE_T=8; $g="g"; } while (($output=shift) && ($output!~/\w[\w\-]*\.\w+$/)) {} open STDOUT,">$output"; $softonly=0; # allow hardware support $t0="%r0"; $mask="%r0"; $t1="%r1"; $t2="%r2"; $inp="%r2"; $t3="%r3"; $out="%r3"; $bits="%r3"; $key="%r4"; $i1="%r5"; $i2="%r6"; $i3="%r7"; $s0="%r8"; $s1="%r9"; $s2="%r10"; $s3="%r11"; $tbl="%r12"; $rounds="%r13"; $ra="%r14"; $sp="%r15"; $stdframe=16*$SIZE_T+4*8; sub _data_word() { my $i; while(defined($i=shift)) { $code.=sprintf".long\t0x%08x,0x%08x\n",$i,$i; } } $code=<<___; #include "s390x_arch.h" .text .type AES_Te,\@object .align 256 AES_Te: ___ &_data_word( 0xc66363a5, 0xf87c7c84, 0xee777799, 0xf67b7b8d, 0xfff2f20d, 0xd66b6bbd, 0xde6f6fb1, 0x91c5c554, 0x60303050, 0x02010103, 0xce6767a9, 0x562b2b7d, 0xe7fefe19, 0xb5d7d762, 0x4dababe6, 0xec76769a, 0x8fcaca45, 0x1f82829d, 0x89c9c940, 0xfa7d7d87, 0xeffafa15, 0xb25959eb, 0x8e4747c9, 0xfbf0f00b, 0x41adadec, 0xb3d4d467, 0x5fa2a2fd, 0x45afafea, 0x239c9cbf, 0x53a4a4f7, 0xe4727296, 0x9bc0c05b, 0x75b7b7c2, 0xe1fdfd1c, 0x3d9393ae, 0x4c26266a, 0x6c36365a, 0x7e3f3f41, 0xf5f7f702, 0x83cccc4f, 0x6834345c, 0x51a5a5f4, 0xd1e5e534, 0xf9f1f108, 0xe2717193, 0xabd8d873, 0x62313153, 0x2a15153f, 0x0804040c, 0x95c7c752, 0x46232365, 0x9dc3c35e, 0x30181828, 0x379696a1, 0x0a05050f, 0x2f9a9ab5, 0x0e070709, 0x24121236, 0x1b80809b, 0xdfe2e23d, 0xcdebeb26, 0x4e272769, 0x7fb2b2cd, 0xea75759f, 0x1209091b, 0x1d83839e, 0x582c2c74, 0x341a1a2e, 0x361b1b2d, 0xdc6e6eb2, 0xb45a5aee, 0x5ba0a0fb, 0xa45252f6, 0x763b3b4d, 0xb7d6d661, 0x7db3b3ce, 0x5229297b, 0xdde3e33e, 0x5e2f2f71, 0x13848497, 0xa65353f5, 0xb9d1d168, 0x00000000, 0xc1eded2c, 0x40202060, 0xe3fcfc1f, 0x79b1b1c8, 0xb65b5bed, 0xd46a6abe, 0x8dcbcb46, 0x67bebed9, 0x7239394b, 0x944a4ade, 0x984c4cd4, 0xb05858e8, 0x85cfcf4a, 0xbbd0d06b, 0xc5efef2a, 0x4faaaae5, 0xedfbfb16, 0x864343c5, 0x9a4d4dd7, 0x66333355, 0x11858594, 0x8a4545cf, 0xe9f9f910, 0x04020206, 0xfe7f7f81, 0xa05050f0, 0x783c3c44, 0x259f9fba, 0x4ba8a8e3, 0xa25151f3, 0x5da3a3fe, 0x804040c0, 0x058f8f8a, 0x3f9292ad, 0x219d9dbc, 0x70383848, 0xf1f5f504, 0x63bcbcdf, 0x77b6b6c1, 0xafdada75, 0x42212163, 0x20101030, 0xe5ffff1a, 0xfdf3f30e, 0xbfd2d26d, 0x81cdcd4c, 0x180c0c14, 0x26131335, 0xc3ecec2f, 0xbe5f5fe1, 0x359797a2, 0x884444cc, 0x2e171739, 0x93c4c457, 0x55a7a7f2, 0xfc7e7e82, 0x7a3d3d47, 0xc86464ac, 0xba5d5de7, 0x3219192b, 0xe6737395, 0xc06060a0, 0x19818198, 0x9e4f4fd1, 0xa3dcdc7f, 0x44222266, 0x542a2a7e, 0x3b9090ab, 0x0b888883, 0x8c4646ca, 0xc7eeee29, 0x6bb8b8d3, 0x2814143c, 0xa7dede79, 0xbc5e5ee2, 0x160b0b1d, 0xaddbdb76, 0xdbe0e03b, 0x64323256, 0x743a3a4e, 0x140a0a1e, 0x924949db, 0x0c06060a, 0x4824246c, 0xb85c5ce4, 0x9fc2c25d, 0xbdd3d36e, 0x43acacef, 0xc46262a6, 0x399191a8, 0x319595a4, 0xd3e4e437, 0xf279798b, 0xd5e7e732, 0x8bc8c843, 0x6e373759, 0xda6d6db7, 0x018d8d8c, 0xb1d5d564, 0x9c4e4ed2, 0x49a9a9e0, 0xd86c6cb4, 0xac5656fa, 0xf3f4f407, 0xcfeaea25, 0xca6565af, 0xf47a7a8e, 0x47aeaee9, 0x10080818, 0x6fbabad5, 0xf0787888, 0x4a25256f, 0x5c2e2e72, 0x381c1c24, 0x57a6a6f1, 0x73b4b4c7, 0x97c6c651, 0xcbe8e823, 0xa1dddd7c, 0xe874749c, 0x3e1f1f21, 0x964b4bdd, 0x61bdbddc, 0x0d8b8b86, 0x0f8a8a85, 0xe0707090, 0x7c3e3e42, 0x71b5b5c4, 0xcc6666aa, 0x904848d8, 0x06030305, 0xf7f6f601, 0x1c0e0e12, 0xc26161a3, 0x6a35355f, 0xae5757f9, 0x69b9b9d0, 0x17868691, 0x99c1c158, 0x3a1d1d27, 0x279e9eb9, 0xd9e1e138, 0xebf8f813, 0x2b9898b3, 0x22111133, 0xd26969bb, 0xa9d9d970, 0x078e8e89, 0x339494a7, 0x2d9b9bb6, 0x3c1e1e22, 0x15878792, 0xc9e9e920, 0x87cece49, 0xaa5555ff, 0x50282878, 0xa5dfdf7a, 0x038c8c8f, 0x59a1a1f8, 0x09898980, 0x1a0d0d17, 0x65bfbfda, 0xd7e6e631, 0x844242c6, 0xd06868b8, 0x824141c3, 0x299999b0, 0x5a2d2d77, 0x1e0f0f11, 0x7bb0b0cb, 0xa85454fc, 0x6dbbbbd6, 0x2c16163a); $code.=<<___; # Te4[256] .byte 0x63, 0x7c, 0x77, 0x7b, 0xf2, 0x6b, 0x6f, 0xc5 .byte 0x30, 0x01, 0x67, 0x2b, 0xfe, 0xd7, 0xab, 0x76 .byte 0xca, 0x82, 0xc9, 0x7d, 0xfa, 0x59, 0x47, 0xf0 .byte 0xad, 0xd4, 0xa2, 0xaf, 0x9c, 0xa4, 0x72, 0xc0 .byte 0xb7, 0xfd, 0x93, 0x26, 0x36, 0x3f, 0xf7, 0xcc .byte 0x34, 0xa5, 0xe5, 0xf1, 0x71, 0xd8, 0x31, 0x15 .byte 0x04, 0xc7, 0x23, 0xc3, 0x18, 0x96, 0x05, 0x9a .byte 0x07, 0x12, 0x80, 0xe2, 0xeb, 0x27, 0xb2, 0x75 .byte 0x09, 0x83, 0x2c, 0x1a, 0x1b, 0x6e, 0x5a, 0xa0 .byte 0x52, 0x3b, 0xd6, 0xb3, 0x29, 0xe3, 0x2f, 0x84 .byte 0x53, 0xd1, 0x00, 0xed, 0x20, 0xfc, 0xb1, 0x5b .byte 0x6a, 0xcb, 0xbe, 0x39, 0x4a, 0x4c, 0x58, 0xcf .byte 0xd0, 0xef, 0xaa, 0xfb, 0x43, 0x4d, 0x33, 0x85 .byte 0x45, 0xf9, 0x02, 0x7f, 0x50, 0x3c, 0x9f, 0xa8 .byte 0x51, 0xa3, 0x40, 0x8f, 0x92, 0x9d, 0x38, 0xf5 .byte 0xbc, 0xb6, 0xda, 0x21, 0x10, 0xff, 0xf3, 0xd2 .byte 0xcd, 0x0c, 0x13, 0xec, 0x5f, 0x97, 0x44, 0x17 .byte 0xc4, 0xa7, 0x7e, 0x3d, 0x64, 0x5d, 0x19, 0x73 .byte 0x60, 0x81, 0x4f, 0xdc, 0x22, 0x2a, 0x90, 0x88 .byte 0x46, 0xee, 0xb8, 0x14, 0xde, 0x5e, 0x0b, 0xdb .byte 0xe0, 0x32, 0x3a, 0x0a, 0x49, 0x06, 0x24, 0x5c .byte 0xc2, 0xd3, 0xac, 0x62, 0x91, 0x95, 0xe4, 0x79 .byte 0xe7, 0xc8, 0x37, 0x6d, 0x8d, 0xd5, 0x4e, 0xa9 .byte 0x6c, 0x56, 0xf4, 0xea, 0x65, 0x7a, 0xae, 0x08 .byte 0xba, 0x78, 0x25, 0x2e, 0x1c, 0xa6, 0xb4, 0xc6 .byte 0xe8, 0xdd, 0x74, 0x1f, 0x4b, 0xbd, 0x8b, 0x8a .byte 0x70, 0x3e, 0xb5, 0x66, 0x48, 0x03, 0xf6, 0x0e .byte 0x61, 0x35, 0x57, 0xb9, 0x86, 0xc1, 0x1d, 0x9e .byte 0xe1, 0xf8, 0x98, 0x11, 0x69, 0xd9, 0x8e, 0x94 .byte 0x9b, 0x1e, 0x87, 0xe9, 0xce, 0x55, 0x28, 0xdf .byte 0x8c, 0xa1, 0x89, 0x0d, 0xbf, 0xe6, 0x42, 0x68 .byte 0x41, 0x99, 0x2d, 0x0f, 0xb0, 0x54, 0xbb, 0x16 # rcon[] .long 0x01000000, 0x02000000, 0x04000000, 0x08000000 .long 0x10000000, 0x20000000, 0x40000000, 0x80000000 .long 0x1B000000, 0x36000000, 0, 0, 0, 0, 0, 0 .align 256 .size AES_Te,.-AES_Te # void AES_encrypt(const unsigned char *inp, unsigned char *out, # const AES_KEY *key) { .globl AES_encrypt .type AES_encrypt,\@function AES_encrypt: ___ $code.=<<___ if (!$softonly); l %r0,240($key) lhi %r1,16 clr %r0,%r1 jl .Lesoft la %r1,0($key) #la %r2,0($inp) la %r4,0($out) lghi %r3,16 # single block length .long 0xb92e0042 # km %r4,%r2 brc 1,.-4 # can this happen? br %r14 .align 64 .Lesoft: ___ $code.=<<___; stm${g} %r3,$ra,3*$SIZE_T($sp) llgf $s0,0($inp) llgf $s1,4($inp) llgf $s2,8($inp) llgf $s3,12($inp) larl $tbl,AES_Te bras $ra,_s390x_AES_encrypt l${g} $out,3*$SIZE_T($sp) st $s0,0($out) st $s1,4($out) st $s2,8($out) st $s3,12($out) lm${g} %r6,$ra,6*$SIZE_T($sp) br $ra .size AES_encrypt,.-AES_encrypt .type _s390x_AES_encrypt,\@function .align 16 _s390x_AES_encrypt: st${g} $ra,15*$SIZE_T($sp) x $s0,0($key) x $s1,4($key) x $s2,8($key) x $s3,12($key) l $rounds,240($key) llill $mask,`0xff<<3` aghi $rounds,-1 j .Lenc_loop .align 16 .Lenc_loop: sllg $t1,$s0,`0+3` srlg $t2,$s0,`8-3` srlg $t3,$s0,`16-3` srl $s0,`24-3` nr $s0,$mask ngr $t1,$mask nr $t2,$mask nr $t3,$mask srlg $i1,$s1,`16-3` # i0 sllg $i2,$s1,`0+3` srlg $i3,$s1,`8-3` srl $s1,`24-3` nr $i1,$mask nr $s1,$mask ngr $i2,$mask nr $i3,$mask l $s0,0($s0,$tbl) # Te0[s0>>24] l $t1,1($t1,$tbl) # Te3[s0>>0] l $t2,2($t2,$tbl) # Te2[s0>>8] l $t3,3($t3,$tbl) # Te1[s0>>16] x $s0,3($i1,$tbl) # Te1[s1>>16] l $s1,0($s1,$tbl) # Te0[s1>>24] x $t2,1($i2,$tbl) # Te3[s1>>0] x $t3,2($i3,$tbl) # Te2[s1>>8] srlg $i1,$s2,`8-3` # i0 srlg $i2,$s2,`16-3` # i1 nr $i1,$mask nr $i2,$mask sllg $i3,$s2,`0+3` srl $s2,`24-3` nr $s2,$mask ngr $i3,$mask xr $s1,$t1 srlg $ra,$s3,`8-3` # i1 sllg $t1,$s3,`0+3` # i0 nr $ra,$mask la $key,16($key) ngr $t1,$mask x $s0,2($i1,$tbl) # Te2[s2>>8] x $s1,3($i2,$tbl) # Te1[s2>>16] l $s2,0($s2,$tbl) # Te0[s2>>24] x $t3,1($i3,$tbl) # Te3[s2>>0] srlg $i3,$s3,`16-3` # i2 xr $s2,$t2 srl $s3,`24-3` nr $i3,$mask nr $s3,$mask x $s0,0($key) x $s1,4($key) x $s2,8($key) x $t3,12($key) x $s0,1($t1,$tbl) # Te3[s3>>0] x $s1,2($ra,$tbl) # Te2[s3>>8] x $s2,3($i3,$tbl) # Te1[s3>>16] l $s3,0($s3,$tbl) # Te0[s3>>24] xr $s3,$t3 brct $rounds,.Lenc_loop .align 16 sllg $t1,$s0,`0+3` srlg $t2,$s0,`8-3` ngr $t1,$mask srlg $t3,$s0,`16-3` srl $s0,`24-3` nr $s0,$mask nr $t2,$mask nr $t3,$mask srlg $i1,$s1,`16-3` # i0 sllg $i2,$s1,`0+3` ngr $i2,$mask srlg $i3,$s1,`8-3` srl $s1,`24-3` nr $i1,$mask nr $s1,$mask nr $i3,$mask llgc $s0,2($s0,$tbl) # Te4[s0>>24] llgc $t1,2($t1,$tbl) # Te4[s0>>0] sll $s0,24 llgc $t2,2($t2,$tbl) # Te4[s0>>8] llgc $t3,2($t3,$tbl) # Te4[s0>>16] sll $t2,8 sll $t3,16 llgc $i1,2($i1,$tbl) # Te4[s1>>16] llgc $s1,2($s1,$tbl) # Te4[s1>>24] llgc $i2,2($i2,$tbl) # Te4[s1>>0] llgc $i3,2($i3,$tbl) # Te4[s1>>8] sll $i1,16 sll $s1,24 sll $i3,8 or $s0,$i1 or $s1,$t1 or $t2,$i2 or $t3,$i3 srlg $i1,$s2,`8-3` # i0 srlg $i2,$s2,`16-3` # i1 nr $i1,$mask nr $i2,$mask sllg $i3,$s2,`0+3` srl $s2,`24-3` ngr $i3,$mask nr $s2,$mask sllg $t1,$s3,`0+3` # i0 srlg $ra,$s3,`8-3` # i1 ngr $t1,$mask llgc $i1,2($i1,$tbl) # Te4[s2>>8] llgc $i2,2($i2,$tbl) # Te4[s2>>16] sll $i1,8 llgc $s2,2($s2,$tbl) # Te4[s2>>24] llgc $i3,2($i3,$tbl) # Te4[s2>>0] sll $i2,16 nr $ra,$mask sll $s2,24 or $s0,$i1 or $s1,$i2 or $s2,$t2 or $t3,$i3 srlg $i3,$s3,`16-3` # i2 srl $s3,`24-3` nr $i3,$mask nr $s3,$mask l $t0,16($key) l $t2,20($key) llgc $i1,2($t1,$tbl) # Te4[s3>>0] llgc $i2,2($ra,$tbl) # Te4[s3>>8] llgc $i3,2($i3,$tbl) # Te4[s3>>16] llgc $s3,2($s3,$tbl) # Te4[s3>>24] sll $i2,8 sll $i3,16 sll $s3,24 or $s0,$i1 or $s1,$i2 or $s2,$i3 or $s3,$t3 l${g} $ra,15*$SIZE_T($sp) xr $s0,$t0 xr $s1,$t2 x $s2,24($key) x $s3,28($key) br $ra .size _s390x_AES_encrypt,.-_s390x_AES_encrypt ___ $code.=<<___; .type AES_Td,\@object .align 256 AES_Td: ___ &_data_word( 0x51f4a750, 0x7e416553, 0x1a17a4c3, 0x3a275e96, 0x3bab6bcb, 0x1f9d45f1, 0xacfa58ab, 0x4be30393, 0x2030fa55, 0xad766df6, 0x88cc7691, 0xf5024c25, 0x4fe5d7fc, 0xc52acbd7, 0x26354480, 0xb562a38f, 0xdeb15a49, 0x25ba1b67, 0x45ea0e98, 0x5dfec0e1, 0xc32f7502, 0x814cf012, 0x8d4697a3, 0x6bd3f9c6, 0x038f5fe7, 0x15929c95, 0xbf6d7aeb, 0x955259da, 0xd4be832d, 0x587421d3, 0x49e06929, 0x8ec9c844, 0x75c2896a, 0xf48e7978, 0x99583e6b, 0x27b971dd, 0xbee14fb6, 0xf088ad17, 0xc920ac66, 0x7dce3ab4, 0x63df4a18, 0xe51a3182, 0x97513360, 0x62537f45, 0xb16477e0, 0xbb6bae84, 0xfe81a01c, 0xf9082b94, 0x70486858, 0x8f45fd19, 0x94de6c87, 0x527bf8b7, 0xab73d323, 0x724b02e2, 0xe31f8f57, 0x6655ab2a, 0xb2eb2807, 0x2fb5c203, 0x86c57b9a, 0xd33708a5, 0x302887f2, 0x23bfa5b2, 0x02036aba, 0xed16825c, 0x8acf1c2b, 0xa779b492, 0xf307f2f0, 0x4e69e2a1, 0x65daf4cd, 0x0605bed5, 0xd134621f, 0xc4a6fe8a, 0x342e539d, 0xa2f355a0, 0x058ae132, 0xa4f6eb75, 0x0b83ec39, 0x4060efaa, 0x5e719f06, 0xbd6e1051, 0x3e218af9, 0x96dd063d, 0xdd3e05ae, 0x4de6bd46, 0x91548db5, 0x71c45d05, 0x0406d46f, 0x605015ff, 0x1998fb24, 0xd6bde997, 0x894043cc, 0x67d99e77, 0xb0e842bd, 0x07898b88, 0xe7195b38, 0x79c8eedb, 0xa17c0a47, 0x7c420fe9, 0xf8841ec9, 0x00000000, 0x09808683, 0x322bed48, 0x1e1170ac, 0x6c5a724e, 0xfd0efffb, 0x0f853856, 0x3daed51e, 0x362d3927, 0x0a0fd964, 0x685ca621, 0x9b5b54d1, 0x24362e3a, 0x0c0a67b1, 0x9357e70f, 0xb4ee96d2, 0x1b9b919e, 0x80c0c54f, 0x61dc20a2, 0x5a774b69, 0x1c121a16, 0xe293ba0a, 0xc0a02ae5, 0x3c22e043, 0x121b171d, 0x0e090d0b, 0xf28bc7ad, 0x2db6a8b9, 0x141ea9c8, 0x57f11985, 0xaf75074c, 0xee99ddbb, 0xa37f60fd, 0xf701269f, 0x5c72f5bc, 0x44663bc5, 0x5bfb7e34, 0x8b432976, 0xcb23c6dc, 0xb6edfc68, 0xb8e4f163, 0xd731dcca, 0x42638510, 0x13972240, 0x84c61120, 0x854a247d, 0xd2bb3df8, 0xaef93211, 0xc729a16d, 0x1d9e2f4b, 0xdcb230f3, 0x0d8652ec, 0x77c1e3d0, 0x2bb3166c, 0xa970b999, 0x119448fa, 0x47e96422, 0xa8fc8cc4, 0xa0f03f1a, 0x567d2cd8, 0x223390ef, 0x87494ec7, 0xd938d1c1, 0x8ccaa2fe, 0x98d40b36, 0xa6f581cf, 0xa57ade28, 0xdab78e26, 0x3fadbfa4, 0x2c3a9de4, 0x5078920d, 0x6a5fcc9b, 0x547e4662, 0xf68d13c2, 0x90d8b8e8, 0x2e39f75e, 0x82c3aff5, 0x9f5d80be, 0x69d0937c, 0x6fd52da9, 0xcf2512b3, 0xc8ac993b, 0x10187da7, 0xe89c636e, 0xdb3bbb7b, 0xcd267809, 0x6e5918f4, 0xec9ab701, 0x834f9aa8, 0xe6956e65, 0xaaffe67e, 0x21bccf08, 0xef15e8e6, 0xbae79bd9, 0x4a6f36ce, 0xea9f09d4, 0x29b07cd6, 0x31a4b2af, 0x2a3f2331, 0xc6a59430, 0x35a266c0, 0x744ebc37, 0xfc82caa6, 0xe090d0b0, 0x33a7d815, 0xf104984a, 0x41ecdaf7, 0x7fcd500e, 0x1791f62f, 0x764dd68d, 0x43efb04d, 0xccaa4d54, 0xe49604df, 0x9ed1b5e3, 0x4c6a881b, 0xc12c1fb8, 0x4665517f, 0x9d5eea04, 0x018c355d, 0xfa877473, 0xfb0b412e, 0xb3671d5a, 0x92dbd252, 0xe9105633, 0x6dd64713, 0x9ad7618c, 0x37a10c7a, 0x59f8148e, 0xeb133c89, 0xcea927ee, 0xb761c935, 0xe11ce5ed, 0x7a47b13c, 0x9cd2df59, 0x55f2733f, 0x1814ce79, 0x73c737bf, 0x53f7cdea, 0x5ffdaa5b, 0xdf3d6f14, 0x7844db86, 0xcaaff381, 0xb968c43e, 0x3824342c, 0xc2a3405f, 0x161dc372, 0xbce2250c, 0x283c498b, 0xff0d9541, 0x39a80171, 0x080cb3de, 0xd8b4e49c, 0x6456c190, 0x7bcb8461, 0xd532b670, 0x486c5c74, 0xd0b85742); $code.=<<___; # Td4[256] .byte 0x52, 0x09, 0x6a, 0xd5, 0x30, 0x36, 0xa5, 0x38 .byte 0xbf, 0x40, 0xa3, 0x9e, 0x81, 0xf3, 0xd7, 0xfb .byte 0x7c, 0xe3, 0x39, 0x82, 0x9b, 0x2f, 0xff, 0x87 .byte 0x34, 0x8e, 0x43, 0x44, 0xc4, 0xde, 0xe9, 0xcb .byte 0x54, 0x7b, 0x94, 0x32, 0xa6, 0xc2, 0x23, 0x3d .byte 0xee, 0x4c, 0x95, 0x0b, 0x42, 0xfa, 0xc3, 0x4e .byte 0x08, 0x2e, 0xa1, 0x66, 0x28, 0xd9, 0x24, 0xb2 .byte 0x76, 0x5b, 0xa2, 0x49, 0x6d, 0x8b, 0xd1, 0x25 .byte 0x72, 0xf8, 0xf6, 0x64, 0x86, 0x68, 0x98, 0x16 .byte 0xd4, 0xa4, 0x5c, 0xcc, 0x5d, 0x65, 0xb6, 0x92 .byte 0x6c, 0x70, 0x48, 0x50, 0xfd, 0xed, 0xb9, 0xda .byte 0x5e, 0x15, 0x46, 0x57, 0xa7, 0x8d, 0x9d, 0x84 .byte 0x90, 0xd8, 0xab, 0x00, 0x8c, 0xbc, 0xd3, 0x0a .byte 0xf7, 0xe4, 0x58, 0x05, 0xb8, 0xb3, 0x45, 0x06 .byte 0xd0, 0x2c, 0x1e, 0x8f, 0xca, 0x3f, 0x0f, 0x02 .byte 0xc1, 0xaf, 0xbd, 0x03, 0x01, 0x13, 0x8a, 0x6b .byte 0x3a, 0x91, 0x11, 0x41, 0x4f, 0x67, 0xdc, 0xea .byte 0x97, 0xf2, 0xcf, 0xce, 0xf0, 0xb4, 0xe6, 0x73 .byte 0x96, 0xac, 0x74, 0x22, 0xe7, 0xad, 0x35, 0x85 .byte 0xe2, 0xf9, 0x37, 0xe8, 0x1c, 0x75, 0xdf, 0x6e .byte 0x47, 0xf1, 0x1a, 0x71, 0x1d, 0x29, 0xc5, 0x89 .byte 0x6f, 0xb7, 0x62, 0x0e, 0xaa, 0x18, 0xbe, 0x1b .byte 0xfc, 0x56, 0x3e, 0x4b, 0xc6, 0xd2, 0x79, 0x20 .byte 0x9a, 0xdb, 0xc0, 0xfe, 0x78, 0xcd, 0x5a, 0xf4 .byte 0x1f, 0xdd, 0xa8, 0x33, 0x88, 0x07, 0xc7, 0x31 .byte 0xb1, 0x12, 0x10, 0x59, 0x27, 0x80, 0xec, 0x5f .byte 0x60, 0x51, 0x7f, 0xa9, 0x19, 0xb5, 0x4a, 0x0d .byte 0x2d, 0xe5, 0x7a, 0x9f, 0x93, 0xc9, 0x9c, 0xef .byte 0xa0, 0xe0, 0x3b, 0x4d, 0xae, 0x2a, 0xf5, 0xb0 .byte 0xc8, 0xeb, 0xbb, 0x3c, 0x83, 0x53, 0x99, 0x61 .byte 0x17, 0x2b, 0x04, 0x7e, 0xba, 0x77, 0xd6, 0x26 .byte 0xe1, 0x69, 0x14, 0x63, 0x55, 0x21, 0x0c, 0x7d .size AES_Td,.-AES_Td # void AES_decrypt(const unsigned char *inp, unsigned char *out, # const AES_KEY *key) { .globl AES_decrypt .type AES_decrypt,\@function AES_decrypt: ___ $code.=<<___ if (!$softonly); l %r0,240($key) lhi %r1,16 clr %r0,%r1 jl .Ldsoft la %r1,0($key) #la %r2,0($inp) la %r4,0($out) lghi %r3,16 # single block length .long 0xb92e0042 # km %r4,%r2 brc 1,.-4 # can this happen? br %r14 .align 64 .Ldsoft: ___ $code.=<<___; stm${g} %r3,$ra,3*$SIZE_T($sp) llgf $s0,0($inp) llgf $s1,4($inp) llgf $s2,8($inp) llgf $s3,12($inp) larl $tbl,AES_Td bras $ra,_s390x_AES_decrypt l${g} $out,3*$SIZE_T($sp) st $s0,0($out) st $s1,4($out) st $s2,8($out) st $s3,12($out) lm${g} %r6,$ra,6*$SIZE_T($sp) br $ra .size AES_decrypt,.-AES_decrypt .type _s390x_AES_decrypt,\@function .align 16 _s390x_AES_decrypt: st${g} $ra,15*$SIZE_T($sp) x $s0,0($key) x $s1,4($key) x $s2,8($key) x $s3,12($key) l $rounds,240($key) llill $mask,`0xff<<3` aghi $rounds,-1 j .Ldec_loop .align 16 .Ldec_loop: srlg $t1,$s0,`16-3` srlg $t2,$s0,`8-3` sllg $t3,$s0,`0+3` srl $s0,`24-3` nr $s0,$mask nr $t1,$mask nr $t2,$mask ngr $t3,$mask sllg $i1,$s1,`0+3` # i0 srlg $i2,$s1,`16-3` srlg $i3,$s1,`8-3` srl $s1,`24-3` ngr $i1,$mask nr $s1,$mask nr $i2,$mask nr $i3,$mask l $s0,0($s0,$tbl) # Td0[s0>>24] l $t1,3($t1,$tbl) # Td1[s0>>16] l $t2,2($t2,$tbl) # Td2[s0>>8] l $t3,1($t3,$tbl) # Td3[s0>>0] x $s0,1($i1,$tbl) # Td3[s1>>0] l $s1,0($s1,$tbl) # Td0[s1>>24] x $t2,3($i2,$tbl) # Td1[s1>>16] x $t3,2($i3,$tbl) # Td2[s1>>8] srlg $i1,$s2,`8-3` # i0 sllg $i2,$s2,`0+3` # i1 srlg $i3,$s2,`16-3` srl $s2,`24-3` nr $i1,$mask ngr $i2,$mask nr $s2,$mask nr $i3,$mask xr $s1,$t1 srlg $ra,$s3,`8-3` # i1 srlg $t1,$s3,`16-3` # i0 nr $ra,$mask la $key,16($key) nr $t1,$mask x $s0,2($i1,$tbl) # Td2[s2>>8] x $s1,1($i2,$tbl) # Td3[s2>>0] l $s2,0($s2,$tbl) # Td0[s2>>24] x $t3,3($i3,$tbl) # Td1[s2>>16] sllg $i3,$s3,`0+3` # i2 srl $s3,`24-3` ngr $i3,$mask nr $s3,$mask xr $s2,$t2 x $s0,0($key) x $s1,4($key) x $s2,8($key) x $t3,12($key) x $s0,3($t1,$tbl) # Td1[s3>>16] x $s1,2($ra,$tbl) # Td2[s3>>8] x $s2,1($i3,$tbl) # Td3[s3>>0] l $s3,0($s3,$tbl) # Td0[s3>>24] xr $s3,$t3 brct $rounds,.Ldec_loop .align 16 l $t1,`2048+0`($tbl) # prefetch Td4 l $t2,`2048+64`($tbl) l $t3,`2048+128`($tbl) l $i1,`2048+192`($tbl) llill $mask,0xff srlg $i3,$s0,24 # i0 srlg $t1,$s0,16 srlg $t2,$s0,8 nr $s0,$mask # i3 nr $t1,$mask srlg $i1,$s1,24 nr $t2,$mask srlg $i2,$s1,16 srlg $ra,$s1,8 nr $s1,$mask # i0 nr $i2,$mask nr $ra,$mask llgc $i3,2048($i3,$tbl) # Td4[s0>>24] llgc $t1,2048($t1,$tbl) # Td4[s0>>16] llgc $t2,2048($t2,$tbl) # Td4[s0>>8] sll $t1,16 llgc $t3,2048($s0,$tbl) # Td4[s0>>0] sllg $s0,$i3,24 sll $t2,8 llgc $s1,2048($s1,$tbl) # Td4[s1>>0] llgc $i1,2048($i1,$tbl) # Td4[s1>>24] llgc $i2,2048($i2,$tbl) # Td4[s1>>16] sll $i1,24 llgc $i3,2048($ra,$tbl) # Td4[s1>>8] sll $i2,16 sll $i3,8 or $s0,$s1 or $t1,$i1 or $t2,$i2 or $t3,$i3 srlg $i1,$s2,8 # i0 srlg $i2,$s2,24 srlg $i3,$s2,16 nr $s2,$mask # i1 nr $i1,$mask nr $i3,$mask llgc $i1,2048($i1,$tbl) # Td4[s2>>8] llgc $s1,2048($s2,$tbl) # Td4[s2>>0] llgc $i2,2048($i2,$tbl) # Td4[s2>>24] llgc $i3,2048($i3,$tbl) # Td4[s2>>16] sll $i1,8 sll $i2,24 or $s0,$i1 sll $i3,16 or $t2,$i2 or $t3,$i3 srlg $i1,$s3,16 # i0 srlg $i2,$s3,8 # i1 srlg $i3,$s3,24 nr $s3,$mask # i2 nr $i1,$mask nr $i2,$mask l${g} $ra,15*$SIZE_T($sp) or $s1,$t1 l $t0,16($key) l $t1,20($key) llgc $i1,2048($i1,$tbl) # Td4[s3>>16] llgc $i2,2048($i2,$tbl) # Td4[s3>>8] sll $i1,16 llgc $s2,2048($s3,$tbl) # Td4[s3>>0] llgc $s3,2048($i3,$tbl) # Td4[s3>>24] sll $i2,8 sll $s3,24 or $s0,$i1 or $s1,$i2 or $s2,$t2 or $s3,$t3 xr $s0,$t0 xr $s1,$t1 x $s2,24($key) x $s3,28($key) br $ra .size _s390x_AES_decrypt,.-_s390x_AES_decrypt ___ $code.=<<___; # void AES_set_encrypt_key(const unsigned char *in, int bits, # AES_KEY *key) { .globl AES_set_encrypt_key .type AES_set_encrypt_key,\@function .align 16 AES_set_encrypt_key: _s390x_AES_set_encrypt_key: lghi $t0,0 cl${g}r $inp,$t0 je .Lminus1 cl${g}r $key,$t0 je .Lminus1 lghi $t0,128 clr $bits,$t0 je .Lproceed lghi $t0,192 clr $bits,$t0 je .Lproceed lghi $t0,256 clr $bits,$t0 je .Lproceed lghi %r2,-2 br %r14 .align 16 .Lproceed: ___ $code.=<<___ if (!$softonly); # convert bits to km(c) code, [128,192,256]->[18,19,20] lhi %r5,-128 lhi %r0,18 ar %r5,$bits srl %r5,6 ar %r5,%r0 larl %r1,OPENSSL_s390xcap_P llihh %r0,0x8000 srlg %r0,%r0,0(%r5) ng %r0,S390X_KM(%r1) # check availability of both km... ng %r0,S390X_KMC(%r1) # ...and kmc support for given key length jz .Lekey_internal lmg %r0,%r1,0($inp) # just copy 128 bits... stmg %r0,%r1,0($key) lhi %r0,192 cr $bits,%r0 jl 1f lg %r1,16($inp) stg %r1,16($key) je 1f lg %r1,24($inp) stg %r1,24($key) 1: st $bits,236($key) # save bits [for debugging purposes] lgr $t0,%r5 st %r5,240($key) # save km(c) code lghi %r2,0 br %r14 ___ $code.=<<___; .align 16 .Lekey_internal: stm${g} %r4,%r13,4*$SIZE_T($sp) # all non-volatile regs and $key larl $tbl,AES_Te+2048 llgf $s0,0($inp) llgf $s1,4($inp) llgf $s2,8($inp) llgf $s3,12($inp) st $s0,0($key) st $s1,4($key) st $s2,8($key) st $s3,12($key) lghi $t0,128 cr $bits,$t0 jne .Lnot128 llill $mask,0xff lghi $t3,0 # i=0 lghi $rounds,10 st $rounds,240($key) llgfr $t2,$s3 # temp=rk[3] srlg $i1,$s3,8 srlg $i2,$s3,16 srlg $i3,$s3,24 nr $t2,$mask nr $i1,$mask nr $i2,$mask .align 16 .L128_loop: la $t2,0($t2,$tbl) la $i1,0($i1,$tbl) la $i2,0($i2,$tbl) la $i3,0($i3,$tbl) icm $t2,2,0($t2) # Te4[rk[3]>>0]<<8 icm $t2,4,0($i1) # Te4[rk[3]>>8]<<16 icm $t2,8,0($i2) # Te4[rk[3]>>16]<<24 icm $t2,1,0($i3) # Te4[rk[3]>>24] x $t2,256($t3,$tbl) # rcon[i] xr $s0,$t2 # rk[4]=rk[0]^... xr $s1,$s0 # rk[5]=rk[1]^rk[4] xr $s2,$s1 # rk[6]=rk[2]^rk[5] xr $s3,$s2 # rk[7]=rk[3]^rk[6] llgfr $t2,$s3 # temp=rk[3] srlg $i1,$s3,8 srlg $i2,$s3,16 nr $t2,$mask nr $i1,$mask srlg $i3,$s3,24 nr $i2,$mask st $s0,16($key) st $s1,20($key) st $s2,24($key) st $s3,28($key) la $key,16($key) # key+=4 la $t3,4($t3) # i++ brct $rounds,.L128_loop lghi $t0,10 lghi %r2,0 lm${g} %r4,%r13,4*$SIZE_T($sp) br $ra .align 16 .Lnot128: llgf $t0,16($inp) llgf $t1,20($inp) st $t0,16($key) st $t1,20($key) lghi $t0,192 cr $bits,$t0 jne .Lnot192 llill $mask,0xff lghi $t3,0 # i=0 lghi $rounds,12 st $rounds,240($key) lghi $rounds,8 srlg $i1,$t1,8 srlg $i2,$t1,16 srlg $i3,$t1,24 nr $t1,$mask nr $i1,$mask nr $i2,$mask .align 16 .L192_loop: la $t1,0($t1,$tbl) la $i1,0($i1,$tbl) la $i2,0($i2,$tbl) la $i3,0($i3,$tbl) icm $t1,2,0($t1) # Te4[rk[5]>>0]<<8 icm $t1,4,0($i1) # Te4[rk[5]>>8]<<16 icm $t1,8,0($i2) # Te4[rk[5]>>16]<<24 icm $t1,1,0($i3) # Te4[rk[5]>>24] x $t1,256($t3,$tbl) # rcon[i] xr $s0,$t1 # rk[6]=rk[0]^... xr $s1,$s0 # rk[7]=rk[1]^rk[6] xr $s2,$s1 # rk[8]=rk[2]^rk[7] xr $s3,$s2 # rk[9]=rk[3]^rk[8] st $s0,24($key) st $s1,28($key) st $s2,32($key) st $s3,36($key) brct $rounds,.L192_continue lghi $t0,12 lghi %r2,0 lm${g} %r4,%r13,4*$SIZE_T($sp) br $ra .align 16 .L192_continue: lgr $t1,$s3 x $t1,16($key) # rk[10]=rk[4]^rk[9] st $t1,40($key) x $t1,20($key) # rk[11]=rk[5]^rk[10] st $t1,44($key) srlg $i1,$t1,8 srlg $i2,$t1,16 srlg $i3,$t1,24 nr $t1,$mask nr $i1,$mask nr $i2,$mask la $key,24($key) # key+=6 la $t3,4($t3) # i++ j .L192_loop .align 16 .Lnot192: llgf $t0,24($inp) llgf $t1,28($inp) st $t0,24($key) st $t1,28($key) llill $mask,0xff lghi $t3,0 # i=0 lghi $rounds,14 st $rounds,240($key) lghi $rounds,7 srlg $i1,$t1,8 srlg $i2,$t1,16 srlg $i3,$t1,24 nr $t1,$mask nr $i1,$mask nr $i2,$mask .align 16 .L256_loop: la $t1,0($t1,$tbl) la $i1,0($i1,$tbl) la $i2,0($i2,$tbl) la $i3,0($i3,$tbl) icm $t1,2,0($t1) # Te4[rk[7]>>0]<<8 icm $t1,4,0($i1) # Te4[rk[7]>>8]<<16 icm $t1,8,0($i2) # Te4[rk[7]>>16]<<24 icm $t1,1,0($i3) # Te4[rk[7]>>24] x $t1,256($t3,$tbl) # rcon[i] xr $s0,$t1 # rk[8]=rk[0]^... xr $s1,$s0 # rk[9]=rk[1]^rk[8] xr $s2,$s1 # rk[10]=rk[2]^rk[9] xr $s3,$s2 # rk[11]=rk[3]^rk[10] st $s0,32($key) st $s1,36($key) st $s2,40($key) st $s3,44($key) brct $rounds,.L256_continue lghi $t0,14 lghi %r2,0 lm${g} %r4,%r13,4*$SIZE_T($sp) br $ra .align 16 .L256_continue: lgr $t1,$s3 # temp=rk[11] srlg $i1,$s3,8 srlg $i2,$s3,16 srlg $i3,$s3,24 nr $t1,$mask nr $i1,$mask nr $i2,$mask la $t1,0($t1,$tbl) la $i1,0($i1,$tbl) la $i2,0($i2,$tbl) la $i3,0($i3,$tbl) llgc $t1,0($t1) # Te4[rk[11]>>0] icm $t1,2,0($i1) # Te4[rk[11]>>8]<<8 icm $t1,4,0($i2) # Te4[rk[11]>>16]<<16 icm $t1,8,0($i3) # Te4[rk[11]>>24]<<24 x $t1,16($key) # rk[12]=rk[4]^... st $t1,48($key) x $t1,20($key) # rk[13]=rk[5]^rk[12] st $t1,52($key) x $t1,24($key) # rk[14]=rk[6]^rk[13] st $t1,56($key) x $t1,28($key) # rk[15]=rk[7]^rk[14] st $t1,60($key) srlg $i1,$t1,8 srlg $i2,$t1,16 srlg $i3,$t1,24 nr $t1,$mask nr $i1,$mask nr $i2,$mask la $key,32($key) # key+=8 la $t3,4($t3) # i++ j .L256_loop .Lminus1: lghi %r2,-1 br $ra .size AES_set_encrypt_key,.-AES_set_encrypt_key # void AES_set_decrypt_key(const unsigned char *in, int bits, # AES_KEY *key) { .globl AES_set_decrypt_key .type AES_set_decrypt_key,\@function .align 16 AES_set_decrypt_key: #st${g} $key,4*$SIZE_T($sp) # I rely on AES_set_encrypt_key to st${g} $ra,14*$SIZE_T($sp) # save non-volatile registers and $key! bras $ra,_s390x_AES_set_encrypt_key #l${g} $key,4*$SIZE_T($sp) l${g} $ra,14*$SIZE_T($sp) ltgr %r2,%r2 bnzr $ra ___ $code.=<<___ if (!$softonly); #l $t0,240($key) lhi $t1,16 cr $t0,$t1 jl .Lgo oill $t0,0x80 # set "decrypt" bit st $t0,240($key) br $ra ___ $code.=<<___; .align 16 .Lgo: lgr $rounds,$t0 #llgf $rounds,240($key) la $i1,0($key) sllg $i2,$rounds,4 la $i2,0($i2,$key) srl $rounds,1 lghi $t1,-16 .align 16 .Linv: lmg $s0,$s1,0($i1) lmg $s2,$s3,0($i2) stmg $s0,$s1,0($i2) stmg $s2,$s3,0($i1) la $i1,16($i1) la $i2,0($t1,$i2) brct $rounds,.Linv ___ $mask80=$i1; $mask1b=$i2; $maskfe=$i3; $code.=<<___; llgf $rounds,240($key) aghi $rounds,-1 sll $rounds,2 # (rounds-1)*4 llilh $mask80,0x8080 llilh $mask1b,0x1b1b llilh $maskfe,0xfefe oill $mask80,0x8080 oill $mask1b,0x1b1b oill $maskfe,0xfefe .align 16 .Lmix: l $s0,16($key) # tp1 lr $s1,$s0 ngr $s1,$mask80 srlg $t1,$s1,7 slr $s1,$t1 nr $s1,$mask1b sllg $t1,$s0,1 nr $t1,$maskfe xr $s1,$t1 # tp2 lr $s2,$s1 ngr $s2,$mask80 srlg $t1,$s2,7 slr $s2,$t1 nr $s2,$mask1b sllg $t1,$s1,1 nr $t1,$maskfe xr $s2,$t1 # tp4 lr $s3,$s2 ngr $s3,$mask80 srlg $t1,$s3,7 slr $s3,$t1 nr $s3,$mask1b sllg $t1,$s2,1 nr $t1,$maskfe xr $s3,$t1 # tp8 xr $s1,$s0 # tp2^tp1 xr $s2,$s0 # tp4^tp1 rll $s0,$s0,24 # = ROTATE(tp1,8) xr $s2,$s3 # ^=tp8 xr $s0,$s1 # ^=tp2^tp1 xr $s1,$s3 # tp2^tp1^tp8 xr $s0,$s2 # ^=tp4^tp1^tp8 rll $s1,$s1,8 rll $s2,$s2,16 xr $s0,$s1 # ^= ROTATE(tp8^tp2^tp1,24) rll $s3,$s3,24 xr $s0,$s2 # ^= ROTATE(tp8^tp4^tp1,16) xr $s0,$s3 # ^= ROTATE(tp8,8) st $s0,16($key) la $key,4($key) brct $rounds,.Lmix lm${g} %r6,%r13,6*$SIZE_T($sp)# as was saved by AES_set_encrypt_key! lghi %r2,0 br $ra .size AES_set_decrypt_key,.-AES_set_decrypt_key ___ ######################################################################## # void AES_cbc_encrypt(const unsigned char *in, unsigned char *out, # size_t length, const AES_KEY *key, # unsigned char *ivec, const int enc) { my $inp="%r2"; my $out="%r4"; # length and out are swapped my $len="%r3"; my $key="%r5"; my $ivp="%r6"; $code.=<<___; .globl AES_cbc_encrypt .type AES_cbc_encrypt,\@function .align 16 AES_cbc_encrypt: xgr %r3,%r4 # flip %r3 and %r4, out and len xgr %r4,%r3 xgr %r3,%r4 ___ $code.=<<___ if (!$softonly); lhi %r0,16 cl %r0,240($key) jh .Lcbc_software lg %r0,0($ivp) # copy ivec lg %r1,8($ivp) stmg %r0,%r1,16($sp) lmg %r0,%r1,0($key) # copy key, cover 256 bit stmg %r0,%r1,32($sp) lmg %r0,%r1,16($key) stmg %r0,%r1,48($sp) l %r0,240($key) # load kmc code lghi $key,15 # res=len%16, len-=res; ngr $key,$len sl${g}r $len,$key la %r1,16($sp) # parameter block - ivec || key jz .Lkmc_truncated .long 0xb92f0042 # kmc %r4,%r2 brc 1,.-4 # pay attention to "partial completion" ltr $key,$key jnz .Lkmc_truncated .Lkmc_done: lmg %r0,%r1,16($sp) # copy ivec to caller stg %r0,0($ivp) stg %r1,8($ivp) br $ra .align 16 .Lkmc_truncated: ahi $key,-1 # it's the way it's encoded in mvc tmll %r0,0x80 jnz .Lkmc_truncated_dec lghi %r1,0 stg %r1,16*$SIZE_T($sp) stg %r1,16*$SIZE_T+8($sp) bras %r1,1f mvc 16*$SIZE_T(1,$sp),0($inp) 1: ex $key,0(%r1) la %r1,16($sp) # restore parameter block la $inp,16*$SIZE_T($sp) lghi $len,16 .long 0xb92f0042 # kmc %r4,%r2 j .Lkmc_done .align 16 .Lkmc_truncated_dec: st${g} $out,4*$SIZE_T($sp) la $out,16*$SIZE_T($sp) lghi $len,16 .long 0xb92f0042 # kmc %r4,%r2 l${g} $out,4*$SIZE_T($sp) bras %r1,2f mvc 0(1,$out),16*$SIZE_T($sp) 2: ex $key,0(%r1) j .Lkmc_done .align 16 .Lcbc_software: ___ $code.=<<___; stm${g} $key,$ra,5*$SIZE_T($sp) lhi %r0,0 cl %r0,`$stdframe+$SIZE_T-4`($sp) je .Lcbc_decrypt larl $tbl,AES_Te llgf $s0,0($ivp) llgf $s1,4($ivp) llgf $s2,8($ivp) llgf $s3,12($ivp) lghi $t0,16 sl${g}r $len,$t0 brc 4,.Lcbc_enc_tail # if borrow .Lcbc_enc_loop: stm${g} $inp,$out,2*$SIZE_T($sp) x $s0,0($inp) x $s1,4($inp) x $s2,8($inp) x $s3,12($inp) lgr %r4,$key bras $ra,_s390x_AES_encrypt lm${g} $inp,$key,2*$SIZE_T($sp) st $s0,0($out) st $s1,4($out) st $s2,8($out) st $s3,12($out) la $inp,16($inp) la $out,16($out) lghi $t0,16 lt${g}r $len,$len jz .Lcbc_enc_done sl${g}r $len,$t0 brc 4,.Lcbc_enc_tail # if borrow j .Lcbc_enc_loop .align 16 .Lcbc_enc_done: l${g} $ivp,6*$SIZE_T($sp) st $s0,0($ivp) st $s1,4($ivp) st $s2,8($ivp) st $s3,12($ivp) lm${g} %r7,$ra,7*$SIZE_T($sp) br $ra .align 16 .Lcbc_enc_tail: aghi $len,15 lghi $t0,0 stg $t0,16*$SIZE_T($sp) stg $t0,16*$SIZE_T+8($sp) bras $t1,3f mvc 16*$SIZE_T(1,$sp),0($inp) 3: ex $len,0($t1) lghi $len,0 la $inp,16*$SIZE_T($sp) j .Lcbc_enc_loop .align 16 .Lcbc_decrypt: larl $tbl,AES_Td lg $t0,0($ivp) lg $t1,8($ivp) stmg $t0,$t1,16*$SIZE_T($sp) .Lcbc_dec_loop: stm${g} $inp,$out,2*$SIZE_T($sp) llgf $s0,0($inp) llgf $s1,4($inp) llgf $s2,8($inp) llgf $s3,12($inp) lgr %r4,$key bras $ra,_s390x_AES_decrypt lm${g} $inp,$key,2*$SIZE_T($sp) sllg $s0,$s0,32 sllg $s2,$s2,32 lr $s0,$s1 lr $s2,$s3 lg $t0,0($inp) lg $t1,8($inp) xg $s0,16*$SIZE_T($sp) xg $s2,16*$SIZE_T+8($sp) lghi $s1,16 sl${g}r $len,$s1 brc 4,.Lcbc_dec_tail # if borrow brc 2,.Lcbc_dec_done # if zero stg $s0,0($out) stg $s2,8($out) stmg $t0,$t1,16*$SIZE_T($sp) la $inp,16($inp) la $out,16($out) j .Lcbc_dec_loop .Lcbc_dec_done: stg $s0,0($out) stg $s2,8($out) .Lcbc_dec_exit: lm${g} %r6,$ra,6*$SIZE_T($sp) stmg $t0,$t1,0($ivp) br $ra .align 16 .Lcbc_dec_tail: aghi $len,15 stg $s0,16*$SIZE_T($sp) stg $s2,16*$SIZE_T+8($sp) bras $s1,4f mvc 0(1,$out),16*$SIZE_T($sp) 4: ex $len,0($s1) j .Lcbc_dec_exit .size AES_cbc_encrypt,.-AES_cbc_encrypt ___ } ######################################################################## # void AES_ctr32_encrypt(const unsigned char *in, unsigned char *out, # size_t blocks, const AES_KEY *key, # const unsigned char *ivec) { my $inp="%r2"; my $out="%r4"; # blocks and out are swapped my $len="%r3"; my $key="%r5"; my $iv0="%r5"; my $ivp="%r6"; my $fp ="%r7"; $code.=<<___; .globl AES_ctr32_encrypt .type AES_ctr32_encrypt,\@function .align 16 AES_ctr32_encrypt: xgr %r3,%r4 # flip %r3 and %r4, $out and $len xgr %r4,%r3 xgr %r3,%r4 llgfr $len,$len # safe in ctr32 subroutine even in 64-bit case ___ $code.=<<___ if (!$softonly); l %r0,240($key) lhi %r1,16 clr %r0,%r1 jl .Lctr32_software stm${g} %r6,$s3,6*$SIZE_T($sp) slgr $out,$inp la %r1,0($key) # %r1 is permanent copy of $key lg $iv0,0($ivp) # load ivec lg $ivp,8($ivp) # prepare and allocate stack frame at the top of 4K page # with 1K reserved for eventual signal handling lghi $s0,-1024-256-16# guarantee at least 256-bytes buffer lghi $s1,-4096 algr $s0,$sp lgr $fp,$sp ngr $s0,$s1 # align at page boundary slgr $fp,$s0 # total buffer size lgr $s2,$sp lghi $s1,1024+16 # sl[g]fi is extended-immediate facility slgr $fp,$s1 # deduct reservation to get usable buffer size # buffer size is at lest 256 and at most 3072+256-16 la $sp,1024($s0) # alloca srlg $fp,$fp,4 # convert bytes to blocks, minimum 16 st${g} $s2,0($sp) # back-chain st${g} $fp,$SIZE_T($sp) slgr $len,$fp brc 1,.Lctr32_hw_switch # not zero, no borrow algr $fp,$len # input is shorter than allocated buffer lghi $len,0 st${g} $fp,$SIZE_T($sp) .Lctr32_hw_switch: ___ $code.=<<___ if (!$softonly && 0);# kmctr code was measured to be ~12% slower llgfr $s0,%r0 lgr $s1,%r1 larl %r1,OPENSSL_s390xcap_P llihh %r0,0x8000 # check if kmctr supports the function code srlg %r0,%r0,0($s0) ng %r0,S390X_KMCTR(%r1) # check kmctr capability vector lgr %r0,$s0 lgr %r1,$s1 jz .Lctr32_km_loop ####### kmctr code algr $out,$inp # restore $out lgr $s1,$len # $s1 undertakes $len j .Lctr32_kmctr_loop .align 16 .Lctr32_kmctr_loop: la $s2,16($sp) lgr $s3,$fp .Lctr32_kmctr_prepare: stg $iv0,0($s2) stg $ivp,8($s2) la $s2,16($s2) ahi $ivp,1 # 32-bit increment, preserves upper half brct $s3,.Lctr32_kmctr_prepare #la $inp,0($inp) # inp sllg $len,$fp,4 # len #la $out,0($out) # out la $s2,16($sp) # iv .long 0xb92da042 # kmctr $out,$s2,$inp brc 1,.-4 # pay attention to "partial completion" slgr $s1,$fp brc 1,.Lctr32_kmctr_loop # not zero, no borrow algr $fp,$s1 lghi $s1,0 brc 4+1,.Lctr32_kmctr_loop # not zero l${g} $sp,0($sp) lm${g} %r6,$s3,6*$SIZE_T($sp) br $ra .align 16 ___ $code.=<<___ if (!$softonly); .Lctr32_km_loop: la $s2,16($sp) lgr $s3,$fp .Lctr32_km_prepare: stg $iv0,0($s2) stg $ivp,8($s2) la $s2,16($s2) ahi $ivp,1 # 32-bit increment, preserves upper half brct $s3,.Lctr32_km_prepare la $s0,16($sp) # inp sllg $s1,$fp,4 # len la $s2,16($sp) # out .long 0xb92e00a8 # km %r10,%r8 brc 1,.-4 # pay attention to "partial completion" la $s2,16($sp) lgr $s3,$fp slgr $s2,$inp .Lctr32_km_xor: lg $s0,0($inp) lg $s1,8($inp) xg $s0,0($s2,$inp) xg $s1,8($s2,$inp) stg $s0,0($out,$inp) stg $s1,8($out,$inp) la $inp,16($inp) brct $s3,.Lctr32_km_xor slgr $len,$fp brc 1,.Lctr32_km_loop # not zero, no borrow algr $fp,$len lghi $len,0 brc 4+1,.Lctr32_km_loop # not zero l${g} $s0,0($sp) l${g} $s1,$SIZE_T($sp) la $s2,16($sp) .Lctr32_km_zap: stg $s0,0($s2) stg $s0,8($s2) la $s2,16($s2) brct $s1,.Lctr32_km_zap la $sp,0($s0) lm${g} %r6,$s3,6*$SIZE_T($sp) br $ra .align 16 .Lctr32_software: ___ $code.=<<___; stm${g} $key,$ra,5*$SIZE_T($sp) sl${g}r $inp,$out larl $tbl,AES_Te llgf $t1,12($ivp) .Lctr32_loop: stm${g} $inp,$out,2*$SIZE_T($sp) llgf $s0,0($ivp) llgf $s1,4($ivp) llgf $s2,8($ivp) lgr $s3,$t1 st $t1,16*$SIZE_T($sp) lgr %r4,$key bras $ra,_s390x_AES_encrypt lm${g} $inp,$ivp,2*$SIZE_T($sp) llgf $t1,16*$SIZE_T($sp) x $s0,0($inp,$out) x $s1,4($inp,$out) x $s2,8($inp,$out) x $s3,12($inp,$out) stm $s0,$s3,0($out) la $out,16($out) ahi $t1,1 # 32-bit increment brct $len,.Lctr32_loop lm${g} %r6,$ra,6*$SIZE_T($sp) br $ra .size AES_ctr32_encrypt,.-AES_ctr32_encrypt ___ } ######################################################################## # void AES_xts_encrypt(const unsigned char *inp, unsigned char *out, # size_t len, const AES_KEY *key1, const AES_KEY *key2, # const unsigned char iv[16]); # { my $inp="%r2"; my $out="%r4"; # len and out are swapped my $len="%r3"; my $key1="%r5"; # $i1 my $key2="%r6"; # $i2 my $fp="%r7"; # $i3 my $tweak=16*$SIZE_T+16; # or $stdframe-16, bottom of the frame... $code.=<<___; .type _s390x_xts_km,\@function .align 16 _s390x_xts_km: ___ $code.=<<___ if(1); llgfr $s0,%r0 # put aside the function code lghi $s1,0x7f nr $s1,%r0 larl %r1,OPENSSL_s390xcap_P llihh %r0,0x8000 srlg %r0,%r0,32($s1) # check for 32+function code ng %r0,S390X_KM(%r1) # check km capability vector lgr %r0,$s0 # restore the function code la %r1,0($key1) # restore $key1 jz .Lxts_km_vanilla lmg $i2,$i3,$tweak($sp) # put aside the tweak value algr $out,$inp oill %r0,32 # switch to xts function code aghi $s1,-18 # sllg $s1,$s1,3 # (function code - 18)*8, 0 or 16 la %r1,$tweak-16($sp) slgr %r1,$s1 # parameter block position lmg $s0,$s3,0($key1) # load 256 bits of key material, stmg $s0,$s3,0(%r1) # and copy it to parameter block. # yes, it contains junk and overlaps # with the tweak in 128-bit case. # it's done to avoid conditional # branch. stmg $i2,$i3,$tweak($sp) # "re-seat" the tweak value .long 0xb92e0042 # km %r4,%r2 brc 1,.-4 # pay attention to "partial completion" lrvg $s0,$tweak+0($sp) # load the last tweak lrvg $s1,$tweak+8($sp) stmg %r0,%r3,$tweak-32($sp) # wipe copy of the key nill %r0,0xffdf # switch back to original function code la %r1,0($key1) # restore pointer to $key1 slgr $out,$inp llgc $len,2*$SIZE_T-1($sp) nill $len,0x0f # $len%=16 br $ra .align 16 .Lxts_km_vanilla: ___ $code.=<<___; # prepare and allocate stack frame at the top of 4K page # with 1K reserved for eventual signal handling lghi $s0,-1024-256-16# guarantee at least 256-bytes buffer lghi $s1,-4096 algr $s0,$sp lgr $fp,$sp ngr $s0,$s1 # align at page boundary slgr $fp,$s0 # total buffer size lgr $s2,$sp lghi $s1,1024+16 # sl[g]fi is extended-immediate facility slgr $fp,$s1 # deduct reservation to get usable buffer size # buffer size is at lest 256 and at most 3072+256-16 la $sp,1024($s0) # alloca nill $fp,0xfff0 # round to 16*n st${g} $s2,0($sp) # back-chain nill $len,0xfff0 # redundant st${g} $fp,$SIZE_T($sp) slgr $len,$fp brc 1,.Lxts_km_go # not zero, no borrow algr $fp,$len # input is shorter than allocated buffer lghi $len,0 st${g} $fp,$SIZE_T($sp) .Lxts_km_go: lrvg $s0,$tweak+0($s2) # load the tweak value in little-endian lrvg $s1,$tweak+8($s2) la $s2,16($sp) # vector of ascending tweak values slgr $s2,$inp srlg $s3,$fp,4 j .Lxts_km_start .Lxts_km_loop: la $s2,16($sp) slgr $s2,$inp srlg $s3,$fp,4 .Lxts_km_prepare: lghi $i1,0x87 srag $i2,$s1,63 # broadcast upper bit ngr $i1,$i2 # rem algr $s0,$s0 alcgr $s1,$s1 xgr $s0,$i1 .Lxts_km_start: lrvgr $i1,$s0 # flip byte order lrvgr $i2,$s1 stg $i1,0($s2,$inp) stg $i2,8($s2,$inp) xg $i1,0($inp) xg $i2,8($inp) stg $i1,0($out,$inp) stg $i2,8($out,$inp) la $inp,16($inp) brct $s3,.Lxts_km_prepare slgr $inp,$fp # rewind $inp la $s2,0($out,$inp) lgr $s3,$fp .long 0xb92e00aa # km $s2,$s2 brc 1,.-4 # pay attention to "partial completion" la $s2,16($sp) slgr $s2,$inp srlg $s3,$fp,4 .Lxts_km_xor: lg $i1,0($out,$inp) lg $i2,8($out,$inp) xg $i1,0($s2,$inp) xg $i2,8($s2,$inp) stg $i1,0($out,$inp) stg $i2,8($out,$inp) la $inp,16($inp) brct $s3,.Lxts_km_xor slgr $len,$fp brc 1,.Lxts_km_loop # not zero, no borrow algr $fp,$len lghi $len,0 brc 4+1,.Lxts_km_loop # not zero l${g} $i1,0($sp) # back-chain llgf $fp,`2*$SIZE_T-4`($sp) # bytes used la $i2,16($sp) srlg $fp,$fp,4 .Lxts_km_zap: stg $i1,0($i2) stg $i1,8($i2) la $i2,16($i2) brct $fp,.Lxts_km_zap la $sp,0($i1) llgc $len,2*$SIZE_T-1($i1) nill $len,0x0f # $len%=16 bzr $ra # generate one more tweak... lghi $i1,0x87 srag $i2,$s1,63 # broadcast upper bit ngr $i1,$i2 # rem algr $s0,$s0 alcgr $s1,$s1 xgr $s0,$i1 ltr $len,$len # clear zero flag br $ra .size _s390x_xts_km,.-_s390x_xts_km .globl AES_xts_encrypt .type AES_xts_encrypt,\@function .align 16 AES_xts_encrypt: xgr %r3,%r4 # flip %r3 and %r4, $out and $len xgr %r4,%r3 xgr %r3,%r4 ___ $code.=<<___ if ($SIZE_T==4); llgfr $len,$len ___ $code.=<<___; st${g} $len,1*$SIZE_T($sp) # save copy of $len srag $len,$len,4 # formally wrong, because it expands # sign byte, but who can afford asking # to process more than 2^63-1 bytes? # I use it, because it sets condition # code... bcr 8,$ra # abort if zero (i.e. less than 16) ___ $code.=<<___ if (!$softonly); llgf %r0,240($key2) lhi %r1,16 clr %r0,%r1 jl .Lxts_enc_software st${g} $ra,5*$SIZE_T($sp) stm${g} %r6,$s3,6*$SIZE_T($sp) sllg $len,$len,4 # $len&=~15 slgr $out,$inp # generate the tweak value l${g} $s3,$stdframe($sp) # pointer to iv la $s2,$tweak($sp) lmg $s0,$s1,0($s3) lghi $s3,16 stmg $s0,$s1,0($s2) la %r1,0($key2) # $key2 is not needed anymore .long 0xb92e00aa # km $s2,$s2, generate the tweak brc 1,.-4 # can this happen? l %r0,240($key1) la %r1,0($key1) # $key1 is not needed anymore bras $ra,_s390x_xts_km jz .Lxts_enc_km_done aghi $inp,-16 # take one step back la $i3,0($out,$inp) # put aside real $out .Lxts_enc_km_steal: llgc $i1,16($inp) llgc $i2,0($out,$inp) stc $i1,0($out,$inp) stc $i2,16($out,$inp) la $inp,1($inp) brct $len,.Lxts_enc_km_steal la $s2,0($i3) lghi $s3,16 lrvgr $i1,$s0 # flip byte order lrvgr $i2,$s1 xg $i1,0($s2) xg $i2,8($s2) stg $i1,0($s2) stg $i2,8($s2) .long 0xb92e00aa # km $s2,$s2 brc 1,.-4 # can this happen? lrvgr $i1,$s0 # flip byte order lrvgr $i2,$s1 xg $i1,0($i3) xg $i2,8($i3) stg $i1,0($i3) stg $i2,8($i3) .Lxts_enc_km_done: stg $sp,$tweak+0($sp) # wipe tweak stg $sp,$tweak+8($sp) l${g} $ra,5*$SIZE_T($sp) lm${g} %r6,$s3,6*$SIZE_T($sp) br $ra .align 16 .Lxts_enc_software: ___ $code.=<<___; stm${g} %r6,$ra,6*$SIZE_T($sp) slgr $out,$inp l${g} $s3,$stdframe($sp) # ivp llgf $s0,0($s3) # load iv llgf $s1,4($s3) llgf $s2,8($s3) llgf $s3,12($s3) stm${g} %r2,%r5,2*$SIZE_T($sp) la $key,0($key2) larl $tbl,AES_Te bras $ra,_s390x_AES_encrypt # generate the tweak lm${g} %r2,%r5,2*$SIZE_T($sp) stm $s0,$s3,$tweak($sp) # save the tweak j .Lxts_enc_enter .align 16 .Lxts_enc_loop: lrvg $s1,$tweak+0($sp) # load the tweak in little-endian lrvg $s3,$tweak+8($sp) lghi %r1,0x87 srag %r0,$s3,63 # broadcast upper bit ngr %r1,%r0 # rem algr $s1,$s1 alcgr $s3,$s3 xgr $s1,%r1 lrvgr $s1,$s1 # flip byte order lrvgr $s3,$s3 srlg $s0,$s1,32 # smash the tweak to 4x32-bits stg $s1,$tweak+0($sp) # save the tweak llgfr $s1,$s1 srlg $s2,$s3,32 stg $s3,$tweak+8($sp) llgfr $s3,$s3 la $inp,16($inp) # $inp+=16 .Lxts_enc_enter: x $s0,0($inp) # ^=*($inp) x $s1,4($inp) x $s2,8($inp) x $s3,12($inp) stm${g} %r2,%r3,2*$SIZE_T($sp) # only two registers are changing la $key,0($key1) bras $ra,_s390x_AES_encrypt lm${g} %r2,%r5,2*$SIZE_T($sp) x $s0,$tweak+0($sp) # ^=tweak x $s1,$tweak+4($sp) x $s2,$tweak+8($sp) x $s3,$tweak+12($sp) st $s0,0($out,$inp) st $s1,4($out,$inp) st $s2,8($out,$inp) st $s3,12($out,$inp) brct${g} $len,.Lxts_enc_loop llgc $len,`2*$SIZE_T-1`($sp) nill $len,0x0f # $len%16 jz .Lxts_enc_done la $i3,0($inp,$out) # put aside real $out .Lxts_enc_steal: llgc %r0,16($inp) llgc %r1,0($out,$inp) stc %r0,0($out,$inp) stc %r1,16($out,$inp) la $inp,1($inp) brct $len,.Lxts_enc_steal la $out,0($i3) # restore real $out # generate last tweak... lrvg $s1,$tweak+0($sp) # load the tweak in little-endian lrvg $s3,$tweak+8($sp) lghi %r1,0x87 srag %r0,$s3,63 # broadcast upper bit ngr %r1,%r0 # rem algr $s1,$s1 alcgr $s3,$s3 xgr $s1,%r1 lrvgr $s1,$s1 # flip byte order lrvgr $s3,$s3 srlg $s0,$s1,32 # smash the tweak to 4x32-bits stg $s1,$tweak+0($sp) # save the tweak llgfr $s1,$s1 srlg $s2,$s3,32 stg $s3,$tweak+8($sp) llgfr $s3,$s3 x $s0,0($out) # ^=*(inp)|stolen cipther-text x $s1,4($out) x $s2,8($out) x $s3,12($out) st${g} $out,4*$SIZE_T($sp) la $key,0($key1) bras $ra,_s390x_AES_encrypt l${g} $out,4*$SIZE_T($sp) x $s0,`$tweak+0`($sp) # ^=tweak x $s1,`$tweak+4`($sp) x $s2,`$tweak+8`($sp) x $s3,`$tweak+12`($sp) st $s0,0($out) st $s1,4($out) st $s2,8($out) st $s3,12($out) .Lxts_enc_done: stg $sp,$tweak+0($sp) # wipe tweak stg $sp,$twesk+8($sp) lm${g} %r6,$ra,6*$SIZE_T($sp) br $ra .size AES_xts_encrypt,.-AES_xts_encrypt ___ # void AES_xts_decrypt(const unsigned char *inp, unsigned char *out, # size_t len, const AES_KEY *key1, const AES_KEY *key2, # const unsigned char iv[16]); # $code.=<<___; .globl AES_xts_decrypt .type AES_xts_decrypt,\@function .align 16 AES_xts_decrypt: xgr %r3,%r4 # flip %r3 and %r4, $out and $len xgr %r4,%r3 xgr %r3,%r4 ___ $code.=<<___ if ($SIZE_T==4); llgfr $len,$len ___ $code.=<<___; st${g} $len,1*$SIZE_T($sp) # save copy of $len aghi $len,-16 bcr 4,$ra # abort if less than zero. formally # wrong, because $len is unsigned, # but who can afford asking to # process more than 2^63-1 bytes? tmll $len,0x0f jnz .Lxts_dec_proceed aghi $len,16 .Lxts_dec_proceed: ___ $code.=<<___ if (!$softonly); llgf %r0,240($key2) lhi %r1,16 clr %r0,%r1 jl .Lxts_dec_software st${g} $ra,5*$SIZE_T($sp) stm${g} %r6,$s3,6*$SIZE_T($sp) nill $len,0xfff0 # $len&=~15 slgr $out,$inp # generate the tweak value l${g} $s3,$stdframe($sp) # pointer to iv la $s2,$tweak($sp) lmg $s0,$s1,0($s3) lghi $s3,16 stmg $s0,$s1,0($s2) la %r1,0($key2) # $key2 is not needed past this point .long 0xb92e00aa # km $s2,$s2, generate the tweak brc 1,.-4 # can this happen? l %r0,240($key1) la %r1,0($key1) # $key1 is not needed anymore ltgr $len,$len jz .Lxts_dec_km_short bras $ra,_s390x_xts_km jz .Lxts_dec_km_done lrvgr $s2,$s0 # make copy in reverse byte order lrvgr $s3,$s1 j .Lxts_dec_km_2ndtweak .Lxts_dec_km_short: llgc $len,`2*$SIZE_T-1`($sp) nill $len,0x0f # $len%=16 lrvg $s0,$tweak+0($sp) # load the tweak lrvg $s1,$tweak+8($sp) lrvgr $s2,$s0 # make copy in reverse byte order lrvgr $s3,$s1 .Lxts_dec_km_2ndtweak: lghi $i1,0x87 srag $i2,$s1,63 # broadcast upper bit ngr $i1,$i2 # rem algr $s0,$s0 alcgr $s1,$s1 xgr $s0,$i1 lrvgr $i1,$s0 # flip byte order lrvgr $i2,$s1 xg $i1,0($inp) xg $i2,8($inp) stg $i1,0($out,$inp) stg $i2,8($out,$inp) la $i2,0($out,$inp) lghi $i3,16 .long 0xb92e0066 # km $i2,$i2 brc 1,.-4 # can this happen? lrvgr $i1,$s0 lrvgr $i2,$s1 xg $i1,0($out,$inp) xg $i2,8($out,$inp) stg $i1,0($out,$inp) stg $i2,8($out,$inp) la $i3,0($out,$inp) # put aside real $out .Lxts_dec_km_steal: llgc $i1,16($inp) llgc $i2,0($out,$inp) stc $i1,0($out,$inp) stc $i2,16($out,$inp) la $inp,1($inp) brct $len,.Lxts_dec_km_steal lgr $s0,$s2 lgr $s1,$s3 xg $s0,0($i3) xg $s1,8($i3) stg $s0,0($i3) stg $s1,8($i3) la $s0,0($i3) lghi $s1,16 .long 0xb92e0088 # km $s0,$s0 brc 1,.-4 # can this happen? xg $s2,0($i3) xg $s3,8($i3) stg $s2,0($i3) stg $s3,8($i3) .Lxts_dec_km_done: stg $sp,$tweak+0($sp) # wipe tweak stg $sp,$tweak+8($sp) l${g} $ra,5*$SIZE_T($sp) lm${g} %r6,$s3,6*$SIZE_T($sp) br $ra .align 16 .Lxts_dec_software: ___ $code.=<<___; stm${g} %r6,$ra,6*$SIZE_T($sp) srlg $len,$len,4 slgr $out,$inp l${g} $s3,$stdframe($sp) # ivp llgf $s0,0($s3) # load iv llgf $s1,4($s3) llgf $s2,8($s3) llgf $s3,12($s3) stm${g} %r2,%r5,2*$SIZE_T($sp) la $key,0($key2) larl $tbl,AES_Te bras $ra,_s390x_AES_encrypt # generate the tweak lm${g} %r2,%r5,2*$SIZE_T($sp) larl $tbl,AES_Td lt${g}r $len,$len stm $s0,$s3,$tweak($sp) # save the tweak jz .Lxts_dec_short j .Lxts_dec_enter .align 16 .Lxts_dec_loop: lrvg $s1,$tweak+0($sp) # load the tweak in little-endian lrvg $s3,$tweak+8($sp) lghi %r1,0x87 srag %r0,$s3,63 # broadcast upper bit ngr %r1,%r0 # rem algr $s1,$s1 alcgr $s3,$s3 xgr $s1,%r1 lrvgr $s1,$s1 # flip byte order lrvgr $s3,$s3 srlg $s0,$s1,32 # smash the tweak to 4x32-bits stg $s1,$tweak+0($sp) # save the tweak llgfr $s1,$s1 srlg $s2,$s3,32 stg $s3,$tweak+8($sp) llgfr $s3,$s3 .Lxts_dec_enter: x $s0,0($inp) # tweak^=*(inp) x $s1,4($inp) x $s2,8($inp) x $s3,12($inp) stm${g} %r2,%r3,2*$SIZE_T($sp) # only two registers are changing la $key,0($key1) bras $ra,_s390x_AES_decrypt lm${g} %r2,%r5,2*$SIZE_T($sp) x $s0,$tweak+0($sp) # ^=tweak x $s1,$tweak+4($sp) x $s2,$tweak+8($sp) x $s3,$tweak+12($sp) st $s0,0($out,$inp) st $s1,4($out,$inp) st $s2,8($out,$inp) st $s3,12($out,$inp) la $inp,16($inp) brct${g} $len,.Lxts_dec_loop llgc $len,`2*$SIZE_T-1`($sp) nill $len,0x0f # $len%16 jz .Lxts_dec_done # generate pair of tweaks... lrvg $s1,$tweak+0($sp) # load the tweak in little-endian lrvg $s3,$tweak+8($sp) lghi %r1,0x87 srag %r0,$s3,63 # broadcast upper bit ngr %r1,%r0 # rem algr $s1,$s1 alcgr $s3,$s3 xgr $s1,%r1 lrvgr $i2,$s1 # flip byte order lrvgr $i3,$s3 stmg $i2,$i3,$tweak($sp) # save the 1st tweak j .Lxts_dec_2ndtweak .align 16 .Lxts_dec_short: llgc $len,`2*$SIZE_T-1`($sp) nill $len,0x0f # $len%16 lrvg $s1,$tweak+0($sp) # load the tweak in little-endian lrvg $s3,$tweak+8($sp) .Lxts_dec_2ndtweak: lghi %r1,0x87 srag %r0,$s3,63 # broadcast upper bit ngr %r1,%r0 # rem algr $s1,$s1 alcgr $s3,$s3 xgr $s1,%r1 lrvgr $s1,$s1 # flip byte order lrvgr $s3,$s3 srlg $s0,$s1,32 # smash the tweak to 4x32-bits stg $s1,$tweak-16+0($sp) # save the 2nd tweak llgfr $s1,$s1 srlg $s2,$s3,32 stg $s3,$tweak-16+8($sp) llgfr $s3,$s3 x $s0,0($inp) # tweak_the_2nd^=*(inp) x $s1,4($inp) x $s2,8($inp) x $s3,12($inp) stm${g} %r2,%r3,2*$SIZE_T($sp) la $key,0($key1) bras $ra,_s390x_AES_decrypt lm${g} %r2,%r5,2*$SIZE_T($sp) x $s0,$tweak-16+0($sp) # ^=tweak_the_2nd x $s1,$tweak-16+4($sp) x $s2,$tweak-16+8($sp) x $s3,$tweak-16+12($sp) st $s0,0($out,$inp) st $s1,4($out,$inp) st $s2,8($out,$inp) st $s3,12($out,$inp) la $i3,0($out,$inp) # put aside real $out .Lxts_dec_steal: llgc %r0,16($inp) llgc %r1,0($out,$inp) stc %r0,0($out,$inp) stc %r1,16($out,$inp) la $inp,1($inp) brct $len,.Lxts_dec_steal la $out,0($i3) # restore real $out lm $s0,$s3,$tweak($sp) # load the 1st tweak x $s0,0($out) # tweak^=*(inp)|stolen cipher-text x $s1,4($out) x $s2,8($out) x $s3,12($out) st${g} $out,4*$SIZE_T($sp) la $key,0($key1) bras $ra,_s390x_AES_decrypt l${g} $out,4*$SIZE_T($sp) x $s0,$tweak+0($sp) # ^=tweak x $s1,$tweak+4($sp) x $s2,$tweak+8($sp) x $s3,$tweak+12($sp) st $s0,0($out) st $s1,4($out) st $s2,8($out) st $s3,12($out) stg $sp,$tweak-16+0($sp) # wipe 2nd tweak stg $sp,$tweak-16+8($sp) .Lxts_dec_done: stg $sp,$tweak+0($sp) # wipe tweak stg $sp,$twesk+8($sp) lm${g} %r6,$ra,6*$SIZE_T($sp) br $ra .size AES_xts_decrypt,.-AES_xts_decrypt ___ } $code.=<<___; .string "AES for s390x, CRYPTOGAMS by " ___ $code =~ s/\`([^\`]*)\`/eval $1/gem; print $code; close STDOUT; # force flush