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git-svn-id: svn://svn.code.sf.net/p/irrlicht/code/trunk@6000 dfc29bdd-3216-0410-991c-e03cc46cb475
462 lines
15 KiB
C++
462 lines
15 KiB
C++
/*
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---------------------------------------------------------------------------
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Copyright (c) 2003, Dr Brian Gladman < >, Worcester, UK.
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All rights reserved.
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LICENSE TERMS
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The free distribution and use of this software in both source and binary
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form is allowed (with or without changes) provided that:
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1. distributions of this source code include the above copyright
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notice, this list of conditions and the following disclaimer;
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2. distributions in binary form include the above copyright
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notice, this list of conditions and the following disclaimer
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in the documentation and/or other associated materials;
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3. the copyright holder's name is not used to endorse products
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built using this software without specific written permission.
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ALTERNATIVELY, provided that this notice is retained in full, this product
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may be distributed under the terms of the GNU General Public License (GPL),
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in which case the provisions of the GPL apply INSTEAD OF those given above.
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DISCLAIMER
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This software is provided 'as is' with no explicit or implied warranties
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in respect of its properties, including, but not limited to, correctness
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and/or fitness for purpose.
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---------------------------------------------------------------------------
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Issue Date: 26/08/2003
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This file contains the code for implementing the key schedule for AES
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(Rijndael) for block and key sizes of 16, 24, and 32 bytes. See aesopt.h
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for further details including optimisation.
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*/
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#include "aesopt.h"
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/* Initialise the key schedule from the user supplied key. The key
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length can be specified in bytes, with legal values of 16, 24
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and 32, or in bits, with legal values of 128, 192 and 256. These
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values correspond with Nk values of 4, 6 and 8 respectively.
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The following macros implement a single cycle in the key
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schedule generation process. The number of cycles needed
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for each cx->n_col and nk value is:
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nk = 4 5 6 7 8
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------------------------------
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cx->n_col = 4 10 9 8 7 7
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cx->n_col = 5 14 11 10 9 9
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cx->n_col = 6 19 15 12 11 11
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cx->n_col = 7 21 19 16 13 14
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cx->n_col = 8 29 23 19 17 14
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*/
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#define ke4(k,i) \
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{ k[4*(i)+4] = ss[0] ^= ls_box(ss[3],3) ^ t_use(r,c)[i]; k[4*(i)+5] = ss[1] ^= ss[0]; \
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k[4*(i)+6] = ss[2] ^= ss[1]; k[4*(i)+7] = ss[3] ^= ss[2]; \
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}
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#define kel4(k,i) \
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{ k[4*(i)+4] = ss[0] ^= ls_box(ss[3],3) ^ t_use(r,c)[i]; k[4*(i)+5] = ss[1] ^= ss[0]; \
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k[4*(i)+6] = ss[2] ^= ss[1]; k[4*(i)+7] = ss[3] ^= ss[2]; \
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}
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#define ke6(k,i) \
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{ k[6*(i)+ 6] = ss[0] ^= ls_box(ss[5],3) ^ t_use(r,c)[i]; k[6*(i)+ 7] = ss[1] ^= ss[0]; \
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k[6*(i)+ 8] = ss[2] ^= ss[1]; k[6*(i)+ 9] = ss[3] ^= ss[2]; \
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k[6*(i)+10] = ss[4] ^= ss[3]; k[6*(i)+11] = ss[5] ^= ss[4]; \
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}
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#define kel6(k,i) \
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{ k[6*(i)+ 6] = ss[0] ^= ls_box(ss[5],3) ^ t_use(r,c)[i]; k[6*(i)+ 7] = ss[1] ^= ss[0]; \
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k[6*(i)+ 8] = ss[2] ^= ss[1]; k[6*(i)+ 9] = ss[3] ^= ss[2]; \
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}
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#define ke8(k,i) \
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{ k[8*(i)+ 8] = ss[0] ^= ls_box(ss[7],3) ^ t_use(r,c)[i]; k[8*(i)+ 9] = ss[1] ^= ss[0]; \
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k[8*(i)+10] = ss[2] ^= ss[1]; k[8*(i)+11] = ss[3] ^= ss[2]; \
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k[8*(i)+12] = ss[4] ^= ls_box(ss[3],0); k[8*(i)+13] = ss[5] ^= ss[4]; \
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k[8*(i)+14] = ss[6] ^= ss[5]; k[8*(i)+15] = ss[7] ^= ss[6]; \
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}
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#define kel8(k,i) \
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{ k[8*(i)+ 8] = ss[0] ^= ls_box(ss[7],3) ^ t_use(r,c)[i]; k[8*(i)+ 9] = ss[1] ^= ss[0]; \
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k[8*(i)+10] = ss[2] ^= ss[1]; k[8*(i)+11] = ss[3] ^= ss[2]; \
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}
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#if defined(ENCRYPTION_KEY_SCHEDULE)
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#if defined(AES_128) || defined(AES_VAR)
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aes_rval aes_encrypt_key128(const void *in_key, aes_encrypt_ctx cx[1])
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{ aes_32t ss[4];
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cx->ks[0] = ss[0] = word_in(in_key, 0);
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cx->ks[1] = ss[1] = word_in(in_key, 1);
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cx->ks[2] = ss[2] = word_in(in_key, 2);
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cx->ks[3] = ss[3] = word_in(in_key, 3);
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#if ENC_UNROLL == NONE
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{ aes_32t i;
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for(i = 0; i < ((11 * N_COLS - 1) / 4); ++i)
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ke4(cx->ks, i);
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}
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#else
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ke4(cx->ks, 0); ke4(cx->ks, 1);
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ke4(cx->ks, 2); ke4(cx->ks, 3);
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ke4(cx->ks, 4); ke4(cx->ks, 5);
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ke4(cx->ks, 6); ke4(cx->ks, 7);
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ke4(cx->ks, 8); kel4(cx->ks, 9);
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#endif
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/* cx->ks[45] ^ cx->ks[52] ^ cx->ks[53] is zero for a 256 bit */
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/* key and must be non-zero for 128 and 192 bits keys */
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cx->ks[53] = cx->ks[45] = 0;
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cx->ks[52] = 10;
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#ifdef AES_ERR_CHK
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return aes_good;
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#endif
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}
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#endif
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#if defined(AES_192) || defined(AES_VAR)
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aes_rval aes_encrypt_key192(const void *in_key, aes_encrypt_ctx cx[1])
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{ aes_32t ss[6];
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cx->ks[0] = ss[0] = word_in(in_key, 0);
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cx->ks[1] = ss[1] = word_in(in_key, 1);
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cx->ks[2] = ss[2] = word_in(in_key, 2);
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cx->ks[3] = ss[3] = word_in(in_key, 3);
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cx->ks[4] = ss[4] = word_in(in_key, 4);
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cx->ks[5] = ss[5] = word_in(in_key, 5);
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#if ENC_UNROLL == NONE
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{ aes_32t i;
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for(i = 0; i < (13 * N_COLS - 1) / 6; ++i)
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ke6(cx->ks, i);
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}
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#else
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ke6(cx->ks, 0); ke6(cx->ks, 1);
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ke6(cx->ks, 2); ke6(cx->ks, 3);
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ke6(cx->ks, 4); ke6(cx->ks, 5);
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ke6(cx->ks, 6); kel6(cx->ks, 7);
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#endif
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/* cx->ks[45] ^ cx->ks[52] ^ cx->ks[53] is zero for a 256 bit */
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/* key and must be non-zero for 128 and 192 bits keys */
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cx->ks[53] = cx->ks[45];
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cx->ks[52] = 12;
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#ifdef AES_ERR_CHK
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return aes_good;
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#endif
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}
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#endif
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#if defined(AES_256) || defined(AES_VAR)
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aes_rval aes_encrypt_key256(const void *in_key, aes_encrypt_ctx cx[1])
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{ aes_32t ss[8];
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cx->ks[0] = ss[0] = word_in(in_key, 0);
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cx->ks[1] = ss[1] = word_in(in_key, 1);
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cx->ks[2] = ss[2] = word_in(in_key, 2);
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cx->ks[3] = ss[3] = word_in(in_key, 3);
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cx->ks[4] = ss[4] = word_in(in_key, 4);
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cx->ks[5] = ss[5] = word_in(in_key, 5);
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cx->ks[6] = ss[6] = word_in(in_key, 6);
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cx->ks[7] = ss[7] = word_in(in_key, 7);
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#if ENC_UNROLL == NONE
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{ aes_32t i;
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for(i = 0; i < (15 * N_COLS - 1) / 8; ++i)
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ke8(cx->ks, i);
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}
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#else
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ke8(cx->ks, 0); ke8(cx->ks, 1);
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ke8(cx->ks, 2); ke8(cx->ks, 3);
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ke8(cx->ks, 4); ke8(cx->ks, 5);
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kel8(cx->ks, 6);
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#endif
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#ifdef AES_ERR_CHK
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return aes_good;
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#endif
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}
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#endif
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#if defined(AES_VAR)
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aes_rval aes_encrypt_key(const void *in_key, int key_len, aes_encrypt_ctx cx[1])
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{
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switch(key_len)
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{
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#ifdef AES_ERR_CHK
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case 16: case 128: return aes_encrypt_key128(in_key, cx);
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case 24: case 192: return aes_encrypt_key192(in_key, cx);
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case 32: case 256: return aes_encrypt_key256(in_key, cx);
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default: return aes_error;
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#else
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case 16: case 128: aes_encrypt_key128(in_key, cx); return;
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case 24: case 192: aes_encrypt_key192(in_key, cx); return;
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case 32: case 256: aes_encrypt_key256(in_key, cx); return;
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#endif
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}
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}
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#endif
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#endif
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#if defined(DECRYPTION_KEY_SCHEDULE)
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#if DEC_ROUND == NO_TABLES
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#define ff(x) (x)
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#else
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#define ff(x) inv_mcol(x)
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#ifdef dec_imvars
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#define d_vars dec_imvars
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#endif
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#endif
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#if 1
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#define kdf4(k,i) \
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{ ss[0] = ss[0] ^ ss[2] ^ ss[1] ^ ss[3]; ss[1] = ss[1] ^ ss[3]; ss[2] = ss[2] ^ ss[3]; ss[3] = ss[3]; \
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ss[4] = ls_box(ss[(i+3) % 4], 3) ^ t_use(r,c)[i]; ss[i % 4] ^= ss[4]; \
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ss[4] ^= k[4*(i)]; k[4*(i)+4] = ff(ss[4]); ss[4] ^= k[4*(i)+1]; k[4*(i)+5] = ff(ss[4]); \
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ss[4] ^= k[4*(i)+2]; k[4*(i)+6] = ff(ss[4]); ss[4] ^= k[4*(i)+3]; k[4*(i)+7] = ff(ss[4]); \
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}
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#define kd4(k,i) \
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{ ss[4] = ls_box(ss[(i+3) % 4], 3) ^ t_use(r,c)[i]; ss[i % 4] ^= ss[4]; ss[4] = ff(ss[4]); \
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k[4*(i)+4] = ss[4] ^= k[4*(i)]; k[4*(i)+5] = ss[4] ^= k[4*(i)+1]; \
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k[4*(i)+6] = ss[4] ^= k[4*(i)+2]; k[4*(i)+7] = ss[4] ^= k[4*(i)+3]; \
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}
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#define kdl4(k,i) \
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{ ss[4] = ls_box(ss[(i+3) % 4], 3) ^ t_use(r,c)[i]; ss[i % 4] ^= ss[4]; \
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k[4*(i)+4] = (ss[0] ^= ss[1]) ^ ss[2] ^ ss[3]; k[4*(i)+5] = ss[1] ^ ss[3]; \
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k[4*(i)+6] = ss[0]; k[4*(i)+7] = ss[1]; \
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}
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#else
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#define kdf4(k,i) \
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{ ss[0] ^= ls_box(ss[3],3) ^ t_use(r,c)[i]; k[4*(i)+ 4] = ff(ss[0]); ss[1] ^= ss[0]; k[4*(i)+ 5] = ff(ss[1]); \
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ss[2] ^= ss[1]; k[4*(i)+ 6] = ff(ss[2]); ss[3] ^= ss[2]; k[4*(i)+ 7] = ff(ss[3]); \
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}
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#define kd4(k,i) \
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{ ss[4] = ls_box(ss[3],3) ^ t_use(r,c)[i]; \
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ss[0] ^= ss[4]; ss[4] = ff(ss[4]); k[4*(i)+ 4] = ss[4] ^= k[4*(i)]; \
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ss[1] ^= ss[0]; k[4*(i)+ 5] = ss[4] ^= k[4*(i)+ 1]; \
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ss[2] ^= ss[1]; k[4*(i)+ 6] = ss[4] ^= k[4*(i)+ 2]; \
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ss[3] ^= ss[2]; k[4*(i)+ 7] = ss[4] ^= k[4*(i)+ 3]; \
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}
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#define kdl4(k,i) \
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{ ss[0] ^= ls_box(ss[3],3) ^ t_use(r,c)[i]; k[4*(i)+ 4] = ss[0]; ss[1] ^= ss[0]; k[4*(i)+ 5] = ss[1]; \
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ss[2] ^= ss[1]; k[4*(i)+ 6] = ss[2]; ss[3] ^= ss[2]; k[4*(i)+ 7] = ss[3]; \
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}
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#endif
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#define kdf6(k,i) \
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{ ss[0] ^= ls_box(ss[5],3) ^ t_use(r,c)[i]; k[6*(i)+ 6] = ff(ss[0]); ss[1] ^= ss[0]; k[6*(i)+ 7] = ff(ss[1]); \
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ss[2] ^= ss[1]; k[6*(i)+ 8] = ff(ss[2]); ss[3] ^= ss[2]; k[6*(i)+ 9] = ff(ss[3]); \
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ss[4] ^= ss[3]; k[6*(i)+10] = ff(ss[4]); ss[5] ^= ss[4]; k[6*(i)+11] = ff(ss[5]); \
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}
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#define kd6(k,i) \
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{ ss[6] = ls_box(ss[5],3) ^ t_use(r,c)[i]; \
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ss[0] ^= ss[6]; ss[6] = ff(ss[6]); k[6*(i)+ 6] = ss[6] ^= k[6*(i)]; \
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ss[1] ^= ss[0]; k[6*(i)+ 7] = ss[6] ^= k[6*(i)+ 1]; \
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ss[2] ^= ss[1]; k[6*(i)+ 8] = ss[6] ^= k[6*(i)+ 2]; \
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ss[3] ^= ss[2]; k[6*(i)+ 9] = ss[6] ^= k[6*(i)+ 3]; \
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ss[4] ^= ss[3]; k[6*(i)+10] = ss[6] ^= k[6*(i)+ 4]; \
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ss[5] ^= ss[4]; k[6*(i)+11] = ss[6] ^= k[6*(i)+ 5]; \
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}
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#define kdl6(k,i) \
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{ ss[0] ^= ls_box(ss[5],3) ^ t_use(r,c)[i]; k[6*(i)+ 6] = ss[0]; ss[1] ^= ss[0]; k[6*(i)+ 7] = ss[1]; \
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ss[2] ^= ss[1]; k[6*(i)+ 8] = ss[2]; ss[3] ^= ss[2]; k[6*(i)+ 9] = ss[3]; \
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}
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#define kdf8(k,i) \
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{ ss[0] ^= ls_box(ss[7],3) ^ t_use(r,c)[i]; k[8*(i)+ 8] = ff(ss[0]); ss[1] ^= ss[0]; k[8*(i)+ 9] = ff(ss[1]); \
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ss[2] ^= ss[1]; k[8*(i)+10] = ff(ss[2]); ss[3] ^= ss[2]; k[8*(i)+11] = ff(ss[3]); \
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ss[4] ^= ls_box(ss[3],0); k[8*(i)+12] = ff(ss[4]); ss[5] ^= ss[4]; k[8*(i)+13] = ff(ss[5]); \
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ss[6] ^= ss[5]; k[8*(i)+14] = ff(ss[6]); ss[7] ^= ss[6]; k[8*(i)+15] = ff(ss[7]); \
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}
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#define kd8(k,i) \
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{ aes_32t g = ls_box(ss[7],3) ^ t_use(r,c)[i]; \
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ss[0] ^= g; g = ff(g); k[8*(i)+ 8] = g ^= k[8*(i)]; \
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ss[1] ^= ss[0]; k[8*(i)+ 9] = g ^= k[8*(i)+ 1]; \
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ss[2] ^= ss[1]; k[8*(i)+10] = g ^= k[8*(i)+ 2]; \
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ss[3] ^= ss[2]; k[8*(i)+11] = g ^= k[8*(i)+ 3]; \
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g = ls_box(ss[3],0); \
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ss[4] ^= g; g = ff(g); k[8*(i)+12] = g ^= k[8*(i)+ 4]; \
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ss[5] ^= ss[4]; k[8*(i)+13] = g ^= k[8*(i)+ 5]; \
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ss[6] ^= ss[5]; k[8*(i)+14] = g ^= k[8*(i)+ 6]; \
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ss[7] ^= ss[6]; k[8*(i)+15] = g ^= k[8*(i)+ 7]; \
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}
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#define kdl8(k,i) \
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{ ss[0] ^= ls_box(ss[7],3) ^ t_use(r,c)[i]; k[8*(i)+ 8] = ss[0]; ss[1] ^= ss[0]; k[8*(i)+ 9] = ss[1]; \
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ss[2] ^= ss[1]; k[8*(i)+10] = ss[2]; ss[3] ^= ss[2]; k[8*(i)+11] = ss[3]; \
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}
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#if defined(AES_128) || defined(AES_VAR)
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aes_rval aes_decrypt_key128(const void *in_key, aes_decrypt_ctx cx[1])
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{ aes_32t ss[5];
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#ifdef d_vars
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d_vars;
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#endif
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cx->ks[0] = ss[0] = word_in(in_key, 0);
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cx->ks[1] = ss[1] = word_in(in_key, 1);
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cx->ks[2] = ss[2] = word_in(in_key, 2);
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cx->ks[3] = ss[3] = word_in(in_key, 3);
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#if DEC_UNROLL == NONE
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{ aes_32t i;
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for(i = 0; i < (11 * N_COLS - 1) / 4; ++i)
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ke4(cx->ks, i);
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#if !(DEC_ROUND == NO_TABLES)
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for(i = N_COLS; i < 10 * N_COLS; ++i)
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cx->ks[i] = inv_mcol(cx->ks[i]);
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#endif
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}
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#else
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kdf4(cx->ks, 0); kd4(cx->ks, 1);
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kd4(cx->ks, 2); kd4(cx->ks, 3);
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kd4(cx->ks, 4); kd4(cx->ks, 5);
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kd4(cx->ks, 6); kd4(cx->ks, 7);
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kd4(cx->ks, 8); kdl4(cx->ks, 9);
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#endif
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/* cx->ks[45] ^ cx->ks[52] ^ cx->ks[53] is zero for a 256 bit */
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/* key and must be non-zero for 128 and 192 bits keys */
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cx->ks[53] = cx->ks[45] = 0;
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cx->ks[52] = 10;
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#ifdef AES_ERR_CHK
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return aes_good;
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#endif
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}
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#endif
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#if defined(AES_192) || defined(AES_VAR)
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aes_rval aes_decrypt_key192(const void *in_key, aes_decrypt_ctx cx[1])
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{ aes_32t ss[7];
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#ifdef d_vars
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d_vars;
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#endif
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cx->ks[0] = ss[0] = word_in(in_key, 0);
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cx->ks[1] = ss[1] = word_in(in_key, 1);
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cx->ks[2] = ss[2] = word_in(in_key, 2);
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cx->ks[3] = ss[3] = word_in(in_key, 3);
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#if DEC_UNROLL == NONE
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cx->ks[4] = ss[4] = word_in(in_key, 4);
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cx->ks[5] = ss[5] = word_in(in_key, 5);
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{ aes_32t i;
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for(i = 0; i < (13 * N_COLS - 1) / 6; ++i)
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ke6(cx->ks, i);
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#if !(DEC_ROUND == NO_TABLES)
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for(i = N_COLS; i < 12 * N_COLS; ++i)
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cx->ks[i] = inv_mcol(cx->ks[i]);
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#endif
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}
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#else
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ss[4] = word_in(in_key, 4);
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cx->ks[4] = ff(ss[4]);
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ss[5] = word_in(in_key, 5);
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|
cx->ks[5] = ff(ss[5]);
|
|
kdf6(cx->ks, 0); kd6(cx->ks, 1);
|
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kd6(cx->ks, 2); kd6(cx->ks, 3);
|
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kd6(cx->ks, 4); kd6(cx->ks, 5);
|
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kd6(cx->ks, 6); kdl6(cx->ks, 7);
|
|
#endif
|
|
|
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/* cx->ks[45] ^ cx->ks[52] ^ cx->ks[53] is zero for a 256 bit */
|
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/* key and must be non-zero for 128 and 192 bits keys */
|
|
cx->ks[53] = cx->ks[45];
|
|
cx->ks[52] = 12;
|
|
#ifdef AES_ERR_CHK
|
|
return aes_good;
|
|
#endif
|
|
}
|
|
|
|
#endif
|
|
|
|
#if defined(AES_256) || defined(AES_VAR)
|
|
|
|
aes_rval aes_decrypt_key256(const void *in_key, aes_decrypt_ctx cx[1])
|
|
{ aes_32t ss[8];
|
|
#ifdef d_vars
|
|
d_vars;
|
|
#endif
|
|
cx->ks[0] = ss[0] = word_in(in_key, 0);
|
|
cx->ks[1] = ss[1] = word_in(in_key, 1);
|
|
cx->ks[2] = ss[2] = word_in(in_key, 2);
|
|
cx->ks[3] = ss[3] = word_in(in_key, 3);
|
|
|
|
#if DEC_UNROLL == NONE
|
|
cx->ks[4] = ss[4] = word_in(in_key, 4);
|
|
cx->ks[5] = ss[5] = word_in(in_key, 5);
|
|
cx->ks[6] = ss[6] = word_in(in_key, 6);
|
|
cx->ks[7] = ss[7] = word_in(in_key, 7);
|
|
{ aes_32t i;
|
|
|
|
for(i = 0; i < (15 * N_COLS - 1) / 8; ++i)
|
|
ke8(cx->ks, i);
|
|
#if !(DEC_ROUND == NO_TABLES)
|
|
for(i = N_COLS; i < 14 * N_COLS; ++i)
|
|
cx->ks[i] = inv_mcol(cx->ks[i]);
|
|
#endif
|
|
}
|
|
#else
|
|
ss[4] = word_in(in_key, 4);
|
|
cx->ks[4] = ff(ss[4]);
|
|
ss[5] = word_in(in_key, 5);
|
|
cx->ks[5] = ff(ss[5]);
|
|
ss[6] = word_in(in_key, 6);
|
|
cx->ks[6] = ff(ss[6]);
|
|
ss[7] = word_in(in_key, 7);
|
|
cx->ks[7] = ff(ss[7]);
|
|
kdf8(cx->ks, 0); kd8(cx->ks, 1);
|
|
kd8(cx->ks, 2); kd8(cx->ks, 3);
|
|
kd8(cx->ks, 4); kd8(cx->ks, 5);
|
|
kdl8(cx->ks, 6);
|
|
#endif
|
|
#ifdef AES_ERR_CHK
|
|
return aes_good;
|
|
#endif
|
|
}
|
|
|
|
#endif
|
|
|
|
#if defined(AES_VAR)
|
|
|
|
aes_rval aes_decrypt_key(const void *in_key, int key_len, aes_decrypt_ctx cx[1])
|
|
{
|
|
switch(key_len)
|
|
{
|
|
#ifdef AES_ERR_CHK
|
|
case 16: case 128: return aes_decrypt_key128(in_key, cx);
|
|
case 24: case 192: return aes_decrypt_key192(in_key, cx);
|
|
case 32: case 256: return aes_decrypt_key256(in_key, cx);
|
|
default: return aes_error;
|
|
#else
|
|
case 16: case 128: aes_decrypt_key128(in_key, cx); return;
|
|
case 24: case 192: aes_decrypt_key192(in_key, cx); return;
|
|
case 32: case 256: aes_decrypt_key256(in_key, cx); return;
|
|
#endif
|
|
}
|
|
}
|
|
|
|
#endif
|
|
|
|
#endif
|
|
|