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nest-open-source / nest-learning-thermostat / 5.1 / libgcrypt / refs/heads/master / . / libgcrypt-1.4.6 / cipher / rijndael.c
blob: d43b349b419be11d089992ae39fb0a7b2722bdeb [file] [log] [blame]
/* Rijndael (AES) for GnuPG
* Copyright (C) 2000, 2001, 2002, 2003, 2007,
* 2008 Free Software Foundation, Inc.
*
* This file is part of Libgcrypt.
*
* Libgcrypt is free software; you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation; either version 2.1 of
* the License, or (at your option) any later version.
*
* Libgcrypt is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this program; if not, see <http://www.gnu.org/licenses/>.
*******************************************************************
* The code here is based on the optimized implementation taken from
* http://www.esat.kuleuven.ac.be/~rijmen/rijndael/ on Oct 2, 2000,
* which carries this notice:
*------------------------------------------
* rijndael-alg-fst.c v2.3 April '2000
*
* Optimised ANSI C code
*
* authors: v1.0: Antoon Bosselaers
* v2.0: Vincent Rijmen
* v2.3: Paulo Barreto
*
* This code is placed in the public domain.
*------------------------------------------
*
* The SP800-38a document is available at:
* http://csrc.nist.gov/publications/nistpubs/800-38a/sp800-38a.pdf
*
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h> /* for memcmp() */
#include "types.h" /* for byte and u32 typedefs */
#include "g10lib.h"
#include "cipher.h"
#define MAXKC (256/32)
#define MAXROUNDS 14
#define BLOCKSIZE (128/8)
/* USE_PADLOCK indicates whether to compile the padlock specific
code. */
#undef USE_PADLOCK
#ifdef ENABLE_PADLOCK_SUPPORT
# if defined (__i386__) && SIZEOF_UNSIGNED_LONG == 4 && defined (__GNUC__)
# define USE_PADLOCK
# endif
#endif /*ENABLE_PADLOCK_SUPPORT*/
static const char *selftest(void);
typedef struct
{
int ROUNDS; /* Key-length-dependent number of rounds. */
int decryption_prepared; /* The decryption key schedule is available. */
#ifdef USE_PADLOCK
int use_padlock; /* Padlock shall be used. */
/* The key as passed to the padlock engine. */
unsigned char padlock_key[16] __attribute__ ((aligned (16)));
#endif
union
{
PROPERLY_ALIGNED_TYPE dummy;
byte keyschedule[MAXROUNDS+1][4][4];
} u1;
union
{
PROPERLY_ALIGNED_TYPE dummy;
byte keyschedule[MAXROUNDS+1][4][4];
} u2;
} RIJNDAEL_context;
#define keySched u1.keyschedule
#define keySched2 u2.keyschedule
/* All the numbers. */
#include "rijndael-tables.h"
/* Perform the key setup. */
static gcry_err_code_t
do_setkey (RIJNDAEL_context *ctx, const byte *key, const unsigned keylen)
{
static int initialized = 0;
static const char *selftest_failed=0;
int ROUNDS;
int i,j, r, t, rconpointer = 0;
int KC;
union
{
PROPERLY_ALIGNED_TYPE dummy;
byte k[MAXKC][4];
} k;
#define k k.k
union
{
PROPERLY_ALIGNED_TYPE dummy;
byte tk[MAXKC][4];
} tk;
#define tk tk.tk
/* The on-the-fly self tests are only run in non-fips mode. In fips
mode explicit self-tests are required. Actually the on-the-fly
self-tests are not fully thread-safe and it might happen that a
failed self-test won't get noticed in another thread.
FIXME: We might want to have a central registry of succeeded
self-tests. */
if (!fips_mode () && !initialized)
{
initialized = 1;
selftest_failed = selftest ();
if (selftest_failed)
log_error ("%s\n", selftest_failed );
}
if (selftest_failed)
return GPG_ERR_SELFTEST_FAILED;
ctx->decryption_prepared = 0;
#ifdef USE_PADLOCK
ctx->use_padlock = 0;
#endif
if( keylen == 128/8 )
{
ROUNDS = 10;
KC = 4;
#ifdef USE_PADLOCK
if ((_gcry_get_hw_features () & HWF_PADLOCK_AES))
{
ctx->use_padlock = 1;
memcpy (ctx->padlock_key, key, keylen);
}
#endif
}
else if ( keylen == 192/8 )
{
ROUNDS = 12;
KC = 6;
}
else if ( keylen == 256/8 )
{
ROUNDS = 14;
KC = 8;
}
else
return GPG_ERR_INV_KEYLEN;
ctx->ROUNDS = ROUNDS;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
{
/* Nothing to do as we support only hardware key generation for
now. */
}
else
#endif /*USE_PADLOCK*/
{
#define W (ctx->keySched)
for (i = 0; i < keylen; i++)
{
k[i >> 2][i & 3] = key[i];
}
for (j = KC-1; j >= 0; j--)
{
*((u32*)tk[j]) = *((u32*)k[j]);
}
r = 0;
t = 0;
/* Copy values into round key array. */
for (j = 0; (j < KC) && (r < ROUNDS + 1); )
{
for (; (j < KC) && (t < 4); j++, t++)
{
*((u32*)W[r][t]) = *((u32*)tk[j]);
}
if (t == 4)
{
r++;
t = 0;
}
}
while (r < ROUNDS + 1)
{
/* While not enough round key material calculated calculate
new values. */
tk[0][0] ^= S[tk[KC-1][1]];
tk[0][1] ^= S[tk[KC-1][2]];
tk[0][2] ^= S[tk[KC-1][3]];
tk[0][3] ^= S[tk[KC-1][0]];
tk[0][0] ^= rcon[rconpointer++];
if (KC != 8)
{
for (j = 1; j < KC; j++)
{
*((u32*)tk[j]) ^= *((u32*)tk[j-1]);
}
}
else
{
for (j = 1; j < KC/2; j++)
{
*((u32*)tk[j]) ^= *((u32*)tk[j-1]);
}
tk[KC/2][0] ^= S[tk[KC/2 - 1][0]];
tk[KC/2][1] ^= S[tk[KC/2 - 1][1]];
tk[KC/2][2] ^= S[tk[KC/2 - 1][2]];
tk[KC/2][3] ^= S[tk[KC/2 - 1][3]];
for (j = KC/2 + 1; j < KC; j++)
{
*((u32*)tk[j]) ^= *((u32*)tk[j-1]);
}
}
/* Copy values into round key array. */
for (j = 0; (j < KC) && (r < ROUNDS + 1); )
{
for (; (j < KC) && (t < 4); j++, t++)
{
*((u32*)W[r][t]) = *((u32*)tk[j]);
}
if (t == 4)
{
r++;
t = 0;
}
}
}
#undef W
}
return 0;
#undef tk
#undef k
}
static gcry_err_code_t
rijndael_setkey (void *context, const byte *key, const unsigned keylen)
{
RIJNDAEL_context *ctx = context;
int rc = do_setkey (ctx, key, keylen);
_gcry_burn_stack ( 100 + 16*sizeof(int));
return rc;
}
/* Make a decryption key from an encryption key. */
static void
prepare_decryption( RIJNDAEL_context *ctx )
{
int r;
union
{
PROPERLY_ALIGNED_TYPE dummy;
byte *w;
} w;
#define w w.w
for (r=0; r < MAXROUNDS+1; r++ )
{
*((u32*)ctx->keySched2[r][0]) = *((u32*)ctx->keySched[r][0]);
*((u32*)ctx->keySched2[r][1]) = *((u32*)ctx->keySched[r][1]);
*((u32*)ctx->keySched2[r][2]) = *((u32*)ctx->keySched[r][2]);
*((u32*)ctx->keySched2[r][3]) = *((u32*)ctx->keySched[r][3]);
}
#define W (ctx->keySched2)
for (r = 1; r < ctx->ROUNDS; r++)
{
w = W[r][0];
*((u32*)w) = *((u32*)U1[w[0]]) ^ *((u32*)U2[w[1]])
^ *((u32*)U3[w[2]]) ^ *((u32*)U4[w[3]]);
w = W[r][1];
*((u32*)w) = *((u32*)U1[w[0]]) ^ *((u32*)U2[w[1]])
^ *((u32*)U3[w[2]]) ^ *((u32*)U4[w[3]]);
w = W[r][2];
*((u32*)w) = *((u32*)U1[w[0]]) ^ *((u32*)U2[w[1]])
^ *((u32*)U3[w[2]]) ^ *((u32*)U4[w[3]]);
w = W[r][3];
*((u32*)w) = *((u32*)U1[w[0]]) ^ *((u32*)U2[w[1]])
^ *((u32*)U3[w[2]]) ^ *((u32*)U4[w[3]]);
}
#undef W
#undef w
}
/* Encrypt one block. A and B need to be aligned on a 4 byte
boundary. A and B may be the same. */
static void
do_encrypt_aligned (const RIJNDAEL_context *ctx,
unsigned char *b, const unsigned char *a)
{
#define rk (ctx->keySched)
int ROUNDS = ctx->ROUNDS;
int r;
union
{
u32 tempu32[4]; /* Force correct alignment. */
byte temp[4][4];
} u;
*((u32*)u.temp[0]) = *((u32*)(a )) ^ *((u32*)rk[0][0]);
*((u32*)u.temp[1]) = *((u32*)(a+ 4)) ^ *((u32*)rk[0][1]);
*((u32*)u.temp[2]) = *((u32*)(a+ 8)) ^ *((u32*)rk[0][2]);
*((u32*)u.temp[3]) = *((u32*)(a+12)) ^ *((u32*)rk[0][3]);
*((u32*)(b )) = (*((u32*)T1[u.temp[0][0]])
^ *((u32*)T2[u.temp[1][1]])
^ *((u32*)T3[u.temp[2][2]])
^ *((u32*)T4[u.temp[3][3]]));
*((u32*)(b + 4)) = (*((u32*)T1[u.temp[1][0]])
^ *((u32*)T2[u.temp[2][1]])
^ *((u32*)T3[u.temp[3][2]])
^ *((u32*)T4[u.temp[0][3]]));
*((u32*)(b + 8)) = (*((u32*)T1[u.temp[2][0]])
^ *((u32*)T2[u.temp[3][1]])
^ *((u32*)T3[u.temp[0][2]])
^ *((u32*)T4[u.temp[1][3]]));
*((u32*)(b +12)) = (*((u32*)T1[u.temp[3][0]])
^ *((u32*)T2[u.temp[0][1]])
^ *((u32*)T3[u.temp[1][2]])
^ *((u32*)T4[u.temp[2][3]]));
for (r = 1; r < ROUNDS-1; r++)
{
*((u32*)u.temp[0]) = *((u32*)(b )) ^ *((u32*)rk[r][0]);
*((u32*)u.temp[1]) = *((u32*)(b+ 4)) ^ *((u32*)rk[r][1]);
*((u32*)u.temp[2]) = *((u32*)(b+ 8)) ^ *((u32*)rk[r][2]);
*((u32*)u.temp[3]) = *((u32*)(b+12)) ^ *((u32*)rk[r][3]);
*((u32*)(b )) = (*((u32*)T1[u.temp[0][0]])
^ *((u32*)T2[u.temp[1][1]])
^ *((u32*)T3[u.temp[2][2]])
^ *((u32*)T4[u.temp[3][3]]));
*((u32*)(b + 4)) = (*((u32*)T1[u.temp[1][0]])
^ *((u32*)T2[u.temp[2][1]])
^ *((u32*)T3[u.temp[3][2]])
^ *((u32*)T4[u.temp[0][3]]));
*((u32*)(b + 8)) = (*((u32*)T1[u.temp[2][0]])
^ *((u32*)T2[u.temp[3][1]])
^ *((u32*)T3[u.temp[0][2]])
^ *((u32*)T4[u.temp[1][3]]));
*((u32*)(b +12)) = (*((u32*)T1[u.temp[3][0]])
^ *((u32*)T2[u.temp[0][1]])
^ *((u32*)T3[u.temp[1][2]])
^ *((u32*)T4[u.temp[2][3]]));
}
/* Last round is special. */
*((u32*)u.temp[0]) = *((u32*)(b )) ^ *((u32*)rk[ROUNDS-1][0]);
*((u32*)u.temp[1]) = *((u32*)(b+ 4)) ^ *((u32*)rk[ROUNDS-1][1]);
*((u32*)u.temp[2]) = *((u32*)(b+ 8)) ^ *((u32*)rk[ROUNDS-1][2]);
*((u32*)u.temp[3]) = *((u32*)(b+12)) ^ *((u32*)rk[ROUNDS-1][3]);
b[ 0] = T1[u.temp[0][0]][1];
b[ 1] = T1[u.temp[1][1]][1];
b[ 2] = T1[u.temp[2][2]][1];
b[ 3] = T1[u.temp[3][3]][1];
b[ 4] = T1[u.temp[1][0]][1];
b[ 5] = T1[u.temp[2][1]][1];
b[ 6] = T1[u.temp[3][2]][1];
b[ 7] = T1[u.temp[0][3]][1];
b[ 8] = T1[u.temp[2][0]][1];
b[ 9] = T1[u.temp[3][1]][1];
b[10] = T1[u.temp[0][2]][1];
b[11] = T1[u.temp[1][3]][1];
b[12] = T1[u.temp[3][0]][1];
b[13] = T1[u.temp[0][1]][1];
b[14] = T1[u.temp[1][2]][1];
b[15] = T1[u.temp[2][3]][1];
*((u32*)(b )) ^= *((u32*)rk[ROUNDS][0]);
*((u32*)(b+ 4)) ^= *((u32*)rk[ROUNDS][1]);
*((u32*)(b+ 8)) ^= *((u32*)rk[ROUNDS][2]);
*((u32*)(b+12)) ^= *((u32*)rk[ROUNDS][3]);
#undef rk
}
static void
do_encrypt (const RIJNDAEL_context *ctx,
unsigned char *bx, const unsigned char *ax)
{
/* BX and AX are not necessary correctly aligned. Thus we need to
copy them here. */
union
{
u32 dummy[4];
byte a[16];
} a;
union
{
u32 dummy[4];
byte b[16];
} b;
memcpy (a.a, ax, 16);
do_encrypt_aligned (ctx, b.b, a.a);
memcpy (bx, b.b, 16);
}
/* Encrypt or decrypt one block using the padlock engine. A and B may
be the same. */
#ifdef USE_PADLOCK
static void
do_padlock (const RIJNDAEL_context *ctx, int decrypt_flag,
unsigned char *bx, const unsigned char *ax)
{
/* BX and AX are not necessary correctly aligned. Thus we need to
copy them here. */
unsigned char a[16] __attribute__ ((aligned (16)));
unsigned char b[16] __attribute__ ((aligned (16)));
unsigned int cword[4] __attribute__ ((aligned (16)));
/* The control word fields are:
127:12 11:10 9 8 7 6 5 4 3:0
RESERVED KSIZE CRYPT INTER KEYGN CIPHR ALIGN DGEST ROUND */
cword[0] = (ctx->ROUNDS & 15); /* (The mask is just a safeguard.) */
cword[1] = 0;
cword[2] = 0;
cword[3] = 0;
if (decrypt_flag)
cword[0] |= 0x00000200;
memcpy (a, ax, 16);
asm volatile
("pushfl\n\t" /* Force key reload. */
"popfl\n\t"
"xchg %3, %%ebx\n\t" /* Load key. */
"movl $1, %%ecx\n\t" /* Init counter for just one block. */
".byte 0xf3, 0x0f, 0xa7, 0xc8\n\t" /* REP XSTORE ECB. */
"xchg %3, %%ebx\n" /* Restore GOT register. */
: /* No output */
: "S" (a), "D" (b), "d" (cword), "r" (ctx->padlock_key)
: "%ecx", "cc", "memory"
);
memcpy (bx, b, 16);
}
#endif /*USE_PADLOCK*/
static void
rijndael_encrypt (void *context, byte *b, const byte *a)
{
RIJNDAEL_context *ctx = context;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
{
do_padlock (ctx, 0, b, a);
_gcry_burn_stack (48 + 15 /* possible padding for alignment */);
}
else
#endif /*USE_PADLOCK*/
{
do_encrypt (ctx, b, a);
_gcry_burn_stack (48 + 2*sizeof(int));
}
}
/* Bulk encryption of complete blocks in CFB mode. Caller needs to
make sure that IV is aligned on an unsigned long boundary. This
function is only intended for the bulk encryption feature of
cipher.c. */
void
_gcry_aes_cfb_enc (void *context, unsigned char *iv,
void *outbuf_arg, const void *inbuf_arg,
unsigned int nblocks)
{
RIJNDAEL_context *ctx = context;
unsigned char *outbuf = outbuf_arg;
const unsigned char *inbuf = inbuf_arg;
unsigned char *ivp;
int i;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
{
/* Fixme: Let Padlock do the CFBing. */
for ( ;nblocks; nblocks-- )
{
/* Encrypt the IV. */
do_padlock (ctx, 0, iv, iv);
/* XOR the input with the IV and store input into IV. */
for (ivp=iv,i=0; i < BLOCKSIZE; i++ )
*outbuf++ = (*ivp++ ^= *inbuf++);
}
}
else
#endif /* USE_PADLOCK*/
{
for ( ;nblocks; nblocks-- )
{
/* Encrypt the IV. */
do_encrypt_aligned (ctx, iv, iv);
/* XOR the input with the IV and store input into IV. */
for (ivp=iv,i=0; i < BLOCKSIZE; i++ )
*outbuf++ = (*ivp++ ^= *inbuf++);
}
}
_gcry_burn_stack (48 + 2*sizeof(int));
}
/* Bulk encryption of complete blocks in CBC mode. Caller needs to
make sure that IV is aligned on an unsigned long boundary. This
function is only intended for the bulk encryption feature of
cipher.c. */
void
_gcry_aes_cbc_enc (void *context, unsigned char *iv,
void *outbuf_arg, const void *inbuf_arg,
unsigned int nblocks, int cbc_mac)
{
RIJNDAEL_context *ctx = context;
unsigned char *outbuf = outbuf_arg;
const unsigned char *inbuf = inbuf_arg;
unsigned char *ivp;
int i;
for ( ;nblocks; nblocks-- )
{
for (ivp=iv, i=0; i < BLOCKSIZE; i++ )
outbuf[i] = inbuf[i] ^ *ivp++;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
do_padlock (ctx, 0, outbuf, outbuf);
else
#endif /*USE_PADLOCK*/
do_encrypt (ctx, outbuf, outbuf );
memcpy (iv, outbuf, BLOCKSIZE);
inbuf += BLOCKSIZE;
if (!cbc_mac)
outbuf += BLOCKSIZE;
}
_gcry_burn_stack (48 + 2*sizeof(int));
}
/* Decrypt one block. A and B need to be aligned on a 4 byte boundary
and the decryption must have been prepared. A and B may be the
same. */
static void
do_decrypt_aligned (RIJNDAEL_context *ctx,
unsigned char *b, const unsigned char *a)
{
#define rk (ctx->keySched2)
int ROUNDS = ctx->ROUNDS;
int r;
union
{
u32 tempu32[4]; /* Force correct alignment. */
byte temp[4][4];
} u;
*((u32*)u.temp[0]) = *((u32*)(a )) ^ *((u32*)rk[ROUNDS][0]);
*((u32*)u.temp[1]) = *((u32*)(a+ 4)) ^ *((u32*)rk[ROUNDS][1]);
*((u32*)u.temp[2]) = *((u32*)(a+ 8)) ^ *((u32*)rk[ROUNDS][2]);
*((u32*)u.temp[3]) = *((u32*)(a+12)) ^ *((u32*)rk[ROUNDS][3]);
*((u32*)(b )) = (*((u32*)T5[u.temp[0][0]])
^ *((u32*)T6[u.temp[3][1]])
^ *((u32*)T7[u.temp[2][2]])
^ *((u32*)T8[u.temp[1][3]]));
*((u32*)(b+ 4)) = (*((u32*)T5[u.temp[1][0]])
^ *((u32*)T6[u.temp[0][1]])
^ *((u32*)T7[u.temp[3][2]])
^ *((u32*)T8[u.temp[2][3]]));
*((u32*)(b+ 8)) = (*((u32*)T5[u.temp[2][0]])
^ *((u32*)T6[u.temp[1][1]])
^ *((u32*)T7[u.temp[0][2]])
^ *((u32*)T8[u.temp[3][3]]));
*((u32*)(b+12)) = (*((u32*)T5[u.temp[3][0]])
^ *((u32*)T6[u.temp[2][1]])
^ *((u32*)T7[u.temp[1][2]])
^ *((u32*)T8[u.temp[0][3]]));
for (r = ROUNDS-1; r > 1; r--)
{
*((u32*)u.temp[0]) = *((u32*)(b )) ^ *((u32*)rk[r][0]);
*((u32*)u.temp[1]) = *((u32*)(b+ 4)) ^ *((u32*)rk[r][1]);
*((u32*)u.temp[2]) = *((u32*)(b+ 8)) ^ *((u32*)rk[r][2]);
*((u32*)u.temp[3]) = *((u32*)(b+12)) ^ *((u32*)rk[r][3]);
*((u32*)(b )) = (*((u32*)T5[u.temp[0][0]])
^ *((u32*)T6[u.temp[3][1]])
^ *((u32*)T7[u.temp[2][2]])
^ *((u32*)T8[u.temp[1][3]]));
*((u32*)(b+ 4)) = (*((u32*)T5[u.temp[1][0]])
^ *((u32*)T6[u.temp[0][1]])
^ *((u32*)T7[u.temp[3][2]])
^ *((u32*)T8[u.temp[2][3]]));
*((u32*)(b+ 8)) = (*((u32*)T5[u.temp[2][0]])
^ *((u32*)T6[u.temp[1][1]])
^ *((u32*)T7[u.temp[0][2]])
^ *((u32*)T8[u.temp[3][3]]));
*((u32*)(b+12)) = (*((u32*)T5[u.temp[3][0]])
^ *((u32*)T6[u.temp[2][1]])
^ *((u32*)T7[u.temp[1][2]])
^ *((u32*)T8[u.temp[0][3]]));
}
/* Last round is special. */
*((u32*)u.temp[0]) = *((u32*)(b )) ^ *((u32*)rk[1][0]);
*((u32*)u.temp[1]) = *((u32*)(b+ 4)) ^ *((u32*)rk[1][1]);
*((u32*)u.temp[2]) = *((u32*)(b+ 8)) ^ *((u32*)rk[1][2]);
*((u32*)u.temp[3]) = *((u32*)(b+12)) ^ *((u32*)rk[1][3]);
b[ 0] = S5[u.temp[0][0]];
b[ 1] = S5[u.temp[3][1]];
b[ 2] = S5[u.temp[2][2]];
b[ 3] = S5[u.temp[1][3]];
b[ 4] = S5[u.temp[1][0]];
b[ 5] = S5[u.temp[0][1]];
b[ 6] = S5[u.temp[3][2]];
b[ 7] = S5[u.temp[2][3]];
b[ 8] = S5[u.temp[2][0]];
b[ 9] = S5[u.temp[1][1]];
b[10] = S5[u.temp[0][2]];
b[11] = S5[u.temp[3][3]];
b[12] = S5[u.temp[3][0]];
b[13] = S5[u.temp[2][1]];
b[14] = S5[u.temp[1][2]];
b[15] = S5[u.temp[0][3]];
*((u32*)(b )) ^= *((u32*)rk[0][0]);
*((u32*)(b+ 4)) ^= *((u32*)rk[0][1]);
*((u32*)(b+ 8)) ^= *((u32*)rk[0][2]);
*((u32*)(b+12)) ^= *((u32*)rk[0][3]);
#undef rk
}
/* Decrypt one block. AX and BX may be the same. */
static void
do_decrypt (RIJNDAEL_context *ctx, byte *bx, const byte *ax)
{
/* BX and AX are not necessary correctly aligned. Thus we need to
copy them here. */
union
{
u32 dummy[4];
byte a[16];
} a;
union
{
u32 dummy[4];
byte b[16];
} b;
if ( !ctx->decryption_prepared )
{
prepare_decryption ( ctx );
_gcry_burn_stack (64);
ctx->decryption_prepared = 1;
}
memcpy (a.a, ax, 16);
do_decrypt_aligned (ctx, b.b, a.a);
memcpy (bx, b.b, 16);
#undef rk
}
static void
rijndael_decrypt (void *context, byte *b, const byte *a)
{
RIJNDAEL_context *ctx = context;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
{
do_padlock (ctx, 1, b, a);
_gcry_burn_stack (48 + 2*sizeof(int) /* FIXME */);
}
else
#endif /*USE_PADLOCK*/
{
do_decrypt (ctx, b, a);
_gcry_burn_stack (48+2*sizeof(int));
}
}
/* Bulk decryption of complete blocks in CFB mode. Caller needs to
make sure that IV is aligned on an unisgned lonhg boundary. This
function is only intended for the bulk encryption feature of
cipher.c. */
void
_gcry_aes_cfb_dec (void *context, unsigned char *iv,
void *outbuf_arg, const void *inbuf_arg,
unsigned int nblocks)
{
RIJNDAEL_context *ctx = context;
unsigned char *outbuf = outbuf_arg;
const unsigned char *inbuf = inbuf_arg;
unsigned char *ivp;
unsigned char temp;
int i;
#ifdef USE_PADLOCK
if (ctx->use_padlock)
{
/* Fixme: Let Padlock do the CFBing. */
for ( ;nblocks; nblocks-- )
{
do_padlock (ctx, 0, iv, iv);
for (ivp=iv,i=0; i < BLOCKSIZE; i++ )
{
temp = *inbuf++;
*outbuf++ = *ivp ^ temp;
*ivp++ = temp;
}
}
}
else
#endif /*USE_PADLOCK*/
{
for ( ;nblocks; nblocks-- )
{
do_encrypt_aligned (ctx, iv, iv);
for (ivp=iv,i=0; i < BLOCKSIZE; i++ )
{
temp = *inbuf++;
*outbuf++ = *ivp ^ temp;
*ivp++ = temp;
}
}
}
_gcry_burn_stack (48 + 2*sizeof(int));
}
/* Bulk decryption of complete blocks in CBC mode. Caller needs to
make sure that IV is aligned on an unsigned long boundary. This
function is only intended for the bulk encryption feature of
cipher.c. */
void
_gcry_aes_cbc_dec (void *context, unsigned char *iv,
void *outbuf_arg, const void *inbuf_arg,
unsigned int nblocks)
{
RIJNDAEL_context *ctx = context;
unsigned char *outbuf = outbuf_arg;
const unsigned char *inbuf = inbuf_arg;
unsigned char *ivp;
int i;
unsigned char savebuf[BLOCKSIZE];
for ( ;nblocks; nblocks-- )
{
/* We need to save INBUF away because it may be identical to
OUTBUF. */
memcpy (savebuf, inbuf, BLOCKSIZE);
#ifdef USE_PADLOCK
if (ctx->use_padlock)
do_padlock (ctx, 1, outbuf, inbuf);
else
#endif /*USE_PADLOCK*/
do_decrypt (ctx, outbuf, inbuf);
for (ivp=iv, i=0; i < BLOCKSIZE; i++ )
outbuf[i] ^= *ivp++;
memcpy (iv, savebuf, BLOCKSIZE);
inbuf += BLOCKSIZE;
outbuf += BLOCKSIZE;
}
_gcry_burn_stack (48 + 2*sizeof(int) + BLOCKSIZE + 4*sizeof (char*));
}
/* Run the self-tests for AES 128. Returns NULL on success. */
static const char*
selftest_basic_128 (void)
{
RIJNDAEL_context ctx;
unsigned char scratch[16];
/* The test vectors are from the AES supplied ones; more or less
randomly taken from ecb_tbl.txt (I=42,81,14) */
static const unsigned char plaintext_128[16] =
{
0x01,0x4B,0xAF,0x22,0x78,0xA6,0x9D,0x33,
0x1D,0x51,0x80,0x10,0x36,0x43,0xE9,0x9A
};
static const unsigned char key_128[16] =
{
0xE8,0xE9,0xEA,0xEB,0xED,0xEE,0xEF,0xF0,
0xF2,0xF3,0xF4,0xF5,0xF7,0xF8,0xF9,0xFA
};
static const unsigned char ciphertext_128[16] =
{
0x67,0x43,0xC3,0xD1,0x51,0x9A,0xB4,0xF2,
0xCD,0x9A,0x78,0xAB,0x09,0xA5,0x11,0xBD
};
rijndael_setkey (&ctx, key_128, sizeof (key_128));
rijndael_encrypt (&ctx, scratch, plaintext_128);
if (memcmp (scratch, ciphertext_128, sizeof (ciphertext_128)))
return "AES-128 test encryption failed.";
rijndael_decrypt (&ctx, scratch, scratch);
if (memcmp (scratch, plaintext_128, sizeof (plaintext_128)))
return "AES-128 test decryption failed.";
return NULL;
}
/* Run the self-tests for AES 192. Returns NULL on success. */
static const char*
selftest_basic_192 (void)
{
RIJNDAEL_context ctx;
unsigned char scratch[16];
static unsigned char plaintext_192[16] =
{
0x76,0x77,0x74,0x75,0xF1,0xF2,0xF3,0xF4,
0xF8,0xF9,0xE6,0xE7,0x77,0x70,0x71,0x72
};
static unsigned char key_192[24] =
{
0x04,0x05,0x06,0x07,0x09,0x0A,0x0B,0x0C,
0x0E,0x0F,0x10,0x11,0x13,0x14,0x15,0x16,
0x18,0x19,0x1A,0x1B,0x1D,0x1E,0x1F,0x20
};
static const unsigned char ciphertext_192[16] =
{
0x5D,0x1E,0xF2,0x0D,0xCE,0xD6,0xBC,0xBC,
0x12,0x13,0x1A,0xC7,0xC5,0x47,0x88,0xAA
};
rijndael_setkey (&ctx, key_192, sizeof(key_192));
rijndael_encrypt (&ctx, scratch, plaintext_192);
if (memcmp (scratch, ciphertext_192, sizeof (ciphertext_192)))
return "AES-192 test encryption failed.";
rijndael_decrypt (&ctx, scratch, scratch);
if (memcmp (scratch, plaintext_192, sizeof (plaintext_192)))
return "AES-192 test decryption failed.";
return NULL;
}
/* Run the self-tests for AES 256. Returns NULL on success. */
static const char*
selftest_basic_256 (void)
{
RIJNDAEL_context ctx;
unsigned char scratch[16];
static unsigned char plaintext_256[16] =
{
0x06,0x9A,0x00,0x7F,0xC7,0x6A,0x45,0x9F,
0x98,0xBA,0xF9,0x17,0xFE,0xDF,0x95,0x21
};
static unsigned char key_256[32] =
{
0x08,0x09,0x0A,0x0B,0x0D,0x0E,0x0F,0x10,
0x12,0x13,0x14,0x15,0x17,0x18,0x19,0x1A,
0x1C,0x1D,0x1E,0x1F,0x21,0x22,0x23,0x24,
0x26,0x27,0x28,0x29,0x2B,0x2C,0x2D,0x2E
};
static const unsigned char ciphertext_256[16] =
{
0x08,0x0E,0x95,0x17,0xEB,0x16,0x77,0x71,
0x9A,0xCF,0x72,0x80,0x86,0x04,0x0A,0xE3
};
rijndael_setkey (&ctx, key_256, sizeof(key_256));
rijndael_encrypt (&ctx, scratch, plaintext_256);
if (memcmp (scratch, ciphertext_256, sizeof (ciphertext_256)))
return "AES-256 test encryption failed.";
rijndael_decrypt (&ctx, scratch, scratch);
if (memcmp (scratch, plaintext_256, sizeof (plaintext_256)))
return "AES-256 test decryption failed.";
return NULL;
}
/* Run all the self-tests and return NULL on success. This function
is used for the on-the-fly self-tests. */
static const char *
selftest (void)
{
const char *r;
if ( (r = selftest_basic_128 ())
|| (r = selftest_basic_192 ())
|| (r = selftest_basic_256 ()) )
return r;
return r;
}
/* SP800-38a.pdf for AES-128. */
static const char *
selftest_fips_128_38a (int requested_mode)
{
struct tv
{
int mode;
const unsigned char key[16];
const unsigned char iv[16];
struct
{
const unsigned char input[16];
const unsigned char output[16];
} data[4];
} tv[2] =
{
{
GCRY_CIPHER_MODE_CFB, /* F.3.13, CFB128-AES128 */
{ 0x2b, 0x7e, 0x15, 0x16, 0x28, 0xae, 0xd2, 0xa6,
0xab, 0xf7, 0x15, 0x88, 0x09, 0xcf, 0x4f, 0x3c },
{ 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f },
{
{ { 0x6b, 0xc1, 0xbe, 0xe2, 0x2e, 0x40, 0x9f, 0x96,
0xe9, 0x3d, 0x7e, 0x11, 0x73, 0x93, 0x17, 0x2a },
{ 0x3b, 0x3f, 0xd9, 0x2e, 0xb7, 0x2d, 0xad, 0x20,
0x33, 0x34, 0x49, 0xf8, 0xe8, 0x3c, 0xfb, 0x4a } },
{ { 0xae, 0x2d, 0x8a, 0x57, 0x1e, 0x03, 0xac, 0x9c,
0x9e, 0xb7, 0x6f, 0xac, 0x45, 0xaf, 0x8e, 0x51 },
{ 0xc8, 0xa6, 0x45, 0x37, 0xa0, 0xb3, 0xa9, 0x3f,
0xcd, 0xe3, 0xcd, 0xad, 0x9f, 0x1c, 0xe5, 0x8b } },
{ { 0x30, 0xc8, 0x1c, 0x46, 0xa3, 0x5c, 0xe4, 0x11,
0xe5, 0xfb, 0xc1, 0x19, 0x1a, 0x0a, 0x52, 0xef },
{ 0x26, 0x75, 0x1f, 0x67, 0xa3, 0xcb, 0xb1, 0x40,
0xb1, 0x80, 0x8c, 0xf1, 0x87, 0xa4, 0xf4, 0xdf } },
{ { 0xf6, 0x9f, 0x24, 0x45, 0xdf, 0x4f, 0x9b, 0x17,
0xad, 0x2b, 0x41, 0x7b, 0xe6, 0x6c, 0x37, 0x10 },
{ 0xc0, 0x4b, 0x05, 0x35, 0x7c, 0x5d, 0x1c, 0x0e,
0xea, 0xc4, 0xc6, 0x6f, 0x9f, 0xf7, 0xf2, 0xe6 } }
}
},
{
GCRY_CIPHER_MODE_OFB,
{ 0x2b, 0x7e, 0x15, 0x16, 0x28, 0xae, 0xd2, 0xa6,
0xab, 0xf7, 0x15, 0x88, 0x09, 0xcf, 0x4f, 0x3c },
{ 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f },
{
{ { 0x6b, 0xc1, 0xbe, 0xe2, 0x2e, 0x40, 0x9f, 0x96,
0xe9, 0x3d, 0x7e, 0x11, 0x73, 0x93, 0x17, 0x2a },
{ 0x3b, 0x3f, 0xd9, 0x2e, 0xb7, 0x2d, 0xad, 0x20,
0x33, 0x34, 0x49, 0xf8, 0xe8, 0x3c, 0xfb, 0x4a } },
{ { 0xae, 0x2d, 0x8a, 0x57, 0x1e, 0x03, 0xac, 0x9c,
0x9e, 0xb7, 0x6f, 0xac, 0x45, 0xaf, 0x8e, 0x51 },
{ 0x77, 0x89, 0x50, 0x8d, 0x16, 0x91, 0x8f, 0x03,
0xf5, 0x3c, 0x52, 0xda, 0xc5, 0x4e, 0xd8, 0x25 } },
{ { 0x30, 0xc8, 0x1c, 0x46, 0xa3, 0x5c, 0xe4, 0x11,
0xe5, 0xfb, 0xc1, 0x19, 0x1a, 0x0a, 0x52, 0xef },
{ 0x97, 0x40, 0x05, 0x1e, 0x9c, 0x5f, 0xec, 0xf6,
0x43, 0x44, 0xf7, 0xa8, 0x22, 0x60, 0xed, 0xcc } },
{ { 0xf6, 0x9f, 0x24, 0x45, 0xdf, 0x4f, 0x9b, 0x17,
0xad, 0x2b, 0x41, 0x7b, 0xe6, 0x6c, 0x37, 0x10 },
{ 0x30, 0x4c, 0x65, 0x28, 0xf6, 0x59, 0xc7, 0x78,
0x66, 0xa5, 0x10, 0xd9, 0xc1, 0xd6, 0xae, 0x5e } },
}
}
};
unsigned char scratch[16];
gpg_error_t err;
int tvi, idx;
gcry_cipher_hd_t hdenc = NULL;
gcry_cipher_hd_t hddec = NULL;
#define Fail(a) do { \
_gcry_cipher_close (hdenc); \
_gcry_cipher_close (hddec); \
return a; \
} while (0)
gcry_assert (sizeof tv[0].data[0].input == sizeof scratch);
gcry_assert (sizeof tv[0].data[0].output == sizeof scratch);
for (tvi=0; tvi < DIM (tv); tvi++)
if (tv[tvi].mode == requested_mode)
break;
if (tvi == DIM (tv))
Fail ("no test data for this mode");
err = _gcry_cipher_open (&hdenc, GCRY_CIPHER_AES, tv[tvi].mode, 0);
if (err)
Fail ("open");
err = _gcry_cipher_open (&hddec, GCRY_CIPHER_AES, tv[tvi].mode, 0);
if (err)
Fail ("open");
err = _gcry_cipher_setkey (hdenc, tv[tvi].key, sizeof tv[tvi].key);
if (!err)
err = _gcry_cipher_setkey (hddec, tv[tvi].key, sizeof tv[tvi].key);
if (err)
Fail ("set key");
err = _gcry_cipher_setiv (hdenc, tv[tvi].iv, sizeof tv[tvi].iv);
if (!err)
err = _gcry_cipher_setiv (hddec, tv[tvi].iv, sizeof tv[tvi].iv);
if (err)
Fail ("set IV");
for (idx=0; idx < DIM (tv[tvi].data); idx++)
{
err = _gcry_cipher_encrypt (hdenc, scratch, sizeof scratch,
tv[tvi].data[idx].input,
sizeof tv[tvi].data[idx].input);
if (err)
Fail ("encrypt command");
if (memcmp (scratch, tv[tvi].data[idx].output, sizeof scratch))
Fail ("encrypt mismatch");
err = _gcry_cipher_decrypt (hddec, scratch, sizeof scratch,
tv[tvi].data[idx].output,
sizeof tv[tvi].data[idx].output);
if (err)
Fail ("decrypt command");
if (memcmp (scratch, tv[tvi].data[idx].input, sizeof scratch))
Fail ("decrypt mismatch");
}
#undef Fail
_gcry_cipher_close (hdenc);
_gcry_cipher_close (hddec);
return NULL;
}
/* Complete selftest for AES-128 with all modes and driver code. */
static gpg_err_code_t
selftest_fips_128 (int extended, selftest_report_func_t report)
{
const char *what;
const char *errtxt;
what = "low-level";
errtxt = selftest_basic_128 ();
if (errtxt)
goto failed;
if (extended)
{
what = "cfb";
errtxt = selftest_fips_128_38a (GCRY_CIPHER_MODE_CFB);
if (errtxt)
goto failed;
what = "ofb";
errtxt = selftest_fips_128_38a (GCRY_CIPHER_MODE_OFB);
if (errtxt)
goto failed;
}
return 0; /* Succeeded. */
failed:
if (report)
report ("cipher", GCRY_CIPHER_AES128, what, errtxt);
return GPG_ERR_SELFTEST_FAILED;
}
/* Complete selftest for AES-192. */
static gpg_err_code_t
selftest_fips_192 (int extended, selftest_report_func_t report)
{
const char *what;
const char *errtxt;
(void)extended; /* No extended tests available. */
what = "low-level";
errtxt = selftest_basic_192 ();
if (errtxt)
goto failed;
return 0; /* Succeeded. */
failed:
if (report)
report ("cipher", GCRY_CIPHER_AES192, what, errtxt);
return GPG_ERR_SELFTEST_FAILED;
}
/* Complete selftest for AES-256. */
static gpg_err_code_t
selftest_fips_256 (int extended, selftest_report_func_t report)
{
const char *what;
const char *errtxt;
(void)extended; /* No extended tests available. */
what = "low-level";
errtxt = selftest_basic_256 ();
if (errtxt)
goto failed;
return 0; /* Succeeded. */
failed:
if (report)
report ("cipher", GCRY_CIPHER_AES256, what, errtxt);
return GPG_ERR_SELFTEST_FAILED;
}
/* Run a full self-test for ALGO and return 0 on success. */
static gpg_err_code_t
run_selftests (int algo, int extended, selftest_report_func_t report)
{
gpg_err_code_t ec;
switch (algo)
{
case GCRY_CIPHER_AES128:
ec = selftest_fips_128 (extended, report);
break;
case GCRY_CIPHER_AES192:
ec = selftest_fips_192 (extended, report);
break;
case GCRY_CIPHER_AES256:
ec = selftest_fips_256 (extended, report);
break;
default:
ec = GPG_ERR_CIPHER_ALGO;
break;
}
return ec;
}
static const char *rijndael_names[] =
{
"RIJNDAEL",
"AES128",
"AES-128",
NULL
};
static gcry_cipher_oid_spec_t rijndael_oids[] =
{
{ "2.16.840.1.101.3.4.1.1", GCRY_CIPHER_MODE_ECB },
{ "2.16.840.1.101.3.4.1.2", GCRY_CIPHER_MODE_CBC },
{ "2.16.840.1.101.3.4.1.3", GCRY_CIPHER_MODE_OFB },
{ "2.16.840.1.101.3.4.1.4", GCRY_CIPHER_MODE_CFB },
{ NULL }
};
gcry_cipher_spec_t _gcry_cipher_spec_aes =
{
"AES", rijndael_names, rijndael_oids, 16, 128, sizeof (RIJNDAEL_context),
rijndael_setkey, rijndael_encrypt, rijndael_decrypt
};
cipher_extra_spec_t _gcry_cipher_extraspec_aes =
{
run_selftests
};
static const char *rijndael192_names[] =
{
"RIJNDAEL192",
"AES-192",
NULL
};
static gcry_cipher_oid_spec_t rijndael192_oids[] =
{
{ "2.16.840.1.101.3.4.1.21", GCRY_CIPHER_MODE_ECB },
{ "2.16.840.1.101.3.4.1.22", GCRY_CIPHER_MODE_CBC },
{ "2.16.840.1.101.3.4.1.23", GCRY_CIPHER_MODE_OFB },
{ "2.16.840.1.101.3.4.1.24", GCRY_CIPHER_MODE_CFB },
{ NULL }
};
gcry_cipher_spec_t _gcry_cipher_spec_aes192 =
{
"AES192", rijndael192_names, rijndael192_oids, 16, 192, sizeof (RIJNDAEL_context),
rijndael_setkey, rijndael_encrypt, rijndael_decrypt
};
cipher_extra_spec_t _gcry_cipher_extraspec_aes192 =
{
run_selftests
};
static const char *rijndael256_names[] =
{
"RIJNDAEL256",
"AES-256",
NULL
};
static gcry_cipher_oid_spec_t rijndael256_oids[] =
{
{ "2.16.840.1.101.3.4.1.41", GCRY_CIPHER_MODE_ECB },
{ "2.16.840.1.101.3.4.1.42", GCRY_CIPHER_MODE_CBC },
{ "2.16.840.1.101.3.4.1.43", GCRY_CIPHER_MODE_OFB },
{ "2.16.840.1.101.3.4.1.44", GCRY_CIPHER_MODE_CFB },
{ NULL }
};
gcry_cipher_spec_t _gcry_cipher_spec_aes256 =
{
"AES256", rijndael256_names, rijndael256_oids, 16, 256,
sizeof (RIJNDAEL_context),
rijndael_setkey, rijndael_encrypt, rijndael_decrypt
};
cipher_extra_spec_t _gcry_cipher_extraspec_aes256 =
{
run_selftests
};