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nest-open-source / nest-learning-thermostat / 5.0.2 / libgcrypt / refs/heads/master / . / libgcrypt-1.4.6 / cipher / serpent.c
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/* serpent.c - Implementation of the Serpent encryption algorithm.
* Copyright (C) 2003, 2004, 2005 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, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
* 02111-1307, USA.
*/
#include <config.h>
#include <string.h>
#include <stdio.h>
#include "types.h"
#include "g10lib.h"
#include "cipher.h"
#include "bithelp.h"
/* Number of rounds per Serpent encrypt/decrypt operation. */
#define ROUNDS 32
/* Magic number, used during generating of the subkeys. */
#define PHI 0x9E3779B9
/* Serpent works on 128 bit blocks. */
typedef u32 serpent_block_t[4];
/* Serpent key, provided by the user. If the original key is shorter
than 256 bits, it is padded. */
typedef u32 serpent_key_t[8];
/* The key schedule consists of 33 128 bit subkeys. */
typedef u32 serpent_subkeys_t[ROUNDS + 1][4];
/* A Serpent context. */
typedef struct serpent_context
{
serpent_subkeys_t keys; /* Generated subkeys. */
} serpent_context_t;
/* A prototype. */
static const char *serpent_test (void);
#define byte_swap_32(x) \
(0 \
| (((x) & 0xff000000) >> 24) | (((x) & 0x00ff0000) >> 8) \
| (((x) & 0x0000ff00) << 8) | (((x) & 0x000000ff) << 24))
/* These are the S-Boxes of Serpent. They are copied from Serpents
reference implementation (the optimized one, contained in
`floppy2') and are therefore:
Copyright (C) 1998 Ross Anderson, Eli Biham, Lars Knudsen.
To quote the Serpent homepage
(http://www.cl.cam.ac.uk/~rja14/serpent.html):
"Serpent is now completely in the public domain, and we impose no
restrictions on its use. This was announced on the 21st August at
the First AES Candidate Conference. The optimised implementations
in the submission package are now under the GNU PUBLIC LICENSE
(GPL), although some comments in the code still say otherwise. You
are welcome to use Serpent for any application." */
#define SBOX0(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t05, t06, t07, t08, t09; \
u32 t11, t12, t13, t14, t15, t17, t01; \
t01 = b ^ c ; \
t02 = a | d ; \
t03 = a ^ b ; \
z = t02 ^ t01; \
t05 = c | z ; \
t06 = a ^ d ; \
t07 = b | c ; \
t08 = d & t05; \
t09 = t03 & t07; \
y = t09 ^ t08; \
t11 = t09 & y ; \
t12 = c ^ d ; \
t13 = t07 ^ t11; \
t14 = b & t06; \
t15 = t06 ^ t13; \
w = ~ t15; \
t17 = w ^ t14; \
x = t12 ^ t17; \
}
#define SBOX0_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t08, t09, t10; \
u32 t12, t13, t14, t15, t17, t18, t01; \
t01 = c ^ d ; \
t02 = a | b ; \
t03 = b | c ; \
t04 = c & t01; \
t05 = t02 ^ t01; \
t06 = a | t04; \
y = ~ t05; \
t08 = b ^ d ; \
t09 = t03 & t08; \
t10 = d | y ; \
x = t09 ^ t06; \
t12 = a | t05; \
t13 = x ^ t12; \
t14 = t03 ^ t10; \
t15 = a ^ c ; \
z = t14 ^ t13; \
t17 = t05 & t13; \
t18 = t14 | t17; \
w = t15 ^ t18; \
}
#define SBOX1(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t08; \
u32 t10, t11, t12, t13, t16, t17, t01; \
t01 = a | d ; \
t02 = c ^ d ; \
t03 = ~ b ; \
t04 = a ^ c ; \
t05 = a | t03; \
t06 = d & t04; \
t07 = t01 & t02; \
t08 = b | t06; \
y = t02 ^ t05; \
t10 = t07 ^ t08; \
t11 = t01 ^ t10; \
t12 = y ^ t11; \
t13 = b & d ; \
z = ~ t10; \
x = t13 ^ t12; \
t16 = t10 | x ; \
t17 = t05 & t16; \
w = c ^ t17; \
}
#define SBOX1_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t08; \
u32 t09, t10, t11, t14, t15, t17, t01; \
t01 = a ^ b ; \
t02 = b | d ; \
t03 = a & c ; \
t04 = c ^ t02; \
t05 = a | t04; \
t06 = t01 & t05; \
t07 = d | t03; \
t08 = b ^ t06; \
t09 = t07 ^ t06; \
t10 = t04 | t03; \
t11 = d & t08; \
y = ~ t09; \
x = t10 ^ t11; \
t14 = a | y ; \
t15 = t06 ^ x ; \
z = t01 ^ t04; \
t17 = c ^ t15; \
w = t14 ^ t17; \
}
#define SBOX2(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t05, t06, t07, t08; \
u32 t09, t10, t12, t13, t14, t01; \
t01 = a | c ; \
t02 = a ^ b ; \
t03 = d ^ t01; \
w = t02 ^ t03; \
t05 = c ^ w ; \
t06 = b ^ t05; \
t07 = b | t05; \
t08 = t01 & t06; \
t09 = t03 ^ t07; \
t10 = t02 | t09; \
x = t10 ^ t08; \
t12 = a | d ; \
t13 = t09 ^ x ; \
t14 = b ^ t13; \
z = ~ t09; \
y = t12 ^ t14; \
}
#define SBOX2_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t06, t07, t08, t09; \
u32 t10, t11, t12, t15, t16, t17, t01; \
t01 = a ^ d ; \
t02 = c ^ d ; \
t03 = a & c ; \
t04 = b | t02; \
w = t01 ^ t04; \
t06 = a | c ; \
t07 = d | w ; \
t08 = ~ d ; \
t09 = b & t06; \
t10 = t08 | t03; \
t11 = b & t07; \
t12 = t06 & t02; \
z = t09 ^ t10; \
x = t12 ^ t11; \
t15 = c & z ; \
t16 = w ^ x ; \
t17 = t10 ^ t15; \
y = t16 ^ t17; \
}
#define SBOX3(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t08; \
u32 t09, t10, t11, t13, t14, t15, t01; \
t01 = a ^ c ; \
t02 = a | d ; \
t03 = a & d ; \
t04 = t01 & t02; \
t05 = b | t03; \
t06 = a & b ; \
t07 = d ^ t04; \
t08 = c | t06; \
t09 = b ^ t07; \
t10 = d & t05; \
t11 = t02 ^ t10; \
z = t08 ^ t09; \
t13 = d | z ; \
t14 = a | t07; \
t15 = b & t13; \
y = t08 ^ t11; \
w = t14 ^ t15; \
x = t05 ^ t04; \
}
#define SBOX3_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t09; \
u32 t11, t12, t13, t14, t16, t01; \
t01 = c | d ; \
t02 = a | d ; \
t03 = c ^ t02; \
t04 = b ^ t02; \
t05 = a ^ d ; \
t06 = t04 & t03; \
t07 = b & t01; \
y = t05 ^ t06; \
t09 = a ^ t03; \
w = t07 ^ t03; \
t11 = w | t05; \
t12 = t09 & t11; \
t13 = a & y ; \
t14 = t01 ^ t05; \
x = b ^ t12; \
t16 = b | t13; \
z = t14 ^ t16; \
}
#define SBOX4(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t08, t09; \
u32 t10, t11, t12, t13, t14, t15, t16, t01; \
t01 = a | b ; \
t02 = b | c ; \
t03 = a ^ t02; \
t04 = b ^ d ; \
t05 = d | t03; \
t06 = d & t01; \
z = t03 ^ t06; \
t08 = z & t04; \
t09 = t04 & t05; \
t10 = c ^ t06; \
t11 = b & c ; \
t12 = t04 ^ t08; \
t13 = t11 | t03; \
t14 = t10 ^ t09; \
t15 = a & t05; \
t16 = t11 | t12; \
y = t13 ^ t08; \
x = t15 ^ t16; \
w = ~ t14; \
}
#define SBOX4_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t09; \
u32 t10, t11, t12, t13, t15, t01; \
t01 = b | d ; \
t02 = c | d ; \
t03 = a & t01; \
t04 = b ^ t02; \
t05 = c ^ d ; \
t06 = ~ t03; \
t07 = a & t04; \
x = t05 ^ t07; \
t09 = x | t06; \
t10 = a ^ t07; \
t11 = t01 ^ t09; \
t12 = d ^ t04; \
t13 = c | t10; \
z = t03 ^ t12; \
t15 = a ^ t04; \
y = t11 ^ t13; \
w = t15 ^ t09; \
}
#define SBOX5(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t07, t08, t09; \
u32 t10, t11, t12, t13, t14, t01; \
t01 = b ^ d ; \
t02 = b | d ; \
t03 = a & t01; \
t04 = c ^ t02; \
t05 = t03 ^ t04; \
w = ~ t05; \
t07 = a ^ t01; \
t08 = d | w ; \
t09 = b | t05; \
t10 = d ^ t08; \
t11 = b | t07; \
t12 = t03 | w ; \
t13 = t07 | t10; \
t14 = t01 ^ t11; \
y = t09 ^ t13; \
x = t07 ^ t08; \
z = t12 ^ t14; \
}
#define SBOX5_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t07, t08, t09; \
u32 t10, t12, t13, t15, t16, t01; \
t01 = a & d ; \
t02 = c ^ t01; \
t03 = a ^ d ; \
t04 = b & t02; \
t05 = a & c ; \
w = t03 ^ t04; \
t07 = a & w ; \
t08 = t01 ^ w ; \
t09 = b | t05; \
t10 = ~ b ; \
x = t08 ^ t09; \
t12 = t10 | t07; \
t13 = w | x ; \
z = t02 ^ t12; \
t15 = t02 ^ t13; \
t16 = b ^ d ; \
y = t16 ^ t15; \
}
#define SBOX6(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t07, t08, t09, t10; \
u32 t11, t12, t13, t15, t17, t18, t01; \
t01 = a & d ; \
t02 = b ^ c ; \
t03 = a ^ d ; \
t04 = t01 ^ t02; \
t05 = b | c ; \
x = ~ t04; \
t07 = t03 & t05; \
t08 = b & x ; \
t09 = a | c ; \
t10 = t07 ^ t08; \
t11 = b | d ; \
t12 = c ^ t11; \
t13 = t09 ^ t10; \
y = ~ t13; \
t15 = x & t03; \
z = t12 ^ t07; \
t17 = a ^ b ; \
t18 = y ^ t15; \
w = t17 ^ t18; \
}
#define SBOX6_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t07, t08, t09; \
u32 t12, t13, t14, t15, t16, t17, t01; \
t01 = a ^ c ; \
t02 = ~ c ; \
t03 = b & t01; \
t04 = b | t02; \
t05 = d | t03; \
t06 = b ^ d ; \
t07 = a & t04; \
t08 = a | t02; \
t09 = t07 ^ t05; \
x = t06 ^ t08; \
w = ~ t09; \
t12 = b & w ; \
t13 = t01 & t05; \
t14 = t01 ^ t12; \
t15 = t07 ^ t13; \
t16 = d | t02; \
t17 = a ^ x ; \
z = t17 ^ t15; \
y = t16 ^ t14; \
}
#define SBOX7(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t05, t06, t08, t09, t10; \
u32 t11, t13, t14, t15, t16, t17, t01; \
t01 = a & c ; \
t02 = ~ d ; \
t03 = a & t02; \
t04 = b | t01; \
t05 = a & b ; \
t06 = c ^ t04; \
z = t03 ^ t06; \
t08 = c | z ; \
t09 = d | t05; \
t10 = a ^ t08; \
t11 = t04 & z ; \
x = t09 ^ t10; \
t13 = b ^ x ; \
t14 = t01 ^ x ; \
t15 = c ^ t05; \
t16 = t11 | t13; \
t17 = t02 | t14; \
w = t15 ^ t17; \
y = a ^ t16; \
}
#define SBOX7_INVERSE(a, b, c, d, w, x, y, z) \
{ \
u32 t02, t03, t04, t06, t07, t08, t09; \
u32 t10, t11, t13, t14, t15, t16, t01; \
t01 = a & b ; \
t02 = a | b ; \
t03 = c | t01; \
t04 = d & t02; \
z = t03 ^ t04; \
t06 = b ^ t04; \
t07 = d ^ z ; \
t08 = ~ t07; \
t09 = t06 | t08; \
t10 = b ^ d ; \
t11 = a | d ; \
x = a ^ t09; \
t13 = c ^ t06; \
t14 = c & t11; \
t15 = d | x ; \
t16 = t01 | t10; \
w = t13 ^ t15; \
y = t14 ^ t16; \
}
/* XOR BLOCK1 into BLOCK0. */
#define BLOCK_XOR(block0, block1) \
{ \
block0[0] ^= block1[0]; \
block0[1] ^= block1[1]; \
block0[2] ^= block1[2]; \
block0[3] ^= block1[3]; \
}
/* Copy BLOCK_SRC to BLOCK_DST. */
#define BLOCK_COPY(block_dst, block_src) \
{ \
block_dst[0] = block_src[0]; \
block_dst[1] = block_src[1]; \
block_dst[2] = block_src[2]; \
block_dst[3] = block_src[3]; \
}
/* Apply SBOX number WHICH to to the block found in ARRAY0 at index
INDEX, writing the output to the block found in ARRAY1 at index
INDEX. */
#define SBOX(which, array0, array1, index) \
SBOX##which (array0[index + 0], array0[index + 1], \
array0[index + 2], array0[index + 3], \
array1[index + 0], array1[index + 1], \
array1[index + 2], array1[index + 3]);
/* Apply inverse SBOX number WHICH to to the block found in ARRAY0 at
index INDEX, writing the output to the block found in ARRAY1 at
index INDEX. */
#define SBOX_INVERSE(which, array0, array1, index) \
SBOX##which##_INVERSE (array0[index + 0], array0[index + 1], \
array0[index + 2], array0[index + 3], \
array1[index + 0], array1[index + 1], \
array1[index + 2], array1[index + 3]);
/* Apply the linear transformation to BLOCK. */
#define LINEAR_TRANSFORMATION(block) \
{ \
block[0] = rol (block[0], 13); \
block[2] = rol (block[2], 3); \
block[1] = block[1] ^ block[0] ^ block[2]; \
block[3] = block[3] ^ block[2] ^ (block[0] << 3); \
block[1] = rol (block[1], 1); \
block[3] = rol (block[3], 7); \
block[0] = block[0] ^ block[1] ^ block[3]; \
block[2] = block[2] ^ block[3] ^ (block[1] << 7); \
block[0] = rol (block[0], 5); \
block[2] = rol (block[2], 22); \
}
/* Apply the inverse linear transformation to BLOCK. */
#define LINEAR_TRANSFORMATION_INVERSE(block) \
{ \
block[2] = ror (block[2], 22); \
block[0] = ror (block[0] , 5); \
block[2] = block[2] ^ block[3] ^ (block[1] << 7); \
block[0] = block[0] ^ block[1] ^ block[3]; \
block[3] = ror (block[3], 7); \
block[1] = ror (block[1], 1); \
block[3] = block[3] ^ block[2] ^ (block[0] << 3); \
block[1] = block[1] ^ block[0] ^ block[2]; \
block[2] = ror (block[2], 3); \
block[0] = ror (block[0], 13); \
}
/* Apply a Serpent round to BLOCK, using the SBOX number WHICH and the
subkeys contained in SUBKEYS. Use BLOCK_TMP as temporary storage.
This macro increments `round'. */
#define ROUND(which, subkeys, block, block_tmp) \
{ \
BLOCK_XOR (block, subkeys[round]); \
round++; \
SBOX (which, block, block_tmp, 0); \
LINEAR_TRANSFORMATION (block_tmp); \
BLOCK_COPY (block, block_tmp); \
}
/* Apply the last Serpent round to BLOCK, using the SBOX number WHICH
and the subkeys contained in SUBKEYS. Use BLOCK_TMP as temporary
storage. The result will be stored in BLOCK_TMP. This macro
increments `round'. */
#define ROUND_LAST(which, subkeys, block, block_tmp) \
{ \
BLOCK_XOR (block, subkeys[round]); \
round++; \
SBOX (which, block, block_tmp, 0); \
BLOCK_XOR (block_tmp, subkeys[round]); \
round++; \
}
/* Apply an inverse Serpent round to BLOCK, using the SBOX number
WHICH and the subkeys contained in SUBKEYS. Use BLOCK_TMP as
temporary storage. This macro increments `round'. */
#define ROUND_INVERSE(which, subkey, block, block_tmp) \
{ \
LINEAR_TRANSFORMATION_INVERSE (block); \
SBOX_INVERSE (which, block, block_tmp, 0); \
BLOCK_XOR (block_tmp, subkey[round]); \
round--; \
BLOCK_COPY (block, block_tmp); \
}
/* Apply the first Serpent round to BLOCK, using the SBOX number WHICH
and the subkeys contained in SUBKEYS. Use BLOCK_TMP as temporary
storage. The result will be stored in BLOCK_TMP. This macro
increments `round'. */
#define ROUND_FIRST_INVERSE(which, subkeys, block, block_tmp) \
{ \
BLOCK_XOR (block, subkeys[round]); \
round--; \
SBOX_INVERSE (which, block, block_tmp, 0); \
BLOCK_XOR (block_tmp, subkeys[round]); \
round--; \
}
/* Convert the user provided key KEY of KEY_LENGTH bytes into the
internally used format. */
static void
serpent_key_prepare (const byte *key, unsigned int key_length,
serpent_key_t key_prepared)
{
int i;
/* Copy key. */
for (i = 0; i < key_length / 4; i++)
{
#ifdef WORDS_BIGENDIAN
key_prepared[i] = byte_swap_32 (((u32 *) key)[i]);
#else
key_prepared[i] = ((u32 *) key)[i];
#endif
}
if (i < 8)
{
/* Key must be padded according to the Serpent
specification. */
key_prepared[i] = 0x00000001;
for (i++; i < 8; i++)
key_prepared[i] = 0;
}
}
/* Derive the 33 subkeys from KEY and store them in SUBKEYS. */
static void
serpent_subkeys_generate (serpent_key_t key, serpent_subkeys_t subkeys)
{
u32 w_real[140]; /* The `prekey'. */
u32 k[132];
u32 *w = &w_real[8];
int i, j;
/* Initialize with key values. */
for (i = 0; i < 8; i++)
w[i - 8] = key[i];
/* Expand to intermediate key using the affine recurrence. */
for (i = 0; i < 132; i++)
w[i] = rol (w[i - 8] ^ w[i - 5] ^ w[i - 3] ^ w[i - 1] ^ PHI ^ i, 11);
/* Calculate subkeys via S-Boxes, in bitslice mode. */
SBOX (3, w, k, 0);
SBOX (2, w, k, 4);
SBOX (1, w, k, 8);
SBOX (0, w, k, 12);
SBOX (7, w, k, 16);
SBOX (6, w, k, 20);
SBOX (5, w, k, 24);
SBOX (4, w, k, 28);
SBOX (3, w, k, 32);
SBOX (2, w, k, 36);
SBOX (1, w, k, 40);
SBOX (0, w, k, 44);
SBOX (7, w, k, 48);
SBOX (6, w, k, 52);
SBOX (5, w, k, 56);
SBOX (4, w, k, 60);
SBOX (3, w, k, 64);
SBOX (2, w, k, 68);
SBOX (1, w, k, 72);
SBOX (0, w, k, 76);
SBOX (7, w, k, 80);
SBOX (6, w, k, 84);
SBOX (5, w, k, 88);
SBOX (4, w, k, 92);
SBOX (3, w, k, 96);
SBOX (2, w, k, 100);
SBOX (1, w, k, 104);
SBOX (0, w, k, 108);
SBOX (7, w, k, 112);
SBOX (6, w, k, 116);
SBOX (5, w, k, 120);
SBOX (4, w, k, 124);
SBOX (3, w, k, 128);
/* Renumber subkeys. */
for (i = 0; i < ROUNDS + 1; i++)
for (j = 0; j < 4; j++)
subkeys[i][j] = k[4 * i + j];
}
/* Initialize CONTEXT with the key KEY of KEY_LENGTH bits. */
static void
serpent_setkey_internal (serpent_context_t *context,
const byte *key, unsigned int key_length)
{
serpent_key_t key_prepared;
serpent_key_prepare (key, key_length, key_prepared);
serpent_subkeys_generate (key_prepared, context->keys);
_gcry_burn_stack (272 * sizeof (u32));
}
/* Initialize CTX with the key KEY of KEY_LENGTH bytes. */
static gcry_err_code_t
serpent_setkey (void *ctx,
const byte *key, unsigned int key_length)
{
serpent_context_t *context = ctx;
static const char *serpent_test_ret;
static int serpent_init_done;
gcry_err_code_t ret = GPG_ERR_NO_ERROR;
if (! serpent_init_done)
{
/* Execute a self-test the first time, Serpent is used. */
serpent_test_ret = serpent_test ();
if (serpent_test_ret)
log_error ("Serpent test failure: %s\n", serpent_test_ret);
serpent_init_done = 1;
}
if (serpent_test_ret)
ret = GPG_ERR_SELFTEST_FAILED;
else
{
serpent_setkey_internal (context, key, key_length);
_gcry_burn_stack (sizeof (serpent_key_t));
}
return ret;
}
static void
serpent_encrypt_internal (serpent_context_t *context,
const serpent_block_t input, serpent_block_t output)
{
serpent_block_t b, b_next;
int round = 0;
#ifdef WORDS_BIGENDIAN
b[0] = byte_swap_32 (input[0]);
b[1] = byte_swap_32 (input[1]);
b[2] = byte_swap_32 (input[2]);
b[3] = byte_swap_32 (input[3]);
#else
b[0] = input[0];
b[1] = input[1];
b[2] = input[2];
b[3] = input[3];
#endif
ROUND (0, context->keys, b, b_next);
ROUND (1, context->keys, b, b_next);
ROUND (2, context->keys, b, b_next);
ROUND (3, context->keys, b, b_next);
ROUND (4, context->keys, b, b_next);
ROUND (5, context->keys, b, b_next);
ROUND (6, context->keys, b, b_next);
ROUND (7, context->keys, b, b_next);
ROUND (0, context->keys, b, b_next);
ROUND (1, context->keys, b, b_next);
ROUND (2, context->keys, b, b_next);
ROUND (3, context->keys, b, b_next);
ROUND (4, context->keys, b, b_next);
ROUND (5, context->keys, b, b_next);
ROUND (6, context->keys, b, b_next);
ROUND (7, context->keys, b, b_next);
ROUND (0, context->keys, b, b_next);
ROUND (1, context->keys, b, b_next);
ROUND (2, context->keys, b, b_next);
ROUND (3, context->keys, b, b_next);
ROUND (4, context->keys, b, b_next);
ROUND (5, context->keys, b, b_next);
ROUND (6, context->keys, b, b_next);
ROUND (7, context->keys, b, b_next);
ROUND (0, context->keys, b, b_next);
ROUND (1, context->keys, b, b_next);
ROUND (2, context->keys, b, b_next);
ROUND (3, context->keys, b, b_next);
ROUND (4, context->keys, b, b_next);
ROUND (5, context->keys, b, b_next);
ROUND (6, context->keys, b, b_next);
ROUND_LAST (7, context->keys, b, b_next);
#ifdef WORDS_BIGENDIAN
output[0] = byte_swap_32 (b_next[0]);
output[1] = byte_swap_32 (b_next[1]);
output[2] = byte_swap_32 (b_next[2]);
output[3] = byte_swap_32 (b_next[3]);
#else
output[0] = b_next[0];
output[1] = b_next[1];
output[2] = b_next[2];
output[3] = b_next[3];
#endif
}
static void
serpent_decrypt_internal (serpent_context_t *context,
const serpent_block_t input, serpent_block_t output)
{
serpent_block_t b, b_next;
int round = ROUNDS;
#ifdef WORDS_BIGENDIAN
b_next[0] = byte_swap_32 (input[0]);
b_next[1] = byte_swap_32 (input[1]);
b_next[2] = byte_swap_32 (input[2]);
b_next[3] = byte_swap_32 (input[3]);
#else
b_next[0] = input[0];
b_next[1] = input[1];
b_next[2] = input[2];
b_next[3] = input[3];
#endif
ROUND_FIRST_INVERSE (7, context->keys, b_next, b);
ROUND_INVERSE (6, context->keys, b, b_next);
ROUND_INVERSE (5, context->keys, b, b_next);
ROUND_INVERSE (4, context->keys, b, b_next);
ROUND_INVERSE (3, context->keys, b, b_next);
ROUND_INVERSE (2, context->keys, b, b_next);
ROUND_INVERSE (1, context->keys, b, b_next);
ROUND_INVERSE (0, context->keys, b, b_next);
ROUND_INVERSE (7, context->keys, b, b_next);
ROUND_INVERSE (6, context->keys, b, b_next);
ROUND_INVERSE (5, context->keys, b, b_next);
ROUND_INVERSE (4, context->keys, b, b_next);
ROUND_INVERSE (3, context->keys, b, b_next);
ROUND_INVERSE (2, context->keys, b, b_next);
ROUND_INVERSE (1, context->keys, b, b_next);
ROUND_INVERSE (0, context->keys, b, b_next);
ROUND_INVERSE (7, context->keys, b, b_next);
ROUND_INVERSE (6, context->keys, b, b_next);
ROUND_INVERSE (5, context->keys, b, b_next);
ROUND_INVERSE (4, context->keys, b, b_next);
ROUND_INVERSE (3, context->keys, b, b_next);
ROUND_INVERSE (2, context->keys, b, b_next);
ROUND_INVERSE (1, context->keys, b, b_next);
ROUND_INVERSE (0, context->keys, b, b_next);
ROUND_INVERSE (7, context->keys, b, b_next);
ROUND_INVERSE (6, context->keys, b, b_next);
ROUND_INVERSE (5, context->keys, b, b_next);
ROUND_INVERSE (4, context->keys, b, b_next);
ROUND_INVERSE (3, context->keys, b, b_next);
ROUND_INVERSE (2, context->keys, b, b_next);
ROUND_INVERSE (1, context->keys, b, b_next);
ROUND_INVERSE (0, context->keys, b, b_next);
#ifdef WORDS_BIGENDIAN
output[0] = byte_swap_32 (b_next[0]);
output[1] = byte_swap_32 (b_next[1]);
output[2] = byte_swap_32 (b_next[2]);
output[3] = byte_swap_32 (b_next[3]);
#else
output[0] = b_next[0];
output[1] = b_next[1];
output[2] = b_next[2];
output[3] = b_next[3];
#endif
}
static void
serpent_encrypt (void *ctx, byte *buffer_out, const byte *buffer_in)
{
serpent_context_t *context = ctx;
serpent_encrypt_internal (context,
(const u32 *) buffer_in, (u32 *) buffer_out);
_gcry_burn_stack (2 * sizeof (serpent_block_t));
}
static void
serpent_decrypt (void *ctx, byte *buffer_out, const byte *buffer_in)
{
serpent_context_t *context = ctx;
serpent_decrypt_internal (context,
(const u32 *) buffer_in,
(u32 *) buffer_out);
_gcry_burn_stack (2 * sizeof (serpent_block_t));
}
/* Serpent test. */
static const char *
serpent_test (void)
{
serpent_context_t context;
unsigned char scratch[16];
unsigned int i;
static struct test
{
int key_length;
unsigned char key[32];
unsigned char text_plain[16];
unsigned char text_cipher[16];
} test_data[] =
{
{
16,
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00",
"\xD2\x9D\x57\x6F\xCE\xA3\xA3\xA7\xED\x90\x99\xF2\x92\x73\xD7\x8E",
"\xB2\x28\x8B\x96\x8A\xE8\xB0\x86\x48\xD1\xCE\x96\x06\xFD\x99\x2D"
},
{
24,
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
"\x00\x00\x00\x00\x00\x00\x00\x00",
"\xD2\x9D\x57\x6F\xCE\xAB\xA3\xA7\xED\x98\x99\xF2\x92\x7B\xD7\x8E",
"\x13\x0E\x35\x3E\x10\x37\xC2\x24\x05\xE8\xFA\xEF\xB2\xC3\xC3\xE9"
},
{
32,
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00",
"\xD0\x95\x57\x6F\xCE\xA3\xE3\xA7\xED\x98\xD9\xF2\x90\x73\xD7\x8E",
"\xB9\x0E\xE5\x86\x2D\xE6\x91\x68\xF2\xBD\xD5\x12\x5B\x45\x47\x2B"
},
{
32,
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00",
"\x00\x00\x00\x00\x01\x00\x00\x00\x02\x00\x00\x00\x03\x00\x00\x00",
"\x20\x61\xA4\x27\x82\xBD\x52\xEC\x69\x1E\xC3\x83\xB0\x3B\xA7\x7C"
},
{
0
},
};
for (i = 0; test_data[i].key_length; i++)
{
serpent_setkey_internal (&context, test_data[i].key,
test_data[i].key_length);
serpent_encrypt_internal (&context,
(const u32 *) test_data[i].text_plain,
(u32 *) scratch);
if (memcmp (scratch, test_data[i].text_cipher, sizeof (serpent_block_t)))
switch (test_data[i].key_length)
{
case 16:
return "Serpent-128 test encryption failed.";
case 24:
return "Serpent-192 test encryption failed.";
case 32:
return "Serpent-256 test encryption failed.";
}
serpent_decrypt_internal (&context,
(const u32 *) test_data[i].text_cipher,
(u32 *) scratch);
if (memcmp (scratch, test_data[i].text_plain, sizeof (serpent_block_t)))
switch (test_data[i].key_length)
{
case 16:
return "Serpent-128 test decryption failed.";
case 24:
return "Serpent-192 test decryption failed.";
case 32:
return "Serpent-256 test decryption failed.";
}
}
return NULL;
}
/* "SERPENT" is an alias for "SERPENT128". */
static const char *cipher_spec_serpent128_aliases[] =
{
"SERPENT",
NULL
};
gcry_cipher_spec_t _gcry_cipher_spec_serpent128 =
{
"SERPENT128", cipher_spec_serpent128_aliases, NULL, 16, 128,
sizeof (serpent_context_t),
serpent_setkey, serpent_encrypt, serpent_decrypt
};
gcry_cipher_spec_t _gcry_cipher_spec_serpent192 =
{
"SERPENT192", NULL, NULL, 16, 192,
sizeof (serpent_context_t),
serpent_setkey, serpent_encrypt, serpent_decrypt
};
gcry_cipher_spec_t _gcry_cipher_spec_serpent256 =
{
"SERPENT256", NULL, NULL, 16, 256,
sizeof (serpent_context_t),
serpent_setkey, serpent_encrypt, serpent_decrypt
};