twofish.h
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/*
* Copyright (C) 2013 Freie Universität Berlin, Computer Systems & Telematics
*
* This file is subject to the terms and conditions of the GNU Lesser
* General Public License v2.1. See the file LICENSE in the top level
* directory for more details.
*/
/**
* @ingroup sys_crypto
* @{
*
* @file
* @brief Headers for the implementation of the TwoFish Cipher-Algorithm
*
* @author Freie Universitaet Berlin, Computer Systems & Telematics
* @author Nicolai Schmittberger <nicolai.schmittberger@fu-berlin.de>
* @author Zakaria Kasmi <zkasmi@inf.fu-berlin.de> *
*/
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#include <stdlib.h>
#include <stdint.h>
#include "crypto/ciphers.h"
#ifndef TWOFISH_H_
#define TWOFISH_H_
#ifdef __cplusplus
extern "C" {
#endif
#define TWOFISH_BLOCK_SIZE 16
#define TWOFISH_KEY_SIZE 16 //only alternative is 32!
#define TWOFISH_CONTEXT_SIZE 20
/**
* Macro to perform one column of the RS matrix multiplication. The
* parameters a, b, c, and d are the four bytes of output; i is the index
* of the key bytes, and w, x, y, and z, are the column of constants from
* the RS matrix, preprocessed through the poly_to_exp table.
**/
#define CALC_S(a, b, c, d, i, w, x, y, z) \
if (key[i]) { \
tmp = poly_to_exp[key[i] - 1]; \
(a) ^= exp_to_poly[tmp + (w)]; \
(b) ^= exp_to_poly[tmp + (x)]; \
(c) ^= exp_to_poly[tmp + (y)]; \
(d) ^= exp_to_poly[tmp + (z)]; \
}
/**
* Macros to calculate the key-dependent S-boxes for a 128-bit key using
* the S vector from CALC_S. CALC_SB_2 computes a single entry in all
* four S-boxes, where i is the index of the entry to compute, and a and b
* are the index numbers preprocessed through the q0 and q1 tables
* respectively. CALC_SB is simply a convenience to make the code shorter;
* it calls CALC_SB_2 four times with consecutive indices from i to i+3,
* using the remaining parameters two by two.
**/
#define CALC_SB_2(i, a, b) \
ctx->s[0][i] = mds[0][q0[(a) ^ sa] ^ se]; \
ctx->s[1][i] = mds[1][q0[(b) ^ sb] ^ sf]; \
ctx->s[2][i] = mds[2][q1[(a) ^ sc] ^ sg]; \
ctx->s[3][i] = mds[3][q1[(b) ^ sd] ^ sh]
#define CALC_SB(i, a, b, c, d, e, f, g, h) \
CALC_SB_2 (i, a, b); CALC_SB_2 ((i)+1, c, d); \
CALC_SB_2 ((i)+2, e, f); CALC_SB_2 ((i)+3, g, h)
/* Macros exactly like CALC_SB and CALC_SB_2, but for 256-bit keys. */
#define CALC_SB256_2(i, a, b) \
ctx->s[0][i] = mds[0][q0[q0[q1[(b) ^ sa] ^ se] ^ si] ^ sm]; \
ctx->s[1][i] = mds[1][q0[q1[q1[(a) ^ sb] ^ sf] ^ sj] ^ sn]; \
ctx->s[2][i] = mds[2][q1[q0[q0[(a) ^ sc] ^ sg] ^ sk] ^ so]; \
ctx->s[3][i] = mds[3][q1[q1[q0[(b) ^ sd] ^ sh] ^ sl] ^ sp];
#define CALC_SB256(i, a, b, c, d, e, f, g, h) \
CALC_SB256_2 (i, a, b); CALC_SB256_2 ((i)+1, c, d); \
CALC_SB256_2 ((i)+2, e, f); CALC_SB256_2 ((i)+3, g, h)
/**
* Macros to calculate the whitening and round subkeys. CALC_K_2 computes the
* last two stages of the h() function for a given index (either 2i or 2i+1).
* a, b, c, and d are the four bytes going into the last two stages. For
* 128-bit keys, this is the entire h() function and a and c are the index
* preprocessed through q0 and q1 respectively; for longer keys they are the
* output of previous stages. j is the index of the first key byte to use.
* CALC_K computes a pair of subkeys for 128-bit Twofish, by calling CALC_K_2
* twice, doing the Psuedo-Hadamard Transform, and doing the necessary
* rotations. Its parameters are: a, the array to write the results into,
* j, the index of the first output entry, k and l, the preprocessed indices
* for index 2i, and m and n, the preprocessed indices for index 2i+1.
* CALC_K256_2 expands CALC_K_2 to handle 256-bit keys, by doing two
* additional lookup-and-XOR stages. The parameters a and b are the index
* preprocessed through q0 and q1 respectively; j is the index of the first
* key byte to use. CALC_K256 is identical to CALC_K but for using the
* CALC_K256_2 macro instead of CALC_K_2.
**/
#define CALC_K_2(a, b, c, d, j) \
mds[0][q0[a ^ key[(j) + 8]] ^ key[j]] \
^ mds[1][q0[b ^ key[(j) + 9]] ^ key[(j) + 1]] \
^ mds[2][q1[c ^ key[(j) + 10]] ^ key[(j) + 2]] \
^ mds[3][q1[d ^ key[(j) + 11]] ^ key[(j) + 3]]
#define CALC_K(a, j, k, l, m, n) \
x = CALC_K_2 (k, l, k, l, 0); \
y = CALC_K_2 (m, n, m, n, 4); \
y = (y << 8) + (y >> 24); \
x += y; y += x; ctx->a[j] = x; \
ctx->a[(j) + 1] = (y << 9) + (y >> 23)
#define CALC_K256_2(a, b, j) \
CALC_K_2 (q0[q1[b ^ key[(j) + 24]] ^ key[(j) + 16]], \
q1[q1[a ^ key[(j) + 25]] ^ key[(j) + 17]], \
q0[q0[a ^ key[(j) + 26]] ^ key[(j) + 18]], \
q1[q0[b ^ key[(j) + 27]] ^ key[(j) + 19]], j)
#define CALC_K256(a, j, k, l, m, n) \
x = CALC_K256_2 (k, l, 0); \
y = CALC_K256_2 (m, n, 4); \
y = (y << 8) + (y >> 24); \
x += y; y += x; ctx->a[j] = x; \
ctx->a[(j) + 1] = (y << 9) + (y >> 23)
/**
* Macros to compute the g() function in the encryption and decryption
* rounds. G1 is the straight g() function; G2 includes the 8-bit
* rotation for the high 32-bit word.
**/
#define G1(a) \
(ctx->s[0][(a) & 0xFF]) ^ (ctx->s[1][((a) >> 8) & 0xFF]) \
^ (ctx->s[2][((a) >> 16) & 0xFF]) ^ (ctx->s[3][(a) >> 24])
#define G2(b) \
(ctx->s[1][(b) & 0xFF]) ^ (ctx->s[2][((b) >> 8) & 0xFF]) \
^ (ctx->s[3][((b) >> 16) & 0xFF]) ^ (ctx->s[0][(b) >> 24])
/**
* Encryption and decryption Feistel rounds. Each one calls the two g()
* macros, does the PHT, and performs the XOR and the appropriate bit
* rotations. The parameters are the round number (used to select subkeys),
* and the four 32-bit chunks of the text.
**/
#define ENCROUND(n, a, b, c, d) \
x = G1 (a); y = G2 (b); \
x += y; y += x + ctx->k[2 * (n) + 1]; \
(c) ^= x + ctx->k[2 * (n)]; \
(c) = ((c) >> 1) + ((c) << 31); \
(d) = (((d) << 1)+((d) >> 31)) ^ y
#define DECROUND(n, a, b, c, d) \
x = G1 (a); y = G2 (b); \
x += y; y += x; \
(d) ^= y + ctx->k[2 * (n) + 1]; \
(d) = ((d) >> 1) + ((d) << 31); \
(c) = (((c) << 1)+((c) >> 31)); \
(c) ^= (x + ctx->k[2 * (n)])
/**
* Encryption and decryption cycles; each one is simply two Feistel rounds
* with the 32-bit chunks re-ordered to simulate the "swap"
**/
#define ENCCYCLE(n) \
ENCROUND (2 * (n), a, b, c, d); \
ENCROUND (2 * (n) + 1, c, d, a, b)
#define DECCYCLE(n) \
DECROUND (2 * (n) + 1, c, d, a, b); \
DECROUND (2 * (n), a, b, c, d)
/**
* Macros to convert the input and output bytes into 32-bit words,
* and simultaneously perform the whitening step. INPACK packs word
* number n into the variable named by x, using whitening subkey number m.
* OUTUNPACK unpacks word number n from the variable named by x, using
* whitening subkey number m.
**/
#define INPACK(n, x, m) \
x = in[4 * (n)] ^ (in[4 * (n) + 1] << 8) \
^ ((uint32_t)in[4 * (n) + 2] << 16) ^ ((uint32_t)in[4 * (n) + 3] << 24) ^ ctx->w[m]
#define OUTUNPACK(n, x, m) \
x ^= ctx->w[m]; \
out[4 * (n)] = x; out[4 * (n) + 1] = x >> 8; \
out[4 * (n) + 2] = x >> 16; out[4 * (n) + 3] = x >> 24
/**
* @brief Structure for an expanded Twofish key.
*
* Note that k[i] corresponds to what the Twofish paper calls K[i+8].
*/
typedef struct {
/** contains the key-dependent S-boxes composed with the MDS matrix */
uint32_t s[4][256],
/** contains the eight "whitening" subkeys, K[0] through K[7] */
w[8],
/** holds the remaining, "round" subkeys */
k[32];
} twofish_context_t;
/**
* @brief Initialize the TwoFish-BlockCipher context.
*
* @param context structure to hold the opaque data from this
* initialization
* call. It should be passed to future invocations of
* this module
* which use this particular key.
* @param key_size key size in bytes
* @param key pointer to the key
*
* @return CIPHER_INIT_SUCCESS if the initialization was successful.
* The command may be unsuccessful if the key size is not valid.
* CIPHER_ERR_BAD_CONTEXT_SIZE if CIPHER_MAX_CONTEXT_SIZE has not been defined (which means that the cipher has not been included in the build)
*/
int twofish_init(cipher_context_t *context, const uint8_t *key, uint8_t key_size);
/**
* @brief Encrypts a single block (of blockSize) using the passed context.
*
* @param context holds the module specific opaque data related to the
* key (perhaps key expansions).
* @param in a plaintext block of blockSize
* @param out the resulting ciphertext block of blockSize
*
* @return Whether the encryption was successful. Possible failure reasons
* include not calling init().
*/
int twofish_encrypt(const cipher_context_t *context, const uint8_t *in, uint8_t *out);
/**
* @brief Decrypts a single block (of blockSize) using the passed context.
*
* @param context holds the module specific opaque data related to the
* key (perhaps key expansions).
* @param in a ciphertext block of blockSize
* @param out the resulting plaintext block of blockSize
*
* @return Whether the decryption was successful. Possible failure reasons
* include not calling init()
*/
int twofish_decrypt(const cipher_context_t *context, const uint8_t *in, uint8_t *out);
#ifdef __cplusplus
}
#endif
/** @} */
#endif /* TWOFISH_H_ */