/* * $Id: cast-128.c,v 1.12 2003/01/19 17:48:27 nmav Exp $ * * CAST-128 in C * Written by Steve Reid * 100% Public Domain - no warranty * Released 1997.10.11 */ /* Adapted to the pike cryptographic toolkit by Niels Möller */ /* modified in order to use the libmcrypt API by Nikos Mavroyanopoulos * All modifications are placed under the license of libmcrypt. */ /* $Id: cast-128.c,v 1.12 2003/01/19 17:48:27 nmav Exp $ */ #include #include #include "cast-128.h" #define _mcrypt_set_key cast_128_LTX__mcrypt_set_key #define _mcrypt_encrypt cast_128_LTX__mcrypt_encrypt #define _mcrypt_decrypt cast_128_LTX__mcrypt_decrypt #define _mcrypt_get_size cast_128_LTX__mcrypt_get_size #define _mcrypt_get_block_size cast_128_LTX__mcrypt_get_block_size #define _is_block_algorithm cast_128_LTX__is_block_algorithm #define _mcrypt_get_key_size cast_128_LTX__mcrypt_get_key_size #define _mcrypt_get_supported_key_sizes cast_128_LTX__mcrypt_get_supported_key_sizes #define _mcrypt_get_algorithms_name cast_128_LTX__mcrypt_get_algorithms_name #define _mcrypt_self_test cast_128_LTX__mcrypt_self_test #define _mcrypt_algorithm_version cast_128_LTX__mcrypt_algorithm_version #define u8 byte #define u32 word32 #include "cast-128_sboxes.h" /* Macros to access 8-bit bytes out of a 32-bit word */ #define U8a(x) ( (u8) (x>>24) ) #define U8b(x) ( (u8) ((x>>16)&255) ) #define U8c(x) ( (u8) ((x>>8)&255) ) #define U8d(x) ( (u8) ((x)&255) ) /* Circular left shift */ #define ROL(x, n) ( ((x)<<(n)) | ((x)>>(32-(n))) ) /* CAST-128 uses three different round functions */ #define F1(l, r, i) \ t = ROL(key->xkey[i] + r, key->xkey[i+16]); \ l ^= ((cast_sbox1[U8a(t)] ^ cast_sbox2[U8b(t)]) \ - cast_sbox3[U8c(t)]) + cast_sbox4[U8d(t)]; #define F2(l, r, i) \ t = ROL(key->xkey[i] ^ r, key->xkey[i+16]); \ l ^= ((cast_sbox1[U8a(t)] - cast_sbox2[U8b(t)]) \ + cast_sbox3[U8c(t)]) ^ cast_sbox4[U8d(t)]; #define F3(l, r, i) \ t = ROL(key->xkey[i] - r, key->xkey[i+16]); \ l ^= ((cast_sbox1[U8a(t)] + cast_sbox2[U8b(t)]) \ ^ cast_sbox3[U8c(t)]) - cast_sbox4[U8d(t)]; /***** Encryption Function *****/ WIN32DLL_DEFINE void _mcrypt_encrypt(CAST_KEY * key, u8 * block) { u32 t, l, r; /* Get inblock into l,r */ l = ((u32) block[0] << 24) | ((u32) block[1] << 16) | ((u32) block[2] << 8) | (u32) block[3]; r = ((u32) block[4] << 24) | ((u32) block[5] << 16) | ((u32) block[6] << 8) | (u32) block[7]; /* Do the work */ F1(l, r, 0); F2(r, l, 1); F3(l, r, 2); F1(r, l, 3); F2(l, r, 4); F3(r, l, 5); F1(l, r, 6); F2(r, l, 7); F3(l, r, 8); F1(r, l, 9); F2(l, r, 10); F3(r, l, 11); /* Only do full 16 rounds if key length > 80 bits */ if (key->rounds > 12) { F1(l, r, 12); F2(r, l, 13); F3(l, r, 14); F1(r, l, 15); } /* Put l,r into outblock */ block[0] = U8a(r); block[1] = U8b(r); block[2] = U8c(r); block[3] = U8d(r); block[4] = U8a(l); block[5] = U8b(l); block[6] = U8c(l); block[7] = U8d(l); /* Wipe clean */ t = l = r = 0; } /***** Decryption Function *****/ WIN32DLL_DEFINE void _mcrypt_decrypt(CAST_KEY * key, u8 * block) { u32 t, l, r; /* Get inblock into l,r */ r = ((u32) block[0] << 24) | ((u32) block[1] << 16) | ((u32) block[2] << 8) | (u32) block[3]; l = ((u32) block[4] << 24) | ((u32) block[5] << 16) | ((u32) block[6] << 8) | (u32) block[7]; /* Do the work */ /* Only do full 16 rounds if key length > 80 bits */ if (key->rounds > 12) { F1(r, l, 15); F3(l, r, 14); F2(r, l, 13); F1(l, r, 12); } F3(r, l, 11); F2(l, r, 10); F1(r, l, 9); F3(l, r, 8); F2(r, l, 7); F1(l, r, 6); F3(r, l, 5); F2(l, r, 4); F1(r, l, 3); F3(l, r, 2); F2(r, l, 1); F1(l, r, 0); /* Put l,r into outblock */ block[0] = U8a(l); block[1] = U8b(l); block[2] = U8c(l); block[3] = U8d(l); block[4] = U8a(r); block[5] = U8b(r); block[6] = U8c(r); block[7] = U8d(r); /* Wipe clean */ t = l = r = 0; } /***** Key Schedual *****/ WIN32DLL_DEFINE int _mcrypt_set_key(CAST_KEY * key, u8 * rawkey, unsigned keybytes) { u32 t[4], z[4], x[4]; unsigned i; /* Set number of rounds to 12 or 16, depending on key length */ key->rounds = (keybytes <= CAST_SMALL_KEY) ? CAST_SMALL_ROUNDS : CAST_FULL_ROUNDS; /* Copy key to workspace x */ for (i = 0; i < 4; i++) { x[i] = 0; if ((i * 4 + 0) < keybytes) x[i] = (u32) rawkey[i * 4 + 0] << 24; if ((i * 4 + 1) < keybytes) x[i] |= (u32) rawkey[i * 4 + 1] << 16; if ((i * 4 + 2) < keybytes) x[i] |= (u32) rawkey[i * 4 + 2] << 8; if ((i * 4 + 3) < keybytes) x[i] |= (u32) rawkey[i * 4 + 3]; } /* Generate 32 subkeys, four at a time */ for (i = 0; i < 32; i += 4) { switch (i & 4) { case 0: t[0] = z[0] = x[0] ^ cast_sbox5[U8b(x[3])] ^ cast_sbox6[U8d(x[3])] ^ cast_sbox7[U8a(x[3])] ^ cast_sbox8[U8c(x[3])] ^ cast_sbox7[U8a(x[2])]; t[1] = z[1] = x[2] ^ cast_sbox5[U8a(z[0])] ^ cast_sbox6[U8c(z[0])] ^ cast_sbox7[U8b(z[0])] ^ cast_sbox8[U8d(z[0])] ^ cast_sbox8[U8c(x[2])]; t[2] = z[2] = x[3] ^ cast_sbox5[U8d(z[1])] ^ cast_sbox6[U8c(z[1])] ^ cast_sbox7[U8b(z[1])] ^ cast_sbox8[U8a(z[1])] ^ cast_sbox5[U8b(x[2])]; t[3] = z[3] = x[1] ^ cast_sbox5[U8c(z[2])] ^ cast_sbox6[U8b(z[2])] ^ cast_sbox7[U8d(z[2])] ^ cast_sbox8[U8a(z[2])] ^ cast_sbox6[U8d(x[2])]; break; case 4: t[0] = x[0] = z[2] ^ cast_sbox5[U8b(z[1])] ^ cast_sbox6[U8d(z[1])] ^ cast_sbox7[U8a(z[1])] ^ cast_sbox8[U8c(z[1])] ^ cast_sbox7[U8a(z[0])]; t[1] = x[1] = z[0] ^ cast_sbox5[U8a(x[0])] ^ cast_sbox6[U8c(x[0])] ^ cast_sbox7[U8b(x[0])] ^ cast_sbox8[U8d(x[0])] ^ cast_sbox8[U8c(z[0])]; t[2] = x[2] = z[1] ^ cast_sbox5[U8d(x[1])] ^ cast_sbox6[U8c(x[1])] ^ cast_sbox7[U8b(x[1])] ^ cast_sbox8[U8a(x[1])] ^ cast_sbox5[U8b(z[0])]; t[3] = x[3] = z[3] ^ cast_sbox5[U8c(x[2])] ^ cast_sbox6[U8b(x[2])] ^ cast_sbox7[U8d(x[2])] ^ cast_sbox8[U8a(x[2])] ^ cast_sbox6[U8d(z[0])]; break; } switch (i & 12) { case 0: case 12: key->xkey[i + 0] = cast_sbox5[U8a(t[2])] ^ cast_sbox6[U8b(t[2])] ^ cast_sbox7[U8d(t[1])] ^ cast_sbox8[U8c(t[1])]; key->xkey[i + 1] = cast_sbox5[U8c(t[2])] ^ cast_sbox6[U8d(t[2])] ^ cast_sbox7[U8b(t[1])] ^ cast_sbox8[U8a(t[1])]; key->xkey[i + 2] = cast_sbox5[U8a(t[3])] ^ cast_sbox6[U8b(t[3])] ^ cast_sbox7[U8d(t[0])] ^ cast_sbox8[U8c(t[0])]; key->xkey[i + 3] = cast_sbox5[U8c(t[3])] ^ cast_sbox6[U8d(t[3])] ^ cast_sbox7[U8b(t[0])] ^ cast_sbox8[U8a(t[0])]; break; case 4: case 8: key->xkey[i + 0] = cast_sbox5[U8d(t[0])] ^ cast_sbox6[U8c(t[0])] ^ cast_sbox7[U8a(t[3])] ^ cast_sbox8[U8b(t[3])]; key->xkey[i + 1] = cast_sbox5[U8b(t[0])] ^ cast_sbox6[U8a(t[0])] ^ cast_sbox7[U8c(t[3])] ^ cast_sbox8[U8d(t[3])]; key->xkey[i + 2] = cast_sbox5[U8d(t[1])] ^ cast_sbox6[U8c(t[1])] ^ cast_sbox7[U8a(t[2])] ^ cast_sbox8[U8b(t[2])]; key->xkey[i + 3] = cast_sbox5[U8b(t[1])] ^ cast_sbox6[U8a(t[1])] ^ cast_sbox7[U8c(t[2])] ^ cast_sbox8[U8d(t[2])]; break; } switch (i & 12) { case 0: key->xkey[i + 0] ^= cast_sbox5[U8c(z[0])]; key->xkey[i + 1] ^= cast_sbox6[U8c(z[1])]; key->xkey[i + 2] ^= cast_sbox7[U8b(z[2])]; key->xkey[i + 3] ^= cast_sbox8[U8a(z[3])]; break; case 4: key->xkey[i + 0] ^= cast_sbox5[U8a(x[2])]; key->xkey[i + 1] ^= cast_sbox6[U8b(x[3])]; key->xkey[i + 2] ^= cast_sbox7[U8d(x[0])]; key->xkey[i + 3] ^= cast_sbox8[U8d(x[1])]; break; case 8: key->xkey[i + 0] ^= cast_sbox5[U8b(z[2])]; key->xkey[i + 1] ^= cast_sbox6[U8a(z[3])]; key->xkey[i + 2] ^= cast_sbox7[U8c(z[0])]; key->xkey[i + 3] ^= cast_sbox8[U8c(z[1])]; break; case 12: key->xkey[i + 0] ^= cast_sbox5[U8d(x[0])]; key->xkey[i + 1] ^= cast_sbox6[U8d(x[1])]; key->xkey[i + 2] ^= cast_sbox7[U8a(x[2])]; key->xkey[i + 3] ^= cast_sbox8[U8b(x[3])]; break; } if (i >= 16) { key->xkey[i + 0] &= 31; key->xkey[i + 1] &= 31; key->xkey[i + 2] &= 31; key->xkey[i + 3] &= 31; } } /* Wipe clean */ for (i = 0; i < 4; i++) { t[i] = x[i] = z[i] = 0; } return 0; } /* Made in Canada */ WIN32DLL_DEFINE int _mcrypt_get_size() { return sizeof(CAST_KEY); } WIN32DLL_DEFINE int _mcrypt_get_block_size() { return 8; } WIN32DLL_DEFINE int _is_block_algorithm() { return 1; } WIN32DLL_DEFINE int _mcrypt_get_key_size() { return 16; } static const int key_sizes[] = { 16 }; WIN32DLL_DEFINE const int *_mcrypt_get_supported_key_sizes(int *len) { *len = sizeof(key_sizes)/sizeof(int); return key_sizes; } WIN32DLL_DEFINE const char *_mcrypt_get_algorithms_name() { return "CAST-128"; } #define CIPHER "434e25460c8c9525" WIN32DLL_DEFINE int _mcrypt_self_test() { char *keyword; unsigned char plaintext[16]; unsigned char ciphertext[16]; int blocksize = _mcrypt_get_block_size(), j; void *key; unsigned char cipher_tmp[200]; keyword = calloc(1, _mcrypt_get_key_size()); if (keyword == NULL) return -1; for (j = 0; j < _mcrypt_get_key_size(); j++) { keyword[j] = ((j * 2 + 10) % 256); } for (j = 0; j < blocksize; j++) { plaintext[j] = j % 256; } key = malloc(_mcrypt_get_size()); if (key == NULL) return -1; memcpy(ciphertext, plaintext, blocksize); _mcrypt_set_key(key, (void *) keyword, _mcrypt_get_key_size()); free(keyword); _mcrypt_encrypt(key, (void *) ciphertext); for (j = 0; j < blocksize; j++) { sprintf(&((char *) cipher_tmp)[2 * j], "%.2x", ciphertext[j]); } if (strcmp((char *) cipher_tmp, CIPHER) != 0) { printf("failed compatibility\n"); printf("Expected: %s\nGot: %s\n", CIPHER, (char *) cipher_tmp); free(key); return -1; } _mcrypt_decrypt(key, (void *) ciphertext); free(key); if (strcmp(ciphertext, plaintext) != 0) { printf("failed internally\n"); return -1; } return 0; } WIN32DLL_DEFINE word32 _mcrypt_algorithm_version() { return 20010801; } #ifdef WIN32 # ifdef USE_LTDL WIN32DLL_DEFINE int main (void) { /* empty main function to avoid linker error (see cygwin FAQ) */ } # endif #endif