Mercurial > dropbear
view rc2.c @ 211:f01f0400314d libtomcrypt
disapproval of revision 6a39eb8b36778460fca83b8149df2a8b6d3327fd
| author | Matt Johnston <matt@ucc.asn.au> |
|---|---|
| date | Wed, 06 Jul 2005 13:23:45 +0000 |
| parents | d7da3b1e1540 |
| children | 5d99163f7e32 |
line wrap: on
line source
/* LibTomCrypt, modular cryptographic library -- Tom St Denis * * LibTomCrypt is a library that provides various cryptographic * algorithms in a highly modular and flexible manner. * * The library is free for all purposes without any express * guarantee it works. * * Tom St Denis, [email protected], http://libtomcrypt.org */ /**********************************************************************\ * To commemorate the 1996 RSA Data Security Conference, the following * * code is released into the public domain by its author. Prost! * * * * This cipher uses 16-bit words and little-endian byte ordering. * * I wonder which processor it was optimized for? * * * * Thanks to CodeView, SoftIce, and D86 for helping bring this code to * * the public. * \**********************************************************************/ #include <mycrypt.h> #ifdef RC2 const struct _cipher_descriptor rc2_desc = { "rc2", 12, 8, 128, 8, 16, &rc2_setup, &rc2_ecb_encrypt, &rc2_ecb_decrypt, &rc2_test, &rc2_keysize }; /**********************************************************************\ * Expand a variable-length user key (between 1 and 128 bytes) to a * * 64-short working rc2 key, of at most "bits" effective key bits. * * The effective key bits parameter looks like an export control hack. * * For normal use, it should always be set to 1024. For convenience, * * zero is accepted as an alias for 1024. * \**********************************************************************/ /* 256-entry permutation table, probably derived somehow from pi */ static const unsigned char permute[256] = { 217,120,249,196, 25,221,181,237, 40,233,253,121, 74,160,216,157, 198,126, 55,131, 43,118, 83,142, 98, 76,100,136, 68,139,251,162, 23,154, 89,245,135,179, 79, 19, 97, 69,109,141, 9,129,125, 50, 189,143, 64,235,134,183,123, 11,240,149, 33, 34, 92,107, 78,130, 84,214,101,147,206, 96,178, 28,115, 86,192, 20,167,140,241,220, 18,117,202, 31, 59,190,228,209, 66, 61,212, 48,163, 60,182, 38, 111,191, 14,218, 70,105, 7, 87, 39,242, 29,155,188,148, 67, 3, 248, 17,199,246,144,239, 62,231, 6,195,213, 47,200,102, 30,215, 8,232,234,222,128, 82,238,247,132,170,114,172, 53, 77,106, 42, 150, 26,210,113, 90, 21, 73,116, 75,159,208, 94, 4, 24,164,236, 194,224, 65,110, 15, 81,203,204, 36,145,175, 80,161,244,112, 57, 153,124, 58,133, 35,184,180,122,252, 2, 54, 91, 37, 85,151, 49, 45, 93,250,152,227,138,146,174, 5,223, 41, 16,103,108,186,201, 211, 0,230,207,225,158,168, 44, 99, 22, 1, 63, 88,226,137,169, 13, 56, 52, 27,171, 51,255,176,187, 72, 12, 95,185,177,205, 46, 197,243,219, 71,229,165,156,119, 10,166, 32,104,254,127,193,173 }; int rc2_setup(const unsigned char *key, int keylen, int rounds, symmetric_key *skey) { unsigned *xkey = skey->rc2.xkey; unsigned char tmp[128]; unsigned T8, TM; int i, bits; _ARGCHK(key != NULL); _ARGCHK(skey != NULL); if (keylen < 8 || keylen > 128) { return CRYPT_INVALID_KEYSIZE; } if (rounds != 0 && rounds != 16) { return CRYPT_INVALID_ROUNDS; } for (i = 0; i < keylen; i++) { tmp[i] = key[i] & 255; } /* Phase 1: Expand input key to 128 bytes */ if (keylen < 128) { for (i = keylen; i < 128; i++) { tmp[i] = permute[(int)((tmp[i - 1] + tmp[i - keylen]) & 255)]; } } /* Phase 2 - reduce effective key size to "bits" */ bits = keylen*8; T8 = (unsigned)(bits+7)>>3; TM = (255 >> (unsigned)(7 & -bits)); tmp[128 - T8] = permute[(int)(tmp[128 - T8] & TM)]; for (i = 127 - T8; i >= 0; i--) { tmp[i] = permute[(int)(tmp[i + 1] ^ tmp[i + T8])]; } /* Phase 3 - copy to xkey in little-endian order */ i = 63; do { xkey[i] = (unsigned)tmp[2*i] + ((unsigned)tmp[2*i+1] << 8); } while (i-- > 0); #ifdef CLEAN_STACK zeromem(tmp, sizeof(tmp)); #endif return CRYPT_OK; } /**********************************************************************\ * Encrypt an 8-byte block of plaintext using the given key. * \**********************************************************************/ #ifdef CLEAN_STACK static void _rc2_ecb_encrypt( const unsigned char *plain, unsigned char *cipher, symmetric_key *skey) #else void rc2_ecb_encrypt( const unsigned char *plain, unsigned char *cipher, symmetric_key *skey) #endif { unsigned *xkey; unsigned x76, x54, x32, x10, i; _ARGCHK(plain != NULL); _ARGCHK(cipher != NULL); _ARGCHK(skey != NULL); xkey = skey->rc2.xkey; x76 = ((unsigned)plain[7] << 8) + (unsigned)plain[6]; x54 = ((unsigned)plain[5] << 8) + (unsigned)plain[4]; x32 = ((unsigned)plain[3] << 8) + (unsigned)plain[2]; x10 = ((unsigned)plain[1] << 8) + (unsigned)plain[0]; for (i = 0; i < 16; i++) { x10 = (x10 + (x32 & ~x76) + (x54 & x76) + xkey[4*i+0]) & 0xFFFF; x10 = ((x10 << 1) | (x10 >> 15)) & 0xFFFF; x32 = (x32 + (x54 & ~x10) + (x76 & x10) + xkey[4*i+1]) & 0xFFFF; x32 = ((x32 << 2) | (x32 >> 14)) & 0xFFFF; x54 = (x54 + (x76 & ~x32) + (x10 & x32) + xkey[4*i+2]) & 0xFFFF; x54 = ((x54 << 3) | (x54 >> 13)) & 0xFFFF; x76 = (x76 + (x10 & ~x54) + (x32 & x54) + xkey[4*i+3]) & 0xFFFF; x76 = ((x76 << 5) | (x76 >> 11)) & 0xFFFF; if (i == 4 || i == 10) { x10 = (x10 + xkey[x76 & 63]) & 0xFFFF; x32 = (x32 + xkey[x10 & 63]) & 0xFFFF; x54 = (x54 + xkey[x32 & 63]) & 0xFFFF; x76 = (x76 + xkey[x54 & 63]) & 0xFFFF; } } cipher[0] = (unsigned char)x10; cipher[1] = (unsigned char)(x10 >> 8); cipher[2] = (unsigned char)x32; cipher[3] = (unsigned char)(x32 >> 8); cipher[4] = (unsigned char)x54; cipher[5] = (unsigned char)(x54 >> 8); cipher[6] = (unsigned char)x76; cipher[7] = (unsigned char)(x76 >> 8); } #ifdef CLEAN_STACK void rc2_ecb_encrypt( const unsigned char *plain, unsigned char *cipher, symmetric_key *skey) { _rc2_ecb_encrypt(plain, cipher, skey); burn_stack(sizeof(unsigned *) + sizeof(unsigned) * 5); } #endif /**********************************************************************\ * Decrypt an 8-byte block of ciphertext using the given key. * \**********************************************************************/ #ifdef CLEAN_STACK static void _rc2_ecb_decrypt( const unsigned char *cipher, unsigned char *plain, symmetric_key *skey) #else void rc2_ecb_decrypt( const unsigned char *cipher, unsigned char *plain, symmetric_key *skey) #endif { unsigned x76, x54, x32, x10; unsigned *xkey; int i; _ARGCHK(plain != NULL); _ARGCHK(cipher != NULL); _ARGCHK(skey != NULL); xkey = skey->rc2.xkey; x76 = ((unsigned)cipher[7] << 8) + (unsigned)cipher[6]; x54 = ((unsigned)cipher[5] << 8) + (unsigned)cipher[4]; x32 = ((unsigned)cipher[3] << 8) + (unsigned)cipher[2]; x10 = ((unsigned)cipher[1] << 8) + (unsigned)cipher[0]; for (i = 15; i >= 0; i--) { if (i == 4 || i == 10) { x76 = (x76 - xkey[x54 & 63]) & 0xFFFF; x54 = (x54 - xkey[x32 & 63]) & 0xFFFF; x32 = (x32 - xkey[x10 & 63]) & 0xFFFF; x10 = (x10 - xkey[x76 & 63]) & 0xFFFF; } x76 = ((x76 << 11) | (x76 >> 5)) & 0xFFFF; x76 = (x76 - ((x10 & ~x54) + (x32 & x54) + xkey[4*i+3])) & 0xFFFF; x54 = ((x54 << 13) | (x54 >> 3)) & 0xFFFF; x54 = (x54 - ((x76 & ~x32) + (x10 & x32) + xkey[4*i+2])) & 0xFFFF; x32 = ((x32 << 14) | (x32 >> 2)) & 0xFFFF; x32 = (x32 - ((x54 & ~x10) + (x76 & x10) + xkey[4*i+1])) & 0xFFFF; x10 = ((x10 << 15) | (x10 >> 1)) & 0xFFFF; x10 = (x10 - ((x32 & ~x76) + (x54 & x76) + xkey[4*i+0])) & 0xFFFF; } plain[0] = (unsigned char)x10; plain[1] = (unsigned char)(x10 >> 8); plain[2] = (unsigned char)x32; plain[3] = (unsigned char)(x32 >> 8); plain[4] = (unsigned char)x54; plain[5] = (unsigned char)(x54 >> 8); plain[6] = (unsigned char)x76; plain[7] = (unsigned char)(x76 >> 8); } #ifdef CLEAN_STACK void rc2_ecb_decrypt( const unsigned char *cipher, unsigned char *plain, symmetric_key *skey) { _rc2_ecb_decrypt(cipher, plain, skey); burn_stack(sizeof(unsigned *) + sizeof(unsigned) * 4 + sizeof(int)); } #endif int rc2_test(void) { #ifndef LTC_TEST return CRYPT_NOP; #else static const struct { int keylen; unsigned char key[16], pt[8], ct[8]; } tests[] = { { 8, { 0x30, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }, { 0x10, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01 }, { 0x30, 0x64, 0x9e, 0xdf, 0x9b, 0xe7, 0xd2, 0xc2 } }, { 16, { 0x88, 0xbc, 0xa9, 0x0e, 0x90, 0x87, 0x5a, 0x7f, 0x0f, 0x79, 0xc3, 0x84, 0x62, 0x7b, 0xaf, 0xb2 }, { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }, { 0x22, 0x69, 0x55, 0x2a, 0xb0, 0xf8, 0x5c, 0xa6 } } }; int x, y, err; symmetric_key skey; unsigned char tmp[2][8]; for (x = 0; x < (int)(sizeof(tests) / sizeof(tests[0])); x++) { zeromem(tmp, sizeof(tmp)); if ((err = rc2_setup(tests[x].key, tests[x].keylen, 0, &skey)) != CRYPT_OK) { return err; } rc2_ecb_encrypt(tests[x].pt, tmp[0], &skey); rc2_ecb_decrypt(tmp[0], tmp[1], &skey); if (memcmp(tmp[0], tests[x].ct, 8) != 0 || memcmp(tmp[1], tests[x].pt, 8) != 0) { return CRYPT_FAIL_TESTVECTOR; } /* now see if we can encrypt all zero bytes 1000 times, decrypt and come back where we started */ for (y = 0; y < 8; y++) tmp[0][y] = 0; for (y = 0; y < 1000; y++) rc2_ecb_encrypt(tmp[0], tmp[0], &skey); for (y = 0; y < 1000; y++) rc2_ecb_decrypt(tmp[0], tmp[0], &skey); for (y = 0; y < 8; y++) if (tmp[0][y] != 0) return CRYPT_FAIL_TESTVECTOR; } return CRYPT_OK; #endif } int rc2_keysize(int *keysize) { _ARGCHK(keysize != NULL); if (*keysize < 8) { return CRYPT_INVALID_KEYSIZE; } else if (*keysize > 128) { *keysize = 128; } return CRYPT_OK; } #endif