/* * RC6 * (C) 1999-2007 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include namespace Botan { BOTAN_REGISTER_BLOCK_CIPHER_NOARGS(RC6); /* * RC6 Encryption */ void RC6::encrypt_n(const byte in[], byte out[], size_t blocks) const { for(size_t i = 0; i != blocks; ++i) { u32bit A = load_le(in, 0); u32bit B = load_le(in, 1); u32bit C = load_le(in, 2); u32bit D = load_le(in, 3); B += S[0]; D += S[1]; for(size_t j = 0; j != 20; j += 4) { u32bit T1, T2; T1 = rotate_left(B*(2*B+1), 5); T2 = rotate_left(D*(2*D+1), 5); A = rotate_left(A ^ T1, T2 % 32) + S[2*j+2]; C = rotate_left(C ^ T2, T1 % 32) + S[2*j+3]; T1 = rotate_left(C*(2*C+1), 5); T2 = rotate_left(A*(2*A+1), 5); B = rotate_left(B ^ T1, T2 % 32) + S[2*j+4]; D = rotate_left(D ^ T2, T1 % 32) + S[2*j+5]; T1 = rotate_left(D*(2*D+1), 5); T2 = rotate_left(B*(2*B+1), 5); C = rotate_left(C ^ T1, T2 % 32) + S[2*j+6]; A = rotate_left(A ^ T2, T1 % 32) + S[2*j+7]; T1 = rotate_left(A*(2*A+1), 5); T2 = rotate_left(C*(2*C+1), 5); D = rotate_left(D ^ T1, T2 % 32) + S[2*j+8]; B = rotate_left(B ^ T2, T1 % 32) + S[2*j+9]; } A += S[42]; C += S[43]; store_le(out, A, B, C, D); in += BLOCK_SIZE; out += BLOCK_SIZE; } } /* * RC6 Decryption */ void RC6::decrypt_n(const byte in[], byte out[], size_t blocks) const { for(size_t i = 0; i != blocks; ++i) { u32bit A = load_le(in, 0); u32bit B = load_le(in, 1); u32bit C = load_le(in, 2); u32bit D = load_le(in, 3); C -= S[43]; A -= S[42]; for(size_t j = 0; j != 20; j += 4) { u32bit T1, T2; T1 = rotate_left(A*(2*A+1), 5); T2 = rotate_left(C*(2*C+1), 5); B = rotate_right(B - S[41 - 2*j], T1 % 32) ^ T2; D = rotate_right(D - S[40 - 2*j], T2 % 32) ^ T1; T1 = rotate_left(D*(2*D+1), 5); T2 = rotate_left(B*(2*B+1), 5); A = rotate_right(A - S[39 - 2*j], T1 % 32) ^ T2; C = rotate_right(C - S[38 - 2*j], T2 % 32) ^ T1; T1 = rotate_left(C*(2*C+1), 5); T2 = rotate_left(A*(2*A+1), 5); D = rotate_right(D - S[37 - 2*j], T1 % 32) ^ T2; B = rotate_right(B - S[36 - 2*j], T2 % 32) ^ T1; T1 = rotate_left(B*(2*B+1), 5); T2 = rotate_left(D*(2*D+1), 5); C = rotate_right(C - S[35 - 2*j], T1 % 32) ^ T2; A = rotate_right(A - S[34 - 2*j], T2 % 32) ^ T1; } D -= S[1]; B -= S[0]; store_le(out, A, B, C, D); in += BLOCK_SIZE; out += BLOCK_SIZE; } } /* * RC6 Key Schedule */ void RC6::key_schedule(const byte key[], size_t length) { S.resize(44); const size_t WORD_KEYLENGTH = (((length - 1) / 4) + 1); const size_t MIX_ROUNDS = 3 * std::max(WORD_KEYLENGTH, S.size()); S[0] = 0xB7E15163; for(size_t i = 1; i != S.size(); ++i) S[i] = S[i-1] + 0x9E3779B9; secure_vector K(8); for(s32bit i = length-1; i >= 0; --i) K[i/4] = (K[i/4] << 8) + key[i]; u32bit A = 0, B = 0; for(size_t i = 0; i != MIX_ROUNDS; ++i) { A = rotate_left(S[i % S.size()] + A + B, 3); B = rotate_left(K[i % WORD_KEYLENGTH] + A + B, (A + B) % 32); S[i % S.size()] = A; K[i % WORD_KEYLENGTH] = B; } } void RC6::clear() { zap(S); } }