/* * Tiger * (C) 1999-2007 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include namespace Botan { std::unique_ptr Tiger::copy_state() const { return std::unique_ptr(new Tiger(*this)); } namespace { /* * Tiger Mixing Function */ inline void mix(secure_vector& X) { X[0] -= X[7] ^ 0xA5A5A5A5A5A5A5A5; X[1] ^= X[0]; X[2] += X[1]; X[3] -= X[2] ^ ((~X[1]) << 19); X[4] ^= X[3]; X[5] += X[4]; X[6] -= X[5] ^ ((~X[4]) >> 23); X[7] ^= X[6]; X[0] += X[7]; X[1] -= X[0] ^ ((~X[7]) << 19); X[2] ^= X[1]; X[3] += X[2]; X[4] -= X[3] ^ ((~X[2]) >> 23); X[5] ^= X[4]; X[6] += X[5]; X[7] -= X[6] ^ 0x0123456789ABCDEF; } } /* * Tiger Compression Function */ void Tiger::compress_n(const uint8_t input[], size_t blocks) { uint64_t A = m_digest[0], B = m_digest[1], C = m_digest[2]; for(size_t i = 0; i != blocks; ++i) { load_le(m_X.data(), input, m_X.size()); pass(A, B, C, m_X, 5); mix(m_X); pass(C, A, B, m_X, 7); mix(m_X); pass(B, C, A, m_X, 9); for(size_t j = 3; j != m_passes; ++j) { mix(m_X); pass(A, B, C, m_X, 9); uint64_t T = A; A = C; C = B; B = T; } A = (m_digest[0] ^= A); B = m_digest[1] = B - m_digest[1]; C = (m_digest[2] += C); input += hash_block_size(); } } /* * Copy out the digest */ void Tiger::copy_out(uint8_t output[]) { copy_out_vec_le(output, output_length(), m_digest); } /* * Tiger Pass */ void Tiger::pass(uint64_t& A, uint64_t& B, uint64_t& C, const secure_vector& X, uint8_t mul) { C ^= X[0]; A -= SBOX1[get_byte(7, C)] ^ SBOX2[get_byte(5, C)] ^ SBOX3[get_byte(3, C)] ^ SBOX4[get_byte(1, C)]; B += SBOX1[get_byte(0, C)] ^ SBOX2[get_byte(2, C)] ^ SBOX3[get_byte(4, C)] ^ SBOX4[get_byte(6, C)]; B *= mul; A ^= X[1]; B -= SBOX1[get_byte(7, A)] ^ SBOX2[get_byte(5, A)] ^ SBOX3[get_byte(3, A)] ^ SBOX4[get_byte(1, A)]; C += SBOX1[get_byte(0, A)] ^ SBOX2[get_byte(2, A)] ^ SBOX3[get_byte(4, A)] ^ SBOX4[get_byte(6, A)]; C *= mul; B ^= X[2]; C -= SBOX1[get_byte(7, B)] ^ SBOX2[get_byte(5, B)] ^ SBOX3[get_byte(3, B)] ^ SBOX4[get_byte(1, B)]; A += SBOX1[get_byte(0, B)] ^ SBOX2[get_byte(2, B)] ^ SBOX3[get_byte(4, B)] ^ SBOX4[get_byte(6, B)]; A *= mul; C ^= X[3]; A -= SBOX1[get_byte(7, C)] ^ SBOX2[get_byte(5, C)] ^ SBOX3[get_byte(3, C)] ^ SBOX4[get_byte(1, C)]; B += SBOX1[get_byte(0, C)] ^ SBOX2[get_byte(2, C)] ^ SBOX3[get_byte(4, C)] ^ SBOX4[get_byte(6, C)]; B *= mul; A ^= X[4]; B -= SBOX1[get_byte(7, A)] ^ SBOX2[get_byte(5, A)] ^ SBOX3[get_byte(3, A)] ^ SBOX4[get_byte(1, A)]; C += SBOX1[get_byte(0, A)] ^ SBOX2[get_byte(2, A)] ^ SBOX3[get_byte(4, A)] ^ SBOX4[get_byte(6, A)]; C *= mul; B ^= X[5]; C -= SBOX1[get_byte(7, B)] ^ SBOX2[get_byte(5, B)] ^ SBOX3[get_byte(3, B)] ^ SBOX4[get_byte(1, B)]; A += SBOX1[get_byte(0, B)] ^ SBOX2[get_byte(2, B)] ^ SBOX3[get_byte(4, B)] ^ SBOX4[get_byte(6, B)]; A *= mul; C ^= X[6]; A -= SBOX1[get_byte(7, C)] ^ SBOX2[get_byte(5, C)] ^ SBOX3[get_byte(3, C)] ^ SBOX4[get_byte(1, C)]; B += SBOX1[get_byte(0, C)] ^ SBOX2[get_byte(2, C)] ^ SBOX3[get_byte(4, C)] ^ SBOX4[get_byte(6, C)]; B *= mul; A ^= X[7]; B -= SBOX1[get_byte(7, A)] ^ SBOX2[get_byte(5, A)] ^ SBOX3[get_byte(3, A)] ^ SBOX4[get_byte(1, A)]; C += SBOX1[get_byte(0, A)] ^ SBOX2[get_byte(2, A)] ^ SBOX3[get_byte(4, A)] ^ SBOX4[get_byte(6, A)]; C *= mul; } /* * Clear memory of sensitive data */ void Tiger::clear() { MDx_HashFunction::clear(); zeroise(m_X); m_digest[0] = 0x0123456789ABCDEF; m_digest[1] = 0xFEDCBA9876543210; m_digest[2] = 0xF096A5B4C3B2E187; } /* * Return the name of this type */ std::string Tiger::name() const { return "Tiger(" + std::to_string(output_length()) + "," + std::to_string(m_passes) + ")"; } /* * Tiger Constructor */ Tiger::Tiger(size_t hash_len, size_t passes) : MDx_HashFunction(64, false, false), m_X(8), m_digest(3), m_hash_len(hash_len), m_passes(passes) { if(output_length() != 16 && output_length() != 20 && output_length() != 24) throw Invalid_Argument("Tiger: Illegal hash output size: " + std::to_string(output_length())); if(passes < 3) throw Invalid_Argument("Tiger: Invalid number of passes: " + std::to_string(passes)); clear(); } }