/* * Streebog * (C) 2017 Ribose Inc. * (C) 2018 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include namespace Botan { extern const uint64_t STREEBOG_Ax[8][256]; extern const uint64_t STREEBOG_C[12][8]; std::unique_ptr Streebog::copy_state() const { return std::unique_ptr(new Streebog(*this)); } Streebog::Streebog(size_t output_bits) : m_output_bits(output_bits), m_count(0), m_position(0), m_buffer(64), m_h(8), m_S(8) { if(output_bits != 256 && output_bits != 512) throw Invalid_Argument("Streebog: Invalid output length " + std::to_string(output_bits)); clear(); } std::string Streebog::name() const { return "Streebog-" + std::to_string(m_output_bits); } /* * Clear memory of sensitive data */ void Streebog::clear() { m_count = 0; m_position = 0; zeroise(m_buffer); zeroise(m_S); const uint64_t fill = (m_output_bits == 512) ? 0 : 0x0101010101010101; std::fill(m_h.begin(), m_h.end(), fill); } /* * Update the hash */ void Streebog::add_data(const uint8_t input[], size_t length) { const size_t block_size = m_buffer.size(); if(m_position) { buffer_insert(m_buffer, m_position, input, length); if(m_position + length >= block_size) { compress(m_buffer.data()); m_count += 512; input += (block_size - m_position); length -= (block_size - m_position); m_position = 0; } } const size_t full_blocks = length / block_size; const size_t remaining = length % block_size; for(size_t i = 0; i != full_blocks; ++i) { compress(input + block_size * i); m_count += 512; } buffer_insert(m_buffer, m_position, input + full_blocks * block_size, remaining); m_position += remaining; } /* * Finalize a hash */ void Streebog::final_result(uint8_t output[]) { m_buffer[m_position++] = 0x01; if(m_position != m_buffer.size()) clear_mem(&m_buffer[m_position], m_buffer.size() - m_position); compress(m_buffer.data()); m_count += (m_position - 1) * 8; zeroise(m_buffer); store_le(m_count, m_buffer.data()); compress(m_buffer.data(), true); compress_64(m_S.data(), true); // FIXME std::memcpy(output, &m_h[8 - output_length() / 8], output_length()); clear(); } namespace { inline uint64_t force_le(uint64_t x) { #if defined(BOTAN_TARGET_CPU_IS_LITTLE_ENDIAN) return x; #elif defined(BOTAN_TARGET_CPU_IS_BIG_ENDIAN) return reverse_bytes(x); #else store_le(x, reinterpret_cast(&x)); return x; #endif } inline void lps(uint64_t block[8]) { uint8_t r[64]; // FIXME std::memcpy(r, block, 64); for(int i = 0; i < 8; ++i) { block[i] = force_le(STREEBOG_Ax[0][r[i + 0*8]]) ^ force_le(STREEBOG_Ax[1][r[i + 1*8]]) ^ force_le(STREEBOG_Ax[2][r[i + 2*8]]) ^ force_le(STREEBOG_Ax[3][r[i + 3*8]]) ^ force_le(STREEBOG_Ax[4][r[i + 4*8]]) ^ force_le(STREEBOG_Ax[5][r[i + 5*8]]) ^ force_le(STREEBOG_Ax[6][r[i + 6*8]]) ^ force_le(STREEBOG_Ax[7][r[i + 7*8]]); } } } //namespace void Streebog::compress(const uint8_t input[], bool last_block) { uint64_t M[8]; std::memcpy(M, input, 64); compress_64(M, last_block); } void Streebog::compress_64(const uint64_t M[], bool last_block) { const uint64_t N = last_block ? 0 : force_le(m_count); uint64_t hN[8]; uint64_t A[8]; copy_mem(hN, m_h.data(), 8); hN[0] ^= N; lps(hN); copy_mem(A, hN, 8); for(size_t i = 0; i != 8; ++i) { hN[i] ^= M[i]; } for(size_t i = 0; i < 12; ++i) { for(size_t j = 0; j != 8; ++j) A[j] ^= force_le(STREEBOG_C[i][j]); lps(A); lps(hN); for(size_t j = 0; j != 8; ++j) hN[j] ^= A[j]; } for(size_t i = 0; i != 8; ++i) { m_h[i] ^= hN[i] ^ M[i]; } if(!last_block) { uint64_t carry = 0; for(int i = 0; i < 8; i++) { const uint64_t m = force_le(M[i]); const uint64_t hi = force_le(m_S[i]); const uint64_t t = hi + m + carry; m_S[i] = force_le(t); if(t != m) carry = (t < m); } } } }