/* * Passhash9 Password Hashing * (C) 2010 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include namespace Botan { namespace { const std::string MAGIC_PREFIX = "$9$"; const size_t WORKFACTOR_BYTES = 2; const size_t ALGID_BYTES = 1; const size_t SALT_BYTES = 12; // 96 bits of salt const size_t PASSHASH9_PBKDF_OUTPUT_LEN = 24; // 192 bits output const size_t WORK_FACTOR_SCALE = 10000; std::unique_ptr get_pbkdf_prf(byte alg_id) { if(alg_id == 0) return MessageAuthenticationCode::create("HMAC(SHA-1)"); else if(alg_id == 1) return MessageAuthenticationCode::create("HMAC(SHA-256)"); else if(alg_id == 2) return MessageAuthenticationCode::create("CMAC(Blowfish)"); else if(alg_id == 3) return MessageAuthenticationCode::create("HMAC(SHA-384)"); else if(alg_id == 4) return MessageAuthenticationCode::create("HMAC(SHA-512)"); return nullptr; } } std::string generate_passhash9(const std::string& pass, RandomNumberGenerator& rng, u16bit work_factor, byte alg_id) { std::unique_ptr prf = get_pbkdf_prf(alg_id); if(!prf) throw Invalid_Argument("Passhash9: Algorithm id " + std::to_string(alg_id) + " is not defined"); PKCS5_PBKDF2 kdf(prf.release()); // takes ownership of pointer secure_vector salt(SALT_BYTES); rng.randomize(salt.data(), salt.size()); const size_t kdf_iterations = WORK_FACTOR_SCALE * work_factor; secure_vector blob; blob.push_back(alg_id); blob.push_back(get_byte(0, work_factor)); blob.push_back(get_byte(1, work_factor)); blob += salt; blob += kdf.derive_key(PASSHASH9_PBKDF_OUTPUT_LEN, pass, salt.data(), salt.size(), kdf_iterations).bits_of(); return MAGIC_PREFIX + base64_encode(blob); } bool check_passhash9(const std::string& pass, const std::string& hash) { const size_t BINARY_LENGTH = ALGID_BYTES + WORKFACTOR_BYTES + PASSHASH9_PBKDF_OUTPUT_LEN + SALT_BYTES; const size_t BASE64_LENGTH = MAGIC_PREFIX.size() + (BINARY_LENGTH * 8) / 6; if(hash.size() != BASE64_LENGTH) return false; for(size_t i = 0; i != MAGIC_PREFIX.size(); ++i) if(hash[i] != MAGIC_PREFIX[i]) return false; secure_vector bin = base64_decode(hash.c_str() + MAGIC_PREFIX.size()); if(bin.size() != BINARY_LENGTH) return false; byte alg_id = bin[0]; const size_t work_factor = load_be(&bin[ALGID_BYTES], 0); // Bug in the format, bad states shouldn't be representable, but are... if(work_factor == 0) return false; if(work_factor > 512) throw std::invalid_argument("Requested Bcrypt work factor " + std::to_string(work_factor) + " too large"); const size_t kdf_iterations = WORK_FACTOR_SCALE * work_factor; std::unique_ptr pbkdf_prf = get_pbkdf_prf(alg_id); if(!pbkdf_prf) return false; // unknown algorithm, reject PKCS5_PBKDF2 kdf(pbkdf_prf.release()); // takes ownership of pointer secure_vector cmp = kdf.derive_key( PASSHASH9_PBKDF_OUTPUT_LEN, pass, &bin[ALGID_BYTES + WORKFACTOR_BYTES], SALT_BYTES, kdf_iterations).bits_of(); return same_mem(cmp.data(), &bin[ALGID_BYTES + WORKFACTOR_BYTES + SALT_BYTES], PASSHASH9_PBKDF_OUTPUT_LEN); } }