/* * Client Key Exchange Message * (C) 2004-2010,2016 Jack Lloyd * 2017 Harry Reimann, Rohde & Schwarz Cybersecurity * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include #include #include #include #include #include #include #include #include namespace Botan::TLS { /* * Create a new Client Key Exchange message */ Client_Key_Exchange::Client_Key_Exchange(Handshake_IO& io, Handshake_State& state, const Policy& policy, Credentials_Manager& creds, const Public_Key* server_public_key, std::string_view hostname, RandomNumberGenerator& rng) { const Kex_Algo kex_algo = state.ciphersuite().kex_method(); if(kex_algo == Kex_Algo::PSK) { std::string identity_hint; if(state.server_kex()) { TLS_Data_Reader reader("ClientKeyExchange", state.server_kex()->params()); identity_hint = reader.get_string(2, 0, 65535); } m_psk_identity = creds.psk_identity("tls-client", std::string(hostname), identity_hint); append_tls_length_value(m_key_material, to_byte_vector(m_psk_identity.value()), 2); SymmetricKey psk = creds.psk("tls-client", std::string(hostname), m_psk_identity.value()); std::vector zeros(psk.length()); append_tls_length_value(m_pre_master, zeros, 2); append_tls_length_value(m_pre_master, psk.bits_of(), 2); } else if(state.server_kex()) { TLS_Data_Reader reader("ClientKeyExchange", state.server_kex()->params()); SymmetricKey psk; if(kex_algo == Kex_Algo::ECDHE_PSK) { std::string identity_hint = reader.get_string(2, 0, 65535); m_psk_identity = creds.psk_identity("tls-client", std::string(hostname), identity_hint); append_tls_length_value(m_key_material, to_byte_vector(m_psk_identity.value()), 2); psk = creds.psk("tls-client", std::string(hostname), m_psk_identity.value()); } if(kex_algo == Kex_Algo::DH) { const auto modulus = BigInt::from_bytes(reader.get_range(2, 1, 65535)); const auto generator = BigInt::from_bytes(reader.get_range(2, 1, 65535)); const std::vector peer_public_value = reader.get_range(2, 1, 65535); if(reader.remaining_bytes()) { throw Decoding_Error("Bad params size for DH key exchange"); } DL_Group group(modulus, generator); if(!group.verify_group(rng, false)) { throw TLS_Exception(Alert::InsufficientSecurity, "DH group validation failed"); } const auto private_key = state.callbacks().tls_generate_ephemeral_key(group, rng); m_pre_master = CT::strip_leading_zeros( state.callbacks().tls_ephemeral_key_agreement(group, *private_key, peer_public_value, rng, policy)); append_tls_length_value(m_key_material, private_key->public_value(), 2); } else if(kex_algo == Kex_Algo::ECDH || kex_algo == Kex_Algo::ECDHE_PSK) { const uint8_t curve_type = reader.get_byte(); if(curve_type != 3) { throw Decoding_Error("Server sent non-named ECC curve"); } const Group_Params curve_id = static_cast(reader.get_uint16_t()); const std::vector peer_public_value = reader.get_range(1, 1, 255); if(!curve_id.is_ecdh_named_curve() && !curve_id.is_x25519() && !curve_id.is_x448()) { throw TLS_Exception(Alert::IllegalParameter, "Server selected a group that is not compatible with the negotiated ciphersuite"); } if(policy.choose_key_exchange_group({curve_id}, {}) != curve_id) { throw TLS_Exception(Alert::HandshakeFailure, "Server sent ECC curve prohibited by policy"); } const auto private_key = state.callbacks().tls_generate_ephemeral_key(curve_id, rng); auto shared_secret = state.callbacks().tls_ephemeral_key_agreement(curve_id, *private_key, peer_public_value, rng, policy); if(kex_algo == Kex_Algo::ECDH) { m_pre_master = std::move(shared_secret); } else { append_tls_length_value(m_pre_master, shared_secret, 2); append_tls_length_value(m_pre_master, psk.bits_of(), 2); } if(curve_id.is_ecdh_named_curve()) { auto ecdh_key = dynamic_cast(private_key.get()); if(!ecdh_key) { throw TLS_Exception(Alert::InternalError, "Application did not provide a ECDH_PublicKey"); } append_tls_length_value(m_key_material, ecdh_key->public_value(state.server_hello()->prefers_compressed_ec_points() ? EC_Point_Format::Compressed : EC_Point_Format::Uncompressed), 1); } else { append_tls_length_value(m_key_material, private_key->public_value(), 1); } } else { throw Internal_Error("Client_Key_Exchange: Unknown key exchange method was negotiated"); } reader.assert_done(); } else { // No server key exchange msg better mean RSA kex + RSA key in cert if(kex_algo != Kex_Algo::STATIC_RSA) { throw Unexpected_Message("No server kex message, but negotiated a key exchange that required it"); } if(!server_public_key) { throw Internal_Error("No server public key for RSA exchange"); } if(auto rsa_pub = dynamic_cast(server_public_key)) { const Protocol_Version offered_version = state.client_hello()->legacy_version(); rng.random_vec(m_pre_master, 48); m_pre_master[0] = offered_version.major_version(); m_pre_master[1] = offered_version.minor_version(); PK_Encryptor_EME encryptor(*rsa_pub, rng, "PKCS1v15"); const std::vector encrypted_key = encryptor.encrypt(m_pre_master, rng); append_tls_length_value(m_key_material, encrypted_key, 2); } else { throw TLS_Exception(Alert::HandshakeFailure, "Expected a RSA key in server cert but got " + server_public_key->algo_name()); } } state.hash().update(io.send(*this)); } /* * Read a Client Key Exchange message */ Client_Key_Exchange::Client_Key_Exchange(const std::vector& contents, const Handshake_State& state, const Private_Key* server_rsa_kex_key, Credentials_Manager& creds, const Policy& policy, RandomNumberGenerator& rng) { const Kex_Algo kex_algo = state.ciphersuite().kex_method(); if(kex_algo == Kex_Algo::STATIC_RSA) { BOTAN_ASSERT(state.server_certs() && !state.server_certs()->cert_chain().empty(), "RSA key exchange negotiated so server sent a certificate"); if(!server_rsa_kex_key) { throw Internal_Error("Expected RSA kex but no server kex key set"); } if(server_rsa_kex_key->algo_name() != "RSA") { throw Internal_Error("Expected RSA key but got " + server_rsa_kex_key->algo_name()); } TLS_Data_Reader reader("ClientKeyExchange", contents); const std::vector encrypted_pre_master = reader.get_range(2, 0, 65535); reader.assert_done(); PK_Decryptor_EME decryptor(*server_rsa_kex_key, rng, "PKCS1v15"); const uint8_t client_major = state.client_hello()->legacy_version().major_version(); const uint8_t client_minor = state.client_hello()->legacy_version().minor_version(); /* * PK_Decryptor::decrypt_or_random will return a random value if * either the length does not match the expected value or if the * version number embedded in the PMS does not match the one sent * in the client hello. */ const size_t expected_plaintext_size = 48; const size_t expected_content_size = 2; const uint8_t expected_content_bytes[expected_content_size] = {client_major, client_minor}; const uint8_t expected_content_pos[expected_content_size] = {0, 1}; m_pre_master = decryptor.decrypt_or_random(encrypted_pre_master.data(), encrypted_pre_master.size(), expected_plaintext_size, rng, expected_content_bytes, expected_content_pos, expected_content_size); } else { TLS_Data_Reader reader("ClientKeyExchange", contents); SymmetricKey psk; if(key_exchange_is_psk(kex_algo)) { m_psk_identity = reader.get_string(2, 0, 65535); psk = creds.psk("tls-server", state.client_hello()->sni_hostname(), m_psk_identity.value()); if(psk.empty()) { if(policy.hide_unknown_users()) { psk = SymmetricKey(rng, 16); } else { throw TLS_Exception(Alert::UnknownPSKIdentity, "No PSK for identifier " + m_psk_identity.value()); } } } if(kex_algo == Kex_Algo::PSK) { std::vector zeros(psk.length()); append_tls_length_value(m_pre_master, zeros, 2); append_tls_length_value(m_pre_master, psk.bits_of(), 2); } else if(kex_algo == Kex_Algo::DH || kex_algo == Kex_Algo::ECDH || kex_algo == Kex_Algo::ECDHE_PSK) { const PK_Key_Agreement_Key& ka_key = state.server_kex()->server_kex_key(); const std::vector client_pubkey = (ka_key.algo_name() == "DH") ? reader.get_range(2, 0, 65535) : reader.get_range(1, 1, 255); const auto shared_group = state.server_kex()->shared_group(); BOTAN_STATE_CHECK(shared_group && shared_group.value() != Group_Params::NONE); try { auto shared_secret = state.callbacks().tls_ephemeral_key_agreement(shared_group.value(), ka_key, client_pubkey, rng, policy); if(ka_key.algo_name() == "DH") { shared_secret = CT::strip_leading_zeros(shared_secret); } if(kex_algo == Kex_Algo::ECDHE_PSK) { append_tls_length_value(m_pre_master, shared_secret, 2); append_tls_length_value(m_pre_master, psk.bits_of(), 2); } else { m_pre_master = shared_secret; } } catch(Invalid_Argument& e) { throw TLS_Exception(Alert::IllegalParameter, e.what()); } catch(TLS_Exception& e) { // NOLINTNEXTLINE(cert-err60-cpp) throw e; } catch(std::exception&) { /* * Something failed in the DH/ECDH computation. To avoid possible * attacks which are based on triggering and detecting some edge * failure condition, randomize the pre-master output and carry on, * allowing the protocol to fail later in the finished checks. */ rng.random_vec(m_pre_master, ka_key.public_value().size()); } reader.assert_done(); } else { throw Internal_Error("Client_Key_Exchange: Unknown key exchange negotiated"); } } } } // namespace Botan::TLS