/* * Policies for TLS * (C) 2004-2010,2012,2015 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include #include namespace Botan { namespace TLS { std::vector Policy::allowed_ciphers() const { return { //"AES-256/OCB(12)", //"AES-128/OCB(12)", "AES-256/GCM", "AES-128/GCM", "ChaCha20Poly1305", "AES-256/CCM", "AES-128/CCM", "AES-256/CCM(8)", "AES-128/CCM(8)", //"Camellia-256/GCM", //"Camellia-128/GCM", "AES-256", "AES-128", //"Camellia-256", //"Camellia-128", //"SEED" //"3DES", }; } std::vector Policy::allowed_signature_hashes() const { return { "SHA-512", "SHA-384", "SHA-256", //"SHA-224", //"SHA-1", //"MD5", }; } std::vector Policy::allowed_macs() const { return { "AEAD", "SHA-384", "SHA-256", "SHA-1", //"MD5", }; } std::vector Policy::allowed_key_exchange_methods() const { return { "SRP_SHA", //"ECDHE_PSK", //"DHE_PSK", //"PSK", "ECDH", "DH", "RSA", }; } std::vector Policy::allowed_signature_methods() const { return { "ECDSA", "RSA", "DSA", //"" }; } std::vector Policy::allowed_ecc_curves() const { return { "brainpool512r1", "secp521r1", "brainpool384r1", "secp384r1", "brainpool256r1", "secp256r1", //"secp256k1", //"secp224r1", //"secp224k1", //"secp192r1", //"secp192k1", //"secp160r2", //"secp160r1", //"secp160k1", }; } /* * Choose an ECC curve to use */ std::string Policy::choose_curve(const std::vector& curve_names) const { const std::vector our_curves = allowed_ecc_curves(); for(size_t i = 0; i != our_curves.size(); ++i) if(value_exists(curve_names, our_curves[i])) return our_curves[i]; return ""; // no shared curve } std::string Policy::dh_group() const { return "modp/ietf/2048"; } size_t Policy::minimum_dh_group_size() const { return 1024; } /* * Return allowed compression algorithms */ std::vector Policy::compression() const { return std::vector{ NO_COMPRESSION }; } u32bit Policy::session_ticket_lifetime() const { return 86400; // ~1 day } bool Policy::send_fallback_scsv(Protocol_Version version) const { return version != latest_supported_version(version.is_datagram_protocol()); } bool Policy::acceptable_protocol_version(Protocol_Version version) const { if(version.is_datagram_protocol()) return (version >= Protocol_Version::DTLS_V12); else return (version >= Protocol_Version::TLS_V10); } Protocol_Version Policy::latest_supported_version(bool datagram) const { if(datagram) return Protocol_Version::latest_dtls_version(); else return Protocol_Version::latest_tls_version(); } bool Policy::acceptable_ciphersuite(const Ciphersuite&) const { return true; } bool Policy::negotiate_heartbeat_support() const { return false; } bool Policy::allow_server_initiated_renegotiation() const { return false; } bool Policy::allow_insecure_renegotiation() const { return false; } bool Policy::include_time_in_hello_random() const { return true; } bool Policy::hide_unknown_users() const { return false; } bool Policy::server_uses_own_ciphersuite_preferences() const { return true; } // 1 second initial timeout, 60 second max - see RFC 6347 sec 4.2.4.1 size_t Policy::dtls_initial_timeout() const { return 1*1000; } size_t Policy::dtls_maximum_timeout() const { return 60*1000; } size_t Policy::dtls_default_mtu() const { // default MTU is IPv6 min MTU minus UDP/IP headers return 1280 - 40 - 8; } std::vector Policy::srtp_profiles() const { return std::vector(); } namespace { class Ciphersuite_Preference_Ordering { public: Ciphersuite_Preference_Ordering(const std::vector& ciphers, const std::vector& macs, const std::vector& kex, const std::vector& sigs) : m_ciphers(ciphers), m_macs(macs), m_kex(kex), m_sigs(sigs) {} bool operator()(const Ciphersuite& a, const Ciphersuite& b) const { if(a.kex_algo() != b.kex_algo()) { for(size_t i = 0; i != m_kex.size(); ++i) { if(a.kex_algo() == m_kex[i]) return true; if(b.kex_algo() == m_kex[i]) return false; } } if(a.cipher_algo() != b.cipher_algo()) { for(size_t i = 0; i != m_ciphers.size(); ++i) { if(a.cipher_algo() == m_ciphers[i]) return true; if(b.cipher_algo() == m_ciphers[i]) return false; } } if(a.cipher_keylen() != b.cipher_keylen()) { if(a.cipher_keylen() < b.cipher_keylen()) return false; if(a.cipher_keylen() > b.cipher_keylen()) return true; } if(a.sig_algo() != b.sig_algo()) { for(size_t i = 0; i != m_sigs.size(); ++i) { if(a.sig_algo() == m_sigs[i]) return true; if(b.sig_algo() == m_sigs[i]) return false; } } if(a.mac_algo() != b.mac_algo()) { for(size_t i = 0; i != m_macs.size(); ++i) { if(a.mac_algo() == m_macs[i]) return true; if(b.mac_algo() == m_macs[i]) return false; } } return false; // equal (?!?) } private: std::vector m_ciphers, m_macs, m_kex, m_sigs; }; } std::vector Policy::ciphersuite_list(Protocol_Version version, bool have_srp) const { const std::vector ciphers = allowed_ciphers(); const std::vector macs = allowed_macs(); const std::vector kex = allowed_key_exchange_methods(); const std::vector sigs = allowed_signature_methods(); Ciphersuite_Preference_Ordering order(ciphers, macs, kex, sigs); std::set ciphersuites(order); for(auto&& suite : Ciphersuite::all_known_ciphersuites()) { if(!acceptable_ciphersuite(suite)) continue; if(!have_srp && suite.kex_algo() == "SRP_SHA") continue; if(!version.supports_aead_modes() && suite.mac_algo() == "AEAD") continue; if(!value_exists(kex, suite.kex_algo())) continue; // unsupported key exchange if(!value_exists(ciphers, suite.cipher_algo())) continue; // unsupported cipher if(!value_exists(macs, suite.mac_algo())) continue; // unsupported MAC algo if(!value_exists(sigs, suite.sig_algo())) { // allow if it's an empty sig algo and we want to use PSK if(suite.sig_algo() != "" || !suite.psk_ciphersuite()) continue; } // OK, allow it: ciphersuites.insert(suite); } if(ciphersuites.empty()) throw Exception("Policy does not allow any available cipher suite"); std::vector ciphersuite_codes; for(auto i : ciphersuites) ciphersuite_codes.push_back(i.ciphersuite_code()); return ciphersuite_codes; } namespace { void print_vec(std::ostream& o, const char* key, const std::vector& v) { o << key << " = "; for(size_t i = 0; i != v.size(); ++i) { o << v[i]; if(i != v.size() - 1) o << ' '; } o << '\n'; } void print_bool(std::ostream& o, const char* key, bool b) { o << key << " = " << (b ? "true" : "false") << '\n'; } } void Policy::print(std::ostream& o) const { print_vec(o, "ciphers", allowed_ciphers()); print_vec(o, "macs", allowed_macs()); print_vec(o, "signature_hashes", allowed_signature_hashes()); print_vec(o, "signature_methods", allowed_signature_methods()); print_vec(o, "key_exchange_methods", allowed_key_exchange_methods()); print_vec(o, "ecc_curves", allowed_ecc_curves()); print_bool(o, "negotiate_heartbeat_support", negotiate_heartbeat_support()); print_bool(o, "allow_insecure_renegotiation", allow_insecure_renegotiation()); print_bool(o, "include_time_in_hello_random", include_time_in_hello_random()); print_bool(o, "allow_server_initiated_renegotiation", allow_server_initiated_renegotiation()); print_bool(o, "hide_unknown_users", hide_unknown_users()); print_bool(o, "server_uses_own_ciphersuite_preferences", server_uses_own_ciphersuite_preferences()); o << "session_ticket_lifetime = " << session_ticket_lifetime() << '\n'; o << "dh_group = " << dh_group() << '\n'; o << "minimum_dh_group_size = " << minimum_dh_group_size() << '\n'; } std::vector Strict_Policy::allowed_ciphers() const { return { "ChaCha20Poly1305", "AES-256/GCM", "AES-128/GCM" }; } std::vector Strict_Policy::allowed_signature_hashes() const { return { "SHA-512", "SHA-384"}; } std::vector Strict_Policy::allowed_macs() const { return { "AEAD" }; } std::vector Strict_Policy::allowed_key_exchange_methods() const { return { "ECDH" }; } bool Strict_Policy::acceptable_protocol_version(Protocol_Version version) const { if(version.is_datagram_protocol()) return (version >= Protocol_Version::DTLS_V12); else return (version >= Protocol_Version::TLS_V12); } } }