/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * */ #ifndef DNS_RESPONDER_H #define DNS_RESPONDER_H #include #include #include #include #include #include #include #include #include #include "android-base/unique_fd.h" // Default TTL of the DNS answer record. constexpr unsigned kAnswerRecordTtlSec = 5; // The maximum UDP response size in bytes the DNS responder allows to send. It is used in non-EDNS // case. See RFC 1035 section 4.2.1. constexpr unsigned kMaximumUdpSize = 512; namespace test { struct DNSName { std::string name; const char* read(const char* buffer, const char* buffer_end); char* write(char* buffer, const char* buffer_end) const; private: const char* parseField(const char* buffer, const char* buffer_end, bool* last); }; struct DNSQuestion { DNSName qname; unsigned qtype; unsigned qclass; const char* read(const char* buffer, const char* buffer_end); char* write(char* buffer, const char* buffer_end) const; std::string toString() const; }; struct DNSRecord { DNSName name; unsigned rtype; unsigned rclass; unsigned ttl; std::vector rdata; const char* read(const char* buffer, const char* buffer_end); char* write(char* buffer, const char* buffer_end) const; std::string toString() const; private: struct IntFields { uint16_t rtype; uint16_t rclass; uint32_t ttl; uint16_t rdlen; } __attribute__((__packed__)); const char* readIntFields(const char* buffer, const char* buffer_end, unsigned* rdlen); char* writeIntFields(unsigned rdlen, char* buffer, const char* buffer_end) const; }; // TODO: Perhaps rename to DNSMessage. Per RFC 1035 section 4.1, struct DNSHeader more likes a // message because it has not only header section but also question section and other RRs. struct DNSHeader { unsigned id; bool ra; uint8_t rcode; bool qr; uint8_t opcode; bool aa; bool tr; bool rd; bool ad; std::vector questions; std::vector answers; std::vector authorities; std::vector additionals; const char* read(const char* buffer, const char* buffer_end); char* write(char* buffer, const char* buffer_end) const; bool write(std::vector* out) const; std::string toString() const; private: struct Header { uint16_t id; uint8_t flags0; uint8_t flags1; uint16_t qdcount; uint16_t ancount; uint16_t nscount; uint16_t arcount; } __attribute__((__packed__)); const char* readHeader(const char* buffer, const char* buffer_end, unsigned* qdcount, unsigned* ancount, unsigned* nscount, unsigned* arcount); }; inline const std::string kDefaultListenAddr = "127.0.0.3"; inline const std::string kDefaultListenService = "53"; inline const ns_rcode kDefaultErrorCode = ns_rcode::ns_r_servfail; /* * Simple DNS responder, which replies to queries with the registered response * for that type. Class is assumed to be IN. If no response is registered, the * default error response code is returned. */ class DNSResponder { public: enum class Edns { ON, FORMERR_ON_EDNS, // DNS server not supporting EDNS will reply FORMERR. FORMERR_UNCOND, // DNS server reply FORMERR unconditionally DROP // DNS server not supporting EDNS will not do any response. }; // Indicate which mapping the DNS server used to build the response. // See also addMapping{, DnsHeader, BinaryPacket}, removeMapping{, DnsHeader, BinaryPacket}, // makeResponse{, FromDnsHeader, FromBinaryPacket}. // TODO: Perhaps break class DNSResponder for each mapping. enum class MappingType { ADDRESS_OR_HOSTNAME, // Use the mapping from (name, type) to (address or hostname) DNS_HEADER, // Use the mapping from (name, type) to (DNSHeader) BINARY_PACKET, // Use the mapping from (query packet) to (response packet) }; struct QueryInfo { std::string name; ns_type type; int protocol; // Either IPPROTO_TCP or IPPROTO_UDP }; DNSResponder(std::string listen_address = kDefaultListenAddr, std::string listen_service = kDefaultListenService, ns_rcode error_rcode = kDefaultErrorCode, DNSResponder::MappingType mapping_type = MappingType::ADDRESS_OR_HOSTNAME); DNSResponder(ns_rcode error_rcode) : DNSResponder(kDefaultListenAddr, kDefaultListenService, error_rcode){}; DNSResponder(MappingType mapping_type) : DNSResponder(kDefaultListenAddr, kDefaultListenService, kDefaultErrorCode, mapping_type){}; DNSResponder(unsigned netId, std::string listen_address) : DNSResponder(listen_address) { mNetId = netId; }; ~DNSResponder(); // Functions used for accessing mapping {ADDRESS_OR_HOSTNAME, DNS_HEADER, BINARY_PACKET}. void addMapping(const std::string& name, ns_type type, const std::string& addr); void addMappingDnsHeader(const std::string& name, ns_type type, const DNSHeader& header); void addMappingBinaryPacket(const std::vector& query, const std::vector& response); void removeMapping(const std::string& name, ns_type type); void removeMappingDnsHeader(const std::string& name, ns_type type); void removeMappingBinaryPacket(const std::vector& query); void setResponseProbability(double response_probability); void setResponseProbability(double response_probability, int protocol); void setResponseDelayMs(unsigned); void setErrorRcode(ns_rcode error_rcode) { error_rcode_ = error_rcode; } void setEdns(Edns edns); void setTtl(unsigned ttl); bool running() const; bool startServer(); bool stopServer(); const std::string& listen_address() const { return listen_address_; } const std::string& listen_service() const { return listen_service_; } std::vector queries() const; std::string dumpQueries() const; void clearQueries(); std::condition_variable& getCv() { return cv; } std::mutex& getCvMutex() { return cv_mutex_; } void setDeferredResp(bool deferred_resp); static bool fillRdata(const std::string& rdatastr, DNSRecord& record); // These functions are helpers for binding the listening sockets to a specific network, which // is necessary only for multinetwork tests. Since binding sockets to a network requires // the dependency of libnetd_client, and DNSResponder is also widely used in other tests like // resolv_unit_test which doesn't need that dependency, so expose the socket fds to let the // callers perform binding operations by themselves. Callers MUST not close the fds. void setNetwork(unsigned netId) { mNetId = netId; } std::optional getNetwork() const { return mNetId; } int getUdpSocket() const { return udp_socket_.get(); } int getTcpSocket() const { return tcp_socket_.get(); } // TODO: Make DNSResponder record unknown queries in a vector for improving the debugging. // Unit test could dump the unexpected query for further debug if any unexpected failure. private: // Key used for accessing mappings. struct QueryKey { std::string name; unsigned type; QueryKey(std::string n, unsigned t) : name(move(n)), type(t) {} bool operator==(const QueryKey& o) const { return name == o.name && type == o.type; } bool operator<(const QueryKey& o) const { if (name < o.name) return true; if (name > o.name) return false; return type < o.type; } }; struct QueryKeyHash { size_t operator()(const QueryKey& key) const { return std::hash()(key.name) + static_cast(key.type); } }; // Used for generating combined hash value of a vector. // std::hash doesn't provide a specialization for std::vector. struct QueryKeyVectorHash { std::size_t operator()(const std::vector& v) const { std::size_t combined = 0; for (const uint8_t i : v) { // Hash combination comes from boost::hash_combine // See also system/extras/simpleperf/utils.h combined ^= std::hash{}(i) + 0x9e3779b9 + (combined << 6) + (combined >> 2); } return combined; } }; void requestHandler(); // Check if any OPT Pseudo RR in the additional section. bool hasOptPseudoRR(DNSHeader* header) const; // Parses and generates a response message for incoming DNS requests. // Returns false to ignore the request, which might be due to either parsing error // or unresponsiveness. bool handleDNSRequest(const char* buffer, ssize_t buffer_len, int protocol, char* response, size_t* response_len) const; bool addAnswerRecords(const DNSQuestion& question, std::vector* answers) const; bool generateErrorResponse(DNSHeader* header, ns_rcode rcode, char* response, size_t* response_len) const; // TODO: Change writePacket, makeErrorResponse, makeTruncatedResponse and // makeResponse{, FromAddressOrHostname, FromDnsHeader, FromBinaryPacket} to use C++ containers // instead of the unsafe pointer + length buffer. bool writePacket(const DNSHeader* header, char* response, size_t* response_len) const; // Build an error response with a given rcode. bool makeErrorResponse(DNSHeader* header, ns_rcode rcode, char* response, size_t* response_len) const; // Build a truncated response. bool makeTruncatedResponse(DNSHeader* header, char* response, size_t* response_len) const; // Build a response. bool makeResponse(DNSHeader* header, int protocol, char* response, size_t* response_len) const; // Helper for building a response from mapping {ADDRESS_OR_HOSTNAME, DNS_HEADER, BINARY_PACKET}. bool makeResponseFromAddressOrHostname(DNSHeader* header, char* response, size_t* response_len) const; bool makeResponseFromDnsHeader(DNSHeader* header, char* response, size_t* response_len) const; bool makeResponseFromBinaryPacket(DNSHeader* header, char* response, size_t* response_len) const; // Add a new file descriptor to be polled by the handler thread. bool addFd(int fd, uint32_t events); // Read the query sent from the client and send the answer back to the client. It // makes sure the I/O communicated with the client is correct. void handleQuery(int protocol); // Trigger the handler thread to terminate. bool sendToEventFd(); // Used in the handler thread for the termination signal. void handleEventFd(); // TODO: Move createListeningSocket to resolv_test_utils.h android::base::unique_fd createListeningSocket(int socket_type); double getResponseProbability(int protocol) const; // Address and service to listen on TCP and UDP. const std::string listen_address_; const std::string listen_service_; // TODO: Consider refactoring atomic members of this class to a single big mutex. // Error code to return for requests for an unknown name. ns_rcode error_rcode_; // Mapping type the DNS server used to build the response. const MappingType mapping_type_; // Probability that a valid response on TCP is being sent instead of // returning error_rcode_ or no response. std::atomic response_probability_tcp_ = 1.0; // Probability that a valid response on UDP is being sent instead of // returning error_rcode_ or no response. std::atomic response_probability_udp_ = 1.0; std::atomic answer_record_ttl_sec_ = kAnswerRecordTtlSec; std::atomic response_delayed_ms_ = 0; // Maximum number of fds for epoll. const int EPOLL_MAX_EVENTS = 2; // Control how the DNS server behaves when it receives the requests containing OPT RR. // If it's set Edns::ON, the server can recognize and reply the response; if it's set // Edns::FORMERR_ON_EDNS, the server behaves like an old DNS server that doesn't support EDNS0, // and replying FORMERR; if it's Edns::DROP, the server doesn't support EDNS0 either, and // ignoring the requests. std::atomic edns_ = Edns::ON; // Mappings used for building the DNS response by registered mapping items. |mapping_type_| // decides which mapping is used. See also makeResponse{, FromDnsHeader}. // - mappings_: Mapping from (name, type) to (address or hostname). // - dnsheader_mappings_: Mapping from (name, type) to (DNSHeader). // - packet_mappings_: Mapping from (query packet) to (response packet). std::unordered_map mappings_ GUARDED_BY(mappings_mutex_); std::unordered_map dnsheader_mappings_ GUARDED_BY(mappings_mutex_); std::unordered_map, std::vector, QueryKeyVectorHash> packet_mappings_ GUARDED_BY(mappings_mutex_); mutable std::mutex mappings_mutex_; // Query names received so far and the corresponding mutex. mutable std::vector queries_ GUARDED_BY(queries_mutex_); mutable std::mutex queries_mutex_; // Socket on which the server is listening. android::base::unique_fd udp_socket_; android::base::unique_fd tcp_socket_; // File descriptor for epoll. android::base::unique_fd epoll_fd_; // Eventfd used to signal for the handler thread termination. android::base::unique_fd event_fd_; // Thread for handling incoming threads. std::thread handler_thread_ GUARDED_BY(update_mutex_); std::mutex update_mutex_; std::condition_variable cv; std::mutex cv_mutex_; std::condition_variable cv_for_deferred_resp_; std::mutex cv_mutex_for_deferred_resp_; bool deferred_resp_ GUARDED_BY(cv_mutex_for_deferred_resp_) = false; // The network to which the listening sockets will be bound. std::optional mNetId; }; } // namespace test #endif // DNS_RESPONDER_H