/* * 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. * */ #define LOG_TAG "resolv_integration_test" #include #include #include #include #include // ResNsendFlags #include #include #include #include #include #include #include #include #include #include // SHA256_SIZE #include #include #include #include #include #include /* poll */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // NETID_USE_LOCAL_NAMESERVERS #include #include #include #include #include // getApiLevel #include "Experiments.h" #include "NetdClient.h" #include "ResolverStats.h" #include "netid_client.h" // NETID_UNSET #include "params.h" // MAXNS #include "stats.h" // RCODE_TIMEOUT #include "tests/dns_metrics_listener/dns_metrics_listener.h" #include "tests/dns_responder/dns_responder.h" #include "tests/dns_responder/dns_responder_client_ndk.h" #include "tests/dns_responder/dns_tls_certificate.h" #include "tests/dns_responder/dns_tls_frontend.h" #include "tests/resolv_test_utils.h" #include "tests/tun_forwarder.h" #include "tests/unsolicited_listener/unsolicited_event_listener.h" // This mainline module test still needs to be able to run on pre-S devices, // and thus may run across pre-4.9 non-eBPF capable devices like the Pixel 2. #define SKIP_IF_BPF_NOT_SUPPORTED \ do { \ if (!android::bpf::isAtLeastKernelVersion(4, 9, 0)) \ GTEST_SKIP() << "Skip: bpf is not supported."; \ } while (0) // Valid VPN netId range is 100 ~ 65535 constexpr int TEST_VPN_NETID = 65502; constexpr int MAXPACKET = (8 * 1024); // Sync from packages/modules/DnsResolver/resolv_private.h constexpr int RES_TIMEOUT = 5000; /* min. milliseconds between retries */ constexpr int RES_DFLRETRY = 2; /* Default #/tries. */ // Semi-public Bionic hook used by the NDK (frameworks/base/native/android/net.c) // Tested here for convenience. extern "C" int android_getaddrinfofornet(const char* hostname, const char* servname, const addrinfo* hints, unsigned netid, unsigned mark, struct addrinfo** result); using namespace std::chrono_literals; using aidl::android::net::IDnsResolver; using aidl::android::net::INetd; using aidl::android::net::ResolverOptionsParcel; using aidl::android::net::ResolverParamsParcel; using aidl::android::net::UidRangeParcel; using aidl::android::net::metrics::INetdEventListener; using aidl::android::net::netd::aidl::NativeUidRangeConfig; using aidl::android::net::resolv::aidl::DnsHealthEventParcel; using aidl::android::net::resolv::aidl::IDnsResolverUnsolicitedEventListener; using aidl::android::net::resolv::aidl::Nat64PrefixEventParcel; using aidl::android::net::resolv::aidl::PrivateDnsValidationEventParcel; using android::base::Error; using android::base::GetProperty; using android::base::ParseInt; using android::base::Result; using android::base::unique_fd; using android::net::ResolverStats; using android::net::TunForwarder; using android::net::metrics::DnsMetricsListener; using android::net::resolv::aidl::UnsolicitedEventListener; using android::netdutils::enableSockopt; using android::netdutils::makeSlice; using android::netdutils::ResponseCode; using android::netdutils::ScopedAddrinfo; using android::netdutils::Stopwatch; using android::netdutils::toHex; namespace fs = std::filesystem; namespace { std::pair safe_getaddrinfo_time_taken(const char* node, const char* service, const addrinfo& hints) { Stopwatch s; ScopedAddrinfo result = safe_getaddrinfo(node, service, &hints); return {std::move(result), s.timeTakenUs() / 1000}; } struct NameserverStats { NameserverStats() = delete; NameserverStats(const std::string server) : server(server) {} NameserverStats& setSuccesses(int val) { successes = val; return *this; } NameserverStats& setErrors(int val) { errors = val; return *this; } NameserverStats& setTimeouts(int val) { timeouts = val; return *this; } NameserverStats& setInternalErrors(int val) { internal_errors = val; return *this; } NameserverStats& setRttAvg(int val) { rtt_avg = val; return *this; } const std::string server; int successes = 0; int errors = 0; int timeouts = 0; int internal_errors = 0; int rtt_avg = -1; }; #define SKIP_IF_KERNEL_VERSION_LOWER_THAN(major, minor, sub) \ do { \ if (!android::bpf::isAtLeastKernelVersion(major, minor, sub)) \ GTEST_SKIP() << "Required kernel: " << (major) << "." << (minor) << "." << (sub); \ } while (0) } // namespace class ResolverTest : public NetNativeTestBase { public: static void SetUpTestSuite() { // Get binder service. // Note that |mDnsClient| is not used for getting binder service in this static function. // The reason is that wants to keep |mDnsClient| as a non-static data member. |mDnsClient| // which sets up device network configuration could be independent from every test. // TODO: Perhaps add a static function in resolv_test_binder_utils.{cpp,h} to get binder // service. AIBinder* binder = AServiceManager_getService("dnsresolver"); sResolvBinder = ndk::SpAIBinder(binder); auto resolvService = aidl::android::net::IDnsResolver::fromBinder(sResolvBinder); ASSERT_NE(nullptr, resolvService.get()); // Subscribe the death recipient to the service IDnsResolver for detecting Netd death. // GTEST assertion macros are not invoked for generating a test failure in the death // recipient because the macros can't indicate failed test if Netd died between tests. // Moreover, continuing testing may have no meaningful after Netd death. Therefore, the // death recipient aborts process by GTEST_LOG_(FATAL) once Netd died. sResolvDeathRecipient = AIBinder_DeathRecipient_new([](void*) { constexpr char errorMessage[] = "Netd died"; LOG(ERROR) << errorMessage; GTEST_LOG_(FATAL) << errorMessage; }); ASSERT_EQ(STATUS_OK, AIBinder_linkToDeath(binder, sResolvDeathRecipient, nullptr)); // Subscribe the DNS listener for verifying DNS metrics event contents. sDnsMetricsListener = ndk::SharedRefBase::make( TEST_NETID /*monitor specific network*/); ASSERT_TRUE(resolvService->registerEventListener(sDnsMetricsListener).isOk()); // Subscribe the unsolicited event listener for verifying unsolicited event contents. sUnsolicitedEventListener = ndk::SharedRefBase::make( TEST_NETID /*monitor specific network*/); ASSERT_TRUE( resolvService->registerUnsolicitedEventListener(sUnsolicitedEventListener).isOk()); // Start the binder thread pool for listening DNS metrics events and receiving death // recipient. ABinderProcess_startThreadPool(); AllowNetworkInBackground(TEST_UID, true); AllowNetworkInBackground(TEST_UID2, true); } static void TearDownTestSuite() { AIBinder_DeathRecipient_delete(sResolvDeathRecipient); AllowNetworkInBackground(TEST_UID, false); AllowNetworkInBackground(TEST_UID2, false); } protected: void SetUp() { mDnsClient.SetUp(); sDnsMetricsListener->reset(); sUnsolicitedEventListener->reset(); SetMdnsRoute(); mIsResolverOptionIPCSupported = DnsResponderClient::isRemoteVersionSupported(mDnsClient.resolvService(), 9); } void TearDown() { // Ensure the dump works at the end of each test. DumpResolverService(); RemoveMdnsRoute(); mDnsClient.TearDown(); } void resetNetwork() { EXPECT_EQ(mDnsClient.TearDownOemNetwork(TEST_NETID), 0); EXPECT_EQ(mDnsClient.SetupOemNetwork(TEST_NETID), 0); } void StartDns(test::DNSResponder& dns, const std::vector& records) { for (const auto& r : records) { dns.addMapping(r.host_name, r.type, r.addr); } ASSERT_TRUE(dns.startServer()); dns.clearQueries(); } void DumpResolverService() { unique_fd fd(open("/dev/null", O_WRONLY)); EXPECT_EQ(mDnsClient.resolvService()->dump(fd, nullptr, 0), 0); const char* querylogCmd[] = {"querylog"}; // Keep it sync with DnsQueryLog::DUMP_KEYWORD. EXPECT_EQ(mDnsClient.resolvService()->dump(fd, querylogCmd, std::size(querylogCmd)), 0); } bool WaitForNat64Prefix(ExpectNat64PrefixStatus status, std::chrono::milliseconds timeout = std::chrono::milliseconds(1000)) { return sDnsMetricsListener->waitForNat64Prefix(status, timeout) && sUnsolicitedEventListener->waitForNat64Prefix( status == EXPECT_FOUND ? IDnsResolverUnsolicitedEventListener::PREFIX_OPERATION_ADDED : IDnsResolverUnsolicitedEventListener::PREFIX_OPERATION_REMOVED, timeout); } bool WaitForPrivateDnsValidation(std::string serverAddr, bool validated) { return sDnsMetricsListener->waitForPrivateDnsValidation(serverAddr, validated) && sUnsolicitedEventListener->waitForPrivateDnsValidation( serverAddr, validated ? IDnsResolverUnsolicitedEventListener::VALIDATION_RESULT_SUCCESS : IDnsResolverUnsolicitedEventListener::VALIDATION_RESULT_FAILURE, IDnsResolverUnsolicitedEventListener::PROTOCOL_DOT); } bool hasUncaughtPrivateDnsValidation(const std::string& serverAddr) { return sDnsMetricsListener->findValidationRecord(serverAddr) && sUnsolicitedEventListener->findValidationRecord( serverAddr, IDnsResolverUnsolicitedEventListener::PROTOCOL_DOT); } void ExpectDnsEvent(int32_t eventType, int32_t returnCode, const std::string& hostname, const std::vector& ipAddresses) { const DnsMetricsListener::DnsEvent expect = { TEST_NETID, eventType, returnCode, hostname, ipAddresses, static_cast(ipAddresses.size())}; do { // Blocking call until timeout. const auto dnsEvent = sDnsMetricsListener->popDnsEvent(); ASSERT_TRUE(dnsEvent.has_value()) << "Expected DnsEvent " << expect; if (dnsEvent.value() == expect) break; LOG(INFO) << "Skip unexpected DnsEvent: " << dnsEvent.value(); } while (true); while (returnCode == 0 || returnCode == RCODE_TIMEOUT) { // Blocking call until timeout. Result result = sUnsolicitedEventListener->popDnsHealthResult(); ASSERT_TRUE(result.ok()) << "Expected dns health result is " << returnCode; if ((returnCode == 0 && result.value() == IDnsResolverUnsolicitedEventListener::DNS_HEALTH_RESULT_OK) || (returnCode == RCODE_TIMEOUT && result.value() == IDnsResolverUnsolicitedEventListener::DNS_HEALTH_RESULT_TIMEOUT)) { break; } LOG(INFO) << "Skip unexpected dns health result:" << result.value(); } } enum class StatsCmp { LE, EQ }; bool expectStatsNotGreaterThan(const std::vector& nameserversStats) { return expectStatsFromGetResolverInfo(nameserversStats, StatsCmp::LE); } bool expectStatsEqualTo(const std::vector& nameserversStats) { return expectStatsFromGetResolverInfo(nameserversStats, StatsCmp::EQ); } bool expectStatsFromGetResolverInfo(const std::vector& nameserversStats, const StatsCmp cmp) { constexpr int RTT_TOLERANCE_MS = 200; const auto resolvInfo = mDnsClient.getResolverInfo(); if (!resolvInfo.ok()) { ADD_FAILURE() << resolvInfo.error().message(); return false; } const std::vector& res_servers = resolvInfo.value().dnsServers; const std::vector& res_stats = resolvInfo.value().stats; if (res_servers.size() != res_stats.size()) { ADD_FAILURE() << fmt::format("res_servers.size() != res_stats.size(): {} != {}", res_servers.size(), res_stats.size()); return false; } if (res_servers.size() != nameserversStats.size()) { ADD_FAILURE() << fmt::format("res_servers.size() != nameserversStats.size(): {} != {}", res_servers.size(), nameserversStats.size()); return false; } for (const auto& stats : nameserversStats) { SCOPED_TRACE(stats.server); const auto it = std::find(res_servers.begin(), res_servers.end(), stats.server); if (it == res_servers.end()) { ADD_FAILURE() << fmt::format("nameserver {} not found in the list {{{}}}", stats.server, fmt::join(res_servers, ", ")); return false; } const int index = std::distance(res_servers.begin(), it); // The check excludes last_sample_time and usable since they will be obsolete // after |res_stats| is retrieved from NetConfig.dnsStats rather than NetConfig.nsstats. switch (cmp) { case StatsCmp::EQ: EXPECT_EQ(res_stats[index].successes, stats.successes); EXPECT_EQ(res_stats[index].errors, stats.errors); EXPECT_EQ(res_stats[index].timeouts, stats.timeouts); EXPECT_EQ(res_stats[index].internal_errors, stats.internal_errors); // A negative rtt_avg means that there is no effective rtt in the // stats. The value should be deterministic. // See android_net_res_stats_aggregate() for mor details. if (res_stats[index].rtt_avg < 0 || stats.rtt_avg < 0) { EXPECT_EQ(res_stats[index].rtt_avg, stats.rtt_avg); } else { EXPECT_NEAR(res_stats[index].rtt_avg, stats.rtt_avg, RTT_TOLERANCE_MS); } break; case StatsCmp::LE: EXPECT_LE(res_stats[index].successes, stats.successes); EXPECT_LE(res_stats[index].errors, stats.errors); EXPECT_LE(res_stats[index].timeouts, stats.timeouts); EXPECT_LE(res_stats[index].internal_errors, stats.internal_errors); EXPECT_LE(res_stats[index].rtt_avg, stats.rtt_avg + RTT_TOLERANCE_MS); break; default: ADD_FAILURE() << "Unknown comparator " << static_cast(cmp); return false; } } return true; } // Since there's no way to terminate private DNS validation threads at any time. Tests that // focus on the results of private DNS validation can interfere with each other if they use the // same IP address for test servers. getUniqueIPv4Address() is a workaround to reduce the // possibility of tests being flaky. A feasible solution is to forbid the validation threads, // which are considered as outdated (e.g. switch the resolver to private DNS OFF mode), updating // the result to the PrivateDnsConfiguration instance. static std::string getUniqueIPv4Address() { static int counter = 0; return fmt::format("127.0.100.{}", (++counter & 0xff)); } DnsResponderClient mDnsClient; bool mIsResolverOptionIPCSupported = false; // Use a shared static DNS listener for all tests to avoid registering lots of listeners // which may be released late until process terminated. Currently, registered DNS listener // is removed by binder death notification which is fired when the process hosting an // IBinder has gone away. If every test in ResolverTest registers its DNS listener, Netd // may temporarily hold lots of dead listeners until the unit test process terminates. // TODO: Perhaps add an unregistering listener binder call or fork a listener process which // could be terminated earlier. static std::shared_ptr sDnsMetricsListener; // Initialized in SetUpTestSuite. inline static std::shared_ptr sUnsolicitedEventListener; // Initialized in SetUpTestSuite. // Use a shared static death recipient to monitor the service death. The static death // recipient could monitor the death not only during the test but also between tests. static AIBinder_DeathRecipient* sResolvDeathRecipient; // Initialized in SetUpTestSuite. // The linked AIBinder_DeathRecipient will be automatically unlinked if the binder is deleted. // The binder needs to be retained throughout tests. static ndk::SpAIBinder sResolvBinder; }; // Initialize static member of class. std::shared_ptr ResolverTest::sDnsMetricsListener; AIBinder_DeathRecipient* ResolverTest::sResolvDeathRecipient; ndk::SpAIBinder ResolverTest::sResolvBinder; TEST_F(ResolverTest, GetHostByName) { constexpr char nonexistent_host_name[] = "nonexistent.example.com."; test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, "1.2.3.3"}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); const hostent* result; result = gethostbyname("nonexistent"); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, nonexistent_host_name)); ASSERT_TRUE(result == nullptr); EXPECT_EQ(HOST_NOT_FOUND, h_errno); dns.clearQueries(); result = gethostbyname("hello"); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, kHelloExampleCom)); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } TEST_F(ResolverTest, GetHostByName_NULL) { // Most libc implementations would just crash on gethostbyname(NULL). Instead, Bionic // serializes the null argument over dnsproxyd, causing the server-side to crash! // This is a regression test. const char* const testcases[] = {nullptr, "", "^"}; for (const char* name : testcases) { SCOPED_TRACE(fmt::format("gethostbyname({})", name ? name : "NULL")); const hostent* result = gethostbyname(name); EXPECT_TRUE(result == nullptr); EXPECT_EQ(HOST_NOT_FOUND, h_errno); } } TEST_F(ResolverTest, GetHostByName_cnames) { constexpr char host_name[] = "host.example.com."; size_t cnamecount = 0; test::DNSResponder dns; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_cname, "a.example.com."}, {"a.example.com.", ns_type::ns_t_cname, "b.example.com."}, {"b.example.com.", ns_type::ns_t_cname, "c.example.com."}, {"c.example.com.", ns_type::ns_t_cname, "d.example.com."}, {"d.example.com.", ns_type::ns_t_cname, "e.example.com."}, {"e.example.com.", ns_type::ns_t_cname, host_name}, {host_name, ns_type::ns_t_a, "1.2.3.3"}, {host_name, ns_type::ns_t_aaaa, "2001:db8::42"}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // using gethostbyname2() to resolve ipv4 hello.example.com. to 1.2.3.3 // Ensure the v4 address and cnames are correct const hostent* result; result = gethostbyname2("hello", AF_INET); ASSERT_FALSE(result == nullptr); for (int i = 0; result != nullptr && result->h_aliases[i] != nullptr; i++) { std::string domain_name = records[i].host_name.substr(0, records[i].host_name.size() - 1); EXPECT_EQ(result->h_aliases[i], domain_name); cnamecount++; } // The size of "Non-cname type" record in DNS records is 2 ASSERT_EQ(cnamecount, records.size() - 2); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); EXPECT_EQ(1U, dns.queries().size()) << dns.dumpQueries(); // using gethostbyname2() to resolve ipv6 hello.example.com. to 2001:db8::42 // Ensure the v6 address and cnames are correct cnamecount = 0; dns.clearQueries(); result = gethostbyname2("hello", AF_INET6); for (unsigned i = 0; result != nullptr && result->h_aliases[i] != nullptr; i++) { std::string domain_name = records[i].host_name.substr(0, records[i].host_name.size() - 1); EXPECT_EQ(result->h_aliases[i], domain_name); cnamecount++; } // The size of "Non-cname type" DNS record in records is 2 ASSERT_EQ(cnamecount, records.size() - 2); ASSERT_FALSE(result == nullptr); ASSERT_EQ(16, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ("2001:db8::42", ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } TEST_F(ResolverTest, GetHostByName_cnamesInfiniteLoop) { test::DNSResponder dns; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_cname, "a.example.com."}, {"a.example.com.", ns_type::ns_t_cname, kHelloExampleCom}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); const hostent* result; result = gethostbyname2("hello", AF_INET); ASSERT_TRUE(result == nullptr); dns.clearQueries(); result = gethostbyname2("hello", AF_INET6); ASSERT_TRUE(result == nullptr); } TEST_F(ResolverTest, GetHostByName_localhost) { constexpr char name_camelcase[] = "LocalHost"; constexpr char name_ip6_dot[] = "ip6-localhost."; constexpr char name_ip6_fqdn[] = "ip6-localhost.example.com."; // Add a no-op nameserver which shouldn't receive any queries test::DNSResponder dns; StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // Expect no DNS queries; localhost is resolved via /etc/hosts const hostent* result = gethostbyname(kLocalHost); EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(kLocalHostAddr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); // Ensure the hosts file resolver ignores case of hostnames result = gethostbyname(name_camelcase); EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(kLocalHostAddr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); // The hosts file also contains ip6-localhost, but gethostbyname() won't // return it. This would be easy to // change, but there's no point in changing the legacy behavior; new code // should be calling getaddrinfo() anyway. // So we check the legacy behavior, which results in amusing A-record // lookups for ip6-localhost, with and without search domains appended. dns.clearQueries(); result = gethostbyname(kIp6LocalHost); EXPECT_EQ(2U, dns.queries().size()) << dns.dumpQueries(); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, name_ip6_dot)) << dns.dumpQueries(); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, name_ip6_fqdn)) << dns.dumpQueries(); ASSERT_TRUE(result == nullptr); // Finally, use gethostbyname2() to resolve ip6-localhost to ::1 from // the hosts file. dns.clearQueries(); result = gethostbyname2(kIp6LocalHost, AF_INET6); EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); ASSERT_FALSE(result == nullptr); ASSERT_EQ(16, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(kIp6LocalHostAddr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } TEST_F(ResolverTest, GetHostByName_numeric) { // Add a no-op nameserver which shouldn't receive any queries test::DNSResponder dns; StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // Numeric v4 address: expect no DNS queries constexpr char numeric_v4[] = "192.168.0.1"; const hostent* result = gethostbyname(numeric_v4); EXPECT_EQ(0U, dns.queries().size()); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); // v4 ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(numeric_v4, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); // gethostbyname() recognizes a v6 address, and fails with no DNS queries constexpr char numeric_v6[] = "2001:db8::42"; dns.clearQueries(); result = gethostbyname(numeric_v6); EXPECT_EQ(0U, dns.queries().size()); EXPECT_TRUE(result == nullptr); // Numeric v6 address with gethostbyname2(): succeeds with no DNS queries dns.clearQueries(); result = gethostbyname2(numeric_v6, AF_INET6); EXPECT_EQ(0U, dns.queries().size()); ASSERT_FALSE(result == nullptr); ASSERT_EQ(16, result->h_length); // v6 ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(numeric_v6, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); // Numeric v6 address with scope work with getaddrinfo(), // but gethostbyname2() does not understand them; it issues two dns // queries, then fails. This hardly ever happens, there's no point // in fixing this. This test simply verifies the current (bogus) // behavior to avoid further regressions (like crashes, or leaks). constexpr char numeric_v6_scope[] = "fe80::1%lo"; dns.clearQueries(); result = gethostbyname2(numeric_v6_scope, AF_INET6); EXPECT_EQ(2U, dns.queries().size()); // OUCH! ASSERT_TRUE(result == nullptr); } TEST_F(ResolverTest, BinderSerialization) { std::array params_offsets = { IDnsResolver::RESOLVER_PARAMS_SAMPLE_VALIDITY, IDnsResolver::RESOLVER_PARAMS_SUCCESS_THRESHOLD, IDnsResolver::RESOLVER_PARAMS_MIN_SAMPLES, IDnsResolver::RESOLVER_PARAMS_MAX_SAMPLES, IDnsResolver::RESOLVER_PARAMS_BASE_TIMEOUT_MSEC, IDnsResolver::RESOLVER_PARAMS_RETRY_COUNT, }; const int size = static_cast(params_offsets.size()); EXPECT_EQ(size, IDnsResolver::RESOLVER_PARAMS_COUNT); std::sort(params_offsets.begin(), params_offsets.end()); for (int i = 0; i < size; ++i) { EXPECT_EQ(params_offsets[i], i); } } TEST_F(ResolverTest, GetHostByName_Binder) { std::vector domains = {"example.com"}; std::vector> dns; std::vector servers; std::vector mappings; ASSERT_NO_FATAL_FAILURE(mDnsClient.SetupMappings(1, domains, &mappings)); ASSERT_NO_FATAL_FAILURE(mDnsClient.SetupDNSServers(4, mappings, &dns, &servers)); ASSERT_EQ(1U, mappings.size()); const DnsResponderClient::Mapping& mapping = mappings[0]; const auto resolverParams = ResolverParams::Builder() .setDomains(domains) .setDnsServers(servers) .setDotServers({}) .build(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(resolverParams)); const hostent* result = gethostbyname(mapping.host.c_str()); const size_t total_queries = std::accumulate(dns.begin(), dns.end(), 0, [&mapping](size_t total, auto& d) { return total + GetNumQueriesForType(*d, ns_type::ns_t_a, mapping.entry.c_str()); }); EXPECT_LE(1U, total_queries); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(mapping.ip4, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_EQ(servers.size(), resolvInfo.value().dnsServers.size()); EXPECT_EQ(domains.size(), resolvInfo.value().domains.size()); EXPECT_TRUE(resolvInfo.value().dotServers.empty()); EXPECT_EQ(resolverParams.sampleValiditySeconds, resolvInfo.value().params.sample_validity); EXPECT_EQ(resolverParams.successThreshold, resolvInfo.value().params.success_threshold); EXPECT_EQ(resolverParams.minSamples, resolvInfo.value().params.min_samples); EXPECT_EQ(resolverParams.maxSamples, resolvInfo.value().params.max_samples); EXPECT_EQ(resolverParams.baseTimeoutMsec, resolvInfo.value().params.base_timeout_msec); EXPECT_EQ(resolverParams.retryCount, resolvInfo.value().params.retry_count); EXPECT_EQ(servers.size(), resolvInfo.value().stats.size()); EXPECT_THAT(resolvInfo.value().dnsServers, testing::UnorderedElementsAreArray(servers)); EXPECT_THAT(resolvInfo.value().domains, testing::UnorderedElementsAreArray(domains)); } TEST_F(ResolverTest, GetAddrInfo) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char listen_addr2[] = "127.0.0.5"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); test::DNSResponder dns2(listen_addr2); StartDns(dns, records); StartDns(dns2, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork({listen_addr})); dns.clearQueries(); dns2.clearQueries(); ScopedAddrinfo result = safe_getaddrinfo("howdy", nullptr, nullptr); EXPECT_TRUE(result != nullptr); size_t found = GetNumQueries(dns, host_name); EXPECT_LE(1U, found); // Could be A or AAAA std::string result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4" || result_str == "::1.2.3.4") << ", result_str='" << result_str << "'"; // Verify that the name is cached. size_t old_found = found; result = safe_getaddrinfo("howdy", nullptr, nullptr); EXPECT_TRUE(result != nullptr); found = GetNumQueries(dns, host_name); EXPECT_LE(1U, found); EXPECT_EQ(old_found, found); result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4" || result_str == "::1.2.3.4") << result_str; // Change the DNS resolver, ensure that queries are still cached. ASSERT_TRUE(mDnsClient.SetResolversForNetwork({listen_addr2})); dns.clearQueries(); dns2.clearQueries(); result = safe_getaddrinfo("howdy", nullptr, nullptr); EXPECT_TRUE(result != nullptr); found = GetNumQueries(dns, host_name); size_t found2 = GetNumQueries(dns2, host_name); EXPECT_EQ(0U, found); EXPECT_LE(0U, found2); // Could be A or AAAA result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4" || result_str == "::1.2.3.4") << ", result_str='" << result_str << "'"; } TEST_F(ResolverTest, GetAddrInfoV4) { test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, "1.2.3.5"}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); const addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(1U, GetNumQueries(dns, kHelloExampleCom)); EXPECT_EQ("1.2.3.5", ToString(result)); } TEST_F(ResolverTest, GetAddrInfo_localhost) { // Add a no-op nameserver which shouldn't receive any queries test::DNSResponder dns; StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); ScopedAddrinfo result = safe_getaddrinfo(kLocalHost, nullptr, nullptr); EXPECT_TRUE(result != nullptr); // Expect no DNS queries; localhost is resolved via /etc/hosts EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); EXPECT_EQ(kLocalHostAddr, ToString(result)); result = safe_getaddrinfo(kIp6LocalHost, nullptr, nullptr); EXPECT_TRUE(result != nullptr); // Expect no DNS queries; ip6-localhost is resolved via /etc/hosts EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); EXPECT_EQ(kIp6LocalHostAddr, ToString(result)); } TEST_F(ResolverTest, GetAddrInfo_NumericHostname) { // Add a no-op nameserver which shouldn't receive any queries test::DNSResponder dns; StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); ScopedAddrinfo result = safe_getaddrinfo("1.2.3.4", nullptr, nullptr); EXPECT_TRUE(result != nullptr); // Expect no DNS queries. Numeric hostname doesn't need to resolve. EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); EXPECT_EQ("1.2.3.4", ToString(result)); result = safe_getaddrinfo("2001:db8::1", nullptr, nullptr); EXPECT_TRUE(result != nullptr); // Expect no DNS queries. Numeric hostname doesn't need to resolve. EXPECT_TRUE(dns.queries().empty()) << dns.dumpQueries(); EXPECT_EQ("2001:db8::1", ToString(result)); } TEST_F(ResolverTest, GetAddrInfo_InvalidSocketType) { test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, "1.2.3.5"}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // TODO: Test other invalid socket types. const addrinfo hints = { .ai_family = AF_UNSPEC, .ai_socktype = SOCK_PACKET, }; addrinfo* result = nullptr; // This is a valid hint, but the query won't be sent because the socket type is // not supported. EXPECT_EQ(EAI_NODATA, getaddrinfo("hello", nullptr, &hints, &result)); ScopedAddrinfo result_cleanup(result); EXPECT_EQ(nullptr, result); } // Verify if the resolver correctly handle multiple queries simultaneously // step 1: set dns server#1 into deferred responding mode. // step 2: thread#1 query "hello.example.com." --> resolver send query to server#1. // step 3: thread#2 query "hello.example.com." --> resolver hold the request and wait for // response of previous pending query sent by thread#1. // step 4: thread#3 query "konbanha.example.com." --> resolver send query to server#3. Server // respond to resolver immediately. // step 5: check if server#1 get 1 query by thread#1, server#2 get 0 query, server#3 get 1 query. // step 6: resume dns server#1 to respond dns query in step#2. // step 7: thread#1 and #2 should get returned from DNS query after step#6. Also, check the // number of queries in server#2 is 0 to ensure thread#2 does not wake up unexpectedly // before signaled by thread#1. TEST_F(ResolverTest, GetAddrInfoV4_deferred_resp) { const char* listen_addr1 = "127.0.0.9"; const char* listen_addr2 = "127.0.0.10"; const char* listen_addr3 = "127.0.0.11"; const char* listen_srv = "53"; const char* host_name_deferred = "hello.example.com."; const char* host_name_normal = "konbanha.example.com."; test::DNSResponder dns1(listen_addr1, listen_srv, ns_rcode::ns_r_servfail); test::DNSResponder dns2(listen_addr2, listen_srv, ns_rcode::ns_r_servfail); test::DNSResponder dns3(listen_addr3, listen_srv, ns_rcode::ns_r_servfail); dns1.addMapping(host_name_deferred, ns_type::ns_t_a, "1.2.3.4"); dns2.addMapping(host_name_deferred, ns_type::ns_t_a, "1.2.3.4"); dns3.addMapping(host_name_normal, ns_type::ns_t_a, "1.2.3.5"); ASSERT_TRUE(dns1.startServer()); ASSERT_TRUE(dns2.startServer()); ASSERT_TRUE(dns3.startServer()); const std::vector servers_for_t1 = {listen_addr1}; const std::vector servers_for_t2 = {listen_addr2}; const std::vector servers_for_t3 = {listen_addr3}; addrinfo hints = {.ai_family = AF_INET}; const std::array params = {300, 25, 8, 8, 5000, 0}; bool t3_task_done = false; bool t2_sv_setup_done = false; dns1.setDeferredResp(true); std::thread t1([&, this]() { ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder() .setDnsServers(servers_for_t1) .setDotServers({}) .setParams(params) .build())); ScopedAddrinfo result = safe_getaddrinfo(host_name_deferred, nullptr, &hints); // t3's dns query should got returned first EXPECT_TRUE(t3_task_done); EXPECT_EQ(1U, GetNumQueries(dns1, host_name_deferred)); EXPECT_TRUE(result != nullptr); EXPECT_EQ("1.2.3.4", ToString(result)); }); // ensuring t1 and t2 handler functions are processed in order EXPECT_TRUE(PollForCondition([&]() { return GetNumQueries(dns1, host_name_deferred); })); std::thread t2([&, this]() { ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder() .setDnsServers(servers_for_t2) .setDotServers({}) .setParams(params) .build())); t2_sv_setup_done = true; ScopedAddrinfo result = safe_getaddrinfo(host_name_deferred, nullptr, &hints); EXPECT_TRUE(t3_task_done); EXPECT_EQ(0U, GetNumQueries(dns2, host_name_deferred)); EXPECT_TRUE(result != nullptr); EXPECT_EQ("1.2.3.4", ToString(result)); const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_EQ(0, resolvInfo.value().waitForPendingReqTimeoutCount); }); // ensuring t2 and t3 handler functions are processed in order EXPECT_TRUE(PollForCondition([&]() { return t2_sv_setup_done; })); std::thread t3([&, this]() { ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder() .setDnsServers(servers_for_t3) .setDotServers({}) .setParams(params) .build())); ScopedAddrinfo result = safe_getaddrinfo(host_name_normal, nullptr, &hints); EXPECT_EQ(1U, GetNumQueries(dns1, host_name_deferred)); EXPECT_EQ(0U, GetNumQueries(dns2, host_name_deferred)); EXPECT_EQ(1U, GetNumQueries(dns3, host_name_normal)); EXPECT_TRUE(result != nullptr); EXPECT_EQ("1.2.3.5", ToString(result)); t3_task_done = true; dns1.setDeferredResp(false); }); t3.join(); t1.join(); t2.join(); } TEST_F(ResolverTest, GetAddrInfoV4_MultiAnswers) { test::DNSResponder dns(test::DNSResponder::MappingType::BINARY_PACKET); dns.addMappingBinaryPacket(kHelloExampleComQueryV4, kHelloExampleComResponsesV4); StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // Expect the DNS result order is the same as the RR order in the DNS response // |kHelloExampleComResponsesV4| because none of rule in the native sorting // function _rfc6724_compare() is matched. // // The reason is here for the sorting result from _rfc6724_compare. // For rule 1: avoid unusable destinations, all addresses are unusable on a fake test network. // For rule 2: prefer matching scope, all addresses don't match because of no source address. // See rule#1 as well. // (rule 3 is not implemented) // (rule 4 is not implemented) // For rule 5: prefer matching label, all addresses get the same label 4 for AF_INET. // For rule 6: prefer higher precedence, all addresses get the same precedence 35 for AF_INET. // (rule 7 is not implemented) // For rule 8: prefer smaller scope, all destination addresses has the same scope. // For rule 9: use longest matching prefix, IPv6 only. // For rule 10: leave the order unchanged, these IPv4 DNS addresses meet this rule. // // See packages/modules/DnsResolver/getaddrinfo.cpp EXPECT_THAT(ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV4, kHelloExampleComAddrV4_2, kHelloExampleComAddrV4_3)); // .ai_socktype will be 0. hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // The results are sorted in every querying by explore_options and then concatenates all sorted // results. resolv_getaddrinfo() calls explore_fqdn() many times by the different // explore_options. It means that resolv_rfc6724_sort() only sorts the ordering in the results // of each explore_options and concatenates all sorted results into one link list. The address // order of the output addrinfo is: // 1.2.3.4 (socktype=2, protocol=17) -> // 8.8.8.8 (socktype=2, protocol=17) -> // 81.117.21.202 (socktype=2, protocol=17) -> // 1.2.3.4 (socktype=1, protocol=6) -> // 8.8.8.8 (socktype=1, protocol=6) -> // 81.117.21.202 (socktype=1, protocol=6) // // See resolv_getaddrinfo, explore_fqdn and dns_getaddrinfo. EXPECT_THAT(ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV4, kHelloExampleComAddrV4_2, kHelloExampleComAddrV4_3, kHelloExampleComAddrV4, kHelloExampleComAddrV4_2, kHelloExampleComAddrV4_3)); } TEST_F(ResolverTest, GetAddrInfoV6_MultiAnswers) { test::DNSResponder dns(test::DNSResponder::MappingType::BINARY_PACKET); dns.addMappingBinaryPacket(kHelloExampleComQueryV6, kHelloExampleComResponsesV6); StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // Expect the DNS result order is GUA, teredo tunneling address and IPv4-compatible address // because of the precedence comparison of RFC 6724. // // The reason is here for the sorting result from _rfc6724_compare. // For rule 1: avoid unusable destinations, all addresses are unusable on a fake test network. // For rule 2: prefer matching scope, all addresses don't match because of no source address. // See rule#1 as well. // (rule 3 is not implemented) // (rule 4 is not implemented) // For rule 5: prefer matching label, the source address is not valid and can't match the dns // reply addresses. See rule#1 as well. // For rule 6: prefer higher precedence, sorted by the order: gua(40), teredo(5) and // ipv4-compatible(1). // Ignore from rule 7 to rule 10 because the results has been sorted by rule 6. // // See _get_precedence, _rfc6724_compare in packages/modules/DnsResolver/getaddrinfo.cpp EXPECT_THAT(ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT)); hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // The results are sorted in every querying by explore_options and then concatenates all sorted // results. resolv_getaddrinfo() calls explore_fqdn() many times by the different // explore_options. It means that resolv_rfc6724_sort() only sorts the ordering in the results // of each explore_options and concatenates all sorted results into one link list. The address // order of the output addrinfo is: // 2404:6800::5175:15ca (socktype=2, protocol=17) -> // 2001::47c1 (socktype=2, protocol=17) -> // ::1.2.3.4 (socktype=2, protocol=17) -> // 2404:6800::5175:15ca (socktype=1, protocol=6) -> // 2001::47c1 (socktype=1, protocol=6) -> // ::1.2.3.4 (socktype=1, protocol=6) // // See resolv_getaddrinfo, explore_fqdn and dns_getaddrinfo. EXPECT_THAT( ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT)); } TEST_F(ResolverTest, GetAddrInfoV4V6_MultiAnswers) { test::DNSResponder dns(test::DNSResponder::MappingType::BINARY_PACKET); // Use one IPv4 address only because we can't control IPv4 address ordering in this test // which uses a fake network. dns.addMappingBinaryPacket(kHelloExampleComQueryV4, kHelloExampleComResponseV4); dns.addMappingBinaryPacket(kHelloExampleComQueryV6, kHelloExampleComResponsesV6); StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // Expect the DNS result order is ipv6 global unicast address, IPv4 address, IPv6 teredo // tunneling address and IPv4-compatible IPv6 address because of the precedence comparison // of RFC 6724. // // The reason is here for the sorting result from _rfc6724_compare. // For rule 1: avoid unusable destinations, all addresses are unusable on a fake test network. // For rule 2: prefer matching scope, all addresses don't match because of no source address. // See rule#1 as well. // (rule 3 is not implemented) // (rule 4 is not implemented) // For rule 5: prefer matching label, the source address is not valid and can't match the dns // reply addresses. See rule#1 as well. // For rule 6: prefer higher precedence, sorted by the order: gua(40), ipv4(35), teredo(5) and // ipv4-compatible(1). // Ignore from rule 7 to rule 10 because the results has been sorted by rule 6. // // See _get_precedence, _rfc6724_compare in packages/modules/DnsResolver/getaddrinfo.cpp EXPECT_THAT( ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV4, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT)); hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // The results are sorted in every querying by explore_options and then concatenates all sorted // results. resolv_getaddrinfo() calls explore_fqdn() many times by the different // explore_options. It means that resolv_rfc6724_sort() only sorts the ordering in the results // of each explore_options and concatenates all sorted results into one link list. The address // order of the output addrinfo is: // 2404:6800::5175:15ca (socktype=2, protocol=17) -> // 1.2.3.4 (socktype=2, protocol=17) -> // 2001::47c1 (socktype=2, protocol=17) -> // ::1.2.3.4 (socktype=2, protocol=17) -> // 2404:6800::5175:15ca (socktype=1, protocol=6) -> // 1.2.3.4 (socktype=1, protocol=6) -> // 2001::47c1 (socktype=1, protocol=6) -> // ::1.2.3.4 (socktype=1, protocol=6) // // See resolv_getaddrinfo, explore_fqdn and dns_getaddrinfo. EXPECT_THAT( ToStrings(result), testing::ElementsAre(kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV4, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV4, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV6_IPV4COMPAT)); } TEST_F(ResolverTest, GetAddrInfo_cnames) { constexpr char host_name[] = "host.example.com."; test::DNSResponder dns; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_cname, "a.example.com."}, {"a.example.com.", ns_type::ns_t_cname, "b.example.com."}, {"b.example.com.", ns_type::ns_t_cname, "c.example.com."}, {"c.example.com.", ns_type::ns_t_cname, "d.example.com."}, {"d.example.com.", ns_type::ns_t_cname, "e.example.com."}, {"e.example.com.", ns_type::ns_t_cname, host_name}, {host_name, ns_type::ns_t_a, "1.2.3.3"}, {host_name, ns_type::ns_t_aaaa, "2001:db8::42"}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); dns.clearQueries(); hints = {.ai_family = AF_INET6}; result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ("2001:db8::42", ToString(result)); } TEST_F(ResolverTest, GetAddrInfo_cnamesNoIpAddress) { test::DNSResponder dns; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_cname, "a.example.com."}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result == nullptr); dns.clearQueries(); hints = {.ai_family = AF_INET6}; result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result == nullptr); } TEST_F(ResolverTest, GetAddrInfo_cnamesIllegalRdata) { test::DNSResponder dns; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_cname, ".!#?"}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result == nullptr); dns.clearQueries(); hints = {.ai_family = AF_INET6}; result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result == nullptr); } TEST_F(ResolverTest, GetAddrInfoForCaseInSensitiveDomains) { test::DNSResponder dns; const char* host_name = "howdy.example.com."; const char* host_name2 = "HOWDY.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, {host_name2, ns_type::ns_t_a, "1.2.3.5"}, {host_name2, ns_type::ns_t_aaaa, "::1.2.3.5"}, }; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); ScopedAddrinfo hostname_result = safe_getaddrinfo("howdy", nullptr, nullptr); EXPECT_TRUE(hostname_result != nullptr); const size_t hostname1_count_after_first_query = GetNumQueries(dns, host_name); EXPECT_LE(1U, hostname1_count_after_first_query); // Could be A or AAAA std::string hostname_result_str = ToString(hostname_result); EXPECT_TRUE(hostname_result_str == "1.2.3.4" || hostname_result_str == "::1.2.3.4"); // Verify that the name is cached. ScopedAddrinfo hostname2_result = safe_getaddrinfo("HOWDY", nullptr, nullptr); EXPECT_TRUE(hostname2_result != nullptr); const size_t hostname1_count_after_second_query = GetNumQueries(dns, host_name); EXPECT_LE(1U, hostname1_count_after_second_query); // verify that there is no change in num of queries for howdy.example.com EXPECT_EQ(hostname1_count_after_first_query, hostname1_count_after_second_query); // Number of queries for HOWDY.example.com would be >= 1 if domain names // are considered case-sensitive, else number of queries should be 0. const size_t hostname2_count = GetNumQueries(dns, host_name2); EXPECT_EQ(0U,hostname2_count); std::string hostname2_result_str = ToString(hostname2_result); EXPECT_TRUE(hostname2_result_str == "1.2.3.4" || hostname2_result_str == "::1.2.3.4"); // verify that the result is still the same address even though // mixed-case string is not in the DNS ScopedAddrinfo result = safe_getaddrinfo("HowDY", nullptr, nullptr); EXPECT_TRUE(result != nullptr); std::string result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4" || result_str == "::1.2.3.4"); } TEST_F(ResolverTest, MultidomainResolution) { constexpr char host_name[] = "nihao.example2.com."; std::vector searchDomains = {"example1.com", "example2.com", "example3.com"}; test::DNSResponder dns("127.0.0.6"); StartDns(dns, {{host_name, ns_type::ns_t_a, "1.2.3.3"}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork({"127.0.0.6"}, searchDomains)); const hostent* result = gethostbyname("nihao"); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, host_name)); ASSERT_FALSE(result == nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } TEST_F(ResolverTest, GetAddrInfoV6_numeric) { constexpr char host_name[] = "ohayou.example.com."; constexpr char numeric_addr[] = "fe80::1%lo"; test::DNSResponder dns; dns.setResponseProbability(0.0); StartDns(dns, {{host_name, ns_type::ns_t_aaaa, "2001:db8::5"}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET6}; ScopedAddrinfo result = safe_getaddrinfo(numeric_addr, nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(numeric_addr, ToString(result)); EXPECT_TRUE(dns.queries().empty()); // Ensure no DNS queries were sent out // Now try a non-numeric hostname query with the AI_NUMERICHOST flag set. // We should fail without sending out a DNS query. hints.ai_flags |= AI_NUMERICHOST; result = safe_getaddrinfo(host_name, nullptr, &hints); EXPECT_TRUE(result == nullptr); EXPECT_TRUE(dns.queries().empty()); // Ensure no DNS queries were sent out } TEST_F(ResolverTest, GetAddrInfoV6_failing) { constexpr char listen_addr0[] = "127.0.0.7"; constexpr char listen_addr1[] = "127.0.0.8"; const char* host_name = "ohayou.example.com."; test::DNSResponder dns0(listen_addr0); test::DNSResponder dns1(listen_addr1); dns0.setResponseProbability(0.0); StartDns(dns0, {{host_name, ns_type::ns_t_aaaa, "2001:db8::5"}}); StartDns(dns1, {{host_name, ns_type::ns_t_aaaa, "2001:db8::6"}}); std::vector servers = {listen_addr0, listen_addr1}; // int sample_count = 8; const std::array params = { 300, 25, sample_count, sample_count, 0, 0}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder() .setDnsServers(servers) .setDotServers({}) .setParams(params) .build())); // Repeatedly perform resolutions for non-existing domains until MAXNSSAMPLES resolutions have // reached the dns0, which is set to fail. No more requests should then arrive at that server // for the next sample_lifetime seconds. // TODO: This approach is implementation-dependent, change once metrics reporting is available. const addrinfo hints = {.ai_family = AF_INET6}; for (int i = 0; i < sample_count; ++i) { std::string domain = fmt::format("nonexistent{}", i); ScopedAddrinfo result = safe_getaddrinfo(domain.c_str(), nullptr, &hints); } // Due to 100% errors for all possible samples, the server should be ignored from now on and // only the second one used for all following queries, until NSSAMPLE_VALIDITY is reached. dns0.clearQueries(); dns1.clearQueries(); ScopedAddrinfo result = safe_getaddrinfo("ohayou", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(0U, GetNumQueries(dns0, host_name)); EXPECT_EQ(1U, GetNumQueries(dns1, host_name)); } TEST_F(ResolverTest, GetAddrInfoV6_nonresponsive) { constexpr char listen_addr0[] = "127.0.0.7"; constexpr char listen_addr1[] = "127.0.0.8"; constexpr char listen_srv[] = "53"; constexpr char host_name1[] = "ohayou.example.com."; constexpr char host_name2[] = "ciao.example.com."; const std::vector defaultSearchDomain = {"example.com"}; // The minimal timeout is 1000ms, so we can't decrease timeout // So reduce retry count. const std::array reduceRetryParams = { 300, // sample validity in seconds 25, // success threshod in percent 8, 8, // {MIN,MAX}_SAMPLES 1000, // BASE_TIMEOUT_MSEC 1, // retry count }; const std::vector records0 = { {host_name1, ns_type::ns_t_aaaa, "2001:db8::5"}, {host_name2, ns_type::ns_t_aaaa, "2001:db8::5"}, }; const std::vector records1 = { {host_name1, ns_type::ns_t_aaaa, "2001:db8::6"}, {host_name2, ns_type::ns_t_aaaa, "2001:db8::6"}, }; // dns0 does not respond with 100% probability, while // dns1 responds normally, at least initially. test::DNSResponder dns0(listen_addr0, listen_srv, static_cast(-1)); test::DNSResponder dns1(listen_addr1, listen_srv, static_cast(-1)); dns0.setResponseProbability(0.0); StartDns(dns0, records0); StartDns(dns1, records1); ASSERT_TRUE( mDnsClient.SetResolversFromParcel(ResolverParams::Builder() .setDnsServers({listen_addr0, listen_addr1}) .setDotServers({}) .setParams(reduceRetryParams) .build())); // Specify ai_socktype to make getaddrinfo will only query 1 time const addrinfo hints = {.ai_family = AF_INET6, .ai_socktype = SOCK_STREAM}; // dns0 will ignore the request, and we'll fallback to dns1 after the first // retry. ScopedAddrinfo result = safe_getaddrinfo(host_name1, nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(1U, GetNumQueries(dns0, host_name1)); EXPECT_EQ(1U, GetNumQueries(dns1, host_name1)); ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, 0, host_name1, {"2001:db8::6"}); // Now make dns1 also ignore 100% requests... The resolve should alternate // queries between the nameservers and fail dns1.setResponseProbability(0.0); addrinfo* result2 = nullptr; EXPECT_EQ(EAI_NODATA, getaddrinfo(host_name2, nullptr, &hints, &result2)); EXPECT_EQ(nullptr, result2); EXPECT_EQ(1U, GetNumQueries(dns0, host_name2)); EXPECT_EQ(1U, GetNumQueries(dns1, host_name2)); ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, RCODE_TIMEOUT, host_name2, {}); } TEST_F(ResolverTest, GetAddrInfoV6_concurrent) { constexpr char listen_addr0[] = "127.0.0.9"; constexpr char listen_addr1[] = "127.0.0.10"; constexpr char listen_addr2[] = "127.0.0.11"; constexpr char host_name[] = "konbanha.example.com."; test::DNSResponder dns0(listen_addr0); test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns0, {{host_name, ns_type::ns_t_aaaa, "2001:db8::5"}}); StartDns(dns1, {{host_name, ns_type::ns_t_aaaa, "2001:db8::6"}}); StartDns(dns2, {{host_name, ns_type::ns_t_aaaa, "2001:db8::7"}}); const std::vector servers = {listen_addr0, listen_addr1, listen_addr2}; std::vector threads(10); for (std::thread& thread : threads) { thread = std::thread([this, &servers]() { unsigned delay = arc4random_uniform(1 * 1000 * 1000); // <= 1s usleep(delay); std::vector serverSubset; for (const auto& server : servers) { if (arc4random_uniform(2)) { serverSubset.push_back(server); } } if (serverSubset.empty()) serverSubset = servers; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(serverSubset)); const addrinfo hints = {.ai_family = AF_INET6}; addrinfo* result = nullptr; int rv = getaddrinfo("konbanha", nullptr, &hints, &result); EXPECT_EQ(0, rv) << "error [" << rv << "] " << gai_strerror(rv); if (result) { freeaddrinfo(result); result = nullptr; } }); } for (std::thread& thread : threads) { thread.join(); } const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_EQ(0, resolvInfo.value().waitForPendingReqTimeoutCount); } TEST_F(ResolverTest, SkipBadServersDueToInternalError) { constexpr char listen_addr1[] = "fe80::1"; constexpr char listen_addr2[] = "255.255.255.255"; constexpr char listen_addr3[] = "127.0.0.3"; int counter = 0; // To generate unique hostnames. test::DNSResponder dns(listen_addr3); ASSERT_TRUE(dns.startServer()); ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.servers = {listen_addr1, listen_addr2, listen_addr3}; setupParams.minSamples = 2; // Recognize bad servers in two attempts when sorting not enabled. ResolverParamsParcel cleanupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); cleanupParams.servers.clear(); cleanupParams.tlsServers.clear(); for (const auto& sortNameserversFlag : {"" /* unset */, "0" /* off */, "1" /* on */}) { SCOPED_TRACE(fmt::format("sortNameversFlag_{}", sortNameserversFlag)); ScopedSystemProperties scopedSystemProperties(kSortNameserversFlag, sortNameserversFlag); // Re-setup test network to make experiment flag take effect. resetNetwork(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); // Start sending synchronized querying. for (int i = 0; i < 100; i++) { std::string hostName = fmt::format("hello{}.com.", counter++); dns.addMapping(hostName, ns_type::ns_t_a, "1.2.3.4"); const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; EXPECT_TRUE(safe_getaddrinfo(hostName.c_str(), nullptr, &hints) != nullptr); } const std::vector targetStats = { NameserverStats(listen_addr1).setInternalErrors(5), NameserverStats(listen_addr2).setInternalErrors(5), NameserverStats(listen_addr3).setSuccesses(setupParams.maxSamples).setRttAvg(1), }; EXPECT_TRUE(expectStatsNotGreaterThan(targetStats)); // Also verify the number of queries received in the server because res_stats.successes has // a maximum. EXPECT_EQ(dns.queries().size(), 100U); // Reset the state. ASSERT_TRUE(mDnsClient.SetResolversFromParcel(cleanupParams)); dns.clearQueries(); } } TEST_F(ResolverTest, SkipBadServersDueToTimeout) { constexpr char listen_addr1[] = "127.0.0.3"; constexpr char listen_addr2[] = "127.0.0.4"; int counter = 0; // To generate unique hostnames. ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.servers = {listen_addr1, listen_addr2}; setupParams.minSamples = 2; // Recognize bad servers in two attempts when sorting not enabled. ResolverParamsParcel cleanupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); cleanupParams.servers.clear(); cleanupParams.tlsServers.clear(); // Set dns1 non-responsive and dns2 workable. test::DNSResponder dns1(listen_addr1, test::kDefaultListenService, static_cast(-1)); test::DNSResponder dns2(listen_addr2); dns1.setResponseProbability(0.0); ASSERT_TRUE(dns1.startServer()); ASSERT_TRUE(dns2.startServer()); for (const auto& sortNameserversFlag : {"" /* unset */, "0" /* off */, "1" /* on */}) { SCOPED_TRACE(fmt::format("sortNameversFlag_{}", sortNameserversFlag)); ScopedSystemProperties scopedSystemProperties(kSortNameserversFlag, sortNameserversFlag); // Re-setup test network to make experiment flag take effect. resetNetwork(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); // Start sending synchronized querying. for (int i = 0; i < 100; i++) { std::string hostName = fmt::format("hello{}.com.", counter++); dns1.addMapping(hostName, ns_type::ns_t_a, "1.2.3.4"); dns2.addMapping(hostName, ns_type::ns_t_a, "1.2.3.5"); const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; EXPECT_TRUE(safe_getaddrinfo(hostName.c_str(), nullptr, &hints) != nullptr); } const std::vector targetStats = { NameserverStats(listen_addr1).setTimeouts(5), NameserverStats(listen_addr2).setSuccesses(setupParams.maxSamples).setRttAvg(1), }; EXPECT_TRUE(expectStatsNotGreaterThan(targetStats)); // Also verify the number of queries received in the server because res_stats.successes has // an upper bound. EXPECT_GT(dns1.queries().size(), 0U); EXPECT_LT(dns1.queries().size(), 5U); EXPECT_EQ(dns2.queries().size(), 100U); // Reset the state. ASSERT_TRUE(mDnsClient.SetResolversFromParcel(cleanupParams)); dns1.clearQueries(); dns2.clearQueries(); } } TEST_F(ResolverTest, GetAddrInfoFromCustTable_InvalidInput) { constexpr char hostnameNoip[] = "noip.example.com."; constexpr char hostnameInvalidip[] = "invalidip.example.com."; const std::vector invalidCustHosts = { {"", hostnameNoip}, {"wrong IP", hostnameInvalidip}, }; test::DNSResponder dns; StartDns(dns, {}); auto resolverParams = DnsResponderClient::GetDefaultResolverParamsParcel(); ResolverOptionsParcel resolverOptions; resolverOptions.hosts = invalidCustHosts; if (!mIsResolverOptionIPCSupported) { resolverParams.resolverOptions = resolverOptions; } ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(resolverParams).isOk()); if (mIsResolverOptionIPCSupported) { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(resolverParams.netId, resolverOptions) .isOk()); } for (const auto& hostname : {hostnameNoip, hostnameInvalidip}) { // The query won't get data from customized table because of invalid customized table // and DNSResponder also has no records. hostnameNoip has never registered and // hostnameInvalidip has registered but wrong IP. const addrinfo hints = {.ai_family = AF_UNSPEC}; ScopedAddrinfo result = safe_getaddrinfo(hostname, nullptr, &hints); ASSERT_TRUE(result == nullptr); EXPECT_EQ(4U, GetNumQueries(dns, hostname)); } } TEST_F(ResolverTest, GetAddrInfoFromCustTable) { constexpr char hostnameV4[] = "v4only.example.com."; constexpr char hostnameV6[] = "v6only.example.com."; constexpr char hostnameV4V6[] = "v4v6.example.com."; constexpr char custAddrV4[] = "1.2.3.4"; constexpr char custAddrV6[] = "::1.2.3.4"; constexpr char dnsSvAddrV4[] = "1.2.3.5"; constexpr char dnsSvAddrV6[] = "::1.2.3.5"; const std::vector custHostV4 = { {custAddrV4, hostnameV4}, }; const std::vector custHostV6 = { {custAddrV6, hostnameV6}, }; const std::vector custHostV4V6 = { {custAddrV4, hostnameV4V6}, {custAddrV6, hostnameV4V6}, }; const std::vector dnsSvHostV4 = { {hostnameV4, ns_type::ns_t_a, dnsSvAddrV4}, }; const std::vector dnsSvHostV6 = { {hostnameV6, ns_type::ns_t_aaaa, dnsSvAddrV6}, }; const std::vector dnsSvHostV4V6 = { {hostnameV4V6, ns_type::ns_t_a, dnsSvAddrV4}, {hostnameV4V6, ns_type::ns_t_aaaa, dnsSvAddrV6}, }; struct TestConfig { const std::string name; const std::vector customizedHosts; const std::vector dnsserverHosts; const std::vector queryResult; std::string asParameters() const { return fmt::format("name: {}, customizedHosts: {}, dnsserverHosts: {}", name, customizedHosts.empty() ? "No" : "Yes", dnsserverHosts.empty() ? "No" : "Yes"); } } testConfigs[]{ // clang-format off {hostnameV4, {}, {}, {}}, {hostnameV4, {}, dnsSvHostV4, {dnsSvAddrV4}}, {hostnameV4, custHostV4, {}, {custAddrV4}}, {hostnameV4, custHostV4, dnsSvHostV4, {custAddrV4}}, {hostnameV6, {}, {}, {}}, {hostnameV6, {}, dnsSvHostV6, {dnsSvAddrV6}}, {hostnameV6, custHostV6, {}, {custAddrV6}}, {hostnameV6, custHostV6, dnsSvHostV6, {custAddrV6}}, {hostnameV4V6, {}, {}, {}}, {hostnameV4V6, {}, dnsSvHostV4V6, {dnsSvAddrV4, dnsSvAddrV6}}, {hostnameV4V6, custHostV4V6, {}, {custAddrV4, custAddrV6}}, {hostnameV4V6, custHostV4V6, dnsSvHostV4V6, {custAddrV4, custAddrV6}}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); test::DNSResponder dns; StartDns(dns, config.dnsserverHosts); auto resolverParams = DnsResponderClient::GetDefaultResolverParamsParcel(); ResolverOptionsParcel resolverOptions; resolverOptions.hosts = config.customizedHosts; if (!mIsResolverOptionIPCSupported) { resolverParams.resolverOptions = resolverOptions; } ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(resolverParams).isOk()); if (mIsResolverOptionIPCSupported) { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(resolverParams.netId, resolverOptions) .isOk()); } const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_STREAM}; ScopedAddrinfo result = safe_getaddrinfo(config.name.c_str(), nullptr, &hints); if (config.customizedHosts.empty() && config.dnsserverHosts.empty()) { ASSERT_TRUE(result == nullptr); EXPECT_EQ(2U, GetNumQueries(dns, config.name.c_str())); } else { ASSERT_TRUE(result != nullptr); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.queryResult)); EXPECT_EQ(config.customizedHosts.empty() ? 2U : 0U, GetNumQueries(dns, config.name.c_str())); } EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } TEST_F(ResolverTest, GetAddrInfoFromCustTable_Modify) { constexpr char hostnameV4V6[] = "v4v6.example.com."; constexpr char custAddrV4[] = "1.2.3.4"; constexpr char custAddrV6[] = "::1.2.3.4"; constexpr char dnsSvAddrV4[] = "1.2.3.5"; constexpr char dnsSvAddrV6[] = "::1.2.3.5"; const std::vector dnsSvHostV4V6 = { {hostnameV4V6, ns_type::ns_t_a, dnsSvAddrV4}, {hostnameV4V6, ns_type::ns_t_aaaa, dnsSvAddrV6}, }; const std::vector custHostV4V6 = { {custAddrV4, hostnameV4V6}, {custAddrV6, hostnameV4V6}, }; test::DNSResponder dns; StartDns(dns, dnsSvHostV4V6); auto resolverParams = DnsResponderClient::GetDefaultResolverParamsParcel(); ResolverOptionsParcel resolverOptions; resolverOptions.hosts = custHostV4V6; if (!mIsResolverOptionIPCSupported) { resolverParams.resolverOptions = resolverOptions; } ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(resolverParams).isOk()); if (mIsResolverOptionIPCSupported) { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(resolverParams.netId, resolverOptions) .isOk()); } const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_STREAM}; ScopedAddrinfo result = safe_getaddrinfo(hostnameV4V6, nullptr, &hints); ASSERT_TRUE(result != nullptr); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray({custAddrV4, custAddrV6})); EXPECT_EQ(0U, GetNumQueries(dns, hostnameV4V6)); resolverOptions.hosts = {}; if (!mIsResolverOptionIPCSupported) { resolverParams.resolverOptions = resolverOptions; ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(resolverParams).isOk()); } else { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(resolverParams.netId, resolverOptions) .isOk()); } result = safe_getaddrinfo(hostnameV4V6, nullptr, &hints); ASSERT_TRUE(result != nullptr); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray({dnsSvAddrV4, dnsSvAddrV6})); EXPECT_EQ(2U, GetNumQueries(dns, hostnameV4V6)); } TEST_F(ResolverTest, GetAddrInfoV4V6FromCustTable_MultiAnswers) { test::DNSResponder dns; StartDns(dns, {}); auto resolverParams = DnsResponderClient::GetDefaultResolverParamsParcel(); ResolverOptionsParcel resolverOptions; resolverOptions.hosts = { {kHelloExampleComAddrV4, kHelloExampleCom}, {kHelloExampleComAddrV6_GUA, kHelloExampleCom}, {kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleCom}, {kHelloExampleComAddrV6_TEREDO, kHelloExampleCom}, }; if (!mIsResolverOptionIPCSupported) { resolverParams.resolverOptions = resolverOptions; } ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(resolverParams).isOk()); if (mIsResolverOptionIPCSupported) { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(resolverParams.netId, resolverOptions) .isOk()); } addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_STREAM}; ScopedAddrinfo result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_TRUE(result != nullptr); // Expect the order is the same as the order of record insertion because the custom table uses // std::multimap to store and the queried results are not sorted by RFC 6724. // See getCustomHosts in packages/modules/DnsResolver/getaddrinfo.cpp EXPECT_THAT(ToStrings(result), testing::ElementsAreArray({kHelloExampleComAddrV4, kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleComAddrV6_TEREDO})); EXPECT_EQ(0U, GetNumQueries(dns, kHelloExampleCom)); hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_TRUE(result != nullptr); // The overall result is the concatenation of each result from explore_fqdn(). // resolv_getaddrinfo() calls explore_fqdn() many times by the different explore_options. // It means that the results of each explore_options keep the order and concatenates // all results into one link list. The address order of the output addrinfo is: // 1.2.3.4 (socktype=2, protocol=17) -> // 2404:6800::5175:15ca (socktype=2, protocol=17) -> // ::1.2.3.4 (socktype=2, protocol=17) -> // 2001::47c1 (socktype=2, protocol=17) -> // 1.2.3.4 (socktype=1, protocol=6) -> // 2404:6800::5175:15ca (socktype=1, protocol=6) -> // ::1.2.3.4 (socktype=1, protocol=6) -> // 2001::47c1 (socktype=1, protocol=6) // // See resolv_getaddrinfo, explore_fqdn and dns_getaddrinfo. EXPECT_THAT(ToStrings(result), testing::ElementsAreArray( {kHelloExampleComAddrV4, kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleComAddrV6_TEREDO, kHelloExampleComAddrV4, kHelloExampleComAddrV6_GUA, kHelloExampleComAddrV6_IPV4COMPAT, kHelloExampleComAddrV6_TEREDO})); EXPECT_EQ(0U, GetNumQueries(dns, kHelloExampleCom)); } TEST_F(ResolverTest, EmptySetup) { ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParamsParcel{.netId = TEST_NETID})); const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_TRUE(resolvInfo.value().dnsServers.empty()); EXPECT_TRUE(resolvInfo.value().domains.empty()); EXPECT_TRUE(resolvInfo.value().dotServers.empty()); EXPECT_EQ(0U, resolvInfo.value().params.sample_validity); EXPECT_EQ(0U, resolvInfo.value().params.success_threshold); EXPECT_EQ(0U, resolvInfo.value().params.min_samples); EXPECT_EQ(0U, resolvInfo.value().params.max_samples); // We don't check baseTimeoutMsec and retryCount because their value differ depending on // the experiment flags. } TEST_F(ResolverTest, SearchPathChange) { constexpr char listen_addr[] = "127.0.0.13"; constexpr char host_name1[] = "test13.domain1.org."; constexpr char host_name2[] = "test13.domain2.org."; std::vector servers = {listen_addr}; std::vector domains = {"domain1.org"}; const std::vector records = { {host_name1, ns_type::ns_t_aaaa, "2001:db8::13"}, {host_name2, ns_type::ns_t_aaaa, "2001:db8::1:13"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers, domains)); const addrinfo hints = {.ai_family = AF_INET6}; ScopedAddrinfo result = safe_getaddrinfo("test13", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(1U, dns.queries().size()); EXPECT_EQ(1U, GetNumQueries(dns, host_name1)); EXPECT_EQ("2001:db8::13", ToString(result)); // Test that changing the domain search path on its own works. domains = {"domain2.org"}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers, domains)); dns.clearQueries(); result = safe_getaddrinfo("test13", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(1U, dns.queries().size()); EXPECT_EQ(1U, GetNumQueries(dns, host_name2)); EXPECT_EQ("2001:db8::1:13", ToString(result)); } TEST_F(ResolverTest, SearchPathPrune) { constexpr size_t DUPLICATED_DOMAIN_NUM = 3; constexpr char listen_addr[] = "127.0.0.13"; constexpr char domian_name1[] = "domain13.org."; constexpr char domian_name2[] = "domain14.org."; constexpr char host_name1[] = "test13.domain13.org."; constexpr char host_name2[] = "test14.domain14.org."; std::vector servers = {listen_addr}; std::vector testDomains1; std::vector testDomains2; // Domain length should be <= 255 // Max number of domains in search path is 6 for (size_t i = 0; i < MAXDNSRCH + 1; i++) { // Fill up with invalid domain testDomains1.push_back(std::string(300, i + '0')); // Fill up with valid but duplicated domain testDomains2.push_back(fmt::format("domain{}.org", i % DUPLICATED_DOMAIN_NUM)); } // Add valid domain used for query. testDomains1.push_back(domian_name1); // Add valid domain twice used for query. testDomains2.push_back(domian_name2); testDomains2.push_back(domian_name2); const std::vector records = { {host_name1, ns_type::ns_t_aaaa, "2001:db8::13"}, {host_name2, ns_type::ns_t_aaaa, "2001:db8::1:13"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers, testDomains1)); const addrinfo hints = {.ai_family = AF_INET6}; ScopedAddrinfo result = safe_getaddrinfo("test13", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(1U, dns.queries().size()); EXPECT_EQ(1U, GetNumQueries(dns, host_name1)); EXPECT_EQ("2001:db8::13", ToString(result)); auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); const auto& res_domains1 = resolvInfo.value().domains; // Expect 1 valid domain, invalid domains are removed. ASSERT_EQ(1U, res_domains1.size()); EXPECT_EQ(domian_name1, res_domains1[0]); dns.clearQueries(); ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers, testDomains2)); result = safe_getaddrinfo("test14", nullptr, &hints); EXPECT_TRUE(result != nullptr); // (3 domains * 2 retries) + 1 success query = 7 EXPECT_EQ(7U, dns.queries().size()); EXPECT_EQ(1U, GetNumQueries(dns, host_name2)); EXPECT_EQ("2001:db8::1:13", ToString(result)); resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); const auto& res_domains2 = resolvInfo.value().domains; // Expect 4 valid domain, duplicate domains are removed. EXPECT_EQ(DUPLICATED_DOMAIN_NUM + 1U, res_domains2.size()); EXPECT_THAT( std::vector({"domain0.org", "domain1.org", "domain2.org", domian_name2}), testing::ElementsAreArray(res_domains2)); } // If we move this function to dns_responder_client, it will complicate the dependency need of // dns_tls_frontend.h. static void setupTlsServers(const std::vector& servers, std::vector>* tls) { constexpr char listen_udp[] = "53"; constexpr char listen_tls[] = "853"; for (const auto& server : servers) { auto t = std::make_unique(server, listen_tls, server, listen_udp); t = std::make_unique(server, listen_tls, server, listen_udp); t->startServer(); tls->push_back(std::move(t)); } } TEST_F(ResolverTest, MaxServerPrune_Binder) { std::vector domains; std::vector> dns; std::vector> tls; std::vector servers; std::vector mappings; for (unsigned i = 0; i < MAXDNSRCH + 1; i++) { domains.push_back(fmt::format("example{}.com", i)); } ASSERT_NO_FATAL_FAILURE(mDnsClient.SetupMappings(1, domains, &mappings)); ASSERT_NO_FATAL_FAILURE(mDnsClient.SetupDNSServers(MAXNS + 1, mappings, &dns, &servers)); ASSERT_NO_FATAL_FAILURE(setupTlsServers(servers, &tls)); const auto parcel = ResolverParams::Builder() .setDomains(domains) .setDnsServers(servers) .setDotServers(servers) .setPrivateDnsProvider(kDefaultPrivateDnsHostName) .build(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); // If the private DNS validation hasn't completed yet before backend DNS servers stop, // TLS servers will get stuck in handleOneRequest(), which causes this test stuck in // ~DnsTlsFrontend() because the TLS server loop threads can't be terminated. // So, wait for private DNS validation done before stopping backend DNS servers. for (int i = 0; i < MAXNS; i++) { LOG(INFO) << "Waiting for private DNS validation on " << tls[i]->listen_address() << "."; EXPECT_TRUE(WaitForPrivateDnsValidation(tls[i]->listen_address(), true)); LOG(INFO) << "private DNS validation on " << tls[i]->listen_address() << " done."; } const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_EQ(static_cast(MAXNS), resolvInfo.value().dnsServers.size()); EXPECT_EQ(static_cast(MAXNS), resolvInfo.value().dotServers.size()); EXPECT_EQ(static_cast(MAXDNSRCH), resolvInfo.value().domains.size()); EXPECT_TRUE(std::equal(servers.begin(), servers.begin() + MAXNS, resolvInfo.value().dnsServers.begin())); EXPECT_TRUE(std::equal(servers.begin(), servers.begin() + MAXNS, resolvInfo.value().dotServers.begin())); EXPECT_TRUE(std::equal(domains.begin(), domains.begin() + MAXDNSRCH, resolvInfo.value().domains.begin())); } TEST_F(ResolverTest, ResolverStats) { constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "127.0.0.5"; constexpr char listen_addr3[] = "127.0.0.6"; // Set server 1 timeout. test::DNSResponder dns1(listen_addr1, "53", static_cast(-1)); dns1.setResponseProbability(0.0); ASSERT_TRUE(dns1.startServer()); // Set server 2 responding server failure. test::DNSResponder dns2(listen_addr2); dns2.setResponseProbability(0.0); ASSERT_TRUE(dns2.startServer()); // Set server 3 workable. test::DNSResponder dns3(listen_addr3); dns3.addMapping(kHelloExampleCom, ns_type::ns_t_a, "1.2.3.4"); ASSERT_TRUE(dns3.startServer()); std::vector servers = {listen_addr1, listen_addr2, listen_addr3}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); dns3.clearQueries(); const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); size_t found = GetNumQueries(dns3, kHelloExampleCom); EXPECT_LE(1U, found); std::string result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4") << ", result_str='" << result_str << "'"; const std::vector expectedCleartextDnsStats = { NameserverStats(listen_addr1).setTimeouts(1), NameserverStats(listen_addr2).setErrors(1), NameserverStats(listen_addr3).setSuccesses(1).setRttAvg(1), }; EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); } TEST_F(ResolverTest, AlwaysUseLatestSetupParamsInLookups) { constexpr char listen_addr1[] = "127.0.0.3"; constexpr char listen_addr2[] = "255.255.255.255"; constexpr char listen_addr3[] = "127.0.0.4"; constexpr char hostname[] = "hello"; constexpr char fqdn_with_search_domain[] = "hello.domain2.com."; test::DNSResponder dns1(listen_addr1, test::kDefaultListenService, static_cast(-1)); dns1.setResponseProbability(0.0); ASSERT_TRUE(dns1.startServer()); test::DNSResponder dns3(listen_addr3); StartDns(dns3, {{fqdn_with_search_domain, ns_type::ns_t_a, "1.2.3.4"}}); ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.tlsServers.clear(); parcel.servers = {listen_addr1, listen_addr2}; parcel.domains = {"domain1.com", "domain2.com"}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); // Expect the things happening in t1: // 1. The lookup starts using the first domain for query. It sends queries to the populated // nameserver list {listen_addr1, listen_addr2} for the hostname "hello.domain1.com". // 2. A different list of nameservers is updated to the resolver. Revision ID is incremented. // 3. The query for the hostname times out. The lookup fails to add the timeout record to the // the stats because of the unmatched revision ID. // 4. The lookup starts using the second domain for query. It sends queries to the populated // nameserver list {listen_addr3, listen_addr1, listen_addr2} for another hostname // "hello.domain2.com". // 5. The lookup gets the answer and updates a success record to the stats. std::thread t1([&hostname]() { const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(hostname, nullptr, &hints); EXPECT_NE(result.get(), nullptr); EXPECT_EQ(ToString(result), "1.2.3.4"); }); // Wait for t1 to start the step 1. while (dns1.queries().size() == 0) { usleep(1000); } // Update the resolver with three nameservers. This will increment the revision ID. parcel.servers = {listen_addr3, listen_addr1, listen_addr2}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); t1.join(); EXPECT_EQ(0U, GetNumQueriesForType(dns3, ns_type::ns_t_aaaa, fqdn_with_search_domain)); EXPECT_EQ(1U, GetNumQueriesForType(dns3, ns_type::ns_t_a, fqdn_with_search_domain)); const std::vector expectedCleartextDnsStats = { NameserverStats(listen_addr1), NameserverStats(listen_addr2), NameserverStats(listen_addr3).setSuccesses(1).setRttAvg(1), }; EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); } // Test what happens if the specified TLS server is nonexistent. TEST_F(ResolverTest, GetHostByName_TlsMissing) { constexpr char host_name[] = "tlsmissing.example.com."; test::DNSResponder dns; StartDns(dns, {{host_name, ns_type::ns_t_a, "1.2.3.3"}}); // There's nothing listening on this address, so validation will either fail or /// hang. Either way, queries will continue to flow to the DNSResponder. ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); const hostent* result; result = gethostbyname("tlsmissing"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); } // Test what happens if the specified TLS server replies with garbage. TEST_F(ResolverTest, GetHostByName_TlsBroken) { constexpr char host_name1[] = "tlsbroken1.example.com."; constexpr char host_name2[] = "tlsbroken2.example.com."; const std::vector records = { {host_name1, ns_type::ns_t_a, "1.2.3.1"}, {host_name2, ns_type::ns_t_a, "1.2.3.2"}, }; test::DNSResponder dns; StartDns(dns, records); // Bind the specified private DNS socket but don't respond to any client sockets yet. int s = socket(AF_INET, SOCK_STREAM | SOCK_CLOEXEC, IPPROTO_TCP); ASSERT_TRUE(s >= 0); struct sockaddr_in tlsServer = { .sin_family = AF_INET, .sin_port = htons(853), }; ASSERT_TRUE(inet_pton(AF_INET, kDefaultServer, &tlsServer.sin_addr)); ASSERT_TRUE(enableSockopt(s, SOL_SOCKET, SO_REUSEPORT).ok()); ASSERT_TRUE(enableSockopt(s, SOL_SOCKET, SO_REUSEADDR).ok()); ASSERT_FALSE(bind(s, reinterpret_cast(&tlsServer), sizeof(tlsServer))); ASSERT_FALSE(listen(s, 1)); // Trigger TLS validation. ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); struct sockaddr_storage cliaddr; socklen_t sin_size = sizeof(cliaddr); int new_fd = accept4(s, reinterpret_cast(&cliaddr), &sin_size, SOCK_CLOEXEC); ASSERT_TRUE(new_fd > 0); // We've received the new file descriptor but not written to it or closed, so the // validation is still pending. Queries should still flow correctly because the // server is not used until validation succeeds. const hostent* result; result = gethostbyname("tlsbroken1"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.1", ToString(result)); // Now we cause the validation to fail. std::string garbage = "definitely not a valid TLS ServerHello"; write(new_fd, garbage.data(), garbage.size()); close(new_fd); // Validation failure shouldn't interfere with lookups, because lookups won't be sent // to the TLS server unless validation succeeds. result = gethostbyname("tlsbroken2"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.2", ToString(result)); // Clear TLS bit. ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); close(s); } TEST_F(ResolverTest, GetHostByName_Tls) { constexpr char listen_udp[] = "53"; constexpr char listen_tls[] = "853"; constexpr char host_name1[] = "tls1.example.com."; constexpr char host_name2[] = "tls2.example.com."; constexpr char host_name3[] = "tls3.example.com."; const std::vector records = { {host_name1, ns_type::ns_t_a, "1.2.3.1"}, {host_name2, ns_type::ns_t_a, "1.2.3.2"}, {host_name3, ns_type::ns_t_a, "1.2.3.3"}, }; test::DNSResponder dns; StartDns(dns, records); test::DnsTlsFrontend tls(kDefaultServer, listen_tls, kDefaultServer, listen_udp); ASSERT_TRUE(tls.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); const hostent* result = gethostbyname("tls1"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.1", ToString(result)); // Wait for query to get counted. EXPECT_TRUE(tls.waitForQueries(2)); // Stop the TLS server. Since we're in opportunistic mode, queries will // fall back to the locally-assigned (clear text) nameservers. tls.stopServer(); dns.clearQueries(); result = gethostbyname("tls2"); EXPECT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.2", ToString(result)); const auto queries = dns.queries(); EXPECT_EQ(1U, queries.size()); EXPECT_EQ("tls2.example.com.", queries[0].name); EXPECT_EQ(ns_t_a, queries[0].type); // Reset the resolvers without enabling TLS. Queries should still be routed // to the UDP endpoint. ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); result = gethostbyname("tls3"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.3", ToString(result)); } TEST_F(ResolverTest, GetHostByName_TlsFailover) { constexpr char listen_addr1[] = "127.0.0.3"; constexpr char listen_addr2[] = "127.0.0.4"; constexpr char listen_udp[] = "53"; constexpr char listen_tls[] = "853"; constexpr char host_name1[] = "tlsfailover1.example.com."; constexpr char host_name2[] = "tlsfailover2.example.com."; const std::vector records1 = { {host_name1, ns_type::ns_t_a, "1.2.3.1"}, {host_name2, ns_type::ns_t_a, "1.2.3.2"}, }; const std::vector records2 = { {host_name1, ns_type::ns_t_a, "1.2.3.3"}, {host_name2, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, records1); StartDns(dns2, records2); std::vector servers = {listen_addr1, listen_addr2}; test::DnsTlsFrontend tls1(listen_addr1, listen_tls, listen_addr1, listen_udp); test::DnsTlsFrontend tls2(listen_addr2, listen_tls, listen_addr2, listen_udp); ASSERT_TRUE(tls1.startServer()); ASSERT_TRUE(tls2.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder() .setDnsServers(servers) .setDotServers(servers) .setPrivateDnsProvider(kDefaultPrivateDnsHostName) .build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls1.listen_address(), true)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls2.listen_address(), true)); const hostent* result = gethostbyname("tlsfailover1"); ASSERT_FALSE(result == nullptr); EXPECT_EQ("1.2.3.1", ToString(result)); // Wait for query to get counted. EXPECT_TRUE(tls1.waitForQueries(2)); // No new queries should have reached tls2. EXPECT_TRUE(tls2.waitForQueries(1)); // Stop tls1. Subsequent queries should attempt to reach tls1, fail, and retry to tls2. tls1.stopServer(); result = gethostbyname("tlsfailover2"); EXPECT_EQ("1.2.3.4", ToString(result)); // Wait for query to get counted. EXPECT_TRUE(tls2.waitForQueries(2)); // No additional queries should have reached the insecure servers. EXPECT_EQ(2U, dns1.queries().size()); EXPECT_EQ(2U, dns2.queries().size()); // Clear TLS bit. ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); } TEST_F(ResolverTest, GetHostByName_BadTlsName) { constexpr char listen_udp[] = "53"; constexpr char listen_tls[] = "853"; constexpr char host_name[] = "badtlsname.example.com."; test::DNSResponder dns; StartDns(dns, {{host_name, ns_type::ns_t_a, "1.2.3.1"}}); test::DnsTlsFrontend tls(kDefaultServer, listen_tls, kDefaultServer, listen_udp); ASSERT_TRUE(tls.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder() .setPrivateDnsProvider(kDefaultIncorrectPrivateDnsHostName) .build())); // The TLS handshake would fail because the name of TLS server doesn't // match with TLS server's certificate. EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), false)); // The query should fail hard, because a name was specified. EXPECT_EQ(nullptr, gethostbyname("badtlsname")); // Clear TLS bit. ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); } TEST_F(ResolverTest, GetAddrInfo_Tls) { constexpr char listen_udp[] = "53"; constexpr char listen_tls[] = "853"; constexpr char host_name[] = "addrinfotls.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns; StartDns(dns, records); test::DnsTlsFrontend tls(kDefaultServer, listen_tls, kDefaultServer, listen_udp); ASSERT_TRUE(tls.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder().setPrivateDnsProvider(kDefaultPrivateDnsHostName).build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); dns.clearQueries(); ScopedAddrinfo result = safe_getaddrinfo("addrinfotls", nullptr, nullptr); EXPECT_TRUE(result != nullptr); size_t found = GetNumQueries(dns, host_name); EXPECT_LE(1U, found); // Could be A or AAAA std::string result_str = ToString(result); EXPECT_TRUE(result_str == "1.2.3.4" || result_str == "::1.2.3.4") << ", result_str='" << result_str << "'"; // Wait for both A and AAAA queries to get counted. EXPECT_TRUE(tls.waitForQueries(3)); } TEST_F(ResolverTest, TlsBypass) { const char OFF[] = "off"; const char OPPORTUNISTIC[] = "opportunistic"; const char STRICT[] = "strict"; const char GETHOSTBYNAME[] = "gethostbyname"; const char GETADDRINFO[] = "getaddrinfo"; const char GETADDRINFOFORNET[] = "getaddrinfofornet"; const unsigned BYPASS_NETID = NETID_USE_LOCAL_NAMESERVERS | TEST_NETID; const char ADDR4[] = "192.0.2.1"; const char ADDR6[] = "2001:db8::1"; const char cleartext_addr[] = "127.0.0.53"; const char cleartext_port[] = "53"; const char tls_port[] = "853"; const std::vector servers = {cleartext_addr}; test::DNSResponder dns(cleartext_addr); ASSERT_TRUE(dns.startServer()); test::DnsTlsFrontend tls(cleartext_addr, tls_port, cleartext_addr, cleartext_port); ASSERT_TRUE(tls.startServer()); // clang-format off struct TestConfig { const std::string mode; const bool withWorkingTLS; const std::string method; std::string asHostName() const { return fmt::format("{}.{}.{}.", mode, withWorkingTLS ? "tlsOn" : "tlsOff", method); } } testConfigs[]{ {OFF, true, GETHOSTBYNAME}, {OPPORTUNISTIC, true, GETHOSTBYNAME}, {STRICT, true, GETHOSTBYNAME}, {OFF, true, GETADDRINFO}, {OPPORTUNISTIC, true, GETADDRINFO}, {STRICT, true, GETADDRINFO}, {OFF, true, GETADDRINFOFORNET}, {OPPORTUNISTIC, true, GETADDRINFOFORNET}, {STRICT, true, GETADDRINFOFORNET}, {OFF, false, GETHOSTBYNAME}, {OPPORTUNISTIC, false, GETHOSTBYNAME}, {STRICT, false, GETHOSTBYNAME}, {OFF, false, GETADDRINFO}, {OPPORTUNISTIC, false, GETADDRINFO}, {STRICT, false, GETADDRINFO}, {OFF, false, GETADDRINFOFORNET}, {OPPORTUNISTIC, false, GETADDRINFOFORNET}, {STRICT, false, GETADDRINFOFORNET}, }; // clang-format on for (const auto& config : testConfigs) { const std::string testHostName = config.asHostName(); SCOPED_TRACE(testHostName); // Don't tempt test bugs due to caching. const char* host_name = testHostName.c_str(); dns.addMapping(host_name, ns_type::ns_t_a, ADDR4); dns.addMapping(host_name, ns_type::ns_t_aaaa, ADDR6); if (config.withWorkingTLS) { if (!tls.running()) { ASSERT_TRUE(tls.startServer()); } } else { if (tls.running()) { ASSERT_TRUE(tls.stopServer()); } } if (config.mode == OFF) { ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); } else /* OPPORTUNISTIC or STRICT */ { auto builder = ResolverParams::Builder().setDnsServers(servers).setDotServers(servers); if (config.mode == STRICT) builder.setPrivateDnsProvider(kDefaultPrivateDnsHostName); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(builder.build())); // Wait for the validation event. If the server is running, the validation should // succeed; otherwise, the validation should fail. EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), config.withWorkingTLS)); if (config.withWorkingTLS) { EXPECT_TRUE(tls.waitForQueries(1)); tls.clearQueries(); } } const hostent* h_result = nullptr; ScopedAddrinfo ai_result; if (config.method == GETHOSTBYNAME) { ASSERT_EQ(0, setNetworkForResolv(BYPASS_NETID)); h_result = gethostbyname(host_name); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, host_name)); ASSERT_FALSE(h_result == nullptr); ASSERT_EQ(4, h_result->h_length); ASSERT_FALSE(h_result->h_addr_list[0] == nullptr); EXPECT_EQ(ADDR4, ToString(h_result)); EXPECT_TRUE(h_result->h_addr_list[1] == nullptr); } else if (config.method == GETADDRINFO) { ASSERT_EQ(0, setNetworkForResolv(BYPASS_NETID)); ai_result = safe_getaddrinfo(host_name, nullptr, nullptr); EXPECT_TRUE(ai_result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, host_name)); // Could be A or AAAA const std::string result_str = ToString(ai_result); EXPECT_TRUE(result_str == ADDR4 || result_str == ADDR6) << ", result_str='" << result_str << "'"; } else if (config.method == GETADDRINFOFORNET) { addrinfo* raw_ai_result = nullptr; EXPECT_EQ(0, android_getaddrinfofornet(host_name, /*servname=*/nullptr, /*hints=*/nullptr, BYPASS_NETID, MARK_UNSET, &raw_ai_result)); ai_result.reset(raw_ai_result); EXPECT_LE(1U, GetNumQueries(dns, host_name)); // Could be A or AAAA const std::string result_str = ToString(ai_result); EXPECT_TRUE(result_str == ADDR4 || result_str == ADDR6) << ", result_str='" << result_str << "'"; } EXPECT_EQ(0, tls.queries()); // Clear per-process resolv netid. ASSERT_EQ(0, setNetworkForResolv(NETID_UNSET)); dns.clearQueries(); } } TEST_F(ResolverTest, StrictMode_NoTlsServers) { constexpr char host_name[] = "strictmode.notlsips.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(kDefaultServer); StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder() .setPrivateDnsProvider(kDefaultIncorrectPrivateDnsHostName) .build())); addrinfo* ai_result = nullptr; EXPECT_NE(0, getaddrinfo(host_name, nullptr, nullptr, &ai_result)); EXPECT_EQ(0U, GetNumQueries(dns, host_name)); } namespace { int getAsyncResponse(int fd, int* rcode, uint8_t* buf, int bufLen) { struct pollfd wait_fd[1]; wait_fd[0].fd = fd; wait_fd[0].events = POLLIN; short revents; if (int ret = poll(wait_fd, 1, -1); ret <= 0) { return -1; } revents = wait_fd[0].revents; if (revents & POLLIN) { return resNetworkResult(fd, rcode, buf, bufLen); } return -1; } std::string toString(uint8_t* buf, int bufLen, int ipType) { ns_msg handle; ns_rr rr; if (ns_initparse((const uint8_t*)buf, bufLen, &handle) >= 0) { if (ns_parserr(&handle, ns_s_an, 0, &rr) == 0) { const uint8_t* rdata = ns_rr_rdata(rr); char buffer[INET6_ADDRSTRLEN]; if (inet_ntop(ipType, (const char*)rdata, buffer, sizeof(buffer))) { return buffer; } } } return ""; } int dns_open_proxy() { int s = socket(AF_UNIX, SOCK_STREAM | SOCK_CLOEXEC, 0); if (s == -1) { return -1; } const int one = 1; setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one)); static const struct sockaddr_un proxy_addr = { .sun_family = AF_UNIX, .sun_path = "/dev/socket/dnsproxyd", }; if (TEMP_FAILURE_RETRY(connect(s, (const struct sockaddr*)&proxy_addr, sizeof(proxy_addr))) != 0) { close(s); return -1; } return s; } void expectAnswersValid(int fd, int ipType, const std::string& expectedAnswer) { int rcode = -1; uint8_t buf[MAXPACKET] = {}; int res = getAsyncResponse(fd, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ(expectedAnswer, toString(buf, res, ipType)); } void expectAnswersNotValid(int fd, int expectedErrno) { int rcode = -1; uint8_t buf[MAXPACKET] = {}; int res = getAsyncResponse(fd, &rcode, buf, MAXPACKET); EXPECT_EQ(expectedErrno, res); } } // namespace TEST_F(ResolverTest, Async_NormalQueryV4V6) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); int fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); int fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); uint8_t buf[MAXPACKET] = {}; int rcode; int res = getAsyncResponse(fd2, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("::1.2.3.4", toString(buf, res, AF_INET6)); res = getAsyncResponse(fd1, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); // Re-query verify cache works fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); res = getAsyncResponse(fd2, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("::1.2.3.4", toString(buf, res, AF_INET6)); res = getAsyncResponse(fd1, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); } TEST_F(ResolverTest, Async_BadQuery) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); static struct { int fd; const char* dname; const int queryType; const int expectRcode; } kTestData[] = { {-1, "", ns_t_aaaa, 0}, {-1, "as65ass46", ns_t_aaaa, 0}, {-1, "454564564564", ns_t_aaaa, 0}, {-1, "h645235", ns_t_a, 0}, {-1, "www.google.com", ns_t_a, 0}, }; for (auto& td : kTestData) { SCOPED_TRACE(td.dname); td.fd = resNetworkQuery(TEST_NETID, td.dname, ns_c_in, td.queryType, 0); EXPECT_TRUE(td.fd != -1); } // dns_responder return empty resp(packet only contains query part) with no error currently for (const auto& td : kTestData) { uint8_t buf[MAXPACKET] = {}; int rcode; SCOPED_TRACE(td.dname); int res = getAsyncResponse(td.fd, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ(rcode, td.expectRcode); } } TEST_F(ResolverTest, Async_EmptyAnswer) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); // TODO: Disable retry to make this test explicit. auto& cv = dns.getCv(); auto& cvMutex = dns.getCvMutex(); int fd1; // Wait on the condition variable to ensure that the DNS server has handled our first query. { std::unique_lock lk(cvMutex); fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_EQ(std::cv_status::no_timeout, cv.wait_for(lk, std::chrono::seconds(1))); } ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, 0, "howdy.example.com", {"::1.2.3.4"}); dns.setResponseProbability(0.0); int fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd2 != -1); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); int fd3 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd3 != -1); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); uint8_t buf[MAXPACKET] = {}; int rcode; // expect no response int res = getAsyncResponse(fd3, &rcode, buf, MAXPACKET); EXPECT_EQ(-ETIMEDOUT, res); // expect no response memset(buf, 0, MAXPACKET); res = getAsyncResponse(fd2, &rcode, buf, MAXPACKET); EXPECT_EQ(-ETIMEDOUT, res); dns.setResponseProbability(1.0); int fd4 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd4 != -1); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, 0, "howdy.example.com", {"1.2.3.4"}); memset(buf, 0, MAXPACKET); res = getAsyncResponse(fd4, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); memset(buf, 0, MAXPACKET); res = getAsyncResponse(fd1, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("::1.2.3.4", toString(buf, res, AF_INET6)); } TEST_F(ResolverTest, Async_MalformedQuery) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); int fd = dns_open_proxy(); EXPECT_TRUE(fd > 0); const std::string badMsg = "16-52512#"; static const struct { const std::string cmd; const int expectErr; } kTestData[] = { // Too few arguments {"resnsend " + badMsg + '\0', -EINVAL}, // Bad netId {"resnsend badnetId 0 " + badMsg + '\0', -EINVAL}, // Bad raw data {"resnsend " + std::to_string(TEST_NETID) + " 0 " + badMsg + '\0', -EILSEQ}, }; for (unsigned int i = 0; i < std::size(kTestData); i++) { auto& td = kTestData[i]; SCOPED_TRACE(td.cmd); ssize_t rc = TEMP_FAILURE_RETRY(write(fd, td.cmd.c_str(), td.cmd.size())); EXPECT_EQ(rc, static_cast(td.cmd.size())); int32_t tmp; rc = TEMP_FAILURE_RETRY(read(fd, &tmp, sizeof(tmp))); EXPECT_TRUE(rc > 0); EXPECT_EQ(static_cast(ntohl(tmp)), td.expectErr); } // Normal query with answer buffer // This is raw data of query "howdy.example.com" type 1 class 1 std::string query = "81sBAAABAAAAAAAABWhvd2R5B2V4YW1wbGUDY29tAAABAAE="; std::string cmd = "resnsend " + std::to_string(TEST_NETID) + " 0 " + query + '\0'; ssize_t rc = TEMP_FAILURE_RETRY(write(fd, cmd.c_str(), cmd.size())); EXPECT_EQ(rc, static_cast(cmd.size())); uint8_t smallBuf[1] = {}; int rcode; rc = getAsyncResponse(fd, &rcode, smallBuf, 1); EXPECT_EQ(-EMSGSIZE, rc); // Do the normal test with large buffer again fd = dns_open_proxy(); EXPECT_TRUE(fd > 0); rc = TEMP_FAILURE_RETRY(write(fd, cmd.c_str(), cmd.size())); EXPECT_EQ(rc, static_cast(cmd.size())); uint8_t buf[MAXPACKET] = {}; rc = getAsyncResponse(fd, &rcode, buf, MAXPACKET); EXPECT_EQ("1.2.3.4", toString(buf, rc, AF_INET)); } TEST_F(ResolverTest, Async_CacheFlags) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name1[] = "howdy.example.com."; constexpr char host_name2[] = "howdy.example2.com."; constexpr char host_name3[] = "howdy.example3.com."; const std::vector records = { {host_name1, ns_type::ns_t_a, "1.2.3.4"}, {host_name1, ns_type::ns_t_aaaa, "::1.2.3.4"}, {host_name2, ns_type::ns_t_a, "1.2.3.5"}, {host_name2, ns_type::ns_t_aaaa, "::1.2.3.5"}, {host_name3, ns_type::ns_t_a, "1.2.3.6"}, {host_name3, ns_type::ns_t_aaaa, "::1.2.3.6"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); // ANDROID_RESOLV_NO_CACHE_STORE int fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_STORE); EXPECT_TRUE(fd1 != -1); int fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_STORE); EXPECT_TRUE(fd2 != -1); int fd3 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_STORE); EXPECT_TRUE(fd3 != -1); expectAnswersValid(fd3, AF_INET, "1.2.3.4"); expectAnswersValid(fd2, AF_INET, "1.2.3.4"); expectAnswersValid(fd1, AF_INET, "1.2.3.4"); // No cache exists, expect 3 queries EXPECT_EQ(3U, GetNumQueries(dns, host_name1)); // Raise a query with no flags to ensure no cache exists. Also make an cache entry for the // query. fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET, "1.2.3.4"); // Expect 4 queries because there should be no cache before this query. EXPECT_EQ(4U, GetNumQueries(dns, host_name1)); // Now we have the cache entry, re-query with ANDROID_RESOLV_NO_CACHE_STORE to ensure // that ANDROID_RESOLV_NO_CACHE_STORE implied ANDROID_RESOLV_NO_CACHE_LOOKUP. fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_STORE); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET, "1.2.3.4"); // Expect 5 queries because we shouldn't do cache lookup for the query which has // ANDROID_RESOLV_NO_CACHE_STORE. EXPECT_EQ(5U, GetNumQueries(dns, host_name1)); // ANDROID_RESOLV_NO_CACHE_LOOKUP fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_LOOKUP); fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_LOOKUP); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); expectAnswersValid(fd2, AF_INET, "1.2.3.4"); expectAnswersValid(fd1, AF_INET, "1.2.3.4"); // Cache was skipped, expect 2 more queries. EXPECT_EQ(7U, GetNumQueries(dns, host_name1)); // Re-query verify cache works fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET, "1.2.3.4"); // Cache hits, expect still 7 queries EXPECT_EQ(7U, GetNumQueries(dns, host_name1)); // Start to verify if ANDROID_RESOLV_NO_CACHE_LOOKUP does write response into cache dns.clearQueries(); fd1 = resNetworkQuery(TEST_NETID, "howdy.example2.com", ns_c_in, ns_t_aaaa, ANDROID_RESOLV_NO_CACHE_LOOKUP); fd2 = resNetworkQuery(TEST_NETID, "howdy.example2.com", ns_c_in, ns_t_aaaa, ANDROID_RESOLV_NO_CACHE_LOOKUP); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); expectAnswersValid(fd2, AF_INET6, "::1.2.3.5"); expectAnswersValid(fd1, AF_INET6, "::1.2.3.5"); // Skip cache, expect 2 queries EXPECT_EQ(2U, GetNumQueries(dns, host_name2)); // Re-query without flags fd1 = resNetworkQuery(TEST_NETID, "howdy.example2.com", ns_c_in, ns_t_aaaa, 0); fd2 = resNetworkQuery(TEST_NETID, "howdy.example2.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); expectAnswersValid(fd2, AF_INET6, "::1.2.3.5"); expectAnswersValid(fd1, AF_INET6, "::1.2.3.5"); // Cache hits, expect still 2 queries EXPECT_EQ(2U, GetNumQueries(dns, host_name2)); // Test both ANDROID_RESOLV_NO_CACHE_STORE and ANDROID_RESOLV_NO_CACHE_LOOKUP are set dns.clearQueries(); // Make sure that the cache of "howdy.example3.com" exists. fd1 = resNetworkQuery(TEST_NETID, "howdy.example3.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET6, "::1.2.3.6"); EXPECT_EQ(1U, GetNumQueries(dns, host_name3)); // Re-query with testFlags const int testFlag = ANDROID_RESOLV_NO_CACHE_STORE | ANDROID_RESOLV_NO_CACHE_LOOKUP; fd1 = resNetworkQuery(TEST_NETID, "howdy.example3.com", ns_c_in, ns_t_aaaa, testFlag); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET6, "::1.2.3.6"); // Expect cache lookup is skipped. EXPECT_EQ(2U, GetNumQueries(dns, host_name3)); // Do another query with testFlags fd1 = resNetworkQuery(TEST_NETID, "howdy.example3.com", ns_c_in, ns_t_a, testFlag); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET, "1.2.3.6"); // Expect cache lookup is skipped. EXPECT_EQ(3U, GetNumQueries(dns, host_name3)); // Re-query with no flags fd1 = resNetworkQuery(TEST_NETID, "howdy.example3.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd1 != -1); expectAnswersValid(fd1, AF_INET, "1.2.3.6"); // Expect no cache hit because cache storing is also skipped in previous query. EXPECT_EQ(4U, GetNumQueries(dns, host_name3)); } TEST_F(ResolverTest, Async_NoCacheStoreFlagDoesNotRefreshStaleCacheEntry) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); const unsigned SHORT_TTL_SEC = 1; dns.setTtl(SHORT_TTL_SEC); // Refer to b/148842821 for the purpose of below test steps. // Basically, this test is used to ensure stale cache case is handled // correctly with ANDROID_RESOLV_NO_CACHE_STORE. int fd = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd != -1); expectAnswersValid(fd, AF_INET, "1.2.3.4"); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); dns.clearQueries(); // Wait until cache expired sleep(SHORT_TTL_SEC + 0.5); // Now request the same hostname again. // We should see a new DNS query because the entry in cache has become stale. // Due to ANDROID_RESOLV_NO_CACHE_STORE, this query must *not* refresh that stale entry. fd = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_STORE); EXPECT_TRUE(fd != -1); expectAnswersValid(fd, AF_INET, "1.2.3.4"); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); dns.clearQueries(); // If the cache is still stale, we expect to see one more DNS query // (this time the cache will be refreshed, but we're not checking for it). fd = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd != -1); expectAnswersValid(fd, AF_INET, "1.2.3.4"); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } TEST_F(ResolverTest, Async_NoRetryFlag) { constexpr char listen_addr0[] = "127.0.0.4"; constexpr char listen_addr1[] = "127.0.0.6"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns0(listen_addr0); test::DNSResponder dns1(listen_addr1); StartDns(dns0, records); StartDns(dns1, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork({listen_addr0, listen_addr1})); dns0.clearQueries(); dns1.clearQueries(); dns0.setResponseProbability(0.0); dns1.setResponseProbability(0.0); int fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, ANDROID_RESOLV_NO_RETRY); EXPECT_TRUE(fd1 != -1); int fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_aaaa, ANDROID_RESOLV_NO_RETRY); EXPECT_TRUE(fd2 != -1); // expect no response expectAnswersNotValid(fd1, -ETIMEDOUT); expectAnswersNotValid(fd2, -ETIMEDOUT); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); // No retry case, expect total 2 queries. The server is selected randomly. EXPECT_EQ(2U, GetNumQueries(dns0, host_name) + GetNumQueries(dns1, host_name)); dns0.clearQueries(); dns1.clearQueries(); fd1 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd1 != -1); fd2 = resNetworkQuery(TEST_NETID, "howdy.example.com", ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd2 != -1); // expect no response expectAnswersNotValid(fd1, -ETIMEDOUT); expectAnswersNotValid(fd2, -ETIMEDOUT); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, RCODE_TIMEOUT, "howdy.example.com", {}); // Retry case, expect 4 queries EXPECT_EQ(4U, GetNumQueries(dns0, host_name)); EXPECT_EQ(4U, GetNumQueries(dns1, host_name)); } TEST_F(ResolverTest, Async_VerifyQueryID) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); const uint8_t queryBuf1[] = { /* Header */ 0x55, 0x66, /* Transaction ID */ 0x01, 0x00, /* Flags */ 0x00, 0x01, /* Questions */ 0x00, 0x00, /* Answer RRs */ 0x00, 0x00, /* Authority RRs */ 0x00, 0x00, /* Additional RRs */ /* Queries */ 0x05, 0x68, 0x6f, 0x77, 0x64, 0x79, 0x07, 0x65, 0x78, 0x61, 0x6d, 0x70, 0x6c, 0x65, 0x03, 0x63, 0x6f, 0x6d, 0x00, /* Name */ 0x00, 0x01, /* Type */ 0x00, 0x01 /* Class */ }; int fd = resNetworkSend(TEST_NETID, queryBuf1, sizeof(queryBuf1), 0); EXPECT_TRUE(fd != -1); uint8_t buf[MAXPACKET] = {}; int rcode; int res = getAsyncResponse(fd, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); auto hp = reinterpret_cast(buf); EXPECT_EQ(21862U, htons(hp->id)); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); const uint8_t queryBuf2[] = { /* Header */ 0x00, 0x53, /* Transaction ID */ 0x01, 0x00, /* Flags */ 0x00, 0x01, /* Questions */ 0x00, 0x00, /* Answer RRs */ 0x00, 0x00, /* Authority RRs */ 0x00, 0x00, /* Additional RRs */ /* Queries */ 0x05, 0x68, 0x6f, 0x77, 0x64, 0x79, 0x07, 0x65, 0x78, 0x61, 0x6d, 0x70, 0x6c, 0x65, 0x03, 0x63, 0x6f, 0x6d, 0x00, /* Name */ 0x00, 0x01, /* Type */ 0x00, 0x01 /* Class */ }; // Re-query verify cache works and query id is correct fd = resNetworkSend(TEST_NETID, queryBuf2, sizeof(queryBuf2), 0); EXPECT_TRUE(fd != -1); res = getAsyncResponse(fd, &rcode, buf, MAXPACKET); EXPECT_GT(res, 0); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); EXPECT_EQ(0x0053U, htons(hp->id)); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } // This test checks that the resolver should not generate the request containing OPT RR when using // cleartext DNS. If we query the DNS server not supporting EDNS0 and it reponds with // FORMERR_ON_EDNS, we will fallback to no EDNS0 and try again. If the server does no response, we // won't retry so that we get no answer. TEST_F(ResolverTest, BrokenEdns) { typedef test::DNSResponder::Edns Edns; enum ExpectResult { EXPECT_FAILURE, EXPECT_SUCCESS }; // Perform cleartext query in off mode. const char OFF[] = "off"; // Perform cleartext query when there's no private DNS server validated in opportunistic mode. const char OPPORTUNISTIC_UDP[] = "opportunistic_udp"; // Perform cleartext query when there is a private DNS server validated in opportunistic mode. const char OPPORTUNISTIC_FALLBACK_UDP[] = "opportunistic_fallback_udp"; // Perform cyphertext query in opportunistic mode. const char OPPORTUNISTIC_TLS[] = "opportunistic_tls"; // Perform cyphertext query in strict mode. const char STRICT[] = "strict"; const char GETHOSTBYNAME[] = "gethostbyname"; const char GETADDRINFO[] = "getaddrinfo"; const char ADDR4[] = "192.0.2.1"; test::DNSResponder dns(kDefaultServer, "53", ns_rcode::ns_r_servfail); test::DnsTlsFrontend tls(kDefaultServer, "853", kDefaultServer, "53"); ASSERT_TRUE(dns.startServer()); // clang-format off static const struct TestConfig { std::string mode; std::string method; Edns edns; ExpectResult expectResult; std::string asHostName() const { const char* ednsString; switch (edns) { case Edns::ON: ednsString = "ednsOn"; break; case Edns::FORMERR_ON_EDNS: ednsString = "ednsFormerr"; break; case Edns::DROP: ednsString = "ednsDrop"; break; default: ednsString = ""; break; } return fmt::format("{}.{}.{}.", mode, method, ednsString); } } testConfigs[] = { // In OPPORTUNISTIC_TLS, if the DNS server doesn't support EDNS0 but TLS, the lookup // fails. Could such server exist? if so, we might need to fix it to fallback to // cleartext query. If the server still make no response for the queries with EDNS0, we // might also need to fix it to retry without EDNS0. // Another thing is that {OPPORTUNISTIC_TLS, Edns::DROP} and {STRICT, Edns::DROP} are // commented out since TLS timeout is not configurable. // TODO: Uncomment them after TLS timeout is configurable. {OFF, GETHOSTBYNAME, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETHOSTBYNAME, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_FALLBACK_UDP, GETHOSTBYNAME, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_TLS, GETHOSTBYNAME, Edns::ON, EXPECT_SUCCESS}, {STRICT, GETHOSTBYNAME, Edns::ON, EXPECT_SUCCESS}, {OFF, GETHOSTBYNAME, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETHOSTBYNAME, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_FALLBACK_UDP, GETHOSTBYNAME, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_TLS, GETHOSTBYNAME, Edns::FORMERR_ON_EDNS, EXPECT_FAILURE}, {STRICT, GETHOSTBYNAME, Edns::FORMERR_ON_EDNS, EXPECT_FAILURE}, {OFF, GETHOSTBYNAME, Edns::DROP, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETHOSTBYNAME, Edns::DROP, EXPECT_SUCCESS}, // The failure is due to no retry on timeout. Maybe fix it? {OPPORTUNISTIC_FALLBACK_UDP, GETHOSTBYNAME, Edns::DROP, EXPECT_FAILURE}, //{OPPORTUNISTIC_TLS, GETHOSTBYNAME, Edns::DROP, EXPECT_FAILURE}, //{STRICT, GETHOSTBYNAME, Edns::DROP, EXPECT_FAILURE}, {OFF, GETADDRINFO, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETADDRINFO, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_FALLBACK_UDP, GETADDRINFO, Edns::ON, EXPECT_SUCCESS}, {OPPORTUNISTIC_TLS, GETADDRINFO, Edns::ON, EXPECT_SUCCESS}, {STRICT, GETADDRINFO, Edns::ON, EXPECT_SUCCESS}, {OFF, GETADDRINFO, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETADDRINFO, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_FALLBACK_UDP, GETADDRINFO, Edns::FORMERR_ON_EDNS, EXPECT_SUCCESS}, {OPPORTUNISTIC_TLS, GETADDRINFO, Edns::FORMERR_ON_EDNS, EXPECT_FAILURE}, {STRICT, GETADDRINFO, Edns::FORMERR_ON_EDNS, EXPECT_FAILURE}, {OFF, GETADDRINFO, Edns::DROP, EXPECT_SUCCESS}, {OPPORTUNISTIC_UDP, GETADDRINFO, Edns::DROP, EXPECT_SUCCESS}, // The failure is due to no retry on timeout. Maybe fix it? {OPPORTUNISTIC_FALLBACK_UDP, GETADDRINFO, Edns::DROP, EXPECT_FAILURE}, //{OPPORTUNISTIC_TLS, GETADDRINFO, Edns::DROP, EXPECT_FAILURE}, //{STRICT, GETADDRINFO, Edns::DROP, EXPECT_FAILURE}, }; // clang-format on for (const auto& config : testConfigs) { const std::string testHostName = config.asHostName(); SCOPED_TRACE(testHostName); // Don't skip unusable DoT servers and disable revalidation for this test. ScopedSystemProperties sp1(kDotXportUnusableThresholdFlag, "-1"); ScopedSystemProperties sp2(kDotRevalidationThresholdFlag, "-1"); resetNetwork(); const char* host_name = testHostName.c_str(); dns.addMapping(host_name, ns_type::ns_t_a, ADDR4); dns.setEdns(config.edns); if (config.mode == OFF) { if (tls.running()) { ASSERT_TRUE(tls.stopServer()); } ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); } else if (config.mode == OPPORTUNISTIC_UDP) { if (tls.running()) { ASSERT_TRUE(tls.stopServer()); } ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), false)); } else if (config.mode == OPPORTUNISTIC_TLS || config.mode == OPPORTUNISTIC_FALLBACK_UDP) { if (!tls.running()) { ASSERT_TRUE(tls.startServer()); } ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); if (config.mode == OPPORTUNISTIC_FALLBACK_UDP) { // Force the resolver to fallback to cleartext queries. ASSERT_TRUE(tls.stopServer()); } } else if (config.mode == STRICT) { if (!tls.running()) { ASSERT_TRUE(tls.startServer()); } ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder() .setPrivateDnsProvider(kDefaultPrivateDnsHostName) .build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); } if (config.method == GETHOSTBYNAME) { const hostent* h_result = gethostbyname(host_name); if (config.expectResult == EXPECT_SUCCESS) { EXPECT_LE(1U, GetNumQueries(dns, host_name)); ASSERT_TRUE(h_result != nullptr); ASSERT_EQ(4, h_result->h_length); ASSERT_FALSE(h_result->h_addr_list[0] == nullptr); EXPECT_EQ(ADDR4, ToString(h_result)); EXPECT_TRUE(h_result->h_addr_list[1] == nullptr); ExpectDnsEvent(INetdEventListener::EVENT_GETHOSTBYNAME, 0, host_name, {ADDR4}); } else { EXPECT_EQ(0U, GetNumQueriesForType(dns, ns_type::ns_t_a, host_name)); ASSERT_TRUE(h_result == nullptr); ASSERT_EQ(HOST_NOT_FOUND, h_errno); int returnCode = (config.edns == Edns::DROP) ? RCODE_TIMEOUT : EAI_FAIL; ExpectDnsEvent(INetdEventListener::EVENT_GETHOSTBYNAME, returnCode, host_name, {}); } } else if (config.method == GETADDRINFO) { ScopedAddrinfo ai_result; addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ai_result = safe_getaddrinfo(host_name, nullptr, &hints); if (config.expectResult == EXPECT_SUCCESS) { EXPECT_TRUE(ai_result != nullptr); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); const std::string result_str = ToString(ai_result); EXPECT_EQ(ADDR4, result_str); ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, 0, host_name, {ADDR4}); } else { EXPECT_TRUE(ai_result == nullptr); EXPECT_EQ(0U, GetNumQueries(dns, host_name)); int returnCode = (config.edns == Edns::DROP) ? RCODE_TIMEOUT : EAI_FAIL; ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, returnCode, host_name, {}); } } else { FAIL() << "Unsupported query method: " << config.method; } tls.clearQueries(); dns.clearQueries(); // Set the configuration to OFF mode, so the resolver can validate private DNS servers in // every test config. ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); } } // DNS-over-TLS validation success, but server does not respond to TLS query after a while. // Resolver should have a reasonable number of retries instead of spinning forever. We don't have // an efficient way to know if resolver is stuck in an infinite loop. However, test case will be // failed due to timeout. TEST_F(ResolverTest, UnstableTls) { const char CLEARTEXT_PORT[] = "53"; const char TLS_PORT[] = "853"; const char* host_name1 = "nonexistent1.example.com."; const char* host_name2 = "nonexistent2.example.com."; test::DNSResponder dns(kDefaultServer, CLEARTEXT_PORT, ns_rcode::ns_r_servfail); ASSERT_TRUE(dns.startServer()); dns.setEdns(test::DNSResponder::Edns::FORMERR_ON_EDNS); test::DnsTlsFrontend tls(kDefaultServer, TLS_PORT, kDefaultServer, CLEARTEXT_PORT); ASSERT_TRUE(tls.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); // Shutdown TLS server to get an error. It's similar to no response case but without waiting. tls.stopServer(); const hostent* h_result = gethostbyname(host_name1); EXPECT_EQ(1U, GetNumQueries(dns, host_name1)); ASSERT_TRUE(h_result == nullptr); ASSERT_EQ(HOST_NOT_FOUND, h_errno); addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo ai_result = safe_getaddrinfo(host_name2, nullptr, &hints); EXPECT_TRUE(ai_result == nullptr); EXPECT_EQ(1U, GetNumQueries(dns, host_name2)); } // DNS-over-TLS validation success, but server does not respond to TLS query after a while. // Moreover, server responds RCODE=FORMERR even on non-EDNS query. TEST_F(ResolverTest, BogusDnsServer) { const char CLEARTEXT_PORT[] = "53"; const char TLS_PORT[] = "853"; const char* host_name1 = "nonexistent1.example.com."; const char* host_name2 = "nonexistent2.example.com."; test::DNSResponder dns(kDefaultServer, CLEARTEXT_PORT, ns_rcode::ns_r_servfail); ASSERT_TRUE(dns.startServer()); test::DnsTlsFrontend tls(kDefaultServer, TLS_PORT, kDefaultServer, CLEARTEXT_PORT); ASSERT_TRUE(tls.startServer()); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(ResolverParams::Builder().build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); // Shutdown TLS server to get an error. It's similar to no response case but without waiting. tls.stopServer(); dns.setEdns(test::DNSResponder::Edns::FORMERR_UNCOND); const hostent* h_result = gethostbyname(host_name1); EXPECT_EQ(0U, GetNumQueries(dns, host_name1)); ASSERT_TRUE(h_result == nullptr); ASSERT_EQ(HOST_NOT_FOUND, h_errno); addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo ai_result = safe_getaddrinfo(host_name2, nullptr, &hints); EXPECT_TRUE(ai_result == nullptr); EXPECT_EQ(0U, GetNumQueries(dns, host_name2)); } TEST_F(ResolverTest, GetAddrInfo_Dns64Synthesize) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4only.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // If the socket type is not specified, every address will appear twice, once for // SOCK_STREAM and one for SOCK_DGRAM. Just pick one because the addresses for // the second query of different socket type are responded by the cache. // See android_getaddrinfofornetcontext in packages/modules/DnsResolver/getaddrinfo.cpp const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("v4only", nullptr, &hints); EXPECT_TRUE(result != nullptr); // Expect that there are two queries, one AAAA (which returns no records) and one A // (which returns 1.2.3.4). EXPECT_EQ(2U, GetNumQueries(dns, host_name)); EXPECT_THAT(ToStrings(result), testing::ElementsAre("64:ff9b::102:304", "1.2.3.4")); // Stopping NAT64 prefix discovery disables synthesis. EXPECT_TRUE(mDnsClient.resolvService()->stopPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(WaitForNat64Prefix(EXPECT_NOT_FOUND)); dns.clearQueries(); result = safe_getaddrinfo("v4only", nullptr, &hints); EXPECT_TRUE(result != nullptr); // Expect that there is one query, an AAAA (which returns no records), because the // A is already cached. EXPECT_EQ(1U, GetNumQueries(dns, host_name)); EXPECT_EQ(ToString(result), "1.2.3.4"); } // TODO: merge to #GetAddrInfo_Dns64Synthesize once DNSResponder supports multi DnsRecords for a // hostname. TEST_F(ResolverTest, GetAddrInfo_Dns64SynthesizeMultiAnswers) { test::DNSResponder dns(test::DNSResponder::MappingType::BINARY_PACKET); dns.addMappingBinaryPacket(kHelloExampleComQueryV4, kHelloExampleComResponsesV4); StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(kHelloExampleCom, nullptr, &hints); ASSERT_FALSE(result == nullptr); // Synthesize AAAA if there's no AAAA answer and AF_UNSPEC is specified. EXPECT_THAT(ToStrings(result), testing::ElementsAre("64:ff9b::102:304", "64:ff9b::808:808", "64:ff9b::5175:15ca", "1.2.3.4", "8.8.8.8", "81.117.21.202")); } TEST_F(ResolverTest, GetAddrInfo_Dns64Canonname) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4only.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off static const struct TestConfig { int family; int flags; std::vector expectedAddresses; const char* expectedCanonname; std::string asParameters() const { return fmt::format("family={}, flags={}", family, flags); } } testConfigs[]{ {AF_UNSPEC, 0, {"64:ff9b::102:304", "1.2.3.4"}, nullptr}, {AF_UNSPEC, AI_CANONNAME, {"64:ff9b::102:304", "1.2.3.4"}, "v4only.example.com"}, {AF_INET6, 0, {"64:ff9b::102:304"} , nullptr}, {AF_INET6, AI_CANONNAME, {"64:ff9b::102:304"} , "v4only.example.com"}, }; // clang-format on for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); const addrinfo hints = { .ai_family = config.family, .ai_flags = config.flags, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("v4only", nullptr, &hints); ASSERT_TRUE(result != nullptr); EXPECT_THAT(ToStrings(result), testing::ElementsAreArray(config.expectedAddresses)); for (const auto* ai = result.get(); ai != nullptr; ai = ai->ai_next) { EXPECT_STREQ(ai->ai_canonname, config.expectedCanonname); } } } TEST_F(ResolverTest, GetAddrInfo_Dns64QuerySpecified) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4only.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Synthesize AAAA if AF_INET6 is specified and there is A record only. Make sure that A record // is not returned as well. addrinfo hints = {.ai_family = AF_INET6, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("v4only", nullptr, &hints); EXPECT_TRUE(result != nullptr); // One for AAAA query without an answer and one for A query which is used for DNS64 synthesis. EXPECT_EQ(2U, GetNumQueries(dns, host_name)); EXPECT_EQ(ToString(result), "64:ff9b::102:304"); dns.clearQueries(); // Don't synthesize AAAA if AF_INET is specified and there is A record only. hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; result = safe_getaddrinfo("v4only", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(0U /*cached in previous queries*/, GetNumQueries(dns, host_name)); EXPECT_EQ(ToString(result), "1.2.3.4"); } TEST_F(ResolverTest, GetAddrInfo_Dns64QueryUnspecifiedV6) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4v6.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "2001:db8::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("v4v6", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); // Do not synthesize AAAA if there's at least one AAAA answer. EXPECT_THAT(ToStrings(result), testing::ElementsAre("2001:db8::102:304", "1.2.3.4")); } TEST_F(ResolverTest, GetAddrInfo_Dns64QueryUnspecifiedNoV6) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4v6.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("v4v6", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); // Synthesize AAAA if there's no AAAA answer and AF_UNSPEC is specified. EXPECT_THAT(ToStrings(result), testing::ElementsAre("64:ff9b::102:304", "1.2.3.4")); } TEST_F(ResolverTest, GetAddrInfo_Dns64QuerySpecialUseIPv4Addresses) { constexpr char THIS_NETWORK[] = "this_network"; constexpr char LOOPBACK[] = "loopback"; constexpr char LINK_LOCAL[] = "link_local"; constexpr char MULTICAST[] = "multicast"; constexpr char LIMITED_BROADCAST[] = "limited_broadcast"; constexpr char ADDR_THIS_NETWORK[] = "0.0.0.1"; constexpr char ADDR_LOOPBACK[] = "127.0.0.1"; constexpr char ADDR_LINK_LOCAL[] = "169.254.0.1"; constexpr char ADDR_MULTICAST[] = "224.0.0.1"; constexpr char ADDR_LIMITED_BROADCAST[] = "255.255.255.255"; constexpr char listen_addr[] = "::1"; test::DNSResponder dns(listen_addr); StartDns(dns, {}); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off static const struct TestConfig { std::string name; std::string addr; std::string asHostName() const { return fmt::format("{}.example.com.", name); } } testConfigs[]{ {THIS_NETWORK, ADDR_THIS_NETWORK}, {LOOPBACK, ADDR_LOOPBACK}, {LINK_LOCAL, ADDR_LINK_LOCAL}, {MULTICAST, ADDR_MULTICAST}, {LIMITED_BROADCAST, ADDR_LIMITED_BROADCAST} }; // clang-format on for (const auto& config : testConfigs) { const std::string testHostName = config.asHostName(); SCOPED_TRACE(testHostName); const char* host_name = testHostName.c_str(); dns.addMapping(host_name, ns_type::ns_t_a, config.addr.c_str()); // Expect no result because AF_INET6 is specified and don't synthesize special use IPv4 // address. addrinfo hints = {.ai_family = AF_INET6, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(config.name.c_str(), nullptr, &hints); EXPECT_TRUE(result == nullptr); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); dns.clearQueries(); // Expect special use IPv4 address only because AF_UNSPEC is specified and don't synthesize // special use IPv4 address. hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; result = safe_getaddrinfo(config.name.c_str(), nullptr, &hints); EXPECT_TRUE(result != nullptr); // Expect IPv6 query only. IPv4 answer has been cached in previous query. EXPECT_EQ(1U, GetNumQueries(dns, host_name)); EXPECT_EQ(ToString(result), config.addr); dns.clearQueries(); } } TEST_F(ResolverTest, GetAddrInfo_Dns64QueryWithNullArgumentHints) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "v4only.example.com."; constexpr char host_name2[] = "v4v6.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name2, ns_type::ns_t_a, "1.2.3.4"}, {host_name2, ns_type::ns_t_aaaa, "2001:db8::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Synthesize AAAA if there is A answer only and AF_UNSPEC (hints NULL) is specified. // Assign argument hints of getaddrinfo() as null is equivalent to set ai_family AF_UNSPEC, // ai_socktype 0 (any), and ai_protocol 0 (any). Note the setting ai_socktype 0 (any) causes // that every address will appear twice, once for SOCK_STREAM and one for SOCK_DGRAM. // See resolv_getaddrinfo in packages/modules/DnsResolver/getaddrinfo.cpp. ScopedAddrinfo result = safe_getaddrinfo("v4only", nullptr, nullptr); EXPECT_TRUE(result != nullptr); EXPECT_LE(2U, GetNumQueries(dns, host_name)); EXPECT_THAT(ToStrings(result), testing::ElementsAre("64:ff9b::102:304", "64:ff9b::102:304", "1.2.3.4", "1.2.3.4")); dns.clearQueries(); // Do not synthesize AAAA if there's at least one AAAA answer. // The reason which the addresses appear twice is as mentioned above. result = safe_getaddrinfo("v4v6", nullptr, nullptr); EXPECT_TRUE(result != nullptr); EXPECT_LE(2U, GetNumQueries(dns, host_name2)); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAre("2001:db8::102:304", "2001:db8::102:304", "1.2.3.4", "1.2.3.4")); } TEST_F(ResolverTest, GetAddrInfo_Dns64QueryNullArgumentNode) { constexpr char ADDR_ANYADDR_V4[] = "0.0.0.0"; constexpr char ADDR_ANYADDR_V6[] = "::"; constexpr char ADDR_LOCALHOST_V4[] = "127.0.0.1"; constexpr char ADDR_LOCALHOST_V6[] = "::1"; constexpr char PORT_NAME_HTTP[] = "http"; constexpr char PORT_NUMBER_HTTP[] = "80"; constexpr char listen_addr[] = "::1"; test::DNSResponder dns(listen_addr); StartDns(dns, {}); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off // If node is null, return address is listed by libc/getaddrinfo.c as follows. // - passive socket -> anyaddr (0.0.0.0 or ::) // - non-passive socket -> localhost (127.0.0.1 or ::1) static const struct TestConfig { int flag; std::string addr_v4; std::string addr_v6; std::string asParameters() const { return fmt::format("flag={}, addr_v4={}, addr_v6={}", flag, addr_v4, addr_v6); } } testConfigs[]{ {0 /* non-passive */, ADDR_LOCALHOST_V4, ADDR_LOCALHOST_V6}, {AI_PASSIVE, ADDR_ANYADDR_V4, ADDR_ANYADDR_V6} }; // clang-format on for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); addrinfo hints = { .ai_flags = config.flag, .ai_family = AF_UNSPEC, // any address family .ai_socktype = 0, // any type .ai_protocol = 0, // any protocol }; // Assign hostname as null and service as port name. ScopedAddrinfo result = safe_getaddrinfo(nullptr, PORT_NAME_HTTP, &hints); ASSERT_TRUE(result != nullptr); // Can't be synthesized because it should not get into Netd. // Every address appears twice, once for SOCK_STREAM and one for SOCK_DGRAM because the // socket type is not specified. EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAre(config.addr_v4, config.addr_v4, config.addr_v6, config.addr_v6)); // Assign hostname as null and service as numeric port number. hints.ai_flags = config.flag | AI_NUMERICSERV; result = safe_getaddrinfo(nullptr, PORT_NUMBER_HTTP, &hints); ASSERT_TRUE(result != nullptr); // Can't be synthesized because it should not get into Netd. // The reason which the addresses appear twice is as mentioned above. EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAre(config.addr_v4, config.addr_v4, config.addr_v6, config.addr_v6)); } } TEST_F(ResolverTest, GetHostByAddr_ReverseDnsQueryWithHavingNat64Prefix) { struct hostent* result = nullptr; struct in_addr v4addr; struct in6_addr v6addr; constexpr char listen_addr[] = "::1"; constexpr char ptr_name[] = "v4v6.example.com."; // PTR record for IPv4 address 1.2.3.4 constexpr char ptr_addr_v4[] = "4.3.2.1.in-addr.arpa."; // PTR record for IPv6 address 2001:db8::102:304 constexpr char ptr_addr_v6[] = "4.0.3.0.2.0.1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.8.b.d.0.1.0.0.2.ip6.arpa."; const std::vector records = { {ptr_addr_v4, ns_type::ns_t_ptr, ptr_name}, {ptr_addr_v6, ns_type::ns_t_ptr, ptr_name}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Reverse IPv4 DNS query. Prefix should have no effect on it. inet_pton(AF_INET, "1.2.3.4", &v4addr); result = gethostbyaddr(&v4addr, sizeof(v4addr), AF_INET); ASSERT_TRUE(result != nullptr); std::string result_str = result->h_name ? result->h_name : "null"; EXPECT_EQ(result_str, "v4v6.example.com"); // Reverse IPv6 DNS query. Prefix should have no effect on it. inet_pton(AF_INET6, "2001:db8::102:304", &v6addr); result = gethostbyaddr(&v6addr, sizeof(v6addr), AF_INET6); ASSERT_TRUE(result != nullptr); result_str = result->h_name ? result->h_name : "null"; EXPECT_EQ(result_str, "v4v6.example.com"); } TEST_F(ResolverTest, GetHostByAddr_ReverseDns64Query) { constexpr char listen_addr[] = "::1"; constexpr char ptr_name[] = "v4only.example.com."; // PTR record for IPv4 address 1.2.3.4 constexpr char ptr_addr_v4[] = "4.3.2.1.in-addr.arpa."; // PTR record for IPv6 address 64:ff9b::1.2.3.4 constexpr char ptr_addr_v6_nomapping[] = "4.0.3.0.2.0.1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.b.9.f.f.4.6.0.0.ip6.arpa."; constexpr char ptr_name_v6_synthesis[] = "v6synthesis.example.com."; // PTR record for IPv6 address 64:ff9b::5.6.7.8 constexpr char ptr_addr_v6_synthesis[] = "8.0.7.0.6.0.5.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.b.9.f.f.4.6.0.0.ip6.arpa."; const std::vector records = { {ptr_addr_v4, ns_type::ns_t_ptr, ptr_name}, {ptr_addr_v6_synthesis, ns_type::ns_t_ptr, ptr_name_v6_synthesis}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); // "ptr_addr_v6_nomapping" is not mapped in DNS server const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Synthesized PTR record doesn't exist on DNS server // Reverse IPv6 DNS64 query while DNS server doesn't have an answer for synthesized address. // After querying synthesized address failed, expect that prefix is removed from IPv6 // synthesized address and do reverse IPv4 query instead. struct in6_addr v6addr; inet_pton(AF_INET6, "64:ff9b::1.2.3.4", &v6addr); struct hostent* result = gethostbyaddr(&v6addr, sizeof(v6addr), AF_INET6); ASSERT_TRUE(result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v6_nomapping)); // PTR record not exist EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v4)); // PTR record exist std::string result_str = result->h_name ? result->h_name : "null"; EXPECT_EQ(result_str, "v4only.example.com"); // Check that return address has been mapped from IPv4 to IPv6 address because Netd // removes NAT64 prefix and does IPv4 DNS reverse lookup in this case. Then, Netd // fakes the return IPv4 address as original queried IPv6 address. result_str = ToString(result); EXPECT_EQ(result_str, "64:ff9b::102:304"); dns.clearQueries(); // Synthesized PTR record exists on DNS server // Reverse IPv6 DNS64 query while DNS server has an answer for synthesized address. // Expect to Netd pass through synthesized address for DNS queries. inet_pton(AF_INET6, "64:ff9b::5.6.7.8", &v6addr); result = gethostbyaddr(&v6addr, sizeof(v6addr), AF_INET6); ASSERT_TRUE(result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v6_synthesis)); result_str = result->h_name ? result->h_name : "null"; EXPECT_EQ(result_str, "v6synthesis.example.com"); } TEST_F(ResolverTest, GetHostByAddr_ReverseDns64QueryFromHostFile) { constexpr char host_name[] = "localhost"; // The address is synthesized by prefix64:localhost. constexpr char host_addr[] = "64:ff9b::7f00:1"; constexpr char listen_addr[] = "::1"; test::DNSResponder dns(listen_addr); StartDns(dns, {}); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Using synthesized "localhost" address to be a trick for resolving host name // from host file /etc/hosts and "localhost" is the only name in /etc/hosts. Note that this is // not realistic: the code never synthesizes AAAA records for addresses in 127.0.0.0/8. struct in6_addr v6addr; inet_pton(AF_INET6, host_addr, &v6addr); struct hostent* result = gethostbyaddr(&v6addr, sizeof(v6addr), AF_INET6); ASSERT_TRUE(result != nullptr); // Expect no DNS queries; localhost is resolved via /etc/hosts. EXPECT_EQ(0U, GetNumQueries(dns, host_name)); ASSERT_EQ(sizeof(in6_addr), (unsigned)result->h_length); ASSERT_EQ(AF_INET6, result->h_addrtype); std::string result_str = ToString(result); EXPECT_EQ(result_str, host_addr); result_str = result->h_name ? result->h_name : "null"; EXPECT_EQ(result_str, host_name); } TEST_F(ResolverTest, GetHostByAddr_cnamesClasslessReverseDelegation) { // IPv4 addresses in the subnet with notation '/' or '-'. constexpr char addr_slash[] = "192.0.2.1"; constexpr char addr_hyphen[] = "192.0.3.1"; // Used to verify DNS reverse query for classless reverse lookup zone. See detail in RFC 2317 // section 4. const static std::vector records = { // The records for reverse querying "192.0.2.1" in the subnet with notation '/'. {"1.2.0.192.in-addr.arpa.", ns_type::ns_t_cname, "1.0/25.2.0.192.in-addr.arpa."}, {"1.0/25.2.0.192.in-addr.arpa.", ns_type::ns_t_ptr, kHelloExampleCom}, // The records for reverse querying "192.0.3.1" in the subnet with notation '-'. {"1.3.0.192.in-addr.arpa.", ns_type::ns_t_cname, "1.0-127.3.0.192.in-addr.arpa."}, {"1.0-127.3.0.192.in-addr.arpa.", ns_type::ns_t_ptr, kHelloExampleCom}, }; test::DNSResponder dns; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); for (const auto& address : {addr_slash, addr_hyphen}) { SCOPED_TRACE(address); in_addr v4addr; ASSERT_TRUE(inet_pton(AF_INET, address, &v4addr)); hostent* result = gethostbyaddr(&v4addr, sizeof(v4addr), AF_INET); ASSERT_TRUE(result != nullptr); EXPECT_STREQ("hello.example.com", result->h_name); } } TEST_F(ResolverTest, GetNameInfo_ReverseDnsQueryWithHavingNat64Prefix) { constexpr char listen_addr[] = "::1"; constexpr char ptr_name[] = "v4v6.example.com."; // PTR record for IPv4 address 1.2.3.4 constexpr char ptr_addr_v4[] = "4.3.2.1.in-addr.arpa."; // PTR record for IPv6 address 2001:db8::102:304 constexpr char ptr_addr_v6[] = "4.0.3.0.2.0.1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.8.b.d.0.1.0.0.2.ip6.arpa."; const std::vector records = { {ptr_addr_v4, ns_type::ns_t_ptr, ptr_name}, {ptr_addr_v6, ns_type::ns_t_ptr, ptr_name}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off static const struct TestConfig { int flag; int family; std::string addr; std::string host; std::string asParameters() const { return fmt::format("flag={}, family={}, addr={}, host={}", flag, family, addr, host); } } testConfigs[]{ {NI_NAMEREQD, AF_INET, "1.2.3.4", "v4v6.example.com"}, {NI_NUMERICHOST, AF_INET, "1.2.3.4", "1.2.3.4"}, {0, AF_INET, "1.2.3.4", "v4v6.example.com"}, {0, AF_INET, "5.6.7.8", "5.6.7.8"}, // unmapped {NI_NAMEREQD, AF_INET6, "2001:db8::102:304", "v4v6.example.com"}, {NI_NUMERICHOST, AF_INET6, "2001:db8::102:304", "2001:db8::102:304"}, {0, AF_INET6, "2001:db8::102:304", "v4v6.example.com"}, {0, AF_INET6, "2001:db8::506:708", "2001:db8::506:708"}, // unmapped }; // clang-format on // Reverse IPv4/IPv6 DNS query. Prefix should have no effect on it. for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); int rv; char host[NI_MAXHOST]; struct sockaddr_in sin; struct sockaddr_in6 sin6; if (config.family == AF_INET) { memset(&sin, 0, sizeof(sin)); sin.sin_family = AF_INET; inet_pton(AF_INET, config.addr.c_str(), &sin.sin_addr); rv = getnameinfo((const struct sockaddr*)&sin, sizeof(sin), host, sizeof(host), nullptr, 0, config.flag); if (config.flag == NI_NAMEREQD) EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v4)); } else if (config.family == AF_INET6) { memset(&sin6, 0, sizeof(sin6)); sin6.sin6_family = AF_INET6; inet_pton(AF_INET6, config.addr.c_str(), &sin6.sin6_addr); rv = getnameinfo((const struct sockaddr*)&sin6, sizeof(sin6), host, sizeof(host), nullptr, 0, config.flag); if (config.flag == NI_NAMEREQD) EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v6)); } ASSERT_EQ(0, rv); std::string result_str = host; EXPECT_EQ(result_str, config.host); dns.clearQueries(); } } TEST_F(ResolverTest, GetNameInfo_ReverseDns64Query) { constexpr char listen_addr[] = "::1"; constexpr char ptr_name[] = "v4only.example.com."; // PTR record for IPv4 address 1.2.3.4 constexpr char ptr_addr_v4[] = "4.3.2.1.in-addr.arpa."; // PTR record for IPv6 address 64:ff9b::1.2.3.4 constexpr char ptr_addr_v6_nomapping[] = "4.0.3.0.2.0.1.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.b.9.f.f.4.6.0.0.ip6.arpa."; constexpr char ptr_name_v6_synthesis[] = "v6synthesis.example.com."; // PTR record for IPv6 address 64:ff9b::5.6.7.8 constexpr char ptr_addr_v6_synthesis[] = "8.0.7.0.6.0.5.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.b.9.f.f.4.6.0.0.ip6.arpa."; const std::vector records = { {ptr_addr_v4, ns_type::ns_t_ptr, ptr_name}, {ptr_addr_v6_synthesis, ns_type::ns_t_ptr, ptr_name_v6_synthesis}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off static const struct TestConfig { bool hasSynthesizedPtrRecord; int flag; std::string addr; std::string host; std::string asParameters() const { return fmt::format("hasSynthesizedPtrRecord={}, flag={}, addr={}, host={}", hasSynthesizedPtrRecord, flag, addr, host); } } testConfigs[]{ {false, NI_NAMEREQD, "64:ff9b::102:304", "v4only.example.com"}, {false, NI_NUMERICHOST, "64:ff9b::102:304", "64:ff9b::102:304"}, {false, 0, "64:ff9b::102:304", "v4only.example.com"}, {true, NI_NAMEREQD, "64:ff9b::506:708", "v6synthesis.example.com"}, {true, NI_NUMERICHOST, "64:ff9b::506:708", "64:ff9b::506:708"}, {true, 0, "64:ff9b::506:708", "v6synthesis.example.com"} }; // clang-format on // hasSynthesizedPtrRecord = false // Synthesized PTR record doesn't exist on DNS server // Reverse IPv6 DNS64 query while DNS server doesn't have an answer for synthesized address. // After querying synthesized address failed, expect that prefix is removed from IPv6 // synthesized address and do reverse IPv4 query instead. // // hasSynthesizedPtrRecord = true // Synthesized PTR record exists on DNS server // Reverse IPv6 DNS64 query while DNS server has an answer for synthesized address. // Expect to just pass through synthesized address for DNS queries. for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); char host[NI_MAXHOST]; struct sockaddr_in6 sin6; memset(&sin6, 0, sizeof(sin6)); sin6.sin6_family = AF_INET6; inet_pton(AF_INET6, config.addr.c_str(), &sin6.sin6_addr); int rv = getnameinfo((const struct sockaddr*)&sin6, sizeof(sin6), host, sizeof(host), nullptr, 0, config.flag); ASSERT_EQ(0, rv); if (config.flag == NI_NAMEREQD) { if (config.hasSynthesizedPtrRecord) { EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v6_synthesis)); } else { EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v6_nomapping)); // PTR record not exist. EXPECT_LE(1U, GetNumQueries(dns, ptr_addr_v4)); // PTR record exist. } } std::string result_str = host; EXPECT_EQ(result_str, config.host); dns.clearQueries(); } } TEST_F(ResolverTest, GetNameInfo_ReverseDns64QueryFromHostFile) { constexpr char host_name[] = "localhost"; // The address is synthesized by prefix64:localhost. constexpr char host_addr[] = "64:ff9b::7f00:1"; constexpr char listen_addr[] = "::1"; test::DNSResponder dns(listen_addr); StartDns(dns, {}); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Using synthesized "localhost" address to be a trick for resolving host name // from host file /etc/hosts and "localhost" is the only name in /etc/hosts. Note that this is // not realistic: the code never synthesizes AAAA records for addresses in 127.0.0.0/8. char host[NI_MAXHOST]; struct sockaddr_in6 sin6 = {.sin6_family = AF_INET6}; inet_pton(AF_INET6, host_addr, &sin6.sin6_addr); int rv = getnameinfo((const struct sockaddr*)&sin6, sizeof(sin6), host, sizeof(host), nullptr, 0, NI_NAMEREQD); ASSERT_EQ(0, rv); // Expect no DNS queries; localhost is resolved via /etc/hosts. EXPECT_EQ(0U, GetNumQueries(dns, host_name)); std::string result_str = host; EXPECT_EQ(result_str, host_name); } TEST_F(ResolverTest, GetNameInfo_cnamesClasslessReverseDelegation) { // IPv4 addresses in the subnet with notation '/' or '-'. constexpr char addr_slash[] = "192.0.2.1"; constexpr char addr_hyphen[] = "192.0.3.1"; // Used to verify DNS reverse query for classless reverse lookup zone. See detail in RFC 2317 // section 4. const static std::vector records = { // The records for reverse querying "192.0.2.1" in the subnet with notation '/'. {"1.2.0.192.in-addr.arpa.", ns_type::ns_t_cname, "1.0/25.2.0.192.in-addr.arpa."}, {"1.0/25.2.0.192.in-addr.arpa.", ns_type::ns_t_ptr, kHelloExampleCom}, // The records for reverse querying "192.0.3.1" in the subnet with notation '-'. {"1.3.0.192.in-addr.arpa.", ns_type::ns_t_cname, "1.0-127.3.0.192.in-addr.arpa."}, {"1.0-127.3.0.192.in-addr.arpa.", ns_type::ns_t_ptr, kHelloExampleCom}, }; test::DNSResponder dns; StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); for (const auto& address : {addr_slash, addr_hyphen}) { SCOPED_TRACE(address); char host[NI_MAXHOST]; sockaddr_in sin = {.sin_family = AF_INET}; ASSERT_TRUE(inet_pton(AF_INET, address, &sin.sin_addr)); int rv = getnameinfo((const sockaddr*)&sin, sizeof(sin), host, sizeof(host), nullptr, 0, NI_NAMEREQD); ASSERT_EQ(0, rv); EXPECT_STREQ("hello.example.com", host); } } TEST_F(ResolverTest, GetHostByName2_Dns64Synthesize) { constexpr char listen_addr[] = "::1"; constexpr char host_name[] = "ipv4only.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // Query an IPv4-only hostname. Expect that gets a synthesized address. struct hostent* result = gethostbyname2("ipv4only", AF_INET6); ASSERT_TRUE(result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, host_name)); std::string result_str = ToString(result); EXPECT_EQ(result_str, "64:ff9b::102:304"); } TEST_F(ResolverTest, GetHostByName2_DnsQueryWithHavingNat64Prefix) { constexpr char host_name[] = "v4v6.example.com."; constexpr char listen_addr[] = "::1"; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "2001:db8::1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // IPv4 DNS query. Prefix should have no effect on it. struct hostent* result = gethostbyname2("v4v6", AF_INET); ASSERT_TRUE(result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, host_name)); std::string result_str = ToString(result); EXPECT_EQ(result_str, "1.2.3.4"); dns.clearQueries(); // IPv6 DNS query. Prefix should have no effect on it. result = gethostbyname2("v4v6", AF_INET6); ASSERT_TRUE(result != nullptr); EXPECT_LE(1U, GetNumQueries(dns, host_name)); result_str = ToString(result); EXPECT_EQ(result_str, "2001:db8::102:304"); } TEST_F(ResolverTest, GetHostByName2_Dns64QuerySpecialUseIPv4Addresses) { constexpr char THIS_NETWORK[] = "this_network"; constexpr char LOOPBACK[] = "loopback"; constexpr char LINK_LOCAL[] = "link_local"; constexpr char MULTICAST[] = "multicast"; constexpr char LIMITED_BROADCAST[] = "limited_broadcast"; constexpr char ADDR_THIS_NETWORK[] = "0.0.0.1"; constexpr char ADDR_LOOPBACK[] = "127.0.0.1"; constexpr char ADDR_LINK_LOCAL[] = "169.254.0.1"; constexpr char ADDR_MULTICAST[] = "224.0.0.1"; constexpr char ADDR_LIMITED_BROADCAST[] = "255.255.255.255"; constexpr char listen_addr[] = "::1"; test::DNSResponder dns(listen_addr); StartDns(dns, {}); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); ASSERT_TRUE(mDnsClient.resolvService()->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); // clang-format off static const struct TestConfig { std::string name; std::string addr; std::string asHostName() const { return fmt::format("{}.example.com.", name); } } testConfigs[]{ {THIS_NETWORK, ADDR_THIS_NETWORK}, {LOOPBACK, ADDR_LOOPBACK}, {LINK_LOCAL, ADDR_LINK_LOCAL}, {MULTICAST, ADDR_MULTICAST}, {LIMITED_BROADCAST, ADDR_LIMITED_BROADCAST} }; // clang-format on for (const auto& config : testConfigs) { const std::string testHostName = config.asHostName(); SCOPED_TRACE(testHostName); const char* host_name = testHostName.c_str(); dns.addMapping(host_name, ns_type::ns_t_a, config.addr.c_str()); struct hostent* result = gethostbyname2(config.name.c_str(), AF_INET6); EXPECT_LE(1U, GetNumQueries(dns, host_name)); // In AF_INET6 case, don't synthesize special use IPv4 address. // Expect to have no answer EXPECT_EQ(nullptr, result); dns.clearQueries(); } } TEST_F(ResolverTest, PrefixDiscoveryBypassTls) { constexpr char listen_addr[] = "::1"; constexpr char dns64_name[] = "ipv4only.arpa."; const std::vector servers = {listen_addr}; test::DNSResponder dns(listen_addr); StartDns(dns, {{dns64_name, ns_type::ns_t_aaaa, "64:ff9b::192.0.0.170"}}); test::DnsTlsFrontend tls(listen_addr, "853", listen_addr, "53"); ASSERT_TRUE(tls.startServer()); for (const std::string_view dnsMode : {"OPPORTUNISTIC", "STRICT"}) { SCOPED_TRACE(fmt::format("testConfig: [{}]", dnsMode)); auto builder = ResolverParams::Builder().setDnsServers(servers).setDotServers(servers); if (dnsMode == "STRICT") { builder.setPrivateDnsProvider(kDefaultPrivateDnsHostName); } ASSERT_TRUE(mDnsClient.SetResolversFromParcel(builder.build())); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_TRUE(tls.waitForQueries(1)); tls.clearQueries(); // Start NAT64 prefix discovery. EXPECT_TRUE(mDnsClient.resolvService()->startPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(WaitForNat64Prefix(EXPECT_FOUND)); // Verify that the DNS query for the NAT64 prefix bypassed private DNS. EXPECT_EQ(0, tls.queries()) << dns.dumpQueries(); EXPECT_EQ(1U, GetNumQueries(dns, dns64_name)) << dns.dumpQueries(); // Stop the prefix discovery to make DnsResolver send the prefix-removed event // earlier. Without this, DnsResolver still sends the event once the network // is destroyed; however, it will fail the next test if the test unexpectedly // receives the event that it doesn't want. EXPECT_TRUE(mDnsClient.resolvService()->stopPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(WaitForNat64Prefix(EXPECT_NOT_FOUND)); dns.clearQueries(); EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } EXPECT_EQ(0, sDnsMetricsListener->getUnexpectedNat64PrefixUpdates()); EXPECT_EQ(0, sUnsolicitedEventListener->getUnexpectedNat64PrefixUpdates()); } TEST_F(ResolverTest, SetAndClearNat64Prefix) { constexpr char host_name[] = "v4.example.com."; constexpr char listen_addr[] = "::1"; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, }; test::DNSResponder dns(listen_addr); StartDns(dns, records); const std::vector servers = {listen_addr}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); auto resolvService = mDnsClient.resolvService(); addrinfo hints = {.ai_family = AF_INET6}; // No NAT64 prefix, no AAAA record. ScopedAddrinfo result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_TRUE(result == nullptr); // Set the prefix, and expect to get a synthesized AAAA record. EXPECT_TRUE(resolvService->setPrefix64(TEST_NETID, kNat64Prefix2).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("2001:db8:6464::102:304", ToString(result)); // Update the prefix, expect to see AAAA records from the new prefix. EXPECT_TRUE(resolvService->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); // Non-/96 prefixes are ignored. auto status = resolvService->setPrefix64(TEST_NETID, "64:ff9b::/64"); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EINVAL, status.getServiceSpecificError()); // Invalid prefixes are ignored. status = resolvService->setPrefix64(TEST_NETID, "192.0.2.0/24"); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EINVAL, status.getServiceSpecificError()); status = resolvService->setPrefix64(TEST_NETID, "192.0.2.1"); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EINVAL, status.getServiceSpecificError()); status = resolvService->setPrefix64(TEST_NETID, "hello"); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EINVAL, status.getServiceSpecificError()); // DNS64 synthesis is still working. result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); // Clear the prefix. No AAAA records any more. EXPECT_TRUE(resolvService->setPrefix64(TEST_NETID, "").isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); EXPECT_TRUE(result == nullptr); // Calling startPrefix64Discovery clears the prefix. EXPECT_TRUE(resolvService->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); EXPECT_TRUE(resolvService->startPrefix64Discovery(TEST_NETID).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_TRUE(result == nullptr); // setPrefix64 fails if prefix discovery is started, even if no prefix is yet discovered... status = resolvService->setPrefix64(TEST_NETID, kNat64Prefix); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EEXIST, status.getServiceSpecificError()); // .. and clearing the prefix also has no effect. status = resolvService->setPrefix64(TEST_NETID, ""); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(ENOENT, status.getServiceSpecificError()); // setPrefix64 succeeds again when prefix discovery is stopped. EXPECT_TRUE(resolvService->stopPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(resolvService->setPrefix64(TEST_NETID, kNat64Prefix).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); // Calling stopPrefix64Discovery clears the prefix. EXPECT_TRUE(resolvService->stopPrefix64Discovery(TEST_NETID).isOk()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_TRUE(result == nullptr); // Set up NAT64 prefix discovery. constexpr char dns64_name[] = "ipv4only.arpa."; const std::vector newRecords = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {dns64_name, ns_type::ns_t_aaaa, "64:ff9b::192.0.0.170"}, }; dns.stopServer(); StartDns(dns, newRecords); EXPECT_TRUE(resolvService->startPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(WaitForNat64Prefix(EXPECT_FOUND)); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); // setPrefix64 fails if NAT64 prefix discovery has succeeded, and the discovered prefix // continues to be used. status = resolvService->setPrefix64(TEST_NETID, kNat64Prefix2); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(EEXIST, status.getServiceSpecificError()); // Clearing the prefix also has no effect if discovery is started. status = resolvService->setPrefix64(TEST_NETID, ""); EXPECT_FALSE(status.isOk()); EXPECT_EQ(EX_SERVICE_SPECIFIC, status.getExceptionCode()); EXPECT_EQ(ENOENT, status.getServiceSpecificError()); result = safe_getaddrinfo("v4.example.com", nullptr, &hints); ASSERT_FALSE(result == nullptr); EXPECT_EQ("64:ff9b::102:304", ToString(result)); EXPECT_TRUE(resolvService->stopPrefix64Discovery(TEST_NETID).isOk()); EXPECT_TRUE(WaitForNat64Prefix(EXPECT_NOT_FOUND)); EXPECT_EQ(0, sDnsMetricsListener->getUnexpectedNat64PrefixUpdates()); EXPECT_EQ(0, sUnsolicitedEventListener->getUnexpectedNat64PrefixUpdates()); } namespace { class ScopedSetNetworkForProcess { public: explicit ScopedSetNetworkForProcess(unsigned netId) { mStoredNetId = getNetworkForProcess(); if (netId == mStoredNetId) return; EXPECT_EQ(0, setNetworkForProcess(netId)); } ~ScopedSetNetworkForProcess() { EXPECT_EQ(0, setNetworkForProcess(mStoredNetId)); } private: unsigned mStoredNetId; }; class ScopedSetNetworkForResolv { public: explicit ScopedSetNetworkForResolv(unsigned netId) { EXPECT_EQ(0, setNetworkForResolv(netId)); } ~ScopedSetNetworkForResolv() { EXPECT_EQ(0, setNetworkForResolv(NETID_UNSET)); } }; void sendCommand(int fd, const std::string& cmd) { ssize_t rc = TEMP_FAILURE_RETRY(write(fd, cmd.c_str(), cmd.size() + 1)); EXPECT_EQ(rc, static_cast(cmd.size() + 1)); } int32_t readBE32(int fd) { int32_t tmp; int n = TEMP_FAILURE_RETRY(read(fd, &tmp, sizeof(tmp))); EXPECT_TRUE(n > 0); return ntohl(tmp); } int readResponseCode(int fd) { char buf[4]; int n = TEMP_FAILURE_RETRY(read(fd, &buf, sizeof(buf))); EXPECT_TRUE(n > 0); // The format of response code is that 4 bytes for the code & null. buf[3] = '\0'; int result; EXPECT_TRUE(ParseInt(buf, &result)); return result; } bool checkAndClearUseLocalNameserversFlag(unsigned* netid) { if (netid == nullptr || ((*netid) & NETID_USE_LOCAL_NAMESERVERS) == 0) { return false; } *netid = (*netid) & ~NETID_USE_LOCAL_NAMESERVERS; return true; } aidl::android::net::UidRangeParcel makeUidRangeParcel(int start, int stop) { aidl::android::net::UidRangeParcel res; res.start = start; res.stop = stop; return res; } void expectNetIdWithLocalNameserversFlag(unsigned netId) { unsigned dnsNetId = 0; EXPECT_EQ(0, getNetworkForDns(&dnsNetId)); EXPECT_TRUE(checkAndClearUseLocalNameserversFlag(&dnsNetId)); EXPECT_EQ(netId, static_cast(dnsNetId)); } void expectDnsNetIdEquals(unsigned netId) { unsigned dnsNetId = 0; EXPECT_EQ(0, getNetworkForDns(&dnsNetId)); EXPECT_EQ(netId, static_cast(dnsNetId)); } void expectDnsNetIdIsDefaultNetwork(INetd* netdService) { int currentNetid; EXPECT_TRUE(netdService->networkGetDefault(¤tNetid).isOk()); expectDnsNetIdEquals(currentNetid); } void expectDnsNetIdWithVpn(INetd* netdService, unsigned vpnNetId, unsigned expectedNetId) { if (DnsResponderClient::isRemoteVersionSupported(netdService, 6)) { const auto& config = DnsResponderClient::makeNativeNetworkConfig( vpnNetId, NativeNetworkType::VIRTUAL, INetd::PERMISSION_NONE, /*secure=*/false); EXPECT_TRUE(netdService->networkCreate(config).isOk()); } else { #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wdeprecated-declarations" EXPECT_TRUE(netdService->networkCreateVpn(vpnNetId, false /* secure */).isOk()); #pragma clang diagnostic pop } uid_t uid = getuid(); // Add uid to VPN EXPECT_TRUE(netdService->networkAddUidRanges(vpnNetId, {makeUidRangeParcel(uid, uid)}).isOk()); expectDnsNetIdEquals(expectedNetId); EXPECT_TRUE(netdService->networkDestroy(vpnNetId).isOk()); } } // namespace TEST_F(ResolverTest, getDnsNetId) { // We've called setNetworkForProcess in SetupOemNetwork, so reset to default first. setNetworkForProcess(NETID_UNSET); expectDnsNetIdIsDefaultNetwork(mDnsClient.netdService()); expectDnsNetIdWithVpn(mDnsClient.netdService(), TEST_VPN_NETID, TEST_VPN_NETID); // Test with setNetworkForProcess { ScopedSetNetworkForProcess scopedSetNetworkForProcess(TEST_NETID); expectDnsNetIdEquals(TEST_NETID); } // Test with setNetworkForProcess with NETID_USE_LOCAL_NAMESERVERS { ScopedSetNetworkForProcess scopedSetNetworkForProcess(TEST_NETID | NETID_USE_LOCAL_NAMESERVERS); expectNetIdWithLocalNameserversFlag(TEST_NETID); } // Test with setNetworkForResolv { ScopedSetNetworkForResolv scopedSetNetworkForResolv(TEST_NETID); expectDnsNetIdEquals(TEST_NETID); } // Test with setNetworkForResolv with NETID_USE_LOCAL_NAMESERVERS { ScopedSetNetworkForResolv scopedSetNetworkForResolv(TEST_NETID | NETID_USE_LOCAL_NAMESERVERS); expectNetIdWithLocalNameserversFlag(TEST_NETID); } // Test with setNetworkForResolv under bypassable vpn { ScopedSetNetworkForResolv scopedSetNetworkForResolv(TEST_NETID); expectDnsNetIdWithVpn(mDnsClient.netdService(), TEST_VPN_NETID, TEST_NETID); } // Create socket connected to DnsProxyListener int fd = dns_open_proxy(); EXPECT_TRUE(fd > 0); unique_fd ufd(fd); // Test command with wrong netId sendCommand(fd, "getdnsnetid abc"); EXPECT_EQ(ResponseCode::DnsProxyQueryResult, readResponseCode(fd)); EXPECT_EQ(-EINVAL, readBE32(fd)); // Test unsupported command sendCommand(fd, "getdnsnetidNotSupported"); // Keep in sync with FrameworkListener.cpp (500, "Command not recognized") EXPECT_EQ(500, readResponseCode(fd)); } TEST_F(ResolverTest, BlockDnsQueryWithUidRule) { SKIP_IF_BPF_NOT_SUPPORTED; constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "::1"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; INetd* netdService = mDnsClient.netdService(); test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, records); StartDns(dns2, records); std::vector servers = {listen_addr1, listen_addr2}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); dns1.clearQueries(); dns2.clearQueries(); ScopeBlockedUIDRule scopeBlockUidRule(netdService, TEST_UID); // Dns Query int fd1 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_a, 0); int fd2 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); uint8_t buf1[MAXPACKET] = {}; uint8_t buf2[MAXPACKET] = {}; int rcode; int res2 = getAsyncResponse(fd2, &rcode, buf2, MAXPACKET); int res1 = getAsyncResponse(fd1, &rcode, buf1, MAXPACKET); // If API level >= 30 (R+), these queries should be blocked. EXPECT_EQ(res2, -ECONNREFUSED); EXPECT_EQ(res1, -ECONNREFUSED); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, EAI_SYSTEM, "howdy.example.com", {}); ExpectDnsEvent(INetdEventListener::EVENT_RES_NSEND, EAI_SYSTEM, "howdy.example.com", {}); } TEST_F(ResolverTest, GetAddrinfo_BlockDnsQueryWithUidRule) { SKIP_IF_BPF_NOT_SUPPORTED; constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "::1"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, records); StartDns(dns2, records); std::vector servers = {listen_addr1, listen_addr2}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; static struct { const char* hname; const int expectedErrorCode; } kTestData[] = { {host_name, (isAtLeastT() && fs::exists(DNS_HELPER)) ? EAI_FAIL : EAI_NODATA}, // To test the query with search domain. {"howdy", (isAtLeastT() && fs::exists(DNS_HELPER)) ? EAI_FAIL : EAI_AGAIN}, }; INetd* netdService = mDnsClient.netdService(); for (auto& td : kTestData) { SCOPED_TRACE(td.hname); ScopeBlockedUIDRule scopeBlockUidRule(netdService, TEST_UID); // If API level >= 30 (R+), these queries should be blocked. addrinfo* result = nullptr; // getaddrinfo() in bionic would convert all errors to EAI_NODATA // except EAI_SYSTEM. EXPECT_EQ(EAI_NODATA, getaddrinfo(td.hname, nullptr, &hints, &result)); ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, td.expectedErrorCode, td.hname, {}); } } TEST_F(ResolverTest, EnforceDnsUid) { SKIP_IF_BPF_NOT_SUPPORTED; constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "::1"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; INetd* netdService = mDnsClient.netdService(); test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, records); StartDns(dns2, records); // switch uid of DNS queries from applications to AID_DNS ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {listen_addr1, listen_addr2}; ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk()); uint8_t buf[MAXPACKET] = {}; uint8_t buf2[MAXPACKET] = {}; int rcode; { ScopeBlockedUIDRule scopeBlockUidRule(netdService, TEST_UID); // Dns Queries should be blocked const int fd1 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_a, 0); const int fd2 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); const int res2 = getAsyncResponse(fd2, &rcode, buf2, MAXPACKET); const int res1 = getAsyncResponse(fd1, &rcode, buf, MAXPACKET); // If API level >= 30 (R+), the query should be blocked. EXPECT_EQ(res2, -ECONNREFUSED); EXPECT_EQ(res1, -ECONNREFUSED); } memset(buf, 0, MAXPACKET); ResolverOptionsParcel resolverOptions; resolverOptions.enforceDnsUid = true; if (!mIsResolverOptionIPCSupported) { parcel.resolverOptions = resolverOptions; ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk()); } else { ASSERT_TRUE(mDnsClient.resolvService() ->setResolverOptions(parcel.netId, resolverOptions) .isOk()); } { ScopeBlockedUIDRule scopeBlockUidRule(netdService, TEST_UID); // Dns Queries should NOT be blocked int fd1 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_a, 0); int fd2 = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_aaaa, 0); EXPECT_TRUE(fd1 != -1); EXPECT_TRUE(fd2 != -1); int res = getAsyncResponse(fd2, &rcode, buf, MAXPACKET); EXPECT_EQ("::1.2.3.4", toString(buf, res, AF_INET6)); memset(buf, 0, MAXPACKET); res = getAsyncResponse(fd1, &rcode, buf, MAXPACKET); EXPECT_EQ("1.2.3.4", toString(buf, res, AF_INET)); // @TODO: So far we know that uid of DNS queries are no more set to DNS requester. But we // don't check if they are actually being set to AID_DNS, because system uids are always // allowed in bpf_owner_match(). Audit by firewallSetUidRule(AID_DNS) + sending queries is // infeasible. Fix it if the behavior of bpf_owner_match() is changed in the future, or if // we have better idea to deal with this. } } TEST_F(ResolverTest, ConnectTlsServerTimeout) { constexpr char hostname1[] = "query1.example.com."; constexpr char hostname2[] = "query2.example.com."; const std::vector records = { {hostname1, ns_type::ns_t_a, "1.2.3.4"}, {hostname2, ns_type::ns_t_a, "1.2.3.5"}, }; // TODO: Remove it after b/254186357 is clarified. ASSERT_TRUE(mDnsClient.resolvService() ->setLogSeverity(aidl::android::net::IDnsResolver::DNS_RESOLVER_LOG_VERBOSE) .isOk()); static const struct TestConfig { bool asyncHandshake; int maxRetries; // if asyncHandshake: // expectedTimeout = Min(DotQueryTimeoutMs, dotConnectTimeoutMs * maxRetries) // otherwise: // expectedTimeout = dotConnectTimeoutMs int expectedTimeout; } testConfigs[] = { // Test mis-configured dot_maxtries flag. {false, 0, 1000}, {true, 0, 1000}, {false, 1, 1000}, {false, 3, 1000}, {true, 1, 1000}, {true, 3, 3000}, }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}]", config.asyncHandshake, config.maxRetries)); // Because a DnsTlsTransport lasts at least 5 minutes in spite of network // destroyed, let the resolver creates an unique DnsTlsTransport every time // so that the DnsTlsTransport won't interfere the other tests. const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr); StartDns(dns, records); test::DnsTlsFrontend tls(addr, "853", addr, "53"); ASSERT_TRUE(tls.startServer()); // The resolver will adjust the timeout value to 1000ms since the value is too small. ScopedSystemProperties sp1(kDotConnectTimeoutMsFlag, "100"); // Infinite timeout. ScopedSystemProperties sp2(kDotQueryTimeoutMsFlag, "-1"); ScopedSystemProperties sp3(kDotAsyncHandshakeFlag, config.asyncHandshake ? "1" : "0"); ScopedSystemProperties sp4(kDotMaxretriesFlag, std::to_string(config.maxRetries)); // Don't skip unusable DoT servers and disable revalidation for this test. ScopedSystemProperties sp5(kDotXportUnusableThresholdFlag, "-1"); ScopedSystemProperties sp6(kDotRevalidationThresholdFlag, "-1"); resetNetwork(); // Set up resolver to opportunistic mode. auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_TRUE(tls.waitForQueries(1)); tls.clearQueries(); dns.clearQueries(); // The server becomes unresponsive to the handshake request. tls.setHangOnHandshakeForTesting(true); // Expect the things happening in getaddrinfo(): // 1. Connect to the private DNS server. // 2. SSL handshake times out. // 3. Fallback to UDP transport, and then get the answer. const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; auto [result, timeTakenMs] = safe_getaddrinfo_time_taken(hostname1, nullptr, hints); EXPECT_NE(nullptr, result); EXPECT_EQ(0, tls.queries()); EXPECT_EQ(1U, GetNumQueries(dns, hostname1)); EXPECT_EQ(records.at(0).addr, ToString(result)); // A loose upper bound is set by adding 1000ms buffer time. Theoretically, getaddrinfo() // should just take a bit more than expetTimeout milliseconds. EXPECT_GE(timeTakenMs, config.expectedTimeout); EXPECT_LE(timeTakenMs, config.expectedTimeout + 1000); // Set the server to be responsive. Verify that the resolver will attempt to reconnect // to the server and then get the result within the timeout. tls.setHangOnHandshakeForTesting(false); std::tie(result, timeTakenMs) = safe_getaddrinfo_time_taken(hostname2, nullptr, hints); EXPECT_NE(nullptr, result); EXPECT_TRUE(tls.waitForQueries(1)); EXPECT_EQ(1U, GetNumQueries(dns, hostname2)); EXPECT_EQ(records.at(1).addr, ToString(result)); EXPECT_LE(timeTakenMs, 1000); } // TODO: Remove it after b/254186357 is clarified. ASSERT_TRUE(mDnsClient.resolvService() ->setLogSeverity(aidl::android::net::IDnsResolver::DNS_RESOLVER_LOG_INFO) .isOk()); } TEST_F(ResolverTest, ConnectTlsServerTimeout_ConcurrentQueries) { constexpr uint32_t cacheFlag = ANDROID_RESOLV_NO_CACHE_LOOKUP; constexpr char hostname[] = "hello.example.com."; const std::vector records = { {hostname, ns_type::ns_t_a, "1.2.3.4"}, }; int testConfigCount = 0; static const struct TestConfig { bool asyncHandshake; int dotConnectTimeoutMs; int dotQueryTimeoutMs; int maxRetries; int concurrency; // if asyncHandshake: // expectedTimeout = Min(DotQueryTimeoutMs, dotConnectTimeoutMs * maxRetries) // otherwise: // expectedTimeout = dotConnectTimeoutMs * concurrency int expectedTimeout; } testConfigs[] = { // clang-format off {false, 1000, 3000, 1, 5, 5000}, {false, 1000, 3000, 3, 5, 5000}, {false, 2000, 1500, 3, 2, 4000}, {true, 1000, 3000, 1, 5, 1000}, {true, 2500, 1500, 1, 10, 1500}, {true, 1000, 5000, 3, 5, 3000}, // clang-format on }; // Launch query threads. Expected behaviors are: // - when dot_async_handshake is disabled, one of the query threads triggers a // handshake and then times out. Then same as another query thread, and so forth. // - when dot_async_handshake is enabled, only one handshake is triggered, and then // all of the query threads time out at the same time. for (const auto& config : testConfigs) { testConfigCount++; ScopedSystemProperties sp1(kDotQueryTimeoutMsFlag, std::to_string(config.dotQueryTimeoutMs)); ScopedSystemProperties sp2(kDotConnectTimeoutMsFlag, std::to_string(config.dotConnectTimeoutMs)); ScopedSystemProperties sp3(kDotAsyncHandshakeFlag, config.asyncHandshake ? "1" : "0"); ScopedSystemProperties sp4(kDotMaxretriesFlag, std::to_string(config.maxRetries)); // Don't skip unusable DoT servers and disable revalidation for this test. ScopedSystemProperties sp5(kDotXportUnusableThresholdFlag, "-1"); ScopedSystemProperties sp6(kDotRevalidationThresholdFlag, "-1"); resetNetwork(); for (const std::string_view dnsMode : {"OPPORTUNISTIC", "STRICT"}) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}]", testConfigCount, dnsMode)); // Because a DnsTlsTransport lasts at least 5 minutes in spite of network // destroyed, let the resolver creates an unique DnsTlsTransport every time // so that the DnsTlsTransport won't interfere the other tests. const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr); StartDns(dns, records); test::DnsTlsFrontend tls(addr, "853", addr, "53"); ASSERT_TRUE(tls.startServer()); auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; if (dnsMode == "STRICT") parcel.tlsName = kDefaultPrivateDnsHostName; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_TRUE(tls.waitForQueries(1)); // The server becomes unresponsive to the handshake request. tls.setHangOnHandshakeForTesting(true); Stopwatch s; std::vector threads(config.concurrency); for (std::thread& thread : threads) { thread = std::thread([&]() { int fd = resNetworkQuery(TEST_NETID, hostname, ns_c_in, ns_t_a, cacheFlag); dnsMode == "STRICT" ? expectAnswersNotValid(fd, -ETIMEDOUT) : expectAnswersValid(fd, AF_INET, "1.2.3.4"); }); } for (std::thread& thread : threads) { thread.join(); } const int timeTakenMs = s.timeTakenUs() / 1000; // A loose upper bound is set by adding 1000ms buffer time. Theoretically, it should // just take a bit more than expetTimeout milliseconds for the result. EXPECT_GE(timeTakenMs, config.expectedTimeout); EXPECT_LE(timeTakenMs, config.expectedTimeout + 1000); // Recover the server from being unresponsive and try again. tls.setHangOnHandshakeForTesting(false); int fd = resNetworkQuery(TEST_NETID, hostname, ns_c_in, ns_t_a, cacheFlag); if (dnsMode == "STRICT" && config.asyncHandshake && config.dotQueryTimeoutMs < (config.dotConnectTimeoutMs * config.maxRetries)) { // In this case, the connection handshake is supposed to be in progress. Queries // sent before the handshake finishes will time out (either due to connect timeout // or query timeout). expectAnswersNotValid(fd, -ETIMEDOUT); } else { expectAnswersValid(fd, AF_INET, "1.2.3.4"); } } } } // Tests that the DoT query timeout is configurable via the feature flag "dot_query_timeout_ms". // The test DoT server is configured to postpone DNS queries for DOT_SERVER_UNRESPONSIVE_TIME_MS // (2s). If the feature flag is set to a positive value smaller than // DOT_SERVER_UNRESPONSIVE_TIME_MS, DoT queries should timeout. TEST_F(ResolverTest, QueryTlsServerTimeout) { constexpr int DOT_SERVER_UNRESPONSIVE_TIME_MS = 2000; constexpr int TIMING_TOLERANCE_MS = 500; constexpr char hostname1[] = "query1.example.com."; const std::vector records = { {hostname1, ns_type::ns_t_a, "1.2.3.4"}, }; static const struct TestConfig { std::string dnsMode; int queryTimeoutMs; int expectResultTimedOut; int expectedTimeTakenMs; } testConfigs[] = { // clang-format off {"OPPORTUNISTIC", -1, false, DOT_SERVER_UNRESPONSIVE_TIME_MS}, {"OPPORTUNISTIC", 1000, false, 1000}, {"STRICT", -1, false, DOT_SERVER_UNRESPONSIVE_TIME_MS}, // `expectResultTimedOut` is true in the following testcase because in strict mode // DnsResolver doesn't try Do53 servers after the DoT query is timed out. {"STRICT", 1000, true, 1000}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}] [{}]", config.dnsMode, config.queryTimeoutMs)); const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr); StartDns(dns, records); test::DnsTlsFrontend tls(addr, "853", addr, "53"); ASSERT_TRUE(tls.startServer()); ScopedSystemProperties sp(kDotQueryTimeoutMsFlag, std::to_string(config.queryTimeoutMs)); // Don't skip unusable DoT servers and disable revalidation for this test. ScopedSystemProperties sp2(kDotXportUnusableThresholdFlag, "-1"); ScopedSystemProperties sp3(kDotRevalidationThresholdFlag, "-1"); resetNetwork(); auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; if (config.dnsMode == "STRICT") parcel.tlsName = kDefaultPrivateDnsHostName; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_TRUE(tls.waitForQueries(1)); tls.clearQueries(); // Set the DoT server to be unresponsive to DNS queries for // `DOT_SERVER_UNRESPONSIVE_TIME_MS` ms. tls.setDelayQueries(999); tls.setDelayQueriesTimeout(DOT_SERVER_UNRESPONSIVE_TIME_MS); // Send a DNS query, and then check the result and the response time. Stopwatch s; int fd = resNetworkQuery(TEST_NETID, hostname1, ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_LOOKUP); if (config.expectResultTimedOut) { expectAnswersNotValid(fd, -ETIMEDOUT); } else { expectAnswersValid(fd, AF_INET, "1.2.3.4"); } const int timeTakenMs = s.getTimeAndResetUs() / 1000; EXPECT_NEAR(config.expectedTimeTakenMs, timeTakenMs, TIMING_TOLERANCE_MS); EXPECT_TRUE(tls.waitForQueries(1)); } } // Tests that the DnsResolver can skip using unusable DoT servers if dot_xport_unusable_threshold // flag is set. In this test, we make test DoT servers unresponsive during connection handshake, // so the DnsResolver will skip using a DoT server if the number of timed out queries reaches // the threshold. TEST_F(ResolverTest, SkipUnusableTlsServer) { constexpr int DOT_CONNECT_TIMEOUT_MS = 1000; static const struct TestConfig { int dotXportUnusableThreshold; int queries; int expectedQueriesSentToDot1; int expectedQueriesSentToDot2; } testConfigs[] = { // clang-format off // expectedQueriesSentToDot2 is 0 because dot_quick_fallback flag is set. {-1, 3, 3, 0}, { 1, 3, 1, 1}, { 3, 10, 3, 3}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}, {}, {}]", config.dotXportUnusableThreshold, config.queries, config.expectedQueriesSentToDot1, config.expectedQueriesSentToDot2)); const std::string addr1 = getUniqueIPv4Address(); const std::string addr2 = getUniqueIPv4Address(); test::DNSResponder dns1(addr1); test::DNSResponder dns2(addr2); test::DnsTlsFrontend dot1(addr1, "853", addr1, "53"); test::DnsTlsFrontend dot2(addr2, "853", addr2, "53"); dns1.addMapping(kHelloExampleCom, ns_type::ns_t_aaaa, kHelloExampleComAddrV6); dns2.addMapping(kHelloExampleCom, ns_type::ns_t_aaaa, kHelloExampleComAddrV6); ASSERT_TRUE(dns1.startServer()); ASSERT_TRUE(dns2.startServer()); ASSERT_TRUE(dot1.startServer()); ASSERT_TRUE(dot2.startServer()); ScopedSystemProperties sp1(kDotConnectTimeoutMsFlag, std::to_string(DOT_CONNECT_TIMEOUT_MS)); ScopedSystemProperties sp2(kDotXportUnusableThresholdFlag, std::to_string(config.dotXportUnusableThreshold)); ScopedSystemProperties sp3(kDotQuickFallbackFlag, "1"); ScopedSystemProperties sp4(kDotRevalidationThresholdFlag, "-1"); resetNetwork(); // Private DNS opportunistic mode. auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr1, addr2}; parcel.tlsServers = {addr1, addr2}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(dot1.listen_address(), true)); EXPECT_TRUE(WaitForPrivateDnsValidation(dot2.listen_address(), true)); EXPECT_TRUE(dot1.waitForQueries(1)); EXPECT_TRUE(dot2.waitForQueries(1)); dot1.clearQueries(); dot2.clearQueries(); dot1.clearConnectionsCount(); dot2.clearConnectionsCount(); // Set the DoT servers as unresponsive to connection handshake. dot1.setHangOnHandshakeForTesting(true); dot2.setHangOnHandshakeForTesting(true); // Send sequential queries for (int i = 0; i < config.queries; i++) { int fd = resNetworkQuery(TEST_NETID, kHelloExampleCom, ns_c_in, ns_t_aaaa, ANDROID_RESOLV_NO_CACHE_LOOKUP); expectAnswersValid(fd, AF_INET6, kHelloExampleComAddrV6); } if (GetProperty(kDotAsyncHandshakeFlag, "0") == "0") { EXPECT_EQ(dot1.acceptConnectionsCount(), config.expectedQueriesSentToDot1); EXPECT_EQ(dot2.acceptConnectionsCount(), config.expectedQueriesSentToDot2); } else { // If the flag dot_async_handshake is set to 1, the DnsResolver will try // DoT connection establishment at most |retries| times. const int retries = std::stoi(GetProperty(kDotMaxretriesFlag, "3")); EXPECT_EQ(dot1.acceptConnectionsCount(), config.expectedQueriesSentToDot1 * retries); EXPECT_EQ(dot2.acceptConnectionsCount(), config.expectedQueriesSentToDot2 * retries); } } } // Verifies that the DnsResolver re-validates the DoT server when several DNS queries to // the server fails in a row. TEST_F(ResolverTest, TlsServerRevalidation) { constexpr uint32_t cacheFlag = ANDROID_RESOLV_NO_CACHE_LOOKUP; constexpr int dotXportUnusableThreshold = 10; constexpr int dotQueryTimeoutMs = 1000; constexpr char hostname[] = "hello.example.com."; const std::vector records = { {hostname, ns_type::ns_t_a, "1.2.3.4"}, }; static const struct TestConfig { std::string dnsMode; int validationThreshold; int queries; // Expected behavior in the DnsResolver. bool expectRevalidationHappen; bool expectDotUnusable; } testConfigs[] = { // clang-format off {"OPPORTUNISTIC", -1, 5, false, false}, {"OPPORTUNISTIC", -1, 10, false, true}, {"OPPORTUNISTIC", 5, 5, true, false}, {"OPPORTUNISTIC", 5, 10, true, true}, {"STRICT", -1, 5, false, false}, {"STRICT", -1, 10, false, false}, {"STRICT", 5, 5, false, false}, {"STRICT", 5, 10, false, false}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}, {}]", config.dnsMode, config.validationThreshold, config.queries)); const int queries = config.queries; const int delayQueriesTimeout = dotQueryTimeoutMs + 1000; ScopedSystemProperties sp1(kDotRevalidationThresholdFlag, std::to_string(config.validationThreshold)); ScopedSystemProperties sp2(kDotXportUnusableThresholdFlag, std::to_string(dotXportUnusableThreshold)); ScopedSystemProperties sp3(kDotQueryTimeoutMsFlag, std::to_string(dotQueryTimeoutMs)); resetNetwork(); // This test is sensitive to the number of queries sent in DoT validation. int latencyFactor; int latencyOffsetMs; // The feature is enabled by default in R. latencyFactor = std::stoi(GetProperty(kDotValidationLatencyFactorFlag, "3")); latencyOffsetMs = std::stoi(GetProperty(kDotValidationLatencyOffsetMsFlag, "100")); const bool dotValidationExtraProbes = (config.dnsMode == "OPPORTUNISTIC") && (latencyFactor >= 0 && latencyOffsetMs >= 0 && latencyFactor + latencyOffsetMs != 0); const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr); StartDns(dns, records); test::DnsTlsFrontend tls(addr, "853", addr, "53"); ASSERT_TRUE(tls.startServer()); auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; if (config.dnsMode == "STRICT") parcel.tlsName = kDefaultPrivateDnsHostName; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); if (dotValidationExtraProbes) { EXPECT_TRUE(tls.waitForQueries(2)); } else { EXPECT_TRUE(tls.waitForQueries(1)); } tls.clearQueries(); dns.clearQueries(); // Expect the things happening in order: // 1. Configure the DoT server to postpone |queries + 1| DNS queries. // 2. Send |queries| DNS queries, they will time out in 1 second. // 3. 1 second later, the DoT server still waits for one more DNS query until // |delayQueriesTimeout| times out. // 4. (opportunistic mode only) Meanwhile, DoT revalidation happens. The DnsResolver // creates a new connection and sends a query to the DoT server. // 5. 1 second later, |delayQueriesTimeout| times out. The DoT server flushes all of the // postponed DNS queries, and handles the query which comes from the revalidation. // 6. (opportunistic mode only) The revalidation succeeds. // 7. Send another DNS query, and expect it will succeed. // 8. (opportunistic mode only) If the DoT server has been deemed as unusable, the // DnsResolver skips trying the DoT server. // Step 1. tls.setDelayQueries(queries + 1); tls.setDelayQueriesTimeout(delayQueriesTimeout); // Step 2. std::vector threads1(queries); for (std::thread& thread : threads1) { thread = std::thread([&]() { int fd = resNetworkQuery(TEST_NETID, hostname, ns_c_in, ns_t_a, cacheFlag); config.dnsMode == "STRICT" ? expectAnswersNotValid(fd, -ETIMEDOUT) : expectAnswersValid(fd, AF_INET, "1.2.3.4"); }); } // Step 3 and 4. for (std::thread& thread : threads1) { thread.join(); } // Recover the config to make the revalidation can succeed. tls.setDelayQueries(1); // Step 5 and 6. int expectedDotQueries = queries; int extraDnsProbe = 0; if (config.expectRevalidationHappen) { EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); expectedDotQueries++; if (dotValidationExtraProbes) { expectedDotQueries++; extraDnsProbe = 1; } } // Step 7 and 8. int fd = resNetworkQuery(TEST_NETID, hostname, ns_c_in, ns_t_a, cacheFlag); expectAnswersValid(fd, AF_INET, "1.2.3.4"); expectedDotQueries++; const int expectedDo53Queries = expectedDotQueries + (config.dnsMode == "OPPORTUNISTIC" ? (queries + extraDnsProbe) : 0); if (config.expectDotUnusable) { // A DoT server can be deemed as unusable only in opportunistic mode. When it happens, // the DnsResolver doesn't use the DoT server for a certain period of time. expectedDotQueries--; } // This code makes the test more robust to race condition. EXPECT_TRUE(tls.waitForQueries(expectedDotQueries)); EXPECT_EQ(dns.queries().size(), static_cast(expectedDo53Queries)); EXPECT_EQ(tls.queries(), expectedDotQueries); } } // Verifies that private DNS validation fails if DoT server is much slower than cleartext server. TEST_F(ResolverTest, TlsServerValidation_UdpProbe) { constexpr char backend_addr[] = "127.0.0.3"; test::DNSResponder backend(backend_addr); backend.setResponseDelayMs(200); ASSERT_TRUE(backend.startServer()); static const struct TestConfig { int latencyFactor; int latencyOffsetMs; bool udpProbeLost; size_t expectedUdpProbes; bool expectedValidationPass; } testConfigs[] = { // clang-format off {-1, -1, false, 0, true}, {0, 0, false, 0, true}, {1, 10, false, 1, false}, {1, 10, true, 2, false}, {5, 300, false, 1, true}, {5, 300, true, 2, true}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}, {}]", config.latencyFactor, config.latencyOffsetMs, config.udpProbeLost)); const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr, "53", static_cast(-1)); test::DnsTlsFrontend tls(addr, "853", backend_addr, "53"); dns.setResponseDelayMs(10); ASSERT_TRUE(dns.startServer()); ASSERT_TRUE(tls.startServer()); ScopedSystemProperties sp1(kDotValidationLatencyFactorFlag, std::to_string(config.latencyFactor)); ScopedSystemProperties sp2(kDotValidationLatencyOffsetMsFlag, std::to_string(config.latencyOffsetMs)); resetNetwork(); std::unique_ptr thread; if (config.udpProbeLost) { thread.reset(new std::thread([&dns]() { // Simulate that the first UDP probe is lost and the second UDP probe succeeds. dns.setResponseProbability(0.0); std::this_thread::sleep_for(std::chrono::seconds(2)); dns.setResponseProbability(1.0); })); } // Set up opportunistic mode, and wait for the validation complete. auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); // The timeout of WaitForPrivateDnsValidation is 5 seconds which is still enough for // the testcase of UDP probe lost because the retry of UDP probe happens after 3 seconds. EXPECT_TRUE( WaitForPrivateDnsValidation(tls.listen_address(), config.expectedValidationPass)); EXPECT_EQ(dns.queries().size(), config.expectedUdpProbes); dns.clearQueries(); // Test that Private DNS validation always pass in strict mode. parcel.tlsName = kDefaultPrivateDnsHostName; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_EQ(dns.queries().size(), 0U); if (thread) { thread->join(); thread.reset(); } } } // Verifies that DNS queries can quick fall back to UDP if the first DoT server is unresponsive. TEST_F(ResolverTest, DotQuickFallback) { constexpr int DOT_CONNECT_TIMEOUT_MS = 1000; const std::string addr1 = getUniqueIPv4Address(); const std::string addr2 = getUniqueIPv4Address(); test::DNSResponder dns1(addr1); test::DNSResponder dns2(addr2); test::DnsTlsFrontend dot1(addr1, "853", addr1, "53"); test::DnsTlsFrontend dot2(addr2, "853", addr2, "53"); dns1.addMapping(kHelloExampleCom, ns_type::ns_t_aaaa, kHelloExampleComAddrV6); dns2.addMapping(kHelloExampleCom, ns_type::ns_t_aaaa, kHelloExampleComAddrV6); ASSERT_TRUE(dns1.startServer()); ASSERT_TRUE(dns2.startServer()); ASSERT_TRUE(dot1.startServer()); ASSERT_TRUE(dot2.startServer()); static const struct TestConfig { std::string privateDnsMode; int dotQuickFallbackFlag; } testConfigs[] = { // clang-format off {"OPPORTUNISTIC", 0}, {"OPPORTUNISTIC", 1}, {"STRICT", 0}, {"STRICT", 1}, // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}, {}]", config.privateDnsMode, config.dotQuickFallbackFlag)); const bool canQuickFallback = (config.dotQuickFallbackFlag == 1) && (config.privateDnsMode == "OPPORTUNISTIC"); ScopedSystemProperties sp1(kDotConnectTimeoutMsFlag, std::to_string(DOT_CONNECT_TIMEOUT_MS)); ScopedSystemProperties sp2(kDotQuickFallbackFlag, std::to_string(config.dotQuickFallbackFlag)); // Disable revalidation because we are reusing the same IP address of DoT servers. ScopedSystemProperties sp3(kDotRevalidationThresholdFlag, "-1"); // TODO: Remove the flags and fix the test. ScopedSystemProperties sp4(kDotAsyncHandshakeFlag, "0"); ScopedSystemProperties sp5(kDotMaxretriesFlag, "3"); resetNetwork(); resetNetwork(); auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr1, addr2}; parcel.tlsServers = {addr1, addr2}; parcel.tlsName = (config.privateDnsMode == "STRICT") ? kDefaultPrivateDnsHostName : ""; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(dot1.listen_address(), true)); EXPECT_TRUE(WaitForPrivateDnsValidation(dot2.listen_address(), true)); EXPECT_TRUE(dot1.waitForQueries(1)); EXPECT_TRUE(dot2.waitForQueries(1)); dot1.clearQueries(); dot2.clearQueries(); dot1.clearConnectionsCount(); dot2.clearConnectionsCount(); // Set the DoT server unresponsive to connection handshake. dot1.setHangOnHandshakeForTesting(true); int fd = resNetworkQuery(TEST_NETID, kHelloExampleCom, ns_c_in, ns_t_aaaa, ANDROID_RESOLV_NO_CACHE_LOOKUP); expectAnswersValid(fd, AF_INET6, kHelloExampleComAddrV6); EXPECT_EQ(dot1.acceptConnectionsCount(), 1); EXPECT_EQ(dot2.acceptConnectionsCount(), canQuickFallback ? 0 : 1); EXPECT_TRUE(dot2.waitForQueries(canQuickFallback ? 0 : 1)); dot1.setHangOnHandshakeForTesting(false); } } TEST_F(ResolverTest, FlushNetworkCache) { SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.resolvService(), 4); test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); const hostent* result = gethostbyname("hello"); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, kHelloExampleCom)); std::function HasTheExpectedResult = [result]() -> bool { if (result == nullptr) return false; EXPECT_EQ(4, result->h_length); if (result->h_addr_list[0] == nullptr) return false; EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); return true; }; ASSERT_TRUE(HasTheExpectedResult()); // get result from cache result = gethostbyname("hello"); EXPECT_EQ(1U, GetNumQueriesForType(dns, ns_type::ns_t_a, kHelloExampleCom)); ASSERT_TRUE(HasTheExpectedResult()); EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); result = gethostbyname("hello"); EXPECT_EQ(2U, GetNumQueriesForType(dns, ns_type::ns_t_a, kHelloExampleCom)); ASSERT_TRUE(HasTheExpectedResult()); } TEST_F(ResolverTest, FlushNetworkCache_random) { SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.resolvService(), 4); constexpr int num_flush = 10; constexpr int num_queries = 20; test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); const addrinfo hints = {.ai_family = AF_INET}; std::thread t([this]() { for (int i = 0; i < num_flush; ++i) { unsigned delay = arc4random_uniform(10 * 1000); // 10ms usleep(delay); EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } }); for (int i = 0; i < num_queries; ++i) { ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); } t.join(); } // flush cache while one query is wait-for-response, another is pending. TEST_F(ResolverTest, FlushNetworkCache_concurrent) { SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.resolvService(), 4); const char* listen_addr1 = "127.0.0.9"; const char* listen_addr2 = "127.0.0.10"; test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); StartDns(dns2, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); addrinfo hints = {.ai_family = AF_INET}; // step 1: set server#1 into deferred responding mode dns1.setDeferredResp(true); std::thread t1([&listen_addr1, &hints, this]() { ASSERT_TRUE(mDnsClient.SetResolversForNetwork({listen_addr1})); // step 3: query ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); // step 9: check result EXPECT_TRUE(result != nullptr); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); }); // step 2: wait for the query to reach the server while (GetNumQueries(dns1, kHelloExampleCom) == 0) { usleep(1000); // 1ms } std::thread t2([&listen_addr2, &hints, &dns2, this]() { ASSERT_TRUE(mDnsClient.SetResolversForNetwork({listen_addr2})); // step 5: query (should be blocked in resolver) ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); // step 7: check result EXPECT_TRUE(result != nullptr); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); EXPECT_EQ(1U, GetNumQueriesForType(dns2, ns_type::ns_t_a, kHelloExampleCom)); }); // step 4: wait a bit for the 2nd query to enter pending state usleep(100 * 1000); // 100ms // step 6: flush cache (will unblock pending queries) EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); t2.join(); // step 8: resume server#1 dns1.setDeferredResp(false); t1.join(); // step 10: verify if result is correctly cached dns2.clearQueries(); ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); EXPECT_EQ(0U, GetNumQueries(dns2, kHelloExampleCom)); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); } // TODO: Perhaps to have a boundary conditions test for TCP and UDP. TEST_F(ResolverTest, TcpQueryWithOversizePayload) { test::DNSResponder dns; StartDns(dns, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); int fd = dns_open_proxy(); ASSERT_TRUE(fd > 0); // Sending DNS query over TCP once the packet sizes exceed 512 bytes. // The raw data is combined with Question section and Additional section // Question section : query "hello.example.com", type A, class IN // Additional section : type OPT (41), Option PADDING, Option Length 546 // Padding option which allows DNS clients and servers to artificially // increase the size of a DNS message by a variable number of bytes. // See also RFC7830, section 3 const std::string query = "+c0BAAABAAAAAAABBWhlbGxvB2V4YW1wbGUDY29tAAABAAEAACkgAAAAgAACJgAMAiIAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA="; const std::string cmd = "resnsend " + std::to_string(TEST_NETID) + " 0 " /* ResNsendFlags */ + query + '\0'; ssize_t rc = TEMP_FAILURE_RETRY(write(fd, cmd.c_str(), cmd.size())); EXPECT_EQ(rc, static_cast(cmd.size())); expectAnswersValid(fd, AF_INET, kHelloExampleComAddrV4); EXPECT_EQ(1U, GetNumQueriesForProtocol(dns, IPPROTO_TCP, kHelloExampleCom)); EXPECT_EQ(0U, GetNumQueriesForProtocol(dns, IPPROTO_UDP, kHelloExampleCom)); } TEST_F(ResolverTest, TruncatedRspMode) { constexpr char listen_addr[] = "127.0.0.4"; constexpr char listen_addr2[] = "127.0.0.5"; constexpr char listen_srv[] = "53"; test::DNSResponder dns(listen_addr, listen_srv, static_cast(-1)); test::DNSResponder dns2(listen_addr2, listen_srv, static_cast(-1)); // dns supports UDP only, dns2 support UDP and TCP dns.setResponseProbability(0.0, IPPROTO_TCP); StartDns(dns, kLargeCnameChainRecords); StartDns(dns2, kLargeCnameChainRecords); const struct TestConfig { const std::optional tcMode; const bool ret; const unsigned numQueries; std::string asParameters() const { return fmt::format("tcMode: {}, ret: {}, numQueries: {}", tcMode.value_or(-1), ret ? "true" : "false", numQueries); } } testConfigs[]{ // clang-format off {std::nullopt, true, 0}, /* mode unset */ {aidl::android::net::IDnsResolver::TC_MODE_DEFAULT, true, 0}, /* default mode */ {-666, false, 0}, /* invalid input */ {aidl::android::net::IDnsResolver::TC_MODE_UDP_TCP, true, 1}, /* alternative mode */ // clang-format on }; for (const auto& config : testConfigs) { SCOPED_TRACE(config.asParameters()); ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {listen_addr, listen_addr2}; ResolverOptionsParcel resolverOptions; if (config.tcMode.has_value()) resolverOptions.tcMode = config.tcMode.value(); if (!mIsResolverOptionIPCSupported) { parcel.resolverOptions = resolverOptions; ASSERT_EQ(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk(), config.ret); } else { ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk()); } if (mIsResolverOptionIPCSupported) { ASSERT_EQ(mDnsClient.resolvService() ->setResolverOptions(parcel.netId, resolverOptions) .isOk(), config.ret); } const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); ASSERT_TRUE(result != nullptr); EXPECT_EQ(ToString(result), kHelloExampleComAddrV4); // TC_MODE_DEFAULT: resolver retries on TCP-only on each name server. // TC_MODE_UDP_TCP: resolver retries on TCP on the same server, falls back to UDP from next. ASSERT_EQ(GetNumQueriesForProtocol(dns, IPPROTO_UDP, kHelloExampleCom), 1U); ASSERT_EQ(GetNumQueriesForProtocol(dns, IPPROTO_TCP, kHelloExampleCom), 1U); ASSERT_EQ(GetNumQueriesForProtocol(dns2, IPPROTO_UDP, kHelloExampleCom), config.numQueries); ASSERT_EQ(GetNumQueriesForProtocol(dns2, IPPROTO_TCP, kHelloExampleCom), 1U); dns.clearQueries(); dns2.clearQueries(); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); // Clear the stats to make the resolver always choose the same server for the first query. parcel.servers.clear(); parcel.tlsServers.clear(); if (!mIsResolverOptionIPCSupported) { ASSERT_EQ(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk(), config.ret); } else { ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk()); } } } TEST_F(ResolverTest, RepeatedSetup_ResolverStatusRemains) { constexpr char unusable_listen_addr[] = "127.0.0.3"; constexpr char listen_addr[] = "127.0.0.4"; constexpr char hostname[] = "a.hello.query."; const auto repeatedSetResolversFromParcel = [&](const ResolverParamsParcel& parcel) { ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); }; test::DNSResponder dns(listen_addr); StartDns(dns, {{hostname, ns_type::ns_t_a, "1.2.3.3"}}); test::DnsTlsFrontend tls1(listen_addr, "853", listen_addr, "53"); ASSERT_TRUE(tls1.startServer()); // Private DNS off mode. ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {unusable_listen_addr, listen_addr}; parcel.tlsServers.clear(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); // Send a query. const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; EXPECT_NE(safe_getaddrinfo(hostname, nullptr, &hints), nullptr); // Check the stats as expected. const std::vector expectedCleartextDnsStats = { NameserverStats(unusable_listen_addr).setInternalErrors(1), NameserverStats(listen_addr).setSuccesses(1).setRttAvg(1), }; EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); EXPECT_EQ(GetNumQueries(dns, hostname), 1U); // The stats is supposed to remain as long as the list of cleartext DNS servers is unchanged. static const struct TestConfig { std::vector servers; std::vector tlsServers; std::string tlsName; } testConfigs[] = { // Private DNS opportunistic mode. {{listen_addr, unusable_listen_addr}, {listen_addr, unusable_listen_addr}, ""}, {{unusable_listen_addr, listen_addr}, {unusable_listen_addr, listen_addr}, ""}, // Private DNS strict mode. {{listen_addr, unusable_listen_addr}, {"127.0.0.100"}, kDefaultPrivateDnsHostName}, {{unusable_listen_addr, listen_addr}, {"127.0.0.100"}, kDefaultPrivateDnsHostName}, // Private DNS off mode. {{unusable_listen_addr, listen_addr}, {}, ""}, {{listen_addr, unusable_listen_addr}, {}, ""}, }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}] [{}] [{}]", fmt::join(config.servers, ","), fmt::join(config.tlsServers, ","), config.tlsName)); parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = config.servers; parcel.tlsServers = config.tlsServers; parcel.tlsName = config.tlsName; repeatedSetResolversFromParcel(parcel); EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); // The stats remains when the list of search domains changes. parcel.domains.push_back("tmp.domains"); repeatedSetResolversFromParcel(parcel); EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); // The stats remains when the parameters change (except maxSamples). parcel.sampleValiditySeconds++; parcel.successThreshold++; parcel.minSamples++; parcel.baseTimeoutMsec++; parcel.retryCount++; repeatedSetResolversFromParcel(parcel); EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); } // The cache remains. EXPECT_NE(safe_getaddrinfo(hostname, nullptr, &hints), nullptr); EXPECT_EQ(GetNumQueries(dns, hostname), 1U); } TEST_F(ResolverTest, RepeatedSetup_NoRedundantPrivateDnsValidation) { const std::string addr1 = getUniqueIPv4Address(); // For a workable DNS server. const std::string addr2 = getUniqueIPv4Address(); // For an unresponsive DNS server. const std::string unusable_addr = getUniqueIPv4Address(); const auto waitForPrivateDnsStateUpdated = []() { // A buffer time for the PrivateDnsConfiguration instance to update its map, // mPrivateDnsValidateThreads, which is used for tracking validation threads. // Since there is a time gap between when PrivateDnsConfiguration reports // onPrivateDnsValidationEvent and when PrivateDnsConfiguration updates the map, this is a // workaround to avoid the test starts a subsequent resolver setup during the time gap. // TODO: Report onPrivateDnsValidationEvent after all the relevant updates are complete. // Reference to b/152009023. std::this_thread::sleep_for(20ms); }; test::DNSResponder dns1(addr1); test::DNSResponder dns2(addr2); StartDns(dns1, {}); StartDns(dns2, {}); test::DnsTlsFrontend workableTls(addr1, "853", addr1, "53"); test::DnsTlsFrontend unresponsiveTls(addr2, "853", addr2, "53"); unresponsiveTls.setHangOnHandshakeForTesting(true); ASSERT_TRUE(workableTls.startServer()); ASSERT_TRUE(unresponsiveTls.startServer()); // First setup. ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr1, addr2, unusable_addr}; parcel.tlsServers = {addr1, addr2, unusable_addr}; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); // Check the validation status before proceed. The validation for `unresponsiveTls` // should be running, and the other two should be finished. EXPECT_TRUE(WaitForPrivateDnsValidation(workableTls.listen_address(), true)); EXPECT_TRUE(WaitForPrivateDnsValidation(unusable_addr, false)); EXPECT_TRUE(PollForCondition([&]() { return unresponsiveTls.acceptConnectionsCount() == 1; })); unresponsiveTls.clearConnectionsCount(); static const struct TestConfig { std::vector tlsServers; std::string tlsName; } testConfigs[] = { {{addr1, addr2, unusable_addr}, ""}, {{unusable_addr, addr1, addr2}, ""}, {{unusable_addr, addr1, addr2}, kDefaultPrivateDnsHostName}, {{addr1, addr2, unusable_addr}, kDefaultPrivateDnsHostName}, }; std::string TlsNameLastTime; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("testConfig: [{}] [{}]", fmt::join(config.tlsServers, ","), config.tlsName)); parcel.servers = config.tlsServers; parcel.tlsServers = config.tlsServers; parcel.tlsName = config.tlsName; parcel.caCertificate = config.tlsName.empty() ? "" : kCaCert; const bool dnsModeChanged = (TlsNameLastTime != config.tlsName); bool validationAttemptToUnresponsiveTls = false; waitForPrivateDnsStateUpdated(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); for (const auto& serverAddr : parcel.tlsServers) { SCOPED_TRACE(serverAddr); if (serverAddr == workableTls.listen_address()) { if (dnsModeChanged) { // Despite the identical IP address, the server is regarded as a different // server when DnsTlsServer.name is different. The resolver treats it as a // different object and begins the validation process. EXPECT_TRUE(WaitForPrivateDnsValidation(serverAddr, true)); } } else if (serverAddr == unresponsiveTls.listen_address()) { if (dnsModeChanged) { // Despite the identical IP address, the server is regarded as a different // server when DnsTlsServer.name is different. The resolver treats it as a // different object and begins the validation process. validationAttemptToUnresponsiveTls = true; // This is the limitation from DnsTlsFrontend. DnsTlsFrontend can't operate // concurrently. As soon as there's another connection request, // DnsTlsFrontend resets the unique_fd to the new connection. EXPECT_TRUE(WaitForPrivateDnsValidation(serverAddr, false)); } } else { // Must be unusable_addr. // In opportunistic mode, when a validation for a private DNS server fails, the // resolver just marks the server as failed and doesn't re-evaluate it, but the // server can be re-evaluated when setResolverConfiguration() is called. // However, in strict mode, the resolver automatically re-evaluates the server and // marks the server as in_progress until the validation succeeds, so repeated setup // makes no effect. if (dnsModeChanged || config.tlsName.empty() /* not in strict mode */) { EXPECT_TRUE(WaitForPrivateDnsValidation(serverAddr, false)); } } } // Repeated setups make no effect in strict mode. waitForPrivateDnsStateUpdated(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); if (config.tlsName.empty()) { EXPECT_TRUE(WaitForPrivateDnsValidation(unusable_addr, false)); } waitForPrivateDnsStateUpdated(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); if (config.tlsName.empty()) { EXPECT_TRUE(WaitForPrivateDnsValidation(unusable_addr, false)); } if (validationAttemptToUnresponsiveTls) { EXPECT_TRUE(PollForCondition( [&]() { return unresponsiveTls.acceptConnectionsCount() > 0; })); } else { EXPECT_EQ(unresponsiveTls.acceptConnectionsCount(), 0); } TlsNameLastTime = config.tlsName; unresponsiveTls.clearConnectionsCount(); } // Check that all the validation results are caught. // Note: it doesn't mean no validation being in progress. EXPECT_FALSE(hasUncaughtPrivateDnsValidation(addr1)); EXPECT_FALSE(hasUncaughtPrivateDnsValidation(addr2)); EXPECT_FALSE(hasUncaughtPrivateDnsValidation(unusable_addr)); } TEST_F(ResolverTest, RepeatedSetup_KeepChangingPrivateDnsServers) { enum TlsServerState { WORKING, UNSUPPORTED, UNRESPONSIVE }; const std::string addr1 = getUniqueIPv4Address(); const std::string addr2 = getUniqueIPv4Address(); const auto waitForPrivateDnsStateUpdated = []() { // A buffer time for PrivateDnsConfiguration to update its state. It prevents this test // being flaky. See b/152009023 for the reason. std::this_thread::sleep_for(20ms); }; test::DNSResponder dns1(addr1); test::DNSResponder dns2(addr2); StartDns(dns1, {}); StartDns(dns2, {}); test::DnsTlsFrontend tls1(addr1, "853", addr1, "53"); test::DnsTlsFrontend tls2(addr2, "853", addr2, "53"); ASSERT_TRUE(tls1.startServer()); ASSERT_TRUE(tls2.startServer()); static const struct TestConfig { std::string tlsServer; std::string tlsName; bool expectNothingHappenWhenServerUnsupported; bool expectNothingHappenWhenServerUnresponsive; std::string asTestName() const { return fmt::format("{}, {}, {}, {}", tlsServer, tlsName, expectNothingHappenWhenServerUnsupported, expectNothingHappenWhenServerUnresponsive); } } testConfigs[] = { {{addr1}, "", false, false}, {{addr2}, "", false, false}, {{addr1}, "", false, true}, {{addr2}, "", false, true}, // expectNothingHappenWhenServerUnresponsive is false in the two cases because of the // limitation from DnsTlsFrontend which can't operate concurrently. {{addr1}, kDefaultPrivateDnsHostName, false, false}, {{addr2}, kDefaultPrivateDnsHostName, false, false}, {{addr1}, kDefaultPrivateDnsHostName, true, true}, {{addr2}, kDefaultPrivateDnsHostName, true, true}, // expectNothingHappenWhenServerUnresponsive is true in the two cases because of the // limitation from DnsTlsFrontend which can't operate concurrently. {{addr1}, "", true, false}, {{addr2}, "", true, false}, {{addr1}, "", true, true}, {{addr2}, "", true, true}, }; for (const auto& serverState : {WORKING, UNSUPPORTED, UNRESPONSIVE}) { int testIndex = 0; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("serverState:{} testIndex:{} testConfig:[{}]", static_cast(serverState), testIndex++, config.asTestName())); auto& tls = (config.tlsServer == addr1) ? tls1 : tls2; if (serverState == UNSUPPORTED && tls.running()) ASSERT_TRUE(tls.stopServer()); if (serverState != UNSUPPORTED && !tls.running()) ASSERT_TRUE(tls.startServer()); tls.setHangOnHandshakeForTesting(serverState == UNRESPONSIVE); const int connectCountsBefore = tls.acceptConnectionsCount(); waitForPrivateDnsStateUpdated(); ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {config.tlsServer}; parcel.tlsServers = {config.tlsServer}; parcel.tlsName = config.tlsName; parcel.caCertificate = config.tlsName.empty() ? "" : kCaCert; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); if (serverState == WORKING) { EXPECT_TRUE(WaitForPrivateDnsValidation(config.tlsServer, true)); } else if (serverState == UNSUPPORTED) { if (config.expectNothingHappenWhenServerUnsupported) { // It's possible that the resolver hasn't yet started to // connect. Wait a while. // TODO: See if we can get rid of the hard waiting time, such as comparing // the CountDiff across two tests. std::this_thread::sleep_for(100ms); EXPECT_EQ(tls.acceptConnectionsCount(), connectCountsBefore); } else { EXPECT_TRUE(WaitForPrivateDnsValidation(config.tlsServer, false)); } } else { // Must be UNRESPONSIVE. // DnsTlsFrontend is the only signal for checking whether or not the resolver starts // another validation when the server is unresponsive. // Wait for a while to avoid running the checker code too early. std::this_thread::sleep_for(200ms); if (!config.expectNothingHappenWhenServerUnresponsive) { EXPECT_TRUE(WaitForPrivateDnsValidation(config.tlsServer, false)); } const auto condition = [&]() { const int connectCountsAfter = tls.acceptConnectionsCount(); return config.expectNothingHappenWhenServerUnresponsive ? (connectCountsAfter == connectCountsBefore) : (connectCountsAfter > connectCountsBefore); }; EXPECT_TRUE(PollForCondition(condition)); } } // Set to off mode to reset the PrivateDnsConfiguration state. ResolverParamsParcel setupOffmode = DnsResponderClient::GetDefaultResolverParamsParcel(); setupOffmode.tlsServers.clear(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupOffmode)); } // Check that all the validation results are caught. // Note: it doesn't mean no validation being in progress. EXPECT_FALSE(hasUncaughtPrivateDnsValidation(addr1)); EXPECT_FALSE(hasUncaughtPrivateDnsValidation(addr2)); } TEST_F(ResolverTest, PermissionCheckOnCertificateInjection) { ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.caCertificate = kCaCert; ASSERT_TRUE(mDnsClient.resolvService()->setResolverConfiguration(parcel).isOk()); for (const uid_t uid : {AID_SYSTEM, TEST_UID}) { ScopedChangeUID scopedChangeUID(uid); auto status = mDnsClient.resolvService()->setResolverConfiguration(parcel); EXPECT_EQ(status.getExceptionCode(), EX_SECURITY); } } // Parameterized tests. // TODO: Merge the existing tests as parameterized test if possible. // TODO: Perhaps move parameterized tests to an independent file. enum class CallType { GETADDRINFO, GETHOSTBYNAME }; class ResolverParameterizedTest : public ResolverTest, public testing::WithParamInterface { protected: void VerifyQueryHelloExampleComV4(const test::DNSResponder& dns, const CallType calltype, const bool verifyNumQueries = true) { if (calltype == CallType::GETADDRINFO) { const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello", nullptr, &hints); ASSERT_TRUE(result != nullptr); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); } else if (calltype == CallType::GETHOSTBYNAME) { const hostent* result = gethostbyname("hello"); ASSERT_TRUE(result != nullptr); ASSERT_EQ(4, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(kHelloExampleComAddrV4, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } else { FAIL() << "Unsupported call type: " << static_cast(calltype); } if (verifyNumQueries) EXPECT_EQ(1U, GetNumQueries(dns, kHelloExampleCom)); } }; INSTANTIATE_TEST_SUITE_P(QueryCallTest, ResolverParameterizedTest, testing::Values(CallType::GETADDRINFO, CallType::GETHOSTBYNAME), [](const testing::TestParamInfo& info) { switch (info.param) { case CallType::GETADDRINFO: return "GetAddrInfo"; case CallType::GETHOSTBYNAME: return "GetHostByName"; default: return "InvalidParameter"; // Should not happen. } }); TEST_P(ResolverParameterizedTest, AuthoritySectionAndAdditionalSection) { // DNS response may have more information in authority section and additional section. // Currently, getanswer() of packages/modules/DnsResolver/getaddrinfo.cpp doesn't parse the // content of authority section and additional section. Test these sections if they crash // the resolver, just in case. See also RFC 1035 section 4.1. const auto& calltype = GetParam(); test::DNSHeader header(kDefaultDnsHeader); // Create a DNS response which has a authoritative nameserver record in authority // section and its relevant address record in additional section. // // Question // hello.example.com. IN A // Answer // hello.example.com. IN A 1.2.3.4 // Authority: // hello.example.com. IN NS ns1.example.com. // Additional: // ns1.example.com. IN A 5.6.7.8 // // A response may have only question, answer, and authority section. Current testing response // should be able to cover this condition. // Question section. test::DNSQuestion question{ .qname = {.name = kHelloExampleCom}, .qtype = ns_type::ns_t_a, .qclass = ns_c_in, }; header.questions.push_back(std::move(question)); // Answer section. test::DNSRecord recordAnswer{ .name = {.name = kHelloExampleCom}, .rtype = ns_type::ns_t_a, .rclass = ns_c_in, .ttl = 0, // no cache }; EXPECT_TRUE(test::DNSResponder::fillRdata(kHelloExampleComAddrV4, recordAnswer)); header.answers.push_back(std::move(recordAnswer)); // Authority section. test::DNSRecord recordAuthority{ .name = {.name = kHelloExampleCom}, .rtype = ns_type::ns_t_ns, .rclass = ns_c_in, .ttl = 0, // no cache }; EXPECT_TRUE(test::DNSResponder::fillRdata("ns1.example.com.", recordAuthority)); header.authorities.push_back(std::move(recordAuthority)); // Additional section. test::DNSRecord recordAdditional{ .name = {.name = "ns1.example.com."}, .rtype = ns_type::ns_t_a, .rclass = ns_c_in, .ttl = 0, // no cache }; EXPECT_TRUE(test::DNSResponder::fillRdata("5.6.7.8", recordAdditional)); header.additionals.push_back(std::move(recordAdditional)); // Start DNS server. test::DNSResponder dns(test::DNSResponder::MappingType::DNS_HEADER); dns.addMappingDnsHeader(kHelloExampleCom, ns_type::ns_t_a, header); ASSERT_TRUE(dns.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); dns.clearQueries(); // Expect that get the address and the resolver doesn't crash. VerifyQueryHelloExampleComV4(dns, calltype); } TEST_P(ResolverParameterizedTest, MessageCompression) { const auto& calltype = GetParam(); // The response with compressed domain name by a pointer. See RFC 1035 section 4.1.4. // // Ignoring the other fields of the message, the domain name of question section and answer // section are presented as: // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 12 | 5 | h | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 14 | e | l | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 16 | l | o | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 18 | 7 | e | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 20 | x | a | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 22 | m | p | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 24 | l | e | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 26 | 3 | c | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 28 | o | m | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 30 | 0 | ... | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 35 | 1 1| 12 | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ const std::vector kResponseAPointer = { /* Header */ 0x00, 0x00, /* Transaction ID: 0x0000 */ 0x81, 0x80, /* Flags: qr rd ra */ 0x00, 0x01, /* Questions: 1 */ 0x00, 0x01, /* Answer RRs: 1 */ 0x00, 0x00, /* Authority RRs: 0 */ 0x00, 0x00, /* Additional RRs: 0 */ /* Queries */ 0x05, 0x68, 0x65, 0x6c, 0x6c, 0x6f, 0x07, 0x65, 0x78, 0x61, 0x6d, 0x70, 0x6c, 0x65, 0x03, 0x63, 0x6f, 0x6d, 0x00, /* Name: hello.example.com */ 0x00, 0x01, /* Type: A */ 0x00, 0x01, /* Class: IN */ /* Answers */ 0xc0, 0x0c, /* Name: hello.example.com (a pointer) */ 0x00, 0x01, /* Type: A */ 0x00, 0x01, /* Class: IN */ 0x00, 0x00, 0x00, 0x00, /* Time to live: 0 */ 0x00, 0x04, /* Data length: 4 */ 0x01, 0x02, 0x03, 0x04 /* Address: 1.2.3.4 */ }; // The response with compressed domain name by a sequence of labels ending with a pointer. See // RFC 1035 section 4.1.4. // // Ignoring the other fields of the message, the domain name of question section and answer // section are presented as: // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 12 | 5 | h | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 14 | e | l | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 16 | l | o | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 18 | 7 | e | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 20 | x | a | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 22 | m | p | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 24 | l | e | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 26 | 3 | c | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 28 | o | m | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 30 | 0 | ... | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 35 | 5 | h | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 37 | e | l | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 39 | l | o | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ // 41 | 1 1| 18 | // +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ const std::vector kResponseLabelEndingWithAPointer = { /* Header */ 0x00, 0x00, /* Transaction ID: 0x0000 */ 0x81, 0x80, /* Flags: qr rd ra */ 0x00, 0x01, /* Questions: 1 */ 0x00, 0x01, /* Answer RRs: 1 */ 0x00, 0x00, /* Authority RRs: 0 */ 0x00, 0x00, /* Additional RRs: 0 */ /* Queries */ 0x05, 0x68, 0x65, 0x6c, 0x6c, 0x6f, 0x07, 0x65, 0x78, 0x61, 0x6d, 0x70, 0x6c, 0x65, 0x03, 0x63, 0x6f, 0x6d, 0x00, /* Name: hello.example.com */ 0x00, 0x01, /* Type: A */ 0x00, 0x01, /* Class: IN */ /* Answers */ 0x05, 0x68, 0x65, 0x6c, 0x6c, 0x6f, 0xc0, 0x12, /* Name: hello.example.com (a label ending with a pointer) */ 0x00, 0x01, /* Type: A */ 0x00, 0x01, /* Class: IN */ 0x00, 0x00, 0x00, 0x00, /* Time to live: 0 */ 0x00, 0x04, /* Data length: 4 */ 0x01, 0x02, 0x03, 0x04 /* Address: 1.2.3.4 */ }; for (const auto& response : {kResponseAPointer, kResponseLabelEndingWithAPointer}) { SCOPED_TRACE(fmt::format("Hex dump: {}", toHex(makeSlice(response)))); test::DNSResponder dns(test::DNSResponder::MappingType::BINARY_PACKET); dns.addMappingBinaryPacket(kHelloExampleComQueryV4, response); StartDns(dns, {}); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // Expect no cache because the TTL of testing responses are 0. VerifyQueryHelloExampleComV4(dns, calltype); } } TEST_P(ResolverParameterizedTest, TruncatedResponse) { const auto& calltype = GetParam(); test::DNSResponder dns; StartDns(dns, kLargeCnameChainRecords); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // Expect UDP response is truncated. The resolver retries over TCP. See RFC 1035 section 4.2.1. VerifyQueryHelloExampleComV4(dns, calltype, false); EXPECT_EQ(1U, GetNumQueriesForProtocol(dns, IPPROTO_UDP, kHelloExampleCom)); EXPECT_EQ(1U, GetNumQueriesForProtocol(dns, IPPROTO_TCP, kHelloExampleCom)); } // Tests that the DnsResolver can keep listening to the DNS response from previous DNS servers. // Test scenarios (The timeout for each server is 1 second): // 1. (During the first iteration of DNS servers) While waiting for the DNS response from the // second server, the DnsResolver receives the DNS response from the first server. // 2. (During the second iteration of DNS servers) While waiting for the DNS response from the // second server, the DnsResolver receives the DNS response from the first server. TEST_F(ResolverTest, KeepListeningUDP) { constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "127.0.0.5"; constexpr char host_name[] = "howdy.example.com."; const std::vector records = { {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; auto builder = ResolverParams::Builder().setDnsServers({listen_addr1, listen_addr2}).setDotServers({}); test::DNSResponder neverRespondDns(listen_addr2, "53", static_cast(-1)); neverRespondDns.setResponseProbability(0.0); StartDns(neverRespondDns, records); test::DNSResponder delayedDns(listen_addr1); StartDns(delayedDns, records); const struct TestConfig { int retryCount; int delayTimeMs; int expectedDns1Successes; int expectedDns1Timeouts; int expectedDns2Timeouts; } testConfigs[]{ {1, 1500, 1, 1, 0}, // Actually, there will be two timeouts and one success for DNS1. However, the // DnsResolver doesn't record the stats during the second iteration of DNS servers, so // the success and timeout of DNS1 is 0 and 1, respectively. {2, 3500, 0, 1, 1}, }; for (const std::string_view callType : {"getaddrinfo", "resnsend"}) { for (const auto& cfg : testConfigs) { SCOPED_TRACE(fmt::format("callType={}, retryCount={}, delayTimeMs={}", callType, cfg.retryCount, cfg.delayTimeMs)); const std::array params = { 300, 25, 8, 8, 1000 /* BASE_TIMEOUT_MSEC */, cfg.retryCount /* retry count */}; ScopedSystemProperties sp(kKeepListeningUdpFlag, "1"); resetNetwork(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(builder.setParams(params).build())); delayedDns.setDeferredResp(true); std::thread thread([&]() { std::this_thread::sleep_for(std::chrono::milliseconds(cfg.delayTimeMs)); delayedDns.setDeferredResp(false); }); if (callType == "getaddrinfo") { const addrinfo hints = {.ai_family = AF_INET6, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo(host_name, nullptr, &hints); EXPECT_EQ("::1.2.3.4", ToString(result)); } else { int fd = resNetworkQuery(TEST_NETID, host_name, ns_c_in, ns_t_aaaa, 0); expectAnswersValid(fd, AF_INET6, "::1.2.3.4"); } const std::vector expectedCleartextDnsStats = { NameserverStats(listen_addr1) .setSuccesses(cfg.expectedDns1Successes) .setTimeouts(cfg.expectedDns1Timeouts) .setRttAvg(cfg.retryCount == 1 ? 1500 : -1), NameserverStats(listen_addr2) .setTimeouts(cfg.expectedDns2Timeouts) .setRttAvg(-1), }; EXPECT_TRUE(expectStatsEqualTo(expectedCleartextDnsStats)); thread.join(); } } } TEST_F(ResolverTest, GetAddrInfoParallelLookupTimeout) { constexpr char host_name[] = "howdy.example.com."; constexpr int TIMING_TOLERANCE_MS = 200; constexpr int DNS_TIMEOUT_MS = 1000; const std::vector records = { {host_name, ns_type::ns_t_a, "1.2.3.4"}, {host_name, ns_type::ns_t_aaaa, "::1.2.3.4"}, }; const std::array params = { 300, 25, 8, 8, DNS_TIMEOUT_MS /* BASE_TIMEOUT_MSEC */, 1 /* retry count */}; test::DNSResponder neverRespondDns(kDefaultServer, "53", static_cast(-1)); neverRespondDns.setResponseProbability(0.0); StartDns(neverRespondDns, records); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder().setDotServers({}).setParams(params).build())); neverRespondDns.clearQueries(); // Use a never respond DNS server to verify if the A/AAAA queries are sent in parallel. // The resolver parameters are set to timeout 1s and retry 1 times. // So we expect the safe_getaddrinfo_time_taken() might take ~1s to // return when parallel lookup is enabled. And the DNS server should receive 2 queries. const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; auto [result, timeTakenMs] = safe_getaddrinfo_time_taken(host_name, nullptr, hints); EXPECT_TRUE(result == nullptr); EXPECT_NEAR(DNS_TIMEOUT_MS, timeTakenMs, TIMING_TOLERANCE_MS) << "took time should approximate equal timeout"; EXPECT_EQ(2U, GetNumQueries(neverRespondDns, host_name)); ExpectDnsEvent(INetdEventListener::EVENT_GETADDRINFO, RCODE_TIMEOUT, host_name, {}); } TEST_F(ResolverTest, GetAddrInfoParallelLookupSleepTime) { constexpr int TIMING_TOLERANCE_MS = 200; const std::vector records = { {kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}, {kHelloExampleCom, ns_type::ns_t_aaaa, kHelloExampleComAddrV6}, }; const std::array params = { 300, 25, 8, 8, 1000 /* BASE_TIMEOUT_MSEC */, 1 /* retry count */}; test::DNSResponder dns(kDefaultServer); StartDns(dns, records); constexpr int PARALLEL_LOOKUP_SLEEP_TIME_MS = 500; ScopedSystemProperties sp2(kParallelLookupSleepTimeFlag, std::to_string(PARALLEL_LOOKUP_SLEEP_TIME_MS)); // Re-setup test network to make experiment flag take effect. resetNetwork(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel( ResolverParams::Builder().setDotServers({}).setParams(params).build())); dns.clearQueries(); // Expect the safe_getaddrinfo_time_taken() might take ~500ms to return because we set // parallel_lookup_sleep_time to 500ms. const addrinfo hints = {.ai_family = AF_UNSPEC, .ai_socktype = SOCK_DGRAM}; auto [result, timeTakenMs] = safe_getaddrinfo_time_taken(kHelloExampleCom, nullptr, hints); EXPECT_NE(nullptr, result); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray( {kHelloExampleComAddrV4, kHelloExampleComAddrV6})); EXPECT_NEAR(PARALLEL_LOOKUP_SLEEP_TIME_MS, timeTakenMs, TIMING_TOLERANCE_MS) << "took time should approximate equal timeout"; EXPECT_EQ(2U, GetNumQueries(dns, kHelloExampleCom)); // Expect the PARALLEL_LOOKUP_SLEEP_TIME_MS won't affect the query under cache hit case. dns.clearQueries(); std::tie(result, timeTakenMs) = safe_getaddrinfo_time_taken(kHelloExampleCom, nullptr, hints); EXPECT_NE(nullptr, result); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray( {kHelloExampleComAddrV4, kHelloExampleComAddrV6})); EXPECT_GT(PARALLEL_LOOKUP_SLEEP_TIME_MS, timeTakenMs); EXPECT_EQ(0U, GetNumQueries(dns, kHelloExampleCom)); } TEST_F(ResolverTest, BlockDnsQueryUidDoesNotLeadToBadServer) { SKIP_IF_BPF_NOT_SUPPORTED; constexpr char listen_addr1[] = "127.0.0.4"; constexpr char listen_addr2[] = "::1"; test::DNSResponder dns1(listen_addr1); test::DNSResponder dns2(listen_addr2); StartDns(dns1, {}); StartDns(dns2, {}); std::vector servers = {listen_addr1, listen_addr2}; ASSERT_TRUE(mDnsClient.SetResolversForNetwork(servers)); dns1.clearQueries(); dns2.clearQueries(); { ScopeBlockedUIDRule scopeBlockUidRule(mDnsClient.netdService(), TEST_UID); // Start querying ten times. for (int i = 0; i < 10; i++) { std::string hostName = fmt::format("blocked{}.com", i); const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; // The query result between R+ and Q would be different, but we don't really care // about the result here because this test is only used to ensure blocked uid rule // won't cause bad servers. safe_getaddrinfo(hostName.c_str(), nullptr, &hints); } } ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); // If api level >= 30 (R+), expect all query packets to be blocked, hence we should not see any // of their stats show up. Otherwise, all queries should succeed. const std::vector expectedDnsStats = { NameserverStats(listen_addr1).setSuccesses(0).setRttAvg(-1), NameserverStats(listen_addr2), }; expectStatsEqualTo(expectedDnsStats); // If api level >= 30 (R+), expect server won't receive any queries, // otherwise expect 20 == 10 * (setupParams.domains.size() + 1) queries. EXPECT_EQ(dns1.queries().size(), 0U); EXPECT_EQ(dns2.queries().size(), 0U); } TEST_F(ResolverTest, DnsServerSelection) { test::DNSResponder dns1("127.0.0.3"); test::DNSResponder dns2("127.0.0.4"); test::DNSResponder dns3("127.0.0.5"); dns1.setResponseDelayMs(10); dns2.setResponseDelayMs(50); dns3.setResponseDelayMs(100); StartDns(dns1, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); StartDns(dns2, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); StartDns(dns3, {{kHelloExampleCom, ns_type::ns_t_a, kHelloExampleComAddrV4}}); // NOTE: the servers must be sorted alphabetically. std::vector serverList = { dns1.listen_address(), dns2.listen_address(), dns3.listen_address(), }; do { SCOPED_TRACE(fmt::format("testConfig: [{}]", fmt::join(serverList, ", "))); const int queryNum = 50; int64_t accumulatedTime = 0; // The flag can be reset any time. It's better to re-setup the flag in each iteration. ScopedSystemProperties scopedSystemProperties(kSortNameserversFlag, "1"); // Restart the testing network to 1) make the flag take effect and 2) reset the statistics. resetNetwork(); // DnsServerSelection doesn't apply to private DNS. ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.servers = serverList; setupParams.tlsServers.clear(); ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); // DNSResponder doesn't handle queries concurrently, so don't allow more than // one in-flight query. for (int i = 0; i < queryNum; i++) { Stopwatch s; int fd = resNetworkQuery(TEST_NETID, kHelloExampleCom, ns_c_in, ns_t_a, ANDROID_RESOLV_NO_CACHE_LOOKUP); expectAnswersValid(fd, AF_INET, kHelloExampleComAddrV4); accumulatedTime += s.timeTakenUs(); } const int dns1Count = dns1.queries().size(); const int dns2Count = dns2.queries().size(); const int dns3Count = dns3.queries().size(); // All of the servers have ever been selected. In addition, the less latency server // is selected more frequently. EXPECT_GT(dns1Count, 0); EXPECT_GT(dns2Count, 0); EXPECT_GT(dns3Count, 0); EXPECT_GE(dns1Count, dns2Count); EXPECT_GE(dns2Count, dns3Count); const int averageTime = accumulatedTime / queryNum; LOG(INFO) << "ResolverTest#DnsServerSelection: averageTime " << averageTime << "us"; dns1.clearQueries(); dns2.clearQueries(); dns3.clearQueries(); } while (std::next_permutation(serverList.begin(), serverList.end())); } TEST_F(ResolverTest, MultipleDotQueriesInOnePacket) { constexpr char hostname1[] = "query1.example.com."; constexpr char hostname2[] = "query2.example.com."; const std::vector records = { {hostname1, ns_type::ns_t_a, "1.2.3.4"}, {hostname2, ns_type::ns_t_a, "1.2.3.5"}, }; const std::string addr = getUniqueIPv4Address(); test::DNSResponder dns(addr); StartDns(dns, records); test::DnsTlsFrontend tls(addr, "853", addr, "53"); ASSERT_TRUE(tls.startServer()); // Set up resolver to strict mode. auto parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.servers = {addr}; parcel.tlsServers = {addr}; parcel.tlsName = kDefaultPrivateDnsHostName; parcel.caCertificate = kCaCert; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(parcel)); EXPECT_TRUE(WaitForPrivateDnsValidation(tls.listen_address(), true)); EXPECT_TRUE(tls.waitForQueries(1)); tls.clearQueries(); dns.clearQueries(); const auto queryAndCheck = [&](const std::string& hostname, const std::vector& records) { SCOPED_TRACE(hostname); const addrinfo hints = {.ai_family = AF_INET, .ai_socktype = SOCK_DGRAM}; auto [result, timeTakenMs] = safe_getaddrinfo_time_taken(hostname.c_str(), nullptr, hints); std::vector expectedAnswers; for (const auto& r : records) { if (r.host_name == hostname) expectedAnswers.push_back(r.addr); } EXPECT_LE(timeTakenMs, 200); ASSERT_NE(result, nullptr); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(expectedAnswers)); }; // Set tls to reply DNS responses in one TCP packet and not to close the connection from its // side. tls.setDelayQueries(2); tls.setDelayQueriesTimeout(500); tls.setPassiveClose(true); // Start sending DNS requests at the same time. std::array threads; threads[0] = std::thread(queryAndCheck, hostname1, records); threads[1] = std::thread(queryAndCheck, hostname2, records); threads[0].join(); threads[1].join(); // Also check no additional queries due to DoT reconnection. EXPECT_TRUE(tls.waitForQueries(2)); } TEST_F(ResolverTest, MdnsGetHostByName) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; constexpr char nonexistent_host_name[] = "nonexistent.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_a, v4addr); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv6.addMapping(host_name, ns_type::ns_t_aaaa, v6addr); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); mdnsv4.clearQueries(); mdnsv6.clearQueries(); std::vector keep_listening_udp_enable = {false, true}; for (int value : keep_listening_udp_enable) { if (value == true) { // Set keep_listening_udp enable ScopedSystemProperties sp(kKeepListeningUdpFlag, "1"); // Re-setup test network to make experiment flag take effect. resetNetwork(); } ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); static const struct TestConfig { int ai_family; const std::string expected_addr; } testConfigs[]{ {AF_INET, v4addr}, {AF_INET6, v6addr}, }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("family: {}", config.ai_family)); const hostent* result = nullptr; // No response for "nonexistent.local". result = gethostbyname2("nonexistent.local", config.ai_family); ASSERT_TRUE(result == nullptr); test::DNSResponder& mdns = config.ai_family == AF_INET ? mdnsv4 : mdnsv6; EXPECT_EQ(1U, GetNumQueries(mdns, nonexistent_host_name)); mdns.clearQueries(); EXPECT_EQ(HOST_NOT_FOUND, h_errno); // Normal mDns query result = gethostbyname2("hello.local", config.ai_family); ASSERT_FALSE(result == nullptr); EXPECT_EQ(1U, GetNumQueries(mdns, host_name)); int length = config.ai_family == AF_INET ? 4 : 16; ASSERT_EQ(length, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(config.expected_addr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); mdns.clearQueries(); // Ensure the query result is still cached. result = gethostbyname2("hello.local", config.ai_family); EXPECT_EQ(0U, GetNumQueries(mdnsv4, "hello.local.")); ASSERT_FALSE(result == nullptr); EXPECT_EQ(config.expected_addr, ToString(result)); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } } namespace { static const struct TransportTypeConfig { const std::vector& transportTypes; bool useMdns; } transportTypeConfig[]{ // clang-format off {{}, true}, {{IDnsResolver::TRANSPORT_CELLULAR}, false}, {{IDnsResolver::TRANSPORT_WIFI}, true}, {{IDnsResolver::TRANSPORT_BLUETOOTH}, true}, {{IDnsResolver::TRANSPORT_ETHERNET}, true}, {{IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_WIFI_AWARE}, true}, {{IDnsResolver::TRANSPORT_LOWPAN}, true}, {{IDnsResolver::TRANSPORT_TEST}, true}, {{IDnsResolver::TRANSPORT_USB}, true}, {{IDnsResolver::TRANSPORT_CELLULAR, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_WIFI, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_BLUETOOTH, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_ETHERNET, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_CELLULAR, IDnsResolver::TRANSPORT_WIFI, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_WIFI_AWARE, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_LOWPAN, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_TEST, IDnsResolver::TRANSPORT_VPN}, false}, {{IDnsResolver::TRANSPORT_USB, IDnsResolver::TRANSPORT_VPN}, false}, // clang-format on }; } // namespace TEST_F(ResolverTest, MdnsGetHostByName_transportTypes) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_a, v4addr); mdnsv6.addMapping(host_name, ns_type::ns_t_aaaa, v6addr); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); const std::vector records = { {host_name, ns_type::ns_t_a, v4addr}, {host_name, ns_type::ns_t_aaaa, v6addr}, }; test::DNSResponder dns(v4addr); StartDns(dns, records); for (const auto& tpConfig : transportTypeConfig) { SCOPED_TRACE(fmt::format("transportTypes: [{}], useMdns: {}", fmt::join(tpConfig.transportTypes, ","), tpConfig.useMdns)); ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.transportTypes = tpConfig.transportTypes; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); static const struct TestConfig { int ai_family; const std::string expected_addr; } testConfigs[]{ {AF_INET, v4addr}, {AF_INET6, v6addr}, }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("family: {}", config.ai_family)); const hostent* result = nullptr; test::DNSResponder& mdns = config.ai_family == AF_INET ? mdnsv4 : mdnsv6; result = gethostbyname2("hello.local", config.ai_family); ASSERT_FALSE(result == nullptr); if (tpConfig.useMdns) { EXPECT_EQ(1U, GetNumQueries(mdns, host_name)); EXPECT_EQ(0U, GetNumQueries(dns, host_name)); } else { EXPECT_EQ(0U, GetNumQueries(mdns, host_name)); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } int length = config.ai_family == AF_INET ? 4 : 16; ASSERT_EQ(length, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(config.expected_addr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); mdns.clearQueries(); dns.clearQueries(); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } } TEST_F(ResolverTest, MdnsGetHostByName_cnames) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; const std::vector records = { {"hi.local.", ns_type::ns_t_cname, "a.local."}, {"a.local.", ns_type::ns_t_cname, "b.local."}, {"b.local.", ns_type::ns_t_cname, "c.local."}, {"c.local.", ns_type::ns_t_cname, "d.local."}, {"d.local.", ns_type::ns_t_cname, "e.local."}, {"e.local.", ns_type::ns_t_cname, host_name}, {host_name, ns_type::ns_t_a, v4addr}, {host_name, ns_type::ns_t_aaaa, v6addr}, }; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); for (const auto& r : records) { mdnsv4.addMapping(r.host_name, r.type, r.addr); } test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); for (const auto& r : records) { mdnsv6.addMapping(r.host_name, r.type, r.addr); } ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); mdnsv4.clearQueries(); mdnsv6.clearQueries(); static const struct TestConfig { int ai_family; const std::string expected_addr; } testConfigs[]{ {AF_INET, v4addr}, {AF_INET6, v6addr}, }; for (const auto& config : testConfigs) { size_t cnamecount = 0; // using gethostbyname2() to resolve ipv4 hello.local. to 127.0.0.3 // or ipv6 hello.local. to ::127.0.0.3. // Ensure the v4 address and cnames are correct const hostent* result; result = gethostbyname2("hi.local", config.ai_family); ASSERT_FALSE(result == nullptr); for (int i = 0; result != nullptr && result->h_aliases[i] != nullptr; i++) { std::string domain_name = records[i].host_name.substr(0, records[i].host_name.size() - 1); EXPECT_EQ(result->h_aliases[i], domain_name); cnamecount++; } // The size of "Non-cname type" record in DNS records is 2 ASSERT_EQ(cnamecount, records.size() - 2); test::DNSResponder& mdns = config.ai_family == AF_INET ? mdnsv4 : mdnsv6; EXPECT_EQ(1U, mdnsv4.queries().size()) << mdns.dumpQueries(); int length = config.ai_family == AF_INET ? 4 : 16; ASSERT_EQ(length, result->h_length); ASSERT_FALSE(result->h_addr_list[0] == nullptr); EXPECT_EQ(config.expected_addr, ToString(result)); EXPECT_TRUE(result->h_addr_list[1] == nullptr); } } TEST_F(ResolverTest, MdnsGetHostByName_cnamesInfiniteLoop) { constexpr char host_name1[] = "hello.local."; constexpr char host_name2[] = "hi.local."; const std::vector records = { {host_name1, ns_type::ns_t_cname, host_name2}, {host_name2, ns_type::ns_t_cname, host_name1}, }; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); for (const auto& r : records) { mdnsv4.addMapping(r.host_name, r.type, r.addr); } for (const auto& r : records) { mdnsv6.addMapping(r.host_name, r.type, r.addr); } ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); mdnsv4.clearQueries(); mdnsv6.clearQueries(); const hostent* result; result = gethostbyname2("hello.local", AF_INET); ASSERT_TRUE(result == nullptr); result = gethostbyname2("hello.local", AF_INET6); ASSERT_TRUE(result == nullptr); } TEST_F(ResolverTest, MdnsGetAddrInfo) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_a, v4addr); mdnsv6.addMapping(host_name, ns_type::ns_t_aaaa, v6addr); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); std::vector keep_listening_udp_enable = {false, true}; for (int value : keep_listening_udp_enable) { if (value == true) { // Set keep_listening_udp enable ScopedSystemProperties sp(kKeepListeningUdpFlag, "1"); // Re-setup test network to make experiment flag take effect. resetNetwork(); } ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); static const struct TestConfig { int ai_family; const std::vector expected_addr; } testConfigs[]{ {AF_INET, {v4addr}}, {AF_INET6, {v6addr}}, {AF_UNSPEC, {v4addr, v6addr}}, }; for (const auto& config : testConfigs) { mdnsv4.clearQueries(); mdnsv6.clearQueries(); addrinfo hints = {.ai_family = config.ai_family, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result != nullptr); if (config.ai_family == AF_INET) { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); mdnsv4.clearQueries(); } else if (config.ai_family == AF_INET6) { EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); mdnsv6.clearQueries(); } else if (config.ai_family == AF_UNSPEC) { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); mdnsv4.clearQueries(); mdnsv6.clearQueries(); } std::string result_str = ToString(result); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.expected_addr)); // Ensure the query results are still cached. result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result != nullptr); if (config.ai_family == AF_INET) EXPECT_EQ(0U, GetNumQueries(mdnsv4, host_name)); else if (config.ai_family == AF_INET6) EXPECT_EQ(0U, GetNumQueries(mdnsv6, host_name)); else if (config.ai_family == AF_UNSPEC) { EXPECT_EQ(0U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(0U, GetNumQueries(mdnsv6, host_name)); } result_str = ToString(result); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.expected_addr)); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } } TEST_F(ResolverTest, MdnsGetAddrInfo_transportTypes) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_a, v4addr); mdnsv6.addMapping(host_name, ns_type::ns_t_aaaa, v6addr); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); const std::vector records = { {host_name, ns_type::ns_t_a, v4addr}, {host_name, ns_type::ns_t_aaaa, v6addr}, }; test::DNSResponder dns(v4addr); StartDns(dns, records); for (const auto& tpConfig : transportTypeConfig) { SCOPED_TRACE(fmt::format("transportTypes: [{}], useMdns: {}", fmt::join(tpConfig.transportTypes, ","), tpConfig.useMdns)); ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.transportTypes = tpConfig.transportTypes; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); static const struct TestConfig { int ai_family; const std::vector expected_addr; } testConfigs[]{ {AF_INET, {v4addr}}, {AF_INET6, {v6addr}}, {AF_UNSPEC, {v4addr, v6addr}}, }; for (const auto& config : testConfigs) { addrinfo hints = {.ai_family = config.ai_family, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result != nullptr); if (tpConfig.useMdns) { if (config.ai_family == AF_INET) { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(0U, GetNumQueries(mdnsv6, host_name)); } else if (config.ai_family == AF_INET6) { EXPECT_EQ(0U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); } else { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); } EXPECT_EQ(0U, GetNumQueries(dns, host_name)); } else { EXPECT_EQ(0U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(0U, GetNumQueries(mdnsv6, host_name)); if (config.ai_family == AF_INET || config.ai_family == AF_INET6) { EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } else { EXPECT_EQ(2U, GetNumQueries(dns, host_name)); } } std::string result_str = ToString(result); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.expected_addr)); mdnsv4.clearQueries(); mdnsv6.clearQueries(); dns.clearQueries(); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } } TEST_F(ResolverTest, MdnsGetAddrInfo_InvalidSocketType) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv6.addMapping(host_name, ns_type::ns_t_aaaa, v6addr); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); // TODO: Test other invalid socket types. const addrinfo hints = { .ai_family = AF_UNSPEC, .ai_socktype = SOCK_PACKET, }; addrinfo* result = nullptr; // This is a valid hint, but the query won't be sent because the socket type is // not supported. EXPECT_EQ(EAI_NODATA, getaddrinfo("howdy.local", nullptr, &hints, &result)); ScopedAddrinfo result_cleanup(result); EXPECT_EQ(nullptr, result); } TEST_F(ResolverTest, MdnsGetAddrInfo_cnames) { constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); const std::vector records = { {"hi.local.", ns_type::ns_t_cname, "a.local."}, {"a.local.", ns_type::ns_t_cname, "b.local."}, {"b.local.", ns_type::ns_t_cname, "c.local."}, {"c.local.", ns_type::ns_t_cname, "d.local."}, {"d.local.", ns_type::ns_t_cname, "e.local."}, {"e.local.", ns_type::ns_t_cname, host_name}, {host_name, ns_type::ns_t_a, v4addr}, {host_name, ns_type::ns_t_aaaa, v6addr}, }; for (const auto& r : records) { mdnsv4.addMapping(r.host_name, r.type, r.addr); } for (const auto& r : records) { mdnsv6.addMapping(r.host_name, r.type, r.addr); } ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); static const struct TestConfig { int ai_family; const std::vector expected_addr; } testConfigs[]{ {AF_INET, {v4addr}}, {AF_INET6, {v6addr}}, {AF_UNSPEC, {v4addr, v6addr}}, }; for (const auto& config : testConfigs) { mdnsv4.clearQueries(); mdnsv6.clearQueries(); addrinfo hints = {.ai_family = config.ai_family, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hi.local", nullptr, &hints); EXPECT_TRUE(result != nullptr); EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.expected_addr)); } } TEST_F(ResolverTest, MdnsGetAddrInfo_cnamesNoIpAddress) { constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_cname, "a.local."); mdnsv6.addMapping(host_name, ns_type::ns_t_cname, "a.local."); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); mdnsv4.clearQueries(); hints = {.ai_family = AF_INET6}; result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); mdnsv6.clearQueries(); hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); } TEST_F(ResolverTest, MdnsGetAddrInfo_cnamesIllegalRdata) { constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.addMapping(host_name, ns_type::ns_t_cname, ".!#?"); mdnsv6.addMapping(host_name, ns_type::ns_t_cname, ".!#?"); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); addrinfo hints = {.ai_family = AF_INET}; ScopedAddrinfo result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); mdnsv4.clearQueries(); hints = {.ai_family = AF_INET6}; result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); mdnsv6.clearQueries(); hints = {.ai_family = AF_UNSPEC}; result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result == nullptr); } // Test if .local resolution will try unicast when multicast is failed. TEST_F(ResolverTest, MdnsGetAddrInfo_fallback) { constexpr char v6addr[] = "::1.2.3.4"; constexpr char v4addr[] = "1.2.3.4"; constexpr char host_name[] = "hello.local."; test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService, static_cast(-1)); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService, static_cast(-1)); // Set unresponsive on multicast. mdnsv4.setResponseProbability(0.0); mdnsv6.setResponseProbability(0.0); ASSERT_TRUE(mdnsv4.startServer()); ASSERT_TRUE(mdnsv6.startServer()); const std::vector records = { {host_name, ns_type::ns_t_a, v4addr}, {host_name, ns_type::ns_t_aaaa, v6addr}, }; test::DNSResponder dns("127.0.0.3"); StartDns(dns, records); ASSERT_TRUE(mDnsClient.SetResolversForNetwork()); static const struct TestConfig { int ai_family; const std::vector expected_addr; } testConfigs[]{ {AF_INET, {v4addr}}, {AF_INET6, {v6addr}}, {AF_UNSPEC, {v4addr, v6addr}}, }; for (const auto& config : testConfigs) { SCOPED_TRACE(fmt::format("family: {}", config.ai_family)); addrinfo hints = {.ai_family = config.ai_family, .ai_socktype = SOCK_DGRAM}; ScopedAddrinfo result = safe_getaddrinfo("hello.local", nullptr, &hints); EXPECT_TRUE(result != nullptr); if (config.ai_family == AF_INET) { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(0U, GetNumQueries(mdnsv6, host_name)); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } else if (config.ai_family == AF_INET6) { EXPECT_EQ(0U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); EXPECT_EQ(1U, GetNumQueries(dns, host_name)); } else { EXPECT_EQ(1U, GetNumQueries(mdnsv4, host_name)); EXPECT_EQ(1U, GetNumQueries(mdnsv6, host_name)); EXPECT_EQ(2U, GetNumQueries(dns, host_name)); } EXPECT_THAT(ToStrings(result), testing::UnorderedElementsAreArray(config.expected_addr)); mdnsv4.clearQueries(); mdnsv6.clearQueries(); dns.clearQueries(); ASSERT_TRUE(mDnsClient.resolvService()->flushNetworkCache(TEST_NETID).isOk()); } } // ResolverMultinetworkTest is used to verify multinetwork functionality. Here's how it works: // The resolver sends queries to address A, and then there will be a TunForwarder helping forward // the packets to address B, which is the address on which the testing server is listening. The // answer packets responded from the testing server go through the reverse path back to the // resolver. // // To achieve the that, it needs to set up a interface with routing rules. Tests are not // supposed to initiate DNS servers on their own; instead, some utilities are added to the class to // help the setup. // // An example of how to use it: // TEST_F() { // ScopedPhysicalNetwork network = CreateScopedPhysicalNetwork(V4); // network.init(); // // auto dns = network.addIpv4Dns(); // StartDns(dns.dnsServer, {}); // // network.setDnsConfiguration(); // network.startTunForwarder(); // // // Send queries here // } class ResolverMultinetworkTest : public ResolverTest { protected: enum class ConnectivityType { V4, V6, V4V6 }; static constexpr int TEST_NETID_BASE = 10000; struct DnsServerPair { DnsServerPair(std::shared_ptr server, std::string addr) : dnsServer(server), dnsAddr(addr) {} std::shared_ptr dnsServer; std::string dnsAddr; // The DNS server address used for setResolverConfiguration(). // TODO: Add test::DnsTlsFrontend* and std::string for DoT. }; class ScopedNetwork { public: ScopedNetwork(unsigned netId, ConnectivityType type, INetd* netdSrv, IDnsResolver* dnsResolvSrv, const char* networkName) : mNetId(netId), mConnectivityType(type), mNetdSrv(netdSrv), mDnsResolvSrv(dnsResolvSrv), mNetworkName(networkName) { mIfname = fmt::format("testtun{}", netId); } virtual ~ScopedNetwork() { if (mNetdSrv != nullptr) mNetdSrv->networkDestroy(mNetId); if (mDnsResolvSrv != nullptr) mDnsResolvSrv->destroyNetworkCache(mNetId); } Result init(); Result addIpv4Dns() { return addDns(ConnectivityType::V4); } Result addIpv6Dns() { return addDns(ConnectivityType::V6); } bool startTunForwarder() { return mTunForwarder->startForwarding(); } bool setDnsConfiguration() const; bool clearDnsConfiguration() const; unsigned netId() const { return mNetId; } std::string name() const { return mNetworkName; } Result addUser(uid_t uid) const { return addUidRange(uid, uid); } Result addUidRange(uid_t from, uid_t to) const { if (auto r = mNetdSrv->networkAddUidRanges(mNetId, {makeUidRangeParcel(from, to)}); !r.isOk()) { return Error() << r.getMessage(); } return {}; } Result addUserFromParcel(uid_t uid, int32_t subPriority) const { return addUidRangeFromParcel(uid, uid, subPriority); } Result addUidRangeFromParcel(uid_t from, uid_t to, int32_t subPriority) const { NativeUidRangeConfig cfg = makeNativeUidRangeConfig(mNetId, {makeUidRangeParcel(from, to)}, subPriority); if (auto r = mNetdSrv->networkAddUidRangesParcel(cfg); !r.isOk()) { return Error() << r.getMessage(); } return {}; } const std::string& ifname() { return mIfname; } // Assuming mNetId is unique during ResolverMultinetworkTest, make the // address based on it to avoid conflicts. std::string makeIpv4AddrString(uint8_t n) const { return fmt::format("192.168.{}.{}", (mNetId - TEST_NETID_BASE), n); } std::string makeIpv6AddrString(uint8_t n) const { return fmt::format("2001:db8:{}::{}", (mNetId - TEST_NETID_BASE), n); } protected: // Subclasses should implement it to decide which network should be create. virtual Result createNetwork() const = 0; const unsigned mNetId; const ConnectivityType mConnectivityType; INetd* mNetdSrv; IDnsResolver* mDnsResolvSrv; const std::string mNetworkName; std::string mIfname; std::unique_ptr mTunForwarder; std::vector mDnsServerPairs; private: Result addDns(ConnectivityType connectivity); }; class ScopedPhysicalNetwork : public ScopedNetwork { public: ScopedPhysicalNetwork(unsigned netId, const char* networkName) : ScopedNetwork(netId, ConnectivityType::V4V6, nullptr, nullptr, networkName) {} ScopedPhysicalNetwork(unsigned netId, ConnectivityType type, INetd* netdSrv, IDnsResolver* dnsResolvSrv, const char* name = "Physical") : ScopedNetwork(netId, type, netdSrv, dnsResolvSrv, name) {} protected: Result createNetwork() const override { ::ndk::ScopedAStatus r; if (DnsResponderClient::isRemoteVersionSupported(mNetdSrv, 6)) { const auto& config = DnsResponderClient::makeNativeNetworkConfig( mNetId, NativeNetworkType::PHYSICAL, INetd::PERMISSION_NONE, /*secure=*/false); r = mNetdSrv->networkCreate(config); } else { #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wdeprecated-declarations" r = mNetdSrv->networkCreatePhysical(mNetId, INetd::PERMISSION_NONE); #pragma clang diagnostic pop } if (!r.isOk()) { return Error() << r.getMessage(); } return {}; } }; class ScopedVirtualNetwork : public ScopedNetwork { public: ScopedVirtualNetwork(unsigned netId, ConnectivityType type, INetd* netdSrv, IDnsResolver* dnsResolvSrv, const char* name, bool isSecure) : ScopedNetwork(netId, type, netdSrv, dnsResolvSrv, name), mIsSecure(isSecure) { if (android::modules::sdklevel::IsAtLeastT()) { mFw = Firewall::getInstance(); } } ~ScopedVirtualNetwork() { if (!mVpnIsolationUids.empty()) { const std::vector tmpUids(mVpnIsolationUids.begin(), mVpnIsolationUids.end()); mNetdSrv->firewallRemoveUidInterfaceRules(tmpUids); } } // Enable VPN isolation. Ensures that uid can only receive packets on mIfname. Result enableVpnIsolation(int uid) { if (android::modules::sdklevel::IsAtLeastT()) { if (auto r = mFw->addUidInterfaceRules(mIfname, {uid}); !r.ok()) { return r; } } else if (auto r = mNetdSrv->firewallAddUidInterfaceRules(mIfname, {uid}); !r.isOk()) { return Error() << r.getMessage(); } mVpnIsolationUids.insert(uid); return {}; } Result disableVpnIsolation(int uid) { if (android::modules::sdklevel::IsAtLeastT()) { if (auto r = mFw->removeUidInterfaceRules({uid}); !r.ok()) { return r; } } else if (auto r = mNetdSrv->firewallRemoveUidInterfaceRules({uid}); !r.isOk()) { return Error() << r.getMessage(); } mVpnIsolationUids.erase(uid); return {}; } protected: Result createNetwork() const override { ::ndk::ScopedAStatus r; if (DnsResponderClient::isRemoteVersionSupported(mNetdSrv, 6)) { const auto& config = DnsResponderClient::makeNativeNetworkConfig( mNetId, NativeNetworkType::VIRTUAL, INetd::PERMISSION_NONE, mIsSecure); r = mNetdSrv->networkCreate(config); } else { #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wdeprecated-declarations" r = mNetdSrv->networkCreateVpn(mNetId, mIsSecure); #pragma clang diagnostic pop } if (!r.isOk()) { return Error() << r.getMessage(); } return {}; } bool mIsSecure = false; std::unordered_set mVpnIsolationUids; Firewall* mFw; }; void SetUp() override { ResolverTest::SetUp(); ASSERT_NE(mDnsClient.netdService(), nullptr); ASSERT_NE(mDnsClient.resolvService(), nullptr); } void TearDown() override { ResolverTest::TearDown(); // Restore default network if (mStoredDefaultNetwork >= 0) { mDnsClient.netdService()->networkSetDefault(mStoredDefaultNetwork); } } ScopedPhysicalNetwork CreateScopedPhysicalNetwork(ConnectivityType type, const char* name = "Physical") { return {getFreeNetId(), type, mDnsClient.netdService(), mDnsClient.resolvService(), name}; } ScopedVirtualNetwork CreateScopedVirtualNetwork(ConnectivityType type, bool isSecure, const char* name = "Virtual") { return {getFreeNetId(), type, mDnsClient.netdService(), mDnsClient.resolvService(), name, isSecure}; } void StartDns(test::DNSResponder& dns, const std::vector& records); void setDefaultNetwork(int netId) { // Save current default network at the first call. std::call_once(defaultNetworkFlag, [&]() { ASSERT_TRUE(mDnsClient.netdService()->networkGetDefault(&mStoredDefaultNetwork).isOk()); }); ASSERT_TRUE(mDnsClient.netdService()->networkSetDefault(netId).isOk()); } unsigned getFreeNetId() { if (mNextNetId == TEST_NETID_BASE + 256) mNextNetId = TEST_NETID_BASE; return mNextNetId++; } Result> setupDns(ConnectivityType type, ScopedNetwork* nw, const char* host_name, const char* ipv4_addr, const char* ipv6_addr); void expectDnsQueryCountsFn(std::shared_ptr dnsServer, const char* host_name, size_t count, unsigned expectedDnsNetId) { EXPECT_EQ(GetNumQueries(*dnsServer, host_name), count); EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(expectedDnsNetId).isOk()); dnsServer->clearQueries(); } static NativeUidRangeConfig makeNativeUidRangeConfig(unsigned netId, std::vector uidRanges, int32_t subPriority) { NativeUidRangeConfig res; res.netId = netId; res.uidRanges = std::move(uidRanges); res.subPriority = subPriority; return res; } private: // Use a different netId because this class inherits from the class ResolverTest which // always creates TEST_NETID in setup. It's incremented when CreateScoped{Physical, // Virtual}Network() is called. // Note: 255 is the maximum number of (mNextNetId - TEST_NETID_BASE) here as mNextNetId // is used to create address. unsigned mNextNetId = TEST_NETID_BASE; // Use -1 to represent that default network was not modified because // real netId must be an unsigned value. int mStoredDefaultNetwork = -1; std::once_flag defaultNetworkFlag; }; Result ResolverMultinetworkTest::ScopedNetwork::init() { if (mNetdSrv == nullptr || mDnsResolvSrv == nullptr) return Error() << "srv not available"; unique_fd ufd = TunForwarder::createTun(mIfname); if (!ufd.ok()) { return Errorf("createTun for {} failed", mIfname); } mTunForwarder = std::make_unique(std::move(ufd)); if (auto r = createNetwork(); !r.ok()) { return r; } if (auto r = mDnsResolvSrv->createNetworkCache(mNetId); !r.isOk()) { return Error() << r.getMessage(); } if (auto r = mNetdSrv->networkAddInterface(mNetId, mIfname); !r.isOk()) { return Error() << r.getMessage(); } if (mConnectivityType == ConnectivityType::V4 || mConnectivityType == ConnectivityType::V4V6) { const std::string v4Addr = makeIpv4AddrString(1); if (auto r = mNetdSrv->interfaceAddAddress(mIfname, v4Addr, 32); !r.isOk()) { return Error() << r.getMessage(); } if (auto r = mNetdSrv->networkAddRoute(mNetId, mIfname, "0.0.0.0/0", ""); !r.isOk()) { return Error() << r.getMessage(); } } if (mConnectivityType == ConnectivityType::V6 || mConnectivityType == ConnectivityType::V4V6) { const std::string v6Addr = makeIpv6AddrString(1); if (auto r = mNetdSrv->interfaceAddAddress(mIfname, v6Addr, 128); !r.isOk()) { return Error() << r.getMessage(); } if (auto r = mNetdSrv->networkAddRoute(mNetId, mIfname, "::/0", ""); !r.isOk()) { return Error() << r.getMessage(); } } return {}; } void ResolverMultinetworkTest::StartDns(test::DNSResponder& dns, const std::vector& records) { ResolverTest::StartDns(dns, records); // Bind the DNSResponder's sockets to the network if specified. if (std::optional netId = dns.getNetwork(); netId.has_value()) { setNetworkForSocket(netId.value(), dns.getUdpSocket()); setNetworkForSocket(netId.value(), dns.getTcpSocket()); } } Result> ResolverMultinetworkTest::setupDns( ConnectivityType type, ScopedNetwork* nw, const char* host_name, const char* ipv4_addr, const char* ipv6_addr) { // Add a testing DNS server to networks. const Result dnsSvPair = (type == ConnectivityType::V4) ? nw->addIpv4Dns() : nw->addIpv6Dns(); if (!dnsSvPair.ok()) return Error() << dnsSvPair.error(); StartDns(*dnsSvPair->dnsServer, {{host_name, ns_type::ns_t_a, ipv4_addr}, {host_name, ns_type::ns_t_aaaa, ipv6_addr}}); if (!nw->setDnsConfiguration()) return Error() << "setDnsConfiguration() failed"; if (!nw->startTunForwarder()) return Error() << "startTunForwarder() failed"; return dnsSvPair->dnsServer; } Result ResolverMultinetworkTest::ScopedNetwork::addDns( ConnectivityType type) { const int index = mDnsServerPairs.size(); const int prefixLen = (type == ConnectivityType::V4) ? 32 : 128; const std::function makeIpString = std::bind((type == ConnectivityType::V4) ? &ScopedNetwork::makeIpv4AddrString : &ScopedNetwork::makeIpv6AddrString, this, std::placeholders::_1); std::string src1 = makeIpString(1); // The address from which the resolver will send. std::string dst1 = makeIpString( index + 100 + (mNetId - TEST_NETID_BASE)); // The address to which the resolver will send. std::string src2 = dst1; // The address translated from src1. std::string dst2 = makeIpString( index + 200 + (mNetId - TEST_NETID_BASE)); // The address translated from dst2. if (!mTunForwarder->addForwardingRule({src1, dst1}, {src2, dst2}) || !mTunForwarder->addForwardingRule({dst2, src2}, {dst1, src1})) { return Errorf("Failed to add the rules ({}, {}, {}, {})", src1, dst1, src2, dst2); } if (!mNetdSrv->interfaceAddAddress(mIfname, dst2, prefixLen).isOk()) { return Errorf("interfaceAddAddress({}, {}, {}) failed", mIfname, dst2, prefixLen); } return mDnsServerPairs.emplace_back(std::make_shared(mNetId, dst2), dst1); } bool ResolverMultinetworkTest::ScopedNetwork::setDnsConfiguration() const { if (mDnsResolvSrv == nullptr) return false; ResolverParamsParcel parcel = DnsResponderClient::GetDefaultResolverParamsParcel(); parcel.tlsServers.clear(); parcel.netId = mNetId; parcel.servers.clear(); parcel.interfaceNames.push_back(mIfname); for (const auto& pair : mDnsServerPairs) { parcel.servers.push_back(pair.dnsAddr); } return mDnsResolvSrv->setResolverConfiguration(parcel).isOk(); } bool ResolverMultinetworkTest::ScopedNetwork::clearDnsConfiguration() const { if (mDnsResolvSrv == nullptr) return false; return mDnsResolvSrv->destroyNetworkCache(mNetId).isOk() && mDnsResolvSrv->createNetworkCache(mNetId).isOk(); } namespace { // Convenient wrapper for making getaddrinfo call like framework. Result android_getaddrinfofornet_wrapper(const char* name, int netId) { // Use the same parameter as libcore/ojluni/src/main/java/java/net/Inet6AddressImpl.java. static const addrinfo hints = { .ai_flags = AI_ADDRCONFIG, .ai_family = AF_UNSPEC, .ai_socktype = SOCK_STREAM, }; addrinfo* result = nullptr; if (int r = android_getaddrinfofornet(name, nullptr, &hints, netId, MARK_UNSET, &result)) { return Error() << r; } return ScopedAddrinfo(result); } void expectDnsWorksForUid(const char* name, unsigned netId, uid_t uid, const std::vector& expectedResult) { ScopedChangeUID scopedChangeUID(uid); auto result = android_getaddrinfofornet_wrapper(name, netId); ASSERT_RESULT_OK(result); ScopedAddrinfo ai_result(std::move(result.value())); std::vector result_strs = ToStrings(ai_result); EXPECT_THAT(result_strs, testing::UnorderedElementsAreArray(expectedResult)); } void expectDnsFailedForUid(const char* name, unsigned netId, uid_t uid) { ScopedChangeUID scopedChangeUID(uid); ASSERT_FALSE(android_getaddrinfofornet_wrapper(name, netId).ok()); } } // namespace TEST_F(ResolverMultinetworkTest, GetAddrInfo_AI_ADDRCONFIG) { constexpr char host_name[] = "ohayou.example.com."; const std::array allTypes = { ConnectivityType::V4, ConnectivityType::V6, ConnectivityType::V4V6, }; for (const auto& type : allTypes) { SCOPED_TRACE(fmt::format("ConnectivityType: {}", static_cast(type))); // Create a network. ScopedPhysicalNetwork network = CreateScopedPhysicalNetwork(type); ASSERT_RESULT_OK(network.init()); // Add a testing DNS server. const Result dnsPair = (type == ConnectivityType::V4) ? network.addIpv4Dns() : network.addIpv6Dns(); ASSERT_RESULT_OK(dnsPair); StartDns(*dnsPair->dnsServer, {{host_name, ns_type::ns_t_a, "192.0.2.0"}, {host_name, ns_type::ns_t_aaaa, "2001:db8:cafe:d00d::31"}}); // Set up resolver and start forwarding. ASSERT_TRUE(network.setDnsConfiguration()); ASSERT_TRUE(network.startTunForwarder()); auto result = android_getaddrinfofornet_wrapper(host_name, network.netId()); ASSERT_RESULT_OK(result); ScopedAddrinfo ai_result(std::move(result.value())); std::vector result_strs = ToStrings(ai_result); std::vector expectedResult; size_t expectedQueries = 0; if (type == ConnectivityType::V6 || type == ConnectivityType::V4V6) { expectedResult.emplace_back("2001:db8:cafe:d00d::31"); expectedQueries++; } if (type == ConnectivityType::V4 || type == ConnectivityType::V4V6) { expectedResult.emplace_back("192.0.2.0"); expectedQueries++; } EXPECT_THAT(result_strs, testing::UnorderedElementsAreArray(expectedResult)); EXPECT_EQ(GetNumQueries(*dnsPair->dnsServer, host_name), expectedQueries); } } TEST_F(ResolverMultinetworkTest, NetworkDestroyedDuringQueryInFlight) { constexpr char host_name[] = "ohayou.example.com."; // Create a network and add an ipv4 DNS server. auto network = std::make_unique(getFreeNetId(), ConnectivityType::V4V6, mDnsClient.netdService(), mDnsClient.resolvService()); ASSERT_RESULT_OK(network->init()); const Result dnsPair = network->addIpv4Dns(); ASSERT_RESULT_OK(dnsPair); // Set the DNS server unresponsive. dnsPair->dnsServer->setResponseProbability(0.0); dnsPair->dnsServer->setErrorRcode(static_cast(-1)); StartDns(*dnsPair->dnsServer, {}); // Set up resolver and start forwarding. ASSERT_TRUE(network->setDnsConfiguration()); ASSERT_TRUE(network->startTunForwarder()); // Expect the things happening in order: // 1. The thread sends the query to the dns server which is unresponsive. // 2. The network is destroyed while the thread is waiting for the response from the dns server. // 3. After the dns server timeout, the thread retries but fails to connect. std::thread lookup([&]() { int fd = resNetworkQuery(network->netId(), host_name, ns_c_in, ns_t_a, 0); EXPECT_TRUE(fd != -1); expectAnswersNotValid(fd, -ETIMEDOUT); }); // Tear down the network as soon as the dns server receives the query. const auto condition = [&]() { return GetNumQueries(*dnsPair->dnsServer, host_name) == 1U; }; EXPECT_TRUE(PollForCondition(condition)); network.reset(); lookup.join(); } TEST_F(ResolverMultinetworkTest, OneCachePerNetwork) { SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.resolvService(), 4); constexpr char host_name[] = "ohayou.example.com."; ScopedPhysicalNetwork network1 = CreateScopedPhysicalNetwork(ConnectivityType::V4V6); ScopedPhysicalNetwork network2 = CreateScopedPhysicalNetwork(ConnectivityType::V4V6); ASSERT_RESULT_OK(network1.init()); ASSERT_RESULT_OK(network2.init()); const Result dnsPair1 = network1.addIpv4Dns(); const Result dnsPair2 = network2.addIpv4Dns(); ASSERT_RESULT_OK(dnsPair1); ASSERT_RESULT_OK(dnsPair2); StartDns(*dnsPair1->dnsServer, {{host_name, ns_type::ns_t_a, "192.0.2.0"}}); StartDns(*dnsPair2->dnsServer, {{host_name, ns_type::ns_t_a, "192.0.2.1"}}); // Set up resolver for network 1 and start forwarding. ASSERT_TRUE(network1.setDnsConfiguration()); ASSERT_TRUE(network1.startTunForwarder()); // Set up resolver for network 2 and start forwarding. ASSERT_TRUE(network2.setDnsConfiguration()); ASSERT_TRUE(network2.startTunForwarder()); // Send the same queries to both networks. int fd1 = resNetworkQuery(network1.netId(), host_name, ns_c_in, ns_t_a, 0); int fd2 = resNetworkQuery(network2.netId(), host_name, ns_c_in, ns_t_a, 0); expectAnswersValid(fd1, AF_INET, "192.0.2.0"); expectAnswersValid(fd2, AF_INET, "192.0.2.1"); EXPECT_EQ(GetNumQueries(*dnsPair1->dnsServer, host_name), 1U); EXPECT_EQ(GetNumQueries(*dnsPair2->dnsServer, host_name), 1U); // Flush the cache of network 1, and send the queries again. EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(network1.netId()).isOk()); fd1 = resNetworkQuery(network1.netId(), host_name, ns_c_in, ns_t_a, 0); fd2 = resNetworkQuery(network2.netId(), host_name, ns_c_in, ns_t_a, 0); expectAnswersValid(fd1, AF_INET, "192.0.2.0"); expectAnswersValid(fd2, AF_INET, "192.0.2.1"); EXPECT_EQ(GetNumQueries(*dnsPair1->dnsServer, host_name), 2U); EXPECT_EQ(GetNumQueries(*dnsPair2->dnsServer, host_name), 1U); } TEST_F(ResolverMultinetworkTest, DnsWithVpn) { SKIP_IF_BPF_NOT_SUPPORTED; SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.resolvService(), 4); constexpr char host_name[] = "ohayou.example.com."; constexpr char ipv4_addr[] = "192.0.2.0"; constexpr char ipv6_addr[] = "2001:db8:cafe:d00d::31"; const std::pair> testPairs[] = { {ConnectivityType::V4, {ipv4_addr}}, {ConnectivityType::V6, {ipv6_addr}}, {ConnectivityType::V4V6, {ipv6_addr, ipv4_addr}}, }; for (const auto& [type, result] : testPairs) { SCOPED_TRACE(fmt::format("ConnectivityType: {}", static_cast(type))); // Create a network. ScopedPhysicalNetwork underlyingNetwork = CreateScopedPhysicalNetwork(type, "Underlying"); ScopedVirtualNetwork bypassableVpnNetwork = CreateScopedVirtualNetwork(type, false, "BypassableVpn"); ScopedVirtualNetwork secureVpnNetwork = CreateScopedVirtualNetwork(type, true, "SecureVpn"); ASSERT_RESULT_OK(underlyingNetwork.init()); ASSERT_RESULT_OK(bypassableVpnNetwork.init()); ASSERT_RESULT_OK(secureVpnNetwork.init()); ASSERT_RESULT_OK(bypassableVpnNetwork.addUser(TEST_UID)); ASSERT_RESULT_OK(secureVpnNetwork.addUser(TEST_UID2)); // Set up resolver and start forwarding for networks. auto underlyingNwDnsSv = setupDns(type, &underlyingNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(underlyingNwDnsSv); auto bypassableVpnDnsSv = setupDns(type, &bypassableVpnNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(bypassableVpnDnsSv); auto secureVpnDnsSv = setupDns(type, &secureVpnNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(secureVpnDnsSv); setDefaultNetwork(underlyingNetwork.netId()); const unsigned underlyingNetId = underlyingNetwork.netId(); const unsigned bypassableVpnNetId = bypassableVpnNetwork.netId(); const unsigned secureVpnNetId = secureVpnNetwork.netId(); // We've called setNetworkForProcess in SetupOemNetwork, so reset to default first. ScopedSetNetworkForProcess scopedSetNetworkForProcess(NETID_UNSET); // Create a object to represent default network, do not init it. ScopedPhysicalNetwork defaultNetwork{NETID_UNSET, "Default"}; // Test VPN with DNS server under 4 different network selection scenarios. // See the test config for the expectation. const struct TestConfig { ScopedNetwork* selectedNetwork; unsigned expectedDnsNetId; std::shared_ptr expectedDnsServer; } vpnWithDnsServerConfigs[]{ // clang-format off // Queries use the bypassable VPN by default. {&defaultNetwork, bypassableVpnNetId, *bypassableVpnDnsSv}, // Choosing the underlying network works because the VPN is bypassable. {&underlyingNetwork, underlyingNetId, *underlyingNwDnsSv}, // Selecting the VPN sends the query on the VPN. {&bypassableVpnNetwork, bypassableVpnNetId, *bypassableVpnDnsSv}, // TEST_UID does not have access to the secure VPN. {&secureVpnNetwork, bypassableVpnNetId, *bypassableVpnDnsSv}, // clang-format on }; for (const auto& config : vpnWithDnsServerConfigs) { SCOPED_TRACE(fmt::format("Bypassble VPN with DnsServer, selectedNetwork = {}", config.selectedNetwork->name())); expectDnsWorksForUid(host_name, config.selectedNetwork->netId(), TEST_UID, result); expectDnsQueryCountsFn(config.expectedDnsServer, host_name, result.size(), config.expectedDnsNetId); } std::vector nwVec{&defaultNetwork, &underlyingNetwork, &bypassableVpnNetwork, &secureVpnNetwork}; // Test the VPN without DNS server with the same combination as before. ASSERT_TRUE(bypassableVpnNetwork.clearDnsConfiguration()); // Test bypassable VPN, TEST_UID for (const auto* selectedNetwork : nwVec) { SCOPED_TRACE(fmt::format("Bypassble VPN without DnsServer, selectedNetwork = {}", selectedNetwork->name())); expectDnsWorksForUid(host_name, selectedNetwork->netId(), TEST_UID, result); expectDnsQueryCountsFn(*underlyingNwDnsSv, host_name, result.size(), underlyingNetId); } // The same test scenario as before plus enableVpnIsolation for secure VPN, TEST_UID2. for (bool enableVpnIsolation : {false, true}) { SCOPED_TRACE(fmt::format("enableVpnIsolation = {}", enableVpnIsolation)); if (enableVpnIsolation) { EXPECT_RESULT_OK(secureVpnNetwork.enableVpnIsolation(TEST_UID2)); } // Test secure VPN without DNS server. ASSERT_TRUE(secureVpnNetwork.clearDnsConfiguration()); for (const auto* selectedNetwork : nwVec) { SCOPED_TRACE(fmt::format("Secure VPN without DnsServer, selectedNetwork = {}", selectedNetwork->name())); expectDnsWorksForUid(host_name, selectedNetwork->netId(), TEST_UID2, result); expectDnsQueryCountsFn(*underlyingNwDnsSv, host_name, result.size(), underlyingNetId); } // Test secure VPN with DNS server. ASSERT_TRUE(secureVpnNetwork.setDnsConfiguration()); for (const auto* selectedNetwork : nwVec) { SCOPED_TRACE(fmt::format("Secure VPN with DnsServer, selectedNetwork = {}", selectedNetwork->name())); expectDnsWorksForUid(host_name, selectedNetwork->netId(), TEST_UID2, result); expectDnsQueryCountsFn(*secureVpnDnsSv, host_name, result.size(), secureVpnNetId); } if (enableVpnIsolation) { EXPECT_RESULT_OK(secureVpnNetwork.disableVpnIsolation(TEST_UID2)); } } } } // verify per-application default network selection on DNS. TEST_F(ResolverMultinetworkTest, PerAppDefaultNetwork) { // Netd supports uid ranges on physical network from v6. SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.netdService(), 6); constexpr char host_name[] = "ohayou.example.com."; constexpr char ipv4_addr[] = "192.0.2.0"; constexpr char ipv6_addr[] = "2001:db8:cafe:d00d::31"; const std::pair> testPairs[] = { {ConnectivityType::V4, {ipv4_addr}}, {ConnectivityType::V6, {ipv6_addr}}, {ConnectivityType::V4V6, {ipv6_addr, ipv4_addr}}, }; for (const auto& [ipVersion, expectedDnsReply] : testPairs) { SCOPED_TRACE(fmt::format("ConnectivityType: {}", static_cast(ipVersion))); // Create networks. ScopedPhysicalNetwork sysDefaultNetwork = CreateScopedPhysicalNetwork(ipVersion, "SysDefault"); ScopedPhysicalNetwork appDefaultNetwork = CreateScopedPhysicalNetwork(ipVersion, "AppDefault"); ScopedVirtualNetwork vpn = CreateScopedVirtualNetwork(ipVersion, false, "Vpn"); ASSERT_RESULT_OK(sysDefaultNetwork.init()); ASSERT_RESULT_OK(appDefaultNetwork.init()); ASSERT_RESULT_OK(vpn.init()); // Set up resolver and start forwarding for networks. auto sysDefaultNwDnsSv = setupDns(ipVersion, &sysDefaultNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(sysDefaultNwDnsSv); auto appDefaultNwDnsSv = setupDns(ipVersion, &appDefaultNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(appDefaultNwDnsSv); auto vpnDnsSv = setupDns(ipVersion, &vpn, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(vpnDnsSv); const unsigned systemDefaultNetId = sysDefaultNetwork.netId(); const unsigned appDefaultNetId = appDefaultNetwork.netId(); const unsigned vpnNetId = vpn.netId(); setDefaultNetwork(systemDefaultNetId); EXPECT_TRUE( mDnsClient.netdService() ->networkSetPermissionForNetwork(appDefaultNetId, INetd::PERMISSION_SYSTEM) .isOk()); // We've called setNetworkForProcess in SetupOemNetwork, reset to default first. ScopedSetNetworkForProcess scopedSetNetworkForProcess(NETID_UNSET); // Test DNS query without selecting a network. --> use system default network. expectDnsWorksForUid(host_name, NETID_UNSET, TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(*sysDefaultNwDnsSv, host_name, expectedDnsReply.size(), systemDefaultNetId); // Add user to app default network. --> use app default network. ASSERT_RESULT_OK(appDefaultNetwork.addUser(TEST_UID)); expectDnsWorksForUid(host_name, NETID_UNSET, TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(*appDefaultNwDnsSv, host_name, expectedDnsReply.size(), appDefaultNetId); // Test DNS query with a selected network. // App default network applies to uid, vpn does not applies to uid. const struct TestConfig { ScopedNetwork* selectedNetwork; unsigned expectedDnsNetId; std::shared_ptr expectedDnsServer; } vpnWithDnsServerConfigs[]{ // clang-format off // App can select the system default network without any permission. {&sysDefaultNetwork, systemDefaultNetId, *sysDefaultNwDnsSv}, // App can select the restricted network, since its uid was assigned to the network. {&appDefaultNetwork, appDefaultNetId, *appDefaultNwDnsSv}, // App does not have access to the VPN. --> fallback to app default network. {&vpn, appDefaultNetId, *appDefaultNwDnsSv}, // clang-format on }; for (const auto& config : vpnWithDnsServerConfigs) { SCOPED_TRACE(fmt::format("Dns over app default network, selectedNetwork = {}", config.selectedNetwork->name())); expectDnsWorksForUid(host_name, config.selectedNetwork->netId(), TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(config.expectedDnsServer, host_name, expectedDnsReply.size(), config.expectedDnsNetId); } // App default network applies to uid, vpn applies to uid. --> use vpn. ASSERT_RESULT_OK(vpn.addUser(TEST_UID)); expectDnsWorksForUid(host_name, vpn.netId(), TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(*vpnDnsSv, host_name, expectedDnsReply.size(), vpnNetId); // vpn without server. --> fallback to app default network. ASSERT_TRUE(vpn.clearDnsConfiguration()); expectDnsWorksForUid(host_name, vpn.netId(), TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(*appDefaultNwDnsSv, host_name, expectedDnsReply.size(), appDefaultNetId); } } // Do not send AAAA query when IPv6 address is link-local with a default route. TEST_F(ResolverMultinetworkTest, IPv6LinkLocalWithDefaultRoute) { constexpr char host_name[] = "ohayou.example.com."; ScopedPhysicalNetwork network = CreateScopedPhysicalNetwork(ConnectivityType::V4); ASSERT_RESULT_OK(network.init()); // Add IPv6 default route ASSERT_TRUE(mDnsClient.netdService() ->networkAddRoute(network.netId(), network.ifname(), "::/0", "") .isOk()); const Result dnsPair = network.addIpv4Dns(); ASSERT_RESULT_OK(dnsPair); StartDns(*dnsPair->dnsServer, {{host_name, ns_type::ns_t_a, "192.0.2.0"}, {host_name, ns_type::ns_t_aaaa, "2001:db8:cafe:d00d::31"}}); ASSERT_TRUE(network.setDnsConfiguration()); ASSERT_TRUE(network.startTunForwarder()); auto result = android_getaddrinfofornet_wrapper(host_name, network.netId()); ASSERT_RESULT_OK(result); ScopedAddrinfo ai_result(std::move(result.value())); EXPECT_EQ(ToString(ai_result), "192.0.2.0"); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_a, host_name), 1U); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_aaaa, host_name), 0U); EXPECT_TRUE(mDnsClient.resolvService()->flushNetworkCache(network.netId()).isOk()); dnsPair->dnsServer->clearQueries(); // Add an IPv6 global address. Resolver starts issuing AAAA queries as well as A queries. const std::string v6Addr = network.makeIpv6AddrString(1); EXPECT_TRUE( mDnsClient.netdService()->interfaceAddAddress(network.ifname(), v6Addr, 128).isOk()); // Ensuring that address is applied. This is required for mainline test (b/249225311). usleep(1000 * 1000); result = android_getaddrinfofornet_wrapper(host_name, network.netId()); ASSERT_RESULT_OK(result); ScopedAddrinfo ai_results(std::move(result.value())); std::vector result_strs = ToStrings(ai_results); EXPECT_THAT(result_strs, testing::UnorderedElementsAreArray({"192.0.2.0", "2001:db8:cafe:d00d::31"})); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_a, host_name), 1U); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_aaaa, host_name), 1U); } // v6 mdns is expected to be sent when the IPv6 address is a link-local with a default route. TEST_F(ResolverMultinetworkTest, MdnsIPv6LinkLocalWithDefaultRoute) { // Kernel 4.4 does not provide an IPv6 link-local address when an interface is added to a // network. Skip it because v6 link-local address is a prerequisite for this test. SKIP_IF_KERNEL_VERSION_LOWER_THAN(4, 9, 0); constexpr char v6addr[] = "::127.0.0.3"; constexpr char v4addr[] = "127.0.0.3"; constexpr char host_name[] = "hello.local."; ScopedPhysicalNetwork network = CreateScopedPhysicalNetwork(ConnectivityType::V4); ASSERT_RESULT_OK(network.init()); // Add IPv6 default route ASSERT_TRUE(mDnsClient.netdService() ->networkAddRoute(network.netId(), network.ifname(), "::/0", "") .isOk()); // Ensuring that routing is applied. This is required for mainline test (b/247693272). usleep(1000 * 1000); const Result dnsPair = network.addIpv4Dns(); ASSERT_RESULT_OK(dnsPair); StartDns(*dnsPair->dnsServer, {}); ASSERT_TRUE(network.setDnsConfiguration()); ASSERT_TRUE(network.startTunForwarder()); test::DNSResponder mdnsv4("127.0.0.3", test::kDefaultMdnsListenService); test::DNSResponder mdnsv6("::1", test::kDefaultMdnsListenService); mdnsv4.setNetwork(network.netId()); mdnsv6.setNetwork(network.netId()); StartDns(mdnsv4, {{host_name, ns_type::ns_t_a, v4addr}}); StartDns(mdnsv6, {{host_name, ns_type::ns_t_aaaa, v6addr}}); auto result = android_getaddrinfofornet_wrapper("hello.local", network.netId()); ASSERT_RESULT_OK(result); ScopedAddrinfo ai_result(std::move(result.value())); EXPECT_THAT(ToStrings(ai_result), testing::UnorderedElementsAreArray({v4addr, v6addr})); // make sure queries were sent & received via mdns. EXPECT_EQ(GetNumQueries(mdnsv4, host_name), 1U); EXPECT_EQ(GetNumQueries(mdnsv6, host_name), 1U); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_a, host_name), 0U); EXPECT_EQ(GetNumQueriesForType(*dnsPair->dnsServer, ns_type::ns_t_aaaa, host_name), 0U); } TEST_F(ResolverTest, NegativeValueInExperimentFlag) { // Test setting up different retry count and BASE_TIMEOUT_MSEC in DNS server. const struct TestConfig { int retryCount; int baseTimeoutMsec; int expectedRetryCount; int expectedBaseTimeoutMsec; } TestConfigs[]{{2, 1000, 2, 1000}, {0, 0, RES_DFLRETRY, RES_TIMEOUT}}; for (const auto& config : TestConfigs) { SCOPED_TRACE(fmt::format("Setting up retryCount = {}, baseTimeoutMsec = {}", config.retryCount, config.baseTimeoutMsec)); // Initiate negative values in experiment flags. ScopedSystemProperties sp1(kRetryCountFlag, "-2"); ScopedSystemProperties sp2(kRetransIntervalFlag, "-3000"); resetNetwork(); ResolverParamsParcel setupParams = DnsResponderClient::GetDefaultResolverParamsParcel(); setupParams.retryCount = config.retryCount; setupParams.baseTimeoutMsec = config.baseTimeoutMsec; ASSERT_TRUE(mDnsClient.SetResolversFromParcel(setupParams)); const auto resolvInfo = mDnsClient.getResolverInfo(); ASSERT_RESULT_OK(resolvInfo); EXPECT_EQ(config.expectedRetryCount, resolvInfo.value().params.retry_count); EXPECT_EQ(config.expectedBaseTimeoutMsec, resolvInfo.value().params.base_timeout_msec); } } // Verify that DNS queries can be made for hostnames that exist in etc/hosts when the default // network is not set and the application does not specify a network. (See // NetworkController::isUidAllowed for implementation details.) TEST_F(ResolverTest, NetworkUnspecified_localhost) { ScopedDefaultNetwork scopedDefaultNetwork(mDnsClient.netdService(), NETID_UNSET); ScopedSetNetworkForProcess scopedSetNetworkForProcess(NETID_UNSET); ScopedAddrinfo result = safe_getaddrinfo(kLocalHost, nullptr, nullptr); EXPECT_TRUE(result != nullptr); EXPECT_EQ(kLocalHostAddr, ToString(result)); result = safe_getaddrinfo(kIp6LocalHost, nullptr, nullptr); EXPECT_TRUE(result != nullptr); EXPECT_EQ(kIp6LocalHostAddr, ToString(result)); } // Verify uid-based network permission on DNS, which is controlled by INetd::setNetworkAllowlist(). // // Scenario: // 1. There are three neworks at the same time: // - system default network // - enterprise network #1 // - enterprise network #2 // // 2. Simulate ConnectivityService calling INetd::setNetworkAllowlist so that // - TEST_UID can select only enterprise network #1 and #2. Can not select system default network. // - TEST_UID2 is unrestricted on all networks. TEST_F(ResolverMultinetworkTest, UidAllowedNetworks) { // Netd supports it from v13. SKIP_IF_REMOTE_VERSION_LESS_THAN(mDnsClient.netdService(), 13); constexpr char host_name[] = "ohayou.example.com."; constexpr char ipv4_addr[] = "192.0.2.0"; constexpr char ipv6_addr[] = "2001:db8:cafe:d00d::31"; const std::pair> testPairs[] = { {ConnectivityType::V4, {ipv4_addr}}, {ConnectivityType::V6, {ipv6_addr}}, {ConnectivityType::V4V6, {ipv6_addr, ipv4_addr}}, }; for (const auto& [ipVersion, expectedDnsReply] : testPairs) { SCOPED_TRACE(fmt::format("ConnectivityType: {}", static_cast(ipVersion))); // Create networks. ScopedPhysicalNetwork sysDefaultNetwork = CreateScopedPhysicalNetwork(ipVersion, "SysDefault"); ScopedPhysicalNetwork enterpriseNetwork_1 = CreateScopedPhysicalNetwork(ipVersion, "enterprise_1"); ScopedPhysicalNetwork enterpriseNetwork_2 = CreateScopedPhysicalNetwork(ipVersion, "enterprise_2"); ASSERT_RESULT_OK(sysDefaultNetwork.init()); ASSERT_RESULT_OK(enterpriseNetwork_1.init()); ASSERT_RESULT_OK(enterpriseNetwork_2.init()); // Set up resolver and start forwarding for networks. auto sysDefaultNwDnsSv = setupDns(ipVersion, &sysDefaultNetwork, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(sysDefaultNwDnsSv); auto enterpriseNw1DnsSv = setupDns(ipVersion, &enterpriseNetwork_1, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(enterpriseNw1DnsSv); auto enterpriseNw2DnsSv = setupDns(ipVersion, &enterpriseNetwork_2, host_name, ipv4_addr, ipv6_addr); ASSERT_RESULT_OK(enterpriseNw2DnsSv); const unsigned systemDefaultNetId = sysDefaultNetwork.netId(); const unsigned enterprise1NetId = enterpriseNetwork_1.netId(); const unsigned enterprise2NetId = enterpriseNetwork_2.netId(); setDefaultNetwork(systemDefaultNetId); // We've called setNetworkForProcess in SetupOemNetwork, reset to default first. ScopedSetNetworkForProcess scopedSetNetworkForProcess(NETID_UNSET); // Add profile app default network for UID. DNS should be sent on it. // Note: subPriority 20 = PREFERENCE_ORDER_PROFILE, which is defined // in ConnectivityService.java. The value here doesn't really matter. ASSERT_RESULT_OK(enterpriseNetwork_1.addUserFromParcel(TEST_UID, /*subPriority*/ 20)); expectDnsWorksForUid(host_name, NETID_UNSET, TEST_UID, expectedDnsReply); expectDnsQueryCountsFn(*enterpriseNw1DnsSv, host_name, expectedDnsReply.size(), enterprise1NetId); // Set allowed networks for UIDs. To simplify test, assumes overall UID range is // {0, 1, 2, ..., TEST_UID2, TEST_UID}. // TEST_UID can't select the system default network. 0 - TEST_UID2 are allowed. NativeUidRangeConfig nwDefaultUserConfig = makeNativeUidRangeConfig( systemDefaultNetId, {makeUidRangeParcel(0, TEST_UID2)}, /*unused*/ 0); // All UIDs can select the enterprise network #1. 0 - TEST_UID are allowed. NativeUidRangeConfig nw1UserConfig = makeNativeUidRangeConfig( enterprise1NetId, {makeUidRangeParcel(0, TEST_UID)}, /*unused*/ 0); // All UIDs can select the enterprise network #2. 0 - TEST_UID are allowed. NativeUidRangeConfig nw2UserConfig = makeNativeUidRangeConfig( enterprise2NetId, {makeUidRangeParcel(0, TEST_UID)}, /*unused*/ 0); EXPECT_TRUE( mDnsClient.netdService() ->setNetworkAllowlist({nwDefaultUserConfig, nw1UserConfig, nw2UserConfig}) .isOk()); // Verify that DNS is behaving as the setting. struct TestConfig { int uid; const ScopedNetwork& selectedNetwork; bool expectedSuccess; } configs[]{ // clang-format off {TEST_UID, sysDefaultNetwork, false}, {TEST_UID, enterpriseNetwork_1, true}, {TEST_UID, enterpriseNetwork_2, true}, {TEST_UID2, sysDefaultNetwork, true}, {TEST_UID2, enterpriseNetwork_1, true}, {TEST_UID2, enterpriseNetwork_2, true}, // clang-format on }; for (const auto& cfg : configs) { SCOPED_TRACE(fmt::format("Dns over UID {}, selectedNetwork {}", cfg.uid, cfg.selectedNetwork.name())); if (cfg.expectedSuccess) { expectDnsWorksForUid(host_name, cfg.selectedNetwork.netId(), cfg.uid, expectedDnsReply); } else { expectDnsFailedForUid(host_name, cfg.selectedNetwork.netId(), cfg.uid); } } // Clear network restrictions. EXPECT_TRUE(mDnsClient.netdService()->setNetworkAllowlist({}).isOk()); // TEST_UID and TEST_UID2 can both select all networks. for (const auto& cfg : configs) { SCOPED_TRACE(fmt::format("Dns over UID {}, selectedNetwork {}", cfg.uid, cfg.selectedNetwork.name())); expectDnsWorksForUid(host_name, cfg.selectedNetwork.netId(), cfg.uid, expectedDnsReply); } } }