| /* |
| * Copyright 2009 The WebRTC Project Authors. All rights reserved. |
| * |
| * Use of this source code is governed by a BSD-style license |
| * that can be found in the LICENSE file in the root of the source |
| * tree. An additional intellectual property rights grant can be found |
| * in the file PATENTS. All contributing project authors may |
| * be found in the AUTHORS file in the root of the source tree. |
| */ |
| |
| #include <list> |
| #include <memory> |
| |
| #include "absl/memory/memory.h" |
| #include "p2p/base/fake_port_allocator.h" |
| #include "p2p/base/ice_transport_internal.h" |
| #include "p2p/base/mock_async_resolver.h" |
| #include "p2p/base/p2p_transport_channel.h" |
| #include "p2p/base/packet_transport_internal.h" |
| #include "p2p/base/test_relay_server.h" |
| #include "p2p/base/test_stun_server.h" |
| #include "p2p/base/test_turn_server.h" |
| #include "p2p/client/basic_port_allocator.h" |
| #include "rtc_base/checks.h" |
| #include "rtc_base/dscp.h" |
| #include "rtc_base/fake_clock.h" |
| #include "rtc_base/fake_network.h" |
| #include "rtc_base/firewall_socket_server.h" |
| #include "rtc_base/gunit.h" |
| #include "rtc_base/helpers.h" |
| #include "rtc_base/logging.h" |
| #include "rtc_base/nat_server.h" |
| #include "rtc_base/nat_socket_factory.h" |
| #include "rtc_base/proxy_server.h" |
| #include "rtc_base/socket_address.h" |
| #include "rtc_base/ssl_adapter.h" |
| #include "rtc_base/thread.h" |
| #include "rtc_base/virtual_socket_server.h" |
| #include "system_wrappers/include/metrics.h" |
| #include "test/field_trial.h" |
| |
| namespace { |
| |
| using rtc::SocketAddress; |
| using ::testing::_; |
| using ::testing::Assign; |
| using ::testing::Contains; |
| using ::testing::DoAll; |
| using ::testing::InSequence; |
| using ::testing::InvokeWithoutArgs; |
| using ::testing::NiceMock; |
| using ::testing::Return; |
| using ::testing::SetArgPointee; |
| using ::testing::SizeIs; |
| |
| // Default timeout for tests in this file. |
| // Should be large enough for slow buildbots to run the tests reliably. |
| static const int kDefaultTimeout = 10000; |
| static const int kMediumTimeout = 3000; |
| static const int kShortTimeout = 1000; |
| |
| static const int kOnlyLocalPorts = cricket::PORTALLOCATOR_DISABLE_STUN | |
| cricket::PORTALLOCATOR_DISABLE_RELAY | |
| cricket::PORTALLOCATOR_DISABLE_TCP; |
| static const int LOW_RTT = 20; |
| // Addresses on the public internet. |
| static const SocketAddress kPublicAddrs[2] = {SocketAddress("11.11.11.11", 0), |
| SocketAddress("22.22.22.22", 0)}; |
| // IPv6 Addresses on the public internet. |
| static const SocketAddress kIPv6PublicAddrs[2] = { |
| SocketAddress("2400:4030:1:2c00:be30:abcd:efab:cdef", 0), |
| SocketAddress("2600:0:1000:1b03:2e41:38ff:fea6:f2a4", 0)}; |
| // For configuring multihomed clients. |
| static const SocketAddress kAlternateAddrs[2] = { |
| SocketAddress("101.101.101.101", 0), SocketAddress("202.202.202.202", 0)}; |
| static const SocketAddress kIPv6AlternateAddrs[2] = { |
| SocketAddress("2401:4030:1:2c00:be30:abcd:efab:cdef", 0), |
| SocketAddress("2601:0:1000:1b03:2e41:38ff:fea6:f2a4", 0)}; |
| // Addresses for HTTP proxy servers. |
| static const SocketAddress kHttpsProxyAddrs[2] = { |
| SocketAddress("11.11.11.1", 443), SocketAddress("22.22.22.1", 443)}; |
| // Addresses for SOCKS proxy servers. |
| static const SocketAddress kSocksProxyAddrs[2] = { |
| SocketAddress("11.11.11.1", 1080), SocketAddress("22.22.22.1", 1080)}; |
| // Internal addresses for NAT boxes. |
| static const SocketAddress kNatAddrs[2] = {SocketAddress("192.168.1.1", 0), |
| SocketAddress("192.168.2.1", 0)}; |
| // Private addresses inside the NAT private networks. |
| static const SocketAddress kPrivateAddrs[2] = { |
| SocketAddress("192.168.1.11", 0), SocketAddress("192.168.2.22", 0)}; |
| // For cascaded NATs, the internal addresses of the inner NAT boxes. |
| static const SocketAddress kCascadedNatAddrs[2] = { |
| SocketAddress("192.168.10.1", 0), SocketAddress("192.168.20.1", 0)}; |
| // For cascaded NATs, private addresses inside the inner private networks. |
| static const SocketAddress kCascadedPrivateAddrs[2] = { |
| SocketAddress("192.168.10.11", 0), SocketAddress("192.168.20.22", 0)}; |
| // The address of the public STUN server. |
| static const SocketAddress kStunAddr("99.99.99.1", cricket::STUN_SERVER_PORT); |
| // The addresses for the public turn server. |
| static const SocketAddress kTurnUdpIntAddr("99.99.99.3", |
| cricket::STUN_SERVER_PORT); |
| static const SocketAddress kTurnTcpIntAddr("99.99.99.4", |
| cricket::STUN_SERVER_PORT + 1); |
| static const SocketAddress kTurnUdpExtAddr("99.99.99.5", 0); |
| static const cricket::RelayCredentials kRelayCredentials("test", "test"); |
| |
| // Based on ICE_UFRAG_LENGTH |
| const char* kIceUfrag[4] = {"UF00", "UF01", "UF02", "UF03"}; |
| // Based on ICE_PWD_LENGTH |
| const char* kIcePwd[4] = { |
| "TESTICEPWD00000000000000", "TESTICEPWD00000000000001", |
| "TESTICEPWD00000000000002", "TESTICEPWD00000000000003"}; |
| const cricket::IceParameters kIceParams[4] = { |
| {kIceUfrag[0], kIcePwd[0], false}, |
| {kIceUfrag[1], kIcePwd[1], false}, |
| {kIceUfrag[2], kIcePwd[2], false}, |
| {kIceUfrag[3], kIcePwd[3], false}}; |
| |
| const uint64_t kLowTiebreaker = 11111; |
| const uint64_t kHighTiebreaker = 22222; |
| |
| enum { MSG_ADD_CANDIDATES, MSG_REMOVE_CANDIDATES }; |
| |
| cricket::IceConfig CreateIceConfig( |
| int receiving_timeout, |
| cricket::ContinualGatheringPolicy continual_gathering_policy, |
| absl::optional<int> backup_ping_interval = absl::nullopt) { |
| cricket::IceConfig config; |
| config.receiving_timeout = receiving_timeout; |
| config.continual_gathering_policy = continual_gathering_policy; |
| config.backup_connection_ping_interval = backup_ping_interval; |
| return config; |
| } |
| |
| cricket::Candidate CreateUdpCandidate(const std::string& type, |
| const std::string& ip, |
| int port, |
| int priority, |
| const std::string& ufrag = "") { |
| cricket::Candidate c; |
| c.set_address(rtc::SocketAddress(ip, port)); |
| c.set_component(cricket::ICE_CANDIDATE_COMPONENT_DEFAULT); |
| c.set_protocol(cricket::UDP_PROTOCOL_NAME); |
| c.set_priority(priority); |
| c.set_username(ufrag); |
| c.set_type(type); |
| return c; |
| } |
| |
| cricket::BasicPortAllocator* CreateBasicPortAllocator( |
| rtc::NetworkManager* network_manager, |
| const cricket::ServerAddresses& stun_servers, |
| const rtc::SocketAddress& turn_server_udp, |
| const rtc::SocketAddress& turn_server_tcp) { |
| cricket::RelayServerConfig turn_server(cricket::RELAY_TURN); |
| turn_server.credentials = kRelayCredentials; |
| if (!turn_server_udp.IsNil()) { |
| turn_server.ports.push_back( |
| cricket::ProtocolAddress(turn_server_udp, cricket::PROTO_UDP)); |
| } |
| if (!turn_server_tcp.IsNil()) { |
| turn_server.ports.push_back( |
| cricket::ProtocolAddress(turn_server_tcp, cricket::PROTO_TCP)); |
| } |
| std::vector<cricket::RelayServerConfig> turn_servers(1, turn_server); |
| |
| cricket::BasicPortAllocator* allocator = |
| new cricket::BasicPortAllocator(network_manager); |
| allocator->Initialize(); |
| allocator->SetConfiguration(stun_servers, turn_servers, 0, false); |
| return allocator; |
| } |
| } // namespace |
| |
| namespace cricket { |
| |
| // This test simulates 2 P2P endpoints that want to establish connectivity |
| // with each other over various network topologies and conditions, which can be |
| // specified in each individial test. |
| // A virtual network (via VirtualSocketServer) along with virtual firewalls and |
| // NATs (via Firewall/NATSocketServer) are used to simulate the various network |
| // conditions. We can configure the IP addresses of the endpoints, |
| // block various types of connectivity, or add arbitrary levels of NAT. |
| // We also run a STUN server and a relay server on the virtual network to allow |
| // our typical P2P mechanisms to do their thing. |
| // For each case, we expect the P2P stack to eventually settle on a specific |
| // form of connectivity to the other side. The test checks that the P2P |
| // negotiation successfully establishes connectivity within a certain time, |
| // and that the result is what we expect. |
| // Note that this class is a base class for use by other tests, who will provide |
| // specialized test behavior. |
| class P2PTransportChannelTestBase : public ::testing::Test, |
| public rtc::MessageHandler, |
| public sigslot::has_slots<> { |
| public: |
| P2PTransportChannelTestBase() |
| : vss_(new rtc::VirtualSocketServer()), |
| nss_(new rtc::NATSocketServer(vss_.get())), |
| ss_(new rtc::FirewallSocketServer(nss_.get())), |
| main_(ss_.get()), |
| stun_server_(TestStunServer::Create(&main_, kStunAddr)), |
| turn_server_(&main_, kTurnUdpIntAddr, kTurnUdpExtAddr), |
| socks_server1_(ss_.get(), |
| kSocksProxyAddrs[0], |
| ss_.get(), |
| kSocksProxyAddrs[0]), |
| socks_server2_(ss_.get(), |
| kSocksProxyAddrs[1], |
| ss_.get(), |
| kSocksProxyAddrs[1]), |
| force_relay_(false) { |
| ep1_.role_ = ICEROLE_CONTROLLING; |
| ep2_.role_ = ICEROLE_CONTROLLED; |
| |
| ServerAddresses stun_servers; |
| stun_servers.insert(kStunAddr); |
| ep1_.allocator_.reset( |
| CreateBasicPortAllocator(&ep1_.network_manager_, stun_servers, |
| kTurnUdpIntAddr, rtc::SocketAddress())); |
| ep2_.allocator_.reset( |
| CreateBasicPortAllocator(&ep2_.network_manager_, stun_servers, |
| kTurnUdpIntAddr, rtc::SocketAddress())); |
| webrtc::metrics::Reset(); |
| } |
| |
| protected: |
| enum Config { |
| OPEN, // Open to the Internet |
| NAT_FULL_CONE, // NAT, no filtering |
| NAT_ADDR_RESTRICTED, // NAT, must send to an addr to recv |
| NAT_PORT_RESTRICTED, // NAT, must send to an addr+port to recv |
| NAT_SYMMETRIC, // NAT, endpoint-dependent bindings |
| NAT_DOUBLE_CONE, // Double NAT, both cone |
| NAT_SYMMETRIC_THEN_CONE, // Double NAT, symmetric outer, cone inner |
| BLOCK_UDP, // Firewall, UDP in/out blocked |
| BLOCK_UDP_AND_INCOMING_TCP, // Firewall, UDP in/out and TCP in blocked |
| BLOCK_ALL_BUT_OUTGOING_HTTP, // Firewall, only TCP out on 80/443 |
| PROXY_HTTPS, // All traffic through HTTPS proxy |
| PROXY_SOCKS, // All traffic through SOCKS proxy |
| NUM_CONFIGS |
| }; |
| |
| struct Result { |
| Result(const std::string& controlling_type, |
| const std::string& controlling_protocol, |
| const std::string& controlled_type, |
| const std::string& controlled_protocol, |
| int wait) |
| : controlling_type(controlling_type), |
| controlling_protocol(controlling_protocol), |
| controlled_type(controlled_type), |
| controlled_protocol(controlled_protocol), |
| connect_wait(wait) {} |
| |
| // The expected candidate type and protocol of the controlling ICE agent. |
| std::string controlling_type; |
| std::string controlling_protocol; |
| // The expected candidate type and protocol of the controlled ICE agent. |
| std::string controlled_type; |
| std::string controlled_protocol; |
| // How long to wait before the correct candidate pair is selected. |
| int connect_wait; |
| }; |
| |
| struct ChannelData { |
| bool CheckData(const char* data, int len) { |
| bool ret = false; |
| if (!ch_packets_.empty()) { |
| std::string packet = ch_packets_.front(); |
| ret = (packet == std::string(data, len)); |
| ch_packets_.pop_front(); |
| } |
| return ret; |
| } |
| |
| std::string name_; // TODO(?) - Currently not used. |
| std::list<std::string> ch_packets_; |
| std::unique_ptr<P2PTransportChannel> ch_; |
| }; |
| |
| struct CandidatesData : public rtc::MessageData { |
| CandidatesData(IceTransportInternal* ch, const Candidate& c) |
| : channel(ch), candidates(1, c) {} |
| CandidatesData(IceTransportInternal* ch, const std::vector<Candidate>& cc) |
| : channel(ch), candidates(cc) {} |
| IceTransportInternal* channel; |
| Candidates candidates; |
| }; |
| |
| struct Endpoint : public sigslot::has_slots<> { |
| Endpoint() |
| : role_(ICEROLE_UNKNOWN), |
| tiebreaker_(0), |
| role_conflict_(false), |
| save_candidates_(false) {} |
| bool HasTransport(const rtc::PacketTransportInternal* transport) { |
| return (transport == cd1_.ch_.get() || transport == cd2_.ch_.get()); |
| } |
| ChannelData* GetChannelData(rtc::PacketTransportInternal* transport) { |
| if (!HasTransport(transport)) |
| return NULL; |
| if (cd1_.ch_.get() == transport) |
| return &cd1_; |
| else |
| return &cd2_; |
| } |
| |
| void SetIceRole(IceRole role) { role_ = role; } |
| IceRole ice_role() { return role_; } |
| void SetIceTiebreaker(uint64_t tiebreaker) { tiebreaker_ = tiebreaker; } |
| uint64_t GetIceTiebreaker() { return tiebreaker_; } |
| void OnRoleConflict(bool role_conflict) { role_conflict_ = role_conflict; } |
| bool role_conflict() { return role_conflict_; } |
| void SetAllocationStepDelay(uint32_t delay) { |
| allocator_->set_step_delay(delay); |
| } |
| void SetAllowTcpListen(bool allow_tcp_listen) { |
| allocator_->set_allow_tcp_listen(allow_tcp_listen); |
| } |
| |
| void OnIceRegathering(PortAllocatorSession*, IceRegatheringReason reason) { |
| ++ice_regathering_counter_[reason]; |
| } |
| |
| int GetIceRegatheringCountForReason(IceRegatheringReason reason) { |
| return ice_regathering_counter_[reason]; |
| } |
| |
| rtc::FakeNetworkManager network_manager_; |
| std::unique_ptr<BasicPortAllocator> allocator_; |
| webrtc::AsyncResolverFactory* async_resolver_factory_; |
| ChannelData cd1_; |
| ChannelData cd2_; |
| IceRole role_; |
| uint64_t tiebreaker_; |
| bool role_conflict_; |
| bool save_candidates_; |
| std::vector<std::unique_ptr<CandidatesData>> saved_candidates_; |
| bool ready_to_send_ = false; |
| std::map<IceRegatheringReason, int> ice_regathering_counter_; |
| }; |
| |
| ChannelData* GetChannelData(rtc::PacketTransportInternal* transport) { |
| if (ep1_.HasTransport(transport)) |
| return ep1_.GetChannelData(transport); |
| else |
| return ep2_.GetChannelData(transport); |
| } |
| |
| IceParameters IceParamsWithRenomination(const IceParameters& ice, |
| bool renomination) { |
| IceParameters new_ice = ice; |
| new_ice.renomination = renomination; |
| return new_ice; |
| } |
| |
| void CreateChannels(const IceConfig& ep1_config, |
| const IceConfig& ep2_config, |
| bool renomination = false) { |
| IceParameters ice_ep1_cd1_ch = |
| IceParamsWithRenomination(kIceParams[0], renomination); |
| IceParameters ice_ep2_cd1_ch = |
| IceParamsWithRenomination(kIceParams[1], renomination); |
| ep1_.cd1_.ch_.reset(CreateChannel(0, ICE_CANDIDATE_COMPONENT_DEFAULT, |
| ice_ep1_cd1_ch, ice_ep2_cd1_ch)); |
| ep2_.cd1_.ch_.reset(CreateChannel(1, ICE_CANDIDATE_COMPONENT_DEFAULT, |
| ice_ep2_cd1_ch, ice_ep1_cd1_ch)); |
| ep1_.cd1_.ch_->SetIceConfig(ep1_config); |
| ep2_.cd1_.ch_->SetIceConfig(ep2_config); |
| ep1_.cd1_.ch_->MaybeStartGathering(); |
| ep2_.cd1_.ch_->MaybeStartGathering(); |
| ep1_.cd1_.ch_->allocator_session()->SignalIceRegathering.connect( |
| &ep1_, &Endpoint::OnIceRegathering); |
| ep2_.cd1_.ch_->allocator_session()->SignalIceRegathering.connect( |
| &ep2_, &Endpoint::OnIceRegathering); |
| } |
| |
| void CreateChannels() { |
| IceConfig default_config; |
| CreateChannels(default_config, default_config, false); |
| } |
| |
| P2PTransportChannel* CreateChannel(int endpoint, |
| int component, |
| const IceParameters& local_ice, |
| const IceParameters& remote_ice) { |
| P2PTransportChannel* channel = new P2PTransportChannel( |
| "test content name", component, GetAllocator(endpoint), |
| GetEndpoint(endpoint)->async_resolver_factory_); |
| channel->SignalReadyToSend.connect( |
| this, &P2PTransportChannelTestBase::OnReadyToSend); |
| channel->SignalCandidateGathered.connect( |
| this, &P2PTransportChannelTestBase::OnCandidateGathered); |
| channel->SignalCandidatesRemoved.connect( |
| this, &P2PTransportChannelTestBase::OnCandidatesRemoved); |
| channel->SignalReadPacket.connect( |
| this, &P2PTransportChannelTestBase::OnReadPacket); |
| channel->SignalRoleConflict.connect( |
| this, &P2PTransportChannelTestBase::OnRoleConflict); |
| channel->SignalNetworkRouteChanged.connect( |
| this, &P2PTransportChannelTestBase::OnNetworkRouteChanged); |
| channel->SignalSentPacket.connect( |
| this, &P2PTransportChannelTestBase::OnSentPacket); |
| channel->SetIceParameters(local_ice); |
| if (remote_ice_parameter_source_ == FROM_SETICEPARAMETERS) { |
| channel->SetRemoteIceParameters(remote_ice); |
| } |
| channel->SetIceRole(GetEndpoint(endpoint)->ice_role()); |
| channel->SetIceTiebreaker(GetEndpoint(endpoint)->GetIceTiebreaker()); |
| return channel; |
| } |
| void DestroyChannels() { |
| main_.Clear(this); |
| ep1_.cd1_.ch_.reset(); |
| ep2_.cd1_.ch_.reset(); |
| ep1_.cd2_.ch_.reset(); |
| ep2_.cd2_.ch_.reset(); |
| } |
| P2PTransportChannel* ep1_ch1() { return ep1_.cd1_.ch_.get(); } |
| P2PTransportChannel* ep1_ch2() { return ep1_.cd2_.ch_.get(); } |
| P2PTransportChannel* ep2_ch1() { return ep2_.cd1_.ch_.get(); } |
| P2PTransportChannel* ep2_ch2() { return ep2_.cd2_.ch_.get(); } |
| |
| TestTurnServer* test_turn_server() { return &turn_server_; } |
| rtc::VirtualSocketServer* virtual_socket_server() { return vss_.get(); } |
| |
| // Common results. |
| static const Result kLocalUdpToLocalUdp; |
| static const Result kLocalUdpToStunUdp; |
| static const Result kLocalUdpToPrflxUdp; |
| static const Result kPrflxUdpToLocalUdp; |
| static const Result kStunUdpToLocalUdp; |
| static const Result kStunUdpToStunUdp; |
| static const Result kStunUdpToPrflxUdp; |
| static const Result kPrflxUdpToStunUdp; |
| static const Result kLocalUdpToRelayUdp; |
| static const Result kPrflxUdpToRelayUdp; |
| static const Result kRelayUdpToPrflxUdp; |
| static const Result kLocalTcpToLocalTcp; |
| static const Result kLocalTcpToPrflxTcp; |
| static const Result kPrflxTcpToLocalTcp; |
| |
| rtc::NATSocketServer* nat() { return nss_.get(); } |
| rtc::FirewallSocketServer* fw() { return ss_.get(); } |
| |
| Endpoint* GetEndpoint(int endpoint) { |
| if (endpoint == 0) { |
| return &ep1_; |
| } else if (endpoint == 1) { |
| return &ep2_; |
| } else { |
| return NULL; |
| } |
| } |
| BasicPortAllocator* GetAllocator(int endpoint) { |
| return GetEndpoint(endpoint)->allocator_.get(); |
| } |
| void AddAddress(int endpoint, const SocketAddress& addr) { |
| GetEndpoint(endpoint)->network_manager_.AddInterface(addr); |
| } |
| void AddAddress(int endpoint, |
| const SocketAddress& addr, |
| const std::string& ifname, |
| rtc::AdapterType adapter_type) { |
| GetEndpoint(endpoint)->network_manager_.AddInterface(addr, ifname, |
| adapter_type); |
| } |
| void RemoveAddress(int endpoint, const SocketAddress& addr) { |
| GetEndpoint(endpoint)->network_manager_.RemoveInterface(addr); |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, addr); |
| } |
| void SetProxy(int endpoint, rtc::ProxyType type) { |
| rtc::ProxyInfo info; |
| info.type = type; |
| info.address = (type == rtc::PROXY_HTTPS) ? kHttpsProxyAddrs[endpoint] |
| : kSocksProxyAddrs[endpoint]; |
| GetAllocator(endpoint)->set_proxy("unittest/1.0", info); |
| } |
| void SetAllocatorFlags(int endpoint, int flags) { |
| GetAllocator(endpoint)->set_flags(flags); |
| } |
| void SetIceRole(int endpoint, IceRole role) { |
| GetEndpoint(endpoint)->SetIceRole(role); |
| } |
| void SetIceTiebreaker(int endpoint, uint64_t tiebreaker) { |
| GetEndpoint(endpoint)->SetIceTiebreaker(tiebreaker); |
| } |
| bool GetRoleConflict(int endpoint) { |
| return GetEndpoint(endpoint)->role_conflict(); |
| } |
| void SetAllocationStepDelay(int endpoint, uint32_t delay) { |
| return GetEndpoint(endpoint)->SetAllocationStepDelay(delay); |
| } |
| void SetAllowTcpListen(int endpoint, bool allow_tcp_listen) { |
| return GetEndpoint(endpoint)->SetAllowTcpListen(allow_tcp_listen); |
| } |
| |
| // Return true if the approprite parts of the expected Result, based |
| // on the local and remote candidate of ep1_ch1, match. This can be |
| // used in an EXPECT_TRUE_WAIT. |
| bool CheckCandidate1(const Result& expected) { |
| const std::string& local_type = LocalCandidate(ep1_ch1())->type(); |
| const std::string& local_protocol = LocalCandidate(ep1_ch1())->protocol(); |
| const std::string& remote_type = RemoteCandidate(ep1_ch1())->type(); |
| const std::string& remote_protocol = RemoteCandidate(ep1_ch1())->protocol(); |
| return (local_protocol == expected.controlling_protocol && |
| remote_protocol == expected.controlled_protocol && |
| local_type == expected.controlling_type && |
| remote_type == expected.controlled_type); |
| } |
| |
| // EXPECT_EQ on the approprite parts of the expected Result, based |
| // on the local and remote candidate of ep1_ch1. This is like |
| // CheckCandidate1, except that it will provide more detail about |
| // what didn't match. |
| void ExpectCandidate1(const Result& expected) { |
| if (CheckCandidate1(expected)) { |
| return; |
| } |
| |
| const std::string& local_type = LocalCandidate(ep1_ch1())->type(); |
| const std::string& local_protocol = LocalCandidate(ep1_ch1())->protocol(); |
| const std::string& remote_type = RemoteCandidate(ep1_ch1())->type(); |
| const std::string& remote_protocol = RemoteCandidate(ep1_ch1())->protocol(); |
| EXPECT_EQ(expected.controlling_type, local_type); |
| EXPECT_EQ(expected.controlled_type, remote_type); |
| EXPECT_EQ(expected.controlling_protocol, local_protocol); |
| EXPECT_EQ(expected.controlled_protocol, remote_protocol); |
| } |
| |
| // Return true if the approprite parts of the expected Result, based |
| // on the local and remote candidate of ep2_ch1, match. This can be |
| // used in an EXPECT_TRUE_WAIT. |
| bool CheckCandidate2(const Result& expected) { |
| const std::string& local_type = LocalCandidate(ep2_ch1())->type(); |
| const std::string& local_protocol = LocalCandidate(ep2_ch1())->protocol(); |
| const std::string& remote_type = RemoteCandidate(ep2_ch1())->type(); |
| const std::string& remote_protocol = RemoteCandidate(ep2_ch1())->protocol(); |
| return (local_protocol == expected.controlled_protocol && |
| remote_protocol == expected.controlling_protocol && |
| local_type == expected.controlled_type && |
| remote_type == expected.controlling_type); |
| } |
| |
| // EXPECT_EQ on the approprite parts of the expected Result, based |
| // on the local and remote candidate of ep2_ch1. This is like |
| // CheckCandidate2, except that it will provide more detail about |
| // what didn't match. |
| void ExpectCandidate2(const Result& expected) { |
| if (CheckCandidate2(expected)) { |
| return; |
| } |
| |
| const std::string& local_type = LocalCandidate(ep2_ch1())->type(); |
| const std::string& local_protocol = LocalCandidate(ep2_ch1())->protocol(); |
| const std::string& remote_type = RemoteCandidate(ep2_ch1())->type(); |
| const std::string& remote_protocol = RemoteCandidate(ep2_ch1())->protocol(); |
| EXPECT_EQ(expected.controlled_type, local_type); |
| EXPECT_EQ(expected.controlling_type, remote_type); |
| EXPECT_EQ(expected.controlled_protocol, local_protocol); |
| EXPECT_EQ(expected.controlling_protocol, remote_protocol); |
| } |
| |
| void Test(const Result& expected) { |
| rtc::ScopedFakeClock clock; |
| int64_t connect_start = rtc::TimeMillis(); |
| int64_t connect_time; |
| |
| // Create the channels and wait for them to connect. |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1() != NULL && ep2_ch1() != NULL && ep1_ch1()->receiving() && |
| ep1_ch1()->writable() && ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| expected.connect_wait + kShortTimeout, clock); |
| connect_time = rtc::TimeMillis() - connect_start; |
| if (connect_time < expected.connect_wait) { |
| RTC_LOG(LS_INFO) << "Connect time: " << connect_time << " ms"; |
| } else { |
| RTC_LOG(LS_INFO) << "Connect time: TIMEOUT (" << expected.connect_wait |
| << " ms)"; |
| } |
| |
| // Allow a few turns of the crank for the selected connections to emerge. |
| // This may take up to 2 seconds. |
| if (ep1_ch1()->selected_connection() && ep2_ch1()->selected_connection()) { |
| int64_t converge_start = rtc::TimeMillis(); |
| int64_t converge_time; |
| // Verifying local and remote channel selected connection information. |
| // This is done only for the RFC 5245 as controlled agent will use |
| // USE-CANDIDATE from controlling (ep1) agent. We can easily predict from |
| // EP1 result matrix. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| CheckCandidate1(expected) && CheckCandidate2(expected), |
| kMediumTimeout, clock); |
| // Also do EXPECT_EQ on each part so that failures are more verbose. |
| ExpectCandidate1(expected); |
| ExpectCandidate2(expected); |
| |
| converge_time = rtc::TimeMillis() - converge_start; |
| int64_t converge_wait = 2000; |
| if (converge_time < converge_wait) { |
| RTC_LOG(LS_INFO) << "Converge time: " << converge_time << " ms"; |
| } else { |
| RTC_LOG(LS_INFO) << "Converge time: TIMEOUT (" << converge_wait |
| << " ms)"; |
| } |
| } |
| // Try sending some data to other end. |
| TestSendRecv(&clock); |
| |
| // Destroy the channels, and wait for them to be fully cleaned up. |
| DestroyChannels(); |
| } |
| |
| void TestSendRecv(rtc::ThreadProcessingFakeClock* clock) { |
| for (int i = 0; i < 10; ++i) { |
| const char* data = "ABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890"; |
| int len = static_cast<int>(strlen(data)); |
| // local_channel1 <==> remote_channel1 |
| EXPECT_EQ_SIMULATED_WAIT(len, SendData(ep1_ch1(), data, len), |
| kMediumTimeout, *clock); |
| EXPECT_TRUE_SIMULATED_WAIT(CheckDataOnChannel(ep2_ch1(), data, len), |
| kMediumTimeout, *clock); |
| EXPECT_EQ_SIMULATED_WAIT(len, SendData(ep2_ch1(), data, len), |
| kMediumTimeout, *clock); |
| EXPECT_TRUE_SIMULATED_WAIT(CheckDataOnChannel(ep1_ch1(), data, len), |
| kMediumTimeout, *clock); |
| } |
| } |
| |
| // This test waits for the transport to become receiving and writable on both |
| // end points. Once they are, the end points set new local ice parameters and |
| // restart the ice gathering. Finally it waits for the transport to select a |
| // new connection using the newly generated ice candidates. |
| // Before calling this function the end points must be configured. |
| void TestHandleIceUfragPasswordChanged() { |
| rtc::ScopedFakeClock clock; |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[1]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[0]); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| |
| const Candidate* old_local_candidate1 = LocalCandidate(ep1_ch1()); |
| const Candidate* old_local_candidate2 = LocalCandidate(ep2_ch1()); |
| const Candidate* old_remote_candidate1 = RemoteCandidate(ep1_ch1()); |
| const Candidate* old_remote_candidate2 = RemoteCandidate(ep2_ch1()); |
| |
| ep1_ch1()->SetIceParameters(kIceParams[2]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->MaybeStartGathering(); |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep2_ch1()->MaybeStartGathering(); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(LocalCandidate(ep1_ch1())->generation() != |
| old_local_candidate1->generation(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT(LocalCandidate(ep2_ch1())->generation() != |
| old_local_candidate2->generation(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT(RemoteCandidate(ep1_ch1())->generation() != |
| old_remote_candidate1->generation(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT(RemoteCandidate(ep2_ch1())->generation() != |
| old_remote_candidate2->generation(), |
| kMediumTimeout, clock); |
| EXPECT_EQ(1u, RemoteCandidate(ep2_ch1())->generation()); |
| EXPECT_EQ(1u, RemoteCandidate(ep1_ch1())->generation()); |
| } |
| |
| void TestSignalRoleConflict() { |
| rtc::ScopedFakeClock clock; |
| // Default EP1 is in controlling state. |
| SetIceTiebreaker(0, kLowTiebreaker); |
| |
| SetIceRole(1, ICEROLE_CONTROLLING); |
| SetIceTiebreaker(1, kHighTiebreaker); |
| |
| // Creating channels with both channels role set to CONTROLLING. |
| CreateChannels(); |
| // Since both the channels initiated with controlling state and channel2 |
| // has higher tiebreaker value, channel1 should receive SignalRoleConflict. |
| EXPECT_TRUE_SIMULATED_WAIT(GetRoleConflict(0), kShortTimeout, clock); |
| EXPECT_FALSE(GetRoleConflict(1)); |
| |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| kShortTimeout, clock); |
| |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection()); |
| |
| TestSendRecv(&clock); |
| } |
| |
| void TestPacketInfoIsSet(rtc::PacketInfo info) { |
| EXPECT_NE(info.packet_type, rtc::PacketType::kUnknown); |
| EXPECT_NE(info.protocol, rtc::PacketInfoProtocolType::kUnknown); |
| EXPECT_TRUE(info.network_id.has_value()); |
| } |
| |
| void OnReadyToSend(rtc::PacketTransportInternal* transport) { |
| GetEndpoint(transport)->ready_to_send_ = true; |
| } |
| |
| // We pass the candidates directly to the other side. |
| void OnCandidateGathered(IceTransportInternal* ch, const Candidate& c) { |
| if (force_relay_ && c.type() != RELAY_PORT_TYPE) |
| return; |
| |
| if (GetEndpoint(ch)->save_candidates_) { |
| GetEndpoint(ch)->saved_candidates_.push_back( |
| std::unique_ptr<CandidatesData>(new CandidatesData(ch, c))); |
| } else { |
| main_.Post(RTC_FROM_HERE, this, MSG_ADD_CANDIDATES, |
| new CandidatesData(ch, c)); |
| } |
| } |
| |
| void OnNetworkRouteChanged(absl::optional<rtc::NetworkRoute> network_route) { |
| // If the |network_route| is unset, don't count. This is used in the case |
| // when the network on remote side is down, the signal will be fired with an |
| // unset network route and it shouldn't trigger a connection switch. |
| if (network_route) { |
| ++selected_candidate_pair_switches_; |
| } |
| } |
| |
| int reset_selected_candidate_pair_switches() { |
| int switches = selected_candidate_pair_switches_; |
| selected_candidate_pair_switches_ = 0; |
| return switches; |
| } |
| |
| void PauseCandidates(int endpoint) { |
| GetEndpoint(endpoint)->save_candidates_ = true; |
| } |
| |
| void OnCandidatesRemoved(IceTransportInternal* ch, |
| const std::vector<Candidate>& candidates) { |
| // Candidate removals are not paused. |
| CandidatesData* candidates_data = new CandidatesData(ch, candidates); |
| main_.Post(RTC_FROM_HERE, this, MSG_REMOVE_CANDIDATES, candidates_data); |
| } |
| |
| // Tcp candidate verification has to be done when they are generated. |
| void VerifySavedTcpCandidates(int endpoint, const std::string& tcptype) { |
| for (auto& data : GetEndpoint(endpoint)->saved_candidates_) { |
| for (auto& candidate : data->candidates) { |
| EXPECT_EQ(candidate.protocol(), TCP_PROTOCOL_NAME); |
| EXPECT_EQ(candidate.tcptype(), tcptype); |
| if (candidate.tcptype() == TCPTYPE_ACTIVE_STR) { |
| EXPECT_EQ(candidate.address().port(), DISCARD_PORT); |
| } else if (candidate.tcptype() == TCPTYPE_PASSIVE_STR) { |
| EXPECT_NE(candidate.address().port(), DISCARD_PORT); |
| } else { |
| FAIL() << "Unknown tcptype: " << candidate.tcptype(); |
| } |
| } |
| } |
| } |
| |
| void ResumeCandidates(int endpoint) { |
| Endpoint* ed = GetEndpoint(endpoint); |
| for (auto& candidate : ed->saved_candidates_) { |
| main_.Post(RTC_FROM_HERE, this, MSG_ADD_CANDIDATES, candidate.release()); |
| } |
| ed->saved_candidates_.clear(); |
| ed->save_candidates_ = false; |
| } |
| |
| void OnMessage(rtc::Message* msg) { |
| switch (msg->message_id) { |
| case MSG_ADD_CANDIDATES: { |
| std::unique_ptr<CandidatesData> data( |
| static_cast<CandidatesData*>(msg->pdata)); |
| P2PTransportChannel* rch = GetRemoteChannel(data->channel); |
| if (!rch) { |
| return; |
| } |
| for (auto& c : data->candidates) { |
| if (remote_ice_parameter_source_ != FROM_CANDIDATE) { |
| c.set_username(""); |
| c.set_password(""); |
| } |
| RTC_LOG(LS_INFO) << "Candidate(" << data->channel->component() << "->" |
| << rch->component() << "): " << c.ToString(); |
| rch->AddRemoteCandidate(c); |
| } |
| break; |
| } |
| case MSG_REMOVE_CANDIDATES: { |
| std::unique_ptr<CandidatesData> data( |
| static_cast<CandidatesData*>(msg->pdata)); |
| P2PTransportChannel* rch = GetRemoteChannel(data->channel); |
| if (!rch) { |
| return; |
| } |
| for (Candidate& c : data->candidates) { |
| RTC_LOG(LS_INFO) << "Removed remote candidate " << c.ToString(); |
| rch->RemoveRemoteCandidate(c); |
| } |
| break; |
| } |
| } |
| } |
| |
| void OnReadPacket(rtc::PacketTransportInternal* transport, |
| const char* data, |
| size_t len, |
| const int64_t& /* packet_time_us */, |
| int flags) { |
| std::list<std::string>& packets = GetPacketList(transport); |
| packets.push_front(std::string(data, len)); |
| } |
| |
| void OnRoleConflict(IceTransportInternal* channel) { |
| GetEndpoint(channel)->OnRoleConflict(true); |
| IceRole new_role = GetEndpoint(channel)->ice_role() == ICEROLE_CONTROLLING |
| ? ICEROLE_CONTROLLED |
| : ICEROLE_CONTROLLING; |
| channel->SetIceRole(new_role); |
| } |
| |
| void OnSentPacket(rtc::PacketTransportInternal* transport, |
| const rtc::SentPacket& packet) { |
| TestPacketInfoIsSet(packet.info); |
| } |
| |
| int SendData(IceTransportInternal* channel, const char* data, size_t len) { |
| rtc::PacketOptions options; |
| return channel->SendPacket(data, len, options, 0); |
| } |
| bool CheckDataOnChannel(IceTransportInternal* channel, |
| const char* data, |
| int len) { |
| return GetChannelData(channel)->CheckData(data, len); |
| } |
| static const Candidate* LocalCandidate(P2PTransportChannel* ch) { |
| return (ch && ch->selected_connection()) |
| ? &ch->selected_connection()->local_candidate() |
| : NULL; |
| } |
| static const Candidate* RemoteCandidate(P2PTransportChannel* ch) { |
| return (ch && ch->selected_connection()) |
| ? &ch->selected_connection()->remote_candidate() |
| : NULL; |
| } |
| Endpoint* GetEndpoint(rtc::PacketTransportInternal* transport) { |
| if (ep1_.HasTransport(transport)) { |
| return &ep1_; |
| } else if (ep2_.HasTransport(transport)) { |
| return &ep2_; |
| } else { |
| return NULL; |
| } |
| } |
| P2PTransportChannel* GetRemoteChannel(IceTransportInternal* ch) { |
| if (ch == ep1_ch1()) |
| return ep2_ch1(); |
| else if (ch == ep1_ch2()) |
| return ep2_ch2(); |
| else if (ch == ep2_ch1()) |
| return ep1_ch1(); |
| else if (ch == ep2_ch2()) |
| return ep1_ch2(); |
| else |
| return NULL; |
| } |
| std::list<std::string>& GetPacketList( |
| rtc::PacketTransportInternal* transport) { |
| return GetChannelData(transport)->ch_packets_; |
| } |
| |
| enum RemoteIceParameterSource { FROM_CANDIDATE, FROM_SETICEPARAMETERS }; |
| |
| // How does the test pass ICE parameters to the P2PTransportChannel? |
| // On the candidate itself, or through SetRemoteIceParameters? |
| // Goes through the candidate itself by default. |
| void set_remote_ice_parameter_source(RemoteIceParameterSource source) { |
| remote_ice_parameter_source_ = source; |
| } |
| |
| void set_force_relay(bool relay) { force_relay_ = relay; } |
| |
| void ConnectSignalNominated(Connection* conn) { |
| conn->SignalNominated.connect(this, |
| &P2PTransportChannelTestBase::OnNominated); |
| } |
| |
| void OnNominated(Connection* conn) { nominated_ = true; } |
| bool nominated() { return nominated_; } |
| |
| private: |
| std::unique_ptr<rtc::VirtualSocketServer> vss_; |
| std::unique_ptr<rtc::NATSocketServer> nss_; |
| std::unique_ptr<rtc::FirewallSocketServer> ss_; |
| rtc::AutoSocketServerThread main_; |
| std::unique_ptr<TestStunServer> stun_server_; |
| TestTurnServer turn_server_; |
| rtc::SocksProxyServer socks_server1_; |
| rtc::SocksProxyServer socks_server2_; |
| Endpoint ep1_; |
| Endpoint ep2_; |
| RemoteIceParameterSource remote_ice_parameter_source_ = FROM_CANDIDATE; |
| bool force_relay_; |
| int selected_candidate_pair_switches_ = 0; |
| |
| bool nominated_ = false; |
| }; |
| |
| // The tests have only a few outcomes, which we predefine. |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalUdpToLocalUdp("local", |
| "udp", |
| "local", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalUdpToStunUdp("local", |
| "udp", |
| "stun", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalUdpToPrflxUdp("local", |
| "udp", |
| "prflx", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kPrflxUdpToLocalUdp("prflx", |
| "udp", |
| "local", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kStunUdpToLocalUdp("stun", |
| "udp", |
| "local", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kStunUdpToStunUdp("stun", |
| "udp", |
| "stun", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kStunUdpToPrflxUdp("stun", |
| "udp", |
| "prflx", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kPrflxUdpToStunUdp("prflx", |
| "udp", |
| "stun", |
| "udp", |
| 1000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalUdpToRelayUdp("local", |
| "udp", |
| "relay", |
| "udp", |
| 2000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kPrflxUdpToRelayUdp("prflx", |
| "udp", |
| "relay", |
| "udp", |
| 2000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kRelayUdpToPrflxUdp("relay", |
| "udp", |
| "prflx", |
| "udp", |
| 2000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalTcpToLocalTcp("local", |
| "tcp", |
| "local", |
| "tcp", |
| 3000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kLocalTcpToPrflxTcp("local", |
| "tcp", |
| "prflx", |
| "tcp", |
| 3000); |
| const P2PTransportChannelTestBase::Result |
| P2PTransportChannelTestBase::kPrflxTcpToLocalTcp("prflx", |
| "tcp", |
| "local", |
| "tcp", |
| 3000); |
| |
| // Test the matrix of all the connectivity types we expect to see in the wild. |
| // Just test every combination of the configs in the Config enum. |
| class P2PTransportChannelTest : public P2PTransportChannelTestBase { |
| protected: |
| static const Result* kMatrix[NUM_CONFIGS][NUM_CONFIGS]; |
| void ConfigureEndpoints(Config config1, |
| Config config2, |
| int allocator_flags1, |
| int allocator_flags2) { |
| ConfigureEndpoint(0, config1); |
| SetAllocatorFlags(0, allocator_flags1); |
| SetAllocationStepDelay(0, kMinimumStepDelay); |
| ConfigureEndpoint(1, config2); |
| SetAllocatorFlags(1, allocator_flags2); |
| SetAllocationStepDelay(1, kMinimumStepDelay); |
| |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| } |
| void ConfigureEndpoint(int endpoint, Config config) { |
| switch (config) { |
| case OPEN: |
| AddAddress(endpoint, kPublicAddrs[endpoint]); |
| break; |
| case NAT_FULL_CONE: |
| case NAT_ADDR_RESTRICTED: |
| case NAT_PORT_RESTRICTED: |
| case NAT_SYMMETRIC: |
| AddAddress(endpoint, kPrivateAddrs[endpoint]); |
| // Add a single NAT of the desired type |
| nat() |
| ->AddTranslator(kPublicAddrs[endpoint], kNatAddrs[endpoint], |
| static_cast<rtc::NATType>(config - NAT_FULL_CONE)) |
| ->AddClient(kPrivateAddrs[endpoint]); |
| break; |
| case NAT_DOUBLE_CONE: |
| case NAT_SYMMETRIC_THEN_CONE: |
| AddAddress(endpoint, kCascadedPrivateAddrs[endpoint]); |
| // Add a two cascaded NATs of the desired types |
| nat() |
| ->AddTranslator(kPublicAddrs[endpoint], kNatAddrs[endpoint], |
| (config == NAT_DOUBLE_CONE) ? rtc::NAT_OPEN_CONE |
| : rtc::NAT_SYMMETRIC) |
| ->AddTranslator(kPrivateAddrs[endpoint], |
| kCascadedNatAddrs[endpoint], rtc::NAT_OPEN_CONE) |
| ->AddClient(kCascadedPrivateAddrs[endpoint]); |
| break; |
| case BLOCK_UDP: |
| case BLOCK_UDP_AND_INCOMING_TCP: |
| case BLOCK_ALL_BUT_OUTGOING_HTTP: |
| case PROXY_HTTPS: |
| case PROXY_SOCKS: |
| AddAddress(endpoint, kPublicAddrs[endpoint]); |
| // Block all UDP |
| fw()->AddRule(false, rtc::FP_UDP, rtc::FD_ANY, kPublicAddrs[endpoint]); |
| if (config == BLOCK_UDP_AND_INCOMING_TCP) { |
| // Block TCP inbound to the endpoint |
| fw()->AddRule(false, rtc::FP_TCP, SocketAddress(), |
| kPublicAddrs[endpoint]); |
| } else if (config == BLOCK_ALL_BUT_OUTGOING_HTTP) { |
| // Block all TCP to/from the endpoint except 80/443 out |
| fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint], |
| SocketAddress(rtc::IPAddress(INADDR_ANY), 80)); |
| fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint], |
| SocketAddress(rtc::IPAddress(INADDR_ANY), 443)); |
| fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY, |
| kPublicAddrs[endpoint]); |
| } else if (config == PROXY_HTTPS) { |
| // Block all TCP to/from the endpoint except to the proxy server |
| fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint], |
| kHttpsProxyAddrs[endpoint]); |
| fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY, |
| kPublicAddrs[endpoint]); |
| SetProxy(endpoint, rtc::PROXY_HTTPS); |
| } else if (config == PROXY_SOCKS) { |
| // Block all TCP to/from the endpoint except to the proxy server |
| fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint], |
| kSocksProxyAddrs[endpoint]); |
| fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY, |
| kPublicAddrs[endpoint]); |
| SetProxy(endpoint, rtc::PROXY_SOCKS5); |
| } |
| break; |
| default: |
| RTC_NOTREACHED(); |
| break; |
| } |
| } |
| }; |
| |
| // Shorthands for use in the test matrix. |
| #define LULU &kLocalUdpToLocalUdp |
| #define LUSU &kLocalUdpToStunUdp |
| #define LUPU &kLocalUdpToPrflxUdp |
| #define PULU &kPrflxUdpToLocalUdp |
| #define SULU &kStunUdpToLocalUdp |
| #define SUSU &kStunUdpToStunUdp |
| #define SUPU &kStunUdpToPrflxUdp |
| #define PUSU &kPrflxUdpToStunUdp |
| #define LURU &kLocalUdpToRelayUdp |
| #define PURU &kPrflxUdpToRelayUdp |
| #define RUPU &kRelayUdpToPrflxUdp |
| #define LTLT &kLocalTcpToLocalTcp |
| #define LTPT &kLocalTcpToPrflxTcp |
| #define PTLT &kPrflxTcpToLocalTcp |
| // TODO(?): Enable these once TestRelayServer can accept external TCP. |
| #define LTRT NULL |
| #define LSRS NULL |
| |
| // Test matrix. Originator behavior defined by rows, receiever by columns. |
| |
| // TODO(?): Fix NULLs caused by lack of TCP support in NATSocket. |
| // TODO(?): Fix NULLs caused by no HTTP proxy support. |
| // TODO(?): Rearrange rows/columns from best to worst. |
| const P2PTransportChannelTest::Result* |
| P2PTransportChannelTest::kMatrix[NUM_CONFIGS][NUM_CONFIGS] = { |
| // OPEN CONE ADDR PORT SYMM 2CON SCON !UDP !TCP HTTP PRXH |
| // PRXS |
| /*OP*/ {LULU, LUSU, LUSU, LUSU, LUPU, LUSU, LUPU, LTPT, LTPT, LSRS, |
| NULL, LTPT}, |
| /*CO*/ |
| {SULU, SUSU, SUSU, SUSU, SUPU, SUSU, SUPU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*AD*/ |
| {SULU, SUSU, SUSU, SUSU, SUPU, SUSU, SUPU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*PO*/ |
| {SULU, SUSU, SUSU, SUSU, RUPU, SUSU, RUPU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*SY*/ |
| {PULU, PUSU, PUSU, PURU, PURU, PUSU, PURU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*2C*/ |
| {SULU, SUSU, SUSU, SUSU, SUPU, SUSU, SUPU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*SC*/ |
| {PULU, PUSU, PUSU, PURU, PURU, PUSU, PURU, NULL, NULL, LSRS, NULL, |
| LTRT}, |
| /*!U*/ |
| {LTPT, NULL, NULL, NULL, NULL, NULL, NULL, LTPT, LTPT, LSRS, NULL, |
| LTRT}, |
| /*!T*/ |
| {PTLT, NULL, NULL, NULL, NULL, NULL, NULL, PTLT, LTRT, LSRS, NULL, |
| LTRT}, |
| /*HT*/ |
| {LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, NULL, |
| LSRS}, |
| /*PR*/ |
| {NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, |
| NULL}, |
| /*PR*/ |
| {LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LSRS, NULL, |
| LTRT}, |
| }; |
| |
| // The actual tests that exercise all the various configurations. |
| // Test names are of the form P2PTransportChannelTest_TestOPENToNAT_FULL_CONE |
| #define P2P_TEST_DECLARATION(x, y, z) \ |
| TEST_F(P2PTransportChannelTest, z##Test##x##To##y) { \ |
| ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_SOCKET, \ |
| PORTALLOCATOR_ENABLE_SHARED_SOCKET); \ |
| if (kMatrix[x][y] != NULL) \ |
| Test(*kMatrix[x][y]); \ |
| else \ |
| RTC_LOG(LS_WARNING) << "Not yet implemented"; \ |
| } |
| |
| #define P2P_TEST(x, y) P2P_TEST_DECLARATION(x, y, /* empty argument */) |
| |
| #define P2P_TEST_SET(x) \ |
| P2P_TEST(x, OPEN) \ |
| P2P_TEST(x, NAT_FULL_CONE) \ |
| P2P_TEST(x, NAT_ADDR_RESTRICTED) \ |
| P2P_TEST(x, NAT_PORT_RESTRICTED) \ |
| P2P_TEST(x, NAT_SYMMETRIC) \ |
| P2P_TEST(x, NAT_DOUBLE_CONE) \ |
| P2P_TEST(x, NAT_SYMMETRIC_THEN_CONE) \ |
| P2P_TEST(x, BLOCK_UDP) \ |
| P2P_TEST(x, BLOCK_UDP_AND_INCOMING_TCP) \ |
| P2P_TEST(x, BLOCK_ALL_BUT_OUTGOING_HTTP) \ |
| P2P_TEST(x, PROXY_HTTPS) \ |
| P2P_TEST(x, PROXY_SOCKS) |
| |
| P2P_TEST_SET(OPEN) |
| P2P_TEST_SET(NAT_FULL_CONE) |
| P2P_TEST_SET(NAT_ADDR_RESTRICTED) |
| P2P_TEST_SET(NAT_PORT_RESTRICTED) |
| P2P_TEST_SET(NAT_SYMMETRIC) |
| P2P_TEST_SET(NAT_DOUBLE_CONE) |
| P2P_TEST_SET(NAT_SYMMETRIC_THEN_CONE) |
| P2P_TEST_SET(BLOCK_UDP) |
| P2P_TEST_SET(BLOCK_UDP_AND_INCOMING_TCP) |
| P2P_TEST_SET(BLOCK_ALL_BUT_OUTGOING_HTTP) |
| P2P_TEST_SET(PROXY_HTTPS) |
| P2P_TEST_SET(PROXY_SOCKS) |
| |
| // Test that we restart candidate allocation when local ufrag&pwd changed. |
| // Standard Ice protocol is used. |
| TEST_F(P2PTransportChannelTest, HandleUfragPwdChange) { |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| CreateChannels(); |
| TestHandleIceUfragPasswordChanged(); |
| DestroyChannels(); |
| } |
| |
| // Same as above test, but with a symmetric NAT. |
| // We should end up with relay<->prflx candidate pairs, with generation "1". |
| TEST_F(P2PTransportChannelTest, HandleUfragPwdChangeSymmetricNat) { |
| ConfigureEndpoints(NAT_SYMMETRIC, NAT_SYMMETRIC, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| CreateChannels(); |
| TestHandleIceUfragPasswordChanged(); |
| DestroyChannels(); |
| } |
| |
| // Test the operation of GetStats. |
| TEST_F(P2PTransportChannelTest, GetStats) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| TestSendRecv(&clock); |
| ConnectionInfos infos; |
| CandidateStatsList candidate_stats_list; |
| ASSERT_TRUE(ep1_ch1()->GetStats(&infos, &candidate_stats_list)); |
| ASSERT_GE(infos.size(), 1u); |
| ASSERT_GE(candidate_stats_list.size(), 1u); |
| ConnectionInfo* best_conn_info = nullptr; |
| for (ConnectionInfo& info : infos) { |
| if (info.best_connection) { |
| best_conn_info = &info; |
| break; |
| } |
| } |
| ASSERT_TRUE(best_conn_info != nullptr); |
| EXPECT_TRUE(best_conn_info->new_connection); |
| EXPECT_TRUE(best_conn_info->receiving); |
| EXPECT_TRUE(best_conn_info->writable); |
| EXPECT_FALSE(best_conn_info->timeout); |
| EXPECT_EQ(10U, best_conn_info->sent_total_packets); |
| EXPECT_EQ(0U, best_conn_info->sent_discarded_packets); |
| EXPECT_EQ(10 * 36U, best_conn_info->sent_total_bytes); |
| EXPECT_EQ(10 * 36U, best_conn_info->recv_total_bytes); |
| DestroyChannels(); |
| } |
| |
| // Tests that UMAs are recorded when ICE restarts while the channel |
| // is disconnected. |
| TEST_F(P2PTransportChannelTest, TestUMAIceRestartWhileDisconnected) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| |
| // Drop all packets so that both channels become not writable. |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| const int kWriteTimeoutDelay = 8000; |
| EXPECT_TRUE_SIMULATED_WAIT(!ep1_ch1()->writable() && !ep2_ch1()->writable(), |
| kWriteTimeoutDelay, clock); |
| |
| ep1_ch1()->SetIceParameters(kIceParams[2]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(1, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::DISCONNECTED))); |
| |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep2_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(2, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::DISCONNECTED))); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that UMAs are recorded when ICE restarts while the channel |
| // is connected. |
| TEST_F(P2PTransportChannelTest, TestUMAIceRestartWhileConnected) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| |
| ep1_ch1()->SetIceParameters(kIceParams[2]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(1, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::CONNECTED))); |
| |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep2_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(2, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::CONNECTED))); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that UMAs are recorded when ICE restarts while the channel |
| // is connecting. |
| TEST_F(P2PTransportChannelTest, TestUMAIceRestartWhileConnecting) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| // Create the channels without waiting for them to become connected. |
| CreateChannels(); |
| |
| ep1_ch1()->SetIceParameters(kIceParams[2]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(1, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::CONNECTING))); |
| |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep2_ch1()->MaybeStartGathering(); |
| EXPECT_EQ(2, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRestartState", |
| static_cast<int>(IceRestartState::CONNECTING))); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that a UMA on ICE regathering is recorded when there is a network |
| // change if and only if continual gathering is enabled. |
| TEST_F(P2PTransportChannelTest, |
| TestIceRegatheringReasonContinualGatheringByNetworkChange) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| // ep1 gathers continually but ep2 does not. |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| IceConfig default_config; |
| CreateChannels(continual_gathering_config, default_config); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| |
| // Adding address in ep1 will trigger continual gathering. |
| AddAddress(0, kAlternateAddrs[0]); |
| EXPECT_EQ_SIMULATED_WAIT(1, |
| GetEndpoint(0)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::NETWORK_CHANGE), |
| kDefaultTimeout, clock); |
| |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep2_ch1()->MaybeStartGathering(); |
| |
| AddAddress(1, kAlternateAddrs[1]); |
| SIMULATED_WAIT(false, kDefaultTimeout, clock); |
| // ep2 has not enabled continual gathering. |
| EXPECT_EQ(0, GetEndpoint(1)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::NETWORK_CHANGE)); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that a UMA on ICE regathering is recorded when there is a network |
| // failure if and only if continual gathering is enabled. |
| TEST_F(P2PTransportChannelTest, |
| TestIceRegatheringReasonContinualGatheringByNetworkFailure) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| // ep1 gathers continually but ep2 does not. |
| IceConfig config1 = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| config1.regather_on_failed_networks_interval = 2000; |
| IceConfig config2; |
| config2.regather_on_failed_networks_interval = 2000; |
| CreateChannels(config1, config2); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| // Timeout value such that all connections are deleted. |
| const int kNetworkFailureTimeout = 35000; |
| SIMULATED_WAIT(false, kNetworkFailureTimeout, clock); |
| EXPECT_LE(1, GetEndpoint(0)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::NETWORK_FAILURE)); |
| EXPECT_LE(1, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRegatheringReason", |
| static_cast<int>(IceRegatheringReason::NETWORK_FAILURE))); |
| EXPECT_EQ(0, GetEndpoint(1)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::NETWORK_FAILURE)); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that ICE regathering occurs regularly when |
| // regather_all_networks_interval_range configuration value is set. |
| TEST_F(P2PTransportChannelTest, TestIceRegatherOnAllNetworksContinual) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| |
| // ep1 gathers continually but ep2 does not. |
| const int kRegatherInterval = 2000; |
| IceConfig config1 = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| config1.regather_all_networks_interval_range.emplace(kRegatherInterval, |
| kRegatherInterval); |
| IceConfig config2; |
| CreateChannels(config1, config2); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| // Timeout value such that all connections are deleted. |
| const int kNetworkGatherDuration = 11000; |
| SIMULATED_WAIT(false, kNetworkGatherDuration, clock); |
| // Expect regathering to happen 5 times in 11s with 2s interval. |
| EXPECT_LE(5, GetEndpoint(0)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::OCCASIONAL_REFRESH)); |
| EXPECT_LE(5, webrtc::metrics::NumEvents( |
| "WebRTC.PeerConnection.IceRegatheringReason", |
| static_cast<int>(IceRegatheringReason::OCCASIONAL_REFRESH))); |
| // Expect no regathering if continual gathering not configured. |
| EXPECT_EQ(0, GetEndpoint(1)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::OCCASIONAL_REFRESH)); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that ICE periodic regathering can change the selected connection on the |
| // specified interval and that the peers can communicate over the new |
| // connection. The test is parameterized to test that it works when regathering |
| // is done by the ICE controlling peer and when done by the controlled peer. |
| class P2PTransportRegatherAllNetworksTest : public P2PTransportChannelTest { |
| protected: |
| void TestWithRoles(IceRole p1_role, IceRole p2_role) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(NAT_SYMMETRIC, NAT_SYMMETRIC, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| set_force_relay(true); |
| |
| const int kRegatherInterval = 2000; |
| const int kNumRegathers = 2; |
| |
| // Set up peer 1 to auto regather every 2s. |
| IceConfig config1 = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| config1.regather_all_networks_interval_range.emplace(kRegatherInterval, |
| kRegatherInterval); |
| IceConfig config2 = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| |
| // Set peer roles. |
| SetIceRole(0, p1_role); |
| SetIceRole(1, p2_role); |
| |
| CreateChannels(config1, config2); |
| |
| // Wait for initial connection to be made. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| |
| const Connection* initial_selected = ep1_ch1()->selected_connection(); |
| |
| // Wait long enough for 2 regathering cycles to happen plus some extra so |
| // the new connection has time to settle. |
| const int kWaitRegather = |
| kRegatherInterval * kNumRegathers + kRegatherInterval / 2; |
| SIMULATED_WAIT(false, kWaitRegather, clock); |
| EXPECT_EQ(kNumRegathers, GetEndpoint(0)->GetIceRegatheringCountForReason( |
| IceRegatheringReason::OCCASIONAL_REFRESH)); |
| |
| const Connection* new_selected = ep1_ch1()->selected_connection(); |
| |
| // Want the new selected connection to be different. |
| ASSERT_NE(initial_selected, new_selected); |
| |
| // Make sure we can communicate over the new connection too. |
| TestSendRecv(&clock); |
| } |
| }; |
| |
| TEST_F(P2PTransportRegatherAllNetworksTest, TestControlling) { |
| TestWithRoles(ICEROLE_CONTROLLING, ICEROLE_CONTROLLED); |
| } |
| |
| TEST_F(P2PTransportRegatherAllNetworksTest, TestControlled) { |
| TestWithRoles(ICEROLE_CONTROLLED, ICEROLE_CONTROLLING); |
| } |
| |
| // Test that we properly create a connection on a STUN ping from unknown address |
| // when the signaling is slow. |
| TEST_F(P2PTransportChannelTest, PeerReflexiveCandidateBeforeSignaling) { |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // Emulate no remote parameters coming in. |
| set_remote_ice_parameter_source(FROM_CANDIDATE); |
| CreateChannels(); |
| // Only have remote parameters come in for ep2, not ep1. |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[0]); |
| |
| // Pause sending ep2's candidates to ep1 until ep1 receives the peer reflexive |
| // candidate. |
| PauseCandidates(1); |
| |
| // Wait until the callee becomes writable to make sure that a ping request is |
| // received by the caller before his remote ICE credentials are set. |
| ASSERT_TRUE_WAIT(ep2_ch1()->selected_connection() != nullptr, kMediumTimeout); |
| // Add two sets of remote ICE credentials, so that the ones used by the |
| // candidate will be generation 1 instead of 0. |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[1]); |
| // The caller should have the selected connection connected to the peer |
| // reflexive candidate. |
| const Connection* selected_connection = nullptr; |
| ASSERT_TRUE_WAIT( |
| (selected_connection = ep1_ch1()->selected_connection()) != nullptr, |
| kMediumTimeout); |
| EXPECT_EQ(PRFLX_PORT_TYPE, selected_connection->remote_candidate().type()); |
| EXPECT_EQ(kIceUfrag[1], selected_connection->remote_candidate().username()); |
| EXPECT_EQ(kIcePwd[1], selected_connection->remote_candidate().password()); |
| EXPECT_EQ(1u, selected_connection->remote_candidate().generation()); |
| |
| ResumeCandidates(1); |
| // Verify ep1's selected connection is updated to use the 'local' candidate. |
| EXPECT_EQ_WAIT(LOCAL_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type(), |
| kMediumTimeout); |
| EXPECT_EQ(selected_connection, ep1_ch1()->selected_connection()); |
| DestroyChannels(); |
| } |
| |
| // Test that we properly create a connection on a STUN ping from unknown address |
| // when the signaling is slow and the end points are behind NAT. |
| TEST_F(P2PTransportChannelTest, PeerReflexiveCandidateBeforeSignalingWithNAT) { |
| ConfigureEndpoints(OPEN, NAT_SYMMETRIC, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // Emulate no remote parameters coming in. |
| set_remote_ice_parameter_source(FROM_CANDIDATE); |
| CreateChannels(); |
| // Only have remote parameters come in for ep2, not ep1. |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[0]); |
| // Pause sending ep2's candidates to ep1 until ep1 receives the peer reflexive |
| // candidate. |
| PauseCandidates(1); |
| |
| // Wait until the callee becomes writable to make sure that a ping request is |
| // received by the caller before his remote ICE credentials are set. |
| ASSERT_TRUE_WAIT(ep2_ch1()->selected_connection() != nullptr, kMediumTimeout); |
| // Add two sets of remote ICE credentials, so that the ones used by the |
| // candidate will be generation 1 instead of 0. |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[1]); |
| |
| // The caller's selected connection should be connected to the peer reflexive |
| // candidate. |
| const Connection* selected_connection = nullptr; |
| ASSERT_TRUE_WAIT( |
| (selected_connection = ep1_ch1()->selected_connection()) != nullptr, |
| kMediumTimeout); |
| EXPECT_EQ(PRFLX_PORT_TYPE, selected_connection->remote_candidate().type()); |
| EXPECT_EQ(kIceUfrag[1], selected_connection->remote_candidate().username()); |
| EXPECT_EQ(kIcePwd[1], selected_connection->remote_candidate().password()); |
| EXPECT_EQ(1u, selected_connection->remote_candidate().generation()); |
| |
| ResumeCandidates(1); |
| |
| EXPECT_EQ_WAIT(PRFLX_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type(), |
| kMediumTimeout); |
| EXPECT_EQ(selected_connection, ep1_ch1()->selected_connection()); |
| DestroyChannels(); |
| } |
| |
| // Test that we properly create a connection on a STUN ping from unknown address |
| // when the signaling is slow, even if the new candidate is created due to the |
| // remote peer doing an ICE restart, pairing this candidate across generations. |
| // |
| // Previously this wasn't working due to a bug where the peer reflexive |
| // candidate was only updated for the newest generation candidate pairs, and |
| // not older-generation candidate pairs created by pairing candidates across |
| // generations. This resulted in the old-generation prflx candidate being |
| // prioritized above new-generation candidate pairs. |
| TEST_F(P2PTransportChannelTest, |
| PeerReflexiveCandidateBeforeSignalingWithIceRestart) { |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // Only gather relay candidates, so that when the prflx candidate arrives |
| // it's prioritized above the current candidate pair. |
| GetEndpoint(0)->allocator_->SetCandidateFilter(CF_RELAY); |
| GetEndpoint(1)->allocator_->SetCandidateFilter(CF_RELAY); |
| // Setting this allows us to control when SetRemoteIceParameters is called. |
| set_remote_ice_parameter_source(FROM_CANDIDATE); |
| CreateChannels(); |
| // Wait for the initial connection to be made. |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[1]); |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[0]); |
| EXPECT_TRUE_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| kDefaultTimeout); |
| |
| // Simulate an ICE restart on ep2, but don't signal the candidate or new |
| // ICE parameters until after a prflx connection has been made. |
| PauseCandidates(1); |
| ep2_ch1()->SetIceParameters(kIceParams[3]); |
| |
| ep1_ch1()->SetRemoteIceParameters(kIceParams[3]); |
| ep2_ch1()->MaybeStartGathering(); |
| |
| // The caller should have the selected connection connected to the peer |
| // reflexive candidate. |
| EXPECT_EQ_WAIT(PRFLX_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type(), |
| kDefaultTimeout); |
| const Connection* prflx_selected_connection = |
| ep1_ch1()->selected_connection(); |
| |
| // Now simulate the ICE restart on ep1. |
| ep1_ch1()->SetIceParameters(kIceParams[2]); |
| |
| ep2_ch1()->SetRemoteIceParameters(kIceParams[2]); |
| ep1_ch1()->MaybeStartGathering(); |
| |
| // Finally send the candidates from ep2's ICE restart and verify that ep1 uses |
| // their information to update the peer reflexive candidate. |
| ResumeCandidates(1); |
| |
| EXPECT_EQ_WAIT(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type(), |
| kDefaultTimeout); |
| EXPECT_EQ(prflx_selected_connection, ep1_ch1()->selected_connection()); |
| DestroyChannels(); |
| } |
| |
| // Test that if remote candidates don't have ufrag and pwd, we still work. |
| TEST_F(P2PTransportChannelTest, RemoteCandidatesWithoutUfragPwd) { |
| rtc::ScopedFakeClock clock; |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| CreateChannels(); |
| const Connection* selected_connection = NULL; |
| // Wait until the callee's connections are created. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| (selected_connection = ep2_ch1()->selected_connection()) != NULL, |
| kMediumTimeout, clock); |
| // Wait to make sure the selected connection is not changed. |
| SIMULATED_WAIT(ep2_ch1()->selected_connection() != selected_connection, |
| kShortTimeout, clock); |
| EXPECT_TRUE(ep2_ch1()->selected_connection() == selected_connection); |
| DestroyChannels(); |
| } |
| |
| // Test that a host behind NAT cannot be reached when incoming_only |
| // is set to true. |
| TEST_F(P2PTransportChannelTest, IncomingOnlyBlocked) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(NAT_FULL_CONE, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| CreateChannels(); |
| ep1_ch1()->set_incoming_only(true); |
| |
| // Pump for 1 second and verify that the channels are not connected. |
| SIMULATED_WAIT(false, kShortTimeout, clock); |
| |
| EXPECT_FALSE(ep1_ch1()->receiving()); |
| EXPECT_FALSE(ep1_ch1()->writable()); |
| EXPECT_FALSE(ep2_ch1()->receiving()); |
| EXPECT_FALSE(ep2_ch1()->writable()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that a peer behind NAT can connect to a peer that has |
| // incoming_only flag set. |
| TEST_F(P2PTransportChannelTest, IncomingOnlyOpen) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, NAT_FULL_CONE, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| CreateChannels(); |
| ep1_ch1()->set_incoming_only(true); |
| |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1() != NULL && ep2_ch1() != NULL && ep1_ch1()->receiving() && |
| ep1_ch1()->writable() && ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that two peers can connect when one can only make outgoing TCP |
| // connections. This has been observed in some scenarios involving |
| // VPNs/firewalls. |
| TEST_F(P2PTransportChannelTest, CanOnlyMakeOutgoingTcpConnections) { |
| // The PORTALLOCATOR_ENABLE_ANY_ADDRESS_PORTS flag is required if the |
| // application needs this use case to work, since the application must accept |
| // the tradeoff that more candidates need to be allocated. |
| // |
| // TODO(deadbeef): Later, make this flag the default, and do more elegant |
| // things to ensure extra candidates don't waste resources? |
| ConfigureEndpoints( |
| OPEN, OPEN, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_ANY_ADDRESS_PORTS, |
| kDefaultPortAllocatorFlags); |
| // In order to simulate nothing working but outgoing TCP connections, prevent |
| // the endpoint from binding to its interface's address as well as the |
| // "any" addresses. It can then only make a connection by using "Connect()". |
| fw()->SetUnbindableIps({rtc::GetAnyIP(AF_INET), rtc::GetAnyIP(AF_INET6), |
| kPublicAddrs[0].ipaddr()}); |
| CreateChannels(); |
| // Expect a "prflx" candidate on the side that can only make outgoing |
| // connections, endpoint 0. |
| Test(kPrflxTcpToLocalTcp); |
| DestroyChannels(); |
| } |
| |
| TEST_F(P2PTransportChannelTest, TestTcpConnectionsFromActiveToPassive) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| SetAllocationStepDelay(0, kMinimumStepDelay); |
| SetAllocationStepDelay(1, kMinimumStepDelay); |
| |
| int kOnlyLocalTcpPorts = PORTALLOCATOR_DISABLE_UDP | |
| PORTALLOCATOR_DISABLE_STUN | |
| PORTALLOCATOR_DISABLE_RELAY; |
| // Disable all protocols except TCP. |
| SetAllocatorFlags(0, kOnlyLocalTcpPorts); |
| SetAllocatorFlags(1, kOnlyLocalTcpPorts); |
| |
| SetAllowTcpListen(0, true); // actpass. |
| SetAllowTcpListen(1, false); // active. |
| |
| // We want SetRemoteIceParameters to be called as it normally would. |
| // Otherwise we won't know what parameters to use for the expected |
| // prflx TCP candidates. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| |
| // Pause candidate so we could verify the candidate properties. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| CreateChannels(); |
| |
| // Verify tcp candidates. |
| VerifySavedTcpCandidates(0, TCPTYPE_PASSIVE_STR); |
| VerifySavedTcpCandidates(1, TCPTYPE_ACTIVE_STR); |
| |
| // Resume candidates. |
| ResumeCandidates(0); |
| ResumeCandidates(1); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kShortTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| TestSendRecv(&clock); |
| DestroyChannels(); |
| } |
| |
| TEST_F(P2PTransportChannelTest, TestIceRoleConflict) { |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| TestSignalRoleConflict(); |
| } |
| |
| // Tests that the ice configs (protocol, tiebreaker and role) can be passed |
| // down to ports. |
| TEST_F(P2PTransportChannelTest, TestIceConfigWillPassDownToPort) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| // Give the first connection the higher tiebreaker so its role won't |
| // change unless we tell it to. |
| SetIceRole(0, ICEROLE_CONTROLLING); |
| SetIceTiebreaker(0, kHighTiebreaker); |
| SetIceRole(1, ICEROLE_CONTROLLING); |
| SetIceTiebreaker(1, kLowTiebreaker); |
| |
| CreateChannels(); |
| |
| EXPECT_EQ_SIMULATED_WAIT(2u, ep1_ch1()->ports().size(), kShortTimeout, clock); |
| |
| const std::vector<PortInterface*> ports_before = ep1_ch1()->ports(); |
| for (size_t i = 0; i < ports_before.size(); ++i) { |
| EXPECT_EQ(ICEROLE_CONTROLLING, ports_before[i]->GetIceRole()); |
| EXPECT_EQ(kHighTiebreaker, ports_before[i]->IceTiebreaker()); |
| } |
| |
| ep1_ch1()->SetIceRole(ICEROLE_CONTROLLED); |
| ep1_ch1()->SetIceTiebreaker(kLowTiebreaker); |
| |
| const std::vector<PortInterface*> ports_after = ep1_ch1()->ports(); |
| for (size_t i = 0; i < ports_after.size(); ++i) { |
| EXPECT_EQ(ICEROLE_CONTROLLED, ports_before[i]->GetIceRole()); |
| // SetIceTiebreaker after ports have been created will fail. So expect the |
| // original value. |
| EXPECT_EQ(kHighTiebreaker, ports_before[i]->IceTiebreaker()); |
| } |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kShortTimeout, clock); |
| |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection()); |
| |
| TestSendRecv(&clock); |
| DestroyChannels(); |
| } |
| |
| // Verify that we can set DSCP value and retrieve properly from P2PTC. |
| TEST_F(P2PTransportChannelTest, TestDefaultDscpValue) { |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| CreateChannels(); |
| EXPECT_EQ(rtc::DSCP_NO_CHANGE, GetEndpoint(0)->cd1_.ch_->DefaultDscpValue()); |
| EXPECT_EQ(rtc::DSCP_NO_CHANGE, GetEndpoint(1)->cd1_.ch_->DefaultDscpValue()); |
| GetEndpoint(0)->cd1_.ch_->SetOption(rtc::Socket::OPT_DSCP, rtc::DSCP_CS6); |
| GetEndpoint(1)->cd1_.ch_->SetOption(rtc::Socket::OPT_DSCP, rtc::DSCP_CS6); |
| EXPECT_EQ(rtc::DSCP_CS6, GetEndpoint(0)->cd1_.ch_->DefaultDscpValue()); |
| EXPECT_EQ(rtc::DSCP_CS6, GetEndpoint(1)->cd1_.ch_->DefaultDscpValue()); |
| GetEndpoint(0)->cd1_.ch_->SetOption(rtc::Socket::OPT_DSCP, rtc::DSCP_AF41); |
| GetEndpoint(1)->cd1_.ch_->SetOption(rtc::Socket::OPT_DSCP, rtc::DSCP_AF41); |
| EXPECT_EQ(rtc::DSCP_AF41, GetEndpoint(0)->cd1_.ch_->DefaultDscpValue()); |
| EXPECT_EQ(rtc::DSCP_AF41, GetEndpoint(1)->cd1_.ch_->DefaultDscpValue()); |
| } |
| |
| // Verify IPv6 connection is preferred over IPv4. |
| TEST_F(P2PTransportChannelTest, TestIPv6Connections) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kIPv6PublicAddrs[0]); |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kIPv6PublicAddrs[1]); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| SetAllocationStepDelay(0, kMinimumStepDelay); |
| SetAllocationStepDelay(1, kMinimumStepDelay); |
| |
| // Enable IPv6 |
| SetAllocatorFlags( |
| 0, PORTALLOCATOR_ENABLE_IPV6 | PORTALLOCATOR_ENABLE_IPV6_ON_WIFI); |
| SetAllocatorFlags( |
| 1, PORTALLOCATOR_ENABLE_IPV6 | PORTALLOCATOR_ENABLE_IPV6_ON_WIFI); |
| |
| CreateChannels(); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kShortTimeout, clock); |
| EXPECT_TRUE( |
| ep1_ch1()->selected_connection() && ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kIPv6PublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kIPv6PublicAddrs[1])); |
| |
| TestSendRecv(&clock); |
| DestroyChannels(); |
| } |
| |
| // Testing forceful TURN connections. |
| TEST_F(P2PTransportChannelTest, TestForceTurn) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints( |
| NAT_PORT_RESTRICTED, NAT_SYMMETRIC, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET); |
| set_force_relay(true); |
| |
| SetAllocationStepDelay(0, kMinimumStepDelay); |
| SetAllocationStepDelay(1, kMinimumStepDelay); |
| |
| CreateChannels(); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection()); |
| |
| EXPECT_EQ(RELAY_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, RemoteCandidate(ep2_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep2_ch1())->type()); |
| |
| TestSendRecv(&clock); |
| DestroyChannels(); |
| } |
| |
| // Test that if continual gathering is set to true, ICE gathering state will |
| // not change to "Complete", and vice versa. |
| TEST_F(P2PTransportChannelTest, TestContinualGathering) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| SetAllocationStepDelay(0, kDefaultStepDelay); |
| SetAllocationStepDelay(1, kDefaultStepDelay); |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| // By default, ep2 does not gather continually. |
| IceConfig default_config; |
| CreateChannels(continual_gathering_config, default_config); |
| |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1() != NULL && ep2_ch1() != NULL && ep1_ch1()->receiving() && |
| ep1_ch1()->writable() && ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| SIMULATED_WAIT( |
| IceGatheringState::kIceGatheringComplete == ep1_ch1()->gathering_state(), |
| kShortTimeout, clock); |
| EXPECT_EQ(IceGatheringState::kIceGatheringGathering, |
| ep1_ch1()->gathering_state()); |
| // By now, ep2 should have completed gathering. |
| EXPECT_EQ(IceGatheringState::kIceGatheringComplete, |
| ep2_ch1()->gathering_state()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that a connection succeeds when the P2PTransportChannel uses a pooled |
| // PortAllocatorSession that has not yet finished gathering candidates. |
| TEST_F(P2PTransportChannelTest, TestUsingPooledSessionBeforeDoneGathering) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // First create a pooled session for each endpoint. |
| auto& allocator_1 = GetEndpoint(0)->allocator_; |
| auto& allocator_2 = GetEndpoint(1)->allocator_; |
| int pool_size = 1; |
| allocator_1->SetConfiguration(allocator_1->stun_servers(), |
| allocator_1->turn_servers(), pool_size, false); |
| allocator_2->SetConfiguration(allocator_2->stun_servers(), |
| allocator_2->turn_servers(), pool_size, false); |
| const PortAllocatorSession* pooled_session_1 = |
| allocator_1->GetPooledSession(); |
| const PortAllocatorSession* pooled_session_2 = |
| allocator_2->GetPooledSession(); |
| ASSERT_NE(nullptr, pooled_session_1); |
| ASSERT_NE(nullptr, pooled_session_2); |
| // Sanity check that pooled sessions haven't gathered anything yet. |
| EXPECT_TRUE(pooled_session_1->ReadyPorts().empty()); |
| EXPECT_TRUE(pooled_session_1->ReadyCandidates().empty()); |
| EXPECT_TRUE(pooled_session_2->ReadyPorts().empty()); |
| EXPECT_TRUE(pooled_session_2->ReadyCandidates().empty()); |
| // Now let the endpoints connect and try exchanging some data. |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1() != NULL && ep2_ch1() != NULL && ep1_ch1()->receiving() && |
| ep1_ch1()->writable() && ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| TestSendRecv(&clock); |
| // Make sure the P2PTransportChannels are actually using ports from the |
| // pooled sessions. |
| auto pooled_ports_1 = pooled_session_1->ReadyPorts(); |
| auto pooled_ports_2 = pooled_session_2->ReadyPorts(); |
| EXPECT_THAT(pooled_ports_1, |
| Contains(ep1_ch1()->selected_connection()->port())); |
| EXPECT_THAT(pooled_ports_2, |
| Contains(ep2_ch1()->selected_connection()->port())); |
| } |
| |
| // Test that a connection succeeds when the P2PTransportChannel uses a pooled |
| // PortAllocatorSession that already finished gathering candidates. |
| TEST_F(P2PTransportChannelTest, TestUsingPooledSessionAfterDoneGathering) { |
| rtc::ScopedFakeClock clock; |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // First create a pooled session for each endpoint. |
| auto& allocator_1 = GetEndpoint(0)->allocator_; |
| auto& allocator_2 = GetEndpoint(1)->allocator_; |
| int pool_size = 1; |
| allocator_1->SetConfiguration(allocator_1->stun_servers(), |
| allocator_1->turn_servers(), pool_size, false); |
| allocator_2->SetConfiguration(allocator_2->stun_servers(), |
| allocator_2->turn_servers(), pool_size, false); |
| const PortAllocatorSession* pooled_session_1 = |
| allocator_1->GetPooledSession(); |
| const PortAllocatorSession* pooled_session_2 = |
| allocator_2->GetPooledSession(); |
| ASSERT_NE(nullptr, pooled_session_1); |
| ASSERT_NE(nullptr, pooled_session_2); |
| // Wait for the pooled sessions to finish gathering before the |
| // P2PTransportChannels try to use them. |
| EXPECT_TRUE_SIMULATED_WAIT(pooled_session_1->CandidatesAllocationDone() && |
| pooled_session_2->CandidatesAllocationDone(), |
| kDefaultTimeout, clock); |
| // Now let the endpoints connect and try exchanging some data. |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1() != NULL && ep2_ch1() != NULL && ep1_ch1()->receiving() && |
| ep1_ch1()->writable() && ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| TestSendRecv(&clock); |
| // Make sure the P2PTransportChannels are actually using ports from the |
| // pooled sessions. |
| auto pooled_ports_1 = pooled_session_1->ReadyPorts(); |
| auto pooled_ports_2 = pooled_session_2->ReadyPorts(); |
| EXPECT_THAT(pooled_ports_1, |
| Contains(ep1_ch1()->selected_connection()->port())); |
| EXPECT_THAT(pooled_ports_2, |
| Contains(ep2_ch1()->selected_connection()->port())); |
| } |
| |
| // Test that when the "presume_writable_when_fully_relayed" flag is set to |
| // true and there's a TURN-TURN candidate pair, it's presumed to be writable |
| // as soon as it's created. |
| // TODO(deadbeef): Move this and other "presumed writable" tests into a test |
| // class that operates on a single P2PTransportChannel, once an appropriate one |
| // (which supports TURN servers and TURN candidate gathering) is available. |
| TEST_F(P2PTransportChannelTest, TurnToTurnPresumedWritable) { |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // Only configure one channel so we can control when the remote candidate |
| // is added. |
| GetEndpoint(0)->cd1_.ch_.reset(CreateChannel( |
| 0, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[0], kIceParams[1])); |
| IceConfig config; |
| config.presume_writable_when_fully_relayed = true; |
| ep1_ch1()->SetIceConfig(config); |
| ep1_ch1()->MaybeStartGathering(); |
| EXPECT_EQ_WAIT(IceGatheringState::kIceGatheringComplete, |
| ep1_ch1()->gathering_state(), kDefaultTimeout); |
| // Add two remote candidates; a host candidate (with higher priority) |
| // and TURN candidate. |
| ep1_ch1()->AddRemoteCandidate( |
| CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 100)); |
| ep1_ch1()->AddRemoteCandidate( |
| CreateUdpCandidate(RELAY_PORT_TYPE, "2.2.2.2", 2, 0)); |
| // Expect that the TURN-TURN candidate pair will be prioritized since it's |
| // "probably writable". |
| EXPECT_TRUE(ep1_ch1()->selected_connection() != nullptr); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| // Also expect that the channel instantly indicates that it's writable since |
| // it has a TURN-TURN pair. |
| EXPECT_TRUE(ep1_ch1()->writable()); |
| EXPECT_TRUE(GetEndpoint(0)->ready_to_send_); |
| // Also make sure we can immediately send packets. |
| const char* data = "test"; |
| int len = static_cast<int>(strlen(data)); |
| EXPECT_EQ(len, SendData(ep1_ch1(), data, len)); |
| } |
| |
| // Test that a TURN/peer reflexive candidate pair is also presumed writable. |
| TEST_F(P2PTransportChannelTest, TurnToPrflxPresumedWritable) { |
| rtc::ScopedFakeClock fake_clock; |
| |
| // We need to add artificial network delay to verify that the connection |
| // is presumed writable before it's actually writable. Without this delay |
| // it would become writable instantly. |
| virtual_socket_server()->set_delay_mean(50); |
| virtual_socket_server()->UpdateDelayDistribution(); |
| |
| ConfigureEndpoints(NAT_SYMMETRIC, NAT_SYMMETRIC, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // We want the remote TURN candidate to show up as prflx. To do this we need |
| // to configure the server to accept packets from an address we haven't |
| // explicitly installed permission for. |
| test_turn_server()->set_enable_permission_checks(false); |
| IceConfig config; |
| config.presume_writable_when_fully_relayed = true; |
| GetEndpoint(0)->cd1_.ch_.reset(CreateChannel( |
| 0, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[0], kIceParams[1])); |
| GetEndpoint(1)->cd1_.ch_.reset(CreateChannel( |
| 1, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[1], kIceParams[0])); |
| ep1_ch1()->SetIceConfig(config); |
| ep2_ch1()->SetIceConfig(config); |
| // Don't signal candidates from channel 2, so that channel 1 sees the TURN |
| // candidate as peer reflexive. |
| PauseCandidates(1); |
| ep1_ch1()->MaybeStartGathering(); |
| ep2_ch1()->MaybeStartGathering(); |
| |
| // Wait for the TURN<->prflx connection. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable(), |
| kShortTimeout, fake_clock); |
| ASSERT_NE(nullptr, ep1_ch1()->selected_connection()); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(PRFLX_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| // Make sure that at this point the connection is only presumed writable, |
| // not fully writable. |
| EXPECT_FALSE(ep1_ch1()->selected_connection()->writable()); |
| |
| // Now wait for it to actually become writable. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection()->writable(), |
| kShortTimeout, fake_clock); |
| |
| // Explitly destroy channels, before fake clock is destroyed. |
| DestroyChannels(); |
| } |
| |
| // Test that a presumed-writable TURN<->TURN connection is preferred above an |
| // unreliable connection (one that has failed to be pinged for some time). |
| TEST_F(P2PTransportChannelTest, PresumedWritablePreferredOverUnreliable) { |
| rtc::ScopedFakeClock fake_clock; |
| |
| ConfigureEndpoints(NAT_SYMMETRIC, NAT_SYMMETRIC, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| IceConfig config; |
| config.presume_writable_when_fully_relayed = true; |
| GetEndpoint(0)->cd1_.ch_.reset(CreateChannel( |
| 0, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[0], kIceParams[1])); |
| GetEndpoint(1)->cd1_.ch_.reset(CreateChannel( |
| 1, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[1], kIceParams[0])); |
| ep1_ch1()->SetIceConfig(config); |
| ep2_ch1()->SetIceConfig(config); |
| ep1_ch1()->MaybeStartGathering(); |
| ep2_ch1()->MaybeStartGathering(); |
| // Wait for initial connection as usual. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep1_ch1()->selected_connection()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable() && |
| ep2_ch1()->selected_connection()->writable(), |
| kShortTimeout, fake_clock); |
| const Connection* old_selected_connection = ep1_ch1()->selected_connection(); |
| // Destroy the second channel and wait for the current connection on the |
| // first channel to become "unreliable", making it no longer writable. |
| GetEndpoint(1)->cd1_.ch_.reset(); |
| EXPECT_TRUE_SIMULATED_WAIT(!ep1_ch1()->writable(), kDefaultTimeout, |
| fake_clock); |
| EXPECT_NE(nullptr, ep1_ch1()->selected_connection()); |
| // Add a remote TURN candidate. The first channel should still have a TURN |
| // port available to make a TURN<->TURN pair that's presumed writable. |
| ep1_ch1()->AddRemoteCandidate( |
| CreateUdpCandidate(RELAY_PORT_TYPE, "2.2.2.2", 2, 0)); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| EXPECT_TRUE(ep1_ch1()->writable()); |
| EXPECT_TRUE(GetEndpoint(0)->ready_to_send_); |
| EXPECT_NE(old_selected_connection, ep1_ch1()->selected_connection()); |
| // Explitly destroy channels, before fake clock is destroyed. |
| DestroyChannels(); |
| } |
| |
| // Ensure that "SignalReadyToSend" is fired as expected with a "presumed |
| // writable" connection. Previously this did not work. |
| TEST_F(P2PTransportChannelTest, SignalReadyToSendWithPresumedWritable) { |
| ConfigureEndpoints(OPEN, OPEN, kDefaultPortAllocatorFlags, |
| kDefaultPortAllocatorFlags); |
| // Only test one endpoint, so we can ensure the connection doesn't receive a |
| // binding response and advance beyond being "presumed" writable. |
| GetEndpoint(0)->cd1_.ch_.reset(CreateChannel( |
| 0, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[0], kIceParams[1])); |
| IceConfig config; |
| config.presume_writable_when_fully_relayed = true; |
| ep1_ch1()->SetIceConfig(config); |
| ep1_ch1()->MaybeStartGathering(); |
| EXPECT_EQ_WAIT(IceGatheringState::kIceGatheringComplete, |
| ep1_ch1()->gathering_state(), kDefaultTimeout); |
| ep1_ch1()->AddRemoteCandidate( |
| CreateUdpCandidate(RELAY_PORT_TYPE, "1.1.1.1", 1, 0)); |
| // Sanity checking the type of the connection. |
| EXPECT_TRUE(ep1_ch1()->selected_connection() != nullptr); |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| |
| // Tell the socket server to block packets (returning EWOULDBLOCK). |
| virtual_socket_server()->SetSendingBlocked(true); |
| const char* data = "test"; |
| int len = static_cast<int>(strlen(data)); |
| EXPECT_EQ(-1, SendData(ep1_ch1(), data, len)); |
| |
| // Reset |ready_to_send_| flag, which is set to true if the event fires as it |
| // should. |
| GetEndpoint(0)->ready_to_send_ = false; |
| virtual_socket_server()->SetSendingBlocked(false); |
| EXPECT_TRUE(GetEndpoint(0)->ready_to_send_); |
| EXPECT_EQ(len, SendData(ep1_ch1(), data, len)); |
| } |
| |
| // Test that role conflict error responses are sent as expected when receiving a |
| // ping from an unknown address over a TURN connection. Regression test for |
| // crbug.com/webrtc/9034. |
| TEST_F(P2PTransportChannelTest, |
| TurnToPrflxSelectedAfterResolvingIceControllingRoleConflict) { |
| rtc::ScopedFakeClock clock; |
| // Gather only relay candidates. |
| ConfigureEndpoints(NAT_SYMMETRIC, NAT_SYMMETRIC, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_DISABLE_UDP | |
| PORTALLOCATOR_DISABLE_STUN | PORTALLOCATOR_DISABLE_TCP, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_DISABLE_UDP | |
| PORTALLOCATOR_DISABLE_STUN | |
| PORTALLOCATOR_DISABLE_TCP); |
| // With conflicting ICE roles, endpoint 1 has the higher tie breaker and will |
| // send a binding error response. |
| SetIceRole(0, ICEROLE_CONTROLLING); |
| SetIceTiebreaker(0, kHighTiebreaker); |
| SetIceRole(1, ICEROLE_CONTROLLING); |
| SetIceTiebreaker(1, kLowTiebreaker); |
| // We want the remote TURN candidate to show up as prflx. To do this we need |
| // to configure the server to accept packets from an address we haven't |
| // explicitly installed permission for. |
| test_turn_server()->set_enable_permission_checks(false); |
| GetEndpoint(0)->cd1_.ch_.reset(CreateChannel( |
| 0, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[0], kIceParams[1])); |
| GetEndpoint(1)->cd1_.ch_.reset(CreateChannel( |
| 1, ICE_CANDIDATE_COMPONENT_DEFAULT, kIceParams[1], kIceParams[0])); |
| // Don't signal candidates from channel 2, so that channel 1 sees the TURN |
| // candidate as peer reflexive. |
| PauseCandidates(1); |
| ep1_ch1()->MaybeStartGathering(); |
| ep2_ch1()->MaybeStartGathering(); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable(), |
| kMediumTimeout, clock); |
| |
| ASSERT_NE(nullptr, ep1_ch1()->selected_connection()); |
| |
| EXPECT_EQ(RELAY_PORT_TYPE, LocalCandidate(ep1_ch1())->type()); |
| EXPECT_EQ(PRFLX_PORT_TYPE, RemoteCandidate(ep1_ch1())->type()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test what happens when we have 2 users behind the same NAT. This can lead |
| // to interesting behavior because the STUN server will only give out the |
| // address of the outermost NAT. |
| class P2PTransportChannelSameNatTest : public P2PTransportChannelTestBase { |
| protected: |
| void ConfigureEndpoints(Config nat_type, Config config1, Config config2) { |
| RTC_CHECK_GE(nat_type, NAT_FULL_CONE); |
| RTC_CHECK_LE(nat_type, NAT_SYMMETRIC); |
| rtc::NATSocketServer::Translator* outer_nat = nat()->AddTranslator( |
| kPublicAddrs[0], kNatAddrs[0], |
| static_cast<rtc::NATType>(nat_type - NAT_FULL_CONE)); |
| ConfigureEndpoint(outer_nat, 0, config1); |
| ConfigureEndpoint(outer_nat, 1, config2); |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| } |
| void ConfigureEndpoint(rtc::NATSocketServer::Translator* nat, |
| int endpoint, |
| Config config) { |
| RTC_CHECK(config <= NAT_SYMMETRIC); |
| if (config == OPEN) { |
| AddAddress(endpoint, kPrivateAddrs[endpoint]); |
| nat->AddClient(kPrivateAddrs[endpoint]); |
| } else { |
| AddAddress(endpoint, kCascadedPrivateAddrs[endpoint]); |
| nat->AddTranslator(kPrivateAddrs[endpoint], kCascadedNatAddrs[endpoint], |
| static_cast<rtc::NATType>(config - NAT_FULL_CONE)) |
| ->AddClient(kCascadedPrivateAddrs[endpoint]); |
| } |
| } |
| }; |
| |
| TEST_F(P2PTransportChannelSameNatTest, TestConesBehindSameCone) { |
| ConfigureEndpoints(NAT_FULL_CONE, NAT_FULL_CONE, NAT_FULL_CONE); |
| Test( |
| P2PTransportChannelTestBase::Result("prflx", "udp", "stun", "udp", 1000)); |
| } |
| |
| // Test what happens when we have multiple available pathways. |
| // In the future we will try different RTTs and configs for the different |
| // interfaces, so that we can simulate a user with Ethernet and VPN networks. |
| class P2PTransportChannelMultihomedTest : public P2PTransportChannelTestBase { |
| public: |
| const Connection* GetConnectionWithRemoteAddress( |
| P2PTransportChannel* channel, |
| const SocketAddress& address) { |
| for (Connection* conn : channel->connections()) { |
| if (conn->remote_candidate().address().EqualIPs(address)) { |
| return conn; |
| } |
| } |
| return nullptr; |
| } |
| |
| Connection* GetConnectionWithLocalAddress(P2PTransportChannel* channel, |
| const SocketAddress& address) { |
| for (Connection* conn : channel->connections()) { |
| if (conn->local_candidate().address().EqualIPs(address)) { |
| return conn; |
| } |
| } |
| return nullptr; |
| } |
| |
| Connection* GetConnection(P2PTransportChannel* channel, |
| const SocketAddress& local, |
| const SocketAddress& remote) { |
| for (Connection* conn : channel->connections()) { |
| if (conn->local_candidate().address().EqualIPs(local) && |
| conn->remote_candidate().address().EqualIPs(remote)) { |
| return conn; |
| } |
| } |
| return nullptr; |
| } |
| |
| void DestroyAllButBestConnection(P2PTransportChannel* channel) { |
| const Connection* selected_connection = channel->selected_connection(); |
| for (Connection* conn : channel->connections()) { |
| if (conn != selected_connection) { |
| conn->Destroy(); |
| } |
| } |
| } |
| }; |
| |
| // Test that we can establish connectivity when both peers are multihomed. |
| TEST_F(P2PTransportChannelMultihomedTest, TestBasic) { |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(0, kAlternateAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| AddAddress(1, kAlternateAddrs[1]); |
| Test(kLocalUdpToLocalUdp); |
| } |
| |
| // Test that we can quickly switch links if an interface goes down. |
| // The controlled side has two interfaces and one will die. |
| TEST_F(P2PTransportChannelMultihomedTest, TestFailoverControlledSide) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| // Simulate failing over from Wi-Fi to cell interface. |
| AddAddress(1, kPublicAddrs[1], "eth0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, kAlternateAddrs[1], "wlan0", rtc::ADAPTER_TYPE_CELLULAR); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(config, config); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| // Blackhole any traffic to or from the public addrs. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[1]); |
| // The selected connections may switch, so keep references to them. |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| const Connection* selected_connection2 = ep2_ch1()->selected_connection(); |
| // We should detect loss of receiving within 1 second or so. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| !selected_connection1->receiving() && !selected_connection2->receiving(), |
| kMediumTimeout, clock); |
| |
| // We should switch over to use the alternate addr on both sides |
| // when we are not receiving. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection()->receiving() && |
| ep2_ch1()->selected_connection()->receiving(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0])); |
| EXPECT_TRUE( |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[1])); |
| EXPECT_TRUE( |
| LocalCandidate(ep2_ch1())->address().EqualIPs(kAlternateAddrs[1])); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that we can quickly switch links if an interface goes down. |
| // The controlling side has two interfaces and one will die. |
| TEST_F(P2PTransportChannelMultihomedTest, TestFailoverControllingSide) { |
| rtc::ScopedFakeClock clock; |
| // Simulate failing over from Wi-Fi to cell interface. |
| AddAddress(0, kPublicAddrs[0], "eth0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, kAlternateAddrs[0], "wlan0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(config, config); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| // Blackhole any traffic to or from the public addrs. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| // The selected connections will switch, so keep references to them. |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| const Connection* selected_connection2 = ep2_ch1()->selected_connection(); |
| // We should detect loss of receiving within 1 second or so. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| !selected_connection1->receiving() && !selected_connection2->receiving(), |
| kMediumTimeout, clock); |
| |
| // We should switch over to use the alternate addr on both sides |
| // when we are not receiving. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection()->receiving() && |
| ep2_ch1()->selected_connection()->receiving(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE( |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[0])); |
| EXPECT_TRUE(RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| EXPECT_TRUE( |
| RemoteCandidate(ep2_ch1())->address().EqualIPs(kAlternateAddrs[0])); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that we can quickly switch links if an interface goes down when |
| // there are many connections. |
| TEST_F(P2PTransportChannelMultihomedTest, TestFailoverWithManyConnections) { |
| rtc::ScopedFakeClock clock; |
| test_turn_server()->AddInternalSocket(kTurnTcpIntAddr, PROTO_TCP); |
| RelayServerConfig turn_server(RELAY_TURN); |
| turn_server.credentials = kRelayCredentials; |
| turn_server.ports.push_back(ProtocolAddress(kTurnTcpIntAddr, PROTO_TCP)); |
| GetAllocator(0)->AddTurnServer(turn_server); |
| GetAllocator(1)->AddTurnServer(turn_server); |
| // Enable IPv6 |
| SetAllocatorFlags( |
| 0, PORTALLOCATOR_ENABLE_IPV6 | PORTALLOCATOR_ENABLE_IPV6_ON_WIFI); |
| SetAllocatorFlags( |
| 1, PORTALLOCATOR_ENABLE_IPV6 | PORTALLOCATOR_ENABLE_IPV6_ON_WIFI); |
| SetAllocationStepDelay(0, kMinimumStepDelay); |
| SetAllocationStepDelay(1, kMinimumStepDelay); |
| |
| auto& wifi = kPublicAddrs; |
| auto& cellular = kAlternateAddrs; |
| auto& wifiIpv6 = kIPv6PublicAddrs; |
| auto& cellularIpv6 = kIPv6AlternateAddrs; |
| AddAddress(0, wifi[0], "wifi0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, wifiIpv6[0], "wifi0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, cellular[0], "cellular0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(0, cellularIpv6[0], "cellular0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, wifi[1], "wifi1", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, wifiIpv6[1], "wifi1", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, cellular[1], "cellular1", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, cellularIpv6[1], "cellular1", rtc::ADAPTER_TYPE_CELLULAR); |
| |
| // Set smaller delay on the TCP TURN server so that TCP TURN candidates |
| // will be created in time. |
| virtual_socket_server()->SetDelayOnAddress(kTurnTcpIntAddr, 1); |
| virtual_socket_server()->SetDelayOnAddress(kTurnUdpExtAddr, 1); |
| virtual_socket_server()->set_delay_mean(500); |
| virtual_socket_server()->UpdateDelayDistribution(); |
| |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(config, config, true /* ice_renomination */); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() && ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(wifiIpv6[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(wifiIpv6[1]), |
| kMediumTimeout, clock); |
| |
| // Blackhole any traffic to or from the wifi on endpoint 1. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, wifi[0]); |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, wifiIpv6[0]); |
| |
| // The selected connections may switch, so keep references to them. |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| const Connection* selected_connection2 = ep2_ch1()->selected_connection(); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| !selected_connection1->receiving() && !selected_connection2->receiving(), |
| kMediumTimeout, clock); |
| |
| // Per-network best connections will be pinged at relatively higher rate when |
| // the selected connection becomes not receiving. |
| Connection* per_network_best_connection1 = |
| GetConnection(ep1_ch1(), cellularIpv6[0], wifiIpv6[1]); |
| ASSERT_NE(nullptr, per_network_best_connection1); |
| int64_t last_ping_sent1 = per_network_best_connection1->last_ping_sent(); |
| int num_pings_sent1 = per_network_best_connection1->num_pings_sent(); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| num_pings_sent1 < per_network_best_connection1->num_pings_sent(), |
| kMediumTimeout, clock); |
| int64_t ping_interval1 = |
| (per_network_best_connection1->last_ping_sent() - last_ping_sent1) / |
| (per_network_best_connection1->num_pings_sent() - num_pings_sent1); |
| constexpr int SCHEDULING_DELAY = 200; |
| EXPECT_LT( |
| ping_interval1, |
| WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL + SCHEDULING_DELAY); |
| |
| // It should switch over to use the cellular IPv6 addr on endpoint 1 before |
| // it timed out on writing. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection()->receiving() && |
| ep2_ch1()->selected_connection()->receiving() && |
| RemoteCandidate(ep2_ch1())->address().EqualIPs(cellularIpv6[0]) && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(cellularIpv6[0]), |
| kMediumTimeout, clock); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that when the controlling side switches the selected connection, |
| // the nomination of the selected connection on the controlled side will |
| // increase. |
| TEST_F(P2PTransportChannelMultihomedTest, TestIceRenomination) { |
| rtc::ScopedFakeClock clock; |
| // Simulate failing over from Wi-Fi to cell interface. |
| AddAddress(0, kPublicAddrs[0], "eth0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, kAlternateAddrs[0], "wlan0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // We want it to set the remote ICE parameters when creating channels. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| // Create channels with ICE renomination and let them go writable as usual. |
| CreateChannels(config, config, true); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep2_ch1()->selected_connection()->remote_nomination() > 0 && |
| ep1_ch1()->selected_connection()->acked_nomination() > 0, |
| kDefaultTimeout, clock); |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| Connection* selected_connection2 = |
| const_cast<Connection*>(ep2_ch1()->selected_connection()); |
| uint32_t remote_nomination2 = selected_connection2->remote_nomination(); |
| // |selected_connection2| should not be nominated any more since the previous |
| // nomination has been acknowledged. |
| ConnectSignalNominated(selected_connection2); |
| SIMULATED_WAIT(nominated(), kMediumTimeout, clock); |
| EXPECT_FALSE(nominated()); |
| |
| // Blackhole any traffic to or from the public addrs. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| |
| // The selected connection on the controlling side should switch. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() != selected_connection1, kMediumTimeout, |
| clock); |
| // The connection on the controlled side should be nominated again |
| // and have an increased nomination. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep2_ch1()->selected_connection()->remote_nomination() > |
| remote_nomination2, |
| kDefaultTimeout, clock); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that if an interface fails temporarily and then recovers quickly, |
| // the selected connection will not switch. |
| // The case that it will switch over to the backup connection if the selected |
| // connection does not recover after enough time is covered in |
| // TestFailoverControlledSide and TestFailoverControllingSide. |
| TEST_F(P2PTransportChannelMultihomedTest, |
| TestConnectionSwitchDampeningControlledSide) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| // Simulate failing over from Wi-Fi to cell interface. |
| AddAddress(1, kPublicAddrs[1], "eth0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, kAlternateAddrs[1], "wlan0", rtc::ADAPTER_TYPE_CELLULAR); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| ep1_ch1()->SetIceConfig(config); |
| ep2_ch1()->SetIceConfig(config); |
| reset_selected_candidate_pair_switches(); |
| |
| // Blackhole any traffic to or from the public addrs. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[1]); |
| |
| // The selected connections may switch, so keep references to them. |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| const Connection* selected_connection2 = ep2_ch1()->selected_connection(); |
| // We should detect loss of receiving within 1 second or so. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| !selected_connection1->receiving() && !selected_connection2->receiving(), |
| kMediumTimeout, clock); |
| // After a short while, the link recovers itself. |
| SIMULATED_WAIT(false, 10, clock); |
| fw()->ClearRules(); |
| |
| // We should remain on the public address on both sides and no connection |
| // switches should have happened. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection()->receiving() && |
| ep2_ch1()->selected_connection()->receiving(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| EXPECT_TRUE(LocalCandidate(ep2_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that if an interface fails temporarily and then recovers quickly, |
| // the selected connection will not switch. |
| TEST_F(P2PTransportChannelMultihomedTest, |
| TestConnectionSwitchDampeningControllingSide) { |
| rtc::ScopedFakeClock clock; |
| // Simulate failing over from Wi-Fi to cell interface. |
| AddAddress(0, kPublicAddrs[0], "eth0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, kAlternateAddrs[0], "wlan0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| // Make the receiving timeout shorter for testing. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| ep1_ch1()->SetIceConfig(config); |
| ep2_ch1()->SetIceConfig(config); |
| reset_selected_candidate_pair_switches(); |
| |
| // Blackhole any traffic to or from the public addrs. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, kPublicAddrs[0]); |
| // The selected connections may switch, so keep references to them. |
| const Connection* selected_connection1 = ep1_ch1()->selected_connection(); |
| const Connection* selected_connection2 = ep2_ch1()->selected_connection(); |
| // We should detect loss of receiving within 1 second or so. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| !selected_connection1->receiving() && !selected_connection2->receiving(), |
| kMediumTimeout, clock); |
| // The link recovers after a short while. |
| SIMULATED_WAIT(false, 10, clock); |
| fw()->ClearRules(); |
| |
| // We should not switch to the alternate addr on both sides because of the |
| // dampening. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection()->receiving() && |
| ep2_ch1()->selected_connection()->receiving(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0])); |
| EXPECT_TRUE(RemoteCandidate(ep2_ch1())->address().EqualIPs(kPublicAddrs[0])); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| DestroyChannels(); |
| } |
| |
| // Tests that if the remote side's network failed, it won't cause the local |
| // side to switch connections and networks. |
| TEST_F(P2PTransportChannelMultihomedTest, TestRemoteFailover) { |
| rtc::ScopedFakeClock clock; |
| // The interface names are chosen so that |cellular| would have higher |
| // candidate priority and higher cost. |
| auto& wifi = kPublicAddrs; |
| auto& cellular = kAlternateAddrs; |
| AddAddress(0, wifi[0], "wifi0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, cellular[0], "cellular0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, wifi[1], "wifi0", rtc::ADAPTER_TYPE_WIFI); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| // Make the receiving timeout shorter for testing. |
| // Set the backup connection ping interval to 25s. |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE, 25000); |
| // Ping the best connection more frequently since we don't have traffic. |
| config.stable_writable_connection_ping_interval = 900; |
| ep1_ch1()->SetIceConfig(config); |
| ep2_ch1()->SetIceConfig(config); |
| // Need to wait to make sure the connections on both networks are writable. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(wifi[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(wifi[1]), |
| kDefaultTimeout, clock); |
| Connection* backup_conn = |
| GetConnectionWithLocalAddress(ep1_ch1(), cellular[0]); |
| ASSERT_NE(nullptr, backup_conn); |
| // After a short while, the backup connection will be writable but not |
| // receiving because backup connection is pinged at a slower rate. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| backup_conn->writable() && !backup_conn->receiving(), kDefaultTimeout, |
| clock); |
| reset_selected_candidate_pair_switches(); |
| // Blackhole any traffic to or from the remote WiFi networks. |
| RTC_LOG(LS_INFO) << "Failing over..."; |
| fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY, wifi[1]); |
| |
| int num_switches = 0; |
| SIMULATED_WAIT((num_switches = reset_selected_candidate_pair_switches()) > 0, |
| 20000, clock); |
| EXPECT_EQ(0, num_switches); |
| DestroyChannels(); |
| } |
| |
| // Tests that a Wifi-Wifi connection has the highest precedence. |
| TEST_F(P2PTransportChannelMultihomedTest, TestPreferWifiToWifiConnection) { |
| // The interface names are chosen so that |cellular| would have higher |
| // candidate priority if it is not for the network type. |
| auto& wifi = kAlternateAddrs; |
| auto& cellular = kPublicAddrs; |
| AddAddress(0, wifi[0], "test0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, cellular[0], "test1", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, wifi[1], "test0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, cellular[1], "test1", rtc::ADAPTER_TYPE_CELLULAR); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| |
| EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| 1000, 1000); |
| // Need to wait to make sure the connections on both networks are writable. |
| EXPECT_TRUE_WAIT(ep1_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(wifi[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(wifi[1]), |
| 1000); |
| EXPECT_TRUE_WAIT(ep2_ch1()->selected_connection() && |
| LocalCandidate(ep2_ch1())->address().EqualIPs(wifi[1]) && |
| RemoteCandidate(ep2_ch1())->address().EqualIPs(wifi[0]), |
| 1000); |
| DestroyChannels(); |
| } |
| |
| // Tests that a Wifi-Cellular connection has higher precedence than |
| // a Cellular-Cellular connection. |
| TEST_F(P2PTransportChannelMultihomedTest, TestPreferWifiOverCellularNetwork) { |
| // The interface names are chosen so that |cellular| would have higher |
| // candidate priority if it is not for the network type. |
| auto& wifi = kAlternateAddrs; |
| auto& cellular = kPublicAddrs; |
| AddAddress(0, cellular[0], "test1", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, wifi[1], "test0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, cellular[1], "test1", rtc::ADAPTER_TYPE_CELLULAR); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| |
| EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| 1000, 1000); |
| // Need to wait to make sure the connections on both networks are writable. |
| EXPECT_TRUE_WAIT(ep1_ch1()->selected_connection() && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(wifi[1]), |
| 1000); |
| EXPECT_TRUE_WAIT(ep2_ch1()->selected_connection() && |
| LocalCandidate(ep2_ch1())->address().EqualIPs(wifi[1]), |
| 1000); |
| DestroyChannels(); |
| } |
| |
| // Test that the backup connection is pinged at a rate no faster than |
| // what was configured. |
| TEST_F(P2PTransportChannelMultihomedTest, TestPingBackupConnectionRate) { |
| AddAddress(0, kPublicAddrs[0]); |
| // Adding alternate address will make sure |kPublicAddrs| has the higher |
| // priority than others. This is due to FakeNetwork::AddInterface method. |
| AddAddress(1, kAlternateAddrs[1]); |
| AddAddress(1, kPublicAddrs[1]); |
| |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| 1000, 1000); |
| int backup_ping_interval = 2000; |
| ep2_ch1()->SetIceConfig( |
| CreateIceConfig(2000, GATHER_ONCE, backup_ping_interval)); |
| // After the state becomes COMPLETED, the backup connection will be pinged |
| // once every |backup_ping_interval| milliseconds. |
| ASSERT_TRUE_WAIT(ep2_ch1()->GetState() == IceTransportState::STATE_COMPLETED, |
| 1000); |
| const std::vector<Connection*>& connections = ep2_ch1()->connections(); |
| ASSERT_EQ(2U, connections.size()); |
| Connection* backup_conn = connections[1]; |
| EXPECT_TRUE_WAIT(backup_conn->writable(), kMediumTimeout); |
| int64_t last_ping_response_ms = backup_conn->last_ping_response_received(); |
| EXPECT_TRUE_WAIT( |
| last_ping_response_ms < backup_conn->last_ping_response_received(), |
| kDefaultTimeout); |
| int time_elapsed = |
| backup_conn->last_ping_response_received() - last_ping_response_ms; |
| RTC_LOG(LS_INFO) << "Time elapsed: " << time_elapsed; |
| EXPECT_GE(time_elapsed, backup_ping_interval); |
| |
| DestroyChannels(); |
| } |
| |
| TEST_F(P2PTransportChannelMultihomedTest, TestGetState) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kAlternateAddrs[0]); |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(); |
| |
| // Both transport channels will reach STATE_COMPLETED quickly. |
| EXPECT_EQ_SIMULATED_WAIT(IceTransportState::STATE_COMPLETED, |
| ep1_ch1()->GetState(), kShortTimeout, clock); |
| EXPECT_EQ_SIMULATED_WAIT(IceTransportState::STATE_COMPLETED, |
| ep2_ch1()->GetState(), kShortTimeout, clock); |
| } |
| |
| // Tests that when a network interface becomes inactive, if Continual Gathering |
| // policy is GATHER_CONTINUALLY, the ports associated with that network |
| // will be removed from the port list of the channel, and the respective |
| // remote candidates on the other participant will be removed eventually. |
| TEST_F(P2PTransportChannelMultihomedTest, TestNetworkBecomesInactive) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| // Create channels and let them go writable, as usual. |
| IceConfig ep1_config = CreateIceConfig(2000, GATHER_CONTINUALLY); |
| IceConfig ep2_config = CreateIceConfig(2000, GATHER_ONCE); |
| CreateChannels(ep1_config, ep2_config); |
| |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kDefaultTimeout, clock); |
| // More than one port has been created. |
| EXPECT_LE(1U, ep1_ch1()->ports().size()); |
| // Endpoint 1 enabled continual gathering; the port will be removed |
| // when the interface is removed. |
| RemoveAddress(0, kPublicAddrs[0]); |
| EXPECT_TRUE(ep1_ch1()->ports().empty()); |
| // The remote candidates will be removed eventually. |
| EXPECT_TRUE_SIMULATED_WAIT(ep2_ch1()->remote_candidates().empty(), 1000, |
| clock); |
| |
| size_t num_ports = ep2_ch1()->ports().size(); |
| EXPECT_LE(1U, num_ports); |
| size_t num_remote_candidates = ep1_ch1()->remote_candidates().size(); |
| // Endpoint 2 did not enable continual gathering; the local port will still be |
| // removed when the interface is removed but the remote candidates on the |
| // other participant will not be removed. |
| RemoveAddress(1, kPublicAddrs[1]); |
| |
| EXPECT_EQ_SIMULATED_WAIT(0U, ep2_ch1()->ports().size(), kDefaultTimeout, |
| clock); |
| SIMULATED_WAIT(0U == ep1_ch1()->remote_candidates().size(), 500, clock); |
| EXPECT_EQ(num_remote_candidates, ep1_ch1()->remote_candidates().size()); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that continual gathering will create new connections when a new |
| // interface is added. |
| TEST_F(P2PTransportChannelMultihomedTest, |
| TestContinualGatheringOnNewInterface) { |
| auto& wifi = kAlternateAddrs; |
| auto& cellular = kPublicAddrs; |
| AddAddress(0, wifi[0], "test_wifi0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, cellular[1], "test_cell1", rtc::ADAPTER_TYPE_CELLULAR); |
| // Set continual gathering policy. |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| CreateChannels(continual_gathering_config, continual_gathering_config); |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && ep2_ch1()->writable(), |
| kDefaultTimeout, kDefaultTimeout); |
| |
| // Add a new wifi interface on end point 2. We should expect a new connection |
| // to be created and the new one will be the best connection. |
| AddAddress(1, wifi[1], "test_wifi1", rtc::ADAPTER_TYPE_WIFI); |
| const Connection* conn; |
| EXPECT_TRUE_WAIT((conn = ep1_ch1()->selected_connection()) != nullptr && |
| conn->remote_candidate().address().EqualIPs(wifi[1]), |
| kDefaultTimeout); |
| EXPECT_TRUE_WAIT((conn = ep2_ch1()->selected_connection()) != nullptr && |
| conn->local_candidate().address().EqualIPs(wifi[1]), |
| kDefaultTimeout); |
| |
| // Add a new cellular interface on end point 1, we should expect a new |
| // backup connection created using this new interface. |
| AddAddress(0, cellular[0], "test_cellular0", rtc::ADAPTER_TYPE_CELLULAR); |
| EXPECT_TRUE_WAIT( |
| ep1_ch1()->GetState() == IceTransportState::STATE_COMPLETED && |
| (conn = GetConnectionWithLocalAddress(ep1_ch1(), cellular[0])) != |
| nullptr && |
| conn != ep1_ch1()->selected_connection() && conn->writable(), |
| kDefaultTimeout); |
| EXPECT_TRUE_WAIT( |
| ep2_ch1()->GetState() == IceTransportState::STATE_COMPLETED && |
| (conn = GetConnectionWithRemoteAddress(ep2_ch1(), cellular[0])) != |
| nullptr && |
| conn != ep2_ch1()->selected_connection() && conn->receiving(), |
| kDefaultTimeout); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that we can switch links via continual gathering. |
| TEST_F(P2PTransportChannelMultihomedTest, |
| TestSwitchLinksViaContinualGathering) { |
| rtc::ScopedFakeClock clock; |
| AddAddress(0, kPublicAddrs[0]); |
| AddAddress(1, kPublicAddrs[1]); |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Set continual gathering policy. |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| // Create channels and let them go writable, as usual. |
| CreateChannels(continual_gathering_config, continual_gathering_config); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1])); |
| |
| // Add the new address first and then remove the other one. |
| RTC_LOG(LS_INFO) << "Draining..."; |
| AddAddress(1, kAlternateAddrs[1]); |
| RemoveAddress(1, kPublicAddrs[1]); |
| // We should switch to use the alternate address after an exchange of pings. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() && ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[1]), |
| kMediumTimeout, clock); |
| |
| // Remove one address first and then add another address. |
| RTC_LOG(LS_INFO) << "Draining again..."; |
| RemoveAddress(1, kAlternateAddrs[1]); |
| AddAddress(1, kAlternateAddrs[0]); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() && ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[0]), |
| kMediumTimeout, clock); |
| |
| DestroyChannels(); |
| } |
| |
| // Tests that the backup connection will be restored after it is destroyed. |
| TEST_F(P2PTransportChannelMultihomedTest, TestRestoreBackupConnection) { |
| rtc::ScopedFakeClock clock; |
| auto& wifi = kAlternateAddrs; |
| auto& cellular = kPublicAddrs; |
| AddAddress(0, wifi[0], "test_wifi0", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(0, cellular[0], "test_cell0", rtc::ADAPTER_TYPE_CELLULAR); |
| AddAddress(1, wifi[1], "test_wifi1", rtc::ADAPTER_TYPE_WIFI); |
| AddAddress(1, cellular[1], "test_cell1", rtc::ADAPTER_TYPE_CELLULAR); |
| // Use only local ports for simplicity. |
| SetAllocatorFlags(0, kOnlyLocalPorts); |
| SetAllocatorFlags(1, kOnlyLocalPorts); |
| |
| // Create channels and let them go writable, as usual. |
| IceConfig config = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| config.regather_on_failed_networks_interval = 2000; |
| CreateChannels(config, config); |
| EXPECT_TRUE_SIMULATED_WAIT(ep1_ch1()->receiving() && ep1_ch1()->writable() && |
| ep2_ch1()->receiving() && |
| ep2_ch1()->writable(), |
| kMediumTimeout, clock); |
| EXPECT_TRUE(ep1_ch1()->selected_connection() && |
| ep2_ch1()->selected_connection() && |
| LocalCandidate(ep1_ch1())->address().EqualIPs(wifi[0]) && |
| RemoteCandidate(ep1_ch1())->address().EqualIPs(wifi[1])); |
| |
| // Destroy all backup connections. |
| DestroyAllButBestConnection(ep1_ch1()); |
| // Ensure the backup connection is removed first. |
| EXPECT_TRUE_SIMULATED_WAIT( |
| GetConnectionWithLocalAddress(ep1_ch1(), cellular[0]) == nullptr, |
| kDefaultTimeout, clock); |
| const Connection* conn; |
| EXPECT_TRUE_SIMULATED_WAIT( |
| (conn = GetConnectionWithLocalAddress(ep1_ch1(), cellular[0])) != |
| nullptr && |
| conn != ep1_ch1()->selected_connection() && conn->writable(), |
| kDefaultTimeout, clock); |
| |
| DestroyChannels(); |
| } |
| |
| // A collection of tests which tests a single P2PTransportChannel by sending |
| // pings. |
| class P2PTransportChannelPingTest : public ::testing::Test, |
| public sigslot::has_slots<> { |
| public: |
| P2PTransportChannelPingTest() |
| : vss_(new rtc::VirtualSocketServer()), thread_(vss_.get()) {} |
| |
| protected: |
| void PrepareChannel(P2PTransportChannel* ch) { |
| ch->SetIceRole(ICEROLE_CONTROLLING); |
| ch->SetIceParameters(kIceParams[0]); |
| ch->SetRemoteIceParameters(kIceParams[1]); |
| ch->SignalNetworkRouteChanged.connect( |
| this, &P2PTransportChannelPingTest::OnNetworkRouteChanged); |
| ch->SignalReadyToSend.connect(this, |
| &P2PTransportChannelPingTest::OnReadyToSend); |
| ch->SignalStateChanged.connect( |
| this, &P2PTransportChannelPingTest::OnChannelStateChanged); |
| } |
| |
| Connection* WaitForConnectionTo( |
| P2PTransportChannel* ch, |
| const std::string& ip, |
| int port_num, |
| rtc::ThreadProcessingFakeClock* clock = nullptr) { |
| if (clock == nullptr) { |
| EXPECT_TRUE_WAIT(GetConnectionTo(ch, ip, port_num) != nullptr, |
| kMediumTimeout); |
| } else { |
| EXPECT_TRUE_SIMULATED_WAIT(GetConnectionTo(ch, ip, port_num) != nullptr, |
| kMediumTimeout, *clock); |
| } |
| return GetConnectionTo(ch, ip, port_num); |
| } |
| |
| Port* GetPort(P2PTransportChannel* ch) { |
| if (ch->ports().empty()) { |
| return nullptr; |
| } |
| return static_cast<Port*>(ch->ports()[0]); |
| } |
| |
| Port* GetPrunedPort(P2PTransportChannel* ch) { |
| if (ch->pruned_ports().empty()) { |
| return nullptr; |
| } |
| return static_cast<Port*>(ch->pruned_ports()[0]); |
| } |
| |
| Connection* GetConnectionTo(P2PTransportChannel* ch, |
| const std::string& ip, |
| int port_num) { |
| Port* port = GetPort(ch); |
| if (!port) { |
| return nullptr; |
| } |
| return port->GetConnection(rtc::SocketAddress(ip, port_num)); |
| } |
| |
| Connection* FindNextPingableConnectionAndPingIt(P2PTransportChannel* ch) { |
| Connection* conn = ch->FindNextPingableConnection(); |
| if (conn) { |
| ch->MarkConnectionPinged(conn); |
| } |
| return conn; |
| } |
| |
| int SendData(IceTransportInternal* channel, |
| const char* data, |
| size_t len, |
| int packet_id) { |
| rtc::PacketOptions options; |
| options.packet_id = packet_id; |
| return channel->SendPacket(data, len, options, 0); |
| } |
| |
| Connection* CreateConnectionWithCandidate(P2PTransportChannel* channel, |
| rtc::ScopedFakeClock* clock, |
| const std::string& ip_addr, |
| int port, |
| int priority, |
| bool writable) { |
| channel->AddRemoteCandidate( |
| CreateUdpCandidate(LOCAL_PORT_TYPE, ip_addr, port, priority)); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| GetConnectionTo(channel, ip_addr, port) != nullptr, kMediumTimeout, |
| *clock); |
| Connection* conn = GetConnectionTo(channel, ip_addr, port); |
| |
| if (conn && writable) { |
| conn->ReceivedPingResponse(LOW_RTT, "id"); // make it writable |
| } |
| return conn; |
| } |
| |
| void NominateConnection(Connection* conn, uint32_t remote_nomination = 1U) { |
| conn->set_remote_nomination(remote_nomination); |
| conn->SignalNominated(conn); |
| } |
| |
| void OnNetworkRouteChanged(absl::optional<rtc::NetworkRoute> network_route) { |
| last_network_route_ = network_route; |
| if (last_network_route_) { |
| last_sent_packet_id_ = last_network_route_->last_sent_packet_id; |
| } |
| ++selected_candidate_pair_switches_; |
| } |
| |
| void ReceivePingOnConnection(Connection* conn, |
| const std::string& remote_ufrag, |
| int priority, |
| uint32_t nomination = 0) { |
| IceMessage msg; |
| msg.SetType(STUN_BINDING_REQUEST); |
| msg.AddAttribute(absl::make_unique<StunByteStringAttribute>( |
| STUN_ATTR_USERNAME, |
| conn->local_candidate().username() + ":" + remote_ufrag)); |
| msg.AddAttribute( |
| absl::make_unique<StunUInt32Attribute>(STUN_ATTR_PRIORITY, priority)); |
| if (nomination != 0) { |
| msg.AddAttribute(absl::make_unique<StunUInt32Attribute>( |
| STUN_ATTR_NOMINATION, nomination)); |
| } |
| msg.SetTransactionID(rtc::CreateRandomString(kStunTransactionIdLength)); |
| msg.AddMessageIntegrity(conn->local_candidate().password()); |
| msg.AddFingerprint(); |
| rtc::ByteBufferWriter buf; |
| msg.Write(&buf); |
| conn->OnReadPacket(buf.Data(), buf.Length(), rtc::TimeMicros()); |
| } |
| |
| void OnReadyToSend(rtc::PacketTransportInternal* transport) { |
| channel_ready_to_send_ = true; |
| } |
| void OnChannelStateChanged(IceTransportInternal* channel) { |
| channel_state_ = channel->GetState(); |
| } |
| |
| int last_sent_packet_id() { return last_sent_packet_id_; } |
| bool channel_ready_to_send() { return channel_ready_to_send_; } |
| void reset_channel_ready_to_send() { channel_ready_to_send_ = false; } |
| IceTransportState channel_state() { return channel_state_; } |
| int reset_selected_candidate_pair_switches() { |
| int switches = selected_candidate_pair_switches_; |
| selected_candidate_pair_switches_ = 0; |
| return switches; |
| } |
| |
| // Return true if the |pair| matches the last network route. |
| bool CandidatePairMatchesNetworkRoute(CandidatePairInterface* pair) { |
| if (!pair) { |
| return !last_network_route_.has_value(); |
| } else { |
| return pair->local_candidate().network_id() == |
| last_network_route_->local_network_id && |
| pair->remote_candidate().network_id() == |
| last_network_route_->remote_network_id; |
| } |
| } |
| |
| private: |
| std::unique_ptr<rtc::VirtualSocketServer> vss_; |
| rtc::AutoSocketServerThread thread_; |
| int selected_candidate_pair_switches_ = 0; |
| int last_sent_packet_id_ = -1; |
| bool channel_ready_to_send_ = false; |
| IceTransportState channel_state_ = IceTransportState::STATE_INIT; |
| absl::optional<rtc::NetworkRoute> last_network_route_; |
| }; |
| |
| TEST_F(P2PTransportChannelPingTest, TestTriggeredChecks) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("trigger checks", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn1 != nullptr); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| // Before a triggered check, the first connection to ping is the |
| // highest priority one. |
| EXPECT_EQ(conn2, FindNextPingableConnectionAndPingIt(&ch)); |
| |
| // Receiving a ping causes a triggered check which should make conn1 |
| // be pinged first instead of conn2, even though conn2 has a higher |
| // priority. |
| conn1->ReceivedPing(); |
| EXPECT_EQ(conn1, FindNextPingableConnectionAndPingIt(&ch)); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestAllConnectionsPingedSufficiently) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("ping sufficiently", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn1 != nullptr); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| // Low-priority connection becomes writable so that the other connection |
| // is not pruned. |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_TRUE_WAIT( |
| conn1->num_pings_sent() >= MIN_PINGS_AT_WEAK_PING_INTERVAL && |
| conn2->num_pings_sent() >= MIN_PINGS_AT_WEAK_PING_INTERVAL, |
| kDefaultTimeout); |
| } |
| |
| // Verify that the connections are pinged at the right time. |
| TEST_F(P2PTransportChannelPingTest, TestStunPingIntervals) { |
| rtc::ScopedFakeClock clock; |
| int RTT_RATIO = 4; |
| int SCHEDULING_RANGE = 200; |
| int RTT_RANGE = 10; |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("TestChannel", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| |
| ASSERT_TRUE(conn != nullptr); |
| SIMULATED_WAIT(conn->num_pings_sent() == 1, kDefaultTimeout, clock); |
| |
| // Initializing. |
| |
| int64_t start = clock.TimeNanos(); |
| SIMULATED_WAIT(conn->num_pings_sent() >= MIN_PINGS_AT_WEAK_PING_INTERVAL, |
| kDefaultTimeout, clock); |
| int64_t ping_interval_ms = (clock.TimeNanos() - start) / |
| rtc::kNumNanosecsPerMillisec / |
| (MIN_PINGS_AT_WEAK_PING_INTERVAL - 1); |
| EXPECT_EQ(ping_interval_ms, WEAK_PING_INTERVAL); |
| |
| // Stabilizing. |
| |
| conn->ReceivedPingResponse(LOW_RTT, "id"); |
| int ping_sent_before = conn->num_pings_sent(); |
| start = clock.TimeNanos(); |
| // The connection becomes strong but not stable because we haven't been able |
| // to converge the RTT. |
| SIMULATED_WAIT(conn->num_pings_sent() == ping_sent_before + 1, kMediumTimeout, |
| clock); |
| ping_interval_ms = (clock.TimeNanos() - start) / rtc::kNumNanosecsPerMillisec; |
| EXPECT_GE(ping_interval_ms, |
| WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL); |
| EXPECT_LE( |
| ping_interval_ms, |
| WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL + SCHEDULING_RANGE); |
| |
| // Stabilized. |
| |
| // The connection becomes stable after receiving more than RTT_RATIO rtt |
| // samples. |
| for (int i = 0; i < RTT_RATIO; i++) { |
| conn->ReceivedPingResponse(LOW_RTT, "id"); |
| } |
| ping_sent_before = conn->num_pings_sent(); |
| start = clock.TimeNanos(); |
| SIMULATED_WAIT(conn->num_pings_sent() == ping_sent_before + 1, kMediumTimeout, |
| clock); |
| ping_interval_ms = (clock.TimeNanos() - start) / rtc::kNumNanosecsPerMillisec; |
| EXPECT_GE(ping_interval_ms, |
| STRONG_AND_STABLE_WRITABLE_CONNECTION_PING_INTERVAL); |
| EXPECT_LE( |
| ping_interval_ms, |
| STRONG_AND_STABLE_WRITABLE_CONNECTION_PING_INTERVAL + SCHEDULING_RANGE); |
| |
| // Destabilized. |
| |
| conn->ReceivedPingResponse(LOW_RTT, "id"); |
| // Create a in-flight ping. |
| conn->Ping(clock.TimeNanos() / rtc::kNumNanosecsPerMillisec); |
| start = clock.TimeNanos(); |
| // In-flight ping timeout and the connection will be unstable. |
| SIMULATED_WAIT( |
| !conn->stable(clock.TimeNanos() / rtc::kNumNanosecsPerMillisec), |
| kMediumTimeout, clock); |
| int64_t duration_ms = |
| (clock.TimeNanos() - start) / rtc::kNumNanosecsPerMillisec; |
| EXPECT_GE(duration_ms, 2 * conn->rtt() - RTT_RANGE); |
| EXPECT_LE(duration_ms, 2 * conn->rtt() + RTT_RANGE); |
| // The connection become unstable due to not receiving ping responses. |
| ping_sent_before = conn->num_pings_sent(); |
| SIMULATED_WAIT(conn->num_pings_sent() == ping_sent_before + 1, kMediumTimeout, |
| clock); |
| // The interval is expected to be |
| // WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL. |
| start = clock.TimeNanos(); |
| ping_sent_before = conn->num_pings_sent(); |
| SIMULATED_WAIT(conn->num_pings_sent() == ping_sent_before + 1, kMediumTimeout, |
| clock); |
| ping_interval_ms = (clock.TimeNanos() - start) / rtc::kNumNanosecsPerMillisec; |
| EXPECT_GE(ping_interval_ms, |
| WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL); |
| EXPECT_LE( |
| ping_interval_ms, |
| WEAK_OR_STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL + SCHEDULING_RANGE); |
| } |
| |
| // Test that we start pinging as soon as we have a connection and remote ICE |
| // parameters. |
| TEST_F(P2PTransportChannelPingTest, PingingStartedAsSoonAsPossible) { |
| rtc::ScopedFakeClock clock; |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("TestChannel", 1, &pa); |
| ch.SetIceRole(ICEROLE_CONTROLLING); |
| ch.SetIceParameters(kIceParams[0]); |
| ch.MaybeStartGathering(); |
| EXPECT_EQ_WAIT(IceGatheringState::kIceGatheringComplete, ch.gathering_state(), |
| kDefaultTimeout); |
| |
| // Simulate a binding request being received, creating a peer reflexive |
| // candidate pair while we still don't have remote ICE parameters. |
| IceMessage request; |
| request.SetType(STUN_BINDING_REQUEST); |
| request.AddAttribute(absl::make_unique<StunByteStringAttribute>( |
| STUN_ATTR_USERNAME, kIceUfrag[1])); |
| uint32_t prflx_priority = ICE_TYPE_PREFERENCE_PRFLX << 24; |
| request.AddAttribute(absl::make_unique<StunUInt32Attribute>( |
| STUN_ATTR_PRIORITY, prflx_priority)); |
| Port* port = GetPort(&ch); |
| ASSERT_NE(nullptr, port); |
| port->SignalUnknownAddress(port, rtc::SocketAddress("1.1.1.1", 1), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn = GetConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_NE(nullptr, conn); |
| |
| // Simulate waiting for a second (and change) and verify that no pings were |
| // sent, since we don't yet have remote ICE parameters. |
| SIMULATED_WAIT(conn->num_pings_sent() > 0, 1025, clock); |
| EXPECT_EQ(0, conn->num_pings_sent()); |
| |
| // Set remote ICE parameters. Now we should be able to ping. Ensure that |
| // the first ping is sent as soon as possible, within one simulated clock |
| // tick. |
| ch.SetRemoteIceParameters(kIceParams[1]); |
| EXPECT_TRUE_SIMULATED_WAIT(conn->num_pings_sent() > 0, 1, clock); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestNoTriggeredChecksWhenWritable) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("trigger checks", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn1 != nullptr); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| EXPECT_EQ(conn2, FindNextPingableConnectionAndPingIt(&ch)); |
| EXPECT_EQ(conn1, FindNextPingableConnectionAndPingIt(&ch)); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| ASSERT_TRUE(conn1->writable()); |
| conn1->ReceivedPing(); |
| |
| // Ping received, but the connection is already writable, so no |
| // "triggered check" and conn2 is pinged before conn1 because it has |
| // a higher priority. |
| EXPECT_EQ(conn2, FindNextPingableConnectionAndPingIt(&ch)); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestFailedConnectionNotPingable) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("Do not ping failed connections", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| |
| EXPECT_EQ(conn1, ch.FindNextPingableConnection()); |
| conn1->Prune(); // A pruned connection may still be pingable. |
| EXPECT_EQ(conn1, ch.FindNextPingableConnection()); |
| conn1->FailAndPrune(); |
| EXPECT_TRUE(nullptr == ch.FindNextPingableConnection()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestSignalStateChanged) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("state change", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| // Pruning the connection reduces the set of active connections and changes |
| // the channel state. |
| conn1->Prune(); |
| EXPECT_EQ_WAIT(IceTransportState::STATE_FAILED, channel_state(), |
| kDefaultTimeout); |
| } |
| |
| // Test adding remote candidates with different ufrags. If a remote candidate |
| // is added with an old ufrag, it will be discarded. If it is added with a |
| // ufrag that was not seen before, it will be used to create connections |
| // although the ICE pwd in the remote candidate will be set when the ICE |
| // parameters arrive. If a remote candidate is added with the current ICE |
| // ufrag, its pwd and generation will be set properly. |
| TEST_F(P2PTransportChannelPingTest, TestAddRemoteCandidateWithVariousUfrags) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("add candidate", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| // Add a candidate with a future ufrag. |
| ch.AddRemoteCandidate( |
| CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1, kIceUfrag[2])); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| const Candidate& candidate = conn1->remote_candidate(); |
| EXPECT_EQ(kIceUfrag[2], candidate.username()); |
| EXPECT_TRUE(candidate.password().empty()); |
| EXPECT_TRUE(FindNextPingableConnectionAndPingIt(&ch) == nullptr); |
| |
| // Set the remote ICE parameters with the "future" ufrag. |
| // This should set the ICE pwd in the remote candidate of |conn1|, making |
| // it pingable. |
| ch.SetRemoteIceParameters(kIceParams[2]); |
| EXPECT_EQ(kIceUfrag[2], candidate.username()); |
| EXPECT_EQ(kIcePwd[2], candidate.password()); |
| EXPECT_EQ(conn1, FindNextPingableConnectionAndPingIt(&ch)); |
| |
| // Add a candidate with an old ufrag. No connection will be created. |
| ch.AddRemoteCandidate( |
| CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2, kIceUfrag[1])); |
| rtc::Thread::Current()->ProcessMessages(500); |
| EXPECT_TRUE(GetConnectionTo(&ch, "2.2.2.2", 2) == nullptr); |
| |
| // Add a candidate with the current ufrag, its pwd and generation will be |
| // assigned, even if the generation is not set. |
| ch.AddRemoteCandidate( |
| CreateUdpCandidate(LOCAL_PORT_TYPE, "3.3.3.3", 3, 0, kIceUfrag[2])); |
| Connection* conn3 = nullptr; |
| ASSERT_TRUE_WAIT((conn3 = GetConnectionTo(&ch, "3.3.3.3", 3)) != nullptr, |
| kMediumTimeout); |
| const Candidate& new_candidate = conn3->remote_candidate(); |
| EXPECT_EQ(kIcePwd[2], new_candidate.password()); |
| EXPECT_EQ(1U, new_candidate.generation()); |
| |
| // Check that the pwd of all remote candidates are properly assigned. |
| for (const RemoteCandidate& candidate : ch.remote_candidates()) { |
| EXPECT_TRUE(candidate.username() == kIceUfrag[1] || |
| candidate.username() == kIceUfrag[2]); |
| if (candidate.username() == kIceUfrag[1]) { |
| EXPECT_EQ(kIcePwd[1], candidate.password()); |
| } else if (candidate.username() == kIceUfrag[2]) { |
| EXPECT_EQ(kIcePwd[2], candidate.password()); |
| } |
| } |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, ConnectionResurrection) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("connection resurrection", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| |
| // Create conn1 and keep track of original candidate priority. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| uint32_t remote_priority = conn1->remote_candidate().priority(); |
| |
| // Create a higher priority candidate and make the connection |
| // receiving/writable. This will prune conn1. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPing(); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| |
| // Wait for conn1 to be pruned. |
| EXPECT_TRUE_WAIT(conn1->pruned(), kMediumTimeout); |
| // Destroy the connection to test SignalUnknownAddress. |
| conn1->Destroy(); |
| EXPECT_TRUE_WAIT(GetConnectionTo(&ch, "1.1.1.1", 1) == nullptr, |
| kMediumTimeout); |
| |
| // Create a minimal STUN message with prflx priority. |
| IceMessage request; |
| request.SetType(STUN_BINDING_REQUEST); |
| request.AddAttribute(absl::make_unique<StunByteStringAttribute>( |
| STUN_ATTR_USERNAME, kIceUfrag[1])); |
| uint32_t prflx_priority = ICE_TYPE_PREFERENCE_PRFLX << 24; |
| request.AddAttribute(absl::make_unique<StunUInt32Attribute>( |
| STUN_ATTR_PRIORITY, prflx_priority)); |
| EXPECT_NE(prflx_priority, remote_priority); |
| |
| Port* port = GetPort(&ch); |
| // conn1 should be resurrected with original priority. |
| port->SignalUnknownAddress(port, rtc::SocketAddress("1.1.1.1", 1), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| EXPECT_EQ(conn1->remote_candidate().priority(), remote_priority); |
| |
| // conn3, a real prflx connection, should have prflx priority. |
| port->SignalUnknownAddress(port, rtc::SocketAddress("3.3.3.3", 1), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 1); |
| ASSERT_TRUE(conn3 != nullptr); |
| EXPECT_EQ(conn3->remote_candidate().priority(), prflx_priority); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestReceivingStateChange) { |
| rtc::ScopedFakeClock clock; |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("receiving state change", 1, &pa); |
| PrepareChannel(&ch); |
| // Default receiving timeout and checking receiving interval should not be too |
| // small. |
| EXPECT_LE(1000, ch.config().receiving_timeout_or_default()); |
| EXPECT_LE(200, ch.check_receiving_interval()); |
| ch.SetIceConfig(CreateIceConfig(500, GATHER_ONCE)); |
| EXPECT_EQ(500, ch.config().receiving_timeout_or_default()); |
| EXPECT_EQ(50, ch.check_receiving_interval()); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1, &clock); |
| ASSERT_TRUE(conn1 != nullptr); |
| |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| conn1->ReceivedPing(); |
| conn1->OnReadPacket("ABC", 3, rtc::TimeMicros()); |
| EXPECT_TRUE_SIMULATED_WAIT(ch.receiving(), kShortTimeout, clock); |
| EXPECT_TRUE_SIMULATED_WAIT(!ch.receiving(), kShortTimeout, clock); |
| } |
| |
| // The controlled side will select a connection as the "selected connection" |
| // based on priority until the controlling side nominates a connection, at which |
| // point the controlled side will select that connection as the |
| // "selected connection". Plus, SignalNetworkRouteChanged will be fired if the |
| // selected connection changes and SignalReadyToSend will be fired if the new |
| // selected connection is writable. |
| TEST_F(P2PTransportChannelPingTest, TestSelectConnectionBeforeNomination) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("receiving state change", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| // Channel is not ready to send because it is not writable. |
| EXPECT_FALSE(channel_ready_to_send()); |
| int last_packet_id = 0; |
| const char* data = "ABCDEFGH"; |
| int len = static_cast<int>(strlen(data)); |
| EXPECT_EQ(-1, SendData(&ch, data, len, ++last_packet_id)); |
| EXPECT_EQ(-1, last_sent_packet_id()); |
| |
| // A connection needs to be writable before it is selected for transmission. |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_WAIT(conn1, ch.selected_connection(), kDefaultTimeout); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| EXPECT_EQ(len, SendData(&ch, data, len, ++last_packet_id)); |
| |
| // When a higher priority candidate comes in, the new connection is chosen |
| // as the selected connection. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 10)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_WAIT(conn2, ch.selected_connection(), kDefaultTimeout); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| EXPECT_TRUE(channel_ready_to_send()); |
| EXPECT_EQ(last_packet_id, last_sent_packet_id()); |
| |
| // If a stun request with use-candidate attribute arrives, the receiving |
| // connection will be set as the selected connection, even though |
| // its priority is lower. |
| EXPECT_EQ(len, SendData(&ch, data, len, ++last_packet_id)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "3.3.3.3", 3, 1)); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 3); |
| ASSERT_TRUE(conn3 != nullptr); |
| // Because it has a lower priority, the selected connection is still conn2. |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| conn3->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| // But if it is nominated via use_candidate, it is chosen as the selected |
| // connection. |
| NominateConnection(conn3); |
| EXPECT_EQ(conn3, ch.selected_connection()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn3)); |
| EXPECT_EQ(last_packet_id, last_sent_packet_id()); |
| EXPECT_TRUE(channel_ready_to_send()); |
| |
| // Even if another higher priority candidate arrives, it will not be set as |
| // the selected connection because the selected connection is nominated by |
| // the controlling side. |
| EXPECT_EQ(len, SendData(&ch, data, len, ++last_packet_id)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "4.4.4.4", 4, 100)); |
| Connection* conn4 = WaitForConnectionTo(&ch, "4.4.4.4", 4); |
| ASSERT_TRUE(conn4 != nullptr); |
| EXPECT_EQ(conn3, ch.selected_connection()); |
| // But if it is nominated via use_candidate and writable, it will be set as |
| // the selected connection. |
| NominateConnection(conn4); |
| // Not switched yet because conn4 is not writable. |
| EXPECT_EQ(conn3, ch.selected_connection()); |
| reset_channel_ready_to_send(); |
| // The selected connection switches after conn4 becomes writable. |
| conn4->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_WAIT(conn4, ch.selected_connection(), kDefaultTimeout); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn4)); |
| EXPECT_EQ(last_packet_id, last_sent_packet_id()); |
| // SignalReadyToSend is fired again because conn4 is writable. |
| EXPECT_TRUE(channel_ready_to_send()); |
| } |
| |
| // The controlled side will select a connection as the "selected connection" |
| // based on requests from an unknown address before the controlling side |
| // nominates a connection, and will nominate a connection from an unknown |
| // address if the request contains the use_candidate attribute. Plus, it will |
| // also sends back a ping response and set the ICE pwd in the remote candidate |
| // appropriately. |
| TEST_F(P2PTransportChannelPingTest, TestSelectConnectionFromUnknownAddress) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("receiving state change", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| // A minimal STUN message with prflx priority. |
| IceMessage request; |
| request.SetType(STUN_BINDING_REQUEST); |
| request.AddAttribute(absl::make_unique<StunByteStringAttribute>( |
| STUN_ATTR_USERNAME, kIceUfrag[1])); |
| uint32_t prflx_priority = ICE_TYPE_PREFERENCE_PRFLX << 24; |
| request.AddAttribute(absl::make_unique<StunUInt32Attribute>( |
| STUN_ATTR_PRIORITY, prflx_priority)); |
| TestUDPPort* port = static_cast<TestUDPPort*>(GetPort(&ch)); |
| port->SignalUnknownAddress(port, rtc::SocketAddress("1.1.1.1", 1), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| EXPECT_TRUE(port->sent_binding_response()); |
| EXPECT_NE(conn1, ch.selected_connection()); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_WAIT(conn1, ch.selected_connection(), kDefaultTimeout); |
| port->set_sent_binding_response(false); |
| |
| // Another connection is nominated via use_candidate. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 1)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn2 != nullptr); |
| // Because it has a lower priority, the selected connection is still conn1. |
| EXPECT_EQ(conn1, ch.selected_connection()); |
| // When it is nominated via use_candidate and writable, it is chosen as the |
| // selected connection. |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| NominateConnection(conn2); |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| |
| // Another request with unknown address, it will not be set as the selected |
| // connection because the selected connection was nominated by the controlling |
| // side. |
| port->SignalUnknownAddress(port, rtc::SocketAddress("3.3.3.3", 3), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 3); |
| ASSERT_TRUE(conn3 != nullptr); |
| EXPECT_TRUE(port->sent_binding_response()); |
| conn3->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| port->set_sent_binding_response(false); |
| |
| // However if the request contains use_candidate attribute, it will be |
| // selected as the selected connection. |
| request.AddAttribute( |
| absl::make_unique<StunByteStringAttribute>(STUN_ATTR_USE_CANDIDATE)); |
| port->SignalUnknownAddress(port, rtc::SocketAddress("4.4.4.4", 4), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn4 = WaitForConnectionTo(&ch, "4.4.4.4", 4); |
| ASSERT_TRUE(conn4 != nullptr); |
| EXPECT_TRUE(port->sent_binding_response()); |
| // conn4 is not the selected connection yet because it is not writable. |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| conn4->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| EXPECT_EQ_WAIT(conn4, ch.selected_connection(), kDefaultTimeout); |
| |
| // Test that the request from an unknown address contains a ufrag from an old |
| // generation. |
| port->set_sent_binding_response(false); |
| ch.SetRemoteIceParameters(kIceParams[2]); |
| ch.SetRemoteIceParameters(kIceParams[3]); |
| port->SignalUnknownAddress(port, rtc::SocketAddress("5.5.5.5", 5), PROTO_UDP, |
| &request, kIceUfrag[2], false); |
| Connection* conn5 = WaitForConnectionTo(&ch, "5.5.5.5", 5); |
| ASSERT_TRUE(conn5 != nullptr); |
| EXPECT_TRUE(port->sent_binding_response()); |
| EXPECT_EQ(kIcePwd[2], conn5->remote_candidate().password()); |
| } |
| |
| // The controlled side will select a connection as the "selected connection" |
| // based on media received until the controlling side nominates a connection, |
| // at which point the controlled side will select that connection as |
| // the "selected connection". |
| TEST_F(P2PTransportChannelPingTest, TestSelectConnectionBasedOnMediaReceived) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("receiving state change", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 10)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_WAIT(conn1, ch.selected_connection(), kDefaultTimeout); |
| |
| // If a data packet is received on conn2, the selected connection should |
| // switch to conn2 because the controlled side must mirror the media path |
| // chosen by the controlling side. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 1)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); // Become writable and receiving. |
| conn2->OnReadPacket("ABC", 3, rtc::TimeMicros()); |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| |
| // Now another STUN message with an unknown address and use_candidate will |
| // nominate the selected connection. |
| IceMessage request; |
| request.SetType(STUN_BINDING_REQUEST); |
| request.AddAttribute(absl::make_unique<StunByteStringAttribute>( |
| STUN_ATTR_USERNAME, kIceUfrag[1])); |
| uint32_t prflx_priority = ICE_TYPE_PREFERENCE_PRFLX << 24; |
| request.AddAttribute(absl::make_unique<StunUInt32Attribute>( |
| STUN_ATTR_PRIORITY, prflx_priority)); |
| request.AddAttribute( |
| absl::make_unique<StunByteStringAttribute>(STUN_ATTR_USE_CANDIDATE)); |
| Port* port = GetPort(&ch); |
| port->SignalUnknownAddress(port, rtc::SocketAddress("3.3.3.3", 3), PROTO_UDP, |
| &request, kIceUfrag[1], false); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 3); |
| ASSERT_TRUE(conn3 != nullptr); |
| EXPECT_EQ(conn2, ch.selected_connection()); // Not writable yet. |
| conn3->ReceivedPingResponse(LOW_RTT, "id"); // Become writable. |
| EXPECT_EQ_WAIT(conn3, ch.selected_connection(), kDefaultTimeout); |
| |
| // Now another data packet will not switch the selected connection because the |
| // selected connection was nominated by the controlling side. |
| conn2->ReceivedPing(); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| conn2->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| EXPECT_EQ_WAIT(conn3, ch.selected_connection(), kDefaultTimeout); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, |
| TestControlledAgentDataReceivingTakesHigherPrecedenceThanPriority) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("SwitchSelectedConnection", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| // The connections have decreasing priority. |
| Connection* conn1 = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 10, true); |
| ASSERT_TRUE(conn1 != nullptr); |
| Connection* conn2 = |
| CreateConnectionWithCandidate(&ch, &clock, "2.2.2.2", 2, 9, true); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| // Initially, connections are selected based on priority. |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| |
| // conn2 receives data; it becomes selected. |
| // Advance the clock by 1ms so that the last data receiving timestamp of |
| // conn2 is larger. |
| SIMULATED_WAIT(false, 1, clock); |
| conn2->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // conn1 also receives data; it becomes selected due to priority again. |
| conn1->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // conn2 received data more recently; it is selected now because it |
| // received data more recently. |
| SIMULATED_WAIT(false, 1, clock); |
| // Need to become writable again because it was pruned. |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| conn2->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // Make sure sorting won't reselect candidate pair. |
| SIMULATED_WAIT(false, 10, clock); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, |
| TestControlledAgentNominationTakesHigherPrecedenceThanDataReceiving) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("SwitchSelectedConnection", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| // The connections have decreasing priority. |
| Connection* conn1 = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 10, true); |
| ASSERT_TRUE(conn1 != nullptr); |
| Connection* conn2 = |
| CreateConnectionWithCandidate(&ch, &clock, "2.2.2.2", 2, 9, true); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| // conn1 received data; it is the selected connection. |
| // Advance the clock to have a non-zero last-data-receiving time. |
| SIMULATED_WAIT(false, 1, clock); |
| conn1->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| |
| // conn2 is nominated; it becomes the selected connection. |
| NominateConnection(conn2); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // conn1 is selected because it has higher priority and also nominated. |
| NominateConnection(conn1); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // Make sure sorting won't reselect candidate pair. |
| SIMULATED_WAIT(false, 10, clock); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, |
| TestControlledAgentSelectsConnectionWithHigherNomination) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| // The connections have decreasing priority. |
| Connection* conn1 = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 10, true); |
| ASSERT_TRUE(conn1 != nullptr); |
| Connection* conn2 = |
| CreateConnectionWithCandidate(&ch, &clock, "2.2.2.2", 2, 9, true); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| // conn1 is the selected connection because it has a higher priority, |
| EXPECT_EQ_SIMULATED_WAIT(conn1, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| reset_selected_candidate_pair_switches(); |
| |
| // conn2 is nominated; it becomes selected. |
| NominateConnection(conn2); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // conn1 is selected because of its priority. |
| NominateConnection(conn1); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_EQ(conn1, ch.selected_connection()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| |
| // conn2 gets higher remote nomination; it is selected again. |
| NominateConnection(conn2, 2U); |
| EXPECT_EQ(1, reset_selected_candidate_pair_switches()); |
| EXPECT_EQ(conn2, ch.selected_connection()); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // Make sure sorting won't reselect candidate pair. |
| SIMULATED_WAIT(false, 100, clock); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, |
| TestControlledAgentIgnoresSmallerNomination) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| Connection* conn = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 10, false); |
| ReceivePingOnConnection(conn, kIceUfrag[1], 1, 2U); |
| EXPECT_EQ(2U, conn->remote_nomination()); |
| // Smaller nomination is ignored. |
| ReceivePingOnConnection(conn, kIceUfrag[1], 1, 1U); |
| EXPECT_EQ(2U, conn->remote_nomination()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, |
| TestControlledAgentWriteStateTakesHigherPrecedenceThanNomination) { |
| rtc::ScopedFakeClock clock; |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("SwitchSelectedConnection", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| // The connections have decreasing priority. |
| Connection* conn1 = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 10, false); |
| ASSERT_TRUE(conn1 != nullptr); |
| Connection* conn2 = |
| CreateConnectionWithCandidate(&ch, &clock, "2.2.2.2", 2, 9, false); |
| ASSERT_TRUE(conn2 != nullptr); |
| |
| NominateConnection(conn1); |
| // There is no selected connection because no connection is writable. |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| |
| // conn2 becomes writable; it is selected even though it is not nominated. |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_SIMULATED_WAIT(1, reset_selected_candidate_pair_switches(), |
| kDefaultTimeout, clock); |
| EXPECT_EQ_SIMULATED_WAIT(conn2, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn2)); |
| |
| // If conn1 is also writable, it will become selected. |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_SIMULATED_WAIT(1, reset_selected_candidate_pair_switches(), |
| kDefaultTimeout, clock); |
| EXPECT_EQ_SIMULATED_WAIT(conn1, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| EXPECT_TRUE(CandidatePairMatchesNetworkRoute(conn1)); |
| |
| // Make sure sorting won't reselect candidate pair. |
| SIMULATED_WAIT(false, 10, clock); |
| EXPECT_EQ(0, reset_selected_candidate_pair_switches()); |
| } |
| |
| // Test that if a new remote candidate has the same address and port with |
| // an old one, it will be used to create a new connection. |
| TEST_F(P2PTransportChannelPingTest, TestAddRemoteCandidateWithAddressReuse) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("candidate reuse", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| const std::string host_address = "1.1.1.1"; |
| const int port_num = 1; |
| |
| // kIceUfrag[1] is the current generation ufrag. |
| Candidate candidate = CreateUdpCandidate(LOCAL_PORT_TYPE, host_address, |
| port_num, 1, kIceUfrag[1]); |
| ch.AddRemoteCandidate(candidate); |
| Connection* conn1 = WaitForConnectionTo(&ch, host_address, port_num); |
| ASSERT_TRUE(conn1 != nullptr); |
| EXPECT_EQ(0u, conn1->remote_candidate().generation()); |
| |
| // Simply adding the same candidate again won't create a new connection. |
| ch.AddRemoteCandidate(candidate); |
| Connection* conn2 = GetConnectionTo(&ch, host_address, port_num); |
| EXPECT_EQ(conn1, conn2); |
| |
| // Update the ufrag of the candidate and add it again. |
| candidate.set_username(kIceUfrag[2]); |
| ch.AddRemoteCandidate(candidate); |
| conn2 = GetConnectionTo(&ch, host_address, port_num); |
| EXPECT_NE(conn1, conn2); |
| EXPECT_EQ(kIceUfrag[2], conn2->remote_candidate().username()); |
| EXPECT_EQ(1u, conn2->remote_candidate().generation()); |
| |
| // Verify that a ping with the new ufrag can be received on the new |
| // connection. |
| EXPECT_EQ(0, conn2->last_ping_received()); |
| ReceivePingOnConnection(conn2, kIceUfrag[2], 1 /* priority */); |
| EXPECT_GT(conn2->last_ping_received(), 0); |
| } |
| |
| // When the current selected connection is strong, lower-priority connections |
| // will be pruned. Otherwise, lower-priority connections are kept. |
| TEST_F(P2PTransportChannelPingTest, TestDontPruneWhenWeak) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| EXPECT_EQ(nullptr, ch.selected_connection()); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); // Becomes writable and receiving |
| |
| // When a higher-priority, nominated candidate comes in, the connections with |
| // lower-priority are pruned. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 10)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2, &clock); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); // Becomes writable and receiving |
| NominateConnection(conn2); |
| EXPECT_TRUE_SIMULATED_WAIT(conn1->pruned(), kMediumTimeout, clock); |
| |
| ch.SetIceConfig(CreateIceConfig(500, GATHER_ONCE)); |
| // Wait until conn2 becomes not receiving. |
| EXPECT_TRUE_SIMULATED_WAIT(!conn2->receiving(), kMediumTimeout, clock); |
| |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "3.3.3.3", 3, 1)); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 3, &clock); |
| ASSERT_TRUE(conn3 != nullptr); |
| // The selected connection should still be conn2. Even through conn3 has lower |
| // priority and is not receiving/writable, it is not pruned because the |
| // selected connection is not receiving. |
| SIMULATED_WAIT(conn3->pruned(), kShortTimeout, clock); |
| EXPECT_FALSE(conn3->pruned()); |
| } |
| |
| TEST_F(P2PTransportChannelPingTest, TestDontPruneHighPriorityConnections) { |
| rtc::ScopedFakeClock clock; |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| Connection* conn1 = |
| CreateConnectionWithCandidate(&ch, &clock, "1.1.1.1", 1, 100, true); |
| ASSERT_TRUE(conn1 != nullptr); |
| Connection* conn2 = |
| CreateConnectionWithCandidate(&ch, &clock, "2.2.2.2", 2, 200, false); |
| ASSERT_TRUE(conn2 != nullptr); |
| // Even if conn1 is writable, nominated, receiving data, it should not prune |
| // conn2. |
| NominateConnection(conn1); |
| SIMULATED_WAIT(false, 1, clock); |
| conn1->OnReadPacket("XYZ", 3, rtc::TimeMicros()); |
| SIMULATED_WAIT(conn2->pruned(), 100, clock); |
| EXPECT_FALSE(conn2->pruned()); |
| } |
| |
| // Test that GetState returns the state correctly. |
| TEST_F(P2PTransportChannelPingTest, TestGetState) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| EXPECT_EQ(webrtc::IceTransportState::kNew, ch.GetIceTransportState()); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| // After gathering we are still in the kNew state because we aren't checking |
| // any connections yet. |
| EXPECT_EQ(webrtc::IceTransportState::kNew, ch.GetIceTransportState()); |
| EXPECT_EQ(IceTransportState::STATE_INIT, ch.GetState()); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 100)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 1)); |
| // Checking candidates that have been added with gathered candidates. |
| ASSERT_GT(ch.connections().size(), 0u); |
| EXPECT_EQ(webrtc::IceTransportState::kChecking, ch.GetIceTransportState()); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1, &clock); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2, &clock); |
| ASSERT_TRUE(conn1 != nullptr); |
| ASSERT_TRUE(conn2 != nullptr); |
| // Now there are two connections, so the transport channel is connecting. |
| EXPECT_EQ(IceTransportState::STATE_CONNECTING, ch.GetState()); |
| // No connections are writable yet, so we should still be in the kChecking |
| // state. |
| EXPECT_EQ(webrtc::IceTransportState::kChecking, ch.GetIceTransportState()); |
| // |conn1| becomes writable and receiving; it then should prune |conn2|. |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_TRUE_SIMULATED_WAIT(conn2->pruned(), kShortTimeout, clock); |
| EXPECT_EQ(IceTransportState::STATE_COMPLETED, ch.GetState()); |
| EXPECT_EQ(webrtc::IceTransportState::kConnected, ch.GetIceTransportState()); |
| conn1->Prune(); // All connections are pruned. |
| // Need to wait until the channel state is updated. |
| EXPECT_EQ_SIMULATED_WAIT(IceTransportState::STATE_FAILED, ch.GetState(), |
| kShortTimeout, clock); |
| EXPECT_EQ(webrtc::IceTransportState::kFailed, ch.GetIceTransportState()); |
| } |
| |
| // Test that when a low-priority connection is pruned, it is not deleted |
| // right away, and it can become active and be pruned again. |
| TEST_F(P2PTransportChannelPingTest, TestConnectionPrunedAgain) { |
| rtc::ScopedFakeClock clock; |
| clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| PrepareChannel(&ch); |
| IceConfig config = CreateIceConfig(1000, GATHER_ONCE); |
| config.receiving_switching_delay = 800; |
| ch.SetIceConfig(config); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 100)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1, &clock); |
| ASSERT_TRUE(conn1 != nullptr); |
| EXPECT_EQ(nullptr, ch.selected_connection()); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); // Becomes writable and receiving |
| EXPECT_EQ_SIMULATED_WAIT(conn1, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| |
| // Add a low-priority connection |conn2|, which will be pruned, but it will |
| // not be deleted right away. Once the current selected connection becomes not |
| // receiving, |conn2| will start to ping and upon receiving the ping response, |
| // it will become the selected connection. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 1)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2, &clock); |
| ASSERT_TRUE(conn2 != nullptr); |
| EXPECT_TRUE_SIMULATED_WAIT(!conn2->active(), kDefaultTimeout, clock); |
| // |conn2| should not send a ping yet. |
| EXPECT_EQ(IceCandidatePairState::WAITING, conn2->state()); |
| EXPECT_EQ(IceTransportState::STATE_COMPLETED, ch.GetState()); |
| // Wait for |conn1| becoming not receiving. |
| EXPECT_TRUE_SIMULATED_WAIT(!conn1->receiving(), kMediumTimeout, clock); |
| // Make sure conn2 is not deleted. |
| conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2, &clock); |
| ASSERT_TRUE(conn2 != nullptr); |
| EXPECT_EQ_SIMULATED_WAIT(IceCandidatePairState::IN_PROGRESS, conn2->state(), |
| kDefaultTimeout, clock); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_SIMULATED_WAIT(conn2, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| EXPECT_EQ(IceTransportState::STATE_CONNECTING, ch.GetState()); |
| |
| // When |conn1| comes back again, |conn2| will be pruned again. |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_EQ_SIMULATED_WAIT(conn1, ch.selected_connection(), kDefaultTimeout, |
| clock); |
| EXPECT_TRUE_SIMULATED_WAIT(!conn2->active(), kDefaultTimeout, clock); |
| EXPECT_EQ(IceTransportState::STATE_COMPLETED, ch.GetState()); |
| } |
| |
| // Test that if all connections in a channel has timed out on writing, they |
| // will all be deleted. We use Prune to simulate write_time_out. |
| TEST_F(P2PTransportChannelPingTest, TestDeleteConnectionsIfAllWriteTimedout) { |
| rtc::ScopedFakeClock clock; |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| // Have one connection only but later becomes write-time-out. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 100)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1, &clock); |
| ASSERT_TRUE(conn1 != nullptr); |
| conn1->ReceivedPing(); // Becomes receiving |
| conn1->Prune(); |
| EXPECT_TRUE_SIMULATED_WAIT(ch.connections().empty(), kShortTimeout, clock); |
| |
| // Have two connections but both become write-time-out later. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 1)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2, &clock); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPing(); // Becomes receiving |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "3.3.3.3", 3, 2)); |
| Connection* conn3 = WaitForConnectionTo(&ch, "3.3.3.3", 3, &clock); |
| ASSERT_TRUE(conn3 != nullptr); |
| conn3->ReceivedPing(); // Becomes receiving |
| // Now prune both conn2 and conn3; they will be deleted soon. |
| conn2->Prune(); |
| conn3->Prune(); |
| EXPECT_TRUE_SIMULATED_WAIT(ch.connections().empty(), kShortTimeout, clock); |
| } |
| |
| // Tests that after a port allocator session is started, it will be stopped |
| // when a new connection becomes writable and receiving. Also tests that if a |
| // connection belonging to an old session becomes writable, it won't stop |
| // the current port allocator session. |
| TEST_F(P2PTransportChannelPingTest, TestStopPortAllocatorSessions) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", 1, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceConfig(CreateIceConfig(2000, GATHER_ONCE)); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 100)); |
| Connection* conn1 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn1 != nullptr); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); // Becomes writable and receiving |
| EXPECT_TRUE(!ch.allocator_session()->IsGettingPorts()); |
| |
| // Start a new session. Even though conn1, which belongs to an older |
| // session, becomes unwritable and writable again, it should not stop the |
| // current session. |
| ch.SetIceParameters(kIceParams[1]); |
| ch.MaybeStartGathering(); |
| conn1->Prune(); |
| conn1->ReceivedPingResponse(LOW_RTT, "id"); |
| EXPECT_TRUE(ch.allocator_session()->IsGettingPorts()); |
| |
| // But if a new connection created from the new session becomes writable, |
| // it will stop the current session. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 100)); |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| ASSERT_TRUE(conn2 != nullptr); |
| conn2->ReceivedPingResponse(LOW_RTT, "id"); // Becomes writable and receiving |
| EXPECT_TRUE(!ch.allocator_session()->IsGettingPorts()); |
| } |
| |
| // Test that the ICE role is updated even on ports that has been removed. |
| // These ports may still have connections that need a correct role, in case that |
| // the connections on it may still receive stun pings. |
| TEST_F(P2PTransportChannelPingTest, TestIceRoleUpdatedOnRemovedPort) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", ICE_CANDIDATE_COMPONENT_DEFAULT, &pa); |
| // Starts with ICEROLE_CONTROLLING. |
| PrepareChannel(&ch); |
| IceConfig config = CreateIceConfig(1000, GATHER_CONTINUALLY); |
| ch.SetIceConfig(config); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| |
| Connection* conn = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn != nullptr); |
| |
| // Make a fake signal to remove the ports in the p2ptransportchannel. then |
| // change the ICE role and expect it to be updated. |
| std::vector<PortInterface*> ports(1, conn->port()); |
| ch.allocator_session()->SignalPortsPruned(ch.allocator_session(), ports); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| EXPECT_EQ(ICEROLE_CONTROLLED, conn->port()->GetIceRole()); |
| } |
| |
| // Test that the ICE role is updated even on ports with inactive networks. |
| // These ports may still have connections that need a correct role, for the |
| // pings sent by those connections until they're replaced by newer-generation |
| // connections. |
| TEST_F(P2PTransportChannelPingTest, TestIceRoleUpdatedOnPortAfterIceRestart) { |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", ICE_CANDIDATE_COMPONENT_DEFAULT, &pa); |
| // Starts with ICEROLE_CONTROLLING. |
| PrepareChannel(&ch); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| |
| Connection* conn = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn != nullptr); |
| |
| // Do an ICE restart, change the role, and expect the old port to have its |
| // role updated. |
| ch.SetIceParameters(kIceParams[1]); |
| ch.MaybeStartGathering(); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| EXPECT_EQ(ICEROLE_CONTROLLED, conn->port()->GetIceRole()); |
| } |
| |
| // Test that after some amount of time without receiving data, the connection |
| // will be destroyed. The port will only be destroyed after it is marked as |
| // "pruned." |
| TEST_F(P2PTransportChannelPingTest, TestPortDestroyedAfterTimeoutAndPruned) { |
| rtc::ScopedFakeClock fake_clock; |
| |
| FakePortAllocator pa(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel ch("test channel", ICE_CANDIDATE_COMPONENT_DEFAULT, &pa); |
| PrepareChannel(&ch); |
| ch.SetIceRole(ICEROLE_CONTROLLED); |
| ch.MaybeStartGathering(); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| |
| Connection* conn = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| ASSERT_TRUE(conn != nullptr); |
| |
| // Simulate 2 minutes going by. This should be enough time for the port to |
| // time out. |
| for (int second = 0; second < 120; ++second) { |
| fake_clock.AdvanceTime(webrtc::TimeDelta::seconds(1)); |
| } |
| EXPECT_EQ(nullptr, GetConnectionTo(&ch, "1.1.1.1", 1)); |
| // Port will not be removed because it is not pruned yet. |
| PortInterface* port = GetPort(&ch); |
| ASSERT_NE(nullptr, port); |
| |
| // If the session prunes all ports, the port will be destroyed. |
| ch.allocator_session()->PruneAllPorts(); |
| EXPECT_EQ_SIMULATED_WAIT(nullptr, GetPort(&ch), 1, fake_clock); |
| EXPECT_EQ_SIMULATED_WAIT(nullptr, GetPrunedPort(&ch), 1, fake_clock); |
| } |
| |
| class P2PTransportChannelMostLikelyToWorkFirstTest |
| : public P2PTransportChannelPingTest { |
| public: |
| P2PTransportChannelMostLikelyToWorkFirstTest() |
| : turn_server_(rtc::Thread::Current(), kTurnUdpIntAddr, kTurnUdpExtAddr) { |
| network_manager_.AddInterface(kPublicAddrs[0]); |
| allocator_.reset( |
| CreateBasicPortAllocator(&network_manager_, ServerAddresses(), |
| kTurnUdpIntAddr, rtc::SocketAddress())); |
| allocator_->set_flags(allocator_->flags() | PORTALLOCATOR_DISABLE_STUN | |
| PORTALLOCATOR_DISABLE_TCP); |
| allocator_->set_step_delay(kMinimumStepDelay); |
| } |
| |
| P2PTransportChannel& StartTransportChannel( |
| bool prioritize_most_likely_to_work, |
| int stable_writable_connection_ping_interval) { |
| channel_.reset(new P2PTransportChannel("checks", 1, allocator())); |
| IceConfig config = channel_->config(); |
| config.prioritize_most_likely_candidate_pairs = |
| prioritize_most_likely_to_work; |
| config.stable_writable_connection_ping_interval = |
| stable_writable_connection_ping_interval; |
| channel_->SetIceConfig(config); |
| PrepareChannel(channel_.get()); |
| channel_->MaybeStartGathering(); |
| return *channel_.get(); |
| } |
| |
| BasicPortAllocator* allocator() { return allocator_.get(); } |
| TestTurnServer* turn_server() { return &turn_server_; } |
| |
| // This verifies the next pingable connection has the expected candidates' |
| // types and, for relay local candidate, the expected relay protocol and ping |
| // it. |
| void VerifyNextPingableConnection( |
| const std::string& local_candidate_type, |
| const std::string& remote_candidate_type, |
| const std::string& relay_protocol_type = UDP_PROTOCOL_NAME) { |
| Connection* conn = FindNextPingableConnectionAndPingIt(channel_.get()); |
| EXPECT_EQ(conn->local_candidate().type(), local_candidate_type); |
| if (conn->local_candidate().type() == RELAY_PORT_TYPE) { |
| EXPECT_EQ(conn->local_candidate().relay_protocol(), relay_protocol_type); |
| } |
| EXPECT_EQ(conn->remote_candidate().type(), remote_candidate_type); |
| } |
| |
| private: |
| std::unique_ptr<BasicPortAllocator> allocator_; |
| rtc::FakeNetworkManager network_manager_; |
| TestTurnServer turn_server_; |
| std::unique_ptr<P2PTransportChannel> channel_; |
| }; |
| |
| // Test that Relay/Relay connections will be pinged first when no other |
| // connections have been pinged yet, unless we need to ping a trigger check or |
| // we have a selected connection. |
| TEST_F(P2PTransportChannelMostLikelyToWorkFirstTest, |
| TestRelayRelayFirstWhenNothingPingedYet) { |
| const int max_strong_interval = 500; |
| P2PTransportChannel& ch = StartTransportChannel(true, max_strong_interval); |
| EXPECT_TRUE_WAIT(ch.ports().size() == 2, kDefaultTimeout); |
| EXPECT_EQ(ch.ports()[0]->Type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(ch.ports()[1]->Type(), RELAY_PORT_TYPE); |
| |
| ch.AddRemoteCandidate(CreateUdpCandidate(RELAY_PORT_TYPE, "1.1.1.1", 1, 1)); |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| |
| EXPECT_TRUE_WAIT(ch.connections().size() == 4, kDefaultTimeout); |
| |
| // Relay/Relay should be the first pingable connection. |
| Connection* conn = FindNextPingableConnectionAndPingIt(&ch); |
| EXPECT_EQ(conn->local_candidate().type(), RELAY_PORT_TYPE); |
| EXPECT_EQ(conn->remote_candidate().type(), RELAY_PORT_TYPE); |
| |
| // Unless that we have a trigger check waiting to be pinged. |
| Connection* conn2 = WaitForConnectionTo(&ch, "2.2.2.2", 2); |
| EXPECT_EQ(conn2->local_candidate().type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(conn2->remote_candidate().type(), LOCAL_PORT_TYPE); |
| conn2->ReceivedPing(); |
| EXPECT_EQ(conn2, FindNextPingableConnectionAndPingIt(&ch)); |
| |
| // Make conn3 the selected connection. |
| Connection* conn3 = WaitForConnectionTo(&ch, "1.1.1.1", 1); |
| EXPECT_EQ(conn3->local_candidate().type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(conn3->remote_candidate().type(), RELAY_PORT_TYPE); |
| conn3->ReceivedPingResponse(LOW_RTT, "id"); |
| ASSERT_TRUE(conn3->writable()); |
| conn3->ReceivedPing(); |
| |
| /* |
| |
| TODO(honghaiz): Re-enable this once we use fake clock for this test to fix |
| the flakiness. The following test becomes flaky because we now ping the |
| connections with fast rates until every connection is pinged at least three |
| times. The selected connection may have been pinged before |
| |max_strong_interval|, so it may not be the next connection to be pinged as |
| expected in the test. |
| |
| // Verify that conn3 will be the "selected connection" since it is readable |
| // and writable. After |MAX_CURRENT_STRONG_INTERVAL|, it should be the next |
| // pingable connection. |
| EXPECT_TRUE_WAIT(conn3 == ch.selected_connection(), kDefaultTimeout); |
| WAIT(false, max_strong_interval + 100); |
| conn3->ReceivedPingResponse(LOW_RTT, "id"); |
| ASSERT_TRUE(conn3->writable()); |
| EXPECT_EQ(conn3, FindNextPingableConnectionAndPingIt(&ch)); |
| |
| */ |
| } |
| |
| // Test that Relay/Relay connections will be pinged first when everything has |
| // been pinged even if the Relay/Relay connection wasn't the first to be pinged |
| // in the first round. |
| TEST_F(P2PTransportChannelMostLikelyToWorkFirstTest, |
| TestRelayRelayFirstWhenEverythingPinged) { |
| P2PTransportChannel& ch = StartTransportChannel(true, 500); |
| EXPECT_TRUE_WAIT(ch.ports().size() == 2, kDefaultTimeout); |
| EXPECT_EQ(ch.ports()[0]->Type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(ch.ports()[1]->Type(), RELAY_PORT_TYPE); |
| |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "1.1.1.1", 1, 1)); |
| EXPECT_TRUE_WAIT(ch.connections().size() == 2, kDefaultTimeout); |
| |
| // Initially, only have Local/Local and Local/Relay. |
| VerifyNextPingableConnection(LOCAL_PORT_TYPE, LOCAL_PORT_TYPE); |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, LOCAL_PORT_TYPE); |
| |
| // Remote Relay candidate arrives. |
| ch.AddRemoteCandidate(CreateUdpCandidate(RELAY_PORT_TYPE, "2.2.2.2", 2, 2)); |
| EXPECT_TRUE_WAIT(ch.connections().size() == 4, kDefaultTimeout); |
| |
| // Relay/Relay should be the first since it hasn't been pinged before. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE); |
| |
| // Local/Relay is the final one. |
| VerifyNextPingableConnection(LOCAL_PORT_TYPE, RELAY_PORT_TYPE); |
| |
| // Now, every connection has been pinged once. The next one should be |
| // Relay/Relay. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE); |
| } |
| |
| // Test that when we receive a new remote candidate, they will be tried first |
| // before we re-ping Relay/Relay connections again. |
| TEST_F(P2PTransportChannelMostLikelyToWorkFirstTest, |
| TestNoStarvationOnNonRelayConnection) { |
| P2PTransportChannel& ch = StartTransportChannel(true, 500); |
| EXPECT_TRUE_WAIT(ch.ports().size() == 2, kDefaultTimeout); |
| EXPECT_EQ(ch.ports()[0]->Type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(ch.ports()[1]->Type(), RELAY_PORT_TYPE); |
| |
| ch.AddRemoteCandidate(CreateUdpCandidate(RELAY_PORT_TYPE, "1.1.1.1", 1, 1)); |
| EXPECT_TRUE_WAIT(ch.connections().size() == 2, kDefaultTimeout); |
| |
| // Initially, only have Relay/Relay and Local/Relay. Ping Relay/Relay first. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE); |
| |
| // Next, ping Local/Relay. |
| VerifyNextPingableConnection(LOCAL_PORT_TYPE, RELAY_PORT_TYPE); |
| |
| // Remote Local candidate arrives. |
| ch.AddRemoteCandidate(CreateUdpCandidate(LOCAL_PORT_TYPE, "2.2.2.2", 2, 2)); |
| EXPECT_TRUE_WAIT(ch.connections().size() == 4, kDefaultTimeout); |
| |
| // Local/Local should be the first since it hasn't been pinged before. |
| VerifyNextPingableConnection(LOCAL_PORT_TYPE, LOCAL_PORT_TYPE); |
| |
| // Relay/Local is the final one. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, LOCAL_PORT_TYPE); |
| |
| // Now, every connection has been pinged once. The next one should be |
| // Relay/Relay. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE); |
| } |
| |
| // Test the ping sequence is UDP Relay/Relay followed by TCP Relay/Relay, |
| // followed by the rest. |
| TEST_F(P2PTransportChannelMostLikelyToWorkFirstTest, TestTcpTurn) { |
| // Add a Tcp Turn server. |
| turn_server()->AddInternalSocket(kTurnTcpIntAddr, PROTO_TCP); |
| RelayServerConfig config(RELAY_TURN); |
| config.credentials = kRelayCredentials; |
| config.ports.push_back(ProtocolAddress(kTurnTcpIntAddr, PROTO_TCP)); |
| allocator()->AddTurnServer(config); |
| |
| P2PTransportChannel& ch = StartTransportChannel(true, 500); |
| EXPECT_TRUE_WAIT(ch.ports().size() == 3, kDefaultTimeout); |
| EXPECT_EQ(ch.ports()[0]->Type(), LOCAL_PORT_TYPE); |
| EXPECT_EQ(ch.ports()[1]->Type(), RELAY_PORT_TYPE); |
| EXPECT_EQ(ch.ports()[2]->Type(), RELAY_PORT_TYPE); |
| |
| // Remote Relay candidate arrives. |
| ch.AddRemoteCandidate(CreateUdpCandidate(RELAY_PORT_TYPE, "1.1.1.1", 1, 1)); |
| EXPECT_TRUE_WAIT(ch.connections().size() == 3, kDefaultTimeout); |
| |
| // UDP Relay/Relay should be pinged first. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE); |
| |
| // TCP Relay/Relay is the next. |
| VerifyNextPingableConnection(RELAY_PORT_TYPE, RELAY_PORT_TYPE, |
| TCP_PROTOCOL_NAME); |
| |
| // Finally, Local/Relay will be pinged. |
| VerifyNextPingableConnection(LOCAL_PORT_TYPE, RELAY_PORT_TYPE); |
| } |
| |
| // Test that a resolver is created, asked for a result, and destroyed |
| // when the address is a hostname. The destruction should happen even |
| // if the channel is not destroyed. |
| TEST(P2PTransportChannelResolverTest, HostnameCandidateIsResolved) { |
| rtc::MockAsyncResolver mock_async_resolver; |
| EXPECT_CALL(mock_async_resolver, GetError()).WillOnce(Return(0)); |
| EXPECT_CALL(mock_async_resolver, GetResolvedAddress(_, _)) |
| .WillOnce(Return(true)); |
| // Destroy is called asynchronously after the address is resolved, |
| // so we need a variable to wait on. |
| bool destroy_called = false; |
| EXPECT_CALL(mock_async_resolver, Destroy(_)) |
| .WillOnce(Assign(&destroy_called, true)); |
| webrtc::MockAsyncResolverFactory mock_async_resolver_factory; |
| EXPECT_CALL(mock_async_resolver_factory, Create()) |
| .WillOnce(Return(&mock_async_resolver)); |
| |
| FakePortAllocator allocator(rtc::Thread::Current(), nullptr); |
| P2PTransportChannel channel("tn", 0, &allocator, |
| &mock_async_resolver_factory); |
| Candidate hostname_candidate; |
| SocketAddress hostname_address("fake.test", 1000); |
| hostname_candidate.set_address(hostname_address); |
| channel.AddRemoteCandidate(hostname_candidate); |
| |
| ASSERT_EQ_WAIT(1u, channel.remote_candidates().size(), kDefaultTimeout); |
| const RemoteCandidate& candidate = channel.remote_candidates()[0]; |
| EXPECT_FALSE(candidate.address().IsUnresolvedIP()); |
| WAIT(destroy_called, kShortTimeout); |
| } |
| |
| // Test that if we signal a hostname candidate after the remote endpoint |
| // discovers a prflx remote candidate with the same underlying IP address, the |
| // prflx candidate is updated to a host candidate after the name resolution is |
| // done. |
| TEST_F(P2PTransportChannelTest, |
| PeerReflexiveCandidateBeforeSignalingWithMdnsName) { |
| rtc::MockAsyncResolver mock_async_resolver; |
| webrtc::MockAsyncResolverFactory mock_async_resolver_factory; |
| EXPECT_CALL(mock_async_resolver_factory, Create()) |
| .WillOnce(Return(&mock_async_resolver)); |
| |
| // ep1 and ep2 will only gather host candidates with addresses |
| // kPublicAddrs[0] and kPublicAddrs[1], respectively. |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| // ICE parameter will be set up when creating the channels. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| GetEndpoint(0)->network_manager_.CreateMdnsResponder(rtc::Thread::Current()); |
| GetEndpoint(1)->async_resolver_factory_ = &mock_async_resolver_factory; |
| CreateChannels(); |
| // Pause sending candidates from both endpoints until we find out what port |
| // number is assgined to ep1's host candidate. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| ASSERT_EQ_WAIT(1u, GetEndpoint(0)->saved_candidates_.size(), kMediumTimeout); |
| ASSERT_EQ(1u, GetEndpoint(0)->saved_candidates_[0]->candidates.size()); |
| const auto& local_candidate = |
| GetEndpoint(0)->saved_candidates_[0]->candidates[0]; |
| // The IP address of ep1's host candidate should be obfuscated. |
| EXPECT_TRUE(local_candidate.address().IsUnresolvedIP()); |
| // This is the underlying private IP address of the same candidate at ep1. |
| const auto local_address = rtc::SocketAddress( |
| kPublicAddrs[0].ipaddr(), local_candidate.address().port()); |
| // Let ep2 signal its candidate to ep1. ep1 should form a candidate |
| // pair and start to ping. After receiving the ping, ep2 discovers a prflx |
| // remote candidate and form a candidate pair as well. |
| ResumeCandidates(1); |
| ASSERT_TRUE_WAIT(ep1_ch1()->selected_connection() != nullptr, kMediumTimeout); |
| // ep2 should have the selected connection connected to the prflx remote |
| // candidate. |
| const Connection* selected_connection = nullptr; |
| ASSERT_TRUE_WAIT( |
| (selected_connection = ep2_ch1()->selected_connection()) != nullptr, |
| kMediumTimeout); |
| EXPECT_EQ(PRFLX_PORT_TYPE, selected_connection->remote_candidate().type()); |
| EXPECT_EQ(kIceUfrag[0], selected_connection->remote_candidate().username()); |
| EXPECT_EQ(kIcePwd[0], selected_connection->remote_candidate().password()); |
| // Set expectation before ep1 signals a hostname candidate. |
| { |
| InSequence sequencer; |
| EXPECT_CALL(mock_async_resolver, Start(_)); |
| EXPECT_CALL(mock_async_resolver, GetError()).WillOnce(Return(0)); |
| // Let the mock resolver of ep2 receives the correct resolution. |
| EXPECT_CALL(mock_async_resolver, GetResolvedAddress(_, _)) |
| .WillOnce(DoAll(SetArgPointee<1>(local_address), Return(true))); |
| } |
| // Destroy is called asynchronously after the address is resolved, |
| // so we need a variable to wait on. |
| bool destroy_called = false; |
| EXPECT_CALL(mock_async_resolver, Destroy(_)) |
| .WillOnce(Assign(&destroy_called, true)); |
| ResumeCandidates(0); |
| // Verify ep2's selected connection is updated to use the 'local' candidate. |
| EXPECT_EQ_WAIT(LOCAL_PORT_TYPE, |
| ep2_ch1()->selected_connection()->remote_candidate().type(), |
| kMediumTimeout); |
| EXPECT_EQ(selected_connection, ep2_ch1()->selected_connection()); |
| |
| WAIT(destroy_called, kShortTimeout); |
| DestroyChannels(); |
| } |
| |
| // Test that if we discover a prflx candidate during the process of name |
| // resolution for a remote hostname candidate, we update the prflx candidate to |
| // a host candidate if the hostname candidate turns out to have the same IP |
| // address after the resolution completes. |
| TEST_F(P2PTransportChannelTest, |
| PeerReflexiveCandidateDuringResolvingHostCandidateWithMdnsName) { |
| NiceMock<rtc::MockAsyncResolver> mock_async_resolver; |
| webrtc::MockAsyncResolverFactory mock_async_resolver_factory; |
| EXPECT_CALL(mock_async_resolver_factory, Create()) |
| .WillOnce(Return(&mock_async_resolver)); |
| |
| // ep1 and ep2 will only gather host candidates with addresses |
| // kPublicAddrs[0] and kPublicAddrs[1], respectively. |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| // ICE parameter will be set up when creating the channels. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| GetEndpoint(0)->network_manager_.CreateMdnsResponder(rtc::Thread::Current()); |
| GetEndpoint(1)->async_resolver_factory_ = &mock_async_resolver_factory; |
| CreateChannels(); |
| // Pause sending candidates from both endpoints until we find out what port |
| // number is assgined to ep1's host candidate. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| ASSERT_EQ_WAIT(1u, GetEndpoint(0)->saved_candidates_.size(), kMediumTimeout); |
| ASSERT_EQ(1u, GetEndpoint(0)->saved_candidates_[0]->candidates.size()); |
| const auto& local_candidate = |
| GetEndpoint(0)->saved_candidates_[0]->candidates[0]; |
| // The IP address of ep1's host candidate should be obfuscated. |
| EXPECT_TRUE(local_candidate.address().IsUnresolvedIP()); |
| // This is the underlying private IP address of the same candidate at ep1. |
| const auto local_address = rtc::SocketAddress( |
| kPublicAddrs[0].ipaddr(), local_candidate.address().port()); |
| bool mock_async_resolver_started = false; |
| // Not signaling done yet, and only make sure we are in the process of |
| // resolution. |
| EXPECT_CALL(mock_async_resolver, Start(_)) |
| .WillOnce(InvokeWithoutArgs([&mock_async_resolver_started]() { |
| mock_async_resolver_started = true; |
| })); |
| // Let ep1 signal its hostname candidate to ep2. |
| ResumeCandidates(0); |
| EXPECT_TRUE_WAIT(mock_async_resolver_started, kMediumTimeout); |
| // Now that ep2 is in the process of resolving the hostname candidate signaled |
| // by ep1. Let ep2 signal its host candidate with an IP address to ep1, so |
| // that ep1 can form a candidate pair, select it and start to ping ep2. |
| ResumeCandidates(1); |
| ASSERT_TRUE_WAIT(ep1_ch1()->selected_connection() != nullptr, kMediumTimeout); |
| // Let the mock resolver of ep2 receives the correct resolution. |
| EXPECT_CALL(mock_async_resolver, GetResolvedAddress(_, _)) |
| .WillOnce(DoAll(SetArgPointee<1>(local_address), Return(true))); |
| // Upon receiving a ping from ep1, ep2 adds a prflx candidate from the |
| // unknown address and establishes a connection. |
| // |
| // There is a caveat in our implementation associated with this expectation. |
| // See the big comment in P2PTransportChannel::OnUnknownAddress. |
| ASSERT_TRUE_WAIT(ep2_ch1()->selected_connection() != nullptr, kMediumTimeout); |
| EXPECT_EQ(PRFLX_PORT_TYPE, |
| ep2_ch1()->selected_connection()->remote_candidate().type()); |
| // ep2 should also be able resolve the hostname candidate. The resolved remote |
| // host candidate should be merged with the prflx remote candidate. |
| mock_async_resolver.SignalDone(&mock_async_resolver); |
| EXPECT_EQ_WAIT(LOCAL_PORT_TYPE, |
| ep2_ch1()->selected_connection()->remote_candidate().type(), |
| kMediumTimeout); |
| EXPECT_EQ(1u, ep2_ch1()->remote_candidates().size()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that if we only gather and signal a host candidate, the IP address of |
| // which is obfuscated by an mDNS name, and if the peer can complete the name |
| // resolution with the correct IP address, we can have a p2p connection. |
| TEST_F(P2PTransportChannelTest, CanConnectWithHostCandidateWithMdnsName) { |
| NiceMock<rtc::MockAsyncResolver> mock_async_resolver; |
| webrtc::MockAsyncResolverFactory mock_async_resolver_factory; |
| EXPECT_CALL(mock_async_resolver_factory, Create()) |
| .WillOnce(Return(&mock_async_resolver)); |
| |
| // ep1 and ep2 will only gather host candidates with addresses |
| // kPublicAddrs[0] and kPublicAddrs[1], respectively. |
| ConfigureEndpoints(OPEN, OPEN, kOnlyLocalPorts, kOnlyLocalPorts); |
| // ICE parameter will be set up when creating the channels. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| GetEndpoint(0)->network_manager_.CreateMdnsResponder(rtc::Thread::Current()); |
| GetEndpoint(1)->async_resolver_factory_ = &mock_async_resolver_factory; |
| CreateChannels(); |
| // Pause sending candidates from both endpoints until we find out what port |
| // number is assgined to ep1's host candidate. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| ASSERT_EQ_WAIT(1u, GetEndpoint(0)->saved_candidates_.size(), kMediumTimeout); |
| ASSERT_EQ(1u, GetEndpoint(0)->saved_candidates_[0]->candidates.size()); |
| const auto& local_candidate_ep1 = |
| GetEndpoint(0)->saved_candidates_[0]->candidates[0]; |
| // The IP address of ep1's host candidate should be obfuscated. |
| EXPECT_TRUE(local_candidate_ep1.address().IsUnresolvedIP()); |
| // This is the underlying private IP address of the same candidate at ep1, |
| // and let the mock resolver of ep2 receive the correct resolution. |
| rtc::SocketAddress resolved_address_ep1(local_candidate_ep1.address()); |
| resolved_address_ep1.SetResolvedIP(kPublicAddrs[0].ipaddr()); |
| |
| EXPECT_CALL(mock_async_resolver, GetResolvedAddress(_, _)) |
| .WillOnce(DoAll(SetArgPointee<1>(resolved_address_ep1), Return(true))); |
| // Let ep1 signal its hostname candidate to ep2. |
| ResumeCandidates(0); |
| |
| // We should be able to receive a ping from ep2 and establish a connection |
| // with a peer reflexive candidate from ep2. |
| ASSERT_TRUE_WAIT((ep1_ch1()->selected_connection()) != nullptr, |
| kMediumTimeout); |
| EXPECT_EQ(LOCAL_PORT_TYPE, |
| ep1_ch1()->selected_connection()->local_candidate().type()); |
| EXPECT_EQ(PRFLX_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| |
| DestroyChannels(); |
| } |
| |
| // Test that when the IP of a host candidate is concealed by an mDNS name, the |
| // stats from the gathering ICE endpoint do not reveal the address of this local |
| // host candidate or the related address of a local srflx candidate from the |
| // same endpoint. Also, the remote ICE endpoint that successfully resolves a |
| // signaled host candidate with an mDNS name should not reveal the address of |
| // this remote host candidate in stats. |
| TEST_F(P2PTransportChannelTest, |
| CandidatesSanitizedInStatsWhenMdnsObfuscationEnabled) { |
| NiceMock<rtc::MockAsyncResolver> mock_async_resolver; |
| webrtc::MockAsyncResolverFactory mock_async_resolver_factory; |
| EXPECT_CALL(mock_async_resolver_factory, Create()) |
| .WillOnce(Return(&mock_async_resolver)); |
| |
| // ep1 and ep2 will gather host candidates with addresses |
| // kPublicAddrs[0] and kPublicAddrs[1], respectively. ep1 also gathers a srflx |
| // and a relay candidates. |
| ConfigureEndpoints(OPEN, OPEN, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_DISABLE_TCP, |
| kOnlyLocalPorts); |
| // ICE parameter will be set up when creating the channels. |
| set_remote_ice_parameter_source(FROM_SETICEPARAMETERS); |
| GetEndpoint(0)->network_manager_.CreateMdnsResponder(rtc::Thread::Current()); |
| GetEndpoint(1)->async_resolver_factory_ = &mock_async_resolver_factory; |
| CreateChannels(); |
| // Pause sending candidates from both endpoints until we find out what port |
| // number is assigned to ep1's host candidate. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| // Ep1 has a UDP host, a srflx and a relay candidates. |
| ASSERT_EQ_WAIT(3u, GetEndpoint(0)->saved_candidates_.size(), kMediumTimeout); |
| ASSERT_EQ_WAIT(1u, GetEndpoint(1)->saved_candidates_.size(), kMediumTimeout); |
| |
| for (const auto& candidates_data : GetEndpoint(0)->saved_candidates_) { |
| ASSERT_EQ(1u, candidates_data->candidates.size()); |
| const auto& local_candidate_ep1 = candidates_data->candidates[0]; |
| if (local_candidate_ep1.type() == LOCAL_PORT_TYPE) { |
| // This is the underlying private IP address of the same candidate at ep1, |
| // and let the mock resolver of ep2 receive the correct resolution. |
| rtc::SocketAddress resolved_address_ep1(local_candidate_ep1.address()); |
| resolved_address_ep1.SetResolvedIP(kPublicAddrs[0].ipaddr()); |
| EXPECT_CALL(mock_async_resolver, GetResolvedAddress(_, _)) |
| .WillOnce( |
| DoAll(SetArgPointee<1>(resolved_address_ep1), Return(true))); |
| break; |
| } |
| } |
| ResumeCandidates(0); |
| ResumeCandidates(1); |
| |
| ASSERT_EQ_WAIT(kIceGatheringComplete, ep1_ch1()->gathering_state(), |
| kMediumTimeout); |
| // We should have the following candidate pairs on both endpoints: |
| // ep1_host <-> ep2_host, ep1_srflx <-> ep2_host, ep1_relay <-> ep2_host |
| ASSERT_EQ_WAIT(3u, ep1_ch1()->connections().size(), kMediumTimeout); |
| ASSERT_EQ_WAIT(3u, ep2_ch1()->connections().size(), kMediumTimeout); |
| |
| ConnectionInfos connection_infos_ep1; |
| CandidateStatsList candidate_stats_list_ep1; |
| ConnectionInfos connection_infos_ep2; |
| CandidateStatsList candidate_stats_list_ep2; |
| ep1_ch1()->GetStats(&connection_infos_ep1, &candidate_stats_list_ep1); |
| ep2_ch1()->GetStats(&connection_infos_ep2, &candidate_stats_list_ep2); |
| EXPECT_EQ(3u, connection_infos_ep1.size()); |
| EXPECT_EQ(3u, candidate_stats_list_ep1.size()); |
| EXPECT_EQ(3u, connection_infos_ep2.size()); |
| // Check the stats of ep1 seen by ep1. |
| for (const auto& connection_info : connection_infos_ep1) { |
| const auto& local_candidate = connection_info.local_candidate; |
| if (local_candidate.type() == LOCAL_PORT_TYPE) { |
| EXPECT_TRUE(local_candidate.address().IsUnresolvedIP()); |
| } else if (local_candidate.type() == STUN_PORT_TYPE) { |
| EXPECT_TRUE(local_candidate.related_address().IsAnyIP()); |
| } else if (local_candidate.type() == RELAY_PORT_TYPE) { |
| // The related address of the relay candidate should be equal to the |
| // srflx address. Note that NAT is not configured, hence the following |
| // expectation. |
| EXPECT_EQ(kPublicAddrs[0].ipaddr(), |
| local_candidate.related_address().ipaddr()); |
| } else { |
| FAIL(); |
| } |
| } |
| // Check the stats of ep1 seen by ep2. |
| for (const auto& connection_info : connection_infos_ep2) { |
| const auto& remote_candidate = connection_info.remote_candidate; |
| if (remote_candidate.type() == LOCAL_PORT_TYPE) { |
| EXPECT_TRUE(remote_candidate.address().IsUnresolvedIP()); |
| } else if (remote_candidate.type() == STUN_PORT_TYPE) { |
| EXPECT_TRUE(remote_candidate.related_address().IsAnyIP()); |
| } else if (remote_candidate.type() == RELAY_PORT_TYPE) { |
| EXPECT_EQ(kPublicAddrs[0].ipaddr(), |
| remote_candidate.related_address().ipaddr()); |
| } else { |
| FAIL(); |
| } |
| } |
| DestroyChannels(); |
| } |
| |
| // Test that after changing the candidate filter from relay-only to allowing all |
| // types of candidates when doing continual gathering, we can gather without ICE |
| // restart the other types of candidates that are now enabled and form candidate |
| // pairs. Also, we verify that the relay candidates gathered previously are not |
| // removed and are still usable for necessary route switching. |
| TEST_F(P2PTransportChannelTest, |
| SurfaceHostCandidateOnCandidateFilterChangeFromRelayToAll) { |
| webrtc::test::ScopedFieldTrials field_trials( |
| "WebRTC-GatherOnCandidateFilterChanged/Enabled/"); |
| rtc::ScopedFakeClock clock; |
| |
| ConfigureEndpoints( |
| OPEN, OPEN, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET); |
| auto* ep1 = GetEndpoint(0); |
| auto* ep2 = GetEndpoint(1); |
| ep1->allocator_->SetCandidateFilter(CF_RELAY); |
| ep2->allocator_->SetCandidateFilter(CF_RELAY); |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| CreateChannels(continual_gathering_config, continual_gathering_config); |
| ASSERT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| ASSERT_TRUE_SIMULATED_WAIT(ep2_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->local_candidate().type()); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep2_ch1()->selected_connection()->local_candidate().type()); |
| |
| // Loosen the candidate filter at ep1. |
| ep1->allocator_->SetCandidateFilter(CF_ALL); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() != nullptr && |
| ep1_ch1()->selected_connection()->local_candidate().type() == |
| LOCAL_PORT_TYPE, |
| kDefaultTimeout, clock); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| |
| // Loosen the candidate filter at ep2. |
| ep2->allocator_->SetCandidateFilter(CF_ALL); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep2_ch1()->selected_connection() != nullptr && |
| ep2_ch1()->selected_connection()->local_candidate().type() == |
| LOCAL_PORT_TYPE, |
| kDefaultTimeout, clock); |
| // We have migrated to a host-host candidate pair. |
| EXPECT_EQ(LOCAL_PORT_TYPE, |
| ep2_ch1()->selected_connection()->remote_candidate().type()); |
| |
| // Block the traffic over non-relay-to-relay routes and expect a route change. |
| fw()->AddRule(false, rtc::FP_ANY, kPublicAddrs[0], kPublicAddrs[1]); |
| fw()->AddRule(false, rtc::FP_ANY, kPublicAddrs[1], kPublicAddrs[0]); |
| fw()->AddRule(false, rtc::FP_ANY, kPublicAddrs[0], kTurnUdpExtAddr); |
| fw()->AddRule(false, rtc::FP_ANY, kPublicAddrs[1], kTurnUdpExtAddr); |
| // We should be able to reuse the previously gathered relay candidates. |
| EXPECT_EQ_SIMULATED_WAIT( |
| RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->local_candidate().type(), |
| kDefaultTimeout, clock); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| } |
| |
| // A similar test as SurfaceHostCandidateOnCandidateFilterChangeFromRelayToAll, |
| // and we should surface server-reflexive candidates that are enabled after |
| // changing the candidate filter. |
| TEST_F(P2PTransportChannelTest, |
| SurfaceSrflxCandidateOnCandidateFilterChangeFromRelayToNoHost) { |
| webrtc::test::ScopedFieldTrials field_trials( |
| "WebRTC-GatherOnCandidateFilterChanged/Enabled/"); |
| rtc::ScopedFakeClock clock; |
| // We need an actual NAT so that the host candidate is not equivalent to the |
| // srflx candidate; otherwise, the host candidate would still surface even |
| // though we disable it via the candidate filter below. This is a result of |
| // the following limitation in the current implementation: |
| // 1. We don't generate the srflx candidate when we have public IP. |
| // 2. We keep the host candidate in this case in CheckCandidateFilter even |
| // though we intend to filter them. |
| ConfigureEndpoints( |
| NAT_FULL_CONE, NAT_FULL_CONE, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET); |
| auto* ep1 = GetEndpoint(0); |
| auto* ep2 = GetEndpoint(1); |
| ep1->allocator_->SetCandidateFilter(CF_RELAY); |
| ep2->allocator_->SetCandidateFilter(CF_RELAY); |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| CreateChannels(continual_gathering_config, continual_gathering_config); |
| ASSERT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| ASSERT_TRUE_SIMULATED_WAIT(ep2_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| const uint32_t kCandidateFilterNoHost = CF_ALL & ~CF_HOST; |
| // Loosen the candidate filter at ep1. |
| ep1->allocator_->SetCandidateFilter(kCandidateFilterNoHost); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep1_ch1()->selected_connection() != nullptr && |
| ep1_ch1()->selected_connection()->local_candidate().type() == |
| STUN_PORT_TYPE, |
| kDefaultTimeout, clock); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| |
| // Loosen the candidate filter at ep2. |
| ep2->allocator_->SetCandidateFilter(kCandidateFilterNoHost); |
| EXPECT_TRUE_SIMULATED_WAIT( |
| ep2_ch1()->selected_connection() != nullptr && |
| ep2_ch1()->selected_connection()->local_candidate().type() == |
| STUN_PORT_TYPE, |
| kDefaultTimeout, clock); |
| // We have migrated to a srflx-srflx candidate pair. |
| EXPECT_EQ(STUN_PORT_TYPE, |
| ep2_ch1()->selected_connection()->remote_candidate().type()); |
| |
| // Block the traffic over non-relay-to-relay routes and expect a route change. |
| fw()->AddRule(false, rtc::FP_ANY, kPrivateAddrs[0], kPublicAddrs[1]); |
| fw()->AddRule(false, rtc::FP_ANY, kPrivateAddrs[1], kPublicAddrs[0]); |
| fw()->AddRule(false, rtc::FP_ANY, kPrivateAddrs[0], kTurnUdpExtAddr); |
| fw()->AddRule(false, rtc::FP_ANY, kPrivateAddrs[1], kTurnUdpExtAddr); |
| // We should be able to reuse the previously gathered relay candidates. |
| EXPECT_EQ_SIMULATED_WAIT( |
| RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->local_candidate().type(), |
| kDefaultTimeout, clock); |
| EXPECT_EQ(RELAY_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| } |
| |
| // Test that when the candidate filter is updated to be more restrictive, |
| // candidates that 1) have already been gathered and signaled 2) but no longer |
| // match the filter, are not removed. |
| TEST_F(P2PTransportChannelTest, |
| RestrictingCandidateFilterDoesNotRemoveRegatheredCandidates) { |
| webrtc::test::ScopedFieldTrials field_trials( |
| "WebRTC-GatherOnCandidateFilterChanged/Enabled/"); |
| rtc::ScopedFakeClock clock; |
| |
| ConfigureEndpoints( |
| OPEN, OPEN, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET, |
| kDefaultPortAllocatorFlags | PORTALLOCATOR_ENABLE_SHARED_SOCKET); |
| auto* ep1 = GetEndpoint(0); |
| auto* ep2 = GetEndpoint(1); |
| ep1->allocator_->SetCandidateFilter(CF_ALL); |
| ep2->allocator_->SetCandidateFilter(CF_ALL); |
| IceConfig continual_gathering_config = |
| CreateIceConfig(1000, GATHER_CONTINUALLY); |
| // Pause candidates so we can gather all types of candidates. See |
| // P2PTransportChannel::OnConnectionStateChange, where we would stop the |
| // gathering when we have a strongly connected candidate pair. |
| PauseCandidates(0); |
| PauseCandidates(1); |
| CreateChannels(continual_gathering_config, continual_gathering_config); |
| |
| // We have gathered host, srflx and relay candidates. |
| EXPECT_TRUE_SIMULATED_WAIT(ep1->saved_candidates_.size() == 3u, |
| kDefaultTimeout, clock); |
| ResumeCandidates(0); |
| ResumeCandidates(1); |
| ASSERT_TRUE_SIMULATED_WAIT(ep1_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| ASSERT_TRUE_SIMULATED_WAIT(ep2_ch1()->selected_connection() != nullptr, |
| kDefaultTimeout, clock); |
| // Test that we have a host-host candidate pair selected and the number of |
| // candidates signaled to the remote peer stays the same. |
| auto test_invariants = [this]() { |
| EXPECT_EQ(LOCAL_PORT_TYPE, |
| ep1_ch1()->selected_connection()->local_candidate().type()); |
| EXPECT_EQ(LOCAL_PORT_TYPE, |
| ep1_ch1()->selected_connection()->remote_candidate().type()); |
| EXPECT_THAT(ep2_ch1()->remote_candidates(), SizeIs(3)); |
| }; |
| |
| test_invariants(); |
| |
| // Set a more restrictive candidate filter at ep1. |
| ep1->allocator_->SetCandidateFilter(CF_HOST | CF_REFLEXIVE); |
| SIMULATED_WAIT(false, kDefaultTimeout, clock); |
| test_invariants(); |
| |
| ep1->allocator_->SetCandidateFilter(CF_HOST); |
| SIMULATED_WAIT(false, kDefaultTimeout, clock); |
| test_invariants(); |
| |
| ep1->allocator_->SetCandidateFilter(CF_NONE); |
| SIMULATED_WAIT(false, kDefaultTimeout, clock); |
| test_invariants(); |
| } |
| |
| } // namespace cricket |