/* * Copyright 2016 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 "p2p/base/port_allocator.h" #include #include "absl/strings/string_view.h" #include "p2p/base/fake_port_allocator.h" #include "rtc_base/thread.h" #include "rtc_base/virtual_socket_server.h" #include "test/gtest.h" static const char kContentName[] = "test content"; // Based on ICE_UFRAG_LENGTH static const char kIceUfrag[] = "UF00"; // Based on ICE_PWD_LENGTH static const char kIcePwd[] = "TESTICEPWD00000000000000"; static const char kTurnUsername[] = "test"; static const char kTurnPassword[] = "test"; constexpr uint64_t kTiebreakerDefault = 44444; class PortAllocatorTest : public ::testing::Test, public sigslot::has_slots<> { public: PortAllocatorTest() : vss_(std::make_unique()), main_(vss_.get()), packet_socket_factory_( std::make_unique(vss_.get())), allocator_(std::make_unique( rtc::Thread::Current(), packet_socket_factory_.get())) { allocator_->SetIceTiebreaker(kTiebreakerDefault); } protected: void SetConfigurationWithPoolSize(int candidate_pool_size) { EXPECT_TRUE(allocator_->SetConfiguration( cricket::ServerAddresses(), std::vector(), candidate_pool_size, webrtc::NO_PRUNE)); } void SetConfigurationWithPoolSizeExpectFailure(int candidate_pool_size) { EXPECT_FALSE(allocator_->SetConfiguration( cricket::ServerAddresses(), std::vector(), candidate_pool_size, webrtc::NO_PRUNE)); } std::unique_ptr CreateSession( absl::string_view content_name, int component, absl::string_view ice_ufrag, absl::string_view ice_pwd) { return std::unique_ptr( static_cast( allocator_ ->CreateSession(content_name, component, ice_ufrag, ice_pwd) .release())); } const cricket::FakePortAllocatorSession* GetPooledSession() const { return static_cast( allocator_->GetPooledSession()); } std::unique_ptr TakePooledSession() { return std::unique_ptr( static_cast( allocator_->TakePooledSession(kContentName, 0, kIceUfrag, kIcePwd) .release())); } int GetAllPooledSessionsReturnCount() { int count = 0; while (TakePooledSession() != nullptr) { ++count; } return count; } std::unique_ptr vss_; rtc::AutoSocketServerThread main_; std::unique_ptr packet_socket_factory_; std::unique_ptr allocator_; rtc::SocketAddress stun_server_1{"11.11.11.11", 3478}; rtc::SocketAddress stun_server_2{"22.22.22.22", 3478}; cricket::RelayServerConfig turn_server_1{"11.11.11.11", 3478, kTurnUsername, kTurnPassword, cricket::PROTO_UDP, false}; cricket::RelayServerConfig turn_server_2{"22.22.22.22", 3478, kTurnUsername, kTurnPassword, cricket::PROTO_UDP, false}; }; TEST_F(PortAllocatorTest, TestDefaults) { EXPECT_EQ(0UL, allocator_->stun_servers().size()); EXPECT_EQ(0UL, allocator_->turn_servers().size()); EXPECT_EQ(0, allocator_->candidate_pool_size()); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); } // Call CreateSession and verify that the parameters passed in and the // candidate filter are applied as expected. TEST_F(PortAllocatorTest, CreateSession) { allocator_->SetCandidateFilter(cricket::CF_RELAY); auto session = CreateSession(kContentName, 1, kIceUfrag, kIcePwd); ASSERT_NE(nullptr, session); EXPECT_EQ(cricket::CF_RELAY, session->candidate_filter()); EXPECT_EQ(kContentName, session->content_name()); EXPECT_EQ(1, session->component()); EXPECT_EQ(kIceUfrag, session->ice_ufrag()); EXPECT_EQ(kIcePwd, session->ice_pwd()); } TEST_F(PortAllocatorTest, SetConfigurationUpdatesIceServers) { cricket::ServerAddresses stun_servers_1 = {stun_server_1}; std::vector turn_servers_1 = {turn_server_1}; EXPECT_TRUE(allocator_->SetConfiguration(stun_servers_1, turn_servers_1, 0, webrtc::NO_PRUNE)); EXPECT_EQ(stun_servers_1, allocator_->stun_servers()); EXPECT_EQ(turn_servers_1, allocator_->turn_servers()); // Update with a different set of servers. cricket::ServerAddresses stun_servers_2 = {stun_server_2}; std::vector turn_servers_2 = {turn_server_2}; EXPECT_TRUE(allocator_->SetConfiguration(stun_servers_2, turn_servers_2, 0, webrtc::NO_PRUNE)); EXPECT_EQ(stun_servers_2, allocator_->stun_servers()); EXPECT_EQ(turn_servers_2, allocator_->turn_servers()); } TEST_F(PortAllocatorTest, SetConfigurationUpdatesCandidatePoolSize) { SetConfigurationWithPoolSize(2); EXPECT_EQ(2, allocator_->candidate_pool_size()); SetConfigurationWithPoolSize(3); EXPECT_EQ(3, allocator_->candidate_pool_size()); SetConfigurationWithPoolSize(1); EXPECT_EQ(1, allocator_->candidate_pool_size()); SetConfigurationWithPoolSize(4); EXPECT_EQ(4, allocator_->candidate_pool_size()); } // A negative pool size should just be treated as zero. TEST_F(PortAllocatorTest, SetConfigurationWithNegativePoolSizeFails) { SetConfigurationWithPoolSizeExpectFailure(-1); } // Test that if the candidate pool size is nonzero, pooled sessions are // created, and StartGettingPorts is called on them. TEST_F(PortAllocatorTest, SetConfigurationCreatesPooledSessions) { SetConfigurationWithPoolSize(2); auto session_1 = TakePooledSession(); auto session_2 = TakePooledSession(); ASSERT_NE(nullptr, session_1.get()); ASSERT_NE(nullptr, session_2.get()); EXPECT_EQ(1, session_1->port_config_count()); EXPECT_EQ(1, session_2->port_config_count()); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); } // Test that if the candidate pool size is increased, pooled sessions are // created as necessary. TEST_F(PortAllocatorTest, SetConfigurationCreatesMorePooledSessions) { SetConfigurationWithPoolSize(1); SetConfigurationWithPoolSize(2); EXPECT_EQ(2, GetAllPooledSessionsReturnCount()); } // Test that if the candidate pool size is reduced, extra sessions are // destroyed. TEST_F(PortAllocatorTest, SetConfigurationDestroysPooledSessions) { SetConfigurationWithPoolSize(2); SetConfigurationWithPoolSize(1); EXPECT_EQ(1, GetAllPooledSessionsReturnCount()); } // According to JSEP, existing pooled sessions should be destroyed and new // ones created when the ICE servers change. TEST_F(PortAllocatorTest, SetConfigurationRecreatesPooledSessionsWhenIceServersChange) { cricket::ServerAddresses stun_servers_1 = {stun_server_1}; std::vector turn_servers_1 = {turn_server_1}; allocator_->SetConfiguration(stun_servers_1, turn_servers_1, 1, webrtc::NO_PRUNE); EXPECT_EQ(stun_servers_1, allocator_->stun_servers()); EXPECT_EQ(turn_servers_1, allocator_->turn_servers()); // Update with a different set of servers (and also change pool size). cricket::ServerAddresses stun_servers_2 = {stun_server_2}; std::vector turn_servers_2 = {turn_server_2}; allocator_->SetConfiguration(stun_servers_2, turn_servers_2, 2, webrtc::NO_PRUNE); EXPECT_EQ(stun_servers_2, allocator_->stun_servers()); EXPECT_EQ(turn_servers_2, allocator_->turn_servers()); auto session_1 = TakePooledSession(); auto session_2 = TakePooledSession(); ASSERT_NE(nullptr, session_1.get()); ASSERT_NE(nullptr, session_2.get()); EXPECT_EQ(stun_servers_2, session_1->stun_servers()); EXPECT_EQ(turn_servers_2, session_1->turn_servers()); EXPECT_EQ(stun_servers_2, session_2->stun_servers()); EXPECT_EQ(turn_servers_2, session_2->turn_servers()); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); } // According to JSEP, after SetLocalDescription, setting different ICE servers // will not cause the pool to be refilled. This is implemented by the // PeerConnection calling FreezeCandidatePool when a local description is set. TEST_F(PortAllocatorTest, SetConfigurationDoesNotRecreatePooledSessionsAfterFreezeCandidatePool) { cricket::ServerAddresses stun_servers_1 = {stun_server_1}; std::vector turn_servers_1 = {turn_server_1}; allocator_->SetConfiguration(stun_servers_1, turn_servers_1, 1, webrtc::NO_PRUNE); EXPECT_EQ(stun_servers_1, allocator_->stun_servers()); EXPECT_EQ(turn_servers_1, allocator_->turn_servers()); // Update with a different set of servers, but first freeze the pool. allocator_->FreezeCandidatePool(); cricket::ServerAddresses stun_servers_2 = {stun_server_2}; std::vector turn_servers_2 = {turn_server_2}; allocator_->SetConfiguration(stun_servers_2, turn_servers_2, 2, webrtc::NO_PRUNE); EXPECT_EQ(stun_servers_2, allocator_->stun_servers()); EXPECT_EQ(turn_servers_2, allocator_->turn_servers()); auto session = TakePooledSession(); ASSERT_NE(nullptr, session.get()); EXPECT_EQ(stun_servers_1, session->stun_servers()); EXPECT_EQ(turn_servers_1, session->turn_servers()); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); } TEST_F(PortAllocatorTest, GetPooledSessionReturnsNextSession) { SetConfigurationWithPoolSize(2); auto peeked_session_1 = GetPooledSession(); auto session_1 = TakePooledSession(); EXPECT_EQ(session_1.get(), peeked_session_1); auto peeked_session_2 = GetPooledSession(); auto session_2 = TakePooledSession(); EXPECT_EQ(session_2.get(), peeked_session_2); } // Verify that subclasses of PortAllocatorSession are given a chance to update // ICE parameters when TakePooledSession is called, and the base class updates // the info itself. TEST_F(PortAllocatorTest, TakePooledSessionUpdatesIceParameters) { SetConfigurationWithPoolSize(1); auto peeked_session = GetPooledSession(); ASSERT_NE(nullptr, peeked_session); EXPECT_EQ(0, peeked_session->transport_info_update_count()); std::unique_ptr session( static_cast( allocator_->TakePooledSession(kContentName, 1, kIceUfrag, kIcePwd) .release())); EXPECT_EQ(1, session->transport_info_update_count()); EXPECT_EQ(kContentName, session->content_name()); EXPECT_EQ(1, session->component()); EXPECT_EQ(kIceUfrag, session->ice_ufrag()); EXPECT_EQ(kIcePwd, session->ice_pwd()); } // According to JSEP, candidate filtering should be done when the pooled // candidates are surfaced to the application. This means when a pooled // session is taken. So a pooled session should gather candidates // unfiltered until it's returned by TakePooledSession. TEST_F(PortAllocatorTest, TakePooledSessionUpdatesCandidateFilter) { allocator_->SetCandidateFilter(cricket::CF_RELAY); SetConfigurationWithPoolSize(1); auto peeked_session = GetPooledSession(); ASSERT_NE(nullptr, peeked_session); EXPECT_EQ(cricket::CF_ALL, peeked_session->candidate_filter()); auto session = TakePooledSession(); EXPECT_EQ(cricket::CF_RELAY, session->candidate_filter()); } // Verify that after DiscardCandidatePool, TakePooledSession doesn't return // anything. TEST_F(PortAllocatorTest, DiscardCandidatePool) { SetConfigurationWithPoolSize(1); allocator_->DiscardCandidatePool(); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); } TEST_F(PortAllocatorTest, RestrictIceCredentialsChange) { SetConfigurationWithPoolSize(1); EXPECT_EQ(1, GetAllPooledSessionsReturnCount()); allocator_->DiscardCandidatePool(); // Only return pooled sessions with the ice credentials that // match those requested in TakePooledSession(). allocator_->set_restrict_ice_credentials_change(true); SetConfigurationWithPoolSize(1); EXPECT_EQ(0, GetAllPooledSessionsReturnCount()); allocator_->DiscardCandidatePool(); SetConfigurationWithPoolSize(1); auto credentials = allocator_->GetPooledIceCredentials(); ASSERT_EQ(1u, credentials.size()); EXPECT_EQ(nullptr, allocator_->TakePooledSession(kContentName, 0, kIceUfrag, kIcePwd)); EXPECT_NE(nullptr, allocator_->TakePooledSession(kContentName, 0, credentials[0].ufrag, credentials[0].pwd)); EXPECT_EQ(nullptr, allocator_->TakePooledSession(kContentName, 0, credentials[0].ufrag, credentials[0].pwd)); allocator_->DiscardCandidatePool(); } // Constants for testing candidates const char kIpv4Address[] = "12.34.56.78"; const char kIpv4AddressWithPort[] = "12.34.56.78:443"; TEST_F(PortAllocatorTest, SanitizeEmptyCandidateDefaultConfig) { cricket::Candidate input; cricket::Candidate output = allocator_->SanitizeCandidate(input); EXPECT_EQ("", output.address().ipaddr().ToString()); } TEST_F(PortAllocatorTest, SanitizeIpv4CandidateDefaultConfig) { cricket::Candidate input(1, "udp", rtc::SocketAddress(kIpv4Address, 443), 1, "username", "password", cricket::LOCAL_PORT_TYPE, 1, "foundation", 1, 1); cricket::Candidate output = allocator_->SanitizeCandidate(input); EXPECT_EQ(kIpv4AddressWithPort, output.address().ToString()); EXPECT_EQ(kIpv4Address, output.address().ipaddr().ToString()); } TEST_F(PortAllocatorTest, SanitizeIpv4CandidateMdnsObfuscationEnabled) { allocator_->SetMdnsObfuscationEnabledForTesting(true); cricket::Candidate input(1, "udp", rtc::SocketAddress(kIpv4Address, 443), 1, "username", "password", cricket::LOCAL_PORT_TYPE, 1, "foundation", 1, 1); cricket::Candidate output = allocator_->SanitizeCandidate(input); EXPECT_NE(kIpv4AddressWithPort, output.address().ToString()); EXPECT_EQ("", output.address().ipaddr().ToString()); } TEST_F(PortAllocatorTest, SanitizePrflxCandidateMdnsObfuscationEnabled) { allocator_->SetMdnsObfuscationEnabledForTesting(true); // Create the candidate from an IP literal. This populates the hostname. cricket::Candidate input(1, "udp", rtc::SocketAddress(kIpv4Address, 443), 1, "username", "password", cricket::PRFLX_PORT_TYPE, 1, "foundation", 1, 1); cricket::Candidate output = allocator_->SanitizeCandidate(input); EXPECT_NE(kIpv4AddressWithPort, output.address().ToString()); EXPECT_EQ("", output.address().ipaddr().ToString()); } TEST_F(PortAllocatorTest, SanitizeIpv4NonLiteralMdnsObfuscationEnabled) { // Create the candidate with an empty hostname. allocator_->SetMdnsObfuscationEnabledForTesting(true); rtc::IPAddress ip; EXPECT_TRUE(IPFromString(kIpv4Address, &ip)); cricket::Candidate input(1, "udp", rtc::SocketAddress(ip, 443), 1, "username", "password", cricket::LOCAL_PORT_TYPE, 1, "foundation", 1, 1); cricket::Candidate output = allocator_->SanitizeCandidate(input); EXPECT_NE(kIpv4AddressWithPort, output.address().ToString()); EXPECT_EQ("", output.address().ipaddr().ToString()); }