webrtc/p2p/base/stunport_unittest.cc - src - Git at Google

 /*
  *  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 <memory>

 #include "webrtc/p2p/base/basicpacketsocketfactory.h"
 #include "webrtc/p2p/base/stunport.h"
 #include "webrtc/p2p/base/teststunserver.h"
 #include "webrtc/base/gunit.h"
 #include "webrtc/base/helpers.h"
 #include "webrtc/base/physicalsocketserver.h"
 #include "webrtc/base/socketaddress.h"
 #include "webrtc/base/ssladapter.h"
 #include "webrtc/base/virtualsocketserver.h"

 using cricket::ServerAddresses;
 using rtc::SocketAddress;

 static const SocketAddress kLocalAddr("127.0.0.1", 0);
 static const SocketAddress kStunAddr1("127.0.0.1", 5000);
 static const SocketAddress kStunAddr2("127.0.0.1", 4000);
 static const SocketAddress kStunAddr3("127.0.0.1", 3000);
 static const SocketAddress kBadAddr("0.0.0.1", 5000);
 static const SocketAddress kStunHostnameAddr("localhost", 5000);
 static const SocketAddress kBadHostnameAddr("not-a-real-hostname", 5000);
 // STUN timeout (with all retries) is 9500ms.
 // Add some margin of error for slow bots.
 // TODO(deadbeef): Use simulated clock instead of just increasing timeouts to
 // fix flaky tests.
 static const int kTimeoutMs = 15000;
 // stun prio = 100 << 24 | 30 (IPV4) << 8 | 256 - 0
 static const uint32_t kStunCandidatePriority = 1677729535;
 static const int kInfiniteLifetime = -1;
 static const int kHighCostPortKeepaliveLifetimeMs = 2 * 60 * 1000;

 // Tests connecting a StunPort to a fake STUN server (cricket::StunServer)
 // TODO: Use a VirtualSocketServer here. We have to use a
 // PhysicalSocketServer right now since DNS is not part of SocketServer yet.
 class StunPortTest : public testing::Test,
                      public sigslot::has_slots<> {
  public:
   StunPortTest()
       : pss_(new rtc::PhysicalSocketServer),
         ss_(new rtc::VirtualSocketServer(pss_.get())),
         ss_scope_(ss_.get()),
         network_("unittest", "unittest", rtc::IPAddress(INADDR_ANY), 32),
         socket_factory_(rtc::Thread::Current()),
         stun_server_1_(cricket::TestStunServer::Create(rtc::Thread::Current(),
                                                        kStunAddr1)),
         stun_server_2_(cricket::TestStunServer::Create(rtc::Thread::Current(),
                                                        kStunAddr2)),
         done_(false),
         error_(false),
         stun_keepalive_delay_(0),
         stun_keepalive_lifetime_(-1) {}

   cricket::UDPPort* port() const { return stun_port_.get(); }
   bool done() const { return done_; }
   bool error() const { return error_; }

   void SetNetworkType(rtc::AdapterType adapter_type) {
     network_.set_type(adapter_type);
   }

   void CreateStunPort(const rtc::SocketAddress& server_addr) {
     ServerAddresses stun_servers;
     stun_servers.insert(server_addr);
     CreateStunPort(stun_servers);
   }

   void CreateStunPort(const ServerAddresses& stun_servers) {
     stun_port_.reset(cricket::StunPort::Create(
         rtc::Thread::Current(), &socket_factory_, &network_,
         kLocalAddr.ipaddr(), 0, 0, rtc::CreateRandomString(16),
         rtc::CreateRandomString(22), stun_servers, std::string()));
     stun_port_->set_stun_keepalive_delay(stun_keepalive_delay_);
     // If |stun_keepalive_lifetime_| is negative, let the stun port
     // choose its lifetime from the network type.
     if (stun_keepalive_lifetime_ >= 0) {
       stun_port_->set_stun_keepalive_lifetime(stun_keepalive_lifetime_);
     }
     stun_port_->SignalPortComplete.connect(this,
         &StunPortTest::OnPortComplete);
     stun_port_->SignalPortError.connect(this,
         &StunPortTest::OnPortError);
   }

   void CreateSharedUdpPort(const rtc::SocketAddress& server_addr) {
     socket_.reset(socket_factory_.CreateUdpSocket(
         rtc::SocketAddress(kLocalAddr.ipaddr(), 0), 0, 0));
     ASSERT_TRUE(socket_ != NULL);
     socket_->SignalReadPacket.connect(this, &StunPortTest::OnReadPacket);
     stun_port_.reset(cricket::UDPPort::Create(
         rtc::Thread::Current(), &socket_factory_,
         &network_, socket_.get(),
         rtc::CreateRandomString(16), rtc::CreateRandomString(22),
         std::string(), false));
     ASSERT_TRUE(stun_port_ != NULL);
     ServerAddresses stun_servers;
     stun_servers.insert(server_addr);
     stun_port_->set_server_addresses(stun_servers);
     stun_port_->SignalPortComplete.connect(this,
         &StunPortTest::OnPortComplete);
     stun_port_->SignalPortError.connect(this,
         &StunPortTest::OnPortError);
   }

   void PrepareAddress() {
     stun_port_->PrepareAddress();
   }

   void OnReadPacket(rtc::AsyncPacketSocket* socket, const char* data,
                     size_t size, const rtc::SocketAddress& remote_addr,
                     const rtc::PacketTime& packet_time) {
     stun_port_->HandleIncomingPacket(
         socket, data, size, remote_addr, rtc::PacketTime());
   }

   void SendData(const char* data, size_t len) {
     stun_port_->HandleIncomingPacket(
         socket_.get(), data, len, rtc::SocketAddress("22.22.22.22", 0),
         rtc::PacketTime());
   }

  protected:
   static void SetUpTestCase() {
     // Ensure the RNG is inited.
     rtc::InitRandom(NULL, 0);

   }

   void OnPortComplete(cricket::Port* port) {
     ASSERT_FALSE(done_);
     done_ = true;
     error_ = false;
   }
   void OnPortError(cricket::Port* port) {
     done_ = true;
     error_ = true;
   }
   void SetKeepaliveDelay(int delay) {
     stun_keepalive_delay_ = delay;
   }

   void SetKeepaliveLifetime(int lifetime) {
     stun_keepalive_lifetime_ = lifetime;
   }

   cricket::TestStunServer* stun_server_1() {
     return stun_server_1_.get();
   }
   cricket::TestStunServer* stun_server_2() {
     return stun_server_2_.get();
   }

  private:
   std::unique_ptr<rtc::PhysicalSocketServer> pss_;
   std::unique_ptr<rtc::VirtualSocketServer> ss_;
   rtc::SocketServerScope ss_scope_;
   rtc::Network network_;
   rtc::BasicPacketSocketFactory socket_factory_;
   std::unique_ptr<cricket::UDPPort> stun_port_;
   std::unique_ptr<cricket::TestStunServer> stun_server_1_;
   std::unique_ptr<cricket::TestStunServer> stun_server_2_;
   std::unique_ptr<rtc::AsyncPacketSocket> socket_;
   bool done_;
   bool error_;
   int stun_keepalive_delay_;
   int stun_keepalive_lifetime_;
 };

 // Test that we can create a STUN port.
 TEST_F(StunPortTest, TestCreateStunPort) {
   CreateStunPort(kStunAddr1);
   EXPECT_EQ("stun", port()->Type());
   EXPECT_EQ(0U, port()->Candidates().size());
 }

 // Test that we can create a UDP port.
 TEST_F(StunPortTest, TestCreateUdpPort) {
   CreateSharedUdpPort(kStunAddr1);
   EXPECT_EQ("local", port()->Type());
   EXPECT_EQ(0U, port()->Candidates().size());
 }

 // Test that we can get an address from a STUN server.
 TEST_F(StunPortTest, TestPrepareAddress) {
   CreateStunPort(kStunAddr1);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   ASSERT_EQ(1U, port()->Candidates().size());
   EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));

   // TODO: Add IPv6 tests here, once either physicalsocketserver supports
   // IPv6, or this test is changed to use VirtualSocketServer.
 }

 // Test that we fail properly if we can't get an address.
 TEST_F(StunPortTest, TestPrepareAddressFail) {
   CreateStunPort(kBadAddr);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_TRUE(error());
   EXPECT_EQ(0U, port()->Candidates().size());
 }

 // Test that we can get an address from a STUN server specified by a hostname.
 TEST_F(StunPortTest, TestPrepareAddressHostname) {
   CreateStunPort(kStunHostnameAddr);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   ASSERT_EQ(1U, port()->Candidates().size());
   EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
   EXPECT_EQ(kStunCandidatePriority, port()->Candidates()[0].priority());
 }

 // Test that we handle hostname lookup failures properly.
 TEST_F(StunPortTest, TestPrepareAddressHostnameFail) {
   CreateStunPort(kBadHostnameAddr);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_TRUE(error());
   EXPECT_EQ(0U, port()->Candidates().size());
 }

 // This test verifies keepalive response messages don't result in
 // additional candidate generation.
 TEST_F(StunPortTest, TestKeepAliveResponse) {
   SetKeepaliveDelay(500);  // 500ms of keepalive delay.
   CreateStunPort(kStunHostnameAddr);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   ASSERT_EQ(1U, port()->Candidates().size());
   EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
   // Waiting for 1 seond, which will allow us to process
   // response for keepalive binding request. 500 ms is the keepalive delay.
   rtc::Thread::Current()->ProcessMessages(1000);
   ASSERT_EQ(1U, port()->Candidates().size());
 }

 // Test that a local candidate can be generated using a shared socket.
 TEST_F(StunPortTest, TestSharedSocketPrepareAddress) {
   CreateSharedUdpPort(kStunAddr1);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   ASSERT_EQ(1U, port()->Candidates().size());
   EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
 }

 // Test that we still a get a local candidate with invalid stun server hostname.
 // Also verifing that UDPPort can receive packets when stun address can't be
 // resolved.
 TEST_F(StunPortTest, TestSharedSocketPrepareAddressInvalidHostname) {
   CreateSharedUdpPort(kBadHostnameAddr);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   ASSERT_EQ(1U, port()->Candidates().size());
   EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));

   // Send data to port after it's ready. This is to make sure, UDP port can
   // handle data with unresolved stun server address.
   std::string data = "some random data, sending to cricket::Port.";
   SendData(data.c_str(), data.length());
   // No crash is success.
 }

 // Test that the same address is added only once if two STUN servers are in use.
 TEST_F(StunPortTest, TestNoDuplicatedAddressWithTwoStunServers) {
   ServerAddresses stun_servers;
   stun_servers.insert(kStunAddr1);
   stun_servers.insert(kStunAddr2);
   CreateStunPort(stun_servers);
   EXPECT_EQ("stun", port()->Type());
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_EQ(1U, port()->Candidates().size());
   EXPECT_EQ(port()->Candidates()[0].relay_protocol(), "");
 }

 // Test that candidates can be allocated for multiple STUN servers, one of which
 // is not reachable.
 TEST_F(StunPortTest, TestMultipleStunServersWithBadServer) {
   ServerAddresses stun_servers;
   stun_servers.insert(kStunAddr1);
   stun_servers.insert(kBadAddr);
   CreateStunPort(stun_servers);
   EXPECT_EQ("stun", port()->Type());
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_EQ(1U, port()->Candidates().size());
 }

 // Test that two candidates are allocated if the two STUN servers return
 // different mapped addresses.
 TEST_F(StunPortTest, TestTwoCandidatesWithTwoStunServersAcrossNat) {
   const SocketAddress kStunMappedAddr1("77.77.77.77", 0);
   const SocketAddress kStunMappedAddr2("88.77.77.77", 0);
   stun_server_1()->set_fake_stun_addr(kStunMappedAddr1);
   stun_server_2()->set_fake_stun_addr(kStunMappedAddr2);

   ServerAddresses stun_servers;
   stun_servers.insert(kStunAddr1);
   stun_servers.insert(kStunAddr2);
   CreateStunPort(stun_servers);
   EXPECT_EQ("stun", port()->Type());
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_EQ(2U, port()->Candidates().size());
   EXPECT_EQ(port()->Candidates()[0].relay_protocol(), "");
   EXPECT_EQ(port()->Candidates()[1].relay_protocol(), "");
 }

 // Test that the stun_keepalive_lifetime is set correctly based on the network
 // type on a STUN port. Also test that it will be updated if the network type
 // changes.
 TEST_F(StunPortTest, TestStunPortGetStunKeepaliveLifetime) {
   // Lifetime for the default (unknown) network type is |kInfiniteLifetime|.
   CreateStunPort(kStunAddr1);
   EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
   // Lifetime for the cellular network is |kHighCostPortKeepaliveLifetimeMs|
   SetNetworkType(rtc::ADAPTER_TYPE_CELLULAR);
   EXPECT_EQ(kHighCostPortKeepaliveLifetimeMs,
             port()->stun_keepalive_lifetime());

   // Lifetime for the wifi network is |kInfiniteLifetime|.
   SetNetworkType(rtc::ADAPTER_TYPE_WIFI);
   CreateStunPort(kStunAddr2);
   EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
 }

 // Test that the stun_keepalive_lifetime is set correctly based on the network
 // type on a shared STUN port (UDPPort). Also test that it will be updated
 // if the network type changes.
 TEST_F(StunPortTest, TestUdpPortGetStunKeepaliveLifetime) {
   // Lifetime for the default (unknown) network type is |kInfiniteLifetime|.
   CreateSharedUdpPort(kStunAddr1);
   EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
   // Lifetime for the cellular network is |kHighCostPortKeepaliveLifetimeMs|.
   SetNetworkType(rtc::ADAPTER_TYPE_CELLULAR);
   EXPECT_EQ(kHighCostPortKeepaliveLifetimeMs,
             port()->stun_keepalive_lifetime());

   // Lifetime for the wifi network type is |kInfiniteLifetime|.
   SetNetworkType(rtc::ADAPTER_TYPE_WIFI);
   CreateSharedUdpPort(kStunAddr2);
   EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
 }

 // Test that STUN binding requests will be stopped shortly if the keep-alive
 // lifetime is short.
 TEST_F(StunPortTest, TestStunBindingRequestShortLifetime) {
   SetKeepaliveDelay(101);
   SetKeepaliveLifetime(100);
   CreateStunPort(kStunAddr1);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   EXPECT_TRUE_WAIT(!port()->HasPendingRequest(cricket::STUN_BINDING_REQUEST),
                    2000);
 }

 // Test that by default, the STUN binding requests will last for a long time.
 TEST_F(StunPortTest, TestStunBindingRequestLongLifetime) {
   SetKeepaliveDelay(101);
   CreateStunPort(kStunAddr1);
   PrepareAddress();
   EXPECT_TRUE_WAIT(done(), kTimeoutMs);
   rtc::Thread::Current()->ProcessMessages(1000);
   EXPECT_TRUE(port()->HasPendingRequest(cricket::STUN_BINDING_REQUEST));
 }
	/*
	* 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 <memory>

	#include "webrtc/p2p/base/basicpacketsocketfactory.h"
	#include "webrtc/p2p/base/stunport.h"
	#include "webrtc/p2p/base/teststunserver.h"
	#include "webrtc/base/gunit.h"
	#include "webrtc/base/helpers.h"
	#include "webrtc/base/physicalsocketserver.h"
	#include "webrtc/base/socketaddress.h"
	#include "webrtc/base/ssladapter.h"
	#include "webrtc/base/virtualsocketserver.h"

	using cricket::ServerAddresses;
	using rtc::SocketAddress;

	static const SocketAddress kLocalAddr("127.0.0.1", 0);
	static const SocketAddress kStunAddr1("127.0.0.1", 5000);
	static const SocketAddress kStunAddr2("127.0.0.1", 4000);
	static const SocketAddress kStunAddr3("127.0.0.1", 3000);
	static const SocketAddress kBadAddr("0.0.0.1", 5000);
	static const SocketAddress kStunHostnameAddr("localhost", 5000);
	static const SocketAddress kBadHostnameAddr("not-a-real-hostname", 5000);
	// STUN timeout (with all retries) is 9500ms.
	// Add some margin of error for slow bots.
	// TODO(deadbeef): Use simulated clock instead of just increasing timeouts to
	// fix flaky tests.
	static const int kTimeoutMs = 15000;
	// stun prio = 100 << 24 \| 30 (IPV4) << 8 \| 256 - 0
	static const uint32_t kStunCandidatePriority = 1677729535;
	static const int kInfiniteLifetime = -1;
	static const int kHighCostPortKeepaliveLifetimeMs = 2 * 60 * 1000;

	// Tests connecting a StunPort to a fake STUN server (cricket::StunServer)
	// TODO: Use a VirtualSocketServer here. We have to use a
	// PhysicalSocketServer right now since DNS is not part of SocketServer yet.
	class StunPortTest : public testing::Test,
	public sigslot::has_slots<> {
	public:
	StunPortTest()
	: pss_(new rtc::PhysicalSocketServer),
	ss_(new rtc::VirtualSocketServer(pss_.get())),
	ss_scope_(ss_.get()),
	network_("unittest", "unittest", rtc::IPAddress(INADDR_ANY), 32),
	socket_factory_(rtc::Thread::Current()),
	stun_server_1_(cricket::TestStunServer::Create(rtc::Thread::Current(),
	kStunAddr1)),
	stun_server_2_(cricket::TestStunServer::Create(rtc::Thread::Current(),
	kStunAddr2)),
	done_(false),
	error_(false),
	stun_keepalive_delay_(0),
	stun_keepalive_lifetime_(-1) {}

	cricket::UDPPort* port() const { return stun_port_.get(); }
	bool done() const { return done_; }
	bool error() const { return error_; }

	void SetNetworkType(rtc::AdapterType adapter_type) {
	network_.set_type(adapter_type);
	}

	void CreateStunPort(const rtc::SocketAddress& server_addr) {
	ServerAddresses stun_servers;
	stun_servers.insert(server_addr);
	CreateStunPort(stun_servers);
	}

	void CreateStunPort(const ServerAddresses& stun_servers) {
	stun_port_.reset(cricket::StunPort::Create(
	rtc::Thread::Current(), &socket_factory_, &network_,
	kLocalAddr.ipaddr(), 0, 0, rtc::CreateRandomString(16),
	rtc::CreateRandomString(22), stun_servers, std::string()));
	stun_port_->set_stun_keepalive_delay(stun_keepalive_delay_);
	// If \|stun_keepalive_lifetime_\| is negative, let the stun port
	// choose its lifetime from the network type.
	if (stun_keepalive_lifetime_ >= 0) {
	stun_port_->set_stun_keepalive_lifetime(stun_keepalive_lifetime_);
	}
	stun_port_->SignalPortComplete.connect(this,
	&StunPortTest::OnPortComplete);
	stun_port_->SignalPortError.connect(this,
	&StunPortTest::OnPortError);
	}

	void CreateSharedUdpPort(const rtc::SocketAddress& server_addr) {
	socket_.reset(socket_factory_.CreateUdpSocket(
	rtc::SocketAddress(kLocalAddr.ipaddr(), 0), 0, 0));
	ASSERT_TRUE(socket_ != NULL);
	socket_->SignalReadPacket.connect(this, &StunPortTest::OnReadPacket);
	stun_port_.reset(cricket::UDPPort::Create(
	rtc::Thread::Current(), &socket_factory_,
	&network_, socket_.get(),
	rtc::CreateRandomString(16), rtc::CreateRandomString(22),
	std::string(), false));
	ASSERT_TRUE(stun_port_ != NULL);
	ServerAddresses stun_servers;
	stun_servers.insert(server_addr);
	stun_port_->set_server_addresses(stun_servers);
	stun_port_->SignalPortComplete.connect(this,
	&StunPortTest::OnPortComplete);
	stun_port_->SignalPortError.connect(this,
	&StunPortTest::OnPortError);
	}

	void PrepareAddress() {
	stun_port_->PrepareAddress();
	}

	void OnReadPacket(rtc::AsyncPacketSocket* socket, const char* data,
	size_t size, const rtc::SocketAddress& remote_addr,
	const rtc::PacketTime& packet_time) {
	stun_port_->HandleIncomingPacket(
	socket, data, size, remote_addr, rtc::PacketTime());
	}

	void SendData(const char* data, size_t len) {
	stun_port_->HandleIncomingPacket(
	socket_.get(), data, len, rtc::SocketAddress("22.22.22.22", 0),
	rtc::PacketTime());
	}

	protected:
	static void SetUpTestCase() {
	// Ensure the RNG is inited.
	rtc::InitRandom(NULL, 0);

	}

	void OnPortComplete(cricket::Port* port) {
	ASSERT_FALSE(done_);
	done_ = true;
	error_ = false;
	}
	void OnPortError(cricket::Port* port) {
	done_ = true;
	error_ = true;
	}
	void SetKeepaliveDelay(int delay) {
	stun_keepalive_delay_ = delay;
	}

	void SetKeepaliveLifetime(int lifetime) {
	stun_keepalive_lifetime_ = lifetime;
	}

	cricket::TestStunServer* stun_server_1() {
	return stun_server_1_.get();
	}
	cricket::TestStunServer* stun_server_2() {
	return stun_server_2_.get();
	}

	private:
	std::unique_ptr<rtc::PhysicalSocketServer> pss_;
	std::unique_ptr<rtc::VirtualSocketServer> ss_;
	rtc::SocketServerScope ss_scope_;
	rtc::Network network_;
	rtc::BasicPacketSocketFactory socket_factory_;
	std::unique_ptr<cricket::UDPPort> stun_port_;
	std::unique_ptr<cricket::TestStunServer> stun_server_1_;
	std::unique_ptr<cricket::TestStunServer> stun_server_2_;
	std::unique_ptr<rtc::AsyncPacketSocket> socket_;
	bool done_;
	bool error_;
	int stun_keepalive_delay_;
	int stun_keepalive_lifetime_;
	};

	// Test that we can create a STUN port.
	TEST_F(StunPortTest, TestCreateStunPort) {
	CreateStunPort(kStunAddr1);
	EXPECT_EQ("stun", port()->Type());
	EXPECT_EQ(0U, port()->Candidates().size());
	}

	// Test that we can create a UDP port.
	TEST_F(StunPortTest, TestCreateUdpPort) {
	CreateSharedUdpPort(kStunAddr1);
	EXPECT_EQ("local", port()->Type());
	EXPECT_EQ(0U, port()->Candidates().size());
	}

	// Test that we can get an address from a STUN server.
	TEST_F(StunPortTest, TestPrepareAddress) {
	CreateStunPort(kStunAddr1);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	ASSERT_EQ(1U, port()->Candidates().size());
	EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));

	// TODO: Add IPv6 tests here, once either physicalsocketserver supports
	// IPv6, or this test is changed to use VirtualSocketServer.
	}

	// Test that we fail properly if we can't get an address.
	TEST_F(StunPortTest, TestPrepareAddressFail) {
	CreateStunPort(kBadAddr);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_TRUE(error());
	EXPECT_EQ(0U, port()->Candidates().size());
	}

	// Test that we can get an address from a STUN server specified by a hostname.
	TEST_F(StunPortTest, TestPrepareAddressHostname) {
	CreateStunPort(kStunHostnameAddr);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	ASSERT_EQ(1U, port()->Candidates().size());
	EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
	EXPECT_EQ(kStunCandidatePriority, port()->Candidates()[0].priority());
	}

	// Test that we handle hostname lookup failures properly.
	TEST_F(StunPortTest, TestPrepareAddressHostnameFail) {
	CreateStunPort(kBadHostnameAddr);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_TRUE(error());
	EXPECT_EQ(0U, port()->Candidates().size());
	}

	// This test verifies keepalive response messages don't result in
	// additional candidate generation.
	TEST_F(StunPortTest, TestKeepAliveResponse) {
	SetKeepaliveDelay(500); // 500ms of keepalive delay.
	CreateStunPort(kStunHostnameAddr);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	ASSERT_EQ(1U, port()->Candidates().size());
	EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
	// Waiting for 1 seond, which will allow us to process
	// response for keepalive binding request. 500 ms is the keepalive delay.
	rtc::Thread::Current()->ProcessMessages(1000);
	ASSERT_EQ(1U, port()->Candidates().size());
	}

	// Test that a local candidate can be generated using a shared socket.
	TEST_F(StunPortTest, TestSharedSocketPrepareAddress) {
	CreateSharedUdpPort(kStunAddr1);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	ASSERT_EQ(1U, port()->Candidates().size());
	EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));
	}

	// Test that we still a get a local candidate with invalid stun server hostname.
	// Also verifing that UDPPort can receive packets when stun address can't be
	// resolved.
	TEST_F(StunPortTest, TestSharedSocketPrepareAddressInvalidHostname) {
	CreateSharedUdpPort(kBadHostnameAddr);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	ASSERT_EQ(1U, port()->Candidates().size());
	EXPECT_TRUE(kLocalAddr.EqualIPs(port()->Candidates()[0].address()));

	// Send data to port after it's ready. This is to make sure, UDP port can
	// handle data with unresolved stun server address.
	std::string data = "some random data, sending to cricket::Port.";
	SendData(data.c_str(), data.length());
	// No crash is success.
	}

	// Test that the same address is added only once if two STUN servers are in use.
	TEST_F(StunPortTest, TestNoDuplicatedAddressWithTwoStunServers) {
	ServerAddresses stun_servers;
	stun_servers.insert(kStunAddr1);
	stun_servers.insert(kStunAddr2);
	CreateStunPort(stun_servers);
	EXPECT_EQ("stun", port()->Type());
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_EQ(1U, port()->Candidates().size());
	EXPECT_EQ(port()->Candidates()[0].relay_protocol(), "");
	}

	// Test that candidates can be allocated for multiple STUN servers, one of which
	// is not reachable.
	TEST_F(StunPortTest, TestMultipleStunServersWithBadServer) {
	ServerAddresses stun_servers;
	stun_servers.insert(kStunAddr1);
	stun_servers.insert(kBadAddr);
	CreateStunPort(stun_servers);
	EXPECT_EQ("stun", port()->Type());
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_EQ(1U, port()->Candidates().size());
	}

	// Test that two candidates are allocated if the two STUN servers return
	// different mapped addresses.
	TEST_F(StunPortTest, TestTwoCandidatesWithTwoStunServersAcrossNat) {
	const SocketAddress kStunMappedAddr1("77.77.77.77", 0);
	const SocketAddress kStunMappedAddr2("88.77.77.77", 0);
	stun_server_1()->set_fake_stun_addr(kStunMappedAddr1);
	stun_server_2()->set_fake_stun_addr(kStunMappedAddr2);

	ServerAddresses stun_servers;
	stun_servers.insert(kStunAddr1);
	stun_servers.insert(kStunAddr2);
	CreateStunPort(stun_servers);
	EXPECT_EQ("stun", port()->Type());
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_EQ(2U, port()->Candidates().size());
	EXPECT_EQ(port()->Candidates()[0].relay_protocol(), "");
	EXPECT_EQ(port()->Candidates()[1].relay_protocol(), "");
	}

	// Test that the stun_keepalive_lifetime is set correctly based on the network
	// type on a STUN port. Also test that it will be updated if the network type
	// changes.
	TEST_F(StunPortTest, TestStunPortGetStunKeepaliveLifetime) {
	// Lifetime for the default (unknown) network type is \|kInfiniteLifetime\|.
	CreateStunPort(kStunAddr1);
	EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
	// Lifetime for the cellular network is \|kHighCostPortKeepaliveLifetimeMs\|
	SetNetworkType(rtc::ADAPTER_TYPE_CELLULAR);
	EXPECT_EQ(kHighCostPortKeepaliveLifetimeMs,
	port()->stun_keepalive_lifetime());

	// Lifetime for the wifi network is \|kInfiniteLifetime\|.
	SetNetworkType(rtc::ADAPTER_TYPE_WIFI);
	CreateStunPort(kStunAddr2);
	EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
	}

	// Test that the stun_keepalive_lifetime is set correctly based on the network
	// type on a shared STUN port (UDPPort). Also test that it will be updated
	// if the network type changes.
	TEST_F(StunPortTest, TestUdpPortGetStunKeepaliveLifetime) {
	// Lifetime for the default (unknown) network type is \|kInfiniteLifetime\|.
	CreateSharedUdpPort(kStunAddr1);
	EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
	// Lifetime for the cellular network is \|kHighCostPortKeepaliveLifetimeMs\|.
	SetNetworkType(rtc::ADAPTER_TYPE_CELLULAR);
	EXPECT_EQ(kHighCostPortKeepaliveLifetimeMs,
	port()->stun_keepalive_lifetime());

	// Lifetime for the wifi network type is \|kInfiniteLifetime\|.
	SetNetworkType(rtc::ADAPTER_TYPE_WIFI);
	CreateSharedUdpPort(kStunAddr2);
	EXPECT_EQ(kInfiniteLifetime, port()->stun_keepalive_lifetime());
	}

	// Test that STUN binding requests will be stopped shortly if the keep-alive
	// lifetime is short.
	TEST_F(StunPortTest, TestStunBindingRequestShortLifetime) {
	SetKeepaliveDelay(101);
	SetKeepaliveLifetime(100);
	CreateStunPort(kStunAddr1);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	EXPECT_TRUE_WAIT(!port()->HasPendingRequest(cricket::STUN_BINDING_REQUEST),
	2000);
	}

	// Test that by default, the STUN binding requests will last for a long time.
	TEST_F(StunPortTest, TestStunBindingRequestLongLifetime) {
	SetKeepaliveDelay(101);
	CreateStunPort(kStunAddr1);
	PrepareAddress();
	EXPECT_TRUE_WAIT(done(), kTimeoutMs);
	rtc::Thread::Current()->ProcessMessages(1000);
	EXPECT_TRUE(port()->HasPendingRequest(cricket::STUN_BINDING_REQUEST));
	}