dns_client_unittest.cc - platform/system/connectivity/shill - Gitiles

 // Copyright (c) 2011 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "shill/dns_client.h"

 #include <netdb.h>

 #include <string>
 #include <vector>

 #include <base/memory/scoped_ptr.h>
 #include <gtest/gtest.h>
 #include <gmock/gmock.h>

 #include "shill/event_dispatcher.h"
 #include "shill/io_handler.h"
 #include "shill/mock_ares.h"
 #include "shill/mock_control.h"
 #include "shill/mock_event_dispatcher.h"
 #include "shill/mock_time.h"

 using std::string;
 using std::vector;
 using testing::_;
 using testing::DoAll;
 using testing::Return;
 using testing::ReturnArg;
 using testing::ReturnNew;
 using testing::Test;
 using testing::SetArgumentPointee;
 using testing::StrEq;
 using testing::StrictMock;

 namespace shill {

 namespace {
 const char kGoodName[] = "all-systems.mcast.net";
 const char kResult[] = "224.0.0.1";
 const char kGoodServer[] = "8.8.8.8";
 const char kBadServer[] = "10.9xx8.7";
 const char kNetworkInterface[] = "eth0";
 char kReturnAddressList0[] = { 224, 0, 0, 1 };
 char *kReturnAddressList[] = { kReturnAddressList0, NULL };
 char kFakeAresChannelData = 0;
 const ares_channel kAresChannel =
     reinterpret_cast<ares_channel>(&kFakeAresChannelData);
 const int kAresFd = 10203;
 const int kAresTimeoutMS = 2000;  // ARES transaction timeout
 const int kAresWaitMS = 1000;     // Time period ARES asks caller to wait
 }  // namespace {}

 class DNSClientTest : public Test {
  public:
   DNSClientTest() : ares_result_(ARES_SUCCESS) {
     time_val_.tv_sec = 0;
     time_val_.tv_usec = 0;
     ares_timeout_.tv_sec = kAresWaitMS / 1000;
     ares_timeout_.tv_usec = (kAresWaitMS % 1000) * 1000;
     hostent_.h_addrtype = IPAddress::kFamilyIPv4;
     hostent_.h_length = sizeof(kReturnAddressList0);
     hostent_.h_addr_list = kReturnAddressList;
   }

   virtual void SetUp() {
     EXPECT_CALL(time_, GetTimeOfDay(_, _))
         .WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
     SetInActive();
   }

   virtual void TearDown() {
     // We need to make sure the dns_client instance releases ares_
     // before the destructor for DNSClientTest deletes ares_.
     if (dns_client_.get()) {
       dns_client_->Stop();
     }
   }

   void AdvanceTime(int time_ms) {
     struct timeval adv_time = { time_ms/1000, (time_ms % 1000) * 1000 };
     timeradd(&time_val_, &adv_time, &time_val_);
     EXPECT_CALL(time_, GetTimeOfDay(_, _))
         .WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
   }

   void CallReplyCB() {
     dns_client_->ReceiveDNSReplyCB(dns_client_.get(), ares_result_, 0,
                                    &hostent_);
   }

   void CallDNSRead() {
     dns_client_->HandleDNSRead(kAresFd);
   }

   void CallDNSWrite() {
     dns_client_->HandleDNSWrite(kAresFd);
   }

   void CallTimeout() {
     dns_client_->HandleTimeout();
   }

   void CreateClient(const vector<string> &dns_servers, int timeout_ms) {
     dns_client_.reset(new DNSClient(IPAddress::kFamilyIPv4,
                                     kNetworkInterface,
                                     dns_servers,
                                     timeout_ms,
                                     &dispatcher_,
                                     callback_target_.callback()));
     dns_client_->ares_ = &ares_;
     dns_client_->time_ = &time_;
   }

   void SetActive() {
     // Returns that socket kAresFd is readable.
     EXPECT_CALL(ares_, GetSock(_, _, _))
         .WillRepeatedly(DoAll(SetArgumentPointee<1>(kAresFd), Return(1)));
     EXPECT_CALL(ares_, Timeout(_, _, _))
         .WillRepeatedly(
             DoAll(SetArgumentPointee<2>(ares_timeout_), ReturnArg<2>()));
   }

   void SetInActive() {
     EXPECT_CALL(ares_, GetSock(_, _, _))
         .WillRepeatedly(Return(0));
     EXPECT_CALL(ares_, Timeout(_, _, _))
         .WillRepeatedly(ReturnArg<1>());
   }

   void SetupRequest(const string &name, const string &server) {
     vector<string> dns_servers;
     dns_servers.push_back(server);
     CreateClient(dns_servers, kAresTimeoutMS);
     // These expectations are fulfilled when dns_client_->Start() is called.
     EXPECT_CALL(ares_, InitOptions(_, _, _))
         .WillOnce(DoAll(SetArgumentPointee<0>(kAresChannel),
                         Return(ARES_SUCCESS)));
     EXPECT_CALL(ares_, SetLocalDev(kAresChannel, StrEq(kNetworkInterface)))
         .Times(1);
     EXPECT_CALL(ares_, GetHostByName(kAresChannel, StrEq(name), _, _, _));
   }

   void StartValidRequest() {
     SetupRequest(kGoodName, kGoodServer);
     EXPECT_CALL(dispatcher_,
                 CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
         .WillOnce(ReturnNew<IOHandler>());
     SetActive();
     EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
     ASSERT_TRUE(dns_client_->Start(kGoodName));
     EXPECT_CALL(ares_, Destroy(kAresChannel));
   }

   void TestValidCompletion() {
     EXPECT_CALL(callback_target_, CallTarget(true));
     EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD))
         .WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
     CallDNSRead();
     ASSERT_TRUE(dns_client_->address().IsValid());
     IPAddress ipaddr(dns_client_->address().family());
     ASSERT_TRUE(ipaddr.SetAddressFromString(kResult));
     EXPECT_TRUE(ipaddr.Equals(dns_client_->address()));
   }

  protected:
   class DNSCallbackTarget {
    public:
     DNSCallbackTarget()
         : callback_(NewCallback(this, &DNSCallbackTarget::CallTarget)) {}

     MOCK_METHOD1(CallTarget, void(bool success));
     Callback1<bool>::Type *callback() { return callback_.get(); }

    private:
     scoped_ptr<Callback1<bool>::Type> callback_;
   };

   scoped_ptr<DNSClient> dns_client_;
   MockEventDispatcher dispatcher_;
   string queued_request_;
   StrictMock<DNSCallbackTarget> callback_target_;
   StrictMock<MockAres> ares_;
   StrictMock<MockTime> time_;
   struct timeval time_val_;
   struct timeval ares_timeout_;
   struct hostent hostent_;
   int ares_result_;
 };

 class SentinelIOHandler : public IOHandler {
  public:
   MOCK_METHOD0(Die, void());
   virtual ~SentinelIOHandler() { Die(); }
 };

 TEST_F(DNSClientTest, Constructor) {
   vector<string> dns_servers;
   dns_servers.push_back(kGoodServer);
   CreateClient(dns_servers, kAresTimeoutMS);
   EXPECT_TRUE(dns_client_->address().family() == IPAddress::kFamilyIPv4);
   EXPECT_TRUE(dns_client_->address().IsDefault());
 }

 // Receive error because no DNS servers were specified.
 TEST_F(DNSClientTest, NoServers) {
   CreateClient(vector<string>(), kAresTimeoutMS);
   EXPECT_FALSE(dns_client_->Start(kGoodName));
 }

 // Receive error because the DNS server IP address is invalid.
 TEST_F(DNSClientTest, TimeoutInvalidServer) {
   vector<string> dns_servers;
   dns_servers.push_back(kBadServer);
   CreateClient(dns_servers, kAresTimeoutMS);
   ASSERT_FALSE(dns_client_->Start(kGoodName));
 }

 // Setup error because InitOptions failed.
 TEST_F(DNSClientTest, InitOptionsFailure) {
   vector<string> dns_servers;
   dns_servers.push_back(kGoodServer);
   CreateClient(dns_servers, kAresTimeoutMS);
   EXPECT_CALL(ares_, InitOptions(_, _, _))
       .WillOnce(Return(ARES_EBADFLAGS));
   EXPECT_FALSE(dns_client_->Start(kGoodName));
 }

 // Fail a second request because one is already in progress.
 TEST_F(DNSClientTest, MultipleRequest) {
   StartValidRequest();
   ASSERT_FALSE(dns_client_->Start(kGoodName));
 }

 TEST_F(DNSClientTest, GoodRequest) {
   StartValidRequest();
   TestValidCompletion();
 }

 TEST_F(DNSClientTest, GoodRequestWithTimeout) {
   StartValidRequest();
   // Insert an intermediate HandleTimeout callback.
   AdvanceTime(kAresWaitMS);
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, ARES_SOCKET_BAD));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   CallTimeout();
   AdvanceTime(kAresWaitMS);
   TestValidCompletion();
 }

 TEST_F(DNSClientTest, GoodRequestWithDNSRead) {
   StartValidRequest();
   // Insert an intermediate HandleDNSRead callback.
   AdvanceTime(kAresWaitMS);
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   CallDNSRead();
   AdvanceTime(kAresWaitMS);
   TestValidCompletion();
 }

 TEST_F(DNSClientTest, GoodRequestWithDNSWrite) {
   StartValidRequest();
   // Insert an intermediate HandleDNSWrite callback.
   AdvanceTime(kAresWaitMS);
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, kAresFd));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   CallDNSWrite();
   AdvanceTime(kAresWaitMS);
   TestValidCompletion();
 }

 // Failure due to the timeout occurring during first call to RefreshHandles.
 TEST_F(DNSClientTest, TimeoutFirstRefresh) {
   SetupRequest(kGoodName, kGoodServer);
   struct timeval init_time_val = time_val_;
   AdvanceTime(kAresTimeoutMS);
   EXPECT_CALL(time_, GetTimeOfDay(_, _))
       .WillOnce(DoAll(SetArgumentPointee<0>(init_time_val), Return(0)))
       .WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
   EXPECT_CALL(callback_target_, CallTarget(false));
   EXPECT_CALL(ares_, Destroy(kAresChannel));
   ASSERT_FALSE(dns_client_->Start(kGoodName));
   EXPECT_EQ(string(DNSClient::kErrorTimedOut), dns_client_->error());
 }

 // Failed request due to timeout within the dns_client.
 TEST_F(DNSClientTest, TimeoutDispatcherEvent) {
   StartValidRequest();
   EXPECT_CALL(ares_, ProcessFd(kAresChannel,
                                ARES_SOCKET_BAD, ARES_SOCKET_BAD));
   AdvanceTime(kAresTimeoutMS);
   EXPECT_CALL(callback_target_, CallTarget(false));
   CallTimeout();
 }

 // Failed request due to timeout reported by ARES.
 TEST_F(DNSClientTest, TimeoutFromARES) {
   StartValidRequest();
   AdvanceTime(kAresWaitMS);
   ares_result_ = ARES_ETIMEOUT;
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, ARES_SOCKET_BAD))
         .WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
   EXPECT_CALL(callback_target_, CallTarget(false));
   CallTimeout();
   EXPECT_EQ(string(DNSClient::kErrorTimedOut), dns_client_->error());
 }

 // Failed request due to "host not found" reported by ARES.
 TEST_F(DNSClientTest, HostNotFound) {
   StartValidRequest();
   AdvanceTime(kAresWaitMS);
   ares_result_ = ARES_ENOTFOUND;
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD))
       .WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
   EXPECT_CALL(callback_target_, CallTarget(false));
   CallDNSRead();
   EXPECT_EQ(string(DNSClient::kErrorNotFound), dns_client_->error());
 }

 // Make sure IOHandles are deallocated when GetSock() reports them gone.
 TEST_F(DNSClientTest, IOHandleDeallocGetSock) {
   SetupRequest(kGoodName, kGoodServer);
   // This isn't any kind of scoped/ref pointer because we are tracking dealloc.
   SentinelIOHandler *io_handler = new SentinelIOHandler();
   EXPECT_CALL(dispatcher_,
               CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
       .WillOnce(Return(io_handler));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   SetActive();
   ASSERT_TRUE(dns_client_->Start(kGoodName));
   AdvanceTime(kAresWaitMS);
   SetInActive();
   EXPECT_CALL(*io_handler, Die());
   EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   CallDNSRead();
   EXPECT_CALL(ares_, Destroy(kAresChannel));
 }

 // Make sure IOHandles are deallocated when Stop() is called.
 TEST_F(DNSClientTest, IOHandleDeallocStop) {
   SetupRequest(kGoodName, kGoodServer);
   // This isn't any kind of scoped/ref pointer because we are tracking dealloc.
   SentinelIOHandler *io_handler = new SentinelIOHandler();
   EXPECT_CALL(dispatcher_,
               CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
       .WillOnce(Return(io_handler));
   EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
   SetActive();
   ASSERT_TRUE(dns_client_->Start(kGoodName));
   EXPECT_CALL(*io_handler, Die());
   EXPECT_CALL(ares_, Destroy(kAresChannel));
   dns_client_->Stop();
 }

 }  // namespace shill
	// Copyright (c) 2011 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "shill/dns_client.h"

	#include <netdb.h>

	#include <string>
	#include <vector>

	#include <base/memory/scoped_ptr.h>
	#include <gtest/gtest.h>
	#include <gmock/gmock.h>

	#include "shill/event_dispatcher.h"
	#include "shill/io_handler.h"
	#include "shill/mock_ares.h"
	#include "shill/mock_control.h"
	#include "shill/mock_event_dispatcher.h"
	#include "shill/mock_time.h"

	using std::string;
	using std::vector;
	using testing::_;
	using testing::DoAll;
	using testing::Return;
	using testing::ReturnArg;
	using testing::ReturnNew;
	using testing::Test;
	using testing::SetArgumentPointee;
	using testing::StrEq;
	using testing::StrictMock;

	namespace shill {

	namespace {
	const char kGoodName[] = "all-systems.mcast.net";
	const char kResult[] = "224.0.0.1";
	const char kGoodServer[] = "8.8.8.8";
	const char kBadServer[] = "10.9xx8.7";
	const char kNetworkInterface[] = "eth0";
	char kReturnAddressList0[] = { 224, 0, 0, 1 };
	char *kReturnAddressList[] = { kReturnAddressList0, NULL };
	char kFakeAresChannelData = 0;
	const ares_channel kAresChannel =
	reinterpret_cast<ares_channel>(&kFakeAresChannelData);
	const int kAresFd = 10203;
	const int kAresTimeoutMS = 2000; // ARES transaction timeout
	const int kAresWaitMS = 1000; // Time period ARES asks caller to wait
	} // namespace {}

	class DNSClientTest : public Test {
	public:
	DNSClientTest() : ares_result_(ARES_SUCCESS) {
	time_val_.tv_sec = 0;
	time_val_.tv_usec = 0;
	ares_timeout_.tv_sec = kAresWaitMS / 1000;
	ares_timeout_.tv_usec = (kAresWaitMS % 1000) * 1000;
	hostent_.h_addrtype = IPAddress::kFamilyIPv4;
	hostent_.h_length = sizeof(kReturnAddressList0);
	hostent_.h_addr_list = kReturnAddressList;
	}

	virtual void SetUp() {
	EXPECT_CALL(time_, GetTimeOfDay(_, _))
	.WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
	SetInActive();
	}

	virtual void TearDown() {
	// We need to make sure the dns_client instance releases ares_
	// before the destructor for DNSClientTest deletes ares_.
	if (dns_client_.get()) {
	dns_client_->Stop();
	}
	}

	void AdvanceTime(int time_ms) {
	struct timeval adv_time = { time_ms/1000, (time_ms % 1000) * 1000 };
	timeradd(&time_val_, &adv_time, &time_val_);
	EXPECT_CALL(time_, GetTimeOfDay(_, _))
	.WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
	}

	void CallReplyCB() {
	dns_client_->ReceiveDNSReplyCB(dns_client_.get(), ares_result_, 0,
	&hostent_);
	}

	void CallDNSRead() {
	dns_client_->HandleDNSRead(kAresFd);
	}

	void CallDNSWrite() {
	dns_client_->HandleDNSWrite(kAresFd);
	}

	void CallTimeout() {
	dns_client_->HandleTimeout();
	}

	void CreateClient(const vector<string> &dns_servers, int timeout_ms) {
	dns_client_.reset(new DNSClient(IPAddress::kFamilyIPv4,
	kNetworkInterface,
	dns_servers,
	timeout_ms,
	&dispatcher_,
	callback_target_.callback()));
	dns_client_->ares_ = &ares_;
	dns_client_->time_ = &time_;
	}

	void SetActive() {
	// Returns that socket kAresFd is readable.
	EXPECT_CALL(ares_, GetSock(_, _, _))
	.WillRepeatedly(DoAll(SetArgumentPointee<1>(kAresFd), Return(1)));
	EXPECT_CALL(ares_, Timeout(_, _, _))
	.WillRepeatedly(
	DoAll(SetArgumentPointee<2>(ares_timeout_), ReturnArg<2>()));
	}

	void SetInActive() {
	EXPECT_CALL(ares_, GetSock(_, _, _))
	.WillRepeatedly(Return(0));
	EXPECT_CALL(ares_, Timeout(_, _, _))
	.WillRepeatedly(ReturnArg<1>());
	}

	void SetupRequest(const string &name, const string &server) {
	vector<string> dns_servers;
	dns_servers.push_back(server);
	CreateClient(dns_servers, kAresTimeoutMS);
	// These expectations are fulfilled when dns_client_->Start() is called.
	EXPECT_CALL(ares_, InitOptions(_, _, _))
	.WillOnce(DoAll(SetArgumentPointee<0>(kAresChannel),
	Return(ARES_SUCCESS)));
	EXPECT_CALL(ares_, SetLocalDev(kAresChannel, StrEq(kNetworkInterface)))
	.Times(1);
	EXPECT_CALL(ares_, GetHostByName(kAresChannel, StrEq(name), _, _, _));
	}

	void StartValidRequest() {
	SetupRequest(kGoodName, kGoodServer);
	EXPECT_CALL(dispatcher_,
	CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
	.WillOnce(ReturnNew<IOHandler>());
	SetActive();
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	ASSERT_TRUE(dns_client_->Start(kGoodName));
	EXPECT_CALL(ares_, Destroy(kAresChannel));
	}

	void TestValidCompletion() {
	EXPECT_CALL(callback_target_, CallTarget(true));
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD))
	.WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
	CallDNSRead();
	ASSERT_TRUE(dns_client_->address().IsValid());
	IPAddress ipaddr(dns_client_->address().family());
	ASSERT_TRUE(ipaddr.SetAddressFromString(kResult));
	EXPECT_TRUE(ipaddr.Equals(dns_client_->address()));
	}

	protected:
	class DNSCallbackTarget {
	public:
	DNSCallbackTarget()
	: callback_(NewCallback(this, &DNSCallbackTarget::CallTarget)) {}

	MOCK_METHOD1(CallTarget, void(bool success));
	Callback1<bool>::Type *callback() { return callback_.get(); }

	private:
	scoped_ptr<Callback1<bool>::Type> callback_;
	};

	scoped_ptr<DNSClient> dns_client_;
	MockEventDispatcher dispatcher_;
	string queued_request_;
	StrictMock<DNSCallbackTarget> callback_target_;
	StrictMock<MockAres> ares_;
	StrictMock<MockTime> time_;
	struct timeval time_val_;
	struct timeval ares_timeout_;
	struct hostent hostent_;
	int ares_result_;
	};

	class SentinelIOHandler : public IOHandler {
	public:
	MOCK_METHOD0(Die, void());
	virtual ~SentinelIOHandler() { Die(); }
	};

	TEST_F(DNSClientTest, Constructor) {
	vector<string> dns_servers;
	dns_servers.push_back(kGoodServer);
	CreateClient(dns_servers, kAresTimeoutMS);
	EXPECT_TRUE(dns_client_->address().family() == IPAddress::kFamilyIPv4);
	EXPECT_TRUE(dns_client_->address().IsDefault());
	}

	// Receive error because no DNS servers were specified.
	TEST_F(DNSClientTest, NoServers) {
	CreateClient(vector<string>(), kAresTimeoutMS);
	EXPECT_FALSE(dns_client_->Start(kGoodName));
	}

	// Receive error because the DNS server IP address is invalid.
	TEST_F(DNSClientTest, TimeoutInvalidServer) {
	vector<string> dns_servers;
	dns_servers.push_back(kBadServer);
	CreateClient(dns_servers, kAresTimeoutMS);
	ASSERT_FALSE(dns_client_->Start(kGoodName));
	}

	// Setup error because InitOptions failed.
	TEST_F(DNSClientTest, InitOptionsFailure) {
	vector<string> dns_servers;
	dns_servers.push_back(kGoodServer);
	CreateClient(dns_servers, kAresTimeoutMS);
	EXPECT_CALL(ares_, InitOptions(_, _, _))
	.WillOnce(Return(ARES_EBADFLAGS));
	EXPECT_FALSE(dns_client_->Start(kGoodName));
	}

	// Fail a second request because one is already in progress.
	TEST_F(DNSClientTest, MultipleRequest) {
	StartValidRequest();
	ASSERT_FALSE(dns_client_->Start(kGoodName));
	}

	TEST_F(DNSClientTest, GoodRequest) {
	StartValidRequest();
	TestValidCompletion();
	}

	TEST_F(DNSClientTest, GoodRequestWithTimeout) {
	StartValidRequest();
	// Insert an intermediate HandleTimeout callback.
	AdvanceTime(kAresWaitMS);
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, ARES_SOCKET_BAD));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	CallTimeout();
	AdvanceTime(kAresWaitMS);
	TestValidCompletion();
	}

	TEST_F(DNSClientTest, GoodRequestWithDNSRead) {
	StartValidRequest();
	// Insert an intermediate HandleDNSRead callback.
	AdvanceTime(kAresWaitMS);
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	CallDNSRead();
	AdvanceTime(kAresWaitMS);
	TestValidCompletion();
	}

	TEST_F(DNSClientTest, GoodRequestWithDNSWrite) {
	StartValidRequest();
	// Insert an intermediate HandleDNSWrite callback.
	AdvanceTime(kAresWaitMS);
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, kAresFd));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	CallDNSWrite();
	AdvanceTime(kAresWaitMS);
	TestValidCompletion();
	}

	// Failure due to the timeout occurring during first call to RefreshHandles.
	TEST_F(DNSClientTest, TimeoutFirstRefresh) {
	SetupRequest(kGoodName, kGoodServer);
	struct timeval init_time_val = time_val_;
	AdvanceTime(kAresTimeoutMS);
	EXPECT_CALL(time_, GetTimeOfDay(_, _))
	.WillOnce(DoAll(SetArgumentPointee<0>(init_time_val), Return(0)))
	.WillRepeatedly(DoAll(SetArgumentPointee<0>(time_val_), Return(0)));
	EXPECT_CALL(callback_target_, CallTarget(false));
	EXPECT_CALL(ares_, Destroy(kAresChannel));
	ASSERT_FALSE(dns_client_->Start(kGoodName));
	EXPECT_EQ(string(DNSClient::kErrorTimedOut), dns_client_->error());
	}

	// Failed request due to timeout within the dns_client.
	TEST_F(DNSClientTest, TimeoutDispatcherEvent) {
	StartValidRequest();
	EXPECT_CALL(ares_, ProcessFd(kAresChannel,
	ARES_SOCKET_BAD, ARES_SOCKET_BAD));
	AdvanceTime(kAresTimeoutMS);
	EXPECT_CALL(callback_target_, CallTarget(false));
	CallTimeout();
	}

	// Failed request due to timeout reported by ARES.
	TEST_F(DNSClientTest, TimeoutFromARES) {
	StartValidRequest();
	AdvanceTime(kAresWaitMS);
	ares_result_ = ARES_ETIMEOUT;
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, ARES_SOCKET_BAD, ARES_SOCKET_BAD))
	.WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
	EXPECT_CALL(callback_target_, CallTarget(false));
	CallTimeout();
	EXPECT_EQ(string(DNSClient::kErrorTimedOut), dns_client_->error());
	}

	// Failed request due to "host not found" reported by ARES.
	TEST_F(DNSClientTest, HostNotFound) {
	StartValidRequest();
	AdvanceTime(kAresWaitMS);
	ares_result_ = ARES_ENOTFOUND;
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD))
	.WillOnce(InvokeWithoutArgs(this, &DNSClientTest::CallReplyCB));
	EXPECT_CALL(callback_target_, CallTarget(false));
	CallDNSRead();
	EXPECT_EQ(string(DNSClient::kErrorNotFound), dns_client_->error());
	}

	// Make sure IOHandles are deallocated when GetSock() reports them gone.
	TEST_F(DNSClientTest, IOHandleDeallocGetSock) {
	SetupRequest(kGoodName, kGoodServer);
	// This isn't any kind of scoped/ref pointer because we are tracking dealloc.
	SentinelIOHandler *io_handler = new SentinelIOHandler();
	EXPECT_CALL(dispatcher_,
	CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
	.WillOnce(Return(io_handler));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	SetActive();
	ASSERT_TRUE(dns_client_->Start(kGoodName));
	AdvanceTime(kAresWaitMS);
	SetInActive();
	EXPECT_CALL(*io_handler, Die());
	EXPECT_CALL(ares_, ProcessFd(kAresChannel, kAresFd, ARES_SOCKET_BAD));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	CallDNSRead();
	EXPECT_CALL(ares_, Destroy(kAresChannel));
	}

	// Make sure IOHandles are deallocated when Stop() is called.
	TEST_F(DNSClientTest, IOHandleDeallocStop) {
	SetupRequest(kGoodName, kGoodServer);
	// This isn't any kind of scoped/ref pointer because we are tracking dealloc.
	SentinelIOHandler *io_handler = new SentinelIOHandler();
	EXPECT_CALL(dispatcher_,
	CreateReadyHandler(kAresFd, IOHandler::kModeInput, _))
	.WillOnce(Return(io_handler));
	EXPECT_CALL(dispatcher_, PostDelayedTask(_, kAresWaitMS));
	SetActive();
	ASSERT_TRUE(dns_client_->Start(kGoodName));
	EXPECT_CALL(*io_handler, Die());
	EXPECT_CALL(ares_, Destroy(kAresChannel));
	dns_client_->Stop();
	}

	} // namespace shill