ipc/ipc_perftests.cc - platform/external/chromium_org - Git at Google

 // Copyright (c) 2012 The Chromium 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 "build/build_config.h"

 #include <algorithm>
 #include <string>

 #include "base/basictypes.h"
 #include "base/logging.h"
 #include "base/memory/scoped_ptr.h"
 #include "base/pickle.h"
 #include "base/strings/stringprintf.h"
 #include "base/test/perf_time_logger.h"
 #include "base/threading/thread.h"
 #include "base/time/time.h"
 #include "ipc/ipc_channel.h"
 #include "ipc/ipc_channel_proxy.h"
 #include "ipc/ipc_descriptors.h"
 #include "ipc/ipc_message_utils.h"
 #include "ipc/ipc_sender.h"
 #include "ipc/ipc_test_base.h"

 namespace {

 // This test times the roundtrip IPC message cycle.
 //
 // TODO(brettw): Make this test run by default.

 class IPCChannelPerfTest : public IPCTestBase {
 };

 // This class simply collects stats about abstract "events" (each of which has a
 // start time and an end time).
 class EventTimeTracker {
  public:
   explicit EventTimeTracker(const char* name)
       : name_(name),
         count_(0) {
   }

   void AddEvent(const base::TimeTicks& start, const base::TimeTicks& end) {
     DCHECK(end >= start);
     count_++;
     base::TimeDelta duration = end - start;
     total_duration_ += duration;
     max_duration_ = std::max(max_duration_, duration);
   }

   void ShowResults() const {
     VLOG(1) << name_ << " count: " << count_;
     VLOG(1) << name_ << " total duration: "
             << total_duration_.InMillisecondsF() << " ms";
     VLOG(1) << name_ << " average duration: "
             << (total_duration_.InMillisecondsF() / static_cast<double>(count_))
             << " ms";
     VLOG(1) << name_ << " maximum duration: "
             << max_duration_.InMillisecondsF() << " ms";
   }

   void Reset() {
     count_ = 0;
     total_duration_ = base::TimeDelta();
     max_duration_ = base::TimeDelta();
   }

  private:
   const std::string name_;

   uint64 count_;
   base::TimeDelta total_duration_;
   base::TimeDelta max_duration_;

   DISALLOW_COPY_AND_ASSIGN(EventTimeTracker);
 };

 // This channel listener just replies to all messages with the exact same
 // message. It assumes each message has one string parameter. When the string
 // "quit" is sent, it will exit.
 class ChannelReflectorListener : public IPC::Listener {
  public:
   ChannelReflectorListener()
       : channel_(NULL),
         latency_tracker_("Client messages") {
     VLOG(1) << "Client listener up";
   }

   virtual ~ChannelReflectorListener() {
     VLOG(1) << "Client listener down";
     latency_tracker_.ShowResults();
   }

   void Init(IPC::Channel* channel) {
     DCHECK(!channel_);
     channel_ = channel;
   }

   virtual bool OnMessageReceived(const IPC::Message& message) OVERRIDE {
     CHECK(channel_);

     PickleIterator iter(message);
     int64 time_internal;
     EXPECT_TRUE(iter.ReadInt64(&time_internal));
     int msgid;
     EXPECT_TRUE(iter.ReadInt(&msgid));
     std::string payload;
     EXPECT_TRUE(iter.ReadString(&payload));

     // Include message deserialization in latency.
     base::TimeTicks now = base::TimeTicks::Now();

     if (payload == "hello") {
       latency_tracker_.Reset();
     } else if (payload == "quit") {
       latency_tracker_.ShowResults();
       base::MessageLoop::current()->QuitWhenIdle();
       return true;
     } else {
       // Don't track hello and quit messages.
       latency_tracker_.AddEvent(
           base::TimeTicks::FromInternalValue(time_internal), now);
     }

     IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
     msg->WriteInt64(base::TimeTicks::Now().ToInternalValue());
     msg->WriteInt(msgid);
     msg->WriteString(payload);
     channel_->Send(msg);
     return true;
   }

  private:
   IPC::Channel* channel_;
   EventTimeTracker latency_tracker_;
 };

 class PerformanceChannelListener : public IPC::Listener {
  public:
   PerformanceChannelListener()
       : channel_(NULL),
         msg_count_(0),
         msg_size_(0),
         count_down_(0),
         latency_tracker_("Server messages") {
     VLOG(1) << "Server listener up";
   }

   virtual ~PerformanceChannelListener() {
     VLOG(1) << "Server listener down";
   }

   void Init(IPC::Channel* channel) {
     DCHECK(!channel_);
     channel_ = channel;
   }

   // Call this before running the message loop.
   void SetTestParams(int msg_count, size_t msg_size) {
     DCHECK_EQ(0, count_down_);
     msg_count_ = msg_count;
     msg_size_ = msg_size;
     count_down_ = msg_count_;
     payload_ = std::string(msg_size_, 'a');
   }

   virtual bool OnMessageReceived(const IPC::Message& message) OVERRIDE {
     CHECK(channel_);

     PickleIterator iter(message);
     int64 time_internal;
     EXPECT_TRUE(iter.ReadInt64(&time_internal));
     int msgid;
     EXPECT_TRUE(iter.ReadInt(&msgid));
     std::string reflected_payload;
     EXPECT_TRUE(iter.ReadString(&reflected_payload));

     // Include message deserialization in latency.
     base::TimeTicks now = base::TimeTicks::Now();

     if (reflected_payload == "hello") {
       // Start timing on hello.
       latency_tracker_.Reset();
       DCHECK(!perf_logger_.get());
       std::string test_name = base::StringPrintf(
           "IPC_Perf_%dx_%u", msg_count_, static_cast<unsigned>(msg_size_));
       perf_logger_.reset(new base::PerfTimeLogger(test_name.c_str()));
     } else {
       DCHECK_EQ(payload_.size(), reflected_payload.size());

       latency_tracker_.AddEvent(
           base::TimeTicks::FromInternalValue(time_internal), now);

       CHECK(count_down_ > 0);
       count_down_--;
       if (count_down_ == 0) {
         perf_logger_.reset();  // Stop the perf timer now.
         latency_tracker_.ShowResults();
         base::MessageLoop::current()->QuitWhenIdle();
         return true;
       }
     }

     IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
     msg->WriteInt64(base::TimeTicks::Now().ToInternalValue());
     msg->WriteInt(count_down_);
     msg->WriteString(payload_);
     channel_->Send(msg);
     return true;
   }

  private:
   IPC::Channel* channel_;
   int msg_count_;
   size_t msg_size_;

   int count_down_;
   std::string payload_;
   EventTimeTracker latency_tracker_;
   scoped_ptr<base::PerfTimeLogger> perf_logger_;
 };

 TEST_F(IPCChannelPerfTest, Performance) {
   Init("PerformanceClient");

   // Set up IPC channel and start client.
   PerformanceChannelListener listener;
   CreateChannel(&listener);
   listener.Init(channel());
   ASSERT_TRUE(ConnectChannel());
   ASSERT_TRUE(StartClient());

   // Test several sizes. We use 12^N for message size, and limit the message
   // count to keep the test duration reasonable.
   const size_t kMsgSize[5] = {12, 144, 1728, 20736, 248832};
   const int kMessageCount[5] = {50000, 50000, 50000, 12000, 1000};

   for (size_t i = 0; i < 5; i++) {
     listener.SetTestParams(kMessageCount[i], kMsgSize[i]);

     // This initial message will kick-start the ping-pong of messages.
     IPC::Message* message =
         new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
     message->WriteInt64(base::TimeTicks::Now().ToInternalValue());
     message->WriteInt(-1);
     message->WriteString("hello");
     sender()->Send(message);

     // Run message loop.
     base::MessageLoop::current()->Run();
   }

   // Send quit message.
   IPC::Message* message = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
   message->WriteInt64(base::TimeTicks::Now().ToInternalValue());
   message->WriteInt(-1);
   message->WriteString("quit");
   sender()->Send(message);

   EXPECT_TRUE(WaitForClientShutdown());
   DestroyChannel();
 }

 // This message loop bounces all messages back to the sender.
 MULTIPROCESS_IPC_TEST_CLIENT_MAIN(PerformanceClient) {
   base::MessageLoopForIO main_message_loop;
   ChannelReflectorListener listener;
   scoped_ptr<IPC::Channel> channel(IPC::Channel::CreateClient(
       IPCTestBase::GetChannelName("PerformanceClient"), &listener));
   listener.Init(channel.get());
   CHECK(channel->Connect());

   base::MessageLoop::current()->Run();
   return 0;
 }

 }  // namespace
	// Copyright (c) 2012 The Chromium 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 "build/build_config.h"

	#include <algorithm>
	#include <string>

	#include "base/basictypes.h"
	#include "base/logging.h"
	#include "base/memory/scoped_ptr.h"
	#include "base/pickle.h"
	#include "base/strings/stringprintf.h"
	#include "base/test/perf_time_logger.h"
	#include "base/threading/thread.h"
	#include "base/time/time.h"
	#include "ipc/ipc_channel.h"
	#include "ipc/ipc_channel_proxy.h"
	#include "ipc/ipc_descriptors.h"
	#include "ipc/ipc_message_utils.h"
	#include "ipc/ipc_sender.h"
	#include "ipc/ipc_test_base.h"

	namespace {

	// This test times the roundtrip IPC message cycle.
	//
	// TODO(brettw): Make this test run by default.

	class IPCChannelPerfTest : public IPCTestBase {
	};

	// This class simply collects stats about abstract "events" (each of which has a
	// start time and an end time).
	class EventTimeTracker {
	public:
	explicit EventTimeTracker(const char* name)
	: name_(name),
	count_(0) {
	}

	void AddEvent(const base::TimeTicks& start, const base::TimeTicks& end) {
	DCHECK(end >= start);
	count_++;
	base::TimeDelta duration = end - start;
	total_duration_ += duration;
	max_duration_ = std::max(max_duration_, duration);
	}

	void ShowResults() const {
	VLOG(1) << name_ << " count: " << count_;
	VLOG(1) << name_ << " total duration: "
	<< total_duration_.InMillisecondsF() << " ms";
	VLOG(1) << name_ << " average duration: "
	<< (total_duration_.InMillisecondsF() / static_cast<double>(count_))
	<< " ms";
	VLOG(1) << name_ << " maximum duration: "
	<< max_duration_.InMillisecondsF() << " ms";
	}

	void Reset() {
	count_ = 0;
	total_duration_ = base::TimeDelta();
	max_duration_ = base::TimeDelta();
	}

	private:
	const std::string name_;

	uint64 count_;
	base::TimeDelta total_duration_;
	base::TimeDelta max_duration_;

	DISALLOW_COPY_AND_ASSIGN(EventTimeTracker);
	};

	// This channel listener just replies to all messages with the exact same
	// message. It assumes each message has one string parameter. When the string
	// "quit" is sent, it will exit.
	class ChannelReflectorListener : public IPC::Listener {
	public:
	ChannelReflectorListener()
	: channel_(NULL),
	latency_tracker_("Client messages") {
	VLOG(1) << "Client listener up";
	}

	virtual ~ChannelReflectorListener() {
	VLOG(1) << "Client listener down";
	latency_tracker_.ShowResults();
	}

	void Init(IPC::Channel* channel) {
	DCHECK(!channel_);
	channel_ = channel;
	}

	virtual bool OnMessageReceived(const IPC::Message& message) OVERRIDE {
	CHECK(channel_);

	PickleIterator iter(message);
	int64 time_internal;
	EXPECT_TRUE(iter.ReadInt64(&time_internal));
	int msgid;
	EXPECT_TRUE(iter.ReadInt(&msgid));
	std::string payload;
	EXPECT_TRUE(iter.ReadString(&payload));

	// Include message deserialization in latency.
	base::TimeTicks now = base::TimeTicks::Now();

	if (payload == "hello") {
	latency_tracker_.Reset();
	} else if (payload == "quit") {
	latency_tracker_.ShowResults();
	base::MessageLoop::current()->QuitWhenIdle();
	return true;
	} else {
	// Don't track hello and quit messages.
	latency_tracker_.AddEvent(
	base::TimeTicks::FromInternalValue(time_internal), now);
	}

	IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
	msg->WriteInt64(base::TimeTicks::Now().ToInternalValue());
	msg->WriteInt(msgid);
	msg->WriteString(payload);
	channel_->Send(msg);
	return true;
	}

	private:
	IPC::Channel* channel_;
	EventTimeTracker latency_tracker_;
	};

	class PerformanceChannelListener : public IPC::Listener {
	public:
	PerformanceChannelListener()
	: channel_(NULL),
	msg_count_(0),
	msg_size_(0),
	count_down_(0),
	latency_tracker_("Server messages") {
	VLOG(1) << "Server listener up";
	}

	virtual ~PerformanceChannelListener() {
	VLOG(1) << "Server listener down";
	}

	void Init(IPC::Channel* channel) {
	DCHECK(!channel_);
	channel_ = channel;
	}

	// Call this before running the message loop.
	void SetTestParams(int msg_count, size_t msg_size) {
	DCHECK_EQ(0, count_down_);
	msg_count_ = msg_count;
	msg_size_ = msg_size;
	count_down_ = msg_count_;
	payload_ = std::string(msg_size_, 'a');
	}

	virtual bool OnMessageReceived(const IPC::Message& message) OVERRIDE {
	CHECK(channel_);

	PickleIterator iter(message);
	int64 time_internal;
	EXPECT_TRUE(iter.ReadInt64(&time_internal));
	int msgid;
	EXPECT_TRUE(iter.ReadInt(&msgid));
	std::string reflected_payload;
	EXPECT_TRUE(iter.ReadString(&reflected_payload));

	// Include message deserialization in latency.
	base::TimeTicks now = base::TimeTicks::Now();

	if (reflected_payload == "hello") {
	// Start timing on hello.
	latency_tracker_.Reset();
	DCHECK(!perf_logger_.get());
	std::string test_name = base::StringPrintf(
	"IPC_Perf_%dx_%u", msg_count_, static_cast<unsigned>(msg_size_));
	perf_logger_.reset(new base::PerfTimeLogger(test_name.c_str()));
	} else {
	DCHECK_EQ(payload_.size(), reflected_payload.size());

	latency_tracker_.AddEvent(
	base::TimeTicks::FromInternalValue(time_internal), now);

	CHECK(count_down_ > 0);
	count_down_--;
	if (count_down_ == 0) {
	perf_logger_.reset(); // Stop the perf timer now.
	latency_tracker_.ShowResults();
	base::MessageLoop::current()->QuitWhenIdle();
	return true;
	}
	}

	IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
	msg->WriteInt64(base::TimeTicks::Now().ToInternalValue());
	msg->WriteInt(count_down_);
	msg->WriteString(payload_);
	channel_->Send(msg);
	return true;
	}

	private:
	IPC::Channel* channel_;
	int msg_count_;
	size_t msg_size_;

	int count_down_;
	std::string payload_;
	EventTimeTracker latency_tracker_;
	scoped_ptr<base::PerfTimeLogger> perf_logger_;
	};

	TEST_F(IPCChannelPerfTest, Performance) {
	Init("PerformanceClient");

	// Set up IPC channel and start client.
	PerformanceChannelListener listener;
	CreateChannel(&listener);
	listener.Init(channel());
	ASSERT_TRUE(ConnectChannel());
	ASSERT_TRUE(StartClient());

	// Test several sizes. We use 12^N for message size, and limit the message
	// count to keep the test duration reasonable.
	const size_t kMsgSize[5] = {12, 144, 1728, 20736, 248832};
	const int kMessageCount[5] = {50000, 50000, 50000, 12000, 1000};

	for (size_t i = 0; i < 5; i++) {
	listener.SetTestParams(kMessageCount[i], kMsgSize[i]);

	// This initial message will kick-start the ping-pong of messages.
	IPC::Message* message =
	new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
	message->WriteInt64(base::TimeTicks::Now().ToInternalValue());
	message->WriteInt(-1);
	message->WriteString("hello");
	sender()->Send(message);

	// Run message loop.
	base::MessageLoop::current()->Run();
	}

	// Send quit message.
	IPC::Message* message = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL);
	message->WriteInt64(base::TimeTicks::Now().ToInternalValue());
	message->WriteInt(-1);
	message->WriteString("quit");
	sender()->Send(message);

	EXPECT_TRUE(WaitForClientShutdown());
	DestroyChannel();
	}

	// This message loop bounces all messages back to the sender.
	MULTIPROCESS_IPC_TEST_CLIENT_MAIN(PerformanceClient) {
	base::MessageLoopForIO main_message_loop;
	ChannelReflectorListener listener;
	scoped_ptr<IPC::Channel> channel(IPC::Channel::CreateClient(
	IPCTestBase::GetChannelName("PerformanceClient"), &listener));
	listener.Init(channel.get());
	CHECK(channel->Connect());

	base::MessageLoop::current()->Run();
	return 0;
	}

	} // namespace