// Copyright (c) 2010 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" #if defined(OS_WIN) #include #elif defined(OS_POSIX) #include #include #endif #include #include #include #include "ipc/ipc_tests.h" #include "base/base_switches.h" #include "base/command_line.h" #include "base/debug/debug_on_start_win.h" #include "base/perftimer.h" #include "base/test/perf_test_suite.h" #include "base/test/test_suite.h" #include "base/threading/thread.h" #include "ipc/ipc_descriptors.h" #include "ipc/ipc_channel.h" #include "ipc/ipc_channel_proxy.h" #include "ipc/ipc_message_utils.h" #include "ipc/ipc_switches.h" #include "testing/multiprocess_func_list.h" // Define to enable IPC performance testing instead of the regular unit tests // #define PERFORMANCE_TEST const char kTestClientChannel[] = "T1"; const char kReflectorChannel[] = "T2"; const char kFuzzerChannel[] = "F3"; const char kSyncSocketChannel[] = "S4"; const size_t kLongMessageStringNumBytes = 50000; #ifndef PERFORMANCE_TEST void IPCChannelTest::SetUp() { MultiProcessTest::SetUp(); // Construct a fresh IO Message loop for the duration of each test. message_loop_ = new MessageLoopForIO(); } void IPCChannelTest::TearDown() { delete message_loop_; message_loop_ = NULL; MultiProcessTest::TearDown(); } #if defined(OS_WIN) base::ProcessHandle IPCChannelTest::SpawnChild(ChildType child_type, IPC::Channel *channel) { // kDebugChildren support. bool debug_on_start = CommandLine::ForCurrentProcess()->HasSwitch(switches::kDebugChildren); switch (child_type) { case TEST_CLIENT: return MultiProcessTest::SpawnChild("RunTestClient", debug_on_start); case TEST_REFLECTOR: return MultiProcessTest::SpawnChild("RunReflector", debug_on_start); case FUZZER_SERVER: return MultiProcessTest::SpawnChild("RunFuzzServer", debug_on_start); case SYNC_SOCKET_SERVER: return MultiProcessTest::SpawnChild("RunSyncSocketServer", debug_on_start); default: return NULL; } } #elif defined(OS_POSIX) base::ProcessHandle IPCChannelTest::SpawnChild(ChildType child_type, IPC::Channel *channel) { // kDebugChildren support. bool debug_on_start = CommandLine::ForCurrentProcess()->HasSwitch(switches::kDebugChildren); base::file_handle_mapping_vector fds_to_map; const int ipcfd = channel->GetClientFileDescriptor(); if (ipcfd > -1) { fds_to_map.push_back(std::pair(ipcfd, kPrimaryIPCChannel + 3)); } base::ProcessHandle ret = base::kNullProcessHandle; switch (child_type) { case TEST_CLIENT: ret = MultiProcessTest::SpawnChild("RunTestClient", fds_to_map, debug_on_start); break; case TEST_DESCRIPTOR_CLIENT: ret = MultiProcessTest::SpawnChild("RunTestDescriptorClient", fds_to_map, debug_on_start); break; case TEST_DESCRIPTOR_CLIENT_SANDBOXED: ret = MultiProcessTest::SpawnChild("RunTestDescriptorClientSandboxed", fds_to_map, debug_on_start); break; case TEST_REFLECTOR: ret = MultiProcessTest::SpawnChild("RunReflector", fds_to_map, debug_on_start); break; case FUZZER_SERVER: ret = MultiProcessTest::SpawnChild("RunFuzzServer", fds_to_map, debug_on_start); break; case SYNC_SOCKET_SERVER: ret = MultiProcessTest::SpawnChild("RunSyncSocketServer", fds_to_map, debug_on_start); break; default: return base::kNullProcessHandle; break; } return ret; } #endif // defined(OS_POSIX) TEST_F(IPCChannelTest, BasicMessageTest) { int v1 = 10; std::string v2("foobar"); std::wstring v3(L"hello world"); IPC::Message m(0, 1, IPC::Message::PRIORITY_NORMAL); EXPECT_TRUE(m.WriteInt(v1)); EXPECT_TRUE(m.WriteString(v2)); EXPECT_TRUE(m.WriteWString(v3)); void* iter = NULL; int vi; std::string vs; std::wstring vw; EXPECT_TRUE(m.ReadInt(&iter, &vi)); EXPECT_EQ(v1, vi); EXPECT_TRUE(m.ReadString(&iter, &vs)); EXPECT_EQ(v2, vs); EXPECT_TRUE(m.ReadWString(&iter, &vw)); EXPECT_EQ(v3, vw); // should fail EXPECT_FALSE(m.ReadInt(&iter, &vi)); EXPECT_FALSE(m.ReadString(&iter, &vs)); EXPECT_FALSE(m.ReadWString(&iter, &vw)); } static void Send(IPC::Message::Sender* sender, const char* text) { static int message_index = 0; IPC::Message* message = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL); message->WriteInt(message_index++); message->WriteString(std::string(text)); // Make sure we can handle large messages. char junk[kLongMessageStringNumBytes]; memset(junk, 'a', sizeof(junk)-1); junk[sizeof(junk)-1] = 0; message->WriteString(std::string(junk)); // DEBUG: printf("[%u] sending message [%s]\n", GetCurrentProcessId(), text); sender->Send(message); } class MyChannelListener : public IPC::Channel::Listener { public: virtual bool OnMessageReceived(const IPC::Message& message) { IPC::MessageIterator iter(message); iter.NextInt(); const std::string data = iter.NextString(); const std::string big_string = iter.NextString(); EXPECT_EQ(kLongMessageStringNumBytes - 1, big_string.length()); if (--messages_left_ == 0) { MessageLoop::current()->Quit(); } else { Send(sender_, "Foo"); } return true; } virtual void OnChannelError() { // There is a race when closing the channel so the last message may be lost. EXPECT_LE(messages_left_, 1); MessageLoop::current()->Quit(); } void Init(IPC::Message::Sender* s) { sender_ = s; messages_left_ = 50; } private: IPC::Message::Sender* sender_; int messages_left_; }; TEST_F(IPCChannelTest, ChannelTest) { MyChannelListener channel_listener; // Setup IPC channel. IPC::Channel chan(kTestClientChannel, IPC::Channel::MODE_SERVER, &channel_listener); ASSERT_TRUE(chan.Connect()); channel_listener.Init(&chan); base::ProcessHandle process_handle = SpawnChild(TEST_CLIENT, &chan); ASSERT_TRUE(process_handle); Send(&chan, "hello from parent"); // Run message loop. MessageLoop::current()->Run(); // Close Channel so client gets its OnChannelError() callback fired. chan.Close(); // Cleanup child process. EXPECT_TRUE(base::WaitForSingleProcess(process_handle, 5000)); base::CloseProcessHandle(process_handle); } TEST_F(IPCChannelTest, ChannelProxyTest) { MyChannelListener channel_listener; // The thread needs to out-live the ChannelProxy. base::Thread thread("ChannelProxyTestServer"); base::Thread::Options options; options.message_loop_type = MessageLoop::TYPE_IO; thread.StartWithOptions(options); { // setup IPC channel proxy IPC::ChannelProxy chan(kTestClientChannel, IPC::Channel::MODE_SERVER, &channel_listener, thread.message_loop_proxy()); channel_listener.Init(&chan); #if defined(OS_WIN) base::ProcessHandle process_handle = SpawnChild(TEST_CLIENT, NULL); #elif defined(OS_POSIX) bool debug_on_start = CommandLine::ForCurrentProcess()->HasSwitch( switches::kDebugChildren); base::file_handle_mapping_vector fds_to_map; const int ipcfd = chan.GetClientFileDescriptor(); if (ipcfd > -1) { fds_to_map.push_back(std::pair(ipcfd, kPrimaryIPCChannel + 3)); } base::ProcessHandle process_handle = MultiProcessTest::SpawnChild( "RunTestClient", fds_to_map, debug_on_start); #endif // defined(OS_POSIX) ASSERT_TRUE(process_handle); Send(&chan, "hello from parent"); // run message loop MessageLoop::current()->Run(); // cleanup child process EXPECT_TRUE(base::WaitForSingleProcess(process_handle, 5000)); base::CloseProcessHandle(process_handle); } thread.Stop(); } class ChannelListenerWithOnConnectedSend : public IPC::Channel::Listener { public: virtual void OnChannelConnected(int32 peer_pid) { SendNextMessage(); } virtual bool OnMessageReceived(const IPC::Message& message) { IPC::MessageIterator iter(message); iter.NextInt(); const std::string data = iter.NextString(); const std::string big_string = iter.NextString(); EXPECT_EQ(kLongMessageStringNumBytes - 1, big_string.length()); SendNextMessage(); return true; } virtual void OnChannelError() { // There is a race when closing the channel so the last message may be lost. EXPECT_LE(messages_left_, 1); MessageLoop::current()->Quit(); } void Init(IPC::Message::Sender* s) { sender_ = s; messages_left_ = 50; } private: void SendNextMessage() { if (--messages_left_ == 0) { MessageLoop::current()->Quit(); } else { Send(sender_, "Foo"); } } IPC::Message::Sender* sender_; int messages_left_; }; TEST_F(IPCChannelTest, SendMessageInChannelConnected) { // This tests the case of a listener sending back an event in it's // OnChannelConnected handler. ChannelListenerWithOnConnectedSend channel_listener; // Setup IPC channel. IPC::Channel channel(kTestClientChannel, IPC::Channel::MODE_SERVER, &channel_listener); channel_listener.Init(&channel); ASSERT_TRUE(channel.Connect()); base::ProcessHandle process_handle = SpawnChild(TEST_CLIENT, &channel); ASSERT_TRUE(process_handle); Send(&channel, "hello from parent"); // Run message loop. MessageLoop::current()->Run(); // Close Channel so client gets its OnChannelError() callback fired. channel.Close(); // Cleanup child process. EXPECT_TRUE(base::WaitForSingleProcess(process_handle, 5000)); base::CloseProcessHandle(process_handle); } MULTIPROCESS_TEST_MAIN(RunTestClient) { MessageLoopForIO main_message_loop; MyChannelListener channel_listener; // setup IPC channel IPC::Channel chan(kTestClientChannel, IPC::Channel::MODE_CLIENT, &channel_listener); CHECK(chan.Connect()); channel_listener.Init(&chan); Send(&chan, "hello from child"); // run message loop MessageLoop::current()->Run(); // return true; return 0; } #endif // !PERFORMANCE_TEST #ifdef PERFORMANCE_TEST //----------------------------------------------------------------------------- // Manually performance test // // This test times the roundtrip IPC message cycle. It is enabled with a // special preprocessor define to enable it instead of the standard IPC // unit tests. This works around some funny termination conditions in the // regular unit tests. // // This test is not automated. To test, you will want to vary the message // count and message size in TEST to get the numbers you want. // // FIXME(brettw): Automate this test and have it run by default. // 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::Channel::Listener { public: explicit ChannelReflectorListener(IPC::Channel *channel) : channel_(channel), count_messages_(0), latency_messages_(0) { std::cout << "Reflector up" << std::endl; } ~ChannelReflectorListener() { std::cout << "Client Messages: " << count_messages_ << std::endl; std::cout << "Client Latency: " << latency_messages_ << std::endl; } virtual bool OnMessageReceived(const IPC::Message& message) { count_messages_++; IPC::MessageIterator iter(message); int time = iter.NextInt(); int msgid = iter.NextInt(); std::string payload = iter.NextString(); latency_messages_ += GetTickCount() - time; // cout << "reflector msg received: " << msgid << endl; if (payload == "quit") MessageLoop::current()->Quit(); IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL); msg->WriteInt(GetTickCount()); msg->WriteInt(msgid); msg->WriteString(payload); channel_->Send(msg); return true; } private: IPC::Channel *channel_; int count_messages_; int latency_messages_; }; class ChannelPerfListener : public IPC::Channel::Listener { public: ChannelPerfListener(IPC::Channel* channel, int msg_count, int msg_size) : count_down_(msg_count), channel_(channel), count_messages_(0), latency_messages_(0) { payload_.resize(msg_size); for (int i = 0; i < static_cast(payload_.size()); i++) payload_[i] = 'a'; std::cout << "perflistener up" << std::endl; } ~ChannelPerfListener() { std::cout << "Server Messages: " << count_messages_ << std::endl; std::cout << "Server Latency: " << latency_messages_ << std::endl; } virtual bool OnMessageReceived(const IPC::Message& message) { count_messages_++; // decode the string so this gets counted in the total time IPC::MessageIterator iter(message); int time = iter.NextInt(); int msgid = iter.NextInt(); std::string cur = iter.NextString(); latency_messages_ += GetTickCount() - time; // cout << "perflistener got message" << endl; count_down_--; if (count_down_ == 0) { IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL); msg->WriteInt(GetTickCount()); msg->WriteInt(count_down_); msg->WriteString("quit"); channel_->Send(msg); SetTimer(NULL, 1, 250, (TIMERPROC) PostQuitMessage); return true; } IPC::Message* msg = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL); msg->WriteInt(GetTickCount()); msg->WriteInt(count_down_); msg->WriteString(payload_); channel_->Send(msg); return true; } private: int count_down_; std::string payload_; IPC::Channel *channel_; int count_messages_; int latency_messages_; }; TEST_F(IPCChannelTest, Performance) { // setup IPC channel IPC::Channel chan(kReflectorChannel, IPC::Channel::MODE_SERVER, NULL); ChannelPerfListener perf_listener(&chan, 10000, 100000); chan.set_listener(&perf_listener); ASSERT_TRUE(chan.Connect()); HANDLE process = SpawnChild(TEST_REFLECTOR, &chan); ASSERT_TRUE(process); PlatformThread::Sleep(1000); PerfTimeLogger logger("IPC_Perf"); // this initial message will kick-start the ping-pong of messages IPC::Message* message = new IPC::Message(0, 2, IPC::Message::PRIORITY_NORMAL); message->WriteInt(GetTickCount()); message->WriteInt(-1); message->WriteString("Hello"); chan.Send(message); // run message loop MessageLoop::current()->Run(); // cleanup child process WaitForSingleObject(process, 5000); CloseHandle(process); } // This message loop bounces all messages back to the sender MULTIPROCESS_TEST_MAIN(RunReflector) { MessageLoopForIO main_message_loop; IPC::Channel chan(kReflectorChannel, IPC::Channel::MODE_CLIENT, NULL); ChannelReflectorListener channel_reflector_listener(&chan); chan.set_listener(&channel_reflector_listener); ASSERT_TRUE(chan.Connect()); MessageLoop::current()->Run(); return true; } #endif // PERFORMANCE_TEST int main(int argc, char** argv) { #ifdef PERFORMANCE_TEST int retval = base::PerfTestSuite(argc, argv).Run(); #else int retval = base::TestSuite(argc, argv).Run(); #endif return retval; }