// 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 "net/socket/socket_test_util.h" #include #include "base/memory/ref_counted.h" #include "testing/platform_test.h" #include "testing/gtest/include/gtest/gtest.h" //----------------------------------------------------------------------------- namespace { static const char kMsg1[] = "\0hello!\xff"; static const int kLen1 = arraysize(kMsg1); static const char kMsg2[] = "\0a2345678\0"; static const int kLen2 = arraysize(kMsg2); static const char kMsg3[] = "bye!"; static const int kLen3 = arraysize(kMsg3); } // anonymous namespace namespace net { class DeterministicSocketDataTest : public PlatformTest { public: DeterministicSocketDataTest(); void TearDown() override; void ReentrantReadCallback(int len, int rv); void ReentrantWriteCallback(const char* data, int len, int rv); protected: void Initialize(MockRead* reads, size_t reads_count, MockWrite* writes, size_t writes_count); void AssertSyncReadEquals(const char* data, int len); void AssertAsyncReadEquals(const char* data, int len); void AssertReadReturns(const char* data, int len, int rv); void AssertReadBufferEquals(const char* data, int len); void AssertSyncWriteEquals(const char* data, int len); void AssertAsyncWriteEquals(const char* data, int len); void AssertWriteReturns(const char* data, int len, int rv); TestCompletionCallback read_callback_; TestCompletionCallback write_callback_; StreamSocket* sock_; scoped_ptr data_; private: scoped_refptr read_buf_; MockConnect connect_data_; HostPortPair endpoint_; scoped_refptr tcp_params_; ClientSocketPoolHistograms histograms_; DeterministicMockClientSocketFactory socket_factory_; MockTransportClientSocketPool socket_pool_; ClientSocketHandle connection_; DISALLOW_COPY_AND_ASSIGN(DeterministicSocketDataTest); }; DeterministicSocketDataTest::DeterministicSocketDataTest() : sock_(NULL), read_buf_(NULL), connect_data_(SYNCHRONOUS, OK), endpoint_("www.google.com", 443), tcp_params_(new TransportSocketParams( endpoint_, false, false, OnHostResolutionCallback(), TransportSocketParams::COMBINE_CONNECT_AND_WRITE_DEFAULT)), histograms_(std::string()), socket_pool_(10, 10, &histograms_, &socket_factory_) {} void DeterministicSocketDataTest::TearDown() { // Empty the current queue. base::MessageLoop::current()->RunUntilIdle(); PlatformTest::TearDown(); } void DeterministicSocketDataTest::Initialize(MockRead* reads, size_t reads_count, MockWrite* writes, size_t writes_count) { data_.reset(new DeterministicSocketData(reads, reads_count, writes, writes_count)); data_->set_connect_data(connect_data_); socket_factory_.AddSocketDataProvider(data_.get()); // Perform the TCP connect EXPECT_EQ(OK, connection_.Init(endpoint_.ToString(), tcp_params_, LOWEST, CompletionCallback(), reinterpret_cast(&socket_pool_), BoundNetLog())); sock_ = connection_.socket(); } void DeterministicSocketDataTest::AssertSyncReadEquals(const char* data, int len) { // Issue the read, which will complete immediately AssertReadReturns(data, len, len); AssertReadBufferEquals(data, len); } void DeterministicSocketDataTest::AssertAsyncReadEquals(const char* data, int len) { // Issue the read, which will be completed asynchronously AssertReadReturns(data, len, ERR_IO_PENDING); EXPECT_FALSE(read_callback_.have_result()); EXPECT_TRUE(sock_->IsConnected()); data_->RunFor(1); // Runs 1 step, to cause the callbacks to be invoked // Now the read should complete ASSERT_EQ(len, read_callback_.WaitForResult()); AssertReadBufferEquals(data, len); } void DeterministicSocketDataTest::AssertReadReturns(const char* data, int len, int rv) { read_buf_ = new IOBuffer(len); ASSERT_EQ(rv, sock_->Read(read_buf_.get(), len, read_callback_.callback())); } void DeterministicSocketDataTest::AssertReadBufferEquals(const char* data, int len) { ASSERT_EQ(std::string(data, len), std::string(read_buf_->data(), len)); } void DeterministicSocketDataTest::AssertSyncWriteEquals(const char* data, int len) { scoped_refptr buf(new IOBuffer(len)); memcpy(buf->data(), data, len); // Issue the write, which will complete immediately ASSERT_EQ(len, sock_->Write(buf.get(), len, write_callback_.callback())); } void DeterministicSocketDataTest::AssertAsyncWriteEquals(const char* data, int len) { // Issue the read, which will be completed asynchronously AssertWriteReturns(data, len, ERR_IO_PENDING); EXPECT_FALSE(read_callback_.have_result()); EXPECT_TRUE(sock_->IsConnected()); data_->RunFor(1); // Runs 1 step, to cause the callbacks to be invoked ASSERT_EQ(len, write_callback_.WaitForResult()); } void DeterministicSocketDataTest::AssertWriteReturns(const char* data, int len, int rv) { scoped_refptr buf(new IOBuffer(len)); memcpy(buf->data(), data, len); // Issue the read, which will complete asynchronously ASSERT_EQ(rv, sock_->Write(buf.get(), len, write_callback_.callback())); } void DeterministicSocketDataTest::ReentrantReadCallback(int len, int rv) { scoped_refptr read_buf(new IOBuffer(len)); EXPECT_EQ(len, sock_->Read( read_buf.get(), len, base::Bind(&DeterministicSocketDataTest::ReentrantReadCallback, base::Unretained(this), len))); } void DeterministicSocketDataTest::ReentrantWriteCallback( const char* data, int len, int rv) { scoped_refptr write_buf(new IOBuffer(len)); memcpy(write_buf->data(), data, len); EXPECT_EQ(len, sock_->Write( write_buf.get(), len, base::Bind(&DeterministicSocketDataTest::ReentrantWriteCallback, base::Unretained(this), data, len))); } // ----------- Read TEST_F(DeterministicSocketDataTest, SingleSyncReadWhileStopped) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(SYNCHRONOUS, 0, 1), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); data_->SetStopped(true); AssertReadReturns(kMsg1, kLen1, ERR_UNEXPECTED); } TEST_F(DeterministicSocketDataTest, SingleSyncReadTooEarly) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 1), // Sync Read MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockWrite writes[] = { MockWrite(SYNCHRONOUS, 0, 0) }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); data_->StopAfter(2); ASSERT_FALSE(data_->stopped()); AssertReadReturns(kMsg1, kLen1, ERR_UNEXPECTED); } TEST_F(DeterministicSocketDataTest, SingleSyncRead) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(SYNCHRONOUS, 0, 1), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); // Make sure we don't stop before we've read all the data data_->StopAfter(1); AssertSyncReadEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MultipleSyncReads) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(SYNCHRONOUS, kMsg2, kLen2, 1), // Sync Read MockRead(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Read MockRead(SYNCHRONOUS, kMsg3, kLen3, 3), // Sync Read MockRead(SYNCHRONOUS, kMsg2, kLen2, 4), // Sync Read MockRead(SYNCHRONOUS, kMsg3, kLen3, 5), // Sync Read MockRead(SYNCHRONOUS, kMsg1, kLen1, 6), // Sync Read MockRead(SYNCHRONOUS, 0, 7), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); // Make sure we don't stop before we've read all the data data_->StopAfter(10); AssertSyncReadEquals(kMsg1, kLen1); AssertSyncReadEquals(kMsg2, kLen2); AssertSyncReadEquals(kMsg3, kLen3); AssertSyncReadEquals(kMsg3, kLen3); AssertSyncReadEquals(kMsg2, kLen2); AssertSyncReadEquals(kMsg3, kLen3); AssertSyncReadEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, SingleAsyncRead) { MockRead reads[] = { MockRead(ASYNC, kMsg1, kLen1, 0), // Async Read MockRead(SYNCHRONOUS, 0, 1), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); AssertAsyncReadEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MultipleAsyncReads) { MockRead reads[] = { MockRead(ASYNC, kMsg1, kLen1, 0), // Async Read MockRead(ASYNC, kMsg2, kLen2, 1), // Async Read MockRead(ASYNC, kMsg3, kLen3, 2), // Async Read MockRead(ASYNC, kMsg3, kLen3, 3), // Async Read MockRead(ASYNC, kMsg2, kLen2, 4), // Async Read MockRead(ASYNC, kMsg3, kLen3, 5), // Async Read MockRead(ASYNC, kMsg1, kLen1, 6), // Async Read MockRead(SYNCHRONOUS, 0, 7), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); AssertAsyncReadEquals(kMsg1, kLen1); AssertAsyncReadEquals(kMsg2, kLen2); AssertAsyncReadEquals(kMsg3, kLen3); AssertAsyncReadEquals(kMsg3, kLen3); AssertAsyncReadEquals(kMsg2, kLen2); AssertAsyncReadEquals(kMsg3, kLen3); AssertAsyncReadEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MixedReads) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(ASYNC, kMsg2, kLen2, 1), // Async Read MockRead(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Read MockRead(ASYNC, kMsg3, kLen3, 3), // Async Read MockRead(SYNCHRONOUS, kMsg2, kLen2, 4), // Sync Read MockRead(ASYNC, kMsg3, kLen3, 5), // Async Read MockRead(SYNCHRONOUS, kMsg1, kLen1, 6), // Sync Read MockRead(SYNCHRONOUS, 0, 7), // EOF }; Initialize(reads, arraysize(reads), NULL, 0); data_->StopAfter(1); AssertSyncReadEquals(kMsg1, kLen1); AssertAsyncReadEquals(kMsg2, kLen2); data_->StopAfter(1); AssertSyncReadEquals(kMsg3, kLen3); AssertAsyncReadEquals(kMsg3, kLen3); data_->StopAfter(1); AssertSyncReadEquals(kMsg2, kLen2); AssertAsyncReadEquals(kMsg3, kLen3); data_->StopAfter(1); AssertSyncReadEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, SyncReadFromCompletionCallback) { MockRead reads[] = { MockRead(ASYNC, kMsg1, kLen1, 0), // Async Read MockRead(SYNCHRONOUS, kMsg2, kLen2, 1), // Sync Read }; Initialize(reads, arraysize(reads), NULL, 0); data_->StopAfter(2); scoped_refptr read_buf(new IOBuffer(kLen1)); ASSERT_EQ(ERR_IO_PENDING, sock_->Read( read_buf.get(), kLen1, base::Bind(&DeterministicSocketDataTest::ReentrantReadCallback, base::Unretained(this), kLen2))); data_->Run(); } // ----------- Write TEST_F(DeterministicSocketDataTest, SingleSyncWriteWhileStopped) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read }; Initialize(NULL, 0, writes, arraysize(writes)); data_->SetStopped(true); AssertWriteReturns(kMsg1, kLen1, ERR_UNEXPECTED); } TEST_F(DeterministicSocketDataTest, SingleSyncWriteTooEarly) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg1, kLen1, 1), // Sync Write }; MockRead reads[] = { MockRead(SYNCHRONOUS, 0, 0) }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); data_->StopAfter(2); ASSERT_FALSE(data_->stopped()); AssertWriteReturns(kMsg1, kLen1, ERR_UNEXPECTED); } TEST_F(DeterministicSocketDataTest, SingleSyncWrite) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Write }; Initialize(NULL, 0, writes, arraysize(writes)); // Make sure we don't stop before we've read all the data data_->StopAfter(1); AssertSyncWriteEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MultipleSyncWrites) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Write MockWrite(SYNCHRONOUS, kMsg2, kLen2, 1), // Sync Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 3), // Sync Write MockWrite(SYNCHRONOUS, kMsg2, kLen2, 4), // Sync Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 5), // Sync Write MockWrite(SYNCHRONOUS, kMsg1, kLen1, 6), // Sync Write }; Initialize(NULL, 0, writes, arraysize(writes)); // Make sure we don't stop before we've read all the data data_->StopAfter(10); AssertSyncWriteEquals(kMsg1, kLen1); AssertSyncWriteEquals(kMsg2, kLen2); AssertSyncWriteEquals(kMsg3, kLen3); AssertSyncWriteEquals(kMsg3, kLen3); AssertSyncWriteEquals(kMsg2, kLen2); AssertSyncWriteEquals(kMsg3, kLen3); AssertSyncWriteEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, SingleAsyncWrite) { MockWrite writes[] = { MockWrite(ASYNC, kMsg1, kLen1, 0), // Async Write }; Initialize(NULL, 0, writes, arraysize(writes)); AssertAsyncWriteEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MultipleAsyncWrites) { MockWrite writes[] = { MockWrite(ASYNC, kMsg1, kLen1, 0), // Async Write MockWrite(ASYNC, kMsg2, kLen2, 1), // Async Write MockWrite(ASYNC, kMsg3, kLen3, 2), // Async Write MockWrite(ASYNC, kMsg3, kLen3, 3), // Async Write MockWrite(ASYNC, kMsg2, kLen2, 4), // Async Write MockWrite(ASYNC, kMsg3, kLen3, 5), // Async Write MockWrite(ASYNC, kMsg1, kLen1, 6), // Async Write }; Initialize(NULL, 0, writes, arraysize(writes)); AssertAsyncWriteEquals(kMsg1, kLen1); AssertAsyncWriteEquals(kMsg2, kLen2); AssertAsyncWriteEquals(kMsg3, kLen3); AssertAsyncWriteEquals(kMsg3, kLen3); AssertAsyncWriteEquals(kMsg2, kLen2); AssertAsyncWriteEquals(kMsg3, kLen3); AssertAsyncWriteEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, MixedWrites) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Write MockWrite(ASYNC, kMsg2, kLen2, 1), // Async Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Write MockWrite(ASYNC, kMsg3, kLen3, 3), // Async Write MockWrite(SYNCHRONOUS, kMsg2, kLen2, 4), // Sync Write MockWrite(ASYNC, kMsg3, kLen3, 5), // Async Write MockWrite(SYNCHRONOUS, kMsg1, kLen1, 6), // Sync Write }; Initialize(NULL, 0, writes, arraysize(writes)); data_->StopAfter(1); AssertSyncWriteEquals(kMsg1, kLen1); AssertAsyncWriteEquals(kMsg2, kLen2); data_->StopAfter(1); AssertSyncWriteEquals(kMsg3, kLen3); AssertAsyncWriteEquals(kMsg3, kLen3); data_->StopAfter(1); AssertSyncWriteEquals(kMsg2, kLen2); AssertAsyncWriteEquals(kMsg3, kLen3); data_->StopAfter(1); AssertSyncWriteEquals(kMsg1, kLen1); } TEST_F(DeterministicSocketDataTest, SyncWriteFromCompletionCallback) { MockWrite writes[] = { MockWrite(ASYNC, kMsg1, kLen1, 0), // Async Write MockWrite(SYNCHRONOUS, kMsg2, kLen2, 1), // Sync Write }; Initialize(NULL, 0, writes, arraysize(writes)); data_->StopAfter(2); scoped_refptr write_buf(new IOBuffer(kLen1)); memcpy(write_buf->data(), kMsg1, kLen1); ASSERT_EQ(ERR_IO_PENDING, sock_->Write( write_buf.get(), kLen1, base::Bind(&DeterministicSocketDataTest::ReentrantWriteCallback, base::Unretained(this), kMsg2, kLen2))); data_->Run(); } // ----------- Mixed Reads and Writes TEST_F(DeterministicSocketDataTest, MixedSyncOperations) { MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(SYNCHRONOUS, kMsg2, kLen2, 3), // Sync Read MockRead(SYNCHRONOUS, 0, 4), // EOF }; MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMsg2, kLen2, 1), // Sync Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Write }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); // Make sure we don't stop before we've read/written everything data_->StopAfter(10); AssertSyncReadEquals(kMsg1, kLen1); AssertSyncWriteEquals(kMsg2, kLen2); AssertSyncWriteEquals(kMsg3, kLen3); AssertSyncReadEquals(kMsg2, kLen2); } TEST_F(DeterministicSocketDataTest, MixedAsyncOperations) { MockRead reads[] = { MockRead(ASYNC, kMsg1, kLen1, 0), // Sync Read MockRead(ASYNC, kMsg2, kLen2, 3), // Sync Read MockRead(ASYNC, 0, 4), // EOF }; MockWrite writes[] = { MockWrite(ASYNC, kMsg2, kLen2, 1), // Sync Write MockWrite(ASYNC, kMsg3, kLen3, 2), // Sync Write }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); AssertAsyncReadEquals(kMsg1, kLen1); AssertAsyncWriteEquals(kMsg2, kLen2); AssertAsyncWriteEquals(kMsg3, kLen3); AssertAsyncReadEquals(kMsg2, kLen2); } TEST_F(DeterministicSocketDataTest, InterleavedAsyncOperations) { // Order of completion is read, write, write, read MockRead reads[] = { MockRead(ASYNC, kMsg1, kLen1, 0), // Async Read MockRead(ASYNC, kMsg2, kLen2, 3), // Async Read MockRead(ASYNC, 0, 4), // EOF }; MockWrite writes[] = { MockWrite(ASYNC, kMsg2, kLen2, 1), // Async Write MockWrite(ASYNC, kMsg3, kLen3, 2), // Async Write }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); // Issue the write, which will block until the read completes AssertWriteReturns(kMsg2, kLen2, ERR_IO_PENDING); // Issue the read which will return first AssertReadReturns(kMsg1, kLen1, ERR_IO_PENDING); data_->RunFor(1); ASSERT_TRUE(read_callback_.have_result()); ASSERT_EQ(kLen1, read_callback_.WaitForResult()); AssertReadBufferEquals(kMsg1, kLen1); data_->RunFor(1); ASSERT_TRUE(write_callback_.have_result()); ASSERT_EQ(kLen2, write_callback_.WaitForResult()); data_->StopAfter(1); // Issue the read, which will block until the write completes AssertReadReturns(kMsg2, kLen2, ERR_IO_PENDING); // Issue the writes which will return first AssertWriteReturns(kMsg3, kLen3, ERR_IO_PENDING); data_->RunFor(1); ASSERT_TRUE(write_callback_.have_result()); ASSERT_EQ(kLen3, write_callback_.WaitForResult()); data_->RunFor(1); ASSERT_TRUE(read_callback_.have_result()); ASSERT_EQ(kLen2, read_callback_.WaitForResult()); AssertReadBufferEquals(kMsg2, kLen2); } TEST_F(DeterministicSocketDataTest, InterleavedMixedOperations) { // Order of completion is read, write, write, read MockRead reads[] = { MockRead(SYNCHRONOUS, kMsg1, kLen1, 0), // Sync Read MockRead(ASYNC, kMsg2, kLen2, 3), // Async Read MockRead(SYNCHRONOUS, 0, 4), // EOF }; MockWrite writes[] = { MockWrite(ASYNC, kMsg2, kLen2, 1), // Async Write MockWrite(SYNCHRONOUS, kMsg3, kLen3, 2), // Sync Write }; Initialize(reads, arraysize(reads), writes, arraysize(writes)); // Issue the write, which will block until the read completes AssertWriteReturns(kMsg2, kLen2, ERR_IO_PENDING); // Issue the writes which will complete immediately data_->StopAfter(1); AssertSyncReadEquals(kMsg1, kLen1); data_->RunFor(1); ASSERT_TRUE(write_callback_.have_result()); ASSERT_EQ(kLen2, write_callback_.WaitForResult()); // Issue the read, which will block until the write completes AssertReadReturns(kMsg2, kLen2, ERR_IO_PENDING); // Issue the writes which will complete immediately data_->StopAfter(1); AssertSyncWriteEquals(kMsg3, kLen3); data_->RunFor(1); ASSERT_TRUE(read_callback_.have_result()); ASSERT_EQ(kLen2, read_callback_.WaitForResult()); AssertReadBufferEquals(kMsg2, kLen2); } } // namespace net