// Copyright 2013 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. // // Tests for WebSocketBasicStream. Note that we do not attempt to verify that // frame parsing itself functions correctly, as that is covered by the // WebSocketFrameParser tests. #include "net/websockets/websocket_basic_stream.h" #include <string.h> // for memcpy() and memset(). #include <string> #include "base/basictypes.h" #include "base/big_endian.h" #include "base/port.h" #include "net/base/capturing_net_log.h" #include "net/base/test_completion_callback.h" #include "net/socket/socket_test_util.h" #include "testing/gtest/include/gtest/gtest.h" namespace net { namespace { #define WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(name, value) \ const char k##name[] = value; \ const size_t k##name##Size = arraysize(k##name) - 1; WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(SampleFrame, "\x81\x06Sample"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT( PartialLargeFrame, "\x81\x7F\x00\x00\x00\x00\x7F\xFF\xFF\xFF" "chromiunum ad pasco per loca insanis pullum manducat frumenti"); const size_t kLargeFrameHeaderSize = 10; WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(MultipleFrames, "\x81\x01X\x81\x01Y\x81\x01Z"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(EmptyFirstFrame, "\x01\x00"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(EmptyMiddleFrame, "\x00\x00"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(EmptyFinalTextFrame, "\x81\x00"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(EmptyFinalContinuationFrame, "\x80\x00"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(ValidPong, "\x8A\x00"); // This frame encodes a payload length of 7 in two bytes, which is always // invalid. WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(InvalidFrame, "\x81\x7E\x00\x07Invalid"); // Control frames must have the FIN bit set. This one does not. WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(PingFrameWithoutFin, "\x09\x00"); // Control frames must have a payload of 125 bytes or less. This one has // a payload of 126 bytes. WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT( 126BytePong, "\x8a\x7e\x00\x7eZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZ" "ZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZ"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(CloseFrame, "\x88\x09\x03\xe8occludo"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(WriteFrame, "\x81\x85\x00\x00\x00\x00Write"); WEBSOCKET_BASIC_STREAM_TEST_DEFINE_CONSTANT(MaskedEmptyPong, "\x8A\x80\x00\x00\x00\x00"); const WebSocketMaskingKey kNulMaskingKey = {{'\0', '\0', '\0', '\0'}}; const WebSocketMaskingKey kNonNulMaskingKey = { {'\x0d', '\x1b', '\x06', '\x17'}}; // A masking key generator function which generates the identity mask, // ie. "\0\0\0\0". WebSocketMaskingKey GenerateNulMaskingKey() { return kNulMaskingKey; } // A masking key generation function which generates a fixed masking key with no // nul characters. WebSocketMaskingKey GenerateNonNulMaskingKey() { return kNonNulMaskingKey; } // Base class for WebSocketBasicStream test fixtures. class WebSocketBasicStreamTest : public ::testing::Test { protected: scoped_ptr<WebSocketBasicStream> stream_; CapturingNetLog net_log_; }; // A subclass of StaticSocketDataProvider modified to require that all data // expected to be read or written actually is. class StrictStaticSocketDataProvider : public StaticSocketDataProvider { public: StrictStaticSocketDataProvider(MockRead* reads, size_t reads_count, MockWrite* writes, size_t writes_count, bool strict_mode) : StaticSocketDataProvider(reads, reads_count, writes, writes_count), strict_mode_(strict_mode) {} virtual ~StrictStaticSocketDataProvider() { if (strict_mode_) { EXPECT_EQ(read_count(), read_index()); EXPECT_EQ(write_count(), write_index()); } } private: const bool strict_mode_; }; // A fixture for tests which only perform normal socket operations. class WebSocketBasicStreamSocketTest : public WebSocketBasicStreamTest { protected: WebSocketBasicStreamSocketTest() : histograms_("a"), pool_(1, 1, &histograms_, &factory_), generator_(&GenerateNulMaskingKey), expect_all_io_to_complete_(true) {} virtual ~WebSocketBasicStreamSocketTest() { // stream_ has a reference to socket_data_ (via MockTCPClientSocket) and so // should be destroyed first. stream_.reset(); } scoped_ptr<ClientSocketHandle> MakeTransportSocket(MockRead reads[], size_t reads_count, MockWrite writes[], size_t writes_count) { socket_data_.reset(new StrictStaticSocketDataProvider( reads, reads_count, writes, writes_count, expect_all_io_to_complete_)); socket_data_->set_connect_data(MockConnect(SYNCHRONOUS, OK)); factory_.AddSocketDataProvider(socket_data_.get()); scoped_ptr<ClientSocketHandle> transport_socket(new ClientSocketHandle); scoped_refptr<MockTransportSocketParams> params; transport_socket->Init("a", params, MEDIUM, CompletionCallback(), &pool_, bound_net_log_.bound()); return transport_socket.Pass(); } void SetHttpReadBuffer(const char* data, size_t size) { http_read_buffer_ = new GrowableIOBuffer; http_read_buffer_->SetCapacity(size); memcpy(http_read_buffer_->data(), data, size); http_read_buffer_->set_offset(size); } void CreateStream(MockRead reads[], size_t reads_count, MockWrite writes[], size_t writes_count) { stream_ = WebSocketBasicStream::CreateWebSocketBasicStreamForTesting( MakeTransportSocket(reads, reads_count, writes, writes_count), http_read_buffer_, sub_protocol_, extensions_, generator_); } template <size_t N> void CreateReadOnly(MockRead (&reads)[N]) { CreateStream(reads, N, NULL, 0); } void CreateNullStream() { CreateStream(NULL, 0, NULL, 0); } scoped_ptr<SocketDataProvider> socket_data_; MockClientSocketFactory factory_; ClientSocketPoolHistograms histograms_; MockTransportClientSocketPool pool_; CapturingBoundNetLog(bound_net_log_); ScopedVector<WebSocketFrame> frames_; TestCompletionCallback cb_; scoped_refptr<GrowableIOBuffer> http_read_buffer_; std::string sub_protocol_; std::string extensions_; WebSocketBasicStream::WebSocketMaskingKeyGeneratorFunction generator_; bool expect_all_io_to_complete_; }; // A test fixture for the common case of tests that only perform a single read. class WebSocketBasicStreamSocketSingleReadTest : public WebSocketBasicStreamSocketTest { protected: void CreateRead(const MockRead& read) { reads_[0] = read; CreateStream(reads_, 1U, NULL, 0); } MockRead reads_[1]; }; // A test fixture for tests that perform chunked reads. class WebSocketBasicStreamSocketChunkedReadTest : public WebSocketBasicStreamSocketTest { protected: // Specify the behaviour if there aren't enough chunks to use all the data. If // LAST_FRAME_BIG is specified, then the rest of the data will be // put in the last chunk. If LAST_FRAME_NOT_BIG is specified, then the last // frame will be no bigger than the rest of the frames (but it can be smaller, // if not enough data remains). enum LastFrameBehaviour { LAST_FRAME_BIG, LAST_FRAME_NOT_BIG }; // Prepares a read from |data| of |data_size|, split into |number_of_chunks|, // each of |chunk_size| (except that the last chunk may be larger or // smaller). All reads must be either SYNCHRONOUS or ASYNC (not a mixture), // and errors cannot be simulated. Once data is exhausted, further reads will // return 0 (ie. connection closed). void CreateChunkedRead(IoMode mode, const char data[], size_t data_size, int chunk_size, int number_of_chunks, LastFrameBehaviour last_frame_behaviour) { reads_.reset(new MockRead[number_of_chunks]); const char* start = data; for (int i = 0; i < number_of_chunks; ++i) { int len = chunk_size; const bool is_last_chunk = (i == number_of_chunks - 1); if ((last_frame_behaviour == LAST_FRAME_BIG && is_last_chunk) || static_cast<int>(data + data_size - start) < len) { len = static_cast<int>(data + data_size - start); } reads_[i] = MockRead(mode, start, len); start += len; } CreateStream(reads_.get(), number_of_chunks, NULL, 0); } scoped_ptr<MockRead[]> reads_; }; // Test fixture for write tests. class WebSocketBasicStreamSocketWriteTest : public WebSocketBasicStreamSocketTest { protected: // All write tests use the same frame, so it is easiest to create it during // test creation. virtual void SetUp() OVERRIDE { PrepareWriteFrame(); } // Creates a WebSocketFrame with a wire format matching kWriteFrame and adds // it to |frames_|. void PrepareWriteFrame() { scoped_ptr<WebSocketFrame> frame( new WebSocketFrame(WebSocketFrameHeader::kOpCodeText)); const size_t payload_size = kWriteFrameSize - (WebSocketFrameHeader::kBaseHeaderSize + WebSocketFrameHeader::kMaskingKeyLength); frame->data = new IOBuffer(payload_size); memcpy(frame->data->data(), kWriteFrame + kWriteFrameSize - payload_size, payload_size); WebSocketFrameHeader& header = frame->header; header.final = true; header.masked = true; header.payload_length = payload_size; frames_.push_back(frame.release()); } // Creates a stream that expects the listed writes. template <size_t N> void CreateWriteOnly(MockWrite (&writes)[N]) { CreateStream(NULL, 0, writes, N); } }; TEST_F(WebSocketBasicStreamSocketTest, ConstructionWorks) { CreateNullStream(); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, SyncReadWorks) { CreateRead(MockRead(SYNCHRONOUS, kSampleFrame, kSampleFrameSize)); int result = stream_->ReadFrames(&frames_, cb_.callback()); EXPECT_EQ(OK, result); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); EXPECT_TRUE(frames_[0]->header.final); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, AsyncReadWorks) { CreateRead(MockRead(ASYNC, kSampleFrame, kSampleFrameSize)); int result = stream_->ReadFrames(&frames_, cb_.callback()); ASSERT_EQ(ERR_IO_PENDING, result); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); // Don't repeat all the tests from SyncReadWorks; just enough to be sure the // frame was really read. } // ReadFrames will not return a frame whose header has not been wholly received. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, HeaderFragmentedSync) { CreateChunkedRead( SYNCHRONOUS, kSampleFrame, kSampleFrameSize, 1, 2, LAST_FRAME_BIG); int result = stream_->ReadFrames(&frames_, cb_.callback()); EXPECT_EQ(OK, result); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); } // The same behaviour applies to asynchronous reads. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, HeaderFragmentedAsync) { CreateChunkedRead( ASYNC, kSampleFrame, kSampleFrameSize, 1, 2, LAST_FRAME_BIG); int result = stream_->ReadFrames(&frames_, cb_.callback()); ASSERT_EQ(ERR_IO_PENDING, result); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); } // If it receives an incomplete header in a synchronous call, then has to wait // for the rest of the frame, ReadFrames will return ERR_IO_PENDING. TEST_F(WebSocketBasicStreamSocketTest, HeaderFragmentedSyncAsync) { MockRead reads[] = {MockRead(SYNCHRONOUS, kSampleFrame, 1), MockRead(ASYNC, kSampleFrame + 1, kSampleFrameSize - 1)}; CreateReadOnly(reads); int result = stream_->ReadFrames(&frames_, cb_.callback()); ASSERT_EQ(ERR_IO_PENDING, result); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); } // An extended header should also return ERR_IO_PENDING if it is not completely // received. TEST_F(WebSocketBasicStreamSocketTest, FragmentedLargeHeader) { MockRead reads[] = { MockRead(SYNCHRONOUS, kPartialLargeFrame, kLargeFrameHeaderSize - 1), MockRead(SYNCHRONOUS, ERR_IO_PENDING)}; CreateReadOnly(reads); EXPECT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); } // A frame that does not arrive in a single read should be broken into separate // frames. TEST_F(WebSocketBasicStreamSocketSingleReadTest, LargeFrameFirstChunk) { CreateRead(MockRead(SYNCHRONOUS, kPartialLargeFrame, kPartialLargeFrameSize)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_FALSE(frames_[0]->header.final); EXPECT_EQ(kPartialLargeFrameSize - kLargeFrameHeaderSize, static_cast<size_t>(frames_[0]->header.payload_length)); } // If only the header of a data frame arrives, we should receive a frame with a // zero-size payload. TEST_F(WebSocketBasicStreamSocketSingleReadTest, HeaderOnlyChunk) { CreateRead(MockRead(SYNCHRONOUS, kPartialLargeFrame, kLargeFrameHeaderSize)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(NULL, frames_[0]->data.get()); EXPECT_EQ(0U, frames_[0]->header.payload_length); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, frames_[0]->header.opcode); } // If the header and the body of a data frame arrive seperately, we should see // them as separate frames. TEST_F(WebSocketBasicStreamSocketTest, HeaderBodySeparated) { MockRead reads[] = { MockRead(SYNCHRONOUS, kPartialLargeFrame, kLargeFrameHeaderSize), MockRead(ASYNC, kPartialLargeFrame + kLargeFrameHeaderSize, kPartialLargeFrameSize - kLargeFrameHeaderSize)}; CreateReadOnly(reads); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(NULL, frames_[0]->data.get()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, frames_[0]->header.opcode); frames_.clear(); EXPECT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(kPartialLargeFrameSize - kLargeFrameHeaderSize, frames_[0]->header.payload_length); EXPECT_EQ(WebSocketFrameHeader::kOpCodeContinuation, frames_[0]->header.opcode); } // Every frame has a header with a correct payload_length field. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, LargeFrameTwoChunks) { const size_t kChunkSize = 16; CreateChunkedRead(ASYNC, kPartialLargeFrame, kPartialLargeFrameSize, kChunkSize, 2, LAST_FRAME_NOT_BIG); TestCompletionCallback cb[2]; ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[0].callback())); EXPECT_EQ(OK, cb[0].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(kChunkSize - kLargeFrameHeaderSize, frames_[0]->header.payload_length); frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[1].callback())); EXPECT_EQ(OK, cb[1].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(kChunkSize, frames_[0]->header.payload_length); } // Only the final frame of a fragmented message has |final| bit set. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, OnlyFinalChunkIsFinal) { static const size_t kFirstChunkSize = 4; CreateChunkedRead(ASYNC, kSampleFrame, kSampleFrameSize, kFirstChunkSize, 2, LAST_FRAME_BIG); TestCompletionCallback cb[2]; ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[0].callback())); EXPECT_EQ(OK, cb[0].WaitForResult()); ASSERT_EQ(1U, frames_.size()); ASSERT_FALSE(frames_[0]->header.final); frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[1].callback())); EXPECT_EQ(OK, cb[1].WaitForResult()); ASSERT_EQ(1U, frames_.size()); ASSERT_TRUE(frames_[0]->header.final); } // All frames after the first have their opcode changed to Continuation. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, ContinuationOpCodeUsed) { const size_t kFirstChunkSize = 3; const int kChunkCount = 3; // The input data is one frame with opcode Text, which arrives in three // separate chunks. CreateChunkedRead(ASYNC, kSampleFrame, kSampleFrameSize, kFirstChunkSize, kChunkCount, LAST_FRAME_BIG); TestCompletionCallback cb[kChunkCount]; ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[0].callback())); EXPECT_EQ(OK, cb[0].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, frames_[0]->header.opcode); // This test uses a loop to verify that the opcode for every frames generated // after the first is converted to Continuation. for (int i = 1; i < kChunkCount; ++i) { frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[i].callback())); EXPECT_EQ(OK, cb[i].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeContinuation, frames_[0]->header.opcode); } } // Multiple frames that arrive together should be parsed correctly. TEST_F(WebSocketBasicStreamSocketSingleReadTest, ThreeFramesTogether) { CreateRead(MockRead(SYNCHRONOUS, kMultipleFrames, kMultipleFramesSize)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(3U, frames_.size()); EXPECT_TRUE(frames_[0]->header.final); EXPECT_TRUE(frames_[1]->header.final); EXPECT_TRUE(frames_[2]->header.final); } // ERR_CONNECTION_CLOSED must be returned on close. TEST_F(WebSocketBasicStreamSocketSingleReadTest, SyncClose) { CreateRead(MockRead(SYNCHRONOUS, "", 0)); EXPECT_EQ(ERR_CONNECTION_CLOSED, stream_->ReadFrames(&frames_, cb_.callback())); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, AsyncClose) { CreateRead(MockRead(ASYNC, "", 0)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_CONNECTION_CLOSED, cb_.WaitForResult()); } // The result should be the same if the socket returns // ERR_CONNECTION_CLOSED. This is not expected to happen on an established // connection; a Read of size 0 is the expected behaviour. The key point of this // test is to confirm that ReadFrames() behaviour is identical in both cases. TEST_F(WebSocketBasicStreamSocketSingleReadTest, SyncCloseWithErr) { CreateRead(MockRead(SYNCHRONOUS, ERR_CONNECTION_CLOSED)); EXPECT_EQ(ERR_CONNECTION_CLOSED, stream_->ReadFrames(&frames_, cb_.callback())); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, AsyncCloseWithErr) { CreateRead(MockRead(ASYNC, ERR_CONNECTION_CLOSED)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_CONNECTION_CLOSED, cb_.WaitForResult()); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, SyncErrorsPassedThrough) { // ERR_INSUFFICIENT_RESOURCES here represents an arbitrary error that // WebSocketBasicStream gives no special handling to. CreateRead(MockRead(SYNCHRONOUS, ERR_INSUFFICIENT_RESOURCES)); EXPECT_EQ(ERR_INSUFFICIENT_RESOURCES, stream_->ReadFrames(&frames_, cb_.callback())); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, AsyncErrorsPassedThrough) { CreateRead(MockRead(ASYNC, ERR_INSUFFICIENT_RESOURCES)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_INSUFFICIENT_RESOURCES, cb_.WaitForResult()); } // If we get a frame followed by a close, we should receive them separately. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, CloseAfterFrame) { // The chunk size equals the data size, so the second chunk is 0 size, closing // the connection. CreateChunkedRead(SYNCHRONOUS, kSampleFrame, kSampleFrameSize, kSampleFrameSize, 2, LAST_FRAME_NOT_BIG); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(1U, frames_.size()); frames_.clear(); EXPECT_EQ(ERR_CONNECTION_CLOSED, stream_->ReadFrames(&frames_, cb_.callback())); } // Synchronous close after an async frame header is handled by a different code // path. TEST_F(WebSocketBasicStreamSocketTest, AsyncCloseAfterIncompleteHeader) { MockRead reads[] = {MockRead(ASYNC, kSampleFrame, 1U), MockRead(SYNCHRONOUS, "", 0)}; CreateReadOnly(reads); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_CONNECTION_CLOSED, cb_.WaitForResult()); } // When Stream::Read returns ERR_CONNECTION_CLOSED we get the same result via a // slightly different code path. TEST_F(WebSocketBasicStreamSocketTest, AsyncErrCloseAfterIncompleteHeader) { MockRead reads[] = {MockRead(ASYNC, kSampleFrame, 1U), MockRead(SYNCHRONOUS, ERR_CONNECTION_CLOSED)}; CreateReadOnly(reads); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_CONNECTION_CLOSED, cb_.WaitForResult()); } // An empty first frame is not ignored. TEST_F(WebSocketBasicStreamSocketSingleReadTest, EmptyFirstFrame) { CreateRead(MockRead(SYNCHRONOUS, kEmptyFirstFrame, kEmptyFirstFrameSize)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(NULL, frames_[0]->data.get()); EXPECT_EQ(0U, frames_[0]->header.payload_length); } // An empty frame in the middle of a message is ignored. TEST_F(WebSocketBasicStreamSocketTest, EmptyMiddleFrame) { MockRead reads[] = { MockRead(SYNCHRONOUS, kEmptyFirstFrame, kEmptyFirstFrameSize), MockRead(SYNCHRONOUS, kEmptyMiddleFrame, kEmptyMiddleFrameSize), MockRead(SYNCHRONOUS, ERR_IO_PENDING)}; CreateReadOnly(reads); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(1U, frames_.size()); frames_.clear(); EXPECT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); } // An empty frame in the middle of a message that arrives separately is still // ignored. TEST_F(WebSocketBasicStreamSocketTest, EmptyMiddleFrameAsync) { MockRead reads[] = { MockRead(SYNCHRONOUS, kEmptyFirstFrame, kEmptyFirstFrameSize), MockRead(ASYNC, kEmptyMiddleFrame, kEmptyMiddleFrameSize), // We include a pong message to verify the middle frame was actually // processed. MockRead(ASYNC, kValidPong, kValidPongSize)}; CreateReadOnly(reads); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(1U, frames_.size()); frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodePong, frames_[0]->header.opcode); } // An empty final frame is not ignored. TEST_F(WebSocketBasicStreamSocketSingleReadTest, EmptyFinalFrame) { CreateRead( MockRead(SYNCHRONOUS, kEmptyFinalTextFrame, kEmptyFinalTextFrameSize)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(NULL, frames_[0]->data.get()); EXPECT_EQ(0U, frames_[0]->header.payload_length); } // An empty middle frame is ignored with a final frame present. TEST_F(WebSocketBasicStreamSocketTest, ThreeFrameEmptyMessage) { MockRead reads[] = { MockRead(SYNCHRONOUS, kEmptyFirstFrame, kEmptyFirstFrameSize), MockRead(SYNCHRONOUS, kEmptyMiddleFrame, kEmptyMiddleFrameSize), MockRead(SYNCHRONOUS, kEmptyFinalContinuationFrame, kEmptyFinalContinuationFrameSize)}; CreateReadOnly(reads); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, frames_[0]->header.opcode); frames_.clear(); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_TRUE(frames_[0]->header.final); } // If there was a frame read at the same time as the response headers (and the // handshake succeeded), then we should parse it. TEST_F(WebSocketBasicStreamSocketTest, HttpReadBufferIsUsed) { SetHttpReadBuffer(kSampleFrame, kSampleFrameSize); CreateNullStream(); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); ASSERT_TRUE(frames_[0]->data.get()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); } // Check that a frame whose header partially arrived at the end of the response // headers works correctly. TEST_F(WebSocketBasicStreamSocketSingleReadTest, PartialFrameHeaderInHttpResponse) { SetHttpReadBuffer(kSampleFrame, 1); CreateRead(MockRead(ASYNC, kSampleFrame + 1, kSampleFrameSize - 1)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); ASSERT_TRUE(frames_[0]->data.get()); EXPECT_EQ(GG_UINT64_C(6), frames_[0]->header.payload_length); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, frames_[0]->header.opcode); } // Check that a control frame which partially arrives at the end of the response // headers works correctly. TEST_F(WebSocketBasicStreamSocketSingleReadTest, PartialControlFrameInHttpResponse) { const size_t kPartialFrameBytes = 3; SetHttpReadBuffer(kCloseFrame, kPartialFrameBytes); CreateRead(MockRead(ASYNC, kCloseFrame + kPartialFrameBytes, kCloseFrameSize - kPartialFrameBytes)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeClose, frames_[0]->header.opcode); EXPECT_EQ(kCloseFrameSize - 2, frames_[0]->header.payload_length); EXPECT_EQ( 0, memcmp(frames_[0]->data->data(), kCloseFrame + 2, kCloseFrameSize - 2)); } // Check that a control frame which partially arrives at the end of the response // headers works correctly. Synchronous version (unlikely in practice). TEST_F(WebSocketBasicStreamSocketSingleReadTest, PartialControlFrameInHttpResponseSync) { const size_t kPartialFrameBytes = 3; SetHttpReadBuffer(kCloseFrame, kPartialFrameBytes); CreateRead(MockRead(SYNCHRONOUS, kCloseFrame + kPartialFrameBytes, kCloseFrameSize - kPartialFrameBytes)); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeClose, frames_[0]->header.opcode); } // Check that an invalid frame results in an error. TEST_F(WebSocketBasicStreamSocketSingleReadTest, SyncInvalidFrame) { CreateRead(MockRead(SYNCHRONOUS, kInvalidFrame, kInvalidFrameSize)); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, stream_->ReadFrames(&frames_, cb_.callback())); } TEST_F(WebSocketBasicStreamSocketSingleReadTest, AsyncInvalidFrame) { CreateRead(MockRead(ASYNC, kInvalidFrame, kInvalidFrameSize)); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, cb_.WaitForResult()); } // A control frame without a FIN flag is invalid and should not be passed // through to higher layers. RFC6455 5.5 "All control frames ... MUST NOT be // fragmented." TEST_F(WebSocketBasicStreamSocketSingleReadTest, ControlFrameWithoutFin) { CreateRead( MockRead(SYNCHRONOUS, kPingFrameWithoutFin, kPingFrameWithoutFinSize)); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_TRUE(frames_.empty()); } // A control frame over 125 characters is invalid. RFC6455 5.5 "All control // frames MUST have a payload length of 125 bytes or less". Since we use a // 125-byte buffer to assemble fragmented control frames, we need to detect this // error before attempting to assemble the fragments. TEST_F(WebSocketBasicStreamSocketSingleReadTest, OverlongControlFrame) { CreateRead(MockRead(SYNCHRONOUS, k126BytePong, k126BytePongSize)); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_TRUE(frames_.empty()); } // A control frame over 125 characters should still be rejected if it is split // into multiple chunks. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, SplitOverlongControlFrame) { const size_t kFirstChunkSize = 16; expect_all_io_to_complete_ = false; CreateChunkedRead(SYNCHRONOUS, k126BytePong, k126BytePongSize, kFirstChunkSize, 2, LAST_FRAME_BIG); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_TRUE(frames_.empty()); } TEST_F(WebSocketBasicStreamSocketChunkedReadTest, AsyncSplitOverlongControlFrame) { const size_t kFirstChunkSize = 16; expect_all_io_to_complete_ = false; CreateChunkedRead(ASYNC, k126BytePong, k126BytePongSize, kFirstChunkSize, 2, LAST_FRAME_BIG); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(ERR_WS_PROTOCOL_ERROR, cb_.WaitForResult()); // The caller should not call ReadFrames() again after receiving an error // other than ERR_IO_PENDING. EXPECT_TRUE(frames_.empty()); } // In the synchronous case, ReadFrames assembles the whole control frame before // returning. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, SyncControlFrameAssembly) { const size_t kChunkSize = 3; CreateChunkedRead( SYNCHRONOUS, kCloseFrame, kCloseFrameSize, kChunkSize, 3, LAST_FRAME_BIG); EXPECT_EQ(OK, stream_->ReadFrames(&frames_, cb_.callback())); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeClose, frames_[0]->header.opcode); } // In the asynchronous case, the callback is not called until the control frame // has been completely assembled. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, AsyncControlFrameAssembly) { const size_t kChunkSize = 3; CreateChunkedRead( ASYNC, kCloseFrame, kCloseFrameSize, kChunkSize, 3, LAST_FRAME_BIG); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_EQ(WebSocketFrameHeader::kOpCodeClose, frames_[0]->header.opcode); } // A frame with a 1MB payload that has to be read in chunks. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, OneMegFrame) { // This should be equal to the definition of kReadBufferSize in // websocket_basic_stream.cc. const int kReadBufferSize = 32 * 1024; const uint64 kPayloadSize = 1 << 20; const size_t kWireSize = kPayloadSize + kLargeFrameHeaderSize; const size_t kExpectedFrameCount = (kWireSize + kReadBufferSize - 1) / kReadBufferSize; scoped_ptr<char[]> big_frame(new char[kWireSize]); memcpy(big_frame.get(), "\x81\x7F", 2); base::WriteBigEndian(big_frame.get() + 2, kPayloadSize); memset(big_frame.get() + kLargeFrameHeaderSize, 'A', kPayloadSize); CreateChunkedRead(ASYNC, big_frame.get(), kWireSize, kReadBufferSize, kExpectedFrameCount, LAST_FRAME_BIG); for (size_t frame = 0; frame < kExpectedFrameCount; ++frame) { frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); ASSERT_EQ(1U, frames_.size()); size_t expected_payload_size = kReadBufferSize; if (frame == 0) { expected_payload_size = kReadBufferSize - kLargeFrameHeaderSize; } else if (frame == kExpectedFrameCount - 1) { expected_payload_size = kLargeFrameHeaderSize; } EXPECT_EQ(expected_payload_size, frames_[0]->header.payload_length); } } // A frame with reserved flag(s) set that arrives in chunks should only have the // reserved flag(s) set on the first chunk when split. TEST_F(WebSocketBasicStreamSocketChunkedReadTest, ReservedFlagCleared) { static const char kReservedFlagFrame[] = "\x41\x05Hello"; const size_t kReservedFlagFrameSize = arraysize(kReservedFlagFrame) - 1; const size_t kChunkSize = 5; CreateChunkedRead(ASYNC, kReservedFlagFrame, kReservedFlagFrameSize, kChunkSize, 2, LAST_FRAME_BIG); TestCompletionCallback cb[2]; ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[0].callback())); EXPECT_EQ(OK, cb[0].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_TRUE(frames_[0]->header.reserved1); frames_.clear(); ASSERT_EQ(ERR_IO_PENDING, stream_->ReadFrames(&frames_, cb[1].callback())); EXPECT_EQ(OK, cb[1].WaitForResult()); ASSERT_EQ(1U, frames_.size()); EXPECT_FALSE(frames_[0]->header.reserved1); } // Check that writing a frame all at once works. TEST_F(WebSocketBasicStreamSocketWriteTest, WriteAtOnce) { MockWrite writes[] = {MockWrite(SYNCHRONOUS, kWriteFrame, kWriteFrameSize)}; CreateWriteOnly(writes); EXPECT_EQ(OK, stream_->WriteFrames(&frames_, cb_.callback())); } // Check that completely async writing works. TEST_F(WebSocketBasicStreamSocketWriteTest, AsyncWriteAtOnce) { MockWrite writes[] = {MockWrite(ASYNC, kWriteFrame, kWriteFrameSize)}; CreateWriteOnly(writes); ASSERT_EQ(ERR_IO_PENDING, stream_->WriteFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); } // Check that writing a frame to an extremely full kernel buffer (so that it // ends up being sent in bits) works. The WriteFrames() callback should not be // called until all parts have been written. TEST_F(WebSocketBasicStreamSocketWriteTest, WriteInBits) { MockWrite writes[] = {MockWrite(SYNCHRONOUS, kWriteFrame, 4), MockWrite(ASYNC, kWriteFrame + 4, 4), MockWrite(ASYNC, kWriteFrame + 8, kWriteFrameSize - 8)}; CreateWriteOnly(writes); ASSERT_EQ(ERR_IO_PENDING, stream_->WriteFrames(&frames_, cb_.callback())); EXPECT_EQ(OK, cb_.WaitForResult()); } // Check that writing a Pong frame with a NULL body works. TEST_F(WebSocketBasicStreamSocketWriteTest, WriteNullPong) { MockWrite writes[] = { MockWrite(SYNCHRONOUS, kMaskedEmptyPong, kMaskedEmptyPongSize)}; CreateWriteOnly(writes); scoped_ptr<WebSocketFrame> frame( new WebSocketFrame(WebSocketFrameHeader::kOpCodePong)); WebSocketFrameHeader& header = frame->header; header.final = true; header.masked = true; header.payload_length = 0; ScopedVector<WebSocketFrame> frames; frames.push_back(frame.release()); EXPECT_EQ(OK, stream_->WriteFrames(&frames, cb_.callback())); } // Check that writing with a non-NULL mask works correctly. TEST_F(WebSocketBasicStreamSocketTest, WriteNonNulMask) { std::string masked_frame = std::string("\x81\x88"); masked_frame += std::string(kNonNulMaskingKey.key, 4); masked_frame += "jiggered"; MockWrite writes[] = { MockWrite(SYNCHRONOUS, masked_frame.data(), masked_frame.size())}; generator_ = &GenerateNonNulMaskingKey; CreateStream(NULL, 0, writes, arraysize(writes)); scoped_ptr<WebSocketFrame> frame( new WebSocketFrame(WebSocketFrameHeader::kOpCodeText)); const std::string unmasked_payload = "graphics"; const size_t payload_size = unmasked_payload.size(); frame->data = new IOBuffer(payload_size); memcpy(frame->data->data(), unmasked_payload.data(), payload_size); WebSocketFrameHeader& header = frame->header; header.final = true; header.masked = true; header.payload_length = payload_size; frames_.push_back(frame.release()); EXPECT_EQ(OK, stream_->WriteFrames(&frames_, cb_.callback())); } TEST_F(WebSocketBasicStreamSocketTest, GetExtensionsWorks) { extensions_ = "inflate-uuencode"; CreateNullStream(); EXPECT_EQ("inflate-uuencode", stream_->GetExtensions()); } TEST_F(WebSocketBasicStreamSocketTest, GetSubProtocolWorks) { sub_protocol_ = "cyberchat"; CreateNullStream(); EXPECT_EQ("cyberchat", stream_->GetSubProtocol()); } } // namespace } // namespace net