// 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/http/http_stream_parser.h" #include #include #include #include "base/file_util.h" #include "base/files/file_path.h" #include "base/files/scoped_temp_dir.h" #include "base/memory/ref_counted.h" #include "base/run_loop.h" #include "base/strings/string_piece.h" #include "base/strings/stringprintf.h" #include "net/base/io_buffer.h" #include "net/base/net_errors.h" #include "net/base/test_completion_callback.h" #include "net/base/upload_bytes_element_reader.h" #include "net/base/upload_data_stream.h" #include "net/base/upload_file_element_reader.h" #include "net/http/http_request_headers.h" #include "net/http/http_request_info.h" #include "net/http/http_response_headers.h" #include "net/http/http_response_info.h" #include "net/socket/client_socket_handle.h" #include "net/socket/socket_test_util.h" #include "testing/gtest/include/gtest/gtest.h" #include "url/gurl.h" namespace net { namespace { const size_t kOutputSize = 1024; // Just large enough for this test. // The number of bytes that can fit in a buffer of kOutputSize. const size_t kMaxPayloadSize = kOutputSize - HttpStreamParser::kChunkHeaderFooterSize; // The empty payload is how the last chunk is encoded. TEST(HttpStreamParser, EncodeChunk_EmptyPayload) { char output[kOutputSize]; const base::StringPiece kPayload = ""; const base::StringPiece kExpected = "0\r\n\r\n"; const int num_bytes_written = HttpStreamParser::EncodeChunk(kPayload, output, sizeof(output)); ASSERT_EQ(kExpected.size(), static_cast(num_bytes_written)); EXPECT_EQ(kExpected, base::StringPiece(output, num_bytes_written)); } TEST(HttpStreamParser, EncodeChunk_ShortPayload) { char output[kOutputSize]; const std::string kPayload("foo\x00\x11\x22", 6); // 11 = payload size + sizeof("6") + CRLF x 2. const std::string kExpected("6\r\nfoo\x00\x11\x22\r\n", 11); const int num_bytes_written = HttpStreamParser::EncodeChunk(kPayload, output, sizeof(output)); ASSERT_EQ(kExpected.size(), static_cast(num_bytes_written)); EXPECT_EQ(kExpected, base::StringPiece(output, num_bytes_written)); } TEST(HttpStreamParser, EncodeChunk_LargePayload) { char output[kOutputSize]; const std::string kPayload(1000, '\xff'); // '\xff' x 1000. // 3E8 = 1000 in hex. const std::string kExpected = "3E8\r\n" + kPayload + "\r\n"; const int num_bytes_written = HttpStreamParser::EncodeChunk(kPayload, output, sizeof(output)); ASSERT_EQ(kExpected.size(), static_cast(num_bytes_written)); EXPECT_EQ(kExpected, base::StringPiece(output, num_bytes_written)); } TEST(HttpStreamParser, EncodeChunk_FullPayload) { char output[kOutputSize]; const std::string kPayload(kMaxPayloadSize, '\xff'); // 3F4 = 1012 in hex. const std::string kExpected = "3F4\r\n" + kPayload + "\r\n"; const int num_bytes_written = HttpStreamParser::EncodeChunk(kPayload, output, sizeof(output)); ASSERT_EQ(kExpected.size(), static_cast(num_bytes_written)); EXPECT_EQ(kExpected, base::StringPiece(output, num_bytes_written)); } TEST(HttpStreamParser, EncodeChunk_TooLargePayload) { char output[kOutputSize]; // The payload is one byte larger the output buffer size. const std::string kPayload(kMaxPayloadSize + 1, '\xff'); const int num_bytes_written = HttpStreamParser::EncodeChunk(kPayload, output, sizeof(output)); ASSERT_EQ(ERR_INVALID_ARGUMENT, num_bytes_written); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_NoBody) { // Shouldn't be merged if upload data is non-existent. ASSERT_FALSE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", NULL)); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_EmptyBody) { ScopedVector element_readers; scoped_ptr body( new UploadDataStream(element_readers.Pass(), 0)); ASSERT_EQ(OK, body->Init(CompletionCallback())); // Shouldn't be merged if upload data is empty. ASSERT_FALSE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", body.get())); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_ChunkedBody) { const std::string payload = "123"; scoped_ptr body( new UploadDataStream(UploadDataStream::CHUNKED, 0)); body->AppendChunk(payload.data(), payload.size(), true); ASSERT_EQ(OK, body->Init(CompletionCallback())); // Shouldn't be merged if upload data carries chunked data. ASSERT_FALSE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", body.get())); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_FileBody) { { ScopedVector element_readers; // Create an empty temporary file. base::ScopedTempDir temp_dir; ASSERT_TRUE(temp_dir.CreateUniqueTempDir()); base::FilePath temp_file_path; ASSERT_TRUE(base::CreateTemporaryFileInDir(temp_dir.path(), &temp_file_path)); element_readers.push_back( new UploadFileElementReader(base::MessageLoopProxy::current().get(), temp_file_path, 0, 0, base::Time())); scoped_ptr body( new UploadDataStream(element_readers.Pass(), 0)); TestCompletionCallback callback; ASSERT_EQ(ERR_IO_PENDING, body->Init(callback.callback())); ASSERT_EQ(OK, callback.WaitForResult()); // Shouldn't be merged if upload data carries a file, as it's not in-memory. ASSERT_FALSE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", body.get())); } // UploadFileElementReaders may post clean-up tasks on destruction. base::RunLoop().RunUntilIdle(); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_SmallBodyInMemory) { ScopedVector element_readers; const std::string payload = "123"; element_readers.push_back(new UploadBytesElementReader( payload.data(), payload.size())); scoped_ptr body( new UploadDataStream(element_readers.Pass(), 0)); ASSERT_EQ(OK, body->Init(CompletionCallback())); // Yes, should be merged if the in-memory body is small here. ASSERT_TRUE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", body.get())); } TEST(HttpStreamParser, ShouldMergeRequestHeadersAndBody_LargeBodyInMemory) { ScopedVector element_readers; const std::string payload(10000, 'a'); // 'a' x 10000. element_readers.push_back(new UploadBytesElementReader( payload.data(), payload.size())); scoped_ptr body( new UploadDataStream(element_readers.Pass(), 0)); ASSERT_EQ(OK, body->Init(CompletionCallback())); // Shouldn't be merged if the in-memory body is large here. ASSERT_FALSE(HttpStreamParser::ShouldMergeRequestHeadersAndBody( "some header", body.get())); } // Test to ensure the HttpStreamParser state machine does not get confused // when sending a request with a chunked body, where chunks become available // asynchronously, over a socket where writes may also complete // asynchronously. // This is a regression test for http://crbug.com/132243 TEST(HttpStreamParser, AsyncChunkAndAsyncSocket) { // The chunks that will be written in the request, as reflected in the // MockWrites below. static const char kChunk1[] = "Chunk 1"; static const char kChunk2[] = "Chunky 2"; static const char kChunk3[] = "Test 3"; MockWrite writes[] = { MockWrite(ASYNC, 0, "GET /one.html HTTP/1.1\r\n" "Host: localhost\r\n" "Transfer-Encoding: chunked\r\n" "Connection: keep-alive\r\n\r\n"), MockWrite(ASYNC, 1, "7\r\nChunk 1\r\n"), MockWrite(ASYNC, 2, "8\r\nChunky 2\r\n"), MockWrite(ASYNC, 3, "6\r\nTest 3\r\n"), MockWrite(ASYNC, 4, "0\r\n\r\n"), }; // The size of the response body, as reflected in the Content-Length of the // MockRead below. static const int kBodySize = 8; MockRead reads[] = { MockRead(ASYNC, 5, "HTTP/1.1 200 OK\r\n"), MockRead(ASYNC, 6, "Content-Length: 8\r\n\r\n"), MockRead(ASYNC, 7, "one.html"), MockRead(SYNCHRONOUS, 0, 8), // EOF }; UploadDataStream upload_stream(UploadDataStream::CHUNKED, 0); upload_stream.AppendChunk(kChunk1, arraysize(kChunk1) - 1, false); ASSERT_EQ(OK, upload_stream.Init(CompletionCallback())); DeterministicSocketData data(reads, arraysize(reads), writes, arraysize(writes)); data.set_connect_data(MockConnect(SYNCHRONOUS, OK)); scoped_ptr transport( new DeterministicMockTCPClientSocket(NULL, &data)); data.set_delegate(transport->AsWeakPtr()); TestCompletionCallback callback; int rv = transport->Connect(callback.callback()); rv = callback.GetResult(rv); ASSERT_EQ(OK, rv); scoped_ptr socket_handle(new ClientSocketHandle); socket_handle->SetSocket(transport.PassAs()); HttpRequestInfo request_info; request_info.method = "GET"; request_info.url = GURL("http://localhost"); request_info.load_flags = LOAD_NORMAL; request_info.upload_data_stream = &upload_stream; scoped_refptr read_buffer(new GrowableIOBuffer); HttpStreamParser parser( socket_handle.get(), &request_info, read_buffer.get(), BoundNetLog()); HttpRequestHeaders request_headers; request_headers.SetHeader("Host", "localhost"); request_headers.SetHeader("Transfer-Encoding", "chunked"); request_headers.SetHeader("Connection", "keep-alive"); HttpResponseInfo response_info; // This will attempt to Write() the initial request and headers, which will // complete asynchronously. rv = parser.SendRequest("GET /one.html HTTP/1.1\r\n", request_headers, &response_info, callback.callback()); ASSERT_EQ(ERR_IO_PENDING, rv); // Complete the initial request write. Additionally, this should enqueue the // first chunk. data.RunFor(1); ASSERT_FALSE(callback.have_result()); // Now append another chunk (while the first write is still pending), which // should not confuse the state machine. upload_stream.AppendChunk(kChunk2, arraysize(kChunk2) - 1, false); ASSERT_FALSE(callback.have_result()); // Complete writing the first chunk, which should then enqueue the second // chunk for writing and return, because it is set to complete // asynchronously. data.RunFor(1); ASSERT_FALSE(callback.have_result()); // Complete writing the second chunk. However, because no chunks are // available yet, no further writes should be called until a new chunk is // added. data.RunFor(1); ASSERT_FALSE(callback.have_result()); // Add the final chunk. This will enqueue another write, but it will not // complete due to the async nature. upload_stream.AppendChunk(kChunk3, arraysize(kChunk3) - 1, true); ASSERT_FALSE(callback.have_result()); // Finalize writing the last chunk, which will enqueue the trailer. data.RunFor(1); ASSERT_FALSE(callback.have_result()); // Finalize writing the trailer. data.RunFor(1); ASSERT_TRUE(callback.have_result()); // Warning: This will hang if the callback doesn't already have a result, // due to the deterministic socket provider. Do not remove the above // ASSERT_TRUE, which will avoid this hang. rv = callback.WaitForResult(); ASSERT_EQ(OK, rv); // Attempt to read the response status and the response headers. rv = parser.ReadResponseHeaders(callback.callback()); ASSERT_EQ(ERR_IO_PENDING, rv); data.RunFor(2); ASSERT_TRUE(callback.have_result()); rv = callback.WaitForResult(); ASSERT_GT(rv, 0); // Finally, attempt to read the response body. scoped_refptr body_buffer(new IOBuffer(kBodySize)); rv = parser.ReadResponseBody( body_buffer.get(), kBodySize, callback.callback()); ASSERT_EQ(ERR_IO_PENDING, rv); data.RunFor(1); ASSERT_TRUE(callback.have_result()); rv = callback.WaitForResult(); ASSERT_EQ(kBodySize, rv); } TEST(HttpStreamParser, TruncatedHeaders) { MockRead truncated_status_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 20"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead truncated_after_status_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 200 Ok\r\n"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead truncated_in_header_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 200 Ok\r\nHead"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead truncated_after_header_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 200 Ok\r\nHeader: foo\r\n"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead truncated_after_final_newline_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 200 Ok\r\nHeader: foo\r\n\r"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead not_truncated_reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 200 Ok\r\nHeader: foo\r\n\r\n"), MockRead(SYNCHRONOUS, 0, 2), // EOF }; MockRead* reads[] = { truncated_status_reads, truncated_after_status_reads, truncated_in_header_reads, truncated_after_header_reads, truncated_after_final_newline_reads, not_truncated_reads, }; MockWrite writes[] = { MockWrite(SYNCHRONOUS, 0, "GET / HTTP/1.1\r\n\r\n"), }; enum { HTTP = 0, HTTPS, NUM_PROTOCOLS, }; for (size_t protocol = 0; protocol < NUM_PROTOCOLS; protocol++) { SCOPED_TRACE(protocol); for (size_t i = 0; i < arraysize(reads); i++) { SCOPED_TRACE(i); DeterministicSocketData data(reads[i], 2, writes, arraysize(writes)); data.set_connect_data(MockConnect(SYNCHRONOUS, OK)); data.SetStop(3); scoped_ptr transport( new DeterministicMockTCPClientSocket(NULL, &data)); data.set_delegate(transport->AsWeakPtr()); TestCompletionCallback callback; int rv = transport->Connect(callback.callback()); rv = callback.GetResult(rv); ASSERT_EQ(OK, rv); scoped_ptr socket_handle(new ClientSocketHandle); socket_handle->SetSocket(transport.PassAs()); HttpRequestInfo request_info; request_info.method = "GET"; if (protocol == HTTP) { request_info.url = GURL("http://localhost"); } else { request_info.url = GURL("https://localhost"); } request_info.load_flags = LOAD_NORMAL; scoped_refptr read_buffer(new GrowableIOBuffer); HttpStreamParser parser( socket_handle.get(), &request_info, read_buffer.get(), BoundNetLog()); HttpRequestHeaders request_headers; HttpResponseInfo response_info; rv = parser.SendRequest("GET / HTTP/1.1\r\n", request_headers, &response_info, callback.callback()); ASSERT_EQ(OK, rv); rv = parser.ReadResponseHeaders(callback.callback()); if (i == arraysize(reads) - 1) { EXPECT_EQ(OK, rv); EXPECT_TRUE(response_info.headers.get()); } else { if (protocol == HTTP) { EXPECT_EQ(ERR_CONNECTION_CLOSED, rv); EXPECT_TRUE(response_info.headers.get()); } else { EXPECT_EQ(ERR_RESPONSE_HEADERS_TRUNCATED, rv); EXPECT_FALSE(response_info.headers.get()); } } } } } // Confirm that on 101 response, the headers are parsed but the data that // follows remains in the buffer. TEST(HttpStreamParser, Websocket101Response) { MockRead reads[] = { MockRead(SYNCHRONOUS, 1, "HTTP/1.1 101 Switching Protocols\r\n" "Upgrade: websocket\r\n" "Connection: Upgrade\r\n" "\r\n" "a fake websocket frame"), }; MockWrite writes[] = { MockWrite(SYNCHRONOUS, 0, "GET / HTTP/1.1\r\n\r\n"), }; DeterministicSocketData data(reads, arraysize(reads), writes, arraysize(writes)); data.set_connect_data(MockConnect(SYNCHRONOUS, OK)); data.SetStop(2); scoped_ptr transport( new DeterministicMockTCPClientSocket(NULL, &data)); data.set_delegate(transport->AsWeakPtr()); TestCompletionCallback callback; int rv = transport->Connect(callback.callback()); rv = callback.GetResult(rv); ASSERT_EQ(OK, rv); scoped_ptr socket_handle(new ClientSocketHandle); socket_handle->SetSocket(transport.PassAs()); HttpRequestInfo request_info; request_info.method = "GET"; request_info.url = GURL("http://localhost"); request_info.load_flags = LOAD_NORMAL; scoped_refptr read_buffer(new GrowableIOBuffer); HttpStreamParser parser( socket_handle.get(), &request_info, read_buffer.get(), BoundNetLog()); HttpRequestHeaders request_headers; HttpResponseInfo response_info; rv = parser.SendRequest("GET / HTTP/1.1\r\n", request_headers, &response_info, callback.callback()); ASSERT_EQ(OK, rv); rv = parser.ReadResponseHeaders(callback.callback()); EXPECT_EQ(OK, rv); ASSERT_TRUE(response_info.headers.get()); EXPECT_EQ(101, response_info.headers->response_code()); EXPECT_TRUE(response_info.headers->HasHeaderValue("Connection", "Upgrade")); EXPECT_TRUE(response_info.headers->HasHeaderValue("Upgrade", "websocket")); EXPECT_EQ(read_buffer->capacity(), read_buffer->offset()); EXPECT_EQ("a fake websocket frame", base::StringPiece(read_buffer->StartOfBuffer(), read_buffer->capacity())); } // Helper class for constructing HttpStreamParser and running GET requests. class SimpleGetRunner { public: SimpleGetRunner() : read_buffer_(new GrowableIOBuffer), sequence_number_(0) { writes_.push_back(MockWrite( SYNCHRONOUS, sequence_number_++, "GET / HTTP/1.1\r\n\r\n")); } HttpStreamParser* parser() { return parser_.get(); } GrowableIOBuffer* read_buffer() { return read_buffer_.get(); } HttpResponseInfo* response_info() { return &response_info_; } void AddInitialData(const std::string& data) { int offset = read_buffer_->offset(); int size = data.size(); read_buffer_->SetCapacity(offset + size); memcpy(read_buffer_->StartOfBuffer() + offset, data.data(), size); read_buffer_->set_offset(offset + size); } void AddRead(const std::string& data) { reads_.push_back(MockRead(SYNCHRONOUS, sequence_number_++, data.data())); } void SetupParserAndSendRequest() { reads_.push_back(MockRead(SYNCHRONOUS, 0, sequence_number_++)); // EOF socket_handle_.reset(new ClientSocketHandle); data_.reset(new DeterministicSocketData( &reads_.front(), reads_.size(), &writes_.front(), writes_.size())); data_->set_connect_data(MockConnect(SYNCHRONOUS, OK)); data_->SetStop(reads_.size() + writes_.size()); transport_.reset(new DeterministicMockTCPClientSocket(NULL, data_.get())); data_->set_delegate(transport_->AsWeakPtr()); TestCompletionCallback callback; int rv = transport_->Connect(callback.callback()); rv = callback.GetResult(rv); ASSERT_EQ(OK, rv); socket_handle_->SetSocket(transport_.PassAs()); request_info_.method = "GET"; request_info_.url = GURL("http://localhost"); request_info_.load_flags = LOAD_NORMAL; parser_.reset(new HttpStreamParser( socket_handle_.get(), &request_info_, read_buffer(), BoundNetLog())); rv = parser_->SendRequest("GET / HTTP/1.1\r\n", request_headers_, &response_info_, callback.callback()); ASSERT_EQ(OK, rv); } void ReadHeaders() { TestCompletionCallback callback; EXPECT_EQ(OK, parser_->ReadResponseHeaders(callback.callback())); } void ReadBody(int user_buf_len, int* read_lengths) { TestCompletionCallback callback; scoped_refptr buffer = new IOBuffer(user_buf_len); int rv; int i = 0; while (true) { rv = parser_->ReadResponseBody(buffer, user_buf_len, callback.callback()); EXPECT_EQ(read_lengths[i], rv); i++; if (rv <= 0) return; } } private: HttpRequestHeaders request_headers_; HttpResponseInfo response_info_; HttpRequestInfo request_info_; scoped_refptr read_buffer_; std::vector reads_; std::vector writes_; scoped_ptr socket_handle_; scoped_ptr data_; scoped_ptr transport_; scoped_ptr parser_; int sequence_number_; }; // Test that HTTP/0.9 response size is correctly calculated. TEST(HttpStreamParser, ReceivedBytesNoHeaders) { std::string response = "hello\r\nworld\r\n"; SimpleGetRunner get_runner; get_runner.AddRead(response); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); EXPECT_EQ(0, get_runner.parser()->received_bytes()); int response_size = response.size(); int read_lengths[] = {response_size, 0}; get_runner.ReadBody(response_size, read_lengths); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); } // Test basic case where there is no keep-alive or extra data from the socket, // and the entire response is received in a single read. TEST(HttpStreamParser, ReceivedBytesNormal) { std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 7\r\n\r\n"; std::string body = "content"; std::string response = headers + body; SimpleGetRunner get_runner; get_runner.AddRead(response); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); int64 headers_size = headers.size(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int body_size = body.size(); int read_lengths[] = {body_size, 0}; get_runner.ReadBody(body_size, read_lengths); int64 response_size = response.size(); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); } // Test that bytes that represent "next" response are not counted // as current response "received_bytes". TEST(HttpStreamParser, ReceivedBytesExcludesNextResponse) { std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 8\r\n\r\n"; std::string body = "content8"; std::string response = headers + body; std::string next_response = "HTTP/1.1 200 OK\r\n\r\nFOO"; std::string data = response + next_response; SimpleGetRunner get_runner; get_runner.AddRead(data); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); EXPECT_EQ(39, get_runner.parser()->received_bytes()); int64 headers_size = headers.size(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int body_size = body.size(); int read_lengths[] = {body_size, 0}; get_runner.ReadBody(body_size, read_lengths); int64 response_size = response.size(); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); int64 next_response_size = next_response.size(); EXPECT_EQ(next_response_size, get_runner.read_buffer()->offset()); } // Test that "received_bytes" calculation works fine when last read // contains more data than requested by user. // We send data in two reads: // 1) Headers + beginning of response // 2) remaining part of response + next response start // We setup user read buffer so it fully accepts the beginnig of response // body, but it is larger that remaining part of body. TEST(HttpStreamParser, ReceivedBytesMultiReadExcludesNextResponse) { std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 36\r\n\r\n"; int64 user_buf_len = 32; std::string body_start = std::string(user_buf_len, '#'); int body_start_size = body_start.size(); EXPECT_EQ(user_buf_len, body_start_size); std::string response_start = headers + body_start; std::string body_end = "abcd"; std::string next_response = "HTTP/1.1 200 OK\r\n\r\nFOO"; std::string response_end = body_end + next_response; SimpleGetRunner get_runner; get_runner.AddRead(response_start); get_runner.AddRead(response_end); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); int64 headers_size = headers.size(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int body_end_size = body_end.size(); int read_lengths[] = {body_start_size, body_end_size, 0}; get_runner.ReadBody(body_start_size, read_lengths); int64 response_size = response_start.size() + body_end_size; EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); int64 next_response_size = next_response.size(); EXPECT_EQ(next_response_size, get_runner.read_buffer()->offset()); } // Test that "received_bytes" calculation works fine when there is no // network activity at all; that is when all data is read from read buffer. // In this case read buffer contains two responses. We expect that only // bytes that correspond to the first one are taken into account. TEST(HttpStreamParser, ReceivedBytesFromReadBufExcludesNextResponse) { std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 7\r\n\r\n"; std::string body = "content"; std::string response = headers + body; std::string next_response = "HTTP/1.1 200 OK\r\n\r\nFOO"; std::string data = response + next_response; SimpleGetRunner get_runner; get_runner.AddInitialData(data); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); int64 headers_size = headers.size(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int body_size = body.size(); int read_lengths[] = {body_size, 0}; get_runner.ReadBody(body_size, read_lengths); int64 response_size = response.size(); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); int64 next_response_size = next_response.size(); EXPECT_EQ(next_response_size, get_runner.read_buffer()->offset()); } // Test calculating "received_bytes" when part of request has been already // loaded and placed to read buffer by previous stream parser. TEST(HttpStreamParser, ReceivedBytesUseReadBuf) { std::string buffer = "HTTP/1.1 200 OK\r\n"; std::string remaining_headers = "Content-Length: 7\r\n\r\n"; int64 headers_size = buffer.size() + remaining_headers.size(); std::string body = "content"; std::string response = remaining_headers + body; SimpleGetRunner get_runner; get_runner.AddInitialData(buffer); get_runner.AddRead(response); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int body_size = body.size(); int read_lengths[] = {body_size, 0}; get_runner.ReadBody(body_size, read_lengths); EXPECT_EQ(headers_size + body_size, get_runner.parser()->received_bytes()); EXPECT_EQ(0, get_runner.read_buffer()->offset()); } // Test the case when the resulting read_buf contains both unused bytes and // bytes ejected by chunked-encoding filter. TEST(HttpStreamParser, ReceivedBytesChunkedTransferExcludesNextResponse) { std::string response = "HTTP/1.1 200 OK\r\n" "Transfer-Encoding: chunked\r\n\r\n" "7\r\nChunk 1\r\n" "8\r\nChunky 2\r\n" "6\r\nTest 3\r\n" "0\r\n\r\n"; std::string next_response = "foo bar\r\n"; std::string data = response + next_response; SimpleGetRunner get_runner; get_runner.AddInitialData(data); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); int read_lengths[] = {4, 3, 6, 2, 6, 0}; get_runner.ReadBody(7, read_lengths); int64 response_size = response.size(); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); int64 next_response_size = next_response.size(); EXPECT_EQ(next_response_size, get_runner.read_buffer()->offset()); } // Test that data transfered in multiple reads is correctly processed. // We feed data into 4-bytes reads. Also we set length of read // buffer to 5-bytes to test all possible buffer misaligments. TEST(HttpStreamParser, ReceivedBytesMultipleReads) { std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 33\r\n\r\n"; std::string body = "foo bar baz\r\n" "sputnik mir babushka"; std::string response = headers + body; size_t receive_length = 4; std::vector blocks; for (size_t i = 0; i < response.size(); i += receive_length) { size_t length = std::min(receive_length, response.size() - i); blocks.push_back(response.substr(i, length)); } SimpleGetRunner get_runner; for (std::vector::size_type i = 0; i < blocks.size(); ++i) get_runner.AddRead(blocks[i]); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); int64 headers_size = headers.size(); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int read_lengths[] = {1, 4, 4, 4, 4, 4, 4, 4, 4, 0}; get_runner.ReadBody(receive_length + 1, read_lengths); int64 response_size = response.size(); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); } // Test that "continue" HTTP header is counted as "received_bytes". TEST(HttpStreamParser, ReceivedBytesIncludesContinueHeader) { std::string status100 = "HTTP/1.1 100 OK\r\n\r\n"; std::string headers = "HTTP/1.1 200 OK\r\n" "Content-Length: 7\r\n\r\n"; int64 headers_size = status100.size() + headers.size(); std::string body = "content"; std::string response = headers + body; SimpleGetRunner get_runner; get_runner.AddRead(status100); get_runner.AddRead(response); get_runner.SetupParserAndSendRequest(); get_runner.ReadHeaders(); EXPECT_EQ(100, get_runner.response_info()->headers->response_code()); int64 status100_size = status100.size(); EXPECT_EQ(status100_size, get_runner.parser()->received_bytes()); get_runner.ReadHeaders(); EXPECT_EQ(200, get_runner.response_info()->headers->response_code()); EXPECT_EQ(headers_size, get_runner.parser()->received_bytes()); int64 response_size = headers_size + body.size(); int body_size = body.size(); int read_lengths[] = {body_size, 0}; get_runner.ReadBody(body_size, read_lengths); EXPECT_EQ(response_size, get_runner.parser()->received_bytes()); } } // namespace } // namespace net