root/net/http/http_stream_parser_unittest.cc

DEFINITIONS

1. TEST
2. TEST
3. TEST
4. TEST
5. TEST
6. TEST
7. TEST
8. TEST
9. TEST
10. TEST
11. TEST
12. TEST
13. TEST
14. TEST
15. sequence_number_
16. parser
17. read_buffer
18. response_info
19. AddInitialData
20. AddRead
21. SetupParserAndSendRequest
22. ReadHeaders
23. ReadBody
24. TEST
25. TEST
26. TEST
27. TEST
28. TEST
29. TEST
30. TEST
31. TEST
32. TEST

// 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 <algorithm>
#include <string>
#include <vector>

#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<size_t>(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<size_t>(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<size_t>(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<size_t>(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<UploadElementReader> element_readers;
  scoped_ptr<UploadDataStream> 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<UploadDataStream> 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<UploadElementReader> 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<UploadDataStream> 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<UploadElementReader> element_readers;
  const std::string payload = "123";
  element_readers.push_back(new UploadBytesElementReader(
      payload.data(), payload.size()));

  scoped_ptr<UploadDataStream> 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<UploadElementReader> element_readers;
  const std::string payload(10000, 'a');  // 'a' x 10000.
  element_readers.push_back(new UploadBytesElementReader(
      payload.data(), payload.size()));

  scoped_ptr<UploadDataStream> 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<DeterministicMockTCPClientSocket> 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<ClientSocketHandle> socket_handle(new ClientSocketHandle);
  socket_handle->SetSocket(transport.PassAs<StreamSocket>());

  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<GrowableIOBuffer> 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<IOBuffer> 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<DeterministicMockTCPClientSocket> 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<ClientSocketHandle> socket_handle(new ClientSocketHandle);
      socket_handle->SetSocket(transport.PassAs<StreamSocket>());

      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<GrowableIOBuffer> 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<DeterministicMockTCPClientSocket> 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<ClientSocketHandle> socket_handle(new ClientSocketHandle);
  socket_handle->SetSocket(transport.PassAs<StreamSocket>());

  HttpRequestInfo request_info;
  request_info.method = "GET";
  request_info.url = GURL("http://localhost");
  request_info.load_flags = LOAD_NORMAL;

  scoped_refptr<GrowableIOBuffer> 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<StreamSocket>());

    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<IOBuffer> 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<GrowableIOBuffer> read_buffer_;
  std::vector<MockRead> reads_;
  std::vector<MockWrite> writes_;
  scoped_ptr<ClientSocketHandle> socket_handle_;
  scoped_ptr<DeterministicSocketData> data_;
  scoped_ptr<DeterministicMockTCPClientSocket> transport_;
  scoped_ptr<HttpStreamParser> 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<std::string> 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<std::string>::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