src/net/server/http_connection_unittest.cc - cobalt - Git at Google

 // Copyright 2014 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/server/http_connection.h"

 #include <string>

 #include "base/memory/ref_counted.h"
 #include "base/strings/string_piece.h"
 #include "starboard/memory.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace net {
 namespace {

 std::string GetTestString(int size) {
   std::string test_string;
   for (int i = 0; i < size; ++i) {
     test_string.push_back('A' + (i % 26));
   }
   return test_string;
 }

 TEST(HttpConnectionTest, ReadIOBuffer_SetCapacity) {
   scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->GetCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->RemainingCapacity());
   EXPECT_EQ(0, buffer->GetSize());

   const int kNewCapacity = HttpConnection::ReadIOBuffer::kInitialBufSize + 128;
   buffer->SetCapacity(kNewCapacity);
   EXPECT_EQ(kNewCapacity, buffer->GetCapacity());
   EXPECT_EQ(kNewCapacity, buffer->RemainingCapacity());
   EXPECT_EQ(0, buffer->GetSize());
 }

 TEST(HttpConnectionTest, ReadIOBuffer_SetCapacity_WithData) {
   scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->GetCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->RemainingCapacity());

   // Write arbitrary data up to kInitialBufSize.
   const std::string kReadData(
       GetTestString(HttpConnection::ReadIOBuffer::kInitialBufSize));
   memcpy(buffer->data(), kReadData.data(), kReadData.size());
   buffer->DidRead(kReadData.size());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->GetCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize -
                 static_cast<int>(kReadData.size()),
             buffer->RemainingCapacity());
   EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
   EXPECT_EQ(kReadData,
             base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));

   // Check if read data in the buffer is same after SetCapacity().
   const int kNewCapacity = HttpConnection::ReadIOBuffer::kInitialBufSize + 128;
   buffer->SetCapacity(kNewCapacity);
   EXPECT_EQ(kNewCapacity, buffer->GetCapacity());
   EXPECT_EQ(kNewCapacity - static_cast<int>(kReadData.size()),
             buffer->RemainingCapacity());
   EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
   EXPECT_EQ(kReadData,
             base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));
 }

 TEST(HttpConnectionTest, ReadIOBuffer_IncreaseCapacity) {
   scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
   EXPECT_TRUE(buffer->IncreaseCapacity());
   const int kExpectedInitialBufSize =
       HttpConnection::ReadIOBuffer::kInitialBufSize *
       HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor;
   EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
   EXPECT_EQ(kExpectedInitialBufSize, buffer->RemainingCapacity());
   EXPECT_EQ(0, buffer->GetSize());

   // Increase capacity until it fails.
   while (buffer->IncreaseCapacity());
   EXPECT_FALSE(buffer->IncreaseCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
             buffer->max_buffer_size());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
             buffer->GetCapacity());

   // Enlarge capacity limit.
   buffer->set_max_buffer_size(buffer->max_buffer_size() * 2);
   EXPECT_TRUE(buffer->IncreaseCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize *
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->GetCapacity());

   // Shrink capacity limit. It doesn't change capacity itself.
   buffer->set_max_buffer_size(
       HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize / 2);
   EXPECT_FALSE(buffer->IncreaseCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize *
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->GetCapacity());
 }

 TEST(HttpConnectionTest, ReadIOBuffer_IncreaseCapacity_WithData) {
   scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
   EXPECT_TRUE(buffer->IncreaseCapacity());
   const int kExpectedInitialBufSize =
       HttpConnection::ReadIOBuffer::kInitialBufSize *
       HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor;
   EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
   EXPECT_EQ(kExpectedInitialBufSize, buffer->RemainingCapacity());
   EXPECT_EQ(0, buffer->GetSize());

   // Write arbitrary data up to kExpectedInitialBufSize.
   std::string kReadData(GetTestString(kExpectedInitialBufSize));
   memcpy(buffer->data(), kReadData.data(), kReadData.size());
   buffer->DidRead(kReadData.size());
   EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
   EXPECT_EQ(kExpectedInitialBufSize - static_cast<int>(kReadData.size()),
             buffer->RemainingCapacity());
   EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
   EXPECT_EQ(kReadData,
             base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));

   // Increase capacity until it fails and check if read data in the buffer is
   // same.
   while (buffer->IncreaseCapacity());
   EXPECT_FALSE(buffer->IncreaseCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
             buffer->max_buffer_size());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
             buffer->GetCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize -
                 static_cast<int>(kReadData.size()),
             buffer->RemainingCapacity());
   EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
   EXPECT_EQ(kReadData,
             base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));
 }

 TEST(HttpConnectionTest, ReadIOBuffer_DidRead_DidConsume) {
   scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
   const char* start_of_buffer = buffer->StartOfBuffer();
   EXPECT_EQ(start_of_buffer, buffer->data());

   // Read data.
   const int kReadLength = 128;
   const std::string kReadData(GetTestString(kReadLength));
   memcpy(buffer->data(), kReadData.data(), kReadLength);
   buffer->DidRead(kReadLength);
   // No change in total capacity.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
             buffer->GetCapacity());
   // Change in unused capacity because of read data.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize - kReadLength,
             buffer->RemainingCapacity());
   EXPECT_EQ(kReadLength, buffer->GetSize());
   // No change in start pointers of read data.
   EXPECT_EQ(start_of_buffer, buffer->StartOfBuffer());
   // Change in start pointer of unused buffer.
   EXPECT_EQ(start_of_buffer + kReadLength, buffer->data());
   // Test read data.
   EXPECT_EQ(kReadData, std::string(buffer->StartOfBuffer(), buffer->GetSize()));

   // Consume data partially.
   const int kConsumedLength = 32;
   ASSERT_LT(kConsumedLength, kReadLength);
   buffer->DidConsume(kConsumedLength);
   // Capacity reduced because read data was too small comparing to capacity.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->GetCapacity());
   // Change in unused capacity because of read data.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor -
                 kReadLength + kConsumedLength,
             buffer->RemainingCapacity());
   // Change in read size.
   EXPECT_EQ(kReadLength - kConsumedLength, buffer->GetSize());
   // Start data could be changed even when capacity is reduced.
   start_of_buffer = buffer->StartOfBuffer();
   // Change in start pointer of unused buffer.
   EXPECT_EQ(start_of_buffer + kReadLength - kConsumedLength, buffer->data());
   // Change in read data.
   EXPECT_EQ(kReadData.substr(kConsumedLength),
             std::string(buffer->StartOfBuffer(), buffer->GetSize()));

   // Read more data.
   const int kReadLength2 = 64;
   buffer->DidRead(kReadLength2);
   // No change in total capacity.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->GetCapacity());
   // Change in unused capacity because of read data.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor -
                 kReadLength + kConsumedLength - kReadLength2,
             buffer->RemainingCapacity());
   // Change in read size
   EXPECT_EQ(kReadLength - kConsumedLength + kReadLength2, buffer->GetSize());
   // No change in start pointer of read part.
   EXPECT_EQ(start_of_buffer, buffer->StartOfBuffer());
   // Change in start pointer of unused buffer.
   EXPECT_EQ(start_of_buffer + kReadLength - kConsumedLength + kReadLength2,
             buffer->data());

   // Consume data fully.
   buffer->DidConsume(kReadLength - kConsumedLength + kReadLength2);
   // Capacity reduced again because read data was too small.
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->GetCapacity());
   EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor /
                 HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
             buffer->RemainingCapacity());
   // All reverts to initial because no data is left.
   EXPECT_EQ(0, buffer->GetSize());
   // Start data could be changed even when capacity is reduced.
   start_of_buffer = buffer->StartOfBuffer();
   EXPECT_EQ(start_of_buffer, buffer->data());
 }

 TEST(HttpConnectionTest, QueuedWriteIOBuffer_Append_DidConsume) {
   scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();
   EXPECT_TRUE(buffer->IsEmpty());
   EXPECT_EQ(0, buffer->GetSizeToWrite());
   EXPECT_EQ(0, buffer->total_size());

   const std::string kData("data to write");
   EXPECT_TRUE(buffer->Append(kData));
   EXPECT_FALSE(buffer->IsEmpty());
   EXPECT_EQ(static_cast<int>(kData.size()), buffer->GetSizeToWrite());
   EXPECT_EQ(static_cast<int>(kData.size()), buffer->total_size());
   // First data to write is same to kData.
   EXPECT_EQ(kData, base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

   const std::string kData2("more data to write");
   EXPECT_TRUE(buffer->Append(kData2));
   EXPECT_FALSE(buffer->IsEmpty());
   // No change in size to write.
   EXPECT_EQ(static_cast<int>(kData.size()), buffer->GetSizeToWrite());
   // Change in total size.
   EXPECT_EQ(static_cast<int>(kData.size() + kData2.size()),
             buffer->total_size());
   // First data to write has not been changed. Same to kData.
   EXPECT_EQ(kData, base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

   // Consume data partially.
   const int kConsumedLength = kData.length() - 1;
   buffer->DidConsume(kConsumedLength);
   EXPECT_FALSE(buffer->IsEmpty());
   // Change in size to write.
   EXPECT_EQ(static_cast<int>(kData.size()) - kConsumedLength,
             buffer->GetSizeToWrite());
   // Change in total size.
   EXPECT_EQ(static_cast<int>(kData.size() + kData2.size()) - kConsumedLength,
             buffer->total_size());
   // First data to write has shrinked.
   EXPECT_EQ(kData.substr(kConsumedLength),
             base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

   // Consume first data fully.
   buffer->DidConsume(kData.size() - kConsumedLength);
   EXPECT_FALSE(buffer->IsEmpty());
   // Now, size to write is size of data added second.
   EXPECT_EQ(static_cast<int>(kData2.size()), buffer->GetSizeToWrite());
   // Change in total size.
   EXPECT_EQ(static_cast<int>(kData2.size()), buffer->total_size());
   // First data to write has changed to kData2.
   EXPECT_EQ(kData2,
             base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

   // Consume second data fully.
   buffer->DidConsume(kData2.size());
   EXPECT_TRUE(buffer->IsEmpty());
   EXPECT_EQ(0, buffer->GetSizeToWrite());
   EXPECT_EQ(0, buffer->total_size());
 }

 TEST(HttpConnectionTest, QueuedWriteIOBuffer_TotalSizeLimit) {
   scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();
   EXPECT_EQ(HttpConnection::QueuedWriteIOBuffer::kDefaultMaxBufferSize + 0,
             buffer->max_buffer_size());

   // Set total size limit very small.
   buffer->set_max_buffer_size(10);

   const int kDataLength = 4;
   const std::string kData(kDataLength, 'd');
   EXPECT_TRUE(buffer->Append(kData));
   EXPECT_EQ(kDataLength, buffer->total_size());
   EXPECT_TRUE(buffer->Append(kData));
   EXPECT_EQ(kDataLength * 2, buffer->total_size());

   // Cannot append more data because it exceeds the limit.
   EXPECT_FALSE(buffer->Append(kData));
   EXPECT_EQ(kDataLength * 2, buffer->total_size());

   // Consume data partially.
   const int kConsumedLength = 2;
   buffer->DidConsume(kConsumedLength);
   EXPECT_EQ(kDataLength * 2 - kConsumedLength, buffer->total_size());

   // Can add more data.
   EXPECT_TRUE(buffer->Append(kData));
   EXPECT_EQ(kDataLength * 3 - kConsumedLength, buffer->total_size());

   // Cannot append more data because it exceeds the limit.
   EXPECT_FALSE(buffer->Append(kData));
   EXPECT_EQ(kDataLength * 3 - kConsumedLength, buffer->total_size());

   // Enlarge limit.
   buffer->set_max_buffer_size(20);
   // Can add more data.
   EXPECT_TRUE(buffer->Append(kData));
   EXPECT_EQ(kDataLength * 4 - kConsumedLength, buffer->total_size());
 }

 TEST(HttpConnectionTest, QueuedWriteIOBuffer_DataPointerStability) {
   // This is a regression test that makes sure that QueuedWriteIOBuffer deals
   // with base::queue's semantics differences vs. std::queue right, and still
   // makes sure our data() pointers are stable.
   scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
       base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();

   // We append a short string to make it fit within any short string
   // optimization, so that if the underlying queue moves the std::string,
   // the data should change.
   buffer->Append("abcdefgh");

   // Read part of it, to make sure this handles the case of data() pointing
   // to something other than start of string right.
   buffer->DidConsume(3);
   const char* old_data = buffer->data();
   EXPECT_EQ("defgh", base::StringPiece(buffer->data(), 5));

   // Now append a whole bunch of other things to make the underlying queue
   // grow, and likely need to move stuff around in memory.
   for (int i = 0; i < 256; ++i)
     buffer->Append("some other string data");

   // data() should still be right.
   EXPECT_EQ("defgh", base::StringPiece(buffer->data(), 5));

   // ... it should also be bitwise the same, since the IOBuffer can get passed
   // to async calls and then have Append's come in.
   EXPECT_TRUE(buffer->data() == old_data);
 }

 }  // namespace
 }  // namespace net
	// Copyright 2014 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/server/http_connection.h"

	#include <string>

	#include "base/memory/ref_counted.h"
	#include "base/strings/string_piece.h"
	#include "starboard/memory.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace net {
	namespace {

	std::string GetTestString(int size) {
	std::string test_string;
	for (int i = 0; i < size; ++i) {
	test_string.push_back('A' + (i % 26));
	}
	return test_string;
	}

	TEST(HttpConnectionTest, ReadIOBuffer_SetCapacity) {
	scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->GetCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->RemainingCapacity());
	EXPECT_EQ(0, buffer->GetSize());

	const int kNewCapacity = HttpConnection::ReadIOBuffer::kInitialBufSize + 128;
	buffer->SetCapacity(kNewCapacity);
	EXPECT_EQ(kNewCapacity, buffer->GetCapacity());
	EXPECT_EQ(kNewCapacity, buffer->RemainingCapacity());
	EXPECT_EQ(0, buffer->GetSize());
	}

	TEST(HttpConnectionTest, ReadIOBuffer_SetCapacity_WithData) {
	scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->GetCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->RemainingCapacity());

	// Write arbitrary data up to kInitialBufSize.
	const std::string kReadData(
	GetTestString(HttpConnection::ReadIOBuffer::kInitialBufSize));
	memcpy(buffer->data(), kReadData.data(), kReadData.size());
	buffer->DidRead(kReadData.size());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->GetCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize -
	static_cast<int>(kReadData.size()),
	buffer->RemainingCapacity());
	EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
	EXPECT_EQ(kReadData,
	base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));

	// Check if read data in the buffer is same after SetCapacity().
	const int kNewCapacity = HttpConnection::ReadIOBuffer::kInitialBufSize + 128;
	buffer->SetCapacity(kNewCapacity);
	EXPECT_EQ(kNewCapacity, buffer->GetCapacity());
	EXPECT_EQ(kNewCapacity - static_cast<int>(kReadData.size()),
	buffer->RemainingCapacity());
	EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
	EXPECT_EQ(kReadData,
	base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));
	}

	TEST(HttpConnectionTest, ReadIOBuffer_IncreaseCapacity) {
	scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
	EXPECT_TRUE(buffer->IncreaseCapacity());
	const int kExpectedInitialBufSize =
	HttpConnection::ReadIOBuffer::kInitialBufSize *
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor;
	EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
	EXPECT_EQ(kExpectedInitialBufSize, buffer->RemainingCapacity());
	EXPECT_EQ(0, buffer->GetSize());

	// Increase capacity until it fails.
	while (buffer->IncreaseCapacity());
	EXPECT_FALSE(buffer->IncreaseCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
	buffer->max_buffer_size());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
	buffer->GetCapacity());

	// Enlarge capacity limit.
	buffer->set_max_buffer_size(buffer->max_buffer_size() * 2);
	EXPECT_TRUE(buffer->IncreaseCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize *
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->GetCapacity());

	// Shrink capacity limit. It doesn't change capacity itself.
	buffer->set_max_buffer_size(
	HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize / 2);
	EXPECT_FALSE(buffer->IncreaseCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize *
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->GetCapacity());
	}

	TEST(HttpConnectionTest, ReadIOBuffer_IncreaseCapacity_WithData) {
	scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
	EXPECT_TRUE(buffer->IncreaseCapacity());
	const int kExpectedInitialBufSize =
	HttpConnection::ReadIOBuffer::kInitialBufSize *
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor;
	EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
	EXPECT_EQ(kExpectedInitialBufSize, buffer->RemainingCapacity());
	EXPECT_EQ(0, buffer->GetSize());

	// Write arbitrary data up to kExpectedInitialBufSize.
	std::string kReadData(GetTestString(kExpectedInitialBufSize));
	memcpy(buffer->data(), kReadData.data(), kReadData.size());
	buffer->DidRead(kReadData.size());
	EXPECT_EQ(kExpectedInitialBufSize, buffer->GetCapacity());
	EXPECT_EQ(kExpectedInitialBufSize - static_cast<int>(kReadData.size()),
	buffer->RemainingCapacity());
	EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
	EXPECT_EQ(kReadData,
	base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));

	// Increase capacity until it fails and check if read data in the buffer is
	// same.
	while (buffer->IncreaseCapacity());
	EXPECT_FALSE(buffer->IncreaseCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
	buffer->max_buffer_size());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize + 0,
	buffer->GetCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kDefaultMaxBufferSize -
	static_cast<int>(kReadData.size()),
	buffer->RemainingCapacity());
	EXPECT_EQ(static_cast<int>(kReadData.size()), buffer->GetSize());
	EXPECT_EQ(kReadData,
	base::StringPiece(buffer->StartOfBuffer(), buffer->GetSize()));
	}

	TEST(HttpConnectionTest, ReadIOBuffer_DidRead_DidConsume) {
	scoped_refptr<HttpConnection::ReadIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::ReadIOBuffer>();
	const char* start_of_buffer = buffer->StartOfBuffer();
	EXPECT_EQ(start_of_buffer, buffer->data());

	// Read data.
	const int kReadLength = 128;
	const std::string kReadData(GetTestString(kReadLength));
	memcpy(buffer->data(), kReadData.data(), kReadLength);
	buffer->DidRead(kReadLength);
	// No change in total capacity.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize + 0,
	buffer->GetCapacity());
	// Change in unused capacity because of read data.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize - kReadLength,
	buffer->RemainingCapacity());
	EXPECT_EQ(kReadLength, buffer->GetSize());
	// No change in start pointers of read data.
	EXPECT_EQ(start_of_buffer, buffer->StartOfBuffer());
	// Change in start pointer of unused buffer.
	EXPECT_EQ(start_of_buffer + kReadLength, buffer->data());
	// Test read data.
	EXPECT_EQ(kReadData, std::string(buffer->StartOfBuffer(), buffer->GetSize()));

	// Consume data partially.
	const int kConsumedLength = 32;
	ASSERT_LT(kConsumedLength, kReadLength);
	buffer->DidConsume(kConsumedLength);
	// Capacity reduced because read data was too small comparing to capacity.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->GetCapacity());
	// Change in unused capacity because of read data.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor -
	kReadLength + kConsumedLength,
	buffer->RemainingCapacity());
	// Change in read size.
	EXPECT_EQ(kReadLength - kConsumedLength, buffer->GetSize());
	// Start data could be changed even when capacity is reduced.
	start_of_buffer = buffer->StartOfBuffer();
	// Change in start pointer of unused buffer.
	EXPECT_EQ(start_of_buffer + kReadLength - kConsumedLength, buffer->data());
	// Change in read data.
	EXPECT_EQ(kReadData.substr(kConsumedLength),
	std::string(buffer->StartOfBuffer(), buffer->GetSize()));

	// Read more data.
	const int kReadLength2 = 64;
	buffer->DidRead(kReadLength2);
	// No change in total capacity.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->GetCapacity());
	// Change in unused capacity because of read data.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor -
	kReadLength + kConsumedLength - kReadLength2,
	buffer->RemainingCapacity());
	// Change in read size
	EXPECT_EQ(kReadLength - kConsumedLength + kReadLength2, buffer->GetSize());
	// No change in start pointer of read part.
	EXPECT_EQ(start_of_buffer, buffer->StartOfBuffer());
	// Change in start pointer of unused buffer.
	EXPECT_EQ(start_of_buffer + kReadLength - kConsumedLength + kReadLength2,
	buffer->data());

	// Consume data fully.
	buffer->DidConsume(kReadLength - kConsumedLength + kReadLength2);
	// Capacity reduced again because read data was too small.
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->GetCapacity());
	EXPECT_EQ(HttpConnection::ReadIOBuffer::kInitialBufSize /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor /
	HttpConnection::ReadIOBuffer::kCapacityIncreaseFactor,
	buffer->RemainingCapacity());
	// All reverts to initial because no data is left.
	EXPECT_EQ(0, buffer->GetSize());
	// Start data could be changed even when capacity is reduced.
	start_of_buffer = buffer->StartOfBuffer();
	EXPECT_EQ(start_of_buffer, buffer->data());
	}

	TEST(HttpConnectionTest, QueuedWriteIOBuffer_Append_DidConsume) {
	scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();
	EXPECT_TRUE(buffer->IsEmpty());
	EXPECT_EQ(0, buffer->GetSizeToWrite());
	EXPECT_EQ(0, buffer->total_size());

	const std::string kData("data to write");
	EXPECT_TRUE(buffer->Append(kData));
	EXPECT_FALSE(buffer->IsEmpty());
	EXPECT_EQ(static_cast<int>(kData.size()), buffer->GetSizeToWrite());
	EXPECT_EQ(static_cast<int>(kData.size()), buffer->total_size());
	// First data to write is same to kData.
	EXPECT_EQ(kData, base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

	const std::string kData2("more data to write");
	EXPECT_TRUE(buffer->Append(kData2));
	EXPECT_FALSE(buffer->IsEmpty());
	// No change in size to write.
	EXPECT_EQ(static_cast<int>(kData.size()), buffer->GetSizeToWrite());
	// Change in total size.
	EXPECT_EQ(static_cast<int>(kData.size() + kData2.size()),
	buffer->total_size());
	// First data to write has not been changed. Same to kData.
	EXPECT_EQ(kData, base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

	// Consume data partially.
	const int kConsumedLength = kData.length() - 1;
	buffer->DidConsume(kConsumedLength);
	EXPECT_FALSE(buffer->IsEmpty());
	// Change in size to write.
	EXPECT_EQ(static_cast<int>(kData.size()) - kConsumedLength,
	buffer->GetSizeToWrite());
	// Change in total size.
	EXPECT_EQ(static_cast<int>(kData.size() + kData2.size()) - kConsumedLength,
	buffer->total_size());
	// First data to write has shrinked.
	EXPECT_EQ(kData.substr(kConsumedLength),
	base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

	// Consume first data fully.
	buffer->DidConsume(kData.size() - kConsumedLength);
	EXPECT_FALSE(buffer->IsEmpty());
	// Now, size to write is size of data added second.
	EXPECT_EQ(static_cast<int>(kData2.size()), buffer->GetSizeToWrite());
	// Change in total size.
	EXPECT_EQ(static_cast<int>(kData2.size()), buffer->total_size());
	// First data to write has changed to kData2.
	EXPECT_EQ(kData2,
	base::StringPiece(buffer->data(), buffer->GetSizeToWrite()));

	// Consume second data fully.
	buffer->DidConsume(kData2.size());
	EXPECT_TRUE(buffer->IsEmpty());
	EXPECT_EQ(0, buffer->GetSizeToWrite());
	EXPECT_EQ(0, buffer->total_size());
	}

	TEST(HttpConnectionTest, QueuedWriteIOBuffer_TotalSizeLimit) {
	scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();
	EXPECT_EQ(HttpConnection::QueuedWriteIOBuffer::kDefaultMaxBufferSize + 0,
	buffer->max_buffer_size());

	// Set total size limit very small.
	buffer->set_max_buffer_size(10);

	const int kDataLength = 4;
	const std::string kData(kDataLength, 'd');
	EXPECT_TRUE(buffer->Append(kData));
	EXPECT_EQ(kDataLength, buffer->total_size());
	EXPECT_TRUE(buffer->Append(kData));
	EXPECT_EQ(kDataLength * 2, buffer->total_size());

	// Cannot append more data because it exceeds the limit.
	EXPECT_FALSE(buffer->Append(kData));
	EXPECT_EQ(kDataLength * 2, buffer->total_size());

	// Consume data partially.
	const int kConsumedLength = 2;
	buffer->DidConsume(kConsumedLength);
	EXPECT_EQ(kDataLength * 2 - kConsumedLength, buffer->total_size());

	// Can add more data.
	EXPECT_TRUE(buffer->Append(kData));
	EXPECT_EQ(kDataLength * 3 - kConsumedLength, buffer->total_size());

	// Cannot append more data because it exceeds the limit.
	EXPECT_FALSE(buffer->Append(kData));
	EXPECT_EQ(kDataLength * 3 - kConsumedLength, buffer->total_size());

	// Enlarge limit.
	buffer->set_max_buffer_size(20);
	// Can add more data.
	EXPECT_TRUE(buffer->Append(kData));
	EXPECT_EQ(kDataLength * 4 - kConsumedLength, buffer->total_size());
	}

	TEST(HttpConnectionTest, QueuedWriteIOBuffer_DataPointerStability) {
	// This is a regression test that makes sure that QueuedWriteIOBuffer deals
	// with base::queue's semantics differences vs. std::queue right, and still
	// makes sure our data() pointers are stable.
	scoped_refptr<HttpConnection::QueuedWriteIOBuffer> buffer =
	base::MakeRefCounted<HttpConnection::QueuedWriteIOBuffer>();

	// We append a short string to make it fit within any short string
	// optimization, so that if the underlying queue moves the std::string,
	// the data should change.
	buffer->Append("abcdefgh");

	// Read part of it, to make sure this handles the case of data() pointing
	// to something other than start of string right.
	buffer->DidConsume(3);
	const char* old_data = buffer->data();
	EXPECT_EQ("defgh", base::StringPiece(buffer->data(), 5));

	// Now append a whole bunch of other things to make the underlying queue
	// grow, and likely need to move stuff around in memory.
	for (int i = 0; i < 256; ++i)
	buffer->Append("some other string data");

	// data() should still be right.
	EXPECT_EQ("defgh", base::StringPiece(buffer->data(), 5));

	// ... it should also be bitwise the same, since the IOBuffer can get passed
	// to async calls and then have Append's come in.
	EXPECT_TRUE(buffer->data() == old_data);
	}

	} // namespace
	} // namespace net