src/net/third_party/quic/platform/impl/batch_writer/quic_batch_writer_buffer_test.cc - cobalt - Git at Google

 // Copyright (c) 2018 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/third_party/quic/platform/impl/batch_writer/quic_batch_writer_buffer.h"
 #include <string>

 #include "net/third_party/quic/core/quic_constants.h"
 #include "net/third_party/quic/platform/api/quic_ip_address.h"
 #include "net/third_party/quic/platform/api/quic_ptr_util.h"
 #include "net/third_party/quic/platform/api/quic_socket_address.h"
 #include "net/third_party/quic/platform/api/quic_test.h"
 #include "starboard/memory.h"

 namespace quic {
 namespace test {
 namespace {

 class TestQuicBatchWriterBuffer : public QuicBatchWriterBuffer {
  public:
   using QuicBatchWriterBuffer::buffer_;
   using QuicBatchWriterBuffer::buffered_writes_;
 };

 static const size_t kBatchBufferSize = QuicBatchWriterBuffer::kBufferSize;

 class QuicBatchWriterBufferTest : public QuicTest {
  public:
   QuicBatchWriterBufferTest() { SwitchToNewBuffer(); }

   void SwitchToNewBuffer() {
     batch_buffer_ = QuicMakeUnique<TestQuicBatchWriterBuffer>();
   }

   // Fill packet_buffer_ with kMaxPacketSize bytes of |c|s.
   char* FillPacketBuffer(char c) {
     return FillPacketBuffer(c, packet_buffer_, kMaxPacketSize);
   }

   // Fill |packet_buffer| with kMaxPacketSize bytes of |c|s.
   char* FillPacketBuffer(char c, char* packet_buffer) {
     return FillPacketBuffer(c, packet_buffer, kMaxPacketSize);
   }

   // Fill |packet_buffer| with |buf_len| bytes of |c|s.
   char* FillPacketBuffer(char c, char* packet_buffer, size_t buf_len) {
     memset(packet_buffer, c, buf_len);
     return packet_buffer;
   }

   void CheckBufferedWriteContent(int buffered_write_index,
                                  char buffer_content,
                                  size_t buf_len,
                                  const QuicIpAddress& self_addr,
                                  const QuicSocketAddress& peer_addr,
                                  const PerPacketOptions* options) {
     const BufferedWrite& buffered_write =
         batch_buffer_->buffered_writes()[buffered_write_index];
     EXPECT_EQ(buf_len, buffered_write.buf_len);
     for (size_t i = 0; i < buf_len; ++i) {
       EXPECT_EQ(buffer_content, buffered_write.buffer[i]);
       if (buffer_content != buffered_write.buffer[i]) {
         break;
       }
     }
     EXPECT_EQ(self_addr, buffered_write.self_address);
     EXPECT_EQ(peer_addr, buffered_write.peer_address);
     if (options == nullptr) {
       EXPECT_EQ(nullptr, buffered_write.options);
     } else {
       EXPECT_EQ(options->release_time_delay,
                 buffered_write.options->release_time_delay);
     }
   }

  protected:
   std::unique_ptr<TestQuicBatchWriterBuffer> batch_buffer_;
   QuicIpAddress self_addr_;
   QuicSocketAddress peer_addr_;
   char packet_buffer_[kMaxPacketSize];
 };

 class BufferSizeSequence {
  public:
   explicit BufferSizeSequence(
       std::vector<std::pair<std::vector<size_t>, size_t>> stages)
       : stages_(std::move(stages)),
         total_buf_len_(0),
         stage_index_(0),
         sequence_index_(0) {}

   size_t Next() {
     const std::vector<size_t>& seq = stages_[stage_index_].first;
     size_t buf_len = seq[sequence_index_++ % seq.size()];
     total_buf_len_ += buf_len;
     if (stages_[stage_index_].second <= total_buf_len_) {
       stage_index_ = std::min(stage_index_ + 1, stages_.size() - 1);
     }
     return buf_len;
   }

  private:
   const std::vector<std::pair<std::vector<size_t>, size_t>> stages_;
   size_t total_buf_len_;
   size_t stage_index_;
   size_t sequence_index_;
 };

 // Test in-place pushes. A in-place push is a push with a buffer address that is
 // equal to the result of GetNextWriteLocation().
 TEST_F(QuicBatchWriterBufferTest, InPlacePushes) {
   std::vector<BufferSizeSequence> buffer_size_sequences = {
       // Push large writes until the buffer is near full, then switch to 1-byte
       // writes. This covers the edge cases when detecting insufficient buffer.
       BufferSizeSequence({{{1350}, kBatchBufferSize - 3000}, {{1}, 1e6}}),
       // A sequence that looks real.
       BufferSizeSequence({{{1, 39, 97, 150, 1350, 1350, 1350, 1350}, 1e6}}),
   };

   for (auto& buffer_size_sequence : buffer_size_sequences) {
     SwitchToNewBuffer();
     int64_t num_push_failures = 0;

     while (batch_buffer_->SizeInUse() < kBatchBufferSize) {
       size_t buf_len = buffer_size_sequence.Next();
       const bool has_enough_space =
           (kBatchBufferSize - batch_buffer_->SizeInUse() >= kMaxPacketSize);

       char* buffer = batch_buffer_->GetNextWriteLocation();

       if (has_enough_space) {
         EXPECT_EQ(batch_buffer_->buffer_ + batch_buffer_->SizeInUse(), buffer);
       } else {
         EXPECT_EQ(nullptr, buffer);
       }

       SCOPED_TRACE(testing::Message()
                    << "Before Push: buf_len=" << buf_len
                    << ", has_enough_space=" << has_enough_space
                    << ", batch_buffer=" << batch_buffer_->DebugString());

       auto push_result = batch_buffer_->PushBufferedWrite(
           buffer, buf_len, self_addr_, peer_addr_, nullptr);
       if (!push_result.succeeded) {
         ++num_push_failures;
       }
       EXPECT_EQ(has_enough_space, push_result.succeeded);
       EXPECT_FALSE(push_result.buffer_copied);
       if (!has_enough_space) {
         break;
       }
     }
     // Expect one and only one failure from the final push operation.
     EXPECT_EQ(1, num_push_failures);
   }
 }

 // Test some in-place pushes mixed with pushes with external buffers.
 TEST_F(QuicBatchWriterBufferTest, MixedPushes) {
   // First, a in-place push.
   char* buffer = batch_buffer_->GetNextWriteLocation();
   auto push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('A', buffer), kDefaultMaxPacketSize, self_addr_,
       peer_addr_, nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_FALSE(push_result.buffer_copied);
   CheckBufferedWriteContent(0, 'A', kDefaultMaxPacketSize, self_addr_,
                             peer_addr_, nullptr);

   // Then a push with external buffer.
   push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('B'), kDefaultMaxPacketSize, self_addr_, peer_addr_,
       nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_TRUE(push_result.buffer_copied);
   CheckBufferedWriteContent(1, 'B', kDefaultMaxPacketSize, self_addr_,
                             peer_addr_, nullptr);

   // Then another in-place push.
   buffer = batch_buffer_->GetNextWriteLocation();
   push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('C', buffer), kDefaultMaxPacketSize, self_addr_,
       peer_addr_, nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_FALSE(push_result.buffer_copied);
   CheckBufferedWriteContent(2, 'C', kDefaultMaxPacketSize, self_addr_,
                             peer_addr_, nullptr);

   // Then another push with external buffer.
   push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('D'), kDefaultMaxPacketSize, self_addr_, peer_addr_,
       nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_TRUE(push_result.buffer_copied);
   CheckBufferedWriteContent(3, 'D', kDefaultMaxPacketSize, self_addr_,
                             peer_addr_, nullptr);
 }

 TEST_F(QuicBatchWriterBufferTest, PopAll) {
   const int kNumBufferedWrites = 10;
   for (int i = 0; i < kNumBufferedWrites; ++i) {
     EXPECT_TRUE(batch_buffer_
                     ->PushBufferedWrite(packet_buffer_, kDefaultMaxPacketSize,
                                         self_addr_, peer_addr_, nullptr)
                     .succeeded);
   }
   EXPECT_EQ(static_cast<size_t>(kNumBufferedWrites),
             batch_buffer_->buffered_writes().size());

   auto pop_result = batch_buffer_->PopBufferedWrite(kNumBufferedWrites);
   EXPECT_EQ(0u, batch_buffer_->buffered_writes().size());
   EXPECT_EQ(kNumBufferedWrites, pop_result.num_buffers_popped);
   EXPECT_FALSE(pop_result.moved_remaining_buffers);
 }

 TEST_F(QuicBatchWriterBufferTest, PopPartial) {
   const int kNumBufferedWrites = 10;
   for (int i = 0; i < kNumBufferedWrites; ++i) {
     EXPECT_TRUE(batch_buffer_
                     ->PushBufferedWrite(FillPacketBuffer('A' + i),
                                         kDefaultMaxPacketSize - i, self_addr_,
                                         peer_addr_, nullptr)
                     .succeeded);
   }

   for (size_t i = 0;
        i < kNumBufferedWrites && !batch_buffer_->buffered_writes().empty();
        ++i) {
     const size_t size_before_pop = batch_buffer_->buffered_writes().size();
     const size_t expect_size_after_pop =
         size_before_pop < i ? 0 : size_before_pop - i;
     batch_buffer_->PopBufferedWrite(i);
     ASSERT_EQ(expect_size_after_pop, batch_buffer_->buffered_writes().size());
     const char first_write_content =
         'A' + kNumBufferedWrites - expect_size_after_pop;
     const size_t first_write_len =
         kDefaultMaxPacketSize - kNumBufferedWrites + expect_size_after_pop;
     for (size_t j = 0; j < expect_size_after_pop; ++j) {
       CheckBufferedWriteContent(j, first_write_content + j, first_write_len - j,
                                 self_addr_, peer_addr_, nullptr);
     }
   }
 }

 TEST_F(QuicBatchWriterBufferTest, InPlacePushWithPops) {
   // First, a in-place push.
   char* buffer = batch_buffer_->GetNextWriteLocation();
   const size_t first_packet_len = 2;
   auto push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('A', buffer, first_packet_len), first_packet_len,
       self_addr_, peer_addr_, nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_FALSE(push_result.buffer_copied);
   CheckBufferedWriteContent(0, 'A', first_packet_len, self_addr_, peer_addr_,
                             nullptr);

   // Simulate the case where the writer wants to do another in-place push, but
   // can't do so because it can't be batched with the first buffer.
   buffer = batch_buffer_->GetNextWriteLocation();
   const size_t second_packet_len = 1350;

   // Flush the first buffer.
   auto pop_result = batch_buffer_->PopBufferedWrite(1);
   EXPECT_EQ(1, pop_result.num_buffers_popped);
   EXPECT_FALSE(pop_result.moved_remaining_buffers);

   // Now the second push.
   push_result = batch_buffer_->PushBufferedWrite(
       FillPacketBuffer('B', buffer, second_packet_len), second_packet_len,
       self_addr_, peer_addr_, nullptr);
   EXPECT_TRUE(push_result.succeeded);
   EXPECT_TRUE(push_result.buffer_copied);
   CheckBufferedWriteContent(0, 'B', second_packet_len, self_addr_, peer_addr_,
                             nullptr);
 }

 }  // namespace
 }  // namespace test
 }  // namespace quic
	// Copyright (c) 2018 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/third_party/quic/platform/impl/batch_writer/quic_batch_writer_buffer.h"
	#include <string>

	#include "net/third_party/quic/core/quic_constants.h"
	#include "net/third_party/quic/platform/api/quic_ip_address.h"
	#include "net/third_party/quic/platform/api/quic_ptr_util.h"
	#include "net/third_party/quic/platform/api/quic_socket_address.h"
	#include "net/third_party/quic/platform/api/quic_test.h"
	#include "starboard/memory.h"

	namespace quic {
	namespace test {
	namespace {

	class TestQuicBatchWriterBuffer : public QuicBatchWriterBuffer {
	public:
	using QuicBatchWriterBuffer::buffer_;
	using QuicBatchWriterBuffer::buffered_writes_;
	};

	static const size_t kBatchBufferSize = QuicBatchWriterBuffer::kBufferSize;

	class QuicBatchWriterBufferTest : public QuicTest {
	public:
	QuicBatchWriterBufferTest() { SwitchToNewBuffer(); }

	void SwitchToNewBuffer() {
	batch_buffer_ = QuicMakeUnique<TestQuicBatchWriterBuffer>();
	}

	// Fill packet_buffer_ with kMaxPacketSize bytes of \|c\|s.
	char* FillPacketBuffer(char c) {
	return FillPacketBuffer(c, packet_buffer_, kMaxPacketSize);
	}

	// Fill \|packet_buffer\| with kMaxPacketSize bytes of \|c\|s.
	char* FillPacketBuffer(char c, char* packet_buffer) {
	return FillPacketBuffer(c, packet_buffer, kMaxPacketSize);
	}

	// Fill \|packet_buffer\| with \|buf_len\| bytes of \|c\|s.
	char* FillPacketBuffer(char c, char* packet_buffer, size_t buf_len) {
	memset(packet_buffer, c, buf_len);
	return packet_buffer;
	}

	void CheckBufferedWriteContent(int buffered_write_index,
	char buffer_content,
	size_t buf_len,
	const QuicIpAddress& self_addr,
	const QuicSocketAddress& peer_addr,
	const PerPacketOptions* options) {
	const BufferedWrite& buffered_write =
	batch_buffer_->buffered_writes()[buffered_write_index];
	EXPECT_EQ(buf_len, buffered_write.buf_len);
	for (size_t i = 0; i < buf_len; ++i) {
	EXPECT_EQ(buffer_content, buffered_write.buffer[i]);
	if (buffer_content != buffered_write.buffer[i]) {
	break;
	}
	}
	EXPECT_EQ(self_addr, buffered_write.self_address);
	EXPECT_EQ(peer_addr, buffered_write.peer_address);
	if (options == nullptr) {
	EXPECT_EQ(nullptr, buffered_write.options);
	} else {
	EXPECT_EQ(options->release_time_delay,
	buffered_write.options->release_time_delay);
	}
	}

	protected:
	std::unique_ptr<TestQuicBatchWriterBuffer> batch_buffer_;
	QuicIpAddress self_addr_;
	QuicSocketAddress peer_addr_;
	char packet_buffer_[kMaxPacketSize];
	};

	class BufferSizeSequence {
	public:
	explicit BufferSizeSequence(
	std::vector<std::pair<std::vector<size_t>, size_t>> stages)
	: stages_(std::move(stages)),
	total_buf_len_(0),
	stage_index_(0),
	sequence_index_(0) {}

	size_t Next() {
	const std::vector<size_t>& seq = stages_[stage_index_].first;
	size_t buf_len = seq[sequence_index_++ % seq.size()];
	total_buf_len_ += buf_len;
	if (stages_[stage_index_].second <= total_buf_len_) {
	stage_index_ = std::min(stage_index_ + 1, stages_.size() - 1);
	}
	return buf_len;
	}

	private:
	const std::vector<std::pair<std::vector<size_t>, size_t>> stages_;
	size_t total_buf_len_;
	size_t stage_index_;
	size_t sequence_index_;
	};

	// Test in-place pushes. A in-place push is a push with a buffer address that is
	// equal to the result of GetNextWriteLocation().
	TEST_F(QuicBatchWriterBufferTest, InPlacePushes) {
	std::vector<BufferSizeSequence> buffer_size_sequences = {
	// Push large writes until the buffer is near full, then switch to 1-byte
	// writes. This covers the edge cases when detecting insufficient buffer.
	BufferSizeSequence({{{1350}, kBatchBufferSize - 3000}, {{1}, 1e6}}),
	// A sequence that looks real.
	BufferSizeSequence({{{1, 39, 97, 150, 1350, 1350, 1350, 1350}, 1e6}}),
	};

	for (auto& buffer_size_sequence : buffer_size_sequences) {
	SwitchToNewBuffer();
	int64_t num_push_failures = 0;

	while (batch_buffer_->SizeInUse() < kBatchBufferSize) {
	size_t buf_len = buffer_size_sequence.Next();
	const bool has_enough_space =
	(kBatchBufferSize - batch_buffer_->SizeInUse() >= kMaxPacketSize);

	char* buffer = batch_buffer_->GetNextWriteLocation();

	if (has_enough_space) {
	EXPECT_EQ(batch_buffer_->buffer_ + batch_buffer_->SizeInUse(), buffer);
	} else {
	EXPECT_EQ(nullptr, buffer);
	}

	SCOPED_TRACE(testing::Message()
	<< "Before Push: buf_len=" << buf_len
	<< ", has_enough_space=" << has_enough_space
	<< ", batch_buffer=" << batch_buffer_->DebugString());

	auto push_result = batch_buffer_->PushBufferedWrite(
	buffer, buf_len, self_addr_, peer_addr_, nullptr);
	if (!push_result.succeeded) {
	++num_push_failures;
	}
	EXPECT_EQ(has_enough_space, push_result.succeeded);
	EXPECT_FALSE(push_result.buffer_copied);
	if (!has_enough_space) {
	break;
	}
	}
	// Expect one and only one failure from the final push operation.
	EXPECT_EQ(1, num_push_failures);
	}
	}

	// Test some in-place pushes mixed with pushes with external buffers.
	TEST_F(QuicBatchWriterBufferTest, MixedPushes) {
	// First, a in-place push.
	char* buffer = batch_buffer_->GetNextWriteLocation();
	auto push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('A', buffer), kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_FALSE(push_result.buffer_copied);
	CheckBufferedWriteContent(0, 'A', kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);

	// Then a push with external buffer.
	push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('B'), kDefaultMaxPacketSize, self_addr_, peer_addr_,
	nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_TRUE(push_result.buffer_copied);
	CheckBufferedWriteContent(1, 'B', kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);

	// Then another in-place push.
	buffer = batch_buffer_->GetNextWriteLocation();
	push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('C', buffer), kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_FALSE(push_result.buffer_copied);
	CheckBufferedWriteContent(2, 'C', kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);

	// Then another push with external buffer.
	push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('D'), kDefaultMaxPacketSize, self_addr_, peer_addr_,
	nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_TRUE(push_result.buffer_copied);
	CheckBufferedWriteContent(3, 'D', kDefaultMaxPacketSize, self_addr_,
	peer_addr_, nullptr);
	}

	TEST_F(QuicBatchWriterBufferTest, PopAll) {
	const int kNumBufferedWrites = 10;
	for (int i = 0; i < kNumBufferedWrites; ++i) {
	EXPECT_TRUE(batch_buffer_
	->PushBufferedWrite(packet_buffer_, kDefaultMaxPacketSize,
	self_addr_, peer_addr_, nullptr)
	.succeeded);
	}
	EXPECT_EQ(static_cast<size_t>(kNumBufferedWrites),
	batch_buffer_->buffered_writes().size());

	auto pop_result = batch_buffer_->PopBufferedWrite(kNumBufferedWrites);
	EXPECT_EQ(0u, batch_buffer_->buffered_writes().size());
	EXPECT_EQ(kNumBufferedWrites, pop_result.num_buffers_popped);
	EXPECT_FALSE(pop_result.moved_remaining_buffers);
	}

	TEST_F(QuicBatchWriterBufferTest, PopPartial) {
	const int kNumBufferedWrites = 10;
	for (int i = 0; i < kNumBufferedWrites; ++i) {
	EXPECT_TRUE(batch_buffer_
	->PushBufferedWrite(FillPacketBuffer('A' + i),
	kDefaultMaxPacketSize - i, self_addr_,
	peer_addr_, nullptr)
	.succeeded);
	}

	for (size_t i = 0;
	i < kNumBufferedWrites && !batch_buffer_->buffered_writes().empty();
	++i) {
	const size_t size_before_pop = batch_buffer_->buffered_writes().size();
	const size_t expect_size_after_pop =
	size_before_pop < i ? 0 : size_before_pop - i;
	batch_buffer_->PopBufferedWrite(i);
	ASSERT_EQ(expect_size_after_pop, batch_buffer_->buffered_writes().size());
	const char first_write_content =
	'A' + kNumBufferedWrites - expect_size_after_pop;
	const size_t first_write_len =
	kDefaultMaxPacketSize - kNumBufferedWrites + expect_size_after_pop;
	for (size_t j = 0; j < expect_size_after_pop; ++j) {
	CheckBufferedWriteContent(j, first_write_content + j, first_write_len - j,
	self_addr_, peer_addr_, nullptr);
	}
	}
	}

	TEST_F(QuicBatchWriterBufferTest, InPlacePushWithPops) {
	// First, a in-place push.
	char* buffer = batch_buffer_->GetNextWriteLocation();
	const size_t first_packet_len = 2;
	auto push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('A', buffer, first_packet_len), first_packet_len,
	self_addr_, peer_addr_, nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_FALSE(push_result.buffer_copied);
	CheckBufferedWriteContent(0, 'A', first_packet_len, self_addr_, peer_addr_,
	nullptr);

	// Simulate the case where the writer wants to do another in-place push, but
	// can't do so because it can't be batched with the first buffer.
	buffer = batch_buffer_->GetNextWriteLocation();
	const size_t second_packet_len = 1350;

	// Flush the first buffer.
	auto pop_result = batch_buffer_->PopBufferedWrite(1);
	EXPECT_EQ(1, pop_result.num_buffers_popped);
	EXPECT_FALSE(pop_result.moved_remaining_buffers);

	// Now the second push.
	push_result = batch_buffer_->PushBufferedWrite(
	FillPacketBuffer('B', buffer, second_packet_len), second_packet_len,
	self_addr_, peer_addr_, nullptr);
	EXPECT_TRUE(push_result.succeeded);
	EXPECT_TRUE(push_result.buffer_copied);
	CheckBufferedWriteContent(0, 'B', second_packet_len, self_addr_, peer_addr_,
	nullptr);
	}

	} // namespace
	} // namespace test
	} // namespace quic