// 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 "jingle/glue/pseudotcp_adapter.h"
#include <vector>
#include "base/bind.h"
#include "base/bind_helpers.h"
#include "base/compiler_specific.h"
#include "jingle/glue/thread_wrapper.h"
#include "net/base/io_buffer.h"
#include "net/base/net_errors.h"
#include "net/base/test_completion_callback.h"
#include "net/udp/udp_socket.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace jingle_glue {
namespace {
class FakeSocket;
} // namespace
} // namespace jingle_glue
namespace jingle_glue {
namespace {
const int kMessageSize = 1024;
const int kMessages = 100;
const int kTestDataSize = kMessages * kMessageSize;
class RateLimiter {
public:
virtual ~RateLimiter() { };
// Returns true if the new packet needs to be dropped, false otherwise.
virtual bool DropNextPacket() = 0;
};
class LeakyBucket : public RateLimiter {
public:
// |rate| is in drops per second.
LeakyBucket(double volume, double rate)
: volume_(volume),
rate_(rate),
level_(0.0),
last_update_(base::TimeTicks::HighResNow()) {
}
virtual ~LeakyBucket() { }
virtual bool DropNextPacket() OVERRIDE {
base::TimeTicks now = base::TimeTicks::HighResNow();
double interval = (now - last_update_).InSecondsF();
last_update_ = now;
level_ = level_ + 1.0 - interval * rate_;
if (level_ > volume_) {
level_ = volume_;
return true;
} else if (level_ < 0.0) {
level_ = 0.0;
}
return false;
}
private:
double volume_;
double rate_;
double level_;
base::TimeTicks last_update_;
};
class FakeSocket : public net::Socket {
public:
FakeSocket()
: rate_limiter_(NULL),
latency_ms_(0) {
}
virtual ~FakeSocket() { }
void AppendInputPacket(const std::vector<char>& data) {
if (rate_limiter_ && rate_limiter_->DropNextPacket())
return; // Lose the packet.
if (!read_callback_.is_null()) {
int size = std::min(read_buffer_size_, static_cast<int>(data.size()));
memcpy(read_buffer_->data(), &data[0], data.size());
net::CompletionCallback cb = read_callback_;
read_callback_.Reset();
read_buffer_ = NULL;
cb.Run(size);
} else {
incoming_packets_.push_back(data);
}
}
void Connect(FakeSocket* peer_socket) {
peer_socket_ = peer_socket;
}
void set_rate_limiter(RateLimiter* rate_limiter) {
rate_limiter_ = rate_limiter;
};
void set_latency(int latency_ms) { latency_ms_ = latency_ms; };
// net::Socket interface.
virtual int Read(net::IOBuffer* buf, int buf_len,
const net::CompletionCallback& callback) OVERRIDE {
CHECK(read_callback_.is_null());
CHECK(buf);
if (incoming_packets_.size() > 0) {
scoped_refptr<net::IOBuffer> buffer(buf);
int size = std::min(
static_cast<int>(incoming_packets_.front().size()), buf_len);
memcpy(buffer->data(), &*incoming_packets_.front().begin(), size);
incoming_packets_.pop_front();
return size;
} else {
read_callback_ = callback;
read_buffer_ = buf;
read_buffer_size_ = buf_len;
return net::ERR_IO_PENDING;
}
}
virtual int Write(net::IOBuffer* buf, int buf_len,
const net::CompletionCallback& callback) OVERRIDE {
DCHECK(buf);
if (peer_socket_) {
base::MessageLoop::current()->PostDelayedTask(
FROM_HERE,
base::Bind(&FakeSocket::AppendInputPacket,
base::Unretained(peer_socket_),
std::vector<char>(buf->data(), buf->data() + buf_len)),
base::TimeDelta::FromMilliseconds(latency_ms_));
}
return buf_len;
}
virtual bool SetReceiveBufferSize(int32 size) OVERRIDE {
NOTIMPLEMENTED();
return false;
}
virtual bool SetSendBufferSize(int32 size) OVERRIDE {
NOTIMPLEMENTED();
return false;
}
private:
scoped_refptr<net::IOBuffer> read_buffer_;
int read_buffer_size_;
net::CompletionCallback read_callback_;
std::deque<std::vector<char> > incoming_packets_;
FakeSocket* peer_socket_;
RateLimiter* rate_limiter_;
int latency_ms_;
};
class TCPChannelTester : public base::RefCountedThreadSafe<TCPChannelTester> {
public:
TCPChannelTester(base::MessageLoop* message_loop,
net::Socket* client_socket,
net::Socket* host_socket)
: message_loop_(message_loop),
host_socket_(host_socket),
client_socket_(client_socket),
done_(false),
write_errors_(0),
read_errors_(0) {}
void Start() {
message_loop_->PostTask(
FROM_HERE, base::Bind(&TCPChannelTester::DoStart, this));
}
void CheckResults() {
EXPECT_EQ(0, write_errors_);
EXPECT_EQ(0, read_errors_);
ASSERT_EQ(kTestDataSize + kMessageSize, input_buffer_->capacity());
output_buffer_->SetOffset(0);
ASSERT_EQ(kTestDataSize, output_buffer_->size());
EXPECT_EQ(0, memcmp(output_buffer_->data(),
input_buffer_->StartOfBuffer(), kTestDataSize));
}
protected:
virtual ~TCPChannelTester() {}
void Done() {
done_ = true;
message_loop_->PostTask(FROM_HERE, base::MessageLoop::QuitClosure());
}
void DoStart() {
InitBuffers();
DoRead();
DoWrite();
}
void InitBuffers() {
output_buffer_ = new net::DrainableIOBuffer(
new net::IOBuffer(kTestDataSize), kTestDataSize);
memset(output_buffer_->data(), 123, kTestDataSize);
input_buffer_ = new net::GrowableIOBuffer();
// Always keep kMessageSize bytes available at the end of the input buffer.
input_buffer_->SetCapacity(kMessageSize);
}
void DoWrite() {
int result = 1;
while (result > 0) {
if (output_buffer_->BytesRemaining() == 0)
break;
int bytes_to_write = std::min(output_buffer_->BytesRemaining(),
kMessageSize);
result = client_socket_->Write(
output_buffer_.get(),
bytes_to_write,
base::Bind(&TCPChannelTester::OnWritten, base::Unretained(this)));
HandleWriteResult(result);
}
}
void OnWritten(int result) {
HandleWriteResult(result);
DoWrite();
}
void HandleWriteResult(int result) {
if (result <= 0 && result != net::ERR_IO_PENDING) {
LOG(ERROR) << "Received error " << result << " when trying to write";
write_errors_++;
Done();
} else if (result > 0) {
output_buffer_->DidConsume(result);
}
}
void DoRead() {
int result = 1;
while (result > 0) {
input_buffer_->set_offset(input_buffer_->capacity() - kMessageSize);
result = host_socket_->Read(
input_buffer_.get(),
kMessageSize,
base::Bind(&TCPChannelTester::OnRead, base::Unretained(this)));
HandleReadResult(result);
};
}
void OnRead(int result) {
HandleReadResult(result);
DoRead();
}
void HandleReadResult(int result) {
if (result <= 0 && result != net::ERR_IO_PENDING) {
if (!done_) {
LOG(ERROR) << "Received error " << result << " when trying to read";
read_errors_++;
Done();
}
} else if (result > 0) {
// Allocate memory for the next read.
input_buffer_->SetCapacity(input_buffer_->capacity() + result);
if (input_buffer_->capacity() == kTestDataSize + kMessageSize)
Done();
}
}
private:
friend class base::RefCountedThreadSafe<TCPChannelTester>;
base::MessageLoop* message_loop_;
net::Socket* host_socket_;
net::Socket* client_socket_;
bool done_;
scoped_refptr<net::DrainableIOBuffer> output_buffer_;
scoped_refptr<net::GrowableIOBuffer> input_buffer_;
int write_errors_;
int read_errors_;
};
class PseudoTcpAdapterTest : public testing::Test {
protected:
virtual void SetUp() OVERRIDE {
JingleThreadWrapper::EnsureForCurrentMessageLoop();
host_socket_ = new FakeSocket();
client_socket_ = new FakeSocket();
host_socket_->Connect(client_socket_);
client_socket_->Connect(host_socket_);
host_pseudotcp_.reset(new PseudoTcpAdapter(host_socket_));
client_pseudotcp_.reset(new PseudoTcpAdapter(client_socket_));
}
FakeSocket* host_socket_;
FakeSocket* client_socket_;
scoped_ptr<PseudoTcpAdapter> host_pseudotcp_;
scoped_ptr<PseudoTcpAdapter> client_pseudotcp_;
base::MessageLoop message_loop_;
};
TEST_F(PseudoTcpAdapterTest, DataTransfer) {
net::TestCompletionCallback host_connect_cb;
net::TestCompletionCallback client_connect_cb;
int rv1 = host_pseudotcp_->Connect(host_connect_cb.callback());
int rv2 = client_pseudotcp_->Connect(client_connect_cb.callback());
if (rv1 == net::ERR_IO_PENDING)
rv1 = host_connect_cb.WaitForResult();
if (rv2 == net::ERR_IO_PENDING)
rv2 = client_connect_cb.WaitForResult();
ASSERT_EQ(net::OK, rv1);
ASSERT_EQ(net::OK, rv2);
scoped_refptr<TCPChannelTester> tester =
new TCPChannelTester(&message_loop_, host_pseudotcp_.get(),
client_pseudotcp_.get());
tester->Start();
message_loop_.Run();
tester->CheckResults();
}
TEST_F(PseudoTcpAdapterTest, LimitedChannel) {
const int kLatencyMs = 20;
const int kPacketsPerSecond = 400;
const int kBurstPackets = 10;
LeakyBucket host_limiter(kBurstPackets, kPacketsPerSecond);
host_socket_->set_latency(kLatencyMs);
host_socket_->set_rate_limiter(&host_limiter);
LeakyBucket client_limiter(kBurstPackets, kPacketsPerSecond);
host_socket_->set_latency(kLatencyMs);
client_socket_->set_rate_limiter(&client_limiter);
net::TestCompletionCallback host_connect_cb;
net::TestCompletionCallback client_connect_cb;
int rv1 = host_pseudotcp_->Connect(host_connect_cb.callback());
int rv2 = client_pseudotcp_->Connect(client_connect_cb.callback());
if (rv1 == net::ERR_IO_PENDING)
rv1 = host_connect_cb.WaitForResult();
if (rv2 == net::ERR_IO_PENDING)
rv2 = client_connect_cb.WaitForResult();
ASSERT_EQ(net::OK, rv1);
ASSERT_EQ(net::OK, rv2);
scoped_refptr<TCPChannelTester> tester =
new TCPChannelTester(&message_loop_, host_pseudotcp_.get(),
client_pseudotcp_.get());
tester->Start();
message_loop_.Run();
tester->CheckResults();
}
class DeleteOnConnected {
public:
DeleteOnConnected(base::MessageLoop* message_loop,
scoped_ptr<PseudoTcpAdapter>* adapter)
: message_loop_(message_loop), adapter_(adapter) {}
void OnConnected(int error) {
adapter_->reset();
message_loop_->PostTask(FROM_HERE, base::MessageLoop::QuitClosure());
}
base::MessageLoop* message_loop_;
scoped_ptr<PseudoTcpAdapter>* adapter_;
};
TEST_F(PseudoTcpAdapterTest, DeleteOnConnected) {
// This test verifies that deleting the adapter mid-callback doesn't lead
// to deleted structures being touched as the stack unrolls, so the failure
// mode is a crash rather than a normal test failure.
net::TestCompletionCallback client_connect_cb;
DeleteOnConnected host_delete(&message_loop_, &host_pseudotcp_);
host_pseudotcp_->Connect(base::Bind(&DeleteOnConnected::OnConnected,
base::Unretained(&host_delete)));
client_pseudotcp_->Connect(client_connect_cb.callback());
message_loop_.Run();
ASSERT_EQ(NULL, host_pseudotcp_.get());
}
// Verify that we can send/receive data with the write-waits-for-send
// flag set.
TEST_F(PseudoTcpAdapterTest, WriteWaitsForSendLetsDataThrough) {
net::TestCompletionCallback host_connect_cb;
net::TestCompletionCallback client_connect_cb;
host_pseudotcp_->SetWriteWaitsForSend(true);
client_pseudotcp_->SetWriteWaitsForSend(true);
// Disable Nagle's algorithm because the test is slow when it is
// enabled.
host_pseudotcp_->SetNoDelay(true);
int rv1 = host_pseudotcp_->Connect(host_connect_cb.callback());
int rv2 = client_pseudotcp_->Connect(client_connect_cb.callback());
if (rv1 == net::ERR_IO_PENDING)
rv1 = host_connect_cb.WaitForResult();
if (rv2 == net::ERR_IO_PENDING)
rv2 = client_connect_cb.WaitForResult();
ASSERT_EQ(net::OK, rv1);
ASSERT_EQ(net::OK, rv2);
scoped_refptr<TCPChannelTester> tester =
new TCPChannelTester(&message_loop_, host_pseudotcp_.get(),
client_pseudotcp_.get());
tester->Start();
message_loop_.Run();
tester->CheckResults();
}
} // namespace
} // namespace jingle_glue