blob: 470c01c34fab85ed64642e8827b0cf35e896c47f [file] [log] [blame]
/*
* Copyright 2022 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "pc/data_channel_controller.h"
#include <memory>
#include "pc/peer_connection_internal.h"
#include "pc/sctp_data_channel.h"
#include "pc/test/mock_peer_connection_internal.h"
#include "rtc_base/null_socket_server.h"
#include "test/gmock.h"
#include "test/gtest.h"
#include "test/run_loop.h"
namespace webrtc {
namespace {
using ::testing::NiceMock;
using ::testing::Return;
class MockDataChannelTransport : public webrtc::DataChannelTransportInterface {
public:
~MockDataChannelTransport() override {}
MOCK_METHOD(RTCError, OpenChannel, (int channel_id), (override));
MOCK_METHOD(RTCError,
SendData,
(int channel_id,
const SendDataParams& params,
const rtc::CopyOnWriteBuffer& buffer),
(override));
MOCK_METHOD(RTCError, CloseChannel, (int channel_id), (override));
MOCK_METHOD(void, SetDataSink, (DataChannelSink * sink), (override));
MOCK_METHOD(bool, IsReadyToSend, (), (const, override));
};
class DataChannelControllerTest : public ::testing::Test {
protected:
DataChannelControllerTest()
: network_thread_(std::make_unique<rtc::NullSocketServer>()) {
network_thread_.Start();
pc_ = rtc::make_ref_counted<NiceMock<MockPeerConnectionInternal>>();
ON_CALL(*pc_, signaling_thread)
.WillByDefault(Return(rtc::Thread::Current()));
ON_CALL(*pc_, network_thread).WillByDefault(Return(&network_thread_));
}
~DataChannelControllerTest() override {
run_loop_.Flush();
network_thread_.Stop();
}
test::RunLoop run_loop_;
rtc::Thread network_thread_;
rtc::scoped_refptr<NiceMock<MockPeerConnectionInternal>> pc_;
};
TEST_F(DataChannelControllerTest, CreateAndDestroy) {
DataChannelController dcc(pc_.get());
}
TEST_F(DataChannelControllerTest, CreateDataChannelEarlyRelease) {
DataChannelController dcc(pc_.get());
auto ret = dcc.InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
ASSERT_TRUE(ret.ok());
auto channel = ret.MoveValue();
// DCC still holds a reference to the channel. Release this reference early.
channel = nullptr;
}
TEST_F(DataChannelControllerTest, CreateDataChannelEarlyClose) {
DataChannelController dcc(pc_.get());
EXPECT_FALSE(dcc.HasDataChannelsForTest());
EXPECT_FALSE(dcc.HasUsedDataChannels());
auto ret = dcc.InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
ASSERT_TRUE(ret.ok());
auto channel = ret.MoveValue();
EXPECT_TRUE(dcc.HasDataChannelsForTest());
EXPECT_TRUE(dcc.HasUsedDataChannels());
channel->Close();
EXPECT_FALSE(dcc.HasDataChannelsForTest());
EXPECT_TRUE(dcc.HasUsedDataChannels());
}
TEST_F(DataChannelControllerTest, CreateDataChannelLateRelease) {
auto dcc = std::make_unique<DataChannelController>(pc_.get());
auto ret = dcc->InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
ASSERT_TRUE(ret.ok());
auto channel = ret.MoveValue();
dcc.reset();
channel = nullptr;
}
TEST_F(DataChannelControllerTest, CloseAfterControllerDestroyed) {
auto dcc = std::make_unique<DataChannelController>(pc_.get());
auto ret = dcc->InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
ASSERT_TRUE(ret.ok());
auto channel = ret.MoveValue();
dcc.reset();
channel->Close();
}
TEST_F(DataChannelControllerTest, AsyncChannelCloseTeardown) {
DataChannelController dcc(pc_.get());
auto ret = dcc.InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
ASSERT_TRUE(ret.ok());
auto channel = ret.MoveValue();
SctpDataChannel* inner_channel =
DowncastProxiedDataChannelInterfaceToSctpDataChannelForTesting(
channel.get());
// Grab a reference for testing purposes.
inner_channel->AddRef();
channel = nullptr; // dcc still holds a reference to `channel`.
EXPECT_TRUE(dcc.HasDataChannelsForTest());
// Trigger a Close() for the channel. This will send events back to dcc,
// eventually reaching `OnSctpDataChannelClosed` where dcc removes
// the channel from the internal list of data channels, but does not release
// the reference synchronously since that reference might be the last one.
inner_channel->Close();
// Now there should be no tracked data channels.
EXPECT_FALSE(dcc.HasDataChannelsForTest());
// But there should be an async operation queued that still holds a reference.
// That means that the test reference, must not be the last one.
ASSERT_NE(inner_channel->Release(),
rtc::RefCountReleaseStatus::kDroppedLastRef);
// Grab a reference again (using the pointer is safe since the object still
// exists and we control the single-threaded environment manually).
inner_channel->AddRef();
// Now run the queued up async operations on the signaling (current) thread.
// This time, the reference formerly owned by dcc, should be release and the
// truly last reference is now held by the test.
run_loop_.Flush();
// Check that this is the last reference.
EXPECT_EQ(inner_channel->Release(),
rtc::RefCountReleaseStatus::kDroppedLastRef);
}
// Allocate the maximum number of data channels and then one more.
// The last allocation should fail.
TEST_F(DataChannelControllerTest, MaxChannels) {
NiceMock<MockDataChannelTransport> transport;
int channel_id = 0;
ON_CALL(*pc_, GetSctpSslRole_n).WillByDefault([&]() {
return absl::optional<rtc::SSLRole>((channel_id & 1) ? rtc::SSL_SERVER
: rtc::SSL_CLIENT);
});
DataChannelController dcc(pc_.get());
pc_->network_thread()->BlockingCall(
[&] { dcc.set_data_channel_transport(&transport); });
// Allocate the maximum number of channels + 1. Inside the loop, the creation
// process will allocate a stream id for each channel.
for (channel_id = 0; channel_id <= cricket::kMaxSctpStreams; ++channel_id) {
auto ret = dcc.InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()));
if (channel_id == cricket::kMaxSctpStreams) {
// We've reached the maximum and the previous call should have failed.
EXPECT_FALSE(ret.ok());
} else {
// We're still working on saturating the pool. Things should be working.
EXPECT_TRUE(ret.ok());
}
}
}
// Test that while a data channel is in the `kClosing` state, its StreamId does
// not get re-used for new channels. Only once the state reaches `kClosed`
// should a StreamId be available again for allocation.
TEST_F(DataChannelControllerTest, NoStreamIdReuseWhileClosing) {
ON_CALL(*pc_, GetSctpSslRole_n).WillByDefault([&]() {
return rtc::SSL_CLIENT;
});
DataChannelController dcc(pc_.get());
NiceMock<MockDataChannelTransport> transport;
pc_->network_thread()->BlockingCall(
[&] { dcc.set_data_channel_transport(&transport); });
// Create the first channel and check that we got the expected, first sid.
auto channel1 = dcc.InternalCreateDataChannelWithProxy(
"label", InternalDataChannelInit(DataChannelInit()))
.MoveValue();
ASSERT_EQ(channel1->id(), 0);
// Start closing the channel and make sure its state is `kClosing`
channel1->Close();
ASSERT_EQ(channel1->state(), DataChannelInterface::DataState::kClosing);
// Create a second channel and make sure we get a new StreamId, not the same
// as that of channel1.
auto channel2 = dcc.InternalCreateDataChannelWithProxy(
"label2", InternalDataChannelInit(DataChannelInit()))
.MoveValue();
ASSERT_NE(channel2->id(), channel1->id()); // In practice the id will be 2.
// Simulate the acknowledgement of the channel closing from the transport.
// This completes the closing operation of channel1.
pc_->network_thread()->BlockingCall([&] { dcc.OnChannelClosed(0); });
run_loop_.Flush();
ASSERT_EQ(channel1->state(), DataChannelInterface::DataState::kClosed);
// Now create a third channel. This time, the id of the first channel should
// be available again and therefore the ids of the first and third channels
// should be the same.
auto channel3 = dcc.InternalCreateDataChannelWithProxy(
"label3", InternalDataChannelInit(DataChannelInit()))
.MoveValue();
EXPECT_EQ(channel3->id(), channel1->id());
}
} // namespace
} // namespace webrtc