blob: c9babc7b79df5ab512ed7033fbe5a0cc6e313735 [file] [log] [blame]
/*
* Copyright 2018 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 "test/scenario/call_client.h"
#include <iostream>
#include <memory>
#include <utility>
#include "api/rtc_event_log/rtc_event_log.h"
#include "api/rtc_event_log/rtc_event_log_factory.h"
#include "api/transport/network_types.h"
#include "call/call.h"
#include "call/rtp_transport_controller_send_factory.h"
#include "modules/audio_mixer/audio_mixer_impl.h"
#include "modules/rtp_rtcp/source/rtp_util.h"
namespace webrtc {
namespace test {
namespace {
static constexpr size_t kNumSsrcs = 6;
const uint32_t kSendRtxSsrcs[kNumSsrcs] = {0xBADCAFD, 0xBADCAFE, 0xBADCAFF,
0xBADCB00, 0xBADCB01, 0xBADCB02};
const uint32_t kVideoSendSsrcs[kNumSsrcs] = {0xC0FFED, 0xC0FFEE, 0xC0FFEF,
0xC0FFF0, 0xC0FFF1, 0xC0FFF2};
const uint32_t kVideoRecvLocalSsrcs[kNumSsrcs] = {0xDAB001, 0xDAB002, 0xDAB003,
0xDAB004, 0xDAB005, 0xDAB006};
const uint32_t kAudioSendSsrc = 0xDEADBEEF;
const uint32_t kReceiverLocalAudioSsrc = 0x1234567;
constexpr int kEventLogOutputIntervalMs = 5000;
CallClientFakeAudio InitAudio(TimeController* time_controller) {
CallClientFakeAudio setup;
auto capturer = TestAudioDeviceModule::CreatePulsedNoiseCapturer(256, 48000);
auto renderer = TestAudioDeviceModule::CreateDiscardRenderer(48000);
setup.fake_audio_device = TestAudioDeviceModule::Create(
time_controller->GetTaskQueueFactory(), std::move(capturer),
std::move(renderer), 1.f);
setup.apm = AudioProcessingBuilder().Create();
setup.fake_audio_device->Init();
AudioState::Config audio_state_config;
audio_state_config.audio_mixer = AudioMixerImpl::Create();
audio_state_config.audio_processing = setup.apm;
audio_state_config.audio_device_module = setup.fake_audio_device;
setup.audio_state = AudioState::Create(audio_state_config);
setup.fake_audio_device->RegisterAudioCallback(
setup.audio_state->audio_transport());
return setup;
}
Call* CreateCall(TimeController* time_controller,
RtcEventLog* event_log,
CallClientConfig config,
LoggingNetworkControllerFactory* network_controller_factory,
rtc::scoped_refptr<AudioState> audio_state) {
CallConfig call_config(event_log);
call_config.bitrate_config.max_bitrate_bps =
config.transport.rates.max_rate.bps_or(-1);
call_config.bitrate_config.min_bitrate_bps =
config.transport.rates.min_rate.bps();
call_config.bitrate_config.start_bitrate_bps =
config.transport.rates.start_rate.bps();
call_config.task_queue_factory = time_controller->GetTaskQueueFactory();
call_config.network_controller_factory = network_controller_factory;
call_config.audio_state = audio_state;
call_config.trials = config.field_trials;
Clock* clock = time_controller->GetClock();
return Call::Create(call_config, clock,
RtpTransportControllerSendFactory().Create(
call_config.ExtractTransportConfig(), clock));
}
std::unique_ptr<RtcEventLog> CreateEventLog(
TaskQueueFactory* task_queue_factory,
LogWriterFactoryInterface* log_writer_factory) {
if (!log_writer_factory) {
return std::make_unique<RtcEventLogNull>();
}
auto event_log = RtcEventLogFactory(task_queue_factory)
.CreateRtcEventLog(RtcEventLog::EncodingType::NewFormat);
bool success = event_log->StartLogging(log_writer_factory->Create(".rtc.dat"),
kEventLogOutputIntervalMs);
RTC_CHECK(success);
return event_log;
}
} // namespace
NetworkControleUpdateCache::NetworkControleUpdateCache(
std::unique_ptr<NetworkControllerInterface> controller)
: controller_(std::move(controller)) {}
NetworkControlUpdate NetworkControleUpdateCache::OnNetworkAvailability(
NetworkAvailability msg) {
return Update(controller_->OnNetworkAvailability(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnNetworkRouteChange(
NetworkRouteChange msg) {
return Update(controller_->OnNetworkRouteChange(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnProcessInterval(
ProcessInterval msg) {
return Update(controller_->OnProcessInterval(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnRemoteBitrateReport(
RemoteBitrateReport msg) {
return Update(controller_->OnRemoteBitrateReport(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnRoundTripTimeUpdate(
RoundTripTimeUpdate msg) {
return Update(controller_->OnRoundTripTimeUpdate(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnSentPacket(SentPacket msg) {
return Update(controller_->OnSentPacket(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnReceivedPacket(
ReceivedPacket msg) {
return Update(controller_->OnReceivedPacket(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnStreamsConfig(
StreamsConfig msg) {
return Update(controller_->OnStreamsConfig(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnTargetRateConstraints(
TargetRateConstraints msg) {
return Update(controller_->OnTargetRateConstraints(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnTransportLossReport(
TransportLossReport msg) {
return Update(controller_->OnTransportLossReport(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnTransportPacketsFeedback(
TransportPacketsFeedback msg) {
return Update(controller_->OnTransportPacketsFeedback(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::OnNetworkStateEstimate(
NetworkStateEstimate msg) {
return Update(controller_->OnNetworkStateEstimate(msg));
}
NetworkControlUpdate NetworkControleUpdateCache::update_state() const {
return update_state_;
}
NetworkControlUpdate NetworkControleUpdateCache::Update(
NetworkControlUpdate update) {
if (update.target_rate)
update_state_.target_rate = update.target_rate;
if (update.pacer_config)
update_state_.pacer_config = update.pacer_config;
if (update.congestion_window)
update_state_.congestion_window = update.congestion_window;
if (!update.probe_cluster_configs.empty())
update_state_.probe_cluster_configs = update.probe_cluster_configs;
return update;
}
LoggingNetworkControllerFactory::LoggingNetworkControllerFactory(
LogWriterFactoryInterface* log_writer_factory,
TransportControllerConfig config) {
if (config.cc_factory) {
cc_factory_ = config.cc_factory;
if (log_writer_factory)
RTC_LOG(LS_WARNING)
<< "Can't log controller state for injected network controllers";
} else {
if (log_writer_factory) {
goog_cc_factory_.AttachWriter(
log_writer_factory->Create(".cc_state.txt"));
print_cc_state_ = true;
}
cc_factory_ = &goog_cc_factory_;
}
}
LoggingNetworkControllerFactory::~LoggingNetworkControllerFactory() {}
void LoggingNetworkControllerFactory::LogCongestionControllerStats(
Timestamp at_time) {
if (print_cc_state_)
goog_cc_factory_.PrintState(at_time);
}
NetworkControlUpdate LoggingNetworkControllerFactory::GetUpdate() const {
if (last_controller_)
return last_controller_->update_state();
return NetworkControlUpdate();
}
std::unique_ptr<NetworkControllerInterface>
LoggingNetworkControllerFactory::Create(NetworkControllerConfig config) {
auto controller =
std::make_unique<NetworkControleUpdateCache>(cc_factory_->Create(config));
last_controller_ = controller.get();
return controller;
}
TimeDelta LoggingNetworkControllerFactory::GetProcessInterval() const {
return cc_factory_->GetProcessInterval();
}
void LoggingNetworkControllerFactory::SetRemoteBitrateEstimate(
RemoteBitrateReport msg) {
if (last_controller_)
last_controller_->OnRemoteBitrateReport(msg);
}
CallClient::CallClient(
TimeController* time_controller,
std::unique_ptr<LogWriterFactoryInterface> log_writer_factory,
CallClientConfig config)
: time_controller_(time_controller),
clock_(time_controller->GetClock()),
log_writer_factory_(std::move(log_writer_factory)),
network_controller_factory_(log_writer_factory_.get(), config.transport),
task_queue_(time_controller->GetTaskQueueFactory()->CreateTaskQueue(
"CallClient",
TaskQueueFactory::Priority::NORMAL)) {
config.field_trials = &field_trials_;
SendTask([this, config] {
event_log_ = CreateEventLog(time_controller_->GetTaskQueueFactory(),
log_writer_factory_.get());
fake_audio_setup_ = InitAudio(time_controller_);
call_.reset(CreateCall(time_controller_, event_log_.get(), config,
&network_controller_factory_,
fake_audio_setup_.audio_state));
transport_ = std::make_unique<NetworkNodeTransport>(clock_, call_.get());
});
}
CallClient::~CallClient() {
SendTask([&] {
call_.reset();
fake_audio_setup_ = {};
rtc::Event done;
event_log_->StopLogging([&done] { done.Set(); });
done.Wait(rtc::Event::kForever);
event_log_.reset();
});
}
ColumnPrinter CallClient::StatsPrinter() {
return ColumnPrinter::Lambda(
"pacer_delay call_send_bw",
[this](rtc::SimpleStringBuilder& sb) {
Call::Stats call_stats = call_->GetStats();
sb.AppendFormat("%.3lf %.0lf", call_stats.pacer_delay_ms / 1000.0,
call_stats.send_bandwidth_bps / 8.0);
},
64);
}
Call::Stats CallClient::GetStats() {
// This call needs to be made on the thread that `call_` was constructed on.
Call::Stats stats;
SendTask([this, &stats] { stats = call_->GetStats(); });
return stats;
}
DataRate CallClient::target_rate() const {
return network_controller_factory_.GetUpdate().target_rate->target_rate;
}
DataRate CallClient::stable_target_rate() const {
return network_controller_factory_.GetUpdate()
.target_rate->stable_target_rate;
}
DataRate CallClient::padding_rate() const {
return network_controller_factory_.GetUpdate().pacer_config->pad_rate();
}
void CallClient::SetRemoteBitrate(DataRate bitrate) {
RemoteBitrateReport msg;
msg.bandwidth = bitrate;
msg.receive_time = clock_->CurrentTime();
network_controller_factory_.SetRemoteBitrateEstimate(msg);
}
void CallClient::UpdateBitrateConstraints(
const BitrateConstraints& constraints) {
SendTask([this, &constraints]() {
call_->GetTransportControllerSend()->SetSdpBitrateParameters(constraints);
});
}
void CallClient::OnPacketReceived(EmulatedIpPacket packet) {
MediaType media_type = MediaType::ANY;
if (IsRtpPacket(packet.data)) {
media_type = ssrc_media_types_[ParseRtpSsrc(packet.data)];
}
task_queue_.PostTask(
[call = call_.get(), media_type, packet = std::move(packet)]() mutable {
call->Receiver()->DeliverPacket(media_type, packet.data,
packet.arrival_time.us());
});
}
std::unique_ptr<RtcEventLogOutput> CallClient::GetLogWriter(std::string name) {
if (!log_writer_factory_ || name.empty())
return nullptr;
return log_writer_factory_->Create(name);
}
uint32_t CallClient::GetNextVideoSsrc() {
RTC_CHECK_LT(next_video_ssrc_index_, kNumSsrcs);
return kVideoSendSsrcs[next_video_ssrc_index_++];
}
uint32_t CallClient::GetNextVideoLocalSsrc() {
RTC_CHECK_LT(next_video_local_ssrc_index_, kNumSsrcs);
return kVideoRecvLocalSsrcs[next_video_local_ssrc_index_++];
}
uint32_t CallClient::GetNextAudioSsrc() {
RTC_CHECK_LT(next_audio_ssrc_index_, 1);
next_audio_ssrc_index_++;
return kAudioSendSsrc;
}
uint32_t CallClient::GetNextAudioLocalSsrc() {
RTC_CHECK_LT(next_audio_local_ssrc_index_, 1);
next_audio_local_ssrc_index_++;
return kReceiverLocalAudioSsrc;
}
uint32_t CallClient::GetNextRtxSsrc() {
RTC_CHECK_LT(next_rtx_ssrc_index_, kNumSsrcs);
return kSendRtxSsrcs[next_rtx_ssrc_index_++];
}
void CallClient::SendTask(std::function<void()> task) {
task_queue_.SendTask(std::move(task));
}
int16_t CallClient::Bind(EmulatedEndpoint* endpoint) {
uint16_t port = endpoint->BindReceiver(0, this).value();
endpoints_.push_back({endpoint, port});
return port;
}
void CallClient::UnBind() {
for (auto ep_port : endpoints_)
ep_port.first->UnbindReceiver(ep_port.second);
}
CallClientPair::~CallClientPair() = default;
} // namespace test
} // namespace webrtc