webrtc/talk/session/media/channelmanager.cc

959 lines
31 KiB
C++
Raw Normal View History

/*
* libjingle
* Copyright 2004 Google Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
* EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "talk/session/media/channelmanager.h"
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <algorithm>
#include "talk/media/base/capturemanager.h"
#include "talk/media/base/hybriddataengine.h"
#include "talk/media/base/rtpdataengine.h"
#include "talk/media/base/videocapturer.h"
#include "talk/media/devices/devicemanager.h"
#ifdef HAVE_SCTP
#include "talk/media/sctp/sctpdataengine.h"
#endif
#include "talk/session/media/soundclip.h"
#include "talk/session/media/srtpfilter.h"
#include "webrtc/base/bind.h"
#include "webrtc/base/common.h"
#include "webrtc/base/logging.h"
#include "webrtc/base/sigslotrepeater.h"
#include "webrtc/base/stringencode.h"
#include "webrtc/base/stringutils.h"
namespace cricket {
enum {
MSG_VIDEOCAPTURESTATE = 1,
};
using rtc::Bind;
static const int kNotSetOutputVolume = -1;
struct CaptureStateParams : public rtc::MessageData {
CaptureStateParams(cricket::VideoCapturer* c, cricket::CaptureState s)
: capturer(c),
state(s) {}
cricket::VideoCapturer* capturer;
cricket::CaptureState state;
};
static DataEngineInterface* ConstructDataEngine() {
#ifdef HAVE_SCTP
return new HybridDataEngine(new RtpDataEngine(), new SctpDataEngine());
#else
return new RtpDataEngine();
#endif
}
#if !defined(DISABLE_MEDIA_ENGINE_FACTORY)
ChannelManager::ChannelManager(rtc::Thread* worker_thread) {
Construct(MediaEngineFactory::Create(),
ConstructDataEngine(),
cricket::DeviceManagerFactory::Create(),
new CaptureManager(),
worker_thread);
}
#endif
ChannelManager::ChannelManager(MediaEngineInterface* me,
DataEngineInterface* dme,
DeviceManagerInterface* dm,
CaptureManager* cm,
rtc::Thread* worker_thread) {
Construct(me, dme, dm, cm, worker_thread);
}
ChannelManager::ChannelManager(MediaEngineInterface* me,
DeviceManagerInterface* dm,
rtc::Thread* worker_thread) {
Construct(me,
ConstructDataEngine(),
dm,
new CaptureManager(),
worker_thread);
}
void ChannelManager::Construct(MediaEngineInterface* me,
DataEngineInterface* dme,
DeviceManagerInterface* dm,
CaptureManager* cm,
rtc::Thread* worker_thread) {
media_engine_.reset(me);
data_media_engine_.reset(dme);
device_manager_.reset(dm);
capture_manager_.reset(cm);
initialized_ = false;
main_thread_ = rtc::Thread::Current();
worker_thread_ = worker_thread;
// Get the default audio options from the media engine.
audio_options_ = media_engine_->GetAudioOptions();
audio_in_device_ = DeviceManagerInterface::kDefaultDeviceName;
audio_out_device_ = DeviceManagerInterface::kDefaultDeviceName;
audio_delay_offset_ = kDefaultAudioDelayOffset;
audio_output_volume_ = kNotSetOutputVolume;
local_renderer_ = NULL;
capturing_ = false;
monitoring_ = false;
enable_rtx_ = false;
// Init the device manager immediately, and set up our default video device.
SignalDevicesChange.repeat(device_manager_->SignalDevicesChange);
device_manager_->Init();
// Camera is started asynchronously, request callbacks when startup
// completes to be able to forward them to the rendering manager.
media_engine_->SignalVideoCaptureStateChange().connect(
this, &ChannelManager::OnVideoCaptureStateChange);
capture_manager_->SignalCapturerStateChange.connect(
this, &ChannelManager::OnVideoCaptureStateChange);
}
ChannelManager::~ChannelManager() {
if (initialized_) {
Terminate();
// If srtp is initialized (done by the Channel) then we must call
// srtp_shutdown to free all crypto kernel lists. But we need to make sure
// shutdown always called at the end, after channels are destroyed.
// ChannelManager d'tor is always called last, it's safe place to call
// shutdown.
ShutdownSrtp();
}
}
bool ChannelManager::SetVideoRtxEnabled(bool enable) {
// To be safe, this call is only allowed before initialization. Apps like
// Flute only have a singleton ChannelManager and we don't want this flag to
// be toggled between calls or when there's concurrent calls. We expect apps
// to enable this at startup and retain that setting for the lifetime of the
// app.
if (!initialized_) {
enable_rtx_ = enable;
return true;
} else {
LOG(LS_WARNING) << "Cannot toggle rtx after initialization!";
return false;
}
}
int ChannelManager::GetCapabilities() {
return media_engine_->GetCapabilities() & device_manager_->GetCapabilities();
}
void ChannelManager::GetSupportedAudioCodecs(
std::vector<AudioCodec>* codecs) const {
codecs->clear();
for (std::vector<AudioCodec>::const_iterator it =
media_engine_->audio_codecs().begin();
it != media_engine_->audio_codecs().end(); ++it) {
codecs->push_back(*it);
}
}
void ChannelManager::GetSupportedAudioRtpHeaderExtensions(
RtpHeaderExtensions* ext) const {
*ext = media_engine_->audio_rtp_header_extensions();
}
void ChannelManager::GetSupportedVideoCodecs(
std::vector<VideoCodec>* codecs) const {
codecs->clear();
std::vector<VideoCodec>::const_iterator it;
for (it = media_engine_->video_codecs().begin();
it != media_engine_->video_codecs().end(); ++it) {
if (!enable_rtx_ && _stricmp(kRtxCodecName, it->name.c_str()) == 0) {
continue;
}
codecs->push_back(*it);
}
}
void ChannelManager::GetSupportedVideoRtpHeaderExtensions(
RtpHeaderExtensions* ext) const {
*ext = media_engine_->video_rtp_header_extensions();
}
void ChannelManager::GetSupportedDataCodecs(
std::vector<DataCodec>* codecs) const {
*codecs = data_media_engine_->data_codecs();
}
bool ChannelManager::Init() {
ASSERT(!initialized_);
if (initialized_) {
return false;
}
ASSERT(worker_thread_ != NULL);
if (worker_thread_) {
if (media_engine_->Init(worker_thread_)) {
initialized_ = true;
// Now that we're initialized, apply any stored preferences. A preferred
// device might have been unplugged. In this case, we fallback to the
// default device but keep the user preferences. The preferences are
// changed only when the Javascript FE changes them.
const std::string preferred_audio_in_device = audio_in_device_;
const std::string preferred_audio_out_device = audio_out_device_;
const std::string preferred_camera_device = camera_device_;
Device device;
if (!device_manager_->GetAudioInputDevice(audio_in_device_, &device)) {
LOG(LS_WARNING) << "The preferred microphone '" << audio_in_device_
<< "' is unavailable. Fall back to the default.";
audio_in_device_ = DeviceManagerInterface::kDefaultDeviceName;
}
if (!device_manager_->GetAudioOutputDevice(audio_out_device_, &device)) {
LOG(LS_WARNING) << "The preferred speaker '" << audio_out_device_
<< "' is unavailable. Fall back to the default.";
audio_out_device_ = DeviceManagerInterface::kDefaultDeviceName;
}
if (!device_manager_->GetVideoCaptureDevice(camera_device_, &device)) {
if (!camera_device_.empty()) {
LOG(LS_WARNING) << "The preferred camera '" << camera_device_
<< "' is unavailable. Fall back to the default.";
}
camera_device_ = DeviceManagerInterface::kDefaultDeviceName;
}
if (!SetAudioOptions(audio_in_device_, audio_out_device_,
audio_options_, audio_delay_offset_)) {
LOG(LS_WARNING) << "Failed to SetAudioOptions with"
<< " microphone: " << audio_in_device_
<< " speaker: " << audio_out_device_
<< " options: " << audio_options_.ToString()
<< " delay: " << audio_delay_offset_;
}
// If audio_output_volume_ has been set via SetOutputVolume(), set the
// audio output volume of the engine.
if (kNotSetOutputVolume != audio_output_volume_ &&
!SetOutputVolume(audio_output_volume_)) {
LOG(LS_WARNING) << "Failed to SetOutputVolume to "
<< audio_output_volume_;
}
if (!SetCaptureDevice(camera_device_) && !camera_device_.empty()) {
LOG(LS_WARNING) << "Failed to SetCaptureDevice with camera: "
<< camera_device_;
}
// Restore the user preferences.
audio_in_device_ = preferred_audio_in_device;
audio_out_device_ = preferred_audio_out_device;
camera_device_ = preferred_camera_device;
// Now apply the default video codec that has been set earlier.
if (default_video_encoder_config_.max_codec.id != 0) {
SetDefaultVideoEncoderConfig(default_video_encoder_config_);
}
}
}
return initialized_;
}
void ChannelManager::Terminate() {
ASSERT(initialized_);
if (!initialized_) {
return;
}
worker_thread_->Invoke<void>(Bind(&ChannelManager::Terminate_w, this));
media_engine_->Terminate();
initialized_ = false;
}
void ChannelManager::Terminate_w() {
ASSERT(worker_thread_ == rtc::Thread::Current());
// Need to destroy the voice/video channels
while (!video_channels_.empty()) {
DestroyVideoChannel_w(video_channels_.back());
}
while (!voice_channels_.empty()) {
DestroyVoiceChannel_w(voice_channels_.back());
}
while (!soundclips_.empty()) {
DestroySoundclip_w(soundclips_.back());
}
if (!SetCaptureDevice_w(NULL)) {
LOG(LS_WARNING) << "failed to delete video capturer";
}
}
VoiceChannel* ChannelManager::CreateVoiceChannel(
BaseSession* session, const std::string& content_name, bool rtcp) {
return worker_thread_->Invoke<VoiceChannel*>(
Bind(&ChannelManager::CreateVoiceChannel_w, this,
session, content_name, rtcp));
}
VoiceChannel* ChannelManager::CreateVoiceChannel_w(
BaseSession* session, const std::string& content_name, bool rtcp) {
// This is ok to alloc from a thread other than the worker thread
ASSERT(initialized_);
VoiceMediaChannel* media_channel = media_engine_->CreateChannel();
if (media_channel == NULL)
return NULL;
VoiceChannel* voice_channel = new VoiceChannel(
worker_thread_, media_engine_.get(), media_channel,
session, content_name, rtcp);
if (!voice_channel->Init()) {
delete voice_channel;
return NULL;
}
voice_channels_.push_back(voice_channel);
return voice_channel;
}
void ChannelManager::DestroyVoiceChannel(VoiceChannel* voice_channel) {
if (voice_channel) {
worker_thread_->Invoke<void>(
Bind(&ChannelManager::DestroyVoiceChannel_w, this, voice_channel));
}
}
void ChannelManager::DestroyVoiceChannel_w(VoiceChannel* voice_channel) {
// Destroy voice channel.
ASSERT(initialized_);
VoiceChannels::iterator it = std::find(voice_channels_.begin(),
voice_channels_.end(), voice_channel);
ASSERT(it != voice_channels_.end());
if (it == voice_channels_.end())
return;
voice_channels_.erase(it);
delete voice_channel;
}
VideoChannel* ChannelManager::CreateVideoChannel(
BaseSession* session, const std::string& content_name, bool rtcp,
VoiceChannel* voice_channel) {
return worker_thread_->Invoke<VideoChannel*>(
Bind(&ChannelManager::CreateVideoChannel_w, this, session,
content_name, rtcp, voice_channel));
}
VideoChannel* ChannelManager::CreateVideoChannel_w(
BaseSession* session, const std::string& content_name, bool rtcp,
VoiceChannel* voice_channel) {
// This is ok to alloc from a thread other than the worker thread
ASSERT(initialized_);
VideoMediaChannel* media_channel =
// voice_channel can be NULL in case of NullVoiceEngine.
media_engine_->CreateVideoChannel(voice_channel ?
voice_channel->media_channel() : NULL);
if (media_channel == NULL)
return NULL;
VideoChannel* video_channel = new VideoChannel(
worker_thread_, media_engine_.get(), media_channel,
session, content_name, rtcp, voice_channel);
if (!video_channel->Init()) {
delete video_channel;
return NULL;
}
video_channels_.push_back(video_channel);
return video_channel;
}
void ChannelManager::DestroyVideoChannel(VideoChannel* video_channel) {
if (video_channel) {
worker_thread_->Invoke<void>(
Bind(&ChannelManager::DestroyVideoChannel_w, this, video_channel));
}
}
void ChannelManager::DestroyVideoChannel_w(VideoChannel* video_channel) {
// Destroy video channel.
ASSERT(initialized_);
VideoChannels::iterator it = std::find(video_channels_.begin(),
video_channels_.end(), video_channel);
ASSERT(it != video_channels_.end());
if (it == video_channels_.end())
return;
video_channels_.erase(it);
delete video_channel;
}
DataChannel* ChannelManager::CreateDataChannel(
BaseSession* session, const std::string& content_name,
bool rtcp, DataChannelType channel_type) {
return worker_thread_->Invoke<DataChannel*>(
Bind(&ChannelManager::CreateDataChannel_w, this, session, content_name,
rtcp, channel_type));
}
DataChannel* ChannelManager::CreateDataChannel_w(
BaseSession* session, const std::string& content_name,
bool rtcp, DataChannelType data_channel_type) {
// This is ok to alloc from a thread other than the worker thread.
ASSERT(initialized_);
DataMediaChannel* media_channel = data_media_engine_->CreateChannel(
data_channel_type);
if (!media_channel) {
LOG(LS_WARNING) << "Failed to create data channel of type "
<< data_channel_type;
return NULL;
}
DataChannel* data_channel = new DataChannel(
worker_thread_, media_channel,
session, content_name, rtcp);
if (!data_channel->Init()) {
LOG(LS_WARNING) << "Failed to init data channel.";
delete data_channel;
return NULL;
}
data_channels_.push_back(data_channel);
return data_channel;
}
void ChannelManager::DestroyDataChannel(DataChannel* data_channel) {
if (data_channel) {
worker_thread_->Invoke<void>(
Bind(&ChannelManager::DestroyDataChannel_w, this, data_channel));
}
}
void ChannelManager::DestroyDataChannel_w(DataChannel* data_channel) {
// Destroy data channel.
ASSERT(initialized_);
DataChannels::iterator it = std::find(data_channels_.begin(),
data_channels_.end(), data_channel);
ASSERT(it != data_channels_.end());
if (it == data_channels_.end())
return;
data_channels_.erase(it);
delete data_channel;
}
Soundclip* ChannelManager::CreateSoundclip() {
return worker_thread_->Invoke<Soundclip*>(
Bind(&ChannelManager::CreateSoundclip_w, this));
}
Soundclip* ChannelManager::CreateSoundclip_w() {
ASSERT(initialized_);
ASSERT(worker_thread_ == rtc::Thread::Current());
SoundclipMedia* soundclip_media = media_engine_->CreateSoundclip();
if (!soundclip_media) {
return NULL;
}
Soundclip* soundclip = new Soundclip(worker_thread_, soundclip_media);
soundclips_.push_back(soundclip);
return soundclip;
}
void ChannelManager::DestroySoundclip(Soundclip* soundclip) {
if (soundclip) {
worker_thread_->Invoke<void>(
Bind(&ChannelManager::DestroySoundclip_w, this, soundclip));
}
}
void ChannelManager::DestroySoundclip_w(Soundclip* soundclip) {
// Destroy soundclip.
ASSERT(initialized_);
Soundclips::iterator it = std::find(soundclips_.begin(),
soundclips_.end(), soundclip);
ASSERT(it != soundclips_.end());
if (it == soundclips_.end())
return;
soundclips_.erase(it);
delete soundclip;
}
bool ChannelManager::GetAudioOptions(std::string* in_name,
std::string* out_name,
AudioOptions* options) {
if (in_name)
*in_name = audio_in_device_;
if (out_name)
*out_name = audio_out_device_;
if (options)
*options = audio_options_;
return true;
}
bool ChannelManager::SetAudioOptions(const std::string& in_name,
const std::string& out_name,
const AudioOptions& options) {
return SetAudioOptions(in_name, out_name, options, audio_delay_offset_);
}
bool ChannelManager::SetAudioOptions(const std::string& in_name,
const std::string& out_name,
const AudioOptions& options,
int delay_offset) {
// Get device ids from DeviceManager.
Device in_dev, out_dev;
if (!device_manager_->GetAudioInputDevice(in_name, &in_dev)) {
LOG(LS_WARNING) << "Failed to GetAudioInputDevice: " << in_name;
return false;
}
if (!device_manager_->GetAudioOutputDevice(out_name, &out_dev)) {
LOG(LS_WARNING) << "Failed to GetAudioOutputDevice: " << out_name;
return false;
}
// If we're initialized, pass the settings to the media engine.
bool ret = true;
if (initialized_) {
ret = worker_thread_->Invoke<bool>(
Bind(&ChannelManager::SetAudioOptions_w, this,
options, delay_offset, &in_dev, &out_dev));
}
// If all worked well, save the values for use in GetAudioOptions.
if (ret) {
audio_options_ = options;
audio_in_device_ = in_name;
audio_out_device_ = out_name;
audio_delay_offset_ = delay_offset;
}
return ret;
}
bool ChannelManager::SetAudioOptions_w(
const AudioOptions& options, int delay_offset,
const Device* in_dev, const Device* out_dev) {
ASSERT(worker_thread_ == rtc::Thread::Current());
ASSERT(initialized_);
// Set audio options
bool ret = media_engine_->SetAudioOptions(options);
if (ret) {
ret = media_engine_->SetAudioDelayOffset(delay_offset);
}
// Set the audio devices
if (ret) {
ret = media_engine_->SetSoundDevices(in_dev, out_dev);
}
return ret;
}
// Sets Engine-specific audio options according to enabled experiments.
bool ChannelManager::SetEngineAudioOptions(const AudioOptions& options) {
// If we're initialized, pass the settings to the media engine.
bool ret = false;
if (initialized_) {
ret = worker_thread_->Invoke<bool>(
Bind(&ChannelManager::SetEngineAudioOptions_w, this, options));
}
// If all worked well, save the audio options.
if (ret) {
audio_options_ = options;
}
return ret;
}
bool ChannelManager::SetEngineAudioOptions_w(const AudioOptions& options) {
ASSERT(worker_thread_ == rtc::Thread::Current());
ASSERT(initialized_);
return media_engine_->SetAudioOptions(options);
}
bool ChannelManager::GetOutputVolume(int* level) {
if (!initialized_) {
return false;
}
return worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::GetOutputVolume, media_engine_.get(), level));
}
bool ChannelManager::SetOutputVolume(int level) {
bool ret = level >= 0 && level <= 255;
if (initialized_) {
ret &= worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::SetOutputVolume,
media_engine_.get(), level));
}
if (ret) {
audio_output_volume_ = level;
}
return ret;
}
bool ChannelManager::IsSameCapturer(const std::string& capturer_name,
VideoCapturer* capturer) {
if (capturer == NULL) {
return false;
}
Device device;
if (!device_manager_->GetVideoCaptureDevice(capturer_name, &device)) {
return false;
}
return capturer->GetId() == device.id;
}
bool ChannelManager::GetVideoCaptureDevice(Device* device) {
std::string device_name;
if (!GetCaptureDevice(&device_name)) {
return false;
}
return device_manager_->GetVideoCaptureDevice(device_name, device);
}
bool ChannelManager::GetCaptureDevice(std::string* cam_name) {
if (camera_device_.empty()) {
// Initialize camera_device_ with default.
Device device;
if (!device_manager_->GetVideoCaptureDevice(
DeviceManagerInterface::kDefaultDeviceName, &device)) {
LOG(LS_WARNING) << "Device manager can't find default camera: " <<
DeviceManagerInterface::kDefaultDeviceName;
return false;
}
camera_device_ = device.name;
}
*cam_name = camera_device_;
return true;
}
bool ChannelManager::SetCaptureDevice(const std::string& cam_name) {
Device device;
bool ret = true;
if (!device_manager_->GetVideoCaptureDevice(cam_name, &device)) {
if (!cam_name.empty()) {
LOG(LS_WARNING) << "Device manager can't find camera: " << cam_name;
}
ret = false;
}
// If we're running, tell the media engine about it.
if (initialized_ && ret) {
ret = worker_thread_->Invoke<bool>(
Bind(&ChannelManager::SetCaptureDevice_w, this, &device));
}
// If everything worked, retain the name of the selected camera.
if (ret) {
camera_device_ = device.name;
} else if (camera_device_.empty()) {
// When video option setting fails, we still want camera_device_ to be in a
// good state, so we initialize it with default if it's empty.
Device default_device;
if (!device_manager_->GetVideoCaptureDevice(
DeviceManagerInterface::kDefaultDeviceName, &default_device)) {
LOG(LS_WARNING) << "Device manager can't find default camera: " <<
DeviceManagerInterface::kDefaultDeviceName;
}
camera_device_ = default_device.name;
}
return ret;
}
VideoCapturer* ChannelManager::CreateVideoCapturer() {
Device device;
if (!device_manager_->GetVideoCaptureDevice(camera_device_, &device)) {
if (!camera_device_.empty()) {
LOG(LS_WARNING) << "Device manager can't find camera: " << camera_device_;
}
return NULL;
}
VideoCapturer* capturer = device_manager_->CreateVideoCapturer(device);
if (capturer && default_video_encoder_config_.max_codec.id != 0) {
// For now, use the aspect ratio of the default_video_encoder_config_,
// which may be different than the native aspect ratio of the start
// format the camera may use.
capturer->UpdateAspectRatio(
default_video_encoder_config_.max_codec.width,
default_video_encoder_config_.max_codec.height);
}
return capturer;
}
VideoCapturer* ChannelManager::CreateScreenCapturer(
const ScreencastId& screenid) {
return device_manager_->CreateScreenCapturer(screenid);
}
bool ChannelManager::SetCaptureDevice_w(const Device* cam_device) {
ASSERT(worker_thread_ == rtc::Thread::Current());
ASSERT(initialized_);
if (!cam_device) {
video_device_name_.clear();
return true;
}
video_device_name_ = cam_device->name;
return true;
}
bool ChannelManager::SetDefaultVideoEncoderConfig(const VideoEncoderConfig& c) {
bool ret = true;
if (initialized_) {
ret = worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::SetDefaultVideoEncoderConfig,
media_engine_.get(), c));
}
if (ret) {
default_video_encoder_config_ = c;
}
return ret;
}
bool ChannelManager::SetLocalMonitor(bool enable) {
bool ret = initialized_ && worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::SetLocalMonitor,
media_engine_.get(), enable));
if (ret) {
monitoring_ = enable;
}
return ret;
}
void ChannelManager::SetVoiceLogging(int level, const char* filter) {
if (initialized_) {
worker_thread_->Invoke<void>(
Bind(&MediaEngineInterface::SetVoiceLogging,
media_engine_.get(), level, filter));
} else {
media_engine_->SetVoiceLogging(level, filter);
}
}
void ChannelManager::SetVideoLogging(int level, const char* filter) {
if (initialized_) {
worker_thread_->Invoke<void>(
Bind(&MediaEngineInterface::SetVideoLogging,
media_engine_.get(), level, filter));
} else {
media_engine_->SetVideoLogging(level, filter);
}
}
// TODO(janahan): For now pass this request through the mediaengine to the
// voice and video engines to do the real work. Once the capturer refactoring
// is done, we will access the capturer using the ssrc (similar to how the
// renderer is accessed today) and register with it directly.
bool ChannelManager::RegisterVideoProcessor(VideoCapturer* capturer,
VideoProcessor* processor) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&ChannelManager::RegisterVideoProcessor_w, this,
capturer, processor));
}
bool ChannelManager::RegisterVideoProcessor_w(VideoCapturer* capturer,
VideoProcessor* processor) {
return capture_manager_->AddVideoProcessor(capturer, processor);
}
bool ChannelManager::UnregisterVideoProcessor(VideoCapturer* capturer,
VideoProcessor* processor) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&ChannelManager::UnregisterVideoProcessor_w, this,
capturer, processor));
}
bool ChannelManager::UnregisterVideoProcessor_w(VideoCapturer* capturer,
VideoProcessor* processor) {
return capture_manager_->RemoveVideoProcessor(capturer, processor);
}
bool ChannelManager::RegisterVoiceProcessor(
uint32 ssrc,
VoiceProcessor* processor,
MediaProcessorDirection direction) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::RegisterVoiceProcessor, media_engine_.get(),
ssrc, processor, direction));
}
bool ChannelManager::UnregisterVoiceProcessor(
uint32 ssrc,
VoiceProcessor* processor,
MediaProcessorDirection direction) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::UnregisterVoiceProcessor,
media_engine_.get(), ssrc, processor, direction));
}
// The following are done in the new "CaptureManager" style that
// all local video capturers, processors, and managers should move
// to.
// TODO(pthatcher): Add more of the CaptureManager interface.
bool ChannelManager::StartVideoCapture(
VideoCapturer* capturer, const VideoFormat& video_format) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&CaptureManager::StartVideoCapture,
capture_manager_.get(), capturer, video_format));
}
bool ChannelManager::MuteToBlackThenPause(
VideoCapturer* video_capturer, bool muted) {
if (!initialized_) {
return false;
}
worker_thread_->Invoke<void>(
Bind(&VideoCapturer::MuteToBlackThenPause, video_capturer, muted));
return true;
}
bool ChannelManager::StopVideoCapture(
VideoCapturer* capturer, const VideoFormat& video_format) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&CaptureManager::StopVideoCapture,
capture_manager_.get(), capturer, video_format));
}
bool ChannelManager::RestartVideoCapture(
VideoCapturer* video_capturer,
const VideoFormat& previous_format,
const VideoFormat& desired_format,
CaptureManager::RestartOptions options) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&CaptureManager::RestartVideoCapture, capture_manager_.get(),
video_capturer, previous_format, desired_format, options));
}
bool ChannelManager::AddVideoRenderer(
VideoCapturer* capturer, VideoRenderer* renderer) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&CaptureManager::AddVideoRenderer,
capture_manager_.get(), capturer, renderer));
}
bool ChannelManager::RemoveVideoRenderer(
VideoCapturer* capturer, VideoRenderer* renderer) {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&CaptureManager::RemoveVideoRenderer,
capture_manager_.get(), capturer, renderer));
}
bool ChannelManager::IsScreencastRunning() const {
return initialized_ && worker_thread_->Invoke<bool>(
Bind(&ChannelManager::IsScreencastRunning_w, this));
}
bool ChannelManager::IsScreencastRunning_w() const {
VideoChannels::const_iterator it = video_channels_.begin();
for ( ; it != video_channels_.end(); ++it) {
if ((*it) && (*it)->IsScreencasting()) {
return true;
}
}
return false;
}
void ChannelManager::OnVideoCaptureStateChange(VideoCapturer* capturer,
CaptureState result) {
// TODO(whyuan): Check capturer and signal failure only for camera video, not
// screencast.
capturing_ = result == CS_RUNNING;
main_thread_->Post(this, MSG_VIDEOCAPTURESTATE,
new CaptureStateParams(capturer, result));
}
void ChannelManager::OnMessage(rtc::Message* message) {
switch (message->message_id) {
case MSG_VIDEOCAPTURESTATE: {
CaptureStateParams* data =
static_cast<CaptureStateParams*>(message->pdata);
SignalVideoCaptureStateChange(data->capturer, data->state);
delete data;
break;
}
}
}
static void GetDeviceNames(const std::vector<Device>& devs,
std::vector<std::string>* names) {
names->clear();
for (size_t i = 0; i < devs.size(); ++i) {
names->push_back(devs[i].name);
}
}
bool ChannelManager::GetAudioInputDevices(std::vector<std::string>* names) {
names->clear();
std::vector<Device> devs;
bool ret = device_manager_->GetAudioInputDevices(&devs);
if (ret)
GetDeviceNames(devs, names);
return ret;
}
bool ChannelManager::GetAudioOutputDevices(std::vector<std::string>* names) {
names->clear();
std::vector<Device> devs;
bool ret = device_manager_->GetAudioOutputDevices(&devs);
if (ret)
GetDeviceNames(devs, names);
return ret;
}
bool ChannelManager::GetVideoCaptureDevices(std::vector<std::string>* names) {
names->clear();
std::vector<Device> devs;
bool ret = device_manager_->GetVideoCaptureDevices(&devs);
if (ret)
GetDeviceNames(devs, names);
return ret;
}
void ChannelManager::SetVideoCaptureDeviceMaxFormat(
const std::string& usb_id,
const VideoFormat& max_format) {
device_manager_->SetVideoCaptureDeviceMaxFormat(usb_id, max_format);
}
VideoFormat ChannelManager::GetStartCaptureFormat() {
return worker_thread_->Invoke<VideoFormat>(
Bind(&MediaEngineInterface::GetStartCaptureFormat, media_engine_.get()));
}
bool ChannelManager::StartAecDump(rtc::PlatformFile file) {
return worker_thread_->Invoke<bool>(
Bind(&MediaEngineInterface::StartAecDump, media_engine_.get(), file));
}
} // namespace cricket