一、 简介
多媒体播放框架次要的实现在PlayerServer服务中,这个服务提供了媒体播放框架所须要的实现环境,持续跟踪代码剖析发现,PlayerServer次要通过gstreamer适配层,对gstreamer进行调用。gstreamer属于更加具体的实现,所以本篇文章次要是剖析PlayerServer通过适配层调用到gstreamer的过程。
此前,我在《OpenHarmony 3.2 Beta多媒体系列-音视频播放框架》一文中,次要剖析了多媒体播放的框架层代码,本地接口通过服务端的proxy代理类进行IPC调用,最终调用到PlayerServer服务端。本篇次要剖析了多媒体gstreamer的调用,波及到从PlayerServer到gstreamer的整体流程。
二、 目录
gstreamer
├── BUILD.gn
├── common
│ ├── BUILD.gn
│ ├── playbin_adapter
│ │ ├── i_playbin_ctrler.h
│ │ ├── playbin2_ctrler.cpp
│ │ ├── playbin2_ctrler.h
│ │ ├── playbin_ctrler_base.cpp
│ │ ├── playbin_ctrler_base.h
│ │ ├── playbin_msg_define.h
│ │ ├── playbin_sink_provider.h
│ │ ├── playbin_state.cpp
│ │ ├── playbin_state.h
│ │ ├── playbin_task_mgr.cpp
│ │ └── playbin_task_mgr.h
│ ├── state_machine
│ │ ├── state_machine.cpp
│ │ └── state_machine.h
├── factory
│ ├── BUILD.gn
│ └── engine_factory.cpp
└── player
├── BUILD.gn
├── player_codec_ctrl.cpp
├── player_codec_ctrl.h
├── player_engine_gst_impl.cpp
├── player_engine_gst_impl.h
├── player_sinkprovider.cpp
├── player_sinkprovider.h
├── player_track_parse.cpp
└── player_track_parse.h
目录次要是多媒体子系统中的engine局部,波及到了gstreamer的适配层,gstreamer具体的实现是在third_party/gstreamer目录中。
三 、Gstreamer介绍
- 简介
Gstreamer是一个跨平台的多媒体框架,应用程序能够通过管道(Pipeline)的形式,将多媒体解决的各个步骤串联起来,达到预期的成果。每个步骤通过元素(Element)基于GObject对象零碎通过插件(plugins)的形式实现,不便了各项性能的扩大。
2.Gstreamer几个重要的概念
Element
Element是Gstreamer中最重要的对象类型之一。一个element实现一个性能(读取文件,解码,输入等),程序须要创立多个element,并按程序将其串联起来,形成一个残缺的Pipeline。
Pad
Pad是一个element的输出/输入接口,分为src pad(生产数据)和sink pad(生产数据)两种。
两个element必须通过pad能力连接起来,pad领有以后element能解决数据类型的能力(capabilities),会在连贯时通过比拟src pad和sink pad中所反对的能力,来抉择最失当的数据类型用于传输,如果element不反对,程序会间接退出。在element通过pad连贯胜利后,数据会从上一个element的src pad传到下一个element的sink pad而后进行解决。
Bin和Pipeline
Bin是一个容器,用于治理多个element,扭转bin的状态时,bin会主动去批改所蕴含的element的状态,也会转发所收到的音讯。如果没有bin,咱们须要顺次操作咱们所应用的element。通过bin升高了利用的复杂度。
Pipeline继承自bin,为程序提供一个bus用于传输音讯,并且对所有子element进行同步。当将Pipeline的状态设置为PLAYING时,Pipeline会在一个/多个新的线程中通过element解决数据。
四、调用流程
五、源码剖析
-
PrepareAsync剖析
首先,在PlayerServer的PrepareAsync中会调用OnPrepare(false),具体是在OnPrepare(false)中实现,参数传入false,表明调用的是异步办法。int32_t PlayerServer::PrepareAsync() { std::lock_guard<std::mutex> lock(mutex_); MEDIA_LOGW("KPI-TRACE: PlayerServer PrepareAsync in"); if (lastOpStatus_ == PLAYER_INITIALIZED || lastOpStatus_ == PLAYER_STOPPED) { return OnPrepare(false); } else { MEDIA_LOGE("Can not Prepare, currentState is %{public}s", GetStatusDescription(lastOpStatus_).c_str()); return MSERR_INVALID_OPERATION; } }OnPrepare办法中,先通过playerEngine_调用SerVideoSurface的办法,将surface_设置到PlayerEngineGstImpl中(producerSurface_),接着启动一个工作,调用目前状态的Prepare()办法。
int32_t PlayerServer::OnPrepare(bool sync) { CHECK_AND_RETURN_RET_LOG(playerEngine_ != nullptr, MSERR_NO_MEMORY, "playerEngine_ is nullptr"); int32_t ret = MSERR_OK; #ifdef SUPPORT_VIDEO if (surface_ != nullptr) { ret = playerEngine_->SetVideoSurface(surface_); CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, MSERR_INVALID_OPERATION, "Engine SetVideoSurface Failed!"); } #endif lastOpStatus_ = PLAYER_PREPARED; auto preparedTask = std::make_shared<TaskHandler<int32_t>>([this]() { MediaTrace::TraceBegin("PlayerServer::PrepareAsync", FAKE_POINTER(this)); auto currState = std::static_pointer_cast<BaseState>(GetCurrState()); return currState->Prepare(); }); ret = taskMgr_.LaunchTask(preparedTask, PlayerServerTaskType::STATE_CHANGE); CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, ret, "Prepare launch task failed"); if (sync) { (void)preparedTask->GetResult(); // wait HandlePrpare } return MSERR_OK; }
进入Preparing状态后,会触发PlayerServer的HandlePrepare()办法被调用,在这个办法里会通过playerEngine_调用PrepareAsync办法,这个办法调用的是PlayerEngineGstImpl对应的PrepareAsync办法。
int32_t PlayerServer::HandlePrepare()
{
int32_t ret = playerEngine_->PrepareAsync();
CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, MSERR_INVALID_OPERATION, "Server Prepare Failed!");
if (config_.leftVolume <= 1.0f || config_.rightVolume <= 1.0f) {
ret = playerEngine_->SetVolume(config_.leftVolume, config_.rightVolume);
MEDIA_LOGD("Prepared SetVolume leftVolume:%{public}f rightVolume:%{public}f, ret:%{public}d", \
config_.leftVolume, config_.rightVolume, ret);
}
(void)playerEngine_->SetLooping(config_.looping);
{
auto rateTask = std::make_shared<TaskHandler<void>>([this]() {
auto currState = std::static_pointer_cast<BaseState>(GetCurrState());
(void)currState->SetPlaybackSpeed(config_.speedMode);
});
(void)taskMgr_.LaunchTask(rateTask, PlayerServerTaskType::RATE_CHANGE);
}
return MSERR_OK;
}
首先初始化playBinCtrler_,后续的操作都是通过PlayBinCtrlerBase对象来操作的,所以PlayBinCtrlerInit()办法会创立PlayBinCtrlerBase对象(playBinCtrler_),创立好当前通过playBinCtrler_进行SetSource和SetXXXListener的设置。
int32_t PlayerEngineGstImpl::PrepareAsync()
{
std::unique_lock<std::mutex> lock(mutex_);
MEDIA_LOGD("Prepare in");
int32_t ret = PlayBinCtrlerInit();
CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, MSERR_INVALID_VAL, "PlayBinCtrlerInit failed");
CHECK_AND_RETURN_RET_LOG(playBinCtrler_ != nullptr, MSERR_INVALID_VAL, "playBinCtrler_ is nullptr");
ret = playBinCtrler_->PrepareAsync();
CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, ret, "PrepareAsync failed");
// The duration of some resources without header information cannot be obtained.
MEDIA_LOGD("Prepared ok out");
return MSERR_OK;
}
初始化实现当前,接下来进行playBinCtrler_的PrepareAsync的调用,PlayBinCtrlerBase中的PrepareAsync的办法间接地调用了PrepareAsyncInternal。
int32_t PlayBinCtrlerBase::PrepareAsync()
{
MEDIA_LOGD("enter");
std::unique_lock<std::mutex> lock(mutex_);
return PrepareAsyncInternal();
}
PrepareAsyncInternal首先判断以后的状态,如果是preparingState或preparedState,那么就间接返回胜利,否则持续向下调用。接下来会调用EnterInitializedState(),这个办法中会创立playbin,设置signal的回调以及gstreamer参数的设置。最初调用目前状态的Prepare办法,此时的状态是InitializedState。
int32_t PlayBinCtrlerBase::PrepareAsyncInternal()
{
if ((GetCurrState() == preparingState_) || (GetCurrState() == preparedState_)) {
MEDIA_LOGI("already at preparing state, skip");
return MSERR_OK;
}
CHECK_AND_RETURN_RET_LOG((!uri_.empty() || appsrcWrap_), MSERR_INVALID_OPERATION, "Set uri firsty!");
int32_t ret = EnterInitializedState();
CHECK_AND_RETURN_RET(ret == MSERR_OK, ret);
auto currState = std::static_pointer_cast<BaseState>(GetCurrState());
ret = currState->Prepare();
CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, ret, "PrepareAsyncInternal failed");
return MSERR_OK;
}
InitializedState的Prepare办法又通过ctrler_调回到PlayBinCtrlerBase的ChangeState办法,这个办法是在PlayBinCtrlerBase的父类StateMachine中,它是一个状态机,治理着各种状态的切换。
int32_t PlayBinCtrlerBase::InitializedState::Prepare()
{
ctrler_.ChangeState(ctrler_.preparingState_);
return MSERR_OK;
}
很多示意状态的类在PlayBinCtrlerBase中进行申明,这些子类的具体实现性能在playbin_state.cpp中。
private:
class BaseState;
class IdleState;
class InitializedState;
class PreparingState;
class PreparedState;
class PlayingState;
class PausedState;
class StoppedState;
class StoppingState;
class PlaybackCompletedState;接下来看一下状态机的ChangeState办法,能够看出切换状态的时候,先调用切换前状态的StateExit()办法,再调用切换后状态的StateEnter()。如果须要一些操作,咱们能够在状态的StateEnter和StateExit中进行。
void StateMachine::ChangeState(const std::shared_ptr<State> &state)
{
......
if (currState_ != nullptr && currState_->GetStateName() == "stopping_state" && state->GetStateName() != "stopped_state") {
return;
}
if (currState_) {
currState_->StateExit();
}
currState_ = state;
state->StateEnter();
}
因为下面切换状态调用的是ctrler_.ChangeState(ctrler_.preparingState_),所以接下来看一下PreparingState状态的StateEnter办法。这个办法中首先是调用了ctrler_.ReportMessage(msg),字面上看是用来上报msg信息的。
void PlayBinCtrlerBase::PreparingState::StateEnter()
{
PlayBinMessage msg = { PLAYBIN_MSG_SUBTYPE, PLAYBIN_SUB_MSG_BUFFERING_START, 0, {} };
ctrler_.ReportMessage(msg);
GstStateChangeReturn ret;
(void)ChangePlayBinState(GST_STATE_PAUSED, ret);
MEDIA_LOGD("PreparingState::StateEnter finished");
}
ctrler_是PlayBinCtrlerBase类型的变量,间接看PlayBinCtrlerBase的ReportMessage办法,这个办法的外围,是创立一个工作后,将工作放入音讯队列中,期待音讯被解决,这里咱们最想晓得的是这个音讯会在什么中央被解决。msgReportHandler创立了TaskHandler,这个外面会调用notifier_(msg),这里的notifier_比拟重要,咱们能够顺着这个变量向上剖析。
void PlayBinCtrlerBase::ReportMessage(const PlayBinMessage &msg)
{
......
auto msgReportHandler = std::make_shared<TaskHandler<void>>([this, msg]() { notifier_(msg); });
int32_t ret = msgQueue_->EnqueueTask(msgReportHandler);
if (ret != MSERR_OK) {
MEDIA_LOGE("async report msg failed, type: %{public}d, subType: %{public}d, code: %{public}d",
msg.type, msg.subType, msg.code);
};
if (msg.type == PlayBinMsgType::PLAYBIN_MSG_EOS) {
ProcessEndOfStream();
}
}
notifier_是在PlayBinCtrlerBase被创立的时候赋值的。
PlayBinCtrlerBase::PlayBinCtrlerBase(const PlayBinCreateParam &createParam)
: renderMode_(createParam.renderMode),
notifier_(createParam.notifier),
sinkProvider_(createParam.sinkProvider)
{
MEDIA_LOGD("enter ctor, instance: 0x%{public}06" PRIXPTR "", FAKE_POINTER(this));
}
在源码剖析的后期PlayerEngineGstImpl初始化PlayBinCtrlerBase的时候进行了创立notifier = std::bind(&PlayerEngineGstImpl::OnNotifyMessage, this, std::placeholders::_1) notifier相当于是调用了PlayerEngineGstImpl::OnNotifyMessage办法。所以上述中的处理函数就是PlayerEngineGstImpl::OnNotifyMessage。
int32_t PlayerEngineGstImpl::PlayBinCtrlerPrepare()
{
uint8_t renderMode = IPlayBinCtrler::PlayBinRenderMode::DEFAULT_RENDER;
auto notifier = std::bind(&PlayerEngineGstImpl::OnNotifyMessage, this, std::placeholders::_1);
{
std::unique_lock<std::mutex> lk(trackParseMutex_);
sinkProvider_ = std::make_shared<PlayerSinkProvider>(producerSurface_);
sinkProvider_->SetAppInfo(appuid_, apppid_);
}
IPlayBinCtrler::PlayBinCreateParam createParam = {
static_cast<IPlayBinCtrler::PlayBinRenderMode>(renderMode), notifier, sinkProvider_
};
playBinCtrler_ = IPlayBinCtrler::Create(IPlayBinCtrler::PlayBinKind::PLAYBIN2, createParam);
......
return MSERR_OK;
}
在OnNotifyMessage中指定了各种音讯类型对应的执行函数,上述代码中创立的Message类型是PLAYBIN_MSG_SUBTYPE,子类型为PLAYBIN_SUB_MSG_BUFFERING_START。
void PlayerEngineGstImpl::OnNotifyMessage(const PlayBinMessage &msg)
{
const std::unordered_map<int32_t, MsgNotifyFunc> MSG_NOTIFY_FUNC_TABLE = {
{ PLAYBIN_MSG_ERROR, std::bind(&PlayerEngineGstImpl::HandleErrorMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_SEEKDONE, std::bind(&PlayerEngineGstImpl::HandleSeekDoneMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_SPEEDDONE, std::bind(&PlayerEngineGstImpl::HandleInfoMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_BITRATEDONE, std::bind(&PlayerEngineGstImpl::HandleInfoMessage, this, std::placeholders::_1)},
{ PLAYBIN_MSG_EOS, std::bind(&PlayerEngineGstImpl::HandleInfoMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_STATE_CHANGE, std::bind(&PlayerEngineGstImpl::HandleInfoMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_SUBTYPE, std::bind(&PlayerEngineGstImpl::HandleSubTypeMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_AUDIO_SINK, std::bind(&PlayerEngineGstImpl::HandleAudioMessage, this, std::placeholders::_1) },
{ PLAYBIN_MSG_POSITION_UPDATE, std::bind(&PlayerEngineGstImpl::HandlePositionUpdateMessage, this,
std::placeholders::_1) },
};
if (MSG_NOTIFY_FUNC_TABLE.count(msg.type) != 0) {
MSG_NOTIFY_FUNC_TABLE.at(msg.type)(msg);
}
}
最终的流程走到了PlayerEngineGstImpl::HandleBufferingStart(),在这个办法中,次要通过obs_将format传给IPlayerEngineObs的OnInfo办法。
void PlayerEngineGstImpl::HandleBufferingStart()
{
percent_ = 0;
Format format;
(void)format.PutIntValue(std::string(PlayerKeys::PLAYER_BUFFERING_START), 0);
std::shared_ptr<IPlayerEngineObs> notifyObs = obs_.lock();
if (notifyObs != nullptr) {
notifyObs->OnInfo(INFO_TYPE_BUFFERING_UPDATE, 0, format);
}
}
咱们重点看一下obs_是哪里设置的,在PlayerServer的初始化InitPlayEngine。shared_from_this()相当于是把PlayerServer本身赋值给obs,PlayerServer也是实现了IPlayerEngineObs对应的接口。
int32_t PlayerServer::InitPlayEngine(const std::string &url)
{
......
int32_t ret = taskMgr_.Init();
auto engineFactory = EngineFactoryRepo::Instance().GetEngineFactory(IEngineFactory::Scene::SCENE_PLAYBACK, url);
playerEngine_ = engineFactory->CreatePlayerEngine(appUid_, appPid_);
if (dataSrc_ == nullptr) {
ret = playerEngine_->SetSource(url);
} else {
ret = playerEngine_->SetSource(dataSrc_);
}
std::shared_ptr<IPlayerEngineObs> obs = shared_from_this();
ret = playerEngine_->SetObs(obs);
lastOpStatus_ = PLAYER_INITIALIZED;
ChangeState(initializedState_);
return MSERR_OK;
}
这样咱们就跟踪到了PlayerServer的OnInfo()办法。
void PlayerServer::OnInfo(PlayerOnInfoType type, int32_t extra, const Format &infoBody)
{
std::lock_guard<std::mutex> lockCb(mutexCb_);
int32_t ret = HandleMessage(type, extra, infoBody);
if (playerCb_ != nullptr && ret == MSERR_OK) {
playerCb_->OnInfo(type, extra, infoBody);
}
}
-
Play剖析
从PlayerServer开始跟踪,调用到PlayerServer的OnPlay()办法。int32_t PlayerServer::Play() { ...... if (lastOpStatus_ == PLAYER_PREPARED || lastOpStatus_ == PLAYER_PLAYBACK_COMPLETE || lastOpStatus_ == PLAYER_PAUSED) { return OnPlay(); } else { return MSERR_INVALID_OPERATION; } }
在OnPlay中会启动一个工作,在工作中获取以后的状态,而后调用以后状态的Play()办法。
int32_t PlayerServer::OnPlay()
{
......
auto playingTask = std::make_shared<TaskHandler<void>>([this]() {
auto currState = std::static_pointer_cast<BaseState>(GetCurrState());
(void)currState->Play();
});
int ret = taskMgr_.LaunchTask(playingTask, PlayerServerTaskType::STATE_CHANGE);
lastOpStatus_ = PLAYER_STARTED;
return MSERR_OK;
}
后面调用了PrepareAsync,所以以后的状态是Prepared,调用到了PreparedState的Play()办法,这个办法还是依照之前Prepare的形式,调回到PlayerServer的HandlePlay()。
int32_t PlayerServer::PreparedState::Play()
{
return server_.HandlePlay();
}
在PlayServer中通过播放引擎持续向下调用。
int32_t PlayerServer::HandlePlay()
{
int32_t ret = playerEngine_->Play();
CHECK_AND_RETURN_RET_LOG(ret == MSERR_OK, MSERR_INVALID_OPERATION, "Engine Play Failed!");
return MSERR_OK;
}
在PlayerEngineGstImpl的Play()办法会持续调用playBinCtrler_的Play()办法。
int32_t PlayerEngineGstImpl::Play()
{
......
playBinCtrler_->Play();
return MSERR_OK;
}
PlayBinCtrlerBase的Play()办法依据以后的State,调用currSate->Play()。
int32_t PlayBinCtrlerBase::Play()
{
......
auto currState = std::static_pointer_cast<BaseState>(GetCurrState());
int32_t ret = currState->Play();
return MSERR_OK;
}
在PreparedState的Play()办法中扭转了PlayBin的状态为playing。
int32_t PlayBinCtrlerBase::PreparedState::Play()
{
GstStateChangeReturn ret;
return ChangePlayBinState(GST_STATE_PLAYING, ret);
}
ChangePlayBinState次要是调用了gst_element_set_state(GST_ELEMENT_CAST(ctrler_.playbin_),GST_STATE_PLAYING),这个间接调用了gstreamer三方库的实现,调用完这个办法当前,gstreamer就开始进行播放了。
int32_t PlayBinCtrlerBase::BaseState::ChangePlayBinState(GstState targetState, GstStateChangeReturn &ret)
{
......
ret = gst_element_set_state(GST_ELEMENT_CAST(ctrler_.playbin_), targetState);
if (ret == GST_STATE_CHANGE_FAILURE) {
MEDIA_LOGE("Failed to change playbin's state to %{public}s", gst_element_state_get_name(targetState));
return MSERR_INVALID_OPERATION;
}
return MSERR_OK;
}
六、总结
本篇文章次要从PlayerServer播放服务开始剖析音视频播放的流程,波及到gstreamer引擎的调用,绝对于多媒体播放框架来说,更加底层,便于相熟从框架到gstreamer的整体流程。
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