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本文均属自己阅读源码的点滴总结,转账请注明出处谢谢。
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Android源码版本Version:4.2.2; 硬件平台 全志A31
前沿:
在前面的博文中,基本提到的是stagefright相关的控制流,具体分析了android架构中的MediaExtractor、AwesomePlayer、StagefrightPlayer、OMXCodec等的创建,底层OMXNodinstance实例的创建。分析了OMX最底层插件库、编解码器组件的架构以及如何创建属于我们自己的OMX Plugin。
分析源码架构的另一个关键是数据流的分析,从这里开始,我们将对stagefright中的编解码缓存区进行分析:
1.
回到OMXCodec的创建过程的源码:
status_t AwesomePlayer::initVideoDecoder(uint32_t flags) { ....... mVideoSource = OMXCodec::Create( mClient.interface(), mVideoTrack->getFormat(),//提取视频流的格式, mClient:BpOMX;mVideoTrack->getFormat() false, // createEncoder,不创建编码器false mVideoTrack, NULL, flags, USE_SURFACE_ALLOC ? mNativeWindow : NULL);//创建一个解码器mVideoSource if (mVideoSource != NULL) { int64_t durationUs; if (mVideoTrack->getFormat()->findInt64(kKeyDuration, &durationUs)) { Mutex::Autolock autoLock(mMiscStateLock); if (mDurationUs < 0 || durationUs > mDurationUs) { mDurationUs = durationUs; } } status_t err = mVideoSource->start();//启动解码器OMXCodec,完成解码器的init初始化操作 ............. }
在Android4.2.2下Stagefright多媒体架构中的A31的OMX插件和Codec组件 博文我们对于OMXCodec::create已经做了详细的分析,这里来关注mVideoSource->start的相关功能,即OMXCodec::start的处理:
status_t OMXCodec::start(MetaData *meta) { Mutex::Autolock autoLock(mLock); ........ return init();//进行初始化操作 }
这里调用init()的过程,将会进行buffer的申请操作,为后续的流操作打下基础:
status_t OMXCodec::init() { // mLock is held. ......... err = allocateBuffers();//缓存区的分配 if (err != (status_t)OK) { return err; } if (mQuirks & kRequiresLoadedToIdleAfterAllocation) { err = mOMX->sendCommand(mNode, OMX_CommandStateSet, OMX_StateIdle); CHECK_EQ(err, (status_t)OK); setState(LOADED_TO_IDLE); } ............ }
我们来看allocateBuffers的实现
2.关注allocateBuffersOnPort的实现
status_t OMXCodec::allocateBuffers() { status_t err = allocateBuffersOnPort(kPortIndexInput);//输入缓存input口分配 if (err != OK) { return err; } return allocateBuffersOnPort(kPortIndexOutput);//输出缓存input口分配 }
这里分别将对输入和输出口进行Buffer的申请与分配,对于解码器,需要输入口来存储待解码的数据源,需要将解码后的数据源存储到输出口,而这也符合硬件的实现逻辑。以输入缓存区分配为例展开分析:
status_t OMXCodec::allocateBuffersOnPort(OMX_U32 portIndex) { ....... OMX_PARAM_PORTDEFINITIONTYPE def; InitOMXParams(&def); def.nPortIndex = portIndex;//输入口 err = mOMX->getParameter( mNode, OMX_IndexParamPortDefinition, &def, sizeof(def));//获取输入口参数到def .......... err = mOMX->allocateBuffer( mNode, portIndex, def.nBufferSize, &buffer, &info.mData); ........ info.mBuffer = buffer;//获取对应的buffer_id,有保存有底层的buffer的相关信息 info.mStatus = OWNED_BY_US; info.mMem = mem; info.mMediaBuffer = NULL; ........... mPortBuffers[portIndex].push(info);//把当前的buffer恢复到mPortBuffers[2]中去
上述过程主要分为:
step1:先是获取底层解码器组件的当前的参数熟悉,一般这些参数都在建立OMX_Codec时完成的初始配置,前一博文中已经提到过。
step2:进行allocateBuffer的处理,这个函数的调用最终交给底层的OMX组件来完成,相关的实现将集成到A31的底层OMX编解码组件的处理流中进行分析。
step3:完成对分配好的buffer信息info,维护在mPortBuffers[0]这个端口中。
上述过程完成了输入与输出的Buffer分配,为后续解码操作buffer打下了基础。
3.mediaplay启动播放器
通过start的API调用,进入MediaplayerService::Client,再依次经过stagefrightplayer,AwesomePlayer。触发play的videoevent的发生.
void AwesomePlayer::postVideoEvent_l(int64_t delayUs) { ATRACE_CALL(); if (mVideoEventPending) { return; } mVideoEventPending = true; mQueue.postEventWithDelay(mVideoEvent, delayUs < 0 ? 10000 : delayUs); }
根据前一博文的分析可知,该事件对应的处理函数为AwesomePlayer::onVideoEvent(),该部分代码量较大,提取核心内容read的处理进行分析:
status_t err = mVideoSource->read(&mVideoBuffer, &options);//循环读数据实际的OMX_CODEC::read,读取到mVideoBuffer
read的核心是获取可以用于render的视频数据,这表明了read函数主要完成了从视频源读取元数据,并调用解码器完成解码生成可送显的数据。
4. read函数的实现
可以想象read函数的应该是一个比较复杂的过程,我们从OMX_Codec的read函数入手来分析:
status_t OMXCodec::read( MediaBuffer **buffer, const ReadOptions *options) { status_t err = OK; *buffer = NULL; Mutex::Autolock autoLock(mLock); drainInputBuffers();//buffer,填充数据源 if (mState == EXECUTING) { // Otherwise mState == RECONFIGURING and this code will trigger // after the output port is reenabled. fillOutputBuffers(); } } ........... }
read的核心逻辑总结为drainInputBuffers()和fillOutputBuffers(),我们对其依次进行深入的分析
5. drainInputBuffers()读取待解码的视频数据源到解码器的Inport
这里贴出其较为复杂的处理过程代码,主要分为以下3个部分进行分析:
(1)
bool OMXCodec::drainInputBuffer(BufferInfo *info) {if (mCodecSpecificDataIndex < mCodecSpecificData.size()) { CHECK(!(mFlags & kUseSecureInputBuffers)); const CodecSpecificData *specific = mCodecSpecificData[mCodecSpecificDataIndex]; size_t size = specific->mSize; if (!strcasecmp(MEDIA_MIMETYPE_VIDEO_AVC, mMIME) && !(mQuirks & kWantsNALFragments)) { static const uint8_t kNALStartCode[4] = { 0x00, 0x00, 0x00, 0x01 }; CHECK(info->mSize >= specific->mSize + 4); size += 4; memcpy(info->mData, kNALStartCode, 4); memcpy((uint8_t *)info->mData + 4, specific->mData, specific->mSize); } else { CHECK(info->mSize >= specific->mSize); memcpy(info->mData, specific->mData, specific->mSize);//copy前面的数据字段 } mNoMoreOutputData = false; CODEC_LOGV("calling emptyBuffer with codec specific data"); status_t err = mOMX->emptyBuffer( mNode, info->mBuffer, 0, size, OMX_BUFFERFLAG_ENDOFFRAME | OMX_BUFFERFLAG_CODECCONFIG, 0);//处理buffer CHECK_EQ(err, (status_t)OK); info->mStatus = OWNED_BY_COMPONENT; ++mCodecSpecificDataIndex; return true; }...............(1)
这部分的内容主要是提取一部分解码器字段,填充到info->mData的存储空间中去。这部分主要基于视频源的格式,如mp4等在创建OXMCodec病configureCodec时就完成了这个mCodecSpecificData字段的添加,应该些解码需要的特殊字段吧。是否需要要看其视频源的格式。获取完这个字段信息后就是正式读取视频源的数据了。
(2)
for (;;) { MediaBuffer *srcBuffer; if (mSeekTimeUs >= 0) { if (mLeftOverBuffer) { mLeftOverBuffer->release(); mLeftOverBuffer = NULL; } MediaSource::ReadOptions options; options.setSeekTo(mSeekTimeUs, mSeekMode); mSeekTimeUs = -1; mSeekMode = ReadOptions::SEEK_CLOSEST_SYNC; mBufferFilled.signal(); err = mSource->read(&srcBuffer, &options);//读取视频源中的真实数据这里是MPEG4Source的read if (err == OK) { int64_t targetTimeUs; if (srcBuffer->meta_data()->findInt64( kKeyTargetTime, &targetTimeUs) && targetTimeUs >= 0) { CODEC_LOGV("targetTimeUs = %lld us", targetTimeUs); mTargetTimeUs = targetTimeUs; } else { mTargetTimeUs = -1; } } } else if (mLeftOverBuffer) { srcBuffer = mLeftOverBuffer; mLeftOverBuffer = NULL; err = OK; } else { err = mSource->read(&srcBuffer); } if (err != OK) { signalEOS = true; mFinalStatus = err; mSignalledEOS = true; mBufferFilled.signal(); break; } if (mFlags & kUseSecureInputBuffers) { info = findInputBufferByDataPointer(srcBuffer->data()); CHECK(info != NULL); } size_t remainingBytes = info->mSize - offset;//buffer中剩余的可以存储视频数据的空间 if (srcBuffer->range_length() > remainingBytes) {//当前读取的数据已经达到解码的数据量 if (offset == 0) { CODEC_LOGE( "Codec‘s input buffers are too small to accomodate " "buffer read from source (info->mSize = %d, srcLength = %d)", info->mSize, srcBuffer->range_length()); srcBuffer->release(); srcBuffer = NULL; setState(ERROR); return false; } mLeftOverBuffer = srcBuffer;//把没读取的buffer记录下来 break; } bool releaseBuffer = true; if (mFlags & kStoreMetaDataInVideoBuffers) { releaseBuffer = false; info->mMediaBuffer = srcBuffer; } if (mFlags & kUseSecureInputBuffers) { // Data in "info" is already provided at this time. releaseBuffer = false; CHECK(info->mMediaBuffer == NULL); info->mMediaBuffer = srcBuffer; } else { CHECK(srcBuffer->data() != NULL) ; memcpy((uint8_t *)info->mData + offset, (const uint8_t *)srcBuffer->data() + srcBuffer->range_offset(), srcBuffer->range_length());//copy数据源数据到输入缓存,数据容量srcBuffer->range_length() } int64_t lastBufferTimeUs; CHECK(srcBuffer->meta_data()->findInt64(kKeyTime, &lastBufferTimeUs)); CHECK(lastBufferTimeUs >= 0); if (mIsEncoder && mIsVideo) { mDecodingTimeList.push_back(lastBufferTimeUs); } if (offset == 0) { timestampUs = lastBufferTimeUs; } offset += srcBuffer->range_length();//增加偏移量 if (!strcasecmp(MEDIA_MIMETYPE_AUDIO_VORBIS, mMIME)) { CHECK(!(mQuirks & kSupportsMultipleFramesPerInputBuffer)); CHECK_GE(info->mSize, offset + sizeof(int32_t)); int32_t numPageSamples; if (!srcBuffer->meta_data()->findInt32( kKeyValidSamples, &numPageSamples)) { numPageSamples = -1; } memcpy((uint8_t *)info->mData + offset, &numPageSamples, sizeof(numPageSamples)); offset += sizeof(numPageSamples); } if (releaseBuffer) { srcBuffer->release(); srcBuffer = NULL; } ++n; if (!(mQuirks & kSupportsMultipleFramesPerInputBuffer)) { break; } int64_t coalescedDurationUs = lastBufferTimeUs - timestampUs; if (coalescedDurationUs > 250000ll) { // Don‘t coalesce more than 250ms worth of encoded data at once. break; } }...........
该部分是提取视频源数据的关键,主要通过 err = mSource->read(&srcBuffer, &options)来完成,mSource是在创建编解码器传入的,实际是一个对应于视频源格式的一个解析器MediaExtractor。比如在建立MP4的解析器MPEG4Extractor,通过新建一个new MPEG4Source。故最终这里调用的是MPEG4Source的read成员函数,其实际也维护着整个待解码的原始视频流。
我们可以看大在read函数后,会将待解码的数据流以for循环依次读入到底层的buffer空间中,只有当满足当前读取的原始数据片段比底层的input口的buffer剩余空间小srcBuffer->range_length() > remainingBytes,那就可以继续读取,否则直接break后,去进行下一步操作。或者如果一次待解码的数据时张是大于250ms也直接跳出。
这处理体现了处理的高效性。最终视频原始数据存储在info->mData的底层输入空间中。
(3)
err = mOMX->emptyBuffer( mNode, info->mBuffer, 0, offset, flags, timestampUs);
触发底层的解码器组件进行处理。这部分留在后续对A31的底层编解码API操作时进行分析。
6.fillOutputBuffers对输出buffer口的填充,即实现解码过程:
void OMXCodec::fillOutputBuffers() { CHECK_EQ((int)mState, (int)EXECUTING); ........... Vector<BufferInfo> *buffers = &mPortBuffers[kPortIndexOutput];输出端口 for (size_t i = 0; i < buffers->size(); ++i) { BufferInfo *info = &buffers->editItemAt(i); if (info->mStatus == OWNED_BY_US) { fillOutputBuffer(&buffers->editItemAt(i)); } } }
void OMXCodec::fillOutputBuffer(BufferInfo *info) { CHECK_EQ((int)info->mStatus, (int)OWNED_BY_US); if (mNoMoreOutputData) { CODEC_LOGV("There is no more output data available, not " "calling fillOutputBuffer"); return; } CODEC_LOGV("Calling fillBuffer on buffer %p", info->mBuffer); status_t err = mOMX->fillBuffer(mNode, info->mBuffer); if (err != OK) { CODEC_LOGE("fillBuffer failed w/ error 0x%08x", err); setState(ERROR); return; } info->mStatus = OWNED_BY_COMPONENT; }
从上面的代码看来,fillOutputBuffer的实现比drainInputBuffers简单了很多。但相同的是,两者最终都讲控制权交给底层的解码器来完成。
7.等待解码数据被fill到outbuffer中,OMXCodecObserver完成回调处理
等待解码完成的这部分内容在read函数中通过以下函数来实现:
while (mState != ERROR && !mNoMoreOutputData && mFilledBuffers.empty()) { if ((err = waitForBufferFilled_l()) != OK) {//进入等待buffer被填充 return err; } }
上述表明,只要mFilledBuffers为空则进入等待填充pthread_cond_timedwait。而这个线程被唤醒是通过底层的组件回调来完成的,回调函数的注册哎底层编解码器Node完成的,实际最终的回调是交给OMXCodecObserver来完成的:
struct OMXCodecObserver : public BnOMXObserver { OMXCodecObserver() { } void setCodec(const sp<OMXCodec> &target) { mTarget = target; } // from IOMXObserver virtual void onMessage(const omx_message &msg) { sp<OMXCodec> codec = mTarget.promote(); if (codec.get() != NULL) { Mutex::Autolock autoLock(codec->mLock); codec->on_message(msg);//OMX_Codec的on_message处理 codec.clear(); } }
最终可以看到是由OMX_Codec->on_message来进行消息的处理,这部分的内容主要包括EMPTY_BUFFER_DONE和FILL_BUFFER_DONE两个message处理,对FILL_BUFFER_DONE完成后的消息回调进行分析:
void OMXCodec::on_message(const omx_message &msg) { if (mState == ERROR) { /* * only drop EVENT messages, EBD and FBD are still * processed for bookkeeping purposes */ if (msg.type == omx_message::EVENT) { ALOGW("Dropping OMX EVENT message - we‘re in ERROR state."); return; } } switch (msg.type) { case omx_message::FILL_BUFFER_DONE://底层回调callback告知当前 .............. mFilledBuffers.push_back(i);//当前的输出buffer信息维护在mFilledBuffers mBufferFilled.signal();//发出信息用于渲染
可以看到这里对read线程进行了唤醒。
8.提取一个可用的解码后的数据帧
size_t index = *mFilledBuffers.begin(); mFilledBuffers.erase(mFilledBuffers.begin()); BufferInfo *info = &mPortBuffers[kPortIndexOutput].editItemAt(index);//从获取解码后的视频源 CHECK_EQ((int)info->mStatus, (int)OWNED_BY_US); info->mStatus = OWNED_BY_CLIENT; info->mMediaBuffer->add_ref();// if (mSkipCutBuffer != NULL) { mSkipCutBuffer->submit(info->mMediaBuffer); } *buffer = info->mMediaBuffer;
获得了线程唤醒后的buffer,从这里获取到输出端口对应的Bufferinfo,作为最终的BufferInfo信息返回给read函数
9
经过5、6、7、8的处理过程,read最终返回可用于显示的mVideoBuffer,接下去就是如何送显的过程了。可以看到下面的代码,将会创建一个渲染器mVideoRenderer来完成这个解码后视频源的显示:
if ((mNativeWindow != NULL) && (mVideoRendererIsPreview || mVideoRenderer == NULL)) {//首次创建渲染器 mVideoRendererIsPreview = false;
initRenderer_l();//初始化渲染器,新建一个AwesomeLocalRenderer }
if (mVideoRenderer != NULL) { mSinceLastDropped++; mVideoRenderer->render(mVideoBuffer);//启动渲染,即显示当前buffer if (!mVideoRenderingStarted) { mVideoRenderingStarted = true; notifyListener_l(MEDIA_INFO, MEDIA_INFO_RENDERING_START); }
}
void AwesomePlayer::initRenderer_l() { ATRACE_CALL(); if (mNativeWindow == NULL) { return; } sp<MetaData> meta = mVideoSource->getFormat(); int32_t format; const char *component; int32_t decodedWidth, decodedHeight; CHECK(meta->findInt32(kKeyColorFormat, &format)); CHECK(meta->findCString(kKeyDecoderComponent, &component)); CHECK(meta->findInt32(kKeyWidth, &decodedWidth)); CHECK(meta->findInt32(kKeyHeight, &decodedHeight)); int32_t rotationDegrees; if (!mVideoTrack->getFormat()->findInt32( kKeyRotation, &rotationDegrees)) { rotationDegrees = 0; } mVideoRenderer.clear(); // Must ensure that mVideoRenderer‘s destructor is actually executed // before creating a new one. IPCThreadState::self()->flushCommands(); // Even if set scaling mode fails, we will continue anyway setVideoScalingMode_l(mVideoScalingMode); if (USE_SURFACE_ALLOC && !strncmp(component, "OMX.", 4) && strncmp(component, "OMX.google.", 11) && strcmp(component, "OMX.Nvidia.mpeg2v.decode")) {//使用硬件渲染器,除去上述的解码器 // Hardware decoders avoid the CPU color conversion by decoding // directly to ANativeBuffers, so we must use a renderer that // just pushes those buffers to the ANativeWindow. mVideoRenderer = new AwesomeNativeWindowRenderer(mNativeWindow, rotationDegrees);//一般是使用硬件渲染机制 } else { // Other decoders are instantiated locally and as a consequence // allocate their buffers in local address space. This renderer // then performs a color conversion and copy to get the data // into the ANativeBuffer. mVideoRenderer = new AwesomeLocalRenderer(mNativeWindow, meta); } }
可以看到这里有2个渲染器的创建分支,OMX和OMX.google说明底层的解码器用的是软解码,那么他渲染器也使用所谓的本地渲染器实际是软渲染器。故这里我们使用的是AwesomeNativeWindowRenderer渲染器,其结构如下所述:
struct AwesomeNativeWindowRenderer : public AwesomeRenderer { AwesomeNativeWindowRenderer( const sp<ANativeWindow> &nativeWindow, int32_t rotationDegrees) : mNativeWindow(nativeWindow) { applyRotation(rotationDegrees); } virtual void render(MediaBuffer *buffer) { ATRACE_CALL(); int64_t timeUs; CHECK(buffer->meta_data()->findInt64(kKeyTime, &timeUs)); native_window_set_buffers_timestamp(mNativeWindow.get(), timeUs * 1000); status_t err = mNativeWindow->queueBuffer( mNativeWindow.get(), buffer->graphicBuffer().get(), -1);//直接使用queuebuffer进行渲染显示 if (err != 0) { ALOGE("queueBuffer failed with error %s (%d)", strerror(-err), -err); return; } sp<MetaData> metaData = buffer->meta_data(); metaData->setInt32(kKeyRendered, 1); }
不是很复杂,只是实现了AwesomeRenderer渲染接口render。最终调用这个函数来实现对buffer的显示。这里看到很熟悉的queueBuffer,大家可以回看我的博文Android4.2.2 SurfaceFlinger之图形渲染queueBuffer实现和VSYNC的存在感 ,这是通过应用程序的本地窗口mNativeWindow(因为播放器videoview继承了sufaceview,surfaceview类会创建一个本地的surface,其继承了本地窗口类)将当前buffer提交给SurfaceFlinger服务进行显示,具体内容不在展开。
至此我们完成了stagefright下的编解码的数据流的相关操作,程序上复杂主要体现在emptybuffer和fillbuffer为主。当然由于能力有限,在很多细节上也没有进行很详细的分析,也希望大家多交流,多学习。
Android4.2.2的Stagefright中编解码器数据流的维护,布布扣,bubuko.com
Android4.2.2的Stagefright中编解码器数据流的维护
标签:des android style class blog c
原文地址:http://blog.csdn.net/gzzaigcnforever/article/details/26694059