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1 /*
2  * Copyright 2015 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #ifndef MEDIA_SYNC_H
18 #define MEDIA_SYNC_H
19 
20 #include <gui/IConsumerListener.h>
21 #include <gui/IProducerListener.h>
22 
23 #include <media/AudioResamplerPublic.h>
24 #include <media/AVSyncSettings.h>
25 #include <media/stagefright/foundation/AHandler.h>
26 
27 #include <utils/Condition.h>
28 #include <utils/KeyedVector.h>
29 #include <utils/Mutex.h>
30 
31 namespace android {
32 
33 class AudioTrack;
34 class BufferItem;
35 class Fence;
36 class GraphicBuffer;
37 class IGraphicBufferConsumer;
38 class IGraphicBufferProducer;
39 struct MediaClock;
40 struct VideoFrameScheduler;
41 
42 // MediaSync manages media playback and its synchronization to a media clock
43 // source. It can be also used for video-only playback.
44 //
45 // For video playback, it requires an output surface and provides an input
46 // surface. It then controls the rendering of input buffers (buffer queued to
47 // the input surface) on the output surface to happen at the appropriate time.
48 //
49 // For audio playback, it requires an audio track and takes updates of
50 // information of rendered audio data to maintain media clock when audio track
51 // serves as media clock source. (TODO: move audio rendering from JAVA to
52 // native code).
53 //
54 // It can use the audio or video track as media clock source, as well as an
55 // external clock. (TODO: actually support external clock as media clock
56 // sources; use video track as media clock source for audio-and-video stream).
57 //
58 // In video-only mode, MediaSync will playback every video frame even though
59 // a video frame arrives late based on its timestamp and last frame's.
60 //
61 // The client needs to configure surface (for output video rendering) and audio
62 // track (for querying information of audio rendering) for MediaSync.
63 //
64 // Then the client needs to obtain a surface from MediaSync and render video
65 // frames onto that surface. Internally, the MediaSync will receive those video
66 // frames and render them onto the output surface at the appropriate time.
67 //
68 // The client needs to call updateQueuedAudioData() immediately after it writes
69 // audio data to the audio track. Such information will be used to update media
70 // clock.
71 //
72 class MediaSync : public AHandler {
73 public:
74     // Create an instance of MediaSync.
75     static sp<MediaSync> create();
76 
77     // Called when MediaSync is used to render video. It should be called
78     // before createInputSurface().
79     status_t setSurface(const sp<IGraphicBufferProducer> &output);
80 
81     // Called when audio track is used as media clock source. It should be
82     // called before updateQueuedAudioData().
83     status_t setAudioTrack(const sp<AudioTrack> &audioTrack);
84 
85     // Create a surface for client to render video frames. This is the surface
86     // on which the client should render video frames. Those video frames will
87     // be internally directed to output surface for rendering at appropriate
88     // time.
89     status_t createInputSurface(sp<IGraphicBufferProducer> *outBufferProducer);
90 
91     // Update just-rendered audio data size and the presentation timestamp of
92     // the first frame of that audio data. It should be called immediately
93     // after the client write audio data into AudioTrack.
94     // This function assumes continous audio stream.
95     // TODO: support gap or backwards updates.
96     status_t updateQueuedAudioData(
97             size_t sizeInBytes, int64_t presentationTimeUs);
98 
99     // Set the consumer name of the input queue.
100     void setName(const AString &name);
101 
102     // Get the media clock used by the MediaSync so that the client can obtain
103     // corresponding media time or real time via
104     // MediaClock::getMediaTime() and MediaClock::getRealTimeFor().
105     sp<const MediaClock> getMediaClock();
106 
107     // Flush mediasync
108     void flush();
109 
110     // Set the video frame rate hint - this is used by the video FrameScheduler
111     status_t setVideoFrameRateHint(float rate);
112 
113     // Get the video frame rate measurement from the FrameScheduler
114     // returns -1 if there is no measurement
115     float getVideoFrameRate();
116 
117     // Set the sync settings parameters.
118     status_t setSyncSettings(const AVSyncSettings &syncSettings);
119 
120     // Gets the sync settings parameters.
121     void getSyncSettings(AVSyncSettings *syncSettings /* nonnull */);
122 
123     // Sets the playback rate using playback settings.
124     // This method can be called any time.
125     status_t setPlaybackSettings(const AudioPlaybackRate &rate);
126 
127     // Gets the playback rate (playback settings parameters).
128     void getPlaybackSettings(AudioPlaybackRate *rate /* nonnull */);
129 
130     // Get the play time for pending audio frames in audio sink.
131     status_t getPlayTimeForPendingAudioFrames(int64_t *outTimeUs);
132 
133 protected:
134     virtual void onMessageReceived(const sp<AMessage> &msg);
135 
136 private:
137     enum {
138         kWhatDrainVideo = 'dVid',
139     };
140 
141     // This is a thin wrapper class that lets us listen to
142     // IConsumerListener::onFrameAvailable from mInput.
143     class InputListener : public BnConsumerListener,
144                           public IBinder::DeathRecipient {
145     public:
146         InputListener(const sp<MediaSync> &sync);
147         virtual ~InputListener();
148 
149         // From IConsumerListener
150         virtual void onFrameAvailable(const BufferItem &item);
151 
152         // From IConsumerListener
153         // We don't care about released buffers because we detach each buffer as
154         // soon as we acquire it. See the comment for onBufferReleased below for
155         // some clarifying notes about the name.
onBuffersReleased()156         virtual void onBuffersReleased() {}
157 
158         // From IConsumerListener
159         // We don't care about sideband streams, since we won't relay them.
160         virtual void onSidebandStreamChanged();
161 
162         // From IBinder::DeathRecipient
163         virtual void binderDied(const wp<IBinder> &who);
164 
165     private:
166         sp<MediaSync> mSync;
167     };
168 
169     // This is a thin wrapper class that lets us listen to
170     // IProducerListener::onBufferReleased from mOutput.
171     class OutputListener : public BnProducerListener,
172                            public IBinder::DeathRecipient {
173     public:
174         OutputListener(const sp<MediaSync> &sync, const sp<IGraphicBufferProducer> &output);
175         virtual ~OutputListener();
176 
177         // From IProducerListener
178         virtual void onBufferReleased();
179 
180         // From IBinder::DeathRecipient
181         virtual void binderDied(const wp<IBinder> &who);
182 
183     private:
184         sp<MediaSync> mSync;
185         sp<IGraphicBufferProducer> mOutput;
186     };
187 
188     // mIsAbandoned is set to true when the input or output dies.
189     // Once the MediaSync has been abandoned by one side, it will disconnect
190     // from the other side and not attempt to communicate with it further.
191     bool mIsAbandoned;
192 
193     mutable Mutex mMutex;
194     Condition mReleaseCondition;
195     size_t mNumOutstandingBuffers;
196     sp<IGraphicBufferConsumer> mInput;
197     sp<IGraphicBufferProducer> mOutput;
198     int mUsageFlagsFromOutput;
199     uint32_t mMaxAcquiredBufferCount; // max acquired buffer count
200     bool mReturnPendingInputFrame;    // set while we are pending before acquiring an input frame
201 
202     sp<AudioTrack> mAudioTrack;
203     uint32_t mNativeSampleRateInHz;
204     int64_t mNumFramesWritten;
205     bool mHasAudio;
206 
207     int64_t mNextBufferItemMediaUs;
208     List<BufferItem> mBufferItems;
209     sp<VideoFrameScheduler> mFrameScheduler;
210 
211     // Keep track of buffers received from |mInput|. This is needed because
212     // it's possible the consumer of |mOutput| could return a different
213     // GraphicBuffer::handle (e.g., due to passing buffers through IPC),
214     // and that could cause problem if the producer of |mInput| only
215     // supports pre-registered buffers.
216     KeyedVector<uint64_t, sp<GraphicBuffer> > mBuffersFromInput;
217 
218     // Keep track of buffers sent to |mOutput|. When a new output surface comes
219     // in, those buffers will be returned to input and old output surface will
220     // be disconnected immediately.
221     KeyedVector<uint64_t, sp<GraphicBuffer> > mBuffersSentToOutput;
222 
223     sp<ALooper> mLooper;
224     float mPlaybackRate;
225 
226     AudioPlaybackRate mPlaybackSettings;
227     AVSyncSettings mSyncSettings;
228 
229     sp<MediaClock> mMediaClock;
230 
231     MediaSync();
232 
233     // Must be accessed through RefBase
234     virtual ~MediaSync();
235 
236     int64_t getRealTime(int64_t mediaTimeUs, int64_t nowUs);
237     int64_t getDurationIfPlayedAtNativeSampleRate_l(int64_t numFrames);
238     int64_t getPlayedOutAudioDurationMedia_l(int64_t nowUs);
239 
240     void onDrainVideo_l();
241 
242     // This implements the onFrameAvailable callback from IConsumerListener.
243     // It gets called from an InputListener.
244     // During this callback, we detach the buffer from the input, and queue
245     // it for rendering on the output. This call can block if there are too
246     // many outstanding buffers. If it blocks, it will resume when
247     // onBufferReleasedByOutput releases a buffer back to the input.
248     void onFrameAvailableFromInput();
249 
250     // Send |bufferItem| to the output for rendering.
251     void renderOneBufferItem_l(const BufferItem &bufferItem);
252 
253     // This implements the onBufferReleased callback from IProducerListener.
254     // It gets called from an OutputListener.
255     // During this callback, we detach the buffer from the output, and release
256     // it to the input. A blocked onFrameAvailable call will be allowed to proceed.
257     void onBufferReleasedByOutput(sp<IGraphicBufferProducer> &output);
258 
259     // Return |buffer| back to the input.
260     void returnBufferToInput_l(const sp<GraphicBuffer> &buffer, const sp<Fence> &fence);
261 
262     // When this is called, the MediaSync disconnects from (i.e., abandons) its
263     // input or output, and signals any waiting onFrameAvailable calls to wake
264     // up. This must be called with mMutex locked.
265     void onAbandoned_l(bool isInput);
266 
267     // Set the playback in a desired speed.
268     // This method can be called any time.
269     // |rate| is the ratio between desired speed and the normal one, and should
270     // be non-negative. The meaning of rate values:
271     // 1.0 -- normal playback
272     // 0.0 -- stop or pause
273     // larger than 1.0 -- faster than normal speed
274     // between 0.0 and 1.0 -- slower than normal speed
275     void updatePlaybackRate_l(float rate);
276 
277     // apply new sync settings
278     void resync_l();
279 
280     // apply playback settings only - without resyncing or updating playback rate
281     status_t setPlaybackSettings_l(const AudioPlaybackRate &rate);
282 
283     // helper.
isPlaying()284     bool isPlaying() { return mPlaybackRate != 0.0; }
285 
286     DISALLOW_EVIL_CONSTRUCTORS(MediaSync);
287 };
288 
289 } // namespace android
290 
291 #endif
292