/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package android.media; import android.annotation.IntDef; import android.annotation.NonNull; import android.annotation.Nullable; import android.media.AudioTrack; import android.media.PlaybackParams; import android.os.Handler; import android.os.Looper; import android.os.Message; import android.util.Log; import android.view.Surface; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; import java.nio.ByteBuffer; import java.util.concurrent.TimeUnit; import java.util.LinkedList; import java.util.List; /** * MediaSync class can be used to synchronously playback audio and video streams. * It can be used to play audio-only or video-only stream, too. * *

MediaSync is generally used like this: * 

 * MediaSync sync = new MediaSync();
 * sync.setSurface(surface);
 * Surface inputSurface = sync.createInputSurface();
 * ...
 * // MediaCodec videoDecoder = ...;
 * videoDecoder.configure(format, inputSurface, ...);
 * ...
 * sync.setAudioTrack(audioTrack);
 * sync.setCallback(new MediaSync.Callback() {
 *     {@literal @Override}
 *     public void onAudioBufferConsumed(MediaSync sync, ByteBuffer audioBuffer, int bufferId) {
 *         ...
 *     }
 * }, null);
 * // This needs to be done since sync is paused on creation.
 * sync.setPlaybackParams(new PlaybackParams().setSpeed(1.f));
 *
 * for (;;) {
 *   ...
 *   // send video frames to surface for rendering, e.g., call
 *   // videoDecoder.releaseOutputBuffer(videoOutputBufferIx, videoPresentationTimeNs);
 *   // More details are available as below.
 *   ...
 *   sync.queueAudio(audioByteBuffer, bufferId, audioPresentationTimeUs); // non-blocking.
 *   // The audioByteBuffer and bufferId will be returned via callback.
 *   // More details are available as below.
 *   ...
 *     ...
 * }
 * sync.setPlaybackParams(new PlaybackParams().setSpeed(0.f));
 * sync.release();
 * sync = null;
 *
 * // The following code snippet illustrates how video/audio raw frames are created by
 * // MediaCodec's, how they are fed to MediaSync and how they are returned by MediaSync.
 * // This is the callback from MediaCodec.
 * onOutputBufferAvailable(MediaCodec codec, int bufferId, BufferInfo info) {
 *     // ...
 *     if (codec == videoDecoder) {
 *         // surface timestamp must contain media presentation time in nanoseconds.
 *         codec.releaseOutputBuffer(bufferId, 1000 * info.presentationTime);
 *     } else {
 *         ByteBuffer audioByteBuffer = codec.getOutputBuffer(bufferId);
 *         sync.queueAudio(audioByteBuffer, bufferId, info.presentationTime);
 *     }
 *     // ...
 * }
 *
 * // This is the callback from MediaSync.
 * onAudioBufferConsumed(MediaSync sync, ByteBuffer buffer, int bufferId) {
 *     // ...
 *     audioDecoder.releaseBuffer(bufferId, false);
 *     // ...
 * }
 *
 *
* * The client needs to configure corresponding sink by setting the Surface and/or AudioTrack * based on the stream type it will play. *

* For video, the client needs to call {@link #createInputSurface} to obtain a surface on * which it will render video frames. *

* For audio, the client needs to set up audio track correctly, e.g., using {@link * AudioTrack#MODE_STREAM}. The audio buffers are sent to MediaSync directly via {@link * #queueAudio}, and are returned to the client via {@link Callback#onAudioBufferConsumed} * asynchronously. The client should not modify an audio buffer till it's returned. *

* The client can optionally pre-fill audio/video buffers by setting playback rate to 0.0, * and then feed audio/video buffers to corresponding components. This can reduce possible * initial underrun. *

*/ public final class MediaSync { /** * MediaSync callback interface. Used to notify the user asynchronously * of various MediaSync events. */ public static abstract class Callback { /** * Called when returning an audio buffer which has been consumed. * * @param sync The MediaSync object. * @param audioBuffer The returned audio buffer. * @param bufferId The ID associated with audioBuffer as passed into * {@link MediaSync#queueAudio}. */ public abstract void onAudioBufferConsumed( @NonNull MediaSync sync, @NonNull ByteBuffer audioBuffer, int bufferId); } /** Audio track failed. * @see android.media.MediaSync.OnErrorListener */ public static final int MEDIASYNC_ERROR_AUDIOTRACK_FAIL = 1; /** The surface failed to handle video buffers. * @see android.media.MediaSync.OnErrorListener */ public static final int MEDIASYNC_ERROR_SURFACE_FAIL = 2; /** * Interface definition of a callback to be invoked when there * has been an error during an asynchronous operation (other errors * will throw exceptions at method call time). */ public interface OnErrorListener { /** * Called to indicate an error. * * @param sync The MediaSync the error pertains to * @param what The type of error that has occurred: *

* @param extra an extra code, specific to the error. Typically * implementation dependent. */ void onError(@NonNull MediaSync sync, int what, int extra); } private static final String TAG = "MediaSync"; private static final int EVENT_CALLBACK = 1; private static final int EVENT_SET_CALLBACK = 2; private static final int CB_RETURN_AUDIO_BUFFER = 1; private static class AudioBuffer { public ByteBuffer mByteBuffer; public int mBufferIndex; long mPresentationTimeUs; public AudioBuffer(@NonNull ByteBuffer byteBuffer, int bufferId, long presentationTimeUs) { mByteBuffer = byteBuffer; mBufferIndex = bufferId; mPresentationTimeUs = presentationTimeUs; } } private final Object mCallbackLock = new Object(); private Handler mCallbackHandler = null; private MediaSync.Callback mCallback = null; private final Object mOnErrorListenerLock = new Object(); private Handler mOnErrorListenerHandler = null; private MediaSync.OnErrorListener mOnErrorListener = null; private Thread mAudioThread = null; // Created on mAudioThread when mAudioThread is started. When used on user thread, they should // be guarded by checking mAudioThread. private Handler mAudioHandler = null; private Looper mAudioLooper = null; private final Object mAudioLock = new Object(); private AudioTrack mAudioTrack = null; private List mAudioBuffers = new LinkedList(); // this is only used for paused/running decisions, so it is not affected by clock drift private float mPlaybackRate = 0.0f; private long mNativeContext; /** * Class constructor. On creation, MediaSync is paused, i.e., playback rate is 0.0f. */ public MediaSync() { native_setup(); } private native final void native_setup(); @Override protected void finalize() { native_finalize(); } private native final void native_finalize(); /** * Make sure you call this when you're done to free up any opened * component instance instead of relying on the garbage collector * to do this for you at some point in the future. */ public final void release() { returnAudioBuffers(); if (mAudioThread != null) { if (mAudioLooper != null) { mAudioLooper.quit(); } } setCallback(null, null); native_release(); } private native final void native_release(); /** * Sets an asynchronous callback for actionable MediaSync events. *

* This method can be called multiple times to update a previously set callback. If the * handler is changed, undelivered notifications scheduled for the old handler may be dropped. *

* Do not call this inside callback. * * @param cb The callback that will run. Use {@code null} to stop receiving callbacks. * @param handler The Handler that will run the callback. Use {@code null} to use MediaSync's * internal handler if it exists. */ public void setCallback(@Nullable /* MediaSync. */ Callback cb, @Nullable Handler handler) { synchronized(mCallbackLock) { if (handler != null) { mCallbackHandler = handler; } else { Looper looper; if ((looper = Looper.myLooper()) == null) { looper = Looper.getMainLooper(); } if (looper == null) { mCallbackHandler = null; } else { mCallbackHandler = new Handler(looper); } } mCallback = cb; } } /** * Sets an asynchronous callback for error events. *

* This method can be called multiple times to update a previously set listener. If the * handler is changed, undelivered notifications scheduled for the old handler may be dropped. *

* Do not call this inside callback. * * @param listener The callback that will run. Use {@code null} to stop receiving callbacks. * @param handler The Handler that will run the callback. Use {@code null} to use MediaSync's * internal handler if it exists. */ public void setOnErrorListener(@Nullable /* MediaSync. */ OnErrorListener listener, @Nullable Handler handler) { synchronized(mOnErrorListenerLock) { if (handler != null) { mOnErrorListenerHandler = handler; } else { Looper looper; if ((looper = Looper.myLooper()) == null) { looper = Looper.getMainLooper(); } if (looper == null) { mOnErrorListenerHandler = null; } else { mOnErrorListenerHandler = new Handler(looper); } } mOnErrorListener = listener; } } /** * Sets the output surface for MediaSync. *

* Currently, this is only supported in the Initialized state. * * @param surface Specify a surface on which to render the video data. * @throws IllegalArgumentException if the surface has been released, is invalid, * or can not be connected. * @throws IllegalStateException if setting the surface is not supported, e.g. * not in the Initialized state, or another surface has already been set. */ public void setSurface(@Nullable Surface surface) { native_setSurface(surface); } private native final void native_setSurface(@Nullable Surface surface); /** * Sets the audio track for MediaSync. *

* Currently, this is only supported in the Initialized state. * * @param audioTrack Specify an AudioTrack through which to render the audio data. * @throws IllegalArgumentException if the audioTrack has been released, or is invalid. * @throws IllegalStateException if setting the audio track is not supported, e.g. * not in the Initialized state, or another audio track has already been set. */ public void setAudioTrack(@Nullable AudioTrack audioTrack) { native_setAudioTrack(audioTrack); mAudioTrack = audioTrack; if (audioTrack != null && mAudioThread == null) { createAudioThread(); } } private native final void native_setAudioTrack(@Nullable AudioTrack audioTrack); /** * Requests a Surface to use as the input. This may only be called after * {@link #setSurface}. *

* The application is responsible for calling release() on the Surface when * done. * @throws IllegalStateException if not set, or another input surface has * already been created. */ @NonNull public native final Surface createInputSurface(); /** * Sets playback rate using {@link PlaybackParams}. *

* When using MediaSync with {@link AudioTrack}, set playback params using this * call instead of calling it directly on the track, so that the sync is aware of * the params change. *

* This call also works if there is no audio track. * * @param params the playback params to use. {@link PlaybackParams#getSpeed * Speed} is the ratio between desired playback rate and normal one. 1.0 means * normal playback speed. 0.0 means pause. Value larger than 1.0 means faster playback, * while value between 0.0 and 1.0 for slower playback. Note: the normal rate * does not change as a result of this call. To restore the original rate at any time, * use speed of 1.0. * * @throws IllegalStateException if the internal sync engine or the audio track has not * been initialized. * @throws IllegalArgumentException if the params are not supported. */ public void setPlaybackParams(@NonNull PlaybackParams params) { synchronized(mAudioLock) { mPlaybackRate = native_setPlaybackParams(params);; } if (mPlaybackRate != 0.0 && mAudioThread != null) { postRenderAudio(0); } } /** * Gets the playback rate using {@link PlaybackParams}. * * @return the playback rate being used. * * @throws IllegalStateException if the internal sync engine or the audio track has not * been initialized. */ @NonNull public native PlaybackParams getPlaybackParams(); private native float native_setPlaybackParams(@NonNull PlaybackParams params); /** * Sets A/V sync mode. * * @param params the A/V sync params to apply * * @throws IllegalStateException if the internal player engine has not been * initialized. * @throws IllegalArgumentException if params are not supported. */ public void setSyncParams(@NonNull SyncParams params) { synchronized(mAudioLock) { mPlaybackRate = native_setSyncParams(params);; } if (mPlaybackRate != 0.0 && mAudioThread != null) { postRenderAudio(0); } } private native float native_setSyncParams(@NonNull SyncParams params); /** * Gets the A/V sync mode. * * @return the A/V sync params * * @throws IllegalStateException if the internal player engine has not been * initialized. */ @NonNull public native SyncParams getSyncParams(); /** * Flushes all buffers from the sync object. *

* All pending unprocessed audio and video buffers are discarded. If an audio track was * configured, it is flushed and stopped. If a video output surface was configured, the * last frame queued to it is left on the frame. Queue a blank video frame to clear the * surface, *

* No callbacks are received for the flushed buffers. * * @throws IllegalStateException if the internal player engine has not been * initialized. */ public void flush() { synchronized(mAudioLock) { mAudioBuffers.clear(); mCallbackHandler.removeCallbacksAndMessages(null); } if (mAudioTrack != null) { mAudioTrack.pause(); mAudioTrack.flush(); // Call stop() to signal to the AudioSink to completely fill the // internal buffer before resuming playback. mAudioTrack.stop(); } native_flush(); } private native final void native_flush(); /** * Get current playback position. *

* The MediaTimestamp represents how the media time correlates to the system time in * a linear fashion using an anchor and a clock rate. During regular playback, the media * time moves fairly constantly (though the anchor frame may be rebased to a current * system time, the linear correlation stays steady). Therefore, this method does not * need to be called often. *

* To help users get current playback position, this method always anchors the timestamp * to the current {@link System#nanoTime system time}, so * {@link MediaTimestamp#getAnchorMediaTimeUs} can be used as current playback position. * * @return a MediaTimestamp object if a timestamp is available, or {@code null} if no timestamp * is available, e.g. because the media player has not been initialized. * * @see MediaTimestamp */ @Nullable public MediaTimestamp getTimestamp() { try { // TODO: create the timestamp in native MediaTimestamp timestamp = new MediaTimestamp(); if (native_getTimestamp(timestamp)) { return timestamp; } else { return null; } } catch (IllegalStateException e) { return null; } } private native final boolean native_getTimestamp(@NonNull MediaTimestamp timestamp); /** * Queues the audio data asynchronously for playback (AudioTrack must be in streaming mode). * If the audio track was flushed as a result of {@link #flush}, it will be restarted. * @param audioData the buffer that holds the data to play. This buffer will be returned * to the client via registered callback. * @param bufferId an integer used to identify audioData. It will be returned to * the client along with audioData. This helps applications to keep track of audioData, * e.g., it can be used to store the output buffer index used by the audio codec. * @param presentationTimeUs the presentation timestamp in microseconds for the first frame * in the buffer. * @throws IllegalStateException if audio track is not set or internal configureation * has not been done correctly. */ public void queueAudio( @NonNull ByteBuffer audioData, int bufferId, long presentationTimeUs) { if (mAudioTrack == null || mAudioThread == null) { throw new IllegalStateException( "AudioTrack is NOT set or audio thread is not created"); } synchronized(mAudioLock) { mAudioBuffers.add(new AudioBuffer(audioData, bufferId, presentationTimeUs)); } if (mPlaybackRate != 0.0) { postRenderAudio(0); } } // When called on user thread, make sure to check mAudioThread != null. private void postRenderAudio(long delayMillis) { mAudioHandler.postDelayed(new Runnable() { public void run() { synchronized(mAudioLock) { if (mPlaybackRate == 0.0) { return; } if (mAudioBuffers.isEmpty()) { return; } AudioBuffer audioBuffer = mAudioBuffers.get(0); int size = audioBuffer.mByteBuffer.remaining(); // restart audio track after flush if (size > 0 && mAudioTrack.getPlayState() != AudioTrack.PLAYSTATE_PLAYING) { try { mAudioTrack.play(); } catch (IllegalStateException e) { Log.w(TAG, "could not start audio track"); } } int sizeWritten = mAudioTrack.write( audioBuffer.mByteBuffer, size, AudioTrack.WRITE_NON_BLOCKING); if (sizeWritten > 0) { if (audioBuffer.mPresentationTimeUs != -1) { native_updateQueuedAudioData( size, audioBuffer.mPresentationTimeUs); audioBuffer.mPresentationTimeUs = -1; } if (sizeWritten == size) { postReturnByteBuffer(audioBuffer); mAudioBuffers.remove(0); if (!mAudioBuffers.isEmpty()) { postRenderAudio(0); } return; } } long pendingTimeMs = TimeUnit.MICROSECONDS.toMillis( native_getPlayTimeForPendingAudioFrames()); postRenderAudio(pendingTimeMs / 2); } } }, delayMillis); } private native final void native_updateQueuedAudioData( int sizeInBytes, long presentationTimeUs); private native final long native_getPlayTimeForPendingAudioFrames(); private final void postReturnByteBuffer(@NonNull final AudioBuffer audioBuffer) { synchronized(mCallbackLock) { if (mCallbackHandler != null) { final MediaSync sync = this; mCallbackHandler.post(new Runnable() { public void run() { Callback callback; synchronized(mCallbackLock) { callback = mCallback; if (mCallbackHandler == null || mCallbackHandler.getLooper().getThread() != Thread.currentThread()) { // callback handler has been changed. return; } } if (callback != null) { callback.onAudioBufferConsumed(sync, audioBuffer.mByteBuffer, audioBuffer.mBufferIndex); } } }); } } } private final void returnAudioBuffers() { synchronized(mAudioLock) { for (AudioBuffer audioBuffer: mAudioBuffers) { postReturnByteBuffer(audioBuffer); } mAudioBuffers.clear(); } } private void createAudioThread() { mAudioThread = new Thread() { @Override public void run() { Looper.prepare(); synchronized(mAudioLock) { mAudioLooper = Looper.myLooper(); mAudioHandler = new Handler(); mAudioLock.notify(); } Looper.loop(); } }; mAudioThread.start(); synchronized(mAudioLock) { try { mAudioLock.wait(); } catch(InterruptedException e) { } } } static { System.loadLibrary("media_jni"); native_init(); } private static native final void native_init(); }