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android / platform / frameworks / base / 4a8034c / . / media / java / android / media / AudioTrack.java
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/*
* Copyright (C) 2008 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 java.lang.annotation.Retention;
import java.lang.annotation.RetentionPolicy;
import java.lang.ref.WeakReference;
import java.lang.Math;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.NioUtils;
import java.util.Collection;
import android.annotation.IntDef;
import android.annotation.NonNull;
import android.app.ActivityThread;
import android.app.AppOpsManager;
import android.content.Context;
import android.os.Handler;
import android.os.IBinder;
import android.os.Looper;
import android.os.Message;
import android.os.Process;
import android.os.RemoteException;
import android.os.ServiceManager;
import android.util.ArrayMap;
import android.util.Log;
import com.android.internal.app.IAppOpsService;
/**
* The AudioTrack class manages and plays a single audio resource for Java applications.
* It allows streaming of PCM audio buffers to the audio sink for playback. This is
* achieved by "pushing" the data to the AudioTrack object using one of the
* {@link #write(byte[], int, int)}, {@link #write(short[], int, int)},
* and {@link #write(float[], int, int, int)} methods.
*
* <p>An AudioTrack instance can operate under two modes: static or streaming.<br>
* In Streaming mode, the application writes a continuous stream of data to the AudioTrack, using
* one of the {@code write()} methods. These are blocking and return when the data has been
* transferred from the Java layer to the native layer and queued for playback. The streaming
* mode is most useful when playing blocks of audio data that for instance are:
*
* <ul>
* <li>too big to fit in memory because of the duration of the sound to play,</li>
* <li>too big to fit in memory because of the characteristics of the audio data
* (high sampling rate, bits per sample ...)</li>
* <li>received or generated while previously queued audio is playing.</li>
* </ul>
*
* The static mode should be chosen when dealing with short sounds that fit in memory and
* that need to be played with the smallest latency possible. The static mode will
* therefore be preferred for UI and game sounds that are played often, and with the
* smallest overhead possible.
*
* <p>Upon creation, an AudioTrack object initializes its associated audio buffer.
* The size of this buffer, specified during the construction, determines how long an AudioTrack
* can play before running out of data.<br>
* For an AudioTrack using the static mode, this size is the maximum size of the sound that can
* be played from it.<br>
* For the streaming mode, data will be written to the audio sink in chunks of
* sizes less than or equal to the total buffer size.
*
* AudioTrack is not final and thus permits subclasses, but such use is not recommended.
*/
public class AudioTrack
{
//---------------------------------------------------------
// Constants
//--------------------
/** Minimum value for a linear gain or auxiliary effect level.
* This value must be exactly equal to 0.0f; do not change it.
*/
private static final float GAIN_MIN = 0.0f;
/** Maximum value for a linear gain or auxiliary effect level.
* This value must be greater than or equal to 1.0f.
*/
private static final float GAIN_MAX = 1.0f;
/** Minimum value for sample rate */
private static final int SAMPLE_RATE_HZ_MIN = 4000;
/** Maximum value for sample rate */
private static final int SAMPLE_RATE_HZ_MAX = 192000;
// FCC_8
/** Maximum value for AudioTrack channel count */
private static final int CHANNEL_COUNT_MAX = 8;
/** indicates AudioTrack state is stopped */
public static final int PLAYSTATE_STOPPED = 1; // matches SL_PLAYSTATE_STOPPED
/** indicates AudioTrack state is paused */
public static final int PLAYSTATE_PAUSED = 2; // matches SL_PLAYSTATE_PAUSED
/** indicates AudioTrack state is playing */
public static final int PLAYSTATE_PLAYING = 3; // matches SL_PLAYSTATE_PLAYING
// keep these values in sync with android_media_AudioTrack.cpp
/**
* Creation mode where audio data is transferred from Java to the native layer
* only once before the audio starts playing.
*/
public static final int MODE_STATIC = 0;
/**
* Creation mode where audio data is streamed from Java to the native layer
* as the audio is playing.
*/
public static final int MODE_STREAM = 1;
/** @hide */
@IntDef({
MODE_STATIC,
MODE_STREAM
})
@Retention(RetentionPolicy.SOURCE)
public @interface TransferMode {}
/**
* State of an AudioTrack that was not successfully initialized upon creation.
*/
public static final int STATE_UNINITIALIZED = 0;
/**
* State of an AudioTrack that is ready to be used.
*/
public static final int STATE_INITIALIZED = 1;
/**
* State of a successfully initialized AudioTrack that uses static data,
* but that hasn't received that data yet.
*/
public static final int STATE_NO_STATIC_DATA = 2;
/**
* Denotes a successful operation.
*/
public static final int SUCCESS = AudioSystem.SUCCESS;
/**
* Denotes a generic operation failure.
*/
public static final int ERROR = AudioSystem.ERROR;
/**
* Denotes a failure due to the use of an invalid value.
*/
public static final int ERROR_BAD_VALUE = AudioSystem.BAD_VALUE;
/**
* Denotes a failure due to the improper use of a method.
*/
public static final int ERROR_INVALID_OPERATION = AudioSystem.INVALID_OPERATION;
/**
* An error code indicating that the object reporting it is no longer valid and needs to
* be recreated.
* @hide
*/
public static final int ERROR_DEAD_OBJECT = AudioSystem.DEAD_OBJECT;
/**
* {@link #getTimestampWithStatus(AudioTimestamp)} is called in STOPPED or FLUSHED state,
* or immediately after start/ACTIVE.
* @hide
*/
public static final int ERROR_WOULD_BLOCK = AudioSystem.WOULD_BLOCK;
// Error codes:
// to keep in sync with frameworks/base/core/jni/android_media_AudioTrack.cpp
private static final int ERROR_NATIVESETUP_AUDIOSYSTEM = -16;
private static final int ERROR_NATIVESETUP_INVALIDCHANNELMASK = -17;
private static final int ERROR_NATIVESETUP_INVALIDFORMAT = -18;
private static final int ERROR_NATIVESETUP_INVALIDSTREAMTYPE = -19;
private static final int ERROR_NATIVESETUP_NATIVEINITFAILED = -20;
// Events:
// to keep in sync with frameworks/av/include/media/AudioTrack.h
/**
* Event id denotes when playback head has reached a previously set marker.
*/
private static final int NATIVE_EVENT_MARKER = 3;
/**
* Event id denotes when previously set update period has elapsed during playback.
*/
private static final int NATIVE_EVENT_NEW_POS = 4;
private final static String TAG = "android.media.AudioTrack";
/** @hide */
@IntDef({
WRITE_BLOCKING,
WRITE_NON_BLOCKING
})
@Retention(RetentionPolicy.SOURCE)
public @interface WriteMode {}
/**
* The write mode indicating the write operation will block until all data has been written,
* to be used as the actual value of the writeMode parameter in
* {@link #write(byte[], int, int, int)}, {@link #write(short[], int, int, int)},
* {@link #write(float[], int, int, int)}, {@link #write(ByteBuffer, int, int)}, and
* {@link #write(ByteBuffer, int, int, long)}.
*/
public final static int WRITE_BLOCKING = 0;
/**
* The write mode indicating the write operation will return immediately after
* queuing as much audio data for playback as possible without blocking,
* to be used as the actual value of the writeMode parameter in
* {@link #write(ByteBuffer, int, int)}, {@link #write(short[], int, int, int)},
* {@link #write(float[], int, int, int)}, {@link #write(ByteBuffer, int, int)}, and
* {@link #write(ByteBuffer, int, int, long)}.
*/
public final static int WRITE_NON_BLOCKING = 1;
//--------------------------------------------------------------------------
// Member variables
//--------------------
/**
* Indicates the state of the AudioTrack instance.
* One of STATE_UNINITIALIZED, STATE_INITIALIZED, or STATE_NO_STATIC_DATA.
*/
private int mState = STATE_UNINITIALIZED;
/**
* Indicates the play state of the AudioTrack instance.
* One of PLAYSTATE_STOPPED, PLAYSTATE_PAUSED, or PLAYSTATE_PLAYING.
*/
private int mPlayState = PLAYSTATE_STOPPED;
/**
* Lock to ensure mPlayState updates reflect the actual state of the object.
*/
private final Object mPlayStateLock = new Object();
/**
* Sizes of the native audio buffer.
* These values are set during construction and can be stale.
* To obtain the current native audio buffer frame count use {@link #getBufferSizeInFrames()}.
*/
private int mNativeBufferSizeInBytes = 0;
private int mNativeBufferSizeInFrames = 0;
/**
* Handler for events coming from the native code.
*/
private NativePositionEventHandlerDelegate mEventHandlerDelegate;
/**
* Looper associated with the thread that creates the AudioTrack instance.
*/
private final Looper mInitializationLooper;
/**
* The audio data source sampling rate in Hz.
*/
private int mSampleRate; // initialized by all constructors via audioParamCheck()
/**
* The number of audio output channels (1 is mono, 2 is stereo, etc.).
*/
private int mChannelCount = 1;
/**
* The audio channel mask used for calling native AudioTrack
*/
private int mChannelMask = AudioFormat.CHANNEL_OUT_MONO;
/**
* The type of the audio stream to play. See
* {@link AudioManager#STREAM_VOICE_CALL}, {@link AudioManager#STREAM_SYSTEM},
* {@link AudioManager#STREAM_RING}, {@link AudioManager#STREAM_MUSIC},
* {@link AudioManager#STREAM_ALARM}, {@link AudioManager#STREAM_NOTIFICATION}, and
* {@link AudioManager#STREAM_DTMF}.
*/
private int mStreamType = AudioManager.STREAM_MUSIC;
private final AudioAttributes mAttributes;
/**
* The way audio is consumed by the audio sink, one of MODE_STATIC or MODE_STREAM.
*/
private int mDataLoadMode = MODE_STREAM;
/**
* The current channel position mask, as specified on AudioTrack creation.
* Can be set simultaneously with channel index mask {@link #mChannelIndexMask}.
* May be set to {@link AudioFormat#CHANNEL_INVALID} if a channel index mask is specified.
*/
private int mChannelConfiguration = AudioFormat.CHANNEL_OUT_MONO;
/**
* The channel index mask if specified, otherwise 0.
*/
private int mChannelIndexMask = 0;
/**
* The encoding of the audio samples.
* @see AudioFormat#ENCODING_PCM_8BIT
* @see AudioFormat#ENCODING_PCM_16BIT
* @see AudioFormat#ENCODING_PCM_FLOAT
*/
private int mAudioFormat; // initialized by all constructors via audioParamCheck()
/**
* Audio session ID
*/
private int mSessionId = AudioSystem.AUDIO_SESSION_ALLOCATE;
/**
* Reference to the app-ops service.
*/
private final IAppOpsService mAppOps;
/**
* HW_AV_SYNC track AV Sync Header
*/
private ByteBuffer mAvSyncHeader = null;
/**
* HW_AV_SYNC track audio data bytes remaining to write after current AV sync header
*/
private int mAvSyncBytesRemaining = 0;
//--------------------------------
// Used exclusively by native code
//--------------------
/**
* Accessed by native methods: provides access to C++ AudioTrack object.
*/
@SuppressWarnings("unused")
private long mNativeTrackInJavaObj;
/**
* Accessed by native methods: provides access to the JNI data (i.e. resources used by
* the native AudioTrack object, but not stored in it).
*/
@SuppressWarnings("unused")
private long mJniData;
//--------------------------------------------------------------------------
// Constructor, Finalize
//--------------------
/**
* Class constructor.
* @param streamType the type of the audio stream. See
* {@link AudioManager#STREAM_VOICE_CALL}, {@link AudioManager#STREAM_SYSTEM},
* {@link AudioManager#STREAM_RING}, {@link AudioManager#STREAM_MUSIC},
* {@link AudioManager#STREAM_ALARM}, and {@link AudioManager#STREAM_NOTIFICATION}.
* @param sampleRateInHz the initial source sample rate expressed in Hz.
* @param channelConfig describes the configuration of the audio channels.
* See {@link AudioFormat#CHANNEL_OUT_MONO} and
* {@link AudioFormat#CHANNEL_OUT_STEREO}
* @param audioFormat the format in which the audio data is represented.
* See {@link AudioFormat#ENCODING_PCM_16BIT},
* {@link AudioFormat#ENCODING_PCM_8BIT},
* and {@link AudioFormat#ENCODING_PCM_FLOAT}.
* @param bufferSizeInBytes the total size (in bytes) of the internal buffer where audio data is
* read from for playback. This should be a multiple of the frame size in bytes.
* <p> If the track's creation mode is {@link #MODE_STATIC},
* this is the maximum length sample, or audio clip, that can be played by this instance.
* <p> If the track's creation mode is {@link #MODE_STREAM},
* this should be the desired buffer size
* for the <code>AudioTrack</code> to satisfy the application's
* natural latency requirements.
* If <code>bufferSizeInBytes</code> is less than the
* minimum buffer size for the output sink, it is automatically increased to the minimum
* buffer size.
* The method {@link #getBufferSizeInFrames()} returns the
* actual size in frames of the native buffer created, which
* determines the frequency to write
* to the streaming <code>AudioTrack</code> to avoid underrun.
* @param mode streaming or static buffer. See {@link #MODE_STATIC} and {@link #MODE_STREAM}
* @throws java.lang.IllegalArgumentException
*/
public AudioTrack(int streamType, int sampleRateInHz, int channelConfig, int audioFormat,
int bufferSizeInBytes, int mode)
throws IllegalArgumentException {
this(streamType, sampleRateInHz, channelConfig, audioFormat,
bufferSizeInBytes, mode, AudioSystem.AUDIO_SESSION_ALLOCATE);
}
/**
* Class constructor with audio session. Use this constructor when the AudioTrack must be
* attached to a particular audio session. The primary use of the audio session ID is to
* associate audio effects to a particular instance of AudioTrack: if an audio session ID
* is provided when creating an AudioEffect, this effect will be applied only to audio tracks
* and media players in the same session and not to the output mix.
* When an AudioTrack is created without specifying a session, it will create its own session
* which can be retrieved by calling the {@link #getAudioSessionId()} method.
* If a non-zero session ID is provided, this AudioTrack will share effects attached to this
* session
* with all other media players or audio tracks in the same session, otherwise a new session
* will be created for this track if none is supplied.
* @param streamType the type of the audio stream. See
* {@link AudioManager#STREAM_VOICE_CALL}, {@link AudioManager#STREAM_SYSTEM},
* {@link AudioManager#STREAM_RING}, {@link AudioManager#STREAM_MUSIC},
* {@link AudioManager#STREAM_ALARM}, and {@link AudioManager#STREAM_NOTIFICATION}.
* @param sampleRateInHz the initial source sample rate expressed in Hz.
* @param channelConfig describes the configuration of the audio channels.
* See {@link AudioFormat#CHANNEL_OUT_MONO} and
* {@link AudioFormat#CHANNEL_OUT_STEREO}
* @param audioFormat the format in which the audio data is represented.
* See {@link AudioFormat#ENCODING_PCM_16BIT} and
* {@link AudioFormat#ENCODING_PCM_8BIT},
* and {@link AudioFormat#ENCODING_PCM_FLOAT}.
* @param bufferSizeInBytes the total size (in bytes) of the buffer where audio data is read
* from for playback. If using the AudioTrack in streaming mode, you can write data into
* this buffer in smaller chunks than this size. If using the AudioTrack in static mode,
* this is the maximum size of the sound that will be played for this instance.
* See {@link #getMinBufferSize(int, int, int)} to determine the minimum required buffer size
* for the successful creation of an AudioTrack instance in streaming mode. Using values
* smaller than getMinBufferSize() will result in an initialization failure.
* @param mode streaming or static buffer. See {@link #MODE_STATIC} and {@link #MODE_STREAM}
* @param sessionId Id of audio session the AudioTrack must be attached to
* @throws java.lang.IllegalArgumentException
*/
public AudioTrack(int streamType, int sampleRateInHz, int channelConfig, int audioFormat,
int bufferSizeInBytes, int mode, int sessionId)
throws IllegalArgumentException {
// mState already == STATE_UNINITIALIZED
this((new AudioAttributes.Builder())
.setLegacyStreamType(streamType)
.build(),
(new AudioFormat.Builder())
.setChannelMask(channelConfig)
.setEncoding(audioFormat)
.setSampleRate(sampleRateInHz)
.build(),
bufferSizeInBytes,
mode, sessionId);
}
/**
* Class constructor with {@link AudioAttributes} and {@link AudioFormat}.
* @param attributes a non-null {@link AudioAttributes} instance.
* @param format a non-null {@link AudioFormat} instance describing the format of the data
* that will be played through this AudioTrack. See {@link AudioFormat.Builder} for
* configuring the audio format parameters such as encoding, channel mask and sample rate.
* @param bufferSizeInBytes the total size (in bytes) of the buffer where audio data is read
* from for playback. If using the AudioTrack in streaming mode, you can write data into
* this buffer in smaller chunks than this size. If using the AudioTrack in static mode,
* this is the maximum size of the sound that will be played for this instance.
* See {@link #getMinBufferSize(int, int, int)} to determine the minimum required buffer size
* for the successful creation of an AudioTrack instance in streaming mode. Using values
* smaller than getMinBufferSize() will result in an initialization failure.
* @param mode streaming or static buffer. See {@link #MODE_STATIC} and {@link #MODE_STREAM}.
* @param sessionId ID of audio session the AudioTrack must be attached to, or
* {@link AudioManager#AUDIO_SESSION_ID_GENERATE} if the session isn't known at construction
* time. See also {@link AudioManager#generateAudioSessionId()} to obtain a session ID before
* construction.
* @throws IllegalArgumentException
*/
public AudioTrack(AudioAttributes attributes, AudioFormat format, int bufferSizeInBytes,
int mode, int sessionId)
throws IllegalArgumentException {
// mState already == STATE_UNINITIALIZED
if (attributes == null) {
throw new IllegalArgumentException("Illegal null AudioAttributes");
}
if (format == null) {
throw new IllegalArgumentException("Illegal null AudioFormat");
}
// remember which looper is associated with the AudioTrack instantiation
Looper looper;
if ((looper = Looper.myLooper()) == null) {
looper = Looper.getMainLooper();
}
int rate = 0;
if ((format.getPropertySetMask() & AudioFormat.AUDIO_FORMAT_HAS_PROPERTY_SAMPLE_RATE) != 0)
{
rate = format.getSampleRate();
} else {
rate = AudioSystem.getPrimaryOutputSamplingRate();
if (rate <= 0) {
rate = 44100;
}
}
int channelIndexMask = 0;
if ((format.getPropertySetMask()
& AudioFormat.AUDIO_FORMAT_HAS_PROPERTY_CHANNEL_INDEX_MASK) != 0) {
channelIndexMask = format.getChannelIndexMask();
}
int channelMask = 0;
if ((format.getPropertySetMask()
& AudioFormat.AUDIO_FORMAT_HAS_PROPERTY_CHANNEL_MASK) != 0) {
channelMask = format.getChannelMask();
} else if (channelIndexMask == 0) { // if no masks at all, use stereo
channelMask = AudioFormat.CHANNEL_OUT_FRONT_LEFT
| AudioFormat.CHANNEL_OUT_FRONT_RIGHT;
}
int encoding = AudioFormat.ENCODING_DEFAULT;
if ((format.getPropertySetMask() & AudioFormat.AUDIO_FORMAT_HAS_PROPERTY_ENCODING) != 0) {
encoding = format.getEncoding();
}
audioParamCheck(rate, channelMask, channelIndexMask, encoding, mode);
mStreamType = AudioSystem.STREAM_DEFAULT;
audioBuffSizeCheck(bufferSizeInBytes);
mInitializationLooper = looper;
IBinder b = ServiceManager.getService(Context.APP_OPS_SERVICE);
mAppOps = IAppOpsService.Stub.asInterface(b);
mAttributes = new AudioAttributes.Builder(attributes).build();
if (sessionId < 0) {
throw new IllegalArgumentException("Invalid audio session ID: "+sessionId);
}
int[] session = new int[1];
session[0] = sessionId;
// native initialization
int initResult = native_setup(new WeakReference<AudioTrack>(this), mAttributes,
mSampleRate, mChannelMask, mChannelIndexMask, mAudioFormat,
mNativeBufferSizeInBytes, mDataLoadMode, session);
if (initResult != SUCCESS) {
loge("Error code "+initResult+" when initializing AudioTrack.");
return; // with mState == STATE_UNINITIALIZED
}
mSessionId = session[0];
if (mDataLoadMode == MODE_STATIC) {
mState = STATE_NO_STATIC_DATA;
} else {
mState = STATE_INITIALIZED;
}
}
/**
* Builder class for {@link AudioTrack} objects.
* Use this class to configure and create an <code>AudioTrack</code> instance. By setting audio
* attributes and audio format parameters, you indicate which of those vary from the default
* behavior on the device.
* <p> Here is an example where <code>Builder</code> is used to specify all {@link AudioFormat}
* parameters, to be used by a new <code>AudioTrack</code> instance:
*
* <pre class="prettyprint">
* AudioTrack player = new AudioTrack.Builder()
* .setAudioAttributes(new AudioAttributes.Builder()
* .setUsage(AudioAttributes.USAGE_ALARM)
* .setContentType(CONTENT_TYPE_MUSIC)
* .build())
* .setAudioFormat(new AudioFormat.Builder()
* .setEncoding(AudioFormat.ENCODING_PCM_16BIT)
* .setSampleRate(441000)
* .setChannelMask(AudioFormat.CHANNEL_OUT_STEREO)
* .build())
* .setBufferSize(minBuffSize)
* .build();
* </pre>
* <p>
* If the audio attributes are not set with {@link #setAudioAttributes(AudioAttributes)},
* attributes comprising {@link AudioAttributes#USAGE_MEDIA} will be used.
* <br>If the audio format is not specified or is incomplete, its sample rate will be the
* default output sample rate of the device (see
* {@link AudioManager#PROPERTY_OUTPUT_SAMPLE_RATE}), its channel configuration will be
* {@link AudioFormat#CHANNEL_OUT_STEREO} and the encoding will be
* {@link AudioFormat#ENCODING_PCM_16BIT}.
* <br>If the buffer size is not specified with {@link #setBufferSizeInBytes(int)},
* and the mode is {@link AudioTrack#MODE_STREAM}, the minimum buffer size is used.
* <br>If the transfer mode is not specified with {@link #setTransferMode(int)},
* <code>MODE_STREAM</code> will be used.
* <br>If the session ID is not specified with {@link #setSessionId(int)}, a new one will
* be generated.
*/
public static class Builder {
private AudioAttributes mAttributes;
private AudioFormat mFormat;
private int mBufferSizeInBytes;
private int mSessionId = AudioManager.AUDIO_SESSION_ID_GENERATE;
private int mMode = MODE_STREAM;
/**
* Constructs a new Builder with the default values as described above.
*/
public Builder() {
}
/**
* Sets the {@link AudioAttributes}.
* @param attributes a non-null {@link AudioAttributes} instance that describes the audio
* data to be played.
* @return the same Builder instance.
* @throws IllegalArgumentException
*/
public @NonNull Builder setAudioAttributes(@NonNull AudioAttributes attributes)
throws IllegalArgumentException {
if (attributes == null) {
throw new IllegalArgumentException("Illegal null AudioAttributes argument");
}
// keep reference, we only copy the data when building
mAttributes = attributes;
return this;
}
/**
* Sets the format of the audio data to be played by the {@link AudioTrack}.
* See {@link AudioFormat.Builder} for configuring the audio format parameters such
* as encoding, channel mask and sample rate.
* @param format a non-null {@link AudioFormat} instance.
* @return the same Builder instance.
* @throws IllegalArgumentException
*/
public @NonNull Builder setAudioFormat(@NonNull AudioFormat format)
throws IllegalArgumentException {
if (format == null) {
throw new IllegalArgumentException("Illegal null AudioFormat argument");
}
// keep reference, we only copy the data when building
mFormat = format;
return this;
}
/**
* Sets the total size (in bytes) of the buffer where audio data is read from for playback.
* If using the {@link AudioTrack} in streaming mode
* (see {@link AudioTrack#MODE_STREAM}, you can write data into this buffer in smaller
* chunks than this size. See {@link #getMinBufferSize(int, int, int)} to determine
* the minimum required buffer size for the successful creation of an AudioTrack instance
* in streaming mode. Using values smaller than <code>getMinBufferSize()</code> will result
* in an exception when trying to build the <code>AudioTrack</code>.
* <br>If using the <code>AudioTrack</code> in static mode (see
* {@link AudioTrack#MODE_STATIC}), this is the maximum size of the sound that will be
* played by this instance.
* @param bufferSizeInBytes
* @return the same Builder instance.
* @throws IllegalArgumentException
*/
public @NonNull Builder setBufferSizeInBytes(int bufferSizeInBytes)
throws IllegalArgumentException {
if (bufferSizeInBytes <= 0) {
throw new IllegalArgumentException("Invalid buffer size " + bufferSizeInBytes);
}
mBufferSizeInBytes = bufferSizeInBytes;
return this;
}
/**
* Sets the mode under which buffers of audio data are transferred from the
* {@link AudioTrack} to the framework.
* @param mode one of {@link AudioTrack#MODE_STREAM}, {@link AudioTrack#MODE_STATIC}.
* @return the same Builder instance.
* @throws IllegalArgumentException
*/
public @NonNull Builder setTransferMode(@TransferMode int mode)
throws IllegalArgumentException {
switch(mode) {
case MODE_STREAM:
case MODE_STATIC:
mMode = mode;
break;
default:
throw new IllegalArgumentException("Invalid transfer mode " + mode);
}
return this;
}
/**
* Sets the session ID the {@link AudioTrack} will be attached to.
* @param sessionId a strictly positive ID number retrieved from another
* <code>AudioTrack</code> via {@link AudioTrack#getAudioSessionId()} or allocated by
* {@link AudioManager} via {@link AudioManager#generateAudioSessionId()}, or
* {@link AudioManager#AUDIO_SESSION_ID_GENERATE}.
* @return the same Builder instance.
* @throws IllegalArgumentException
*/
public @NonNull Builder setSessionId(int sessionId)
throws IllegalArgumentException {
if ((sessionId != AudioManager.AUDIO_SESSION_ID_GENERATE) && (sessionId < 1)) {
throw new IllegalArgumentException("Invalid audio session ID " + sessionId);
}
mSessionId = sessionId;
return this;
}
/**
* Builds an {@link AudioTrack} instance initialized with all the parameters set
* on this <code>Builder</code>.
* @return a new successfully initialized {@link AudioTrack} instance.
* @throws UnsupportedOperationException if the parameters set on the <code>Builder</code>
* were incompatible, or if they are not supported by the device,
* or if the device was not available.
*/
public @NonNull AudioTrack build() throws UnsupportedOperationException {
if (mAttributes == null) {
mAttributes = new AudioAttributes.Builder()
.setUsage(AudioAttributes.USAGE_MEDIA)
.build();
}
if (mFormat == null) {
mFormat = new AudioFormat.Builder()
.setChannelMask(AudioFormat.CHANNEL_OUT_STEREO)
.setSampleRate(AudioSystem.getPrimaryOutputSamplingRate())
.setEncoding(AudioFormat.ENCODING_DEFAULT)
.build();
}
try {
// If the buffer size is not specified in streaming mode,
// use a single frame for the buffer size and let the
// native code figure out the minimum buffer size.
if (mMode == MODE_STREAM && mBufferSizeInBytes == 0) {
mBufferSizeInBytes = mFormat.getChannelCount()
* mFormat.getBytesPerSample(mFormat.getEncoding());
}
final AudioTrack track = new AudioTrack(
mAttributes, mFormat, mBufferSizeInBytes, mMode, mSessionId);
if (track.getState() == STATE_UNINITIALIZED) {
// release is not necessary
throw new UnsupportedOperationException("Cannot create AudioTrack");
}
return track;
} catch (IllegalArgumentException e) {
throw new UnsupportedOperationException(e.getMessage());
}
}
}
// mask of all the positional channels supported, however the allowed combinations
// are further restricted by the matching left/right rule and CHANNEL_COUNT_MAX
private static final int SUPPORTED_OUT_CHANNELS =
AudioFormat.CHANNEL_OUT_FRONT_LEFT |
AudioFormat.CHANNEL_OUT_FRONT_RIGHT |
AudioFormat.CHANNEL_OUT_FRONT_CENTER |
AudioFormat.CHANNEL_OUT_LOW_FREQUENCY |
AudioFormat.CHANNEL_OUT_BACK_LEFT |
AudioFormat.CHANNEL_OUT_BACK_RIGHT |
AudioFormat.CHANNEL_OUT_BACK_CENTER |
AudioFormat.CHANNEL_OUT_SIDE_LEFT |
AudioFormat.CHANNEL_OUT_SIDE_RIGHT;
// Convenience method for the constructor's parameter checks.
// This is where constructor IllegalArgumentException-s are thrown
// postconditions:
// mChannelCount is valid
// mChannelMask is valid
// mAudioFormat is valid
// mSampleRate is valid
// mDataLoadMode is valid
private void audioParamCheck(int sampleRateInHz, int channelConfig, int channelIndexMask,
int audioFormat, int mode) {
//--------------
// sample rate, note these values are subject to change
if (sampleRateInHz < SAMPLE_RATE_HZ_MIN || sampleRateInHz > SAMPLE_RATE_HZ_MAX) {
throw new IllegalArgumentException(sampleRateInHz
+ "Hz is not a supported sample rate.");
}
mSampleRate = sampleRateInHz;
//--------------
// channel config
mChannelConfiguration = channelConfig;
switch (channelConfig) {
case AudioFormat.CHANNEL_OUT_DEFAULT: //AudioFormat.CHANNEL_CONFIGURATION_DEFAULT
case AudioFormat.CHANNEL_OUT_MONO:
case AudioFormat.CHANNEL_CONFIGURATION_MONO:
mChannelCount = 1;
mChannelMask = AudioFormat.CHANNEL_OUT_MONO;
break;
case AudioFormat.CHANNEL_OUT_STEREO:
case AudioFormat.CHANNEL_CONFIGURATION_STEREO:
mChannelCount = 2;
mChannelMask = AudioFormat.CHANNEL_OUT_STEREO;
break;
default:
if (channelConfig == AudioFormat.CHANNEL_INVALID && channelIndexMask != 0) {
mChannelCount = 0;
break; // channel index configuration only
}
if (!isMultichannelConfigSupported(channelConfig)) {
// input channel configuration features unsupported channels
throw new IllegalArgumentException("Unsupported channel configuration.");
}
mChannelMask = channelConfig;
mChannelCount = AudioFormat.channelCountFromOutChannelMask(channelConfig);
}
// check the channel index configuration (if present)
mChannelIndexMask = channelIndexMask;
if (mChannelIndexMask != 0) {
// restrictive: indexMask could allow up to AUDIO_CHANNEL_BITS_LOG2
final int indexMask = (1 << CHANNEL_COUNT_MAX) - 1;
if ((channelIndexMask & ~indexMask) != 0) {
throw new IllegalArgumentException("Unsupported channel index configuration "
+ channelIndexMask);
}
int channelIndexCount = Integer.bitCount(channelIndexMask);
if (mChannelCount == 0) {
mChannelCount = channelIndexCount;
} else if (mChannelCount != channelIndexCount) {
throw new IllegalArgumentException("Channel count must match");
}
}
//--------------
// audio format
if (audioFormat == AudioFormat.ENCODING_DEFAULT) {
audioFormat = AudioFormat.ENCODING_PCM_16BIT;
}
if (!AudioFormat.isPublicEncoding(audioFormat)) {
throw new IllegalArgumentException("Unsupported audio encoding.");
}
mAudioFormat = audioFormat;
//--------------
// audio load mode
if (((mode != MODE_STREAM) && (mode != MODE_STATIC)) ||
((mode != MODE_STREAM) && !AudioFormat.isEncodingLinearPcm(mAudioFormat))) {
throw new IllegalArgumentException("Invalid mode.");
}
mDataLoadMode = mode;
}
/**
* Convenience method to check that the channel configuration (a.k.a channel mask) is supported
* @param channelConfig the mask to validate
* @return false if the AudioTrack can't be used with such a mask
*/
private static boolean isMultichannelConfigSupported(int channelConfig) {
// check for unsupported channels
if ((channelConfig & SUPPORTED_OUT_CHANNELS) != channelConfig) {
loge("Channel configuration features unsupported channels");
return false;
}
final int channelCount = AudioFormat.channelCountFromOutChannelMask(channelConfig);
if (channelCount > CHANNEL_COUNT_MAX) {
loge("Channel configuration contains too many channels " +
channelCount + ">" + CHANNEL_COUNT_MAX);
return false;
}
// check for unsupported multichannel combinations:
// - FL/FR must be present
// - L/R channels must be paired (e.g. no single L channel)
final int frontPair =
AudioFormat.CHANNEL_OUT_FRONT_LEFT | AudioFormat.CHANNEL_OUT_FRONT_RIGHT;
if ((channelConfig & frontPair) != frontPair) {
loge("Front channels must be present in multichannel configurations");
return false;
}
final int backPair =
AudioFormat.CHANNEL_OUT_BACK_LEFT | AudioFormat.CHANNEL_OUT_BACK_RIGHT;
if ((channelConfig & backPair) != 0) {
if ((channelConfig & backPair) != backPair) {
loge("Rear channels can't be used independently");
return false;
}
}
final int sidePair =
AudioFormat.CHANNEL_OUT_SIDE_LEFT | AudioFormat.CHANNEL_OUT_SIDE_RIGHT;
if ((channelConfig & sidePair) != 0
&& (channelConfig & sidePair) != sidePair) {
loge("Side channels can't be used independently");
return false;
}
return true;
}
// Convenience method for the constructor's audio buffer size check.
// preconditions:
// mChannelCount is valid
// mAudioFormat is valid
// postcondition:
// mNativeBufferSizeInBytes is valid (multiple of frame size, positive)
private void audioBuffSizeCheck(int audioBufferSize) {
// NB: this section is only valid with PCM data.
// To update when supporting compressed formats
int frameSizeInBytes;
if (AudioFormat.isEncodingLinearPcm(mAudioFormat)) {
frameSizeInBytes = mChannelCount * AudioFormat.getBytesPerSample(mAudioFormat);
} else {
frameSizeInBytes = 1;
}
if ((audioBufferSize % frameSizeInBytes != 0) || (audioBufferSize < 1)) {
throw new IllegalArgumentException("Invalid audio buffer size.");
}
mNativeBufferSizeInBytes = audioBufferSize;
mNativeBufferSizeInFrames = audioBufferSize / frameSizeInBytes;
}
/**
* Releases the native AudioTrack resources.
*/
public void release() {
// even though native_release() stops the native AudioTrack, we need to stop
// AudioTrack subclasses too.
try {
stop();
} catch(IllegalStateException ise) {
// don't raise an exception, we're releasing the resources.
}
native_release();
mState = STATE_UNINITIALIZED;
}
@Override
protected void finalize() {
native_finalize();
}
//--------------------------------------------------------------------------
// Getters
//--------------------
/**
* Returns the minimum gain value, which is the constant 0.0.
* Gain values less than 0.0 will be clamped to 0.0.
* <p>The word "volume" in the API name is historical; this is actually a linear gain.
* @return the minimum value, which is the constant 0.0.
*/
static public float getMinVolume() {
return GAIN_MIN;
}
/**
* Returns the maximum gain value, which is greater than or equal to 1.0.
* Gain values greater than the maximum will be clamped to the maximum.
* <p>The word "volume" in the API name is historical; this is actually a gain.
* expressed as a linear multiplier on sample values, where a maximum value of 1.0
* corresponds to a gain of 0 dB (sample values left unmodified).
* @return the maximum value, which is greater than or equal to 1.0.
*/
static public float getMaxVolume() {
return GAIN_MAX;
}
/**
* Returns the configured audio data sample rate in Hz
*/
public int getSampleRate() {
return mSampleRate;
}
/**
* Returns the current playback sample rate rate in Hz.
*/
public int getPlaybackRate() {
return native_get_playback_rate();
}
/**
* Returns the current playback parameters.
* See {@link #setPlaybackParams(PlaybackParams)} to set playback parameters
* @return current {@link PlaybackParams}.
* @throws IllegalStateException if track is not initialized.
*/
public @NonNull PlaybackParams getPlaybackParams() {
return native_get_playback_params();
}
/**
* Returns the configured audio data encoding. See {@link AudioFormat#ENCODING_PCM_8BIT},
* {@link AudioFormat#ENCODING_PCM_16BIT}, and {@link AudioFormat#ENCODING_PCM_FLOAT}.
*/
public int getAudioFormat() {
return mAudioFormat;
}
/**
* Returns the type of audio stream this AudioTrack is configured for.
* Compare the result against {@link AudioManager#STREAM_VOICE_CALL},
* {@link AudioManager#STREAM_SYSTEM}, {@link AudioManager#STREAM_RING},
* {@link AudioManager#STREAM_MUSIC}, {@link AudioManager#STREAM_ALARM},
* {@link AudioManager#STREAM_NOTIFICATION}, or {@link AudioManager#STREAM_DTMF}.
*/
public int getStreamType() {
return mStreamType;
}
/**
* Returns the configured channel position mask.
* <p> For example, refer to {@link AudioFormat#CHANNEL_OUT_MONO},
* {@link AudioFormat#CHANNEL_OUT_STEREO}, {@link AudioFormat#CHANNEL_OUT_5POINT1}.
* This method may return {@link AudioFormat#CHANNEL_INVALID} if
* a channel index mask was used. Consider
* {@link #getFormat()} instead, to obtain an {@link AudioFormat},
* which contains both the channel position mask and the channel index mask.
*/
public int getChannelConfiguration() {
return mChannelConfiguration;
}
/**
* Returns the configured <code>AudioTrack</code> format.
* @return an {@link AudioFormat} containing the
* <code>AudioTrack</code> parameters at the time of configuration.
*/
public @NonNull AudioFormat getFormat() {
AudioFormat.Builder builder = new AudioFormat.Builder()
.setSampleRate(mSampleRate)
.setEncoding(mAudioFormat);
if (mChannelConfiguration != AudioFormat.CHANNEL_INVALID) {
builder.setChannelMask(mChannelConfiguration);
}
if (mChannelIndexMask != AudioFormat.CHANNEL_INVALID /* 0 */) {
builder.setChannelIndexMask(mChannelIndexMask);
}
return builder.build();
}
/**
* Returns the configured number of channels.
*/
public int getChannelCount() {
return mChannelCount;
}
/**
* Returns the state of the AudioTrack instance. This is useful after the
* AudioTrack instance has been created to check if it was initialized
* properly. This ensures that the appropriate resources have been acquired.
* @see #STATE_UNINITIALIZED
* @see #STATE_INITIALIZED
* @see #STATE_NO_STATIC_DATA
*/
public int getState() {
return mState;
}
/**
* Returns the playback state of the AudioTrack instance.
* @see #PLAYSTATE_STOPPED
* @see #PLAYSTATE_PAUSED
* @see #PLAYSTATE_PLAYING
*/
public int getPlayState() {
synchronized (mPlayStateLock) {
return mPlayState;
}
}
/**
* Returns the frame count of the native <code>AudioTrack</code> buffer.
* <p> If the track's creation mode is {@link #MODE_STATIC},
* it is equal to the specified bufferSizeInBytes on construction, converted to frame units.
* A static track's native frame count will not change.
* <p> If the track's creation mode is {@link #MODE_STREAM},
* it is greater than or equal to the specified bufferSizeInBytes converted to frame units.
* For streaming tracks, this value may be rounded up to a larger value if needed by
* the target output sink, and
* if the track is subsequently routed to a different output sink, the native
* frame count may enlarge to accommodate.
* <p> If the <code>AudioTrack</code> encoding indicates compressed data,
* e.g. {@link AudioFormat#ENCODING_AC3}, then the frame count returned is
* the size of the native <code>AudioTrack</code> buffer in bytes.
* <p> See also {@link AudioManager#getProperty(String)} for key
* {@link AudioManager#PROPERTY_OUTPUT_FRAMES_PER_BUFFER}.
* @return current size in frames of the <code>AudioTrack</code> buffer.
* @throws IllegalStateException
*/
public int getBufferSizeInFrames() {
return native_get_native_frame_count();
}
/**
* Returns the frame count of the native <code>AudioTrack</code> buffer.
* @return current size in frames of the <code>AudioTrack</code> buffer.
* @throws IllegalStateException
* @deprecated Use the identical public method {@link #getBufferSizeInFrames()} instead.
*/
@Deprecated
protected int getNativeFrameCount() {
return native_get_native_frame_count();
}
/**
* Returns marker position expressed in frames.
* @return marker position in wrapping frame units similar to {@link #getPlaybackHeadPosition},
* or zero if marker is disabled.
*/
public int getNotificationMarkerPosition() {
return native_get_marker_pos();
}
/**
* Returns the notification update period expressed in frames.
* Zero means that no position update notifications are being delivered.
*/
public int getPositionNotificationPeriod() {
return native_get_pos_update_period();
}
/**
* Returns the playback head position expressed in frames.
* Though the "int" type is signed 32-bits, the value should be reinterpreted as if it is
* unsigned 32-bits. That is, the next position after 0x7FFFFFFF is (int) 0x80000000.
* This is a continuously advancing counter. It will wrap (overflow) periodically,
* for example approximately once every 27:03:11 hours:minutes:seconds at 44.1 kHz.
* It is reset to zero by {@link #flush()}, {@link #reloadStaticData()}, and {@link #stop()}.
* If the track's creation mode is {@link #MODE_STATIC}, the return value indicates
* the total number of frames played since reset,
* <i>not</i> the current offset within the buffer.
*/
public int getPlaybackHeadPosition() {
return native_get_position();
}
/**
* Returns this track's estimated latency in milliseconds. This includes the latency due
* to AudioTrack buffer size, AudioMixer (if any) and audio hardware driver.
*
* DO NOT UNHIDE. The existing approach for doing A/V sync has too many problems. We need
* a better solution.
* @hide
*/
public int getLatency() {
return native_get_latency();
}
/**
* Returns the output sample rate in Hz for the specified stream type.
*/
static public int getNativeOutputSampleRate(int streamType) {
return native_get_output_sample_rate(streamType);
}
/**
* Returns the minimum buffer size required for the successful creation of an AudioTrack
* object to be created in the {@link #MODE_STREAM} mode. Note that this size doesn't
* guarantee a smooth playback under load, and higher values should be chosen according to
* the expected frequency at which the buffer will be refilled with additional data to play.
* For example, if you intend to dynamically set the source sample rate of an AudioTrack
* to a higher value than the initial source sample rate, be sure to configure the buffer size
* based on the highest planned sample rate.
* @param sampleRateInHz the source sample rate expressed in Hz.
* @param channelConfig describes the configuration of the audio channels.
* See {@link AudioFormat#CHANNEL_OUT_MONO} and
* {@link AudioFormat#CHANNEL_OUT_STEREO}
* @param audioFormat the format in which the audio data is represented.
* See {@link AudioFormat#ENCODING_PCM_16BIT} and
* {@link AudioFormat#ENCODING_PCM_8BIT},
* and {@link AudioFormat#ENCODING_PCM_FLOAT}.
* @return {@link #ERROR_BAD_VALUE} if an invalid parameter was passed,
* or {@link #ERROR} if unable to query for output properties,
* or the minimum buffer size expressed in bytes.
*/
static public int getMinBufferSize(int sampleRateInHz, int channelConfig, int audioFormat) {
int channelCount = 0;
switch(channelConfig) {
case AudioFormat.CHANNEL_OUT_MONO:
case AudioFormat.CHANNEL_CONFIGURATION_MONO:
channelCount = 1;
break;
case AudioFormat.CHANNEL_OUT_STEREO:
case AudioFormat.CHANNEL_CONFIGURATION_STEREO:
channelCount = 2;
break;
default:
if (!isMultichannelConfigSupported(channelConfig)) {
loge("getMinBufferSize(): Invalid channel configuration.");
return ERROR_BAD_VALUE;
} else {
channelCount = AudioFormat.channelCountFromOutChannelMask(channelConfig);
}
}
if (!AudioFormat.isPublicEncoding(audioFormat)) {
loge("getMinBufferSize(): Invalid audio format.");
return ERROR_BAD_VALUE;
}
// sample rate, note these values are subject to change
if ( (sampleRateInHz < SAMPLE_RATE_HZ_MIN) || (sampleRateInHz > SAMPLE_RATE_HZ_MAX) ) {
loge("getMinBufferSize(): " + sampleRateInHz + " Hz is not a supported sample rate.");
return ERROR_BAD_VALUE;
}
int size = native_get_min_buff_size(sampleRateInHz, channelCount, audioFormat);
if (size <= 0) {
loge("getMinBufferSize(): error querying hardware");
return ERROR;
}
else {
return size;
}
}
/**
* Returns the audio session ID.
*
* @return the ID of the audio session this AudioTrack belongs to.
*/
public int getAudioSessionId() {
return mSessionId;
}
/**
* Poll for a timestamp on demand.
* <p>
* If you need to track timestamps during initial warmup or after a routing or mode change,
* you should request a new timestamp periodically until the reported timestamps
* show that the frame position is advancing, or until it becomes clear that
* timestamps are unavailable for this route.
* <p>
* After the clock is advancing at a stable rate,
* query for a new timestamp approximately once every 10 seconds to once per minute.
* Calling this method more often is inefficient.
* It is also counter-productive to call this method more often than recommended,
* because the short-term differences between successive timestamp reports are not meaningful.
* If you need a high-resolution mapping between frame position and presentation time,
* consider implementing that at application level, based on low-resolution timestamps.
* <p>
* The audio data at the returned position may either already have been
* presented, or may have not yet been presented but is committed to be presented.
* It is not possible to request the time corresponding to a particular position,
* or to request the (fractional) position corresponding to a particular time.
* If you need such features, consider implementing them at application level.
*
* @param timestamp a reference to a non-null AudioTimestamp instance allocated
* and owned by caller.
* @return true if a timestamp is available, or false if no timestamp is available.
* If a timestamp if available,
* the AudioTimestamp instance is filled in with a position in frame units, together
* with the estimated time when that frame was presented or is committed to
* be presented.
* In the case that no timestamp is available, any supplied instance is left unaltered.
* A timestamp may be temporarily unavailable while the audio clock is stabilizing,
* or during and immediately after a route change.
* A timestamp is permanently unavailable for a given route if the route does not support
* timestamps. In this case, the approximate frame position can be obtained
* using {@link #getPlaybackHeadPosition}.
* However, it may be useful to continue to query for
* timestamps occasionally, to recover after a route change.
*/
// Add this text when the "on new timestamp" API is added:
// Use if you need to get the most recent timestamp outside of the event callback handler.
public boolean getTimestamp(AudioTimestamp timestamp)
{
if (timestamp == null) {
throw new IllegalArgumentException();
}
// It's unfortunate, but we have to either create garbage every time or use synchronized
long[] longArray = new long[2];
int ret = native_get_timestamp(longArray);
if (ret != SUCCESS) {
return false;
}
timestamp.framePosition = longArray[0];
timestamp.nanoTime = longArray[1];
return true;
}
/**
* Poll for a timestamp on demand.
* <p>
* Same as {@link #getTimestamp(AudioTimestamp)} but with a more useful return code.
*
* @param timestamp a reference to a non-null AudioTimestamp instance allocated
* and owned by caller.
* @return {@link #SUCCESS} if a timestamp is available
* {@link #ERROR_WOULD_BLOCK} if called in STOPPED or FLUSHED state, or if called
* immediately after start/ACTIVE, when the number of frames consumed is less than the
* overall hardware latency to physical output. In WOULD_BLOCK cases, one might poll
* again, or use {@link #getPlaybackHeadPosition}, or use 0 position and current time
* for the timestamp.
* {@link #ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* {@link #ERROR_INVALID_OPERATION} if current route does not support
* timestamps. In this case, the approximate frame position can be obtained
* using {@link #getPlaybackHeadPosition}.
*
* The AudioTimestamp instance is filled in with a position in frame units, together
* with the estimated time when that frame was presented or is committed to
* be presented.
* @hide
*/
// Add this text when the "on new timestamp" API is added:
// Use if you need to get the most recent timestamp outside of the event callback handler.
public int getTimestampWithStatus(AudioTimestamp timestamp)
{
if (timestamp == null) {
throw new IllegalArgumentException();
}
// It's unfortunate, but we have to either create garbage every time or use synchronized
long[] longArray = new long[2];
int ret = native_get_timestamp(longArray);
timestamp.framePosition = longArray[0];
timestamp.nanoTime = longArray[1];
return ret;
}
//--------------------------------------------------------------------------
// Initialization / configuration
//--------------------
/**
* Sets the listener the AudioTrack notifies when a previously set marker is reached or
* for each periodic playback head position update.
* Notifications will be received in the same thread as the one in which the AudioTrack
* instance was created.
* @param listener
*/
public void setPlaybackPositionUpdateListener(OnPlaybackPositionUpdateListener listener) {
setPlaybackPositionUpdateListener(listener, null);
}
/**
* Sets the listener the AudioTrack notifies when a previously set marker is reached or
* for each periodic playback head position update.
* Use this method to receive AudioTrack events in the Handler associated with another
* thread than the one in which you created the AudioTrack instance.
* @param listener
* @param handler the Handler that will receive the event notification messages.
*/
public void setPlaybackPositionUpdateListener(OnPlaybackPositionUpdateListener listener,
Handler handler) {
if (listener != null) {
mEventHandlerDelegate = new NativePositionEventHandlerDelegate(this, listener, handler);
} else {
mEventHandlerDelegate = null;
}
}
private static float clampGainOrLevel(float gainOrLevel) {
if (Float.isNaN(gainOrLevel)) {
throw new IllegalArgumentException();
}
if (gainOrLevel < GAIN_MIN) {
gainOrLevel = GAIN_MIN;
} else if (gainOrLevel > GAIN_MAX) {
gainOrLevel = GAIN_MAX;
}
return gainOrLevel;
}
/**
* Sets the specified left and right output gain values on the AudioTrack.
* <p>Gain values are clamped to the closed interval [0.0, max] where
* max is the value of {@link #getMaxVolume}.
* A value of 0.0 results in zero gain (silence), and
* a value of 1.0 means unity gain (signal unchanged).
* The default value is 1.0 meaning unity gain.
* <p>The word "volume" in the API name is historical; this is actually a linear gain.
* @param leftGain output gain for the left channel.
* @param rightGain output gain for the right channel
* @return error code or success, see {@link #SUCCESS},
* {@link #ERROR_INVALID_OPERATION}
* @deprecated Applications should use {@link #setVolume} instead, as it
* more gracefully scales down to mono, and up to multi-channel content beyond stereo.
*/
public int setStereoVolume(float leftGain, float rightGain) {
if (isRestricted()) {
return SUCCESS;
}
if (mState == STATE_UNINITIALIZED) {
return ERROR_INVALID_OPERATION;
}
leftGain = clampGainOrLevel(leftGain);
rightGain = clampGainOrLevel(rightGain);
native_setVolume(leftGain, rightGain);
return SUCCESS;
}
/**
* Sets the specified output gain value on all channels of this track.
* <p>Gain values are clamped to the closed interval [0.0, max] where
* max is the value of {@link #getMaxVolume}.
* A value of 0.0 results in zero gain (silence), and
* a value of 1.0 means unity gain (signal unchanged).
* The default value is 1.0 meaning unity gain.
* <p>This API is preferred over {@link #setStereoVolume}, as it
* more gracefully scales down to mono, and up to multi-channel content beyond stereo.
* <p>The word "volume" in the API name is historical; this is actually a linear gain.
* @param gain output gain for all channels.
* @return error code or success, see {@link #SUCCESS},
* {@link #ERROR_INVALID_OPERATION}
*/
public int setVolume(float gain) {
return setStereoVolume(gain, gain);
}
/**
* Sets the playback sample rate for this track. This sets the sampling rate at which
* the audio data will be consumed and played back
* (as set by the sampleRateInHz parameter in the
* {@link #AudioTrack(int, int, int, int, int, int)} constructor),
* not the original sampling rate of the
* content. For example, setting it to half the sample rate of the content will cause the
* playback to last twice as long, but will also result in a pitch shift down by one octave.
* The valid sample rate range is from 1 Hz to twice the value returned by
* {@link #getNativeOutputSampleRate(int)}.
* Use {@link #setPlaybackParams(PlaybackParams)} for speed control.
* <p> This method may also be used to repurpose an existing <code>AudioTrack</code>
* for playback of content of differing sample rate,
* but with identical encoding and channel mask.
* @param sampleRateInHz the sample rate expressed in Hz
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_BAD_VALUE},
* {@link #ERROR_INVALID_OPERATION}
*/
public int setPlaybackRate(int sampleRateInHz) {
if (mState != STATE_INITIALIZED) {
return ERROR_INVALID_OPERATION;
}
if (sampleRateInHz <= 0) {
return ERROR_BAD_VALUE;
}
return native_set_playback_rate(sampleRateInHz);
}
/**
* Sets the playback parameters.
* This method returns failure if it cannot apply the playback parameters.
* One possible cause is that the parameters for speed or pitch are out of range.
* Another possible cause is that the <code>AudioTrack</code> is streaming
* (see {@link #MODE_STREAM}) and the
* buffer size is too small. For speeds greater than 1.0f, the <code>AudioTrack</code> buffer
* on configuration must be larger than the speed multiplied by the minimum size
* {@link #getMinBufferSize(int, int, int)}) to allow proper playback.
* @param params see {@link PlaybackParams}. In particular,
* speed, pitch, and audio mode should be set.
* @throws IllegalArgumentException if the parameters are invalid or not accepted.
* @throws IllegalStateException if track is not initialized.
*/
public void setPlaybackParams(@NonNull PlaybackParams params) {
if (params == null) {
throw new IllegalArgumentException("params is null");
}
native_set_playback_params(params);
}
/**
* Sets the position of the notification marker. At most one marker can be active.
* @param markerInFrames marker position in wrapping frame units similar to
* {@link #getPlaybackHeadPosition}, or zero to disable the marker.
* To set a marker at a position which would appear as zero due to wraparound,
* a workaround is to use a non-zero position near zero, such as -1 or 1.
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_BAD_VALUE},
* {@link #ERROR_INVALID_OPERATION}
*/
public int setNotificationMarkerPosition(int markerInFrames) {
if (mState == STATE_UNINITIALIZED) {
return ERROR_INVALID_OPERATION;
}
return native_set_marker_pos(markerInFrames);
}
/**
* Sets the period for the periodic notification event.
* @param periodInFrames update period expressed in frames.
* Zero period means no position updates. A negative period is not allowed.
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_INVALID_OPERATION}
*/
public int setPositionNotificationPeriod(int periodInFrames) {
if (mState == STATE_UNINITIALIZED) {
return ERROR_INVALID_OPERATION;
}
return native_set_pos_update_period(periodInFrames);
}
/**
* Sets the playback head position within the static buffer.
* The track must be stopped or paused for the position to be changed,
* and must use the {@link #MODE_STATIC} mode.
* @param positionInFrames playback head position within buffer, expressed in frames.
* Zero corresponds to start of buffer.
* The position must not be greater than the buffer size in frames, or negative.
* Though this method and {@link #getPlaybackHeadPosition()} have similar names,
* the position values have different meanings.
* <br>
* If looping is currently enabled and the new position is greater than or equal to the
* loop end marker, the behavior varies by API level:
* as of {@link android.os.Build.VERSION_CODES#M},
* the looping is first disabled and then the position is set.
* For earlier API levels, the behavior is unspecified.
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_BAD_VALUE},
* {@link #ERROR_INVALID_OPERATION}
*/
public int setPlaybackHeadPosition(int positionInFrames) {
if (mDataLoadMode == MODE_STREAM || mState == STATE_UNINITIALIZED ||
getPlayState() == PLAYSTATE_PLAYING) {
return ERROR_INVALID_OPERATION;
}
if (!(0 <= positionInFrames && positionInFrames <= mNativeBufferSizeInFrames)) {
return ERROR_BAD_VALUE;
}
return native_set_position(positionInFrames);
}
/**
* Sets the loop points and the loop count. The loop can be infinite.
* Similarly to setPlaybackHeadPosition,
* the track must be stopped or paused for the loop points to be changed,
* and must use the {@link #MODE_STATIC} mode.
* @param startInFrames loop start marker expressed in frames.
* Zero corresponds to start of buffer.
* The start marker must not be greater than or equal to the buffer size in frames, or negative.
* @param endInFrames loop end marker expressed in frames.
* The total buffer size in frames corresponds to end of buffer.
* The end marker must not be greater than the buffer size in frames.
* For looping, the end marker must not be less than or equal to the start marker,
* but to disable looping
* it is permitted for start marker, end marker, and loop count to all be 0.
* If any input parameters are out of range, this method returns {@link #ERROR_BAD_VALUE}.
* If the loop period (endInFrames - startInFrames) is too small for the implementation to
* support,
* {@link #ERROR_BAD_VALUE} is returned.
* The loop range is the interval [startInFrames, endInFrames).
* <br>
* As of {@link android.os.Build.VERSION_CODES#M}, the position is left unchanged,
* unless it is greater than or equal to the loop end marker, in which case
* it is forced to the loop start marker.
* For earlier API levels, the effect on position is unspecified.
* @param loopCount the number of times the loop is looped; must be greater than or equal to -1.
* A value of -1 means infinite looping, and 0 disables looping.
* A value of positive N means to "loop" (go back) N times. For example,
* a value of one means to play the region two times in total.
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_BAD_VALUE},
* {@link #ERROR_INVALID_OPERATION}
*/
public int setLoopPoints(int startInFrames, int endInFrames, int loopCount) {
if (mDataLoadMode == MODE_STREAM || mState == STATE_UNINITIALIZED ||
getPlayState() == PLAYSTATE_PLAYING) {
return ERROR_INVALID_OPERATION;
}
if (loopCount == 0) {
; // explicitly allowed as an exception to the loop region range check
} else if (!(0 <= startInFrames && startInFrames < mNativeBufferSizeInFrames &&
startInFrames < endInFrames && endInFrames <= mNativeBufferSizeInFrames)) {
return ERROR_BAD_VALUE;
}
return native_set_loop(startInFrames, endInFrames, loopCount);
}
/**
* Sets the initialization state of the instance. This method was originally intended to be used
* in an AudioTrack subclass constructor to set a subclass-specific post-initialization state.
* However, subclasses of AudioTrack are no longer recommended, so this method is obsolete.
* @param state the state of the AudioTrack instance
* @deprecated Only accessible by subclasses, which are not recommended for AudioTrack.
*/
@Deprecated
protected void setState(int state) {
mState = state;
}
//---------------------------------------------------------
// Transport control methods
//--------------------
/**
* Starts playing an AudioTrack.
* <p>
* If track's creation mode is {@link #MODE_STATIC}, you must have called one of
* the write methods ({@link #write(byte[], int, int)}, {@link #write(byte[], int, int, int)},
* {@link #write(short[], int, int)}, {@link #write(short[], int, int, int)},
* {@link #write(float[], int, int, int)}, or {@link #write(ByteBuffer, int, int)}) prior to
* play().
* <p>
* If the mode is {@link #MODE_STREAM}, you can optionally prime the data path prior to
* calling play(), by writing up to <code>bufferSizeInBytes</code> (from constructor).
* If you don't call write() first, or if you call write() but with an insufficient amount of
* data, then the track will be in underrun state at play(). In this case,
* playback will not actually start playing until the data path is filled to a
* device-specific minimum level. This requirement for the path to be filled
* to a minimum level is also true when resuming audio playback after calling stop().
* Similarly the buffer will need to be filled up again after
* the track underruns due to failure to call write() in a timely manner with sufficient data.
* For portability, an application should prime the data path to the maximum allowed
* by writing data until the write() method returns a short transfer count.
* This allows play() to start immediately, and reduces the chance of underrun.
*
* @throws IllegalStateException if the track isn't properly initialized
*/
public void play()
throws IllegalStateException {
if (mState != STATE_INITIALIZED) {
throw new IllegalStateException("play() called on uninitialized AudioTrack.");
}
if (isRestricted()) {
setVolume(0);
}
synchronized(mPlayStateLock) {
native_start();
mPlayState = PLAYSTATE_PLAYING;
}
}
private boolean isRestricted() {
if ((mAttributes.getAllFlags() & AudioAttributes.FLAG_BYPASS_INTERRUPTION_POLICY) != 0) {
return false;
}
try {
final int usage = AudioAttributes.usageForLegacyStreamType(mStreamType);
final int mode = mAppOps.checkAudioOperation(AppOpsManager.OP_PLAY_AUDIO, usage,
Process.myUid(), ActivityThread.currentPackageName());
return mode != AppOpsManager.MODE_ALLOWED;
} catch (RemoteException e) {
return false;
}
}
/**
* Stops playing the audio data.
* When used on an instance created in {@link #MODE_STREAM} mode, audio will stop playing
* after the last buffer that was written has been played. For an immediate stop, use
* {@link #pause()}, followed by {@link #flush()} to discard audio data that hasn't been played
* back yet.
* @throws IllegalStateException
*/
public void stop()
throws IllegalStateException {
if (mState != STATE_INITIALIZED) {
throw new IllegalStateException("stop() called on uninitialized AudioTrack.");
}
// stop playing
synchronized(mPlayStateLock) {
native_stop();
mPlayState = PLAYSTATE_STOPPED;
mAvSyncHeader = null;
mAvSyncBytesRemaining = 0;
}
}
/**
* Pauses the playback of the audio data. Data that has not been played
* back will not be discarded. Subsequent calls to {@link #play} will play
* this data back. See {@link #flush()} to discard this data.
*
* @throws IllegalStateException
*/
public void pause()
throws IllegalStateException {
if (mState != STATE_INITIALIZED) {
throw new IllegalStateException("pause() called on uninitialized AudioTrack.");
}
//logd("pause()");
// pause playback
synchronized(mPlayStateLock) {
native_pause();
mPlayState = PLAYSTATE_PAUSED;
}
}
//---------------------------------------------------------
// Audio data supply
//--------------------
/**
* Flushes the audio data currently queued for playback. Any data that has
* been written but not yet presented will be discarded. No-op if not stopped or paused,
* or if the track's creation mode is not {@link #MODE_STREAM}.
* <BR> Note that although data written but not yet presented is discarded, there is no
* guarantee that all of the buffer space formerly used by that data
* is available for a subsequent write.
* For example, a call to {@link #write(byte[], int, int)} with <code>sizeInBytes</code>
* less than or equal to the total buffer size
* may return a short actual transfer count.
*/
public void flush() {
if (mState == STATE_INITIALIZED) {
// flush the data in native layer
native_flush();
mAvSyncHeader = null;
mAvSyncBytesRemaining = 0;
}
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The format specified in the AudioTrack constructor should be
* {@link AudioFormat#ENCODING_PCM_8BIT} to correspond to the data in the array.
* <p>
* In streaming mode, the write will normally block until all the data has been enqueued for
* playback, and will return a full transfer count. However, if the track is stopped or paused
* on entry, or another thread interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the array that holds the data to play.
* @param offsetInBytes the offset expressed in bytes in audioData where the data to play
* starts.
* @param sizeInBytes the number of bytes to read in audioData after the offset.
* @return zero or the positive number of bytes that were written, or
* {@link #ERROR_INVALID_OPERATION}
* if the track isn't properly initialized, or {@link #ERROR_BAD_VALUE} if
* the parameters don't resolve to valid data and indexes, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*
* This is equivalent to {@link #write(byte[], int, int, int)} with <code>writeMode</code>
* set to {@link #WRITE_BLOCKING}.
*/
public int write(@NonNull byte[] audioData, int offsetInBytes, int sizeInBytes) {
return write(audioData, offsetInBytes, sizeInBytes, WRITE_BLOCKING);
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The format specified in the AudioTrack constructor should be
* {@link AudioFormat#ENCODING_PCM_8BIT} to correspond to the data in the array.
* <p>
* In streaming mode, the blocking behavior depends on the write mode. If the write mode is
* {@link #WRITE_BLOCKING}, the write will normally block until all the data has been enqueued
* for playback, and will return a full transfer count. However, if the write mode is
* {@link #WRITE_NON_BLOCKING}, or the track is stopped or paused on entry, or another thread
* interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0,
* and the write mode is ignored.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the array that holds the data to play.
* @param offsetInBytes the offset expressed in bytes in audioData where the data to play
* starts.
* @param sizeInBytes the number of bytes to read in audioData after the offset.
* @param writeMode one of {@link #WRITE_BLOCKING}, {@link #WRITE_NON_BLOCKING}. It has no
* effect in static mode.
* <br>With {@link #WRITE_BLOCKING}, the write will block until all data has been written
* to the audio sink.
* <br>With {@link #WRITE_NON_BLOCKING}, the write will return immediately after
* queuing as much audio data for playback as possible without blocking.
* @return zero or the positive number of bytes that were written, or
* {@link #ERROR_INVALID_OPERATION}
* if the track isn't properly initialized, or {@link #ERROR_BAD_VALUE} if
* the parameters don't resolve to valid data and indexes, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*/
public int write(@NonNull byte[] audioData, int offsetInBytes, int sizeInBytes,
@WriteMode int writeMode) {
if (mState == STATE_UNINITIALIZED || mAudioFormat == AudioFormat.ENCODING_PCM_FLOAT) {
return ERROR_INVALID_OPERATION;
}
if ((writeMode != WRITE_BLOCKING) && (writeMode != WRITE_NON_BLOCKING)) {
Log.e(TAG, "AudioTrack.write() called with invalid blocking mode");
return ERROR_BAD_VALUE;
}
if ( (audioData == null) || (offsetInBytes < 0 ) || (sizeInBytes < 0)
|| (offsetInBytes + sizeInBytes < 0) // detect integer overflow
|| (offsetInBytes + sizeInBytes > audioData.length)) {
return ERROR_BAD_VALUE;
}
int ret = native_write_byte(audioData, offsetInBytes, sizeInBytes, mAudioFormat,
writeMode == WRITE_BLOCKING);
if ((mDataLoadMode == MODE_STATIC)
&& (mState == STATE_NO_STATIC_DATA)
&& (ret > 0)) {
// benign race with respect to other APIs that read mState
mState = STATE_INITIALIZED;
}
return ret;
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The format specified in the AudioTrack constructor should be
* {@link AudioFormat#ENCODING_PCM_16BIT} to correspond to the data in the array.
* <p>
* In streaming mode, the write will normally block until all the data has been enqueued for
* playback, and will return a full transfer count. However, if the track is stopped or paused
* on entry, or another thread interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the array that holds the data to play.
* @param offsetInShorts the offset expressed in shorts in audioData where the data to play
* starts.
* @param sizeInShorts the number of shorts to read in audioData after the offset.
* @return zero or the positive number of shorts that were written, or
* {@link #ERROR_INVALID_OPERATION}
* if the track isn't properly initialized, or {@link #ERROR_BAD_VALUE} if
* the parameters don't resolve to valid data and indexes, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*
* This is equivalent to {@link #write(short[], int, int, int)} with <code>writeMode</code>
* set to {@link #WRITE_BLOCKING}.
*/
public int write(@NonNull short[] audioData, int offsetInShorts, int sizeInShorts) {
return write(audioData, offsetInShorts, sizeInShorts, WRITE_BLOCKING);
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The format specified in the AudioTrack constructor should be
* {@link AudioFormat#ENCODING_PCM_16BIT} to correspond to the data in the array.
* <p>
* In streaming mode, the blocking behavior depends on the write mode. If the write mode is
* {@link #WRITE_BLOCKING}, the write will normally block until all the data has been enqueued
* for playback, and will return a full transfer count. However, if the write mode is
* {@link #WRITE_NON_BLOCKING}, or the track is stopped or paused on entry, or another thread
* interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the array that holds the data to play.
* @param offsetInShorts the offset expressed in shorts in audioData where the data to play
* starts.
* @param sizeInShorts the number of shorts to read in audioData after the offset.
* @param writeMode one of {@link #WRITE_BLOCKING}, {@link #WRITE_NON_BLOCKING}. It has no
* effect in static mode.
* <br>With {@link #WRITE_BLOCKING}, the write will block until all data has been written
* to the audio sink.
* <br>With {@link #WRITE_NON_BLOCKING}, the write will return immediately after
* queuing as much audio data for playback as possible without blocking.
* @return zero or the positive number of shorts that were written, or
* {@link #ERROR_INVALID_OPERATION}
* if the track isn't properly initialized, or {@link #ERROR_BAD_VALUE} if
* the parameters don't resolve to valid data and indexes, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*/
public int write(@NonNull short[] audioData, int offsetInShorts, int sizeInShorts,
@WriteMode int writeMode) {
if (mState == STATE_UNINITIALIZED || mAudioFormat == AudioFormat.ENCODING_PCM_FLOAT) {
return ERROR_INVALID_OPERATION;
}
if ((writeMode != WRITE_BLOCKING) && (writeMode != WRITE_NON_BLOCKING)) {
Log.e(TAG, "AudioTrack.write() called with invalid blocking mode");
return ERROR_BAD_VALUE;
}
if ( (audioData == null) || (offsetInShorts < 0 ) || (sizeInShorts < 0)
|| (offsetInShorts + sizeInShorts < 0) // detect integer overflow
|| (offsetInShorts + sizeInShorts > audioData.length)) {
return ERROR_BAD_VALUE;
}
int ret = native_write_short(audioData, offsetInShorts, sizeInShorts, mAudioFormat,
writeMode == WRITE_BLOCKING);
if ((mDataLoadMode == MODE_STATIC)
&& (mState == STATE_NO_STATIC_DATA)
&& (ret > 0)) {
// benign race with respect to other APIs that read mState
mState = STATE_INITIALIZED;
}
return ret;
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The format specified in the AudioTrack constructor should be
* {@link AudioFormat#ENCODING_PCM_FLOAT} to correspond to the data in the array.
* <p>
* In streaming mode, the blocking behavior depends on the write mode. If the write mode is
* {@link #WRITE_BLOCKING}, the write will normally block until all the data has been enqueued
* for playback, and will return a full transfer count. However, if the write mode is
* {@link #WRITE_NON_BLOCKING}, or the track is stopped or paused on entry, or another thread
* interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0,
* and the write mode is ignored.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the array that holds the data to play.
* The implementation does not clip for sample values within the nominal range
* [-1.0f, 1.0f], provided that all gains in the audio pipeline are
* less than or equal to unity (1.0f), and in the absence of post-processing effects
* that could add energy, such as reverb. For the convenience of applications
* that compute samples using filters with non-unity gain,
* sample values +3 dB beyond the nominal range are permitted.
* However such values may eventually be limited or clipped, depending on various gains
* and later processing in the audio path. Therefore applications are encouraged
* to provide samples values within the nominal range.
* @param offsetInFloats the offset, expressed as a number of floats,
* in audioData where the data to play starts.
* @param sizeInFloats the number of floats to read in audioData after the offset.
* @param writeMode one of {@link #WRITE_BLOCKING}, {@link #WRITE_NON_BLOCKING}. It has no
* effect in static mode.
* <br>With {@link #WRITE_BLOCKING}, the write will block until all data has been written
* to the audio sink.
* <br>With {@link #WRITE_NON_BLOCKING}, the write will return immediately after
* queuing as much audio data for playback as possible without blocking.
* @return zero or the positive number of floats that were written, or
* {@link #ERROR_INVALID_OPERATION}
* if the track isn't properly initialized, or {@link #ERROR_BAD_VALUE} if
* the parameters don't resolve to valid data and indexes, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*/
public int write(@NonNull float[] audioData, int offsetInFloats, int sizeInFloats,
@WriteMode int writeMode) {
if (mState == STATE_UNINITIALIZED) {
Log.e(TAG, "AudioTrack.write() called in invalid state STATE_UNINITIALIZED");
return ERROR_INVALID_OPERATION;
}
if (mAudioFormat != AudioFormat.ENCODING_PCM_FLOAT) {
Log.e(TAG, "AudioTrack.write(float[] ...) requires format ENCODING_PCM_FLOAT");
return ERROR_INVALID_OPERATION;
}
if ((writeMode != WRITE_BLOCKING) && (writeMode != WRITE_NON_BLOCKING)) {
Log.e(TAG, "AudioTrack.write() called with invalid blocking mode");
return ERROR_BAD_VALUE;
}
if ( (audioData == null) || (offsetInFloats < 0 ) || (sizeInFloats < 0)
|| (offsetInFloats + sizeInFloats < 0) // detect integer overflow
|| (offsetInFloats + sizeInFloats > audioData.length)) {
Log.e(TAG, "AudioTrack.write() called with invalid array, offset, or size");
return ERROR_BAD_VALUE;
}
int ret = native_write_float(audioData, offsetInFloats, sizeInFloats, mAudioFormat,
writeMode == WRITE_BLOCKING);
if ((mDataLoadMode == MODE_STATIC)
&& (mState == STATE_NO_STATIC_DATA)
&& (ret > 0)) {
// benign race with respect to other APIs that read mState
mState = STATE_INITIALIZED;
}
return ret;
}
/**
* Writes the audio data to the audio sink for playback (streaming mode),
* or copies audio data for later playback (static buffer mode).
* The audioData in ByteBuffer should match the format specified in the AudioTrack constructor.
* <p>
* In streaming mode, the blocking behavior depends on the write mode. If the write mode is
* {@link #WRITE_BLOCKING}, the write will normally block until all the data has been enqueued
* for playback, and will return a full transfer count. However, if the write mode is
* {@link #WRITE_NON_BLOCKING}, or the track is stopped or paused on entry, or another thread
* interrupts the write by calling stop or pause, or an I/O error
* occurs during the write, then the write may return a short transfer count.
* <p>
* In static buffer mode, copies the data to the buffer starting at offset 0,
* and the write mode is ignored.
* Note that the actual playback of this data might occur after this function returns.
*
* @param audioData the buffer that holds the data to play, starting at the position reported
* by <code>audioData.position()</code>.
* <BR>Note that upon return, the buffer position (<code>audioData.position()</code>) will
* have been advanced to reflect the amount of data that was successfully written to
* the AudioTrack.
* @param sizeInBytes number of bytes to write.
* <BR>Note this may differ from <code>audioData.remaining()</code>, but cannot exceed it.
* @param writeMode one of {@link #WRITE_BLOCKING}, {@link #WRITE_NON_BLOCKING}. It has no
* effect in static mode.
* <BR>With {@link #WRITE_BLOCKING}, the write will block until all data has been written
* to the audio sink.
* <BR>With {@link #WRITE_NON_BLOCKING}, the write will return immediately after
* queuing as much audio data for playback as possible without blocking.
* @return zero or the positive number of bytes that were written, or
* {@link #ERROR_BAD_VALUE}, {@link #ERROR_INVALID_OPERATION}, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*/
public int write(@NonNull ByteBuffer audioData, int sizeInBytes,
@WriteMode int writeMode) {
if (mState == STATE_UNINITIALIZED) {
Log.e(TAG, "AudioTrack.write() called in invalid state STATE_UNINITIALIZED");
return ERROR_INVALID_OPERATION;
}
if ((writeMode != WRITE_BLOCKING) && (writeMode != WRITE_NON_BLOCKING)) {
Log.e(TAG, "AudioTrack.write() called with invalid blocking mode");
return ERROR_BAD_VALUE;
}
if ( (audioData == null) || (sizeInBytes < 0) || (sizeInBytes > audioData.remaining())) {
Log.e(TAG, "AudioTrack.write() called with invalid size (" + sizeInBytes + ") value");
return ERROR_BAD_VALUE;
}
int ret = 0;
if (audioData.isDirect()) {
ret = native_write_native_bytes(audioData,
audioData.position(), sizeInBytes, mAudioFormat,
writeMode == WRITE_BLOCKING);
} else {
ret = native_write_byte(NioUtils.unsafeArray(audioData),
NioUtils.unsafeArrayOffset(audioData) + audioData.position(),
sizeInBytes, mAudioFormat,
writeMode == WRITE_BLOCKING);
}
if ((mDataLoadMode == MODE_STATIC)
&& (mState == STATE_NO_STATIC_DATA)
&& (ret > 0)) {
// benign race with respect to other APIs that read mState
mState = STATE_INITIALIZED;
}
if (ret > 0) {
audioData.position(audioData.position() + ret);
}
return ret;
}
/**
* Writes the audio data to the audio sink for playback in streaming mode on a HW_AV_SYNC track.
* The blocking behavior will depend on the write mode.
* @param audioData the buffer that holds the data to play, starting at the position reported
* by <code>audioData.position()</code>.
* <BR>Note that upon return, the buffer position (<code>audioData.position()</code>) will
* have been advanced to reflect the amount of data that was successfully written to
* the AudioTrack.
* @param sizeInBytes number of bytes to write.
* <BR>Note this may differ from <code>audioData.remaining()</code>, but cannot exceed it.
* @param writeMode one of {@link #WRITE_BLOCKING}, {@link #WRITE_NON_BLOCKING}.
* <BR>With {@link #WRITE_BLOCKING}, the write will block until all data has been written
* to the audio sink.
* <BR>With {@link #WRITE_NON_BLOCKING}, the write will return immediately after
* queuing as much audio data for playback as possible without blocking.
* @param timestamp The timestamp of the first decodable audio frame in the provided audioData.
* @return zero or a positive number of bytes that were written, or
* {@link #ERROR_BAD_VALUE}, {@link #ERROR_INVALID_OPERATION}, or
* {@link AudioManager#ERROR_DEAD_OBJECT} if the AudioTrack is not valid anymore and
* needs to be recreated.
* The dead object error code is not returned if some data was successfully transferred.
* In this case, the error is returned at the next write().
*/
public int write(@NonNull ByteBuffer audioData, int sizeInBytes,
@WriteMode int writeMode, long timestamp) {
if (mState == STATE_UNINITIALIZED) {
Log.e(TAG, "AudioTrack.write() called in invalid state STATE_UNINITIALIZED");
return ERROR_INVALID_OPERATION;
}
if ((writeMode != WRITE_BLOCKING) && (writeMode != WRITE_NON_BLOCKING)) {
Log.e(TAG, "AudioTrack.write() called with invalid blocking mode");
return ERROR_BAD_VALUE;
}
if (mDataLoadMode != MODE_STREAM) {
Log.e(TAG, "AudioTrack.write() with timestamp called for non-streaming mode track");
return ERROR_INVALID_OPERATION;
}
if ((mAttributes.getFlags() & AudioAttributes.FLAG_HW_AV_SYNC) == 0) {
Log.d(TAG, "AudioTrack.write() called on a regular AudioTrack. Ignoring pts...");
return write(audioData, sizeInBytes, writeMode);
}
if ((audioData == null) || (sizeInBytes < 0) || (sizeInBytes > audioData.remaining())) {
Log.e(TAG, "AudioTrack.write() called with invalid size (" + sizeInBytes + ") value");
return ERROR_BAD_VALUE;
}
// create timestamp header if none exists
if (mAvSyncHeader == null) {
mAvSyncHeader = ByteBuffer.allocate(16);
mAvSyncHeader.order(ByteOrder.BIG_ENDIAN);
mAvSyncHeader.putInt(0x55550001);
mAvSyncHeader.putInt(sizeInBytes);
mAvSyncHeader.putLong(timestamp);
mAvSyncHeader.position(0);
mAvSyncBytesRemaining = sizeInBytes;
}
// write timestamp header if not completely written already
int ret = 0;
if (mAvSyncHeader.remaining() != 0) {
ret = write(mAvSyncHeader, mAvSyncHeader.remaining(), writeMode);
if (ret < 0) {
Log.e(TAG, "AudioTrack.write() could not write timestamp header!");
mAvSyncHeader = null;
mAvSyncBytesRemaining = 0;
return ret;
}
if (mAvSyncHeader.remaining() > 0) {
Log.v(TAG, "AudioTrack.write() partial timestamp header written.");
return 0;
}
}
// write audio data
int sizeToWrite = Math.min(mAvSyncBytesRemaining, sizeInBytes);
ret = write(audioData, sizeToWrite, writeMode);
if (ret < 0) {
Log.e(TAG, "AudioTrack.write() could not write audio data!");
mAvSyncHeader = null;
mAvSyncBytesRemaining = 0;
return ret;
}
mAvSyncBytesRemaining -= ret;
if (mAvSyncBytesRemaining == 0) {
mAvSyncHeader = null;
}
return ret;
}
/**
* Sets the playback head position within the static buffer to zero,
* that is it rewinds to start of static buffer.
* The track must be stopped or paused, and
* the track's creation mode must be {@link #MODE_STATIC}.
* <p>
* As of {@link android.os.Build.VERSION_CODES#M}, also resets the value returned by
* {@link #getPlaybackHeadPosition()} to zero.
* For earlier API levels, the reset behavior is unspecified.
* <p>
* Use {@link #setPlaybackHeadPosition(int)} with a zero position
* if the reset of <code>getPlaybackHeadPosition()</code> is not needed.
* @return error code or success, see {@link #SUCCESS}, {@link #ERROR_BAD_VALUE},
* {@link #ERROR_INVALID_OPERATION}
*/
public int reloadStaticData() {
if (mDataLoadMode == MODE_STREAM || mState != STATE_INITIALIZED) {
return ERROR_INVALID_OPERATION;
}
return native_reload_static();
}
//--------------------------------------------------------------------------
// Audio effects management
//--------------------
/**
* Attaches an auxiliary effect to the audio track. A typical auxiliary
* effect is a reverberation effect which can be applied on any sound source
* that directs a certain amount of its energy to this effect. This amount
* is defined by setAuxEffectSendLevel().
* {@see #setAuxEffectSendLevel(float)}.
* <p>After creating an auxiliary effect (e.g.
* {@link android.media.audiofx.EnvironmentalReverb}), retrieve its ID with
* {@link android.media.audiofx.AudioEffect#getId()} and use it when calling
* this method to attach the audio track to the effect.
* <p>To detach the effect from the audio track, call this method with a
* null effect id.
*
* @param effectId system wide unique id of the effect to attach
* @return error code or success, see {@link #SUCCESS},
* {@link #ERROR_INVALID_OPERATION}, {@link #ERROR_BAD_VALUE}
*/
public int attachAuxEffect(int effectId) {
if (mState == STATE_UNINITIALIZED) {
return ERROR_INVALID_OPERATION;
}
return native_attachAuxEffect(effectId);
}
/**
* Sets the send level of the audio track to the attached auxiliary effect
* {@link #attachAuxEffect(int)}. Effect levels
* are clamped to the closed interval [0.0, max] where
* max is the value of {@link #getMaxVolume}.
* A value of 0.0 results in no effect, and a value of 1.0 is full send.
* <p>By default the send level is 0.0f, so even if an effect is attached to the player
* this method must be called for the effect to be applied.
* <p>Note that the passed level value is a linear scalar. UI controls should be scaled
* logarithmically: the gain applied by audio framework ranges from -72dB to at least 0dB,
* so an appropriate conversion from linear UI input x to level is:
* x == 0 -&gt; level = 0
* 0 &lt; x &lt;= R -&gt; level = 10^(72*(x-R)/20/R)
*
* @param level linear send level
* @return error code or success, see {@link #SUCCESS},
* {@link #ERROR_INVALID_OPERATION}, {@link #ERROR}
*/
public int setAuxEffectSendLevel(float level) {
if (isRestricted()) {
return SUCCESS;
}
if (mState == STATE_UNINITIALIZED) {
return ERROR_INVALID_OPERATION;
}
level = clampGainOrLevel(level);
int err = native_setAuxEffectSendLevel(level);
return err == 0 ? SUCCESS : ERROR;
}
//--------------------------------------------------------------------------
// Explicit Routing
//--------------------
private AudioDeviceInfo mPreferredDevice = null;
/**
* Specifies an audio device (via an {@link AudioDeviceInfo} object) to route
* the output from this AudioTrack.
* @param deviceInfo The {@link AudioDeviceInfo} specifying the audio sink.
* If deviceInfo is null, default routing is restored.
* @return true if succesful, false if the specified {@link AudioDeviceInfo} is non-null and
* does not correspond to a valid audio output device.
*/
public boolean setPreferredDevice(AudioDeviceInfo deviceInfo) {
// Do some validation....
if (deviceInfo != null && !deviceInfo.isSink()) {
return false;
}
int preferredDeviceId = deviceInfo != null ? deviceInfo.getId() : 0;
boolean status = native_setOutputDevice(preferredDeviceId);
if (status == true) {
synchronized (this) {
mPreferredDevice = deviceInfo;
}
}
return status;
}
/**
* Returns the selected output specified by {@link #setPreferredDevice}. Note that this
* is not guaranteed to correspond to the actual device being used for playback.
*/
public AudioDeviceInfo getPreferredDevice() {
synchronized (this) {
return mPreferredDevice;
}
}
//--------------------------------------------------------------------------
// (Re)Routing Info
//--------------------
/**
* Defines the interface by which applications can receive notifications of routing
* changes for the associated {@link AudioTrack}.
*/
public interface OnRoutingChangedListener {
/**
* Called when the routing of an AudioTrack changes from either and explicit or
* policy rerouting. Use {@link #getRoutedDevice()} to retrieve the newly routed-to
* device.
*/
public void onRoutingChanged(AudioTrack audioTrack);
}
/**
* Returns an {@link AudioDeviceInfo} identifying the current routing of this AudioTrack.
* Note: The query is only valid if the AudioTrack is currently playing. If it is not,
* <code>getRoutedDevice()</code> will return null.
*/
public AudioDeviceInfo getRoutedDevice() {
int deviceId = native_getRoutedDeviceId();
if (deviceId == 0) {
return null;
}
AudioDeviceInfo[] devices =
AudioManager.getDevicesStatic(AudioManager.GET_DEVICES_OUTPUTS);
for (int i = 0; i < devices.length; i++) {
if (devices[i].getId() == deviceId) {
return devices[i];
}
}
return null;
}
/**
* The list of AudioTrack.OnRoutingChangedListener interfaces added (with
* {@link AudioTrack#addOnRoutingChangedListener(OnRoutingChangedListener, android.os.Handler)}
* by an app to receive (re)routing notifications.
*/
private ArrayMap<OnRoutingChangedListener, NativeRoutingEventHandlerDelegate>
mRoutingChangeListeners =
new ArrayMap<OnRoutingChangedListener, NativeRoutingEventHandlerDelegate>();
/**
* Adds an {@link OnRoutingChangedListener} to receive notifications of routing changes
* on this AudioTrack.
* @param listener The {@link OnRoutingChangedListener} interface to receive notifications
* of rerouting events.
* @param handler Specifies the {@link Handler} object for the thread on which to execute
* the callback. If <code>null</code>, the {@link Handler} associated with the main
* {@link Looper} will be used.
*/
public void addOnRoutingChangedListener(OnRoutingChangedListener listener,
android.os.Handler handler) {
if (listener != null && !mRoutingChangeListeners.containsKey(listener)) {
synchronized (mRoutingChangeListeners) {
if (mRoutingChangeListeners.size() == 0) {
native_enableDeviceCallback();
}
mRoutingChangeListeners.put(
listener, new NativeRoutingEventHandlerDelegate(this, listener,
handler != null ? handler : new Handler(mInitializationLooper)));
}
}
}
/**
* Removes an {@link OnRoutingChangedListener} which has been previously added
* to receive rerouting notifications.
* @param listener The previously added {@link OnRoutingChangedListener} interface to remove.
*/
public void removeOnRoutingChangedListener(OnRoutingChangedListener listener) {
synchronized (mRoutingChangeListeners) {
if (mRoutingChangeListeners.containsKey(listener)) {
mRoutingChangeListeners.remove(listener);
}
if (mRoutingChangeListeners.size() == 0) {
native_disableDeviceCallback();
}
}
}
/**
* Sends device list change notification to all listeners.
*/
private void broadcastRoutingChange() {
Collection<NativeRoutingEventHandlerDelegate> values;
synchronized (mRoutingChangeListeners) {
values = mRoutingChangeListeners.values();
}
AudioManager.resetAudioPortGeneration();
for(NativeRoutingEventHandlerDelegate delegate : values) {
Handler handler = delegate.getHandler();
if (handler != null) {
handler.sendEmptyMessage(AudioSystem.NATIVE_EVENT_ROUTING_CHANGE);
}
}
}
//---------------------------------------------------------
// Interface definitions
//--------------------
/**
* Interface definition for a callback to be invoked when the playback head position of
* an AudioTrack has reached a notification marker or has increased by a certain period.
*/
public interface OnPlaybackPositionUpdateListener {
/**
* Called on the listener to notify it that the previously set marker has been reached
* by the playback head.
*/
void onMarkerReached(AudioTrack track);
/**
* Called on the listener to periodically notify it that the playback head has reached
* a multiple of the notification period.
*/
void onPeriodicNotification(AudioTrack track);
}
//---------------------------------------------------------
// Inner classes
//--------------------
/**
* Helper class to handle the forwarding of native events to the appropriate listener
* (potentially) handled in a different thread
*/
private class NativePositionEventHandlerDelegate {
private final Handler mHandler;
NativePositionEventHandlerDelegate(final AudioTrack track,
final OnPlaybackPositionUpdateListener listener,
Handler handler) {
// find the looper for our new event handler
Looper looper;
if (handler != null) {
looper = handler.getLooper();
} else {
// no given handler, use the looper the AudioTrack was created in
looper = mInitializationLooper;
}
// construct the event handler with this looper
if (looper != null) {
// implement the event handler delegate
mHandler = new Handler(looper) {
@Override
public void handleMessage(Message msg) {
if (track == null) {
return;
}
switch(msg.what) {
case NATIVE_EVENT_MARKER:
if (listener != null) {
listener.onMarkerReached(track);
}
break;
case NATIVE_EVENT_NEW_POS:
if (listener != null) {
listener.onPeriodicNotification(track);
}
break;
default:
loge("Unknown native event type: " + msg.what);
break;
}
}
};
} else {
mHandler = null;
}
}
Handler getHandler() {
return mHandler;
}
}
/**
* Helper class to handle the forwarding of native events to the appropriate listener
* (potentially) handled in a different thread
*/
private class NativeRoutingEventHandlerDelegate {
private final Handler mHandler;
NativeRoutingEventHandlerDelegate(final AudioTrack track,
final OnRoutingChangedListener listener,
Handler handler) {
// find the looper for our new event handler
Looper looper;
if (handler != null) {
looper = handler.getLooper();
} else {
// no given handler, use the looper the AudioTrack was created in
looper = mInitializationLooper;
}
// construct the event handler with this looper
if (looper != null) {
// implement the event handler delegate
mHandler = new Handler(looper) {
@Override
public void handleMessage(Message msg) {
if (track == null) {
return;
}
switch(msg.what) {
case AudioSystem.NATIVE_EVENT_ROUTING_CHANGE:
if (listener != null) {
listener.onRoutingChanged(track);
}
break;
default:
loge("Unknown native event type: " + msg.what);
break;
}
}
};
} else {
mHandler = null;
}
}
Handler getHandler() {
return mHandler;
}
}
//---------------------------------------------------------
// Java methods called from the native side
//--------------------
@SuppressWarnings("unused")
private static void postEventFromNative(Object audiotrack_ref,
int what, int arg1, int arg2, Object obj) {
//logd("Event posted from the native side: event="+ what + " args="+ arg1+" "+arg2);
AudioTrack track = (AudioTrack)((WeakReference)audiotrack_ref).get();
if (track == null) {
return;
}
if (what == AudioSystem.NATIVE_EVENT_ROUTING_CHANGE) {
track.broadcastRoutingChange();
return;
}
NativePositionEventHandlerDelegate delegate = track.mEventHandlerDelegate;
if (delegate != null) {
Handler handler = delegate.getHandler();
if (handler != null) {
Message m = handler.obtainMessage(what, arg1, arg2, obj);
handler.sendMessage(m);
}
}
}
//---------------------------------------------------------
// Native methods called from the Java side
//--------------------
// post-condition: mStreamType is overwritten with a value
// that reflects the audio attributes (e.g. an AudioAttributes object with a usage of
// AudioAttributes.USAGE_MEDIA will map to AudioManager.STREAM_MUSIC
private native final int native_setup(Object /*WeakReference<AudioTrack>*/ audiotrack_this,
Object /*AudioAttributes*/ attributes,
int sampleRate, int channelMask, int channelIndexMask, int audioFormat,
int buffSizeInBytes, int mode, int[] sessionId);
private native final void native_finalize();
private native final void native_release();
private native final void native_start();
private native final void native_stop();
private native final void native_pause();
private native final void native_flush();
private native final int native_write_byte(byte[] audioData,
int offsetInBytes, int sizeInBytes, int format,
boolean isBlocking);
private native final int native_write_short(short[] audioData,
int offsetInShorts, int sizeInShorts, int format,
boolean isBlocking);
private native final int native_write_float(float[] audioData,
int offsetInFloats, int sizeInFloats, int format,
boolean isBlocking);
private native final int native_write_native_bytes(Object audioData,
int positionInBytes, int sizeInBytes, int format, boolean blocking);
private native final int native_reload_static();
private native final int native_get_native_frame_count();
private native final void native_setVolume(float leftVolume, float rightVolume);
private native final int native_set_playback_rate(int sampleRateInHz);
private native final int native_get_playback_rate();
private native final void native_set_playback_params(@NonNull PlaybackParams params);
private native final @NonNull PlaybackParams native_get_playback_params();
private native final int native_set_marker_pos(int marker);
private native final int native_get_marker_pos();
private native final int native_set_pos_update_period(int updatePeriod);
private native final int native_get_pos_update_period();
private native final int native_set_position(int position);
private native final int native_get_position();
private native final int native_get_latency();
// longArray must be a non-null array of length >= 2
// [0] is assigned the frame position
// [1] is assigned the time in CLOCK_MONOTONIC nanoseconds
private native final int native_get_timestamp(long[] longArray);
private native final int native_set_loop(int start, int end, int loopCount);
static private native final int native_get_output_sample_rate(int streamType);
static private native final int native_get_min_buff_size(
int sampleRateInHz, int channelConfig, int audioFormat);
private native final int native_attachAuxEffect(int effectId);
private native final int native_setAuxEffectSendLevel(float level);
private native final boolean native_setOutputDevice(int deviceId);
private native final int native_getRoutedDeviceId();
private native final void native_enableDeviceCallback();
private native final void native_disableDeviceCallback();
//---------------------------------------------------------
// Utility methods
//------------------
private static void logd(String msg) {
Log.d(TAG, msg);
}
private static void loge(String msg) {
Log.e(TAG, msg);
}
}