blob: 7a72d28c7a86dcb128be80e82f38b9903db9b398 [file] [log] [blame]
/*
* Copyright (C) 2010 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.
*/
/* OutputMixExt implementation */
#include "sles_allinclusive.h"
#include <math.h>
// OutputMixExt is used by SDL, but is not specific to or dependent on SDL
// stereo is a frame consisting of a pair of 16-bit PCM samples
typedef struct {
short left;
short right;
} stereo;
/** \brief Summary of the gain, as an optimization for the mixer */
typedef enum {
GAIN_MUTE = 0, // mValue == 0.0f within epsilon
GAIN_UNITY = 1, // mValue == 1.0f within epsilon
GAIN_OTHER = 2 // 0.0f < mValue < 1.0f
} Summary;
/** \brief Check whether a track has any data for us to read */
static SLboolean track_check(Track *track)
{
assert(NULL != track);
SLboolean trackHasData = SL_BOOLEAN_FALSE;
CAudioPlayer *audioPlayer = track->mAudioPlayer;
if (NULL != audioPlayer) {
// track is initialized
// FIXME This lock could block and result in stuttering;
// a trylock with retry or lockless solution would be ideal
object_lock_exclusive(&audioPlayer->mObject);
assert(audioPlayer->mTrack == track);
SLuint32 framesMixed = track->mFramesMixed;
if (0 != framesMixed) {
track->mFramesMixed = 0;
audioPlayer->mPlay.mFramesSinceLastSeek += framesMixed;
audioPlayer->mPlay.mFramesSincePositionUpdate += framesMixed;
}
SLboolean doBroadcast = SL_BOOLEAN_FALSE;
const BufferHeader *oldFront;
if (audioPlayer->mBufferQueue.mClearRequested) {
// application thread(s) that call BufferQueue::Clear while mixer is active
// will block synchronously until mixer acknowledges the Clear request
audioPlayer->mBufferQueue.mFront = &audioPlayer->mBufferQueue.mArray[0];
audioPlayer->mBufferQueue.mRear = &audioPlayer->mBufferQueue.mArray[0];
audioPlayer->mBufferQueue.mState.count = 0;
audioPlayer->mBufferQueue.mState.playIndex = 0;
audioPlayer->mBufferQueue.mClearRequested = SL_BOOLEAN_FALSE;
track->mReader = NULL;
track->mAvail = 0;
doBroadcast = SL_BOOLEAN_TRUE;
}
if (audioPlayer->mDestroyRequested) {
// an application thread that calls Object::Destroy while mixer is active will block
// synchronously in the PreDestroy hook until mixer acknowledges the Destroy request
COutputMix *outputMix = CAudioPlayer_GetOutputMix(audioPlayer);
unsigned i = track - outputMix->mOutputMixExt.mTracks;
assert( /* 0 <= i && */ i < MAX_TRACK);
unsigned mask = 1 << i;
track->mAudioPlayer = NULL;
assert(outputMix->mOutputMixExt.mActiveMask & mask);
outputMix->mOutputMixExt.mActiveMask &= ~mask;
audioPlayer->mTrack = NULL;
audioPlayer->mDestroyRequested = SL_BOOLEAN_FALSE;
doBroadcast = SL_BOOLEAN_TRUE;
goto broadcast;
}
switch (audioPlayer->mPlay.mState) {
case SL_PLAYSTATE_PLAYING: // continue playing current track data
if (0 < track->mAvail) {
trackHasData = SL_BOOLEAN_TRUE;
break;
}
// try to get another buffer from queue
oldFront = audioPlayer->mBufferQueue.mFront;
if (oldFront != audioPlayer->mBufferQueue.mRear) {
assert(0 < audioPlayer->mBufferQueue.mState.count);
track->mReader = oldFront->mBuffer;
track->mAvail = oldFront->mSize;
// note that the buffer stays on the queue while we are reading
audioPlayer->mPlay.mState = SL_PLAYSTATE_PLAYING;
trackHasData = SL_BOOLEAN_TRUE;
} else {
// no buffers on queue, so playable but not playing
// NTH should be able to call a desperation callback when completely starved,
// or call less often than every buffer based on high/low water-marks
}
// copy gains from audio player to track
track->mGains[0] = audioPlayer->mGains[0];
track->mGains[1] = audioPlayer->mGains[1];
break;
case SL_PLAYSTATE_STOPPING: // application thread(s) called Play::SetPlayState(STOPPED)
audioPlayer->mPlay.mPosition = (SLmillisecond) 0;
audioPlayer->mPlay.mFramesSinceLastSeek = 0;
audioPlayer->mPlay.mFramesSincePositionUpdate = 0;
audioPlayer->mPlay.mLastSeekPosition = 0;
audioPlayer->mPlay.mState = SL_PLAYSTATE_STOPPED;
// stop cancels a pending seek
audioPlayer->mSeek.mPos = SL_TIME_UNKNOWN;
oldFront = audioPlayer->mBufferQueue.mFront;
if (oldFront != audioPlayer->mBufferQueue.mRear) {
assert(0 < audioPlayer->mBufferQueue.mState.count);
track->mReader = oldFront->mBuffer;
track->mAvail = oldFront->mSize;
}
doBroadcast = SL_BOOLEAN_TRUE;
break;
case SL_PLAYSTATE_STOPPED: // idle
case SL_PLAYSTATE_PAUSED: // idle
break;
default:
assert(SL_BOOLEAN_FALSE);
break;
}
broadcast:
if (doBroadcast) {
object_cond_broadcast(&audioPlayer->mObject);
}
object_unlock_exclusive(&audioPlayer->mObject);
}
return trackHasData;
}
/** \brief This is the track mixer: fill the specified 16-bit stereo PCM buffer */
void IOutputMixExt_FillBuffer(SLOutputMixExtItf self, void *pBuffer, SLuint32 size)
{
SL_ENTER_INTERFACE_VOID
// Force to be a multiple of a frame, assumes stereo 16-bit PCM
size &= ~3;
SLboolean mixBufferHasData = SL_BOOLEAN_FALSE;
IOutputMixExt *thiz = (IOutputMixExt *) self;
IObject *thisObject = thiz->mThis;
// This lock should never block, except when the application destroys the output mix object
object_lock_exclusive(thisObject);
unsigned activeMask;
// If the output mix is marked for destruction, then acknowledge the request
if (thiz->mDestroyRequested) {
IEngine *thisEngine = &thisObject->mEngine->mEngine;
interface_lock_exclusive(thisEngine);
assert(&thisEngine->mOutputMix->mObject == thisObject);
thisEngine->mOutputMix = NULL;
// Note we don't attempt to connect another output mix, even if there is one
interface_unlock_exclusive(thisEngine);
// Acknowledge the destroy request, and notify the pre-destroy hook
thiz->mDestroyRequested = SL_BOOLEAN_FALSE;
object_cond_broadcast(thisObject);
activeMask = 0;
} else {
activeMask = thiz->mActiveMask;
}
while (activeMask) {
unsigned i = ctz(activeMask);
assert(MAX_TRACK > i);
activeMask &= ~(1 << i);
Track *track = &thiz->mTracks[i];
// track is allocated
if (!track_check(track)) {
continue;
}
// track is playing
void *dstWriter = pBuffer;
unsigned desired = size;
SLboolean trackContributedToMix = SL_BOOLEAN_FALSE;
float gains[STEREO_CHANNELS];
Summary summaries[STEREO_CHANNELS];
unsigned channel;
for (channel = 0; channel < STEREO_CHANNELS; ++channel) {
float gain = track->mGains[channel];
gains[channel] = gain;
Summary summary;
if (gain <= 0.001) {
summary = GAIN_MUTE;
} else if (gain >= 0.999) {
summary = GAIN_UNITY;
} else {
summary = GAIN_OTHER;
}
summaries[channel] = summary;
}
while (desired > 0) {
unsigned actual = desired;
if (track->mAvail < actual) {
actual = track->mAvail;
}
// force actual to be a frame multiple
if (actual > 0) {
assert(NULL != track->mReader);
stereo *mixBuffer = (stereo *) dstWriter;
const stereo *source = (const stereo *) track->mReader;
unsigned j;
if (GAIN_MUTE != summaries[0] || GAIN_MUTE != summaries[1]) {
if (mixBufferHasData) {
// apply gain during add
if (GAIN_UNITY != summaries[0] || GAIN_UNITY != summaries[1]) {
for (j = 0; j < actual; j += sizeof(stereo), ++mixBuffer, ++source) {
mixBuffer->left += (short) (source->left * track->mGains[0]);
mixBuffer->right += (short) (source->right * track->mGains[1]);
}
// no gain adjustment needed, so do a simple add
} else {
for (j = 0; j < actual; j += sizeof(stereo), ++mixBuffer, ++source) {
mixBuffer->left += source->left;
mixBuffer->right += source->right;
}
}
} else {
// apply gain during copy
if (GAIN_UNITY != summaries[0] || GAIN_UNITY != summaries[1]) {
for (j = 0; j < actual; j += sizeof(stereo), ++mixBuffer, ++source) {
mixBuffer->left = (short) (source->left * track->mGains[0]);
mixBuffer->right = (short) (source->right * track->mGains[1]);
}
// no gain adjustment needed, so do a simple copy
} else {
memcpy(dstWriter, track->mReader, actual);
}
}
trackContributedToMix = SL_BOOLEAN_TRUE;
}
dstWriter = (char *) dstWriter + actual;
desired -= actual;
track->mReader = (char *) track->mReader + actual;
track->mAvail -= actual;
if (track->mAvail == 0) {
IBufferQueue *bufferQueue = &track->mAudioPlayer->mBufferQueue;
interface_lock_exclusive(bufferQueue);
const BufferHeader *oldFront, *newFront, *rear;
oldFront = bufferQueue->mFront;
rear = bufferQueue->mRear;
// a buffer stays on queue while playing, so it better still be there
assert(oldFront != rear);
newFront = oldFront;
if (++newFront == &bufferQueue->mArray[bufferQueue->mNumBuffers + 1]) {
newFront = bufferQueue->mArray;
}
bufferQueue->mFront = (BufferHeader *) newFront;
assert(0 < bufferQueue->mState.count);
--bufferQueue->mState.count;
if (newFront != rear) {
// we don't acknowledge application requests between buffers
// within the same mixer frame
assert(0 < bufferQueue->mState.count);
track->mReader = newFront->mBuffer;
track->mAvail = newFront->mSize;
}
// else we would set play state to playable but not playing during next mixer
// frame if the queue is still empty at that time
++bufferQueue->mState.playIndex;
slBufferQueueCallback callback = bufferQueue->mCallback;
void *context = bufferQueue->mContext;
interface_unlock_exclusive(bufferQueue);
// The callback function is called on each buffer completion
if (NULL != callback) {
(*callback)((SLBufferQueueItf) bufferQueue, context);
// Maybe it enqueued another buffer, or maybe it didn't.
// We will find out later during the next mixer frame.
}
}
// no lock, but safe because noone else updates this field
track->mFramesMixed += actual >> 2; // sizeof(short) * STEREO_CHANNELS
continue;
}
// we need more data: desired > 0 but actual == 0
if (track_check(track)) {
continue;
}
// underflow: clear out rest of partial buffer (NTH synthesize comfort noise)
if (!mixBufferHasData && trackContributedToMix) {
memset(dstWriter, 0, actual);
}
break;
}
if (trackContributedToMix) {
mixBufferHasData = SL_BOOLEAN_TRUE;
}
}
object_unlock_exclusive(thisObject);
// No active tracks, so output silence
if (!mixBufferHasData) {
memset(pBuffer, 0, size);
}
SL_LEAVE_INTERFACE_VOID
}
static const struct SLOutputMixExtItf_ IOutputMixExt_Itf = {
IOutputMixExt_FillBuffer
};
void IOutputMixExt_init(void *self)
{
IOutputMixExt *thiz = (IOutputMixExt *) self;
thiz->mItf = &IOutputMixExt_Itf;
thiz->mActiveMask = 0;
Track *track = &thiz->mTracks[0];
unsigned i;
for (i = 0; i < MAX_TRACK; ++i, ++track) {
track->mAudioPlayer = NULL;
}
thiz->mDestroyRequested = SL_BOOLEAN_FALSE;
}
/** \brief Called by Engine::CreateAudioPlayer to allocate a track */
SLresult IOutputMixExt_checkAudioPlayerSourceSink(CAudioPlayer *thiz)
{
thiz->mTrack = NULL;
// check the source for compatibility
switch (thiz->mDataSource.mLocator.mLocatorType) {
case SL_DATALOCATOR_BUFFERQUEUE:
#ifdef ANDROID
case SL_DATALOCATOR_ANDROIDSIMPLEBUFFERQUEUE:
#endif
switch (thiz->mDataSource.mFormat.mFormatType) {
case SL_DATAFORMAT_PCM:
#ifdef USE_SDL
// SDL is hard-coded to 44.1 kHz, and there is no sample rate converter
if (SL_SAMPLINGRATE_44_1 != thiz->mDataSource.mFormat.mPCM.samplesPerSec)
return SL_RESULT_CONTENT_UNSUPPORTED;
#endif
break;
default:
break;
}
break;
default:
break;
}
// check the sink for compatibility
const SLDataSink *pAudioSnk = &thiz->mDataSink.u.mSink;
Track *track = NULL;
switch (*(SLuint32 *)pAudioSnk->pLocator) {
case SL_DATALOCATOR_OUTPUTMIX:
{
// pAudioSnk->pFormat is ignored
IOutputMixExt *omExt = &((COutputMix *) ((SLDataLocator_OutputMix *)
pAudioSnk->pLocator)->outputMix)->mOutputMixExt;
// allocate an entry within OutputMix for this track
interface_lock_exclusive(omExt);
unsigned availMask = ~omExt->mActiveMask;
if (!availMask) {
interface_unlock_exclusive(omExt);
// All track slots full in output mix
return SL_RESULT_MEMORY_FAILURE;
}
unsigned i = ctz(availMask);
assert(MAX_TRACK > i);
omExt->mActiveMask |= 1 << i;
track = &omExt->mTracks[i];
track->mAudioPlayer = NULL; // only field that is accessed before full initialization
interface_unlock_exclusive(omExt);
thiz->mTrack = track;
thiz->mGains[0] = 1.0f;
thiz->mGains[1] = 1.0f;
thiz->mDestroyRequested = SL_BOOLEAN_FALSE;
}
break;
default:
return SL_RESULT_CONTENT_UNSUPPORTED;
}
assert(NULL != track);
track->mBufferQueue = &thiz->mBufferQueue;
track->mAudioPlayer = thiz;
track->mReader = NULL;
track->mAvail = 0;
track->mGains[0] = 1.0f;
track->mGains[1] = 1.0f;
track->mFramesMixed = 0;
return SL_RESULT_SUCCESS;
}
/** \brief Called when a gain-related field (mute, solo, volume, stereo position, etc.) updated */
void audioPlayerGainUpdate(CAudioPlayer *audioPlayer)
{
SLboolean mute = audioPlayer->mVolume.mMute;
SLuint8 muteMask = audioPlayer->mMuteMask;
SLuint8 soloMask = audioPlayer->mSoloMask;
SLmillibel level = audioPlayer->mVolume.mLevel;
SLboolean enableStereoPosition = audioPlayer->mVolume.mEnableStereoPosition;
SLpermille stereoPosition = audioPlayer->mVolume.mStereoPosition;
if (soloMask) {
muteMask |= ~soloMask;
}
if (mute || !(~muteMask & 3)) {
audioPlayer->mGains[0] = 0.0f;
audioPlayer->mGains[1] = 0.0f;
} else {
float playerGain = powf(10.0f, level / 2000.0f);
unsigned channel;
for (channel = 0; channel < STEREO_CHANNELS; ++channel) {
float gain;
if (muteMask & (1 << channel)) {
gain = 0.0f;
} else {
gain = playerGain;
if (enableStereoPosition) {
switch (channel) {
case 0:
if (stereoPosition > 0) {
gain *= (1000 - stereoPosition) / 1000.0f;
}
break;
case 1:
if (stereoPosition < 0) {
gain *= (1000 + stereoPosition) / 1000.0f;
}
break;
default:
assert(SL_BOOLEAN_FALSE);
break;
}
}
}
audioPlayer->mGains[channel] = gain;
}
}
}