blob: 102bbf0e5931623e6383140168ecbcab42d2a9cf [file] [log] [blame]
/*
* Copyright (C) 2007 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.
*/
//#define LOG_NDEBUG 0
#define LOG_TAG "SoundPool"
#include <chrono>
#include <inttypes.h>
#include <thread>
#include <utils/Log.h>
#define USE_SHARED_MEM_BUFFER
#include <media/AudioTrack.h>
#include "SoundPool.h"
#include "SoundPoolThread.h"
#include <media/NdkMediaCodec.h>
#include <media/NdkMediaExtractor.h>
#include <media/NdkMediaFormat.h>
namespace android
{
int kDefaultBufferCount = 4;
uint32_t kMaxSampleRate = 48000;
uint32_t kDefaultSampleRate = 44100;
uint32_t kDefaultFrameCount = 1200;
size_t kDefaultHeapSize = 1024 * 1024; // 1MB
SoundPool::SoundPool(int maxChannels, const audio_attributes_t* pAttributes)
{
ALOGV("SoundPool constructor: maxChannels=%d, attr.usage=%d, attr.flags=0x%x, attr.tags=%s",
maxChannels, pAttributes->usage, pAttributes->flags, pAttributes->tags);
// check limits
mMaxChannels = maxChannels;
if (mMaxChannels < 1) {
mMaxChannels = 1;
}
else if (mMaxChannels > 32) {
mMaxChannels = 32;
}
ALOGW_IF(maxChannels != mMaxChannels, "App requested %d channels", maxChannels);
mQuit = false;
mMuted = false;
mDecodeThread = 0;
memcpy(&mAttributes, pAttributes, sizeof(audio_attributes_t));
mAllocated = 0;
mNextSampleID = 0;
mNextChannelID = 0;
mCallback = 0;
mUserData = 0;
mChannelPool = new SoundChannel[mMaxChannels];
for (int i = 0; i < mMaxChannels; ++i) {
mChannelPool[i].init(this);
mChannels.push_back(&mChannelPool[i]);
}
// start decode thread
startThreads();
}
SoundPool::~SoundPool()
{
ALOGV("SoundPool destructor");
mDecodeThread->quit();
quit();
Mutex::Autolock lock(&mLock);
mChannels.clear();
if (mChannelPool)
delete [] mChannelPool;
// clean up samples
ALOGV("clear samples");
mSamples.clear();
if (mDecodeThread)
delete mDecodeThread;
}
void SoundPool::addToRestartList(SoundChannel* channel)
{
Mutex::Autolock lock(&mRestartLock);
if (!mQuit) {
mRestart.push_back(channel);
mCondition.signal();
}
}
void SoundPool::addToStopList(SoundChannel* channel)
{
Mutex::Autolock lock(&mRestartLock);
if (!mQuit) {
mStop.push_back(channel);
mCondition.signal();
}
}
int SoundPool::beginThread(void* arg)
{
SoundPool* p = (SoundPool*)arg;
return p->run();
}
int SoundPool::run()
{
mRestartLock.lock();
while (!mQuit) {
mCondition.wait(mRestartLock);
ALOGV("awake");
if (mQuit) break;
while (!mStop.empty()) {
SoundChannel* channel;
ALOGV("Getting channel from stop list");
List<SoundChannel* >::iterator iter = mStop.begin();
channel = *iter;
mStop.erase(iter);
mRestartLock.unlock();
if (channel != 0) {
Mutex::Autolock lock(&mLock);
channel->stop();
}
mRestartLock.lock();
if (mQuit) break;
}
while (!mRestart.empty()) {
SoundChannel* channel;
ALOGV("Getting channel from list");
List<SoundChannel*>::iterator iter = mRestart.begin();
channel = *iter;
mRestart.erase(iter);
mRestartLock.unlock();
if (channel != 0) {
Mutex::Autolock lock(&mLock);
channel->nextEvent();
}
mRestartLock.lock();
if (mQuit) break;
}
}
mStop.clear();
mRestart.clear();
mCondition.signal();
mRestartLock.unlock();
ALOGV("goodbye");
return 0;
}
void SoundPool::quit()
{
mRestartLock.lock();
mQuit = true;
mCondition.signal();
mCondition.wait(mRestartLock);
ALOGV("return from quit");
mRestartLock.unlock();
}
bool SoundPool::startThreads()
{
createThreadEtc(beginThread, this, "SoundPool");
if (mDecodeThread == NULL)
mDecodeThread = new SoundPoolThread(this);
return mDecodeThread != NULL;
}
sp<Sample> SoundPool::findSample(int sampleID)
{
Mutex::Autolock lock(&mLock);
return findSample_l(sampleID);
}
sp<Sample> SoundPool::findSample_l(int sampleID)
{
return mSamples.valueFor(sampleID);
}
SoundChannel* SoundPool::findChannel(int channelID)
{
for (int i = 0; i < mMaxChannels; ++i) {
if (mChannelPool[i].channelID() == channelID) {
return &mChannelPool[i];
}
}
return NULL;
}
SoundChannel* SoundPool::findNextChannel(int channelID)
{
for (int i = 0; i < mMaxChannels; ++i) {
if (mChannelPool[i].nextChannelID() == channelID) {
return &mChannelPool[i];
}
}
return NULL;
}
int SoundPool::load(int fd, int64_t offset, int64_t length, int priority __unused)
{
ALOGV("load: fd=%d, offset=%" PRId64 ", length=%" PRId64 ", priority=%d",
fd, offset, length, priority);
int sampleID;
{
Mutex::Autolock lock(&mLock);
sampleID = ++mNextSampleID;
sp<Sample> sample = new Sample(sampleID, fd, offset, length);
mSamples.add(sampleID, sample);
sample->startLoad();
}
// mDecodeThread->loadSample() must be called outside of mLock.
// mDecodeThread->loadSample() may block on mDecodeThread message queue space;
// the message queue emptying may block on SoundPool::findSample().
//
// It theoretically possible that sample loads might decode out-of-order.
mDecodeThread->loadSample(sampleID);
return sampleID;
}
bool SoundPool::unload(int sampleID)
{
ALOGV("unload: sampleID=%d", sampleID);
Mutex::Autolock lock(&mLock);
return mSamples.removeItem(sampleID) >= 0; // removeItem() returns index or BAD_VALUE
}
int SoundPool::play(int sampleID, float leftVolume, float rightVolume,
int priority, int loop, float rate)
{
ALOGV("play sampleID=%d, leftVolume=%f, rightVolume=%f, priority=%d, loop=%d, rate=%f",
sampleID, leftVolume, rightVolume, priority, loop, rate);
SoundChannel* channel;
int channelID;
Mutex::Autolock lock(&mLock);
if (mQuit) {
return 0;
}
// is sample ready?
sp<Sample> sample(findSample_l(sampleID));
if ((sample == 0) || (sample->state() != Sample::READY)) {
ALOGW(" sample %d not READY", sampleID);
return 0;
}
dump();
// allocate a channel
channel = allocateChannel_l(priority, sampleID);
// no channel allocated - return 0
if (!channel) {
ALOGV("No channel allocated");
return 0;
}
channelID = ++mNextChannelID;
ALOGV("play channel %p state = %d", channel, channel->state());
channel->play(sample, channelID, leftVolume, rightVolume, priority, loop, rate);
return channelID;
}
SoundChannel* SoundPool::allocateChannel_l(int priority, int sampleID)
{
List<SoundChannel*>::iterator iter;
SoundChannel* channel = NULL;
// check if channel for given sampleID still available
if (!mChannels.empty()) {
for (iter = mChannels.begin(); iter != mChannels.end(); ++iter) {
if (sampleID == (*iter)->getPrevSampleID() && (*iter)->state() == SoundChannel::IDLE) {
channel = *iter;
mChannels.erase(iter);
ALOGV("Allocated recycled channel for same sampleID");
break;
}
}
}
// allocate any channel
if (!channel && !mChannels.empty()) {
iter = mChannels.begin();
if (priority >= (*iter)->priority()) {
channel = *iter;
mChannels.erase(iter);
ALOGV("Allocated active channel");
}
}
// update priority and put it back in the list
if (channel) {
channel->setPriority(priority);
for (iter = mChannels.begin(); iter != mChannels.end(); ++iter) {
if (priority < (*iter)->priority()) {
break;
}
}
mChannels.insert(iter, channel);
}
return channel;
}
// move a channel from its current position to the front of the list
void SoundPool::moveToFront_l(SoundChannel* channel)
{
for (List<SoundChannel*>::iterator iter = mChannels.begin(); iter != mChannels.end(); ++iter) {
if (*iter == channel) {
mChannels.erase(iter);
mChannels.push_front(channel);
break;
}
}
}
void SoundPool::pause(int channelID)
{
ALOGV("pause(%d)", channelID);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->pause();
}
}
void SoundPool::autoPause()
{
ALOGV("autoPause()");
Mutex::Autolock lock(&mLock);
for (int i = 0; i < mMaxChannels; ++i) {
SoundChannel* channel = &mChannelPool[i];
channel->autoPause();
}
}
void SoundPool::resume(int channelID)
{
ALOGV("resume(%d)", channelID);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->resume();
}
}
void SoundPool::mute(bool muting)
{
ALOGV("mute(%d)", muting);
Mutex::Autolock lock(&mLock);
mMuted = muting;
if (!mChannels.empty()) {
for (List<SoundChannel*>::iterator iter = mChannels.begin();
iter != mChannels.end(); ++iter) {
(*iter)->mute(muting);
}
}
}
void SoundPool::autoResume()
{
ALOGV("autoResume()");
Mutex::Autolock lock(&mLock);
for (int i = 0; i < mMaxChannels; ++i) {
SoundChannel* channel = &mChannelPool[i];
channel->autoResume();
}
}
void SoundPool::stop(int channelID)
{
ALOGV("stop(%d)", channelID);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->stop();
} else {
channel = findNextChannel(channelID);
if (channel)
channel->clearNextEvent();
}
}
void SoundPool::setVolume(int channelID, float leftVolume, float rightVolume)
{
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->setVolume(leftVolume, rightVolume);
}
}
void SoundPool::setPriority(int channelID, int priority)
{
ALOGV("setPriority(%d, %d)", channelID, priority);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->setPriority(priority);
}
}
void SoundPool::setLoop(int channelID, int loop)
{
ALOGV("setLoop(%d, %d)", channelID, loop);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->setLoop(loop);
}
}
void SoundPool::setRate(int channelID, float rate)
{
ALOGV("setRate(%d, %f)", channelID, rate);
Mutex::Autolock lock(&mLock);
SoundChannel* channel = findChannel(channelID);
if (channel) {
channel->setRate(rate);
}
}
// call with lock held
void SoundPool::done_l(SoundChannel* channel)
{
ALOGV("done_l(%d)", channel->channelID());
// if "stolen", play next event
if (channel->nextChannelID() != 0) {
ALOGV("add to restart list");
addToRestartList(channel);
}
// return to idle state
else {
ALOGV("move to front");
moveToFront_l(channel);
}
}
void SoundPool::setCallback(SoundPoolCallback* callback, void* user)
{
Mutex::Autolock lock(&mCallbackLock);
mCallback = callback;
mUserData = user;
}
void SoundPool::notify(SoundPoolEvent event)
{
Mutex::Autolock lock(&mCallbackLock);
if (mCallback != NULL) {
mCallback(event, this, mUserData);
}
}
void SoundPool::dump()
{
for (int i = 0; i < mMaxChannels; ++i) {
mChannelPool[i].dump();
}
}
Sample::Sample(int sampleID, int fd, int64_t offset, int64_t length)
{
init();
mSampleID = sampleID;
mFd = dup(fd);
mOffset = offset;
mLength = length;
ALOGV("create sampleID=%d, fd=%d, offset=%" PRId64 " length=%" PRId64,
mSampleID, mFd, mLength, mOffset);
}
void Sample::init()
{
mSize = 0;
mRefCount = 0;
mSampleID = 0;
mState = UNLOADED;
mFd = -1;
mOffset = 0;
mLength = 0;
}
Sample::~Sample()
{
ALOGV("Sample::destructor sampleID=%d, fd=%d", mSampleID, mFd);
if (mFd > 0) {
ALOGV("close(%d)", mFd);
::close(mFd);
}
}
static status_t decode(int fd, int64_t offset, int64_t length,
uint32_t *rate, int *numChannels, audio_format_t *audioFormat,
audio_channel_mask_t *channelMask, sp<MemoryHeapBase> heap,
size_t *memsize) {
ALOGV("fd %d, offset %" PRId64 ", size %" PRId64, fd, offset, length);
AMediaExtractor *ex = AMediaExtractor_new();
status_t err = AMediaExtractor_setDataSourceFd(ex, fd, offset, length);
if (err != AMEDIA_OK) {
AMediaExtractor_delete(ex);
return err;
}
*audioFormat = AUDIO_FORMAT_PCM_16_BIT;
size_t numTracks = AMediaExtractor_getTrackCount(ex);
for (size_t i = 0; i < numTracks; i++) {
AMediaFormat *format = AMediaExtractor_getTrackFormat(ex, i);
const char *mime;
if (!AMediaFormat_getString(format, AMEDIAFORMAT_KEY_MIME, &mime)) {
AMediaExtractor_delete(ex);
AMediaFormat_delete(format);
return UNKNOWN_ERROR;
}
if (strncmp(mime, "audio/", 6) == 0) {
AMediaCodec *codec = AMediaCodec_createDecoderByType(mime);
if (codec == NULL
|| AMediaCodec_configure(codec, format,
NULL /* window */, NULL /* drm */, 0 /* flags */) != AMEDIA_OK
|| AMediaCodec_start(codec) != AMEDIA_OK
|| AMediaExtractor_selectTrack(ex, i) != AMEDIA_OK) {
AMediaExtractor_delete(ex);
AMediaCodec_delete(codec);
AMediaFormat_delete(format);
return UNKNOWN_ERROR;
}
bool sawInputEOS = false;
bool sawOutputEOS = false;
uint8_t* writePos = static_cast<uint8_t*>(heap->getBase());
size_t available = heap->getSize();
size_t written = 0;
AMediaFormat_delete(format);
format = AMediaCodec_getOutputFormat(codec);
while (!sawOutputEOS) {
if (!sawInputEOS) {
ssize_t bufidx = AMediaCodec_dequeueInputBuffer(codec, 5000);
ALOGV("input buffer %zd", bufidx);
if (bufidx >= 0) {
size_t bufsize;
uint8_t *buf = AMediaCodec_getInputBuffer(codec, bufidx, &bufsize);
if (buf == nullptr) {
ALOGE("AMediaCodec_getInputBuffer returned nullptr, short decode");
break;
}
int sampleSize = AMediaExtractor_readSampleData(ex, buf, bufsize);
ALOGV("read %d", sampleSize);
if (sampleSize < 0) {
sampleSize = 0;
sawInputEOS = true;
ALOGV("EOS");
}
int64_t presentationTimeUs = AMediaExtractor_getSampleTime(ex);
media_status_t mstatus = AMediaCodec_queueInputBuffer(codec, bufidx,
0 /* offset */, sampleSize, presentationTimeUs,
sawInputEOS ? AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM : 0);
if (mstatus != AMEDIA_OK) {
// AMEDIA_ERROR_UNKNOWN == { -ERANGE -EINVAL -EACCES }
ALOGE("AMediaCodec_queueInputBuffer returned status %d, short decode",
(int)mstatus);
break;
}
(void)AMediaExtractor_advance(ex);
}
}
AMediaCodecBufferInfo info;
int status = AMediaCodec_dequeueOutputBuffer(codec, &info, 1);
ALOGV("dequeueoutput returned: %d", status);
if (status >= 0) {
if (info.flags & AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM) {
ALOGV("output EOS");
sawOutputEOS = true;
}
ALOGV("got decoded buffer size %d", info.size);
uint8_t *buf = AMediaCodec_getOutputBuffer(codec, status, NULL /* out_size */);
if (buf == nullptr) {
ALOGE("AMediaCodec_getOutputBuffer returned nullptr, short decode");
break;
}
size_t dataSize = info.size;
if (dataSize > available) {
dataSize = available;
}
memcpy(writePos, buf + info.offset, dataSize);
writePos += dataSize;
written += dataSize;
available -= dataSize;
media_status_t mstatus = AMediaCodec_releaseOutputBuffer(
codec, status, false /* render */);
if (mstatus != AMEDIA_OK) {
// AMEDIA_ERROR_UNKNOWN == { -ERANGE -EINVAL -EACCES }
ALOGE("AMediaCodec_releaseOutputBuffer returned status %d, short decode",
(int)mstatus);
break;
}
if (available == 0) {
// there might be more data, but there's no space for it
sawOutputEOS = true;
}
} else if (status == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
ALOGV("output buffers changed");
} else if (status == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
AMediaFormat_delete(format);
format = AMediaCodec_getOutputFormat(codec);
ALOGV("format changed to: %s", AMediaFormat_toString(format));
} else if (status == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
ALOGV("no output buffer right now");
} else if (status <= AMEDIA_ERROR_BASE) {
ALOGE("decode error: %d", status);
break;
} else {
ALOGV("unexpected info code: %d", status);
}
}
(void)AMediaCodec_stop(codec);
(void)AMediaCodec_delete(codec);
(void)AMediaExtractor_delete(ex);
if (!AMediaFormat_getInt32(format, AMEDIAFORMAT_KEY_SAMPLE_RATE, (int32_t*) rate) ||
!AMediaFormat_getInt32(format, AMEDIAFORMAT_KEY_CHANNEL_COUNT, numChannels)) {
(void)AMediaFormat_delete(format);
return UNKNOWN_ERROR;
}
if (!AMediaFormat_getInt32(format, AMEDIAFORMAT_KEY_CHANNEL_MASK,
(int32_t*) channelMask)) {
*channelMask = AUDIO_CHANNEL_NONE;
}
(void)AMediaFormat_delete(format);
*memsize = written;
return OK;
}
(void)AMediaFormat_delete(format);
}
(void)AMediaExtractor_delete(ex);
return UNKNOWN_ERROR;
}
status_t Sample::doLoad()
{
uint32_t sampleRate;
int numChannels;
audio_format_t format;
audio_channel_mask_t channelMask;
status_t status;
mHeap = new MemoryHeapBase(kDefaultHeapSize);
ALOGV("Start decode");
status = decode(mFd, mOffset, mLength, &sampleRate, &numChannels, &format,
&channelMask, mHeap, &mSize);
ALOGV("close(%d)", mFd);
::close(mFd);
mFd = -1;
if (status != NO_ERROR) {
ALOGE("Unable to load sample");
goto error;
}
ALOGV("pointer = %p, size = %zu, sampleRate = %u, numChannels = %d",
mHeap->getBase(), mSize, sampleRate, numChannels);
if (sampleRate > kMaxSampleRate) {
ALOGE("Sample rate (%u) out of range", sampleRate);
status = BAD_VALUE;
goto error;
}
if ((numChannels < 1) || (numChannels > FCC_8)) {
ALOGE("Sample channel count (%d) out of range", numChannels);
status = BAD_VALUE;
goto error;
}
mData = new MemoryBase(mHeap, 0, mSize);
mSampleRate = sampleRate;
mNumChannels = numChannels;
mFormat = format;
mChannelMask = channelMask;
mState = READY;
return NO_ERROR;
error:
mHeap.clear();
return status;
}
void SoundChannel::init(SoundPool* soundPool)
{
mSoundPool = soundPool;
mPrevSampleID = -1;
}
// call with sound pool lock held
void SoundChannel::play(const sp<Sample>& sample, int nextChannelID, float leftVolume,
float rightVolume, int priority, int loop, float rate)
{
sp<AudioTrack> oldTrack;
sp<AudioTrack> newTrack;
status_t status = NO_ERROR;
{ // scope for the lock
Mutex::Autolock lock(&mLock);
ALOGV("SoundChannel::play %p: sampleID=%d, channelID=%d, leftVolume=%f, rightVolume=%f,"
" priority=%d, loop=%d, rate=%f",
this, sample->sampleID(), nextChannelID, leftVolume, rightVolume,
priority, loop, rate);
// if not idle, this voice is being stolen
if (mState != IDLE) {
ALOGV("channel %d stolen - event queued for channel %d", channelID(), nextChannelID);
mNextEvent.set(sample, nextChannelID, leftVolume, rightVolume, priority, loop, rate);
stop_l();
return;
}
// initialize track
size_t afFrameCount;
uint32_t afSampleRate;
audio_stream_type_t streamType =
AudioSystem::attributesToStreamType(*mSoundPool->attributes());
if (AudioSystem::getOutputFrameCount(&afFrameCount, streamType) != NO_ERROR) {
afFrameCount = kDefaultFrameCount;
}
if (AudioSystem::getOutputSamplingRate(&afSampleRate, streamType) != NO_ERROR) {
afSampleRate = kDefaultSampleRate;
}
int numChannels = sample->numChannels();
uint32_t sampleRate = uint32_t(float(sample->sampleRate()) * rate + 0.5);
size_t frameCount = 0;
if (loop) {
const audio_format_t format = sample->format();
const size_t frameSize = audio_is_linear_pcm(format)
? numChannels * audio_bytes_per_sample(format) : 1;
frameCount = sample->size() / frameSize;
}
#ifndef USE_SHARED_MEM_BUFFER
uint32_t totalFrames = (kDefaultBufferCount * afFrameCount * sampleRate) / afSampleRate;
// Ensure minimum audio buffer size in case of short looped sample
if(frameCount < totalFrames) {
frameCount = totalFrames;
}
#endif
// check if the existing track has the same sample id.
if (mAudioTrack != 0 && mPrevSampleID == sample->sampleID()) {
// the sample rate may fail to change if the audio track is a fast track.
if (mAudioTrack->setSampleRate(sampleRate) == NO_ERROR) {
newTrack = mAudioTrack;
ALOGV("reusing track %p for sample %d", mAudioTrack.get(), sample->sampleID());
}
}
if (newTrack == 0) {
// mToggle toggles each time a track is started on a given channel.
// The toggle is concatenated with the SoundChannel address and passed to AudioTrack
// as callback user data. This enables the detection of callbacks received from the old
// audio track while the new one is being started and avoids processing them with
// wrong audio audio buffer size (mAudioBufferSize)
unsigned long toggle = mToggle ^ 1;
void *userData = (void *)((unsigned long)this | toggle);
audio_channel_mask_t sampleChannelMask = sample->channelMask();
// When sample contains a not none channel mask, use it as is.
// Otherwise, use channel count to calculate channel mask.
audio_channel_mask_t channelMask = sampleChannelMask != AUDIO_CHANNEL_NONE
? sampleChannelMask : audio_channel_out_mask_from_count(numChannels);
// do not create a new audio track if current track is compatible with sample parameters
#ifdef USE_SHARED_MEM_BUFFER
newTrack = new AudioTrack(streamType, sampleRate, sample->format(),
channelMask, sample->getIMemory(), AUDIO_OUTPUT_FLAG_FAST, callback, userData,
0 /*default notification frames*/, AUDIO_SESSION_ALLOCATE,
AudioTrack::TRANSFER_DEFAULT,
NULL /*offloadInfo*/, -1 /*uid*/, -1 /*pid*/, mSoundPool->attributes());
#else
uint32_t bufferFrames = (totalFrames + (kDefaultBufferCount - 1)) / kDefaultBufferCount;
newTrack = new AudioTrack(streamType, sampleRate, sample->format(),
channelMask, frameCount, AUDIO_OUTPUT_FLAG_FAST, callback, userData,
bufferFrames, AUDIO_SESSION_ALLOCATE, AudioTrack::TRANSFER_DEFAULT,
NULL /*offloadInfo*/, -1 /*uid*/, -1 /*pid*/, mSoundPool->attributes());
#endif
oldTrack = mAudioTrack;
status = newTrack->initCheck();
if (status != NO_ERROR) {
ALOGE("Error creating AudioTrack");
// newTrack goes out of scope, so reference count drops to zero
goto exit;
}
// From now on, AudioTrack callbacks received with previous toggle value will be ignored.
mToggle = toggle;
mAudioTrack = newTrack;
ALOGV("using new track %p for sample %d", newTrack.get(), sample->sampleID());
}
if (mMuted) {
newTrack->setVolume(0.0f, 0.0f);
} else {
newTrack->setVolume(leftVolume, rightVolume);
}
newTrack->setLoop(0, frameCount, loop);
mPos = 0;
mSample = sample;
mChannelID = nextChannelID;
mPriority = priority;
mLoop = loop;
mLeftVolume = leftVolume;
mRightVolume = rightVolume;
mNumChannels = numChannels;
mRate = rate;
clearNextEvent();
mState = PLAYING;
mAudioTrack->start();
mAudioBufferSize = newTrack->frameCount()*newTrack->frameSize();
}
exit:
ALOGV("delete oldTrack %p", oldTrack.get());
if (status != NO_ERROR) {
mAudioTrack.clear();
}
}
void SoundChannel::nextEvent()
{
sp<Sample> sample;
int nextChannelID;
float leftVolume;
float rightVolume;
int priority;
int loop;
float rate;
// check for valid event
{
Mutex::Autolock lock(&mLock);
nextChannelID = mNextEvent.channelID();
if (nextChannelID == 0) {
ALOGV("stolen channel has no event");
return;
}
sample = mNextEvent.sample();
leftVolume = mNextEvent.leftVolume();
rightVolume = mNextEvent.rightVolume();
priority = mNextEvent.priority();
loop = mNextEvent.loop();
rate = mNextEvent.rate();
}
ALOGV("Starting stolen channel %d -> %d", channelID(), nextChannelID);
play(sample, nextChannelID, leftVolume, rightVolume, priority, loop, rate);
}
void SoundChannel::callback(int event, void* user, void *info)
{
SoundChannel* channel = static_cast<SoundChannel*>((void *)((unsigned long)user & ~1));
channel->process(event, info, (unsigned long)user & 1);
}
void SoundChannel::process(int event, void *info, unsigned long toggle)
{
//ALOGV("process(%d)", mChannelID);
Mutex::Autolock lock(&mLock);
AudioTrack::Buffer* b = NULL;
if (event == AudioTrack::EVENT_MORE_DATA) {
b = static_cast<AudioTrack::Buffer *>(info);
}
if (mToggle != toggle) {
ALOGV("process wrong toggle %p channel %d", this, mChannelID);
if (b != NULL) {
b->size = 0;
}
return;
}
sp<Sample> sample = mSample;
// ALOGV("SoundChannel::process event %d", event);
if (event == AudioTrack::EVENT_MORE_DATA) {
// check for stop state
if (b->size == 0) return;
if (mState == IDLE) {
b->size = 0;
return;
}
if (sample != 0) {
// fill buffer
uint8_t* q = (uint8_t*) b->i8;
size_t count = 0;
if (mPos < (int)sample->size()) {
uint8_t* p = sample->data() + mPos;
count = sample->size() - mPos;
if (count > b->size) {
count = b->size;
}
memcpy(q, p, count);
// ALOGV("fill: q=%p, p=%p, mPos=%u, b->size=%u, count=%d", q, p, mPos, b->size,
// count);
} else if (mPos < mAudioBufferSize) {
count = mAudioBufferSize - mPos;
if (count > b->size) {
count = b->size;
}
memset(q, 0, count);
// ALOGV("fill extra: q=%p, mPos=%u, b->size=%u, count=%d", q, mPos, b->size, count);
}
mPos += count;
b->size = count;
//ALOGV("buffer=%p, [0]=%d", b->i16, b->i16[0]);
}
} else if (event == AudioTrack::EVENT_UNDERRUN || event == AudioTrack::EVENT_BUFFER_END) {
ALOGV("process %p channel %d event %s",
this, mChannelID, (event == AudioTrack::EVENT_UNDERRUN) ? "UNDERRUN" :
"BUFFER_END");
// Only BUFFER_END should happen as we use static tracks.
setVolume_l(0.f, 0.f); // set volume to 0 to indicate no need to ramp volume down.
mSoundPool->addToStopList(this);
} else if (event == AudioTrack::EVENT_LOOP_END) {
ALOGV("End loop %p channel %d", this, mChannelID);
} else if (event == AudioTrack::EVENT_NEW_IAUDIOTRACK) {
ALOGV("process %p channel %d NEW_IAUDIOTRACK", this, mChannelID);
} else {
ALOGW("SoundChannel::process unexpected event %d", event);
}
}
// call with lock held
bool SoundChannel::doStop_l()
{
if (mState != IDLE) {
ALOGV("stop");
if (mLeftVolume != 0.f || mRightVolume != 0.f) {
setVolume_l(0.f, 0.f);
if (mSoundPool->attributes()->usage != AUDIO_USAGE_GAME) {
// Since we're forcibly halting the previously playing content,
// we sleep here to ensure the volume is ramped down before we stop the track.
// Ideally the sleep time is the mixer period, or an approximation thereof
// (Fast vs Normal tracks are different).
ALOGV("sleeping: ChannelID:%d SampleID:%d", mChannelID, mSample->sampleID());
std::this_thread::sleep_for(std::chrono::milliseconds(20));
}
}
mAudioTrack->stop();
mPrevSampleID = mSample->sampleID();
mSample.clear();
mState = IDLE;
mPriority = IDLE_PRIORITY;
return true;
}
return false;
}
// call with lock held and sound pool lock held
void SoundChannel::stop_l()
{
if (doStop_l()) {
mSoundPool->done_l(this);
}
}
// call with sound pool lock held
void SoundChannel::stop()
{
bool stopped;
{
Mutex::Autolock lock(&mLock);
stopped = doStop_l();
}
if (stopped) {
mSoundPool->done_l(this);
}
}
//FIXME: Pause is a little broken right now
void SoundChannel::pause()
{
Mutex::Autolock lock(&mLock);
if (mState == PLAYING) {
ALOGV("pause track");
mState = PAUSED;
mAudioTrack->pause();
}
}
void SoundChannel::autoPause()
{
Mutex::Autolock lock(&mLock);
if (mState == PLAYING) {
ALOGV("pause track");
mState = PAUSED;
mAutoPaused = true;
mAudioTrack->pause();
}
}
void SoundChannel::resume()
{
Mutex::Autolock lock(&mLock);
if (mState == PAUSED) {
ALOGV("resume track");
mState = PLAYING;
mAutoPaused = false;
mAudioTrack->start();
}
}
void SoundChannel::autoResume()
{
Mutex::Autolock lock(&mLock);
if (mAutoPaused && (mState == PAUSED)) {
ALOGV("resume track");
mState = PLAYING;
mAutoPaused = false;
mAudioTrack->start();
}
}
void SoundChannel::setRate(float rate)
{
Mutex::Autolock lock(&mLock);
if (mAudioTrack != NULL && mSample != 0) {
uint32_t sampleRate = uint32_t(float(mSample->sampleRate()) * rate + 0.5);
mAudioTrack->setSampleRate(sampleRate);
mRate = rate;
}
}
// call with lock held
void SoundChannel::setVolume_l(float leftVolume, float rightVolume)
{
mLeftVolume = leftVolume;
mRightVolume = rightVolume;
if (mAudioTrack != NULL && !mMuted)
mAudioTrack->setVolume(leftVolume, rightVolume);
}
void SoundChannel::setVolume(float leftVolume, float rightVolume)
{
Mutex::Autolock lock(&mLock);
setVolume_l(leftVolume, rightVolume);
}
void SoundChannel::mute(bool muting)
{
Mutex::Autolock lock(&mLock);
mMuted = muting;
if (mAudioTrack != NULL) {
if (mMuted) {
mAudioTrack->setVolume(0.0f, 0.0f);
} else {
mAudioTrack->setVolume(mLeftVolume, mRightVolume);
}
}
}
void SoundChannel::setLoop(int loop)
{
Mutex::Autolock lock(&mLock);
if (mAudioTrack != NULL && mSample != 0) {
uint32_t loopEnd = mSample->size()/mNumChannels/
((mSample->format() == AUDIO_FORMAT_PCM_16_BIT) ? sizeof(int16_t) : sizeof(uint8_t));
mAudioTrack->setLoop(0, loopEnd, loop);
mLoop = loop;
}
}
SoundChannel::~SoundChannel()
{
ALOGV("SoundChannel destructor %p", this);
{
Mutex::Autolock lock(&mLock);
clearNextEvent();
doStop_l();
}
// do not call AudioTrack destructor with mLock held as it will wait for the AudioTrack
// callback thread to exit which may need to execute process() and acquire the mLock.
mAudioTrack.clear();
}
void SoundChannel::dump()
{
ALOGV("mState = %d mChannelID=%d, mNumChannels=%d, mPos = %d, mPriority=%d, mLoop=%d",
mState, mChannelID, mNumChannels, mPos, mPriority, mLoop);
}
void SoundEvent::set(const sp<Sample>& sample, int channelID, float leftVolume,
float rightVolume, int priority, int loop, float rate)
{
mSample = sample;
mChannelID = channelID;
mLeftVolume = leftVolume;
mRightVolume = rightVolume;
mPriority = priority;
mLoop = loop;
mRate =rate;
}
} // end namespace android