/* ** ** Copyright 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. */ //#define LOG_NDEBUG 0 #define LOG_TAG "AudioRecord" #include #include #include #include #include #include #define WAIT_PERIOD_MS 10 namespace android { // --------------------------------------------------------------------------- // static status_t AudioRecord::getMinFrameCount( size_t* frameCount, uint32_t sampleRate, audio_format_t format, audio_channel_mask_t channelMask) { if (frameCount == NULL) { return BAD_VALUE; } // default to 0 in case of error *frameCount = 0; size_t size = 0; status_t status = AudioSystem::getInputBufferSize(sampleRate, format, channelMask, &size); if (status != NO_ERROR) { ALOGE("AudioSystem could not query the input buffer size; status %d", status); return NO_INIT; } if (size == 0) { ALOGE("Unsupported configuration: sampleRate %u, format %d, channelMask %#x", sampleRate, format, channelMask); return BAD_VALUE; } // We double the size of input buffer for ping pong use of record buffer. size <<= 1; // Assumes audio_is_linear_pcm(format) uint32_t channelCount = popcount(channelMask); size /= channelCount * audio_bytes_per_sample(format); *frameCount = size; return NO_ERROR; } // --------------------------------------------------------------------------- AudioRecord::AudioRecord() : mStatus(NO_INIT), mSessionId(0), mPreviousPriority(ANDROID_PRIORITY_NORMAL), mPreviousSchedulingGroup(SP_DEFAULT) { } AudioRecord::AudioRecord( audio_source_t inputSource, uint32_t sampleRate, audio_format_t format, audio_channel_mask_t channelMask, int frameCount, callback_t cbf, void* user, int notificationFrames, int sessionId, transfer_type transferType, audio_input_flags_t flags) : mStatus(NO_INIT), mSessionId(0), mPreviousPriority(ANDROID_PRIORITY_NORMAL), mPreviousSchedulingGroup(SP_DEFAULT), mProxy(NULL) { mStatus = set(inputSource, sampleRate, format, channelMask, frameCount, cbf, user, notificationFrames, false /*threadCanCallJava*/, sessionId, transferType); } AudioRecord::~AudioRecord() { if (mStatus == NO_ERROR) { // Make sure that callback function exits in the case where // it is looping on buffer empty condition in obtainBuffer(). // Otherwise the callback thread will never exit. stop(); if (mAudioRecordThread != 0) { mProxy->interrupt(); mAudioRecordThread->requestExit(); // see comment in AudioRecord.h mAudioRecordThread->requestExitAndWait(); mAudioRecordThread.clear(); } if (mAudioRecord != 0) { mAudioRecord->asBinder()->unlinkToDeath(mDeathNotifier, this); mAudioRecord.clear(); } IPCThreadState::self()->flushCommands(); AudioSystem::releaseAudioSessionId(mSessionId); } } status_t AudioRecord::set( audio_source_t inputSource, uint32_t sampleRate, audio_format_t format, audio_channel_mask_t channelMask, int frameCountInt, callback_t cbf, void* user, int notificationFrames, bool threadCanCallJava, int sessionId, transfer_type transferType, audio_input_flags_t flags) { switch (transferType) { case TRANSFER_DEFAULT: if (cbf == NULL || threadCanCallJava) { transferType = TRANSFER_SYNC; } else { transferType = TRANSFER_CALLBACK; } break; case TRANSFER_CALLBACK: if (cbf == NULL) { ALOGE("Transfer type TRANSFER_CALLBACK but cbf == NULL"); return BAD_VALUE; } break; case TRANSFER_OBTAIN: case TRANSFER_SYNC: break; default: ALOGE("Invalid transfer type %d", transferType); return BAD_VALUE; } mTransfer = transferType; // FIXME "int" here is legacy and will be replaced by size_t later if (frameCountInt < 0) { ALOGE("Invalid frame count %d", frameCountInt); return BAD_VALUE; } size_t frameCount = frameCountInt; ALOGV("set(): sampleRate %u, channelMask %#x, frameCount %u", sampleRate, channelMask, frameCount); AutoMutex lock(mLock); if (mAudioRecord != 0) { ALOGE("Track already in use"); return INVALID_OPERATION; } if (inputSource == AUDIO_SOURCE_DEFAULT) { inputSource = AUDIO_SOURCE_MIC; } mInputSource = inputSource; if (sampleRate == 0) { ALOGE("Invalid sample rate %u", sampleRate); return BAD_VALUE; } mSampleRate = sampleRate; // these below should probably come from the audioFlinger too... if (format == AUDIO_FORMAT_DEFAULT) { format = AUDIO_FORMAT_PCM_16_BIT; } // validate parameters if (!audio_is_valid_format(format)) { ALOGE("Invalid format %d", format); return BAD_VALUE; } // Temporary restriction: AudioFlinger currently supports 16-bit PCM only if (format != AUDIO_FORMAT_PCM_16_BIT) { ALOGE("Format %d is not supported", format); return BAD_VALUE; } mFormat = format; if (!audio_is_input_channel(channelMask)) { ALOGE("Invalid channel mask %#x", channelMask); return BAD_VALUE; } mChannelMask = channelMask; uint32_t channelCount = popcount(channelMask); mChannelCount = channelCount; // Assumes audio_is_linear_pcm(format), else sizeof(uint8_t) mFrameSize = channelCount * audio_bytes_per_sample(format); // validate framecount size_t minFrameCount = 0; status_t status = AudioRecord::getMinFrameCount(&minFrameCount, sampleRate, format, channelMask); if (status != NO_ERROR) { ALOGE("getMinFrameCount() failed; status %d", status); return status; } ALOGV("AudioRecord::set() minFrameCount = %d", minFrameCount); if (frameCount == 0) { frameCount = minFrameCount; } else if (frameCount < minFrameCount) { ALOGE("frameCount %u < minFrameCount %u", frameCount, minFrameCount); return BAD_VALUE; } mFrameCount = frameCount; mNotificationFramesReq = notificationFrames; mNotificationFramesAct = 0; if (sessionId == 0 ) { mSessionId = AudioSystem::newAudioSessionId(); } else { mSessionId = sessionId; } ALOGV("set(): mSessionId %d", mSessionId); mFlags = flags; // create the IAudioRecord status = openRecord_l(0 /*epoch*/); if (status) { return status; } if (cbf != NULL) { mAudioRecordThread = new AudioRecordThread(*this, threadCanCallJava); mAudioRecordThread->run("AudioRecord", ANDROID_PRIORITY_AUDIO); } mStatus = NO_ERROR; // Update buffer size in case it has been limited by AudioFlinger during track creation mFrameCount = mCblk->frameCount_; mActive = false; mCbf = cbf; mRefreshRemaining = true; mUserData = user; // TODO: add audio hardware input latency here mLatency = (1000*mFrameCount) / sampleRate; mMarkerPosition = 0; mMarkerReached = false; mNewPosition = 0; mUpdatePeriod = 0; AudioSystem::acquireAudioSessionId(mSessionId); mSequence = 1; mObservedSequence = mSequence; mInOverrun = false; return NO_ERROR; } // ------------------------------------------------------------------------- status_t AudioRecord::start(AudioSystem::sync_event_t event, int triggerSession) { ALOGV("start, sync event %d trigger session %d", event, triggerSession); AutoMutex lock(mLock); if (mActive) { return NO_ERROR; } // reset current position as seen by client to 0 mProxy->setEpoch(mProxy->getEpoch() - mProxy->getPosition()); mNewPosition = mProxy->getPosition() + mUpdatePeriod; int32_t flags = android_atomic_acquire_load(&mCblk->mFlags); status_t status = NO_ERROR; if (!(flags & CBLK_INVALID)) { ALOGV("mAudioRecord->start()"); status = mAudioRecord->start(event, triggerSession); if (status == DEAD_OBJECT) { flags |= CBLK_INVALID; } } if (flags & CBLK_INVALID) { status = restoreRecord_l("start"); } if (status != NO_ERROR) { ALOGE("start() status %d", status); } else { mActive = true; sp t = mAudioRecordThread; if (t != 0) { t->resume(); } else { mPreviousPriority = getpriority(PRIO_PROCESS, 0); get_sched_policy(0, &mPreviousSchedulingGroup); androidSetThreadPriority(0, ANDROID_PRIORITY_AUDIO); } } return status; } void AudioRecord::stop() { AutoMutex lock(mLock); if (!mActive) { return; } mActive = false; mProxy->interrupt(); mAudioRecord->stop(); // the record head position will reset to 0, so if a marker is set, we need // to activate it again mMarkerReached = false; sp t = mAudioRecordThread; if (t != 0) { t->pause(); } else { setpriority(PRIO_PROCESS, 0, mPreviousPriority); set_sched_policy(0, mPreviousSchedulingGroup); } } bool AudioRecord::stopped() const { AutoMutex lock(mLock); return !mActive; } status_t AudioRecord::setMarkerPosition(uint32_t marker) { if (mCbf == NULL) { return INVALID_OPERATION; } AutoMutex lock(mLock); mMarkerPosition = marker; mMarkerReached = false; return NO_ERROR; } status_t AudioRecord::getMarkerPosition(uint32_t *marker) const { if (marker == NULL) { return BAD_VALUE; } AutoMutex lock(mLock); *marker = mMarkerPosition; return NO_ERROR; } status_t AudioRecord::setPositionUpdatePeriod(uint32_t updatePeriod) { if (mCbf == NULL) { return INVALID_OPERATION; } AutoMutex lock(mLock); mNewPosition = mProxy->getPosition() + updatePeriod; mUpdatePeriod = updatePeriod; return NO_ERROR; } status_t AudioRecord::getPositionUpdatePeriod(uint32_t *updatePeriod) const { if (updatePeriod == NULL) { return BAD_VALUE; } AutoMutex lock(mLock); *updatePeriod = mUpdatePeriod; return NO_ERROR; } status_t AudioRecord::getPosition(uint32_t *position) const { if (position == NULL) { return BAD_VALUE; } AutoMutex lock(mLock); *position = mProxy->getPosition(); return NO_ERROR; } unsigned int AudioRecord::getInputFramesLost() const { // no need to check mActive, because if inactive this will return 0, which is what we want return AudioSystem::getInputFramesLost(getInput()); } // ------------------------------------------------------------------------- // must be called with mLock held status_t AudioRecord::openRecord_l(size_t epoch) { status_t status; const sp& audioFlinger = AudioSystem::get_audio_flinger(); if (audioFlinger == 0) { ALOGE("Could not get audioflinger"); return NO_INIT; } IAudioFlinger::track_flags_t trackFlags = IAudioFlinger::TRACK_DEFAULT; pid_t tid = -1; // Client can only express a preference for FAST. Server will perform additional tests. // The only supported use case for FAST is callback transfer mode. if (mFlags & AUDIO_INPUT_FLAG_FAST) { if ((mTransfer != TRANSFER_CALLBACK) || (mAudioRecordThread == 0)) { ALOGW("AUDIO_INPUT_FLAG_FAST denied by client"); // once denied, do not request again if IAudioRecord is re-created mFlags = (audio_input_flags_t) (mFlags & ~AUDIO_INPUT_FLAG_FAST); } else { trackFlags |= IAudioFlinger::TRACK_FAST; tid = mAudioRecordThread->getTid(); } } mNotificationFramesAct = mNotificationFramesReq; if (!(mFlags & AUDIO_INPUT_FLAG_FAST)) { // Make sure that application is notified with sufficient margin before overrun if (mNotificationFramesAct == 0 || mNotificationFramesAct > mFrameCount/2) { mNotificationFramesAct = mFrameCount/2; } } audio_io_handle_t input = AudioSystem::getInput(mInputSource, mSampleRate, mFormat, mChannelMask, mSessionId); if (input == 0) { ALOGE("Could not get audio input for record source %d", mInputSource); return BAD_VALUE; } int originalSessionId = mSessionId; sp record = audioFlinger->openRecord(input, mSampleRate, mFormat, mChannelMask, mFrameCount, &trackFlags, tid, &mSessionId, &status); ALOGE_IF(originalSessionId != 0 && mSessionId != originalSessionId, "session ID changed from %d to %d", originalSessionId, mSessionId); if (record == 0 || status != NO_ERROR) { ALOGE("AudioFlinger could not create record track, status: %d", status); AudioSystem::releaseInput(input); return status; } sp iMem = record->getCblk(); if (iMem == 0) { ALOGE("Could not get control block"); return NO_INIT; } void *iMemPointer = iMem->pointer(); if (iMemPointer == NULL) { ALOGE("Could not get control block pointer"); return NO_INIT; } if (mAudioRecord != 0) { mAudioRecord->asBinder()->unlinkToDeath(mDeathNotifier, this); mDeathNotifier.clear(); } mInput = input; mAudioRecord = record; mCblkMemory = iMem; audio_track_cblk_t* cblk = static_cast(iMemPointer); mCblk = cblk; // FIXME missing fast track frameCount logic mAwaitBoost = false; if (mFlags & AUDIO_INPUT_FLAG_FAST) { if (trackFlags & IAudioFlinger::TRACK_FAST) { ALOGV("AUDIO_INPUT_FLAG_FAST successful; frameCount %u", mFrameCount); mAwaitBoost = true; // double-buffering is not required for fast tracks, due to tighter scheduling if (mNotificationFramesAct == 0 || mNotificationFramesAct > mFrameCount) { mNotificationFramesAct = mFrameCount; } } else { ALOGV("AUDIO_INPUT_FLAG_FAST denied by server; frameCount %u", mFrameCount); // once denied, do not request again if IAudioRecord is re-created mFlags = (audio_input_flags_t) (mFlags & ~AUDIO_INPUT_FLAG_FAST); if (mNotificationFramesAct == 0 || mNotificationFramesAct > mFrameCount/2) { mNotificationFramesAct = mFrameCount/2; } } } // starting address of buffers in shared memory void *buffers = (char*)cblk + sizeof(audio_track_cblk_t); // update proxy mProxy = new AudioRecordClientProxy(cblk, buffers, mFrameCount, mFrameSize); mProxy->setEpoch(epoch); mProxy->setMinimum(mNotificationFramesAct); mDeathNotifier = new DeathNotifier(this); mAudioRecord->asBinder()->linkToDeath(mDeathNotifier, this); return NO_ERROR; } status_t AudioRecord::obtainBuffer(Buffer* audioBuffer, int32_t waitCount) { if (audioBuffer == NULL) { return BAD_VALUE; } if (mTransfer != TRANSFER_OBTAIN) { audioBuffer->frameCount = 0; audioBuffer->size = 0; audioBuffer->raw = NULL; return INVALID_OPERATION; } const struct timespec *requested; struct timespec timeout; if (waitCount == -1) { requested = &ClientProxy::kForever; } else if (waitCount == 0) { requested = &ClientProxy::kNonBlocking; } else if (waitCount > 0) { long long ms = WAIT_PERIOD_MS * (long long) waitCount; timeout.tv_sec = ms / 1000; timeout.tv_nsec = (int) (ms % 1000) * 1000000; requested = &timeout; } else { ALOGE("%s invalid waitCount %d", __func__, waitCount); requested = NULL; } return obtainBuffer(audioBuffer, requested); } status_t AudioRecord::obtainBuffer(Buffer* audioBuffer, const struct timespec *requested, struct timespec *elapsed, size_t *nonContig) { // previous and new IAudioRecord sequence numbers are used to detect track re-creation uint32_t oldSequence = 0; uint32_t newSequence; Proxy::Buffer buffer; status_t status = NO_ERROR; static const int32_t kMaxTries = 5; int32_t tryCounter = kMaxTries; do { // obtainBuffer() is called with mutex unlocked, so keep extra references to these fields to // keep them from going away if another thread re-creates the track during obtainBuffer() sp proxy; sp iMem; { // start of lock scope AutoMutex lock(mLock); newSequence = mSequence; // did previous obtainBuffer() fail due to media server death or voluntary invalidation? if (status == DEAD_OBJECT) { // re-create track, unless someone else has already done so if (newSequence == oldSequence) { status = restoreRecord_l("obtainBuffer"); if (status != NO_ERROR) { break; } } } oldSequence = newSequence; // Keep the extra references proxy = mProxy; iMem = mCblkMemory; // Non-blocking if track is stopped if (!mActive) { requested = &ClientProxy::kNonBlocking; } } // end of lock scope buffer.mFrameCount = audioBuffer->frameCount; // FIXME starts the requested timeout and elapsed over from scratch status = proxy->obtainBuffer(&buffer, requested, elapsed); } while ((status == DEAD_OBJECT) && (tryCounter-- > 0)); audioBuffer->frameCount = buffer.mFrameCount; audioBuffer->size = buffer.mFrameCount * mFrameSize; audioBuffer->raw = buffer.mRaw; if (nonContig != NULL) { *nonContig = buffer.mNonContig; } return status; } void AudioRecord::releaseBuffer(Buffer* audioBuffer) { // all TRANSFER_* are valid size_t stepCount = audioBuffer->size / mFrameSize; if (stepCount == 0) { return; } Proxy::Buffer buffer; buffer.mFrameCount = stepCount; buffer.mRaw = audioBuffer->raw; AutoMutex lock(mLock); mInOverrun = false; mProxy->releaseBuffer(&buffer); // the server does not automatically disable recorder on overrun, so no need to restart } audio_io_handle_t AudioRecord::getInput() const { AutoMutex lock(mLock); return mInput; } // ------------------------------------------------------------------------- ssize_t AudioRecord::read(void* buffer, size_t userSize) { if (mTransfer != TRANSFER_SYNC) { return INVALID_OPERATION; } if (ssize_t(userSize) < 0 || (buffer == NULL && userSize != 0)) { // sanity-check. user is most-likely passing an error code, and it would // make the return value ambiguous (actualSize vs error). ALOGE("AudioRecord::read(buffer=%p, size=%u (%d)", buffer, userSize, userSize); return BAD_VALUE; } ssize_t read = 0; Buffer audioBuffer; while (userSize >= mFrameSize) { audioBuffer.frameCount = userSize / mFrameSize; status_t err = obtainBuffer(&audioBuffer, &ClientProxy::kForever); if (err < 0) { if (read > 0) { break; } return ssize_t(err); } size_t bytesRead = audioBuffer.size; memcpy(buffer, audioBuffer.i8, bytesRead); buffer = ((char *) buffer) + bytesRead; userSize -= bytesRead; read += bytesRead; releaseBuffer(&audioBuffer); } return read; } // ------------------------------------------------------------------------- nsecs_t AudioRecord::processAudioBuffer(const sp& thread) { mLock.lock(); if (mAwaitBoost) { mAwaitBoost = false; mLock.unlock(); static const int32_t kMaxTries = 5; int32_t tryCounter = kMaxTries; uint32_t pollUs = 10000; do { int policy = sched_getscheduler(0); if (policy == SCHED_FIFO || policy == SCHED_RR) { break; } usleep(pollUs); pollUs <<= 1; } while (tryCounter-- > 0); if (tryCounter < 0) { ALOGE("did not receive expected priority boost on time"); } // Run again immediately return 0; } // Can only reference mCblk while locked int32_t flags = android_atomic_and(~CBLK_OVERRUN, &mCblk->mFlags); // Check for track invalidation if (flags & CBLK_INVALID) { (void) restoreRecord_l("processAudioBuffer"); mLock.unlock(); // Run again immediately, but with a new IAudioRecord return 0; } bool active = mActive; // Manage overrun callback, must be done under lock to avoid race with releaseBuffer() bool newOverrun = false; if (flags & CBLK_OVERRUN) { if (!mInOverrun) { mInOverrun = true; newOverrun = true; } } // Get current position of server size_t position = mProxy->getPosition(); // Manage marker callback bool markerReached = false; size_t markerPosition = mMarkerPosition; // FIXME fails for wraparound, need 64 bits if (!mMarkerReached && (markerPosition > 0) && (position >= markerPosition)) { mMarkerReached = markerReached = true; } // Determine the number of new position callback(s) that will be needed, while locked size_t newPosCount = 0; size_t newPosition = mNewPosition; uint32_t updatePeriod = mUpdatePeriod; // FIXME fails for wraparound, need 64 bits if (updatePeriod > 0 && position >= newPosition) { newPosCount = ((position - newPosition) / updatePeriod) + 1; mNewPosition += updatePeriod * newPosCount; } // Cache other fields that will be needed soon size_t notificationFrames = mNotificationFramesAct; if (mRefreshRemaining) { mRefreshRemaining = false; mRemainingFrames = notificationFrames; mRetryOnPartialBuffer = false; } size_t misalignment = mProxy->getMisalignment(); int32_t sequence = mSequence; // These fields don't need to be cached, because they are assigned only by set(): // mTransfer, mCbf, mUserData, mSampleRate mLock.unlock(); // perform callbacks while unlocked if (newOverrun) { mCbf(EVENT_OVERRUN, mUserData, NULL); } if (markerReached) { mCbf(EVENT_MARKER, mUserData, &markerPosition); } while (newPosCount > 0) { size_t temp = newPosition; mCbf(EVENT_NEW_POS, mUserData, &temp); newPosition += updatePeriod; newPosCount--; } if (mObservedSequence != sequence) { mObservedSequence = sequence; mCbf(EVENT_NEW_IAUDIORECORD, mUserData, NULL); } // if inactive, then don't run me again until re-started if (!active) { return NS_INACTIVE; } // Compute the estimated time until the next timed event (position, markers) uint32_t minFrames = ~0; if (!markerReached && position < markerPosition) { minFrames = markerPosition - position; } if (updatePeriod > 0 && updatePeriod < minFrames) { minFrames = updatePeriod; } // If > 0, poll periodically to recover from a stuck server. A good value is 2. static const uint32_t kPoll = 0; if (kPoll > 0 && mTransfer == TRANSFER_CALLBACK && kPoll * notificationFrames < minFrames) { minFrames = kPoll * notificationFrames; } // Convert frame units to time units nsecs_t ns = NS_WHENEVER; if (minFrames != (uint32_t) ~0) { // This "fudge factor" avoids soaking CPU, and compensates for late progress by server static const nsecs_t kFudgeNs = 10000000LL; // 10 ms ns = ((minFrames * 1000000000LL) / mSampleRate) + kFudgeNs; } // If not supplying data by EVENT_MORE_DATA, then we're done if (mTransfer != TRANSFER_CALLBACK) { return ns; } struct timespec timeout; const struct timespec *requested = &ClientProxy::kForever; if (ns != NS_WHENEVER) { timeout.tv_sec = ns / 1000000000LL; timeout.tv_nsec = ns % 1000000000LL; ALOGV("timeout %ld.%03d", timeout.tv_sec, (int) timeout.tv_nsec / 1000000); requested = &timeout; } while (mRemainingFrames > 0) { Buffer audioBuffer; audioBuffer.frameCount = mRemainingFrames; size_t nonContig; status_t err = obtainBuffer(&audioBuffer, requested, NULL, &nonContig); LOG_ALWAYS_FATAL_IF((err != NO_ERROR) != (audioBuffer.frameCount == 0), "obtainBuffer() err=%d frameCount=%u", err, audioBuffer.frameCount); requested = &ClientProxy::kNonBlocking; size_t avail = audioBuffer.frameCount + nonContig; ALOGV("obtainBuffer(%u) returned %u = %u + %u", mRemainingFrames, avail, audioBuffer.frameCount, nonContig); if (err != NO_ERROR) { if (err == TIMED_OUT || err == WOULD_BLOCK || err == -EINTR) { break; } ALOGE("Error %d obtaining an audio buffer, giving up.", err); return NS_NEVER; } if (mRetryOnPartialBuffer) { mRetryOnPartialBuffer = false; if (avail < mRemainingFrames) { int64_t myns = ((mRemainingFrames - avail) * 1100000000LL) / mSampleRate; if (ns < 0 || myns < ns) { ns = myns; } return ns; } } size_t reqSize = audioBuffer.size; mCbf(EVENT_MORE_DATA, mUserData, &audioBuffer); size_t readSize = audioBuffer.size; // Sanity check on returned size if (ssize_t(readSize) < 0 || readSize > reqSize) { ALOGE("EVENT_MORE_DATA requested %u bytes but callback returned %d bytes", reqSize, (int) readSize); return NS_NEVER; } if (readSize == 0) { // The callback is done consuming buffers // Keep this thread going to handle timed events and // still try to provide more data in intervals of WAIT_PERIOD_MS // but don't just loop and block the CPU, so wait return WAIT_PERIOD_MS * 1000000LL; } size_t releasedFrames = readSize / mFrameSize; audioBuffer.frameCount = releasedFrames; mRemainingFrames -= releasedFrames; if (misalignment >= releasedFrames) { misalignment -= releasedFrames; } else { misalignment = 0; } releaseBuffer(&audioBuffer); // FIXME here is where we would repeat EVENT_MORE_DATA again on same advanced buffer // if callback doesn't like to accept the full chunk if (readSize < reqSize) { continue; } // There could be enough non-contiguous frames available to satisfy the remaining request if (mRemainingFrames <= nonContig) { continue; } #if 0 // This heuristic tries to collapse a series of EVENT_MORE_DATA that would total to a // sum <= notificationFrames. It replaces that series by at most two EVENT_MORE_DATA // that total to a sum == notificationFrames. if (0 < misalignment && misalignment <= mRemainingFrames) { mRemainingFrames = misalignment; return (mRemainingFrames * 1100000000LL) / mSampleRate; } #endif } mRemainingFrames = notificationFrames; mRetryOnPartialBuffer = true; // A lot has transpired since ns was calculated, so run again immediately and re-calculate return 0; } status_t AudioRecord::restoreRecord_l(const char *from) { ALOGW("dead IAudioRecord, creating a new one from %s()", from); ++mSequence; status_t result; // if the new IAudioRecord is created, openRecord_l() will modify the // following member variables: mAudioRecord, mCblkMemory and mCblk. // It will also delete the strong references on previous IAudioRecord and IMemory size_t position = mProxy->getPosition(); mNewPosition = position + mUpdatePeriod; result = openRecord_l(position); if (result == NO_ERROR) { if (mActive) { // callback thread or sync event hasn't changed // FIXME this fails if we have a new AudioFlinger instance result = mAudioRecord->start(AudioSystem::SYNC_EVENT_SAME, 0); } } if (result != NO_ERROR) { ALOGW("restoreRecord_l() failed status %d", result); mActive = false; } return result; } // ========================================================================= void AudioRecord::DeathNotifier::binderDied(const wp& who) { sp audioRecord = mAudioRecord.promote(); if (audioRecord != 0) { AutoMutex lock(audioRecord->mLock); audioRecord->mProxy->binderDied(); } } // ========================================================================= AudioRecord::AudioRecordThread::AudioRecordThread(AudioRecord& receiver, bool bCanCallJava) : Thread(bCanCallJava), mReceiver(receiver), mPaused(true), mPausedInt(false), mPausedNs(0LL) { } AudioRecord::AudioRecordThread::~AudioRecordThread() { } bool AudioRecord::AudioRecordThread::threadLoop() { { AutoMutex _l(mMyLock); if (mPaused) { mMyCond.wait(mMyLock); // caller will check for exitPending() return true; } if (mPausedInt) { if (mPausedNs > 0) { (void) mMyCond.waitRelative(mMyLock, mPausedNs); } else { mMyCond.wait(mMyLock); } mPausedInt = false; return true; } } nsecs_t ns = mReceiver.processAudioBuffer(this); switch (ns) { case 0: return true; case NS_INACTIVE: pauseInternal(); return true; case NS_NEVER: return false; case NS_WHENEVER: // FIXME increase poll interval, or make event-driven ns = 1000000000LL; // fall through default: LOG_ALWAYS_FATAL_IF(ns < 0, "processAudioBuffer() returned %lld", ns); pauseInternal(ns); return true; } } void AudioRecord::AudioRecordThread::requestExit() { // must be in this order to avoid a race condition Thread::requestExit(); AutoMutex _l(mMyLock); if (mPaused || mPausedInt) { mPaused = false; mPausedInt = false; mMyCond.signal(); } } void AudioRecord::AudioRecordThread::pause() { AutoMutex _l(mMyLock); mPaused = true; } void AudioRecord::AudioRecordThread::resume() { AutoMutex _l(mMyLock); if (mPaused || mPausedInt) { mPaused = false; mPausedInt = false; mMyCond.signal(); } } void AudioRecord::AudioRecordThread::pauseInternal(nsecs_t ns) { AutoMutex _l(mMyLock); mPausedInt = true; mPausedNs = ns; } // ------------------------------------------------------------------------- }; // namespace android