/* * Copyright (C) 2018 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_TAG "StreamOutHAL" #include "core/default/StreamOut.h" #include "core/default/Util.h" //#define LOG_NDEBUG 0 #define ATRACE_TAG ATRACE_TAG_AUDIO #include #include #include #include #include #include #include #include namespace android { namespace hardware { namespace audio { namespace CPP_VERSION { namespace implementation { using ::android::hardware::audio::common::COMMON_TYPES_CPP_VERSION::implementation::HidlUtils; using ::android::hardware::audio::CORE_TYPES_CPP_VERSION::implementation::CoreUtils; namespace util { using namespace ::android::hardware::audio::CORE_TYPES_CPP_VERSION::implementation::util; } namespace { class WriteThread : public Thread { public: // WriteThread's lifespan never exceeds StreamOut's lifespan. WriteThread(std::atomic* stop, audio_stream_out_t* stream, StreamOut::CommandMQ* commandMQ, StreamOut::DataMQ* dataMQ, StreamOut::StatusMQ* statusMQ, EventFlag* efGroup) : Thread(false /*canCallJava*/), mStop(stop), mStream(stream), mCommandMQ(commandMQ), mDataMQ(dataMQ), mStatusMQ(statusMQ), mEfGroup(efGroup), mBuffer(nullptr) {} bool init() { mBuffer.reset(new (std::nothrow) uint8_t[mDataMQ->getQuantumCount()]); return mBuffer != nullptr; } virtual ~WriteThread() {} private: std::atomic* mStop; audio_stream_out_t* mStream; StreamOut::CommandMQ* mCommandMQ; StreamOut::DataMQ* mDataMQ; StreamOut::StatusMQ* mStatusMQ; EventFlag* mEfGroup; std::unique_ptr mBuffer; IStreamOut::WriteStatus mStatus; bool threadLoop() override; void doGetLatency(); void doGetPresentationPosition(); void doWrite(); }; void WriteThread::doWrite() { const size_t availToRead = mDataMQ->availableToRead(); mStatus.retval = Result::OK; mStatus.reply.written = 0; if (mDataMQ->read(&mBuffer[0], availToRead)) { ssize_t writeResult = mStream->write(mStream, &mBuffer[0], availToRead); if (writeResult >= 0) { mStatus.reply.written = writeResult; } else { mStatus.retval = Stream::analyzeStatus("write", writeResult); } } } void WriteThread::doGetPresentationPosition() { mStatus.retval = StreamOut::getPresentationPositionImpl(mStream, &mStatus.reply.presentationPosition.frames, &mStatus.reply.presentationPosition.timeStamp); } void WriteThread::doGetLatency() { mStatus.retval = Result::OK; mStatus.reply.latencyMs = mStream->get_latency(mStream); } bool WriteThread::threadLoop() { // This implementation doesn't return control back to the Thread until it // decides to stop, // as the Thread uses mutexes, and this can lead to priority inversion. while (!std::atomic_load_explicit(mStop, std::memory_order_acquire)) { uint32_t efState = 0; mEfGroup->wait(static_cast(MessageQueueFlagBits::NOT_EMPTY), &efState); if (!(efState & static_cast(MessageQueueFlagBits::NOT_EMPTY))) { continue; // Nothing to do. } if (!mCommandMQ->read(&mStatus.replyTo)) { continue; // Nothing to do. } switch (mStatus.replyTo) { case IStreamOut::WriteCommand::WRITE: doWrite(); break; case IStreamOut::WriteCommand::GET_PRESENTATION_POSITION: doGetPresentationPosition(); break; case IStreamOut::WriteCommand::GET_LATENCY: doGetLatency(); break; default: ALOGE("Unknown write thread command code %d", mStatus.replyTo); mStatus.retval = Result::NOT_SUPPORTED; break; } if (!mStatusMQ->write(&mStatus)) { ALOGE("status message queue write failed"); } mEfGroup->wake(static_cast(MessageQueueFlagBits::NOT_FULL)); } return false; } } // namespace StreamOut::StreamOut(const sp& device, audio_stream_out_t* stream) : mDevice(device), mStream(stream), mStreamCommon(new Stream(false /*isInput*/, &stream->common)), mStreamMmap(new StreamMmap(stream)), mEfGroup(nullptr), mStopWriteThread(false) {} StreamOut::~StreamOut() { ATRACE_CALL(); (void)close(); if (mWriteThread.get()) { ATRACE_NAME("mWriteThread->join"); status_t status = mWriteThread->join(); ALOGE_IF(status, "write thread exit error: %s", strerror(-status)); } if (mEfGroup) { status_t status = EventFlag::deleteEventFlag(&mEfGroup); ALOGE_IF(status, "write MQ event flag deletion error: %s", strerror(-status)); } mCallback = nullptr; #if MAJOR_VERSION <= 5 mDevice->closeOutputStream(mStream); // Closing the output stream in the HAL waits for the callback to finish, // and joins the callback thread. Thus is it guaranteed that the callback // thread will not be accessing our object anymore. #endif mStream = nullptr; } // Methods from ::android::hardware::audio::CPP_VERSION::IStream follow. Return StreamOut::getFrameSize() { return audio_stream_out_frame_size(mStream); } Return StreamOut::getFrameCount() { return mStreamCommon->getFrameCount(); } Return StreamOut::getBufferSize() { return mStreamCommon->getBufferSize(); } #if MAJOR_VERSION <= 6 Return StreamOut::getSampleRate() { return mStreamCommon->getSampleRate(); } #if MAJOR_VERSION == 2 Return StreamOut::getSupportedChannelMasks(getSupportedChannelMasks_cb _hidl_cb) { return mStreamCommon->getSupportedChannelMasks(_hidl_cb); } Return StreamOut::getSupportedSampleRates(getSupportedSampleRates_cb _hidl_cb) { return mStreamCommon->getSupportedSampleRates(_hidl_cb); } #endif Return StreamOut::getSupportedChannelMasks(AudioFormat format, getSupportedChannelMasks_cb _hidl_cb) { return mStreamCommon->getSupportedChannelMasks(format, _hidl_cb); } Return StreamOut::getSupportedSampleRates(AudioFormat format, getSupportedSampleRates_cb _hidl_cb) { return mStreamCommon->getSupportedSampleRates(format, _hidl_cb); } Return StreamOut::setSampleRate(uint32_t sampleRateHz) { return mStreamCommon->setSampleRate(sampleRateHz); } Return StreamOut::getChannelMask() { return mStreamCommon->getChannelMask(); } Return StreamOut::setChannelMask(AudioChannelBitfield mask) { return mStreamCommon->setChannelMask(mask); } Return StreamOut::getFormat() { return mStreamCommon->getFormat(); } Return StreamOut::getSupportedFormats(getSupportedFormats_cb _hidl_cb) { return mStreamCommon->getSupportedFormats(_hidl_cb); } Return StreamOut::setFormat(AudioFormat format) { return mStreamCommon->setFormat(format); } #else Return StreamOut::getSupportedProfiles(getSupportedProfiles_cb _hidl_cb) { return mStreamCommon->getSupportedProfiles(_hidl_cb); } Return StreamOut::setAudioProperties(const AudioConfigBaseOptional& config) { return mStreamCommon->setAudioProperties(config); } #endif // MAJOR_VERSION <= 6 Return StreamOut::getAudioProperties(getAudioProperties_cb _hidl_cb) { return mStreamCommon->getAudioProperties(_hidl_cb); } Return StreamOut::addEffect(uint64_t effectId) { return mStreamCommon->addEffect(effectId); } Return StreamOut::removeEffect(uint64_t effectId) { return mStreamCommon->removeEffect(effectId); } Return StreamOut::standby() { return mStreamCommon->standby(); } Return StreamOut::setHwAvSync(uint32_t hwAvSync) { return mStreamCommon->setHwAvSync(hwAvSync); } #if MAJOR_VERSION == 2 Return StreamOut::setConnectedState(const DeviceAddress& address, bool connected) { return mStreamCommon->setConnectedState(address, connected); } Return StreamOut::getDevice() { return mStreamCommon->getDevice(); } Return StreamOut::setDevice(const DeviceAddress& address) { return mStreamCommon->setDevice(address); } Return StreamOut::getParameters(const hidl_vec& keys, getParameters_cb _hidl_cb) { return mStreamCommon->getParameters(keys, _hidl_cb); } Return StreamOut::setParameters(const hidl_vec& parameters) { return mStreamCommon->setParameters(parameters); } Return StreamOut::debugDump(const hidl_handle& fd) { return mStreamCommon->debugDump(fd); } #elif MAJOR_VERSION >= 4 Return StreamOut::getDevices(getDevices_cb _hidl_cb) { return mStreamCommon->getDevices(_hidl_cb); } Return StreamOut::setDevices(const hidl_vec& devices) { return mStreamCommon->setDevices(devices); } Return StreamOut::getParameters(const hidl_vec& context, const hidl_vec& keys, getParameters_cb _hidl_cb) { return mStreamCommon->getParameters(context, keys, _hidl_cb); } Return StreamOut::setParameters(const hidl_vec& context, const hidl_vec& parameters) { return mStreamCommon->setParameters(context, parameters); } #endif Return StreamOut::close() { if (mStopWriteThread.load(std::memory_order_relaxed)) { // only this thread writes return Result::INVALID_STATE; } mStopWriteThread.store(true, std::memory_order_release); if (mEfGroup) { mEfGroup->wake(static_cast(MessageQueueFlagBits::NOT_EMPTY)); } #if MAJOR_VERSION >= 6 mDevice->closeOutputStream(mStream); #endif return Result::OK; } // Methods from ::android::hardware::audio::CPP_VERSION::IStreamOut follow. Return StreamOut::getLatency() { return mStream->get_latency(mStream); } Return StreamOut::setVolume(float left, float right) { if (mStream->set_volume == NULL) { return Result::NOT_SUPPORTED; } if (!util::isGainNormalized(left)) { ALOGW("Can not set a stream output volume {%f, %f} outside [0,1]", left, right); return Result::INVALID_ARGUMENTS; } return Stream::analyzeStatus("set_volume", mStream->set_volume(mStream, left, right), {ENOSYS} /*ignore*/); } Return StreamOut::prepareForWriting(uint32_t frameSize, uint32_t framesCount, prepareForWriting_cb _hidl_cb) { status_t status; #if MAJOR_VERSION <= 6 ThreadInfo threadInfo = {0, 0}; #else int32_t threadInfo = 0; #endif // Wrap the _hidl_cb to return an error auto sendError = [&threadInfo, &_hidl_cb](Result result) { _hidl_cb(result, CommandMQ::Descriptor(), DataMQ::Descriptor(), StatusMQ::Descriptor(), threadInfo); }; // Create message queues. if (mDataMQ) { ALOGE("the client attempts to call prepareForWriting twice"); sendError(Result::INVALID_STATE); return Void(); } std::unique_ptr tempCommandMQ(new CommandMQ(1)); // Check frameSize and framesCount if (frameSize == 0 || framesCount == 0) { ALOGE("Null frameSize (%u) or framesCount (%u)", frameSize, framesCount); sendError(Result::INVALID_ARGUMENTS); return Void(); } if (frameSize > Stream::MAX_BUFFER_SIZE / framesCount) { ALOGE("Buffer too big: %u*%u bytes > MAX_BUFFER_SIZE (%u)", frameSize, framesCount, Stream::MAX_BUFFER_SIZE); sendError(Result::INVALID_ARGUMENTS); return Void(); } std::unique_ptr tempDataMQ(new DataMQ(frameSize * framesCount, true /* EventFlag */)); std::unique_ptr tempStatusMQ(new StatusMQ(1)); if (!tempCommandMQ->isValid() || !tempDataMQ->isValid() || !tempStatusMQ->isValid()) { ALOGE_IF(!tempCommandMQ->isValid(), "command MQ is invalid"); ALOGE_IF(!tempDataMQ->isValid(), "data MQ is invalid"); ALOGE_IF(!tempStatusMQ->isValid(), "status MQ is invalid"); sendError(Result::INVALID_ARGUMENTS); return Void(); } EventFlag* tempRawEfGroup{}; status = EventFlag::createEventFlag(tempDataMQ->getEventFlagWord(), &tempRawEfGroup); std::unique_ptr tempElfGroup( tempRawEfGroup, [](auto* ef) { EventFlag::deleteEventFlag(&ef); }); if (status != OK || !tempElfGroup) { ALOGE("failed creating event flag for data MQ: %s", strerror(-status)); sendError(Result::INVALID_ARGUMENTS); return Void(); } // Create and launch the thread. auto tempWriteThread = sp::make(&mStopWriteThread, mStream, tempCommandMQ.get(), tempDataMQ.get(), tempStatusMQ.get(), tempElfGroup.get()); if (!tempWriteThread->init()) { ALOGW("failed to start writer thread: %s", strerror(-status)); sendError(Result::INVALID_ARGUMENTS); return Void(); } status = tempWriteThread->run("writer", PRIORITY_URGENT_AUDIO); if (status != OK) { ALOGW("failed to start writer thread: %s", strerror(-status)); sendError(Result::INVALID_ARGUMENTS); return Void(); } mCommandMQ = std::move(tempCommandMQ); mDataMQ = std::move(tempDataMQ); mStatusMQ = std::move(tempStatusMQ); mWriteThread = tempWriteThread; mEfGroup = tempElfGroup.release(); #if MAJOR_VERSION <= 6 threadInfo.pid = getpid(); threadInfo.tid = mWriteThread->getTid(); #else threadInfo = mWriteThread->getTid(); #endif _hidl_cb(Result::OK, *mCommandMQ->getDesc(), *mDataMQ->getDesc(), *mStatusMQ->getDesc(), threadInfo); return Void(); } Return StreamOut::getRenderPosition(getRenderPosition_cb _hidl_cb) { uint32_t halDspFrames; Result retval = Stream::analyzeStatus("get_render_position", mStream->get_render_position(mStream, &halDspFrames), {ENOSYS} /*ignore*/); _hidl_cb(retval, halDspFrames); return Void(); } Return StreamOut::getNextWriteTimestamp(getNextWriteTimestamp_cb _hidl_cb) { Result retval(Result::NOT_SUPPORTED); int64_t timestampUs = 0; if (mStream->get_next_write_timestamp != NULL) { retval = Stream::analyzeStatus("get_next_write_timestamp", mStream->get_next_write_timestamp(mStream, ×tampUs), {ENOSYS} /*ignore*/); } _hidl_cb(retval, timestampUs); return Void(); } Return StreamOut::setCallback(const sp& callback) { if (mStream->set_callback == NULL) return Result::NOT_SUPPORTED; // Safe to pass 'this' because it is guaranteed that the callback thread // is joined prior to exit from StreamOut's destructor. int result = mStream->set_callback(mStream, StreamOut::asyncCallback, this); if (result == 0) { mCallback = callback; } return Stream::analyzeStatus("set_callback", result, {ENOSYS} /*ignore*/); } Return StreamOut::clearCallback() { if (mStream->set_callback == NULL) return Result::NOT_SUPPORTED; mCallback = nullptr; return Result::OK; } // static int StreamOut::asyncCallback(stream_callback_event_t event, void*, void* cookie) { // It is guaranteed that the callback thread is joined prior // to exiting from StreamOut's destructor. Must *not* use sp // here because it can make this code the last owner of StreamOut, // and an attempt to run the destructor on the callback thread // will cause a deadlock in the legacy HAL code. StreamOut* self = reinterpret_cast(cookie); // It's correct to hold an sp<> to callback because the reference // in the StreamOut instance can be cleared in the meantime. There is // no difference on which thread to run IStreamOutCallback's destructor. sp callback = self->mCallback.load(); if (callback.get() == nullptr) return 0; ALOGV("asyncCallback() event %d", event); Return result; switch (event) { case STREAM_CBK_EVENT_WRITE_READY: result = callback->onWriteReady(); break; case STREAM_CBK_EVENT_DRAIN_READY: result = callback->onDrainReady(); break; case STREAM_CBK_EVENT_ERROR: result = callback->onError(); break; default: ALOGW("asyncCallback() unknown event %d", event); break; } ALOGW_IF(!result.isOk(), "Client callback failed: %s", result.description().c_str()); return 0; } Return StreamOut::supportsPauseAndResume(supportsPauseAndResume_cb _hidl_cb) { _hidl_cb(mStream->pause != NULL, mStream->resume != NULL); return Void(); } Return StreamOut::pause() { return mStream->pause != NULL ? Stream::analyzeStatus("pause", mStream->pause(mStream), {ENOSYS} /*ignore*/) : Result::NOT_SUPPORTED; } Return StreamOut::resume() { return mStream->resume != NULL ? Stream::analyzeStatus("resume", mStream->resume(mStream), {ENOSYS} /*ignore*/) : Result::NOT_SUPPORTED; } Return StreamOut::supportsDrain() { return mStream->drain != NULL; } Return StreamOut::drain(AudioDrain type) { audio_drain_type_t halDrainType = type == AudioDrain::EARLY_NOTIFY ? AUDIO_DRAIN_EARLY_NOTIFY : AUDIO_DRAIN_ALL; return mStream->drain != NULL ? Stream::analyzeStatus("drain", mStream->drain(mStream, halDrainType), {ENOSYS} /*ignore*/) : Result::NOT_SUPPORTED; } Return StreamOut::flush() { return mStream->flush != NULL ? Stream::analyzeStatus("flush", mStream->flush(mStream), {ENOSYS} /*ignore*/) : Result::NOT_SUPPORTED; } // static Result StreamOut::getPresentationPositionImpl(audio_stream_out_t* stream, uint64_t* frames, TimeSpec* timeStamp) { // Don't logspam on EINVAL--it's normal for get_presentation_position // to return it sometimes. EAGAIN may be returned by A2DP audio HAL // implementation. ENODATA can also be reported while the writer is // continuously querying it, but the stream has been stopped. static const std::vector ignoredErrors{EINVAL, EAGAIN, ENODATA, ENOSYS}; Result retval(Result::NOT_SUPPORTED); if (stream->get_presentation_position == NULL) return retval; struct timespec halTimeStamp; retval = Stream::analyzeStatus("get_presentation_position", stream->get_presentation_position(stream, frames, &halTimeStamp), ignoredErrors); if (retval == Result::OK) { timeStamp->tvSec = halTimeStamp.tv_sec; timeStamp->tvNSec = halTimeStamp.tv_nsec; } return retval; } Return StreamOut::getPresentationPosition(getPresentationPosition_cb _hidl_cb) { uint64_t frames = 0; TimeSpec timeStamp = {0, 0}; Result retval = getPresentationPositionImpl(mStream, &frames, &timeStamp); _hidl_cb(retval, frames, timeStamp); return Void(); } Return StreamOut::start() { return mStreamMmap->start(); } Return StreamOut::stop() { return mStreamMmap->stop(); } Return StreamOut::createMmapBuffer(int32_t minSizeFrames, createMmapBuffer_cb _hidl_cb) { return mStreamMmap->createMmapBuffer(minSizeFrames, audio_stream_out_frame_size(mStream), _hidl_cb); } Return StreamOut::getMmapPosition(getMmapPosition_cb _hidl_cb) { return mStreamMmap->getMmapPosition(_hidl_cb); } Return StreamOut::debug(const hidl_handle& fd, const hidl_vec& options) { return mStreamCommon->debug(fd, options); } #if MAJOR_VERSION >= 4 Result StreamOut::doUpdateSourceMetadata(const SourceMetadata& sourceMetadata) { std::vector halTracks; #if MAJOR_VERSION <= 6 (void)CoreUtils::sourceMetadataToHal(sourceMetadata, &halTracks); #else // Validate whether a conversion to V7 is possible. This is needed // to have a consistent behavior of the HAL regardless of the API // version of the legacy HAL (and also to be consistent with openOutputStream). std::vector halTracksV7; if (status_t status = CoreUtils::sourceMetadataToHalV7( sourceMetadata, false /*ignoreNonVendorTags*/, &halTracksV7); status == NO_ERROR) { halTracks.reserve(halTracksV7.size()); for (auto metadata_v7 : halTracksV7) { halTracks.push_back(std::move(metadata_v7.base)); } } else { return Stream::analyzeStatus("sourceMetadataToHal", status); } #endif // MAJOR_VERSION <= 6 const source_metadata_t halMetadata = { .track_count = halTracks.size(), .tracks = halTracks.data(), }; mStream->update_source_metadata(mStream, &halMetadata); return Result::OK; } #if MAJOR_VERSION >= 7 Result StreamOut::doUpdateSourceMetadataV7(const SourceMetadata& sourceMetadata) { std::vector halTracks; if (status_t status = CoreUtils::sourceMetadataToHalV7( sourceMetadata, false /*ignoreNonVendorTags*/, &halTracks); status != NO_ERROR) { return Stream::analyzeStatus("sourceMetadataToHal", status); } const source_metadata_v7_t halMetadata = { .track_count = halTracks.size(), .tracks = halTracks.data(), }; mStream->update_source_metadata_v7(mStream, &halMetadata); return Result::OK; } #endif // MAJOR_VERSION >= 7 #if MAJOR_VERSION <= 6 Return StreamOut::updateSourceMetadata(const SourceMetadata& sourceMetadata) { if (mStream->update_source_metadata == nullptr) { return Void(); // not supported by the HAL } (void)doUpdateSourceMetadata(sourceMetadata); return Void(); } #elif MAJOR_VERSION >= 7 Return StreamOut::updateSourceMetadata(const SourceMetadata& sourceMetadata) { if (mDevice->version() < AUDIO_DEVICE_API_VERSION_3_2) { if (mStream->update_source_metadata == nullptr) { return Result::NOT_SUPPORTED; } return doUpdateSourceMetadata(sourceMetadata); } else { if (mStream->update_source_metadata_v7 == nullptr) { return Result::NOT_SUPPORTED; } return doUpdateSourceMetadataV7(sourceMetadata); } } #endif Return StreamOut::selectPresentation(int32_t /*presentationId*/, int32_t /*programId*/) { return Result::NOT_SUPPORTED; // TODO: propagate to legacy } #endif #if MAJOR_VERSION >= 6 Return StreamOut::getDualMonoMode(getDualMonoMode_cb _hidl_cb) { audio_dual_mono_mode_t mode = AUDIO_DUAL_MONO_MODE_OFF; Result retval = mStream->get_dual_mono_mode != nullptr ? Stream::analyzeStatus("get_dual_mono_mode", mStream->get_dual_mono_mode(mStream, &mode)) : Result::NOT_SUPPORTED; _hidl_cb(retval, DualMonoMode(mode)); return Void(); } Return StreamOut::setDualMonoMode(DualMonoMode mode) { return mStream->set_dual_mono_mode != nullptr ? Stream::analyzeStatus( "set_dual_mono_mode", mStream->set_dual_mono_mode(mStream, static_cast(mode))) : Result::NOT_SUPPORTED; } Return StreamOut::getAudioDescriptionMixLevel(getAudioDescriptionMixLevel_cb _hidl_cb) { float leveldB = -std::numeric_limits::infinity(); Result retval = mStream->get_audio_description_mix_level != nullptr ? Stream::analyzeStatus( "get_audio_description_mix_level", mStream->get_audio_description_mix_level(mStream, &leveldB)) : Result::NOT_SUPPORTED; _hidl_cb(retval, leveldB); return Void(); } Return StreamOut::setAudioDescriptionMixLevel(float leveldB) { return mStream->set_audio_description_mix_level != nullptr ? Stream::analyzeStatus( "set_audio_description_mix_level", mStream->set_audio_description_mix_level(mStream, leveldB)) : Result::NOT_SUPPORTED; } Return StreamOut::getPlaybackRateParameters(getPlaybackRateParameters_cb _hidl_cb) { audio_playback_rate_t rate = AUDIO_PLAYBACK_RATE_INITIALIZER; Result retval = mStream->get_playback_rate_parameters != nullptr ? Stream::analyzeStatus("get_playback_rate_parameters", mStream->get_playback_rate_parameters(mStream, &rate)) : Result::NOT_SUPPORTED; _hidl_cb(retval, PlaybackRate{rate.mSpeed, rate.mPitch, static_cast(rate.mStretchMode), static_cast(rate.mFallbackMode)}); return Void(); } Return StreamOut::setPlaybackRateParameters(const PlaybackRate& playbackRate) { audio_playback_rate_t rate = { playbackRate.speed, playbackRate.pitch, static_cast(playbackRate.timestretchMode), static_cast(playbackRate.fallbackMode)}; return mStream->set_playback_rate_parameters != nullptr ? Stream::analyzeStatus("set_playback_rate_parameters", mStream->set_playback_rate_parameters(mStream, &rate)) : Result::NOT_SUPPORTED; } Return StreamOut::setEventCallback(const sp& callback) { if (mStream->set_event_callback == nullptr) return Result::NOT_SUPPORTED; int result = mStream->set_event_callback(mStream, StreamOut::asyncEventCallback, this); if (result == 0) { mEventCallback = callback; } return Stream::analyzeStatus("set_stream_out_callback", result, {ENOSYS} /*ignore*/); } // static int StreamOut::asyncEventCallback(stream_event_callback_type_t event, void* param, void* cookie) { StreamOut* self = reinterpret_cast(cookie); sp eventCallback = self->mEventCallback.load(); if (eventCallback.get() == nullptr) return 0; ALOGV("%s event %d", __func__, event); Return result; switch (event) { case STREAM_EVENT_CBK_TYPE_CODEC_FORMAT_CHANGED: { hidl_vec audioMetadata; // void* param is the byte string buffer from byte_string_from_audio_metadata(). // As the byte string buffer may have embedded zeroes, we cannot use strlen() // but instead use audio_utils::metadata::dataByteStringLen(). audioMetadata.setToExternal((uint8_t*)param, audio_utils::metadata::dataByteStringLen( (const uint8_t*)param)); result = eventCallback->onCodecFormatChanged(audioMetadata); } break; default: ALOGW("%s unknown event %d", __func__, event); break; } ALOGW_IF(!result.isOk(), "Client callback failed: %s", result.description().c_str()); return 0; } #if MAJOR_VERSION == 7 && MINOR_VERSION == 1 Return StreamOut::setLatencyMode(LatencyMode mode) { return mStream->set_latency_mode != nullptr ? Stream::analyzeStatus( "set_latency_mode", mStream->set_latency_mode(mStream, static_cast(mode))) : Result::NOT_SUPPORTED; }; Return StreamOut::getRecommendedLatencyModes(getRecommendedLatencyModes_cb _hidl_cb) { Result retval = Result::NOT_SUPPORTED; hidl_vec hidlModes; size_t num_modes = AUDIO_LATENCY_MODE_CNT; audio_latency_mode_t modes[AUDIO_LATENCY_MODE_CNT]; if (mStream->get_recommended_latency_modes != nullptr && mStream->get_recommended_latency_modes(mStream, &modes[0], &num_modes) == 0) { if (num_modes == 0 || num_modes > AUDIO_LATENCY_MODE_CNT) { ALOGW("%s invalid number of modes returned: %zu", __func__, num_modes); retval = Result::INVALID_STATE; } else { hidlModes.resize(num_modes); for (size_t i = 0; i < num_modes; ++i) { hidlModes[i] = static_cast(modes[i]); } retval = Result::OK; } } _hidl_cb(retval, hidlModes); return Void(); }; // static void StreamOut::latencyModeCallback(audio_latency_mode_t* modes, size_t num_modes, void* cookie) { StreamOut* self = reinterpret_cast(cookie); sp callback = self->mLatencyModeCallback.load(); if (callback.get() == nullptr) return; ALOGV("%s", __func__); if (num_modes == 0 || num_modes > AUDIO_LATENCY_MODE_CNT) { ALOGW("%s invalid number of modes returned: %zu", __func__, num_modes); return; } hidl_vec hidlModes(num_modes); for (size_t i = 0; i < num_modes; ++i) { hidlModes[i] = static_cast(modes[i]); } Return result = callback->onRecommendedLatencyModeChanged(hidlModes); ALOGW_IF(!result.isOk(), "Client callback failed: %s", result.description().c_str()); } Return StreamOut::setLatencyModeCallback( const sp& callback) { if (mStream->set_latency_mode_callback == nullptr) return Result::NOT_SUPPORTED; int result = mStream->set_latency_mode_callback(mStream, StreamOut::latencyModeCallback, this); if (result == 0) { mLatencyModeCallback = callback; } return Stream::analyzeStatus("set_latency_mode_callback", result, {ENOSYS} /*ignore*/); }; #endif #endif } // namespace implementation } // namespace CPP_VERSION } // namespace audio } // namespace hardware } // namespace android