// Copyright (c) 2017-2022, Mudita Sp. z.o.o. All rights reserved.
// For licensing, see https://github.com/mudita/MuditaOS/LICENSE.md
#include "DecoderWorker.hpp"
#include <Audio/AbstractStream.hpp>
#include <Audio/decoder/Decoder.hpp>
audio::DecoderWorker::DecoderWorker(audio::AbstractStream *audioStreamOut,
Decoder *decoder,
EndOfFileCallback endOfFileCallback,
ChannelMode mode)
: sys::Worker(DecoderWorker::workerName, DecoderWorker::workerPriority, stackDepth), audioStreamOut(audioStreamOut),
decoder(decoder), endOfFileCallback(std::move(endOfFileCallback)),
bufferSize(audioStreamOut->getInputTraits().blockSize / sizeof(BufferInternalType)), channelMode(mode)
{}
audio::DecoderWorker::~DecoderWorker()
{
audioStreamOut->unregisterListeners(queueListener.get());
}
auto audio::DecoderWorker::init(std::list<sys::WorkerQueueInfo> queues) -> bool
{
std::list<sys::WorkerQueueInfo> list{
{listenerQueueName, StreamQueuedEventsListener::listenerElementSize, listenerQueueCapacity}};
auto isSuccessful = Worker::init(list);
queueListener = std::make_unique<StreamQueuedEventsListener>(getQueueByName(listenerQueueName));
if (!queueListener) {
return false;
}
audioStreamOut->registerListener(queueListener.get());
decoderBuffer = std::make_unique<BufferInternalType[]>(bufferSize);
if (!decoderBuffer) {
return false;
}
return isSuccessful;
}
bool audio::DecoderWorker::handleMessage(uint32_t queueID)
{
auto queue = queues[queueID];
auto &queueName = queue->GetQueueName();
if (queueName == listenerQueueName && queueListener) {
auto event = queueListener->getEvent();
switch (event.second) {
case Stream::Event::StreamOverflow:
break;
case Stream::Event::StreamUnderFlow:
break;
case Stream::Event::NoEvent:
break;
case Stream::Event::StreamFull:
break;
case Stream::Event::StreamHalfUsed:
[[fallthrough]];
case Stream::Event::StreamEmpty:
pushAudioData();
}
}
else if (queueName == SERVICE_QUEUE_NAME) {
auto &serviceQueue = getServiceQueue();
sys::WorkerCommand cmd;
if (serviceQueue.Dequeue(&cmd)) {
switch (static_cast<Command>(cmd.command)) {
case Command::EnablePlayback: {
playbackEnabled = true;
stateSemaphore.Give();
pushAudioData();
break;
}
case Command::DisablePlayback: {
playbackEnabled = false;
stateSemaphore.Give();
}
}
}
}
return true;
}
void audio::DecoderWorker::pushAudioData()
{
auto samplesRead = 0;
const unsigned int readScale = channelMode == ChannelMode::ForceStereo ? 2 : 1;
while (!audioStreamOut->isFull() && playbackEnabled) {
auto buffer = decoderBuffer.get();
samplesRead = decoder->decode(bufferSize / readScale, buffer);
if (samplesRead == 0) {
endOfFileCallback();
break;
}
// pcm mono to stereo force conversion
if (channelMode == ChannelMode::ForceStereo) {
for (unsigned int i = bufferSize / 2; i > 0; i--) {
buffer[i * 2 - 1] = buffer[i * 2 - 2] = buffer[i - 1];
}
}
if (!audioStreamOut->push(decoderBuffer.get(), samplesRead * sizeof(BufferInternalType) * readScale)) {
LOG_FATAL("Decoder failed to push to stream.");
break;
}
}
}
bool audio::DecoderWorker::enablePlayback()
{
return sendCommand({.command = static_cast<uint32_t>(Command::EnablePlayback), .data = nullptr}) &&
stateChangeWait();
}
bool audio::DecoderWorker::disablePlayback()
{
return sendCommand({.command = static_cast<uint32_t>(Command::DisablePlayback), .data = nullptr}) &&
stateChangeWait();
}
bool audio::DecoderWorker::stateChangeWait()
{
return stateSemaphore.Take();
}