#include "FFmpegDecoderAudio.hpp" #include #include #include //DEBUG //#include namespace osgFFmpeg { FFmpegDecoderAudio::FFmpegDecoderAudio(PacketQueue & packets, FFmpegClocks & clocks) : m_packets(packets), m_clocks(clocks), m_stream(0), m_context(0), m_packet_data(0), m_bytes_remaining(0), m_audio_buffer((AVCODEC_MAX_AUDIO_FRAME_SIZE * 3) / 2), m_audio_buf_size(0), m_audio_buf_index(0), m_end_of_stream(false), m_paused(true), m_exit(false) { } FFmpegDecoderAudio::~FFmpegDecoderAudio() { if (isRunning()) { m_exit = true; #if 0 while(isRunning()) { OpenThreads::YieldCurrentThread(); } #else join(); #endif } } void FFmpegDecoderAudio::open(AVStream * const stream) { try { // Sound can be optional (i.e. no audio stream is present) if (stream == 0) return; m_stream = stream; m_context = stream->codec; m_frequency = m_context->sample_rate; m_nb_channels = m_context->channels; m_sample_format = osg::AudioStream::SampleFormat(m_context->sample_fmt); // Check stream sanity if (m_context->codec_id == CODEC_ID_NONE) throw std::runtime_error("invalid audio codec");; // Find the decoder for the audio stream AVCodec * const p_codec = avcodec_find_decoder(m_context->codec_id); if (p_codec == 0) throw std::runtime_error("avcodec_find_decoder() failed"); // Inform the codec that we can handle truncated bitstreams //if (p_codec->capabilities & CODEC_CAP_TRUNCATED) // m_context->flags |= CODEC_FLAG_TRUNCATED; // Open codec if (avcodec_open(m_context, p_codec) < 0) throw std::runtime_error("avcodec_open() failed"); } catch (...) { m_context = 0; throw; } } void FFmpegDecoderAudio::pause(bool pause) { if(pause) m_paused = true; else m_paused = false; } void FFmpegDecoderAudio::close(bool waitForThreadToExit) { m_exit = true; if (isRunning() && waitForThreadToExit) { while(isRunning()) { OpenThreads::Thread::YieldCurrentThread(); } } } void FFmpegDecoderAudio::run() { try { decodeLoop(); } catch (const std::exception & error) { osg::notify(osg::WARN) << "FFmpegDecoderAudio::run : " << error.what() << std::endl; } catch (...) { osg::notify(osg::WARN) << "FFmpegDecoderAudio::run : unhandled exception" << std::endl; } } void FFmpegDecoderAudio::setAudioSink(osg::ref_ptr audio_sink) { // The FFmpegDecoderAudio object takes the responsability of destroying the audio_sink. osg::notify(osg::NOTICE)<<"Assigning "<(buffer); while (size != 0) { if (m_audio_buf_index == m_audio_buf_size) { m_audio_buf_index = 0; // Pre-fetch audio buffer is empty, refill it. const size_t bytes_decoded = decodeFrame(&m_audio_buffer[0], m_audio_buffer.size()); // If nothing could be decoded (e.g. error or no packet available), output a bit of silence if (bytes_decoded == 0) { m_audio_buf_size = std::min(Buffer::size_type(1024), m_audio_buffer.size()); memset(&m_audio_buffer[0], 0, m_audio_buf_size); } else { m_audio_buf_size = bytes_decoded; } } const size_t fill_size = std::min(m_audio_buf_size - m_audio_buf_index, size); memcpy(dst_buffer, &m_audio_buffer[m_audio_buf_index], fill_size); size -= fill_size; dst_buffer += fill_size; m_audio_buf_index += fill_size; adjustBufferEndTps(fill_size); } } void FFmpegDecoderAudio::decodeLoop() { const bool skip_audio = ! validContext() || ! m_audio_sink.valid(); if (! skip_audio && ! m_audio_sink->playing()) { m_clocks.audioSetDelay(m_audio_sink->getDelay()); m_audio_sink->startPlaying(); } else { m_clocks.audioDisable(); } while (! m_exit) { if(m_paused) { m_clocks.pause(true); m_pause_timer.setStartTick(); while(m_paused) { microSleep(10000); } m_clocks.setPauseTime(m_pause_timer.time_s()); m_clocks.pause(false); } // If skipping audio, make sure the audio stream is still consumed. if (skip_audio) { bool is_empty; FFmpegPacket packet = m_packets.timedPop(is_empty, 10); if (packet.valid()) packet.clear(); } // Else, just idle in this thread. // Note: If m_audio_sink has an audio callback, this thread will still be awaken // from time to time to refill the audio buffer. else { OpenThreads::Thread::microSleep(10000); } } } void FFmpegDecoderAudio::adjustBufferEndTps(const size_t buffer_size) { int sample_size = nbChannels() * frequency(); switch (sampleFormat()) { case osg::AudioStream::SAMPLE_FORMAT_U8: sample_size *= 1; break; case osg::AudioStream::SAMPLE_FORMAT_S16: sample_size *= 2; break; case osg::AudioStream::SAMPLE_FORMAT_S24: sample_size *= 3; break; case osg::AudioStream::SAMPLE_FORMAT_S32: sample_size *= 4; break; case osg::AudioStream::SAMPLE_FORMAT_F32: sample_size *= 4; break; default: throw std::runtime_error("unsupported audio sample format"); } m_clocks.audioAdjustBufferEndPts(double(buffer_size) / double(sample_size)); } size_t FFmpegDecoderAudio::decodeFrame(void * const buffer, const size_t size) { for (;;) { // Decode current packet while (m_bytes_remaining > 0) { int data_size = size; const int bytes_decoded = avcodec_decode_audio2(m_context, reinterpret_cast(buffer), &data_size, m_packet_data, m_bytes_remaining); if (bytes_decoded < 0) { // if error, skip frame m_bytes_remaining = 0; break; } m_bytes_remaining -= bytes_decoded; m_packet_data += bytes_decoded; // If we have some data, return it and come back for more later. if (data_size > 0) return data_size; } // Get next packet if (m_packet.valid()) m_packet.clear(); if (m_exit) return 0; bool is_empty = true; m_packet = m_packets.tryPop(is_empty); if (is_empty) return 0; if (m_packet.type == FFmpegPacket::PACKET_DATA) { if (m_packet.packet.pts != int64_t(AV_NOPTS_VALUE)) { const double pts = av_q2d(m_stream->time_base) * m_packet.packet.pts; m_clocks.audioSetBufferEndPts(pts); } m_bytes_remaining = m_packet.packet.size; m_packet_data = m_packet.packet.data; } else if (m_packet.type == FFmpegPacket::PACKET_END_OF_STREAM) { m_end_of_stream = true; } else if (m_packet.type == FFmpegPacket::PACKET_FLUSH) { avcodec_flush_buffers(m_context); } // just output silence when we reached the end of stream if (m_end_of_stream) { memset(buffer, 0, size); return size; } } } } // namespace osgFFmpeg