#include #include "ffmpeg.h" #ifdef Q_OS_WIN32 #include "ffmpeg-renderers/dxva2.h" #endif #ifdef Q_OS_DARWIN #include "ffmpeg-renderers/vt.h" #endif #ifdef HAVE_LIBVA #include "ffmpeg-renderers/vaapi.h" #endif #ifdef HAVE_LIBVDPAU #include "ffmpeg-renderers/vdpau.h" #endif // This is gross but it allows us to use sizeof() #include "ffmpeg_videosamples.cpp" #define FAILED_DECODES_RESET_THRESHOLD 20 bool FFmpegVideoDecoder::isHardwareAccelerated() { return m_HwDecodeCfg != nullptr; } enum AVPixelFormat FFmpegVideoDecoder::ffGetFormat(AVCodecContext* context, const enum AVPixelFormat* pixFmts) { FFmpegVideoDecoder* decoder = (FFmpegVideoDecoder*)context->opaque; const enum AVPixelFormat *p; for (p = pixFmts; *p != -1; p++) { // Only match our hardware decoding codec or SW pixel // format (if not using hardware decoding). It's crucial // to override the default get_format() which will try // to gracefully fall back to software decode and break us. if (*p == (decoder->m_HwDecodeCfg ? decoder->m_HwDecodeCfg->pix_fmt : context->pix_fmt)) { return *p; } } return AV_PIX_FMT_NONE; } FFmpegVideoDecoder::FFmpegVideoDecoder() : m_VideoDecoderCtx(nullptr), m_DecodeBuffer(1024 * 1024, 0), m_HwDecodeCfg(nullptr), m_Renderer(nullptr), m_ConsecutiveFailedDecodes(0) { av_init_packet(&m_Pkt); SDL_AtomicSet(&m_QueuedFrames, 0); // Use linear filtering when renderer scaling is required SDL_SetHint(SDL_HINT_RENDER_SCALE_QUALITY, "1"); } FFmpegVideoDecoder::~FFmpegVideoDecoder() { reset(); } IFFmpegRenderer* FFmpegVideoDecoder::getRenderer() { return m_Renderer; } void FFmpegVideoDecoder::reset() { // Drop any frames still queued to ensure // they are properly freed. SDL_Event event; while (SDL_AtomicGet(&m_QueuedFrames) > 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Waiting for %d frames to return", SDL_AtomicGet(&m_QueuedFrames)); if (SDL_PeepEvents(&event, 1, SDL_GETEVENT, SDL_USEREVENT, SDL_USEREVENT) == 1) { dropFrame(&event.user); } else { SDL_Delay(100); SDL_PumpEvents(); } } delete m_Renderer; m_Renderer = nullptr; avcodec_free_context(&m_VideoDecoderCtx); } bool FFmpegVideoDecoder::completeInitialization(AVCodec* decoder, int videoFormat, int width, int height, bool testOnly) { m_VideoDecoderCtx = avcodec_alloc_context3(decoder); if (!m_VideoDecoderCtx) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Unable to allocate video decoder context"); return false; } // Always request low delay decoding m_VideoDecoderCtx->flags |= AV_CODEC_FLAG_LOW_DELAY; // Enable slice multi-threading for software decoding if (!m_HwDecodeCfg) { m_VideoDecoderCtx->thread_type = FF_THREAD_SLICE; m_VideoDecoderCtx->thread_count = qMin(MAX_SLICES, SDL_GetCPUCount()); } else { // No threading for HW decode m_VideoDecoderCtx->thread_count = 1; } // Setup decoding parameters m_VideoDecoderCtx->width = width; m_VideoDecoderCtx->height = height; m_VideoDecoderCtx->pix_fmt = AV_PIX_FMT_YUV420P; // FIXME: HDR m_VideoDecoderCtx->get_format = ffGetFormat; // Allow the renderer to attach data to this decoder if (!m_Renderer->prepareDecoderContext(m_VideoDecoderCtx)) { return false; } // Nobody must override our ffGetFormat SDL_assert(m_VideoDecoderCtx->get_format == ffGetFormat); // Stash a pointer to this object in the context SDL_assert(m_VideoDecoderCtx->opaque == nullptr); m_VideoDecoderCtx->opaque = this; int err = avcodec_open2(m_VideoDecoderCtx, decoder, nullptr); if (err < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Unable to open decoder for format: %x", videoFormat); return false; } // FFMpeg doesn't completely initialize the codec until the codec // config data comes in. This would be too late for us to change // our minds on the selected video codec, so we'll do a trial run // now to see if things will actually work when the video stream // comes in. if (testOnly) { if (videoFormat & VIDEO_FORMAT_MASK_H264) { m_Pkt.data = (uint8_t*)k_H264TestFrame; m_Pkt.size = sizeof(k_H264TestFrame); } else { m_Pkt.data = (uint8_t*)k_HEVCTestFrame; m_Pkt.size = sizeof(k_HEVCTestFrame); } err = avcodec_send_packet(m_VideoDecoderCtx, &m_Pkt); if (err < 0) { char errorstring[512]; av_strerror(err, errorstring, sizeof(errorstring)); SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Test decode failed: %s", errorstring); return false; } } #ifdef QT_DEBUG // Restore default log level before streaming av_log_set_level(AV_LOG_INFO); #endif return true; } IFFmpegRenderer* FFmpegVideoDecoder::createAcceleratedRenderer(const AVCodecHWConfig* hwDecodeCfg) { if (!(hwDecodeCfg->methods & AV_CODEC_HW_CONFIG_METHOD_HW_DEVICE_CTX)) { return nullptr; } // Look for acceleration types we support switch (hwDecodeCfg->device_type) { #ifdef Q_OS_WIN32 case AV_HWDEVICE_TYPE_DXVA2: return new DXVA2Renderer(); #endif #ifdef Q_OS_DARWIN case AV_HWDEVICE_TYPE_VIDEOTOOLBOX: return VTRendererFactory::createRenderer(); #endif #ifdef HAVE_LIBVA case AV_HWDEVICE_TYPE_VAAPI: return new VAAPIRenderer(); #endif #ifdef HAVE_LIBVDPAU case AV_HWDEVICE_TYPE_VDPAU: return new VDPAURenderer(); #endif default: return nullptr; } } bool FFmpegVideoDecoder::initialize( StreamingPreferences::VideoDecoderSelection vds, SDL_Window* window, int videoFormat, int width, int height, int maxFps) { AVCodec* decoder; #ifdef QT_DEBUG // Increase log level during initialization av_log_set_level(AV_LOG_DEBUG); #endif if (videoFormat & VIDEO_FORMAT_MASK_H264) { decoder = avcodec_find_decoder(AV_CODEC_ID_H264); } else if (videoFormat & VIDEO_FORMAT_MASK_H265) { decoder = avcodec_find_decoder(AV_CODEC_ID_HEVC); } else { Q_ASSERT(false); decoder = nullptr; } if (!decoder) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Unable to find decoder for format: %x", videoFormat); return false; } for (int i = 0;; i++) { const AVCodecHWConfig *config = avcodec_get_hw_config(decoder, i); if (!config || vds == StreamingPreferences::VDS_FORCE_SOFTWARE) { // No matching hardware acceleration support. // This is not an error. m_HwDecodeCfg = nullptr; m_Renderer = new SdlRenderer(); if (vds != StreamingPreferences::VDS_FORCE_HARDWARE && m_Renderer->initialize(window, videoFormat, width, height, maxFps) && completeInitialization(decoder, videoFormat, width, height, false)) { return true; } else { reset(); return false; } } m_Renderer = createAcceleratedRenderer(config); if (!m_Renderer) { continue; } m_HwDecodeCfg = config; // Submit test frame to ensure this codec really works if (m_Renderer->initialize(window, videoFormat, width, height, maxFps) && completeInitialization(decoder, videoFormat, width, height, true)) { // OK, it worked, so now let's initialize it for real reset(); if ((m_Renderer = createAcceleratedRenderer(config)) != nullptr && m_Renderer->initialize(window, videoFormat, width, height, maxFps) && completeInitialization(decoder, videoFormat, width, height, false)) { return true; } else { SDL_LogCritical(SDL_LOG_CATEGORY_APPLICATION, "Decoder failed to initialize after successful test"); reset(); } } else { // Failed to initialize or test frame failed, so keep looking reset(); } } } int FFmpegVideoDecoder::submitDecodeUnit(PDECODE_UNIT du) { PLENTRY entry = du->bufferList; int err; if (du->fullLength + AV_INPUT_BUFFER_PADDING_SIZE > m_DecodeBuffer.length()) { m_DecodeBuffer = QByteArray(du->fullLength + AV_INPUT_BUFFER_PADDING_SIZE, 0); } int offset = 0; while (entry != nullptr) { memcpy(&m_DecodeBuffer.data()[offset], entry->data, entry->length); offset += entry->length; entry = entry->next; } SDL_assert(offset == du->fullLength); m_Pkt.data = reinterpret_cast(m_DecodeBuffer.data()); m_Pkt.size = du->fullLength; err = avcodec_send_packet(m_VideoDecoderCtx, &m_Pkt); if (err < 0) { char errorstring[512]; av_strerror(err, errorstring, sizeof(errorstring)); SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "avcodec_send_packet() failed: %s", errorstring); // If we've failed a bunch of decodes in a row, the decoder/renderer is // clearly unhealthy, so let's generate a synthetic reset event to trigger // the event loop to destroy and recreate the decoder. if (++m_ConsecutiveFailedDecodes == FAILED_DECODES_RESET_THRESHOLD) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Resetting decoder due to consistent failure"); SDL_Event event; event.type = SDL_RENDER_DEVICE_RESET; SDL_PushEvent(&event); } return DR_NEED_IDR; } AVFrame* frame = av_frame_alloc(); if (!frame) { // Failed to allocate a frame but we did submit, // so we can return DR_OK SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Failed to allocate frame"); return DR_OK; } err = avcodec_receive_frame(m_VideoDecoderCtx, frame); if (err == 0) { // Reset failed decodes count if we reached this far m_ConsecutiveFailedDecodes = 0; // Queue the frame for rendering from the main thread SDL_AtomicIncRef(&m_QueuedFrames); queueFrame(frame); } else { av_frame_free(&frame); char errorstring[512]; av_strerror(err, errorstring, sizeof(errorstring)); SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "avcodec_receive_frame() failed: %s", errorstring); if (++m_ConsecutiveFailedDecodes == FAILED_DECODES_RESET_THRESHOLD) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Resetting decoder due to consistent failure"); SDL_Event event; event.type = SDL_RENDER_DEVICE_RESET; SDL_PushEvent(&event); } } return DR_OK; } // Called on main thread void FFmpegVideoDecoder::renderFrame(SDL_UserEvent* event) { AVFrame* frame = reinterpret_cast(event->data1); m_Renderer->renderFrame(frame); SDL_AtomicDecRef(&m_QueuedFrames); } // Called on main thread void FFmpegVideoDecoder::dropFrame(SDL_UserEvent* event) { AVFrame* frame = reinterpret_cast(event->data1); av_frame_free(&frame); SDL_AtomicDecRef(&m_QueuedFrames); }