#include "drm.h" extern "C" { #include } #include // Special Rockchip type #ifndef DRM_FORMAT_NV12_10 #define DRM_FORMAT_NV12_10 fourcc_code('N', 'A', '1', '2') #endif // Special Raspberry Pi type (upstreamed) #ifndef DRM_FORMAT_P030 #define DRM_FORMAT_P030 fourcc_code('P', '0', '3', '0') #endif // Regular P010 (not present in some old libdrm headers) #ifndef DRM_FORMAT_P010 #define DRM_FORMAT_P010 fourcc_code('P', '0', '1', '0') #endif #include #include #include "streaming/streamutils.h" #include "streaming/session.h" #include // HACK: Avoid including X11 headers which conflict with QDir #ifdef SDL_VIDEO_DRIVER_X11 #undef SDL_VIDEO_DRIVER_X11 #endif #include #include DrmRenderer::DrmRenderer(IFFmpegRenderer *backendRenderer) : m_BackendRenderer(backendRenderer), m_HwContext(nullptr), m_DrmFd(-1), m_SdlOwnsDrmFd(false), m_SupportsDirectRendering(false), m_Main10Hdr(false), m_ConnectorId(0), m_EncoderId(0), m_CrtcId(0), m_PlaneId(0), m_CurrentFbId(0), m_LastFullRange(false), m_LastColorSpace(-1), m_ColorEncodingProp(nullptr), m_ColorRangeProp(nullptr), m_HdrOutputMetadataProp(nullptr), m_HdrOutputMetadataBlobId(0) { #ifdef HAVE_EGL m_EGLExtDmaBuf = false; m_eglCreateImage = nullptr; m_eglCreateImageKHR = nullptr; m_eglDestroyImage = nullptr; m_eglDestroyImageKHR = nullptr; #endif } DrmRenderer::~DrmRenderer() { // Ensure we're out of HDR mode setHdrMode(false); if (m_CurrentFbId != 0) { drmModeRmFB(m_DrmFd, m_CurrentFbId); } if (m_HdrOutputMetadataBlobId != 0) { drmModeDestroyPropertyBlob(m_DrmFd, m_HdrOutputMetadataBlobId); } if (m_ColorEncodingProp != nullptr) { drmModeFreeProperty(m_ColorEncodingProp); } if (m_ColorRangeProp != nullptr) { drmModeFreeProperty(m_ColorRangeProp); } if (m_HdrOutputMetadataProp != nullptr) { drmModeFreeProperty(m_HdrOutputMetadataProp); } if (m_HwContext != nullptr) { av_buffer_unref(&m_HwContext); } if (!m_SdlOwnsDrmFd && m_DrmFd != -1) { close(m_DrmFd); } } bool DrmRenderer::prepareDecoderContext(AVCodecContext* context, AVDictionary** options) { // The out-of-tree LibreELEC patches use this option to control the type of the V4L2 // buffers that we get back. We only support NV12 buffers now. av_dict_set_int(options, "pixel_format", AV_PIX_FMT_NV12, 0); context->hw_device_ctx = av_buffer_ref(m_HwContext); SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Using DRM renderer"); return true; } bool DrmRenderer::initialize(PDECODER_PARAMETERS params) { int i; m_Main10Hdr = (params->videoFormat & VIDEO_FORMAT_MASK_10BIT); #if SDL_VERSION_ATLEAST(2, 0, 15) SDL_SysWMinfo info; SDL_VERSION(&info.version); if (!SDL_GetWindowWMInfo(params->window, &info)) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_GetWindowWMInfo() failed: %s", SDL_GetError()); return false; } if (info.subsystem == SDL_SYSWM_KMSDRM) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Sharing DRM FD with SDL"); SDL_assert(info.info.kmsdrm.drm_fd >= 0); m_DrmFd = info.info.kmsdrm.drm_fd; m_SdlOwnsDrmFd = true; } else #endif { const char* userDevice = SDL_getenv("DRM_DEV"); if (userDevice != nullptr) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Opening user-specified DRM device: %s", userDevice); m_DrmFd = open(userDevice, O_RDWR | O_CLOEXEC); } else { QDir driDir("/dev/dri"); // We have to explicitly ask for devices to be returned driDir.setFilter(QDir::Files | QDir::System); // Try a render node first since we aren't using DRM for output in this codepath for (QFileInfo& node : driDir.entryInfoList(QStringList("renderD*"))) { QByteArray absolutePath = node.absoluteFilePath().toUtf8(); m_DrmFd = open(absolutePath.constData(), O_RDWR | O_CLOEXEC); if (m_DrmFd >= 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Opened DRM render node: %s", absolutePath.constData()); break; } } // If that fails, try to use a primary node and hope for the best if (m_DrmFd < 0) { for (QFileInfo& node : driDir.entryInfoList(QStringList("card*"))) { QByteArray absolutePath = node.absoluteFilePath().toUtf8(); m_DrmFd = open(absolutePath.constData(), O_RDWR | O_CLOEXEC); if (m_DrmFd >= 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Opened DRM primary node: %s", absolutePath.constData()); break; } } } } if (m_DrmFd < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Failed to open DRM device: %d", errno); return false; } } // Create the device context first because it is needed whether we can // actually use direct rendering or not. m_HwContext = av_hwdevice_ctx_alloc(AV_HWDEVICE_TYPE_DRM); if (m_HwContext == nullptr) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "av_hwdevice_ctx_alloc(DRM) failed"); return false; } AVHWDeviceContext* deviceContext = (AVHWDeviceContext*)m_HwContext->data; AVDRMDeviceContext* drmDeviceContext = (AVDRMDeviceContext*)deviceContext->hwctx; drmDeviceContext->fd = m_DrmFd; int err = av_hwdevice_ctx_init(m_HwContext); if (err < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "av_hwdevice_ctx_init(DRM) failed: %d", err); return false; } // Still return true if we fail to initialize DRM direct rendering // stuff, since we have EGLRenderer and SDLRenderer that we can use // for indirect rendering. Our FFmpeg renderer selection code will // handle the case where those also fail to render the test frame. // If we are just acting as a frontend renderer (m_BackendRenderer // == nullptr), we want to fail if we can't render directly since // that's the whole point it's trying to use us for. const bool DIRECT_RENDERING_INIT_FAILED = (m_BackendRenderer == nullptr); // If we're not sharing the DRM FD with SDL, that means we don't // have DRM master, so we can't call drmModeSetPlane(). We can // use EGLRenderer or SDLRenderer to render in this situation. if (!m_SdlOwnsDrmFd) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Direct rendering via DRM is disabled"); return DIRECT_RENDERING_INIT_FAILED; } if (!params->testOnly) { // Create a dummy renderer to force SDL to complete the modesetting // operation that the KMSDRM backend keeps pending until the next // time we swap buffers. We have to do this before we enumerate // CRTC modes below. SDL_Renderer* renderer = SDL_CreateRenderer(params->window, -1, SDL_RENDERER_SOFTWARE); if (renderer != nullptr) { SDL_SetRenderDrawColor(renderer, 0, 0, 0, SDL_ALPHA_OPAQUE); SDL_RenderClear(renderer); SDL_RenderPresent(renderer); SDL_DestroyRenderer(renderer); } else { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_CreateRenderer() failed: %s", SDL_GetError()); } } drmModeRes* resources = drmModeGetResources(m_DrmFd); if (resources == nullptr) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeGetResources() failed: %d", errno); return DIRECT_RENDERING_INIT_FAILED; } // Look for a connected connector and get the associated encoder m_ConnectorId = 0; m_EncoderId = 0; for (i = 0; i < resources->count_connectors && m_EncoderId == 0; i++) { drmModeConnector* connector = drmModeGetConnector(m_DrmFd, resources->connectors[i]); if (connector != nullptr) { if (connector->connection == DRM_MODE_CONNECTED && connector->count_modes > 0) { m_ConnectorId = resources->connectors[i]; m_EncoderId = connector->encoder_id; } drmModeFreeConnector(connector); } } if (m_EncoderId == 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "No connected displays found!"); drmModeFreeResources(resources); return DIRECT_RENDERING_INIT_FAILED; } // Now find the CRTC from the encoder m_CrtcId = 0; for (i = 0; i < resources->count_encoders && m_CrtcId == 0; i++) { drmModeEncoder* encoder = drmModeGetEncoder(m_DrmFd, resources->encoders[i]); if (encoder != nullptr) { if (encoder->encoder_id == m_EncoderId) { m_CrtcId = encoder->crtc_id; } drmModeFreeEncoder(encoder); } } if (m_CrtcId == 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "DRM encoder not found!"); drmModeFreeResources(resources); return DIRECT_RENDERING_INIT_FAILED; } int crtcIndex = -1; for (int i = 0; i < resources->count_crtcs; i++) { if (resources->crtcs[i] == m_CrtcId) { drmModeCrtc* crtc = drmModeGetCrtc(m_DrmFd, resources->crtcs[i]); crtcIndex = i; m_OutputRect.x = m_OutputRect.y = 0; m_OutputRect.w = crtc->width; m_OutputRect.h = crtc->height; drmModeFreeCrtc(crtc); break; } } drmModeFreeResources(resources); if (crtcIndex == -1) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Failed to get CRTC!"); return DIRECT_RENDERING_INIT_FAILED; } drmSetClientCap(m_DrmFd, DRM_CLIENT_CAP_UNIVERSAL_PLANES, 1); drmModePlaneRes* planeRes = drmModeGetPlaneResources(m_DrmFd); if (planeRes == nullptr) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmGetPlaneResources() failed: %d", errno); return DIRECT_RENDERING_INIT_FAILED; } // Find an overlay plane with the required format to render on // // FIXME: We should check the actual DRM format in a real AVFrame rather // than just assuming it will be a certain hardcoded type like NV12 based // on the chosen video format. m_PlaneId = 0; for (uint32_t i = 0; i < planeRes->count_planes && m_PlaneId == 0; i++) { drmModePlane* plane = drmModeGetPlane(m_DrmFd, planeRes->planes[i]); if (plane != nullptr) { bool matchingFormat = false; for (uint32_t j = 0; j < plane->count_formats && !matchingFormat; j++) { if (m_Main10Hdr) { switch (plane->formats[j]) { case DRM_FORMAT_P010: case DRM_FORMAT_P030: case DRM_FORMAT_NV12_10: matchingFormat = true; break; } } else { switch (plane->formats[j]) { case DRM_FORMAT_NV12: matchingFormat = true; break; } } } if (matchingFormat == false) { drmModeFreePlane(plane); continue; } if ((plane->possible_crtcs & (1 << crtcIndex)) && plane->crtc_id == 0) { drmModeObjectPropertiesPtr props = drmModeObjectGetProperties(m_DrmFd, planeRes->planes[i], DRM_MODE_OBJECT_PLANE); if (props != nullptr) { for (uint32_t j = 0; j < props->count_props; j++) { drmModePropertyPtr prop = drmModeGetProperty(m_DrmFd, props->props[j]); if (prop != nullptr) { if (!strcmp(prop->name, "type") && props->prop_values[j] == DRM_PLANE_TYPE_OVERLAY) { m_PlaneId = plane->plane_id; } if (!strcmp(prop->name, "COLOR_ENCODING")) { m_ColorEncodingProp = prop; } else if (!strcmp(prop->name, "COLOR_RANGE")) { m_ColorRangeProp = prop; } else { drmModeFreeProperty(prop); } } } drmModeFreeObjectProperties(props); } } drmModeFreePlane(plane); } } drmModeFreePlaneResources(planeRes); if (m_PlaneId == 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Failed to find suitable overlay plane!"); return DIRECT_RENDERING_INIT_FAILED; } drmModeObjectPropertiesPtr props = drmModeObjectGetProperties(m_DrmFd, m_ConnectorId, DRM_MODE_OBJECT_CONNECTOR); if (props != nullptr) { for (uint32_t j = 0; j < props->count_props; j++) { drmModePropertyPtr prop = drmModeGetProperty(m_DrmFd, props->props[j]); if (prop != nullptr) { if (!strcmp(prop->name, "HDR_OUTPUT_METADATA")) { m_HdrOutputMetadataProp = prop; } else { drmModeFreeProperty(prop); } } } drmModeFreeObjectProperties(props); } // If we got this far, we can do direct rendering via the DRM FD. m_SupportsDirectRendering = true; return true; } enum AVPixelFormat DrmRenderer::getPreferredPixelFormat(int videoFormat) { // DRM PRIME buffers, or whatever the backend renderer wants if (m_BackendRenderer != nullptr) { return m_BackendRenderer->getPreferredPixelFormat(videoFormat); } else { return AV_PIX_FMT_DRM_PRIME; } } bool DrmRenderer::isPixelFormatSupported(int videoFormat, AVPixelFormat pixelFormat) { // Pass through the backend renderer if we have one. Otherwise we use // the default behavior which only supports the preferred format. if (m_BackendRenderer != nullptr) { return m_BackendRenderer->isPixelFormatSupported(videoFormat, pixelFormat); } else { return getPreferredPixelFormat(videoFormat); } } int DrmRenderer::getRendererAttributes() { int attributes = 0; // This renderer can only draw in full-screen attributes |= RENDERER_ATTRIBUTE_FULLSCREEN_ONLY; // This renderer supports HDR attributes |= RENDERER_ATTRIBUTE_HDR_SUPPORT; // This renderer does not buffer any frames in the graphics pipeline attributes |= RENDERER_ATTRIBUTE_NO_BUFFERING; return attributes; } void DrmRenderer::setHdrMode(bool enabled) { if (m_HdrOutputMetadataProp != nullptr) { if (m_HdrOutputMetadataBlobId != 0) { drmModeDestroyPropertyBlob(m_DrmFd, m_HdrOutputMetadataBlobId); m_HdrOutputMetadataBlobId = 0; } if (enabled) { DrmDefs::hdr_output_metadata outputMetadata; SS_HDR_METADATA sunshineHdrMetadata; // Sunshine will have HDR metadata but GFE will not if (!LiGetHdrMetadata(&sunshineHdrMetadata)) { memset(&sunshineHdrMetadata, 0, sizeof(sunshineHdrMetadata)); } outputMetadata.metadata_type = 0; // HDMI_STATIC_METADATA_TYPE1 outputMetadata.hdmi_metadata_type1.eotf = 2; // SMPTE ST 2084 outputMetadata.hdmi_metadata_type1.metadata_type = 0; // Static Metadata Type 1 for (int i = 0; i < 3; i++) { outputMetadata.hdmi_metadata_type1.display_primaries[i].x = sunshineHdrMetadata.displayPrimaries[i].x; outputMetadata.hdmi_metadata_type1.display_primaries[i].y = sunshineHdrMetadata.displayPrimaries[i].y; } outputMetadata.hdmi_metadata_type1.white_point.x = sunshineHdrMetadata.whitePoint.x; outputMetadata.hdmi_metadata_type1.white_point.y = sunshineHdrMetadata.whitePoint.y; outputMetadata.hdmi_metadata_type1.max_display_mastering_luminance = sunshineHdrMetadata.maxDisplayLuminance; outputMetadata.hdmi_metadata_type1.min_display_mastering_luminance = sunshineHdrMetadata.minDisplayLuminance; outputMetadata.hdmi_metadata_type1.max_cll = sunshineHdrMetadata.maxContentLightLevel; outputMetadata.hdmi_metadata_type1.max_fall = sunshineHdrMetadata.maxFrameAverageLightLevel; int err = drmModeCreatePropertyBlob(m_DrmFd, &outputMetadata, sizeof(outputMetadata), &m_HdrOutputMetadataBlobId); if (err < 0) { m_HdrOutputMetadataBlobId = 0; SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeCreatePropertyBlob() failed: %d", errno); // Non-fatal } } int err = drmModeObjectSetProperty(m_DrmFd, m_ConnectorId, DRM_MODE_OBJECT_CONNECTOR, m_HdrOutputMetadataProp->prop_id, enabled ? m_HdrOutputMetadataBlobId : 0); if (err == 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Set display HDR mode: %s", enabled ? "enabled" : "disabled"); } else { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeObjectSetProperty(%s) failed: %d", m_HdrOutputMetadataProp->name, errno); // Non-fatal } } else if (enabled) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "HDR_OUTPUT_METADATA is unavailable on this display. Unable to enter HDR mode!"); } } void DrmRenderer::renderFrame(AVFrame* frame) { AVDRMFrameDescriptor mappedFrame; AVDRMFrameDescriptor* drmFrame; // If we are acting as the frontend renderer, we'll need to have the backend // map this frame into a DRM PRIME descriptor that we can render. if (m_BackendRenderer != nullptr) { if (!m_BackendRenderer->mapDrmPrimeFrame(frame, &mappedFrame)) { return; } drmFrame = &mappedFrame; } else { // If we're the backend renderer, the frame should already have it. SDL_assert(frame->format == AV_PIX_FMT_DRM_PRIME); drmFrame = (AVDRMFrameDescriptor*)frame->data[0]; } int err; uint32_t handles[4] = {}; uint32_t pitches[4] = {}; uint32_t offsets[4] = {}; uint64_t modifiers[4] = {}; uint32_t flags = 0; SDL_Rect src, dst; src.x = src.y = 0; src.w = frame->width; src.h = frame->height; dst = m_OutputRect; StreamUtils::scaleSourceToDestinationSurface(&src, &dst); // DRM requires composed layers rather than separate layers per plane SDL_assert(drmFrame->nb_layers == 1); const auto &layer = drmFrame->layers[0]; for (int i = 0; i < layer.nb_planes; i++) { const auto &object = drmFrame->objects[layer.planes[i].object_index]; err = drmPrimeFDToHandle(m_DrmFd, object.fd, &handles[i]); if (err < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmPrimeFDToHandle() failed: %d", errno); if (m_BackendRenderer != nullptr) { SDL_assert(drmFrame == &mappedFrame); m_BackendRenderer->unmapDrmPrimeFrame(drmFrame); } return; } pitches[i] = layer.planes[i].pitch; offsets[i] = layer.planes[i].offset; modifiers[i] = object.format_modifier; // Pass along the modifiers to DRM if there are some in the descriptor if (modifiers[i] != DRM_FORMAT_MOD_INVALID) { flags |= DRM_MODE_FB_MODIFIERS; } } // Remember the last FB object we created so we can free it // when we are finished rendering this one (if successful). uint32_t lastFbId = m_CurrentFbId; // Create a frame buffer object from the PRIME buffer // NB: It is an error to pass modifiers without DRM_MODE_FB_MODIFIERS set. err = drmModeAddFB2WithModifiers(m_DrmFd, frame->width, frame->height, drmFrame->layers[0].format, handles, pitches, offsets, (flags & DRM_MODE_FB_MODIFIERS) ? modifiers : NULL, &m_CurrentFbId, flags); if (m_BackendRenderer != nullptr) { SDL_assert(drmFrame == &mappedFrame); m_BackendRenderer->unmapDrmPrimeFrame(drmFrame); } if (err < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeAddFB2WithModifiers() failed: %d", errno); m_CurrentFbId = lastFbId; return; } int colorspace = getFrameColorspace(frame); bool fullRange = isFrameFullRange(frame); // We also update the color range when the colorspace changes in order to handle initialization // where the last color range value may not actual be applied to the plane. if (fullRange != m_LastFullRange || colorspace != m_LastColorSpace) { const char* desiredValue = getDrmColorRangeValue(frame); if (m_ColorRangeProp != nullptr && desiredValue != nullptr) { int i; for (i = 0; i < m_ColorRangeProp->count_enums; i++) { if (!strcmp(desiredValue, m_ColorRangeProp->enums[i].name)) { err = drmModeObjectSetProperty(m_DrmFd, m_PlaneId, DRM_MODE_OBJECT_PLANE, m_ColorRangeProp->prop_id, m_ColorRangeProp->enums[i].value); if (err == 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "%s: %s", m_ColorRangeProp->name, desiredValue); } else { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeObjectSetProperty(%s) failed: %d", m_ColorRangeProp->name, errno); // Non-fatal } break; } } if (i == m_ColorRangeProp->count_enums) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Unable to find matching COLOR_RANGE value for '%s'. Colors may be inaccurate!", desiredValue); } } else if (desiredValue != nullptr) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "COLOR_RANGE property does not exist on output plane. Colors may be inaccurate!"); } m_LastFullRange = fullRange; } if (colorspace != m_LastColorSpace) { const char* desiredValue = getDrmColorEncodingValue(frame); if (m_ColorEncodingProp != nullptr && desiredValue != nullptr) { int i; for (i = 0; i < m_ColorEncodingProp->count_enums; i++) { if (!strcmp(desiredValue, m_ColorEncodingProp->enums[i].name)) { err = drmModeObjectSetProperty(m_DrmFd, m_PlaneId, DRM_MODE_OBJECT_PLANE, m_ColorEncodingProp->prop_id, m_ColorEncodingProp->enums[i].value); if (err == 0) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "%s: %s", m_ColorEncodingProp->name, desiredValue); } else { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeObjectSetProperty(%s) failed: %d", m_ColorEncodingProp->name, errno); // Non-fatal } break; } } if (i == m_ColorEncodingProp->count_enums) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Unable to find matching COLOR_ENCODING value for '%s'. Colors may be inaccurate!", desiredValue); } } else if (desiredValue != nullptr) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "COLOR_ENCODING property does not exist on output plane. Colors may be inaccurate!"); } m_LastColorSpace = colorspace; } // Update the overlay err = drmModeSetPlane(m_DrmFd, m_PlaneId, m_CrtcId, m_CurrentFbId, 0, dst.x, dst.y, dst.w, dst.h, 0, 0, frame->width << 16, frame->height << 16); if (err < 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "drmModeSetPlane() failed: %d", errno); drmModeRmFB(m_DrmFd, m_CurrentFbId); m_CurrentFbId = lastFbId; return; } // Free the previous FB object which has now been superseded drmModeRmFB(m_DrmFd, lastFbId); } bool DrmRenderer::needsTestFrame() { return true; } bool DrmRenderer::testRenderFrame(AVFrame* frame) { // If we have a backend renderer, we must make sure it can // successfully export DRM PRIME frames. if (m_BackendRenderer != nullptr) { AVDRMFrameDescriptor drmDescriptor; // We shouldn't get here unless the backend at least claims // it can export DRM PRIME frames. SDL_assert(m_BackendRenderer->canExportDrmPrime()); if (!m_BackendRenderer->mapDrmPrimeFrame(frame, &drmDescriptor)) { // It can't, so we can't use this renderer. return false; } m_BackendRenderer->unmapDrmPrimeFrame(&drmDescriptor); } return true; } bool DrmRenderer::isDirectRenderingSupported() { return m_SupportsDirectRendering; } const char* DrmRenderer::getDrmColorEncodingValue(AVFrame* frame) { switch (getFrameColorspace(frame)) { case COLORSPACE_REC_601: return "ITU-R BT.601 YCbCr"; case COLORSPACE_REC_709: return "ITU-R BT.709 YCbCr"; case COLORSPACE_REC_2020: return "ITU-R BT.2020 YCbCr"; default: return NULL; } } const char* DrmRenderer::getDrmColorRangeValue(AVFrame* frame) { return isFrameFullRange(frame) ? "YCbCr full range" : "YCbCr limited range"; } #ifdef HAVE_EGL bool DrmRenderer::canExportEGL() { if (qgetenv("DRM_FORCE_DIRECT") == "1") { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Using direct rendering due to environment variable"); return false; } else if (qgetenv("DRM_FORCE_EGL") == "1") { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Using EGL rendering due to environment variable"); return true; } else if (m_SupportsDirectRendering && m_Main10Hdr) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Using direct rendering for HDR support"); return false; } SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "DRM backend supports exporting EGLImage"); return true; } AVPixelFormat DrmRenderer::getEGLImagePixelFormat() { // This tells EGLRenderer to treat the EGLImage as a single opaque texture return AV_PIX_FMT_DRM_PRIME; } bool DrmRenderer::initializeEGL(EGLDisplay, const EGLExtensions &ext) { if (!ext.isSupported("EGL_EXT_image_dma_buf_import")) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "DRM-EGL: DMABUF unsupported"); return false; } m_EGLExtDmaBuf = ext.isSupported("EGL_EXT_image_dma_buf_import_modifiers"); // NB: eglCreateImage() and eglCreateImageKHR() have slightly different definitions m_eglCreateImage = (typeof(m_eglCreateImage))eglGetProcAddress("eglCreateImage"); m_eglCreateImageKHR = (typeof(m_eglCreateImageKHR))eglGetProcAddress("eglCreateImageKHR"); m_eglDestroyImage = (typeof(m_eglDestroyImage))eglGetProcAddress("eglDestroyImage"); m_eglDestroyImageKHR = (typeof(m_eglDestroyImageKHR))eglGetProcAddress("eglDestroyImageKHR"); if (!(m_eglCreateImage && m_eglDestroyImage) && !(m_eglCreateImageKHR && m_eglDestroyImageKHR)) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Missing eglCreateImage()/eglDestroyImage() in EGL driver"); return false; } return true; } ssize_t DrmRenderer::exportEGLImages(AVFrame *frame, EGLDisplay dpy, EGLImage images[EGL_MAX_PLANES]) { AVDRMFrameDescriptor* drmFrame = (AVDRMFrameDescriptor*)frame->data[0]; memset(images, 0, sizeof(EGLImage) * EGL_MAX_PLANES); // DRM requires composed layers rather than separate layers per plane SDL_assert(drmFrame->nb_layers == 1); // Max 30 attributes (1 key + 1 value for each) const int MAX_ATTRIB_COUNT = 30 * 2; EGLAttrib attribs[MAX_ATTRIB_COUNT] = { EGL_LINUX_DRM_FOURCC_EXT, (EGLAttrib)drmFrame->layers[0].format, EGL_WIDTH, frame->width, EGL_HEIGHT, frame->height, }; int attribIndex = 6; for (int i = 0; i < drmFrame->layers[0].nb_planes; ++i) { const auto &plane = drmFrame->layers[0].planes[i]; const auto &object = drmFrame->objects[plane.object_index]; switch (i) { case 0: attribs[attribIndex++] = EGL_DMA_BUF_PLANE0_FD_EXT; attribs[attribIndex++] = object.fd; attribs[attribIndex++] = EGL_DMA_BUF_PLANE0_OFFSET_EXT; attribs[attribIndex++] = plane.offset; attribs[attribIndex++] = EGL_DMA_BUF_PLANE0_PITCH_EXT; attribs[attribIndex++] = plane.pitch; if (m_EGLExtDmaBuf && object.format_modifier != DRM_FORMAT_MOD_INVALID) { attribs[attribIndex++] = EGL_DMA_BUF_PLANE0_MODIFIER_LO_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier & 0xFFFFFFFF); attribs[attribIndex++] = EGL_DMA_BUF_PLANE0_MODIFIER_HI_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier >> 32); } break; case 1: attribs[attribIndex++] = EGL_DMA_BUF_PLANE1_FD_EXT; attribs[attribIndex++] = object.fd; attribs[attribIndex++] = EGL_DMA_BUF_PLANE1_OFFSET_EXT; attribs[attribIndex++] = plane.offset; attribs[attribIndex++] = EGL_DMA_BUF_PLANE1_PITCH_EXT; attribs[attribIndex++] = plane.pitch; if (m_EGLExtDmaBuf && object.format_modifier != DRM_FORMAT_MOD_INVALID) { attribs[attribIndex++] = EGL_DMA_BUF_PLANE1_MODIFIER_LO_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier & 0xFFFFFFFF); attribs[attribIndex++] = EGL_DMA_BUF_PLANE1_MODIFIER_HI_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier >> 32); } break; case 2: attribs[attribIndex++] = EGL_DMA_BUF_PLANE2_FD_EXT; attribs[attribIndex++] = object.fd; attribs[attribIndex++] = EGL_DMA_BUF_PLANE2_OFFSET_EXT; attribs[attribIndex++] = plane.offset; attribs[attribIndex++] = EGL_DMA_BUF_PLANE2_PITCH_EXT; attribs[attribIndex++] = plane.pitch; if (m_EGLExtDmaBuf && object.format_modifier != DRM_FORMAT_MOD_INVALID) { attribs[attribIndex++] = EGL_DMA_BUF_PLANE2_MODIFIER_LO_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier & 0xFFFFFFFF); attribs[attribIndex++] = EGL_DMA_BUF_PLANE2_MODIFIER_HI_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier >> 32); } break; case 3: attribs[attribIndex++] = EGL_DMA_BUF_PLANE3_FD_EXT; attribs[attribIndex++] = object.fd; attribs[attribIndex++] = EGL_DMA_BUF_PLANE3_OFFSET_EXT; attribs[attribIndex++] = plane.offset; attribs[attribIndex++] = EGL_DMA_BUF_PLANE3_PITCH_EXT; attribs[attribIndex++] = plane.pitch; if (m_EGLExtDmaBuf && object.format_modifier != DRM_FORMAT_MOD_INVALID) { attribs[attribIndex++] = EGL_DMA_BUF_PLANE3_MODIFIER_LO_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier & 0xFFFFFFFF); attribs[attribIndex++] = EGL_DMA_BUF_PLANE3_MODIFIER_HI_EXT; attribs[attribIndex++] = (EGLint)(object.format_modifier >> 32); } break; default: Q_UNREACHABLE(); } } // Add colorspace metadata switch (getFrameColorspace(frame)) { case COLORSPACE_REC_601: attribs[attribIndex++] = EGL_YUV_COLOR_SPACE_HINT_EXT; attribs[attribIndex++] = EGL_ITU_REC601_EXT; break; case COLORSPACE_REC_709: attribs[attribIndex++] = EGL_YUV_COLOR_SPACE_HINT_EXT; attribs[attribIndex++] = EGL_ITU_REC709_EXT; break; case COLORSPACE_REC_2020: attribs[attribIndex++] = EGL_YUV_COLOR_SPACE_HINT_EXT; attribs[attribIndex++] = EGL_ITU_REC2020_EXT; break; } // Add color range metadata attribs[attribIndex++] = EGL_SAMPLE_RANGE_HINT_EXT; attribs[attribIndex++] = isFrameFullRange(frame) ? EGL_YUV_FULL_RANGE_EXT : EGL_YUV_NARROW_RANGE_EXT; // Terminate the attribute list attribs[attribIndex++] = EGL_NONE; SDL_assert(attribIndex <= MAX_ATTRIB_COUNT); // Our EGLImages are non-planar, so we only populate the first entry if (m_eglCreateImage) { images[0] = m_eglCreateImage(dpy, EGL_NO_CONTEXT, EGL_LINUX_DMA_BUF_EXT, nullptr, attribs); if (!images[0]) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "eglCreateImage() Failed: %d", eglGetError()); goto fail; } } else { // Cast the EGLAttrib array elements to EGLint for the KHR extension EGLint intAttribs[MAX_ATTRIB_COUNT]; for (int i = 0; i < MAX_ATTRIB_COUNT; i++) { intAttribs[i] = (EGLint)attribs[i]; } images[0] = m_eglCreateImageKHR(dpy, EGL_NO_CONTEXT, EGL_LINUX_DMA_BUF_EXT, nullptr, intAttribs); if (!images[0]) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "eglCreateImageKHR() Failed: %d", eglGetError()); goto fail; } } return 1; fail: freeEGLImages(dpy, images); return -1; } void DrmRenderer::freeEGLImages(EGLDisplay dpy, EGLImage images[EGL_MAX_PLANES]) { if (m_eglDestroyImage) { m_eglDestroyImage(dpy, images[0]); } else { m_eglDestroyImageKHR(dpy, images[0]); } // Our EGLImages are non-planar SDL_assert(images[1] == 0); SDL_assert(images[2] == 0); } #endif