#include "../include/utils.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include double clock_get_monotonic_seconds(void) { struct timespec ts; ts.tv_sec = 0; ts.tv_nsec = 0; clock_gettime(CLOCK_MONOTONIC, &ts); return (double)ts.tv_sec + (double)ts.tv_nsec * 0.000000001; } static gsr_monitor_rotation wayland_transform_to_gsr_rotation(int32_t rot) { switch(rot) { case 0: return GSR_MONITOR_ROT_0; case 1: return GSR_MONITOR_ROT_90; case 2: return GSR_MONITOR_ROT_180; case 3: return GSR_MONITOR_ROT_270; } return GSR_MONITOR_ROT_0; } static const XRRModeInfo* get_mode_info(const XRRScreenResources *sr, RRMode id) { for(int i = 0; i < sr->nmode; ++i) { if(sr->modes[i].id == id) return &sr->modes[i]; } return NULL; } static gsr_monitor_rotation x11_rotation_to_gsr_rotation(int rot) { switch(rot) { case RR_Rotate_0: return GSR_MONITOR_ROT_0; case RR_Rotate_90: return GSR_MONITOR_ROT_90; case RR_Rotate_180: return GSR_MONITOR_ROT_180; case RR_Rotate_270: return GSR_MONITOR_ROT_270; } return GSR_MONITOR_ROT_0; } static uint32_t x11_output_get_connector_id(Display *dpy, RROutput output, Atom randr_connector_id_atom) { Atom type = 0; int format = 0; unsigned long bytes_after = 0; unsigned long nitems = 0; unsigned char *prop = NULL; XRRGetOutputProperty(dpy, output, randr_connector_id_atom, 0, 128, false, false, AnyPropertyType, &type, &format, &nitems, &bytes_after, &prop); long result = 0; if(type == XA_INTEGER && format == 32) result = *(long*)prop; free(prop); return result; } static vec2i get_monitor_size_rotated(int width, int height, gsr_monitor_rotation rotation) { vec2i size = { .x = width, .y = height }; if(rotation == GSR_MONITOR_ROT_90 || rotation == GSR_MONITOR_ROT_270) { int tmp_x = size.x; size.x = size.y; size.y = tmp_x; } return size; } void for_each_active_monitor_output_x11_not_cached(Display *display, active_monitor_callback callback, void *userdata) { XRRScreenResources *screen_res = XRRGetScreenResources(display, DefaultRootWindow(display)); if(!screen_res) return; const Atom randr_connector_id_atom = XInternAtom(display, "CONNECTOR_ID", False); char display_name[256]; for(int i = 0; i < screen_res->noutput; ++i) { XRROutputInfo *out_info = XRRGetOutputInfo(display, screen_res, screen_res->outputs[i]); if(out_info && out_info->crtc && out_info->connection == RR_Connected) { XRRCrtcInfo *crt_info = XRRGetCrtcInfo(display, screen_res, out_info->crtc); if(crt_info && crt_info->mode) { // We want to use the current mode info width/height (mode_info->width/height) instead of crtc info width/height (crt_info->width/height) because crtc info // is scaled if the monitor is scaled (xrandr --output DP-1 --scale 1.5). Normally this is not an issue for x11 applications, // but gpu screen recorder captures the drm framebuffer instead of x11 api. This drm framebuffer which doesn't increase in size when using xrandr scaling. // Maybe a better option would be to get the drm crtc size instead. const XRRModeInfo *mode_info = get_mode_info(screen_res, crt_info->mode); if(mode_info && out_info->nameLen < (int)sizeof(display_name)) { snprintf(display_name, sizeof(display_name), "%.*s", (int)out_info->nameLen, out_info->name); const gsr_monitor_rotation rotation = x11_rotation_to_gsr_rotation(crt_info->rotation); const vec2i monitor_size = get_monitor_size_rotated(mode_info->width, mode_info->height, rotation); const gsr_monitor monitor = { .name = display_name, .name_len = out_info->nameLen, .pos = { .x = crt_info->x, .y = crt_info->y }, .size = monitor_size, .connector_id = x11_output_get_connector_id(display, screen_res->outputs[i], randr_connector_id_atom), .rotation = rotation, .monitor_identifier = out_info->crtc }; callback(&monitor, userdata); } } if(crt_info) XRRFreeCrtcInfo(crt_info); } if(out_info) XRRFreeOutputInfo(out_info); } XRRFreeScreenResources(screen_res); } void for_each_active_monitor_output_x11(const gsr_egl *egl, active_monitor_callback callback, void *userdata) { for(int i = 0; i < egl->x11.num_outputs; ++i) { const gsr_x11_output *output = &egl->x11.outputs[i]; const gsr_monitor monitor = { .name = output->name, .name_len = strlen(output->name), .pos = output->pos, .size = output->size, .connector_id = output->connector_id, .rotation = output->rotation, .monitor_identifier = output->monitor_identifier }; callback(&monitor, userdata); } } typedef struct { int type; int count; int count_active; } drm_connector_type_count; #define CONNECTOR_TYPE_COUNTS 32 static drm_connector_type_count* drm_connector_types_get_index(drm_connector_type_count *type_counts, int *num_type_counts, int connector_type) { for(int i = 0; i < *num_type_counts; ++i) { if(type_counts[i].type == connector_type) return &type_counts[i]; } if(*num_type_counts == CONNECTOR_TYPE_COUNTS) return NULL; const int index = *num_type_counts; type_counts[index].type = connector_type; type_counts[index].count = 0; type_counts[index].count_active = 0; ++*num_type_counts; return &type_counts[index]; } static bool connector_get_property_by_name(int drmfd, drmModeConnectorPtr props, const char *name, uint64_t *result) { for(int i = 0; i < props->count_props; ++i) { drmModePropertyPtr prop = drmModeGetProperty(drmfd, props->props[i]); if(prop) { if(strcmp(name, prop->name) == 0) { *result = props->prop_values[i]; drmModeFreeProperty(prop); return true; } drmModeFreeProperty(prop); } } return false; } /* TODO: Support more connector types */ static int get_connector_type_by_name(const char *name) { int len = strlen(name); if(len >= 5 && strncmp(name, "HDMI-", 5) == 0) return 1; else if(len >= 3 && strncmp(name, "DP-", 3) == 0) return 2; else if(len >= 12 && strncmp(name, "DisplayPort-", 12) == 0) return 3; else if(len >= 4 && strncmp(name, "eDP-", 4) == 0) return 4; else return -1; } static uint32_t monitor_identifier_from_type_and_count(int monitor_type_index, int monitor_type_count) { return ((uint32_t)monitor_type_index << 16) | ((uint32_t)monitor_type_count); } static void for_each_active_monitor_output_wayland(const gsr_egl *egl, active_monitor_callback callback, void *userdata) { drm_connector_type_count type_counts[CONNECTOR_TYPE_COUNTS]; int num_type_counts = 0; for(int i = 0; i < egl->wayland.num_outputs; ++i) { const gsr_wayland_output *output = &egl->wayland.outputs[i]; if(!output->name) continue; const int connector_type_index = get_connector_type_by_name(output->name); drm_connector_type_count *connector_type = NULL; if(connector_type_index != -1) connector_type = drm_connector_types_get_index(type_counts, &num_type_counts, connector_type_index); if(connector_type) { ++connector_type->count; ++connector_type->count_active; } const gsr_monitor monitor = { .name = output->name, .name_len = strlen(output->name), .pos = { .x = output->pos.x, .y = output->pos.y }, .size = { .x = output->size.x, .y = output->size.y }, .connector_id = 0, .rotation = wayland_transform_to_gsr_rotation(output->transform), .monitor_identifier = connector_type ? monitor_identifier_from_type_and_count(connector_type_index, connector_type->count_active) : 0 }; callback(&monitor, userdata); } } static void for_each_active_monitor_output_drm(const gsr_egl *egl, active_monitor_callback callback, void *userdata) { int fd = open(egl->card_path, O_RDONLY); if(fd == -1) return; drmSetClientCap(fd, DRM_CLIENT_CAP_ATOMIC, 1); drm_connector_type_count type_counts[CONNECTOR_TYPE_COUNTS]; int num_type_counts = 0; char display_name[256]; drmModeResPtr resources = drmModeGetResources(fd); if(resources) { for(int i = 0; i < resources->count_connectors; ++i) { drmModeConnectorPtr connector = drmModeGetConnectorCurrent(fd, resources->connectors[i]); if(!connector) continue; drm_connector_type_count *connector_type = drm_connector_types_get_index(type_counts, &num_type_counts, connector->connector_type); const char *connection_name = drmModeGetConnectorTypeName(connector->connector_type); const int connection_name_len = strlen(connection_name); if(connector_type) ++connector_type->count; if(connector->connection != DRM_MODE_CONNECTED) { drmModeFreeConnector(connector); continue; } if(connector_type) ++connector_type->count_active; uint64_t crtc_id = 0; connector_get_property_by_name(fd, connector, "CRTC_ID", &crtc_id); drmModeCrtcPtr crtc = drmModeGetCrtc(fd, crtc_id); if(connector_type && crtc_id > 0 && crtc && connection_name_len + 5 < (int)sizeof(display_name)) { const int display_name_len = snprintf(display_name, sizeof(display_name), "%s-%d", connection_name, connector_type->count); const int connector_type_index_name = get_connector_type_by_name(display_name); gsr_monitor monitor = { .name = display_name, .name_len = display_name_len, .pos = { .x = crtc->x, .y = crtc->y }, .size = { .x = (int)crtc->width, .y = (int)crtc->height }, .connector_id = connector->connector_id, .rotation = GSR_MONITOR_ROT_0, .monitor_identifier = connector_type_index_name != -1 ? monitor_identifier_from_type_and_count(connector_type_index_name, connector_type->count_active) : 0 }; callback(&monitor, userdata); } if(crtc) drmModeFreeCrtc(crtc); drmModeFreeConnector(connector); } drmModeFreeResources(resources); } close(fd); } void for_each_active_monitor_output(const gsr_egl *egl, gsr_connection_type connection_type, active_monitor_callback callback, void *userdata) { switch(connection_type) { case GSR_CONNECTION_X11: for_each_active_monitor_output_x11(egl, callback, userdata); break; case GSR_CONNECTION_WAYLAND: for_each_active_monitor_output_wayland(egl, callback, userdata); break; case GSR_CONNECTION_DRM: for_each_active_monitor_output_drm(egl, callback, userdata); break; } } static void get_monitor_by_name_callback(const gsr_monitor *monitor, void *userdata) { get_monitor_by_name_userdata *data = (get_monitor_by_name_userdata*)userdata; if(!data->found_monitor && strcmp(data->name, monitor->name) == 0) { data->monitor->pos = monitor->pos; data->monitor->size = monitor->size; data->monitor->connector_id = monitor->connector_id; data->monitor->rotation = monitor->rotation; data->monitor->monitor_identifier = monitor->monitor_identifier; data->found_monitor = true; } } bool get_monitor_by_name(const gsr_egl *egl, gsr_connection_type connection_type, const char *name, gsr_monitor *monitor) { get_monitor_by_name_userdata userdata; userdata.name = name; userdata.name_len = strlen(name); userdata.monitor = monitor; userdata.found_monitor = false; for_each_active_monitor_output(egl, connection_type, get_monitor_by_name_callback, &userdata); return userdata.found_monitor; } typedef struct { const gsr_monitor *monitor; gsr_monitor_rotation rotation; bool match_found; } get_monitor_by_connector_id_userdata; static bool vec2i_eql(vec2i a, vec2i b) { return a.x == b.x && a.y == b.y; } static void get_monitor_by_name_and_size_callback(const gsr_monitor *monitor, void *userdata) { get_monitor_by_connector_id_userdata *data = (get_monitor_by_connector_id_userdata*)userdata; if(monitor->name && data->monitor->name && strcmp(monitor->name, data->monitor->name) == 0 && vec2i_eql(monitor->size, data->monitor->size)) { data->rotation = monitor->rotation; data->match_found = true; } } static void get_monitor_by_connector_id_callback(const gsr_monitor *monitor, void *userdata) { get_monitor_by_connector_id_userdata *data = (get_monitor_by_connector_id_userdata*)userdata; if(monitor->connector_id == data->monitor->connector_id || (!monitor->connector_id && monitor->monitor_identifier == data->monitor->monitor_identifier)) { data->rotation = monitor->rotation; data->match_found = true; } } gsr_monitor_rotation drm_monitor_get_display_server_rotation(const gsr_egl *egl, const gsr_monitor *monitor) { if(gsr_egl_get_display_server(egl) == GSR_DISPLAY_SERVER_WAYLAND) { { get_monitor_by_connector_id_userdata userdata; userdata.monitor = monitor; userdata.rotation = GSR_MONITOR_ROT_0; userdata.match_found = false; for_each_active_monitor_output_wayland(egl, get_monitor_by_name_and_size_callback, &userdata); if(userdata.match_found) return userdata.rotation; } { get_monitor_by_connector_id_userdata userdata; userdata.monitor = monitor; userdata.rotation = GSR_MONITOR_ROT_0; userdata.match_found = false; for_each_active_monitor_output_wayland(egl, get_monitor_by_connector_id_callback, &userdata); return userdata.rotation; } } else { get_monitor_by_connector_id_userdata userdata; userdata.monitor = monitor; userdata.rotation = GSR_MONITOR_ROT_0; userdata.match_found = false; for_each_active_monitor_output_x11(egl, get_monitor_by_connector_id_callback, &userdata); return userdata.rotation; } return GSR_MONITOR_ROT_0; } bool gl_get_gpu_info(gsr_egl *egl, gsr_gpu_info *info) { const char *software_renderers[] = { "llvmpipe", "SWR", "softpipe", NULL }; bool supported = true; const unsigned char *gl_vendor = egl->glGetString(GL_VENDOR); const unsigned char *gl_renderer = egl->glGetString(GL_RENDERER); info->gpu_version = 0; info->is_steam_deck = false; if(!gl_vendor) { fprintf(stderr, "gsr error: failed to get gpu vendor\n"); supported = false; goto end; } if(gl_renderer) { for(int i = 0; software_renderers[i]; ++i) { if(strstr((const char*)gl_renderer, software_renderers[i])) { fprintf(stderr, "gsr error: your opengl environment is not properly setup. It's using %s (software rendering) for opengl instead of your graphics card. Please make sure your graphics driver is properly installed\n", software_renderers[i]); supported = false; goto end; } } } if(strstr((const char*)gl_vendor, "AMD")) info->vendor = GSR_GPU_VENDOR_AMD; else if(strstr((const char*)gl_vendor, "Mesa") && gl_renderer && strstr((const char*)gl_renderer, "AMD")) info->vendor = GSR_GPU_VENDOR_AMD; else if(strstr((const char*)gl_vendor, "Intel")) info->vendor = GSR_GPU_VENDOR_INTEL; else if(strstr((const char*)gl_vendor, "NVIDIA")) info->vendor = GSR_GPU_VENDOR_NVIDIA; else { fprintf(stderr, "gsr error: unknown gpu vendor: %s\n", gl_vendor); supported = false; goto end; } if(gl_renderer) { if(info->vendor == GSR_GPU_VENDOR_NVIDIA) sscanf((const char*)gl_renderer, "%*s %*s %*s %d", &info->gpu_version); info->is_steam_deck = strstr((const char*)gl_renderer, "vangogh") != NULL; } end: return supported; } static bool try_card_has_valid_plane(const char *card_path) { drmVersion *ver = NULL; drmModePlaneResPtr planes = NULL; bool found_screen_card = false; int fd = open(card_path, O_RDONLY); if(fd == -1) return false; ver = drmGetVersion(fd); if(!ver || strstr(ver->name, "nouveau")) goto next; drmSetClientCap(fd, DRM_CLIENT_CAP_UNIVERSAL_PLANES, 1); planes = drmModeGetPlaneResources(fd); if(!planes) goto next; for(uint32_t j = 0; j < planes->count_planes; ++j) { drmModePlanePtr plane = drmModeGetPlane(fd, planes->planes[j]); if(!plane) continue; if(plane->fb_id) found_screen_card = true; drmModeFreePlane(plane); if(found_screen_card) break; } next: if(planes) drmModeFreePlaneResources(planes); if(ver) drmFreeVersion(ver); close(fd); if(found_screen_card) return true; return false; } bool gsr_get_valid_card_path(gsr_egl *egl, char *output, bool is_monitor_capture) { if(egl->dri_card_path) { snprintf(output, 128, "%s", egl->dri_card_path); return is_monitor_capture ? try_card_has_valid_plane(output) : true; } for(int i = 0; i < 10; ++i) { snprintf(output, 128, DRM_DEV_NAME, DRM_DIR_NAME, i); if(try_card_has_valid_plane(output)) return true; } return false; } bool gsr_card_path_get_render_path(const char *card_path, char *render_path) { int fd = open(card_path, O_RDONLY); if(fd == -1) return false; char *render_path_tmp = drmGetRenderDeviceNameFromFd(fd); if(render_path_tmp) { snprintf(render_path, 128, "%s", render_path_tmp); free(render_path_tmp); close(fd); return true; } close(fd); return false; } int create_directory_recursive(char *path) { int path_len = strlen(path); char *p = path; char *end = path + path_len; for(;;) { char *slash_p = strchr(p, '/'); // Skips first '/', we don't want to try and create the root directory if(slash_p == path) { ++p; continue; } if(!slash_p) slash_p = end; char prev_char = *slash_p; *slash_p = '\0'; int err = mkdir(path, S_IRWXU); *slash_p = prev_char; if(err == -1 && errno != EEXIST) return err; if(slash_p == end) break; else p = slash_p + 1; } return 0; } void setup_dma_buf_attrs(intptr_t *img_attr, uint32_t format, uint32_t width, uint32_t height, const int *fds, const uint32_t *offsets, const uint32_t *pitches, const uint64_t *modifiers, int num_planes, bool use_modifier) { size_t img_attr_index = 0; img_attr[img_attr_index++] = EGL_LINUX_DRM_FOURCC_EXT; img_attr[img_attr_index++] = format; img_attr[img_attr_index++] = EGL_WIDTH; img_attr[img_attr_index++] = width; img_attr[img_attr_index++] = EGL_HEIGHT; img_attr[img_attr_index++] = height; if(num_planes >= 1) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE0_FD_EXT; img_attr[img_attr_index++] = fds[0]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE0_OFFSET_EXT; img_attr[img_attr_index++] = offsets[0]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE0_PITCH_EXT; img_attr[img_attr_index++] = pitches[0]; if(use_modifier) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE0_MODIFIER_LO_EXT; img_attr[img_attr_index++] = modifiers[0] & 0xFFFFFFFFULL; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE0_MODIFIER_HI_EXT; img_attr[img_attr_index++] = modifiers[0] >> 32ULL; } } if(num_planes >= 2) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE1_FD_EXT; img_attr[img_attr_index++] = fds[1]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE1_OFFSET_EXT; img_attr[img_attr_index++] = offsets[1]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE1_PITCH_EXT; img_attr[img_attr_index++] = pitches[1]; if(use_modifier) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE1_MODIFIER_LO_EXT; img_attr[img_attr_index++] = modifiers[1] & 0xFFFFFFFFULL; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE1_MODIFIER_HI_EXT; img_attr[img_attr_index++] = modifiers[1] >> 32ULL; } } if(num_planes >= 3) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE2_FD_EXT; img_attr[img_attr_index++] = fds[2]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE2_OFFSET_EXT; img_attr[img_attr_index++] = offsets[2]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE2_PITCH_EXT; img_attr[img_attr_index++] = pitches[2]; if(use_modifier) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE2_MODIFIER_LO_EXT; img_attr[img_attr_index++] = modifiers[2] & 0xFFFFFFFFULL; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE2_MODIFIER_HI_EXT; img_attr[img_attr_index++] = modifiers[2] >> 32ULL; } } if(num_planes >= 4) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE3_FD_EXT; img_attr[img_attr_index++] = fds[3]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE3_OFFSET_EXT; img_attr[img_attr_index++] = offsets[3]; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE3_PITCH_EXT; img_attr[img_attr_index++] = pitches[3]; if(use_modifier) { img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE3_MODIFIER_LO_EXT; img_attr[img_attr_index++] = modifiers[3] & 0xFFFFFFFFULL; img_attr[img_attr_index++] = EGL_DMA_BUF_PLANE3_MODIFIER_HI_EXT; img_attr[img_attr_index++] = modifiers[3] >> 32ULL; } } img_attr[img_attr_index++] = EGL_NONE; assert(img_attr_index <= 44); } static VADisplay video_codec_context_get_vaapi_display(AVCodecContext *video_codec_context) { AVBufferRef *hw_frames_ctx = video_codec_context->hw_frames_ctx; if(!hw_frames_ctx) return NULL; AVHWFramesContext *hw_frame_context = (AVHWFramesContext*)hw_frames_ctx->data; AVHWDeviceContext *device_context = (AVHWDeviceContext*)hw_frame_context->device_ctx; if(device_context->type != AV_HWDEVICE_TYPE_VAAPI) return NULL; AVVAAPIDeviceContext *vactx = device_context->hwctx; return vactx->display; } bool video_codec_context_is_vaapi(AVCodecContext *video_codec_context) { AVBufferRef *hw_frames_ctx = video_codec_context->hw_frames_ctx; if(!hw_frames_ctx) return NULL; AVHWFramesContext *hw_frame_context = (AVHWFramesContext*)hw_frames_ctx->data; AVHWDeviceContext *device_context = (AVHWDeviceContext*)hw_frame_context->device_ctx; return device_context->type == AV_HWDEVICE_TYPE_VAAPI; } static uint32_t drm_fourcc_to_va_fourcc(uint32_t drm_fourcc) { switch(drm_fourcc) { case DRM_FORMAT_XRGB8888: return VA_FOURCC_BGRX; case DRM_FORMAT_XBGR8888: return VA_FOURCC_RGBX; case DRM_FORMAT_RGBX8888: return VA_FOURCC_XBGR; case DRM_FORMAT_BGRX8888: return VA_FOURCC_XRGB; case DRM_FORMAT_ARGB8888: return VA_FOURCC_BGRA; case DRM_FORMAT_ABGR8888: return VA_FOURCC_RGBA; case DRM_FORMAT_RGBA8888: return VA_FOURCC_ABGR; case DRM_FORMAT_BGRA8888: return VA_FOURCC_ARGB; default: return drm_fourcc; } } bool vaapi_copy_drm_planes_to_video_surface(AVCodecContext *video_codec_context, AVFrame *video_frame, vec2i source_pos, vec2i source_size, vec2i dest_pos, vec2i dest_size, uint32_t format, vec2i size, const int *fds, const uint32_t *offsets, const uint32_t *pitches, const uint64_t *modifiers, int num_planes) { VAConfigID config_id = 0; VAContextID context_id = 0; VASurfaceID input_surface_id = 0; VABufferID buffer_id = 0; bool success = true; VADisplay va_dpy = video_codec_context_get_vaapi_display(video_codec_context); if(!va_dpy) { success = false; goto done; } VAStatus va_status = vaCreateConfig(va_dpy, VAProfileNone, VAEntrypointVideoProc, NULL, 0, &config_id); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaCreateConfig failed, error: %s\n", vaErrorStr(va_status)); success = false; goto done; } VASurfaceID output_surface_id = (uintptr_t)video_frame->data[3]; va_status = vaCreateContext(va_dpy, config_id, size.x, size.y, VA_PROGRESSIVE, &output_surface_id, 1, &context_id); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaCreateContext failed, error: %s\n", vaErrorStr(va_status)); success = false; goto done; } VADRMPRIMESurfaceDescriptor buf = {0}; buf.fourcc = drm_fourcc_to_va_fourcc(format);//VA_FOURCC_BGRX; // TODO: VA_FOURCC_BGRA, VA_FOURCC_X2R10G10B10 buf.width = size.x; buf.height = size.y; buf.num_objects = num_planes; buf.num_layers = 1; buf.layers[0].drm_format = format; buf.layers[0].num_planes = buf.num_objects; for(int i = 0; i < num_planes; ++i) { buf.objects[i].fd = fds[i]; buf.objects[i].size = size.y * pitches[i]; // TODO: buf.objects[i].drm_format_modifier = modifiers[i]; buf.layers[0].object_index[i] = i; buf.layers[0].offset[i] = offsets[i]; buf.layers[0].pitch[i] = pitches[i]; } VASurfaceAttrib attribs[2] = {0}; attribs[0].type = VASurfaceAttribMemoryType; attribs[0].flags = VA_SURFACE_ATTRIB_SETTABLE; attribs[0].value.type = VAGenericValueTypeInteger; attribs[0].value.value.i = VA_SURFACE_ATTRIB_MEM_TYPE_DRM_PRIME_2; attribs[1].type = VASurfaceAttribExternalBufferDescriptor; attribs[1].flags = VA_SURFACE_ATTRIB_SETTABLE; attribs[1].value.type = VAGenericValueTypePointer; attribs[1].value.value.p = &buf; // TODO: RT_FORMAT with 10 bit/hdr, VA_RT_FORMAT_RGB32_10 // TODO: Max size same as source_size va_status = vaCreateSurfaces(va_dpy, VA_RT_FORMAT_RGB32, size.x, size.y, &input_surface_id, 1, attribs, 2); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaCreateSurfaces failed, error: %s\n", vaErrorStr(va_status)); success = false; goto done; } const VARectangle source_region = { .x = source_pos.x, .y = source_pos.y, .width = source_size.x, .height = source_size.y }; const VARectangle output_region = { .x = dest_pos.x, .y = dest_pos.y, .width = dest_size.x, .height = dest_size.y }; const bool scaled = dest_size.x != source_size.x || dest_size.y != source_size.y; // Copying a surface to another surface will automatically perform the color conversion. Thanks vaapi! VAProcPipelineParameterBuffer params = {0}; params.surface = input_surface_id; params.surface_region = NULL; params.surface_region = &source_region; params.output_region = &output_region; params.output_background_color = 0; params.filter_flags = scaled ? (VA_FILTER_SCALING_HQ | VA_FILTER_INTERPOLATION_BILINEAR) : 0; params.pipeline_flags = VA_PROC_PIPELINE_FAST; params.input_color_properties.colour_primaries = 1; params.input_color_properties.transfer_characteristics = 1; params.input_color_properties.matrix_coefficients = 1; params.surface_color_standard = VAProcColorStandardBT709; // TODO: params.input_color_properties.color_range = video_frame->color_range == AVCOL_RANGE_JPEG ? VA_SOURCE_RANGE_FULL : VA_SOURCE_RANGE_REDUCED; params.output_color_properties.colour_primaries = 1; params.output_color_properties.transfer_characteristics = 1; params.output_color_properties.matrix_coefficients = 1; params.output_color_standard = VAProcColorStandardBT709; // TODO: params.output_color_properties.color_range = video_frame->color_range == AVCOL_RANGE_JPEG ? VA_SOURCE_RANGE_FULL : VA_SOURCE_RANGE_REDUCED; params.processing_mode = VAProcPerformanceMode; // VAProcPipelineCaps pipeline_caps = {0}; // va_status = vaQueryVideoProcPipelineCaps(self->va_dpy, // self->context_id, // NULL, 0, // &pipeline_caps); // if(va_status == VA_STATUS_SUCCESS) { // fprintf(stderr, "pipeline_caps: %u, %u\n", (unsigned int)pipeline_caps.rotation_flags, pipeline_caps.blend_flags); // } // TODO: params.output_hdr_metadata // TODO: // if (first surface to render) // pipeline_param->output_background_color = 0xff000000; // black va_status = vaCreateBuffer(va_dpy, context_id, VAProcPipelineParameterBufferType, sizeof(params), 1, ¶ms, &buffer_id); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaCreateBuffer failed, error: %d\n", va_status); success = false; goto done; } va_status = vaBeginPicture(va_dpy, context_id, output_surface_id); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaBeginPicture failed, error: %d\n", va_status); success = false; goto done; } va_status = vaRenderPicture(va_dpy, context_id, &buffer_id, 1); if(va_status != VA_STATUS_SUCCESS) { vaEndPicture(va_dpy, context_id); fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaRenderPicture failed, error: %d\n", va_status); success = false; goto done; } va_status = vaEndPicture(va_dpy, context_id); if(va_status != VA_STATUS_SUCCESS) { fprintf(stderr, "gsr error: vaapi_copy_drm_planes_to_video_surface: vaEndPicture failed, error: %d\n", va_status); success = false; goto done; } // vaSyncBuffer(va_dpy, buffer_id, 1000 * 1000 * 1000); // vaSyncSurface(va_dpy, input_surface_id); // vaSyncSurface(va_dpy, output_surface_id); done: if(buffer_id) vaDestroyBuffer(va_dpy, buffer_id); if(input_surface_id) vaDestroySurfaces(va_dpy, &input_surface_id, 1); if(context_id) vaDestroyContext(va_dpy, context_id); if(config_id) vaDestroyConfig(va_dpy, config_id); return success; } bool vaapi_copy_egl_image_to_video_surface(gsr_egl *egl, EGLImage image, vec2i source_pos, vec2i source_size, vec2i dest_pos, vec2i dest_size, AVCodecContext *video_codec_context, AVFrame *video_frame) { if(!image) return false; int texture_fourcc = 0; int texture_num_planes = 0; uint64_t texture_modifiers = 0; if(!egl->eglExportDMABUFImageQueryMESA(egl->egl_display, image, &texture_fourcc, &texture_num_planes, &texture_modifiers)) { fprintf(stderr, "gsr error: gsr_capture_xcomposite_vaapi_tick: eglExportDMABUFImageQueryMESA failed\n"); return false; } if(texture_num_planes <= 0 || texture_num_planes > 8) { fprintf(stderr, "gsr error: gsr_capture_xcomposite_vaapi_tick: expected planes size to be 0eglGetError() != EGL_SUCCESS){} if(!egl->eglExportDMABUFImageMESA(egl->egl_display, image, texture_fds, texture_strides, texture_offsets)) { fprintf(stderr, "gsr error: gsr_capture_xcomposite_vaapi_tick: eglExportDMABUFImageMESA failed, error: %d\n", egl->eglGetError()); return false; } int fds[8]; uint32_t offsets[8]; uint32_t pitches[8]; uint64_t modifiers[8]; for(int i = 0; i < texture_num_planes; ++i) { fds[i] = texture_fds[i]; offsets[i] = texture_offsets[i]; pitches[i] = texture_strides[i]; modifiers[i] = texture_modifiers; if(fds[i] == -1) texture_num_planes = i; } const bool success = texture_num_planes > 0 && vaapi_copy_drm_planes_to_video_surface(video_codec_context, video_frame, source_pos, source_size, dest_pos, dest_size, texture_fourcc, source_size, fds, offsets, pitches, modifiers, texture_num_planes); for(int i = 0; i < texture_num_planes; ++i) { if(texture_fds[i] > 0) { close(texture_fds[i]); texture_fds[i] = -1; } } return success; } vec2i scale_keep_aspect_ratio(vec2i from, vec2i to) { if(from.x == 0 || from.y == 0) return (vec2i){0, 0}; const double height_to_width_ratio = (double)from.y / (double)from.x; from.x = to.x; from.y = from.x * height_to_width_ratio; if(from.y > to.y) { const double width_height_ratio = (double)from.x / (double)from.y; from.y = to.y; from.x = from.y * width_height_ratio; } return from; }