#ifndef LIFTOFF_H #define LIFTOFF_H #include #include #include #include #include struct liftoff_device; struct liftoff_output; struct liftoff_layer; /** * Initialize libliftoff for a DRM node. * * The node is expected to have DRM_CLIENT_CAP_UNIVERSAL_PLANES and * DRM_CLIENT_CAP_ATOMIC enabled. */ struct liftoff_device *liftoff_device_create(int drm_fd); /** * Destroy a libliftoff device. * * The caller is expected to destroy the outputs and layers explicitly. */ void liftoff_device_destroy(struct liftoff_device *device); /** * Build a layer to plane mapping and append the plane configuration to `req`. * * Callers are expected to commit `req` afterwards and can read the layer to * plane mapping with `liftoff_layer_get_plane_id`. * * `flags` is the atomic commit flags the caller intends to use. */ bool liftoff_output_apply(struct liftoff_output *output, drmModeAtomicReq *req, uint32_t flags); /** * Make the device manage a CRTC's planes. * * The returned output allows callers to attach layers. */ struct liftoff_output *liftoff_output_create(struct liftoff_device *device, uint32_t crtc_id); /** * Destroy a libliftoff output. * * The caller is expected to destroy the output's layers explicitly. */ void liftoff_output_destroy(struct liftoff_output *output); /** * Indicate on which layer composition can take place. * * Users should be able to blend layers that haven't been mapped to a plane to * this layer. The composition layer won't be used if all other layers have been * mapped to a plane. There is at most one composition layer per output. */ void liftoff_output_set_composition_layer(struct liftoff_output *output, struct liftoff_layer *layer); /** * Create a new layer on an output. * * A layer is a virtual plane. Users can create as many layers as they want and * set any KMS property on them, without any constraint. libliftoff will try * to map layers to hardware planes on a best-effort basis. The user will need * to manually handle layers that couldn't be mapped to a plane. */ struct liftoff_layer *liftoff_layer_create(struct liftoff_output *output); /** * Destroy a layer. */ void liftoff_layer_destroy(struct liftoff_layer *layer); /** * Set a property on the layer. * * Any plane property can be set (except CRTC_ID). If none of the planes support * the property, the layer won't be mapped to any plane. * * Setting a zero FB_ID disables the layer. */ void liftoff_layer_set_property(struct liftoff_layer *layer, const char *name, uint64_t value); /** * Force composition on this layer. * * This unsets any previous FB_ID value. To switch back to direct scan-out, set * FB_ID again. * * This can be used when no KMS FB ID is available for this layer but it still * needs to be displayed (e.g. the buffer cannot be imported in KMS). */ void liftoff_layer_set_fb_composited(struct liftoff_layer *layer); /** * Retrieve the plane mapped to this layer. * * Zero is returned if no plane is mapped. */ uint32_t liftoff_layer_get_plane_id(struct liftoff_layer *layer); enum liftoff_log_importance { LIFTOFF_SILENT, LIFTOFF_ERROR, LIFTOFF_DEBUG, }; typedef void (*liftoff_log_func)(enum liftoff_log_importance importance, const char *fmt, va_list args); /** * Initialize libliftoff's log infrastructure. * * Only messages with a priority higher than the provided `verbosity` will be * logged. If `callback` is non-NULL, libliftoff will call the function instead * of printing the messages to stderr. */ void liftoff_log_init(enum liftoff_log_importance verbosity, liftoff_log_func callback); #endif