src/wayland-client-core.h - external/anongit.freedesktop.org/git/wayland/wayland - Git at Google

 /*
  * Copyright © 2008 Kristian Høgsberg
  *
  * Permission is hereby granted, free of charge, to any person obtaining
  * a copy of this software and associated documentation files (the
  * "Software"), to deal in the Software without restriction, including
  * without limitation the rights to use, copy, modify, merge, publish,
  * distribute, sublicense, and/or sell copies of the Software, and to
  * permit persons to whom the Software is furnished to do so, subject to
  * the following conditions:
  *
  * The above copyright notice and this permission notice (including the
  * next paragraph) shall be included in all copies or substantial
  * portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
  * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
  * NONINFRINGEMENT.  IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
  * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
  * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
  * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
  * SOFTWARE.
  */

 #ifndef WAYLAND_CLIENT_CORE_H
 #define WAYLAND_CLIENT_CORE_H

 #include <stdint.h>
 #include "wayland-util.h"
 #include "wayland-version.h"

 #ifdef  __cplusplus
 extern "C" {
 #endif

 /** \class wl_proxy
  *
  * \brief Represents a protocol object on the client side.
  *
  * A wl_proxy acts as a client side proxy to an object existing in the
  * compositor. The proxy is responsible for converting requests made by the
  * clients with \ref wl_proxy_marshal() into Wayland's wire format. Events
  * coming from the compositor are also handled by the proxy, which will in
  * turn call the handler set with \ref wl_proxy_add_listener().
  *
  * \note With the exception of function \ref wl_proxy_set_queue(), functions
  * accessing a wl_proxy are not normally used by client code. Clients
  * should normally use the higher level interface generated by the scanner to
  * interact with compositor objects.
  *
  */
 struct wl_proxy;

 /** \class wl_display
  *
  * \brief Represents a connection to the compositor and acts as a proxy to
  * the wl_display singleton object.
  *
  * A wl_display object represents a client connection to a Wayland
  * compositor. It is created with either \ref wl_display_connect() or
  * \ref wl_display_connect_to_fd(). A connection is terminated using
  * \ref wl_display_disconnect().
  *
  * A wl_display is also used as the \ref wl_proxy for the wl_display
  * singleton object on the compositor side.
  *
  * A wl_display object handles all the data sent from and to the
  * compositor. When a \ref wl_proxy marshals a request, it will write its wire
  * representation to the display's write buffer. The data is sent to the
  * compositor when the client calls \ref wl_display_flush().
  *
  * Incoming data is handled in two steps: queueing and dispatching. In the
  * queue step, the data coming from the display fd is interpreted and
  * added to a queue. On the dispatch step, the handler for the incoming
  * event set by the client on the corresponding \ref wl_proxy is called.
  *
  * A wl_display has at least one event queue, called the <em>default
  * queue</em>. Clients can create additional event queues with \ref
  * wl_display_create_queue() and assign \ref wl_proxy's to it. Events
  * occurring in a particular proxy are always queued in its assigned queue.
  * A client can ensure that a certain assumption, such as holding a lock
  * or running from a given thread, is true when a proxy event handler is
  * called by assigning that proxy to an event queue and making sure that
  * this queue is only dispatched when the assumption holds.
  *
  * The default queue is dispatched by calling \ref wl_display_dispatch().
  * This will dispatch any events queued on the default queue and attempt
  * to read from the display fd if it's empty. Events read are then queued
  * on the appropriate queues according to the proxy assignment.
  *
  * A user created queue is dispatched with \ref wl_display_dispatch_queue().
  * This function behaves exactly the same as wl_display_dispatch()
  * but it dispatches given queue instead of the default queue.
  *
  * A real world example of event queue usage is Mesa's implementation of
  * eglSwapBuffers() for the Wayland platform. This function might need
  * to block until a frame callback is received, but dispatching the default
  * queue could cause an event handler on the client to start drawing
  * again. This problem is solved using another event queue, so that only
  * the events handled by the EGL code are dispatched during the block.
  *
  * This creates a problem where a thread dispatches a non-default
  * queue, reading all the data from the display fd. If the application
  * would call \em poll(2) after that it would block, even though there
  * might be events queued on the default queue. Those events should be
  * dispatched with \ref wl_display_dispatch_pending() or \ref
  * wl_display_dispatch_queue_pending() before flushing and blocking.
  */
 struct wl_display;

 /** \class wl_event_queue
  *
  * \brief A queue for \ref wl_proxy object events.
  *
  * Event queues allows the events on a display to be handled in a thread-safe
  * manner. See \ref wl_display for details.
  *
  */
 struct wl_event_queue;

 void
 wl_event_queue_destroy(struct wl_event_queue *queue);

 void
 wl_proxy_marshal(struct wl_proxy *p, uint32_t opcode, ...);

 void
 wl_proxy_marshal_array(struct wl_proxy *p, uint32_t opcode,
 		       union wl_argument *args);

 struct wl_proxy *
 wl_proxy_create(struct wl_proxy *factory,
 		const struct wl_interface *interface);

 void *
 wl_proxy_create_wrapper(void *proxy);

 void
 wl_proxy_wrapper_destroy(void *proxy_wrapper);

 struct wl_proxy *
 wl_proxy_marshal_constructor(struct wl_proxy *proxy,
 			     uint32_t opcode,
 			     const struct wl_interface *interface,
 			     ...);

 struct wl_proxy *
 wl_proxy_marshal_constructor_versioned(struct wl_proxy *proxy,
 				       uint32_t opcode,
 				       const struct wl_interface *interface,
 				       uint32_t version,
 				       ...);

 struct wl_proxy *
 wl_proxy_marshal_array_constructor(struct wl_proxy *proxy,
 				   uint32_t opcode, union wl_argument *args,
 				   const struct wl_interface *interface);

 struct wl_proxy *
 wl_proxy_marshal_array_constructor_versioned(struct wl_proxy *proxy,
 					     uint32_t opcode,
 					     union wl_argument *args,
 					     const struct wl_interface *interface,
 					     uint32_t version);

 void
 wl_proxy_destroy(struct wl_proxy *proxy);

 int
 wl_proxy_add_listener(struct wl_proxy *proxy,
 		      void (**implementation)(void), void *data);

 const void *
 wl_proxy_get_listener(struct wl_proxy *proxy);

 int
 wl_proxy_add_dispatcher(struct wl_proxy *proxy,
 			wl_dispatcher_func_t dispatcher_func,
 			const void * dispatcher_data, void *data);

 void
 wl_proxy_set_user_data(struct wl_proxy *proxy, void *user_data);

 void *
 wl_proxy_get_user_data(struct wl_proxy *proxy);

 uint32_t
 wl_proxy_get_version(struct wl_proxy *proxy);

 uint32_t
 wl_proxy_get_id(struct wl_proxy *proxy);

 void
 wl_proxy_set_tag(struct wl_proxy *proxy,
 		 const char * const *tag);

 const char * const *
 wl_proxy_get_tag(struct wl_proxy *proxy);

 const char *
 wl_proxy_get_class(struct wl_proxy *proxy);

 void
 wl_proxy_set_queue(struct wl_proxy *proxy, struct wl_event_queue *queue);

 struct wl_display *
 wl_display_connect(const char *name);

 struct wl_display *
 wl_display_connect_to_fd(int fd);

 void
 wl_display_disconnect(struct wl_display *display);

 int
 wl_display_get_fd(struct wl_display *display);

 int
 wl_display_dispatch(struct wl_display *display);

 int
 wl_display_dispatch_queue(struct wl_display *display,
 			  struct wl_event_queue *queue);

 int
 wl_display_dispatch_queue_pending(struct wl_display *display,
 				  struct wl_event_queue *queue);

 int
 wl_display_dispatch_pending(struct wl_display *display);

 int
 wl_display_get_error(struct wl_display *display);

 uint32_t
 wl_display_get_protocol_error(struct wl_display *display,
 			      const struct wl_interface **interface,
 			      uint32_t *id);

 int
 wl_display_flush(struct wl_display *display);

 int
 wl_display_roundtrip_queue(struct wl_display *display,
 			   struct wl_event_queue *queue);

 int
 wl_display_roundtrip(struct wl_display *display);

 struct wl_event_queue *
 wl_display_create_queue(struct wl_display *display);

 int
 wl_display_prepare_read_queue(struct wl_display *display,
 			      struct wl_event_queue *queue);

 int
 wl_display_prepare_read(struct wl_display *display);

 void
 wl_display_cancel_read(struct wl_display *display);

 int
 wl_display_read_events(struct wl_display *display);

 void
 wl_log_set_handler_client(wl_log_func_t handler);

 #ifdef  __cplusplus
 }
 #endif

 #endif
	/*
	* Copyright © 2008 Kristian Høgsberg
	*
	* Permission is hereby granted, free of charge, to any person obtaining
	* a copy of this software and associated documentation files (the
	* "Software"), to deal in the Software without restriction, including
	* without limitation the rights to use, copy, modify, merge, publish,
	* distribute, sublicense, and/or sell copies of the Software, and to
	* permit persons to whom the Software is furnished to do so, subject to
	* the following conditions:
	*
	* The above copyright notice and this permission notice (including the
	* next paragraph) shall be included in all copies or substantial
	* portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
	* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
	* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
	* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
	* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
	* SOFTWARE.
	*/

	#ifndef WAYLAND_CLIENT_CORE_H
	#define WAYLAND_CLIENT_CORE_H

	#include <stdint.h>
	#include "wayland-util.h"
	#include "wayland-version.h"

	#ifdef __cplusplus
	extern "C" {
	#endif

	/** \class wl_proxy
	*
	* \brief Represents a protocol object on the client side.
	*
	* A wl_proxy acts as a client side proxy to an object existing in the
	* compositor. The proxy is responsible for converting requests made by the
	* clients with \ref wl_proxy_marshal() into Wayland's wire format. Events
	* coming from the compositor are also handled by the proxy, which will in
	* turn call the handler set with \ref wl_proxy_add_listener().
	*
	* \note With the exception of function \ref wl_proxy_set_queue(), functions
	* accessing a wl_proxy are not normally used by client code. Clients
	* should normally use the higher level interface generated by the scanner to
	* interact with compositor objects.
	*
	*/
	struct wl_proxy;

	/** \class wl_display
	*
	* \brief Represents a connection to the compositor and acts as a proxy to
	* the wl_display singleton object.
	*
	* A wl_display object represents a client connection to a Wayland
	* compositor. It is created with either \ref wl_display_connect() or
	* \ref wl_display_connect_to_fd(). A connection is terminated using
	* \ref wl_display_disconnect().
	*
	* A wl_display is also used as the \ref wl_proxy for the wl_display
	* singleton object on the compositor side.
	*
	* A wl_display object handles all the data sent from and to the
	* compositor. When a \ref wl_proxy marshals a request, it will write its wire
	* representation to the display's write buffer. The data is sent to the
	* compositor when the client calls \ref wl_display_flush().
	*
	* Incoming data is handled in two steps: queueing and dispatching. In the
	* queue step, the data coming from the display fd is interpreted and
	* added to a queue. On the dispatch step, the handler for the incoming
	* event set by the client on the corresponding \ref wl_proxy is called.
	*
	* A wl_display has at least one event queue, called the <em>default
	* queue</em>. Clients can create additional event queues with \ref
	* wl_display_create_queue() and assign \ref wl_proxy's to it. Events
	* occurring in a particular proxy are always queued in its assigned queue.
	* A client can ensure that a certain assumption, such as holding a lock
	* or running from a given thread, is true when a proxy event handler is
	* called by assigning that proxy to an event queue and making sure that
	* this queue is only dispatched when the assumption holds.
	*
	* The default queue is dispatched by calling \ref wl_display_dispatch().
	* This will dispatch any events queued on the default queue and attempt
	* to read from the display fd if it's empty. Events read are then queued
	* on the appropriate queues according to the proxy assignment.
	*
	* A user created queue is dispatched with \ref wl_display_dispatch_queue().
	* This function behaves exactly the same as wl_display_dispatch()
	* but it dispatches given queue instead of the default queue.
	*
	* A real world example of event queue usage is Mesa's implementation of
	* eglSwapBuffers() for the Wayland platform. This function might need
	* to block until a frame callback is received, but dispatching the default
	* queue could cause an event handler on the client to start drawing
	* again. This problem is solved using another event queue, so that only
	* the events handled by the EGL code are dispatched during the block.
	*
	* This creates a problem where a thread dispatches a non-default
	* queue, reading all the data from the display fd. If the application
	* would call \em poll(2) after that it would block, even though there
	* might be events queued on the default queue. Those events should be
	* dispatched with \ref wl_display_dispatch_pending() or \ref
	* wl_display_dispatch_queue_pending() before flushing and blocking.
	*/
	struct wl_display;

	/** \class wl_event_queue
	*
	* \brief A queue for \ref wl_proxy object events.
	*
	* Event queues allows the events on a display to be handled in a thread-safe
	* manner. See \ref wl_display for details.
	*
	*/
	struct wl_event_queue;

	void
	wl_event_queue_destroy(struct wl_event_queue *queue);

	void
	wl_proxy_marshal(struct wl_proxy *p, uint32_t opcode, ...);

	void
	wl_proxy_marshal_array(struct wl_proxy *p, uint32_t opcode,
	union wl_argument *args);

	struct wl_proxy *
	wl_proxy_create(struct wl_proxy *factory,
	const struct wl_interface *interface);

	void *
	wl_proxy_create_wrapper(void *proxy);

	void
	wl_proxy_wrapper_destroy(void *proxy_wrapper);

	struct wl_proxy *
	wl_proxy_marshal_constructor(struct wl_proxy *proxy,
	uint32_t opcode,
	const struct wl_interface *interface,
	...);

	struct wl_proxy *
	wl_proxy_marshal_constructor_versioned(struct wl_proxy *proxy,
	uint32_t opcode,
	const struct wl_interface *interface,
	uint32_t version,
	...);

	struct wl_proxy *
	wl_proxy_marshal_array_constructor(struct wl_proxy *proxy,
	uint32_t opcode, union wl_argument *args,
	const struct wl_interface *interface);

	struct wl_proxy *
	wl_proxy_marshal_array_constructor_versioned(struct wl_proxy *proxy,
	uint32_t opcode,
	union wl_argument *args,
	const struct wl_interface *interface,
	uint32_t version);

	void
	wl_proxy_destroy(struct wl_proxy *proxy);

	int
	wl_proxy_add_listener(struct wl_proxy *proxy,
	void (*implementation)(void), void data);

	const void *
	wl_proxy_get_listener(struct wl_proxy *proxy);

	int
	wl_proxy_add_dispatcher(struct wl_proxy *proxy,
	wl_dispatcher_func_t dispatcher_func,
	const void * dispatcher_data, void *data);

	void
	wl_proxy_set_user_data(struct wl_proxy proxy, void user_data);

	void *
	wl_proxy_get_user_data(struct wl_proxy *proxy);

	uint32_t
	wl_proxy_get_version(struct wl_proxy *proxy);

	uint32_t
	wl_proxy_get_id(struct wl_proxy *proxy);

	void
	wl_proxy_set_tag(struct wl_proxy *proxy,
	const char * const *tag);

	const char * const *
	wl_proxy_get_tag(struct wl_proxy *proxy);

	const char *
	wl_proxy_get_class(struct wl_proxy *proxy);

	void
	wl_proxy_set_queue(struct wl_proxy proxy, struct wl_event_queue queue);

	struct wl_display *
	wl_display_connect(const char *name);

	struct wl_display *
	wl_display_connect_to_fd(int fd);

	void
	wl_display_disconnect(struct wl_display *display);

	int
	wl_display_get_fd(struct wl_display *display);

	int
	wl_display_dispatch(struct wl_display *display);

	int
	wl_display_dispatch_queue(struct wl_display *display,
	struct wl_event_queue *queue);

	int
	wl_display_dispatch_queue_pending(struct wl_display *display,
	struct wl_event_queue *queue);

	int
	wl_display_dispatch_pending(struct wl_display *display);

	int
	wl_display_get_error(struct wl_display *display);

	uint32_t
	wl_display_get_protocol_error(struct wl_display *display,
	const struct wl_interface **interface,
	uint32_t *id);

	int
	wl_display_flush(struct wl_display *display);

	int
	wl_display_roundtrip_queue(struct wl_display *display,
	struct wl_event_queue *queue);

	int
	wl_display_roundtrip(struct wl_display *display);

	struct wl_event_queue *
	wl_display_create_queue(struct wl_display *display);

	int
	wl_display_prepare_read_queue(struct wl_display *display,
	struct wl_event_queue *queue);

	int
	wl_display_prepare_read(struct wl_display *display);

	void
	wl_display_cancel_read(struct wl_display *display);

	int
	wl_display_read_events(struct wl_display *display);

	void
	wl_log_set_handler_client(wl_log_func_t handler);

	#ifdef __cplusplus
	}
	#endif

	#endif