wayland-util.h source code [include/wayland-util.h]

1	/*
2	* Copyright © 2008 Kristian Høgsberg
3	*
4	* Permission is hereby granted, free of charge, to any person obtaining
5	* a copy of this software and associated documentation files (the
6	* "Software"), to deal in the Software without restriction, including
7	* without limitation the rights to use, copy, modify, merge, publish,
8	* distribute, sublicense, and/or sell copies of the Software, and to
9	* permit persons to whom the Software is furnished to do so, subject to
10	* the following conditions:
11	*
12	* The above copyright notice and this permission notice (including the
13	* next paragraph) shall be included in all copies or substantial
14	* portions of the Software.
15	*
16	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
17	* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
18	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
19	* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
20	* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
21	* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
22	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
23	* SOFTWARE.
24	*/
25
26	/* \file wayland-util.h*
27	*
28	* \brief Utility classes, functions, and macros.
29	*/
30
31	#ifndef WAYLAND_UTIL_H
32	#define WAYLAND_UTIL_H
33
34	#include <math.h>
35	#include <stddef.h>
36	#include <inttypes.h>
37	#include <stdarg.h>
38
39	#ifdef __cplusplus
40	extern "C" {
41	#endif
42
43	/* Visibility attribute /
44	#if defined(__GNUC__) && __GNUC__ >= 4
45	#define WL_EXPORT __attribute__ ((visibility("default")))
46	#else
47	#define WL_EXPORT
48	#endif
49
50	/* Deprecated attribute /
51	#if defined(__GNUC__) && __GNUC__ >= 4
52	#define WL_DEPRECATED __attribute__ ((deprecated))
53	#else
54	#define WL_DEPRECATED
55	#endif
56
57	/**
58	* Printf-style argument attribute
59	*
60	* \param x Ordinality of the format string argument
61	* \param y Ordinality of the argument to check against the format string
62	*
63	* \sa https://gcc.gnu.org/onlinedocs/gcc-3.2.1/gcc/Function-Attributes.html
64	*/
65	#if defined(__GNUC__) && __GNUC__ >= 4
66	#define WL_PRINTF(x, y) __attribute__((__format__(__printf__, x, y)))
67	#else
68	#define WL_PRINTF(x, y)
69	#endif
70
71	/* \class wl_object*
72	*
73	* \brief A protocol object.
74	*
75	* A `wl_object` is an opaque struct identifying the protocol object
76	* underlying a `wl_proxy` or `wl_resource`.
77	*
78	* \note Functions accessing a `wl_object` are not normally used by client code.
79	* Clients should normally use the higher level interface generated by the
80	* scanner to interact with compositor objects.
81	*
82	*/
83	struct wl_object;
84
85	/**
86	* Protocol message signature
87	*
88	* A wl_message describes the signature of an actual protocol message, such as a
89	* request or event, that adheres to the Wayland protocol wire format. The
90	* protocol implementation uses a wl_message within its demarshal machinery for
91	* decoding messages between a compositor and its clients. In a sense, a
92	* wl_message is to a protocol message like a class is to an object.
93	*
94	* The `name` of a wl_message is the name of the corresponding protocol message.
95	*
96	* The `signature` is an ordered list of symbols representing the data types
97	* of message arguments and, optionally, a protocol version and indicators for
98	* nullability. A leading integer in the `signature` indicates the _since_
99	* version of the protocol message. A `?` preceding a data type symbol indicates
100	* that the following argument type is nullable. While it is a protocol violation
101	* to send messages with non-nullable arguments set to `NULL`, event handlers in
102	* clients might still get called with non-nullable object arguments set to
103	* `NULL`. This can happen when the client destroyed the object being used as
104	* argument on its side and an event referencing that object was sent before the
105	* server knew about its destruction. As this race cannot be prevented, clients
106	* should - as a general rule - program their event handlers such that they can
107	* handle object arguments declared non-nullable being `NULL` gracefully.
108	*
109	* When no arguments accompany a message, `signature` is an empty string.
110	*
111	* Symbols:
112	*
113	* * `i`: int
114	* * `u`: uint
115	* * `f`: fixed
116	* * `s`: string
117	* * `o`: object
118	* * `n`: new_id
119	* * `a`: array
120	* * `h`: fd
121	* * `?`: following argument is nullable
122	*
123	* While demarshaling primitive arguments is straightforward, when demarshaling
124	* messages containing `object` or `new_id` arguments, the protocol
125	* implementation often must determine the type of the object. The `types` of a
126	* wl_message is an array of wl_interface references that correspond to `o` and
127	* `n` arguments in `signature`, with `NULL` placeholders for arguments with
128	* non-object types.
129	*
130	* Consider the protocol event wl_display `delete_id` that has a single `uint`
131	* argument. The wl_message is:
132	*
133	* \code
134	* { "delete_id", "u", [NULL] }
135	* \endcode
136	*
137	* Here, the message `name` is `"delete_id"`, the `signature` is `"u"`, and the
138	* argument `types` is `[NULL]`, indicating that the `uint` argument has no
139	* corresponding wl_interface since it is a primitive argument.
140	*
141	* In contrast, consider a `wl_foo` interface supporting protocol request `bar`
142	* that has existed since version 2, and has two arguments: a `uint` and an
143	* object of type `wl_baz_interface` that may be `NULL`. Such a `wl_message`
144	* might be:
145	*
146	* \code
147	* { "bar", "2u?o", [NULL, &wl_baz_interface] }
148	* \endcode
149	*
150	* Here, the message `name` is `"bar"`, and the `signature` is `"2u?o"`. Notice
151	* how the `2` indicates the protocol version, the `u` indicates the first
152	* argument type is `uint`, and the `?o` indicates that the second argument
153	* is an object that may be `NULL`. Lastly, the argument `types` array indicates
154	* that no wl_interface corresponds to the first argument, while the type
155	* `wl_baz_interface` corresponds to the second argument.
156	*
157	* \sa wl_argument
158	* \sa wl_interface
159	* \sa <a href="https://wayland.freedesktop.org/docs/html/ch04.html#sect-Protocol-Wire-Format">Wire Format</a>
160	*/
161	struct wl_message {
162	/* Message name /
163	const char *name;
164	/* Message signature /
165	const char *signature;
166	/* Object argument interfaces /
167	const struct wl_interface **types;
168	};
169
170	/**
171	* Protocol object interface
172	*
173	* A wl_interface describes the API of a protocol object defined in the Wayland
174	* protocol specification. The protocol implementation uses a wl_interface
175	* within its marshalling machinery for encoding client requests.
176	*
177	* The `name` of a wl_interface is the name of the corresponding protocol
178	* interface, and `version` represents the version of the interface. The members
179	* `method_count` and `event_count` represent the number of `methods` (requests)
180	* and `events` in the respective wl_message members.
181	*
182	* For example, consider a protocol interface `foo`, marked as version `1`, with
183	* two requests and one event.
184	*
185	* \code
186	* <interface name="foo" version="1">
187	* <request name="a"></request>
188	* <request name="b"></request>
189	* <event name="c"></event>
190	* </interface>
191	* \endcode
192	*
193	* Given two wl_message arrays `foo_requests` and `foo_events`, a wl_interface
194	* for `foo` might be:
195	*
196	* \code
197	* struct wl_interface foo_interface = {
198	* "foo", 1,
199	* 2, foo_requests,
200	* 1, foo_events
201	* };
202	* \endcode
203	*
204	* \note The server side of the protocol may define interface <em>implementation
205	* types</em> that incorporate the term `interface` in their name. Take
206	* care to not confuse these server-side `struct`s with a wl_interface
207	* variable whose name also ends in `interface`. For example, while the
208	* server may define a type `struct wl_foo_interface`, the client may
209	* define a `struct wl_interface wl_foo_interface`.
210	*
211	* \sa wl_message
212	* \sa wl_proxy
213	* \sa <a href="https://wayland.freedesktop.org/docs/html/ch04.html#sect-Protocol-Interfaces">Interfaces</a>
214	* \sa <a href="https://wayland.freedesktop.org/docs/html/ch04.html#sect-Protocol-Versioning">Versioning</a>
215	*/
216	struct wl_interface {
217	/* Interface name /
218	const char *name;
219	/* Interface version /
220	int version;
221	/* Number of methods (requests) /
222	int method_count;
223	/* Method (request) signatures /
224	const struct wl_message *methods;
225	/* Number of events /
226	int event_count;
227	/* Event signatures /
228	const struct wl_message *events;
229	};
230
231	/* \class wl_list*
232	*
233	* \brief Doubly-linked list
234	*
235	* On its own, an instance of `struct wl_list` represents the sentinel head of
236	* a doubly-linked list, and must be initialized using wl_list_init().
237	* When empty, the list head's `next` and `prev` members point to the list head
238	* itself, otherwise `next` references the first element in the list, and `prev`
239	* refers to the last element in the list.
240	*
241	* Use the `struct wl_list` type to represent both the list head and the links
242	* between elements within the list. Use wl_list_empty() to determine if the
243	* list is empty in O(1).
244	*
245	* All elements in the list must be of the same type. The element type must have
246	* a `struct wl_list` member, often named `link` by convention. Prior to
247	* insertion, there is no need to initialize an element's `link` - invoking
248	* wl_list_init() on an individual list element's `struct wl_list` member is
249	* unnecessary if the very next operation is wl_list_insert(). However, a
250	* common idiom is to initialize an element's `link` prior to removal - ensure
251	* safety by invoking wl_list_init() before wl_list_remove().
252	*
253	* Consider a list reference `struct wl_list foo_list`, an element type as
254	* `struct element`, and an element's link member as `struct wl_list link`.
255	*
256	* The following code initializes a list and adds three elements to it.
257	*
258	* \code
259	* struct wl_list foo_list;
260	*
261	* struct element {
262	* int foo;
263	* struct wl_list link;
264	* };
265	* struct element e1, e2, e3;
266	*
267	* wl_list_init(&foo_list);
268	* wl_list_insert(&foo_list, &e1.link); // e1 is the first element
269	* wl_list_insert(&foo_list, &e2.link); // e2 is now the first element
270	* wl_list_insert(&e2.link, &e3.link); // insert e3 after e2
271	* \endcode
272	*
273	* The list now looks like <em>[e2, e3, e1]</em>.
274	*
275	* The `wl_list` API provides some iterator macros. For example, to iterate
276	* a list in ascending order:
277	*
278	* \code
279	* struct element *e;
280	* wl_list_for_each(e, foo_list, link) {
281	* do_something_with_element(e);
282	* }
283	* \endcode
284	*
285	* See the documentation of each iterator for details.
286	* \sa http://git.kernel.org/cgit/linux/kernel/git/torvalds/linux.git/tree/include/linux/list.h
287	*/
288	struct wl_list {
289	/* Previous list element /
290	struct wl_list *prev;
291	/* Next list element /
292	struct wl_list *next;
293	};
294
295	/**
296	* Initializes the list.
297	*
298	* \param list List to initialize
299	*
300	* \memberof wl_list
301	*/
302	void
303	wl_list_init(struct wl_list *list);
304
305	/**
306	* Inserts an element into the list, after the element represented by \p list.
307	* When \p list is a reference to the list itself (the head), set the containing
308	* struct of \p elm as the first element in the list.
309	*
310	* \note If \p elm is already part of a list, inserting it again will lead to
311	* list corruption.
312	*
313	* \param list List element after which the new element is inserted
314	* \param elm Link of the containing struct to insert into the list
315	*
316	* \memberof wl_list
317	*/
318	void
319	wl_list_insert(struct wl_list list, struct* wl_list *elm);
320
321	/**
322	* Removes an element from the list.
323	*
324	* \note This operation leaves \p elm in an invalid state.
325	*
326	* \param elm Link of the containing struct to remove from the list
327	*
328	* \memberof wl_list
329	*/
330	void
331	wl_list_remove(struct wl_list *elm);
332
333	/**
334	* Determines the length of the list.
335	*
336	* \note This is an O(n) operation.
337	*
338	* \param list List whose length is to be determined
339	*
340	* \return Number of elements in the list
341	*
342	* \memberof wl_list
343	*/
344	int
345	wl_list_length(const struct wl_list *list);
346
347	/**
348	* Determines if the list is empty.
349	*
350	* \param list List whose emptiness is to be determined
351	*
352	* \return 1 if empty, or 0 if not empty
353	*
354	* \memberof wl_list
355	*/
356	int
357	wl_list_empty(const struct wl_list *list);
358
359	/**
360	* Inserts all of the elements of one list into another, after the element
361	* represented by \p list.
362	*
363	* \note This leaves \p other in an invalid state.
364	*
365	* \param list List element after which the other list elements will be inserted
366	* \param other List of elements to insert
367	*
368	* \memberof wl_list
369	*/
370	void
371	wl_list_insert_list(struct wl_list list, struct* wl_list *other);
372
373	/**
374	* Retrieves a pointer to a containing struct, given a member name.
375	*
376	* This macro allows "conversion" from a pointer to a member to its containing
377	* struct. This is useful if you have a contained item like a wl_list,
378	* wl_listener, or wl_signal, provided via a callback or other means, and would
379	* like to retrieve the struct that contains it.
380	*
381	* To demonstrate, the following example retrieves a pointer to
382	* `example_container` given only its `destroy_listener` member:
383	*
384	* \code
385	* struct example_container {
386	* struct wl_listener destroy_listener;
387	* // other members...
388	* };
389	*
390	* void example_container_destroy(struct wl_listener listener, void data)
391	* {
392	* struct example_container *ctr;
393	*
394	* ctr = wl_container_of(listener, ctr, destroy_listener);
395	* // destroy ctr...
396	* }
397	* \endcode
398	*
399	* \note `sample` need not be a valid pointer. A null or uninitialised pointer
400	* is sufficient.
401	*
402	* \param ptr Valid pointer to the contained member
403	* \param sample Pointer to a struct whose type contains \p ptr
404	* \param member Named location of \p ptr within the \p sample type
405	*
406	* \return The container for the specified pointer
407	*/
408	#define wl_container_of(ptr, sample, member) \
409	(__typeof__(sample))((char *)(ptr) - \
410	offsetof(__typeof__(*sample), member))
411
412	/**
413	* Iterates over a list.
414	*
415	* This macro expresses a for-each iterator for wl_list. Given a list and
416	* wl_list link member name (often named `link` by convention), this macro
417	* assigns each element in the list to \p pos, which can then be referenced in
418	* a trailing code block. For example, given a wl_list of `struct message`
419	* elements:
420	*
421	* \code
422	* struct message {
423	* char *contents;
424	* wl_list link;
425	* };
426	*
427	* struct wl_list *message_list;
428	* // Assume message_list now "contains" many messages
429	*
430	* struct message *m;
431	* wl_list_for_each(m, message_list, link) {
432	* do_something_with_message(m);
433	* }
434	* \endcode
435	*
436	* \param pos Cursor that each list element will be assigned to
437	* \param head Head of the list to iterate over
438	* \param member Name of the link member within the element struct
439	*
440	* \relates wl_list
441	*/
442	#define wl_list_for_each(pos, head, member) \
443	for (pos = wl_container_of((head)->next, pos, member); \
444	&pos->member != (head); \
445	pos = wl_container_of(pos->member.next, pos, member))
446
447	/**
448	* Iterates over a list, safe against removal of the list element.
449	*
450	* \note Only removal of the current element, \p pos, is safe. Removing
451	* any other element during traversal may lead to a loop malfunction.
452	*
453	* \sa wl_list_for_each()
454	*
455	* \param pos Cursor that each list element will be assigned to
456	* \param tmp Temporary pointer of the same type as \p pos
457	* \param head Head of the list to iterate over
458	* \param member Name of the link member within the element struct
459	*
460	* \relates wl_list
461	*/
462	#define wl_list_for_each_safe(pos, tmp, head, member) \
463	for (pos = wl_container_of((head)->next, pos, member), \
464	tmp = wl_container_of((pos)->member.next, tmp, member); \
465	&pos->member != (head); \
466	pos = tmp, \
467	tmp = wl_container_of(pos->member.next, tmp, member))
468
469	/**
470	* Iterates backwards over a list.
471	*
472	* \sa wl_list_for_each()
473	*
474	* \param pos Cursor that each list element will be assigned to
475	* \param head Head of the list to iterate over
476	* \param member Name of the link member within the element struct
477	*
478	* \relates wl_list
479	*/
480	#define wl_list_for_each_reverse(pos, head, member) \
481	for (pos = wl_container_of((head)->prev, pos, member); \
482	&pos->member != (head); \
483	pos = wl_container_of(pos->member.prev, pos, member))
484
485	/**
486	* Iterates backwards over a list, safe against removal of the list element.
487	*
488	* \note Only removal of the current element, \p pos, is safe. Removing
489	* any other element during traversal may lead to a loop malfunction.
490	*
491	* \sa wl_list_for_each()
492	*
493	* \param pos Cursor that each list element will be assigned to
494	* \param tmp Temporary pointer of the same type as \p pos
495	* \param head Head of the list to iterate over
496	* \param member Name of the link member within the element struct
497	*
498	* \relates wl_list
499	*/
500	#define wl_list_for_each_reverse_safe(pos, tmp, head, member) \
501	for (pos = wl_container_of((head)->prev, pos, member), \
502	tmp = wl_container_of((pos)->member.prev, tmp, member); \
503	&pos->member != (head); \
504	pos = tmp, \
505	tmp = wl_container_of(pos->member.prev, tmp, member))
506
507	/**
508	* \class wl_array
509	*
510	* Dynamic array
511	*
512	* A wl_array is a dynamic array that can only grow until released. It is
513	* intended for relatively small allocations whose size is variable or not known
514	* in advance. While construction of a wl_array does not require all elements to
515	* be of the same size, wl_array_for_each() does require all elements to have
516	* the same type and size.
517	*
518	*/
519	struct wl_array {
520	/* Array size /
521	size_t size;
522	/* Allocated space /
523	size_t alloc;
524	/* Array data /
525	void *data;
526	};
527
528	/**
529	* Initializes the array.
530	*
531	* \param array Array to initialize
532	*
533	* \memberof wl_array
534	*/
535	void
536	wl_array_init(struct wl_array *array);
537
538	/**
539	* Releases the array data.
540	*
541	* \note Leaves the array in an invalid state.
542	*
543	* \param array Array whose data is to be released
544	*
545	* \memberof wl_array
546	*/
547	void
548	wl_array_release(struct wl_array *array);
549
550	/**
551	* Increases the size of the array by \p size bytes.
552	*
553	* \param array Array whose size is to be increased
554	* \param size Number of bytes to increase the size of the array by
555	*
556	* \return A pointer to the beginning of the newly appended space, or NULL when
557	* resizing fails.
558	*
559	* \memberof wl_array
560	*/
561	void *
562	wl_array_add(struct wl_array *array, size_t size);
563
564	/**
565	* Copies the contents of \p source to \p array.
566	*
567	* \param array Destination array to copy to
568	* \param source Source array to copy from
569	*
570	* \return 0 on success, or -1 on failure
571	*
572	* \memberof wl_array
573	*/
574	int
575	wl_array_copy(struct wl_array array, struct* wl_array *source);
576
577	/**
578	* Iterates over an array.
579	*
580	* This macro expresses a for-each iterator for wl_array. It assigns each
581	* element in the array to \p pos, which can then be referenced in a trailing
582	* code block. \p pos must be a pointer to the array element type, and all
583	* array elements must be of the same type and size.
584	*
585	* \param pos Cursor that each array element will be assigned to
586	* \param array Array to iterate over
587	*
588	* \relates wl_array
589	* \sa wl_list_for_each()
590	*/
591	#define wl_array_for_each(pos, array) \
592	for (pos = (array)->data; \
593	(const char ) pos < ((const char ) (array)->data + (array)->size); \
594	(pos)++)
595
596	/**
597	* Fixed-point number
598	*
599	* A `wl_fixed_t` is a 24.8 signed fixed-point number with a sign bit, 23 bits
600	* of integer precision and 8 bits of decimal precision. Consider `wl_fixed_t`
601	* as an opaque struct with methods that facilitate conversion to and from
602	* `double` and `int` types.
603	*/
604	typedef int32_t wl_fixed_t;
605
606	/**
607	* Converts a fixed-point number to a floating-point number.
608	*
609	* \param f Fixed-point number to convert
610	*
611	* \return Floating-point representation of the fixed-point argument
612	*/
613	static inline double
614	wl_fixed_to_double(wl_fixed_t f)
615	{
616	union {
617	double d;
618	int64_t i;
619	} u;
620
621	u.i = ((`1023LL` + `44LL`) << `52`) + (`1LL` << `51`) + f;
622
623	return u.d - (`3LL` << `43`);
624	}
625
626	/**
627	* Converts a floating-point number to a fixed-point number.
628	*
629	* \param d Floating-point number to convert
630	*
631	* \return Fixed-point representation of the floating-point argument
632	*/
633	static inline wl_fixed_t
634	wl_fixed_from_double(double d)
635	{
636	union {
637	double d;
638	int64_t i;
639	} u;
640
641	u.d = d + (`3LL` << (`51` - `8`));
642
643	return (wl_fixed_t)u.i;
644	}
645
646	/**
647	* Converts a fixed-point number to an integer.
648	*
649	* \param f Fixed-point number to convert
650	*
651	* \return Integer component of the fixed-point argument
652	*/
653	static inline int
654	wl_fixed_to_int(wl_fixed_t f)
655	{
656	return f / `256`;
657	}
658
659	/**
660	* Converts an integer to a fixed-point number.
661	*
662	* \param i Integer to convert
663	*
664	* \return Fixed-point representation of the integer argument
665	*/
666	static inline wl_fixed_t
667	wl_fixed_from_int(int i)
668	{
669	return i * `256`;
670	}
671
672	/**
673	* Protocol message argument data types
674	*
675	* This union represents all of the argument types in the Wayland protocol wire
676	* format. The protocol implementation uses wl_argument within its marshalling
677	* machinery for dispatching messages between a client and a compositor.
678	*
679	* \sa wl_message
680	* \sa wl_interface
681	* \sa <a href="https://wayland.freedesktop.org/docs/html/ch04.html#sect-Protocol-wire-Format">Wire Format</a>
682	*/
683	union wl_argument {
684	int32_t i; /< `int` /*
685	uint32_t u; /< `uint` /*
686	wl_fixed_t f; /< `fixed` /*
687	const char s; /*< `string` /*
688	struct wl_object o; /*< `object` /*
689	uint32_t n; /< `new_id` /*
690	struct wl_array a; /*< `array` /*
691	int32_t h; /< `fd` /*
692	};
693
694	/**
695	* Dispatcher function type alias
696	*
697	* A dispatcher is a function that handles the emitting of callbacks in client
698	* code. For programs directly using the C library, this is done by using
699	* libffi to call function pointers. When binding to languages other than C,
700	* dispatchers provide a way to abstract the function calling process to be
701	* friendlier to other function calling systems.
702	*
703	* A dispatcher takes five arguments: The first is the dispatcher-specific
704	* implementation associated with the target object. The second is the object
705	* upon which the callback is being invoked (either wl_proxy or wl_resource).
706	* The third and fourth arguments are the opcode and the wl_message
707	* corresponding to the callback. The final argument is an array of arguments
708	* received from the other process via the wire protocol.
709	*
710	* \param "const void *" Dispatcher-specific implementation data
711	* \param "void *" Callback invocation target (wl_proxy or `wl_resource`)
712	* \param uint32_t Callback opcode
713	* \param "const struct wl_message *" Callback message signature
714	* \param "union wl_argument *" Array of received arguments
715	*
716	* \return 0 on success, or -1 on failure
717	*/
718	typedef int (wl_dispatcher_func_t)(const* void , void* *, uint32_t,
719	const struct wl_message *,
720	union wl_argument *);
721
722	/**
723	* Log function type alias
724	*
725	* The C implementation of the Wayland protocol abstracts the details of
726	* logging. Users may customize the logging behavior, with a function conforming
727	* to the `wl_log_func_t` type, via `wl_log_set_handler_client` and
728	* `wl_log_set_handler_server`.
729	*
730	* A `wl_log_func_t` must conform to the expectations of `vprintf`, and
731	* expects two arguments: a string to write and a corresponding variable
732	* argument list. While the string to write may contain format specifiers and
733	* use values in the variable argument list, the behavior of any `wl_log_func_t`
734	* depends on the implementation.
735	*
736	* \note Take care to not confuse this with `wl_protocol_logger_func_t`, which
737	* is a specific server-side logger for requests and events.
738	*
739	* \param "const char *" String to write to the log, containing optional format
740	* specifiers
741	* \param "va_list" Variable argument list
742	*
743	* \sa wl_log_set_handler_client
744	* \sa wl_log_set_handler_server
745	*/
746	typedef void (wl_log_func_t)(const* char *, va_list) WL_PRINTF(`1`, `0`);
747
748	/**
749	* Return value of an iterator function
750	*
751	* \sa wl_client_for_each_resource_iterator_func_t
752	* \sa wl_client_for_each_resource
753	*/
754	enum wl_iterator_result {
755	/* Stop the iteration /
756	WL_ITERATOR_STOP,
757	/* Continue the iteration /
758	WL_ITERATOR_CONTINUE
759	};
760
761	#ifdef __cplusplus
762	}
763	#endif
764
765	#endif
766

source code of include/wayland-util.h