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source: rtems/cpukit/libnetworking/sys/queue.h @ df49c60

4.104.114.84.95

Last change on this file since df49c60 was 39e6e65a, checked in by Joel Sherrill <joel.sherrill@…>, on 08/19/98 at 21:32:28
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1	/*
2	* Copyright (c) 1991, 1993
3	* The Regents of the University of California. All rights reserved.
4	*
5	* Redistribution and use in source and binary forms, with or without
6	* modification, are permitted provided that the following conditions
7	* are met:
8	* 1. Redistributions of source code must retain the above copyright
9	* notice, this list of conditions and the following disclaimer.
10	* 2. Redistributions in binary form must reproduce the above copyright
11	* notice, this list of conditions and the following disclaimer in the
12	* documentation and/or other materials provided with the distribution.
13	* 3. All advertising materials mentioning features or use of this software
14	* must display the following acknowledgement:
15	* This product includes software developed by the University of
16	* California, Berkeley and its contributors.
17	* 4. Neither the name of the University nor the names of its contributors
18	* may be used to endorse or promote products derived from this software
19	* without specific prior written permission.
20	*
21	* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
22	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
23	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
24	* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
25	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
26	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
27	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
28	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
29	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
30	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
31	* SUCH DAMAGE.
32	*
33	* @(#)queue.h 8.5 (Berkeley) 8/20/94
34	* $Id$
35	*/
36
37	#ifndef _SYS_QUEUE_H_
38	#define _SYS_QUEUE_H_
39
40	/*
41	* This file defines five types of data structures: singly-linked lists,
42	* slingly-linked tail queues, lists, tail queues, and circular queues.
43	*
44	* A singly-linked list is headed by a single forward pointer. The elements
45	* are singly linked for minimum space and pointer manipulation overhead at
46	* the expense of O(n) removal for arbitrary elements. New elements can be
47	* added to the list after an existing element or at the head of the list.
48	* Elements being removed from the head of the list should use the explicit
49	* macro for this purpose for optimum efficiency. A singly-linked list may
50	* only be traversed in the forward direction. Singly-linked lists are ideal
51	* for applications with large datasets and few or no removals or for
52	* implementing a LIFO queue.
53	*
54	* A singly-linked tail queue is headed by a pair of pointers, one to the
55	* head of the list and the other to the tail of the list. The elements are
56	* singly linked for minimum space and pointer manipulation overhead at the
57	* expense of O(n) removal for arbitrary elements. New elements can be added
58	* to the list after an existing element, at the head of the list, or at the
59	* end of the list. Elements being removed from the head of the tail queue
60	* should use the explicit macro for this purpose for optimum efficiency.
61	* A singly-linked tail queue may only be traversed in the forward direction.
62	* Singly-linked tail queues are ideal for applications with large datasets
63	* and few or no removals or for implementing a FIFO queue.
64	*
65	* A list is headed by a single forward pointer (or an array of forward
66	* pointers for a hash table header). The elements are doubly linked
67	* so that an arbitrary element can be removed without a need to
68	* traverse the list. New elements can be added to the list before
69	* or after an existing element or at the head of the list. A list
70	* may only be traversed in the forward direction.
71	*
72	* A tail queue is headed by a pair of pointers, one to the head of the
73	* list and the other to the tail of the list. The elements are doubly
74	* linked so that an arbitrary element can be removed without a need to
75	* traverse the list. New elements can be added to the list before or
76	* after an existing element, at the head of the list, or at the end of
77	* the list. A tail queue may only be traversed in the forward direction.
78	*
79	* A circle queue is headed by a pair of pointers, one to the head of the
80	* list and the other to the tail of the list. The elements are doubly
81	* linked so that an arbitrary element can be removed without a need to
82	* traverse the list. New elements can be added to the list before or after
83	* an existing element, at the head of the list, or at the end of the list.
84	* A circle queue may be traversed in either direction, but has a more
85	* complex end of list detection.
86	*
87	* For details on the use of these macros, see the queue(3) manual page.
88	*/
89
90	/*
91	* Singly-linked List definitions.
92	*/
93	#define SLIST_HEAD(name, type) \
94	struct name { \
95	struct type slh_first; / first element */ \
96	}
97
98	#define SLIST_ENTRY(type) \
99	struct { \
100	struct type sle_next; / next element */ \
101	}
102
103	/*
104	* Singly-linked List functions.
105	*/
106	#define SLIST_INIT(head) { \
107	(head)->slh_first = NULL; \
108	}
109
110	#define SLIST_INSERT_AFTER(slistelm, elm, field) { \
111	(elm)->field.sle_next = (slistelm)->field.sle_next; \
112	(slistelm)->field.sle_next = (elm); \
113	}
114
115	#define SLIST_INSERT_HEAD(head, elm, field) { \
116	(elm)->field.sle_next = (head)->slh_first; \
117	(head)->slh_first = (elm); \
118	}
119
120	#define SLIST_REMOVE_HEAD(head, field) { \
121	(head)->slh_first = (head)->slh_first->field.sle_next; \
122	}
123
124	#define SLIST_REMOVE(head, elm, type, field) { \
125	if ((head)->slh_first == (elm)) { \
126	SLIST_REMOVE_HEAD((head), field); \
127	} \
128	else { \
129	struct type *curelm = (head)->slh_first; \
130	while( curelm->field.sle_next != (elm) ) \
131	curelm = curelm->field.sle_next; \
132	curelm->field.sle_next = \
133	curelm->field.sle_next->field.sle_next; \
134	} \
135	}
136
137	/*
138	* Singly-linked Tail queue definitions.
139	*/
140	#define STAILQ_HEAD(name, type) \
141	struct name { \
142	struct type stqh_first;/ first element */ \
143	struct type *stqh_last;/ addr of last next element */ \
144	}
145
146	#define STAILQ_ENTRY(type) \
147	struct { \
148	struct type stqe_next; / next element */ \
149	}
150
151	/*
152	* Singly-linked Tail queue functions.
153	*/
154	#define STAILQ_INIT(head) { \
155	(head)->stqh_first = NULL; \
156	(head)->stqh_last = &(head)->stqh_first; \
157	}
158
159	#define STAILQ_INSERT_HEAD(head, elm, field) { \
160	if (((elm)->field.stqe_next = (head)->stqh_first) == NULL) \
161	(head)->stqh_last = &(elm)->field.stqe_next; \
162	(head)->stqh_first = (elm); \
163	}
164
165	#define STAILQ_INSERT_TAIL(head, elm, field) { \
166	(elm)->field.stqe_next = NULL; \
167	*(head)->stqh_last = (elm); \
168	(head)->stqh_last = &(elm)->field.stqe_next; \
169	}
170
171	#define STAILQ_INSERT_AFTER(head, tqelm, elm, field) { \
172	if (((elm)->field.stqe_next = (tqelm)->field.stqe_next) == NULL)\
173	(head)->stqh_last = &(elm)->field.stqe_next; \
174	(tqelm)->field.stqe_next = (elm); \
175	}
176
177	#define STAILQ_REMOVE_HEAD(head, field) { \
178	if (((head)->stqh_first = \
179	(head)->stqh_first->field.stqe_next) == NULL) \
180	(head)->stqh_last = &(head)->stqh_first; \
181	}
182
183	#define STAILQ_REMOVE(head, elm, type, field) { \
184	if ((head)->stqh_first == (elm)) { \
185	STAILQ_REMOVE_HEAD(head, field); \
186	} \
187	else { \
188	struct type *curelm = (head)->stqh_first; \
189	while( curelm->field.stqe_next != (elm) ) \
190	curelm = curelm->field.stqe_next; \
191	if((curelm->field.stqe_next = \
192	curelm->field.stqe_next->field.stqe_next) == NULL) \
193	(head)->stqh_last = &(curelm)->field.stqe_next; \
194	} \
195	}
196
197	/*
198	* List definitions.
199	*/
200	#define LIST_HEAD(name, type) \
201	struct name { \
202	struct type lh_first; / first element */ \
203	}
204
205	#define LIST_ENTRY(type) \
206	struct { \
207	struct type le_next; / next element */ \
208	struct type *le_prev; / address of previous next element */ \
209	}
210
211	/*
212	* List functions.
213	*/
214	#define LIST_INIT(head) { \
215	(head)->lh_first = NULL; \
216	}
217
218	#define LIST_INSERT_AFTER(listelm, elm, field) { \
219	if (((elm)->field.le_next = (listelm)->field.le_next) != NULL) \
220	(listelm)->field.le_next->field.le_prev = \
221	&(elm)->field.le_next; \
222	(listelm)->field.le_next = (elm); \
223	(elm)->field.le_prev = &(listelm)->field.le_next; \
224	}
225
226	#define LIST_INSERT_BEFORE(listelm, elm, field) { \
227	(elm)->field.le_prev = (listelm)->field.le_prev; \
228	(elm)->field.le_next = (listelm); \
229	*(listelm)->field.le_prev = (elm); \
230	(listelm)->field.le_prev = &(elm)->field.le_next; \
231	}
232
233	#define LIST_INSERT_HEAD(head, elm, field) { \
234	if (((elm)->field.le_next = (head)->lh_first) != NULL) \
235	(head)->lh_first->field.le_prev = &(elm)->field.le_next;\
236	(head)->lh_first = (elm); \
237	(elm)->field.le_prev = &(head)->lh_first; \
238	}
239
240	#define LIST_REMOVE(elm, field) { \
241	if ((elm)->field.le_next != NULL) \
242	(elm)->field.le_next->field.le_prev = \
243	(elm)->field.le_prev; \
244	*(elm)->field.le_prev = (elm)->field.le_next; \
245	}
246
247	/*
248	* Tail queue definitions.
249	*/
250	#define TAILQ_HEAD(name, type) \
251	struct name { \
252	struct type tqh_first; / first element */ \
253	struct type *tqh_last; / addr of last next element */ \
254	}
255
256	#define TAILQ_HEAD_INITIALIZER(head) \
257	{ NULL, &(head).tqh_first }
258
259	#define TAILQ_ENTRY(type) \
260	struct { \
261	struct type tqe_next; / next element */ \
262	struct type *tqe_prev; / address of previous next element */ \
263	}
264
265	/*
266	* Tail queue functions.
267	*/
268	#define TAILQ_EMPTY(head) ((head)->tqh_first == NULL)
269
270	#define TAILQ_FIRST(head) ((head)->tqh_first)
271
272	#define TAILQ_LAST(head) ((head)->tqh_last)
273
274	#define TAILQ_NEXT(elm, field) ((elm)->field.tqe_next)
275
276	#define TAILQ_PREV(elm, field) ((elm)->field.tqe_prev)
277
278	#define TAILQ_INIT(head) { \
279	(head)->tqh_first = NULL; \
280	(head)->tqh_last = &(head)->tqh_first; \
281	}
282
283	#define TAILQ_INSERT_HEAD(head, elm, field) { \
284	if (((elm)->field.tqe_next = (head)->tqh_first) != NULL) \
285	(head)->tqh_first->field.tqe_prev = \
286	&(elm)->field.tqe_next; \
287	else \
288	(head)->tqh_last = &(elm)->field.tqe_next; \
289	(head)->tqh_first = (elm); \
290	(elm)->field.tqe_prev = &(head)->tqh_first; \
291	}
292
293	#define TAILQ_INSERT_TAIL(head, elm, field) { \
294	(elm)->field.tqe_next = NULL; \
295	(elm)->field.tqe_prev = (head)->tqh_last; \
296	*(head)->tqh_last = (elm); \
297	(head)->tqh_last = &(elm)->field.tqe_next; \
298	}
299
300	#define TAILQ_INSERT_AFTER(head, listelm, elm, field) { \
301	if (((elm)->field.tqe_next = (listelm)->field.tqe_next) != NULL)\
302	(elm)->field.tqe_next->field.tqe_prev = \
303	&(elm)->field.tqe_next; \
304	else \
305	(head)->tqh_last = &(elm)->field.tqe_next; \
306	(listelm)->field.tqe_next = (elm); \
307	(elm)->field.tqe_prev = &(listelm)->field.tqe_next; \
308	}
309
310	#define TAILQ_INSERT_BEFORE(listelm, elm, field) { \
311	(elm)->field.tqe_prev = (listelm)->field.tqe_prev; \
312	(elm)->field.tqe_next = (listelm); \
313	*(listelm)->field.tqe_prev = (elm); \
314	(listelm)->field.tqe_prev = &(elm)->field.tqe_next; \
315	}
316
317	#define TAILQ_REMOVE(head, elm, field) { \
318	if (((elm)->field.tqe_next) != NULL) \
319	(elm)->field.tqe_next->field.tqe_prev = \
320	(elm)->field.tqe_prev; \
321	else \
322	(head)->tqh_last = (elm)->field.tqe_prev; \
323	*(elm)->field.tqe_prev = (elm)->field.tqe_next; \
324	}
325
326	/*
327	* Circular queue definitions.
328	*/
329	#define CIRCLEQ_HEAD(name, type) \
330	struct name { \
331	struct type cqh_first; / first element */ \
332	struct type cqh_last; / last element */ \
333	}
334
335	#define CIRCLEQ_ENTRY(type) \
336	struct { \
337	struct type cqe_next; / next element */ \
338	struct type cqe_prev; / previous element */ \
339	}
340
341	/*
342	* Circular queue functions.
343	*/
344	#define CIRCLEQ_INIT(head) { \
345	(head)->cqh_first = (void *)(head); \
346	(head)->cqh_last = (void *)(head); \
347	}
348
349	#define CIRCLEQ_INSERT_AFTER(head, listelm, elm, field) { \
350	(elm)->field.cqe_next = (listelm)->field.cqe_next; \
351	(elm)->field.cqe_prev = (listelm); \
352	if ((listelm)->field.cqe_next == (void *)(head)) \
353	(head)->cqh_last = (elm); \
354	else \
355	(listelm)->field.cqe_next->field.cqe_prev = (elm); \
356	(listelm)->field.cqe_next = (elm); \
357	}
358
359	#define CIRCLEQ_INSERT_BEFORE(head, listelm, elm, field) { \
360	(elm)->field.cqe_next = (listelm); \
361	(elm)->field.cqe_prev = (listelm)->field.cqe_prev; \
362	if ((listelm)->field.cqe_prev == (void *)(head)) \
363	(head)->cqh_first = (elm); \
364	else \
365	(listelm)->field.cqe_prev->field.cqe_next = (elm); \
366	(listelm)->field.cqe_prev = (elm); \
367	}
368
369	#define CIRCLEQ_INSERT_HEAD(head, elm, field) { \
370	(elm)->field.cqe_next = (head)->cqh_first; \
371	(elm)->field.cqe_prev = (void *)(head); \
372	if ((head)->cqh_last == (void *)(head)) \
373	(head)->cqh_last = (elm); \
374	else \
375	(head)->cqh_first->field.cqe_prev = (elm); \
376	(head)->cqh_first = (elm); \
377	}
378
379	#define CIRCLEQ_INSERT_TAIL(head, elm, field) { \
380	(elm)->field.cqe_next = (void *)(head); \
381	(elm)->field.cqe_prev = (head)->cqh_last; \
382	if ((head)->cqh_first == (void *)(head)) \
383	(head)->cqh_first = (elm); \
384	else \
385	(head)->cqh_last->field.cqe_next = (elm); \
386	(head)->cqh_last = (elm); \
387	}
388
389	#define CIRCLEQ_REMOVE(head, elm, field) { \
390	if ((elm)->field.cqe_next == (void *)(head)) \
391	(head)->cqh_last = (elm)->field.cqe_prev; \
392	else \
393	(elm)->field.cqe_next->field.cqe_prev = \
394	(elm)->field.cqe_prev; \
395	if ((elm)->field.cqe_prev == (void *)(head)) \
396	(head)->cqh_first = (elm)->field.cqe_next; \
397	else \
398	(elm)->field.cqe_prev->field.cqe_next = \
399	(elm)->field.cqe_next; \
400	}
401
402	#ifdef KERNEL
403
404	/*
405	* XXX insque() and remque() are an old way of handling certain queues.
406	* They bogusly assumes that all queue heads look alike.
407	*/
408
409	struct quehead {
410	struct quehead *qh_link;
411	struct quehead *qh_rlink;
412	};
413
414	#ifdef __GNUC__
415
416	static __inline void
417	insque(void a, void b)
418	{
419	struct quehead element = a, head = b;
420
421	element->qh_link = head->qh_link;
422	element->qh_rlink = head;
423	head->qh_link = element;
424	element->qh_link->qh_rlink = element;
425	}
426
427	static __inline void
428	remque(void *a)
429	{
430	struct quehead *element = a;
431
432	element->qh_link->qh_rlink = element->qh_rlink;
433	element->qh_rlink->qh_link = element->qh_link;
434	element->qh_rlink = 0;
435	}
436
437	#else /* !__GNUC__ */
438
439	void insque __P((void a, void b));
440	void remque __P((void *a));
441
442	#endif /* __GNUC__ */
443
444	#endif /* KERNEL */
445
446	#endif /* !_SYS_QUEUE_H_ */

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