include/common/mini-clist.h - haproxy - Gitiles

 /*
  * list.h : list manipulation macros and structures.
  * Copyright 2002-2010 Willy Tarreau <w@1wt.eu>
  *
  */

 #ifndef _COMMON_MINI_CLIST_H
 #define _COMMON_MINI_CLIST_H

 #include <common/config.h>

 /* these are circular or bidirectionnal lists only. Each list pointer points to
  * another list pointer in a structure, and not the structure itself. The
  * pointer to the next element MUST be the first one so that the list is easily
  * cast as a single linked list or pointer.
  */
 struct list {
     struct list *n;	/* next */
     struct list *p;	/* prev */
 };

 /* a back-ref is a pointer to a target list entry. It is used to detect when an
  * element being deleted is currently being tracked by another user. The best
  * example is a user dumping the session table. The table does not fit in the
  * output buffer so we have to set a mark on a session and go on later. But if
  * that marked session gets deleted, we don't want the user's pointer to go in
  * the wild. So we can simply link this user's request to the list of this
  * session's users, and put a pointer to the list element in ref, that will be
  * used as the mark for next iteration.
  */
 struct bref {
 	struct list users;
 	struct list *ref; /* pointer to the target's list entry */
 };

 /* a word list is a generic list with a pointer to a string in each element. */
 struct wordlist {
 	struct list list;
 	char *s;
 };

 /* this is the same as above with an additional pointer to a condition. */
 struct cond_wordlist {
 	struct list list;
 	void *cond;
 	char *s;
 };

 /* First undefine some macros which happen to also be defined on OpenBSD,
  * in sys/queue.h, used by sys/event.h
  */
 #undef LIST_HEAD
 #undef LIST_INIT
 #undef LIST_NEXT

 /* ILH = Initialized List Head : used to prevent gcc from moving an empty
  * list to BSS. Some older version tend to trim all the array and cause
  * corruption.
  */
 #define ILH		{ .n = (struct list *)1, .p = (struct list *)2 }

 #define LIST_HEAD(a)	((void *)(&(a)))

 #define LIST_INIT(l) ((l)->n = (l)->p = (l))

 #define LIST_HEAD_INIT(l) { &l, &l }

 /* dual linked lists :
  * Start = (struct list *) pointer to the next elem's prev list entry
  * For each element :
  *   - prev = pointer to previous element's next (or start). Cannot be NULL
  *   - next = pointer to next element's prev. NULL = end.
  *
  */

 /* adds an element at the beginning of a dual-linked list ; returns the element */
 #define DLIST_ADD(lh, el) ({ typeof(el) __ret = (el); __ret->n = (void *)(lh); __ret->p = (void *)&(lh); if (likely(__ret->n != NULL)) __ret->n->p = __ret; (lh) = (typeof(lh))&__ret->n; __ret; })

 /* removes an element from a dual-linked list and returns it */
 #define DLIST_DEL(el) ({ typeof(el) __ret = (el); if (likely(__ret->n != NULL)) __ret->n->p = __ret->p; __ret->p->n = __ret->n; __ret; })

 /*
  * iterates through a list of items of type "<struct_type>" which are
  * linked via a "struct list" member named <struct_member>. The head of the
  * list is stored at a location designed by <list_head>, which should be a
  * "struct list *". A variable <end_item> of type "<struct_type>" will
  * be used as temporary end of list pointer. It can be derived from <list_head>
  * since this one is only used before. <list_head> will be modified except for
  * foreach_dlist_item_cst which is slightly slower.
  * Major difference between FOREACH_ITEM is that it stops at NULL.
  * Example: foreach_dlist_item(cur_node, args, struct node *, list) { ... };
  *          foreach_dlist_item_cst(cur_node, &node->args, struct node *, list) { ... };
  */
 #define foreach_dlist_item_cst(iterator, list_head, struct_type, struct_member)	\
 	for ((iterator) = LIST_ELEM(&(list_head), struct_type, struct_member.n);	\
 	     ((iterator)->struct_member.n != NULL) && \
              (((iterator) = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member.n)), 1);\
 	     )

 #define foreach_dlist_item(iterator, var_list_head, struct_type, struct_member)	\
 	while ((var_list_head != NULL) &&			\
 	       ((var_list_head=((iterator)=LIST_ELEM(var_list_head, struct_type, struct_member.n))->struct_member.n), 1))

 /*
  * Like foreach_dlist_item, except that this one only operates on the head of
  * the list. It's to the inner instructions to iterate the list head. If not,
  * this will be an endless loop.
  */
 #define while_dlist_item(iterator, var_list_head, struct_type, struct_member)	\
 	while ((var_list_head != NULL) &&			\
 	       (((iterator)=LIST_ELEM(var_list_head, struct_type, struct_member.n)),1))


 /****** circular lists ********/

 /* adds an element at the beginning of a list ; returns the element */
 #define LIST_ADD(lh, el) ({ (el)->n = (lh)->n; (el)->n->p = (lh)->n = (el); (el)->p = (lh); (el); })

 /* adds an element at the end of a list ; returns the element */
 #define LIST_ADDQ(lh, el) ({ (el)->p = (lh)->p; (el)->p->n = (lh)->p = (el); (el)->n = (lh); (el); })

 /* removes an element from a list and returns it */
 #define LIST_DEL(el) ({ typeof(el) __ret = (el); (el)->n->p = (el)->p; (el)->p->n = (el)->n; (__ret); })

 /* returns a pointer of type <pt> to a structure containing a list head called
  * <el> at address <lh>. Note that <lh> can be the result of a function or macro
  * since it's used only once.
  * Example: LIST_ELEM(cur_node->args.next, struct node *, args)
  */
 #define LIST_ELEM(lh, pt, el) ((pt)(((void *)(lh)) - ((void *)&((pt)NULL)->el)))

 /* checks if the list head <lh> is empty or not */
 #define LIST_ISEMPTY(lh) ((lh)->n == (lh))

 /* returns a pointer of type <pt> to a structure following the element
  * which contains list head <lh>, which is known as element <el> in
  * struct pt.
  * Example: LIST_NEXT(args, struct node *, list)
  */
 #define LIST_NEXT(lh, pt, el) (LIST_ELEM((lh)->n, pt, el))


 /* returns a pointer of type <pt> to a structure preceeding the element
  * which contains list head <lh>, which is known as element <el> in
  * struct pt.
  */
 #define LIST_PREV(lh, pt, el) (LIST_ELEM((lh)->p, pt, el))

 /*
  * DEPRECATED !!!  Use list_for_each_entry() below instead !
  *
  * iterates through a list of items of type "<struct_type>" which are
  * linked via a "struct list" member named <struct_member>. The head of the
  * list is stored at a location designed by <list_head>, which should be a
  * "struct list *". A variable <end_item> of type "<struct_type>" will
  * be used as temporary end of list pointer. It can be derived from <list_head>
  * since this one is only used before.
  * Example: FOREACH_ITEM(cur_node, &node->args, node, struct node *, neigh) { ... };
  */
 #define FOREACH_ITEM(iterator, list_head, end_item, struct_type, struct_member) \
 	iterator = end_item = LIST_ELEM(list_head, struct_type, struct_member); \
 	while (((iterator) = LIST_ELEM((iterator)->struct_member.n, 		\
 			     struct_type, struct_member)) != (end_item))

 /*
  * DEPRECATED !!!  Use list_for_each_entry_safe() below instead !
  *
  * idem except that this one is safe against deletion, but it needs a backup
  * pointer of the element after the iterator.
  * Example: FOREACH_ITEM_SAFE(cur_node, backup, &node->args, node, struct node *, neigh) { ... };
  */
 #define FOREACH_ITEM_SAFE(iterator, backup, list_head, end_item, struct_type, struct_member) \
 	end_item = LIST_ELEM(list_head, struct_type, struct_member); \
 	iterator = LIST_ELEM((end_item)->struct_member.n, struct_type, struct_member); \
 	if ((iterator) != (end_item)) \
 		backup = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member); \
 	for ( ; (iterator) != (end_item); (iterator) = (backup),   \
 		backup = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member))

 /*
  * Simpler FOREACH_ITEM macro inspired from Linux sources.
  * Iterates <item> through a list of items of type "typeof(*item)" which are
  * linked via a "struct list" member named <member>. A pointer to the head of
  * the list is passed in <list_head>. No temporary variable is needed. Note
  * that <item> must not be modified during the loop.
  * Example: list_for_each_entry(cur_acl, known_acl, list) { ... };
  */
 #define list_for_each_entry(item, list_head, member)                      \
 	for (item = LIST_ELEM((list_head)->n, typeof(item), member);     \
 	     &item->member != (list_head);                                \
 	     item = LIST_ELEM(item->member.n, typeof(item), member))

 /*
  * Simpler FOREACH_ITEM_SAFE macro inspired from Linux sources.
  * Iterates <item> through a list of items of type "typeof(*item)" which are
  * linked via a "struct list" member named <member>. A pointer to the head of
  * the list is passed in <list_head>. A temporary variable <back> of same type
  * as <item> is needed so that <item> may safely be deleted if needed.
  * Example: list_for_each_entry_safe(cur_acl, tmp, known_acl, list) { ... };
  */
 #define list_for_each_entry_safe(item, back, list_head, member)           \
 	for (item = LIST_ELEM((list_head)->n, typeof(item), member),     \
 	     back = LIST_ELEM(item->member.n, typeof(item), member);     \
 	     &item->member != (list_head);                                \
 	     item = back, back = LIST_ELEM(back->member.n, typeof(back), member))


 #endif /* _COMMON_MINI_CLIST_H */
	/*
	* list.h : list manipulation macros and structures.
	* Copyright 2002-2010 Willy Tarreau <w@1wt.eu>
	*
	*/

	#ifndef _COMMON_MINI_CLIST_H
	#define _COMMON_MINI_CLIST_H

	#include <common/config.h>

	/* these are circular or bidirectionnal lists only. Each list pointer points to
	* another list pointer in a structure, and not the structure itself. The
	* pointer to the next element MUST be the first one so that the list is easily
	* cast as a single linked list or pointer.
	*/
	struct list {
	struct list n; / next */
	struct list p; / prev */
	};

	/* a back-ref is a pointer to a target list entry. It is used to detect when an
	* element being deleted is currently being tracked by another user. The best
	* example is a user dumping the session table. The table does not fit in the
	* output buffer so we have to set a mark on a session and go on later. But if
	* that marked session gets deleted, we don't want the user's pointer to go in
	* the wild. So we can simply link this user's request to the list of this
	* session's users, and put a pointer to the list element in ref, that will be
	* used as the mark for next iteration.
	*/
	struct bref {
	struct list users;
	struct list ref; / pointer to the target's list entry */
	};

	/* a word list is a generic list with a pointer to a string in each element. */
	struct wordlist {
	struct list list;
	char *s;
	};

	/* this is the same as above with an additional pointer to a condition. */
	struct cond_wordlist {
	struct list list;
	void *cond;
	char *s;
	};

	/* First undefine some macros which happen to also be defined on OpenBSD,
	* in sys/queue.h, used by sys/event.h
	*/
	#undef LIST_HEAD
	#undef LIST_INIT
	#undef LIST_NEXT

	/* ILH = Initialized List Head : used to prevent gcc from moving an empty
	* list to BSS. Some older version tend to trim all the array and cause
	* corruption.
	*/
	#define ILH { .n = (struct list )1, .p = (struct list )2 }

	#define LIST_HEAD(a) ((void *)(&(a)))

	#define LIST_INIT(l) ((l)->n = (l)->p = (l))

	#define LIST_HEAD_INIT(l) { &l, &l }

	/* dual linked lists :
	* Start = (struct list *) pointer to the next elem's prev list entry
	* For each element :
	* - prev = pointer to previous element's next (or start). Cannot be NULL
	* - next = pointer to next element's prev. NULL = end.
	*
	*/

	/* adds an element at the beginning of a dual-linked list ; returns the element */
	#define DLIST_ADD(lh, el) ({ typeof(el) __ret = (el); __ret->n = (void )(lh); __ret->p = (void )&(lh); if (likely(__ret->n != NULL)) __ret->n->p = __ret; (lh) = (typeof(lh))&__ret->n; __ret; })

	/* removes an element from a dual-linked list and returns it */
	#define DLIST_DEL(el) ({ typeof(el) __ret = (el); if (likely(__ret->n != NULL)) __ret->n->p = __ret->p; __ret->p->n = __ret->n; __ret; })

	/*
	* iterates through a list of items of type "<struct_type>" which are
	* linked via a "struct list" member named <struct_member>. The head of the
	* list is stored at a location designed by <list_head>, which should be a
	* "struct list *". A variable <end_item> of type "<struct_type>" will
	* be used as temporary end of list pointer. It can be derived from <list_head>
	* since this one is only used before. <list_head> will be modified except for
	* foreach_dlist_item_cst which is slightly slower.
	* Major difference between FOREACH_ITEM is that it stops at NULL.
	* Example: foreach_dlist_item(cur_node, args, struct node *, list) { ... };
	* foreach_dlist_item_cst(cur_node, &node->args, struct node *, list) { ... };
	*/
	#define foreach_dlist_item_cst(iterator, list_head, struct_type, struct_member) \
	for ((iterator) = LIST_ELEM(&(list_head), struct_type, struct_member.n); \
	((iterator)->struct_member.n != NULL) && \
	(((iterator) = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member.n)), 1);\
	)

	#define foreach_dlist_item(iterator, var_list_head, struct_type, struct_member) \
	while ((var_list_head != NULL) && \
	((var_list_head=((iterator)=LIST_ELEM(var_list_head, struct_type, struct_member.n))->struct_member.n), 1))

	/*
	* Like foreach_dlist_item, except that this one only operates on the head of
	* the list. It's to the inner instructions to iterate the list head. If not,
	* this will be an endless loop.
	*/
	#define while_dlist_item(iterator, var_list_head, struct_type, struct_member) \
	while ((var_list_head != NULL) && \
	(((iterator)=LIST_ELEM(var_list_head, struct_type, struct_member.n)),1))


	/**** circular lists ******/

	/* adds an element at the beginning of a list ; returns the element */
	#define LIST_ADD(lh, el) ({ (el)->n = (lh)->n; (el)->n->p = (lh)->n = (el); (el)->p = (lh); (el); })

	/* adds an element at the end of a list ; returns the element */
	#define LIST_ADDQ(lh, el) ({ (el)->p = (lh)->p; (el)->p->n = (lh)->p = (el); (el)->n = (lh); (el); })

	/* removes an element from a list and returns it */
	#define LIST_DEL(el) ({ typeof(el) __ret = (el); (el)->n->p = (el)->p; (el)->p->n = (el)->n; (__ret); })

	/* returns a pointer of type <pt> to a structure containing a list head called
	* <el> at address <lh>. Note that <lh> can be the result of a function or macro
	* since it's used only once.
	* Example: LIST_ELEM(cur_node->args.next, struct node *, args)
	*/
	#define LIST_ELEM(lh, pt, el) ((pt)(((void )(lh)) - ((void )&((pt)NULL)->el)))

	/* checks if the list head <lh> is empty or not */
	#define LIST_ISEMPTY(lh) ((lh)->n == (lh))

	/* returns a pointer of type <pt> to a structure following the element
	* which contains list head <lh>, which is known as element <el> in
	* struct pt.
	* Example: LIST_NEXT(args, struct node *, list)
	*/
	#define LIST_NEXT(lh, pt, el) (LIST_ELEM((lh)->n, pt, el))


	/* returns a pointer of type <pt> to a structure preceeding the element
	* which contains list head <lh>, which is known as element <el> in
	* struct pt.
	*/
	#define LIST_PREV(lh, pt, el) (LIST_ELEM((lh)->p, pt, el))

	/*
	* DEPRECATED !!! Use list_for_each_entry() below instead !
	*
	* iterates through a list of items of type "<struct_type>" which are
	* linked via a "struct list" member named <struct_member>. The head of the
	* list is stored at a location designed by <list_head>, which should be a
	* "struct list *". A variable <end_item> of type "<struct_type>" will
	* be used as temporary end of list pointer. It can be derived from <list_head>
	* since this one is only used before.
	* Example: FOREACH_ITEM(cur_node, &node->args, node, struct node *, neigh) { ... };
	*/
	#define FOREACH_ITEM(iterator, list_head, end_item, struct_type, struct_member) \
	iterator = end_item = LIST_ELEM(list_head, struct_type, struct_member); \
	while (((iterator) = LIST_ELEM((iterator)->struct_member.n, \
	struct_type, struct_member)) != (end_item))

	/*
	* DEPRECATED !!! Use list_for_each_entry_safe() below instead !
	*
	* idem except that this one is safe against deletion, but it needs a backup
	* pointer of the element after the iterator.
	* Example: FOREACH_ITEM_SAFE(cur_node, backup, &node->args, node, struct node *, neigh) { ... };
	*/
	#define FOREACH_ITEM_SAFE(iterator, backup, list_head, end_item, struct_type, struct_member) \
	end_item = LIST_ELEM(list_head, struct_type, struct_member); \
	iterator = LIST_ELEM((end_item)->struct_member.n, struct_type, struct_member); \
	if ((iterator) != (end_item)) \
	backup = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member); \
	for ( ; (iterator) != (end_item); (iterator) = (backup), \
	backup = LIST_ELEM((iterator)->struct_member.n, struct_type, struct_member))

	/*
	* Simpler FOREACH_ITEM macro inspired from Linux sources.
	* Iterates <item> through a list of items of type "typeof(*item)" which are
	* linked via a "struct list" member named <member>. A pointer to the head of
	* the list is passed in <list_head>. No temporary variable is needed. Note
	* that <item> must not be modified during the loop.
	* Example: list_for_each_entry(cur_acl, known_acl, list) { ... };
	*/
	#define list_for_each_entry(item, list_head, member) \
	for (item = LIST_ELEM((list_head)->n, typeof(item), member); \
	&item->member != (list_head); \
	item = LIST_ELEM(item->member.n, typeof(item), member))

	/*
	* Simpler FOREACH_ITEM_SAFE macro inspired from Linux sources.
	* Iterates <item> through a list of items of type "typeof(*item)" which are
	* linked via a "struct list" member named <member>. A pointer to the head of
	* the list is passed in <list_head>. A temporary variable <back> of same type
	* as <item> is needed so that <item> may safely be deleted if needed.
	* Example: list_for_each_entry_safe(cur_acl, tmp, known_acl, list) { ... };
	*/
	#define list_for_each_entry_safe(item, back, list_head, member) \
	for (item = LIST_ELEM((list_head)->n, typeof(item), member), \
	back = LIST_ELEM(item->member.n, typeof(item), member); \
	&item->member != (list_head); \
	item = back, back = LIST_ELEM(back->member.n, typeof(back), member))


	#endif /* _COMMON_MINI_CLIST_H */