KSP
/
sksp2024-mcu
42
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity
Workshop o mikrokontrolérech na SKSP 2024.
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
12 Commits
1 Branch
0 Tags
11 MiB
 
 
 
 
 
 
Tree: 25422326fe
Branches Tags
${ item.name }
Create tag ${ searchTerm }
Create branch ${ searchTerm }
from '25422326fe'
${ noResults }
sksp2024-mcu/libucw/ucw/clists.h

279 lines
6.9 KiB
Raw Blame History

/*
* UCW Library -- Circular Linked Lists
*
* (c) 2003--2010 Martin Mares <mj@ucw.cz>
* (c) 2017 Pavel Charvat <pchar@ucw.cz>
*
* This software may be freely distributed and used according to the terms
* of the GNU Lesser General Public License.
*/
#ifndef _UCW_CLISTS_H
#define _UCW_CLISTS_H
/**
* Common header for list nodes.
**/
typedef struct cnode {
struct cnode *next, *prev;
} cnode;
/**
* Circular doubly linked list.
**/
typedef struct clist {
struct cnode head;
} clist;
/**
* Initialize a new circular linked list. Must be called before any other function.
**/
static inline void clist_init(clist *l)
{
cnode *head = &l->head;
head->next = head->prev = head;
}
/**
* Return the first node on @l or NULL if @l is empty.
**/
static inline void *clist_head(clist *l)
{
return (l->head.next != &l->head) ? l->head.next : NULL;
}
/**
* Return the last node on @l or NULL if @l is empty.
**/
static inline void *clist_tail(clist *l)
{
return (l->head.prev != &l->head) ? l->head.prev : NULL;
}
/**
* Find the next node to @n or NULL if @n is the last one.
**/
static inline void *clist_next(clist *l, cnode *n)
{
return (n->next != &l->head) ? (void *) n->next : NULL;
}
/**
* Find the previous node to @n or NULL if @n is the first one.
**/
static inline void *clist_prev(clist *l, cnode *n)
{
return (n->prev != &l->head) ? (void *) n->prev : NULL;
}
/**
* Return a non-zero value iff @l is empty.
**/
static inline int clist_empty(clist *l)
{
return (l->head.next == &l->head);
}
/**
* Loop over all nodes in the @list and perform the next C statement on them. The current node is stored in @n which must be defined before as pointer to any type.
* The list should not be changed during this loop command.
**/
#define CLIST_WALK(n,list) for(n=(void*)(list).head.next; (cnode*)(n) != &(list).head; n=(void*)((cnode*)(n))->next)
/**
* Same as @CLIST_WALK(), but allows removal of the current node. This macro requires one more variable to store some temporary pointers.
**/
#define CLIST_WALK_DELSAFE(n,list,tmp) for(n=(void*)(list).head.next; tmp=(void*)((cnode*)(n))->next, (cnode*)(n) != &(list).head; n=(void*)tmp)
/**
* Same as @CLIST_WALK(), but it defines the variable for the current node in place. @type should be a pointer type.
**/
#define CLIST_FOR_EACH(type,n,list) for(type n=(void*)(list).head.next; (cnode*)(n) != &(list).head; n=(void*)((cnode*)(n))->next)
/**
* Same as @CLIST_WALK_DELSAFE(), but it defines the variable for the current node in place. @type should be a pointer type. The temporary variable must be still known before.
**/
#define CLIST_FOR_EACH_DELSAFE(type,n,list,tmp) for(type n=(void*)(list).head.next; tmp=(void*)((cnode*)(n))->next, (cnode*)(n) != &(list).head; n=(void*)tmp)
/**
* Reversed version of @CLIST_FOR_EACH().
**/
#define CLIST_FOR_EACH_BACKWARDS(type,n,list) for(type n=(void*)(list).head.prev; (cnode*)(n) != &(list).head; n=(void*)((cnode*)(n))->prev)
/**
* Insert a new node just after the node @after. To insert at the head of the list, use @clist_add_head() instead.
**/
static inline void clist_insert_after(cnode *what, cnode *after)
{
cnode *before = after->next;
what->next = before;
what->prev = after;
before->prev = what;
after->next = what;
}
/**
* Insert a new node just before the node @before. To insert at the tail of the list, use @clist_add_tail() instead.
**/
static inline void clist_insert_before(cnode *what, cnode *before)
{
cnode *after = before->prev;
what->next = before;
what->prev = after;
before->prev = what;
after->next = what;
}
/**
* Insert a new node in front of all other nodes.
**/
static inline void clist_add_head(clist *l, cnode *n)
{
clist_insert_after(n, &l->head);
}
/**
* Insert a new node after all other nodes.
**/
static inline void clist_add_tail(clist *l, cnode *n)
{
clist_insert_before(n, &l->head);
}
/**
* Remove node @n.
**/
static inline void clist_remove(cnode *n)
{
cnode *before = n->prev;
cnode *after = n->next;
before->next = after;
after->prev = before;
}
/**
* Remove the first node in @l, if it exists. Return the pointer to that node or NULL.
**/
static inline void *clist_remove_head(clist *l)
{
cnode *n = clist_head(l);
if (n)
clist_remove(n);
return n;
}
/**
* Remove the last node in @l, if it exists. Return the pointer to that node or NULL.
**/
static inline void *clist_remove_tail(clist *l)
{
cnode *n = clist_tail(l);
if (n)
clist_remove(n);
return n;
}
/**
* Merge two lists by inserting the list @what just after the node @after in a different list.
* The first list is then cleared.
**/
static inline void clist_insert_list_after(clist *what, cnode *after)
{
if (!clist_empty(what))
{
cnode *w = &what->head;
w->prev->next = after->next;
after->next->prev = w->prev;
w->next->prev = after;
after->next = w->next;
clist_init(what);
}
}
/**
* Merge two lists by inserting the list @what in front of all other nodes in a different list @l.
* The first list is then cleared.
**/
static inline void clist_add_list_head(clist *l, clist *what)
{
clist_insert_list_after(what, &l->head);
}
/**
* Merge two lists by inserting the list @what after all other nodes in a different list @l.
* The first list is then cleared.
**/
static inline void clist_add_list_tail(clist *l, clist *what)
{
clist_insert_list_after(what, l->head.prev);
}
/**
* Move all items from a source list to a destination list. The source list
* becomes empty, the original contents of the destination list are destroyed.
**/
static inline void clist_move(clist *to, clist *from)
{
clist_init(to);
clist_insert_list_after(from, &to->head);
clist_init(from);
}
/**
* Compute the number of nodes in @l. Beware of linear time complexity.
**/
static inline uint clist_size(clist *l)
{
uint i = 0;
CLIST_FOR_EACH(cnode *, n, *l)
i++;
return i;
}
/**
* Remove a node @n and mark it as unlinked by setting the previous and next pointers to NULL.
**/
static inline void clist_unlink(cnode *n)
{
clist_remove(n);
n->prev = n->next = NULL;
}
/**
* Remove the first node on @l and mark it as unlinked.
* Return the pointer to that node or NULL.
**/
static inline void *clist_unlink_head(clist *l)
{
cnode *n = clist_head(l);
if (n)
clist_unlink(n);
return n;
}
/**
* Remove the last node on @l and mark it as unlinked.
* Return the pointer to that node or NULL.
**/
static inline void *clist_unlink_tail(clist *l)
{
cnode *n = clist_tail(l);
if (n)
clist_unlink(n);
return n;
}
/**
* Check if a node is linked a list. Unlinked nodes are recognized by having their
* previous and next pointers equal to NULL. Returns 0 or 1.
*
* Nodes initialized to all zeroes are unlinked, inserting a node anywhere in a list
* makes it linked. Normal removal functions like @clist_remove() do not mark nodes
* as unlinked, you need to call @clist_unlink() instead.
**/
static inline int clist_is_linked(cnode *n)
{
return !!n->next;
}
#endif