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GList * | g_list_append () |
GList * | g_list_prepend () |
GList * | g_list_insert () |
GList * | g_list_insert_before () |
GList * | g_list_insert_before_link () |
GList * | g_list_insert_sorted () |
GList * | g_list_remove () |
GList * | g_list_remove_link () |
GList * | g_list_delete_link () |
GList * | g_list_remove_all () |
void | g_list_free () |
void | g_list_free_full () |
void | g_clear_list () |
GList * | g_list_alloc () |
void | g_list_free_1 () |
guint | g_list_length () |
GList * | g_list_copy () |
GList * | g_list_copy_deep () |
GList * | g_list_reverse () |
GList * | g_list_sort () |
gint | (*GCompareFunc) () |
GList * | g_list_insert_sorted_with_data () |
GList * | g_list_sort_with_data () |
gint | (*GCompareDataFunc) () |
GList * | g_list_concat () |
void | g_list_foreach () |
void | (*GFunc) () |
GList * | g_list_first () |
GList * | g_list_last () |
#define | g_list_previous() |
#define | g_list_next() |
GList * | g_list_nth () |
gpointer | g_list_nth_data () |
GList * | g_list_nth_prev () |
GList * | g_list_find () |
GList * | g_list_find_custom () |
gint | g_list_position () |
gint | g_list_index () |
The GList structure and its associated functions provide a standard doubly-linked list data structure. The benefit of this data-structure is to provide insertion/deletion operations in O(1) complexity where access/search operations are in O(n). The benefit of GList over GSList (singly linked list) is that the worst case on access/search operations is divided by two which comes at a cost in space as we need to retain two pointers in place of one.
Each element in the list contains a piece of data, together with pointers which link to the previous and next elements in the list. Using these pointers it is possible to move through the list in both directions (unlike the singly-linked GSList, which only allows movement through the list in the forward direction).
The double linked list does not keep track of the number of items and does not keep track of both the start and end of the list. If you want fast access to both the start and the end of the list, and/or the number of items in the list, use a GQueue instead.
The data contained in each element can be either integer values, by using one of the Type Conversion Macros, or simply pointers to any type of data.
List elements are allocated from the slice allocator, which is more efficient than allocating elements individually.
Note that most of the GList functions expect to be passed a pointer to the first element in the list. The functions which insert elements return the new start of the list, which may have changed.
There is no function to create a GList. NULL
is considered to be
a valid, empty list so you simply set a GList* to NULL
to initialize
it.
To add elements, use g_list_append()
, g_list_prepend()
,
g_list_insert()
and g_list_insert_sorted()
.
To visit all elements in the list, use a loop over the list:
1 2 3 4 5 |
GList *l; for (l = list; l != NULL; l = l->next) { // do something with l->data } |
To call a function for each element in the list, use g_list_foreach()
.
To loop over the list and modify it (e.g. remove a certain element) a while loop is more appropriate, for example:
1 2 3 4 5 6 7 8 9 10 11 |
GList *l = list; while (l != NULL) { GList *next = l->next; if (should_be_removed (l)) { // possibly free l->data list = g_list_delete_link (list, l); } l = next; } |
To remove elements, use g_list_remove()
.
To navigate in a list, use g_list_first()
, g_list_last()
,
g_list_next()
, g_list_previous()
.
To find elements in the list use g_list_nth()
, g_list_nth_data()
,
g_list_find()
and g_list_find_custom()
.
To find the index of an element use g_list_position()
and
g_list_index()
.
To free the entire list, use g_list_free()
or g_list_free_full()
.
GList * g_list_append (GList *list
,gpointer data
);
Adds a new element on to the end of the list.
Note that the return value is the new start of the list,
if list
was empty; make sure you store the new value.
g_list_append() has to traverse the entire list to find the end,
which is inefficient when adding multiple elements. A common idiom
to avoid the inefficiency is to use g_list_prepend()
and reverse
the list with g_list_reverse()
when all elements have been added.
1 2 3 4 5 6 7 8 9 10 |
// Notice that these are initialized to the empty list. GList *string_list = NULL, *number_list = NULL; // This is a list of strings. string_list = g_list_append (string_list, "first"); string_list = g_list_append (string_list, "second"); // This is a list of integers. number_list = g_list_append (number_list, GINT_TO_POINTER (27)); number_list = g_list_append (number_list, GINT_TO_POINTER (14)); |
GList * g_list_prepend (GList *list
,gpointer data
);
Prepends a new element on to the start of the list.
Note that the return value is the new start of the list, which will have changed, so make sure you store the new value.
1 2 3 4 5 |
// Notice that it is initialized to the empty list. GList *list = NULL; list = g_list_prepend (list, "last"); list = g_list_prepend (list, "first"); |
Do not use this function to prepend a new element to a different
element than the start of the list. Use g_list_insert_before()
instead.
list |
a pointer to a GList, this must point to the top of the list |
|
data |
the data for the new element |
GList * g_list_insert (GList *list
,gpointer data
,gint position
);
Inserts a new element into the list at the given position.
list |
a pointer to a GList, this must point to the top of the list |
|
data |
the data for the new element |
|
position |
the position to insert the element. If this is negative, or is larger than the number of elements in the list, the new element is added on to the end of the list. |
GList * g_list_insert_before (GList *list
,GList *sibling
,gpointer data
);
Inserts a new element into the list before the given position.
GList * g_list_insert_before_link (GList *list
,GList *sibling
,GList *link_
);
Inserts link_
into the list before the given position.
Since: 2.62
GList * g_list_insert_sorted (GList *list
,gpointer data
,GCompareFunc func
);
Inserts a new element into the list, using the given comparison function to determine its position.
If you are adding many new elements to a list, and the number of
new elements is much larger than the length of the list, use
g_list_prepend()
to add the new items and sort the list afterwards
with g_list_sort()
.
list |
a pointer to a GList, this must point to the top of the already sorted list |
|
data |
the data for the new element |
|
func |
the function to compare elements in the list. It should return a number > 0 if the first parameter comes after the second parameter in the sort order. |
GList * g_list_remove (GList *list
,gconstpointer data
);
Removes an element from a GList. If two elements contain the same data, only the first is removed. If none of the elements contain the data, the GList is unchanged.
list |
a GList, this must point to the top of the list |
|
data |
the data of the element to remove |
GList * g_list_remove_link (GList *list
,GList *llink
);
Removes an element from a GList, without freeing the element.
The removed element's prev and next links are set to NULL
, so
that it becomes a self-contained list with one element.
This function is for example used to move an element in the list
(see the example for g_list_concat()
) or to remove an element in
the list before freeing its data:
1 2 3 |
list = g_list_remove_link (list, llink); free_some_data_that_may_access_the_list_again (llink->data); g_list_free (llink); |
GList * g_list_delete_link (GList *list
,GList *link_
);
Removes the node link_ from the list and frees it.
Compare this to g_list_remove_link()
which removes the node
without freeing it.
GList * g_list_remove_all (GList *list
,gconstpointer data
);
Removes all list nodes with data equal to data
.
Returns the new head of the list. Contrast with
g_list_remove()
which removes only the first node
matching the given data.
void
g_list_free (GList *list
);
Frees all of the memory used by a GList. The freed elements are returned to the slice allocator.
If list elements contain dynamically-allocated memory, you should
either use g_list_free_full()
or free them manually first.
It can be combined with g_steal_pointer()
to ensure the list head pointer
is not left dangling:
1 2 |
GList *list_of_borrowed_things = …; /<!-- -->* (transfer container) *<!-- -->/ g_list_free (g_steal_pointer (&list_of_borrowed_things)); |
void g_list_free_full (GList *list
,GDestroyNotify free_func
);
Convenience method, which frees all the memory used by a GList,
and calls free_func
on every element's data.
free_func
must not modify the list (eg, by removing the freed
element from it).
It can be combined with g_steal_pointer()
to ensure the list head pointer
is not left dangling — this also has the nice property that the head pointer
is cleared before any of the list elements are freed, to prevent double frees
from free_func
:
1 2 |
GList *list_of_owned_things = …; /<!-- -->* (transfer full) (element-type GObject) *<!-- -->/ g_list_free_full (g_steal_pointer (&list_of_owned_things), g_object_unref); |
list |
the first link of a GList |
|
free_func |
the function to be called to free each element's data |
Since: 2.28
void g_clear_list (GList **list_ptr
,GDestroyNotify destroy
);
Clears a pointer to a GList, freeing it and, optionally, freeing its elements using destroy
.
list_ptr
must be a valid pointer. If list_ptr
points to a null GList, this does nothing.
[skip]
list_ptr |
a GList return location. |
[not nullable] |
destroy |
the function to pass to |
[nullable] |
Since: 2.64
GList *
g_list_alloc (void
);
Allocates space for one GList element. It is called by
g_list_append()
, g_list_prepend()
, g_list_insert()
and
g_list_insert_sorted()
and so is rarely used on its own.
void
g_list_free_1 (GList *list
);
Frees one GList element, but does not update links from the next and previous elements in the list, so you should not call this function on an element that is currently part of a list.
It is usually used after g_list_remove_link()
.
guint
g_list_length (GList *list
);
Gets the number of elements in a GList.
This function iterates over the whole list to count its elements.
Use a GQueue instead of a GList if you regularly need the number
of items. To check whether the list is non-empty, it is faster to check
list
against NULL
.
GList *
g_list_copy (GList *list
);
Copies a GList.
Note that this is a "shallow" copy. If the list elements
consist of pointers to data, the pointers are copied but
the actual data is not. See g_list_copy_deep()
if you need
to copy the data as well.
GList * g_list_copy_deep (GList *list
,GCopyFunc func
,gpointer user_data
);
Makes a full (deep) copy of a GList.
In contrast with g_list_copy()
, this function uses func
to make
a copy of each list element, in addition to copying the list
container itself.
func
, as a GCopyFunc, takes two arguments, the data to be copied
and a user_data
pointer. On common processor architectures, it's safe to
pass NULL
as user_data
if the copy function takes only one argument. You
may get compiler warnings from this though if compiling with GCC’s
-Wcast-function-type
warning.
For instance, if list
holds a list of GObjects, you can do:
1 |
another_list = g_list_copy_deep (list, (GCopyFunc) g_object_ref, NULL); |
And, to entirely free the new list, you could do:
1 |
g_list_free_full (another_list, g_object_unref); |
the start of the new list that holds a full copy of list
,
use g_list_free_full()
to free it
Since: 2.34
GList *
g_list_reverse (GList *list
);
Reverses a GList. It simply switches the next and prev pointers of each element.
GList * g_list_sort (GList *list
,GCompareFunc compare_func
);
Sorts a GList using the given comparison function. The algorithm used is a stable sort.
list |
a GList, this must point to the top of the list |
|
compare_func |
the comparison function used to sort the GList. This function is passed the data from 2 elements of the GList and should return 0 if they are equal, a negative value if the first element comes before the second, or a positive value if the first element comes after the second. |
gint (*GCompareFunc) (gconstpointer a
,gconstpointer b
);
Specifies the type of a comparison function used to compare two values. The function should return a negative integer if the first value comes before the second, 0 if they are equal, or a positive integer if the first value comes after the second.
GList * g_list_insert_sorted_with_data (GList *list
,gpointer data
,GCompareDataFunc func
,gpointer user_data
);
Inserts a new element into the list, using the given comparison function to determine its position.
If you are adding many new elements to a list, and the number of
new elements is much larger than the length of the list, use
g_list_prepend()
to add the new items and sort the list afterwards
with g_list_sort()
.
list |
a pointer to a GList, this must point to the top of the already sorted list |
|
data |
the data for the new element |
|
func |
the function to compare elements in the list. It should return a number > 0 if the first parameter comes after the second parameter in the sort order. |
|
user_data |
user data to pass to comparison function |
Since: 2.10
GList * g_list_sort_with_data (GList *list
,GCompareDataFunc compare_func
,gpointer user_data
);
Like g_list_sort()
, but the comparison function accepts
a user data argument.
list |
a GList, this must point to the top of the list |
|
compare_func |
comparison function |
|
user_data |
user data to pass to comparison function |
gint (*GCompareDataFunc) (gconstpointer a
,gconstpointer b
,gpointer user_data
);
Specifies the type of a comparison function used to compare two values. The function should return a negative integer if the first value comes before the second, 0 if they are equal, or a positive integer if the first value comes after the second.
GList * g_list_concat (GList *list1
,GList *list2
);
Adds the second GList onto the end of the first GList. Note that the elements of the second GList are not copied. They are used directly.
This function is for example used to move an element in the list. The following example moves an element to the top of the list:
1 2 |
list = g_list_remove_link (list, llink); list = g_list_concat (llink, list); |
void g_list_foreach (GList *list
,GFunc func
,gpointer user_data
);
Calls a function for each element of a GList.
It is safe for func
to remove the element from list
, but it must
not modify any part of the list after that element.
list |
a GList, this must point to the top of the list |
|
func |
the function to call with each element's data |
|
user_data |
user data to pass to the function |
void (*GFunc) (gpointer data
,gpointer user_data
);
Specifies the type of functions passed to g_list_foreach()
and
g_slist_foreach()
.
data |
the element's data |
|
user_data |
user data passed to |
#define g_list_previous(list)
A convenience macro to get the previous element in a GList.
Note that it is considered perfectly acceptable to access
list->prev
directly.
#define g_list_next(list)
A convenience macro to get the next element in a GList.
Note that it is considered perfectly acceptable to access
list->next
directly.
GList * g_list_nth (GList *list
,guint n
);
Gets the element at the given position in a GList.
This iterates over the list until it reaches the n
-th position. If you
intend to iterate over every element, it is better to use a for-loop as
described in the GList introduction.
list |
a GList, this must point to the top of the list |
|
n |
the position of the element, counting from 0 |
gpointer g_list_nth_data (GList *list
,guint n
);
Gets the data of the element at the given position.
This iterates over the list until it reaches the n
-th position. If you
intend to iterate over every element, it is better to use a for-loop as
described in the GList introduction.
GList * g_list_nth_prev (GList *list
,guint n
);
Gets the element n
places before list
.
GList * g_list_find (GList *list
,gconstpointer data
);
Finds the element in a GList which contains the given data.
GList * g_list_find_custom (GList *list
,gconstpointer data
,GCompareFunc func
);
Finds an element in a GList, using a supplied function to find the desired element. It iterates over the list, calling the given function which should return 0 when the desired element is found. The function takes two gconstpointer arguments, the GList element's data as the first argument and the given user data.
list |
a GList, this must point to the top of the list |
|
data |
user data passed to the function |
|
func |
the function to call for each element. It should return 0 when the desired element is found |
gint g_list_position (GList *list
,GList *llink
);
Gets the position of the given element in the GList (starting from 0).
gint g_list_index (GList *list
,gconstpointer data
);
Gets the position of the element containing the given data (starting from 0).
struct GList { gpointer data; GList *next; GList *prev; };
The GList struct is used for each element in a doubly-linked list.
gpointer |
holds the element's data, which can be a pointer to any kind of data, or any integer value using the Type Conversion Macros |
|
GList * |
contains the link to the next element in the list |
|
GList * |
contains the link to the previous element in the list |