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glib/glib/gnode.c
Philip Withnall 00bfb3ab44 tree: Fix various typos and outdated terminology 
This was mostly machine generated with the following command:
```
codespell \
    --builtin clear,rare,usage \
    --skip './po/*' --skip './.git/*' --skip './NEWS*' \
    --write-changes .
```
using the latest git version of `codespell` as per [these
instructions](https://github.com/codespell-project/codespell#user-content-updating).

Then I manually checked each change using `git add -p`, made a few
manual fixups and dropped a load of incorrect changes.

There are still some outdated or loaded terms used in GLib, mostly to do
with git branch terminology. They will need to be changed later as part
of a wider migration of git terminology.

If I’ve missed anything, please file an issue!

Signed-off-by: Philip Withnall <withnall@endlessm.com>
2020-06-12 15:01:08 +01:00

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/* GLIB - Library of useful routines for C programming
* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
*
* GNode: N-way tree implementation.
* Copyright (C) 1998 Tim Janik
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
/*
* Modified by the GLib Team and others 1997-2000. See the AUTHORS
* file for a list of people on the GLib Team. See the ChangeLog
* files for a list of changes. These files are distributed with
* GLib at ftp://ftp.gtk.org/pub/gtk/.
*/
/*
* MT safe
*/
#include "config.h"
#include "gnode.h"
#include "gslice.h"
#include "gtestutils.h"
/**
* SECTION:trees-nary
* @title: N-ary Trees
* @short_description: trees of data with any number of branches
*
* The #GNode struct and its associated functions provide a N-ary tree
* data structure, where nodes in the tree can contain arbitrary data.
*
* To create a new tree use g_node_new().
*
* To insert a node into a tree use g_node_insert(),
* g_node_insert_before(), g_node_append() and g_node_prepend().
*
* To create a new node and insert it into a tree use
* g_node_insert_data(), g_node_insert_data_after(),
* g_node_insert_data_before(), g_node_append_data()
* and g_node_prepend_data().
*
* To reverse the children of a node use g_node_reverse_children().
*
* To find a node use g_node_get_root(), g_node_find(),
* g_node_find_child(), g_node_child_index(), g_node_child_position(),
* g_node_first_child(), g_node_last_child(), g_node_nth_child(),
* g_node_first_sibling(), g_node_prev_sibling(), g_node_next_sibling()
* or g_node_last_sibling().
*
* To get information about a node or tree use G_NODE_IS_LEAF(),
* G_NODE_IS_ROOT(), g_node_depth(), g_node_n_nodes(),
* g_node_n_children(), g_node_is_ancestor() or g_node_max_height().
*
* To traverse a tree, calling a function for each node visited in the
* traversal, use g_node_traverse() or g_node_children_foreach().
*
* To remove a node or subtree from a tree use g_node_unlink() or
* g_node_destroy().
**/
/**
* GNode:
* @data: contains the actual data of the node.
* @next: points to the node's next sibling (a sibling is another
* #GNode with the same parent).
* @prev: points to the node's previous sibling.
* @parent: points to the parent of the #GNode, or is %NULL if the
* #GNode is the root of the tree.
* @children: points to the first child of the #GNode. The other
* children are accessed by using the @next pointer of each
* child.
*
* The #GNode struct represents one node in a [n-ary tree][glib-N-ary-Trees].
**/
#define g_node_alloc0() g_slice_new0 (GNode)
#define g_node_free(node) g_slice_free (GNode, node)
/* --- functions --- */
/**
* g_node_new:
* @data: the data of the new node
*
* Creates a new #GNode containing the given data.
* Used to create the first node in a tree.
*
* Returns: a new #GNode
*/
GNode*
g_node_new (gpointer data)
{
GNode *node = g_node_alloc0 ();
node->data = data;
return node;
}
static void
g_nodes_free (GNode *node)
{
while (node)
{
GNode *next = node->next;
if (node->children)
g_nodes_free (node->children);
g_node_free (node);
node = next;
}
}
/**
* g_node_destroy:
* @root: the root of the tree/subtree to destroy
*
* Removes @root and its children from the tree, freeing any memory
* allocated.
*/
void
g_node_destroy (GNode *root)
{
g_return_if_fail (root != NULL);
if (!G_NODE_IS_ROOT (root))
g_node_unlink (root);
g_nodes_free (root);
}
/**
* g_node_unlink:
* @node: the #GNode to unlink, which becomes the root of a new tree
*
* Unlinks a #GNode from a tree, resulting in two separate trees.
*/
void
g_node_unlink (GNode *node)
{
g_return_if_fail (node != NULL);
if (node->prev)
node->prev->next = node->next;
else if (node->parent)
node->parent->children = node->next;
node->parent = NULL;
if (node->next)
{
node->next->prev = node->prev;
node->next = NULL;
}
node->prev = NULL;
}
/**
* g_node_copy_deep:
* @node: a #GNode
* @copy_func: the function which is called to copy the data inside each node,
* or %NULL to use the original data.
* @data: data to pass to @copy_func
*
* Recursively copies a #GNode and its data.
*
* Returns: a new #GNode containing copies of the data in @node.
*
* Since: 2.4
**/
GNode*
g_node_copy_deep (GNode *node,
GCopyFunc copy_func,
gpointer data)
{
GNode *new_node = NULL;
if (copy_func == NULL)
return g_node_copy (node);
if (node)
{
GNode *child, *new_child;
new_node = g_node_new (copy_func (node->data, data));
for (child = g_node_last_child (node); child; child = child->prev)
{
new_child = g_node_copy_deep (child, copy_func, data);
g_node_prepend (new_node, new_child);
}
}
return new_node;
}
/**
* g_node_copy:
* @node: a #GNode
*
* Recursively copies a #GNode (but does not deep-copy the data inside the
* nodes, see g_node_copy_deep() if you need that).
*
* Returns: a new #GNode containing the same data pointers
*/
GNode*
g_node_copy (GNode *node)
{
GNode *new_node = NULL;
if (node)
{
GNode *child;
new_node = g_node_new (node->data);
for (child = g_node_last_child (node); child; child = child->prev)
g_node_prepend (new_node, g_node_copy (child));
}
return new_node;
}
/**
* g_node_insert:
* @parent: the #GNode to place @node under
* @position: the position to place @node at, with respect to its siblings
* If position is -1, @node is inserted as the last child of @parent
* @node: the #GNode to insert
*
* Inserts a #GNode beneath the parent at the given position.
*
* Returns: the inserted #GNode
*/
GNode*
g_node_insert (GNode *parent,
gint position,
GNode *node)
{
g_return_val_if_fail (parent != NULL, node);
g_return_val_if_fail (node != NULL, node);
g_return_val_if_fail (G_NODE_IS_ROOT (node), node);
if (position > 0)
return g_node_insert_before (parent,
g_node_nth_child (parent, position),
node);
else if (position == 0)
return g_node_prepend (parent, node);
else /* if (position < 0) */
return g_node_append (parent, node);
}
/**
* g_node_insert_before:
* @parent: the #GNode to place @node under
* @sibling: the sibling #GNode to place @node before.
* If sibling is %NULL, the node is inserted as the last child of @parent.
* @node: the #GNode to insert
*
* Inserts a #GNode beneath the parent before the given sibling.
*
* Returns: the inserted #GNode
*/
GNode*
g_node_insert_before (GNode *parent,
GNode *sibling,
GNode *node)
{
g_return_val_if_fail (parent != NULL, node);
g_return_val_if_fail (node != NULL, node);
g_return_val_if_fail (G_NODE_IS_ROOT (node), node);
if (sibling)
g_return_val_if_fail (sibling->parent == parent, node);
node->parent = parent;
if (sibling)
{
if (sibling->prev)
{
node->prev = sibling->prev;
node->prev->next = node;
node->next = sibling;
sibling->prev = node;
}
else
{
node->parent->children = node;
node->next = sibling;
sibling->prev = node;
}
}
else
{
if (parent->children)
{
sibling = parent->children;
while (sibling->next)
sibling = sibling->next;
node->prev = sibling;
sibling->next = node;
}
else
node->parent->children = node;
}
return node;
}
/**
* g_node_insert_after:
* @parent: the #GNode to place @node under
* @sibling: the sibling #GNode to place @node after.
* If sibling is %NULL, the node is inserted as the first child of @parent.
* @node: the #GNode to insert
*
* Inserts a #GNode beneath the parent after the given sibling.
*
* Returns: the inserted #GNode
*/
GNode*
g_node_insert_after (GNode *parent,
GNode *sibling,
GNode *node)
{
g_return_val_if_fail (parent != NULL, node);
g_return_val_if_fail (node != NULL, node);
g_return_val_if_fail (G_NODE_IS_ROOT (node), node);
if (sibling)
g_return_val_if_fail (sibling->parent == parent, node);
node->parent = parent;
if (sibling)
{
if (sibling->next)
{
sibling->next->prev = node;
}
node->next = sibling->next;
node->prev = sibling;
sibling->next = node;
}
else
{
if (parent->children)
{
node->next = parent->children;
parent->children->prev = node;
}
parent->children = node;
}
return node;
}
/**
* g_node_prepend:
* @parent: the #GNode to place the new #GNode under
* @node: the #GNode to insert
*
* Inserts a #GNode as the first child of the given parent.
*
* Returns: the inserted #GNode
*/
GNode*
g_node_prepend (GNode *parent,
GNode *node)
{
g_return_val_if_fail (parent != NULL, node);
return g_node_insert_before (parent, parent->children, node);
}
/**
* g_node_get_root:
* @node: a #GNode
*
* Gets the root of a tree.
*
* Returns: the root of the tree
*/
GNode*
g_node_get_root (GNode *node)
{
g_return_val_if_fail (node != NULL, NULL);
while (node->parent)
node = node->parent;
return node;
}
/**
* g_node_is_ancestor:
* @node: a #GNode
* @descendant: a #GNode
*
* Returns %TRUE if @node is an ancestor of @descendant.
* This is true if node is the parent of @descendant,
* or if node is the grandparent of @descendant etc.
*
* Returns: %TRUE if @node is an ancestor of @descendant
*/
gboolean
g_node_is_ancestor (GNode *node,
GNode *descendant)
{
g_return_val_if_fail (node != NULL, FALSE);
g_return_val_if_fail (descendant != NULL, FALSE);
while (descendant)
{
if (descendant->parent == node)
return TRUE;
descendant = descendant->parent;
}
return FALSE;
}
/**
* g_node_depth:
* @node: a #GNode
*
* Gets the depth of a #GNode.
*
* If @node is %NULL the depth is 0. The root node has a depth of 1.
* For the children of the root node the depth is 2. And so on.
*
* Returns: the depth of the #GNode
*/
guint
g_node_depth (GNode *node)
{
guint depth = 0;
while (node)
{
depth++;
node = node->parent;
}
return depth;
}
/**
* g_node_reverse_children:
* @node: a #GNode.
*
* Reverses the order of the children of a #GNode.
* (It doesn't change the order of the grandchildren.)
*/
void
g_node_reverse_children (GNode *node)
{
GNode *child;
GNode *last;
g_return_if_fail (node != NULL);
child = node->children;
last = NULL;
while (child)
{
last = child;
child = last->next;
last->next = last->prev;
last->prev = child;
}
node->children = last;
}
/**
* g_node_max_height:
* @root: a #GNode
*
* Gets the maximum height of all branches beneath a #GNode.
* This is the maximum distance from the #GNode to all leaf nodes.
*
* If @root is %NULL, 0 is returned. If @root has no children,
* 1 is returned. If @root has children, 2 is returned. And so on.
*
* Returns: the maximum height of the tree beneath @root
*/
guint
g_node_max_height (GNode *root)
{
GNode *child;
guint max_height = 0;
if (!root)
return 0;
child = root->children;
while (child)
{
guint tmp_height;
tmp_height = g_node_max_height (child);
if (tmp_height > max_height)
max_height = tmp_height;
child = child->next;
}
return max_height + 1;
}
static gboolean
g_node_traverse_pre_order (GNode *node,
GTraverseFlags flags,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
GNode *child;
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
child = node->children;
while (child)
{
GNode *current;
current = child;
child = current->next;
if (g_node_traverse_pre_order (current, flags, func, data))
return TRUE;
}
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_depth_traverse_pre_order (GNode *node,
GTraverseFlags flags,
guint depth,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
GNode *child;
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
depth--;
if (!depth)
return FALSE;
child = node->children;
while (child)
{
GNode *current;
current = child;
child = current->next;
if (g_node_depth_traverse_pre_order (current, flags, depth, func, data))
return TRUE;
}
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_traverse_post_order (GNode *node,
GTraverseFlags flags,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
GNode *child;
child = node->children;
while (child)
{
GNode *current;
current = child;
child = current->next;
if (g_node_traverse_post_order (current, flags, func, data))
return TRUE;
}
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_depth_traverse_post_order (GNode *node,
GTraverseFlags flags,
guint depth,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
depth--;
if (depth)
{
GNode *child;
child = node->children;
while (child)
{
GNode *current;
current = child;
child = current->next;
if (g_node_depth_traverse_post_order (current, flags, depth, func, data))
return TRUE;
}
}
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_traverse_in_order (GNode *node,
GTraverseFlags flags,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
GNode *child;
GNode *current;
child = node->children;
current = child;
child = current->next;
if (g_node_traverse_in_order (current, flags, func, data))
return TRUE;
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
while (child)
{
current = child;
child = current->next;
if (g_node_traverse_in_order (current, flags, func, data))
return TRUE;
}
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_depth_traverse_in_order (GNode *node,
GTraverseFlags flags,
guint depth,
GNodeTraverseFunc func,
gpointer data)
{
if (node->children)
{
depth--;
if (depth)
{
GNode *child;
GNode *current;
child = node->children;
current = child;
child = current->next;
if (g_node_depth_traverse_in_order (current, flags, depth, func, data))
return TRUE;
if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
while (child)
{
current = child;
child = current->next;
if (g_node_depth_traverse_in_order (current, flags, depth, func, data))
return TRUE;
}
}
else if ((flags & G_TRAVERSE_NON_LEAFS) &&
func (node, data))
return TRUE;
}
else if ((flags & G_TRAVERSE_LEAFS) &&
func (node, data))
return TRUE;
return FALSE;
}
static gboolean
g_node_traverse_level (GNode *node,
GTraverseFlags flags,
guint level,
GNodeTraverseFunc func,
gpointer data,
gboolean *more_levels)
{
if (level == 0)
{
if (node->children)
{
*more_levels = TRUE;
return (flags & G_TRAVERSE_NON_LEAFS) && func (node, data);
}
else
{
return (flags & G_TRAVERSE_LEAFS) && func (node, data);
}
}
else
{
node = node->children;
while (node)
{
if (g_node_traverse_level (node, flags, level - 1, func, data, more_levels))
return TRUE;
node = node->next;
}
}
return FALSE;
}
static gboolean
g_node_depth_traverse_level (GNode *node,
GTraverseFlags flags,
gint depth,
GNodeTraverseFunc func,
gpointer data)
{
guint level;
gboolean more_levels;
level = 0;
while (depth < 0 || level != (guint) depth)
{
more_levels = FALSE;
if (g_node_traverse_level (node, flags, level, func, data, &more_levels))
return TRUE;
if (!more_levels)
break;
level++;
}
return FALSE;
}
/**
* g_node_traverse:
* @root: the root #GNode of the tree to traverse
* @order: the order in which nodes are visited - %G_IN_ORDER,
* %G_PRE_ORDER, %G_POST_ORDER, or %G_LEVEL_ORDER.
* @flags: which types of children are to be visited, one of
* %G_TRAVERSE_ALL, %G_TRAVERSE_LEAVES and %G_TRAVERSE_NON_LEAVES
* @max_depth: the maximum depth of the traversal. Nodes below this
* depth will not be visited. If max_depth is -1 all nodes in
* the tree are visited. If depth is 1, only the root is visited.
* If depth is 2, the root and its children are visited. And so on.
* @func: the function to call for each visited #GNode
* @data: user data to pass to the function
*
* Traverses a tree starting at the given root #GNode.
* It calls the given function for each node visited.
* The traversal can be halted at any point by returning %TRUE from @func.
* @func must not do anything that would modify the structure of the tree.
*/
/**
* GTraverseType:
* @G_IN_ORDER: vists a node's left child first, then the node itself,
* then its right child. This is the one to use if you
* want the output sorted according to the compare
* function.
* @G_PRE_ORDER: visits a node, then its children.
* @G_POST_ORDER: visits the node's children, then the node itself.
* @G_LEVEL_ORDER: is not implemented for
* [balanced binary trees][glib-Balanced-Binary-Trees].
* For [n-ary trees][glib-N-ary-Trees], it
* vists the root node first, then its children, then
* its grandchildren, and so on. Note that this is less
* efficient than the other orders.
*
* Specifies the type of traversal performed by g_tree_traverse(),
* g_node_traverse() and g_node_find(). The different orders are
* illustrated here:
* - In order: A, B, C, D, E, F, G, H, I
* ![](Sorted_binary_tree_inorder.svg)
* - Pre order: F, B, A, D, C, E, G, I, H
* ![](Sorted_binary_tree_preorder.svg)
* - Post order: A, C, E, D, B, H, I, G, F
* ![](Sorted_binary_tree_postorder.svg)
* - Level order: F, B, G, A, D, I, C, E, H
* ![](Sorted_binary_tree_breadth-first_traversal.svg)
*/
/**
* GTraverseFlags:
* @G_TRAVERSE_LEAVES: only leaf nodes should be visited. This name has
* been introduced in 2.6, for older version use
* %G_TRAVERSE_LEAFS.
* @G_TRAVERSE_NON_LEAVES: only non-leaf nodes should be visited. This
* name has been introduced in 2.6, for older
* version use %G_TRAVERSE_NON_LEAFS.
* @G_TRAVERSE_ALL: all nodes should be visited.
* @G_TRAVERSE_MASK: a mask of all traverse flags.
* @G_TRAVERSE_LEAFS: identical to %G_TRAVERSE_LEAVES.
* @G_TRAVERSE_NON_LEAFS: identical to %G_TRAVERSE_NON_LEAVES.
*
* Specifies which nodes are visited during several of the tree
* functions, including g_node_traverse() and g_node_find().
**/
/**
* GNodeTraverseFunc:
* @node: a #GNode.
* @data: user data passed to g_node_traverse().
*
* Specifies the type of function passed to g_node_traverse(). The
* function is called with each of the nodes visited, together with the
* user data passed to g_node_traverse(). If the function returns
* %TRUE, then the traversal is stopped.
*
* Returns: %TRUE to stop the traversal.
**/
void
g_node_traverse (GNode *root,
GTraverseType order,
GTraverseFlags flags,
gint depth,
GNodeTraverseFunc func,
gpointer data)
{
g_return_if_fail (root != NULL);
g_return_if_fail (func != NULL);
g_return_if_fail (order <= G_LEVEL_ORDER);
g_return_if_fail (flags <= G_TRAVERSE_MASK);
g_return_if_fail (depth == -1 || depth > 0);
switch (order)
{
case G_PRE_ORDER:
if (depth < 0)
g_node_traverse_pre_order (root, flags, func, data);
else
g_node_depth_traverse_pre_order (root, flags, depth, func, data);
break;
case G_POST_ORDER:
if (depth < 0)
g_node_traverse_post_order (root, flags, func, data);
else
g_node_depth_traverse_post_order (root, flags, depth, func, data);
break;
case G_IN_ORDER:
if (depth < 0)
g_node_traverse_in_order (root, flags, func, data);
else
g_node_depth_traverse_in_order (root, flags, depth, func, data);
break;
case G_LEVEL_ORDER:
g_node_depth_traverse_level (root, flags, depth, func, data);
break;
}
}
static gboolean
g_node_find_func (GNode *node,
gpointer data)
{
gpointer *d = data;
if (*d != node->data)
return FALSE;
*(++d) = node;
return TRUE;
}
/**
* g_node_find:
* @root: the root #GNode of the tree to search
* @order: the order in which nodes are visited - %G_IN_ORDER,
* %G_PRE_ORDER, %G_POST_ORDER, or %G_LEVEL_ORDER
* @flags: which types of children are to be searched, one of
* %G_TRAVERSE_ALL, %G_TRAVERSE_LEAVES and %G_TRAVERSE_NON_LEAVES
* @data: the data to find
*
* Finds a #GNode in a tree.
*
* Returns: the found #GNode, or %NULL if the data is not found
*/
GNode*
g_node_find (GNode *root,
GTraverseType order,
GTraverseFlags flags,
gpointer data)
{
gpointer d[2];
g_return_val_if_fail (root != NULL, NULL);
g_return_val_if_fail (order <= G_LEVEL_ORDER, NULL);
g_return_val_if_fail (flags <= G_TRAVERSE_MASK, NULL);
d[0] = data;
d[1] = NULL;
g_node_traverse (root, order, flags, -1, g_node_find_func, d);
return d[1];
}
static void
g_node_count_func (GNode *node,
GTraverseFlags flags,
guint *n)
{
if (node->children)
{
GNode *child;
if (flags & G_TRAVERSE_NON_LEAFS)
(*n)++;
child = node->children;
while (child)
{
g_node_count_func (child, flags, n);
child = child->next;
}
}
else if (flags & G_TRAVERSE_LEAFS)
(*n)++;
}
/**
* g_node_n_nodes:
* @root: a #GNode
* @flags: which types of children are to be counted, one of
* %G_TRAVERSE_ALL, %G_TRAVERSE_LEAVES and %G_TRAVERSE_NON_LEAVES
*
* Gets the number of nodes in a tree.
*
* Returns: the number of nodes in the tree
*/
guint
g_node_n_nodes (GNode *root,
GTraverseFlags flags)
{
guint n = 0;
g_return_val_if_fail (root != NULL, 0);
g_return_val_if_fail (flags <= G_TRAVERSE_MASK, 0);
g_node_count_func (root, flags, &n);
return n;
}
/**
* g_node_last_child:
* @node: a #GNode (must not be %NULL)
*
* Gets the last child of a #GNode.
*
* Returns: the last child of @node, or %NULL if @node has no children
*/
GNode*
g_node_last_child (GNode *node)
{
g_return_val_if_fail (node != NULL, NULL);
node = node->children;
if (node)
while (node->next)
node = node->next;
return node;
}
/**
* g_node_nth_child:
* @node: a #GNode
* @n: the index of the desired child
*
* Gets a child of a #GNode, using the given index.
* The first child is at index 0. If the index is
* too big, %NULL is returned.
*
* Returns: the child of @node at index @n
*/
GNode*
g_node_nth_child (GNode *node,
guint n)
{
g_return_val_if_fail (node != NULL, NULL);
node = node->children;
if (node)
while ((n-- > 0) && node)
node = node->next;
return node;
}
/**
* g_node_n_children:
* @node: a #GNode
*
* Gets the number of children of a #GNode.
*
* Returns: the number of children of @node
*/
guint
g_node_n_children (GNode *node)
{
guint n = 0;
g_return_val_if_fail (node != NULL, 0);
node = node->children;
while (node)
{
n++;
node = node->next;
}
return n;
}
/**
* g_node_find_child:
* @node: a #GNode
* @flags: which types of children are to be searched, one of
* %G_TRAVERSE_ALL, %G_TRAVERSE_LEAVES and %G_TRAVERSE_NON_LEAVES
* @data: the data to find
*
* Finds the first child of a #GNode with the given data.
*
* Returns: the found child #GNode, or %NULL if the data is not found
*/
GNode*
g_node_find_child (GNode *node,
GTraverseFlags flags,
gpointer data)
{
g_return_val_if_fail (node != NULL, NULL);
g_return_val_if_fail (flags <= G_TRAVERSE_MASK, NULL);
node = node->children;
while (node)
{
if (node->data == data)
{
if (G_NODE_IS_LEAF (node))
{
if (flags & G_TRAVERSE_LEAFS)
return node;
}
else
{
if (flags & G_TRAVERSE_NON_LEAFS)
return node;
}
}
node = node->next;
}
return NULL;
}
/**
* g_node_child_position:
* @node: a #GNode
* @child: a child of @node
*
* Gets the position of a #GNode with respect to its siblings.
* @child must be a child of @node. The first child is numbered 0,
* the second 1, and so on.
*
* Returns: the position of @child with respect to its siblings
*/
gint
g_node_child_position (GNode *node,
GNode *child)
{
guint n = 0;
g_return_val_if_fail (node != NULL, -1);
g_return_val_if_fail (child != NULL, -1);
g_return_val_if_fail (child->parent == node, -1);
node = node->children;
while (node)
{
if (node == child)
return n;
n++;
node = node->next;
}
return -1;
}
/**
* g_node_child_index:
* @node: a #GNode
* @data: the data to find
*
* Gets the position of the first child of a #GNode
* which contains the given data.
*
* Returns: the index of the child of @node which contains
* @data, or -1 if the data is not found
*/
gint
g_node_child_index (GNode *node,
gpointer data)
{
guint n = 0;
g_return_val_if_fail (node != NULL, -1);
node = node->children;
while (node)
{
if (node->data == data)
return n;
n++;
node = node->next;
}
return -1;
}
/**
* g_node_first_sibling:
* @node: a #GNode
*
* Gets the first sibling of a #GNode.
* This could possibly be the node itself.
*
* Returns: the first sibling of @node
*/
GNode*
g_node_first_sibling (GNode *node)
{
g_return_val_if_fail (node != NULL, NULL);
if (node->parent)
return node->parent->children;
while (node->prev)
node = node->prev;
return node;
}
/**
* g_node_last_sibling:
* @node: a #GNode
*
* Gets the last sibling of a #GNode.
* This could possibly be the node itself.
*
* Returns: the last sibling of @node
*/
GNode*
g_node_last_sibling (GNode *node)
{
g_return_val_if_fail (node != NULL, NULL);
while (node->next)
node = node->next;
return node;
}
/**
* g_node_children_foreach:
* @node: a #GNode
* @flags: which types of children are to be visited, one of
* %G_TRAVERSE_ALL, %G_TRAVERSE_LEAVES and %G_TRAVERSE_NON_LEAVES
* @func: the function to call for each visited node
* @data: user data to pass to the function
*
* Calls a function for each of the children of a #GNode. Note that it
* doesn't descend beneath the child nodes. @func must not do anything
* that would modify the structure of the tree.
*/
/**
* GNodeForeachFunc:
* @node: a #GNode.
* @data: user data passed to g_node_children_foreach().
*
* Specifies the type of function passed to g_node_children_foreach().
* The function is called with each child node, together with the user
* data passed to g_node_children_foreach().
**/
void
g_node_children_foreach (GNode *node,
GTraverseFlags flags,
GNodeForeachFunc func,
gpointer data)
{
g_return_if_fail (node != NULL);
g_return_if_fail (flags <= G_TRAVERSE_MASK);
g_return_if_fail (func != NULL);
node = node->children;
while (node)
{
GNode *current;
current = node;
node = current->next;
if (G_NODE_IS_LEAF (current))
{
if (flags & G_TRAVERSE_LEAFS)
func (current, data);
}
else
{
if (flags & G_TRAVERSE_NON_LEAFS)
func (current, data);
}
}
}
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