sudo-1.7.4p4/redblack.c - nest-learning-thermostat/5.1.8/sudo - Git at Google

 /*
  * Copyright (c) 2004-2005, 2007,2009 Todd C. Miller <Todd.Miller@courtesan.com>
  *
  * Permission to use, copy, modify, and distribute this software for any
  * purpose with or without fee is hereby granted, provided that the above
  * copyright notice and this permission notice appear in all copies.
  *
  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
  */

 /*
  * Adapted from the following code written by Emin Martinian:
  * http://web.mit.edu/~emin/www/source_code/red_black_tree/index.html
  *
  * Copyright (c) 2001 Emin Martinian
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that neither the name of Emin
  * Martinian nor the names of any contributors are be used to endorse or
  * promote products derived from this software without specific prior
  * written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
  * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include <config.h>

 #include <sys/types.h>
 #include <sys/param.h>

 #include <stdio.h>
 #ifdef STDC_HEADERS
 # include <stdlib.h>
 # include <stddef.h>
 #else
 # ifdef HAVE_STDLIB_H
 #  include <stdlib.h>
 # endif
 #endif /* STDC_HEADERS */

 #include "sudo.h"
 #include "redblack.h"

 static void rbrepair		__P((struct rbtree *, struct rbnode *));
 static void rotate_left		__P((struct rbtree *, struct rbnode *));
 static void rotate_right	__P((struct rbtree *, struct rbnode *));
 static void _rbdestroy		__P((struct rbtree *, struct rbnode *,
 				    void (*)(void *)));

 /*
  * Red-Black tree, see http://en.wikipedia.org/wiki/Red-black_tree
  *
  * A red-black tree is a binary search tree where each node has a color
  * attribute, the value of which is either red or black.  Essentially, it
  * is just a convenient way to express a 2-3-4 binary search tree where
  * the color indicates whether the node is part of a 3-node or a 4-node.
  * In addition to the ordinary requirements imposed on binary search
  * trees, we make the following additional requirements of any valid
  * red-black tree:
  *  1) Every node is either red or black.
  *  2) The root is black.
  *  3) All leaves are black.
  *  4) Both children of each red node are black.
  *  5) The paths from each leaf up to the root each contain the same
  *     number of black nodes.
  */

 /*
  * Create a red black tree struct using the specified compare routine.
  * Allocates and returns the initialized (empty) tree.
  */
 struct rbtree *
 rbcreate(compar)
     int (*compar)__P((const void *, const void*));
 {
     struct rbtree *tree;

     tree = (struct rbtree *) emalloc(sizeof(*tree));
     tree->compar = compar;

     /*
      * We use a self-referencing sentinel node called nil to simplify the
      * code by avoiding the need to check for NULL pointers.
      */
     tree->nil.left = tree->nil.right = tree->nil.parent = &tree->nil;
     tree->nil.color = black;
     tree->nil.data = NULL;

     /*
      * Similarly, the fake root node keeps us from having to worry
      * about splitting the root.
      */
     tree->root.left = tree->root.right = tree->root.parent = &tree->nil;
     tree->root.color = black;
     tree->root.data = NULL;

     return(tree);
 }

 /*
  * Perform a left rotation starting at node.
  */
 static void
 rotate_left(tree, node)
     struct rbtree *tree;
     struct rbnode *node;
 {
     struct rbnode *child;

     child = node->right;
     node->right = child->left;

     if (child->left != rbnil(tree))
         child->left->parent = node;
     child->parent = node->parent;

     if (node == node->parent->left)
 	node->parent->left = child;
     else
 	node->parent->right = child;
     child->left = node;
     node->parent = child;
 }

 /*
  * Perform a right rotation starting at node.
  */
 static void
 rotate_right(tree, node)
     struct rbtree *tree;
     struct rbnode *node;
 {
     struct rbnode *child;

     child = node->left;
     node->left = child->right;

     if (child->right != rbnil(tree))
         child->right->parent = node;
     child->parent = node->parent;

     if (node == node->parent->left)
 	node->parent->left = child;
     else
 	node->parent->right = child;
     child->right = node;
     node->parent = child;
 }

 /*
  * Insert data pointer into a redblack tree.
  * Returns a NULL pointer on success.  If a node matching "data"
  * already exists, a pointer to the existant node is returned.
  */
 struct rbnode *
 rbinsert(tree, data)
     struct rbtree *tree;
     void *data;
 {
     struct rbnode *node = rbfirst(tree);
     struct rbnode *parent = rbroot(tree);
     int res;

     /* Find correct insertion point. */
     while (node != rbnil(tree)) {
 	parent = node;
 	if ((res = tree->compar(data, node->data)) == 0)
 	    return(node);
 	node = res < 0 ? node->left : node->right;
     }

     node = (struct rbnode *) emalloc(sizeof(*node));
     node->data = data;
     node->left = node->right = rbnil(tree);
     node->parent = parent;
     if (parent == rbroot(tree) || tree->compar(data, parent->data) < 0)
 	parent->left = node;
     else
 	parent->right = node;
     node->color = red;

     /*
      * If the parent node is black we are all set, if it is red we have
      * the following possible cases to deal with.  We iterate through
      * the rest of the tree to make sure none of the required properties
      * is violated.
      *
      *	1) The uncle is red.  We repaint both the parent and uncle black
      *     and repaint the grandparent node red.
      *
      *  2) The uncle is black and the new node is the right child of its
      *     parent, and the parent in turn is the left child of its parent.
      *     We do a left rotation to switch the roles of the parent and
      *     child, relying on further iterations to fixup the old parent.
      *
      *  3) The uncle is black and the new node is the left child of its
      *     parent, and the parent in turn is the left child of its parent.
      *     We switch the colors of the parent and grandparent and perform
      *     a right rotation around the grandparent.  This makes the former
      *     parent the parent of the new node and the former grandparent.
      *
      * Note that because we use a sentinel for the root node we never
      * need to worry about replacing the root.
      */
     while (node->parent->color == red) {
 	struct rbnode *uncle;
 	if (node->parent == node->parent->parent->left) {
 	    uncle = node->parent->parent->right;
 	    if (uncle->color == red) {
 		node->parent->color = black;
 		uncle->color = black;
 		node->parent->parent->color = red;
 		node = node->parent->parent;
 	    } else /* if (uncle->color == black) */ {
 		if (node == node->parent->right) {
 		    node = node->parent;
 		    rotate_left(tree, node);
 		}
 		node->parent->color = black;
 		node->parent->parent->color = red;
 		rotate_right(tree, node->parent->parent);
 	    }
 	} else { /* if (node->parent == node->parent->parent->right) */
 	    uncle = node->parent->parent->left;
 	    if (uncle->color == red) {
 		node->parent->color = black;
 		uncle->color = black;
 		node->parent->parent->color = red;
 		node = node->parent->parent;
 	    } else /* if (uncle->color == black) */ {
 		if (node == node->parent->left) {
 		    node = node->parent;
 		    rotate_right(tree, node);
 		}
 		node->parent->color = black;
 		node->parent->parent->color = red;
 		rotate_left(tree, node->parent->parent);
 	    }
 	}
     }
     rbfirst(tree)->color = black;	/* first node is always black */
     return(NULL);
 }

 /*
  * Look for a node matching key in tree.
  * Returns a pointer to the node if found, else NULL.
  */
 struct rbnode *
 rbfind(tree, key)
     struct rbtree *tree;
     void *key;
 {
     struct rbnode *node = rbfirst(tree);
     int res;

     while (node != rbnil(tree)) {
 	if ((res = tree->compar(key, node->data)) == 0)
 	    return(node);
 	node = res < 0 ? node->left : node->right;
     }
     return(NULL);
 }

 /*
  * Call func() for each node, passing it the node data and a cookie;
  * If func() returns non-zero for a node, the traversal stops and the
  * error value is returned.  Returns 0 on successful traversal.
  */
 int
 rbapply_node(tree, node, func, cookie, order)
     struct rbtree *tree;
     struct rbnode *node;
     int (*func)__P((void *, void *));
     void *cookie;
     enum rbtraversal order;
 {
     int error;

     if (node != rbnil(tree)) {
 	if (order == preorder)
 	    if ((error = func(node->data, cookie)) != 0)
 		return(error);
 	if ((error = rbapply_node(tree, node->left, func, cookie, order)) != 0)
 	    return(error);
 	if (order == inorder)
 	    if ((error = func(node->data, cookie)) != 0)
 		return(error);
 	if ((error = rbapply_node(tree, node->right, func, cookie, order)) != 0)
 	    return(error);
 	if (order == postorder)
 	    if ((error = func(node->data, cookie)) != 0)
 		return(error);
     }
     return (0);
 }

 /*
  * Returns the successor of node, or nil if there is none.
  */
 static struct rbnode *
 rbsuccessor(tree, node)
     struct rbtree *tree;
     struct rbnode *node;
 {
     struct rbnode *succ;

     if ((succ = node->right) != rbnil(tree)) {
 	while (succ->left != rbnil(tree))
 	    succ = succ->left;
     } else {
 	/* No right child, move up until we find it or hit the root */
 	for (succ = node->parent; node == succ->right; succ = succ->parent)
 	    node = succ;
 	if (succ == rbroot(tree))
 	    succ = rbnil(tree);
     }
     return(succ);
 }

 /*
  * Recursive portion of rbdestroy().
  */
 static void
 _rbdestroy(tree, node, destroy)
     struct rbtree *tree;
     struct rbnode *node;
     void (*destroy)__P((void *));
 {
     if (node != rbnil(tree)) {
 	_rbdestroy(tree, node->left, destroy);
 	_rbdestroy(tree, node->right, destroy);
 	if (destroy != NULL)
 	    destroy(node->data);
 	efree(node);
     }
 }

 /*
  * Destroy the specified tree, calling the destructor destroy
  * for each node and then freeing the tree itself.
  */
 void
 rbdestroy(tree, destroy)
     struct rbtree *tree;
     void (*destroy)__P((void *));
 {
     _rbdestroy(tree, rbfirst(tree), destroy);
     efree(tree);
 }

 /*
  * Delete node 'z' from the tree and return its data pointer.
  */
 void *rbdelete(tree, z)
     struct rbtree *tree;
     struct rbnode *z;
 {
     struct rbnode *x, *y;
     void *data = z->data;

     if (z->left == rbnil(tree) || z->right == rbnil(tree))
 	y = z;
     else
 	y = rbsuccessor(tree, z);
     x = (y->left == rbnil(tree)) ? y->right : y->left;

     if ((x->parent = y->parent) == rbroot(tree)) {
 	rbfirst(tree) = x;
     } else {
 	if (y == y->parent->left)
 	    y->parent->left = x;
 	else
 	    y->parent->right = x;
     }
     if (y->color == black)
 	rbrepair(tree, x);
     if (y != z) {
 	y->left = z->left;
 	y->right = z->right;
 	y->parent = z->parent;
 	y->color = z->color;
 	z->left->parent = z->right->parent = y;
 	if (z == z->parent->left)
 	    z->parent->left = y;
 	else
 	    z->parent->right = y;
     }
     free(z);

     return (data);
 }

 /*
  * Repair the tree after a node has been deleted by rotating and repainting
  * colors to restore the 4 properties inherent in red-black trees.
  */
 static void
 rbrepair(tree, node)
     struct rbtree *tree;
     struct rbnode *node;
 {
     struct rbnode *sibling;

     while (node->color == black && node != rbroot(tree)) {
 	if (node == node->parent->left) {
 	    sibling = node->parent->right;
 	    if (sibling->color == red) {
 		sibling->color = black;
 		node->parent->color = red;
 		rotate_left(tree, node->parent);
 		sibling = node->parent->right;
 	    }
 	    if (sibling->right->color == black && sibling->left->color == black) {
 		sibling->color = red;
 		node = node->parent;
 	    } else {
 		if (sibling->right->color == black) {
 		      sibling->left->color = black;
 		      sibling->color = red;
 		      rotate_right(tree, sibling);
 		      sibling = node->parent->right;
 		}
 		sibling->color = node->parent->color;
 		node->parent->color = black;
 		sibling->right->color = black;
 		rotate_left(tree, node->parent);
 		node = rbroot(tree); /* exit loop */
 	    }
 	} else { /* if (node == node->parent->right) */
 	    sibling = node->parent->left;
 	    if (sibling->color == red) {
 		sibling->color = black;
 		node->parent->color = red;
 		rotate_right(tree, node->parent);
 		sibling = node->parent->left;
 	    }
 	    if (sibling->right->color == black && sibling->left->color == black) {
 		sibling->color = red;
 		node = node->parent;
 	    } else {
 		if (sibling->left->color == black) {
 		    sibling->right->color = black;
 		    sibling->color = red;
 		    rotate_left(tree, sibling);
 		    sibling = node->parent->left;
 		}
 		sibling->color = node->parent->color;
 		node->parent->color = black;
 		sibling->left->color = black;
 		rotate_right(tree, node->parent);
 		node = rbroot(tree); /* exit loop */
 	    }
 	}
     }
     node->color = black;
 }
	/*
	* Copyright (c) 2004-2005, 2007,2009 Todd C. Miller <Todd.Miller@courtesan.com>
	*
	* Permission to use, copy, modify, and distribute this software for any
	* purpose with or without fee is hereby granted, provided that the above
	* copyright notice and this permission notice appear in all copies.
	*
	* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
	* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
	* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
	* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
	* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
	* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
	*/

	/*
	* Adapted from the following code written by Emin Martinian:
	* http://web.mit.edu/~emin/www/source_code/red_black_tree/index.html
	*
	* Copyright (c) 2001 Emin Martinian
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that neither the name of Emin
	* Martinian nor the names of any contributors are be used to endorse or
	* promote products derived from this software without specific prior
	* written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <config.h>

	#include <sys/types.h>
	#include <sys/param.h>

	#include <stdio.h>
	#ifdef STDC_HEADERS
	# include <stdlib.h>
	# include <stddef.h>
	#else
	# ifdef HAVE_STDLIB_H
	# include <stdlib.h>
	# endif
	#endif /* STDC_HEADERS */

	#include "sudo.h"
	#include "redblack.h"

	static void rbrepair __P((struct rbtree , struct rbnode ));
	static void rotate_left __P((struct rbtree , struct rbnode ));
	static void rotate_right __P((struct rbtree , struct rbnode ));
	static void _rbdestroy __P((struct rbtree , struct rbnode ,
	void ()(void )));

	/*
	* Red-Black tree, see http://en.wikipedia.org/wiki/Red-black_tree
	*
	* A red-black tree is a binary search tree where each node has a color
	* attribute, the value of which is either red or black. Essentially, it
	* is just a convenient way to express a 2-3-4 binary search tree where
	* the color indicates whether the node is part of a 3-node or a 4-node.
	* In addition to the ordinary requirements imposed on binary search
	* trees, we make the following additional requirements of any valid
	* red-black tree:
	* 1) Every node is either red or black.
	* 2) The root is black.
	* 3) All leaves are black.
	* 4) Both children of each red node are black.
	* 5) The paths from each leaf up to the root each contain the same
	* number of black nodes.
	*/

	/*
	* Create a red black tree struct using the specified compare routine.
	* Allocates and returns the initialized (empty) tree.
	*/
	struct rbtree *
	rbcreate(compar)
	int (compar)__P((const void , const void*));
	{
	struct rbtree *tree;

	tree = (struct rbtree ) emalloc(sizeof(tree));
	tree->compar = compar;

	/*
	* We use a self-referencing sentinel node called nil to simplify the
	* code by avoiding the need to check for NULL pointers.
	*/
	tree->nil.left = tree->nil.right = tree->nil.parent = &tree->nil;
	tree->nil.color = black;
	tree->nil.data = NULL;

	/*
	* Similarly, the fake root node keeps us from having to worry
	* about splitting the root.
	*/
	tree->root.left = tree->root.right = tree->root.parent = &tree->nil;
	tree->root.color = black;
	tree->root.data = NULL;

	return(tree);
	}

	/*
	* Perform a left rotation starting at node.
	*/
	static void
	rotate_left(tree, node)
	struct rbtree *tree;
	struct rbnode *node;
	{
	struct rbnode *child;

	child = node->right;
	node->right = child->left;

	if (child->left != rbnil(tree))
	child->left->parent = node;
	child->parent = node->parent;

	if (node == node->parent->left)
	node->parent->left = child;
	else
	node->parent->right = child;
	child->left = node;
	node->parent = child;
	}

	/*
	* Perform a right rotation starting at node.
	*/
	static void
	rotate_right(tree, node)
	struct rbtree *tree;
	struct rbnode *node;
	{
	struct rbnode *child;

	child = node->left;
	node->left = child->right;

	if (child->right != rbnil(tree))
	child->right->parent = node;
	child->parent = node->parent;

	if (node == node->parent->left)
	node->parent->left = child;
	else
	node->parent->right = child;
	child->right = node;
	node->parent = child;
	}

	/*
	* Insert data pointer into a redblack tree.
	* Returns a NULL pointer on success. If a node matching "data"
	* already exists, a pointer to the existant node is returned.
	*/
	struct rbnode *
	rbinsert(tree, data)
	struct rbtree *tree;
	void *data;
	{
	struct rbnode *node = rbfirst(tree);
	struct rbnode *parent = rbroot(tree);
	int res;

	/* Find correct insertion point. */
	while (node != rbnil(tree)) {
	parent = node;
	if ((res = tree->compar(data, node->data)) == 0)
	return(node);
	node = res < 0 ? node->left : node->right;
	}

	node = (struct rbnode ) emalloc(sizeof(node));
	node->data = data;
	node->left = node->right = rbnil(tree);
	node->parent = parent;
	if (parent == rbroot(tree) \|\| tree->compar(data, parent->data) < 0)
	parent->left = node;
	else
	parent->right = node;
	node->color = red;

	/*
	* If the parent node is black we are all set, if it is red we have
	* the following possible cases to deal with. We iterate through
	* the rest of the tree to make sure none of the required properties
	* is violated.
	*
	* 1) The uncle is red. We repaint both the parent and uncle black
	* and repaint the grandparent node red.
	*
	* 2) The uncle is black and the new node is the right child of its
	* parent, and the parent in turn is the left child of its parent.
	* We do a left rotation to switch the roles of the parent and
	* child, relying on further iterations to fixup the old parent.
	*
	* 3) The uncle is black and the new node is the left child of its
	* parent, and the parent in turn is the left child of its parent.
	* We switch the colors of the parent and grandparent and perform
	* a right rotation around the grandparent. This makes the former
	* parent the parent of the new node and the former grandparent.
	*
	* Note that because we use a sentinel for the root node we never
	* need to worry about replacing the root.
	*/
	while (node->parent->color == red) {
	struct rbnode *uncle;
	if (node->parent == node->parent->parent->left) {
	uncle = node->parent->parent->right;
	if (uncle->color == red) {
	node->parent->color = black;
	uncle->color = black;
	node->parent->parent->color = red;
	node = node->parent->parent;
	} else /* if (uncle->color == black) */ {
	if (node == node->parent->right) {
	node = node->parent;
	rotate_left(tree, node);
	}
	node->parent->color = black;
	node->parent->parent->color = red;
	rotate_right(tree, node->parent->parent);
	}
	} else { /* if (node->parent == node->parent->parent->right) */
	uncle = node->parent->parent->left;
	if (uncle->color == red) {
	node->parent->color = black;
	uncle->color = black;
	node->parent->parent->color = red;
	node = node->parent->parent;
	} else /* if (uncle->color == black) */ {
	if (node == node->parent->left) {
	node = node->parent;
	rotate_right(tree, node);
	}
	node->parent->color = black;
	node->parent->parent->color = red;
	rotate_left(tree, node->parent->parent);
	}
	}
	}
	rbfirst(tree)->color = black; /* first node is always black */
	return(NULL);
	}

	/*
	* Look for a node matching key in tree.
	* Returns a pointer to the node if found, else NULL.
	*/
	struct rbnode *
	rbfind(tree, key)
	struct rbtree *tree;
	void *key;
	{
	struct rbnode *node = rbfirst(tree);
	int res;

	while (node != rbnil(tree)) {
	if ((res = tree->compar(key, node->data)) == 0)
	return(node);
	node = res < 0 ? node->left : node->right;
	}
	return(NULL);
	}

	/*
	* Call func() for each node, passing it the node data and a cookie;
	* If func() returns non-zero for a node, the traversal stops and the
	* error value is returned. Returns 0 on successful traversal.
	*/
	int
	rbapply_node(tree, node, func, cookie, order)
	struct rbtree *tree;
	struct rbnode *node;
	int (func)__P((void , void *));
	void *cookie;
	enum rbtraversal order;
	{
	int error;

	if (node != rbnil(tree)) {
	if (order == preorder)
	if ((error = func(node->data, cookie)) != 0)
	return(error);
	if ((error = rbapply_node(tree, node->left, func, cookie, order)) != 0)
	return(error);
	if (order == inorder)
	if ((error = func(node->data, cookie)) != 0)
	return(error);
	if ((error = rbapply_node(tree, node->right, func, cookie, order)) != 0)
	return(error);
	if (order == postorder)
	if ((error = func(node->data, cookie)) != 0)
	return(error);
	}
	return (0);
	}

	/*
	* Returns the successor of node, or nil if there is none.
	*/
	static struct rbnode *
	rbsuccessor(tree, node)
	struct rbtree *tree;
	struct rbnode *node;
	{
	struct rbnode *succ;

	if ((succ = node->right) != rbnil(tree)) {
	while (succ->left != rbnil(tree))
	succ = succ->left;
	} else {
	/* No right child, move up until we find it or hit the root */
	for (succ = node->parent; node == succ->right; succ = succ->parent)
	node = succ;
	if (succ == rbroot(tree))
	succ = rbnil(tree);
	}
	return(succ);
	}

	/*
	* Recursive portion of rbdestroy().
	*/
	static void
	_rbdestroy(tree, node, destroy)
	struct rbtree *tree;
	struct rbnode *node;
	void (destroy)__P((void ));
	{
	if (node != rbnil(tree)) {
	_rbdestroy(tree, node->left, destroy);
	_rbdestroy(tree, node->right, destroy);
	if (destroy != NULL)
	destroy(node->data);
	efree(node);
	}
	}

	/*
	* Destroy the specified tree, calling the destructor destroy
	* for each node and then freeing the tree itself.
	*/
	void
	rbdestroy(tree, destroy)
	struct rbtree *tree;
	void (destroy)__P((void ));
	{
	_rbdestroy(tree, rbfirst(tree), destroy);
	efree(tree);
	}

	/*
	* Delete node 'z' from the tree and return its data pointer.
	*/
	void *rbdelete(tree, z)
	struct rbtree *tree;
	struct rbnode *z;
	{
	struct rbnode x, y;
	void *data = z->data;

	if (z->left == rbnil(tree) \|\| z->right == rbnil(tree))
	y = z;
	else
	y = rbsuccessor(tree, z);
	x = (y->left == rbnil(tree)) ? y->right : y->left;

	if ((x->parent = y->parent) == rbroot(tree)) {
	rbfirst(tree) = x;
	} else {
	if (y == y->parent->left)
	y->parent->left = x;
	else
	y->parent->right = x;
	}
	if (y->color == black)
	rbrepair(tree, x);
	if (y != z) {
	y->left = z->left;
	y->right = z->right;
	y->parent = z->parent;
	y->color = z->color;
	z->left->parent = z->right->parent = y;
	if (z == z->parent->left)
	z->parent->left = y;
	else
	z->parent->right = y;
	}
	free(z);

	return (data);
	}

	/*
	* Repair the tree after a node has been deleted by rotating and repainting
	* colors to restore the 4 properties inherent in red-black trees.
	*/
	static void
	rbrepair(tree, node)
	struct rbtree *tree;
	struct rbnode *node;
	{
	struct rbnode *sibling;

	while (node->color == black && node != rbroot(tree)) {
	if (node == node->parent->left) {
	sibling = node->parent->right;
	if (sibling->color == red) {
	sibling->color = black;
	node->parent->color = red;
	rotate_left(tree, node->parent);
	sibling = node->parent->right;
	}
	if (sibling->right->color == black && sibling->left->color == black) {
	sibling->color = red;
	node = node->parent;
	} else {
	if (sibling->right->color == black) {
	sibling->left->color = black;
	sibling->color = red;
	rotate_right(tree, sibling);
	sibling = node->parent->right;
	}
	sibling->color = node->parent->color;
	node->parent->color = black;
	sibling->right->color = black;
	rotate_left(tree, node->parent);
	node = rbroot(tree); /* exit loop */
	}
	} else { /* if (node == node->parent->right) */
	sibling = node->parent->left;
	if (sibling->color == red) {
	sibling->color = black;
	node->parent->color = red;
	rotate_right(tree, node->parent);
	sibling = node->parent->left;
	}
	if (sibling->right->color == black && sibling->left->color == black) {
	sibling->color = red;
	node = node->parent;
	} else {
	if (sibling->left->color == black) {
	sibling->right->color = black;
	sibling->color = red;
	rotate_left(tree, sibling);
	sibling = node->parent->left;
	}
	sibling->color = node->parent->color;
	node->parent->color = black;
	sibling->left->color = black;
	rotate_right(tree, node->parent);
	node = rbroot(tree); /* exit loop */
	}
	}
	}
	node->color = black;
	}