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/*
 * Dictionary Abstract Data Type
 * Copyright (C) 1997 Kaz Kylheku <kaz@ashi.footprints.net>
 *
 * Free Software License:
 *
 * All rights are reserved by the author, with the following exceptions:
 * Permission is granted to freely reproduce and distribute this software,
 * possibly in exchange for a fee, provided that this copyright notice appears
 * intact. Permission is also granted to adapt this software to produce
 * derivative works, as long as the modified versions carry this copyright
 * notice and additional notices stating that the work has been modified.
 * This source code may be translated into executable form and incorporated
 * into proprietary software; there is no requirement for such software to
 * contain a copyright notice related to this source.
 *
 * $Id: dict.c,v 1.40.2.7 2000/11/13 01:36:44 kaz Exp $
 * $Name: kazlib_1_20 $
 */

#define DICT_NODEBUG

#include "config.h"
#include <stdlib.h>
#include <stddef.h>
#ifdef DICT_NODEBUG
#define dict_assert(x)
#else
#include <assert.h>
#define dict_assert(x) assert(x)
#endif
#define DICT_IMPLEMENTATION
#include "dict.h"
#include <f2fs_fs.h>

#ifdef KAZLIB_RCSID
static const char rcsid[] = "$Id: dict.c,v 1.40.2.7 2000/11/13 01:36:44 kaz Exp $";
#endif

/*
 * These macros provide short convenient names for structure members,
 * which are embellished with dict_ prefixes so that they are
 * properly confined to the documented namespace. It's legal for a
 * program which uses dict to define, for instance, a macro called ``parent''.
 * Such a macro would interfere with the dnode_t struct definition.
 * In general, highly portable and reusable C modules which expose their
 * structures need to confine structure member names to well-defined spaces.
 * The resulting identifiers aren't necessarily convenient to use, nor
 * readable, in the implementation, however!
 */

#define left dict_left
#define right dict_right
#define parent dict_parent
#define color dict_color
#define key dict_key
#define data dict_data

#define nilnode dict_nilnode
#define nodecount dict_nodecount
#define maxcount dict_maxcount
#define compare dict_compare
#define allocnode dict_allocnode
#define freenode dict_freenode
#define context dict_context
#define dupes dict_dupes

#define dictptr dict_dictptr

#define dict_root(D) ((D)->nilnode.left)
#define dict_nil(D) (&(D)->nilnode)
#define DICT_DEPTH_MAX 64

static dnode_t *dnode_alloc(void *context);
static void dnode_free(dnode_t *node, void *context);

/*
 * Perform a ``left rotation'' adjustment on the tree.  The given node P and
 * its right child C are rearranged so that the P instead becomes the left
 * child of C.   The left subtree of C is inherited as the new right subtree
 * for P.  The ordering of the keys within the tree is thus preserved.
 */
static void rotate_left(dnode_t *upper)
{
	dnode_t *lower, *lowleft, *upparent;

	lower = upper->right;
	upper->right = lowleft = lower->left;
	lowleft->parent = upper;

	lower->parent = upparent = upper->parent;

	/* don't need to check for root node here because root->parent is
	   the sentinel nil node, and root->parent->left points back to root */

	if (upper == upparent->left) {
		upparent->left = lower;
	} else {
		dict_assert(upper == upparent->right);
		upparent->right = lower;
	}

	lower->left = upper;
	upper->parent = lower;
}

/*
 * This operation is the ``mirror'' image of rotate_left. It is
 * the same procedure, but with left and right interchanged.
 */
static void rotate_right(dnode_t *upper)
{
	dnode_t *lower, *lowright, *upparent;

	lower = upper->left;
	upper->left = lowright = lower->right;
	lowright->parent = upper;

	lower->parent = upparent = upper->parent;

	if (upper == upparent->right) {
		upparent->right = lower;
	} else {
		dict_assert(upper == upparent->left);
		upparent->left = lower;
	}

	lower->right = upper;
	upper->parent = lower;
}

/*
 * Do a postorder traversal of the tree rooted at the specified
 * node and free everything under it.  Used by dict_free().
 */
static void free_nodes(dict_t *dict, dnode_t *node, dnode_t *nil)
{
	if (node == nil)
		return;
	free_nodes(dict, node->left, nil);
	free_nodes(dict, node->right, nil);
	dict->freenode(node, dict->context);
}

/*
 * This procedure performs a verification that the given subtree is a binary
 * search tree. It performs an inorder traversal of the tree using the
 * dict_next() successor function, verifying that the key of each node is
 * strictly lower than that of its successor, if duplicates are not allowed,
 * or lower or equal if duplicates are allowed.  This function is used for
 * debugging purposes.
 */
#ifndef DICT_NODEBUG
static int verify_bintree(dict_t *dict)
{
	dnode_t *first, *next;

	first = dict_first(dict);

	if (dict->dupes) {
		while (first && (next = dict_next(dict, first))) {
			if (dict->compare(first->key, next->key) > 0)
				return 0;
			first = next;
		}
	} else {
		while (first && (next = dict_next(dict, first))) {
			if (dict->compare(first->key, next->key) >= 0)
				return 0;
			first = next;
		}
	}
	return 1;
}

/*
 * This function recursively verifies that the given binary subtree satisfies
 * three of the red black properties. It checks that every red node has only
 * black children. It makes sure that each node is either red or black. And it
 * checks that every path has the same count of black nodes from root to leaf.
 * It returns the blackheight of the given subtree; this allows blackheights to
 * be computed recursively and compared for left and right siblings for
 * mismatches. It does not check for every nil node being black, because there
 * is only one sentinel nil node. The return value of this function is the
 * black height of the subtree rooted at the node ``root'', or zero if the
 * subtree is not red-black.
 */
static unsigned int verify_redblack(dnode_t *nil, dnode_t *root)
{
	unsigned height_left, height_right;

	if (root != nil) {
		height_left = verify_redblack(nil, root->left);
		height_right = verify_redblack(nil, root->right);
		if (height_left == 0 || height_right == 0)
			return 0;
		if (height_left != height_right)
			return 0;
		if (root->color == dnode_red) {
			if (root->left->color != dnode_black)
				return 0;
			if (root->right->color != dnode_black)
				return 0;
			return height_left;
		}
		if (root->color != dnode_black)
			return 0;
		return height_left + 1;
	}
	return 1;
}

/*
 * Compute the actual count of nodes by traversing the tree and
 * return it. This could be compared against the stored count to
 * detect a mismatch.
 */
static dictcount_t verify_node_count(dnode_t *nil, dnode_t *root)
{
	if (root == nil)
		return 0;
	else
		return 1 + verify_node_count(nil, root->left)
			+ verify_node_count(nil, root->right);
}
#endif

/*
 * Verify that the tree contains the given node. This is done by
 * traversing all of the nodes and comparing their pointers to the
 * given pointer. Returns 1 if the node is found, otherwise
 * returns zero. It is intended for debugging purposes.
 */
static int verify_dict_has_node(dnode_t *nil, dnode_t *root, dnode_t *node)
{
	if (root != nil) {
		return root == node
			|| verify_dict_has_node(nil, root->left, node)
			|| verify_dict_has_node(nil, root->right, node);
	}
	return 0;
}

#ifdef FSCK_NOTUSED
/*
 * Dynamically allocate and initialize a dictionary object.
 */
dict_t *dict_create(dictcount_t maxcount, dict_comp_t comp)
{
	dict_t *new = malloc(sizeof *new);

	if (new) {
		new->compare = comp;
		new->allocnode = dnode_alloc;
		new->freenode = dnode_free;
		new->context = NULL;
		new->nodecount = 0;
		new->maxcount = maxcount;
		new->nilnode.left = &new->nilnode;
		new->nilnode.right = &new->nilnode;
		new->nilnode.parent = &new->nilnode;
		new->nilnode.color = dnode_black;
		new->dupes = 0;
	}
	return new;
}
#endif /* FSCK_NOTUSED */

/*
 * Select a different set of node allocator routines.
 */
void dict_set_allocator(dict_t *dict, dnode_alloc_t al,
		dnode_free_t fr, void *context)
{
	dict_assert(dict_count(dict) == 0);
	dict_assert((al == NULL && fr == NULL) || (al != NULL && fr != NULL));

	dict->allocnode = al ? al : dnode_alloc;
	dict->freenode = fr ? fr : dnode_free;
	dict->context = context;
}

#ifdef FSCK_NOTUSED
/*
 * Free a dynamically allocated dictionary object. Removing the nodes
 * from the tree before deleting it is required.
 */
void dict_destroy(dict_t *dict)
{
	dict_assert(dict_isempty(dict));
	free(dict);
}
#endif

/*
 * Free all the nodes in the dictionary by using the dictionary's
 * installed free routine. The dictionary is emptied.
 */
void dict_free_nodes(dict_t *dict)
{
	dnode_t *nil = dict_nil(dict), *root = dict_root(dict);
	free_nodes(dict, root, nil);
	dict->nodecount = 0;
	dict->nilnode.left = &dict->nilnode;
	dict->nilnode.right = &dict->nilnode;
}

#ifdef FSCK_NOTUSED
/*
 * Obsolescent function, equivalent to dict_free_nodes
 */
void dict_free(dict_t *dict)
{
#ifdef KAZLIB_OBSOLESCENT_DEBUG
	dict_assert("call to obsolescent function dict_free()" && 0);
#endif
	dict_free_nodes(dict);
}
#endif

/*
 * Initialize a user-supplied dictionary object.
 */
dict_t *dict_init(dict_t *dict, dictcount_t maxcount, dict_comp_t comp)
{
	dict->compare = comp;
	dict->allocnode = dnode_alloc;
	dict->freenode = dnode_free;
	dict->context = NULL;
	dict->nodecount = 0;
	dict->maxcount = maxcount;
	dict->nilnode.left = &dict->nilnode;
	dict->nilnode.right = &dict->nilnode;
	dict->nilnode.parent = &dict->nilnode;
	dict->nilnode.color = dnode_black;
	dict->dupes = 0;
	return dict;
}

#ifdef FSCK_NOTUSED
/*
 * Initialize a dictionary in the likeness of another dictionary
 */
void dict_init_like(dict_t *dict, const dict_t *template)
{
	dict->compare = template->compare;
	dict->allocnode = template->allocnode;
	dict->freenode = template->freenode;
	dict->context = template->context;
	dict->nodecount = 0;
	dict->maxcount = template->maxcount;
	dict->nilnode.left = &dict->nilnode;
	dict->nilnode.right = &dict->nilnode;
	dict->nilnode.parent = &dict->nilnode;
	dict->nilnode.color = dnode_black;
	dict->dupes = template->dupes;

	dict_assert(dict_similar(dict, template));
}

/*
 * Remove all nodes from the dictionary (without freeing them in any way).
 */
static void dict_clear(dict_t *dict)
{
	dict->nodecount = 0;
	dict->nilnode.left = &dict->nilnode;
	dict->nilnode.right = &dict->nilnode;
	dict->nilnode.parent = &dict->nilnode;
	dict_assert(dict->nilnode.color == dnode_black);
}
#endif /* FSCK_NOTUSED */

/*
 * Verify the integrity of the dictionary structure.  This is provided for
 * debugging purposes, and should be placed in assert statements.   Just because
 * this function succeeds doesn't mean that the tree is not corrupt. Certain
 * corruptions in the tree may simply cause undefined behavior.
 */
#ifndef DICT_NODEBUG
int dict_verify(dict_t *dict)
{
	dnode_t *nil = dict_nil(dict), *root = dict_root(dict);

	/* check that the sentinel node and root node are black */
	if (root->color != dnode_black)
		return 0;
	if (nil->color != dnode_black)
		return 0;
	if (nil->right != nil)
		return 0;
	/* nil->left is the root node; check that its parent pointer is nil */
	if (nil->left->parent != nil)
		return 0;
	/* perform a weak test that the tree is a binary search tree */
	if (!verify_bintree(dict))
		return 0;
	/* verify that the tree is a red-black tree */
	if (!verify_redblack(nil, root))
		return 0;
	if (verify_node_count(nil, root) != dict_count(dict))
		return 0;
	return 1;
}
#endif /* DICT_NODEBUG */

#ifdef FSCK_NOTUSED
/*
 * Determine whether two dictionaries are similar: have the same comparison and
 * allocator functions, and same status as to whether duplicates are allowed.
 */
int dict_similar(const dict_t *left, const dict_t *right)
{
	if (left->compare != right->compare)
		return 0;

	if (left->allocnode != right->allocnode)
		return 0;

	if (left->freenode != right->freenode)
		return 0;

	if (left->context != right->context)
		return 0;

	if (left->dupes != right->dupes)
		return 0;

	return 1;
}
#endif /* FSCK_NOTUSED */

/*
 * Locate a node in the dictionary having the given key.
 * If the node is not found, a null a pointer is returned (rather than
 * a pointer that dictionary's nil sentinel node), otherwise a pointer to the
 * located node is returned.
 */
dnode_t *dict_lookup(dict_t *dict, const void *key)
{
	dnode_t *root = dict_root(dict);
	dnode_t *nil = dict_nil(dict);
	dnode_t *saved;
	int result;

	/* simple binary search adapted for trees that contain duplicate keys */

	while (root != nil) {
		result = dict->compare(key, root->key);
		if (result < 0)
			root = root->left;
		else if (result > 0)
			root = root->right;
		else {
			if (!dict->dupes) {	/* no duplicates, return match		*/
				return root;
			} else {		/* could be dupes, find leftmost one	*/
				do {
					saved = root;
					root = root->left;
					while (root != nil && dict->compare(key, root->key))
						root = root->right;
				} while (root != nil);
				return saved;
			}
		}
	}

	return NULL;
}

#ifdef FSCK_NOTUSED
/*
 * Look for the node corresponding to the lowest key that is equal to or
 * greater than the given key.  If there is no such node, return null.
 */
dnode_t *dict_lower_bound(dict_t *dict, const void *key)
{
	dnode_t *root = dict_root(dict);
	dnode_t *nil = dict_nil(dict);
	dnode_t *tentative = 0;

	while (root != nil) {
		int result = dict->compare(key, root->key);

		if (result > 0) {
			root = root->right;
		} else if (result < 0) {
			tentative = root;
			root = root->left;
		} else {
			if (!dict->dupes) {
				return root;
			} else {
				tentative = root;
				root = root->left;
			}
		}
	}

	return tentative;
}

/*
 * Look for the node corresponding to the greatest key that is equal to or
 * lower than the given key.  If there is no such node, return null.
 */
dnode_t *dict_upper_bound(dict_t *dict, const void *key)
{
	dnode_t *root = dict_root(dict);
	dnode_t *nil = dict_nil(dict);
	dnode_t *tentative = 0;

	while (root != nil) {
		int result = dict->compare(key, root->key);

		if (result < 0) {
			root = root->left;
		} else if (result > 0) {
			tentative = root;
			root = root->right;
		} else {
			if (!dict->dupes) {
				return root;
			} else {
				tentative = root;
				root = root->right;
			}
		}
	}

	return tentative;
}
#endif

/*
 * Insert a node into the dictionary. The node should have been
 * initialized with a data field. All other fields are ignored.
 * The behavior is undefined if the user attempts to insert into
 * a dictionary that is already full (for which the dict_isfull()
 * function returns true).
 */
void dict_insert(dict_t *dict, dnode_t *node, const void *key)
{
	dnode_t *where = dict_root(dict), *nil = dict_nil(dict);
	dnode_t *parent = nil, *uncle, *grandpa;
	int result = -1;

	node->key = key;

	dict_assert(!dict_isfull(dict));
	dict_assert(!dict_contains(dict, node));
	dict_assert(!dnode_is_in_a_dict(node));

	/* basic binary tree insert */

	while (where != nil) {
		parent = where;
		result = dict->compare(key, where->key);
		/* trap attempts at duplicate key insertion unless it's explicitly allowed */
		dict_assert(dict->dupes || result != 0);
		if (result < 0)
			where = where->left;
		else
			where = where->right;
	}

	dict_assert(where == nil);

	if (result < 0)
		parent->left = node;
	else
		parent->right = node;

	node->parent = parent;
	node->left = nil;
	node->right = nil;

	dict->nodecount++;

	/* red black adjustments */

	node->color = dnode_red;

	while (parent->color == dnode_red) {
		grandpa = parent->parent;
		if (parent == grandpa->left) {
			uncle = grandpa->right;
			if (uncle->color == dnode_red) {	/* red parent, red uncle */
				parent->color = dnode_black;
				uncle->color = dnode_black;
				grandpa->color = dnode_red;
				node = grandpa;
				parent = grandpa->parent;
			} else {				/* red parent, black uncle */
				if (node == parent->right) {
					rotate_left(parent);
					parent = node;
					dict_assert(grandpa == parent->parent);
					/* rotation between parent and child preserves grandpa */
				}
				parent->color = dnode_black;
				grandpa->color = dnode_red;
				rotate_right(grandpa);
				break;
			}
		} else { 	/* symmetric cases: parent == parent->parent->right */
			uncle = grandpa->left;
			if (uncle->color == dnode_red) {
				parent->color = dnode_black;
				uncle->color = dnode_black;
				grandpa->color = dnode_red;
				node = grandpa;
				parent = grandpa->parent;
			} else {
				if (node == parent->left) {
					rotate_right(parent);
					parent = node;
					dict_assert(grandpa == parent->parent);
				}
				parent->color = dnode_black;
				grandpa->color = dnode_red;
				rotate_left(grandpa);
				break;
			}
		}
	}

	dict_root(dict)->color = dnode_black;

	dict_assert(dict_verify(dict));
}

#ifdef FSCK_NOTUSED
/*
 * Delete the given node from the dictionary. If the given node does not belong
 * to the given dictionary, undefined behavior results.  A pointer to the
 * deleted node is returned.
 */
dnode_t *dict_delete(dict_t *dict, dnode_t *delete)
{
	dnode_t *nil = dict_nil(dict), *child, *delparent = delete->parent;

	/* basic deletion */

	dict_assert(!dict_isempty(dict));
	dict_assert(dict_contains(dict, delete));

	/*
	 * If the node being deleted has two children, then we replace it with its
	 * successor (i.e. the leftmost node in the right subtree.) By doing this,
	 * we avoid the traditional algorithm under which the successor's key and
	 * value *only* move to the deleted node and the successor is spliced out
	 * from the tree. We cannot use this approach because the user may hold
	 * pointers to the successor, or nodes may be inextricably tied to some
	 * other structures by way of embedding, etc. So we must splice out the
	 * node we are given, not some other node, and must not move contents from
	 * one node to another behind the user's back.
	 */

	if (delete->left != nil && delete->right != nil) {
		dnode_t *next = dict_next(dict, delete);
		dnode_t *nextparent = next->parent;
		dnode_color_t nextcolor = next->color;

		dict_assert(next != nil);
		dict_assert(next->parent != nil);
		dict_assert(next->left == nil);

		/*
		 * First, splice out the successor from the tree completely, by
		 * moving up its right child into its place.
		 */

		child = next->right;
		child->parent = nextparent;

		if (nextparent->left == next) {
			nextparent->left = child;
		} else {
			dict_assert(nextparent->right == next);
			nextparent->right = child;
		}

		/*
		 * Now that the successor has been extricated from the tree, install it
		 * in place of the node that we want deleted.
		 */

		next->parent = delparent;
		next->left = delete->left;
		next->right = delete->right;
		next->left->parent = next;
		next->right->parent = next;
		next->color = delete->color;
		delete->color = nextcolor;

		if (delparent->left == delete) {
			delparent->left = next;
		} else {
			dict_assert(delparent->right == delete);
			delparent->right = next;
		}

	} else {
		dict_assert(delete != nil);
		dict_assert(delete->left == nil || delete->right == nil);

		child = (delete->left != nil) ? delete->left : delete->right;

		child->parent = delparent = delete->parent;

		if (delete == delparent->left) {
			delparent->left = child;
		} else {
			dict_assert(delete == delparent->right);
			delparent->right = child;
		}
	}

	delete->parent = NULL;
	delete->right = NULL;
	delete->left = NULL;

	dict->nodecount--;

	dict_assert(verify_bintree(dict));

	/* red-black adjustments */

	if (delete->color == dnode_black) {
		dnode_t *parent, *sister;

		dict_root(dict)->color = dnode_red;

		while (child->color == dnode_black) {
			parent = child->parent;
			if (child == parent->left) {
				sister = parent->right;
				dict_assert(sister != nil);
				if (sister->color == dnode_red) {
					sister->color = dnode_black;
					parent->color = dnode_red;
					rotate_left(parent);
					sister = parent->right;
					dict_assert(sister != nil);
				}
				if (sister->left->color == dnode_black
						&& sister->right->color == dnode_black) {
					sister->color = dnode_red;
					child = parent;
				} else {
					if (sister->right->color == dnode_black) {
						dict_assert(sister->left->color == dnode_red);
						sister->left->color = dnode_black;
						sister->color = dnode_red;
						rotate_right(sister);
						sister = parent->right;
						dict_assert(sister != nil);
					}
					sister->color = parent->color;
					sister->right->color = dnode_black;
					parent->color = dnode_black;
					rotate_left(parent);
					break;
				}
			} else {	/* symmetric case: child == child->parent->right */
				dict_assert(child == parent->right);
				sister = parent->left;
				dict_assert(sister != nil);
				if (sister->color == dnode_red) {
					sister->color = dnode_black;
					parent->color = dnode_red;
					rotate_right(parent);
					sister = parent->left;
					dict_assert(sister != nil);
				}
				if (sister->right->color == dnode_black
						&& sister->left->color == dnode_black) {
					sister->color = dnode_red;
					child = parent;
				} else {
					if (sister->left->color == dnode_black) {
						dict_assert(sister->right->color == dnode_red);
						sister->right->color = dnode_black;
						sister->color = dnode_red;
						rotate_left(sister);
						sister = parent->left;
						dict_assert(sister != nil);
					}
					sister->color = parent->color;
					sister->left->color = dnode_black;
					parent->color = dnode_black;
					rotate_right(parent);
					break;
				}
			}
		}

		child->color = dnode_black;
		dict_root(dict)->color = dnode_black;
	}

	dict_assert(dict_verify(dict));

	return delete;
}
#endif /* FSCK_NOTUSED */

/*
 * Allocate a node using the dictionary's allocator routine, give it
 * the data item.
 */
int dict_alloc_insert(dict_t *dict, const void *key, void *data)
{
	dnode_t *node = dict->allocnode(dict->context);

	if (node) {
		dnode_init(node, data);
		dict_insert(dict, node, key);
		return 1;
	}
	return 0;
}

#ifdef FSCK_NOTUSED
void dict_delete_free(dict_t *dict, dnode_t *node)
{
	dict_delete(dict, node);
	dict->freenode(node, dict->context);
}
#endif

/*
 * Return the node with the lowest (leftmost) key. If the dictionary is empty
 * (that is, dict_isempty(dict) returns 1) a null pointer is returned.
 */
dnode_t *dict_first(dict_t *dict)
{
	dnode_t *nil = dict_nil(dict), *root = dict_root(dict), *left;

	if (root != nil)
		while ((left = root->left) != nil)
			root = left;

	return (root == nil) ? NULL : root;
}

/*
 * Return the node with the highest (rightmost) key. If the dictionary is empty
 * (that is, dict_isempty(dict) returns 1) a null pointer is returned.
 */
dnode_t *dict_last(dict_t *dict)
{
	dnode_t *nil = dict_nil(dict), *root = dict_root(dict), *right;

	if (root != nil)
		while ((right = root->right) != nil)
			root = right;

	return (root == nil) ? NULL : root;
}

/*
 * Return the given node's successor node---the node which has the
 * next key in the the left to right ordering. If the node has
 * no successor, a null pointer is returned rather than a pointer to
 * the nil node.
 */
dnode_t *dict_next(dict_t *dict, dnode_t *curr)
{
	dnode_t *nil = dict_nil(dict), *parent, *left;

	if (curr->right != nil) {
		curr = curr->right;
		while ((left = curr->left) != nil)
			curr = left;
		return curr;
	}

	parent = curr->parent;

	while (parent != nil && curr == parent->right) {
		curr = parent;
		parent = curr->parent;
	}

	return (parent == nil) ? NULL : parent;
}

/*
 * Return the given node's predecessor, in the key order.
 * The nil sentinel node is returned if there is no predecessor.
 */
dnode_t *dict_prev(dict_t *dict, dnode_t *curr)
{
	dnode_t *nil = dict_nil(dict), *parent, *right;

	if (curr->left != nil) {
		curr = curr->left;
		while ((right = curr->right) != nil)
			curr = right;
		return curr;
	}

	parent = curr->parent;

	while (parent != nil && curr == parent->left) {
		curr = parent;
		parent = curr->parent;
	}

	return (parent == nil) ? NULL : parent;
}

void dict_allow_dupes(dict_t *dict)
{
	dict->dupes = 1;
}

#undef dict_count
#undef dict_isempty
#undef dict_isfull
#undef dnode_get
#undef dnode_put
#undef dnode_getkey

dictcount_t dict_count(dict_t *dict)
{
	return dict->nodecount;
}

int dict_isempty(dict_t *dict)
{
	return dict->nodecount == 0;
}

int dict_isfull(dict_t *dict)
{
	return dict->nodecount == dict->maxcount;
}

int dict_contains(dict_t *dict, dnode_t *node)
{
	return verify_dict_has_node(dict_nil(dict), dict_root(dict), node);
}

static dnode_t *dnode_alloc(void *UNUSED(context))
{
	return malloc(sizeof *dnode_alloc(NULL));
}

static void dnode_free(dnode_t *node, void *UNUSED(context))
{
	free(node);
}

dnode_t *dnode_create(void *data)
{
	dnode_t *new = malloc(sizeof *new);
	if (new) {
		new->data = data;
		new->parent = NULL;
		new->left = NULL;
		new->right = NULL;
	}
	return new;
}

dnode_t *dnode_init(dnode_t *dnode, void *data)
{
	dnode->data = data;
	dnode->parent = NULL;
	dnode->left = NULL;
	dnode->right = NULL;
	return dnode;
}

void dnode_destroy(dnode_t *dnode)
{
	dict_assert(!dnode_is_in_a_dict(dnode));
	free(dnode);
}

void *dnode_get(dnode_t *dnode)
{
	return dnode->data;
}

const void *dnode_getkey(dnode_t *dnode)
{
	return dnode->key;
}

#ifdef FSCK_NOTUSED
void dnode_put(dnode_t *dnode, void *data)
{
	dnode->data = data;
}
#endif

#ifndef DICT_NODEBUG
int dnode_is_in_a_dict(dnode_t *dnode)
{
	return (dnode->parent && dnode->left && dnode->right);
}
#endif

#ifdef FSCK_NOTUSED
void dict_process(dict_t *dict, void *context, dnode_process_t function)
{
	dnode_t *node = dict_first(dict), *next;

	while (node != NULL) {
		/* check for callback function deleting	*/
		/* the next node from under us		*/
		dict_assert(dict_contains(dict, node));
		next = dict_next(dict, node);
		function(dict, node, context);
		node = next;
	}
}

static void load_begin_internal(dict_load_t *load, dict_t *dict)
{
	load->dictptr = dict;
	load->nilnode.left = &load->nilnode;
	load->nilnode.right = &load->nilnode;
}

void dict_load_begin(dict_load_t *load, dict_t *dict)
{
	dict_assert(dict_isempty(dict));
	load_begin_internal(load, dict);
}

void dict_load_next(dict_load_t *load, dnode_t *newnode, const void *key)
{
	dict_t *dict = load->dictptr;
	dnode_t *nil = &load->nilnode;

	dict_assert(!dnode_is_in_a_dict(newnode));
	dict_assert(dict->nodecount < dict->maxcount);

#ifndef DICT_NODEBUG
	if (dict->nodecount > 0) {
		if (dict->dupes)
			dict_assert(dict->compare(nil->left->key, key) <= 0);
		else
			dict_assert(dict->compare(nil->left->key, key) < 0);
	}
#endif

	newnode->key = key;
	nil->right->left = newnode;
	nil->right = newnode;
	newnode->left = nil;
	dict->nodecount++;
}

void dict_load_end(dict_load_t *load)
{
	dict_t *dict = load->dictptr;
	dnode_t *tree[DICT_DEPTH_MAX] = { 0 };
	dnode_t *curr, *dictnil = dict_nil(dict), *loadnil = &load->nilnode, *next;
	dnode_t *complete = 0;
	dictcount_t fullcount = DICTCOUNT_T_MAX, nodecount = dict->nodecount;
	dictcount_t botrowcount;
	unsigned baselevel = 0, level = 0, i;

	dict_assert(dnode_red == 0 && dnode_black == 1);

	while (fullcount >= nodecount && fullcount)
		fullcount >>= 1;

	botrowcount = nodecount - fullcount;

	for (curr = loadnil->left; curr != loadnil; curr = next) {
		next = curr->left;

		if (complete == NULL && botrowcount-- == 0) {
			dict_assert(baselevel == 0);
			dict_assert(level == 0);
			baselevel = level = 1;
			complete = tree[0];

			if (complete != 0) {
				tree[0] = 0;
				complete->right = dictnil;
				while (tree[level] != 0) {
					tree[level]->right = complete;
					complete->parent = tree[level];
					complete = tree[level];
					tree[level++] = 0;
				}
			}
		}

		if (complete == NULL) {
			curr->left = dictnil;
			curr->right = dictnil;
			curr->color = level % 2;
			complete = curr;

			dict_assert(level == baselevel);
			while (tree[level] != 0) {
				tree[level]->right = complete;
				complete->parent = tree[level];
				complete = tree[level];
				tree[level++] = 0;
			}
		} else {
			curr->left = complete;
			curr->color = (level + 1) % 2;
			complete->parent = curr;
			tree[level] = curr;
			complete = 0;
			level = baselevel;
		}
	}

	if (complete == NULL)
		complete = dictnil;

	for (i = 0; i < DICT_DEPTH_MAX; i++) {
		if (tree[i] != 0) {
			tree[i]->right = complete;
			complete->parent = tree[i];
			complete = tree[i];
		}
	}

	dictnil->color = dnode_black;
	dictnil->right = dictnil;
	complete->parent = dictnil;
	complete->color = dnode_black;
	dict_root(dict) = complete;

	dict_assert(dict_verify(dict));
}

void dict_merge(dict_t *dest, dict_t *source)
{
	dict_load_t load;
	dnode_t *leftnode = dict_first(dest), *rightnode = dict_first(source);

	dict_assert(dict_similar(dest, source));

	if (source == dest)
		return;

	dest->nodecount = 0;
	load_begin_internal(&load, dest);

	for (;;) {
		if (leftnode != NULL && rightnode != NULL) {
			if (dest->compare(leftnode->key, rightnode->key) < 0)
				goto copyleft;
			else
				goto copyright;
		} else if (leftnode != NULL) {
			goto copyleft;
		} else if (rightnode != NULL) {
			goto copyright;
		} else {
			dict_assert(leftnode == NULL && rightnode == NULL);
			break;
		}

copyleft:
		{
			dnode_t *next = dict_next(dest, leftnode);
#ifndef DICT_NODEBUG
			leftnode->left = NULL;	/* suppress assertion in dict_load_next */
#endif
			dict_load_next(&load, leftnode, leftnode->key);
			leftnode = next;
			continue;
		}

copyright:
		{
			dnode_t *next = dict_next(source, rightnode);
#ifndef DICT_NODEBUG
			rightnode->left = NULL;
#endif
			dict_load_next(&load, rightnode, rightnode->key);
			rightnode = next;
			continue;
		}
	}

	dict_clear(source);
	dict_load_end(&load);
}
#endif /* FSCK_NOTUSED */

#ifdef KAZLIB_TEST_MAIN

#include <stdio.h>
#include <string.h>
#include <ctype.h>
#include <stdarg.h>

typedef char input_t[256];

static int tokenize(char *string, ...)
{
	char **tokptr;
	va_list arglist;
	int tokcount = 0;

	va_start(arglist, string);
	tokptr = va_arg(arglist, char **);
	while (tokptr) {
		while (*string && isspace((unsigned char) *string))
			string++;
		if (!*string)
			break;
		*tokptr = string;
		while (*string && !isspace((unsigned char) *string))
			string++;
		tokptr = va_arg(arglist, char **);
		tokcount++;
		if (!*string)
			break;
		*string++ = 0;
	}
	va_end(arglist);

	return tokcount;
}

static int comparef(const void *key1, const void *key2)
{
	return strcmp(key1, key2);
}

static char *dupstring(char *str)
{
	int sz = strlen(str) + 1;
	char *new = malloc(sz);
	if (new)
		memcpy(new, str, sz);
	return new;
}

static dnode_t *new_node(void *c)
{
	static dnode_t few[5];
	static int count;

	if (count < 5)
		return few + count++;

	return NULL;
}

static void del_node(dnode_t *n, void *c)
{
}

static int prompt = 0;

static void construct(dict_t *d)
{
	input_t in;
	int done = 0;
	dict_load_t dl;
	dnode_t *dn;
	char *tok1, *tok2, *val;
	const char *key;
	char *help =
		"p                      turn prompt on\n"
		"q                      finish construction\n"
		"a <key> <val>          add new entry\n";

	if (!dict_isempty(d))
		puts("warning: dictionary not empty!");

	dict_load_begin(&dl, d);

	while (!done) {
		if (prompt)
			putchar('>');
		fflush(stdout);

		if (!fgets(in, sizeof(input_t), stdin))
			break;

		switch (in[0]) {
			case '?':
				puts(help);
				break;
			case 'p':
				prompt = 1;
				break;
			case 'q':
				done = 1;
				break;
			case 'a':
				if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {
					puts("what?");
					break;
				}
				key = dupstring(tok1);
				val = dupstring(tok2);
				dn = dnode_create(val);

				if (!key || !val || !dn) {
					puts("out of memory");
					free((void *) key);
					free(val);
					if (dn)
						dnode_destroy(dn);
				}

				dict_load_next(&dl, dn, key);
				break;
			default:
				putchar('?');
				putchar('\n');
				break;
		}
	}

	dict_load_end(&dl);
}

int main(void)
{
	input_t in;
	dict_t darray[10];
	dict_t *d = &darray[0];
	dnode_t *dn;
	int i;
	char *tok1, *tok2, *val;
	const char *key;

	char *help =
		"a <key> <val>          add value to dictionary\n"
		"d <key>                delete value from dictionary\n"
		"l <key>                lookup value in dictionary\n"
		"( <key>                lookup lower bound\n"
		") <key>                lookup upper bound\n"
		"# <num>                switch to alternate dictionary (0-9)\n"
		"j <num> <num>          merge two dictionaries\n"
		"f                      free the whole dictionary\n"
		"k                      allow duplicate keys\n"
		"c                      show number of entries\n"
		"t                      dump whole dictionary in sort order\n"
		"m                      make dictionary out of sorted items\n"
		"p                      turn prompt on\n"
		"s                      switch to non-functioning allocator\n"
		"q                      quit";

	for (i = 0; i < sizeof darray / sizeof *darray; i++)
		dict_init(&darray[i], DICTCOUNT_T_MAX, comparef);

	for (;;) {
		if (prompt)
			putchar('>');
		fflush(stdout);

		if (!fgets(in, sizeof(input_t), stdin))
			break;

		switch(in[0]) {
			case '?':
				puts(help);
				break;
			case 'a':
				if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {
					puts("what?");
					break;
				}
				key = dupstring(tok1);
				val = dupstring(tok2);

				if (!key || !val) {
					puts("out of memory");
					free((void *) key);
					free(val);
				}

				if (!dict_alloc_insert(d, key, val)) {
					puts("dict_alloc_insert failed");
					free((void *) key);
					free(val);
					break;
				}
				break;
			case 'd':
				if (tokenize(in+1, &tok1, (char **) 0) != 1) {
					puts("what?");
					break;
				}
				dn = dict_lookup(d, tok1);
				if (!dn) {
					puts("dict_lookup failed");
					break;
				}
				val = dnode_get(dn);
				key = dnode_getkey(dn);
				dict_delete_free(d, dn);

				free(val);
				free((void *) key);
				break;
			case 'f':
				dict_free(d);
				break;
			case 'l':
			case '(':
			case ')':
				if (tokenize(in+1, &tok1, (char **) 0) != 1) {
					puts("what?");
					break;
				}
				dn = 0;
				switch (in[0]) {
					case 'l':
						dn = dict_lookup(d, tok1);
						break;
					case '(':
						dn = dict_lower_bound(d, tok1);
						break;
					case ')':
						dn = dict_upper_bound(d, tok1);
						break;
				}
				if (!dn) {
					puts("lookup failed");
					break;
				}
				val = dnode_get(dn);
				puts(val);
				break;
			case 'm':
				construct(d);
				break;
			case 'k':
				dict_allow_dupes(d);
				break;
			case 'c':
				printf("%lu\n", (unsigned long) dict_count(d));
				break;
			case 't':
				for (dn = dict_first(d); dn; dn = dict_next(d, dn)) {
					printf("%s\t%s\n", (char *) dnode_getkey(dn),
							(char *) dnode_get(dn));
				}
				break;
			case 'q':
				exit(0);
				break;
			case '\0':
				break;
			case 'p':
				prompt = 1;
				break;
			case 's':
				dict_set_allocator(d, new_node, del_node, NULL);
				break;
			case '#':
				if (tokenize(in+1, &tok1, (char **) 0) != 1) {
					puts("what?");
					break;
				} else {
					int dictnum = atoi(tok1);
					if (dictnum < 0 || dictnum > 9) {
						puts("invalid number");
						break;
					}
					d = &darray[dictnum];
				}
				break;
			case 'j':
				if (tokenize(in+1, &tok1, &tok2, (char **) 0) != 2) {
					puts("what?");
					break;
				} else {
					int dict1 = atoi(tok1), dict2 = atoi(tok2);
					if (dict1 < 0 || dict1 > 9 || dict2 < 0 || dict2 > 9) {
						puts("invalid number");
						break;
					}
					dict_merge(&darray[dict1], &darray[dict2]);
				}
				break;
			default:
				putchar('?');
				putchar('\n');
				break;
		}
	}

	return 0;
}

#endif