cayasso/order statistic tree.js

## order statistic tree.js
// Use: var tree = new OST(); tree.select(4); tree.insert(key,value)
var OST = function () {
  // Order statistic tree node
  var Node = function (leftChild, key, value, rightChild, parent) {
    return {
      leftChild: (typeof leftChild === "undefined") ? null :
      leftChild,
      key: (typeof key === "undefined") ? null : key,
      value: (typeof value === "undefined") ? null : value,
      rightChild: (typeof rightChild === "undefined") ? null :
      rightChild,
      parent: (typeof parent === "undefined") ? null : parent,
      size: (typeof size  === "undefined") ? 0 : size,
    };
  },
  /*
  * Private Class: Node
  *
  * A OST node constructor
  *
  * Parameters:
  *        leftChild - a reference to the left child of the node.
  *        key - The key of the node.
  *        value - the value of the node.
  *        rightChild - a reference to the right child of the node.
  *        parent - a reference to the parent of the node.
  *        size - size of subtree rooted at the node.
  *
  * Note: All parameters default to null.
  */

  /*
   * Private Variable: root
   *
   * The root node of the BST.
   */
  root = new Node(),

  /*
   * Private Method: searchNode
   *
   * Search through a binary tree.
   *
   * Parameters:
   *     node - the node to search on.
   *     key - the key to search for (as an integer).
   *
   * Returns:
   *     the value of the found node,
   *     or null if no node was found.
   *
   */
  searchNode = function (node, key) {
    if (node.key === null) {
      return null; // key not found
    }

    var nodeKey = parseInt(node.key, 10);

    if (key < nodeKey) {
      return searchNode(node.leftChild, key);
    } else if (key > nodeKey) {
      return searchNode(node.rightChild, key);
    }
    else { // key is equal to node key
        return node;
    }
  },

  deleteNode = function(key, current) {
    childCount = (current.leftChild !== null ? 1 : 0) + (current.rightChild !== null ? 1 : 0);
    var parent = current.parent;

    if (current === root){
      switch(childCount){
        case 0:
          root = null;
          break;

        case 1:
          root = (current.rightChild === null ? current.leftChild : current.rightChild);
          break;

        case 2:
          //new root will be the old root's leftChild child
          //...maybe
          var replacement = root.leftChild;

          //find the rightChild-most leaf node to be
          //the real new root
          while (replacement.rightChild !== null){
            var replacementParent = replacement;
            replacement = replacement.rightChild;
          }

          //it's not the first node on the leftChild
          if (replacementParent !== null){

            //remove the new root from it's
            //previous position
            replacementParent.rightChild = replacement.leftChild;

            //give the new root all of the old
            //root's children
            replacement.rightChild = root.rightChild;
            replacement.leftChild = root.leftChild;
          }
          else {

            //just assign the children
            replacement.rightChild = root.rightChild;
          }

          //officially assign new root
          root = replacement;
      }

    //non-root values
    }
    else {
      switch (childCount){
        case 0:
          //if the current key is less than its
          //parent's, null out the leftChild pointer
          if (current.key < parent.key){
            parent.leftChild = null;
            //if the current key is greater than its
            //parent's, null out the rightChild pointer
          }
          else {
            parent.rightChild = null;
          }
          break;

        //one child, just reassign to parent
        case 1:
          //if the current key is less than its
          //parent's, reset the leftChild pointer
          if (current.key < parent.key){
            parent.leftChild = (current.leftChild === null ?
            current.rightChild : current.leftChild);

            //if the current key is greater than its
            //parent's, reset the rightChild pointer
          }
          else {
            parent.rightChild = (current.leftChild === null ?
            current.rightChild : current.leftChild);
          }
          break;
        //two children, a bit more complicated
        case 2:

          //reset pointers for new traversal
          var replacement = current.leftChild;
          var replacementParent = current;

          //find the rightChild-most node
          while(replacement.rightChild !== null){
            replacementParent = replacement;
            replacement = replacement.rightChild;
          }

          replacementParent.rightChild = replacement.leftChild;

          //assign children to the replacement
          replacement.rightChild = current.rightChild;
          replacement.leftChild = current.leftChild;

          //place the replacement in the rightChild spot
          if (current.key < parent.key){
            parent.leftChild = replacement;
          } else {
            parent.rightChild = replacement;
          }

          //no default
      }
    }
  },

  /*
   * Private Method: insertNode
   *
   * Insert into a binary tree.
   *
   * Parameters:
   *     node - the node to search on.
   *     key - the key to insert (as an integer).
   *     value - the value to associate with the key (any type of
   *             object).
   *
   * Returns:
   *     true.
   *
   */
   insertNode = function (node, key, value, parent) {
    if (node.key === null) {
      node.leftChild = new Node();
      node.key = key;
      node.value = value;
      node.rightChild = new Node();
      node.parent = parent;
      node.size = 1;
      var recurseToRoot = node;
      while(recurseToRoot.parent != null){
        recurseToRoot.parent.size++;
        recurseToRoot = recurseToRoot.parent;
      }
      return true;
    }

    var nodeKey = parseInt(node.key, 10);

    if (key < nodeKey) {
      insertNode(node.leftChild, key, value, node);
    }
    else if (key > nodeKey) {
      insertNode(node.rightChild, key, value, node);
    }
    else { // key is equal to node key, update the value
      node.value = value;
      return true;
    }
  },

  /*
   * Private Method: traverseNode
   *
   * Call a function on each node of a binary tree.
   *
   * Parameters:
   *     node - the node to traverse.
   *     callback - the function to call on each node, this function
   *                takes a key and a value as parameters.
   *
   * Returns:
   *     true.
   *
   */
  traverseNode = function (node, callback) {
    if (node.key !== null) {
      traverseNode(node.leftChild, callback);
      callback(node.key, node.value);
      traverseNode(node.rightChild, callback);
    }

    return true;
  },

  /*
   * Private Method: minNode
   *
   * Find the key of the node with the lowest key number.
   *
   * Parameters:
   *     node - the node to traverse.
   *
   * Returns: the key of the node with the lowest key number.
   *
   */
  minNode = function (node) {
    while (node.leftChild.key !== null) {
      node = node.leftChild;
    }

    return node;
  },

  /*
   * Private Method: maxNode
   *
   * Find the key of the node with the highest key number.
   *
   * Parameters:
   *     node - the node to traverse.
   *
   * Returns: the key of the node with the highest key number.
   *
   */
  maxNode = function (node) {
    while (node.rightChild.key !== null) {
      node = node.rightChild;
    }

    return node;
  },

  /*
   * Private Method: successorNode
   *
   * Find the key that successes the given node.
   *
   * Parameters:
   *		node - the node to find the successor for
   *
   * Returns: the node that successes the given node.
   *
   */
  successorNode = function (node) {
    var parent;

    if (node.rightChild.key !== null) {
      return minNode(node.rightChild);
    }

    parent = node.parent;
    while (parent.key !== null && node == parent.rightChild) {
      node = parent;
      parent = parent.parent;
    }

    return parent
  },
  /*
  * Private Method: selectNode
  *
  * find the i'th smallest element stored in the tree
  *
  * Parameters:
  *      node - initially root
  *      i - index
  *
  * Returns: find the i'th smallest element stored in the tree
  *
  */
  selectNode = function (i, node) {
    var l = node.leftChild.size
    if(i = l)
      return node
    else if(i < l)
      return select(i, node.leftChild)
    else
      return select(i - (l+1), node.rightChild)
  },
  /*
  * Private Method: rankNode
  *
  * find the rank of node x in the tree, i.e. its index in the sorted list of elements of the tree
  *
  * Parameters:
  *      x - Node
  *
  * Returns: the rank of x
  *
  */
  rankNode = function (x) {
    var l = x.leftChild.size + 1;
    var iter = x;
    var r = 1;
    while(iter != root){
      if(iter == iter.parent.rightChild)
        r = r + iter.parent.leftChild.size + 1;
      iter = iter.parent;
    }
    return r;
  },

  /*
   * Private Method: predecessorNode
   *
   * Find the key that preceeds the given node.
   *
   * Parameters:
   *		node - the node to find the predecessor for
   *
   * Returns: the node that preceeds the given node.
   *
   */
  predecessorNode = function (node) {
    var parent;

    if (node.leftChild.key !== null) {
      return maxNode(node.leftChild);
    }

    parent = node.parent;
    while (parent.key !== null && node == parent.leftChild) {
      node = parent;
      parent = parent.parent;
    }

    return parent;
  };

  return {
    /*
     * Method: search
     *
     * Search through a binary tree.
     *
     * Parameters:
     *     key - the key to search for.
     *
     * Returns:
     *     the node,
     *     or null if no node was found,
     *     or undefined if no key was specified.
     *
     */
    search: function (key) {
      var keyInt = parseInt(key, 10);

      if (isNaN(keyInt)) {
        return undefined; // key must be a number
      }
      else {
        return searchNode(root, keyInt);
      }
    },
    /*
     * Method: select
     *
     * find the i'th smallest element stored in the tree
     *
     * Parameters:
     *     i - index
     *
     *
     * Returns:
     *     the node,
     *     or undefined if i > size of tree
     *
     */
    select: function (i) {
      if(root.size < i)
        return undefined
      else
        return selectNode(i, root)
    },
    /*
     * Method: rank
     *
     * find the rank of element x in the tree, i.e. its index in the sorted list of elements of the tree
     *
     *
     * Parameters:
     *     x - element
     *
     *
     * Returns:
     *     rank of x (one-indexed!!!! i.e. 1,2,3...)
     *     or undefined if x is undefined
     *
     */
    rank: function (x) {
      return rankNode(x);
    },
    /*
     * Method: insert
     *
     * Insert into a binary tree.
     *
     * Parameters:
     *     key - the key to search for.
     *     value - the value to associate with the key (any type of
     *             object).
     *
     * Returns:
     *     true,
     *     or undefined if no key was specified.
     *
     */
    insert: function (key, value) {
      var keyInt = parseInt(key, 10);

      if (isNaN(keyInt)) {
        return undefined; // key must be a number
      }
      else {
        return insertNode(root, keyInt, value, null);
      }
    },
    /*
     * Method: delete
     *
     * Deletes Node x
     *
     * Parameters:
     *     x - the Node to delete (of type Node)
     *
     * Returns:
     *     true.
     *
     */
    delete: function (x) {
      return deleteNode(x.key,x);
    },
    /*
     * Method: traverse
     *
     * Call a function on each node of a binary tree.
     *
     * Parameters:
     *     callback - the function to call on each node, this function
     *                takes a key and a value as parameters. If no
     *                callback is specified, print is called.
     *
     * Returns:
     *     true.
     *
     */
    traverse: function (callback) {
      if (typeof callback === "undefined") {
        callback = function (key, value) {
          print(key + ": " + value);
        };
      }

      return traverseNode(root, callback);
    },

    /*
     * Method: min
     *
     * Find the key of the node with the lowest key number.
     *
     * Parameters: none
     *
     * Returns: the node with the lowest key number.
     *
     */
    min: function () {
      return minNode(root);
    },

    /*
     * Method: max
     *
     * Find the key of the node with the highest key number.
     *
     * Parameters: none
     *
     * Returns: the node with the highest key number.
     *
     */
    max: function () {
      return maxNode(root);
    },
    // Returns the root node
    getRoot: function() {
      return root;
    },
    /*
     * Method: successor
     *
     * Find the key that successes the root node.
     *
     * Parameters: none
     *
     * Returns: the node that successes the root node.
     *
     */
    successor: function () {
      return successorNode(root);
    },
    /*
     * Method: predecessor
     *
     * Find the key that preceeds the root node.
     *
     * Parameters: none
     *
     * Returns: the node that preceeds the root node.
     *
     */
    predecessor: function () {
      return predecessorNode(root);
    }
  };
};

/* David Furlong used the below BST Class to build the OST Class
 *
 * License:
 *
 * Copyright (c) 2011 Trevor Lalish-Menagh (http://www.trevmex.com/)
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */
	// Use: var tree = new OST(); tree.select(4); tree.insert(key,value)
	var OST = function () {
	// Order statistic tree node
	var Node = function (leftChild, key, value, rightChild, parent) {
	return {
	leftChild: (typeof leftChild === "undefined") ? null :
	leftChild,
	key: (typeof key === "undefined") ? null : key,
	value: (typeof value === "undefined") ? null : value,
	rightChild: (typeof rightChild === "undefined") ? null :
	rightChild,
	parent: (typeof parent === "undefined") ? null : parent,
	size: (typeof size === "undefined") ? 0 : size,
	};
	},
	/*
	* Private Class: Node
	*
	* A OST node constructor
	*
	* Parameters:
	* leftChild - a reference to the left child of the node.
	* key - The key of the node.
	* value - the value of the node.
	* rightChild - a reference to the right child of the node.
	* parent - a reference to the parent of the node.
	* size - size of subtree rooted at the node.
	*
	* Note: All parameters default to null.
	*/

	/*
	* Private Variable: root
	*
	* The root node of the BST.
	*/
	root = new Node(),

	/*
	* Private Method: searchNode
	*
	* Search through a binary tree.
	*
	* Parameters:
	* node - the node to search on.
	* key - the key to search for (as an integer).
	*
	* Returns:
	* the value of the found node,
	* or null if no node was found.
	*
	*/
	searchNode = function (node, key) {
	if (node.key === null) {
	return null; // key not found
	}

	var nodeKey = parseInt(node.key, 10);

	if (key < nodeKey) {
	return searchNode(node.leftChild, key);
	} else if (key > nodeKey) {
	return searchNode(node.rightChild, key);
	}
	else { // key is equal to node key
	return node;
	}
	},

	deleteNode = function(key, current) {
	childCount = (current.leftChild !== null ? 1 : 0) + (current.rightChild !== null ? 1 : 0);
	var parent = current.parent;

	if (current === root){
	switch(childCount){
	case 0:
	root = null;
	break;

	case 1:
	root = (current.rightChild === null ? current.leftChild : current.rightChild);
	break;

	case 2:
	//new root will be the old root's leftChild child
	//...maybe
	var replacement = root.leftChild;

	//find the rightChild-most leaf node to be
	//the real new root
	while (replacement.rightChild !== null){
	var replacementParent = replacement;
	replacement = replacement.rightChild;
	}

	//it's not the first node on the leftChild
	if (replacementParent !== null){

	//remove the new root from it's
	//previous position
	replacementParent.rightChild = replacement.leftChild;

	//give the new root all of the old
	//root's children
	replacement.rightChild = root.rightChild;
	replacement.leftChild = root.leftChild;
	}
	else {

	//just assign the children
	replacement.rightChild = root.rightChild;
	}

	//officially assign new root
	root = replacement;
	}

	//non-root values
	}
	else {
	switch (childCount){
	case 0:
	//if the current key is less than its
	//parent's, null out the leftChild pointer
	if (current.key < parent.key){
	parent.leftChild = null;
	//if the current key is greater than its
	//parent's, null out the rightChild pointer
	}
	else {
	parent.rightChild = null;
	}
	break;

	//one child, just reassign to parent
	case 1:
	//if the current key is less than its
	//parent's, reset the leftChild pointer
	if (current.key < parent.key){
	parent.leftChild = (current.leftChild === null ?
	current.rightChild : current.leftChild);

	//if the current key is greater than its
	//parent's, reset the rightChild pointer
	}
	else {
	parent.rightChild = (current.leftChild === null ?
	current.rightChild : current.leftChild);
	}
	break;
	//two children, a bit more complicated
	case 2:

	//reset pointers for new traversal
	var replacement = current.leftChild;
	var replacementParent = current;

	//find the rightChild-most node
	while(replacement.rightChild !== null){
	replacementParent = replacement;
	replacement = replacement.rightChild;
	}

	replacementParent.rightChild = replacement.leftChild;

	//assign children to the replacement
	replacement.rightChild = current.rightChild;
	replacement.leftChild = current.leftChild;

	//place the replacement in the rightChild spot
	if (current.key < parent.key){
	parent.leftChild = replacement;
	} else {
	parent.rightChild = replacement;
	}

	//no default
	}
	}
	},

	/*
	* Private Method: insertNode
	*
	* Insert into a binary tree.
	*
	* Parameters:
	* node - the node to search on.
	* key - the key to insert (as an integer).
	* value - the value to associate with the key (any type of
	* object).
	*
	* Returns:
	* true.
	*
	*/
	insertNode = function (node, key, value, parent) {
	if (node.key === null) {
	node.leftChild = new Node();
	node.key = key;
	node.value = value;
	node.rightChild = new Node();
	node.parent = parent;
	node.size = 1;
	var recurseToRoot = node;
	while(recurseToRoot.parent != null){
	recurseToRoot.parent.size++;
	recurseToRoot = recurseToRoot.parent;
	}
	return true;
	}

	var nodeKey = parseInt(node.key, 10);

	if (key < nodeKey) {
	insertNode(node.leftChild, key, value, node);
	}
	else if (key > nodeKey) {
	insertNode(node.rightChild, key, value, node);
	}
	else { // key is equal to node key, update the value
	node.value = value;
	return true;
	}
	},

	/*
	* Private Method: traverseNode
	*
	* Call a function on each node of a binary tree.
	*
	* Parameters:
	* node - the node to traverse.
	* callback - the function to call on each node, this function
	* takes a key and a value as parameters.
	*
	* Returns:
	* true.
	*
	*/
	traverseNode = function (node, callback) {
	if (node.key !== null) {
	traverseNode(node.leftChild, callback);
	callback(node.key, node.value);
	traverseNode(node.rightChild, callback);
	}

	return true;
	},

	/*
	* Private Method: minNode
	*
	* Find the key of the node with the lowest key number.
	*
	* Parameters:
	* node - the node to traverse.
	*
	* Returns: the key of the node with the lowest key number.
	*
	*/
	minNode = function (node) {
	while (node.leftChild.key !== null) {
	node = node.leftChild;
	}

	return node;
	},

	/*
	* Private Method: maxNode
	*
	* Find the key of the node with the highest key number.
	*
	* Parameters:
	* node - the node to traverse.
	*
	* Returns: the key of the node with the highest key number.
	*
	*/
	maxNode = function (node) {
	while (node.rightChild.key !== null) {
	node = node.rightChild;
	}

	return node;
	},

	/*
	* Private Method: successorNode
	*
	* Find the key that successes the given node.
	*
	* Parameters:
	* node - the node to find the successor for
	*
	* Returns: the node that successes the given node.
	*
	*/
	successorNode = function (node) {
	var parent;

	if (node.rightChild.key !== null) {
	return minNode(node.rightChild);
	}

	parent = node.parent;
	while (parent.key !== null && node == parent.rightChild) {
	node = parent;
	parent = parent.parent;
	}

	return parent
	},
	/*
	* Private Method: selectNode
	*
	* find the i'th smallest element stored in the tree
	*
	* Parameters:
	* node - initially root
	* i - index
	*
	* Returns: find the i'th smallest element stored in the tree
	*
	*/
	selectNode = function (i, node) {
	var l = node.leftChild.size
	if(i = l)
	return node
	else if(i < l)
	return select(i, node.leftChild)
	else
	return select(i - (l+1), node.rightChild)
	},
	/*
	* Private Method: rankNode
	*
	* find the rank of node x in the tree, i.e. its index in the sorted list of elements of the tree
	*
	* Parameters:
	* x - Node
	*
	* Returns: the rank of x
	*
	*/
	rankNode = function (x) {
	var l = x.leftChild.size + 1;
	var iter = x;
	var r = 1;
	while(iter != root){
	if(iter == iter.parent.rightChild)
	r = r + iter.parent.leftChild.size + 1;
	iter = iter.parent;
	}
	return r;
	},

	/*
	* Private Method: predecessorNode
	*
	* Find the key that preceeds the given node.
	*
	* Parameters:
	* node - the node to find the predecessor for
	*
	* Returns: the node that preceeds the given node.
	*
	*/
	predecessorNode = function (node) {
	var parent;

	if (node.leftChild.key !== null) {
	return maxNode(node.leftChild);
	}

	parent = node.parent;
	while (parent.key !== null && node == parent.leftChild) {
	node = parent;
	parent = parent.parent;
	}

	return parent;
	};

	return {
	/*
	* Method: search
	*
	* Search through a binary tree.
	*
	* Parameters:
	* key - the key to search for.
	*
	* Returns:
	* the node,
	* or null if no node was found,
	* or undefined if no key was specified.
	*
	*/
	search: function (key) {
	var keyInt = parseInt(key, 10);

	if (isNaN(keyInt)) {
	return undefined; // key must be a number
	}
	else {
	return searchNode(root, keyInt);
	}
	},
	/*
	* Method: select
	*
	* find the i'th smallest element stored in the tree
	*
	* Parameters:
	* i - index
	*
	*
	* Returns:
	* the node,
	* or undefined if i > size of tree
	*
	*/
	select: function (i) {
	if(root.size < i)
	return undefined
	else
	return selectNode(i, root)
	},
	/*
	* Method: rank
	*
	* find the rank of element x in the tree, i.e. its index in the sorted list of elements of the tree
	*
	*
	* Parameters:
	* x - element
	*
	*
	* Returns:
	* rank of x (one-indexed!!!! i.e. 1,2,3...)
	* or undefined if x is undefined
	*
	*/
	rank: function (x) {
	return rankNode(x);
	},
	/*
	* Method: insert
	*
	* Insert into a binary tree.
	*
	* Parameters:
	* key - the key to search for.
	* value - the value to associate with the key (any type of
	* object).
	*
	* Returns:
	* true,
	* or undefined if no key was specified.
	*
	*/
	insert: function (key, value) {
	var keyInt = parseInt(key, 10);

	if (isNaN(keyInt)) {
	return undefined; // key must be a number
	}
	else {
	return insertNode(root, keyInt, value, null);
	}
	},
	/*
	* Method: delete
	*
	* Deletes Node x
	*
	* Parameters:
	* x - the Node to delete (of type Node)
	*
	* Returns:
	* true.
	*
	*/
	delete: function (x) {
	return deleteNode(x.key,x);
	},
	/*
	* Method: traverse
	*
	* Call a function on each node of a binary tree.
	*
	* Parameters:
	* callback - the function to call on each node, this function
	* takes a key and a value as parameters. If no
	* callback is specified, print is called.
	*
	* Returns:
	* true.
	*
	*/
	traverse: function (callback) {
	if (typeof callback === "undefined") {
	callback = function (key, value) {
	print(key + ": " + value);
	};
	}

	return traverseNode(root, callback);
	},

	/*
	* Method: min
	*
	* Find the key of the node with the lowest key number.
	*
	* Parameters: none
	*
	* Returns: the node with the lowest key number.
	*
	*/
	min: function () {
	return minNode(root);
	},

	/*
	* Method: max
	*
	* Find the key of the node with the highest key number.
	*
	* Parameters: none
	*
	* Returns: the node with the highest key number.
	*
	*/
	max: function () {
	return maxNode(root);
	},
	// Returns the root node
	getRoot: function() {
	return root;
	},
	/*
	* Method: successor
	*
	* Find the key that successes the root node.
	*
	* Parameters: none
	*
	* Returns: the node that successes the root node.
	*
	*/
	successor: function () {
	return successorNode(root);
	},
	/*
	* Method: predecessor
	*
	* Find the key that preceeds the root node.
	*
	* Parameters: none
	*
	* Returns: the node that preceeds the root node.
	*
	*/
	predecessor: function () {
	return predecessorNode(root);
	}
	};
	};

	/* David Furlong used the below BST Class to build the OST Class
	*
	* License:
	*
	* Copyright (c) 2011 Trevor Lalish-Menagh (http://www.trevmex.com/)
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to deal
	* in the Software without restriction, including without limitation the rights
	* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	* copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	* THE SOFTWARE.
	*/