android-platform-libcore/luni/src/main/java/org/apache/xml/utils/NodeVector.java - nest-cam/4320010/android-platform-libcore - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one
  * or more contributor license agreements. See the NOTICE file
  * distributed with this work for additional information
  * regarding copyright ownership. The ASF licenses this file
  * to you under the Apache License, Version 2.0 (the  "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 /*
  * $Id: NodeVector.java 468655 2006-10-28 07:12:06Z minchau $
  */
 package org.apache.xml.utils;

 import java.io.Serializable;

 import org.apache.xml.dtm.DTM;

 /**
  * A very simple table that stores a list of Nodes.
  * @xsl.usage internal
  */
 public class NodeVector implements Serializable, Cloneable
 {
     static final long serialVersionUID = -713473092200731870L;

   /**
    * Size of blocks to allocate.
    *  @serial
    */
   private int m_blocksize;

   /**
    * Array of nodes this points to.
    *  @serial
    */
   private int m_map[];

   /**
    * Number of nodes in this NodeVector.
    *  @serial
    */
   protected int m_firstFree = 0;

   /**
    * Size of the array this points to.
    *  @serial
    */
   private int m_mapSize;  // lazy initialization

   /**
    * Default constructor.
    */
   public NodeVector()
   {
     m_blocksize = 32;
     m_mapSize = 0;
   }

   /**
    * Construct a NodeVector, using the given block size.
    *
    * @param blocksize Size of blocks to allocate
    */
   public NodeVector(int blocksize)
   {
     m_blocksize = blocksize;
     m_mapSize = 0;
   }

   /**
    * Get a cloned LocPathIterator.
    *
    * @return A clone of this
    *
    * @throws CloneNotSupportedException
    */
   public Object clone() throws CloneNotSupportedException
   {

     NodeVector clone = (NodeVector) super.clone();

     if ((null != this.m_map) && (this.m_map == clone.m_map))
     {
       clone.m_map = new int[this.m_map.length];

       System.arraycopy(this.m_map, 0, clone.m_map, 0, this.m_map.length);
     }

     return clone;
   }

   /**
    * Get the length of the list.
    *
    * @return Number of nodes in this NodeVector
    */
   public int size()
   {
     return m_firstFree;
   }

   /**
    * Append a Node onto the vector.
    *
    * @param value Node to add to the vector
    */
   public void addElement(int value)
   {

     if ((m_firstFree + 1) >= m_mapSize)
     {
       if (null == m_map)
       {
         m_map = new int[m_blocksize];
         m_mapSize = m_blocksize;
       }
       else
       {
         m_mapSize += m_blocksize;

         int newMap[] = new int[m_mapSize];

         System.arraycopy(m_map, 0, newMap, 0, m_firstFree + 1);

         m_map = newMap;
       }
     }

     m_map[m_firstFree] = value;

     m_firstFree++;
   }

   /**
    * Append a Node onto the vector.
    *
    * @param value Node to add to the vector
    */
   public final void push(int value)
   {

     int ff = m_firstFree;

     if ((ff + 1) >= m_mapSize)
     {
       if (null == m_map)
       {
         m_map = new int[m_blocksize];
         m_mapSize = m_blocksize;
       }
       else
       {
         m_mapSize += m_blocksize;

         int newMap[] = new int[m_mapSize];

         System.arraycopy(m_map, 0, newMap, 0, ff + 1);

         m_map = newMap;
       }
     }

     m_map[ff] = value;

     ff++;

     m_firstFree = ff;
   }

   /**
    * Pop a node from the tail of the vector and return the result.
    *
    * @return the node at the tail of the vector
    */
   public final int pop()
   {

     m_firstFree--;

     int n = m_map[m_firstFree];

     m_map[m_firstFree] = DTM.NULL;

     return n;
   }

   /**
    * Pop a node from the tail of the vector and return the
    * top of the stack after the pop.
    *
    * @return The top of the stack after it's been popped
    */
   public final int popAndTop()
   {

     m_firstFree--;

     m_map[m_firstFree] = DTM.NULL;

     return (m_firstFree == 0) ? DTM.NULL : m_map[m_firstFree - 1];
   }

   /**
    * Pop a node from the tail of the vector.
    */
   public final void popQuick()
   {

     m_firstFree--;

     m_map[m_firstFree] = DTM.NULL;
   }

   /**
    * Return the node at the top of the stack without popping the stack.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @return Node at the top of the stack or null if stack is empty.
    */
   public final int peepOrNull()
   {
     return ((null != m_map) && (m_firstFree > 0))
            ? m_map[m_firstFree - 1] : DTM.NULL;
   }

   /**
    * Push a pair of nodes into the stack.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @param v1 First node to add to vector
    * @param v2 Second node to add to vector
    */
   public final void pushPair(int v1, int v2)
   {

     if (null == m_map)
     {
       m_map = new int[m_blocksize];
       m_mapSize = m_blocksize;
     }
     else
     {
       if ((m_firstFree + 2) >= m_mapSize)
       {
         m_mapSize += m_blocksize;

         int newMap[] = new int[m_mapSize];

         System.arraycopy(m_map, 0, newMap, 0, m_firstFree);

         m_map = newMap;
       }
     }

     m_map[m_firstFree] = v1;
     m_map[m_firstFree + 1] = v2;
     m_firstFree += 2;
   }

   /**
    * Pop a pair of nodes from the tail of the stack.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    */
   public final void popPair()
   {

     m_firstFree -= 2;
     m_map[m_firstFree] = DTM.NULL;
     m_map[m_firstFree + 1] = DTM.NULL;
   }

   /**
    * Set the tail of the stack to the given node.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @param n Node to set at the tail of vector
    */
   public final void setTail(int n)
   {
     m_map[m_firstFree - 1] = n;
   }

   /**
    * Set the given node one position from the tail.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @param n Node to set
    */
   public final void setTailSub1(int n)
   {
     m_map[m_firstFree - 2] = n;
   }

   /**
    * Return the node at the tail of the vector without popping
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @return Node at the tail of the vector
    */
   public final int peepTail()
   {
     return m_map[m_firstFree - 1];
   }

   /**
    * Return the node one position from the tail without popping.
    * Special purpose method for TransformerImpl, pushElemTemplateElement.
    * Performance critical.
    *
    * @return Node one away from the tail
    */
   public final int peepTailSub1()
   {
     return m_map[m_firstFree - 2];
   }

   /**
    * Insert a node in order in the list.
    *
    * @param value Node to insert
    */
   public void insertInOrder(int value)
   {

     for (int i = 0; i < m_firstFree; i++)
     {
       if (value < m_map[i])
       {
         insertElementAt(value, i);

         return;
       }
     }

     addElement(value);
   }

   /**
    * Inserts the specified node in this vector at the specified index.
    * Each component in this vector with an index greater or equal to
    * the specified index is shifted upward to have an index one greater
    * than the value it had previously.
    *
    * @param value Node to insert
    * @param at Position where to insert
    */
   public void insertElementAt(int value, int at)
   {

     if (null == m_map)
     {
       m_map = new int[m_blocksize];
       m_mapSize = m_blocksize;
     }
     else if ((m_firstFree + 1) >= m_mapSize)
     {
       m_mapSize += m_blocksize;

       int newMap[] = new int[m_mapSize];

       System.arraycopy(m_map, 0, newMap, 0, m_firstFree + 1);

       m_map = newMap;
     }

     if (at <= (m_firstFree - 1))
     {
       System.arraycopy(m_map, at, m_map, at + 1, m_firstFree - at);
     }

     m_map[at] = value;

     m_firstFree++;
   }

   /**
    * Append the nodes to the list.
    *
    * @param nodes NodeVector to append to this list
    */
   public void appendNodes(NodeVector nodes)
   {

     int nNodes = nodes.size();

     if (null == m_map)
     {
       m_mapSize = nNodes + m_blocksize;
       m_map = new int[m_mapSize];
     }
     else if ((m_firstFree + nNodes) >= m_mapSize)
     {
       m_mapSize += (nNodes + m_blocksize);

       int newMap[] = new int[m_mapSize];

       System.arraycopy(m_map, 0, newMap, 0, m_firstFree + nNodes);

       m_map = newMap;
     }

     System.arraycopy(nodes.m_map, 0, m_map, m_firstFree, nNodes);

     m_firstFree += nNodes;
   }

   /**
    * Inserts the specified node in this vector at the specified index.
    * Each component in this vector with an index greater or equal to
    * the specified index is shifted upward to have an index one greater
    * than the value it had previously.
    */
   public void removeAllElements()
   {

     if (null == m_map)
       return;

     for (int i = 0; i < m_firstFree; i++)
     {
       m_map[i] = DTM.NULL;
     }

     m_firstFree = 0;
   }

   /**
    * Set the length to zero, but don't clear the array.
    */
   public void RemoveAllNoClear()
   {

     if (null == m_map)
       return;

     m_firstFree = 0;
   }

   /**
    * Removes the first occurrence of the argument from this vector.
    * If the object is found in this vector, each component in the vector
    * with an index greater or equal to the object's index is shifted
    * downward to have an index one smaller than the value it had
    * previously.
    *
    * @param s Node to remove from the list
    *
    * @return True if the node was successfully removed
    */
   public boolean removeElement(int s)
   {

     if (null == m_map)
       return false;

     for (int i = 0; i < m_firstFree; i++)
     {
       int node = m_map[i];

       if (node == s)
       {
         if (i > m_firstFree)
           System.arraycopy(m_map, i + 1, m_map, i - 1, m_firstFree - i);
         else
           m_map[i] = DTM.NULL;

         m_firstFree--;

         return true;
       }
     }

     return false;
   }

   /**
    * Deletes the component at the specified index. Each component in
    * this vector with an index greater or equal to the specified
    * index is shifted downward to have an index one smaller than
    * the value it had previously.
    *
    * @param i Index of node to remove
    */
   public void removeElementAt(int i)
   {

     if (null == m_map)
       return;

     if (i > m_firstFree)
       System.arraycopy(m_map, i + 1, m_map, i - 1, m_firstFree - i);
     else
       m_map[i] = DTM.NULL;
   }

   /**
    * Sets the component at the specified index of this vector to be the
    * specified object. The previous component at that position is discarded.
    *
    * The index must be a value greater than or equal to 0 and less
    * than the current size of the vector.
    *
    * @param node Node to set
    * @param index Index of where to set the node
    */
   public void setElementAt(int node, int index)
   {

     if (null == m_map)
     {
       m_map = new int[m_blocksize];
       m_mapSize = m_blocksize;
     }

     if(index == -1)
     	addElement(node);

     m_map[index] = node;
   }

   /**
    * Get the nth element.
    *
    * @param i Index of node to get
    *
    * @return Node at specified index
    */
   public int elementAt(int i)
   {

     if (null == m_map)
       return DTM.NULL;

     return m_map[i];
   }

   /**
    * Tell if the table contains the given node.
    *
    * @param s Node to look for
    *
    * @return True if the given node was found.
    */
   public boolean contains(int s)
   {

     if (null == m_map)
       return false;

     for (int i = 0; i < m_firstFree; i++)
     {
       int node = m_map[i];

       if (node == s)
         return true;
     }

     return false;
   }

   /**
    * Searches for the first occurence of the given argument,
    * beginning the search at index, and testing for equality
    * using the equals method.
    *
    * @param elem Node to look for
    * @param index Index of where to start the search
    * @return the index of the first occurrence of the object
    * argument in this vector at position index or later in the
    * vector; returns -1 if the object is not found.
    */
   public int indexOf(int elem, int index)
   {

     if (null == m_map)
       return -1;

     for (int i = index; i < m_firstFree; i++)
     {
       int node = m_map[i];

       if (node == elem)
         return i;
     }

     return -1;
   }

   /**
    * Searches for the first occurence of the given argument,
    * beginning the search at index, and testing for equality
    * using the equals method.
    *
    * @param elem Node to look for
    * @return the index of the first occurrence of the object
    * argument in this vector at position index or later in the
    * vector; returns -1 if the object is not found.
    */
   public int indexOf(int elem)
   {

     if (null == m_map)
       return -1;

     for (int i = 0; i < m_firstFree; i++)
     {
       int node = m_map[i];

       if (node == elem)
         return i;
     }

     return -1;
   }

   /**
    * Sort an array using a quicksort algorithm.
    *
    * @param a The array to be sorted.
    * @param lo0  The low index.
    * @param hi0  The high index.
    *
    * @throws Exception
    */
   public void sort(int a[], int lo0, int hi0) throws Exception
   {

     int lo = lo0;
     int hi = hi0;

     // pause(lo, hi);
     if (lo >= hi)
     {
       return;
     }
     else if (lo == hi - 1)
     {

       /*
        *  sort a two element list by swapping if necessary
        */
       if (a[lo] > a[hi])
       {
         int T = a[lo];

         a[lo] = a[hi];
         a[hi] = T;
       }

       return;
     }

     /*
      *  Pick a pivot and move it out of the way
      */
     int pivot = a[(lo + hi) / 2];

     a[(lo + hi) / 2] = a[hi];
     a[hi] = pivot;

     while (lo < hi)
     {

       /*
        *  Search forward from a[lo] until an element is found that
        *  is greater than the pivot or lo >= hi
        */
       while (a[lo] <= pivot && lo < hi)
       {
         lo++;
       }

       /*
        *  Search backward from a[hi] until element is found that
        *  is less than the pivot, or lo >= hi
        */
       while (pivot <= a[hi] && lo < hi)
       {
         hi--;
       }

       /*
        *  Swap elements a[lo] and a[hi]
        */
       if (lo < hi)
       {
         int T = a[lo];

         a[lo] = a[hi];
         a[hi] = T;

         // pause();
       }

       // if (stopRequested) {
       //    return;
       // }
     }

     /*
      *  Put the median in the "center" of the list
      */
     a[hi0] = a[hi];
     a[hi] = pivot;

     /*
      *  Recursive calls, elements a[lo0] to a[lo-1] are less than or
      *  equal to pivot, elements a[hi+1] to a[hi0] are greater than
      *  pivot.
      */
     sort(a, lo0, lo - 1);
     sort(a, hi + 1, hi0);
   }

   /**
    * Sort an array using a quicksort algorithm.
    *
    * @throws Exception
    */
   public void sort() throws Exception
   {
     sort(m_map, 0, m_firstFree - 1);
   }
 }
	/*
	* Licensed to the Apache Software Foundation (ASF) under one
	* or more contributor license agreements. See the NOTICE file
	* distributed with this work for additional information
	* regarding copyright ownership. The ASF licenses this file
	* to you under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	/*
	* $Id: NodeVector.java 468655 2006-10-28 07:12:06Z minchau $
	*/
	package org.apache.xml.utils;

	import java.io.Serializable;

	import org.apache.xml.dtm.DTM;

	/**
	* A very simple table that stores a list of Nodes.
	* @xsl.usage internal
	*/
	public class NodeVector implements Serializable, Cloneable
	{
	static final long serialVersionUID = -713473092200731870L;

	/**
	* Size of blocks to allocate.
	* @serial
	*/
	private int m_blocksize;

	/**
	* Array of nodes this points to.
	* @serial
	*/
	private int m_map[];

	/**
	* Number of nodes in this NodeVector.
	* @serial
	*/
	protected int m_firstFree = 0;

	/**
	* Size of the array this points to.
	* @serial
	*/
	private int m_mapSize; // lazy initialization

	/**
	* Default constructor.
	*/
	public NodeVector()
	{
	m_blocksize = 32;
	m_mapSize = 0;
	}

	/**
	* Construct a NodeVector, using the given block size.
	*
	* @param blocksize Size of blocks to allocate
	*/
	public NodeVector(int blocksize)
	{
	m_blocksize = blocksize;
	m_mapSize = 0;
	}

	/**
	* Get a cloned LocPathIterator.
	*
	* @return A clone of this
	*
	* @throws CloneNotSupportedException
	*/
	public Object clone() throws CloneNotSupportedException
	{

	NodeVector clone = (NodeVector) super.clone();

	if ((null != this.m_map) && (this.m_map == clone.m_map))
	{
	clone.m_map = new int[this.m_map.length];

	System.arraycopy(this.m_map, 0, clone.m_map, 0, this.m_map.length);
	}

	return clone;
	}

	/**
	* Get the length of the list.
	*
	* @return Number of nodes in this NodeVector
	*/
	public int size()
	{
	return m_firstFree;
	}

	/**
	* Append a Node onto the vector.
	*
	* @param value Node to add to the vector
	*/
	public void addElement(int value)
	{

	if ((m_firstFree + 1) >= m_mapSize)
	{
	if (null == m_map)
	{
	m_map = new int[m_blocksize];
	m_mapSize = m_blocksize;
	}
	else
	{
	m_mapSize += m_blocksize;

	int newMap[] = new int[m_mapSize];

	System.arraycopy(m_map, 0, newMap, 0, m_firstFree + 1);

	m_map = newMap;
	}
	}

	m_map[m_firstFree] = value;

	m_firstFree++;
	}

	/**
	* Append a Node onto the vector.
	*
	* @param value Node to add to the vector
	*/
	public final void push(int value)
	{

	int ff = m_firstFree;

	if ((ff + 1) >= m_mapSize)
	{
	if (null == m_map)
	{
	m_map = new int[m_blocksize];
	m_mapSize = m_blocksize;
	}
	else
	{
	m_mapSize += m_blocksize;

	int newMap[] = new int[m_mapSize];

	System.arraycopy(m_map, 0, newMap, 0, ff + 1);

	m_map = newMap;
	}
	}

	m_map[ff] = value;

	ff++;

	m_firstFree = ff;
	}

	/**
	* Pop a node from the tail of the vector and return the result.
	*
	* @return the node at the tail of the vector
	*/
	public final int pop()
	{

	m_firstFree--;

	int n = m_map[m_firstFree];

	m_map[m_firstFree] = DTM.NULL;

	return n;
	}

	/**
	* Pop a node from the tail of the vector and return the
	* top of the stack after the pop.
	*
	* @return The top of the stack after it's been popped
	*/
	public final int popAndTop()
	{

	m_firstFree--;

	m_map[m_firstFree] = DTM.NULL;

	return (m_firstFree == 0) ? DTM.NULL : m_map[m_firstFree - 1];
	}

	/**
	* Pop a node from the tail of the vector.
	*/
	public final void popQuick()
	{

	m_firstFree--;

	m_map[m_firstFree] = DTM.NULL;
	}

	/**
	* Return the node at the top of the stack without popping the stack.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @return Node at the top of the stack or null if stack is empty.
	*/
	public final int peepOrNull()
	{
	return ((null != m_map) && (m_firstFree > 0))
	? m_map[m_firstFree - 1] : DTM.NULL;
	}

	/**
	* Push a pair of nodes into the stack.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @param v1 First node to add to vector
	* @param v2 Second node to add to vector
	*/
	public final void pushPair(int v1, int v2)
	{

	if (null == m_map)
	{
	m_map = new int[m_blocksize];
	m_mapSize = m_blocksize;
	}
	else
	{
	if ((m_firstFree + 2) >= m_mapSize)
	{
	m_mapSize += m_blocksize;

	int newMap[] = new int[m_mapSize];

	System.arraycopy(m_map, 0, newMap, 0, m_firstFree);

	m_map = newMap;
	}
	}

	m_map[m_firstFree] = v1;
	m_map[m_firstFree + 1] = v2;
	m_firstFree += 2;
	}

	/**
	* Pop a pair of nodes from the tail of the stack.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*/
	public final void popPair()
	{

	m_firstFree -= 2;
	m_map[m_firstFree] = DTM.NULL;
	m_map[m_firstFree + 1] = DTM.NULL;
	}

	/**
	* Set the tail of the stack to the given node.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @param n Node to set at the tail of vector
	*/
	public final void setTail(int n)
	{
	m_map[m_firstFree - 1] = n;
	}

	/**
	* Set the given node one position from the tail.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @param n Node to set
	*/
	public final void setTailSub1(int n)
	{
	m_map[m_firstFree - 2] = n;
	}

	/**
	* Return the node at the tail of the vector without popping
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @return Node at the tail of the vector
	*/
	public final int peepTail()
	{
	return m_map[m_firstFree - 1];
	}

	/**
	* Return the node one position from the tail without popping.
	* Special purpose method for TransformerImpl, pushElemTemplateElement.
	* Performance critical.
	*
	* @return Node one away from the tail
	*/
	public final int peepTailSub1()
	{
	return m_map[m_firstFree - 2];
	}

	/**
	* Insert a node in order in the list.
	*
	* @param value Node to insert
	*/
	public void insertInOrder(int value)
	{

	for (int i = 0; i < m_firstFree; i++)
	{
	if (value < m_map[i])
	{
	insertElementAt(value, i);

	return;
	}
	}

	addElement(value);
	}

	/**
	* Inserts the specified node in this vector at the specified index.
	* Each component in this vector with an index greater or equal to
	* the specified index is shifted upward to have an index one greater
	* than the value it had previously.
	*
	* @param value Node to insert
	* @param at Position where to insert
	*/
	public void insertElementAt(int value, int at)
	{

	if (null == m_map)
	{
	m_map = new int[m_blocksize];
	m_mapSize = m_blocksize;
	}
	else if ((m_firstFree + 1) >= m_mapSize)
	{
	m_mapSize += m_blocksize;

	int newMap[] = new int[m_mapSize];

	System.arraycopy(m_map, 0, newMap, 0, m_firstFree + 1);

	m_map = newMap;
	}

	if (at <= (m_firstFree - 1))
	{
	System.arraycopy(m_map, at, m_map, at + 1, m_firstFree - at);
	}

	m_map[at] = value;

	m_firstFree++;
	}

	/**
	* Append the nodes to the list.
	*
	* @param nodes NodeVector to append to this list
	*/
	public void appendNodes(NodeVector nodes)
	{

	int nNodes = nodes.size();

	if (null == m_map)
	{
	m_mapSize = nNodes + m_blocksize;
	m_map = new int[m_mapSize];
	}
	else if ((m_firstFree + nNodes) >= m_mapSize)
	{
	m_mapSize += (nNodes + m_blocksize);

	int newMap[] = new int[m_mapSize];

	System.arraycopy(m_map, 0, newMap, 0, m_firstFree + nNodes);

	m_map = newMap;
	}

	System.arraycopy(nodes.m_map, 0, m_map, m_firstFree, nNodes);

	m_firstFree += nNodes;
	}

	/**
	* Inserts the specified node in this vector at the specified index.
	* Each component in this vector with an index greater or equal to
	* the specified index is shifted upward to have an index one greater
	* than the value it had previously.
	*/
	public void removeAllElements()
	{

	if (null == m_map)
	return;

	for (int i = 0; i < m_firstFree; i++)
	{
	m_map[i] = DTM.NULL;
	}

	m_firstFree = 0;
	}

	/**
	* Set the length to zero, but don't clear the array.
	*/
	public void RemoveAllNoClear()
	{

	if (null == m_map)
	return;

	m_firstFree = 0;
	}

	/**
	* Removes the first occurrence of the argument from this vector.
	* If the object is found in this vector, each component in the vector
	* with an index greater or equal to the object's index is shifted
	* downward to have an index one smaller than the value it had
	* previously.
	*
	* @param s Node to remove from the list
	*
	* @return True if the node was successfully removed
	*/
	public boolean removeElement(int s)
	{

	if (null == m_map)
	return false;

	for (int i = 0; i < m_firstFree; i++)
	{
	int node = m_map[i];

	if (node == s)
	{
	if (i > m_firstFree)
	System.arraycopy(m_map, i + 1, m_map, i - 1, m_firstFree - i);
	else
	m_map[i] = DTM.NULL;

	m_firstFree--;

	return true;
	}
	}

	return false;
	}

	/**
	* Deletes the component at the specified index. Each component in
	* this vector with an index greater or equal to the specified
	* index is shifted downward to have an index one smaller than
	* the value it had previously.
	*
	* @param i Index of node to remove
	*/
	public void removeElementAt(int i)
	{

	if (null == m_map)
	return;

	if (i > m_firstFree)
	System.arraycopy(m_map, i + 1, m_map, i - 1, m_firstFree - i);
	else
	m_map[i] = DTM.NULL;
	}

	/**
	* Sets the component at the specified index of this vector to be the
	* specified object. The previous component at that position is discarded.
	*
	* The index must be a value greater than or equal to 0 and less
	* than the current size of the vector.
	*
	* @param node Node to set
	* @param index Index of where to set the node
	*/
	public void setElementAt(int node, int index)
	{

	if (null == m_map)
	{
	m_map = new int[m_blocksize];
	m_mapSize = m_blocksize;
	}

	if(index == -1)
	addElement(node);

	m_map[index] = node;
	}

	/**
	* Get the nth element.
	*
	* @param i Index of node to get
	*
	* @return Node at specified index
	*/
	public int elementAt(int i)
	{

	if (null == m_map)
	return DTM.NULL;

	return m_map[i];
	}

	/**
	* Tell if the table contains the given node.
	*
	* @param s Node to look for
	*
	* @return True if the given node was found.
	*/
	public boolean contains(int s)
	{

	if (null == m_map)
	return false;

	for (int i = 0; i < m_firstFree; i++)
	{
	int node = m_map[i];

	if (node == s)
	return true;
	}

	return false;
	}

	/**
	* Searches for the first occurence of the given argument,
	* beginning the search at index, and testing for equality
	* using the equals method.
	*
	* @param elem Node to look for
	* @param index Index of where to start the search
	* @return the index of the first occurrence of the object
	* argument in this vector at position index or later in the
	* vector; returns -1 if the object is not found.
	*/
	public int indexOf(int elem, int index)
	{

	if (null == m_map)
	return -1;

	for (int i = index; i < m_firstFree; i++)
	{
	int node = m_map[i];

	if (node == elem)
	return i;
	}

	return -1;
	}

	/**
	* Searches for the first occurence of the given argument,
	* beginning the search at index, and testing for equality
	* using the equals method.
	*
	* @param elem Node to look for
	* @return the index of the first occurrence of the object
	* argument in this vector at position index or later in the
	* vector; returns -1 if the object is not found.
	*/
	public int indexOf(int elem)
	{

	if (null == m_map)
	return -1;

	for (int i = 0; i < m_firstFree; i++)
	{
	int node = m_map[i];

	if (node == elem)
	return i;
	}

	return -1;
	}

	/**
	* Sort an array using a quicksort algorithm.
	*
	* @param a The array to be sorted.
	* @param lo0 The low index.
	* @param hi0 The high index.
	*
	* @throws Exception
	*/
	public void sort(int a[], int lo0, int hi0) throws Exception
	{

	int lo = lo0;
	int hi = hi0;

	// pause(lo, hi);
	if (lo >= hi)
	{
	return;
	}
	else if (lo == hi - 1)
	{

	/*
	* sort a two element list by swapping if necessary
	*/
	if (a[lo] > a[hi])
	{
	int T = a[lo];

	a[lo] = a[hi];
	a[hi] = T;
	}

	return;
	}

	/*
	* Pick a pivot and move it out of the way
	*/
	int pivot = a[(lo + hi) / 2];

	a[(lo + hi) / 2] = a[hi];
	a[hi] = pivot;

	while (lo < hi)
	{

	/*
	* Search forward from a[lo] until an element is found that
	* is greater than the pivot or lo >= hi
	*/
	while (a[lo] <= pivot && lo < hi)
	{
	lo++;
	}

	/*
	* Search backward from a[hi] until element is found that
	* is less than the pivot, or lo >= hi
	*/
	while (pivot <= a[hi] && lo < hi)
	{
	hi--;
	}

	/*
	* Swap elements a[lo] and a[hi]
	*/
	if (lo < hi)
	{
	int T = a[lo];

	a[lo] = a[hi];
	a[hi] = T;

	// pause();
	}

	// if (stopRequested) {
	// return;
	// }
	}

	/*
	* Put the median in the "center" of the list
	*/
	a[hi0] = a[hi];
	a[hi] = pivot;

	/*
	* Recursive calls, elements a[lo0] to a[lo-1] are less than or
	* equal to pivot, elements a[hi+1] to a[hi0] are greater than
	* pivot.
	*/
	sort(a, lo0, lo - 1);
	sort(a, hi + 1, hi0);
	}

	/**
	* Sort an array using a quicksort algorithm.
	*
	* @throws Exception
	*/
	public void sort() throws Exception
	{
	sort(m_map, 0, m_firstFree - 1);
	}
	}