package weiss.nonstandard;
// BinarySearchTree class
//
// CONSTRUCTION: with no initializer
//
// ******************PUBLIC OPERATIONS*********************
// void insert( x ) --> Insert x
// void remove( x ) --> Remove x
// void removeMin( ) --> Remove minimum item
// Comparable find( x ) --> Return item that matches x
// Comparable findMin( ) --> Return smallest item
// Comparable findMax( ) --> Return largest item
// boolean isEmpty( ) --> Return true if empty; else false
// void makeEmpty( ) --> Remove all items
// ******************ERRORS********************************
// Exceptions are thrown by insert, remove, and removeMin if warranted
/**
* Implements an unbalanced binary search tree.
* Note that all "matching" is based on the compareTo method.
* @author Mark Allen Weiss
*/
public class BinarySearchTree<AnyType extends Comparable<? super AnyType>>
{
/**
* Construct the tree.
*/
public BinarySearchTree( )
{
root = null;
}
/**
* Insert into the tree.
* @param x the item to insert.
* @throws DuplicateItemException if x is already present.
*/
public void insert( AnyType x )
{
root = insert( x, root );
}
/**
* Remove from the tree..
* @param x the item to remove.
* @throws ItemNotFoundException if x is not found.
*/
public void remove( AnyType x )
{
root = remove( x, root );
}
/**
* Remove minimum item from the tree.
* @throws ItemNotFoundException if tree is empty.
*/
public void removeMin( )
{
root = removeMin( root );
}
/**
* Find the smallest item in the tree.
* @return smallest item or null if empty.
*/
public AnyType findMin( )
{
return elementAt( findMin( root ) );
}
/**
* Find the largest item in the tree.
* @return the largest item or null if empty.
*/
public AnyType findMax( )
{
return elementAt( findMax( root ) );
}
/**
* Find an item in the tree.
* @param x the item to search for.
* @return the matching item or null if not found.
*/
public AnyType find( AnyType x )
{
return elementAt( find( x, root ) );
}
/**
* Make the tree logically empty.
*/
public void makeEmpty( )
{
root = null;
}
/**
* Test if the tree is logically empty.
* @return true if empty, false otherwise.
*/
public boolean isEmpty( )
{
return root == null;
}
/**
* Internal method to get element field.
* @param t the node.
* @return the element field or null if t is null.
*/
private AnyType elementAt( BinaryNode<AnyType> t )
{
return t == null ? null : t.element;
}
/**
* Internal method to insert into a subtree.
* @param x the item to insert.
* @param t the node that roots the tree.
* @return the new root.
* @throws DuplicateItemException if x is already present.
*/
protected BinaryNode<AnyType> insert( AnyType x, BinaryNode<AnyType> t )
{
if( t == null )
t = new BinaryNode<AnyType>( x );
else if( x.compareTo( t.element ) < 0 )
t.left = insert( x, t.left );
else if( x.compareTo( t.element ) > 0 )
t.right = insert( x, t.right );
else
throw new DuplicateItemException( x.toString( ) ); // Duplicate
return t;
}
/**
* Internal method to remove from a subtree.
* @param x the item to remove.
* @param t the node that roots the tree.
* @return the new root.
* @throws ItemNotFoundException if x is not found.
*/
protected BinaryNode<AnyType> remove( AnyType x, BinaryNode<AnyType> t )
{
if( t == null )
throw new ItemNotFoundException( x.toString( ) );
if( x.compareTo( t.element ) < 0 )
t.left = remove( x, t.left );
else if( x.compareTo( t.element ) > 0 )
t.right = remove( x, t.right );
else if( t.left != null && t.right != null ) // Two children
{
t.element = findMin( t.right ).element;
t.right = removeMin( t.right );
}
else
t = ( t.left != null ) ? t.left : t.right;
return t;
}
/**
* Internal method to remove minimum item from a subtree.
* @param t the node that roots the tree.
* @return the new root.
* @throws ItemNotFoundException if t is empty.
*/
protected BinaryNode<AnyType> removeMin( BinaryNode<AnyType> t )
{
if( t == null )
throw new ItemNotFoundException( );
else if( t.left != null )
{
t.left = removeMin( t.left );
return t;
}
else
return t.right;
}
/**
* Internal method to find the smallest item in a subtree.
* @param t the node that roots the tree.
* @return node containing the smallest item.
*/
protected BinaryNode<AnyType> findMin( BinaryNode<AnyType> t )
{
if( t != null )
while( t.left != null )
t = t.left;
return t;
}
/**
* Internal method to find the largest item in a subtree.
* @param t the node that roots the tree.
* @return node containing the largest item.
*/
private BinaryNode<AnyType> findMax( BinaryNode<AnyType> t )
{
if( t != null )
while( t.right != null )
t = t.right;
return t;
}
/**
* Internal method to find an item in a subtree.
* @param x is item to search for.
* @param t the node that roots the tree.
* @return node containing the matched item.
*/
private BinaryNode<AnyType> find( AnyType x, BinaryNode<AnyType> t )
{
while( t != null )
{
if( x.compareTo( t.element ) < 0 )
t = t.left;
else if( x.compareTo( t.element ) > 0 )
t = t.right;
else
return t; // Match
}
return null; // Not found
}
/** The tree root. */
protected BinaryNode<AnyType> root;
// Test program
public static void main( String [ ] args )
{
BinarySearchTree<Integer> t = new BinarySearchTree<Integer>( );
final int NUMS = 4000;
final int GAP = 37;
System.out.println( "Checking... (no more output means success)" );
for( int i = GAP; i != 0; i = ( i + GAP ) % NUMS )
t.insert( i );
for( int i = 1; i < NUMS; i += 2 )
t.remove( i );
if( t.findMin( ) != 2 || t.findMax( ) != NUMS - 2 )
System.out.println( "FindMin or FindMax error!" );
for( int i = 2; i < NUMS; i += 2 )
if( t.find( i ) != i )
System.out.println( "Find error1!" );
for( int i = 1; i < NUMS; i += 2 )
if( t.find( i ) != null )
System.out.println( "Find error2!" );
}
}