// Searches for a node with name key, name. If found it returns a reference
        // to the node and to thenodes parent. Else returns null.
        private TTreeNode findParent(string name, ref TTreeNode parent)
        {
            TTreeNode np = root;

            parent = null;
            int cmp;

            while (np != null)
            {
                cmp = String.Compare(name, np.name);
                if (cmp == 0)                   // found !
                {
                    return(np);
                }

                if (cmp < 0)
                {
                    parent = np;
                    np     = np.left;
                }
                else
                {
                    parent = np;
                    np     = np.right;
                }
            }
            return(null);             // Return null to indicate failure to find name
        }
        // Recursively locates an empty slot in the binary tree and inserts the node
        private void add(TTreeNode node, ref TTreeNode tree)
        {
            if (tree == null)
            {
                tree = node;
            }
            else
            {
                // If we find a node with the same name then it's
                // a duplicate and we can't continue
                int comparison = String.Compare(node.name, tree.name);
                if (comparison == 0)
                {
                    throw new Exception();
                }

                if (comparison < 0)
                {
                    add(node, ref tree.left);
                }
                else
                {
                    add(node, ref tree.right);
                }
            }
        }
 // Constructor  to create a single node
 public TTreeNode(string name, double d)
 {
     this.name = name;
     value     = d;
     left      = null;
     right     = null;
 }
 // Recursive destruction of binary search tree, called by method clear
 // and destroy. Can be used to kill a sub-tree of a larger tree.
 // This is a hanger on from its Delphi origins, it might be dispensable
 // given the garbage collection abilities of .NET
 private void killTree(ref TTreeNode p)
 {
     if (p != null)
     {
         killTree(ref p.left);
         killTree(ref p.right);
         p = null;
     }
 }
 /// <summary>
 /// Find the next ordinal node starting at node startNode.
 /// Due to the structure of a binary search tree, the
 /// successor node is simply the left most node on the right branch.
 /// </summary>
 /// <param name="startNode">Name key to use for searching</param>
 /// <param name="parent">Returns the parent node if search successful</param>
 /// <returns>Returns a reference to the node if successful, else null</returns>
 public TTreeNode findSuccessor(TTreeNode startNode, ref TTreeNode parent)
 {
     parent = startNode;
     // Look for the left-most node on the right side
     startNode = startNode.right;
     while (startNode.left != null)
     {
         parent    = startNode;
         startNode = startNode.left;
     }
     return(startNode);
 }
        private double getValue(string name)
        {
            TTreeNode np = findSymbol(name);     // np points to node in tree holding name

            if (np != null)
            {
                return(np.value); // return value of name given the pointer
            }
            else
            {
                throw new Exception("Error: Can''t locate symbol <" + name + ">");
            }
        }
        /// <summary>
        /// Add a symbol to the tree if it's a new one. Returns reference to the new
        /// node if a new node inserted, else returns null to indicate node already present.
        /// </summary>
        /// <param name="name">Name of node to add to tree</param>
        /// <param name="d">Value of node</param>
        /// <returns> Returns reference to the new node is the node was inserted.
        /// If a duplicate node (same name was located then returns null</returns>
        public TTreeNode insert(string name, double d)
        {
            TTreeNode node = new TTreeNode(name, d);

            try {
                if (root == null)
                {
                    root = node;
                }
                else
                {
                    add(node, ref root);
                }
                return(node);
            } catch (Exception) {
                return(null);
            }
        }
        /// <summary>
        /// Add a symbol to the tree if it's a new one. Returns reference to the new
        /// node if a new node inserted, else returns null to indicate node already present.
        /// </summary>
        /// <param name="name">Name of node to add to tree</param>
        /// <param name="d">Value of node</param>
        /// <returns> Returns reference to the new node is the node was inserted.
        /// If a duplicate node (same name was located then returns null</returns>
        public TTreeNode insert(string name, double d)
        {
            TTreeNode node = new TTreeNode(name, d);

            try
            {
                if (root == null)
                {
                    root = node;
                }
                else
                {
                    //Console.WriteLine("llamando add");
                    add(node, ref root);
                }
                _count++;
                return(node);
            }
            catch (Exception)
            {
                return(null);
            }
        }
        // Simple 'drawing' routines
        private string drawNode(TTreeNode node)
        {
            if (node == null)
            {
                return("empty");
            }

            if ((node.left == null) && (node.right == null))
            {
                return(node.name);
            }
            if ((node.left != null) && (node.right == null))
            {
                return(node.name + "(" + drawNode(node.left) + ", _)");
            }

            if ((node.right != null) && (node.left == null))
            {
                return(node.name + "(_, " + drawNode(node.right) + ")");
            }

            return(node.name + "(" + drawNode(node.left) + ", " + drawNode(node.right) + ")");
        }
        /// <summary>
        /// Find name in tree. Return a reference to the node
        /// if symbol found else return null to indicate failure.
        /// </summary>
        /// <param name="name">Name of node to locate</param>
        /// <returns>Returns null if it fails to find the node, else returns reference to node</returns>
        public TTreeNode findSymbol(string name)
        {
            TTreeNode np = root;
            int       cmp;

            while (np != null)
            {
                cmp = String.Compare(name, np.name);
                if (cmp == 0)       // found !
                {
                    return(np);
                }

                if (cmp < 0)
                {
                    np = np.left;
                }
                else
                {
                    np = np.right;
                }
            }
            return(null);   // Return null to indicate failure to find name
        }
Exemplo n.º 11
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		// Recursive destruction of binary search tree, called by method clear
		// and destroy. Can be used to kill a sub-tree of a larger tree.
		// This is a hanger on from its Delphi origins, it might be dispensable
		// given the garbage collection abilities of .NET
        private void killTree (ref TTreeNode p) {
           if (p != null) {
             killTree (ref p.left);
             killTree (ref p.right);
             p = null;
		   }
        }
Exemplo n.º 12
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     	public TBinarySTree()
		{
		    root = null;
			// nodeList is a shortcut to the nodes on the tree
		    nodeList = new ArrayList();
		}
Exemplo n.º 13
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        // Constructor  to create a single node 
		public TTreeNode (string name, double d) {
              this.name = name;
              value = d;
              left = null;
              right = null;
           }
Exemplo n.º 14
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		// Simple 'drawing' routines
		private string drawNode (TTreeNode node) {
			if (node == null)
				return "empty";

			if ((node.left == null) && (node.right == null))
				return node.name;
			if ((node.left != null) && (node.right == null))
				return node.name + "(" + drawNode (node.left) + ", _)";
			
			if ((node.right != null) && (node.left == null))
				return node.name + "(_, " + drawNode (node.right) + ")";

			return node.name + "(" + drawNode (node.left) + ", " + drawNode (node.right) + ")";
		}
Exemplo n.º 15
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		/// <summary>
		/// Delete a given node. This is the more complex method in the binary search
		/// class. The method considers three senarios, 1) the deleted node has no
		/// children; 2) the deleted node as one child; 3) the deleted node has two
		/// children. Case one and two are relatively simple to handle, the only
		/// unusual considerations are when the node is the root node. Case 3) is
		/// much more complicated. It requires the location of the successor node.
		/// The node to be deleted is then replaced by the sucessor node and the
		/// successor node itself deleted. Throws an exception if the method fails
		/// to locate the node for deletion.
		/// </summary>
		/// <param name="key">Name key of node to delete</param>
		public void delete (string key) {
			TTreeNode parent = null;
			// First find the node to delete and its parent
			TTreeNode nodeToDelete = findParent (key, ref parent);
			if (nodeToDelete == null) 
				throw new Exception ("Unable to delete node: " + key.ToString());  // can't find node, then say so 
			
			// Three cases to consider, leaf, one child, two children

			// If it is a simple leaf then just null what the parent is pointing to
			if ((nodeToDelete.left == null) && (nodeToDelete.right == null)) {
				if (parent == null) {
					root = null;
					return;
				}

				// find out whether left or right is associated 
				// with the parent and null as appropriate
				if (parent.left == nodeToDelete)
					parent.left = null;
				else
					parent.right = null;
				return;
			}

			// One of the children is null, in this case
			// delete the node and move child up
			if (nodeToDelete.left == null) {
				// Special case if we're at the root
				if (parent == null) {
					root = nodeToDelete.right;
					return;
				}

				// Identify the child and point the parent at the child
				if (parent.left == nodeToDelete)
                    parent.right = nodeToDelete.right;
				else 
					parent.left = nodeToDelete.right;
				nodeToDelete = null; // Clean up the deleted node
				return;
			}

			// One of the children is null, in this case
			// delete the node and move child up
			if (nodeToDelete.right == null) {
				// Special case if we're at the root			
				if (parent == null) {
					root = nodeToDelete.left;
					return;
				}

				// Identify the child and point the parent at the child
				if (parent.left == nodeToDelete)
					parent.left = nodeToDelete.left;
				else 
					parent.right = nodeToDelete.left;
				nodeToDelete = null; // Clean up the deleted node
				return;
			}

			// Both children have nodes, therefore find the successor, 
			// replace deleted node with successor and remove successor
			// The parent argument becomes the parent of the successor
			TTreeNode successor = findSuccessor (nodeToDelete, ref parent);
			// Make a copy of the successor node
			TTreeNode tmp = new TTreeNode (successor.name, successor.value);
			// Find out which side the successor parent is pointing to the
			// successor and remove the successor
			if (parent.left == successor)
				parent.left = null;
			else
				parent.right = null;

			// Copy over the successor values to the deleted node position
			nodeToDelete.name = tmp.name;
			nodeToDelete.value = tmp.value;
		}
Exemplo n.º 16
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		/// <summary>
		/// Find the next ordinal node starting at node startNode.
		/// Due to the structure of a binary search tree, the
		/// successor node is simply the left most node on the right branch.
		/// </summary>
		/// <param name="startNode">Name key to use for searching</param>
		/// <param name="parent">Returns the parent node if search successful</param>
		/// <returns>Returns a reference to the node if successful, else null</returns>
		public TTreeNode findSuccessor (TTreeNode startNode, ref TTreeNode parent) {
			parent = startNode;
			// Look for the left-most node on the right side
			startNode = startNode.right; 
			while (startNode.left != null) {
				parent = startNode;
				startNode = startNode.left;
			}
			return startNode;
		}
Exemplo n.º 17
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		// Searches for a node with name key, name. If found it returns a reference
		// to the node and to thenodes parent. Else returns null.
		private TTreeNode findParent (string name, ref TTreeNode parent) {
			TTreeNode np = root;
			parent = null;
			int cmp;
			while (np != null) {
				cmp = String.Compare (name, np.name);
				if (cmp == 0)   // found !
					return np;

				if (cmp < 0) { 
					parent = np;
					np = np.left;
				}
				else {
					parent = np;
					np = np.right;
				}
			}
			return null;  // Return null to indicate failure to find name
		}
Exemplo n.º 18
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		/// <summary>
		/// Add a symbol to the tree if it's a new one. Returns reference to the new
		/// node if a new node inserted, else returns null to indicate node already present.
		/// </summary>
		/// <param name="name">Name of node to add to tree</param>
		/// <param name="d">Value of node</param>
		/// <returns> Returns reference to the new node is the node was inserted.
		/// If a duplicate node (same name was located then returns null</returns>
		public TTreeNode insert (string name, double d) {
            TTreeNode node = new TTreeNode(name, d);
			try {  
				if (root == null) 
					root = node;
				else
					add (node, ref root); 
				return node;
			} catch (Exception) {
				return null;
			}
		}
Exemplo n.º 19
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	    // Recursively locates an empty slot in the binary tree and inserts the node
		private void add (TTreeNode node, ref TTreeNode tree) {
		  if (tree == null) 
		     tree = node;
		  else {
			  // If we find a node with the same name then it's 
			  // a duplicate and we can't continue
			  int comparison = String.Compare (node.name, tree.name);
			  if (comparison == 0) 
				  throw new Exception ();
             
			  if (comparison < 0) { 
                 add (node, ref tree.left);
             } else {
                 add (node, ref tree.right);
             }
             nodeList.Add (node);
   		  }
		}
 public TBinarySTree()
 {
     root = null;
     // nodeList is a shortcut to the nodes on the tree
     nodeList = new ArrayList();
 }
 public TBinarySTree()
 {
     root   = null;
     _count = 0;
 }
Exemplo n.º 22
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     	public TBinarySTree()
		{
		    root = null;
			_count = 0;
		}
        /// <summary>
        /// Delete a given node. This is the more complex method in the binary search
        /// class. The method considers three senarios, 1) the deleted node has no
        /// children; 2) the deleted node as one child; 3) the deleted node has two
        /// children. Case one and two are relatively simple to handle, the only
        /// unusual considerations are when the node is the root node. Case 3) is
        /// much more complicated. It requires the location of the successor node.
        /// The node to be deleted is then replaced by the sucessor node and the
        /// successor node itself deleted. Throws an exception if the method fails
        /// to locate the node for deletion.
        /// </summary>
        /// <param name="key">Name key of node to delete</param>
        public void delete(string key)
        {
            TTreeNode parent = null;
            // First find the node to delete and its parent
            TTreeNode nodeToDelete = findParent(key, ref parent);

            if (nodeToDelete == null)
            {
                throw new Exception("Unable to delete node: " + key.ToString());                   // can't find node, then say so
            }
            // Three cases to consider, leaf, one child, two children

            // If it is a simple leaf then just null what the parent is pointing to
            if ((nodeToDelete.left == null) && (nodeToDelete.right == null))
            {
                if (parent == null)
                {
                    root = null;
                    return;
                }

                // find out whether left or right is associated
                // with the parent and null as appropriate
                if (parent.left == nodeToDelete)
                {
                    parent.left = null;
                }
                else
                {
                    parent.right = null;
                }
                _count--;
                return;
            }

            // One of the children is null, in this case
            // delete the node and move child up
            if (nodeToDelete.left == null)
            {
                // Special case if we're at the root
                if (parent == null)
                {
                    root = nodeToDelete.right;
                    return;
                }

                // Identify the child and point the parent at the child
                if (parent.left == nodeToDelete)
                {
                    parent.right = nodeToDelete.right;
                }
                else
                {
                    parent.left = nodeToDelete.right;
                }
                nodeToDelete = null;                 // Clean up the deleted node
                _count--;
                return;
            }

            // One of the children is null, in this case
            // delete the node and move child up
            if (nodeToDelete.right == null)
            {
                // Special case if we're at the root
                if (parent == null)
                {
                    root = nodeToDelete.left;
                    return;
                }

                // Identify the child and point the parent at the child
                if (parent.left == nodeToDelete)
                {
                    parent.left = nodeToDelete.left;
                }
                else
                {
                    parent.right = nodeToDelete.left;
                }
                nodeToDelete = null;                 // Clean up the deleted node
                _count--;
                return;
            }

            // Both children have nodes, therefore find the successor,
            // replace deleted node with successor and remove successor
            // The parent argument becomes the parent of the successor
            TTreeNode successor = findSuccessor(nodeToDelete, ref parent);
            // Make a copy of the successor node
            TTreeNode tmp = new TTreeNode(successor.name, successor.value);

            // Find out which side the successor parent is pointing to the
            // successor and remove the successor
            if (parent.left == successor)
            {
                parent.left = null;
            }
            else
            {
                parent.right = null;
            }

            // Copy over the successor values to the deleted node position
            nodeToDelete.name  = tmp.name;
            nodeToDelete.value = tmp.value;
            _count--;
        }