I created a small BST project in managed C++ for school. Worked well, but now I'm trying to figure out how to do the same project using generics (first project used int). For the life of me I cannot see what I'm fundamentally screwing up. Hoping for direction.

GenericNodeClass.h:

```
/*
GenericNodeClass.h. Created by Ed Thompson for IS375, C++ Intermediate, City University
of Seattle.
GenericNodeClass.h provides for members for creation of a generic binary tree
*/
#pragma once
#include "stdafx.h"
#include <iostream>
#include <deque>
#include <climits>
using namespace std;
using namespace System;
using namespace System::Collections;
using namespace System::Collections::Generic;
generic <typename T> where T : IComparable<T>, IEquatable<T>
ref class Node
{
public:
T data;
T parent;
Node<T> ^ left;
Node<T> ^ right;
// Constructor that takes one parameter:
// a T, representing the value of a new node
Node(T n)
{
data = n;
}
};
```

BinarySearchTreeClass.h

```
#include "stdafx.h"
#include <iostream>
#include <deque>
#include <climits>
#include "GenericNodeClass.h"
using namespace std;
using namespace System;
using namespace System::Collections;
using namespace System::Collections::Generic;
generic <typename T> where T : IComparable<T> , IEquatable<T>
ref class BinarySearchTreeClass
{
public:
Node<T>^ rootNode;
T _p;
// constructors
// default
BinarySearchTreeClass(){}
BinarySearchTreeClass(T t)
{
// create a new Node in the Binary Search Tree
rootNode = gcnew Node<T> (t);
}
// method to return a node if it exists in the tree
// takes two parameters: an instance of the Node class, and a
// value representing the value of the node to be looked up
Node<T> ^ lookUp(Node<T> ^node, T key)
{
if(node == nullptr)
return node;
if(node->data == key)
return node;
else
{
if (node->data->CompareTo(key) < 0)
return lookUp(node->right, key);
else
return lookUp(node->left, key);
}
}
// method to create new node. Method takes two parameters:
// a parameter of the value for the node data, and a value
// for the node's parent.
Node<T> ^newNode(T key, T parent)
{
Node<T> ^node = gcnew Node<T>(key);
node->data = key;
node->left = nullptr;
node->right = nullptr;
node->parent = parent;
return node;
}
// insertNode method inserts a new node into an existing
// Binary Search Tree. This method takes two parameters:
// an instance of Node<T> (node), and a value of T,
// representing the value of the node being inserted
Node<T> ^insertNode(Node<T> ^node, T input)
{
Node<T> ^returnNode;
if (node != nullptr)
_p = node->data;
// if the node is non-existant, create a new node
// with the value of the parameter 'input' and the
// value of the new node's parent (_p).
if (node == nullptr)
{
// pass class variable _p to set value
// of the new node's parent value.
returnNode = newNode(input, _p);
return returnNode;
}
// if the input parameter value is less than
// or equal to the node value, insert node using
// the left hand node leaf of the current node
// as starting point
if (input->CompareTo(node->data) < 0)
{
// set variable p to value of node->data value (this
// will be the parent of the new node)
_p = node->data;
node->left = insertNode(node->left, input);
}
// if the input parameter value is greater than
// the node value, insert node using the right hand
// node leaf of the current node as starting point
else
{
_p = node->data;
node->right = insertNode(node->right, input);
}
return node;
}
// method to find the left most node in a Binary Search Tree
// takes an instance of Node<T> as parameter
Node<T> ^leftMost(Node<T> ^node)
{
if (node == nullptr)
return nullptr;
while (node->left != nullptr)
node = leftMost(node->left);
return node;
}
// method of return the right most node in a Binary Search Tree
// takes an instance of Node<T> as parameter
Node<T> ^rightMost(Node<T> ^node)
{
if (node == nullptr)
return nullptr;
while (node->right != nullptr)
node = rightMost(node->right);
return node;
}
// method to return the size of a Binary Tree
// takes an instance of Node<T> as parameter
int treeSize(Node<T> ^node)
{
if(node == nullptr || node->left == nullptr && node->right == nullptr)
return 0;
else
return treeSize(node->left) + 1 + treeSize(node->right);
}
// method that prints to console the value of each node from lowest to highest
// takes an instance of Node<T> as parameter
void printTreeInOrder(Node<T> ^node)
{
if (node != nullptr)
{
printTreeInOrder(node->left);
Console::WriteLine(node->data);
printTreeInOrder(node->right);
}
}
// method that prints to console a graphic representation of a binary tree
// takes an instance of Node<T> as parameter
void printGraphicRepresentation(Node<T> ^node)
{
// the width of the tree is the max height /2 (?)
// need to know how wide the tree is
// At treeWidth / 2, print node
// on new line, at nodePosition - 1, if node has a left, print a "/"
// on same line, at nodePosition + 1, if node has a right, print a "\"
}
// method that prints to console all members of a given node
// takes an instance of Node<T> as parameter
void printNodeMembers(Node<T> ^node)
{
Console::WriteLine("Members of Node " + node->data + " include: ");
if (node->parent != nullptr)
Console::WriteLine("Parent: " + node->parent);
else
Console::WriteLine("This node has no parent.");
if (node->left != nullptr)
Console::WriteLine("Left-member: " + node->left->data);
else
Console::WriteLine("This node has no left-member.");
if (node->right != nullptr)
Console::WriteLine("Right-Member: " + node->right->data);
else
Console::WriteLine("This node has no right-member.");
}
};
```

TestClass.cpp

```
#include "stdafx.h"
#include "GenericNodeClass.h"
#include "BinarySearchTreeClass.h"
#include <iostream>
using namespace std;
using namespace System;
using namespace System::IO;
using namespace System::Collections::Generic;
int main ()
{
BinarySearchTreeClass<int>^ BTree = gcnew BinarySearchTreeClass<int>();
// instantiate new Node instance with starter value
Node<int> ^rootNode = gcnew Node<int>(5);
// insert additional nodes
BTree->insertNode(rootNode, 3);
BTree->insertNode(rootNode, 7);
BTree->insertNode(rootNode, 4);
BTree->insertNode(rootNode, 6);
BTree->insertNode(rootNode, 2);
BTree->insertNode(rootNode, 9);
BTree->insertNode(rootNode, 1);
BTree->insertNode(rootNode, 8);
BTree->insertNode(rootNode, 0);
BTree->insertNode(rootNode, 10);
BTree->insertNode(rootNode, 12);
BTree->insertNode(rootNode, 11);
Console::WriteLine("The value of the left-most node in this tree is: " + BTree->leftMost(rootNode)->data);
Console::WriteLine("The value of the right-most node in this tree is: " + BTree->rightMost(rootNode)->data);
Console::WriteLine("The size of this Binary Search Tree is: " + BTree->treeSize(rootNode));
Console::WriteLine("Printing Binary Search Tree in order: ");
BTree->printTreeInOrder(rootNode);
// TO EXAMINE THE PROPERTIES OF A GIVEN NODE, CHANGE THE SECOND PARAMETER OF
// THE lookUp METHOD IN THE FOLLOWING LINE OF CODE TO THE NODE DESIRED TO BE EXAMINED
BTree->printNodeMembers(BTree->lookUp(rootNode, 7));
Console::WriteLine();
return 0;
}
```