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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;
}
share|improve this question

closed as too localized by Hans Passant, Brad Werth, hims056, poke, Michal Klouda Nov 29 '12 at 12:40

This question is unlikely to help any future visitors; it is only relevant to a small geographic area, a specific moment in time, or an extraordinarily narrow situation that is not generally applicable to the worldwide audience of the internet. For help making this question more broadly applicable, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

    
You are badly mixing up both the syntax and semantics of .NET generics with native C++ templates. Talk to your teacher, this is almost certainly not what you should be doing. –  Hans Passant Nov 29 '12 at 1:53
    
Well, I've got the error list down to the edited list above by fixing the mistake on instantiation of the Node<T> class to the above from "Node<T> newNode = gcnew Node<T>(5)" duh, and by adding the condition where T : IComparable , IEquatable<T> to the Node Class and BinarySearchTree class. It looks like the only problem I'm still having is to deal with the <= operator. –  deadEddie Nov 29 '12 at 2:48

1 Answer 1

up vote 0 down vote accepted

The comparison operators are not available for use with generics. There's no interface that defines them, and unlike C++ templates, the compiler doesn't know all the types that will be used.

The thing you want is IComparable<T>. This interface defines the method CompareTo(T), which will return a negative number, zero, or a positive number if the first object is less than, equal to, or greater than the other one, respectively. (That can be a little hard to remember, so remember this: (x [symbol] y) turns into (x.CompareTo(y) [symbol] 0).)

Given a general type T, you don't know whether T actually implements IComparable<T> or not. What you want to do is force the compiler to only allow classes that implement IComparable<T>.

generic <typename T> where T : IComparable<T> ref class Node { ... };
generic <typename T> where T : IComparable<T> ref class BinarySearchTreeClass { ... };

Now you can use the CompareTo method in your class:

if (node->data->CompareTo(key) < 0)
    return lookUp(node->right, key);
else
    return lookUp(node->left, key);

A couple other minor syntax issues:

generic <typename T> ref class Node<T>: Don't need Node<T>, just Node. The Node class is generic already because of the generic <typename T>, you don't need the <T> as well.

Node<T>(){}: You don't need the <T>. The constructor of a generic class is already generic, you don't need to specify it again.

share|improve this answer
    
Thanks David! :) –  deadEddie Nov 29 '12 at 16:46
    
Edited original code samples above to reflect changes for anyone looking for a very basic example of a generic Binary Search Tree in managed C++. Works like a champ. –  deadEddie Nov 29 '12 at 17:27

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