BST

What I've Written, I may not change,but can someone help with the 4 functions I made comments for?


class BST
{
public:
    TreeNode* root;

    //member functions

    BST() {
        root = NULL;
    }

    bool isTreeEmpty()
    {
        if (root == NULL)
            return true;   //the tree is empty
        else
            return false;  //the tree is not empty
    }

    void insertNode(TreeNode* new_node) {
        if (root == NULL) {
            root = new_node;
         } //insert the root node
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (new_node->value == temp->value) {
                    cout << "Value Already exist," <<
                        "Insert another value!" << endl;
                    return;
                }
                else if ((new_node->value < temp->value) && (temp->left == NULL)) {
                    temp->left = new_node;  //insert value to the left
                    break;
                }
                else if (new_node->value < temp->value) {
                    temp = temp->left;
                }
                else if ((new_node->value > temp->value) && (temp->right == NULL)) {
                    temp->right = new_node;  //insert value to the right
                    break;
                }
                else {
                    temp = temp->right;
                }
            }
        }
    } //insertNode

    int heightOfTree(TreeNode* r)

    {
           //determine height of tree
           //return value to calling procedure

    }
    };


    void printPreorder(TreeNode* r) //(current node, Left, Right)
    {
          //provide the code for the preorder binary tree traversal function 
	  //print the results to the console
 
    }//printPreorder

    void printInorder(TreeNode* r) //  (Left, current node, Right)
    {
        //provide the code for the inorder binary tree traversal function 
        //print the results to the console

    } //printInorder

    void printPostorder(TreeNode* r) //left, right, root
    {
          //provide the code for the postorder binary tree traversal function 
	  //print the results to the console

    }// printPostorder

    TreeNode *searchForNode(int v) {
        if (root == NULL) {
            return root;
        }
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (v == temp->value) {
                    return temp;
                }
                else if (v < temp->value) {
                    temp = temp->left;
                }
                else {
                    temp = temp->right;
                }
            }
            return NULL;
        }
    }

    TreeNode* minValueNode(TreeNode* node) {
        TreeNode* current = node;
        /* loop down to find the leftmost leaf */
        while (current->left != NULL) {
            current = current->left;
        }
        return current;
    }



    TreeNode* deleteNode(TreeNode* r, int v) {
        // base case
        if (r == NULL) {
            return NULL;
        }
        // If the key to be deleted is smaller than the root's key,
        // then it lies in left subtree
        else if (v < r->value) {
            r->left = deleteNode(r->left, v);
        }
        // If the key to be deleted is greater than the root's key,
        // then it lies in right subtree
        else if (v > r->value) {
            r->right = deleteNode(r->right, v);
        }
        // if key is same as root's key, then This is the node to be deleted
        else {
            // node with only one child or no child
            if (r->left == NULL) {
                TreeNode* temp = r->right;
                delete r;
                return temp;
            }
            else if (r->right == NULL) {
                TreeNode* temp = r->left;
                delete r;
                return temp;
            }
            else {
                // node with two children: Get the inorder successor (smallest
                // in the right subtree)
                TreeNode* temp = minValueNode(r->right);
                // Copy the inorder successor's content to this node
                r->value = temp->value;
                // Delete the inorder successor
                r->right = deleteNode(r->right, temp->value);
                //deleteNode(r->right, temp->value);
            }
        }
        return r;
    }

    void readFromFileData(string thePath) {
        //Open text file and read data into an array
		//Do not change anything
        fstream myFile(thePath + "data.txt", ios_base::in);
        int nextVal;
        if (myFile.is_open()) {
            string tp;
            while (getline(myFile, tp)) {
                myFile >> nextVal;
                TreeNode* new_node = new TreeNode(); //create the instance in the heap-memory (pointer) - can be seen global and stays in memory
                new_node->value = nextVal;
                insertNode(new_node);
            }
        }
    }

}; //BST = binary search tree - nodes are added at the end of the tree (lowest level)


int main()
{
	//do not change anything in main()
    string thePath = "C:\\data\\";

    BST obj;
    int option, val;

    //Open text file and read data to test with
    fstream myFileTest(thePath + "datatest.txt", ios_base::in);
    int searchForNode1, searchForNode2, nodeToDelete;

    myFileTest >> searchForNode1 >> searchForNode2 >> nodeToDelete;

    cout << "Sorted Binary Trees!\n";

    cout << "MENU \n \n";

    do {

        cout << "\n\n";
        cout << "Choose an option, 0 to stop \n";
        cout << " 1. Read Nodes from file \n";
        cout << " 2. Search Node \n";
        cout << " 3. Delete Node \n";
        cout << " 4. Print BST values \n";
        cout << " 5. Height of tree \n";
        cout << " 6. Clear the screen \n";
        cout << " 0. Exit \n";

        cin >> option;
        TreeNode* new_node = new TreeNode(); //create the instance in the heap-memory (pointer) - can be seen global and stays in memory

        switch (option) {
        case 0:
			break;
        case 1:
            obj.readFromFileData(thePath);  //read the initial values from a text file C:\\data\\data.txt
            break;
        case 2:
            //search for first node
            cout << "SEARCH FOR " << searchForNode1 << " \n";

			val =  searchForNode1;

            new_node = obj.searchForNode(val);              //iterative search
            //new_node = obj.searchForNodeIt(obj.root,val)  //recursive search - you can decide whether you want to do an iterative or recursive search
            if (new_node != NULL) {
                cout << " Value found \n";
            }
            else {
                cout << " Value not found \n";
            }

            //search for second node
            cout << "SEARCH FOR " << searchForNode2 << " \n";
            val = searchForNode2;

            new_node = obj.searchForNode(val);              //iterative search
            //new_node = obj.searchForNodeIt(obj.root,val)  //recursive search - you may decide between iterative and recursive search
            if (new_node != NULL) {
                cout << " Value found \n";
            }
            else {
                cout << " Value not found \n";
            }
			break;

        case 3:
            cout << "DELETE NODE " << nodeToDelete << " \n"; break;
            val = nodeToDelete;
            new_node = obj.searchForNode(val);
            if (new_node != NULL) {
                obj.deleteNode(obj.root, val);
                cout << "OBJECT DELETED \n";
            }
            else {
                cout << "OBJECT NOT FOUND \n";
            }
            break;

        case 4:
            cout << "PRINT BST VALUES \n";
            //obj.print2D(obj.root, 5);

            cout << "PRINT INORDER TRAVERSAL\n";
            obj.printInorder(obj.root);
            cout << "\n\n";

            cout << "PRINT PREORDER TRAVERSAL\n";
            obj.printPreorder(obj.root);
            cout << "\n\n";

            cout << "PRINT POSTORDER TRAVERSAL \n";
            obj.printPostorder(obj.root);
            cout << "\n\n";
            break;

        case 5:
            cout << "HEIGHT OF TREE \n";
            cout << obj.heightOfTree(obj.root);
            cout << "\n\n";
            break;

        case 6:
			system("cls");
			break;

		default:
			cout << "Select from the menu \n";
			break;
        }

    } while (option != 0);

    return 0;
}

anonomyss (32)

#include <iostream>
#include <fstream>
#include <string>
#include<vector>

using namespace std;

class TreeNode
{
//keep this class as is
public:

    int value;          //key or data
    TreeNode* left;
    TreeNode* right;

    //constructors

    TreeNode() {
        value = 0;
        left = NULL;
        right = NULL;
    } //default constructor

    TreeNode(int v) {
        value = v;
        left = NULL;
        right = NULL;
    } //parametrized constructor

}; //TreeNode

the first part

seeplus (6590)

Well for traversals, you use something like in general (NOT tried)

void printInorder(TreeNode* root) {
   if (root) {
      printInorder(root->left);
      std::cout << root->data << " ";
      printInorder(root->right);
   }
}

and similar for pre-order and post-order:

void printPreorder(TreeNode *root) {
   if (root) {
      std::cout << root->data << " ";
      printPreorder(root->left);
      printPreorder(root->right);
   }
}

void printPostorder(TreeNode *root) {
  if (root) {
      printPostorder(root->left);
      printPostorder(root->right);
      std::cout << root->data << " ";
   }
}

The difference between these is the ordering of the 2 recursive calls and the std::cout statement.

Also in C++ use nullptr instead of NULL.

bool isTreeEmpty()
    {
        if (root == NULL)
            return true;   //the tree is empty
        else
            return false;  //the tree is not empty
    }

becomes:

1
2

bool isTreeEmpty() {
    return root == nullptr;

Re tree height. This is done similar to displaying a tree. Something like [NOT tried]:

1
2
3

int heightOfTree(TreeNode* root) {
    return root ? 1 + std::max(heightOfTree(root->left), heightOfTree(root->right)) : 0;
}

Last edited on

seeplus (6590)

Also note that BST should have a destructor that removes all nodes and frees all allocated memory.

There are no copy constructor and copy assignment provided. If these are not needed for this exercise then to avoid unwanted incorrect copies/assignments being done (default is a shallow copy whereas a deep copy is required) then these should be defined and marked as deleted. Something like:

1
2
3

BST (const BST&) = delete;
BST (BST&&) = delete;
BST& operator=(BST) = delete;

anonomyss (32)

int main()
{
	//do not change anything in main()
    string thePath = "C:\\data\\";

    BST obj;
    int option, val;

    //Open text file and read data to test with
    fstream myFileTest(thePath + "datatest.txt", ios_base::in);
    int searchForNode1, searchForNode2, nodeToDelete;

    myFileTest >> searchForNode1 >> searchForNode2 >> nodeToDelete;

    cout << "Sorted Binary Trees!\n";

    cout << "MENU \n \n";

    do {

        cout << "\n\n";
        cout << "Choose an option, 0 to stop \n";
        cout << " 1. Read Nodes from file \n";
        cout << " 2. Search Node \n";
        cout << " 3. Delete Node \n";
        cout << " 4. Print BST values \n";
        cout << " 5. Height of tree \n";
        cout << " 6. Clear the screen \n";
        cout << " 0. Exit \n";

        cin >> option;
        TreeNode* new_node = new TreeNode(); //create the instance in the heap-memory (pointer) - can be seen global and stays in memory

        switch (option) {
        case 0:
			break;
        case 1:
            obj.readFromFileData(thePath);  //read the initial values from a text file C:\\data\\data.txt
            break;
        case 2:
            //search for first node
            cout << "SEARCH FOR " << searchForNode1 << " \n";

			val =  searchForNode1;

            new_node = obj.searchForNode(val);              //iterative search
            //new_node = obj.searchForNodeIt(obj.root,val)  //recursive search - you can decide whether you want to do an iterative or recursive search
            if (new_node != NULL) {
                cout << " Value found \n";
            }
            else {
                cout << " Value not found \n";
            }

            //search for second node
            cout << "SEARCH FOR " << searchForNode2 << " \n";
            val = searchForNode2;

            new_node = obj.searchForNode(val);              //iterative search
            //new_node = obj.searchForNodeIt(obj.root,val)  //recursive search - you may decide between iterative and recursive search
            if (new_node != NULL) {
                cout << " Value found \n";
            }
            else {
                cout << " Value not found \n";
            }
			break;

        case 3:
            cout << "DELETE NODE " << nodeToDelete << " \n"; break;
            val = nodeToDelete;
            new_node = obj.searchForNode(val);
            if (new_node != NULL) {
                obj.deleteNode(obj.root, val);
                cout << "OBJECT DELETED \n";
            }
            else {
                cout << "OBJECT NOT FOUND \n";
            }
            break;

        case 4:
            cout << "PRINT BST VALUES \n";
            //obj.print2D(obj.root, 5);

            cout << "PRINT INORDER TRAVERSAL\n";
            obj.printInorder(obj.root);
            cout << "\n\n";

            cout << "PRINT PREORDER TRAVERSAL\n";
            obj.printPreorder(obj.root);
            cout << "\n\n";

            cout << "PRINT POSTORDER TRAVERSAL \n";
            obj.printPostorder(obj.root);
            cout << "\n\n";
            break;

        case 5:
            cout << "HEIGHT OF TREE \n";
            cout << obj.heightOfTree(obj.root);
            cout << "\n\n";
            break;

        case 6:
			system("cls");
			break;

		default:
			cout << "Select from the menu \n";
			break;
        }

    } while (option != 0);

    return 0;
}

and

class BST
{
public:
    TreeNode* root;

    //member functions

    BST() {
        root = NULL;
    }

    bool isTreeEmpty()
    {
       return root == nullptr;
    }

    void insertNode(TreeNode* new_node) {
        if (root == NULL) {
            root = new_node;
         } //insert the root node
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (new_node->value == temp->value) {
                    cout << "Value Already exist," <<
                        "Insert another value!" << endl;
                    return;
                }
                else if ((new_node->value < temp->value) && (temp->left == NULL)) {
                    temp->left = new_node;  //insert value to the left
                    break;
                }
                else if (new_node->value < temp->value) {
                    temp = temp->left;
                }
                else if ((new_node->value > temp->value) && (temp->right == NULL)) {
                    temp->right = new_node;  //insert value to the right
                    break;
                }
                else {
                    temp = temp->right;
                }
            }
        }
    } //insertNode

    int heightOfTree(TreeNode* root)

    {

     return root ? 1 + std::max(heightOfTree(root->left), heightOfTree(root->right)) : 0;

    }
};

Im getting an error that from the main() - Class BST has no member named 'readFromFileData'/'searchForNode'/'deleteNode'/'printInorder'/'printPreorder' etc

seeplus (6590)

Im getting an error that from the main() - Class BST has no member named 'readFromFileData'/'searchForNode'/'deleteNode'/'printInorder'/'printPreorder' etc

For the code posted just above, this is correct as the class BST now doesn't contain these functions. The original posted code did, however....

anonomyss (32)

Alright I've fixed that now I got 3 errors,

insertNode was not declared in this scope

void readFromFileData(string thePath) {
        //Open text file and read data into an array
		//Do not change anything
        fstream myFile(thePath + "data.txt", ios_base::in);
        int nextVal;
        if (myFile.is_open()) {
            string tp;
            while (getline(myFile, tp)) {
                myFile >> nextVal;
                TreeNode* new_node = new TreeNode(); //create the instance in the heap-memory (pointer) - can be seen global and stays in memory
                new_node->value = nextVal;
                insertNode(new_node);
            }
        }
    }

};

Root was not declared in this scope

TreeNode *searchForNode(int v) {
        if (root == NULL) {
            return root;
        }
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (v == temp->value) {
                    return temp;
                }
                else if (v < temp->value) {
                    temp = temp->left;
                }
                else {
                    temp = temp->right;
                }
            }
            return NULL;
        }
    }

and expected declaration before '}' token

class BST
{
public:
    TreeNode* root;

    //member functions

    BST() {
        root = NULL;
    }

    bool isTreeEmpty()
    {
        return root = nullptr;
    }

    void insertNode(TreeNode* new_node) {
        if (root == NULL) {
            root = new_node;
         } //insert the root node
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (new_node->value == temp->value) {
                    cout << "Value Already exist," <<
                        "Insert another value!" << endl;
                    return;
                }
                else if ((new_node->value < temp->value) && (temp->left == NULL)) {
                    temp->left = new_node;  //insert value to the left
                    break;
                }
                else if (new_node->value < temp->value) {
                    temp = temp->left;
                }
                else if ((new_node->value > temp->value) && (temp->right == NULL)) {
                    temp->right = new_node;  //insert value to the right
                    break;
                }
                else {
                    temp = temp->right;
                }
            }
        }
    } //insertNode

    int heightOfTree(TreeNode* root)

    {
        return root ? 1 + std::max(heightOfTree(root->left), heightOfTree(root->right)) : 0;

    }
    };


    void printPreorder(TreeNode* root) //(current node, Left, Right)
    {
         if (root) {
      std::cout << root->data << " ";
      printPreorder(root->left);
      printPreorder(root->right);
   }

    }//printPreorder

    void printInorder(TreeNode* root) //  (Left, current node, Right)
    {
         if (root) {
      printInorder(root->left);
      std::cout << root->data << " ";
      printInorder(root->right);
   }

    } //printInorder

    void printPostorder(TreeNode* root) //left, right, root
    {
           if (root) {
      printPostorder(root->left);
      printPostorder(root->right);
      std::cout << root->data << " ";
   }

    }// printPostorder

    TreeNode *searchForNode(int v) {
        if (root == NULL) {
            return root;
        }
        else {
            TreeNode* temp = root;
            while (temp != NULL) {
                if (v == temp->value) {
                    return temp;
                }
                else if (v < temp->value) {
                    temp = temp->left;
                }
                else {
                    temp = temp->right;
                }
            }
            return NULL;
        }
    }

    TreeNode* minValueNode(TreeNode* node) {
        TreeNode* current = node;
        /* loop down to find the leftmost leaf */
        while (current->left != NULL) {
            current = current->left;
        }
        return current;
    }



    TreeNode* deleteNode(TreeNode* r, int v) {
        // base case
        if (r == NULL) {
            return NULL;
        }
        // If the key to be deleted is smaller than the root's key,
        // then it lies in left subtree
        else if (v < r->value) {
            r->left = deleteNode(r->left, v);
        }
        // If the key to be deleted is greater than the root's key,
        // then it lies in right subtree
        else if (v > r->value) {
            r->right = deleteNode(r->right, v);
        }
        // if key is same as root's key, then This is the node to be deleted
        else {
            // node with only one child or no child
            if (r->left == NULL) {
                TreeNode* temp = r->right;
                delete r;
                return temp;
            }
            else if (r->right == NULL) {
                TreeNode* temp = r->left;
                delete r;
                return temp;
            }
            else {
                // node with two children: Get the inorder successor (smallest
                // in the right subtree)
                TreeNode* temp = minValueNode(r->right);
                // Copy the inorder successor's content to this node
                r->value = temp->value;
                // Delete the inorder successor
                r->right = deleteNode(r->right, temp->value);
                //deleteNode(r->right, temp->value);
            }
        }
        return r;
    }

    void readFromFileData(string thePath) {
        //Open text file and read data into an array
		//Do not change anything
        fstream myFile(thePath + "data.txt", ios_base::in);
        int nextVal;
        if (myFile.is_open()) {
            string tp;
            while (getline(myFile, tp)) {
                myFile >> nextVal;
                TreeNode* new_node = new TreeNode(); //create the instance in the heap-memory (pointer) - can be seen global and stays in memory
                new_node->value = nextVal;
                insertNode(new_node);
            }
        }
    }

};

seeplus (6590)

Consider L53...

anonomyss (32)

Thank you seeplus, I have fixed the issues, code is working.

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