297 lines
8.1 KiB
Java
297 lines
8.1 KiB
Java
package DataStructures.Trees;
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import java.util.ArrayList;
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import java.util.List;
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/**
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* <h1>Binary Search Tree (Recursive) Generic Type Implementation</h1>
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*
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* <p>
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* A recursive implementation of generic type BST.
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*
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* Reference: https://en.wikipedia.org/wiki/Binary_search_tree
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* </p>
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*
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* @author [Madhur Panwar](https://github.com/mdrpanwar)
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*/
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public class BSTRecursiveGeneric<T extends Comparable<T>> {
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/** only data member is root of BST */
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private Node<T> root;
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/** Constructor use to initialize node as null */
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public BSTRecursiveGeneric() {
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root = null;
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}
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/** main function for testing */
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public static void main(String[] args) {
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System.out.println("Testing for integer data...");
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// Integer
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DataStructures.Trees.BSTRecursiveGeneric<Integer> integerTree = new DataStructures.Trees.BSTRecursiveGeneric<Integer>();
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integerTree.add(5);
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integerTree.add(10);
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integerTree.add(9);
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assert !integerTree.find(4) : "4 is not yet present in BST";
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assert integerTree.find(10) : "10 should be present in BST";
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integerTree.remove(9);
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assert !integerTree.find(9) : "9 was just deleted from BST";
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integerTree.remove(1);
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assert !integerTree.find(1) : "Since 1 was not present so find deleting would do no change";
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integerTree.add(20);
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integerTree.add(70);
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assert integerTree.find(70) : "70 was inserted but not found";
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/*
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Will print in following order
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5 10 20 70
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*/
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integerTree.inorder();
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System.out.println();
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System.out.println("Testing for string data...");
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// String
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DataStructures.Trees.BSTRecursiveGeneric<String> stringTree = new DataStructures.Trees.BSTRecursiveGeneric<String>();
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stringTree.add("banana");
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stringTree.add("pineapple");
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stringTree.add("date");
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assert !stringTree.find("girl") : "girl is not yet present in BST";
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assert stringTree.find("pineapple") : "10 should be present in BST";
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stringTree.remove("date");
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assert !stringTree.find("date") : "date was just deleted from BST";
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stringTree.remove("boy");
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assert !stringTree.find("boy") : "Since boy was not present so deleting would do no change";
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stringTree.add("india");
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stringTree.add("hills");
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assert stringTree.find("hills") : "hills was inserted but not found";
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/*
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Will print in following order
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banana hills india pineapple
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*/
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stringTree.inorder();
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}
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/**
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* Recursive method to delete a data if present in BST.
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*
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* @param node the node under which to (recursively) search for data
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* @param data the value to be deleted
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* @return Node the updated value of root parameter after delete operation
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*/
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private Node<T> delete(Node<T> node, T data) {
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if (node == null) {
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System.out.println("No such data present in BST.");
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} else if (node.data.compareTo(data) > 0) {
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node.left = delete(node.left, data);
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} else if (node.data.compareTo(data) < 0) {
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node.right = delete(node.right, data);
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} else {
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if (node.right == null && node.left == null) { // If it is leaf node
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node = null;
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} else if (node.left == null) { // If only right node is present
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Node<T> temp = node.right;
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node.right = null;
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node = temp;
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} else if (node.right == null) { // Only left node is present
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Node<T> temp = node.left;
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node.left = null;
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node = temp;
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} else { // both child are present
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Node<T> temp = node.right;
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// Find leftmost child of right subtree
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while (temp.left != null) {
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temp = temp.left;
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}
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node.data = temp.data;
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node.right = delete(node.right, temp.data);
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}
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}
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return node;
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}
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/**
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* Recursive insertion of value in BST.
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*
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* @param node to check if the data can be inserted in current node or its subtree
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* @param data the value to be inserted
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* @return the modified value of the root parameter after insertion
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*/
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private Node<T> insert(Node<T> node, T data) {
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if (node == null) {
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node = new Node<>(data);
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} else if (node.data.compareTo(data) > 0) {
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node.left = insert(node.left, data);
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} else if (node.data.compareTo(data) < 0) {
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node.right = insert(node.right, data);
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}
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return node;
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}
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/**
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* Recursively print Preorder traversal of the BST
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*
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* @param node the root node
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*/
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private void preOrder(Node<T> node) {
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if (node == null) {
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return;
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}
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System.out.print(node.data + " ");
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if (node.left != null) {
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preOrder(node.left);
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}
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if (node.right != null) {
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preOrder(node.right);
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}
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}
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/**
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* Recursively print Postorder traversal of BST.
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*
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* @param node the root node
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*/
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private void postOrder(Node<T> node) {
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if (node == null) {
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return;
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}
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if (node.left != null) {
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postOrder(node.left);
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}
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if (node.right != null) {
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postOrder(node.right);
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}
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System.out.print(node.data + " ");
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}
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/**
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* Recursively print Inorder traversal of BST.
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*
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* @param node the root node
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*/
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private void inOrder(Node<T> node) {
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if (node == null) {
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return;
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}
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if (node.left != null) {
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inOrder(node.left);
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}
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System.out.print(node.data + " ");
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if (node.right != null) {
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inOrder(node.right);
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}
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}
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/**
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* Recursively traverse the tree using inorder traversal
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* and keep adding elements to argument list.
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*
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* @param node the root node
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* @param sortedList the list to add the srted elements into
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*/
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private void inOrderSort(Node<T> node, List<T> sortedList) {
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if (node == null) {
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return;
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}
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if (node.left != null) {
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inOrderSort(node.left, sortedList);
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}
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sortedList.add(node.data);
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if (node.right != null) {
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inOrderSort(node.right, sortedList);
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}
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}
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/**
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* Serach recursively if the given value is present in BST or not.
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*
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* @param node the node under which to check
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* @param data the value to be checked
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* @return boolean if data is present or not
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*/
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private boolean search(Node<T> node, T data) {
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if (node == null) {
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return false;
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} else if (node.data.compareTo(data) == 0) {
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return true;
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} else if (node.data.compareTo(data) > 0) {
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return search(node.left, data);
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} else {
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return search(node.right, data);
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}
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}
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/**
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* add in BST. if the value is not already present it is inserted or else no change takes place.
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*
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* @param data the value to be inserted
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*/
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public void add(T data) {
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this.root = insert(this.root, data);
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}
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/**
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* If data is present in BST delete it else do nothing.
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*
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* @param data the value to be removed
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*/
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public void remove(T data) {
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this.root = delete(this.root, data);
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}
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/** To call inorder traversal on tree */
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public void inorder() {
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System.out.println("Inorder traversal of this tree is:");
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inOrder(this.root);
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System.out.println(); // for next line
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}
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/** return a sorted list by traversing the tree elements using inorder traversal */
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public List<T> inorderSort() {
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List<T> sortedList = new ArrayList<>();
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inOrderSort(this.root, sortedList);
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return sortedList;
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}
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/** To call postorder traversal on tree */
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public void postorder() {
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System.out.println("Postorder traversal of this tree is:");
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postOrder(this.root);
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System.out.println(); // for next line
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}
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/** To call preorder traversal on tree. */
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public void preorder() {
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System.out.println("Preorder traversal of this tree is:");
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preOrder(this.root);
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System.out.println(); // for next line
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}
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/**
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* To check if given value is present in tree or not.
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*
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* @param data the data to be found for
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*/
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public boolean find(T data) {
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if (search(this.root, data)) {
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System.out.println(data + " is present in given BST.");
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return true;
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}
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System.out.println(data + " not found.");
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return false;
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}
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/** The generic Node class used for building binary search tree */
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private static class Node<T> {
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T data;
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Node<T> left;
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Node<T> right;
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/** Constructor with data as parameter */
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Node(T d) {
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data = d;
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left = null;
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right = null;
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}
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}
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}
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