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159 lines
4.8 KiB
Java
159 lines
4.8 KiB
Java
/**
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* File: binary_search_tree.java
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* Created Time: 2022-11-25
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* Author: krahets (krahets@163.com)
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*/
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package chapter_tree;
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import utils.*;
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/* Binary search tree */
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class BinarySearchTree {
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private TreeNode root;
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/* Constructor */
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public BinarySearchTree() {
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// Initialize empty tree
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root = null;
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}
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/* Get binary tree root node */
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public TreeNode getRoot() {
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return root;
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}
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/* Search node */
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public TreeNode search(int num) {
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TreeNode cur = root;
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// Loop search, exit after passing leaf node
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while (cur != null) {
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// Target node is in cur's right subtree
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if (cur.val < num)
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cur = cur.right;
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// Target node is in cur's left subtree
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else if (cur.val > num)
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cur = cur.left;
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// Found target node, exit loop
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else
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break;
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}
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// Return target node
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return cur;
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}
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/* Insert node */
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public void insert(int num) {
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// If tree is empty, initialize root node
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if (root == null) {
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root = new TreeNode(num);
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return;
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}
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TreeNode cur = root, pre = null;
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// Loop search, exit after passing leaf node
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while (cur != null) {
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// Found duplicate node, return directly
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if (cur.val == num)
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return;
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pre = cur;
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// Insertion position is in cur's right subtree
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if (cur.val < num)
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cur = cur.right;
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// Insertion position is in cur's left subtree
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else
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cur = cur.left;
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}
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// Insert node
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TreeNode node = new TreeNode(num);
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if (pre.val < num)
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pre.right = node;
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else
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pre.left = node;
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}
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/* Remove node */
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public void remove(int num) {
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// If tree is empty, return directly
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if (root == null)
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return;
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TreeNode cur = root, pre = null;
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// Loop search, exit after passing leaf node
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while (cur != null) {
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// Found node to delete, exit loop
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if (cur.val == num)
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break;
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pre = cur;
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// Node to delete is in cur's right subtree
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if (cur.val < num)
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cur = cur.right;
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// Node to delete is in cur's left subtree
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else
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cur = cur.left;
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}
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// If no node to delete, return directly
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if (cur == null)
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return;
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// Number of child nodes = 0 or 1
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if (cur.left == null || cur.right == null) {
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// When number of child nodes = 0 / 1, child = null / that child node
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TreeNode child = cur.left != null ? cur.left : cur.right;
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// Delete node cur
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if (cur != root) {
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if (pre.left == cur)
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pre.left = child;
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else
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pre.right = child;
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} else {
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// If deleted node is root node, reassign root node
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root = child;
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}
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}
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// Number of child nodes = 2
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else {
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// Get next node of cur in inorder traversal
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TreeNode tmp = cur.right;
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while (tmp.left != null) {
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tmp = tmp.left;
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}
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// Recursively delete node tmp
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remove(tmp.val);
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// Replace cur with tmp
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cur.val = tmp.val;
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}
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}
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}
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public class binary_search_tree {
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public static void main(String[] args) {
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/* Initialize binary search tree */
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BinarySearchTree bst = new BinarySearchTree();
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// Please note that different insertion orders will generate different binary trees, this sequence can generate a perfect binary tree
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int[] nums = { 8, 4, 12, 2, 6, 10, 14, 1, 3, 5, 7, 9, 11, 13, 15 };
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for (int num : nums) {
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bst.insert(num);
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}
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System.out.println("\nInitialized binary tree is\n");
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PrintUtil.printTree(bst.getRoot());
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/* Search node */
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TreeNode node = bst.search(7);
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System.out.println("\nFound node object is " + node + ", node value = " + node.val);
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/* Insert node */
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bst.insert(16);
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System.out.println("\nAfter inserting node 16, binary tree is\n");
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PrintUtil.printTree(bst.getRoot());
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/* Remove node */
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bst.remove(1);
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System.out.println("\nAfter removing node 1, binary tree is\n");
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PrintUtil.printTree(bst.getRoot());
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bst.remove(2);
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System.out.println("\nAfter removing node 2, binary tree is\n");
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PrintUtil.printTree(bst.getRoot());
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bst.remove(4);
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System.out.println("\nAfter removing node 4, binary tree is\n");
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PrintUtil.printTree(bst.getRoot());
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}
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}
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