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* Add the intial translation of code of all the languages * test * revert * Remove * Add Python and Java code for EN version
220 lines
7.1 KiB
Java
220 lines
7.1 KiB
Java
/**
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* File: avl_tree.java
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* Created Time: 2022-12-10
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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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/* AVL tree */
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class AVLTree {
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TreeNode root; // Root node
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/* Get node height */
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public int height(TreeNode node) {
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// Empty node height is -1, leaf node height is 0
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return node == null ? -1 : node.height;
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}
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/* Update node height */
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private void updateHeight(TreeNode node) {
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// Node height equals the height of the tallest subtree + 1
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node.height = Math.max(height(node.left), height(node.right)) + 1;
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}
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/* Get balance factor */
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public int balanceFactor(TreeNode node) {
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// Empty node balance factor is 0
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if (node == null)
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return 0;
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// Node balance factor = left subtree height - right subtree height
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return height(node.left) - height(node.right);
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}
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/* Right rotation operation */
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private TreeNode rightRotate(TreeNode node) {
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TreeNode child = node.left;
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TreeNode grandChild = child.right;
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// Rotate node to the right around child
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child.right = node;
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node.left = grandChild;
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// Update node height
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updateHeight(node);
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updateHeight(child);
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// Return the root of the subtree after rotation
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return child;
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}
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/* Left rotation operation */
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private TreeNode leftRotate(TreeNode node) {
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TreeNode child = node.right;
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TreeNode grandChild = child.left;
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// Rotate node to the left around child
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child.left = node;
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node.right = grandChild;
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// Update node height
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updateHeight(node);
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updateHeight(child);
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// Return the root of the subtree after rotation
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return child;
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}
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/* Perform rotation operation to restore balance to the subtree */
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private TreeNode rotate(TreeNode node) {
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// Get the balance factor of node
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int balanceFactor = balanceFactor(node);
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// Left-leaning tree
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if (balanceFactor > 1) {
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if (balanceFactor(node.left) >= 0) {
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// Right rotation
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return rightRotate(node);
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} else {
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// First left rotation then right rotation
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node.left = leftRotate(node.left);
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return rightRotate(node);
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}
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}
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// Right-leaning tree
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if (balanceFactor < -1) {
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if (balanceFactor(node.right) <= 0) {
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// Left rotation
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return leftRotate(node);
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} else {
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// First right rotation then left rotation
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node.right = rightRotate(node.right);
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return leftRotate(node);
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}
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}
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// Balanced tree, no rotation needed, return
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return node;
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}
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/* Insert node */
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public void insert(int val) {
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root = insertHelper(root, val);
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}
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/* Recursively insert node (helper method) */
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private TreeNode insertHelper(TreeNode node, int val) {
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if (node == null)
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return new TreeNode(val);
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/* 1. Find insertion position and insert node */
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if (val < node.val)
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node.left = insertHelper(node.left, val);
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else if (val > node.val)
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node.right = insertHelper(node.right, val);
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else
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return node; // Do not insert duplicate nodes, return
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updateHeight(node); // Update node height
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/* 2. Perform rotation operation to restore balance to the subtree */
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node = rotate(node);
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// Return the root node of the subtree
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return node;
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}
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/* Remove node */
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public void remove(int val) {
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root = removeHelper(root, val);
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}
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/* Recursively remove node (helper method) */
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private TreeNode removeHelper(TreeNode node, int val) {
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if (node == null)
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return null;
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/* 1. Find and remove the node */
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if (val < node.val)
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node.left = removeHelper(node.left, val);
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else if (val > node.val)
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node.right = removeHelper(node.right, val);
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else {
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if (node.left == null || node.right == null) {
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TreeNode child = node.left != null ? node.left : node.right;
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// Number of child nodes = 0, remove node and return
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if (child == null)
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return null;
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// Number of child nodes = 1, remove node
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else
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node = child;
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} else {
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// Number of child nodes = 2, remove the next node in in-order traversal and replace the current node with it
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TreeNode temp = node.right;
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while (temp.left != null) {
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temp = temp.left;
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}
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node.right = removeHelper(node.right, temp.val);
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node.val = temp.val;
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}
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}
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updateHeight(node); // Update node height
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/* 2. Perform rotation operation to restore balance to the subtree */
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node = rotate(node);
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// Return the root node of the subtree
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return node;
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}
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/* Search node */
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public TreeNode search(int val) {
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TreeNode cur = root;
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// Loop find, break after passing leaf nodes
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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 < val)
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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 > val)
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cur = cur.left;
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// Found target node, break 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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}
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public class avl_tree {
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static void testInsert(AVLTree tree, int val) {
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tree.insert(val);
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System.out.println("\nAfter inserting node " + val + ", the AVL tree is ");
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PrintUtil.printTree(tree.root);
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}
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static void testRemove(AVLTree tree, int val) {
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tree.remove(val);
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System.out.println("\nAfter removing node " + val + ", the AVL tree is ");
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PrintUtil.printTree(tree.root);
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}
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public static void main(String[] args) {
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/* Initialize empty AVL tree */
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AVLTree avlTree = new AVLTree();
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/* Insert node */
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// Notice how the AVL tree maintains balance after inserting nodes
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testInsert(avlTree, 1);
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testInsert(avlTree, 2);
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testInsert(avlTree, 3);
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testInsert(avlTree, 4);
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testInsert(avlTree, 5);
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testInsert(avlTree, 8);
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testInsert(avlTree, 7);
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testInsert(avlTree, 9);
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testInsert(avlTree, 10);
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testInsert(avlTree, 6);
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/* Insert duplicate node */
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testInsert(avlTree, 7);
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/* Remove node */
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// Notice how the AVL tree maintains balance after removing nodes
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testRemove(avlTree, 8); // Remove node with degree 0
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testRemove(avlTree, 5); // Remove node with degree 1
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testRemove(avlTree, 4); // Remove node with degree 2
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/* Search node */
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TreeNode node = avlTree.search(7);
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System.out.println("\nThe found node object is " + node + ", node value = " + node.val);
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}
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}
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