# How to determine if a binary tree is height-balanced?

• Difficulty Level : Medium
• Last Updated : 16 Jun, 2022

A tree where no leaf is much farther away from the root than any other leaf. Different balancing schemes allow different definitions of “much farther” and different amounts of work to keep them balanced.
Consider a height-balancing scheme where the following conditions should be checked to determine if a binary tree is balanced.
An empty tree is height-balanced. A non-empty binary tree T is balanced if:

1. Left subtree of T is balanced
2. Right subtree of T is balanced
3. The difference between heights of left subtree and the right subtree is not more than 1.

The above height-balancing scheme is used in AVL trees. The diagram below shows two trees, one of them is height-balanced and other is not. The second tree is not height-balanced because height of left subtree is 2 more than height of right subtree. To check if a tree is height-balanced, get the height of left and right subtrees. Return true if difference between heights is not more than 1 and left and right subtrees are balanced, otherwise return false.

## C++

 `/* CPP program to check if` `a tree is height-balanced or not */` `#include ` `using` `namespace` `std;`   `/* A binary tree node has data,` `pointer to left child and ` `a pointer to right child */` `class` `node {` `public``:` `    ``int` `data;` `    ``node* left;` `    ``node* right;` `};`   `/* Returns the height of a binary tree */` `int` `height(node* node);`   `/* Returns true if binary tree` `with root as root is height-balanced */` `bool` `isBalanced(node* root)` `{` `    ``int` `lh; ``/* for height of left subtree */` `    ``int` `rh; ``/* for height of right subtree */`   `    ``/* If tree is empty then return true */` `    ``if` `(root == NULL)` `        ``return` `1;`   `    ``/* Get the height of left and right sub trees */` `    ``lh = height(root->left);` `    ``rh = height(root->right);`   `    ``if` `(``abs``(lh - rh) <= 1 && isBalanced(root->left) && isBalanced(root->right))` `        ``return` `1;`   `    ``/* If we reach here then ` `    ``tree is not height-balanced */` `    ``return` `0;` `}`   `/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */`   `/* returns maximum of two integers */` `int` `max(``int` `a, ``int` `b)` `{` `    ``return` `(a >= b) ? a : b;` `}`   `/* The function Compute the "height" ` `of a tree. Height is the number of ` `nodes along the longest path from ` `the root node down to the farthest leaf node.*/` `int` `height(node* node)` `{` `    ``/* base case tree is empty */` `    ``if` `(node == NULL)` `        ``return` `0;`   `    ``/* If tree is not empty then ` `    ``height = 1 + max of left ` `        ``height and right heights */` `    ``return` `1 + max(height(node->left),` `                   ``height(node->right));` `}`   `/* Helper function that allocates` `a new node with the given data ` `and NULL left and right pointers. */` `node* newNode(``int` `data)` `{` `    ``node* Node = ``new` `node();` `    ``Node->data = data;` `    ``Node->left = NULL;` `    ``Node->right = NULL;`   `    ``return` `(Node);` `}`   `// Driver code` `int` `main()` `{` `    ``node* root = newNode(1);` `    ``root->left = newNode(2);` `    ``root->right = newNode(3);` `    ``root->left->left = newNode(4);` `    ``root->left->right = newNode(5);` `    ``root->left->left->left = newNode(8);`   `    ``if` `(isBalanced(root))` `        ``cout << ``"Tree is balanced"``;` `    ``else` `        ``cout << ``"Tree is not balanced"``;` `    ``return` `0;` `}`   `// This code is contributed by rathbhupendra`

## C

 `/* C program to check if a tree is height-balanced or not */` `#include ` `#include ` `#define bool int`   `/* A binary tree node has data, pointer to left child` `   ``and a pointer to right child */` `struct` `node {` `    ``int` `data;` `    ``struct` `node* left;` `    ``struct` `node* right;` `};`   `/* Returns the height of a binary tree */` `int` `height(``struct` `node* node);`   `/* Returns true if binary tree with root as root is height-balanced */` `bool` `isBalanced(``struct` `node* root)` `{` `    ``int` `lh; ``/* for height of left subtree */` `    ``int` `rh; ``/* for height of right subtree */`   `    ``/* If tree is empty then return true */` `    ``if` `(root == NULL)` `        ``return` `1;`   `    ``/* Get the height of left and right sub trees */` `    ``lh = height(root->left);` `    ``rh = height(root->right);`   `    ``if` `(``abs``(lh - rh) <= 1 && isBalanced(root->left) && isBalanced(root->right))` `        ``return` `1;`   `    ``/* If we reach here then tree is not height-balanced */` `    ``return` `0;` `}`   `/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */`   `/* returns maximum of two integers */` `int` `max(``int` `a, ``int` `b)` `{` `    ``return` `(a >= b) ? a : b;` `}`   `/*  The function Compute the "height" of a tree. Height is the` `    ``number of nodes along the longest path from the root node` `    ``down to the farthest leaf node.*/` `int` `height(``struct` `node* node)` `{` `    ``/* base case tree is empty */` `    ``if` `(node == NULL)` `        ``return` `0;`   `    ``/* If tree is not empty then height = 1 + max of left` `      ``height and right heights */` `    ``return` `1 + max(height(node->left), height(node->right));` `}`   `/* Helper function that allocates a new node with the` `   ``given data and NULL left and right pointers. */` `struct` `node* newNode(``int` `data)` `{` `    ``struct` `node* node = (``struct` `node*)` `        ``malloc``(``sizeof``(``struct` `node));` `    ``node->data = data;` `    ``node->left = NULL;` `    ``node->right = NULL;`   `    ``return` `(node);` `}`   `int` `main()` `{` `    ``struct` `node* root = newNode(1);` `    ``root->left = newNode(2);` `    ``root->right = newNode(3);` `    ``root->left->left = newNode(4);` `    ``root->left->right = newNode(5);` `    ``root->left->left->left = newNode(8);`   `    ``if` `(isBalanced(root))` `        ``printf``(``"Tree is balanced"``);` `    ``else` `        ``printf``(``"Tree is not balanced"``);`   `    ``getchar``();` `    ``return` `0;` `}`

## Java

 `/* Java program to determine if binary tree is ` `   ``height balanced or not */`   `/* A binary tree node has data, pointer to left child,` `   ``and a pointer to right child */` `class` `Node {` `    ``int` `data;` `    ``Node left, right;` `    ``Node(``int` `d)` `    ``{` `        ``data = d;` `        ``left = right = ``null``;` `    ``}` `}`   `class` `BinaryTree {` `    ``Node root;`   `    ``/* Returns true if binary tree with root as root is height-balanced */` `    ``boolean` `isBalanced(Node node)` `    ``{` `        ``int` `lh; ``/* for height of left subtree */`   `        ``int` `rh; ``/* for height of right subtree */`   `        ``/* If tree is empty then return true */` `        ``if` `(node == ``null``)` `            ``return` `true``;`   `        ``/* Get the height of left and right sub trees */` `        ``lh = height(node.left);` `        ``rh = height(node.right);`   `        ``if` `(Math.abs(lh - rh) <= ``1` `            ``&& isBalanced(node.left)` `            ``&& isBalanced(node.right))` `            ``return` `true``;`   `        ``/* If we reach here then tree is not height-balanced */` `        ``return` `false``;` `    ``}`   `    ``/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */` `    ``/*  The function Compute the "height" of a tree. Height is the` `        ``number of nodes along the longest path from the root node` `        ``down to the farthest leaf node.*/` `    ``int` `height(Node node)` `    ``{` `        ``/* base case tree is empty */` `        ``if` `(node == ``null``)` `            ``return` `0``;`   `        ``/* If tree is not empty then height = 1 + max of left` `         ``height and right heights */` `        ``return` `1` `+ Math.max(height(node.left), height(node.right));` `    ``}`   `    ``public` `static` `void` `main(String args[])` `    ``{` `        ``BinaryTree tree = ``new` `BinaryTree();` `        ``tree.root = ``new` `Node(``1``);` `        ``tree.root.left = ``new` `Node(``2``);` `        ``tree.root.right = ``new` `Node(``3``);` `        ``tree.root.left.left = ``new` `Node(``4``);` `        ``tree.root.left.right = ``new` `Node(``5``);` `        ``tree.root.left.left.left = ``new` `Node(``8``);`   `        ``if` `(tree.isBalanced(tree.root))` `            ``System.out.println(``"Tree is balanced"``);` `        ``else` `            ``System.out.println(``"Tree is not balanced"``);` `    ``}` `}`   `// This code has been contributed by Mayank Jaiswal(mayank_24)`

## Python3

 `"""` `Python3 program to check if a tree is height-balanced` `"""` `# A binary tree Node`       `class` `Node:` `    ``# Constructor to create a new Node` `    ``def` `__init__(``self``, data):` `        ``self``.data ``=` `data` `        ``self``.left ``=` `None` `        ``self``.right ``=` `None`   `# function to find height of binary tree` `def` `height(root):` `    `  `    ``# base condition when binary tree is empty` `    ``if` `root ``is` `None``:` `        ``return` `0` `    ``return` `max``(height(root.left), height(root.right)) ``+` `1`   `# function to check if tree is height-balanced or not` `def` `isBalanced(root):` `    `  `    ``# Base condition` `    ``if` `root ``is` `None``:` `        ``return` `True`   `    ``# for left and right subtree height` `    ``lh ``=` `height(root.left)` `    ``rh ``=` `height(root.right)`   `    ``# allowed values for (lh - rh) are 1, -1, 0` `    ``if` `(``abs``(lh ``-` `rh) <``=` `1``) ``and` `isBalanced(` `    ``root.left) ``is` `True` `and` `isBalanced( root.right) ``is` `True``:` `        ``return` `True`   `    ``# if we reach here means tree is not ` `    ``# height-balanced tree` `    ``return` `False`   `# Driver function to test the above function` `root ``=` `Node(``1``)` `root.left ``=` `Node(``2``)` `root.right ``=` `Node(``3``)` `root.left.left ``=` `Node(``4``)` `root.left.right ``=` `Node(``5``)` `root.left.left.left ``=` `Node(``8``)` `if` `isBalanced(root):` `    ``print``(``"Tree is balanced"``)` `else``:` `    ``print``(``"Tree is not balanced"``)`   `# This code is contributed by Shweta Singh`

## C#

 `using` `System;`   `/* C# program to determine if binary tree is ` `height balanced or not */`   `/* A binary tree node has data, pointer to left child, ` `and a pointer to right child */` `public` `class` `Node {` `    ``public` `int` `data;` `    ``public` `Node left, right;` `    ``public` `Node(``int` `d)` `    ``{` `        ``data = d;` `        ``left = right = ``null``;` `    ``}` `}`   `public` `class` `BinaryTree {` `    ``public` `Node root;`   `    ``/* Returns true if binary tree with root as` `    ``root is height-balanced */` `    ``public` `virtual` `bool` `isBalanced(Node node)` `    ``{` `        ``int` `lh; ``// for height of left subtree`   `        ``int` `rh; ``// for height of right subtree`   `        ``/* If tree is empty then return true */` `        ``if` `(node == ``null``) {` `            ``return` `true``;` `        ``}`   `        ``/* Get the height of left and right sub trees */` `        ``lh = height(node.left);` `        ``rh = height(node.right);`   `        ``if` `(Math.Abs(lh - rh) <= 1 && isBalanced(node.left)` `            ``&& isBalanced(node.right)) {` `            ``return` `true``;` `        ``}`   `        ``/* If we reach here then tree is not height-balanced */` `        ``return` `false``;` `    ``}`   `    ``/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */` `    ``/* The function Compute the "height" of a tree. Height is the ` `        ``number of nodes along the longest path from the root node ` `        ``down to the farthest leaf node.*/` `    ``public` `virtual` `int` `height(Node node)` `    ``{` `        ``/* base case tree is empty */` `        ``if` `(node == ``null``) {` `            ``return` `0;` `        ``}`   `        ``/* If tree is not empty then height = 1 + max of left ` `        ``height and right heights */` `        ``return` `1 + Math.Max(height(node.left), height(node.right));` `    ``}`   `    ``public` `static` `void` `Main(``string``[] args)` `    ``{` `        ``BinaryTree tree = ``new` `BinaryTree();` `        ``tree.root = ``new` `Node(1);` `        ``tree.root.left = ``new` `Node(2);` `        ``tree.root.right = ``new` `Node(3);` `        ``tree.root.left.left = ``new` `Node(4);` `        ``tree.root.left.right = ``new` `Node(5);` `        ``tree.root.left.left.left = ``new` `Node(8);`   `        ``if` `(tree.isBalanced(tree.root)) {` `            ``Console.WriteLine(``"Tree is balanced"``);` `        ``}` `        ``else` `{` `            ``Console.WriteLine(``"Tree is not balanced"``);` `        ``}` `    ``}` `}`   `// This code is contributed by Shrikant13`

## Javascript

 ``

Output:

`Tree is not balanced`

Time Complexity: O(n^2) in case of full binary tree.

Auxiliary Space: O(n) space for call stack since using recursion

Optimized implementation: Above implementation can be optimized by calculating the height in the same recursion rather than calling a height() function separately. Thanks to Amar for suggesting this optimized version. This optimization reduces time complexity to O(n).

## C++

 `/* C++ program to check if a tree ` `is height-balanced or not */` `#include ` `using` `namespace` `std;` `#define bool int`   `/* A binary tree node has data,` `pointer to left child and ` `a pointer to right child */` `class` `node {` `public``:` `    ``int` `data;` `    ``node* left;` `    ``node* right;` `};`   `/* The function returns true if root is ` `balanced else false The second parameter ` `is to store the height of tree. Initially,` `we need to pass a pointer to a location with ` `value as 0. We can also write a wrapper ` `over this function */` `bool` `isBalanced(node* root, ``int``* height)` `{`   `    ``/* lh --> Height of left subtree ` `    ``rh --> Height of right subtree */` `    ``int` `lh = 0, rh = 0;`   `    ``/* l will be true if left subtree is balanced ` `    ``and r will be true if right subtree is balanced */` `    ``int` `l = 0, r = 0;`   `    ``if` `(root == NULL) {` `        ``*height = 0;` `        ``return` `1;` `    ``}`   `    ``/* Get the heights of left and right subtrees in lh and rh ` `    ``And store the returned values in l and r */` `    ``l = isBalanced(root->left, &lh);` `    ``r = isBalanced(root->right, &rh);`   `    ``/* Height of current node is max of heights of left and ` `    ``right subtrees plus 1*/` `    ``*height = (lh > rh ? lh : rh) + 1;`   `    ``/* If difference between heights of left and right ` `    ``subtrees is more than 2 then this node is not balanced ` `    ``so return 0 */` `    ``if` `(``abs``(lh - rh) >= 2)` `        ``return` `0;`   `    ``/* If this node is balanced and left and right subtrees ` `    ``are balanced then return true */` `    ``else` `        ``return` `l && r;` `}`   `/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */`   `/* Helper function that allocates a new node with the ` `given data and NULL left and right pointers. */` `node* newNode(``int` `data)` `{` `    ``node* Node = ``new` `node();` `    ``Node->data = data;` `    ``Node->left = NULL;` `    ``Node->right = NULL;`   `    ``return` `(Node);` `}`   `// Driver code` `int` `main()` `{` `    ``int` `height = 0;`   `    ``/* Constructed binary tree is ` `            ``1 ` `            ``/ \ ` `            ``2 3 ` `            ``/ \ / ` `            ``4 5 6 ` `            ``/ ` `            ``7 ` `    ``*/` `    ``node* root = newNode(1);` `    ``root->left = newNode(2);` `    ``root->right = newNode(3);` `    ``root->left->left = newNode(4);` `    ``root->left->right = newNode(5);` `    ``root->right->left = newNode(6);` `    ``root->left->left->left = newNode(7);`   `    ``if` `(isBalanced(root, &height))` `        ``cout << ``"Tree is balanced"``;` `    ``else` `        ``cout << ``"Tree is not balanced"``;`   `    ``return` `0;` `}`   `// This is code is contributed by rathbhupendra`

## C

 `/* C program to check if a tree is height-balanced or not */` `#include ` `#include ` `#define bool int`   `/* A binary tree node has data, pointer to left child` `   ``and a pointer to right child */` `struct` `node {` `    ``int` `data;` `    ``struct` `node* left;` `    ``struct` `node* right;` `};`   `/* The function returns true if root is balanced else false` `   ``The second parameter is to store the height of tree.  ` `   ``Initially, we need to pass a pointer to a location with value ` `   ``as 0. We can also write a wrapper over this function */` `bool` `isBalanced(``struct` `node* root, ``int``* height)` `{` `    ``/* lh --> Height of left subtree ` `     ``rh --> Height of right subtree */` `    ``int` `lh = 0, rh = 0;`   `    ``/* l will be true if left subtree is balanced ` `    ``and r will be true if right subtree is balanced */` `    ``int` `l = 0, r = 0;`   `    ``if` `(root == NULL) {` `        ``*height = 0;` `        ``return` `1;` `    ``}`   `    ``/* Get the heights of left and right subtrees in lh and rh ` `    ``And store the returned values in l and r */` `    ``l = isBalanced(root->left, &lh);` `    ``r = isBalanced(root->right, &rh);`   `    ``/* Height of current node is max of heights of left and ` `     ``right subtrees plus 1*/` `    ``*height = (lh > rh ? lh : rh) + 1;`   `    ``/* If difference between heights of left and right ` `     ``subtrees is more than 2 then this node is not balanced` `     ``so return 0 */` `    ``if` `(``abs``(lh - rh) >= 2)` `        ``return` `0;`   `    ``/* If this node is balanced and left and right subtrees ` `    ``are balanced then return true */` `    ``else` `        ``return` `l && r;` `}`   `/* UTILITY FUNCTIONS TO TEST isBalanced() FUNCTION */`   `/* Helper function that allocates a new node with the` `   ``given data and NULL left and right pointers. */` `struct` `node* newNode(``int` `data)` `{` `    ``struct` `node* node = (``struct` `node*)` `        ``malloc``(``sizeof``(``struct` `node));` `    ``node->data = data;` `    ``node->left = NULL;` `    ``node->right = NULL;`   `    ``return` `(node);` `}`   `// Driver code` `int` `main()` `{` `    ``int` `height = 0;`   `    ``/* Constructed binary tree is` `             ``1` `           ``/   \` `         ``2      3` `       ``/  \    /` `     ``4     5  6` `    ``/` `   ``7` `  ``*/` `    ``struct` `node* root = newNode(1);` `    ``root->left = newNode(2);` `    ``root->right = newNode(3);` `    ``root->left->left = newNode(4);` `    ``root->left->right = newNode(5);` `    ``root->right->left = newNode(6);` `    ``root->left->left->left = newNode(7);`   `    ``if` `(isBalanced(root, &height))` `        ``printf``(``"Tree is balanced"``);` `    ``else` `        ``printf``(``"Tree is not balanced"``);`   `    ``getchar``();` `    ``return` `0;` `}`

## Java

 `/* Java program to determine if binary tree is` `   ``height balanced or not */`   `/* A binary tree node has data, pointer to left child,` `   ``and a pointer to right child */` `class` `Node {`   `    ``int` `data;` `    ``Node left, right;`   `    ``Node(``int` `d)` `    ``{` `        ``data = d;` `        ``left = right = ``null``;` `    ``}` `}`   `// A wrapper class used to modify height across` `// recursive calls.` `class` `Height {` `    ``int` `height = ``0``;` `}`   `class` `BinaryTree {`   `    ``Node root;`   `    ``/* Returns true if binary tree with root as root is height-balanced */` `    ``boolean` `isBalanced(Node root, Height height)` `    ``{` `        ``/* If tree is empty then return true */` `        ``if` `(root == ``null``) {` `            ``height.height = ``0``;` `            ``return` `true``;` `        ``}`   `        ``/* Get heights of left and right sub trees */` `        ``Height lheight = ``new` `Height(), rheight = ``new` `Height();` `        ``boolean` `l = isBalanced(root.left, lheight);` `        ``boolean` `r = isBalanced(root.right, rheight);` `        ``int` `lh = lheight.height, rh = rheight.height;`   `        ``/* Height of current node is max of heights of` `           ``left and right subtrees plus 1*/` `        ``height.height = (lh > rh ? lh : rh) + ``1``;`   `        ``/* If difference between heights of left and right` `           ``subtrees is more than 2 then this node is not balanced` `           ``so return 0 */` `        ``if` `(Math.abs(lh - rh) >= ``2``)` `            ``return` `false``;`   `        ``/* If this node is balanced and left and right subtrees` `           ``are balanced then return true */` `        ``else` `            ``return` `l && r;` `    ``}`   `    ``public` `static` `void` `main(String args[])` `    ``{` `        ``Height height = ``new` `Height();`   `        ``/* Constructed binary tree is` `                   ``1` `                 ``/   \` `                ``2      3` `              ``/  \    /` `            ``4     5  6` `            ``/` `           ``7         */` `        ``BinaryTree tree = ``new` `BinaryTree();` `        ``tree.root = ``new` `Node(``1``);` `        ``tree.root.left = ``new` `Node(``2``);` `        ``tree.root.right = ``new` `Node(``3``);` `        ``tree.root.left.left = ``new` `Node(``4``);` `        ``tree.root.left.right = ``new` `Node(``5``);` `        ``tree.root.right.right = ``new` `Node(``6``);` `        ``tree.root.left.left.left = ``new` `Node(``7``);`   `        ``if` `(tree.isBalanced(tree.root, height))` `            ``System.out.println(``"Tree is balanced"``);` `        ``else` `            ``System.out.println(``"Tree is not balanced"``);` `    ``}` `}`   `// This code has been contributed by Mayank Jaiswal(mayank_24)`

## Python3

 `"""` `Python3 program to check if Binary tree is` `height-balanced` `"""`   `# A binary tree node` `class` `Node:` `    `  `    ``# constructor to create node of` `    ``# binary tree` `    ``def` `__init__(``self``, data):` `        ``self``.data ``=` `data` `        ``self``.left ``=` `self``.right ``=` `None`   `# utility class to pass height object` `class` `Height:` `    ``def` `__init__(``self``):` `        ``self``.height ``=` `0`   `# function to find height of binary tree` `def` `height(root):` `    `  `    ``# base condition when binary tree is empty` `    ``if` `root ``is` `None``:` `        ``return` `0` `    ``return` `max``(height(root.left), height(root.right)) ``+` `1`   `# helper function to check if binary` `# tree is height balanced` `def` `isBalanced(root):` `    ``# Base condition when tree is` `    ``# empty return true` `    ``if` `root ``is` `None``:` `        ``return` `True`   `    ``# lh and rh to store height of` `    ``# left and right subtree` `    ``lh ``=` `Height()` `    ``rh ``=` `Height()` `    `  `    ``# Calculating height of left and right tree` `    ``lh.height ``=` `height(root.left)` `    ``rh.height ``=` `height(root.right)`     `    ``# l and r are used to check if left` `    ``# and right subtree are balanced` `    ``l ``=` `isBalanced(root.left)` `    ``r ``=` `isBalanced(root.right)`   `    ``# height of tree is maximum of` `    ``# left subtree height and` `    ``# right subtree height plus 1`   `    ``if` `abs``(lh.height ``-` `rh.height) <``=` `1``:` `        ``return` `l ``and` `r`   `    ``# if we reach here then the tree` `    ``# is not balanced` `    ``return` `False`   `# Driver function to test the above function` `"""` `Constructed binary tree is` `            ``1` `        ``/ \` `        ``2     3` `    ``/ \ /` `    ``4 5 6 / 7` `"""` `# to store the height of tree during traversal`   `root ``=` `Node(``1``)` `root.left ``=` `Node(``2``)` `root.right ``=` `Node(``3``)` `root.left.left ``=` `Node(``4``)` `root.left.right ``=` `Node(``5``)` `root.right.left ``=` `Node(``6``)` `root.left.left.left ``=` `Node(``7``)`   `if` `isBalanced(root):` `    ``print``(``'Tree is balanced'``)` `else``:` `    ``print``(``'Tree is not balanced'``)`   `# This code is contributed by Shubhank Gupta`

## C#

 `using` `System;`   `/* C# program to determine if binary tree is ` `   ``height balanced or not */`   `/* A binary tree node has data, pointer to left child, ` `   ``and a pointer to right child */` `public` `class` `Node {`   `    ``public` `int` `data;` `    ``public` `Node left, right;`   `    ``public` `Node(``int` `d)` `    ``{` `        ``data = d;` `        ``left = right = ``null``;` `    ``}` `}`   `// A wrapper class used to modify height across` `// recursive calls.` `public` `class` `Height {` `    ``public` `int` `height = 0;` `}`   `public` `class` `BinaryTree {`   `    ``public` `Node root;`   `    ``/* Returns true if binary tree with root as root is height-balanced */` `    ``public` `virtual` `bool` `isBalanced(Node root, Height height)` `    ``{` `        ``/* If tree is empty then return true */` `        ``if` `(root == ``null``) {` `            ``height.height = 0;` `            ``return` `true``;` `        ``}`   `        ``/* Get heights of left and right sub trees */` `        ``Height lheight = ``new` `Height(), rheight = ``new` `Height();` `        ``bool` `l = isBalanced(root.left, lheight);` `        ``bool` `r = isBalanced(root.right, rheight);` `        ``int` `lh = lheight.height, rh = rheight.height;`   `        ``/* Height of current node is max of heights of ` `           ``left and right subtrees plus 1*/` `        ``height.height = (lh > rh ? lh : rh) + 1;`   `        ``/* If difference between heights of left and right ` `           ``subtrees is more than 2 then this node is not balanced ` `           ``so return 0 */` `        ``if` `(Math.Abs(lh - rh) >= 2) {` `            ``return` `false``;` `        ``}`   `        ``/* If this node is balanced and left and right subtrees ` `           ``are balanced then return true */` `        ``else` `{` `            ``return` `l && r;` `        ``}` `    ``}`   `    ``/*  The function Compute the "height" of a tree. Height is the ` `        ``number of nodes along the longest path from the root node ` `        ``down to the farthest leaf node.*/` `    ``public` `virtual` `int` `height(Node node)` `    ``{` `        ``/* base case tree is empty */` `        ``if` `(node == ``null``) {` `            ``return` `0;` `        ``}`   `        ``/* If tree is not empty then height = 1 + max of left ` `         ``height and right heights */` `        ``return` `1 + Math.Max(height(node.left), height(node.right));` `    ``}`   `    ``public` `static` `void` `Main(``string``[] args)` `    ``{` `        ``Height height = ``new` `Height();`   `        ``/* Constructed binary tree is ` `                   ``1 ` `                 ``/   \ ` `                ``2      3 ` `              ``/  \    / ` `            ``4     5  6 ` `            ``/ ` `           ``7         */` `        ``BinaryTree tree = ``new` `BinaryTree();` `        ``tree.root = ``new` `Node(1);` `        ``tree.root.left = ``new` `Node(2);` `        ``tree.root.right = ``new` `Node(3);` `        ``tree.root.left.left = ``new` `Node(4);` `        ``tree.root.left.right = ``new` `Node(5);` `        ``tree.root.right.right = ``new` `Node(6);` `        ``tree.root.left.left.left = ``new` `Node(7);`   `        ``if` `(tree.isBalanced(tree.root, height)) {` `            ``Console.WriteLine(``"Tree is balanced"``);` `        ``}` `        ``else` `{` `            ``Console.WriteLine(``"Tree is not balanced"``);` `        ``}` `    ``}` `}`   `// This code is contributed by Shrikant13`

## Javascript

 ``

Output:

`Tree is balanced`

Time Complexity: O(n)
Auxiliary Space: O(n)