Open In App

Find Count of Single Valued Subtrees

Improve
Improve
Like Article
Like
Save
Share
Report

Given a binary tree, write a program to count the number of Single Valued Subtrees. A Single Valued Subtree is one in which all the nodes have same value. Expected time complexity is O(n).

Example: 

Input: root of below tree
5
/ \
1 5
/ \ \
5 5 5
Output: 4
There are 4 subtrees with single values.
Input: root of below tree
5
/ \
4 5
/ \ \
4 4 5
Output: 5
There are five subtrees with single values.

We strongly recommend you to minimize your browser and try this yourself first.

A Simple Solution is to traverse the tree. For every traversed node, check if all values under this node are same or not. If same, then increment count. Time complexity of this solution is O(n2).
An Efficient Solution is to traverse the tree in bottom up manner. For every subtree visited, return true if subtree rooted under it is single valued and increment count. So the idea is to use count as a reference parameter in recursive calls and use returned values to find out if left and right subtrees are single valued or not. 

Below is the implementation of above idea. 

C++




// C++ program to find count of single valued subtrees
#include<bits/stdc++.h>
using namespace std;
 
// A Tree node
struct Node
{
    int data;
    struct Node* left, *right;
};
 
// Utility function to create a new node
Node* newNode(int data)
{
    Node* temp = new Node;
    temp->data = data;
    temp->left = temp->right = NULL;
    return (temp);
}
 
// This function increments count by number of single
// valued subtrees under root. It returns true if subtree
// under root is Singly, else false.
bool countSingleRec(Node* root, int &count)
{
    // Return true to indicate NULL
    if (root == NULL)
       return true;
 
    // Recursively count in left and right subtrees also
    bool left = countSingleRec(root->left, count);
    bool right = countSingleRec(root->right, count);
 
    // If any of the subtrees is not singly, then this
    // cannot be singly.
    if (left == false || right == false)
       return false;
 
    // If left subtree is singly and non-empty, but data
    // doesn't match
    if (root->left && root->data != root->left->data)
        return false;
 
    // Same for right subtree
    if (root->right && root->data != root->right->data)
        return false;
 
    // If none of the above conditions is true, then
    // tree rooted under root is single valued, increment
    // count and return true.
    count++;
    return true;
}
 
// This function mainly calls countSingleRec()
// after initializing count as 0
int countSingle(Node* root)
{
    // Initialize result
    int count = 0;
 
    // Recursive function to count
    countSingleRec(root, count);
 
    return count;
}
 
// Driver program to test
int main()
{
    /* Let us construct the below tree
            5
          /   \
        4      5
      /  \      \
     4    4      5 */
    Node* root        = newNode(5);
    root->left        = newNode(4);
    root->right       = newNode(5);
    root->left->left  = newNode(4);
    root->left->right = newNode(4);
    root->right->right = newNode(5);
 
    cout << "Count of Single Valued Subtrees is "
         << countSingle(root);
    return 0;
}


Java




// Java program to find count of single valued subtrees
  
/* Class containing left and right child of current
 node and key value*/
class Node
{
    int data;
    Node left, right;
  
    public Node(int item)
    {
        data = item;
        left = right = null;
    }
}
  
class Count
{
    int count = 0;
}
  
class BinaryTree
{
    Node root; 
    Count ct = new Count();
      
    // This function increments count by number of single
    // valued subtrees under root. It returns true if subtree
    // under root is Singly, else false.
    boolean countSingleRec(Node node, Count c)
    {
        // Return false to indicate NULL
        if (node == null)
            return true;
          
        // Recursively count in left and right subtrees also
        boolean left = countSingleRec(node.left, c);
        boolean right = countSingleRec(node.right, c);
  
        // If any of the subtrees is not singly, then this
        // cannot be singly.
        if (left == false || right == false)
            return false;
  
        // If left subtree is singly and non-empty, but data
        // doesn't match
        if (node.left != null && node.data != node.left.data)
            return false;
  
        // Same for right subtree
        if (node.right != null && node.data != node.right.data)
            return false;
  
        // If none of the above conditions is true, then
        // tree rooted under root is single valued, increment
        // count and return true.
        c.count++;
        return true;
    }
  
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    int countSingle()
    {
        return countSingle(root);
    }
  
    int countSingle(Node node)
    {
        // Recursive function to count
        countSingleRec(node, ct);
        return ct.count;
    }
  
    // Driver program to test above functions
    public static void main(String args[])
    {
           /* Let us construct the below tree
                5
              /   \
            4      5
          /  \      \
         4    4      5 */
        BinaryTree tree = new BinaryTree();
        tree.root = new Node(5);
        tree.root.left = new Node(4);
        tree.root.right = new Node(5);
        tree.root.left.left = new Node(4);
        tree.root.left.right = new Node(4);
        tree.root.right.right = new Node(5);
  
        System.out.println("The count of single valued sub trees is : "
                                            + tree.countSingle());
    }
}
  
// This code has been contributed by Mayank Jaiswal


Python3




# Python program to find the count of single valued subtrees
 
# Node Structure
class Node:
    # Utility function to create a new node
    def __init__(self ,data):
        self.data = data
        self.left = None
        self.right = None
 
 
# This function increments count by number of single
# valued subtrees under root. It returns true if subtree
# under root is Singly, else false.
def countSingleRec(root , count):
    # Return False to indicate None
    if root is None :
        return True
 
    # Recursively count in left and right subtrees also
    left = countSingleRec(root.left , count)
    right = countSingleRec(root.right , count)
     
    # If any of the subtrees is not singly, then this
    # cannot be singly
    if left == False or right  == False :
        return False
     
    # If left subtree is singly and non-empty , but data
    # doesn't match
    if root.left and root.data != root.left.data:
        return False
 
    # same for right subtree
    if root.right and root.data != root.right.data:
        return False
 
    # If none of the above conditions is True, then
    # tree rooted under root is single valued,increment
    # count and return true
    count[0] += 1
    return True
 
 
# This function mainly class countSingleRec()
# after initializing count as 0
def countSingle(root):
    # initialize result
    count = [0]
 
    # Recursive function to count
    countSingleRec(root , count)
 
    return count[0]
 
 
# Driver program to test
 
"""Let us construct the below tree
            5
          /   \
        4       5
       /  \      \
      4    4      5
"""
root = Node(5)
root.left = Node(4)
root.right = Node(5)
root.left.left = Node(4)
root.left.right = Node(4)
root.right.right = Node(5)
countSingle(root)
print ("Count of Single Valued Subtrees is" , countSingle(root))
 
# This code is contributed by Nikhil Kumar Singh(nickzuck_007)


C#




using System;
 
// C# program to find count of single valued subtrees
 
/* Class containing left and right child of current 
 node and key value*/
public class Node
{
    public int data;
    public Node left, right;
 
    public Node(int item)
    {
        data = item;
        left = right = null;
    }
}
 
public class Count
{
    public int count = 0;
}
 
public class BinaryTree
{
    public Node root;
    public Count ct = new Count();
 
    // This function increments count by number of single 
    // valued subtrees under root. It returns true if subtree 
    // under root is Singly, else false.
    public virtual bool countSingleRec(Node node, Count c)
    {
        // Return false to indicate NULL
        if (node == null)
        {
            return true;
        }
 
        // Recursively count in left and right subtrees also
        bool left = countSingleRec(node.left, c);
        bool right = countSingleRec(node.right, c);
 
        // If any of the subtrees is not singly, then this
        // cannot be singly.
        if (left == false || right == false)
        {
            return false;
        }
 
        // If left subtree is singly and non-empty, but data
        // doesn't match
        if (node.left != null && node.data != node.left.data)
        {
            return false;
        }
 
        // Same for right subtree
        if (node.right != null && node.data != node.right.data)
        {
            return false;
        }
 
        // If none of the above conditions is true, then
        // tree rooted under root is single valued, increment
        // count and return true.
        c.count++;
        return true;
    }
 
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    public virtual int countSingle()
    {
        return countSingle(root);
    }
 
    public virtual int countSingle(Node node)
    {
        // Recursive function to count
        countSingleRec(node, ct);
        return ct.count;
    }
 
    // Driver program to test above functions
    public static void Main(string[] args)
    {
           /* Let us construct the below tree
                5
              /   \
            4      5
          /  \      \
         4    4      5 */
        BinaryTree tree = new BinaryTree();
        tree.root = new Node(5);
        tree.root.left = new Node(4);
        tree.root.right = new Node(5);
        tree.root.left.left = new Node(4);
        tree.root.left.right = new Node(4);
        tree.root.right.right = new Node(5);
 
        Console.WriteLine("The count of single valued sub trees is : " + tree.countSingle());
    }
}
 
  // This code is contributed by Shrikant13


Javascript




<script>
// javascript program to find count of single valued subtrees
  
/* Class containing left and right child of current
 node and key value*/
class Node
{
    constructor(item)
    {
        this.data = item;
        this.left = this.right = null;
    }
}
  
class Count
{
constructor(){
    this.count = 0;
    }
}
  
var root; 
    var ct = new Count();
      
    // This function increments count by number of single
    // valued subtrees under root. It returns true if subtree
    // under root is Singly, else false.
    function countSingleRec( node,  c)
    {
        // Return false to indicate NULL
        if (node == null)
            return true;
          
        // Recursively count in left and right subtrees also
        var left = countSingleRec(node.left, c);
        var right = countSingleRec(node.right, c);
  
        // If any of the subtrees is not singly, then this
        // cannot be singly.
        if (left == false || right == false)
            return false;
  
        // If left subtree is singly and non-empty, but data
        // doesn't match
        if (node.left != null && node.data != node.left.data)
            return false;
  
        // Same for right subtree
        if (node.right != null && node.data != node.right.data)
            return false;
  
        // If none of the above conditions is true, then
        // tree rooted under root is single valued, increment
        // count and return true.
        c.count++;
        return true;
    }
  
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    function countSingle()
    {
        return countSingle(root);
    }
  
    function countSingle( node)
    {
        // Recursive function to count
        countSingleRec(node, ct);
        return ct.count;
    }
  
    // Driver program to test above functions
      
 
           /* Let us construct the below tree
                5
              /   \
            4      5
          /  \      \
         4    4      5 */
 
        root = new Node(5);
        root.left = new Node(4);
        root.right = new Node(5);
        root.left.left = new Node(4);
        root.left.right = new Node(4);
        root.right.right = new Node(5);
  
        document.write("The count of single valued sub trees is : "
                                            + countSingle(root));
 
// This code contributed by aashish1995
</script>


Output

Count of Single Valued Subtrees is 5






Time complexity of this solution is O(n) where n is number of nodes in given binary tree.
Auxiliary Space: O(h) where h is the height of the tree due to recursion call.

Approach 2: Breadth First Search:

Here’s the overall approach of the algorithm using BFS:

  • The algorithm includes a helper method to check if a given node is part of a singly valued subtree. It compares the node’s value with its left and right child nodes’ values.
  • The algorithm initializes the count variable to 0.
  • It performs a BFS traversal using a queue. It starts by enqueuing the root node.
  • Inside the BFS loop, it dequeues a node and checks if it is singly valued.
  • If the current node is singly valued, it increments the count variable.
  • The algorithm enqueues the left and right child nodes of the current node, if they exist.
  • Once the BFS traversal is complete, the count variable contains the total count of single-valued subtrees.
  • The algorithm returns the count of single-valued subtrees.

Here is the code of above approach:

C++




#include <iostream>
#include <queue>
using namespace std;
 
// Class containing left and right child of current
// node and key value
class Node
{
public:
    int data;
    Node *left, *right;
 
    Node(int item)
    {
        data = item;
        left = right = NULL;
    }
};
 
class Count
{
public:
    int count = 0;
};
 
class BinaryTree
{
public:
    Node *root;
    Count ct;
 
    // This function increments count by number of single
    // valued subtrees under root. It returns true if subtree
    // under root is Singly, else false.
    bool countSingleRec(Node *node, Count &c)
    {
        // Return false to indicate NULL
        if (node == NULL)
        {
            return true;
        }
 
        // Perform BFS
        queue<Node *> q;
        q.push(node);
 
        while (!q.empty())
        {
            Node *curr = q.front();
            q.pop();
 
            // Check if the current node is singly valued
            if (isSingleValued(curr))
            {
                c.count++;
            }
 
            // Enqueue the left and right child nodes
            if (curr->left != NULL)
            {
                q.push(curr->left);
            }
            if (curr->right != NULL)
            {
                q.push(curr->right);
            }
        }
 
        return true;
    }
 
    // Helper function to check if a node is singly valued
    bool isSingleValued(Node *node)
    {
        if (node->left != NULL && node->data != node->left->data)
        {
            return false;
        }
        if (node->right != NULL && node->data != node->right->data)
        {
            return false;
        }
 
        return true;
    }
 
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    int countSingle()
    {
        return countSingle(root);
    }
 
    int countSingle(Node *node)
    {
        // Recursive function to count
        countSingleRec(node, ct);
        return ct.count;
    }
};
 
// Driver program to test above functions
int main()
{
    /* Let us construct the below tree
            5
           / \
          4   5
         / \   \
        4   4   5 */
    BinaryTree tree;
    tree.root = new Node(5);
    tree.root->left = new Node(4);
    tree.root->right = new Node(5);
    tree.root->left->left = new Node(4);
    tree.root->left->right = new Node(4);
    tree.root->right->right = new Node(5);
 
    cout << "The count of single valued subtrees is: " << tree.countSingle() << endl;
 
    return 0;
}


Java




import java.util.LinkedList;
import java.util.Queue;
 
class Node {
    int data;
    Node left, right;
 
    Node(int item) {
        data = item;
        left = right = null;
    }
}
 
class Count {
    int count = 0;
}
 
class BinaryTree {
    Node root;
    Count ct = new Count();
 
    // This function increments count by number of single valued subtrees under root.
    // It returns true if subtree under root is singly valued, else false.
    boolean countSingleRec(Node node, Count c) {
        if (node == null) {
            return true;
        }
 
        Queue<Node> queue = new LinkedList<>();
        queue.add(node);
 
        while (!queue.isEmpty()) {
            Node curr = queue.poll();
 
            if (isSingleValued(curr)) {
                c.count++;
            }
 
            if (curr.left != null) {
                queue.add(curr.left);
            }
            if (curr.right != null) {
                queue.add(curr.right);
            }
        }
 
        return true;
    }
 
    // Helper function to check if a node is singly valued
    boolean isSingleValued(Node node) {
        if (node.left != null && node.data != node.left.data) {
            return false;
        }
        if (node.right != null && node.data != node.right.data) {
            return false;
        }
 
        return true;
    }
 
    // This function mainly calls countSingleRec() after initializing count as 0
    int countSingle() {
        return countSingleRec(root, ct) ? ct.count : 0;
    }
 
    // Driver program to test above functions
    public static void main(String[] args) {
        // Let us construct the below tree
        //        5
        //       / \
        //      4   5
        //     / \   \
        //    4   4   5
        BinaryTree tree = new BinaryTree();
        tree.root = new Node(5);
        tree.root.left = new Node(4);
        tree.root.right = new Node(5);
        tree.root.left.left = new Node(4);
        tree.root.left.right = new Node(4);
        tree.root.right.right = new Node(5);
 
        System.out.println("The count of single valued subtrees is: " + tree.countSingle());
    }
}


Python




from collections import deque
 
class Node:
    def __init__(self, item):
        self.data = item
        self.left = None
        self.right = None
 
class Count:
    def __init__(self):
        self.count = 0
 
class BinaryTree:
    def __init__(self):
        self.root = None
        self.ct = Count()
 
    def countSingleRec(self, node, c):
        if node is None:
            return True
 
        q = deque()
        q.append(node)
 
        while q:
            curr = q.popleft()
 
            if self.isSingleValued(curr):
                c.count += 1
 
            if curr.left:
                q.append(curr.left)
            if curr.right:
                q.append(curr.right)
 
        return True
 
    def isSingleValued(self, node):
        if node.left and node.data != node.left.data:
            return False
        if node.right and node.data != node.right.data:
            return False
 
        return True
 
    def countSingle(self):
        self.countSingleRec(self.root, self.ct)
        return self.ct.count
 
if __name__ == "__main__":
    # Construct the tree
    tree = BinaryTree()
    tree.root = Node(5)
    tree.root.left = Node(4)
    tree.root.right = Node(5)
    tree.root.left.left = Node(4)
    tree.root.left.right = Node(4)
    tree.root.right.right = Node(5)
 
    print("The count of single valued subtrees is:", tree.countSingle())


C#




using System;
using System.Collections.Generic;
 
/* Class containing left and right child of current
node and key value*/
public class Node
{
    public int data;
    public Node left, right;
 
    public Node(int item)
    {
        data = item;
        left = right = null;
    }
}
 
public class Count
{
    public int count = 0;
}
 
public class BinaryTree
{
    public Node root;
    public Count ct = new Count();
 
    // This function increments count by number of single
    // valued subtrees under root. It returns true if subtree
    // under root is Singly, else false.
    public virtual bool countSingleRec(Node node, Count c)
    {
        // Return false to indicate NULL
        if (node == null)
        {
            return true;
        }
 
        // Perform BFS
        Queue<Node> queue = new Queue<Node>();
        queue.Enqueue(node);
 
        while (queue.Count > 0)
        {
            Node curr = queue.Dequeue();
 
            // Check if the current node is singly valued
            if (isSingleValued(curr))
            {
                c.count++;
            }
 
            // Enqueue the left and right child nodes
            if (curr.left != null)
            {
                queue.Enqueue(curr.left);
            }
            if (curr.right != null)
            {
                queue.Enqueue(curr.right);
            }
        }
 
        return true;
    }
 
    // Helper function to check if a node is singly valued
    private bool isSingleValued(Node node)
    {
        if (node.left != null && node.data != node.left.data)
        {
            return false;
        }
        if (node.right != null && node.data != node.right.data)
        {
            return false;
        }
 
        return true;
    }
 
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    public virtual int countSingle()
    {
        return countSingle(root);
    }
 
    public virtual int countSingle(Node node)
    {
        // Recursive function to count
        countSingleRec(node, ct);
        return ct.count;
    }
 
    // Driver program to test above functions
    public static void Main(string[] args)
    {
        /* Let us construct the below tree
                5
               / \
              4   5
             / \   \
            4   4   5 */
        BinaryTree tree = new BinaryTree();
        tree.root = new Node(5);
        tree.root.left = new Node(4);
        tree.root.right = new Node(5);
        tree.root.left.left = new Node(4);
        tree.root.left.right = new Node(4);
        tree.root.right.right = new Node(5);
 
        Console.WriteLine("The count of single valued subtrees is: " + tree.countSingle());
    }
}


Javascript




class Node {
    constructor(item) {
        this.data = item;
        this.left = this.right = null;
    }
}
 
class Count {
    constructor() {
        this.count = 0;
    }
}
 
class BinaryTree {
    constructor() {
        this.root = null;
        this.ct = new Count();
    }
 
    // This function increments count by the number of single
    // valued subtrees under root. It returns true if the subtree
    // under root is singly, else false.
    countSingleRec(node, c) {
        // Return true to indicate null node
        if (node === null) {
            return true;
        }
 
        // Perform BFS
        const queue = [];
        queue.push(node);
 
        while (queue.length !== 0) {
            const curr = queue.shift();
 
            // Check if the current node is singly valued
            if (this.isSingleValued(curr)) {
                c.count++;
            }
 
            // Enqueue the left and right child nodes
            if (curr.left !== null) {
                queue.push(curr.left);
            }
            if (curr.right !== null) {
                queue.push(curr.right);
            }
        }
 
        return true;
    }
 
    // Helper function to check if a node is singly valued
    isSingleValued(node) {
        if (node.left !== null && node.data !== node.left.data) {
            return false;
        }
        if (node.right !== null && node.data !== node.right.data) {
            return false;
        }
 
        return true;
    }
 
    // This function mainly calls countSingleRec()
    // after initializing count as 0
    countSingle() {
        return this.countSingle(this.root);
    }
 
    countSingle(node) {
        // Recursive function to count
        this.countSingleRec(node, this.ct);
        return this.ct.count;
    }
}
 
// Driver program to test above functions
function main() {
    /* Let us construct the below tree
                5
               / \
              4   5
             / \   \
            4   4   5 */
 
    const tree = new BinaryTree();
    tree.root = new Node(5);
    tree.root.left = new Node(4);
    tree.root.right = new Node(5);
    tree.root.left.left = new Node(4);
    tree.root.left.right = new Node(4);
    tree.root.right.right = new Node(5);
 
    console.log("The count of single valued subtrees is:", tree.countSingle());
}
 
main();


Output

The count of single valued sub trees is : 5

Time complexity: O(n),  where n is the number of nodes in given binary tree.
Auxiliary Space: O(h), where h is the height of the tree due to recursion call.



Last Updated : 04 Oct, 2023
Like Article
Save Article
Previous
Next
Share your thoughts in the comments
Similar Reads