Given a Binary Tree consisting of N nodes, the task is to find the maximum width of the given tree where the maximum width is defined as the maximum of all the widths at each level of the given Tree.
The width of a tree for any level is defined as the number of nodes between the two extreme nodes of that level including the NULL node in between.
Examples:
Input:
1
/ \
2 3
/ \ \
4 5 8
/ \
6 7
Output: 4
Explanation:
The width of level 1 is 1
The width of level 2 is 2
The width of level 3 is 4 (because it has a null node in between 5 and 8)
The width of level 4 is 2Therefore, the maximum width of the tree is the maximum of all the widths i.e., max{1, 2, 4, 2} = 4.
Input:
1
/
2
/
3
Output: 1
Approach: The given problem can be solved by representing the Binary Tree as the array representation of the Heap. Assume the index of a node is i then the indices of their children are (2*i + 1) and (2*i + 2). Now, for each level, find the position of the leftmost node and rightmost node in each level, then the difference between them will give the width of that level. Follow the steps below to solve this problem:
- Initialize two HashMap, say HMMax and HMMin that stores the position of the leftmost node and rightmost node in each level
- Create a recursive function getMaxWidthHelper(root, lvl, i) that takes the root of the tree, starting level of the tree initially 0, and position of the root node of the tree initially 0 and perform the following steps:
- If the root of the tree is NULL, then return.
- Store the leftmost node index at level lvl in the HMMin.
- Store the rightmost node index at level lvl in the HMMax.
- Recursively call for the left sub-tree by updating the value of lvl to lvl + 1 and i to (2*i + 1).
- Recursively call for the right sub-tree by updating the value of lvl to lvl + 1 and i to (2*i + 2).
- Call the function getMaxWidthHelper(root, 0, 0) to fill the HashMap.
- After completing the above steps, print the maximum value of (HMMax(L) – HMMin(L) + 1) among all possible values of level L.
Below is the implementation of the above approach:
// C++ program for the above approach #include <bits/stdc++.h> using namespace std;
// Tree Node structure struct Node
{ int data;
Node *left, *right;
// Constructor
Node( int item)
{
data = item;
left = right = NULL;
}
}; Node *root; int maxx = 0;
// Stores the position of leftmost // and rightmost node in each level map< int , int > hm_min;
map< int , int > hm_max;
// Function to store the min and the // max index of each nodes in hashmaps void getMaxWidthHelper(Node *node,
int lvl, int i)
{ // Base Case
if (node == NULL)
{
return ;
}
// Stores rightmost node index
// in the hm_max
if (hm_max[lvl])
{
hm_max[lvl] = max(i, hm_max[lvl]);
}
else
{
hm_max[lvl] = i;
}
// Stores leftmost node index
// in the hm_min
if (hm_min[lvl])
{
hm_min[lvl] = min(i, hm_min[lvl]);
}
// Otherwise
else
{
hm_min[lvl] = i;
}
// If the left child of the node
// is not empty, traverse next
// level with index = 2*i + 1
getMaxWidthHelper(node->left, lvl + 1,
2 * i + 1);
// If the right child of the node
// is not empty, traverse next
// level with index = 2*i + 2
getMaxWidthHelper(node->right, lvl + 1,
2 * i + 2);
} // Function to find the maximum // width of the tree int getMaxWidth(Node *root)
{ // Helper function to fill
// the hashmaps
getMaxWidthHelper(root, 0, 0);
// Traverse to each level and
// find the maximum width
for ( auto lvl : hm_max)
{
maxx = max(maxx, hm_max[lvl.first] -
hm_min[lvl.first] + 1);
}
// Return the result
return maxx;
} // Driver Code int main()
{ /*
Constructed binary tree is:
1
/ \
2 3
/ \ \
4 5 8
/ \
6 7
*/
root = new Node(1);
root->left = new Node(2);
root->right = new Node(3);
root->left->left = new Node(4);
root->left->right = new Node(5);
root->right->right = new Node(8);
root->right->right->left = new Node(6);
root->right->right->right = new Node(7);
// Function Call
cout << (getMaxWidth(root));
} // This code is contributed by mohit kumar 29 |
// Java program for the above approach import java.util.*;
// Tree Node structure class Node {
int data;
Node left, right;
// Constructor
Node( int item)
{
data = item;
left = right = null ;
}
} // Driver Code public class Main {
Node root;
int maxx = 0 ;
// Stores the position of leftmost
// and rightmost node in each level
HashMap<Integer, Integer> hm_min
= new HashMap<>();
HashMap<Integer, Integer> hm_max
= new HashMap<>();
// Function to store the min and the
// max index of each nodes in hashmaps
void getMaxWidthHelper(Node node,
int lvl, int i)
{
// Base Case
if (node == null ) {
return ;
}
// Stores rightmost node index
// in the hm_max
if (hm_max.containsKey(lvl)) {
hm_max.put(lvl,
Math.max(
i, hm_max.get(lvl)));
}
else {
hm_max.put(lvl, i);
}
// Stores leftmost node index
// in the hm_min
if (hm_min.containsKey(lvl)) {
hm_min.put(lvl,
Math.min(
i, hm_min.get(lvl)));
}
// Otherwise
else {
hm_min.put(lvl, i);
}
// If the left child of the node
// is not empty, traverse next
// level with index = 2*i + 1
getMaxWidthHelper(node.left, lvl + 1 ,
2 * i + 1 );
// If the right child of the node
// is not empty, traverse next
// level with index = 2*i + 2
getMaxWidthHelper(node.right, lvl + 1 ,
2 * i + 2 );
}
// Function to find the maximum
// width of the tree
int getMaxWidth(Node root)
{
// Helper function to fill
// the hashmaps
getMaxWidthHelper(root, 0 , 0 );
// Traverse to each level and
// find the maximum width
for (Integer lvl : hm_max.keySet()) {
maxx
= Math.max(
maxx,
hm_max.get(lvl)
- hm_min.get(lvl) + 1 );
}
// Return the result
return maxx;
}
// Driver Code
public static void main(String args[])
{
Main tree = new Main();
/*
Constructed binary tree is:
1
/ \
2 3
/ \ \
4 5 8
/ \
6 7
*/
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( 8 );
tree.root.right.right.left = new Node( 6 );
tree.root.right.right.right = new Node( 7 );
// Function Call
System.out.println(
tree.getMaxWidth(
tree.root));
}
} |
# Python3 program for the above approach # Tree Node structure class Node:
def __init__( self , item):
self .data = item
self .left = None
self .right = None
maxx = 0
# Stores the position of leftmost # and rightmost node in each level hm_min = {}
hm_max = {}
# Function to store the min and the # max index of each nodes in hashmaps def getMaxWidthHelper(node, lvl, i):
# Base Case
if (node = = None ):
return
# Stores rightmost node index
# in the hm_max
if (lvl in hm_max):
hm_max[lvl] = max (i, hm_max[lvl])
else :
hm_max[lvl] = i
# Stores leftmost node index
# in the hm_min
if (lvl in hm_min):
hm_min[lvl] = min (i, hm_min[lvl])
# Otherwise
else :
hm_min[lvl] = i
# If the left child of the node
# is not empty, traverse next
# level with index = 2*i + 1
getMaxWidthHelper(node.left, lvl + 1 , 2 * i + 1 )
# If the right child of the node
# is not empty, traverse next
# level with index = 2*i + 2
getMaxWidthHelper(node.right, lvl + 1 , 2 * i + 2 )
# Function to find the maximum # width of the tree def getMaxWidth(root):
global maxx
# Helper function to fill
# the hashmaps
getMaxWidthHelper(root, 0 , 0 )
# Traverse to each level and
# find the maximum width
for lvl in hm_max.keys():
maxx = max (maxx, hm_max[lvl] - hm_min[lvl] + 1 )
# Return the result
return maxx
""" Constructed binary tree is: 1
/ \
2 3
/ \ \
4 5 8 / \
6 7
""" root = Node( 1 )
root.left = Node( 2 )
root.right = Node( 3 )
root.left.left = Node( 4 )
root.left.right = Node( 5 )
root.right.right = Node( 8 )
root.right.right.left = Node( 6 )
root.right.right.right = Node( 7 )
# Function Call print (getMaxWidth(root))
# This code is contributed by decode2207. |
// C# program for the above approach using System;
using System.Collections.Generic;
class GFG {
// A Binary Tree Node
class Node
{
public int data;
public Node left;
public Node right;
public Node( int item)
{
data = item;
left = right = null ;
}
};
static int maxx = 0;
// Stores the position of leftmost
// and rightmost node in each level
static Dictionary< int , int > hm_min = new Dictionary< int , int >();
static Dictionary< int , int > hm_max = new Dictionary< int , int >();
// Function to store the min and the
// max index of each nodes in hashmaps
static void getMaxWidthHelper(Node node,
int lvl, int i)
{
// Base Case
if (node == null ) {
return ;
}
// Stores rightmost node index
// in the hm_max
if (hm_max.ContainsKey(lvl)) {
hm_max[lvl] = Math.Max(i, hm_max[lvl]);
}
else {
hm_max[lvl] = i;
}
// Stores leftmost node index
// in the hm_min
if (hm_min.ContainsKey(lvl)) {
hm_min[lvl] = Math.Min(i, hm_min[lvl]);
}
// Otherwise
else {
hm_min[lvl] = i;
}
// If the left child of the node
// is not empty, traverse next
// level with index = 2*i + 1
getMaxWidthHelper(node.left, lvl + 1,
2 * i + 1);
// If the right child of the node
// is not empty, traverse next
// level with index = 2*i + 2
getMaxWidthHelper(node.right, lvl + 1,
2 * i + 2);
}
// Function to find the maximum
// width of the tree
static int getMaxWidth(Node root)
{
// Helper function to fill
// the hashmaps
getMaxWidthHelper(root, 0, 0);
// Traverse to each level and
// find the maximum width
foreach (KeyValuePair< int , int > lvl in hm_max) {
maxx = Math.Max(maxx, hm_max[lvl.Key] - hm_min[lvl.Key] + 1);
}
// Return the result
return maxx;
}
// Driver code
static void Main()
{
/*
Constructed binary tree is:
1
/ \
2 3
/ \ \
4 5 8
/ \
6 7
*/
Node root = new Node(1);
root.left = new Node(2);
root.right = new Node(3);
root.left.left = new Node(4);
root.left.right = new Node(5);
root.right.right = new Node(8);
root.right.right.left = new Node(6);
root.right.right.right = new Node(7);
// Function Call
Console.Write(getMaxWidth(root));
}
} // This code is contributed by divyeshrabadiya07. |
<script> // JavaScript program for the above approach // Tree Node structure class Node { constructor(item)
{
this .data=item;
this .left= this .right= null ;
}
} // Driver Code let root; let maxx = 0; // Stores the position of leftmost // and rightmost node in each level
let hm_min= new Map();
let hm_max= new Map();
// Function to store the min and the // max index of each nodes in hashmaps
function getMaxWidthHelper(node,lvl,i)
{ // Base Case
if (node == null ) {
return ;
}
// Stores rightmost node index
// in the hm_max
if (hm_max.has(lvl)) {
hm_max.set(lvl,
Math.max(
i, hm_max.get(lvl)));
}
else {
hm_max.set(lvl, i);
}
// Stores leftmost node index
// in the hm_min
if (hm_min.has(lvl)) {
hm_min.set(lvl,
Math.min(
i, hm_min.get(lvl)));
}
// Otherwise
else {
hm_min.set(lvl, i);
}
// If the left child of the node
// is not empty, traverse next
// level with index = 2*i + 1
getMaxWidthHelper(node.left, lvl + 1,
2 * i + 1);
// If the right child of the node
// is not empty, traverse next
// level with index = 2*i + 2
getMaxWidthHelper(node.right, lvl + 1,
2 * i + 2);
} // Function to find the maximum // width of the tree
function getMaxWidth(root)
{ // Helper function to fill
// the hashmaps
getMaxWidthHelper(root, 0, 0);
// Traverse to each level and
// find the maximum width
for (let [lvl, value] of hm_max.entries()) {
maxx
= Math.max(
maxx,
hm_max.get(lvl)
- hm_min.get(lvl) + 1);
}
// Return the result
return maxx;
} // Driver Code root = new Node(1);
root.left = new Node(2);
root.right = new Node(3);
root.left.left = new Node(4);
root.left.right = new Node(5);
root.right.right = new Node(8);
root.right.right.left = new Node(6);
root.right.right.right = new Node(7);
// Function Call document.write(getMaxWidth(root)); // This code is contributed by unknown2108 </script> |
4
Time Complexity: O(N)
Auxiliary Space: O(N)