Given a Binary Tree consisting of N nodes, the task is to print its Mix Order Traversal.
Mix Order Traversal is a tree traversal technique, which involves any two of the existing traversal techniques like Inorder, Preorder and Postorder Traversal. Any two of them can be performed or alternate levels of given tree and a mix traversal can be obtained.
Examples:
Input: N = 6
Output: 7 4 5 1 3 6
Explanation:
Inorder-Preorder Mix Traversal is applied to the given tree in the following order:
Inorder Traversal is applied at level 0
Preorder Traversal is applied at level 1
Inorder Traversal at level 2.
Output: 4 5 7 1 6 3
Explanation:
Inorder-Postorder Mix Traversal is applied to the given tree in the following order:
Inorder Traversal is applied at level 0
Postorder Traversal is applied at level 1
Inorder Traversal at level 2.
Approach:
The possible Mix Order Traversals are as follows:
Inorder-Preorder Mix Traversal
Steps for inorder() will be:
- Perform Preorder Traversal on the left subtree.
- Print the current node.
- Perform Preorder Traversal on right subtree.
Steps for preorder() will be:
- Print the current node.
- Perform Inorder Traversal on left subtree(root->left).
- Perform Inorder Traversal on right subtree.
Below is the implementation of the above approach:
// C++ Program to implement // the above approach #include <bits/stdc++.h> using namespace std;
void inOrder( struct node* root);
void preOrder( struct node* root);
// Node structure struct node {
char data;
struct node *left, *right;
}; // Creates and initialize a new node struct node* newNode( char ch)
{ // Allocating memory to a new node
struct node* n = ( struct node*)
malloc ( sizeof ( struct node));
n->data = ch;
n->left = NULL;
n->right = NULL;
return n;
} // Perform Inorder Traversal void inOrder( struct node* root)
{ if (root) {
preOrder(root->left);
cout << root->data << " " ;
preOrder(root->right);
}
} // Perform Preorder Traversal void preOrder( struct node* root)
{ if (root) {
cout << root->data << " " ;
inOrder(root->left);
inOrder(root->right);
}
} // Driver Code int main()
{ // Given tree
struct node* root = newNode( '1' );
root->left = newNode( '7' );
root->right = newNode( '3' );
root->left->left = newNode( '4' );
root->left->right = newNode( '5' );
root->right->left = newNode( '6' );
// Perform Mix order traversal
inOrder(root);
return 0;
} |
// Java program to implement // the above approach import java.util.*;
class GFG{
// Node structure static class node
{ char data;
node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Inorder Traversal static void inOrder(node root)
{ if (root != null )
{
preOrder(root.left);
System.out.print(root.data + " " );
preOrder(root.right);
}
} // Perform Preorder Traversal static void preOrder(node root)
{ if (root != null )
{
System.out.print(root.data + " " );
inOrder(root.left);
inOrder(root.right);
}
} // Driver Code public static void main(String[] args)
{ // Given tree
node root = newNode( '1' );
root.left = newNode( '7' );
root.right = newNode( '3' );
root.left.left = newNode( '4' );
root.left.right = newNode( '5' );
root.right.left = newNode( '6' );
// Perform Mix order traversal
inOrder(root);
} } // This code is contributed by 29AjayKumar |
# Python3 program to implement the above approach # Node structure class node:
def __init__( self ):
self .data = 0
self .left = None
self .right = None
# Creates and initialize a new node def newNode(ch):
# Allocating memory to a new node
n = node()
n.data = ch
n.left = None
n.right = None
return n
# Perform Inorder Traversal def inOrder(root):
if root ! = None :
preOrder(root.left)
print (root.data, end = " " )
preOrder(root.right)
# Perform Preorder Traversal def preOrder(root):
if root ! = None :
print (root.data, end = " " )
inOrder(root.left)
inOrder(root.right)
# Driver Code # Given tree root = newNode( '1' )
root.left = newNode( '7' )
root.right = newNode( '3' )
root.left.left = newNode( '4' )
root.left.right = newNode( '5' )
root.right.left = newNode( '6' )
# Perform Mix order traversal inOrder(root) # This code is contributed by divyeshrabadiya07. |
// C# program to implement // the above approach using System;
class GFG{
// Node structure class node
{ public char data;
public node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Inorder Traversal static void inOrder(node root)
{ if (root != null )
{
preOrder(root.left);
Console.Write(root.data + " " );
preOrder(root.right);
}
} // Perform Preorder Traversal static void preOrder(node root)
{ if (root != null )
{
Console.Write(root.data + " " );
inOrder(root.left);
inOrder(root.right);
}
} // Driver Code public static void Main(String[] args)
{ // Given tree
node root = newNode( '1' );
root.left = newNode( '7' );
root.right = newNode( '3' );
root.left.left = newNode( '4' );
root.left.right = newNode( '5' );
root.right.left = newNode( '6' );
// Perform Mix order traversal
inOrder(root);
} } // This code is contributed by sapnasingh4991 |
<script> // Javascript program to implement // the above approach // Node structure class node { constructor()
{
this .data = 0;
this .left = null ;
this .right = null ;
}
}; // Creates and initialize a new node function newNode(ch)
{ // Allocating memory to a new node
var n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Inorder Traversal function inOrder(root)
{ if (root != null )
{
preOrder(root.left);
document.write(root.data + " " );
preOrder(root.right);
}
} // Perform Preorder Traversal function preOrder(root)
{ if (root != null )
{
document.write(root.data + " " );
inOrder(root.left);
inOrder(root.right);
}
} // Driver Code // Given tree var root = newNode( '1' );
root.left = newNode( '7' );
root.right = newNode( '3' );
root.left.left = newNode( '4' );
root.left.right = newNode( '5' );
root.right.left = newNode( '6' );
// Perform Mix order traversal inOrder(root); </script> |
7 4 5 1 3 6
The time complexity for both inOrder and preOrder traversals is O(n), where n is the number of nodes in the tree. This is because each node is visited once.
Auxiliary space complexity:
The auxiliary space of newNode function is O(1), because it only allocates memory for a single node.
The auxiliary space complexity of inOrder and preOrder functions is O(h), where h is the height of the tree.
Preorder-Postorder Mix Traversal
Steps for preorder() are as follows:
- Print the current node.
- Perform Postorder traversal on left subtree.
- Perform Postorder Traversal on the right subtree.
Steps for postorder() are as follows:
- Perform preorder traversal on the left subtree.
- Perform preorder traversal on right subtree.
- Print the current node.
Below is the implementation of the above approach:
// C++ Program to implement // the above approach #include <bits/stdc++.h> using namespace std;
void preOrder( struct node* root);
void postOrder( struct node* root);
// Node structure struct node {
char data;
struct node *left, *right;
}; // Creates and initialize a new node struct node* newNode( char ch)
{ // Allocating memory to a new node
struct node* n = ( struct node*)
malloc ( sizeof ( struct node));
n->data = ch;
n->left = NULL;
n->right = NULL;
return n;
} // Perform Preorder Traversal void preOrder( struct node* root)
{ if (root) {
cout << root->data << " " ;
postOrder(root->left);
postOrder(root->right);
}
} // Perform Postorder Traversal void postOrder( struct node* root)
{ if (root) {
preOrder(root->left);
preOrder(root->right);
cout << root->data << " " ;
}
} // Driver Code int main()
{ // Given tree
struct node* root = newNode( 'A' );
root->left = newNode( 'B' );
root->right = newNode( 'C' );
root->left->left = newNode( 'F' );
root->left->right = newNode( 'D' );
root->right->right = newNode( 'E' );
// Starting Mix order traversal
preOrder(root);
return 0;
} |
// Java Program to implement // the above approach class GFG{
// Node structure static class node
{ char data;
node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Preorder Traversal static void preOrder(node root)
{ if (root != null )
{
System.out.print(root.data + " " );
postOrder(root.left);
postOrder(root.right);
}
} // Perform Postorder Traversal static void postOrder(node root)
{ if (root != null )
{
preOrder(root.left);
preOrder(root.right);
System.out.print(root.data + " " );
}
} // Driver Code public static void main(String[] args)
{ // Given tree
node root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
preOrder(root);
} } // This code is contributed by Rajput-Ji |
# Python3 Program to implement the above approach # Node structure class node:
def __init__( self ):
self .data = '0'
self .left = None
self .right = None
# Creates and initialize a new node def newNode(ch):
# Allocating memory to a new node
n = node()
n.data = ch
n.left = None
n.right = None
return n
# Perform Preorder Traversal def preOrder(root):
if root ! = None :
print (root.data, end = " " )
postOrder(root.left)
postOrder(root.right)
# Perform Postorder Traversal def postOrder(root):
if root ! = None :
preOrder(root.left)
preOrder(root.right)
print (root.data, end = " " )
# Given tree root = newNode( 'A' )
root.left = newNode( 'B' )
root.right = newNode( 'C' )
root.left.left = newNode( 'F' )
root.left.right = newNode( 'D' )
root.right.right = newNode( 'E' )
# Starting Mix order traversal preOrder(root) # This code is contributed by divyesh072019. |
// C# Program to implement // the above approach using System;
class GFG{
// Node structure class node
{ public char data;
public node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Preorder Traversal static void preOrder(node root)
{ if (root != null )
{
Console.Write(root.data + " " );
postOrder(root.left);
postOrder(root.right);
}
} // Perform Postorder Traversal static void postOrder(node root)
{ if (root != null )
{
preOrder(root.left);
preOrder(root.right);
Console.Write(root.data + " " );
}
} // Driver Code public static void Main(String[] args)
{ // Given tree
node root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
preOrder(root);
} } // This code is contributed by Rohit_ranjan |
<script> // Javascript Program to implement the above approach
// Node structure
class node
{
constructor() {
this .left;
this .right;
this .data;
}
}
// Creates and initialize a new node
function newNode(ch)
{
// Allocating memory to a new node
let n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
}
// Perform Preorder Traversal
function preOrder(root)
{
if (root != null )
{
document.write(root.data + " " );
postOrder(root.left);
postOrder(root.right);
}
}
// Perform Postorder Traversal
function postOrder(root)
{
if (root != null )
{
preOrder(root.left);
preOrder(root.right);
document.write(root.data + " " );
}
}
// Given tree
let root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
preOrder(root);
// This code is contributed by rameshtravel07.
</script> |
A F D B E C
Time Complexity: O(N) where N is the number of nodes in the tree.
Auxiliary Space: O(log(N))
Inorder-Postorder Mix Traversal
Steps for inorder() are as follows:
- Perform Postorder Traversal on the left subtree.
- Print the current node.
- Perform Postorder Traversal on the right subtree.
Steps for postorder() will be:
- Perform Inorder Traversal on left subtree.
- Perform Inorder Traversal on right subtree.
- Print the current node.
Below is the implementation of the above approach:
// C++ Program to implement // the above approach #include <bits/stdc++.h> using namespace std;
void inOrder( struct node* root);
void postOrder( struct node* root);
// Node structure struct node {
char data;
struct node *left, *right;
}; // Creates and initialize a new node struct node* newNode( char ch)
{ // Allocating memory to a new node
struct node* n = ( struct node*)
malloc ( sizeof ( struct node));
n->data = ch;
n->left = NULL;
n->right = NULL;
return n;
} // Perform Inorder Traversal void inOrder( struct node* root)
{ if (root) {
postOrder(root->left);
cout << root->data << " " ;
postOrder(root->right);
}
} // Perform Postorder Traversal void postOrder( struct node* root)
{ if (root) {
inOrder(root->left);
inOrder(root->right);
cout << root->data << " " ;
}
} // Driver Code int main()
{ // Given tree
struct node* root = newNode( 'A' );
root->left = newNode( 'B' );
root->right = newNode( 'C' );
root->left->left = newNode( 'F' );
root->left->right = newNode( 'D' );
root->right->right = newNode( 'E' );
// Starting Mix order traversal
inOrder(root);
return 0;
} |
// Java Program to implement // the above approach import java.util.*;
class GFG{
// Node structure static class node
{ char data;
node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Inorder Traversal static void inOrder(node root)
{ if (root != null )
{
postOrder(root.left);
System.out.print(root.data + " " );
postOrder(root.right);
}
} // Perform Postorder Traversal static void postOrder(node root)
{ if (root != null )
{
inOrder(root.left);
inOrder(root.right);
System.out.print(root.data + " " );
}
} // Driver Code public static void main(String[] args)
{ // Given tree
node root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
inOrder(root);
} } // This code is contributed by sapnasingh4991 |
# Python3 Program to implement the above approach # Node structure class node:
def __init__( self ):
self .data = '0'
self .left = None
self .right = None
# Creates and initialize a new node def newNode(ch):
# Allocating memory to a new node
n = node()
n.data = ch
n.left = None
n.right = None
return n
# Perform Inorder Traversal def inOrder(root):
if root ! = None :
postOrder(root.left)
print (root.data, end = " " )
postOrder(root.right)
# Perform Postorder Traversal def postOrder(root):
if root ! = None :
inOrder(root.left)
inOrder(root.right)
print (root.data, end = " " )
# Given tree root = newNode( 'A' )
root.left = newNode( 'B' )
root.right = newNode( 'C' )
root.left.left = newNode( 'F' )
root.left.right = newNode( 'D' )
root.right.right = newNode( 'E' )
# Starting Mix order traversal inOrder(root) # This code is contributed by decode2207. |
// C# Program to implement // the above approach using System;
class GFG{
// Node structure class node
{ public char data;
public node left, right;
}; // Creates and initialize a new node static node newNode( char ch)
{ // Allocating memory to a new node
node n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
} // Perform Inorder Traversal static void inOrder(node root)
{ if (root != null )
{
postOrder(root.left);
Console.Write(root.data + " " );
postOrder(root.right);
}
} // Perform Postorder Traversal static void postOrder(node root)
{ if (root != null )
{
inOrder(root.left);
inOrder(root.right);
Console.Write(root.data + " " );
}
} // Driver Code public static void Main(String[] args)
{ // Given tree
node root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
inOrder(root);
} } // This code is contributed by sapnasingh4991 |
<script> // Javascript Program to implement the above approach
// Node structure
class node
{
constructor() {
this .left;
this .right;
this .data;
}
}
// Creates and initialize a new node
function newNode(ch)
{
// Allocating memory to a new node
let n = new node();
n.data = ch;
n.left = null ;
n.right = null ;
return n;
}
// Perform Inorder Traversal
function inOrder(root)
{
if (root != null )
{
postOrder(root.left);
document.write(root.data + " " );
postOrder(root.right);
}
}
// Perform Postorder Traversal
function postOrder(root)
{
if (root != null )
{
inOrder(root.left);
inOrder(root.right);
document.write(root.data + " " );
}
}
// Given tree
let root = newNode( 'A' );
root.left = newNode( 'B' );
root.right = newNode( 'C' );
root.left.left = newNode( 'F' );
root.left.right = newNode( 'D' );
root.right.right = newNode( 'E' );
// Starting Mix order traversal
inOrder(root);
// This code is contributed by mukesh07.
</script> |
F D B A E C
Time Complexity: O(N)
Auxiliary Space: O(N)