Construct a BST from given postorder traversal using Stack
Given postorder traversal of a binary search tree, construct the BST.
For example,
If the given traversal is {1, 7, 5, 50, 40, 10}, then following tree should be constructed and root of the tree should be returned.
10 / \ 5 40 / \ \ 1 7 50
Input : 1 7 5 50 40 10
Output :
Inorder traversal of the constructed tree:
1 5 7 10 40 50
If the given traversal is {2, 6, 4, 9, 13, 11, 7}, then following tree should be constructed and root of the tree should be returned.
7 / \ 4 11 / \ / \ 2 6 9 13
Input : 2 6 4 9 13 11 7
Output :
Inorder traversal of the constructed tree:
2 4 6 7 9 11 13
Let us first see working Postorder traversal.
Left Right Root Hence last node of post order will be root of tree, create it and push to stack. If next element(i-1) is greater then it should be in right subtree. If next element(i-1) is less then it should be in left subtree.
Algorithm:
- Create an empty stack.
- Initialize the root node as the last element in the postorder traversal array. Push the root node to the stack.
- Iterate through the rest of the elements in the postorder traversal array, starting from the second last element.
- For each element in the array:
- If the element is less than the root node, set it as the left child of the root node and push it to the stack.
- If the element is greater than the root node, pop the top element from the stack and set it as the right child of the popped element. Repeat this until the element is less than or equal to the top element of the stack or the stack is empty. Then, push the element to the stack.
- When all elements in the postorder traversal array have been processed, the stack will contain the nodes of the BST in the order they were added. You can use this stack to construct the BST by setting the left and right children of each node according to the next nodes in the stack.
Below is the implementation of the above algorithm.
C++
// C++ implementation of the algorithm /* A binary tree node has data, pointer to left child and a pointer to right child */ #include<bits/stdc++.h> using namespace std; // Class Node has data and references // to the left and the right child. class Node { public : int data; Node* left, *right; Node( int data) { this ->data = data; left = right = NULL; } }; // Function that creates the tree Node* constructTreeUtil( int post[], int n) { // Last node is root Node* root = new Node(post[n - 1]); stack<Node*> s; s.push(root); // Traverse from second last node for ( int i = n - 2; i >= 0; --i) { Node* x = new Node(post[i]); // Keep popping nodes while top() // of stack is greater. Node* temp = NULL; while (s.size() && post[i] < s.top()->data) temp = s.top(), s.pop(); // Make x as left child of temp if (temp != NULL) temp->left = x; // Else make x as right of top else s.top()->right = x; s.push(x); } return root; } // Function that calls the method // which constructs the tree Node* constructTree( int post[], int size) { return constructTreeUtil(post, size); } // A utility function to print // inorder traversal of a Binary Tree void printInorder(Node* node) { if (node == NULL) return ; printInorder(node->left); cout << node->data << " " ; printInorder(node->right); } // Driver Code int main() { int post[] = { 1, 7, 5, 50, 40, 10 }; int size = sizeof (post)/ sizeof ( int ); Node* root = constructTree(post, size); cout << "Inorder traversal of " << "the constructed tree:\n" ; printInorder(root); } // This code is contributed by Arnab Kundu |
Java
// Java implementation of the algorithm /* A binary tree node has data, pointer to left child and a pointer to right child */ import java.util.*; // Class Node has data and references to the left // and the right child. class Node { int data; Node left, right; Node( int data) { this .data = data; left = right = null ; } } class BinaryTree { // Function that creates the tree Node constructTreeUtil( int post[], int n) { // Last node is root Node root = new Node(post[n - 1 ]); Stack<Node> s = new Stack<>(); s.push(root); // Traverse from second last node for ( int i = n - 2 ; i >= 0 ; --i) { Node x = new Node(post[i]); // Keep popping nodes while top() of stack // is greater. Node temp = null ; while (!s.isEmpty() && post[i] < s.peek().data) temp = s.pop(); // Make x as left child of temp if (temp != null ) temp.left = x; // Else make x as right of top else s.peek().right = x; s.push(x); } return root; } // Function that calls the method which constructs the tree Node constructTree( int post[], int size) { return constructTreeUtil(post, size); } // A utility function to print inorder traversal // of a Binary Tree void printInorder(Node node) { if (node == null ) return ; printInorder(node.left); System.out.print(node.data + " " ); printInorder(node.right); } // Driver program to test above functions public static void main(String[] args) { BinaryTree tree = new BinaryTree(); int post[] = new int [] { 1 , 7 , 5 , 50 , 40 , 10 }; int size = post.length; Node root = tree.constructTree(post, size); System.out.println( "Inorder traversal of the constructed tree:" ); tree.printInorder(root); } } |
Python3
# Python3 implementation of the algorithm # A binary tree node has data, # pointer to left child and a pointer # to right child # Class Node has data and references # to the left and the right child. class Node: def __init__( self , data = 0 ): self .data = data self .left = None self .right = None # Function that creates the tree def constructTreeUtil(post , n): # Last node is root root = Node(post[n - 1 ]) s = [] s.append(root) i = n - 2 # Traverse from second last node while ( i > = 0 ): x = Node(post[i]) # Keep popping nodes while top() # of stack is greater. temp = None while ( len (s) > 0 and post[i] < s[ - 1 ].data) : temp = s[ - 1 ] s.pop() # Make x as left child of temp if (temp ! = None ): temp.left = x # Else make x as right of top else : s[ - 1 ].right = x s.append(x) i = i - 1 return root # Function that calls the method # which constructs the tree def constructTree( post, size): return constructTreeUtil(post, size) # A utility function to print # inorder traversal of a Binary Tree def printInorder( node): if (node = = None ): return printInorder(node.left) print ( node.data, end = " " ) printInorder(node.right) # Driver Code post = [ 1 , 7 , 5 , 50 , 40 , 10 ] size = len (post) root = constructTree(post, size) print ( "Inorder traversal of the constructed tree:" ) printInorder(root) # This code is contributed by Arnab Kundu |
C#
// C# implementation of the algorithm /* A binary tree node has data, pointer to left child and a pointer to right child */ using System; using System.Collections.Generic; // Class Node has data and references // to the left and the right child. public class Node { public int data; public Node left, right; public Node( int data) { this .data = data; left = right = null ; } } public class BinaryTree { // Function that creates the tree Node constructTreeUtil( int []post, int n) { // Last node is root Node root = new Node(post[n - 1]); Stack<Node> s = new Stack<Node>(); s.Push(root); // Traverse from second last node for ( int i = n - 2; i >= 0; --i) { Node x = new Node(post[i]); // Keep popping nodes while top() of stack // is greater. Node temp = null ; while (s.Count!=0 && post[i] < s.Peek().data) temp = s.Pop(); // Make x as left child of temp if (temp != null ) temp.left = x; // Else make x as right of top else s.Peek().right = x; s.Push(x); } return root; } // Function that calls the // method which constructs the tree Node constructTree( int []post, int size) { return constructTreeUtil(post, size); } // A utility function to print // inorder traversal of a Binary Tree void printInorder(Node node) { if (node == null ) return ; printInorder(node.left); Console.Write(node.data + " " ); printInorder(node.right); } // Driver code public static void Main() { BinaryTree tree = new BinaryTree(); int []post = new int [] { 1, 7, 5, 50, 40, 10 }; int size = post.Length; Node root = tree.constructTree(post, size); Console.WriteLine( "Inorder traversal of the constructed tree:" ); tree.printInorder(root); } } /* This code contributed by PrinciRaj1992 */ |
Javascript
<script> // JavaScript implementation of the algorithm /* A binary tree node has data, pointer to left child and a pointer to right child */ // Class Node has data and references // to the left and the right child. class Node { constructor(data) { this .data = data; this .left = null ; this .right = null ; } } // Function that creates the tree function constructTreeUtil(post, n) { // Last node is root var root = new Node(post[n - 1]); var s = []; s.push(root); // Traverse from second last node for ( var i = n - 2; i >= 0; --i) { var x = new Node(post[i]); // Keep popping nodes while top() of stack // is greater. var temp = null ; while (s.length!=0 && post[i] < s[s.length-1].data) temp = s.pop(); // Make x as left child of temp if (temp != null ) temp.left = x; // Else make x as right of top else s[s.length-1].right = x; s.push(x); } return root; } // Function that calls the // method which constructs the tree function constructTree(post, size) { return constructTreeUtil(post, size); } // A utility function to print // inorder traversal of a Binary Tree function printInorder(node) { if (node == null ) return ; printInorder(node.left); document.write(node.data + " " ); printInorder(node.right); } // Driver code var post = [1, 7, 5, 50, 40, 10]; var size = post.length; var root = constructTree(post, size); document.write( "Inorder traversal of the constructed tree:<br>" ); printInorder(root); </script> |
Output
Inorder traversal of the constructed tree: 1 5 7 10 40 50
complexity Analysis:
- Time complexity: O(n2) where n is size of input array
- Auxiliary space: O(n) because using Stack s