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Iterative method to find ancestors of a given binary tree

Last Updated : 18 Sep, 2023
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Given a binary tree, print all the ancestors of a particular key existing in the tree without using recursion.
Here we will be discussing the implementation for the above problem. 

Examples: 

Input : 
            1
        /       \
       2         7
     /   \     /   \
    3     5    8    9 
   /       \       /
  4         6     10 
Key = 6 

Output : 5 2 1
Ancestors of 6 are 5, 2 and 1.

The idea is to use iterative postorder traversal of given binary tree.  

Algorithm:

Step 1: Start
Step 2: create a function of void return type called “printAncestors” which takes a root node and an integer value as input                          parameter.
             a. set the base condition as if root == null then return.
             b. create a stack of node types to hold ancestors
             c. start a while loop with condition 1==1 which means it will always be true.
                 1. Move each node into the stack by moving them up and along the left side of the tree starting at the root until we                            reach the node that matches the key. 
                 2. End the while loop if the node with the specified key is located.
                 3. Remove the node from the stack and assign it to the root if the right subtree of the node at the top of the stack, st, is                       null.
                 4. Pop that node as well if it is the right child of the node at the top of the stack, st.
                 5. Set root as the right child of the node at the top of the stack st if it is not empty and carry on exploring the right                               subtree.
Step 3: If the stack st is not empty when we have located the node with the specified key, print the data of each node in the stack              st starting at the top and continuing until the stack is empty.
Step 4: End

Implementation:

C++




// C++ program to print all ancestors of a given key
#include <bits/stdc++.h>
using namespace std;
  
// Structure for a tree node
struct Node {
    int data;
    struct Node* left, *right;
};
  
// A utility function to create a new tree node
struct Node* newNode(int data)
{
    struct Node* node = (struct Node*)malloc(sizeof(struct Node));
    node->data = data;
    node->left = node->right = NULL;
    return node;
}
  
// Iterative Function to print all ancestors of a
// given key
void printAncestors(struct Node* root, int key)
{
    if (root == NULL)
        return;
  
    // Create a stack to hold ancestors
    stack<struct Node*> st;
  
    // Traverse the complete tree in postorder way till
    // we find the key
    while (1) {
  
        // Traverse the left side. While traversing, push
        // the nodes into  the stack so that their right
        // subtrees can be traversed later
        while (root && root->data != key) {
            st.push(root); // push current node
            root = root->left; // move to next node
        }
  
        // If the node whose ancestors are to be printed
        // is found, then break the while loop.
        if (root && root->data == key)
            break;
  
        // Check if right sub-tree exists for the node at top
        // If not then pop that node because we don't need
        // this node any more.
        if (st.top()->right == NULL) {
            root = st.top();
            st.pop();
  
            // If the popped node is right child of top,
            // then remove the top as well. Left child of
            // the top must have processed before.
            while (!st.empty() && st.top()->right == root) {
                root = st.top();
                st.pop();
            }
        }
  
        // if stack is not empty then simply set the root
        // as right child of top and start traversing right
        // sub-tree.
        root = st.empty() ? NULL : st.top()->right;
    }
  
    // If stack is not empty, print contents of stack
    // Here assumption is that the key is there in tree
    while (!st.empty()) {
        cout << st.top()->data << " ";
        st.pop();
    }
}
  
// Driver program to test above functions
int main()
{
    // Let us construct a binary tree
    struct Node* root = newNode(1);
    root->left = newNode(2);
    root->right = newNode(7);
    root->left->left = newNode(3);
    root->left->right = newNode(5);
    root->right->left = newNode(8);
    root->right->right = newNode(9);
    root->left->left->left = newNode(4);
    root->left->right->right = newNode(6);
    root->right->right->left = newNode(10);
  
    int key = 6;
    printAncestors(root, key);
  
    return 0;
}


Java




// Java program to print all 
// ancestors of a given key 
import java.util.*;
  
class GfG 
{
  
// Structure for a tree node 
static class Node
    int data; 
    Node left, right; 
}
  
// A utility function to 
// create a new tree node 
static Node newNode(int data) 
    Node node = new Node(); 
    node.data = data; 
    node.left = null;
    node.right = null
    return node; 
  
// Iterative Function to print 
// all ancestors of a given key 
static void printAncestors(Node root, int key) 
    if (root == null
        return
  
    // Create a stack to hold ancestors 
    Stack<Node> st = new Stack<Node> (); 
  
    // Traverse the complete tree in 
    // postorder way till we find the key 
    while (1 == 1
    
  
        // Traverse the left side. While 
        // traversing, push the nodes into 
        // the stack so that their right 
        // subtrees can be traversed later 
        while (root != null && root.data != key) 
        
            st.push(root); // push current node 
            root = root.left; // move to next node 
        
  
        // If the node whose ancestors 
        // are to be printed is found,
        // then break the while loop. 
        if (root != null && root.data == key) 
            break
  
        // Check if right sub-tree exists
        // for the node at top If not then
        // pop that node because we don't  
        // need this node any more. 
        if (st.peek().right == null
        
            root = st.peek(); 
            st.pop(); 
  
            // If the popped node is right child of top, 
            // then remove the top as well. Left child of 
            // the top must have processed before. 
            while (!st.isEmpty() && st.peek().right == root)
            
                root = st.peek(); 
                st.pop(); 
            
        
  
        // if stack is not empty then simply 
        // set the root as right child of 
        // top and start traversing right 
        // sub-tree. 
        root = st.isEmpty() ? null : st.peek().right; 
    
  
    // If stack is not empty, print contents of stack 
    // Here assumption is that the key is there in tree 
    while (!st.isEmpty())
    
        System.out.print(st.peek().data + " "); 
        st.pop(); 
    
  
// Driver code 
public static void main(String[] args) 
    // Let us construct a binary tree 
    Node root = newNode(1); 
    root.left = newNode(2); 
    root.right = newNode(7); 
    root.left.left = newNode(3); 
    root.left.right = newNode(5); 
    root.right.left = newNode(8); 
    root.right.right = newNode(9); 
    root.left.left.left = newNode(4); 
    root.left.right.right = newNode(6); 
    root.right.right.left = newNode(10); 
  
    int key = 6
    printAncestors(root, key); 
}
}
  
// This code is contributed 
// by prerna saini


Python3




# Python program to print all ancestors of a given key
  
# A class to create a new tree node 
class newNode:
    def __init__(self, data):
        self.data = data 
        self.left = self.right = None
  
# Iterative Function to print all ancestors of a 
# given key 
def printAncestors(root, key):
    if (root == None): 
        return
  
    # Create a stack to hold ancestors 
    st = []
  
    # Traverse the complete tree in postorder way till 
    # we find the key 
    while (1):
  
        # Traverse the left side. While traversing, push 
        # the nodes into the stack so that their right 
        # subtrees can be traversed later 
        while (root and root.data != key): 
            st.append(root) # push current node 
            root = root.left # move to next node
  
        # If the node whose ancestors are to be printed 
        # is found, then break the while loop. 
        if (root and root.data == key): 
            break
  
        # Check if right sub-tree exists for the node at top 
        # If not then pop that node because we don't need 
        # this node any more. 
        if (st[-1].right == None): 
            root = st[-1
            st.pop() 
  
            # If the popped node is right child of top, 
            # then remove the top as well. Left child of 
            # the top must have processed before. 
            while (len(st) != 0 and st[-1].right == root): 
                root = st[-1
                st.pop()
  
        # if stack is not empty then simply set the root 
        # as right child of top and start traversing right 
        # sub-tree. 
        root = None if len(st) == 0 else st[-1].right
  
    # If stack is not empty, print contents of stack 
    # Here assumption is that the key is there in tree 
    while (len(st) != 0): 
        print(st[-1].data,end = " "
        st.pop()
  
# Driver code
if __name__ == '__main__':
  
    # Let us construct a binary tree 
    root = newNode(1
    root.left = newNode(2
    root.right = newNode(7
    root.left.left = newNode(3
    root.left.right = newNode(5
    root.right.left = newNode(8
    root.right.right = newNode(9
    root.left.left.left = newNode(4
    root.left.right.right = newNode(6
    root.right.right.left = newNode(10
  
    key = 6
    printAncestors(root, key)
      
# This code is contributed by PranchalK.


C#




// C# program to print all 
// ancestors of a given key 
using System;
using System.Collections.Generic;
  
class GfG 
{
  
// Structure for a tree node 
public class Node
    public int data; 
    public Node left, right; 
}
  
// A utility function to 
// create a new tree node 
static Node newNode(int data) 
    Node node = new Node(); 
    node.data = data; 
    node.left = null;
    node.right = null
    return node; 
  
// Iterative Function to print 
// all ancestors of a given key 
static void printAncestors(Node root, int key) 
    if (root == null
        return
  
    // Create a stack to hold ancestors 
    Stack<Node> st = new Stack<Node> (); 
  
    // Traverse the complete tree in 
    // postorder way till we find the key 
    while (1 == 1) 
    
  
        // Traverse the left side. While 
        // traversing, push the nodes into 
        // the stack so that their right 
        // subtrees can be traversed later 
        while (root != null && root.data != key) 
        
            st.Push(root); // push current node 
            root = root.left; // move to next node 
        
  
        // If the node whose ancestors 
        // are to be printed is found,
        // then break the while loop. 
        if (root != null && root.data == key) 
            break
  
        // Check if right sub-tree exists
        // for the node at top If not then
        // pop that node because we don't 
        // need this node any more. 
        if (st.Peek().right == null
        
            root = st.Peek(); 
            st.Pop(); 
  
            // If the popped node is right child of top, 
            // then remove the top as well. Left child of 
            // the top must have processed before. 
            while (st.Count != 0 && st.Peek().right == root)
            
                root = st.Peek(); 
                st.Pop(); 
            
        
  
        // if stack is not empty then simply 
        // set the root as right child of 
        // top and start traversing right 
        // sub-tree. 
        root = st.Count == 0 ? null : st.Peek().right; 
    
  
    // If stack is not empty, print contents of stack 
    // Here assumption is that the key is there in tree 
    while (st.Count != 0)
    
        Console.Write(st.Peek().data + " "); 
        st.Pop(); 
    
  
// Driver code 
public static void Main(String[] args) 
    // Let us construct a binary tree 
    Node root = newNode(1); 
    root.left = newNode(2); 
    root.right = newNode(7); 
    root.left.left = newNode(3); 
    root.left.right = newNode(5); 
    root.right.left = newNode(8); 
    root.right.right = newNode(9); 
    root.left.left.left = newNode(4); 
    root.left.right.right = newNode(6); 
    root.right.right.left = newNode(10); 
  
    int key = 6; 
    printAncestors(root, key); 
}
}
  
// This code has been contributed by 29AjayKumar


Javascript




<script>
  
// Javascript program to print all 
// ancestors of a given key 
class Node
{
    constructor(data) 
    {
        this.left = null;
        this.right = null;
        this.data = data;
    }
}
  
// A utility function to 
// create a new tree node 
function newNode(data) 
    let node = new Node(data); 
    return node; 
  
// Iterative Function to print 
// all ancestors of a given key 
function printAncestors(root, key) 
    if (root == null
        return
  
    // Create a stack to hold ancestors 
    let st = []; 
  
    // Traverse the complete tree in 
    // postorder way till we find the key 
    while (1 == 1) 
    {
          
        // Traverse the left side. While 
        // traversing, push the nodes into 
        // the stack so that their right 
        // subtrees can be traversed later 
        while (root != null && root.data != key) 
        
              
            // Push current node 
            st.push(root); 
              
            // Move to next node 
            root = root.left; 
        
  
        // If the node whose ancestors 
        // are to be printed is found,
        // then break the while loop. 
        if (root != null && root.data == key) 
            break
  
        // Check if right sub-tree exists
        // for the node at top If not then
        // pop that node because we don't 
        // need this node any more. 
        if (st[st.length - 1].right == null
        
            root = st[st.length - 1]; 
            st.pop(); 
  
            // If the popped node is right child of top, 
            // then remove the top as well. Left child of 
            // the top must have processed before. 
            while (st.length != 0 && 
                st[st.length - 1].right == root)
            
                root = st[st.length - 1]; 
                st.pop(); 
            
        
  
        // If stack is not empty then simply 
        // set the root as right child of 
        // top and start traversing right 
        // sub-tree. 
        root = st.length == 0 ? null
            st[st.length - 1].right; 
    
  
    // If stack is not empty, print contents
    // of stack. Here assumption is that the 
    // key is there in tree 
    while (st.length != 0)
    
        document.write(st[st.length - 1].data + " "); 
        st.pop(); 
    
  
// Driver code
  
// Let us construct a binary tree 
let root = newNode(1); 
root.left = newNode(2); 
root.right = newNode(7); 
root.left.left = newNode(3); 
root.left.right = newNode(5); 
root.right.left = newNode(8); 
root.right.right = newNode(9); 
root.left.left.left = newNode(4); 
root.left.right.right = newNode(6); 
root.right.right.left = newNode(10); 
  
let key = 6; 
printAncestors(root, key); 
  
// This code is contributed by divyeshrabadiya07
  
</script>


Output

5 2 1 

Complexity Analysis:

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

 



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