LCA In A BST
You are given a binary search tree of integers with N nodes. You are also given references to two nodes P and Q from this BST.

Your task is to find the lowest common ancestor(LCA) of these two given nodes.

The lowest common ancestor for two nodes P and Q is defined as the lowest node that has both P and Q as descendants (where we allow a node to be a descendant of itself)

A binary search tree (BST) is a binary tree data structure which has the following properties.

• The left subtree of a node contains only nodes with data less than the node’s data. • The right subtree of a node contains only nodes with data greater than the node’s data. • Both the left and right subtrees must also be binary search trees.

Input Format:

The first line contains an integer 'T' which denotes the number of test cases or queries to be run. Then the test cases follow. The first line of each test case contains two space separated integers P and Q, the nodes whose LCA we have to find. The second line of each test case contains the elements of the BST in the level order form separated by a single space. If any node does not have a left or right child, take -1 in its place. Refer to the example below. Example: Elements are in the level order form. The input consists of values of nodes separated by a single space in a single line. In case a node is null, we take -1 in its place. For example, the input for the tree depicted in the below image would be :

1 2 3 4 -1 5 6 -1 7 -1 -1 -1 -1 -1 -1 Explanation : Level 1 : The root node of the tree is 1 Level 2 : Left child of 1 = 2 Right child of 1 = 3 Level 3 : Left child of 2 = 4 Right child of 2 = null (-1) Left child of 3 = 5 Right child of 3 = 6 Level 4 : Left child of 4 = null (-1) Right child of 4 = 7 Left child of 5 = null (-1) Right child of 5 = null (-1) Left child of 6 = null (-1) Right child of 6 = null (-1) Level 5 : Left child of 7 = null (-1) Right child of 7 = null (-1) The first not-null node (of the previous level) is treated as the parent of the first two nodes of the current level. The second not-null node (of the previous level) is treated as the parent node for the next two nodes of the current level and so on. The input ends when all nodes at the last level are null (-1).

Note :

The above format was just to provide clarity on how the input is formed for a given tree. The sequence will be put together in a single line separated by a single space. Hence, for the above-depicted tree, the input will be given as: 1 2 3 4 -1 5 6 -1 7 -1 -1 -1 -1 -1 -1

Output Format :

For each test case print the LCA of nodes P and Q. Output for every test case will be printed in a separate line.

Constraints:

1

Question

LCA In A BST

You are given a binary search tree of integers with N nodes. You are also given references to two nodes P and Q from this BST.

Your task is to find the lowest common ancestor(LCA) of these two given nodes.

The lowest common ancestor for two nodes P and Q is defined as the lowest node that has both P and Q as descendants (where we allow a node to be a descendant of itself)

A binary search tree (BST) is a binary tree data structure which has the following properties.

• The left subtree of a node contains only nodes with data less than the node’s data.
• The right subtree of a node contains only nodes with data greater than the node’s data.
• Both the left and right subtrees must also be binary search trees.

Input Format:

The first line contains an integer 'T' which denotes the number of test cases or queries to be run. Then the test cases follow.

The first line of each test case contains two space separated integers P and Q, the nodes whose LCA we have to find.

The second line of each test case contains the elements of the BST in the level order form separated by a single space.

If any node does not have a left or right child, take -1 in its place. Refer to the example below.

Example:

Elements are in the level order form. The input consists of values of nodes separated by a single space in a single line. In case a node is null, we take -1 in its place.

For example, the input for the tree depicted in the below image would be :

Example

1
2 3
4 -1 5 6
-1 7 -1 -1 -1 -1
-1 -1

Explanation :
Level 1 :
The root node of the tree is 1

Level 2 :
Left child of 1 = 2
Right child of 1 = 3

Level 3 :
Left child of 2 = 4
Right child of 2 = null (-1)
Left child of 3 = 5
Right child of 3 = 6

Level 4 :
Left child of 4 = null (-1)
Right child of 4 = 7
Left child of 5 = null (-1)
Right child of 5 = null (-1)
Left child of 6 = null (-1)
Right child of 6 = null (-1)

Level 5 :
Left child of 7 = null (-1)
Right child of 7 = null (-1)

The first not-null node (of the previous level) is treated as the parent of the first two nodes of the current level. The second not-null node (of the previous level) is treated as the parent node for the next two nodes of the current level and so on.

The input ends when all nodes at the last level are null (-1).

Note :

The above format was just to provide clarity on how the input is formed for a given tree. 

The sequence will be put together in a single line separated by a single space. Hence, for the above-depicted tree, the input will be given as:

1 2 3 4 -1 5 6 -1 7 -1 -1 -1 -1 -1 -1

Output Format :

For each test case print the LCA of nodes P and Q.

Output for every test case will be printed in a separate line.

Constraints:

1 <= T <= 100
1 <= N <= 5000
0 <= Data <= 10^6 and Data != -1

Time Limit: 1sec

Accepted Answer

Depth - First Traversal

We will traverse the BST in a depth-first manner. The moment we encounter either of the nodes P or Q, we will return some boolean flag. The least common ancestor would then be the node for which both the subtree recursions return a ‘True’ flag value.

The algorithm will be -

We will start traversing a BST from the root node in a recursive manner.
Let the current node in each recursive call be ‘currNode’. In each recursive call, we will-
- If currNode is equal to P we increment ‘isTrue’ by 1.
- If currNode is equal to Q we increment ‘isTrue’ by 1.
- We will recurse over the left subtree and find the value of ‘isTrueLeft’.
- We will recurse over the right subtree and find the value of ‘isTrueRight’.
- If the value of (isTrue + isTrueLeft + isTrueRight) >= 2 then ‘currNode’ is the LCA.
- If (isTrue + isTrueLeft + isTrueRight) > 0, we return 1. Else, we return 0.

Space Complexity: O(n)Explanation:

O(N), where N denotes the number of nodes in the BST.

In the worst case(skewed trees), the size of the recursion stack will be O(N).

Time Complexity: O(n)Explanation:

O(N), where N denotes the number of nodes in the BST.

In the worst case, we might end up visiting all the nodes of the BST. Hence, time complexity will be O(N).

Java (SE 1.8)

/*

    Time Complexity: O(N)

    Space Complexity: O(N)



    where 'N' is the total number of nodes of the BST.

*/



public class Solution 

{   

    public static TreeNode lca ;

    private static int findLCA(TreeNode currNode, TreeNode p, TreeNode q) 

    {   

        if (currNode == null) 

        {

            return 0;

        }



        int isTrueLeft = findLCA(currNode.left, p, q);

        int isTrueRight = findLCA(currNode.right, p, q);

        int isTrue = 0;



        if (currNode.data == p.data) 

        {

            isTrue++;

        }



        if (currNode.data == q.data) 

        {

            isTrue++;

        }



        // Current Node is the LCA

        if ((isTrueLeft + isTrueRight + isTrue) >= 2) 

        {

            lca = currNode;

        }

        

        if ((isTrueLeft + isTrueRight + isTrue) > 0) 

        {

            return 1;

        }

      

        return 0;

    }



    public static TreeNode LCAinaBST(TreeNode root, TreeNode p, TreeNode q) 

    {   

        lca = null;

		findLCA(root, p, q);

		return lca;

	}

}

C++ (g++ 5.4)

/*

    Time Complexity: O(N)

    Space Complexity: O(N)



    where N is the total number of nodes of the BST.

*/





int findLCA(TreeNode* currNode, TreeNode* P, 

            TreeNode* Q, TreeNode* &LCA)

{

    if (currNode == NULL)

    {

        return 0;

    }



    int isTrueLeft = findLCA(currNode -> left, P, Q, LCA);

    int isTrueRight = findLCA(currNode -> right, P, Q, LCA);

    int isTrue = 0;



    if (currNode -> data == P -> data)

    {

        isTrue++;

    }



    if (currNode -> data == Q -> data)

    {

        isTrue++;

    }



    // Current Node is the LCA

    if (isTrueLeft + isTrueRight + isTrue >= 2)

    {

        LCA = currNode;

    }



    if (isTrueLeft + isTrueRight + isTrue)

    {

        return 1;

    }

    

    return 0;

}





TreeNode* LCAinaBST(TreeNode* root, TreeNode* P, TreeNode* Q)

{

    TreeNode* LCA;



    findLCA(root, P, Q, LCA);



    return LCA;

}

Python (3.5)

'''

    Time Complexity: O(N)

    Space Complexity: O(N)



    where N is the total number of nodes of the BST.

'''





def findLCA(currNode, P, Q, LCA):



    if currNode == None:

        return 0



    isTrueLeft = findLCA(currNode.left, P, Q, LCA)

    isTrueRight = findLCA(currNode.right, P, Q, LCA)

    isTrue = 0



    if currNode == P:

        isTrue += 1



    if currNode == Q:

        isTrue += 1



    # Current Node is the LCA

    if isTrueLeft + isTrueRight + isTrue >= 2:

        LCA[0] = currNode



    if isTrueLeft + isTrueRight + isTrue:

        return 1

    

    return 0





def LCAinaBST(root, P, Q):



    # Passing LCA by reference

    LCA = [None]

    findLCA(root, P, Q, LCA)



    return LCA[0]

Accepted Answer

Recursive Approach

The lowest common ancestor of two nodes P and Q would be the last ancestor in terms of depth of the node, which is common to both the nodes. The key observation here is that for the LCA node, one of P or Q would be in the left subtree, and one would be in the right subtree.

The algorithm will be -

We can use a recursive approach for finding out the LCA.
Let the current node in each recursive call be ‘currNode’. In each recursive call, we will-
- If currNode -> data is less than P -> data and Q -> data, then LCA would be in the right subtree.
- If currNode -> data is greater than P -> data and Q -> data, then LCA would be in the left subtree.
- Else, currNode would be the LCA.

Space Complexity: O(n)Explanation:

O(N), where N denotes the number of nodes in the BST.

In the worst case(skewed trees), the size of the recursion stack will be O(N).

Time Complexity: O(n)Explanation:

O(N), where N denotes the number of nodes in the BST.

In the worst case(skewed trees), we might end up visiting all the nodes of the BST. Hence, time complexity will be O(N).

Python (3.5)

'''

    Time Complexity: O(N)

    Space Complexity: O(N)



    where N is the total number of nodes of the BST.

'''





def LCAinaBST(root, P, Q):



    if root.data < P.data and root.data < Q.data:

        return LCAinaBST(root.right, P, Q)

    

    if root.data > P.data and root.data > Q.data:

        return LCAinaBST(root.left, P, Q)



    return root

C++ (g++ 5.4)

/*
    Time Complexity: O(N)
    Space Complexity: O(N)

    where N is the total number of nodes of the BST.
*/


TreeNode* LCAinaBST(TreeNode* root, TreeNode* P, TreeNode* Q)
{
	if (root -> data < P -> data && root -> data < Q -> data)
	{
		return LCAinaBST(root -> right, P, Q);
	}
	
	if (root -> data > P -> data && root -> data > Q -> data)
	{
		return LCAinaBST(root -> left, P, Q);
	}

	return root;
}

Java (SE 1.8)

/* 

   Time Complexity: O(N)

   Space Complexity: O(N)



    where 'N' is the total number of nodes of the BST

*/



public class Solution 

{

    public static TreeNode LCAinaBST(TreeNode root, TreeNode p, TreeNode q) 

    {



        if ((root.data < p.data) && (root.data < q.data)) 

        {

            return LCAinaBST(root.right, p, q);

        }



        if ((root.data > p.data) && (root.data > q.data)) 

        {

            return LCAinaBST(root.left, p, q);

        }



        return root;

    }

}

Accepted Answer

Iterative approach

We can also use an iterative approach to find out the LCA of two nodes P and Q.

The algorithm will be -

Let the current node in the iteration be ‘currNode’.
While currNode is not equal to NULL:
- If currNode -> data is less than P -> data and Q -> data, then LCA would be in the right subtree.
- If currNode -> data is greater than P -> data and Q -> data, then LCA would be in the left subtree.
- Else, currNode would be the LCA.

Space Complexity: O(1)Explanation:

O(1), constant space is used.

Time Complexity: O(n)Explanation:

O(N), where N denotes the number of nodes in the BST.

In the worst case(skewed trees), we will visit all the nodes of the BST. Hence, time complexity will be O(N).

Java (SE 1.8)

/*

    Time Complexity: O(N)

    Space Complexity: O(1)



    where 'N' is the total number of nodes of the BST.

*/



public class Solution 

{

	public static TreeNode LCAinaBST(TreeNode root, TreeNode p, TreeNode q) 

	{



		while (root != null) 

		{

			if ((root.data < p.data) && (root.data < q.data)) 

			{

				root = root.right;

			} 

			else if ((root.data > p.data) && (root.data > q.data)) 

			{

				root = root.left;

			} 

			else 

			{

				return root;

			}

		}

		

		return root;

	}

}

Python (3.5)

'''

    Time Complexity: O(N)

    Space Complexity: O(1)



    where N is the total number of nodes of the BST.

'''





def LCAinaBST(root, P, Q):



    while root != None:



        if root.data < P.data and root.data < Q.data:

            root = root.right



        elif root.data > P.data and root.data > Q.data:

            root = root.left



        else:

            return root

C++ (g++ 5.4)

/*
    Time Complexity: O(N)
    Space Complexity: O(1)

    where N is the total number of nodes of the BST.
*/


TreeNode* LCAinaBST(TreeNode* root, TreeNode* P, TreeNode* Q)
{
	while (root != NULL)
	{
		if (root -> data < P -> data && root -> data < Q -> data)
		{
			root = root -> right;
		}
		else if (root -> data > P -> data && root -> data > Q -> data)
		{
			root = root -> left;
		}
		else
		{
			return root;
		}
	}
}

You are given a binary search tree of integers with N nodes. You are also given references to two nodes P and Q from this BST.

Your task is to find the lowest common ancestor(LCA) of these two given nodes.

The lowest common ancestor for two nodes P and Q is defined as the lowest node that has both P and Q as descendants (where we allow a node to be a descendant of itself)

A binary search tree (BST) is a binary tree data structure which has the following properties.

Input Format:

Note :

Output Format :

Constraints:

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