How to find the lowest common ancestor of two nodes in any binary tree?

The Binary Tree here is may not necessarily be a Binary Search Tree.
The structure could be taken as -

``````struct node {
int data;
struct node *left;
struct node *right;
};
``````

The maximum solution I could work out with a friend was something of this sort -
Consider this binary tree :

The inorder traversal yields - 8, 4, 9, 2, 5, 1, 6, 3, 7

And the postorder traversal yields - 8, 9, 4, 5, 2, 6, 7, 3, 1

So for instance, if we want to find the common ancestor of nodes 8 and 5, then we make a list of all the nodes which are between 8 and 5 in the inorder tree traversal, which in this case happens to be [4, 9, 2]. Then we check which node in this list appears last in the postorder traversal, which is 2. Hence the common ancestor for 8 and 5 is 2.

The complexity for this algorithm, I believe is O(n) (O(n) for inorder/postorder traversals, the rest of the steps again being O(n) since they are nothing more than simple iterations in arrays). But there is a strong chance that this is wrong. :-)

But this is a very crude approach, and I'm not sure if it breaks down for some case. Is there any other (possibly more optimal) solution to this problem?

-
Out of curiosity, what is the practical use of this? –  David Brunelle Feb 10 '10 at 13:49
@David: LCA query answering is pretty useful. LCA + Suffix tree = powerful string related algorithms. –  Aryabhatta May 17 '10 at 19:59
And when I asked a similar question it got voted down with comments like its interview question. Duality of SO? :( –  Some_other_guy Aug 24 '12 at 11:15
@Siddant +1 for the details given in the question. :) –  amod0017 Mar 8 '13 at 22:40
@DavidBrunelle One practical application of computing the LCA: it is an essential calculation when rendering web pages, specifically when computing the Cascading Style Sheets (CSS) that is applicable to a particular DOM element. –  zc22 Jun 7 '14 at 14:37

25 Answers

Nick Johnson is correct. But keep in mind that if your nodes have parent pointers, a slight variation on his algorithm is possible. For both nodes in question construct a list containing the path from root to the node by starting at the node, and front inserting the parent.

So for 8 in your example, you get (showing steps): {4}, {2, 4}, {1, 2, 4}

Do the same for your other node in question, resulting in (steps not shown): {1, 2}

Now compare the two lists you made looking for the first element where the list differ, or the last element of one of the lists, whichever comes first.

This algorithm requires O(h) where h is the height of the tree. If the tree is balanced, that is O(log(n)).

Regardless of how the tree is constructed, if this will be an operation you perform many times on the tree without changing it in between, there are other algorithms you can use that require O(n) [linear] time preparation, but then finding any pair takes only O(1) [constant] time. For references to these algorithms, see the the lowest common ancestor problem page on Wikipedia. (Credit to Jason for originally posting this link)

-
That does the job if the parent pointer is given. The nodes in the tree are as the structure I gave in my question - just the left/right child pointers, no parent pointer. Is there any O(log(n)) solution if there is no parent pointer available, and the tree is not a binary search tree, and is just a binary tree? –  Siddhant Sep 28 '09 at 9:58
If you have no particular way of finding the path between the parent and a given node, then it will take O(n) time on average to find that. That will make it impossible to have O(log(n)) time. However, the O(n) one time cost, with O(1) pair finding may be your best bet anyway if you were going to perform this operation many times without changing the tree in between. Otherwise, If at all possible you should add the parent pointer. It can make quite a few potential algorithms faster, yet I'm pretty sure it does not change the order of any existing algorithm. Hope this helps. –  Kevin Cathcart Oct 7 '09 at 4:25
this approach can be done using O(1) memory -- see Artelius's (and others) solution at stackoverflow.com/questions/1594061/… –  Tom Sirgedas Mar 8 '11 at 20:52
@Tom: Indeed, that would work to limit the memory complexity to O(1) for the list based algorithm. Obviously that means iterating through the tree itself once once for each side to get the depths of the nodes, and then a (partial) second time to find the common ancestor. O(h) time and O(1) space is clearly optimal for the case of having parent pointers, and not doing O(n) precomputation. –  Kevin Cathcart Mar 10 '11 at 17:40
@ALBI `O(h)` is only `O(log(n))` if the tree is balanced. For any tree, be it binary or not, if you have parent pointers you can determine the path from a leaf to the root in `O(h)` time, simply by following the parent pointer up to `h` times. That gives you the path from the leaf to the root. If the paths are stored as a stack, then iterating the stack gives you the path from root to leaf. If you lack parent pointers, and have no special structure to the tree, then finding the path from root to leaf does take `O(n)` time. –  Kevin Cathcart Dec 18 '13 at 16:43

Here is the working code in JAVA

``````public static Node LCA(Node root, Node a, Node b) {
if (root == null) {
return null;
}

// If the root is one of a or b, then it is the LCA
if (root == a || root == b) {
return root;
}

Node left = LCA(root.left, a, b);
Node right = LCA(root.right, a, b);

// If both nodes lie in left or right then their LCA is in left or right,
// Otherwise root is their LCA
if (left != null && right != null) {
return root;
}

return (left != null) ? left : right;
}
``````
-
Great solution. Will this work on DAG? –  vincent mathew Apr 1 at 17:20
This does not work when a node does not exist in the tree. –  Pratik Khadloya Jun 25 at 21:38

Although this has been answered already, this is my approach to this problem using C programming language. Although the code shows a binary search tree (as far as insert() is concerned), but the algorithm works for a binary tree as well. The idea is to go over all nodes that lie from node A to node B in inorder traversal, lookup the indices for these in the post order traversal. The node with maximum index in post order traversal is the lowest common ancestor.

This is a working C code to implement a function to find the lowest common ancestor in a binary tree. I am providing all the utility functions etc. as well, but jump to CommonAncestor() for quick understanding.

``````#include <stdio.h>
#include <malloc.h>
#include <stdlib.h>
#include <math.h>

static inline int min (int a, int b)
{
return ((a < b) ? a : b);
}
static inline int max (int a, int b)
{
return ((a > b) ? a : b);
}

typedef struct node_ {
int value;
struct node_ * left;
struct node_ * right;
} node;

#define MAX 12

int IN_ORDER[MAX] = {0};
int POST_ORDER[MAX] = {0};

createNode(int value)
{
node * temp_node = (node *)malloc(sizeof(node));
temp_node->left = temp_node->right = NULL;
temp_node->value = value;
return temp_node;
}

node *
insert(node * root, int value)
{
if (!root) {
return createNode(value);
}

if (root->value > value) {
root->left = insert(root->left, value);
} else {
root->right = insert(root->right, value);
}

return root;
}

/* Builds inorder traversal path in the IN array */
void
inorder(node * root, int * IN)
{
static int i = 0;

if (!root) return;

inorder(root->left, IN);
IN[i] = root->value;
i++;
inorder(root->right, IN);
}

/* Builds post traversal path in the POST array */

void
postorder (node * root, int * POST)
{
static int i = 0;

if (!root) return;

postorder(root->left, POST);
postorder(root->right, POST);
POST[i] = root->value;
i++;
}

int
findIndex(int * A, int value)
{
int i = 0;
for(i = 0; i< MAX; i++) {
if(A[i] == value) return i;
}
}
int
CommonAncestor(int val1, int val2)
{
int in_val1, in_val2;
int post_val1, post_val2;
int j=0, i = 0; int max_index = -1;

in_val1 = findIndex(IN_ORDER, val1);
in_val2 = findIndex(IN_ORDER, val2);
post_val1 = findIndex(POST_ORDER, val1);
post_val2 = findIndex(POST_ORDER, val2);

for (i = min(in_val1, in_val2); i<= max(in_val1, in_val2); i++) {
for(j = 0; j < MAX; j++) {
if (IN_ORDER[i] == POST_ORDER[j]) {
if (j > max_index) {
max_index = j;
}
}
}
}
printf("\ncommon ancestor of %d and %d is %d\n", val1, val2, POST_ORDER[max_index]);
return max_index;
}
int main()
{
node * root = NULL;

/* Build a tree with following values */
//40, 20, 10, 30, 5, 15, 25, 35, 1, 80, 60, 100
root = insert(root, 40);
insert(root, 20);
insert(root, 10);
insert(root, 30);
insert(root, 5);
insert(root, 15);
insert(root, 25);
insert(root, 35);
insert(root, 1);
insert(root, 80);
insert(root, 60);
insert(root, 100);

/* Get IN_ORDER traversal in the array */
inorder(root, IN_ORDER);

/* Get post order traversal in the array */
postorder(root, POST_ORDER);

CommonAncestor(1, 100);

}
``````
-

The below recursive algorithm will run in O(log N) for a balanced binary tree. If either of the nodes passed into the getLCA() function are the same as the root then the root will be the LCA and there will be no need to perform any recussrion.

Test cases. [1] Both nodes n1 & n2 are in the tree and reside on either side of their parent node. [2] Either node n1 or n2 is the root, the LCA is the root. [3] Only n1 or n2 is in the tree, LCA will be either the root node of the left subtree of the tree root, or the LCA will be the root node of the right subtree of the tree root.

[4] Neither n1 or n2 is in the tree, there is no LCA. [5] Both n1 and n2 are in a straight line next to each other, LCA will be either of n1 or n2 which ever is closes to the root of the tree.

``````//find the search node below root
bool findNode(node* root, node* search)
{
//base case
if(root == NULL)
return false;

if(root->val == search->val)
return true;

//search for the node in the left and right subtrees, if found in either return true
return (findNode(root->left, search) || findNode(root->right, search));
}

//returns the LCA, n1 & n2 are the 2 nodes for which we are
//establishing the LCA for
node* getLCA(node* root, node* n1, node* n2)
{
//base case
if(root == NULL)
return NULL;

//If 1 of the nodes is the root then the root is the LCA
//no need to recurse.
if(n1 == root || n2 == root)
return root;

//check on which side of the root n1 and n2 reside
bool n1OnLeft = findNode(root->left, n1);
bool n2OnLeft = findNode(root->left, n2);

//n1 & n2 are on different sides of the root, so root is the LCA
if(n1OnLeft != n2OnLeft)
return root;

//if both n1 & n2 are on the left of the root traverse left sub tree only
//to find the node where n1 & n2 diverge otherwise traverse right subtree
if(n1OnLeft)
return getLCA(root->left, n1, n2);
else
return getLCA(root->right, n1, n2);
}
``````
-

//If both the values are less than the current node then traverse the left subtree //Or If both the values are greater than the current node then traverse the right subtree //Or LCA is the current node

``````public BSTNode findLowestCommonAncestor(BSTNode currentRoot, int a, int b){
BSTNode commonAncestor = null;
if (currentRoot == null) {
System.out.println("The Tree does not exist");
return null;
}

int currentNodeValue = currentRoot.getValue();
//If both the values are less than the current node then traverse the left subtree
//Or If both the values are greater than the current node then traverse the right subtree
//Or LCA is the current node
if (a < currentNodeValue && b < currentNodeValue) {
commonAncestor = findLowestCommonAncestor(currentRoot.getLeft(), a, b);
} else if (a > currentNodeValue && b > currentNodeValue) {
commonAncestor = findLowestCommonAncestor(currentRoot.getRight(), a, b);
} else {
commonAncestor = currentRoot;
}

return commonAncestor;
}
``````
-
you are asuming BST and the question was for any BT. –  Mariano Latorre Oct 16 '14 at 12:43

If someone interested in pseudo code(for university home works) here is one.

``````GETLCA(BINARYTREE BT, NODE A, NODE  B)
IF Root==NIL
return NIL
ENDIF

IF Root==A OR root==B
return Root
ENDIF

Left = GETLCA (Root.Left, A, B)
Right = GETLCA (Root.Right, A, B)

IF Left! = NIL AND Right! = NIL
return root
ELSEIF Left! = NIL
Return Left
ELSE
Return Right
ENDIF
``````
-

Here are two approaches in c# (.net) (both discussed above) for reference:

1. Recursive version of finding LCA in binary tree (O(N) - as at most each node is visited) (main points of the solution is LCA is (a) only node in binary tree where both elements reside either side of the subtrees (left and right) is LCA. (b) And also it doesn't matter which node is present either side - initially i tried to keep that info, and obviously the recursive function become so confusing. once i realized it, it became very elegant.

2. Searching both nodes (O(N)), and keeping track of paths (uses extra space - so, #1 is probably superior even thought the space is probably negligible if the binary tree is well balanced as then extra memory consumption will be just in O(log(N)).

so that the paths are compared (essentailly similar to accepted answer - but the paths is calculated by assuming pointer node is not present in the binary tree node)

3. Just for the completion (not related to question), LCA in BST (O(log(N))

4. Tests

Recursive:

``````private BinaryTreeNode LeastCommonAncestorUsingRecursion(BinaryTreeNode treeNode,
int e1, int e2)
{
Debug.Assert(e1 != e2);

if(treeNode == null)
{
return null;
}
if((treeNode.Element == e1)
|| (treeNode.Element == e2))
{
//we don't care which element is present (e1 or e2), we just need to check
//if one of them is there
return treeNode;
}
var nLeft = this.LeastCommonAncestorUsingRecursion(treeNode.Left, e1, e2);
var nRight = this.LeastCommonAncestorUsingRecursion(treeNode.Right, e1, e2);
if(nLeft != null && nRight != null)
{
//note that this condition will be true only at least common ancestor
return treeNode;
}
else if(nLeft != null)
{
return nLeft;
}
else if(nRight != null)
{
return nRight;
}
return null;
}
``````

where above private recursive version is invoked by following public method:

``````public BinaryTreeNode LeastCommonAncestorUsingRecursion(int e1, int e2)
{
var n = this.FindNode(this._root, e1);
if(null == n)
{
throw new Exception("Element not found: " + e1);
}
if (e1 == e2)
{
return n;
}
n = this.FindNode(this._root, e2);
if (null == n)
{
throw new Exception("Element not found: " + e2);
}
var node = this.LeastCommonAncestorUsingRecursion(this._root, e1, e2);
if (null == node)
{
throw new Exception(string.Format("Least common ancenstor not found for the given elements: {0},{1}", e1, e2));
}
return node;
}
``````

Solution by keeping track of paths of both nodes:

``````public BinaryTreeNode LeastCommonAncestorUsingPaths(int e1, int e2)
{
var path1 = new List<BinaryTreeNode>();
var node1 = this.FindNodeAndPath(this._root, e1, path1);
if(node1 == null)
{
throw new Exception(string.Format("Element {0} is not found", e1));
}
if(e1 == e2)
{
return node1;
}
List<BinaryTreeNode> path2 = new List<BinaryTreeNode>();
var node2 = this.FindNodeAndPath(this._root, e2, path2);
if (node1 == null)
{
throw new Exception(string.Format("Element {0} is not found", e2));
}
BinaryTreeNode lca = null;
Debug.Assert(path1[0] == this._root);
Debug.Assert(path2[0] == this._root);
int i = 0;
while((i < path1.Count)
&& (i < path2.Count)
&& (path2[i] == path1[i]))
{
lca = path1[i];
i++;
}
Debug.Assert(null != lca);
return lca;
}
``````

where FindNodeAndPath is defined as

``````private BinaryTreeNode FindNodeAndPath(BinaryTreeNode node, int e, List<BinaryTreeNode> path)
{
if(node == null)
{
return null;
}
if(node.Element == e)
{
path.Add(node);
return node;
}
var n = this.FindNodeAndPath(node.Left, e, path);
if(n == null)
{
n = this.FindNodeAndPath(node.Right, e, path);
}
if(n != null)
{
path.Insert(0, node);
return n;
}
return null;
}
``````

BST (LCA) - not related (just for completion for reference)

``````public BinaryTreeNode BstLeastCommonAncestor(int e1, int e2)
{
//ensure both elements are there in the bst
var n1 = this.BstFind(e1, throwIfNotFound: true);
if(e1 == e2)
{
return n1;
}
this.BstFind(e2, throwIfNotFound: true);
BinaryTreeNode leastCommonAcncestor = this._root;
var iterativeNode = this._root;
while(iterativeNode != null)
{
if((iterativeNode.Element > e1 ) && (iterativeNode.Element > e2))
{
iterativeNode = iterativeNode.Left;
}
else if((iterativeNode.Element < e1) && (iterativeNode.Element < e2))
{
iterativeNode = iterativeNode.Right;
}
else
{
//i.e; either iterative node is equal to e1 or e2 or in between e1 and e2
return iterativeNode;
}
}
//control will never come here
return leastCommonAcncestor;
}
``````

Unit Tests

``````[TestMethod]
public void LeastCommonAncestorTests()
{
int[] a = { 13, 2, 18, 1, 5, 17, 20, 3, 6, 16, 21, 4, 14, 15, 25, 22, 24 };
int[] b = { 13, 13, 13, 2, 13, 18, 13, 5, 13, 18, 13, 13, 14, 18, 25, 22};
BinarySearchTree bst = new BinarySearchTree();
foreach (int e in a)
{
bst.Add(e);
bst.Delete(e);
bst.Add(e);
}
for(int i = 0; i < b.Length; i++)
{
var n = bst.BstLeastCommonAncestor(a[i], a[i + 1]);
Assert.IsTrue(n.Element == b[i]);
var n1 = bst.LeastCommonAncestorUsingPaths(a[i], a[i + 1]);
Assert.IsTrue(n1.Element == b[i]);
Assert.IsTrue(n == n1);
var n2 = bst.LeastCommonAncestorUsingRecursion(a[i], a[i + 1]);
Assert.IsTrue(n2.Element == b[i]);
Assert.IsTrue(n2 == n1);
Assert.IsTrue(n2 == n);
}
}
``````
-

If it is full binary tree with children of node x as 2*x and 2*x+1 than there is a faster way to do it

``````int get_bits(unsigned int x) {
int high = 31;
int low = 0,mid;
while(high>=low) {
mid = (high+low)/2;
if(1<<mid==x)
return mid+1;
if(1<<mid<x) {
low = mid+1;
}
else {
high = mid-1;
}
}
if(1<<mid>x)
return mid;
return mid+1;
}

unsigned int Common_Ancestor(unsigned int x,unsigned int y) {

int xbits = get_bits(x);
int ybits = get_bits(y);
int diff,kbits;
unsigned int k;
if(xbits>ybits) {
diff = xbits-ybits;
x = x >> diff;
}
else if(xbits<ybits) {
diff = ybits-xbits;
y = y >> diff;
}
k = x^y;
kbits = get_bits(k);
return y>>kbits;
}
``````

How does it work

1. get bits needed to represent x & y which using binary search is O(log(32))
2. the common prefix of binary notation of x & y is the common ancestor
3. whichever is represented by larger no of bits is brought to same bit by k >> diff
4. k = x^y erazes common prefix of x & y
5. find bits representing the remaining suffix
6. shift x or y by suffix bits to get common prefix which is the common ancestor.

This works because basically divide the larger number by two recursively until both numbers are equal. That number is the common ancestor. Dividing is effectively the right shift opearation. So we need to find common prefix of two numbers to find the nearest ancestor

-

Here is what I think,

1. Find the route for the fist node , store it on to arr1.
2. Start finding the route for the 2 node , while doing so check every value from root to arr1.
3. time when value differs , exit. Old matched value is the LCA.

Complexity : step 1 : O(n) , step 2 =~ O(n) , total =~ O(n).

-

Consider this tree

If we do postorder and preorder traversal and find the first occuring common predecessor and successor, we get the common ancestor.

postorder => 0,2,1,5,4,6,3,8,10,11,9,14,15,13,12,7 preorder => 7,3,1,0,2,6,4,5,12,9,8,11,10,13,15,14

• eg :1

Least common ancestor of 8,11

in postorder we have = >9,14,15,13,12,7 after 8 & 11 in preorder we have =>7,3,1,0,2,6,4,5,12,9 before 8 & 11

9 is the first common number that occurs after 8& 11 in postorder and before 8 & 11 in preorder, hence 9 is the answer

• eg :2

Least common ancestor of 5,10

11,9,14,15,13,12,7 in postorder 7,3,1,0,2,6,4 in preorder

7 is the first number that occurs after 5,10 in postorder and before 5,10 in preorder, hence 7 is the answer

-
``````public class LeastCommonAncestor {

private TreeNode root;

private static class TreeNode {
TreeNode left;
TreeNode right;
int item;

TreeNode (TreeNode left, TreeNode right, int item) {
this.left = left;
this.right = right;
this.item = item;
}
}

public void createBinaryTree (Integer[] arr) {
if (arr == null)  {
throw new NullPointerException("The input array is null.");
}

root = new TreeNode(null, null, arr[0]);

final Queue<TreeNode> queue = new LinkedList<TreeNode>();
queue.add(root);

final int half = arr.length / 2;

for (int i = 0; i < half; i++) {
if (arr[i] != null) {
final TreeNode current = queue.poll();
final int left = 2 * i + 1;
final int right = 2 * i + 2;

if (arr[left] != null) {
current.left = new TreeNode(null, null, arr[left]);
queue.add(current.left);
}
if (right < arr.length && arr[right] != null) {
current.right = new TreeNode(null, null, arr[right]);
queue.add(current.right);
}
}
}
}

private static class LCAData {
TreeNode lca;
int count;

public LCAData(TreeNode parent, int count) {
this.lca = parent;
this.count = count;
}
}

public int leastCommonAncestor(int n1, int n2) {
if (root == null) {
throw new NoSuchElementException("The tree is empty.");
}

LCAData lcaData = new LCAData(null, 0);
// foundMatch (root, lcaData, n1,  n2);

/**
* QQ: boolean was returned but never used by caller.
*/
foundMatchAndDuplicate (root, lcaData, n1,  n2, new HashSet<Integer>());

if (lcaData.lca != null) {
return lcaData.lca.item;
} else {
/**
* QQ: Illegal thrown after processing function.
*/
throw new IllegalArgumentException("The tree does not contain either one or more of input data. ");
}
}

//    /**
//     * Duplicate n1, n1         Duplicate in Tree
//     *      x                           x               => succeeds
//     *      x                           1               => fails.
//     *      1                           x               => succeeds by throwing exception
//     *      1                           1               => succeeds
//     */
//    private boolean foundMatch (TreeNode node, LCAData lcaData, int n1, int n2) {
//        if (node == null) {
//            return false;
//        }
//
//        if (lcaData.count == 2) {
//            return false;
//        }
//
//        if ((node.item == n1 || node.item == n2) && lcaData.count == 1) {
//            lcaData.count++;
//            return true;
//        }
//
//        boolean foundInCurrent = false;
//        if (node.item == n1 || node.item == n2) {
//            lcaData.count++;
//            foundInCurrent = true;
//        }
//
//        boolean foundInLeft = foundMatch(node.left, lcaData, n1, n2);
//        boolean foundInRight = foundMatch(node.right, lcaData, n1, n2);
//
//        if ((foundInLeft && foundInRight) || (foundInCurrent && foundInRight) || (foundInCurrent && foundInLeft)) {
//            lcaData.lca = node;
//            return true;
//        }
//        return foundInCurrent || (foundInLeft || foundInRight);
//    }

private boolean foundMatchAndDuplicate (TreeNode node, LCAData lcaData, int n1, int n2, Set<Integer> set) {
if (node == null) {
return false;
}

// when both were found
if (lcaData.count == 2) {
return false;
}

// when only one of them is found
if ((node.item == n1 || node.item == n2) && lcaData.count == 1) {
if (!set.contains(node.item)) {
lcaData.count++;
return true;
}
}

boolean foundInCurrent = false;
// when nothing was found (count == 0), or a duplicate was found (count == 1)
if (node.item == n1 || node.item == n2) {
if (!set.contains(node.item)) {
set.add(node.item);
lcaData.count++;
}
foundInCurrent = true;
}

boolean foundInLeft = foundMatchAndDuplicate(node.left, lcaData, n1, n2, set);
boolean foundInRight = foundMatchAndDuplicate(node.right, lcaData, n1, n2, set);

if (((foundInLeft && foundInRight) ||
(foundInCurrent && foundInRight) ||
(foundInCurrent && foundInLeft)) &&
lcaData.lca == null) {
lcaData.lca = node;
return true;
}
return foundInCurrent || (foundInLeft || foundInRight);
}

public static void main(String args[]) {
/**
* Binary tree with unique values.
*/
Integer[] arr1 = {1, 2, 3, 4, null, 6, 7, 8, null, null, null, null, 9};
LeastCommonAncestor commonAncestor = new LeastCommonAncestor();
commonAncestor.createBinaryTree(arr1);

int ancestor = commonAncestor.leastCommonAncestor(2, 4);
System.out.println("Expected 2, actual " + ancestor);

ancestor = commonAncestor.leastCommonAncestor(2, 7);
System.out.println("Expected 1, actual " +ancestor);

ancestor = commonAncestor.leastCommonAncestor(2, 6);
System.out.println("Expected 1, actual " + ancestor);

ancestor = commonAncestor.leastCommonAncestor(2, 1);
System.out.println("Expected 1, actual " +ancestor);

ancestor = commonAncestor.leastCommonAncestor(3, 8);
System.out.println("Expected 1, actual " +ancestor);

ancestor = commonAncestor.leastCommonAncestor(7, 9);
System.out.println("Expected 3, actual " +ancestor);

// duplicate request
try {
ancestor = commonAncestor.leastCommonAncestor(7, 7);
} catch (Exception e) {
System.out.println("expected exception");
}

/**
* Binary tree with duplicate values.
*/
Integer[] arr2 = {1, 2, 8, 4, null, 6, 7, 8, null, null, null, null, 9};
commonAncestor = new LeastCommonAncestor();
commonAncestor.createBinaryTree(arr2);

// duplicate requested
ancestor = commonAncestor.leastCommonAncestor(8, 8);
System.out.println("Expected 1, actual " + ancestor);

ancestor = commonAncestor.leastCommonAncestor(4, 8);
System.out.println("Expected 4, actual " +ancestor);

ancestor = commonAncestor.leastCommonAncestor(7, 8);
System.out.println("Expected 8, actual " +ancestor);

ancestor = commonAncestor.leastCommonAncestor(2, 6);
System.out.println("Expected 1, actual " + ancestor);

ancestor = commonAncestor.leastCommonAncestor(8, 9);
System.out.println("Expected 8, actual " +ancestor); // failed.
}
}
``````
-

My implementation using the given binary tree, and the described algorithm, in Java. Time and space complexities are both `O(n)`.

OP's approach does not work in the case of 2 nodes being the same, or one being a direct parent of another, otherwise it is an elegant way of solving this problem.

``````import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.Map;
import java.util.TreeMap;

public class BinaryTree {

private static class Node {
Node left;
Node right;
int value;

Node(int value) {this.value = value;}
}

private Node root = new Node(1);
private List<Node> inOrder = new ArrayList<>();
private List<Node> postOrder = new ArrayList<>();

public void traverseInOrder() {
inOrder.clear();
traverseInOrderMain(inOrder, root);
}

private void traverseInOrderMain(List<Node> inOrder, Node node) {
if (node != null) {
traverseInOrderMain(inOrder, node.left);
inOrder.add(node);
traverseInOrderMain(inOrder, node.right);
}
}

public void traversePostOrder() {
postOrder.clear();
traversePostOrderMain(postOrder, root);
}

private void traversePostOrderMain(List<Node> postOrder, Node node) {
if (node != null) {
traversePostOrderMain(postOrder, node.left);
traversePostOrderMain(postOrder, node.right);
postOrder.add(node);
}
}

private void printResultOfTraversals() {
System.out.print("in order: ");
for (Node n : inOrder) {
System.out.print(n.value + " ");
}
System.out.println();

System.out.print("post order: ");
for (Node n : postOrder) {
System.out.print(n.value + " ");
}
System.out.println();
}

private List<Node> getNodesBetweenTwoNodes(Node a, Node b) {
int aIndex = inOrder.indexOf(a);
int bIndex = inOrder.indexOf(b);
List<Node> inOrderRange;
if (aIndex < bIndex) {
inOrderRange = inOrder.subList(aIndex, bIndex+1);
}
else {
inOrderRange = inOrder.subList(bIndex, aIndex+1);
}

return inOrderRange;
}

/*Time & Space complexity: O(n)*/
private Node lowestCommonAncestor(Node a, Node b) {
if (a == b) {
return a;
}

traverseInOrder();
traversePostOrder();
List<Node> potentialLCAs = getNodesBetweenTwoNodes(a, b); //get nodes between and inclusive of 2 ends
Map<Integer, Node> map = new TreeMap<>(Collections.reverseOrder()); //descending order of keys

for (Node n : potentialLCAs) {
map.put(postOrder.indexOf(n), n); //store location of node in post-order list, along with the node
}

return ((TreeMap<Integer, Node>)map).firstEntry().getValue(); //first node is LCA
}

public void prettyPrint(Node a, Node b) {
int result = lowestCommonAncestor(a, b).value;
System.out.println("LCA of " + a.value + " and " + b.value + " is " + result);
}

public static void main(String[] args) {
/*building the tree*/
BinaryTree bt = new BinaryTree();
bt.root.left = new Node(2);
bt.root.right = new Node(3);
bt.root.left.left = new Node(4);
bt.root.left.right = new Node(5);
bt.root.left.left.left = new Node(8);
bt.root.left.left.right = new Node(9);
bt.root.right.left = new Node(6);
bt.root.right.right = new Node(7);
bt.traverseInOrder();
bt.traversePostOrder();
bt.printResultOfTraversals();

/*find LCA*/
Node two = bt.root.left;
Node three = bt.root.right;
Node four = bt.root.left.left;
Node five = bt.root.left.right;
Node six = bt.root.right.left;
Node seven = bt.root.right.right;
Node eight = bt.root.left.left.left;
Node nine = bt.root.left.left.right;

bt.prettyPrint(nine, nine);
bt.prettyPrint(eight, five);
bt.prettyPrint(two, seven);
bt.prettyPrint(two, four);
bt.prettyPrint(nine, four);
bt.prettyPrint(three, four);
bt.prettyPrint(seven, six);
}

}
``````
-
can the person who downvoted shed some light on why so? –  Nhan Jun 8 '14 at 0:11
If condition `(a==b)` is not correct, this tree is not BST, which means there could be same values but at different location. –  REALFREE Jul 4 '14 at 3:21

I found a solution

1. Take inorder
2. Take preorder
3. Take postorder

Depending on 3 traversals, you can decide who is the LCA. From LCA find distance of both nodes. Add these two distances, which is the answer.

-

Starting from `root` node and moving downwards if you find any node that has either `p` or `q` as its direct child then it is the LCA.

Else if you find a node with `p` in its right(or left) subtree and `q` in its left(or right) subtree then it is the LCA.

``````treeNodePtr findLCA(treeNodePtr root, treeNodePtr p, treeNodePtr q) {

// no root no LCA.
if(!root) {
return NULL;
}

// if either p or q is direct child of root then root is LCA.
if(root->left==p || root->left==q ||
root->right ==p || root->right ==q) {
return root;
} else {
// get LCA of p and q in left subtree.
treeNodePtr l=findLCA(root->left , p , q);

// get LCA of p and q in right subtree.
treeNodePtr r=findLCA(root->right , p, q);

// if one of p or q is in leftsubtree and other is in right
// then root it the LCA.
if(l && r) {
return root;
}
// else if l is not null, l is LCA.
else if(l) {
return l;
} else {
return r;
}
}
}
``````

The above code fails when either is the direct child of other. The following fixes that:

``````treeNodePtr findLCA(treeNodePtr root, treeNodePtr p, treeNodePtr q) {

// no root no LCA.
if(!root) {
return NULL;
}

// if either p or q is the root then root is LCA.
if(root==p || root==q) {
return root;
} else {
// get LCA of p and q in left subtree.
treeNodePtr l=findLCA(root->left , p , q);

// get LCA of p and q in right subtree.
treeNodePtr r=findLCA(root->right , p, q);

// if one of p or q is in leftsubtree and other is in right
// then root it the LCA.
if(l && r) {
return root;
}
// else if l is not null, l is LCA.
else if(l) {
return l;
} else {
return r;
}
}
}
``````

Code In Action

-
elegant solution, but the root==p || root==q => return root bit seems overoptimistic. What if it turns out root is p/q, but the other sought-for node is not actually in the tree? –  Ian Durkan Jun 3 '11 at 2:12
I guess this code fails when p or q is a value which is not in the binary tree. Am I right? For example LCA(8,20). ur code returns 8. but 20 is not present in binary tree –  javaMan Nov 20 '11 at 13:42
What's the cost for this solution? Is it efficient? It appears to continue searching even after it has found both p and q. Is that because of the possibility that p and q might not be unique in the tree since it's not a BST and may contain duplicates? –  MikeB Jan 22 '13 at 14:57
@MikeB, this solution is definitely O(n), because you traverse each node only once in the worst case. Peter Lee, this is the most efficient you can make it without using parent pointers. Do you have a better solution? –  gsingh2011 May 30 '14 at 21:08
the first imperfect solution should be deleted so that it's not distracting –  Zinan Xing Aug 15 '14 at 18:32

The easiest way to find the Lowest Common Ancestor is using the following algorithm:

```Examine root node

if value1 and value2 are strictly less that the value at the root node
Examine left subtree
else if value1 and value2 are strictly greater that the value at the root node
Examine right subtree
else
return root
```
``````public int LCA(TreeNode root, int value 1, int value 2) {
while (root != null) {
if (value1 < root.data && value2 < root.data)
return LCA(root.left, value1, value2);
else if (value2 > root.data && value2 2 root.data)
return LCA(root.right, value1, value2);
else
return root
}

return null;
}
``````
-
It's NOT a BST! –  Peter Lee Oct 6 '13 at 4:11

The code in Php. I've assumed the tree is an Array binary tree. Therefore, you don't even require the tree to calculate the LCA. input: index of two nodes output: index of LCA

``````    <?php
global \$Ps;

function parents(\$l,\$Ps)
{

if(\$l % 2 ==0)
\$p = (\$l-2)/2;
else
\$p = (\$l-1)/2;

array_push(\$Ps,\$p);
if(\$p !=0)
parents(\$p,\$Ps);

return \$Ps;
}
function lca(\$n,\$m)
{
\$LCA = 0;
\$arr1 = array();
\$arr2 = array();
unset(\$Ps);
\$Ps = array_fill(0,1,0);
\$arr1 = parents(\$n,\$arr1);
unset(\$Ps);
\$Ps = array_fill(0,1,0);
\$arr2 = parents(\$m,\$arr2);

if(count(\$arr1) > count(\$arr2))
\$limit = count(\$arr2);
else
\$limit = count(\$arr1);

for(\$i =0;\$i<\$limit;\$i++)
{
if(\$arr1[\$i] == \$arr2[\$i])
{
\$LCA = \$arr1[\$i];
break;
}
}
return \$LCA;//this is the index of the element in the tree

}

var_dump(lca(5,6));
?>
``````

Do tell me if there are any shortcomings.

-

Here is the C++ way of doing it. Have tried to keep the algorithm as much easy as possible to understand:

``````// Assuming that `BinaryNode_t` has `getData()`, `getLeft()` and `getRight()`
class LowestCommonAncestor
{
typedef char type;
// Data members which would behave as place holders
const BinaryNode_t* m_pLCA;
type m_Node1, m_Node2;

static const unsigned int TOTAL_NODES = 2;

// The core function which actually finds the LCA; It returns the number of nodes found
// At any point of time if the number of nodes found are 2, then it updates the `m_pLCA` and once updated, we have found it!
unsigned int Search (const BinaryNode_t* const pNode)
{
if(pNode == 0)
return 0;

unsigned int found = 0;

found += (pNode->getData() == m_Node1);
found += (pNode->getData() == m_Node2);

found += Search(pNode->getLeft()); // below condition can be after this as well
found += Search(pNode->getRight());

if(found == TOTAL_NODES && m_pLCA == 0)
m_pLCA = pNode;  // found !

return found;
}

public:
// Interface method which will be called externally by the client
const BinaryNode_t* Search (const BinaryNode_t* const pHead,
const type node1,
const type node2)
{
// Initialize the data members of the class
m_Node1 = node1;
m_Node2 = node2;
m_pLCA = 0;

// Find the LCA, populate to `m_pLCANode` and return
(void) Search(pHead);
return m_pLCA;
}
};
``````

How to use it:

``````LowestCommonAncestor lca;
BinaryNode_t* pNode = lca.Search(pWhateverBinaryTreeNodeToBeginWith);
if(pNode != 0)
...
``````
-
``````Node *LCA(Node *root, Node *p, Node *q) {
if (!root) return NULL;
if (root == p || root == q) return root;
Node *L = LCA(root->left, p, q);
Node *R = LCA(root->right, p, q);
if (L && R) return root;  // if p and q are on both sides
return L ? L : R;  // either one of p,q is on one side OR p,q is not in L&R subtrees
}
``````
-

In scala, the code is:

``````abstract class Tree
case class Node(a:Int, left:Tree, right:Tree) extends Tree
case class Leaf(a:Int) extends Tree

def lca(tree:Tree, a:Int, b:Int):Tree = {
tree match {
case Node(ab,l,r) => {
if(ab==a || ab ==b) tree else {
val temp = lca(l,a,b);
val temp2 = lca(r,a,b);
if(temp!=null && temp2 !=null)
tree
else if (temp==null && temp2==null)
null
else if (temp==null) r else l
}

}
case Leaf(ab) => if(ab==a || ab ==b) tree else null
}
}
``````
-

The answers given so far uses recursion or stores, for instance, a path in memory.

Both of these approaches might fail if you have a very deep tree.

Here is my take on this question. When we check the depth (distance from the root) of both nodes, if they are equal, then we can safely move upward from both nodes towards the common ancestor. If one of the depth is bigger then we should move upward from the deeper node while staying in the other one.

Here is the code:

``````findLowestCommonAncestor(v,w):
depth_vv = depth(v);
depth_ww = depth(w);

vv = v;
ww = w;

while( depth_vv != depth_ww ) {
if ( depth_vv > depth_ww ) {
vv = parent(v);
depth_vv--;
else {
ww = parent(ww);
depth_ww--;
}
}

while( vv != ww ) {
vv = parent(vv);
ww = parent(ww);
}

return vv;
``````

The time complexity of this algorithm is: O(n). The space complexity of this algorithm is: O(1).

Regarding the computation of the depth, we can first remember the definition: If v is root, depth(v) = 0; Otherwise, depth(v) = depth(parent(v)) + 1. We can compute depth as follows:

``````depth(v):
int d = 0;
vv = v;
while ( vv is not root ) {
vv = parent(vv);
d++;
}
return d;
``````
-
Very elegant! Thanks –  ilker Acar Jun 8 '13 at 3:26
Binary trees don't have a reference to the parent element, typically. Adding a parent reference can be done without any issue, but I would consider that O(n) auxiliary space. –  John Kurlak Jul 15 '13 at 5:35

This can be found at:- http://goursaha.freeoda.com/DataStructure/LowestCommonAncestor.html

`````` tree_node_type *LowestCommonAncestor(
tree_node_type *root , tree_node_type *p , tree_node_type *q)
{
tree_node_type *l , *r , *temp;
if(root==NULL)
{
return NULL;
}

if(root->left==p || root->left==q || root->right ==p || root->right ==q)
{
return root;
}
else
{
l=LowestCommonAncestor(root->left , p , q);
r=LowestCommonAncestor(root->right , p, q);

if(l!=NULL && r!=NULL)
{
return root;
}
else
{
temp = (l!=NULL)?l:r;
return temp;
}
}
}
``````
-
can you please tell me how will your code will behave if p is present but q is not at all present in the tree? Similarly both p and q are not present. Thanks!!! –  Trying Feb 28 '13 at 20:40
What's the big O in terms of time? I think it's O(n*log(n)), two slow. –  Peter Lee Oct 6 '13 at 4:18

To find out common ancestor of two node :-

• Find the given node Node1 in the tree using binary search and save all nodes visited in this process in an array say A1. Time - O(logn), Space - O(logn)
• Find the given Node2 in the tree using binary search and save all nodes visited in this process in an array say A2. Time - O(logn), Space - O(logn)
• If A1 list or A2 list is empty then one the node does not exist so there is no common ancestor.
• If A1 list and A2 list are non-empty then look into the list until you find non-matching node. As soon as you find such a node then node prior to that is common ancestor.

This would work for binary search tree.

-
He clearly stated the tree is NOT necessarily a BST. –  Peter Lee Oct 6 '13 at 4:10

I have made an attempt with illustrative pictures and working code in Java,

http://www.technicalypto.com/2010/02/least-common-ancestor-without-using.html

-

Well, this kind of depends how your Binary Tree is structured. Presumably you have some way of finding the desired leaf node given the root of the tree - simply apply that to both values until the branches you choose diverge.

If you don't have a way to find the desired leaf given the root, then your only solution - both in normal operation and to find the last common node - is a brute-force search of the tree.

-

Tarjan's off-line least common ancestors algorithm is good enough (cf. also Wikipedia). There is more on the problem (the lowest common ancestor problem) on Wikipedia.

-