# Find kth smallest element in a binary search tree in Optimum way

I need to find the kth smallest element in the binary search tree without using any static/global variable. How to achieve it efficiently? The solution that I have in my mind is doing the operation in O(n), the worst case since I am planning to do an inorder traversal of the entire tree. But deep down I feel that I am not using the BST property here. Is my assumptive solution correct or is there a better one available ?

• Is the tree balanced? Feb 24, 2010 at 20:21
• Its not. But if it were balanced, is there an optimum way? Feb 24, 2010 at 20:27
• If you do a search on "Order Statistics" you will find what you need.
– RAL
Feb 24, 2010 at 20:41
• I sort of feel most of the answers below, while correct are cheating in that they are using a global variable of some sort (whether it's a reference to an integer, or a variable that gets decremented and returned). If absolutely none of those are allowed, I would use recursion without any references being passed in. Aug 15, 2013 at 2:10

Here's just an outline of the idea:

In a BST, the left subtree of node `T` contains only elements smaller than the value stored in `T`. If `k` is smaller than the number of elements in the left subtree, the `k`th smallest element must belong to the left subtree. Otherwise, if `k` is larger, then the `k`th smallest element is in the right subtree.

We can augment the BST to have each node in it store the number of elements in its left subtree (assume that the left subtree of a given node includes that node). With this piece of information, it is simple to traverse the tree by repeatedly asking for the number of elements in the left subtree, to decide whether to do recurse into the left or right subtree.

Now, suppose we are at node T:

1. If k == num_elements(left subtree of T), then the answer we're looking for is the value in node `T`.
2. If k > num_elements(left subtree of T), then obviously we can ignore the left subtree, because those elements will also be smaller than the `k`th smallest. So, we reduce the problem to finding the `k - num_elements(left subtree of T)` smallest element of the right subtree.
3. If k < num_elements(left subtree of T), then the `k`th smallest is somewhere in the left subtree, so we reduce the problem to finding the `k`th smallest element in the left subtree.

Complexity analysis:

This takes `O(depth of node)` time, which is `O(log n)` in the worst case on a balanced BST, or `O(log n)` on average for a random BST.

A BST requires `O(n)` storage, and it takes another `O(n)` to store the information about the number of elements. All BST operations take `O(depth of node)` time, and it takes `O(depth of node)` extra time to maintain the "number of elements" information for insertion, deletion or rotation of nodes. Therefore, storing information about the number of elements in the left subtree keeps the space and time complexity of a BST.

• To find the Nth smallest item, you only need to store the size of the left sub-tree. You'd use the size of the right sub-tree iif you also wanted to be able to find the Nth largest item. Actually, you can make that less expensive though: store the total size of the tree in the root, and the size of the left sub-tree. When you need to size of the right sub-tree, you can subtract the size of the left from the total size. Feb 24, 2010 at 20:33
• Such an augmented BST is called an 'order statistics tree'. Aug 13, 2010 at 17:34
• @Ivlad: in step 2: I think "k - num_elements" should be "k - num_elements -1", since you've to include root element too. Sep 13, 2010 at 5:13
• @understack - not if you assume the root to be part of the subtree. Sep 13, 2010 at 8:48
• If the tree doesn't contain a field containing the "number of elements in its left and right subtree" then the method will end up being BigO( n ) as you will need to walk the right or left subtree at each node in order to calculate the k index of the current node. Jan 29, 2011 at 16:26

A simpler solution would be to do an inorder traversal and keep track of the element currently to be printed (without printing it). When we reach k, print the element and skip rest of tree traversal.

``````void findK(Node* p, int* k) {
if(!p || k < 0) return;
findK(p->left, k);
--k;
if(k == 0) {
print p->data;
return;
}
findK(p->right, k);
}
``````
• +1: The idea is in the right direction, but some loose ends may need to be tightened; see stackoverflow.com/a/23069077/278326
– Arun
Apr 14, 2014 at 19:55
• I like this solution, since BST is already ordered, a traversal should be enough. Jun 11, 2015 at 15:43
• If n is close to the total number of nodes in this tree, your algorithm will take O(n) time to finish, which is bad for the selected answer-O(log n) Jul 2, 2015 at 14:58
``````public int ReturnKthSmallestElement1(int k)
{
Node node = Root;

int count = k;

int sizeOfLeftSubtree = 0;

while(node != null)
{

sizeOfLeftSubtree = node.SizeOfLeftSubtree();

if (sizeOfLeftSubtree + 1 == count)
return node.Value;
else if (sizeOfLeftSubtree < count)
{
node = node.Right;
count -= sizeOfLeftSubtree+1;
}
else
{
node = node.Left;
}
}

return -1;
}
``````

this is my implementation in C# based on the algorithm above just thought I'd post it so people can understand better it works for me

//add a java version without recursion

``````public static <T> void find(TreeNode<T> node, int num){
Stack<TreeNode<T>> stack = new Stack<TreeNode<T>>();

TreeNode<T> current = node;
int tmp = num;

while(stack.size() > 0 || current!=null){
if(current!= null){
current = current.getLeft();
}else{
current = stack.pop();
tmp--;

if(tmp == 0){
System.out.println(current.getValue());
return;
}

current = current.getRight();
}
}
}
``````
• I like this solution and the corresponding recursive one. Honestly, most of the answers to this question are too confusing/complex to read. Aug 15, 2013 at 2:11
• I love this solution! Clear and great! Sep 25, 2015 at 19:21
• This solution is traversing the tree 'in-order' and decreasing a counter after visiting the node, to later stop when the counter gets equals to zero. The worst case is then of order O(n). Not the most optimal comparing with @IVlad's recursive solutions whose worst case takes O(log n) Feb 3, 2017 at 1:59

A simpler solution would be to do an inorder traversal and keep track of the element currently to be printed with a counter k. When we reach k, print the element. The runtime is O(n). Remember the function return type can not be void, it has to return its updated value of k after each recursive call. A better solution to this would be an augmented BST with a sorted position value at each node.

``````public static int kthSmallest (Node pivot, int k){
if(pivot == null )
return k;
k = kthSmallest(pivot.left, k);
k--;
if(k == 0){
System.out.println(pivot.value);
}
k = kthSmallest(pivot.right, k);
return k;
}
``````
• I guess your solution is better in terms of space complexity, compared with the augmented BST.
– zach
Feb 7, 2017 at 7:36
• The search doesn't stop even after the k-th smallest element is found. Nov 29, 2018 at 12:23

You can use iterative inorder traversal: http://en.wikipedia.org/wiki/Tree_traversal#Iterative_Traversal with a simple check for kth element after poping a node out of the stack.

Given just a plain binary search tree, about all you can do is start from the smallest, and traverse upward to find the right node.

If you're going to do this very often, you can add an attribute to each node signifying how many nodes are in its left sub-tree. Using that, you can descend the tree directly to the correct node.

### Recursive In-order Walk with a counter

``````Time Complexity: O( N ), N is the number of nodes
Space Complexity: O( 1 ), excluding the function call stack
``````

The idea is similar to @prasadvk solution, but it has some shortcomings (see notes below), so I am posting this as a separate answer.

``````// Private Helper Macro
#define testAndReturn( k, counter, result )                         \
do { if( (counter == k) && (result == -1) ) {                   \
result = pn->key_;                                          \
return;                                                     \
} } while( 0 )

// Private Helper Function
static void findKthSmallest(
BstNode const * pn, int const k, int & counter, int & result ) {

if( ! pn ) return;

findKthSmallest( pn->left_, k, counter, result );
testAndReturn( k, counter, result );

counter += 1;
testAndReturn( k, counter, result );

findKthSmallest( pn->right_, k, counter, result );
testAndReturn( k, counter, result );
}

// Public API function
void findKthSmallest( Bst const * pt, int const k ) {
int counter = 0;
findKthSmallest( pt->root_, k, counter, result );
printf("%d-th element: element = %d\n", k, result );
}
``````

Notes (and differences from @prasadvk's solution):

1. `if( counter == k )` test is required at three places: (a) after left-subtree, (b) after root, and (c) after right subtree. This is to ensure that kth element is detected for all locations, i.e. irrespective of the subtree it is located.

2. `if( result == -1 )` test required to ensure only the result element is printed, otherwise all the elements starting from the kth smallest up to the root are printed.

• Time complexity for this solution is `O(k + d)`, where `d` is max depth of the tree. Therefore it uses a global variable `counter` but it's illegal for this question. Dec 16, 2014 at 16:50
• Hi Arun, can you please explain with an example. I am not understand this particularly your first point. Jan 5, 2015 at 16:48

For not balanced searching tree, it takes O(n).

For balanced searching tree, it takes O(k + log n) in the worst case but just O(k) in Amortized sense.

Having and managing the extra integer for every node: the size of the sub-tree gives O(log n) time complexity. Such balanced searching tree is usually called RankTree.

In general, there are solutions (based not on tree).

Regards.

This works well: status : is the array which holds whether element is found. k : is kth element to be found. count : keeps track of number of nodes traversed during the tree traversal.

``````int kth(struct tree* node, int* status, int k, int count)
{
if (!node) return count;
count = kth(node->lft, status, k, count);
if( status ) return status;
if (count == k) {
status = node->val;
status = 1;
return status;
}
count = kth(node->rgt, status, k, count+1);
if( status ) return status;
return count;
}
``````

While this is definitely not the optimal solution to the problem, it is another potential solution which I thought some people might find interesting:

``````/**
* Treat the bst as a sorted list in descending order and find the element
* in position k.
*
* Time complexity BigO ( n^2 )
*
* 2n + sum( 1 * n/2 + 2 * n/4 + ... ( 2^n-1) * n/n ) =
* 2n + sigma a=1 to n ( (2^(a-1)) * n / 2^a ) = 2n + n(n-1)/4
*
* @param t The root of the binary search tree.
* @param k The position of the element to find.
* @return The value of the element at position k.
*/
public static int kElement2( Node t, int k ) {
int treeSize = sizeOfTree( t );

return kElement2( t, k, treeSize, 0 ).intValue();
}

/**
* Find the value at position k in the bst by doing an in-order traversal
* of the tree and mapping the ascending order index to the descending order
* index.
*
*
* @param t Root of the bst to search in.
* @param k Index of the element being searched for.
* @param treeSize Size of the entire bst.
* @param count The number of node already visited.
* @return Either the value of the kth node, or Double.POSITIVE_INFINITY if
*/
private static Double kElement2( Node t, int k, int treeSize, int count ) {
// Double.POSITIVE_INFINITY is a marker value indicating that the kth
// element wasn't found in this sub-tree.
if ( t == null )
return Double.POSITIVE_INFINITY;

Double kea = kElement2( t.getLeftSon(), k, treeSize, count );

if ( kea != Double.POSITIVE_INFINITY )
return kea;

// The index of the current node.
count += 1 + sizeOfTree( t.getLeftSon() );

// Given any index from the ascending in order traversal of the bst,
// treeSize + 1 - index gives the
// corresponding index in the descending order list.
if ( ( treeSize + 1 - count ) == k )
return (double)t.getNumber();

return kElement2( t.getRightSon(), k, treeSize, count );
}
``````

signature:

``````Node * find(Node* tree, int *n, int k);
``````

call as:

``````*n = 0;
kthNode = find(root, n, k);
``````

definition:

``````Node * find ( Node * tree, int *n, int k)
{
Node *temp = NULL;

if (tree->left && *n<k)
temp = find(tree->left, n, k);

*n++;

if(*n==k)
temp = root;

if (tree->right && *n<k)
temp = find(tree->right, n, k);

return temp;
}
``````

Well here is my 2 cents...

``````int numBSTnodes(const Node* pNode){
if(pNode == NULL) return 0;
return (numBSTnodes(pNode->left)+numBSTnodes(pNode->right)+1);
}

//This function will find Kth smallest element
Node* findKthSmallestBSTelement(Node* root, int k){
Node* pTrav = root;
while(k > 0){
int numNodes = numBSTnodes(pTrav->left);
if(numNodes >= k){
pTrav = pTrav->left;
}
else{
//subtract left tree nodes and root count from 'k'
k -= (numBSTnodes(pTrav->left) + 1);
if(k == 0) return pTrav;
pTrav = pTrav->right;
}

return NULL;
}
``````

This is what I though and it works. It will run in o(log n )

``````public static int FindkThSmallestElemet(Node root, int k)
{
int count = 0;
Node current = root;

while (current != null)
{
count++;
current = current.left;
}
current = root;

while (current != null)
{
if (count == k)
return current.data;
else
{
current = current.left;
count--;
}
}

return -1;

} // end of function FindkThSmallestElemet
``````
• i don't think this solution will work. What if the Kth smallest is in the right sub tree of the tree node ? Sep 25, 2010 at 6:54

Well we can simply use the in order traversal and push the visited element onto a stack. pop k number of times, to get the answer.

we can also stop after k elements

• this is not an optimum solution Feb 12, 2011 at 11:49

Solution for complete BST case :-

``````Node kSmallest(Node root, int k) {
int i = root.size(); // 2^height - 1, single node is height = 1;
Node result = root;
while (i - 1 > k) {
i = (i-1)/2;  // size of left subtree
if (k < i) {
result = result.left;
} else {
result = result.right;
k -= i;
}
}
return i-1==k ? result: null;
}
``````

The Linux Kernel has an excellent augmented red-black tree data structure that supports rank-based operations in O(log n) in linux/lib/rbtree.c.

A very crude Java port can also be found at http://code.google.com/p/refolding/source/browse/trunk/core/src/main/java/it/unibo/refolding/alg/RbTree.java, together with RbRoot.java and RbNode.java. The n'th element can be obtained by calling RbNode.nth(RbNode node, int n), passing in the root of the tree.

Here's a concise version in C# that returns the k-th smallest element, but requires passing k in as a ref argument (it's the same approach as @prasadvk):

``````Node FindSmall(Node root, ref int k)
{
if (root == null || k < 1)
return null;

Node node = FindSmall(root.LeftChild, ref k);
if (node != null)
return node;

if (--k == 0)
return node ?? root;
return FindSmall(root.RightChild, ref k);
}
``````

It's O(log n) to find the smallest node, and then O(k) to traverse to k-th node, so it's O(k + log n).

• how about the java version? Aug 14, 2013 at 21:02

http://www.geeksforgeeks.org/archives/10379

this is the exact answer to this question:-

1.using inorder traversal on O(n) time 2.using Augmented tree in k+log n time

I couldn't find a better algorithm..so decided to write one :) Correct me if this is wrong.

``````class KthLargestBST{
protected static int findKthSmallest(BSTNode root,int k){//user calls this function
int [] result=findKthSmallest(root,k,0);//I call another function inside
return result;
}
private static int[] findKthSmallest(BSTNode root,int k,int count){//returns result[]2 array containing count in rval and desired element in rval position.
if(root==null){
int[]  i=new int;
i=-1;
i=-1;
return i;
}else{
int rval[]=new int;
int temp[]=new int;
rval=findKthSmallest(root.leftChild,k,count);
if(rval!=-1){
count=rval;
}
count++;
if(count==k){
rval=root.data;
}
temp=findKthSmallest(root.rightChild,k,(count));
if(temp!=-1){
count=temp;
}
if(temp!=-1){
rval=temp;
}
rval=count;
return rval;
}
}
public static void main(String args[]){
BinarySearchTree bst=new BinarySearchTree();
bst.insert(6);
bst.insert(8);
bst.insert(7);
bst.insert(4);
bst.insert(3);
bst.insert(4);
bst.insert(1);
bst.insert(12);
bst.insert(18);
bst.insert(15);
bst.insert(16);
bst.inOrderTraversal();
System.out.println();
System.out.println(findKthSmallest(bst.root,11));
}
``````

}

Here is the java code,

max(Node root, int k) - to find kth largest

min(Node root, int k) - to find kth Smallest

``````static int count(Node root){
if(root == null)
return 0;
else
return count(root.left) + count(root.right) +1;
}
static int max(Node root, int k) {
if(root == null)
return -1;
int right= count(root.right);

if(k == right+1)
return root.data;
else if(right < k)
return max(root.left, k-right-1);
else return max(root.right, k);
}

static int min(Node root, int k) {
if (root==null)
return -1;

int left= count(root.left);
if(k == left+1)
return root.data;
else if (left < k)
return min(root.right, k-left-1);
else
return min(root.left, k);
}
``````

this would work too. just call the function with maxNode in the tree

def k_largest(self, node , k): if k < 0 : return None
if k == 0: return node else: k -=1 return self.k_largest(self.predecessor(node), k)

I think this is better than the accepted answer because it doesn't need to modify the original tree node to store the number of it's children nodes.

We just need to use the in-order traversal to count the smallest node from the left to right, stop searching once the count equals to K.

``````private static int count = 0;
public static void printKthSmallestNode(Node node, int k){
if(node == null){
return;
}

if( node.getLeftNode() != null ){
printKthSmallestNode(node.getLeftNode(), k);
}

count ++ ;
if(count <= k )
System.out.println(node.getValue() + ", count=" + count + ", k=" + k);

if(count < k  && node.getRightNode() != null)
printKthSmallestNode(node.getRightNode(), k);
}
``````

Best approach is already there.But I'd like to add a simple Code for that

``````int kthsmallest(treenode *q,int k){
int n = size(q->left) + 1;
if(n==k){
return q->val;
}
if(n > k){
return kthsmallest(q->left,k);
}
if(n < k){
return kthsmallest(q->right,k - n);
}
``````

}

``````int size(treenode *q){
if(q==NULL){
return 0;
}
else{
return ( size(q->left) + size(q->right) + 1 );
}}
``````

Using auxiliary Result class to track if node is found and current k.

``````public class KthSmallestElementWithAux {

public int kthsmallest(TreeNode a, int k) {
TreeNode ans = kthsmallestRec(a, k).node;
if (ans != null) {
return ans.val;
} else {
return -1;
}
}

private Result kthsmallestRec(TreeNode a, int k) {
//Leaf node, do nothing and return
if (a == null) {
return new Result(k, null);
}

//Search left first
Result leftSearch = kthsmallestRec(a.left, k);

//We are done, no need to check right.
if (leftSearch.node != null) {
return leftSearch;
}

//Consider number of nodes found to the left
k = leftSearch.k;

//Check if current root is the solution before going right
k--;
if (k == 0) {
return new Result(k - 1, a);
}

//Check right
Result rightBalanced = kthsmallestRec(a.right, k);

//Consider all nodes found to the right
k = rightBalanced.k;

if (rightBalanced.node != null) {
return rightBalanced;
}

//No node found, recursion will continue at the higher level
return new Result(k, null);

}

private class Result {
private final int k;
private final TreeNode node;

Result(int max, TreeNode node) {
this.k = max;
this.node = node;
}
}
}
``````

Python Solution Time Complexity : O(n) Space Complexity : O(1)

Idea is to use Morris Inorder Traversal

``````class Solution(object):
def inorderTraversal(self, current , k ):
while(current is not None):    #This Means we have reached Right Most Node i.e end of LDR traversal

if(current.left is not None):  #If Left Exists traverse Left First
pre = current.left   #Goal is to find the node which will be just before the current node i.e predecessor of current node, let's say current is D in LDR goal is to find L here
while(pre.right is not None and pre.right != current ): #Find predecesor here
pre = pre.right
if(pre.right is None):  #In this case predecessor is found , now link this predecessor to current so that there is a path and current is not lost
pre.right = current
current = current.left
else:                   #This means we have traverse all nodes left to current so in LDR traversal of L is done
k -= 1
if(k == 0):
return current.val
pre.right = None       #Remove the link tree restored to original here
current = current.right
else:               #In LDR  LD traversal is done move to R
k -= 1
if(k == 0):
return current.val
current = current.right

return 0

def kthSmallest(self, root, k):
return self.inorderTraversal( root , k  )
``````
``````public int kthSmallest(TreeNode root, int k) {

while (true) {
while (root != null) {
stack.push(root);
root = root.left;
}
root = stack.pop();
k = k - 1;
if (k == 0) return root.val;
root = root.right;
}

}
``````

Here are the steps:

1.Add a field to each node indicating the size of the tree it roots. This supports operation in O(logN) average time.

2.To save space, one field indicating the size of a node it roots is enough. We don't need to save both the left subtree and right subtree size.

3.Do an inorder traversal until LeftTree == K, LeftTree = Size(T->Left) + 1.

4.Here is the sample code:

``````int Size(SearchTree T)
{
if(T == NULL) return 0;
return T->Size;
}
Position KthSmallest(SearchTree T, int K)
{
if(T == NULL) return NULL;

int LeftTree;
LeftTree = Size(T->Left) + 1;

if(LeftTree == K) return T;

if(LeftTree > K){
T = KthSmallest(T->Left, K);
}else if(LeftTree < K){
T = KthSmallest(T->Right, K - LeftTree);
}

return T;
}
``````

5.Similarly, we can also get the KthLargest function.

i wrote a neat function to calculate the kth smallest element. I uses in-order traversal and stops when the it reaches the kth smallest element.

``````void btree::kthSmallest(node* temp, int& k){
if( temp!= NULL)   {
kthSmallest(temp->left,k);
if(k >0)
{
if(k==1)
{
cout<<temp->value<<endl;
return;
}

k--;
}

kthSmallest(temp->right,k);  }}
``````
• No metrics provided as to why this is optimal. In both large and small cases Oct 21, 2012 at 15:09
``````public static Node kth(Node n, int k){
Stack<Node> s=new Stack<Node>();
int countPopped=0;
while(!s.isEmpty()||n!=null){
if(n!=null){
s.push(n);
n=n.left;
}else{
node=s.pop();
countPopped++;
if(countPopped==k){
return node;
}
node=node.right;

}
}
``````

}