# Performing Breadth First Search recursively

Let's say you wanted to implement a breadth-first search of a binary tree recursively. How would you go about it?

Is it possible using only the call-stack as auxiliary storage?

• very good question. this is not straightforward at all. basically you're asking to implement a BFS using only a stack. Mar 31, 2010 at 0:22
• recursively with just a stack? this hurts my head. Mar 31, 2010 at 0:52
• I usually use a stack to remove recursive behaviour Mar 31, 2010 at 2:46
• If i use BFS on a Max heap , i wonder if solutions given below work properly ? Any thoughts ? Dec 8, 2014 at 22:15

(I'm assuming that this is just some kind of thought exercise, or even a trick homework/interview question, but I suppose I could imagine some bizarre scenario where you're not allowed any heap space for some reason [some really bad custom memory manager? some bizarre runtime/OS issues?] while you still have access to the stack...)

Breadth-first traversal traditionally uses a queue, not a stack. The nature of a queue and a stack are pretty much opposite, so trying to use the call stack (which is a stack, hence the name) as the auxiliary storage (a queue) is pretty much doomed to failure, unless you're doing something stupidly ridiculous with the call stack that you shouldn't be.

On the same token, the nature of any non-tail recursion you try to implement is essentially adding a stack to the algorithm. This makes it no longer breadth first search on a binary tree, and thus the run-time and whatnot for traditional BFS no longer completely apply. Of course, you can always trivially turn any loop into a recursive call, but that's not any sort of meaningful recursion.

However, there are ways, as demonstrated by others, to implement something that follows the semantics of BFS at some cost. If the cost of comparison is expensive but node traversal is cheap, then as @Simon Buchan did, you can simply run an iterative depth-first search, only processing the leaves. This would mean no growing queue stored in the heap, just a local depth variable, and stacks being built up over and over on the call stack as the tree is traversed over and over again. And as @Patrick noted, a binary tree backed by an array is typically stored in breadth-first traversal order anyway, so a breadth-first search on that would be trivial, also without needing an auxiliary queue.

• This is indeed just a thought exercise. I can't really imagine a situation in which you'd actually want to do this. Thanks for the well thought out answer!
– Nate
Mar 31, 2010 at 3:08
• "but I suppose I could imagine some bizarre scenario where you're not allowed any heap space for some reason": dunno, I can imagine an embedded environment where only the stack (along with any read-only memory space) is available (it's actually quite easy and efficient to write software without using the heap at all if you know exactly what your program is going to do, which is usually the case in embedded software). So it's not that "bizarre" to me. Unusual, maybe, but not bizarre. Aug 9, 2013 at 5:40
• If the only constraint is to use "stacks" and "no queue" - Use two stacks to mimic a queue Aug 16, 2021 at 5:33

If you use an array to back the binary tree, you can determine the next node algebraically. if `i` is a node, then its children can be found at `2i + 1` (for the left node) and `2i + 2` (for the right node). A node's next neighbor is given by `i + 1`, unless `i` is a power of `2`

Here's pseudocode for a very naive implementation of breadth first search on an array backed binary search tree. This assumes a fixed size array and therefore a fixed depth tree. It will look at parentless nodes, and could create an unmanageably large stack.

``````bintree-bfs(bintree, elt, i)
if (i == LENGTH)
return false

else if (bintree[i] == elt)
return true

else
return bintree-bfs(bintree, elt, i+1)
``````
• Nice. I overlooked the fact that we are dealing with a binary tree. The indexes can be assigned using a DFS. BTW, you forgot a return false at the first case. Mar 31, 2010 at 1:33
• I think I prefer the queueing method ;P. Added return false. Mar 31, 2010 at 1:36
• Clever. The idea of storing the nodes in an array and referencing them algebraically hadn't occurred to me.
– Nate
Mar 31, 2010 at 3:03

I couldn't find a way to do it completely recursive (without any auxiliary data-structure). But if the queue Q is passed by reference, then you can have the following silly tail recursive function:

``````BFS(Q)
{
if (|Q| > 0)
v <- Dequeue(Q)
Traverse(v)
foreach w in children(v)
Enqueue(Q, w)

BFS(Q)
}
``````
• This is unnatural way, to add recursive to clean and correct function. Aug 9, 2013 at 5:34
• Completely disagree - I find it more natural - and also more useful; you can extend this method to pass down working state as you go through layers Apr 11, 2020 at 19:38

The following method used a DFS algorithm to get all nodes in a particular depth - which is same as doing BFS for that level. If you find out depth of the tree and do this for all levels, the results will be same as a BFS.

``````public void PrintLevelNodes(Tree root, int level) {
if (root != null) {
if (level == 0) {
Console.Write(root.Data);
return;
}
PrintLevelNodes(root.Left, level - 1);
PrintLevelNodes(root.Right, level - 1);
}
}

for (int i = 0; i < depth; i++) {
PrintLevelNodes(root, i);
}
``````

Finding depth of a tree is a piece of cake:

``````public int MaxDepth(Tree root) {
if (root == null) {
return 0;
} else {
return Math.Max(MaxDepth(root.Left), MaxDepth(root.Right)) + 1;
}
}
``````
• Please pay a little bit more attention to your code formating. I did some changes. Aug 9, 2013 at 5:24
• But, hold on... is this a DFS rather than BFS? Because PrintLevelNodes does not return until `level` is zero. Feb 16, 2014 at 11:30
• @HerringtonDarkholme, Correct. It does DFS search but the outputs values as if it did a BFS for a level. Thanks for pointing out that.
– Sanj
May 9, 2014 at 20:51
• @Sanjay , this indeed is a good demonstration of how one might perform some action on nodes in DFS-order. It is not necessarily how one would actually "touch" nodes in DFS-order, but will certainly allow to recursively "act" on nodes in DFS order, in this case printing their values. Aug 5, 2014 at 23:55

A simple BFS and DFS recursion in Java:
Just push/offer the root node of the tree in the stack/queue and call these functions.

``````public static void breadthFirstSearch(Queue queue) {

if (queue.isEmpty())
return;

Node node = (Node) queue.poll();

System.out.println(node + " ");

if (node.right != null)
queue.offer(node.right);

if (node.left != null)
queue.offer(node.left);

}

public static void depthFirstSearch(Stack stack) {

if (stack.isEmpty())
return;

Node node = (Node) stack.pop();

System.out.println(node + " ");

if (node.right != null)
stack.push(node.right);

if (node.left != null)
stack.push(node.left);

depthFirstSearch(stack);
}
``````
• It's a bit weird to pass stack as a parameter for DFS, because you already have implicit stack there. Also the question was to use only call stack as a data structure. Jan 23, 2017 at 20:18

Here is a BFS recursive traversal Python implementation, working for a graph with no cycle.

``````def bfs_recursive(level):
'''
@params level: List<Node> containing the node for a specific level.
'''
next_level = []
for node in level:
print(node.value)
next_level.append(child_node)
if len(next_level) != 0:
bfs_recursive(next_level)

class Node:
def __init__(self, value):
self.value = value
``````

I found a very beautiful recursive (even functional) Breadth-First traversal related algorithm. Not my idea, but i think it should be mentioned in this topic.

Chris Okasaki explains his breadth-first numbering algorithm from ICFP 2000 at http://okasaki.blogspot.de/2008/07/breadth-first-numbering-algorithm-in.html very clearly with only 3 pictures.

The Scala implementation of Debasish Ghosh, which i found at http://debasishg.blogspot.de/2008/09/breadth-first-numbering-okasakis.html, is:

``````trait Tree[+T]
case class Node[+T](data: T, left: Tree[T], right: Tree[T]) extends Tree[T]
case object E extends Tree[Nothing]

def bfsNumForest[T](i: Int, trees: Queue[Tree[T]]): Queue[Tree[Int]] = {
if (trees.isEmpty) Queue.Empty
else {
trees.dequeue match {
case (E, ts) =>
bfsNumForest(i, ts).enqueue[Tree[Int]](E)
case (Node(d, l, r), ts) =>
val q = ts.enqueue(l, r)
val qq = bfsNumForest(i+1, q)
val (bb, qqq) = qq.dequeue
val (aa, tss) = qqq.dequeue
tss.enqueue[org.dg.collection.BFSNumber.Tree[Int]](Node(i, aa, bb))
}
}
}

def bfsNumTree[T](t: Tree[T]): Tree[Int] = {
val q = Queue.Empty.enqueue[Tree[T]](t)
val qq = bfsNumForest(1, q)
qq.dequeue._1
}
``````
• +1 for the beautiful algorithm. However, I found it still using a queue. The left side of "Rule 3" itself is actually the dequeue and enqueue operations. Oct 27, 2016 at 6:41

I would like to add my cents to the top answer in that if the language supports something like generator, bfs can be done co-recursively.

Breadth-first traversal traditionally uses a queue, not a stack. The nature of a queue and a stack are pretty much opposite, so trying to use the call stack (which is a stack, hence the name) as the auxiliary storage (a queue) is pretty much doomed to failure

Indeed, ordinary function call's stack won't behave like a normal stack. But generator function will suspend the execution of function so it gives us the chance to yield next level of nodes' children without delving into deeper descendants of the node.

The following code is recursive bfs in Python.

``````def bfs(root):
yield root
for n in bfs(root):
for c in n.children:
yield c
``````

The intuition here is:

1. bfs first will return the root as first result
2. suppose we already have the bfs sequence, the next level of elements in bfs is the immediate children of previous node in the sequence
3. repeat the above two procedures
• I don't know Python but I think your code translates to this C# code. It does the BFS traversal but crashes with a stackoverflow exception. I haven't figured out the why so far. However, I modified the algorithm so that it stops (and performs better probably). You find my working sample here. May 9, 2020 at 19:23

The dumb way:

``````template<typename T>
struct Node { Node* left; Node* right; T value; };

template<typename T, typename P>
bool searchNodeDepth(Node<T>* node, Node<T>** result, int depth, P pred) {
if (!node) return false;
if (!depth) {
if (pred(node->value)) {
*result = node;
}
return true;
}
--depth;
searchNodeDepth(node->left, result, depth, pred);
if (!*result)
searchNodeDepth(node->right, result, depth, pred);
return true;
}

template<typename T, typename P>
Node<T>* searchNode(Node<T>* node, P pred) {
Node<T>* result = NULL;
int depth = 0;
while (searchNodeDepth(node, &result, depth, pred) && !result)
++depth;
return result;
}

int main()
{
// a c   f
//  b   e
//    d
Node<char*>
a = { NULL, NULL, "A" },
c = { NULL, NULL, "C" },
b = { &a, &c, "B" },
f = { NULL, NULL, "F" },
e = { NULL, &f, "E" },
d = { &b, &e, "D" };

Node<char*>* found = searchNode(&d, [](char* value) -> bool {
printf("%s\n", value);
return !strcmp((char*)value, "F");
});

printf("found: %s\n", found->value);

return 0;
}
``````

Here is short Scala solution:

``````  def bfs(nodes: List[Node]): List[Node] = {
if (nodes.nonEmpty) {
nodes ++ bfs(nodes.flatMap(_.children))
} else {
List.empty
}
}
``````

Idea of using return value as accumulator is well suited. Can be implemented in other languages in similar way, just make sure that your recursive function process list of nodes.

Test code listing (using @marco test tree):

``````import org.scalatest.FlatSpec

import scala.collection.mutable

class Node(val value: Int) {

private val _children: mutable.ArrayBuffer[Node] = mutable.ArrayBuffer.empty

def add(child: Node): Unit = _children += child

def children = _children.toList

override def toString: String = s"\$value"
}

class BfsTestScala extends FlatSpec {

//            1
//          / | \
//        2   3   4
//      / |       | \
//    5   6       7  8
//  / |           | \
// 9  10         11  12
def tree(): Node = {
val root = new Node(1)
root
}

def bfs(nodes: List[Node]): List[Node] = {
if (nodes.nonEmpty) {
nodes ++ bfs(nodes.flatMap(_.children))
} else {
List.empty
}
}

"BFS" should "work" in {
println(bfs(List(tree())))
}
}
``````

Output:

``````List(1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
``````

Here's a python implementation:

``````graph = {'A': ['B', 'C'],
'B': ['C', 'D'],
'C': ['D'],
'D': ['C'],
'E': ['F'],
'F': ['C']}

def bfs(paths, goal):
if not paths:
raise StopIteration

new_paths = []
for path in paths:
if path[-1] == goal:
yield path

last = path[-1]
for neighbor in graph[last]:
if neighbor not in path:
new_paths.append(path + [neighbor])
yield from bfs(new_paths, goal)

for path in bfs([['A']], 'D'):
print(path)
``````

Here's a Scala 2.11.4 implementation of recursive BFS. I've sacrificed tail-call optimization for brevity, but the TCOd version is very similar. See also @snv's post.

``````import scala.collection.immutable.Queue

object RecursiveBfs {
def bfs[A](tree: Tree[A], target: A): Boolean = {
bfs(Queue(tree), target)
}

private def bfs[A](forest: Queue[Tree[A]], target: A): Boolean = {
forest.dequeueOption exists {
case (E, tail) => bfs(tail, target)
case (Node(value, _, _), _) if value == target => true
case (Node(_, l, r), tail) => bfs(tail.enqueue(List(l, r)), target)
}
}

sealed trait Tree[+A]
case class Node[+A](data: A, left: Tree[A], right: Tree[A]) extends Tree[A]
case object E extends Tree[Nothing]
}
``````

The following seems pretty natural to me, using Haskell. Iterate recursively over levels of the tree (here I collect names into a big ordered string to show the path through the tree):

``````data Node = Node {name :: String, children :: [Node]}
aTree = Node "r" [Node "c1" [Node "gc1" [Node "ggc1" []], Node "gc2" []] , Node "c2" [Node "gc3" []], Node "c3" [] ]
where levelRecurser level = if length level == 0
then ""
else concat [name node ++ " " | node <- level] ++ levelRecurser (concat [children node | node <- level])
``````

I had to implement a heap traversal which outputs in a BFS order. It isn't actually BFS but accomplishes the same task.

``````private void getNodeValue(Node node, int index, int[] array) {
array[index] = node.value;
index = (index*2)+1;

Node left = node.leftNode;
if (left!=null) getNodeValue(left,index,array);
Node right = node.rightNode;
if (right!=null) getNodeValue(right,index+1,array);
}

public int[] getHeap() {
int[] nodes = new int[size];
getNodeValue(root,0,nodes);
return nodes;
}
``````
• For other viewers: this is an example of implementing a complete tree in an array; Specifically, @Justin is doing a pre-order traversal, during which he saves node values (in BFS order) in an array at the appropriate BFS index. This allows the calling function to iterate linearly through the array, printing values in the BFS order. See this general description Note: the calling function must handle the case of non-complete trees. Aug 6, 2014 at 0:17

Let v be the starting vertex

Let G be the graph in question

The following is the pseudo code without using queue

``````Initially label v as visited as you start from v
BFS(G,v)
for all adjacent vertices w of v in G:
if vertex w is not visited:
label w as visited
for all adjacent vertices w of v in G:
recursively call BFS(G,w)
``````
• I think this might get stuck in an infinite loop -- the vertices are being marked as visited, but they are never tested for visited-ness before recursing again.
– user755921
Feb 9, 2016 at 17:43
• This snippet is similar to DFS rather than BFS
– Dení
Aug 2, 2017 at 5:13

BFS for a binary (or n-ary) tree can be done recursively without queues as follows (here in Java):

``````public class BreathFirst {

static class Node {
Node(int value) {
this(value, 0);
}
Node(int value, int nChildren) {
this.value = value;
this.children = new Node[nChildren];
}
int value;
Node[] children;
}

static void breathFirst(Node root, Consumer<? super Node> printer) {
boolean keepGoing = true;
for (int level = 0; keepGoing; level++) {
keepGoing = breathFirst(root, printer, level);
}
}

static boolean breathFirst(Node node, Consumer<? super Node> printer, int depth) {
if (depth < 0 || node == null) return false;
if (depth == 0) {
printer.accept(node);
return true;
}
boolean any = false;
for (final Node child : node.children) {
any |= breathFirst(child, printer, depth - 1);
}
return any;
}
}
``````

An example traversal printing numbers 1-12 in ascending order:

``````public static void main(String... args) {
//            1
//          / | \
//        2   3   4
//      / |       | \
//    5   6       7  8
//  / |           | \
// 9  10         11  12

Node root = new Node(1, 3);
root.children = new Node(2, 2);
root.children = new Node(3);
root.children = new Node(4, 2);
root.children.children = new Node(5, 2);
root.children.children = new Node(6);
root.children.children = new Node(7, 2);
root.children.children = new Node(8);
root.children.children.children = new Node(9);
root.children.children.children = new Node(10);
root.children.children.children = new Node(11);
root.children.children.children = new Node(12);

breathFirst(root, n -> System.out.println(n.value));
}
``````
``````#include <bits/stdc++.h>
using namespace std;
#define Max 1000

bool visited[Max];

void bfs_recursion_utils(queue<int>& Q) {
while(!Q.empty()) {
int u = Q.front();
visited[u] = true;
cout << u << endl;
Q.pop();
for(int i = 0; i < (int)adj[u].size(); ++i) {
if(!visited[v])
Q.push(v), visited[v] = true;
}
bfs_recursion_utils(Q);
}
}

void bfs_recursion(int source, queue <int>& Q) {
memset(visited, false, sizeof visited);
Q.push(source);
bfs_recursion_utils(Q);
}

int main(void) {
queue <int> Q;

bfs_recursion(1, Q);
return 0;
}
``````

Here is a JavaScript Implementation that fakes Breadth First Traversal with Depth First recursion. I'm storing the node values at each depth inside an array, inside of a hash. If a level already exists(we have a collision), so we just push to the array at that level. You could use an array instead of a JavaScript object as well since our levels are numeric and can serve as array indices. You can return nodes, values, convert to a Linked List, or whatever you want. I'm just returning values for the sake of simplicity.

``````BinarySearchTree.prototype.breadthFirstRec = function() {

var levels = {};

var traverse = function(current, depth) {
if (!current) return null;
if (!levels[depth]) levels[depth] = [current.value];
else levels[depth].push(current.value);
traverse(current.left, depth + 1);
traverse(current.right, depth + 1);
};

traverse(this.root, 0);
return levels;
};

var bst = new BinarySearchTree();
bst.add(20, 22, 8, 4, 12, 10, 14, 24);
{ '0': [ 20 ],
'1': [ 8, 22 ],
'2': [ 4, 12, 24 ],
'3': [ 10, 14 ] } */
``````

Here is an example of actual Breadth First Traversal using an iterative approach.

``````BinarySearchTree.prototype.breadthFirst = function() {

var result = '',
queue = [],
current = this.root;

if (!current) return null;
queue.push(current);

while (current = queue.shift()) {
result += current.value + ' ';
current.left && queue.push(current.left);
current.right && queue.push(current.right);
}
return result;
};

//Breadth First:  20 8 22 4 12 24 10 14
``````

Following is my code for completely recursive implementation of breadth-first-search of a bidirectional graph without using loop and queue.

``````

public class Graph
{
public int V;

Graph(int v)
{
V = v;
for (int i=0; i<v; ++i)
}

{
}

{
}

public String toString()
{
String s = "";

{
s = s +"\n"+i +"-->"+ adj[i] ;
}
return s;
}
}

//BFS IMPLEMENTATION

public static void recursiveBFS(Graph graph, int vertex,boolean visited[], boolean isAdjPrinted[])
{
if (!visited[vertex])
{
System.out.print(vertex +" ");
visited[vertex] = true;
}

{
}
}

public static void recursiveBFS(Graph graph, List<Integer> vertexList, boolean visited[], int i, boolean isAdjPrinted[])
{
if (i < vertexList.size())
{
}
}

public static void printAdjecent(Graph graph, List<Integer> list, boolean visited[], int i, boolean isAdjPrinted[])
{
if (i < list.size())
{
if (!visited[list.get(i)])
{
System.out.print(list.get(i)+" ");
visited[list.get(i)] = true;
}
}
else
{
}
}
``````

C# implementation of recursive breadth-first search algorithm for a binary tree.

Binary tree data visualization

``````IDictionary<string, string[]> graph = new Dictionary<string, string[]> {
{"A", new [] {"B", "C"}},
{"B", new [] {"D", "E"}},
{"C", new [] {"F", "G"}},
{"E", new [] {"H"}}
};

void Main()
{
var pathFound = BreadthFirstSearch("A", "H", new string);
Console.WriteLine(pathFound); // [A, B, E, H]

var pathNotFound = BreadthFirstSearch("A", "Z", new string);
Console.WriteLine(pathNotFound); // []
}

IEnumerable<string> BreadthFirstSearch(string start, string end, IEnumerable<string> path)
{
if (start == end)
{
return path.Concat(new[] { end });
}

if (!graph.ContainsKey(start)) { return new string; }

return graph[start].SelectMany(letter => BreadthFirstSearch(letter, end, path.Concat(new[] { start })));
}
``````

If you want algorithm to work not only with binary-tree but with graphs what can have two and more nodes that points to same another node you must to avoid self-cycling by holding list of already visited nodes. Implementation may be looks like this.

Graph data visualization

``````IDictionary<string, string[]> graph = new Dictionary<string, string[]> {
{"A", new [] {"B", "C"}},
{"B", new [] {"D", "E"}},
{"C", new [] {"F", "G", "E"}},
{"E", new [] {"H"}}
};

void Main()
{
var pathFound = BreadthFirstSearch("A", "H", new string, new List<string>());
Console.WriteLine(pathFound); // [A, B, E, H]

var pathNotFound = BreadthFirstSearch("A", "Z", new string, new List<string>());
Console.WriteLine(pathNotFound); // []
}

IEnumerable<string> BreadthFirstSearch(string start, string end, IEnumerable<string> path, IList<string> visited)
{
if (start == end)
{
return path.Concat(new[] { end });
}

if (!graph.ContainsKey(start)) { return new string; }

return graph[start].Aggregate(new string, (acc, letter) =>
{
if (visited.Contains(letter))
{
return acc;
}

var result = BreadthFirstSearch(letter, end, path.Concat(new[] { start }), visited);
return acc.Concat(result).ToArray();
});
}
``````

I have made a program using c++ which is working in joint and disjoint graph too .

``````    #include <queue>
#include "iostream"
#include "vector"
#include "queue"

using namespace std;

struct Edge {
int source,destination;
};

class Graph{
int V;
public:

Graph(vector<Edge> edges,int V){
this->V = V;
for(auto i : edges){
}
}
void BFSRecursivelyJoinandDisjointtGraphUtil(vector<bool> &discovered, queue<int> &q);
void BFSRecursivelyJointandDisjointGraph(int s);
void printGraph();

};

void Graph :: printGraph()
{
for (int i = 0; i < this->adjList.size(); i++)
{
cout << i << " -- ";
cout <<"->"<< v << " ";
cout << endl;
}
}

void Graph ::BFSRecursivelyJoinandDisjointtGraphUtil(vector<bool> &discovered, queue<int> &q) {
if (q.empty())
return;
int v = q.front();
q.pop();
cout << v <<" ";
{
if (!discovered[u])
{
discovered[u] = true;
q.push(u);
}
}
BFSRecursivelyJoinandDisjointtGraphUtil(discovered, q);

}

void Graph ::BFSRecursivelyJointandDisjointGraph(int s) {
vector<bool> discovered(V, false);
queue<int> q;

for (int i = s; i < V; i++) {
if (discovered[i] == false)
{
discovered[i] = true;
q.push(i);
BFSRecursivelyJoinandDisjointtGraphUtil(discovered, q);
}
}
}

int main()
{

vector<Edge> edges =
{
{0, 1}, {0, 2}, {1, 2}, {2, 0}, {2,3},{3,3}
};

int V = 4;
Graph graph(edges, V);
//   graph.printGraph();
graph.BFSRecursivelyJointandDisjointGraph(2);
cout << "\n";

edges = {
{0,4},{1,2},{1,3},{1,4},{2,3},{3,4}
};

Graph graph2(edges,5);

graph2.BFSRecursivelyJointandDisjointGraph(0);
return 0;
}
``````

I think this can be done using pointers, without using any QUEUE.

Basically we are maintaining two pointers at any point, one is pointing to the parents, the other is pointing to the children to be processed ( linkedlist to all which have been processed )

Now you simply assign the pointer of the child & when parent processing finishes you just make the child to be parent for processing next level

following is my code :

``````//Tree Node
struct Node {
int val;
Node* left;
Node* right;
Node* next;

Node() : val(0), left(NULL), right(NULL), next(NULL) {}

Node(int _val) : val(_val), left(NULL), right(NULL), next(NULL) {}

Node(int _val, Node* _left, Node* _right, Node* _next)
: val(_val), left(_left), right(_right), next(_next) {}
};

``````

//Algorightm :

``````    void LevelTraverse(Node* parent,Node* chidstart,Node* childend ){
if(!parent && !chidstart) return;  // we processed everything

if(!parent && chidstart){ //finished processing last level
parent=chidstart;chidstart=childend=NULL; // assgin child to parent for processing next level
LevelTraverse(parent,chidstart,childend);
}else if(parent && !chidstart){ // This is new level first node tobe processed
Node* temp=parent; parent=parent->next;
if(temp->left) { childend=chidstart=temp->left; }
if(chidstart){
if(temp->right) { childend->next=temp->right; childend=temp->right; }
}else{
if(temp->right) { childend=chidstart=temp->right; }
}
LevelTraverse(parent,chidstart,childend);
}else if(parent && chidstart){ //we are in mid of some level processing
Node* temp=parent; parent=parent->next;
if(temp->left) { childend->next=temp->left; childend=temp->left; }
if(temp->right) { childend->next=temp->right; childend=temp->right; }
LevelTraverse(parent,chidstart,childend);
}
}
``````

//Driver code :

``````    Node* connect(Node* root) {
if(!root) return NULL;
Node* parent; Node* childs, *childe; parent=childs=childe=NULL;
parent=root;
LevelTraverse(parent, childs, childe);
return root;
}
``````