# Nodes at a distance k in binary tree

You are given a function printKDistanceNodes which takes in a root node of a binary tree, a start node and an integer K. Complete the function to print the value of all the nodes (one-per-line) which are a K distance from the given start node in sorted order. Distance can be upwards or downwards.

``````private void printNodeAtN(Node root, Node start, int k) {
if (root != null) {
// calculate if the start is in left or right subtree - if start is
// root this variable is null
Boolean left = isLeft(root, start);
int depth = depth(root, start, 0);

if (depth == -1)
return;
printNodeDown(root, k);

if (root == start)
return;

if (left) {
if (depth > k) {
// print the nodes at depth-k level in left tree
printNode(depth - k - 1, root.left);
} else if (depth < k) {
// print the nodes at right tree level k-depth
printNode(k - depth - 1, root.right);
} else {
System.out.println(root.data);
}
} else {
// similar if the start is in right subtree
if (depth > k) {
// print the nodes at depth-k level in left tree
printNode(depth - k - 1, root.right);
} else if (depth < k) {
// print the nodes at right tree level k-depth
printNode(k - depth - 1, root.left);
} else {
System.out.println(root.data);
}
}
}
}

// print the nodes at depth - "level" from root
void printNode(int level, Node root) {
if (level == 0 && root != null) {
System.out.println(root.data);
} else {
printNode(level - 1, root.left);
printNode(level - 1, root.right);
}

}

// print the children of the start
void printNodeDown(Node start, int k) {
if (start != null) {
if (k == 0) {
System.out.println(start.data);
}
printNodeDown(start.left, k - 1);
printNodeDown(start.right, k - 1);
}
}

private int depth(Node root, Node node, int d) {
if (root == null)
return -1;
if (root != null && node == root) {
return d;
} else {
int left = depth(root.left, node, d + 1);
int right = depth(root.right, node, d + 1);
if (left > right)
return left;
else
return right;
}
}
``````

There is at most one node at distance K which upwards - just start from the start node and move up along parents for K steps. Add this to a sorted data structure.

Then you need to add the downward nodes. To do that you can do a BFS with queue, where you store the depth together with the node when you insert it in the queue (the starting node is at level 0, it's children at level 1 and so on). Then when you pop the nodes if they are at level K add them to the sorted data structure. when you start poping nodes at level K+1 you can stop.

Finally print the nodes from the sorted data structure (they will be sorted).

EDIT: If there is no parent pointer:

Write a recursive function `int Go(Node node)`, which returns the depth of the start node with respect to the passed in node and -1 if the subtree of node doesn't contain start. The function will find the K-th parent as a side effect. Pseudo code:

``````static Node KthParent = null;
static Node start = ...;
static int K = ...;

int Go(Node node) {
if (node == start) return 0;

intDepth = -1;

if(node.LeftChild != null) {
int leftDepth = Go(node.LeftChild);
if(leftDepth >= 0) intDepth = leftDepth+1;
}
if (intDepth < 0 && node.rightChild != null) {
int rightDepth = Go(node.RightChild);
if(rightDepth >= 0) intDepth = rightDepth+1;
}

if(intDepth == K) KthParent = node;

return intDepth;
}
``````
• I have a question, say, we have a simple tree (root 1, left child 2, right child 3), should the distance between left child and right child equal 2.
– J.W.
Mar 20 '14 at 3:17
• `There is at most one node at distance K which upwards` is wrong. For example, seeking for distance 2 to x, suppose x is the left child of parent, so the parent's right child is 2 steps away from x, if it is not Empty Mar 23 '14 at 16:56
``````private static int printNodeAtK(Node root, Node start, int k, boolean found){
if(root != null){
if(k == 0 && found){
System.out.println(root.data);
}
if(root==start || found == true){
int leftd = printNodeAtK(root.left, start, k-1, true);
int rightd = printNodeAtK(root.right,start,k-1,true);
return 1;
}else{
int leftd = printNodeAtK(root.left, start, k, false);
int rightd = printNodeAtK(root.right,start,k,false);
if(leftd == k || rightd == k){
System.out.println(root.data);
}
if(leftd != -1 && leftd > rightd){
return leftd+1;
}else if(rightd != -1 && rightd>leftd){
return rightd+1;
}else{
return -1;
}
}

}
return -1;
}
``````
``````struct node{
int data;
node* left;
node* right;
bool printed;
};

void print_k_dist(node** root,node** p,int k,int kmax);
void reinit_printed(node **root);

void print_k_dist(node** root,node **p,int k,int kmax)
{
if(*p==NULL) return;
node* par=parent(root,p);
if(k<=kmax &&(*p)->printed==0)
{
cout<<(*p)->data<<" ";
(*p)->printed=1;
k++;
print_k_dist(root,&par,k,kmax);
print_k_dist(root,&(*p)->left,k,kmax);
print_k_dist(root,&(*p)->right,k,kmax);
}
else
return;
}

void reinit_printed(node **root)
{
if(*root==NULL) return;
else
{
(*root)->printed=0;
reinit_printed(&(*root)->left);
reinit_printed(&(*root)->right);
}
}
``````
``````typedef struct node
{
int data;
struct node *left;
struct node *right;

}node;

void printkdistanceNodeDown(node *n, int k)
{
if(!n)
return ;

if(k==0)
{
printf("%d\n",n->data);
return;
}

printkdistanceNodeDown(n->left,k-1);
printkdistanceNodeDown(n->right,k-1);
}

void  printkdistanceNodeDown_fromUp(node* target ,int *k)
{
if(!target)
return ;

if(*k==0)
{
printf("%d\n",target->data);
return;
}
else
{
int val=*k;
printkdistanceNodeDown(target,val-1);
}
}

int printkdistanceNodeUp(node* root, node* n , int k)
{
if(!root)
return 0;

if(root->data==n->data)
return 1;

int pl=printkdistanceNodeUp(root->left,n,k);
int pr=printkdistanceNodeUp(root->right,n,k);

if(pl )
{
k--;

if(k==0)
printf("%d\n",root->data);
else
{
printkdistanceNodeDown_fromUp(root->right,k);
printkdistanceNodeDown_fromUp(root->left,k-1);
}
return 1;
}

if(pr )
{
k--;
if(k==0)
printf("%d\n",root->data);
else
{
printkdistanceNodeDown_fromUp(root->left,k);
printkdistanceNodeDown_fromUp(root->right,k-1);
}

return 1;
}

return 0;
}

void printkdistanceNode(node* root, node* n , int k )
{
if(!root)
return ;

int val=k;
printkdistanceNodeUp(root,n,k);
printkdistanceNodeDown(n,val);

}
``````

caller function: `printkdistanceNode(root,n,k);`

The output will print all the nodes at a distance k from given node upward and downward.

Here in this code PrintNodesAtKDistance will first try to find the required node.

``````if(root.value == requiredNode)
``````

When we find the desired node we print all the child nodes at the distance K from this node.

Now our task is to print all nodes which are in other branches(Go up and print). We return -1 till we didn't find our desired node. As we get our desired node we get `lPath` or `rPath >=0` . Now we have to print all nodes which are at distance `(lPath/rPath) -1`

``````public void PrintNodes(Node Root, int requiredNode, int iDistance)

{
PrintNodesAtKDistance(Root, requiredNode, iDistance);
}

public int PrintNodesAtKDistance(Node root, int requiredNode, int iDistance)
{
if ((root == null) || (iDistance < 0))
return -1;

int lPath = -1, rPath = -1;

if(root.value == requiredNode)
{
PrintChildNodes(root, iDistance);
return iDistance - 1;
}

lPath = PrintNodesAtKDistance(root.left, requiredNode, iDistance);
rPath = PrintNodesAtKDistance(root.right, requiredNode, iDistance);

if (lPath > 0)
{
PrintChildNodes(root.right, lPath - 1);
return lPath - 1;
}
else if(lPath == 0)
{
Debug.WriteLine(root.value);
}

if(rPath > 0)
{
PrintChildNodes(root.left, rPath - 1);
return rPath - 1;
}
else if (rPath == 0)
{
Debug.WriteLine(root.value);
}

return -1;
}

public void PrintChildNodes(Node aNode, int iDistance)
{
if (aNode == null)
return;

if(iDistance == 0)
{
Debug.WriteLine(aNode.value);
}

PrintChildNodes(aNode.left, iDistance - 1);
PrintChildNodes(aNode.right, iDistance - 1);
}
``````

Here is complete java program . Inspired from geeksforgeeks Algorith

``````// Java program to print all nodes at a distance k from given node

class BinaryTreePrintKDistance {
Node root;

/*
* Recursive function to print all the nodes at distance k in tree (or
* subtree) rooted with given root.
*/

void printKDistanceForDescendant(Node targetNode, int currentDist,
int inputDist) {
// Base Case
if (targetNode == null || currentDist > inputDist)
return;

// If we reach a k distant node, print it
if (currentDist == inputDist) {
System.out.print(targetNode.data);
System.out.println("");
return;
}

++currentDist;
// Recur for left and right subtrees
printKDistanceForDescendant(targetNode.left, currentDist, inputDist);
printKDistanceForDescendant(targetNode.right, currentDist, inputDist);
}

public int printkdistance(Node targetNode, Node currentNode,
int inputDist) {

if (currentNode == null) {
return -1;
}

if (targetNode.data == currentNode.data) {
printKDistanceForDescendant(currentNode, 0, inputDist);
return 0;
}

int ld = printkdistance(targetNode, currentNode.left, inputDist);

if (ld != -1) {

if (ld + 1 == inputDist) {
System.out.println(currentNode.data);

} else {
printKDistanceForDescendant(currentNode.right, 0, inputDist
- ld - 2);
}

return ld + 1;
}

int rd = printkdistance(targetNode, currentNode.right, inputDist);

if (rd != -1) {

if (rd + 1 == inputDist) {
System.out.println(currentNode.data);

} else {
printKDistanceForDescendant(currentNode.left, 0, inputDist - rd
- 2);
}

return rd + 1;
}

return -1;

}

// Driver program to test the above functions
@SuppressWarnings("unchecked")
public static void main(String args[]) {
BinaryTreePrintKDistance tree = new BinaryTreePrintKDistance();

/* Let us construct the tree shown in above diagram */
tree.root = new Node(20);
tree.root.left = new Node(8);
tree.root.right = new Node(22);
tree.root.left.left = new Node(4);
tree.root.left.right = new Node(12);
tree.root.left.right.left = new Node(10);
tree.root.left.right.right = new Node(14);
Node target = tree.root.left;

tree.printkdistance(target, tree.root, 2);
}

static class Node<T> {
public Node left;
public Node right;
public T data;

Node(T data) {
this.data = data;
}
}

}
``````