# Algorithm to print all paths with a given sum in a binary tree

The following is an interview question.

You are given a binary tree (not necessarily BST) in which each node contains a value. Design an algorithm to print all paths which sum up to that value. Note that it can be any path in the tree - it does not have to start at the root.

Although I am able to find all paths in tree that start at the root have the given sum, I am not able to do so for paths not not starting at the root.

• Any constraints on the values? Are they allowed to be negative? – Fred Foo Jul 4 '12 at 11:46
• Reuse your algorithm with all other nodes as root. – nhahtdh Jul 4 '12 at 11:47
• Despite my abortive answer below (which I'll remove if not useful), I admit that I see no way to do what the interviewer wants in the general case other than a brute-force search. – thb Jul 4 '12 at 11:54
• possible duplicate of Find paths in a binary search tree summing to a target value – David Z Jul 8 '12 at 6:52
• What do they mean by "any path in the tree"? It still has to be strictly directed downwards (from root towards leaves), right? E.g. `aNode -> parentOfaNode -> siblingOfaNode` wouldn't be a valid path would it? – Alderath Jul 19 '12 at 8:31

Well, this is a tree, not a graph. So, you can do something like this:

Pseudocode:

``````global ResultList

function ProcessNode(CurrentNode, CurrentSum)
CurrentSum+=CurrentNode->Value
for all Children of CurrentNode
ProcessNode(Child,CurrentSum)
``````

Well, this gives you the paths that start at the root. However, you can just make a tiny change:

``````    for all Children of CurrentNode
ProcessNode(Child,CurrentSum)
ProcessNode(Child,0)
``````

You might need to think about it for a second (I'm busy with other things), but this should basically run the same algorithm rooted at every node in the tree

EDIT: this actually gives the "end node" only. However, as this is a tree, you can just start at those end nodes and walk back up until you get the required sum.

EDIT 2: and, of course, if all values are positive then you can abort the descent if your current sum is >= the required one

• Nice answer @Christian, but what is the time complexity of that ? I would guess it is O(n^2), since you are from one node n visiting the others O(n), and doing it n times, since you are changing the root, and that would output O(n^2). Do what I said makes sense ? – Tito Nov 7 '13 at 14:04
• I don't think this solution will work after trying to implement it. – J.W. Jun 13 '14 at 1:31
• what if a path goes from one leaf to other this will not handle that case. – Prashant Bhanarkar Aug 19 '16 at 16:13

Here's an `O(n + numResults)` answer (essentially the same as @Somebody's answer, but with all issues resolved):

1. Do a pre-order, in-order, or post-order traversal of the binary tree.
2. As you do the traversal, maintain the cumulative sum of node values from the root node to the node above the current node. Let's call this value `cumulativeSumBeforeNode`.
3. When you visit a node in the traversal, add it to a hashtable at key `cumulativeSumBeforeNode` (the value at that key will be a list of nodes).
4. Compute the difference between `cumulativeSumBeforeNode` and the target sum. Look up this difference in the hash table.
5. If the hash table lookup succeeds, it should produce a list of nodes. Each one of those nodes represents the start node of a solution. The current node represents the end node for each corresponding start node. Add each [start node, end node] combination to your list of answers. If the hash table lookup fails, do nothing.
6. When you've finished visiting a node in the traversal, remove the node from the list stored at key `cumulativeSumBeforeNode` in the hash table.

Code:

``````import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
import java.util.HashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;

public class BinaryTreePathsWithSum {
public static void main(String[] args) {
BinaryTreeNode a = new BinaryTreeNode(5);
BinaryTreeNode b = new BinaryTreeNode(16);
BinaryTreeNode c = new BinaryTreeNode(16);
BinaryTreeNode d = new BinaryTreeNode(4);
BinaryTreeNode e = new BinaryTreeNode(19);
BinaryTreeNode f = new BinaryTreeNode(2);
BinaryTreeNode g = new BinaryTreeNode(15);
BinaryTreeNode h = new BinaryTreeNode(91);
BinaryTreeNode i = new BinaryTreeNode(8);

BinaryTreeNode root = a;
a.left = b;
a.right = c;
b.right = e;
c.right = d;
e.left = f;
f.left = g;
f.right = h;
h.right = i;

/*
5
/   \
16     16
\     \
19     4
/
2
/ \
15  91
\
8
*/

List<BinaryTreePath> pathsWithSum = getBinaryTreePathsWithSum(root, 112); // 19 => 2 => 91

System.out.println(Arrays.toString(pathsWithSum.toArray()));
}

public static List<BinaryTreePath> getBinaryTreePathsWithSum(BinaryTreeNode root, int sum) {
if (root == null) {
throw new IllegalArgumentException("Must pass non-null binary tree!");
}

List<BinaryTreePath> paths = new ArrayList<BinaryTreePath>();
Map<Integer, List<BinaryTreeNode>> cumulativeSumMap = new HashMap<Integer, List<BinaryTreeNode>>();

populateBinaryTreePathsWithSum(root, 0, cumulativeSumMap, sum, paths);

return paths;
}

private static void populateBinaryTreePathsWithSum(BinaryTreeNode node, int cumulativeSumBeforeNode, Map<Integer, List<BinaryTreeNode>> cumulativeSumMap, int targetSum, List<BinaryTreePath> paths) {
if (node == null) {
return;
}

int cumulativeSumIncludingNode = cumulativeSumBeforeNode + node.value;
int sumToFind = cumulativeSumIncludingNode - targetSum;

if (cumulativeSumMap.containsKey(sumToFind)) {
List<BinaryTreeNode> candidatePathStartNodes = cumulativeSumMap.get(sumToFind);

for (BinaryTreeNode pathStartNode : candidatePathStartNodes) {
}
}

populateBinaryTreePathsWithSum(node.left, cumulativeSumIncludingNode, cumulativeSumMap, targetSum, paths);
populateBinaryTreePathsWithSum(node.right, cumulativeSumIncludingNode, cumulativeSumMap, targetSum, paths);

removeFromMap(cumulativeSumMap, cumulativeSumBeforeNode);
}

private static void addToMap(Map<Integer, List<BinaryTreeNode>> cumulativeSumMap, int cumulativeSumBeforeNode, BinaryTreeNode node) {
if (cumulativeSumMap.containsKey(cumulativeSumBeforeNode)) {
List<BinaryTreeNode> nodes = cumulativeSumMap.get(cumulativeSumBeforeNode);
} else {
List<BinaryTreeNode> nodes = new ArrayList<BinaryTreeNode>();
cumulativeSumMap.put(cumulativeSumBeforeNode, nodes);
}
}

private static void removeFromMap(Map<Integer, List<BinaryTreeNode>> cumulativeSumMap, int cumulativeSumBeforeNode) {
List<BinaryTreeNode> nodes = cumulativeSumMap.get(cumulativeSumBeforeNode);
nodes.remove(nodes.size() - 1);
}

private static class BinaryTreeNode {
public int value;
public BinaryTreeNode left;
public BinaryTreeNode right;

public BinaryTreeNode(int value) {
this.value = value;
}

public String toString() {
return this.value + "";
}

public int hashCode() {
return Integer.valueOf(this.value).hashCode();
}

public boolean equals(Object other) {
return this == other;
}
}

private static class BinaryTreePath {
public BinaryTreeNode start;
public BinaryTreeNode end;

public BinaryTreePath(BinaryTreeNode start, BinaryTreeNode end) {
this.start = start;
this.end = end;
}

public String toString() {
return this.start + " to " + this.end;
}
}
}
``````
• Wouldn't we also need to ensure that the nodes found (start and end) are on the same path ? – Anant Jan 2 '17 at 19:47
• @Anant: Step 6 in my algorithm ensures this. The hash table contains only values for a single root to node path at any given time. In this way, we ensure that the start and end node are on the same path. Does that make sense? – John Kurlak Jan 2 '17 at 23:33
• Interesting algorithm, however, is it slightly off? What if tree is inorder:{19,16,5,16} with root=5, root.left=16, root.right=16, and target=56? the path I'd like to return is then 19-16-5-16. However, based on the algorithm you listed, you'd not get the start node (since step #6 would remove root.left from the map) right? – Nishant Kelkar Feb 12 '17 at 9:13
• @NishantKelkar: I'm interpreting "path" as "strictly directed downwards (from root towards leaves)" as presumed in the question comments. – John Kurlak Feb 14 '17 at 21:33

``````public void printSums(Node n, int sum, int currentSum, String buffer) {
if (n == null) {
return;
}
int newSum = currentSum + n.val;
String newBuffer = buffer + " " + n.val;
if (newSum == sum) {
System.out.println(newBuffer);
}
printSums(n.left, sum, newSum, newBuffer);
printSums(n.right, sum, newSum, newBuffer);
printSums(n.left, sum, 0, "");
printSums(n.right, sum, 0, "");
}

printSums(root, targetSum, 0, "");
``````
• wrong answer!! sample test case [code] 11 / \ 8 13 / \ 1 9 target sum: 18 – titan Feb 15 '14 at 19:44
• Hi @titan, I dont understand how 11/\8 13/\1 9 is supposed to be structured. – mawaldne Feb 19 '14 at 15:49
• Just enter the numbers 11, 8, 13, 1, 9 in sequence in a BST – titan Feb 20 '14 at 16:31
• it does not contain the path starting from a left sub-tree node to a right sub-tree node. say: 2<-1->3, 1 as the root. the path: 2->1->3. right? – Pan Aug 21 '14 at 14:29
• -1 Wrong. Consider a full balanced tree with `1`'s, depth 3, and print paths for `sum==1`. Leaf nodes will be printed twice. A quick fix: Surround the two last lines with a conditional check that `buffer.equals("")`. – gamliela Nov 9 '16 at 9:17

Here is an approach with `nlogn` complexity.

1. Traverse the tree with inorder.
2. At the same time maintain all the nodes along with the cumulative sum in a `Hashmap<CumulativeSum, reference to the corresponding node>`.
3. Now at a given node calculate cumulative sum from root to till the node say this be `SUM`.
4. Now look for the value `SUM-K` in the `HashMap`.
5. If the entry exists take the corresponding node reference in the `HashMap`.
6. Now we have a valid path from the node reference to the current node.
• @Somebody This doesn't quite work. It's possible that the two nodes we find aren't in the same path. We can check if the two nodes are a part of the same path by doing a lowest common ancestor (LCA) query. If the LCA of the two nodes is one of the two nodes, then they belong to the same path. Fortunately, it is possible to answer LCA queries in O(1) time after O(n) preprocessing. Alternatively, we can maintain a hash map of parents to the current node. Then, if we find a matching node, we can check to see if it is a parent of the current node. If so, then they belong to the same path. – John Kurlak Jun 17 '15 at 5:43
• @Somebody I posted an answer with a coded solution. My answer addresses the issues I mention above. – John Kurlak Jun 17 '15 at 15:49
• @Somebody: The easier remedy than the ones I described above is to remove nodes from the hash table as you finish visiting them (on the way back up from the recursion). – John Kurlak Nov 4 '16 at 2:42

A clean solution in JAVA. Using internal recursive calls keeping track of the traversed paths.

``````private static void pathSunInternal(TreeNode root, int sum, List<List<Integer>> result, List<Integer> path){
if(root == null)
return;
if(sum == root.val && root.left == null && root.right == null){
}

else if(sum != root.val && root.left == null && root.right == null)
return;
else{
List<Integer> leftPath = new ArrayList<>(path);
List<Integer> rightPath = new ArrayList<>(path);
pathSunInternal(root.left, sum - root.val, result, leftPath);
pathSunInternal(root.right, sum - root.val, result, rightPath);
}
}

public static List<List<Integer>> pathSum(TreeNode root, int sum) {
List<List<Integer>> result = new ArrayList<>();
List<Integer> path = new ArrayList<>();
pathSunInternal(root, sum, result, path);
return result;
}
``````

Update: I see now that my answer does not directly answer your question. I will leave it here if it proves useful, but it needs no upvotes. If not useful, I'll remove it. I do agree with @nhahtdh, however, when he advises, "Reuse your algorithm with all other nodes as root."

One suspects that the interviewer is fishing for recursion here. Don't disappoint him!

Given a node, your routine should call itself against each of its child nodes, if it has any, and then add the node's own datum to the return values, then return the sum.

For extra credit, warn the interviewer that your routine can fail, entering an bottomless, endless recursion, if used on a general graph rather than a binary tree.

• This is brute-force, but also asymptotically optimal. In the worst case, all values are zero, the requested sum is zero, and all partial paths through the tree must be enumerated, so brute-force is the best you can do. Structure sharing can be exploited to improve the space complexity, though. – Fred Foo Jul 4 '12 at 12:04

One can reduce this tree to a weighted graph G, where each edge weight = sum of values in each of its nodes.

Then, run Floyd-Warshall algorithm on the graph G. By inspecting elements in the resulting matrix, we can get all pairs of nodes between which the total sum is equal to the desired sum.

Also, note that the shortest path the algorithm gives is also the only path between 2 nodes in this tree.

This is just another approach, not as efficient as a recursive approach.

• You should NEVER use Floyd-Warshall algorithm on a sparse graph. – Thomash Jul 5 '12 at 10:43
• @Thomash I understand this is not the most efficient, and I expressed that in the last sentence. I just wanted to show a possible reduction. With this reduction, one could always use the Johnsons-algorithm for spare graphs. But, again may be I am going down the rabbit-hole of complicating things. – grdvnl Jul 5 '12 at 13:51

We can solve it with tree-structure dynamic programming, and both the time and space complexity is O(n^2), where n is the number of all the tree nodes.

The idea is as follows:

For a tree node, we keep a set recording all possible sums starting from u to its all descendants. Then recursively, any node's set can be updated by its two children, specifically, by merging two children's sets.

The pseudocode is:

``````bool findPath(Node u, Set uset, int finalSum) {
Set lset, rset;
if (findPath(u.left, lset, finalSum) || findPath(u.right, rset, finalSum)) return true;
for (int s1 : lset) {
if (finalSum - u.val - s1 == 0 || rset.contains(finalSum - u.val - s1)) return true;
// first condition means a path from u to some descendant in u's left child
// second condition means a path from some node in u's left child to some node in u's right child

uset.insert(s1 + u.val); // update u's set
}
for (int s2 : rset) {
if (finalSum - u.val - s2 == 0) return true;
// don't forget the path from u to some descendant in u's right child
uset.insert(s2 + u.val); // update u's set
}
return false;
}
``````

I notice the original question is to find all paths, but the algorithm above is to find whether existed. I think the idea is similar, but this version makes the problem easier to explain :)

``````public void printPath(N n) {
printPath(n,n.parent);
}

private void printPath(N n, N endN) {
if (n == null)
return;
if (n.left == null && n.right == null) {
do {
System.out.print(n.value);
System.out.print(" ");
} while ((n = n.parent)!=endN);
System.out.println("");
return;
}
printPath(n.left, endN);
printPath(n.right, endN);
}
``````

You can print tree path end the n node. like this printPath(n);

``````void printpath(int sum,int arr[],int level,struct node * root)
{
int tmp=sum,i;
if(root == NULL)
return;
arr[level]=root->data;
for(i=level;i>=0;i--)
tmp-=arr[i];
if(tmp == 0)
print(arr,level,i+1);
printpath(sum,arr,level+1,root->left);
printpath(sum,arr,level+1,root->right);
}
void print(int arr[],int end,int start)
{

int i;
for(i=start;i<=end;i++)
printf("%d ",arr[i]);
printf("\n");
}
``````

complexity(n logn) Space complexity(n)

• Can you explain how time-complexity is O(nlogn) ? – JavaDeveloper Dec 26 '14 at 3:18
• It wont print all paths... consider below tree(in-oreder) and search for 7 sum... it will return only one path: 1 2 3 4 5 10 11 6 7 8 9 12 13 14 15 – Madhu S. Kapoor Jan 2 '15 at 0:20
``````# include<stdio.h>
# include <stdlib.h>
struct Node
{
int data;
struct Node *left, *right;
};

struct Node * newNode(int item)
{
struct Node *temp =  (struct Node *)malloc(sizeof(struct Node));
temp->data = item;
temp->left =  NULL;
temp->right = NULL;
return temp;
}
void print(int p[], int level, int t){
int i;
for(i=t;i<=level;i++){
printf("\n%d",p[i]);
}
}
void check_paths_with_given_sum(struct Node * root, int da, int path[100], int level){

if(root == NULL)
return ;
path[level]=root->data;
int i;int temp=0;
for(i=level;i>=0;i--){
temp=temp+path[i];
if(temp==da){
print(path,level,i);
}
}
check_paths_with_given_sum(root->left, da, path,level+1);
check_paths_with_given_sum(root->right, da, path,level+1);

}
int main(){
int par[100];
struct Node *root = newNode(10);
root->left = newNode(2);
root->right = newNode(4);
root->left->left = newNode(1);
root->right->right = newNode(5);
check_paths_with_given_sum(root, 9, par,0);

}
``````

This works.....

I have attempted an answer, expecting code review. My code as well as the reviewers should be helpful source.

Below is the solution using recurssion. We perform a in order traversal of the binary tree, as we move down a level we sum up the total path weight by adding the weight of the current level to the weights of previous levels of the tree, if we hit our sum we then print out the path. This solution will handle cases where we may have more than 1 solution along any given path path.

Assume you have a binary tree rooted at root.

``````#include <iostream>
#include <vector>
using namespace std;

class Node
{
private:
Node* left;
Node* right;
int value;

public:
Node(const int value)
{
left=NULL;
right=NULL;
this->value=value;
}

void setLeft(Node* left)
{
this->left=left;
}

void setRight(Node* right)
{
this->right = right;
}

Node* getLeft() const
{
return left;
}

Node* getRight() const
{
return right;
}

const int& getValue() const
{
return value;
}
};

//get maximum height of the tree so we know how much space to allocate for our
//path vector

int getMaxHeight(Node* root)
{
if (root == NULL)
return 0;

int leftHeight = getMaxHeight(root->getLeft());
int rightHeight = getMaxHeight(root->getRight());

return max(leftHeight, rightHeight) + 1;
}

//found our target sum, output the path
void printPaths(vector<int>& paths, int start, int end)
{
for(int i = start; i<=end; i++)
cerr<<paths[i]<< " ";

cerr<<endl;
}

void generatePaths(Node* root, vector<int>& paths, int depth, const int sum)
{
//base case, empty tree, no path
if( root == NULL)
return;

paths[depth] = root->getValue();
int total =0;

//sum up the weights of the nodes in the path traversed
//so far, if we hit our target, output the path
for(int i = depth; i>=0; i--)
{
total += paths[i];
if(total == sum)
printPaths(paths, i, depth);
}

//go down 1 level where we will then sum up from that level
//back up the tree to see if any sub path hits our target sum
generatePaths(root->getLeft(), paths, depth+1, sum);
generatePaths(root->getRight(), paths, depth+1, sum);
}

int main(void)
{
vector<int> paths (getMaxHeight(&root));
generatePaths(&root, paths, 0,0);
}
``````

space complexity depends on the the height of the tree, assumming this is a balanced tree then space complexity is 0(log n) based on the depth of the recurssion stack. Time complexity O(n Log n) - based on a balanced tree where there are n nodes at each level and at each level n amount of work will be done(summing the paths). We also know the tree height is bounded by O(log n) for a balanced binary tree, so n amount of work done for each level on a balanced binary tree gives a run time of O( n log n)

``````// assumption node have integer value other than zero
void printAllPaths(Node root, int sum , ArrayList<Integer> path) {

if(sum == 0) {
print(path); // simply print the arraylist
}

if(root ==null) {
//traversed one end of the tree...just return
return;
}
int data = root.data;
//this node can be at the start, end or in middle of path only if it is       //less than the sum
if(data<=sum) {
//go left and right
printAllPaths(root.left, sum-data ,  path);
printAllPaths(root.right, sum-data ,  path);

}
//note it is not else condition to ensure root can start from anywhere
printAllPaths(root.left, sum ,  path);
printAllPaths(root.right, sum ,  path);
}
``````

I have improved some coding logic of answer by Arvind Upadhyay. Once the if loop done, you can not use the same list. So need to create the new list. Also, there is need to maintain count of level the logic go down for from current node to search path. If we do not find path, so before going to its children, we need to come out from the recursive call equal to count times.

``````int count =0;
public void printAllPathWithSum(Node node, int sum, ArrayList<Integer> list)
{
if(node == null)
return;
if(node.data<=sum)
{
if(node.data == sum)
print(list);
else
{
count ++;
printAllPathWithSum(node.left, sum-node.data, list);
printAllPathWithSum(node.right, sum-node.data, list);
count --;
}
}
if(count != 0)
return ;

printAllPathWithSum(node.left, this.sum, new ArrayList());
if(count != 0)
return;
printAllPathWithSum(node.right, this.sum, new ArrayList());

}
public void print(List list)
{
System.out.println("Next path");
for(int i=0; i<list.size(); i++)
System.out.print(Integer.toString((Integer)list.get(i)) + " ");
System.out.println();
}
``````

Check the full code at: https://github.com/ganeshzilpe/java/blob/master/Tree/BinarySearchTree.java

Search:

``````Recursively traverse the tree, comparing with the input key, as in binary search tree.

If the key is found, move the target node (where the key was found) to the root position using splaysteps.

Pseudocode:

Algorithm: search (key)
Input: a search-key
1.   found = false;
2.   node = recursiveSearch (root, key)
3.   if found
4.     Move node to root-position using splaysteps;
5.     return value
6.   else
7.     return null
8.   endif
Output: value corresponding to key, if found.

Algorithm: recursiveSearch (node, key)
Input: tree node, search-key
1.   if key = node.key
2.     found = true
3.     return node
4.   endif
// Otherwise, traverse further
5.   if key < node.key
6.     if node.left is null
7.       return node
8.     else
9.       return recursiveSearch (node.left, key)
10.    endif
11.  else
12.    if node.right is null
13.      return node
14.    else
15.      return recursiveSearch (node.right, key)
16.    endif
17.  endif
Output: pointer to node where found; if not found, pointer to node for insertion.
``````

Since we need the paths having sum == k . I assume worst case complexity can be O(total_paths_in_tree) .

So why not generate every path and check for the sum , anyways it is a tree having negative numbers and is not even a binary search tree .

``````    struct node{
int val;
node *left,*right;

node(int vl)
{
val = vl;
left = NULL;
right = NULL;
}
};

vector<vector<int> > all_paths;
vector<vector<int> > gen_paths(node* root)
{
if(root==NULL)
{
return vector<vector<int> > ();
}

vector<vector<int> >    left_paths = gen_paths(root->left);
vector<vector<int> >    right_paths = gen_paths(root->right);

left_paths.push_back(vector<int> ()); //empty path
right_paths.push_back(vector<int> ());

vector<vector<int> > paths_here;
paths_here.clear();

for(int i=0;i<left_paths.size();i++)
{
for(int j=0;j<right_paths.size();j++)
{
vector<int> vec;
vec.clear();
vec.insert(vec.end(), left_paths[i].begin(), left_paths[i].end());
vec.push_back(root->val);
vec.insert(vec.end(), right_paths[j].begin(), right_paths[j].end());
paths_here.push_back(vec);
}
}

all_paths.insert(all_paths.end(),paths_here.begin(),paths_here.end());

vector<vector<int> > paths_to_extend;
paths_to_extend.clear();

for(int i=0;i<left_paths.size();i++)
{
paths_to_extend.push_back(left_paths[i]);
paths_to_extend[i].push_back(root->val);
}

for(int i=0;i<right_paths.size();i++)
{
paths_to_extend.push_back(right_paths[i]);
paths_to_extend[paths_to_extend.size()-1].push_back(root->val);
}

return paths_to_extend;
}
``````

For generating paths I have generated all left paths and all right paths And added the left_paths + node->val + right_paths to all_paths at each node. And have sent the paths which can still be extended .i.e all paths from both sides + node .