# Finding three elements in an array whose sum is closest to a given number

Given an array of integers, A1, A2, ..., An, including negatives and positives, and another integer S. Now we need to find three different integers in the array, whose sum is closest to the given integer S. If there exists more than one solution, any of them is ok.

You can assume all the integers are within int32_t range, and no arithmetic overflow will occur with calculating the sum. S is nothing special but a randomly picked number.

Is there any efficient algorithm other than brute force search to find the three integers?

• If you're looking for a sum equal to a number (and not closest), this would be the 3SUM problem. Nov 5 '17 at 17:10

Is there any efficient algorithm other than brute force search to find the three integers?

Yep; we can solve this in O(n2) time! First, consider that your problem `P` can be phrased equivalently in a slightly different way that eliminates the need for a "target value":

original problem `P`: Given an array `A` of `n` integers and a target value `S`, does there exist a 3-tuple from `A` that sums to `S`?

modified problem `P'`: Given an array `A` of `n` integers, does there exist a 3-tuple from `A` that sums to zero?

Notice that you can go from this version of the problem `P'` from `P` by subtracting your S/3 from each element in `A`, but now you don't need the target value anymore.

Clearly, if we simply test all possible 3-tuples, we'd solve the problem in O(n3) -- that's the brute-force baseline. Is it possible to do better? What if we pick the tuples in a somewhat smarter way?

First, we invest some time to sort the array, which costs us an initial penalty of O(n log n). Now we execute this algorithm:

``````for (i in 1..n-2) {
j = i+1  // Start right after i.
k = n    // Start at the end of the array.

while (k >= j) {
// We got a match! All done.
if (A[i] + A[j] + A[k] == 0) return (A[i], A[j], A[k])

// We didn't match. Let's try to get a little closer:
//   If the sum was too big, decrement k.
//   If the sum was too small, increment j.
(A[i] + A[j] + A[k] > 0) ? k-- : j++
}
// When the while-loop finishes, j and k have passed each other and there's
// no more useful combinations that we can try with this i.
}
``````

This algorithm works by placing three pointers, `i`, `j`, and `k` at various points in the array. `i` starts off at the beginning and slowly works its way to the end. `k` points to the very last element. `j` points to where `i` has started at. We iteratively try to sum the elements at their respective indices, and each time one of the following happens:

• The sum is exactly right! We've found the answer.
• The sum was too small. Move `j` closer to the end to select the next biggest number.
• The sum was too big. Move `k` closer to the beginning to select the next smallest number.

For each `i`, the pointers of `j` and `k` will gradually get closer to each other. Eventually they will pass each other, and at that point we don't need to try anything else for that `i`, since we'd be summing the same elements, just in a different order. After that point, we try the next `i` and repeat.

Eventually, we'll either exhaust the useful possibilities, or we'll find the solution. You can see that this is O(n2) since we execute the outer loop O(n) times and we execute the inner loop O(n) times. It's possible to do this sub-quadratically if you get really fancy, by representing each integer as a bit vector and performing a fast Fourier transform, but that's beyond the scope of this answer.

Note: Because this is an interview question, I've cheated a little bit here: this algorithm allows the selection of the same element multiple times. That is, (-1, -1, 2) would be a valid solution, as would (0, 0, 0). It also finds only the exact answers, not the closest answer, as the title mentions. As an exercise to the reader, I'll let you figure out how to make it work with distinct elements only (but it's a very simple change) and exact answers (which is also a simple change).

• It seems the algorithm can only find 3-tuple that equals to S, not closest to S. Jan 15 '10 at 10:37
• ZelluX: As I mentioned in the note, I didn't want to give too much away since it's an interview problem. Hopefully you can see how to modify it so that it gets you the closest answer, though. (Hint: one way is to keep track of the closest answer so far and overwrite it if you find a better one.) Jan 15 '10 at 10:40
• what if we don't modify the problem statement, instead we will search for aj and ak that sum to ai +S. May 20 '11 at 14:59
• @ZelluX: It's similar to how a merge sort works (that's how it first clicked for me). What that inner loop is trying to do is prove that either A[j] or A[k] cannot be part of any satisfying solution. The problem at any point is: "Is there any pair j' >= j and k' <= k such that A[j] + A[k] = S - A[i]?" Looking at the current pair (i, j), there are 3 possibilities: the sum is bang on (stop -- we've won!), it's too low, or it's too high. If it's too low, then the sum A[j] + A[k'] must also be too low for every k' <= k, since in each such sum the first term (A[j]) will be the same... Oct 3 '12 at 18:30
• ... and the second term (A[k']) will be the same or even lower than A[k]. So in this case we have proven that A[j] cannot participate in any satisfying sum -- so we may as well discard it! Which we do by setting j = j+1 and starting over (though it may help to think in terms of solving a smaller subproblem recursively instead). Likewise if the sum A[j] + A[k] is too high, then we know that A[j'] + A[k] must also be too high for every j' >= j, since A[j'] must be at least as big as A[j] and we're already too high. This means we can safely discard A[k] by setting k = k-1 and starting over. Oct 3 '12 at 18:36

certainly this is a better solution because it's easier to read and therefore less prone to errors. The only problem is, we need to add a few lines of code to avoid multiple selection of one element.

Another O(n^2) solution (by using a hashset).

``````// K is the sum that we are looking for
for i 1..n
int s1 = K - A[i]
for j 1..i
int s2 = s1 - A[j]
if (set.contains(s2))
print the numbers
``````
• Downside is O(N) storage, rather than doing it in-place. Nov 16 '12 at 21:10
• Using a hashset isn't strict O(n^2) since the hash set can degenerate in rare occasions, resulting in up to linear lookup times. Jul 24 '14 at 17:24
• @Charles - Also the solution of John needs O(N) space, since you change the original array while sorting. That means the caller might need a defensive copy before using the function. Feb 22 '16 at 13:57
• I think there's an error in your algorithm. `s2` might be an already selected element. E.g. if the array is `0,1,2` and `K` is `2`, there shouldn't be an answer. I think your algorithm will output `0,1,1` which is obviously incorrect. Jan 20 '18 at 6:24

John Feminella's solution has a bug.

At the line

``````if (A[i] + A[j] + A[k] == 0) return (A[i], A[j], A[k])
``````

We need to check if i,j,k are all distinct. Otherwise, if my target element is `6` and if my input array contains `{3,2,1,7,9,0,-4,6}` . If i print out the tuples that sum to 6, then I would also get `0,0,6` as output . To avoid this, we need to modify the condition in this way.

``````if ((A[i] + A[j] + A[k] == 0) && (i!=j) && (i!=k) && (j!=k)) return (A[i], A[j], A[k])
``````
• John Feminella solution is just to present algorithm to solve problem, he has also specified that his solution wouldn't work for distinct number condition and you have to modify above code little bit which he has left for reader. Dec 17 '13 at 12:22
• Actually, i will never be j since you are always starting it at j = i + 1. The only real condition that you should check is whether j == k. However, by setting the while loop to j < k, you've solved the problems without a lengthy if statement since k will always be greater than j and j always greater than i. Jul 4 '16 at 21:21
• This does not seem like an answer to the question, but rather like a comment on John Feminella's answer. Nov 5 '17 at 17:56

How about something like this, which is O(n^2)

``````for(each ele in the sorted array)
{
ele = arr[i] - YOUR_NUMBER;
let front be the pointer to the front of the array;
let rear be the pointer to the rear element of the array.;

// till front is not greater than rear.
while(front <= rear)
{
if(*front + *rear == ele)
{
print "Found triplet "<<*front<<","<<*rear<<","<<ele<<endl;
break;
}
else
{
// sum is > ele, so we need to decrease the sum by decrementing rear pointer.
if((*front + *rear) > ele)
decrement rear pointer.
// sum is < ele, so we need to increase the sum by incrementing the front pointer.
else
increment front pointer.
}
}
``````

This finds if sum of 3 elements is exactly equal to your number. If you want closest, you can modify it to remember the smallest delta(difference between your number of current triplet) and at the end print the triplet corresponding to smallest delta.

• if you want to find k elements to get the sum what is the complexity? How you deal with this? Feb 18 '12 at 6:30
• With this approach, complexity for k elements is O(n^(k-1)) for k >= 2. You need to add an outer loop for every additional summand. Jul 24 '14 at 17:40

Note that we have a sorted array. This solution is similar to John's solution only that it looks for the sum and does not repeat the same element.

``````#include <stdio.h>;

int checkForSum (int arr[], int len, int sum) { //arr is sorted
int i;
for (i = 0; i < len ; i++) {
int left = i + 1;
int right = len - 1;
while (right > left) {
printf ("values are %d %d %d\n", arr[i], arr[left], arr[right]);
if (arr[right] + arr[left] + arr[i] - sum == 0) {
printf ("final values are %d %d %d\n", arr[i], arr[left], arr[right]);
return 1;
}
if (arr[right] + arr[left] + arr[i] - sum > 0)
right--;
else
left++;
}
}
return -1;
}
int main (int argc, char **argv) {
int arr[] = {-99, -45, -6, -5, 0, 9, 12, 16, 21, 29};
int sum = 4;
printf ("check for sum %d in arr is %d\n", sum, checkForSum(arr, 10, sum));
}
``````
• It is needed to calculate absolute difference of `a[r] + a[l] + a[i] - sum`. Try on `arr = [-1, 2, 1, -4] sum = 1`. Nov 21 '18 at 19:26

Here is the C++ code:

``````bool FindSumZero(int a[], int n, int& x, int& y, int& z)
{
if (n < 3)
return false;

sort(a, a+n);

for (int i = 0; i < n-2; ++i)
{
int j = i+1;
int k = n-1;

while (k >= j)
{
int s = a[i]+a[j]+a[k];

if (s == 0 && i != j && j != k && k != i)
{
x = a[i], y = a[j], z = a[k];
return true;
}

if (s > 0)
--k;
else
++j;
}
}

return false;
}
``````

Very simple N^2*logN solution: sort the input array, then go through all pairs Ai, Aj (N^2 time), and for each pair check whether (S - Ai - Aj) is in array (logN time).

Another O(S*N) solution uses classical dynamic programming approach.

In short:

Create an 2-d array V[S + 1]. Fill it in such a way, that:

V = 1, V[x] = 0;

V1[Ai]= 1 for any i, V1[x] = 0 for all other x

V[Ai + Aj]= 1, for any i, j. V[x] = 0 for all other x

V[sum of any 3 elements] = 1.

To fill it, iterate through Ai, for each Ai iterate through the array from right to left.

• slight change to the first algorithm.. if the element doesn't exist, then at the end of the binary search, we'd have to look at the element on the left, current, and right to see which one gives the closest result. Jan 15 '10 at 9:25
• The array is too big and it is not O(s*N) . This step is O(N^2 ) : V[Ai + Aj]= 1, for any i, j. V[x] = 0 for all other x . May 31 '16 at 6:16

This can be solved efficiently in O(n log (n)) as following. I am giving solution which tells if sum of any three numbers equal a given number.

``````import java.util.*;
public class MainClass {
public static void main(String[] args) {
int[] a = {-1, 0, 1, 2, 3, 5, -4, 6};
System.out.println(((Object) isThreeSumEqualsTarget(a, 11)).toString());
}

public static boolean isThreeSumEqualsTarget(int[] array, int targetNumber) {

//O(n log (n))
Arrays.sort(array);
System.out.println(Arrays.toString(array));

int leftIndex = 0;
int rightIndex = array.length - 1;

//O(n)
while (leftIndex + 1 < rightIndex - 1) {
//take sum of two corners
int sum = array[leftIndex] + array[rightIndex];
//find if the number matches exactly. Or get the closest match.
//here i am not storing closest matches. You can do it for yourself.
//O(log (n)) complexity
int binarySearchClosestIndex = binarySearch(leftIndex + 1, rightIndex - 1, targetNumber - sum, array);
if (-1 == binarySearchClosestIndex) {
System.out.println(("combo is " + array[leftIndex] + ", " + array[rightIndex] + ", " + (targetNumber - sum)));
return true;
}
//if exact match is not found, we have to decide which pointer, left or right to move inwards
//we are here means , either we are on left end or on right end
else {

//we ended up searching towards start of array,i.e. we need a lesser sum , lets move inwards from right
//we need to have a lower sum, lets decrease right index
if (binarySearchClosestIndex == leftIndex + 1) {
rightIndex--;
} else if (binarySearchClosestIndex == rightIndex - 1) {
//we need to have a higher sum, lets decrease right index
leftIndex++;
}
}
}
return false;
}

public static int binarySearch(int start, int end, int elem, int[] array) {
int mid = 0;
while (start <= end) {
mid = (start + end) >>> 1;
if (elem < array[mid]) {
end = mid - 1;
} else if (elem > array[mid]) {
start = mid + 1;
} else {
//exact match case
//Suits more for this particular case to return -1
return -1;
}
}
return mid;
}
}
``````
• I don't think this is going to work. Granted, you have two simple cases of how to advance `leftIndex` or `rightIndex` when all the elements in the middle are either strictly smaller or larger than your desired number. But what about the case when binary search stopped somewhere in the middle? You would need to check both branches (where `rightIndex--` and `leftIndex++`). In your solution you just ignore this situation. But I don't think that there is a way to overcome this issue. May 20 '17 at 5:52

Reduction : I think @John Feminella solution O(n2) is most elegant. We can still reduce the A[n] in which to search for tuple. By observing A[k] such that all elements would be in A - A[k], when our search array is huge and SUM (s) really small.

A is minimum :- Ascending sorted array.

s = 2A + A[k] : Given s and A[] we can find A[k] using binary search in log(n) time.

Here is the program in java which is O(N^2)

``````import java.util.Stack;

public class GetTripletPair {

/** Set a value for target sum */
public static final int TARGET_SUM = 32;

private Stack<Integer> stack = new Stack<Integer>();

/** Store the sum of current elements stored in stack */
private int sumInStack = 0;
private int count =0 ;

public void populateSubset(int[] data, int fromIndex, int endIndex) {

/*
* Check if sum of elements stored in Stack is equal to the expected
* target sum.
*
* If so, call print method to print the candidate satisfied result.
*/
if (sumInStack == TARGET_SUM) {
print(stack);
}

for (int currentIndex = fromIndex; currentIndex < endIndex; currentIndex++) {

if (sumInStack + data[currentIndex] <= TARGET_SUM) {
++count;
stack.push(data[currentIndex]);
sumInStack += data[currentIndex];

/*
* Make the currentIndex +1, and then use recursion to proceed
* further.
*/
populateSubset(data, currentIndex + 1, endIndex);
--count;
sumInStack -= (Integer) stack.pop();
}else{
return;
}
}
}

/**
* Print satisfied result. i.e. 15 = 4+6+5
*/

private void print(Stack<Integer> stack) {
StringBuilder sb = new StringBuilder();
sb.append(TARGET_SUM).append(" = ");
for (Integer i : stack) {
sb.append(i).append("+");
}
System.out.println(sb.deleteCharAt(sb.length() - 1).toString());
}

private static final int[] DATA = {4,13,14,15,17};

public static void main(String[] args) {
GetAllSubsetByStack get = new GetAllSubsetByStack();
get.populateSubset(DATA, 0, DATA.length);
}
}
``````
• Nice approach, but I could not get the point where you restrict the number of results to a triplet. For example consider the input: [1,11,3,4,5,6,7,8, 2] and sum 12, from your solution it appears that [1, 11] [4,8] [1,4,5,2] etc would all work. Dec 19 '18 at 1:31

The problem can be solved in O(n^2) by extending the 2-sum problem with minor modifications.A is the vector containing elements and B is the required sum.

int Solution::threeSumClosest(vector &A, int B) {

``````sort(A.begin(),A.end());

int k=0,i,j,closest,val;int diff=INT_MAX;

while(k<A.size()-2)
{
i=k+1;
j=A.size()-1;

while(i<j)
{
val=A[i]+A[j]+A[k];
if(val==B) return B;
if(abs(B-val)<diff)
{
diff=abs(B-val);
closest=val;
}
if(B>val)
++i;
if(B<val)
--j;
}
++k;

}
return closest;
``````

Here is the Python3 code

``````class Solution:
def threeSumClosest(self, nums: List[int], target: int) -> int:
result = set()
nums.sort()
L = len(nums)
for i in range(L):
if i > 0 and nums[i] == nums[i-1]:
continue
for j in range(i+1,L):
if j > i + 1 and nums[j] == nums[j-1]:
continue
l = j+1
r = L -1
while l <= r:
sum = nums[i] + nums[j] + nums[l]
l = l + 1
while l<=r and nums[l] == nums[l-1]:
l = l + 1
result = list(result)
min = result
for i in range(1,len(result)):
if abs(target - result[i]) < abs(target - min):
min = result[i]
return min
``````

Another solution that checks and fails early:

``````public boolean solution(int[] input) {
int length = input.length;

if (length < 3) {
return false;
}

// x + y + z = 0  => -z = x + y
final Set<Integer> z = new HashSet<>(length);
int zeroCounter = 0, sum; // if they're more than 3 zeros we're done

for (int element : input) {
if (element < 0) {
}

if (element == 0) {
++zeroCounter;
if (zeroCounter >= 3) {
return true;
}
}
}

if (z.isEmpty() || z.size() == length || (z.size() + zeroCounter == length)) {
return false;
} else {
for (int x = 0; x < length; ++x) {
for (int y = x + 1; y < length; ++y) {
sum = input[x] + input[y]; // will use it as inverse addition
if (sum < 0) {
continue;
}
if (z.contains(sum * -1)) {
return true;
}
}
}
}
return false;
}
``````

I added some unit tests here: GivenArrayReturnTrueIfThreeElementsSumZeroTest.

If the set is using too much space I can easily use a java.util.BitSet that will use O(n/w) space.

Program to get those three elements. I have just sorted the array/list first and them updated `minCloseness` based upon each triplet.

``````public int[] threeSumClosest(ArrayList<Integer> A, int B) {
Collections.sort(A);
int ansSum = 0;
int ans[] = new int;
int minCloseness = Integer.MAX_VALUE;
for (int i = 0; i < A.size()-2; i++){
int j = i+1;
int k = A.size()-1;
while (j < k){
int sum = A.get(i) + A.get(j) + A.get(k);
if (sum < B){
j++;
}else{
k--;
}
if (minCloseness >  Math.abs(sum - B)){
minCloseness = Math.abs(sum - B);
ans = A.get(i); ans = A.get(j); ans = A.get(k);
}
}
}
return ans;
}
``````

I did this in n^3, my pseudocode is below;

//Create a hashMap with key as Integer and value as ArrayList //iterate through list using a for loop, for each value in list iterate again starting from next value;

``````for (int i=0; i<=arr.length-1 ; i++){
for (int j=i+1; j<=arr.length-1;j++){
``````

//if the sum of arr[i] and arr[j] is less than desired sum then there is potential to find a third digit so do another for loop

``````      if (arr[i]+arr[j] < sum){
for (int k= j+1; k<=arr.length-1;k++)
``````

//in this case we are now looking for the third value; if the sum of arr[i] and arr[j] and arr[k] is the desired sum then add these to the HashMap by making the arr[i] the key and then adding arr[j] and arr[k] into the ArrayList in the value of that key

``````          if (arr[i]+arr[j]+arr[k] ==  sum){
map.put(arr[i],new ArrayList<Integer>());