How do I find the closest possible sum of an Array's elements to a particular value?

In Java, how should I find the closest (or equal) possible sum of an Array's elements to a particular value K?

For example, for the array {19,23,41,5,40,36} and K=44, the closest possible sum is 23+19=42. I've been struggling on this for hours; I know almost nothing about dynamic programming. By the way, the array contains only positive numbers.

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This is a fair question, but probably more suited here: math.stackexchange.com – Magnilex Apr 15 '13 at 18:29
Wouldn't 5 + 40 be the closest possible sum? – splungebob Apr 15 '13 at 18:31
I meant that the sum would be under or equal to K – Karim El Sheikh Apr 15 '13 at 18:32
Is there a limit of numbers you can add up? For example, can you only use two elements per sum, or could you also use the sum over all elements? – G. Bach Apr 15 '13 at 18:38

You would typically use dynamic programming for such a problem. However, that essentially boils down to keeping a set of possible sums and adding the input values one by one, as in the following code, and has the same asymptotic running time: `O(n K)`, where `n` is the size of your input array and `K` is the target value.

The constants in the version below are probably bigger, however, but I think the code is much easier to follow, than the dynamic programming version would be.

``````public class Test {
public static void main(String[] args) {
int K = 44;
List<Integer> inputs = Arrays.asList(19,23,41,5,40,36);

int opt = 0;                // optimal solution so far

Set<Integer> sums = new HashSet<>();

// loop over all input values
for (Integer input : inputs) {
Set<Integer> newSums = new HashSet<>();

// loop over all sums so far
for (Integer sum : sums) {
int newSum = sum + input;

// ignore too big sums
if (newSum <= K) {

// update optimum
if (newSum > opt) {
opt = newSum;
}
}
}

}

System.out.println(opt);
}
}
``````

EDIT

A short note on running time might be useful, since I just claimed `O(n K)` without justification.

Clearly, initialization and printing the result just takes constant time, so we should analyse the double loop.

The outer loop runs over all inputs, so it's body is executed `n` times.

The inner loop runs over all sums so far, which could be an exponential number in theory. However, we use an upper bound of `K`, so all values in `sums` are in the range `[0, K]`. Since `sums` is a set, it contains at most `K+1` elements.

All computations inside the inner loop take constant time, so the total loop takes `O(K)`. The set `newSums` also contains at most `K+1` elements, for the same reason, so the `addAll` in the end takes `O(K)` as well.

Wrapping up: the outer loop is executed `n` times. The loop body takes `O(K)`. Therefore, the algorithm runs in `O(n K)`.

EDIT 2

Upon request on how to also find the elements that lead to the optimal sum:

Instead of keeping track of a single integer - the sum of the sublist - you should also keep track of the sublist itself. This is relatively straightforward if you create a new type (no getters/setters to keep the example concise):

``````public class SubList {
public int size;
public List<Integer> subList;

public SubList() {
this(0, new ArrayList<>());
}

public SubList(int size, List<Integer> subList) {
this.size = size;
this.subList = subList;
}
}
``````

The initialization now becomes:

``````SubList opt = new SubList();

Set<SubList> sums = new HashSet<>();
``````

The inner loop over the `sums` needs some small adaptations as well:

``````for (SubList sum : sums) {
Set<SubList> newSums = new HashSet<>();

// loop over all sums so far
for (SubList sum : sums) {
List<Integer> newSubList = new ArrayList<>(sum.subList);
SubList newSum = new SubList(sum.size + input, newSubList);

// ignore too big sums
if (newSum.size <= K) {

// update optimum
if (newSum.size > opt) {
opt = newSum;
}
}
}

}
``````
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I read your solution and try to understand, maybe my question is stupid, but I can see where you add a number in the final solution, what I don't see is where you exclude a number of the final solution. I would expect that, at some point, you should realise that a included number should be excluded to lead to a better solution, isn't it? – zafeiris.m Apr 15 '13 at 19:27
@zafeiris.m I only keep track of the sums, not of the values they are composed off. Basically, after iteration `i` of the outer loop (over `inputs`), the set `sums` contains all possible sums that can be made with the first `i` input values. To make sure that the size of that set doesn't grow exponentially, I added `upperBound`, which makes sure `sums` contains at most `2*K` values. – Vincent van der Weele Apr 15 '13 at 19:32
but what if the best solution does not include the first `i` elements, but, say, the 1st, the 4th, and the 6th? – zafeiris.m Apr 15 '13 at 19:41
@Heuster Thank you, I can see it now, nice solution! But what I don't understand is the worst case complexity. In the example of your comment (and in any example that most of the elements will be included in the result), I see the result set gets doubled everytime, resulting in exponential complexity, isn't it? Tell me if I'm wrong. Update: Also space complexity is exponential since you keep each sub-result, right? – zafeiris.m Apr 15 '13 at 21:04
@zafeiris.m I added a note on running time. The trick is in `upperBound`, which keeps the size of `sums` linear in `K`. – Vincent van der Weele Apr 16 '13 at 6:05

You can see it as a `n-choose-k` problem for all possible `k` so the complexity is exponential.

1. Find a set of numbers that sum at most up to `K`. The set should include `i` numbers, for `i=1; i<=N; i++`. To implement this, for each `i` just take all the `n-choose-i` combinations of the numbers in the array.
2. Keep a `finalResult` variable with the best set of numbers found so far and their sum.
3. Compare each sub-result of step 1 with the `finalResult` and update it if necessary.

It reminds me of the Knapsack problem, so you may want to take a look at it.

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I would say first sort the array. Then your example would be: arr = {5, 19, 23, 36, 40, 41}. Then: 1) Take arr[0] and arr[i], where i = arr.Size. Sum it and record the difference between the sum and K, if the sum is lower than K. 2) If sum > K, do step 1, but instead of arr[i], use arr[i-1], because we want to lower our sum. If sum < K, do step 1, but instead of arr[0], use arr[1], because we want to increase our sum. Keep repeating step2, by either increasing or decreasing the indices, until the indices for the two elements are equal. Then, we know the pair of elements that result in the smallest difference between the sum and K.

----------------Edited for arbitrary number of elements in the solution----------------

I believe you may need a tree. Here's what I'm thinking:

1) Choose a number as your top node.

2) For each number in the set, create a child node, and for each branch that was created, calculate the sum of that branch.

3) If the sum is less then K, we branch again, creating child nodes for all the elements in the set. If the sum is greater than K, we stop, keep the difference between the sum and K(If sum < K). If we find a branch with a better sum, then we keep that branch. Repeat this process until all branches are done branching.

Do steps 1-3 with different topnodes.

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If I understand you correctly, this will not solve his problem correctly; take for example [1, 2, 10] searching for 13. – G. Bach Apr 15 '13 at 18:41
@Calpis, but what about more than two numbers participating in the result? – zafeiris.m Apr 15 '13 at 18:42
O sorry, I didn't realize it was an arbitrary number for the solution..Let me rethink this – Calpis Apr 15 '13 at 18:43