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<>();
sums.add(opt);
// 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) {
newSums.add(newSum);
// update optimum
if (newSum > opt) {
opt = newSum;
}
}
}
sums.addAll(newSums);
}
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<>();
sums.add(opt);
```

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);
newSubList.add(input);
SubList newSum = new SubList(sum.size + input, newSubList);
// ignore too big sums
if (newSum.size <= K) {
newSums.add(newSum);
// update optimum
if (newSum.size > opt) {
opt = newSum;
}
}
}
sums.addAll(newSums);
}
```