I'll explain how a person could work on this without knowing magic words (like "partition problem", "dynamic programming", etc.) with which to consult some big book of answers (like Wikipedia).

If you take one instance of the largest not-yet-used number from the input and assign it to one of your two groups, then you have reduced the problem to a smaller instance of (a generalized version of) the same problem.

The generalized problem is, can you divide the input numbers into two groups such that the difference between the two groups' sums is a particular non-negative integer?

Let's say our input numbers are 4, 3, 2, 1 and we need to make two groups so that the difference between the groups' sums is 0.

We assign 4 to one of the groups, and in this particular case it doesn't matter which group.

Now our remaining input numbers are 3, 2, 1 and, ignoring the 4 that we already dealt with, we need to make these three numbers into two groups so that the difference between the groups' sums is 4. (That will balance out the difference between the two groups that we created by assigning the 4 to one of the groups.) As promised, this is a smaller instance of the original type of problem.

The difficulty is that sometimes, such as with 5, 5, 4, 3, 3 (example found in Wikipedia "Partition problem"), it's not obvious which group the next number needs to go into. If you keep track of what you've done, then when you find out your latest attempt didn't work, you can come back ("backtrack") and try the other way.

```
5, 5, 4, 3, 3 {} {}
5, 4, 3, 3 {5} {}
4, 3, 3 {5} {5}
3, 3 {5, 4} {5}
3 {5, 4} {5, 3}
{5, 4} {5, 3, 3} NO - backtrack
{5, 4, 3} {5, 3} NO - backtrack
3 {5, 4, 3} {5}
{5, 4, 3} {5, 3} NO - already tried - backtrack
{5, 4, 3, 3} {3} NO - backtrack
3, 3 {5} {5, 4} NO - symmetric to what we already tried - backtrack
4, 3, 3 {5, 5} {}
3, 3 {5, 5} {4}
3 {5, 5} {4, 3}
{5, 5} {4, 3, 3} YES
```

Will we be able to get the answer quickly? Well, this isn't the question that was asked, but in light of the complexity of backtracking, it's natural to ask. And the answer turns out to be, no, not even if we have the smartest person in the history of the world working for us. No one has ever found a method that is guaranteed to perform quickly no matter what instance of this kind of problem we give it. Maybe we can do pretty well for many instances of these problems, but in general and on average, a program to do this sort of thing is destined to be slow.