### Targeting one statistic

This is pretty straightforward. First, a few assumptions:

You didn't mention this, but presumably one can only wear at most one kind of armor for a particular slot. That is, you can't wear two pairs of pants, or two shirts.

Presumably, also, the choice of one piece of gear does not affect or conflict with others (other than the constraint of not having more than one piece of clothing in the same slot). That is, if you wear pants, this in no way precludes you from wearing a shirt. But notice, more subtly, that we're assuming you don't get some sort of synergy effect from wearing two related items.

Suppose that you want to target statistic X. Then the algorithm is as follows:

- Group all the items by slot.
- Within each group, sort the potential items in that group by how much they boost X, in descending order.
- Pick the first item in each group and wear it.
- The set of items chosen is the optimal loadout.

Proof: The only way to get a higher X stat would be if there was an item `A`

which provided more X than some other in its group. But we already sorted all the items in each group in descending order, so there can be no such `A`

.

What happens if the assumptions are violated?

If assumption one isn't true -- that is, you *can* wear multiple items in each slot -- then instead of picking the first item from each group, pick the first *Q(s)* items from each group, where *Q(s)* is the number of items that can go in slot *s*.

If assumption two isn't true -- that is, items *do* affect each other -- then we don't have enough information to solve the problem. We'd need to know specifically how items can affect each other, or else be forced to try every possible combination of items through brute force and see which ones have the best overall results.

### Targeting N statistics

If you want to target multiple stats at once, you need a way to tell "how good" something is. This is called a *fitness function*. You'll need to decide how important the N statistics are, relative to each other. For example, you might decide that every +1 to Perception is worth 10 points, while every +1 to Intelligence is only worth 6 points. You now have a way to evaluate the "goodness" of items relative to each other.

Once you have that, instead of optimizing for X, you instead optimize for F, the fitness function. The process is then the same as the above for one statistic.