You could try a heuristical approach using existing AI tools for optimizations, such as **Genetic Algorithms** or **Hill Climbing**.

I'll give more details on hill climbing, since it is my favorite.

**Represent your problem as states graph** `G = (V,E)`

such that `V = {all possible states }`

and `E = {(u,v) | swapping one player you can move from u to v }`

.

Also, let `u:V->R`

be a utility function for a formation.

Since we do not want to generate the graph, let `next:V->2^V`

be a function such that `next(v) = {all possible formation that you can get by changing one player }`

The idea of hill climbing is to **start from a random formation, and greedily make the best change possible**, when you are stuck - restart the algorithm from a new random formation.

```
1. best<- -INFINITY
2. while there is more time
3. choose a random matching
4. NEXT <- next(s)
5. if max{ u(v) | for each v in NEXT} < u(s): //s is a local maximum
5.1. if u(s) > best: best <- u(s) //if s is better then the previous result - store it.
5.2. go to 2. //restart the hill climbing from a different random point.
6. else:
6.1. s <- max { NEXT }
6.2. goto 4.
7. return best //when out of time, return the best solution found so far.
```

Note that this variation of hill climbing (hill climbing with random restarts) is an **any time algorithm** - meaning it will become better when more time is given, and when infinite time is given - it founds the global maximum.

everydifferent combination. – Zairja May 29 '12 at 19:09