First try, use the following pattern (I'm assuming that `MU Terran Terran`

and other self-relations are allowed.):

```
foo (MU Terran Terran) = ...
foo (MU Terran Zerg) = ...
foo (MU Terran Protoss) = ...
foo (MU Zerg Zerg) = ...
foo (MU Zerg Protoss) = ...
foo (MU Protoss Protoss) = ...
foo (MU x y) = foo (MU y x)
```

You have to be very careful with functions defined like that, because if you don't get the cases to be exhaustive it's an infinite loop.

Second try: I had a shot at generalizing the pattern, and the best I came up with is this, which is barely any better:

```
forceSymmetric :: (MU -> Maybe r) -> MU -> r
forceSymmetric f = \p -> case f p of
Nothing -> fromJust (f (swap p))
Just r -> r
foo (MU Terran Terran) = Just ...
foo (MU Terran Zerg) = Just ...
foo (MU Terran Protoss) = Just ...
foo (MU Zerg Zerg) = Just ...
foo (MU Zerg Protoss) = Just ...
foo (MU Protoss Protoss) = Just ...
foo (MU x y) = Nothing
```

This has the virtue that you'd gen an error instead of an infinite loop if you mess up.

Third, deeper try: the heart of the problem is that you want **symmetry**. Let's forget that `MU`

is a constructor, and just treat it as a function. You want it to obey this symmetry law:

```
MU a b == MU b a
```

By `==`

I don't necessarily mean the `Eq`

type class here, but rather **mutual substitutibility**; substituting one expression for the other should not affect the meaning of any program.

Well, algebraic data types don't have that property, period. For an algebraic data type constructor like `MU`

, `MU a b == MU c d`

if and only if `a == b`

and `c == d`

. So if you want to make it impossible for any function to distinguish between `MU Terran Zerg`

and `MU Zerg Terran`

, you need to make the `MU`

type abstract, so that its users cannot see its internal representation.

The formula for number of combinations of *n* items taken *r* at a time, with duplicates allowed, is `factorial (n + r - 1) / (factorial r * factorial (n - 1))`

; for `n = 3`

and `r = 2`

, this is 6 combinations. So what we want is to define a type `MU`

that has only six possible values, a function `toMU :: Race -> Race -> MU`

such that `mu a b == mu b a`

, and a function `fromMU :: MU -> (Race, Race)`

such that `uncurry toMU . fromMU == id`

. The easiest way I can think of doing this is to use sorted tuples:

```
data Race = Terran | Zerg | Protoss deriving (Eq, Show, Read, Ord);
data SortedPair a = SP a a -- The constructor here needs to be private
makeSortedPair :: Ord a => a -> a -> SortedPair a
makeSortedPair a b | a < b = SP a b
| otherwise = SP b a
breakSortedPair :: SortedPair a a -> (a, a)
breakSortedPair (SP a b) = (a, b)
type MU = SortedPair Race
toMU :: Race -> Race -> MU
toMU = makeSortedPair
fromMU :: MU -> (Race, Race)
fromMU = breakSortedPair
```

Now you're guaranteed that `fromMU`

can produce `(Terran, Zerg)`

but not `(Zerg, Terran)`

, so you can leave out the final "catch-all" cases from the first two proposals above. (The compiler doesn't know anything about this, however, so it will still complain about non-exhaustive patterns.)

`TvZ`

over`(MU Terran Zerg)`

? – Emrakul Apr 15 '13 at 3:58