If you want an ultra short, "ulta-Haskelly" version:

```
enumAll :: (Bounded a, Enum a) => [a]
enumAll = [minBound..maxBound]
positions :: [Pos]
positions = (,) <$> enumAll <*> enumAll
```

(You'll also need to import Control.Applicative for the `<$>`

and `<*>`

operators)

Then in ghci:

```
*Main> positions
[(A,X),(A,Y),(A,Z),(B,X),(B,Y),(B,Z),(C,X),(C,Y),(C,Z)]
```

How the hell does this work?

`enumAll`

is just a generic helper function (I was surprised not to be able to quickly find it in the standard libraries; it's possible I missed it and you don't even need to define it yourself). It gives you a list of every possibility for any bounded enumerable type. It's fairly straightforward; `Bounded`

means the type has `minBound`

and `maxBound`

, `Enum`

means you can use the `[a..b]`

syntax to get a list of everything from `a`

to `b`

.

`(,)`

is just the pair-building function. If you type `:t (,)`

into ghci, it tells you `(,) :: a -> b -> (a, b)`

.

Now, what about those weird `<$>`

and `<*>`

symbols? They're basically "special" forms of function application. So you can read it almost like we're simply applying `(,)`

to the two arguments `enumAll`

and `enumAll`

. But because it's "special" application, it doesn't just give us the pair `(enumAll, enumAll)`

.

What we're doing here is using the `Applicative`

instance for lists. I'm not going to get into that in full detail, but what this does is help us think that `[Row]`

is not a list of row values, but rather a single "unknown" row value. It's a value that *could* be any element of the list, but we don't know which one. The technical term usually used for this is that `[Row]`

can be thought of as a *nondeterministic* `Row`

; it's a `Row`

value that could be a number of possibilities, but we haven't been able to determine which one it actually is.

So what we're doing is applying the function `(,)`

(which just takes two arguments to build a pair), to two *nondeterminsitic* values, to get a nondeterminsitic pair (this is where we need the "special" version of function application with `<$>`

and `<*>`

; if we apply `(,)`

normally with `(,) enumAll enumAll`

or build the pair directly with `(enumAll, enumAll)`

then all we get is a normal pair of nondeterminsitic values, instead of a nondeterministic pair of normal values - `([a], [b])`

vs `[(a, b)]`

) . And if I take a pair from all possibilities of one bounded enum and all possibilities of another bounded enum, then I should get all possibilities of pair! Which is exactly what happens.

The type signature `positions :: [Pos]`

is actually necessary here. That's what tells Haskell we're building a list of `(Row, Column)`

pairs rather than any other kind of pair of enums, which is how it knows that the first `enumAll`

was enumerating all rows and the second wsa enumerating all columns. The most general type `(,) <$> enumAll <*> enumAll`

is actually `(Enum a, Bounded a, Enum b, Bounded b) => [(a, b)]`

, which will work just fine but is a pain to work with interactively in ghci because you'll keep getting ambiguous type variables whenever you try to print things.