You can add a type annotation as dave4420 mentions, but the normal way of doing so is this:

```
sasiad :: (Int, Int) -> [(Int, Int)]
sasiad (x,y) = [ (x+dx,y+dy) | dy <- [-1..1], dx <- [-1..1], x+dx >= 0, y+dy >= 0]
```

There is, however, an argument to be made for using the type that the compiler infers:

```
sasiad :: (Ord t1, Ord t, Num t1, Num t, Enum t, Enum t1) => (t, t1) -> [(t, t1)]
```

As this blog entry argues, the more complex type has advantages. For example, the fact that the inferred type for your function distinguishes between `t`

and `t1`

means that if you declare this type, the compiler won't let you mix up the arguments; basically, this type guarantees that the first elements of the pairs in the result list are computed using `x`

only, and the second elements are computed using `y`

only. Whether this is an useful invariant depends on your program.

Also, I can't help but to refactor your function:

```
sasiad :: (Ord t1, Ord t, Num t1, Num t, Enum t, Enum t1) => (t, t1) -> [(t, t1)]
sasiad (x,y) = cross (generate x) (generate y)
where generate x = filter (>=0) . map (\dx -> x+dx) $ [-1..1]
cross xs ys = [ (x,y) | x <- xs, y <- ys ]
```

`(Int, Int)`

to your function, youwillget back an`[(Int, Int)]`

. There really is no downside to the function being polymorphic. – sepp2k Jun 29 '12 at 17:28