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I'm pretty new to Haskell, so I hope this isn't a stupid question. I have this data type:

data N = I Int | D Double deriving (Show, Eq)

I'm trying to write a function with the signature (Num a) => (a -> a -> a) -> N -> N -> N which applies the function to the numbers within the Ns and returns an N with the result. If the Ns are both Ds, it should just apply the function and return a D; if one is an I and the other is a D, it should convert the Int in the I to a Double, apply the function to the two Doubles, and return a D; and if both are Is, it should apply the function and return an I. Here's the (broken) code I have so far:

widen :: N -> N -> (N, N)
widen (I i) d@(D _) = (D (fromIntegral i), d)
widen d@(D _) i@(I _) = widen i d
widen x y = (x, y)

numOp :: (Num a) => (a -> a -> a) -> N -> N -> N
numOp op x y = case widen x y of (D x', D y') -> D $ x' `op` y'
                                 (I x', I y') -> I $ x' `op` y'

I get an error on both lines of numOp, though. The first one is:

Could not deduce (a ~ Double)
from the context (Num a)
  bound by the type signature for
             numOp :: Num a => (a -> a -> a) -> N -> N -> N
  at <line num>
In the second argument of `($)', namely x' `op` y'
In the expression: D $ x' `op` y'
In a case alternative: (D x', D y') -> D $ x' `op` y'

And the second:

Couldn't match type `Double' with `Int'
Expected type: Int
  Actual type: a
In the second argument of `($), namely x' `op` y'
In the expression: I $ x' `op` y'
In a case alternative: (I x', I y') -> I $ x' `op` y'

I'm pretty sure I understand what both errors mean; I think the first one is saying that the information in my type signature isn't enough for GHC to assume that op returns a Double, which is required by the D value constructor, and the second one is saying that since the first line implies that a is Double, this line can't use a value of type a as though it's an Int. I don't have any idea where to start looking for the right way to do this, though.

If it helps, the reason I'm trying to get this to work is that I'm following along with the Write Yourself a Scheme tutorial; all the examples in the tutorial (specifically in the Evaluation section) only deal with integers, but as an exercise I'd like to add the ability to support both integral and floating point numbers so that e.g. (+ 1 2.5 2.5) returns 6.0 and (+ 1 2 3) returns 6. If I'm thinking about this the wrong way or there's an easier way to accomplish it, I'd love to hear suggestions.

share|improve this question
Not a stupid question at all. The issue is a fairly non-obvious one. – Daniel Fischer Dec 31 '12 at 1:34
up vote 7 down vote accepted

The signature

numOp :: (Num a) => (a -> a -> a) -> N -> N -> N

says that numOp takes any monomorphic function of type a -> a -> a for every specific instance of Num and two Ns and from that computes an N. So for example, a function of type

Complex Float -> Complex Float -> Complex Float


approxRational :: RealFrac a => a -> a -> Rational

(specialised to a = Rational) would be legitimate first arguments.

What you need is a polymorphic function that can handle all Num instances as the first argument, i.e. the rank 2 type

numOp :: (forall a. Num a => a -> a -> a) -> N -> N -> N

(you need the RankNTypes language extension for that).

share|improve this answer
Awesome, thanks so much! – jcsmnt0 Dec 31 '12 at 1:47
If you're only dealing with rank-2 types, as opposed to higher-rank types, you can use Rank2Types instead. This has the advantage that it preserves decidable type inference (which fails for higher-rank types), although I've never seen this come up in practice. – Antal Spector-Zabusky Dec 31 '12 at 4:10
Would you mind explaining a bit further what you mean by that? I figured preserving decidable type inference would mean that that I could remove the explicit type signature from my numOp function and the compiler would successfully infer it if I had the Rank2Types language pragma, but that doesn't seem to be the case. – jcsmnt0 Dec 31 '12 at 4:51
@AntalS-Z The Rank2Types extension is being deprecated. I'm not sure if it will be totally removed or kept around as an alias for RankNTypes. While it is being kept around, it won't be rank <= 2 only, so I prefer to go with the times and use RankNTypes everywhere now. – Daniel Fischer Dec 31 '12 at 5:20

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