Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to write a simple ray-tracer in Haskell. I wanted to define a typeclass representing the various kinds of surfaces available, with a function to determine where a ray intersects them:

{-# LANGUAGE RankNTypes #-}

data Vector = Vector Double Double Double
data Ray = Ray Vector Vector

class Surface s where
  intersections :: s -> Ray -> [Vector]

-- Obviously there would be some concrete surface implementations here...

data Renderable = Renderable
  { surface    :: (Surface s) => s
  , otherStuff :: Int
  }

getRenderableIntersections :: Renderable -> Ray -> [Vector]
getRenderableIntersections re ra = intersections (surface re) ra

However this gives me the error:

Ambiguous type variable 's' in the constraint:
  'Surface'
    arising from a use of 'surface'

(The actual code is more complex but I've tried to distill it to something simpler, while keeping the gist of what I'm trying to achieve).

How do I fix this? Or alternatively, given that I come from a standard OO background, what am I fundamentally doing wrong?

share|improve this question

2 Answers 2

up vote 9 down vote accepted

Please don't use existential types for this! You could, but there would be no point.

From a functional standpoint you can drop this typeclass notion of Surface entirely. A Surface is something that maps a Ray to a list of Vectors, no? So:

type Surface = Ray -> [Vector]

data Renderable = Renderable
 { surface    :: Surface
 , otherStuff :: Int
}

Now if you really want, you can have a ToSurface typeclass essentially as you gave:

class ToSurface a where
     toSurface :: a -> Surface

But that's just for convenience and ad-hoc polymorphism. Nothing in your model requires it.

In general, there are a very few use cases for existentials, but at least 90% of the time you can substitute an existential with the functions it represents and obtain something cleaner and easier to reason about.

Also, even though it may be a tad too much for you to take in, and the issues don't exactly match, you might find useful some of Conal's writing on denotational design: http://conal.net/blog/posts/thoughts-on-semantics-for-3d-graphics/

share|improve this answer

In your getRenderableIntersections function you call surface. There is no way for the interpreter to figure out what instance of the class Surface you want to use. If you have two such instances:

instance Surface SurfaceA where
  -- ...
instance Surface SurfaceB where
  -- ...

How can the interpreter determine the type of surface?

The way you defined Renderable means there is a function surface :: Surface s => Renderable -> s.

Try creating an instance Surface SurfaceA and asking the following type query (given a simple constructor SurfaceA):

> :t surface (Renderable SurfaceA 0) -- What's the type of the expression?

So, what type is this expression? I bet you're expecting SurfaceA. Wrong. Take the type of surface. It takes a Renderable argument and we're passing it a Renderable argument. What is left after that? Surface s => s. That's the type of that expression. We still don't know what type does s represent.

If you want the type to be SurfaceA you need to change your code so it becomes something like surface :: Surface s => Renderable s -> s. This way what s is can be determined, because it is the same s used in Renderable.

EDIT: As suggested by @mokus, you could also try the ExistentialTypes extension. It allows "hiding" away type parameters on the right side of a type declaration.

data Renderable = forall s. Surface s => Renderable
  { surface    :: s
  , otherStuff :: Int
  }

The HaskellWiki page I linked to above even has an example very similar to what you want to do.

EDIT: (By @stusmith) - For the record, I'm including code below which compiles based on these suggestions here. However I've accepted the answer which I think shows a better way of approaching things.

{-# LANGUAGE ExistentialQuantification #-}

data Vector = Vector Double Double Double
data Ray = Ray Vector Vector

class Surface_ s where
  intersections :: s -> Ray -> [Vector]

data Surface = forall s. Surface_ s => Surface s

instance Surface_ Surface where
  intersections (Surface s) ra = intersections s ra

data Renderable = Renderable
  { surface :: Surface
  }

getRenderableIntersections :: Renderable -> Ray -> [Vector]
getRenderableIntersections re ra = intersections (surface re) ra
share|improve this answer
    
...but since all surfaces implement the 'intersections' method, why isn't that enough? Obviously with my background I'm seeing 'Surface' as an abstract class, and 'intersections' as a virtual method. –  stusmith Feb 15 '11 at 14:43
    
@stusmith: see my update. You cannot have open type parameters in the middle of expressions. Either the entire expression is parametric, or the types can all be determined statically. (Maybe there is a GHC extension or something that allows that, but I don't know it) –  R. Martinho Fernandes Feb 15 '11 at 15:11
    
So does this mean that Haskell doesn't have the equivalent of 'virtual' functions? I wanted to have a list of Renderables, and to be able to work on them as abstract types. Do I therefore need to have [Renderable s] instead? And can that list contain heterogenous Renderable instances with different Surface instances? –  stusmith Feb 15 '11 at 15:11
1  
@stusmith: The type of the surface field is not what you're expecting. It is forall s. Surface s => s, so values in that field must be valid values of every Surface type. The only possible such value is undefined and the like (since the Surface class defines no functions that yield s). What you're looking for is the ExistentialTypes extension, not RankNTypes, and the Surface s => context would go before the data constructor, i.e. data Renderable = forall s. Surface s => Renderable ... if I'm remembering the syntax correctly. That should be enough to google anyway ;) –  mokus Feb 15 '11 at 15:17
    
@mokus: thanks for chiming in with the name of the extension. –  R. Martinho Fernandes Feb 15 '11 at 15:27

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.