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Suppose I have the following:

class Shape a where
    draw a :: a -> IO ()

data Rectangle = Rectangle Int Int

instance Shape Rectangle where
    draw (Rectangle length width) = ...

data Circle = Circle Int Int

instance Shape Circle where
    draw (Circle center radius) = ...

Is there any way for me to define a list of shapes, traverse over the list, and call the draw function on each shape? The following code won't compile because the list elements aren't all the same type:

shapes = [(Circle 5 10), (Circle 20, 30), (Rectangle 10 15)]

I know I'm thinking in an OO way and trying to apply it to Haskell, and that might not be the best approach. What would be the best Haskell approach for programs that need to deal with collections of different types of objects?

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5 Answers 5

up vote 20 down vote accepted

If you really do need to do this, then use an existential:


class IsShape a where
    draw :: a -> IO ()

data Rectangle = Rectangle Int Int

instance IsShape Rectangle where
    draw (Rectangle length width) = ...

data Circle = Circle Int Int

instance IsShape Circle where
    draw (Circle center radius) = ...

data Shape where
    Shape :: IsShape a => a -> Shape

shapes = [Shape (Circle 5 10), Shape (Circle 20 30), Shape (Rectangle 10 15)]

(I renamed your class as there would be a name clash with the datatype otherwise, and having the naming this way round seems more natural).

The advantage of this solution over the other answer involving a single datatype with different constructors is that it is open; you can define new instances of IsShape wherever you like. The advantage of the other answer is that it's more "functional", and also that the closedness may in some cases be an advantage as it means that clients know exactly what to expect.

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I couldn't get your example to compile. But, the wiki page you reference answers my question perfectly. –  Clint Miller Jun 15 '09 at 14:38
Try now - I had a Shape where I should have had an IsShape in the signature of the data constructor for Shape. –  Ganesh Sittampalam Jun 15 '09 at 15:06
It's worth noting for future readers that the disadvantage of this approach is that code getting circles and rectangles out of the Shape container won't be able to use any other properties than what's given in the IsShape instance; you can't get at the coordinates, can't tell whether it is a Circle or a Rectangle, and can't call any other functions that operate specifically on circles or rectangles, rather than any shape. That's a fundamental consequence of the openness Ganesh is talking about (and shows up in statically typed OO programming when you feel forced to "downcast"). –  Ben Feb 27 at 20:29

Consider using a single type instead of separate types and a typeclass.

data Shape = Rectangle Int Int
           | Circle Int Int

draw (Rectangle length width) = ...
draw (Circle center radius)   = ...

shapes = [Circle 5 10, Circle 20 30, Rectangle 10 15]
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While this works, I was looking for a solution that allows new data types to be defined elsewhere so that the code that processes the shapes list doesn't need to be aware of every type of shape. –  Clint Miller Jun 15 '09 at 14:36

One way to do it would be with vtables:

data Shape = Shape {
  draw :: IO (),
  etc :: ...

rectangle :: Int -> Int -> Shape
rectangle len width = Shape {
  draw = ...,
  etc = ...

circle :: Int -> Int -> Shape
circle center radius = Shape {
  draw = ...,
  etc = ...
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The problem here is that your Shape data type has to be a union of all the fields of all possible shapes. That may work fine for my (contrived) case, but it will be an awkward approach in more complex cases. –  Clint Miller Jun 15 '09 at 14:17
Interesting answer, hadn't thought of something like this. @Clint: I don't think the Shape data type here has be be the union of all possible fields. It describes all the functions in your Shape class, each constructor function (rectangle, circle) constructs a shape by providing a unique implementation for the functions, just like with instances. –  Tom Lokhorst Jun 15 '09 at 15:15
This is basically working with explicit type class dictionaries. It works, but most of the time implicit dictionaries are much simpler. The existential-based solution I posted will end up being the same as this under the covers (at least with a compiler like GHC that uses dictionaries to implement type classes). –  Ganesh Sittampalam Jun 15 '09 at 20:23
I get it. I mis-read this the first time. The rectangle and circle functions return Shape objects with functions that are closures over len and width or center and radius. Pretty clever. –  Clint Miller Jun 16 '09 at 15:56

As Ganesh said, you could indeed use GADTs to have more type safety. But if you don't want (or need) to, here's my take on this:

As you already know, all elements of a list need to be of the same type. It isn't very useful to have a list of elements of different types, because then your throwing away your type information.

In this case however, since you want throw away type information (you're just interested in the drawable part of the value), you would suggest to change the type of your values to something that is just drawable.

type Drawable = IO ()

shapes :: [Drawable]
shapes = [draw (Circle 5 10), draw (Circle 20 30), draw (Rectangle 10 15)]

Presumably, your actual Drawable will be something more interesting than just IO () (maybe something like: MaxWidth -> IO ()).

And also, due to lazy evaluation, the actual value won't be drawn until you force the list with something like sequence_. So you don't have to worry about side effects (but you probably already saw that from the type of shapes).

Just to be complete (and incorporate my comment into this answer): This is a more general implementation, useful if Shape has more functions:

type MaxWith = Int

class Shape a where
    draw :: a -> MaxWidth -> IO ()
    size :: a -> Int

type ShapeResult = (MaxWidth -> IO (), Int)

shape :: (Shape a) => a -> ShapeResult
shape x = (draw x, size x)

shapes :: [ShapeResult]
shapes = [shape (Circle 5 10), shape (Circle 20 30), shape (Rectangle 10 15)]

Here, the shape function transforms a Shape a value into a ShapeResult value, by simply calling all the functions in the Shape class. Due to laziness, none of the values are actually computed until you need them.

To be honest, I don't think I would actually use a construct like this. I would either use the Drawable-method from above, or if a more general solution is needed, use GADTs. That being said, this is a fun exercise.

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This is nice if drawing is really all you want to do with them - if you might want to do different things from the Shape class, then this doesn't scale all that well - though in some senses my solution is the natural extension of this approach as it passes around the entire class dictionary with each value which you can then apply as you want. –  Ganesh Sittampalam Jun 15 '09 at 12:56
Sure, this only works if Shape has nothing more than draw. When I started writing this I had a Drawable data type, with a single IO () field, and a toDrawable :: (Shape a) => a -> Drawable function. That would be extensible to more fields (for each function in Shape) and that of course is just a manually constructed class dictionary... –  Tom Lokhorst Jun 15 '09 at 13:03
Ganesh's comment was my reaction to this as well. It does show a really interesting use of Haskell's lazy evaluation. That's kind of cool. Being new to Haskell, I have to admit that it's going to take me a bit to get used to taking advantage of lazy evaluation. –  Clint Miller Jun 15 '09 at 14:19

How to deal with a heterogeneous list of shapes in Haskell — Abstract polymorphism with type classes: http://pastebin.com/hL9ME7qP via @pastebin



class Shape s where
 area :: s -> Double
 perimeter :: s -> Double

data Rectangle = Rectangle {
 width :: Double,
 height :: Double
} deriving Show

instance Shape Rectangle where
 area rectangle = (width rectangle) * (height rectangle)
 perimeter rectangle = 2 * ((width rectangle) + (height rectangle))

data Circle = Circle {
 radius :: Double
} deriving Show

instance Shape Circle where
 area circle = pi * (radius circle) * (radius circle)
 perimeter circle = 2.0 * pi * (radius circle)

r=Rectangle 10.0 3.0 
c=Circle 10.0
list=[WrapShape r,WrapShape c]

data ShapeWrapper where
 WrapShape :: Shape s => s -> ShapeWrapper

getArea :: ShapeWrapper -> Double
getArea (WrapShape s) = area s

getPerimeter :: ShapeWrapper -> Double
getPerimeter (WrapShape s) = perimeter s

areas = map getArea list
perimeters = map getPerimeter list
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