# List of different types?

``````data Plane = Plane { point :: Point, normal :: Vector Double }
data Sphere = Sphere { center :: Point, radius :: Double }

class Shape s where
intersect :: s -> Ray -> Maybe Point
surfaceNormal :: s -> Point -> Vector Double
``````

I have also made both `Plane` and `Sphere` instances of `Shape`.

I'm trying to store spheres and planes in the same list, but it doesn't work. I understand that it shouldn't work because `Sphere` and `Plane` are two different types, but they are both instances of `Shape`, so shouldn't it work? How would I store shapes and planes in a list?

``````shapes :: (Shape t) => [t]
shapes = [ Sphere { center = Point [0, 0, 0], radius = 2.0 },
Plane { point = Point [1, 2, 1], normal = 3 |> [0.5, 0.6, 0.2] }
]
``````
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I was aware of heterogeneous collections, but it's something that I wanted to avoid. –  Arlen Oct 17 '11 at 0:33

This problem represents a turning point between object-oriented and functional thinking. Sometimes even sophisticated Haskellers are still in this mental transition, and their designs often fall into the existential typeclass pattern, mentioned in Thomas's answer.

A functional solution to this problem involves reifying the typeclass into a data type (usually once this is done, the need for the typeclass vanishes):

``````data Shape = Shape {
intersect :: Ray -> Maybe Point,
surfaceNormal :: Point -> Vector Double
}
``````

Now you can easily construct a list of `Shape`s, because it is a monomorphic type. Because Haskell does not support downcasting, no information is lost by removing the representational distinction between `Plane`s and `Sphere`s. The specific data types become functions that construct `Shape`s:

``````plane :: Point -> Vector Double -> Shape
sphere :: Point -> Double -> Shape
``````

If you cannot capture everything you need to know about a shape in the `Shape` data type, you can enumerate the cases with an algebraic data type, as Thomas suggested. But I would recommend against that if possible; instead, try to find the essential characteristics of a shape that you need rather than just listing off examples.

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wow, that worked, and I really like it :-) –  Arlen Oct 17 '11 at 0:32
This nicely put that we should not think of Type classes as OO inheritance or interfaces and think of them subtype. They are just a set of functions that a type can support –  Ankur Oct 17 '11 at 4:11

You are looking for a heterogeneous list, which most Haskellers don't particularly like even though they've asked themselves this same question when first learning Haskell.

You write:

``````shapes :: (Shape t) => [t]
``````

This says the list has type `t`, all of which are the same and happen to be a Shape (the same shape!). In other words - no, it shouldn't work how you have it.

Two common ways to handle it (a Haskell 98 way first, then a fancier way that I don't recommend second) are:

Use a new type to statically union the subtypes of interest:

``````data Foo = F deriving Show
data Bar = B deriving Show

data Contain = CFoo Foo | CBar Bar deriving Show
stuffExplicit :: [Contain]
stuffExplicit = [CFoo F, CBar B]

main = print stuffExplicit
``````

This is nice seeing as it's straight forward and you don't lose any information about what is contained in the list. You can determine the first element is a `Foo` and the second element is a `Bar`. The drawback, as you probably already realize, is that you must explicitly add each component type by making a new `Contain` type constructor. If this is undesirable then keep reading.

Use Existential Types: Another solution involves losing information about the elements - you just retain, say, knowledge that the elements are in a particular class. As a result you can only use operations from that class on the list elements. For example, the below will only remember the elements are of the `Show` class, so the only thing you can do to the elements is use functions that are polymorphic in `Show`:

``````data AnyShow = forall s. Show s => AS s

showIt (AS s) = show s

stuffAnyShow :: [AnyShow]
stuffAnyShow = [AS F, AS B]

main = print (map showIt stuffAnyShow)
``````

This requires some extensions to the Haskell language, namely `ExplicitForAll` and `ExistentialQuantification`. We had to define `showIt` explicitly (using pattern matching to deconstruct the `AnyShow` type) because you can't use field names for data types that use existential quantification.

There are more solutions (hopefully another answer will use `Data.Dynamic` - if no one does and you are interested then read up on it and feel free to post any questions that reading generates).

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The first method is the very first thing I tried, and it didn't work out well. I'm not sure if I like the second method! I would also like to avoid using extensions. –  Arlen Oct 17 '11 at 0:39