Are you sure you really want to put different types in a list?
You could use something like jetxee's example with existential quantification, but think about what that actually does: You have a list of terms of unknown type, and the only thing you can do with them is apply
putOut to get an
IO () value back. That is to say, if the "interface" only provides one function with a known result type, there's no difference between a list of existentials and a list of results. The only possible use of the former involves converting it to the latter, so why add the extra intermediate step? Use something like this instead:
main :: IO ()
main = do
where lst :: [IO ()]
lst = [out1 1, out2 1 2]
out1 x = putStrLn $ unwords ["Out1", show x]
out2 x y = putStrLn $ unwords ["Out2", show x, show y]
This may seem counterintuitive at first, because it relies on some unusual features of Haskell. Consider:
- No extra computation is done--lazy evaluation means that
unwords, &c. won't be run unless the
IO action is executed.
- No side effects are involved in simply creating
IO () values--they can be stored in lists, passed around in pure code, and so on. It's only the
sequence_ function in
main that runs them.
The same argument applies to lists of "instances of
Show" and whatnot. It doesn't work well for instances of something like
Eq, where you need two values of the type, but a list of existentials wouldn't work any better because you don't know if any two values are the same type. All you could do in that case would be check each element to be equal to itself, and then you might as well (as above) just create a list of
Bools and be done with it.
In more general cases, it's best to keep in mind that Haskell type classes are not OOP interfaces. Type classes are a powerful means of implementing ad-hoc polymorphism, but are not as well-suited to hiding implementation details. OOP languages tend to conflate ad-hoc polymorphism, code reuse, data encapsulation, behavioral subtyping, and such by tying everything to the same class hierarchy; in Haskell you can (and often must) deal with each separately.
An object in an OOP language is, roughly speaking, a collection of (hidden, encapsulated) data bundled with functions to manipulate that data, each of which takes the encapsulated data as an implicit argument (
self, etc.). To replicate this in Haskell, you don't need type classes at all:
- Write each "class method" as a regular function, with the
self parameter made explicit.
- Partially apply each function to a value of the "encapsulated" data
- Combine the partially applied functions into a single record type
The record type replaces the interface; any collection of functions with the proper signatures represents an implementation of the interface. In some ways this is actually better object-oriented style, because the private data is completely hidden and only the exterior behavior is exposed.
As in the simpler case above, this is almost exactly equivalent to the existential version; the record of functions is what you'd get by applying each method of the type class to each existential.
There are some type classes where using a record of functions wouldn't work well--
Monad, for instance--which are generally also the same type classes that can't be expressed by conventional OOP interfaces, as demonstrated by modern versions of C# making extensive use of monadic style yet not providing any sort of generic
See also this article covering the same things I'm saying. You may also want to look at Graphics.DrawingCombinators for an example of a library offering extensible, composable graphics without using type classes.