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Say, I want to define a record Attribute like this:

data Attribute = Attribute {name :: String, value :: Any}

This is not valid haskell code of course. But is there a type 'Any' which basically say any type will do? Or is to use type variable the only way?

data Attribute a = Attribute {name :: String, value :: a}

share|improve this question
Look into GHC.Prim.Any. – Josh Lee Jun 25 '11 at 17:47
If you want name to have really any type, you should use a type variable. But: are you sure, that the name of a person should have any type? Probably (for instance) an Int-value as a name or a Bool-value as a name is not sound!? – phynfo Jun 25 '11 at 18:02
@phynfo, the sample I used was hypothetical. I just amended it to be more general. – edwardw Jun 25 '11 at 18:42
That level of genericity might be better translated at the Template Haskell level, if you really need it. – Dan Burton Jun 25 '11 at 18:59
up vote 58 down vote accepted

Generally speaking, Any types aren't very useful. Consider: If you make a polymorphic list that can hold anything, what can you do with the types in the list? The answer, of course, is nothing - you have no guarantee that there is any operation common to these elements.

What one will typically do is either:

  1. Use GADTs to make a list that can contain elements of a specific typeclass, as in:

    data FooWrap where
        FooWrap :: Foo a => a -> FooWrap
    type FooList = [FooWrap]

    With this approach, you don't know the concrete type of the elements, but you know they can be manipulated using elements of the Foo typeclass.

  2. Create a type to switch between specific concrete types contained in the list:

    data FooElem = ElemFoo Foo | ElemBar Bar
    type FooList = [FooElem]

    This can be combined with approach 1 to create a list that can hold elements that are of one of a fixed set of typeclasses.

  3. In some cases, it can be helpful to build a list of manipulation functions:

    type FooList = [Int -> IO ()]

    This is useful for things like event notification systems. At the time of adding an element to the list, you bind it up in a function that performs whatever manipulation you'll later want to do.

  4. Use Data.Dynamic (not recommended!) as a cheat. However, this provides no guarantee that a specific element can be manipulated at all, and so the above approaches should be preferred.

share|improve this answer
+1 for suggesting the "proper" approaches. – Dan Burton Jun 25 '11 at 18:58
N.B. -- Note that Any types are extremely useful in a language with subtyping -- a common example being an Object class at the top of an OOP inheritance hierarchy. Haskell doesn't have a real notion of subtyping, so the concept is mostly useless here. – C. A. McCann Jun 26 '11 at 1:54
Why use a made-up FooList GADT when there's a normal [] list, with a zillion functions written for it, lying around? One just needs a little wrapper around the typeclass to store in the list. – n.m. Jun 26 '11 at 2:10
Any (as well as forall a. a) may be useful when you store type in other way and unwrap it by unsafeCoerce and you cannot use Typeable for whatever reason. Of course in 99% of cases it means that the design cries "unspeakable horrors". – Maciej Piechotka Jun 26 '11 at 10:03
@n.m. FooList is only a type synonym, so it can be used in exactly the same way as [FooWrap]. – Lambda Fairy Dec 15 '11 at 22:49

Adding to bdonlan's answer: Instead of GADTs, you can also use existential types:

{-# LANGUAGE ExistentialQuantification #-}

class Foo a where
  foo :: a -> a

data AnyFoo = forall a. Foo a => AnyFoo a

instance Foo AnyFoo where
  foo (AnyFoo a) = AnyFoo $ foo a

mapFoo :: [AnyFoo] -> [AnyFoo]
mapFoo = map foo

This is basically equivalent to bdonlan's GADT solution, but doesn't impose the choice of data structure on you - you can use a Map instead of a list, for example:

import qualified Data.Map as M

mFoo :: M.Map String AnyFoo
mFoo = M.fromList [("a", AnyFoo SomeFoo), ("b", AnyFoo SomeBar)]

The data AnyFoo = forall a. Foo a => AnyFoo a bit can also be written in GADT notation as:

data AnyFoo where
  AnyFoo :: Foo a => a -> AnyFoo
share|improve this answer
Yes, this is the way. – augustss Jun 26 '11 at 0:22

There is the type Dynamic from Data.Dynamic which can hold anything (well, anything Typeable). But that is rarely the right way to do it. What is the problem that you are trying to solve?

share|improve this answer
Hi @augustss, one is that I'm looking for equivalent of Erlang's any() type in order to translate some code. The other is that I wonder how to declare a polymorphic list which can hold anything. A [Data.Dynamic.Dynamic] then? – edwardw Jun 25 '11 at 18:26
I would recommend against using Dynamic, instead make a type class with the properties the elements need to have, and then use an existential type to hide the actual type of the elements. I can elaborate if you want. – augustss Jun 25 '11 at 23:08

This sounds like a pretty basic question, so I'm going to give an even more basic answer than anybody else. Here's what is almost always the right solution:

data Attribute a = Attribute { name :: String, value :: a }

Then, if you want an attribute that wraps an Int, that attribute would have type Attribute Int, or an attribute that wraps a Bool would have type Attribute Bool, etc. You can create these attributes with values of any type; for example, we can write

testAttr = Attribute { name = "this is only a test", value = Node 3 [] }

to create a value of type Attribute (Tree Int).

share|improve this answer

If your data needs to be eventually a specific type, You could use Convertible with GADTs. Because as consumer, you are only interested in a the datatype you need to consume.

import Data.Convertible 

data Conv b where 
   Conv ::  a -> (a -> b) -> Conv b
   Chain :: Conv b -> (b -> c) -> Conv c

unconv :: (Conv b) -> b 
unconv (Conv a f) = f a
unconv (Chain c f) = f $ unconv c

conv :: Convertible a b => a -> Conv b 
conv a = (Conv a convert)

totype :: Convertible b c => Conv b -> Conv c
totype a = Chain a convert

It is not very difficult to derive functor, comonad and monad instances for this. I can post them if you are interested.

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