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How to convert following Java implementation into Haskell?

The major purpose here is having a list that contains various elements which are sub-type of a particular interface.
I tried to make a Haskell version below but fail to meet my purpose. The point here is xs has type [Bar] rather than Foo a => [a]

Do that mean Haskell can not do this and shall I think in another way?

I'm wondering it's a common newbie question but not yet find any answer.

Thank you.

Java

interface Foo {
    void bar ();
}

public class Bar1 implements Foo {
    @Override
    public void bar() {
        System.out.println("I am bar 1 class");
    }   
}

public class Bar2 implements Foo {
    @Override
    public void bar() {
        System.out.println("I am bar 2 class");
    }   
}

public static void main(String[] args) {
    // The major purpose here is having a list 
    // that contains elements which are sub-type of "Foo"
    List<Foo> ys = new ArrayList<Foo>();

    Foo e1 = new Bar1();
    Foo e2 = new Bar2();

    ys.add(e1);
    ys.add(e2);

    for (Foo foo : ys) {
        foo.bar();
    }
}

Haskell

class Foo a where
  bar :: a -> IO ()

data Bar = Bar1 | Bar2

instance Foo Bar where
  bar Bar1 = print "I am Bar1"
  bar Bar2 = print "I am Bar2"

--xs :: Foo a => [a]
xs :: [Bar]
xs = [Bar1, Bar2]

main :: IO ()
main = mapM_ bar xs
share|improve this question
1  
Your implementation in Haskell looks fine to me. I'd even go as far and say that the proper translation is: bar1 = "I am Bar1"; bar2 = "I am Bar2"; xs = [bar1, bar2]; main = mapM_ putStrLn xs –  kosmikus Jan 8 at 14:09
    
Actually the point here is that to have a list of elements which implement particular interface. –  Simon Jan 8 at 14:12
1  
Yes, but that interface is (in this case) of type String, or perhaps IO String. –  kosmikus Jan 8 at 14:13

4 Answers 4

up vote 11 down vote accepted

Simple answer: don't! Haskell is not an OO language, and it's not much good pretending it is and just trying to translate inheritance patterns to a mixture of type classes and ADTs.

Your List<Foo> in Java is quite substantially different from a Foo a => [a] in Haskell: such a signature actually means forall a . Foo a => [a]. The a is basically an extra argument to the function, i.e. it can be chosen from the outside what particular Foo instance is used here.

Quite the opposite in Java: there you don't have any control of what types are in the list at all, only know that they implement the Foo interface. In Haskell, we call this an existential type, and generally avoid it because it's stupid. Ok, you disagree – sorry, you're wrong!
...No, seriously, if you have such an existential list, the only thing you can ever do1 is execute the bar action. Well, then why not simply put that action in the list right away! IO() actions are values just like anything else (they aren't functions; anyway those can be put in lists just as well). I'd write your program

xs :: [IO ()]
xs = [bar Bar1, bar Bar2]


That said, if you absolutely insist you can have existential lists in Haskell as well:

{-# LANGUAGE ExistentialQuantification #-}

data AFoo = forall a. Foo a => AFoo a

xs :: [AFoo]
xs = [AFoo Bar1, AFoo Bar2]

main = mapM_ (\(AFoo f) -> bar f) xs

As this has become quite a rant: I do acknoledge that OO style is for some applications more convenient than Haskell's functional style. And existentials do have their valid use cases (though, like chunksOf 50, I rather prefer to write them as GADTs). Only, for lots of problems Haskell allows for far more concise, powerful, general, yet in many ways simpler solutions than the "if all you have's a hammer..." inheritance you'd use in OO programming, so before using existentials you should get a proper feeling for Haskell's "native" features.


1Yeah, I know you can also do "typesafe dynamic casts" etc. in Java. In Haskell, there's the Typeable class for this kind of stuff. But you might as well use a dynamic language right away if you take such paths.

share|improve this answer
    
With XConstraintKinds one may perform few interesting tricks. But generally you're right about uselessness of such OOP simulation. –  user3974391 Jan 8 at 16:18
1  
GADTs are a prettier way of doing existential quantification, but list of IO() or a data type representing everything you want is best, like you say, yes. –  enough rep to comment Jan 8 at 17:01
3  
Using existentials isn't always wrong, it's just usually wrong. –  augustss Jan 8 at 17:30
    
Thanks your explanation. I'm "shaped out" by Java and I do want more functional thinking! –  Simon Jan 9 at 1:17
    
The only "painful" thing about writing xs = [bar Bar1, bar Bar2] is that I need type bar function many times while I have lots of Bar (Bar3, Bar4,etc). I'm wondering to design in another way or I have to use existentials type at such case? –  Simon Jan 9 at 1:26

Your translation has an important drawback. Whereas in your Java version, you could easily add a Bar3 that also supports the Foo interface, you cannot easily achieve the same without touching the Bar type in the Haskell version. So this is rather not the version you are looking for.

In a way you are looking for a heterogeneous list. Other questions are covering this aspect already.

What you really want though is to get rid of the need of a type class altogether. Instead have a data type representing the behavior of Foo:

data Foo = Foo { bar :: IO () }

Then you can construct your list of object satisfying the Foo interface as a [Foo].

share|improve this answer
1  
It's worth noting that this is very similar to the existential data Boxy = forall a. Classy a => Boxy a since typeclasses are eventually transformed into records. –  jozefg Jan 8 at 17:02

This is possible but probably not desirable. There is such language extension as 'existential types' that allows dynamic polymorphism.

The idea of existential type is following:

data Foo = Foo a

Note that type variable "a" doesn't appear on the left side of ADT declaration. Simple example of possible implementation of dynamic polymorphic list and map function:

{-# LANGUAGE UnicodeSyntax, Rank2Types, GADTs, ConstraintKinds #-}

import Data.Constraint

-- List datatype:
data PList α where
   Nil  ∷ PList α
   (:*) ∷ α a ⇒ a → PList α → PList α

infixr 6 :*

-- Polymorphic map:
pmap ∷ (∀ a. α a ⇒ a → b) → PList α → [b]
pmap _ Nil      = []
pmap f (a :* t) = f a : pmap f t

main = let
        -- Declare list of arbitrary typed values with overloaded instance Show:
        l ∷ PList Show
        l = "Truly polymorphic list " :* 'a' :* 1 :* (2, 2) :* Nil
    in do
        -- Map show to list:
        print $ pmap show l

Output:

["\"Truly polymorphic list \"","'a'","1","(2,2)"]

Another example using this technique:

class Show a ⇒ Named a where
    name ∷ a → String

instance Named Int where
    name a = "I'm Int and my value is " ++ show a

instance Named Char where
    name a = "I'm Char and my value is " ++ show a

 main = let
        -- Declare list of arbitrary typed values with overloaded instance Named:
        l2 :: PList Named
        l2 = 'a' :* (1 ∷ Int) :* Nil
    in do 
        print $ pmap name l2
        print $ pmap show l2

Output:

["I'm Char and my value is 'a'","I'm Int and my value is 1"]
["'a'","1"]
share|improve this answer
    
This would be another impl. Thanks. Is the Foo named "phatom type"? –  Simon Jan 9 at 1:29
    
No it isn't. This is pseudocode for existential type. –  user3974391 Jan 9 at 8:33

To migrate from OOP to Haskell, read this:

http://www.haskell.org/haskellwiki/OOP_vs_type_classes

share|improve this answer
    
This is helpful. Thanks. –  Simon Jan 9 at 9:37

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