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I'm trying to go through the YesNo example from Learn You a Haskell for Great Good! book.

Here is my source code:

module Main where

main :: IO ()

main = putStrLn ( show (yesno 12) )

class YesNo a where
    yesno :: a -> Bool

instance YesNo Bool where
    yesno b = b

instance YesNo [a] where
    yesno [] = False
    yesno _ = True

instance YesNo Int where
    yesno 0 = False
    yesno _ = True

When I execute this code following exception occurs:

Ambiguous type variable `a0' in the constraints:
  (YesNo a0) arising from a use of `yesno'
             at /Users/mkhadikov/Projects/personal/haskell/hello-world/yesno.hs:5:25-29
  (Num a0) arising from the literal `12'
           at /Users/mkhadikov/Projects/personal/haskell/hello-world/yesno.hs:5:31-32
Probable fix: add a type signature that fixes these type variable(s)
In the first argument of `show', namely `(yesno 12)'
In the first argument of `putStrLn', namely `(show (yesno 12))'
In the expression: putStrLn (show (yesno 12))

Can you please explain what's wrong with this code?

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up vote 28 down vote accepted

The problem is that it doesn't know what type 12 is! It can be any type with a Num instance:

GHCi> :t 12
12 :: Num a => a

You need to specify the type you want directly: try putStrLn (show (yesno (12 :: Int))).

Why can't GHC pick Int, since no other choice would work, you ask? Good question. The answer is that with Haskell's typeclass system, adding an instance can never invalidate existing correct programs or change their behaviour. (This is referred to as the open world assumption.) If it did pick Int, then what would happen if you added instance YesNo Integer? The choice would become ambiguous, and your program would break!

So when you want to use a typeclass like this with a polymorphic value, you have to specify what type you mean more precisely. This shouldn't come up much in practice, since there'll usually be some surrounding context to force the type to be what you want; it's mainly numeric literals that are affected by this.

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The problem is that 12 actually has type Num a => a and not Int as you expect. If you add an explicit type anotation such as 12 :: Int, it should compile.

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Is it possible to create your own kind of data constructors that work like 12 in haskell? It seems that whenever you create a data constructor, it constructs a value of a single type. But when you write 12, as you can see it constructs not a value of a single type, but a value of any type where the type is constrained by Num. Thus Num a => a. Am I interpreting this correctly? Is this kind of like constructing a value which has a existential/union? – CMCDragonkai Feb 18 '15 at 6:03
@CMCDragonkai I'm a bit fuzzy on the details but basically the typeclass Num contains a function fromInteger :: Num a => Integer -> a. A numeric literal works as if fromInteger was called on it. – FUZxxl Feb 18 '15 at 10:04
Ah, so the a does kind of become an existential/union. Very interesting. – CMCDragonkai Feb 18 '15 at 11:02
What is the implementation though? That's the type signature, what's the actual function implementation? Or is it kind of like a GADT kind of thing? (where the implementation is just inferred) Otherwise I would like to create my own fromSomething to create a typeclass constrained value rather than a typed value. – CMCDragonkai Feb 18 '15 at 11:04
@CMCDragonkai Not really. The quantor is forall; the fully qualified type is fromInteger :: forall a. Num a => Integer -> a. Since fromInteger is a type class member, ghci chooses the implementation of fromInteger appropriate for the type you want to get. – FUZxxl Feb 18 '15 at 11:05

I had the same problem.

This is a solution, perhaps not the best one but it works:

class YesNo a where
     yesno  ::  a -> Bool

instance YesNo Int where
     yesno 0    =   False
     yesno _    =   True

instance YesNo Integer where
     yesno 0    =   False
     yesno _    =   True
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