I have a function that has type Read a => String -> a, is it possible to have another function with the same name that does things differently when a is for example String? Are there any GHC extensions that allow this?

Something like:

f :: Read a => String -> a
f = read

f :: String -> String
f = id
  • If you're just concerned about performance, these kind of things should get optimized out by the compiler. – leftaroundabout Mar 27 '12 at 0:31
  • I'm not concerned about performance, I want a version of read that doesn't require quotation marks around strings, but works as normal read for everything else. – Marek Sapota Mar 27 '12 at 0:37
  • The question stackoverflow.com/questions/9870962/… addresses exactly the same problem; some answers there may be useful. – John L Mar 27 '12 at 1:23

In Haskell, this kind of function overloading (ad-hoc polymorphism) is accomplished by using type classes, not by binding the same name under multiple types.

{-# LANGUAGE FlexibleInstances, TypeSynonymInstances #-}

class F a where f :: String -> a

instance F String where f = id
instance F Int where f = read
instance F Char where f = read
instance F Float where f = read
-- etc.

Now, f can operate on any type for which an instance of F has been declared.

Unfortunately, you can't get away with the following:

instance Read a => F a where f = read

Perhaps unintuitively, this does not declare an instance of F only for types which have an instance of Read. Because GHC resolves instances using only the head of the instance declaration (the part to the right of the =>), this actually declares all types a to be instances of F, but makes it a type error to call f on anything which is not also an instance of Read.

It will compile if you enable the UndecidableInstances extension, but this just leads to other problems. It's a rabbit hole you don't really want to venture down.

Instead, you should declare an instance of F for each individual type you intend f to operate on. This isn't very burdensome for a simple class like this one, but if you use a recent version of GHC, you can use the following to make it slightly easier:

{-# LANGUAGE DefaultSignatures #-}

class F a where f :: String -> a
                default f :: Read a => String -> a
                f = read

Now, for any type which is an instance of Read, you may declare its instance of F without having to provide the implementation of f explicitly:

instance F Int
instance F Char
instance F Float
-- etc.

For any types without instances of Read, you'll still have to write an explicit implementation for f.


I got it to work, but I had to turn on a bunch of questionable language options:

{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}
{-# LANGUAGE TypeSynonymInstances #-}
{-# LANGUAGE OverlappingInstances #-}

class SpecialRead a where
  specialRead :: String -> a

instance Read a => SpecialRead a where
  specialRead = read

instance SpecialRead String where
  specialRead = id

main = do
    print (specialRead "10" :: Int)
    print (specialRead "10" :: String)
  • 5
    FlexibleInstances and TypeSynonymInstances are uncontroversial; they just relax some restrictions imposed by the Haskell standard, but aren't anything to worry about. UndecidableInstances and OverlappingInstances are dangerous territory, however, and should generally be avoided unless you know what you're doing. – bitbucket Mar 27 '12 at 1:12

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