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I have a following working definition:

{-# LANGUAGE ScopedTypeVariables #-}
module Control.Retry where

import Prelude hiding (catch)
import Control.Exception
import Control.Concurrent

retrying [] action = action 
retrying (i:is) action = catch action processError
    processError (e :: IOException) = threadDelay i >> retrying is action

Just out of curiosity I am wondering how I could reimplement this without utilizing the ScopedTypeVariables pragma, or whether I could at all, and what the inferred type declaration of processError actually is, because specifying processError :: IOException -> IO a makes it uncompilable.

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up vote 5 down vote accepted

If you want to avoid ScopedTypeVariables, you can most of the time use asTypeOf.

retrying [] action = action 
retrying (i:is) action = catch action processError
    processError e = snd (e `asTypeOf` (undefined :: IOException), threadDelay i >> retrying is action)

The undefined :: IOException is an expression type signature, and that is allowed by the standard. The asTypeOf requires the exception e to be an IOException.

I would prefer ScopedTypeVariables here, though.


retrying :: [Int] -> IO a -> IO a

the type of processError is inferred as

processError :: IOException -> IO a

with the a here being the same type variable as in the signature of retrying. That type can, however, not be specified in Haskell without the ScopedTypeVariables extension, since type variables in written-down signatures are by default universally quantified.

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Thanks. But what about the type signature of processError - how does it bind the type of action to the outer function? – Nikita Volkov Dec 11 '12 at 21:32
processError can't have a type signature without ScopedTypeVariables. In its inferred type, using action from the enclosing scope dtermines its result type as IO whatever_the_result_type_of_retrying_is. So, given retrying :: [Int] -> IO a -> IO a, the inferred type of processError is processError :: IOException -> IO a. But you cannot write down that type without STV. – Daniel Fischer Dec 11 '12 at 21:37
Just out of curiosity, is there any fancy name for this trick that a lambda calculus mathematician would use? – Tarrasch Dec 11 '12 at 23:23
@Tarrasch I have no idea if it's widespread enough to have a name. – Daniel Fischer Dec 11 '12 at 23:28

How about this:

retrying [] action = action 
retrying (i:is) action = catch action $ processError $
                         threadDelay i >> retrying is action
    processError :: IO a -> IOException -> IO a
    processError foo e = foo

Basically, this takes care of the problem of doing processError :: IOException -> IO a, where the a is generic and not the same a as in the enclosing function, by taking in an argument with the type a in it in order to tie it to the type in the enclosing function.

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Another option, maybe a little cleaner than asTypeOf:

retrying [] action = action 
retrying (i:is) action = catch action processError                                                                                                                                
    processError e = threadDelay i >> retrying is action
        _ = e :: IOException

Not sure if this is idiomatic; I just made it up and it worked.

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I've seen this mostly in the context of quickcheck tests, where you see the idiom where _types = (foo :: A, bar :: B) – luqui Dec 11 '12 at 23:38

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