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Given two monads, Monad m and Monad n, I would like to transform m (n a) into n (m a). But there seems to be no generic way because both (>>=) and return deals with only one monad type, and although (>>=) allows extracting content from a monad, you must pack them back to the same monad type so it can be a result value.

However, if we set m to a fixed type, the job becomes easy. Take Maybe as an example:

reorder :: (Monad n) => Maybe (n a) -> n (Maybe a)
reorder Nothing = return Nothing
reorder (Just x) = do
    x' <- x
    return $ Just x'

Or a list:

reorder :: (Monad n) => [n a] -> n [a]
reorder [] = return []
reorder (x:xs) = do
    x'  <- x
    xs' <- reorder xs
    return (x':xs')

Not hard to see, we've got a pattern here. To be more obvious, write it in a Applicative way, and it's no more than applying the data constructor to each element:

reorder (Just x) = Just <$> x
reorder (x:xs) = (:) <$> x <*> (reorder xs)

My question is: does a haskell typeclass already exist to describe such operations, or do I have to invent the wheel myself?

I had a brief search in the GHC documentation, and found nothing useful for this topic.

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4 Answers 4

up vote 14 down vote accepted

Data.Traversable provides what you are looking for:

sequenceA :: (Traversable t, Applicative f) => t (f a) -> f (t a)

GHC even provides support for automatically deriving instances:

{-# LANGUAGE DeriveFunctor, DeriveFoldable, DeriveTraversable #-}
import Data.Foldable
import Data.Traversable

data List a = Nil | Cons a (List a) 
  deriving(Functor, Foldable, Traversable)
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This, of course, only works when your outer type constructor is a Traversable (not all Monads are). The bonus is that the inner one only has to be Applicative. –  Dan Burton Mar 13 '12 at 18:57
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A quick search on hoogle for (Monad m, Monad n) => m (n a) -> n (m a) showed me that there are several functions that (roughly) comply with the signature you're looking for:

  1. Data.Traversable.sequence :: (Traversable t, Monad m) => t (m a) -> m (t a);
  2. Data.Traversable.sequenceA :: Applicative f => t (f a) -> f (t a);
  3. Contro.Monad.sequence :: Monad m => [m a] -> m [a] (also exported by Prelude).

Both [a] and Maybe a are instances of traversable, so your reorder functions are just applications of Data.Traversable.sequence. One could write, in example:

ghci> (Data.Traversable.sequence $ Just (return 1)) :: IO (Maybe Int)
Just 1
it :: Maybe Int

ghci> (Data.Traversable.sequence $ Just ([1])) :: [Maybe Int]
[Just 1]
it :: [Maybe Int]

ghci> (Data.Traversable.sequence $ [Just 1]) :: Maybe [Int]
Just [1]
it :: Maybe [Int]

Please note however that the specific class declaration is class (Functor t, Foldable t) => Traversable t, and if you look also at the types of the other two functions, it does not seems like what you're looking for could possibly be done in a generic way for all monads m and n without restrictions/preconditions.

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It can't be done in general: a good example of a monad that can't do this is the reader (or function) monad. That would require the following function to be definable:

impossible :: (r -> IO a) -> IO (r -> a)

It's not straightforward to prove that a function cannot be implemented. But intuitively, the problem is that whatever IO has to be done in the value returned has to be done before we know what the r parameter is. So impossible readFile would have to yield a pure function FilePath -> String before it knew which files to open. Clearly, at least, impossible can't do what you'd want it to.

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Not all Monads can commute in that way. Edward Kmett's distributive package provides a typeclass Distributive for type constructors that is similar to what you desire (simplified):

class Functor g => Distributive g where
  distribute  :: Functor f => f (g a) -> g (f a)
  collect     :: Functor f => (a -> g b) -> f a -> g (f b)

Default definitions are provided for distribute and collect, written in terms of each other. I found this package by searching hayoo for the desired type signature.

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