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I am currently writing a project where I make a heavy use of ListT monad transformer. When using plain lists, implementing nondeterminism is very easy. However once I had to convert my code to ListT, it got much more complicated 1.

As a simple example: converting from [a] to ListT a actually requires composing two functions:

conv :: (Monad m) => [a] -> ListT m a
conv = ListT . return

Though it's simple, I am surprised it's not already there.

Questions:

  • Is there some better way to handle nondeterminism where a monad transformer is needed?
  • Are there any techniques / libraries for converting cleanly back and forth between lists and ListT?

1 The exact reasons are quite complicated, so I don't really want to elaborate too much on that.

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2 Answers

up vote 6 down vote accepted

I don't think there are any libraries for this; conv is an incredibly simple function, after all, and the other way around is just runListT.

conv is similar to the liftMaybe often desired when using MaybeT:

liftMaybe :: (Monad m) => Maybe a -> MaybeT m a
liftMaybe = MaybeT . return

I would recommend naming it something along the lines of liftList.1

As far as a better monad transformer for nondeterminism goes, I recommend taking a look at the logict package, based on Oleg's LogicT transformer, which is a continuation-based backtracking logic monad with some helpful operations. As a bonus, since [] is an instance of MonadLogic, those operations also work on lists.


1 Interestingly, we can define a function that generalises the pattern of conv and liftMaybe:

import Data.Foldable (Foldable)
import qualified Data.Foldable as F

choose :: (Foldable t, MonadPlus m) => t a -> m a
choose = F.foldr (\a b -> return a `mplus` b) mzero

This will probably make your code quite confusing, so I don't recommend using it :)

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Yes, I agree that conv is a simple function. I'm just surprised that it's not already there. There are hardly any utilities in the ListT module which makes me feel like I reinvent the wheel. That's all. –  julkiewicz Feb 9 '12 at 16:41
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I just came across this question a few months later because I was wondering something similar to this. So I came up with the following:

{-# LANGUAGE MultiParamTypeClasses, FunctionalDependencies #-}

import Control.Monad.Trans.Class
import Control.Monad.Trans.Maybe
import Control.Monad.Trans.List


-- | Minimal implementation: either joinLift or joinT
class (MonadTrans t, Monad m) => MonadTransJoin t m | m -> t, t -> m where
    joinLift :: (Monad m', Monad (t m')) => m' (m a) -> t m' a
    joinLift = joinT . lift

    joinT :: (Monad m', Monad (t m')) => t m' (m a) -> t m' a
    joinT = (>>= (joinLift . return))


instance MonadTransJoin MaybeT Maybe where
    joinLift = MaybeT
    joinT = (>>= maybe mzero return)

instance MonadTransJoin ListT [] where
    joinLift = ListT
    joinT = (>>= foldr mcons mzero)
        where mcons x xs = return x `mplus` xs

So far so good—and my joinT method for the ListT/[] pair looks like it has something to do with ehird's choose.

But the problem with this is that there is actually no uniform interface between a monad transformer and the monad whose behavior it endows to its base monad. We have MaybeT :: m (Maybe a) -> MaybeT m a and ListT :: m [a] -> ListT m a, but OTOH we have StateT :: (s -> m (a, s)) -> StateT s m a. I don't know if there's a way to get around this—it certaindly requires

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