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When use Data.Traversable I frequently requires some code like

import Control.Applicative (Applicative,(<*>),pure)
import Data.Traversable (Traversable,traverse,sequenceA)
import Control.Monad.State (state,runState)

traverseF :: Traversable t => ((a,s) -> (b,s)) -> (t a, s) -> (t b, s)
traverseF f (t,s) = runState (traverse (state.curry f) t) s

to traverse the structure and build up a new one driven by some state. And I notice the type signature pattern and believe it could be able to generalized as

fmapInner :: (Applicative f,Traversable t) => (f a -> f b) -> f (t a) -> f (t b)
fmapInner f t = ???

But I fail to implement this with just traverse, sequenceA, fmap, <*> and pure. Maybe I need stronger type class constrain? Do I absolutely need a Monad here?

UPDATE

Specifically, I want to know if I can define fmapInner for a f that work for any Traversable t and some laws for intuition applied (I don't know what the laws should be yet), is it imply that the f thing is a Monad? Since, for Monads the implementation is trivial:

--Monad m implies Applicative m but we still 
--  have to say it unless we use mapM instead
fmapInner :: (Monad m,Traversable t) => (m a -> m b) -> m (t a) -> m (t b)
fmapInner f t = t >>= Data.Traversable.mapM (\a -> f (return a))

UPDATE

Thanks for the excellent answer. I have found that my traverseF is just

import Data.Traversable (mapAccumL)
traverseF1 :: Traversable t => ((a, b) -> (a, c)) -> (a, t b) -> (a, t c)
traverseF1 =uncurry.mapAccumL.curry

without using Monad.State explicitly and have all pairs flipped. Previously I though it was mapAccumR but it is actually mapAccumL that works like traverseF.

share|improve this question
    
The type you're asking for in fmapInner looks substantially different from the type of traverseF to me. Perhaps you would prefer foo :: (a -> f b) -> (t a -> f (t b)) or some such thing, in which case it's just traverse. Then f can specialize to State s and give you essentially the type of traverseF. –  Daniel Wagner Oct 11 '13 at 0:39
    
On rereading, I've just convinced myself that I don't really understand what you're asking for. So feel free to ignore my previous comment, but I'll leave it for posterity anyway. –  Daniel Wagner Oct 11 '13 at 0:42
    
I see what you mean, and I see the thing you have just pointed out. I already know that I can write the function like yours; However, in my opinion it looks natural to define a reusable function f a -> f b and then use it to convert a f (t a) into f (t b), and it looks like there is no good way to do so unless I assume f is a Monad. –  Earth Engine Oct 11 '13 at 0:55
    
What do you imagine the Applicative instance for ((,) s) is (we have to put s first since we don't have flip defined for types)? –  Cirdec Oct 11 '13 at 1:03
    
I am not saying ((,) s) is currently an instance of Applicative, but if you want we can define a newtype to instantiate it. The point is about the type signature pattern, not the specific types. –  Earth Engine Oct 11 '13 at 1:12

1 Answer 1

up vote 2 down vote accepted

I've now convinced myself that this is impossible. Here's why,

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

So we have this side-effecting computation that returns t a and we want to use this to determine what side effects happen. In other words, the value of type t a will determine what side effects happen when we apply traverse.

However this isn't possible possible with the applicative type class. We can dynamically choose values, but the side effects of out computations are static. To see what I mean,

pure :: a -> f a -- No side effects
(<*>) :: f (a -> b) -> f a -> f b -- The side effects of `f a` can't
                                  -- decide based on `f (a -> b)`.

Now there are two conceivable ways to determine side effects at depending on previous values,

smash :: f (f a) -> f a

Because then we can simply do

smash $ (f :: a -> f a) <$> (fa :: f a) :: f a

Now your function becomes

traverseF f t = smash $ traverse (f . pure) <$> t

Or we can have

bind :: m a -> (a -> m b) -> m b -- and it's obvious how `a -> m b`
                                 -- can choose side effects.

and

traverseF f t = bind t (traverse $ f . pure)

But these are join and >>= respectively and are members of the Monad typeclass. So yes, you need a monad. :(

Also, a nice, pointfree implementation of your function with monad constraints is

traverseM = (=<<) . mapM . (.return)

Edit,

I suppose it's worth noting that

traverseF :: (Applicative f,Traversable t) => (f a -> f b) -> t a -> f (t a)
traverseF = traverse . (.pure)
share|improve this answer
    
I have tried to follow your comments on pure, <*> and bind, but I don't think I understand them well. Can you gives more explain them a bit more? –  Earth Engine Oct 13 '13 at 6:33

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