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# Haskell function from (a -> [b]) -> [a -> b]

I have a function `seperateFuncs` such that

``````seperateFuncs :: [a -> b] -> (a -> [b])
seperateFuncs xs = \x -> map (\$ x) xs
``````

I was wondering whether the converse existed, i.e. is there a function

``````joinFuncs :: (a -> [b]) -> [a -> b]
``````

I think not (mainly because lists are not fixed length), but perhaps I'll be proved wrong. The question then is there some datatype `f` which has a function :: (a -> f b) -> f (a -> b)?

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Other than the trivial solution, I guess. – Don Stewart Dec 7 '12 at 14:55
There is such a function for infinite lists, and for tuples of known length. Basically, i-th element of the output is the i-th projection of the input. – n.m. Dec 7 '12 at 15:01
A different explanation might come from `Applicative f => Monad f`: every `f (a -> b)` can be turned into a `(a -> f b)`, but not necessarily the other way around (moreover, you can implement `(<*>) :: f (a -> b) -> (f a -> f b)` in terms of `(=<<) :: (a -> f b) -> (f a -> f b)`, but not always the other way around). Not sure about this, though. – Rhymoid Dec 7 '12 at 15:40

You can generalize `seperateFuncs` to `Applicative` (or `Monad`) pretty cleanly:

``````seperateFuncs :: (Applicative f) => f (a -> b) -> (a -> f b)
seperateFuncs f x = f <*> pure x
``````

Written in point-free style, you have `seperateFuncs = ((. pure) . (<*>))`, so you basically want `unap . (. extract)`, giving the following definition if you write it in pointful style:

``````joinFuncs :: (Unapplicative f) => (a -> f b) -> f (a -> b)
joinFuncs f = unap f (\ g -> f (extract g))
``````

Here I define `Unapplictaive` as:

``````class Functor f => Unapplicactive f where
extract  :: f a -> a
unap     :: (f a -> f b) -> f (a -> b)
``````

To get the definitions given by leftaroundabout, you could give the following instances:

``````instance Unapplicative [] where
unap f = [\a -> f [a] !! i | i <- [0..]]

instance Unapplicative ((->) c) where
extract f = f undefined
unap f = \x y -> f (const y) x
``````

I think it's hard to come up with a "useful" function `f :: (f a -> f b) -> f (a -> b)` for any `f` that isn't like `(->)`.

-
By the way, in the same gist as Matt Fenwick's answer: you could see `coap` as an instance of `g (f a) (f b) -> f (g a b)`, so kinda like `sequenceA`, you are "transposing" a functor (`f`) and a bifunctor (`(->)`). – Rhymoid Dec 7 '12 at 18:41

First of all, you can brute-force yourself this function all right:

``````joinFuncs f = [\x -> f x !! i | i<-[0..]]
``````

but this is obviously troublesome – the resulting list is always infinite but evaluating the `i`th element with `x` only succeds if `length(f x) > i`.

To give a "real" solution to

The question then is there some datatype `f` which has a function `:: (a -> f b) -> f (a -> b)`?

Consider `(->)c`. With that, your signature reads `(a -> (c->b)) -> (c->(a->b))` or equivalently `(a -> c -> b) -> c -> a -> b` which, it turns out, is just `flip`.

Of course, this is a bit of a trivial one since `seperateFuncs` has the same signature for this type...

-

"Is there some datatype f which has a function :: (a -> f b) -> f (a -> b)?"

In fact, there is an even more general version of this function in the Traversable type class, which deals with commutable functors:

``````class (Functor t, Foldable t) => Traversable t where

...

sequenceA :: Applicative f => t (f b) -> f (t b)
``````

How is this related to your function? Starting from your type, with one type substitution, we recover `sequenceA`:

1. `(a -> f b) -> f (a -> b)` ==> `let t = (->) a`
2. `t (f b) -> f (t b)`

However, this type has the constraint that `t` must be a Traversable -- and there isn't a Traversable instance for `(->) a`, which means that this operation can't be done in general with functions. Although note that the "other direction" -- `f (a -> b) -> (a -> f b)` works fine for all functions and all Applicatives `f`.

-

I have recently had to think quite a bit about problems that reduce to a question very similar to yours. Here's the generalizations that I found.

First, it is trivial to do this (at Tinctorius pointed out):

``````f2m :: Functor f => f (a -> b) -> a -> f b
f2m f a = fmap (\$a) f
``````

But it is impossible to do this in general:

``````m2a :: Monad m => (a -> m b) -> m (a -> b)
``````

One insightful way of understanding this, which somebody kindly explained to me in the #haskell irc channel, is that if there existed an `m2a` function, there would be no difference between `Applicative` and `Monad`. Why? Well, I don't follow it 100%, but it's something like this: `Monad m => a -> m b` is the very common type of monadic actions with one parameter, while `Applicative f => f (a -> b)` is the also very common type of what, for not knowing the proper name, I'll call "applicable applicatives." And the fact that `Monad` can do things that `Applicative` cannot is tied to the fact that `m2a` cannot exist.

So now, applied to your question:

``````joinFuncs :: (a -> [b]) -> [a -> b]
``````

I suspect the same "Monad /= Applicative" argument (which, again, let me stress, I don't fully understand) should apply here. We know that the `Monad []` instance can do things that the `Applicative []` instance cannot. If you could write a `joinFuncs` with the specified type, then the `[a -> b]` result must in some sense "lose information" compared to the `a -> [b]` argument, because otherwise `Applicative []` is the same as `Monad []`. (And by "lose" information I mean that any function with `joinFuncs`'s type cannot have an inverse, and thus it is guaranteed to obliterate the distinction between some pair of functions `f, g :: a -> [b]`. The extreme case of that is `joinFuncs = undefined`.)

I did find that I needed functions similar to `m2a` So the special case that I found is that it's possible to do this:

``````import Data.Map (Map)
import qualified Data.Map as Map

-- | Enumerate a monadic action within the domain enumerated by the
-- argument list.
boundedM2a :: Monad m => (a -> m b) -> [a] -> m [(a,b)]
boundedM2a f = mapM f'
where f' a = do b <- f a
return (a, b)

-- | The variant that makes a 'Map' is rather useful.
boundedM2a' :: (Monad m, Ord a) => (a -> m b) -> [a] -> m (Map a b)
boundedM2a' f = liftM Map.fromList . boundedM2a f
``````

Note that in addition to the requirement that we enumerate the `a`s, an interesting observation is that to do this we have to "materialize" the result in a sense; turn it from a function/action into a list, map or table of some sort.

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– Matt Fenwick Dec 7 '12 at 19:47