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.

`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