The type is trivially inhabited for any `Applicative`

:

```
{-# LANGUAGE RankNTypes #-}
import Control.Applicative
import Control.Monad
import Data.Functor.Identity
import qualified Data.Traversable as T
f' :: (Applicative f) => f [f a] -> f [a]
f' = const $ pure []
```

which is clearly not what you intended. So let's ask for inhabitation of

```
(Traversable t) => Behavior u (t (Behavior u a)) -> Behavior u (t a)
```

or more generally for which applicatives we can construct

```
(T.Traversable t) => f (t (f a)) -> f (t a)
```

This is inhabited for any `f`

that is also a monad:

```
f :: (Monad m, T.Traversable t) => m (t (m a)) -> m (t a)
f = join . liftM T.sequence
```

An obvious question arises: If an applicative has such an `f`

, does it have to be a monad? The answer is *yes*. We just apply `f`

to the `Identity`

traversable (one-element collection - the `Traversable`

instance of `Identity`

) and construct `join`

as

```
g :: (Applicative m) => (forall t . (T.Traversable t) => m (t (m a)) -> m (t a))
-> (m (m a) -> m a)
g f = fmap runIdentity . f . fmap Identity
```

So our function is inhabited precisely for those applicatives that are also monads.

To conclude: **The function you're seeking would exist if and only if **`Behavior`

were a `Monad`

. And because it is not, most likely there is no such function. (I believe that if there were a way how to make it a monad, it'd be included in the library.)

`Behavior a`

is`Time -> a`

such that`Behavior [Behavior a]`

is`Time -> [Time -> a]`

while`Behavior [a]`

is`Time -> [a]`

. Are you looking for something like`fix :: Behavior [Behavior a] -> Behavior [a]; fix as t = map ($ t) (as t)`

? – J. Abrahamson Jan 2 '14 at 5:48Highlysuggest playing around with Software Foundations or Certified Programming with Dependent Types if that stuff interests you. – J. Abrahamson Jan 2 '14 at 5:56