Will this do?

```
flip . (evalState .) . traverse . traverse . const . state $ head &&& tail
```

EDIT: let me expand on the construction...

The essential centre of it is `traverse . traverse`

. If you stare at the problem with sufficiently poor spectacles, you can see that it's "do something with the elements of a container of containers". For that sort of thing, `traverse`

(from `Data.Traversable`

) is a very useful gadget (ok, I'm biased).

```
traverse :: (Traversable f, Applicative a) => (s -> a t) -> f s -> a (f t)
```

or, if I change to longer but more suggestive type variables

```
traverse :: (Traversable containerOf, Applicative doingSomethingToGet) =>
(s -> doingSomethingToGet t) ->
containerOf s -> doingSomethingToGet (containerOf t)
```

Crucially, `traverse`

preserves the structure of the container it operates on, whatever that might be. If you view `traverse`

as a higher-order function, you can see that it gives back an operator on containers whose type fits with the type of operators on elements it demands. That's to say `(traverse . traverse)`

makes sense, and gives you structure-preserving operations on *two* layers of container.

```
traverse . traverse ::
(Traversable g, Traversable f, Applicative a) => (s -> a t) -> g (f s) -> a (g (f t))
```

So we've got the key gadget for structure-preserving "do something" operations on lists of lists. The `length`

and `splitAt`

approach works fine for lists (the structure of a list is given by its length), but the essential characteristic of lists which enables that approach is already pretty much bottled by the `Traversable`

class.

Now we need to figure out how to "do something". We want to replace the old elements with new things drawn successively from a supply stream. If we were allowed the side-effect of updating the supply, we could say what to do at each element: "return `head`

of supply, updating supply with its `tail`

". The `State s`

monad (in `Control.Monad.State`

which is an instance of `Applicative`

, from `Control.Applicative`

) lets us capture that idea. The type `State s a`

represents computations which deliver a value of type `a`

whilst mutating a state of type `s`

. Typical such computations are made by this gadget.

```
state :: (s -> (a, s)) -> State s a
```

That's to say, given an initial state, just compute the value and the new state. In our case, `s`

is a stream, `head`

gets the value, `tail`

gets the new state. The `&&&`

operator (from `Control.Arrow`

) is a nice way to glue two functions on the same data to get a function making a pair. So

```
head &&& tail :: [x] -> (x, [x])
```

which makes

```
state $ head &&& tail :: State [x] x
```

and thus

```
const . state $ head &&& tail :: u -> State [x] x
```

explains what to "do" with each element of the old container, namely ignore it and take a new element from the head of the supply stream.

Feeding that into `(traverse . traverse)`

gives us a big mutatey traversal of type

```
f (g u) -> State [x] (f (g x))
```

where `f`

and `g`

are any `Traversable`

structures (e.g. lists).

Now, to extract the function we want, taking the initial supply stream, we need to unpack the state-mutating computation as a function from initial state to final value. That's what this does:

```
evalState :: State s a -> s -> a
```

So we end up with something in

```
f (g u) -> [x] -> f (g x)
```

which had better get flipped if it's to match the original spec.

**tl;dr** The `State [x]`

monad is a readymade tool for describing computations which read and update an input stream. The `Traversable`

class captures a readymade notion of structure-preserving operation on containers. The rest is plumbing (and/or golf).