Yes, it is indeed impossible. Consider the following definition of `State`

:

```
newtype State s a = State { runState :: s -> (a, s) }
```

To `extract`

the value this data type we would first need to supply some state.

We can create a specialized `extract`

function if we know the type of the state. For example:

```
extract' :: State () a -> a
extract' (State f) = f ()
extractT :: State Bool a -> a
extractT (State f) = f True
extractF :: State Bool a -> a
extractF (State f) = f False
```

However, we can't create a generic extract function. For example:

```
extract :: State s a -> a
extract (State f) = f undefined
```

The above `extract`

function is generic. The only state we can supply is ⊥ which is incorrect. It is only safe if the function `f :: s -> (a, s)`

passes along its input transparently (i.e. `f = (,) a`

for some value `a`

). However, `f`

may take some state and use it to generate some value and a new state. Hence, `f`

may use its input non-transparently and if the input is ⊥ then we get an error.

Thus, we cannot create a generic `extract`

function for the `State`

data type.

Now, for a data type to be an instance of `Traversable`

it first needs to be an instance of `Foldable`

. Hence, to make `State`

an instance of `Traversable`

we first need to define the following instance:

```
instance Foldable (State s) where
foldMap f (State g) = mempty
-- or
foldMap f (State g) = let x = f (extract g) in mconcat [x]
-- or
foldMap f (State g) = let x = f (extract g) in mconcat [x,x]
-- or
foldMap f (State g) = let x = f (extract g) in mconcat [x,x,x]
-- ad infinitum
```

Note that `foldMap`

has the type `Monoid m => (a -> m) -> State s a -> m`

. Hence, the expression `foldMap f (State g)`

must return a value of the type `Monoid m => m`

. Trivially, we can always return `mempty`

by defining `foldMap = const (const mempty)`

. However, in my humble opinion this is incorrect because:

- We aren't really folding anything by always returning
`mempty`

.
- Every data type can be trivially made an instance of
`Foldable`

by always returning `mempty`

.

The only other way to produce a value of the type `Monoid m => m`

is to apply `f`

to some value `x`

of the type `a`

. However, we don't have any value of the type `a`

. If we could `extract`

the value `a`

from `State s a`

then we could apply `f`

to that value, but we already proved that it's not possibly to define a generic `extract`

function for `State s a`

that never crashes.

Thus, `State s`

cannot be made an instance of `Foldable`

and consequently it cannot be an instance of `Traversable`

.