In even more general, what you're trying to do is apply a transformation to an inner layer of a transformer stack. For two arbitrary monads, the type signature might look something like this:

```
fmapMT :: (MonadTrans t, Monad m1, Monad m2) => (m1 a -> m2 a) -> t m1 a -> t m2 a
```

Basically a higher-level `fmap`

. In fact, it would probably make even more sense to combine it with a map over the final parameter as well:

```
fmapMT :: (MonadTrans t, Monad m1, Monad m2) => (m1 a -> m2 b) -> t m1 a -> t m2 b
```

Clearly this isn't going to be possible in all cases, though when the "source" monad is `Identity`

it's likely to be easier, but I can imagine defining another type class for the places it does work. I don't think there's anything like this in the typical monad transformer libraries; however, some browsing on hackage turns up something very similar in the `Monatron`

package:

```
class MonadT t => FMonadT t where
tmap' :: FunctorD m -> FunctorD n -> (a -> b)
-> (forall x. m x -> n x) -> t m a -> t n b
tmap :: (FMonadT t, Functor m, Functor n) => (forall b. m b -> n b)
-> t m a -> t n a
tmap = tmap' functor functor id
```

In the signature for `tmap'`

, the `FunctorD`

types are basically ad-hoc implementations of `fmap`

instead of using `Functor`

instances directly.

Also, for two Functor-like type constructors F and G, a function with a type like `(forall a. F a -> G a)`

describes a natural transformation from F to G. There's quite possibly another implementation of the transformer map that you want somewhere in the `category-extras`

package but I'm not sure what the category-theoretic version of a monad transformer would be so I don't know what it might be called.

Since `tmap`

requires only a `Functor`

instance (which any `Monad`

must have) and a natural transformation, and any `Monad`

has a natural transformation from the `Identity`

monad provided by `return`

, the function you want can be written generically for any instance of `FMonadT`

as `tmap (return . runIdentity)`

--assuming the "basic" monad is defined as a synonym for the transformer applied to `Identity`

, at any rate, which is generally the case with transformer libraries.

Getting back to your specific example, note that Monatron does indeed have an instance of `FMonadT`

for `StateT`

.

`g :: StateT [Int] IO Int`

should stand.