If you want to use the underlying monad in a monad transformer, you can use `lift`

:

```
lift :: (MonadTrans t, Monad m) => m a -> t m a
```

In this case, `t`

is `StateT MyState`

, and `m`

is `MyMonad`

. So, for example:

```
foo :: StateT MyState MyMonad MyType
foo = do
modify $ \s -> s+1
lift $ doSomethingInMyMonad 42
```

Monad transformers aren't "layered on" in the sense that you'd return a value of type `MyMonad MyType`

from inside; it's a more literal *transformation:* they turn a monad into a new one that has the ability to run actions in the transformed monad. So, you can think of `StateT s m`

as just the regular `State s`

monad, except that you can also use `lift`

to run turn actions in `m`

into actions in `StateT s m`

.

If you're using the standard Monad Transformer Library (mtl) transformers like `StateT`

, `ReaderT`

, etc., you don't actually have to use `lift`

; things like `modify`

and `ask`

work in *any* monad with the right transformer somewhere in the stack. (A stack is just a tower of transformed monads, like `StateT s (ReaderT r IO)`

.)

Additionally, if you have a large stack with `IO`

at the bottom, there's a convenience function for lifting an `IO`

action up any number of layers:

```
liftIO :: (MonadIO m) => IO a -> m a
```

So `liftIO (putStrLn "Hello, world!")`

works in `IO`

, `StateT Int IO`

, `ContT r (WriterT [String] IO)`

, and so on.

(As an additional note, `foo`

here isn't actually a function; a more accurate term is *action* or *computation*.)