I don't think that definition for `SbT`

is what you want. That defines *functor composition*, and assuming the `m`

parameter is a `Functor`

or `Applicative`

, this should preserve those properties. But composition like that does not, in general, create a new monad out of two others. See this question for more on that subject.

So, how *do* you create the monad transformer you want, then? While monads don't compose directly, monad *transformers* can be composed. So to build a new transformer out of existing ones, you essentially just want to give a name to that composition. This differs from the `newtype`

you have because there you're applying the `m`

directly, instead of passing it in to the transformer stack.

One thing to keep in mind about defining monad transformers is that they necessarily work "backwards" in certain ways--when you apply a composite transformer to a monad, the "innermost" transformer gets the first crack at it, and the transformed monad it produces is what the next transformer out gets to work with, &c. Note that this isn't any different from the order you get when applying a composed function to an argument, e.g. `(f . g . h) x`

gives the argument to `h`

first, even though `f`

is the "first" function in the composition.

Okay, so your composite transformer needs to take the monad it's applied to and pass it to the innermost transformer, which is, uhm.... oops, turns out that `SB`

is *already* applied to a monad. No wonder this wasn't working. We'll need to remove that, first. Where is it? Not `State`

--we *could* remove that, but we don't want to, because it's part of what you want. Hmm, but wait--what is `State`

defined as, again? Oh yeah:

```
type State s = StateT s Identity
```

Aha, there we go. Let's get that `Identity`

out of there. We go from your current definition:

```
type SB i a = ReaderT ( AlgRO i ) (State ( AlgState i ) ) a
```

To the equivalent form:

```
type SB i a = ReaderT ( AlgRO i ) ( StateT ( AlgState i ) Identity ) a
```

Then we kick the lazy bum out:

```
type SB' i m a = ReaderT ( AlgRO i ) ( StateT ( AlgState i ) m ) a
type SB i a = SB' i Identity a
```

But now `SB'`

looks suspiciously like a monad transformer definition, and with good reason, because it is. So we recreate the `newtype`

wrapper, and toss a few instances out there:

```
newtype SbT i m a = SbT { getSB :: ReaderT ( AlgRO i ) ( StateT ( AlgState i ) m ) a }
instance (Functor m) => Functor (SbT i m) where
fmap f (SbT sb) = SbT (fmap f sb)
instance (Monad m) => Monad (SbT i m) where
return x = SbT (return x)
SbT m >>= k = SbT (m >>= (getSB . k))
instance MonadTrans (SbT i) where
lift = SbT . lift . lift
runSbT :: SbT i m a -> AlgRO i -> AlgState i -> m (a, AlgState t)
runSbT (SbT m) e s = runStateT (runReaderT m e) s
```

A couple things to take note of: The `runSbT`

function here is not the field accessor, but rather a composed "run" function for each transformer in the stack that we know of. Similarly, the `lift`

function has to lift once for the two inner transformers, then add the final `newtype`

wrapper. Both of these make it work as a single monad transformer, hiding the fact that it's actually a composite.

If you'd like, it should be straightforward to write instances for `MonadReader`

and `MonadState`

as well, by lifting the instances for the composed transformers.