There is a lot of talk about `Applicative`

*not* needing its own transformer class, like this:

```
class AppTrans t where
liftA :: Applicative f => f a -> t f a
```

But I can define applicative transformers that don't seem to be compositions of applicatives! For example *sideeffectful streams*:

```
data MStream f a = MStream (f (a, MStream f a))
```

Lifting just performs the side effect at every step:

```
instance AppTrans MStream where
liftA action = MStream $ (,) <$> action <*> pure (liftA action)
```

And if `f`

is an applicative, then `MStream f`

is as well:

```
instance Functor f => Functor (MStream f) where
fmap fun (MStream stream) = MStream $ (\(a, as) -> (fun a, fmap fun as)) <$> stream
instance Applicative f => Applicative (MStream f) where
pure = liftA . pure
MStream fstream <*> MStream astream = MStream
$ (\(f, fs) (a, as) -> (f a, fs <*> as)) <$> fstream <*> astream
```

I know that for any practical purposes, `f`

should be a monad:

```
joinS :: Monad m => MStream m a -> m [a]
joinS (MStream stream) = do
(a, as) <- stream
aslist <- joinS as
return $ a : aslist
```

But while there is a `Monad`

instance for `MStream m`

, it's inefficient. (Or even incorrect?) The `Applicative`

instance is actually useful!

Now note that usual streams arise as special cases for the identity functor:

```
import Data.Functor.Identity
type Stream a = MStream Identity a
```

But the composition of `Stream`

and `f`

is not `MStream f`

! Rather, `Compose Stream f a`

is isomorphic to `Stream (f a)`

.

*I'd like to know whether MStream is a composition of any two applicatives.*

Edit:

I'd like to offer a category theoretic viewpoint. A transformer is a "nice" endofunctor `t`

on the category `C`

of applicative functors (i.e. lax monoidal functors with strength), together with a natural transformation `liftA`

from the identity on `C`

to `t`

. The more general question is now what useful transformers exist that are not of the form "compose with `g`

" (where `g`

is an applicative). My claim is that `MStream`

is one of them.