First, let's start with a simple problem. Let's say, we need to get a sum of two integers, each wrapped in both `Future`

and `Option`

. Let's take `cats`

library in order to resemble Haskell’s standard library definitions with Scala-syntax.

If we use monad approach (aka `flatMap`

), we need:

- both
`Future`

and `Option`

should have `Monad`

instances defined over them
- we also need monadic transformer
`OptionT`

which will work only for `Option`

(precisely `F[Option[T]]`

)

So, here is the code (let's forget about for-comprehension and lifting to make it simpler):

```
val fa = OptionT[Future, Int](Future(Some(1)))
val fb = OptionT[Future, Int](Future(Some(2)))
fa.flatMap(a => fb.map(b => a + b)) //note that a and b are already Int's not Future's
```

if you look at `OptionT.flatMap`

sources:

```
def flatMap[B](f: A => OptionT[F, B])(implicit F: Monad[F]): OptionT[F, B] =
flatMapF(a => f(a).value)
def flatMapF[B](f: A => F[Option[B]])(implicit F: Monad[F]): OptionT[F, B] =
OptionT(F.flatMap(value)(_.fold(F.pure[Option[B]](None))(f)))
```

You'll notice that the code is pretty specific to `Option`

's internal logic and structure (`fold`

, `None`

). Same problem for `EitherT`

, `StateT`

etc.

Important thing here is that there is no `FutureT`

defined in cats, so you can compose `Future[Option[T]]`

, but can't do that with `Option[Future[T]]`

(later I'll show that this problem is even more generic).

On the other hand, if you choose composition using `Applicative`

, you'll have to meet only one requirement:

- both
`Future`

and `Option`

should have `Applicative`

instances defined over them

You don't need any special transformers for `Option`

, basically cats library provides `Nested`

class that works for any `Applicative`

(let's forget about applicative builder's sugar to simplify understanding):

```
val fa = Nested[Future, Option, Int](Future(Some(1)))
val fb = Nested[Future, Option, Int](Future(Some(1)))
fa.map(x => (y: Int) => y + x).ap(fb)
```

Let's swap Option and Future:

```
val fa = Nested[Option, Future, Int](Some(Future(1)))
val fb = Nested[Option, Future, Int](Some(Future(1)))
fa.map(x => (y: Int) => y + x).ap(fb)
```

Works!

So yes Monad is Applicative, `Option[Future[T]]`

is still a monad (on `Future[T]`

but not on `T`

itself) but it allows you to operate only with `Future[T]`

not `T`

. In order to "merge" `Option`

with `Future`

layers - you have to define monadic transformer `FutureT`

, in order to merge `Future`

with `Option`

- you have to define `OptionT`

. And, `OptionT`

is defined in cats/scalaz, but not `FutureT`

.

In general (from here):

Unfortunately, our real goal, composition of monads, is rather more
difficult. .. In fact, we can actually prove that, in a certain sense,
there is no way to construct a join function with the type above using
only the operations of the two monads (see the appendix for an outline
of the proof). It follows that the only way that we might hope to form
a composition is if there are some additional constructions linking
the two component

And this composition is not even necessary commutative (swappable) as I demonstrated for `Option`

and `Future`

.

As an exercise, you can try to define `FutureT`

's flatMap:

```
def flatMapF[B](f: A => F[Future[B]])(implicit F: Monad[F]): FutureT[F, B] =
FutureT(F.flatMap(value){ x: Future[A] =>
val r: Future[F[Future[B]] = x.map(f)
//you have to return F[Future[B]] here using only f and F.pure,
//where F can be List, Option whatever
})
```

basically the problem with such implementation is that you have to "extract" value from r which is impossible here, assuming you can't extract value from `Future`

(there is no comonad defined on it) at least in a "non-blocking" context (like ScalaJs). This basically means that you can't "swap" `Future`

and `F`

, like `Future[F[Future[B]] => F[Future[Future[B]`

. The latter is a natural transformation (morphism between functors), so that explains the first comment on this general answer:

you can compose monads if you can provide a natural transformation swap : N M a -> M N a

`Applicative`

s however don't have such problems - you can easily compose them, but keep in mind that result of composition of two `Applicatives`

may not be a monad (but will always be an applicative). `Nested[Future, Option, T]`

is not a monad on `T`

, regardless that both `Option`

and `Future`

are monads on `T`

. Putting in simple words Nested as a class doesn't have `flatMap`

.

It would be also helpful to read:

Putting it all together (`F`

and `G`

are monads)

`F[G[T]]`

is a monad on `G[T]`

, but not on `T`

`G_TRANSFORMER[F, T]`

required in order to get a monad on `T`

from `F[G[T]]`

.
- there is no
`MEGA_TRANSFORMER[G, F, T]`

as such transformer can't be build on top of monad - it requires additional operations defined on `G`

(it seems like comonad on `G`

should be enough)
- every monad (including
`G`

and `F`

) is applicative, but not every applicative is a monad
- in theory
`F[G[T]]`

is an applicative over both `G[T]`

and `T`

. However scala requires to create `NESTED[F, G, T]`

in order to get composed applicative on `T`

(which is implemented in cats library).
`NESTED[F, G, T]`

is applicative, but not a monad

That means you can compose `Future x Option`

(aka `Option[Future[T]]`

) to one single monad (coz `OptionT`

exists), but you can't compose `Option x Future`

(aka `Future[Option[T]]`

) without knowing that Future is something else besides being a monad (even though they’re inherently applicative functors - applicative is not enough to neither build a monad nor monad transformer on it) . Basically:

`OptionT`

can be seen as non-commutative binary operator defined as `OptionT: Monad[Option] x Monad[F] -> OptionT[F, T]; for all Monad[F], T; for some F[T]`

. Or in general: `Merge: Monad[G] x Monad[F] -> Monad[Merge]; for all T, Monad[F]; but only for **some of Monad[G]**, some F[T], G[T]`

;

you can compose any two applicatives into one single applicative `Nested: Applicative[F] x Applicative[G] -> Nested[F, G]; for all Applicative[F], Applicative[G], T; for some F[T], G[T]`

,

but you can compose any two monads (inherently functors) only into one *applicative* (but not into monad).

doesn't contain a single line of Haskell. – ziggystar Oct 16 '15 at 7:39codedemonstrating the problem, not for an abstract answer. And he asked forscalacode. That's a reasonable thing to ask. It's often easier to understand something with a concrete example, and only then can you really generalize this knowledge. – Régis Jean-Gilles Oct 19 '15 at 9:05