While thinking about how to generalize monads, I came up with the following property of a functor F:

```
inject :: (a -> F b) -> F(a -> b)
```

-- which should be a natural transformation in both a and b.

In absence of a better name, I call the functor F **bindable** if there exists a natural transformation `inject`

shown above.

The main question is, whether this property is already known and has a name, and how is it related to other well-known properties of functors (such as, being applicative, monadic, pointed, traversable, etc.)

The motivation for the name "bindable" comes from the following consideration: Suppose M is a monad and F is a "bindable" functor. Then one has the following natural morphism:

```
fbind :: M a -> (a -> F(M b)) -> F(M b)
```

This is similar to the monadic "bind",

```
bind :: M a -> (a -> M b) -> M b
```

except the result is decorated with the functor F.

The idea behind `fbind`

was that a generalized monadic operation can produce not just a single result M b but a "functor-ful" F of such results. I want to express the situation when a monadic operation yields several "strands of computation" rather than just one; each "strand of computation" being again a monadic computation.

Note that every functor F has the morphism

```
eject :: F(a -> b) -> a -> F b
```

which is converse to "inject". But not every functor F has "inject".

Examples of functors that have "inject": `F t = (t,t,t)`

or `F t = c -> (t,t)`

where c is a constant type. Functors `F t = c`

(constant functor) or `F t = (c,t)`

are not "bindable" (i.e. do not have "inject"). The continuation functor `F t = (t -> r) -> r`

also does not seem to have `inject`

.

The existence of "inject" can be formulated in a different way. Consider the "reader" functor `R t = c -> t`

where c is a constant type. (This functor is applicative and monadic, but that's beside the point.) The "inject" property then means `R (F t) -> F (R t)`

, in other words, that R commutes with F. Note that this is not the same as the requirement that F be traversable; that would have been `F (R t) -> R (F t)`

, which is always satisfied for any functor F with respect to R.

So far, I was able to show that "inject" implies "fbind" for any monad M.

In addition, I showed that every functor F that has "inject" will also have these additional properties:

- it is pointed

`point :: t -> F t`

if F is "bindable" and applicative then F is also a monad

if F and G are "bindable" then so is the pair functor F * G (but not F + G)

if F is "bindable" and A is any profunctor then the (pro)functor

`G t = A t -> F t`

is bindablethe identity functor is bindable.

Open questions:

is the property of being "bindable" equivalent to some other well-known properties, or is it a new property of a functor that is not usually considered?

are there any other properties of the functor "F" that follow from the existence of "inject"?

do we need any laws for "inject", would that be useful? For instance, we could require that R (F t) be isomorphic to F (R t) in one or both directions.

`F (a->b) -> a -> F b`

holds for any functor F, not only for traversable.`inject id :: IO (IO a -> a)`

. That would be very dangerous, effectively providing access to`unsafePerformIO`

in pure code with the mild requirement that eventually this is being called from IO (which always happens, since we start from`main`

). Basically we only have to do`main = do upIO <- inject id ; print (pureF upIO 12) ; ...`

to allow the purely typed`pureF`

to run side-effects. Scary.`Identity`

and`(->) a`

. So I suspect it'smuchstronger than`Monad`

.`Distributive f`

gets you`distribute :: Functor g => g (f a) -> f (g a)`

, which from a Haskell type standpoint is more powerful than your function. I don't know if it satisfies your category-theoretic laws. Every`Representable`

functor is distributive, and the documentation says the other way round holds mathematically.32more comments