# Is this property of a functor stronger than a monad?

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 bindable

• the 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.

• Side question: Do you have some useful piece of code which demonstrates the usefulness of this? Sep 22 '16 at 22:05
• @BenjaminHodgson I think the property `F (a->b) -> a -> F b` holds for any functor F, not only for traversable. Sep 22 '16 at 22:46
• This looks way stronger than a monad to me. From a purely practical point of view, there's no way we can construct something like `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.
– chi
Sep 23 '16 at 0:01
• Note that I asked this question: stackoverflow.com/questions/26264411/… a while ago, and as far as anyone could find, the only functors with this property are `Identity` and `(->) a`. So I suspect it's much stronger than `Monad`. Sep 23 '16 at 0:15
• `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. Sep 23 '16 at 1:28

To improve terminology a little bit, I propose to call these functors "rigid" instead of "bindable". The motivation for saying "rigid" will be explained below.

## Definition

A functor `f` is called rigid if it has the `inject` method as shown. Note that every functor has the `eject` method.

``````class (Functor f) => Rigid f where
inject :: (a -> f b) -> f(a -> b)

eject :: f(a -> b) -> a -> f b
eject fab x = fmap (\ab -> ab x) fab
``````

The law of "nondegeneracy" must hold:

``````eject . inject = id
``````

## Properties

A rigid functor is always pointed:

``````instance (Rigid f) => Pointed f where
point :: t -> f t
point x = fmap (const x) (inject id)
``````

If a rigid functor is applicative then it is automatically monadic:

``````instance (Rigid f, Applicative f) => Monad f where
bind :: f a -> (a -> f b) -> f b
bind fa afb = (inject afb) <*> fa
``````

The property of being rigid is not comparable (neither weaker nor stronger) than the property of being monadic: If a functor is rigid, it does not seem to follow that it is automatically monadic (although I don't know specific counterexamples for this case). If a functor is monadic, it does not follow that it is rigid (there are counterexamples).

Basic counterexamples of monadic functors that are not rigid are `Maybe` and `List`. These are functors that have more than one constructor: such functors cannot be rigid.

The problem with implementing `inject` for `Maybe` is that `inject` must transform a function of type `a -> Maybe b` into `Maybe(a -> b)` while `Maybe` has two constructors. A function of type `a -> Maybe b` could return different constructors for different values of `a`. However, we are supposed to construct a value of type `Maybe(a -> b)`. If for some `a` the given function produces `Nothing`, we don't have a `b` so we can't produce a total function `a->b`. Thus we cannot return `Just(a->b)`; we are forced to return `Nothing` as long as the given function produces `Nothing` even for one value of `a`. But we cannot check that a given function of type `a -> Maybe b` produces `Just(...)` for all values of `a`. Therefore we are forced to return `Nothing` in all cases. This will not satisfy the law of nondegeneracy.

So, we can implement `inject` if `f t` is a container of "fixed shape" (having only one constructor). Hence the name "rigid".

Another explanation as to why rigidity is more restrictive than monadicity is to consider the naturally defined expression

``````(inject id) :: f(f a -> a)
``````

where `id :: f a -> f a`. This shows that we can have an f-algebra `f a -> a` for any type `a`, as long as it is wrapped inside `f`. It is not true that any monad has an algebra; for example, the various "future" monads as well as the `IO` monad describe computations of type `f a` that do not allow us to extract values of type `a` - we shouldn't be able to have a method of type `f a -> a` even if wrapped inside an `f`-container. This shows that the "future" monads and the `IO` monad are not rigid.

A property that is strictly stronger than rigidity is distributivity from one of E. Kmett's packages. A functor `f` is distributive if we can interchange the order as in `p (f t) -> f (p t)` for any functor `p`. Rigidity is the same as being able to interchange the order only with respect to the "reader" functor `r t = a -> t`. So, all distributive functors are rigid.

All distributive functors are necessarily representable, which means they are equivalent to the "reader" functor `c -> t` with some fixed type `c`. However, not all rigid functors are representable. An example is the functor `g` defined by

``````type g t = (t -> r) -> t
``````

The functor `g` are not equivalent to `c -> t` with a fixed type `c`.

## Constructions and examples

Further examples of rigid functors that are not representable (i.e. not "distributive") are functors of the form `a t -> f t` where `a` is any contrafunctor and `f` is a rigid functor. Also, the Cartesian product and the composition of two rigid functors is again rigid. In this way, we can produce many examples of rigid functors within the exponential-polynomial class of functors.

My answer to What is the general case of QuickCheck's promote function? also lists the constructions of rigid functors:

1. `f = Identity`
2. if `f` and `g` are both rigid then the functor product `h t = (f t, g t)` is also rigid
3. if `f` and `g` are both rigid then the composition `h t = f (g t)` is also rigid
4. if `f` is rigid and `g` is any contravariant functor then the functor `h t = g t -> f t` is rigid

One other property of rigid functors is that the type `r ()` is equivalent to `()`, i.e. there is only one distinct value of the type `r ()`. This value is `point ()`, where `point` is defined above for any rigid functor `r`. (I have a proof but I will not write it here, because I could not find an easy one-line proof.) A consequence is that a rigid functor must have only one constructor. This immediately shows that `Maybe`, `Either`, `List` etc. cannot be rigid.

If `f` is a monad that has a monad transformer of the "composed-outside" kind, `t m a = f (m a)`, then `f` is a rigid functor.

The "rigid monads" are possibly a subset of rigid functors because construction 4 only yields a rigid monad if `f` is also a rigid monad rather than an arbitrary rigid functor (but the contravariant functor `g` can still be arbitrary). However, I do not have any examples of a rigid functor that is not also a monad.

The simplest example of a rigid monad is `type r a = (a -> p) -> a`, the "search monad". (Here `p` is a fixed type.)

To prove that a monad `f` with the "composed-outside" transformer `t m a = f (m a)` also has an `inject` method, we consider the transformer `t m a` with the foreign monad `m` chosen as the reader monad, `m a = r -> a`. Then the function `inject` with the correct type signature is defined as

`````` inject = join @t . return @r . (fmap @m (fmap @f return @m))
``````

with appropriate choices of type parameters.

The non-degeneracy law follows from the monadic naturality of `t`: the monadic morphism `m -> Identity` (substituting a value of type `r` into the reader) is lifted to the monadic morphism `t m a -> t Id a`. I omit the details of this proof.

## Use cases

Finally, I found two use cases for rigid functors.

The first use case was the original motivation for considering rigid functors: we would like to return several monadic results at once. If `m` is a monad and we want to have `fbind` as shown in the question, we need `f` to be rigid. Then we can implement `fbind` as

``````fbind :: m a -> (a -> f (m b)) -> f (m b)
fbind ma afmb = fmap (bind ma) (inject afmb)
``````

We can use `fbind` to have monadic operations that return more than one monadic result (or, more generally, a rigid functor-ful of monadic results), for any monad `m`.

The second use case grows out of the following consideration. Suppose we have a program `p :: a` that internally uses a function `f :: b -> c`. Now, we notice that the function `f` is very slow, and we would like to refactor the program by replacing `f` with a monadic "future" or "task", or generally with a Kleisli arrow `f' :: b -> m c` for some monad `m`. We, of course, expect that the program `p` will become monadic as well: `p' :: m a`. Our task is to refactor `p` into `p'`.

The refactoring proceeds in two steps: First, we refactor the program `p` so that the function `f` is explicitly an argument of `p`. Assume that this has been done, so that now we have `p = q f` where

``````q :: (b -> c) -> a
``````

Second, we replace `f` by `f'`. We now assume that `q` and `f'` are given. We would like to construct the new program `q'` of the type

``````q' :: (b -> m c) -> m a
``````

so that `p' = q' f'`. The question is whether we can define a general combinator that will refactor `q` into `q'`,

``````refactor :: ((b -> c) -> a) -> (b -> m c) -> m a
``````

It turns out that `refactor` can be constructed only if `m` is a rigid functor. In trying to implement `refactor`, we find essentially the same problem as when we tried to implement `inject` for `Maybe`: we are given a function `f' :: b -> m c` that could return different monadic effects `m c` for different `b`, but we are required to construct `m a`, which must represent the same monadic effect for all `b`. This cannot work, for instance, if `m` is a monad with more than one constructor.

If `m` is rigid (and we do not need to require that `m` be a monad), we can implement `refactor`:

``````refactor bca bmc = fmap bca (inject bmc)
``````

If `m` is not rigid, we cannot refactor arbitrary programs. So far we have seen that the continuation monad is rigid, but the "future"-like monads and the `IO` monad are not rigid. This again shows that rigidity is, in a sense, a stronger property than monadicity.

• The functor `W r` defined as `type W r t = (t->r) -> t` is actually a monad. The definition of `join` is `join :: W r (W r t) -> W r t;` `join ww = \y -> ww (\w -> y (w y)) y)` and I checked that all monad laws hold. More generally, if `M` is a monad then the functor `g t = (M t -> r) -> M t` is also a monad, as are the functors `r -> M t` and `M(r -> t)`. Oct 5 '16 at 5:39
• Is the continuation monad rigid? Nov 29 '17 at 23:11
• @PyRulez No, the continuation monad is not rigid, despite what I said in the answer above. The required type for `inject` is not inhabitable for the continuation monad. In my answer to stackoverflow.com/questions/26264411/… I have detailed some constructions of rigid functors, and the continuation monad does not fit there. Feb 27 '18 at 5:42

I have been doing some experiments lately to better understand `Distributive`. Happily enough, my results appear closely related to your rigid functors, in a way that clarifies them both.

To begin with, here is one possible presentation of rigid functors. I have taken the liberty to bikeshed your names a bit, for reasons I'll soon get to:

``````flap :: Functor f => f (a -> b) -> a -> f b
flap u a = (\$ a) <\$> u

class Functor g => Rigid g where
fflip :: (a -> g b) -> g (a -> b)
fflip f = (. f) <\$> extractors

extractors :: g (g a -> a)
extractors = fflip id

-- "Left inverse"/non-degeneracy law: flap . fflip = id

instance Rigid ((->) r) where
fflip = flip
``````

Some remarks on my phrasing:

• I have changed the names of `inject` and `eject` to `fflip` and `flap`, mainly because, to my eyes, `flap` looks more like injecting, due to things like this:

``````sweep :: Functor f => f a -> b -> f (a, b)
sweep u b = flap ((,) <\$> u) b
``````
• I took the `flap` name from protolude. It is a play on `flip`, which is fitting because it is one of two symmetrical ways of generalising it. (We can either pull the function outside of an arbitrary `Functor`, as in `flap`, or pull a `Rigid` functor outside of a function, as in `fflip`.)

• I first realised the significance of `extractors` while playing with `Distributive`, but it hadn't occured to me that it might make sense as part of a different class. `extractors` and `fflip` are interdefinable, making it possible to write, for example, this rather neat instance for the search/selection monad:

``````newtype Sel r a = Sel { runSel :: (a -> r) -> a }
deriving (Functor, Applicative, Monad) via SelectT r Identity

instance Rigid (Sel r) where
-- Sel r (Sel r a -> a) ~ ((Sel r a -> a) -> r) -> Sel r a -> a
extractors = Sel \$ \k m -> m `runSel` \a -> k (const a)
``````

Every distributive functor is rigid:

``````fflipDistrib :: Distributive g => (a -> g b) -> g (a -> b)
fflipDistrib = distribute @_ @((->) _)
-- From this point on, I will pretend Rigid is a superclass of Distributive.
-- There would be some tough questions about interface ergonomics if we were
-- writing this into a library. We don't have to worry about that right now,
-- though.
``````

From the other direction, we can write a function which imitates the signature of `distribute` using `Rigid`:

``````infuse :: (Rigid g, Functor f) => f (g a) -> g (f a)
infuse u = (<\$> u) <\$> extractors
``````

`infuse`, however, is not `distribute`. As you note, there are rigid functors that are not distributive, such as `Sel`. Therefore, we have to conclude that `infuse`, in the general case, does not follow the distributive laws.

(An aside: that `infuse` is not a lawful `distribute` in the case of `Sel` can be established by a cardinality argument. If `infuse` followed the distributive laws, we would have `infuse . infuse = id` for any two rigid functors. However, something like `infuse @((->) Bool) @(Sel r)` leads to a result type with fewer inhabitants than the argument type; therefore, there is no way it can have a left inverse.)

## A place in the constellation

At this point, it would be relevant to sharpen our picture of exactly what distinguishes `Distributive` from `Rigid`. Given that your rigid law is `flap . fflip = id`, intuition suggests the other half of an isomorphism, `fflip . flap = id`, might hold in the case of `Distributive`. Checking that hypothesis requires a detour through `Distributive`.

There is an alternative presentation of `Distributive` (and `Rigid`) in which `distribute` (or `fflip`) is factored through the function functor. More specifically, any functorial value of type `g a` can be converted into a CPS suspension that takes a `forall x. g x -> x` extractor:

``````-- The existential wrapper is needed to prevent undue specialisation by GHC.
-- With pen and paper, we can leave it implicit.
-- https://stackoverflow.com/q/56826733/2751851
data Ev g a where
Ev :: ((g x -> x) -> a) -> Ev g a

-- Existential aside, this is ultimately just a function type.
deriving instance Functor (Ev g)

-- Morally, evert = flip id
evert :: g a -> Ev g a
evert u = Ev \$ \e -> e u
``````

If `g` is `Rigid`, we can go in the other direction and recover the functorial value from the suspension:

``````-- Morally, revert = flip fmap extractors
revert :: Rigid g => Ev g a -> g a
revert (Ev s) = s <\$> extractors
``````

`Ev g` itself is `Distributive`, regardless of what `g` is -- after all, it is just a function:

``````-- We need unsafeCoerce (yikes!) because GHC can't be persuaded that we aren't
-- doing anything untoward with the existential.
-- Note that flip = fflip @((->) _)
instance Rigid (Ev g) where
fflip = Ev . flip . fmap (\(Ev s) -> unsafeCoerce s)

-- Analogously, flap = distribute @((->) _)
instance Distributive (Ev g) where
distribute = Ev . flap . fmap (\(Ev s) -> unsafeCoerce s)
``````

Further, `fflip` and `distribute` for arbitrary `Rigid`/`Distributive` functors can be routed through `evert` and `revert`:

``````-- fflip @(Ev g) ~ flip = distribute @((->) _) @((->) _)
fflipEv :: Rigid g => (a -> g b) -> g (a -> b)
fflipEv = revert . fflip . fmap evert

-- distribute @(Ev g) ~ flap = distribute @((->) _) _
distributeEv :: (Rigid g, Functor f) => f (g a) -> g (f a)
distributeEv = revert . distribute . fmap evert
``````

`revert`, in fact, would be enough for implementing `Distributive`. In such terms, the distributive laws amount to requiring `evert` and `revert` being inverses:

``````revert . evert = id  -- "home" roundtrip, right inverse law
evert . revert = id  -- "away" roundtrip, left inverse law
``````

The two roundtrips correspond, respectively, to the two non-free distributive laws:

``````fmap runIdentity . distribute = runIdentity                               -- identity
fmap getCompose . distribute = distribute . fmap distribute . getCompose  -- composition
``````

(The `distribute . distribute = id` requirement stated in the `Data.Distributive` docs ultimately amounts to those two laws, plus naturality.)

Earlier on, I speculated about an isomorphism involving `fflip`:

``````flap . fflip = id  -- "home" roundtrip, left inverse Rigid law
fflip . flap = id  -- "away" roundtrip, would-be right inverse law
``````

It can be verified directly that the rigid law, `flap . fflip = id`, is equivalent to the other "home" roundtrip, `revert . evert = id`. The other direction is trickier. The purported isomorphisms can be chained like this:

``````                        g (a -> b)
{fflip => <= flap}              {evert => <= revert}
a -> g b                                                   Ev g (a -> b)
{fmap evert => <= fmap revert} {distribute => <= distribute}
a -> Ev g b
``````

Let's assume the rigid law holds. We want to prove that `fflip . flap = id` if and only if `evert . revert = id`, so we must handle both directions:

• Firstly, let's assume `evert . revert = id`. The counterclockwise way of going around the square from `a -> g b` to `g (a -> b)` amounts to `fflip` (see the definition of `fflipEv` above). As the conterclockwise way is made out of three isomorphisms, it follows that `fflip` has an inverse. Since `flap` is its left inverse (by the rigid law), it must also be its inverse. Therefore `fflip . flap = id`.

• Secondly, let's assume `fflip . flap = id`. Again, the counterclockwise way from `a -> g b` to `g (a -> b)` is `fflip`, but now we know that it has an inverse, namely `flap`. It follows that each of the functions composed to make up the counterclockwise way must have an inverse. In particular, `revert` must have an inverse. Since `evert` is its right inverse (by the rigid law), it must also be its inverse. Therefore, `evert . revert = id`.

The results above allow us to precisely situate where `Rigid` stands in relation to `Distributive`. A rigid functor is a would-be distributive, except that it only follows the identity law of distributive, and not the composition one. Making `fflip` an isomorphism, with `flap` as its inverse, amounts to upgrading `Rigid` to `Distributive`.

## Miscellaneous remarks

• Looking at `fflip` and `flap` from a monadic point of view, we might say that rigid monads are equipped with an injective conversion from Kleisli arrows to static arrows. With distributive monads, the conversion is upgraded to an isomorphism, which is a generalisation of how `Applicative` and `Monad` are equivalent for `Reader`.

• `extractors` condenses much of what `Distributive` is about. For any distributive functor `g`, there is a `g (g a -> a)` value in which each position is filled with a matching `g a -> a` extractor function. It seems accurate to say that when we move from `Distributive` to `Rigid` we lose this guarantee that position and extractor will match, and, with it, the ability to reconstruct an adequate functorial shape out of nothing. In this context, it is worth having a second look at the `extractors` implementation for `Sel` early in this answer. Any `a -> r` function corresponds to a `Sel r a -> a` extractor, which means there generally will be a myriad of extractors we can't enumerate, so we have to satisfy ourselves with non-isomorphic `fflip` and `infuse` (in hindsight, the `const` that shows up in the implementation of `extractors` already gives the game away). This feels a bit like the lack of a `Traversable` instance for functions. (In that case, though, there is a way to cheat if the domain type of the function is enumerable, `Data.Universe` style. I'm not sure if there actually is such a workaround, however impractical, for `Sel`.)

• I obtained the results about the `revert` isomorphism for `Distributive` largely by mirroring how the shape-and-contents decomposition of `Traversable`, the dual class, works. (A very readable paper that explores the shape-and-contents theme is Understanding Idiomatic Traversals Backwards and Forwards, by Bird et. al.). While covering that in more detail would probably be better left for a separate post, there is at least one question worth posing here: does a notion analogous to `Rigid` make sense for `Traversable`? I believe it does, albeit my feeling is that it sounds less useful than `Rigid` might be. One example of a "co-rigid" pseudo-traversable would be a data structure equipped with a traversal that duplicates effects, but then discards the corresponding duplicate elements upon rebuilding the structure under the applicative layer, so that the identity law is followed -- but not the composition one.

• Speaking of `revert`, the `Ev` construction is in itself quite meaningful: it is an encoding of the free distributive functor. In particular, `evert` and `revert` are comparable to `liftF` and `retract` for free monads, as well as to similar functions for other free constructions. (In such a context, `revert` being a full inverse to `evert` hints at how strong `Distributive` is. It is more usual for the retraction to discard information in some cases, as it happens in the general case of `Rigid`.)

• Last, but not least, there is another way still of making sense of `Ev`: it means the polymorphic extractor type represents the distributive functor, in the `Representable` sense, with `evert` corresponding to `index`, and `revert`, to `tabulate`. Unfortunately, the quantification makes it very awkward to express that in Haskell with the actual `Representable` interface. (It is symptomatic that I had to reach for `unsafeCoerce` to give `Ev` its natural `Rigid` and `Distributive` instances.) If it serves as solace, it wouldn't be a terribly practical representation anyway: if I already have a polymorphic extractor in hands, I don't actually need `index` for extracting values.

• It is very interesting to see that `Rigid` has one fewer law than `Distributive`. Two questions: 1) Is `Traversable` similar in that it has two laws, and we can omit one law to have a weaker typeclass (your conjectured "co-Rigid")? 2) What exactly is the usefulness of `Distributive` functors, and are there any examples of `Distributive` other than the `Reader` monad? Jun 30 '19 at 3:22
• [1/3] (1) Indeed. Implementation details aside, the `Traversable` isomorphism amounts to a `clear` function, which empties the traversable structure giving out its shape and a list of its contents, and a `fill` function, which remakes the structure from shape and contents. `fill . clear = id` is equivalent to the identity law of `Traversable`, and adding `clear . fill = id` amounts to adding the composition law. A pseudo-traversable class with only the identity law is conceivable, but I suspect it wouldn't see much use -- the main problem being that traversals wouldn't compose cleanly. Jun 30 '19 at 4:15
• [2/3] (2a) All distributive functors are isomorphic to `Reader r` for some `r`, though working with the non-function form can be more convenient depending on what one wants to do. Examples include infinite streams, fixed length vectors, and more generally any data structure with a fixed shape. Jun 30 '19 at 4:15
• [3/3] (2b) While there are some nifty things one might do with the `Distributive` methods (for instance, with a vector type like `Duo a = Duo a a`, `cotraverse @Duo @[]` can be used to zip a list of vectors with a fold), the class has a rather tiny interface. The real power comes with `Representable`, which gives direct access to the isomorphism, thus making it possible to do with the functorial values almost anything you'd do with a function. (`Distributive` and `Representable` are separate classes mostly for the sake of packaging a simpler subset of the interface separately.) Jun 30 '19 at 4:16
• @winitzki Beyond `Distributive` and `Representable`, there is still a further layer of bells and whistles that can be added to the interface, resulting in `Adjunction`, the class of Hask/Hask adjunctions. The answer I wrote about it the other day is somewhat relevant when it comes to what `Distributive`-like things can do. Jun 30 '19 at 4:26

We are all familiar with the `Traversable` typeclass, which can be boiled down to the following:

``````class Functor t => Traversable t
where
sequenceA :: Applicative f => t (f a) -> f (t a)
``````

This makes use of the concept of an `Applicative` functor. There is a laws-only strengthening of the categorical concept underlying `Applicative` that goes like this:

``````-- Laxities of a lax monoidal endofunctor on Hask under (,)
zip :: Applicative f => (f a, f b) -> f (a, b)
zip = uncurry \$ liftA2 (,)

husk :: Applicative f => () -> f ()
husk = pure

-- Oplaxities of an oplax monoidal endofunctor on ... (this is trivial for all endofunctors on Hask)
unzip :: Functor f => f (a, b) -> (f a, f b)
unzip fab = (fst <\$> fab, snd <\$> fab)

unhusk :: f () -> ()
unhusk = const ()

-- The class
class Applicative f => StrongApplicative f

-- The laws
-- zip . unzip = id
-- unzip . zip = id
-- husk . unhusk = id
-- unhusk . husk = id -- this one is trivial
``````

The linked question and its answers have more details, but the gist is that `StrongApplicative`s model some notion of "fixed size" for functors. This typeclass has an interesting connection to `Representable` functors. For reference, `Representable` is:

``````class Functor f => Representable x f | f -> x
where
rep :: f a -> (x -> a)
unrep :: (x -> a) -> f a

instance Representable a ((->) a)
where
rep = id
unrep = id
``````

An argument by @Daniel Wagner shows that `StrongApplicative` is a generalization of `Representable`, in that every `Representable` is `StrongApplicative`. Whether there are any `StrongApplicative`s that are not `Representable` is not yet clear.

Now, we know that `Traversable` is formulated in terms of `Applicative`, and runs in one direction. Since `StrongApplicative` promotes the `Applicative` laxities to isomorphisms, perhaps we want to use this extra equiment to invert the distributive law that `Traversable` supplies:

``````class Functor f => Something f
where
unsequence :: StrongApplicative f => f (t a) -> t (f a)
``````

It just so happens that `(->) a` is a `StrongApplicative`, and in fact a representative specimen (if you'll pardon the pun) of the genus of `Representable` `StrongApplicative` functors. Hence we can write your `inject`/`promote` operation as:

``````promote :: Something f => (a -> f b) -> f (a -> b)
promote = unsequence
``````

We mentioned before that `StrongApplicative` is a superclass of the family of `Representative` functors. From examining the type of `unsequence`, it is obvious that the stronger a constraint we place on the polymorphic applicative, the easier it will be to implement `unsequence` (and hence the more instances of the resulting class).

So in a sense there is a hierarchy of "detraversable" functors that flows in the opposite direction to a hierarchy of applicative effects with respect to which you might wish to detraverse them. The hierarchy of "inner" functors would go like this:

``````Functor f => Applicative f => StrongApplicative f => Representable x f
``````

And the corresponding hierarchy of detraversable/distributive functors might go like this:

``````Distributive t <= ADistributive t <= SADistributive t <= RDistributive t
``````

With definitions:

``````class RDistributive t
where
rdistribute :: Representable x f => f (t a) -> t (f a)

default rdistribute :: (SADistributive t, StrongApplicative f) => f (t a) -> t (f a)

class RDistributive t => SADistributive t
where
sadistribute :: StrongApplicative f => f (t a) -> t (f a)

default sadistribute :: (ADistributive t, Applicative f) => f (t a) -> t (f a)

where
adistribute :: Applicative f => f (t a) -> t (f a)

default adistribute :: (Distributive t, Functor f) => f (t a) -> t (f a)

class ADistributive t => Distributive t
where
distribute :: Functor f => f (t a) -> t (f a)

``````

Our definition of `promote` can be generalized to depend on `RDistributive` (since `(->) a` itself is indeed a representable functor):

``````promote :: RDistributive f => (a -> f b) -> f (a -> b)
promote = rdistribute
``````

In a strange turn of events, once you get down to the bottom of this hierarchy (i.e. to `Distributive`), your promise of detraversability has become so strong relative to your demands that the only functors for which you can implement it are themselves `Representable`. An example of such a distributive, representable (and hence rigid) functor is that of pairs:

``````data Pair a = Pair { pfst :: a, psnd :: a }
deriving Functor

instance RDistributive Pair
instance Distributive Pair
where
distribute x = Pair (pfst <\$> x) (psnd <\$> x)
``````

Of course if you make a strong demand of the polymorphic "inner functor", for example `Representable x f` in `RDistributive`, instances like this become possible:

``````newtype Weird r a = Weird { runWeird :: (a -> r) -> a }
deriving Functor

instance RDistributive (Weird r)
where
rdistribute = fmap unrep . promoteWeird . rep
where
promoteWeird :: (x -> Weird r a) -> Weird r (x -> a)
promoteWeird f = fmap (. f) \$ Weird \$ \k m -> m `runWeird` \a -> k (const a)
``````

TODO: Check where (if anywhere) in the hierarchy all the other examples of rigid functors fall.

As I said I haven't thought about it super carefully, so maybe the folks here that have devoted some thought to the rigid functor concept can immediately poke holes in it. Alternately, maybe it makes things fall into place that I can't yet see.

It's probably worthwhile thinking about some laws for these untraversing typeclasses. An obvious one that suggests itself is `sequence . unsequence = id` and `unsequence . sequence = id` wherever the functor supports both `Traversable` and `Untraverse`.

It's also worth mentioning that the interaction of "distributive law"s of functors with monads and comonads is quite well studied, so that might have some relevance to the monad related discussion in your posts.

• "Whether there are any `StrongApplicative`s that are not `Representable` is not yet clear" -- `StrongApplicative` does imply `Representable`. `husk . unhusk = id` means `() <\$ u = husk ()` for any `u`. That being so, the shape of `husk ()` is the only possible one for a `StrongApplicative`, and having a single shape amounts to being `Representable`/`Distributive`. Nov 27 '21 at 1:00