# Can I model a list of successes with short circuiting failure via the composition of applicative functors?

The user 'singpolyma' asked on reddit if there was some general structure underlying:

``````data FailList a e = Done | Next a (FailList a e) | Fail e
``````

A free monad was suggested, but I wondered if this could be modeled more generally via applicative functors. In Abstracting with Applicatives, Bazerman shows us that the sum of two applicative functors is also an applicative functor, with bias to the left/right, provided we have a natural transformation in the direction of the bias. This sounds like it's what we need! Thus, I started my proposal, but then quickly ran into problems. Can anyone see solutions to these problems?:

Firstly, we start with the definition of the sum of two functors. I started here because we want to model sum types - either successes or successes and a failure.

``````data Sum f g a = InL (f a) | InR (g a)
``````

And the two functors we want to work with are:

``````data Success a = Success [a]
data Failure e a = Failure e [a]
``````

`Success` is straight forward - it's essentially `Const [a]`. However, `Failure e` I'm not so sure about. It's not an applicative functor, because `pure` doesn't have any definition. It is, however, an instance of Apply:

``````instance Functor Success where
fmap f (Success a) = Success a

instance Functor (Failure e) where
fmap f (Failure e a) = Failure e a

instance Apply (Failure e) where
(Failure e a) <.> (Failure _ b) = Failure e a

instance Apply Success where
(Success a) <.> (Success b) = Success (a <> b)

instance Applicative Success where
pure = const (Success [])
a <*> b = a <.> b
``````

Next, we can define the sum of these functors, with a natural transformation from right to left (so a left bias):

``````instance (Apply f, Apply g, Applicative g, Natural g f) => Applicative (Sum f g) where
pure x = InR \$ pure x
(InL f) <*> (InL x) = InL (f <*> x)
(InR g) <*> (InR y) = InR (g <*> y)
(InL f) <*> (InR x) = InL (f <.> eta x)
(InR g) <*> (InL x) = InL (eta g <.> x)
``````

And the only thing we now have to do is define our natural transformation, and this is where it all comes crumbling down.

``````instance Natural Success (Failure e) where
eta (Success a) = Failure ???? a
``````

The inability to create a `Failure` seems to be the problem. Furthermore, even being hacky and using ⊥ isn't an option, because this will be evaluated, in the case where you have `InR (Success ...) <*> InL (Failure ...)`.

I feel like I'm missing something, but I have no idea what it is.

Can this be done?

-
The naturality condition `forall (f :: a -> b). eta . fmap f == fmap f . eta` strongly suggests that the error component must be constant. That makes me want to write an `Default e => Applicative (Failure e)`. –  J. Abrahamson Mar 20 '13 at 14:16
Also, your `Apply`/`Applicative` instances are weird. I fixed the heads so that they kind-check, but they generally aren't type-checking either! `Success a` isn't really isomorphic to `Constant [a]` either, though... at the very least, it needs more type indices! –  J. Abrahamson Mar 20 '13 at 14:20
@tel - `Default` seems possible, I just can't see what a sane "default error message" would be. Also, your edits were rejected by other SO editors, though they are valid. I'll apply them myself. –  ocharles Mar 20 '13 at 14:54
The instances of `Functor` and `Apply` of `Success` and `Failure` don't typecheck. Please update them so that we have a working starting point. –  Petr Pudlák Mar 20 '13 at 17:18

I'm pretty sure the "correct" answer is to make `e` a monoid, much as you disliked the idea on the reddit discussion.

Consider `Failure "oops" [(*1),(*2),(*3)] <*> Failure "doh" [1,2,3]` Should the result have "oops" or "doh" as the failure? By making the `e` a monoid we capture the fact that there's no canonical choice, and let the consumer pick their poison (be it `First`, `Last`, `[]`, etc.)

Note that this solution, much like the `(Maybe e, [a])` representation, doesn't deal correctly with streaming/potentially-infinite data, since it is strict in whether we have a failure ending the list.

A different encoding would use fixpoints of applicatives, as per the followup post (http://comonad.com/reader/2013/algebras-of-applicatives/).

Then you take the list representation presented there (`FixF (ProductF Embed (Sum (Const ()))) a`) and alter it by sticking your error monoid in the unit position, to get the following:

`Monid mon => FixF (ProductF Embed (Sum (Const mon))) a`

And note that you can use a `Maybe` instead of a monoid to get exactly a `FailList`, but just as with `FailList` you then don't get an applicative instance for free unless you write one specifying the right way to combine errors.

Also note that with the fixpoint approach if we have the equivalent of `Success [(*1),(*2),(*3)] <*> Failure "doh" [1,2,3,4,5]` then we get back a `Success` with three elements (i.e. we are genuinely nonstrict in failure) while in the approach you suggest, we get back a `Failure` with three elements and the error from the five element failing list. Such are the tradeoffs of streaming vs. strict.

Finally, and most straightforwardly, we can just take `type FailList e = Product (Const (First e)) ZipList` to use standard applicative machinery and get something very close to the original data type.

-
``````{-# LANGUAGE FlexibleInstances #-}

instance Applicative (Sum Success (Failure e)) where
pure x = InL \$ pure x
(InL f) <*> (InL x) = InL (f <*> x)
(InR (Failure e fs)) <*> (InR (Failure _ gs)) = InR (Failure e (fs <*> gs))
(InR (Failure e fs)) <*> (InL (Success gs)) = InR (Failure e (fs <*> gs))
(InL (Success gs)) <*> (InR (Failure e fs)) = InR (Failure e (gs <*> fs))
``````

This is because you can always add a failure to a list of successes ;)

You may also use this type class instead of `Natural f g`:

``````class Transplant f g where
transplant :: f a -> g b -> f b

instance Transplant (Failure e) Success where
transplant (Failure e _) (Success a) = Failure e a
``````

Have no idea what it means category-theory-wise.

-
Yea, I'm aware I can write a specific `Applicative` instance for `Sum` `Success`/`Failure`, but that would overlap with the general instance for `Sum`, which I'd like to preserve. Also, your definitions for the `Failure`/`Success` combination aren't quite what I want because `Failure` should prevent any further success (so the left/right side should be entirely discarded). Transplate is along the right lines, but I wonder if there is some fancy category theory/abstract algebra structure underlying it :) –  ocharles Mar 17 '13 at 18:54
Transplant works absolutely the same way as the handwritten instance. I'm not quite sure how would you define `Failure`/`Success` combination in a different way, is this at all possible? –  n.m. Mar 17 '13 at 19:11
Oh sure, `Transplant` is fine, but it would have to be defined for all `Sum` types so I'm just wondering if there is an actual name/category theoretical concept there, or any other approaches. –  ocharles Mar 17 '13 at 23:10