Useful operations on free arrows

We know free monads are useful, and packages like Operational make it easy to define new monads by only caring about the application-specific effects, not the monadic structure itself.

We can easily define "free arrows" analogous to how free monads are defined:

``````{-# LANGUAGE GADTs #-}
module FreeA
( FreeA, effect
) where

import Prelude hiding ((.), id)
import Control.Category
import Control.Arrow
import Control.Applicative
import Data.Monoid

data FreeA eff a b where
Pure :: (a -> b) -> FreeA eff a b
Effect :: eff a b -> FreeA eff a b
Seq :: FreeA eff a b -> FreeA eff b c -> FreeA eff a c
Par :: FreeA eff a₁ b₁ -> FreeA eff a₂ b₂ -> FreeA eff (a₁, a₂) (b₁, b₂)

effect :: eff a b -> FreeA eff a b
effect = Effect

instance Category (FreeA eff) where
id = Pure id
(.) = flip Seq

instance Arrow (FreeA eff) where
arr = Pure
first f = Par f id
second f = Par id f
(***) = Par
``````

My question is, what would be the most useful generic operations on free arrows? For my particular application, I needed special cases of these two:

``````{-# LANGUAGE Rank2Types #-}
{-# LANGUAGE ScopedTypeVariables #-}
analyze :: forall f eff a₀ b₀ r. (Applicative f, Monoid r)
=> (forall a b. eff a b -> f r)
-> FreeA eff a₀ b₀ -> f r
analyze visit = go
where
go :: forall a b. FreeA eff a b -> f r
go arr = case arr of
Pure _ -> pure mempty
Seq f₁ f₂ -> mappend <\$> go f₁ <*> go f₂
Par f₁ f₂ -> mappend <\$> go f₁ <*> go f₂
Effect eff -> visit eff

evalA :: forall eff arr a₀ b₀. (Arrow arr) => (forall a b. eff a b -> arr a b) -> FreeA eff a₀ b₀ -> arr a₀ b₀
evalA exec = go
where
go :: forall a b. FreeA eff a b -> arr a b
go freeA = case freeA of
Pure f -> arr f
Seq f₁ f₂ -> go f₂ . go f₁
Par f₁ f₂ -> go f₁ *** go f₂
Effect eff -> exec eff
``````

but I don't have any theoretical arguments on why these (and not others) would be the useful ones.

• Are you sure that your FreeA is truly free? That's a genuine question because I don't know the answer. Aug 17, 2012 at 21:45
• I worry that this question might be too awesome for StackOverflow. But I'm sure not going to flag it ;) Aug 22, 2012 at 5:59
• note that `arr id` is just `id` Mar 25, 2014 at 10:37
• Oh, I meant for your definitions of `first` and `second`. Mar 25, 2014 at 21:11
• The Category instance isn't associative is it? You can distinguish (a.b).c from a.(b.c) can't you? Apr 29, 2014 at 15:37

A free functor is left adjoint to a forgetful functor. For the adjunction you need to have the isomorphism (natural in `x` and `y`):

``````(Free y :~> x) <-> (y :~> Forget x)
``````

In what category should this be? The forgetful functor forgets the `Arrow` instance, so it goes from the category of `Arrow` instances to the category of all bifunctors. And the free functor goes the other way, it turns any bifunctor into a free `Arrow` instance.

The haskell type of arrows in the category of bifunctors is:

``````type x :~> y = forall a b. x a b -> y a b
``````

It's the same for arrows in the category of `Arrow` instances, but with addition of `Arrow` constraints. Since the forgetful functor only forgets the constraint, we don't need to represent it in Haskell. This turns the above isomorphism into two functions:

``````leftAdjunct :: (FreeA x :~> y) -> x :~> y
rightAdjunct :: Arrow y => (x :~> y) -> FreeA x :~> y
``````

`leftAdjunct` should also have an `Arrow y` constraint, but it turns out it is never needed in the implementation. There's actually a very simple implementation in terms of the more useful `unit`:

``````unit :: x :~> FreeA x

leftAdjunct f = f . unit
``````

`unit` is your `effect` and `rightAdjunct` is your `evalA`. So you have exactly the functions needed for the adjunction! You'd need to show that `leftAdjunct` and `rightAdjunct` are isomorphic. The easiest way to do that is to prove that `rightAdjunct unit = id`, in your case `evalA effect = id`, which is straightforward.

What about `analyze`? That's `evalA` specialized to the constant arrow, with the resulting `Monoid` constraint specialized to the applicative monoid. I.e.

``````analyze visit = getApp . getConstArr . evalA (ConstArr . Ap . visit)
``````

with

``````newtype ConstArr m a b = ConstArr { getConstArr :: m }
``````

and `Ap` from the reducers package. (Edit: since GHC 8.6 it is also in base in `Data.Monoid`)

Edit: I almost forgot, FreeA should be a higher order functor! Edit2: Which, on second thought, can also be implemented with `rightAdjunct` and `unit`.

``````hfmap :: (x :~> y) -> FreeA x :~> FreeA y
hfmap f = evalA (effect . f)
``````

By the way: There's another way to define free functors, for which I put a package on Hackage recently. It does not support kind `* -> * -> *` (Edit: it does now!), but the code can be adapted to free arrows:

``````newtype FreeA eff a b = FreeA { runFreeA :: forall arr. Arrow arr => (eff :~> arr) -> arr a b }
evalA f a = runFreeA a f
effect a = FreeA \$ \k -> k a

instance Category (FreeA f) where
id = FreeA \$ const id
FreeA f . FreeA g = FreeA \$ \k -> f k . g k

instance Arrow (FreeA f) where
arr f = FreeA \$ const (arr f)
first (FreeA f) = FreeA \$ \k -> first (f k)
second (FreeA f) = FreeA \$ \k -> second (f k)
FreeA f *** FreeA g = FreeA \$ \k -> f k *** g k
FreeA f &&& FreeA g = FreeA \$ \k -> f k &&& g k
``````

If you don't need the introspection your `FreeA` offers, this `FreeA` is probably faster.