I recently read the very interesting paper Monotonicity Types in which a new HM-language is described that keeps track of monotonicity across operations, so that the programmer does not have to do this manually (and fail at compile-time when a non-monotonic operation is passed to something that requires one).

I was thinking that it probably would be possible to model this in Haskell, since the `sfun`

s that the paper describes seem to be 'just another Arrow instance', so I set out to create a very small POC.

However, I came across the problem that there are, simply put, four kinds of 'tonicities' (for lack of a better term): monotonic, antitonic, constant (which is both) and unknown (which is neither), which can turn into one-another under composition or application:

When two 'tonic functions' are applied, the resulting tonic function's tonicity ought to be the most specific one that matches both types ('Qualifier Contraction; Figure 7' in the paper):

- if both are constant tonicity, the result should be constant.
- if both are monotonic, the result should be monotonic
- if both are antitonic, the result should be antitonic
- if one is constant and the other monotonic, the result should be monotonic
- if one is constant and the other antitonic, the result should be antitonic
- if one is monotonic and one antitonic, the result should be unknown.
- if either is unknown, the result is unknown.

When two 'tonic functions' are composed, the resulting tonic function's tonicity might flip ('Qualifier Composition; Figure 6' in the paper):

- if both are constant tonicity, the result should be constant.
- if both are monotonic, the result should be monotonic
- if both are antitonic, the result should be monotonic
- if one is monotonic and one antitonic, the result should be antitonic.
- if either is unknown, the result is unknown.

I have a problem to properly express this (the relationship between tonicities, and how 'tonic functions' will compose) in Haskell's types. My latest attempt looks like this, using GADTs, Type Families, DataKinds and a slew of other type-level programming constructs:

```
{-# LANGUAGE GADTs, FlexibleInstances, MultiParamTypeClasses, AllowAmbiguousTypes, UndecidableInstances, KindSignatures, DataKinds, PolyKinds, TypeOperators, TypeFamilies #-}
module Main2 where
import qualified Control.Category
import Control.Category (Category, (>>>), (<<<))
import qualified Control.Arrow
import Control.Arrow (Arrow, (***), first)
main :: IO ()
main =
putStrLn "Hi!"
data Tonic t a b where
Tonic :: Tonicity t => (a -> b) -> Tonic t a b
Tonic2 :: (TCR t1 t2) ~ t3 => Tonic t1 a b -> Tonic t2 b c -> Tonic t3 a c
data Monotonic = Monotonic
data Antitonic = Antitonic
class Tonicity t
instance Tonicity Monotonic
instance Tonicity Antitonic
type family TCR (t1 :: k) (t2 :: k) :: k where
TCR Monotonic Antitonic = Antitonic
TCR Antitonic Monotonic = Antitonic
TCR t t = Monotonic
--- But now how to define instances for Control.Category and Control.Arrow?
```

I have the feeling I am greatly overcomplicating things. Another attempt I had introduced

```
class (Tonicity a, Tonicity b) => TonicCompose a b where
type TonicComposeResult a b :: *
```

but it is not possible to use `TonicComposeResult`

in the instance declaration of e.g. `Control.Category`

("illegal type synonym family application in instance").

What am I missing? How can this concept properly be expressed in type-safe code?

`Tonic t :: * -> * -> *`

has the right kind for`Arrow`

or`Category`

, but`Tonic Antitonic`

is not a category since the composition of two (antitonic) arrows is no longer an (antitonic) arrow. Indeed, antitonic functions do not make a category. At best, we can make a category with "functions of known tonicity", using a type which doesnotexpose the tonicity (a sort of existential type) and juggle between`Tonicity t a b`

(not a category) and`SomeTonicity a b`

(category). Alternatively, we could use a`IndexedCategory`

class to allow for tonicity changes. – chi May 6 '19 at 11:44`IndexedCategory`

class would work? – Qqwy May 6 '19 at 13:26`class IC k where type F k t1 t2 ; type B k ; comp :: k t1 a b -> k t2 b c -> k (F k t1 t2) a c ; id :: k (B k) a c`

, I guess, forcing`k`

to define the composition rule for indices`t`

s (and the index for`id`

). This is untested, it might require some more changes. – chi May 6 '19 at 13:35`KnownNat n`

and`SomeNat`

? – Qqwy May 6 '19 at 14:00`IC`

above to arrows. Anyway, many standard typeclasses over the years have been extended/generalized in the libraries, but only a few of such generalizations proved useful enough to become widespread. This however does not mean that one should not experiment and have some fun ;) – chi May 7 '19 at 20:104more comments