I was just looking at the type of map :: (a -> b) -> [a] -> [b] and just the shape of this function made me wonder whether we could see the list forming operator [ ] as obeying various axioms common to normal modal logics (e.g, T, S4, S5, B), since we seem to have at least the K-axiom of normal modal logics, with [(a -> b)] -> [a] -> [b].

This leads to my question: are there familiar, interesting operators or functors in Haskell which have the syntax of modal operators of a certain kind, and which obey the axioms common to normal modal logics (i.e, K, T, S4, S5 and B)?

This question can be sharpened and made more specific. Consider an operator L, and its dual M. Now the question becomes: are there any familiar, interesting operators in Haskell with some of the following properties:

(1) L(a -> b) -> La -> Lb

(2) La -> a

(3) Ma -> L(M a)

(4) La -> L(L a)

(5) a -> L(M a)

It would be very interesting to see some nice examples.

I've thought of a potential example, but it would be good to know whether I am correct: the double negation translation with L as not not and M as not. This translation takes every formula a to its double negation translation (a -> ⊥) -> ⊥ and, crucially, validates axioms (1)-(4), but not axiom (5). I asked a question here https://math.stackexchange.com/questions/2347437/continuations-in-mathematics-nice-examples and it seems the double negation translation can be simulated via the continuation monad, the endofunctor taking every formula a to its double negation translation (a -> ⊥) -> ⊥. There Derek Elkins notes the existence of a couple of double negation translations corresponding, via the Curry-Howard isomorphism, to different continuation-passing style transforms, e.g. Kolmogorov's corresponds to the call-by-name CPS transform.

Perhaps there are other operations that can be done in the continuation monad via Haskell which can validate axioms (1)-(5).

(And just to eliminate one example: there are clear relations between so-called Lax logic https://www.sciencedirect.com/science/article/pii/S0890540197926274 and Monads in Haskell, with the return operation obeying the laws of the modal operator of this logic (which is an endofunctor). I am not interested so much in those examples, but in examples of Haskell operators which obey some of the axioms of modal operators in classical normal modal logics)

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    I don't know what your question is but [a -> b] -> [a] -> [b] is the type of (<*>) specialized to the [] instance of Applicative. – Rein Henrichs Mar 13 at 18:00
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    We have (<*>) :: [a -> b] -> [a] -> [b], and also for the "function modality" we have (<*>) :: (e -> (a -> b)) -> (e -> a) -> (e -> b) which is the well-known K combinator. Probably just coincidence that they share the K name, though. ;-) – Daniel Wagner Mar 13 at 18:01
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    On the "too broad" close votes: FWIW, I don't feel this question should be closed. It is phrased in a rather speculative way (likely due to the OP's unfamiliarity with Haskell, which was mentioned in the original revision of the question); however, at its core there is a fairly reasonable question about whether the functor classes have something to do with modal operators. – duplode Mar 13 at 19:36
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    L sure as heck looks like a comonad, not sure what a corresponding M would be offhand. But e.g. known comonads such as nonempty lists of a, pairs (w,a) would satisfy. – luqui Mar 13 at 21:25
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    You should definitely read Getting a Quick Fix on Comonads, which argues for (restricted use of) ComonadApply for some modal logic. – dfeuer Mar 13 at 22:20

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