I have been reading up on adjunctions during the last couple of days. While I start to understand their importance from a theoretical point of view, I wonder how and why people use them in Haskell. `Data.Functor.Adjunction` provides an implementation and among its instances are free functor / forgetful functor and curry / uncurry. Again those are very interesting from the theoretical view point but I can't see how I would use them for more practical programming problems.

Are there examples of programming problems people solved using `Data.Functor.Adjunction` and why you would prefer this implementation over others?

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• I could (so, so easily) be wrong, but I think `Data.Functor.Adjunction` exists primarily to demonstrate that the categorical idea of adjunction can be represented in Haskell. – chepner Jun 12 at 21:35

1) Literally any mathematical abstraction, no matter how obscure, will be implemented by somebody - just because they can!

2) At some point, somebody else will find that abstraction useful for the work they are doing ("hey, this happens to be an adjunction") - and actually use the library implemented as per point 1

In re adjunctions, you can find a practical use of them in the diagrams library - where the adjunctions library is used for query planning, specifically its implementation of representable functors (which they use for calculating a shape's bounding region)

Generally speaking, adjunctions would be most useful when you want to handle things that are quote "equal" unquote (that is, equal for all practical purposes, despite having different internal implementations, and thus not being equal in the Eq/== sense).

I.e. the diagrams library has composite shapes - shapes generated by combining transformations over base shapes. You could have two shapes that are constructed in different ways (the transformation stack is different, and thus the two are not equal in the `==` sense), but produce the same final shape when rendered (and thus have equal outcome - not equal, but isomorphic).

• I find this an unsatisfying example. Representable functors don't really require adjunctions, that is merely a context in which they can be considered. And what `diagrams` does with representable functors isn't new; basically the class just acts as a replacement for the previously used `HasBasis`. With a vector-space / manifold level abstraction, the types could arguably be expressed better / more geometrical than with the current representable-functor one. – leftaroundabout 7 hours ago
• Your point that adjunctions are useful for equivalence classes is interesting though; elaborate? – leftaroundabout 7 hours ago
• To borrow Bartosz Milewski's example, `(Char, Bool)` and `(Bool, Char)` contain the same information - but are they equal? Structurally, no. But they could be equal, depending on what you do with them - what are they transformed into. If they are used to generate the same results, they can be said to have a "weak" equality. – typedfern 7 hours ago
• And yes, not an ideal example - a bit like saying that every use of Monad is an example usage of Applicative, since Haskell implements Monad by extending Applicative; but that's frequently the case - the more abstract a concept, the more likely it ends up mostly being used "under the hood". – typedfern 7 hours ago