I recently stumbled on the concept of a Kleisli and every tutorial/link/reference that I read motivates the use of Kleisli via the following constructs:

**Composing functions that return monads**:`f: a -> m[b]`

with`g: b -> m[c]`

- I think the very*definition*of a monad already captures this case -`do/bind/for/flatMap`

do that. One needn't lean on the Kleisli construct to achieve this. So this cannot be the "primary" use case of a Kleisli IMO.**Inserting configuration**: This one states that if multiple objects (types, case/data classes etc.,) need to have a`Config`

*injected*then a Kleisli construct can be used to abstract away the repeatable injection. There are numerous ways of achieving this (for example with`implicit`

s in Scala) that invoking a Kleisli may not be necessary. Again, IMO this doesn't stand out as a "primary" use case.**Monad Transformers:**I don't have a solid understanding of this but here's my interpretation: If you have the need of "composing monads" you*need*a construct that allows you to*parameterize*the monads themselves. For example`M1[M2[M1[M2[a]]]]`

could be transformed to`[M1[M2[a]]]`

which*could*(I may be wrong) be*flattened across monadic boundaries*to be composable with an`a -> M3[b]`

(say). For this one*could*us a Kleisli triple and invoke the construct since if you were to do it from scratch you may just*reinvent*the Kleisli.*This*seems to be a good candidate for justifying the use of a Kleisli. Is this correct?

I believe `#1-#2`

above are "secondary uses". That is, if you do happen to use the Kleisli construct, you can *also* get patterns for composing functions that return monads as well as config injection. However, they cannot be *motivating problems* advocating the power of Kleislis.

Under the assumption of using the *least powerful abstraction* to solve the problem at hand, what *motivating* problems can be used to showcase their use?

**Alternate Thesis:** It's entirely possible that I am totally wrong and my understanding of Kleislis is incorrect. I lack the necessary category theory background, but it *could* be that a Kleisli is an *orthogonal construct* that can be used in place of monads and they (Kleisli) are a category theoretic lens through which we view the problems of the functional world (i.e., a Klesli simply wraps a monadic function `a -> M[b]`

and now we can work at a higher level of abstraction where the function is the object of *manipulation* vs an object of *usage*). Thus, the use of Kleisli can be simply understood to be "*Functional Programming with Kleisli*". If this is true, then there *ought* to be a situation where a Kleisli can solve a problem *better* than existing constructs and we circle back to the issue of a *motivating problem*. It's equally likely, that there isn't such a motivating problem per se, if it's simply a *lens* which offers *different* solutions to the same problem. Which is it?

It'd be really helpful to get some input be able to reconstruct the need for Kleislis.

`Choice`

transform of the`Kleisli`

arrow of`List`

", and just like that you have the appropriate powerful foundation to express your ideas. – luqui May 20 '20 at 0:08what is this thingandwhen/where/howcan I grasp its usefulness. Perhaps Kleisli offers a "lens" as you suggested where you can think of "monadic values" or "effectful transformations" as themain thing. Once you select the POV you can express your ideas accordingly. More like aframe of referenceIMO. From my current POV a Kleisli doesn't seem to warrant attention. However, I amcuriousthat if I gave it attention, what can I learn about it from ametaPOV. – PhD May 20 '20 at 1:46arrowcomes from category theory, but in Haskell you can think of it as a generalization of a function. Given a function`f :: a -> b`

and a monad`m`

, the corresponding Kleisli arrow is a new function`f' :: a -> m b`

. (The same applies to Scala, I assume, using different syntax.) – chepner May 20 '20 at 12:24