# formal definition of “monadic function”

The wiki says:

monadic functions (i.e. functions that use values from the monad as their arguments or return value).

My understanding is a function takes or returns a monad is monadic function, but it seems it has more strict definition when I came across this blog

The author said:

A monadic function is a function that produces a monadic value. (Note that we said nothing about its input type)

and

Functions of the form `f :: a -> m b`, where `a` is the type of the inner value of the monad. (Call these classic monadic functions)

Functions of the form `f :: anything -> m b`, where the input of the function really doesn't matter. (Call these loose monadic functions)

It seems the definition is pretty strict and formal, but I can't find anywhere says anything about classic monadic functions, loose monadic functions.

So what precisely is a monadic function?

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The main reason you can't find those terms anywhere else is indicated at the top of that article, which says: It contains my personal and intuitive way of thinking of monadic functions – AndrewC Feb 18 '14 at 15:16
"Monadic function" isn't a strictly defined term. Monad is strictly defined, monadic function isn't. If you mean `a -> m b` you could say Kleisli arrow or monadic function. You could call `ma -> m b -> m c` a monadic function. It depends on the context, and I'm afraid there's no definitive answer. – AndrewC Feb 18 '14 at 15:30
Maybe we could help you better if we only knew what relevance this has for you. Mind you, we're talking about definitions. Everybody is free to define the term he uses as he sees fit. To be sure, once a certain term is established, it is unwise to stick with ones own different definition. But, as you say, you don't find the terms widely used, so either take over the definition from the blog you cited, or come up with an own. – Ingo Feb 18 '14 at 15:43
This distinction between "classic" monadic functions and "loose" monadic functions is not well-defined. There's no such thing as "the inner value of the monad". I wouldn't take this blog post too seriously. We all like to share the journey we took to discover new concepts, but that doesn't mean our understanding of the journey will be helpful to others, or contain well-defined standard concepts. – Tom Ellis Feb 18 '14 at 16:33
I would call `a -> m b` a Kleisli arrow and `m a -> b` a Cokleisli arrow. The former is generally connected to Monads and the latter is generally more connected to Comonads. This way we can avoid the vague terminology that can cause some confusion. Note how the Kleisli arrow fits into the `>>=` (bind) Monad method and how the Cokleisli arrow fits into the `extend` (aka `<<=`) Comonad method. – David Young Feb 18 '14 at 18:45

Let's examine the possibilities of having a monad in an input or output of a function.

1. Monad in one of the input arguments: `f :: m a -> X`. Because for any monad we have `return :: a -> m a`, we can compose it with f and get

``````f . return :: a -> X
``````
2. Pure output: `f :: X -> b`. By composing it with return from the other side we get

``````return . f :: X -> m b
``````

So we can always convert a pure output into monadic one and a monadic input into a pure one. And any function that has pure or monadic inputs/output can be always converted to the form

``````    f :: a1 -> ... -> an -> m b
``````

However, the reverse isn't possible (in general).

I'd say that there is no wide use of terms 'classic' and 'loose' monadic function.

-

In your context, "monadic functions" designates functions that you would compose to write bigger ones, taking advantage of the implicit context handling done by `(>>=)` and `return`.

Example : suppose you have a `Map` of `Map`s to represent the output values of 4 combinations "aa" -> 1, "ab" -> 2, "bc" -> 3, "bd" -> 4

``````import Data.Map (Map, lookup, fromList)

type Map1 = Map Char Int
v1 = fromList [('a',1),('b',2)]    :: Map1
v2 = fromList [('c',3),('d',4)]    :: Map1

type Map2 = Map Char Map1
myMap = fromList [('a',v1),('b',v2)]   :: Map2
``````

Your best friend Hoogle says that `lookup :: Ord k => k -> Map k a -> Maybe a`

Here `lookup` is the so-called "monadic function" that must be composed (here with itself) to give a function of type `:: Char -> Char -> Map2 -> Maybe Int`

``````composedLookup a b m = do
v  <- lookup a m
v' <- lookup b v
return v'
``````

or

``````composedLookup' a b m = lookup a m >>= (lookup b)
``````

EDIT : And functions of type `m a -> b` would be called comonadic in the context of `m` being a comonad. I found this great SO answer about algebra/coalgebra quite enlightening because it ultimately explains monads and comonads in terms of types and applications.

Hope this helps

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I think functions of type `m a -> b` could only reasonably be called comonadic when `m` is a comonad. – Alexey Romanov Feb 19 '14 at 6:09
My bad, thanks for the correction. Answer edited in accordance. – Titou Feb 19 '14 at 10:45