I am having difficulty understanding how a function can be a monad.

Function `(->) r`

is a monad according to a declaration in `Control.Monad.Instances`

:

```
instance Monad ((->) r) where
return x = \_ -> x
h >>= f = \w -> f (h w) w
```

Even what Miran Lipovača says about it makes me confused:

The implementation for

`>>=`

seems a bit cryptic, but it's really not all that. When we use`>>=`

to feed a monadic value to a function, the result is always a monadic value. So in this case, when we feed a function to another function, the result is a function as well. That's why the result starts off as a lambda. All of the implementations of`>>=`

so far always somehow isolated the result from the monadic value and then applied the function f to that result. The same thing happens here. To get the result from a function, we have to apply it to something, which is why we do`(h w)`

here to get the result from the function and then we apply f to that. f returns a monadic value, which is a function in our case, so we apply it to w as well.

The type signature of (>>=) is this: (>>=) :: m a -> (a -> m b) -> m b

So I take that `h`

is typed as `m a`

and `f`

as `(a -> m b)`

. If a function is `m a`

, does it return an `a`

type value? or does it return something else taking an `a`

type?

If the non-monad value of `h`

is fed to `f`

, then we get:
f (h w)
Looks fine. Since `f`

is a function and has taken its sole argument, it is already a value, no? Since it's a monadic function the value is also a monadic value. Why then does it need another value `w`

? Doesn't feeding `w`

to `f something`

make it non-monadic, i.e., it is not a function any more, no? I also cannot understand why `f something`

and `h`

take the same argument `w`

and return different value types (`m a`

and `m b`

).