I'm playing around with CPS and `Control.Monad.Cont`

and wonder what we gain by noticing the monadic structure. For code like this:

```
sumOfSquares'cps :: Cont r Int -> Cont r Int -> Cont r Int
sumOfSquares'cps x y = x >>= \x' ->
y >>= \y' ->
return (x'*x' + y'*y')
```

Can easily be rewritten as

```
type Cont' r a = (a -> r) -> r
sos'cps :: Cont' r Int -> Cont' r Int -> Cont' r Int
sos'cps x y = \k -> x $ \x' ->
y $ \y' ->
k (x'*x' + y'*y')
```

Don't get me wrong, but I can't see the sensation here apart from being able to use `do`

notation and a `newtype`

. I don't think that `callCC`

is dependent on the monad instance either.

I'm lacking imagination to come up with an example. What do we actually get for declaring `Cont r`

a monad?

`callCC`

is dependent on the monad instance either". Strictly speaking, nothing ever is. For example, in the`Maybe`

monad`return = Just`

and`(=<<) = maybe Nothing`

. The`Monad`

class abstracts over preexisting functionality to make the things Michael Snoyman mentions in his answer possible. – duplode Jun 10 '14 at 18:26`Cont`

, because there is no real difference in syntax, I guess. – Sebastian Jun 10 '14 at 19:43`Cont`

, you might want to check out The Mother of all Monads. – Ørjan Johansen Jun 12 '14 at 22:40