Often you have something like an `Applicative`

without `pure`

, or something like a `Monad`

, but without `return`

. The semigroupoid package covers these cases with `Apply`

and `Bind`

. Now I'm in a similar situation concerning `Arrow`

, where I can't define a meaningful `arr`

function, but I think the other functions would make perfect sense.

I defined a type that holds a function and it's reverse function:

```
import Control.Category
data Rev a b = Rev (a -> b) (b -> a)
reverse (Rev f g) = Rev g f
apply (Rev f _) x = f x
applyReverse (Rev _ g) y = g y
compose (Rev f f') (Rev g g') = Rev ((Prelude..) f g) ((Prelude..) g' f')
instance Category Rev where
id = Rev Prelude.id Prelude.id
(.) x y = compose x y
```

Now I can't implement `Arrow`

, but something weaker:

```
--"Ow" is an "Arrow" without "arr"
class Category a => Ow a where
first :: a b c -> a (b,d) (c,d)
first f = stars f Control.Category.id
second :: a b c -> a (d,b) (d,c)
second f = stars Control.Category.id f
--same as (***)
stars :: a b c -> a b' c' -> a (b,b') (c,c')
...
import Control.Arrow
instance Ow Rev where
stars (Rev f f') (Rev g g') = Rev (f *** g) (f' *** g')
```

I think I can't implement the equivalent of `&&&`

, as it is defined as `f &&& g = arr (\b -> (b,b)) >>> f *** g`

, and `(\b -> (b,b))`

isn't reversable. Still, do you think this weaker type class could be useful? Does it even make sense from a theoretical point of view?

`Arrow`

functions exactly the definition of a category ? – Alexandre C. Aug 9 '11 at 15:41`Category`

functions are the definition of a category. Well, morphisms, anyway (and no laws)—as I understand it,`Category`

corresponds to a subcategory ofHaskwhich has the same objects (all types) but different morphisms.`Arrow`

adds a lot more structure, but I don't know enough to say anything about what sort of structure. – Antal Spector-Zabusky Aug 9 '11 at 15:54`Category`

specifies a category whose objects are those ofHaskwith arrows given by some 2-ary type constructor.`Functor`

describes a subcategory ofHaskwhose arrows are those ofHaskwith objects given by some 1-ary type constructor.`Applicative`

maps the monoidal structure of`(,)`

to the`Functor`

, while`(&&&)`

etc. map it to the`Category`

. And`arr`

gives a functor fromHaskto the`Category`

. – C. A. McCann Aug 9 '11 at 16:20`ArrowApply`

makes the`Category`

cartesian closed, giving the full power of lambda calculus with higher-order arrows, currying, etc., and the ability to map all of that fromHaskto the`Category`

. Arrows from a fixed object then give the usual`Reader`

monad structure, which is why`Kleisli m a b`

is isomorphic to`ReaderT a m b`

. – C. A. McCann Aug 9 '11 at 16:34