I just found myself writing some code like the following:

```
import Prelude hiding (id, (.))
import Control.Category
import Control.Monad ((<=<))
-- | Intended law:
--
-- map forward . backward == id
--
data Invertible a b =
Invertible { forward :: a -> b
-- Maybe switch from [a] to Monad m => m a? (Requires RankNTypes)
, backward :: b -> [a] }
instance Category Invertible where
id = Invertible id (:[])
f . g = Invertible { forward = forward f . forward g
, backward = backward g <=< backward f
}
```

I've tried searching Google for uses of the terms "inverse image" or "preimage" in pages about Haskell, but no luck there. Have any of you trod the path that I'm trodding now and discovered the lay of the land?

I've already worked out that `Invertible a`

is not a `Functor`

, because when you try to implement `fmap :: (a -> r) -> Invertible a b -> Invertible a r`

there is no sensible value for `backward . fmap f`

(no sensible function of type `(a -> r) -> (b -> [a]) -> r -> [a]`

). But maybe there are some other interesting operations on this that I'm just not aware of.

`map forward . backward == return`

. Do you not want a roundtrip law for the other direction? Why do you need the list at all? (If you agree with my proposed law, then`backward`

must always return a singleton list anyway.) – Daniel Wagner Oct 24 '12 at 7:19`nub . map forward . backward == return`

, but that only works for lists. If the structure in question were a set, then Daniel's law would be correct. (I'mnotadvocating adding an Eq or Ord context.) There's no roundtrip law for the reverse direction because`backward`

can genuinely produce multiple elements. They'd only be the same after mapping`forward`

, but that's covered by the first roundtrip law. – AndrewC Oct 24 '12 at 10:24`Bij (a->b) (b->a)`

). However, since you're clearly interested in fucntions with no inverse, it would be better to do exactly as you did, and declare the Category instance. – AndrewC Oct 24 '12 at 10:33