A `type Prism' s a = Prism s s a a`

(hackage) can be thought of as a relation between some structure `s`

and its member `a`

, such that you can always produce the structure from the member (`a -> s`

), but can only optionally retrieve the member from the structure (`s -> Maybe a`

).

This model is helpful in relating a sum type to one of its constructors ... as well as (more relevant here) in route encoding and decoding. If `s`

is the encoded route URL, and `a`

is the route type, then we have `a -> s`

representing the encoding function (always succeeds), and `s -> Maybe a`

representing the decoding function (can fail).

Now, on to these pairs of functions, I want to add a "context" argument that is to be used in the encoding and decoding process (imagine that the decoding process needs to "look up" some database before successfully producing a relevant route). Basically:

```
encode :: ctx -> a -> s
decode :: ctx -> s -> Maybe a
```

Is there a type that models these conversions? It looks very much like a `Prism'`

but with an extra `ctx`

argument.

As a next step, I'd like to define a functor for this prism such that it can transform all three types: `ctx`

, `s`

, `a`

. I currently have a class like this, but it appears I might be missing an existing library that I could use to simplify all of this:

```
class PartialIsoFunctor (f :: Type -> Type -> Type -> Type) where
-- x, y are the context
-- a, b are the structure `s`
-- c, d are the route types `a`
pimap ::
Prism' b a -> -- Note: contravariant prism
Prism' c d ->
(y -> x) -> -- Note: this is contravariant
f x a c ->
f y b d
```

The idea here is that there is a `RouteEncoder ctx r`

type (see also) representing a value that knows how to encode/decode routes. And I want to be able to transform these route encoders on the `r`

, `ctx`

, and the URL string (internally a `FilePath`

, actually) it encodes to/ decodes from.

Notes:

- I use
`optics-core`

rather than`lens`

.

**EDIT**: Here's my current approach:

```
type RouteEncoder ctx s route = Prism' (ctx, s) (ctx, route)
```

And the functor that transforms it:

```
mapRouteEncoder ::
Prism' b a ->
Prism' c d ->
(y -> x) ->
RouteEncoder x a c ->
RouteEncoder y b d
mapRouteEncoder = undefined
```

The encoding/decoding functions:

```
-- The use of `snd` here suggests that the use of tuples in
-- RouteEncoder is a bit of a hack
encodeRoute :: RouteEncoder ctx r -> ctx -> r -> FilePath
encodeRoute enc ctx r = snd $ review enc (ctx, r)
decodeRoute :: RouteEncoder ctx r -> ctx -> FilePath -> Maybe r
decodeRoute enc m s = snd <$> preview enc (ctx, s)
```

How can this be simplified? Note that `RouteEncoder`

's are created ahead, and composed. But the actual encoding/decoding happens later, passing the 'ctx' that varies over time.

`type CtxPrism ctx s a = Prism (ctx, s) s (Maybe a) (ctx, a)`

would naively capture it. A slightly better approach (how?) is to somehow compose a`Reader`

and a`Prism'`

.`ctx -> Prism' s a`

.`ctx`

is time-varying and is not a constant value that is known at the time of creation of route encoders. Furthermore,`ctx`

isrequiredfor encoding and decoding correctly, and therefore must be part of the prism function arguments. Think of`ctx`

as data from some in-memory database. I've also edited the question with more information.extractingsmaller contexts from larger ones, or are you making more general changes? If you're only doing extraction, you might consider a`reflection`

-based approach.`reflection`

is a fun package that gives the class system a bit of a different flavor. It's not so much about "having to" use type classes as about "getting to" use type classes.3more comments