If you have a closed set of types that are the only ones your program will want to reason about, you could consider sidestepping `Data.Typeable`

and just roll your own type representations with GADTs as shown below. The differences between this and the standard `Typeable`

are the following:

`TypeRep`

s from `Data.Typeable`

don't have a type variable representing the type they stand for, whereas the in the alternative below you get `TypeRep a`

, where `a`

is the type that your `TypeRep`

stands for (e.g., `typeOf "foo" :: TypeRep [Char]`

).
- However the GADT approach shown below only works for a set of types fixed at compilation time, because your homebrew
`TypeRep`

definition needs to list out all the representable types and type constructors.

Why am I suggesting to go this complex route? Because you can use this technique to eliminate the sequence of pattern guards in your definition of `field`

:

```
data Schema a = ...
| Field (TypeRep a) -- my TypeRep from below, not the standard one!
| ...
field :: TypeRep a -> Schema a
field t = Field typeRep
```

The downside here is that the GADT `TypeRep`

s have a type parameter, it's going to require some other approach to handle the case for your `Object :: [Schema] -> Schema`

constructor, because this replaces `[Schema]`

with `[Schema a]`

. Maybe you could try something like this:

```
{-# LANGUAGE GADTs #-}
data Schema a where
Field :: TypeRep a -> Schema a
Array :: Schema a -> Schema (Array a)
Object2 :: Schema a -> Schema b -> Schema (a, b)
Object3 :: Schema a -> Schema b -> Schema c -> Schema (a, b, c)
...
```

But I figure that if you study the code below you may find some ideas that you could incorporate into what you're doing—your `TypeEnum`

type is similar to my `TypeRep`

type below, except that mine is able to represent type constructors in addition to atomic types.

So here's the code (which should be easy to modify for your choice of types):

```
{-# LANGUAGE GADTs #-}
import Control.Applicative
----------------------------------------------------------------
----------------------------------------------------------------
--
-- | Type representations. If @x :: TypeRep a@, then @x@ is a singleton
-- value that stands in for type @a@.
data TypeRep a where
Integer :: TypeRep Integer
Char :: TypeRep Char
Maybe :: TypeRep a -> TypeRep (Maybe a)
List :: TypeRep a -> TypeRep [a]
Pair :: TypeRep a -> TypeRep b -> TypeRep (a, b)
-- | Typeclass for types that have a TypeRep
class Representable a where
typeRep :: TypeRep a
instance Representable Integer where typeRep = Integer
instance Representable Char where typeRep = Char
instance Representable a => Representable (Maybe a) where
typeRep = Maybe typeRep
instance Representable a => Representable [a] where
typeRep = List typeRep
instance (Representable a, Representable b) => Representable (a,b) where
typeRep = Pair typeRep typeRep
typeOf :: Representable a => a -> TypeRep a
typeOf = const typeRep
----------------------------------------------------------------
----------------------------------------------------------------
--
-- | Type equality proofs.
data Equal a b where
Reflexivity :: Equal a a
-- | Induction rules for type equality proofs for parametric types
induction :: Equal a b -> Equal (f a) (f b)
induction Reflexivity = Reflexivity
induction2 :: Equal a a' -> Equal b b' -> Equal (f a b) (f a' b')
induction2 Reflexivity Reflexivity = Reflexivity
-- | Given two TypeReps, prove or disprove their equality.
matchTypes :: TypeRep a -> TypeRep b -> Maybe (Equal a b)
matchTypes Integer Integer = Just Reflexivity
matchTypes Char Char = Just Reflexivity
matchTypes (List a) (List b) = induction <$> (matchTypes a b)
matchTypes (Maybe a) (Maybe b) = induction <$> (matchTypes a b)
matchTypes (Pair a b) (Pair a' b') =
induction2 <$> matchTypes a a' <*> matchTypes b b'
matchTypes _ _ = Nothing
----------------------------------------------------------------
----------------------------------------------------------------
--
-- Example use: type-safe coercions and casts
--
-- | Given a proof that a and b are the same type, you can
-- actually have an a -> b function.
coerce :: Equal a b -> a -> b
coerce Reflexivity x = x
cast :: TypeRep a -> TypeRep b -> a -> Maybe b
cast a b x = coerce <$> (matchTypes a b) <*> pure x
----------------------------------------------------------------
----------------------------------------------------------------
--
-- Example use: dynamic data
--
data Dynamic where
Dyn :: TypeRep a -> a -> Dynamic
-- | Inject a value of a @Representable@ type into @Dynamic@.
toDynamic :: Representable a => a -> Dynamic
toDynamic = Dyn typeRep
-- | Cast a @Dynamic@ into a @Representable@ type.
fromDynamic :: Representable a => Dynamic -> Maybe a
fromDynamic = fromDynamic' typeRep
fromDynamic' :: TypeRep a -> Dynamic -> Maybe a
fromDynamic' :: TypeRep a -> Dynamic -> Maybe a
fromDynamic' target (Dyn source value) = cast source target value
```

**EDIT:** I couldn't help but play some more with the above:

```
{-# LANGUAGE StandaloneDeriving #-}
import Data.List (intercalate)
--
-- And now, I believe this is very close to what you want...
--
data Schema where
Field :: TypeRep a -> Schema
Object :: [Schema] -> Schema
Array :: Schema -> Schema
deriving instance Show (TypeRep a)
deriving instance Show (Schema)
example :: Schema
example = Object [Field (List Char), Field Integer]
describeSchema :: Schema -> String
describeSchema (Field t) = "Field of type " ++ show t
describeSchema (Array s) = "Array of type " ++ show s
describeSchema (Object schemata) =
"an Object with these schemas: "
++ intercalate ", " (map describeSchema schemata)
```

With that, `describeSchema example`

produces `"an Object with these schemas: Field of type List Char, Field of type Integer"`

.