Here's a proposal. The primary thing we want your `typeEnum`

function to do that it doesn't yet is bring a `Num a`

dictionary into scope. So let's use GADTs to make that happen. I'll simplify a few things to make it easier to explain the idea and write the code, but nothing essential: I'll focus on `Number`

rather than `LispVal`

and I won't report detailed errors when things go wrong. First some boilerplate:

```
{-# LANGUAGE GADTs #-}
{-# LANGUAGE Rank2Types #-}
import Control.Applicative
import Data.Complex
```

Now, you didn't give your definition of a type enumeration. But I'll give mine, because it's part of the secret sauce: my type enumeration is going to have a connection between Haskell's term level and Haskell's type level via a GADT.

```
data TypeEnum a where
Integer :: TypeEnum Integer
Rational :: TypeEnum Rational
Real :: TypeEnum Double
Complex :: TypeEnum (Complex Double)
```

Because of this connection, my `Number`

type won't need to repeat each of these cases again. (I suspect your `TypeEnum`

and `Number`

types are quite repetitive compared to each other.)

```
data Number where
Number :: TypeEnum a -> a -> Number
```

Now we're going to define a new type that you didn't have, which will tie a `TypeEnum`

together with a `Num`

dictionary for the appropriate type. This will be the return type of our `typeEnum`

function.

```
data TypeDict where
TypeDict :: Num a => TypeEnum a -> TypeDict
ordering :: TypeEnum a -> Int
ordering Integer = 0 -- lowest
ordering Rational = 1
ordering Real = 2
ordering Complex = 3 -- highest
instance Eq TypeDict where TypeDict l == TypeDict r = ordering l == ordering r
instance Ord TypeDict where compare (TypeDict l) (TypeDict r) = compare (ordering l) (ordering r)
```

The `ordering`

function reflects (my guess at) the direction that casts can go. If you try to implement `Eq`

and `Ord`

yourself for this type, without peeking at my solution, I suspect you will discover why GHC balks at deriving these classes for GADTs. (At the very least, it took me a few tries! The obvious definitions don't type-check, and the slightly less obvious definitions had the wrong behavior.)

Now we are ready to write a function that produces a dictionary for a number.

```
typeEnum :: Number -> TypeDict
typeEnum (Number Integer _) = TypeDict Integer
typeEnum (Number Rational _) = TypeDict Rational
typeEnum (Number Real _) = TypeDict Real
typeEnum (Number Complex _) = TypeDict Complex
```

We will also need the casting function; you can essentially just concatenate your definitions of `toComplex`

and friends here:

```
-- combines toComplex, toFrac, toReal, toInt
to :: TypeEnum a -> Number -> Maybe a
to Rational (Number Integer n) = Just (fromInteger n)
to Rational (Number Rational n) = Just n
to Rational _ = Nothing
-- etc.
to _ _ = Nothing
```

Once we have this machinery in place, `liftNum`

is surprisingly short. We just find the appropriate type to cast to, get a dictionary for that type, and perform the casts and the operation.

```
liftNum :: (forall a. Num a => a -> a -> a) -> Number -> Number -> Maybe Number
liftNum f a b = case typeEnum a `max` typeEnum b of
TypeDict ty -> Number ty <$> liftA2 f (to ty a) (to ty b)
```

At this point you may be complaining: your ultimate goal was to not have one case per class instance in `liftNum`

, and we've achieved that goal, but it looks like we just pushed it off into the definition of `typeEnum`

, where there is one case per class instance. However, I defend myself: you have not shown us your `typeEnum`

, which I suspect already had one case per class instance. So we have not incurred any *new* cost in functions other than `liftNum`

, and have indeed significantly simplified `liftNum`

. This also gives a smooth upgrade path for more complex `Complex`

manipulations: extend the `TypeEnum`

definition, the cast `ordering`

, and the `to`

function and you're good to go; `liftNum`

may stay the same. (If it turns out that types are not linearly ordered but instead some kind of lattice or similar, then you can switch away from the `Ord`

class.)