As far as I know there's no "nice" way to accomplish this. You're stuck with adding cruft somewhere. Since you don't want wrapper types, the other option I can think of is messing with the class definitions instead, which means we're off to type-metaprogramming-land.

Now, the reason why this approach won't be "nice" is that class constraints are basically *irrevocable*. Once GHC sees the constraint, it's sticking with it, and if it can't satisfy the constraint compilation fails. This is fine for an "intersection" of class instances, but not helpful for a "union".

To get around this, we need *type predicates* with *type-level booleans*, rather than direct class constraints. In order to do that, we use **multi-parameter type classes with functional dependencies** to create type functions and **overlapping instances with delayed unification** to write "default instances".

First, we need some fun language pragmas:

```
{-# LANGUAGE TypeSynonymInstances #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE FunctionalDependencies #-}
{-# LANGUAGE OverlappingInstances #-}
{-# LANGUAGE UndecidableInstances #-}
```

Define some type-level booleans:

```
data Yes = Yes deriving Show
data No = No deriving Show
class TypeBool b where bval :: b
instance TypeBool Yes where bval = Yes
instance TypeBool No where bval = No
```

The `TypeBool`

class isn't strictly necessary--I mostly use it to avoid working with `undefined`

.

Next, we write membership predicates for the type classes we want to take the union of, with default instances to serve as the fall-through case:

```
class (TypeBool flag) => IsA a flag | a -> flag
class (TypeBool flag) => IsB b flag | b -> flag
instance (TypeBool flag, TypeCast flag No) => IsA a flag
instance (TypeBool flag, TypeCast flag No) => IsB b flag
```

The `TypeCast`

constraint is of course Oleg's infamous type unification class. The code for it can be found at the end of this answer. It's necessary here to delay picking the result type--the fundep says that the first parameter determines the second, and the default instances are fully generic, so putting `No`

directly in the instance head would be interpreted as the predicate always evaluating to false, which isn't helpful. Using `TypeCast`

instead waits until after GHC picks the most specific overlapped instance, which forces the result to be `No`

when, and only when, no more specific instance can be found.

I'm going to make another not strictly necessary adjustment to the type classes themselves:

```
class (IsA a Yes) => A a where
fA :: a -> Bool
gA :: a -> Int
class (IsB b Yes) => B b where
fB :: b -> Bool
gB :: b -> b -> String
```

The class context constraint ensures that, if we write an instance for a class without also writing the matching predicate instance, we'll get a cryptic error immediately rather than very confusing bugs later. I've also added a few functions to the classes for demonstration purposes.

Next, the union class gets split into two pieces. The first has a single universal instance that just applies the membership predicates and invokes the second, which maps predicate results to the actual instances.

```
class AB ab where
fAB :: ab -> Bool
instance (IsA ab isA, IsB ab isB, AB' isA isB ab) => AB ab where
fAB = fAB' (bval :: isA) (bval :: isB)
class AB' isA isB ab where fAB' :: isA -> isB -> ab -> Bool
instance (A a) => AB' Yes No a where fAB' Yes No = fA
instance (B b) => AB' No Yes b where fAB' No Yes = fB
instance (A ab) => AB' Yes Yes ab where fAB' Yes Yes = fA
-- instance (B ab) => AB' Yes Yes ab where fAB' Yes Yes = fB
```

Note that, if both predicates are true, we're explicitly choosing the `A`

instance. The commented out instance does the same, but uses `B`

instead. You could also remove both, in which case you'd get the exclusive disjunction of the two classes. The `bval`

here is where I'm using the `TypeBool`

class. Note also the type signatures to get the correct type boolean--this requires `ScopedTypeVariables`

, which we enabled above.

To wrap things up, some instances to try out:

```
instance IsA Int Yes
instance A Int where
fA = (> 0)
gA = (+ 1)
instance IsB String Yes
instance B String where
fB = not . null
gB = (++)
instance IsA Bool Yes
instance A Bool where
fA = id
gA = fromEnum
instance IsB Bool Yes
instance B Bool where
fB = not
gB x y = show (x && y)
```

Trying it out in GHCi:

```
> fAB True
True
> fAB ""
False
> fAB (5 :: Int)
True
> fAB ()
No instance for (AB' No No ())
. . .
```

And here's the `TypeCast`

code, courtesy of Oleg.

```
class TypeCast a b | a -> b, b->a where typeCast :: a -> b
class TypeCast' t a b | t a -> b, t b -> a where typeCast' :: t->a->b
class TypeCast'' t a b | t a -> b, t b -> a where typeCast'' :: t->a->b
instance TypeCast' () a b => TypeCast a b where typeCast x = typeCast' () x
instance TypeCast'' t a b => TypeCast' t a b where typeCast' = typeCast''
instance TypeCast'' () a a where typeCast'' _ x = x
```