A lot of constraints seem to come together. Let's abstract these away.

```
type MonadNumState a m = (MonadState a m, Num a)
```

`MonadNumState`

is just a constraint synonym, so I get the benefit of functional dependencies at every use, and can easily throw a `MonadNumState a m`

into a context. Now, suppose I wish to abstract this into a constraint family:

```
class Iterator t where
type MonadIter t a m :: Constraint
next :: (MonadIter t a m) => m t
...
instance Iterator Foo where
type MonadIter Foo a m = (MonadState a m, Num a)
...
instance Iterator Bar where
type MonadIter Bar a m = (MonadRandom m, MonadSplit a m, RandomGen a)
...
```

But now `a`

is not a functional dependency. `next`

is virtually unusable since `a`

cannot be inferred. What can I do? Well, I could, of course, use a type family instead. `MonadState`

is written using fundeps, but it should be easy to convert the fundeps to type families.

```
instance (MonadState s m) => MonadStateFamily m where
type St m = s
get' = get
...
instance (MonadStateFamily m) => MonadState (St m) m where
get = get'
...
```

Guess not.

```
Foo.hs:25:3:
The RHS of an associated type declaration mentions type variable `s'
All such variables must be bound on the LHS
```

What else might I be able to do? What I really want is to existentially quantify away `s`

. I've not found any way to do that without explicit dictionary passing.

So, how do I get the benefit of fundeps for constraint families?