Your `Scheduler`

class

```
class Scheduler s where
add :: (Schedulable a) => a -> s -> s
next :: (Schedulable a) => s -> (a, s)
empty :: s -> Bool
```

is not going to work.

`add`

promises that values of any `Schedulable`

type can be added to the scheduler. That is possible, but it requires an extension, `ExistentialQuantification`

or `GADTs`

would allow to define a type wrapping *any* `Schedulable`

value.

`next`

, however, promises to deliver a value of *any* `Schedulable`

type, whatever the caller desires, and that's not going to work. If I only ever add `Int`

values to the scheduler, and then ask for a `String`

, how would it construct one out of thin air?

One way to get your code to work is

```
{-# LANGUAGE GADTs #-}
module Schedules where
class Schedulable s where
isFinal :: s -> Bool
class Scheduler s where
add :: (Schedulable a) => a -> s -> s
next :: s -> (Schedule, s) -- returns a Schedulable item of unknown type, wrapped in a Schedule
empty :: s -> Bool
-- Wrapper type for any Schedulable
data Schedule where
Schedule :: Schedulable a => a -> Schedule
-- Equivalent alternative using existential quantification instead of GADT syntax
-- data Schedule = forall a. Schedulable a => Schedule a
-- make Schedules Schedulable, maybe not necessary
instance Schedulable Schedule where
isFinal (Schedule s) = isFinal s
-- RoundRobin queues schedulable items, wrapped as Schedules, since lists are homogeneous
data RoundRobin = RoundRobin [Schedule] [Schedule]
-- How RoundRobin works
instance Scheduler RoundRobin where
-- enqueue item after wrapping it
add p (RoundRobin ps qs) = RoundRobin (ps ++ [Schedule p]) qs
-- deliver next item to process
-- the first equation suggests that (Maybe Schedule, s) would be the better return type
next (RoundRobin [] []) = error "Nothing to schedule"
next (RoundRobin [] qs) = next (RoundRobin qs [])
next (RoundRobin (p:ps) qs) = (p, RoundRobin ps (qs ++ [p]))
empty (RoundRobin [] _) = True
empty _ = False
```

Using `GADT`

syntax or existential quantification makes the constraints imposed on the constructor available via pattern matching, in contrast to the old `DatatypeContexts`

that despite the constraints on the type, required the context put on the functions using the type.