`Set`

, similarly to `[]`

has a perfectly defined monadic operations. The problem is that they require that the values satisfy `Ord`

constraint, and so it's impossible to define `return`

and `>>=`

without any constraints. The same problem applies to many other data structures that require some kind of constraints on possible values.

The standard trick (suggested to me in a haskell-cafe post) is to wrap `Set`

into the continuation monad. `ContT`

doesn't care if the underlying type functor has any constraints. The constraints become only needed when wrapping/unwrapping `Set`

s into/from continuations:

```
import Control.Monad.Cont
import Data.Foldable (foldrM)
import Data.Set
setReturn :: a -> Set a
setReturn = singleton
setBind :: (Ord b) => Set a -> (a -> Set b) -> Set b
setBind set f = foldl' (\s -> union s . f) empty set
type SetM r a = ContT r Set a
fromSet :: (Ord r) => Set a -> SetM r a
fromSet = ContT . setBind
toSet :: SetM r r -> Set r
toSet c = runContT c setReturn
```

This works as needed. For example, we can simulate a non-deterministic function that either increases its argument by 1 or leaves it intact:

```
step :: (Ord r) => Int -> SetM r Int
step i = fromSet $ fromList [i, i + 1]
-- repeated application of step:
stepN :: Int -> Int -> Set Int
stepN times start = toSet $ foldrM ($) start (replicate times step)
```

Indeed, `stepN 5 0`

yields `fromList [0,1,2,3,4,5]`

. If we used `[]`

monad instead, we would get

```
[0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4,1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5]
```

instead.

The problem is **efficiency**. If we call `stepN 20 0`

the output takes a few seconds and `stepN 30 0`

doesn't finish within a reasonable amount of time. It turns out that all `Set.union`

operations are performed at the end, instead of performing them after each monadic computation. The result is that exponentially many `Set`

s are constructed and `union`

ed only at the end, which is unacceptable for most tasks.

Is there any way around it, to make this construction efficient? I tried but without success.

(I even suspect that there could be some kinds of theoretical limits following from Curry-Howard isomorphism and Glivenko's theorem. Glivenko's theorem says that for any propositional tautology *φ* the formula *¬¬φ* can be proved in intuitionistic logic. However, I suspect that the length of the proof (in normal form) can be exponentially long. So, perhaps, there could be cases when wrapping a computation into the continuation monad will make it exponentially longer?)

`Monad`

instance for`Set`

unless there is also an efficient`Functor`

instance. And I'm having a hard time seeing how you can have an efficient`fmap`

for`Set`

. The existing`map`

for`Set`

is n * log n.`Set`

's implemented as strict trees, so laziness won't help you ever either. – Luis Casillas Aug 30 '12 at 1:12