Let's see what happens when we adapt GHC's Set code to accommodate infinite sets:

```
module InfSet where
data InfSet a = Bin a (InfSet a) (InfSet a)
-- create an infinite set by unfolding a value
ofUnfold :: (x -> (x, a, x)) -> x -> InfSet a
ofUnfold f x =
let (lx,a,rx) = f x
l = ofUnfold f lx
r = ofUnfold f rx
in Bin a l r
-- check for membership in the infinite set
member :: Ord a => a -> InfSet a -> Bool
member x (Bin y l r) = case compare x y of
LT -> member x l
GT -> member x r
EQ -> True
-- construct an infinite set representing a range of numbers
range :: Fractional a => (a, a) -> InfSet a
range = ofUnfold $ \(lo,hi) ->
let mid = (hi+lo) / 2
in ( (lo, mid), mid, (mid, hi) )
```

Note how, instead of constructing the infinite set from an infinite list,
I instead define a function `ofUnfold`

to unfold a single value into an infinite list.
It allows us to construct both branches lazily in parallel (we don't need to finish
one branch before constructing another).

Let's give it a whirl:

```
ghci> :l InfSet
[1 of 1] Compiling InfSet ( InfSet.hs, interpreted )
Ok, modules loaded: InfSet.
ghci> let r = range (0,128)
ghci> member 64 r
True
ghci> member 63 r
True
ghci> member 62 r
True
ghci> member (1/2) r
True
ghci> member (3/4) r
True
```

Well, that seems to work. What if we try a value outside of the Set?

```
ghci> member 129 r
^CInterrupted.
```

That will just run and run and never quit. There's no stopping branches in the inifinite set,
so the search never quits. We could check the original range somehow, but that's not practical for infinite sets of discrete elements:

```
ghci> let ex = ofUnfold (\f -> ( f . (LT:), f [EQ], f . (GT:) )) id
ghci> :t ex
ex :: InfSet [Ordering]
ghci> member [EQ] ex
True
ghci> member [LT,EQ] ex
True
ghci> member [EQ,LT] ex
^CInterrupted.
```

So infinite sets are *possible* but I'm not sure they're *useful*.