Given an arbitrary tree, I can construct a subtype relation over that tree, using Schubert numbering:

```
constructH :: Tree a -> Tree (Type a)
```

where `Type`

nests the original label, and additionally provides the data needed to perform child/parent (or subtype) checks. With Schubert Numbering, the two Int parameters are sufficient for that.

```
data Type a where !Int -> !Int -> a -> Type a
```

This leads to the binary predicate

```
subtypeOf :: Type a -> Type a -> Bool
```

I now want to test with QuickCheck that this does indeed do what I want it to do. The following property, however, does not work, because QuickCheck just gives up:

```
subtypeSanity ∷ Tree (Type ()) → Gen Prop
subtypeSanity Node { rootLabel = t, subForest = f } =
let subtypes = concatMap flatten f
in (not $ null subtypes) ==> conjoin
(forAll (elements subtypes) (\x → x `subtypeOf` t):(map subtypeSanity f))
```

If I leave out the recursive call to `subtypeSanity`

, i.e. the tail of the list I'm passing to `conjoin`

, the property runs fine, but tests just the root node of the tree! How can I descend into my data structure recursively without QuickCheck giving up on generating new test cases?

If needed, I could provide the code to construct the Schubert Hierarchy, and the `Arbitrary`

instance for `Tree (Type a)`

, to provide a complete runnable example, but that would be quite a bit of code. I'm convinced that I'm just not "getting" QuickCheck, and using it in the wrong way here.

EDIT: unfortunately, the `sized`

function does not seem to eliminate the problem here. It ends up with the same result (see comment to J. Abrahamson's answer.)

EDIT II: I ended up "fixing" my problem by avoiding the recursive step, and avoiding `conjoin`

. We just make a list of all nodes in the tree, then test the single-node property (which worked fine from the beginning) on those.

```
allNodes ∷ Tree a → [Tree a]
allNodes n@(Node { subForest = f }) = n:(concatMap allNodes f)
subtypeSanity ∷ Tree (Type ()) → Gen Prop
subtypeSanity tree = forAll (elements $ allNodes tree)
(\(Node { rootLabel = t, subForest = f }) →
let subtypes = concatMap flatten f
in (not $ null subtypes) ==> forAll (elements subtypes) (\x → x `subtypeOf` t))
```

Tweaking the `Arbitrary`

instance for trees did not work. Here is the arbitrary instance I'm still using:

```
instance (Arbitrary a, Eq a) ⇒ Arbitrary (Tree (Type a)) where
arbitrary = liftM (constructH) $ sized arbTree
arbTree ∷ Arbitrary a ⇒ Int → Gen (Tree a)
arbTree n = do
m ← choose (0,n)
if m == 0
then Node <$> arbitrary <*> (return [])
else do part ← randomPartition n m
Node <$> arbitrary <*> mapM arbTree part
-- this is a crude way to find a sufficiently random x1,..,xm,
-- such that x1 + .. + xm = n, for any n, m, with 0 < m.
randomPartition ∷ Int → Int → Gen [Int]
randomPartition n m' = do
let m = m' - 1
seed ← liftM ((++[n]) . sort) $ replicateM m (choose (0,n))
return $ zipWith (-) seed (0:seed)
```

I consider the problem "solved for now," but if someone could explain to me why the recursive step and/or `conjoin`

made QuickCheck give up (after passing "only" 0 tests,) I would be more than grateful.