For another answer of mine, I wrote the following code, providing diagonally traversed `Universe`

instances for enumerable `Generic`

s (it's slightly updated from the version there, but uses the same logic):

```
{-# LANGUAGE DeriveGeneric, TypeOperators, ScopedTypeVariables #-}
{-# LANGUAGE FlexibleInstances, FlexibleContexts, DefaultSignatures #-}
{-# LANGUAGE UndecidableInstances, OverlappingInstances #-}
import Data.Universe
import Control.Monad.Omega
import GHC.Generics
import Control.Monad (mplus, liftM2)
class GUniverse f where
guniverse :: Omega (f x)
instance GUniverse U1 where
guniverse = return U1
instance (Universe c) => GUniverse (K1 i c) where
guniverse = fmap K1 $ each (universe :: [c]) -- (1)
instance (GUniverse f) => GUniverse (M1 i c f) where
guniverse = fmap M1 (guniverse :: Omega (f p))
instance (GUniverse f, GUniverse g) => GUniverse (f :*: g) where
guniverse = liftM2 (:*:) ls rs
where ls = (guniverse :: Omega (f p))
rs = (guniverse :: Omega (g p))
instance (GUniverse f, GUniverse g) => GUniverse (f :+: g) where
guniverse = (fmap L1 $ ls) `mplus` (fmap R1 $ rs) -- (2)
where ls = (guniverse :: Omega (f p))
rs = (guniverse :: Omega (g p))
instance (Generic a, GUniverse (Rep a)) => Universe a where
universe = runOmega $ fmap to $ (guniverse :: Omega (Rep a x))
```

(`Omega`

is probably not related to the problem, but was part of the question.)

This works for most types, even recursive ones like those:

```
data T6 = T6' | T6 T6 deriving (Show, Generic)
data T = A | B T | C T T deriving (Show, Generic)
data Tree a = Leaf a | Branch (Tree a) (Tree a) deriving (Show, Generic, Eq)
```

Examples:

```
*Main> take 5 $ (universe :: [T6])
[T6',T6 T6',T6 (T6 T6'),T6 (T6 (T6 T6')),T6 (T6 (T6 (T6 T6')))]
*Main> take 5 $ (universe :: [T])
[A,B A,B (B A),C A A,B (B (B A))]
*Main> take 5 $ (universe :: [Tree Bool])
[Leaf False,Leaf True,Branch (Leaf False) (Leaf False),Branch (Leaf False) (Leaf True),Branch (Leaf True) (Leaf False)]
```

But note that above types all have their recursive constructors *not at the first place*! In fact (and this is the problem), the following diverges:

```
*Main> data T7 = T7 T7 | T7' deriving (Show, Generic)
*Main> take 5 $ (universe :: [T7])
*** Exception: <<loop>>
```

I first thought that maybe there's something with `Omegas`

's evaluation order, but swapping the left and right parts in line `(2)`

only makes `T7`

work, and `T6`

fail, which is what I'd expect as correct behavior.

My current suspicion is that the call to `universe`

in line `(1)`

is evaluated too early. For example, the following also diverges, while there should be exactly *one* value in the list, which should not even be evaluated:

```
*Main> data T8 = T8 T8 deriving (Show, Generic)
*Main> null $ (universe :: [T8])
*** Exception: <<loop>>
```

So, the only instance, `T8 (T8 (...) ... )`

, gets evaluated *inside the list*, even though it is not needed! I have no idea where this effect is coming from -- is it the recursive use of its own `Universe`

instance? But why, then, do "right recursive" types like `T6`

behave correctly, while "left recursive" ones (`T7`

) don't?

Is this a strictness issue? If so, in which part of the code? My `Universe`

instance? `Generic`

? And how to fix it? I use GHC 7.6.3, if that matters.