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I was following Conor McBride's "Kleisli arrows of outrageous fortune" paper and I've posted my implementation of his code here. Briefly, he defines the following types and classes:

type a :-> b = forall i . a i -> b i

class IFunctor f where imap :: (a :-> b) -> (f a :-> f b)

class (IFunctor m) => IMonad m where
    skip :: a :-> m a
    bind :: (a :-> m b) -> (m a :-> m b)

data (a := i) j where
    V :: a -> (a := i) i

Then he defines two types of binds, the latter of which uses (:=) to restrict the initial index:

-- Conor McBride's "demonic bind"
(?>=) :: (IMonad m) => m a i -> (a :-> m b) -> m b i
(?>=) = flip bind

-- Conor McBride's "angelic bind"   
(>>=) :: (IMonad m) => m (a := j) i -> (a -> m b j) -> m b i
m >>= f = bind (\(V a) -> f a) m

The latter bind works perfectly fine for rebinding do notation to use indexed monads with the RebindableSyntax extension, using the following corresponding definitions for return and fail:

return :: (IMonad m) => a -> m (a := i) i
return = skip . V

fail :: String -> m a i
fail = error

... but the problem is that I cannot get the former bind (i.e. (?>=)) to work. I tried instead defining (>>=) and return to be:

(>>=) :: (IMonad m) => m a i -> (a :-> m b) -> m b i
(>>=) = (?>=)

return :: (IMonad m) => a :-> m a
return = skip

Then I created a data type guaranteed to inhabit a specific index:

data Unit a where
    Unit :: Unit ()

But when I try to rebind do notation using the new definitions for (>>=) and return, it does not work, as demonstrated in the following example:

-- Without do notation
test1 = skip Unit >>= \Unit -> skip Unit

-- With do notation
test2 = do
    Unit <- skip Unit
    skip Unit

test1 type-checks, but test2 does not, which is weird, since I thought all that RebindableSyntax did was let do notation desugar test2 to test1, so if test1 type-checks, then why does not test2? The error I get is:

Couldn't match expected type `t0 -> t1'
            with actual type `a0 :-> m0 b0'
Expected type: m0 a0 i0 -> (t0 -> t1) -> m Unit ()
  Actual type: m0 a0 i0 -> (a0 :-> m0 b0) -> m0 b0 i0
In a stmt of a 'do' block: Unit <- skip Unit
In the expression:
  do { Unit <- skip Unit;
       skip Unit }

The error remains even when I use the explicit forall syntax instead of the :-> type operator.

Now, I know there is another problem with using the "demonic bind", which is that you can't define (>>), but I still wanted to see how far I could go with it. Can anybody explain why I cannot get GHC to desugar the "demonic bind", even when it would normally type-check?

share|improve this question
Since this came up in a newer duplicate question, I'll point out that nowadays GHC (currently 7.10.2) hardly supports ImpredicativeTypes at all, so a lot more than do notation breaks for this code now. – Ørjan Johansen Nov 2 '15 at 23:41
up vote 9 down vote accepted

IIUC, the GHC desugarer actually runs after the typechecker (source). That explains why the situation you observe is theoretically possible. The typechecker probably has some special typing rules for the do-notation, and those may be inconsistent with what the typechecker would do with the desugarred code.

Of course, it's reasonable to expect them to be consistent, so I would recommend filing a GHC bug.

share|improve this answer
Thanks for the link. I will check this out. If they agree that's the reason for the type error I'll accept your answer. – Gabriel Gonzalez Jun 16 '12 at 0:32
I'm also keen to know what's going on. I faced the same issue, but was less agitated. I expect the demonic polymorphism was unexpected: it's surprised lots of people. – pigworker Jun 16 '12 at 0:42

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