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?