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In GHC, the equality instance for IORef and STRef are based on the following primitive operation:

sameMutVar# :: MutVar# s a -> MutVar# s a -> Int#

I would like to be able to compute a heterogeneous reference equality,

sameReference :: IORef a -> IORef b -> Bool

(or similarly for STRefs with potentially different types). Is it okay to just use unsafeCoerce for the purpose of checking the reference equality? Is there a reason that sameMutVar# is not given a heterogenous type signature?

EDIT: To add some context, I would like to have this hetereogenous pointer equality because I want to use the equality method to remove a particular IORef a from a list of IORefs whose types are existentially quantified over.

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    Should be safe... In fact, I'm a bit surprised there isn't an unsafeCoerceMutVar# :: MutVar# s a -> MutVar# s b... – Alec Mar 16 at 2:52
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    I think it would be possible to admit as a primitive sameRef :: IORef a -> IORef b -> Maybe (a :~: b) since if the references are equal, then the types must be the same. I'd expect unsafe coercions could actually be safe in this case, but I can't back this up. – chi Mar 16 at 9:48
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    @chi I don't think so. Remember the classic polyRef :: IORef [a]; polyRef = unsafePerformIO $ newIORef []; unsafeCoerce :: a -> IO b; unsafeCoerce x = writeIORef polyRef [x] >> head <$> readIORef polyRef. Granted, I feel this behavior is a mistake: polyRef is a function; the two occurrences in unsafeCoerce should be different IORefs, and your sameRef should be fine. However, I'm not in charge, so, in the current situation, your sameRef is probably not the best idea. The Bool version seems OK, however. – HTNW Mar 17 at 2:16
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    @chi, in this case, plain old safe coerce is enough to break everything. oops :: Coercible a b => IORef a -> a :~: b; oops ref = fromJust (sameRef ref (coerce ref)). – dfeuer Mar 18 at 22:28
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    @dfeuer Ah, that's an excellent point, thanks! I guess it should be something like sameRef :: ... -> Maybe (Dict (Coercible a b)) then. (Or changing the role of IORef's argument, but that's probably overkill). Still, my point is that I'd rather get a Maybe SomeProof than a boring boolean, if possible. – chi Mar 18 at 22:55
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It is perfectly safe to write

sameReference :: IORef a -> IORef b -> Bool
sameReference = unsafeCoerce ((==) :: IORef a -> IORef a -> Bool)

It would have been entirely reasonable for the primop to have been given type

sameMutVar# :: MutVar# s a -> MutVar# s b -> Int#

but the designers apparently felt that using that function on references of different types was more likely to be a mistake than otherwise.

What you can't do safely is conclude that sameReference (r1 :: IORef a) (r2 :: IORef b) = True implies that a and b are the same. Suppose you had

sameRefSameType :: IORef a -> IORef b -> Maybe (a :~: b)

Then you could easily write

oops :: Coercible a b => IORef a -> a :~: b
oops r = fromJust (sameRefSameType r (coerce r))

producing bogus evidence that any two coercible types are equal. You should be able to figure out how to use a GADT to get from there to mkUC :: IO (a -> b).

I believe that it would be safe to write

sameRefCoercibleTypes :: IORef a -> IORef b -> Maybe (Coercion a b)

Since Daniel Wagner mentioned stable names, I should mention that the situation for those is even worse in this context. I'll need to start with a bit of background. Suppose you write

f :: Either x Int -> Either x Bool
f (Left x) = Left x
f (Right _) = Right False

In the first case, it would be a shame to allocate a fresh Left constructor just to change the type. So GHC has a low-level optimization (after the core-to-core optimization pipeline) that tries to turn this into (essentially)

f p@(Left x) = unsafeCoerce p
f (Right _) = Right False

That means that you could have m :: Either x a and n :: Either x b where m and n refer to the same heap object despite a and b having completely unrelated types. If you create a stable name for m and a stable name for n, then those stable names will compare equal! If you posit even as much as

sameSNCoercibleTypes
  :: StableName a
  -> StableName b
  -> Maybe (Coercion a b)

then you can use m and n to "prove" Coercible (Either x a) (Either x b) from which you can convert any a into any b. It's a bit delicate, but since it's possible at all, assuming otherwise is rather unsafe.

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    The last part about the low-level optimization is a bit scary, but OTOH it's good to know that the runtime can allow values of different type to share their representation. – chi Mar 18 at 23:09
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    I suggested StableName because the StableName API already offers heterogeneous equality via eqStableName :: StableName a -> StableName b -> Bool. So getting a Bool out (rather than your proposed coercion) can't be that dangerous. – Daniel Wagner Mar 21 at 12:10

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