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.

`unsafeCoerceMutVar# :: MutVar# s a -> MutVar# s b`

... – Alec Mar 16 at 2:52`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`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 afunction; the two occurrences in`unsafeCoerce`

should be different`IORef`

s, 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`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`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