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[-] TehPers@beehaw.org 2 points 1 year ago* (last edited 1 year ago)

If you run Miri on your code (Tools -> Miri in the Playground), it actually seems to complain about UB. I'm not experienced enough with unsafe rust to translate that error message to something meaningful though.

Edit: Wait, that's the while_here_it_isnt method. I'm clearly tired...

[-] soulsource@discuss.tchncs.de 1 points 1 year ago

Until yesterday I wouldn't have expected either to be sane. But then I got the reply above, that aliasing pointers is fine. The playground link is how I interpreted that statement.

So, if my previous intuition was correct, how is https://discuss.tchncs.de/comment/2544085 to be interpreted?

[-] TehPers@beehaw.org 1 points 1 year ago* (last edited 1 year ago)

Edit: Lemmy decided to completely butcher my comment, so I've replaced all the ampersands with %. Sorry, this will look a bit funny.

You (and they) are right that aliasing pointers is fine. I was running Miri on your playground link, and it gave the expected results. I was just too tired to realize that it was saying your failure case (where you did multiple mutable aliasing with borrows) caused UB and that your success case (where you did multiple mutable aliasing with pointers) did not cause UB.

Generally speaking, the rules around aliasing only apply to borrows in Rust, from my understanding. Any code that creates two %mut borrows of the same value is immediate UB. Any code that could possibly cause that to happen using safe code is unsound. Since your method operates only on the raw pointers, no aliasing rules have been broken, however the compiler also can't optimize around your code the same way it could had you used regular borrows (assuming it's possible). At a lower level, this is reflected by the compiler telling LLVM that %mut T values (usually) are not aliased, and LLVM applies optimizations around that. (Note that UnsafeCell is a bit of a weird case, but is fundamental to how the other cell types work.)

This is actually why shared pointers like Rc and Arc only give you shared borrows (%) of the values contained in them, and why you're required to implement some kind of interior mutability if you want to mutate the shared values. The shared pointer cannot guarantee that two borrows of the same value are not active at the same time, but does allow for shared ownership of it. The Cell/RefCell/Mutex/etc types verify that there is only one active %mut T (unique borrow) of the inner value at a time (or in Cell's case even allows you to mutate without ever receiving a %mut T).

Note that while %T and %mut T are often referred to as "immutable" and "mutable" references, it's probably more accurate to refer to them as "shared" and "unique" references. Mutability is not actually tied to whether you have a %T or a %mut T. This is trivially shown by looking at the Atomic* types, which only require a %self for their store operation.

this post was submitted on 31 Aug 2023
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