The Arc<T> documentation says:

impl<T> Sync for Arc<T> where T: Send + Sync + ?Sized
impl<T> Send for Arc<T> where T: Send + Sync + ?Sized

An Arc allows multiple threads to concurrently access the underlying T via an immutable reference &T. This is safe as long as T can't be modified in an unsynchronized manner via &T. This is true for all types with 'inherited mutability' (nearly all types) and false for the ones with unsynchronized 'interior mutability' (e.g. RefCell, ...).

As far as I understand it, the Send bound is not required here. For example, I think sharing my artificial type which implements Sync but not Send in an Arc is safe.

Lastly, &T itself also doesn't have this bound! In the documentation for Send and Sync we find:

impl<'a, T> Send for &'a T where T: Sync + ?Sized
impl<'a, T> Sync for &'a T where T: Sync + ?Sized

And as Arc<T> allows the same access to T as &T does, I don't understand why Arc<T> has the additional Send bound. Why is that?

  • I wonder if this is a remnant from when Send implied static, since sharing data across threads require static in the standard library at the moment. Jan 28, 2017 at 12:40

1 Answer 1


I believe this is because an Arc owns the value it contains, and is thus responsible for dropping it.

Consider the following sequence:

  • A value of type T is created in thread 1. It is not Send, which means it is not safe to move this value to another thread.
  • This value is moved into an Arc handle.
  • A clone of the handle is sent to thread 2.
  • The handle stored by thread 1 is dropped.
  • The handle stored by thread 2 is dropped. Since this is the last handle, it assumes full ownership of the stored value and drops it.

And just like that, we've moved a value of type T from one thread to another, violating memory safety.

&T doesn't require Send because dropping a &T never allows you to drop the underlying value.

Addendum: As an example of a type where this would be a problem, consider a type like struct Handle(usize); which is backed by a thread-local array of resources. If the Drop implementation for such a type is run on the wrong thread, this will lead to it either doing an out-of-bounds access (where it tries to destroy a resource that doesn't exist on this thread), or destroys a resource that's still in use.

  • Ahh! Right, thank you! @Matthieu M. even mentioned the hidden access via drop() in the other question. So I guess my statement "Arc<T> only accesses T in the same way &T does" is wrong, because Arc<T> mutably access T for drop(). Awesome! Jan 28, 2017 at 12:49
  • One thing thought: could you maybe use my Foo type from the other question to show that we could achieve unsafety? I think a specific example is easier to understand than "a T that is not Send". Jan 28, 2017 at 12:51
  • 2
    @LukasKalbertodt I don't think that specific example would be a problem in practice. Off the top of my head, things like handles into thread-local storage, or OS values that must only be used from a specific thread come to mind. Think something like struct Handle(usize); that indexes into a thread-local array of resources; dropping it on the wrong thread would result in either an out-of-bounds access, or deleting the wrong resource.
    – DK.
    Jan 28, 2017 at 12:54
  • Oh, true. My bad, you are right. And you just showed me another example for a type implementing Sync but not Send. Interesting... thanks! Jan 28, 2017 at 13:00
  • 1
    Also note that Arc<T> provides a method try_unwrap() which consumes the Arc<T> and moves the contained T out, if the strong ref count is one. That's another way to move T to another thread.
    – jtepe
    Jan 30, 2017 at 14:20

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