Trait scale_info::prelude::marker::Sync1.0.0[][src]

pub unsafe auto trait Sync { }
Expand description

Types for which it is safe to share references between threads.

This trait is automatically implemented when the compiler determines it’s appropriate.

The precise definition is: a type T is Sync if and only if &T is Send. In other words, if there is no possibility of undefined behavior (including data races) when passing &T references between threads.

As one would expect, primitive types like u8 and f64 are all Sync, and so are simple aggregate types containing them, like tuples, structs and enums. More examples of basic Sync types include “immutable” types like &T, and those with simple inherited mutability, such as Box<T>, Vec<T> and most other collection types. (Generic parameters need to be Sync for their container to be Sync.)

A somewhat surprising consequence of the definition is that &mut T is Sync (if T is Sync) even though it seems like that might provide unsynchronized mutation. The trick is that a mutable reference behind a shared reference (that is, & &mut T) becomes read-only, as if it were a & &T. Hence there is no risk of a data race.

Types that are not Sync are those that have “interior mutability” in a non-thread-safe form, such as Cell and RefCell. These types allow for mutation of their contents even through an immutable, shared reference. For example the set method on Cell<T> takes &self, so it requires only a shared reference &Cell<T>. The method performs no synchronization, thus Cell cannot be Sync.

Another example of a non-Sync type is the reference-counting pointer Rc. Given any reference &Rc<T>, you can clone a new Rc<T>, modifying the reference counts in a non-atomic way.

For cases when one does need thread-safe interior mutability, Rust provides atomic data types, as well as explicit locking via sync::Mutex and sync::RwLock. These types ensure that any mutation cannot cause data races, hence the types are Sync. Likewise, sync::Arc provides a thread-safe analogue of Rc.

Any types with interior mutability must also use the cell::UnsafeCell wrapper around the value(s) which can be mutated through a shared reference. Failing to doing this is undefined behavior. For example, transmute-ing from &T to &mut T is invalid.

See the Nomicon for more details about Sync.

Implementations on Foreign Types

NonNull pointers are not Sync because the data they reference may be aliased.

Conditionally mark BitSlice as Sync based on its T type argument.

In order for BitSlice to be Sync (that is, &BitSlice can be copied across thread boundaries), it must be capable of reading from memory without being invalidated by any other &mut BitSlice handles that alias the same memory address.

This is true when T is one of the fundamental integers, because no other &mut BitSlice handle can exist to effect mutations, or when T is a BitSafe type that implements atomic read-modify-write instructions, because it will guard against other &mut BitSlice modifications in hardware.

When T is a non-atomic BitSafe type, BitSlice cannot be Sync, because one &BitSlice moved across a thread boundary may read from memory that is modified by the originally-owning thread, but the instructions used to access memory do not guard against such data races.

A &BitSlice over aliased memory addresses is equivalent to either a &Cell or &AtomicT, depending on what the radium crate makes available for the register width.

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