Struct std::sync::Arc 1.0.0[−][src]
pub struct Arc<T> where
T: ?Sized, { /* fields omitted */ }Expand description
A thread-safe reference-counting pointer. ‘Arc’ stands for ‘Atomically Reference Counted’.
The type Arc<T> provides shared ownership of a value of type T,
allocated in the heap. Invoking clone on Arc produces
a new Arc instance, which points to the same allocation on the heap as the
source Arc, while increasing a reference count. When the last Arc
pointer to a given allocation is destroyed, the value stored in that allocation (often
referred to as “inner value”) is also dropped.
Shared references in Rust disallow mutation by default, and Arc is no
exception: you cannot generally obtain a mutable reference to something
inside an Arc. If you need to mutate through an Arc, use
Mutex, RwLock, or one of the Atomic
types.
Thread Safety
Unlike Rc<T>, Arc<T> uses atomic operations for its reference
counting. This means that it is thread-safe. The disadvantage is that
atomic operations are more expensive than ordinary memory accesses. If you
are not sharing reference-counted allocations between threads, consider using
Rc<T> for lower overhead. Rc<T> is a safe default, because the
compiler will catch any attempt to send an Rc<T> between threads.
However, a library might choose Arc<T> in order to give library consumers
more flexibility.
Arc<T> will implement Send and Sync as long as the T implements
Send and Sync. Why can’t you put a non-thread-safe type T in an
Arc<T> to make it thread-safe? This may be a bit counter-intuitive at
first: after all, isn’t the point of Arc<T> thread safety? The key is
this: Arc<T> makes it thread safe to have multiple ownership of the same
data, but it doesn’t add thread safety to its data. Consider
Arc<RefCell<T>>. RefCell<T> isn’t Sync, and if Arc<T> was always
Send, Arc<RefCell<T>> would be as well. But then we’d have a problem:
RefCell<T> is not thread safe; it keeps track of the borrowing count using
non-atomic operations.
In the end, this means that you may need to pair Arc<T> with some sort of
std::sync type, usually Mutex<T>.
Breaking cycles with Weak
The downgrade method can be used to create a non-owning
Weak pointer. A Weak pointer can be upgraded
to an Arc, but this will return None if the value stored in the allocation has
already been dropped. In other words, Weak pointers do not keep the value
inside the allocation alive; however, they do keep the allocation
(the backing store for the value) alive.
A cycle between Arc pointers will never be deallocated. For this reason,
Weak is used to break cycles. For example, a tree could have
strong Arc pointers from parent nodes to children, and Weak
pointers from children back to their parents.
Cloning references
Creating a new reference from an existing reference-counted pointer is done using the
Clone trait implemented for Arc<T> and Weak<T>.
use std::sync::Arc;
let foo = Arc::new(vec![1.0, 2.0, 3.0]);
// The two syntaxes below are equivalent.
let a = foo.clone();
let b = Arc::clone(&foo);
// a, b, and foo are all Arcs that point to the same memory locationDeref behavior
Arc<T> automatically dereferences to T (via the Deref trait),
so you can call T’s methods on a value of type Arc<T>. To avoid name
clashes with T’s methods, the methods of Arc<T> itself are associated
functions, called using fully qualified syntax:
use std::sync::Arc;
let my_arc = Arc::new(());
Arc::downgrade(&my_arc);Arc<T>’s implementations of traits like Clone may also be called using
fully qualified syntax. Some people prefer to use fully qualified syntax,
while others prefer using method-call syntax.
use std::sync::Arc;
let arc = Arc::new(());
// Method-call syntax
let arc2 = arc.clone();
// Fully qualified syntax
let arc3 = Arc::clone(&arc);Weak<T> does not auto-dereference to T, because the inner value may have
already been dropped.
Examples
Sharing some immutable data between threads:
use std::sync::Arc;
use std::thread;
let five = Arc::new(5);
for _ in 0..10 {
let five = Arc::clone(&five);
thread::spawn(move || {
println!("{:?}", five);
});
}Sharing a mutable AtomicUsize:
use std::sync::Arc;
use std::sync::atomic::{AtomicUsize, Ordering};
use std::thread;
let val = Arc::new(AtomicUsize::new(5));
for _ in 0..10 {
let val = Arc::clone(&val);
thread::spawn(move || {
let v = val.fetch_add(1, Ordering::SeqCst);
println!("{:?}", v);
});
}See the rc documentation for more examples of reference
counting in general.
Implementations
Constructs a new Arc<T> using a weak reference to itself. Attempting
to upgrade the weak reference before this function returns will result
in a None value. However, the weak reference may be cloned freely and
stored for use at a later time.
Examples
#![feature(arc_new_cyclic)]
#![allow(dead_code)]
use std::sync::{Arc, Weak};
struct Foo {
me: Weak<Foo>,
}
let foo = Arc::new_cyclic(|me| Foo {
me: me.clone(),
});Constructs a new Arc with uninitialized contents.
Examples
#![feature(new_uninit)]
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut five = Arc::<u32>::new_uninit();
let five = unsafe {
// Deferred initialization:
Arc::get_mut_unchecked(&mut five).as_mut_ptr().write(5);
five.assume_init()
};
assert_eq!(*five, 5)Constructs a new Arc with uninitialized contents, with the memory
being filled with 0 bytes.
See MaybeUninit::zeroed for examples of correct and incorrect usage
of this method.
Examples
#![feature(new_uninit)]
use std::sync::Arc;
let zero = Arc::<u32>::new_zeroed();
let zero = unsafe { zero.assume_init() };
assert_eq!(*zero, 0)Constructs a new Pin<Arc<T>>. If T does not implement Unpin, then
data will be pinned in memory and unable to be moved.
Constructs a new Pin<Arc<T>>, return an error if allocation fails.
Constructs a new Arc with uninitialized contents, returning an error
if allocation fails.
Examples
#![feature(new_uninit, allocator_api)]
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut five = Arc::<u32>::try_new_uninit()?;
let five = unsafe {
// Deferred initialization:
Arc::get_mut_unchecked(&mut five).as_mut_ptr().write(5);
five.assume_init()
};
assert_eq!(*five, 5);Constructs a new Arc with uninitialized contents, with the memory
being filled with 0 bytes, returning an error if allocation fails.
See MaybeUninit::zeroed for examples of correct and incorrect usage
of this method.
Examples
#![feature(new_uninit, allocator_api)]
use std::sync::Arc;
let zero = Arc::<u32>::try_new_zeroed()?;
let zero = unsafe { zero.assume_init() };
assert_eq!(*zero, 0);Returns the inner value, if the Arc has exactly one strong reference.
Otherwise, an Err is returned with the same Arc that was
passed in.
This will succeed even if there are outstanding weak references.
Examples
use std::sync::Arc;
let x = Arc::new(3);
assert_eq!(Arc::try_unwrap(x), Ok(3));
let x = Arc::new(4);
let _y = Arc::clone(&x);
assert_eq!(*Arc::try_unwrap(x).unwrap_err(), 4);Constructs a new atomically reference-counted slice with uninitialized contents.
Examples
#![feature(new_uninit)]
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut values = Arc::<[u32]>::new_uninit_slice(3);
let values = unsafe {
// Deferred initialization:
Arc::get_mut_unchecked(&mut values)[0].as_mut_ptr().write(1);
Arc::get_mut_unchecked(&mut values)[1].as_mut_ptr().write(2);
Arc::get_mut_unchecked(&mut values)[2].as_mut_ptr().write(3);
values.assume_init()
};
assert_eq!(*values, [1, 2, 3])Constructs a new atomically reference-counted slice with uninitialized contents, with the memory being
filled with 0 bytes.
See MaybeUninit::zeroed for examples of correct and
incorrect usage of this method.
Examples
#![feature(new_uninit)]
use std::sync::Arc;
let values = Arc::<[u32]>::new_zeroed_slice(3);
let values = unsafe { values.assume_init() };
assert_eq!(*values, [0, 0, 0])Converts to Arc<T>.
Safety
As with MaybeUninit::assume_init,
it is up to the caller to guarantee that the inner value
really is in an initialized state.
Calling this when the content is not yet fully initialized
causes immediate undefined behavior.
Examples
#![feature(new_uninit)]
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut five = Arc::<u32>::new_uninit();
let five = unsafe {
// Deferred initialization:
Arc::get_mut_unchecked(&mut five).as_mut_ptr().write(5);
five.assume_init()
};
assert_eq!(*five, 5)Converts to Arc<[T]>.
Safety
As with MaybeUninit::assume_init,
it is up to the caller to guarantee that the inner value
really is in an initialized state.
Calling this when the content is not yet fully initialized
causes immediate undefined behavior.
Examples
#![feature(new_uninit)]
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut values = Arc::<[u32]>::new_uninit_slice(3);
let values = unsafe {
// Deferred initialization:
Arc::get_mut_unchecked(&mut values)[0].as_mut_ptr().write(1);
Arc::get_mut_unchecked(&mut values)[1].as_mut_ptr().write(2);
Arc::get_mut_unchecked(&mut values)[2].as_mut_ptr().write(3);
values.assume_init()
};
assert_eq!(*values, [1, 2, 3])Consumes the Arc, returning the wrapped pointer.
To avoid a memory leak the pointer must be converted back to an Arc using
Arc::from_raw.
Examples
use std::sync::Arc;
let x = Arc::new("hello".to_owned());
let x_ptr = Arc::into_raw(x);
assert_eq!(unsafe { &*x_ptr }, "hello");Provides a raw pointer to the data.
The counts are not affected in any way and the Arc is not consumed. The pointer is valid for
as long as there are strong counts in the Arc.
Examples
use std::sync::Arc;
let x = Arc::new("hello".to_owned());
let y = Arc::clone(&x);
let x_ptr = Arc::as_ptr(&x);
assert_eq!(x_ptr, Arc::as_ptr(&y));
assert_eq!(unsafe { &*x_ptr }, "hello");Constructs an Arc<T> from a raw pointer.
The raw pointer must have been previously returned by a call to
Arc<U>::into_raw where U must have the same size and
alignment as T. This is trivially true if U is T.
Note that if U is not T but has the same size and alignment, this is
basically like transmuting references of different types. See
mem::transmute for more information on what
restrictions apply in this case.
The user of from_raw has to make sure a specific value of T is only
dropped once.
This function is unsafe because improper use may lead to memory unsafety,
even if the returned Arc<T> is never accessed.
Examples
use std::sync::Arc;
let x = Arc::new("hello".to_owned());
let x_ptr = Arc::into_raw(x);
unsafe {
// Convert back to an `Arc` to prevent leak.
let x = Arc::from_raw(x_ptr);
assert_eq!(&*x, "hello");
// Further calls to `Arc::from_raw(x_ptr)` would be memory-unsafe.
}
// The memory was freed when `x` went out of scope above, so `x_ptr` is now dangling!Gets the number of Weak pointers to this allocation.
Safety
This method by itself is safe, but using it correctly requires extra care. Another thread can change the weak count at any time, including potentially between calling this method and acting on the result.
Examples
use std::sync::Arc;
let five = Arc::new(5);
let _weak_five = Arc::downgrade(&five);
// This assertion is deterministic because we haven't shared
// the `Arc` or `Weak` between threads.
assert_eq!(1, Arc::weak_count(&five));Gets the number of strong (Arc) pointers to this allocation.
Safety
This method by itself is safe, but using it correctly requires extra care. Another thread can change the strong count at any time, including potentially between calling this method and acting on the result.
Examples
use std::sync::Arc;
let five = Arc::new(5);
let _also_five = Arc::clone(&five);
// This assertion is deterministic because we haven't shared
// the `Arc` between threads.
assert_eq!(2, Arc::strong_count(&five));Increments the strong reference count on the Arc<T> associated with the
provided pointer by one.
Safety
The pointer must have been obtained through Arc::into_raw, and the
associated Arc instance must be valid (i.e. the strong count must be at
least 1) for the duration of this method.
Examples
use std::sync::Arc;
let five = Arc::new(5);
unsafe {
let ptr = Arc::into_raw(five);
Arc::increment_strong_count(ptr);
// This assertion is deterministic because we haven't shared
// the `Arc` between threads.
let five = Arc::from_raw(ptr);
assert_eq!(2, Arc::strong_count(&five));
}Decrements the strong reference count on the Arc<T> associated with the
provided pointer by one.
Safety
The pointer must have been obtained through Arc::into_raw, and the
associated Arc instance must be valid (i.e. the strong count must be at
least 1) when invoking this method. This method can be used to release the final
Arc and backing storage, but should not be called after the final Arc has been
released.
Examples
use std::sync::Arc;
let five = Arc::new(5);
unsafe {
let ptr = Arc::into_raw(five);
Arc::increment_strong_count(ptr);
// Those assertions are deterministic because we haven't shared
// the `Arc` between threads.
let five = Arc::from_raw(ptr);
assert_eq!(2, Arc::strong_count(&five));
Arc::decrement_strong_count(ptr);
assert_eq!(1, Arc::strong_count(&five));
}Makes a mutable reference into the given Arc.
If there are other Arc pointers to the same allocation, then make_mut will
clone the inner value to a new allocation to ensure unique ownership. This is also
referred to as clone-on-write.
However, if there are no other Arc pointers to this allocation, but some Weak
pointers, then the Weak pointers will be disassociated and the inner value will not
be cloned.
See also get_mut, which will fail rather than cloning the inner value
or diassociating Weak pointers.
Examples
use std::sync::Arc;
let mut data = Arc::new(5);
*Arc::make_mut(&mut data) += 1; // Won't clone anything
let mut other_data = Arc::clone(&data); // Won't clone inner data
*Arc::make_mut(&mut data) += 1; // Clones inner data
*Arc::make_mut(&mut data) += 1; // Won't clone anything
*Arc::make_mut(&mut other_data) *= 2; // Won't clone anything
// Now `data` and `other_data` point to different allocations.
assert_eq!(*data, 8);
assert_eq!(*other_data, 12);Weak pointers will be disassociated:
use std::sync::Arc;
let mut data = Arc::new(75);
let weak = Arc::downgrade(&data);
assert!(75 == *data);
assert!(75 == *weak.upgrade().unwrap());
*Arc::make_mut(&mut data) += 1;
assert!(76 == *data);
assert!(weak.upgrade().is_none());Returns a mutable reference into the given Arc, if there are
no other Arc or Weak pointers to the same allocation.
Returns None otherwise, because it is not safe to
mutate a shared value.
See also make_mut, which will clone
the inner value when there are other Arc pointers.
Examples
use std::sync::Arc;
let mut x = Arc::new(3);
*Arc::get_mut(&mut x).unwrap() = 4;
assert_eq!(*x, 4);
let _y = Arc::clone(&x);
assert!(Arc::get_mut(&mut x).is_none());Returns a mutable reference into the given Arc,
without any check.
See also get_mut, which is safe and does appropriate checks.
Safety
Any other Arc or Weak pointers to the same allocation must not be dereferenced
for the duration of the returned borrow.
This is trivially the case if no such pointers exist,
for example immediately after Arc::new.
Examples
#![feature(get_mut_unchecked)]
use std::sync::Arc;
let mut x = Arc::new(String::new());
unsafe {
Arc::get_mut_unchecked(&mut x).push_str("foo")
}
assert_eq!(*x, "foo");Attempt to downcast the Arc<dyn Any + Send + Sync> to a concrete type.
Examples
use std::any::Any;
use std::sync::Arc;
fn print_if_string(value: Arc<dyn Any + Send + Sync>) {
if let Ok(string) = value.downcast::<String>() {
println!("String ({}): {}", string.len(), string);
}
}
let my_string = "Hello World".to_string();
print_if_string(Arc::new(my_string));
print_if_string(Arc::new(0i8));Trait Implementations
Performs copy-assignment from source. Read more
Drops the Arc.
This will decrement the strong reference count. If the strong reference
count reaches zero then the only other references (if any) are
Weak, so we drop the inner value.
Examples
use std::sync::Arc;
struct Foo;
impl Drop for Foo {
fn drop(&mut self) {
println!("dropped!");
}
}
let foo = Arc::new(Foo);
let foo2 = Arc::clone(&foo);
drop(foo); // Doesn't print anything
drop(foo2); // Prints "dropped!"use the Display impl or to_string()
replaced by Error::source, which can support downcasting
The lower-level source of this error, if any. Read more
Takes each element in the Iterator and collects it into an Arc<[T]>.
Performance characteristics
The general case
In the general case, collecting into Arc<[T]> is done by first
collecting into a Vec<T>. That is, when writing the following:
let evens: Arc<[u8]> = (0..10).filter(|&x| x % 2 == 0).collect();this behaves as if we wrote:
let evens: Arc<[u8]> = (0..10).filter(|&x| x % 2 == 0)
.collect::<Vec<_>>() // The first set of allocations happens here.
.into(); // A second allocation for `Arc<[T]>` happens here.This will allocate as many times as needed for constructing the Vec<T>
and then it will allocate once for turning the Vec<T> into the Arc<[T]>.
Iterators of known length
When your Iterator implements TrustedLen and is of an exact size,
a single allocation will be made for the Arc<[T]>. For example:
let evens: Arc<[u8]> = (0..10).collect(); // Just a single allocation happens here.Equality for two Arcs.
Two Arcs are equal if their inner values are equal, even if they are
stored in different allocation.
If T also implements Eq (implying reflexivity of equality),
two Arcs that point to the same allocation are always equal.
Examples
use std::sync::Arc;
let five = Arc::new(5);
assert!(five == Arc::new(5));Auto Trait Implementations
impl<T: ?Sized> RefUnwindSafe for Arc<T> where
T: RefUnwindSafe,
Blanket Implementations
Mutably borrows from an owned value. Read more