pub struct AtomicPtr<T> { /* private fields */ }Expand description
A raw pointer type which can be safely shared between threads.
This type has the same in-memory representation as a *mut T.
Note: This type is only available on platforms that support atomic loads and stores of pointers. Its size depends on the target pointer’s size.
Implementations
sourceimpl<T> AtomicPtr<T>
impl<T> AtomicPtr<T>
const: 1.24.0 · sourcepub const fn new(p: *mut T) -> AtomicPtr<T>
pub const fn new(p: *mut T) -> AtomicPtr<T>
Creates a new AtomicPtr.
Examples
use std::sync::atomic::AtomicPtr;
let ptr = &mut 5;
let atomic_ptr = AtomicPtr::new(ptr);1.15.0 · sourcepub fn get_mut(&mut self) -> &mut *mut T
pub fn get_mut(&mut self) -> &mut *mut T
Returns a mutable reference to the underlying pointer.
This is safe because the mutable reference guarantees that no other threads are concurrently accessing the atomic data.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let mut data = 10;
let mut atomic_ptr = AtomicPtr::new(&mut data);
let mut other_data = 5;
*atomic_ptr.get_mut() = &mut other_data;
assert_eq!(unsafe { *atomic_ptr.load(Ordering::SeqCst) }, 5);sourcepub fn from_mut(v: &mut *mut T) -> &mut AtomicPtr<T>
🔬This is a nightly-only experimental API. (atomic_from_mut)
pub fn from_mut(v: &mut *mut T) -> &mut AtomicPtr<T>
atomic_from_mut)Get atomic access to a pointer.
Examples
#![feature(atomic_from_mut)]
use std::sync::atomic::{AtomicPtr, Ordering};
let mut data = 123;
let mut some_ptr = &mut data as *mut i32;
let a = AtomicPtr::from_mut(&mut some_ptr);
let mut other_data = 456;
a.store(&mut other_data, Ordering::Relaxed);
assert_eq!(unsafe { *some_ptr }, 456);sourcepub fn get_mut_slice(this: &mut [AtomicPtr<T>]) -> &mut [*mut T]
🔬This is a nightly-only experimental API. (atomic_from_mut)
pub fn get_mut_slice(this: &mut [AtomicPtr<T>]) -> &mut [*mut T]
atomic_from_mut)Get non-atomic access to a &mut [AtomicPtr] slice.
This is safe because the mutable reference guarantees that no other threads are concurrently accessing the atomic data.
Examples
#![feature(atomic_from_mut, inline_const)]
use std::ptr::null_mut;
use std::sync::atomic::{AtomicPtr, Ordering};
let mut some_ptrs = [const { AtomicPtr::new(null_mut::<String>()) }; 10];
let view: &mut [*mut String] = AtomicPtr::get_mut_slice(&mut some_ptrs);
assert_eq!(view, [null_mut::<String>(); 10]);
view
.iter_mut()
.enumerate()
.for_each(|(i, ptr)| *ptr = Box::into_raw(Box::new(format!("iteration#{i}"))));
std::thread::scope(|s| {
for ptr in &some_ptrs {
s.spawn(move || {
let ptr = ptr.load(Ordering::Relaxed);
assert!(!ptr.is_null());
let name = unsafe { Box::from_raw(ptr) };
println!("Hello, {name}!");
});
}
});sourcepub fn from_mut_slice(v: &mut [*mut T]) -> &mut [AtomicPtr<T>]
🔬This is a nightly-only experimental API. (atomic_from_mut)
pub fn from_mut_slice(v: &mut [*mut T]) -> &mut [AtomicPtr<T>]
atomic_from_mut)Get atomic access to a slice of pointers.
Examples
#![feature(atomic_from_mut)]
use std::ptr::null_mut;
use std::sync::atomic::{AtomicPtr, Ordering};
let mut some_ptrs = [null_mut::<String>(); 10];
let a = &*AtomicPtr::from_mut_slice(&mut some_ptrs);
std::thread::scope(|s| {
for i in 0..a.len() {
s.spawn(move || {
let name = Box::new(format!("thread{i}"));
a[i].store(Box::into_raw(name), Ordering::Relaxed);
});
}
});
for p in some_ptrs {
assert!(!p.is_null());
let name = unsafe { Box::from_raw(p) };
println!("Hello, {name}!");
}1.15.0 (const: unstable) · sourcepub fn into_inner(self) -> *mut T
pub fn into_inner(self) -> *mut T
Consumes the atomic and returns the contained value.
This is safe because passing self by value guarantees that no other threads are
concurrently accessing the atomic data.
Examples
use std::sync::atomic::AtomicPtr;
let mut data = 5;
let atomic_ptr = AtomicPtr::new(&mut data);
assert_eq!(unsafe { *atomic_ptr.into_inner() }, 5);sourcepub fn load(&self, order: Ordering) -> *mut T
pub fn load(&self, order: Ordering) -> *mut T
Loads a value from the pointer.
load takes an Ordering argument which describes the memory ordering
of this operation. Possible values are SeqCst, Acquire and Relaxed.
Panics
Panics if order is Release or AcqRel.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let value = some_ptr.load(Ordering::Relaxed);sourcepub fn store(&self, ptr: *mut T, order: Ordering)
pub fn store(&self, ptr: *mut T, order: Ordering)
Stores a value into the pointer.
store takes an Ordering argument which describes the memory ordering
of this operation. Possible values are SeqCst, Release and Relaxed.
Panics
Panics if order is Acquire or AcqRel.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let other_ptr = &mut 10;
some_ptr.store(other_ptr, Ordering::Relaxed);sourcepub fn swap(&self, ptr: *mut T, order: Ordering) -> *mut T
pub fn swap(&self, ptr: *mut T, order: Ordering) -> *mut T
Stores a value into the pointer, returning the previous value.
swap takes an Ordering argument which describes the memory ordering
of this operation. All ordering modes are possible. Note that using
Acquire makes the store part of this operation Relaxed, and
using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic operations on pointers.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let other_ptr = &mut 10;
let value = some_ptr.swap(other_ptr, Ordering::Relaxed);sourcepub fn compare_and_swap(
&self,
current: *mut T,
new: *mut T,
order: Ordering
) -> *mut T
👎Deprecated since 1.50.0: Use compare_exchange or compare_exchange_weak instead
pub fn compare_and_swap(
&self,
current: *mut T,
new: *mut T,
order: Ordering
) -> *mut T
compare_exchange or compare_exchange_weak insteadStores a value into the pointer if the current value is the same as the current value.
The return value is always the previous value. If it is equal to current, then the value
was updated.
compare_and_swap also takes an Ordering argument which describes the memory
ordering of this operation. Notice that even when using AcqRel, the operation
might fail and hence just perform an Acquire load, but not have Release semantics.
Using Acquire makes the store part of this operation Relaxed if it
happens, and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic operations on pointers.
Migrating to compare_exchange and compare_exchange_weak
compare_and_swap is equivalent to compare_exchange with the following mapping for
memory orderings:
| Original | Success | Failure |
|---|---|---|
| Relaxed | Relaxed | Relaxed |
| Acquire | Acquire | Acquire |
| Release | Release | Relaxed |
| AcqRel | AcqRel | Acquire |
| SeqCst | SeqCst | SeqCst |
compare_exchange_weak is allowed to fail spuriously even when the comparison succeeds,
which allows the compiler to generate better assembly code when the compare and swap
is used in a loop.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let other_ptr = &mut 10;
let value = some_ptr.compare_and_swap(ptr, other_ptr, Ordering::Relaxed);1.10.0 · sourcepub fn compare_exchange(
&self,
current: *mut T,
new: *mut T,
success: Ordering,
failure: Ordering
) -> Result<*mut T, *mut T>
pub fn compare_exchange(
&self,
current: *mut T,
new: *mut T,
success: Ordering,
failure: Ordering
) -> Result<*mut T, *mut T>
Stores a value into the pointer if the current value is the same as the current value.
The return value is a result indicating whether the new value was written and containing
the previous value. On success this value is guaranteed to be equal to current.
compare_exchange takes two Ordering arguments to describe the memory
ordering of this operation. success describes the required ordering for the
read-modify-write operation that takes place if the comparison with current succeeds.
failure describes the required ordering for the load operation that takes place when
the comparison fails. Using Acquire as success ordering makes the store part
of this operation Relaxed, and using Release makes the successful load
Relaxed. The failure ordering can only be SeqCst, Acquire or Relaxed.
Note: This method is only available on platforms that support atomic operations on pointers.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let other_ptr = &mut 10;
let value = some_ptr.compare_exchange(ptr, other_ptr,
Ordering::SeqCst, Ordering::Relaxed);1.10.0 · sourcepub fn compare_exchange_weak(
&self,
current: *mut T,
new: *mut T,
success: Ordering,
failure: Ordering
) -> Result<*mut T, *mut T>
pub fn compare_exchange_weak(
&self,
current: *mut T,
new: *mut T,
success: Ordering,
failure: Ordering
) -> Result<*mut T, *mut T>
Stores a value into the pointer if the current value is the same as the current value.
Unlike AtomicPtr::compare_exchange, this function is allowed to spuriously fail even when the
comparison succeeds, which can result in more efficient code on some platforms. The
return value is a result indicating whether the new value was written and containing the
previous value.
compare_exchange_weak takes two Ordering arguments to describe the memory
ordering of this operation. success describes the required ordering for the
read-modify-write operation that takes place if the comparison with current succeeds.
failure describes the required ordering for the load operation that takes place when
the comparison fails. Using Acquire as success ordering makes the store part
of this operation Relaxed, and using Release makes the successful load
Relaxed. The failure ordering can only be SeqCst, Acquire or Relaxed.
Note: This method is only available on platforms that support atomic operations on pointers.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let some_ptr = AtomicPtr::new(&mut 5);
let new = &mut 10;
let mut old = some_ptr.load(Ordering::Relaxed);
loop {
match some_ptr.compare_exchange_weak(old, new, Ordering::SeqCst, Ordering::Relaxed) {
Ok(_) => break,
Err(x) => old = x,
}
}1.53.0 · sourcepub fn fetch_update<F>(
&self,
set_order: Ordering,
fetch_order: Ordering,
f: F
) -> Result<*mut T, *mut T>where
F: FnMut(*mut T) -> Option<*mut T>,
pub fn fetch_update<F>(
&self,
set_order: Ordering,
fetch_order: Ordering,
f: F
) -> Result<*mut T, *mut T>where
F: FnMut(*mut T) -> Option<*mut T>,
Fetches the value, and applies a function to it that returns an optional
new value. Returns a Result of Ok(previous_value) if the function
returned Some(_), else Err(previous_value).
Note: This may call the function multiple times if the value has been
changed from other threads in the meantime, as long as the function
returns Some(_), but the function will have been applied only once to
the stored value.
fetch_update takes two Ordering arguments to describe the memory
ordering of this operation. The first describes the required ordering for
when the operation finally succeeds while the second describes the
required ordering for loads. These correspond to the success and failure
orderings of AtomicPtr::compare_exchange respectively.
Using Acquire as success ordering makes the store part of this
operation Relaxed, and using Release makes the final successful
load Relaxed. The (failed) load ordering can only be SeqCst,
Acquire or Relaxed.
Note: This method is only available on platforms that support atomic operations on pointers.
Considerations
This method is not magic; it is not provided by the hardware.
It is implemented in terms of AtomicPtr::compare_exchange_weak, and suffers from the same drawbacks.
In particular, this method will not circumvent the ABA Problem.
Examples
use std::sync::atomic::{AtomicPtr, Ordering};
let ptr: *mut _ = &mut 5;
let some_ptr = AtomicPtr::new(ptr);
let new: *mut _ = &mut 10;
assert_eq!(some_ptr.fetch_update(Ordering::SeqCst, Ordering::SeqCst, |_| None), Err(ptr));
let result = some_ptr.fetch_update(Ordering::SeqCst, Ordering::SeqCst, |x| {
if x == ptr {
Some(new)
} else {
None
}
});
assert_eq!(result, Ok(ptr));
assert_eq!(some_ptr.load(Ordering::SeqCst), new);sourcepub fn fetch_ptr_add(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_ptr_add(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Offsets the pointer’s address by adding val (in units of T),
returning the previous pointer.
This is equivalent to using wrapping_add to atomically perform the
equivalent of ptr = ptr.wrapping_add(val);.
This method operates in units of T, which means that it cannot be used
to offset the pointer by an amount which is not a multiple of
size_of::<T>(). This can sometimes be inconvenient, as you may want to
work with a deliberately misaligned pointer. In such cases, you may use
the fetch_byte_add method instead.
fetch_ptr_add takes an Ordering argument which describes the
memory ordering of this operation. All ordering modes are possible. Note
that using Acquire makes the store part of this operation
Relaxed, and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let atom = AtomicPtr::<i64>::new(core::ptr::null_mut());
assert_eq!(atom.fetch_ptr_add(1, Ordering::Relaxed).addr(), 0);
// Note: units of `size_of::<i64>()`.
assert_eq!(atom.load(Ordering::Relaxed).addr(), 8);sourcepub fn fetch_ptr_sub(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_ptr_sub(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Offsets the pointer’s address by subtracting val (in units of T),
returning the previous pointer.
This is equivalent to using wrapping_sub to atomically perform the
equivalent of ptr = ptr.wrapping_sub(val);.
This method operates in units of T, which means that it cannot be used
to offset the pointer by an amount which is not a multiple of
size_of::<T>(). This can sometimes be inconvenient, as you may want to
work with a deliberately misaligned pointer. In such cases, you may use
the fetch_byte_sub method instead.
fetch_ptr_sub takes an Ordering argument which describes the memory
ordering of this operation. All ordering modes are possible. Note that
using Acquire makes the store part of this operation Relaxed,
and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
Examples
#![feature(strict_provenance_atomic_ptr)]
use core::sync::atomic::{AtomicPtr, Ordering};
let array = [1i32, 2i32];
let atom = AtomicPtr::new(array.as_ptr().wrapping_add(1) as *mut _);
assert!(core::ptr::eq(
atom.fetch_ptr_sub(1, Ordering::Relaxed),
&array[1],
));
assert!(core::ptr::eq(atom.load(Ordering::Relaxed), &array[0]));sourcepub fn fetch_byte_add(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_byte_add(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Offsets the pointer’s address by adding val bytes, returning the
previous pointer.
This is equivalent to using wrapping_byte_add to atomically
perform ptr = ptr.wrapping_byte_add(val).
fetch_byte_add takes an Ordering argument which describes the
memory ordering of this operation. All ordering modes are possible. Note
that using Acquire makes the store part of this operation
Relaxed, and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let atom = AtomicPtr::<i64>::new(core::ptr::null_mut());
assert_eq!(atom.fetch_byte_add(1, Ordering::Relaxed).addr(), 0);
// Note: in units of bytes, not `size_of::<i64>()`.
assert_eq!(atom.load(Ordering::Relaxed).addr(), 1);sourcepub fn fetch_byte_sub(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_byte_sub(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Offsets the pointer’s address by subtracting val bytes, returning the
previous pointer.
This is equivalent to using wrapping_byte_sub to atomically
perform ptr = ptr.wrapping_byte_sub(val).
fetch_byte_sub takes an Ordering argument which describes the
memory ordering of this operation. All ordering modes are possible. Note
that using Acquire makes the store part of this operation
Relaxed, and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let atom = AtomicPtr::<i64>::new(core::ptr::invalid_mut(1));
assert_eq!(atom.fetch_byte_sub(1, Ordering::Relaxed).addr(), 1);
assert_eq!(atom.load(Ordering::Relaxed).addr(), 0);sourcepub fn fetch_or(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_or(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Performs a bitwise “or” operation on the address of the current pointer,
and the argument val, and stores a pointer with provenance of the
current pointer and the resulting address.
This is equivalent to using map_addr to atomically perform
ptr = ptr.map_addr(|a| a | val). This can be used in tagged
pointer schemes to atomically set tag bits.
Caveat: This operation returns the previous value. To compute the
stored value without losing provenance, you may use map_addr. For
example: a.fetch_or(val).map_addr(|a| a | val).
fetch_or takes an Ordering argument which describes the memory
ordering of this operation. All ordering modes are possible. Note that
using Acquire makes the store part of this operation Relaxed,
and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
This API and its claimed semantics are part of the Strict Provenance
experiment, see the module documentation for ptr for
details.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let pointer = &mut 3i64 as *mut i64;
let atom = AtomicPtr::<i64>::new(pointer);
// Tag the bottom bit of the pointer.
assert_eq!(atom.fetch_or(1, Ordering::Relaxed).addr() & 1, 0);
// Extract and untag.
let tagged = atom.load(Ordering::Relaxed);
assert_eq!(tagged.addr() & 1, 1);
assert_eq!(tagged.map_addr(|p| p & !1), pointer);sourcepub fn fetch_and(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_and(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Performs a bitwise “and” operation on the address of the current
pointer, and the argument val, and stores a pointer with provenance of
the current pointer and the resulting address.
This is equivalent to using map_addr to atomically perform
ptr = ptr.map_addr(|a| a & val). This can be used in tagged
pointer schemes to atomically unset tag bits.
Caveat: This operation returns the previous value. To compute the
stored value without losing provenance, you may use map_addr. For
example: a.fetch_and(val).map_addr(|a| a & val).
fetch_and takes an Ordering argument which describes the memory
ordering of this operation. All ordering modes are possible. Note that
using Acquire makes the store part of this operation Relaxed,
and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
This API and its claimed semantics are part of the Strict Provenance
experiment, see the module documentation for ptr for
details.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let pointer = &mut 3i64 as *mut i64;
// A tagged pointer
let atom = AtomicPtr::<i64>::new(pointer.map_addr(|a| a | 1));
assert_eq!(atom.fetch_or(1, Ordering::Relaxed).addr() & 1, 1);
// Untag, and extract the previously tagged pointer.
let untagged = atom.fetch_and(!1, Ordering::Relaxed)
.map_addr(|a| a & !1);
assert_eq!(untagged, pointer);sourcepub fn fetch_xor(&self, val: usize, order: Ordering) -> *mut T
🔬This is a nightly-only experimental API. (strict_provenance_atomic_ptr)
pub fn fetch_xor(&self, val: usize, order: Ordering) -> *mut T
strict_provenance_atomic_ptr)Performs a bitwise “xor” operation on the address of the current
pointer, and the argument val, and stores a pointer with provenance of
the current pointer and the resulting address.
This is equivalent to using map_addr to atomically perform
ptr = ptr.map_addr(|a| a ^ val). This can be used in tagged
pointer schemes to atomically toggle tag bits.
Caveat: This operation returns the previous value. To compute the
stored value without losing provenance, you may use map_addr. For
example: a.fetch_xor(val).map_addr(|a| a ^ val).
fetch_xor takes an Ordering argument which describes the memory
ordering of this operation. All ordering modes are possible. Note that
using Acquire makes the store part of this operation Relaxed,
and using Release makes the load part Relaxed.
Note: This method is only available on platforms that support atomic
operations on AtomicPtr.
This API and its claimed semantics are part of the Strict Provenance
experiment, see the module documentation for ptr for
details.
Examples
#![feature(strict_provenance_atomic_ptr, strict_provenance)]
use core::sync::atomic::{AtomicPtr, Ordering};
let pointer = &mut 3i64 as *mut i64;
let atom = AtomicPtr::<i64>::new(pointer);
// Toggle a tag bit on the pointer.
atom.fetch_xor(1, Ordering::Relaxed);
assert_eq!(atom.load(Ordering::Relaxed).addr() & 1, 1);