Struct gclient::ext::sp_core::sp_std::sync::atomic::AtomicI32

#[repr(C, align(4))]
pub struct AtomicI32 { /* private fields */ }

An integer type which can be safely shared between threads.

This type has the same in-memory representation as the underlying integer type, i32. For more about the differences between atomic types and non-atomic types as well as information about the portability of this type, please see the module-level documentation.

Note: This type is only available on platforms that support atomic loads and stores of i32.

Implementations

impl AtomicI32

pub const fn new(v: i32) -> AtomicI32

Creates a new atomic integer.

Examples

use std::sync::atomic::AtomicI32;

let atomic_forty_two = AtomicI32::new(42);

pub unsafe fn from_ptr<'a>(ptr: *mut i32) -> &'a AtomicI32

Creates a new reference to an atomic integer from a pointer.

Examples

#![feature(pointer_is_aligned)]
use std::sync::atomic::{self, AtomicI32};
use std::mem::align_of;

// Get a pointer to an allocated value
let ptr: *mut i32 = Box::into_raw(Box::new(0));

assert!(ptr.is_aligned_to(align_of::<AtomicI32>()));

{
    // Create an atomic view of the allocated value
    let atomic = unsafe {AtomicI32::from_ptr(ptr) };

    // Use `atomic` for atomic operations, possibly share it with other threads
    atomic.store(1, atomic::Ordering::Relaxed);
}

// It's ok to non-atomically access the value behind `ptr`,
// since the reference to the atomic ended its lifetime in the block above
assert_eq!(unsafe { *ptr }, 1);

// Deallocate the value
unsafe { drop(Box::from_raw(ptr)) }

Safety

• ptr must be aligned to align_of::<AtomicI32>() (note that on some platforms this can be bigger than align_of::<i32>()).
• ptr must be valid for both reads and writes for the whole lifetime 'a.
• You must adhere to the Memory model for atomic accesses. In particular, it is not allowed to mix atomic and non-atomic accesses, or atomic accesses of different sizes, without synchronization.

pub fn get_mut(&mut self) -> &mut i32

Returns a mutable reference to the underlying integer.

This is safe because the mutable reference guarantees that no other threads are concurrently accessing the atomic data.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let mut some_var = AtomicI32::new(10);
assert_eq!(*some_var.get_mut(), 10);
*some_var.get_mut() = 5;
assert_eq!(some_var.load(Ordering::SeqCst), 5);

pub fn from_mut(v: &mut i32) -> &mut AtomicI32

🔬This is a nightly-only experimental API. (atomic_from_mut)

Get atomic access to a &mut i32.

Note: This function is only available on targets where i32 has an alignment of 4 bytes.

Examples

#![feature(atomic_from_mut)]
use std::sync::atomic::{AtomicI32, Ordering};

let mut some_int = 123;
let a = AtomicI32::from_mut(&mut some_int);
a.store(100, Ordering::Relaxed);
assert_eq!(some_int, 100);

pub fn get_mut_slice(this: &mut [AtomicI32]) -> &mut [i32]

🔬This is a nightly-only experimental API. (atomic_from_mut)

Get non-atomic access to a &mut [AtomicI32] 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::sync::atomic::{AtomicI32, Ordering};

let mut some_ints = [const { AtomicI32::new(0) }; 10];

let view: &mut [i32] = AtomicI32::get_mut_slice(&mut some_ints);
assert_eq!(view, [0; 10]);
view
    .iter_mut()
    .enumerate()
    .for_each(|(idx, int)| *int = idx as _);

std::thread::scope(|s| {
    some_ints
        .iter()
        .enumerate()
        .for_each(|(idx, int)| {
            s.spawn(move || assert_eq!(int.load(Ordering::Relaxed), idx as _));
        })
});

pub fn from_mut_slice(v: &mut [i32]) -> &mut [AtomicI32]

🔬This is a nightly-only experimental API. (atomic_from_mut)

Get atomic access to a &mut [i32] slice.

Examples

#![feature(atomic_from_mut)]
use std::sync::atomic::{AtomicI32, Ordering};

let mut some_ints = [0; 10];
let a = &*AtomicI32::from_mut_slice(&mut some_ints);
std::thread::scope(|s| {
    for i in 0..a.len() {
        s.spawn(move || a[i].store(i as _, Ordering::Relaxed));
    }
});
for (i, n) in some_ints.into_iter().enumerate() {
    assert_eq!(i, n as usize);
}

pub fn into_inner(self) -> i32

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::AtomicI32;

let some_var = AtomicI32::new(5);
assert_eq!(some_var.into_inner(), 5);

pub fn load(&self, order: Ordering) -> i32

Loads a value from the atomic integer.

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::{AtomicI32, Ordering};

let some_var = AtomicI32::new(5);

assert_eq!(some_var.load(Ordering::Relaxed), 5);

pub fn store(&self, val: i32, order: Ordering)

Stores a value into the atomic integer.

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::{AtomicI32, Ordering};

let some_var = AtomicI32::new(5);

some_var.store(10, Ordering::Relaxed);
assert_eq!(some_var.load(Ordering::Relaxed), 10);

pub fn swap(&self, val: i32, order: Ordering) -> i32

Stores a value into the atomic integer, 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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let some_var = AtomicI32::new(5);

assert_eq!(some_var.swap(10, Ordering::Relaxed), 5);

pub fn compare_and_swap(&self, current: i32, new: i32, order: Ordering) -> i32

👎Deprecated since 1.50.0: Use compare_exchange or compare_exchange_weak instead

Stores a value into the atomic integer 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 i32.

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::{AtomicI32, Ordering};

let some_var = AtomicI32::new(5);

assert_eq!(some_var.compare_and_swap(5, 10, Ordering::Relaxed), 5);
assert_eq!(some_var.load(Ordering::Relaxed), 10);

assert_eq!(some_var.compare_and_swap(6, 12, Ordering::Relaxed), 10);
assert_eq!(some_var.load(Ordering::Relaxed), 10);

pub fn compare_exchange( &self, current: i32, new: i32, success: Ordering, failure: Ordering ) -> Result<i32, i32>

Stores a value into the atomic integer 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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let some_var = AtomicI32::new(5);

assert_eq!(some_var.compare_exchange(5, 10,
                                     Ordering::Acquire,
                                     Ordering::Relaxed),
           Ok(5));
assert_eq!(some_var.load(Ordering::Relaxed), 10);

assert_eq!(some_var.compare_exchange(6, 12,
                                     Ordering::SeqCst,
                                     Ordering::Acquire),
           Err(10));
assert_eq!(some_var.load(Ordering::Relaxed), 10);

pub fn compare_exchange_weak( &self, current: i32, new: i32, success: Ordering, failure: Ordering ) -> Result<i32, i32>

Stores a value into the atomic integer if the current value is the same as the current value.

Unlike AtomicI32::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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let val = AtomicI32::new(4);

let mut old = val.load(Ordering::Relaxed);
loop {
    let new = old * 2;
    match val.compare_exchange_weak(old, new, Ordering::SeqCst, Ordering::Relaxed) {
        Ok(_) => break,
        Err(x) => old = x,
    }
}

pub fn fetch_add(&self, val: i32, order: Ordering) -> i32

Adds to the current value, returning the previous value.

This operation wraps around on overflow.

fetch_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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(0);
assert_eq!(foo.fetch_add(10, Ordering::SeqCst), 0);
assert_eq!(foo.load(Ordering::SeqCst), 10);

pub fn fetch_sub(&self, val: i32, order: Ordering) -> i32

Subtracts from the current value, returning the previous value.

This operation wraps around on overflow.

fetch_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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(20);
assert_eq!(foo.fetch_sub(10, Ordering::SeqCst), 20);
assert_eq!(foo.load(Ordering::SeqCst), 10);

pub fn fetch_and(&self, val: i32, order: Ordering) -> i32

Bitwise “and” with the current value.

Performs a bitwise “and” operation on the current value and the argument val, and sets the new value to the result.

Returns the previous value.

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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(0b101101);
assert_eq!(foo.fetch_and(0b110011, Ordering::SeqCst), 0b101101);
assert_eq!(foo.load(Ordering::SeqCst), 0b100001);

pub fn fetch_nand(&self, val: i32, order: Ordering) -> i32

Bitwise “nand” with the current value.

Performs a bitwise “nand” operation on the current value and the argument val, and sets the new value to the result.

Returns the previous value.

fetch_nand 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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(0x13);
assert_eq!(foo.fetch_nand(0x31, Ordering::SeqCst), 0x13);
assert_eq!(foo.load(Ordering::SeqCst), !(0x13 & 0x31));

pub fn fetch_or(&self, val: i32, order: Ordering) -> i32

Bitwise “or” with the current value.

Performs a bitwise “or” operation on the current value and the argument val, and sets the new value to the result.

Returns the previous value.

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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(0b101101);
assert_eq!(foo.fetch_or(0b110011, Ordering::SeqCst), 0b101101);
assert_eq!(foo.load(Ordering::SeqCst), 0b111111);

pub fn fetch_xor(&self, val: i32, order: Ordering) -> i32

Bitwise “xor” with the current value.

Performs a bitwise “xor” operation on the current value and the argument val, and sets the new value to the result.

Returns the previous value.

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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(0b101101);
assert_eq!(foo.fetch_xor(0b110011, Ordering::SeqCst), 0b101101);
assert_eq!(foo.load(Ordering::SeqCst), 0b011110);

pub fn fetch_update<F>( &self, set_order: Ordering, fetch_order: Ordering, f: F ) -> Result<i32, i32>

where F: FnMut(i32) -> Option<i32>,

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 AtomicI32::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 i32.

Considerations

This method is not magic; it is not provided by the hardware. It is implemented in terms of AtomicI32::compare_exchange_weak, and suffers from the same drawbacks. In particular, this method will not circumvent the ABA Problem.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let x = AtomicI32::new(7);
assert_eq!(x.fetch_update(Ordering::SeqCst, Ordering::SeqCst, |_| None), Err(7));
assert_eq!(x.fetch_update(Ordering::SeqCst, Ordering::SeqCst, |x| Some(x + 1)), Ok(7));
assert_eq!(x.fetch_update(Ordering::SeqCst, Ordering::SeqCst, |x| Some(x + 1)), Ok(8));
assert_eq!(x.load(Ordering::SeqCst), 9);

pub fn fetch_max(&self, val: i32, order: Ordering) -> i32

Maximum with the current value.

Finds the maximum of the current value and the argument val, and sets the new value to the result.

Returns the previous value.

fetch_max 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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(23);
assert_eq!(foo.fetch_max(42, Ordering::SeqCst), 23);
assert_eq!(foo.load(Ordering::SeqCst), 42);

If you want to obtain the maximum value in one step, you can use the following:

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(23);
let bar = 42;
let max_foo = foo.fetch_max(bar, Ordering::SeqCst).max(bar);
assert!(max_foo == 42);

pub fn fetch_min(&self, val: i32, order: Ordering) -> i32

Minimum with the current value.

Finds the minimum of the current value and the argument val, and sets the new value to the result.

Returns the previous value.

fetch_min 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 i32.

Examples

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(23);
assert_eq!(foo.fetch_min(42, Ordering::Relaxed), 23);
assert_eq!(foo.load(Ordering::Relaxed), 23);
assert_eq!(foo.fetch_min(22, Ordering::Relaxed), 23);
assert_eq!(foo.load(Ordering::Relaxed), 22);

If you want to obtain the minimum value in one step, you can use the following:

use std::sync::atomic::{AtomicI32, Ordering};

let foo = AtomicI32::new(23);
let bar = 12;
let min_foo = foo.fetch_min(bar, Ordering::SeqCst).min(bar);
assert_eq!(min_foo, 12);

pub const fn as_ptr(&self) -> *mut i32

Returns a mutable pointer to the underlying integer.

Doing non-atomic reads and writes on the resulting integer can be a data race. This method is mostly useful for FFI, where the function signature may use *mut i32 instead of &AtomicI32.

Returning an *mut pointer from a shared reference to this atomic is safe because the atomic types work with interior mutability. All modifications of an atomic change the value through a shared reference, and can do so safely as long as they use atomic operations. Any use of the returned raw pointer requires an unsafe block and still has to uphold the same restriction: operations on it must be atomic.

Examples

use std::sync::atomic::AtomicI32;

extern "C" {
    fn my_atomic_op(arg: *mut i32);
}

let atomic = AtomicI32::new(1);

// SAFETY: Safe as long as `my_atomic_op` is atomic.
unsafe {
    my_atomic_op(atomic.as_ptr());
}

Trait Implementations

impl Debug for AtomicI32

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl Default for AtomicI32

fn default() -> AtomicI32

Returns the “default value” for a type.

impl<'de> Deserialize<'de> for AtomicI32

fn deserialize<D>( deserializer: D ) -> Result<AtomicI32, <D as Deserializer<'de>>::Error>

where D: Deserializer<'de>,

Deserialize this value from the given Serde deserializer.

impl From<i32> for AtomicI32

fn from(v: i32) -> AtomicI32

Converts an i32 into an AtomicI32.

impl Radium for AtomicI32

type Item = i32

fn new(value: i32) -> AtomicI32

Creates a new value of this type.

fn fence(order: Ordering)

If the underlying value is atomic, calls fence with the given Ordering. Otherwise, does nothing.

fn get_mut(&mut self) -> &mut i32

Returns a mutable reference to the underlying value.

fn into_inner(self) -> i32

Consumes the wrapper and returns the contained value.

fn load(&self, order: Ordering) -> i32

Load a value from this object.

fn store(&self, value: i32, order: Ordering)

Store a value in this object.

fn swap(&self, value: i32, order: Ordering) -> i32

Swap with the value stored in this object.

fn compare_and_swap(&self, current: i32, new: i32, order: Ordering) -> i32

👎Deprecated: Use compare_exchange or compare_exchange_weak instead

Stores a value into this object if the currently-stored value is the same as the current value.

fn compare_exchange( &self, current: i32, new: i32, success: Ordering, failure: Ordering ) -> Result<i32, i32>

Stores a value into this object if the currently-stored value is the same as the current value.

fn compare_exchange_weak( &self, current: i32, new: i32, success: Ordering, failure: Ordering ) -> Result<i32, i32>

Stores a value into this object if the currently-stored value is the same as the current value.

fn fetch_update<F>( &self, set_order: Ordering, fetch_order: Ordering, f: F ) -> Result<i32, i32>

where F: FnMut(i32) -> Option<i32>,

Fetches the value, and applies a function to it that returns an optional new value.

fn fetch_and(&self, value: i32, order: Ordering) -> i32

Performs a bitwise “and” on the currently-stored value and the argument value, and stores the result in self.

fn fetch_nand(&self, value: i32, order: Ordering) -> i32

Performs a bitwise “nand” on the currently-stored value and the argument value, and stores the result in self.

fn fetch_or(&self, value: i32, order: Ordering) -> i32

Performs a bitwise “or” on the currently-stored value and the argument value, and stores the result in self.

fn fetch_xor(&self, value: i32, order: Ordering) -> i32

Performs a bitwise “xor” on the currently-stored value and the argument value, and stores the result in self.

fn fetch_add(&self, value: i32, order: Ordering) -> i32

Adds value to the currently-stored value, wrapping on overflow, and stores the result in self.

fn fetch_sub(&self, value: i32, order: Ordering) -> i32

Subtracts value from the currently-stored value, wrapping on underflow, and stores the result in self.

impl Serialize for AtomicI32

fn serialize<S>( &self, serializer: S ) -> Result<<S as Serializer>::Ok, <S as Serializer>::Error>

where S: Serializer,

Serialize this value into the given Serde serializer.

impl RefUnwindSafe for AtomicI32

impl Sync for AtomicI32