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once.rs
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once.rs
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//! A "once initialization" primitive
//!
//! This primitive is meant to be used to run one-time initialization. An
//! example use case would be for initializing an FFI library.
// A "once" is a relatively simple primitive, and it's also typically provided
// by the OS as well (see `pthread_once` or `InitOnceExecuteOnce`). The OS
// primitives, however, tend to have surprising restrictions, such as the Unix
// one doesn't allow an argument to be passed to the function.
//
// As a result, we end up implementing it ourselves in the standard library.
// This also gives us the opportunity to optimize the implementation a bit which
// should help the fast path on call sites. Consequently, let's explain how this
// primitive works now!
//
// So to recap, the guarantees of a Once are that it will call the
// initialization closure at most once, and it will never return until the one
// that's running has finished running. This means that we need some form of
// blocking here while the custom callback is running at the very least.
// Additionally, we add on the restriction of **poisoning**. Whenever an
// initialization closure panics, the Once enters a "poisoned" state which means
// that all future calls will immediately panic as well.
//
// So to implement this, one might first reach for a `Mutex`, but those cannot
// be put into a `static`. It also gets a lot harder with poisoning to figure
// out when the mutex needs to be deallocated because it's not after the closure
// finishes, but after the first successful closure finishes.
//
// All in all, this is instead implemented with atomics and lock-free
// operations! Whee! Each `Once` has one word of atomic state, and this state is
// CAS'd on to determine what to do. There are four possible state of a `Once`:
//
// * Incomplete - no initialization has run yet, and no thread is currently
// using the Once.
// * Poisoned - some thread has previously attempted to initialize the Once, but
// it panicked, so the Once is now poisoned. There are no other
// threads currently accessing this Once.
// * Running - some thread is currently attempting to run initialization. It may
// succeed, so all future threads need to wait for it to finish.
// Note that this state is accompanied with a payload, described
// below.
// * Complete - initialization has completed and all future calls should finish
// immediately.
//
// With 4 states we need 2 bits to encode this, and we use the remaining bits
// in the word we have allocated as a queue of threads waiting for the thread
// responsible for entering the RUNNING state. This queue is just a linked list
// of Waiter nodes which is monotonically increasing in size. Each node is
// allocated on the stack, and whenever the running closure finishes it will
// consume the entire queue and notify all waiters they should try again.
//
// You'll find a few more details in the implementation, but that's the gist of
// it!
//
// Atomic orderings:
// When running `Once` we deal with multiple atomics:
// `Once.state_and_queue` and an unknown number of `Waiter.signaled`.
// * `state_and_queue` is used (1) as a state flag, (2) for synchronizing the
// result of the `Once`, and (3) for synchronizing `Waiter` nodes.
// - At the end of the `call_inner` function we have to make sure the result
// of the `Once` is acquired. So every load which can be the only one to
// load COMPLETED must have at least Acquire ordering, which means all
// three of them.
// - `WaiterQueue::Drop` is the only place that may store COMPLETED, and
// must do so with Release ordering to make the result available.
// - `wait` inserts `Waiter` nodes as a pointer in `state_and_queue`, and
// needs to make the nodes available with Release ordering. The load in
// its `compare_and_swap` can be Relaxed because it only has to compare
// the atomic, not to read other data.
// - `WaiterQueue::Drop` must see the `Waiter` nodes, so it must load
// `state_and_queue` with Acquire ordering.
// - There is just one store where `state_and_queue` is used only as a
// state flag, without having to synchronize data: switching the state
// from INCOMPLETE to RUNNING in `call_inner`. This store can be Relaxed,
// but the read has to be Acquire because of the requirements mentioned
// above.
// * `Waiter.signaled` is both used as a flag, and to protect a field with
// interior mutability in `Waiter`. `Waiter.thread` is changed in
// `WaiterQueue::Drop` which then sets `signaled` with Release ordering.
// After `wait` loads `signaled` with Acquire and sees it is true, it needs to
// see the changes to drop the `Waiter` struct correctly.
// * There is one place where the two atomics `Once.state_and_queue` and
// `Waiter.signaled` come together, and might be reordered by the compiler or
// processor. Because both use Aquire ordering such a reordering is not
// allowed, so no need for SeqCst.
use crate::cell::Cell;
use crate::fmt;
use crate::marker;
use crate::ptr;
use crate::sync::atomic::{AtomicUsize, AtomicBool, Ordering};
use crate::thread::{self, Thread};
/// A synchronization primitive which can be used to run a one-time global
/// initialization. Useful for one-time initialization for FFI or related
/// functionality. This type can only be constructed with the [`Once::new`]
/// constructor.
///
/// [`Once::new`]: struct.Once.html#method.new
///
/// # Examples
///
/// ```
/// use std::sync::Once;
///
/// static START: Once = Once::new();
///
/// START.call_once(|| {
/// // run initialization here
/// });
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
pub struct Once {
// `state_and_queue` is actually an a pointer to a `Waiter` with extra state
// bits, so we add the `PhantomData` appropriately.
state_and_queue: AtomicUsize,
_marker: marker::PhantomData<*const Waiter>,
}
// The `PhantomData` of a raw pointer removes these two auto traits, but we
// enforce both below in the implementation so this should be safe to add.
#[stable(feature = "rust1", since = "1.0.0")]
unsafe impl Sync for Once {}
#[stable(feature = "rust1", since = "1.0.0")]
unsafe impl Send for Once {}
/// State yielded to [`call_once_force`]’s closure parameter. The state can be
/// used to query the poison status of the [`Once`].
///
/// [`call_once_force`]: struct.Once.html#method.call_once_force
/// [`Once`]: struct.Once.html
#[unstable(feature = "once_poison", issue = "33577")]
#[derive(Debug)]
pub struct OnceState {
poisoned: bool,
}
/// Initialization value for static [`Once`] values.
///
/// [`Once`]: struct.Once.html
///
/// # Examples
///
/// ```
/// use std::sync::{Once, ONCE_INIT};
///
/// static START: Once = ONCE_INIT;
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_deprecated(
since = "1.38.0",
reason = "the `new` function is now preferred",
suggestion = "Once::new()",
)]
pub const ONCE_INIT: Once = Once::new();
// Four states that a Once can be in, encoded into the lower bits of
// `state_and_queue` in the Once structure.
const INCOMPLETE: usize = 0x0;
const POISONED: usize = 0x1;
const RUNNING: usize = 0x2;
const COMPLETE: usize = 0x3;
// Mask to learn about the state. All other bits are the queue of waiters if
// this is in the RUNNING state.
const STATE_MASK: usize = 0x3;
// Representation of a node in the linked list of waiters, used while in the
// RUNNING state.
// Note: `Waiter` can't hold a mutable pointer to the next thread, because then
// `wait` would both hand out a mutable reference to its `Waiter` node, and keep
// a shared reference to check `signaled`. Instead we hold shared references and
// use interior mutability.
#[repr(align(4))] // Ensure the two lower bits are free to use as state bits.
struct Waiter {
thread: Cell<Option<Thread>>,
signaled: AtomicBool,
next: *const Waiter,
}
// Head of a linked list of waiters.
// Every node is a struct on the stack of a waiting thread.
// Will wake up the waiters when it gets dropped, i.e. also on panic.
struct WaiterQueue<'a> {
state_and_queue: &'a AtomicUsize,
set_state_on_drop_to: usize,
}
impl Once {
/// Creates a new `Once` value.
#[stable(feature = "once_new", since = "1.2.0")]
pub const fn new() -> Once {
Once {
state_and_queue: AtomicUsize::new(INCOMPLETE),
_marker: marker::PhantomData,
}
}
/// Performs an initialization routine once and only once. The given closure
/// will be executed if this is the first time `call_once` has been called,
/// and otherwise the routine will *not* be invoked.
///
/// This method will block the calling thread if another initialization
/// routine is currently running.
///
/// When this function returns, it is guaranteed that some initialization
/// has run and completed (it may not be the closure specified). It is also
/// guaranteed that any memory writes performed by the executed closure can
/// be reliably observed by other threads at this point (there is a
/// happens-before relation between the closure and code executing after the
/// return).
///
/// If the given closure recursively invokes `call_once` on the same `Once`
/// instance the exact behavior is not specified, allowed outcomes are
/// a panic or a deadlock.
///
/// # Examples
///
/// ```
/// use std::sync::Once;
///
/// static mut VAL: usize = 0;
/// static INIT: Once = Once::new();
///
/// // Accessing a `static mut` is unsafe much of the time, but if we do so
/// // in a synchronized fashion (e.g., write once or read all) then we're
/// // good to go!
/// //
/// // This function will only call `expensive_computation` once, and will
/// // otherwise always return the value returned from the first invocation.
/// fn get_cached_val() -> usize {
/// unsafe {
/// INIT.call_once(|| {
/// VAL = expensive_computation();
/// });
/// VAL
/// }
/// }
///
/// fn expensive_computation() -> usize {
/// // ...
/// # 2
/// }
/// ```
///
/// # Panics
///
/// The closure `f` will only be executed once if this is called
/// concurrently amongst many threads. If that closure panics, however, then
/// it will *poison* this `Once` instance, causing all future invocations of
/// `call_once` to also panic.
///
/// This is similar to [poisoning with mutexes][poison].
///
/// [poison]: struct.Mutex.html#poisoning
#[stable(feature = "rust1", since = "1.0.0")]
pub fn call_once<F>(&self, f: F) where F: FnOnce() {
// Fast path check
if self.is_completed() {
return;
}
let mut f = Some(f);
self.call_inner(false, &mut |_| f.take().unwrap()());
}
/// Performs the same function as [`call_once`] except ignores poisoning.
///
/// Unlike [`call_once`], if this `Once` has been poisoned (i.e., a previous
/// call to `call_once` or `call_once_force` caused a panic), calling
/// `call_once_force` will still invoke the closure `f` and will _not_
/// result in an immediate panic. If `f` panics, the `Once` will remain
/// in a poison state. If `f` does _not_ panic, the `Once` will no
/// longer be in a poison state and all future calls to `call_once` or
/// `call_one_force` will be no-ops.
///
/// The closure `f` is yielded a [`OnceState`] structure which can be used
/// to query the poison status of the `Once`.
///
/// [`call_once`]: struct.Once.html#method.call_once
/// [`OnceState`]: struct.OnceState.html
///
/// # Examples
///
/// ```
/// #![feature(once_poison)]
///
/// use std::sync::Once;
/// use std::thread;
///
/// static INIT: Once = Once::new();
///
/// // poison the once
/// let handle = thread::spawn(|| {
/// INIT.call_once(|| panic!());
/// });
/// assert!(handle.join().is_err());
///
/// // poisoning propagates
/// let handle = thread::spawn(|| {
/// INIT.call_once(|| {});
/// });
/// assert!(handle.join().is_err());
///
/// // call_once_force will still run and reset the poisoned state
/// INIT.call_once_force(|state| {
/// assert!(state.poisoned());
/// });
///
/// // once any success happens, we stop propagating the poison
/// INIT.call_once(|| {});
/// ```
#[unstable(feature = "once_poison", issue = "33577")]
pub fn call_once_force<F>(&self, f: F) where F: FnOnce(&OnceState) {
// Fast path check
if self.is_completed() {
return;
}
let mut f = Some(f);
self.call_inner(true, &mut |p| {
f.take().unwrap()(&OnceState { poisoned: p })
});
}
/// Returns `true` if some `call_once` call has completed
/// successfully. Specifically, `is_completed` will return false in
/// the following situations:
/// * `call_once` was not called at all,
/// * `call_once` was called, but has not yet completed,
/// * the `Once` instance is poisoned
///
/// It is also possible that immediately after `is_completed`
/// returns false, some other thread finishes executing
/// `call_once`.
///
/// # Examples
///
/// ```
/// #![feature(once_is_completed)]
/// use std::sync::Once;
///
/// static INIT: Once = Once::new();
///
/// assert_eq!(INIT.is_completed(), false);
/// INIT.call_once(|| {
/// assert_eq!(INIT.is_completed(), false);
/// });
/// assert_eq!(INIT.is_completed(), true);
/// ```
///
/// ```
/// #![feature(once_is_completed)]
/// use std::sync::Once;
/// use std::thread;
///
/// static INIT: Once = Once::new();
///
/// assert_eq!(INIT.is_completed(), false);
/// let handle = thread::spawn(|| {
/// INIT.call_once(|| panic!());
/// });
/// assert!(handle.join().is_err());
/// assert_eq!(INIT.is_completed(), false);
/// ```
#[unstable(feature = "once_is_completed", issue = "54890")]
#[inline]
pub fn is_completed(&self) -> bool {
// An `Acquire` load is enough because that makes all the initialization
// operations visible to us, and, this being a fast path, weaker
// ordering helps with performance. This `Acquire` synchronizes with
// `Release` operations on the slow path.
self.state_and_queue.load(Ordering::Acquire) == COMPLETE
}
// This is a non-generic function to reduce the monomorphization cost of
// using `call_once` (this isn't exactly a trivial or small implementation).
//
// Additionally, this is tagged with `#[cold]` as it should indeed be cold
// and it helps let LLVM know that calls to this function should be off the
// fast path. Essentially, this should help generate more straight line code
// in LLVM.
//
// Finally, this takes an `FnMut` instead of a `FnOnce` because there's
// currently no way to take an `FnOnce` and call it via virtual dispatch
// without some allocation overhead.
#[cold]
fn call_inner(&self,
ignore_poisoning: bool,
init: &mut dyn FnMut(bool))
{
let mut state_and_queue = self.state_and_queue.load(Ordering::Acquire);
loop {
match state_and_queue {
COMPLETE => break,
POISONED if !ignore_poisoning => {
// Panic to propagate the poison.
panic!("Once instance has previously been poisoned");
}
POISONED |
INCOMPLETE => {
// Try to register this thread as the one RUNNING.
let old = self.state_and_queue.compare_and_swap(state_and_queue,
RUNNING,
Ordering::Acquire);
if old != state_and_queue {
state_and_queue = old;
continue
}
// `waiter_queue` will manage other waiting threads, and
// wake them up on drop.
let mut waiter_queue = WaiterQueue {
state_and_queue: &self.state_and_queue,
set_state_on_drop_to: POISONED,
};
// Run the initialization function, letting it know if we're
// poisoned or not.
init(state_and_queue == POISONED);
waiter_queue.set_state_on_drop_to = COMPLETE;
break
}
_ => {
// All other values must be RUNNING with possibly a
// pointer to the waiter queue in the more significant bits.
assert!(state_and_queue & STATE_MASK == RUNNING);
wait(&self.state_and_queue, state_and_queue);
state_and_queue = self.state_and_queue.load(Ordering::Acquire);
}
}
}
}
}
fn wait(state_and_queue: &AtomicUsize, current_state: usize) {
// Create the node for our current thread that we are going to try to slot
// in at the head of the linked list.
let mut node = Waiter {
thread: Cell::new(Some(thread::current())),
signaled: AtomicBool::new(false),
next: ptr::null(),
};
let me = &node as *const Waiter as usize;
assert!(me & STATE_MASK == 0); // We assume pointers have 2 free bits that
// we can use for state.
// Try to slide in the node at the head of the linked list.
// Run in a loop where we make sure the status is still RUNNING, and that
// another thread did not just replace the head of the linked list.
let mut old_head_and_status = current_state;
loop {
if old_head_and_status & STATE_MASK != RUNNING {
return; // No need anymore to enqueue ourselves.
}
node.next = (old_head_and_status & !STATE_MASK) as *const Waiter;
let old = state_and_queue.compare_and_swap(old_head_and_status,
me | RUNNING,
Ordering::Release);
if old == old_head_and_status {
break; // Success!
}
old_head_and_status = old;
}
// We have enqueued ourselves, now lets wait.
// It is important not to return before being signaled, otherwise we would
// drop our `Waiter` node and leave a hole in the linked list (and a
// dangling reference). Guard against spurious wakeups by reparking
// ourselves until we are signaled.
while !node.signaled.load(Ordering::Acquire) {
thread::park();
}
}
#[stable(feature = "std_debug", since = "1.16.0")]
impl fmt::Debug for Once {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.pad("Once { .. }")
}
}
impl Drop for WaiterQueue<'_> {
fn drop(&mut self) {
// Swap out our state with however we finished.
let state_and_queue = self.state_and_queue.swap(self.set_state_on_drop_to,
Ordering::AcqRel);
// We should only ever see an old state which was RUNNING.
assert_eq!(state_and_queue & STATE_MASK, RUNNING);
// Walk the entire linked list of waiters and wake them up (in lifo
// order, last to register is first to wake up).
unsafe {
// Right after setting `node.signaled = true` the other thread may
// free `node` if there happens to be has a spurious wakeup.
// So we have to take out the `thread` field and copy the pointer to
// `next` first.
let mut queue = (state_and_queue & !STATE_MASK) as *const Waiter;
while !queue.is_null() {
let next = (*queue).next;
let thread = (*queue).thread.replace(None).unwrap();
(*queue).signaled.store(true, Ordering::Release);
// ^- FIXME (maybe): This is another case of issue #55005
// `store()` has a potentially dangling ref to `signaled`.
queue = next;
thread.unpark();
}
}
}
}
impl OnceState {
/// Returns `true` if the associated [`Once`] was poisoned prior to the
/// invocation of the closure passed to [`call_once_force`].
///
/// [`call_once_force`]: struct.Once.html#method.call_once_force
/// [`Once`]: struct.Once.html
///
/// # Examples
///
/// A poisoned `Once`:
///
/// ```
/// #![feature(once_poison)]
///
/// use std::sync::Once;
/// use std::thread;
///
/// static INIT: Once = Once::new();
///
/// // poison the once
/// let handle = thread::spawn(|| {
/// INIT.call_once(|| panic!());
/// });
/// assert!(handle.join().is_err());
///
/// INIT.call_once_force(|state| {
/// assert!(state.poisoned());
/// });
/// ```
///
/// An unpoisoned `Once`:
///
/// ```
/// #![feature(once_poison)]
///
/// use std::sync::Once;
///
/// static INIT: Once = Once::new();
///
/// INIT.call_once_force(|state| {
/// assert!(!state.poisoned());
/// });
#[unstable(feature = "once_poison", issue = "33577")]
pub fn poisoned(&self) -> bool {
self.poisoned
}
}
#[cfg(all(test, not(target_os = "emscripten")))]
mod tests {
use crate::panic;
use crate::sync::mpsc::channel;
use crate::thread;
use super::Once;
#[test]
fn smoke_once() {
static O: Once = Once::new();
let mut a = 0;
O.call_once(|| a += 1);
assert_eq!(a, 1);
O.call_once(|| a += 1);
assert_eq!(a, 1);
}
#[test]
fn stampede_once() {
static O: Once = Once::new();
static mut RUN: bool = false;
let (tx, rx) = channel();
for _ in 0..10 {
let tx = tx.clone();
thread::spawn(move|| {
for _ in 0..4 { thread::yield_now() }
unsafe {
O.call_once(|| {
assert!(!RUN);
RUN = true;
});
assert!(RUN);
}
tx.send(()).unwrap();
});
}
unsafe {
O.call_once(|| {
assert!(!RUN);
RUN = true;
});
assert!(RUN);
}
for _ in 0..10 {
rx.recv().unwrap();
}
}
#[test]
fn poison_bad() {
static O: Once = Once::new();
// poison the once
let t = panic::catch_unwind(|| {
O.call_once(|| panic!());
});
assert!(t.is_err());
// poisoning propagates
let t = panic::catch_unwind(|| {
O.call_once(|| {});
});
assert!(t.is_err());
// we can subvert poisoning, however
let mut called = false;
O.call_once_force(|p| {
called = true;
assert!(p.poisoned())
});
assert!(called);
// once any success happens, we stop propagating the poison
O.call_once(|| {});
}
#[test]
fn wait_for_force_to_finish() {
static O: Once = Once::new();
// poison the once
let t = panic::catch_unwind(|| {
O.call_once(|| panic!());
});
assert!(t.is_err());
// make sure someone's waiting inside the once via a force
let (tx1, rx1) = channel();
let (tx2, rx2) = channel();
let t1 = thread::spawn(move || {
O.call_once_force(|p| {
assert!(p.poisoned());
tx1.send(()).unwrap();
rx2.recv().unwrap();
});
});
rx1.recv().unwrap();
// put another waiter on the once
let t2 = thread::spawn(|| {
let mut called = false;
O.call_once(|| {
called = true;
});
assert!(!called);
});
tx2.send(()).unwrap();
assert!(t1.join().is_ok());
assert!(t2.join().is_ok());
}
}