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rust/src/libstd/sys/common/helper_thread.rs
Alex Crichton 9e224c2bf1 std: Re-enable at_exit() 
The new semantics of this function are that the callbacks are run when the *main
thread* exits, not when all threads have exited. This implies that other threads
may still be running when the `at_exit` callbacks are invoked and users need to
be prepared for this situation.

Users in the standard library have been audited in accordance to these new rules
as well.

Closes #20012
2014-12-30 14:33:59 -08:00

171 lines
6.1 KiB
Rust
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// Copyright 2013-2014 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Implementation of the helper thread for the timer module
//!
//! This module contains the management necessary for the timer worker thread.
//! This thread is responsible for performing the send()s on channels for timers
//! that are using channels instead of a blocking call.
//!
//! The timer thread is lazily initialized, and it's shut down via the
//! `shutdown` function provided. It must be maintained as an invariant that
//! `shutdown` is only called when the entire program is finished. No new timers
//! can be created in the future and there must be no active timers at that
//! time.
#![macro_escape]
use prelude::*;
use cell::UnsafeCell;
use mem;
use sync::{StaticMutex, StaticCondvar};
use rt;
use sys::helper_signal;
use thread::Thread;
/// A structure for management of a helper thread.
///
/// This is generally a static structure which tracks the lifetime of a helper
/// thread.
///
/// The fields of this helper are all public, but they should not be used, this
/// is for static initialization.
pub struct Helper<M> {
/// Internal lock which protects the remaining fields
pub lock: StaticMutex,
pub cond: StaticCondvar,
// You'll notice that the remaining fields are UnsafeCell<T>, and this is
// because all helper thread operations are done through &self, but we need
// these to be mutable (once `lock` is held).
/// Lazily allocated channel to send messages to the helper thread.
pub chan: UnsafeCell<*mut Sender<M>>,
/// OS handle used to wake up a blocked helper thread
pub signal: UnsafeCell<uint>,
/// Flag if this helper thread has booted and been initialized yet.
pub initialized: UnsafeCell<bool>,
/// Flag if this helper thread has shut down
pub shutdown: UnsafeCell<bool>,
}
unsafe impl<M:Send> Send for Helper<M> { }
unsafe impl<M:Send> Sync for Helper<M> { }
struct RaceBox(helper_signal::signal);
unsafe impl Send for RaceBox {}
unsafe impl Sync for RaceBox {}
macro_rules! helper_init { (static $name:ident: Helper<$m:ty>) => (
static $name: Helper<$m> = Helper {
lock: ::sync::MUTEX_INIT,
cond: ::sync::CONDVAR_INIT,
chan: ::cell::UnsafeCell { value: 0 as *mut Sender<$m> },
signal: ::cell::UnsafeCell { value: 0 },
initialized: ::cell::UnsafeCell { value: false },
shutdown: ::cell::UnsafeCell { value: false },
};
) }
impl<M: Send> Helper<M> {
/// Lazily boots a helper thread, becoming a no-op if the helper has already
/// been spawned.
///
/// This function will check to see if the thread has been initialized, and
/// if it has it returns quickly. If initialization has not happened yet,
/// the closure `f` will be run (inside of the initialization lock) and
/// passed to the helper thread in a separate task.
///
/// This function is safe to be called many times.
pub fn boot<T, F>(&'static self, f: F, helper: fn(helper_signal::signal, Receiver<M>, T)) where
T: Send,
F: FnOnce() -> T,
{
unsafe {
let _guard = self.lock.lock().unwrap();
if *self.chan.get() as uint == 0 {
let (tx, rx) = channel();
*self.chan.get() = mem::transmute(box tx);
let (receive, send) = helper_signal::new();
*self.signal.get() = send as uint;
let receive = RaceBox(receive);
let t = f();
Thread::spawn(move || {
helper(receive.0, rx, t);
let _g = self.lock.lock().unwrap();
*self.shutdown.get() = true;
self.cond.notify_one()
}).detach();
rt::at_exit(move || { self.shutdown() });
*self.initialized.get() = true;
} else if *self.chan.get() as uint == 1 {
panic!("cannot continue usage after shutdown");
}
}
}
/// Sends a message to a spawned worker thread.
///
/// This is only valid if the worker thread has previously booted
pub fn send(&'static self, msg: M) {
unsafe {
let _guard = self.lock.lock().unwrap();
// Must send and *then* signal to ensure that the child receives the
// message. Otherwise it could wake up and go to sleep before we
// send the message.
assert!(*self.chan.get() as uint != 0);
assert!(*self.chan.get() as uint != 1,
"cannot continue usage after shutdown");
(**self.chan.get()).send(msg);
helper_signal::signal(*self.signal.get() as helper_signal::signal);
}
}
fn shutdown(&'static self) {
unsafe {
// Shut down, but make sure this is done inside our lock to ensure
// that we'll always receive the exit signal when the thread
// returns.
let mut guard = self.lock.lock().unwrap();
let ptr = *self.chan.get();
if ptr as uint == 1 {
panic!("cannot continue usage after shutdown");
}
// Close the channel by destroying it
let chan: Box<Sender<M>> = mem::transmute(*self.chan.get());
*self.chan.get() = 1 as *mut Sender<M>;
drop(chan);
helper_signal::signal(*self.signal.get() as helper_signal::signal);
// Wait for the child to exit
while !*self.shutdown.get() {
guard = self.cond.wait(guard).unwrap();
}
drop(guard);
// Clean up after ourselves
self.lock.destroy();
helper_signal::close(*self.signal.get() as helper_signal::signal);
*self.signal.get() = 0;
}
}
}
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