rust/src/libstd/thread.rs
Alex Crichton aec67c2ee0 Revert "std: Re-enable at_exit()"
This reverts commit 9e224c2bf1.

Conflicts:
	src/libstd/sys/windows/os.rs
2014-12-31 10:20:31 -08:00

667 lines
21 KiB
Rust

// Copyright 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.
//! Native threads
//!
//! ## The threading model
//!
//! An executing Rust program consists of a collection of native OS threads,
//! each with their own stack and local state.
//!
//! Communication between threads can be done through
//! [channels](../../std/comm/index.html), Rust's message-passing
//! types, along with [other forms of thread
//! synchronization](../../std/sync/index.html) and shared-memory data
//! structures. In particular, types that are guaranteed to be
//! threadsafe are easily shared between threads using the
//! atomically-reference-counted container,
//! [`Arc`](../../std/sync/struct.Arc.html).
//!
//! Fatal logic errors in Rust cause *thread panic*, during which
//! a thread will unwind the stack, running destructors and freeing
//! owned resources. Thread panic is unrecoverable from within
//! the panicking thread (i.e. there is no 'try/catch' in Rust), but
//! panic may optionally be detected from a different thread. If
//! the main thread panics the application will exit with a non-zero
//! exit code.
//!
//! When the main thread of a Rust program terminates, the entire program shuts
//! down, even if other threads are still running. However, this module provides
//! convenient facilities for automatically waiting for the termination of a
//! child thread (i.e., join), described below.
//!
//! ## The `Thread` type
//!
//! Already-running threads are represented via the `Thread` type, which you can
//! get in one of two ways:
//!
//! * By spawning a new thread, e.g. using the `Thread::spawn` constructor;
//! * By requesting the current thread, using the `Thread::current` function.
//!
//! Threads can be named, and provide some built-in support for low-level
//! synchronization described below.
//!
//! The `Thread::current()` function is available even for threads not spawned
//! by the APIs of this module.
//!
//! ## Spawning a thread
//!
//! A new thread can be spawned using the `Thread::spawn` function:
//!
//! ```rust
//! use std::thread::Thread;
//!
//! let guard = Thread::spawn(move || {
//! println!("Hello, World!");
//! // some computation here
//! });
//! let result = guard.join();
//! ```
//!
//! The `spawn` function doesn't return a `Thread` directly; instead, it returns
//! a *join guard* from which a `Thread` can be extracted. The join guard is an
//! RAII-style guard that will automatically join the child thread (block until
//! it terminates) when it is dropped. You can join the child thread in advance
//! by calling the `join` method on the guard, which will also return the result
//! produced by the thread.
//!
//! If you instead wish to *detach* the child thread, allowing it to outlive its
//! parent, you can use the `detach` method on the guard,
//!
//! A handle to the thread itself is available via the `thread` method on the
//! join guard.
//!
//! ## Configuring threads
//!
//! A new thread can be configured before it is spawned via the `Builder` type,
//! which currently allows you to set the name, stack size, and writers for
//! `println!` and `panic!` for the child thread:
//!
//! ```rust
//! use std::thread;
//!
//! thread::Builder::new().name("child1".to_string()).spawn(move || {
//! println!("Hello, world!")
//! }).detach();
//! ```
//!
//! ## Blocking support: park and unpark
//!
//! Every thread is equipped with some basic low-level blocking support, via the
//! `park` and `unpark` functions.
//!
//! Conceptually, each `Thread` handle has an associated token, which is
//! initially not present:
//!
//! * The `Thread::park()` function blocks the current thread unless or until
//! the token is available for its thread handle, at which point It atomically
//! consumes the token. It may also return *spuriously*, without consuming the
//! token.
//!
//! * The `unpark()` method on a `Thread` atomically makes the token available
//! if it wasn't already.
//!
//! In other words, each `Thread` acts a bit like a semaphore with initial count
//! 0, except that the semaphore is *saturating* (the count cannot go above 1),
//! and can return spuriously.
//!
//! The API is typically used by acquiring a handle to the current thread,
//! placing that handle in a shared data structure so that other threads can
//! find it, and then `park`ing. When some desired condition is met, another
//! thread calls `unpark` on the handle.
//!
//! The motivation for this design is twofold:
//!
//! * It avoids the need to allocate mutexes and condvars when building new
//! synchronization primitives; the threads already provide basic blocking/signaling.
//!
//! * It can be implemented highly efficiently on many platforms.
use any::Any;
use borrow::IntoCow;
use boxed::Box;
use cell::UnsafeCell;
use clone::Clone;
use kinds::{Send, Sync};
use ops::{Drop, FnOnce};
use option::Option::{mod, Some, None};
use result::Result::{Err, Ok};
use sync::{Mutex, Condvar, Arc};
use str::Str;
use string::String;
use rt::{mod, unwind};
use io::{Writer, stdio};
use thunk::Thunk;
use sys::thread as imp;
use sys_common::{stack, thread_info};
/// Thread configuation. Provides detailed control over the properties
/// and behavior of new threads.
pub struct Builder {
// A name for the thread-to-be, for identification in panic messages
name: Option<String>,
// The size of the stack for the spawned thread
stack_size: Option<uint>,
// Thread-local stdout
stdout: Option<Box<Writer + Send>>,
// Thread-local stderr
stderr: Option<Box<Writer + Send>>,
}
impl Builder {
/// Generate the base configuration for spawning a thread, from which
/// configuration methods can be chained.
pub fn new() -> Builder {
Builder {
name: None,
stack_size: None,
stdout: None,
stderr: None,
}
}
/// Name the thread-to-be. Currently the name is used for identification
/// only in panic messages.
pub fn name(mut self, name: String) -> Builder {
self.name = Some(name);
self
}
/// Deprecated: use `name` instead
#[deprecated = "use name instead"]
pub fn named<T: IntoCow<'static, String, str>>(self, name: T) -> Builder {
self.name(name.into_cow().into_owned())
}
/// Set the size of the stack for the new thread.
pub fn stack_size(mut self, size: uint) -> Builder {
self.stack_size = Some(size);
self
}
/// Redirect thread-local stdout.
#[experimental = "Will likely go away after proc removal"]
pub fn stdout(mut self, stdout: Box<Writer + Send>) -> Builder {
self.stdout = Some(stdout);
self
}
/// Redirect thread-local stderr.
#[experimental = "Will likely go away after proc removal"]
pub fn stderr(mut self, stderr: Box<Writer + Send>) -> Builder {
self.stderr = Some(stderr);
self
}
/// Spawn a new joinable thread, and return a JoinGuard guard for it.
///
/// See `Thead::spawn` and the module doc for more details.
pub fn spawn<T, F>(self, f: F) -> JoinGuard<T> where
T: Send, F: FnOnce() -> T, F: Send
{
self.spawn_inner(Thunk::new(f))
}
fn spawn_inner<T: Send>(self, f: Thunk<(), T>) -> JoinGuard<T> {
let my_packet = Packet(Arc::new(UnsafeCell::new(None)));
let their_packet = Packet(my_packet.0.clone());
let Builder { name, stack_size, stdout, stderr } = self;
let stack_size = stack_size.unwrap_or(rt::min_stack());
let my_thread = Thread::new(name);
let their_thread = my_thread.clone();
// Spawning a new OS thread guarantees that __morestack will never get
// triggered, but we must manually set up the actual stack bounds once
// this function starts executing. This raises the lower limit by a bit
// because by the time that this function is executing we've already
// consumed at least a little bit of stack (we don't know the exact byte
// address at which our stack started).
let main = move |:| {
let something_around_the_top_of_the_stack = 1;
let addr = &something_around_the_top_of_the_stack as *const int;
let my_stack_top = addr as uint;
let my_stack_bottom = my_stack_top - stack_size + 1024;
unsafe {
stack::record_os_managed_stack_bounds(my_stack_bottom, my_stack_top);
}
thread_info::set(
(my_stack_bottom, my_stack_top),
unsafe { imp::guard::current() },
their_thread
);
let mut output = None;
let f: Thunk<(), T> = if stdout.is_some() || stderr.is_some() {
Thunk::new(move |:| {
let _ = stdout.map(stdio::set_stdout);
let _ = stderr.map(stdio::set_stderr);
f.invoke(())
})
} else {
f
};
let try_result = {
let ptr = &mut output;
// There are two primary reasons that general try/catch is
// unsafe. The first is that we do not support nested
// try/catch. The fact that this is happening in a newly-spawned
// thread suffices. The second is that unwinding while unwinding
// is not defined. We take care of that by having an
// 'unwinding' flag in the thread itself. For these reasons,
// this unsafety should be ok.
unsafe {
unwind::try(move || *ptr = Some(f.invoke(())))
}
};
unsafe {
*their_packet.0.get() = Some(match (output, try_result) {
(Some(data), Ok(_)) => Ok(data),
(None, Err(cause)) => Err(cause),
_ => unreachable!()
});
}
};
JoinGuard {
native: unsafe { imp::create(stack_size, Thunk::new(main)) },
joined: false,
packet: my_packet,
thread: my_thread,
}
}
}
struct Inner {
name: Option<String>,
lock: Mutex<bool>, // true when there is a buffered unpark
cvar: Condvar,
}
unsafe impl Sync for Inner {}
#[deriving(Clone)]
/// A handle to a thread.
pub struct Thread {
inner: Arc<Inner>,
}
unsafe impl Sync for Thread {}
impl Thread {
// Used only internally to construct a thread object without spawning
fn new(name: Option<String>) -> Thread {
Thread {
inner: Arc::new(Inner {
name: name,
lock: Mutex::new(false),
cvar: Condvar::new(),
})
}
}
/// Spawn a new joinable thread, returning a `JoinGuard` for it.
///
/// The join guard can be used to explicitly join the child thread (via
/// `join`), returning `Result<T>`, or it will implicitly join the child
/// upon being dropped. To detach the child, allowing it to outlive the
/// current thread, use `detach`. See the module documentation for additional details.
pub fn spawn<T, F>(f: F) -> JoinGuard<T> where
T: Send, F: FnOnce() -> T, F: Send
{
Builder::new().spawn(f)
}
/// Gets a handle to the thread that invokes it.
pub fn current() -> Thread {
thread_info::current_thread()
}
/// Cooperatively give up a timeslice to the OS scheduler.
pub fn yield_now() {
unsafe { imp::yield_now() }
}
/// Determines whether the current thread is panicking.
#[inline]
pub fn panicking() -> bool {
unwind::panicking()
}
/// Block unless or until the current thread's token is made available (may wake spuriously).
///
/// See the module doc for more detail.
//
// The implementation currently uses the trivial strategy of a Mutex+Condvar
// with wakeup flag, which does not actually allow spurious wakeups. In the
// future, this will be implemented in a more efficient way, perhaps along the lines of
// http://cr.openjdk.java.net/~stefank/6989984.1/raw_files/new/src/os/linux/vm/os_linux.cpp
// or futuxes, and in either case may allow spurious wakeups.
pub fn park() {
let thread = Thread::current();
let mut guard = thread.inner.lock.lock().unwrap();
while !*guard {
guard = thread.inner.cvar.wait(guard).unwrap();
}
*guard = false;
}
/// Atomically makes the handle's token available if it is not already.
///
/// See the module doc for more detail.
pub fn unpark(&self) {
let mut guard = self.inner.lock.lock().unwrap();
if !*guard {
*guard = true;
self.inner.cvar.notify_one();
}
}
/// Get the thread's name.
pub fn name(&self) -> Option<&str> {
self.inner.name.as_ref().map(|s| s.as_slice())
}
}
// a hack to get around privacy restrictions
impl thread_info::NewThread for Thread {
fn new(name: Option<String>) -> Thread { Thread::new(name) }
}
/// Indicates the manner in which a thread exited.
///
/// A thread that completes without panicking is considered to exit successfully.
pub type Result<T> = ::result::Result<T, Box<Any + Send>>;
struct Packet<T>(Arc<UnsafeCell<Option<Result<T>>>>);
unsafe impl<T:'static+Send> Send for Packet<T> {}
unsafe impl<T> Sync for Packet<T> {}
#[must_use]
/// An RAII-style guard that will block until thread termination when dropped.
///
/// The type `T` is the return type for the thread's main function.
pub struct JoinGuard<T> {
native: imp::rust_thread,
thread: Thread,
joined: bool,
packet: Packet<T>,
}
unsafe impl<T: Send> Sync for JoinGuard<T> {}
impl<T: Send> JoinGuard<T> {
/// Extract a handle to the thread this guard will join on.
pub fn thread(&self) -> &Thread {
&self.thread
}
/// Wait for the associated thread to finish, returning the result of the thread's
/// calculation.
///
/// If the child thread panics, `Err` is returned with the parameter given
/// to `panic`.
pub fn join(mut self) -> Result<T> {
assert!(!self.joined);
unsafe { imp::join(self.native) };
self.joined = true;
unsafe {
(*self.packet.0.get()).take().unwrap()
}
}
/// Detaches the child thread, allowing it to outlive its parent.
pub fn detach(mut self) {
unsafe { imp::detach(self.native) };
self.joined = true; // avoid joining in the destructor
}
}
#[unsafe_destructor]
impl<T: Send> Drop for JoinGuard<T> {
fn drop(&mut self) {
if !self.joined {
unsafe { imp::join(self.native) };
}
}
}
#[cfg(test)]
mod test {
use prelude::*;
use any::{Any, AnyRefExt};
use boxed::BoxAny;
use result;
use std::io::{ChanReader, ChanWriter};
use thunk::Thunk;
use super::{Thread, Builder};
// !!! These tests are dangerous. If something is buggy, they will hang, !!!
// !!! instead of exiting cleanly. This might wedge the buildbots. !!!
#[test]
fn test_unnamed_thread() {
Thread::spawn(move|| {
assert!(Thread::current().name().is_none());
}).join().map_err(|_| ()).unwrap();
}
#[test]
fn test_named_thread() {
Builder::new().name("ada lovelace".to_string()).spawn(move|| {
assert!(Thread::current().name().unwrap() == "ada lovelace".to_string());
}).join().map_err(|_| ()).unwrap();
}
#[test]
fn test_run_basic() {
let (tx, rx) = channel();
Thread::spawn(move|| {
tx.send(());
}).detach();
rx.recv();
}
#[test]
fn test_join_success() {
match Thread::spawn(move|| -> String {
"Success!".to_string()
}).join().as_ref().map(|s| s.as_slice()) {
result::Result::Ok("Success!") => (),
_ => panic!()
}
}
#[test]
fn test_join_panic() {
match Thread::spawn(move|| {
panic!()
}).join() {
result::Result::Err(_) => (),
result::Result::Ok(()) => panic!()
}
}
#[test]
fn test_spawn_sched() {
use clone::Clone;
let (tx, rx) = channel();
fn f(i: int, tx: Sender<()>) {
let tx = tx.clone();
Thread::spawn(move|| {
if i == 0 {
tx.send(());
} else {
f(i - 1, tx);
}
}).detach();
}
f(10, tx);
rx.recv();
}
#[test]
fn test_spawn_sched_childs_on_default_sched() {
let (tx, rx) = channel();
Thread::spawn(move|| {
Thread::spawn(move|| {
tx.send(());
}).detach();
}).detach();
rx.recv();
}
fn avoid_copying_the_body<F>(spawnfn: F) where F: FnOnce(Thunk) {
let (tx, rx) = channel::<uint>();
let x = box 1;
let x_in_parent = (&*x) as *const int as uint;
spawnfn(Thunk::new(move|| {
let x_in_child = (&*x) as *const int as uint;
tx.send(x_in_child);
}));
let x_in_child = rx.recv();
assert_eq!(x_in_parent, x_in_child);
}
#[test]
fn test_avoid_copying_the_body_spawn() {
avoid_copying_the_body(|v| {
Thread::spawn(move || v.invoke(())).detach();
});
}
#[test]
fn test_avoid_copying_the_body_thread_spawn() {
avoid_copying_the_body(|f| {
Thread::spawn(move|| {
f.invoke(());
}).detach();
})
}
#[test]
fn test_avoid_copying_the_body_join() {
avoid_copying_the_body(|f| {
let _ = Thread::spawn(move|| {
f.invoke(())
}).join();
})
}
#[test]
fn test_child_doesnt_ref_parent() {
// If the child refcounts the parent task, this will stack overflow when
// climbing the task tree to dereference each ancestor. (See #1789)
// (well, it would if the constant were 8000+ - I lowered it to be more
// valgrind-friendly. try this at home, instead..!)
static GENERATIONS: uint = 16;
fn child_no(x: uint) -> Thunk {
return Thunk::new(move|| {
if x < GENERATIONS {
Thread::spawn(move|| child_no(x+1).invoke(())).detach();
}
});
}
Thread::spawn(|| child_no(0).invoke(())).detach();
}
#[test]
fn test_simple_newsched_spawn() {
Thread::spawn(move || {}).detach();
}
#[test]
fn test_try_panic_message_static_str() {
match Thread::spawn(move|| {
panic!("static string");
}).join() {
Err(e) => {
type T = &'static str;
assert!(e.is::<T>());
assert_eq!(*e.downcast::<T>().unwrap(), "static string");
}
Ok(()) => panic!()
}
}
#[test]
fn test_try_panic_message_owned_str() {
match Thread::spawn(move|| {
panic!("owned string".to_string());
}).join() {
Err(e) => {
type T = String;
assert!(e.is::<T>());
assert_eq!(*e.downcast::<T>().unwrap(), "owned string".to_string());
}
Ok(()) => panic!()
}
}
#[test]
fn test_try_panic_message_any() {
match Thread::spawn(move|| {
panic!(box 413u16 as Box<Any + Send>);
}).join() {
Err(e) => {
type T = Box<Any + Send>;
assert!(e.is::<T>());
let any = e.downcast::<T>().unwrap();
assert!(any.is::<u16>());
assert_eq!(*any.downcast::<u16>().unwrap(), 413u16);
}
Ok(()) => panic!()
}
}
#[test]
fn test_try_panic_message_unit_struct() {
struct Juju;
match Thread::spawn(move|| {
panic!(Juju)
}).join() {
Err(ref e) if e.is::<Juju>() => {}
Err(_) | Ok(()) => panic!()
}
}
#[test]
fn test_stdout() {
let (tx, rx) = channel();
let mut reader = ChanReader::new(rx);
let stdout = ChanWriter::new(tx);
let r = Builder::new().stdout(box stdout as Box<Writer + Send>).spawn(move|| {
print!("Hello, world!");
}).join();
assert!(r.is_ok());
let output = reader.read_to_string().unwrap();
assert_eq!(output, "Hello, world!".to_string());
}
// NOTE: the corresponding test for stderr is in run-pass/task-stderr, due
// to the test harness apparently interfering with stderr configuration.
}