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//! Asynchronous signal handling.
//!
//! This crate provides the [`Signals`] type, which can be used to listen for POSIX signals asynchronously.
//! It can be seen as an asynchronous version of [`signal_hook::iterator::Signals`].
//!
//! [`signal_hook::iterator::Signals`]: https://docs.rs/signal-hook/latest/signal_hook/iterator/struct.Signals.html
//!
//! # Implementation
//!
//! This crate uses the [`signal_hook_registry`] crate to register a listener for each signal. That
//! listener will then send a message through a Unix socket to the [`Signals`] type, which will
//! receive it and notify the user. Asynchronous notification is done through the [`async-io`] crate.
//!
//! Note that the internal pipe has a limited capacity. Once it has reached capacity, additional
//! signals will be dropped.
//!
//! On Windows, a different implementation that only supports `SIGINT` is used. This implementation
//! uses a channel to notify the user.
//!
//! [`signal_hook_registry`]: https://crates.io/crates/signal-hook-registry
//! [`async-io`]: https://crates.io/crates/async-io
//!
//! # Examples
//!
//! ```no_run
//! use async_signal::{Signal, Signals};
//! use futures_lite::prelude::*;
//! use signal_hook::low_level;
//!
//! # fn main() -> Result<(), Box<dyn std::error::Error>> {
//! # async_io::block_on(async {
//! // Register the signals we want to receive.
//! let mut signals = Signals::new(&[
//! Signal::Term,
//! Signal::Quit,
//! Signal::Int,
//! ])?;
//!
//! // Wait for a signal to be received.
//! while let Some(signal) = signals.next().await {
//! // Print the signal.
//! eprintln!("Received signal {:?}", signal);
//!
//! // After printing it, do whatever the signal was supposed to do in the first place.
//! low_level::emulate_default_handler(signal.unwrap() as i32).unwrap();
//! }
//! # Ok(())
//! # })
//! # }
//! ```
#![doc(
html_favicon_url = "https://raw.githubusercontent.com/smol-rs/smol/master/assets/images/logo_fullsize_transparent.png"
)]
#![doc(
html_logo_url = "https://raw.githubusercontent.com/smol-rs/smol/master/assets/images/logo_fullsize_transparent.png"
)]
cfg_if::cfg_if! {
if #[cfg(windows)] {
mod channel;
use channel as sys;
} else {
mod pipe;
use pipe as sys;
}
}
cfg_if::cfg_if! {
if #[cfg(unix)] {
use signal_hook_registry as registry;
} else if #[cfg(windows)] {
mod windows_registry;
use windows_registry as registry;
}
}
use futures_core::ready;
use futures_core::stream::Stream;
use registry::SigId;
use std::borrow::Borrow;
use std::collections::HashMap;
use std::fmt;
use std::io;
use std::pin::Pin;
use std::task::{Context, Poll};
#[cfg(unix)]
use std::os::unix::io::{AsFd, AsRawFd, BorrowedFd, RawFd};
mod signum {
pub(crate) use std::os::raw::c_int;
macro_rules! sig {
($rustix_name:ident, $raw_value:literal) => {{
#[cfg(unix)]
{
rustix::process::Signal::$rustix_name as c_int
}
#[cfg(windows)]
{
$raw_value
}
}};
}
// Define these ourselves.
pub const SIGHUP: c_int = sig!(Hup, 1);
pub const SIGINT: c_int = sig!(Int, 2);
pub const SIGQUIT: c_int = sig!(Quit, 3);
pub const SIGILL: c_int = sig!(Ill, 4);
pub const SIGTRAP: c_int = sig!(Trap, 5);
pub const SIGABRT: c_int = sig!(Abort, 6);
pub const SIGFPE: c_int = sig!(Fpe, 8);
pub const SIGKILL: c_int = sig!(Kill, 9);
pub const SIGSEGV: c_int = sig!(Segv, 11);
pub const SIGPIPE: c_int = sig!(Pipe, 13);
pub const SIGALRM: c_int = sig!(Alarm, 14);
pub const SIGTERM: c_int = sig!(Term, 15);
pub const SIGTTIN: c_int = sig!(Ttin, 21);
pub const SIGTTOU: c_int = sig!(Ttou, 22);
pub const SIGXCPU: c_int = sig!(Xcpu, 24);
pub const SIGXFSZ: c_int = sig!(Xfsz, 25);
pub const SIGVTALRM: c_int = sig!(Vtalarm, 26);
pub const SIGPROF: c_int = sig!(Prof, 27);
pub const SIGWINCH: c_int = sig!(Winch, 28);
pub const SIGCHLD: c_int = sig!(Child, 17);
pub const SIGBUS: c_int = sig!(Bus, 7);
pub const SIGUSR1: c_int = sig!(Usr1, 10);
pub const SIGUSR2: c_int = sig!(Usr2, 12);
pub const SIGCONT: c_int = sig!(Cont, 18);
pub const SIGSTOP: c_int = sig!(Stop, 19);
pub const SIGTSTP: c_int = sig!(Tstp, 20);
pub const SIGURG: c_int = sig!(Urg, 23);
pub const SIGIO: c_int = sig!(Io, 29);
pub const SIGSYS: c_int = sig!(Sys, 31);
}
macro_rules! define_signal_enum {
(
$(#[$outer:meta])*
pub enum Signal {
$(
$(#[$inner:meta])*
$name:ident = $value:ident,
)*
}
) => {
$(#[$outer])*
#[derive(Copy, Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Hash)]
#[repr(i32)]
pub enum Signal {
$(
$(#[$inner])*
$name = signum::$value,
)*
}
impl Signal {
/// Returns the signal number.
fn number(self) -> std::os::raw::c_int {
match self {
$(
Signal::$name => signum::$value,
)*
}
}
/// Parse a signal from its number.
#[cfg(unix)]
fn from_number(number: std::os::raw::c_int) -> Option<Self> {
match number {
$(
signum::$value => Some(Signal::$name),
)*
_ => None,
}
}
}
}
}
define_signal_enum! {
// Copied from https://github.com/bytecodealliance/rustix/blob/main/src/backend/linux_raw/process/types.rs#L81-L161
/// The signal types that we are able to listen for.
pub enum Signal {
/// `SIGHUP`
Hup = SIGHUP,
/// `SIGINT`
Int = SIGINT,
/// `SIGQUIT`
Quit = SIGQUIT,
/// `SIGILL`
Ill = SIGILL,
/// `SIGTRAP`
Trap = SIGTRAP,
/// `SIGABRT`, aka `SIGIOT`
#[doc(alias = "Iot")]
#[doc(alias = "Abrt")]
Abort = SIGABRT,
/// `SIGBUS`
Bus = SIGBUS,
/// `SIGFPE`
Fpe = SIGFPE,
/// `SIGKILL`
Kill = SIGKILL,
/// `SIGUSR1`
Usr1 = SIGUSR1,
/// `SIGSEGV`
Segv = SIGSEGV,
/// `SIGUSR2`
Usr2 = SIGUSR2,
/// `SIGPIPE`
Pipe = SIGPIPE,
/// `SIGALRM`
#[doc(alias = "Alrm")]
Alarm = SIGALRM,
/// `SIGTERM`
Term = SIGTERM,
/// `SIGCHLD`
#[doc(alias = "Chld")]
Child = SIGCHLD,
/// `SIGCONT`
Cont = SIGCONT,
/// `SIGSTOP`
Stop = SIGSTOP,
/// `SIGTSTP`
Tstp = SIGTSTP,
/// `SIGTTIN`
Ttin = SIGTTIN,
/// `SIGTTOU`
Ttou = SIGTTOU,
/// `SIGURG`
Urg = SIGURG,
/// `SIGXCPU`
Xcpu = SIGXCPU,
/// `SIGXFSZ`
Xfsz = SIGXFSZ,
/// `SIGVTALRM`
#[doc(alias = "Vtalrm")]
Vtalarm = SIGVTALRM,
/// `SIGPROF`
Prof = SIGPROF,
/// `SIGWINCH`
Winch = SIGWINCH,
/// `SIGIO`, aka `SIGPOLL`
#[doc(alias = "Poll")]
Io = SIGIO,
/// `SIGSYS`, aka `SIGUNUSED`
#[doc(alias = "Unused")]
Sys = SIGSYS,
}
}
/// Wait for a specific set of signals.
///
/// See the [module-level documentation](index.html) for more details.
pub struct Signals {
/// The strategy used to read the signals.
notifier: sys::Notifier,
/// The map between signal numbers and signal IDs.
signal_ids: HashMap<Signal, SigId>,
}
impl Drop for Signals {
fn drop(&mut self) {
for signal in self.signal_ids.values() {
registry::unregister(*signal);
}
}
}
impl fmt::Debug for Signals {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
struct RegisteredSignals<'a>(&'a HashMap<Signal, SigId>);
impl fmt::Debug for RegisteredSignals<'_> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_set().entries(self.0.keys()).finish()
}
}
f.debug_struct("Signals")
.field("notifier", &self.notifier)
.field("signal_ids", &RegisteredSignals(&self.signal_ids))
.finish()
}
}
impl Signals {
/// Create a new `Signals` instance with a set of signals.
pub fn new<B>(signals: impl IntoIterator<Item = B>) -> io::Result<Self>
where
B: Borrow<Signal>,
{
let mut this = Self {
notifier: sys::Notifier::new()?,
signal_ids: HashMap::new(),
};
// Add the signals to the set of signals to wait for.
this.add_signals(signals)?;
Ok(this)
}
/// Add signals to the set of signals to wait for.
///
/// One signal cannot be added twice. If a signal that has already been added is passed to this
/// method, it will be ignored.
///
/// Registering a signal prevents the default behavior of that signal from occurring. For
/// example, if you register `SIGINT`, pressing `Ctrl+C` will no longer terminate the process.
/// To run the default signal handler, use [`signal_hook::low_level::emulate_default_handler`]
/// instead.
///
/// [`signal_hook::low_level::emulate_default_handler`]: https://docs.rs/signal-hook/latest/signal_hook/low_level/fn.emulate_default_handler.html
pub fn add_signals<B>(&mut self, signals: impl IntoIterator<Item = B>) -> io::Result<()>
where
B: Borrow<Signal>,
{
for signal in signals {
let signal = signal.borrow();
// If we've already registered this signal, skip it.
if self.signal_ids.contains_key(signal) {
continue;
}
// Get the closure to call when the signal is received.
let closure = self.notifier.add_signal(*signal)?;
let id = unsafe {
// SAFETY: Closure is guaranteed to be signal-safe.
registry::register(signal.number(), closure)?
};
// Add the signal ID to the map.
self.signal_ids.insert(*signal, id);
}
Ok(())
}
/// Remove signals from the set of signals to wait for.
///
/// This function can be used to opt out of listening to signals previously registered via
/// [`add_signals`](Self::add_signals) or [`new`](Self::new). If a signal that has not been
/// registered is passed to this method, it will be ignored.
pub fn remove_signals<B>(&mut self, signals: impl IntoIterator<Item = B>) -> io::Result<()>
where
B: Borrow<Signal>,
{
for signal in signals {
let signal = signal.borrow();
// If we haven't registered this signal, skip it.
let id = match self.signal_ids.remove(signal) {
Some(id) => id,
None => continue,
};
// Remove the signal from the notifier.
self.notifier.remove_signal(*signal)?;
// Use `signal-hook-registry` to unregister the signal.
registry::unregister(id);
}
Ok(())
}
}
#[cfg(unix)]
impl AsRawFd for Signals {
fn as_raw_fd(&self) -> RawFd {
self.notifier.as_raw_fd()
}
}
#[cfg(unix)]
impl AsFd for Signals {
fn as_fd(&self) -> BorrowedFd<'_> {
self.notifier.as_fd()
}
}
impl Unpin for Signals {}
impl Stream for Signals {
type Item = io::Result<Signal>;
#[inline]
fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
Pin::new(&mut &*self).poll_next(cx)
}
#[inline]
fn size_hint(&self) -> (usize, Option<usize>) {
// This stream is expected to never end.
(std::usize::MAX, None)
}
}
impl Stream for &Signals {
type Item = io::Result<Signal>;
fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
let signal = ready!(self.notifier.poll_next(cx))?;
Poll::Ready(Some(Ok(signal)))
}
#[inline]
fn size_hint(&self) -> (usize, Option<usize>) {
// This stream is expected to never end.
(std::usize::MAX, None)
}
}