fish-shell/src/job_group.rs

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Rust
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use crate::global_safety::RelaxedAtomicBool;
use crate::proc::JobGroupRef;
use crate::signal::Signal;
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use crate::wchar::prelude::*;
use std::cell::RefCell;
use std::num::NonZeroU32;
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use std::sync::atomic::{AtomicI32, Ordering};
use std::sync::{Arc, Mutex};
/// A job id, corresponding to what is printed by `jobs`. 1 is the first valid job id.
#[derive(Clone, Copy, Debug, Eq, Ord, PartialEq, PartialOrd)]
#[repr(transparent)]
pub struct JobId(NonZeroU32);
#[derive(Clone, Copy, Debug, Eq, PartialEq)]
pub struct MaybeJobId(pub Option<JobId>);
impl std::ops::Deref for MaybeJobId {
type Target = Option<JobId>;
fn deref(&self) -> &Self::Target {
&self.0
}
}
impl MaybeJobId {
pub fn as_num(&self) -> i64 {
self.0.map(|j| i64::from(u32::from(j.0))).unwrap_or(-1)
}
}
impl std::fmt::Display for MaybeJobId {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
self.as_num().fmt(f)
}
}
impl ToWString for MaybeJobId {
fn to_wstring(&self) -> WString {
self.as_num().to_wstring()
}
}
impl<'a> fish_printf::ToArg<'a> for MaybeJobId {
fn to_arg(self) -> fish_printf::Arg<'a> {
self.as_num().to_arg()
}
}
/// `JobGroup` is conceptually similar to the idea of a process group. It represents data which
/// is shared among all of the "subjobs" that may be spawned by a single job.
/// For example, two fish functions in a pipeline may themselves spawn multiple jobs, but all will
/// share the same job group.
/// There is also a notion of a "internal" job group. Internal groups are used when executing a
/// foreground function or block with no pipeline. These are not jobs as the user understands them -
/// they do not consume a job id, they do not show up in job lists, and they do not have a pgid
/// because they contain no external procs. Note that `JobGroup` is intended to eventually be
/// shared between threads, and so must be thread safe.
#[derive(Debug)]
pub struct JobGroup {
/// If set, the saved terminal modes of this job. This needs to be saved so that we can restore
/// the terminal to the same state when resuming a stopped job.
pub tmodes: RefCell<Option<libc::termios>>,
/// Whether job control is enabled in this `JobGroup` or not.
///
/// If this is set, then the first process in the root job must be external, as it will become
/// the process group leader.
pub job_control: bool,
/// Whether we should `tcsetpgrp()` the job when it runs in the foreground. Should be checked
/// via [`Self::wants_terminal()`] only.
wants_term: bool,
/// Whether we are in the foreground, meaning the user is waiting for this job to complete.
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pub is_foreground: RelaxedAtomicBool,
/// The pgid leading our group. This is only ever set if [`job_control`](Self::JobControl) is
/// true. We ensure the value (when set) is always non-negative.
pgid: RefCell<Option<libc::pid_t>>,
/// The original command which produced this job tree.
pub command: WString,
/// Our job id, if any. `None` here should evaluate to `-1` for ffi purposes.
/// "Simple block" groups like function calls do not have a job id.
pub job_id: MaybeJobId,
/// The signal causing the group to cancel or `0` if none.
/// Not using an `Option<Signal>` to be able to atomically load/store to this field.
signal: AtomicI32,
}
// safety: all fields without interior mutabillity are only written to once
unsafe impl Send for JobGroup {}
unsafe impl Sync for JobGroup {}
impl JobGroup {
/// Whether this job wants job control.
pub fn wants_job_control(&self) -> bool {
self.job_control
}
/// If this job should own the terminal when it runs. True only if both [`Self::wants_term]` and
/// [`Self::is_foreground`] are true.
pub fn wants_terminal(&self) -> bool {
self.wants_term && self.is_foreground()
}
/// Whether we are the currently the foreground group. Should never be true for more than one
/// `JobGroup` at any given moment.
pub fn is_foreground(&self) -> bool {
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self.is_foreground.load()
}
/// Mark whether we are in the foreground.
pub fn set_is_foreground(&self, in_foreground: bool) {
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self.is_foreground.store(in_foreground);
}
/// Returns whether we have valid job id. "Simple block" groups like function calls do not.
pub fn has_job_id(&self) -> bool {
self.job_id.is_some()
}
/// Gets the cancellation signal, if any.
pub fn get_cancel_signal(&self) -> Option<Signal> {
match self.signal.load(Ordering::Relaxed) {
0 => None,
s => Some(Signal::new(s)),
}
}
/// Mark that a process in this group got a signal and should cancel.
pub fn cancel_with_signal(&self, signal: Signal) {
// We only assign the signal if one hasn't yet been assigned. This means the first signal to
// register wins over any that come later.
self.signal
.compare_exchange(0, signal.code(), Ordering::Relaxed, Ordering::Relaxed)
.ok();
}
/// Set the pgid for this job group, latching it to this value. This should only be called if
/// job control is active for this group. The pgid should not already have been set, and should
/// be different from fish's pgid. Of course this does not keep the pgid alive by itself.
///
/// Note we need not be concerned about thread safety. job_groups are intended to be shared
/// across threads, but any pgid should always have been set beforehand, since it's set
/// immediately after the first process launches.
///
/// As such, this method takes `&mut self` rather than `&self` to enforce that this operation is
/// only available during initial construction/initialization.
pub fn set_pgid(&self, pgid: libc::pid_t) {
assert!(
self.wants_job_control(),
"Should not set a pgid for a group that doesn't want job control!"
);
assert!(pgid >= 0, "Invalid pgid!");
assert!(self.pgid.borrow().is_none(), "JobGroup::pgid already set!");
self.pgid.replace(Some(pgid));
}
/// Returns the value of [`JobGroup::pgid`]. This is never fish's own pgid!
pub fn get_pgid(&self) -> Option<libc::pid_t> {
*self.pgid.borrow()
}
}
/// Basic thread-safe sorted vector of job ids currently in use.
///
/// In the C++ codebase, this is deliberately leaked to avoid destructor ordering issues - see
/// #6539. Rust automatically "leaks" all `static` variables (does not call their `Drop` impls)
/// because of the inherent difficulty in doing that correctly (i.e. what we ran into).
static CONSUMED_JOB_IDS: Mutex<Vec<JobId>> = Mutex::new(Vec::new());
impl JobId {
pub const NONE: MaybeJobId = MaybeJobId(None);
pub fn new(value: NonZeroU32) -> Self {
JobId(value)
}
/// Return a `JobId` that is greater than all extant job ids stored in [`CONSUMED_JOB_IDS`].
/// The `JobId` should be freed with [`JobId::release()`] when it is no longer in use.
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fn acquire() -> JobId {
let mut consumed_job_ids = CONSUMED_JOB_IDS.lock().expect("Poisoned mutex!");
// The new job id should be greater than the largest currently used id (#6053). The job ids
// in CONSUMED_JOB_IDS are sorted in ascending order, so we just have to check the last.
let job_id = consumed_job_ids
.last()
.map(JobId::next)
.unwrap_or(JobId(1.try_into().unwrap()));
consumed_job_ids.push(job_id);
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job_id
}
/// Remove the provided `JobId` from [`CONSUMED_JOB_IDS`].
fn release(id: JobId) {
let mut consumed_job_ids = CONSUMED_JOB_IDS.lock().expect("Poisoned mutex!");
let pos = consumed_job_ids
.binary_search(&id)
.expect("Job id was not in use!");
consumed_job_ids.remove(pos);
}
/// Increments the internal id and returns it wrapped in a new `JobId`.
fn next(&self) -> JobId {
JobId(self.0.checked_add(1).expect("Job id overflow!"))
}
}
impl JobGroup {
pub fn new(command: WString, id: MaybeJobId, job_control: bool, wants_term: bool) -> Self {
// We *can* have a job id without job control, but not the reverse.
if job_control {
assert!(id.is_some(), "Cannot have job control without a job id!");
}
if wants_term {
assert!(job_control, "Cannot take terminal without job control!");
}
Self {
job_id: id,
job_control,
wants_term,
command,
tmodes: RefCell::default(),
signal: 0.into(),
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is_foreground: RelaxedAtomicBool::new(false),
pgid: RefCell::default(),
}
}
/// Return a new `JobGroup` with the provided `command`. The `JobGroup` is only assigned a
/// `JobId` if `wants_job_id` is true and is created with job control disabled and
/// [`JobGroup::wants_term`] set to false.
pub fn create(command: WString, wants_job_id: bool) -> JobGroupRef {
Arc::new(JobGroup::new(
command,
if wants_job_id {
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MaybeJobId(Some(JobId::acquire()))
} else {
JobId::NONE
},
false, /* job_control */
false, /* wants_term */
))
}
/// Return a new `JobGroup` with the provided `command` with job control enabled. A [`JobId`] is
/// automatically acquired and assigned. If `wants_term` is true then [`JobGroup::wants_term`]
/// is also set to `true` accordingly.
pub fn create_with_job_control(command: WString, wants_term: bool) -> JobGroupRef {
Arc::new(JobGroup::new(
command,
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MaybeJobId(Some(JobId::acquire())),
true, /* job_control */
wants_term,
))
}
}
impl Drop for JobGroup {
fn drop(&mut self) {
if let Some(job_id) = *self.job_id {
JobId::release(job_id);
}
}
}