fish-shell/src/event.rs
Fabian Boehm 0a92d03498 Remove L! from sprintf calls
Remove unnecessary L!
2024-01-13 08:52:54 +01:00

685 lines
23 KiB
Rust

//! Functions for handling event triggers
//!
//! Because most of these functions can be called by signal handler, it is important to make it well
//! defined when these functions produce output or perform memory allocations, since such functions
//! may not be safely called by signal handlers.
use libc::pid_t;
use std::sync::atomic::{AtomicBool, AtomicU32, Ordering};
use std::sync::{Arc, Mutex};
use crate::common::{escape, scoped_push_replacer, ScopeGuard};
use crate::flog::FLOG;
use crate::io::{IoChain, IoStreams};
use crate::job_group::MaybeJobId;
use crate::parser::{Block, Parser};
use crate::signal::{signal_check_cancel, signal_handle, Signal};
use crate::termsize;
use crate::wchar::prelude::*;
pub enum event_type_t {
any,
signal,
variable,
process_exit,
job_exit,
caller_exit,
generic,
}
pub const ANY_PID: pid_t = 0;
#[derive(Debug, Clone, PartialEq, Eq, PartialOrd, Ord)]
pub enum EventDescription {
/// Matches any event type (not always any event, as the function name may limit the choice as
/// well).
Any,
/// An event triggered by a signal.
Signal { signal: Signal },
/// An event triggered by a variable update.
Variable { name: WString },
/// An event triggered by a process exit.
ProcessExit {
/// Process ID. Use [`ANY_PID`] to match any pid.
pid: pid_t,
},
/// An event triggered by a job exit.
JobExit {
/// pid requested by the event, or [`ANY_PID`] for all.
pid: pid_t,
/// `internal_job_id` of the job to match.
/// If this is 0, we match either all jobs (`pid == ANY_PID`) or no jobs (otherwise).
internal_job_id: u64,
},
/// An event triggered by a job exit, triggering the 'caller'-style events only.
CallerExit {
/// Internal job ID.
caller_id: u64,
},
/// A generic event.
Generic {
/// The parameter describing this generic event.
param: WString,
},
}
impl EventDescription {
fn str_param1(&self) -> Option<&wstr> {
match self {
EventDescription::Any
| EventDescription::Signal { .. }
| EventDescription::ProcessExit { .. }
| EventDescription::JobExit { .. }
| EventDescription::CallerExit { .. } => None,
EventDescription::Variable { name } => Some(name),
EventDescription::Generic { param } => Some(param),
}
}
fn name(&self) -> &'static wstr {
match self {
EventDescription::Any => L!("any"),
EventDescription::Signal { .. } => L!("signal"),
EventDescription::Variable { .. } => L!("variable"),
EventDescription::ProcessExit { .. } => L!("process-exit"),
EventDescription::JobExit { .. } => L!("job-exit"),
EventDescription::CallerExit { .. } => L!("caller-exit"),
EventDescription::Generic { .. } => L!("generic"),
}
}
fn matches_filter(&self, filter: &wstr) -> bool {
if filter.is_empty() {
return true;
}
match self {
EventDescription::Any => false,
EventDescription::ProcessExit { .. }
| EventDescription::JobExit { .. }
| EventDescription::CallerExit { .. }
if filter == "exit" =>
{
true
}
_ => filter == self.name(),
}
}
}
impl From<&EventDescription> for event_type_t {
fn from(desc: &EventDescription) -> Self {
match desc {
EventDescription::Any => event_type_t::any,
EventDescription::Signal { .. } => event_type_t::signal,
EventDescription::Variable { .. } => event_type_t::variable,
EventDescription::ProcessExit { .. } => event_type_t::process_exit,
EventDescription::JobExit { .. } => event_type_t::job_exit,
EventDescription::CallerExit { .. } => event_type_t::caller_exit,
EventDescription::Generic { .. } => event_type_t::generic,
}
}
}
#[derive(Debug)]
pub struct EventHandler {
/// Properties of the event to match.
pub desc: EventDescription,
/// Name of the function to invoke.
pub function_name: WString,
/// A flag set when an event handler is removed from the global list.
/// Once set, this is never cleared.
pub removed: AtomicBool,
/// A flag set when an event handler is first fired.
pub fired: AtomicBool,
}
impl EventHandler {
pub fn new(desc: EventDescription, name: Option<WString>) -> Self {
Self {
desc,
function_name: name.unwrap_or_default(),
removed: AtomicBool::new(false),
fired: AtomicBool::new(false),
}
}
/// \return true if a handler is "one shot": it fires at most once.
fn is_one_shot(&self) -> bool {
match self.desc {
EventDescription::ProcessExit { pid } => pid != ANY_PID,
EventDescription::JobExit { pid, .. } => pid != ANY_PID,
EventDescription::CallerExit { .. } => true,
EventDescription::Signal { .. }
| EventDescription::Variable { .. }
| EventDescription::Generic { .. }
| EventDescription::Any => false,
}
}
/// Tests if this event handler matches an event that has occurred.
fn matches(&self, event: &Event) -> bool {
match (&self.desc, &event.desc) {
(EventDescription::Any, _) => true,
(
EventDescription::Signal { signal },
EventDescription::Signal { signal: ev_signal },
) => signal == ev_signal,
(EventDescription::Variable { name }, EventDescription::Variable { name: ev_name }) => {
name == ev_name
}
(
EventDescription::ProcessExit { pid },
EventDescription::ProcessExit { pid: ev_pid },
) => *pid == ANY_PID || pid == ev_pid,
(
EventDescription::JobExit {
pid,
internal_job_id,
},
EventDescription::JobExit {
internal_job_id: ev_internal_job_id,
..
},
) => *pid == ANY_PID || internal_job_id == ev_internal_job_id,
(
EventDescription::CallerExit { caller_id },
EventDescription::CallerExit {
caller_id: ev_caller_id,
},
) => caller_id == ev_caller_id,
(
EventDescription::Generic { param },
EventDescription::Generic { param: ev_param },
) => param == ev_param,
(_, _) => false,
}
}
}
type EventHandlerList = Vec<Arc<EventHandler>>;
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct Event {
desc: EventDescription,
arguments: Vec<WString>,
}
impl Event {
pub fn generic(desc: WString) -> Self {
Self {
desc: EventDescription::Generic { param: desc },
arguments: vec![],
}
}
pub fn variable_erase(name: WString) -> Self {
Self {
desc: EventDescription::Variable { name: name.clone() },
arguments: vec!["VARIABLE".into(), "ERASE".into(), name],
}
}
pub fn variable_set(name: WString) -> Self {
Self {
desc: EventDescription::Variable { name: name.clone() },
arguments: vec!["VARIABLE".into(), "SET".into(), name],
}
}
pub fn process_exit(pid: pid_t, status: i32) -> Self {
Self {
desc: EventDescription::ProcessExit { pid },
arguments: vec![
"PROCESS_EXIT".into(),
pid.to_string().into(),
status.to_string().into(),
],
}
}
pub fn job_exit(pgid: pid_t, jid: u64) -> Self {
Self {
desc: EventDescription::JobExit {
pid: pgid,
internal_job_id: jid,
},
arguments: vec![
"JOB_EXIT".into(),
pgid.to_string().into(),
"0".into(), // historical
],
}
}
pub fn caller_exit(internal_job_id: u64, job_id: MaybeJobId) -> Self {
Self {
desc: EventDescription::CallerExit {
caller_id: internal_job_id,
},
arguments: vec![
"JOB_EXIT".into(),
job_id.to_wstring(),
"0".into(), // historical
],
}
}
/// Test if specified event is blocked.
fn is_blocked(&self, parser: &Parser) -> bool {
for block in parser.blocks().iter().rev() {
if block.event_blocks != 0 {
return true;
}
}
parser.global_event_blocks.load(Ordering::Relaxed) != 0
}
}
/// All the signals we are interested in are in the 1-32 range (with 32 being the typical SIGRTMAX),
/// but we can expand it to 64 just to be safe. All code checks if a signal value is within bounds
/// before handling it.
const SIGNAL_COUNT: usize = 64;
struct PendingSignals {
/// A counter that is incremented each time a pending signal is received.
counter: AtomicU32,
/// List of pending signals.
received: [AtomicBool; SIGNAL_COUNT],
/// The last counter visible in `acquire_pending()`.
/// This is not accessed from a signal handler.
last_counter: Mutex<u32>,
}
impl PendingSignals {
/// Mark a signal as pending. This may be called from a signal handler. We expect only one
/// signal handler to execute at once. Also note that these may be coalesced.
pub fn mark(&self, sig: libc::c_int) {
if let Some(received) = self.received.get(usize::try_from(sig).unwrap()) {
received.store(true, Ordering::Relaxed);
self.counter.fetch_add(1, Ordering::Relaxed);
}
}
/// Return the list of signals that were set as the bits in a u64, clearing them.
pub fn acquire_pending(&self) -> u64 {
let mut current = self
.last_counter
.lock()
.expect("mutex should not be poisoned");
// Check the counter first. If it hasn't changed, no signals have been received.
let count = self.counter.load(Ordering::Acquire);
if count == *current {
return 0;
}
// The signal count has changed. Store the new counter and fetch all set signals.
*current = count;
let mut result = 0;
for (i, received) in self.received.iter().enumerate() {
if received.load(Ordering::Relaxed) {
result |= 1_u64 << i;
received.store(false, Ordering::Relaxed);
}
}
result
}
}
// Required until inline const is stabilized.
#[allow(clippy::declare_interior_mutable_const)]
const ATOMIC_BOOL_FALSE: AtomicBool = AtomicBool::new(false);
#[allow(clippy::declare_interior_mutable_const)]
const ATOMIC_U32_0: AtomicU32 = AtomicU32::new(0);
static PENDING_SIGNALS: PendingSignals = PendingSignals {
counter: AtomicU32::new(0),
received: [ATOMIC_BOOL_FALSE; SIGNAL_COUNT],
last_counter: Mutex::new(0),
};
/// List of event handlers. **While this is locked to allow safely accessing/modifying the vector,
/// note that it does NOT provide exclusive access to the [`EventHandler`] objects which are shared
/// references (in an `Arc<T>`).**
static EVENT_HANDLERS: Mutex<EventHandlerList> = Mutex::new(Vec::new());
/// Tracks the number of registered event handlers for each signal.
/// This is inspected by a signal handler. We assume no values in here overflow.
static OBSERVED_SIGNALS: [AtomicU32; SIGNAL_COUNT] = [ATOMIC_U32_0; SIGNAL_COUNT];
/// List of events that have been sent but have not yet been delivered because they are blocked.
///
/// This was part of profile_item_t accessed as parser.libdata().blocked_events and has been
/// temporarily moved here. There was no mutex around this in the cpp code. TODO: Move it back.
static BLOCKED_EVENTS: Mutex<Vec<Event>> = Mutex::new(Vec::new());
fn inc_signal_observed(sig: Signal) {
if let Some(sig) = OBSERVED_SIGNALS.get(usize::from(sig)) {
sig.fetch_add(1, Ordering::Relaxed);
}
}
fn dec_signal_observed(sig: Signal) {
if let Some(sig) = OBSERVED_SIGNALS.get(usize::from(sig)) {
sig.fetch_sub(1, Ordering::Relaxed);
}
}
/// Returns whether an event listener is registered for the given signal. This is safe to call from
/// a signal handler.
pub fn is_signal_observed(sig: libc::c_int) -> bool {
// We are in a signal handler!
OBSERVED_SIGNALS
.get(usize::try_from(sig).unwrap())
.map_or(false, |s| s.load(Ordering::Relaxed) > 0)
}
pub fn get_desc(parser: &Parser, evt: &Event) -> WString {
let s = match &evt.desc {
EventDescription::Signal { signal } => {
format!("signal handler for {} ({})", signal.name(), signal.desc(),)
}
EventDescription::Variable { name } => format!("handler for variable '{name}'"),
EventDescription::ProcessExit { pid } => format!("exit handler for process {pid}"),
EventDescription::JobExit { pid, .. } => {
if let Some(job) = parser.job_get_from_pid(*pid) {
format!("exit handler for job {}, '{}'", job.job_id(), job.command())
} else {
format!("exit handler for job with pid {pid}")
}
}
EventDescription::CallerExit { .. } => {
"exit handler for command substitution caller".to_string()
}
EventDescription::Generic { param } => format!("handler for generic event '{param}'"),
EventDescription::Any => unreachable!(),
};
WString::from_str(&s)
}
/// Add an event handler.
pub fn add_handler(eh: EventHandler) {
if let EventDescription::Signal { signal } = eh.desc {
signal_handle(signal);
inc_signal_observed(signal);
}
EVENT_HANDLERS
.lock()
.expect("event handler list should not be poisoned")
.push(Arc::new(eh));
}
/// Remove handlers where `pred` returns true. Simultaneously update our `signal_observed` array.
fn remove_handlers_if(pred: impl Fn(&EventHandler) -> bool) -> usize {
let mut handlers = EVENT_HANDLERS
.lock()
.expect("event handler list should not be poisoned");
let mut removed = 0;
for i in (0..handlers.len()).rev() {
let handler = &handlers[i];
if pred(handler) {
handler.removed.store(true, Ordering::Relaxed);
if let EventDescription::Signal { signal } = handler.desc {
dec_signal_observed(signal);
}
handlers.remove(i);
removed += 1;
}
}
removed
}
/// Remove all events for the given function name.
pub fn remove_function_handlers(name: &wstr) -> usize {
remove_handlers_if(|h| h.function_name == name)
}
/// Return all event handlers for the given function.
pub fn get_function_handlers(name: &wstr) -> EventHandlerList {
EVENT_HANDLERS
.lock()
.expect("event handler list should not be poisoned")
.iter()
.filter(|h| h.function_name == name)
.cloned()
.collect()
}
/// Perform the specified event. Since almost all event firings will not be matched by even a single
/// event handler, we make sure to optimize the 'no matches' path. This means that nothing is
/// allocated/initialized unless needed.
fn fire_internal(parser: &Parser, event: &Event) {
assert!(
parser.libdata().pods.is_event >= 0,
"is_event should not be negative"
);
// Suppress fish_trace during events.
let is_event = parser.libdata().pods.is_event;
let _inc_event = scoped_push_replacer(
|new_value| std::mem::replace(&mut parser.libdata_mut().pods.is_event, new_value),
is_event + 1,
);
let _suppress_trace = scoped_push_replacer(
|new_value| {
std::mem::replace(
&mut parser.libdata_mut().pods.suppress_fish_trace,
new_value,
)
},
true,
);
// Capture the event handlers that match this event.
let fire: Vec<_> = EVENT_HANDLERS
.lock()
.expect("event handler list should not be poisoned")
.iter()
.filter(|h| h.matches(event))
.cloned()
.collect();
// Iterate over our list of matching events. Fire the ones that are still present.
let mut fired_one_shot = false;
for handler in fire {
// A previous handler may have erased this one.
if handler.removed.load(Ordering::Relaxed) {
continue;
};
// Construct a buffer to evaluate, starting with the function name and then all the
// arguments.
let mut buffer = handler.function_name.clone();
for arg in &event.arguments {
buffer.push(' ');
buffer.push_utfstr(&escape(arg));
}
// Event handlers are not part of the main flow of code, so they are marked as
// non-interactive.
let saved_is_interactive =
std::mem::replace(&mut parser.libdata_mut().pods.is_interactive, false);
let saved_statuses = parser.get_last_statuses();
let _cleanup = ScopeGuard::new((), |()| {
parser.set_last_statuses(saved_statuses);
parser.libdata_mut().pods.is_interactive = saved_is_interactive;
});
FLOG!(
event,
"Firing event '",
event.desc.str_param1().unwrap_or(L!("")),
"' to handler '",
handler.function_name,
"'"
);
let b = parser.push_block(Block::event_block(event.clone()));
parser.eval(&buffer, &IoChain::new());
parser.pop_block(b);
handler.fired.store(true, Ordering::Relaxed);
fired_one_shot |= handler.is_one_shot();
}
if fired_one_shot {
remove_handlers_if(|h| h.fired.load(Ordering::Relaxed) && h.is_one_shot());
}
}
/// Fire all delayed events attached to the given parser.
pub fn fire_delayed(parser: &Parser) {
{
let ld = &parser.libdata().pods;
// Do not invoke new event handlers from within event handlers.
if ld.is_event != 0 {
return;
};
}
// Do not invoke new event handlers if we are unwinding (#6649).
if signal_check_cancel() != 0 {
return;
};
// We unfortunately can't keep this locked until we're done with it because the SIGWINCH handler
// code might call back into here and we would delay processing of the events, leading to a test
// failure under CI.
let mut to_send = std::mem::take(&mut *BLOCKED_EVENTS.lock().expect("Mutex poisoned!"));
// Append all signal events to to_send.
// 'signals' contains a bit set for each signal that has been received.
let mut signals: u64 = PENDING_SIGNALS.acquire_pending();
while signals != 0 {
let sig = signals.trailing_zeros() as i32;
signals &= !(1_u64 << sig);
let sig = Signal::new(sig);
// HACK: The only variables we change in response to a *signal* are $COLUMNS and $LINES.
// Do that now.
if sig == libc::SIGWINCH {
termsize::SHARED_CONTAINER.updating(parser);
}
let event = Event {
desc: EventDescription::Signal { signal: sig },
arguments: vec![sig.name().into()],
};
to_send.push(event);
}
// Fire or re-block all events. Don't obtain BLOCKED_EVENTS until we know that we have at least
// one event that is blocked.
let mut blocked_events = None;
for event in to_send {
if event.is_blocked(parser) {
if blocked_events.is_none() {
blocked_events = Some(BLOCKED_EVENTS.lock().expect("Mutex poisoned"));
}
blocked_events.as_mut().unwrap().push(event);
} else {
// fire_internal() does not access BLOCKED_EVENTS so this call can't deadlock.
fire_internal(parser, &event);
}
}
}
/// Enqueue a signal event. Invoked from a signal handler.
pub fn enqueue_signal(signal: libc::c_int) {
// Beware, we are in a signal handler
PENDING_SIGNALS.mark(signal);
}
/// Fire the specified event event, executing it on `parser`.
pub fn fire(parser: &Parser, event: Event) {
// Fire events triggered by signals.
fire_delayed(parser);
if event.is_blocked(parser) {
BLOCKED_EVENTS.lock().expect("Mutex poisoned!").push(event);
} else {
fire_internal(parser, &event);
}
}
pub const EVENT_FILTER_NAMES: [&wstr; 7] = [
L!("signal"),
L!("variable"),
L!("exit"),
L!("process-exit"),
L!("job-exit"),
L!("caller-exit"),
L!("generic"),
];
/// Print all events. If type_filter is not empty, only output events with that type.
pub fn print(streams: &mut IoStreams, type_filter: &wstr) {
let mut tmp = EVENT_HANDLERS
.lock()
.expect("event handler list should not be poisoned")
.clone();
tmp.sort_by(|e1, e2| e1.desc.cmp(&e2.desc));
let mut last_type = std::mem::discriminant(&EventDescription::Any);
for evt in tmp {
// If we have a filter, skip events that don't match.
if !evt.desc.matches_filter(type_filter) {
continue;
}
// Print a "Event $TYPE" header for each event type.
// This compares only the event *type*, not the entire event,
// so we don't compare variable events for different variables as different.
//
// This assumes EventDescription::Any is not a valid value for an event to have
// - it's marked "unreachable!()" below!
if last_type != std::mem::discriminant(&evt.desc) {
if last_type != std::mem::discriminant(&EventDescription::Any) {
streams.out.append(L!("\n"));
}
last_type = std::mem::discriminant(&evt.desc);
streams.out.append(sprintf!("Event %ls\n", evt.desc.name()));
}
match &evt.desc {
EventDescription::Signal { signal } => {
let name: WString = signal.name().into();
streams
.out
.append(sprintf!("%ls %ls\n", name, evt.function_name));
}
EventDescription::ProcessExit { .. } | EventDescription::JobExit { .. } => {}
EventDescription::CallerExit { .. } => {
streams
.out
.append(sprintf!("caller-exit %ls\n", evt.function_name));
}
EventDescription::Variable { name: param } | EventDescription::Generic { param } => {
streams
.out
.append(sprintf!("%ls %ls\n", param, evt.function_name));
}
EventDescription::Any => unreachable!(),
}
}
}
/// Fire a generic event with the specified name.
pub fn fire_generic(parser: &Parser, name: WString, arguments: Vec<WString>) {
fire(
parser,
Event {
desc: EventDescription::Generic { param: name },
arguments,
},
)
}