rust/src/librustc/ty/query/job.rs

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#![allow(warnings)]
use std::mem;
use rustc_data_structures::fx::FxHashSet;
use rustc_data_structures::sync::{Lock, LockGuard, Lrc, Weak};
use rustc_data_structures::OnDrop;
use syntax_pos::Span;
use ty::tls;
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use ty::query::Query;
use ty::query::plumbing::CycleError;
#[cfg(not(parallel_compiler))]
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use ty::query::{
plumbing::TryGetJob,
config::QueryDescription,
};
use ty::context::TyCtxt;
use std::process;
use std::{fmt, ptr};
#[cfg(parallel_compiler)]
use {
rayon_core,
parking_lot::{Mutex, Condvar},
std::sync::atomic::Ordering,
std::thread,
std::iter,
std::iter::FromIterator,
syntax_pos::DUMMY_SP,
rustc_data_structures::stable_hasher::{StableHasherResult, StableHasher, HashStable},
};
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/// Indicates the state of a query for a given key in a query map
pub(super) enum QueryResult<'tcx> {
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/// An already executing query. The query job can be used to await for its completion
Started(Lrc<QueryJob<'tcx>>),
/// The query panicked. Queries trying to wait on this will raise a fatal error / silently panic
Poisoned,
}
/// A span and a query key
#[derive(Clone, Debug)]
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pub struct QueryInfo<'tcx> {
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/// The span for a reason this query was required
pub span: Span,
pub query: Query<'tcx>,
}
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/// A object representing an active query job.
pub struct QueryJob<'tcx> {
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pub info: QueryInfo<'tcx>,
/// The parent query job which created this job and is implicitly waiting on it.
pub parent: Option<Lrc<QueryJob<'tcx>>>,
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/// The latch which is used to wait on this job
#[cfg(parallel_compiler)]
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latch: QueryLatch<'tcx>,
}
impl<'tcx> QueryJob<'tcx> {
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/// Creates a new query job
pub fn new(info: QueryInfo<'tcx>, parent: Option<Lrc<QueryJob<'tcx>>>) -> Self {
QueryJob {
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info,
parent,
#[cfg(parallel_compiler)]
latch: QueryLatch::new(),
}
}
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/// Awaits for the query job to complete.
///
/// For single threaded rustc there's no concurrent jobs running, so if we are waiting for any
/// query that means that there is a query cycle, thus this always running a cycle error.
#[cfg(not(parallel_compiler))]
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#[inline(never)]
#[cold]
pub(super) fn cycle_error<'lcx, 'a, D: QueryDescription<'tcx>>(
&self,
tcx: TyCtxt<'_, 'tcx, 'lcx>,
span: Span,
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) -> TryGetJob<'a, 'tcx, D> {
TryGetJob::JobCompleted(Err(Box::new(self.find_cycle_in_stack(tcx, span))))
}
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/// Awaits for the query job to complete.
///
/// For single threaded rustc there's no concurrent jobs running, so if we are waiting for any
/// query that means that there is a query cycle, thus this always running a cycle error.
#[cfg(parallel_compiler)]
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pub(super) fn await<'lcx>(
&self,
tcx: TyCtxt<'_, 'tcx, 'lcx>,
span: Span,
) -> Result<(), Box<CycleError<'tcx>>> {
tls::with_related_context(tcx, move |icx| {
let mut waiter = Lrc::new(QueryWaiter {
query: icx.query.clone(),
span,
cycle: Lock::new(None),
condvar: Condvar::new(),
});
self.latch.await(&waiter);
// FIXME: Get rid of this lock. We have ownership of the QueryWaiter
// although another thread may still have a Lrc reference so we cannot
// use Lrc::get_mut
let mut cycle = waiter.cycle.lock();
match cycle.take() {
None => Ok(()),
Some(cycle) => Err(Box::new(cycle))
}
})
}
#[cfg(not(parallel_compiler))]
fn find_cycle_in_stack<'lcx>(
&self,
tcx: TyCtxt<'_, 'tcx, 'lcx>,
span: Span,
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) -> CycleError<'tcx> {
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// Get the current executing query (waiter) and find the waitee amongst its parents
let mut current_job = tls::with_related_context(tcx, |icx| icx.query.clone());
let mut cycle = Vec::new();
while let Some(job) = current_job {
cycle.push(job.info.clone());
if ptr::eq(&*job, self) {
cycle.reverse();
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// This is the end of the cycle
// The span entry we included was for the usage
// of the cycle itself, and not part of the cycle
// Replace it with the span which caused the cycle to form
cycle[0].span = span;
// Find out why the cycle itself was used
let usage = job.parent.as_ref().map(|parent| {
(job.info.span, parent.info.query.clone())
});
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return CycleError { usage, cycle };
}
current_job = job.parent.clone();
}
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panic!("did not find a cycle")
}
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/// Signals to waiters that the query is complete.
///
/// This does nothing for single threaded rustc,
/// as there are no concurrent jobs which could be waiting on us
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pub fn signal_complete(&self) {
#[cfg(parallel_compiler)]
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self.latch.set();
}
fn as_ptr(&self) -> *const QueryJob<'tcx> {
self as *const _
}
}
#[cfg(parallel_compiler)]
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struct QueryWaiter<'tcx> {
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query: Option<Lrc<QueryJob<'tcx>>>,
condvar: Condvar,
span: Span,
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cycle: Lock<Option<CycleError<'tcx>>>,
}
#[cfg(parallel_compiler)]
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impl<'tcx> QueryWaiter<'tcx> {
fn notify(&self, registry: &rayon_core::Registry) {
rayon_core::mark_unblocked(registry);
self.condvar.notify_one();
}
}
#[cfg(parallel_compiler)]
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struct QueryLatchInfo<'tcx> {
complete: bool,
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waiters: Vec<Lrc<QueryWaiter<'tcx>>>,
}
#[cfg(parallel_compiler)]
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struct QueryLatch<'tcx> {
info: Mutex<QueryLatchInfo<'tcx>>,
}
#[cfg(parallel_compiler)]
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impl<'tcx> QueryLatch<'tcx> {
fn new() -> Self {
QueryLatch {
info: Mutex::new(QueryLatchInfo {
complete: false,
waiters: Vec::new(),
}),
}
}
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/// Awaits the caller on this latch by blocking the current thread.
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fn await(&self, waiter: &Lrc<QueryWaiter<'tcx>>) {
let mut info = self.info.lock();
if !info.complete {
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// We push the waiter on to the `waiters` list. It can be accessed inside
// the `wait` call below, by 1) the `set` method or 2) by deadlock detection.
// Both of these will remove it from the `waiters` list before resuming
// this thread.
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info.waiters.push(waiter.clone());
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// If this detects a deadlock and the deadlock handler wants to resume this thread
// we have to be in the `wait` call. This is ensured by the deadlock handler
// getting the self.info lock.
rayon_core::mark_blocked();
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waiter.condvar.wait(&mut info);
}
}
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/// Sets the latch and resumes all waiters on it
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fn set(&self) {
let mut info = self.info.lock();
debug_assert!(!info.complete);
info.complete = true;
let registry = rayon_core::Registry::current();
for waiter in info.waiters.drain(..) {
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waiter.notify(&registry);
}
}
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/// Remove a single waiter from the list of waiters.
/// This is used to break query cycles.
fn extract_waiter(
&self,
waiter: usize,
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) -> Lrc<QueryWaiter<'tcx>> {
let mut info = self.info.lock();
debug_assert!(!info.complete);
// Remove the waiter from the list of waiters
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info.waiters.remove(waiter)
}
}
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/// A resumable waiter of a query. The usize is the index into waiters in the query's latch
#[cfg(parallel_compiler)]
type Waiter<'tcx> = (Lrc<QueryJob<'tcx>>, usize);
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/// Visits all the non-resumable and resumable waiters of a query.
/// Only waiters in a query are visited.
/// `visit` is called for every waiter and is passed a query waiting on `query_ref`
/// and a span indicating the reason the query waited on `query_ref`.
/// If `visit` returns Some, this function returns.
/// For visits of non-resumable waiters it returns the return value of `visit`.
/// For visits of resumable waiters it returns Some(Some(Waiter)) which has the
/// required information to resume the waiter.
/// If all `visit` calls returns None, this function also returns None.
#[cfg(parallel_compiler)]
fn visit_waiters<'tcx, F>(query: Lrc<QueryJob<'tcx>>, mut visit: F) -> Option<Option<Waiter<'tcx>>>
where
F: FnMut(Span, Lrc<QueryJob<'tcx>>) -> Option<Option<Waiter<'tcx>>>
{
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// Visit the parent query which is a non-resumable waiter since it's on the same stack
if let Some(ref parent) = query.parent {
if let Some(cycle) = visit(query.info.span, parent.clone()) {
return Some(cycle);
}
}
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// Visit the explicit waiters which use condvars and are resumable
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for (i, waiter) in query.latch.info.lock().waiters.iter().enumerate() {
if let Some(ref waiter_query) = waiter.query {
if visit(waiter.span, waiter_query.clone()).is_some() {
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// Return a value which indicates that this waiter can be resumed
return Some(Some((query.clone(), i)));
}
}
}
None
}
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/// Look for query cycles by doing a depth first search starting at `query`.
/// `span` is the reason for the `query` to execute. This is initially DUMMY_SP.
/// If a cycle is detected, this initial value is replaced with the span causing
/// the cycle.
#[cfg(parallel_compiler)]
fn cycle_check<'tcx>(query: Lrc<QueryJob<'tcx>>,
span: Span,
stack: &mut Vec<(Span, Lrc<QueryJob<'tcx>>)>,
visited: &mut FxHashSet<*const QueryJob<'tcx>>
) -> Option<Option<Waiter<'tcx>>> {
if !visited.insert(query.as_ptr()) {
return if let Some(p) = stack.iter().position(|q| q.1.as_ptr() == query.as_ptr()) {
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// We detected a query cycle, fix up the initial span and return Some
// Remove previous stack entries
stack.drain(0..p);
// Replace the span for the first query with the cycle cause
stack[0].0 = span;
Some(None)
} else {
None
}
}
// Query marked as visited is added it to the stack
stack.push((span, query.clone()));
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// Visit all the waiters
let r = visit_waiters(query, |span, successor| {
cycle_check(successor, span, stack, visited)
});
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// Remove the entry in our stack if we didn't find a cycle
if r.is_none() {
stack.pop();
}
r
}
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/// Finds out if there's a path to the compiler root (aka. code which isn't in a query)
/// from `query` without going through any of the queries in `visited`.
/// This is achieved with a depth first search.
#[cfg(parallel_compiler)]
fn connected_to_root<'tcx>(
query: Lrc<QueryJob<'tcx>>,
visited: &mut FxHashSet<*const QueryJob<'tcx>>
) -> bool {
// We already visited this or we're deliberately ignoring it
if !visited.insert(query.as_ptr()) {
return false;
}
// This query is connected to the root (it has no query parent), return true
if query.parent.is_none() {
return true;
}
visit_waiters(query, |_, successor| {
if connected_to_root(successor, visited) {
Some(None)
} else {
None
}
}).is_some()
}
// Deterministically pick an query from a list
#[cfg(parallel_compiler)]
fn pick_query<'a, 'tcx, T, F: Fn(&T) -> (Span, Lrc<QueryJob<'tcx>>)>(
tcx: TyCtxt<'_, 'tcx, '_>,
queries: &'a [T],
f: F
) -> &'a T {
// Deterministically pick an entry point
// FIXME: Sort this instead
let mut hcx = tcx.create_stable_hashing_context();
queries.iter().min_by_key(|v| {
let (span, query) = f(v);
let mut stable_hasher = StableHasher::<u64>::new();
query.info.query.hash_stable(&mut hcx, &mut stable_hasher);
// Prefer entry points which have valid spans for nicer error messages
// We add an integer to the tuple ensuring that entry points
// with valid spans are picked first
let span_cmp = if span == DUMMY_SP { 1 } else { 0 };
(span_cmp, stable_hasher.finish())
}).unwrap()
}
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/// Looks for query cycles starting from the last query in `jobs`.
/// If a cycle is found, all queries in the cycle is removed from `jobs` and
/// the function return true.
/// If a cycle was not found, the starting query is removed from `jobs` and
/// the function returns false.
#[cfg(parallel_compiler)]
fn remove_cycle<'tcx>(
jobs: &mut Vec<Lrc<QueryJob<'tcx>>>,
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wakelist: &mut Vec<Lrc<QueryWaiter<'tcx>>>,
tcx: TyCtxt<'_, 'tcx, '_>
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) -> bool {
let mut visited = FxHashSet::default();
let mut stack = Vec::new();
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// Look for a cycle starting with the last query in `jobs`
if let Some(waiter) = cycle_check(jobs.pop().unwrap(),
DUMMY_SP,
&mut stack,
&mut visited) {
// The stack is a vector of pairs of spans and queries; reverse it so that
// the earlier entries require later entries
let (mut spans, queries): (Vec<_>, Vec<_>) = stack.into_iter().rev().unzip();
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// Shift the spans so that queries are matched with the span for their waitee
spans.rotate_right(1);
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// Zip them back together
let mut stack: Vec<_> = spans.into_iter().zip(queries).collect();
// Remove the queries in our cycle from the list of jobs to look at
for r in &stack {
if let Some(pos) = jobs.iter().position(|j| j.as_ptr() == r.1.as_ptr()) {
jobs.remove(pos);
}
}
// Find the queries in the cycle which are
// connected to queries outside the cycle
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let entry_points = stack.iter().filter_map(|(span, query)| {
if query.parent.is_none() {
// This query is connected to the root (it has no query parent)
Some((*span, query.clone(), None))
} else {
let mut waiters = Vec::new();
// Find all the direct waiters who lead to the root
visit_waiters(query.clone(), |span, waiter| {
// Mark all the other queries in the cycle as already visited
let mut visited = FxHashSet::from_iter(stack.iter().map(|q| q.1.as_ptr()));
if connected_to_root(waiter.clone(), &mut visited) {
waiters.push((span, waiter));
}
None
});
if waiters.is_empty() {
None
} else {
// Deterministically pick one of the waiters to show to the user
let waiter = pick_query(tcx, &waiters, |s| s.clone()).clone();
Some((*span, query.clone(), Some(waiter)))
}
}
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}).collect::<Vec<(Span, Lrc<QueryJob<'tcx>>, Option<(Span, Lrc<QueryJob<'tcx>>)>)>>();
// Deterministically pick an entry point
let (_, entry_point, usage) = pick_query(tcx, &entry_points, |e| (e.0, e.1.clone()));
// Shift the stack so that our entry point is first
let entry_point_pos = stack.iter().position(|(_, query)| {
query.as_ptr() == entry_point.as_ptr()
});
if let Some(pos) = entry_point_pos {
stack.rotate_left(pos);
}
let usage = usage.as_ref().map(|(span, query)| (*span, query.info.query.clone()));
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// Create the cycle error
let mut error = CycleError {
usage,
cycle: stack.iter().map(|&(s, ref q)| QueryInfo {
span: s,
query: q.info.query.clone(),
} ).collect(),
};
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// We unwrap `waiter` here since there must always be one
// edge which is resumeable / waited using a query latch
let (waitee_query, waiter_idx) = waiter.unwrap();
// Extract the waiter we want to resume
let waiter = waitee_query.latch.extract_waiter(waiter_idx);
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// Set the cycle error so it will be picked up when resumed
*waiter.cycle.lock() = Some(error);
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// Put the waiter on the list of things to resume
wakelist.push(waiter);
true
} else {
false
}
}
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/// Creates a new thread and forwards information in thread locals to it.
/// The new thread runs the deadlock handler.
/// Must only be called when a deadlock is about to happen.
#[cfg(parallel_compiler)]
pub unsafe fn handle_deadlock() {
use syntax;
use syntax_pos;
let registry = rayon_core::Registry::current();
let gcx_ptr = tls::GCX_PTR.with(|gcx_ptr| {
gcx_ptr as *const _
});
let gcx_ptr = &*gcx_ptr;
let syntax_globals = syntax::GLOBALS.with(|syntax_globals| {
syntax_globals as *const _
});
let syntax_globals = &*syntax_globals;
let syntax_pos_globals = syntax_pos::GLOBALS.with(|syntax_pos_globals| {
syntax_pos_globals as *const _
});
let syntax_pos_globals = &*syntax_pos_globals;
thread::spawn(move || {
tls::GCX_PTR.set(gcx_ptr, || {
syntax_pos::GLOBALS.set(syntax_pos_globals, || {
syntax_pos::GLOBALS.set(syntax_pos_globals, || {
tls::with_thread_locals(|| {
tls::with_global(|tcx| deadlock(tcx, &registry))
})
})
})
})
});
}
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/// Detects query cycles by using depth first search over all active query jobs.
/// If a query cycle is found it will break the cycle by finding an edge which
/// uses a query latch and then resuming that waiter.
/// There may be multiple cycles involved in a deadlock, so this searches
/// all active queries for cycles before finally resuming all the waiters at once.
#[cfg(parallel_compiler)]
fn deadlock(tcx: TyCtxt<'_, '_, '_>, registry: &rayon_core::Registry) {
let on_panic = OnDrop(|| {
eprintln!("deadlock handler panicked, aborting process");
process::abort();
});
let mut wakelist = Vec::new();
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let mut jobs: Vec<_> = tcx.queries.collect_active_jobs();
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let mut found_cycle = false;
while jobs.len() > 0 {
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if remove_cycle(&mut jobs, &mut wakelist, tcx) {
found_cycle = true;
}
}
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// Check that a cycle was found. It is possible for a deadlock to occur without
// a query cycle if a query which can be waited on uses Rayon to do multithreading
// internally. Such a query (X) may be executing on 2 threads (A and B) and A may
// wait using Rayon on B. Rayon may then switch to executing another query (Y)
// which in turn will wait on X causing a deadlock. We have a false dependency from
// X to Y due to Rayon waiting and a true dependency from Y to X. The algorithm here
// only considers the true dependency and won't detect a cycle.
assert!(found_cycle);
// FIXME: Ensure this won't cause a deadlock before we return
for waiter in wakelist.into_iter() {
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waiter.notify(registry);
}
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on_panic.disable();
}