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rust/rust-lang/rust/refs/heads/perf-tmp/./compiler/rustc_query_impl/src/execution.rs
blob: 826a794bc8fa649750ab85c6ad241cebb62ea755 [file] [log] [blame] [edit]
use std::hash::Hash;
use std::mem;
use rustc_data_structures::hash_table::{Entry, HashTable};
use rustc_data_structures::stack::ensure_sufficient_stack;
use rustc_data_structures::{outline, sharded, sync};
use rustc_errors::{Diag, FatalError, StashKey};
use rustc_middle::dep_graph::{DepGraphData, DepNodeKey, HasDepContext};
use rustc_middle::query::{
ActiveKeyStatus, CycleError, CycleErrorHandling, QueryCache, QueryJob, QueryJobId, QueryLatch,
QueryMode, QueryStackDeferred, QueryStackFrame, QueryState,
};
use rustc_middle::ty::TyCtxt;
use rustc_middle::verify_ich::incremental_verify_ich;
use rustc_span::{DUMMY_SP, Span};
use crate::dep_graph::{DepNode, DepNodeIndex};
use crate::job::{QueryJobInfo, QueryJobMap, find_cycle_in_stack, report_cycle};
use crate::{QueryCtxt, QueryFlags, SemiDynamicQueryDispatcher};
#[inline]
fn equivalent_key<K: Eq, V>(k: &K) -> impl Fn(&(K, V)) -> bool + '_ {
move |x| x.0 == *k
}
/// Obtains the enclosed [`QueryJob`], or panics if this query evaluation
/// was poisoned by a panic.
fn expect_job<'tcx>(status: ActiveKeyStatus<'tcx>) -> QueryJob<'tcx> {
match status {
ActiveKeyStatus::Started(job) => job,
ActiveKeyStatus::Poisoned => {
panic!("job for query failed to start and was poisoned")
}
}
}
pub(crate) fn all_inactive<'tcx, K>(state: &QueryState<'tcx, K>) -> bool {
state.active.lock_shards().all(|shard| shard.is_empty())
}
/// Internal plumbing for collecting the set of active jobs for this query.
///
/// Should only be called from `gather_active_jobs`.
pub(crate) fn gather_active_jobs_inner<'tcx, K: Copy>(
state: &QueryState<'tcx, K>,
tcx: TyCtxt<'tcx>,
make_frame: fn(TyCtxt<'tcx>, K) -> QueryStackFrame<QueryStackDeferred<'tcx>>,
require_complete: bool,
job_map_out: &mut QueryJobMap<'tcx>, // Out-param; job info is gathered into this map
) -> Option<()> {
let mut active = Vec::new();
// Helper to gather active jobs from a single shard.
let mut gather_shard_jobs = |shard: &HashTable<(K, ActiveKeyStatus<'tcx>)>| {
for (k, v) in shard.iter() {
if let ActiveKeyStatus::Started(ref job) = *v {
active.push((*k, job.clone()));
}
}
};
// Lock shards and gather jobs from each shard.
if require_complete {
for shard in state.active.lock_shards() {
gather_shard_jobs(&shard);
}
} else {
// We use try_lock_shards here since we are called from the
// deadlock handler, and this shouldn't be locked.
for shard in state.active.try_lock_shards() {
let shard = shard?;
gather_shard_jobs(&shard);
}
}
// Call `make_frame` while we're not holding a `state.active` lock as `make_frame` may call
// queries leading to a deadlock.
for (key, job) in active {
let frame = make_frame(tcx, key);
job_map_out.insert(job.id, QueryJobInfo { frame, job });
}
Some(())
}
/// Guard object representing the responsibility to execute a query job and
/// mark it as completed.
///
/// This will poison the relevant query key if it is dropped without calling
/// [`Self::complete`].
struct ActiveJobGuard<'tcx, K>
where
K: Eq + Hash + Copy,
{
state: &'tcx QueryState<'tcx, K>,
key: K,
key_hash: u64,
}
#[cold]
#[inline(never)]
fn mk_cycle<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
cycle_error: CycleError,
) -> C::Value {
let error = report_cycle(qcx.tcx.sess, &cycle_error);
handle_cycle_error(query, qcx, &cycle_error, error)
}
fn handle_cycle_error<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
cycle_error: &CycleError,
error: Diag<'_>,
) -> C::Value {
match query.cycle_error_handling() {
CycleErrorHandling::Error => {
let guar = error.emit();
query.value_from_cycle_error(qcx.tcx, cycle_error, guar)
}
CycleErrorHandling::Fatal => {
error.emit();
qcx.tcx.dcx().abort_if_errors();
unreachable!()
}
CycleErrorHandling::DelayBug => {
let guar = error.delay_as_bug();
query.value_from_cycle_error(qcx.tcx, cycle_error, guar)
}
CycleErrorHandling::Stash => {
let guar = if let Some(root) = cycle_error.cycle.first()
&& let Some(span) = root.frame.info.span
{
error.stash(span, StashKey::Cycle).unwrap()
} else {
error.emit()
};
query.value_from_cycle_error(qcx.tcx, cycle_error, guar)
}
}
}
impl<'tcx, K> ActiveJobGuard<'tcx, K>
where
K: Eq + Hash + Copy,
{
/// Completes the query by updating the query cache with the `result`,
/// signals the waiter, and forgets the guard so it won't poison the query.
fn complete<C>(self, cache: &C, result: C::Value, dep_node_index: DepNodeIndex)
where
C: QueryCache<Key = K>,
{
// Forget ourself so our destructor won't poison the query.
// (Extract fields by value first to make sure we don't leak anything.)
let Self { state, key, key_hash }: Self = self;
mem::forget(self);
// Mark as complete before we remove the job from the active state
// so no other thread can re-execute this query.
cache.complete(key, result, dep_node_index);
let job = {
// don't keep the lock during the `unwrap()` of the retrieved value, or we taint the
// underlying shard.
// since unwinding also wants to look at this map, this can also prevent a double
// panic.
let mut shard = state.active.lock_shard_by_hash(key_hash);
match shard.find_entry(key_hash, equivalent_key(&key)) {
Err(_) => None,
Ok(occupied) => Some(occupied.remove().0.1),
}
};
let job = expect_job(job.expect("active query job entry"));
job.signal_complete();
}
}
impl<'tcx, K> Drop for ActiveJobGuard<'tcx, K>
where
K: Eq + Hash + Copy,
{
#[inline(never)]
#[cold]
fn drop(&mut self) {
// Poison the query so jobs waiting on it panic.
let Self { state, key, key_hash } = *self;
let job = {
let mut shard = state.active.lock_shard_by_hash(key_hash);
match shard.find_entry(key_hash, equivalent_key(&key)) {
Err(_) => panic!(),
Ok(occupied) => {
let ((key, value), vacant) = occupied.remove();
vacant.insert((key, ActiveKeyStatus::Poisoned));
expect_job(value)
}
}
};
// Also signal the completion of the job, so waiters
// will continue execution.
job.signal_complete();
}
}
#[cold]
#[inline(never)]
fn cycle_error<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
try_execute: QueryJobId,
span: Span,
) -> (C::Value, Option<DepNodeIndex>) {
// Ensure there was no errors collecting all active jobs.
// We need the complete map to ensure we find a cycle to break.
let job_map = qcx
.collect_active_jobs_from_all_queries(false)
.ok()
.expect("failed to collect active queries");
let error = find_cycle_in_stack(try_execute, job_map, &qcx.current_query_job(), span);
(mk_cycle(query, qcx, error.lift()), None)
}
#[inline(always)]
fn wait_for_query<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
span: Span,
key: C::Key,
latch: QueryLatch<'tcx>,
current: Option<QueryJobId>,
) -> (C::Value, Option<DepNodeIndex>) {
// For parallel queries, we'll block and wait until the query running
// in another thread has completed. Record how long we wait in the
// self-profiler.
let query_blocked_prof_timer = qcx.tcx.prof.query_blocked();
// With parallel queries we might just have to wait on some other
// thread.
let result = latch.wait_on(qcx.tcx, current, span);
match result {
Ok(()) => {
let Some((v, index)) = query.query_cache(qcx).lookup(&key) else {
outline(|| {
// We didn't find the query result in the query cache. Check if it was
// poisoned due to a panic instead.
let key_hash = sharded::make_hash(&key);
let shard = query.query_state(qcx).active.lock_shard_by_hash(key_hash);
match shard.find(key_hash, equivalent_key(&key)) {
// The query we waited on panicked. Continue unwinding here.
Some((_, ActiveKeyStatus::Poisoned)) => FatalError.raise(),
_ => panic!(
"query '{}' result must be in the cache or the query must be poisoned after a wait",
query.name()
),
}
})
};
qcx.tcx.prof.query_cache_hit(index.into());
query_blocked_prof_timer.finish_with_query_invocation_id(index.into());
(v, Some(index))
}
Err(cycle) => (mk_cycle(query, qcx, cycle.lift()), None),
}
}
#[inline(never)]
fn try_execute_query<'tcx, C: QueryCache, const FLAGS: QueryFlags, const INCR: bool>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
span: Span,
key: C::Key,
dep_node: Option<DepNode>,
) -> (C::Value, Option<DepNodeIndex>) {
let state = query.query_state(qcx);
let key_hash = sharded::make_hash(&key);
let mut state_lock = state.active.lock_shard_by_hash(key_hash);
// For the parallel compiler we need to check both the query cache and query state structures
// while holding the state lock to ensure that 1) the query has not yet completed and 2) the
// query is not still executing. Without checking the query cache here, we can end up
// re-executing the query since `try_start` only checks that the query is not currently
// executing, but another thread may have already completed the query and stores it result
// in the query cache.
if qcx.tcx.sess.threads() > 1 {
if let Some((value, index)) = query.query_cache(qcx).lookup(&key) {
qcx.tcx.prof.query_cache_hit(index.into());
return (value, Some(index));
}
}
let current_job_id = qcx.current_query_job();
match state_lock.entry(key_hash, equivalent_key(&key), |(k, _)| sharded::make_hash(k)) {
Entry::Vacant(entry) => {
// Nothing has computed or is computing the query, so we start a new job and insert it in the
// state map.
let id = qcx.next_job_id();
let job = QueryJob::new(id, span, current_job_id);
entry.insert((key, ActiveKeyStatus::Started(job)));
// Drop the lock before we start executing the query
drop(state_lock);
execute_job::<C, FLAGS, INCR>(query, qcx, state, key, key_hash, id, dep_node)
}
Entry::Occupied(mut entry) => {
match &mut entry.get_mut().1 {
ActiveKeyStatus::Started(job) => {
if sync::is_dyn_thread_safe() {
// Get the latch out
let latch = job.latch();
drop(state_lock);
// Only call `wait_for_query` if we're using a Rayon thread pool
// as it will attempt to mark the worker thread as blocked.
return wait_for_query(query, qcx, span, key, latch, current_job_id);
}
let id = job.id;
drop(state_lock);
// If we are single-threaded we know that we have cycle error,
// so we just return the error.
cycle_error(query, qcx, id, span)
}
ActiveKeyStatus::Poisoned => FatalError.raise(),
}
}
}
}
#[inline(always)]
fn execute_job<'tcx, C: QueryCache, const FLAGS: QueryFlags, const INCR: bool>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
state: &'tcx QueryState<'tcx, C::Key>,
key: C::Key,
key_hash: u64,
id: QueryJobId,
dep_node: Option<DepNode>,
) -> (C::Value, Option<DepNodeIndex>) {
// Set up a guard object that will automatically poison the query if a
// panic occurs while executing the query (or any intermediate plumbing).
let job_guard = ActiveJobGuard { state, key, key_hash };
debug_assert_eq!(qcx.tcx.dep_graph.is_fully_enabled(), INCR);
// Delegate to another function to actually execute the query job.
let (result, dep_node_index) = if INCR {
execute_job_incr(query, qcx, qcx.tcx.dep_graph.data().unwrap(), key, dep_node, id)
} else {
execute_job_non_incr(query, qcx, key, id)
};
let cache = query.query_cache(qcx);
if query.feedable() {
// We should not compute queries that also got a value via feeding.
// This can't happen, as query feeding adds the very dependencies to the fed query
// as its feeding query had. So if the fed query is red, so is its feeder, which will
// get evaluated first, and re-feed the query.
if let Some((cached_result, _)) = cache.lookup(&key) {
let Some(hasher) = query.hash_result() else {
panic!(
"no_hash fed query later has its value computed.\n\
Remove `no_hash` modifier to allow recomputation.\n\
The already cached value: {}",
(query.format_value())(&cached_result)
);
};
let (old_hash, new_hash) = qcx.dep_context().with_stable_hashing_context(|mut hcx| {
(hasher(&mut hcx, &cached_result), hasher(&mut hcx, &result))
});
let formatter = query.format_value();
if old_hash != new_hash {
// We have an inconsistency. This can happen if one of the two
// results is tainted by errors.
assert!(
qcx.tcx.dcx().has_errors().is_some(),
"Computed query value for {:?}({:?}) is inconsistent with fed value,\n\
computed={:#?}\nfed={:#?}",
query.dep_kind(),
key,
formatter(&result),
formatter(&cached_result),
);
}
}
}
// Tell the guard to perform completion bookkeeping, and also to not poison the query.
job_guard.complete(cache, result, dep_node_index);
(result, Some(dep_node_index))
}
// Fast path for when incr. comp. is off.
#[inline(always)]
fn execute_job_non_incr<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
key: C::Key,
job_id: QueryJobId,
) -> (C::Value, DepNodeIndex) {
debug_assert!(!qcx.tcx.dep_graph.is_fully_enabled());
// Fingerprint the key, just to assert that it doesn't
// have anything we don't consider hashable
if cfg!(debug_assertions) {
let _ = key.to_fingerprint(qcx.tcx);
}
let prof_timer = qcx.tcx.prof.query_provider();
// Call the query provider.
let result = qcx.start_query(job_id, query.depth_limit(), || query.invoke_provider(qcx, key));
let dep_node_index = qcx.tcx.dep_graph.next_virtual_depnode_index();
prof_timer.finish_with_query_invocation_id(dep_node_index.into());
// Similarly, fingerprint the result to assert that
// it doesn't have anything not considered hashable.
if cfg!(debug_assertions)
&& let Some(hash_result) = query.hash_result()
{
qcx.dep_context().with_stable_hashing_context(|mut hcx| {
hash_result(&mut hcx, &result);
});
}
(result, dep_node_index)
}
#[inline(always)]
fn execute_job_incr<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
dep_graph_data: &DepGraphData,
key: C::Key,
mut dep_node_opt: Option<DepNode>,
job_id: QueryJobId,
) -> (C::Value, DepNodeIndex) {
if !query.anon() && !query.eval_always() {
// `to_dep_node` is expensive for some `DepKind`s.
let dep_node = dep_node_opt.get_or_insert_with(|| query.construct_dep_node(qcx.tcx, &key));
// The diagnostics for this query will be promoted to the current session during
// `try_mark_green()`, so we can ignore them here.
if let Some(ret) = qcx.start_query(job_id, false, || {
try_load_from_disk_and_cache_in_memory(query, dep_graph_data, qcx, &key, dep_node)
}) {
return ret;
}
}
let prof_timer = qcx.tcx.prof.query_provider();
let (result, dep_node_index) = qcx.start_query(job_id, query.depth_limit(), || {
if query.anon() {
// Call the query provider inside an anon task.
return dep_graph_data.with_anon_task_inner(qcx.tcx, query.dep_kind(), || {
query.invoke_provider(qcx, key)
});
}
// `to_dep_node` is expensive for some `DepKind`s.
let dep_node = dep_node_opt.unwrap_or_else(|| query.construct_dep_node(qcx.tcx, &key));
// Call the query provider.
dep_graph_data.with_task(
dep_node,
(qcx, query),
key,
|(qcx, query), key| query.invoke_provider(qcx, key),
query.hash_result(),
)
});
prof_timer.finish_with_query_invocation_id(dep_node_index.into());
(result, dep_node_index)
}
#[inline(always)]
fn try_load_from_disk_and_cache_in_memory<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
dep_graph_data: &DepGraphData,
qcx: QueryCtxt<'tcx>,
key: &C::Key,
dep_node: &DepNode,
) -> Option<(C::Value, DepNodeIndex)> {
// Note this function can be called concurrently from the same query
// We must ensure that this is handled correctly.
let (prev_dep_node_index, dep_node_index) = dep_graph_data.try_mark_green(qcx.tcx, dep_node)?;
debug_assert!(dep_graph_data.is_index_green(prev_dep_node_index));
// First we try to load the result from the on-disk cache.
// Some things are never cached on disk.
if let Some(result) = query.try_load_from_disk(qcx, key, prev_dep_node_index, dep_node_index) {
if std::intrinsics::unlikely(qcx.tcx.sess.opts.unstable_opts.query_dep_graph) {
dep_graph_data.mark_debug_loaded_from_disk(*dep_node)
}
let prev_fingerprint = dep_graph_data.prev_fingerprint_of(prev_dep_node_index);
// If `-Zincremental-verify-ich` is specified, re-hash results from
// the cache and make sure that they have the expected fingerprint.
//
// If not, we still seek to verify a subset of fingerprints loaded
// from disk. Re-hashing results is fairly expensive, so we can't
// currently afford to verify every hash. This subset should still
// give us some coverage of potential bugs though.
let try_verify = prev_fingerprint.split().1.as_u64().is_multiple_of(32);
if std::intrinsics::unlikely(
try_verify || qcx.tcx.sess.opts.unstable_opts.incremental_verify_ich,
) {
incremental_verify_ich(
qcx.tcx,
dep_graph_data,
&result,
prev_dep_node_index,
query.hash_result(),
query.format_value(),
);
}
return Some((result, dep_node_index));
}
// We always expect to find a cached result for things that
// can be forced from `DepNode`.
debug_assert!(
!query.will_cache_on_disk_for_key(qcx.tcx, key)
|| !qcx.tcx.fingerprint_style(dep_node.kind).reconstructible(),
"missing on-disk cache entry for {dep_node:?}"
);
// Sanity check for the logic in `ensure`: if the node is green and the result loadable,
// we should actually be able to load it.
debug_assert!(
!query.is_loadable_from_disk(qcx, key, prev_dep_node_index),
"missing on-disk cache entry for loadable {dep_node:?}"
);
// We could not load a result from the on-disk cache, so
// recompute.
let prof_timer = qcx.tcx.prof.query_provider();
// The dep-graph for this computation is already in-place.
// Call the query provider.
let result = qcx.tcx.dep_graph.with_ignore(|| query.invoke_provider(qcx, *key));
prof_timer.finish_with_query_invocation_id(dep_node_index.into());
// Verify that re-running the query produced a result with the expected hash
// This catches bugs in query implementations, turning them into ICEs.
// For example, a query might sort its result by `DefId` - since `DefId`s are
// not stable across compilation sessions, the result could get up getting sorted
// in a different order when the query is re-run, even though all of the inputs
// (e.g. `DefPathHash` values) were green.
//
// See issue #82920 for an example of a miscompilation that would get turned into
// an ICE by this check
incremental_verify_ich(
qcx.tcx,
dep_graph_data,
&result,
prev_dep_node_index,
query.hash_result(),
query.format_value(),
);
Some((result, dep_node_index))
}
/// Ensure that either this query has all green inputs or been executed.
/// Executing `query::ensure(D)` is considered a read of the dep-node `D`.
/// Returns true if the query should still run.
///
/// This function is particularly useful when executing passes for their
/// side-effects -- e.g., in order to report errors for erroneous programs.
///
/// Note: The optimization is only available during incr. comp.
#[inline(never)]
fn ensure_must_run<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
key: &C::Key,
check_cache: bool,
) -> (bool, Option<DepNode>) {
if query.eval_always() {
return (true, None);
}
// Ensuring an anonymous query makes no sense
assert!(!query.anon());
let dep_node = query.construct_dep_node(qcx.tcx, key);
let dep_graph = &qcx.tcx.dep_graph;
let serialized_dep_node_index = match dep_graph.try_mark_green(qcx.tcx, &dep_node) {
None => {
// A None return from `try_mark_green` means that this is either
// a new dep node or that the dep node has already been marked red.
// Either way, we can't call `dep_graph.read()` as we don't have the
// DepNodeIndex. We must invoke the query itself. The performance cost
// this introduces should be negligible as we'll immediately hit the
// in-memory cache, or another query down the line will.
return (true, Some(dep_node));
}
Some((serialized_dep_node_index, dep_node_index)) => {
dep_graph.read_index(dep_node_index);
qcx.tcx.prof.query_cache_hit(dep_node_index.into());
serialized_dep_node_index
}
};
// We do not need the value at all, so do not check the cache.
if !check_cache {
return (false, None);
}
let loadable = query.is_loadable_from_disk(qcx, key, serialized_dep_node_index);
(!loadable, Some(dep_node))
}
#[inline(always)]
pub(super) fn get_query_non_incr<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
span: Span,
key: C::Key,
) -> C::Value {
debug_assert!(!qcx.tcx.dep_graph.is_fully_enabled());
ensure_sufficient_stack(|| try_execute_query::<C, FLAGS, false>(query, qcx, span, key, None).0)
}
#[inline(always)]
pub(super) fn get_query_incr<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
span: Span,
key: C::Key,
mode: QueryMode,
) -> Option<C::Value> {
debug_assert!(qcx.tcx.dep_graph.is_fully_enabled());
let dep_node = if let QueryMode::Ensure { check_cache } = mode {
let (must_run, dep_node) = ensure_must_run(query, qcx, &key, check_cache);
if !must_run {
return None;
}
dep_node
} else {
None
};
let (result, dep_node_index) = ensure_sufficient_stack(|| {
try_execute_query::<C, FLAGS, true>(query, qcx, span, key, dep_node)
});
if let Some(dep_node_index) = dep_node_index {
qcx.tcx.dep_graph.read_index(dep_node_index)
}
Some(result)
}
pub(crate) fn force_query<'tcx, C: QueryCache, const FLAGS: QueryFlags>(
query: SemiDynamicQueryDispatcher<'tcx, C, FLAGS>,
qcx: QueryCtxt<'tcx>,
key: C::Key,
dep_node: DepNode,
) {
// We may be concurrently trying both execute and force a query.
// Ensure that only one of them runs the query.
if let Some((_, index)) = query.query_cache(qcx).lookup(&key) {
qcx.tcx.prof.query_cache_hit(index.into());
return;
}
debug_assert!(!query.anon());
ensure_sufficient_stack(|| {
try_execute_query::<C, FLAGS, true>(query, qcx, DUMMY_SP, key, Some(dep_node))
});
}