1 use crate::dep_graph
::SerializedDepNodeIndex
;
2 use crate::mir
::interpret
::{GlobalId, LitToConstInput}
;
4 use crate::traits
::query
::{
5 CanonicalPredicateGoal
, CanonicalProjectionGoal
, CanonicalTyGoal
,
6 CanonicalTypeOpAscribeUserTypeGoal
, CanonicalTypeOpEqGoal
, CanonicalTypeOpNormalizeGoal
,
7 CanonicalTypeOpProvePredicateGoal
, CanonicalTypeOpSubtypeGoal
,
9 use crate::ty
::query
::queries
;
10 use crate::ty
::subst
::{GenericArg, SubstsRef}
;
11 use crate::ty
::{self, ParamEnvAnd, Ty, TyCtxt}
;
12 use rustc_hir
::def_id
::{CrateNum, DefId, LocalDefId}
;
13 use rustc_query_system
::query
::QueryDescription
;
15 use rustc_span
::symbol
::Symbol
;
18 fn describe_as_module(def_id
: LocalDefId
, tcx
: TyCtxt
<'_
>) -> String
{
19 if def_id
.is_top_level_module() {
20 "top-level module".to_string()
22 format
!("module `{}`", tcx
.def_path_str(def_id
.to_def_id()))
26 // Each of these queries corresponds to a function pointer field in the
27 // `Providers` struct for requesting a value of that type, and a method
28 // on `tcx: TyCtxt` (and `tcx.at(span)`) for doing that request in a way
29 // which memoizes and does dep-graph tracking, wrapping around the actual
30 // `Providers` that the driver creates (using several `rustc_*` crates).
32 // The result type of each query must implement `Clone`, and additionally
33 // `ty::query::values::Value`, which produces an appropriate placeholder
34 // (error) value if the query resulted in a query cycle.
35 // Queries marked with `fatal_cycle` do not need the latter implementation,
36 // as they will raise an fatal error on query cycles instead.
39 query
trigger_delay_span_bug(key
: DefId
) -> () {
40 desc { "trigger a delay span bug" }
45 // Represents crate as a whole (as distinct from the top-level crate module).
46 // If you call `hir_crate` (e.g., indirectly by calling `tcx.hir().krate()`),
47 // we will have to assume that any change means that you need to be recompiled.
48 // This is because the `hir_crate` query gives you access to all other items.
49 // To avoid this fate, do not call `tcx.hir().krate()`; instead,
50 // prefer wrappers like `tcx.visit_all_items_in_krate()`.
51 query
hir_crate(key
: CrateNum
) -> &'tcx Crate
<'tcx
> {
54 desc { "get the crate HIR" }
57 // The indexed HIR. This can be conveniently accessed by `tcx.hir()`.
58 // Avoid calling this query directly.
59 query
index_hir(_
: CrateNum
) -> &'tcx map
::IndexedHir
<'tcx
> {
65 // The items in a module.
67 // This can be conveniently accessed by `tcx.hir().visit_item_likes_in_module`.
68 // Avoid calling this query directly.
69 query
hir_module_items(key
: LocalDefId
) -> &'tcx hir
::ModuleItems
{
71 desc { |tcx| "HIR module items in `{}`
", tcx.def_path_str(key.to_def_id()) }
74 // Gives access to the HIR node for the HIR owner `key`.
76 // This can be conveniently accessed by methods on `tcx.hir()`.
77 // Avoid calling this query directly.
78 query hir_owner(key: LocalDefId) -> Option<&'tcx crate::hir::Owner<'tcx>> {
80 desc { |tcx| "HIR owner of `{}`", tcx
.def_path_str(key
.to_def_id()) }
83 // Gives access to the HIR nodes and bodies inside the HIR owner `key`.
85 // This can be conveniently accessed by methods on `tcx.hir()`.
86 // Avoid calling this query directly.
87 query
hir_owner_nodes(key
: LocalDefId
) -> Option
<&'tcx
crate::hir
::OwnerNodes
<'tcx
>> {
89 desc { |tcx| "HIR owner items in `{}`
", tcx.def_path_str(key.to_def_id()) }
92 /// Computes the `DefId` of the corresponding const parameter in case the `key` is a
93 /// const argument and returns `None` otherwise.
96 /// let a = foo::<7>();
97 /// // ^ Calling `opt_const_param_of` for this argument,
99 /// fn foo<const N: usize>()
100 /// // ^ returns this `DefId`.
103 /// // ^ While calling `opt_const_param_of` for other bodies returns `None`.
106 // It looks like caching this query on disk actually slightly
107 // worsened performance in #74376.
109 // Once const generics are more prevalently used, we might want to
110 // consider only caching calls returning `Some`.
111 query opt_const_param_of(key: LocalDefId) -> Option<DefId> {
112 desc { |tcx| "computing the optional const parameter of `{}`", tcx
.def_path_str(key
.to_def_id()) }
115 /// Records the type of every item.
116 query
type_of(key
: DefId
) -> Ty
<'tcx
> {
117 desc { |tcx| "computing type of `{}`
", tcx.def_path_str(key) }
118 cache_on_disk_if { key.is_local() }
121 query analysis(key: CrateNum) -> Result<(), ErrorReported> {
123 desc { "running analysis passes on this crate" }
126 /// Maps from the `DefId` of an item (trait/struct/enum/fn) to its
127 /// associated generics.
128 query generics_of(key: DefId) -> ty::Generics {
129 desc { |tcx| "computing generics of `{}`", tcx
.def_path_str(key
) }
130 storage(ArenaCacheSelector
<'tcx
>)
131 cache_on_disk_if { key.is_local() }
132 load_cached(tcx
, id
) {
133 let generics
: Option
<ty
::Generics
> = tcx
.queries
.on_disk_cache
134 .try_load_query_result(tcx
, id
);
139 /// Maps from the `DefId` of an item (trait/struct/enum/fn) to the
140 /// predicates (where-clauses) that must be proven true in order
141 /// to reference it. This is almost always the "predicates query"
144 /// `predicates_of` builds on `predicates_defined_on` -- in fact,
145 /// it is almost always the same as that query, except for the
146 /// case of traits. For traits, `predicates_of` contains
147 /// an additional `Self: Trait<...>` predicate that users don't
148 /// actually write. This reflects the fact that to invoke the
149 /// trait (e.g., via `Default::default`) you must supply types
150 /// that actually implement the trait. (However, this extra
151 /// predicate gets in the way of some checks, which are intended
152 /// to operate over only the actual where-clauses written by the
154 query
predicates_of(key
: DefId
) -> ty
::GenericPredicates
<'tcx
> {
155 desc { |tcx| "computing predicates of `{}`
", tcx.def_path_str(key) }
156 cache_on_disk_if { key.is_local() }
159 /// Returns the list of predicates that can be used for
160 /// `SelectionCandidate::ProjectionCandidate` and
161 /// `ProjectionTyCandidate::TraitDef`.
162 /// Specifically this is the bounds (equivalent to) those
163 /// written on the trait's type definition, or those
164 /// after the `impl` keyword
166 /// type X: Bound + 'lt
168 /// impl Debug + Display
171 /// `key` is the `DefId` of the associated type or opaque type.
172 query projection_predicates(key: DefId) -> &'tcx ty::List<ty::Predicate<'tcx>> {
173 desc { |tcx| "finding projection predicates for `{}`", tcx
.def_path_str(key
) }
176 query
native_libraries(_
: CrateNum
) -> Lrc
<Vec
<NativeLib
>> {
177 desc { "looking up the native libraries of a linked crate" }
180 query
lint_levels(_
: CrateNum
) -> LintLevelMap
{
181 storage(ArenaCacheSelector
<'tcx
>)
183 desc { "computing the lint levels for items in this crate" }
186 query
parent_module_from_def_id(key
: LocalDefId
) -> LocalDefId
{
188 desc { |tcx| "parent module of `{}`
", tcx.def_path_str(key.to_def_id()) }
193 query is_panic_runtime(_: CrateNum) -> bool {
195 desc { "checking if the crate is_panic_runtime" }
200 /// Set of all the `DefId`s in this crate that have MIR associated with
201 /// them. This includes all the body owners, but also things like struct
203 query mir_keys(_: CrateNum) -> FxHashSet<LocalDefId> {
204 storage(ArenaCacheSelector<'tcx>)
205 desc { "getting a list of all mir_keys" }
208 /// Maps DefId's that have an associated `mir::Body` to the result
209 /// of the MIR const-checking pass. This is the set of qualifs in
210 /// the final value of a `const`.
211 query mir_const_qualif(key: DefId) -> mir::ConstQualifs {
212 desc { |tcx| "const checking `{}`", tcx
.def_path_str(key
) }
213 cache_on_disk_if { key.is_local() }
215 query
mir_const_qualif_const_arg(
216 key
: (LocalDefId
, DefId
)
217 ) -> mir
::ConstQualifs
{
219 |tcx
| "const checking the const argument `{}`",
220 tcx
.def_path_str(key
.0.to_def_id())
224 /// Fetch the MIR for a given `DefId` right after it's built - this includes
225 /// unreachable code.
226 query
mir_built(key
: ty
::WithOptConstParam
<LocalDefId
>) -> &'tcx Steal
<mir
::Body
<'tcx
>> {
227 desc { |tcx| "building MIR for `{}`
", tcx.def_path_str(key.did.to_def_id()) }
230 /// Fetch the MIR for a given `DefId` up till the point where it is
231 /// ready for const qualification.
233 /// See the README for the `mir` module for details.
234 query mir_const(key: ty::WithOptConstParam<LocalDefId>) -> &'tcx Steal<mir::Body<'tcx>> {
236 |tcx| "processing MIR
for {}`{}`
",
237 if key.const_param_did.is_some() { "the const argument " } else { "" },
238 tcx.def_path_str(key.did.to_def_id()),
243 query mir_drops_elaborated_and_const_checked(
244 key: ty::WithOptConstParam<LocalDefId>
245 ) -> &'tcx Steal<mir::Body<'tcx>> {
247 desc { |tcx| "elaborating drops for `{}`", tcx
.def_path_str(key
.did
.to_def_id()) }
250 query
mir_promoted(key
: ty
::WithOptConstParam
<LocalDefId
>) ->
252 &'tcx Steal
<mir
::Body
<'tcx
>>,
253 &'tcx Steal
<IndexVec
<mir
::Promoted
, mir
::Body
<'tcx
>>>
257 |tcx
| "processing {}`{}`",
258 if key
.const_param_did
.is_some() { "the const argument " }
else { "" }
,
259 tcx
.def_path_str(key
.did
.to_def_id()),
263 /// MIR after our optimization passes have run. This is MIR that is ready
264 /// for codegen. This is also the only query that can fetch non-local MIR, at present.
265 query
optimized_mir(key
: DefId
) -> &'tcx mir
::Body
<'tcx
> {
266 desc { |tcx| "optimizing MIR for `{}`
", tcx.def_path_str(key) }
267 cache_on_disk_if { key.is_local() }
269 query optimized_mir_of_const_arg(key: (LocalDefId, DefId)) -> &'tcx mir::Body<'tcx> {
271 |tcx| "optimizing MIR
for the
const argument `{}`
",
272 tcx.def_path_str(key.0.to_def_id())
276 /// Returns coverage summary info for a function, after executing the `InstrumentCoverage`
277 /// MIR pass (assuming the -Zinstrument-coverage option is enabled).
278 query coverageinfo(key: DefId) -> mir::CoverageInfo {
279 desc { |tcx| "retrieving coverage info from MIR for `{}`", tcx
.def_path_str(key
) }
280 storage(ArenaCacheSelector
<'tcx
>)
281 cache_on_disk_if { key.is_local() }
284 /// The `DefId` is the `DefId` of the containing MIR body. Promoteds do not have their own
285 /// `DefId`. This function returns all promoteds in the specified body. The body references
286 /// promoteds by the `DefId` and the `mir::Promoted` index. This is necessary, because
287 /// after inlining a body may refer to promoteds from other bodies. In that case you still
288 /// need to use the `DefId` of the original body.
289 query
promoted_mir(key
: DefId
) -> &'tcx IndexVec
<mir
::Promoted
, mir
::Body
<'tcx
>> {
290 desc { |tcx| "optimizing promoted MIR for `{}`
", tcx.def_path_str(key) }
291 cache_on_disk_if { key.is_local() }
293 query promoted_mir_of_const_arg(
294 key: (LocalDefId, DefId)
295 ) -> &'tcx IndexVec<mir::Promoted, mir::Body<'tcx>> {
297 |tcx| "optimizing promoted MIR
for the
const argument `{}`
",
298 tcx.def_path_str(key.0.to_def_id()),
304 // Erases regions from `ty` to yield a new type.
305 // Normally you would just use `tcx.erase_regions(&value)`,
306 // however, which uses this query as a kind of cache.
307 query erase_regions_ty(ty: Ty<'tcx>) -> Ty<'tcx> {
308 // This query is not expected to have input -- as a result, it
309 // is not a good candidates for "replay
" because it is essentially a
310 // pure function of its input (and hence the expectation is that
311 // no caller would be green **apart** from just these
312 // queries). Making it anonymous avoids hashing the result, which
313 // may save a bit of time.
315 desc { "erasing regions from `{:?}`", ty
}
320 query
wasm_import_module_map(_
: CrateNum
) -> FxHashMap
<DefId
, String
> {
321 storage(ArenaCacheSelector
<'tcx
>)
322 desc { "wasm import module map" }
327 /// Maps from the `DefId` of an item (trait/struct/enum/fn) to the
328 /// predicates (where-clauses) directly defined on it. This is
329 /// equal to the `explicit_predicates_of` predicates plus the
330 /// `inferred_outlives_of` predicates.
331 query
predicates_defined_on(key
: DefId
) -> ty
::GenericPredicates
<'tcx
> {
332 desc { |tcx| "computing predicates of `{}`
", tcx.def_path_str(key) }
335 /// Returns the predicates written explicitly by the user.
336 query explicit_predicates_of(key: DefId) -> ty::GenericPredicates<'tcx> {
337 desc { |tcx| "computing explicit predicates of `{}`", tcx
.def_path_str(key
) }
340 /// Returns the inferred outlives predicates (e.g., for `struct
341 /// Foo<'a, T> { x: &'a T }`, this would return `T: 'a`).
342 query
inferred_outlives_of(key
: DefId
) -> &'tcx
[(ty
::Predicate
<'tcx
>, Span
)] {
343 desc { |tcx| "computing inferred outlives predicates of `{}`
", tcx.def_path_str(key) }
346 /// Maps from the `DefId` of a trait to the list of
347 /// super-predicates. This is a subset of the full list of
348 /// predicates. We store these in a separate map because we must
349 /// evaluate them even during type conversion, often before the
350 /// full predicates are available (note that supertraits have
351 /// additional acyclicity requirements).
352 query super_predicates_of(key: DefId) -> ty::GenericPredicates<'tcx> {
353 desc { |tcx| "computing the supertraits of `{}`", tcx
.def_path_str(key
) }
356 /// To avoid cycles within the predicates of a single item we compute
357 /// per-type-parameter predicates for resolving `T::AssocTy`.
358 query
type_param_predicates(key
: (DefId
, LocalDefId
)) -> ty
::GenericPredicates
<'tcx
> {
359 desc { |tcx| "computing the bounds for type parameter `{}`
", {
360 let id = tcx.hir().local_def_id_to_hir_id(key.1);
361 tcx.hir().ty_param_name(id)
365 query trait_def(key: DefId) -> ty::TraitDef {
366 desc { |tcx| "computing trait definition for `{}`", tcx
.def_path_str(key
) }
367 storage(ArenaCacheSelector
<'tcx
>)
369 query
adt_def(key
: DefId
) -> &'tcx ty
::AdtDef
{
370 desc { |tcx| "computing ADT definition for `{}`
", tcx.def_path_str(key) }
372 query adt_destructor(key: DefId) -> Option<ty::Destructor> {
373 desc { |tcx| "computing `Drop` impl for `{}`", tcx
.def_path_str(key
) }
376 // The cycle error here should be reported as an error by `check_representable`.
377 // We consider the type as Sized in the meanwhile to avoid
378 // further errors (done in impl Value for AdtSizedConstraint).
379 // Use `cycle_delay_bug` to delay the cycle error here to be emitted later
380 // in case we accidentally otherwise don't emit an error.
381 query
adt_sized_constraint(
383 ) -> AdtSizedConstraint
<'tcx
> {
384 desc { |tcx| "computing `Sized` constraints for `{}`
", tcx.def_path_str(key) }
388 query adt_dtorck_constraint(
390 ) -> Result<DtorckConstraint<'tcx>, NoSolution> {
391 desc { |tcx| "computing drop-check constraints for `{}`", tcx
.def_path_str(key
) }
394 /// Returns `true` if this is a const fn, use the `is_const_fn` to know whether your crate
395 /// actually sees it as const fn (e.g., the const-fn-ness might be unstable and you might
396 /// not have the feature gate active).
398 /// **Do not call this function manually.** It is only meant to cache the base data for the
399 /// `is_const_fn` function.
400 query
is_const_fn_raw(key
: DefId
) -> bool
{
401 desc { |tcx| "checking if item is const fn: `{}`
", tcx.def_path_str(key) }
404 /// Returns `true` if this is a const `impl`. **Do not call this function manually.**
406 /// This query caches the base data for the `is_const_impl` helper function, which also
407 /// takes into account stability attributes (e.g., `#[rustc_const_unstable]`).
408 query is_const_impl_raw(key: DefId) -> bool {
409 desc { |tcx| "checking if item is const impl: `{}`", tcx
.def_path_str(key
) }
412 query
asyncness(key
: DefId
) -> hir
::IsAsync
{
413 desc { |tcx| "checking if the function is async: `{}`
", tcx.def_path_str(key) }
416 /// Returns `true` if calls to the function may be promoted.
418 /// This is either because the function is e.g., a tuple-struct or tuple-variant
419 /// constructor, or because it has the `#[rustc_promotable]` attribute. The attribute should
420 /// be removed in the future in favour of some form of check which figures out whether the
421 /// function does not inspect the bits of any of its arguments (so is essentially just a
422 /// constructor function).
423 query is_promotable_const_fn(key: DefId) -> bool {
424 desc { |tcx| "checking if item is promotable: `{}`", tcx
.def_path_str(key
) }
427 query
const_fn_is_allowed_fn_ptr(key
: DefId
) -> bool
{
428 desc { |tcx| "checking if const fn allows `fn()` types: `{}`
", tcx.def_path_str(key) }
431 /// Returns `true` if this is a foreign item (i.e., linked via `extern { ... }`).
432 query is_foreign_item(key: DefId) -> bool {
433 desc { |tcx| "checking if `{}` is a foreign item", tcx
.def_path_str(key
) }
436 /// Returns `Some(mutability)` if the node pointed to by `def_id` is a static item.
437 query
static_mutability(def_id
: DefId
) -> Option
<hir
::Mutability
> {
438 desc { |tcx| "looking up static mutability of `{}`
", tcx.def_path_str(def_id) }
441 /// Returns `Some(generator_kind)` if the node pointed to by `def_id` is a generator.
442 query generator_kind(def_id: DefId) -> Option<hir::GeneratorKind> {
443 desc { |tcx| "looking up generator kind of `{}`", tcx
.def_path_str(def_id
) }
446 /// Gets a map with the variance of every item; use `item_variance` instead.
447 query
crate_variances(_
: CrateNum
) -> ty
::CrateVariancesMap
<'tcx
> {
448 storage(ArenaCacheSelector
<'tcx
>)
449 desc { "computing the variances for items in this crate" }
452 /// Maps from the `DefId` of a type or region parameter to its (inferred) variance.
453 query
variances_of(def_id
: DefId
) -> &'tcx
[ty
::Variance
] {
454 desc { |tcx| "computing the variances of `{}`
", tcx.def_path_str(def_id) }
459 /// Maps from thee `DefId` of a type to its (inferred) outlives.
460 query inferred_outlives_crate(_: CrateNum)
461 -> ty::CratePredicatesMap<'tcx> {
462 storage(ArenaCacheSelector<'tcx>)
463 desc { "computing the inferred outlives predicates for items in this crate" }
468 /// Maps from an impl/trait `DefId to a list of the `DefId`s of its items.
469 query associated_item_def_ids(key: DefId) -> &'tcx [DefId] {
470 desc { |tcx| "collecting associated items of `{}`", tcx
.def_path_str(key
) }
473 /// Maps from a trait item to the trait item "descriptor".
474 query
associated_item(key
: DefId
) -> ty
::AssocItem
{
475 desc { |tcx| "computing associated item data for `{}`
", tcx.def_path_str(key) }
476 storage(ArenaCacheSelector<'tcx>)
479 /// Collects the associated items defined on a trait or impl.
480 query associated_items(key: DefId) -> ty::AssociatedItems<'tcx> {
481 storage(ArenaCacheSelector<'tcx>)
482 desc { |tcx| "collecting associated items of {}", tcx
.def_path_str(key
) }
485 query
impl_trait_ref(key
: DefId
) -> Option
<ty
::TraitRef
<'tcx
>> {
486 desc { |tcx| "computing trait implemented by `{}`
", tcx.def_path_str(key) }
488 query impl_polarity(key: DefId) -> ty::ImplPolarity {
489 desc { |tcx| "computing implementation polarity of `{}`", tcx
.def_path_str(key
) }
492 query
issue33140_self_ty(key
: DefId
) -> Option
<ty
::Ty
<'tcx
>> {
493 desc { |tcx| "computing Self type wrt issue #33140 `{}`
", tcx.def_path_str(key) }
498 /// Maps a `DefId` of a type to a list of its inherent impls.
499 /// Contains implementations of methods that are inherent to a type.
500 /// Methods in these implementations don't need to be exported.
501 query inherent_impls(key: DefId) -> &'tcx [DefId] {
502 desc { |tcx| "collecting inherent impls for `{}`", tcx
.def_path_str(key
) }
508 /// The result of unsafety-checking this `LocalDefId`.
509 query
unsafety_check_result(key
: LocalDefId
) -> &'tcx mir
::UnsafetyCheckResult
{
510 desc { |tcx| "unsafety-checking `{}`
", tcx.def_path_str(key.to_def_id()) }
511 cache_on_disk_if { true }
513 query unsafety_check_result_for_const_arg(key: (LocalDefId, DefId)) -> &'tcx mir::UnsafetyCheckResult {
515 |tcx| "unsafety
-checking the
const argument `{}`
",
516 tcx.def_path_str(key.0.to_def_id())
520 /// HACK: when evaluated, this reports a "unsafe derive on
repr(packed
)" error.
522 /// Unsafety checking is executed for each method separately, but we only want
523 /// to emit this error once per derive. As there are some impls with multiple
524 /// methods, we use a query for deduplication.
525 query unsafe_derive_on_repr_packed(key: LocalDefId) -> () {
526 desc { |tcx| "processing `{}`", tcx
.def_path_str(key
.to_def_id()) }
529 /// The signature of functions.
530 query
fn_sig(key
: DefId
) -> ty
::PolyFnSig
<'tcx
> {
531 desc { |tcx| "computing function signature of `{}`
", tcx.def_path_str(key) }
536 query lint_mod(key: LocalDefId) -> () {
537 desc { |tcx| "linting {}", describe_as_module(key
, tcx
) }
540 /// Checks the attributes in the module.
541 query
check_mod_attrs(key
: LocalDefId
) -> () {
542 desc { |tcx| "checking attributes in {}
", describe_as_module(key, tcx) }
545 query check_mod_unstable_api_usage(key: LocalDefId) -> () {
546 desc { |tcx| "checking for unstable API usage in {}", describe_as_module(key
, tcx
) }
549 /// Checks the const bodies in the module for illegal operations (e.g. `if` or `loop`).
550 query
check_mod_const_bodies(key
: LocalDefId
) -> () {
551 desc { |tcx| "checking consts in {}
", describe_as_module(key, tcx) }
554 /// Checks the loops in the module.
555 query check_mod_loops(key: LocalDefId) -> () {
556 desc { |tcx| "checking loops in {}", describe_as_module(key
, tcx
) }
559 query
check_mod_item_types(key
: LocalDefId
) -> () {
560 desc { |tcx| "checking item types in {}
", describe_as_module(key, tcx) }
563 query check_mod_privacy(key: LocalDefId) -> () {
564 desc { |tcx| "checking privacy in {}", describe_as_module(key
, tcx
) }
567 query
check_mod_intrinsics(key
: LocalDefId
) -> () {
568 desc { |tcx| "checking intrinsics in {}
", describe_as_module(key, tcx) }
571 query check_mod_liveness(key: LocalDefId) -> () {
572 desc { |tcx| "checking liveness of variables in {}", describe_as_module(key
, tcx
) }
575 query
check_mod_impl_wf(key
: LocalDefId
) -> () {
576 desc { |tcx| "checking that impls are well-formed in {}
", describe_as_module(key, tcx) }
579 query collect_mod_item_types(key: LocalDefId) -> () {
580 desc { |tcx| "collecting item types in {}", describe_as_module(key
, tcx
) }
583 /// Caches `CoerceUnsized` kinds for impls on custom types.
584 query
coerce_unsized_info(key
: DefId
)
585 -> ty
::adjustment
::CoerceUnsizedInfo
{
586 desc { |tcx| "computing CoerceUnsized info for `{}`
", tcx.def_path_str(key) }
591 query typeck_item_bodies(_: CrateNum) -> () {
592 desc { "type-checking all item bodies" }
595 query typeck(key: LocalDefId) -> &'tcx ty::TypeckResults<'tcx> {
596 desc { |tcx| "type-checking `{}`", tcx
.def_path_str(key
.to_def_id()) }
597 cache_on_disk_if { true }
599 query
typeck_const_arg(
600 key
: (LocalDefId
, DefId
)
601 ) -> &'tcx ty
::TypeckResults
<'tcx
> {
603 |tcx
| "type-checking the const argument `{}`",
604 tcx
.def_path_str(key
.0.to_def_id()),
607 query
diagnostic_only_typeck(key
: LocalDefId
) -> &'tcx ty
::TypeckResults
<'tcx
> {
608 desc { |tcx| "type-checking `{}`
", tcx.def_path_str(key.to_def_id()) }
609 cache_on_disk_if { true }
610 load_cached(tcx, id) {
611 let typeck_results: Option<ty::TypeckResults<'tcx>> = tcx
612 .queries.on_disk_cache
613 .try_load_query_result(tcx, id);
615 typeck_results.map(|x| &*tcx.arena.alloc(x))
621 query used_trait_imports(key: LocalDefId) -> &'tcx FxHashSet<LocalDefId> {
622 desc { |tcx| "used_trait_imports `{}`", tcx
.def_path_str(key
.to_def_id()) }
623 cache_on_disk_if { true }
628 query
has_typeck_results(def_id
: DefId
) -> bool
{
629 desc { |tcx| "checking whether `{}` has a body
", tcx.def_path_str(def_id) }
632 query coherent_trait(def_id: DefId) -> () {
633 desc { |tcx| "coherence checking all impls of trait `{}`", tcx
.def_path_str(def_id
) }
638 /// Borrow-checks the function body. If this is a closure, returns
639 /// additional requirements that the closure's creator must verify.
640 query
mir_borrowck(key
: LocalDefId
) -> &'tcx mir
::BorrowCheckResult
<'tcx
> {
641 desc { |tcx| "borrow-checking `{}`
", tcx.def_path_str(key.to_def_id()) }
642 cache_on_disk_if(tcx, opt_result) {
643 tcx.is_closure(key.to_def_id())
644 || opt_result.map_or(false, |r| !r.concrete_opaque_types.is_empty())
647 query mir_borrowck_const_arg(key: (LocalDefId, DefId)) -> &'tcx mir::BorrowCheckResult<'tcx> {
649 |tcx| "borrow
-checking the
const argument`{}`
",
650 tcx.def_path_str(key.0.to_def_id())
656 /// Gets a complete map from all types to their inherent impls.
657 /// Not meant to be used directly outside of coherence.
658 /// (Defined only for `LOCAL_CRATE`.)
659 query crate_inherent_impls(k: CrateNum)
660 -> CrateInherentImpls {
661 storage(ArenaCacheSelector<'tcx>)
663 desc { "all inherent impls defined in crate `{:?}`", k
}
666 /// Checks all types in the crate for overlap in their inherent impls. Reports errors.
667 /// Not meant to be used directly outside of coherence.
668 /// (Defined only for `LOCAL_CRATE`.)
669 query
crate_inherent_impls_overlap_check(_
: CrateNum
)
672 desc { "check for overlap between inherent impls defined in this crate" }
677 /// Evaluates a constant without running sanity checks.
679 /// **Do not use this** outside const eval. Const eval uses this to break query cycles
680 /// during validation. Please add a comment to every use site explaining why using
681 /// `const_eval_validated` isn't sufficient. The returned constant also isn't in a suitable
682 /// form to be used outside of const eval.
683 query
const_eval_raw(key
: ty
::ParamEnvAnd
<'tcx
, GlobalId
<'tcx
>>)
684 -> ConstEvalRawResult
<'tcx
> {
686 "const-evaluating `{}`",
687 key
.value
.display(tcx
)
691 /// Results of evaluating const items or constants embedded in
692 /// other items (such as enum variant explicit discriminants).
694 /// In contrast to `const_eval_raw` this performs some validation on the constant, and
695 /// returns a proper constant that is usable by the rest of the compiler.
697 /// **Do not use this** directly, use one of the following wrappers: `tcx.const_eval_poly`,
698 /// `tcx.const_eval_resolve`, `tcx.const_eval_instance`, or `tcx.const_eval_global_id`.
699 query
const_eval_validated(key
: ty
::ParamEnvAnd
<'tcx
, GlobalId
<'tcx
>>)
700 -> ConstEvalResult
<'tcx
> {
702 "const-evaluating + checking `{}`",
703 key
.value
.display(tcx
)
705 cache_on_disk_if(_
, opt_result
) {
706 // Only store results without errors
707 opt_result
.map_or(true, |r
| r
.is_ok())
711 /// Destructure a constant ADT or array into its variant index and its
713 query
destructure_const(
714 key
: ty
::ParamEnvAnd
<'tcx
, &'tcx ty
::Const
<'tcx
>>
715 ) -> mir
::DestructuredConst
<'tcx
> {
716 desc { "destructure constant" }
719 query
const_caller_location(key
: (rustc_span
::Symbol
, u32, u32)) -> ConstValue
<'tcx
> {
720 desc { "get a &core::panic::Location referring to a span" }
724 key
: LitToConstInput
<'tcx
>
725 ) -> Result
<&'tcx ty
::Const
<'tcx
>, LitToConstError
> {
726 desc { "converting literal to const" }
731 query
check_match(key
: DefId
) {
732 desc { |tcx| "match-checking `{}`
", tcx.def_path_str(key) }
733 cache_on_disk_if { key.is_local() }
736 /// Performs part of the privacy check and computes "access levels
".
737 query privacy_access_levels(_: CrateNum) -> &'tcx AccessLevels {
739 desc { "privacy access levels" }
741 query check_private_in_public(_: CrateNum) -> () {
743 desc { "checking for private elements in public interfaces" }
748 query reachable_set(_: CrateNum) -> FxHashSet<LocalDefId> {
749 storage(ArenaCacheSelector<'tcx>)
750 desc { "reachability" }
753 /// Per-body `region::ScopeTree`. The `DefId` should be the owner `DefId` for the body;
754 /// in the case of closures, this will be redirected to the enclosing function.
755 query region_scope_tree(def_id: DefId) -> &'tcx region::ScopeTree {
756 desc { |tcx| "computing drop scopes for `{}`", tcx
.def_path_str(def_id
) }
759 query
mir_shims(key
: ty
::InstanceDef
<'tcx
>) -> mir
::Body
<'tcx
> {
760 storage(ArenaCacheSelector
<'tcx
>)
761 desc { |tcx| "generating MIR shim for `{}`
", tcx.def_path_str(key.def_id()) }
764 /// The `symbol_name` query provides the symbol name for calling a
765 /// given instance from the local crate. In particular, it will also
766 /// look up the correct symbol name of instances from upstream crates.
767 query symbol_name(key: ty::Instance<'tcx>) -> ty::SymbolName<'tcx> {
768 desc { "computing the symbol for `{}`", key
}
769 cache_on_disk_if { true }
772 query
def_kind(def_id
: DefId
) -> DefKind
{
773 desc { |tcx| "looking up definition kind of `{}`
", tcx.def_path_str(def_id) }
775 query def_span(def_id: DefId) -> Span {
776 desc { |tcx| "looking up span for `{}`", tcx
.def_path_str(def_id
) }
777 // FIXME(mw): DefSpans are not really inputs since they are derived from
778 // HIR. But at the moment HIR hashing still contains some hacks that allow
779 // to make type debuginfo to be source location independent. Declaring
780 // DefSpan an input makes sure that changes to these are always detected
781 // regardless of HIR hashing.
784 query
lookup_stability(def_id
: DefId
) -> Option
<&'tcx attr
::Stability
> {
785 desc { |tcx| "looking up stability of `{}`
", tcx.def_path_str(def_id) }
787 query lookup_const_stability(def_id: DefId) -> Option<&'tcx attr::ConstStability> {
788 desc { |tcx| "looking up const stability of `{}`", tcx
.def_path_str(def_id
) }
790 query
lookup_deprecation_entry(def_id
: DefId
) -> Option
<DeprecationEntry
> {
791 desc { |tcx| "checking whether `{}` is deprecated
", tcx.def_path_str(def_id) }
793 query item_attrs(def_id: DefId) -> &'tcx [ast::Attribute] {
794 desc { |tcx| "collecting attributes of `{}`", tcx
.def_path_str(def_id
) }
799 query
codegen_fn_attrs(def_id
: DefId
) -> CodegenFnAttrs
{
800 desc { |tcx| "computing codegen attributes of `{}`
", tcx.def_path_str(def_id) }
801 storage(ArenaCacheSelector<'tcx>)
802 cache_on_disk_if { true }
807 query fn_arg_names(def_id: DefId) -> &'tcx [rustc_span::symbol::Ident] {
808 desc { |tcx| "looking up function parameter names for `{}`", tcx
.def_path_str(def_id
) }
810 /// Gets the rendered value of the specified constant or associated constant.
812 query
rendered_const(def_id
: DefId
) -> String
{
813 desc { |tcx| "rendering constant intializer of `{}`
", tcx.def_path_str(def_id) }
815 query impl_parent(def_id: DefId) -> Option<DefId> {
816 desc { |tcx| "computing specialization parent impl of `{}`", tcx
.def_path_str(def_id
) }
821 query
trait_of_item(def_id
: DefId
) -> Option
<DefId
> {
822 desc { |tcx| "finding trait defining `{}`
", tcx.def_path_str(def_id) }
827 query is_mir_available(key: DefId) -> bool {
828 desc { |tcx| "checking if item has mir available: `{}`", tcx
.def_path_str(key
) }
833 query
vtable_methods(key
: ty
::PolyTraitRef
<'tcx
>)
834 -> &'tcx
[Option
<(DefId
, SubstsRef
<'tcx
>)>] {
835 desc { |tcx| "finding all methods for trait {}
", tcx.def_path_str(key.def_id()) }
840 query codegen_fulfill_obligation(
841 key: (ty::ParamEnv<'tcx>, ty::PolyTraitRef<'tcx>)
842 ) -> Result<ImplSource<'tcx, ()>, ErrorReported> {
843 cache_on_disk_if { true }
845 "checking
if `{}` fulfills its obligations
",
846 tcx.def_path_str(key.1.def_id())
852 query all_local_trait_impls(key: CrateNum) -> &'tcx BTreeMap<DefId, Vec<hir::HirId>> {
853 desc { "local trait impls" }
855 query trait_impls_of(key: DefId) -> ty::trait_def::TraitImpls {
856 storage(ArenaCacheSelector<'tcx>)
857 desc { |tcx| "trait impls of `{}`", tcx
.def_path_str(key
) }
859 query
specialization_graph_of(key
: DefId
) -> specialization_graph
::Graph
{
860 storage(ArenaCacheSelector
<'tcx
>)
861 desc { |tcx| "building specialization graph of trait `{}`
", tcx.def_path_str(key) }
862 cache_on_disk_if { true }
864 query object_safety_violations(key: DefId) -> &'tcx [traits::ObjectSafetyViolation] {
865 desc { |tcx| "determine object safety of trait `{}`", tcx
.def_path_str(key
) }
868 /// Gets the ParameterEnvironment for a given item; this environment
869 /// will be in "user-facing" mode, meaning that it is suitable for
870 /// type-checking etc, and it does not normalize specializable
871 /// associated types. This is almost always what you want,
872 /// unless you are doing MIR optimizations, in which case you
873 query
param_env(def_id
: DefId
) -> ty
::ParamEnv
<'tcx
> {
874 desc { |tcx| "computing normalized predicates of `{}`
", tcx.def_path_str(def_id) }
877 /// Like `param_env`, but returns the `ParamEnv in `Reveal::All` mode.
878 /// Prefer this over `tcx.param_env(def_id).with_reveal_all_normalized(tcx)`,
879 /// as this method is more efficient.
880 query param_env_reveal_all_normalized(def_id: DefId) -> ty::ParamEnv<'tcx> {
881 desc { |tcx| "computing revealed normalized predicates of `{}`", tcx
.def_path_str(def_id
) }
884 /// Trait selection queries. These are best used by invoking `ty.is_copy_modulo_regions()`,
885 /// `ty.is_copy()`, etc, since that will prune the environment where possible.
886 query
is_copy_raw(env
: ty
::ParamEnvAnd
<'tcx
, Ty
<'tcx
>>) -> bool
{
887 desc { "computing whether `{}` is `Copy`
", env.value }
889 /// Query backing `TyS::is_sized`.
890 query is_sized_raw(env: ty::ParamEnvAnd<'tcx, Ty<'tcx>>) -> bool {
891 desc { "computing whether `{}` is `Sized`", env
.value
}
893 /// Query backing `TyS::is_freeze`.
894 query
is_freeze_raw(env
: ty
::ParamEnvAnd
<'tcx
, Ty
<'tcx
>>) -> bool
{
895 desc { "computing whether `{}` is freeze
", env.value }
897 /// Query backing `TyS::needs_drop`.
898 query needs_drop_raw(env: ty::ParamEnvAnd<'tcx, Ty<'tcx>>) -> bool {
899 desc { "computing whether `{}` needs drop", env
.value
}
902 /// Query backing `TyS::is_structural_eq_shallow`.
904 /// This is only correct for ADTs. Call `is_structural_eq_shallow` to handle all types
906 query
has_structural_eq_impls(ty
: Ty
<'tcx
>) -> bool
{
908 "computing whether `{:?}` implements `PartialStructuralEq` and `StructuralEq`",
913 /// A list of types where the ADT requires drop if and only if any of
914 /// those types require drop. If the ADT is known to always need drop
915 /// then `Err(AlwaysRequiresDrop)` is returned.
916 query
adt_drop_tys(def_id
: DefId
) -> Result
<&'tcx ty
::List
<Ty
<'tcx
>>, AlwaysRequiresDrop
> {
917 desc { |tcx| "computing when `{}` needs drop
", tcx.def_path_str(def_id) }
918 cache_on_disk_if { true }
922 env: ty::ParamEnvAnd<'tcx, Ty<'tcx>>
923 ) -> Result<&'tcx rustc_target::abi::Layout, ty::layout::LayoutError<'tcx>> {
924 desc { "computing layout of `{}`", env
.value
}
929 query
dylib_dependency_formats(_
: CrateNum
)
930 -> &'tcx
[(CrateNum
, LinkagePreference
)] {
931 desc { "dylib dependency formats of crate" }
934 query
dependency_formats(_
: CrateNum
)
935 -> Lrc
<crate::middle
::dependency_format
::Dependencies
>
937 desc { "get the linkage format of all dependencies" }
942 query
is_compiler_builtins(_
: CrateNum
) -> bool
{
944 desc { "checking if the crate is_compiler_builtins" }
946 query
has_global_allocator(_
: CrateNum
) -> bool
{
948 desc { "checking if the crate has_global_allocator" }
950 query
has_panic_handler(_
: CrateNum
) -> bool
{
952 desc { "checking if the crate has_panic_handler" }
954 query
is_profiler_runtime(_
: CrateNum
) -> bool
{
956 desc { "query a crate is `#![profiler_runtime]`" }
958 query
panic_strategy(_
: CrateNum
) -> PanicStrategy
{
960 desc { "query a crate's configured panic strategy" }
962 query
is_no_builtins(_
: CrateNum
) -> bool
{
964 desc { "test whether a crate has `#![no_builtins]`" }
966 query
symbol_mangling_version(_
: CrateNum
) -> SymbolManglingVersion
{
968 desc { "query a crate's symbol mangling version" }
971 query
extern_crate(def_id
: DefId
) -> Option
<&'tcx ExternCrate
> {
973 desc { "getting crate's ExternCrateData" }
978 query
specializes(_
: (DefId
, DefId
)) -> bool
{
979 desc { "computing whether impls specialize one another" }
981 query
in_scope_traits_map(_
: LocalDefId
)
982 -> Option
<&'tcx FxHashMap
<ItemLocalId
, StableVec
<TraitCandidate
>>> {
984 desc { "traits in scope at a block" }
989 query
module_exports(def_id
: LocalDefId
) -> Option
<&'tcx
[Export
<LocalDefId
>]> {
990 desc { |tcx| "looking up items exported by `{}`
", tcx.def_path_str(def_id.to_def_id()) }
996 query impl_defaultness(def_id: DefId) -> hir::Defaultness {
997 desc { |tcx| "looking up whether `{}` is a default impl", tcx
.def_path_str(def_id
) }
1000 query
check_item_well_formed(key
: LocalDefId
) -> () {
1001 desc { |tcx| "checking that `{}` is well
-formed
", tcx.def_path_str(key.to_def_id()) }
1003 query check_trait_item_well_formed(key: LocalDefId) -> () {
1004 desc { |tcx| "checking that `{}` is well-formed", tcx
.def_path_str(key
.to_def_id()) }
1006 query
check_impl_item_well_formed(key
: LocalDefId
) -> () {
1007 desc { |tcx| "checking that `{}` is well
-formed
", tcx.def_path_str(key.to_def_id()) }
1013 // The `DefId`s of all non-generic functions and statics in the given crate
1014 // that can be reached from outside the crate.
1016 // We expect this items to be available for being linked to.
1018 // This query can also be called for `LOCAL_CRATE`. In this case it will
1019 // compute which items will be reachable to other crates, taking into account
1020 // the kind of crate that is currently compiled. Crates with only a
1021 // C interface have fewer reachable things.
1023 // Does not include external symbols that don't have a corresponding DefId,
1024 // like the compiler-generated `main` function and so on.
1025 query reachable_non_generics(_: CrateNum)
1026 -> DefIdMap<SymbolExportLevel> {
1027 storage(ArenaCacheSelector<'tcx>)
1028 desc { "looking up the exported symbols of a crate" }
1030 query is_reachable_non_generic(def_id: DefId) -> bool {
1031 desc { |tcx| "checking whether `{}` is an exported symbol", tcx
.def_path_str(def_id
) }
1033 query
is_unreachable_local_definition(def_id
: DefId
) -> bool
{
1035 "checking whether `{}` is reachable from outside the crate",
1036 tcx
.def_path_str(def_id
),
1042 /// The entire set of monomorphizations the local crate can safely link
1043 /// to because they are exported from upstream crates. Do not depend on
1044 /// this directly, as its value changes anytime a monomorphization gets
1045 /// added or removed in any upstream crate. Instead use the narrower
1046 /// `upstream_monomorphizations_for`, `upstream_drop_glue_for`, or, even
1047 /// better, `Instance::upstream_monomorphization()`.
1048 query
upstream_monomorphizations(
1050 ) -> DefIdMap
<FxHashMap
<SubstsRef
<'tcx
>, CrateNum
>> {
1051 storage(ArenaCacheSelector
<'tcx
>)
1052 desc { "collecting available upstream monomorphizations `{:?}`
", k }
1055 /// Returns the set of upstream monomorphizations available for the
1056 /// generic function identified by the given `def_id`. The query makes
1057 /// sure to make a stable selection if the same monomorphization is
1058 /// available in multiple upstream crates.
1060 /// You likely want to call `Instance::upstream_monomorphization()`
1061 /// instead of invoking this query directly.
1062 query upstream_monomorphizations_for(def_id: DefId)
1063 -> Option<&'tcx FxHashMap<SubstsRef<'tcx>, CrateNum>> {
1065 "collecting available upstream monomorphizations
for `{}`
",
1066 tcx.def_path_str(def_id),
1070 /// Returns the upstream crate that exports drop-glue for the given
1071 /// type (`substs` is expected to be a single-item list containing the
1072 /// type one wants drop-glue for).
1074 /// This is a subset of `upstream_monomorphizations_for` in order to
1075 /// increase dep-tracking granularity. Otherwise adding or removing any
1076 /// type with drop-glue in any upstream crate would invalidate all
1077 /// functions calling drop-glue of an upstream type.
1079 /// You likely want to call `Instance::upstream_monomorphization()`
1080 /// instead of invoking this query directly.
1082 /// NOTE: This query could easily be extended to also support other
1083 /// common functions that have are large set of monomorphizations
1084 /// (like `Clone::clone` for example).
1085 query upstream_drop_glue_for(substs: SubstsRef<'tcx>) -> Option<CrateNum> {
1086 desc { "available upstream drop-glue for `{:?}`", substs
}
1091 query
foreign_modules(_
: CrateNum
) -> &'tcx
[ForeignModule
] {
1092 desc { "looking up the foreign modules of a linked crate" }
1095 /// Identifies the entry-point (e.g., the `main` function) for a given
1096 /// crate, returning `None` if there is no entry point (such as for library crates).
1097 query
entry_fn(_
: CrateNum
) -> Option
<(LocalDefId
, EntryFnType
)> {
1098 desc { "looking up the entry function of a crate" }
1100 query
plugin_registrar_fn(_
: CrateNum
) -> Option
<DefId
> {
1101 desc { "looking up the plugin registrar for a crate" }
1103 query
proc_macro_decls_static(_
: CrateNum
) -> Option
<DefId
> {
1104 desc { "looking up the derive registrar for a crate" }
1106 query
crate_disambiguator(_
: CrateNum
) -> CrateDisambiguator
{
1108 desc { "looking up the disambiguator a crate" }
1110 query
crate_hash(_
: CrateNum
) -> Svh
{
1112 desc { "looking up the hash a crate" }
1114 query
crate_host_hash(_
: CrateNum
) -> Option
<Svh
> {
1116 desc { "looking up the hash of a host version of a crate" }
1118 query
original_crate_name(_
: CrateNum
) -> Symbol
{
1120 desc { "looking up the original name a crate" }
1122 query
extra_filename(_
: CrateNum
) -> String
{
1124 desc { "looking up the extra filename for a crate" }
1126 query
crate_extern_paths(_
: CrateNum
) -> Vec
<PathBuf
> {
1128 desc { "looking up the paths for extern crates" }
1133 query
implementations_of_trait(_
: (CrateNum
, DefId
))
1134 -> &'tcx
[(DefId
, Option
<ty
::fast_reject
::SimplifiedType
>)] {
1135 desc { "looking up implementations of a trait in a crate" }
1137 query
all_trait_implementations(_
: CrateNum
)
1138 -> &'tcx
[(DefId
, Option
<ty
::fast_reject
::SimplifiedType
>)] {
1139 desc { "looking up all (?) trait implementations" }
1144 query
dllimport_foreign_items(_
: CrateNum
)
1145 -> FxHashSet
<DefId
> {
1146 storage(ArenaCacheSelector
<'tcx
>)
1147 desc { "dllimport_foreign_items" }
1149 query
is_dllimport_foreign_item(def_id
: DefId
) -> bool
{
1150 desc { |tcx| "is_dllimport_foreign_item({}
)", tcx.def_path_str(def_id) }
1152 query is_statically_included_foreign_item(def_id: DefId) -> bool {
1153 desc { |tcx| "is_statically_included_foreign_item({})", tcx
.def_path_str(def_id
) }
1155 query
native_library_kind(def_id
: DefId
)
1156 -> Option
<NativeLibKind
> {
1157 desc { |tcx| "native_library_kind({}
)", tcx.def_path_str(def_id) }
1162 query link_args(_: CrateNum) -> Lrc<Vec<String>> {
1164 desc { "looking up link arguments for a crate" }
1169 /// Lifetime resolution. See `middle::resolve_lifetimes`.
1170 query resolve_lifetimes(_: CrateNum) -> ResolveLifetimes {
1171 storage(ArenaCacheSelector<'tcx>)
1172 desc { "resolving lifetimes" }
1174 query named_region_map(_: LocalDefId) ->
1175 Option<&'tcx FxHashMap<ItemLocalId, Region>> {
1176 desc { "looking up a named region" }
1178 query is_late_bound_map(_: LocalDefId) ->
1179 Option<&'tcx FxHashSet<ItemLocalId>> {
1180 desc { "testing if a region is late bound" }
1182 query object_lifetime_defaults_map(_: LocalDefId)
1183 -> Option<&'tcx FxHashMap<ItemLocalId, Vec<ObjectLifetimeDefault>>> {
1184 desc { "looking up lifetime defaults for a region" }
1189 query visibility(def_id: DefId) -> ty::Visibility {
1190 desc { |tcx| "computing visibility of `{}`", tcx
.def_path_str(def_id
) }
1195 query
dep_kind(_
: CrateNum
) -> CrateDepKind
{
1197 desc { "fetching what a dependency looks like" }
1199 query
crate_name(_
: CrateNum
) -> Symbol
{
1201 desc { "fetching what a crate is named" }
1203 query
item_children(def_id
: DefId
) -> &'tcx
[Export
<hir
::HirId
>] {
1204 desc { |tcx| "collecting child items of `{}`
", tcx.def_path_str(def_id) }
1206 query extern_mod_stmt_cnum(def_id: LocalDefId) -> Option<CrateNum> {
1207 desc { |tcx| "computing crate imported by `{}`", tcx
.def_path_str(def_id
.to_def_id()) }
1210 query
get_lib_features(_
: CrateNum
) -> LibFeatures
{
1211 storage(ArenaCacheSelector
<'tcx
>)
1213 desc { "calculating the lib features map" }
1215 query
defined_lib_features(_
: CrateNum
)
1216 -> &'tcx
[(Symbol
, Option
<Symbol
>)] {
1217 desc { "calculating the lib features defined in a crate" }
1219 /// Returns the lang items defined in another crate by loading it from metadata.
1220 // FIXME: It is illegal to pass a `CrateNum` other than `LOCAL_CRATE` here, just get rid
1221 // of that argument?
1222 query
get_lang_items(_
: CrateNum
) -> LanguageItems
{
1223 storage(ArenaCacheSelector
<'tcx
>)
1225 desc { "calculating the lang items map" }
1228 /// Returns all diagnostic items defined in all crates.
1229 query
all_diagnostic_items(_
: CrateNum
) -> FxHashMap
<Symbol
, DefId
> {
1230 storage(ArenaCacheSelector
<'tcx
>)
1232 desc { "calculating the diagnostic items map" }
1235 /// Returns the lang items defined in another crate by loading it from metadata.
1236 query
defined_lang_items(_
: CrateNum
) -> &'tcx
[(DefId
, usize)] {
1237 desc { "calculating the lang items defined in a crate" }
1240 /// Returns the diagnostic items defined in a crate.
1241 query
diagnostic_items(_
: CrateNum
) -> FxHashMap
<Symbol
, DefId
> {
1242 storage(ArenaCacheSelector
<'tcx
>)
1243 desc { "calculating the diagnostic items map in a crate" }
1246 query
missing_lang_items(_
: CrateNum
) -> &'tcx
[LangItem
] {
1247 desc { "calculating the missing lang items in a crate" }
1249 query
visible_parent_map(_
: CrateNum
)
1250 -> DefIdMap
<DefId
> {
1251 storage(ArenaCacheSelector
<'tcx
>)
1252 desc { "calculating the visible parent map" }
1254 query
missing_extern_crate_item(_
: CrateNum
) -> bool
{
1256 desc { "seeing if we're missing an `extern crate` item for this crate" }
1258 query
used_crate_source(_
: CrateNum
) -> Lrc
<CrateSource
> {
1260 desc { "looking at the source for a crate" }
1262 query
postorder_cnums(_
: CrateNum
) -> &'tcx
[CrateNum
] {
1264 desc { "generating a postorder list of CrateNums" }
1267 query
upvars_mentioned(def_id
: DefId
) -> Option
<&'tcx FxIndexMap
<hir
::HirId
, hir
::Upvar
>> {
1268 desc { |tcx| "collecting upvars mentioned in `{}`
", tcx.def_path_str(def_id) }
1271 query maybe_unused_trait_import(def_id: LocalDefId) -> bool {
1273 desc { |tcx| "maybe_unused_trait_import for `{}`", tcx
.def_path_str(def_id
.to_def_id()) }
1275 query
maybe_unused_extern_crates(_
: CrateNum
)
1276 -> &'tcx
[(LocalDefId
, Span
)] {
1278 desc { "looking up all possibly unused extern crates" }
1280 query
names_imported_by_glob_use(def_id
: LocalDefId
)
1281 -> &'tcx FxHashSet
<Symbol
> {
1283 desc { |tcx| "names_imported_by_glob_use for `{}`
", tcx.def_path_str(def_id.to_def_id()) }
1286 query stability_index(_: CrateNum) -> stability::Index<'tcx> {
1287 storage(ArenaCacheSelector<'tcx>)
1289 desc { "calculating the stability index for the local crate" }
1291 query all_crate_nums(_: CrateNum) -> &'tcx [CrateNum] {
1293 desc { "fetching all foreign CrateNum instances" }
1296 /// A vector of every trait accessible in the whole crate
1297 /// (i.e., including those from subcrates). This is used only for
1298 /// error reporting.
1299 query all_traits(_: CrateNum) -> &'tcx [DefId] {
1300 desc { "fetching all foreign and local traits" }
1305 /// The list of symbols exported from the given crate.
1307 /// - All names contained in `exported_symbols(cnum)` are guaranteed to
1308 /// correspond to a publicly visible symbol in `cnum` machine code.
1309 /// - The `exported_symbols` sets of different crates do not intersect.
1310 query exported_symbols(_: CrateNum)
1311 -> &'tcx [(ExportedSymbol<'tcx>, SymbolExportLevel)] {
1312 desc { "exported_symbols" }
1317 query collect_and_partition_mono_items(_: CrateNum)
1318 -> (&'tcx DefIdSet, &'tcx [CodegenUnit<'tcx>]) {
1320 desc { "collect_and_partition_mono_items" }
1322 query is_codegened_item(def_id: DefId) -> bool {
1323 desc { |tcx| "determining whether `{}` needs codegen", tcx
.def_path_str(def_id
) }
1325 query
codegen_unit(_
: Symbol
) -> &'tcx CodegenUnit
<'tcx
> {
1326 desc { "codegen_unit" }
1328 query
unused_generic_params(key
: DefId
) -> FiniteBitSet
<u32> {
1329 cache_on_disk_if { key.is_local() }
1331 |tcx
| "determining which generic parameters are unused by `{}`",
1332 tcx
.def_path_str(key
)
1335 query
backend_optimization_level(_
: CrateNum
) -> OptLevel
{
1336 desc { "optimization level used by backend" }
1341 query
output_filenames(_
: CrateNum
) -> Arc
<OutputFilenames
> {
1343 desc { "output_filenames" }
1348 /// Do not call this query directly: invoke `normalize` instead.
1349 query
normalize_projection_ty(
1350 goal
: CanonicalProjectionGoal
<'tcx
>
1352 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, NormalizationResult
<'tcx
>>>,
1355 desc { "normalizing `{:?}`
", goal }
1358 /// Do not call this query directly: invoke `normalize_erasing_regions` instead.
1359 query normalize_generic_arg_after_erasing_regions(
1360 goal: ParamEnvAnd<'tcx, GenericArg<'tcx>>
1361 ) -> GenericArg<'tcx> {
1362 desc { "normalizing `{}`", goal
.value
}
1365 query
implied_outlives_bounds(
1366 goal
: CanonicalTyGoal
<'tcx
>
1368 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, Vec
<OutlivesBound
<'tcx
>>>>,
1371 desc { "computing implied outlives bounds for `{:?}`
", goal }
1374 /// Do not call this query directly: invoke `infcx.at().dropck_outlives()` instead.
1375 query dropck_outlives(
1376 goal: CanonicalTyGoal<'tcx>
1378 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, DropckOutlivesResult<'tcx>>>,
1381 desc { "computing dropck types for `{:?}`", goal
}
1384 /// Do not call this query directly: invoke `infcx.predicate_may_hold()` or
1385 /// `infcx.predicate_must_hold()` instead.
1386 query
evaluate_obligation(
1387 goal
: CanonicalPredicateGoal
<'tcx
>
1388 ) -> Result
<traits
::EvaluationResult
, traits
::OverflowError
> {
1389 desc { "evaluating trait selection obligation `{}`
", goal.value.value }
1392 query evaluate_goal(
1393 goal: traits::ChalkCanonicalGoal<'tcx>
1395 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, ()>>,
1398 desc { "evaluating trait selection obligation `{}`", goal
.value
}
1401 query
type_implements_trait(
1402 key
: (DefId
, Ty
<'tcx
>, SubstsRef
<'tcx
>, ty
::ParamEnv
<'tcx
>, )
1404 desc { "evaluating `type_implements_trait` `{:?}`
", key }
1407 /// Do not call this query directly: part of the `Eq` type-op
1408 query type_op_ascribe_user_type(
1409 goal: CanonicalTypeOpAscribeUserTypeGoal<'tcx>
1411 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, ()>>,
1414 desc { "evaluating `type_op_ascribe_user_type` `{:?}`", goal
}
1417 /// Do not call this query directly: part of the `Eq` type-op
1419 goal
: CanonicalTypeOpEqGoal
<'tcx
>
1421 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, ()>>,
1424 desc { "evaluating `type_op_eq` `{:?}`
", goal }
1427 /// Do not call this query directly: part of the `Subtype` type-op
1428 query type_op_subtype(
1429 goal: CanonicalTypeOpSubtypeGoal<'tcx>
1431 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, ()>>,
1434 desc { "evaluating `type_op_subtype` `{:?}`", goal
}
1437 /// Do not call this query directly: part of the `ProvePredicate` type-op
1438 query
type_op_prove_predicate(
1439 goal
: CanonicalTypeOpProvePredicateGoal
<'tcx
>
1441 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, ()>>,
1444 desc { "evaluating `type_op_prove_predicate` `{:?}`
", goal }
1447 /// Do not call this query directly: part of the `Normalize` type-op
1448 query type_op_normalize_ty(
1449 goal: CanonicalTypeOpNormalizeGoal<'tcx, Ty<'tcx>>
1451 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, Ty<'tcx>>>,
1454 desc { "normalizing `{:?}`", goal
}
1457 /// Do not call this query directly: part of the `Normalize` type-op
1458 query
type_op_normalize_predicate(
1459 goal
: CanonicalTypeOpNormalizeGoal
<'tcx
, ty
::Predicate
<'tcx
>>
1461 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, ty
::Predicate
<'tcx
>>>,
1464 desc { "normalizing `{:?}`
", goal }
1467 /// Do not call this query directly: part of the `Normalize` type-op
1468 query type_op_normalize_poly_fn_sig(
1469 goal: CanonicalTypeOpNormalizeGoal<'tcx, ty::PolyFnSig<'tcx>>
1471 &'tcx Canonical<'tcx, canonical::QueryResponse<'tcx, ty::PolyFnSig<'tcx>>>,
1474 desc { "normalizing `{:?}`", goal
}
1477 /// Do not call this query directly: part of the `Normalize` type-op
1478 query
type_op_normalize_fn_sig(
1479 goal
: CanonicalTypeOpNormalizeGoal
<'tcx
, ty
::FnSig
<'tcx
>>
1481 &'tcx Canonical
<'tcx
, canonical
::QueryResponse
<'tcx
, ty
::FnSig
<'tcx
>>>,
1484 desc { "normalizing `{:?}`
", goal }
1487 query subst_and_check_impossible_predicates(key: (DefId, SubstsRef<'tcx>)) -> bool {
1489 "impossible substituted predicates
:`{}`
",
1490 tcx.def_path_str(key.0)
1494 query method_autoderef_steps(
1495 goal: CanonicalTyGoal<'tcx>
1496 ) -> MethodAutoderefStepsResult<'tcx> {
1497 desc { "computing autoderef types for `{:?}`", goal
}
1502 query
supported_target_features(_
: CrateNum
) -> FxHashMap
<String
, Option
<Symbol
>> {
1503 storage(ArenaCacheSelector
<'tcx
>)
1505 desc { "looking up supported target features" }
1508 // Get an estimate of the size of an InstanceDef based on its MIR for CGU partitioning.
1509 query
instance_def_size_estimate(def
: ty
::InstanceDef
<'tcx
>)
1511 desc { |tcx| "estimating size for `{}`
", tcx.def_path_str(def.def_id()) }
1514 query features_query(_: CrateNum) -> &'tcx rustc_feature::Features {
1516 desc { "looking up enabled feature gates" }
1519 /// Attempt to resolve the given `DefId` to an `Instance`, for the
1520 /// given generics args (`SubstsRef`), returning one of:
1521 /// * `Ok(Some(instance))` on success
1522 /// * `Ok(None)` when the `SubstsRef` are still too generic,
1523 /// and therefore don't allow finding the final `Instance`
1524 /// * `Err(ErrorReported)` when the `Instance` resolution process
1525 /// couldn't complete due to errors elsewhere - this is distinct
1526 /// from `Ok(None)` to avoid misleading diagnostics when an error
1527 /// has already been/will be emitted, for the original cause
1528 query resolve_instance(
1529 key: ty::ParamEnvAnd<'tcx, (DefId, SubstsRef<'tcx>)>
1530 ) -> Result<Option<ty::Instance<'tcx>>, ErrorReported> {
1531 desc { "resolving instance `{}`", ty
::Instance
::new(key
.value
.0, key
.value
.1) }
1534 query
resolve_instance_of_const_arg(
1535 key
: ty
::ParamEnvAnd
<'tcx
, (LocalDefId
, DefId
, SubstsRef
<'tcx
>)>
1536 ) -> Result
<Option
<ty
::Instance
<'tcx
>>, ErrorReported
> {
1538 "resolving instance of the const argument `{}`",
1539 ty
::Instance
::new(key
.value
.0.to_def_id(), key
.value
.2),
1543 query
normalize_opaque_types(key
: &'tcx ty
::List
<ty
::Predicate
<'tcx
>>) -> &'tcx ty
::List
<ty
::Predicate
<'tcx
>> {
1544 desc { "normalizing opaque types in {:?}
", key }