1 use rustc_data_structures::fx::FxHashMap;
2 use rustc_data_structures::vec_map::VecMap;
3 use rustc_hir::def_id::LocalDefId;
4 use rustc_hir::OpaqueTyOrigin;
5 use rustc_infer::infer::TyCtxtInferExt as _;
6 use rustc_infer::infer::{DefiningAnchor, InferCtxt};
7 use rustc_infer::traits::{Obligation, ObligationCause};
8 use rustc_middle::ty::subst::{GenericArgKind, InternalSubsts};
9 use rustc_middle::ty::visit::TypeVisitable;
10 use rustc_middle::ty::{self, OpaqueHiddenType, OpaqueTypeKey, Ty, TyCtxt, TypeFoldable};
12 use rustc_trait_selection::traits::error_reporting::TypeErrCtxtExt as _;
13 use rustc_trait_selection::traits::ObligationCtxt;
15 use super::RegionInferenceContext;
17 impl<'tcx> RegionInferenceContext<'tcx> {
18 /// Resolve any opaque types that were encountered while borrow checking
19 /// this item. This is then used to get the type in the `type_of` query.
21 /// For example consider `fn f<'a>(x: &'a i32) -> impl Sized + 'a { x }`.
22 /// This is lowered to give HIR something like
24 /// type f<'a>::_Return<'_a> = impl Sized + '_a;
25 /// fn f<'a>(x: &'a i32) -> f<'static>::_Return<'a> { x }
27 /// When checking the return type record the type from the return and the
28 /// type used in the return value. In this case they might be `_Return<'1>`
29 /// and `&'2 i32` respectively.
31 /// Once we to this method, we have completed region inference and want to
32 /// call `infer_opaque_definition_from_instantiation` to get the inferred
33 /// type of `_Return<'_a>`. `infer_opaque_definition_from_instantiation`
34 /// compares lifetimes directly, so we need to map the inference variables
35 /// back to concrete lifetimes: `'static`, `ReEarlyBound` or `ReFree`.
37 /// First we map all the lifetimes in the concrete type to an equal
38 /// universal region that occurs in the concrete type's substs, in this case
39 /// this would result in `&'1 i32`. We only consider regions in the substs
40 /// in case there is an equal region that does not. For example, this should
42 /// `fn f<'a: 'b, 'b: 'a>(x: *mut &'b i32) -> impl Sized + 'a { x }`
44 /// Then we map the regions in both the type and the subst to their
45 /// `external_name` giving `concrete_type = &'a i32`,
46 /// `substs = ['static, 'a]`. This will then allow
47 /// `infer_opaque_definition_from_instantiation` to determine that
48 /// `_Return<'_a> = &'_a i32`.
50 /// There's a slight complication around closures. Given
51 /// `fn f<'a: 'a>() { || {} }` the closure's type is something like
52 /// `f::<'a>::{{closure}}`. The region parameter from f is essentially
53 /// ignored by type checking so ends up being inferred to an empty region.
54 /// Calling `universal_upper_bound` for such a region gives `fr_fn_body`,
55 /// which has no `external_name` in which case we use `'empty` as the
56 /// region to pass to `infer_opaque_definition_from_instantiation`.
57 #[instrument(level = "debug", skip(self, infcx), ret)]
58 pub(crate) fn infer_opaque_types(
60 infcx: &InferCtxt<'tcx>,
61 opaque_ty_decls: VecMap<OpaqueTypeKey<'tcx>, (OpaqueHiddenType<'tcx>, OpaqueTyOrigin)>,
62 ) -> VecMap<LocalDefId, OpaqueHiddenType<'tcx>> {
63 let mut result: VecMap<LocalDefId, OpaqueHiddenType<'tcx>> = VecMap::new();
64 for (opaque_type_key, (concrete_type, origin)) in opaque_ty_decls {
65 let substs = opaque_type_key.substs;
66 debug!(?concrete_type, ?substs);
68 let mut subst_regions = vec![self.universal_regions.fr_static];
69 let universal_substs = infcx.tcx.fold_regions(substs, |region, _| {
70 if let ty::RePlaceholder(..) = region.kind() {
71 // Higher kinded regions don't need remapping, they don't refer to anything outside of this the substs.
74 let vid = self.to_region_vid(region);
76 let scc = self.constraint_sccs.scc(vid);
78 match self.scc_values.universal_regions_outlived_by(scc).find_map(|lb| {
79 self.eval_equal(vid, lb).then_some(self.definitions[lb].external_name?)
82 let vid = self.universal_regions.to_region_vid(region);
83 subst_regions.push(vid);
87 subst_regions.push(vid);
88 infcx.tcx.sess.delay_span_bug(
90 "opaque type with non-universal region substs",
92 infcx.tcx.lifetimes.re_static
98 subst_regions.dedup();
100 let universal_concrete_type =
101 infcx.tcx.fold_regions(concrete_type, |region, _| match *region {
102 ty::ReVar(vid) => subst_regions
104 .find(|ur_vid| self.eval_equal(vid, **ur_vid))
105 .and_then(|ur_vid| self.definitions[*ur_vid].external_name)
106 .unwrap_or(infcx.tcx.lifetimes.re_erased),
110 debug!(?universal_concrete_type, ?universal_substs);
112 let opaque_type_key =
113 OpaqueTypeKey { def_id: opaque_type_key.def_id, substs: universal_substs };
114 let ty = infcx.infer_opaque_definition_from_instantiation(
116 universal_concrete_type,
119 // Sometimes two opaque types are the same only after we remap the generic parameters
120 // back to the opaque type definition. E.g. we may have `OpaqueType<X, Y>` mapped to `(X, Y)`
121 // and `OpaqueType<Y, X>` mapped to `(Y, X)`, and those are the same, but we only know that
122 // once we convert the generic parameters to those of the opaque type.
123 if let Some(prev) = result.get_mut(&opaque_type_key.def_id) {
125 if !ty.references_error() {
126 prev.report_mismatch(
127 &OpaqueHiddenType { ty, span: concrete_type.span },
131 prev.ty = infcx.tcx.ty_error();
133 // Pick a better span if there is one.
134 // FIXME(oli-obk): collect multiple spans for better diagnostics down the road.
135 prev.span = prev.span.substitute_dummy(concrete_type.span);
138 opaque_type_key.def_id,
139 OpaqueHiddenType { ty, span: concrete_type.span },
146 /// Map the regions in the type to named regions. This is similar to what
147 /// `infer_opaque_types` does, but can infer any universal region, not only
148 /// ones from the substs for the opaque type. It also doesn't double check
149 /// that the regions produced are in fact equal to the named region they are
150 /// replaced with. This is fine because this function is only to improve the
151 /// region names in error messages.
152 pub(crate) fn name_regions<T>(&self, tcx: TyCtxt<'tcx>, ty: T) -> T
154 T: TypeFoldable<'tcx>,
156 tcx.fold_regions(ty, |region, _| match *region {
158 // Find something that we can name
159 let upper_bound = self.approx_universal_upper_bound(vid);
160 let upper_bound = &self.definitions[upper_bound];
161 match upper_bound.external_name {
164 // Nothing exact found, so we pick the first one that we find.
165 let scc = self.constraint_sccs.scc(vid);
166 for vid in self.rev_scc_graph.as_ref().unwrap().upper_bounds(scc) {
167 match self.definitions[vid].external_name {
169 Some(region) if region.is_static() => {}
170 Some(region) => return region,
182 pub trait InferCtxtExt<'tcx> {
183 fn infer_opaque_definition_from_instantiation(
185 opaque_type_key: OpaqueTypeKey<'tcx>,
186 instantiated_ty: OpaqueHiddenType<'tcx>,
187 origin: OpaqueTyOrigin,
191 impl<'tcx> InferCtxtExt<'tcx> for InferCtxt<'tcx> {
192 /// Given the fully resolved, instantiated type for an opaque
193 /// type, i.e., the value of an inference variable like C1 or C2
194 /// (*), computes the "definition type" for an opaque type
195 /// definition -- that is, the inferred value of `Foo1<'x>` or
196 /// `Foo2<'x>` that we would conceptually use in its definition:
197 /// ```ignore (illustrative)
198 /// type Foo1<'x> = impl Bar<'x> = AAA; // <-- this type AAA
199 /// type Foo2<'x> = impl Bar<'x> = BBB; // <-- or this type BBB
200 /// fn foo<'a, 'b>(..) -> (Foo1<'a>, Foo2<'b>) { .. }
202 /// Note that these values are defined in terms of a distinct set of
203 /// generic parameters (`'x` instead of `'a`) from C1 or C2. The main
204 /// purpose of this function is to do that translation.
206 /// (*) C1 and C2 were introduced in the comments on
207 /// `register_member_constraints`. Read that comment for more context.
211 /// - `def_id`, the `impl Trait` type
212 /// - `substs`, the substs used to instantiate this opaque type
213 /// - `instantiated_ty`, the inferred type C1 -- fully resolved, lifted version of
214 /// `opaque_defn.concrete_ty`
215 #[instrument(level = "debug", skip(self))]
216 fn infer_opaque_definition_from_instantiation(
218 opaque_type_key: OpaqueTypeKey<'tcx>,
219 instantiated_ty: OpaqueHiddenType<'tcx>,
220 origin: OpaqueTyOrigin,
222 if let Some(e) = self.tainted_by_errors() {
223 return self.tcx.ty_error_with_guaranteed(e);
226 let definition_ty = instantiated_ty
227 .remap_generic_params_to_declaration_params(opaque_type_key, self.tcx, false, origin)
230 if !check_opaque_type_parameter_valid(
234 instantiated_ty.span,
236 return self.tcx.ty_error();
239 // Only check this for TAIT. RPIT already supports `src/test/ui/impl-trait/nested-return-type2.rs`
240 // on stable and we'd break that.
241 let OpaqueTyOrigin::TyAlias = origin else {
242 return definition_ty;
244 let def_id = opaque_type_key.def_id;
245 // This logic duplicates most of `check_opaque_meets_bounds`.
246 // FIXME(oli-obk): Also do region checks here and then consider removing `check_opaque_meets_bounds` entirely.
247 let param_env = self.tcx.param_env(def_id);
248 let body_id = self.tcx.local_def_id_to_hir_id(def_id);
249 // HACK This bubble is required for this tests to pass:
250 // type-alias-impl-trait/issue-67844-nested-opaque.rs
252 self.tcx.infer_ctxt().with_opaque_type_inference(DefiningAnchor::Bubble).build();
253 let ocx = ObligationCtxt::new(&infcx);
254 // Require the hidden type to be well-formed with only the generics of the opaque type.
255 // Defining use functions may have more bounds than the opaque type, which is ok, as long as the
256 // hidden type is well formed even without those bounds.
257 let predicate = ty::Binder::dummy(ty::PredicateKind::WellFormed(definition_ty.into()));
259 let id_substs = InternalSubsts::identity_for_item(self.tcx, def_id.to_def_id());
261 // Require that the hidden type actually fulfills all the bounds of the opaque type, even without
262 // the bounds that the function supplies.
263 let opaque_ty = self.tcx.mk_opaque(def_id.to_def_id(), id_substs);
264 if let Err(err) = ocx.eq(
265 &ObligationCause::misc(instantiated_ty.span, body_id),
272 .report_mismatched_types(
273 &ObligationCause::misc(instantiated_ty.span, body_id),
281 ocx.register_obligation(Obligation::misc(
283 instantiated_ty.span,
289 // Check that all obligations are satisfied by the implementation's
291 let errors = ocx.select_all_or_error();
293 // This is still required for many(half of the tests in ui/type-alias-impl-trait)
295 let _ = infcx.inner.borrow_mut().opaque_type_storage.take_opaque_types();
297 if errors.is_empty() {
300 let reported = infcx.err_ctxt().report_fulfillment_errors(&errors, None);
301 self.tcx.ty_error_with_guaranteed(reported)
306 fn check_opaque_type_parameter_valid(
308 opaque_type_key: OpaqueTypeKey<'_>,
309 origin: OpaqueTyOrigin,
313 // No need to check return position impl trait (RPIT)
314 // because for type and const parameters they are correct
315 // by construction: we convert
317 // fn foo<P0..Pn>() -> impl Trait
322 // fn foo<P0..Pn>() -> Foo<P0...Pn>.
324 // For lifetime parameters we convert
326 // fn foo<'l0..'ln>() -> impl Trait<'l0..'lm>
330 // type foo::<'p0..'pn>::Foo<'q0..'qm>
331 // fn foo<l0..'ln>() -> foo::<'static..'static>::Foo<'l0..'lm>.
333 // which would error here on all of the `'static` args.
334 OpaqueTyOrigin::FnReturn(..) | OpaqueTyOrigin::AsyncFn(..) => return true,
336 OpaqueTyOrigin::TyAlias => {}
338 let opaque_generics = tcx.generics_of(opaque_type_key.def_id);
339 let mut seen_params: FxHashMap<_, Vec<_>> = FxHashMap::default();
340 for (i, arg) in opaque_type_key.substs.iter().enumerate() {
341 let arg_is_param = match arg.unpack() {
342 GenericArgKind::Type(ty) => matches!(ty.kind(), ty::Param(_)),
343 GenericArgKind::Lifetime(lt) if lt.is_static() => {
345 .struct_span_err(span, "non-defining opaque type use in defining scope")
347 tcx.def_span(opaque_generics.param_at(i, tcx).def_id),
348 "cannot use static lifetime; use a bound lifetime \
349 instead or remove the lifetime parameter from the \
355 GenericArgKind::Lifetime(lt) => {
356 matches!(*lt, ty::ReEarlyBound(_) | ty::ReFree(_))
358 GenericArgKind::Const(ct) => matches!(ct.kind(), ty::ConstKind::Param(_)),
362 seen_params.entry(arg).or_default().push(i);
364 // Prevent `fn foo() -> Foo<u32>` from being defining.
365 let opaque_param = opaque_generics.param_at(i, tcx);
367 .struct_span_err(span, "non-defining opaque type use in defining scope")
369 tcx.def_span(opaque_param.def_id),
371 "used non-generic {} `{}` for generic parameter",
372 opaque_param.kind.descr(),
381 for (_, indices) in seen_params {
382 if indices.len() > 1 {
383 let descr = opaque_generics.param_at(indices[0], tcx).kind.descr();
384 let spans: Vec<_> = indices
386 .map(|i| tcx.def_span(opaque_generics.param_at(i, tcx).def_id))
389 .struct_span_err(span, "non-defining opaque type use in defining scope")
390 .span_note(spans, &format!("{} used multiple times", descr))