use rustc_errors::{Applicability, StashKey}; use rustc_hir as hir; use rustc_hir::def_id::{DefId, LocalDefId}; use rustc_hir::intravisit; use rustc_hir::intravisit::Visitor; use rustc_hir::{HirId, Node}; use rustc_middle::hir::nested_filter; use rustc_middle::ty::print::with_forced_trimmed_paths; use rustc_middle::ty::subst::InternalSubsts; use rustc_middle::ty::util::IntTypeExt; use rustc_middle::ty::{ self, DefIdTree, IsSuggestable, Ty, TyCtxt, TypeFolder, TypeSuperFoldable, TypeVisitableExt, }; use rustc_span::symbol::Ident; use rustc_span::{Span, DUMMY_SP}; use super::ItemCtxt; use super::{bad_placeholder, is_suggestable_infer_ty}; use crate::errors::UnconstrainedOpaqueType; /// Computes the relevant generic parameter for a potential generic const argument. /// /// This should be called using the query `tcx.opt_const_param_of`. pub(super) fn opt_const_param_of(tcx: TyCtxt<'_>, def_id: LocalDefId) -> Option { use hir::*; let hir_id = tcx.hir().local_def_id_to_hir_id(def_id); match tcx.hir().get(hir_id) { Node::AnonConst(_) => (), _ => return None, }; let parent_node_id = tcx.hir().parent_id(hir_id); let parent_node = tcx.hir().get(parent_node_id); let (generics, arg_idx) = match parent_node { // This match arm is for when the def_id appears in a GAT whose // path can't be resolved without typechecking e.g. // // trait Foo { // type Assoc; // fn foo() -> Self::Assoc<3>; // } // // In the above code we would call this query with the def_id of 3 and // the parent_node we match on would be the hir node for Self::Assoc<3> // // `Self::Assoc<3>` cant be resolved without typechecking here as we // didnt write ::Assoc<3>. If we did then another match // arm would handle this. // // I believe this match arm is only needed for GAT but I am not 100% sure - BoxyUwU Node::Ty(hir_ty @ Ty { kind: TyKind::Path(QPath::TypeRelative(_, segment)), .. }) => { // Find the Item containing the associated type so we can create an ItemCtxt. // Using the ItemCtxt convert the HIR for the unresolved assoc type into a // ty which is a fully resolved projection. // For the code example above, this would mean converting Self::Assoc<3> // into a ty::Alias(ty::Projection, ::Assoc<3>) let item_def_id = tcx .hir() .parent_owner_iter(hir_id) .find(|(_, node)| matches!(node, OwnerNode::Item(_))) .unwrap() .0 .to_def_id(); let item_ctxt = &ItemCtxt::new(tcx, item_def_id) as &dyn crate::astconv::AstConv<'_>; let ty = item_ctxt.ast_ty_to_ty(hir_ty); // Iterate through the generics of the projection to find the one that corresponds to // the def_id that this query was called with. We filter to only type and const args here // as a precaution for if it's ever allowed to elide lifetimes in GAT's. It currently isn't // but it can't hurt to be safe ^^ if let ty::Alias(ty::Projection, projection) = ty.kind() { let generics = tcx.generics_of(projection.def_id); let arg_index = segment .args .and_then(|args| { args.args .iter() .filter(|arg| arg.is_ty_or_const()) .position(|arg| arg.hir_id() == hir_id) }) .unwrap_or_else(|| { bug!("no arg matching AnonConst in segment"); }); (generics, arg_index) } else { // I dont think it's possible to reach this but I'm not 100% sure - BoxyUwU tcx.sess.delay_span_bug( tcx.def_span(def_id), "unexpected non-GAT usage of an anon const", ); return None; } } Node::Expr(&Expr { kind: ExprKind::MethodCall(segment, ..) | ExprKind::Path(QPath::TypeRelative(_, segment)), .. }) => { let body_owner = tcx.hir().enclosing_body_owner(hir_id); let tables = tcx.typeck(body_owner); // This may fail in case the method/path does not actually exist. // As there is no relevant param for `def_id`, we simply return // `None` here. let type_dependent_def = tables.type_dependent_def_id(parent_node_id)?; let idx = segment .args .and_then(|args| { args.args .iter() .filter(|arg| arg.is_ty_or_const()) .position(|arg| arg.hir_id() == hir_id) }) .unwrap_or_else(|| { bug!("no arg matching AnonConst in segment"); }); (tcx.generics_of(type_dependent_def), idx) } Node::Ty(&Ty { kind: TyKind::Path(_), .. }) | Node::Expr(&Expr { kind: ExprKind::Path(_) | ExprKind::Struct(..), .. }) | Node::TraitRef(..) | Node::Pat(_) => { let path = match parent_node { Node::Ty(&Ty { kind: TyKind::Path(QPath::Resolved(_, path)), .. }) | Node::TraitRef(&TraitRef { path, .. }) => &*path, Node::Expr(&Expr { kind: ExprKind::Path(QPath::Resolved(_, path)) | ExprKind::Struct(&QPath::Resolved(_, path), ..), .. }) => { let body_owner = tcx.hir().enclosing_body_owner(hir_id); let _tables = tcx.typeck(body_owner); &*path } Node::Pat(pat) => { if let Some(path) = get_path_containing_arg_in_pat(pat, hir_id) { path } else { tcx.sess.delay_span_bug( tcx.def_span(def_id), &format!("unable to find const parent for {} in pat {:?}", hir_id, pat), ); return None; } } _ => { tcx.sess.delay_span_bug( tcx.def_span(def_id), &format!("unexpected const parent path {:?}", parent_node), ); return None; } }; // We've encountered an `AnonConst` in some path, so we need to // figure out which generic parameter it corresponds to and return // the relevant type. let Some((arg_index, segment)) = path.segments.iter().find_map(|seg| { let args = seg.args?; args.args .iter() .filter(|arg| arg.is_ty_or_const()) .position(|arg| arg.hir_id() == hir_id) .map(|index| (index, seg)).or_else(|| args.bindings .iter() .filter_map(TypeBinding::opt_const) .position(|ct| ct.hir_id == hir_id) .map(|idx| (idx, seg))) }) else { tcx.sess.delay_span_bug( tcx.def_span(def_id), "no arg matching AnonConst in path", ); return None; }; let generics = match tcx.res_generics_def_id(segment.res) { Some(def_id) => tcx.generics_of(def_id), None => { tcx.sess.delay_span_bug( tcx.def_span(def_id), &format!("unexpected anon const res {:?} in path: {:?}", segment.res, path), ); return None; } }; (generics, arg_index) } _ => return None, }; debug!(?parent_node); debug!(?generics, ?arg_idx); generics .params .iter() .filter(|param| param.kind.is_ty_or_const()) .nth(match generics.has_self && generics.parent.is_none() { true => arg_idx + 1, false => arg_idx, }) .and_then(|param| match param.kind { ty::GenericParamDefKind::Const { .. } => { debug!(?param); Some(param.def_id) } _ => None, }) } fn get_path_containing_arg_in_pat<'hir>( pat: &'hir hir::Pat<'hir>, arg_id: HirId, ) -> Option<&'hir hir::Path<'hir>> { use hir::*; let is_arg_in_path = |p: &hir::Path<'_>| { p.segments .iter() .filter_map(|seg| seg.args) .flat_map(|args| args.args) .any(|arg| arg.hir_id() == arg_id) }; let mut arg_path = None; pat.walk(|pat| match pat.kind { PatKind::Struct(QPath::Resolved(_, path), _, _) | PatKind::TupleStruct(QPath::Resolved(_, path), _, _) | PatKind::Path(QPath::Resolved(_, path)) if is_arg_in_path(path) => { arg_path = Some(path); false } _ => true, }); arg_path } pub(super) fn type_of(tcx: TyCtxt<'_>, def_id: DefId) -> ty::EarlyBinder> { let def_id = def_id.expect_local(); use rustc_hir::*; let hir_id = tcx.hir().local_def_id_to_hir_id(def_id); let icx = ItemCtxt::new(tcx, def_id.to_def_id()); let output = match tcx.hir().get(hir_id) { Node::TraitItem(item) => match item.kind { TraitItemKind::Fn(..) => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_fn_def(def_id.to_def_id(), substs) } TraitItemKind::Const(ty, body_id) => body_id .and_then(|body_id| { is_suggestable_infer_ty(ty) .then(|| infer_placeholder_type(tcx, def_id, body_id, ty.span, item.ident, "constant",)) }) .unwrap_or_else(|| icx.to_ty(ty)), TraitItemKind::Type(_, Some(ty)) => icx.to_ty(ty), TraitItemKind::Type(_, None) => { span_bug!(item.span, "associated type missing default"); } }, Node::ImplItem(item) => match item.kind { ImplItemKind::Fn(..) => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_fn_def(def_id.to_def_id(), substs) } ImplItemKind::Const(ty, body_id) => { if is_suggestable_infer_ty(ty) { infer_placeholder_type(tcx, def_id, body_id, ty.span, item.ident, "constant") } else { icx.to_ty(ty) } } ImplItemKind::Type(ty) => { if tcx.impl_trait_ref(tcx.hir().get_parent_item(hir_id)).is_none() { check_feature_inherent_assoc_ty(tcx, item.span); } icx.to_ty(ty) } }, Node::Item(item) => { match item.kind { ItemKind::Static(ty, .., body_id) => { if is_suggestable_infer_ty(ty) { infer_placeholder_type( tcx, def_id, body_id, ty.span, item.ident, "static variable", ) } else { icx.to_ty(ty) } } ItemKind::Const(ty, body_id) => { if is_suggestable_infer_ty(ty) { infer_placeholder_type( tcx, def_id, body_id, ty.span, item.ident, "constant", ) } else { icx.to_ty(ty) } } ItemKind::TyAlias(self_ty, _) => icx.to_ty(self_ty), ItemKind::Impl(hir::Impl { self_ty, .. }) => { match self_ty.find_self_aliases() { spans if spans.len() > 0 => { let guar = tcx.sess.emit_err(crate::errors::SelfInImplSelf { span: spans.into(), note: () }); tcx.ty_error(guar) }, _ => icx.to_ty(*self_ty), } }, ItemKind::Fn(..) => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_fn_def(def_id.to_def_id(), substs) } ItemKind::Enum(..) | ItemKind::Struct(..) | ItemKind::Union(..) => { let def = tcx.adt_def(def_id); let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_adt(def, substs) } ItemKind::OpaqueTy(OpaqueTy { origin: hir::OpaqueTyOrigin::TyAlias, .. }) => { find_opaque_ty_constraints_for_tait(tcx, def_id) } // Opaque types desugared from `impl Trait`. ItemKind::OpaqueTy(OpaqueTy { origin: hir::OpaqueTyOrigin::FnReturn(owner) | hir::OpaqueTyOrigin::AsyncFn(owner), in_trait, .. }) => { if in_trait { assert!(tcx.impl_defaultness(owner).has_value()); } find_opaque_ty_constraints_for_rpit(tcx, def_id, owner) } ItemKind::Trait(..) | ItemKind::TraitAlias(..) | ItemKind::Macro(..) | ItemKind::Mod(..) | ItemKind::ForeignMod { .. } | ItemKind::GlobalAsm(..) | ItemKind::ExternCrate(..) | ItemKind::Use(..) => { span_bug!( item.span, "compute_type_of_item: unexpected item type: {:?}", item.kind ); } } } Node::ForeignItem(foreign_item) => match foreign_item.kind { ForeignItemKind::Fn(..) => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_fn_def(def_id.to_def_id(), substs) } ForeignItemKind::Static(t, _) => icx.to_ty(t), ForeignItemKind::Type => tcx.mk_foreign(def_id.to_def_id()), }, Node::Ctor(def) | Node::Variant(Variant { data: def, .. }) => match def { VariantData::Unit(..) | VariantData::Struct(..) => { tcx.type_of(tcx.hir().get_parent_item(hir_id)).subst_identity() } VariantData::Tuple(..) => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); tcx.mk_fn_def(def_id.to_def_id(), substs) } }, Node::Field(field) => icx.to_ty(field.ty), Node::Expr(&Expr { kind: ExprKind::Closure { .. }, .. }) => { tcx.typeck(def_id).node_type(hir_id) } Node::AnonConst(_) if let Some(param) = tcx.opt_const_param_of(def_id) => { // We defer to `type_of` of the corresponding parameter // for generic arguments. tcx.type_of(param).subst_identity() } Node::AnonConst(_) => { let parent_node = tcx.hir().get_parent(hir_id); match parent_node { Node::Ty(Ty { kind: TyKind::Array(_, constant), .. }) | Node::Expr(Expr { kind: ExprKind::Repeat(_, constant), .. }) if constant.hir_id() == hir_id => { tcx.types.usize } Node::Ty(Ty { kind: TyKind::Typeof(e), .. }) if e.hir_id == hir_id => { tcx.typeck(def_id).node_type(e.hir_id) } Node::Expr(Expr { kind: ExprKind::ConstBlock(anon_const), .. }) if anon_const.hir_id == hir_id => { let substs = InternalSubsts::identity_for_item(tcx, def_id.to_def_id()); substs.as_inline_const().ty() } Node::Expr(&Expr { kind: ExprKind::InlineAsm(asm), .. }) | Node::Item(&Item { kind: ItemKind::GlobalAsm(asm), .. }) if asm.operands.iter().any(|(op, _op_sp)| match op { hir::InlineAsmOperand::Const { anon_const } | hir::InlineAsmOperand::SymFn { anon_const } => { anon_const.hir_id == hir_id } _ => false, }) => { tcx.typeck(def_id).node_type(hir_id) } Node::Variant(Variant { disr_expr: Some(e), .. }) if e.hir_id == hir_id => { tcx.adt_def(tcx.hir().get_parent_item(hir_id)).repr().discr_type().to_ty(tcx) } Node::TypeBinding( TypeBinding { hir_id: binding_id, kind: TypeBindingKind::Equality { term: Term::Const(e) }, ident, .. }, ) if let Node::TraitRef(trait_ref) = tcx.hir().get_parent(*binding_id) && e.hir_id == hir_id => { let Some(trait_def_id) = trait_ref.trait_def_id() else { return ty::EarlyBinder(tcx.ty_error_with_message(DUMMY_SP, "Could not find trait")); }; let assoc_items = tcx.associated_items(trait_def_id); let assoc_item = assoc_items.find_by_name_and_kind( tcx, *ident, ty::AssocKind::Const, def_id.to_def_id(), ); if let Some(assoc_item) = assoc_item { tcx.type_of(assoc_item.def_id).subst_identity() } else { // FIXME(associated_const_equality): add a useful error message here. tcx.ty_error_with_message( DUMMY_SP, "Could not find associated const on trait", ) } } Node::TypeBinding( TypeBinding { hir_id: binding_id, gen_args, kind, ident, .. }, ) if let Node::TraitRef(trait_ref) = tcx.hir().get_parent(*binding_id) && let Some((idx, _)) = gen_args.args.iter().enumerate().find(|(_, arg)| { if let GenericArg::Const(ct) = arg { ct.value.hir_id == hir_id } else { false } }) => { let Some(trait_def_id) = trait_ref.trait_def_id() else { return ty::EarlyBinder(tcx.ty_error_with_message(DUMMY_SP, "Could not find trait")); }; let assoc_items = tcx.associated_items(trait_def_id); let assoc_item = assoc_items.find_by_name_and_kind( tcx, *ident, match kind { // I think `` type bindings requires that `A` is a type TypeBindingKind::Constraint { .. } | TypeBindingKind::Equality { term: Term::Ty(..) } => { ty::AssocKind::Type } TypeBindingKind::Equality { term: Term::Const(..) } => { ty::AssocKind::Const } }, def_id.to_def_id(), ); if let Some(param) = assoc_item.map(|item| &tcx.generics_of(item.def_id).params[idx]).filter(|param| param.kind.is_ty_or_const()) { tcx.type_of(param.def_id).subst_identity() } else { // FIXME(associated_const_equality): add a useful error message here. tcx.ty_error_with_message( DUMMY_SP, "Could not find associated const on trait", ) } } Node::GenericParam(&GenericParam { def_id: param_def_id, kind: GenericParamKind::Const { default: Some(ct), .. }, .. }) if ct.hir_id == hir_id => tcx.type_of(param_def_id).subst_identity(), x => tcx.ty_error_with_message( DUMMY_SP, &format!("unexpected const parent in type_of(): {x:?}"), ), } } Node::GenericParam(param) => match ¶m.kind { GenericParamKind::Type { default: Some(ty), .. } | GenericParamKind::Const { ty, .. } => icx.to_ty(ty), x => bug!("unexpected non-type Node::GenericParam: {:?}", x), }, x => { bug!("unexpected sort of node in type_of(): {:?}", x); } }; ty::EarlyBinder(output) } #[instrument(skip(tcx), level = "debug")] /// Checks "defining uses" of opaque `impl Trait` types to ensure that they meet the restrictions /// laid for "higher-order pattern unification". /// This ensures that inference is tractable. /// In particular, definitions of opaque types can only use other generics as arguments, /// and they cannot repeat an argument. Example: /// /// ```ignore (illustrative) /// type Foo = impl Bar; /// /// // Okay -- `Foo` is applied to two distinct, generic types. /// fn a() -> Foo { .. } /// /// // Not okay -- `Foo` is applied to `T` twice. /// fn b() -> Foo { .. } /// /// // Not okay -- `Foo` is applied to a non-generic type. /// fn b() -> Foo { .. } /// ``` /// fn find_opaque_ty_constraints_for_tait(tcx: TyCtxt<'_>, def_id: LocalDefId) -> Ty<'_> { use rustc_hir::{Expr, ImplItem, Item, TraitItem}; struct ConstraintLocator<'tcx> { tcx: TyCtxt<'tcx>, /// def_id of the opaque type whose defining uses are being checked def_id: LocalDefId, /// as we walk the defining uses, we are checking that all of them /// define the same hidden type. This variable is set to `Some` /// with the first type that we find, and then later types are /// checked against it (we also carry the span of that first /// type). found: Option>, /// In the presence of dead code, typeck may figure out a hidden type /// while borrowck will now. We collect these cases here and check at /// the end that we actually found a type that matches (modulo regions). typeck_types: Vec>, } impl ConstraintLocator<'_> { #[instrument(skip(self), level = "debug")] fn check(&mut self, item_def_id: LocalDefId) { // Don't try to check items that cannot possibly constrain the type. if !self.tcx.has_typeck_results(item_def_id) { debug!("no constraint: no typeck results"); return; } // Calling `mir_borrowck` can lead to cycle errors through // const-checking, avoid calling it if we don't have to. // ```rust // type Foo = impl Fn() -> usize; // when computing type for this // const fn bar() -> Foo { // || 0usize // } // const BAZR: Foo = bar(); // we would mir-borrowck this, causing cycles // // because we again need to reveal `Foo` so we can check whether the // // constant does not contain interior mutability. // ``` let tables = self.tcx.typeck(item_def_id); if let Some(guar) = tables.tainted_by_errors { self.found = Some(ty::OpaqueHiddenType { span: DUMMY_SP, ty: self.tcx.ty_error(guar) }); return; } let Some(&typeck_hidden_ty) = tables.concrete_opaque_types.get(&self.def_id) else { debug!("no constraints in typeck results"); return; }; if self.typeck_types.iter().all(|prev| prev.ty != typeck_hidden_ty.ty) { self.typeck_types.push(typeck_hidden_ty); } // Use borrowck to get the type with unerased regions. let concrete_opaque_types = &self.tcx.mir_borrowck(item_def_id).concrete_opaque_types; debug!(?concrete_opaque_types); if let Some(&concrete_type) = concrete_opaque_types.get(&self.def_id) { debug!(?concrete_type, "found constraint"); if let Some(prev) = &mut self.found { if concrete_type.ty != prev.ty && !(concrete_type, prev.ty).references_error() { let guar = prev.report_mismatch(&concrete_type, self.tcx); prev.ty = self.tcx.ty_error(guar); } } else { self.found = Some(concrete_type); } } } } impl<'tcx> intravisit::Visitor<'tcx> for ConstraintLocator<'tcx> { type NestedFilter = nested_filter::All; fn nested_visit_map(&mut self) -> Self::Map { self.tcx.hir() } fn visit_expr(&mut self, ex: &'tcx Expr<'tcx>) { if let hir::ExprKind::Closure(closure) = ex.kind { self.check(closure.def_id); } intravisit::walk_expr(self, ex); } fn visit_item(&mut self, it: &'tcx Item<'tcx>) { trace!(?it.owner_id); // The opaque type itself or its children are not within its reveal scope. if it.owner_id.def_id != self.def_id { self.check(it.owner_id.def_id); intravisit::walk_item(self, it); } } fn visit_impl_item(&mut self, it: &'tcx ImplItem<'tcx>) { trace!(?it.owner_id); // The opaque type itself or its children are not within its reveal scope. if it.owner_id.def_id != self.def_id { self.check(it.owner_id.def_id); intravisit::walk_impl_item(self, it); } } fn visit_trait_item(&mut self, it: &'tcx TraitItem<'tcx>) { trace!(?it.owner_id); self.check(it.owner_id.def_id); intravisit::walk_trait_item(self, it); } } let hir_id = tcx.hir().local_def_id_to_hir_id(def_id); let scope = tcx.hir().get_defining_scope(hir_id); let mut locator = ConstraintLocator { def_id, tcx, found: None, typeck_types: vec![] }; debug!(?scope); if scope == hir::CRATE_HIR_ID { tcx.hir().walk_toplevel_module(&mut locator); } else { trace!("scope={:#?}", tcx.hir().get(scope)); match tcx.hir().get(scope) { // We explicitly call `visit_*` methods, instead of using `intravisit::walk_*` methods // This allows our visitor to process the defining item itself, causing // it to pick up any 'sibling' defining uses. // // For example, this code: // ``` // fn foo() { // type Blah = impl Debug; // let my_closure = || -> Blah { true }; // } // ``` // // requires us to explicitly process `foo()` in order // to notice the defining usage of `Blah`. Node::Item(it) => locator.visit_item(it), Node::ImplItem(it) => locator.visit_impl_item(it), Node::TraitItem(it) => locator.visit_trait_item(it), other => bug!("{:?} is not a valid scope for an opaque type item", other), } } let Some(hidden) = locator.found else { let reported = tcx.sess.emit_err(UnconstrainedOpaqueType { span: tcx.def_span(def_id), name: tcx.item_name(tcx.local_parent(def_id).to_def_id()), what: match tcx.hir().get(scope) { _ if scope == hir::CRATE_HIR_ID => "module", Node::Item(hir::Item { kind: hir::ItemKind::Mod(_), .. }) => "module", Node::Item(hir::Item { kind: hir::ItemKind::Impl(_), .. }) => "impl", _ => "item", }, }); return tcx.ty_error(reported); }; // Only check against typeck if we didn't already error if !hidden.ty.references_error() { for concrete_type in locator.typeck_types { if tcx.erase_regions(concrete_type.ty) != tcx.erase_regions(hidden.ty) && !(concrete_type, hidden).references_error() { hidden.report_mismatch(&concrete_type, tcx); } } } hidden.ty } fn find_opaque_ty_constraints_for_rpit( tcx: TyCtxt<'_>, def_id: LocalDefId, owner_def_id: LocalDefId, ) -> Ty<'_> { use rustc_hir::{Expr, ImplItem, Item, TraitItem}; struct ConstraintChecker<'tcx> { tcx: TyCtxt<'tcx>, /// def_id of the opaque type whose defining uses are being checked def_id: LocalDefId, found: ty::OpaqueHiddenType<'tcx>, } impl ConstraintChecker<'_> { #[instrument(skip(self), level = "debug")] fn check(&self, def_id: LocalDefId) { // Use borrowck to get the type with unerased regions. let concrete_opaque_types = &self.tcx.mir_borrowck(def_id).concrete_opaque_types; debug!(?concrete_opaque_types); for &(def_id, concrete_type) in concrete_opaque_types { if def_id != self.def_id { // Ignore constraints for other opaque types. continue; } debug!(?concrete_type, "found constraint"); if concrete_type.ty != self.found.ty && !(concrete_type, self.found).references_error() { self.found.report_mismatch(&concrete_type, self.tcx); } } } } impl<'tcx> intravisit::Visitor<'tcx> for ConstraintChecker<'tcx> { type NestedFilter = nested_filter::OnlyBodies; fn nested_visit_map(&mut self) -> Self::Map { self.tcx.hir() } fn visit_expr(&mut self, ex: &'tcx Expr<'tcx>) { if let hir::ExprKind::Closure(closure) = ex.kind { self.check(closure.def_id); } intravisit::walk_expr(self, ex); } fn visit_item(&mut self, it: &'tcx Item<'tcx>) { trace!(?it.owner_id); // The opaque type itself or its children are not within its reveal scope. if it.owner_id.def_id != self.def_id { self.check(it.owner_id.def_id); intravisit::walk_item(self, it); } } fn visit_impl_item(&mut self, it: &'tcx ImplItem<'tcx>) { trace!(?it.owner_id); // The opaque type itself or its children are not within its reveal scope. if it.owner_id.def_id != self.def_id { self.check(it.owner_id.def_id); intravisit::walk_impl_item(self, it); } } fn visit_trait_item(&mut self, it: &'tcx TraitItem<'tcx>) { trace!(?it.owner_id); self.check(it.owner_id.def_id); intravisit::walk_trait_item(self, it); } } let concrete = tcx.mir_borrowck(owner_def_id).concrete_opaque_types.get(&def_id).copied(); if let Some(concrete) = concrete { let scope = tcx.hir().local_def_id_to_hir_id(owner_def_id); debug!(?scope); let mut locator = ConstraintChecker { def_id, tcx, found: concrete }; match tcx.hir().get(scope) { Node::Item(it) => intravisit::walk_item(&mut locator, it), Node::ImplItem(it) => intravisit::walk_impl_item(&mut locator, it), Node::TraitItem(it) => intravisit::walk_trait_item(&mut locator, it), other => bug!("{:?} is not a valid scope for an opaque type item", other), } } concrete.map(|concrete| concrete.ty).unwrap_or_else(|| { let table = tcx.typeck(owner_def_id); if let Some(guar) = table.tainted_by_errors { // Some error in the // owner fn prevented us from populating // the `concrete_opaque_types` table. tcx.ty_error(guar) } else { table.concrete_opaque_types.get(&def_id).map(|ty| ty.ty).unwrap_or_else(|| { // We failed to resolve the opaque type or it // resolves to itself. We interpret this as the // no values of the hidden type ever being constructed, // so we can just make the hidden type be `!`. // For backwards compatibility reasons, we fall back to // `()` until we the diverging default is changed. tcx.mk_diverging_default() }) } }) } fn infer_placeholder_type<'a>( tcx: TyCtxt<'a>, def_id: LocalDefId, body_id: hir::BodyId, span: Span, item_ident: Ident, kind: &'static str, ) -> Ty<'a> { // Attempts to make the type nameable by turning FnDefs into FnPtrs. struct MakeNameable<'tcx> { tcx: TyCtxt<'tcx>, } impl<'tcx> TypeFolder> for MakeNameable<'tcx> { fn interner(&self) -> TyCtxt<'tcx> { self.tcx } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { let ty = match *ty.kind() { ty::FnDef(def_id, substs) => { self.tcx.mk_fn_ptr(self.tcx.fn_sig(def_id).subst(self.tcx, substs)) } _ => ty, }; ty.super_fold_with(self) } } let ty = tcx.diagnostic_only_typeck(def_id).node_type(body_id.hir_id); // If this came from a free `const` or `static mut?` item, // then the user may have written e.g. `const A = 42;`. // In this case, the parser has stashed a diagnostic for // us to improve in typeck so we do that now. match tcx.sess.diagnostic().steal_diagnostic(span, StashKey::ItemNoType) { Some(mut err) => { if !ty.references_error() { // Only suggest adding `:` if it was missing (and suggested by parsing diagnostic) let colon = if span == item_ident.span.shrink_to_hi() { ":" } else { "" }; // The parser provided a sub-optimal `HasPlaceholders` suggestion for the type. // We are typeck and have the real type, so remove that and suggest the actual type. // FIXME(eddyb) this looks like it should be functionality on `Diagnostic`. if let Ok(suggestions) = &mut err.suggestions { suggestions.clear(); } if let Some(ty) = ty.make_suggestable(tcx, false) { err.span_suggestion( span, &format!("provide a type for the {item}", item = kind), format!("{colon} {ty}"), Applicability::MachineApplicable, ); } else { with_forced_trimmed_paths!(err.span_note( tcx.hir().body(body_id).value.span, &format!("however, the inferred type `{ty}` cannot be named"), )); } } err.emit(); } None => { let mut diag = bad_placeholder(tcx, vec![span], kind); if !ty.references_error() { if let Some(ty) = ty.make_suggestable(tcx, false) { diag.span_suggestion( span, "replace with the correct type", ty, Applicability::MachineApplicable, ); } else { with_forced_trimmed_paths!(diag.span_note( tcx.hir().body(body_id).value.span, &format!("however, the inferred type `{ty}` cannot be named"), )); } } diag.emit(); } } // Typeck doesn't expect erased regions to be returned from `type_of`. tcx.fold_regions(ty, |r, _| match *r { ty::ReErased => tcx.lifetimes.re_static, _ => r, }) } fn check_feature_inherent_assoc_ty(tcx: TyCtxt<'_>, span: Span) { if !tcx.features().inherent_associated_types { use rustc_session::parse::feature_err; use rustc_span::symbol::sym; feature_err( &tcx.sess.parse_sess, sym::inherent_associated_types, span, "inherent associated types are unstable", ) .emit(); } }