//! Detecting language items. //! //! Language items are items that represent concepts intrinsic to the language //! itself. Examples are: //! //! * Traits that specify "kinds"; e.g., `Sync`, `Send`. //! * Traits that represent operators; e.g., `Add`, `Sub`, `Index`. //! * Functions called by the compiler itself. use crate::errors::{ DuplicateLangItem, IncorrectTarget, LangItemOnIncorrectTarget, UnknownLangItem, }; use crate::weak_lang_items; use rustc_ast as ast; use rustc_ast::visit; use rustc_data_structures::fx::FxHashMap; use rustc_hir::def_id::{DefId, LocalDefId}; use rustc_hir::lang_items::{extract, GenericRequirement}; use rustc_hir::{LangItem, LanguageItems, MethodKind, Target}; use rustc_middle::ty::{ResolverAstLowering, TyCtxt}; use rustc_session::cstore::ExternCrate; use rustc_span::symbol::kw::Empty; use rustc_span::Span; use rustc_middle::query::Providers; pub(crate) enum Duplicate { Plain, Crate, CrateDepends, } struct LanguageItemCollector<'ast, 'tcx> { items: LanguageItems, tcx: TyCtxt<'tcx>, resolver: &'ast ResolverAstLowering, // FIXME(#118552): We should probably feed def_span eagerly on def-id creation // so we can avoid constructing this map for local def-ids. item_spans: FxHashMap, parent_item: Option<&'ast ast::Item>, } impl<'ast, 'tcx> LanguageItemCollector<'ast, 'tcx> { fn new( tcx: TyCtxt<'tcx>, resolver: &'ast ResolverAstLowering, ) -> LanguageItemCollector<'ast, 'tcx> { LanguageItemCollector { tcx, resolver, items: LanguageItems::new(), item_spans: FxHashMap::default(), parent_item: None, } } fn check_for_lang( &mut self, actual_target: Target, def_id: LocalDefId, attrs: &'ast [ast::Attribute], item_span: Span, generics: Option<&'ast ast::Generics>, ) { if let Some((name, attr_span)) = extract(attrs) { match LangItem::from_name(name) { // Known lang item with attribute on correct target. Some(lang_item) if actual_target == lang_item.target() => { self.collect_item_extended( lang_item, def_id, item_span, attr_span, generics, actual_target, ); } // Known lang item with attribute on incorrect target. Some(lang_item) => { self.tcx.sess.emit_err(LangItemOnIncorrectTarget { span: attr_span, name, expected_target: lang_item.target(), actual_target, }); } // Unknown lang item. _ => { self.tcx.sess.emit_err(UnknownLangItem { span: attr_span, name }); } } } } fn collect_item(&mut self, lang_item: LangItem, item_def_id: DefId, item_span: Option) { // Check for duplicates. if let Some(original_def_id) = self.items.get(lang_item) && original_def_id != item_def_id { let lang_item_name = lang_item.name(); let crate_name = self.tcx.crate_name(item_def_id.krate); let mut dependency_of = Empty; let is_local = item_def_id.is_local(); let path = if is_local { String::new() } else { self.tcx .crate_extern_paths(item_def_id.krate) .iter() .map(|p| p.display().to_string()) .collect::>() .join(", ") }; let first_defined_span = self.item_spans.get(&original_def_id).copied(); let mut orig_crate_name = Empty; let mut orig_dependency_of = Empty; let orig_is_local = original_def_id.is_local(); let orig_path = if orig_is_local { String::new() } else { self.tcx .crate_extern_paths(original_def_id.krate) .iter() .map(|p| p.display().to_string()) .collect::>() .join(", ") }; if first_defined_span.is_none() { orig_crate_name = self.tcx.crate_name(original_def_id.krate); if let Some(ExternCrate { dependency_of: inner_dependency_of, .. }) = self.tcx.extern_crate(original_def_id) { orig_dependency_of = self.tcx.crate_name(*inner_dependency_of); } } let duplicate = if item_span.is_some() { Duplicate::Plain } else { match self.tcx.extern_crate(item_def_id) { Some(ExternCrate { dependency_of: inner_dependency_of, .. }) => { dependency_of = self.tcx.crate_name(*inner_dependency_of); Duplicate::CrateDepends } _ => Duplicate::Crate, } }; self.tcx.sess.emit_err(DuplicateLangItem { local_span: item_span, lang_item_name, crate_name, dependency_of, is_local, path, first_defined_span, orig_crate_name, orig_dependency_of, orig_is_local, orig_path, duplicate, }); } else { // Matched. self.items.set(lang_item, item_def_id); // Collect span for error later if let Some(item_span) = item_span { self.item_spans.insert(item_def_id, item_span); } } } // Like collect_item() above, but also checks whether the lang item is declared // with the right number of generic arguments. fn collect_item_extended( &mut self, lang_item: LangItem, item_def_id: LocalDefId, item_span: Span, attr_span: Span, generics: Option<&'ast ast::Generics>, target: Target, ) { let name = lang_item.name(); if let Some(generics) = generics { // Now check whether the lang_item has the expected number of generic // arguments. Generally speaking, binary and indexing operations have // one (for the RHS/index), unary operations have none, the closure // traits have one for the argument list, coroutines have one for the // resume argument, and ordering/equality relations have one for the RHS // Some other types like Box and various functions like drop_in_place // have minimum requirements. // FIXME: This still doesn't count, e.g., elided lifetimes and APITs. let mut actual_num = generics.params.len(); if target.is_associated_item() { actual_num += self .parent_item .unwrap() .opt_generics() .map_or(0, |generics| generics.params.len()); } let mut at_least = false; let required = match lang_item.required_generics() { GenericRequirement::Exact(num) if num != actual_num => Some(num), GenericRequirement::Minimum(num) if actual_num < num => { at_least = true; Some(num) } // If the number matches, or there is no requirement, handle it normally _ => None, }; if let Some(num) = required { // We are issuing E0718 "incorrect target" here, because while the // item kind of the target is correct, the target is still wrong // because of the wrong number of generic arguments. self.tcx.sess.emit_err(IncorrectTarget { span: attr_span, generics_span: generics.span, name: name.as_str(), kind: target.name(), num, actual_num, at_least, }); // return early to not collect the lang item return; } } self.collect_item(lang_item, item_def_id.to_def_id(), Some(item_span)); } } /// Traverses and collects all the lang items in all crates. fn get_lang_items(tcx: TyCtxt<'_>, (): ()) -> LanguageItems { let resolver = tcx.resolver_for_lowering(()).borrow(); let (resolver, krate) = &*resolver; // Initialize the collector. let mut collector = LanguageItemCollector::new(tcx, resolver); // Collect lang items in other crates. for &cnum in tcx.crates(()).iter() { for &(def_id, lang_item) in tcx.defined_lang_items(cnum).iter() { collector.collect_item(lang_item, def_id, None); } } // Collect lang items local to this crate. visit::Visitor::visit_crate(&mut collector, krate); // Find all required but not-yet-defined lang items. weak_lang_items::check_crate(tcx, &mut collector.items, krate); // Return all the lang items that were found. collector.items } impl<'ast, 'tcx> visit::Visitor<'ast> for LanguageItemCollector<'ast, 'tcx> { fn visit_item(&mut self, i: &'ast ast::Item) { let target = match &i.kind { ast::ItemKind::ExternCrate(_) => Target::ExternCrate, ast::ItemKind::Use(_) => Target::Use, ast::ItemKind::Static(_) => Target::Static, ast::ItemKind::Const(_) => Target::Const, ast::ItemKind::Fn(_) => Target::Fn, ast::ItemKind::Mod(_, _) => Target::Mod, ast::ItemKind::ForeignMod(_) => Target::ForeignFn, ast::ItemKind::GlobalAsm(_) => Target::GlobalAsm, ast::ItemKind::TyAlias(_) => Target::TyAlias, ast::ItemKind::Enum(_, _) => Target::Enum, ast::ItemKind::Struct(_, _) => Target::Struct, ast::ItemKind::Union(_, _) => Target::Union, ast::ItemKind::Trait(_) => Target::Trait, ast::ItemKind::TraitAlias(_, _) => Target::TraitAlias, ast::ItemKind::Impl(_) => Target::Impl, ast::ItemKind::MacroDef(_) => Target::MacroDef, ast::ItemKind::MacCall(_) => unreachable!("macros should have been expanded"), }; self.check_for_lang( target, self.resolver.node_id_to_def_id[&i.id], &i.attrs, i.span, i.opt_generics(), ); let parent_item = self.parent_item.replace(i); visit::walk_item(self, i); self.parent_item = parent_item; } fn visit_enum_def(&mut self, enum_definition: &'ast ast::EnumDef) { for variant in &enum_definition.variants { self.check_for_lang( Target::Variant, self.resolver.node_id_to_def_id[&variant.id], &variant.attrs, variant.span, None, ); } visit::walk_enum_def(self, enum_definition); } fn visit_assoc_item(&mut self, i: &'ast ast::AssocItem, ctxt: visit::AssocCtxt) { let (target, generics) = match &i.kind { ast::AssocItemKind::Fn(fun) => ( match &self.parent_item.unwrap().kind { ast::ItemKind::Impl(i) => { if i.of_trait.is_some() { Target::Method(MethodKind::Trait { body: fun.body.is_some() }) } else { Target::Method(MethodKind::Inherent) } } ast::ItemKind::Trait(_) => { Target::Method(MethodKind::Trait { body: fun.body.is_some() }) } _ => unreachable!(), }, &fun.generics, ), ast::AssocItemKind::Const(ct) => (Target::AssocConst, &ct.generics), ast::AssocItemKind::Type(ty) => (Target::AssocTy, &ty.generics), ast::AssocItemKind::MacCall(_) => unreachable!("macros should have been expanded"), }; self.check_for_lang( target, self.resolver.node_id_to_def_id[&i.id], &i.attrs, i.span, Some(generics), ); visit::walk_assoc_item(self, i, ctxt); } } pub fn provide(providers: &mut Providers) { providers.get_lang_items = get_lang_items; }