use rustc_ast::expand::StrippedCfgItem; use rustc_ast::ptr::P; use rustc_ast::visit::{self, Visitor}; use rustc_ast::{self as ast, Crate, ItemKind, ModKind, NodeId, Path, CRATE_NODE_ID}; use rustc_ast::{MetaItemKind, NestedMetaItem}; use rustc_ast_pretty::pprust; use rustc_data_structures::fx::FxHashSet; use rustc_errors::{pluralize, report_ambiguity_error, struct_span_err, SuggestionStyle}; use rustc_errors::{Applicability, Diagnostic, DiagnosticBuilder, ErrorGuaranteed, MultiSpan}; use rustc_feature::BUILTIN_ATTRIBUTES; use rustc_hir::def::Namespace::{self, *}; use rustc_hir::def::{self, CtorKind, CtorOf, DefKind, NonMacroAttrKind, PerNS}; use rustc_hir::def_id::{DefId, CRATE_DEF_ID}; use rustc_hir::PrimTy; use rustc_middle::bug; use rustc_middle::ty::TyCtxt; use rustc_session::lint::builtin::ABSOLUTE_PATHS_NOT_STARTING_WITH_CRATE; use rustc_session::lint::builtin::AMBIGUOUS_GLOB_IMPORTS; use rustc_session::lint::builtin::MACRO_EXPANDED_MACRO_EXPORTS_ACCESSED_BY_ABSOLUTE_PATHS; use rustc_session::lint::{AmbiguityErrorDiag, BuiltinLintDiagnostics}; use rustc_session::Session; use rustc_span::edit_distance::find_best_match_for_name; use rustc_span::edition::Edition; use rustc_span::hygiene::MacroKind; use rustc_span::source_map::SourceMap; use rustc_span::symbol::{kw, sym, Ident, Symbol}; use rustc_span::{BytePos, Span, SyntaxContext}; use thin_vec::ThinVec; use crate::errors::{ AddedMacroUse, ChangeImportBinding, ChangeImportBindingSuggestion, ConsiderAddingADerive, ExplicitUnsafeTraits, }; use crate::imports::{Import, ImportKind}; use crate::late::{PatternSource, Rib}; use crate::path_names_to_string; use crate::{errors as errs, BindingKey}; use crate::{AmbiguityError, AmbiguityErrorMisc, AmbiguityKind, BindingError, Finalize}; use crate::{HasGenericParams, MacroRulesScope, Module, ModuleKind, ModuleOrUniformRoot}; use crate::{LexicalScopeBinding, NameBinding, NameBindingKind, PrivacyError, VisResolutionError}; use crate::{ParentScope, PathResult, ResolutionError, Resolver, Scope, ScopeSet}; use crate::{Segment, UseError}; #[cfg(test)] mod tests; type Res = def::Res; /// A vector of spans and replacements, a message and applicability. pub(crate) type Suggestion = (Vec<(Span, String)>, String, Applicability); /// Potential candidate for an undeclared or out-of-scope label - contains the ident of a /// similarly named label and whether or not it is reachable. pub(crate) type LabelSuggestion = (Ident, bool); #[derive(Debug)] pub(crate) enum SuggestionTarget { /// The target has a similar name as the name used by the programmer (probably a typo) SimilarlyNamed, /// The target is the only valid item that can be used in the corresponding context SingleItem, } #[derive(Debug)] pub(crate) struct TypoSuggestion { pub candidate: Symbol, /// The source location where the name is defined; None if the name is not defined /// in source e.g. primitives pub span: Option, pub res: Res, pub target: SuggestionTarget, } impl TypoSuggestion { pub(crate) fn typo_from_ident(ident: Ident, res: Res) -> TypoSuggestion { Self { candidate: ident.name, span: Some(ident.span), res, target: SuggestionTarget::SimilarlyNamed, } } pub(crate) fn typo_from_name(candidate: Symbol, res: Res) -> TypoSuggestion { Self { candidate, span: None, res, target: SuggestionTarget::SimilarlyNamed } } pub(crate) fn single_item_from_ident(ident: Ident, res: Res) -> TypoSuggestion { Self { candidate: ident.name, span: Some(ident.span), res, target: SuggestionTarget::SingleItem, } } } /// A free importable items suggested in case of resolution failure. #[derive(Debug, Clone)] pub(crate) struct ImportSuggestion { pub did: Option, pub descr: &'static str, pub path: Path, pub accessible: bool, pub via_import: bool, /// An extra note that should be issued if this item is suggested pub note: Option, } /// Adjust the impl span so that just the `impl` keyword is taken by removing /// everything after `<` (`"impl Iterator for A {}" -> "impl"`) and /// everything after the first whitespace (`"impl Iterator for A" -> "impl"`). /// /// *Attention*: the method used is very fragile since it essentially duplicates the work of the /// parser. If you need to use this function or something similar, please consider updating the /// `source_map` functions and this function to something more robust. fn reduce_impl_span_to_impl_keyword(sm: &SourceMap, impl_span: Span) -> Span { let impl_span = sm.span_until_char(impl_span, '<'); sm.span_until_whitespace(impl_span) } impl<'a, 'tcx> Resolver<'a, 'tcx> { pub(crate) fn report_errors(&mut self, krate: &Crate) { self.report_with_use_injections(krate); for &(span_use, span_def) in &self.macro_expanded_macro_export_errors { let msg = "macro-expanded `macro_export` macros from the current crate \ cannot be referred to by absolute paths"; self.lint_buffer.buffer_lint_with_diagnostic( MACRO_EXPANDED_MACRO_EXPORTS_ACCESSED_BY_ABSOLUTE_PATHS, CRATE_NODE_ID, span_use, msg, BuiltinLintDiagnostics::MacroExpandedMacroExportsAccessedByAbsolutePaths(span_def), ); } for ambiguity_error in &self.ambiguity_errors { let diag = self.ambiguity_diagnostics(ambiguity_error); if ambiguity_error.warning { let NameBindingKind::Import { import, .. } = ambiguity_error.b1.0.kind else { unreachable!() }; self.lint_buffer.buffer_lint_with_diagnostic( AMBIGUOUS_GLOB_IMPORTS, import.root_id, ambiguity_error.ident.span, diag.msg.to_string(), BuiltinLintDiagnostics::AmbiguousGlobImports { diag }, ); } else { let mut err = struct_span_err!(self.tcx.sess, diag.span, E0659, "{}", &diag.msg); report_ambiguity_error(&mut err, diag); err.emit(); } } let mut reported_spans = FxHashSet::default(); for error in std::mem::take(&mut self.privacy_errors) { if reported_spans.insert(error.dedup_span) { self.report_privacy_error(&error); } } } fn report_with_use_injections(&mut self, krate: &Crate) { for UseError { mut err, candidates, def_id, instead, suggestion, path, is_call } in self.use_injections.drain(..) { let (span, found_use) = if let Some(def_id) = def_id.as_local() { UsePlacementFinder::check(krate, self.def_id_to_node_id[def_id]) } else { (None, FoundUse::No) }; if !candidates.is_empty() { show_candidates( self.tcx, &mut err, span, &candidates, if instead { Instead::Yes } else { Instead::No }, found_use, DiagnosticMode::Normal, path, "", ); err.emit(); } else if let Some((span, msg, sugg, appl)) = suggestion { err.span_suggestion_verbose(span, msg, sugg, appl); err.emit(); } else if let [segment] = path.as_slice() && is_call { err.stash(segment.ident.span, rustc_errors::StashKey::CallIntoMethod); } else { err.emit(); } } } pub(crate) fn report_conflict( &mut self, parent: Module<'_>, ident: Ident, ns: Namespace, new_binding: NameBinding<'a>, old_binding: NameBinding<'a>, ) { // Error on the second of two conflicting names if old_binding.span.lo() > new_binding.span.lo() { return self.report_conflict(parent, ident, ns, old_binding, new_binding); } let container = match parent.kind { // Avoid using TyCtxt::def_kind_descr in the resolver, because it // indirectly *calls* the resolver, and would cause a query cycle. ModuleKind::Def(kind, _, _) => kind.descr(parent.def_id()), ModuleKind::Block => "block", }; let old_noun = match old_binding.is_import_user_facing() { true => "import", false => "definition", }; let new_participle = match new_binding.is_import_user_facing() { true => "imported", false => "defined", }; let (name, span) = (ident.name, self.tcx.sess.source_map().guess_head_span(new_binding.span)); if let Some(s) = self.name_already_seen.get(&name) { if s == &span { return; } } let old_kind = match (ns, old_binding.module()) { (ValueNS, _) => "value", (MacroNS, _) => "macro", (TypeNS, _) if old_binding.is_extern_crate() => "extern crate", (TypeNS, Some(module)) if module.is_normal() => "module", (TypeNS, Some(module)) if module.is_trait() => "trait", (TypeNS, _) => "type", }; let msg = format!("the name `{name}` is defined multiple times"); let mut err = match (old_binding.is_extern_crate(), new_binding.is_extern_crate()) { (true, true) => struct_span_err!(self.tcx.sess, span, E0259, "{}", msg), (true, _) | (_, true) => match new_binding.is_import() && old_binding.is_import() { true => struct_span_err!(self.tcx.sess, span, E0254, "{}", msg), false => struct_span_err!(self.tcx.sess, span, E0260, "{}", msg), }, _ => match (old_binding.is_import_user_facing(), new_binding.is_import_user_facing()) { (false, false) => struct_span_err!(self.tcx.sess, span, E0428, "{}", msg), (true, true) => struct_span_err!(self.tcx.sess, span, E0252, "{}", msg), _ => struct_span_err!(self.tcx.sess, span, E0255, "{}", msg), }, }; err.note(format!( "`{}` must be defined only once in the {} namespace of this {}", name, ns.descr(), container )); err.span_label(span, format!("`{name}` re{new_participle} here")); if !old_binding.span.is_dummy() && old_binding.span != span { err.span_label( self.tcx.sess.source_map().guess_head_span(old_binding.span), format!("previous {old_noun} of the {old_kind} `{name}` here"), ); } // See https://github.com/rust-lang/rust/issues/32354 use NameBindingKind::Import; let can_suggest = |binding: NameBinding<'_>, import: self::Import<'_>| { !binding.span.is_dummy() && !matches!(import.kind, ImportKind::MacroUse | ImportKind::MacroExport) }; let import = match (&new_binding.kind, &old_binding.kind) { // If there are two imports where one or both have attributes then prefer removing the // import without attributes. (Import { import: new, .. }, Import { import: old, .. }) if { (new.has_attributes || old.has_attributes) && can_suggest(old_binding, *old) && can_suggest(new_binding, *new) } => { if old.has_attributes { Some((*new, new_binding.span, true)) } else { Some((*old, old_binding.span, true)) } } // Otherwise prioritize the new binding. (Import { import, .. }, other) if can_suggest(new_binding, *import) => { Some((*import, new_binding.span, other.is_import())) } (other, Import { import, .. }) if can_suggest(old_binding, *import) => { Some((*import, old_binding.span, other.is_import())) } _ => None, }; // Check if the target of the use for both bindings is the same. let duplicate = new_binding.res().opt_def_id() == old_binding.res().opt_def_id(); let has_dummy_span = new_binding.span.is_dummy() || old_binding.span.is_dummy(); let from_item = self.extern_prelude.get(&ident).map_or(true, |entry| entry.introduced_by_item); // Only suggest removing an import if both bindings are to the same def, if both spans // aren't dummy spans. Further, if both bindings are imports, then the ident must have // been introduced by an item. let should_remove_import = duplicate && !has_dummy_span && ((new_binding.is_extern_crate() || old_binding.is_extern_crate()) || from_item); match import { Some((import, span, true)) if should_remove_import && import.is_nested() => { self.add_suggestion_for_duplicate_nested_use(&mut err, import, span) } Some((import, _, true)) if should_remove_import && !import.is_glob() => { // Simple case - remove the entire import. Due to the above match arm, this can // only be a single use so just remove it entirely. err.tool_only_span_suggestion( import.use_span_with_attributes, "remove unnecessary import", "", Applicability::MaybeIncorrect, ); } Some((import, span, _)) => { self.add_suggestion_for_rename_of_use(&mut err, name, import, span) } _ => {} } err.emit(); self.name_already_seen.insert(name, span); } /// This function adds a suggestion to change the binding name of a new import that conflicts /// with an existing import. /// /// ```text,ignore (diagnostic) /// help: you can use `as` to change the binding name of the import /// | /// LL | use foo::bar as other_bar; /// | ^^^^^^^^^^^^^^^^^^^^^ /// ``` fn add_suggestion_for_rename_of_use( &self, err: &mut Diagnostic, name: Symbol, import: Import<'_>, binding_span: Span, ) { let suggested_name = if name.as_str().chars().next().unwrap().is_uppercase() { format!("Other{name}") } else { format!("other_{name}") }; let mut suggestion = None; match import.kind { ImportKind::Single { type_ns_only: true, .. } => { suggestion = Some(format!("self as {suggested_name}")) } ImportKind::Single { source, .. } => { if let Some(pos) = source.span.hi().0.checked_sub(binding_span.lo().0).map(|pos| pos as usize) { if let Ok(snippet) = self.tcx.sess.source_map().span_to_snippet(binding_span) { if pos <= snippet.len() { suggestion = Some(format!( "{} as {}{}", &snippet[..pos], suggested_name, if snippet.ends_with(';') { ";" } else { "" } )) } } } } ImportKind::ExternCrate { source, target, .. } => { suggestion = Some(format!( "extern crate {} as {};", source.unwrap_or(target.name), suggested_name, )) } _ => unreachable!(), } if let Some(suggestion) = suggestion { err.subdiagnostic(ChangeImportBindingSuggestion { span: binding_span, suggestion }); } else { err.subdiagnostic(ChangeImportBinding { span: binding_span }); } } /// This function adds a suggestion to remove an unnecessary binding from an import that is /// nested. In the following example, this function will be invoked to remove the `a` binding /// in the second use statement: /// /// ```ignore (diagnostic) /// use issue_52891::a; /// use issue_52891::{d, a, e}; /// ``` /// /// The following suggestion will be added: /// /// ```ignore (diagnostic) /// use issue_52891::{d, a, e}; /// ^-- help: remove unnecessary import /// ``` /// /// If the nested use contains only one import then the suggestion will remove the entire /// line. /// /// It is expected that the provided import is nested - this isn't checked by the /// function. If this invariant is not upheld, this function's behaviour will be unexpected /// as characters expected by span manipulations won't be present. fn add_suggestion_for_duplicate_nested_use( &self, err: &mut Diagnostic, import: Import<'_>, binding_span: Span, ) { assert!(import.is_nested()); let message = "remove unnecessary import"; // Two examples will be used to illustrate the span manipulations we're doing: // // - Given `use issue_52891::{d, a, e};` where `a` is a duplicate then `binding_span` is // `a` and `import.use_span` is `issue_52891::{d, a, e};`. // - Given `use issue_52891::{d, e, a};` where `a` is a duplicate then `binding_span` is // `a` and `import.use_span` is `issue_52891::{d, e, a};`. let (found_closing_brace, span) = find_span_of_binding_until_next_binding(self.tcx.sess, binding_span, import.use_span); // If there was a closing brace then identify the span to remove any trailing commas from // previous imports. if found_closing_brace { if let Some(span) = extend_span_to_previous_binding(self.tcx.sess, span) { err.tool_only_span_suggestion(span, message, "", Applicability::MaybeIncorrect); } else { // Remove the entire line if we cannot extend the span back, this indicates an // `issue_52891::{self}` case. err.span_suggestion( import.use_span_with_attributes, message, "", Applicability::MaybeIncorrect, ); } return; } err.span_suggestion(span, message, "", Applicability::MachineApplicable); } pub(crate) fn lint_if_path_starts_with_module( &mut self, finalize: Option, path: &[Segment], second_binding: Option>, ) { let Some(Finalize { node_id, root_span, .. }) = finalize else { return; }; let first_name = match path.get(0) { // In the 2018 edition this lint is a hard error, so nothing to do Some(seg) if seg.ident.span.is_rust_2015() && self.tcx.sess.is_rust_2015() => { seg.ident.name } _ => return, }; // We're only interested in `use` paths which should start with // `{{root}}` currently. if first_name != kw::PathRoot { return; } match path.get(1) { // If this import looks like `crate::...` it's already good Some(Segment { ident, .. }) if ident.name == kw::Crate => return, // Otherwise go below to see if it's an extern crate Some(_) => {} // If the path has length one (and it's `PathRoot` most likely) // then we don't know whether we're gonna be importing a crate or an // item in our crate. Defer this lint to elsewhere None => return, } // If the first element of our path was actually resolved to an // `ExternCrate` (also used for `crate::...`) then no need to issue a // warning, this looks all good! if let Some(binding) = second_binding { if let NameBindingKind::Import { import, .. } = binding.kind { // Careful: we still want to rewrite paths from renamed extern crates. if let ImportKind::ExternCrate { source: None, .. } = import.kind { return; } } } let diag = BuiltinLintDiagnostics::AbsPathWithModule(root_span); self.lint_buffer.buffer_lint_with_diagnostic( ABSOLUTE_PATHS_NOT_STARTING_WITH_CRATE, node_id, root_span, "absolute paths must start with `self`, `super`, \ `crate`, or an external crate name in the 2018 edition", diag, ); } pub(crate) fn add_module_candidates( &mut self, module: Module<'a>, names: &mut Vec, filter_fn: &impl Fn(Res) -> bool, ctxt: Option, ) { for (key, resolution) in self.resolutions(module).borrow().iter() { if let Some(binding) = resolution.borrow().binding { let res = binding.res(); if filter_fn(res) && ctxt.map_or(true, |ctxt| ctxt == key.ident.span.ctxt()) { names.push(TypoSuggestion::typo_from_ident(key.ident, res)); } } } } /// Combines an error with provided span and emits it. /// /// This takes the error provided, combines it with the span and any additional spans inside the /// error and emits it. pub(crate) fn report_error(&mut self, span: Span, resolution_error: ResolutionError<'a>) { self.into_struct_error(span, resolution_error).emit(); } pub(crate) fn into_struct_error( &mut self, span: Span, resolution_error: ResolutionError<'a>, ) -> DiagnosticBuilder<'_, ErrorGuaranteed> { match resolution_error { ResolutionError::GenericParamsFromOuterFunction(outer_res, has_generic_params) => { let mut err = struct_span_err!( self.tcx.sess, span, E0401, "can't use generic parameters from outer function", ); err.span_label(span, "use of generic parameter from outer function"); let sm = self.tcx.sess.source_map(); let def_id = match outer_res { Res::SelfTyParam { .. } => { err.span_label(span, "can't use `Self` here"); return err; } Res::SelfTyAlias { alias_to: def_id, .. } => { err.span_label( reduce_impl_span_to_impl_keyword(sm, self.def_span(def_id)), "`Self` type implicitly declared here, by this `impl`", ); err.span_label(span, "use a type here instead"); return err; } Res::Def(DefKind::TyParam, def_id) => { err.span_label(self.def_span(def_id), "type parameter from outer function"); def_id } Res::Def(DefKind::ConstParam, def_id) => { err.span_label( self.def_span(def_id), "const parameter from outer function", ); def_id } _ => { bug!( "GenericParamsFromOuterFunction should only be used with \ Res::SelfTyParam, Res::SelfTyAlias, DefKind::TyParam or \ DefKind::ConstParam" ); } }; if let HasGenericParams::Yes(span) = has_generic_params { // Try to retrieve the span of the function signature and generate a new // message with a local type or const parameter. let sugg_msg = "try using a local generic parameter instead"; let name = self.tcx.item_name(def_id); let (span, snippet) = if span.is_empty() { let snippet = format!("<{name}>"); (span, snippet) } else { let span = sm.span_through_char(span, '<').shrink_to_hi(); let snippet = format!("{name}, "); (span, snippet) }; // Suggest the modification to the user err.span_suggestion(span, sugg_msg, snippet, Applicability::MaybeIncorrect); } err } ResolutionError::NameAlreadyUsedInParameterList(name, first_use_span) => self .tcx .sess .create_err(errs::NameAlreadyUsedInParameterList { span, first_use_span, name }), ResolutionError::MethodNotMemberOfTrait(method, trait_, candidate) => { self.tcx.sess.create_err(errs::MethodNotMemberOfTrait { span, method, trait_, sub: candidate.map(|c| errs::AssociatedFnWithSimilarNameExists { span: method.span, candidate: c, }), }) } ResolutionError::TypeNotMemberOfTrait(type_, trait_, candidate) => { self.tcx.sess.create_err(errs::TypeNotMemberOfTrait { span, type_, trait_, sub: candidate.map(|c| errs::AssociatedTypeWithSimilarNameExists { span: type_.span, candidate: c, }), }) } ResolutionError::ConstNotMemberOfTrait(const_, trait_, candidate) => { self.tcx.sess.create_err(errs::ConstNotMemberOfTrait { span, const_, trait_, sub: candidate.map(|c| errs::AssociatedConstWithSimilarNameExists { span: const_.span, candidate: c, }), }) } ResolutionError::VariableNotBoundInPattern(binding_error, parent_scope) => { let BindingError { name, target, origin, could_be_path } = binding_error; let target_sp = target.iter().copied().collect::>(); let origin_sp = origin.iter().copied().collect::>(); let msp = MultiSpan::from_spans(target_sp.clone()); let mut err = struct_span_err!( self.tcx.sess, msp, E0408, "variable `{}` is not bound in all patterns", name, ); for sp in target_sp { err.span_label(sp, format!("pattern doesn't bind `{name}`")); } for sp in origin_sp { err.span_label(sp, "variable not in all patterns"); } if could_be_path { let import_suggestions = self.lookup_import_candidates( Ident::with_dummy_span(name), Namespace::ValueNS, &parent_scope, &|res: Res| { matches!( res, Res::Def( DefKind::Ctor(CtorOf::Variant, CtorKind::Const) | DefKind::Ctor(CtorOf::Struct, CtorKind::Const) | DefKind::Const | DefKind::AssocConst, _, ) ) }, ); if import_suggestions.is_empty() { let help_msg = format!( "if you meant to match on a variant or a `const` item, consider \ making the path in the pattern qualified: `path::to::ModOrType::{name}`", ); err.span_help(span, help_msg); } show_candidates( self.tcx, &mut err, Some(span), &import_suggestions, Instead::No, FoundUse::Yes, DiagnosticMode::Pattern, vec![], "", ); } err } ResolutionError::VariableBoundWithDifferentMode(variable_name, first_binding_span) => { self.tcx.sess.create_err(errs::VariableBoundWithDifferentMode { span, first_binding_span, variable_name, }) } ResolutionError::IdentifierBoundMoreThanOnceInParameterList(identifier) => self .tcx .sess .create_err(errs::IdentifierBoundMoreThanOnceInParameterList { span, identifier }), ResolutionError::IdentifierBoundMoreThanOnceInSamePattern(identifier) => self .tcx .sess .create_err(errs::IdentifierBoundMoreThanOnceInSamePattern { span, identifier }), ResolutionError::UndeclaredLabel { name, suggestion } => { let ((sub_reachable, sub_reachable_suggestion), sub_unreachable) = match suggestion { // A reachable label with a similar name exists. Some((ident, true)) => ( ( Some(errs::LabelWithSimilarNameReachable(ident.span)), Some(errs::TryUsingSimilarlyNamedLabel { span, ident_name: ident.name, }), ), None, ), // An unreachable label with a similar name exists. Some((ident, false)) => ( (None, None), Some(errs::UnreachableLabelWithSimilarNameExists { ident_span: ident.span, }), ), // No similarly-named labels exist. None => ((None, None), None), }; self.tcx.sess.create_err(errs::UndeclaredLabel { span, name, sub_reachable, sub_reachable_suggestion, sub_unreachable, }) } ResolutionError::SelfImportsOnlyAllowedWithin { root, span_with_rename } => { // None of the suggestions below would help with a case like `use self`. let (suggestion, mpart_suggestion) = if root { (None, None) } else { // use foo::bar::self -> foo::bar // use foo::bar::self as abc -> foo::bar as abc let suggestion = errs::SelfImportsOnlyAllowedWithinSuggestion { span }; // use foo::bar::self -> foo::bar::{self} // use foo::bar::self as abc -> foo::bar::{self as abc} let mpart_suggestion = errs::SelfImportsOnlyAllowedWithinMultipartSuggestion { multipart_start: span_with_rename.shrink_to_lo(), multipart_end: span_with_rename.shrink_to_hi(), }; (Some(suggestion), Some(mpart_suggestion)) }; self.tcx.sess.create_err(errs::SelfImportsOnlyAllowedWithin { span, suggestion, mpart_suggestion, }) } ResolutionError::SelfImportCanOnlyAppearOnceInTheList => { self.tcx.sess.create_err(errs::SelfImportCanOnlyAppearOnceInTheList { span }) } ResolutionError::SelfImportOnlyInImportListWithNonEmptyPrefix => self .tcx .sess .create_err(errs::SelfImportOnlyInImportListWithNonEmptyPrefix { span }), ResolutionError::FailedToResolve { last_segment, label, suggestion, module } => { let mut err = struct_span_err!(self.tcx.sess, span, E0433, "failed to resolve: {}", &label); err.span_label(span, label); if let Some((suggestions, msg, applicability)) = suggestion { if suggestions.is_empty() { err.help(msg); return err; } err.multipart_suggestion(msg, suggestions, applicability); } if let Some(ModuleOrUniformRoot::Module(module)) = module && let Some(module) = module.opt_def_id() && let Some(last_segment) = last_segment { self.find_cfg_stripped(&mut err, &last_segment, module); } err } ResolutionError::CannotCaptureDynamicEnvironmentInFnItem => { self.tcx.sess.create_err(errs::CannotCaptureDynamicEnvironmentInFnItem { span }) } ResolutionError::AttemptToUseNonConstantValueInConstant(ident, suggestion, current) => { // let foo =... // ^^^ given this Span // ------- get this Span to have an applicable suggestion // edit: // only do this if the const and usage of the non-constant value are on the same line // the further the two are apart, the higher the chance of the suggestion being wrong let sp = self .tcx .sess .source_map() .span_extend_to_prev_str(ident.span, current, true, false); let ((with, with_label), without) = match sp { Some(sp) if !self.tcx.sess.source_map().is_multiline(sp) => { let sp = sp.with_lo(BytePos(sp.lo().0 - (current.len() as u32))); ( (Some(errs::AttemptToUseNonConstantValueInConstantWithSuggestion { span: sp, ident, suggestion, current, }), Some(errs::AttemptToUseNonConstantValueInConstantLabelWithSuggestion {span})), None, ) } _ => ( (None, None), Some(errs::AttemptToUseNonConstantValueInConstantWithoutSuggestion { ident_span: ident.span, suggestion, }), ), }; self.tcx.sess.create_err(errs::AttemptToUseNonConstantValueInConstant { span, with, with_label, without, }) } ResolutionError::BindingShadowsSomethingUnacceptable { shadowing_binding, name, participle, article, shadowed_binding, shadowed_binding_span, } => self.tcx.sess.create_err(errs::BindingShadowsSomethingUnacceptable { span, shadowing_binding, shadowed_binding, article, sub_suggestion: match (shadowing_binding, shadowed_binding) { ( PatternSource::Match, Res::Def(DefKind::Ctor(CtorOf::Variant | CtorOf::Struct, CtorKind::Fn), _), ) => Some(errs::BindingShadowsSomethingUnacceptableSuggestion { span, name }), _ => None, }, shadowed_binding_span, participle, name, }), ResolutionError::ForwardDeclaredGenericParam => { self.tcx.sess.create_err(errs::ForwardDeclaredGenericParam { span }) } ResolutionError::ParamInTyOfConstParam { name, param_kind: is_type } => self .tcx .sess .create_err(errs::ParamInTyOfConstParam { span, name, param_kind: is_type }), ResolutionError::ParamInNonTrivialAnonConst { name, param_kind: is_type } => { self.tcx.sess.create_err(errs::ParamInNonTrivialAnonConst { span, name, param_kind: is_type, help: self .tcx .sess .is_nightly_build() .then_some(errs::ParamInNonTrivialAnonConstHelp), }) } ResolutionError::ParamInEnumDiscriminant { name, param_kind: is_type } => self .tcx .sess .create_err(errs::ParamInEnumDiscriminant { span, name, param_kind: is_type }), ResolutionError::SelfInGenericParamDefault => { self.tcx.sess.create_err(errs::SelfInGenericParamDefault { span }) } ResolutionError::UnreachableLabel { name, definition_span, suggestion } => { let ((sub_suggestion_label, sub_suggestion), sub_unreachable_label) = match suggestion { // A reachable label with a similar name exists. Some((ident, true)) => ( ( Some(errs::UnreachableLabelSubLabel { ident_span: ident.span }), Some(errs::UnreachableLabelSubSuggestion { span, // intentionally taking 'ident.name' instead of 'ident' itself, as this // could be used in suggestion context ident_name: ident.name, }), ), None, ), // An unreachable label with a similar name exists. Some((ident, false)) => ( (None, None), Some(errs::UnreachableLabelSubLabelUnreachable { ident_span: ident.span, }), ), // No similarly-named labels exist. None => ((None, None), None), }; self.tcx.sess.create_err(errs::UnreachableLabel { span, name, definition_span, sub_suggestion, sub_suggestion_label, sub_unreachable_label, }) } ResolutionError::TraitImplMismatch { name, kind, code, trait_item_span, trait_path, } => { let mut err = self.tcx.sess.struct_span_err_with_code( span, format!( "item `{name}` is an associated {kind}, which doesn't match its trait `{trait_path}`", ), code, ); err.span_label(span, "does not match trait"); err.span_label(trait_item_span, "item in trait"); err } ResolutionError::TraitImplDuplicate { name, trait_item_span, old_span } => self .tcx .sess .create_err(errs::TraitImplDuplicate { span, name, trait_item_span, old_span }), ResolutionError::InvalidAsmSym => { self.tcx.sess.create_err(errs::InvalidAsmSym { span }) } ResolutionError::LowercaseSelf => { self.tcx.sess.create_err(errs::LowercaseSelf { span }) } } } pub(crate) fn report_vis_error( &mut self, vis_resolution_error: VisResolutionError<'_>, ) -> ErrorGuaranteed { match vis_resolution_error { VisResolutionError::Relative2018(span, path) => { self.tcx.sess.create_err(errs::Relative2018 { span, path_span: path.span, // intentionally converting to String, as the text would also be used as // in suggestion context path_str: pprust::path_to_string(&path), }) } VisResolutionError::AncestorOnly(span) => { self.tcx.sess.create_err(errs::AncestorOnly(span)) } VisResolutionError::FailedToResolve(span, label, suggestion) => self.into_struct_error( span, ResolutionError::FailedToResolve { last_segment: None, label, suggestion, module: None, }, ), VisResolutionError::ExpectedFound(span, path_str, res) => { self.tcx.sess.create_err(errs::ExpectedFound { span, res, path_str }) } VisResolutionError::Indeterminate(span) => { self.tcx.sess.create_err(errs::Indeterminate(span)) } VisResolutionError::ModuleOnly(span) => { self.tcx.sess.create_err(errs::ModuleOnly(span)) } } .emit() } /// Lookup typo candidate in scope for a macro or import. fn early_lookup_typo_candidate( &mut self, scope_set: ScopeSet<'a>, parent_scope: &ParentScope<'a>, ident: Ident, filter_fn: &impl Fn(Res) -> bool, ) -> Option { let mut suggestions = Vec::new(); let ctxt = ident.span.ctxt(); self.visit_scopes(scope_set, parent_scope, ctxt, |this, scope, use_prelude, _| { match scope { Scope::DeriveHelpers(expn_id) => { let res = Res::NonMacroAttr(NonMacroAttrKind::DeriveHelper); if filter_fn(res) { suggestions.extend( this.helper_attrs .get(&expn_id) .into_iter() .flatten() .map(|ident| TypoSuggestion::typo_from_ident(*ident, res)), ); } } Scope::DeriveHelpersCompat => { let res = Res::NonMacroAttr(NonMacroAttrKind::DeriveHelperCompat); if filter_fn(res) { for derive in parent_scope.derives { let parent_scope = &ParentScope { derives: &[], ..*parent_scope }; if let Ok((Some(ext), _)) = this.resolve_macro_path( derive, Some(MacroKind::Derive), parent_scope, false, false, ) { suggestions.extend( ext.helper_attrs .iter() .map(|name| TypoSuggestion::typo_from_name(*name, res)), ); } } } } Scope::MacroRules(macro_rules_scope) => { if let MacroRulesScope::Binding(macro_rules_binding) = macro_rules_scope.get() { let res = macro_rules_binding.binding.res(); if filter_fn(res) { suggestions.push(TypoSuggestion::typo_from_ident( macro_rules_binding.ident, res, )) } } } Scope::CrateRoot => { let root_ident = Ident::new(kw::PathRoot, ident.span); let root_module = this.resolve_crate_root(root_ident); this.add_module_candidates(root_module, &mut suggestions, filter_fn, None); } Scope::Module(module, _) => { this.add_module_candidates(module, &mut suggestions, filter_fn, None); } Scope::MacroUsePrelude => { suggestions.extend(this.macro_use_prelude.iter().filter_map( |(name, binding)| { let res = binding.res(); filter_fn(res).then_some(TypoSuggestion::typo_from_name(*name, res)) }, )); } Scope::BuiltinAttrs => { let res = Res::NonMacroAttr(NonMacroAttrKind::Builtin(kw::Empty)); if filter_fn(res) { suggestions.extend( BUILTIN_ATTRIBUTES .iter() .map(|attr| TypoSuggestion::typo_from_name(attr.name, res)), ); } } Scope::ExternPrelude => { suggestions.extend(this.extern_prelude.iter().filter_map(|(ident, _)| { let res = Res::Def(DefKind::Mod, CRATE_DEF_ID.to_def_id()); filter_fn(res).then_some(TypoSuggestion::typo_from_ident(*ident, res)) })); } Scope::ToolPrelude => { let res = Res::NonMacroAttr(NonMacroAttrKind::Tool); suggestions.extend( this.registered_tools .iter() .map(|ident| TypoSuggestion::typo_from_ident(*ident, res)), ); } Scope::StdLibPrelude => { if let Some(prelude) = this.prelude { let mut tmp_suggestions = Vec::new(); this.add_module_candidates(prelude, &mut tmp_suggestions, filter_fn, None); suggestions.extend( tmp_suggestions .into_iter() .filter(|s| use_prelude || this.is_builtin_macro(s.res)), ); } } Scope::BuiltinTypes => { suggestions.extend(PrimTy::ALL.iter().filter_map(|prim_ty| { let res = Res::PrimTy(*prim_ty); filter_fn(res) .then_some(TypoSuggestion::typo_from_name(prim_ty.name(), res)) })) } } None::<()> }); // Make sure error reporting is deterministic. suggestions.sort_by(|a, b| a.candidate.as_str().partial_cmp(b.candidate.as_str()).unwrap()); match find_best_match_for_name( &suggestions.iter().map(|suggestion| suggestion.candidate).collect::>(), ident.name, None, ) { Some(found) if found != ident.name => { suggestions.into_iter().find(|suggestion| suggestion.candidate == found) } _ => None, } } fn lookup_import_candidates_from_module( &mut self, lookup_ident: Ident, namespace: Namespace, parent_scope: &ParentScope<'a>, start_module: Module<'a>, crate_name: Ident, filter_fn: FilterFn, ) -> Vec where FilterFn: Fn(Res) -> bool, { let mut candidates = Vec::new(); let mut seen_modules = FxHashSet::default(); let mut worklist = vec![(start_module, ThinVec::::new(), true)]; let mut worklist_via_import = vec![]; while let Some((in_module, path_segments, accessible)) = match worklist.pop() { None => worklist_via_import.pop(), Some(x) => Some(x), } { let in_module_is_extern = !in_module.def_id().is_local(); // We have to visit module children in deterministic order to avoid // instabilities in reported imports (#43552). in_module.for_each_child(self, |this, ident, ns, name_binding| { // avoid non-importable candidates if !name_binding.is_importable() { return; } let child_accessible = accessible && this.is_accessible_from(name_binding.vis, parent_scope.module); // do not venture inside inaccessible items of other crates if in_module_is_extern && !child_accessible { return; } let via_import = name_binding.is_import() && !name_binding.is_extern_crate(); // There is an assumption elsewhere that paths of variants are in the enum's // declaration and not imported. With this assumption, the variant component is // chopped and the rest of the path is assumed to be the enum's own path. For // errors where a variant is used as the type instead of the enum, this causes // funny looking invalid suggestions, i.e `foo` instead of `foo::MyEnum`. if via_import && name_binding.is_possibly_imported_variant() { return; } // #90113: Do not count an inaccessible reexported item as a candidate. if let NameBindingKind::Import { binding, .. } = name_binding.kind { if this.is_accessible_from(binding.vis, parent_scope.module) && !this.is_accessible_from(name_binding.vis, parent_scope.module) { return; } } // collect results based on the filter function // avoid suggesting anything from the same module in which we are resolving // avoid suggesting anything with a hygienic name if ident.name == lookup_ident.name && ns == namespace && in_module != parent_scope.module && !ident.span.normalize_to_macros_2_0().from_expansion() { let res = name_binding.res(); if filter_fn(res) { // create the path let mut segms = path_segments.clone(); if lookup_ident.span.at_least_rust_2018() { // crate-local absolute paths start with `crate::` in edition 2018 // FIXME: may also be stabilized for Rust 2015 (Issues #45477, #44660) segms.insert(0, ast::PathSegment::from_ident(crate_name)); } segms.push(ast::PathSegment::from_ident(ident)); let path = Path { span: name_binding.span, segments: segms, tokens: None }; let did = match res { Res::Def(DefKind::Ctor(..), did) => this.tcx.opt_parent(did), _ => res.opt_def_id(), }; if child_accessible { // Remove invisible match if exists if let Some(idx) = candidates .iter() .position(|v: &ImportSuggestion| v.did == did && !v.accessible) { candidates.remove(idx); } } if candidates.iter().all(|v: &ImportSuggestion| v.did != did) { // See if we're recommending TryFrom, TryInto, or FromIterator and add // a note about editions let note = if let Some(did) = did { let requires_note = !did.is_local() && this.tcx.get_attrs(did, sym::rustc_diagnostic_item).any( |attr| { [sym::TryInto, sym::TryFrom, sym::FromIterator] .map(|x| Some(x)) .contains(&attr.value_str()) }, ); requires_note.then(|| { format!( "'{}' is included in the prelude starting in Edition 2021", path_names_to_string(&path) ) }) } else { None }; candidates.push(ImportSuggestion { did, descr: res.descr(), path, accessible: child_accessible, note, via_import, }); } } } // collect submodules to explore if let Some(module) = name_binding.module() { // form the path let mut path_segments = path_segments.clone(); path_segments.push(ast::PathSegment::from_ident(ident)); let is_extern_crate_that_also_appears_in_prelude = name_binding.is_extern_crate() && lookup_ident.span.at_least_rust_2018(); if !is_extern_crate_that_also_appears_in_prelude { // add the module to the lookup if seen_modules.insert(module.def_id()) { if via_import { &mut worklist_via_import } else { &mut worklist } .push((module, path_segments, child_accessible)); } } } }) } // If only some candidates are accessible, take just them if !candidates.iter().all(|v: &ImportSuggestion| !v.accessible) { candidates.retain(|x| x.accessible) } candidates } /// When name resolution fails, this method can be used to look up candidate /// entities with the expected name. It allows filtering them using the /// supplied predicate (which should be used to only accept the types of /// definitions expected, e.g., traits). The lookup spans across all crates. /// /// N.B., the method does not look into imports, but this is not a problem, /// since we report the definitions (thus, the de-aliased imports). pub(crate) fn lookup_import_candidates( &mut self, lookup_ident: Ident, namespace: Namespace, parent_scope: &ParentScope<'a>, filter_fn: FilterFn, ) -> Vec where FilterFn: Fn(Res) -> bool, { let mut suggestions = self.lookup_import_candidates_from_module( lookup_ident, namespace, parent_scope, self.graph_root, Ident::with_dummy_span(kw::Crate), &filter_fn, ); if lookup_ident.span.at_least_rust_2018() { let extern_prelude_names = self.extern_prelude.clone(); for (ident, _) in extern_prelude_names.into_iter() { if ident.span.from_expansion() { // Idents are adjusted to the root context before being // resolved in the extern prelude, so reporting this to the // user is no help. This skips the injected // `extern crate std` in the 2018 edition, which would // otherwise cause duplicate suggestions. continue; } let crate_id = self.crate_loader(|c| c.maybe_process_path_extern(ident.name)); if let Some(crate_id) = crate_id { let crate_root = self.expect_module(crate_id.as_def_id()); suggestions.extend(self.lookup_import_candidates_from_module( lookup_ident, namespace, parent_scope, crate_root, ident, &filter_fn, )); } } } suggestions } pub(crate) fn unresolved_macro_suggestions( &mut self, err: &mut Diagnostic, macro_kind: MacroKind, parent_scope: &ParentScope<'a>, ident: Ident, krate: &Crate, ) { let is_expected = &|res: Res| res.macro_kind() == Some(macro_kind); let suggestion = self.early_lookup_typo_candidate( ScopeSet::Macro(macro_kind), parent_scope, ident, is_expected, ); self.add_typo_suggestion(err, suggestion, ident.span); let import_suggestions = self.lookup_import_candidates(ident, Namespace::MacroNS, parent_scope, is_expected); let (span, found_use) = match parent_scope.module.nearest_parent_mod().as_local() { Some(def_id) => UsePlacementFinder::check(krate, self.def_id_to_node_id[def_id]), None => (None, FoundUse::No), }; show_candidates( self.tcx, err, span, &import_suggestions, Instead::No, found_use, DiagnosticMode::Normal, vec![], "", ); if macro_kind == MacroKind::Derive && (ident.name == sym::Send || ident.name == sym::Sync) { err.subdiagnostic(ExplicitUnsafeTraits { span: ident.span, ident }); return; } if self.macro_names.contains(&ident.normalize_to_macros_2_0()) { err.subdiagnostic(AddedMacroUse); return; } if ident.name == kw::Default && let ModuleKind::Def(DefKind::Enum, def_id, _) = parent_scope.module.kind { let span = self.def_span(def_id); let source_map = self.tcx.sess.source_map(); let head_span = source_map.guess_head_span(span); err.subdiagnostic(ConsiderAddingADerive { span: head_span.shrink_to_lo(), suggestion: "#[derive(Default)]\n".to_string(), }); } for ns in [Namespace::MacroNS, Namespace::TypeNS, Namespace::ValueNS] { if let Ok(binding) = self.early_resolve_ident_in_lexical_scope( ident, ScopeSet::All(ns), &parent_scope, None, false, None, ) { let desc = match binding.res() { Res::Def(DefKind::Macro(MacroKind::Bang), _) => { "a function-like macro".to_string() } Res::Def(DefKind::Macro(MacroKind::Attr), _) | Res::NonMacroAttr(..) => { format!("an attribute: `#[{ident}]`") } Res::Def(DefKind::Macro(MacroKind::Derive), _) => { format!("a derive macro: `#[derive({ident})]`") } Res::ToolMod => { // Don't confuse the user with tool modules. continue; } Res::Def(DefKind::Trait, _) if macro_kind == MacroKind::Derive => { "only a trait, without a derive macro".to_string() } res => format!( "{} {}, not {} {}", res.article(), res.descr(), macro_kind.article(), macro_kind.descr_expected(), ), }; if let crate::NameBindingKind::Import { import, .. } = binding.kind { if !import.span.is_dummy() { err.span_note( import.span, format!("`{ident}` is imported here, but it is {desc}"), ); // Silence the 'unused import' warning we might get, // since this diagnostic already covers that import. self.record_use(ident, binding, false); return; } } err.note(format!("`{ident}` is in scope, but it is {desc}")); return; } } } pub(crate) fn add_typo_suggestion( &self, err: &mut Diagnostic, suggestion: Option, span: Span, ) -> bool { let suggestion = match suggestion { None => return false, // We shouldn't suggest underscore. Some(suggestion) if suggestion.candidate == kw::Underscore => return false, Some(suggestion) => suggestion, }; if let Some(def_span) = suggestion.res.opt_def_id().map(|def_id| self.def_span(def_id)) { if span.overlaps(def_span) { // Don't suggest typo suggestion for itself like in the following: // error[E0423]: expected function, tuple struct or tuple variant, found struct `X` // --> $DIR/issue-64792-bad-unicode-ctor.rs:3:14 // | // LL | struct X {} // | ----------- `X` defined here // LL | // LL | const Y: X = X("ö"); // | -------------^^^^^^- similarly named constant `Y` defined here // | // help: use struct literal syntax instead // | // LL | const Y: X = X {}; // | ^^^^ // help: a constant with a similar name exists // | // LL | const Y: X = Y("ö"); // | ^ return false; } let prefix = match suggestion.target { SuggestionTarget::SimilarlyNamed => "similarly named ", SuggestionTarget::SingleItem => "", }; err.span_label( self.tcx.sess.source_map().guess_head_span(def_span), format!( "{}{} `{}` defined here", prefix, suggestion.res.descr(), suggestion.candidate, ), ); } let msg = match suggestion.target { SuggestionTarget::SimilarlyNamed => format!( "{} {} with a similar name exists", suggestion.res.article(), suggestion.res.descr() ), SuggestionTarget::SingleItem => { format!("maybe you meant this {}", suggestion.res.descr()) } }; err.span_suggestion(span, msg, suggestion.candidate, Applicability::MaybeIncorrect); true } fn binding_description(&self, b: NameBinding<'_>, ident: Ident, from_prelude: bool) -> String { let res = b.res(); if b.span.is_dummy() || !self.tcx.sess.source_map().is_span_accessible(b.span) { // These already contain the "built-in" prefix or look bad with it. let add_built_in = !matches!(b.res(), Res::NonMacroAttr(..) | Res::PrimTy(..) | Res::ToolMod); let (built_in, from) = if from_prelude { ("", " from prelude") } else if b.is_extern_crate() && !b.is_import() && self.tcx.sess.opts.externs.get(ident.as_str()).is_some() { ("", " passed with `--extern`") } else if add_built_in { (" built-in", "") } else { ("", "") }; let a = if built_in.is_empty() { res.article() } else { "a" }; format!("{a}{built_in} {thing}{from}", thing = res.descr()) } else { let introduced = if b.is_import_user_facing() { "imported" } else { "defined" }; format!("the {thing} {introduced} here", thing = res.descr()) } } fn ambiguity_diagnostics(&self, ambiguity_error: &AmbiguityError<'_>) -> AmbiguityErrorDiag { let AmbiguityError { kind, ident, b1, b2, misc1, misc2, .. } = *ambiguity_error; let (b1, b2, misc1, misc2, swapped) = if b2.span.is_dummy() && !b1.span.is_dummy() { // We have to print the span-less alternative first, otherwise formatting looks bad. (b2, b1, misc2, misc1, true) } else { (b1, b2, misc1, misc2, false) }; let could_refer_to = |b: NameBinding<'_>, misc: AmbiguityErrorMisc, also: &str| { let what = self.binding_description(b, ident, misc == AmbiguityErrorMisc::FromPrelude); let note_msg = format!("`{ident}` could{also} refer to {what}"); let thing = b.res().descr(); let mut help_msgs = Vec::new(); if b.is_glob_import() && (kind == AmbiguityKind::GlobVsGlob || kind == AmbiguityKind::GlobVsExpanded || kind == AmbiguityKind::GlobVsOuter && swapped != also.is_empty()) { help_msgs.push(format!( "consider adding an explicit import of `{ident}` to disambiguate" )) } if b.is_extern_crate() && ident.span.at_least_rust_2018() { help_msgs.push(format!("use `::{ident}` to refer to this {thing} unambiguously")) } match misc { AmbiguityErrorMisc::SuggestCrate => help_msgs .push(format!("use `crate::{ident}` to refer to this {thing} unambiguously")), AmbiguityErrorMisc::SuggestSelf => help_msgs .push(format!("use `self::{ident}` to refer to this {thing} unambiguously")), AmbiguityErrorMisc::FromPrelude | AmbiguityErrorMisc::None => {} } ( b.span, note_msg, help_msgs .iter() .enumerate() .map(|(i, help_msg)| { let or = if i == 0 { "" } else { "or " }; format!("{or}{help_msg}") }) .collect::>(), ) }; let (b1_span, b1_note_msg, b1_help_msgs) = could_refer_to(b1, misc1, ""); let (b2_span, b2_note_msg, b2_help_msgs) = could_refer_to(b2, misc2, " also"); AmbiguityErrorDiag { msg: format!("`{ident}` is ambiguous"), span: ident.span, label_span: ident.span, label_msg: "ambiguous name".to_string(), note_msg: format!("ambiguous because of {}", kind.descr()), b1_span, b1_note_msg, b1_help_msgs, b2_span, b2_note_msg, b2_help_msgs, } } /// If the binding refers to a tuple struct constructor with fields, /// returns the span of its fields. fn ctor_fields_span(&self, binding: NameBinding<'_>) -> Option { if let NameBindingKind::Res(Res::Def( DefKind::Ctor(CtorOf::Struct, CtorKind::Fn), ctor_def_id, )) = binding.kind { let def_id = self.tcx.parent(ctor_def_id); return self .field_def_ids(def_id)? .iter() .map(|&field_id| self.def_span(field_id)) .reduce(Span::to); // None for `struct Foo()` } None } fn report_privacy_error(&mut self, privacy_error: &PrivacyError<'a>) { let PrivacyError { ident, binding, outermost_res, parent_scope, dedup_span } = *privacy_error; let res = binding.res(); let ctor_fields_span = self.ctor_fields_span(binding); let plain_descr = res.descr().to_string(); let nonimport_descr = if ctor_fields_span.is_some() { plain_descr + " constructor" } else { plain_descr }; let import_descr = nonimport_descr.clone() + " import"; let get_descr = |b: NameBinding<'_>| if b.is_import() { &import_descr } else { &nonimport_descr }; // Print the primary message. let descr = get_descr(binding); let mut err = struct_span_err!(self.tcx.sess, ident.span, E0603, "{} `{}` is private", descr, ident); err.span_label(ident.span, format!("private {descr}")); if let Some((this_res, outer_ident)) = outermost_res { let import_suggestions = self.lookup_import_candidates( outer_ident, this_res.ns().unwrap_or(Namespace::TypeNS), &parent_scope, &|res: Res| res == this_res, ); let point_to_def = !show_candidates( self.tcx, &mut err, Some(dedup_span.until(outer_ident.span.shrink_to_hi())), &import_suggestions, Instead::Yes, FoundUse::Yes, DiagnosticMode::Import, vec![], "", ); // If we suggest importing a public re-export, don't point at the definition. if point_to_def && ident.span != outer_ident.span { err.span_label( outer_ident.span, format!("{} `{outer_ident}` is not publicly re-exported", this_res.descr()), ); } } let mut non_exhaustive = None; // If an ADT is foreign and marked as `non_exhaustive`, then that's // probably why we have the privacy error. // Otherwise, point out if the struct has any private fields. if let Some(def_id) = res.opt_def_id() && !def_id.is_local() && let Some(attr) = self.tcx.get_attr(def_id, sym::non_exhaustive) { non_exhaustive = Some(attr.span); } else if let Some(span) = ctor_fields_span { err.span_label(span, "a constructor is private if any of the fields is private"); if let Res::Def(_, d) = res && let Some(fields) = self.field_visibility_spans.get(&d) { err.multipart_suggestion_verbose( format!( "consider making the field{} publicly accessible", pluralize!(fields.len()) ), fields.iter().map(|span| (*span, "pub ".to_string())).collect(), Applicability::MaybeIncorrect, ); } } // Print the whole import chain to make it easier to see what happens. let first_binding = binding; let mut next_binding = Some(binding); let mut next_ident = ident; while let Some(binding) = next_binding { let name = next_ident; next_binding = match binding.kind { _ if res == Res::Err => None, NameBindingKind::Import { binding, import, .. } => match import.kind { _ if binding.span.is_dummy() => None, ImportKind::Single { source, .. } => { next_ident = source; Some(binding) } ImportKind::Glob { .. } | ImportKind::MacroUse | ImportKind::MacroExport => { Some(binding) } ImportKind::ExternCrate { .. } => None, }, _ => None, }; let first = binding == first_binding; let msg = format!( "{and_refers_to}the {item} `{name}`{which} is defined here{dots}", and_refers_to = if first { "" } else { "...and refers to " }, item = get_descr(binding), which = if first { "" } else { " which" }, dots = if next_binding.is_some() { "..." } else { "" }, ); let def_span = self.tcx.sess.source_map().guess_head_span(binding.span); let mut note_span = MultiSpan::from_span(def_span); if !first && binding.vis.is_public() { note_span.push_span_label(def_span, "consider importing it directly"); } // Final step in the import chain, point out if the ADT is `non_exhaustive` // which is probably why this privacy violation occurred. if next_binding.is_none() && let Some(span) = non_exhaustive { note_span.push_span_label( span, "cannot be constructed because it is `#[non_exhaustive]`", ); } err.span_note(note_span, msg); } err.emit(); } pub(crate) fn find_similarly_named_module_or_crate( &mut self, ident: Symbol, current_module: Module<'a>, ) -> Option { let mut candidates = self .extern_prelude .keys() .map(|ident| ident.name) .chain( self.module_map .iter() .filter(|(_, module)| { current_module.is_ancestor_of(**module) && current_module != **module }) .flat_map(|(_, module)| module.kind.name()), ) .filter(|c| !c.to_string().is_empty()) .collect::>(); candidates.sort(); candidates.dedup(); match find_best_match_for_name(&candidates, ident, None) { Some(sugg) if sugg == ident => None, sugg => sugg, } } pub(crate) fn report_path_resolution_error( &mut self, path: &[Segment], opt_ns: Option, // `None` indicates a module path in import parent_scope: &ParentScope<'a>, ribs: Option<&PerNS>>>, ignore_binding: Option>, module: Option>, failed_segment_idx: usize, ident: Ident, ) -> (String, Option) { let is_last = failed_segment_idx == path.len() - 1; let ns = if is_last { opt_ns.unwrap_or(TypeNS) } else { TypeNS }; let module_res = match module { Some(ModuleOrUniformRoot::Module(module)) => module.res(), _ => None, }; if module_res == self.graph_root.res() { let is_mod = |res| matches!(res, Res::Def(DefKind::Mod, _)); let mut candidates = self.lookup_import_candidates(ident, TypeNS, parent_scope, is_mod); candidates .sort_by_cached_key(|c| (c.path.segments.len(), pprust::path_to_string(&c.path))); if let Some(candidate) = candidates.get(0) { ( String::from("unresolved import"), Some(( vec![(ident.span, pprust::path_to_string(&candidate.path))], String::from("a similar path exists"), Applicability::MaybeIncorrect, )), ) } else if self.tcx.sess.is_rust_2015() { ( format!("maybe a missing crate `{ident}`?"), Some(( vec![], format!( "consider adding `extern crate {ident}` to use the `{ident}` crate" ), Applicability::MaybeIncorrect, )), ) } else { (format!("could not find `{ident}` in the crate root"), None) } } else if failed_segment_idx > 0 { let parent = path[failed_segment_idx - 1].ident.name; let parent = match parent { // ::foo is mounted at the crate root for 2015, and is the extern // prelude for 2018+ kw::PathRoot if self.tcx.sess.edition() > Edition::Edition2015 => { "the list of imported crates".to_owned() } kw::PathRoot | kw::Crate => "the crate root".to_owned(), _ => format!("`{parent}`"), }; let mut msg = format!("could not find `{ident}` in {parent}"); if ns == TypeNS || ns == ValueNS { let ns_to_try = if ns == TypeNS { ValueNS } else { TypeNS }; let binding = if let Some(module) = module { self.resolve_ident_in_module( module, ident, ns_to_try, parent_scope, None, ignore_binding, ).ok() } else if let Some(ribs) = ribs && let Some(TypeNS | ValueNS) = opt_ns { match self.resolve_ident_in_lexical_scope( ident, ns_to_try, parent_scope, None, &ribs[ns_to_try], ignore_binding, ) { // we found a locally-imported or available item/module Some(LexicalScopeBinding::Item(binding)) => Some(binding), _ => None, } } else { self.early_resolve_ident_in_lexical_scope( ident, ScopeSet::All(ns_to_try), parent_scope, None, false, ignore_binding, ).ok() }; if let Some(binding) = binding { let mut found = |what| { msg = format!( "expected {}, found {} `{}` in {}", ns.descr(), what, ident, parent ) }; if binding.module().is_some() { found("module") } else { match binding.res() { // Avoid using TyCtxt::def_kind_descr in the resolver, because it // indirectly *calls* the resolver, and would cause a query cycle. Res::Def(kind, id) => found(kind.descr(id)), _ => found(ns_to_try.descr()), } } }; } (msg, None) } else if ident.name == kw::SelfUpper { // As mentioned above, `opt_ns` being `None` indicates a module path in import. // We can use this to improve a confusing error for, e.g. `use Self::Variant` in an // impl if opt_ns.is_none() { ("`Self` cannot be used in imports".to_string(), None) } else { ( "`Self` is only available in impls, traits, and type definitions".to_string(), None, ) } } else if ident.name.as_str().chars().next().is_some_and(|c| c.is_ascii_uppercase()) { // Check whether the name refers to an item in the value namespace. let binding = if let Some(ribs) = ribs { self.resolve_ident_in_lexical_scope( ident, ValueNS, parent_scope, None, &ribs[ValueNS], ignore_binding, ) } else { None }; let match_span = match binding { // Name matches a local variable. For example: // ``` // fn f() { // let Foo: &str = ""; // println!("{}", Foo::Bar); // Name refers to local // // variable `Foo`. // } // ``` Some(LexicalScopeBinding::Res(Res::Local(id))) => { Some(*self.pat_span_map.get(&id).unwrap()) } // Name matches item from a local name binding // created by `use` declaration. For example: // ``` // pub Foo: &str = ""; // // mod submod { // use super::Foo; // println!("{}", Foo::Bar); // Name refers to local // // binding `Foo`. // } // ``` Some(LexicalScopeBinding::Item(name_binding)) => Some(name_binding.span), _ => None, }; let suggestion = match_span.map(|span| { ( vec![(span, String::from(""))], format!("`{ident}` is defined here, but is not a type"), Applicability::MaybeIncorrect, ) }); (format!("use of undeclared type `{ident}`"), suggestion) } else { let mut suggestion = None; if ident.name == sym::alloc { suggestion = Some(( vec![], String::from("add `extern crate alloc` to use the `alloc` crate"), Applicability::MaybeIncorrect, )) } suggestion = suggestion.or_else(|| { self.find_similarly_named_module_or_crate(ident.name, parent_scope.module).map( |sugg| { ( vec![(ident.span, sugg.to_string())], String::from("there is a crate or module with a similar name"), Applicability::MaybeIncorrect, ) }, ) }); (format!("use of undeclared crate or module `{ident}`"), suggestion) } } /// Adds suggestions for a path that cannot be resolved. pub(crate) fn make_path_suggestion( &mut self, span: Span, mut path: Vec, parent_scope: &ParentScope<'a>, ) -> Option<(Vec, Option)> { debug!("make_path_suggestion: span={:?} path={:?}", span, path); match (path.get(0), path.get(1)) { // `{{root}}::ident::...` on both editions. // On 2015 `{{root}}` is usually added implicitly. (Some(fst), Some(snd)) if fst.ident.name == kw::PathRoot && !snd.ident.is_path_segment_keyword() => {} // `ident::...` on 2018. (Some(fst), _) if fst.ident.span.at_least_rust_2018() && !fst.ident.is_path_segment_keyword() => { // Insert a placeholder that's later replaced by `self`/`super`/etc. path.insert(0, Segment::from_ident(Ident::empty())); } _ => return None, } self.make_missing_self_suggestion(path.clone(), parent_scope) .or_else(|| self.make_missing_crate_suggestion(path.clone(), parent_scope)) .or_else(|| self.make_missing_super_suggestion(path.clone(), parent_scope)) .or_else(|| self.make_external_crate_suggestion(path, parent_scope)) } /// Suggest a missing `self::` if that resolves to an correct module. /// /// ```text /// | /// LL | use foo::Bar; /// | ^^^ did you mean `self::foo`? /// ``` fn make_missing_self_suggestion( &mut self, mut path: Vec, parent_scope: &ParentScope<'a>, ) -> Option<(Vec, Option)> { // Replace first ident with `self` and check if that is valid. path[0].ident.name = kw::SelfLower; let result = self.maybe_resolve_path(&path, None, parent_scope); debug!("make_missing_self_suggestion: path={:?} result={:?}", path, result); if let PathResult::Module(..) = result { Some((path, None)) } else { None } } /// Suggests a missing `crate::` if that resolves to an correct module. /// /// ```text /// | /// LL | use foo::Bar; /// | ^^^ did you mean `crate::foo`? /// ``` fn make_missing_crate_suggestion( &mut self, mut path: Vec, parent_scope: &ParentScope<'a>, ) -> Option<(Vec, Option)> { // Replace first ident with `crate` and check if that is valid. path[0].ident.name = kw::Crate; let result = self.maybe_resolve_path(&path, None, parent_scope); debug!("make_missing_crate_suggestion: path={:?} result={:?}", path, result); if let PathResult::Module(..) = result { Some(( path, Some( "`use` statements changed in Rust 2018; read more at \ " .to_string(), ), )) } else { None } } /// Suggests a missing `super::` if that resolves to an correct module. /// /// ```text /// | /// LL | use foo::Bar; /// | ^^^ did you mean `super::foo`? /// ``` fn make_missing_super_suggestion( &mut self, mut path: Vec, parent_scope: &ParentScope<'a>, ) -> Option<(Vec, Option)> { // Replace first ident with `crate` and check if that is valid. path[0].ident.name = kw::Super; let result = self.maybe_resolve_path(&path, None, parent_scope); debug!("make_missing_super_suggestion: path={:?} result={:?}", path, result); if let PathResult::Module(..) = result { Some((path, None)) } else { None } } /// Suggests a missing external crate name if that resolves to an correct module. /// /// ```text /// | /// LL | use foobar::Baz; /// | ^^^^^^ did you mean `baz::foobar`? /// ``` /// /// Used when importing a submodule of an external crate but missing that crate's /// name as the first part of path. fn make_external_crate_suggestion( &mut self, mut path: Vec, parent_scope: &ParentScope<'a>, ) -> Option<(Vec, Option)> { if path[1].ident.span.is_rust_2015() { return None; } // Sort extern crate names in *reverse* order to get // 1) some consistent ordering for emitted diagnostics, and // 2) `std` suggestions before `core` suggestions. let mut extern_crate_names = self.extern_prelude.keys().map(|ident| ident.name).collect::>(); extern_crate_names.sort_by(|a, b| b.as_str().partial_cmp(a.as_str()).unwrap()); for name in extern_crate_names.into_iter() { // Replace first ident with a crate name and check if that is valid. path[0].ident.name = name; let result = self.maybe_resolve_path(&path, None, parent_scope); debug!( "make_external_crate_suggestion: name={:?} path={:?} result={:?}", name, path, result ); if let PathResult::Module(..) = result { return Some((path, None)); } } None } /// Suggests importing a macro from the root of the crate rather than a module within /// the crate. /// /// ```text /// help: a macro with this name exists at the root of the crate /// | /// LL | use issue_59764::makro; /// | ^^^^^^^^^^^^^^^^^^ /// | /// = note: this could be because a macro annotated with `#[macro_export]` will be exported /// at the root of the crate instead of the module where it is defined /// ``` pub(crate) fn check_for_module_export_macro( &mut self, import: Import<'a>, module: ModuleOrUniformRoot<'a>, ident: Ident, ) -> Option<(Option, Option)> { let ModuleOrUniformRoot::Module(mut crate_module) = module else { return None; }; while let Some(parent) = crate_module.parent { crate_module = parent; } if module == ModuleOrUniformRoot::Module(crate_module) { // Don't make a suggestion if the import was already from the root of the crate. return None; } let resolutions = self.resolutions(crate_module).borrow(); let binding_key = BindingKey::new(ident, MacroNS); let resolution = resolutions.get(&binding_key)?; let binding = resolution.borrow().binding()?; if let Res::Def(DefKind::Macro(MacroKind::Bang), _) = binding.res() { let module_name = crate_module.kind.name().unwrap(); let import_snippet = match import.kind { ImportKind::Single { source, target, .. } if source != target => { format!("{source} as {target}") } _ => format!("{ident}"), }; let mut corrections: Vec<(Span, String)> = Vec::new(); if !import.is_nested() { // Assume this is the easy case of `use issue_59764::foo::makro;` and just remove // intermediate segments. corrections.push((import.span, format!("{module_name}::{import_snippet}"))); } else { // Find the binding span (and any trailing commas and spaces). // ie. `use a::b::{c, d, e};` // ^^^ let (found_closing_brace, binding_span) = find_span_of_binding_until_next_binding( self.tcx.sess, import.span, import.use_span, ); debug!( "check_for_module_export_macro: found_closing_brace={:?} binding_span={:?}", found_closing_brace, binding_span ); let mut removal_span = binding_span; if found_closing_brace { // If the binding span ended with a closing brace, as in the below example: // ie. `use a::b::{c, d};` // ^ // Then expand the span of characters to remove to include the previous // binding's trailing comma. // ie. `use a::b::{c, d};` // ^^^ if let Some(previous_span) = extend_span_to_previous_binding(self.tcx.sess, binding_span) { debug!("check_for_module_export_macro: previous_span={:?}", previous_span); removal_span = removal_span.with_lo(previous_span.lo()); } } debug!("check_for_module_export_macro: removal_span={:?}", removal_span); // Remove the `removal_span`. corrections.push((removal_span, "".to_string())); // Find the span after the crate name and if it has nested imports immediately // after the crate name already. // ie. `use a::b::{c, d};` // ^^^^^^^^^ // or `use a::{b, c, d}};` // ^^^^^^^^^^^ let (has_nested, after_crate_name) = find_span_immediately_after_crate_name( self.tcx.sess, module_name, import.use_span, ); debug!( "check_for_module_export_macro: has_nested={:?} after_crate_name={:?}", has_nested, after_crate_name ); let source_map = self.tcx.sess.source_map(); // Make sure this is actually crate-relative. let is_definitely_crate = import .module_path .first() .is_some_and(|f| f.ident.name != kw::SelfLower && f.ident.name != kw::Super); // Add the import to the start, with a `{` if required. let start_point = source_map.start_point(after_crate_name); if is_definitely_crate && let Ok(start_snippet) = source_map.span_to_snippet(start_point) { corrections.push(( start_point, if has_nested { // In this case, `start_snippet` must equal '{'. format!("{start_snippet}{import_snippet}, ") } else { // In this case, add a `{`, then the moved import, then whatever // was there before. format!("{{{import_snippet}, {start_snippet}") }, )); // Add a `};` to the end if nested, matching the `{` added at the start. if !has_nested { corrections.push((source_map.end_point(after_crate_name), "};".to_string())); } } else { // If the root import is module-relative, add the import separately corrections.push(( import.use_span.shrink_to_lo(), format!("use {module_name}::{import_snippet};\n"), )); } } let suggestion = Some(( corrections, String::from("a macro with this name exists at the root of the crate"), Applicability::MaybeIncorrect, )); Some((suggestion, Some("this could be because a macro annotated with `#[macro_export]` will be exported \ at the root of the crate instead of the module where it is defined" .to_string()))) } else { None } } /// Finds a cfg-ed out item inside `module` with the matching name. pub(crate) fn find_cfg_stripped( &mut self, err: &mut Diagnostic, last_segment: &Symbol, module: DefId, ) { let local_items; let symbols = if module.is_local() { local_items = self .stripped_cfg_items .iter() .filter_map(|item| { let parent_module = self.opt_local_def_id(item.parent_module)?.to_def_id(); Some(StrippedCfgItem { parent_module, name: item.name, cfg: item.cfg.clone() }) }) .collect::>(); local_items.as_slice() } else { self.tcx.stripped_cfg_items(module.krate) }; for &StrippedCfgItem { parent_module, name, ref cfg } in symbols { if parent_module != module || name.name != *last_segment { continue; } err.span_note(name.span, "found an item that was configured out"); if let MetaItemKind::List(nested) = &cfg.kind && let NestedMetaItem::MetaItem(meta_item) = &nested[0] && let MetaItemKind::NameValue(feature_name) = &meta_item.kind { err.note(format!("the item is gated behind the `{}` feature", feature_name.symbol)); } } } } /// Given a `binding_span` of a binding within a use statement: /// /// ```ignore (illustrative) /// use foo::{a, b, c}; /// // ^ /// ``` /// /// then return the span until the next binding or the end of the statement: /// /// ```ignore (illustrative) /// use foo::{a, b, c}; /// // ^^^ /// ``` fn find_span_of_binding_until_next_binding( sess: &Session, binding_span: Span, use_span: Span, ) -> (bool, Span) { let source_map = sess.source_map(); // Find the span of everything after the binding. // ie. `a, e};` or `a};` let binding_until_end = binding_span.with_hi(use_span.hi()); // Find everything after the binding but not including the binding. // ie. `, e};` or `};` let after_binding_until_end = binding_until_end.with_lo(binding_span.hi()); // Keep characters in the span until we encounter something that isn't a comma or // whitespace. // ie. `, ` or ``. // // Also note whether a closing brace character was encountered. If there // was, then later go backwards to remove any trailing commas that are left. let mut found_closing_brace = false; let after_binding_until_next_binding = source_map.span_take_while(after_binding_until_end, |&ch| { if ch == '}' { found_closing_brace = true; } ch == ' ' || ch == ',' }); // Combine the two spans. // ie. `a, ` or `a`. // // Removing these would leave `issue_52891::{d, e};` or `issue_52891::{d, e, };` let span = binding_span.with_hi(after_binding_until_next_binding.hi()); (found_closing_brace, span) } /// Given a `binding_span`, return the span through to the comma or opening brace of the previous /// binding. /// /// ```ignore (illustrative) /// use foo::a::{a, b, c}; /// // ^^--- binding span /// // | /// // returned span /// /// use foo::{a, b, c}; /// // --- binding span /// ``` fn extend_span_to_previous_binding(sess: &Session, binding_span: Span) -> Option { let source_map = sess.source_map(); // `prev_source` will contain all of the source that came before the span. // Then split based on a command and take the first (ie. closest to our span) // snippet. In the example, this is a space. let prev_source = source_map.span_to_prev_source(binding_span).ok()?; let prev_comma = prev_source.rsplit(',').collect::>(); let prev_starting_brace = prev_source.rsplit('{').collect::>(); if prev_comma.len() <= 1 || prev_starting_brace.len() <= 1 { return None; } let prev_comma = prev_comma.first().unwrap(); let prev_starting_brace = prev_starting_brace.first().unwrap(); // If the amount of source code before the comma is greater than // the amount of source code before the starting brace then we've only // got one item in the nested item (eg. `issue_52891::{self}`). if prev_comma.len() > prev_starting_brace.len() { return None; } Some(binding_span.with_lo(BytePos( // Take away the number of bytes for the characters we've found and an // extra for the comma. binding_span.lo().0 - (prev_comma.as_bytes().len() as u32) - 1, ))) } /// Given a `use_span` of a binding within a use statement, returns the highlighted span and if /// it is a nested use tree. /// /// ```ignore (illustrative) /// use foo::a::{b, c}; /// // ^^^^^^^^^^ -- false /// /// use foo::{a, b, c}; /// // ^^^^^^^^^^ -- true /// /// use foo::{a, b::{c, d}}; /// // ^^^^^^^^^^^^^^^ -- true /// ``` fn find_span_immediately_after_crate_name( sess: &Session, module_name: Symbol, use_span: Span, ) -> (bool, Span) { debug!( "find_span_immediately_after_crate_name: module_name={:?} use_span={:?}", module_name, use_span ); let source_map = sess.source_map(); // Using `use issue_59764::foo::{baz, makro};` as an example throughout.. let mut num_colons = 0; // Find second colon.. `use issue_59764:` let until_second_colon = source_map.span_take_while(use_span, |c| { if *c == ':' { num_colons += 1; } !matches!(c, ':' if num_colons == 2) }); // Find everything after the second colon.. `foo::{baz, makro};` let from_second_colon = use_span.with_lo(until_second_colon.hi() + BytePos(1)); let mut found_a_non_whitespace_character = false; // Find the first non-whitespace character in `from_second_colon`.. `f` let after_second_colon = source_map.span_take_while(from_second_colon, |c| { if found_a_non_whitespace_character { return false; } if !c.is_whitespace() { found_a_non_whitespace_character = true; } true }); // Find the first `{` in from_second_colon.. `foo::{` let next_left_bracket = source_map.span_through_char(from_second_colon, '{'); (next_left_bracket == after_second_colon, from_second_colon) } /// A suggestion has already been emitted, change the wording slightly to clarify that both are /// independent options. enum Instead { Yes, No, } /// Whether an existing place with an `use` item was found. enum FoundUse { Yes, No, } /// Whether a binding is part of a pattern or a use statement. Used for diagnostics. pub(crate) enum DiagnosticMode { Normal, /// The binding is part of a pattern Pattern, /// The binding is part of a use statement Import, } pub(crate) fn import_candidates( tcx: TyCtxt<'_>, err: &mut Diagnostic, // This is `None` if all placement locations are inside expansions use_placement_span: Option, candidates: &[ImportSuggestion], mode: DiagnosticMode, append: &str, ) { show_candidates( tcx, err, use_placement_span, candidates, Instead::Yes, FoundUse::Yes, mode, vec![], append, ); } /// When an entity with a given name is not available in scope, we search for /// entities with that name in all crates. This method allows outputting the /// results of this search in a programmer-friendly way. If any entities are /// found and suggested, returns `true`, otherwise returns `false`. fn show_candidates( tcx: TyCtxt<'_>, err: &mut Diagnostic, // This is `None` if all placement locations are inside expansions use_placement_span: Option, candidates: &[ImportSuggestion], instead: Instead, found_use: FoundUse, mode: DiagnosticMode, path: Vec, append: &str, ) -> bool { if candidates.is_empty() { return false; } let mut accessible_path_strings: Vec<(String, &str, Option, &Option, bool)> = Vec::new(); let mut inaccessible_path_strings: Vec<(String, &str, Option, &Option, bool)> = Vec::new(); candidates.iter().for_each(|c| { (if c.accessible { &mut accessible_path_strings } else { &mut inaccessible_path_strings }) .push((path_names_to_string(&c.path), c.descr, c.did, &c.note, c.via_import)) }); // we want consistent results across executions, but candidates are produced // by iterating through a hash map, so make sure they are ordered: for path_strings in [&mut accessible_path_strings, &mut inaccessible_path_strings] { path_strings.sort_by(|a, b| a.0.cmp(&b.0)); let core_path_strings = path_strings.extract_if(|p| p.0.starts_with("core::")).collect::>(); path_strings.extend(core_path_strings); path_strings.dedup_by(|a, b| a.0 == b.0); } if !accessible_path_strings.is_empty() { let (determiner, kind, name, through) = if let [(name, descr, _, _, via_import)] = &accessible_path_strings[..] { ( "this", *descr, format!(" `{name}`"), if *via_import { " through its public re-export" } else { "" }, ) } else { ("one of these", "items", String::new(), "") }; let instead = if let Instead::Yes = instead { " instead" } else { "" }; let mut msg = if let DiagnosticMode::Pattern = mode { format!( "if you meant to match on {kind}{instead}{name}, use the full path in the pattern", ) } else { format!("consider importing {determiner} {kind}{through}{instead}") }; for note in accessible_path_strings.iter().flat_map(|cand| cand.3.as_ref()) { err.note(note.clone()); } if let Some(span) = use_placement_span { let (add_use, trailing) = match mode { DiagnosticMode::Pattern => { err.span_suggestions( span, msg, accessible_path_strings.into_iter().map(|a| a.0), Applicability::MaybeIncorrect, ); return true; } DiagnosticMode::Import => ("", ""), DiagnosticMode::Normal => ("use ", ";\n"), }; for candidate in &mut accessible_path_strings { // produce an additional newline to separate the new use statement // from the directly following item. let additional_newline = if let FoundUse::No = found_use && let DiagnosticMode::Normal = mode { "\n" } else { "" }; candidate.0 = format!("{add_use}{}{append}{trailing}{additional_newline}", &candidate.0); } err.span_suggestions_with_style( span, msg, accessible_path_strings.into_iter().map(|a| a.0), Applicability::MaybeIncorrect, SuggestionStyle::ShowAlways, ); if let [first, .., last] = &path[..] { let sp = first.ident.span.until(last.ident.span); if sp.can_be_used_for_suggestions() { err.span_suggestion_verbose( sp, format!("if you import `{}`, refer to it directly", last.ident), "", Applicability::Unspecified, ); } } } else { msg.push(':'); for candidate in accessible_path_strings { msg.push('\n'); msg.push_str(&candidate.0); } err.help(msg); } true } else if !matches!(mode, DiagnosticMode::Import) { assert!(!inaccessible_path_strings.is_empty()); let prefix = if let DiagnosticMode::Pattern = mode { "you might have meant to match on " } else { "" }; if let [(name, descr, def_id, note, _)] = &inaccessible_path_strings[..] { let msg = format!( "{prefix}{descr} `{name}`{} exists but is inaccessible", if let DiagnosticMode::Pattern = mode { ", which" } else { "" } ); if let Some(local_def_id) = def_id.and_then(|did| did.as_local()) { let span = tcx.source_span(local_def_id); let span = tcx.sess.source_map().guess_head_span(span); let mut multi_span = MultiSpan::from_span(span); multi_span.push_span_label(span, "not accessible"); err.span_note(multi_span, msg); } else { err.note(msg); } if let Some(note) = (*note).as_deref() { err.note(note.to_string()); } } else { let (_, descr_first, _, _, _) = &inaccessible_path_strings[0]; let descr = if inaccessible_path_strings .iter() .skip(1) .all(|(_, descr, _, _, _)| descr == descr_first) { descr_first } else { "item" }; let plural_descr = if descr.ends_with('s') { format!("{descr}es") } else { format!("{descr}s") }; let mut msg = format!("{prefix}these {plural_descr} exist but are inaccessible"); let mut has_colon = false; let mut spans = Vec::new(); for (name, _, def_id, _, _) in &inaccessible_path_strings { if let Some(local_def_id) = def_id.and_then(|did| did.as_local()) { let span = tcx.source_span(local_def_id); let span = tcx.sess.source_map().guess_head_span(span); spans.push((name, span)); } else { if !has_colon { msg.push(':'); has_colon = true; } msg.push('\n'); msg.push_str(name); } } let mut multi_span = MultiSpan::from_spans(spans.iter().map(|(_, sp)| *sp).collect()); for (name, span) in spans { multi_span.push_span_label(span, format!("`{name}`: not accessible")); } for note in inaccessible_path_strings.iter().flat_map(|cand| cand.3.as_ref()) { err.note(note.clone()); } err.span_note(multi_span, msg); } true } else { false } } #[derive(Debug)] struct UsePlacementFinder { target_module: NodeId, first_legal_span: Option, first_use_span: Option, } impl UsePlacementFinder { fn check(krate: &Crate, target_module: NodeId) -> (Option, FoundUse) { let mut finder = UsePlacementFinder { target_module, first_legal_span: None, first_use_span: None }; finder.visit_crate(krate); if let Some(use_span) = finder.first_use_span { (Some(use_span), FoundUse::Yes) } else { (finder.first_legal_span, FoundUse::No) } } } impl<'tcx> visit::Visitor<'tcx> for UsePlacementFinder { fn visit_crate(&mut self, c: &Crate) { if self.target_module == CRATE_NODE_ID { let inject = c.spans.inject_use_span; if is_span_suitable_for_use_injection(inject) { self.first_legal_span = Some(inject); } self.first_use_span = search_for_any_use_in_items(&c.items); return; } else { visit::walk_crate(self, c); } } fn visit_item(&mut self, item: &'tcx ast::Item) { if self.target_module == item.id { if let ItemKind::Mod(_, ModKind::Loaded(items, _inline, mod_spans)) = &item.kind { let inject = mod_spans.inject_use_span; if is_span_suitable_for_use_injection(inject) { self.first_legal_span = Some(inject); } self.first_use_span = search_for_any_use_in_items(items); return; } } else { visit::walk_item(self, item); } } } fn search_for_any_use_in_items(items: &[P]) -> Option { for item in items { if let ItemKind::Use(..) = item.kind { if is_span_suitable_for_use_injection(item.span) { return Some(item.span.shrink_to_lo()); } } } return None; } fn is_span_suitable_for_use_injection(s: Span) -> bool { // don't suggest placing a use before the prelude // import or other generated ones !s.from_expansion() } /// Convert the given number into the corresponding ordinal pub(crate) fn ordinalize(v: usize) -> String { let suffix = match ((11..=13).contains(&(v % 100)), v % 10) { (false, 1) => "st", (false, 2) => "nd", (false, 3) => "rd", _ => "th", }; format!("{v}{suffix}") }