//! Validate AST before lowering it to HIR. //! //! This pass intends to check that the constructed AST is *syntactically valid* to allow the rest //! of the compiler to assume that the AST is valid. These checks cannot be performed during parsing //! because attribute macros are allowed to accept certain pieces of invalid syntax such as a //! function without body outside of a trait definition: //! //! ```ignore (illustrative) //! #[my_attribute] //! mod foo { //! fn missing_body(); //! } //! ``` //! //! These checks are run post-expansion, after AST is frozen, to be able to check for erroneous //! constructions produced by proc macros. This pass is only intended for simple checks that do not //! require name resolution or type checking, or other kinds of complex analysis. use std::mem; use std::ops::{Deref, DerefMut}; use itertools::{Either, Itertools}; use rustc_ast::ptr::P; use rustc_ast::visit::{AssocCtxt, BoundKind, FnCtxt, FnKind, Visitor, walk_list}; use rustc_ast::*; use rustc_ast_pretty::pprust::{self, State}; use rustc_data_structures::fx::FxIndexMap; use rustc_errors::DiagCtxtHandle; use rustc_feature::Features; use rustc_parse::validate_attr; use rustc_session::Session; use rustc_session::lint::builtin::{ DEPRECATED_WHERE_CLAUSE_LOCATION, MISSING_ABI, MISSING_UNSAFE_ON_EXTERN, PATTERNS_IN_FNS_WITHOUT_BODY, }; use rustc_session::lint::{BuiltinLintDiag, LintBuffer}; use rustc_span::Span; use rustc_span::symbol::{Ident, kw, sym}; use rustc_target::spec::abi; use thin_vec::thin_vec; use crate::errors::{self, TildeConstReason}; /// Is `self` allowed semantically as the first parameter in an `FnDecl`? enum SelfSemantic { Yes, No, } enum TraitOrTraitImpl { Trait { span: Span, constness: Option }, TraitImpl { constness: Const, polarity: ImplPolarity, trait_ref: Span }, } impl TraitOrTraitImpl { fn constness(&self) -> Option { match self { Self::Trait { constness: Some(span), .. } | Self::TraitImpl { constness: Const::Yes(span), .. } => Some(*span), _ => None, } } } struct AstValidator<'a> { sess: &'a Session, features: &'a Features, /// The span of the `extern` in an `extern { ... }` block, if any. extern_mod: Option, outer_trait_or_trait_impl: Option, has_proc_macro_decls: bool, /// Used to ban nested `impl Trait`, e.g., `impl Into`. /// Nested `impl Trait` _is_ allowed in associated type position, /// e.g., `impl Iterator`. outer_impl_trait: Option, disallow_tilde_const: Option, /// Used to ban explicit safety on foreign items when the extern block is not marked as unsafe. extern_mod_safety: Option, lint_buffer: &'a mut LintBuffer, } impl<'a> AstValidator<'a> { fn with_in_trait_impl( &mut self, trait_: Option<(Const, ImplPolarity, &'a TraitRef)>, f: impl FnOnce(&mut Self), ) { let old = mem::replace( &mut self.outer_trait_or_trait_impl, trait_.map(|(constness, polarity, trait_ref)| TraitOrTraitImpl::TraitImpl { constness, polarity, trait_ref: trait_ref.path.span, }), ); f(self); self.outer_trait_or_trait_impl = old; } fn with_in_trait(&mut self, span: Span, constness: Option, f: impl FnOnce(&mut Self)) { let old = mem::replace( &mut self.outer_trait_or_trait_impl, Some(TraitOrTraitImpl::Trait { span, constness }), ); f(self); self.outer_trait_or_trait_impl = old; } fn with_in_extern_mod(&mut self, extern_mod_safety: Safety, f: impl FnOnce(&mut Self)) { let old = mem::replace(&mut self.extern_mod_safety, Some(extern_mod_safety)); f(self); self.extern_mod_safety = old; } fn with_tilde_const( &mut self, disallowed: Option, f: impl FnOnce(&mut Self), ) { let old = mem::replace(&mut self.disallow_tilde_const, disallowed); f(self); self.disallow_tilde_const = old; } fn check_type_alias_where_clause_location( &mut self, ty_alias: &TyAlias, ) -> Result<(), errors::WhereClauseBeforeTypeAlias> { if ty_alias.ty.is_none() || !ty_alias.where_clauses.before.has_where_token { return Ok(()); } let (before_predicates, after_predicates) = ty_alias.generics.where_clause.predicates.split_at(ty_alias.where_clauses.split); let span = ty_alias.where_clauses.before.span; let sugg = if !before_predicates.is_empty() || !ty_alias.where_clauses.after.has_where_token { let mut state = State::new(); if !ty_alias.where_clauses.after.has_where_token { state.space(); state.word_space("where"); } let mut first = after_predicates.is_empty(); for p in before_predicates { if !first { state.word_space(","); } first = false; state.print_where_predicate(p); } errors::WhereClauseBeforeTypeAliasSugg::Move { left: span, snippet: state.s.eof(), right: ty_alias.where_clauses.after.span.shrink_to_hi(), } } else { errors::WhereClauseBeforeTypeAliasSugg::Remove { span } }; Err(errors::WhereClauseBeforeTypeAlias { span, sugg }) } fn with_impl_trait(&mut self, outer: Option, f: impl FnOnce(&mut Self)) { let old = mem::replace(&mut self.outer_impl_trait, outer); f(self); self.outer_impl_trait = old; } // Mirrors `visit::walk_ty`, but tracks relevant state. fn walk_ty(&mut self, t: &'a Ty) { match &t.kind { TyKind::ImplTrait(_, bounds) => { self.with_impl_trait(Some(t.span), |this| visit::walk_ty(this, t)); // FIXME(precise_capturing): If we were to allow `use` in other positions // (e.g. GATs), then we must validate those as well. However, we don't have // a good way of doing this with the current `Visitor` structure. let mut use_bounds = bounds .iter() .filter_map(|bound| match bound { GenericBound::Use(_, span) => Some(span), _ => None, }) .copied(); if let Some(bound1) = use_bounds.next() && let Some(bound2) = use_bounds.next() { self.dcx().emit_err(errors::DuplicatePreciseCapturing { bound1, bound2 }); } } TyKind::TraitObject(..) => self .with_tilde_const(Some(TildeConstReason::TraitObject), |this| { visit::walk_ty(this, t) }), _ => visit::walk_ty(self, t), } } fn visit_struct_field_def(&mut self, field: &'a FieldDef) { if let Some(ref ident) = field.ident && ident.name == kw::Underscore { self.visit_vis(&field.vis); self.visit_ident(ident); self.visit_ty_common(&field.ty); self.walk_ty(&field.ty); walk_list!(self, visit_attribute, &field.attrs); } else { self.visit_field_def(field); } } fn dcx(&self) -> DiagCtxtHandle<'a> { self.sess.dcx() } fn visibility_not_permitted(&self, vis: &Visibility, note: errors::VisibilityNotPermittedNote) { if let VisibilityKind::Inherited = vis.kind { return; } self.dcx().emit_err(errors::VisibilityNotPermitted { span: vis.span, note, remove_qualifier_sugg: vis.span, }); } fn check_decl_no_pat(decl: &FnDecl, mut report_err: impl FnMut(Span, Option, bool)) { for Param { pat, .. } in &decl.inputs { match pat.kind { PatKind::Ident(BindingMode::NONE, _, None) | PatKind::Wild => {} PatKind::Ident(BindingMode::MUT, ident, None) => { report_err(pat.span, Some(ident), true) } _ => report_err(pat.span, None, false), } } } fn check_trait_fn_not_const(&self, constness: Const, parent: &TraitOrTraitImpl) { let Const::Yes(span) = constness else { return; }; let const_trait_impl = self.features.const_trait_impl(); let make_impl_const_sugg = if const_trait_impl && let TraitOrTraitImpl::TraitImpl { constness: Const::No, polarity: ImplPolarity::Positive, trait_ref, .. } = parent { Some(trait_ref.shrink_to_lo()) } else { None }; let make_trait_const_sugg = if const_trait_impl && let TraitOrTraitImpl::Trait { span, constness: None } = parent { Some(span.shrink_to_lo()) } else { None }; let parent_constness = parent.constness(); self.dcx().emit_err(errors::TraitFnConst { span, in_impl: matches!(parent, TraitOrTraitImpl::TraitImpl { .. }), const_context_label: parent_constness, remove_const_sugg: ( self.sess.source_map().span_extend_while_whitespace(span), match parent_constness { Some(_) => rustc_errors::Applicability::MachineApplicable, None => rustc_errors::Applicability::MaybeIncorrect, }, ), requires_multiple_changes: make_impl_const_sugg.is_some() || make_trait_const_sugg.is_some(), make_impl_const_sugg, make_trait_const_sugg, }); } fn check_fn_decl(&self, fn_decl: &FnDecl, self_semantic: SelfSemantic) { self.check_decl_num_args(fn_decl); self.check_decl_cvariadic_pos(fn_decl); self.check_decl_attrs(fn_decl); self.check_decl_self_param(fn_decl, self_semantic); } /// Emits fatal error if function declaration has more than `u16::MAX` arguments /// Error is fatal to prevent errors during typechecking fn check_decl_num_args(&self, fn_decl: &FnDecl) { let max_num_args: usize = u16::MAX.into(); if fn_decl.inputs.len() > max_num_args { let Param { span, .. } = fn_decl.inputs[0]; self.dcx().emit_fatal(errors::FnParamTooMany { span, max_num_args }); } } /// Emits an error if a function declaration has a variadic parameter in the /// beginning or middle of parameter list. /// Example: `fn foo(..., x: i32)` will emit an error. fn check_decl_cvariadic_pos(&self, fn_decl: &FnDecl) { match &*fn_decl.inputs { [ps @ .., _] => { for Param { ty, span, .. } in ps { if let TyKind::CVarArgs = ty.kind { self.dcx().emit_err(errors::FnParamCVarArgsNotLast { span: *span }); } } } _ => {} } } fn check_decl_attrs(&self, fn_decl: &FnDecl) { fn_decl .inputs .iter() .flat_map(|i| i.attrs.as_ref()) .filter(|attr| { let arr = [ sym::allow, sym::cfg, sym::cfg_attr, sym::deny, sym::expect, sym::forbid, sym::warn, ]; !arr.contains(&attr.name_or_empty()) && rustc_attr::is_builtin_attr(attr) }) .for_each(|attr| { if attr.is_doc_comment() { self.dcx().emit_err(errors::FnParamDocComment { span: attr.span }); } else { self.dcx().emit_err(errors::FnParamForbiddenAttr { span: attr.span }); } }); } fn check_decl_self_param(&self, fn_decl: &FnDecl, self_semantic: SelfSemantic) { if let (SelfSemantic::No, [param, ..]) = (self_semantic, &*fn_decl.inputs) { if param.is_self() { self.dcx().emit_err(errors::FnParamForbiddenSelf { span: param.span }); } } } /// This ensures that items can only be `unsafe` (or unmarked) outside of extern /// blocks. /// /// This additionally ensures that within extern blocks, items can only be /// `safe`/`unsafe` inside of a `unsafe`-adorned extern block. fn check_item_safety(&self, span: Span, safety: Safety) { match self.extern_mod_safety { Some(extern_safety) => { if matches!(safety, Safety::Unsafe(_) | Safety::Safe(_)) && extern_safety == Safety::Default { self.dcx().emit_err(errors::InvalidSafetyOnExtern { item_span: span, block: Some(self.current_extern_span().shrink_to_lo()), }); } } None => { if matches!(safety, Safety::Safe(_)) { self.dcx().emit_err(errors::InvalidSafetyOnItem { span }); } } } } fn check_bare_fn_safety(&self, span: Span, safety: Safety) { if matches!(safety, Safety::Safe(_)) { self.dcx().emit_err(errors::InvalidSafetyOnBareFn { span }); } } fn check_defaultness(&self, span: Span, defaultness: Defaultness) { if let Defaultness::Default(def_span) = defaultness { let span = self.sess.source_map().guess_head_span(span); self.dcx().emit_err(errors::ForbiddenDefault { span, def_span }); } } /// If `sp` ends with a semicolon, returns it as a `Span` /// Otherwise, returns `sp.shrink_to_hi()` fn ending_semi_or_hi(&self, sp: Span) -> Span { let source_map = self.sess.source_map(); let end = source_map.end_point(sp); if source_map.span_to_snippet(end).is_ok_and(|s| s == ";") { end } else { sp.shrink_to_hi() } } fn check_type_no_bounds(&self, bounds: &[GenericBound], ctx: &str) { let span = match bounds { [] => return, [b0] => b0.span(), [b0, .., bl] => b0.span().to(bl.span()), }; self.dcx().emit_err(errors::BoundInContext { span, ctx }); } fn check_foreign_ty_genericless( &self, generics: &Generics, where_clauses: &TyAliasWhereClauses, ) { let cannot_have = |span, descr, remove_descr| { self.dcx().emit_err(errors::ExternTypesCannotHave { span, descr, remove_descr, block_span: self.current_extern_span(), }); }; if !generics.params.is_empty() { cannot_have(generics.span, "generic parameters", "generic parameters"); } let check_where_clause = |where_clause: TyAliasWhereClause| { if where_clause.has_where_token { cannot_have(where_clause.span, "`where` clauses", "`where` clause"); } }; check_where_clause(where_clauses.before); check_where_clause(where_clauses.after); } fn check_foreign_kind_bodyless(&self, ident: Ident, kind: &str, body: Option) { let Some(body) = body else { return; }; self.dcx().emit_err(errors::BodyInExtern { span: ident.span, body, block: self.current_extern_span(), kind, }); } /// An `fn` in `extern { ... }` cannot have a body `{ ... }`. fn check_foreign_fn_bodyless(&self, ident: Ident, body: Option<&Block>) { let Some(body) = body else { return; }; self.dcx().emit_err(errors::FnBodyInExtern { span: ident.span, body: body.span, block: self.current_extern_span(), }); } fn current_extern_span(&self) -> Span { self.sess.source_map().guess_head_span(self.extern_mod.unwrap()) } /// An `fn` in `extern { ... }` cannot have qualifiers, e.g. `async fn`. fn check_foreign_fn_headerless( &self, // Deconstruct to ensure exhaustiveness FnHeader { safety: _, coroutine_kind, constness, ext }: FnHeader, ) { let report_err = |span, kw| { self.dcx().emit_err(errors::FnQualifierInExtern { span, kw, block: self.current_extern_span(), }); }; match coroutine_kind { Some(kind) => report_err(kind.span(), kind.as_str()), None => (), } match constness { Const::Yes(span) => report_err(span, "const"), Const::No => (), } match ext { Extern::None => (), Extern::Implicit(span) | Extern::Explicit(_, span) => report_err(span, "extern"), } } /// An item in `extern { ... }` cannot use non-ascii identifier. fn check_foreign_item_ascii_only(&self, ident: Ident) { if !ident.as_str().is_ascii() { self.dcx().emit_err(errors::ExternItemAscii { span: ident.span, block: self.current_extern_span(), }); } } /// Reject invalid C-variadic types. /// /// C-variadics must be: /// - Non-const /// - Either foreign, or free and `unsafe extern "C"` semantically fn check_c_variadic_type(&self, fk: FnKind<'a>) { let variadic_spans: Vec<_> = fk .decl() .inputs .iter() .filter(|arg| matches!(arg.ty.kind, TyKind::CVarArgs)) .map(|arg| arg.span) .collect(); if variadic_spans.is_empty() { return; } if let Some(header) = fk.header() { if let Const::Yes(const_span) = header.constness { let mut spans = variadic_spans.clone(); spans.push(const_span); self.dcx().emit_err(errors::ConstAndCVariadic { spans, const_span, variadic_spans: variadic_spans.clone(), }); } } match (fk.ctxt(), fk.header()) { (Some(FnCtxt::Foreign), _) => return, (Some(FnCtxt::Free), Some(header)) => match header.ext { Extern::Explicit(StrLit { symbol_unescaped: sym::C, .. }, _) | Extern::Explicit(StrLit { symbol_unescaped: sym::C_dash_unwind, .. }, _) | Extern::Implicit(_) if matches!(header.safety, Safety::Unsafe(_)) => { return; } _ => {} }, _ => {} }; self.dcx().emit_err(errors::BadCVariadic { span: variadic_spans }); } fn check_item_named(&self, ident: Ident, kind: &str) { if ident.name != kw::Underscore { return; } self.dcx().emit_err(errors::ItemUnderscore { span: ident.span, kind }); } fn check_nomangle_item_asciionly(&self, ident: Ident, item_span: Span) { if ident.name.as_str().is_ascii() { return; } let span = self.sess.source_map().guess_head_span(item_span); self.dcx().emit_err(errors::NoMangleAscii { span }); } fn check_mod_file_item_asciionly(&self, ident: Ident) { if ident.name.as_str().is_ascii() { return; } self.dcx().emit_err(errors::ModuleNonAscii { span: ident.span, name: ident.name }); } fn deny_generic_params(&self, generics: &Generics, ident: Span) { if !generics.params.is_empty() { self.dcx().emit_err(errors::AutoTraitGeneric { span: generics.span, ident }); } } fn deny_super_traits(&self, bounds: &GenericBounds, ident_span: Span) { if let [.., last] = &bounds[..] { let span = ident_span.shrink_to_hi().to(last.span()); self.dcx().emit_err(errors::AutoTraitBounds { span, ident: ident_span }); } } fn deny_where_clause(&self, where_clause: &WhereClause, ident_span: Span) { if !where_clause.predicates.is_empty() { // FIXME: The current diagnostic is misleading since it only talks about // super trait and lifetime bounds while we should just say “bounds”. self.dcx() .emit_err(errors::AutoTraitBounds { span: where_clause.span, ident: ident_span }); } } fn deny_items(&self, trait_items: &[P], ident: Span) { if !trait_items.is_empty() { let spans: Vec<_> = trait_items.iter().map(|i| i.ident.span).collect(); let total = trait_items.first().unwrap().span.to(trait_items.last().unwrap().span); self.dcx().emit_err(errors::AutoTraitItems { spans, total, ident }); } } fn correct_generic_order_suggestion(&self, data: &AngleBracketedArgs) -> String { // Lifetimes always come first. let lt_sugg = data.args.iter().filter_map(|arg| match arg { AngleBracketedArg::Arg(lt @ GenericArg::Lifetime(_)) => { Some(pprust::to_string(|s| s.print_generic_arg(lt))) } _ => None, }); let args_sugg = data.args.iter().filter_map(|a| match a { AngleBracketedArg::Arg(GenericArg::Lifetime(_)) | AngleBracketedArg::Constraint(_) => { None } AngleBracketedArg::Arg(arg) => Some(pprust::to_string(|s| s.print_generic_arg(arg))), }); // Constraints always come last. let constraint_sugg = data.args.iter().filter_map(|a| match a { AngleBracketedArg::Arg(_) => None, AngleBracketedArg::Constraint(c) => { Some(pprust::to_string(|s| s.print_assoc_item_constraint(c))) } }); format!( "<{}>", lt_sugg.chain(args_sugg).chain(constraint_sugg).collect::>().join(", ") ) } /// Enforce generic args coming before constraints in `<...>` of a path segment. fn check_generic_args_before_constraints(&self, data: &AngleBracketedArgs) { // Early exit in case it's partitioned as it should be. if data.args.iter().is_partitioned(|arg| matches!(arg, AngleBracketedArg::Arg(_))) { return; } // Find all generic argument coming after the first constraint... let (constraint_spans, arg_spans): (Vec, Vec) = data.args.iter().partition_map(|arg| match arg { AngleBracketedArg::Constraint(c) => Either::Left(c.span), AngleBracketedArg::Arg(a) => Either::Right(a.span()), }); let args_len = arg_spans.len(); let constraint_len = constraint_spans.len(); // ...and then error: self.dcx().emit_err(errors::ArgsBeforeConstraint { arg_spans: arg_spans.clone(), constraints: constraint_spans[0], args: *arg_spans.iter().last().unwrap(), data: data.span, constraint_spans: errors::EmptyLabelManySpans(constraint_spans), arg_spans2: errors::EmptyLabelManySpans(arg_spans), suggestion: self.correct_generic_order_suggestion(data), constraint_len, args_len, }); } fn visit_ty_common(&mut self, ty: &'a Ty) { match &ty.kind { TyKind::BareFn(bfty) => { self.check_bare_fn_safety(bfty.decl_span, bfty.safety); self.check_fn_decl(&bfty.decl, SelfSemantic::No); Self::check_decl_no_pat(&bfty.decl, |span, _, _| { self.dcx().emit_err(errors::PatternFnPointer { span }); }); if let Extern::Implicit(extern_span) = bfty.ext { self.maybe_lint_missing_abi(extern_span, ty.id); } } TyKind::TraitObject(bounds, ..) => { let mut any_lifetime_bounds = false; for bound in bounds { if let GenericBound::Outlives(lifetime) = bound { if any_lifetime_bounds { self.dcx() .emit_err(errors::TraitObjectBound { span: lifetime.ident.span }); break; } any_lifetime_bounds = true; } } } TyKind::ImplTrait(_, bounds) => { if let Some(outer_impl_trait_sp) = self.outer_impl_trait { self.dcx().emit_err(errors::NestedImplTrait { span: ty.span, outer: outer_impl_trait_sp, inner: ty.span, }); } if !bounds.iter().any(|b| matches!(b, GenericBound::Trait(..))) { self.dcx().emit_err(errors::AtLeastOneTrait { span: ty.span }); } } _ => {} } } fn maybe_lint_missing_abi(&mut self, span: Span, id: NodeId) { // FIXME(davidtwco): This is a hack to detect macros which produce spans of the // call site which do not have a macro backtrace. See #61963. if self .sess .source_map() .span_to_snippet(span) .is_ok_and(|snippet| !snippet.starts_with("#[")) { self.lint_buffer.buffer_lint( MISSING_ABI, id, span, BuiltinLintDiag::MissingAbi(span, abi::Abi::FALLBACK), ) } } } /// Checks that generic parameters are in the correct order, /// which is lifetimes, then types and then consts. (`<'a, T, const N: usize>`) fn validate_generic_param_order(dcx: DiagCtxtHandle<'_>, generics: &[GenericParam], span: Span) { let mut max_param: Option = None; let mut out_of_order = FxIndexMap::default(); let mut param_idents = Vec::with_capacity(generics.len()); for (idx, param) in generics.iter().enumerate() { let ident = param.ident; let (kind, bounds, span) = (¶m.kind, ¶m.bounds, ident.span); let (ord_kind, ident) = match ¶m.kind { GenericParamKind::Lifetime => (ParamKindOrd::Lifetime, ident.to_string()), GenericParamKind::Type { .. } => (ParamKindOrd::TypeOrConst, ident.to_string()), GenericParamKind::Const { ty, .. } => { let ty = pprust::ty_to_string(ty); (ParamKindOrd::TypeOrConst, format!("const {ident}: {ty}")) } }; param_idents.push((kind, ord_kind, bounds, idx, ident)); match max_param { Some(max_param) if max_param > ord_kind => { let entry = out_of_order.entry(ord_kind).or_insert((max_param, vec![])); entry.1.push(span); } Some(_) | None => max_param = Some(ord_kind), }; } if !out_of_order.is_empty() { let mut ordered_params = "<".to_string(); param_idents.sort_by_key(|&(_, po, _, i, _)| (po, i)); let mut first = true; for (kind, _, bounds, _, ident) in param_idents { if !first { ordered_params += ", "; } ordered_params += &ident; if !bounds.is_empty() { ordered_params += ": "; ordered_params += &pprust::bounds_to_string(bounds); } match kind { GenericParamKind::Type { default: Some(default) } => { ordered_params += " = "; ordered_params += &pprust::ty_to_string(default); } GenericParamKind::Type { default: None } => (), GenericParamKind::Lifetime => (), GenericParamKind::Const { ty: _, kw_span: _, default: Some(default) } => { ordered_params += " = "; ordered_params += &pprust::expr_to_string(&default.value); } GenericParamKind::Const { ty: _, kw_span: _, default: None } => (), } first = false; } ordered_params += ">"; for (param_ord, (max_param, spans)) in &out_of_order { dcx.emit_err(errors::OutOfOrderParams { spans: spans.clone(), sugg_span: span, param_ord, max_param, ordered_params: &ordered_params, }); } } } impl<'a> Visitor<'a> for AstValidator<'a> { fn visit_attribute(&mut self, attr: &Attribute) { validate_attr::check_attr(&self.sess.psess, attr); } fn visit_ty(&mut self, ty: &'a Ty) { self.visit_ty_common(ty); self.walk_ty(ty) } fn visit_item(&mut self, item: &'a Item) { if item.attrs.iter().any(|attr| attr.is_proc_macro_attr()) { self.has_proc_macro_decls = true; } if attr::contains_name(&item.attrs, sym::no_mangle) { self.check_nomangle_item_asciionly(item.ident, item.span); } match &item.kind { ItemKind::Impl(box Impl { safety, polarity, defaultness: _, constness, generics, of_trait: Some(t), self_ty, items, }) => { self.with_in_trait_impl(Some((*constness, *polarity, t)), |this| { this.visibility_not_permitted( &item.vis, errors::VisibilityNotPermittedNote::TraitImpl, ); if let TyKind::Dummy = self_ty.kind { // Abort immediately otherwise the `TyKind::Dummy` will reach HIR lowering, // which isn't allowed. Not a problem for this obscure, obsolete syntax. this.dcx().emit_fatal(errors::ObsoleteAuto { span: item.span }); } if let (&Safety::Unsafe(span), &ImplPolarity::Negative(sp)) = (safety, polarity) { this.dcx().emit_err(errors::UnsafeNegativeImpl { span: sp.to(t.path.span), negative: sp, r#unsafe: span, }); } this.visit_vis(&item.vis); this.visit_ident(&item.ident); let disallowed = matches!(constness, Const::No) .then(|| TildeConstReason::TraitImpl { span: item.span }); this.with_tilde_const(disallowed, |this| this.visit_generics(generics)); this.visit_trait_ref(t); this.visit_ty(self_ty); walk_list!(this, visit_assoc_item, items, AssocCtxt::Impl); }); walk_list!(self, visit_attribute, &item.attrs); return; // Avoid visiting again. } ItemKind::Impl(box Impl { safety, polarity, defaultness, constness, generics, of_trait: None, self_ty, items, }) => { let error = |annotation_span, annotation, only_trait| errors::InherentImplCannot { span: self_ty.span, annotation_span, annotation, self_ty: self_ty.span, only_trait, }; self.with_in_trait_impl(None, |this| { this.visibility_not_permitted( &item.vis, errors::VisibilityNotPermittedNote::IndividualImplItems, ); if let &Safety::Unsafe(span) = safety { this.dcx().emit_err(errors::InherentImplCannotUnsafe { span: self_ty.span, annotation_span: span, annotation: "unsafe", self_ty: self_ty.span, }); } if let &ImplPolarity::Negative(span) = polarity { this.dcx().emit_err(error(span, "negative", false)); } if let &Defaultness::Default(def_span) = defaultness { this.dcx().emit_err(error(def_span, "`default`", true)); } if let &Const::Yes(span) = constness { this.dcx().emit_err(error(span, "`const`", true)); } this.visit_vis(&item.vis); this.visit_ident(&item.ident); this.with_tilde_const( Some(TildeConstReason::Impl { span: item.span }), |this| this.visit_generics(generics), ); this.visit_ty(self_ty); walk_list!(this, visit_assoc_item, items, AssocCtxt::Impl); }); walk_list!(self, visit_attribute, &item.attrs); return; // Avoid visiting again. } ItemKind::Fn(box Fn { defaultness, sig, generics, body }) => { self.check_defaultness(item.span, *defaultness); if body.is_none() { self.dcx().emit_err(errors::FnWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), extern_block_suggestion: match sig.header.ext { Extern::None => None, Extern::Implicit(start_span) => { Some(errors::ExternBlockSuggestion::Implicit { start_span, end_span: item.span.shrink_to_hi(), }) } Extern::Explicit(abi, start_span) => { Some(errors::ExternBlockSuggestion::Explicit { start_span, end_span: item.span.shrink_to_hi(), abi: abi.symbol_unescaped, }) } }, }); } self.visit_vis(&item.vis); self.visit_ident(&item.ident); let kind = FnKind::Fn(FnCtxt::Free, item.ident, sig, &item.vis, generics, body.as_deref()); self.visit_fn(kind, item.span, item.id); walk_list!(self, visit_attribute, &item.attrs); return; // Avoid visiting again. } ItemKind::ForeignMod(ForeignMod { extern_span, abi, safety, .. }) => { self.with_in_extern_mod(*safety, |this| { let old_item = mem::replace(&mut this.extern_mod, Some(item.span)); this.visibility_not_permitted( &item.vis, errors::VisibilityNotPermittedNote::IndividualForeignItems, ); if &Safety::Default == safety { if item.span.at_least_rust_2024() { this.dcx().emit_err(errors::MissingUnsafeOnExtern { span: item.span }); } else { this.lint_buffer.buffer_lint( MISSING_UNSAFE_ON_EXTERN, item.id, item.span, BuiltinLintDiag::MissingUnsafeOnExtern { suggestion: item.span.shrink_to_lo(), }, ); } } if abi.is_none() { this.maybe_lint_missing_abi(*extern_span, item.id); } visit::walk_item(this, item); this.extern_mod = old_item; }); return; // Avoid visiting again. } ItemKind::Enum(def, _) => { for variant in &def.variants { self.visibility_not_permitted( &variant.vis, errors::VisibilityNotPermittedNote::EnumVariant, ); for field in variant.data.fields() { self.visibility_not_permitted( &field.vis, errors::VisibilityNotPermittedNote::EnumVariant, ); } } } ItemKind::Trait(box Trait { is_auto, generics, bounds, items, .. }) => { let is_const_trait = attr::find_by_name(&item.attrs, sym::const_trait).map(|attr| attr.span); self.with_in_trait(item.span, is_const_trait, |this| { if *is_auto == IsAuto::Yes { // Auto traits cannot have generics, super traits nor contain items. this.deny_generic_params(generics, item.ident.span); this.deny_super_traits(bounds, item.ident.span); this.deny_where_clause(&generics.where_clause, item.ident.span); this.deny_items(items, item.ident.span); } // Equivalent of `visit::walk_item` for `ItemKind::Trait` that inserts a bound // context for the supertraits. this.visit_vis(&item.vis); this.visit_ident(&item.ident); let disallowed = is_const_trait .is_none() .then(|| TildeConstReason::Trait { span: item.span }); this.with_tilde_const(disallowed, |this| { this.visit_generics(generics); walk_list!(this, visit_param_bound, bounds, BoundKind::SuperTraits) }); walk_list!(this, visit_assoc_item, items, AssocCtxt::Trait); }); walk_list!(self, visit_attribute, &item.attrs); return; // Avoid visiting again } ItemKind::Mod(safety, mod_kind) => { if let &Safety::Unsafe(span) = safety { self.dcx().emit_err(errors::UnsafeItem { span, kind: "module" }); } // Ensure that `path` attributes on modules are recorded as used (cf. issue #35584). if !matches!(mod_kind, ModKind::Loaded(_, Inline::Yes, _)) && !attr::contains_name(&item.attrs, sym::path) { self.check_mod_file_item_asciionly(item.ident); } } ItemKind::Struct(vdata, generics) => match vdata { VariantData::Struct { fields, .. } => { self.visit_vis(&item.vis); self.visit_ident(&item.ident); self.visit_generics(generics); // Permit `Anon{Struct,Union}` as field type. walk_list!(self, visit_struct_field_def, fields); walk_list!(self, visit_attribute, &item.attrs); return; } _ => {} }, ItemKind::Union(vdata, generics) => { if vdata.fields().is_empty() { self.dcx().emit_err(errors::FieldlessUnion { span: item.span }); } match vdata { VariantData::Struct { fields, .. } => { self.visit_vis(&item.vis); self.visit_ident(&item.ident); self.visit_generics(generics); // Permit `Anon{Struct,Union}` as field type. walk_list!(self, visit_struct_field_def, fields); walk_list!(self, visit_attribute, &item.attrs); return; } _ => {} } } ItemKind::Const(box ConstItem { defaultness, expr, .. }) => { self.check_defaultness(item.span, *defaultness); if expr.is_none() { self.dcx().emit_err(errors::ConstWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } } ItemKind::Static(box StaticItem { expr, safety, .. }) => { self.check_item_safety(item.span, *safety); if matches!(safety, Safety::Unsafe(_)) { self.dcx().emit_err(errors::UnsafeStatic { span: item.span }); } if expr.is_none() { self.dcx().emit_err(errors::StaticWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } } ItemKind::TyAlias( ty_alias @ box TyAlias { defaultness, bounds, where_clauses, ty, .. }, ) => { self.check_defaultness(item.span, *defaultness); if ty.is_none() { self.dcx().emit_err(errors::TyAliasWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } self.check_type_no_bounds(bounds, "this context"); if self.features.lazy_type_alias() { if let Err(err) = self.check_type_alias_where_clause_location(ty_alias) { self.dcx().emit_err(err); } } else if where_clauses.after.has_where_token { self.dcx().emit_err(errors::WhereClauseAfterTypeAlias { span: where_clauses.after.span, help: self.sess.is_nightly_build(), }); } } _ => {} } visit::walk_item(self, item); } fn visit_foreign_item(&mut self, fi: &'a ForeignItem) { match &fi.kind { ForeignItemKind::Fn(box Fn { defaultness, sig, body, .. }) => { self.check_defaultness(fi.span, *defaultness); self.check_foreign_fn_bodyless(fi.ident, body.as_deref()); self.check_foreign_fn_headerless(sig.header); self.check_foreign_item_ascii_only(fi.ident); } ForeignItemKind::TyAlias(box TyAlias { defaultness, generics, where_clauses, bounds, ty, .. }) => { self.check_defaultness(fi.span, *defaultness); self.check_foreign_kind_bodyless(fi.ident, "type", ty.as_ref().map(|b| b.span)); self.check_type_no_bounds(bounds, "`extern` blocks"); self.check_foreign_ty_genericless(generics, where_clauses); self.check_foreign_item_ascii_only(fi.ident); } ForeignItemKind::Static(box StaticItem { expr, safety, .. }) => { self.check_item_safety(fi.span, *safety); self.check_foreign_kind_bodyless(fi.ident, "static", expr.as_ref().map(|b| b.span)); self.check_foreign_item_ascii_only(fi.ident); } ForeignItemKind::MacCall(..) => {} } visit::walk_item(self, fi) } // Mirrors `visit::walk_generic_args`, but tracks relevant state. fn visit_generic_args(&mut self, generic_args: &'a GenericArgs) { match generic_args { GenericArgs::AngleBracketed(data) => { self.check_generic_args_before_constraints(data); for arg in &data.args { match arg { AngleBracketedArg::Arg(arg) => self.visit_generic_arg(arg), // Associated type bindings such as `Item = impl Debug` in // `Iterator` are allowed to contain nested `impl Trait`. AngleBracketedArg::Constraint(constraint) => { self.with_impl_trait(None, |this| { this.visit_assoc_item_constraint(constraint); }); } } } } GenericArgs::Parenthesized(data) => { walk_list!(self, visit_ty, &data.inputs); if let FnRetTy::Ty(ty) = &data.output { // `-> Foo` syntax is essentially an associated type binding, // so it is also allowed to contain nested `impl Trait`. self.with_impl_trait(None, |this| this.visit_ty(ty)); } } GenericArgs::ParenthesizedElided(_span) => {} } } fn visit_generics(&mut self, generics: &'a Generics) { let mut prev_param_default = None; for param in &generics.params { match param.kind { GenericParamKind::Lifetime => (), GenericParamKind::Type { default: Some(_), .. } | GenericParamKind::Const { default: Some(_), .. } => { prev_param_default = Some(param.ident.span); } GenericParamKind::Type { .. } | GenericParamKind::Const { .. } => { if let Some(span) = prev_param_default { self.dcx().emit_err(errors::GenericDefaultTrailing { span }); break; } } } } validate_generic_param_order(self.dcx(), &generics.params, generics.span); for predicate in &generics.where_clause.predicates { if let WherePredicate::EqPredicate(predicate) = predicate { deny_equality_constraints(self, predicate, generics); } } walk_list!(self, visit_generic_param, &generics.params); for predicate in &generics.where_clause.predicates { match predicate { WherePredicate::BoundPredicate(bound_pred) => { // This is slightly complicated. Our representation for poly-trait-refs contains a single // binder and thus we only allow a single level of quantification. However, // the syntax of Rust permits quantification in two places in where clauses, // e.g., `T: for <'a> Foo<'a>` and `for <'a, 'b> &'b T: Foo<'a>`. If both are // defined, then error. if !bound_pred.bound_generic_params.is_empty() { for bound in &bound_pred.bounds { match bound { GenericBound::Trait(t) => { if !t.bound_generic_params.is_empty() { self.dcx() .emit_err(errors::NestedLifetimes { span: t.span }); } } GenericBound::Outlives(_) => {} GenericBound::Use(..) => {} } } } } _ => {} } self.visit_where_predicate(predicate); } } fn visit_param_bound(&mut self, bound: &'a GenericBound, ctxt: BoundKind) { match bound { GenericBound::Trait(trait_ref) => { match (ctxt, trait_ref.modifiers.constness, trait_ref.modifiers.polarity) { (BoundKind::SuperTraits, BoundConstness::Never, BoundPolarity::Maybe(_)) if !self.features.more_maybe_bounds() => { self.sess .create_feature_err( errors::OptionalTraitSupertrait { span: trait_ref.span, path_str: pprust::path_to_string(&trait_ref.trait_ref.path), }, sym::more_maybe_bounds, ) .emit(); } (BoundKind::TraitObject, BoundConstness::Never, BoundPolarity::Maybe(_)) if !self.features.more_maybe_bounds() => { self.sess .create_feature_err( errors::OptionalTraitObject { span: trait_ref.span }, sym::more_maybe_bounds, ) .emit(); } ( BoundKind::TraitObject, BoundConstness::Always(_), BoundPolarity::Positive, ) => { self.dcx().emit_err(errors::ConstBoundTraitObject { span: trait_ref.span }); } (_, BoundConstness::Maybe(span), BoundPolarity::Positive) if let Some(reason) = self.disallow_tilde_const => { self.dcx().emit_err(errors::TildeConstDisallowed { span, reason }); } _ => {} } // Negative trait bounds are not allowed to have associated constraints if let BoundPolarity::Negative(_) = trait_ref.modifiers.polarity && let Some(segment) = trait_ref.trait_ref.path.segments.last() { match segment.args.as_deref() { Some(ast::GenericArgs::AngleBracketed(args)) => { for arg in &args.args { if let ast::AngleBracketedArg::Constraint(constraint) = arg { self.dcx().emit_err(errors::ConstraintOnNegativeBound { span: constraint.span, }); } } } // The lowered form of parenthesized generic args contains an associated type binding. Some(ast::GenericArgs::Parenthesized(args)) => { self.dcx().emit_err(errors::NegativeBoundWithParentheticalNotation { span: args.span, }); } Some(ast::GenericArgs::ParenthesizedElided(_)) | None => {} } } } GenericBound::Outlives(_) => {} GenericBound::Use(_, span) => match ctxt { BoundKind::Impl => {} BoundKind::Bound | BoundKind::TraitObject | BoundKind::SuperTraits => { self.dcx().emit_err(errors::PreciseCapturingNotAllowedHere { loc: ctxt.descr(), span: *span, }); } }, } visit::walk_param_bound(self, bound) } fn visit_fn(&mut self, fk: FnKind<'a>, span: Span, id: NodeId) { // Only associated `fn`s can have `self` parameters. let self_semantic = match fk.ctxt() { Some(FnCtxt::Assoc(_)) => SelfSemantic::Yes, _ => SelfSemantic::No, }; self.check_fn_decl(fk.decl(), self_semantic); if let Some(&FnHeader { safety, .. }) = fk.header() { self.check_item_safety(span, safety); } self.check_c_variadic_type(fk); // Functions cannot both be `const async` or `const gen` if let Some(&FnHeader { constness: Const::Yes(const_span), coroutine_kind: Some(coroutine_kind), .. }) = fk.header() { self.dcx().emit_err(errors::ConstAndCoroutine { spans: vec![coroutine_kind.span(), const_span], const_span, coroutine_span: coroutine_kind.span(), coroutine_kind: coroutine_kind.as_str(), span, }); } if let FnKind::Fn( _, _, FnSig { header: FnHeader { ext: Extern::Implicit(extern_span), .. }, .. }, _, _, _, ) = fk { self.maybe_lint_missing_abi(*extern_span, id); } // Functions without bodies cannot have patterns. if let FnKind::Fn(ctxt, _, sig, _, _, None) = fk { Self::check_decl_no_pat(&sig.decl, |span, ident, mut_ident| { if mut_ident && matches!(ctxt, FnCtxt::Assoc(_)) { if let Some(ident) = ident { self.lint_buffer.buffer_lint( PATTERNS_IN_FNS_WITHOUT_BODY, id, span, BuiltinLintDiag::PatternsInFnsWithoutBody { span, ident, is_foreign: matches!(ctxt, FnCtxt::Foreign), }, ) } } else { match ctxt { FnCtxt::Foreign => self.dcx().emit_err(errors::PatternInForeign { span }), _ => self.dcx().emit_err(errors::PatternInBodiless { span }), }; } }); } let tilde_const_allowed = matches!(fk.header(), Some(FnHeader { constness: ast::Const::Yes(_), .. })) || matches!(fk.ctxt(), Some(FnCtxt::Assoc(_))) && self .outer_trait_or_trait_impl .as_ref() .and_then(TraitOrTraitImpl::constness) .is_some(); let disallowed = (!tilde_const_allowed).then(|| match fk { FnKind::Fn(_, ident, _, _, _, _) => TildeConstReason::Function { ident: ident.span }, FnKind::Closure(..) => TildeConstReason::Closure, }); self.with_tilde_const(disallowed, |this| visit::walk_fn(this, fk)); } fn visit_assoc_item(&mut self, item: &'a AssocItem, ctxt: AssocCtxt) { if attr::contains_name(&item.attrs, sym::no_mangle) { self.check_nomangle_item_asciionly(item.ident, item.span); } if ctxt == AssocCtxt::Trait || self.outer_trait_or_trait_impl.is_none() { self.check_defaultness(item.span, item.kind.defaultness()); } if ctxt == AssocCtxt::Impl { match &item.kind { AssocItemKind::Const(box ConstItem { expr: None, .. }) => { self.dcx().emit_err(errors::AssocConstWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } AssocItemKind::Fn(box Fn { body, .. }) => { if body.is_none() { self.dcx().emit_err(errors::AssocFnWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } } AssocItemKind::Type(box TyAlias { bounds, ty, .. }) => { if ty.is_none() { self.dcx().emit_err(errors::AssocTypeWithoutBody { span: item.span, replace_span: self.ending_semi_or_hi(item.span), }); } self.check_type_no_bounds(bounds, "`impl`s"); } _ => {} } } if let AssocItemKind::Type(ty_alias) = &item.kind && let Err(err) = self.check_type_alias_where_clause_location(ty_alias) { let sugg = match err.sugg { errors::WhereClauseBeforeTypeAliasSugg::Remove { .. } => None, errors::WhereClauseBeforeTypeAliasSugg::Move { snippet, right, .. } => { Some((right, snippet)) } }; self.lint_buffer.buffer_lint( DEPRECATED_WHERE_CLAUSE_LOCATION, item.id, err.span, BuiltinLintDiag::DeprecatedWhereclauseLocation(err.span, sugg), ); } if let Some(parent) = &self.outer_trait_or_trait_impl { self.visibility_not_permitted(&item.vis, errors::VisibilityNotPermittedNote::TraitImpl); if let AssocItemKind::Fn(box Fn { sig, .. }) = &item.kind { self.check_trait_fn_not_const(sig.header.constness, parent); } } if let AssocItemKind::Const(..) = item.kind { self.check_item_named(item.ident, "const"); } let parent_is_const = self.outer_trait_or_trait_impl.as_ref().and_then(TraitOrTraitImpl::constness).is_some(); match &item.kind { AssocItemKind::Fn(box Fn { sig, generics, body, .. }) if parent_is_const || ctxt == AssocCtxt::Trait || matches!(sig.header.constness, Const::Yes(_)) => { self.visit_vis(&item.vis); self.visit_ident(&item.ident); let kind = FnKind::Fn( FnCtxt::Assoc(ctxt), item.ident, sig, &item.vis, generics, body.as_deref(), ); walk_list!(self, visit_attribute, &item.attrs); self.visit_fn(kind, item.span, item.id); } AssocItemKind::Type(_) => { let disallowed = (!parent_is_const).then(|| match self.outer_trait_or_trait_impl { Some(TraitOrTraitImpl::Trait { .. }) => { TildeConstReason::TraitAssocTy { span: item.span } } Some(TraitOrTraitImpl::TraitImpl { .. }) => { TildeConstReason::TraitImplAssocTy { span: item.span } } None => TildeConstReason::InherentAssocTy { span: item.span }, }); self.with_tilde_const(disallowed, |this| { this.with_in_trait_impl(None, |this| visit::walk_assoc_item(this, item, ctxt)) }) } _ => self.with_in_trait_impl(None, |this| visit::walk_assoc_item(this, item, ctxt)), } } } /// When encountering an equality constraint in a `where` clause, emit an error. If the code seems /// like it's setting an associated type, provide an appropriate suggestion. fn deny_equality_constraints( this: &AstValidator<'_>, predicate: &WhereEqPredicate, generics: &Generics, ) { let mut err = errors::EqualityInWhere { span: predicate.span, assoc: None, assoc2: None }; // Given `::Bar = RhsTy`, suggest `A: Foo`. if let TyKind::Path(Some(qself), full_path) = &predicate.lhs_ty.kind && let TyKind::Path(None, path) = &qself.ty.kind && let [PathSegment { ident, args: None, .. }] = &path.segments[..] { for param in &generics.params { if param.ident == *ident && let [PathSegment { ident, args, .. }] = &full_path.segments[qself.position..] { // Make a new `Path` from `foo::Bar` to `Foo`. let mut assoc_path = full_path.clone(); // Remove `Bar` from `Foo::Bar`. assoc_path.segments.pop(); let len = assoc_path.segments.len() - 1; let gen_args = args.as_deref().cloned(); // Build ``. let arg = AngleBracketedArg::Constraint(AssocItemConstraint { id: rustc_ast::node_id::DUMMY_NODE_ID, ident: *ident, gen_args, kind: AssocItemConstraintKind::Equality { term: predicate.rhs_ty.clone().into(), }, span: ident.span, }); // Add `` to `Foo`. match &mut assoc_path.segments[len].args { Some(args) => match args.deref_mut() { GenericArgs::Parenthesized(_) | GenericArgs::ParenthesizedElided(..) => { continue; } GenericArgs::AngleBracketed(args) => { args.args.push(arg); } }, empty_args => { *empty_args = Some( AngleBracketedArgs { span: ident.span, args: thin_vec![arg] }.into(), ); } } err.assoc = Some(errors::AssociatedSuggestion { span: predicate.span, ident: *ident, param: param.ident, path: pprust::path_to_string(&assoc_path), }) } } } let mut suggest = |poly: &PolyTraitRef, potential_assoc: &PathSegment, predicate: &WhereEqPredicate| { if let [trait_segment] = &poly.trait_ref.path.segments[..] { let assoc = pprust::path_to_string(&ast::Path::from_ident(potential_assoc.ident)); let ty = pprust::ty_to_string(&predicate.rhs_ty); let (args, span) = match &trait_segment.args { Some(args) => match args.deref() { ast::GenericArgs::AngleBracketed(args) => { let Some(arg) = args.args.last() else { return; }; (format!(", {assoc} = {ty}"), arg.span().shrink_to_hi()) } _ => return, }, None => (format!("<{assoc} = {ty}>"), trait_segment.span().shrink_to_hi()), }; let removal_span = if generics.where_clause.predicates.len() == 1 { // We're removing th eonly where bound left, remove the whole thing. generics.where_clause.span } else { let mut span = predicate.span; let mut prev: Option = None; let mut preds = generics.where_clause.predicates.iter().peekable(); // Find the predicate that shouldn't have been in the where bound list. while let Some(pred) = preds.next() { if let WherePredicate::EqPredicate(pred) = pred && pred.span == predicate.span { if let Some(next) = preds.peek() { // This is the first predicate, remove the trailing comma as well. span = span.with_hi(next.span().lo()); } else if let Some(prev) = prev { // Remove the previous comma as well. span = span.with_lo(prev.hi()); } } prev = Some(pred.span()); } span }; err.assoc2 = Some(errors::AssociatedSuggestion2 { span, args, predicate: removal_span, trait_segment: trait_segment.ident, potential_assoc: potential_assoc.ident, }); } }; if let TyKind::Path(None, full_path) = &predicate.lhs_ty.kind { // Given `A: Foo, Foo::Bar = RhsTy`, suggest `A: Foo`. for bounds in generics.params.iter().map(|p| &p.bounds).chain( generics.where_clause.predicates.iter().filter_map(|pred| match pred { WherePredicate::BoundPredicate(p) => Some(&p.bounds), _ => None, }), ) { for bound in bounds { if let GenericBound::Trait(poly) = bound && poly.modifiers == TraitBoundModifiers::NONE { if full_path.segments[..full_path.segments.len() - 1] .iter() .map(|segment| segment.ident.name) .zip(poly.trait_ref.path.segments.iter().map(|segment| segment.ident.name)) .all(|(a, b)| a == b) && let Some(potential_assoc) = full_path.segments.iter().last() { suggest(poly, potential_assoc, predicate); } } } } // Given `A: Foo, A::Bar = RhsTy`, suggest `A: Foo`. if let [potential_param, potential_assoc] = &full_path.segments[..] { for (ident, bounds) in generics.params.iter().map(|p| (p.ident, &p.bounds)).chain( generics.where_clause.predicates.iter().filter_map(|pred| match pred { WherePredicate::BoundPredicate(p) if let ast::TyKind::Path(None, path) = &p.bounded_ty.kind && let [segment] = &path.segments[..] => { Some((segment.ident, &p.bounds)) } _ => None, }), ) { if ident == potential_param.ident { for bound in bounds { if let ast::GenericBound::Trait(poly) = bound && poly.modifiers == TraitBoundModifiers::NONE { suggest(poly, potential_assoc, predicate); } } } } } } this.dcx().emit_err(err); } pub fn check_crate( sess: &Session, features: &Features, krate: &Crate, lints: &mut LintBuffer, ) -> bool { let mut validator = AstValidator { sess, features, extern_mod: None, outer_trait_or_trait_impl: None, has_proc_macro_decls: false, outer_impl_trait: None, disallow_tilde_const: Some(TildeConstReason::Item), extern_mod_safety: None, lint_buffer: lints, }; visit::walk_crate(&mut validator, krate); validator.has_proc_macro_decls }