// Validate AST before lowering it to HIR. // // This pass is supposed to catch things that fit into AST data structures, // but not permitted by the language. It runs after expansion when AST is frozen, // so it can check for erroneous constructions produced by syntax extensions. // This pass is supposed to perform only simple checks not requiring name resolution // or type checking or some other kind of complex analysis. use rustc_data_structures::fx::FxHashMap; use rustc_errors::{struct_span_err, Applicability, FatalError}; use rustc_parse::validate_attr; use rustc_session::lint::builtin::PATTERNS_IN_FNS_WITHOUT_BODY; use rustc_session::lint::LintBuffer; use rustc_session::Session; use rustc_span::source_map::Spanned; use rustc_span::symbol::{kw, sym}; use rustc_span::Span; use std::mem; use syntax::ast::*; use syntax::attr; use syntax::expand::is_proc_macro_attr; use syntax::print::pprust; use syntax::visit::{self, Visitor}; use syntax::walk_list; use rustc_error_codes::*; /// A syntactic context that disallows certain kinds of bounds (e.g., `?Trait` or `?const Trait`). #[derive(Clone, Copy)] enum BoundContext { ImplTrait, TraitBounds, TraitObject, } impl BoundContext { fn description(&self) -> &'static str { match self { Self::ImplTrait => "`impl Trait`", Self::TraitBounds => "supertraits", Self::TraitObject => "trait objects", } } } struct AstValidator<'a> { session: &'a Session, 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, /// Keeps track of the `BoundContext` as we recurse. /// /// This is used to forbid `?const Trait` bounds in, e.g., /// `impl Iterator`. bound_context: Option, /// Used to ban `impl Trait` in path projections like `::Item` /// or `Foo::Bar` is_impl_trait_banned: bool, /// Used to ban associated type bounds (i.e., `Type`) in /// certain positions. is_assoc_ty_bound_banned: bool, lint_buffer: &'a mut LintBuffer, } impl<'a> AstValidator<'a> { fn with_banned_impl_trait(&mut self, f: impl FnOnce(&mut Self)) { let old = mem::replace(&mut self.is_impl_trait_banned, true); f(self); self.is_impl_trait_banned = old; } fn with_banned_assoc_ty_bound(&mut self, f: impl FnOnce(&mut Self)) { let old = mem::replace(&mut self.is_assoc_ty_bound_banned, true); f(self); self.is_assoc_ty_bound_banned = old; } fn with_impl_trait(&mut self, outer: Option, f: impl FnOnce(&mut Self)) { let old = mem::replace(&mut self.outer_impl_trait, outer); if outer.is_some() { self.with_bound_context(BoundContext::ImplTrait, |this| f(this)); } else { f(self) } self.outer_impl_trait = old; } fn with_bound_context(&mut self, ctx: BoundContext, f: impl FnOnce(&mut Self)) { let old = self.bound_context.replace(ctx); f(self); self.bound_context = old; } fn visit_assoc_ty_constraint_from_generic_args(&mut self, constraint: &'a AssocTyConstraint) { match constraint.kind { AssocTyConstraintKind::Equality { .. } => {} AssocTyConstraintKind::Bound { .. } => { if self.is_assoc_ty_bound_banned { self.err_handler().span_err( constraint.span, "associated type bounds are not allowed within structs, enums, or unions", ); } } } self.visit_assoc_ty_constraint(constraint); } // Mirrors `visit::walk_ty`, but tracks relevant state. fn walk_ty(&mut self, t: &'a Ty) { match t.kind { TyKind::ImplTrait(..) => { self.with_impl_trait(Some(t.span), |this| visit::walk_ty(this, t)) } TyKind::TraitObject(..) => { self.with_bound_context(BoundContext::TraitObject, |this| visit::walk_ty(this, t)); } TyKind::Path(ref qself, ref path) => { // We allow these: // - `Option` // - `option::Option` // - `option::Option::Foo // // But not these: // - `::Foo` // - `option::Option::Foo`. // // To implement this, we disallow `impl Trait` from `qself` // (for cases like `::Foo>`) // but we allow `impl Trait` in `GenericArgs` // iff there are no more PathSegments. if let Some(ref qself) = *qself { // `impl Trait` in `qself` is always illegal self.with_banned_impl_trait(|this| this.visit_ty(&qself.ty)); } // Note that there should be a call to visit_path here, // so if any logic is added to process `Path`s a call to it should be // added both in visit_path and here. This code mirrors visit::walk_path. for (i, segment) in path.segments.iter().enumerate() { // Allow `impl Trait` iff we're on the final path segment if i == path.segments.len() - 1 { self.visit_path_segment(path.span, segment); } else { self.with_banned_impl_trait(|this| { this.visit_path_segment(path.span, segment) }); } } } _ => visit::walk_ty(self, t), } } fn err_handler(&self) -> &rustc_errors::Handler { &self.session.diagnostic() } fn check_lifetime(&self, ident: Ident) { let valid_names = [kw::UnderscoreLifetime, kw::StaticLifetime, kw::Invalid]; if !valid_names.contains(&ident.name) && ident.without_first_quote().is_reserved() { self.err_handler().span_err(ident.span, "lifetimes cannot use keyword names"); } } fn check_label(&self, ident: Ident) { if ident.without_first_quote().is_reserved() { self.err_handler() .span_err(ident.span, &format!("invalid label name `{}`", ident.name)); } } fn invalid_visibility(&self, vis: &Visibility, note: Option<&str>) { if let VisibilityKind::Inherited = vis.node { return; } let mut err = struct_span_err!(self.session, vis.span, E0449, "unnecessary visibility qualifier"); if vis.node.is_pub() { err.span_label(vis.span, "`pub` not permitted here because it's implied"); } if let Some(note) = note { err.note(note); } err.emit(); } fn check_decl_no_pat(decl: &FnDecl, mut report_err: impl FnMut(Span, bool)) { for Param { pat, .. } in &decl.inputs { match pat.kind { PatKind::Ident(BindingMode::ByValue(Mutability::Not), _, None) | PatKind::Wild => {} PatKind::Ident(BindingMode::ByValue(Mutability::Mut), _, None) => { report_err(pat.span, true) } _ => report_err(pat.span, false), } } } fn check_trait_fn_not_async(&self, span: Span, asyncness: IsAsync) { if asyncness.is_async() { struct_span_err!(self.session, span, E0706, "trait fns cannot be declared `async`") .note("`async` trait functions are not currently supported") .note( "consider using the `async-trait` crate: \ https://crates.io/crates/async-trait", ) .emit(); } } fn check_trait_fn_not_const(&self, constness: Spanned) { if constness.node == Constness::Const { struct_span_err!( self.session, constness.span, E0379, "trait fns cannot be declared const" ) .span_label(constness.span, "trait fns cannot be const") .emit(); } } // FIXME(ecstaticmorse): Instead, use `bound_context` to check this in `visit_param_bound`. fn no_questions_in_bounds(&self, bounds: &GenericBounds, where_: &str, is_trait: bool) { for bound in bounds { if let GenericBound::Trait(ref poly, TraitBoundModifier::Maybe) = *bound { let mut err = self.err_handler().struct_span_err( poly.span, &format!("`?Trait` is not permitted in {}", where_), ); if is_trait { let path_str = pprust::path_to_string(&poly.trait_ref.path); err.note(&format!("traits are `?{}` by default", path_str)); } err.emit(); } } } /// Matches `'-' lit | lit (cf. parser::Parser::parse_literal_maybe_minus)`, /// or paths for ranges. // // FIXME: do we want to allow `expr -> pattern` conversion to create path expressions? // That means making this work: // // ```rust,ignore (FIXME) // struct S; // macro_rules! m { // ($a:expr) => { // let $a = S; // } // } // m!(S); // ``` fn check_expr_within_pat(&self, expr: &Expr, allow_paths: bool) { match expr.kind { ExprKind::Lit(..) | ExprKind::Err => {} ExprKind::Path(..) if allow_paths => {} ExprKind::Unary(UnOp::Neg, ref inner) if match inner.kind { ExprKind::Lit(_) => true, _ => false, } => {} _ => self.err_handler().span_err( expr.span, "arbitrary expressions aren't allowed \ in patterns", ), } } fn check_late_bound_lifetime_defs(&self, params: &[GenericParam]) { // Check only lifetime parameters are present and that the lifetime // parameters that are present have no bounds. let non_lt_param_spans: Vec<_> = params .iter() .filter_map(|param| match param.kind { GenericParamKind::Lifetime { .. } => { if !param.bounds.is_empty() { let spans: Vec<_> = param.bounds.iter().map(|b| b.span()).collect(); self.err_handler() .span_err(spans, "lifetime bounds cannot be used in this context"); } None } _ => Some(param.ident.span), }) .collect(); if !non_lt_param_spans.is_empty() { self.err_handler().span_err( non_lt_param_spans, "only lifetime parameters can be used in this context", ); } } fn check_fn_decl(&self, fn_decl: &FnDecl) { match &*fn_decl.inputs { [Param { ty, span, .. }] => { if let TyKind::CVarArgs = ty.kind { self.err_handler().span_err( *span, "C-variadic function must be declared with at least one named argument", ); } } [ps @ .., _] => { for Param { ty, span, .. } in ps { if let TyKind::CVarArgs = ty.kind { self.err_handler().span_err( *span, "`...` must be the last argument of a C-variadic function", ); } } } _ => {} } 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::forbid, sym::warn]; !arr.contains(&attr.name_or_empty()) && attr::is_builtin_attr(attr) }) .for_each(|attr| { if attr.is_doc_comment() { self.err_handler() .struct_span_err( attr.span, "documentation comments cannot be applied to function parameters", ) .span_label(attr.span, "doc comments are not allowed here") .emit(); } else { self.err_handler().span_err( attr.span, "allow, cfg, cfg_attr, deny, \ forbid, and warn are the only allowed built-in attributes in function parameters", ) } }); } fn check_defaultness(&self, span: Span, defaultness: Defaultness) { if let Defaultness::Default = defaultness { self.err_handler() .struct_span_err(span, "`default` is only allowed on items in `impl` definitions") .emit(); } } fn check_impl_item_provided(&self, sp: Span, body: &Option, ctx: &str, sugg: &str) { if body.is_some() { return; } self.err_handler() .struct_span_err(sp, &format!("associated {} in `impl` without body", ctx)) .span_suggestion( self.session.source_map().end_point(sp), &format!("provide a definition for the {}", ctx), sugg.to_string(), Applicability::HasPlaceholders, ) .emit(); } fn check_impl_assoc_type_no_bounds(&self, bounds: &[GenericBound]) { let span = match bounds { [] => return, [b0] => b0.span(), [b0, .., bl] => b0.span().to(bl.span()), }; self.err_handler() .struct_span_err(span, "bounds on associated `type`s in `impl`s have no effect") .emit(); } fn check_c_varadic_type(&self, decl: &FnDecl) { for Param { ty, span, .. } in &decl.inputs { if let TyKind::CVarArgs = ty.kind { self.err_handler() .struct_span_err( *span, "only foreign or `unsafe extern \"C\" functions may be C-variadic", ) .emit(); } } } } enum GenericPosition { Param, Arg, } fn validate_generics_order<'a>( sess: &Session, handler: &rustc_errors::Handler, generics: impl Iterator, Span, Option)>, pos: GenericPosition, span: Span, ) { let mut max_param: Option = None; let mut out_of_order = FxHashMap::default(); let mut param_idents = vec![]; let mut found_type = false; let mut found_const = false; for (kind, bounds, span, ident) in generics { if let Some(ident) = ident { param_idents.push((kind, bounds, param_idents.len(), ident)); } let max_param = &mut max_param; match max_param { Some(max_param) if *max_param > kind => { let entry = out_of_order.entry(kind).or_insert((*max_param, vec![])); entry.1.push(span); } Some(_) | None => *max_param = Some(kind), }; match kind { ParamKindOrd::Type => found_type = true, ParamKindOrd::Const => found_const = true, _ => {} } } let mut ordered_params = "<".to_string(); if !out_of_order.is_empty() { param_idents.sort_by_key(|&(po, _, i, _)| (po, i)); let mut first = true; for (_, bounds, _, ident) in param_idents { if !first { ordered_params += ", "; } ordered_params += &ident; if let Some(bounds) = bounds { if !bounds.is_empty() { ordered_params += ": "; ordered_params += &pprust::bounds_to_string(&bounds); } } first = false; } } ordered_params += ">"; let pos_str = match pos { GenericPosition::Param => "parameter", GenericPosition::Arg => "argument", }; for (param_ord, (max_param, spans)) in &out_of_order { let mut err = handler.struct_span_err( spans.clone(), &format!( "{} {pos}s must be declared prior to {} {pos}s", param_ord, max_param, pos = pos_str, ), ); if let GenericPosition::Param = pos { err.span_suggestion( span, &format!( "reorder the {}s: lifetimes, then types{}", pos_str, if sess.features_untracked().const_generics { ", then consts" } else { "" }, ), ordered_params.clone(), Applicability::MachineApplicable, ); } err.emit(); } // FIXME(const_generics): we shouldn't have to abort here at all, but we currently get ICEs // if we don't. Const parameters and type parameters can currently conflict if they // are out-of-order. if !out_of_order.is_empty() && found_type && found_const { FatalError.raise(); } } impl<'a> Visitor<'a> for AstValidator<'a> { fn visit_attribute(&mut self, attr: &Attribute) { validate_attr::check_meta(&self.session.parse_sess, attr); } fn visit_expr(&mut self, expr: &'a Expr) { match &expr.kind { ExprKind::Closure(_, _, _, fn_decl, _, _) => { self.check_fn_decl(fn_decl); } ExprKind::InlineAsm(..) if !self.session.target.target.options.allow_asm => { struct_span_err!( self.session, expr.span, E0472, "asm! is unsupported on this target" ) .emit(); } _ => {} } visit::walk_expr(self, expr); } fn visit_ty(&mut self, ty: &'a Ty) { match ty.kind { TyKind::BareFn(ref bfty) => { self.check_fn_decl(&bfty.decl); Self::check_decl_no_pat(&bfty.decl, |span, _| { struct_span_err!( self.session, span, E0561, "patterns aren't allowed in function pointer types" ) .emit(); }); self.check_late_bound_lifetime_defs(&bfty.generic_params); } TyKind::TraitObject(ref bounds, ..) => { let mut any_lifetime_bounds = false; for bound in bounds { if let GenericBound::Outlives(ref lifetime) = *bound { if any_lifetime_bounds { struct_span_err!( self.session, lifetime.ident.span, E0226, "only a single explicit lifetime bound is permitted" ) .emit(); break; } any_lifetime_bounds = true; } } self.no_questions_in_bounds(bounds, "trait object types", false); } TyKind::ImplTrait(_, ref bounds) => { if self.is_impl_trait_banned { struct_span_err!( self.session, ty.span, E0667, "`impl Trait` is not allowed in path parameters" ) .emit(); } if let Some(outer_impl_trait_sp) = self.outer_impl_trait { struct_span_err!( self.session, ty.span, E0666, "nested `impl Trait` is not allowed" ) .span_label(outer_impl_trait_sp, "outer `impl Trait`") .span_label(ty.span, "nested `impl Trait` here") .emit(); } if !bounds .iter() .any(|b| if let GenericBound::Trait(..) = *b { true } else { false }) { self.err_handler().span_err(ty.span, "at least one trait must be specified"); } self.walk_ty(ty); return; } _ => {} } self.walk_ty(ty) } fn visit_label(&mut self, label: &'a Label) { self.check_label(label.ident); visit::walk_label(self, label); } fn visit_lifetime(&mut self, lifetime: &'a Lifetime) { self.check_lifetime(lifetime.ident); visit::walk_lifetime(self, lifetime); } fn visit_item(&mut self, item: &'a Item) { if item.attrs.iter().any(|attr| is_proc_macro_attr(attr)) { self.has_proc_macro_decls = true; } match item.kind { ItemKind::Impl(unsafety, polarity, _, _, Some(..), ref ty, ref impl_items) => { self.invalid_visibility(&item.vis, None); if let TyKind::Err = ty.kind { self.err_handler() .struct_span_err(item.span, "`impl Trait for .. {}` is an obsolete syntax") .help("use `auto trait Trait {}` instead") .emit(); } if unsafety == Unsafety::Unsafe && polarity == ImplPolarity::Negative { struct_span_err!( self.session, item.span, E0198, "negative impls cannot be unsafe" ) .emit(); } for impl_item in impl_items { self.invalid_visibility(&impl_item.vis, None); if let AssocItemKind::Fn(ref sig, _) = impl_item.kind { self.check_trait_fn_not_const(sig.header.constness); self.check_trait_fn_not_async(impl_item.span, sig.header.asyncness.node); } } } ItemKind::Impl(unsafety, polarity, defaultness, _, None, _, _) => { self.invalid_visibility( &item.vis, Some("place qualifiers on individual impl items instead"), ); if unsafety == Unsafety::Unsafe { struct_span_err!( self.session, item.span, E0197, "inherent impls cannot be unsafe" ) .emit(); } if polarity == ImplPolarity::Negative { self.err_handler().span_err(item.span, "inherent impls cannot be negative"); } if defaultness == Defaultness::Default { self.err_handler() .struct_span_err(item.span, "inherent impls cannot be default") .note("only trait implementations may be annotated with default") .emit(); } } ItemKind::Fn(ref sig, ref generics, _) => { self.visit_fn_header(&sig.header); self.check_fn_decl(&sig.decl); // We currently do not permit const generics in `const fn`, as // this is tantamount to allowing compile-time dependent typing. if sig.header.constness.node == Constness::Const { // Look for const generics and error if we find any. for param in &generics.params { match param.kind { GenericParamKind::Const { .. } => { self.err_handler() .struct_span_err( item.span, "const parameters are not permitted in `const fn`", ) .emit(); } _ => {} } } } // Reject C-varadic type unless the function is `unsafe extern "C"` semantically. match sig.header.ext { Extern::Explicit(StrLit { symbol_unescaped: sym::C, .. }) | Extern::Implicit if sig.header.unsafety == Unsafety::Unsafe => {} _ => self.check_c_varadic_type(&sig.decl), } } ItemKind::ForeignMod(..) => { self.invalid_visibility( &item.vis, Some("place qualifiers on individual foreign items instead"), ); } ItemKind::Enum(ref def, _) => { for variant in &def.variants { self.invalid_visibility(&variant.vis, None); for field in variant.data.fields() { self.invalid_visibility(&field.vis, None); } } } ItemKind::Trait(is_auto, _, ref generics, ref bounds, ref trait_items) => { if is_auto == IsAuto::Yes { // Auto traits cannot have generics, super traits nor contain items. if !generics.params.is_empty() { struct_span_err!( self.session, item.span, E0567, "auto traits cannot have generic parameters" ) .emit(); } if !bounds.is_empty() { struct_span_err!( self.session, item.span, E0568, "auto traits cannot have super traits" ) .emit(); } if !trait_items.is_empty() { struct_span_err!( self.session, item.span, E0380, "auto traits cannot have methods or associated items" ) .emit(); } } self.no_questions_in_bounds(bounds, "supertraits", true); // Equivalent of `visit::walk_item` for `ItemKind::Trait` that inserts a bound // context for the supertraits. self.visit_vis(&item.vis); self.visit_ident(item.ident); self.visit_generics(generics); self.with_bound_context(BoundContext::TraitBounds, |this| { walk_list!(this, visit_param_bound, bounds); }); walk_list!(self, visit_trait_item, trait_items); walk_list!(self, visit_attribute, &item.attrs); return; } ItemKind::Mod(_) => { // Ensure that `path` attributes on modules are recorded as used (cf. issue #35584). attr::first_attr_value_str_by_name(&item.attrs, sym::path); } ItemKind::Union(ref vdata, _) => { if let VariantData::Tuple(..) | VariantData::Unit(..) = vdata { self.err_handler() .span_err(item.span, "tuple and unit unions are not permitted"); } if vdata.fields().is_empty() { self.err_handler().span_err(item.span, "unions cannot have zero fields"); } } _ => {} } visit::walk_item(self, item) } fn visit_foreign_item(&mut self, fi: &'a ForeignItem) { match fi.kind { ForeignItemKind::Fn(ref decl, _) => { self.check_fn_decl(decl); Self::check_decl_no_pat(decl, |span, _| { struct_span_err!( self.session, span, E0130, "patterns aren't allowed in foreign function declarations" ) .span_label(span, "pattern not allowed in foreign function") .emit(); }); } ForeignItemKind::Static(..) | ForeignItemKind::Ty | ForeignItemKind::Macro(..) => {} } visit::walk_foreign_item(self, fi) } // Mirrors `visit::walk_generic_args`, but tracks relevant state. fn visit_generic_args(&mut self, _: Span, generic_args: &'a GenericArgs) { match *generic_args { GenericArgs::AngleBracketed(ref data) => { walk_list!(self, visit_generic_arg, &data.args); validate_generics_order( self.session, self.err_handler(), data.args.iter().map(|arg| { ( match arg { GenericArg::Lifetime(..) => ParamKindOrd::Lifetime, GenericArg::Type(..) => ParamKindOrd::Type, GenericArg::Const(..) => ParamKindOrd::Const, }, None, arg.span(), None, ) }), GenericPosition::Arg, generic_args.span(), ); // Type bindings such as `Item = impl Debug` in `Iterator` // are allowed to contain nested `impl Trait`. self.with_impl_trait(None, |this| { walk_list!( this, visit_assoc_ty_constraint_from_generic_args, &data.constraints ); }); } GenericArgs::Parenthesized(ref data) => { walk_list!(self, visit_ty, &data.inputs); if let FunctionRetTy::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)); } } } } fn visit_generics(&mut self, generics: &'a Generics) { let mut prev_ty_default = None; for param in &generics.params { if let GenericParamKind::Type { ref default, .. } = param.kind { if default.is_some() { prev_ty_default = Some(param.ident.span); } else if let Some(span) = prev_ty_default { self.err_handler() .span_err(span, "type parameters with a default must be trailing"); break; } } } validate_generics_order( self.session, self.err_handler(), generics.params.iter().map(|param| { let ident = Some(param.ident.to_string()); let (kind, ident) = match ¶m.kind { GenericParamKind::Lifetime { .. } => (ParamKindOrd::Lifetime, ident), GenericParamKind::Type { .. } => (ParamKindOrd::Type, ident), GenericParamKind::Const { ref ty } => { let ty = pprust::ty_to_string(ty); (ParamKindOrd::Const, Some(format!("const {}: {}", param.ident, ty))) } }; (kind, Some(&*param.bounds), param.ident.span, ident) }), GenericPosition::Param, generics.span, ); for predicate in &generics.where_clause.predicates { if let WherePredicate::EqPredicate(ref predicate) = *predicate { self.err_handler() .struct_span_err( predicate.span, "equality constraints are not yet supported in `where` clauses", ) .span_label(predicate.span, "not supported") .note( "for more information, see https://github.com/rust-lang/rust/issues/20041", ) .emit(); } } visit::walk_generics(self, generics) } fn visit_generic_param(&mut self, param: &'a GenericParam) { if let GenericParamKind::Lifetime { .. } = param.kind { self.check_lifetime(param.ident); } visit::walk_generic_param(self, param); } fn visit_param_bound(&mut self, bound: &'a GenericBound) { if let GenericBound::Trait(poly, maybe_bound) = bound { match poly.trait_ref.constness { Some(Constness::NotConst) => { if *maybe_bound == TraitBoundModifier::Maybe { self.err_handler() .span_err(bound.span(), "`?const` and `?` are mutually exclusive"); } if let Some(ctx) = self.bound_context { let msg = format!("`?const` is not permitted in {}", ctx.description()); self.err_handler().span_err(bound.span(), &msg); } } Some(Constness::Const) => panic!("Parser should reject bare `const` on bounds"), None => {} } } visit::walk_param_bound(self, bound) } fn visit_pat(&mut self, pat: &'a Pat) { match pat.kind { PatKind::Lit(ref expr) => { self.check_expr_within_pat(expr, false); } PatKind::Range(ref start, ref end, _) => { if let Some(expr) = start { self.check_expr_within_pat(expr, true); } if let Some(expr) = end { self.check_expr_within_pat(expr, true); } } _ => {} } visit::walk_pat(self, pat) } fn visit_where_predicate(&mut self, p: &'a WherePredicate) { if let &WherePredicate::BoundPredicate(ref bound_predicate) = p { // A type binding, eg `for<'c> Foo: Send+Clone+'c` self.check_late_bound_lifetime_defs(&bound_predicate.bound_generic_params); } visit::walk_where_predicate(self, p); } fn visit_poly_trait_ref(&mut self, t: &'a PolyTraitRef, m: &'a TraitBoundModifier) { self.check_late_bound_lifetime_defs(&t.bound_generic_params); visit::walk_poly_trait_ref(self, t, m); } fn visit_variant_data(&mut self, s: &'a VariantData) { self.with_banned_assoc_ty_bound(|this| visit::walk_struct_def(this, s)) } fn visit_enum_def( &mut self, enum_definition: &'a EnumDef, generics: &'a Generics, item_id: NodeId, _: Span, ) { self.with_banned_assoc_ty_bound(|this| { visit::walk_enum_def(this, enum_definition, generics, item_id) }) } fn visit_impl_item(&mut self, ii: &'a AssocItem) { match &ii.kind { AssocItemKind::Const(_, body) => { self.check_impl_item_provided(ii.span, body, "constant", " = ;"); } AssocItemKind::Fn(sig, body) => { self.check_impl_item_provided(ii.span, body, "function", " { }"); self.check_fn_decl(&sig.decl); } AssocItemKind::TyAlias(bounds, body) => { self.check_impl_item_provided(ii.span, body, "type", " = ;"); self.check_impl_assoc_type_no_bounds(bounds); } _ => {} } visit::walk_impl_item(self, ii); } fn visit_trait_item(&mut self, ti: &'a AssocItem) { self.invalid_visibility(&ti.vis, None); self.check_defaultness(ti.span, ti.defaultness); if let AssocItemKind::Fn(sig, block) = &ti.kind { self.check_fn_decl(&sig.decl); self.check_trait_fn_not_async(ti.span, sig.header.asyncness.node); self.check_trait_fn_not_const(sig.header.constness); if block.is_none() { Self::check_decl_no_pat(&sig.decl, |span, mut_ident| { if mut_ident { self.lint_buffer.buffer_lint( PATTERNS_IN_FNS_WITHOUT_BODY, ti.id, span, "patterns aren't allowed in methods without bodies", ); } else { struct_span_err!( self.session, span, E0642, "patterns aren't allowed in methods without bodies" ) .emit(); } }); } } visit::walk_trait_item(self, ti); } fn visit_assoc_item(&mut self, item: &'a AssocItem) { if let AssocItemKind::Fn(sig, _) = &item.kind { self.check_c_varadic_type(&sig.decl); } visit::walk_assoc_item(self, item); } } pub fn check_crate(session: &Session, krate: &Crate, lints: &mut LintBuffer) -> bool { let mut validator = AstValidator { session, has_proc_macro_decls: false, outer_impl_trait: None, bound_context: None, is_impl_trait_banned: false, is_assoc_ty_bound_banned: false, lint_buffer: lints, }; visit::walk_crate(&mut validator, krate); validator.has_proc_macro_decls }