// Copyright 2016 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use {AmbiguityError, CrateLint, Resolver, ResolutionError, resolve_error}; use {Module, ModuleKind, NameBinding, NameBindingKind, PathResult}; use Namespace::{self, MacroNS}; use build_reduced_graph::BuildReducedGraphVisitor; use resolve_imports::ImportResolver; use rustc::hir::def_id::{DefId, BUILTIN_MACROS_CRATE, CRATE_DEF_INDEX, DefIndex, DefIndexAddressSpace}; use rustc::hir::def::{Def, Export}; use rustc::hir::map::{self, DefCollector}; use rustc::{ty, lint}; use syntax::ast::{self, Name, Ident}; use syntax::attr::{self, HasAttrs}; use syntax::errors::DiagnosticBuilder; use syntax::ext::base::{self, Annotatable, Determinacy, MultiModifier, MultiDecorator}; use syntax::ext::base::{MacroKind, SyntaxExtension, Resolver as SyntaxResolver}; use syntax::ext::expand::{self, AstFragment, AstFragmentKind, Invocation, InvocationKind}; use syntax::ext::hygiene::{self, Mark, Transparency}; use syntax::ext::placeholders::placeholder; use syntax::ext::tt::macro_rules; use syntax::feature_gate::{self, emit_feature_err, GateIssue}; use syntax::fold::{self, Folder}; use syntax::parse::parser::PathStyle; use syntax::parse::token::{self, Token}; use syntax::ptr::P; use syntax::symbol::{Symbol, keywords}; use syntax::tokenstream::{TokenStream, TokenTree, Delimited}; use syntax::util::lev_distance::find_best_match_for_name; use syntax_pos::{Span, DUMMY_SP}; use std::cell::Cell; use std::mem; use rustc_data_structures::sync::Lrc; #[derive(Clone)] pub struct InvocationData<'a> { pub module: Cell>, pub def_index: DefIndex, // The scope in which the invocation path is resolved. pub legacy_scope: Cell>, // The smallest scope that includes this invocation's expansion, // or `Empty` if this invocation has not been expanded yet. pub expansion: Cell>, } impl<'a> InvocationData<'a> { pub fn root(graph_root: Module<'a>) -> Self { InvocationData { module: Cell::new(graph_root), def_index: CRATE_DEF_INDEX, legacy_scope: Cell::new(LegacyScope::Empty), expansion: Cell::new(LegacyScope::Empty), } } } #[derive(Copy, Clone)] pub enum LegacyScope<'a> { Empty, Invocation(&'a InvocationData<'a>), // The scope of the invocation, not including its expansion Expansion(&'a InvocationData<'a>), // The scope of the invocation, including its expansion Binding(&'a LegacyBinding<'a>), } pub struct LegacyBinding<'a> { pub parent: Cell>, pub ident: Ident, def_id: DefId, pub span: Span, } pub struct ProcMacError { crate_name: Symbol, name: Symbol, module: ast::NodeId, use_span: Span, warn_msg: &'static str, } #[derive(Copy, Clone)] pub enum MacroBinding<'a> { Legacy(&'a LegacyBinding<'a>), Global(&'a NameBinding<'a>), Modern(&'a NameBinding<'a>), } impl<'a> MacroBinding<'a> { pub fn span(self) -> Span { match self { MacroBinding::Legacy(binding) => binding.span, MacroBinding::Global(binding) | MacroBinding::Modern(binding) => binding.span, } } pub fn binding(self) -> &'a NameBinding<'a> { match self { MacroBinding::Global(binding) | MacroBinding::Modern(binding) => binding, MacroBinding::Legacy(_) => panic!("unexpected MacroBinding::Legacy"), } } pub fn def_ignoring_ambiguity(self) -> Def { match self { MacroBinding::Legacy(binding) => Def::Macro(binding.def_id, MacroKind::Bang), MacroBinding::Global(binding) | MacroBinding::Modern(binding) => binding.def_ignoring_ambiguity(), } } } impl<'a> base::Resolver for Resolver<'a> { fn next_node_id(&mut self) -> ast::NodeId { self.session.next_node_id() } fn get_module_scope(&mut self, id: ast::NodeId) -> Mark { let mark = Mark::fresh(Mark::root()); let module = self.module_map[&self.definitions.local_def_id(id)]; self.invocations.insert(mark, self.arenas.alloc_invocation_data(InvocationData { module: Cell::new(module), def_index: module.def_id().unwrap().index, legacy_scope: Cell::new(LegacyScope::Empty), expansion: Cell::new(LegacyScope::Empty), })); mark } fn eliminate_crate_var(&mut self, item: P) -> P { struct EliminateCrateVar<'b, 'a: 'b>(&'b mut Resolver<'a>, Span); impl<'a, 'b> Folder for EliminateCrateVar<'a, 'b> { fn fold_path(&mut self, path: ast::Path) -> ast::Path { match self.fold_qpath(None, path) { (None, path) => path, _ => unreachable!(), } } fn fold_qpath(&mut self, mut qself: Option, mut path: ast::Path) -> (Option, ast::Path) { qself = qself.map(|ast::QSelf { ty, path_span, position }| { ast::QSelf { ty: self.fold_ty(ty), path_span: self.new_span(path_span), position, } }); if path.segments[0].ident.name == keywords::DollarCrate.name() { let module = self.0.resolve_crate_root(path.segments[0].ident); path.segments[0].ident.name = keywords::CrateRoot.name(); if !module.is_local() { let span = path.segments[0].ident.span; path.segments.insert(1, match module.kind { ModuleKind::Def(_, name) => ast::PathSegment::from_ident( ast::Ident::with_empty_ctxt(name).with_span_pos(span) ), _ => unreachable!(), }); if let Some(qself) = &mut qself { qself.position += 1; } } } (qself, path) } fn fold_mac(&mut self, mac: ast::Mac) -> ast::Mac { fold::noop_fold_mac(mac, self) } } EliminateCrateVar(self, item.span).fold_item(item).expect_one("") } fn is_whitelisted_legacy_custom_derive(&self, name: Name) -> bool { self.whitelisted_legacy_custom_derives.contains(&name) } fn visit_ast_fragment_with_placeholders(&mut self, mark: Mark, fragment: &AstFragment, derives: &[Mark]) { let invocation = self.invocations[&mark]; self.collect_def_ids(mark, invocation, fragment); self.current_module = invocation.module.get(); self.current_module.unresolved_invocations.borrow_mut().remove(&mark); self.current_module.unresolved_invocations.borrow_mut().extend(derives); for &derive in derives { self.invocations.insert(derive, invocation); } let mut visitor = BuildReducedGraphVisitor { resolver: self, legacy_scope: LegacyScope::Invocation(invocation), expansion: mark, }; fragment.visit_with(&mut visitor); invocation.expansion.set(visitor.legacy_scope); } fn add_builtin(&mut self, ident: ast::Ident, ext: Lrc) { let def_id = DefId { krate: BUILTIN_MACROS_CRATE, index: DefIndex::from_array_index(self.macro_map.len(), DefIndexAddressSpace::Low), }; let kind = ext.kind(); self.macro_map.insert(def_id, ext); let binding = self.arenas.alloc_name_binding(NameBinding { kind: NameBindingKind::Def(Def::Macro(def_id, kind)), span: DUMMY_SP, vis: ty::Visibility::Invisible, expansion: Mark::root(), }); self.global_macros.insert(ident.name, binding); } fn resolve_imports(&mut self) { ImportResolver { resolver: self }.resolve_imports() } // Resolves attribute and derive legacy macros from `#![plugin(..)]`. fn find_legacy_attr_invoc(&mut self, attrs: &mut Vec, allow_derive: bool) -> Option { for i in 0..attrs.len() { let name = attrs[i].name(); if self.session.plugin_attributes.borrow().iter() .any(|&(ref attr_nm, _)| name == &**attr_nm) { attr::mark_known(&attrs[i]); } match self.global_macros.get(&name).cloned() { Some(binding) => match *binding.get_macro(self) { MultiModifier(..) | MultiDecorator(..) | SyntaxExtension::AttrProcMacro(..) => { return Some(attrs.remove(i)) } _ => {} }, None => {} } } if !allow_derive { return None } // Check for legacy derives for i in 0..attrs.len() { let name = attrs[i].name(); if name == "derive" { let result = attrs[i].parse_list(&self.session.parse_sess, |parser| { parser.parse_path_allowing_meta(PathStyle::Mod) }); let mut traits = match result { Ok(traits) => traits, Err(mut e) => { e.cancel(); continue } }; for j in 0..traits.len() { if traits[j].segments.len() > 1 { continue } let trait_name = traits[j].segments[0].ident.name; let legacy_name = Symbol::intern(&format!("derive_{}", trait_name)); if !self.global_macros.contains_key(&legacy_name) { continue } let span = traits.remove(j).span; self.gate_legacy_custom_derive(legacy_name, span); if traits.is_empty() { attrs.remove(i); } else { let mut tokens = Vec::new(); for (j, path) in traits.iter().enumerate() { if j > 0 { tokens.push(TokenTree::Token(attrs[i].span, Token::Comma).into()); } for (k, segment) in path.segments.iter().enumerate() { if k > 0 { tokens.push(TokenTree::Token(path.span, Token::ModSep).into()); } let tok = Token::from_ast_ident(segment.ident); tokens.push(TokenTree::Token(path.span, tok).into()); } } attrs[i].tokens = TokenTree::Delimited(attrs[i].span, Delimited { delim: token::Paren, tts: TokenStream::concat(tokens).into(), }).into(); } return Some(ast::Attribute { path: ast::Path::from_ident(Ident::new(legacy_name, span)), tokens: TokenStream::empty(), id: attr::mk_attr_id(), style: ast::AttrStyle::Outer, is_sugared_doc: false, span, }); } } } None } fn resolve_invoc(&mut self, invoc: &mut Invocation, scope: Mark, force: bool) -> Result>, Determinacy> { let def = match invoc.kind { InvocationKind::Attr { attr: None, .. } => return Ok(None), _ => self.resolve_invoc_to_def(invoc, scope, force)?, }; let def_id = def.def_id(); self.macro_defs.insert(invoc.expansion_data.mark, def_id); let normal_module_def_id = self.macro_def_scope(invoc.expansion_data.mark).normal_ancestor_id; self.definitions.add_parent_module_of_macro_def(invoc.expansion_data.mark, normal_module_def_id); self.unused_macros.remove(&def_id); let ext = self.get_macro(def); if ext.is_modern() { let transparency = if ext.is_transparent() { Transparency::Transparent } else { Transparency::Opaque }; invoc.expansion_data.mark.set_transparency(transparency); } else if def_id.krate == BUILTIN_MACROS_CRATE { invoc.expansion_data.mark.set_is_builtin(true); } Ok(Some(ext)) } fn resolve_macro(&mut self, scope: Mark, path: &ast::Path, kind: MacroKind, force: bool) -> Result, Determinacy> { self.resolve_macro_to_def(scope, path, kind, force).map(|def| { self.unused_macros.remove(&def.def_id()); self.get_macro(def) }) } fn check_unused_macros(&self) { for did in self.unused_macros.iter() { let id_span = match *self.macro_map[did] { SyntaxExtension::NormalTT { def_info, .. } | SyntaxExtension::DeclMacro { def_info, .. } => def_info, _ => None, }; if let Some((id, span)) = id_span { let lint = lint::builtin::UNUSED_MACROS; let msg = "unused macro definition"; self.session.buffer_lint(lint, id, span, msg); } else { bug!("attempted to create unused macro error, but span not available"); } } } } impl<'a> Resolver<'a> { fn resolve_invoc_to_def(&mut self, invoc: &mut Invocation, scope: Mark, force: bool) -> Result { let (attr, traits, item) = match invoc.kind { InvocationKind::Attr { ref mut attr, ref traits, ref mut item } => (attr, traits, item), InvocationKind::Bang { ref mac, .. } => { return self.resolve_macro_to_def(scope, &mac.node.path, MacroKind::Bang, force); } InvocationKind::Derive { ref path, .. } => { return self.resolve_macro_to_def(scope, path, MacroKind::Derive, force); } }; let path = attr.as_ref().unwrap().path.clone(); let mut determinacy = Determinacy::Determined; match self.resolve_macro_to_def(scope, &path, MacroKind::Attr, force) { Ok(def) => return Ok(def), Err(Determinacy::Undetermined) => determinacy = Determinacy::Undetermined, Err(Determinacy::Determined) if force => return Err(Determinacy::Determined), Err(Determinacy::Determined) => {} } let attr_name = match path.segments.len() { 1 => path.segments[0].ident.name, _ => return Err(determinacy), }; for path in traits { match self.resolve_macro(scope, path, MacroKind::Derive, force) { Ok(ext) => if let SyntaxExtension::ProcMacroDerive(_, ref inert_attrs, _) = *ext { if inert_attrs.contains(&attr_name) { // FIXME(jseyfried) Avoid `mem::replace` here. let dummy_item = placeholder(AstFragmentKind::Items, ast::DUMMY_NODE_ID) .make_items().pop().unwrap(); let dummy_item = Annotatable::Item(dummy_item); *item = mem::replace(item, dummy_item).map_attrs(|mut attrs| { let inert_attr = attr.take().unwrap(); attr::mark_known(&inert_attr); if self.proc_macro_enabled { *attr = expand::find_attr_invoc(&mut attrs); } attrs.push(inert_attr); attrs }); } return Err(Determinacy::Undetermined); }, Err(Determinacy::Undetermined) => determinacy = Determinacy::Undetermined, Err(Determinacy::Determined) => {} } } Err(determinacy) } fn resolve_macro_to_def(&mut self, scope: Mark, path: &ast::Path, kind: MacroKind, force: bool) -> Result { if kind != MacroKind::Bang && path.segments.len() > 1 { if !self.session.features_untracked().proc_macro_path_invoc { emit_feature_err( &self.session.parse_sess, "proc_macro_path_invoc", path.span, GateIssue::Language, "paths of length greater than one in macro invocations are \ currently unstable", ); } } let def = self.resolve_macro_to_def_inner(scope, path, kind, force); if def != Err(Determinacy::Undetermined) { // Do not report duplicated errors on every undetermined resolution. path.segments.iter().find(|segment| segment.args.is_some()).map(|segment| { self.session.span_err(segment.args.as_ref().unwrap().span(), "generic arguments in macro path"); }); } def } pub fn resolve_macro_to_def_inner(&mut self, scope: Mark, path: &ast::Path, kind: MacroKind, force: bool) -> Result { let ast::Path { ref segments, span } = *path; let mut path: Vec<_> = segments.iter().map(|seg| seg.ident).collect(); let invocation = self.invocations[&scope]; let module = invocation.module.get(); self.current_module = if module.is_trait() { module.parent.unwrap() } else { module }; // Possibly apply the macro helper hack if self.use_extern_macros && kind == MacroKind::Bang && path.len() == 1 && path[0].span.ctxt().outer().expn_info().map_or(false, |info| info.local_inner_macros) { let root = Ident::new(keywords::DollarCrate.name(), path[0].span); path.insert(0, root); } if path.len() > 1 { if !self.use_extern_macros && self.gated_errors.insert(span) { let msg = "non-ident macro paths are experimental"; let feature = "use_extern_macros"; emit_feature_err(&self.session.parse_sess, feature, span, GateIssue::Language, msg); self.found_unresolved_macro = true; return Err(Determinacy::Determined); } let def = match self.resolve_path(&path, Some(MacroNS), false, span, CrateLint::No) { PathResult::NonModule(path_res) => match path_res.base_def() { Def::Err => Err(Determinacy::Determined), def @ _ => { if path_res.unresolved_segments() > 0 { self.found_unresolved_macro = true; self.session.span_err(span, "fail to resolve non-ident macro path"); Err(Determinacy::Determined) } else { Ok(def) } } }, PathResult::Module(..) => unreachable!(), PathResult::Indeterminate if !force => return Err(Determinacy::Undetermined), _ => { self.found_unresolved_macro = true; Err(Determinacy::Determined) }, }; self.current_module.nearest_item_scope().macro_resolutions.borrow_mut() .push((path.into_boxed_slice(), span)); return def; } let legacy_resolution = self.resolve_legacy_scope(&invocation.legacy_scope, path[0], false); let result = if let Some(MacroBinding::Legacy(binding)) = legacy_resolution { Ok(Def::Macro(binding.def_id, MacroKind::Bang)) } else { match self.resolve_lexical_macro_path_segment(path[0], MacroNS, false, span) { Ok(binding) => Ok(binding.binding().def_ignoring_ambiguity()), Err(Determinacy::Undetermined) if !force => return Err(Determinacy::Undetermined), Err(_) => { self.found_unresolved_macro = true; Err(Determinacy::Determined) } } }; self.current_module.nearest_item_scope().legacy_macro_resolutions.borrow_mut() .push((scope, path[0], kind, result.ok())); result } // Resolve the initial segment of a non-global macro path (e.g. `foo` in `foo::bar!();`) pub fn resolve_lexical_macro_path_segment(&mut self, mut ident: Ident, ns: Namespace, record_used: bool, path_span: Span) -> Result, Determinacy> { ident = ident.modern(); let mut module = Some(self.current_module); let mut potential_illegal_shadower = Err(Determinacy::Determined); let determinacy = if record_used { Determinacy::Determined } else { Determinacy::Undetermined }; loop { let orig_current_module = self.current_module; let result = if let Some(module) = module { self.current_module = module; // Lexical resolutions can never be a privacy error. // Since expanded macros may not shadow the lexical scope and // globs may not shadow global macros (both enforced below), // we resolve with restricted shadowing (indicated by the penultimate argument). self.resolve_ident_in_module_unadjusted( module, ident, ns, true, record_used, path_span, ).map(MacroBinding::Modern) } else { self.global_macros.get(&ident.name).cloned().ok_or(determinacy) .map(MacroBinding::Global) }; self.current_module = orig_current_module; match result.map(MacroBinding::binding) { Ok(binding) => { if !record_used { return result; } if let Ok(MacroBinding::Modern(shadower)) = potential_illegal_shadower { if shadower.def() != binding.def() { let name = ident.name; self.ambiguity_errors.push(AmbiguityError { span: path_span, name, b1: shadower, b2: binding, lexical: true, }); return potential_illegal_shadower; } } if binding.expansion != Mark::root() || (binding.is_glob_import() && module.unwrap().def().is_some()) { potential_illegal_shadower = result; } else { return result; } }, Err(Determinacy::Undetermined) => return Err(Determinacy::Undetermined), Err(Determinacy::Determined) => {} } module = match module { Some(module) => self.hygienic_lexical_parent(module, &mut ident.span), None => return potential_illegal_shadower, } } } pub fn resolve_legacy_scope(&mut self, mut scope: &'a Cell>, ident: Ident, record_used: bool) -> Option> { let ident = ident.modern(); let mut possible_time_travel = None; let mut relative_depth: u32 = 0; let mut binding = None; loop { match scope.get() { LegacyScope::Empty => break, LegacyScope::Expansion(invocation) => { match invocation.expansion.get() { LegacyScope::Invocation(_) => scope.set(invocation.legacy_scope.get()), LegacyScope::Empty => { if possible_time_travel.is_none() { possible_time_travel = Some(scope); } scope = &invocation.legacy_scope; } _ => { relative_depth += 1; scope = &invocation.expansion; } } } LegacyScope::Invocation(invocation) => { relative_depth = relative_depth.saturating_sub(1); scope = &invocation.legacy_scope; } LegacyScope::Binding(potential_binding) => { if potential_binding.ident == ident { if (!self.use_extern_macros || record_used) && relative_depth > 0 { self.disallowed_shadowing.push(potential_binding); } binding = Some(potential_binding); break } scope = &potential_binding.parent; } }; } let binding = if let Some(binding) = binding { MacroBinding::Legacy(binding) } else if let Some(binding) = self.global_macros.get(&ident.name).cloned() { if !self.use_extern_macros { self.record_use(ident, MacroNS, binding, DUMMY_SP); } MacroBinding::Global(binding) } else { return None; }; if !self.use_extern_macros { if let Some(scope) = possible_time_travel { // Check for disallowed shadowing later self.lexical_macro_resolutions.push((ident, scope)); } } Some(binding) } pub fn finalize_current_module_macro_resolutions(&mut self) { let module = self.current_module; for &(ref path, span) in module.macro_resolutions.borrow().iter() { match self.resolve_path(&path, Some(MacroNS), true, span, CrateLint::No) { PathResult::NonModule(_) => {}, PathResult::Failed(span, msg, _) => { resolve_error(self, span, ResolutionError::FailedToResolve(&msg)); } _ => unreachable!(), } } for &(mark, ident, kind, def) in module.legacy_macro_resolutions.borrow().iter() { let span = ident.span; let legacy_scope = &self.invocations[&mark].legacy_scope; let legacy_resolution = self.resolve_legacy_scope(legacy_scope, ident, true); let resolution = self.resolve_lexical_macro_path_segment(ident, MacroNS, true, span); let check_consistency = |this: &Self, binding: MacroBinding| { if let Some(def) = def { if this.ambiguity_errors.is_empty() && this.disallowed_shadowing.is_empty() && binding.def_ignoring_ambiguity() != def { // Make sure compilation does not succeed if preferred macro resolution // has changed after the macro had been expanded. In theory all such // situations should be reported as ambiguity errors, so this is span-bug. span_bug!(span, "inconsistent resolution for a macro"); } } else { // It's possible that the macro was unresolved (indeterminate) and silently // expanded into a dummy fragment for recovery during expansion. // Now, post-expansion, the resolution may succeed, but we can't change the // past and need to report an error. let msg = format!("cannot determine resolution for the {} `{}`", kind.descr(), ident); let msg_note = "import resolution is stuck, try simplifying macro imports"; this.session.struct_span_err(span, &msg).note(msg_note).emit(); } }; match (legacy_resolution, resolution) { (Some(MacroBinding::Legacy(legacy_binding)), Ok(MacroBinding::Modern(binding))) => { let msg1 = format!("`{}` could refer to the macro defined here", ident); let msg2 = format!("`{}` could also refer to the macro imported here", ident); self.session.struct_span_err(span, &format!("`{}` is ambiguous", ident)) .span_note(legacy_binding.span, &msg1) .span_note(binding.span, &msg2) .emit(); }, (None, Err(_)) => { assert!(def.is_none()); let bang = if kind == MacroKind::Bang { "!" } else { "" }; let msg = format!("cannot find {} `{}{}` in this scope", kind.descr(), ident, bang); let mut err = self.session.struct_span_err(span, &msg); self.suggest_macro_name(&ident.as_str(), kind, &mut err, span); err.emit(); }, (Some(MacroBinding::Modern(_)), _) | (_, Ok(MacroBinding::Legacy(_))) => { span_bug!(span, "impossible macro resolution result"); } // OK, unambiguous resolution (Some(binding), Err(_)) | (None, Ok(binding)) | // OK, legacy wins over global even if their definitions are different (Some(binding @ MacroBinding::Legacy(_)), Ok(MacroBinding::Global(_))) | // OK, modern wins over global even if their definitions are different (Some(MacroBinding::Global(_)), Ok(binding @ MacroBinding::Modern(_))) => { check_consistency(self, binding); } (Some(MacroBinding::Global(binding1)), Ok(MacroBinding::Global(binding2))) => { if binding1.def() != binding2.def() { span_bug!(span, "mismatch between same global macro resolutions"); } check_consistency(self, MacroBinding::Global(binding1)); self.record_use(ident, MacroNS, binding1, span); self.err_if_macro_use_proc_macro(ident.name, span, binding1); }, }; } } fn suggest_macro_name(&mut self, name: &str, kind: MacroKind, err: &mut DiagnosticBuilder<'a>, span: Span) { // First check if this is a locally-defined bang macro. let suggestion = if let MacroKind::Bang = kind { find_best_match_for_name(self.macro_names.iter().map(|ident| &ident.name), name, None) } else { None // Then check global macros. }.or_else(|| { // FIXME: get_macro needs an &mut Resolver, can we do it without cloning? let global_macros = self.global_macros.clone(); let names = global_macros.iter().filter_map(|(name, binding)| { if binding.get_macro(self).kind() == kind { Some(name) } else { None } }); find_best_match_for_name(names, name, None) // Then check modules. }).or_else(|| { if !self.use_extern_macros { return None; } let is_macro = |def| { if let Def::Macro(_, def_kind) = def { def_kind == kind } else { false } }; let ident = Ident::new(Symbol::intern(name), span); self.lookup_typo_candidate(&vec![ident], MacroNS, is_macro, span) }); if let Some(suggestion) = suggestion { if suggestion != name { if let MacroKind::Bang = kind { err.span_suggestion(span, "you could try the macro", suggestion.to_string()); } else { err.span_suggestion(span, "try", suggestion.to_string()); } } else { err.help("have you added the `#[macro_use]` on the module/import?"); } } } fn collect_def_ids(&mut self, mark: Mark, invocation: &'a InvocationData<'a>, fragment: &AstFragment) { let Resolver { ref mut invocations, arenas, graph_root, .. } = *self; let InvocationData { def_index, .. } = *invocation; let visit_macro_invoc = &mut |invoc: map::MacroInvocationData| { invocations.entry(invoc.mark).or_insert_with(|| { arenas.alloc_invocation_data(InvocationData { def_index: invoc.def_index, module: Cell::new(graph_root), expansion: Cell::new(LegacyScope::Empty), legacy_scope: Cell::new(LegacyScope::Empty), }) }); }; let mut def_collector = DefCollector::new(&mut self.definitions, mark); def_collector.visit_macro_invoc = Some(visit_macro_invoc); def_collector.with_parent(def_index, |def_collector| { fragment.visit_with(def_collector) }); } pub fn define_macro(&mut self, item: &ast::Item, expansion: Mark, legacy_scope: &mut LegacyScope<'a>) { self.local_macro_def_scopes.insert(item.id, self.current_module); let ident = item.ident; if ident.name == "macro_rules" { self.session.span_err(item.span, "user-defined macros may not be named `macro_rules`"); } let def_id = self.definitions.local_def_id(item.id); let ext = Lrc::new(macro_rules::compile(&self.session.parse_sess, &self.session.features_untracked(), item, hygiene::default_edition())); self.macro_map.insert(def_id, ext); let def = match item.node { ast::ItemKind::MacroDef(ref def) => def, _ => unreachable!() }; if def.legacy { let ident = ident.modern(); self.macro_names.insert(ident); *legacy_scope = LegacyScope::Binding(self.arenas.alloc_legacy_binding(LegacyBinding { parent: Cell::new(*legacy_scope), ident: ident, def_id: def_id, span: item.span, })); let def = Def::Macro(def_id, MacroKind::Bang); self.all_macros.insert(ident.name, def); if attr::contains_name(&item.attrs, "macro_export") { self.macro_exports.push(Export { ident: ident.modern(), def: def, vis: ty::Visibility::Public, span: item.span, }); } else { self.unused_macros.insert(def_id); } } else { let module = self.current_module; let def = Def::Macro(def_id, MacroKind::Bang); let vis = self.resolve_visibility(&item.vis); if vis != ty::Visibility::Public { self.unused_macros.insert(def_id); } self.define(module, ident, MacroNS, (def, vis, item.span, expansion)); } } /// Error if `ext` is a Macros 1.1 procedural macro being imported by `#[macro_use]` fn err_if_macro_use_proc_macro(&mut self, name: Name, use_span: Span, binding: &NameBinding<'a>) { let krate = binding.def().def_id().krate; // Plugin-based syntax extensions are exempt from this check if krate == BUILTIN_MACROS_CRATE { return; } let ext = binding.get_macro(self); match *ext { // If `ext` is a procedural macro, check if we've already warned about it SyntaxExtension::AttrProcMacro(..) | SyntaxExtension::ProcMacro { .. } => if !self.warned_proc_macros.insert(name) { return; }, _ => return, } let warn_msg = match *ext { SyntaxExtension::AttrProcMacro(..) => "attribute procedural macros cannot be imported with `#[macro_use]`", SyntaxExtension::ProcMacro { .. } => "procedural macros cannot be imported with `#[macro_use]`", _ => return, }; let def_id = self.current_module.normal_ancestor_id; let node_id = self.definitions.as_local_node_id(def_id).unwrap(); self.proc_mac_errors.push(ProcMacError { crate_name: self.cstore.crate_name_untracked(krate), name, module: node_id, use_span, warn_msg, }); } pub fn report_proc_macro_import(&mut self, krate: &ast::Crate) { for err in self.proc_mac_errors.drain(..) { let (span, found_use) = ::UsePlacementFinder::check(krate, err.module); if let Some(span) = span { let found_use = if found_use { "" } else { "\n" }; self.session.struct_span_err(err.use_span, err.warn_msg) .span_suggestion( span, "instead, import the procedural macro like any other item", format!("use {}::{};{}", err.crate_name, err.name, found_use), ).emit(); } else { self.session.struct_span_err(err.use_span, err.warn_msg) .help(&format!("instead, import the procedural macro like any other item: \ `use {}::{};`", err.crate_name, err.name)) .emit(); } } } fn gate_legacy_custom_derive(&mut self, name: Symbol, span: Span) { if !self.session.features_untracked().custom_derive { let sess = &self.session.parse_sess; let explain = feature_gate::EXPLAIN_CUSTOM_DERIVE; emit_feature_err(sess, "custom_derive", span, GateIssue::Language, explain); } else if !self.is_whitelisted_legacy_custom_derive(name) { self.session.span_warn(span, feature_gate::EXPLAIN_DEPR_CUSTOM_DERIVE); } } }