// Copyright 2012-2014 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. //! Reduced graph building //! //! Here we build the "reduced graph": the graph of the module tree without //! any imports resolved. use DefModifiers; use resolve_imports::ImportDirectiveSubclass::{self, GlobImport}; use Module; use Namespace::{self, TypeNS, ValueNS}; use {NameBinding, NameBindingKind}; use ParentLink::{ModuleParentLink, BlockParentLink}; use Resolver; use {resolve_error, resolve_struct_error, ResolutionError}; use rustc::middle::cstore::{CrateStore, ChildItem, DlDef}; use rustc::lint; use rustc::middle::def::*; use rustc::middle::def_id::{CRATE_DEF_INDEX, DefId}; use rustc::ty::VariantKind; use syntax::ast::Name; use syntax::attr::AttrMetaMethods; use syntax::parse::token::{special_idents, SELF_KEYWORD_NAME, SUPER_KEYWORD_NAME}; use syntax::codemap::{Span, DUMMY_SP}; use rustc::hir; use rustc::hir::{Block, DeclItem}; use rustc::hir::{ForeignItem, ForeignItemFn, ForeignItemStatic}; use rustc::hir::{Item, ItemConst, ItemEnum, ItemExternCrate, ItemFn}; use rustc::hir::{ItemForeignMod, ItemImpl, ItemMod, ItemStatic, ItemDefaultImpl}; use rustc::hir::{ItemStruct, ItemTrait, ItemTy, ItemUse}; use rustc::hir::{PathListIdent, PathListMod, StmtDecl}; use rustc::hir::{Variant, ViewPathGlob, ViewPathList, ViewPathSimple}; use rustc::hir::intravisit::{self, Visitor}; trait ToNameBinding<'a> { fn to_name_binding(self) -> NameBinding<'a>; } impl<'a> ToNameBinding<'a> for (Module<'a>, Span) { fn to_name_binding(self) -> NameBinding<'a> { NameBinding::create_from_module(self.0, Some(self.1)) } } impl<'a> ToNameBinding<'a> for (Def, Span, DefModifiers) { fn to_name_binding(self) -> NameBinding<'a> { let kind = NameBindingKind::Def(self.0); NameBinding { modifiers: self.2, kind: kind, span: Some(self.1) } } } impl<'b, 'tcx:'b> Resolver<'b, 'tcx> { /// Constructs the reduced graph for the entire crate. pub fn build_reduced_graph(&mut self, krate: &hir::Crate) { let mut visitor = BuildReducedGraphVisitor { parent: self.graph_root, resolver: self, }; intravisit::walk_crate(&mut visitor, krate); } /// Defines `name` in namespace `ns` of module `parent` to be `def` if it is not yet defined. fn try_define(&self, parent: Module<'b>, name: Name, ns: Namespace, def: T) where T: ToNameBinding<'b> { let _ = parent.try_define_child(name, ns, def.to_name_binding()); } /// Defines `name` in namespace `ns` of module `parent` to be `def` if it is not yet defined; /// otherwise, reports an error. fn define>(&self, parent: Module<'b>, name: Name, ns: Namespace, def: T) { let binding = def.to_name_binding(); if let Err(old_binding) = parent.try_define_child(name, ns, binding.clone()) { self.report_conflict(parent, name, ns, old_binding, &binding); } } fn block_needs_anonymous_module(&mut self, block: &Block) -> bool { fn is_item(statement: &hir::Stmt) -> bool { if let StmtDecl(ref declaration, _) = statement.node { if let DeclItem(_) = declaration.node { return true; } } false } // If any statements are items, we need to create an anonymous module block.stmts.iter().any(is_item) } /// Constructs the reduced graph for one item. fn build_reduced_graph_for_item(&mut self, item: &Item, parent_ref: &mut Module<'b>) { let parent = *parent_ref; let name = item.name; let sp = item.span; let is_public = item.vis == hir::Public; let modifiers = if is_public { DefModifiers::PUBLIC } else { DefModifiers::empty() } | DefModifiers::IMPORTABLE; match item.node { ItemUse(ref view_path) => { // Extract and intern the module part of the path. For // globs and lists, the path is found directly in the AST; // for simple paths we have to munge the path a little. let is_global; let module_path: Vec = match view_path.node { ViewPathSimple(_, ref full_path) => { is_global = full_path.global; full_path.segments .split_last() .unwrap() .1 .iter() .map(|seg| seg.identifier.name) .collect() } ViewPathGlob(ref module_ident_path) | ViewPathList(ref module_ident_path, _) => { is_global = module_ident_path.global; module_ident_path.segments .iter() .map(|seg| seg.identifier.name) .collect() } }; // Checking for special identifiers in path // prevent `self` or `super` at beginning of global path if is_global && (module_path.first() == Some(&SELF_KEYWORD_NAME) || module_path.first() == Some(&SUPER_KEYWORD_NAME)) { self.session.add_lint( lint::builtin::SUPER_OR_SELF_IN_GLOBAL_PATH, item.id, item.span, format!("expected identifier, found keyword `{}`", module_path.first().unwrap().as_str())); } // Build up the import directives. let is_prelude = item.attrs.iter().any(|attr| { attr.name() == special_idents::prelude_import.name.as_str() }); match view_path.node { ViewPathSimple(binding, ref full_path) => { let source_name = full_path.segments.last().unwrap().identifier.name; if source_name.as_str() == "mod" || source_name.as_str() == "self" { resolve_error(self, view_path.span, ResolutionError::SelfImportsOnlyAllowedWithin); } let subclass = ImportDirectiveSubclass::single(binding, source_name); self.unresolved_imports += 1; parent.add_import_directive(module_path, subclass, view_path.span, item.id, is_public, is_prelude); } ViewPathList(_, ref source_items) => { // Make sure there's at most one `mod` import in the list. let mod_spans = source_items.iter() .filter_map(|item| { match item.node { PathListMod { .. } => Some(item.span), _ => None, } }) .collect::>(); if mod_spans.len() > 1 { let mut e = resolve_struct_error(self, mod_spans[0], ResolutionError::SelfImportCanOnlyAppearOnceInTheList); for other_span in mod_spans.iter().skip(1) { e.span_note(*other_span, "another `self` import appears here"); } e.emit(); } for source_item in source_items { let (module_path, name, rename) = match source_item.node { PathListIdent { name, rename, .. } => (module_path.clone(), name, rename.unwrap_or(name)), PathListMod { rename, .. } => { let name = match module_path.last() { Some(name) => *name, None => { resolve_error( self, source_item.span, ResolutionError:: SelfImportOnlyInImportListWithNonEmptyPrefix ); continue; } }; let module_path = module_path.split_last().unwrap().1; let rename = rename.unwrap_or(name); (module_path.to_vec(), name, rename) } }; let subclass = ImportDirectiveSubclass::single(rename, name); self.unresolved_imports += 1; parent.add_import_directive(module_path, subclass, source_item.span, source_item.node.id(), is_public, is_prelude); } } ViewPathGlob(_) => { self.unresolved_imports += 1; parent.add_import_directive(module_path, GlobImport, view_path.span, item.id, is_public, is_prelude); } } } ItemExternCrate(_) => { // n.b. we don't need to look at the path option here, because cstore already // did if let Some(crate_id) = self.session.cstore.extern_mod_stmt_cnum(item.id) { let def_id = DefId { krate: crate_id, index: CRATE_DEF_INDEX, }; let parent_link = ModuleParentLink(parent, name); let def = Def::Mod(def_id); let module = self.new_extern_crate_module(parent_link, def, is_public, item.id); self.define(parent, name, TypeNS, (module, sp)); self.build_reduced_graph_for_external_crate(module); } } ItemMod(..) => { let parent_link = ModuleParentLink(parent, name); let def = Def::Mod(self.ast_map.local_def_id(item.id)); let module = self.new_module(parent_link, Some(def), false, is_public); self.define(parent, name, TypeNS, (module, sp)); parent.module_children.borrow_mut().insert(item.id, module); *parent_ref = module; } ItemForeignMod(..) => {} // These items live in the value namespace. ItemStatic(_, m, _) => { let mutbl = m == hir::MutMutable; let def = Def::Static(self.ast_map.local_def_id(item.id), mutbl); self.define(parent, name, ValueNS, (def, sp, modifiers)); } ItemConst(_, _) => { let def = Def::Const(self.ast_map.local_def_id(item.id)); self.define(parent, name, ValueNS, (def, sp, modifiers)); } ItemFn(_, _, _, _, _, _) => { let def = Def::Fn(self.ast_map.local_def_id(item.id)); self.define(parent, name, ValueNS, (def, sp, modifiers)); } // These items live in the type namespace. ItemTy(..) => { let def = Def::TyAlias(self.ast_map.local_def_id(item.id)); self.define(parent, name, TypeNS, (def, sp, modifiers)); } ItemEnum(ref enum_definition, _) => { let parent_link = ModuleParentLink(parent, name); let def = Def::Enum(self.ast_map.local_def_id(item.id)); let module = self.new_module(parent_link, Some(def), false, is_public); self.define(parent, name, TypeNS, (module, sp)); let variant_modifiers = if is_public { DefModifiers::empty() } else { DefModifiers::PRIVATE_VARIANT }; for variant in &(*enum_definition).variants { let item_def_id = self.ast_map.local_def_id(item.id); self.build_reduced_graph_for_variant(variant, item_def_id, module, variant_modifiers); } } // These items live in both the type and value namespaces. ItemStruct(ref struct_def, _) => { // Define a name in the type namespace. let def = Def::Struct(self.ast_map.local_def_id(item.id)); self.define(parent, name, TypeNS, (def, sp, modifiers)); // If this is a newtype or unit-like struct, define a name // in the value namespace as well if !struct_def.is_struct() { let def = Def::Struct(self.ast_map.local_def_id(struct_def.id())); self.define(parent, name, ValueNS, (def, sp, modifiers)); } // Record the def ID and fields of this struct. let field_names = struct_def.fields() .iter() .map(|f| f.name) .collect(); let item_def_id = self.ast_map.local_def_id(item.id); self.structs.insert(item_def_id, field_names); } ItemDefaultImpl(_, _) | ItemImpl(..) => {} ItemTrait(_, _, _, ref items) => { let def_id = self.ast_map.local_def_id(item.id); // Add all the items within to a new module. let parent_link = ModuleParentLink(parent, name); let def = Def::Trait(def_id); let module_parent = self.new_module(parent_link, Some(def), false, is_public); self.define(parent, name, TypeNS, (module_parent, sp)); // Add the names of all the items to the trait info. for item in items { let item_def_id = self.ast_map.local_def_id(item.id); let (def, ns) = match item.node { hir::ConstTraitItem(..) => (Def::AssociatedConst(item_def_id), ValueNS), hir::MethodTraitItem(..) => (Def::Method(item_def_id), ValueNS), hir::TypeTraitItem(..) => (Def::AssociatedTy(def_id, item_def_id), TypeNS), }; let modifiers = DefModifiers::PUBLIC; // NB: not DefModifiers::IMPORTABLE self.define(module_parent, item.name, ns, (def, item.span, modifiers)); self.trait_item_map.insert((item.name, def_id), item_def_id); } } } } // Constructs the reduced graph for one variant. Variants exist in the // type and value namespaces. fn build_reduced_graph_for_variant(&mut self, variant: &Variant, item_id: DefId, parent: Module<'b>, variant_modifiers: DefModifiers) { let name = variant.node.name; if variant.node.data.is_struct() { // Not adding fields for variants as they are not accessed with a self receiver let variant_def_id = self.ast_map.local_def_id(variant.node.data.id()); self.structs.insert(variant_def_id, Vec::new()); } // Variants are always treated as importable to allow them to be glob used. // All variants are defined in both type and value namespaces as future-proofing. let modifiers = DefModifiers::PUBLIC | DefModifiers::IMPORTABLE | variant_modifiers; let def = Def::Variant(item_id, self.ast_map.local_def_id(variant.node.data.id())); self.define(parent, name, ValueNS, (def, variant.span, modifiers)); self.define(parent, name, TypeNS, (def, variant.span, modifiers)); } /// Constructs the reduced graph for one foreign item. fn build_reduced_graph_for_foreign_item(&mut self, foreign_item: &ForeignItem, parent: Module<'b>) { let name = foreign_item.name; let is_public = foreign_item.vis == hir::Public; let modifiers = if is_public { DefModifiers::PUBLIC } else { DefModifiers::empty() } | DefModifiers::IMPORTABLE; let def = match foreign_item.node { ForeignItemFn(..) => { Def::Fn(self.ast_map.local_def_id(foreign_item.id)) } ForeignItemStatic(_, m) => { Def::Static(self.ast_map.local_def_id(foreign_item.id), m) } }; self.define(parent, name, ValueNS, (def, foreign_item.span, modifiers)); } fn build_reduced_graph_for_block(&mut self, block: &Block, parent: &mut Module<'b>) { if self.block_needs_anonymous_module(block) { let block_id = block.id; debug!("(building reduced graph for block) creating a new anonymous module for block \ {}", block_id); let parent_link = BlockParentLink(parent, block_id); let new_module = self.new_module(parent_link, None, false, false); parent.module_children.borrow_mut().insert(block_id, new_module); *parent = new_module; } } /// Builds the reduced graph for a single item in an external crate. fn build_reduced_graph_for_external_crate_def(&mut self, parent: Module<'b>, xcdef: ChildItem) { let def = match xcdef.def { DlDef(def) => def, _ => return, }; if let Def::ForeignMod(def_id) = def { // Foreign modules have no names. Recur and populate eagerly. for child in self.session.cstore.item_children(def_id) { self.build_reduced_graph_for_external_crate_def(parent, child); } return; } let name = xcdef.name; let is_public = xcdef.vis == hir::Public || parent.is_trait(); let mut modifiers = DefModifiers::empty(); if is_public { modifiers = modifiers | DefModifiers::PUBLIC; } if parent.is_normal() { modifiers = modifiers | DefModifiers::IMPORTABLE; } match def { Def::Mod(_) | Def::ForeignMod(_) | Def::Enum(..) => { debug!("(building reduced graph for external crate) building module {} {}", name, is_public); let parent_link = ModuleParentLink(parent, name); let module = self.new_module(parent_link, Some(def), true, is_public); self.try_define(parent, name, TypeNS, (module, DUMMY_SP)); } Def::Variant(_, variant_id) => { debug!("(building reduced graph for external crate) building variant {}", name); // Variants are always treated as importable to allow them to be glob used. // All variants are defined in both type and value namespaces as future-proofing. let modifiers = DefModifiers::PUBLIC | DefModifiers::IMPORTABLE; self.try_define(parent, name, TypeNS, (def, DUMMY_SP, modifiers)); self.try_define(parent, name, ValueNS, (def, DUMMY_SP, modifiers)); if self.session.cstore.variant_kind(variant_id) == Some(VariantKind::Struct) { // Not adding fields for variants as they are not accessed with a self receiver self.structs.insert(variant_id, Vec::new()); } } Def::Fn(..) | Def::Static(..) | Def::Const(..) | Def::AssociatedConst(..) | Def::Method(..) => { debug!("(building reduced graph for external crate) building value (fn/static) {}", name); self.try_define(parent, name, ValueNS, (def, DUMMY_SP, modifiers)); } Def::Trait(def_id) => { debug!("(building reduced graph for external crate) building type {}", name); // If this is a trait, add all the trait item names to the trait // info. let trait_item_def_ids = self.session.cstore.trait_item_def_ids(def_id); for trait_item_def in &trait_item_def_ids { let trait_item_name = self.session.cstore.item_name(trait_item_def.def_id()); debug!("(building reduced graph for external crate) ... adding trait item \ '{}'", trait_item_name); self.trait_item_map.insert((trait_item_name, def_id), trait_item_def.def_id()); } let parent_link = ModuleParentLink(parent, name); let module = self.new_module(parent_link, Some(def), true, is_public); self.try_define(parent, name, TypeNS, (module, DUMMY_SP)); } Def::TyAlias(..) | Def::AssociatedTy(..) => { debug!("(building reduced graph for external crate) building type {}", name); self.try_define(parent, name, TypeNS, (def, DUMMY_SP, modifiers)); } Def::Struct(def_id) if self.session.cstore.tuple_struct_definition_if_ctor(def_id).is_none() => { debug!("(building reduced graph for external crate) building type and value for {}", name); self.try_define(parent, name, TypeNS, (def, DUMMY_SP, modifiers)); if let Some(ctor_def_id) = self.session.cstore.struct_ctor_def_id(def_id) { let def = Def::Struct(ctor_def_id); self.try_define(parent, name, ValueNS, (def, DUMMY_SP, modifiers)); } // Record the def ID and fields of this struct. let fields = self.session.cstore.struct_field_names(def_id); self.structs.insert(def_id, fields); } Def::Struct(..) => {} Def::Local(..) | Def::PrimTy(..) | Def::TyParam(..) | Def::Upvar(..) | Def::Label(..) | Def::SelfTy(..) | Def::Err => { bug!("didn't expect `{:?}`", def); } } } /// Builds the reduced graph rooted at the 'use' directive for an external /// crate. fn build_reduced_graph_for_external_crate(&mut self, root: Module<'b>) { let root_cnum = root.def_id().unwrap().krate; for child in self.session.cstore.crate_top_level_items(root_cnum) { self.build_reduced_graph_for_external_crate_def(root, child); } } /// Ensures that the reduced graph rooted at the given external module /// is built, building it if it is not. pub fn populate_module_if_necessary(&mut self, module: Module<'b>) { if module.populated.get() { return } for child in self.session.cstore.item_children(module.def_id().unwrap()) { self.build_reduced_graph_for_external_crate_def(module, child); } module.populated.set(true) } } struct BuildReducedGraphVisitor<'a, 'b: 'a, 'tcx: 'b> { resolver: &'a mut Resolver<'b, 'tcx>, parent: Module<'b>, } impl<'a, 'b, 'v, 'tcx> Visitor<'v> for BuildReducedGraphVisitor<'a, 'b, 'tcx> { fn visit_nested_item(&mut self, item: hir::ItemId) { self.visit_item(self.resolver.ast_map.expect_item(item.id)) } fn visit_item(&mut self, item: &Item) { let old_parent = self.parent; self.resolver.build_reduced_graph_for_item(item, &mut self.parent); intravisit::walk_item(self, item); self.parent = old_parent; } fn visit_foreign_item(&mut self, foreign_item: &ForeignItem) { self.resolver.build_reduced_graph_for_foreign_item(foreign_item, &self.parent); } fn visit_block(&mut self, block: &Block) { let old_parent = self.parent; self.resolver.build_reduced_graph_for_block(block, &mut self.parent); intravisit::walk_block(self, block); self.parent = old_parent; } }