// 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, PUBLIC, IMPORTABLE}; use ImportDirective; use ImportDirectiveSubclass::{self, SingleImport, GlobImport}; use ImportResolution; use Module; use ModuleKind::*; use Namespace::{TypeNS, ValueNS}; use NameBindings; use ParentLink::{self, ModuleParentLink, BlockParentLink}; use Resolver; use RibKind::*; use Shadowable; use TypeNsDef; use TypeParameters::HasTypeParameters; use self::DuplicateCheckingMode::*; use self::NamespaceError::*; use rustc::metadata::csearch; use rustc::metadata::decoder::{DefLike, DlDef, DlField, DlImpl}; use rustc::middle::def::*; use rustc::middle::subst::FnSpace; use syntax::ast::{Block, Crate}; use syntax::ast::{DeclItem, DefId}; use syntax::ast::{ForeignItem, ForeignItemFn, ForeignItemStatic}; use syntax::ast::{Item, ItemConst, ItemEnum, ItemFn}; use syntax::ast::{ItemForeignMod, ItemImpl, ItemMac, ItemMod, ItemStatic}; use syntax::ast::{ItemStruct, ItemTrait, ItemTy}; use syntax::ast::{MethodImplItem, Name, NamedField, NodeId}; use syntax::ast::{PathListIdent, PathListMod}; use syntax::ast::{Public, SelfStatic}; use syntax::ast::StmtDecl; use syntax::ast::StructVariantKind; use syntax::ast::TupleVariantKind; use syntax::ast::TyObjectSum; use syntax::ast::{TypeImplItem, UnnamedField}; use syntax::ast::{Variant, ViewItem, ViewItemExternCrate}; use syntax::ast::{ViewItemUse, ViewPathGlob, ViewPathList, ViewPathSimple}; use syntax::ast::{Visibility}; use syntax::ast::TyPath; use syntax::ast; use syntax::ast_util::{self, PostExpansionMethod, local_def}; use syntax::attr::AttrMetaMethods; use syntax::parse::token::{self, special_idents}; use syntax::codemap::{Span, DUMMY_SP}; use syntax::visit::{self, Visitor}; use std::mem::replace; use std::ops::{Deref, DerefMut}; use std::rc::Rc; // Specifies how duplicates should be handled when adding a child item if // another item exists with the same name in some namespace. #[derive(Copy, PartialEq)] enum DuplicateCheckingMode { ForbidDuplicateModules, ForbidDuplicateTypesAndModules, ForbidDuplicateValues, ForbidDuplicateTypesAndValues, OverwriteDuplicates } #[derive(Copy, PartialEq)] enum NamespaceError { NoError, ModuleError, TypeError, ValueError } fn namespace_error_to_string(ns: NamespaceError) -> &'static str { match ns { NoError => "", ModuleError | TypeError => "type or module", ValueError => "value", } } struct GraphBuilder<'a, 'b:'a, 'tcx:'b> { resolver: &'a mut Resolver<'b, 'tcx> } impl<'a, 'b:'a, 'tcx:'b> Deref for GraphBuilder<'a, 'b, 'tcx> { type Target = Resolver<'b, 'tcx>; fn deref(&self) -> &Resolver<'b, 'tcx> { &*self.resolver } } impl<'a, 'b:'a, 'tcx:'b> DerefMut for GraphBuilder<'a, 'b, 'tcx> { fn deref_mut(&mut self) -> &mut Resolver<'b, 'tcx> { &mut *self.resolver } } impl<'a, 'b:'a, 'tcx:'b> GraphBuilder<'a, 'b, 'tcx> { /// Constructs the reduced graph for the entire crate. fn build_reduced_graph(self, krate: &ast::Crate) { let parent = self.graph_root.get_module(); let mut visitor = BuildReducedGraphVisitor { builder: self, parent: parent }; visit::walk_crate(&mut visitor, krate); } /// Adds a new child item to the module definition of the parent node and /// returns its corresponding name bindings as well as the current parent. /// Or, if we're inside a block, creates (or reuses) an anonymous module /// corresponding to the innermost block ID and returns the name bindings /// as well as the newly-created parent. /// /// # Panics /// /// Panics if this node does not have a module definition and we are not inside /// a block. fn add_child(&self, name: Name, parent: &Rc, duplicate_checking_mode: DuplicateCheckingMode, // For printing errors sp: Span) -> Rc { // If this is the immediate descendant of a module, then we add the // child name directly. Otherwise, we create or reuse an anonymous // module and add the child to that. self.check_for_conflicts_between_external_crates_and_items(&**parent, name, sp); // Add or reuse the child. let child = parent.children.borrow().get(&name).cloned(); match child { None => { let child = Rc::new(NameBindings::new()); parent.children.borrow_mut().insert(name, child.clone()); child } Some(child) => { // Enforce the duplicate checking mode: // // * If we're requesting duplicate module checking, check that // there isn't a module in the module with the same name. // // * If we're requesting duplicate type checking, check that // there isn't a type in the module with the same name. // // * If we're requesting duplicate value checking, check that // there isn't a value in the module with the same name. // // * If we're requesting duplicate type checking and duplicate // value checking, check that there isn't a duplicate type // and a duplicate value with the same name. // // * If no duplicate checking was requested at all, do // nothing. let mut duplicate_type = NoError; let ns = match duplicate_checking_mode { ForbidDuplicateModules => { if child.get_module_if_available().is_some() { duplicate_type = ModuleError; } Some(TypeNS) } ForbidDuplicateTypesAndModules => { match child.def_for_namespace(TypeNS) { None => {} Some(_) if child.get_module_if_available() .map(|m| m.kind.get()) == Some(ImplModuleKind) => {} Some(_) => duplicate_type = TypeError } Some(TypeNS) } ForbidDuplicateValues => { if child.defined_in_namespace(ValueNS) { duplicate_type = ValueError; } Some(ValueNS) } ForbidDuplicateTypesAndValues => { let mut n = None; match child.def_for_namespace(TypeNS) { Some(DefMod(_)) | None => {} Some(_) => { n = Some(TypeNS); duplicate_type = TypeError; } }; if child.defined_in_namespace(ValueNS) { duplicate_type = ValueError; n = Some(ValueNS); } n } OverwriteDuplicates => None }; if duplicate_type != NoError { // Return an error here by looking up the namespace that // had the duplicate. let ns = ns.unwrap(); self.resolve_error(sp, &format!("duplicate definition of {} `{}`", namespace_error_to_string(duplicate_type), token::get_name(name))[]); { let r = child.span_for_namespace(ns); for sp in r.iter() { self.session.span_note(*sp, &format!("first definition of {} `{}` here", namespace_error_to_string(duplicate_type), token::get_name(name))[]); } } } child } } } fn block_needs_anonymous_module(&mut self, block: &Block) -> bool { // If the block has view items, we need an anonymous module. if block.view_items.len() > 0 { return true; } // Check each statement. for statement in block.stmts.iter() { match statement.node { StmtDecl(ref declaration, _) => { match declaration.node { DeclItem(_) => { return true; } _ => { // Keep searching. } } } _ => { // Keep searching. } } } // If we found neither view items nor items, we don't need to create // an anonymous module. return false; } fn get_parent_link(&mut self, parent: &Rc, name: Name) -> ParentLink { ModuleParentLink(parent.downgrade(), name) } /// Constructs the reduced graph for one item. fn build_reduced_graph_for_item(&mut self, item: &Item, parent: &Rc) -> Rc { let name = item.ident.name; let sp = item.span; let is_public = item.vis == ast::Public; let modifiers = if is_public { PUBLIC } else { DefModifiers::empty() } | IMPORTABLE; match item.node { ItemMod(..) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateModules, sp); let parent_link = self.get_parent_link(parent, name); let def_id = DefId { krate: 0, node: item.id }; name_bindings.define_module(parent_link, Some(def_id), NormalModuleKind, false, item.vis == ast::Public, sp); name_bindings.get_module() } ItemForeignMod(..) => parent.clone(), // These items live in the value namespace. ItemStatic(_, m, _) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateValues, sp); let mutbl = m == ast::MutMutable; name_bindings.define_value(DefStatic(local_def(item.id), mutbl), sp, modifiers); parent.clone() } ItemConst(_, _) => { self.add_child(name, parent, ForbidDuplicateValues, sp) .define_value(DefConst(local_def(item.id)), sp, modifiers); parent.clone() } ItemFn(_, _, _, _, _) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateValues, sp); let def = DefFn(local_def(item.id), false); name_bindings.define_value(def, sp, modifiers); parent.clone() } // These items live in the type namespace. ItemTy(..) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateTypesAndModules, sp); name_bindings.define_type(DefTy(local_def(item.id), false), sp, modifiers); parent.clone() } ItemEnum(ref enum_definition, _) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateTypesAndModules, sp); name_bindings.define_type(DefTy(local_def(item.id), true), sp, modifiers); let parent_link = self.get_parent_link(parent, name); // We want to make sure the module type is EnumModuleKind // even if there's already an ImplModuleKind module defined, // since that's how we prevent duplicate enum definitions name_bindings.set_module_kind(parent_link, Some(local_def(item.id)), EnumModuleKind, false, is_public, sp); let module = name_bindings.get_module(); for variant in (*enum_definition).variants.iter() { self.build_reduced_graph_for_variant( &**variant, local_def(item.id), &module); } parent.clone() } // These items live in both the type and value namespaces. ItemStruct(ref struct_def, _) => { // Adding to both Type and Value namespaces or just Type? let (forbid, ctor_id) = match struct_def.ctor_id { Some(ctor_id) => (ForbidDuplicateTypesAndValues, Some(ctor_id)), None => (ForbidDuplicateTypesAndModules, None) }; let name_bindings = self.add_child(name, parent, forbid, sp); // Define a name in the type namespace. name_bindings.define_type(DefTy(local_def(item.id), false), sp, modifiers); // If this is a newtype or unit-like struct, define a name // in the value namespace as well if let Some(cid) = ctor_id { name_bindings.define_value(DefStruct(local_def(cid)), sp, modifiers); } // Record the def ID and fields of this struct. let named_fields = struct_def.fields.iter().filter_map(|f| { match f.node.kind { NamedField(ident, _) => Some(ident.name), UnnamedField(_) => None } }).collect(); self.structs.insert(local_def(item.id), named_fields); parent.clone() } ItemImpl(_, _, _, None, ref ty, ref impl_items) => { // If this implements an anonymous trait, then add all the // methods within to a new module, if the type was defined // within this module. let mod_name = match ty.node { TyPath(ref path, _) if path.segments.len() == 1 => { // FIXME(18446) we should distinguish between the name of // a trait and the name of an impl of that trait. Some(path.segments.last().unwrap().identifier.name) } TyObjectSum(ref lhs_ty, _) => { match lhs_ty.node { TyPath(ref path, _) if path.segments.len() == 1 => { Some(path.segments.last().unwrap().identifier.name) } _ => { None } } } _ => { None } }; match mod_name { None => { self.resolve_error(ty.span, "inherent implementations may \ only be implemented in the same \ module as the type they are \ implemented for") } Some(mod_name) => { // Create the module and add all methods. let parent_opt = parent.children.borrow().get(&mod_name).cloned(); let new_parent = match parent_opt { // It already exists Some(ref child) if child.get_module_if_available() .is_some() && (child.get_module().kind.get() == ImplModuleKind || child.get_module().kind.get() == TraitModuleKind) => { child.get_module() } Some(ref child) if child.get_module_if_available() .is_some() && child.get_module().kind.get() == EnumModuleKind => child.get_module(), // Create the module _ => { let name_bindings = self.add_child(mod_name, parent, ForbidDuplicateModules, sp); let parent_link = self.get_parent_link(parent, name); let def_id = local_def(item.id); let ns = TypeNS; let is_public = !name_bindings.defined_in_namespace(ns) || name_bindings.defined_in_public_namespace(ns); name_bindings.define_module(parent_link, Some(def_id), ImplModuleKind, false, is_public, sp); name_bindings.get_module() } }; // For each implementation item... for impl_item in impl_items.iter() { match *impl_item { MethodImplItem(ref method) => { // Add the method to the module. let name = method.pe_ident().name; let method_name_bindings = self.add_child(name, &new_parent, ForbidDuplicateValues, method.span); let def = match method.pe_explicit_self() .node { SelfStatic => { // Static methods become // `DefStaticMethod`s. DefStaticMethod(local_def(method.id), FromImpl(local_def(item.id))) } _ => { // Non-static methods become // `DefMethod`s. DefMethod(local_def(method.id), None, FromImpl(local_def(item.id))) } }; // NB: not IMPORTABLE let modifiers = if method.pe_vis() == ast::Public { PUBLIC } else { DefModifiers::empty() }; method_name_bindings.define_value( def, method.span, modifiers); } TypeImplItem(ref typedef) => { // Add the typedef to the module. let name = typedef.ident.name; let typedef_name_bindings = self.add_child( name, &new_parent, ForbidDuplicateTypesAndModules, typedef.span); let def = DefAssociatedTy(local_def( typedef.id)); // NB: not IMPORTABLE let modifiers = if typedef.vis == ast::Public { PUBLIC } else { DefModifiers::empty() }; typedef_name_bindings.define_type( def, typedef.span, modifiers); } } } } } parent.clone() } ItemImpl(_, _, _, Some(_), _, _) => parent.clone(), ItemTrait(_, _, _, ref items) => { let name_bindings = self.add_child(name, parent, ForbidDuplicateTypesAndModules, sp); // Add all the items within to a new module. let parent_link = self.get_parent_link(parent, name); name_bindings.define_module(parent_link, Some(local_def(item.id)), TraitModuleKind, false, item.vis == ast::Public, sp); let module_parent = name_bindings.get_module(); let def_id = local_def(item.id); // Add the names of all the items to the trait info. for trait_item in items.iter() { let (name, kind) = match *trait_item { ast::RequiredMethod(_) | ast::ProvidedMethod(_) => { let ty_m = ast_util::trait_item_to_ty_method(trait_item); let name = ty_m.ident.name; // Add it as a name in the trait module. let (def, static_flag) = match ty_m.explicit_self .node { SelfStatic => { // Static methods become `DefStaticMethod`s. (DefStaticMethod( local_def(ty_m.id), FromTrait(local_def(item.id))), StaticMethodTraitItemKind) } _ => { // Non-static methods become `DefMethod`s. (DefMethod(local_def(ty_m.id), Some(local_def(item.id)), FromTrait(local_def(item.id))), NonstaticMethodTraitItemKind) } }; let method_name_bindings = self.add_child(name, &module_parent, ForbidDuplicateTypesAndValues, ty_m.span); // NB: not IMPORTABLE method_name_bindings.define_value(def, ty_m.span, PUBLIC); (name, static_flag) } ast::TypeTraitItem(ref associated_type) => { let def = DefAssociatedTy(local_def( associated_type.ty_param.id)); let name_bindings = self.add_child(associated_type.ty_param.ident.name, &module_parent, ForbidDuplicateTypesAndValues, associated_type.ty_param.span); // NB: not IMPORTABLE name_bindings.define_type(def, associated_type.ty_param.span, PUBLIC); (associated_type.ty_param.ident.name, TypeTraitItemKind) } }; self.trait_item_map.insert((name, def_id), kind); } name_bindings.define_type(DefTrait(def_id), sp, modifiers); parent.clone() } ItemMac(..) => parent.clone() } } // 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: &Rc) { let name = variant.node.name.name; let is_exported = match variant.node.kind { TupleVariantKind(_) => false, StructVariantKind(_) => { // Not adding fields for variants as they are not accessed with a self receiver self.structs.insert(local_def(variant.node.id), Vec::new()); true } }; let child = self.add_child(name, parent, ForbidDuplicateTypesAndValues, variant.span); // variants are always treated as importable to allow them to be glob // used child.define_value(DefVariant(item_id, local_def(variant.node.id), is_exported), variant.span, PUBLIC | IMPORTABLE); child.define_type(DefVariant(item_id, local_def(variant.node.id), is_exported), variant.span, PUBLIC | IMPORTABLE); } /// Constructs the reduced graph for one 'view item'. View items consist /// of imports and use directives. fn build_reduced_graph_for_view_item(&mut self, view_item: &ViewItem, parent: &Rc) { match view_item.node { ViewItemUse(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 module_path = match view_path.node { ViewPathSimple(_, ref full_path, _) => { full_path.segments .init() .iter().map(|ident| ident.identifier.name) .collect() } ViewPathGlob(ref module_ident_path, _) | ViewPathList(ref module_ident_path, _, _) => { module_ident_path.segments .iter().map(|ident| ident.identifier.name).collect() } }; // Build up the import directives. let is_public = view_item.vis == ast::Public; let shadowable = view_item.attrs .iter() .any(|attr| { attr.name() == token::get_name( special_idents::prelude_import.name) }); let shadowable = if shadowable { Shadowable::Always } else { Shadowable::Never }; match view_path.node { ViewPathSimple(binding, ref full_path, id) => { let source_name = full_path.segments.last().unwrap().identifier.name; if token::get_name(source_name).get() == "mod" || token::get_name(source_name).get() == "self" { self.resolve_error(view_path.span, "`self` imports are only allowed within a { } list"); } let subclass = SingleImport(binding.name, source_name); self.build_import_directive(&**parent, module_path, subclass, view_path.span, id, is_public, shadowable); } 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 { self.resolve_error(mod_spans[0], "`self` import can only appear once in the list"); for other_span in mod_spans.iter().skip(1) { self.session.span_note(*other_span, "another `self` import appears here"); } } for source_item in source_items.iter() { let (module_path, name) = match source_item.node { PathListIdent { name, .. } => (module_path.clone(), name.name), PathListMod { .. } => { let name = match module_path.last() { Some(name) => *name, None => { self.resolve_error(source_item.span, "`self` import can only appear in an import list \ with a non-empty prefix"); continue; } }; let module_path = module_path.init(); (module_path.to_vec(), name) } }; self.build_import_directive( &**parent, module_path, SingleImport(name, name), source_item.span, source_item.node.id(), is_public, shadowable); } } ViewPathGlob(_, id) => { self.build_import_directive(&**parent, module_path, GlobImport, view_path.span, id, is_public, shadowable); } } } ViewItemExternCrate(name, _, node_id) => { // n.b. we don't need to look at the path option here, because cstore already did for &crate_id in self.session.cstore .find_extern_mod_stmt_cnum(node_id).iter() { let def_id = DefId { krate: crate_id, node: 0 }; self.external_exports.insert(def_id); let parent_link = ModuleParentLink(parent.downgrade(), name.name); let external_module = Rc::new(Module::new(parent_link, Some(def_id), NormalModuleKind, false, true)); debug!("(build reduced graph for item) found extern `{}`", self.module_to_string(&*external_module)); self.check_for_conflicts_between_external_crates( &**parent, name.name, view_item.span); parent.external_module_children.borrow_mut() .insert(name.name, external_module.clone()); self.build_reduced_graph_for_external_crate(&external_module); } } } } /// Constructs the reduced graph for one foreign item. fn build_reduced_graph_for_foreign_item(&mut self, foreign_item: &ForeignItem, parent: &Rc, f: F) where F: FnOnce(&mut Resolver), { let name = foreign_item.ident.name; let is_public = foreign_item.vis == ast::Public; let modifiers = if is_public { PUBLIC } else { DefModifiers::empty() } | IMPORTABLE; let name_bindings = self.add_child(name, parent, ForbidDuplicateValues, foreign_item.span); match foreign_item.node { ForeignItemFn(_, ref generics) => { let def = DefFn(local_def(foreign_item.id), false); name_bindings.define_value(def, foreign_item.span, modifiers); self.with_type_parameter_rib( HasTypeParameters(generics, FnSpace, foreign_item.id, NormalRibKind), f); } ForeignItemStatic(_, m) => { let def = DefStatic(local_def(foreign_item.id), m); name_bindings.define_value(def, foreign_item.span, modifiers); f(self.resolver) } } } fn build_reduced_graph_for_block(&mut self, block: &Block, parent: &Rc) -> Rc { 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 new_module = Rc::new(Module::new( BlockParentLink(parent.downgrade(), block_id), None, AnonymousModuleKind, false, false)); parent.anonymous_children.borrow_mut().insert(block_id, new_module.clone()); new_module } else { parent.clone() } } fn handle_external_def(&mut self, def: Def, vis: Visibility, child_name_bindings: &NameBindings, final_ident: &str, name: Name, new_parent: &Rc) { debug!("(building reduced graph for \ external crate) building external def, priv {:?}", vis); let is_public = vis == ast::Public; let modifiers = if is_public { PUBLIC } else { DefModifiers::empty() } | IMPORTABLE; let is_exported = is_public && match new_parent.def_id.get() { None => true, Some(did) => self.external_exports.contains(&did) }; if is_exported { self.external_exports.insert(def.def_id()); } let kind = match def { DefTy(_, true) => EnumModuleKind, DefStruct(..) | DefTy(..) => ImplModuleKind, _ => NormalModuleKind }; match def { DefMod(def_id) | DefForeignMod(def_id) | DefStruct(def_id) | DefTy(def_id, _) => { let type_def = child_name_bindings.type_def.borrow().clone(); match type_def { Some(TypeNsDef { module_def: Some(module_def), .. }) => { debug!("(building reduced graph for external crate) \ already created module"); module_def.def_id.set(Some(def_id)); } Some(_) | None => { debug!("(building reduced graph for \ external crate) building module \ {}", final_ident); let parent_link = self.get_parent_link(new_parent, name); child_name_bindings.define_module(parent_link, Some(def_id), kind, true, is_public, DUMMY_SP); } } } _ => {} } match def { DefMod(_) | DefForeignMod(_) => {} DefVariant(_, variant_id, is_struct) => { debug!("(building reduced graph for external crate) building \ variant {}", final_ident); // variants are always treated as importable to allow them to be // glob used let modifiers = PUBLIC | IMPORTABLE; if is_struct { child_name_bindings.define_type(def, DUMMY_SP, modifiers); // Not adding fields for variants as they are not accessed with a self receiver self.structs.insert(variant_id, Vec::new()); } else { child_name_bindings.define_value(def, DUMMY_SP, modifiers); } } DefFn(ctor_id, true) => { child_name_bindings.define_value( csearch::get_tuple_struct_definition_if_ctor(&self.session.cstore, ctor_id) .map_or(def, |_| DefStruct(ctor_id)), DUMMY_SP, modifiers); } DefFn(..) | DefStaticMethod(..) | DefStatic(..) | DefConst(..) | DefMethod(..) => { debug!("(building reduced graph for external \ crate) building value (fn/static) {}", final_ident); // impl methods have already been defined with the correct importability modifier let mut modifiers = match *child_name_bindings.value_def.borrow() { Some(ref def) => (modifiers & !IMPORTABLE) | (def.modifiers & IMPORTABLE), None => modifiers }; if new_parent.kind.get() != NormalModuleKind { modifiers = modifiers & !IMPORTABLE; } child_name_bindings.define_value(def, DUMMY_SP, modifiers); } DefTrait(def_id) => { debug!("(building reduced graph for external \ crate) building type {}", final_ident); // If this is a trait, add all the trait item names to the trait // info. let trait_item_def_ids = csearch::get_trait_item_def_ids(&self.session.cstore, def_id); for trait_item_def_id in trait_item_def_ids.iter() { let (trait_item_name, trait_item_kind) = csearch::get_trait_item_name_and_kind( &self.session.cstore, trait_item_def_id.def_id()); debug!("(building reduced graph for external crate) ... \ adding trait item '{}'", token::get_name(trait_item_name)); self.trait_item_map.insert((trait_item_name, def_id), trait_item_kind); if is_exported { self.external_exports .insert(trait_item_def_id.def_id()); } } child_name_bindings.define_type(def, DUMMY_SP, modifiers); // Define a module if necessary. let parent_link = self.get_parent_link(new_parent, name); child_name_bindings.set_module_kind(parent_link, Some(def_id), TraitModuleKind, true, is_public, DUMMY_SP) } DefTy(..) | DefAssociatedTy(..) | DefAssociatedPath(..) => { debug!("(building reduced graph for external \ crate) building type {}", final_ident); child_name_bindings.define_type(def, DUMMY_SP, modifiers); } DefStruct(def_id) => { debug!("(building reduced graph for external \ crate) building type and value for {}", final_ident); child_name_bindings.define_type(def, DUMMY_SP, modifiers); let fields = csearch::get_struct_fields(&self.session.cstore, def_id).iter().map(|f| { f.name }).collect::>(); if fields.len() == 0 { child_name_bindings.define_value(def, DUMMY_SP, modifiers); } // Record the def ID and fields of this struct. self.structs.insert(def_id, fields); } DefLocal(..) | DefPrimTy(..) | DefTyParam(..) | DefUse(..) | DefUpvar(..) | DefRegion(..) | DefTyParamBinder(..) | DefLabel(..) | DefSelfTy(..) => { panic!("didn't expect `{:?}`", def); } } } /// Builds the reduced graph for a single item in an external crate. fn build_reduced_graph_for_external_crate_def(&mut self, root: &Rc, def_like: DefLike, name: Name, def_visibility: Visibility) { match def_like { DlDef(def) => { // Add the new child item, if necessary. match def { DefForeignMod(def_id) => { // Foreign modules have no names. Recur and populate // eagerly. csearch::each_child_of_item(&self.session.cstore, def_id, |def_like, child_name, vis| { self.build_reduced_graph_for_external_crate_def( root, def_like, child_name, vis) }); } _ => { let child_name_bindings = self.add_child(name, root, OverwriteDuplicates, DUMMY_SP); self.handle_external_def(def, def_visibility, &*child_name_bindings, token::get_name(name).get(), name, root); } } } DlImpl(def) => { match csearch::get_type_name_if_impl(&self.session.cstore, def) { None => {} Some(final_name) => { let methods_opt = csearch::get_methods_if_impl(&self.session.cstore, def); match methods_opt { Some(ref methods) if methods.len() >= 1 => { debug!("(building reduced graph for \ external crate) processing \ static methods for type name {}", token::get_name(final_name)); let child_name_bindings = self.add_child( final_name, root, OverwriteDuplicates, DUMMY_SP); // Process the static methods. First, // create the module. let type_module; let type_def = child_name_bindings.type_def.borrow().clone(); match type_def { Some(TypeNsDef { module_def: Some(module_def), .. }) => { // We already have a module. This // is OK. type_module = module_def; // Mark it as an impl module if // necessary. type_module.kind.set(ImplModuleKind); } Some(_) | None => { let parent_link = self.get_parent_link(root, final_name); child_name_bindings.define_module( parent_link, Some(def), ImplModuleKind, true, true, DUMMY_SP); type_module = child_name_bindings. get_module(); } } // Add each static method to the module. let new_parent = type_module; for method_info in methods.iter() { let name = method_info.name; debug!("(building reduced graph for \ external crate) creating \ static method '{}'", token::get_name(name)); let method_name_bindings = self.add_child(name, &new_parent, OverwriteDuplicates, DUMMY_SP); let def = DefFn(method_info.def_id, false); // NB: not IMPORTABLE let modifiers = if method_info.vis == ast::Public { PUBLIC } else { DefModifiers::empty() }; method_name_bindings.define_value( def, DUMMY_SP, modifiers); } } // Otherwise, do nothing. Some(_) | None => {} } } } } DlField => { debug!("(building reduced graph for external crate) \ ignoring field"); } } } /// Builds the reduced graph rooted at the given external module. fn populate_external_module(&mut self, module: &Rc) { debug!("(populating external module) attempting to populate {}", self.module_to_string(&**module)); let def_id = match module.def_id.get() { None => { debug!("(populating external module) ... no def ID!"); return } Some(def_id) => def_id, }; csearch::each_child_of_item(&self.session.cstore, def_id, |def_like, child_name, visibility| { debug!("(populating external module) ... found ident: {}", token::get_name(child_name)); self.build_reduced_graph_for_external_crate_def(module, def_like, child_name, visibility) }); module.populated.set(true) } /// Ensures that the reduced graph rooted at the given external module /// is built, building it if it is not. fn populate_module_if_necessary(&mut self, module: &Rc) { if !module.populated.get() { self.populate_external_module(module) } assert!(module.populated.get()) } /// Builds the reduced graph rooted at the 'use' directive for an external /// crate. fn build_reduced_graph_for_external_crate(&mut self, root: &Rc) { csearch::each_top_level_item_of_crate(&self.session.cstore, root.def_id .get() .unwrap() .krate, |def_like, name, visibility| { self.build_reduced_graph_for_external_crate_def(root, def_like, name, visibility) }); } /// Creates and adds an import directive to the given module. fn build_import_directive(&mut self, module_: &Module, module_path: Vec, subclass: ImportDirectiveSubclass, span: Span, id: NodeId, is_public: bool, shadowable: Shadowable) { module_.imports.borrow_mut().push(ImportDirective::new(module_path, subclass, span, id, is_public, shadowable)); self.unresolved_imports += 1; // Bump the reference count on the name. Or, if this is a glob, set // the appropriate flag. match subclass { SingleImport(target, _) => { debug!("(building import directive) building import \ directive: {}::{}", self.names_to_string(&module_.imports.borrow().last().unwrap(). module_path[]), token::get_name(target)); let mut import_resolutions = module_.import_resolutions .borrow_mut(); match import_resolutions.get_mut(&target) { Some(resolution) => { debug!("(building import directive) bumping \ reference"); resolution.outstanding_references += 1; // the source of this name is different now resolution.type_id = id; resolution.value_id = id; resolution.is_public = is_public; return; } None => {} } debug!("(building import directive) creating new"); let mut resolution = ImportResolution::new(id, is_public); resolution.outstanding_references = 1; import_resolutions.insert(target, resolution); } GlobImport => { // Set the glob flag. This tells us that we don't know the // module's exports ahead of time. module_.glob_count.set(module_.glob_count.get() + 1); } } } } struct BuildReducedGraphVisitor<'a, 'b:'a, 'tcx:'b> { builder: GraphBuilder<'a, 'b, 'tcx>, parent: Rc } impl<'a, 'b, 'v, 'tcx> Visitor<'v> for BuildReducedGraphVisitor<'a, 'b, 'tcx> { fn visit_item(&mut self, item: &Item) { let p = self.builder.build_reduced_graph_for_item(item, &self.parent); let old_parent = replace(&mut self.parent, p); visit::walk_item(self, item); self.parent = old_parent; } fn visit_foreign_item(&mut self, foreign_item: &ForeignItem) { let parent = &self.parent; self.builder.build_reduced_graph_for_foreign_item(foreign_item, parent, |r| { let mut v = BuildReducedGraphVisitor { builder: GraphBuilder { resolver: r }, parent: parent.clone() }; visit::walk_foreign_item(&mut v, foreign_item); }) } fn visit_view_item(&mut self, view_item: &ViewItem) { self.builder.build_reduced_graph_for_view_item(view_item, &self.parent); } fn visit_block(&mut self, block: &Block) { let np = self.builder.build_reduced_graph_for_block(block, &self.parent); let old_parent = replace(&mut self.parent, np); visit::walk_block(self, block); self.parent = old_parent; } } pub fn build_reduced_graph(resolver: &mut Resolver, krate: &ast::Crate) { GraphBuilder { resolver: resolver }.build_reduced_graph(krate); } pub fn populate_module_if_necessary(resolver: &mut Resolver, module: &Rc) { GraphBuilder { resolver: resolver }.populate_module_if_necessary(module); }