build_reduced_graph.rs

// 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 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, 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 macros::{InvocationData, LegacyScope};
use resolve_imports::ImportDirective;
use resolve_imports::ImportDirectiveSubclass::{self, GlobImport, SingleImport};
use {Module, ModuleData, ModuleKind, NameBinding, NameBindingKind, ToNameBinding};
use {Resolver, ResolverArenas};
use Namespace::{self, TypeNS, ValueNS, MacroNS};
use {resolve_error, resolve_struct_error, ResolutionError};

use rustc::middle::cstore::LoadedMacro;
use rustc::hir::def::*;
use rustc::hir::def_id::{BUILTIN_MACROS_CRATE, CRATE_DEF_INDEX, LOCAL_CRATE, DefId};
use rustc::ty;

use std::cell::Cell;
use std::rc::Rc;

use syntax::ast::{Name, Ident};
use syntax::attr;

use syntax::ast::{self, Block, ForeignItem, ForeignItemKind, Item, ItemKind, NodeId};
use syntax::ast::{Mutability, StmtKind, TraitItem, TraitItemKind, Variant};
use syntax::codemap::respan;
use syntax::ext::base::SyntaxExtension;
use syntax::ext::base::Determinacy::Undetermined;
use syntax::ext::hygiene::Mark;
use syntax::ext::tt::macro_rules;
use syntax::parse::token::{self, Token};
use syntax::std_inject::injected_crate_name;
use syntax::symbol::keywords;
use syntax::symbol::Symbol;
use syntax::visit::{self, Visitor};

use syntax_pos::{Span, DUMMY_SP};

impl<'a> ToNameBinding<'a> for (Module<'a>, ty::Visibility, Span, Mark) {
    fn to_name_binding(self, arenas: &'a ResolverArenas<'a>) -> &'a NameBinding<'a> {
        arenas.alloc_name_binding(NameBinding {
            kind: NameBindingKind::Module(self.0),
            vis: self.1,
            span: self.2,
            expansion: self.3,
        })
    }
}

impl<'a> ToNameBinding<'a> for (Def, ty::Visibility, Span, Mark) {
    fn to_name_binding(self, arenas: &'a ResolverArenas<'a>) -> &'a NameBinding<'a> {
        arenas.alloc_name_binding(NameBinding {
            kind: NameBindingKind::Def(self.0),
            vis: self.1,
            span: self.2,
            expansion: self.3,
        })
    }
}

#[derive(Default, PartialEq, Eq)]
struct LegacyMacroImports {
    import_all: Option<Span>,
    imports: Vec<(Name, Span)>,
    reexports: Vec<(Name, Span)>,
}

impl<'a> Resolver<'a> {
    /// Defines `name` in namespace `ns` of module `parent` to be `def` if it is not yet defined;
    /// otherwise, reports an error.
    pub fn define<T>(&mut self, parent: Module<'a>, ident: Ident, ns: Namespace, def: T)
        where T: ToNameBinding<'a>,
    {
        let binding = def.to_name_binding(self.arenas);
        if let Err(old_binding) = self.try_define(parent, ident, ns, binding) {
            self.report_conflict(parent, ident, ns, old_binding, &binding);
        }
    }

    fn block_needs_anonymous_module(&mut self, block: &Block) -> bool {
        // If any statements are items, we need to create an anonymous module
        block.stmts.iter().any(|statement| match statement.node {
            StmtKind::Item(_) | StmtKind::Mac(_) => true,
            _ => false,
        })
    }

    fn insert_field_names(&mut self, def_id: DefId, field_names: Vec<Name>) {
        if !field_names.is_empty() {
            self.field_names.insert(def_id, field_names);
        }
    }

    fn build_reduced_graph_for_use_tree(&mut self,
                                        use_tree: &ast::UseTree,
                                        id: NodeId,
                                        vis: ty::Visibility,
                                        prefix: &ast::Path,
                                        nested: bool,
                                        item: &Item,
                                        expansion: Mark) {
        let is_prelude = attr::contains_name(&item.attrs, "prelude_import");
        let path = &use_tree.prefix;

        let mut module_path: Vec<_> = prefix.segments.iter()
            .chain(path.segments.iter())
            .map(|seg| respan(seg.span, seg.identifier))
            .collect();

        match use_tree.kind {
            ast::UseTreeKind::Simple(mut ident) => {
                let mut source = module_path.pop().unwrap().node;
                let mut type_ns_only = false;

                if nested {
                    // Correctly handle `self`
                    if source.name == keywords::SelfValue.name() {
                        type_ns_only = true;

                        let last_segment = *module_path.last().unwrap();
                        if last_segment.node.name == keywords::CrateRoot.name() {
                            resolve_error(
                                self,
                                use_tree.span,
                                ResolutionError::
                                SelfImportOnlyInImportListWithNonEmptyPrefix
                            );
                            return;
                        }

                        // Replace `use foo::self;` with `use foo;`
                        let _ = module_path.pop();
                        source = last_segment.node;
                        if ident.name == keywords::SelfValue.name() {
                            ident = last_segment.node;
                        }
                    }
                } else {
                    // Disallow `self`
                    if source.name == keywords::SelfValue.name() {
                        resolve_error(self,
                                      use_tree.span,
                                      ResolutionError::SelfImportsOnlyAllowedWithin);
                    }

                    // Disallow `use $crate;`
                    if source.name == keywords::DollarCrate.name() && path.segments.len() == 1 {
                        let crate_root = self.resolve_crate_root(source.ctxt);
                        let crate_name = match crate_root.kind {
                            ModuleKind::Def(_, name) => name,
                            ModuleKind::Block(..) => unreachable!(),
                        };
                        source.name = crate_name;
                        if ident.name == keywords::DollarCrate.name() {
                            ident.name = crate_name;
                        }

                        self.session.struct_span_warn(item.span, "`$crate` may not be imported")
                            .note("`use $crate;` was erroneously allowed and \
                                   will become a hard error in a future release")
                            .emit();
                    }
                }

                let subclass = SingleImport {
                    target: ident,
                    source,
                    result: self.per_ns(|_, _| Cell::new(Err(Undetermined))),
                    type_ns_only,
                };
                self.add_import_directive(
                    module_path, subclass, use_tree.span, id, vis, expansion,
                );
            }
            ast::UseTreeKind::Glob => {
                let subclass = GlobImport {
                    is_prelude,
                    max_vis: Cell::new(ty::Visibility::Invisible),
                };
                self.add_import_directive(
                    module_path, subclass, use_tree.span, id, vis, expansion,
                );
            }
            ast::UseTreeKind::Nested(ref items) => {
                let prefix = ast::Path {
                    segments: module_path.iter()
                        .map(|s| ast::PathSegment {
                            identifier: s.node,
                            span: s.span,
                            parameters: None,
                        })
                        .collect(),
                    span: path.span,
                };

                // Ensure there is at most one `self` in the list
                let self_spans = items.iter().filter_map(|&(ref use_tree, _)| {
                    if let ast::UseTreeKind::Simple(ident) = use_tree.kind {
                        if ident.name == keywords::SelfValue.name() {
                            return Some(use_tree.span);
                        }
                    }

                    None
                }).collect::<Vec<_>>();
                if self_spans.len() > 1 {
                    let mut e = resolve_struct_error(self,
                        self_spans[0],
                        ResolutionError::SelfImportCanOnlyAppearOnceInTheList);

                    for other_span in self_spans.iter().skip(1) {
                        e.span_note(*other_span, "another `self` import appears here");
                    }

                    e.emit();
                }

                for &(ref tree, id) in items {
                    self.build_reduced_graph_for_use_tree(
                        tree, id, vis, &prefix, true, item, expansion
                    );
                }
            }
        }
    }

    /// Constructs the reduced graph for one item.
    fn build_reduced_graph_for_item(&mut self, item: &Item, expansion: Mark) {
        let parent = self.current_module;
        let ident = item.ident;
        let sp = item.span;
        let vis = self.resolve_visibility(&item.vis);

        match item.node {
            ItemKind::Use(ref use_tree) => {
                // Just an empty prefix to start out
                let prefix = ast::Path {
                    segments: vec![],
                    span: use_tree.span,
                };

                self.build_reduced_graph_for_use_tree(
                    use_tree, item.id, vis, &prefix, false, item, expansion,
                );
            }

            ItemKind::ExternCrate(as_name) => {
                self.crate_loader.process_item(item, &self.definitions);

                // n.b. we don't need to look at the path option here, because cstore already did
                let crate_id = self.cstore.extern_mod_stmt_cnum_untracked(item.id).unwrap();
                let module =
                    self.get_module(DefId { krate: crate_id, index: CRATE_DEF_INDEX });
                self.populate_module_if_necessary(module);
                if injected_crate_name().map_or(false, |name| item.ident.name == name) {
                    self.injected_crate = Some(module);
                }

                let used = self.process_legacy_macro_imports(item, module, expansion);
                let binding =
                    (module, ty::Visibility::Public, sp, expansion).to_name_binding(self.arenas);
                let directive = self.arenas.alloc_import_directive(ImportDirective {
                    id: item.id,
                    parent,
                    imported_module: Cell::new(Some(module)),
                    subclass: ImportDirectiveSubclass::ExternCrate(as_name),
                    span: item.span,
                    module_path: Vec::new(),
                    vis: Cell::new(vis),
                    expansion,
                    used: Cell::new(used),
                });
                self.potentially_unused_imports.push(directive);
                let imported_binding = self.import(binding, directive);
                self.define(parent, ident, TypeNS, imported_binding);
            }

            ItemKind::GlobalAsm(..) => {}

            ItemKind::Mod(..) if item.ident == keywords::Invalid.ident() => {} // Crate root

            ItemKind::Mod(..) => {
                let def_id = self.definitions.local_def_id(item.id);
                let module_kind = ModuleKind::Def(Def::Mod(def_id), ident.name);
                let module = self.arenas.alloc_module(ModuleData {
                    no_implicit_prelude: parent.no_implicit_prelude || {
                        attr::contains_name(&item.attrs, "no_implicit_prelude")
                    },
                    ..ModuleData::new(Some(parent), module_kind, def_id, expansion, item.span)
                });
                self.define(parent, ident, TypeNS, (module, vis, sp, expansion));
                self.module_map.insert(def_id, module);

                // Descend into the module.
                self.current_module = module;
            }

            ItemKind::ForeignMod(..) => self.crate_loader.process_item(item, &self.definitions),

            // These items live in the value namespace.
            ItemKind::Static(_, m, _) => {
                let mutbl = m == Mutability::Mutable;
                let def = Def::Static(self.definitions.local_def_id(item.id), mutbl);
                self.define(parent, ident, ValueNS, (def, vis, sp, expansion));
            }
            ItemKind::Const(..) => {
                let def = Def::Const(self.definitions.local_def_id(item.id));
                self.define(parent, ident, ValueNS, (def, vis, sp, expansion));
            }
            ItemKind::Fn(..) => {
                let def = Def::Fn(self.definitions.local_def_id(item.id));
                self.define(parent, ident, ValueNS, (def, vis, sp, expansion));
            }

            // These items live in the type namespace.
            ItemKind::Ty(..) => {
                let def = Def::TyAlias(self.definitions.local_def_id(item.id));
                self.define(parent, ident, TypeNS, (def, vis, sp, expansion));
            }

            ItemKind::Enum(ref enum_definition, _) => {
                let def = Def::Enum(self.definitions.local_def_id(item.id));
                let module_kind = ModuleKind::Def(def, ident.name);
                let module = self.new_module(parent,
                                             module_kind,
                                             parent.normal_ancestor_id,
                                             expansion,
                                             item.span);
                self.define(parent, ident, TypeNS, (module, vis, sp, expansion));

                for variant in &(*enum_definition).variants {
                    self.build_reduced_graph_for_variant(variant, module, vis, expansion);
                }
            }

            ItemKind::TraitAlias(..) => {
                let def = Def::TraitAlias(self.definitions.local_def_id(item.id));
                self.define(parent, ident, TypeNS, (def, vis, sp, expansion));
            }

            // These items live in both the type and value namespaces.
            ItemKind::Struct(ref struct_def, _) => {
                // Define a name in the type namespace.
                let def_id = self.definitions.local_def_id(item.id);
                let def = Def::Struct(def_id);
                self.define(parent, ident, TypeNS, (def, vis, sp, expansion));

                let mut ctor_vis = vis;

                let has_non_exhaustive = item.attrs.iter()
                    .any(|item| item.check_name("non_exhaustive"));

                // If the structure is marked as non_exhaustive then lower the visibility
                // to within the crate.
                if has_non_exhaustive && vis == ty::Visibility::Public {
                    ctor_vis = ty::Visibility::Restricted(DefId::local(CRATE_DEF_INDEX));
                }

                // Record field names for error reporting.
                let field_names = struct_def.fields().iter().filter_map(|field| {
                    let field_vis = self.resolve_visibility(&field.vis);
                    if ctor_vis.is_at_least(field_vis, &*self) {
                        ctor_vis = field_vis;
                    }
                    field.ident.map(|ident| ident.name)
                }).collect();
                let item_def_id = self.definitions.local_def_id(item.id);
                self.insert_field_names(item_def_id, field_names);

                // If this is a tuple or unit struct, define a name
                // in the value namespace as well.
                if !struct_def.is_struct() {
                    let ctor_def = Def::StructCtor(self.definitions.local_def_id(struct_def.id()),
                                                   CtorKind::from_ast(struct_def));
                    self.define(parent, ident, ValueNS, (ctor_def, ctor_vis, sp, expansion));
                    self.struct_constructors.insert(def.def_id(), (ctor_def, ctor_vis));
                }
            }

            ItemKind::Union(ref vdata, _) => {
                let def = Def::Union(self.definitions.local_def_id(item.id));
                self.define(parent, ident, TypeNS, (def, vis, sp, expansion));

                // Record field names for error reporting.
                let field_names = vdata.fields().iter().filter_map(|field| {
                    self.resolve_visibility(&field.vis);
                    field.ident.map(|ident| ident.name)
                }).collect();
                let item_def_id = self.definitions.local_def_id(item.id);
                self.insert_field_names(item_def_id, field_names);
            }

            ItemKind::AutoImpl(..) | ItemKind::Impl(..) => {}

            ItemKind::Trait(..) => {
                let def_id = self.definitions.local_def_id(item.id);

                // Add all the items within to a new module.
                let module_kind = ModuleKind::Def(Def::Trait(def_id), ident.name);
                let module = self.new_module(parent,
                                             module_kind,
                                             parent.normal_ancestor_id,
                                             expansion,
                                             item.span);
                self.define(parent, ident, TypeNS, (module, vis, sp, expansion));
                self.current_module = module;
            }

            ItemKind::MacroDef(..) | ItemKind::Mac(_) => unreachable!(),
        }
    }

    // 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,
                                       parent: Module<'a>,
                                       vis: ty::Visibility,
                                       expansion: Mark) {
        let ident = variant.node.name;
        let def_id = self.definitions.local_def_id(variant.node.data.id());

        // Define a name in the type namespace.
        let def = Def::Variant(def_id);
        self.define(parent, ident, TypeNS, (def, vis, variant.span, expansion));

        // Define a constructor name in the value namespace.
        // Braced variants, unlike structs, generate unusable names in
        // value namespace, they are reserved for possible future use.
        let ctor_kind = CtorKind::from_ast(&variant.node.data);
        let ctor_def = Def::VariantCtor(def_id, ctor_kind);

        self.define(parent, ident, ValueNS, (ctor_def, vis, variant.span, expansion));
    }

    /// Constructs the reduced graph for one foreign item.
    fn build_reduced_graph_for_foreign_item(&mut self, item: &ForeignItem, expansion: Mark) {
        let (def, ns) = match item.node {
            ForeignItemKind::Fn(..) => {
                (Def::Fn(self.definitions.local_def_id(item.id)), ValueNS)
            }
            ForeignItemKind::Static(_, m) => {
                (Def::Static(self.definitions.local_def_id(item.id), m), ValueNS)
            }
            ForeignItemKind::Ty => {
                (Def::TyForeign(self.definitions.local_def_id(item.id)), TypeNS)
            }
        };
        let parent = self.current_module;
        let vis = self.resolve_visibility(&item.vis);
        self.define(parent, item.ident, ns, (def, vis, item.span, expansion));
    }

    fn build_reduced_graph_for_block(&mut self, block: &Block, expansion: Mark) {
        let parent = self.current_module;
        if self.block_needs_anonymous_module(block) {
            let module = self.new_module(parent,
                                         ModuleKind::Block(block.id),
                                         parent.normal_ancestor_id,
                                         expansion,
                                         block.span);
            self.block_map.insert(block.id, module);
            self.current_module = module; // Descend into the block.
        }
    }

    /// Builds the reduced graph for a single item in an external crate.
    fn build_reduced_graph_for_external_crate_def(&mut self, parent: Module<'a>, child: Export) {
        let Export { ident, def, vis, span, .. } = child;
        let def_id = def.def_id();
        let expansion = Mark::root(); // FIXME(jseyfried) intercrate hygiene
        match def {
            Def::Mod(..) | Def::Enum(..) => {
                let module = self.new_module(parent,
                                             ModuleKind::Def(def, ident.name),
                                             def_id,
                                             expansion,
                                             span);
                self.define(parent, ident, TypeNS, (module, vis, DUMMY_SP, expansion));
            }
            Def::Variant(..) | Def::TyAlias(..) | Def::TyForeign(..) => {
                self.define(parent, ident, TypeNS, (def, vis, DUMMY_SP, expansion));
            }
            Def::Fn(..) | Def::Static(..) | Def::Const(..) | Def::VariantCtor(..) => {
                self.define(parent, ident, ValueNS, (def, vis, DUMMY_SP, expansion));
            }
            Def::StructCtor(..) => {
                self.define(parent, ident, ValueNS, (def, vis, DUMMY_SP, expansion));

                if let Some(struct_def_id) =
                        self.cstore.def_key(def_id).parent
                            .map(|index| DefId { krate: def_id.krate, index: index }) {
                    self.struct_constructors.insert(struct_def_id, (def, vis));
                }
            }
            Def::Trait(..) => {
                let module_kind = ModuleKind::Def(def, ident.name);
                let module = self.new_module(parent,
                                             module_kind,
                                             parent.normal_ancestor_id,
                                             expansion,
                                             span);
                self.define(parent, ident, TypeNS, (module, vis, DUMMY_SP, expansion));

                for child in self.cstore.item_children_untracked(def_id, self.session) {
                    let ns = if let Def::AssociatedTy(..) = child.def { TypeNS } else { ValueNS };
                    self.define(module, child.ident, ns,
                                (child.def, ty::Visibility::Public, DUMMY_SP, expansion));

                    if self.cstore.associated_item_cloned_untracked(child.def.def_id())
                           .method_has_self_argument {
                        self.has_self.insert(child.def.def_id());
                    }
                }
                module.populated.set(true);
            }
            Def::Struct(..) | Def::Union(..) => {
                self.define(parent, ident, TypeNS, (def, vis, DUMMY_SP, expansion));

                // Record field names for error reporting.
                let field_names = self.cstore.struct_field_names_untracked(def_id);
                self.insert_field_names(def_id, field_names);
            }
            Def::Macro(..) => {
                self.define(parent, ident, MacroNS, (def, vis, DUMMY_SP, expansion));
            }
            _ => bug!("unexpected definition: {:?}", def)
        }
    }

    pub fn get_module(&mut self, def_id: DefId) -> Module<'a> {
        if def_id.krate == LOCAL_CRATE {
            return self.module_map[&def_id]
        }

        let macros_only = self.cstore.dep_kind_untracked(def_id.krate).macros_only();
        if let Some(&module) = self.extern_module_map.get(&(def_id, macros_only)) {
            return module;
        }

        let (name, parent) = if def_id.index == CRATE_DEF_INDEX {
            (self.cstore.crate_name_untracked(def_id.krate).as_str(), None)
        } else {
            let def_key = self.cstore.def_key(def_id);
            (def_key.disambiguated_data.data.get_opt_name().unwrap(),
             Some(self.get_module(DefId { index: def_key.parent.unwrap(), ..def_id })))
        };

        let kind = ModuleKind::Def(Def::Mod(def_id), Symbol::intern(&name));
        let module =
            self.arenas.alloc_module(ModuleData::new(parent, kind, def_id, Mark::root(), DUMMY_SP));
        self.extern_module_map.insert((def_id, macros_only), module);
        module
    }

    pub fn macro_def_scope(&mut self, expansion: Mark) -> Module<'a> {
        let def_id = self.macro_defs[&expansion];
        if let Some(id) = self.definitions.as_local_node_id(def_id) {
            self.local_macro_def_scopes[&id]
        } else if def_id.krate == BUILTIN_MACROS_CRATE {
            self.injected_crate.unwrap_or(self.graph_root)
        } else {
            let module_def_id = ty::DefIdTree::parent(&*self, def_id).unwrap();
            self.get_module(module_def_id)
        }
    }

    pub fn get_macro(&mut self, def: Def) -> Rc<SyntaxExtension> {
        let def_id = match def {
            Def::Macro(def_id, ..) => def_id,
            _ => panic!("Expected Def::Macro(..)"),
        };
        if let Some(ext) = self.macro_map.get(&def_id) {
            return ext.clone();
        }

        let macro_def = match self.cstore.load_macro_untracked(def_id, &self.session) {
            LoadedMacro::MacroDef(macro_def) => macro_def,
            LoadedMacro::ProcMacro(ext) => return ext,
        };

        let ext = Rc::new(macro_rules::compile(&self.session.parse_sess,
                                               &self.session.features,
                                               &macro_def));
        self.macro_map.insert(def_id, ext.clone());
        ext
    }

    /// 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<'a>) {
        if module.populated.get() { return }
        let def_id = module.def_id().unwrap();
        for child in self.cstore.item_children_untracked(def_id, self.session) {
            self.build_reduced_graph_for_external_crate_def(module, child);
        }
        module.populated.set(true)
    }

    fn legacy_import_macro(&mut self,
                           name: Name,
                           binding: &'a NameBinding<'a>,
                           span: Span,
                           allow_shadowing: bool) {
        if self.global_macros.insert(name, binding).is_some() && !allow_shadowing {
            let msg = format!("`{}` is already in scope", name);
            let note =
                "macro-expanded `#[macro_use]`s may not shadow existing macros (see RFC 1560)";
            self.session.struct_span_err(span, &msg).note(note).emit();
        }
    }

    // This returns true if we should consider the underlying `extern crate` to be used.
    fn process_legacy_macro_imports(&mut self, item: &Item, module: Module<'a>, expansion: Mark)
                                    -> bool {
        let allow_shadowing = expansion == Mark::root();
        let legacy_imports = self.legacy_macro_imports(&item.attrs);
        let mut used = legacy_imports != LegacyMacroImports::default();

        // `#[macro_use]` and `#[macro_reexport]` are only allowed at the crate root.
        if self.current_module.parent.is_some() && used {
            span_err!(self.session, item.span, E0468,
                      "an `extern crate` loading macros must be at the crate root");
        } else if !self.use_extern_macros && !used &&
                  self.cstore.dep_kind_untracked(module.def_id().unwrap().krate)
                      .macros_only() {
            let msg = "proc macro crates and `#[no_link]` crates have no effect without \
                       `#[macro_use]`";
            self.session.span_warn(item.span, msg);
            used = true; // Avoid the normal unused extern crate warning
        }

        let (graph_root, arenas) = (self.graph_root, self.arenas);
        let macro_use_directive = |span| arenas.alloc_import_directive(ImportDirective {
            id: item.id,
            parent: graph_root,
            imported_module: Cell::new(Some(module)),
            subclass: ImportDirectiveSubclass::MacroUse,
            span,
            module_path: Vec::new(),
            vis: Cell::new(ty::Visibility::Restricted(DefId::local(CRATE_DEF_INDEX))),
            expansion,
            used: Cell::new(false),
        });

        if let Some(span) = legacy_imports.import_all {
            let directive = macro_use_directive(span);
            self.potentially_unused_imports.push(directive);
            module.for_each_child(|ident, ns, binding| if ns == MacroNS {
                let imported_binding = self.import(binding, directive);
                self.legacy_import_macro(ident.name, imported_binding, span, allow_shadowing);
            });
        } else {
            for (name, span) in legacy_imports.imports {
                let ident = Ident::with_empty_ctxt(name);
                let result = self.resolve_ident_in_module(module, ident, MacroNS,
                                                          false, false, span);
                if let Ok(binding) = result {
                    let directive = macro_use_directive(span);
                    self.potentially_unused_imports.push(directive);
                    let imported_binding = self.import(binding, directive);
                    self.legacy_import_macro(name, imported_binding, span, allow_shadowing);
                } else {
                    span_err!(self.session, span, E0469, "imported macro not found");
                }
            }
        }
        for (name, span) in legacy_imports.reexports {
            self.cstore.export_macros_untracked(module.def_id().unwrap().krate);
            let ident = Ident::with_empty_ctxt(name);
            let result = self.resolve_ident_in_module(module, ident, MacroNS, false, false, span);
            if let Ok(binding) = result {
                let (def, vis) = (binding.def(), binding.vis);
                self.macro_exports.push(Export { ident, def, vis, span, is_import: true });
            } else {
                span_err!(self.session, span, E0470, "reexported macro not found");
            }
        }
        used
    }

    // does this attribute list contain "macro_use"?
    fn contains_macro_use(&mut self, attrs: &[ast::Attribute]) -> bool {
        for attr in attrs {
            if attr.check_name("macro_escape") {
                let msg = "macro_escape is a deprecated synonym for macro_use";
                let mut err = self.session.struct_span_warn(attr.span, msg);
                if let ast::AttrStyle::Inner = attr.style {
                    err.help("consider an outer attribute, #[macro_use] mod ...").emit();
                } else {
                    err.emit();
                }
            } else if !attr.check_name("macro_use") {
                continue;
            }

            if !attr.is_word() {
                self.session.span_err(attr.span, "arguments to macro_use are not allowed here");
            }
            return true;
        }

        false
    }

    fn legacy_macro_imports(&mut self, attrs: &[ast::Attribute]) -> LegacyMacroImports {
        let mut imports = LegacyMacroImports::default();
        for attr in attrs {
            if attr.check_name("macro_use") {
                match attr.meta_item_list() {
                    Some(names) => for attr in names {
                        if let Some(word) = attr.word() {
                            imports.imports.push((word.name(), attr.span()));
                        } else {
                            span_err!(self.session, attr.span(), E0466, "bad macro import");
                        }
                    },
                    None => imports.import_all = Some(attr.span),
                }
            } else if attr.check_name("macro_reexport") {
                let bad_macro_reexport = |this: &mut Self, span| {
                    span_err!(this.session, span, E0467, "bad macro reexport");
                };
                if let Some(names) = attr.meta_item_list() {
                    for attr in names {
                        if let Some(word) = attr.word() {
                            imports.reexports.push((word.name(), attr.span()));
                        } else {
                            bad_macro_reexport(self, attr.span());
                        }
                    }
                } else {
                    bad_macro_reexport(self, attr.span());
                }
            }
        }
        imports
    }
}

pub struct BuildReducedGraphVisitor<'a, 'b: 'a> {
    pub resolver: &'a mut Resolver<'b>,
    pub legacy_scope: LegacyScope<'b>,
    pub expansion: Mark,
}

impl<'a, 'b> BuildReducedGraphVisitor<'a, 'b> {
    fn visit_invoc(&mut self, id: ast::NodeId) -> &'b InvocationData<'b> {
        let mark = id.placeholder_to_mark();
        self.resolver.current_module.unresolved_invocations.borrow_mut().insert(mark);
        let invocation = self.resolver.invocations[&mark];
        invocation.module.set(self.resolver.current_module);
        invocation.legacy_scope.set(self.legacy_scope);
        invocation
    }
}

macro_rules! method {
    ($visit:ident: $ty:ty, $invoc:path, $walk:ident) => {
        fn $visit(&mut self, node: &'a $ty) {
            if let $invoc(..) = node.node {
                self.visit_invoc(node.id);
            } else {
                visit::$walk(self, node);
            }
        }
    }
}

impl<'a, 'b> Visitor<'a> for BuildReducedGraphVisitor<'a, 'b> {
    method!(visit_impl_item: ast::ImplItem, ast::ImplItemKind::Macro, walk_impl_item);
    method!(visit_expr:      ast::Expr,     ast::ExprKind::Mac,       walk_expr);
    method!(visit_pat:       ast::Pat,      ast::PatKind::Mac,        walk_pat);
    method!(visit_ty:        ast::Ty,       ast::TyKind::Mac,         walk_ty);

    fn visit_item(&mut self, item: &'a Item) {
        let macro_use = match item.node {
            ItemKind::MacroDef(..) => {
                self.resolver.define_macro(item, self.expansion, &mut self.legacy_scope);
                return
            }
            ItemKind::Mac(..) => {
                self.legacy_scope = LegacyScope::Expansion(self.visit_invoc(item.id));
                return
            }
            ItemKind::Mod(..) => self.resolver.contains_macro_use(&item.attrs),
            _ => false,
        };

        let (parent, legacy_scope) = (self.resolver.current_module, self.legacy_scope);
        self.resolver.build_reduced_graph_for_item(item, self.expansion);
        visit::walk_item(self, item);
        self.resolver.current_module = parent;
        if !macro_use {
            self.legacy_scope = legacy_scope;
        }
    }

    fn visit_stmt(&mut self, stmt: &'a ast::Stmt) {
        if let ast::StmtKind::Mac(..) = stmt.node {
            self.legacy_scope = LegacyScope::Expansion(self.visit_invoc(stmt.id));
        } else {
            visit::walk_stmt(self, stmt);
        }
    }

    fn visit_foreign_item(&mut self, foreign_item: &'a ForeignItem) {
        self.resolver.build_reduced_graph_for_foreign_item(foreign_item, self.expansion);
        visit::walk_foreign_item(self, foreign_item);
    }

    fn visit_block(&mut self, block: &'a Block) {
        let (parent, legacy_scope) = (self.resolver.current_module, self.legacy_scope);
        self.resolver.build_reduced_graph_for_block(block, self.expansion);
        visit::walk_block(self, block);
        self.resolver.current_module = parent;
        self.legacy_scope = legacy_scope;
    }

    fn visit_trait_item(&mut self, item: &'a TraitItem) {
        let parent = self.resolver.current_module;

        if let TraitItemKind::Macro(_) = item.node {
            self.visit_invoc(item.id);
            return
        }

        // Add the item to the trait info.
        let item_def_id = self.resolver.definitions.local_def_id(item.id);
        let (def, ns) = match item.node {
            TraitItemKind::Const(..) => (Def::AssociatedConst(item_def_id), ValueNS),
            TraitItemKind::Method(ref sig, _) => {
                if sig.decl.has_self() {
                    self.resolver.has_self.insert(item_def_id);
                }
                (Def::Method(item_def_id), ValueNS)
            }
            TraitItemKind::Type(..) => (Def::AssociatedTy(item_def_id), TypeNS),
            TraitItemKind::Macro(_) => bug!(),  // handled above
        };

        let vis = ty::Visibility::Public;
        self.resolver.define(parent, item.ident, ns, (def, vis, item.span, self.expansion));

        self.resolver.current_module = parent.parent.unwrap(); // nearest normal ancestor
        visit::walk_trait_item(self, item);
        self.resolver.current_module = parent;
    }

    fn visit_token(&mut self, t: Token) {
        if let Token::Interpolated(nt) = t {
            match nt.0 {
                token::NtExpr(ref expr) => {
                    if let ast::ExprKind::Mac(..) = expr.node {
                        self.visit_invoc(expr.id);
                    }
                }
                _ => {}
            }
        }
    }
}