src/librustdoc/visit_ast.rs - third_party/rust - Git at Google

 //! The Rust AST Visitor. Extracts useful information and massages it into a form
 //! usable for `clean`.

 use rustc::hir::{self, Node};
 use rustc::hir::def::Def;
 use rustc::hir::def_id::{DefId, LOCAL_CRATE};
 use rustc::middle::privacy::AccessLevel;
 use rustc::util::nodemap::{FxHashSet, FxHashMap};
 use syntax::ast;
 use syntax::attr;
 use syntax::ext::base::MacroKind;
 use syntax::source_map::Spanned;
 use syntax_pos::{self, Span};

 use std::mem;

 use crate::core;
 use crate::clean::{self, AttributesExt, NestedAttributesExt, def_id_to_path};
 use crate::doctree::*;


 // Looks to me like the first two of these are actually
 // output parameters, maybe only mutated once; perhaps
 // better simply to have the visit method return a tuple
 // containing them?

 // Also, is there some reason that this doesn't use the 'visit'
 // framework from syntax?.

 pub struct RustdocVisitor<'a, 'tcx> {
     pub module: Module,
     pub attrs: hir::HirVec<ast::Attribute>,
     pub cx: &'a core::DocContext<'tcx>,
     view_item_stack: FxHashSet<ast::NodeId>,
     inlining: bool,
     /// Are the current module and all of its parents public?
     inside_public_path: bool,
     exact_paths: Option<FxHashMap<DefId, Vec<String>>>,
 }

 impl<'a, 'tcx> RustdocVisitor<'a, 'tcx> {
     pub fn new(
         cx: &'a core::DocContext<'tcx>
     ) -> RustdocVisitor<'a, 'tcx> {
         // If the root is re-exported, terminate all recursion.
         let mut stack = FxHashSet::default();
         stack.insert(ast::CRATE_NODE_ID);
         RustdocVisitor {
             module: Module::new(None),
             attrs: hir::HirVec::new(),
             cx,
             view_item_stack: stack,
             inlining: false,
             inside_public_path: true,
             exact_paths: Some(FxHashMap::default()),
         }
     }

     fn store_path(&mut self, did: DefId) {
         // We can't use the entry API, as that keeps the mutable borrow of `self` active
         // when we try to use `cx`.
         let exact_paths = self.exact_paths.as_mut().unwrap();
         if exact_paths.get(&did).is_none() {
             let path = def_id_to_path(self.cx, did, self.cx.crate_name.clone());
             exact_paths.insert(did, path);
         }
     }

     fn stability(&self, id: hir::HirId) -> Option<attr::Stability> {
         self.cx.tcx.hir().opt_local_def_id_from_hir_id(id)
             .and_then(|def_id| self.cx.tcx.lookup_stability(def_id)).cloned()
     }

     fn deprecation(&self, id: hir::HirId) -> Option<attr::Deprecation> {
         self.cx.tcx.hir().opt_local_def_id_from_hir_id(id)
             .and_then(|def_id| self.cx.tcx.lookup_deprecation(def_id))
     }

     pub fn visit(&mut self, krate: &hir::Crate) {
         self.attrs = krate.attrs.clone();

         self.module = self.visit_mod_contents(krate.span,
                                               krate.attrs.clone(),
                                               Spanned { span: syntax_pos::DUMMY_SP,
                                                         node: hir::VisibilityKind::Public },
                                               hir::CRATE_HIR_ID,
                                               &krate.module,
                                               None);
         // Attach the crate's exported macros to the top-level module:
         let macro_exports: Vec<_> =
             krate.exported_macros.iter().map(|def| self.visit_local_macro(def, None)).collect();
         self.module.macros.extend(macro_exports);
         self.module.is_crate = true;

         self.cx.renderinfo.borrow_mut().exact_paths = self.exact_paths.take().unwrap();
     }

     pub fn visit_variant_data(&mut self, item: &hir::Item,
                               name: ast::Name, sd: &hir::VariantData,
                               generics: &hir::Generics) -> Struct {
         debug!("Visiting struct");
         let struct_type = struct_type_from_def(&*sd);
         Struct {
             id: item.hir_id,
             struct_type,
             name,
             vis: item.vis.clone(),
             stab: self.stability(item.hir_id),
             depr: self.deprecation(item.hir_id),
             attrs: item.attrs.clone(),
             generics: generics.clone(),
             fields: sd.fields().iter().cloned().collect(),
             whence: item.span
         }
     }

     pub fn visit_union_data(&mut self, item: &hir::Item,
                             name: ast::Name, sd: &hir::VariantData,
                             generics: &hir::Generics) -> Union {
         debug!("Visiting union");
         let struct_type = struct_type_from_def(&*sd);
         Union {
             id: item.hir_id,
             struct_type,
             name,
             vis: item.vis.clone(),
             stab: self.stability(item.hir_id),
             depr: self.deprecation(item.hir_id),
             attrs: item.attrs.clone(),
             generics: generics.clone(),
             fields: sd.fields().iter().cloned().collect(),
             whence: item.span
         }
     }

     pub fn visit_enum_def(&mut self, it: &hir::Item,
                           name: ast::Name, def: &hir::EnumDef,
                           params: &hir::Generics) -> Enum {
         debug!("Visiting enum");
         Enum {
             name,
             variants: def.variants.iter().map(|v| Variant {
                 name: v.node.ident.name,
                 attrs: v.node.attrs.clone(),
                 stab: self.stability(v.node.data.hir_id()),
                 depr: self.deprecation(v.node.data.hir_id()),
                 def: v.node.data.clone(),
                 whence: v.span,
             }).collect(),
             vis: it.vis.clone(),
             stab: self.stability(it.hir_id),
             depr: self.deprecation(it.hir_id),
             generics: params.clone(),
             attrs: it.attrs.clone(),
             id: it.hir_id,
             whence: it.span,
         }
     }

     pub fn visit_fn(&mut self, om: &mut Module, item: &hir::Item,
                     name: ast::Name, fd: &hir::FnDecl,
                     header: hir::FnHeader,
                     gen: &hir::Generics,
                     body: hir::BodyId) {
         debug!("Visiting fn");
         let macro_kind = item.attrs.iter().filter_map(|a| {
             if a.check_name("proc_macro") {
                 Some(MacroKind::Bang)
             } else if a.check_name("proc_macro_derive") {
                 Some(MacroKind::Derive)
             } else if a.check_name("proc_macro_attribute") {
                 Some(MacroKind::Attr)
             } else {
                 None
             }
         }).next();
         match macro_kind {
             Some(kind) => {
                 let name = if kind == MacroKind::Derive {
                     item.attrs.lists("proc_macro_derive")
                               .filter_map(|mi| mi.ident())
                               .next()
                               .expect("proc-macro derives require a name")
                               .name
                 } else {
                     name
                 };

                 let mut helpers = Vec::new();
                 for mi in item.attrs.lists("proc_macro_derive") {
                     if !mi.check_name("attributes") {
                         continue;
                     }

                     if let Some(list) = mi.meta_item_list() {
                         for inner_mi in list {
                             if let Some(ident) = inner_mi.ident() {
                                 helpers.push(ident.name);
                             }
                         }
                     }
                 }

                 om.proc_macros.push(ProcMacro {
                     name,
                     id: item.hir_id,
                     kind,
                     helpers,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 });
             }
             None => {
                 om.fns.push(Function {
                     id: item.hir_id,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                     attrs: item.attrs.clone(),
                     decl: fd.clone(),
                     name,
                     whence: item.span,
                     generics: gen.clone(),
                     header,
                     body,
                 });
             }
         }
     }

     pub fn visit_mod_contents(&mut self, span: Span, attrs: hir::HirVec<ast::Attribute>,
                               vis: hir::Visibility, id: hir::HirId,
                               m: &hir::Mod,
                               name: Option<ast::Name>) -> Module {
         let mut om = Module::new(name);
         om.where_outer = span;
         om.where_inner = m.inner;
         om.attrs = attrs;
         om.vis = vis.clone();
         om.stab = self.stability(id);
         om.depr = self.deprecation(id);
         om.id = self.cx.tcx.hir().hir_to_node_id(id);
         // Keep track of if there were any private modules in the path.
         let orig_inside_public_path = self.inside_public_path;
         self.inside_public_path &= vis.node.is_pub();
         for i in &m.item_ids {
             let item = self.cx.tcx.hir().expect_item(i.id);
             self.visit_item(item, None, &mut om);
         }
         self.inside_public_path = orig_inside_public_path;
         om
     }

     /// Tries to resolve the target of a `pub use` statement and inlines the
     /// target if it is defined locally and would not be documented otherwise,
     /// or when it is specifically requested with `please_inline`.
     /// (the latter is the case when the import is marked `doc(inline)`)
     ///
     /// Cross-crate inlining occurs later on during crate cleaning
     /// and follows different rules.
     ///
     /// Returns `true` if the target has been inlined.
     fn maybe_inline_local(&mut self,
                           id: hir::HirId,
                           def: Def,
                           renamed: Option<ast::Ident>,
                           glob: bool,
                           om: &mut Module,
                           please_inline: bool) -> bool {

         fn inherits_doc_hidden(cx: &core::DocContext<'_>, mut node: ast::NodeId) -> bool {
             while let Some(id) = cx.tcx.hir().get_enclosing_scope(node) {
                 node = id;
                 if cx.tcx.hir().attrs(node).lists("doc").has_word("hidden") {
                     return true;
                 }
                 if node == ast::CRATE_NODE_ID {
                     break;
                 }
             }
             false
         }

         debug!("maybe_inline_local def: {:?}", def);

         let tcx = self.cx.tcx;
         let def_did = if let Some(did) = def.opt_def_id() {
             did
         } else {
             return false;
         };

         let use_attrs = tcx.hir().attrs_by_hir_id(id);
         // Don't inline `doc(hidden)` imports so they can be stripped at a later stage.
         let is_no_inline = use_attrs.lists("doc").has_word("no_inline") ||
                            use_attrs.lists("doc").has_word("hidden");

         // For cross-crate impl inlining we need to know whether items are
         // reachable in documentation -- a previously nonreachable item can be
         // made reachable by cross-crate inlining which we're checking here.
         // (this is done here because we need to know this upfront).
         if !def_did.is_local() && !is_no_inline {
             let attrs = clean::inline::load_attrs(self.cx, def_did);
             let self_is_hidden = attrs.lists("doc").has_word("hidden");
             match def {
                 Def::Trait(did) |
                 Def::Struct(did) |
                 Def::Union(did) |
                 Def::Enum(did) |
                 Def::ForeignTy(did) |
                 Def::TyAlias(did) if !self_is_hidden => {
                     self.cx.renderinfo
                         .borrow_mut()
                         .access_levels.map
                         .insert(did, AccessLevel::Public);
                 },
                 Def::Mod(did) => if !self_is_hidden {
                     crate::visit_lib::LibEmbargoVisitor::new(self.cx).visit_mod(did);
                 },
                 _ => {},
             }

             return false
         }

         let def_node_id = match tcx.hir().as_local_node_id(def_did) {
             Some(n) => n, None => return false
         };

         let is_private = !self.cx.renderinfo.borrow().access_levels.is_public(def_did);
         let is_hidden = inherits_doc_hidden(self.cx, def_node_id);

         // Only inline if requested or if the item would otherwise be stripped.
         if (!please_inline && !is_private && !is_hidden) || is_no_inline {
             return false
         }

         if !self.view_item_stack.insert(def_node_id) { return false }

         let ret = match tcx.hir().get(def_node_id) {
             Node::Item(&hir::Item { node: hir::ItemKind::Mod(ref m), .. }) if glob => {
                 let prev = mem::replace(&mut self.inlining, true);
                 for i in &m.item_ids {
                     let i = self.cx.tcx.hir().expect_item(i.id);
                     self.visit_item(i, None, om);
                 }
                 self.inlining = prev;
                 true
             }
             Node::Item(it) if !glob => {
                 let prev = mem::replace(&mut self.inlining, true);
                 self.visit_item(it, renamed, om);
                 self.inlining = prev;
                 true
             }
             Node::ForeignItem(it) if !glob => {
                 // Generate a fresh `extern {}` block if we want to inline a foreign item.
                 om.foreigns.push(hir::ForeignMod {
                     abi: tcx.hir().get_foreign_abi_by_hir_id(it.hir_id),
                     items: vec![hir::ForeignItem {
                         ident: renamed.unwrap_or(it.ident),
                         .. it.clone()
                     }].into(),
                 });
                 true
             }
             Node::MacroDef(def) if !glob => {
                 om.macros.push(self.visit_local_macro(def, renamed.map(|i| i.name)));
                 true
             }
             _ => false,
         };
         self.view_item_stack.remove(&def_node_id);
         ret
     }

     pub fn visit_item(&mut self, item: &hir::Item,
                       renamed: Option<ast::Ident>, om: &mut Module) {
         debug!("Visiting item {:?}", item);
         let ident = renamed.unwrap_or(item.ident);

         if item.vis.node.is_pub() {
             let def_id = self.cx.tcx.hir().local_def_id_from_hir_id(item.hir_id);
             self.store_path(def_id);
         }

         match item.node {
             hir::ItemKind::ForeignMod(ref fm) => {
                 // If inlining we only want to include public functions.
                 om.foreigns.push(if self.inlining {
                     hir::ForeignMod {
                         abi: fm.abi,
                         items: fm.items.iter().filter(|i| i.vis.node.is_pub()).cloned().collect(),
                     }
                 } else {
                     fm.clone()
                 });
             }
             // If we're inlining, skip private items.
             _ if self.inlining && !item.vis.node.is_pub() => {}
             hir::ItemKind::GlobalAsm(..) => {}
             hir::ItemKind::ExternCrate(orig_name) => {
                 let def_id = self.cx.tcx.hir().local_def_id_from_hir_id(item.hir_id);
                 om.extern_crates.push(ExternCrate {
                     cnum: self.cx.tcx.extern_mod_stmt_cnum(def_id)
                                 .unwrap_or(LOCAL_CRATE),
                     name: ident.name,
                     path: orig_name.map(|x|x.to_string()),
                     vis: item.vis.clone(),
                     attrs: item.attrs.clone(),
                     whence: item.span,
                 })
             }
             hir::ItemKind::Use(_, hir::UseKind::ListStem) => {}
             hir::ItemKind::Use(ref path, kind) => {
                 let is_glob = kind == hir::UseKind::Glob;

                 // Struct and variant constructors and proc macro stubs always show up alongside
                 // their definitions, we've already processed them so just discard these.
                 match path.def {
                     Def::StructCtor(..) | Def::VariantCtor(..) | Def::SelfCtor(..) |
                     Def::Macro(_, MacroKind::ProcMacroStub) => return,
                     _ => {}
                 }

                 // If there was a private module in the current path then don't bother inlining
                 // anything as it will probably be stripped anyway.
                 if item.vis.node.is_pub() && self.inside_public_path {
                     let please_inline = item.attrs.iter().any(|item| {
                         match item.meta_item_list() {
                             Some(ref list) if item.check_name("doc") => {
                                 list.iter().any(|i| i.check_name("inline"))
                             }
                             _ => false,
                         }
                     });
                     let ident = if is_glob { None } else { Some(ident) };
                     if self.maybe_inline_local(item.hir_id,
                                                path.def,
                                                ident,
                                                is_glob,
                                                om,
                                                please_inline) {
                         return;
                     }
                 }

                 om.imports.push(Import {
                     name: ident.name,
                     id: item.hir_id,
                     vis: item.vis.clone(),
                     attrs: item.attrs.clone(),
                     path: (**path).clone(),
                     glob: is_glob,
                     whence: item.span,
                 });
             }
             hir::ItemKind::Mod(ref m) => {
                 om.mods.push(self.visit_mod_contents(item.span,
                                                      item.attrs.clone(),
                                                      item.vis.clone(),
                                                      item.hir_id,
                                                      m,
                                                      Some(ident.name)));
             },
             hir::ItemKind::Enum(ref ed, ref gen) =>
                 om.enums.push(self.visit_enum_def(item, ident.name, ed, gen)),
             hir::ItemKind::Struct(ref sd, ref gen) =>
                 om.structs.push(self.visit_variant_data(item, ident.name, sd, gen)),
             hir::ItemKind::Union(ref sd, ref gen) =>
                 om.unions.push(self.visit_union_data(item, ident.name, sd, gen)),
             hir::ItemKind::Fn(ref fd, header, ref gen, body) =>
                 self.visit_fn(om, item, ident.name, &**fd, header, gen, body),
             hir::ItemKind::Ty(ref ty, ref gen) => {
                 let t = Typedef {
                     ty: ty.clone(),
                     gen: gen.clone(),
                     name: ident.name,
                     id: item.hir_id,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.typedefs.push(t);
             },
             hir::ItemKind::Existential(ref exist_ty) => {
                 let t = Existential {
                     exist_ty: exist_ty.clone(),
                     name: ident.name,
                     id: item.hir_id,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.existentials.push(t);
             },
             hir::ItemKind::Static(ref ty, ref mut_, ref exp) => {
                 let s = Static {
                     type_: ty.clone(),
                     mutability: mut_.clone(),
                     expr: exp.clone(),
                     id: item.hir_id,
                     name: ident.name,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.statics.push(s);
             },
             hir::ItemKind::Const(ref ty, ref exp) => {
                 let s = Constant {
                     type_: ty.clone(),
                     expr: exp.clone(),
                     id: item.hir_id,
                     name: ident.name,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.constants.push(s);
             },
             hir::ItemKind::Trait(is_auto, unsafety, ref gen, ref b, ref item_ids) => {
                 let items = item_ids.iter()
                                     .map(|ti| self.cx.tcx.hir().trait_item(ti.id).clone())
                                     .collect();
                 let t = Trait {
                     is_auto,
                     unsafety,
                     name: ident.name,
                     items,
                     generics: gen.clone(),
                     bounds: b.iter().cloned().collect(),
                     id: item.hir_id,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.traits.push(t);
             },
             hir::ItemKind::TraitAlias(ref gen, ref b) => {
                 let t = TraitAlias {
                     name: ident.name,
                     generics: gen.clone(),
                     bounds: b.iter().cloned().collect(),
                     id: item.hir_id,
                     attrs: item.attrs.clone(),
                     whence: item.span,
                     vis: item.vis.clone(),
                     stab: self.stability(item.hir_id),
                     depr: self.deprecation(item.hir_id),
                 };
                 om.trait_aliases.push(t);
             },

             hir::ItemKind::Impl(unsafety,
                           polarity,
                           defaultness,
                           ref gen,
                           ref tr,
                           ref ty,
                           ref item_ids) => {
                 // Don't duplicate impls when inlining or if it's implementing a trait, we'll pick
                 // them up regardless of where they're located.
                 if !self.inlining && tr.is_none() {
                     let items = item_ids.iter()
                                         .map(|ii| self.cx.tcx.hir().impl_item(ii.id).clone())
                                         .collect();
                     let i = Impl {
                         unsafety,
                         polarity,
                         defaultness,
                         generics: gen.clone(),
                         trait_: tr.clone(),
                         for_: ty.clone(),
                         items,
                         attrs: item.attrs.clone(),
                         id: item.hir_id,
                         whence: item.span,
                         vis: item.vis.clone(),
                         stab: self.stability(item.hir_id),
                         depr: self.deprecation(item.hir_id),
                     };
                     om.impls.push(i);
                 }
             },
         }
     }

     // Convert each `exported_macro` into a doc item.
     fn visit_local_macro(
         &self,
         def: &hir::MacroDef,
         renamed: Option<ast::Name>
     ) -> Macro {
         debug!("visit_local_macro: {}", def.name);
         let tts = def.body.trees().collect::<Vec<_>>();
         // Extract the spans of all matchers. They represent the "interface" of the macro.
         let matchers = tts.chunks(4).map(|arm| arm[0].span()).collect();

         Macro {

             def_id: self.cx.tcx.hir().local_def_id_from_hir_id(def.hir_id),
             attrs: def.attrs.clone(),
             name: renamed.unwrap_or(def.name),
             whence: def.span,
             matchers,
             stab: self.stability(def.hir_id),
             depr: self.deprecation(def.hir_id),
             imported_from: None,
         }
     }
 }
	//! The Rust AST Visitor. Extracts useful information and massages it into a form
	//! usable for `clean`.

	use rustc::hir::{self, Node};
	use rustc::hir::def::Def;
	use rustc::hir::def_id::{DefId, LOCAL_CRATE};
	use rustc::middle::privacy::AccessLevel;
	use rustc::util::nodemap::{FxHashSet, FxHashMap};
	use syntax::ast;
	use syntax::attr;
	use syntax::ext::base::MacroKind;
	use syntax::source_map::Spanned;
	use syntax_pos::{self, Span};

	use std::mem;

	use crate::core;
	use crate::clean::{self, AttributesExt, NestedAttributesExt, def_id_to_path};
	use crate::doctree::*;


	// Looks to me like the first two of these are actually
	// output parameters, maybe only mutated once; perhaps
	// better simply to have the visit method return a tuple
	// containing them?

	// Also, is there some reason that this doesn't use the 'visit'
	// framework from syntax?.

	pub struct RustdocVisitor<'a, 'tcx> {
	pub module: Module,
	pub attrs: hir::HirVec<ast::Attribute>,
	pub cx: &'a core::DocContext<'tcx>,
	view_item_stack: FxHashSet<ast::NodeId>,
	inlining: bool,
	/// Are the current module and all of its parents public?
	inside_public_path: bool,
	exact_paths: Option<FxHashMap<DefId, Vec<String>>>,
	}

	impl<'a, 'tcx> RustdocVisitor<'a, 'tcx> {
	pub fn new(
	cx: &'a core::DocContext<'tcx>
	) -> RustdocVisitor<'a, 'tcx> {
	// If the root is re-exported, terminate all recursion.
	let mut stack = FxHashSet::default();
	stack.insert(ast::CRATE_NODE_ID);
	RustdocVisitor {
	module: Module::new(None),
	attrs: hir::HirVec::new(),
	cx,
	view_item_stack: stack,
	inlining: false,
	inside_public_path: true,
	exact_paths: Some(FxHashMap::default()),
	}
	}

	fn store_path(&mut self, did: DefId) {
	// We can't use the entry API, as that keeps the mutable borrow of `self` active
	// when we try to use `cx`.
	let exact_paths = self.exact_paths.as_mut().unwrap();
	if exact_paths.get(&did).is_none() {
	let path = def_id_to_path(self.cx, did, self.cx.crate_name.clone());
	exact_paths.insert(did, path);
	}
	}

	fn stability(&self, id: hir::HirId) -> Option<attr::Stability> {
	self.cx.tcx.hir().opt_local_def_id_from_hir_id(id)
	.and_then(\|def_id\| self.cx.tcx.lookup_stability(def_id)).cloned()
	}

	fn deprecation(&self, id: hir::HirId) -> Option<attr::Deprecation> {
	self.cx.tcx.hir().opt_local_def_id_from_hir_id(id)
	.and_then(\|def_id\| self.cx.tcx.lookup_deprecation(def_id))
	}

	pub fn visit(&mut self, krate: &hir::Crate) {
	self.attrs = krate.attrs.clone();

	self.module = self.visit_mod_contents(krate.span,
	krate.attrs.clone(),
	Spanned { span: syntax_pos::DUMMY_SP,
	node: hir::VisibilityKind::Public },
	hir::CRATE_HIR_ID,
	&krate.module,
	None);
	// Attach the crate's exported macros to the top-level module:
	let macro_exports: Vec<_> =
	krate.exported_macros.iter().map(\|def\| self.visit_local_macro(def, None)).collect();
	self.module.macros.extend(macro_exports);
	self.module.is_crate = true;

	self.cx.renderinfo.borrow_mut().exact_paths = self.exact_paths.take().unwrap();
	}

	pub fn visit_variant_data(&mut self, item: &hir::Item,
	name: ast::Name, sd: &hir::VariantData,
	generics: &hir::Generics) -> Struct {
	debug!("Visiting struct");
	let struct_type = struct_type_from_def(&*sd);
	Struct {
	id: item.hir_id,
	struct_type,
	name,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	attrs: item.attrs.clone(),
	generics: generics.clone(),
	fields: sd.fields().iter().cloned().collect(),
	whence: item.span
	}
	}

	pub fn visit_union_data(&mut self, item: &hir::Item,
	name: ast::Name, sd: &hir::VariantData,
	generics: &hir::Generics) -> Union {
	debug!("Visiting union");
	let struct_type = struct_type_from_def(&*sd);
	Union {
	id: item.hir_id,
	struct_type,
	name,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	attrs: item.attrs.clone(),
	generics: generics.clone(),
	fields: sd.fields().iter().cloned().collect(),
	whence: item.span
	}
	}

	pub fn visit_enum_def(&mut self, it: &hir::Item,
	name: ast::Name, def: &hir::EnumDef,
	params: &hir::Generics) -> Enum {
	debug!("Visiting enum");
	Enum {
	name,
	variants: def.variants.iter().map(\|v\| Variant {
	name: v.node.ident.name,
	attrs: v.node.attrs.clone(),
	stab: self.stability(v.node.data.hir_id()),
	depr: self.deprecation(v.node.data.hir_id()),
	def: v.node.data.clone(),
	whence: v.span,
	}).collect(),
	vis: it.vis.clone(),
	stab: self.stability(it.hir_id),
	depr: self.deprecation(it.hir_id),
	generics: params.clone(),
	attrs: it.attrs.clone(),
	id: it.hir_id,
	whence: it.span,
	}
	}

	pub fn visit_fn(&mut self, om: &mut Module, item: &hir::Item,
	name: ast::Name, fd: &hir::FnDecl,
	header: hir::FnHeader,
	gen: &hir::Generics,
	body: hir::BodyId) {
	debug!("Visiting fn");
	let macro_kind = item.attrs.iter().filter_map(\|a\| {
	if a.check_name("proc_macro") {
	Some(MacroKind::Bang)
	} else if a.check_name("proc_macro_derive") {
	Some(MacroKind::Derive)
	} else if a.check_name("proc_macro_attribute") {
	Some(MacroKind::Attr)
	} else {
	None
	}
	}).next();
	match macro_kind {
	Some(kind) => {
	let name = if kind == MacroKind::Derive {
	item.attrs.lists("proc_macro_derive")
	.filter_map(\|mi\| mi.ident())
	.next()
	.expect("proc-macro derives require a name")
	.name
	} else {
	name
	};

	let mut helpers = Vec::new();
	for mi in item.attrs.lists("proc_macro_derive") {
	if !mi.check_name("attributes") {
	continue;
	}

	if let Some(list) = mi.meta_item_list() {
	for inner_mi in list {
	if let Some(ident) = inner_mi.ident() {
	helpers.push(ident.name);
	}
	}
	}
	}

	om.proc_macros.push(ProcMacro {
	name,
	id: item.hir_id,
	kind,
	helpers,
	attrs: item.attrs.clone(),
	whence: item.span,
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	});
	}
	None => {
	om.fns.push(Function {
	id: item.hir_id,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	attrs: item.attrs.clone(),
	decl: fd.clone(),
	name,
	whence: item.span,
	generics: gen.clone(),
	header,
	body,
	});
	}
	}
	}

	pub fn visit_mod_contents(&mut self, span: Span, attrs: hir::HirVec<ast::Attribute>,
	vis: hir::Visibility, id: hir::HirId,
	m: &hir::Mod,
	name: Option<ast::Name>) -> Module {
	let mut om = Module::new(name);
	om.where_outer = span;
	om.where_inner = m.inner;
	om.attrs = attrs;
	om.vis = vis.clone();
	om.stab = self.stability(id);
	om.depr = self.deprecation(id);
	om.id = self.cx.tcx.hir().hir_to_node_id(id);
	// Keep track of if there were any private modules in the path.
	let orig_inside_public_path = self.inside_public_path;
	self.inside_public_path &= vis.node.is_pub();
	for i in &m.item_ids {
	let item = self.cx.tcx.hir().expect_item(i.id);
	self.visit_item(item, None, &mut om);
	}
	self.inside_public_path = orig_inside_public_path;
	om
	}

	/// Tries to resolve the target of a `pub use` statement and inlines the
	/// target if it is defined locally and would not be documented otherwise,
	/// or when it is specifically requested with `please_inline`.
	/// (the latter is the case when the import is marked `doc(inline)`)
	///
	/// Cross-crate inlining occurs later on during crate cleaning
	/// and follows different rules.
	///
	/// Returns `true` if the target has been inlined.
	fn maybe_inline_local(&mut self,
	id: hir::HirId,
	def: Def,
	renamed: Option<ast::Ident>,
	glob: bool,
	om: &mut Module,
	please_inline: bool) -> bool {

	fn inherits_doc_hidden(cx: &core::DocContext<'_>, mut node: ast::NodeId) -> bool {
	while let Some(id) = cx.tcx.hir().get_enclosing_scope(node) {
	node = id;
	if cx.tcx.hir().attrs(node).lists("doc").has_word("hidden") {
	return true;
	}
	if node == ast::CRATE_NODE_ID {
	break;
	}
	}
	false
	}

	debug!("maybe_inline_local def: {:?}", def);

	let tcx = self.cx.tcx;
	let def_did = if let Some(did) = def.opt_def_id() {
	did
	} else {
	return false;
	};

	let use_attrs = tcx.hir().attrs_by_hir_id(id);
	// Don't inline `doc(hidden)` imports so they can be stripped at a later stage.
	let is_no_inline = use_attrs.lists("doc").has_word("no_inline") \|\|
	use_attrs.lists("doc").has_word("hidden");

	// For cross-crate impl inlining we need to know whether items are
	// reachable in documentation -- a previously nonreachable item can be
	// made reachable by cross-crate inlining which we're checking here.
	// (this is done here because we need to know this upfront).
	if !def_did.is_local() && !is_no_inline {
	let attrs = clean::inline::load_attrs(self.cx, def_did);
	let self_is_hidden = attrs.lists("doc").has_word("hidden");
	match def {
	Def::Trait(did) \|
	Def::Struct(did) \|
	Def::Union(did) \|
	Def::Enum(did) \|
	Def::ForeignTy(did) \|
	Def::TyAlias(did) if !self_is_hidden => {
	self.cx.renderinfo
	.borrow_mut()
	.access_levels.map
	.insert(did, AccessLevel::Public);
	},
	Def::Mod(did) => if !self_is_hidden {
	crate::visit_lib::LibEmbargoVisitor::new(self.cx).visit_mod(did);
	},
	_ => {},
	}

	return false
	}

	let def_node_id = match tcx.hir().as_local_node_id(def_did) {
	Some(n) => n, None => return false
	};

	let is_private = !self.cx.renderinfo.borrow().access_levels.is_public(def_did);
	let is_hidden = inherits_doc_hidden(self.cx, def_node_id);

	// Only inline if requested or if the item would otherwise be stripped.
	if (!please_inline && !is_private && !is_hidden) \|\| is_no_inline {
	return false
	}

	if !self.view_item_stack.insert(def_node_id) { return false }

	let ret = match tcx.hir().get(def_node_id) {
	Node::Item(&hir::Item { node: hir::ItemKind::Mod(ref m), .. }) if glob => {
	let prev = mem::replace(&mut self.inlining, true);
	for i in &m.item_ids {
	let i = self.cx.tcx.hir().expect_item(i.id);
	self.visit_item(i, None, om);
	}
	self.inlining = prev;
	true
	}
	Node::Item(it) if !glob => {
	let prev = mem::replace(&mut self.inlining, true);
	self.visit_item(it, renamed, om);
	self.inlining = prev;
	true
	}
	Node::ForeignItem(it) if !glob => {
	// Generate a fresh `extern {}` block if we want to inline a foreign item.
	om.foreigns.push(hir::ForeignMod {
	abi: tcx.hir().get_foreign_abi_by_hir_id(it.hir_id),
	items: vec![hir::ForeignItem {
	ident: renamed.unwrap_or(it.ident),
	.. it.clone()
	}].into(),
	});
	true
	}
	Node::MacroDef(def) if !glob => {
	om.macros.push(self.visit_local_macro(def, renamed.map(\|i\| i.name)));
	true
	}
	_ => false,
	};
	self.view_item_stack.remove(&def_node_id);
	ret
	}

	pub fn visit_item(&mut self, item: &hir::Item,
	renamed: Option<ast::Ident>, om: &mut Module) {
	debug!("Visiting item {:?}", item);
	let ident = renamed.unwrap_or(item.ident);

	if item.vis.node.is_pub() {
	let def_id = self.cx.tcx.hir().local_def_id_from_hir_id(item.hir_id);
	self.store_path(def_id);
	}

	match item.node {
	hir::ItemKind::ForeignMod(ref fm) => {
	// If inlining we only want to include public functions.
	om.foreigns.push(if self.inlining {
	hir::ForeignMod {
	abi: fm.abi,
	items: fm.items.iter().filter(\|i\| i.vis.node.is_pub()).cloned().collect(),
	}
	} else {
	fm.clone()
	});
	}
	// If we're inlining, skip private items.
	_ if self.inlining && !item.vis.node.is_pub() => {}
	hir::ItemKind::GlobalAsm(..) => {}
	hir::ItemKind::ExternCrate(orig_name) => {
	let def_id = self.cx.tcx.hir().local_def_id_from_hir_id(item.hir_id);
	om.extern_crates.push(ExternCrate {
	cnum: self.cx.tcx.extern_mod_stmt_cnum(def_id)
	.unwrap_or(LOCAL_CRATE),
	name: ident.name,
	path: orig_name.map(\|x\|x.to_string()),
	vis: item.vis.clone(),
	attrs: item.attrs.clone(),
	whence: item.span,
	})
	}
	hir::ItemKind::Use(_, hir::UseKind::ListStem) => {}
	hir::ItemKind::Use(ref path, kind) => {
	let is_glob = kind == hir::UseKind::Glob;

	// Struct and variant constructors and proc macro stubs always show up alongside
	// their definitions, we've already processed them so just discard these.
	match path.def {
	Def::StructCtor(..) \| Def::VariantCtor(..) \| Def::SelfCtor(..) \|
	Def::Macro(_, MacroKind::ProcMacroStub) => return,
	_ => {}
	}

	// If there was a private module in the current path then don't bother inlining
	// anything as it will probably be stripped anyway.
	if item.vis.node.is_pub() && self.inside_public_path {
	let please_inline = item.attrs.iter().any(\|item\| {
	match item.meta_item_list() {
	Some(ref list) if item.check_name("doc") => {
	list.iter().any(\|i\| i.check_name("inline"))
	}
	_ => false,
	}
	});
	let ident = if is_glob { None } else { Some(ident) };
	if self.maybe_inline_local(item.hir_id,
	path.def,
	ident,
	is_glob,
	om,
	please_inline) {
	return;
	}
	}

	om.imports.push(Import {
	name: ident.name,
	id: item.hir_id,
	vis: item.vis.clone(),
	attrs: item.attrs.clone(),
	path: (**path).clone(),
	glob: is_glob,
	whence: item.span,
	});
	}
	hir::ItemKind::Mod(ref m) => {
	om.mods.push(self.visit_mod_contents(item.span,
	item.attrs.clone(),
	item.vis.clone(),
	item.hir_id,
	m,
	Some(ident.name)));
	},
	hir::ItemKind::Enum(ref ed, ref gen) =>
	om.enums.push(self.visit_enum_def(item, ident.name, ed, gen)),
	hir::ItemKind::Struct(ref sd, ref gen) =>
	om.structs.push(self.visit_variant_data(item, ident.name, sd, gen)),
	hir::ItemKind::Union(ref sd, ref gen) =>
	om.unions.push(self.visit_union_data(item, ident.name, sd, gen)),
	hir::ItemKind::Fn(ref fd, header, ref gen, body) =>
	self.visit_fn(om, item, ident.name, &**fd, header, gen, body),
	hir::ItemKind::Ty(ref ty, ref gen) => {
	let t = Typedef {
	ty: ty.clone(),
	gen: gen.clone(),
	name: ident.name,
	id: item.hir_id,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.typedefs.push(t);
	},
	hir::ItemKind::Existential(ref exist_ty) => {
	let t = Existential {
	exist_ty: exist_ty.clone(),
	name: ident.name,
	id: item.hir_id,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.existentials.push(t);
	},
	hir::ItemKind::Static(ref ty, ref mut_, ref exp) => {
	let s = Static {
	type_: ty.clone(),
	mutability: mut_.clone(),
	expr: exp.clone(),
	id: item.hir_id,
	name: ident.name,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.statics.push(s);
	},
	hir::ItemKind::Const(ref ty, ref exp) => {
	let s = Constant {
	type_: ty.clone(),
	expr: exp.clone(),
	id: item.hir_id,
	name: ident.name,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.constants.push(s);
	},
	hir::ItemKind::Trait(is_auto, unsafety, ref gen, ref b, ref item_ids) => {
	let items = item_ids.iter()
	.map(\|ti\| self.cx.tcx.hir().trait_item(ti.id).clone())
	.collect();
	let t = Trait {
	is_auto,
	unsafety,
	name: ident.name,
	items,
	generics: gen.clone(),
	bounds: b.iter().cloned().collect(),
	id: item.hir_id,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.traits.push(t);
	},
	hir::ItemKind::TraitAlias(ref gen, ref b) => {
	let t = TraitAlias {
	name: ident.name,
	generics: gen.clone(),
	bounds: b.iter().cloned().collect(),
	id: item.hir_id,
	attrs: item.attrs.clone(),
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.trait_aliases.push(t);
	},

	hir::ItemKind::Impl(unsafety,
	polarity,
	defaultness,
	ref gen,
	ref tr,
	ref ty,
	ref item_ids) => {
	// Don't duplicate impls when inlining or if it's implementing a trait, we'll pick
	// them up regardless of where they're located.
	if !self.inlining && tr.is_none() {
	let items = item_ids.iter()
	.map(\|ii\| self.cx.tcx.hir().impl_item(ii.id).clone())
	.collect();
	let i = Impl {
	unsafety,
	polarity,
	defaultness,
	generics: gen.clone(),
	trait_: tr.clone(),
	for_: ty.clone(),
	items,
	attrs: item.attrs.clone(),
	id: item.hir_id,
	whence: item.span,
	vis: item.vis.clone(),
	stab: self.stability(item.hir_id),
	depr: self.deprecation(item.hir_id),
	};
	om.impls.push(i);
	}
	},
	}
	}

	// Convert each `exported_macro` into a doc item.
	fn visit_local_macro(
	&self,
	def: &hir::MacroDef,
	renamed: Option<ast::Name>
	) -> Macro {
	debug!("visit_local_macro: {}", def.name);
	let tts = def.body.trees().collect::<Vec<_>>();
	// Extract the spans of all matchers. They represent the "interface" of the macro.
	let matchers = tts.chunks(4).map(\|arm\| arm[0].span()).collect();

	Macro {

	def_id: self.cx.tcx.hir().local_def_id_from_hir_id(def.hir_id),
	attrs: def.attrs.clone(),
	name: renamed.unwrap_or(def.name),
	whence: def.span,
	matchers,
	stab: self.stability(def.hir_id),
	depr: self.deprecation(def.hir_id),
	imported_from: None,
	}
	}
	}