src/librustc/hir/map/collector.rs - third_party/rust - Git at Google

 use super::*;
 use dep_graph::{DepGraph, DepKind, DepNodeIndex};
 use hir::def_id::{LOCAL_CRATE, CrateNum};
 use hir::intravisit::{Visitor, NestedVisitorMap};
 use rustc_data_structures::svh::Svh;
 use ich::Fingerprint;
 use middle::cstore::CrateStore;
 use session::CrateDisambiguator;
 use session::Session;
 use std::iter::repeat;
 use syntax::ast::{NodeId, CRATE_NODE_ID};
 use syntax::source_map::SourceMap;
 use syntax_pos::Span;

 use ich::StableHashingContext;
 use rustc_data_structures::stable_hasher::{HashStable, StableHasher, StableHasherResult};

 /// A Visitor that walks over the HIR and collects Nodes into a HIR map
 pub(super) struct NodeCollector<'a, 'hir> {
     /// The crate
     krate: &'hir Crate,

     /// Source map
     source_map: &'a SourceMap,

     /// The node map
     map: Vec<Option<Entry<'hir>>>,
     /// The parent of this node
     parent_node: NodeId,

     // These fields keep track of the currently relevant DepNodes during
     // the visitor's traversal.
     current_dep_node_owner: DefIndex,
     current_signature_dep_index: DepNodeIndex,
     current_full_dep_index: DepNodeIndex,
     currently_in_body: bool,

     dep_graph: &'a DepGraph,
     definitions: &'a definitions::Definitions,

     hcx: StableHashingContext<'a>,

     // We are collecting DepNode::HirBody hashes here so we can compute the
     // crate hash from then later on.
     hir_body_nodes: Vec<(DefPathHash, Fingerprint)>,
 }

 fn input_dep_node_and_hash<'a, I>(
     dep_graph: &DepGraph,
     hcx: &mut StableHashingContext<'a>,
     dep_node: DepNode,
     input: I,
 ) -> (DepNodeIndex, Fingerprint)
 where
     I: HashStable<StableHashingContext<'a>>,
 {
     let dep_node_index = dep_graph.input_task(dep_node, &mut *hcx, &input).1;

     let hash = if dep_graph.is_fully_enabled() {
         dep_graph.fingerprint_of(dep_node_index)
     } else {
         let mut stable_hasher = StableHasher::new();
         input.hash_stable(hcx, &mut stable_hasher);
         stable_hasher.finish()
     };

     (dep_node_index, hash)
 }

 fn alloc_hir_dep_nodes<'a, I>(
     dep_graph: &DepGraph,
     hcx: &mut StableHashingContext<'a>,
     def_path_hash: DefPathHash,
     item_like: I,
     hir_body_nodes: &mut Vec<(DefPathHash, Fingerprint)>,
 ) -> (DepNodeIndex, DepNodeIndex)
 where
     I: HashStable<StableHashingContext<'a>>,
 {
     let sig = dep_graph.input_task(
         def_path_hash.to_dep_node(DepKind::Hir),
         &mut *hcx,
         HirItemLike { item_like: &item_like, hash_bodies: false },
     ).1;
     let (full, hash) = input_dep_node_and_hash(
         dep_graph,
         hcx,
         def_path_hash.to_dep_node(DepKind::HirBody),
         HirItemLike { item_like: &item_like, hash_bodies: true },
     );
     hir_body_nodes.push((def_path_hash, hash));
     (sig, full)
 }

 impl<'a, 'hir> NodeCollector<'a, 'hir> {
     pub(super) fn root(sess: &'a Session,
                        krate: &'hir Crate,
                        dep_graph: &'a DepGraph,
                        definitions: &'a definitions::Definitions,
                        mut hcx: StableHashingContext<'a>)
                 -> NodeCollector<'a, 'hir> {
         let root_mod_def_path_hash = definitions.def_path_hash(CRATE_DEF_INDEX);

         let mut hir_body_nodes = Vec::new();

         // Allocate DepNodes for the root module
         let (root_mod_sig_dep_index, root_mod_full_dep_index) = {
             let Crate {
                 ref module,
                 // Crate attributes are not copied over to the root `Mod`, so hash
                 // them explicitly here.
                 ref attrs,
                 span,
                 // These fields are handled separately:
                 exported_macros: _,
                 items: _,
                 trait_items: _,
                 impl_items: _,
                 bodies: _,
                 trait_impls: _,
                 trait_auto_impl: _,
                 body_ids: _,
                 modules: _,
             } = *krate;

             alloc_hir_dep_nodes(
                 dep_graph,
                 &mut hcx,
                 root_mod_def_path_hash,
                 (module, attrs, span),
                 &mut hir_body_nodes,
             )
         };

         {
             dep_graph.input_task(
                 DepNode::new_no_params(DepKind::AllLocalTraitImpls),
                 &mut hcx,
                 &krate.trait_impls,
             );
         }

         let mut collector = NodeCollector {
             krate,
             source_map: sess.source_map(),
             map: repeat(None).take(sess.current_node_id_count()).collect(),
             parent_node: CRATE_NODE_ID,
             current_signature_dep_index: root_mod_sig_dep_index,
             current_full_dep_index: root_mod_full_dep_index,
             current_dep_node_owner: CRATE_DEF_INDEX,
             currently_in_body: false,
             dep_graph,
             definitions,
             hcx,
             hir_body_nodes,
         };
         collector.insert_entry(CRATE_NODE_ID, Entry {
             parent: CRATE_NODE_ID,
             dep_node: root_mod_sig_dep_index,
             node: Node::Crate,
         });

         collector
     }

     pub(super) fn finalize_and_compute_crate_hash(mut self,
                                                   crate_disambiguator: CrateDisambiguator,
                                                   cstore: &dyn CrateStore,
                                                   commandline_args_hash: u64)
                                                   -> (Vec<Option<Entry<'hir>>>, Svh)
     {
         self.hir_body_nodes.sort_unstable_by_key(|bn| bn.0);

         let node_hashes = self
             .hir_body_nodes
             .iter()
             .fold(Fingerprint::ZERO, |combined_fingerprint, &(def_path_hash, fingerprint)| {
                 combined_fingerprint.combine(def_path_hash.0.combine(fingerprint))
             });

         let mut upstream_crates: Vec<_> = cstore.crates_untracked().iter().map(|&cnum| {
             let name = cstore.crate_name_untracked(cnum).as_str();
             let disambiguator = cstore.crate_disambiguator_untracked(cnum).to_fingerprint();
             let hash = cstore.crate_hash_untracked(cnum);
             (name, disambiguator, hash)
         }).collect();

         upstream_crates.sort_unstable_by_key(|&(name, dis, _)| (name, dis));

         // We hash the final, remapped names of all local source files so we
         // don't have to include the path prefix remapping commandline args.
         // If we included the full mapping in the SVH, we could only have
         // reproducible builds by compiling from the same directory. So we just
         // hash the result of the mapping instead of the mapping itself.
         let mut source_file_names: Vec<_> = self
             .source_map
             .files()
             .iter()
             .filter(|source_file| CrateNum::from_u32(source_file.crate_of_origin) == LOCAL_CRATE)
             .map(|source_file| source_file.name_hash)
             .collect();

         source_file_names.sort_unstable();

         let crate_hash_input = (
             ((node_hashes, upstream_crates), source_file_names),
             (commandline_args_hash, crate_disambiguator.to_fingerprint())
         );

         let (_, crate_hash) = input_dep_node_and_hash(
             self.dep_graph,
             &mut self.hcx,
             DepNode::new_no_params(DepKind::Krate),
             crate_hash_input,
         );

         let svh = Svh::new(crate_hash.to_smaller_hash());
         (self.map, svh)
     }

     fn insert_entry(&mut self, id: NodeId, entry: Entry<'hir>) {
         debug!("hir_map: {:?} => {:?}", id, entry);
         self.map[id.as_usize()] = Some(entry);
     }

     fn insert(&mut self, span: Span, id: NodeId, node: Node<'hir>) {
         let entry = Entry {
             parent: self.parent_node,
             dep_node: if self.currently_in_body {
                 self.current_full_dep_index
             } else {
                 self.current_signature_dep_index
             },
             node,
         };

         // Make sure that the DepNode of some node coincides with the HirId
         // owner of that node.
         if cfg!(debug_assertions) {
             let hir_id = self.definitions.node_to_hir_id(id);

             if hir_id.owner != self.current_dep_node_owner {
                 let node_str = match self.definitions.opt_def_index(id) {
                     Some(def_index) => {
                         self.definitions.def_path(def_index).to_string_no_crate()
                     }
                     None => format!("{:?}", node)
                 };

                 let forgot_str = if hir_id == ::hir::DUMMY_HIR_ID {
                     format!("\nMaybe you forgot to lower the node id {:?}?", id)
                 } else {
                     String::new()
                 };

                 span_bug!(
                     span,
                     "inconsistent DepNode at `{:?}` for `{}`: \
                      current_dep_node_owner={} ({:?}), hir_id.owner={} ({:?}){}",
                     self.source_map.span_to_string(span),
                     node_str,
                     self.definitions
                         .def_path(self.current_dep_node_owner)
                         .to_string_no_crate(),
                     self.current_dep_node_owner,
                     self.definitions.def_path(hir_id.owner).to_string_no_crate(),
                     hir_id.owner,
                     forgot_str,
                 )
             }
         }

         self.insert_entry(id, entry);
     }

     fn with_parent<F: FnOnce(&mut Self)>(&mut self, parent_id: NodeId, f: F) {
         let parent_node = self.parent_node;
         self.parent_node = parent_id;
         f(self);
         self.parent_node = parent_node;
     }

     fn with_dep_node_owner<T: HashStable<StableHashingContext<'a>>,
                            F: FnOnce(&mut Self)>(&mut self,
                                                  dep_node_owner: DefIndex,
                                                  item_like: &T,
                                                  f: F) {
         let prev_owner = self.current_dep_node_owner;
         let prev_signature_dep_index = self.current_signature_dep_index;
         let prev_full_dep_index = self.current_full_dep_index;
         let prev_in_body = self.currently_in_body;

         let def_path_hash = self.definitions.def_path_hash(dep_node_owner);

         let (signature_dep_index, full_dep_index) = alloc_hir_dep_nodes(
             self.dep_graph,
             &mut self.hcx,
             def_path_hash,
             item_like,
             &mut self.hir_body_nodes,
         );
         self.current_signature_dep_index = signature_dep_index;
         self.current_full_dep_index = full_dep_index;

         self.current_dep_node_owner = dep_node_owner;
         self.currently_in_body = false;
         f(self);
         self.currently_in_body = prev_in_body;
         self.current_dep_node_owner = prev_owner;
         self.current_full_dep_index = prev_full_dep_index;
         self.current_signature_dep_index = prev_signature_dep_index;
     }
 }

 impl<'a, 'hir> Visitor<'hir> for NodeCollector<'a, 'hir> {
     /// Because we want to track parent items and so forth, enable
     /// deep walking so that we walk nested items in the context of
     /// their outer items.

     fn nested_visit_map<'this>(&'this mut self) -> NestedVisitorMap<'this, 'hir> {
         panic!("visit_nested_xxx must be manually implemented in this visitor")
     }

     fn visit_nested_item(&mut self, item: ItemId) {
         debug!("visit_nested_item: {:?}", item);
         self.visit_item(self.krate.item(item.id));
     }

     fn visit_nested_trait_item(&mut self, item_id: TraitItemId) {
         self.visit_trait_item(self.krate.trait_item(item_id));
     }

     fn visit_nested_impl_item(&mut self, item_id: ImplItemId) {
         self.visit_impl_item(self.krate.impl_item(item_id));
     }

     fn visit_nested_body(&mut self, id: BodyId) {
         let prev_in_body = self.currently_in_body;
         self.currently_in_body = true;
         self.visit_body(self.krate.body(id));
         self.currently_in_body = prev_in_body;
     }

     fn visit_item(&mut self, i: &'hir Item) {
         debug!("visit_item: {:?}", i);
         debug_assert_eq!(i.hir_id.owner,
                          self.definitions.opt_def_index(i.id).unwrap());
         self.with_dep_node_owner(i.hir_id.owner, i, |this| {
             this.insert(i.span, i.id, Node::Item(i));
             this.with_parent(i.id, |this| {
                 if let ItemKind::Struct(ref struct_def, _) = i.node {
                     // If this is a tuple-like struct, register the constructor.
                     if !struct_def.is_struct() {
                         this.insert(i.span, struct_def.id(), Node::StructCtor(struct_def));
                     }
                 }
                 intravisit::walk_item(this, i);
             });
         });
     }

     fn visit_foreign_item(&mut self, foreign_item: &'hir ForeignItem) {
         self.insert(foreign_item.span, foreign_item.id, Node::ForeignItem(foreign_item));

         self.with_parent(foreign_item.id, |this| {
             intravisit::walk_foreign_item(this, foreign_item);
         });
     }

     fn visit_generic_param(&mut self, param: &'hir GenericParam) {
         self.insert(param.span, param.id, Node::GenericParam(param));
         intravisit::walk_generic_param(self, param);
     }

     fn visit_trait_item(&mut self, ti: &'hir TraitItem) {
         debug_assert_eq!(ti.hir_id.owner,
                          self.definitions.opt_def_index(ti.id).unwrap());
         self.with_dep_node_owner(ti.hir_id.owner, ti, |this| {
             this.insert(ti.span, ti.id, Node::TraitItem(ti));

             this.with_parent(ti.id, |this| {
                 intravisit::walk_trait_item(this, ti);
             });
         });
     }

     fn visit_impl_item(&mut self, ii: &'hir ImplItem) {
         debug_assert_eq!(ii.hir_id.owner,
                          self.definitions.opt_def_index(ii.id).unwrap());
         self.with_dep_node_owner(ii.hir_id.owner, ii, |this| {
             this.insert(ii.span, ii.id, Node::ImplItem(ii));

             this.with_parent(ii.id, |this| {
                 intravisit::walk_impl_item(this, ii);
             });
         });
     }

     fn visit_pat(&mut self, pat: &'hir Pat) {
         let node = if let PatKind::Binding(..) = pat.node {
             Node::Binding(pat)
         } else {
             Node::Pat(pat)
         };
         self.insert(pat.span, pat.id, node);

         self.with_parent(pat.id, |this| {
             intravisit::walk_pat(this, pat);
         });
     }

     fn visit_anon_const(&mut self, constant: &'hir AnonConst) {
         self.insert(DUMMY_SP, constant.id, Node::AnonConst(constant));

         self.with_parent(constant.id, |this| {
             intravisit::walk_anon_const(this, constant);
         });
     }

     fn visit_expr(&mut self, expr: &'hir Expr) {
         self.insert(expr.span, expr.id, Node::Expr(expr));

         self.with_parent(expr.id, |this| {
             intravisit::walk_expr(this, expr);
         });
     }

     fn visit_stmt(&mut self, stmt: &'hir Stmt) {
         let id = stmt.id;
         self.insert(stmt.span, id, Node::Stmt(stmt));

         self.with_parent(id, |this| {
             intravisit::walk_stmt(this, stmt);
         });
     }

     fn visit_path_segment(&mut self, path_span: Span, path_segment: &'hir PathSegment) {
         if let Some(id) = path_segment.id {
             self.insert(path_span, id, Node::PathSegment(path_segment));
         }
         intravisit::walk_path_segment(self, path_span, path_segment);
     }

     fn visit_ty(&mut self, ty: &'hir Ty) {
         self.insert(ty.span, ty.id, Node::Ty(ty));

         self.with_parent(ty.id, |this| {
             intravisit::walk_ty(this, ty);
         });
     }

     fn visit_trait_ref(&mut self, tr: &'hir TraitRef) {
         self.insert(tr.path.span, tr.ref_id, Node::TraitRef(tr));

         self.with_parent(tr.ref_id, |this| {
             intravisit::walk_trait_ref(this, tr);
         });
     }

     fn visit_fn(&mut self, fk: intravisit::FnKind<'hir>, fd: &'hir FnDecl,
                 b: BodyId, s: Span, id: NodeId) {
         assert_eq!(self.parent_node, id);
         intravisit::walk_fn(self, fk, fd, b, s, id);
     }

     fn visit_block(&mut self, block: &'hir Block) {
         self.insert(block.span, block.id, Node::Block(block));
         self.with_parent(block.id, |this| {
             intravisit::walk_block(this, block);
         });
     }

     fn visit_local(&mut self, l: &'hir Local) {
         self.insert(l.span, l.id, Node::Local(l));
         self.with_parent(l.id, |this| {
             intravisit::walk_local(this, l)
         })
     }

     fn visit_lifetime(&mut self, lifetime: &'hir Lifetime) {
         self.insert(lifetime.span, lifetime.id, Node::Lifetime(lifetime));
     }

     fn visit_vis(&mut self, visibility: &'hir Visibility) {
         match visibility.node {
             VisibilityKind::Public |
             VisibilityKind::Crate(_) |
             VisibilityKind::Inherited => {}
             VisibilityKind::Restricted { id, .. } => {
                 self.insert(visibility.span, id, Node::Visibility(visibility));
                 self.with_parent(id, |this| {
                     intravisit::walk_vis(this, visibility);
                 });
             }
         }
     }

     fn visit_macro_def(&mut self, macro_def: &'hir MacroDef) {
         let def_index = self.definitions.opt_def_index(macro_def.id).unwrap();

         self.with_dep_node_owner(def_index, macro_def, |this| {
             this.insert(macro_def.span, macro_def.id, Node::MacroDef(macro_def));
         });
     }

     fn visit_variant(&mut self, v: &'hir Variant, g: &'hir Generics, item_id: NodeId) {
         let id = v.node.data.id();
         self.insert(v.span, id, Node::Variant(v));
         self.with_parent(id, |this| {
             intravisit::walk_variant(this, v, g, item_id);
         });
     }

     fn visit_struct_field(&mut self, field: &'hir StructField) {
         self.insert(field.span, field.id, Node::Field(field));
         self.with_parent(field.id, |this| {
             intravisit::walk_struct_field(this, field);
         });
     }

     fn visit_trait_item_ref(&mut self, ii: &'hir TraitItemRef) {
         // Do not visit the duplicate information in TraitItemRef. We want to
         // map the actual nodes, not the duplicate ones in the *Ref.
         let TraitItemRef {
             id,
             ident: _,
             kind: _,
             span: _,
             defaultness: _,
         } = *ii;

         self.visit_nested_trait_item(id);
     }

     fn visit_impl_item_ref(&mut self, ii: &'hir ImplItemRef) {
         // Do not visit the duplicate information in ImplItemRef. We want to
         // map the actual nodes, not the duplicate ones in the *Ref.
         let ImplItemRef {
             id,
             ident: _,
             kind: _,
             span: _,
             vis: _,
             defaultness: _,
         } = *ii;

         self.visit_nested_impl_item(id);
     }
 }

 // This is a wrapper structure that allows determining if span values within
 // the wrapped item should be hashed or not.
 struct HirItemLike<T> {
     item_like: T,
     hash_bodies: bool,
 }

 impl<'a, 'hir, T> HashStable<StableHashingContext<'hir>> for HirItemLike<T>
     where T: HashStable<StableHashingContext<'hir>>
 {
     fn hash_stable<W: StableHasherResult>(&self,
                                           hcx: &mut StableHashingContext<'hir>,
                                           hasher: &mut StableHasher<W>) {
         hcx.while_hashing_hir_bodies(self.hash_bodies, |hcx| {
             self.item_like.hash_stable(hcx, hasher);
         });
     }
 }
	use super::*;
	use dep_graph::{DepGraph, DepKind, DepNodeIndex};
	use hir::def_id::{LOCAL_CRATE, CrateNum};
	use hir::intravisit::{Visitor, NestedVisitorMap};
	use rustc_data_structures::svh::Svh;
	use ich::Fingerprint;
	use middle::cstore::CrateStore;
	use session::CrateDisambiguator;
	use session::Session;
	use std::iter::repeat;
	use syntax::ast::{NodeId, CRATE_NODE_ID};
	use syntax::source_map::SourceMap;
	use syntax_pos::Span;

	use ich::StableHashingContext;
	use rustc_data_structures::stable_hasher::{HashStable, StableHasher, StableHasherResult};

	/// A Visitor that walks over the HIR and collects Nodes into a HIR map
	pub(super) struct NodeCollector<'a, 'hir> {
	/// The crate
	krate: &'hir Crate,

	/// Source map
	source_map: &'a SourceMap,

	/// The node map
	map: Vec<Option<Entry<'hir>>>,
	/// The parent of this node
	parent_node: NodeId,

	// These fields keep track of the currently relevant DepNodes during
	// the visitor's traversal.
	current_dep_node_owner: DefIndex,
	current_signature_dep_index: DepNodeIndex,
	current_full_dep_index: DepNodeIndex,
	currently_in_body: bool,

	dep_graph: &'a DepGraph,
	definitions: &'a definitions::Definitions,

	hcx: StableHashingContext<'a>,

	// We are collecting DepNode::HirBody hashes here so we can compute the
	// crate hash from then later on.
	hir_body_nodes: Vec<(DefPathHash, Fingerprint)>,
	}

	fn input_dep_node_and_hash<'a, I>(
	dep_graph: &DepGraph,
	hcx: &mut StableHashingContext<'a>,
	dep_node: DepNode,
	input: I,
	) -> (DepNodeIndex, Fingerprint)
	where
	I: HashStable<StableHashingContext<'a>>,
	{
	let dep_node_index = dep_graph.input_task(dep_node, &mut *hcx, &input).1;

	let hash = if dep_graph.is_fully_enabled() {
	dep_graph.fingerprint_of(dep_node_index)
	} else {
	let mut stable_hasher = StableHasher::new();
	input.hash_stable(hcx, &mut stable_hasher);
	stable_hasher.finish()
	};

	(dep_node_index, hash)
	}

	fn alloc_hir_dep_nodes<'a, I>(
	dep_graph: &DepGraph,
	hcx: &mut StableHashingContext<'a>,
	def_path_hash: DefPathHash,
	item_like: I,
	hir_body_nodes: &mut Vec<(DefPathHash, Fingerprint)>,
	) -> (DepNodeIndex, DepNodeIndex)
	where
	I: HashStable<StableHashingContext<'a>>,
	{
	let sig = dep_graph.input_task(
	def_path_hash.to_dep_node(DepKind::Hir),
	&mut *hcx,
	HirItemLike { item_like: &item_like, hash_bodies: false },
	).1;
	let (full, hash) = input_dep_node_and_hash(
	dep_graph,
	hcx,
	def_path_hash.to_dep_node(DepKind::HirBody),
	HirItemLike { item_like: &item_like, hash_bodies: true },
	);
	hir_body_nodes.push((def_path_hash, hash));
	(sig, full)
	}

	impl<'a, 'hir> NodeCollector<'a, 'hir> {
	pub(super) fn root(sess: &'a Session,
	krate: &'hir Crate,
	dep_graph: &'a DepGraph,
	definitions: &'a definitions::Definitions,
	mut hcx: StableHashingContext<'a>)
	-> NodeCollector<'a, 'hir> {
	let root_mod_def_path_hash = definitions.def_path_hash(CRATE_DEF_INDEX);

	let mut hir_body_nodes = Vec::new();

	// Allocate DepNodes for the root module
	let (root_mod_sig_dep_index, root_mod_full_dep_index) = {
	let Crate {
	ref module,
	// Crate attributes are not copied over to the root `Mod`, so hash
	// them explicitly here.
	ref attrs,
	span,
	// These fields are handled separately:
	exported_macros: _,
	items: _,
	trait_items: _,
	impl_items: _,
	bodies: _,
	trait_impls: _,
	trait_auto_impl: _,
	body_ids: _,
	modules: _,
	} = *krate;

	alloc_hir_dep_nodes(
	dep_graph,
	&mut hcx,
	root_mod_def_path_hash,
	(module, attrs, span),
	&mut hir_body_nodes,
	)
	};

	{
	dep_graph.input_task(
	DepNode::new_no_params(DepKind::AllLocalTraitImpls),
	&mut hcx,
	&krate.trait_impls,
	);
	}

	let mut collector = NodeCollector {
	krate,
	source_map: sess.source_map(),
	map: repeat(None).take(sess.current_node_id_count()).collect(),
	parent_node: CRATE_NODE_ID,
	current_signature_dep_index: root_mod_sig_dep_index,
	current_full_dep_index: root_mod_full_dep_index,
	current_dep_node_owner: CRATE_DEF_INDEX,
	currently_in_body: false,
	dep_graph,
	definitions,
	hcx,
	hir_body_nodes,
	};
	collector.insert_entry(CRATE_NODE_ID, Entry {
	parent: CRATE_NODE_ID,
	dep_node: root_mod_sig_dep_index,
	node: Node::Crate,
	});

	collector
	}

	pub(super) fn finalize_and_compute_crate_hash(mut self,
	crate_disambiguator: CrateDisambiguator,
	cstore: &dyn CrateStore,
	commandline_args_hash: u64)
	-> (Vec<Option<Entry<'hir>>>, Svh)
	{
	self.hir_body_nodes.sort_unstable_by_key(\|bn\| bn.0);

	let node_hashes = self
	.hir_body_nodes
	.iter()
	.fold(Fingerprint::ZERO, \|combined_fingerprint, &(def_path_hash, fingerprint)\| {
	combined_fingerprint.combine(def_path_hash.0.combine(fingerprint))
	});

	let mut upstream_crates: Vec<_> = cstore.crates_untracked().iter().map(\|&cnum\| {
	let name = cstore.crate_name_untracked(cnum).as_str();
	let disambiguator = cstore.crate_disambiguator_untracked(cnum).to_fingerprint();
	let hash = cstore.crate_hash_untracked(cnum);
	(name, disambiguator, hash)
	}).collect();

	upstream_crates.sort_unstable_by_key(\|&(name, dis, _)\| (name, dis));

	// We hash the final, remapped names of all local source files so we
	// don't have to include the path prefix remapping commandline args.
	// If we included the full mapping in the SVH, we could only have
	// reproducible builds by compiling from the same directory. So we just
	// hash the result of the mapping instead of the mapping itself.
	let mut source_file_names: Vec<_> = self
	.source_map
	.files()
	.iter()
	.filter(\|source_file\| CrateNum::from_u32(source_file.crate_of_origin) == LOCAL_CRATE)
	.map(\|source_file\| source_file.name_hash)
	.collect();

	source_file_names.sort_unstable();

	let crate_hash_input = (
	((node_hashes, upstream_crates), source_file_names),
	(commandline_args_hash, crate_disambiguator.to_fingerprint())
	);

	let (_, crate_hash) = input_dep_node_and_hash(
	self.dep_graph,
	&mut self.hcx,
	DepNode::new_no_params(DepKind::Krate),
	crate_hash_input,
	);

	let svh = Svh::new(crate_hash.to_smaller_hash());
	(self.map, svh)
	}

	fn insert_entry(&mut self, id: NodeId, entry: Entry<'hir>) {
	debug!("hir_map: {:?} => {:?}", id, entry);
	self.map[id.as_usize()] = Some(entry);
	}

	fn insert(&mut self, span: Span, id: NodeId, node: Node<'hir>) {
	let entry = Entry {
	parent: self.parent_node,
	dep_node: if self.currently_in_body {
	self.current_full_dep_index
	} else {
	self.current_signature_dep_index
	},
	node,
	};

	// Make sure that the DepNode of some node coincides with the HirId
	// owner of that node.
	if cfg!(debug_assertions) {
	let hir_id = self.definitions.node_to_hir_id(id);

	if hir_id.owner != self.current_dep_node_owner {
	let node_str = match self.definitions.opt_def_index(id) {
	Some(def_index) => {
	self.definitions.def_path(def_index).to_string_no_crate()
	}
	None => format!("{:?}", node)
	};

	let forgot_str = if hir_id == ::hir::DUMMY_HIR_ID {
	format!("\nMaybe you forgot to lower the node id {:?}?", id)
	} else {
	String::new()
	};

	span_bug!(
	span,
	"inconsistent DepNode at `{:?}` for `{}`: \
	current_dep_node_owner={} ({:?}), hir_id.owner={} ({:?}){}",
	self.source_map.span_to_string(span),
	node_str,
	self.definitions
	.def_path(self.current_dep_node_owner)
	.to_string_no_crate(),
	self.current_dep_node_owner,
	self.definitions.def_path(hir_id.owner).to_string_no_crate(),
	hir_id.owner,
	forgot_str,
	)
	}
	}

	self.insert_entry(id, entry);
	}

	fn with_parent<F: FnOnce(&mut Self)>(&mut self, parent_id: NodeId, f: F) {
	let parent_node = self.parent_node;
	self.parent_node = parent_id;
	f(self);
	self.parent_node = parent_node;
	}

	fn with_dep_node_owner<T: HashStable<StableHashingContext<'a>>,
	F: FnOnce(&mut Self)>(&mut self,
	dep_node_owner: DefIndex,
	item_like: &T,
	f: F) {
	let prev_owner = self.current_dep_node_owner;
	let prev_signature_dep_index = self.current_signature_dep_index;
	let prev_full_dep_index = self.current_full_dep_index;
	let prev_in_body = self.currently_in_body;

	let def_path_hash = self.definitions.def_path_hash(dep_node_owner);

	let (signature_dep_index, full_dep_index) = alloc_hir_dep_nodes(
	self.dep_graph,
	&mut self.hcx,
	def_path_hash,
	item_like,
	&mut self.hir_body_nodes,
	);
	self.current_signature_dep_index = signature_dep_index;
	self.current_full_dep_index = full_dep_index;

	self.current_dep_node_owner = dep_node_owner;
	self.currently_in_body = false;
	f(self);
	self.currently_in_body = prev_in_body;
	self.current_dep_node_owner = prev_owner;
	self.current_full_dep_index = prev_full_dep_index;
	self.current_signature_dep_index = prev_signature_dep_index;
	}
	}

	impl<'a, 'hir> Visitor<'hir> for NodeCollector<'a, 'hir> {
	/// Because we want to track parent items and so forth, enable
	/// deep walking so that we walk nested items in the context of
	/// their outer items.

	fn nested_visit_map<'this>(&'this mut self) -> NestedVisitorMap<'this, 'hir> {
	panic!("visit_nested_xxx must be manually implemented in this visitor")
	}

	fn visit_nested_item(&mut self, item: ItemId) {
	debug!("visit_nested_item: {:?}", item);
	self.visit_item(self.krate.item(item.id));
	}

	fn visit_nested_trait_item(&mut self, item_id: TraitItemId) {
	self.visit_trait_item(self.krate.trait_item(item_id));
	}

	fn visit_nested_impl_item(&mut self, item_id: ImplItemId) {
	self.visit_impl_item(self.krate.impl_item(item_id));
	}

	fn visit_nested_body(&mut self, id: BodyId) {
	let prev_in_body = self.currently_in_body;
	self.currently_in_body = true;
	self.visit_body(self.krate.body(id));
	self.currently_in_body = prev_in_body;
	}

	fn visit_item(&mut self, i: &'hir Item) {
	debug!("visit_item: {:?}", i);
	debug_assert_eq!(i.hir_id.owner,
	self.definitions.opt_def_index(i.id).unwrap());
	self.with_dep_node_owner(i.hir_id.owner, i, \|this\| {
	this.insert(i.span, i.id, Node::Item(i));
	this.with_parent(i.id, \|this\| {
	if let ItemKind::Struct(ref struct_def, _) = i.node {
	// If this is a tuple-like struct, register the constructor.
	if !struct_def.is_struct() {
	this.insert(i.span, struct_def.id(), Node::StructCtor(struct_def));
	}
	}
	intravisit::walk_item(this, i);
	});
	});
	}

	fn visit_foreign_item(&mut self, foreign_item: &'hir ForeignItem) {
	self.insert(foreign_item.span, foreign_item.id, Node::ForeignItem(foreign_item));

	self.with_parent(foreign_item.id, \|this\| {
	intravisit::walk_foreign_item(this, foreign_item);
	});
	}

	fn visit_generic_param(&mut self, param: &'hir GenericParam) {
	self.insert(param.span, param.id, Node::GenericParam(param));
	intravisit::walk_generic_param(self, param);
	}

	fn visit_trait_item(&mut self, ti: &'hir TraitItem) {
	debug_assert_eq!(ti.hir_id.owner,
	self.definitions.opt_def_index(ti.id).unwrap());
	self.with_dep_node_owner(ti.hir_id.owner, ti, \|this\| {
	this.insert(ti.span, ti.id, Node::TraitItem(ti));

	this.with_parent(ti.id, \|this\| {
	intravisit::walk_trait_item(this, ti);
	});
	});
	}

	fn visit_impl_item(&mut self, ii: &'hir ImplItem) {
	debug_assert_eq!(ii.hir_id.owner,
	self.definitions.opt_def_index(ii.id).unwrap());
	self.with_dep_node_owner(ii.hir_id.owner, ii, \|this\| {
	this.insert(ii.span, ii.id, Node::ImplItem(ii));

	this.with_parent(ii.id, \|this\| {
	intravisit::walk_impl_item(this, ii);
	});
	});
	}

	fn visit_pat(&mut self, pat: &'hir Pat) {
	let node = if let PatKind::Binding(..) = pat.node {
	Node::Binding(pat)
	} else {
	Node::Pat(pat)
	};
	self.insert(pat.span, pat.id, node);

	self.with_parent(pat.id, \|this\| {
	intravisit::walk_pat(this, pat);
	});
	}

	fn visit_anon_const(&mut self, constant: &'hir AnonConst) {
	self.insert(DUMMY_SP, constant.id, Node::AnonConst(constant));

	self.with_parent(constant.id, \|this\| {
	intravisit::walk_anon_const(this, constant);
	});
	}

	fn visit_expr(&mut self, expr: &'hir Expr) {
	self.insert(expr.span, expr.id, Node::Expr(expr));

	self.with_parent(expr.id, \|this\| {
	intravisit::walk_expr(this, expr);
	});
	}

	fn visit_stmt(&mut self, stmt: &'hir Stmt) {
	let id = stmt.id;
	self.insert(stmt.span, id, Node::Stmt(stmt));

	self.with_parent(id, \|this\| {
	intravisit::walk_stmt(this, stmt);
	});
	}

	fn visit_path_segment(&mut self, path_span: Span, path_segment: &'hir PathSegment) {
	if let Some(id) = path_segment.id {
	self.insert(path_span, id, Node::PathSegment(path_segment));
	}
	intravisit::walk_path_segment(self, path_span, path_segment);
	}

	fn visit_ty(&mut self, ty: &'hir Ty) {
	self.insert(ty.span, ty.id, Node::Ty(ty));

	self.with_parent(ty.id, \|this\| {
	intravisit::walk_ty(this, ty);
	});
	}

	fn visit_trait_ref(&mut self, tr: &'hir TraitRef) {
	self.insert(tr.path.span, tr.ref_id, Node::TraitRef(tr));

	self.with_parent(tr.ref_id, \|this\| {
	intravisit::walk_trait_ref(this, tr);
	});
	}

	fn visit_fn(&mut self, fk: intravisit::FnKind<'hir>, fd: &'hir FnDecl,
	b: BodyId, s: Span, id: NodeId) {
	assert_eq!(self.parent_node, id);
	intravisit::walk_fn(self, fk, fd, b, s, id);
	}

	fn visit_block(&mut self, block: &'hir Block) {
	self.insert(block.span, block.id, Node::Block(block));
	self.with_parent(block.id, \|this\| {
	intravisit::walk_block(this, block);
	});
	}

	fn visit_local(&mut self, l: &'hir Local) {
	self.insert(l.span, l.id, Node::Local(l));
	self.with_parent(l.id, \|this\| {
	intravisit::walk_local(this, l)
	})
	}

	fn visit_lifetime(&mut self, lifetime: &'hir Lifetime) {
	self.insert(lifetime.span, lifetime.id, Node::Lifetime(lifetime));
	}

	fn visit_vis(&mut self, visibility: &'hir Visibility) {
	match visibility.node {
	VisibilityKind::Public \|
	VisibilityKind::Crate(_) \|
	VisibilityKind::Inherited => {}
	VisibilityKind::Restricted { id, .. } => {
	self.insert(visibility.span, id, Node::Visibility(visibility));
	self.with_parent(id, \|this\| {
	intravisit::walk_vis(this, visibility);
	});
	}
	}
	}

	fn visit_macro_def(&mut self, macro_def: &'hir MacroDef) {
	let def_index = self.definitions.opt_def_index(macro_def.id).unwrap();

	self.with_dep_node_owner(def_index, macro_def, \|this\| {
	this.insert(macro_def.span, macro_def.id, Node::MacroDef(macro_def));
	});
	}

	fn visit_variant(&mut self, v: &'hir Variant, g: &'hir Generics, item_id: NodeId) {
	let id = v.node.data.id();
	self.insert(v.span, id, Node::Variant(v));
	self.with_parent(id, \|this\| {
	intravisit::walk_variant(this, v, g, item_id);
	});
	}

	fn visit_struct_field(&mut self, field: &'hir StructField) {
	self.insert(field.span, field.id, Node::Field(field));
	self.with_parent(field.id, \|this\| {
	intravisit::walk_struct_field(this, field);
	});
	}

	fn visit_trait_item_ref(&mut self, ii: &'hir TraitItemRef) {
	// Do not visit the duplicate information in TraitItemRef. We want to
	// map the actual nodes, not the duplicate ones in the *Ref.
	let TraitItemRef {
	id,
	ident: _,
	kind: _,
	span: _,
	defaultness: _,
	} = *ii;

	self.visit_nested_trait_item(id);
	}

	fn visit_impl_item_ref(&mut self, ii: &'hir ImplItemRef) {
	// Do not visit the duplicate information in ImplItemRef. We want to
	// map the actual nodes, not the duplicate ones in the *Ref.
	let ImplItemRef {
	id,
	ident: _,
	kind: _,
	span: _,
	vis: _,
	defaultness: _,
	} = *ii;

	self.visit_nested_impl_item(id);
	}
	}

	// This is a wrapper structure that allows determining if span values within
	// the wrapped item should be hashed or not.
	struct HirItemLike<T> {
	item_like: T,
	hash_bodies: bool,
	}

	impl<'a, 'hir, T> HashStable<StableHashingContext<'hir>> for HirItemLike<T>
	where T: HashStable<StableHashingContext<'hir>>
	{
	fn hash_stable<W: StableHasherResult>(&self,
	hcx: &mut StableHashingContext<'hir>,
	hasher: &mut StableHasher<W>) {
	hcx.while_hashing_hir_bodies(self.hash_bodies, \|hcx\| {
	self.item_like.hash_stable(hcx, hasher);
	});
	}
	}