src/librustdoc/formats/cache.rs - toolchain/rustc - Git at Google

 use std::cell::RefCell;
 use std::collections::BTreeMap;
 use std::mem;
 use std::path::{Path, PathBuf};
 use std::sync::Arc;

 use rustc_data_structures::fx::{FxHashMap, FxHashSet};
 use rustc_hir::def_id::{CrateNum, DefId, CRATE_DEF_INDEX};
 use rustc_middle::middle::privacy::AccessLevels;
 use rustc_span::source_map::FileName;
 use rustc_span::Symbol;

 use crate::clean::{self, GetDefId};
 use crate::config::RenderInfo;
 use crate::fold::DocFolder;
 use crate::formats::item_type::ItemType;
 use crate::formats::Impl;
 use crate::html::markdown::short_markdown_summary;
 use crate::html::render::cache::{extern_location, get_index_search_type, ExternalLocation};
 use crate::html::render::IndexItem;

 thread_local!(crate static CACHE_KEY: RefCell<Arc<Cache>> = Default::default());

 /// This cache is used to store information about the [`clean::Crate`] being
 /// rendered in order to provide more useful documentation. This contains
 /// information like all implementors of a trait, all traits a type implements,
 /// documentation for all known traits, etc.
 ///
 /// This structure purposefully does not implement `Clone` because it's intended
 /// to be a fairly large and expensive structure to clone. Instead this adheres
 /// to `Send` so it may be stored in a `Arc` instance and shared among the various
 /// rendering threads.
 #[derive(Default)]
 crate struct Cache {
     /// Maps a type ID to all known implementations for that type. This is only
     /// recognized for intra-crate `ResolvedPath` types, and is used to print
     /// out extra documentation on the page of an enum/struct.
     ///
     /// The values of the map are a list of implementations and documentation
     /// found on that implementation.
     crate impls: FxHashMap<DefId, Vec<Impl>>,

     /// Maintains a mapping of local crate `DefId`s to the fully qualified name
     /// and "short type description" of that node. This is used when generating
     /// URLs when a type is being linked to. External paths are not located in
     /// this map because the `External` type itself has all the information
     /// necessary.
     crate paths: FxHashMap<DefId, (Vec<String>, ItemType)>,

     /// Similar to `paths`, but only holds external paths. This is only used for
     /// generating explicit hyperlinks to other crates.
     crate external_paths: FxHashMap<DefId, (Vec<String>, ItemType)>,

     /// Maps local `DefId`s of exported types to fully qualified paths.
     /// Unlike 'paths', this mapping ignores any renames that occur
     /// due to 'use' statements.
     ///
     /// This map is used when writing out the special 'implementors'
     /// javascript file. By using the exact path that the type
     /// is declared with, we ensure that each path will be identical
     /// to the path used if the corresponding type is inlined. By
     /// doing this, we can detect duplicate impls on a trait page, and only display
     /// the impl for the inlined type.
     crate exact_paths: FxHashMap<DefId, Vec<String>>,

     /// This map contains information about all known traits of this crate.
     /// Implementations of a crate should inherit the documentation of the
     /// parent trait if no extra documentation is specified, and default methods
     /// should show up in documentation about trait implementations.
     crate traits: FxHashMap<DefId, clean::Trait>,

     /// When rendering traits, it's often useful to be able to list all
     /// implementors of the trait, and this mapping is exactly, that: a mapping
     /// of trait ids to the list of known implementors of the trait
     crate implementors: FxHashMap<DefId, Vec<Impl>>,

     /// Cache of where external crate documentation can be found.
     crate extern_locations: FxHashMap<CrateNum, (Symbol, PathBuf, ExternalLocation)>,

     /// Cache of where documentation for primitives can be found.
     crate primitive_locations: FxHashMap<clean::PrimitiveType, DefId>,

     // Note that external items for which `doc(hidden)` applies to are shown as
     // non-reachable while local items aren't. This is because we're reusing
     // the access levels from the privacy check pass.
     crate access_levels: AccessLevels<DefId>,

     /// The version of the crate being documented, if given from the `--crate-version` flag.
     crate crate_version: Option<String>,

     /// Whether to document private items.
     /// This is stored in `Cache` so it doesn't need to be passed through all rustdoc functions.
     crate document_private: bool,

     // Private fields only used when initially crawling a crate to build a cache
     stack: Vec<String>,
     parent_stack: Vec<DefId>,
     parent_is_trait_impl: bool,
     stripped_mod: bool,
     masked_crates: FxHashSet<CrateNum>,

     crate search_index: Vec<IndexItem>,
     crate deref_trait_did: Option<DefId>,
     crate deref_mut_trait_did: Option<DefId>,
     crate owned_box_did: Option<DefId>,

     // In rare case where a structure is defined in one module but implemented
     // in another, if the implementing module is parsed before defining module,
     // then the fully qualified name of the structure isn't presented in `paths`
     // yet when its implementation methods are being indexed. Caches such methods
     // and their parent id here and indexes them at the end of crate parsing.
     crate orphan_impl_items: Vec<(DefId, clean::Item)>,

     // Similarly to `orphan_impl_items`, sometimes trait impls are picked up
     // even though the trait itself is not exported. This can happen if a trait
     // was defined in function/expression scope, since the impl will be picked
     // up by `collect-trait-impls` but the trait won't be scraped out in the HIR
     // crawl. In order to prevent crashes when looking for spotlight traits or
     // when gathering trait documentation on a type, hold impls here while
     // folding and add them to the cache later on if we find the trait.
     orphan_trait_impls: Vec<(DefId, FxHashSet<DefId>, Impl)>,

     /// Aliases added through `#[doc(alias = "...")]`. Since a few items can have the same alias,
     /// we need the alias element to have an array of items.
     crate aliases: BTreeMap<String, Vec<usize>>,
 }

 impl Cache {
     crate fn from_krate(
         render_info: RenderInfo,
         document_private: bool,
         extern_html_root_urls: &BTreeMap<String, String>,
         dst: &Path,
         mut krate: clean::Crate,
     ) -> (clean::Crate, Cache) {
         // Crawl the crate to build various caches used for the output
         let RenderInfo {
             inlined: _,
             external_paths,
             exact_paths,
             access_levels,
             deref_trait_did,
             deref_mut_trait_did,
             owned_box_did,
             ..
         } = render_info;

         let external_paths =
             external_paths.into_iter().map(|(k, (v, t))| (k, (v, ItemType::from(t)))).collect();

         let mut cache = Cache {
             external_paths,
             exact_paths,
             parent_is_trait_impl: false,
             stripped_mod: false,
             access_levels,
             crate_version: krate.version.take(),
             document_private,
             traits: krate.external_traits.replace(Default::default()),
             deref_trait_did,
             deref_mut_trait_did,
             owned_box_did,
             masked_crates: mem::take(&mut krate.masked_crates),
             ..Cache::default()
         };

         // Cache where all our extern crates are located
         // FIXME: this part is specific to HTML so it'd be nice to remove it from the common code
         for &(n, ref e) in &krate.externs {
             let src_root = match e.src {
                 FileName::Real(ref p) => match p.local_path().parent() {
                     Some(p) => p.to_path_buf(),
                     None => PathBuf::new(),
                 },
                 _ => PathBuf::new(),
             };
             let extern_url = extern_html_root_urls.get(&*e.name.as_str()).map(|u| &**u);
             cache
                 .extern_locations
                 .insert(n, (e.name, src_root, extern_location(e, extern_url, &dst)));

             let did = DefId { krate: n, index: CRATE_DEF_INDEX };
             cache.external_paths.insert(did, (vec![e.name.to_string()], ItemType::Module));
         }

         // Cache where all known primitives have their documentation located.
         //
         // Favor linking to as local extern as possible, so iterate all crates in
         // reverse topological order.
         for &(_, ref e) in krate.externs.iter().rev() {
             for &(def_id, prim) in &e.primitives {
                 cache.primitive_locations.insert(prim, def_id);
             }
         }
         for &(def_id, prim) in &krate.primitives {
             cache.primitive_locations.insert(prim, def_id);
         }

         cache.stack.push(krate.name.to_string());
         krate = cache.fold_crate(krate);

         for (trait_did, dids, impl_) in cache.orphan_trait_impls.drain(..) {
             if cache.traits.contains_key(&trait_did) {
                 for did in dids {
                     cache.impls.entry(did).or_default().push(impl_.clone());
                 }
             }
         }

         (krate, cache)
     }
 }

 impl DocFolder for Cache {
     fn fold_item(&mut self, item: clean::Item) -> Option<clean::Item> {
         if item.def_id.is_local() {
             debug!("folding {} \"{:?}\", id {:?}", item.type_(), item.name, item.def_id);
         }

         // If this is a stripped module,
         // we don't want it or its children in the search index.
         let orig_stripped_mod = match item.kind {
             clean::StrippedItem(box clean::ModuleItem(..)) => {
                 mem::replace(&mut self.stripped_mod, true)
             }
             _ => self.stripped_mod,
         };

         // If the impl is from a masked crate or references something from a
         // masked crate then remove it completely.
         if let clean::ImplItem(ref i) = item.kind {
             if self.masked_crates.contains(&item.def_id.krate)
                 || i.trait_.def_id().map_or(false, |d| self.masked_crates.contains(&d.krate))
                 || i.for_.def_id().map_or(false, |d| self.masked_crates.contains(&d.krate))
             {
                 return None;
             }
         }

         // Propagate a trait method's documentation to all implementors of the
         // trait.
         if let clean::TraitItem(ref t) = item.kind {
             self.traits.entry(item.def_id).or_insert_with(|| t.clone());
         }

         // Collect all the implementors of traits.
         if let clean::ImplItem(ref i) = item.kind {
             if let Some(did) = i.trait_.def_id() {
                 if i.blanket_impl.is_none() {
                     self.implementors
                         .entry(did)
                         .or_default()
                         .push(Impl { impl_item: item.clone() });
                 }
             }
         }

         // Index this method for searching later on.
         if let Some(ref s) = item.name {
             let (parent, is_inherent_impl_item) = match item.kind {
                 clean::StrippedItem(..) => ((None, None), false),
                 clean::AssocConstItem(..) | clean::TypedefItem(_, true)
                     if self.parent_is_trait_impl =>
                 {
                     // skip associated items in trait impls
                     ((None, None), false)
                 }
                 clean::AssocTypeItem(..)
                 | clean::TyMethodItem(..)
                 | clean::StructFieldItem(..)
                 | clean::VariantItem(..) => (
                     (
                         Some(*self.parent_stack.last().expect("parent_stack is empty")),
                         Some(&self.stack[..self.stack.len() - 1]),
                     ),
                     false,
                 ),
                 clean::MethodItem(..) | clean::AssocConstItem(..) => {
                     if self.parent_stack.is_empty() {
                         ((None, None), false)
                     } else {
                         let last = self.parent_stack.last().expect("parent_stack is empty 2");
                         let did = *last;
                         let path = match self.paths.get(&did) {
                             // The current stack not necessarily has correlation
                             // for where the type was defined. On the other
                             // hand, `paths` always has the right
                             // information if present.
                             Some(&(
                                 ref fqp,
                                 ItemType::Trait
                                 | ItemType::Struct
                                 | ItemType::Union
                                 | ItemType::Enum,
                             )) => Some(&fqp[..fqp.len() - 1]),
                             Some(..) => Some(&*self.stack),
                             None => None,
                         };
                         ((Some(*last), path), true)
                     }
                 }
                 _ => ((None, Some(&*self.stack)), false),
             };

             match parent {
                 (parent, Some(path)) if is_inherent_impl_item || !self.stripped_mod => {
                     debug_assert!(!item.is_stripped());

                     // A crate has a module at its root, containing all items,
                     // which should not be indexed. The crate-item itself is
                     // inserted later on when serializing the search-index.
                     if item.def_id.index != CRATE_DEF_INDEX {
                         self.search_index.push(IndexItem {
                             ty: item.type_(),
                             name: s.to_string(),
                             path: path.join("::"),
                             desc: item
                                 .doc_value()
                                 .map_or_else(|| String::new(), short_markdown_summary),
                             parent,
                             parent_idx: None,
                             search_type: get_index_search_type(&item),
                         });

                         for alias in item.attrs.get_doc_aliases() {
                             self.aliases
                                 .entry(alias.to_lowercase())
                                 .or_insert(Vec::new())
                                 .push(self.search_index.len() - 1);
                         }
                     }
                 }
                 (Some(parent), None) if is_inherent_impl_item => {
                     // We have a parent, but we don't know where they're
                     // defined yet. Wait for later to index this item.
                     self.orphan_impl_items.push((parent, item.clone()));
                 }
                 _ => {}
             }
         }

         // Keep track of the fully qualified path for this item.
         let pushed = match item.name {
             Some(n) if !n.is_empty() => {
                 self.stack.push(n.to_string());
                 true
             }
             _ => false,
         };

         match item.kind {
             clean::StructItem(..)
             | clean::EnumItem(..)
             | clean::TypedefItem(..)
             | clean::TraitItem(..)
             | clean::FunctionItem(..)
             | clean::ModuleItem(..)
             | clean::ForeignFunctionItem(..)
             | clean::ForeignStaticItem(..)
             | clean::ConstantItem(..)
             | clean::StaticItem(..)
             | clean::UnionItem(..)
             | clean::ForeignTypeItem
             | clean::MacroItem(..)
             | clean::ProcMacroItem(..)
             | clean::VariantItem(..)
                 if !self.stripped_mod =>
             {
                 // Re-exported items mean that the same id can show up twice
                 // in the rustdoc ast that we're looking at. We know,
                 // however, that a re-exported item doesn't show up in the
                 // `public_items` map, so we can skip inserting into the
                 // paths map if there was already an entry present and we're
                 // not a public item.
                 if !self.paths.contains_key(&item.def_id)
                     || self.access_levels.is_public(item.def_id)
                 {
                     self.paths.insert(item.def_id, (self.stack.clone(), item.type_()));
                 }
             }
             clean::PrimitiveItem(..) => {
                 self.paths.insert(item.def_id, (self.stack.clone(), item.type_()));
             }

             _ => {}
         }

         // Maintain the parent stack
         let orig_parent_is_trait_impl = self.parent_is_trait_impl;
         let parent_pushed = match item.kind {
             clean::TraitItem(..)
             | clean::EnumItem(..)
             | clean::ForeignTypeItem
             | clean::StructItem(..)
             | clean::UnionItem(..)
             | clean::VariantItem(..) => {
                 self.parent_stack.push(item.def_id);
                 self.parent_is_trait_impl = false;
                 true
             }
             clean::ImplItem(ref i) => {
                 self.parent_is_trait_impl = i.trait_.is_some();
                 match i.for_ {
                     clean::ResolvedPath { did, .. } => {
                         self.parent_stack.push(did);
                         true
                     }
                     ref t => {
                         let prim_did = t
                             .primitive_type()
                             .and_then(|t| self.primitive_locations.get(&t).cloned());
                         match prim_did {
                             Some(did) => {
                                 self.parent_stack.push(did);
                                 true
                             }
                             None => false,
                         }
                     }
                 }
             }
             _ => false,
         };

         // Once we've recursively found all the generics, hoard off all the
         // implementations elsewhere.
         let item = self.fold_item_recur(item);
         let ret = if let clean::Item { kind: clean::ImplItem(_), .. } = item {
             // Figure out the id of this impl. This may map to a
             // primitive rather than always to a struct/enum.
             // Note: matching twice to restrict the lifetime of the `i` borrow.
             let mut dids = FxHashSet::default();
             if let clean::Item { kind: clean::ImplItem(ref i), .. } = item {
                 match i.for_ {
                     clean::ResolvedPath { did, .. }
                     | clean::BorrowedRef { type_: box clean::ResolvedPath { did, .. }, .. } => {
                         dids.insert(did);
                     }
                     ref t => {
                         let did = t
                             .primitive_type()
                             .and_then(|t| self.primitive_locations.get(&t).cloned());

                         if let Some(did) = did {
                             dids.insert(did);
                         }
                     }
                 }

                 if let Some(generics) = i.trait_.as_ref().and_then(|t| t.generics()) {
                     for bound in generics {
                         if let Some(did) = bound.def_id() {
                             dids.insert(did);
                         }
                     }
                 }
             } else {
                 unreachable!()
             };
             let impl_item = Impl { impl_item: item };
             if impl_item.trait_did().map_or(true, |d| self.traits.contains_key(&d)) {
                 for did in dids {
                     self.impls.entry(did).or_insert(vec![]).push(impl_item.clone());
                 }
             } else {
                 let trait_did = impl_item.trait_did().expect("no trait did");
                 self.orphan_trait_impls.push((trait_did, dids, impl_item));
             }
             None
         } else {
             Some(item)
         };

         if pushed {
             self.stack.pop().expect("stack already empty");
         }
         if parent_pushed {
             self.parent_stack.pop().expect("parent stack already empty");
         }
         self.stripped_mod = orig_stripped_mod;
         self.parent_is_trait_impl = orig_parent_is_trait_impl;
         ret
     }
 }

 crate fn cache() -> Arc<Cache> {
     CACHE_KEY.with(|c| c.borrow().clone())
 }
	use std::cell::RefCell;
	use std::collections::BTreeMap;
	use std::mem;
	use std::path::{Path, PathBuf};
	use std::sync::Arc;

	use rustc_data_structures::fx::{FxHashMap, FxHashSet};
	use rustc_hir::def_id::{CrateNum, DefId, CRATE_DEF_INDEX};
	use rustc_middle::middle::privacy::AccessLevels;
	use rustc_span::source_map::FileName;
	use rustc_span::Symbol;

	use crate::clean::{self, GetDefId};
	use crate::config::RenderInfo;
	use crate::fold::DocFolder;
	use crate::formats::item_type::ItemType;
	use crate::formats::Impl;
	use crate::html::markdown::short_markdown_summary;
	use crate::html::render::cache::{extern_location, get_index_search_type, ExternalLocation};
	use crate::html::render::IndexItem;

	thread_local!(crate static CACHE_KEY: RefCell<Arc<Cache>> = Default::default());

	/// This cache is used to store information about the [`clean::Crate`] being
	/// rendered in order to provide more useful documentation. This contains
	/// information like all implementors of a trait, all traits a type implements,
	/// documentation for all known traits, etc.
	///
	/// This structure purposefully does not implement `Clone` because it's intended
	/// to be a fairly large and expensive structure to clone. Instead this adheres
	/// to `Send` so it may be stored in a `Arc` instance and shared among the various
	/// rendering threads.
	#[derive(Default)]
	crate struct Cache {
	/// Maps a type ID to all known implementations for that type. This is only
	/// recognized for intra-crate `ResolvedPath` types, and is used to print
	/// out extra documentation on the page of an enum/struct.
	///
	/// The values of the map are a list of implementations and documentation
	/// found on that implementation.
	crate impls: FxHashMap<DefId, Vec<Impl>>,

	/// Maintains a mapping of local crate `DefId`s to the fully qualified name
	/// and "short type description" of that node. This is used when generating
	/// URLs when a type is being linked to. External paths are not located in
	/// this map because the `External` type itself has all the information
	/// necessary.
	crate paths: FxHashMap<DefId, (Vec<String>, ItemType)>,

	/// Similar to `paths`, but only holds external paths. This is only used for
	/// generating explicit hyperlinks to other crates.
	crate external_paths: FxHashMap<DefId, (Vec<String>, ItemType)>,

	/// Maps local `DefId`s of exported types to fully qualified paths.
	/// Unlike 'paths', this mapping ignores any renames that occur
	/// due to 'use' statements.
	///
	/// This map is used when writing out the special 'implementors'
	/// javascript file. By using the exact path that the type
	/// is declared with, we ensure that each path will be identical
	/// to the path used if the corresponding type is inlined. By
	/// doing this, we can detect duplicate impls on a trait page, and only display
	/// the impl for the inlined type.
	crate exact_paths: FxHashMap<DefId, Vec<String>>,

	/// This map contains information about all known traits of this crate.
	/// Implementations of a crate should inherit the documentation of the
	/// parent trait if no extra documentation is specified, and default methods
	/// should show up in documentation about trait implementations.
	crate traits: FxHashMap<DefId, clean::Trait>,

	/// When rendering traits, it's often useful to be able to list all
	/// implementors of the trait, and this mapping is exactly, that: a mapping
	/// of trait ids to the list of known implementors of the trait
	crate implementors: FxHashMap<DefId, Vec<Impl>>,

	/// Cache of where external crate documentation can be found.
	crate extern_locations: FxHashMap<CrateNum, (Symbol, PathBuf, ExternalLocation)>,

	/// Cache of where documentation for primitives can be found.
	crate primitive_locations: FxHashMap<clean::PrimitiveType, DefId>,

	// Note that external items for which `doc(hidden)` applies to are shown as
	// non-reachable while local items aren't. This is because we're reusing
	// the access levels from the privacy check pass.
	crate access_levels: AccessLevels<DefId>,

	/// The version of the crate being documented, if given from the `--crate-version` flag.
	crate crate_version: Option<String>,

	/// Whether to document private items.
	/// This is stored in `Cache` so it doesn't need to be passed through all rustdoc functions.
	crate document_private: bool,

	// Private fields only used when initially crawling a crate to build a cache
	stack: Vec<String>,
	parent_stack: Vec<DefId>,
	parent_is_trait_impl: bool,
	stripped_mod: bool,
	masked_crates: FxHashSet<CrateNum>,

	crate search_index: Vec<IndexItem>,
	crate deref_trait_did: Option<DefId>,
	crate deref_mut_trait_did: Option<DefId>,
	crate owned_box_did: Option<DefId>,

	// In rare case where a structure is defined in one module but implemented
	// in another, if the implementing module is parsed before defining module,
	// then the fully qualified name of the structure isn't presented in `paths`
	// yet when its implementation methods are being indexed. Caches such methods
	// and their parent id here and indexes them at the end of crate parsing.
	crate orphan_impl_items: Vec<(DefId, clean::Item)>,

	// Similarly to `orphan_impl_items`, sometimes trait impls are picked up
	// even though the trait itself is not exported. This can happen if a trait
	// was defined in function/expression scope, since the impl will be picked
	// up by `collect-trait-impls` but the trait won't be scraped out in the HIR
	// crawl. In order to prevent crashes when looking for spotlight traits or
	// when gathering trait documentation on a type, hold impls here while
	// folding and add them to the cache later on if we find the trait.
	orphan_trait_impls: Vec<(DefId, FxHashSet<DefId>, Impl)>,

	/// Aliases added through `#[doc(alias = "...")]`. Since a few items can have the same alias,
	/// we need the alias element to have an array of items.
	crate aliases: BTreeMap<String, Vec<usize>>,
	}

	impl Cache {
	crate fn from_krate(
	render_info: RenderInfo,
	document_private: bool,
	extern_html_root_urls: &BTreeMap<String, String>,
	dst: &Path,
	mut krate: clean::Crate,
	) -> (clean::Crate, Cache) {
	// Crawl the crate to build various caches used for the output
	let RenderInfo {
	inlined: _,
	external_paths,
	exact_paths,
	access_levels,
	deref_trait_did,
	deref_mut_trait_did,
	owned_box_did,
	..
	} = render_info;

	let external_paths =
	external_paths.into_iter().map(\|(k, (v, t))\| (k, (v, ItemType::from(t)))).collect();

	let mut cache = Cache {
	external_paths,
	exact_paths,
	parent_is_trait_impl: false,
	stripped_mod: false,
	access_levels,
	crate_version: krate.version.take(),
	document_private,
	traits: krate.external_traits.replace(Default::default()),
	deref_trait_did,
	deref_mut_trait_did,
	owned_box_did,
	masked_crates: mem::take(&mut krate.masked_crates),
	..Cache::default()
	};

	// Cache where all our extern crates are located
	// FIXME: this part is specific to HTML so it'd be nice to remove it from the common code
	for &(n, ref e) in &krate.externs {
	let src_root = match e.src {
	FileName::Real(ref p) => match p.local_path().parent() {
	Some(p) => p.to_path_buf(),
	None => PathBuf::new(),
	},
	_ => PathBuf::new(),
	};
	let extern_url = extern_html_root_urls.get(&e.name.as_str()).map(\|u\| &*u);
	cache
	.extern_locations
	.insert(n, (e.name, src_root, extern_location(e, extern_url, &dst)));

	let did = DefId { krate: n, index: CRATE_DEF_INDEX };
	cache.external_paths.insert(did, (vec![e.name.to_string()], ItemType::Module));
	}

	// Cache where all known primitives have their documentation located.
	//
	// Favor linking to as local extern as possible, so iterate all crates in
	// reverse topological order.
	for &(_, ref e) in krate.externs.iter().rev() {
	for &(def_id, prim) in &e.primitives {
	cache.primitive_locations.insert(prim, def_id);
	}
	}
	for &(def_id, prim) in &krate.primitives {
	cache.primitive_locations.insert(prim, def_id);
	}

	cache.stack.push(krate.name.to_string());
	krate = cache.fold_crate(krate);

	for (trait_did, dids, impl_) in cache.orphan_trait_impls.drain(..) {
	if cache.traits.contains_key(&trait_did) {
	for did in dids {
	cache.impls.entry(did).or_default().push(impl_.clone());
	}
	}
	}

	(krate, cache)
	}
	}

	impl DocFolder for Cache {
	fn fold_item(&mut self, item: clean::Item) -> Option<clean::Item> {
	if item.def_id.is_local() {
	debug!("folding {} \"{:?}\", id {:?}", item.type_(), item.name, item.def_id);
	}

	// If this is a stripped module,
	// we don't want it or its children in the search index.
	let orig_stripped_mod = match item.kind {
	clean::StrippedItem(box clean::ModuleItem(..)) => {
	mem::replace(&mut self.stripped_mod, true)
	}
	_ => self.stripped_mod,
	};

	// If the impl is from a masked crate or references something from a
	// masked crate then remove it completely.
	if let clean::ImplItem(ref i) = item.kind {
	if self.masked_crates.contains(&item.def_id.krate)
	\|\| i.trait_.def_id().map_or(false, \|d\| self.masked_crates.contains(&d.krate))
	\|\| i.for_.def_id().map_or(false, \|d\| self.masked_crates.contains(&d.krate))
	{
	return None;
	}
	}

	// Propagate a trait method's documentation to all implementors of the
	// trait.
	if let clean::TraitItem(ref t) = item.kind {
	self.traits.entry(item.def_id).or_insert_with(\|\| t.clone());
	}

	// Collect all the implementors of traits.
	if let clean::ImplItem(ref i) = item.kind {
	if let Some(did) = i.trait_.def_id() {
	if i.blanket_impl.is_none() {
	self.implementors
	.entry(did)
	.or_default()
	.push(Impl { impl_item: item.clone() });
	}
	}
	}

	// Index this method for searching later on.
	if let Some(ref s) = item.name {
	let (parent, is_inherent_impl_item) = match item.kind {
	clean::StrippedItem(..) => ((None, None), false),
	clean::AssocConstItem(..) \| clean::TypedefItem(_, true)
	if self.parent_is_trait_impl =>
	{
	// skip associated items in trait impls
	((None, None), false)
	}
	clean::AssocTypeItem(..)
	\| clean::TyMethodItem(..)
	\| clean::StructFieldItem(..)
	\| clean::VariantItem(..) => (
	(
	Some(*self.parent_stack.last().expect("parent_stack is empty")),
	Some(&self.stack[..self.stack.len() - 1]),
	),
	false,
	),
	clean::MethodItem(..) \| clean::AssocConstItem(..) => {
	if self.parent_stack.is_empty() {
	((None, None), false)
	} else {
	let last = self.parent_stack.last().expect("parent_stack is empty 2");
	let did = *last;
	let path = match self.paths.get(&did) {
	// The current stack not necessarily has correlation
	// for where the type was defined. On the other
	// hand, `paths` always has the right
	// information if present.
	Some(&(
	ref fqp,
	ItemType::Trait
	\| ItemType::Struct
	\| ItemType::Union
	\| ItemType::Enum,
	)) => Some(&fqp[..fqp.len() - 1]),
	Some(..) => Some(&*self.stack),
	None => None,
	};
	((Some(*last), path), true)
	}
	}
	_ => ((None, Some(&*self.stack)), false),
	};

	match parent {
	(parent, Some(path)) if is_inherent_impl_item \|\| !self.stripped_mod => {
	debug_assert!(!item.is_stripped());

	// A crate has a module at its root, containing all items,
	// which should not be indexed. The crate-item itself is
	// inserted later on when serializing the search-index.
	if item.def_id.index != CRATE_DEF_INDEX {
	self.search_index.push(IndexItem {
	ty: item.type_(),
	name: s.to_string(),
	path: path.join("::"),
	desc: item
	.doc_value()
	.map_or_else(\|\| String::new(), short_markdown_summary),
	parent,
	parent_idx: None,
	search_type: get_index_search_type(&item),
	});

	for alias in item.attrs.get_doc_aliases() {
	self.aliases
	.entry(alias.to_lowercase())
	.or_insert(Vec::new())
	.push(self.search_index.len() - 1);
	}
	}
	}
	(Some(parent), None) if is_inherent_impl_item => {
	// We have a parent, but we don't know where they're
	// defined yet. Wait for later to index this item.
	self.orphan_impl_items.push((parent, item.clone()));
	}
	_ => {}
	}
	}

	// Keep track of the fully qualified path for this item.
	let pushed = match item.name {
	Some(n) if !n.is_empty() => {
	self.stack.push(n.to_string());
	true
	}
	_ => false,
	};

	match item.kind {
	clean::StructItem(..)
	\| clean::EnumItem(..)
	\| clean::TypedefItem(..)
	\| clean::TraitItem(..)
	\| clean::FunctionItem(..)
	\| clean::ModuleItem(..)
	\| clean::ForeignFunctionItem(..)
	\| clean::ForeignStaticItem(..)
	\| clean::ConstantItem(..)
	\| clean::StaticItem(..)
	\| clean::UnionItem(..)
	\| clean::ForeignTypeItem
	\| clean::MacroItem(..)
	\| clean::ProcMacroItem(..)
	\| clean::VariantItem(..)
	if !self.stripped_mod =>
	{
	// Re-exported items mean that the same id can show up twice
	// in the rustdoc ast that we're looking at. We know,
	// however, that a re-exported item doesn't show up in the
	// `public_items` map, so we can skip inserting into the
	// paths map if there was already an entry present and we're
	// not a public item.
	if !self.paths.contains_key(&item.def_id)
	\|\| self.access_levels.is_public(item.def_id)
	{
	self.paths.insert(item.def_id, (self.stack.clone(), item.type_()));
	}
	}
	clean::PrimitiveItem(..) => {
	self.paths.insert(item.def_id, (self.stack.clone(), item.type_()));
	}

	_ => {}
	}

	// Maintain the parent stack
	let orig_parent_is_trait_impl = self.parent_is_trait_impl;
	let parent_pushed = match item.kind {
	clean::TraitItem(..)
	\| clean::EnumItem(..)
	\| clean::ForeignTypeItem
	\| clean::StructItem(..)
	\| clean::UnionItem(..)
	\| clean::VariantItem(..) => {
	self.parent_stack.push(item.def_id);
	self.parent_is_trait_impl = false;
	true
	}
	clean::ImplItem(ref i) => {
	self.parent_is_trait_impl = i.trait_.is_some();
	match i.for_ {
	clean::ResolvedPath { did, .. } => {
	self.parent_stack.push(did);
	true
	}
	ref t => {
	let prim_did = t
	.primitive_type()
	.and_then(\|t\| self.primitive_locations.get(&t).cloned());
	match prim_did {
	Some(did) => {
	self.parent_stack.push(did);
	true
	}
	None => false,
	}
	}
	}
	}
	_ => false,
	};

	// Once we've recursively found all the generics, hoard off all the
	// implementations elsewhere.
	let item = self.fold_item_recur(item);
	let ret = if let clean::Item { kind: clean::ImplItem(_), .. } = item {
	// Figure out the id of this impl. This may map to a
	// primitive rather than always to a struct/enum.
	// Note: matching twice to restrict the lifetime of the `i` borrow.
	let mut dids = FxHashSet::default();
	if let clean::Item { kind: clean::ImplItem(ref i), .. } = item {
	match i.for_ {
	clean::ResolvedPath { did, .. }
	\| clean::BorrowedRef { type_: box clean::ResolvedPath { did, .. }, .. } => {
	dids.insert(did);
	}
	ref t => {
	let did = t
	.primitive_type()
	.and_then(\|t\| self.primitive_locations.get(&t).cloned());

	if let Some(did) = did {
	dids.insert(did);
	}
	}
	}

	if let Some(generics) = i.trait_.as_ref().and_then(\|t\| t.generics()) {
	for bound in generics {
	if let Some(did) = bound.def_id() {
	dids.insert(did);
	}
	}
	}
	} else {
	unreachable!()
	};
	let impl_item = Impl { impl_item: item };
	if impl_item.trait_did().map_or(true, \|d\| self.traits.contains_key(&d)) {
	for did in dids {
	self.impls.entry(did).or_insert(vec![]).push(impl_item.clone());
	}
	} else {
	let trait_did = impl_item.trait_did().expect("no trait did");
	self.orphan_trait_impls.push((trait_did, dids, impl_item));
	}
	None
	} else {
	Some(item)
	};

	if pushed {
	self.stack.pop().expect("stack already empty");
	}
	if parent_pushed {
	self.parent_stack.pop().expect("parent stack already empty");
	}
	self.stripped_mod = orig_stripped_mod;
	self.parent_is_trait_impl = orig_parent_is_trait_impl;
	ret
	}
	}

	crate fn cache() -> Arc<Cache> {
	CACHE_KEY.with(\|c\| c.borrow().clone())
	}