// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. pub use self::Node::*; use self::MapEntry::*; use self::collector::NodeCollector; use self::def_collector::DefCollector; pub use self::definitions::{Definitions, DefKey, DefPath, DefPathData, DisambiguatedDefPathData, InlinedRootPath}; use dep_graph::{DepGraph, DepNode}; use middle::cstore::InlinedItem; use middle::cstore::InlinedItem as II; use hir::def_id::{CRATE_DEF_INDEX, DefId, DefIndex}; use syntax::abi::Abi; use syntax::ast::{self, Name, NodeId, DUMMY_NODE_ID, }; use syntax::attr::ThinAttributesExt; use syntax::codemap::{Span, Spanned}; use syntax::visit; use hir::*; use hir::fold::Folder; use hir::print as pprust; use arena::TypedArena; use std::cell::RefCell; use std::io; use std::mem; pub mod blocks; mod collector; mod def_collector; pub mod definitions; #[derive(Copy, Clone, Debug)] pub enum Node<'ast> { NodeItem(&'ast Item), NodeForeignItem(&'ast ForeignItem), NodeTraitItem(&'ast TraitItem), NodeImplItem(&'ast ImplItem), NodeVariant(&'ast Variant), NodeExpr(&'ast Expr), NodeStmt(&'ast Stmt), NodeLocal(&'ast Pat), NodePat(&'ast Pat), NodeBlock(&'ast Block), /// NodeStructCtor represents a tuple struct. NodeStructCtor(&'ast VariantData), NodeLifetime(&'ast Lifetime), NodeTyParam(&'ast TyParam) } /// Represents an entry and its parent NodeID. /// The odd layout is to bring down the total size. #[derive(Copy, Debug)] pub enum MapEntry<'ast> { /// Placeholder for holes in the map. NotPresent, /// All the node types, with a parent ID. EntryItem(NodeId, &'ast Item), EntryForeignItem(NodeId, &'ast ForeignItem), EntryTraitItem(NodeId, &'ast TraitItem), EntryImplItem(NodeId, &'ast ImplItem), EntryVariant(NodeId, &'ast Variant), EntryExpr(NodeId, &'ast Expr), EntryStmt(NodeId, &'ast Stmt), EntryLocal(NodeId, &'ast Pat), EntryPat(NodeId, &'ast Pat), EntryBlock(NodeId, &'ast Block), EntryStructCtor(NodeId, &'ast VariantData), EntryLifetime(NodeId, &'ast Lifetime), EntryTyParam(NodeId, &'ast TyParam), /// Roots for node trees. RootCrate, RootInlinedParent(&'ast InlinedItem) } impl<'ast> Clone for MapEntry<'ast> { fn clone(&self) -> MapEntry<'ast> { *self } } impl<'ast> MapEntry<'ast> { fn from_node(p: NodeId, node: Node<'ast>) -> MapEntry<'ast> { match node { NodeItem(n) => EntryItem(p, n), NodeForeignItem(n) => EntryForeignItem(p, n), NodeTraitItem(n) => EntryTraitItem(p, n), NodeImplItem(n) => EntryImplItem(p, n), NodeVariant(n) => EntryVariant(p, n), NodeExpr(n) => EntryExpr(p, n), NodeStmt(n) => EntryStmt(p, n), NodeLocal(n) => EntryLocal(p, n), NodePat(n) => EntryPat(p, n), NodeBlock(n) => EntryBlock(p, n), NodeStructCtor(n) => EntryStructCtor(p, n), NodeLifetime(n) => EntryLifetime(p, n), NodeTyParam(n) => EntryTyParam(p, n), } } fn parent_node(self) -> Option { Some(match self { EntryItem(id, _) => id, EntryForeignItem(id, _) => id, EntryTraitItem(id, _) => id, EntryImplItem(id, _) => id, EntryVariant(id, _) => id, EntryExpr(id, _) => id, EntryStmt(id, _) => id, EntryLocal(id, _) => id, EntryPat(id, _) => id, EntryBlock(id, _) => id, EntryStructCtor(id, _) => id, EntryLifetime(id, _) => id, EntryTyParam(id, _) => id, _ => return None }) } fn to_node(self) -> Option> { Some(match self { EntryItem(_, n) => NodeItem(n), EntryForeignItem(_, n) => NodeForeignItem(n), EntryTraitItem(_, n) => NodeTraitItem(n), EntryImplItem(_, n) => NodeImplItem(n), EntryVariant(_, n) => NodeVariant(n), EntryExpr(_, n) => NodeExpr(n), EntryStmt(_, n) => NodeStmt(n), EntryLocal(_, n) => NodeLocal(n), EntryPat(_, n) => NodePat(n), EntryBlock(_, n) => NodeBlock(n), EntryStructCtor(_, n) => NodeStructCtor(n), EntryLifetime(_, n) => NodeLifetime(n), EntryTyParam(_, n) => NodeTyParam(n), _ => return None }) } } /// Stores a crate and any number of inlined items from other crates. pub struct Forest { krate: Crate, pub dep_graph: DepGraph, inlined_items: TypedArena } impl Forest { pub fn new(krate: Crate, dep_graph: &DepGraph) -> Forest { Forest { krate: krate, dep_graph: dep_graph.clone(), inlined_items: TypedArena::new() } } pub fn krate<'ast>(&'ast self) -> &'ast Crate { self.dep_graph.read(DepNode::Krate); &self.krate } } /// Represents a mapping from Node IDs to AST elements and their parent /// Node IDs #[derive(Clone)] pub struct Map<'ast> { /// The backing storage for all the AST nodes. pub forest: &'ast Forest, /// Same as the dep_graph in forest, just available with one fewer /// deref. This is a gratuitious micro-optimization. pub dep_graph: DepGraph, /// NodeIds are sequential integers from 0, so we can be /// super-compact by storing them in a vector. Not everything with /// a NodeId is in the map, but empirically the occupancy is about /// 75-80%, so there's not too much overhead (certainly less than /// a hashmap, since they (at the time of writing) have a maximum /// of 75% occupancy). /// /// Also, indexing is pretty quick when you've got a vector and /// plain old integers. map: RefCell>>, definitions: RefCell, } impl<'ast> Map<'ast> { /// Registers a read in the dependency graph of the AST node with /// the given `id`. This needs to be called each time a public /// function returns the HIR for a node -- in other words, when it /// "reveals" the content of a node to the caller (who might not /// otherwise have had access to those contents, and hence needs a /// read recorded). If the function just returns a DefId or /// NodeId, no actual content was returned, so no read is needed. fn read(&self, id: NodeId) { self.dep_graph.read(self.dep_node(id)); } fn dep_node(&self, id0: NodeId) -> DepNode { let map = self.map.borrow(); let mut id = id0; loop { match map[id as usize] { EntryItem(_, item) => { let def_id = self.local_def_id(item.id); // NB ^~~~~~~ // // You would expect that `item.id == id`, but this // is not always the case. In particular, for a // ViewPath item like `use self::{mem, foo}`, we // map the ids for `mem` and `foo` to the // enclosing view path item. This seems mega super // ultra wrong, but then who am I to judge? // -nmatsakis return DepNode::Hir(def_id); } EntryForeignItem(p, _) | EntryTraitItem(p, _) | EntryImplItem(p, _) | EntryVariant(p, _) | EntryExpr(p, _) | EntryStmt(p, _) | EntryLocal(p, _) | EntryPat(p, _) | EntryBlock(p, _) | EntryStructCtor(p, _) | EntryLifetime(p, _) | EntryTyParam(p, _) => id = p, RootCrate | RootInlinedParent(_) => // FIXME(#32015) clarify story about cross-crate dep tracking return DepNode::Krate, NotPresent => // Some nodes, notably struct fields, are not // present in the map for whatever reason, but // they *do* have def-ids. So if we encounter an // empty hole, check for that case. return self.opt_local_def_id(id) .map(|def_id| DepNode::Hir(def_id)) .unwrap_or_else(|| { bug!("Walking parents from `{}` \ led to `NotPresent` at `{}`", id0, id) }), } } } pub fn num_local_def_ids(&self) -> usize { self.definitions.borrow().len() } pub fn def_key(&self, def_id: DefId) -> DefKey { assert!(def_id.is_local()); self.definitions.borrow().def_key(def_id.index) } pub fn def_path_from_id(&self, id: NodeId) -> Option { self.opt_local_def_id(id).map(|def_id| { self.def_path(def_id) }) } pub fn def_path(&self, def_id: DefId) -> DefPath { assert!(def_id.is_local()); self.definitions.borrow().def_path(def_id.index) } pub fn def_index_for_def_key(&self, def_key: DefKey) -> Option { self.definitions.borrow().def_index_for_def_key(def_key) } pub fn local_def_id(&self, node: NodeId) -> DefId { self.opt_local_def_id(node).unwrap_or_else(|| { bug!("local_def_id: no entry for `{}`, which has a map of `{:?}`", node, self.find_entry(node)) }) } pub fn opt_local_def_id(&self, node: NodeId) -> Option { self.definitions.borrow().opt_local_def_id(node) } pub fn as_local_node_id(&self, def_id: DefId) -> Option { self.definitions.borrow().as_local_node_id(def_id) } fn entry_count(&self) -> usize { self.map.borrow().len() } fn find_entry(&self, id: NodeId) -> Option> { self.map.borrow().get(id as usize).cloned() } pub fn krate(&self) -> &'ast Crate { self.forest.krate() } /// Get the attributes on the krate. This is preferable to /// invoking `krate.attrs` because it registers a tighter /// dep-graph access. pub fn krate_attrs(&self) -> &'ast [ast::Attribute] { let crate_root_def_id = DefId::local(CRATE_DEF_INDEX); self.dep_graph.read(DepNode::Hir(crate_root_def_id)); &self.forest.krate.attrs } /// Retrieve the Node corresponding to `id`, panicking if it cannot /// be found. pub fn get(&self, id: NodeId) -> Node<'ast> { match self.find(id) { Some(node) => node, // read recorded by `find` None => bug!("couldn't find node id {} in the AST map", id) } } pub fn get_if_local(&self, id: DefId) -> Option> { self.as_local_node_id(id).map(|id| self.get(id)) // read recorded by `get` } /// Retrieve the Node corresponding to `id`, returning None if /// cannot be found. pub fn find(&self, id: NodeId) -> Option> { let result = self.find_entry(id).and_then(|x| x.to_node()); if result.is_some() { self.read(id); } result } /// Similar to get_parent, returns the parent node id or id if there is no /// parent. /// This function returns the immediate parent in the AST, whereas get_parent /// returns the enclosing item. Note that this might not be the actual parent /// node in the AST - some kinds of nodes are not in the map and these will /// never appear as the parent_node. So you can always walk the parent_nodes /// from a node to the root of the ast (unless you get the same id back here /// that can happen if the id is not in the map itself or is just weird). pub fn get_parent_node(&self, id: NodeId) -> NodeId { self.find_entry(id).and_then(|x| x.parent_node()).unwrap_or(id) } /// Check if the node is an argument. An argument is a local variable whose /// immediate parent is an item or a closure. pub fn is_argument(&self, id: NodeId) -> bool { match self.find(id) { Some(NodeLocal(_)) => (), _ => return false, } match self.find(self.get_parent_node(id)) { Some(NodeItem(_)) | Some(NodeTraitItem(_)) | Some(NodeImplItem(_)) => true, Some(NodeExpr(e)) => { match e.node { ExprClosure(..) => true, _ => false, } } _ => false, } } /// If there is some error when walking the parents (e.g., a node does not /// have a parent in the map or a node can't be found), then we return the /// last good node id we found. Note that reaching the crate root (id == 0), /// is not an error, since items in the crate module have the crate root as /// parent. fn walk_parent_nodes(&self, start_id: NodeId, found: F) -> Result where F: Fn(&Node<'ast>) -> bool { let mut id = start_id; loop { let parent_node = self.get_parent_node(id); if parent_node == 0 { return Ok(0); } if parent_node == id { return Err(id); } let node = self.find_entry(parent_node); if node.is_none() { return Err(id); } let node = node.unwrap().to_node(); match node { Some(ref node) => { if found(node) { return Ok(parent_node); } } None => { return Err(parent_node); } } id = parent_node; } } /// Retrieve the NodeId for `id`'s parent item, or `id` itself if no /// parent item is in this map. The "parent item" is the closest parent node /// in the AST which is recorded by the map and is an item, either an item /// in a module, trait, or impl. pub fn get_parent(&self, id: NodeId) -> NodeId { match self.walk_parent_nodes(id, |node| match *node { NodeItem(_) | NodeForeignItem(_) | NodeTraitItem(_) | NodeImplItem(_) => true, _ => false, }) { Ok(id) => id, Err(id) => id, } } /// Returns the NodeId of `id`'s nearest module parent, or `id` itself if no /// module parent is in this map. pub fn get_module_parent(&self, id: NodeId) -> NodeId { match self.walk_parent_nodes(id, |node| match *node { NodeItem(&Item { node: Item_::ItemMod(_), .. }) => true, _ => false, }) { Ok(id) => id, Err(id) => id, } } /// Returns the nearest enclosing scope. A scope is an item or block. /// FIXME it is not clear to me that all items qualify as scopes - statics /// and associated types probably shouldn't, for example. Behaviour in this /// regard should be expected to be highly unstable. pub fn get_enclosing_scope(&self, id: NodeId) -> Option { match self.walk_parent_nodes(id, |node| match *node { NodeItem(_) | NodeForeignItem(_) | NodeTraitItem(_) | NodeImplItem(_) | NodeBlock(_) => true, _ => false, }) { Ok(id) => Some(id), Err(_) => None, } } pub fn get_parent_did(&self, id: NodeId) -> DefId { let parent = self.get_parent(id); match self.find_entry(parent) { Some(RootInlinedParent(&II::TraitItem(did, _))) | Some(RootInlinedParent(&II::ImplItem(did, _))) => did, _ => self.local_def_id(parent) } } pub fn get_foreign_abi(&self, id: NodeId) -> Abi { let parent = self.get_parent(id); let abi = match self.find_entry(parent) { Some(EntryItem(_, i)) => { match i.node { ItemForeignMod(ref nm) => Some(nm.abi), _ => None } } /// Wrong but OK, because the only inlined foreign items are intrinsics. Some(RootInlinedParent(_)) => Some(Abi::RustIntrinsic), _ => None }; match abi { Some(abi) => { self.read(id); // reveals some of the content of a node abi } None => bug!("expected foreign mod or inlined parent, found {}", self.node_to_string(parent)) } } pub fn expect_item(&self, id: NodeId) -> &'ast Item { match self.find(id) { // read recorded by `find` Some(NodeItem(item)) => item, _ => bug!("expected item, found {}", self.node_to_string(id)) } } pub fn expect_trait_item(&self, id: NodeId) -> &'ast TraitItem { match self.find(id) { Some(NodeTraitItem(item)) => item, _ => bug!("expected trait item, found {}", self.node_to_string(id)) } } pub fn expect_struct(&self, id: NodeId) -> &'ast VariantData { match self.find(id) { Some(NodeItem(i)) => { match i.node { ItemStruct(ref struct_def, _) => struct_def, _ => bug!("struct ID bound to non-struct") } } Some(NodeVariant(variant)) => { if variant.node.data.is_struct() { &variant.node.data } else { bug!("struct ID bound to enum variant that isn't struct-like") } } _ => bug!("expected struct, found {}", self.node_to_string(id)), } } pub fn expect_variant(&self, id: NodeId) -> &'ast Variant { match self.find(id) { Some(NodeVariant(variant)) => variant, _ => bug!("expected variant, found {}", self.node_to_string(id)), } } pub fn expect_foreign_item(&self, id: NodeId) -> &'ast ForeignItem { match self.find(id) { Some(NodeForeignItem(item)) => item, _ => bug!("expected foreign item, found {}", self.node_to_string(id)) } } pub fn expect_expr(&self, id: NodeId) -> &'ast Expr { match self.find(id) { // read recorded by find Some(NodeExpr(expr)) => expr, _ => bug!("expected expr, found {}", self.node_to_string(id)) } } /// Returns the name associated with the given NodeId's AST. pub fn name(&self, id: NodeId) -> Name { match self.get(id) { NodeItem(i) => i.name, NodeForeignItem(i) => i.name, NodeImplItem(ii) => ii.name, NodeTraitItem(ti) => ti.name, NodeVariant(v) => v.node.name, NodeLifetime(lt) => lt.name, NodeTyParam(tp) => tp.name, NodeLocal(&Pat { node: PatKind::Binding(_,l,_), .. }) => l.node, NodeStructCtor(_) => self.name(self.get_parent(id)), _ => bug!("no name for {}", self.node_to_string(id)) } } /// Given a node ID, get a list of attributes associated with the AST /// corresponding to the Node ID pub fn attrs(&self, id: NodeId) -> &'ast [ast::Attribute] { self.read(id); // reveals attributes on the node let attrs = match self.find(id) { Some(NodeItem(i)) => Some(&i.attrs[..]), Some(NodeForeignItem(fi)) => Some(&fi.attrs[..]), Some(NodeTraitItem(ref ti)) => Some(&ti.attrs[..]), Some(NodeImplItem(ref ii)) => Some(&ii.attrs[..]), Some(NodeVariant(ref v)) => Some(&v.node.attrs[..]), Some(NodeExpr(ref e)) => Some(e.attrs.as_attr_slice()), Some(NodeStmt(ref s)) => Some(s.node.attrs()), // unit/tuple structs take the attributes straight from // the struct definition. Some(NodeStructCtor(_)) => { return self.attrs(self.get_parent(id)); } _ => None }; attrs.unwrap_or(&[]) } /// Returns an iterator that yields the node id's with paths that /// match `parts`. (Requires `parts` is non-empty.) /// /// For example, if given `parts` equal to `["bar", "quux"]`, then /// the iterator will produce node id's for items with paths /// such as `foo::bar::quux`, `bar::quux`, `other::bar::quux`, and /// any other such items it can find in the map. pub fn nodes_matching_suffix<'a>(&'a self, parts: &'a [String]) -> NodesMatchingSuffix<'a, 'ast> { NodesMatchingSuffix { map: self, item_name: parts.last().unwrap(), in_which: &parts[..parts.len() - 1], idx: 0, } } pub fn opt_span(&self, id: NodeId) -> Option { let sp = match self.find(id) { Some(NodeItem(item)) => item.span, Some(NodeForeignItem(foreign_item)) => foreign_item.span, Some(NodeTraitItem(trait_method)) => trait_method.span, Some(NodeImplItem(ref impl_item)) => impl_item.span, Some(NodeVariant(variant)) => variant.span, Some(NodeExpr(expr)) => expr.span, Some(NodeStmt(stmt)) => stmt.span, Some(NodeLocal(pat)) => pat.span, Some(NodePat(pat)) => pat.span, Some(NodeBlock(block)) => block.span, Some(NodeStructCtor(_)) => self.expect_item(self.get_parent(id)).span, Some(NodeTyParam(ty_param)) => ty_param.span, _ => return None, }; Some(sp) } pub fn span(&self, id: NodeId) -> Span { self.read(id); // reveals span from node self.opt_span(id) .unwrap_or_else(|| bug!("AstMap.span: could not find span for id {:?}", id)) } pub fn span_if_local(&self, id: DefId) -> Option { self.as_local_node_id(id).map(|id| self.span(id)) } pub fn def_id_span(&self, def_id: DefId, fallback: Span) -> Span { if let Some(node_id) = self.as_local_node_id(def_id) { self.opt_span(node_id).unwrap_or(fallback) } else { fallback } } pub fn node_to_string(&self, id: NodeId) -> String { node_id_to_string(self, id, true) } pub fn node_to_user_string(&self, id: NodeId) -> String { node_id_to_string(self, id, false) } } pub struct NodesMatchingSuffix<'a, 'ast:'a> { map: &'a Map<'ast>, item_name: &'a String, in_which: &'a [String], idx: NodeId, } impl<'a, 'ast> NodesMatchingSuffix<'a, 'ast> { /// Returns true only if some suffix of the module path for parent /// matches `self.in_which`. /// /// In other words: let `[x_0,x_1,...,x_k]` be `self.in_which`; /// returns true if parent's path ends with the suffix /// `x_0::x_1::...::x_k`. fn suffix_matches(&self, parent: NodeId) -> bool { let mut cursor = parent; for part in self.in_which.iter().rev() { let (mod_id, mod_name) = match find_first_mod_parent(self.map, cursor) { None => return false, Some((node_id, name)) => (node_id, name), }; if &part[..] != mod_name.as_str() { return false; } cursor = self.map.get_parent(mod_id); } return true; // Finds the first mod in parent chain for `id`, along with // that mod's name. // // If `id` itself is a mod named `m` with parent `p`, then // returns `Some(id, m, p)`. If `id` has no mod in its parent // chain, then returns `None`. fn find_first_mod_parent<'a>(map: &'a Map, mut id: NodeId) -> Option<(NodeId, Name)> { loop { match map.find(id) { None => return None, Some(NodeItem(item)) if item_is_mod(&item) => return Some((id, item.name)), _ => {} } let parent = map.get_parent(id); if parent == id { return None } id = parent; } fn item_is_mod(item: &Item) -> bool { match item.node { ItemMod(_) => true, _ => false, } } } } // We are looking at some node `n` with a given name and parent // id; do their names match what I am seeking? fn matches_names(&self, parent_of_n: NodeId, name: Name) -> bool { name.as_str() == &self.item_name[..] && self.suffix_matches(parent_of_n) } } impl<'a, 'ast> Iterator for NodesMatchingSuffix<'a, 'ast> { type Item = NodeId; fn next(&mut self) -> Option { loop { let idx = self.idx; if idx as usize >= self.map.entry_count() { return None; } self.idx += 1; let name = match self.map.find_entry(idx) { Some(EntryItem(_, n)) => n.name(), Some(EntryForeignItem(_, n))=> n.name(), Some(EntryTraitItem(_, n)) => n.name(), Some(EntryImplItem(_, n)) => n.name(), Some(EntryVariant(_, n)) => n.name(), _ => continue, }; if self.matches_names(self.map.get_parent(idx), name) { return Some(idx) } } } } trait Named { fn name(&self) -> Name; } impl Named for Spanned { fn name(&self) -> Name { self.node.name() } } impl Named for Item { fn name(&self) -> Name { self.name } } impl Named for ForeignItem { fn name(&self) -> Name { self.name } } impl Named for Variant_ { fn name(&self) -> Name { self.name } } impl Named for TraitItem { fn name(&self) -> Name { self.name } } impl Named for ImplItem { fn name(&self) -> Name { self.name } } pub trait FoldOps { fn new_id(&self, id: NodeId) -> NodeId { id } fn new_def_id(&self, def_id: DefId) -> DefId { def_id } fn new_span(&self, span: Span) -> Span { span } } /// A Folder that updates IDs and Span's according to fold_ops. struct IdAndSpanUpdater { fold_ops: F } impl Folder for IdAndSpanUpdater { fn new_id(&mut self, id: NodeId) -> NodeId { self.fold_ops.new_id(id) } fn new_span(&mut self, span: Span) -> Span { self.fold_ops.new_span(span) } } pub fn collect_definitions<'ast>(krate: &'ast ast::Crate) -> Definitions { let mut def_collector = DefCollector::root(); visit::walk_crate(&mut def_collector, krate); def_collector.definitions } pub fn map_crate<'ast>(forest: &'ast mut Forest, definitions: Definitions) -> Map<'ast> { let mut collector = NodeCollector::root(&forest.krate); intravisit::walk_crate(&mut collector, &forest.krate); let map = collector.map; if log_enabled!(::log::DEBUG) { // This only makes sense for ordered stores; note the // enumerate to count the number of entries. let (entries_less_1, _) = map.iter().filter(|&x| { match *x { NotPresent => false, _ => true } }).enumerate().last().expect("AST map was empty after folding?"); let entries = entries_less_1 + 1; let vector_length = map.len(); debug!("The AST map has {} entries with a maximum of {}: occupancy {:.1}%", entries, vector_length, (entries as f64 / vector_length as f64) * 100.); } Map { forest: forest, dep_graph: forest.dep_graph.clone(), map: RefCell::new(map), definitions: RefCell::new(definitions), } } /// Used for items loaded from external crate that are being inlined into this /// crate. pub fn map_decoded_item<'ast, F: FoldOps>(map: &Map<'ast>, parent_def_path: DefPath, parent_def_id: DefId, ii: InlinedItem, fold_ops: F) -> &'ast InlinedItem { let mut fld = IdAndSpanUpdater { fold_ops: fold_ops }; let ii = match ii { II::Item(i) => II::Item(i.map(|i| fld.fold_item(i))), II::TraitItem(d, ti) => { II::TraitItem(fld.fold_ops.new_def_id(d), ti.map(|ti| fld.fold_trait_item(ti))) } II::ImplItem(d, ii) => { II::ImplItem(fld.fold_ops.new_def_id(d), ii.map(|ii| fld.fold_impl_item(ii))) } II::Foreign(i) => II::Foreign(i.map(|i| fld.fold_foreign_item(i))) }; let ii = map.forest.inlined_items.alloc(ii); let ii_parent_id = fld.new_id(DUMMY_NODE_ID); let defs = mem::replace(&mut *map.definitions.borrow_mut(), Definitions::new()); let mut def_collector = DefCollector::extend(ii_parent_id, parent_def_path.clone(), parent_def_id, defs); def_collector.walk_item(ii, map.krate()); *map.definitions.borrow_mut() = def_collector.definitions; let mut collector = NodeCollector::extend(map.krate(), ii, ii_parent_id, parent_def_path, parent_def_id, mem::replace(&mut *map.map.borrow_mut(), vec![])); ii.visit(&mut collector); *map.map.borrow_mut() = collector.map; ii } pub trait NodePrinter { fn print_node(&mut self, node: &Node) -> io::Result<()>; } impl<'a> NodePrinter for pprust::State<'a> { fn print_node(&mut self, node: &Node) -> io::Result<()> { match *node { NodeItem(a) => self.print_item(&a), NodeForeignItem(a) => self.print_foreign_item(&a), NodeTraitItem(a) => self.print_trait_item(a), NodeImplItem(a) => self.print_impl_item(a), NodeVariant(a) => self.print_variant(&a), NodeExpr(a) => self.print_expr(&a), NodeStmt(a) => self.print_stmt(&a), NodePat(a) => self.print_pat(&a), NodeBlock(a) => self.print_block(&a), NodeLifetime(a) => self.print_lifetime(&a), NodeTyParam(_) => bug!("cannot print TyParam"), // these cases do not carry enough information in the // ast_map to reconstruct their full structure for pretty // printing. NodeLocal(_) => bug!("cannot print isolated Local"), NodeStructCtor(_) => bug!("cannot print isolated StructCtor"), } } } fn node_id_to_string(map: &Map, id: NodeId, include_id: bool) -> String { let id_str = format!(" (id={})", id); let id_str = if include_id { &id_str[..] } else { "" }; let path_str = || { // This functionality is used for debugging, try to use TyCtxt to get // the user-friendly path, otherwise fall back to stringifying DefPath. ::ty::tls::with_opt(|tcx| { if let Some(tcx) = tcx { tcx.node_path_str(id) } else if let Some(path) = map.def_path_from_id(id) { path.data.into_iter().map(|elem| { elem.data.to_string() }).collect::>().join("::") } else { String::from("") } }) }; match map.find(id) { Some(NodeItem(item)) => { let item_str = match item.node { ItemExternCrate(..) => "extern crate", ItemUse(..) => "use", ItemStatic(..) => "static", ItemConst(..) => "const", ItemFn(..) => "fn", ItemMod(..) => "mod", ItemForeignMod(..) => "foreign mod", ItemTy(..) => "ty", ItemEnum(..) => "enum", ItemStruct(..) => "struct", ItemTrait(..) => "trait", ItemImpl(..) => "impl", ItemDefaultImpl(..) => "default impl", }; format!("{} {}{}", item_str, path_str(), id_str) } Some(NodeForeignItem(_)) => { format!("foreign item {}{}", path_str(), id_str) } Some(NodeImplItem(ii)) => { match ii.node { ImplItemKind::Const(..) => { format!("assoc const {} in {}{}", ii.name, path_str(), id_str) } ImplItemKind::Method(..) => { format!("method {} in {}{}", ii.name, path_str(), id_str) } ImplItemKind::Type(_) => { format!("assoc type {} in {}{}", ii.name, path_str(), id_str) } } } Some(NodeTraitItem(ti)) => { let kind = match ti.node { ConstTraitItem(..) => "assoc constant", MethodTraitItem(..) => "trait method", TypeTraitItem(..) => "assoc type", }; format!("{} {} in {}{}", kind, ti.name, path_str(), id_str) } Some(NodeVariant(ref variant)) => { format!("variant {} in {}{}", variant.node.name, path_str(), id_str) } Some(NodeExpr(ref expr)) => { format!("expr {}{}", pprust::expr_to_string(&expr), id_str) } Some(NodeStmt(ref stmt)) => { format!("stmt {}{}", pprust::stmt_to_string(&stmt), id_str) } Some(NodeLocal(ref pat)) => { format!("local {}{}", pprust::pat_to_string(&pat), id_str) } Some(NodePat(ref pat)) => { format!("pat {}{}", pprust::pat_to_string(&pat), id_str) } Some(NodeBlock(ref block)) => { format!("block {}{}", pprust::block_to_string(&block), id_str) } Some(NodeStructCtor(_)) => { format!("struct_ctor {}{}", path_str(), id_str) } Some(NodeLifetime(ref l)) => { format!("lifetime {}{}", pprust::lifetime_to_string(&l), id_str) } Some(NodeTyParam(ref ty_param)) => { format!("typaram {:?}{}", ty_param, id_str) } None => { format!("unknown node{}", id_str) } } }