// Copyright 2012-2013 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. // Finds items that are externally reachable, to determine which items // need to have their metadata (and possibly their AST) serialized. // All items that can be referred to through an exported name are // reachable, and when a reachable thing is inline or generic, it // makes all other generics or inline functions that it references // reachable as well. use middle::ty; use middle::typeck; use middle::privacy; use std::cell::RefCell; use std::hashmap::HashSet; use syntax::ast; use syntax::ast_map; use syntax::ast_util::{def_id_of_def, is_local}; use syntax::attr; use syntax::parse::token; use syntax::visit::Visitor; use syntax::visit; // Returns true if the given set of attributes contains the `#[inline]` // attribute. fn attributes_specify_inlining(attrs: &[ast::Attribute]) -> bool { attr::contains_name(attrs, "inline") } // Returns true if the given set of generics implies that the item it's // associated with must be inlined. fn generics_require_inlining(generics: &ast::Generics) -> bool { !generics.ty_params.is_empty() } // Returns true if the given item must be inlined because it may be // monomorphized or it was marked with `#[inline]`. This will only return // true for functions. fn item_might_be_inlined(item: @ast::item) -> bool { if attributes_specify_inlining(item.attrs) { return true } match item.node { ast::item_impl(ref generics, _, _, _) | ast::item_fn(_, _, _, ref generics, _) => { generics_require_inlining(generics) } _ => false, } } fn method_might_be_inlined(tcx: ty::ctxt, method: &ast::method, impl_src: ast::DefId) -> bool { if attributes_specify_inlining(method.attrs) || generics_require_inlining(&method.generics) { return true } if is_local(impl_src) { { let items = tcx.items.borrow(); match items.get().find(&impl_src.node) { Some(&ast_map::node_item(item, _)) => { item_might_be_inlined(item) } Some(..) | None => { tcx.sess.span_bug(method.span, "impl did is not an item") } } } } else { tcx.sess.span_bug(method.span, "found a foreign impl as a parent of a \ local method") } } // Information needed while computing reachability. struct ReachableContext { // The type context. tcx: ty::ctxt, // The method map, which links node IDs of method call expressions to the // methods they've been resolved to. method_map: typeck::method_map, // The set of items which must be exported in the linkage sense. reachable_symbols: @RefCell>, // A worklist of item IDs. Each item ID in this worklist will be inlined // and will be scanned for further references. worklist: @RefCell<~[ast::NodeId]>, } struct MarkSymbolVisitor { worklist: @RefCell<~[ast::NodeId]>, method_map: typeck::method_map, tcx: ty::ctxt, reachable_symbols: @RefCell>, } impl Visitor<()> for MarkSymbolVisitor { fn visit_expr(&mut self, expr:@ast::Expr, _:()) { match expr.node { ast::ExprPath(_) => { let def_map = self.tcx.def_map.borrow(); let def = match def_map.get().find(&expr.id) { Some(&def) => def, None => { self.tcx.sess.span_bug(expr.span, "def ID not in def map?!") } }; let def_id = def_id_of_def(def); if is_local(def_id) { if ReachableContext:: def_id_represents_local_inlined_item(self.tcx, def_id) { { let mut worklist = self.worklist.borrow_mut(); worklist.get().push(def_id.node) } } else { match def { // If this path leads to a static, then we may have // to do some work to figure out whether the static // is indeed reachable (address_insignificant // statics are *never* reachable). ast::DefStatic(..) => { let mut worklist = self.worklist.borrow_mut(); worklist.get().push(def_id.node); } // If this wasn't a static, then this destination is // surely reachable. _ => { let mut reachable_symbols = self.reachable_symbols.borrow_mut(); reachable_symbols.get().insert(def_id.node); } } } } } ast::ExprMethodCall(..) => { let method_map = self.method_map.borrow(); match method_map.get().find(&expr.id) { Some(&typeck::method_map_entry { origin: typeck::method_static(def_id), .. }) => { if is_local(def_id) { if ReachableContext:: def_id_represents_local_inlined_item( self.tcx, def_id) { { let mut worklist = self.worklist .borrow_mut(); worklist.get().push(def_id.node) } } { let mut reachable_symbols = self.reachable_symbols.borrow_mut(); reachable_symbols.get().insert(def_id.node); } } } Some(_) => {} None => { self.tcx.sess.span_bug(expr.span, "method call expression \ not in method map?!") } } } _ => {} } visit::walk_expr(self, expr, ()) } fn visit_item(&mut self, _item: @ast::item, _: ()) { // Do not recurse into items. These items will be added to the worklist // and recursed into manually if necessary. } } impl ReachableContext { // Creates a new reachability computation context. fn new(tcx: ty::ctxt, method_map: typeck::method_map) -> ReachableContext { ReachableContext { tcx: tcx, method_map: method_map, reachable_symbols: @RefCell::new(HashSet::new()), worklist: @RefCell::new(~[]), } } // Returns true if the given def ID represents a local item that is // eligible for inlining and false otherwise. fn def_id_represents_local_inlined_item(tcx: ty::ctxt, def_id: ast::DefId) -> bool { if def_id.crate != ast::LOCAL_CRATE { return false } let node_id = def_id.node; let items = tcx.items.borrow(); match items.get().find(&node_id) { Some(&ast_map::node_item(item, _)) => { match item.node { ast::item_fn(..) => item_might_be_inlined(item), _ => false, } } Some(&ast_map::node_trait_method(trait_method, _, _)) => { match *trait_method { ast::required(_) => false, ast::provided(_) => true, } } Some(&ast_map::node_method(method, impl_did, _)) => { if generics_require_inlining(&method.generics) || attributes_specify_inlining(method.attrs) { true } else { // Check the impl. If the generics on the self type of the // impl require inlining, this method does too. assert!(impl_did.crate == ast::LOCAL_CRATE); match items.get().find(&impl_did.node) { Some(&ast_map::node_item(item, _)) => { match item.node { ast::item_impl(ref generics, _, _, _) => { generics_require_inlining(generics) } _ => false } } Some(_) => { tcx.sess.span_bug(method.span, "method is not inside an \ impl?!") } None => { tcx.sess.span_bug(method.span, "the impl that this method is \ supposedly inside of doesn't \ exist in the AST map?!") } } } } Some(_) => false, None => false // This will happen for default methods. } } // Helper function to set up a visitor for `propagate()` below. fn init_visitor(&self) -> MarkSymbolVisitor { let (worklist, method_map) = (self.worklist, self.method_map); let (tcx, reachable_symbols) = (self.tcx, self.reachable_symbols); MarkSymbolVisitor { worklist: worklist, method_map: method_map, tcx: tcx, reachable_symbols: reachable_symbols, } } // Step 2: Mark all symbols that the symbols on the worklist touch. fn propagate(&self) { let mut visitor = self.init_visitor(); let mut scanned = HashSet::new(); loop { let search_item = { let mut worklist = self.worklist.borrow_mut(); if worklist.get().len() == 0 { break } let search_item = worklist.get().pop(); if scanned.contains(&search_item) { continue } search_item }; scanned.insert(search_item); let items = self.tcx.items.borrow(); match items.get().find(&search_item) { Some(item) => self.propagate_node(item, search_item, &mut visitor), None if search_item == ast::CRATE_NODE_ID => {} None => { self.tcx.sess.bug(format!("found unmapped ID in worklist: \ {}", search_item)) } } } } fn propagate_node(&self, node: &ast_map::ast_node, search_item: ast::NodeId, visitor: &mut MarkSymbolVisitor) { if !self.tcx.sess.building_library.get() { // If we are building an executable, then there's no need to flag // anything as external except for `extern fn` types. These // functions may still participate in some form of native interface, // but all other rust-only interfaces can be private (they will not // participate in linkage after this product is produced) match *node { ast_map::node_item(item, _) => { match item.node { ast::item_fn(_, ast::extern_fn, _, _, _) => { let mut reachable_symbols = self.reachable_symbols.borrow_mut(); reachable_symbols.get().insert(search_item); } _ => {} } } _ => {} } } else { // If we are building a library, then reachable symbols will // continue to participate in linkage after this product is // produced. In this case, we traverse the ast node, recursing on // all reachable nodes from this one. let mut reachable_symbols = self.reachable_symbols.borrow_mut(); reachable_symbols.get().insert(search_item); } match *node { ast_map::node_item(item, _) => { match item.node { ast::item_fn(_, _, _, _, search_block) => { if item_might_be_inlined(item) { visit::walk_block(visitor, search_block, ()) } } // Statics with insignificant addresses are not reachable // because they're inlined specially into all other crates. ast::item_static(..) => { if attr::contains_name(item.attrs, "address_insignificant") { let mut reachable_symbols = self.reachable_symbols.borrow_mut(); reachable_symbols.get().remove(&search_item); } } // These are normal, nothing reachable about these // inherently and their children are already in the // worklist, as determined by the privacy pass ast::item_ty(..) | ast::item_mod(..) | ast::item_foreign_mod(..) | ast::item_impl(..) | ast::item_trait(..) | ast::item_struct(..) | ast::item_enum(..) => {} _ => { self.tcx.sess.span_bug(item.span, "found non-function item \ in worklist?!") } } } ast_map::node_trait_method(trait_method, _, _) => { match *trait_method { ast::required(..) => { // Keep going, nothing to get exported } ast::provided(ref method) => { visit::walk_block(visitor, method.body, ()) } } } ast_map::node_method(method, did, _) => { if method_might_be_inlined(self.tcx, method, did) { visit::walk_block(visitor, method.body, ()) } } // Nothing to recurse on for these ast_map::node_foreign_item(..) | ast_map::node_variant(..) | ast_map::node_struct_ctor(..) => {} _ => { let ident_interner = token::get_ident_interner(); let desc = ast_map::node_id_to_str(self.tcx.items, search_item, ident_interner); self.tcx.sess.bug(format!("found unexpected thingy in \ worklist: {}", desc)) } } } // Step 3: Mark all destructors as reachable. // // XXX(pcwalton): This is a conservative overapproximation, but fixing // this properly would result in the necessity of computing *type* // reachability, which might result in a compile time loss. fn mark_destructors_reachable(&self) { let destructor_for_type = self.tcx.destructor_for_type.borrow(); for (_, destructor_def_id) in destructor_for_type.get().iter() { if destructor_def_id.crate == ast::LOCAL_CRATE { let mut reachable_symbols = self.reachable_symbols .borrow_mut(); reachable_symbols.get().insert(destructor_def_id.node); } } } } pub fn find_reachable(tcx: ty::ctxt, method_map: typeck::method_map, exported_items: &privacy::ExportedItems) -> @RefCell> { let reachable_context = ReachableContext::new(tcx, method_map); // Step 1: Seed the worklist with all nodes which were found to be public as // a result of the privacy pass for &id in exported_items.iter() { let mut worklist = reachable_context.worklist.borrow_mut(); worklist.get().push(id); } // Step 2: Mark all symbols that the symbols on the worklist touch. reachable_context.propagate(); // Step 3: Mark all destructors as reachable. reachable_context.mark_destructors_reachable(); // Return the set of reachable symbols. reachable_context.reachable_symbols }