// Copyright 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. // This implements the dead-code warning pass. It follows middle::reachable // closely. The idea is that all reachable symbols are live, codes called // from live codes are live, and everything else is dead. use middle::ty; use middle::typeck; use middle::privacy; use middle::lint::dead_code; use std::hashmap::HashSet; use syntax::ast; use syntax::ast_map; use syntax::ast_util::{local_def, def_id_of_def, is_local}; use syntax::codemap; use syntax::parse::token; use syntax::visit::Visitor; use syntax::visit; // Any local node that may call something in its body block should be // explored. For example, if it's a live node_item that is a // function, then we should explore its block to check for codes that // may need to be marked as live. fn should_explore(tcx: ty::ctxt, def_id: ast::DefId) -> bool { if !is_local(def_id) { return false; } let items = tcx.items.borrow(); match items.get().find(&def_id.node) { Some(&ast_map::node_item(..)) | Some(&ast_map::node_method(..)) | Some(&ast_map::node_foreign_item(..)) | Some(&ast_map::node_trait_method(..)) => true, _ => false } } struct MarkSymbolVisitor { worklist: ~[ast::NodeId], method_map: typeck::method_map, tcx: ty::ctxt, live_symbols: ~HashSet, } impl MarkSymbolVisitor { fn new(tcx: ty::ctxt, method_map: typeck::method_map, worklist: ~[ast::NodeId]) -> MarkSymbolVisitor { MarkSymbolVisitor { worklist: worklist, method_map: method_map, tcx: tcx, live_symbols: ~HashSet::new(), } } fn check_def_id(&mut self, def_id: ast::DefId) { if should_explore(self.tcx, def_id) { self.worklist.push(def_id.node); } self.live_symbols.insert(def_id.node); } fn lookup_and_handle_definition(&mut self, id: &ast::NodeId) { let def_map = self.tcx.def_map.borrow(); let def = match def_map.get().find(id) { Some(&def) => def, None => return }; let def_id = match def { ast::DefVariant(enum_id, _, _) => Some(enum_id), ast::DefPrimTy(_) => None, _ => Some(def_id_of_def(def)), }; match def_id { Some(def_id) => self.check_def_id(def_id), None => (), } } fn lookup_and_handle_method(&mut self, id: &ast::NodeId, span: codemap::Span) { let method_map = self.method_map.borrow(); match method_map.get().find(id) { Some(&typeck::method_map_entry { origin, .. }) => { match origin { typeck::method_static(def_id) => { match ty::provided_source(self.tcx, def_id) { Some(p_did) => self.check_def_id(p_did), None => self.check_def_id(def_id) } } typeck::method_param(typeck::method_param { trait_id: trait_id, method_num: index, .. }) | typeck::method_object(typeck::method_object { trait_id: trait_id, method_num: index, .. }) => { let def_id = ty::trait_method(self.tcx, trait_id, index).def_id; self.check_def_id(def_id); } } } None => { self.tcx.sess.span_bug(span, "method call expression not \ in method map?!") } } } fn mark_live_symbols(&mut self) { let mut scanned = HashSet::new(); while self.worklist.len() > 0 { let id = self.worklist.pop(); if scanned.contains(&id) { continue } scanned.insert(id); let items = self.tcx.items.borrow(); match items.get().find(&id) { Some(node) => { self.live_symbols.insert(id); self.visit_node(node); } None => (), } } } fn visit_node(&mut self, node: &ast_map::ast_node) { match *node { ast_map::node_item(item, _) => { match item.node { ast::item_fn(..) | ast::item_ty(..) | ast::item_enum(..) | ast::item_struct(..) | ast::item_static(..) => { visit::walk_item(self, item, ()); } _ => () } } ast_map::node_trait_method(trait_method, _, _) => { visit::walk_trait_method(self, trait_method, ()); } ast_map::node_method(method, _, _) => { visit::walk_block(self, method.body, ()); } ast_map::node_foreign_item(foreign_item, _, _, _) => { visit::walk_foreign_item(self, foreign_item, ()); } _ => () } } } impl Visitor<()> for MarkSymbolVisitor { fn visit_expr(&mut self, expr: &ast::Expr, _: ()) { match expr.node { ast::ExprMethodCall(..) => { self.lookup_and_handle_method(&expr.id, expr.span); } _ => () } visit::walk_expr(self, expr, ()) } fn visit_path(&mut self, path: &ast::Path, id: ast::NodeId, _: ()) { self.lookup_and_handle_definition(&id); visit::walk_path(self, path, ()); } 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. } } // This visitor is used to mark the implemented methods of a trait. Since we // can not be sure if such methods are live or dead, we simply mark them // as live. struct TraitMethodSeeder { worklist: ~[ast::NodeId], } impl Visitor<()> for TraitMethodSeeder { fn visit_item(&mut self, item: &ast::item, _: ()) { match item.node { ast::item_impl(_, Some(ref _trait_ref), _, ref methods) => { for method in methods.iter() { self.worklist.push(method.id); } } ast::item_mod(..) | ast::item_fn(..) => { visit::walk_item(self, item, ()); } _ => () } } } fn create_and_seed_worklist(tcx: ty::ctxt, exported_items: &privacy::ExportedItems, reachable_symbols: &HashSet, crate: &ast::Crate) -> ~[ast::NodeId] { let mut worklist = ~[]; // Preferably, we would only need to seed the worklist with reachable // symbols. However, since the set of reachable symbols differs // depending on whether a crate is built as bin or lib, and we want // the warning to be consistent, we also seed the worklist with // exported symbols. for &id in exported_items.iter() { worklist.push(id); } for &id in reachable_symbols.iter() { worklist.push(id); } // Seed entry point match tcx.sess.entry_fn.get() { Some((id, _)) => worklist.push(id), None => () } // Seed implemeneted trait methods let mut trait_method_seeder = TraitMethodSeeder { worklist: worklist }; visit::walk_crate(&mut trait_method_seeder, crate, ()); return trait_method_seeder.worklist; } fn find_live(tcx: ty::ctxt, method_map: typeck::method_map, exported_items: &privacy::ExportedItems, reachable_symbols: &HashSet, crate: &ast::Crate) -> ~HashSet { let worklist = create_and_seed_worklist(tcx, exported_items, reachable_symbols, crate); let mut symbol_visitor = MarkSymbolVisitor::new(tcx, method_map, worklist); symbol_visitor.mark_live_symbols(); symbol_visitor.live_symbols } fn should_warn(item: &ast::item) -> bool { match item.node { ast::item_static(..) | ast::item_fn(..) | ast::item_enum(..) | ast::item_struct(..) => true, _ => false } } fn get_struct_ctor_id(item: &ast::item) -> Option { match item.node { ast::item_struct(struct_def, _) => struct_def.ctor_id, _ => None } } struct DeadVisitor { tcx: ty::ctxt, live_symbols: ~HashSet, } impl DeadVisitor { // id := node id of an item's definition. // ctor_id := `Some` if the item is a struct_ctor (tuple struct), // `None` otherwise. // If the item is a struct_ctor, then either its `id` or // `ctor_id` (unwrapped) is in the live_symbols set. More specifically, // DefMap maps the ExprPath of a struct_ctor to the node referred by // `ctor_id`. On the other hand, in a statement like // `type = ;` where refers to a struct_ctor, // DefMap maps to `id` instead. fn symbol_is_live(&mut self, id: ast::NodeId, ctor_id: Option) -> bool { if self.live_symbols.contains(&id) || ctor_id.map_default(false, |ctor| self.live_symbols.contains(&ctor)) { return true; } // If it's a type whose methods are live, then it's live, too. // This is done to handle the case where, for example, the static // method of a private type is used, but the type itself is never // called directly. let def_id = local_def(id); let inherent_impls = self.tcx.inherent_impls.borrow(); match inherent_impls.get().find(&def_id) { None => (), Some(ref impl_list) => { let impl_list = impl_list.borrow(); for impl_ in impl_list.get().iter() { for method in impl_.methods.iter() { if self.live_symbols.contains(&method.def_id.node) { return true; } } } } } false } fn warn_dead_code(&mut self, id: ast::NodeId, span: codemap::Span, ident: &ast::Ident) { self.tcx.sess.add_lint(dead_code, id, span, format!("code is never used: `{}`", token::ident_to_str(ident))); } } impl Visitor<()> for DeadVisitor { fn visit_item(&mut self, item: &ast::item, _: ()) { let ctor_id = get_struct_ctor_id(item); if !self.symbol_is_live(item.id, ctor_id) && should_warn(item) { self.warn_dead_code(item.id, item.span, &item.ident); } visit::walk_item(self, item, ()); } fn visit_foreign_item(&mut self, fi: &ast::foreign_item, _: ()) { if !self.symbol_is_live(fi.id, None) { self.warn_dead_code(fi.id, fi.span, &fi.ident); } visit::walk_foreign_item(self, fi, ()); } fn visit_fn(&mut self, fk: &visit::fn_kind, _: &ast::fn_decl, block: &ast::Block, span: codemap::Span, id: ast::NodeId, _: ()) { // Have to warn method here because methods are not ast::item match *fk { visit::fk_method(..) => { let ident = visit::name_of_fn(fk); if !self.symbol_is_live(id, None) { self.warn_dead_code(id, span, &ident); } } _ => () } visit::walk_block(self, block, ()); } // Overwrite so that we don't warn the trait method itself. fn visit_trait_method(&mut self, trait_method: &ast::trait_method, _: ()) { match *trait_method { ast::provided(method) => visit::walk_block(self, method.body, ()), ast::required(_) => () } } } pub fn check_crate(tcx: ty::ctxt, method_map: typeck::method_map, exported_items: &privacy::ExportedItems, reachable_symbols: &HashSet, crate: &ast::Crate) { let live_symbols = find_live(tcx, method_map, exported_items, reachable_symbols, crate); let mut visitor = DeadVisitor { tcx: tcx, live_symbols: live_symbols }; visit::walk_crate(&mut visitor, crate, ()); }