dep.cc - platform/build/kati - Git at Google

 // Copyright 2015 Google Inc. All rights reserved
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 // +build ignore

 #include "dep.h"

 #include <algorithm>
 #include <iterator>
 #include <map>
 #include <memory>
 #include <unordered_map>
 #include <unordered_set>

 #include "eval.h"
 #include "fileutil.h"
 #include "log.h"
 #include "rule.h"
 #include "strutil.h"
 #include "symtab.h"
 #include "var.h"

 namespace {

 static vector<DepNode*>* g_dep_node_pool;

 static Symbol ReplaceSuffix(Symbol s, Symbol newsuf) {
   string r;
   AppendString(StripExt(s.str()), &r);
   r += '.';
   AppendString(newsuf.str(), &r);
   return Intern(r);
 }

 class RuleTrie {
   struct Entry {
     Entry(shared_ptr<Rule> r, StringPiece s)
         : rule(r), suffix(s) {
     }
     shared_ptr<Rule> rule;
     StringPiece suffix;
   };

  public:
   RuleTrie() {}
   ~RuleTrie() {
     for (auto& p : children_)
       delete p.second;
   }

   void Add(StringPiece name, shared_ptr<Rule> rule) {
     if (name.empty() || name[0] == '%') {
       rules_.push_back(Entry(rule, name));
       return;
     }
     const char c = name[0];
     auto p = children_.emplace(c, nullptr);
     if (p.second) {
       p.first->second = new RuleTrie();
     }
     p.first->second->Add(name.substr(1), rule);
   }

   void Get(StringPiece name, vector<shared_ptr<Rule>>* rules) const {
     for (const Entry& ent : rules_) {
       if ((ent.suffix.empty() && name.empty()) ||
           HasSuffix(name, ent.suffix.substr(1))) {
         rules->push_back(ent.rule);
       }
     }
     if (name.empty())
       return;
     auto found = children_.find(name[0]);
     if (found != children_.end()) {
       found->second->Get(name.substr(1), rules);
     }
   }

   size_t size() const {
     size_t r = rules_.size();
     for (const auto& c : children_)
       r += c.second->size();
     return r;
   }

  private:
   vector<Entry> rules_;
   unordered_map<char, RuleTrie*> children_;
 };

 }  // namespace

 DepNode::DepNode(Symbol o, bool p, bool r)
     : output(o),
       has_rule(false),
       is_default_target(false),
       is_phony(p),
       is_restat(r),
       rule_vars(NULL),
       output_pattern(Symbol::IsUninitialized()) {
   g_dep_node_pool->push_back(this);
 }

 class DepBuilder {
  public:
   DepBuilder(Evaluator* ev,
              const vector<shared_ptr<Rule>>& rules,
              const unordered_map<Symbol, Vars*>& rule_vars)
       : ev_(ev),
         rule_vars_(rule_vars),
         implicit_rules_(new RuleTrie()),
         first_rule_(NULL) {
     PopulateRules(rules);
     LOG_STAT("%zu variables", ev->mutable_vars()->size());
     LOG_STAT("%zu explicit rules", rules_.size());
     LOG_STAT("%zu implicit rules", implicit_rules_->size());
     LOG_STAT("%zu suffix rules", suffix_rules_.size());

     auto found = rules_.find(Intern(".PHONY"));
     if (found != rules_.end()) {
       for (Symbol input : found->second->inputs) {
         phony_.insert(input);
       }
     }
     found = rules_.find(Intern(".KATI_RESTAT"));
     if (found != rules_.end()) {
       for (Symbol input : found->second->inputs) {
         restat_.insert(input);
       }
     }
   }

   ~DepBuilder() {
   }

   void Build(vector<Symbol> targets, vector<DepNode*>* nodes) {
     if (!first_rule_) {
       ERROR("*** No targets.");
     }
     CHECK(!first_rule_->outputs.empty());

     if (!g_flags.gen_all_targets && targets.empty()) {
       targets.push_back(first_rule_->outputs[0]);
     }
     if (g_flags.gen_all_phony_targets) {
       for (Symbol s : phony_)
         targets.push_back(s);
     }
     if (g_flags.gen_all_targets) {
       unordered_set<Symbol> non_root_targets;
       for (const auto& p : rules_) {
         for (Symbol t : p.second->inputs)
           non_root_targets.insert(t);
         for (Symbol t : p.second->order_only_inputs)
           non_root_targets.insert(t);
       }

       for (const auto& p : rules_) {
         Symbol t = p.first;
         if (!non_root_targets.count(t)) {
           targets.push_back(p.first);
         }
       }
     }

     // TODO: LogStats?

     for (Symbol target : targets) {
       cur_rule_vars_.reset(new Vars);
       ev_->set_current_scope(cur_rule_vars_.get());
       DepNode* n = BuildPlan(target, Intern(""));
       nodes->push_back(n);
       ev_->set_current_scope(NULL);
       cur_rule_vars_.reset(NULL);
     }
   }

  private:
   bool Exists(Symbol target) {
     auto found = rules_.find(target);
     if (found != rules_.end())
       return true;
     if (phony_.count(target))
       return true;
     return ::Exists(target.str());
   }

   void PopulateRules(const vector<shared_ptr<Rule>>& rules) {
     for (shared_ptr<Rule> rule : rules) {
       if (rule->outputs.empty()) {
         PopulateImplicitRule(rule);
       } else {
         PopulateExplicitRule(rule);
       }
     }
     for (auto& p : suffix_rules_) {
       reverse(p.second.begin(), p.second.end());
     }
   }

   bool PopulateSuffixRule(shared_ptr<Rule> rule, Symbol output) {
     if (output.empty() || output.str()[0] != '.')
       return false;

     const StringPiece rest = StringPiece(output.str()).substr(1);
     size_t dot_index = rest.find('.');
     // If there is only a single dot or the third dot, this is not a
     // suffix rule.
     if (dot_index == string::npos ||
         rest.substr(dot_index+1).find('.') != string::npos) {
       return false;
     }

     StringPiece input_suffix = rest.substr(0, dot_index);
     StringPiece output_suffix = rest.substr(dot_index+1);
     shared_ptr<Rule> r = make_shared<Rule>(*rule);
     r->inputs.clear();
     r->inputs.push_back(Intern(input_suffix));
     r->is_suffix_rule = true;
     suffix_rules_[output_suffix].push_back(r);
     return true;
   }

   void ApplyOutputPattern(const Rule& r,
                           Symbol output,
                           const vector<Symbol>& inputs,
                           vector<Symbol>* out_inputs) {
     if (inputs.empty())
       return;
     if (r.is_suffix_rule) {
       for (Symbol input : inputs) {
         out_inputs->push_back(ReplaceSuffix(output, input));
       }
       return;
     }
     if (r.output_patterns.empty()) {
       copy(inputs.begin(), inputs.end(), back_inserter(*out_inputs));
       return;
     }
     CHECK(r.output_patterns.size() == 1);
     Pattern pat(r.output_patterns[0].str());
     for (Symbol input : inputs) {
       string buf;
       pat.AppendSubst(output.str(), input.str(), &buf);
       out_inputs->push_back(Intern(buf));
     }
   }

   shared_ptr<Rule> MergeRules(const Rule& old_rule,
                               const Rule& rule,
                               Symbol output,
                               bool is_suffix_rule) {
     if (old_rule.is_double_colon != rule.is_double_colon) {
       ERROR("%s:%d: *** target file `%s' has both : and :: entries.",
             LOCF(rule.loc), output.str().c_str());
     }
     if (!old_rule.cmds.empty() && !rule.cmds.empty() &&
         !is_suffix_rule && !rule.is_double_colon) {
       WARN("%s:%d: warning: overriding commands for target `%s'",
            LOCF(rule.cmd_loc()), output.str().c_str());
       WARN("%s:%d: warning: ignoring old commands for target `%s'",
            LOCF(old_rule.cmd_loc()), output.str().c_str());
     }

     shared_ptr<Rule> r = make_shared<Rule>(rule);
     if (rule.is_double_colon) {
       r->cmds.clear();
       for (Value* c : old_rule.cmds)
         r->cmds.push_back(c);
       for (Value* c : rule.cmds)
         r->cmds.push_back(c);
       if (!rule.output_patterns.empty() && !old_rule.output_patterns.empty() &&
           rule.output_patterns != old_rule.output_patterns) {
         ERROR("%s:%d: TODO: merging two double rules with output patterns "
               "is not supported", LOCF(rule.loc));
       }
     } else if (!old_rule.cmds.empty() && rule.cmds.empty()) {
       r->cmds = old_rule.cmds;
     }

     // If the latter rule has a command (regardless of the commands in
     // |old_rule|), inputs in the latter rule has a priority.
     if (rule.cmds.empty()) {
       r->inputs = old_rule.inputs;
       ApplyOutputPattern(rule, output, rule.inputs, &r->inputs);
       r->order_only_inputs = old_rule.order_only_inputs;
       ApplyOutputPattern(rule, output, rule.order_only_inputs,
                          &r->order_only_inputs);
       r->output_patterns = old_rule.output_patterns;
     } else {
       ApplyOutputPattern(old_rule, output, old_rule.inputs, &r->inputs);
       ApplyOutputPattern(old_rule, output, old_rule.order_only_inputs,
                          &r->order_only_inputs);
     }
     r->is_default_target |= old_rule.is_default_target;
     return r;
   }

   void PopulateExplicitRule(shared_ptr<Rule> orig_rule) {
     for (Symbol output : orig_rule->outputs) {
       const bool is_suffix_rule = PopulateSuffixRule(orig_rule, output);

       shared_ptr<Rule> rule = make_shared<Rule>(*orig_rule);
       rule->outputs.clear();
       rule->outputs.push_back(output);

       auto p = rules_.insert(make_pair(output, rule));
       if (p.second) {
         if (!first_rule_ && output.get(0) != '.') {
           rule->is_default_target = true;
           first_rule_ = rule;
         }
       } else {
         p.first->second =
             MergeRules(*p.first->second, *rule, output, is_suffix_rule);
       }
     }
   }

   void PopulateImplicitRule(shared_ptr<Rule> rule) {
     for (Symbol output_pattern : rule->output_patterns) {
       shared_ptr<Rule> r = make_shared<Rule>(*rule);
       r->output_patterns.clear();
       r->output_patterns.push_back(output_pattern);
       implicit_rules_->Add(output_pattern.str(), r);
     }
   }

   shared_ptr<Rule> LookupRule(Symbol o) {
     auto found = rules_.find(o);
     if (found != rules_.end())
       return found->second;
     return NULL;
   }

   Vars* LookupRuleVars(Symbol o) {
     auto found = rule_vars_.find(o);
     if (found != rule_vars_.end())
       return found->second;
     return NULL;
   }

   bool CanPickImplicitRule(shared_ptr<Rule> rule, Symbol output) {
     CHECK(rule->output_patterns.size() == 1);
     Pattern pat(rule->output_patterns[0].str());
     if (!pat.Match(output.str())) {
       return false;
     }
     for (Symbol input : rule->inputs) {
       string buf;
       pat.AppendSubst(output.str(), input.str(), &buf);
       if (!Exists(Intern(buf)))
         return false;
     }
     return true;
   }

   Vars* MergeImplicitRuleVars(Symbol output, Vars* vars) {
     auto found = rule_vars_.find(output);
     if (found == rule_vars_.end())
       return vars;
     if (vars == NULL)
       return found->second;
     // TODO: leak.
     Vars* r = new Vars(*found->second);
     for (auto p : *vars) {
       (*r)[p.first] = p.second;
     }
     return r;
   }

   bool PickRule(Symbol output,
                 shared_ptr<Rule>* out_rule, Vars** out_var) {
     shared_ptr<Rule> rule = LookupRule(output);
     Vars* vars = LookupRuleVars(output);
     *out_rule = rule;
     *out_var = vars;
     if (rule) {
       if (!rule->cmds.empty()) {
         return true;
       }
     }

     vector<shared_ptr<Rule>> irules;
     implicit_rules_->Get(output.str(), &irules);
     for (auto iter = irules.rbegin(); iter != irules.rend(); ++iter) {
       shared_ptr<Rule> irule = *iter;
       if (!CanPickImplicitRule(irule, output))
         continue;
       if (rule) {
         shared_ptr<Rule> r = make_shared<Rule>(*rule);
         r->output_patterns = irule->output_patterns;
         r->inputs.clear();
         r->inputs = irule->inputs;
         copy(rule->inputs.begin(), rule->inputs.end(),
              back_inserter(r->inputs));
         r->cmds = irule->cmds;
         r->is_default_target |= irule->is_default_target;
         r->loc = irule->loc;
         r->cmd_lineno = irule->cmd_lineno;
         *out_rule = r;
         return true;
       }
       if (vars) {
         CHECK(irule->output_patterns.size() == 1);
         vars = MergeImplicitRuleVars(irule->output_patterns[0], vars);
         *out_var = vars;
       }
       *out_rule = irule;
       return true;
     }

     StringPiece output_suffix = GetExt(output.str());
     if (output_suffix.get(0) != '.')
       return rule.get();
     output_suffix = output_suffix.substr(1);

     SuffixRuleMap::const_iterator found = suffix_rules_.find(output_suffix);
     if (found == suffix_rules_.end())
       return rule.get();

     for (shared_ptr<Rule> irule : found->second) {
       CHECK(irule->inputs.size() == 1);
       Symbol input = ReplaceSuffix(output, irule->inputs[0]);
       if (!Exists(input))
         continue;

       if (rule) {
         shared_ptr<Rule> r = make_shared<Rule>(*rule);
         r->inputs.insert(r->inputs.begin(), input);
         r->cmds = irule->cmds;
         r->is_default_target |= irule->is_default_target;
         r->loc = irule->loc;
         r->cmd_lineno = irule->cmd_lineno;
         *out_rule = r;
         return true;
       }
       if (vars) {
         CHECK(irule->outputs.size() == 1);
         vars = MergeImplicitRuleVars(irule->outputs[0], vars);
         *out_var = vars;
       }
       *out_rule = irule;
       return true;
     }

     return rule.get();
   }

   DepNode* BuildPlan(Symbol output, Symbol needed_by UNUSED) {
     LOG("BuildPlan: %s for %s",
         output.c_str(),
         needed_by.c_str());

     auto found = done_.find(output);
     if (found != done_.end()) {
       return found->second;
     }

     DepNode* n = new DepNode(output,
                              phony_.count(output),
                              restat_.count(output));
     done_[output] = n;

     shared_ptr<Rule> rule;
     Vars* vars;
     if (!PickRule(output, &rule, &vars)) {
       return n;
     }

     if (rule->output_patterns.size() >= 1) {
       if (rule->output_patterns.size() != 1) {
         fprintf(stderr, "hmm %s\n", rule->DebugString().c_str());
       }
       CHECK(rule->output_patterns.size() == 1);
       n->output_pattern = rule->output_patterns[0];
     }

     vector<unique_ptr<ScopedVar>> sv;
     if (vars) {
       for (const auto& p : *vars) {
         Symbol name = p.first;
         RuleVar* var = reinterpret_cast<RuleVar*>(p.second);
         CHECK(var);
         Var* new_var = var->v();
         if (var->op() == AssignOp::PLUS_EQ) {
           Var* old_var = ev_->LookupVar(name);
           if (old_var->IsDefined()) {
             // TODO: This would be incorrect and has a leak.
             shared_ptr<string> s = make_shared<string>();
             old_var->Eval(ev_, s.get());
             if (!s->empty())
               *s += ' ';
             new_var->Eval(ev_, s.get());
             new_var = new SimpleVar(*s, old_var->Origin());
           }
         } else if (var->op() == AssignOp::QUESTION_EQ) {
           Var* old_var = ev_->LookupVar(name);
           if (old_var->IsDefined()) {
             continue;
           }
         }
         sv.emplace_back(new ScopedVar(cur_rule_vars_.get(), name, new_var));
       }
     }

     ApplyOutputPattern(*rule, output, rule->inputs, &n->actual_inputs);
     for (Symbol input : n->actual_inputs) {
       DepNode* c = BuildPlan(input, output);
       n->deps.push_back(c);
     }

     vector<Symbol> order_only_inputs;
     ApplyOutputPattern(*rule, output, rule->order_only_inputs,
                        &order_only_inputs);
     for (Symbol input : order_only_inputs) {
       DepNode* c = BuildPlan(input, output);
       n->order_onlys.push_back(c);
     }

     n->has_rule = true;
     n->cmds = rule->cmds;
     n->is_default_target = rule->is_default_target;
     if (cur_rule_vars_->empty()) {
       n->rule_vars = NULL;
     } else {
       n->rule_vars = new Vars;
       for (auto p : *cur_rule_vars_) {
         n->rule_vars->insert(p);
       }
     }
     n->loc = rule->loc;
     if (!rule->cmds.empty() && rule->cmd_lineno)
       n->loc.lineno = rule->cmd_lineno;

     return n;
   }

   Evaluator* ev_;
   map<Symbol, shared_ptr<Rule>> rules_;
   const unordered_map<Symbol, Vars*>& rule_vars_;
   unique_ptr<Vars> cur_rule_vars_;

   unique_ptr<RuleTrie> implicit_rules_;
   typedef unordered_map<StringPiece, vector<shared_ptr<Rule>>> SuffixRuleMap;
   SuffixRuleMap suffix_rules_;

   shared_ptr<Rule> first_rule_;
   unordered_map<Symbol, DepNode*> done_;
   unordered_set<Symbol> phony_;
   unordered_set<Symbol> restat_;
 };

 void MakeDep(Evaluator* ev,
              const vector<shared_ptr<Rule>>& rules,
              const unordered_map<Symbol, Vars*>& rule_vars,
              const vector<Symbol>& targets,
              vector<DepNode*>* nodes) {
   DepBuilder db(ev, rules, rule_vars);
   db.Build(targets, nodes);
 }

 void InitDepNodePool() {
   g_dep_node_pool = new vector<DepNode*>;
 }

 void QuitDepNodePool() {
   for (DepNode* n : *g_dep_node_pool)
     delete n;
   delete g_dep_node_pool;
 }
	// Copyright 2015 Google Inc. All rights reserved
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	// +build ignore

	#include "dep.h"

	#include <algorithm>
	#include <iterator>
	#include <map>
	#include <memory>
	#include <unordered_map>
	#include <unordered_set>

	#include "eval.h"
	#include "fileutil.h"
	#include "log.h"
	#include "rule.h"
	#include "strutil.h"
	#include "symtab.h"
	#include "var.h"

	namespace {

	static vector<DepNode> g_dep_node_pool;

	static Symbol ReplaceSuffix(Symbol s, Symbol newsuf) {
	string r;
	AppendString(StripExt(s.str()), &r);
	r += '.';
	AppendString(newsuf.str(), &r);
	return Intern(r);
	}

	class RuleTrie {
	struct Entry {
	Entry(shared_ptr<Rule> r, StringPiece s)
	: rule(r), suffix(s) {
	}
	shared_ptr<Rule> rule;
	StringPiece suffix;
	};

	public:
	RuleTrie() {}
	~RuleTrie() {
	for (auto& p : children_)
	delete p.second;
	}

	void Add(StringPiece name, shared_ptr<Rule> rule) {
	if (name.empty() \|\| name[0] == '%') {
	rules_.push_back(Entry(rule, name));
	return;
	}
	const char c = name[0];
	auto p = children_.emplace(c, nullptr);
	if (p.second) {
	p.first->second = new RuleTrie();
	}
	p.first->second->Add(name.substr(1), rule);
	}

	void Get(StringPiece name, vector<shared_ptr<Rule>>* rules) const {
	for (const Entry& ent : rules_) {
	if ((ent.suffix.empty() && name.empty()) \|\|
	HasSuffix(name, ent.suffix.substr(1))) {
	rules->push_back(ent.rule);
	}
	}
	if (name.empty())
	return;
	auto found = children_.find(name[0]);
	if (found != children_.end()) {
	found->second->Get(name.substr(1), rules);
	}
	}

	size_t size() const {
	size_t r = rules_.size();
	for (const auto& c : children_)
	r += c.second->size();
	return r;
	}

	private:
	vector<Entry> rules_;
	unordered_map<char, RuleTrie*> children_;
	};

	} // namespace

	DepNode::DepNode(Symbol o, bool p, bool r)
	: output(o),
	has_rule(false),
	is_default_target(false),
	is_phony(p),
	is_restat(r),
	rule_vars(NULL),
	output_pattern(Symbol::IsUninitialized()) {
	g_dep_node_pool->push_back(this);
	}

	class DepBuilder {
	public:
	DepBuilder(Evaluator* ev,
	const vector<shared_ptr<Rule>>& rules,
	const unordered_map<Symbol, Vars*>& rule_vars)
	: ev_(ev),
	rule_vars_(rule_vars),
	implicit_rules_(new RuleTrie()),
	first_rule_(NULL) {
	PopulateRules(rules);
	LOG_STAT("%zu variables", ev->mutable_vars()->size());
	LOG_STAT("%zu explicit rules", rules_.size());
	LOG_STAT("%zu implicit rules", implicit_rules_->size());
	LOG_STAT("%zu suffix rules", suffix_rules_.size());

	auto found = rules_.find(Intern(".PHONY"));
	if (found != rules_.end()) {
	for (Symbol input : found->second->inputs) {
	phony_.insert(input);
	}
	}
	found = rules_.find(Intern(".KATI_RESTAT"));
	if (found != rules_.end()) {
	for (Symbol input : found->second->inputs) {
	restat_.insert(input);
	}
	}
	}

	~DepBuilder() {
	}

	void Build(vector<Symbol> targets, vector<DepNode> nodes) {
	if (!first_rule_) {
	ERROR("*** No targets.");
	}
	CHECK(!first_rule_->outputs.empty());

	if (!g_flags.gen_all_targets && targets.empty()) {
	targets.push_back(first_rule_->outputs[0]);
	}
	if (g_flags.gen_all_phony_targets) {
	for (Symbol s : phony_)
	targets.push_back(s);
	}
	if (g_flags.gen_all_targets) {
	unordered_set<Symbol> non_root_targets;
	for (const auto& p : rules_) {
	for (Symbol t : p.second->inputs)
	non_root_targets.insert(t);
	for (Symbol t : p.second->order_only_inputs)
	non_root_targets.insert(t);
	}

	for (const auto& p : rules_) {
	Symbol t = p.first;
	if (!non_root_targets.count(t)) {
	targets.push_back(p.first);
	}
	}
	}

	// TODO: LogStats?

	for (Symbol target : targets) {
	cur_rule_vars_.reset(new Vars);
	ev_->set_current_scope(cur_rule_vars_.get());
	DepNode* n = BuildPlan(target, Intern(""));
	nodes->push_back(n);
	ev_->set_current_scope(NULL);
	cur_rule_vars_.reset(NULL);
	}
	}

	private:
	bool Exists(Symbol target) {
	auto found = rules_.find(target);
	if (found != rules_.end())
	return true;
	if (phony_.count(target))
	return true;
	return ::Exists(target.str());
	}

	void PopulateRules(const vector<shared_ptr<Rule>>& rules) {
	for (shared_ptr<Rule> rule : rules) {
	if (rule->outputs.empty()) {
	PopulateImplicitRule(rule);
	} else {
	PopulateExplicitRule(rule);
	}
	}
	for (auto& p : suffix_rules_) {
	reverse(p.second.begin(), p.second.end());
	}
	}

	bool PopulateSuffixRule(shared_ptr<Rule> rule, Symbol output) {
	if (output.empty() \|\| output.str()[0] != '.')
	return false;

	const StringPiece rest = StringPiece(output.str()).substr(1);
	size_t dot_index = rest.find('.');
	// If there is only a single dot or the third dot, this is not a
	// suffix rule.
	if (dot_index == string::npos \|\|
	rest.substr(dot_index+1).find('.') != string::npos) {
	return false;
	}

	StringPiece input_suffix = rest.substr(0, dot_index);
	StringPiece output_suffix = rest.substr(dot_index+1);
	shared_ptr<Rule> r = make_shared<Rule>(*rule);
	r->inputs.clear();
	r->inputs.push_back(Intern(input_suffix));
	r->is_suffix_rule = true;
	suffix_rules_[output_suffix].push_back(r);
	return true;
	}

	void ApplyOutputPattern(const Rule& r,
	Symbol output,
	const vector<Symbol>& inputs,
	vector<Symbol>* out_inputs) {
	if (inputs.empty())
	return;
	if (r.is_suffix_rule) {
	for (Symbol input : inputs) {
	out_inputs->push_back(ReplaceSuffix(output, input));
	}
	return;
	}
	if (r.output_patterns.empty()) {
	copy(inputs.begin(), inputs.end(), back_inserter(*out_inputs));
	return;
	}
	CHECK(r.output_patterns.size() == 1);
	Pattern pat(r.output_patterns[0].str());
	for (Symbol input : inputs) {
	string buf;
	pat.AppendSubst(output.str(), input.str(), &buf);
	out_inputs->push_back(Intern(buf));
	}
	}

	shared_ptr<Rule> MergeRules(const Rule& old_rule,
	const Rule& rule,
	Symbol output,
	bool is_suffix_rule) {
	if (old_rule.is_double_colon != rule.is_double_colon) {
	ERROR("%s:%d: *** target file `%s' has both : and :: entries.",
	LOCF(rule.loc), output.str().c_str());
	}
	if (!old_rule.cmds.empty() && !rule.cmds.empty() &&
	!is_suffix_rule && !rule.is_double_colon) {
	WARN("%s:%d: warning: overriding commands for target `%s'",
	LOCF(rule.cmd_loc()), output.str().c_str());
	WARN("%s:%d: warning: ignoring old commands for target `%s'",
	LOCF(old_rule.cmd_loc()), output.str().c_str());
	}

	shared_ptr<Rule> r = make_shared<Rule>(rule);
	if (rule.is_double_colon) {
	r->cmds.clear();
	for (Value* c : old_rule.cmds)
	r->cmds.push_back(c);
	for (Value* c : rule.cmds)
	r->cmds.push_back(c);
	if (!rule.output_patterns.empty() && !old_rule.output_patterns.empty() &&
	rule.output_patterns != old_rule.output_patterns) {
	ERROR("%s:%d: TODO: merging two double rules with output patterns "
	"is not supported", LOCF(rule.loc));
	}
	} else if (!old_rule.cmds.empty() && rule.cmds.empty()) {
	r->cmds = old_rule.cmds;
	}

	// If the latter rule has a command (regardless of the commands in
	// \|old_rule\|), inputs in the latter rule has a priority.
	if (rule.cmds.empty()) {
	r->inputs = old_rule.inputs;
	ApplyOutputPattern(rule, output, rule.inputs, &r->inputs);
	r->order_only_inputs = old_rule.order_only_inputs;
	ApplyOutputPattern(rule, output, rule.order_only_inputs,
	&r->order_only_inputs);
	r->output_patterns = old_rule.output_patterns;
	} else {
	ApplyOutputPattern(old_rule, output, old_rule.inputs, &r->inputs);
	ApplyOutputPattern(old_rule, output, old_rule.order_only_inputs,
	&r->order_only_inputs);
	}
	r->is_default_target \|= old_rule.is_default_target;
	return r;
	}

	void PopulateExplicitRule(shared_ptr<Rule> orig_rule) {
	for (Symbol output : orig_rule->outputs) {
	const bool is_suffix_rule = PopulateSuffixRule(orig_rule, output);

	shared_ptr<Rule> rule = make_shared<Rule>(*orig_rule);
	rule->outputs.clear();
	rule->outputs.push_back(output);

	auto p = rules_.insert(make_pair(output, rule));
	if (p.second) {
	if (!first_rule_ && output.get(0) != '.') {
	rule->is_default_target = true;
	first_rule_ = rule;
	}
	} else {
	p.first->second =
	MergeRules(p.first->second, rule, output, is_suffix_rule);
	}
	}
	}

	void PopulateImplicitRule(shared_ptr<Rule> rule) {
	for (Symbol output_pattern : rule->output_patterns) {
	shared_ptr<Rule> r = make_shared<Rule>(*rule);
	r->output_patterns.clear();
	r->output_patterns.push_back(output_pattern);
	implicit_rules_->Add(output_pattern.str(), r);
	}
	}

	shared_ptr<Rule> LookupRule(Symbol o) {
	auto found = rules_.find(o);
	if (found != rules_.end())
	return found->second;
	return NULL;
	}

	Vars* LookupRuleVars(Symbol o) {
	auto found = rule_vars_.find(o);
	if (found != rule_vars_.end())
	return found->second;
	return NULL;
	}

	bool CanPickImplicitRule(shared_ptr<Rule> rule, Symbol output) {
	CHECK(rule->output_patterns.size() == 1);
	Pattern pat(rule->output_patterns[0].str());
	if (!pat.Match(output.str())) {
	return false;
	}
	for (Symbol input : rule->inputs) {
	string buf;
	pat.AppendSubst(output.str(), input.str(), &buf);
	if (!Exists(Intern(buf)))
	return false;
	}
	return true;
	}

	Vars* MergeImplicitRuleVars(Symbol output, Vars* vars) {
	auto found = rule_vars_.find(output);
	if (found == rule_vars_.end())
	return vars;
	if (vars == NULL)
	return found->second;
	// TODO: leak.
	Vars* r = new Vars(*found->second);
	for (auto p : *vars) {
	(*r)[p.first] = p.second;
	}
	return r;
	}

	bool PickRule(Symbol output,
	shared_ptr<Rule>* out_rule, Vars** out_var) {
	shared_ptr<Rule> rule = LookupRule(output);
	Vars* vars = LookupRuleVars(output);
	*out_rule = rule;
	*out_var = vars;
	if (rule) {
	if (!rule->cmds.empty()) {
	return true;
	}
	}

	vector<shared_ptr<Rule>> irules;
	implicit_rules_->Get(output.str(), &irules);
	for (auto iter = irules.rbegin(); iter != irules.rend(); ++iter) {
	shared_ptr<Rule> irule = *iter;
	if (!CanPickImplicitRule(irule, output))
	continue;
	if (rule) {
	shared_ptr<Rule> r = make_shared<Rule>(*rule);
	r->output_patterns = irule->output_patterns;
	r->inputs.clear();
	r->inputs = irule->inputs;
	copy(rule->inputs.begin(), rule->inputs.end(),
	back_inserter(r->inputs));
	r->cmds = irule->cmds;
	r->is_default_target \|= irule->is_default_target;
	r->loc = irule->loc;
	r->cmd_lineno = irule->cmd_lineno;
	*out_rule = r;
	return true;
	}
	if (vars) {
	CHECK(irule->output_patterns.size() == 1);
	vars = MergeImplicitRuleVars(irule->output_patterns[0], vars);
	*out_var = vars;
	}
	*out_rule = irule;
	return true;
	}

	StringPiece output_suffix = GetExt(output.str());
	if (output_suffix.get(0) != '.')
	return rule.get();
	output_suffix = output_suffix.substr(1);

	SuffixRuleMap::const_iterator found = suffix_rules_.find(output_suffix);
	if (found == suffix_rules_.end())
	return rule.get();

	for (shared_ptr<Rule> irule : found->second) {
	CHECK(irule->inputs.size() == 1);
	Symbol input = ReplaceSuffix(output, irule->inputs[0]);
	if (!Exists(input))
	continue;

	if (rule) {
	shared_ptr<Rule> r = make_shared<Rule>(*rule);
	r->inputs.insert(r->inputs.begin(), input);
	r->cmds = irule->cmds;
	r->is_default_target \|= irule->is_default_target;
	r->loc = irule->loc;
	r->cmd_lineno = irule->cmd_lineno;
	*out_rule = r;
	return true;
	}
	if (vars) {
	CHECK(irule->outputs.size() == 1);
	vars = MergeImplicitRuleVars(irule->outputs[0], vars);
	*out_var = vars;
	}
	*out_rule = irule;
	return true;
	}

	return rule.get();
	}

	DepNode* BuildPlan(Symbol output, Symbol needed_by UNUSED) {
	LOG("BuildPlan: %s for %s",
	output.c_str(),
	needed_by.c_str());

	auto found = done_.find(output);
	if (found != done_.end()) {
	return found->second;
	}

	DepNode* n = new DepNode(output,
	phony_.count(output),
	restat_.count(output));
	done_[output] = n;

	shared_ptr<Rule> rule;
	Vars* vars;
	if (!PickRule(output, &rule, &vars)) {
	return n;
	}

	if (rule->output_patterns.size() >= 1) {
	if (rule->output_patterns.size() != 1) {
	fprintf(stderr, "hmm %s\n", rule->DebugString().c_str());
	}
	CHECK(rule->output_patterns.size() == 1);
	n->output_pattern = rule->output_patterns[0];
	}

	vector<unique_ptr<ScopedVar>> sv;
	if (vars) {
	for (const auto& p : *vars) {
	Symbol name = p.first;
	RuleVar* var = reinterpret_cast<RuleVar*>(p.second);
	CHECK(var);
	Var* new_var = var->v();
	if (var->op() == AssignOp::PLUS_EQ) {
	Var* old_var = ev_->LookupVar(name);
	if (old_var->IsDefined()) {
	// TODO: This would be incorrect and has a leak.
	shared_ptr<string> s = make_shared<string>();
	old_var->Eval(ev_, s.get());
	if (!s->empty())
	*s += ' ';
	new_var->Eval(ev_, s.get());
	new_var = new SimpleVar(*s, old_var->Origin());
	}
	} else if (var->op() == AssignOp::QUESTION_EQ) {
	Var* old_var = ev_->LookupVar(name);
	if (old_var->IsDefined()) {
	continue;
	}
	}
	sv.emplace_back(new ScopedVar(cur_rule_vars_.get(), name, new_var));
	}
	}

	ApplyOutputPattern(*rule, output, rule->inputs, &n->actual_inputs);
	for (Symbol input : n->actual_inputs) {
	DepNode* c = BuildPlan(input, output);
	n->deps.push_back(c);
	}

	vector<Symbol> order_only_inputs;
	ApplyOutputPattern(*rule, output, rule->order_only_inputs,
	&order_only_inputs);
	for (Symbol input : order_only_inputs) {
	DepNode* c = BuildPlan(input, output);
	n->order_onlys.push_back(c);
	}

	n->has_rule = true;
	n->cmds = rule->cmds;
	n->is_default_target = rule->is_default_target;
	if (cur_rule_vars_->empty()) {
	n->rule_vars = NULL;
	} else {
	n->rule_vars = new Vars;
	for (auto p : *cur_rule_vars_) {
	n->rule_vars->insert(p);
	}
	}
	n->loc = rule->loc;
	if (!rule->cmds.empty() && rule->cmd_lineno)
	n->loc.lineno = rule->cmd_lineno;

	return n;
	}

	Evaluator* ev_;
	map<Symbol, shared_ptr<Rule>> rules_;
	const unordered_map<Symbol, Vars*>& rule_vars_;
	unique_ptr<Vars> cur_rule_vars_;

	unique_ptr<RuleTrie> implicit_rules_;
	typedef unordered_map<StringPiece, vector<shared_ptr<Rule>>> SuffixRuleMap;
	SuffixRuleMap suffix_rules_;

	shared_ptr<Rule> first_rule_;
	unordered_map<Symbol, DepNode*> done_;
	unordered_set<Symbol> phony_;
	unordered_set<Symbol> restat_;
	};

	void MakeDep(Evaluator* ev,
	const vector<shared_ptr<Rule>>& rules,
	const unordered_map<Symbol, Vars*>& rule_vars,
	const vector<Symbol>& targets,
	vector<DepNode> nodes) {
	DepBuilder db(ev, rules, rule_vars);
	db.Build(targets, nodes);
	}

	void InitDepNodePool() {
	g_dep_node_pool = new vector<DepNode*>;
	}

	void QuitDepNodePool() {
	for (DepNode* n : *g_dep_node_pool)
	delete n;
	delete g_dep_node_pool;
	}