tools/gn/scope.cc - platform/external/chromium_org - Git at Google

 // Copyright (c) 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "tools/gn/scope.h"

 #include "base/logging.h"
 #include "base/stl_util.h"
 #include "tools/gn/parse_tree.h"
 #include "tools/gn/template.h"

 namespace {

 // FLags set in the mode_flags_ of a scope. If a bit is set, it applies
 // recursively to all dependent scopes.
 const unsigned kProcessingBuildConfigFlag = 1;
 const unsigned kProcessingImportFlag = 2;

 // Returns true if this variable name should be considered private. Private
 // values start with an underscore, and are not imported from "gni" files
 // when processing an import.
 bool IsPrivateVar(const base::StringPiece& name) {
   return name.empty() || name[0] == '_';
 }

 }  // namespace

 Scope::Scope(const Settings* settings)
     : const_containing_(NULL),
       mutable_containing_(NULL),
       settings_(settings),
       mode_flags_(0),
       item_collector_(NULL) {
 }

 Scope::Scope(Scope* parent)
     : const_containing_(NULL),
       mutable_containing_(parent),
       settings_(parent->settings()),
       mode_flags_(0),
       item_collector_(NULL) {
 }

 Scope::Scope(const Scope* parent)
     : const_containing_(parent),
       mutable_containing_(NULL),
       settings_(parent->settings()),
       mode_flags_(0),
       item_collector_(NULL) {
 }

 Scope::~Scope() {
   STLDeleteContainerPairSecondPointers(target_defaults_.begin(),
                                        target_defaults_.end());
 }

 const Value* Scope::GetValue(const base::StringPiece& ident,
                              bool counts_as_used) {
   // First check for programatically-provided values.
   for (ProviderSet::const_iterator i = programmatic_providers_.begin();
        i != programmatic_providers_.end(); ++i) {
     const Value* v = (*i)->GetProgrammaticValue(ident);
     if (v)
       return v;
   }

   RecordMap::iterator found = values_.find(ident);
   if (found != values_.end()) {
     if (counts_as_used)
       found->second.used = true;
     return &found->second.value;
   }

   // Search in the parent scope.
   if (const_containing_)
     return const_containing_->GetValue(ident);
   if (mutable_containing_)
     return mutable_containing_->GetValue(ident, counts_as_used);
   return NULL;
 }

 Value* Scope::GetMutableValue(const base::StringPiece& ident,
                               bool counts_as_used) {
   // Don't do programatic values, which are not mutable.
   RecordMap::iterator found = values_.find(ident);
   if (found != values_.end()) {
     if (counts_as_used)
       found->second.used = true;
     return &found->second.value;
   }

   // Search in the parent mutable scope, but not const one.
   if (mutable_containing_)
     return mutable_containing_->GetMutableValue(ident, counts_as_used);
   return NULL;
 }

 Value* Scope::GetValueForcedToCurrentScope(const base::StringPiece& ident,
                                            const ParseNode* set_node) {
   RecordMap::iterator found = values_.find(ident);
   if (found != values_.end())
     return &found->second.value;  // Already have in the current scope.

   // Search in the parent scope.
   if (containing()) {
     const Value* in_containing = containing()->GetValue(ident);
     if (in_containing) {
       // Promote to current scope.
       return SetValue(ident, *in_containing, set_node);
     }
   }
   return NULL;
 }

 const Value* Scope::GetValue(const base::StringPiece& ident) const {
   RecordMap::const_iterator found = values_.find(ident);
   if (found != values_.end())
     return &found->second.value;
   if (containing())
     return containing()->GetValue(ident);
   return NULL;
 }

 Value* Scope::SetValue(const base::StringPiece& ident,
                        const Value& v,
                        const ParseNode* set_node) {
   Record& r = values_[ident];  // Clears any existing value.
   r.value = v;
   r.value.set_origin(set_node);
   return &r.value;
 }

 void Scope::RemoveIdentifier(const base::StringPiece& ident) {
   RecordMap::iterator found = values_.find(ident);
   if (found != values_.end())
     values_.erase(found);
 }

 void Scope::RemovePrivateIdentifiers() {
   // Do it in two phases to avoid mutating while iterating. Our hash map is
   // currently backed by several different vendor-specific implementations and
   // I'm not sure if all of them support mutating while iterating. Since this
   // is not perf-critical, do the safe thing.
   std::vector<base::StringPiece> to_remove;
   for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i) {
     if (IsPrivateVar(i->first))
       to_remove.push_back(i->first);
   }

   for (size_t i = 0; i < to_remove.size(); i++)
     values_.erase(to_remove[i]);
 }

 bool Scope::AddTemplate(const std::string& name, const Template* templ) {
   if (GetTemplate(name))
     return false;
   templates_[name] = templ;
   return true;
 }

 const Template* Scope::GetTemplate(const std::string& name) const {
   TemplateMap::const_iterator found = templates_.find(name);
   if (found != templates_.end())
     return found->second.get();
   if (containing())
     return containing()->GetTemplate(name);
   return NULL;
 }

 void Scope::MarkUsed(const base::StringPiece& ident) {
   RecordMap::iterator found = values_.find(ident);
   if (found == values_.end()) {
     NOTREACHED();
     return;
   }
   found->second.used = true;
 }

 void Scope::MarkUnused(const base::StringPiece& ident) {
   RecordMap::iterator found = values_.find(ident);
   if (found == values_.end()) {
     NOTREACHED();
     return;
   }
   found->second.used = false;
 }

 bool Scope::IsSetButUnused(const base::StringPiece& ident) const {
   RecordMap::const_iterator found = values_.find(ident);
   if (found != values_.end()) {
     if (!found->second.used) {
       return true;
     }
   }
   return false;
 }

 bool Scope::CheckForUnusedVars(Err* err) const {
   for (RecordMap::const_iterator i = values_.begin();
        i != values_.end(); ++i) {
     if (!i->second.used) {
       std::string help = "You set the variable \"" + i->first.as_string() +
           "\" here and it was unused before it went\nout of scope.";

       const BinaryOpNode* binary = i->second.value.origin()->AsBinaryOp();
       if (binary && binary->op().type() == Token::EQUAL) {
         // Make a nicer error message for normal var sets.
         *err = Err(binary->left()->GetRange(), "Assignment had no effect.",
                    help);
       } else {
         // This will happen for internally-generated variables.
         *err = Err(i->second.value.origin(), "Assignment had no effect.", help);
       }
       return false;
     }
   }
   return true;
 }

 void Scope::GetCurrentScopeValues(KeyValueMap* output) const {
   for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i)
     (*output)[i->first] = i->second.value;
 }

 bool Scope::NonRecursiveMergeTo(Scope* dest,
                                 const MergeOptions& options,
                                 const ParseNode* node_for_err,
                                 const char* desc_for_err,
                                 Err* err) const {
   // Values.
   for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i) {
     if (options.skip_private_vars && IsPrivateVar(i->first))
       continue;  // Skip this private var.

     const Value& new_value = i->second.value;
     if (!options.clobber_existing) {
       const Value* existing_value = dest->GetValue(i->first);
       if (existing_value && new_value != *existing_value) {
         // Value present in both the source and the dest.
         std::string desc_string(desc_for_err);
         *err = Err(node_for_err, "Value collision.",
             "This " + desc_string + " contains \"" + i->first.as_string() +
             "\"");
         err->AppendSubErr(Err(i->second.value, "defined here.",
             "Which would clobber the one in your current scope"));
         err->AppendSubErr(Err(*existing_value, "defined here.",
             "Executing " + desc_string + " should not conflict with anything "
             "in the current\nscope unless the values are identical."));
         return false;
       }
     }
     dest->values_[i->first] = i->second;

     if (options.mark_used)
       dest->MarkUsed(i->first);
   }

   // Target defaults are owning pointers.
   for (NamedScopeMap::const_iterator i = target_defaults_.begin();
        i != target_defaults_.end(); ++i) {
     if (!options.clobber_existing) {
       if (dest->GetTargetDefaults(i->first)) {
         // TODO(brettw) it would be nice to know the origin of a
         // set_target_defaults so we can give locations for the colliding target
         // defaults.
         std::string desc_string(desc_for_err);
         *err = Err(node_for_err, "Target defaults collision.",
             "This " + desc_string + " contains target defaults for\n"
             "\"" + i->first + "\" which would clobber one for the\n"
             "same target type in your current scope. It's unfortunate that I'm "
             "too stupid\nto tell you the location of where the target defaults "
             "were set. Usually\nthis happens in the BUILDCONFIG.gn file.");
         return false;
       }
     }

     // Be careful to delete any pointer we're about to clobber.
     Scope** dest_scope = &dest->target_defaults_[i->first];
     if (*dest_scope)
       delete *dest_scope;
     *dest_scope = new Scope(settings_);
     i->second->NonRecursiveMergeTo(*dest_scope, options, node_for_err,
                                    "<SHOULDN'T HAPPEN>", err);
   }

   // Sources assignment filter.
   if (sources_assignment_filter_) {
     if (!options.clobber_existing) {
       if (dest->GetSourcesAssignmentFilter()) {
         // Sources assignment filter present in both the source and the dest.
         std::string desc_string(desc_for_err);
         *err = Err(node_for_err, "Assignment filter collision.",
             "The " + desc_string + " contains a sources_assignment_filter "
             "which\nwould clobber the one in your current scope.");
         return false;
       }
     }
     dest->sources_assignment_filter_.reset(
         new PatternList(*sources_assignment_filter_));
   }

   // Templates.
   for (TemplateMap::const_iterator i = templates_.begin();
        i != templates_.end(); ++i) {
     if (options.skip_private_vars && IsPrivateVar(i->first))
       continue;  // Skip this private template.

     if (!options.clobber_existing) {
       const Template* existing_template = dest->GetTemplate(i->first);
       if (existing_template) {
         // Rule present in both the source and the dest.
         std::string desc_string(desc_for_err);
         *err = Err(node_for_err, "Template collision.",
             "This " + desc_string + " contains a template \"" +
             i->first + "\"");
         err->AppendSubErr(Err(i->second->GetDefinitionRange(), "defined here.",
             "Which would clobber the one in your current scope"));
         err->AppendSubErr(Err(existing_template->GetDefinitionRange(),
             "defined here.",
             "Executing " + desc_string + " should not conflict with anything "
             "in the current\nscope."));
         return false;
       }
     }

     // Be careful to delete any pointer we're about to clobber.
     dest->templates_[i->first] = i->second;
   }

   return true;
 }

 scoped_ptr<Scope> Scope::MakeClosure() const {
   scoped_ptr<Scope> result;
   if (const_containing_) {
     // We reached the top of the mutable scope stack. The result scope just
     // references the const scope (which will never change).
     result.reset(new Scope(const_containing_));
   } else if (mutable_containing_) {
     // There are more nested mutable scopes. Recursively go up the stack to
     // get the closure.
     result = mutable_containing_->MakeClosure();
   } else {
     // This is a standalone scope, just copy it.
     result.reset(new Scope(settings_));
   }

   // Want to clobber since we've flattened some nested scopes, and our parent
   // scope may have a duplicate value set.
   MergeOptions options;
   options.clobber_existing = true;

   // Add in our variables and we're done.
   Err err;
   NonRecursiveMergeTo(result.get(), options, NULL, "<SHOULDN'T HAPPEN>", &err);
   DCHECK(!err.has_error());
   return result.Pass();
 }

 Scope* Scope::MakeTargetDefaults(const std::string& target_type) {
   if (GetTargetDefaults(target_type))
     return NULL;

   Scope** dest = &target_defaults_[target_type];
   if (*dest) {
     NOTREACHED();  // Already set.
     return *dest;
   }
   *dest = new Scope(settings_);
   return *dest;
 }

 const Scope* Scope::GetTargetDefaults(const std::string& target_type) const {
   NamedScopeMap::const_iterator found = target_defaults_.find(target_type);
   if (found != target_defaults_.end())
     return found->second;
   if (containing())
     return containing()->GetTargetDefaults(target_type);
   return NULL;
 }

 const PatternList* Scope::GetSourcesAssignmentFilter() const {
   if (sources_assignment_filter_)
     return sources_assignment_filter_.get();
   if (containing())
     return containing()->GetSourcesAssignmentFilter();
   return NULL;
 }

 void Scope::SetProcessingBuildConfig() {
   DCHECK((mode_flags_ & kProcessingBuildConfigFlag) == 0);
   mode_flags_ |= kProcessingBuildConfigFlag;
 }

 void Scope::ClearProcessingBuildConfig() {
   DCHECK(mode_flags_ & kProcessingBuildConfigFlag);
   mode_flags_ &= ~(kProcessingBuildConfigFlag);
 }

 bool Scope::IsProcessingBuildConfig() const {
   if (mode_flags_ & kProcessingBuildConfigFlag)
     return true;
   if (containing())
     return containing()->IsProcessingBuildConfig();
   return false;
 }

 void Scope::SetProcessingImport() {
   DCHECK((mode_flags_ & kProcessingImportFlag) == 0);
   mode_flags_ |= kProcessingImportFlag;
 }

 void Scope::ClearProcessingImport() {
   DCHECK(mode_flags_ & kProcessingImportFlag);
   mode_flags_ &= ~(kProcessingImportFlag);
 }

 bool Scope::IsProcessingImport() const {
   if (mode_flags_ & kProcessingImportFlag)
     return true;
   if (containing())
     return containing()->IsProcessingImport();
   return false;
 }

 const SourceDir& Scope::GetSourceDir() const {
   if (!source_dir_.is_null())
     return source_dir_;
   if (containing())
     return containing()->GetSourceDir();
   return source_dir_;
 }

 Scope::ItemVector* Scope::GetItemCollector() {
   if (item_collector_)
     return item_collector_;
   if (mutable_containing())
     return mutable_containing()->GetItemCollector();
   return NULL;
 }

 void Scope::SetProperty(const void* key, void* value) {
   if (!value) {
     DCHECK(properties_.find(key) != properties_.end());
     properties_.erase(key);
   } else {
     properties_[key] = value;
   }
 }

 void* Scope::GetProperty(const void* key, const Scope** found_on_scope) const {
   PropertyMap::const_iterator found = properties_.find(key);
   if (found != properties_.end()) {
     if (found_on_scope)
       *found_on_scope = this;
     return found->second;
   }
   if (containing())
     return containing()->GetProperty(key, found_on_scope);
   return NULL;
 }

 void Scope::AddProvider(ProgrammaticProvider* p) {
   programmatic_providers_.insert(p);
 }

 void Scope::RemoveProvider(ProgrammaticProvider* p) {
   DCHECK(programmatic_providers_.find(p) != programmatic_providers_.end());
   programmatic_providers_.erase(p);
 }
	// Copyright (c) 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "tools/gn/scope.h"

	#include "base/logging.h"
	#include "base/stl_util.h"
	#include "tools/gn/parse_tree.h"
	#include "tools/gn/template.h"

	namespace {

	// FLags set in the mode_flags_ of a scope. If a bit is set, it applies
	// recursively to all dependent scopes.
	const unsigned kProcessingBuildConfigFlag = 1;
	const unsigned kProcessingImportFlag = 2;

	// Returns true if this variable name should be considered private. Private
	// values start with an underscore, and are not imported from "gni" files
	// when processing an import.
	bool IsPrivateVar(const base::StringPiece& name) {
	return name.empty() \|\| name[0] == '_';
	}

	} // namespace

	Scope::Scope(const Settings* settings)
	: const_containing_(NULL),
	mutable_containing_(NULL),
	settings_(settings),
	mode_flags_(0),
	item_collector_(NULL) {
	}

	Scope::Scope(Scope* parent)
	: const_containing_(NULL),
	mutable_containing_(parent),
	settings_(parent->settings()),
	mode_flags_(0),
	item_collector_(NULL) {
	}

	Scope::Scope(const Scope* parent)
	: const_containing_(parent),
	mutable_containing_(NULL),
	settings_(parent->settings()),
	mode_flags_(0),
	item_collector_(NULL) {
	}

	Scope::~Scope() {
	STLDeleteContainerPairSecondPointers(target_defaults_.begin(),
	target_defaults_.end());
	}

	const Value* Scope::GetValue(const base::StringPiece& ident,
	bool counts_as_used) {
	// First check for programatically-provided values.
	for (ProviderSet::const_iterator i = programmatic_providers_.begin();
	i != programmatic_providers_.end(); ++i) {
	const Value* v = (*i)->GetProgrammaticValue(ident);
	if (v)
	return v;
	}

	RecordMap::iterator found = values_.find(ident);
	if (found != values_.end()) {
	if (counts_as_used)
	found->second.used = true;
	return &found->second.value;
	}

	// Search in the parent scope.
	if (const_containing_)
	return const_containing_->GetValue(ident);
	if (mutable_containing_)
	return mutable_containing_->GetValue(ident, counts_as_used);
	return NULL;
	}

	Value* Scope::GetMutableValue(const base::StringPiece& ident,
	bool counts_as_used) {
	// Don't do programatic values, which are not mutable.
	RecordMap::iterator found = values_.find(ident);
	if (found != values_.end()) {
	if (counts_as_used)
	found->second.used = true;
	return &found->second.value;
	}

	// Search in the parent mutable scope, but not const one.
	if (mutable_containing_)
	return mutable_containing_->GetMutableValue(ident, counts_as_used);
	return NULL;
	}

	Value* Scope::GetValueForcedToCurrentScope(const base::StringPiece& ident,
	const ParseNode* set_node) {
	RecordMap::iterator found = values_.find(ident);
	if (found != values_.end())
	return &found->second.value; // Already have in the current scope.

	// Search in the parent scope.
	if (containing()) {
	const Value* in_containing = containing()->GetValue(ident);
	if (in_containing) {
	// Promote to current scope.
	return SetValue(ident, *in_containing, set_node);
	}
	}
	return NULL;
	}

	const Value* Scope::GetValue(const base::StringPiece& ident) const {
	RecordMap::const_iterator found = values_.find(ident);
	if (found != values_.end())
	return &found->second.value;
	if (containing())
	return containing()->GetValue(ident);
	return NULL;
	}

	Value* Scope::SetValue(const base::StringPiece& ident,
	const Value& v,
	const ParseNode* set_node) {
	Record& r = values_[ident]; // Clears any existing value.
	r.value = v;
	r.value.set_origin(set_node);
	return &r.value;
	}

	void Scope::RemoveIdentifier(const base::StringPiece& ident) {
	RecordMap::iterator found = values_.find(ident);
	if (found != values_.end())
	values_.erase(found);
	}

	void Scope::RemovePrivateIdentifiers() {
	// Do it in two phases to avoid mutating while iterating. Our hash map is
	// currently backed by several different vendor-specific implementations and
	// I'm not sure if all of them support mutating while iterating. Since this
	// is not perf-critical, do the safe thing.
	std::vector<base::StringPiece> to_remove;
	for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i) {
	if (IsPrivateVar(i->first))
	to_remove.push_back(i->first);
	}

	for (size_t i = 0; i < to_remove.size(); i++)
	values_.erase(to_remove[i]);
	}

	bool Scope::AddTemplate(const std::string& name, const Template* templ) {
	if (GetTemplate(name))
	return false;
	templates_[name] = templ;
	return true;
	}

	const Template* Scope::GetTemplate(const std::string& name) const {
	TemplateMap::const_iterator found = templates_.find(name);
	if (found != templates_.end())
	return found->second.get();
	if (containing())
	return containing()->GetTemplate(name);
	return NULL;
	}

	void Scope::MarkUsed(const base::StringPiece& ident) {
	RecordMap::iterator found = values_.find(ident);
	if (found == values_.end()) {
	NOTREACHED();
	return;
	}
	found->second.used = true;
	}

	void Scope::MarkUnused(const base::StringPiece& ident) {
	RecordMap::iterator found = values_.find(ident);
	if (found == values_.end()) {
	NOTREACHED();
	return;
	}
	found->second.used = false;
	}

	bool Scope::IsSetButUnused(const base::StringPiece& ident) const {
	RecordMap::const_iterator found = values_.find(ident);
	if (found != values_.end()) {
	if (!found->second.used) {
	return true;
	}
	}
	return false;
	}

	bool Scope::CheckForUnusedVars(Err* err) const {
	for (RecordMap::const_iterator i = values_.begin();
	i != values_.end(); ++i) {
	if (!i->second.used) {
	std::string help = "You set the variable \"" + i->first.as_string() +
	"\" here and it was unused before it went\nout of scope.";

	const BinaryOpNode* binary = i->second.value.origin()->AsBinaryOp();
	if (binary && binary->op().type() == Token::EQUAL) {
	// Make a nicer error message for normal var sets.
	*err = Err(binary->left()->GetRange(), "Assignment had no effect.",
	help);
	} else {
	// This will happen for internally-generated variables.
	*err = Err(i->second.value.origin(), "Assignment had no effect.", help);
	}
	return false;
	}
	}
	return true;
	}

	void Scope::GetCurrentScopeValues(KeyValueMap* output) const {
	for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i)
	(*output)[i->first] = i->second.value;
	}

	bool Scope::NonRecursiveMergeTo(Scope* dest,
	const MergeOptions& options,
	const ParseNode* node_for_err,
	const char* desc_for_err,
	Err* err) const {
	// Values.
	for (RecordMap::const_iterator i = values_.begin(); i != values_.end(); ++i) {
	if (options.skip_private_vars && IsPrivateVar(i->first))
	continue; // Skip this private var.

	const Value& new_value = i->second.value;
	if (!options.clobber_existing) {
	const Value* existing_value = dest->GetValue(i->first);
	if (existing_value && new_value != *existing_value) {
	// Value present in both the source and the dest.
	std::string desc_string(desc_for_err);
	*err = Err(node_for_err, "Value collision.",
	"This " + desc_string + " contains \"" + i->first.as_string() +
	"\"");
	err->AppendSubErr(Err(i->second.value, "defined here.",
	"Which would clobber the one in your current scope"));
	err->AppendSubErr(Err(*existing_value, "defined here.",
	"Executing " + desc_string + " should not conflict with anything "
	"in the current\nscope unless the values are identical."));
	return false;
	}
	}
	dest->values_[i->first] = i->second;

	if (options.mark_used)
	dest->MarkUsed(i->first);
	}

	// Target defaults are owning pointers.
	for (NamedScopeMap::const_iterator i = target_defaults_.begin();
	i != target_defaults_.end(); ++i) {
	if (!options.clobber_existing) {
	if (dest->GetTargetDefaults(i->first)) {
	// TODO(brettw) it would be nice to know the origin of a
	// set_target_defaults so we can give locations for the colliding target
	// defaults.
	std::string desc_string(desc_for_err);
	*err = Err(node_for_err, "Target defaults collision.",
	"This " + desc_string + " contains target defaults for\n"
	"\"" + i->first + "\" which would clobber one for the\n"
	"same target type in your current scope. It's unfortunate that I'm "
	"too stupid\nto tell you the location of where the target defaults "
	"were set. Usually\nthis happens in the BUILDCONFIG.gn file.");
	return false;
	}
	}

	// Be careful to delete any pointer we're about to clobber.
	Scope** dest_scope = &dest->target_defaults_[i->first];
	if (*dest_scope)
	delete *dest_scope;
	*dest_scope = new Scope(settings_);
	i->second->NonRecursiveMergeTo(*dest_scope, options, node_for_err,
	"<SHOULDN'T HAPPEN>", err);
	}

	// Sources assignment filter.
	if (sources_assignment_filter_) {
	if (!options.clobber_existing) {
	if (dest->GetSourcesAssignmentFilter()) {
	// Sources assignment filter present in both the source and the dest.
	std::string desc_string(desc_for_err);
	*err = Err(node_for_err, "Assignment filter collision.",
	"The " + desc_string + " contains a sources_assignment_filter "
	"which\nwould clobber the one in your current scope.");
	return false;
	}
	}
	dest->sources_assignment_filter_.reset(
	new PatternList(*sources_assignment_filter_));
	}

	// Templates.
	for (TemplateMap::const_iterator i = templates_.begin();
	i != templates_.end(); ++i) {
	if (options.skip_private_vars && IsPrivateVar(i->first))
	continue; // Skip this private template.

	if (!options.clobber_existing) {
	const Template* existing_template = dest->GetTemplate(i->first);
	if (existing_template) {
	// Rule present in both the source and the dest.
	std::string desc_string(desc_for_err);
	*err = Err(node_for_err, "Template collision.",
	"This " + desc_string + " contains a template \"" +
	i->first + "\"");
	err->AppendSubErr(Err(i->second->GetDefinitionRange(), "defined here.",
	"Which would clobber the one in your current scope"));
	err->AppendSubErr(Err(existing_template->GetDefinitionRange(),
	"defined here.",
	"Executing " + desc_string + " should not conflict with anything "
	"in the current\nscope."));
	return false;
	}
	}

	// Be careful to delete any pointer we're about to clobber.
	dest->templates_[i->first] = i->second;
	}

	return true;
	}

	scoped_ptr<Scope> Scope::MakeClosure() const {
	scoped_ptr<Scope> result;
	if (const_containing_) {
	// We reached the top of the mutable scope stack. The result scope just
	// references the const scope (which will never change).
	result.reset(new Scope(const_containing_));
	} else if (mutable_containing_) {
	// There are more nested mutable scopes. Recursively go up the stack to
	// get the closure.
	result = mutable_containing_->MakeClosure();
	} else {
	// This is a standalone scope, just copy it.
	result.reset(new Scope(settings_));
	}

	// Want to clobber since we've flattened some nested scopes, and our parent
	// scope may have a duplicate value set.
	MergeOptions options;
	options.clobber_existing = true;

	// Add in our variables and we're done.
	Err err;
	NonRecursiveMergeTo(result.get(), options, NULL, "<SHOULDN'T HAPPEN>", &err);
	DCHECK(!err.has_error());
	return result.Pass();
	}

	Scope* Scope::MakeTargetDefaults(const std::string& target_type) {
	if (GetTargetDefaults(target_type))
	return NULL;

	Scope** dest = &target_defaults_[target_type];
	if (*dest) {
	NOTREACHED(); // Already set.
	return *dest;
	}
	*dest = new Scope(settings_);
	return *dest;
	}

	const Scope* Scope::GetTargetDefaults(const std::string& target_type) const {
	NamedScopeMap::const_iterator found = target_defaults_.find(target_type);
	if (found != target_defaults_.end())
	return found->second;
	if (containing())
	return containing()->GetTargetDefaults(target_type);
	return NULL;
	}

	const PatternList* Scope::GetSourcesAssignmentFilter() const {
	if (sources_assignment_filter_)
	return sources_assignment_filter_.get();
	if (containing())
	return containing()->GetSourcesAssignmentFilter();
	return NULL;
	}

	void Scope::SetProcessingBuildConfig() {
	DCHECK((mode_flags_ & kProcessingBuildConfigFlag) == 0);
	mode_flags_ \|= kProcessingBuildConfigFlag;
	}

	void Scope::ClearProcessingBuildConfig() {
	DCHECK(mode_flags_ & kProcessingBuildConfigFlag);
	mode_flags_ &= ~(kProcessingBuildConfigFlag);
	}

	bool Scope::IsProcessingBuildConfig() const {
	if (mode_flags_ & kProcessingBuildConfigFlag)
	return true;
	if (containing())
	return containing()->IsProcessingBuildConfig();
	return false;
	}

	void Scope::SetProcessingImport() {
	DCHECK((mode_flags_ & kProcessingImportFlag) == 0);
	mode_flags_ \|= kProcessingImportFlag;
	}

	void Scope::ClearProcessingImport() {
	DCHECK(mode_flags_ & kProcessingImportFlag);
	mode_flags_ &= ~(kProcessingImportFlag);
	}

	bool Scope::IsProcessingImport() const {
	if (mode_flags_ & kProcessingImportFlag)
	return true;
	if (containing())
	return containing()->IsProcessingImport();
	return false;
	}

	const SourceDir& Scope::GetSourceDir() const {
	if (!source_dir_.is_null())
	return source_dir_;
	if (containing())
	return containing()->GetSourceDir();
	return source_dir_;
	}

	Scope::ItemVector* Scope::GetItemCollector() {
	if (item_collector_)
	return item_collector_;
	if (mutable_containing())
	return mutable_containing()->GetItemCollector();
	return NULL;
	}

	void Scope::SetProperty(const void* key, void* value) {
	if (!value) {
	DCHECK(properties_.find(key) != properties_.end());
	properties_.erase(key);
	} else {
	properties_[key] = value;
	}
	}

	void* Scope::GetProperty(const void* key, const Scope** found_on_scope) const {
	PropertyMap::const_iterator found = properties_.find(key);
	if (found != properties_.end()) {
	if (found_on_scope)
	*found_on_scope = this;
	return found->second;
	}
	if (containing())
	return containing()->GetProperty(key, found_on_scope);
	return NULL;
	}

	void Scope::AddProvider(ProgrammaticProvider* p) {
	programmatic_providers_.insert(p);
	}

	void Scope::RemoveProvider(ProgrammaticProvider* p) {
	DCHECK(programmatic_providers_.find(p) != programmatic_providers_.end());
	programmatic_providers_.erase(p);
	}