tools/clang/blink_gc_plugin/RecordInfo.cpp - experimental/gn - Git at Google

 // Copyright 2014 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 "Config.h"
 #include "RecordInfo.h"

 using namespace clang;
 using std::string;

 RecordInfo::RecordInfo(CXXRecordDecl* record, RecordCache* cache)
     : cache_(cache),
       record_(record),
       name_(record->getName()),
       fields_need_tracing_(TracingStatus::Unknown()),
       bases_(0),
       fields_(0),
       is_stack_allocated_(kNotComputed),
       is_non_newable_(kNotComputed),
       is_only_placement_newable_(kNotComputed),
       does_need_finalization_(kNotComputed),
       has_gc_mixin_methods_(kNotComputed),
       is_declaring_local_trace_(kNotComputed),
       is_eagerly_finalized_(kNotComputed),
       determined_trace_methods_(false),
       trace_method_(0),
       trace_dispatch_method_(0),
       finalize_dispatch_method_(0),
       is_gc_derived_(false) {}

 RecordInfo::~RecordInfo() {
   delete fields_;
   delete bases_;
 }

 // Get |count| number of template arguments. Returns false if there
 // are fewer than |count| arguments or any of the arguments are not
 // of a valid Type structure. If |count| is non-positive, all
 // arguments are collected.
 bool RecordInfo::GetTemplateArgs(size_t count, TemplateArgs* output_args) {
   ClassTemplateSpecializationDecl* tmpl =
       dyn_cast<ClassTemplateSpecializationDecl>(record_);
   if (!tmpl)
     return false;
   const TemplateArgumentList& args = tmpl->getTemplateArgs();
   if (args.size() < count)
     return false;
   if (count <= 0)
     count = args.size();
   for (unsigned i = 0; i < count; ++i) {
     TemplateArgument arg = args[i];
     if (arg.getKind() == TemplateArgument::Type && !arg.getAsType().isNull()) {
       output_args->push_back(arg.getAsType().getTypePtr());
     } else {
       return false;
     }
   }
   return true;
 }

 // Test if a record is a HeapAllocated collection.
 bool RecordInfo::IsHeapAllocatedCollection() {
   if (!Config::IsGCCollection(name_) && !Config::IsWTFCollection(name_))
     return false;

   TemplateArgs args;
   if (GetTemplateArgs(0, &args)) {
     for (TemplateArgs::iterator it = args.begin(); it != args.end(); ++it) {
       if (CXXRecordDecl* decl = (*it)->getAsCXXRecordDecl())
         if (decl->getName() == kHeapAllocatorName)
           return true;
     }
   }

   return Config::IsGCCollection(name_);
 }

 // Test if a record is derived from a garbage collected base.
 bool RecordInfo::IsGCDerived() {
   // If already computed, return the known result.
   if (gc_base_names_.size())
     return is_gc_derived_;

   if (!record_->hasDefinition())
     return false;

   // The base classes are not themselves considered garbage collected objects.
   if (Config::IsGCBase(name_))
     return false;

   // Walk the inheritance tree to find GC base classes.
   walkBases();
   return is_gc_derived_;
 }

 CXXRecordDecl* RecordInfo::GetDependentTemplatedDecl(const Type& type) {
   const TemplateSpecializationType* tmpl_type =
       type.getAs<TemplateSpecializationType>();
   if (!tmpl_type)
     return 0;

   TemplateDecl* tmpl_decl = tmpl_type->getTemplateName().getAsTemplateDecl();
   if (!tmpl_decl)
     return 0;

   return dyn_cast_or_null<CXXRecordDecl>(tmpl_decl->getTemplatedDecl());
 }

 void RecordInfo::walkBases() {
   // This traversal is akin to CXXRecordDecl::forallBases()'s,
   // but without stepping over dependent bases -- these might also
   // have a "GC base name", so are to be included and considered.
   SmallVector<const CXXRecordDecl*, 8> queue;

   const CXXRecordDecl *base_record = record();
   while (true) {
     for (const auto& it : base_record->bases()) {
       const RecordType *type = it.getType()->getAs<RecordType>();
       CXXRecordDecl* base;
       if (!type)
         base = GetDependentTemplatedDecl(*it.getType());
       else {
         base = cast_or_null<CXXRecordDecl>(type->getDecl()->getDefinition());
         if (base)
           queue.push_back(base);
       }
       if (!base)
         continue;

       const std::string& name = base->getName();
       if (Config::IsGCBase(name)) {
         gc_base_names_.push_back(name);
         is_gc_derived_ = true;
       }
     }

     if (queue.empty())
       break;
     base_record = queue.pop_back_val(); // not actually a queue.
   }
 }

 bool RecordInfo::IsGCFinalized() {
   if (!IsGCDerived())
     return false;
   for (const auto& gc_base : gc_base_names_) {
     if (Config::IsGCFinalizedBase(gc_base))
       return true;
   }
   return false;
 }

 // A GC mixin is a class that inherits from a GC mixin base and has
 // not yet been "mixed in" with another GC base class.
 bool RecordInfo::IsGCMixin() {
   if (!IsGCDerived() || !gc_base_names_.size())
     return false;
   for (const auto& gc_base : gc_base_names_) {
       // If it is not a mixin base we are done.
       if (!Config::IsGCMixinBase(gc_base))
           return false;
   }
   // This is a mixin if all GC bases are mixins.
   return true;
 }

 // Test if a record is allocated on the managed heap.
 bool RecordInfo::IsGCAllocated() {
   return IsGCDerived() || IsHeapAllocatedCollection();
 }

 bool RecordInfo::IsEagerlyFinalized() {
   if (is_eagerly_finalized_ == kNotComputed) {
     is_eagerly_finalized_ = kFalse;
     if (IsGCFinalized()) {
       for (Decl* decl : record_->decls()) {
         if (TypedefDecl* typedef_decl = dyn_cast<TypedefDecl>(decl)) {
           if (typedef_decl->getNameAsString() == kIsEagerlyFinalizedName) {
             is_eagerly_finalized_ = kTrue;
             break;
           }
         }
       }
     }
   }
   return is_eagerly_finalized_;
 }

 bool RecordInfo::HasDefinition() {
   return record_->hasDefinition();
 }

 RecordInfo* RecordCache::Lookup(CXXRecordDecl* record) {
   // Ignore classes annotated with the GC_PLUGIN_IGNORE macro.
   if (!record || Config::IsIgnoreAnnotated(record))
     return 0;
   Cache::iterator it = cache_.find(record);
   if (it != cache_.end())
     return &it->second;
   return &cache_.insert(std::make_pair(record, RecordInfo(record, this)))
               .first->second;
 }

 bool RecordInfo::IsStackAllocated() {
   if (is_stack_allocated_ == kNotComputed) {
     is_stack_allocated_ = kFalse;
     for (Bases::iterator it = GetBases().begin();
          it != GetBases().end();
          ++it) {
       if (it->second.info()->IsStackAllocated()) {
         is_stack_allocated_ = kTrue;
         return is_stack_allocated_;
       }
     }
     for (CXXRecordDecl::method_iterator it = record_->method_begin();
          it != record_->method_end();
          ++it) {
       if (it->getNameAsString() == kNewOperatorName &&
           it->isDeleted() &&
           Config::IsStackAnnotated(*it)) {
         is_stack_allocated_ = kTrue;
         return is_stack_allocated_;
       }
     }
   }
   return is_stack_allocated_;
 }

 bool RecordInfo::IsNonNewable() {
   if (is_non_newable_ == kNotComputed) {
     bool deleted = false;
     bool all_deleted = true;
     for (CXXRecordDecl::method_iterator it = record_->method_begin();
          it != record_->method_end();
          ++it) {
       if (it->getNameAsString() == kNewOperatorName) {
         deleted = it->isDeleted();
         all_deleted = all_deleted && deleted;
       }
     }
     is_non_newable_ = (deleted && all_deleted) ? kTrue : kFalse;
   }
   return is_non_newable_;
 }

 bool RecordInfo::IsOnlyPlacementNewable() {
   if (is_only_placement_newable_ == kNotComputed) {
     bool placement = false;
     bool new_deleted = false;
     for (CXXRecordDecl::method_iterator it = record_->method_begin();
          it != record_->method_end();
          ++it) {
       if (it->getNameAsString() == kNewOperatorName) {
         if (it->getNumParams() == 1) {
           new_deleted = it->isDeleted();
         } else if (it->getNumParams() == 2) {
           placement = !it->isDeleted();
         }
       }
     }
     is_only_placement_newable_ = (placement && new_deleted) ? kTrue : kFalse;
   }
   return is_only_placement_newable_;
 }

 CXXMethodDecl* RecordInfo::DeclaresNewOperator() {
   for (CXXRecordDecl::method_iterator it = record_->method_begin();
        it != record_->method_end();
        ++it) {
     if (it->getNameAsString() == kNewOperatorName && it->getNumParams() == 1)
       return *it;
   }
   return 0;
 }

 // An object requires a tracing method if it has any fields that need tracing
 // or if it inherits from multiple bases that need tracing.
 bool RecordInfo::RequiresTraceMethod() {
   if (IsStackAllocated())
     return false;
   unsigned bases_with_trace = 0;
   for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
     if (it->second.NeedsTracing().IsNeeded())
       ++bases_with_trace;
   }
   if (bases_with_trace > 1)
     return true;
   GetFields();
   return fields_need_tracing_.IsNeeded();
 }

 // Get the actual tracing method (ie, can be traceAfterDispatch if there is a
 // dispatch method).
 CXXMethodDecl* RecordInfo::GetTraceMethod() {
   DetermineTracingMethods();
   return trace_method_;
 }

 // Get the static trace dispatch method.
 CXXMethodDecl* RecordInfo::GetTraceDispatchMethod() {
   DetermineTracingMethods();
   return trace_dispatch_method_;
 }

 CXXMethodDecl* RecordInfo::GetFinalizeDispatchMethod() {
   DetermineTracingMethods();
   return finalize_dispatch_method_;
 }

 RecordInfo::Bases& RecordInfo::GetBases() {
   if (!bases_)
     bases_ = CollectBases();
   return *bases_;
 }

 bool RecordInfo::InheritsTrace() {
   if (GetTraceMethod())
     return true;
   for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
     if (it->second.info()->InheritsTrace())
       return true;
   }
   return false;
 }

 CXXMethodDecl* RecordInfo::InheritsNonVirtualTrace() {
   if (CXXMethodDecl* trace = GetTraceMethod())
     return trace->isVirtual() ? 0 : trace;
   for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
     if (CXXMethodDecl* trace = it->second.info()->InheritsNonVirtualTrace())
       return trace;
   }
   return 0;
 }

 bool RecordInfo::DeclaresGCMixinMethods() {
   DetermineTracingMethods();
   return has_gc_mixin_methods_;
 }

 bool RecordInfo::DeclaresLocalTraceMethod() {
   if (is_declaring_local_trace_ != kNotComputed)
     return is_declaring_local_trace_;
   DetermineTracingMethods();
   is_declaring_local_trace_ = trace_method_ ? kTrue : kFalse;
   if (is_declaring_local_trace_) {
     for (auto it = record_->method_begin();
          it != record_->method_end(); ++it) {
       if (*it == trace_method_) {
         is_declaring_local_trace_ = kTrue;
         break;
       }
     }
   }
   return is_declaring_local_trace_;
 }

 bool RecordInfo::IsGCMixinInstance() {
   assert(IsGCDerived());
   if (record_->isAbstract())
     return false;

   assert(!IsGCMixin());

   // true iff the class derives from GCMixin and
   // one or more other GC base classes.
   bool seen_gc_mixin = false;
   bool seen_gc_derived = false;
   for (const auto& gc_base : gc_base_names_) {
     if (Config::IsGCMixinBase(gc_base))
       seen_gc_mixin = true;
     else if (Config::IsGCBase(gc_base))
       seen_gc_derived = true;
   }
   return seen_gc_derived && seen_gc_mixin;
 }

 // A (non-virtual) class is considered abstract in Blink if it has
 // no public constructors and no create methods.
 bool RecordInfo::IsConsideredAbstract() {
   for (CXXRecordDecl::ctor_iterator it = record_->ctor_begin();
        it != record_->ctor_end();
        ++it) {
     if (!it->isCopyOrMoveConstructor() && it->getAccess() == AS_public)
       return false;
   }
   for (CXXRecordDecl::method_iterator it = record_->method_begin();
        it != record_->method_end();
        ++it) {
     if (it->getNameAsString() == kCreateName)
       return false;
   }
   return true;
 }

 RecordInfo::Bases* RecordInfo::CollectBases() {
   // Compute the collection locally to avoid inconsistent states.
   Bases* bases = new Bases;
   if (!record_->hasDefinition())
     return bases;
   for (CXXRecordDecl::base_class_iterator it = record_->bases_begin();
        it != record_->bases_end();
        ++it) {
     const CXXBaseSpecifier& spec = *it;
     RecordInfo* info = cache_->Lookup(spec.getType());
     if (!info)
       continue;
     CXXRecordDecl* base = info->record();
     TracingStatus status = info->InheritsTrace()
                                ? TracingStatus::Needed()
                                : TracingStatus::Unneeded();
     bases->insert(std::make_pair(base, BasePoint(spec, info, status)));
   }
   return bases;
 }

 RecordInfo::Fields& RecordInfo::GetFields() {
   if (!fields_)
     fields_ = CollectFields();
   return *fields_;
 }

 RecordInfo::Fields* RecordInfo::CollectFields() {
   // Compute the collection locally to avoid inconsistent states.
   Fields* fields = new Fields;
   if (!record_->hasDefinition())
     return fields;
   TracingStatus fields_status = TracingStatus::Unneeded();
   for (RecordDecl::field_iterator it = record_->field_begin();
        it != record_->field_end();
        ++it) {
     FieldDecl* field = *it;
     // Ignore fields annotated with the GC_PLUGIN_IGNORE macro.
     if (Config::IsIgnoreAnnotated(field))
       continue;
     if (Edge* edge = CreateEdge(field->getType().getTypePtrOrNull())) {
       fields_status = fields_status.LUB(edge->NeedsTracing(Edge::kRecursive));
       fields->insert(std::make_pair(field, FieldPoint(field, edge)));
     }
   }
   fields_need_tracing_ = fields_status;
   return fields;
 }

 void RecordInfo::DetermineTracingMethods() {
   if (determined_trace_methods_)
     return;
   determined_trace_methods_ = true;
   if (Config::IsGCBase(name_))
     return;
   CXXMethodDecl* trace = nullptr;
   CXXMethodDecl* trace_impl = nullptr;
   CXXMethodDecl* trace_after_dispatch = nullptr;
   bool has_adjust_and_mark = false;
   bool has_is_heap_object_alive = false;
   for (Decl* decl : record_->decls()) {
     CXXMethodDecl* method = dyn_cast<CXXMethodDecl>(decl);
     if (!method) {
       if (FunctionTemplateDecl* func_template =
           dyn_cast<FunctionTemplateDecl>(decl))
         method = dyn_cast<CXXMethodDecl>(func_template->getTemplatedDecl());
     }
     if (!method)
       continue;

     switch (Config::GetTraceMethodType(method)) {
       case Config::TRACE_METHOD:
         trace = method;
         break;
       case Config::TRACE_AFTER_DISPATCH_METHOD:
         trace_after_dispatch = method;
         break;
       case Config::TRACE_IMPL_METHOD:
         trace_impl = method;
         break;
       case Config::TRACE_AFTER_DISPATCH_IMPL_METHOD:
         break;
       case Config::NOT_TRACE_METHOD:
         if (method->getNameAsString() == kFinalizeName) {
           finalize_dispatch_method_ = method;
         } else if (method->getNameAsString() == kAdjustAndMarkName) {
           has_adjust_and_mark = true;
         } else if (method->getNameAsString() == kIsHeapObjectAliveName) {
           has_is_heap_object_alive = true;
         }
         break;
     }
   }

   // Record if class defines the two GCMixin methods.
   has_gc_mixin_methods_ =
       has_adjust_and_mark && has_is_heap_object_alive ? kTrue : kFalse;
   if (trace_after_dispatch) {
     trace_method_ = trace_after_dispatch;
     trace_dispatch_method_ = trace_impl ? trace_impl : trace;
   } else {
     // TODO: Can we never have a dispatch method called trace without the same
     // class defining a traceAfterDispatch method?
     trace_method_ = trace;
     trace_dispatch_method_ = nullptr;
   }
   if (trace_dispatch_method_ && finalize_dispatch_method_)
     return;
   // If this class does not define dispatching methods inherit them.
   for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
     // TODO: Does it make sense to inherit multiple dispatch methods?
     if (CXXMethodDecl* dispatch = it->second.info()->GetTraceDispatchMethod()) {
       assert(!trace_dispatch_method_ && "Multiple trace dispatching methods");
       trace_dispatch_method_ = dispatch;
     }
     if (CXXMethodDecl* dispatch =
             it->second.info()->GetFinalizeDispatchMethod()) {
       assert(!finalize_dispatch_method_ &&
              "Multiple finalize dispatching methods");
       finalize_dispatch_method_ = dispatch;
     }
   }
 }

 // TODO: Add classes with a finalize() method that specialize FinalizerTrait.
 bool RecordInfo::NeedsFinalization() {
   if (does_need_finalization_ == kNotComputed) {
     // Rely on hasNonTrivialDestructor(), but if the only
     // identifiable reason for it being true is the presence
     // of a safely ignorable class as a direct base,
     // or we're processing such an 'ignorable' class, then it does
     // not need finalization.
     does_need_finalization_ =
         record_->hasNonTrivialDestructor() ? kTrue : kFalse;
     if (!does_need_finalization_)
       return does_need_finalization_;

     // Processing a class with a safely-ignorable destructor.
     NamespaceDecl* ns =
         dyn_cast<NamespaceDecl>(record_->getDeclContext());
     if (ns && Config::HasIgnorableDestructor(ns->getName(), name_)) {
       does_need_finalization_ = kFalse;
       return does_need_finalization_;
     }

     CXXDestructorDecl* dtor = record_->getDestructor();
     if (dtor && dtor->isUserProvided())
       return does_need_finalization_;
     for (Fields::iterator it = GetFields().begin();
          it != GetFields().end();
          ++it) {
       if (it->second.edge()->NeedsFinalization())
         return does_need_finalization_;
     }

     for (Bases::iterator it = GetBases().begin();
          it != GetBases().end();
          ++it) {
       if (it->second.info()->NeedsFinalization())
         return does_need_finalization_;
     }
     // Destructor was non-trivial due to bases with destructors that
     // can be safely ignored. Hence, no need for finalization.
     does_need_finalization_ = kFalse;
   }
   return does_need_finalization_;
 }

 // A class needs tracing if:
 // - it is allocated on the managed heap,
 // - it is derived from a class that needs tracing, or
 // - it contains fields that need tracing.
 // TODO: Defining NeedsTracing based on whether a class defines a trace method
 // (of the proper signature) over approximates too much. The use of transition
 // types causes some classes to have trace methods without them needing to be
 // traced.
 TracingStatus RecordInfo::NeedsTracing(Edge::NeedsTracingOption option) {
   if (IsGCAllocated())
     return TracingStatus::Needed();

   if (IsStackAllocated())
     return TracingStatus::Unneeded();

   for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
     if (it->second.info()->NeedsTracing(option).IsNeeded())
       return TracingStatus::Needed();
   }

   if (option == Edge::kRecursive)
     GetFields();

   return fields_need_tracing_;
 }

 Edge* RecordInfo::CreateEdge(const Type* type) {
   if (!type) {
     return 0;
   }

   if (type->isPointerType()) {
     if (Edge* ptr = CreateEdge(type->getPointeeType().getTypePtrOrNull()))
       return new RawPtr(ptr, false);
     return 0;
   }

   RecordInfo* info = cache_->Lookup(type);

   // If the type is neither a pointer or a C++ record we ignore it.
   if (!info) {
     return 0;
   }

   TemplateArgs args;

   if (Config::IsRawPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
     if (Edge* ptr = CreateEdge(args[0]))
       return new RawPtr(ptr, true);
     return 0;
   }

   if (Config::IsRefPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
     if (Edge* ptr = CreateEdge(args[0]))
       return new RefPtr(ptr);
     return 0;
   }

   if (Config::IsOwnPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
     if (Edge* ptr = CreateEdge(args[0]))
       return new OwnPtr(ptr);
     return 0;
   }

   if (Config::IsMember(info->name()) && info->GetTemplateArgs(1, &args)) {
     if (Edge* ptr = CreateEdge(args[0]))
       return new Member(ptr);
     return 0;
   }

   if (Config::IsWeakMember(info->name()) && info->GetTemplateArgs(1, &args)) {
     if (Edge* ptr = CreateEdge(args[0]))
       return new WeakMember(ptr);
     return 0;
   }

   if (Config::IsPersistent(info->name())) {
     // Persistent might refer to v8::Persistent, so check the name space.
     // TODO: Consider using a more canonical identification than names.
     NamespaceDecl* ns =
         dyn_cast<NamespaceDecl>(info->record()->getDeclContext());
     if (!ns || ns->getName() != "blink")
       return 0;
     if (!info->GetTemplateArgs(1, &args))
       return 0;
     if (Edge* ptr = CreateEdge(args[0]))
       return new Persistent(ptr);
     return 0;
   }

   if (Config::IsGCCollection(info->name()) ||
       Config::IsWTFCollection(info->name())) {
     bool is_root = Config::IsPersistentGCCollection(info->name());
     bool on_heap = is_root || info->IsHeapAllocatedCollection();
     size_t count = Config::CollectionDimension(info->name());
     if (!info->GetTemplateArgs(count, &args))
       return 0;
     Collection* edge = new Collection(info, on_heap, is_root);
     for (TemplateArgs::iterator it = args.begin(); it != args.end(); ++it) {
       if (Edge* member = CreateEdge(*it)) {
         edge->members().push_back(member);
       }
       // TODO: Handle the case where we fail to create an edge (eg, if the
       // argument is a primitive type or just not fully known yet).
     }
     return edge;
   }

   return new Value(info);
 }
	// Copyright 2014 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 "Config.h"
	#include "RecordInfo.h"

	using namespace clang;
	using std::string;

	RecordInfo::RecordInfo(CXXRecordDecl* record, RecordCache* cache)
	: cache_(cache),
	record_(record),
	name_(record->getName()),
	fields_need_tracing_(TracingStatus::Unknown()),
	bases_(0),
	fields_(0),
	is_stack_allocated_(kNotComputed),
	is_non_newable_(kNotComputed),
	is_only_placement_newable_(kNotComputed),
	does_need_finalization_(kNotComputed),
	has_gc_mixin_methods_(kNotComputed),
	is_declaring_local_trace_(kNotComputed),
	is_eagerly_finalized_(kNotComputed),
	determined_trace_methods_(false),
	trace_method_(0),
	trace_dispatch_method_(0),
	finalize_dispatch_method_(0),
	is_gc_derived_(false) {}

	RecordInfo::~RecordInfo() {
	delete fields_;
	delete bases_;
	}

	// Get \|count\| number of template arguments. Returns false if there
	// are fewer than \|count\| arguments or any of the arguments are not
	// of a valid Type structure. If \|count\| is non-positive, all
	// arguments are collected.
	bool RecordInfo::GetTemplateArgs(size_t count, TemplateArgs* output_args) {
	ClassTemplateSpecializationDecl* tmpl =
	dyn_cast<ClassTemplateSpecializationDecl>(record_);
	if (!tmpl)
	return false;
	const TemplateArgumentList& args = tmpl->getTemplateArgs();
	if (args.size() < count)
	return false;
	if (count <= 0)
	count = args.size();
	for (unsigned i = 0; i < count; ++i) {
	TemplateArgument arg = args[i];
	if (arg.getKind() == TemplateArgument::Type && !arg.getAsType().isNull()) {
	output_args->push_back(arg.getAsType().getTypePtr());
	} else {
	return false;
	}
	}
	return true;
	}

	// Test if a record is a HeapAllocated collection.
	bool RecordInfo::IsHeapAllocatedCollection() {
	if (!Config::IsGCCollection(name_) && !Config::IsWTFCollection(name_))
	return false;

	TemplateArgs args;
	if (GetTemplateArgs(0, &args)) {
	for (TemplateArgs::iterator it = args.begin(); it != args.end(); ++it) {
	if (CXXRecordDecl* decl = (*it)->getAsCXXRecordDecl())
	if (decl->getName() == kHeapAllocatorName)
	return true;
	}
	}

	return Config::IsGCCollection(name_);
	}

	// Test if a record is derived from a garbage collected base.
	bool RecordInfo::IsGCDerived() {
	// If already computed, return the known result.
	if (gc_base_names_.size())
	return is_gc_derived_;

	if (!record_->hasDefinition())
	return false;

	// The base classes are not themselves considered garbage collected objects.
	if (Config::IsGCBase(name_))
	return false;

	// Walk the inheritance tree to find GC base classes.
	walkBases();
	return is_gc_derived_;
	}

	CXXRecordDecl* RecordInfo::GetDependentTemplatedDecl(const Type& type) {
	const TemplateSpecializationType* tmpl_type =
	type.getAs<TemplateSpecializationType>();
	if (!tmpl_type)
	return 0;

	TemplateDecl* tmpl_decl = tmpl_type->getTemplateName().getAsTemplateDecl();
	if (!tmpl_decl)
	return 0;

	return dyn_cast_or_null<CXXRecordDecl>(tmpl_decl->getTemplatedDecl());
	}

	void RecordInfo::walkBases() {
	// This traversal is akin to CXXRecordDecl::forallBases()'s,
	// but without stepping over dependent bases -- these might also
	// have a "GC base name", so are to be included and considered.
	SmallVector<const CXXRecordDecl*, 8> queue;

	const CXXRecordDecl *base_record = record();
	while (true) {
	for (const auto& it : base_record->bases()) {
	const RecordType *type = it.getType()->getAs<RecordType>();
	CXXRecordDecl* base;
	if (!type)
	base = GetDependentTemplatedDecl(*it.getType());
	else {
	base = cast_or_null<CXXRecordDecl>(type->getDecl()->getDefinition());
	if (base)
	queue.push_back(base);
	}
	if (!base)
	continue;

	const std::string& name = base->getName();
	if (Config::IsGCBase(name)) {
	gc_base_names_.push_back(name);
	is_gc_derived_ = true;
	}
	}

	if (queue.empty())
	break;
	base_record = queue.pop_back_val(); // not actually a queue.
	}
	}

	bool RecordInfo::IsGCFinalized() {
	if (!IsGCDerived())
	return false;
	for (const auto& gc_base : gc_base_names_) {
	if (Config::IsGCFinalizedBase(gc_base))
	return true;
	}
	return false;
	}

	// A GC mixin is a class that inherits from a GC mixin base and has
	// not yet been "mixed in" with another GC base class.
	bool RecordInfo::IsGCMixin() {
	if (!IsGCDerived() \|\| !gc_base_names_.size())
	return false;
	for (const auto& gc_base : gc_base_names_) {
	// If it is not a mixin base we are done.
	if (!Config::IsGCMixinBase(gc_base))
	return false;
	}
	// This is a mixin if all GC bases are mixins.
	return true;
	}

	// Test if a record is allocated on the managed heap.
	bool RecordInfo::IsGCAllocated() {
	return IsGCDerived() \|\| IsHeapAllocatedCollection();
	}

	bool RecordInfo::IsEagerlyFinalized() {
	if (is_eagerly_finalized_ == kNotComputed) {
	is_eagerly_finalized_ = kFalse;
	if (IsGCFinalized()) {
	for (Decl* decl : record_->decls()) {
	if (TypedefDecl* typedef_decl = dyn_cast<TypedefDecl>(decl)) {
	if (typedef_decl->getNameAsString() == kIsEagerlyFinalizedName) {
	is_eagerly_finalized_ = kTrue;
	break;
	}
	}
	}
	}
	}
	return is_eagerly_finalized_;
	}

	bool RecordInfo::HasDefinition() {
	return record_->hasDefinition();
	}

	RecordInfo* RecordCache::Lookup(CXXRecordDecl* record) {
	// Ignore classes annotated with the GC_PLUGIN_IGNORE macro.
	if (!record \|\| Config::IsIgnoreAnnotated(record))
	return 0;
	Cache::iterator it = cache_.find(record);
	if (it != cache_.end())
	return &it->second;
	return &cache_.insert(std::make_pair(record, RecordInfo(record, this)))
	.first->second;
	}

	bool RecordInfo::IsStackAllocated() {
	if (is_stack_allocated_ == kNotComputed) {
	is_stack_allocated_ = kFalse;
	for (Bases::iterator it = GetBases().begin();
	it != GetBases().end();
	++it) {
	if (it->second.info()->IsStackAllocated()) {
	is_stack_allocated_ = kTrue;
	return is_stack_allocated_;
	}
	}
	for (CXXRecordDecl::method_iterator it = record_->method_begin();
	it != record_->method_end();
	++it) {
	if (it->getNameAsString() == kNewOperatorName &&
	it->isDeleted() &&
	Config::IsStackAnnotated(*it)) {
	is_stack_allocated_ = kTrue;
	return is_stack_allocated_;
	}
	}
	}
	return is_stack_allocated_;
	}

	bool RecordInfo::IsNonNewable() {
	if (is_non_newable_ == kNotComputed) {
	bool deleted = false;
	bool all_deleted = true;
	for (CXXRecordDecl::method_iterator it = record_->method_begin();
	it != record_->method_end();
	++it) {
	if (it->getNameAsString() == kNewOperatorName) {
	deleted = it->isDeleted();
	all_deleted = all_deleted && deleted;
	}
	}
	is_non_newable_ = (deleted && all_deleted) ? kTrue : kFalse;
	}
	return is_non_newable_;
	}

	bool RecordInfo::IsOnlyPlacementNewable() {
	if (is_only_placement_newable_ == kNotComputed) {
	bool placement = false;
	bool new_deleted = false;
	for (CXXRecordDecl::method_iterator it = record_->method_begin();
	it != record_->method_end();
	++it) {
	if (it->getNameAsString() == kNewOperatorName) {
	if (it->getNumParams() == 1) {
	new_deleted = it->isDeleted();
	} else if (it->getNumParams() == 2) {
	placement = !it->isDeleted();
	}
	}
	}
	is_only_placement_newable_ = (placement && new_deleted) ? kTrue : kFalse;
	}
	return is_only_placement_newable_;
	}

	CXXMethodDecl* RecordInfo::DeclaresNewOperator() {
	for (CXXRecordDecl::method_iterator it = record_->method_begin();
	it != record_->method_end();
	++it) {
	if (it->getNameAsString() == kNewOperatorName && it->getNumParams() == 1)
	return *it;
	}
	return 0;
	}

	// An object requires a tracing method if it has any fields that need tracing
	// or if it inherits from multiple bases that need tracing.
	bool RecordInfo::RequiresTraceMethod() {
	if (IsStackAllocated())
	return false;
	unsigned bases_with_trace = 0;
	for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
	if (it->second.NeedsTracing().IsNeeded())
	++bases_with_trace;
	}
	if (bases_with_trace > 1)
	return true;
	GetFields();
	return fields_need_tracing_.IsNeeded();
	}

	// Get the actual tracing method (ie, can be traceAfterDispatch if there is a
	// dispatch method).
	CXXMethodDecl* RecordInfo::GetTraceMethod() {
	DetermineTracingMethods();
	return trace_method_;
	}

	// Get the static trace dispatch method.
	CXXMethodDecl* RecordInfo::GetTraceDispatchMethod() {
	DetermineTracingMethods();
	return trace_dispatch_method_;
	}

	CXXMethodDecl* RecordInfo::GetFinalizeDispatchMethod() {
	DetermineTracingMethods();
	return finalize_dispatch_method_;
	}

	RecordInfo::Bases& RecordInfo::GetBases() {
	if (!bases_)
	bases_ = CollectBases();
	return *bases_;
	}

	bool RecordInfo::InheritsTrace() {
	if (GetTraceMethod())
	return true;
	for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
	if (it->second.info()->InheritsTrace())
	return true;
	}
	return false;
	}

	CXXMethodDecl* RecordInfo::InheritsNonVirtualTrace() {
	if (CXXMethodDecl* trace = GetTraceMethod())
	return trace->isVirtual() ? 0 : trace;
	for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
	if (CXXMethodDecl* trace = it->second.info()->InheritsNonVirtualTrace())
	return trace;
	}
	return 0;
	}

	bool RecordInfo::DeclaresGCMixinMethods() {
	DetermineTracingMethods();
	return has_gc_mixin_methods_;
	}

	bool RecordInfo::DeclaresLocalTraceMethod() {
	if (is_declaring_local_trace_ != kNotComputed)
	return is_declaring_local_trace_;
	DetermineTracingMethods();
	is_declaring_local_trace_ = trace_method_ ? kTrue : kFalse;
	if (is_declaring_local_trace_) {
	for (auto it = record_->method_begin();
	it != record_->method_end(); ++it) {
	if (*it == trace_method_) {
	is_declaring_local_trace_ = kTrue;
	break;
	}
	}
	}
	return is_declaring_local_trace_;
	}

	bool RecordInfo::IsGCMixinInstance() {
	assert(IsGCDerived());
	if (record_->isAbstract())
	return false;

	assert(!IsGCMixin());

	// true iff the class derives from GCMixin and
	// one or more other GC base classes.
	bool seen_gc_mixin = false;
	bool seen_gc_derived = false;
	for (const auto& gc_base : gc_base_names_) {
	if (Config::IsGCMixinBase(gc_base))
	seen_gc_mixin = true;
	else if (Config::IsGCBase(gc_base))
	seen_gc_derived = true;
	}
	return seen_gc_derived && seen_gc_mixin;
	}

	// A (non-virtual) class is considered abstract in Blink if it has
	// no public constructors and no create methods.
	bool RecordInfo::IsConsideredAbstract() {
	for (CXXRecordDecl::ctor_iterator it = record_->ctor_begin();
	it != record_->ctor_end();
	++it) {
	if (!it->isCopyOrMoveConstructor() && it->getAccess() == AS_public)
	return false;
	}
	for (CXXRecordDecl::method_iterator it = record_->method_begin();
	it != record_->method_end();
	++it) {
	if (it->getNameAsString() == kCreateName)
	return false;
	}
	return true;
	}

	RecordInfo::Bases* RecordInfo::CollectBases() {
	// Compute the collection locally to avoid inconsistent states.
	Bases* bases = new Bases;
	if (!record_->hasDefinition())
	return bases;
	for (CXXRecordDecl::base_class_iterator it = record_->bases_begin();
	it != record_->bases_end();
	++it) {
	const CXXBaseSpecifier& spec = *it;
	RecordInfo* info = cache_->Lookup(spec.getType());
	if (!info)
	continue;
	CXXRecordDecl* base = info->record();
	TracingStatus status = info->InheritsTrace()
	? TracingStatus::Needed()
	: TracingStatus::Unneeded();
	bases->insert(std::make_pair(base, BasePoint(spec, info, status)));
	}
	return bases;
	}

	RecordInfo::Fields& RecordInfo::GetFields() {
	if (!fields_)
	fields_ = CollectFields();
	return *fields_;
	}

	RecordInfo::Fields* RecordInfo::CollectFields() {
	// Compute the collection locally to avoid inconsistent states.
	Fields* fields = new Fields;
	if (!record_->hasDefinition())
	return fields;
	TracingStatus fields_status = TracingStatus::Unneeded();
	for (RecordDecl::field_iterator it = record_->field_begin();
	it != record_->field_end();
	++it) {
	FieldDecl* field = *it;
	// Ignore fields annotated with the GC_PLUGIN_IGNORE macro.
	if (Config::IsIgnoreAnnotated(field))
	continue;
	if (Edge* edge = CreateEdge(field->getType().getTypePtrOrNull())) {
	fields_status = fields_status.LUB(edge->NeedsTracing(Edge::kRecursive));
	fields->insert(std::make_pair(field, FieldPoint(field, edge)));
	}
	}
	fields_need_tracing_ = fields_status;
	return fields;
	}

	void RecordInfo::DetermineTracingMethods() {
	if (determined_trace_methods_)
	return;
	determined_trace_methods_ = true;
	if (Config::IsGCBase(name_))
	return;
	CXXMethodDecl* trace = nullptr;
	CXXMethodDecl* trace_impl = nullptr;
	CXXMethodDecl* trace_after_dispatch = nullptr;
	bool has_adjust_and_mark = false;
	bool has_is_heap_object_alive = false;
	for (Decl* decl : record_->decls()) {
	CXXMethodDecl* method = dyn_cast<CXXMethodDecl>(decl);
	if (!method) {
	if (FunctionTemplateDecl* func_template =
	dyn_cast<FunctionTemplateDecl>(decl))
	method = dyn_cast<CXXMethodDecl>(func_template->getTemplatedDecl());
	}
	if (!method)
	continue;

	switch (Config::GetTraceMethodType(method)) {
	case Config::TRACE_METHOD:
	trace = method;
	break;
	case Config::TRACE_AFTER_DISPATCH_METHOD:
	trace_after_dispatch = method;
	break;
	case Config::TRACE_IMPL_METHOD:
	trace_impl = method;
	break;
	case Config::TRACE_AFTER_DISPATCH_IMPL_METHOD:
	break;
	case Config::NOT_TRACE_METHOD:
	if (method->getNameAsString() == kFinalizeName) {
	finalize_dispatch_method_ = method;
	} else if (method->getNameAsString() == kAdjustAndMarkName) {
	has_adjust_and_mark = true;
	} else if (method->getNameAsString() == kIsHeapObjectAliveName) {
	has_is_heap_object_alive = true;
	}
	break;
	}
	}

	// Record if class defines the two GCMixin methods.
	has_gc_mixin_methods_ =
	has_adjust_and_mark && has_is_heap_object_alive ? kTrue : kFalse;
	if (trace_after_dispatch) {
	trace_method_ = trace_after_dispatch;
	trace_dispatch_method_ = trace_impl ? trace_impl : trace;
	} else {
	// TODO: Can we never have a dispatch method called trace without the same
	// class defining a traceAfterDispatch method?
	trace_method_ = trace;
	trace_dispatch_method_ = nullptr;
	}
	if (trace_dispatch_method_ && finalize_dispatch_method_)
	return;
	// If this class does not define dispatching methods inherit them.
	for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
	// TODO: Does it make sense to inherit multiple dispatch methods?
	if (CXXMethodDecl* dispatch = it->second.info()->GetTraceDispatchMethod()) {
	assert(!trace_dispatch_method_ && "Multiple trace dispatching methods");
	trace_dispatch_method_ = dispatch;
	}
	if (CXXMethodDecl* dispatch =
	it->second.info()->GetFinalizeDispatchMethod()) {
	assert(!finalize_dispatch_method_ &&
	"Multiple finalize dispatching methods");
	finalize_dispatch_method_ = dispatch;
	}
	}
	}

	// TODO: Add classes with a finalize() method that specialize FinalizerTrait.
	bool RecordInfo::NeedsFinalization() {
	if (does_need_finalization_ == kNotComputed) {
	// Rely on hasNonTrivialDestructor(), but if the only
	// identifiable reason for it being true is the presence
	// of a safely ignorable class as a direct base,
	// or we're processing such an 'ignorable' class, then it does
	// not need finalization.
	does_need_finalization_ =
	record_->hasNonTrivialDestructor() ? kTrue : kFalse;
	if (!does_need_finalization_)
	return does_need_finalization_;

	// Processing a class with a safely-ignorable destructor.
	NamespaceDecl* ns =
	dyn_cast<NamespaceDecl>(record_->getDeclContext());
	if (ns && Config::HasIgnorableDestructor(ns->getName(), name_)) {
	does_need_finalization_ = kFalse;
	return does_need_finalization_;
	}

	CXXDestructorDecl* dtor = record_->getDestructor();
	if (dtor && dtor->isUserProvided())
	return does_need_finalization_;
	for (Fields::iterator it = GetFields().begin();
	it != GetFields().end();
	++it) {
	if (it->second.edge()->NeedsFinalization())
	return does_need_finalization_;
	}

	for (Bases::iterator it = GetBases().begin();
	it != GetBases().end();
	++it) {
	if (it->second.info()->NeedsFinalization())
	return does_need_finalization_;
	}
	// Destructor was non-trivial due to bases with destructors that
	// can be safely ignored. Hence, no need for finalization.
	does_need_finalization_ = kFalse;
	}
	return does_need_finalization_;
	}

	// A class needs tracing if:
	// - it is allocated on the managed heap,
	// - it is derived from a class that needs tracing, or
	// - it contains fields that need tracing.
	// TODO: Defining NeedsTracing based on whether a class defines a trace method
	// (of the proper signature) over approximates too much. The use of transition
	// types causes some classes to have trace methods without them needing to be
	// traced.
	TracingStatus RecordInfo::NeedsTracing(Edge::NeedsTracingOption option) {
	if (IsGCAllocated())
	return TracingStatus::Needed();

	if (IsStackAllocated())
	return TracingStatus::Unneeded();

	for (Bases::iterator it = GetBases().begin(); it != GetBases().end(); ++it) {
	if (it->second.info()->NeedsTracing(option).IsNeeded())
	return TracingStatus::Needed();
	}

	if (option == Edge::kRecursive)
	GetFields();

	return fields_need_tracing_;
	}

	Edge* RecordInfo::CreateEdge(const Type* type) {
	if (!type) {
	return 0;
	}

	if (type->isPointerType()) {
	if (Edge* ptr = CreateEdge(type->getPointeeType().getTypePtrOrNull()))
	return new RawPtr(ptr, false);
	return 0;
	}

	RecordInfo* info = cache_->Lookup(type);

	// If the type is neither a pointer or a C++ record we ignore it.
	if (!info) {
	return 0;
	}

	TemplateArgs args;

	if (Config::IsRawPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
	if (Edge* ptr = CreateEdge(args[0]))
	return new RawPtr(ptr, true);
	return 0;
	}

	if (Config::IsRefPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
	if (Edge* ptr = CreateEdge(args[0]))
	return new RefPtr(ptr);
	return 0;
	}

	if (Config::IsOwnPtr(info->name()) && info->GetTemplateArgs(1, &args)) {
	if (Edge* ptr = CreateEdge(args[0]))
	return new OwnPtr(ptr);
	return 0;
	}

	if (Config::IsMember(info->name()) && info->GetTemplateArgs(1, &args)) {
	if (Edge* ptr = CreateEdge(args[0]))
	return new Member(ptr);
	return 0;
	}

	if (Config::IsWeakMember(info->name()) && info->GetTemplateArgs(1, &args)) {
	if (Edge* ptr = CreateEdge(args[0]))
	return new WeakMember(ptr);
	return 0;
	}

	if (Config::IsPersistent(info->name())) {
	// Persistent might refer to v8::Persistent, so check the name space.
	// TODO: Consider using a more canonical identification than names.
	NamespaceDecl* ns =
	dyn_cast<NamespaceDecl>(info->record()->getDeclContext());
	if (!ns \|\| ns->getName() != "blink")
	return 0;
	if (!info->GetTemplateArgs(1, &args))
	return 0;
	if (Edge* ptr = CreateEdge(args[0]))
	return new Persistent(ptr);
	return 0;
	}

	if (Config::IsGCCollection(info->name()) \|\|
	Config::IsWTFCollection(info->name())) {
	bool is_root = Config::IsPersistentGCCollection(info->name());
	bool on_heap = is_root \|\| info->IsHeapAllocatedCollection();
	size_t count = Config::CollectionDimension(info->name());
	if (!info->GetTemplateArgs(count, &args))
	return 0;
	Collection* edge = new Collection(info, on_heap, is_root);
	for (TemplateArgs::iterator it = args.begin(); it != args.end(); ++it) {
	if (Edge* member = CreateEdge(*it)) {
	edge->members().push_back(member);
	}
	// TODO: Handle the case where we fail to create an edge (eg, if the
	// argument is a primitive type or just not fully known yet).
	}
	return edge;
	}

	return new Value(info);
	}