runtime/vm/class_table.cc - sdk - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/class_table.h"

 #include <memory>

 #include "platform/atomic.h"
 #include "vm/flags.h"
 #include "vm/growable_array.h"
 #include "vm/heap/heap.h"
 #include "vm/object.h"
 #include "vm/object_graph.h"
 #include "vm/raw_object.h"
 #include "vm/visitor.h"

 namespace dart {

 DEFINE_FLAG(bool, print_class_table, false, "Print initial class table.");

 ClassTable::ClassTable(ClassTableAllocator* allocator)
     : allocator_(allocator),
       classes_(allocator),
       top_level_classes_(allocator) {
   if (Dart::vm_isolate() == nullptr) {
     classes_.SetNumCidsAndCapacity(kNumPredefinedCids, kInitialCapacity);
   } else {
     // Duplicate the class table from the VM isolate.
     ClassTable* vm_class_table = Dart::vm_isolate_group()->class_table();
     classes_.SetNumCidsAndCapacity(kNumPredefinedCids,
                                    vm_class_table->classes_.capacity());

     const auto copy_info_for_cid = [&](intptr_t cid) {
       classes_.At<kClassIndex>(cid) = vm_class_table->At(cid);
       classes_.At<kSizeIndex>(cid) = vm_class_table->SizeAt(cid);
     };

     // The following cids don't have a corresponding class object in Dart code.
     // We therefore need to initialize them eagerly.
     COMPILE_ASSERT(kFirstInternalOnlyCid == kObjectCid + 1);
     for (intptr_t i = kObjectCid; i <= kLastInternalOnlyCid; i++) {
       copy_info_for_cid(i);
     }
     copy_info_for_cid(kTypeArgumentsCid);
     copy_info_for_cid(kFreeListElement);
     copy_info_for_cid(kForwardingCorpse);
     copy_info_for_cid(kDynamicCid);
     copy_info_for_cid(kVoidCid);
   }
   UpdateCachedAllocationTracingStateTablePointer();
 }

 ClassTable::~ClassTable() {
 #if !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
   for (intptr_t i = 1; i < classes_.num_cids(); i++) {
     const char* name = UserVisibleNameFor(i);
     if (name != nullptr) {
       free(const_cast<char*>(name));
     }
   }
 #endif  // !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
 }

 void ClassTable::Register(const Class& cls) {
   ASSERT(Thread::Current()->IsDartMutatorThread());
   ASSERT(cls.id() == kIllegalCid || cls.id() < kNumPredefinedCids);
   bool did_grow = false;
   const classid_t cid =
       cls.id() != kIllegalCid ? cls.id() : classes_.AddRow(&did_grow);
   ASSERT(!IsTopLevelCid(cid));

   const intptr_t instance_size =
       cls.is_abstract() ? 0 : Class::host_instance_size(cls.ptr());

   cls.set_id(cid);
   classes_.At<kClassIndex>(cid) = cls.ptr();
   classes_.At<kSizeIndex>(cid) = static_cast<int32_t>(instance_size);
 #if !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
   classes_.At<kClassNameIndex>(cid) = nullptr;
 #endif  // !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)

   if (did_grow) {
     IsolateGroup::Current()->set_cached_class_table_table(
         classes_.GetColumn<kClassIndex>());
     UpdateCachedAllocationTracingStateTablePointer();
   } else {
     std::atomic_thread_fence(std::memory_order_release);
   }
 }

 void ClassTable::RegisterTopLevel(const Class& cls) {
   ASSERT(Thread::Current()->IsDartMutatorThread());
   ASSERT(cls.id() == kIllegalCid);

   bool did_grow = false;
   const intptr_t index = top_level_classes_.AddRow(&did_grow);
   cls.set_id(ClassTable::CidFromTopLevelIndex(index));
   top_level_classes_.At<kClassIndex>(index) = cls.ptr();
 }

 void ClassTable::AllocateIndex(intptr_t index) {
   bool did_grow = false;
   if (IsTopLevelCid(index)) {
     top_level_classes_.AllocateIndex(IndexFromTopLevelCid(index), &did_grow);
     return;
   }

   classes_.AllocateIndex(index, &did_grow);
   if (did_grow) {
     IsolateGroup::Current()->set_cached_class_table_table(table());
     UpdateCachedAllocationTracingStateTablePointer();
   }
 }

 void ClassTable::UnregisterTopLevel(intptr_t cid) {
   ASSERT(IsTopLevelCid(cid));
   const intptr_t tlc_index = IndexFromTopLevelCid(cid);
   top_level_classes_.At<kClassIndex>(tlc_index) = nullptr;
 }

 void ClassTable::Remap(intptr_t* old_to_new_cid) {
   ASSERT(Thread::Current()->OwnsSafepoint());
   classes_.Remap(old_to_new_cid);
 }

 void ClassTable::VisitObjectPointers(ObjectPointerVisitor* visitor) {
   ASSERT(visitor != nullptr);
   visitor->set_gc_root_type("class table");

   const auto visit = [&](ClassPtr* table, intptr_t num_cids) {
     if (num_cids == 0) {
       return;
     }
     ObjectPtr* from = reinterpret_cast<ObjectPtr*>(&table[0]);
     ObjectPtr* to = reinterpret_cast<ObjectPtr*>(&table[num_cids - 1]);
     visitor->VisitPointers(from, to);
   };

   visit(classes_.GetColumn<kClassIndex>(), classes_.num_cids());
   visit(top_level_classes_.GetColumn<kClassIndex>(),
         top_level_classes_.num_cids());
   visitor->clear_gc_root_type();
 }

 void ClassTable::CopySizesFromClassObjects() {
   ASSERT(kIllegalCid == 0);
   for (intptr_t i = 1; i < classes_.num_cids(); i++) {
     UpdateClassSize(i, classes_.At<kClassIndex>(i));
   }
 }

 void ClassTable::SetAt(intptr_t cid, ClassPtr raw_cls) {
   if (IsTopLevelCid(cid)) {
     top_level_classes_.At<kClassIndex>(IndexFromTopLevelCid(cid)) = raw_cls;
     return;
   }

   // This is called by snapshot reader and class finalizer.
   UpdateClassSize(cid, raw_cls);
   classes_.At<kClassIndex>(cid) = raw_cls;
 }

 void ClassTable::UpdateClassSize(intptr_t cid, ClassPtr raw_cls) {
   ASSERT(IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
   ASSERT(!IsTopLevelCid(cid));  // "top-level" classes don't get instantiated
   const intptr_t size =
       raw_cls == nullptr ? 0 : Class::host_instance_size(raw_cls);
   classes_.At<kSizeIndex>(cid) = static_cast<int32_t>(size);
 }

 void ClassTable::Validate() {
   Class& cls = Class::Handle();
   for (intptr_t cid = kNumPredefinedCids; cid < classes_.num_cids(); cid++) {
     // Some of the class table entries maybe nullptr as we create some
     // top level classes but do not add them to the list of anonymous
     // classes in a library if there are no top level fields or functions.
     // Since there are no references to these top level classes they are
     // not written into a full snapshot and will not be recreated when
     // we read back the full snapshot. These class slots end up with nullptr
     // entries.
     if (HasValidClassAt(cid)) {
       cls = At(cid);
       ASSERT(cls.IsClass());
 #if defined(DART_PRECOMPILER)
       // Precompiler can drop classes and set their id() to kIllegalCid.
       // It still leaves them in the class table so dropped program
       // structure could still be accessed while writing debug info.
       ASSERT((cls.id() == cid) || (cls.id() == kIllegalCid));
 #else
       ASSERT(cls.id() == cid);
 #endif  // defined(DART_PRECOMPILER)
     }
   }
 }

 void ClassTable::Print() {
   Class& cls = Class::Handle();
   String& name = String::Handle();

   for (intptr_t i = 1; i < classes_.num_cids(); i++) {
     if (!HasValidClassAt(i)) {
       continue;
     }
     cls = At(i);
     if (cls.ptr() != nullptr) {
       name = cls.Name();
       OS::PrintErr("%" Pd ": %s\n", i, name.ToCString());
     }
   }
 }

 #if defined(DART_PRECOMPILER)
 void ClassTable::PrintObjectLayout(const char* filename) {
   Class& cls = Class::Handle();
   Array& fields = Array::Handle();
   Field& field = Field::Handle();

   JSONWriter js;
   js.OpenArray();
   for (intptr_t i = ClassId::kObjectCid; i < classes_.num_cids(); i++) {
     if (!HasValidClassAt(i)) {
       continue;
     }
     cls = At(i);
     ASSERT(!cls.IsNull());
     ASSERT(cls.id() != kIllegalCid);
     ASSERT(cls.is_finalized());  // Precompiler already finalized all classes.
     ASSERT(!cls.IsTopLevel());
     js.OpenObject();
     js.PrintProperty("class", cls.UserVisibleNameCString());
     js.PrintProperty("size", cls.target_instance_size());
     js.OpenArray("fields");
     fields = cls.fields();
     if (!fields.IsNull()) {
       for (intptr_t i = 0, n = fields.Length(); i < n; ++i) {
         field ^= fields.At(i);
         js.OpenObject();
         js.PrintProperty("field", field.UserVisibleNameCString());
         if (field.is_static()) {
           js.PrintPropertyBool("static", true);
         } else {
           js.PrintProperty("offset", field.TargetOffset());
         }
         js.CloseObject();
       }
     }
     js.CloseArray();
     js.CloseObject();
   }
   js.CloseArray();

   auto file_open = Dart::file_open_callback();
   auto file_write = Dart::file_write_callback();
   auto file_close = Dart::file_close_callback();
   if ((file_open == nullptr) || (file_write == nullptr) ||
       (file_close == nullptr)) {
     OS::PrintErr("warning: Could not access file callbacks.");
     return;
   }

   void* file = file_open(filename, /*write=*/true);
   if (file == nullptr) {
     OS::PrintErr("warning: Failed to write object layout: %s\n", filename);
     return;
   }

   char* output = nullptr;
   intptr_t output_length = 0;
   js.Steal(&output, &output_length);
   file_write(output, output_length, file);
   free(output);
   file_close(file);
 }
 #endif  // defined(DART_PRECOMPILER)

 #if !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
 void ClassTable::PopulateUserVisibleNames() {
   Class& cls = Class::Handle();
   for (intptr_t i = 0; i < classes_.num_cids(); ++i) {
     if (HasValidClassAt(i) && UserVisibleNameFor(i) == nullptr) {
       cls = At(i);
       cls.SetUserVisibleNameInClassTable();
     }
   }
 }
 #endif  // !defined(PRODUCT) || defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)

 #if !defined(PRODUCT)

 void ClassTable::PrintToJSONObject(JSONObject* object) {
   Class& cls = Class::Handle();
   object->AddProperty("type", "ClassList");
   {
     JSONArray members(object, "classes");
     for (intptr_t i = ClassId::kObjectCid; i < classes_.num_cids(); i++) {
       if (HasValidClassAt(i)) {
         cls = At(i);
         members.AddValue(cls);
       }
     }
   }
 }

 void ClassTable::AllocationProfilePrintJSON(JSONStream* stream, bool internal) {
   Isolate* isolate = Isolate::Current();
   ASSERT(isolate != nullptr);
   auto isolate_group = isolate->group();
   Heap* heap = isolate_group->heap();
   ASSERT(heap != nullptr);
   JSONObject obj(stream);
   obj.AddProperty("type", "AllocationProfile");
   if (isolate_group->last_allocationprofile_accumulator_reset_timestamp() !=
       0) {
     obj.AddPropertyF(
         "dateLastAccumulatorReset", "%" Pd64 "",
         isolate_group->last_allocationprofile_accumulator_reset_timestamp());
   }
   if (isolate_group->last_allocationprofile_gc_timestamp() != 0) {
     obj.AddPropertyF("dateLastServiceGC", "%" Pd64 "",
                      isolate_group->last_allocationprofile_gc_timestamp());
   }

   if (internal) {
     JSONObject heaps(&obj, "_heaps");
     { heap->PrintToJSONObject(Heap::kNew, &heaps); }
     { heap->PrintToJSONObject(Heap::kOld, &heaps); }
   }

   {
     JSONObject memory(&obj, "memoryUsage");
     { heap->PrintMemoryUsageJSON(&memory); }
   }

   Thread* thread = Thread::Current();
   CountObjectsVisitor visitor(thread, NumCids());
   {
     HeapIterationScope iter(thread);
     iter.IterateObjects(&visitor);
     isolate->group()->VisitWeakPersistentHandles(&visitor);
   }

   {
     JSONArray arr(&obj, "members");
     Class& cls = Class::Handle();
     for (intptr_t i = 3; i < classes_.num_cids(); i++) {
       if (!HasValidClassAt(i)) continue;

       cls = At(i);
       if (cls.IsNull()) continue;

       JSONObject obj(&arr);
       obj.AddProperty("type", "ClassHeapStats");
       obj.AddProperty("class", cls);
       intptr_t count = visitor.new_count_[i] + visitor.old_count_[i];
       intptr_t size = visitor.new_size_[i] + visitor.old_size_[i];
       obj.AddProperty64("instancesAccumulated", count);
       obj.AddProperty64("accumulatedSize", size);
       obj.AddProperty64("instancesCurrent", count);
       obj.AddProperty64("bytesCurrent", size);

       if (internal) {
         {
           JSONArray new_stats(&obj, "_new");
           new_stats.AddValue(visitor.new_count_[i]);
           new_stats.AddValue(visitor.new_size_[i]);
           new_stats.AddValue(visitor.new_external_size_[i]);
         }
         {
           JSONArray old_stats(&obj, "_old");
           old_stats.AddValue(visitor.old_count_[i]);
           old_stats.AddValue(visitor.old_size_[i]);
           old_stats.AddValue(visitor.old_external_size_[i]);
         }
       }
     }
   }
 }
 #endif  // !PRODUCT

 ClassTableAllocator::ClassTableAllocator()
     : pending_freed_(new MallocGrowableArray<std::pair<void*, Deleter>>()) {}

 ClassTableAllocator::~ClassTableAllocator() {
   FreePending();
   delete pending_freed_;
 }

 void ClassTableAllocator::Free(ClassTable* ptr) {
   if (ptr != nullptr) {
     pending_freed_->Add(std::make_pair(
         ptr, [](void* ptr) { delete static_cast<ClassTable*>(ptr); }));
   }
 }

 void ClassTableAllocator::Free(void* ptr) {
   if (ptr != nullptr) {
     pending_freed_->Add(std::make_pair(ptr, nullptr));
   }
 }

 void ClassTableAllocator::FreePending() {
   while (!pending_freed_->is_empty()) {
     auto [ptr, deleter] = pending_freed_->RemoveLast();
     if (deleter == nullptr) {
       free(ptr);
     } else {
       deleter(ptr);
     }
   }
 }

 }  // namespace dart
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/class_table.h"

	#include <memory>

	#include "platform/atomic.h"
	#include "vm/flags.h"
	#include "vm/growable_array.h"
	#include "vm/heap/heap.h"
	#include "vm/object.h"
	#include "vm/object_graph.h"
	#include "vm/raw_object.h"
	#include "vm/visitor.h"

	namespace dart {

	DEFINE_FLAG(bool, print_class_table, false, "Print initial class table.");

	ClassTable::ClassTable(ClassTableAllocator* allocator)
	: allocator_(allocator),
	classes_(allocator),
	top_level_classes_(allocator) {
	if (Dart::vm_isolate() == nullptr) {
	classes_.SetNumCidsAndCapacity(kNumPredefinedCids, kInitialCapacity);
	} else {
	// Duplicate the class table from the VM isolate.
	ClassTable* vm_class_table = Dart::vm_isolate_group()->class_table();
	classes_.SetNumCidsAndCapacity(kNumPredefinedCids,
	vm_class_table->classes_.capacity());

	const auto copy_info_for_cid = [&](intptr_t cid) {
	classes_.At<kClassIndex>(cid) = vm_class_table->At(cid);
	classes_.At<kSizeIndex>(cid) = vm_class_table->SizeAt(cid);
	};

	// The following cids don't have a corresponding class object in Dart code.
	// We therefore need to initialize them eagerly.
	COMPILE_ASSERT(kFirstInternalOnlyCid == kObjectCid + 1);
	for (intptr_t i = kObjectCid; i <= kLastInternalOnlyCid; i++) {
	copy_info_for_cid(i);
	}
	copy_info_for_cid(kTypeArgumentsCid);
	copy_info_for_cid(kFreeListElement);
	copy_info_for_cid(kForwardingCorpse);
	copy_info_for_cid(kDynamicCid);
	copy_info_for_cid(kVoidCid);
	}
	UpdateCachedAllocationTracingStateTablePointer();
	}

	ClassTable::~ClassTable() {
	#if !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
	for (intptr_t i = 1; i < classes_.num_cids(); i++) {
	const char* name = UserVisibleNameFor(i);
	if (name != nullptr) {
	free(const_cast<char*>(name));
	}
	}
	#endif // !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
	}

	void ClassTable::Register(const Class& cls) {
	ASSERT(Thread::Current()->IsDartMutatorThread());
	ASSERT(cls.id() == kIllegalCid \|\| cls.id() < kNumPredefinedCids);
	bool did_grow = false;
	const classid_t cid =
	cls.id() != kIllegalCid ? cls.id() : classes_.AddRow(&did_grow);
	ASSERT(!IsTopLevelCid(cid));

	const intptr_t instance_size =
	cls.is_abstract() ? 0 : Class::host_instance_size(cls.ptr());

	cls.set_id(cid);
	classes_.At<kClassIndex>(cid) = cls.ptr();
	classes_.At<kSizeIndex>(cid) = static_cast<int32_t>(instance_size);
	#if !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
	classes_.At<kClassNameIndex>(cid) = nullptr;
	#endif // !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)

	if (did_grow) {
	IsolateGroup::Current()->set_cached_class_table_table(
	classes_.GetColumn<kClassIndex>());
	UpdateCachedAllocationTracingStateTablePointer();
	} else {
	std::atomic_thread_fence(std::memory_order_release);
	}
	}

	void ClassTable::RegisterTopLevel(const Class& cls) {
	ASSERT(Thread::Current()->IsDartMutatorThread());
	ASSERT(cls.id() == kIllegalCid);

	bool did_grow = false;
	const intptr_t index = top_level_classes_.AddRow(&did_grow);
	cls.set_id(ClassTable::CidFromTopLevelIndex(index));
	top_level_classes_.At<kClassIndex>(index) = cls.ptr();
	}

	void ClassTable::AllocateIndex(intptr_t index) {
	bool did_grow = false;
	if (IsTopLevelCid(index)) {
	top_level_classes_.AllocateIndex(IndexFromTopLevelCid(index), &did_grow);
	return;
	}

	classes_.AllocateIndex(index, &did_grow);
	if (did_grow) {
	IsolateGroup::Current()->set_cached_class_table_table(table());
	UpdateCachedAllocationTracingStateTablePointer();
	}
	}

	void ClassTable::UnregisterTopLevel(intptr_t cid) {
	ASSERT(IsTopLevelCid(cid));
	const intptr_t tlc_index = IndexFromTopLevelCid(cid);
	top_level_classes_.At<kClassIndex>(tlc_index) = nullptr;
	}

	void ClassTable::Remap(intptr_t* old_to_new_cid) {
	ASSERT(Thread::Current()->OwnsSafepoint());
	classes_.Remap(old_to_new_cid);
	}

	void ClassTable::VisitObjectPointers(ObjectPointerVisitor* visitor) {
	ASSERT(visitor != nullptr);
	visitor->set_gc_root_type("class table");

	const auto visit = [&](ClassPtr* table, intptr_t num_cids) {
	if (num_cids == 0) {
	return;
	}
	ObjectPtr* from = reinterpret_cast<ObjectPtr*>(&table[0]);
	ObjectPtr* to = reinterpret_cast<ObjectPtr*>(&table[num_cids - 1]);
	visitor->VisitPointers(from, to);
	};

	visit(classes_.GetColumn<kClassIndex>(), classes_.num_cids());
	visit(top_level_classes_.GetColumn<kClassIndex>(),
	top_level_classes_.num_cids());
	visitor->clear_gc_root_type();
	}

	void ClassTable::CopySizesFromClassObjects() {
	ASSERT(kIllegalCid == 0);
	for (intptr_t i = 1; i < classes_.num_cids(); i++) {
	UpdateClassSize(i, classes_.At<kClassIndex>(i));
	}
	}

	void ClassTable::SetAt(intptr_t cid, ClassPtr raw_cls) {
	if (IsTopLevelCid(cid)) {
	top_level_classes_.At<kClassIndex>(IndexFromTopLevelCid(cid)) = raw_cls;
	return;
	}

	// This is called by snapshot reader and class finalizer.
	UpdateClassSize(cid, raw_cls);
	classes_.At<kClassIndex>(cid) = raw_cls;
	}

	void ClassTable::UpdateClassSize(intptr_t cid, ClassPtr raw_cls) {
	ASSERT(IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
	ASSERT(!IsTopLevelCid(cid)); // "top-level" classes don't get instantiated
	const intptr_t size =
	raw_cls == nullptr ? 0 : Class::host_instance_size(raw_cls);
	classes_.At<kSizeIndex>(cid) = static_cast<int32_t>(size);
	}

	void ClassTable::Validate() {
	Class& cls = Class::Handle();
	for (intptr_t cid = kNumPredefinedCids; cid < classes_.num_cids(); cid++) {
	// Some of the class table entries maybe nullptr as we create some
	// top level classes but do not add them to the list of anonymous
	// classes in a library if there are no top level fields or functions.
	// Since there are no references to these top level classes they are
	// not written into a full snapshot and will not be recreated when
	// we read back the full snapshot. These class slots end up with nullptr
	// entries.
	if (HasValidClassAt(cid)) {
	cls = At(cid);
	ASSERT(cls.IsClass());
	#if defined(DART_PRECOMPILER)
	// Precompiler can drop classes and set their id() to kIllegalCid.
	// It still leaves them in the class table so dropped program
	// structure could still be accessed while writing debug info.
	ASSERT((cls.id() == cid) \|\| (cls.id() == kIllegalCid));
	#else
	ASSERT(cls.id() == cid);
	#endif // defined(DART_PRECOMPILER)
	}
	}
	}

	void ClassTable::Print() {
	Class& cls = Class::Handle();
	String& name = String::Handle();

	for (intptr_t i = 1; i < classes_.num_cids(); i++) {
	if (!HasValidClassAt(i)) {
	continue;
	}
	cls = At(i);
	if (cls.ptr() != nullptr) {
	name = cls.Name();
	OS::PrintErr("%" Pd ": %s\n", i, name.ToCString());
	}
	}
	}

	#if defined(DART_PRECOMPILER)
	void ClassTable::PrintObjectLayout(const char* filename) {
	Class& cls = Class::Handle();
	Array& fields = Array::Handle();
	Field& field = Field::Handle();

	JSONWriter js;
	js.OpenArray();
	for (intptr_t i = ClassId::kObjectCid; i < classes_.num_cids(); i++) {
	if (!HasValidClassAt(i)) {
	continue;
	}
	cls = At(i);
	ASSERT(!cls.IsNull());
	ASSERT(cls.id() != kIllegalCid);
	ASSERT(cls.is_finalized()); // Precompiler already finalized all classes.
	ASSERT(!cls.IsTopLevel());
	js.OpenObject();
	js.PrintProperty("class", cls.UserVisibleNameCString());
	js.PrintProperty("size", cls.target_instance_size());
	js.OpenArray("fields");
	fields = cls.fields();
	if (!fields.IsNull()) {
	for (intptr_t i = 0, n = fields.Length(); i < n; ++i) {
	field ^= fields.At(i);
	js.OpenObject();
	js.PrintProperty("field", field.UserVisibleNameCString());
	if (field.is_static()) {
	js.PrintPropertyBool("static", true);
	} else {
	js.PrintProperty("offset", field.TargetOffset());
	}
	js.CloseObject();
	}
	}
	js.CloseArray();
	js.CloseObject();
	}
	js.CloseArray();

	auto file_open = Dart::file_open_callback();
	auto file_write = Dart::file_write_callback();
	auto file_close = Dart::file_close_callback();
	if ((file_open == nullptr) \|\| (file_write == nullptr) \|\|
	(file_close == nullptr)) {
	OS::PrintErr("warning: Could not access file callbacks.");
	return;
	}

	void* file = file_open(filename, /write=/true);
	if (file == nullptr) {
	OS::PrintErr("warning: Failed to write object layout: %s\n", filename);
	return;
	}

	char* output = nullptr;
	intptr_t output_length = 0;
	js.Steal(&output, &output_length);
	file_write(output, output_length, file);
	free(output);
	file_close(file);
	}
	#endif // defined(DART_PRECOMPILER)

	#if !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)
	void ClassTable::PopulateUserVisibleNames() {
	Class& cls = Class::Handle();
	for (intptr_t i = 0; i < classes_.num_cids(); ++i) {
	if (HasValidClassAt(i) && UserVisibleNameFor(i) == nullptr) {
	cls = At(i);
	cls.SetUserVisibleNameInClassTable();
	}
	}
	}
	#endif // !defined(PRODUCT) \|\| defined(FORCE_INCLUDE_SAMPLING_HEAP_PROFILER)

	#if !defined(PRODUCT)

	void ClassTable::PrintToJSONObject(JSONObject* object) {
	Class& cls = Class::Handle();
	object->AddProperty("type", "ClassList");
	{
	JSONArray members(object, "classes");
	for (intptr_t i = ClassId::kObjectCid; i < classes_.num_cids(); i++) {
	if (HasValidClassAt(i)) {
	cls = At(i);
	members.AddValue(cls);
	}
	}
	}
	}

	void ClassTable::AllocationProfilePrintJSON(JSONStream* stream, bool internal) {
	Isolate* isolate = Isolate::Current();
	ASSERT(isolate != nullptr);
	auto isolate_group = isolate->group();
	Heap* heap = isolate_group->heap();
	ASSERT(heap != nullptr);
	JSONObject obj(stream);
	obj.AddProperty("type", "AllocationProfile");
	if (isolate_group->last_allocationprofile_accumulator_reset_timestamp() !=
	0) {
	obj.AddPropertyF(
	"dateLastAccumulatorReset", "%" Pd64 "",
	isolate_group->last_allocationprofile_accumulator_reset_timestamp());
	}
	if (isolate_group->last_allocationprofile_gc_timestamp() != 0) {
	obj.AddPropertyF("dateLastServiceGC", "%" Pd64 "",
	isolate_group->last_allocationprofile_gc_timestamp());
	}

	if (internal) {
	JSONObject heaps(&obj, "_heaps");
	{ heap->PrintToJSONObject(Heap::kNew, &heaps); }
	{ heap->PrintToJSONObject(Heap::kOld, &heaps); }
	}

	{
	JSONObject memory(&obj, "memoryUsage");
	{ heap->PrintMemoryUsageJSON(&memory); }
	}

	Thread* thread = Thread::Current();
	CountObjectsVisitor visitor(thread, NumCids());
	{
	HeapIterationScope iter(thread);
	iter.IterateObjects(&visitor);
	isolate->group()->VisitWeakPersistentHandles(&visitor);
	}

	{
	JSONArray arr(&obj, "members");
	Class& cls = Class::Handle();
	for (intptr_t i = 3; i < classes_.num_cids(); i++) {
	if (!HasValidClassAt(i)) continue;

	cls = At(i);
	if (cls.IsNull()) continue;

	JSONObject obj(&arr);
	obj.AddProperty("type", "ClassHeapStats");
	obj.AddProperty("class", cls);
	intptr_t count = visitor.new_count_[i] + visitor.old_count_[i];
	intptr_t size = visitor.new_size_[i] + visitor.old_size_[i];
	obj.AddProperty64("instancesAccumulated", count);
	obj.AddProperty64("accumulatedSize", size);
	obj.AddProperty64("instancesCurrent", count);
	obj.AddProperty64("bytesCurrent", size);

	if (internal) {
	{
	JSONArray new_stats(&obj, "_new");
	new_stats.AddValue(visitor.new_count_[i]);
	new_stats.AddValue(visitor.new_size_[i]);
	new_stats.AddValue(visitor.new_external_size_[i]);
	}
	{
	JSONArray old_stats(&obj, "_old");
	old_stats.AddValue(visitor.old_count_[i]);
	old_stats.AddValue(visitor.old_size_[i]);
	old_stats.AddValue(visitor.old_external_size_[i]);
	}
	}
	}
	}
	}
	#endif // !PRODUCT

	ClassTableAllocator::ClassTableAllocator()
	: pending_freed_(new MallocGrowableArray<std::pair<void*, Deleter>>()) {}

	ClassTableAllocator::~ClassTableAllocator() {
	FreePending();
	delete pending_freed_;
	}

	void ClassTableAllocator::Free(ClassTable* ptr) {
	if (ptr != nullptr) {
	pending_freed_->Add(std::make_pair(
	ptr, [](void* ptr) { delete static_cast<ClassTable*>(ptr); }));
	}
	}

	void ClassTableAllocator::Free(void* ptr) {
	if (ptr != nullptr) {
	pending_freed_->Add(std::make_pair(ptr, nullptr));
	}
	}

	void ClassTableAllocator::FreePending() {
	while (!pending_freed_->is_empty()) {
	auto [ptr, deleter] = pending_freed_->RemoveLast();
	if (deleter == nullptr) {
	free(ptr);
	} else {
	deleter(ptr);
	}
	}
	}

	} // namespace dart