Google Git
Sign in
dart / sdk / f0d88cc96dc977027ba4e6d5cff38d746872c80c / . / runtime / vm / object_graph.cc
blob: e127267c9e545ca9831e4b6d86fa6ce050b2f9b3 [file] [log] [blame]
// Copyright (c) 2014, 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/object_graph.h"
#include "vm/dart.h"
#include "vm/dart_api_state.h"
#include "vm/growable_array.h"
#include "vm/isolate.h"
#include "vm/native_symbol.h"
#include "vm/object.h"
#include "vm/object_store.h"
#include "vm/profiler.h"
#include "vm/raw_object.h"
#include "vm/raw_object_fields.h"
#include "vm/reusable_handles.h"
#include "vm/visitor.h"
namespace dart {
#if !defined(PRODUCT)
static bool IsUserClass(intptr_t cid) {
if (cid == kContextCid) return true;
if (cid == kTypeArgumentsCid) return false;
return cid >= kInstanceCid;
}
// The state of a pre-order, depth-first traversal of an object graph.
// When a node is visited, *all* its children are pushed to the stack at once.
// We insert a sentinel between the node and its children on the stack, to
// remember that the node has been visited. The node is kept on the stack while
// its children are processed, to give the visitor a complete chain of parents.
//
// TODO(koda): Potential optimizations:
// - Use tag bits for compact Node and sentinel representations.
class ObjectGraph::Stack : public ObjectPointerVisitor {
public:
explicit Stack(IsolateGroup* isolate_group)
: ObjectPointerVisitor(isolate_group),
include_vm_objects_(true),
data_(kInitialCapacity) {
object_ids_ = new WeakTable();
}
~Stack() {
delete object_ids_;
object_ids_ = nullptr;
}
// Marks and pushes. Used to initialize this stack with roots.
// We can use ObjectIdTable normally used by serializers because it
// won't be in use while handling a service request (ObjectGraph's only use).
virtual void VisitPointers(ObjectPtr* first, ObjectPtr* last) {
for (ObjectPtr* current = first; current <= last; ++current) {
if ((*current)->IsHeapObject() && !(*current)->ptr()->InVMIsolateHeap() &&
object_ids_->GetValueExclusive(*current) == 0) { // not visited yet
if (!include_vm_objects_ && !IsUserClass((*current)->GetClassId())) {
continue;
}
object_ids_->SetValueExclusive(*current, 1);
Node node;
node.ptr = current;
node.obj = *current;
node.gc_root_type = gc_root_type();
data_.Add(node);
}
}
}
// Traverses the object graph from the current state.
void TraverseGraph(ObjectGraph::Visitor* visitor) {
while (!data_.is_empty()) {
Node node = data_.Last();
if (node.ptr == kSentinel) {
data_.RemoveLast();
// The node below the sentinel has already been visited.
data_.RemoveLast();
continue;
}
ObjectPtr obj = node.obj;
ASSERT(obj->IsHeapObject());
Node sentinel;
sentinel.ptr = kSentinel;
data_.Add(sentinel);
StackIterator it(this, data_.length() - 2);
visitor->gc_root_type = node.gc_root_type;
Visitor::Direction direction = visitor->VisitObject(&it);
if (direction == ObjectGraph::Visitor::kAbort) {
break;
}
if (direction == ObjectGraph::Visitor::kProceed) {
set_gc_root_type(node.gc_root_type);
obj->ptr()->VisitPointers(this);
clear_gc_root_type();
}
}
}
virtual bool visit_weak_persistent_handles() const {
return visit_weak_persistent_handles_;
}
void set_visit_weak_persistent_handles(bool value) {
visit_weak_persistent_handles_ = value;
}
bool include_vm_objects_;
private:
struct Node {
ObjectPtr* ptr; // kSentinel for the sentinel node.
ObjectPtr obj;
const char* gc_root_type;
};
bool visit_weak_persistent_handles_ = false;
static ObjectPtr* const kSentinel;
static const intptr_t kInitialCapacity = 1024;
static const intptr_t kNoParent = -1;
intptr_t Parent(intptr_t index) const {
// The parent is just below the next sentinel.
for (intptr_t i = index; i >= 1; --i) {
if (data_[i].ptr == kSentinel) {
return i - 1;
}
}
return kNoParent;
}
// During the iteration of the heap we are already at a safepoint, so there is
// no need to let the GC know about [object_ids_] (i.e. GC cannot run while we
// use [object_ids]).
WeakTable* object_ids_ = nullptr;
GrowableArray<Node> data_;
friend class StackIterator;
DISALLOW_COPY_AND_ASSIGN(Stack);
};
ObjectPtr* const ObjectGraph::Stack::kSentinel = NULL;
ObjectPtr ObjectGraph::StackIterator::Get() const {
return stack_->data_[index_].obj;
}
bool ObjectGraph::StackIterator::MoveToParent() {
intptr_t parent = stack_->Parent(index_);
if (parent == Stack::kNoParent) {
return false;
} else {
index_ = parent;
return true;
}
}
intptr_t ObjectGraph::StackIterator::OffsetFromParentInWords() const {
intptr_t parent_index = stack_->Parent(index_);
if (parent_index == Stack::kNoParent) {
return -1;
}
Stack::Node parent = stack_->data_[parent_index];
uword parent_start = ObjectLayout::ToAddr(parent.obj);
Stack::Node child = stack_->data_[index_];
ASSERT(child.obj == *child.ptr);
uword child_ptr_addr = reinterpret_cast<uword>(child.ptr);
intptr_t offset = child_ptr_addr - parent_start;
if (offset > 0 && offset < parent.obj->ptr()->HeapSize()) {
ASSERT(Utils::IsAligned(offset, kWordSize));
return offset >> kWordSizeLog2;
} else {
// Some internal VM objects visit pointers not contained within the parent.
// For instance, CodeLayout::VisitCodePointers visits pointers in
// instructions.
ASSERT(!parent.obj->IsDartInstance());
return -1;
}
}
static void IterateUserFields(ObjectPointerVisitor* visitor) {
visitor->set_gc_root_type("user global");
Thread* thread = Thread::Current();
// Scope to prevent handles create here from appearing as stack references.
HANDLESCOPE(thread);
Zone* zone = thread->zone();
const GrowableObjectArray& libraries = GrowableObjectArray::Handle(
zone, thread->isolate()->object_store()->libraries());
Library& library = Library::Handle(zone);
Object& entry = Object::Handle(zone);
Class& cls = Class::Handle(zone);
Array& fields = Array::Handle(zone);
Field& field = Field::Handle(zone);
for (intptr_t i = 0; i < libraries.Length(); i++) {
library ^= libraries.At(i);
DictionaryIterator entries(library);
while (entries.HasNext()) {
entry = entries.GetNext();
if (entry.IsClass()) {
cls ^= entry.raw();
fields = cls.fields();
for (intptr_t j = 0; j < fields.Length(); j++) {
field ^= fields.At(j);
ObjectPtr ptr = field.raw();
visitor->VisitPointer(&ptr);
}
} else if (entry.IsField()) {
field ^= entry.raw();
ObjectPtr ptr = field.raw();
visitor->VisitPointer(&ptr);
}
}
}
visitor->clear_gc_root_type();
}
ObjectGraph::ObjectGraph(Thread* thread) : ThreadStackResource(thread) {
// The VM isolate has all its objects pre-marked, so iterating over it
// would be a no-op.
ASSERT(thread->isolate() != Dart::vm_isolate());
}
ObjectGraph::~ObjectGraph() {}
void ObjectGraph::IterateObjects(ObjectGraph::Visitor* visitor) {
Stack stack(isolate_group());
stack.set_visit_weak_persistent_handles(
visitor->visit_weak_persistent_handles());
isolate_group()->VisitObjectPointers(&stack,
ValidationPolicy::kDontValidateFrames);
stack.TraverseGraph(visitor);
}
void ObjectGraph::IterateUserObjects(ObjectGraph::Visitor* visitor) {
Stack stack(isolate_group());
stack.set_visit_weak_persistent_handles(
visitor->visit_weak_persistent_handles());
IterateUserFields(&stack);
stack.include_vm_objects_ = false;
stack.TraverseGraph(visitor);
}
void ObjectGraph::IterateObjectsFrom(const Object& root,
ObjectGraph::Visitor* visitor) {
Stack stack(isolate_group());
stack.set_visit_weak_persistent_handles(
visitor->visit_weak_persistent_handles());
ObjectPtr root_raw = root.raw();
stack.VisitPointer(&root_raw);
stack.TraverseGraph(visitor);
}
class InstanceAccumulator : public ObjectVisitor {
public:
InstanceAccumulator(ObjectGraph::Stack* stack, intptr_t class_id)
: stack_(stack), class_id_(class_id) {}
void VisitObject(ObjectPtr obj) {
if (obj->GetClassId() == class_id_) {
ObjectPtr rawobj = obj;
stack_->VisitPointer(&rawobj);
}
}
private:
ObjectGraph::Stack* stack_;
const intptr_t class_id_;
DISALLOW_COPY_AND_ASSIGN(InstanceAccumulator);
};
void ObjectGraph::IterateObjectsFrom(intptr_t class_id,
HeapIterationScope* iteration,
ObjectGraph::Visitor* visitor) {
Stack stack(isolate_group());
InstanceAccumulator accumulator(&stack, class_id);
iteration->IterateObjectsNoImagePages(&accumulator);
stack.TraverseGraph(visitor);
}
class SizeVisitor : public ObjectGraph::Visitor {
public:
SizeVisitor() : size_(0) {}
intptr_t size() const { return size_; }
virtual bool ShouldSkip(ObjectPtr obj) const { return false; }
virtual Direction VisitObject(ObjectGraph::StackIterator* it) {
ObjectPtr obj = it->Get();
if (ShouldSkip(obj)) {
return kBacktrack;
}
size_ += obj->ptr()->HeapSize();
return kProceed;
}
private:
intptr_t size_;
};
class SizeExcludingObjectVisitor : public SizeVisitor {
public:
explicit SizeExcludingObjectVisitor(const Object& skip) : skip_(skip) {}
virtual bool ShouldSkip(ObjectPtr obj) const { return obj == skip_.raw(); }
private:
const Object& skip_;
};
class SizeExcludingClassVisitor : public SizeVisitor {
public:
explicit SizeExcludingClassVisitor(intptr_t skip) : skip_(skip) {}
virtual bool ShouldSkip(ObjectPtr obj) const {
return obj->GetClassId() == skip_;
}
private:
const intptr_t skip_;
};
intptr_t ObjectGraph::SizeRetainedByInstance(const Object& obj) {
HeapIterationScope iteration_scope(Thread::Current(), true);
SizeVisitor total;
IterateObjects(&total);
intptr_t size_total = total.size();
SizeExcludingObjectVisitor excluding_obj(obj);
IterateObjects(&excluding_obj);
intptr_t size_excluding_obj = excluding_obj.size();
return size_total - size_excluding_obj;
}
intptr_t ObjectGraph::SizeReachableByInstance(const Object& obj) {
HeapIterationScope iteration_scope(Thread::Current(), true);
SizeVisitor total;
IterateObjectsFrom(obj, &total);
return total.size();
}
intptr_t ObjectGraph::SizeRetainedByClass(intptr_t class_id) {
HeapIterationScope iteration_scope(Thread::Current(), true);
SizeVisitor total;
IterateObjects(&total);
intptr_t size_total = total.size();
SizeExcludingClassVisitor excluding_class(class_id);
IterateObjects(&excluding_class);
intptr_t size_excluding_class = excluding_class.size();
return size_total - size_excluding_class;
}
intptr_t ObjectGraph::SizeReachableByClass(intptr_t class_id) {
HeapIterationScope iteration_scope(Thread::Current(), true);
SizeVisitor total;
IterateObjectsFrom(class_id, &iteration_scope, &total);
return total.size();
}
class RetainingPathVisitor : public ObjectGraph::Visitor {
public:
// We cannot use a GrowableObjectArray, since we must not trigger GC.
RetainingPathVisitor(ObjectPtr obj, const Array& path)
: thread_(Thread::Current()), obj_(obj), path_(path), length_(0) {}
intptr_t length() const { return length_; }
virtual bool visit_weak_persistent_handles() const { return true; }
bool ShouldSkip(ObjectPtr obj) {
// A retaining path through ICData is never the only retaining path,
// and it is less informative than its alternatives.
intptr_t cid = obj->GetClassId();
switch (cid) {
case kICDataCid:
return true;
default:
return false;
}
}
bool ShouldStop(ObjectPtr obj) {
// A static field is considered a root from a language point of view.
if (obj->IsField()) {
const Field& field = Field::Handle(static_cast<FieldPtr>(obj));
return field.is_static();
}
return false;
}
void StartList() { was_last_array_ = false; }
intptr_t HideNDescendant(ObjectPtr obj) {
// A GrowableObjectArray overwrites its internal storage.
// Keeping both of them in the list is redundant.
if (was_last_array_ && obj->IsGrowableObjectArray()) {
was_last_array_ = false;
return 1;
}
// A LinkedHasMap overwrites its internal storage.
// Keeping both of them in the list is redundant.
if (was_last_array_ && obj->IsLinkedHashMap()) {
was_last_array_ = false;
return 1;
}
was_last_array_ = obj->IsArray();
return 0;
}
virtual Direction VisitObject(ObjectGraph::StackIterator* it) {
if (it->Get() != obj_) {
if (ShouldSkip(it->Get())) {
return kBacktrack;
} else {
return kProceed;
}
} else {
HANDLESCOPE(thread_);
Object& current = Object::Handle();
Smi& offset_from_parent = Smi::Handle();
StartList();
do {
// We collapse the backingstore of some internal objects.
length_ -= HideNDescendant(it->Get());
intptr_t obj_index = length_ * 2;
intptr_t offset_index = obj_index + 1;
if (!path_.IsNull() && offset_index < path_.Length()) {
current = it->Get();
path_.SetAt(obj_index, current);
offset_from_parent = Smi::New(it->OffsetFromParentInWords());
path_.SetAt(offset_index, offset_from_parent);
}
++length_;
} while (!ShouldStop(it->Get()) && it->MoveToParent());
return kAbort;
}
}
private:
Thread* thread_;
ObjectPtr obj_;
const Array& path_;
intptr_t length_;
bool was_last_array_;
};
ObjectGraph::RetainingPathResult ObjectGraph::RetainingPath(Object* obj,
const Array& path) {
HeapIterationScope iteration_scope(Thread::Current(), true);
// To break the trivial path, the handle 'obj' is temporarily cleared during
// the search, but restored before returning.
ObjectPtr raw = obj->raw();
*obj = Object::null();
RetainingPathVisitor visitor(raw, path);
IterateUserObjects(&visitor);
if (visitor.length() == 0) {
IterateObjects(&visitor);
}
*obj = raw;
return {visitor.length(), visitor.gc_root_type};
}
class InboundReferencesVisitor : public ObjectVisitor,
public ObjectPointerVisitor {
public:
// We cannot use a GrowableObjectArray, since we must not trigger GC.
InboundReferencesVisitor(Isolate* isolate,
ObjectPtr target,
const Array& references,
Object* scratch)
: ObjectPointerVisitor(isolate->group()),
source_(nullptr),
target_(target),
references_(references),
scratch_(scratch),
length_(0) {
ASSERT(Thread::Current()->no_safepoint_scope_depth() != 0);
}
intptr_t length() const { return length_; }
virtual void VisitObject(ObjectPtr raw_obj) {
source_ = raw_obj;
raw_obj->ptr()->VisitPointers(this);
}
virtual void VisitPointers(ObjectPtr* first, ObjectPtr* last) {
for (ObjectPtr* current_ptr = first; current_ptr <= last; current_ptr++) {
ObjectPtr current_obj = *current_ptr;
if (current_obj == target_) {
intptr_t obj_index = length_ * 2;
intptr_t offset_index = obj_index + 1;
if (!references_.IsNull() && offset_index < references_.Length()) {
*scratch_ = source_;
references_.SetAt(obj_index, *scratch_);
*scratch_ = Smi::New(0);
uword source_start = ObjectLayout::ToAddr(source_);
uword current_ptr_addr = reinterpret_cast<uword>(current_ptr);
intptr_t offset = current_ptr_addr - source_start;
if (offset > 0 && offset < source_->ptr()->HeapSize()) {
ASSERT(Utils::IsAligned(offset, kWordSize));
*scratch_ = Smi::New(offset >> kWordSizeLog2);
} else {
// Some internal VM objects visit pointers not contained within the
// parent. For instance, CodeLayout::VisitCodePointers visits
// pointers in instructions.
ASSERT(!source_->IsDartInstance());
*scratch_ = Smi::New(-1);
}
references_.SetAt(offset_index, *scratch_);
}
++length_;
}
}
}
private:
ObjectPtr source_;
ObjectPtr target_;
const Array& references_;
Object* scratch_;
intptr_t length_;
};
intptr_t ObjectGraph::InboundReferences(Object* obj, const Array& references) {
Object& scratch = Object::Handle();
HeapIterationScope iteration(Thread::Current());
NoSafepointScope no_safepoint;
InboundReferencesVisitor visitor(isolate(), obj->raw(), references, &scratch);
iteration.IterateObjects(&visitor);
return visitor.length();
}
// Each OldPage is divided into blocks of size kBlockSize. Each object belongs
// to the block containing its header word.
// When generating a heap snapshot, we assign objects sequential ids in heap
// iteration order. A bitvector is computed that indicates the number of objects
// in each block, so the id of any object in the block can be found be adding
// the number of bits set before the object to the block's first id.
// Compare ForwardingBlock used for heap compaction.
class CountingBlock {
public:
void Clear() {
base_count_ = 0;
count_bitvector_ = 0;
}
intptr_t Lookup(uword addr) const {
uword block_offset = addr & ~kBlockMask;
intptr_t bitvector_shift = block_offset >> kObjectAlignmentLog2;
ASSERT(bitvector_shift < kBitsPerWord);
uword preceding_bitmask = (static_cast<uword>(1) << bitvector_shift) - 1;
return base_count_ +
Utils::CountOneBitsWord(count_bitvector_ & preceding_bitmask);
}
void Record(uword old_addr, intptr_t id) {
if (base_count_ == 0) {
ASSERT(count_bitvector_ == 0);
base_count_ = id; // First object in the block.
}
uword block_offset = old_addr & ~kBlockMask;
intptr_t bitvector_shift = block_offset >> kObjectAlignmentLog2;
ASSERT(bitvector_shift < kBitsPerWord);
count_bitvector_ |= static_cast<uword>(1) << bitvector_shift;
}
private:
intptr_t base_count_;
uword count_bitvector_;
COMPILE_ASSERT(kBitVectorWordsPerBlock == 1);
DISALLOW_COPY_AND_ASSIGN(CountingBlock);
};
class CountingPage {
public:
void Clear() {
for (intptr_t i = 0; i < kBlocksPerPage; i++) {
blocks_[i].Clear();
}
}
intptr_t Lookup(uword addr) { return BlockFor(addr)->Lookup(addr); }
void Record(uword addr, intptr_t id) {
return BlockFor(addr)->Record(addr, id);
}
CountingBlock* BlockFor(uword addr) {
intptr_t page_offset = addr & ~kOldPageMask;
intptr_t block_number = page_offset / kBlockSize;
ASSERT(block_number >= 0);
ASSERT(block_number <= kBlocksPerPage);
return &blocks_[block_number];
}
private:
CountingBlock blocks_[kBlocksPerPage];
DISALLOW_ALLOCATION();
DISALLOW_IMPLICIT_CONSTRUCTORS(CountingPage);
};
void HeapSnapshotWriter::EnsureAvailable(intptr_t needed) {
intptr_t available = capacity_ - size_;
if (available >= needed) {
return;
}
if (buffer_ != nullptr) {
Flush();
}
ASSERT(buffer_ == nullptr);
intptr_t chunk_size = kPreferredChunkSize;
if (chunk_size < needed + kMetadataReservation) {
chunk_size = needed + kMetadataReservation;
}
buffer_ = reinterpret_cast<uint8_t*>(malloc(chunk_size));
size_ = kMetadataReservation;
capacity_ = chunk_size;
}
void HeapSnapshotWriter::Flush(bool last) {
if (size_ == 0 && !last) {
return;
}
JSONStream js;
{
JSONObject jsobj(&js);
jsobj.AddProperty("jsonrpc", "2.0");
jsobj.AddProperty("method", "streamNotify");
{
JSONObject params(&jsobj, "params");
params.AddProperty("streamId", Service::heapsnapshot_stream.id());
{
JSONObject event(&params, "event");
event.AddProperty("type", "Event");
event.AddProperty("kind", "HeapSnapshot");
event.AddProperty("isolate", thread()->isolate());
event.AddPropertyTimeMillis("timestamp", OS::GetCurrentTimeMillis());
event.AddProperty("last", last);
}
}
}
Service::SendEventWithData(Service::heapsnapshot_stream.id(), "HeapSnapshot",
kMetadataReservation, js.buffer()->buffer(),
js.buffer()->length(), buffer_, size_);
buffer_ = nullptr;
size_ = 0;
capacity_ = 0;
}
void HeapSnapshotWriter::SetupCountingPages() {
for (intptr_t i = 0; i < kMaxImagePages; i++) {
image_page_ranges_[i].base = 0;
image_page_ranges_[i].size = 0;
}
intptr_t next_offset = 0;
OldPage* image_page = Dart::vm_isolate()->heap()->old_space()->image_pages_;
while (image_page != NULL) {
RELEASE_ASSERT(next_offset <= kMaxImagePages);
image_page_ranges_[next_offset].base = image_page->object_start();
image_page_ranges_[next_offset].size =
image_page->object_end() - image_page->object_start();
image_page = image_page->next();
next_offset++;
}
image_page = isolate()->heap()->old_space()->image_pages_;
while (image_page != NULL) {
RELEASE_ASSERT(next_offset <= kMaxImagePages);
image_page_ranges_[next_offset].base = image_page->object_start();
image_page_ranges_[next_offset].size =
image_page->object_end() - image_page->object_start();
image_page = image_page->next();
next_offset++;
}
OldPage* page = isolate()->heap()->old_space()->pages_;
while (page != NULL) {
page->forwarding_page();
CountingPage* counting_page =
reinterpret_cast<CountingPage*>(page->forwarding_page());
ASSERT(counting_page != NULL);
counting_page->Clear();
page = page->next();
}
}
bool HeapSnapshotWriter::OnImagePage(ObjectPtr obj) const {
const uword addr = ObjectLayout::ToAddr(obj);
for (intptr_t i = 0; i < kMaxImagePages; i++) {
if ((addr - image_page_ranges_[i].base) < image_page_ranges_[i].size) {
return true;
}
}
return false;
}
CountingPage* HeapSnapshotWriter::FindCountingPage(ObjectPtr obj) const {
if (obj->IsOldObject() && !OnImagePage(obj)) {
// On a regular or large page.
OldPage* page = OldPage::Of(obj);
return reinterpret_cast<CountingPage*>(page->forwarding_page());
}
// On an image page or in new space.
return nullptr;
}
void HeapSnapshotWriter::AssignObjectId(ObjectPtr obj) {
ASSERT(obj->IsHeapObject());
CountingPage* counting_page = FindCountingPage(obj);
if (counting_page != nullptr) {
// Likely: object on an ordinary page.
counting_page->Record(ObjectLayout::ToAddr(obj), ++object_count_);
} else {
// Unlikely: new space object, or object on a large or image page.
thread()->heap()->SetObjectId(obj, ++object_count_);
}
}
intptr_t HeapSnapshotWriter::GetObjectId(ObjectPtr obj) const {
if (!obj->IsHeapObject()) {
return 0;
}
if (FLAG_write_protect_code && obj->IsInstructions() && !OnImagePage(obj)) {
// A non-writable alias mapping may exist for instruction pages.
obj = OldPage::ToWritable(obj);
}
CountingPage* counting_page = FindCountingPage(obj);
intptr_t id;
if (counting_page != nullptr) {
// Likely: object on an ordinary page.
id = counting_page->Lookup(ObjectLayout::ToAddr(obj));
} else {
// Unlikely: new space object, or object on a large or image page.
id = thread()->heap()->GetObjectId(obj);
}
ASSERT(id != 0);
return id;
}
void HeapSnapshotWriter::ClearObjectIds() {
thread()->heap()->ResetObjectIdTable();
}
void HeapSnapshotWriter::CountReferences(intptr_t count) {
reference_count_ += count;
}
void HeapSnapshotWriter::CountExternalProperty() {
external_property_count_ += 1;
}
class Pass1Visitor : public ObjectVisitor,
public ObjectPointerVisitor,
public HandleVisitor {
public:
explicit Pass1Visitor(HeapSnapshotWriter* writer)
: ObjectVisitor(),
ObjectPointerVisitor(IsolateGroup::Current()),
HandleVisitor(Thread::Current()),
writer_(writer) {}
void VisitObject(ObjectPtr obj) {
if (obj->IsPseudoObject()) return;
writer_->AssignObjectId(obj);
obj->ptr()->VisitPointers(this);
}
void VisitPointers(ObjectPtr* from, ObjectPtr* to) {
intptr_t count = to - from + 1;
ASSERT(count >= 0);
writer_->CountReferences(count);
}
void VisitHandle(uword addr) {
FinalizablePersistentHandle* weak_persistent_handle =
reinterpret_cast<FinalizablePersistentHandle*>(addr);
if (!weak_persistent_handle->raw()->IsHeapObject()) {
return; // Free handle.
}
writer_->CountExternalProperty();
}
private:
HeapSnapshotWriter* const writer_;
DISALLOW_COPY_AND_ASSIGN(Pass1Visitor);
};
enum NonReferenceDataTags {
kNoData = 0,
kNullData,
kBoolData,
kIntData,
kDoubleData,
kLatin1Data,
kUTF16Data,
kLengthData,
kNameData,
};
static const intptr_t kMaxStringElements = 128;
class Pass2Visitor : public ObjectVisitor,
public ObjectPointerVisitor,
public HandleVisitor {
public:
explicit Pass2Visitor(HeapSnapshotWriter* writer)
: ObjectVisitor(),
ObjectPointerVisitor(IsolateGroup::Current()),
HandleVisitor(Thread::Current()),
isolate_(thread()->isolate()),
writer_(writer) {}
void VisitObject(ObjectPtr obj) {
if (obj->IsPseudoObject()) return;
intptr_t cid = obj->GetClassId();
writer_->WriteUnsigned(cid);
writer_->WriteUnsigned(discount_sizes_ ? 0 : obj->ptr()->HeapSize());
if (cid == kNullCid) {
writer_->WriteUnsigned(kNullData);
} else if (cid == kBoolCid) {
writer_->WriteUnsigned(kBoolData);
writer_->WriteUnsigned(
static_cast<uintptr_t>(static_cast<BoolPtr>(obj)->ptr()->value_));
} else if (cid == kSmiCid) {
UNREACHABLE();
} else if (cid == kMintCid) {
writer_->WriteUnsigned(kIntData);
writer_->WriteSigned(static_cast<MintPtr>(obj)->ptr()->value_);
} else if (cid == kDoubleCid) {
writer_->WriteUnsigned(kDoubleData);
writer_->WriteBytes(&(static_cast<DoublePtr>(obj)->ptr()->value_),
sizeof(double));
} else if (cid == kOneByteStringCid) {
OneByteStringPtr str = static_cast<OneByteStringPtr>(obj);
intptr_t len = Smi::Value(str->ptr()->length_);
intptr_t trunc_len = Utils::Minimum(len, kMaxStringElements);
writer_->WriteUnsigned(kLatin1Data);
writer_->WriteUnsigned(len);
writer_->WriteUnsigned(trunc_len);
writer_->WriteBytes(&str->ptr()->data()[0], trunc_len);
} else if (cid == kExternalOneByteStringCid) {
ExternalOneByteStringPtr str = static_cast<ExternalOneByteStringPtr>(obj);
intptr_t len = Smi::Value(str->ptr()->length_);
intptr_t trunc_len = Utils::Minimum(len, kMaxStringElements);
writer_->WriteUnsigned(kLatin1Data);
writer_->WriteUnsigned(len);
writer_->WriteUnsigned(trunc_len);
writer_->WriteBytes(&str->ptr()->external_data_[0], trunc_len);
} else if (cid == kTwoByteStringCid) {
TwoByteStringPtr str = static_cast<TwoByteStringPtr>(obj);
intptr_t len = Smi::Value(str->ptr()->length_);
intptr_t trunc_len = Utils::Minimum(len, kMaxStringElements);
writer_->WriteUnsigned(kUTF16Data);
writer_->WriteUnsigned(len);
writer_->WriteUnsigned(trunc_len);
writer_->WriteBytes(&str->ptr()->data()[0], trunc_len * 2);
} else if (cid == kExternalTwoByteStringCid) {
ExternalTwoByteStringPtr str = static_cast<ExternalTwoByteStringPtr>(obj);
intptr_t len = Smi::Value(str->ptr()->length_);
intptr_t trunc_len = Utils::Minimum(len, kMaxStringElements);
writer_->WriteUnsigned(kUTF16Data);
writer_->WriteUnsigned(len);
writer_->WriteUnsigned(trunc_len);
writer_->WriteBytes(&str->ptr()->external_data_[0], trunc_len * 2);
} else if (cid == kArrayCid || cid == kImmutableArrayCid) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(
Smi::Value(static_cast<ArrayPtr>(obj)->ptr()->length_));
} else if (cid == kGrowableObjectArrayCid) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(
Smi::Value(static_cast<GrowableObjectArrayPtr>(obj)->ptr()->length_));
} else if (cid == kLinkedHashMapCid) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(
Smi::Value(static_cast<LinkedHashMapPtr>(obj)->ptr()->used_data_));
} else if (cid == kObjectPoolCid) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(static_cast<ObjectPoolPtr>(obj)->ptr()->length_);
} else if (IsTypedDataClassId(cid)) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(
Smi::Value(static_cast<TypedDataPtr>(obj)->ptr()->length_));
} else if (IsExternalTypedDataClassId(cid)) {
writer_->WriteUnsigned(kLengthData);
writer_->WriteUnsigned(
Smi::Value(static_cast<ExternalTypedDataPtr>(obj)->ptr()->length_));
} else if (cid == kFunctionCid) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<FunctionPtr>(obj)->ptr()->name_);
} else if (cid == kCodeCid) {
ObjectPtr owner = static_cast<CodePtr>(obj)->ptr()->owner_;
if (owner->IsFunction()) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<FunctionPtr>(owner)->ptr()->name_);
} else if (owner->IsClass()) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<ClassPtr>(owner)->ptr()->name_);
} else {
writer_->WriteUnsigned(kNoData);
}
} else if (cid == kFieldCid) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<FieldPtr>(obj)->ptr()->name_);
} else if (cid == kClassCid) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<ClassPtr>(obj)->ptr()->name_);
} else if (cid == kLibraryCid) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<LibraryPtr>(obj)->ptr()->url_);
} else if (cid == kScriptCid) {
writer_->WriteUnsigned(kNameData);
ScrubAndWriteUtf8(static_cast<ScriptPtr>(obj)->ptr()->url_);
} else {
writer_->WriteUnsigned(kNoData);
}
DoCount();
obj->ptr()->VisitPointersPrecise(isolate_, this);
DoWrite();
obj->ptr()->VisitPointersPrecise(isolate_, this);
}
void ScrubAndWriteUtf8(StringPtr str) {
if (str == String::null()) {
writer_->WriteUtf8("null");
} else {
String handle;
handle = str;
char* value = handle.ToMallocCString();
writer_->ScrubAndWriteUtf8(value);
free(value);
}
}
void set_discount_sizes(bool value) { discount_sizes_ = value; }
void DoCount() {
writing_ = false;
counted_ = 0;
written_ = 0;
}
void DoWrite() {
writing_ = true;
writer_->WriteUnsigned(counted_);
}
void VisitPointers(ObjectPtr* from, ObjectPtr* to) {
if (writing_) {
for (ObjectPtr* ptr = from; ptr <= to; ptr++) {
ObjectPtr target = *ptr;
written_++;
total_++;
writer_->WriteUnsigned(writer_->GetObjectId(target));
}
} else {
intptr_t count = to - from + 1;
ASSERT(count >= 0);
counted_ += count;
}
}
void VisitHandle(uword addr) {
FinalizablePersistentHandle* weak_persistent_handle =
reinterpret_cast<FinalizablePersistentHandle*>(addr);
if (!weak_persistent_handle->raw()->IsHeapObject()) {
return; // Free handle.
}
writer_->WriteUnsigned(writer_->GetObjectId(weak_persistent_handle->raw()));
writer_->WriteUnsigned(weak_persistent_handle->external_size());
// Attempt to include a native symbol name.
auto const name = NativeSymbolResolver::LookupSymbolName(
weak_persistent_handle->callback_address(), nullptr);
writer_->WriteUtf8((name == nullptr) ? "Unknown native function" : name);
if (name != nullptr) {
NativeSymbolResolver::FreeSymbolName(name);
}
}
private:
// TODO(dartbug.com/36097): Once the shared class table contains more
// information than just the size (i.e. includes an immutable class
// descriptor), we can remove this dependency on the current isolate.
Isolate* isolate_;
HeapSnapshotWriter* const writer_;
bool writing_ = false;
intptr_t counted_ = 0;
intptr_t written_ = 0;
intptr_t total_ = 0;
bool discount_sizes_ = false;
DISALLOW_COPY_AND_ASSIGN(Pass2Visitor);
};
void HeapSnapshotWriter::Write() {
HeapIterationScope iteration(thread());
WriteBytes("dartheap", 8); // Magic value.
WriteUnsigned(0); // Flags.
WriteUtf8(isolate()->name());
Heap* H = thread()->heap();
{
intptr_t used = H->TotalUsedInWords() << kWordSizeLog2;
intptr_t capacity = H->TotalCapacityInWords() << kWordSizeLog2;
intptr_t external = H->TotalExternalInWords() << kWordSizeLog2;
intptr_t image = H->old_space()->ImageInWords() << kWordSizeLog2;
WriteUnsigned(used + image);
WriteUnsigned(capacity + image);
WriteUnsigned(external);
}
{
HANDLESCOPE(thread());
ClassTable* class_table = isolate()->class_table();
class_count_ = class_table->NumCids() - 1;
Class& cls = Class::Handle();
Library& lib = Library::Handle();
String& str = String::Handle();
Array& fields = Array::Handle();
Field& field = Field::Handle();
WriteUnsigned(class_count_);
for (intptr_t cid = 1; cid <= class_count_; cid++) {
if (!class_table->HasValidClassAt(cid)) {
WriteUnsigned(0); // Flags
WriteUtf8(""); // Name
WriteUtf8(""); // Library name
WriteUtf8(""); // Library uri
WriteUtf8(""); // Reserved
WriteUnsigned(0); // Field count
} else {
cls = class_table->At(cid);
WriteUnsigned(0); // Flags
str = cls.Name();
ScrubAndWriteUtf8(const_cast<char*>(str.ToCString()));
lib = cls.library();
if (lib.IsNull()) {
WriteUtf8("");
WriteUtf8("");
} else {
str = lib.name();
ScrubAndWriteUtf8(const_cast<char*>(str.ToCString()));
str = lib.url();
ScrubAndWriteUtf8(const_cast<char*>(str.ToCString()));
}
WriteUtf8(""); // Reserved
intptr_t field_count = 0;
intptr_t min_offset = kIntptrMax;
for (intptr_t j = 0; OffsetsTable::offsets_table[j].class_id != -1;
j++) {
if (OffsetsTable::offsets_table[j].class_id == cid) {
field_count++;
intptr_t offset = OffsetsTable::offsets_table[j].offset;
min_offset = Utils::Minimum(min_offset, offset);
}
}
if (cls.is_finalized()) {
do {
fields = cls.fields();
if (!fields.IsNull()) {
for (intptr_t i = 0; i < fields.Length(); i++) {
field ^= fields.At(i);
if (field.is_instance()) {
field_count++;
}
}
}
cls = cls.SuperClass();
} while (!cls.IsNull());
cls = class_table->At(cid);
}
WriteUnsigned(field_count);
for (intptr_t j = 0; OffsetsTable::offsets_table[j].class_id != -1;
j++) {
if (OffsetsTable::offsets_table[j].class_id == cid) {
intptr_t flags = 1; // Strong.
WriteUnsigned(flags);
intptr_t offset = OffsetsTable::offsets_table[j].offset;
intptr_t index = (offset - min_offset) / kWordSize;
ASSERT(index >= 0);
WriteUnsigned(index);
WriteUtf8(OffsetsTable::offsets_table[j].field_name);
WriteUtf8(""); // Reserved
}
}
if (cls.is_finalized()) {
do {
fields = cls.fields();
if (!fields.IsNull()) {
for (intptr_t i = 0; i < fields.Length(); i++) {
field ^= fields.At(i);
if (field.is_instance()) {
intptr_t flags = 1; // Strong.
WriteUnsigned(flags);
intptr_t index = field.HostOffset() / kWordSize - 1;
ASSERT(index >= 0);
WriteUnsigned(index);
str = field.name();
ScrubAndWriteUtf8(const_cast<char*>(str.ToCString()));
WriteUtf8(""); // Reserved
}
}
}
cls = cls.SuperClass();
} while (!cls.IsNull());
cls = class_table->At(cid);
}
}
}
}
SetupCountingPages();
{
Pass1Visitor visitor(this);
// Root "object".
++object_count_;
isolate()->VisitObjectPointers(&visitor,
ValidationPolicy::kDontValidateFrames);
// Heap objects.
iteration.IterateVMIsolateObjects(&visitor);
iteration.IterateObjects(&visitor);
// External properties.
isolate()->group()->VisitWeakPersistentHandles(&visitor);
}
{
Pass2Visitor visitor(this);
WriteUnsigned(reference_count_);
WriteUnsigned(object_count_);
// Root "object".
WriteUnsigned(0); // cid
WriteUnsigned(0); // shallowSize
WriteUnsigned(kNoData);
visitor.DoCount();
isolate()->VisitObjectPointers(&visitor,
ValidationPolicy::kDontValidateFrames);
visitor.DoWrite();
isolate()->VisitObjectPointers(&visitor,
ValidationPolicy::kDontValidateFrames);
// Heap objects.
visitor.set_discount_sizes(true);
iteration.IterateVMIsolateObjects(&visitor);
visitor.set_discount_sizes(false);
iteration.IterateObjects(&visitor);
// External properties.
WriteUnsigned(external_property_count_);
isolate()->group()->VisitWeakPersistentHandles(&visitor);
}
ClearObjectIds();
Flush(true);
}
CountObjectsVisitor::CountObjectsVisitor(Thread* thread, intptr_t class_count)
: ObjectVisitor(),
HandleVisitor(thread),
new_count_(new intptr_t[class_count]),
new_size_(new intptr_t[class_count]),
new_external_size_(new intptr_t[class_count]),
old_count_(new intptr_t[class_count]),
old_size_(new intptr_t[class_count]),
old_external_size_(new intptr_t[class_count]) {
memset(new_count_.get(), 0, class_count * sizeof(intptr_t));
memset(new_size_.get(), 0, class_count * sizeof(intptr_t));
memset(new_external_size_.get(), 0, class_count * sizeof(intptr_t));
memset(old_count_.get(), 0, class_count * sizeof(intptr_t));
memset(old_size_.get(), 0, class_count * sizeof(intptr_t));
memset(old_external_size_.get(), 0, class_count * sizeof(intptr_t));
}
void CountObjectsVisitor::VisitObject(ObjectPtr obj) {
intptr_t cid = obj->GetClassId();
intptr_t size = obj->ptr()->HeapSize();
if (obj->IsNewObject()) {
new_count_[cid] += 1;
new_size_[cid] += size;
} else {
old_count_[cid] += 1;
old_size_[cid] += size;
}
}
void CountObjectsVisitor::VisitHandle(uword addr) {
FinalizablePersistentHandle* handle =
reinterpret_cast<FinalizablePersistentHandle*>(addr);
ObjectPtr obj = handle->raw();
if (!obj->IsHeapObject()) {
return;
}
intptr_t cid = obj->GetClassId();
intptr_t size = handle->external_size();
if (obj->IsNewObject()) {
new_external_size_[cid] += size;
} else {
old_external_size_[cid] += size;
}
}
#endif // !defined(PRODUCT)
} // namespace dart