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// Copyright 2011 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef V8_PROFILE_GENERATOR_H_
#define V8_PROFILE_GENERATOR_H_
#include "allocation.h"
#include "hashmap.h"
#include "../include/v8-profiler.h"
namespace v8 {
namespace internal {
class TokenEnumerator {
public:
TokenEnumerator();
~TokenEnumerator();
int GetTokenId(Object* token);
static const int kNoSecurityToken = -1;
static const int kInheritsSecurityToken = -2;
private:
static void TokenRemovedCallback(v8::Persistent<v8::Value> handle,
void* parameter);
void TokenRemoved(Object** token_location);
List<Object**> token_locations_;
List<bool> token_removed_;
friend class TokenEnumeratorTester;
DISALLOW_COPY_AND_ASSIGN(TokenEnumerator);
};
// Provides a storage of strings allocated in C++ heap, to hold them
// forever, even if they disappear from JS heap or external storage.
class StringsStorage {
public:
StringsStorage();
~StringsStorage();
const char* GetCopy(const char* src);
const char* GetFormatted(const char* format, ...);
const char* GetVFormatted(const char* format, va_list args);
const char* GetName(String* name);
const char* GetName(int index);
inline const char* GetFunctionName(String* name);
inline const char* GetFunctionName(const char* name);
private:
static const int kMaxNameSize = 1024;
INLINE(static bool StringsMatch(void* key1, void* key2)) {
return strcmp(reinterpret_cast<char*>(key1),
reinterpret_cast<char*>(key2)) == 0;
}
const char* AddOrDisposeString(char* str, uint32_t hash);
// Mapping of strings by String::Hash to const char* strings.
HashMap names_;
DISALLOW_COPY_AND_ASSIGN(StringsStorage);
};
class CodeEntry {
public:
// CodeEntry doesn't own name strings, just references them.
INLINE(CodeEntry(Logger::LogEventsAndTags tag,
const char* name_prefix,
const char* name,
const char* resource_name,
int line_number,
int security_token_id));
INLINE(bool is_js_function() const) { return is_js_function_tag(tag_); }
INLINE(const char* name_prefix() const) { return name_prefix_; }
INLINE(bool has_name_prefix() const) { return name_prefix_[0] != '\0'; }
INLINE(const char* name() const) { return name_; }
INLINE(const char* resource_name() const) { return resource_name_; }
INLINE(int line_number() const) { return line_number_; }
INLINE(int shared_id() const) { return shared_id_; }
INLINE(void set_shared_id(int shared_id)) { shared_id_ = shared_id; }
INLINE(int security_token_id() const) { return security_token_id_; }
INLINE(static bool is_js_function_tag(Logger::LogEventsAndTags tag));
void CopyData(const CodeEntry& source);
uint32_t GetCallUid() const;
bool IsSameAs(CodeEntry* entry) const;
static const char* const kEmptyNamePrefix;
private:
Logger::LogEventsAndTags tag_;
const char* name_prefix_;
const char* name_;
const char* resource_name_;
int line_number_;
int shared_id_;
int security_token_id_;
DISALLOW_COPY_AND_ASSIGN(CodeEntry);
};
class ProfileTree;
class ProfileNode {
public:
INLINE(ProfileNode(ProfileTree* tree, CodeEntry* entry));
ProfileNode* FindChild(CodeEntry* entry);
ProfileNode* FindOrAddChild(CodeEntry* entry);
INLINE(void IncrementSelfTicks()) { ++self_ticks_; }
INLINE(void IncreaseSelfTicks(unsigned amount)) { self_ticks_ += amount; }
INLINE(void IncreaseTotalTicks(unsigned amount)) { total_ticks_ += amount; }
INLINE(CodeEntry* entry() const) { return entry_; }
INLINE(unsigned self_ticks() const) { return self_ticks_; }
INLINE(unsigned total_ticks() const) { return total_ticks_; }
INLINE(const List<ProfileNode*>* children() const) { return &children_list_; }
double GetSelfMillis() const;
double GetTotalMillis() const;
void Print(int indent);
private:
INLINE(static bool CodeEntriesMatch(void* entry1, void* entry2)) {
return reinterpret_cast<CodeEntry*>(entry1)->IsSameAs(
reinterpret_cast<CodeEntry*>(entry2));
}
INLINE(static uint32_t CodeEntryHash(CodeEntry* entry)) {
return entry->GetCallUid();
}
ProfileTree* tree_;
CodeEntry* entry_;
unsigned total_ticks_;
unsigned self_ticks_;
// Mapping from CodeEntry* to ProfileNode*
HashMap children_;
List<ProfileNode*> children_list_;
DISALLOW_COPY_AND_ASSIGN(ProfileNode);
};
class ProfileTree {
public:
ProfileTree();
~ProfileTree();
void AddPathFromEnd(const Vector<CodeEntry*>& path);
void AddPathFromStart(const Vector<CodeEntry*>& path);
void CalculateTotalTicks();
void FilteredClone(ProfileTree* src, int security_token_id);
double TicksToMillis(unsigned ticks) const {
return ticks * ms_to_ticks_scale_;
}
ProfileNode* root() const { return root_; }
void SetTickRatePerMs(double ticks_per_ms);
void ShortPrint();
void Print() {
root_->Print(0);
}
private:
template <typename Callback>
void TraverseDepthFirst(Callback* callback);
CodeEntry root_entry_;
ProfileNode* root_;
double ms_to_ticks_scale_;
DISALLOW_COPY_AND_ASSIGN(ProfileTree);
};
class CpuProfile {
public:
CpuProfile(const char* title, unsigned uid)
: title_(title), uid_(uid) { }
// Add pc -> ... -> main() call path to the profile.
void AddPath(const Vector<CodeEntry*>& path);
void CalculateTotalTicks();
void SetActualSamplingRate(double actual_sampling_rate);
CpuProfile* FilteredClone(int security_token_id);
INLINE(const char* title() const) { return title_; }
INLINE(unsigned uid() const) { return uid_; }
INLINE(const ProfileTree* top_down() const) { return &top_down_; }
INLINE(const ProfileTree* bottom_up() const) { return &bottom_up_; }
void UpdateTicksScale();
void ShortPrint();
void Print();
private:
const char* title_;
unsigned uid_;
ProfileTree top_down_;
ProfileTree bottom_up_;
DISALLOW_COPY_AND_ASSIGN(CpuProfile);
};
class CodeMap {
public:
CodeMap() : next_shared_id_(1) { }
void AddCode(Address addr, CodeEntry* entry, unsigned size);
void MoveCode(Address from, Address to);
CodeEntry* FindEntry(Address addr);
int GetSharedId(Address addr);
void Print();
private:
struct CodeEntryInfo {
CodeEntryInfo(CodeEntry* an_entry, unsigned a_size)
: entry(an_entry), size(a_size) { }
CodeEntry* entry;
unsigned size;
};
struct CodeTreeConfig {
typedef Address Key;
typedef CodeEntryInfo Value;
static const Key kNoKey;
static const Value NoValue() { return CodeEntryInfo(NULL, 0); }
static int Compare(const Key& a, const Key& b) {
return a < b ? -1 : (a > b ? 1 : 0);
}
};
typedef SplayTree<CodeTreeConfig> CodeTree;
class CodeTreePrinter {
public:
void Call(const Address& key, const CodeEntryInfo& value);
};
void DeleteAllCoveredCode(Address start, Address end);
// Fake CodeEntry pointer to distinguish shared function entries.
static CodeEntry* const kSharedFunctionCodeEntry;
CodeTree tree_;
int next_shared_id_;
DISALLOW_COPY_AND_ASSIGN(CodeMap);
};
class CpuProfilesCollection {
public:
CpuProfilesCollection();
~CpuProfilesCollection();
bool StartProfiling(const char* title, unsigned uid);
bool StartProfiling(String* title, unsigned uid);
CpuProfile* StopProfiling(int security_token_id,
const char* title,
double actual_sampling_rate);
List<CpuProfile*>* Profiles(int security_token_id);
const char* GetName(String* name) {
return function_and_resource_names_.GetName(name);
}
const char* GetName(int args_count) {
return function_and_resource_names_.GetName(args_count);
}
CpuProfile* GetProfile(int security_token_id, unsigned uid);
bool IsLastProfile(const char* title);
void RemoveProfile(CpuProfile* profile);
bool HasDetachedProfiles() { return detached_profiles_.length() > 0; }
CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
String* name, String* resource_name, int line_number);
CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag, const char* name);
CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
const char* name_prefix, String* name);
CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag, int args_count);
CodeEntry* NewCodeEntry(int security_token_id);
// Called from profile generator thread.
void AddPathToCurrentProfiles(const Vector<CodeEntry*>& path);
// Limits the number of profiles that can be simultaneously collected.
static const int kMaxSimultaneousProfiles = 100;
private:
const char* GetFunctionName(String* name) {
return function_and_resource_names_.GetFunctionName(name);
}
const char* GetFunctionName(const char* name) {
return function_and_resource_names_.GetFunctionName(name);
}
int GetProfileIndex(unsigned uid);
List<CpuProfile*>* GetProfilesList(int security_token_id);
int TokenToIndex(int security_token_id);
INLINE(static bool UidsMatch(void* key1, void* key2)) {
return key1 == key2;
}
StringsStorage function_and_resource_names_;
List<CodeEntry*> code_entries_;
List<List<CpuProfile*>* > profiles_by_token_;
// Mapping from profiles' uids to indexes in the second nested list
// of profiles_by_token_.
HashMap profiles_uids_;
List<CpuProfile*> detached_profiles_;
// Accessed by VM thread and profile generator thread.
List<CpuProfile*> current_profiles_;
Semaphore* current_profiles_semaphore_;
DISALLOW_COPY_AND_ASSIGN(CpuProfilesCollection);
};
class SampleRateCalculator {
public:
SampleRateCalculator()
: result_(Logger::kSamplingIntervalMs * kResultScale),
ticks_per_ms_(Logger::kSamplingIntervalMs),
measurements_count_(0),
wall_time_query_countdown_(1) {
}
double ticks_per_ms() {
return result_ / static_cast<double>(kResultScale);
}
void Tick();
void UpdateMeasurements(double current_time);
// Instead of querying current wall time each tick,
// we use this constant to control query intervals.
static const unsigned kWallTimeQueryIntervalMs = 100;
private:
// As the result needs to be accessed from a different thread, we
// use type that guarantees atomic writes to memory. There should
// be <= 1000 ticks per second, thus storing a value of a 10 ** 5
// order should provide enough precision while keeping away from a
// potential overflow.
static const int kResultScale = 100000;
AtomicWord result_;
// All other fields are accessed only from the sampler thread.
double ticks_per_ms_;
unsigned measurements_count_;
unsigned wall_time_query_countdown_;
double last_wall_time_;
DISALLOW_COPY_AND_ASSIGN(SampleRateCalculator);
};
class ProfileGenerator {
public:
explicit ProfileGenerator(CpuProfilesCollection* profiles);
INLINE(CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
String* name,
String* resource_name,
int line_number)) {
return profiles_->NewCodeEntry(tag, name, resource_name, line_number);
}
INLINE(CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
const char* name)) {
return profiles_->NewCodeEntry(tag, name);
}
INLINE(CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
const char* name_prefix,
String* name)) {
return profiles_->NewCodeEntry(tag, name_prefix, name);
}
INLINE(CodeEntry* NewCodeEntry(Logger::LogEventsAndTags tag,
int args_count)) {
return profiles_->NewCodeEntry(tag, args_count);
}
INLINE(CodeEntry* NewCodeEntry(int security_token_id)) {
return profiles_->NewCodeEntry(security_token_id);
}
void RecordTickSample(const TickSample& sample);
INLINE(CodeMap* code_map()) { return &code_map_; }
INLINE(void Tick()) { sample_rate_calc_.Tick(); }
INLINE(double actual_sampling_rate()) {
return sample_rate_calc_.ticks_per_ms();
}
static const char* const kAnonymousFunctionName;
static const char* const kProgramEntryName;
static const char* const kGarbageCollectorEntryName;
private:
INLINE(CodeEntry* EntryForVMState(StateTag tag));
CpuProfilesCollection* profiles_;
CodeMap code_map_;
CodeEntry* program_entry_;
CodeEntry* gc_entry_;
SampleRateCalculator sample_rate_calc_;
DISALLOW_COPY_AND_ASSIGN(ProfileGenerator);
};
class HeapEntry;
class HeapGraphEdge BASE_EMBEDDED {
public:
enum Type {
kContextVariable = v8::HeapGraphEdge::kContextVariable,
kElement = v8::HeapGraphEdge::kElement,
kProperty = v8::HeapGraphEdge::kProperty,
kInternal = v8::HeapGraphEdge::kInternal,
kHidden = v8::HeapGraphEdge::kHidden,
kShortcut = v8::HeapGraphEdge::kShortcut,
kWeak = v8::HeapGraphEdge::kWeak
};
HeapGraphEdge() { }
void Init(int child_index, Type type, const char* name, HeapEntry* to);
void Init(int child_index, Type type, int index, HeapEntry* to);
void Init(int child_index, int index, HeapEntry* to);
Type type() { return static_cast<Type>(type_); }
int index() {
ASSERT(type_ == kElement || type_ == kHidden || type_ == kWeak);
return index_;
}
const char* name() {
ASSERT(type_ == kContextVariable
|| type_ == kProperty
|| type_ == kInternal
|| type_ == kShortcut);
return name_;
}
HeapEntry* to() { return to_; }
HeapEntry* From();
private:
int child_index_ : 29;
unsigned type_ : 3;
union {
int index_;
const char* name_;
};
HeapEntry* to_;
DISALLOW_COPY_AND_ASSIGN(HeapGraphEdge);
};
class HeapSnapshot;
// HeapEntry instances represent an entity from the heap (or a special
// virtual node, e.g. root). To make heap snapshots more compact,
// HeapEntries has a special memory layout (no Vectors or Lists used):
//
// +-----------------+
// HeapEntry
// +-----------------+
// HeapGraphEdge |
// ... } children_count
// HeapGraphEdge |
// +-----------------+
// HeapGraphEdge* |
// ... } retainers_count
// HeapGraphEdge* |
// +-----------------+
//
// In a HeapSnapshot, all entries are hand-allocated in a continuous array
// of raw bytes.
//
class HeapEntry BASE_EMBEDDED {
public:
enum Type {
kHidden = v8::HeapGraphNode::kHidden,
kArray = v8::HeapGraphNode::kArray,
kString = v8::HeapGraphNode::kString,
kObject = v8::HeapGraphNode::kObject,
kCode = v8::HeapGraphNode::kCode,
kClosure = v8::HeapGraphNode::kClosure,
kRegExp = v8::HeapGraphNode::kRegExp,
kHeapNumber = v8::HeapGraphNode::kHeapNumber,
kNative = v8::HeapGraphNode::kNative
};
HeapEntry() { }
void Init(HeapSnapshot* snapshot,
Type type,
const char* name,
uint64_t id,
int self_size,
int children_count,
int retainers_count);
HeapSnapshot* snapshot() { return snapshot_; }
Type type() { return static_cast<Type>(type_); }
const char* name() { return name_; }
inline uint64_t id();
int self_size() { return self_size_; }
int retained_size() { return retained_size_; }
void add_retained_size(int size) { retained_size_ += size; }
void set_retained_size(int value) { retained_size_ = value; }
int ordered_index() { return ordered_index_; }
void set_ordered_index(int value) { ordered_index_ = value; }
Vector<HeapGraphEdge> children() {
return Vector<HeapGraphEdge>(children_arr(), children_count_); }
Vector<HeapGraphEdge*> retainers() {
return Vector<HeapGraphEdge*>(retainers_arr(), retainers_count_); }
HeapEntry* dominator() { return dominator_; }
void set_dominator(HeapEntry* entry) {
ASSERT(entry != NULL);
dominator_ = entry;
}
void clear_paint() { painted_ = kUnpainted; }
bool painted_reachable() { return painted_ == kPainted; }
void paint_reachable() {
ASSERT(painted_ == kUnpainted);
painted_ = kPainted;
}
bool not_painted_reachable_from_others() {
return painted_ != kPaintedReachableFromOthers;
}
void paint_reachable_from_others() {
painted_ = kPaintedReachableFromOthers;
}
template<class Visitor>
void ApplyAndPaintAllReachable(Visitor* visitor);
void PaintAllReachable();
void SetIndexedReference(HeapGraphEdge::Type type,
int child_index,
int index,
HeapEntry* entry,
int retainer_index);
void SetNamedReference(HeapGraphEdge::Type type,
int child_index,
const char* name,
HeapEntry* entry,
int retainer_index);
void SetUnidirElementReference(int child_index, int index, HeapEntry* entry);
int EntrySize() { return EntriesSize(1, children_count_, retainers_count_); }
int RetainedSize(bool exact);
void Print(
const char* prefix, const char* edge_name, int max_depth, int indent);
Handle<HeapObject> GetHeapObject();
static int EntriesSize(int entries_count,
int children_count,
int retainers_count);
private:
HeapGraphEdge* children_arr() {
return reinterpret_cast<HeapGraphEdge*>(this + 1);
}
HeapGraphEdge** retainers_arr() {
return reinterpret_cast<HeapGraphEdge**>(children_arr() + children_count_);
}
void CalculateExactRetainedSize();
const char* TypeAsString();
unsigned painted_: 2;
unsigned type_: 4;
int children_count_: 26;
int retainers_count_;
int self_size_;
union {
int ordered_index_; // Used during dominator tree building.
int retained_size_; // At that moment, there is no retained size yet.
};
HeapEntry* dominator_;
HeapSnapshot* snapshot_;
struct Id {
uint32_t id1_;
uint32_t id2_;
} id_; // This is to avoid extra padding of 64-bit value.
const char* name_;
// Paints used for exact retained sizes calculation.
static const unsigned kUnpainted = 0;
static const unsigned kPainted = 1;
static const unsigned kPaintedReachableFromOthers = 2;
static const int kExactRetainedSizeTag = 1;
DISALLOW_COPY_AND_ASSIGN(HeapEntry);
};
class HeapSnapshotsCollection;
// HeapSnapshot represents a single heap snapshot. It is stored in
// HeapSnapshotsCollection, which is also a factory for
// HeapSnapshots. All HeapSnapshots share strings copied from JS heap
// to be able to return them even if they were collected.
// HeapSnapshotGenerator fills in a HeapSnapshot.
class HeapSnapshot {
public:
enum Type {
kFull = v8::HeapSnapshot::kFull
};
HeapSnapshot(HeapSnapshotsCollection* collection,
Type type,
const char* title,
unsigned uid);
~HeapSnapshot();
void Delete();
HeapSnapshotsCollection* collection() { return collection_; }
Type type() { return type_; }
const char* title() { return title_; }
unsigned uid() { return uid_; }
HeapEntry* root() { return root_entry_; }
HeapEntry* gc_roots() { return gc_roots_entry_; }
HeapEntry* natives_root() { return natives_root_entry_; }
HeapEntry* gc_subroot(int index) { return gc_subroot_entries_[index]; }
List<HeapEntry*>* entries() { return &entries_; }
int raw_entries_size() { return raw_entries_size_; }
void AllocateEntries(
int entries_count, int children_count, int retainers_count);
HeapEntry* AddEntry(HeapEntry::Type type,
const char* name,
uint64_t id,
int size,
int children_count,
int retainers_count);
HeapEntry* AddRootEntry(int children_count);
HeapEntry* AddGcRootsEntry(int children_count, int retainers_count);
HeapEntry* AddGcSubrootEntry(int tag,
int children_count,
int retainers_count);
HeapEntry* AddNativesRootEntry(int children_count, int retainers_count);
void ClearPaint();
HeapEntry* GetEntryById(uint64_t id);
List<HeapEntry*>* GetSortedEntriesList();
template<class Visitor>
void IterateEntries(Visitor* visitor) { entries_.Iterate(visitor); }
void SetDominatorsToSelf();
void Print(int max_depth);
void PrintEntriesSize();
private:
HeapEntry* GetNextEntryToInit();
HeapSnapshotsCollection* collection_;
Type type_;
const char* title_;
unsigned uid_;
HeapEntry* root_entry_;
HeapEntry* gc_roots_entry_;
HeapEntry* natives_root_entry_;
HeapEntry* gc_subroot_entries_[VisitorSynchronization::kNumberOfSyncTags];
char* raw_entries_;
List<HeapEntry*> entries_;
bool entries_sorted_;
int raw_entries_size_;
friend class HeapSnapshotTester;
DISALLOW_COPY_AND_ASSIGN(HeapSnapshot);
};
class HeapObjectsMap {
public:
HeapObjectsMap();
~HeapObjectsMap();
void SnapshotGenerationFinished();
uint64_t FindObject(Address addr);
void MoveObject(Address from, Address to);
static uint64_t GenerateId(v8::RetainedObjectInfo* info);
static inline uint64_t GetNthGcSubrootId(int delta);
static const int kObjectIdStep = 2;
static const uint64_t kInternalRootObjectId;
static const uint64_t kGcRootsObjectId;
static const uint64_t kNativesRootObjectId;
static const uint64_t kGcRootsFirstSubrootId;
static const uint64_t kFirstAvailableObjectId;
private:
struct EntryInfo {
explicit EntryInfo(uint64_t id) : id(id), accessed(true) { }
EntryInfo(uint64_t id, bool accessed) : id(id), accessed(accessed) { }
uint64_t id;
bool accessed;
};
void AddEntry(Address addr, uint64_t id);
uint64_t FindEntry(Address addr);
void RemoveDeadEntries();
static bool AddressesMatch(void* key1, void* key2) {
return key1 == key2;
}
static uint32_t AddressHash(Address addr) {
return ComputeIntegerHash(
static_cast<uint32_t>(reinterpret_cast<uintptr_t>(addr)),
v8::internal::kZeroHashSeed);
}
bool initial_fill_mode_;
uint64_t next_id_;
HashMap entries_map_;
List<EntryInfo>* entries_;
DISALLOW_COPY_AND_ASSIGN(HeapObjectsMap);
};
class HeapSnapshotsCollection {
public:
HeapSnapshotsCollection();
~HeapSnapshotsCollection();
bool is_tracking_objects() { return is_tracking_objects_; }
HeapSnapshot* NewSnapshot(
HeapSnapshot::Type type, const char* name, unsigned uid);
void SnapshotGenerationFinished(HeapSnapshot* snapshot);
List<HeapSnapshot*>* snapshots() { return &snapshots_; }
HeapSnapshot* GetSnapshot(unsigned uid);
void RemoveSnapshot(HeapSnapshot* snapshot);
StringsStorage* names() { return &names_; }
TokenEnumerator* token_enumerator() { return token_enumerator_; }
uint64_t GetObjectId(Address addr) { return ids_.FindObject(addr); }
Handle<HeapObject> FindHeapObjectById(uint64_t id);
void ObjectMoveEvent(Address from, Address to) { ids_.MoveObject(from, to); }
private:
INLINE(static bool HeapSnapshotsMatch(void* key1, void* key2)) {
return key1 == key2;
}
bool is_tracking_objects_; // Whether tracking object moves is needed.
List<HeapSnapshot*> snapshots_;
// Mapping from snapshots' uids to HeapSnapshot* pointers.
HashMap snapshots_uids_;
StringsStorage names_;
TokenEnumerator* token_enumerator_;
// Mapping from HeapObject addresses to objects' uids.
HeapObjectsMap ids_;
DISALLOW_COPY_AND_ASSIGN(HeapSnapshotsCollection);
};
// A typedef for referencing anything that can be snapshotted living
// in any kind of heap memory.
typedef void* HeapThing;
// An interface that creates HeapEntries by HeapThings.
class HeapEntriesAllocator {
public:
virtual ~HeapEntriesAllocator() { }
virtual HeapEntry* AllocateEntry(
HeapThing ptr, int children_count, int retainers_count) = 0;
};
// The HeapEntriesMap instance is used to track a mapping between
// real heap objects and their representations in heap snapshots.
class HeapEntriesMap {
public:
HeapEntriesMap();
~HeapEntriesMap();
void AllocateEntries();
HeapEntry* Map(HeapThing thing);
void Pair(HeapThing thing, HeapEntriesAllocator* allocator, HeapEntry* entry);
void CountReference(HeapThing from, HeapThing to,
int* prev_children_count = NULL,
int* prev_retainers_count = NULL);
int entries_count() { return entries_count_; }
int total_children_count() { return total_children_count_; }
int total_retainers_count() { return total_retainers_count_; }
static HeapEntry* const kHeapEntryPlaceholder;
private:
struct EntryInfo {
EntryInfo(HeapEntry* entry, HeapEntriesAllocator* allocator)
: entry(entry),
allocator(allocator),
children_count(0),
retainers_count(0) {
}
HeapEntry* entry;
HeapEntriesAllocator* allocator;
int children_count;
int retainers_count;
};
static uint32_t Hash(HeapThing thing) {
return ComputeIntegerHash(
static_cast<uint32_t>(reinterpret_cast<uintptr_t>(thing)),
v8::internal::kZeroHashSeed);
}
static bool HeapThingsMatch(HeapThing key1, HeapThing key2) {
return key1 == key2;
}
HashMap entries_;
int entries_count_;
int total_children_count_;
int total_retainers_count_;
friend class HeapObjectsSet;
DISALLOW_COPY_AND_ASSIGN(HeapEntriesMap);
};
class HeapObjectsSet {
public:
HeapObjectsSet();
void Clear();
bool Contains(Object* object);
void Insert(Object* obj);
const char* GetTag(Object* obj);
void SetTag(Object* obj, const char* tag);
private:
HashMap entries_;
DISALLOW_COPY_AND_ASSIGN(HeapObjectsSet);
};
// An interface used to populate a snapshot with nodes and edges.
class SnapshotFillerInterface {
public:
virtual ~SnapshotFillerInterface() { }
virtual HeapEntry* AddEntry(HeapThing ptr,
HeapEntriesAllocator* allocator) = 0;
virtual HeapEntry* FindEntry(HeapThing ptr) = 0;
virtual HeapEntry* FindOrAddEntry(HeapThing ptr,
HeapEntriesAllocator* allocator) = 0;
virtual void SetIndexedReference(HeapGraphEdge::Type type,
HeapThing parent_ptr,
HeapEntry* parent_entry,
int index,
HeapThing child_ptr,
HeapEntry* child_entry) = 0;
virtual void SetIndexedAutoIndexReference(HeapGraphEdge::Type type,
HeapThing parent_ptr,
HeapEntry* parent_entry,
HeapThing child_ptr,
HeapEntry* child_entry) = 0;
virtual void SetNamedReference(HeapGraphEdge::Type type,
HeapThing parent_ptr,
HeapEntry* parent_entry,
const char* reference_name,
HeapThing child_ptr,
HeapEntry* child_entry) = 0;
virtual void SetNamedAutoIndexReference(HeapGraphEdge::Type type,
HeapThing parent_ptr,
HeapEntry* parent_entry,
HeapThing child_ptr,
HeapEntry* child_entry) = 0;
};
class SnapshottingProgressReportingInterface {
public:
virtual ~SnapshottingProgressReportingInterface() { }
virtual void ProgressStep() = 0;
virtual bool ProgressReport(bool force) = 0;
};
// An implementation of V8 heap graph extractor.
class V8HeapExplorer : public HeapEntriesAllocator {
public:
V8HeapExplorer(HeapSnapshot* snapshot,
SnapshottingProgressReportingInterface* progress);
virtual ~V8HeapExplorer();
virtual HeapEntry* AllocateEntry(
HeapThing ptr, int children_count, int retainers_count);
void AddRootEntries(SnapshotFillerInterface* filler);
int EstimateObjectsCount(HeapIterator* iterator);
bool IterateAndExtractReferences(SnapshotFillerInterface* filler);
void TagGlobalObjects();
static String* GetConstructorName(JSObject* object);
static HeapObject* const kInternalRootObject;
private:
HeapEntry* AddEntry(
HeapObject* object, int children_count, int retainers_count);
HeapEntry* AddEntry(HeapObject* object,
HeapEntry::Type type,
const char* name,
int children_count,
int retainers_count);
const char* GetSystemEntryName(HeapObject* object);
void ExtractReferences(HeapObject* obj);
void ExtractClosureReferences(JSObject* js_obj, HeapEntry* entry);
void ExtractPropertyReferences(JSObject* js_obj, HeapEntry* entry);
void ExtractElementReferences(JSObject* js_obj, HeapEntry* entry);
void ExtractInternalReferences(JSObject* js_obj, HeapEntry* entry);
void SetClosureReference(HeapObject* parent_obj,
HeapEntry* parent,
String* reference_name,
Object* child);
void SetElementReference(HeapObject* parent_obj,
HeapEntry* parent,
int index,
Object* child);
void SetInternalReference(HeapObject* parent_obj,
HeapEntry* parent,
const char* reference_name,
Object* child,
int field_offset = -1);
void SetInternalReference(HeapObject* parent_obj,
HeapEntry* parent,
int index,
Object* child,
int field_offset = -1);
void SetHiddenReference(HeapObject* parent_obj,
HeapEntry* parent,
int index,
Object* child);
void SetWeakReference(HeapObject* parent_obj,
HeapEntry* parent_entry,
int index,
Object* child_obj,
int field_offset);
void SetPropertyReference(HeapObject* parent_obj,
HeapEntry* parent,
String* reference_name,
Object* child,
const char* name_format_string = NULL,
int field_offset = -1);
void SetPropertyShortcutReference(HeapObject* parent_obj,
HeapEntry* parent,
String* reference_name,
Object* child);
void SetRootShortcutReference(Object* child);
void SetRootGcRootsReference();
void SetGcRootsReference(VisitorSynchronization::SyncTag tag);
void SetGcSubrootReference(
VisitorSynchronization::SyncTag tag, bool is_weak, Object* child);
void TagObject(Object* obj, const char* tag);
HeapEntry* GetEntry(Object* obj);
static inline HeapObject* GetNthGcSubrootObject(int delta);
static inline int GetGcSubrootOrder(HeapObject* subroot);
Heap* heap_;
HeapSnapshot* snapshot_;
HeapSnapshotsCollection* collection_;
SnapshottingProgressReportingInterface* progress_;
SnapshotFillerInterface* filler_;
HeapObjectsSet objects_tags_;
static HeapObject* const kGcRootsObject;
static HeapObject* const kFirstGcSubrootObject;
static HeapObject* const kLastGcSubrootObject;
friend class IndexedReferencesExtractor;
friend class GcSubrootsEnumerator;
friend class RootsReferencesExtractor;
DISALLOW_COPY_AND_ASSIGN(V8HeapExplorer);
};
// An implementation of retained native objects extractor.
class NativeObjectsExplorer : public HeapEntriesAllocator {
public:
NativeObjectsExplorer(HeapSnapshot* snapshot,
SnapshottingProgressReportingInterface* progress);
virtual ~NativeObjectsExplorer();
virtual HeapEntry* AllocateEntry(
HeapThing ptr, int children_count, int retainers_count);
void AddRootEntries(SnapshotFillerInterface* filler);
int EstimateObjectsCount();
bool IterateAndExtractReferences(SnapshotFillerInterface* filler);
private:
void FillRetainedObjects();
List<HeapObject*>* GetListMaybeDisposeInfo(v8::RetainedObjectInfo* info);
void SetNativeRootReference(v8::RetainedObjectInfo* info);
void SetRootNativesRootReference();
void SetWrapperNativeReferences(HeapObject* wrapper,
v8::RetainedObjectInfo* info);
void VisitSubtreeWrapper(Object** p, uint16_t class_id);
static uint32_t InfoHash(v8::RetainedObjectInfo* info) {
return ComputeIntegerHash(static_cast<uint32_t>(info->GetHash()),
v8::internal::kZeroHashSeed);
}
static bool RetainedInfosMatch(void* key1, void* key2) {
return key1 == key2 ||
(reinterpret_cast<v8::RetainedObjectInfo*>(key1))->IsEquivalent(
reinterpret_cast<v8::RetainedObjectInfo*>(key2));
}
HeapSnapshot* snapshot_;
HeapSnapshotsCollection* collection_;
SnapshottingProgressReportingInterface* progress_;
bool embedder_queried_;
HeapObjectsSet in_groups_;
// RetainedObjectInfo* -> List<HeapObject*>*
HashMap objects_by_info_;
// Used during references extraction.
SnapshotFillerInterface* filler_;
static HeapThing const kNativesRootObject;
friend class GlobalHandlesExtractor;
DISALLOW_COPY_AND_ASSIGN(NativeObjectsExplorer);
};
class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface {
public:
HeapSnapshotGenerator(HeapSnapshot* snapshot,
v8::ActivityControl* control);
bool GenerateSnapshot();
private:
bool ApproximateRetainedSizes();
bool BuildDominatorTree(const Vector<HeapEntry*>& entries,
Vector<HeapEntry*>* dominators);
bool CountEntriesAndReferences();
bool FillReferences();
void FillReversePostorderIndexes(Vector<HeapEntry*>* entries);
void ProgressStep();
bool ProgressReport(bool force = false);
bool SetEntriesDominators();
void SetProgressTotal(int iterations_count);
HeapSnapshot* snapshot_;
v8::ActivityControl* control_;
V8HeapExplorer v8_heap_explorer_;
NativeObjectsExplorer dom_explorer_;
// Mapping from HeapThing pointers to HeapEntry* pointers.
HeapEntriesMap entries_;
// Used during snapshot generation.
int progress_counter_;
int progress_total_;
DISALLOW_COPY_AND_ASSIGN(HeapSnapshotGenerator);
};
class OutputStreamWriter;
class HeapSnapshotJSONSerializer {
public:
explicit HeapSnapshotJSONSerializer(HeapSnapshot* snapshot)
: snapshot_(snapshot),
nodes_(ObjectsMatch),
strings_(ObjectsMatch),
next_node_id_(1),
next_string_id_(1),
writer_(NULL) {
}
void Serialize(v8::OutputStream* stream);
private:
INLINE(static bool ObjectsMatch(void* key1, void* key2)) {
return key1 == key2;
}
INLINE(static uint32_t ObjectHash(const void* key)) {
return ComputeIntegerHash(
static_cast<uint32_t>(reinterpret_cast<uintptr_t>(key)),
v8::internal::kZeroHashSeed);
}
void EnumerateNodes();
HeapSnapshot* CreateFakeSnapshot();
int GetNodeId(HeapEntry* entry);
int GetStringId(const char* s);
void SerializeEdge(HeapGraphEdge* edge);
void SerializeImpl();
void SerializeNode(HeapEntry* entry);
void SerializeNodes();
void SerializeSnapshot();
void SerializeString(const unsigned char* s);
void SerializeStrings();
void SortHashMap(HashMap* map, List<HashMap::Entry*>* sorted_entries);
static const int kMaxSerializableSnapshotRawSize;
HeapSnapshot* snapshot_;
HashMap nodes_;
HashMap strings_;
int next_node_id_;
int next_string_id_;
OutputStreamWriter* writer_;
friend class HeapSnapshotJSONSerializerEnumerator;
friend class HeapSnapshotJSONSerializerIterator;
DISALLOW_COPY_AND_ASSIGN(HeapSnapshotJSONSerializer);
};
} } // namespace v8::internal
#endif // V8_PROFILE_GENERATOR_H_