v8/src/logging/counters.cc - cobalt - Git at Google

 // Copyright 2012 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/logging/counters.h"

 #include <iomanip>

 #include "src/base/platform/platform.h"
 #include "src/base/platform/time.h"
 #include "src/builtins/builtins-definitions.h"
 #include "src/execution/isolate.h"
 #include "src/logging/counters-inl.h"
 #include "src/logging/log-inl.h"
 #include "src/logging/log.h"
 #include "src/utils/ostreams.h"

 namespace v8 {
 namespace internal {

 StatsTable::StatsTable(Counters* counters)
     : lookup_function_(nullptr),
       create_histogram_function_(nullptr),
       add_histogram_sample_function_(nullptr) {}

 void StatsTable::SetCounterFunction(CounterLookupCallback f) {
   lookup_function_ = f;
 }

 int* StatsCounterBase::FindLocationInStatsTable() const {
   return counters_->FindLocation(name_);
 }

 StatsCounterThreadSafe::StatsCounterThreadSafe(Counters* counters,
                                                const char* name)
     : StatsCounterBase(counters, name) {}

 void StatsCounterThreadSafe::Set(int Value) {
   if (ptr_) {
     base::MutexGuard Guard(&mutex_);
     SetLoc(ptr_, Value);
   }
 }

 void StatsCounterThreadSafe::Increment() {
   if (ptr_) {
     base::MutexGuard Guard(&mutex_);
     IncrementLoc(ptr_);
   }
 }

 void StatsCounterThreadSafe::Increment(int value) {
   if (ptr_) {
     base::MutexGuard Guard(&mutex_);
     IncrementLoc(ptr_, value);
   }
 }

 void StatsCounterThreadSafe::Decrement() {
   if (ptr_) {
     base::MutexGuard Guard(&mutex_);
     DecrementLoc(ptr_);
   }
 }

 void StatsCounterThreadSafe::Decrement(int value) {
   if (ptr_) {
     base::MutexGuard Guard(&mutex_);
     DecrementLoc(ptr_, value);
   }
 }

 void Histogram::AddSample(int sample) {
   if (Enabled()) {
     counters_->AddHistogramSample(histogram_, sample);
   }
 }

 void* Histogram::CreateHistogram() const {
   return counters_->CreateHistogram(name_, min_, max_, num_buckets_);
 }

 void TimedHistogram::AddTimedSample(base::TimeDelta sample) {
   if (Enabled()) {
     int64_t sample_int = resolution_ == HistogramTimerResolution::MICROSECOND
                              ? sample.InMicroseconds()
                              : sample.InMilliseconds();
     AddSample(static_cast<int>(sample_int));
   }
 }

 void TimedHistogram::Start(base::ElapsedTimer* timer, Isolate* isolate) {
   if (Enabled()) timer->Start();
   if (isolate) Logger::CallEventLogger(isolate, name(), Logger::START, true);
 }

 void TimedHistogram::Stop(base::ElapsedTimer* timer, Isolate* isolate) {
   if (Enabled()) {
     base::TimeDelta delta = timer->Elapsed();
     timer->Stop();
     AddTimedSample(delta);
   }
   if (isolate != nullptr) {
     Logger::CallEventLogger(isolate, name(), Logger::END, true);
   }
 }

 void TimedHistogram::RecordAbandon(base::ElapsedTimer* timer,
                                    Isolate* isolate) {
   if (Enabled()) {
     DCHECK(timer->IsStarted());
     timer->Stop();
     int64_t sample = resolution_ == HistogramTimerResolution::MICROSECOND
                          ? base::TimeDelta::Max().InMicroseconds()
                          : base::TimeDelta::Max().InMilliseconds();
     AddSample(static_cast<int>(sample));
   }
   if (isolate != nullptr) {
     Logger::CallEventLogger(isolate, name(), Logger::END, true);
   }
 }

 Counters::Counters(Isolate* isolate)
     : isolate_(isolate),
       stats_table_(this),
 // clang format off
 #define SC(name, caption) name##_(this, "c:" #caption),
       STATS_COUNTER_TS_LIST(SC)
 #undef SC
       // clang format on
       runtime_call_stats_(RuntimeCallStats::kMainIsolateThread),
       worker_thread_runtime_call_stats_() {
   static const struct {
     Histogram Counters::*member;
     const char* caption;
     int min;
     int max;
     int num_buckets;
   } kHistograms[] = {
 #define HR(name, caption, min, max, num_buckets) \
   {&Counters::name##_, #caption, min, max, num_buckets},
       HISTOGRAM_RANGE_LIST(HR)
 #undef HR
   };
   for (const auto& histogram : kHistograms) {
     this->*histogram.member =
         Histogram(histogram.caption, histogram.min, histogram.max,
                   histogram.num_buckets, this);
   }

   const int DefaultTimedHistogramNumBuckets = 50;

   static const struct {
     HistogramTimer Counters::*member;
     const char* caption;
     int max;
     HistogramTimerResolution res;
   } kHistogramTimers[] = {
 #define HT(name, caption, max, res) \
   {&Counters::name##_, #caption, max, HistogramTimerResolution::res},
       HISTOGRAM_TIMER_LIST(HT)
 #undef HT
   };
   for (const auto& timer : kHistogramTimers) {
     this->*timer.member = HistogramTimer(timer.caption, 0, timer.max, timer.res,
                                          DefaultTimedHistogramNumBuckets, this);
   }

   static const struct {
     TimedHistogram Counters::*member;
     const char* caption;
     int max;
     HistogramTimerResolution res;
   } kTimedHistograms[] = {
 #define HT(name, caption, max, res) \
   {&Counters::name##_, #caption, max, HistogramTimerResolution::res},
       TIMED_HISTOGRAM_LIST(HT)
 #undef HT
   };
   for (const auto& timer : kTimedHistograms) {
     this->*timer.member = TimedHistogram(timer.caption, 0, timer.max, timer.res,
                                          DefaultTimedHistogramNumBuckets, this);
   }

   static const struct {
     AggregatableHistogramTimer Counters::*member;
     const char* caption;
   } kAggregatableHistogramTimers[] = {
 #define AHT(name, caption) {&Counters::name##_, #caption},
       AGGREGATABLE_HISTOGRAM_TIMER_LIST(AHT)
 #undef AHT
   };
   for (const auto& aht : kAggregatableHistogramTimers) {
     this->*aht.member = AggregatableHistogramTimer(
         aht.caption, 0, 10000000, DefaultTimedHistogramNumBuckets, this);
   }

   static const struct {
     Histogram Counters::*member;
     const char* caption;
   } kHistogramPercentages[] = {
 #define HP(name, caption) {&Counters::name##_, #caption},
       HISTOGRAM_PERCENTAGE_LIST(HP)
 #undef HP
   };
   for (const auto& percentage : kHistogramPercentages) {
     this->*percentage.member = Histogram(percentage.caption, 0, 101, 100, this);
   }

   // Exponential histogram assigns bucket limits to points
   // p[1], p[2], ... p[n] such that p[i+1] / p[i] = constant.
   // The constant factor is equal to the n-th root of (high / low),
   // where the n is the number of buckets, the low is the lower limit,
   // the high is the upper limit.
   // For n = 50, low = 1000, high = 500000: the factor = 1.13.
   static const struct {
     Histogram Counters::*member;
     const char* caption;
   } kLegacyMemoryHistograms[] = {
 #define HM(name, caption) {&Counters::name##_, #caption},
       HISTOGRAM_LEGACY_MEMORY_LIST(HM)
 #undef HM
   };
   for (const auto& histogram : kLegacyMemoryHistograms) {
     this->*histogram.member =
         Histogram(histogram.caption, 1000, 500000, 50, this);
   }

   // clang-format off
   static const struct {
     StatsCounter Counters::*member;
     const char* caption;
   } kStatsCounters[] = {
 #define SC(name, caption) {&Counters::name##_, "c:" #caption},
   STATS_COUNTER_LIST_1(SC)
   STATS_COUNTER_LIST_2(SC)
   STATS_COUNTER_NATIVE_CODE_LIST(SC)
 #undef SC
 #define SC(name)                                             \
   {&Counters::count_of_##name##_, "c:" "V8.CountOf_" #name}, \
   {&Counters::size_of_##name##_, "c:" "V8.SizeOf_" #name},
       INSTANCE_TYPE_LIST(SC)
 #undef SC
 #define SC(name)                            \
   {&Counters::count_of_CODE_TYPE_##name##_, \
     "c:" "V8.CountOf_CODE_TYPE-" #name},     \
   {&Counters::size_of_CODE_TYPE_##name##_,  \
     "c:" "V8.SizeOf_CODE_TYPE-" #name},
       CODE_KIND_LIST(SC)
 #undef SC
 #define SC(name)                              \
   {&Counters::count_of_FIXED_ARRAY_##name##_, \
     "c:" "V8.CountOf_FIXED_ARRAY-" #name},     \
   {&Counters::size_of_FIXED_ARRAY_##name##_,  \
     "c:" "V8.SizeOf_FIXED_ARRAY-" #name},
       FIXED_ARRAY_SUB_INSTANCE_TYPE_LIST(SC)
 #undef SC
   };
   // clang-format on
   for (const auto& counter : kStatsCounters) {
     this->*counter.member = StatsCounter(this, counter.caption);
   }
 }

 void Counters::ResetCounterFunction(CounterLookupCallback f) {
   stats_table_.SetCounterFunction(f);

 #define SC(name, caption) name##_.Reset();
   STATS_COUNTER_LIST_1(SC)
   STATS_COUNTER_LIST_2(SC)
   STATS_COUNTER_TS_LIST(SC)
   STATS_COUNTER_NATIVE_CODE_LIST(SC)
 #undef SC

 #define SC(name)              \
   count_of_##name##_.Reset(); \
   size_of_##name##_.Reset();
   INSTANCE_TYPE_LIST(SC)
 #undef SC

 #define SC(name)                        \
   count_of_CODE_TYPE_##name##_.Reset(); \
   size_of_CODE_TYPE_##name##_.Reset();
   CODE_KIND_LIST(SC)
 #undef SC

 #define SC(name)                          \
   count_of_FIXED_ARRAY_##name##_.Reset(); \
   size_of_FIXED_ARRAY_##name##_.Reset();
   FIXED_ARRAY_SUB_INSTANCE_TYPE_LIST(SC)
 #undef SC
 }

 void Counters::ResetCreateHistogramFunction(CreateHistogramCallback f) {
   stats_table_.SetCreateHistogramFunction(f);

 #define HR(name, caption, min, max, num_buckets) name##_.Reset();
   HISTOGRAM_RANGE_LIST(HR)
 #undef HR

 #define HT(name, caption, max, res) name##_.Reset();
   HISTOGRAM_TIMER_LIST(HT)
 #undef HT

 #define HT(name, caption, max, res) name##_.Reset();
   TIMED_HISTOGRAM_LIST(HT)
 #undef HT

 #define AHT(name, caption) name##_.Reset();
   AGGREGATABLE_HISTOGRAM_TIMER_LIST(AHT)
 #undef AHT

 #define HP(name, caption) name##_.Reset();
   HISTOGRAM_PERCENTAGE_LIST(HP)
 #undef HP

 #define HM(name, caption) name##_.Reset();
   HISTOGRAM_LEGACY_MEMORY_LIST(HM)
 #undef HM
 }

 base::TimeTicks (*RuntimeCallTimer::Now)() =
     &base::TimeTicks::HighResolutionNow;

 base::TimeTicks RuntimeCallTimer::NowCPUTime() {
   base::ThreadTicks ticks = base::ThreadTicks::Now();
   return base::TimeTicks::FromInternalValue(ticks.ToInternalValue());
 }

 class RuntimeCallStatEntries {
  public:
   void Print(std::ostream& os) {
     if (total_call_count == 0) return;
     std::sort(entries.rbegin(), entries.rend());
     os << std::setw(50) << "Runtime Function/C++ Builtin" << std::setw(12)
        << "Time" << std::setw(18) << "Count" << std::endl
        << std::string(88, '=') << std::endl;
     for (Entry& entry : entries) {
       entry.SetTotal(total_time, total_call_count);
       entry.Print(os);
     }
     os << std::string(88, '-') << std::endl;
     Entry("Total", total_time, total_call_count).Print(os);
   }

   // By default, the compiler will usually inline this, which results in a large
   // binary size increase: std::vector::push_back expands to a large amount of
   // instructions, and this function is invoked repeatedly by macros.
   V8_NOINLINE void Add(RuntimeCallCounter* counter) {
     if (counter->count() == 0) return;
     entries.push_back(
         Entry(counter->name(), counter->time(), counter->count()));
     total_time += counter->time();
     total_call_count += counter->count();
   }

  private:
   class Entry {
    public:
     Entry(const char* name, base::TimeDelta time, uint64_t count)
         : name_(name),
           time_(time.InMicroseconds()),
           count_(count),
           time_percent_(100),
           count_percent_(100) {}

     bool operator<(const Entry& other) const {
       if (time_ < other.time_) return true;
       if (time_ > other.time_) return false;
       return count_ < other.count_;
     }

     V8_NOINLINE void Print(std::ostream& os) {
       os.precision(2);
       os << std::fixed << std::setprecision(2);
       os << std::setw(50) << name_;
       os << std::setw(10) << static_cast<double>(time_) / 1000 << "ms ";
       os << std::setw(6) << time_percent_ << "%";
       os << std::setw(10) << count_ << " ";
       os << std::setw(6) << count_percent_ << "%";
       os << std::endl;
     }

     V8_NOINLINE void SetTotal(base::TimeDelta total_time,
                               uint64_t total_count) {
       if (total_time.InMicroseconds() == 0) {
         time_percent_ = 0;
       } else {
         time_percent_ = 100.0 * time_ / total_time.InMicroseconds();
       }
       count_percent_ = 100.0 * count_ / total_count;
     }

    private:
     const char* name_;
     int64_t time_;
     uint64_t count_;
     double time_percent_;
     double count_percent_;
   };

   uint64_t total_call_count = 0;
   base::TimeDelta total_time;
   std::vector<Entry> entries;
 };

 void RuntimeCallCounter::Reset() {
   count_ = 0;
   time_ = 0;
 }

 void RuntimeCallCounter::Dump(v8::tracing::TracedValue* value) {
   value->BeginArray(name_);
   value->AppendDouble(count_);
   value->AppendDouble(time_);
   value->EndArray();
 }

 void RuntimeCallCounter::Add(RuntimeCallCounter* other) {
   count_ += other->count();
   time_ += other->time().InMicroseconds();
 }

 void RuntimeCallTimer::Snapshot() {
   base::TimeTicks now = Now();
   // Pause only / topmost timer in the timer stack.
   Pause(now);
   // Commit all the timer's elapsed time to the counters.
   RuntimeCallTimer* timer = this;
   while (timer != nullptr) {
     timer->CommitTimeToCounter();
     timer = timer->parent();
   }
   Resume(now);
 }

 RuntimeCallStats::RuntimeCallStats(ThreadType thread_type)
     : in_use_(false), thread_type_(thread_type) {
   static const char* const kNames[] = {
 #define CALL_BUILTIN_COUNTER(name) "GC_" #name,
       FOR_EACH_GC_COUNTER(CALL_BUILTIN_COUNTER)  //
 #undef CALL_BUILTIN_COUNTER
 #define CALL_RUNTIME_COUNTER(name) #name,
       FOR_EACH_MANUAL_COUNTER(CALL_RUNTIME_COUNTER)  //
 #undef CALL_RUNTIME_COUNTER
 #define CALL_RUNTIME_COUNTER(name, nargs, ressize) #name,
       FOR_EACH_INTRINSIC(CALL_RUNTIME_COUNTER)  //
 #undef CALL_RUNTIME_COUNTER
 #define CALL_BUILTIN_COUNTER(name) #name,
       BUILTIN_LIST_C(CALL_BUILTIN_COUNTER)  //
 #undef CALL_BUILTIN_COUNTER
 #define CALL_BUILTIN_COUNTER(name) "API_" #name,
       FOR_EACH_API_COUNTER(CALL_BUILTIN_COUNTER)  //
 #undef CALL_BUILTIN_COUNTER
 #define CALL_BUILTIN_COUNTER(name) #name,
       FOR_EACH_HANDLER_COUNTER(CALL_BUILTIN_COUNTER)  //
 #undef CALL_BUILTIN_COUNTER
 #define THREAD_SPECIFIC_COUNTER(name) #name,
       FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER)  //
 #undef THREAD_SPECIFIC_COUNTER
   };
   for (int i = 0; i < kNumberOfCounters; i++) {
     this->counters_[i] = RuntimeCallCounter(kNames[i]);
   }
   if (FLAG_rcs_cpu_time) {
     CHECK(base::ThreadTicks::IsSupported());
     base::ThreadTicks::WaitUntilInitialized();
     RuntimeCallTimer::Now = &RuntimeCallTimer::NowCPUTime;
   }
 }

 namespace {
 constexpr RuntimeCallCounterId FirstCounter(RuntimeCallCounterId first, ...) {
   return first;
 }

 #define THREAD_SPECIFIC_COUNTER(name) k##name,
 constexpr RuntimeCallCounterId kFirstThreadVariantCounter =
     FirstCounter(FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER) 0);
 #undef THREAD_SPECIFIC_COUNTER

 #define THREAD_SPECIFIC_COUNTER(name) +1
 constexpr int kThreadVariantCounterCount =
     0 FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER);
 #undef THREAD_SPECIFIC_COUNTER

 constexpr auto kLastThreadVariantCounter = static_cast<RuntimeCallCounterId>(
     kFirstThreadVariantCounter + kThreadVariantCounterCount - 1);
 }  // namespace

 bool RuntimeCallStats::HasThreadSpecificCounterVariants(
     RuntimeCallCounterId id) {
   // Check that it's in the range of the thread-specific variant counters and
   // also that it's one of the background counters.
   return id >= kFirstThreadVariantCounter && id <= kLastThreadVariantCounter;
 }

 bool RuntimeCallStats::IsBackgroundThreadSpecificVariant(
     RuntimeCallCounterId id) {
   return HasThreadSpecificCounterVariants(id) &&
          (id - kFirstThreadVariantCounter) % 2 == 1;
 }

 void RuntimeCallStats::Enter(RuntimeCallTimer* timer,
                              RuntimeCallCounterId counter_id) {
   DCHECK(IsCalledOnTheSameThread());
   RuntimeCallCounter* counter = GetCounter(counter_id);
   DCHECK_NOT_NULL(counter->name());
   timer->Start(counter, current_timer());
   current_timer_.SetValue(timer);
   current_counter_.SetValue(counter);
 }

 void RuntimeCallStats::Leave(RuntimeCallTimer* timer) {
   DCHECK(IsCalledOnTheSameThread());
   RuntimeCallTimer* stack_top = current_timer();
   if (stack_top == nullptr) return;  // Missing timer is a result of Reset().
   CHECK(stack_top == timer);
   current_timer_.SetValue(timer->Stop());
   RuntimeCallTimer* cur_timer = current_timer();
   current_counter_.SetValue(cur_timer ? cur_timer->counter() : nullptr);
 }

 void RuntimeCallStats::Add(RuntimeCallStats* other) {
   for (int i = 0; i < kNumberOfCounters; i++) {
     GetCounter(i)->Add(other->GetCounter(i));
   }
 }

 // static
 void RuntimeCallStats::CorrectCurrentCounterId(RuntimeCallCounterId counter_id,
                                                CounterMode mode) {
   DCHECK(IsCalledOnTheSameThread());
   if (mode == RuntimeCallStats::CounterMode::kThreadSpecific) {
     counter_id = CounterIdForThread(counter_id);
   }
   DCHECK(IsCounterAppropriateForThread(counter_id));

   RuntimeCallTimer* timer = current_timer();
   if (timer == nullptr) return;
   RuntimeCallCounter* counter = GetCounter(counter_id);
   timer->set_counter(counter);
   current_counter_.SetValue(counter);
 }

 bool RuntimeCallStats::IsCalledOnTheSameThread() {
   if (thread_id_.IsValid()) return thread_id_ == ThreadId::Current();
   thread_id_ = ThreadId::Current();
   return true;
 }

 void RuntimeCallStats::Print() {
   StdoutStream os;
   Print(os);
 }

 void RuntimeCallStats::Print(std::ostream& os) {
   RuntimeCallStatEntries entries;
   if (current_timer_.Value() != nullptr) {
     current_timer_.Value()->Snapshot();
   }
   for (int i = 0; i < kNumberOfCounters; i++) {
     entries.Add(GetCounter(i));
   }
   entries.Print(os);
 }

 void RuntimeCallStats::EnumerateCounters(
     debug::RuntimeCallCounterCallback callback) {
   if (current_timer_.Value() != nullptr) {
     current_timer_.Value()->Snapshot();
   }
   for (int i = 0; i < kNumberOfCounters; i++) {
     RuntimeCallCounter* counter = GetCounter(i);
     callback(counter->name(), counter->count(), counter->time());
   }
 }

 void RuntimeCallStats::Reset() {
   if (V8_LIKELY(!TracingFlags::is_runtime_stats_enabled())) return;

   // In tracing, we only what to trace the time spent on top level trace events,
   // if runtime counter stack is not empty, we should clear the whole runtime
   // counter stack, and then reset counters so that we can dump counters into
   // top level trace events accurately.
   while (current_timer_.Value()) {
     current_timer_.SetValue(current_timer_.Value()->Stop());
   }

   for (int i = 0; i < kNumberOfCounters; i++) {
     GetCounter(i)->Reset();
   }

   in_use_ = true;
 }

 void RuntimeCallStats::Dump(v8::tracing::TracedValue* value) {
   for (int i = 0; i < kNumberOfCounters; i++) {
     if (GetCounter(i)->count() > 0) GetCounter(i)->Dump(value);
   }
   in_use_ = false;
 }

 WorkerThreadRuntimeCallStats::WorkerThreadRuntimeCallStats()
     : isolate_thread_id_(ThreadId::Current()) {}

 WorkerThreadRuntimeCallStats::~WorkerThreadRuntimeCallStats() {
   if (tls_key_) base::Thread::DeleteThreadLocalKey(*tls_key_);
 }

 base::Thread::LocalStorageKey WorkerThreadRuntimeCallStats::GetKey() {
   base::MutexGuard lock(&mutex_);
   DCHECK(TracingFlags::is_runtime_stats_enabled());
   if (!tls_key_) tls_key_ = base::Thread::CreateThreadLocalKey();
   return *tls_key_;
 }

 RuntimeCallStats* WorkerThreadRuntimeCallStats::NewTable() {
   DCHECK(TracingFlags::is_runtime_stats_enabled());
   // Never create a new worker table on the isolate's main thread.
   DCHECK_NE(ThreadId::Current(), isolate_thread_id_);
   std::unique_ptr<RuntimeCallStats> new_table =
       std::make_unique<RuntimeCallStats>(RuntimeCallStats::kWorkerThread);
   RuntimeCallStats* result = new_table.get();

   base::MutexGuard lock(&mutex_);
   tables_.push_back(std::move(new_table));
   return result;
 }

 void WorkerThreadRuntimeCallStats::AddToMainTable(
     RuntimeCallStats* main_call_stats) {
   base::MutexGuard lock(&mutex_);
   for (auto& worker_stats : tables_) {
     DCHECK_NE(main_call_stats, worker_stats.get());
     main_call_stats->Add(worker_stats.get());
     worker_stats->Reset();
   }
 }

 WorkerThreadRuntimeCallStatsScope::WorkerThreadRuntimeCallStatsScope(
     WorkerThreadRuntimeCallStats* worker_stats)
     : table_(nullptr) {
   if (V8_LIKELY(!TracingFlags::is_runtime_stats_enabled())) return;

   table_ = reinterpret_cast<RuntimeCallStats*>(
       base::Thread::GetThreadLocal(worker_stats->GetKey()));
   if (table_ == nullptr) {
     table_ = worker_stats->NewTable();
     base::Thread::SetThreadLocal(worker_stats->GetKey(), table_);
   }

   if ((TracingFlags::runtime_stats.load(std::memory_order_relaxed) &
        v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING)) {
     table_->Reset();
   }
 }

 WorkerThreadRuntimeCallStatsScope::~WorkerThreadRuntimeCallStatsScope() {
   if (V8_LIKELY(table_ == nullptr)) return;

   if ((TracingFlags::runtime_stats.load(std::memory_order_relaxed) &
        v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING)) {
     auto value = v8::tracing::TracedValue::Create();
     table_->Dump(value.get());
     TRACE_EVENT_INSTANT1(TRACE_DISABLED_BY_DEFAULT("v8.runtime_stats"),
                          "V8.RuntimeStats", TRACE_EVENT_SCOPE_THREAD,
                          "runtime-call-stats", std::move(value));
   }
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2012 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/logging/counters.h"

	#include <iomanip>

	#include "src/base/platform/platform.h"
	#include "src/base/platform/time.h"
	#include "src/builtins/builtins-definitions.h"
	#include "src/execution/isolate.h"
	#include "src/logging/counters-inl.h"
	#include "src/logging/log-inl.h"
	#include "src/logging/log.h"
	#include "src/utils/ostreams.h"

	namespace v8 {
	namespace internal {

	StatsTable::StatsTable(Counters* counters)
	: lookup_function_(nullptr),
	create_histogram_function_(nullptr),
	add_histogram_sample_function_(nullptr) {}

	void StatsTable::SetCounterFunction(CounterLookupCallback f) {
	lookup_function_ = f;
	}

	int* StatsCounterBase::FindLocationInStatsTable() const {
	return counters_->FindLocation(name_);
	}

	StatsCounterThreadSafe::StatsCounterThreadSafe(Counters* counters,
	const char* name)
	: StatsCounterBase(counters, name) {}

	void StatsCounterThreadSafe::Set(int Value) {
	if (ptr_) {
	base::MutexGuard Guard(&mutex_);
	SetLoc(ptr_, Value);
	}
	}

	void StatsCounterThreadSafe::Increment() {
	if (ptr_) {
	base::MutexGuard Guard(&mutex_);
	IncrementLoc(ptr_);
	}
	}

	void StatsCounterThreadSafe::Increment(int value) {
	if (ptr_) {
	base::MutexGuard Guard(&mutex_);
	IncrementLoc(ptr_, value);
	}
	}

	void StatsCounterThreadSafe::Decrement() {
	if (ptr_) {
	base::MutexGuard Guard(&mutex_);
	DecrementLoc(ptr_);
	}
	}

	void StatsCounterThreadSafe::Decrement(int value) {
	if (ptr_) {
	base::MutexGuard Guard(&mutex_);
	DecrementLoc(ptr_, value);
	}
	}

	void Histogram::AddSample(int sample) {
	if (Enabled()) {
	counters_->AddHistogramSample(histogram_, sample);
	}
	}

	void* Histogram::CreateHistogram() const {
	return counters_->CreateHistogram(name_, min_, max_, num_buckets_);
	}

	void TimedHistogram::AddTimedSample(base::TimeDelta sample) {
	if (Enabled()) {
	int64_t sample_int = resolution_ == HistogramTimerResolution::MICROSECOND
	? sample.InMicroseconds()
	: sample.InMilliseconds();
	AddSample(static_cast<int>(sample_int));
	}
	}

	void TimedHistogram::Start(base::ElapsedTimer* timer, Isolate* isolate) {
	if (Enabled()) timer->Start();
	if (isolate) Logger::CallEventLogger(isolate, name(), Logger::START, true);
	}

	void TimedHistogram::Stop(base::ElapsedTimer* timer, Isolate* isolate) {
	if (Enabled()) {
	base::TimeDelta delta = timer->Elapsed();
	timer->Stop();
	AddTimedSample(delta);
	}
	if (isolate != nullptr) {
	Logger::CallEventLogger(isolate, name(), Logger::END, true);
	}
	}

	void TimedHistogram::RecordAbandon(base::ElapsedTimer* timer,
	Isolate* isolate) {
	if (Enabled()) {
	DCHECK(timer->IsStarted());
	timer->Stop();
	int64_t sample = resolution_ == HistogramTimerResolution::MICROSECOND
	? base::TimeDelta::Max().InMicroseconds()
	: base::TimeDelta::Max().InMilliseconds();
	AddSample(static_cast<int>(sample));
	}
	if (isolate != nullptr) {
	Logger::CallEventLogger(isolate, name(), Logger::END, true);
	}
	}

	Counters::Counters(Isolate* isolate)
	: isolate_(isolate),
	stats_table_(this),
	// clang format off
	#define SC(name, caption) name##_(this, "c:" #caption),
	STATS_COUNTER_TS_LIST(SC)
	#undef SC
	// clang format on
	runtime_call_stats_(RuntimeCallStats::kMainIsolateThread),
	worker_thread_runtime_call_stats_() {
	static const struct {
	Histogram Counters::*member;
	const char* caption;
	int min;
	int max;
	int num_buckets;
	} kHistograms[] = {
	#define HR(name, caption, min, max, num_buckets) \
	{&Counters::name##_, #caption, min, max, num_buckets},
	HISTOGRAM_RANGE_LIST(HR)
	#undef HR
	};
	for (const auto& histogram : kHistograms) {
	this->*histogram.member =
	Histogram(histogram.caption, histogram.min, histogram.max,
	histogram.num_buckets, this);
	}

	const int DefaultTimedHistogramNumBuckets = 50;

	static const struct {
	HistogramTimer Counters::*member;
	const char* caption;
	int max;
	HistogramTimerResolution res;
	} kHistogramTimers[] = {
	#define HT(name, caption, max, res) \
	{&Counters::name##_, #caption, max, HistogramTimerResolution::res},
	HISTOGRAM_TIMER_LIST(HT)
	#undef HT
	};
	for (const auto& timer : kHistogramTimers) {
	this->*timer.member = HistogramTimer(timer.caption, 0, timer.max, timer.res,
	DefaultTimedHistogramNumBuckets, this);
	}

	static const struct {
	TimedHistogram Counters::*member;
	const char* caption;
	int max;
	HistogramTimerResolution res;
	} kTimedHistograms[] = {
	#define HT(name, caption, max, res) \
	{&Counters::name##_, #caption, max, HistogramTimerResolution::res},
	TIMED_HISTOGRAM_LIST(HT)
	#undef HT
	};
	for (const auto& timer : kTimedHistograms) {
	this->*timer.member = TimedHistogram(timer.caption, 0, timer.max, timer.res,
	DefaultTimedHistogramNumBuckets, this);
	}

	static const struct {
	AggregatableHistogramTimer Counters::*member;
	const char* caption;
	} kAggregatableHistogramTimers[] = {
	#define AHT(name, caption) {&Counters::name##_, #caption},
	AGGREGATABLE_HISTOGRAM_TIMER_LIST(AHT)
	#undef AHT
	};
	for (const auto& aht : kAggregatableHistogramTimers) {
	this->*aht.member = AggregatableHistogramTimer(
	aht.caption, 0, 10000000, DefaultTimedHistogramNumBuckets, this);
	}

	static const struct {
	Histogram Counters::*member;
	const char* caption;
	} kHistogramPercentages[] = {
	#define HP(name, caption) {&Counters::name##_, #caption},
	HISTOGRAM_PERCENTAGE_LIST(HP)
	#undef HP
	};
	for (const auto& percentage : kHistogramPercentages) {
	this->*percentage.member = Histogram(percentage.caption, 0, 101, 100, this);
	}

	// Exponential histogram assigns bucket limits to points
	// p[1], p[2], ... p[n] such that p[i+1] / p[i] = constant.
	// The constant factor is equal to the n-th root of (high / low),
	// where the n is the number of buckets, the low is the lower limit,
	// the high is the upper limit.
	// For n = 50, low = 1000, high = 500000: the factor = 1.13.
	static const struct {
	Histogram Counters::*member;
	const char* caption;
	} kLegacyMemoryHistograms[] = {
	#define HM(name, caption) {&Counters::name##_, #caption},
	HISTOGRAM_LEGACY_MEMORY_LIST(HM)
	#undef HM
	};
	for (const auto& histogram : kLegacyMemoryHistograms) {
	this->*histogram.member =
	Histogram(histogram.caption, 1000, 500000, 50, this);
	}

	// clang-format off
	static const struct {
	StatsCounter Counters::*member;
	const char* caption;
	} kStatsCounters[] = {
	#define SC(name, caption) {&Counters::name##_, "c:" #caption},
	STATS_COUNTER_LIST_1(SC)
	STATS_COUNTER_LIST_2(SC)
	STATS_COUNTER_NATIVE_CODE_LIST(SC)
	#undef SC
	#define SC(name) \
	{&Counters::count_of_##name##_, "c:" "V8.CountOf_" #name}, \
	{&Counters::size_of_##name##_, "c:" "V8.SizeOf_" #name},
	INSTANCE_TYPE_LIST(SC)
	#undef SC
	#define SC(name) \
	{&Counters::count_of_CODE_TYPE_##name##_, \
	"c:" "V8.CountOf_CODE_TYPE-" #name}, \
	{&Counters::size_of_CODE_TYPE_##name##_, \
	"c:" "V8.SizeOf_CODE_TYPE-" #name},
	CODE_KIND_LIST(SC)
	#undef SC
	#define SC(name) \
	{&Counters::count_of_FIXED_ARRAY_##name##_, \
	"c:" "V8.CountOf_FIXED_ARRAY-" #name}, \
	{&Counters::size_of_FIXED_ARRAY_##name##_, \
	"c:" "V8.SizeOf_FIXED_ARRAY-" #name},
	FIXED_ARRAY_SUB_INSTANCE_TYPE_LIST(SC)
	#undef SC
	};
	// clang-format on
	for (const auto& counter : kStatsCounters) {
	this->*counter.member = StatsCounter(this, counter.caption);
	}
	}

	void Counters::ResetCounterFunction(CounterLookupCallback f) {
	stats_table_.SetCounterFunction(f);

	#define SC(name, caption) name##_.Reset();
	STATS_COUNTER_LIST_1(SC)
	STATS_COUNTER_LIST_2(SC)
	STATS_COUNTER_TS_LIST(SC)
	STATS_COUNTER_NATIVE_CODE_LIST(SC)
	#undef SC

	#define SC(name) \
	count_of_##name##_.Reset(); \
	size_of_##name##_.Reset();
	INSTANCE_TYPE_LIST(SC)
	#undef SC

	#define SC(name) \
	count_of_CODE_TYPE_##name##_.Reset(); \
	size_of_CODE_TYPE_##name##_.Reset();
	CODE_KIND_LIST(SC)
	#undef SC

	#define SC(name) \
	count_of_FIXED_ARRAY_##name##_.Reset(); \
	size_of_FIXED_ARRAY_##name##_.Reset();
	FIXED_ARRAY_SUB_INSTANCE_TYPE_LIST(SC)
	#undef SC
	}

	void Counters::ResetCreateHistogramFunction(CreateHistogramCallback f) {
	stats_table_.SetCreateHistogramFunction(f);

	#define HR(name, caption, min, max, num_buckets) name##_.Reset();
	HISTOGRAM_RANGE_LIST(HR)
	#undef HR

	#define HT(name, caption, max, res) name##_.Reset();
	HISTOGRAM_TIMER_LIST(HT)
	#undef HT

	#define HT(name, caption, max, res) name##_.Reset();
	TIMED_HISTOGRAM_LIST(HT)
	#undef HT

	#define AHT(name, caption) name##_.Reset();
	AGGREGATABLE_HISTOGRAM_TIMER_LIST(AHT)
	#undef AHT

	#define HP(name, caption) name##_.Reset();
	HISTOGRAM_PERCENTAGE_LIST(HP)
	#undef HP

	#define HM(name, caption) name##_.Reset();
	HISTOGRAM_LEGACY_MEMORY_LIST(HM)
	#undef HM
	}

	base::TimeTicks (*RuntimeCallTimer::Now)() =
	&base::TimeTicks::HighResolutionNow;

	base::TimeTicks RuntimeCallTimer::NowCPUTime() {
	base::ThreadTicks ticks = base::ThreadTicks::Now();
	return base::TimeTicks::FromInternalValue(ticks.ToInternalValue());
	}

	class RuntimeCallStatEntries {
	public:
	void Print(std::ostream& os) {
	if (total_call_count == 0) return;
	std::sort(entries.rbegin(), entries.rend());
	os << std::setw(50) << "Runtime Function/C++ Builtin" << std::setw(12)
	<< "Time" << std::setw(18) << "Count" << std::endl
	<< std::string(88, '=') << std::endl;
	for (Entry& entry : entries) {
	entry.SetTotal(total_time, total_call_count);
	entry.Print(os);
	}
	os << std::string(88, '-') << std::endl;
	Entry("Total", total_time, total_call_count).Print(os);
	}

	// By default, the compiler will usually inline this, which results in a large
	// binary size increase: std::vector::push_back expands to a large amount of
	// instructions, and this function is invoked repeatedly by macros.
	V8_NOINLINE void Add(RuntimeCallCounter* counter) {
	if (counter->count() == 0) return;
	entries.push_back(
	Entry(counter->name(), counter->time(), counter->count()));
	total_time += counter->time();
	total_call_count += counter->count();
	}

	private:
	class Entry {
	public:
	Entry(const char* name, base::TimeDelta time, uint64_t count)
	: name_(name),
	time_(time.InMicroseconds()),
	count_(count),
	time_percent_(100),
	count_percent_(100) {}

	bool operator<(const Entry& other) const {
	if (time_ < other.time_) return true;
	if (time_ > other.time_) return false;
	return count_ < other.count_;
	}

	V8_NOINLINE void Print(std::ostream& os) {
	os.precision(2);
	os << std::fixed << std::setprecision(2);
	os << std::setw(50) << name_;
	os << std::setw(10) << static_cast<double>(time_) / 1000 << "ms ";
	os << std::setw(6) << time_percent_ << "%";
	os << std::setw(10) << count_ << " ";
	os << std::setw(6) << count_percent_ << "%";
	os << std::endl;
	}

	V8_NOINLINE void SetTotal(base::TimeDelta total_time,
	uint64_t total_count) {
	if (total_time.InMicroseconds() == 0) {
	time_percent_ = 0;
	} else {
	time_percent_ = 100.0 * time_ / total_time.InMicroseconds();
	}
	count_percent_ = 100.0 * count_ / total_count;
	}

	private:
	const char* name_;
	int64_t time_;
	uint64_t count_;
	double time_percent_;
	double count_percent_;
	};

	uint64_t total_call_count = 0;
	base::TimeDelta total_time;
	std::vector<Entry> entries;
	};

	void RuntimeCallCounter::Reset() {
	count_ = 0;
	time_ = 0;
	}

	void RuntimeCallCounter::Dump(v8::tracing::TracedValue* value) {
	value->BeginArray(name_);
	value->AppendDouble(count_);
	value->AppendDouble(time_);
	value->EndArray();
	}

	void RuntimeCallCounter::Add(RuntimeCallCounter* other) {
	count_ += other->count();
	time_ += other->time().InMicroseconds();
	}

	void RuntimeCallTimer::Snapshot() {
	base::TimeTicks now = Now();
	// Pause only / topmost timer in the timer stack.
	Pause(now);
	// Commit all the timer's elapsed time to the counters.
	RuntimeCallTimer* timer = this;
	while (timer != nullptr) {
	timer->CommitTimeToCounter();
	timer = timer->parent();
	}
	Resume(now);
	}

	RuntimeCallStats::RuntimeCallStats(ThreadType thread_type)
	: in_use_(false), thread_type_(thread_type) {
	static const char* const kNames[] = {
	#define CALL_BUILTIN_COUNTER(name) "GC_" #name,
	FOR_EACH_GC_COUNTER(CALL_BUILTIN_COUNTER) //
	#undef CALL_BUILTIN_COUNTER
	#define CALL_RUNTIME_COUNTER(name) #name,
	FOR_EACH_MANUAL_COUNTER(CALL_RUNTIME_COUNTER) //
	#undef CALL_RUNTIME_COUNTER
	#define CALL_RUNTIME_COUNTER(name, nargs, ressize) #name,
	FOR_EACH_INTRINSIC(CALL_RUNTIME_COUNTER) //
	#undef CALL_RUNTIME_COUNTER
	#define CALL_BUILTIN_COUNTER(name) #name,
	BUILTIN_LIST_C(CALL_BUILTIN_COUNTER) //
	#undef CALL_BUILTIN_COUNTER
	#define CALL_BUILTIN_COUNTER(name) "API_" #name,
	FOR_EACH_API_COUNTER(CALL_BUILTIN_COUNTER) //
	#undef CALL_BUILTIN_COUNTER
	#define CALL_BUILTIN_COUNTER(name) #name,
	FOR_EACH_HANDLER_COUNTER(CALL_BUILTIN_COUNTER) //
	#undef CALL_BUILTIN_COUNTER
	#define THREAD_SPECIFIC_COUNTER(name) #name,
	FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER) //
	#undef THREAD_SPECIFIC_COUNTER
	};
	for (int i = 0; i < kNumberOfCounters; i++) {
	this->counters_[i] = RuntimeCallCounter(kNames[i]);
	}
	if (FLAG_rcs_cpu_time) {
	CHECK(base::ThreadTicks::IsSupported());
	base::ThreadTicks::WaitUntilInitialized();
	RuntimeCallTimer::Now = &RuntimeCallTimer::NowCPUTime;
	}
	}

	namespace {
	constexpr RuntimeCallCounterId FirstCounter(RuntimeCallCounterId first, ...) {
	return first;
	}

	#define THREAD_SPECIFIC_COUNTER(name) k##name,
	constexpr RuntimeCallCounterId kFirstThreadVariantCounter =
	FirstCounter(FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER) 0);
	#undef THREAD_SPECIFIC_COUNTER

	#define THREAD_SPECIFIC_COUNTER(name) +1
	constexpr int kThreadVariantCounterCount =
	0 FOR_EACH_THREAD_SPECIFIC_COUNTER(THREAD_SPECIFIC_COUNTER);
	#undef THREAD_SPECIFIC_COUNTER

	constexpr auto kLastThreadVariantCounter = static_cast<RuntimeCallCounterId>(
	kFirstThreadVariantCounter + kThreadVariantCounterCount - 1);
	} // namespace

	bool RuntimeCallStats::HasThreadSpecificCounterVariants(
	RuntimeCallCounterId id) {
	// Check that it's in the range of the thread-specific variant counters and
	// also that it's one of the background counters.
	return id >= kFirstThreadVariantCounter && id <= kLastThreadVariantCounter;
	}

	bool RuntimeCallStats::IsBackgroundThreadSpecificVariant(
	RuntimeCallCounterId id) {
	return HasThreadSpecificCounterVariants(id) &&
	(id - kFirstThreadVariantCounter) % 2 == 1;
	}

	void RuntimeCallStats::Enter(RuntimeCallTimer* timer,
	RuntimeCallCounterId counter_id) {
	DCHECK(IsCalledOnTheSameThread());
	RuntimeCallCounter* counter = GetCounter(counter_id);
	DCHECK_NOT_NULL(counter->name());
	timer->Start(counter, current_timer());
	current_timer_.SetValue(timer);
	current_counter_.SetValue(counter);
	}

	void RuntimeCallStats::Leave(RuntimeCallTimer* timer) {
	DCHECK(IsCalledOnTheSameThread());
	RuntimeCallTimer* stack_top = current_timer();
	if (stack_top == nullptr) return; // Missing timer is a result of Reset().
	CHECK(stack_top == timer);
	current_timer_.SetValue(timer->Stop());
	RuntimeCallTimer* cur_timer = current_timer();
	current_counter_.SetValue(cur_timer ? cur_timer->counter() : nullptr);
	}

	void RuntimeCallStats::Add(RuntimeCallStats* other) {
	for (int i = 0; i < kNumberOfCounters; i++) {
	GetCounter(i)->Add(other->GetCounter(i));
	}
	}

	// static
	void RuntimeCallStats::CorrectCurrentCounterId(RuntimeCallCounterId counter_id,
	CounterMode mode) {
	DCHECK(IsCalledOnTheSameThread());
	if (mode == RuntimeCallStats::CounterMode::kThreadSpecific) {
	counter_id = CounterIdForThread(counter_id);
	}
	DCHECK(IsCounterAppropriateForThread(counter_id));

	RuntimeCallTimer* timer = current_timer();
	if (timer == nullptr) return;
	RuntimeCallCounter* counter = GetCounter(counter_id);
	timer->set_counter(counter);
	current_counter_.SetValue(counter);
	}

	bool RuntimeCallStats::IsCalledOnTheSameThread() {
	if (thread_id_.IsValid()) return thread_id_ == ThreadId::Current();
	thread_id_ = ThreadId::Current();
	return true;
	}

	void RuntimeCallStats::Print() {
	StdoutStream os;
	Print(os);
	}

	void RuntimeCallStats::Print(std::ostream& os) {
	RuntimeCallStatEntries entries;
	if (current_timer_.Value() != nullptr) {
	current_timer_.Value()->Snapshot();
	}
	for (int i = 0; i < kNumberOfCounters; i++) {
	entries.Add(GetCounter(i));
	}
	entries.Print(os);
	}

	void RuntimeCallStats::EnumerateCounters(
	debug::RuntimeCallCounterCallback callback) {
	if (current_timer_.Value() != nullptr) {
	current_timer_.Value()->Snapshot();
	}
	for (int i = 0; i < kNumberOfCounters; i++) {
	RuntimeCallCounter* counter = GetCounter(i);
	callback(counter->name(), counter->count(), counter->time());
	}
	}

	void RuntimeCallStats::Reset() {
	if (V8_LIKELY(!TracingFlags::is_runtime_stats_enabled())) return;

	// In tracing, we only what to trace the time spent on top level trace events,
	// if runtime counter stack is not empty, we should clear the whole runtime
	// counter stack, and then reset counters so that we can dump counters into
	// top level trace events accurately.
	while (current_timer_.Value()) {
	current_timer_.SetValue(current_timer_.Value()->Stop());
	}

	for (int i = 0; i < kNumberOfCounters; i++) {
	GetCounter(i)->Reset();
	}

	in_use_ = true;
	}

	void RuntimeCallStats::Dump(v8::tracing::TracedValue* value) {
	for (int i = 0; i < kNumberOfCounters; i++) {
	if (GetCounter(i)->count() > 0) GetCounter(i)->Dump(value);
	}
	in_use_ = false;
	}

	WorkerThreadRuntimeCallStats::WorkerThreadRuntimeCallStats()
	: isolate_thread_id_(ThreadId::Current()) {}

	WorkerThreadRuntimeCallStats::~WorkerThreadRuntimeCallStats() {
	if (tls_key_) base::Thread::DeleteThreadLocalKey(*tls_key_);
	}

	base::Thread::LocalStorageKey WorkerThreadRuntimeCallStats::GetKey() {
	base::MutexGuard lock(&mutex_);
	DCHECK(TracingFlags::is_runtime_stats_enabled());
	if (!tls_key_) tls_key_ = base::Thread::CreateThreadLocalKey();
	return *tls_key_;
	}

	RuntimeCallStats* WorkerThreadRuntimeCallStats::NewTable() {
	DCHECK(TracingFlags::is_runtime_stats_enabled());
	// Never create a new worker table on the isolate's main thread.
	DCHECK_NE(ThreadId::Current(), isolate_thread_id_);
	std::unique_ptr<RuntimeCallStats> new_table =
	std::make_unique<RuntimeCallStats>(RuntimeCallStats::kWorkerThread);
	RuntimeCallStats* result = new_table.get();

	base::MutexGuard lock(&mutex_);
	tables_.push_back(std::move(new_table));
	return result;
	}

	void WorkerThreadRuntimeCallStats::AddToMainTable(
	RuntimeCallStats* main_call_stats) {
	base::MutexGuard lock(&mutex_);
	for (auto& worker_stats : tables_) {
	DCHECK_NE(main_call_stats, worker_stats.get());
	main_call_stats->Add(worker_stats.get());
	worker_stats->Reset();
	}
	}

	WorkerThreadRuntimeCallStatsScope::WorkerThreadRuntimeCallStatsScope(
	WorkerThreadRuntimeCallStats* worker_stats)
	: table_(nullptr) {
	if (V8_LIKELY(!TracingFlags::is_runtime_stats_enabled())) return;

	table_ = reinterpret_cast<RuntimeCallStats*>(
	base::Thread::GetThreadLocal(worker_stats->GetKey()));
	if (table_ == nullptr) {
	table_ = worker_stats->NewTable();
	base::Thread::SetThreadLocal(worker_stats->GetKey(), table_);
	}

	if ((TracingFlags::runtime_stats.load(std::memory_order_relaxed) &
	v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING)) {
	table_->Reset();
	}
	}

	WorkerThreadRuntimeCallStatsScope::~WorkerThreadRuntimeCallStatsScope() {
	if (V8_LIKELY(table_ == nullptr)) return;

	if ((TracingFlags::runtime_stats.load(std::memory_order_relaxed) &
	v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING)) {
	auto value = v8::tracing::TracedValue::Create();
	table_->Dump(value.get());
	TRACE_EVENT_INSTANT1(TRACE_DISABLED_BY_DEFAULT("v8.runtime_stats"),
	"V8.RuntimeStats", TRACE_EVENT_SCOPE_THREAD,
	"runtime-call-stats", std::move(value));
	}
	}

	} // namespace internal
	} // namespace v8