llvm/lib/Support/TimeProfiler.cpp - llvm-project - Git at Google

 //===-- TimeProfiler.cpp - Hierarchical Time Profiler ---------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements hierarchical time profiler.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Support/TimeProfiler.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/Support/CommandLine.h"
 #include "llvm/Support/JSON.h"
 #include "llvm/Support/Path.h"
 #include "llvm/Support/Process.h"
 #include "llvm/Support/Threading.h"
 #include <algorithm>
 #include <cassert>
 #include <chrono>
 #include <mutex>
 #include <string>
 #include <vector>

 using namespace std::chrono;
 using namespace llvm;

 static std::mutex Mu;
 // List of all instances
 static std::vector<TimeTraceProfiler *>
     ThreadTimeTraceProfilerInstances; // GUARDED_BY(Mu)
 // Per Thread instance
 static LLVM_THREAD_LOCAL TimeTraceProfiler *TimeTraceProfilerInstance = nullptr;

 TimeTraceProfiler *llvm::getTimeTraceProfilerInstance() {
   return TimeTraceProfilerInstance;
 }

 typedef duration<steady_clock::rep, steady_clock::period> DurationType;
 typedef time_point<steady_clock> TimePointType;
 typedef std::pair<size_t, DurationType> CountAndDurationType;
 typedef std::pair<std::string, CountAndDurationType>
     NameAndCountAndDurationType;

 namespace {
 struct Entry {
   const TimePointType Start;
   TimePointType End;
   const std::string Name;
   const std::string Detail;

   Entry(TimePointType &&S, TimePointType &&E, std::string &&N, std::string &&Dt)
       : Start(std::move(S)), End(std::move(E)), Name(std::move(N)),
         Detail(std::move(Dt)) {}

   // Calculate timings for FlameGraph. Cast time points to microsecond precision
   // rather than casting duration. This avoid truncation issues causing inner
   // scopes overruning outer scopes.
   steady_clock::rep getFlameGraphStartUs(TimePointType StartTime) const {
     return (time_point_cast<microseconds>(Start) -
             time_point_cast<microseconds>(StartTime))
         .count();
   }

   steady_clock::rep getFlameGraphDurUs() const {
     return (time_point_cast<microseconds>(End) -
             time_point_cast<microseconds>(Start))
         .count();
   }
 };
 } // namespace

 struct llvm::TimeTraceProfiler {
   TimeTraceProfiler(unsigned TimeTraceGranularity = 0, StringRef ProcName = "")
       : BeginningOfTime(system_clock::now()), StartTime(steady_clock::now()),
         ProcName(ProcName), Pid(sys::Process::getProcessId()),
         Tid(llvm::get_threadid()), TimeTraceGranularity(TimeTraceGranularity) {
     llvm::get_thread_name(ThreadName);
   }

   void begin(std::string Name, llvm::function_ref<std::string()> Detail) {
     Stack.emplace_back(steady_clock::now(), TimePointType(), std::move(Name),
                        Detail());
   }

   void end() {
     assert(!Stack.empty() && "Must call begin() first");
     Entry &E = Stack.back();
     E.End = steady_clock::now();

     // Check that end times monotonically increase.
     assert((Entries.empty() ||
             (E.getFlameGraphStartUs(StartTime) + E.getFlameGraphDurUs() >=
              Entries.back().getFlameGraphStartUs(StartTime) +
                  Entries.back().getFlameGraphDurUs())) &&
            "TimeProfiler scope ended earlier than previous scope");

     // Calculate duration at full precision for overall counts.
     DurationType Duration = E.End - E.Start;

     // Only include sections longer or equal to TimeTraceGranularity msec.
     if (duration_cast<microseconds>(Duration).count() >= TimeTraceGranularity)
       Entries.emplace_back(E);

     // Track total time taken by each "name", but only the topmost levels of
     // them; e.g. if there's a template instantiation that instantiates other
     // templates from within, we only want to add the topmost one. "topmost"
     // happens to be the ones that don't have any currently open entries above
     // itself.
     if (std::find_if(++Stack.rbegin(), Stack.rend(), [&](const Entry &Val) {
           return Val.Name == E.Name;
         }) == Stack.rend()) {
       auto &CountAndTotal = CountAndTotalPerName[E.Name];
       CountAndTotal.first++;
       CountAndTotal.second += Duration;
     }

     Stack.pop_back();
   }

   // Write events from this TimeTraceProfilerInstance and
   // ThreadTimeTraceProfilerInstances.
   void write(raw_pwrite_stream &OS) {
     // Acquire Mutex as reading ThreadTimeTraceProfilerInstances.
     std::lock_guard<std::mutex> Lock(Mu);
     assert(Stack.empty() &&
            "All profiler sections should be ended when calling write");
     assert(llvm::all_of(ThreadTimeTraceProfilerInstances,
                         [](const auto &TTP) { return TTP->Stack.empty(); }) &&
            "All profiler sections should be ended when calling write");

     json::OStream J(OS);
     J.objectBegin();
     J.attributeBegin("traceEvents");
     J.arrayBegin();

     // Emit all events for the main flame graph.
     auto writeEvent = [&](const auto &E, uint64_t Tid) {
       auto StartUs = E.getFlameGraphStartUs(StartTime);
       auto DurUs = E.getFlameGraphDurUs();

       J.object([&] {
         J.attribute("pid", Pid);
         J.attribute("tid", int64_t(Tid));
         J.attribute("ph", "X");
         J.attribute("ts", StartUs);
         J.attribute("dur", DurUs);
         J.attribute("name", E.Name);
         if (!E.Detail.empty()) {
           J.attributeObject("args", [&] { J.attribute("detail", E.Detail); });
         }
       });
     };
     for (const Entry &E : Entries)
       writeEvent(E, this->Tid);
     for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
       for (const Entry &E : TTP->Entries)
         writeEvent(E, TTP->Tid);

     // Emit totals by section name as additional "thread" events, sorted from
     // longest one.
     // Find highest used thread id.
     uint64_t MaxTid = this->Tid;
     for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
       MaxTid = std::max(MaxTid, TTP->Tid);

     // Combine all CountAndTotalPerName from threads into one.
     StringMap<CountAndDurationType> AllCountAndTotalPerName;
     auto combineStat = [&](const auto &Stat) {
       StringRef Key = Stat.getKey();
       auto Value = Stat.getValue();
       auto &CountAndTotal = AllCountAndTotalPerName[Key];
       CountAndTotal.first += Value.first;
       CountAndTotal.second += Value.second;
     };
     for (const auto &Stat : CountAndTotalPerName)
       combineStat(Stat);
     for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
       for (const auto &Stat : TTP->CountAndTotalPerName)
         combineStat(Stat);

     std::vector<NameAndCountAndDurationType> SortedTotals;
     SortedTotals.reserve(AllCountAndTotalPerName.size());
     for (const auto &Total : AllCountAndTotalPerName)
       SortedTotals.emplace_back(std::string(Total.getKey()), Total.getValue());

     llvm::sort(SortedTotals, [](const NameAndCountAndDurationType &A,
                                 const NameAndCountAndDurationType &B) {
       return A.second.second > B.second.second;
     });

     // Report totals on separate threads of tracing file.
     uint64_t TotalTid = MaxTid + 1;
     for (const NameAndCountAndDurationType &Total : SortedTotals) {
       auto DurUs = duration_cast<microseconds>(Total.second.second).count();
       auto Count = AllCountAndTotalPerName[Total.first].first;

       J.object([&] {
         J.attribute("pid", Pid);
         J.attribute("tid", int64_t(TotalTid));
         J.attribute("ph", "X");
         J.attribute("ts", 0);
         J.attribute("dur", DurUs);
         J.attribute("name", "Total " + Total.first);
         J.attributeObject("args", [&] {
           J.attribute("count", int64_t(Count));
           J.attribute("avg ms", int64_t(DurUs / Count / 1000));
         });
       });

       ++TotalTid;
     }

     auto writeMetadataEvent = [&](const char *Name, uint64_t Tid,
                                   StringRef arg) {
       J.object([&] {
         J.attribute("cat", "");
         J.attribute("pid", Pid);
         J.attribute("tid", int64_t(Tid));
         J.attribute("ts", 0);
         J.attribute("ph", "M");
         J.attribute("name", Name);
         J.attributeObject("args", [&] { J.attribute("name", arg); });
       });
     };

     writeMetadataEvent("process_name", Tid, ProcName);
     writeMetadataEvent("thread_name", Tid, ThreadName);
     for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
       writeMetadataEvent("thread_name", TTP->Tid, TTP->ThreadName);

     J.arrayEnd();
     J.attributeEnd();

     // Emit the absolute time when this TimeProfiler started.
     // This can be used to combine the profiling data from
     // multiple processes and preserve actual time intervals.
     J.attribute("beginningOfTime",
                 time_point_cast<microseconds>(BeginningOfTime)
                     .time_since_epoch()
                     .count());

     J.objectEnd();
   }

   SmallVector<Entry, 16> Stack;
   SmallVector<Entry, 128> Entries;
   StringMap<CountAndDurationType> CountAndTotalPerName;
   const time_point<system_clock> BeginningOfTime;
   const TimePointType StartTime;
   const std::string ProcName;
   const sys::Process::Pid Pid;
   SmallString<0> ThreadName;
   const uint64_t Tid;

   // Minimum time granularity (in microseconds)
   const unsigned TimeTraceGranularity;
 };

 void llvm::timeTraceProfilerInitialize(unsigned TimeTraceGranularity,
                                        StringRef ProcName) {
   assert(TimeTraceProfilerInstance == nullptr &&
          "Profiler should not be initialized");
   TimeTraceProfilerInstance = new TimeTraceProfiler(
       TimeTraceGranularity, llvm::sys::path::filename(ProcName));
 }

 // Removes all TimeTraceProfilerInstances.
 // Called from main thread.
 void llvm::timeTraceProfilerCleanup() {
   delete TimeTraceProfilerInstance;
   std::lock_guard<std::mutex> Lock(Mu);
   for (auto TTP : ThreadTimeTraceProfilerInstances)
     delete TTP;
   ThreadTimeTraceProfilerInstances.clear();
 }

 // Finish TimeTraceProfilerInstance on a worker thread.
 // This doesn't remove the instance, just moves the pointer to global vector.
 void llvm::timeTraceProfilerFinishThread() {
   std::lock_guard<std::mutex> Lock(Mu);
   ThreadTimeTraceProfilerInstances.push_back(TimeTraceProfilerInstance);
   TimeTraceProfilerInstance = nullptr;
 }

 void llvm::timeTraceProfilerWrite(raw_pwrite_stream &OS) {
   assert(TimeTraceProfilerInstance != nullptr &&
          "Profiler object can't be null");
   TimeTraceProfilerInstance->write(OS);
 }

 Error llvm::timeTraceProfilerWrite(StringRef PreferredFileName,
                                    StringRef FallbackFileName) {
   assert(TimeTraceProfilerInstance != nullptr &&
          "Profiler object can't be null");

   std::string Path = PreferredFileName.str();
   if (Path.empty()) {
     Path = FallbackFileName == "-" ? "out" : FallbackFileName.str();
     Path += ".time-trace";
   }

   std::error_code EC;
   raw_fd_ostream OS(Path, EC, sys::fs::OF_Text);
   if (EC)
     return createStringError(EC, "Could not open " + Path);

   timeTraceProfilerWrite(OS);
   return Error::success();
 }

 void llvm::timeTraceProfilerBegin(StringRef Name, StringRef Detail) {
   if (TimeTraceProfilerInstance != nullptr)
     TimeTraceProfilerInstance->begin(std::string(Name),
                                      [&]() { return std::string(Detail); });
 }

 void llvm::timeTraceProfilerBegin(StringRef Name,
                                   llvm::function_ref<std::string()> Detail) {
   if (TimeTraceProfilerInstance != nullptr)
     TimeTraceProfilerInstance->begin(std::string(Name), Detail);
 }

 void llvm::timeTraceProfilerEnd() {
   if (TimeTraceProfilerInstance != nullptr)
     TimeTraceProfilerInstance->end();
 }
	//===-- TimeProfiler.cpp - Hierarchical Time Profiler ---------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements hierarchical time profiler.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Support/TimeProfiler.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/Support/CommandLine.h"
	#include "llvm/Support/JSON.h"
	#include "llvm/Support/Path.h"
	#include "llvm/Support/Process.h"
	#include "llvm/Support/Threading.h"
	#include <algorithm>
	#include <cassert>
	#include <chrono>
	#include <mutex>
	#include <string>
	#include <vector>

	using namespace std::chrono;
	using namespace llvm;

	static std::mutex Mu;
	// List of all instances
	static std::vector<TimeTraceProfiler *>
	ThreadTimeTraceProfilerInstances; // GUARDED_BY(Mu)
	// Per Thread instance
	static LLVM_THREAD_LOCAL TimeTraceProfiler *TimeTraceProfilerInstance = nullptr;

	TimeTraceProfiler *llvm::getTimeTraceProfilerInstance() {
	return TimeTraceProfilerInstance;
	}

	typedef duration<steady_clock::rep, steady_clock::period> DurationType;
	typedef time_point<steady_clock> TimePointType;
	typedef std::pair<size_t, DurationType> CountAndDurationType;
	typedef std::pair<std::string, CountAndDurationType>
	NameAndCountAndDurationType;

	namespace {
	struct Entry {
	const TimePointType Start;
	TimePointType End;
	const std::string Name;
	const std::string Detail;

	Entry(TimePointType &&S, TimePointType &&E, std::string &&N, std::string &&Dt)
	: Start(std::move(S)), End(std::move(E)), Name(std::move(N)),
	Detail(std::move(Dt)) {}

	// Calculate timings for FlameGraph. Cast time points to microsecond precision
	// rather than casting duration. This avoid truncation issues causing inner
	// scopes overruning outer scopes.
	steady_clock::rep getFlameGraphStartUs(TimePointType StartTime) const {
	return (time_point_cast<microseconds>(Start) -
	time_point_cast<microseconds>(StartTime))
	.count();
	}

	steady_clock::rep getFlameGraphDurUs() const {
	return (time_point_cast<microseconds>(End) -
	time_point_cast<microseconds>(Start))
	.count();
	}
	};
	} // namespace

	struct llvm::TimeTraceProfiler {
	TimeTraceProfiler(unsigned TimeTraceGranularity = 0, StringRef ProcName = "")
	: BeginningOfTime(system_clock::now()), StartTime(steady_clock::now()),
	ProcName(ProcName), Pid(sys::Process::getProcessId()),
	Tid(llvm::get_threadid()), TimeTraceGranularity(TimeTraceGranularity) {
	llvm::get_thread_name(ThreadName);
	}

	void begin(std::string Name, llvm::function_ref<std::string()> Detail) {
	Stack.emplace_back(steady_clock::now(), TimePointType(), std::move(Name),
	Detail());
	}

	void end() {
	assert(!Stack.empty() && "Must call begin() first");
	Entry &E = Stack.back();
	E.End = steady_clock::now();

	// Check that end times monotonically increase.
	assert((Entries.empty() \|\|
	(E.getFlameGraphStartUs(StartTime) + E.getFlameGraphDurUs() >=
	Entries.back().getFlameGraphStartUs(StartTime) +
	Entries.back().getFlameGraphDurUs())) &&
	"TimeProfiler scope ended earlier than previous scope");

	// Calculate duration at full precision for overall counts.
	DurationType Duration = E.End - E.Start;

	// Only include sections longer or equal to TimeTraceGranularity msec.
	if (duration_cast<microseconds>(Duration).count() >= TimeTraceGranularity)
	Entries.emplace_back(E);

	// Track total time taken by each "name", but only the topmost levels of
	// them; e.g. if there's a template instantiation that instantiates other
	// templates from within, we only want to add the topmost one. "topmost"
	// happens to be the ones that don't have any currently open entries above
	// itself.
	if (std::find_if(++Stack.rbegin(), Stack.rend(), [&](const Entry &Val) {
	return Val.Name == E.Name;
	}) == Stack.rend()) {
	auto &CountAndTotal = CountAndTotalPerName[E.Name];
	CountAndTotal.first++;
	CountAndTotal.second += Duration;
	}

	Stack.pop_back();
	}

	// Write events from this TimeTraceProfilerInstance and
	// ThreadTimeTraceProfilerInstances.
	void write(raw_pwrite_stream &OS) {
	// Acquire Mutex as reading ThreadTimeTraceProfilerInstances.
	std::lock_guard<std::mutex> Lock(Mu);
	assert(Stack.empty() &&
	"All profiler sections should be ended when calling write");
	assert(llvm::all_of(ThreadTimeTraceProfilerInstances,
	[](const auto &TTP) { return TTP->Stack.empty(); }) &&
	"All profiler sections should be ended when calling write");

	json::OStream J(OS);
	J.objectBegin();
	J.attributeBegin("traceEvents");
	J.arrayBegin();

	// Emit all events for the main flame graph.
	auto writeEvent = [&](const auto &E, uint64_t Tid) {
	auto StartUs = E.getFlameGraphStartUs(StartTime);
	auto DurUs = E.getFlameGraphDurUs();

	J.object([&] {
	J.attribute("pid", Pid);
	J.attribute("tid", int64_t(Tid));
	J.attribute("ph", "X");
	J.attribute("ts", StartUs);
	J.attribute("dur", DurUs);
	J.attribute("name", E.Name);
	if (!E.Detail.empty()) {
	J.attributeObject("args", [&] { J.attribute("detail", E.Detail); });
	}
	});
	};
	for (const Entry &E : Entries)
	writeEvent(E, this->Tid);
	for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
	for (const Entry &E : TTP->Entries)
	writeEvent(E, TTP->Tid);

	// Emit totals by section name as additional "thread" events, sorted from
	// longest one.
	// Find highest used thread id.
	uint64_t MaxTid = this->Tid;
	for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
	MaxTid = std::max(MaxTid, TTP->Tid);

	// Combine all CountAndTotalPerName from threads into one.
	StringMap<CountAndDurationType> AllCountAndTotalPerName;
	auto combineStat = [&](const auto &Stat) {
	StringRef Key = Stat.getKey();
	auto Value = Stat.getValue();
	auto &CountAndTotal = AllCountAndTotalPerName[Key];
	CountAndTotal.first += Value.first;
	CountAndTotal.second += Value.second;
	};
	for (const auto &Stat : CountAndTotalPerName)
	combineStat(Stat);
	for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
	for (const auto &Stat : TTP->CountAndTotalPerName)
	combineStat(Stat);

	std::vector<NameAndCountAndDurationType> SortedTotals;
	SortedTotals.reserve(AllCountAndTotalPerName.size());
	for (const auto &Total : AllCountAndTotalPerName)
	SortedTotals.emplace_back(std::string(Total.getKey()), Total.getValue());

	llvm::sort(SortedTotals, [](const NameAndCountAndDurationType &A,
	const NameAndCountAndDurationType &B) {
	return A.second.second > B.second.second;
	});

	// Report totals on separate threads of tracing file.
	uint64_t TotalTid = MaxTid + 1;
	for (const NameAndCountAndDurationType &Total : SortedTotals) {
	auto DurUs = duration_cast<microseconds>(Total.second.second).count();
	auto Count = AllCountAndTotalPerName[Total.first].first;

	J.object([&] {
	J.attribute("pid", Pid);
	J.attribute("tid", int64_t(TotalTid));
	J.attribute("ph", "X");
	J.attribute("ts", 0);
	J.attribute("dur", DurUs);
	J.attribute("name", "Total " + Total.first);
	J.attributeObject("args", [&] {
	J.attribute("count", int64_t(Count));
	J.attribute("avg ms", int64_t(DurUs / Count / 1000));
	});
	});

	++TotalTid;
	}

	auto writeMetadataEvent = [&](const char *Name, uint64_t Tid,
	StringRef arg) {
	J.object([&] {
	J.attribute("cat", "");
	J.attribute("pid", Pid);
	J.attribute("tid", int64_t(Tid));
	J.attribute("ts", 0);
	J.attribute("ph", "M");
	J.attribute("name", Name);
	J.attributeObject("args", [&] { J.attribute("name", arg); });
	});
	};

	writeMetadataEvent("process_name", Tid, ProcName);
	writeMetadataEvent("thread_name", Tid, ThreadName);
	for (const TimeTraceProfiler *TTP : ThreadTimeTraceProfilerInstances)
	writeMetadataEvent("thread_name", TTP->Tid, TTP->ThreadName);

	J.arrayEnd();
	J.attributeEnd();

	// Emit the absolute time when this TimeProfiler started.
	// This can be used to combine the profiling data from
	// multiple processes and preserve actual time intervals.
	J.attribute("beginningOfTime",
	time_point_cast<microseconds>(BeginningOfTime)
	.time_since_epoch()
	.count());

	J.objectEnd();
	}

	SmallVector<Entry, 16> Stack;
	SmallVector<Entry, 128> Entries;
	StringMap<CountAndDurationType> CountAndTotalPerName;
	const time_point<system_clock> BeginningOfTime;
	const TimePointType StartTime;
	const std::string ProcName;
	const sys::Process::Pid Pid;
	SmallString<0> ThreadName;
	const uint64_t Tid;

	// Minimum time granularity (in microseconds)
	const unsigned TimeTraceGranularity;
	};

	void llvm::timeTraceProfilerInitialize(unsigned TimeTraceGranularity,
	StringRef ProcName) {
	assert(TimeTraceProfilerInstance == nullptr &&
	"Profiler should not be initialized");
	TimeTraceProfilerInstance = new TimeTraceProfiler(
	TimeTraceGranularity, llvm::sys::path::filename(ProcName));
	}

	// Removes all TimeTraceProfilerInstances.
	// Called from main thread.
	void llvm::timeTraceProfilerCleanup() {
	delete TimeTraceProfilerInstance;
	std::lock_guard<std::mutex> Lock(Mu);
	for (auto TTP : ThreadTimeTraceProfilerInstances)
	delete TTP;
	ThreadTimeTraceProfilerInstances.clear();
	}

	// Finish TimeTraceProfilerInstance on a worker thread.
	// This doesn't remove the instance, just moves the pointer to global vector.
	void llvm::timeTraceProfilerFinishThread() {
	std::lock_guard<std::mutex> Lock(Mu);
	ThreadTimeTraceProfilerInstances.push_back(TimeTraceProfilerInstance);
	TimeTraceProfilerInstance = nullptr;
	}

	void llvm::timeTraceProfilerWrite(raw_pwrite_stream &OS) {
	assert(TimeTraceProfilerInstance != nullptr &&
	"Profiler object can't be null");
	TimeTraceProfilerInstance->write(OS);
	}

	Error llvm::timeTraceProfilerWrite(StringRef PreferredFileName,
	StringRef FallbackFileName) {
	assert(TimeTraceProfilerInstance != nullptr &&
	"Profiler object can't be null");

	std::string Path = PreferredFileName.str();
	if (Path.empty()) {
	Path = FallbackFileName == "-" ? "out" : FallbackFileName.str();
	Path += ".time-trace";
	}

	std::error_code EC;
	raw_fd_ostream OS(Path, EC, sys::fs::OF_Text);
	if (EC)
	return createStringError(EC, "Could not open " + Path);

	timeTraceProfilerWrite(OS);
	return Error::success();
	}

	void llvm::timeTraceProfilerBegin(StringRef Name, StringRef Detail) {
	if (TimeTraceProfilerInstance != nullptr)
	TimeTraceProfilerInstance->begin(std::string(Name),
	[&]() { return std::string(Detail); });
	}

	void llvm::timeTraceProfilerBegin(StringRef Name,
	llvm::function_ref<std::string()> Detail) {
	if (TimeTraceProfilerInstance != nullptr)
	TimeTraceProfilerInstance->begin(std::string(Name), Detail);
	}

	void llvm::timeTraceProfilerEnd() {
	if (TimeTraceProfilerInstance != nullptr)
	TimeTraceProfilerInstance->end();
	}