llvm/lib/Support/Timer.cpp - toolchain/llvm-project - Gitiles

 //===-- Timer.cpp - Interval Timing Support -------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Interval Timing implementation.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Support/Timer.h"
 #include "llvm/Support/CommandLine.h"
 #include "llvm/Support/ManagedStatic.h"
 #include "llvm/Support/Streams.h"
 #include "llvm/System/Process.h"
 #include <algorithm>
 #include <fstream>
 #include <functional>
 #include <map>
 using namespace llvm;

 // GetLibSupportInfoOutputFile - Return a file stream to print our output on.
 namespace llvm { extern std::ostream *GetLibSupportInfoOutputFile(); }

 // getLibSupportInfoOutputFilename - This ugly hack is brought to you courtesy
 // of constructor/destructor ordering being unspecified by C++.  Basically the
 // problem is that a Statistic object gets destroyed, which ends up calling
 // 'GetLibSupportInfoOutputFile()' (below), which calls this function.
 // LibSupportInfoOutputFilename used to be a global variable, but sometimes it
 // would get destroyed before the Statistic, causing havoc to ensue.  We "fix"
 // this by creating the string the first time it is needed and never destroying
 // it.
 static ManagedStatic<std::string> LibSupportInfoOutputFilename;
 static std::string &getLibSupportInfoOutputFilename() {
   return *LibSupportInfoOutputFilename;
 }

 static ManagedStatic<sys::SmartMutex<true> > TimerLock;

 namespace {
   static cl::opt<bool>
   TrackSpace("track-memory", cl::desc("Enable -time-passes memory "
                                       "tracking (this may be slow)"),
              cl::Hidden);

   static cl::opt<std::string, true>
   InfoOutputFilename("info-output-file", cl::value_desc("filename"),
                      cl::desc("File to append -stats and -timer output to"),
                    cl::Hidden, cl::location(getLibSupportInfoOutputFilename()));
 }

 static TimerGroup *DefaultTimerGroup = 0;
 static TimerGroup *getDefaultTimerGroup() {
   TimerGroup* tmp = DefaultTimerGroup;
   sys::MemoryFence();
   if (!tmp) {
     llvm_acquire_global_lock();
     tmp = DefaultTimerGroup;
     if (!tmp) {
       tmp = new TimerGroup("Miscellaneous Ungrouped Timers");
       sys::MemoryFence();
       DefaultTimerGroup = tmp;
     }
     llvm_release_global_lock();
   }

   return tmp;
 }

 Timer::Timer(const std::string &N)
   : Elapsed(0), UserTime(0), SystemTime(0), MemUsed(0), PeakMem(0), Name(N),
     Started(false), TG(getDefaultTimerGroup()) {
   TG->addTimer();
 }

 Timer::Timer(const std::string &N, TimerGroup &tg)
   : Elapsed(0), UserTime(0), SystemTime(0), MemUsed(0), PeakMem(0), Name(N),
     Started(false), TG(&tg) {
   TG->addTimer();
 }

 Timer::Timer(const Timer &T) {
   TG = T.TG;
   if (TG) TG->addTimer();
   operator=(T);
 }


 // Copy ctor, initialize with no TG member.
 Timer::Timer(bool, const Timer &T) {
   TG = T.TG;     // Avoid assertion in operator=
   operator=(T);  // Copy contents
   TG = 0;
 }


 Timer::~Timer() {
   if (TG) {
     if (Started) {
       Started = false;
       TG->addTimerToPrint(*this);
     }
     TG->removeTimer();
   }
 }

 static inline size_t getMemUsage() {
   if (TrackSpace)
     return sys::Process::GetMallocUsage();
   return 0;
 }

 struct TimeRecord {
   double Elapsed, UserTime, SystemTime;
   ssize_t MemUsed;
 };

 static TimeRecord getTimeRecord(bool Start) {
   TimeRecord Result;

   sys::TimeValue now(0,0);
   sys::TimeValue user(0,0);
   sys::TimeValue sys(0,0);

   ssize_t MemUsed = 0;
   if (Start) {
     MemUsed = getMemUsage();
     sys::Process::GetTimeUsage(now,user,sys);
   } else {
     sys::Process::GetTimeUsage(now,user,sys);
     MemUsed = getMemUsage();
   }

   Result.Elapsed  = now.seconds()  + now.microseconds()  / 1000000.0;
   Result.UserTime = user.seconds() + user.microseconds() / 1000000.0;
   Result.SystemTime  = sys.seconds()  + sys.microseconds()  / 1000000.0;
   Result.MemUsed  = MemUsed;

   return Result;
 }

 static ManagedStatic<std::vector<Timer*> > ActiveTimers;

 void Timer::startTimer() {
   sys::SmartScopedLock<true> L(Lock);
   Started = true;
   ActiveTimers->push_back(this);
   TimeRecord TR = getTimeRecord(true);
   Elapsed    -= TR.Elapsed;
   UserTime   -= TR.UserTime;
   SystemTime -= TR.SystemTime;
   MemUsed    -= TR.MemUsed;
   PeakMemBase = TR.MemUsed;
 }

 void Timer::stopTimer() {
   sys::SmartScopedLock<true> L(Lock);
   TimeRecord TR = getTimeRecord(false);
   Elapsed    += TR.Elapsed;
   UserTime   += TR.UserTime;
   SystemTime += TR.SystemTime;
   MemUsed    += TR.MemUsed;

   if (ActiveTimers->back() == this) {
     ActiveTimers->pop_back();
   } else {
     std::vector<Timer*>::iterator I =
       std::find(ActiveTimers->begin(), ActiveTimers->end(), this);
     assert(I != ActiveTimers->end() && "stop but no startTimer?");
     ActiveTimers->erase(I);
   }
 }

 void Timer::sum(const Timer &T) {
   if (&T < this) {
     T.Lock.acquire();
     Lock.acquire();
   } else {
     Lock.acquire();
     T.Lock.acquire();
   }

   Elapsed    += T.Elapsed;
   UserTime   += T.UserTime;
   SystemTime += T.SystemTime;
   MemUsed    += T.MemUsed;
   PeakMem    += T.PeakMem;

   if (&T < this) {
     T.Lock.release();
     Lock.release();
   } else {
     Lock.release();
     T.Lock.release();
   }
 }

 /// addPeakMemoryMeasurement - This method should be called whenever memory
 /// usage needs to be checked.  It adds a peak memory measurement to the
 /// currently active timers, which will be printed when the timer group prints
 ///
 void Timer::addPeakMemoryMeasurement() {
   size_t MemUsed = getMemUsage();

   for (std::vector<Timer*>::iterator I = ActiveTimers->begin(),
          E = ActiveTimers->end(); I != E; ++I) {
     (*I)->Lock.acquire();
     (*I)->PeakMem = std::max((*I)->PeakMem, MemUsed-(*I)->PeakMemBase);
     (*I)->Lock.release();
   }
 }

 //===----------------------------------------------------------------------===//
 //   NamedRegionTimer Implementation
 //===----------------------------------------------------------------------===//

 namespace {

 typedef std::map<std::string, Timer> Name2Timer;
 typedef std::map<std::string, std::pair<TimerGroup, Name2Timer> > Name2Pair;

 }

 static ManagedStatic<Name2Timer> NamedTimers;

 static ManagedStatic<Name2Pair> NamedGroupedTimers;

 static Timer &getNamedRegionTimer(const std::string &Name) {
   sys::SmartScopedLock<true> L(*TimerLock);
   Name2Timer::iterator I = NamedTimers->find(Name);
   if (I != NamedTimers->end())
     return I->second;

   return NamedTimers->insert(I, std::make_pair(Name, Timer(Name)))->second;
 }

 static Timer &getNamedRegionTimer(const std::string &Name,
                                   const std::string &GroupName) {
   sys::SmartScopedLock<true> L(*TimerLock);

   Name2Pair::iterator I = NamedGroupedTimers->find(GroupName);
   if (I == NamedGroupedTimers->end()) {
     TimerGroup TG(GroupName);
     std::pair<TimerGroup, Name2Timer> Pair(TG, Name2Timer());
     I = NamedGroupedTimers->insert(I, std::make_pair(GroupName, Pair));
   }

   Name2Timer::iterator J = I->second.second.find(Name);
   if (J == I->second.second.end())
     J = I->second.second.insert(J,
                                 std::make_pair(Name,
                                                Timer(Name,
                                                      I->second.first)));

   return J->second;
 }

 NamedRegionTimer::NamedRegionTimer(const std::string &Name)
   : TimeRegion(getNamedRegionTimer(Name)) {}

 NamedRegionTimer::NamedRegionTimer(const std::string &Name,
                                    const std::string &GroupName)
   : TimeRegion(getNamedRegionTimer(Name, GroupName)) {}

 //===----------------------------------------------------------------------===//
 //   TimerGroup Implementation
 //===----------------------------------------------------------------------===//

 // printAlignedFP - Simulate the printf "%A.Bf" format, where A is the
 // TotalWidth size, and B is the AfterDec size.
 //
 static void printAlignedFP(double Val, unsigned AfterDec, unsigned TotalWidth,
                            std::ostream &OS) {
   assert(TotalWidth >= AfterDec+1 && "Bad FP Format!");
   OS.width(TotalWidth-AfterDec-1);
   char OldFill = OS.fill();
   OS.fill(' ');
   OS << (int)Val;  // Integer part;
   OS << ".";
   OS.width(AfterDec);
   OS.fill('0');
   unsigned ResultFieldSize = 1;
   while (AfterDec--) ResultFieldSize *= 10;
   OS << (int)(Val*ResultFieldSize) % ResultFieldSize;
   OS.fill(OldFill);
 }

 static void printVal(double Val, double Total, std::ostream &OS) {
   if (Total < 1e-7)   // Avoid dividing by zero...
     OS << "        -----     ";
   else {
     OS << "  ";
     printAlignedFP(Val, 4, 7, OS);
     OS << " (";
     printAlignedFP(Val*100/Total, 1, 5, OS);
     OS << "%)";
   }
 }

 void Timer::print(const Timer &Total, std::ostream &OS) {
   if (&Total < this) {
     Total.Lock.acquire();
     Lock.acquire();
   } else {
     Lock.acquire();
     Total.Lock.acquire();
   }

   if (Total.UserTime)
     printVal(UserTime, Total.UserTime, OS);
   if (Total.SystemTime)
     printVal(SystemTime, Total.SystemTime, OS);
   if (Total.getProcessTime())
     printVal(getProcessTime(), Total.getProcessTime(), OS);
   printVal(Elapsed, Total.Elapsed, OS);

   OS << "  ";

   if (Total.MemUsed) {
     OS.width(9);
     OS << MemUsed << "  ";
   }
   if (Total.PeakMem) {
     if (PeakMem) {
       OS.width(9);
       OS << PeakMem << "  ";
     } else
       OS << "           ";
   }
   OS << Name << "\n";

   Started = false;  // Once printed, don't print again

   if (&Total < this) {
     Total.Lock.release();
     Lock.release();
   } else {
     Lock.release();
     Total.Lock.release();
   }
 }

 // GetLibSupportInfoOutputFile - Return a file stream to print our output on...
 std::ostream *
 llvm::GetLibSupportInfoOutputFile() {
   std::string &LibSupportInfoOutputFilename = getLibSupportInfoOutputFilename();
   if (LibSupportInfoOutputFilename.empty())
     return cerr.stream();
   if (LibSupportInfoOutputFilename == "-")
     return cout.stream();

   std::ostream *Result = new std::ofstream(LibSupportInfoOutputFilename.c_str(),
                                            std::ios::app);
   if (!Result->good()) {
     cerr << "Error opening info-output-file '"
          << LibSupportInfoOutputFilename << " for appending!\n";
     delete Result;
     return cerr.stream();
   }
   return Result;
 }


 void TimerGroup::removeTimer() {
   sys::SmartScopedLock<true> L(*TimerLock);
   if (--NumTimers == 0 && !TimersToPrint.empty()) { // Print timing report...
     // Sort the timers in descending order by amount of time taken...
     std::sort(TimersToPrint.begin(), TimersToPrint.end(),
               std::greater<Timer>());

     // Figure out how many spaces to indent TimerGroup name...
     unsigned Padding = (80-Name.length())/2;
     if (Padding > 80) Padding = 0;         // Don't allow "negative" numbers

     std::ostream *OutStream = GetLibSupportInfoOutputFile();

     ++NumTimers;
     {  // Scope to contain Total timer... don't allow total timer to drop us to
        // zero timers...
       Timer Total("TOTAL");

       for (unsigned i = 0, e = TimersToPrint.size(); i != e; ++i)
         Total.sum(TimersToPrint[i]);

       // Print out timing header...
       *OutStream << "===" << std::string(73, '-') << "===\n"
                  << std::string(Padding, ' ') << Name << "\n"
                  << "===" << std::string(73, '-')
                  << "===\n";

       // If this is not an collection of ungrouped times, print the total time.
       // Ungrouped timers don't really make sense to add up.  We still print the
       // TOTAL line to make the percentages make sense.
       if (this != DefaultTimerGroup) {
         *OutStream << "  Total Execution Time: ";

         printAlignedFP(Total.getProcessTime(), 4, 5, *OutStream);
         *OutStream << " seconds (";
         printAlignedFP(Total.getWallTime(), 4, 5, *OutStream);
         *OutStream << " wall clock)\n";
       }
       *OutStream << "\n";

       if (Total.UserTime)
         *OutStream << "   ---User Time---";
       if (Total.SystemTime)
         *OutStream << "   --System Time--";
       if (Total.getProcessTime())
         *OutStream << "   --User+System--";
       *OutStream << "   ---Wall Time---";
       if (Total.getMemUsed())
         *OutStream << "  ---Mem---";
       if (Total.getPeakMem())
         *OutStream << "  -PeakMem-";
       *OutStream << "  --- Name ---\n";

       // Loop through all of the timing data, printing it out...
       for (unsigned i = 0, e = TimersToPrint.size(); i != e; ++i)
         TimersToPrint[i].print(Total, *OutStream);

       Total.print(Total, *OutStream);
       *OutStream << std::endl;  // Flush output
     }
     --NumTimers;

     TimersToPrint.clear();

     if (OutStream != cerr.stream() && OutStream != cout.stream())
       delete OutStream;   // Close the file...
   }
 }

 void TimerGroup::addTimer() {
   sys::SmartScopedLock<true> L(*TimerLock);
   ++NumTimers;
 }

 void TimerGroup::addTimerToPrint(const Timer &T) {
   sys::SmartScopedLock<true> L(*TimerLock);
   TimersToPrint.push_back(Timer(true, T));
 }
	//===-- Timer.cpp - Interval Timing Support -------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Interval Timing implementation.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Support/Timer.h"
	#include "llvm/Support/CommandLine.h"
	#include "llvm/Support/ManagedStatic.h"
	#include "llvm/Support/Streams.h"
	#include "llvm/System/Process.h"
	#include <algorithm>
	#include <fstream>
	#include <functional>
	#include <map>
	using namespace llvm;

	// GetLibSupportInfoOutputFile - Return a file stream to print our output on.
	namespace llvm { extern std::ostream *GetLibSupportInfoOutputFile(); }

	// getLibSupportInfoOutputFilename - This ugly hack is brought to you courtesy
	// of constructor/destructor ordering being unspecified by C++. Basically the
	// problem is that a Statistic object gets destroyed, which ends up calling
	// 'GetLibSupportInfoOutputFile()' (below), which calls this function.
	// LibSupportInfoOutputFilename used to be a global variable, but sometimes it
	// would get destroyed before the Statistic, causing havoc to ensue. We "fix"
	// this by creating the string the first time it is needed and never destroying
	// it.
	static ManagedStatic<std::string> LibSupportInfoOutputFilename;
	static std::string &getLibSupportInfoOutputFilename() {
	return *LibSupportInfoOutputFilename;
	}

	static ManagedStatic<sys::SmartMutex<true> > TimerLock;

	namespace {
	static cl::opt<bool>
	TrackSpace("track-memory", cl::desc("Enable -time-passes memory "
	"tracking (this may be slow)"),
	cl::Hidden);

	static cl::opt<std::string, true>
	InfoOutputFilename("info-output-file", cl::value_desc("filename"),
	cl::desc("File to append -stats and -timer output to"),
	cl::Hidden, cl::location(getLibSupportInfoOutputFilename()));
	}

	static TimerGroup *DefaultTimerGroup = 0;
	static TimerGroup *getDefaultTimerGroup() {
	TimerGroup* tmp = DefaultTimerGroup;
	sys::MemoryFence();
	if (!tmp) {
	llvm_acquire_global_lock();
	tmp = DefaultTimerGroup;
	if (!tmp) {
	tmp = new TimerGroup("Miscellaneous Ungrouped Timers");
	sys::MemoryFence();
	DefaultTimerGroup = tmp;
	}
	llvm_release_global_lock();
	}

	return tmp;
	}

	Timer::Timer(const std::string &N)
	: Elapsed(0), UserTime(0), SystemTime(0), MemUsed(0), PeakMem(0), Name(N),
	Started(false), TG(getDefaultTimerGroup()) {
	TG->addTimer();
	}

	Timer::Timer(const std::string &N, TimerGroup &tg)
	: Elapsed(0), UserTime(0), SystemTime(0), MemUsed(0), PeakMem(0), Name(N),
	Started(false), TG(&tg) {
	TG->addTimer();
	}

	Timer::Timer(const Timer &T) {
	TG = T.TG;
	if (TG) TG->addTimer();
	operator=(T);
	}


	// Copy ctor, initialize with no TG member.
	Timer::Timer(bool, const Timer &T) {
	TG = T.TG; // Avoid assertion in operator=
	operator=(T); // Copy contents
	TG = 0;
	}


	Timer::~Timer() {
	if (TG) {
	if (Started) {
	Started = false;
	TG->addTimerToPrint(*this);
	}
	TG->removeTimer();
	}
	}

	static inline size_t getMemUsage() {
	if (TrackSpace)
	return sys::Process::GetMallocUsage();
	return 0;
	}

	struct TimeRecord {
	double Elapsed, UserTime, SystemTime;
	ssize_t MemUsed;
	};

	static TimeRecord getTimeRecord(bool Start) {
	TimeRecord Result;

	sys::TimeValue now(0,0);
	sys::TimeValue user(0,0);
	sys::TimeValue sys(0,0);

	ssize_t MemUsed = 0;
	if (Start) {
	MemUsed = getMemUsage();
	sys::Process::GetTimeUsage(now,user,sys);
	} else {
	sys::Process::GetTimeUsage(now,user,sys);
	MemUsed = getMemUsage();
	}

	Result.Elapsed = now.seconds() + now.microseconds() / 1000000.0;
	Result.UserTime = user.seconds() + user.microseconds() / 1000000.0;
	Result.SystemTime = sys.seconds() + sys.microseconds() / 1000000.0;
	Result.MemUsed = MemUsed;

	return Result;
	}

	static ManagedStatic<std::vector<Timer*> > ActiveTimers;

	void Timer::startTimer() {
	sys::SmartScopedLock<true> L(Lock);
	Started = true;
	ActiveTimers->push_back(this);
	TimeRecord TR = getTimeRecord(true);
	Elapsed -= TR.Elapsed;
	UserTime -= TR.UserTime;
	SystemTime -= TR.SystemTime;
	MemUsed -= TR.MemUsed;
	PeakMemBase = TR.MemUsed;
	}

	void Timer::stopTimer() {
	sys::SmartScopedLock<true> L(Lock);
	TimeRecord TR = getTimeRecord(false);
	Elapsed += TR.Elapsed;
	UserTime += TR.UserTime;
	SystemTime += TR.SystemTime;
	MemUsed += TR.MemUsed;

	if (ActiveTimers->back() == this) {
	ActiveTimers->pop_back();
	} else {
	std::vector<Timer*>::iterator I =
	std::find(ActiveTimers->begin(), ActiveTimers->end(), this);
	assert(I != ActiveTimers->end() && "stop but no startTimer?");
	ActiveTimers->erase(I);
	}
	}

	void Timer::sum(const Timer &T) {
	if (&T < this) {
	T.Lock.acquire();
	Lock.acquire();
	} else {
	Lock.acquire();
	T.Lock.acquire();
	}

	Elapsed += T.Elapsed;
	UserTime += T.UserTime;
	SystemTime += T.SystemTime;
	MemUsed += T.MemUsed;
	PeakMem += T.PeakMem;

	if (&T < this) {
	T.Lock.release();
	Lock.release();
	} else {
	Lock.release();
	T.Lock.release();
	}
	}

	/// addPeakMemoryMeasurement - This method should be called whenever memory
	/// usage needs to be checked. It adds a peak memory measurement to the
	/// currently active timers, which will be printed when the timer group prints
	///
	void Timer::addPeakMemoryMeasurement() {
	size_t MemUsed = getMemUsage();

	for (std::vector<Timer*>::iterator I = ActiveTimers->begin(),
	E = ActiveTimers->end(); I != E; ++I) {
	(*I)->Lock.acquire();
	(I)->PeakMem = std::max((I)->PeakMem, MemUsed-(*I)->PeakMemBase);
	(*I)->Lock.release();
	}
	}

	//===----------------------------------------------------------------------===//
	// NamedRegionTimer Implementation
	//===----------------------------------------------------------------------===//

	namespace {

	typedef std::map<std::string, Timer> Name2Timer;
	typedef std::map<std::string, std::pair<TimerGroup, Name2Timer> > Name2Pair;

	}

	static ManagedStatic<Name2Timer> NamedTimers;

	static ManagedStatic<Name2Pair> NamedGroupedTimers;

	static Timer &getNamedRegionTimer(const std::string &Name) {
	sys::SmartScopedLock<true> L(*TimerLock);
	Name2Timer::iterator I = NamedTimers->find(Name);
	if (I != NamedTimers->end())
	return I->second;

	return NamedTimers->insert(I, std::make_pair(Name, Timer(Name)))->second;
	}

	static Timer &getNamedRegionTimer(const std::string &Name,
	const std::string &GroupName) {
	sys::SmartScopedLock<true> L(*TimerLock);

	Name2Pair::iterator I = NamedGroupedTimers->find(GroupName);
	if (I == NamedGroupedTimers->end()) {
	TimerGroup TG(GroupName);
	std::pair<TimerGroup, Name2Timer> Pair(TG, Name2Timer());
	I = NamedGroupedTimers->insert(I, std::make_pair(GroupName, Pair));
	}

	Name2Timer::iterator J = I->second.second.find(Name);
	if (J == I->second.second.end())
	J = I->second.second.insert(J,
	std::make_pair(Name,
	Timer(Name,
	I->second.first)));

	return J->second;
	}

	NamedRegionTimer::NamedRegionTimer(const std::string &Name)
	: TimeRegion(getNamedRegionTimer(Name)) {}

	NamedRegionTimer::NamedRegionTimer(const std::string &Name,
	const std::string &GroupName)
	: TimeRegion(getNamedRegionTimer(Name, GroupName)) {}

	//===----------------------------------------------------------------------===//
	// TimerGroup Implementation
	//===----------------------------------------------------------------------===//

	// printAlignedFP - Simulate the printf "%A.Bf" format, where A is the
	// TotalWidth size, and B is the AfterDec size.
	//
	static void printAlignedFP(double Val, unsigned AfterDec, unsigned TotalWidth,
	std::ostream &OS) {
	assert(TotalWidth >= AfterDec+1 && "Bad FP Format!");
	OS.width(TotalWidth-AfterDec-1);
	char OldFill = OS.fill();
	OS.fill(' ');
	OS << (int)Val; // Integer part;
	OS << ".";
	OS.width(AfterDec);
	OS.fill('0');
	unsigned ResultFieldSize = 1;
	while (AfterDec--) ResultFieldSize *= 10;
	OS << (int)(Val*ResultFieldSize) % ResultFieldSize;
	OS.fill(OldFill);
	}

	static void printVal(double Val, double Total, std::ostream &OS) {
	if (Total < 1e-7) // Avoid dividing by zero...
	OS << " ----- ";
	else {
	OS << " ";
	printAlignedFP(Val, 4, 7, OS);
	OS << " (";
	printAlignedFP(Val*100/Total, 1, 5, OS);
	OS << "%)";
	}
	}

	void Timer::print(const Timer &Total, std::ostream &OS) {
	if (&Total < this) {
	Total.Lock.acquire();
	Lock.acquire();
	} else {
	Lock.acquire();
	Total.Lock.acquire();
	}

	if (Total.UserTime)
	printVal(UserTime, Total.UserTime, OS);
	if (Total.SystemTime)
	printVal(SystemTime, Total.SystemTime, OS);
	if (Total.getProcessTime())
	printVal(getProcessTime(), Total.getProcessTime(), OS);
	printVal(Elapsed, Total.Elapsed, OS);

	OS << " ";

	if (Total.MemUsed) {
	OS.width(9);
	OS << MemUsed << " ";
	}
	if (Total.PeakMem) {
	if (PeakMem) {
	OS.width(9);
	OS << PeakMem << " ";
	} else
	OS << " ";
	}
	OS << Name << "\n";

	Started = false; // Once printed, don't print again

	if (&Total < this) {
	Total.Lock.release();
	Lock.release();
	} else {
	Lock.release();
	Total.Lock.release();
	}
	}

	// GetLibSupportInfoOutputFile - Return a file stream to print our output on...
	std::ostream *
	llvm::GetLibSupportInfoOutputFile() {
	std::string &LibSupportInfoOutputFilename = getLibSupportInfoOutputFilename();
	if (LibSupportInfoOutputFilename.empty())
	return cerr.stream();
	if (LibSupportInfoOutputFilename == "-")
	return cout.stream();

	std::ostream *Result = new std::ofstream(LibSupportInfoOutputFilename.c_str(),
	std::ios::app);
	if (!Result->good()) {
	cerr << "Error opening info-output-file '"
	<< LibSupportInfoOutputFilename << " for appending!\n";
	delete Result;
	return cerr.stream();
	}
	return Result;
	}


	void TimerGroup::removeTimer() {
	sys::SmartScopedLock<true> L(*TimerLock);
	if (--NumTimers == 0 && !TimersToPrint.empty()) { // Print timing report...
	// Sort the timers in descending order by amount of time taken...
	std::sort(TimersToPrint.begin(), TimersToPrint.end(),
	std::greater<Timer>());

	// Figure out how many spaces to indent TimerGroup name...
	unsigned Padding = (80-Name.length())/2;
	if (Padding > 80) Padding = 0; // Don't allow "negative" numbers

	std::ostream *OutStream = GetLibSupportInfoOutputFile();

	++NumTimers;
	{ // Scope to contain Total timer... don't allow total timer to drop us to
	// zero timers...
	Timer Total("TOTAL");

	for (unsigned i = 0, e = TimersToPrint.size(); i != e; ++i)
	Total.sum(TimersToPrint[i]);

	// Print out timing header...
	*OutStream << "===" << std::string(73, '-') << "===\n"
	<< std::string(Padding, ' ') << Name << "\n"
	<< "===" << std::string(73, '-')
	<< "===\n";

	// If this is not an collection of ungrouped times, print the total time.
	// Ungrouped timers don't really make sense to add up. We still print the
	// TOTAL line to make the percentages make sense.
	if (this != DefaultTimerGroup) {
	*OutStream << " Total Execution Time: ";

	printAlignedFP(Total.getProcessTime(), 4, 5, *OutStream);
	*OutStream << " seconds (";
	printAlignedFP(Total.getWallTime(), 4, 5, *OutStream);
	*OutStream << " wall clock)\n";
	}
	*OutStream << "\n";

	if (Total.UserTime)
	*OutStream << " ---User Time---";
	if (Total.SystemTime)
	*OutStream << " --System Time--";
	if (Total.getProcessTime())
	*OutStream << " --User+System--";
	*OutStream << " ---Wall Time---";
	if (Total.getMemUsed())
	*OutStream << " ---Mem---";
	if (Total.getPeakMem())
	*OutStream << " -PeakMem-";
	*OutStream << " --- Name ---\n";

	// Loop through all of the timing data, printing it out...
	for (unsigned i = 0, e = TimersToPrint.size(); i != e; ++i)
	TimersToPrint[i].print(Total, *OutStream);

	Total.print(Total, *OutStream);
	*OutStream << std::endl; // Flush output
	}
	--NumTimers;

	TimersToPrint.clear();

	if (OutStream != cerr.stream() && OutStream != cout.stream())
	delete OutStream; // Close the file...
	}
	}

	void TimerGroup::addTimer() {
	sys::SmartScopedLock<true> L(*TimerLock);
	++NumTimers;
	}

	void TimerGroup::addTimerToPrint(const Timer &T) {
	sys::SmartScopedLock<true> L(*TimerLock);
	TimersToPrint.push_back(Timer(true, T));
	}