// @(#)root/base:$Name: $:$Id: TStopwatch.cxx,v 1.6 2002/10/07 10:41:38 rdm Exp $
// Author: Fons Rademakers 11/10/95
/*************************************************************************
* Copyright (C) 1995-2000, Rene Brun and Fons Rademakers. *
* All rights reserved. *
* *
* For the licensing terms see $ROOTSYS/LICENSE. *
* For the list of contributors see $ROOTSYS/README/CREDITS. *
*************************************************************************/
//////////////////////////////////////////////////////////////////////////
// //
// TStopwatch //
// //
// Stopwatch class. This class returns the real and cpu time between //
// the start and stop events. //
// //
//////////////////////////////////////////////////////////////////////////
#include "TStopwatch.h"
#include "TString.h"
#if defined(R__MAC)
# include <time.h>
static clock_t gTicks = CLOCKS_PER_SEC;
#elif defined(R__UNIX)
# include <sys/times.h>
# include <unistd.h>
static clock_t gTicks = 0;
#elif defined(R__VMS)
# include <time.h>
# include <unistd.h>
static clock_t gTicks = 1000;
#elif defined(WIN32)
# include "TError.h"
const Double_t gTicks = 1.0e-7;
# include "Windows4Root.h"
#endif
ClassImp(TStopwatch)
//______________________________________________________________________________
TStopwatch::TStopwatch()
{
// Create a stopwatch and start it.
#ifdef R__UNIX
if (!gTicks) gTicks = (clock_t)sysconf(_SC_CLK_TCK);
#endif
fState = kUndefined;
fTotalCpuTime = 0;
fTotalRealTime = 0;
fCounter = 0;
Start();
}
//______________________________________________________________________________
void TStopwatch::Start(Bool_t reset)
{
// Start the stopwatch. If reset is kTRUE reset the stopwatch before
// starting it (including the stopwatch counter).
// Use kFALSE to continue timing after a Stop() without
// resetting the stopwatch.
if (reset) {
fTotalCpuTime = 0;
fTotalRealTime = 0;
fCounter = 0;
}
if (fState != kRunning) {
#ifndef R__UNIX
fStartRealTime = GetRealTime();
fStartCpuTime = GetCPUTime();
#else
struct tms cpt;
fStartRealTime = (Double_t)times(&cpt) / gTicks;
fStartCpuTime = (Double_t)(cpt.tms_utime+cpt.tms_stime) / gTicks;
#endif
}
fState = kRunning;
fCounter++;
}
//______________________________________________________________________________
void TStopwatch::Stop()
{
// Stop the stopwatch.
#ifndef R__UNIX
fStopRealTime = GetRealTime();
fStopCpuTime = GetCPUTime();
#else
struct tms cpt;
fStopRealTime = (Double_t)times(&cpt) / gTicks;
fStopCpuTime = (Double_t)(cpt.tms_utime+cpt.tms_stime) / gTicks;
#endif
if (fState == kRunning) {
fTotalCpuTime += fStopCpuTime - fStartCpuTime;
fTotalRealTime += fStopRealTime - fStartRealTime;
}
fState = kStopped;
}
//______________________________________________________________________________
void TStopwatch::Continue()
{
// Resume a stopped stopwatch. The stopwatch continues counting from the last
// Start() onwards (this is like the laptimer function).
if (fState == kUndefined)
Error("Continue", "stopwatch not started");
if (fState == kStopped) {
fTotalCpuTime -= fStopCpuTime - fStartCpuTime;
fTotalRealTime -= fStopRealTime - fStartRealTime;
}
fState = kRunning;
}
//______________________________________________________________________________
Double_t TStopwatch::RealTime()
{
// Return the realtime passed between the start and stop events. If the
// stopwatch was still running stop it first.
if (fState == kUndefined)
Error("RealTime", "stopwatch not started");
if (fState == kRunning)
Stop();
return fTotalRealTime;
}
//______________________________________________________________________________
Double_t TStopwatch::CpuTime()
{
// Return the cputime passed between the start and stop events. If the
// stopwatch was still running stop it first.
if (fState == kUndefined)
Error("CpuTime", "stopwatch not started");
if (fState == kRunning)
Stop();
return fTotalCpuTime;
}
//______________________________________________________________________________
Double_t TStopwatch::GetRealTime()
{
// Private static method returning system realtime.
#if defined(R__MAC)
return (Double_t)clock() / gTicks;
#elif defined(R__UNIX)
struct tms cpt;
Double_t trt = (Double_t)times(&cpt);
return trt / (Double_t) gTicks;
#elif defined(R__VMS)
return (Double_t)clock() / gTicks;
#elif defined(WIN32)
union {
FILETIME ftFileTime;
__int64 ftInt64;
} ftRealTime; // time the process has spent in kernel mode
SYSTEMTIME st;
GetSystemTime(&st);
SystemTimeToFileTime(&st,&ftRealTime.ftFileTime);
return (Double_t)ftRealTime.ftInt64 * gTicks;
#endif
}
//______________________________________________________________________________
Double_t TStopwatch::GetCPUTime()
{
// Private static method returning system CPU time.
#if defined(R__MAC)
return (Double_t)clock() / gTicks;
#elif defined(R__UNIX)
struct tms cpt;
times(&cpt);
return (Double_t)(cpt.tms_utime+cpt.tms_stime) / gTicks;
#elif defined(R__VMS)
return (Double_t)clock() / gTicks;
#elif defined(WIN32)
OSVERSIONINFO OsVersionInfo;
// Value Platform
//----------------------------------------------------
// VER_PLATFORM_WIN32s Win32s on Windows 3.1
// VER_PLATFORM_WIN32_WINDOWS Win32 on Windows 95
// VER_PLATFORM_WIN32_NT Windows NT
//
OsVersionInfo.dwOSVersionInfoSize=sizeof(OSVERSIONINFO);
GetVersionEx(&OsVersionInfo);
if (OsVersionInfo.dwPlatformId == VER_PLATFORM_WIN32_NT) {
DWORD ret;
FILETIME ftCreate, // when the process was created
ftExit; // when the process exited
union {
FILETIME ftFileTime;
__int64 ftInt64;
} ftKernel; // time the process has spent in kernel mode
union {
FILETIME ftFileTime;
__int64 ftInt64;
} ftUser; // time the process has spent in user mode
HANDLE hProcess = GetCurrentProcess();
ret = GetProcessTimes (hProcess, &ftCreate, &ftExit,
&ftKernel.ftFileTime,
&ftUser.ftFileTime);
if (ret != TRUE) {
ret = GetLastError ();
::Error ("GetCPUTime", " Error on GetProcessTimes 0x%lx", (int)ret);
}
// Process times are returned in a 64-bit structure, as the number of
// 100 nanosecond ticks since 1 January 1601. User mode and kernel mode
// times for this process are in separate 64-bit structures.
// To convert to floating point seconds, we will:
//
// Convert sum of high 32-bit quantities to 64-bit int
return (Double_t) (ftKernel.ftInt64 + ftUser.ftInt64) * gTicks;
} else
return GetRealTime();
#endif
}
//______________________________________________________________________________
void TStopwatch::Print(Option_t *opt) const
{
// Print the real and cpu time passed between the start and stop events.
// and the number of times (slices) this TStopwatch was called
// (if this number > 1). If opt="m" printout realtime in milli second
// precision.
Double_t realt = const_cast<TStopwatch*>(this)->RealTime();
Double_t cput = const_cast<TStopwatch*>(this)->CpuTime();
Int_t hours = Int_t(realt / 3600);
realt -= hours * 3600;
Int_t min = Int_t(realt / 60);
realt -= min * 60;
Int_t sec = Int_t(realt);
realt = TMath::Max(realt, 0.);
cput = TMath::Max(cput, 0.);
if (opt && *opt == 'm') {
if (Counter() > 1) {
Printf("Real time %d:%02d:%06.3f, CP time %.3f, %d slices", hours, min, realt, cput, Counter());
} else {
Printf("Real time %d:%02d:%06.3f, CP time %.3f", hours, min, realt, cput);
}
} else {
if (Counter() > 1) {
Printf("Real time %d:%02d:%02d, CP time %.3f, %d slices", hours, min, sec, cput, Counter());
} else {
Printf("Real time %d:%02d:%02d, CP time %.3f", hours, min, sec, cput);
}
}
}
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