final/runtime/src/kmp_stats_timing.cpp - openmp - Git at Google

 /** @file kmp_stats_timing.cpp
  * Timing functions
  */


 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.txt for details.
 //
 //===----------------------------------------------------------------------===//


 #include <stdlib.h>
 #include <unistd.h>

 #include <iostream>
 #include <iomanip>
 #include <sstream>

 #include "kmp_stats_timing.h"

 using namespace std;

 #if KMP_OS_LINUX
 # if KMP_MIC
 double tsc_tick_count::tick_time()
 {
     // pretty bad assumption of 1GHz clock for MIC
     return 1/((double)1000*1.e6);
 }
 # else
 #  include <string.h>
 // Extract the value from the CPUID information
 double tsc_tick_count::tick_time()
 {
     static double result = 0.0;

     if (result == 0.0)
     {
         int cpuinfo[4];
         char brand[256];

         __cpuid(cpuinfo, 0x80000000);
         memset(brand, 0, sizeof(brand));
         int ids = cpuinfo[0];

         for (unsigned int i=2; i<(ids^0x80000000)+2; i++)
             __cpuid(brand+(i-2)*sizeof(cpuinfo), i | 0x80000000);

         char * start = &brand[0];
         for (;*start == ' '; start++)
             ;

         char * end = brand + strlen(brand) - 3;
         uint64_t multiplier;

         if (*end == 'M') multiplier = 1000LL*1000LL;
         else if (*end == 'G') multiplier = 1000LL*1000LL*1000LL;
         else if (*end == 'T') multiplier = 1000LL*1000LL*1000LL*1000LL;
         else
         {
             cout << "Error determining multiplier '" << *end << "'\n";
             exit (-1);
         }
         *end = 0;
         while (*end != ' ') end--;
         end++;

         double freq = strtod(end, &start);
         if (freq == 0.0)
         {
             cout << "Error calculating frequency " <<  end << "\n";
             exit (-1);
         }

         result = ((double)1.0)/(freq * multiplier);
     }
     return result;
 }
 # endif
 #endif

 static bool useSI = true;

 // Return a formatted string after normalising the value into
 // engineering style and using a suitable unit prefix (e.g. ms, us, ns).
 std::string formatSI(double interval, int width, char unit)
 {
     std::stringstream os;

     if (useSI)
     {
         // Preserve accuracy for small numbers, since we only multiply and the positive powers
         // of ten are precisely representable.
         static struct { double scale; char prefix; } ranges[] = {
             {1.e12,'f'},
             {1.e9, 'p'},
             {1.e6, 'n'},
             {1.e3, 'u'},
             {1.0,  'm'},
             {1.e-3,' '},
             {1.e-6,'k'},
             {1.e-9,'M'},
             {1.e-12,'G'},
             {1.e-15,'T'},
             {1.e-18,'P'},
             {1.e-21,'E'},
             {1.e-24,'Z'},
             {1.e-27,'Y'}
         };

         if (interval == 0.0)
         {
             os << std::setw(width-3) << std::right << "0.00" << std::setw(3) << unit;
             return os.str();
         }

         bool negative = false;
         if (interval < 0.0)
         {
             negative = true;
             interval = -interval;
         }

         for (int i=0; i<(int)(sizeof(ranges)/sizeof(ranges[0])); i++)
         {
             if (interval*ranges[i].scale < 1.e0)
             {
                 interval = interval * 1000.e0 * ranges[i].scale;
                 os << std::fixed << std::setprecision(2) << std::setw(width-3) << std::right <<
                     (negative ? -interval : interval) << std::setw(2) << ranges[i].prefix << std::setw(1) << unit;

                 return os.str();
             }
         }
     }
     os << std::setprecision(2) << std::fixed << std::right << std::setw(width-3) << interval << std::setw(3) << unit;

     return os.str();
 }

 tsc_tick_count::tsc_interval_t computeLastInLastOutInterval(timePair * times, int nTimes)
 {
     timePair lastTimes = times[0];
     tsc_tick_count * startp = lastTimes.get_startp();
     tsc_tick_count * endp   = lastTimes.get_endp();

     for (int i=1; i<nTimes; i++)
     {
        (*startp) = startp->later(times[i].get_start());
        (*endp)   = endp->later  (times[i].get_end());
     }

     return lastTimes.duration();
 }

 std::string timePair::format() const
 {
     std::ostringstream oss;

     oss << start.getValue() << ":" << end.getValue() << " = " << (end-start).getValue();

     return oss.str();
 }
	/** @file kmp_stats_timing.cpp
	* Timing functions
	*/


	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.txt for details.
	//
	//===----------------------------------------------------------------------===//


	#include <stdlib.h>
	#include <unistd.h>

	#include <iostream>
	#include <iomanip>
	#include <sstream>

	#include "kmp_stats_timing.h"

	using namespace std;

	#if KMP_OS_LINUX
	# if KMP_MIC
	double tsc_tick_count::tick_time()
	{
	// pretty bad assumption of 1GHz clock for MIC
	return 1/((double)1000*1.e6);
	}
	# else
	# include <string.h>
	// Extract the value from the CPUID information
	double tsc_tick_count::tick_time()
	{
	static double result = 0.0;

	if (result == 0.0)
	{
	int cpuinfo[4];
	char brand[256];

	__cpuid(cpuinfo, 0x80000000);
	memset(brand, 0, sizeof(brand));
	int ids = cpuinfo[0];

	for (unsigned int i=2; i<(ids^0x80000000)+2; i++)
	__cpuid(brand+(i-2)*sizeof(cpuinfo), i \| 0x80000000);

	char * start = &brand[0];
	for (;*start == ' '; start++)
	;

	char * end = brand + strlen(brand) - 3;
	uint64_t multiplier;

	if (end == 'M') multiplier = 1000LL1000LL;
	else if (end == 'G') multiplier = 1000LL1000LL*1000LL;
	else if (end == 'T') multiplier = 1000LL1000LL1000LL1000LL;
	else
	{
	cout << "Error determining multiplier '" << *end << "'\n";
	exit (-1);
	}
	*end = 0;
	while (*end != ' ') end--;
	end++;

	double freq = strtod(end, &start);
	if (freq == 0.0)
	{
	cout << "Error calculating frequency " << end << "\n";
	exit (-1);
	}

	result = ((double)1.0)/(freq * multiplier);
	}
	return result;
	}
	# endif
	#endif

	static bool useSI = true;

	// Return a formatted string after normalising the value into
	// engineering style and using a suitable unit prefix (e.g. ms, us, ns).
	std::string formatSI(double interval, int width, char unit)
	{
	std::stringstream os;

	if (useSI)
	{
	// Preserve accuracy for small numbers, since we only multiply and the positive powers
	// of ten are precisely representable.
	static struct { double scale; char prefix; } ranges[] = {
	{1.e12,'f'},
	{1.e9, 'p'},
	{1.e6, 'n'},
	{1.e3, 'u'},
	{1.0, 'm'},
	{1.e-3,' '},
	{1.e-6,'k'},
	{1.e-9,'M'},
	{1.e-12,'G'},
	{1.e-15,'T'},
	{1.e-18,'P'},
	{1.e-21,'E'},
	{1.e-24,'Z'},
	{1.e-27,'Y'}
	};

	if (interval == 0.0)
	{
	os << std::setw(width-3) << std::right << "0.00" << std::setw(3) << unit;
	return os.str();
	}

	bool negative = false;
	if (interval < 0.0)
	{
	negative = true;
	interval = -interval;
	}

	for (int i=0; i<(int)(sizeof(ranges)/sizeof(ranges[0])); i++)
	{
	if (interval*ranges[i].scale < 1.e0)
	{
	interval = interval * 1000.e0 * ranges[i].scale;
	os << std::fixed << std::setprecision(2) << std::setw(width-3) << std::right <<
	(negative ? -interval : interval) << std::setw(2) << ranges[i].prefix << std::setw(1) << unit;

	return os.str();
	}
	}
	}
	os << std::setprecision(2) << std::fixed << std::right << std::setw(width-3) << interval << std::setw(3) << unit;

	return os.str();
	}

	tsc_tick_count::tsc_interval_t computeLastInLastOutInterval(timePair * times, int nTimes)
	{
	timePair lastTimes = times[0];
	tsc_tick_count * startp = lastTimes.get_startp();
	tsc_tick_count * endp = lastTimes.get_endp();

	for (int i=1; i<nTimes; i++)
	{
	(*startp) = startp->later(times[i].get_start());
	(*endp) = endp->later (times[i].get_end());
	}

	return lastTimes.duration();
	}

	std::string timePair::format() const
	{
	std::ostringstream oss;

	oss << start.getValue() << ":" << end.getValue() << " = " << (end-start).getValue();

	return oss.str();
	}