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/** @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 <iomanip>
#include <iostream>
#include <sstream>

#include "kmp.h"
#include "kmp_stats_timing.h"

using namespace std;

#if KMP_HAVE_TICK_TIME
#if KMP_MIC
double tsc_tick_count::tick_time() {
  // pretty bad assumption of 1GHz clock for MIC
  return 1 / ((double)1000 * 1.e6);
}
#elif KMP_ARCH_X86 || KMP_ARCH_X86_64
#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) {
    kmp_cpuid_t cpuinfo;
    char brand[256];

    __kmp_x86_cpuid(0x80000000, 0, &cpuinfo);
    memset(brand, 0, sizeof(brand));
    int ids = cpuinfo.eax;

    for (unsigned int i = 2; i < (ids ^ 0x80000000) + 2; i++)
      __kmp_x86_cpuid(i | 0x80000000, 0,
                      (kmp_cpuid_t *)(brand + (i - 2) * sizeof(kmp_cpuid_t)));

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

    char *end = brand + KMP_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.e21, 'y'},  {1.e18, 'z'},  {1.e15, 'a'},  {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();
}