task_stats.cpp

来自「这是广泛使用的通信开源项目,对于大容量,高并发的通讯要求完全能够胜任,他广泛可用」· C++ 代码 · 共 192 行

//Task_Stats.cpp,v 1.1 2001/12/20 00:02:40 pradeep Exp
#include "Task_Stats.h"
#include "ace/OS.h"
#include "ace/Log_Msg.h"

#if !defined (__ACE_INLINE__)
#include "Task_Stats.inl"
#endif /* __ACE_INLINE__ */

Base_Time::Base_Time (void)
{
  base_time_ = ACE_OS::gethrtime ();
}

Task_Stats::Task_Stats (size_t max_samples)
  : base_time_(0),
    end_time_ (0),
    max_samples_ (max_samples),
    samples_count_ (0),
    time_inv_ (0),
    time_exec_ (0),
    exec_time_min_ (0),
    exec_time_min_at_ (0),
    exec_time_max_ (0),
    exec_time_max_at_(0),
    sum_ (0),
    sum2_ (0)
{
}

Task_Stats::~Task_Stats (void)
{
  delete[] this->time_inv_;
  delete[] this->time_exec_;
}

int
Task_Stats::init (void)
{
  ACE_NEW_RETURN (this->time_inv_, ACE_UINT64[this->max_samples_], -1);
  ACE_NEW_RETURN (this->time_exec_, ACE_UINT64[this->max_samples_], -1);
  return 0;
}

void
Task_Stats::base_time (ACE_hrtime_t time)
{
  base_time_ = time;
}

void
Task_Stats::end_time (ACE_hrtime_t time)
{
  end_time_ = time;
}

void
Task_Stats::dump_samples (const ACE_TCHAR *file_name, const ACE_TCHAR *msg,
                          ACE_UINT32 scale_factor)
{
  FILE* output_file = ACE_OS::fopen (file_name, "w");

  // first dump what the caller has to say.
  ACE_OS::fprintf (output_file, "%s\n",msg);

  // next, compose and dump what we want to say.

  // calc throughput.

  ACE_TCHAR out_msg[BUFSIZ];

  ACE_hrtime_t elapsed_microseconds = (end_time_ - base_time_) / scale_factor;
  double elapsed_seconds =
    ACE_CU64_TO_CU32(elapsed_microseconds) / 1000000.0;
  double throughput =
    double(samples_count_) / elapsed_seconds;

  ACE_OS::sprintf (out_msg, "#Throughtput: %f\n", throughput);
  ACE_OS::fprintf (output_file, "%s\n",out_msg);

  // dump latency stats.
  this->dump_latency_stats (out_msg, scale_factor);
  ACE_OS::fprintf (output_file, "%s\n",out_msg);
  ACE_OS::fprintf (output_file, "#Invocation time \t Execution time\n");

  // dump the samples recorded.
  for (size_t i = 0; i != this->samples_count_; ++i)
    {
      ACE_UINT64 x = this->time_inv_[i] / scale_factor;
      ACE_UINT32 val_1 = ACE_CU64_TO_CU32 (x);

      ACE_UINT64 y = this->time_exec_[i] / scale_factor;
      ACE_UINT32 val_2 = ACE_CU64_TO_CU32 (y);

      ACE_OS::fprintf (output_file, "%u \t %u\n",val_1, val_2);
    }

  ACE_OS::fclose (output_file);
}

void
Task_Stats::dump_latency_stats (ACE_TCHAR *out_msg, ACE_UINT32 sf)
{
  if (this->samples_count_ == 0u)
    {
      ACE_OS::sprintf (out_msg,
                       ACE_LIB_TEXT ("# no data collected\n"));
      return;
    }

  ACE_UINT64 avg = this->sum_ / this->samples_count_;
  ACE_UINT64 dev =
#if defined ACE_LACKS_LONGLONG_T
    ACE_static_cast (ACE_U_LongLong,
                     this->sum2_ / this->samples_count_)
    - avg * ACE_U64_TO_U32(avg);
#else  /* ! ACE_LACKS_LONGLONG_T */
    this->sum2_ / this->samples_count_ - avg * avg;
#endif /* ! ACE_LACKS_LONGLONG_T */

    ACE_UINT64 l_min_ = this->exec_time_min_ / sf;
    ACE_UINT32 l_min = ACE_CU64_TO_CU32 (l_min_);

    ACE_UINT64 l_max_ = this->exec_time_max_ / sf;
    ACE_UINT32 l_max = ACE_CU64_TO_CU32 (l_max_);

    /*
    ACE_UINT64 l_avg_ = avg / sf;
    ACE_UINT32 l_avg = ACE_CU64_TO_CU32 (l_avg_);

    ACE_UINT64 l_dev_ = dev / sf;
    ACE_UINT32 l_dev = ACE_CU64_TO_CU32 (l_dev_);
    */

    double l_avg = ACE_CU64_TO_CU32 (avg) / sf;
    double l_dev = ACE_CU64_TO_CU32 (dev) / (sf * sf);

    ACE_UINT64 tmin_ = this->time_inv_[0] / sf;
    ACE_UINT32 tmin = ACE_CU64_TO_CU32 (tmin_);

    ACE_UINT64 tmax_ = this->time_inv_[samples_count_-1] / sf;
    ACE_UINT32 tmax = ACE_CU64_TO_CU32 (tmax_);

    ACE_OS::sprintf(out_msg,
                  ACE_LIB_TEXT ("#latency   : %u[%d]/%.2f/%u[%d]/%.2f (min/avg/max/var^2)\n #first invocation time = %u, last invocation time = %u\n"),
                  l_min, this->exec_time_min_at_,
                  l_avg,
                  l_max, this->exec_time_max_at_,
                  l_dev,
                  tmin,tmax);
    /*
  double l_min = ACE_CU64_TO_CU32 (this->exec_time_min_) / sf;
  double l_max = ACE_CU64_TO_CU32 (this->exec_time_max_) / sf;
  double l_avg = ACE_CU64_TO_CU32 (avg) / sf;
  double l_dev = ACE_CU64_TO_CU32 (dev) / (sf * sf);

  double tmin = ACE_CU64_TO_CU32 (this->time_inv_[0])/sf;
  double tmax = ACE_CU64_TO_CU32 (this->time_inv_[samples_count_-1])/sf;

  ACE_OS::sprintf(out_msg,
                  ACE_LIB_TEXT ("#latency   : %.2f[%d]/%.2f/%.2f[%d]/%.2f (min/avg/max/var^2)\n #first invocation time = %.0f, last invocation time = %.0f\n"),
                  l_min, this->exec_time_min_at_,
                  l_avg,
                  l_max, this->exec_time_max_at_,
                  l_dev,
                  tmin,tmax);


  ACE_OS::sprintf(out_msg,
                  ACE_LIB_TEXT ("#latency   : %.2f[%d]/%.2f/%.2f[%d]/%.2f (min/avg/max/var^2)\n"),
                  l_min, this->exec_time_min_at_,
                  l_avg,
                  l_max, this->exec_time_max_at_,
                  l_dev);

  ACE_DEBUG ((LM_DEBUG, ACE_LIB_TEXT ("#latency   : %.2f[%d]/%.2f/%.2f[%d]/%.2f (min/avg/max/var^2)\n"),
                  l_min, this->exec_time_min_at_,
                  l_avg,
                  l_max, this->exec_time_max_at_,
                  l_dev));
  */
}
#if defined (ACE_HAS_EXPLICIT_TEMPLATE_INSTANTIATION)

template class ACE_Singleton<Base_Time, TAO_SYNCH_MUTEX>;

#elif defined (ACE_HAS_TEMPLATE_INSTANTIATION_PRAGMA)

#pragma instantiate ACE_Singleton<Base_Time, TAO_SYNCH_MUTEX>

#endif /*ACE_HAS_EXPLICIT_TEMPLATE_INSTANTIATION */