my_rdtsc-t.c 6.34 KB
/* Copyright (C) 2008-2009 Sun Microsystems, Inc

  This program is free software; you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation; version 2 of the License.

  This program is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.

  You should have received a copy of the GNU General Public License
  along with this program; if not, write to the Free Software
  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA */

/*
  rdtsc3 -- multi-platform timer code
  pgulutzan@mysql.com, 2005-08-29
  modified 2008-11-02

  When you run rdtsc3, it will print the contents of
  "my_timer_info". The display indicates
  what timer routine is best for a given platform.

  For example, this is the display on production.mysql.com,
  a 2.8GHz Xeon with Linux 2.6.17, gcc 3.3.3:

  cycles        nanoseconds   microseconds  milliseconds  ticks
------------- ------------- ------------- ------------- -------------
            1            11            13            18            17
   2815019607    1000000000       1000000          1049           102
            1          1000             1             1             1
           88          4116          3888          4092          2044

  The first line shows routines, e.g. 1 = MY_TIMER_ROUTINE_ASM_X86.
  The second line shows frequencies, e.g. 2815019607 is nearly 2.8GHz.
  The third line shows resolutions, e.g. 1000 = very poor resolution.
  The fourth line shows overheads, e.g. ticks takes 2044 cycles.
*/

#include "my_global.h"
#include "my_rdtsc.h"
#include "tap.h"

#define LOOP_COUNT 100

MY_TIMER_INFO myt;

void test_init()
{
  my_timer_init(&myt);

  diag("----- Routine ---------------");
  diag("myt.cycles.routine          : %13llu", myt.cycles.routine);
  diag("myt.nanoseconds.routine     : %13llu", myt.nanoseconds.routine);
  diag("myt.microseconds.routine    : %13llu", myt.microseconds.routine);
  diag("myt.milliseconds.routine    : %13llu", myt.milliseconds.routine);
  diag("myt.ticks.routine           : %13llu", myt.ticks.routine);

  diag("----- Frequency -------------");
  diag("myt.cycles.frequency        : %13llu", myt.cycles.frequency);
  diag("myt.nanoseconds.frequency   : %13llu", myt.nanoseconds.frequency);
  diag("myt.microseconds.frequency  : %13llu", myt.microseconds.frequency);
  diag("myt.milliseconds.frequency  : %13llu", myt.milliseconds.frequency);
  diag("myt.ticks.frequency         : %13llu", myt.ticks.frequency);

  diag("----- Resolution ------------");
  diag("myt.cycles.resolution       : %13llu", myt.cycles.resolution);
  diag("myt.nanoseconds.resolution  : %13llu", myt.nanoseconds.resolution);
  diag("myt.microseconds.resolution : %13llu", myt.microseconds.resolution);
  diag("myt.milliseconds.resolution : %13llu", myt.milliseconds.resolution);
  diag("myt.ticks.resolution        : %13llu", myt.ticks.resolution);

  diag("----- Overhead --------------");
  diag("myt.cycles.overhead         : %13llu", myt.cycles.overhead);
  diag("myt.nanoseconds.overhead    : %13llu", myt.nanoseconds.overhead);
  diag("myt.microseconds.overhead   : %13llu", myt.microseconds.overhead);
  diag("myt.milliseconds.overhead   : %13llu", myt.milliseconds.overhead);
  diag("myt.ticks.overhead          : %13llu", myt.ticks.overhead);

  ok(1, "my_timer_init() did not crash");
}

void test_cycle()
{
  ulonglong t1= my_timer_cycles();
  ulonglong t2;
  int i;
  int backward= 0;
  int nonzero= 0;

  for (i=0 ; i < LOOP_COUNT ; i++)
  {
    t2= my_timer_cycles();
    if (t1 >= t2)
      backward++;
    if (t2 != 0)
      nonzero++;
    t1= t2;
  }

  /* Expect at most 1 backward, the cycle value can overflow */
  ok((backward <= 1), "The cycle timer is strictly increasing");

  if (myt.cycles.routine != 0)
    ok((nonzero != 0), "The cycle timer is implemented");
  else
    ok((nonzero == 0), "The cycle timer is not implemented and returns 0");
}

void test_nanosecond()
{
  ulonglong t1= my_timer_nanoseconds();
  ulonglong t2;
  int i;
  int backward= 0;
  int nonzero= 0;

  for (i=0 ; i < LOOP_COUNT ; i++)
  {
    t2= my_timer_nanoseconds();
    if (t1 > t2)
      backward++;
    if (t2 != 0)
      nonzero++;
    t1= t2;
  }

  ok((backward == 0), "The nanosecond timer is increasing");

  if (myt.nanoseconds.routine != 0)
    ok((nonzero != 0), "The nanosecond timer is implemented");
  else
    ok((nonzero == 0), "The nanosecond timer is not implemented and returns 0");
}

void test_microsecond()
{
  ulonglong t1= my_timer_microseconds();
  ulonglong t2;
  int i;
  int backward= 0;
  int nonzero= 0;

  for (i=0 ; i < LOOP_COUNT ; i++)
  {
    t2= my_timer_microseconds();
    if (t1 > t2)
      backward++;
    if (t2 != 0)
      nonzero++;
    t1= t2;
  }

  ok((backward == 0), "The microsecond timer is increasing");

  if (myt.microseconds.routine != 0)
    ok((nonzero != 0), "The microsecond timer is implemented");
  else
    ok((nonzero == 0), "The microsecond timer is not implemented and returns 0");
}

void test_millisecond()
{
  ulonglong t1= my_timer_milliseconds();
  ulonglong t2;
  int i;
  int backward= 0;
  int nonzero= 0;

  for (i=0 ; i < LOOP_COUNT ; i++)
  {
    t2= my_timer_milliseconds();
    if (t1 > t2)
      backward++;
    if (t2 != 0)
      nonzero++;
    t1= t2;
  }

  ok((backward == 0), "The millisecond timer is increasing");

  if (myt.milliseconds.routine != 0)
    ok((nonzero != 0), "The millisecond timer is implemented");
  else
    ok((nonzero == 0), "The millisecond timer is not implemented and returns 0");
}

void test_tick()
{
  ulonglong t1= my_timer_ticks();
  ulonglong t2;
  int i;
  int backward= 0;
  int nonzero= 0;

  for (i=0 ; i < LOOP_COUNT ; i++)
  {
    t2= my_timer_ticks();
    if (t1 > t2)
      backward++;
    if (t2 != 0)
      nonzero++;
    t1= t2;
  }

  ok((backward == 0), "The tick timer is increasing");

  if (myt.ticks.routine != 0)
    ok((nonzero != 0), "The tick timer is implemented");
  else
    ok((nonzero == 0), "The tick timer is not implemented and returns 0");
}

int main(int argc __attribute__((unused)),
         char ** argv __attribute__((unused)))
{
  plan(11);

  test_init();
  test_cycle();
  test_nanosecond();
  test_microsecond();
  test_millisecond();
  test_tick();

  return 0;
}