netcpu_procstat.c - platform/external/netperf - Git at Google

 char   netcpu_procstat_id[]="\
 @(#)netcpu_procstat.c (c) Copyright 2005-2007 Version 2.4.3";

 /* netcpu_procstat.c

    Implement the /proc/stat specific portions of netperf CPU
    utilization measurements. These are broken-out into a separate file
    to make life much nicer over in netlib.c which had become a maze of
    twisty, CPU-util-related, #ifdefs, all different.  raj 2005-01-26
    */

 #ifdef HAVE_CONFIG_H
 #include <config.h>
 #endif

 #include <stdio.h>

 #ifdef HAVE_FCNTL_H
 # include <fcntl.h>
 #endif
 #if HAVE_UNISTD_H
 # include <unistd.h>
 #endif
 #if STDC_HEADERS
 # include <stdlib.h>
 # include <stddef.h>
 #else
 # if HAVE_STDLIB_H
 #  include <stdlib.h>
 # endif
 #endif

 #include <string.h>

 #include "netsh.h"
 #include "netlib.h"

 /* the lib_start_count and lib_end_count arrays hold the starting
    and ending values of whatever is counting when the system is
    idle. The rate at which this increments during a test is compared
    with a previous calibrarion to arrive at a CPU utilization
    percentage. raj 2005-01-26 */
 static uint64_t  lib_start_count[MAXCPUS];
 static uint64_t  lib_end_count[MAXCPUS];


 /* The max. length of one line of /proc/stat cpu output */
 #define CPU_LINE_LENGTH ((8 * sizeof (long) / 3 + 1) * 4 + 8)
 #define PROC_STAT_FILE_NAME "/proc/stat"
 #define N_CPU_LINES(nr) (nr == 1 ? 1 : 1 + nr)

 static int proc_stat_fd = -1;
 static char *proc_stat_buf = NULL;
 static int proc_stat_buflen = 0;

 void
 cpu_util_init(void)
 {

   if (debug) {
     fprintf(where,
 	    "cpu_util_init enter, proc_stat_fd %d proc_stat_buf %p\n",
 	    proc_stat_fd,
 	    proc_stat_buf);
     fflush(where);
   }
   if (proc_stat_fd < 0) {
     proc_stat_fd = open (PROC_STAT_FILE_NAME, O_RDONLY, NULL);
     if (proc_stat_fd < 0) {
       fprintf (stderr, "Cannot open %s!\n", PROC_STAT_FILE_NAME);
       exit (1);
     };
   };

   if (!proc_stat_buf) {
     proc_stat_buflen = N_CPU_LINES (lib_num_loc_cpus) * CPU_LINE_LENGTH;
     if (debug) {
       fprintf(where,
 	      "lib_num_loc_cpus %d lines %d CPU_LINE_LENGTH %d proc_stat_buflen %d\n",
 	      lib_num_loc_cpus,
 	      N_CPU_LINES(lib_num_loc_cpus),
 	      CPU_LINE_LENGTH,
 	      proc_stat_buflen);
       fflush(where);
     }
     proc_stat_buf = (char *)malloc (proc_stat_buflen);
     if (!proc_stat_buf) {
       fprintf (stderr, "Cannot allocate buffer memory!\n");
       exit (1);
     }
   }
   return;
 }

 void
 cpu_util_terminate(void)
 {
   close(proc_stat_fd);
   proc_stat_fd = -1;
   free(proc_stat_buf);
   proc_stat_buf = NULL;
   return;
 }

 int
 get_cpu_method()
 {
   return PROC_STAT;
 }

 float
 calibrate_idle_rate (int iterations, int interval)
 {
   if (proc_stat_fd < 0) {
     proc_stat_fd = open (PROC_STAT_FILE_NAME, O_RDONLY, NULL);
     if (proc_stat_fd < 0) {
       fprintf (stderr, "Cannot open %s!\n", PROC_STAT_FILE_NAME);
       exit (1);
     };
   };

   if (!proc_stat_buf) {
     proc_stat_buflen = N_CPU_LINES (lib_num_loc_cpus) * CPU_LINE_LENGTH;
     if (debug) {
       fprintf(where,
 	      "calibrate: lib_num_loc_cpus %d lines %d CPU_LINE_LENGTH %d proc_stat_buflen %d\n",
 	      lib_num_loc_cpus,
 	      N_CPU_LINES(lib_num_loc_cpus),
 	      CPU_LINE_LENGTH,
 	      proc_stat_buflen);
       fflush(where);
     }
     proc_stat_buf = (char *)malloc (proc_stat_buflen);
     if (!proc_stat_buf) {
       fprintf (stderr, "Cannot allocate buffer memory!\n");
       exit (1);
     };
   };

   return sysconf (_SC_CLK_TCK);
 }

 void
 get_cpu_idle (uint64_t *res)
 {
   int space;
   int i;
   int n = lib_num_loc_cpus;
   char *p = proc_stat_buf;

   lseek (proc_stat_fd, 0, SEEK_SET);
   read (proc_stat_fd, p, proc_stat_buflen);

   if (debug) {
     fprintf(where,"proc_stat_buf '%.*s'\n",proc_stat_buflen,p);
     fflush(where);
   }
   /* Skip first line (total) on SMP */
   if (n > 1) p = strchr (p, '\n');

   /* Idle time is the 4th space-separated token */
   for (i = 0; i < n; i++) {
     for (space = 0; space < 4; space ++) {
       p = strchr (p, ' ');
       while (*++p == ' ');
     };
     res[i] = strtoul (p, &p, 10);
     if (debug) {
       fprintf(where,"res[%d] is %llu\n",i,res[i]);
       fflush(where);
     }
     p = strchr (p, '\n');
   };

 }

 /* take the initial timestamp and start collecting CPU utilization if
    requested */

 void
 measure_cpu_start()
 {
   cpu_method = PROC_STAT;
   get_cpu_idle(lib_start_count);
 }

 /* collect final CPU utilization raw data */
 void
 measure_cpu_stop()
 {
   get_cpu_idle(lib_end_count);
 }

 float
 calc_cpu_util_internal(float elapsed_time)
 {
   int i;

   float actual_rate;
   float correction_factor;

   lib_local_cpu_util = (float)0.0;
   /* It is possible that the library measured a time other than */
   /* the one that the user want for the cpu utilization */
   /* calculations - for example, tests that were ended by */
   /* watchdog timers such as the udp stream test. We let these */
   /* tests tell up what the elapsed time should be. */

   if (elapsed_time != 0.0) {
     correction_factor = (float) 1.0 +
       ((lib_elapsed - elapsed_time) / elapsed_time);
   }
   else {
     correction_factor = (float) 1.0;
   }

   for (i = 0; i < lib_num_loc_cpus; i++) {

     /* it would appear that on some systems, in loopback, nice is
      *very* effective, causing the looper process to stop dead in its
      tracks. if this happens, we need to ensure that the calculation
      does not go south. raj 6/95 and if we run completely out of idle,
      the same thing could in theory happen to the USE_KSTAT path. raj
      8/2000 */

     if (lib_end_count[i] == lib_start_count[i]) {
       lib_end_count[i]++;
     }

     actual_rate = (lib_end_count[i] > lib_start_count[i]) ?
       (float)(lib_end_count[i] - lib_start_count[i])/lib_elapsed :
       (float)(lib_end_count[i] - lib_start_count[i] +
 	      MAXLONG)/ lib_elapsed;
     lib_local_per_cpu_util[i] = (lib_local_maxrate - actual_rate) /
       lib_local_maxrate * 100;
     if (debug) {
       fprintf(where,
               "calc_cpu_util: actual_rate on processor %d is %f start %llx end %llx util %f\n",
               i,
               actual_rate,
               lib_start_count[i],
               lib_end_count[i],
 	      lib_local_per_cpu_util[i]);
     }
     lib_local_cpu_util += lib_local_per_cpu_util[i];
   }
   /* we want the average across all n processors */
   lib_local_cpu_util /= (float)lib_num_loc_cpus;

   lib_local_cpu_util *= correction_factor;
   return lib_local_cpu_util;
 }

 void
 cpu_start_internal(void)
 {
   get_cpu_idle(lib_start_count);
   return;
 }

 void
 cpu_stop_internal(void)
 {
   get_cpu_idle(lib_end_count);
 }
	char netcpu_procstat_id[]="\
	@(#)netcpu_procstat.c (c) Copyright 2005-2007 Version 2.4.3";

	/* netcpu_procstat.c

	Implement the /proc/stat specific portions of netperf CPU
	utilization measurements. These are broken-out into a separate file
	to make life much nicer over in netlib.c which had become a maze of
	twisty, CPU-util-related, #ifdefs, all different. raj 2005-01-26
	*/

	#ifdef HAVE_CONFIG_H
	#include <config.h>
	#endif

	#include <stdio.h>

	#ifdef HAVE_FCNTL_H
	# include <fcntl.h>
	#endif
	#if HAVE_UNISTD_H
	# include <unistd.h>
	#endif
	#if STDC_HEADERS
	# include <stdlib.h>
	# include <stddef.h>
	#else
	# if HAVE_STDLIB_H
	# include <stdlib.h>
	# endif
	#endif

	#include <string.h>

	#include "netsh.h"
	#include "netlib.h"

	/* the lib_start_count and lib_end_count arrays hold the starting
	and ending values of whatever is counting when the system is
	idle. The rate at which this increments during a test is compared
	with a previous calibrarion to arrive at a CPU utilization
	percentage. raj 2005-01-26 */
	static uint64_t lib_start_count[MAXCPUS];
	static uint64_t lib_end_count[MAXCPUS];


	/* The max. length of one line of /proc/stat cpu output */
	#define CPU_LINE_LENGTH ((8 * sizeof (long) / 3 + 1) * 4 + 8)
	#define PROC_STAT_FILE_NAME "/proc/stat"
	#define N_CPU_LINES(nr) (nr == 1 ? 1 : 1 + nr)

	static int proc_stat_fd = -1;
	static char *proc_stat_buf = NULL;
	static int proc_stat_buflen = 0;

	void
	cpu_util_init(void)
	{

	if (debug) {
	fprintf(where,
	"cpu_util_init enter, proc_stat_fd %d proc_stat_buf %p\n",
	proc_stat_fd,
	proc_stat_buf);
	fflush(where);
	}
	if (proc_stat_fd < 0) {
	proc_stat_fd = open (PROC_STAT_FILE_NAME, O_RDONLY, NULL);
	if (proc_stat_fd < 0) {
	fprintf (stderr, "Cannot open %s!\n", PROC_STAT_FILE_NAME);
	exit (1);
	};
	};

	if (!proc_stat_buf) {
	proc_stat_buflen = N_CPU_LINES (lib_num_loc_cpus) * CPU_LINE_LENGTH;
	if (debug) {
	fprintf(where,
	"lib_num_loc_cpus %d lines %d CPU_LINE_LENGTH %d proc_stat_buflen %d\n",
	lib_num_loc_cpus,
	N_CPU_LINES(lib_num_loc_cpus),
	CPU_LINE_LENGTH,
	proc_stat_buflen);
	fflush(where);
	}
	proc_stat_buf = (char *)malloc (proc_stat_buflen);
	if (!proc_stat_buf) {
	fprintf (stderr, "Cannot allocate buffer memory!\n");
	exit (1);
	}
	}
	return;
	}

	void
	cpu_util_terminate(void)
	{
	close(proc_stat_fd);
	proc_stat_fd = -1;
	free(proc_stat_buf);
	proc_stat_buf = NULL;
	return;
	}

	int
	get_cpu_method()
	{
	return PROC_STAT;
	}

	float
	calibrate_idle_rate (int iterations, int interval)
	{
	if (proc_stat_fd < 0) {
	proc_stat_fd = open (PROC_STAT_FILE_NAME, O_RDONLY, NULL);
	if (proc_stat_fd < 0) {
	fprintf (stderr, "Cannot open %s!\n", PROC_STAT_FILE_NAME);
	exit (1);
	};
	};

	if (!proc_stat_buf) {
	proc_stat_buflen = N_CPU_LINES (lib_num_loc_cpus) * CPU_LINE_LENGTH;
	if (debug) {
	fprintf(where,
	"calibrate: lib_num_loc_cpus %d lines %d CPU_LINE_LENGTH %d proc_stat_buflen %d\n",
	lib_num_loc_cpus,
	N_CPU_LINES(lib_num_loc_cpus),
	CPU_LINE_LENGTH,
	proc_stat_buflen);
	fflush(where);
	}
	proc_stat_buf = (char *)malloc (proc_stat_buflen);
	if (!proc_stat_buf) {
	fprintf (stderr, "Cannot allocate buffer memory!\n");
	exit (1);
	};
	};

	return sysconf (_SC_CLK_TCK);
	}

	void
	get_cpu_idle (uint64_t *res)
	{
	int space;
	int i;
	int n = lib_num_loc_cpus;
	char *p = proc_stat_buf;

	lseek (proc_stat_fd, 0, SEEK_SET);
	read (proc_stat_fd, p, proc_stat_buflen);

	if (debug) {
	fprintf(where,"proc_stat_buf '%.*s'\n",proc_stat_buflen,p);
	fflush(where);
	}
	/* Skip first line (total) on SMP */
	if (n > 1) p = strchr (p, '\n');

	/* Idle time is the 4th space-separated token */
	for (i = 0; i < n; i++) {
	for (space = 0; space < 4; space ++) {
	p = strchr (p, ' ');
	while (*++p == ' ');
	};
	res[i] = strtoul (p, &p, 10);
	if (debug) {
	fprintf(where,"res[%d] is %llu\n",i,res[i]);
	fflush(where);
	}
	p = strchr (p, '\n');
	};

	}

	/* take the initial timestamp and start collecting CPU utilization if
	requested */

	void
	measure_cpu_start()
	{
	cpu_method = PROC_STAT;
	get_cpu_idle(lib_start_count);
	}

	/* collect final CPU utilization raw data */
	void
	measure_cpu_stop()
	{
	get_cpu_idle(lib_end_count);
	}

	float
	calc_cpu_util_internal(float elapsed_time)
	{
	int i;

	float actual_rate;
	float correction_factor;

	lib_local_cpu_util = (float)0.0;
	/* It is possible that the library measured a time other than */
	/* the one that the user want for the cpu utilization */
	/* calculations - for example, tests that were ended by */
	/* watchdog timers such as the udp stream test. We let these */
	/* tests tell up what the elapsed time should be. */

	if (elapsed_time != 0.0) {
	correction_factor = (float) 1.0 +
	((lib_elapsed - elapsed_time) / elapsed_time);
	}
	else {
	correction_factor = (float) 1.0;
	}

	for (i = 0; i < lib_num_loc_cpus; i++) {

	/* it would appear that on some systems, in loopback, nice is
	very effective, causing the looper process to stop dead in its
	tracks. if this happens, we need to ensure that the calculation
	does not go south. raj 6/95 and if we run completely out of idle,
	the same thing could in theory happen to the USE_KSTAT path. raj
	8/2000 */

	if (lib_end_count[i] == lib_start_count[i]) {
	lib_end_count[i]++;
	}

	actual_rate = (lib_end_count[i] > lib_start_count[i]) ?
	(float)(lib_end_count[i] - lib_start_count[i])/lib_elapsed :
	(float)(lib_end_count[i] - lib_start_count[i] +
	MAXLONG)/ lib_elapsed;
	lib_local_per_cpu_util[i] = (lib_local_maxrate - actual_rate) /
	lib_local_maxrate * 100;
	if (debug) {
	fprintf(where,
	"calc_cpu_util: actual_rate on processor %d is %f start %llx end %llx util %f\n",
	i,
	actual_rate,
	lib_start_count[i],
	lib_end_count[i],
	lib_local_per_cpu_util[i]);
	}
	lib_local_cpu_util += lib_local_per_cpu_util[i];
	}
	/* we want the average across all n processors */
	lib_local_cpu_util /= (float)lib_num_loc_cpus;

	lib_local_cpu_util *= correction_factor;
	return lib_local_cpu_util;
	}

	void
	cpu_start_internal(void)
	{
	get_cpu_idle(lib_start_count);
	return;
	}

	void
	cpu_stop_internal(void)
	{
	get_cpu_idle(lib_end_count);
	}