char netcpu_perfstat_id[]="\ @(#)netcpu_perfstat.c Version 2.4.0"; #if HAVE_CONFIG_H # include <config.h> #endif #include <stdio.h> #if HAVE_INTTYPES_H # include <inttypes.h> #else # if HAVE_STDINT_H # include <stdint.h> # endif #endif #if TIME_WITH_SYS_TIME # include <sys/time.h> # include <time.h> #else # if HAVE_SYS_TIME_H # include <sys/time.h> # else # include <time.h> # endif #endif #if HAVE_LIMITS_H # include <limits.h> # ifndef LONG_LONG_MAX # define LONG_LONG_MAX LLONG_MAX # endif /* LONG_LONG_MAX */ #endif #include <errno.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 calibration 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]; void cpu_util_init(void) { return; } void cpu_util_terminate(void) { return; } int get_cpu_method(void) { return PERFSTAT; } void get_cpu_idle(uint64_t *res) { perfstat_cpu_t *perfstat_buffer; perfstat_cpu_t *per_cpu_pointer; perfstat_id_t name; int i,ret; /* a name of "" will cause us to start from the beginning */ strcpy(name.name,""); perfstat_buffer = (perfstat_cpu_t *)malloc(lib_num_loc_cpus * sizeof(perfstat_cpu_t)); if (perfstat_buffer == NULL) { fprintf(where, "cpu_start: malloc failed errno %d\n", errno); fflush(where); exit(-1); } /* happiness and joy, keep going */ ret = perfstat_cpu(&name, perfstat_buffer, sizeof(perfstat_cpu_t), lib_num_loc_cpus); if ((ret == -1) || (ret != lib_num_loc_cpus)) { fprintf(where, "cpu_start: perfstat_cpu failed/count off; errno %d cpus %d count %d\n", errno, lib_num_loc_cpus, ret); fflush(where); exit(-1); } per_cpu_pointer = perfstat_buffer; for (i = 0; i < lib_num_loc_cpus; i++){ res[i] = per_cpu_pointer->idle; per_cpu_pointer++; } free(perfstat_buffer); return; } float calibrate_idle_rate(int iterations, int interval) { unsigned long long firstcnt[MAXCPUS], secondcnt[MAXCPUS]; float elapsed, temp_rate, rate[MAXTIMES], local_maxrate; long sec, usec; int i, j; struct timeval time1, time2 ; struct timezone tz; perfstat_cpu_t *perfstat_buffer; perfstat_cpu_t *per_cpu_pointer; perfstat_id_t name; int ret; if (debug) { fprintf(where,"enter calibrate_perfstat\n"); fflush(where); } if (iterations > MAXTIMES) { iterations = MAXTIMES; } local_maxrate = (float)-1.0; perfstat_buffer = (perfstat_cpu_t *)malloc(lib_num_loc_cpus * sizeof(perfstat_cpu_t)); if (perfstat_buffer == NULL) { fprintf(where, "calibrate_perfstat: malloc failed errno %d\n", errno); fflush(where); exit(-1); } for(i = 0; i < iterations; i++) { rate[i] = (float)0.0; /* a name of "" will cause us to start from the beginning */ strcpy(name.name,""); /* happiness and joy, keep going */ ret = perfstat_cpu(&name, perfstat_buffer, sizeof(perfstat_cpu_t), lib_num_loc_cpus); if ((ret == -1) || (ret != lib_num_loc_cpus)) { fprintf(where, "calibrate_perfstat: perfstat_cpu failed/count off; errno %d cpus %d count %d\n", errno, lib_num_loc_cpus, ret); fflush(where); exit(-1); } per_cpu_pointer = perfstat_buffer; for (j = 0; j < lib_num_loc_cpus; j++) { firstcnt[j] = per_cpu_pointer->idle; per_cpu_pointer++; } gettimeofday (&time1, &tz); sleep(interval); gettimeofday (&time2, &tz); if (time2.tv_usec < time1.tv_usec) { time2.tv_usec += 1000000; time2.tv_sec -=1; } sec = time2.tv_sec - time1.tv_sec; usec = time2.tv_usec - time1.tv_usec; elapsed = (float)sec + ((float)usec/(float)1000000.0); /* happiness and joy, keep going */ ret = perfstat_cpu(&name, perfstat_buffer, sizeof(perfstat_cpu_t), lib_num_loc_cpus); if ((ret == -1) || (ret != lib_num_loc_cpus)) { fprintf(where, "calibrate_perfstat: perfstat_cpu failed/count off; errno %d cpus %d count %d\n", errno, lib_num_loc_cpus, ret); fflush(where); exit(-1); } per_cpu_pointer = perfstat_buffer; if(debug) { fprintf(where, "Calibration for perfstat counter run: %d\n",i); fprintf(where,"\tsec = %ld usec = %ld\n",sec,usec); fprintf(where,"\telapsed time = %g\n",elapsed); } for (j = 0; j < lib_num_loc_cpus; j++) { secondcnt[j] = per_cpu_pointer->idle; per_cpu_pointer++; if(debug) { /* I know that there are situations where compilers know about */ /* long long, but the library functions do not... raj 4/95 */ fprintf(where, "\tfirstcnt[%d] = 0x%8.8lx%8.8lx secondcnt[%d] = 0x%8.8lx%8.8lx\n", j, firstcnt[j], firstcnt[j], j, secondcnt[j], secondcnt[j]); } /* we assume that it would wrap no more than once. we also */ /* assume that the result of subtracting will "fit" raj 4/95 */ temp_rate = (secondcnt[j] >= firstcnt[j]) ? (float)(secondcnt[j] - firstcnt[j])/elapsed : (float)(secondcnt[j]-firstcnt[j]+MAXLONG)/elapsed; if (temp_rate > rate[i]) rate[i] = temp_rate; if(debug) { fprintf(where,"\trate[%d] = %g\n",i,rate[i]); fflush(where); } if (local_maxrate < rate[i]) local_maxrate = rate[i]; } } if(debug) { fprintf(where,"\tlocal maxrate = %g per sec. \n",local_maxrate); fflush(where); } free(perfstat_buffer); return local_maxrate; } 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; } /* this looks just like the looper case. at least I think it */ /* should :) raj 4/95 */ for (i = 0; i < lib_num_loc_cpus; i++) { /* we assume that the two are not more than a long apart. I */ /* know that this is bad, but trying to go from long longs to */ /* a float (perhaps a double) is boggling my mind right now. */ /* raj 4/95 */ long long diff; if (lib_end_count[i] >= lib_start_count[i]) { diff = lib_end_count[i] - lib_start_count[i]; } else { diff = lib_end_count[i] - lib_start_count[i] + LONG_LONG_MAX; } actual_rate = (float) diff / lib_elapsed; lib_local_per_cpu_util[i] = (lib_local_maxrate - actual_rate) / lib_local_maxrate * 100; lib_local_cpu_util += lib_local_per_cpu_util[i]; if (debug) { fprintf(where, "calc_cpu_util: actual_rate on cpu %d is %g max_rate %g cpu %6.2f\n", i, actual_rate, lib_local_maxrate, lib_local_per_cpu_util[i]); } } /* we want the average across all n processors */ lib_local_cpu_util /= (float)lib_num_loc_cpus; if (debug) { fprintf(where, "calc_cpu_util: average across CPUs is %g\n",lib_local_cpu_util); } lib_local_cpu_util *= correction_factor; if (debug) { fprintf(where, "calc_cpu_util: returning %g\n",lib_local_cpu_util); } 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); }