char netcpu_pstatnew_id[]="\ @(#)netcpu_pstatnew.c (c) Copyright 2005, Hewlett-Packard Company, Version 2.4.1"; /* since we "know" that this interface is available only on 11.23 and later, and that 11.23 and later are strictly 64-bit kernels, we can arbitrarily set _PSTAT64 here and not have to worry about it up in the configure script and makefiles. raj 2005/09/06 */ #if HAVE_CONFIG_H # include #endif #include #if HAVE_INTTYPES_H # include #else # if HAVE_STDINT_H # include # endif #endif #include #if HAVE_LIMITS_H # include #endif #include #include /* HP-UX 11.23 seems to have added three other cycle counters to the original psp_idlecycles - one for user, one for kernel and one for interrupt. so, we can now use those to calculate CPU utilization without requiring any calibration phase. raj 2005-02-16 */ #ifndef PSTAT_IPCINFO # error Sorry, pstat() CPU utilization on 10.0 and later only #endif typedef struct cpu_time_counters { uint64_t idle; uint64_t user; uint64_t kernel; uint64_t interrupt; } cpu_time_counters_t; uint64_t lib_iticksperclktick; #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 cpu_time_counters_t starting_cpu_counters[MAXCPUS]; static cpu_time_counters_t ending_cpu_counters[MAXCPUS]; static cpu_time_counters_t delta_cpu_counters[MAXCPUS]; void cpu_util_init(void) { return; } void cpu_util_terminate(void) { return; } int get_cpu_method(void) { return HP_IDLE_COUNTER; } void get_cpu_counters(cpu_time_counters_t *res) { /* get the idle sycle counter for each processor. now while on a 64-bit kernel the ".psc_hi" and ".psc_lo" fields are 64 bits, only the bottom 32-bits are actually valid. don't ask me why, that is just the way it is. soo, we shift the psc_hi value by 32 bits and then just sum-in the psc_lo value. raj 2005/09/06 */ struct pst_processor *psp; psp = (struct pst_processor *)malloc(lib_num_loc_cpus * sizeof(*psp)); if (psp == NULL) { printf("malloc(%d) failed!\n", lib_num_loc_cpus * sizeof(*psp)); exit(1); } if (pstat_getprocessor(psp, sizeof(*psp), lib_num_loc_cpus, 0) != -1) { int i; /* we use lib_iticksperclktick in our sanity checking. we ass-u-me it is the same value for each CPU - famous last words no doubt. raj 2005/09/06 */ lib_iticksperclktick = psp[0].psp_iticksperclktick; for (i = 0; i < lib_num_loc_cpus; i++) { res[i].idle = (((uint64_t)psp[i].psp_idlecycles.psc_hi << 32) + psp[i].psp_idlecycles.psc_lo); if(debug) { fprintf(where, "\tidle[%d] = 0x%"PRIx64" ", i, res[i].idle); fflush(where); } res[i].user = (((uint64_t)psp[i].psp_usercycles.psc_hi << 32) + psp[i].psp_usercycles.psc_lo); if(debug) { fprintf(where, "user[%d] = 0x%"PRIx64" ", i, res[i].user); fflush(where); } res[i].kernel = (((uint64_t)psp[i].psp_systemcycles.psc_hi << 32) + psp[i].psp_systemcycles.psc_lo); if(debug) { fprintf(where, "kern[%d] = 0x%"PRIx64" ", i, res[i].kernel); fflush(where); } res[i].interrupt = (((uint64_t)psp[i].psp_interruptcycles.psc_hi << 32) + psp[i].psp_interruptcycles.psc_lo); if(debug) { fprintf(where, "intr[%d] = 0x%"PRIx64"\n", i, res[i].interrupt); fflush(where); } } free(psp); } } /* calibrate_pstatnew there really isn't anything much to do here since we have all the counters and use their ratios for CPU util measurement. raj 2005-02-16 */ float calibrate_idle_rate(int iterations, int interval) { return 0.0; } static void print_cpu_time_counters(char *name, int instance, cpu_time_counters_t *counters) { fprintf(where,"%s[%d]:\n",name,instance); fprintf(where, "\t idle %llu\n",counters[instance].idle); fprintf(where, "\t user %llu\n",counters[instance].user); fprintf(where, "\t kernel %llu\n",counters[instance].kernel); fprintf(where, "\t interrupt %llu\n",counters[instance].interrupt); } float calc_cpu_util_internal(float elapsed_time) { int i; uint64_t total_cpu_cycles; uint64_t sanity_cpu_cycles; #ifndef USE_INTEGER_MATH double fraction_idle; double fraction_user; double fraction_kernel; double fraction_interrupt; double estimated_fraction_interrupt; #else uint64_t fraction_idle; uint64_t fraction_user; uint64_t fraction_kernel; uint64_t fraction_interrupt; uint64_t estimated_fraction_interrupt; #define CALC_PERCENT 100 #define CALC_TENTH_PERCENT 1000 #define CALC_HUNDREDTH_PERCENT 10000 #define CALC_THOUSANDTH_PERCENT 100000 #define CALC_ACCURACY CALC_THOUSANDTH_PERCENT #endif /* USE_INTEGER_MATH */ 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; } /* calculate our sanity check on cycles */ if (debug) { fprintf(where, "lib_elapsed %g _SC_CLK_TCK %d lib_iticksperclktick %"PRIu64"\n", lib_elapsed, sysconf(_SC_CLK_TCK), lib_iticksperclktick); } /* Ok, elsewhere I may have said that HP-UX 11.23 does the "right" thing in measuring user, kernel, interrupt and idle all together instead of overlapping interrupt with the others like an OS that shall not be named. However.... it seems there is a bug in the accounting for interrupt cycles, whereby the cycles do not get properly accounted. The sum of user, kernel, interrupt and idle does not equal the clock rate multiplied by the elapsed time. Some cycles go missing. Since we see agreement between netperf and glance/vsar with the old "pstat" mechanism, we can presume that the accounting for idle cycles is sufficiently accurate. So, while we will still do math with user, kernel and interrupt cycles, we will only caculate CPU utilization based on the ratio of idle to _real_ total cycles. I am told that a "future release" of HP-UX will fix the interupt cycle accounting. raj 2005/09/14 */ /* calculate what the sum of CPU cycles _SHOULD_ be */ sanity_cpu_cycles = (uint64_t) ((double)lib_elapsed * (double) sysconf(_SC_CLK_TCK) * (double)lib_iticksperclktick); /* 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 ass-u-me that these counters will never wrap during a netperf run. this may not be a particularly safe thing to do. raj 2005-01-28 */ delta_cpu_counters[i].idle = ending_cpu_counters[i].idle - starting_cpu_counters[i].idle; delta_cpu_counters[i].user = ending_cpu_counters[i].user - starting_cpu_counters[i].user; delta_cpu_counters[i].kernel = ending_cpu_counters[i].kernel - starting_cpu_counters[i].kernel; delta_cpu_counters[i].interrupt = ending_cpu_counters[i].interrupt - starting_cpu_counters[i].interrupt; if (debug) { print_cpu_time_counters("delta_cpu_counters",i,delta_cpu_counters); } /* now get the sum, which we ass-u-me does not overflow a 64-bit counter. raj 2005-02-16 */ total_cpu_cycles = delta_cpu_counters[i].idle + delta_cpu_counters[i].user + delta_cpu_counters[i].kernel + delta_cpu_counters[i].interrupt; if (debug) { fprintf(where, "total_cpu_cycles %"PRIu64" sanity_cpu_cycles %"PRIu64" missing %"PRIu64"\n", total_cpu_cycles, sanity_cpu_cycles, sanity_cpu_cycles - total_cpu_cycles); } /* since HP-UX 11.23 does the _RIGHT_ thing and idle/user/kernel does _NOT_ overlap with interrupt, we do not have to apply any correction kludge. raj 2005-02-16 */ #ifndef USE_INTEGER_MATH /* when the accounting for interrupt time gets its act together, we can use total_cpu_cycles rather than sanity_cpu_cycles, but until then, use sanity_cpu_ccles. raj 2005/09/14 */ fraction_idle = (double)delta_cpu_counters[i].idle / (double)sanity_cpu_cycles; fraction_user = (double)delta_cpu_counters[i].user / (double)sanity_cpu_cycles; fraction_kernel = (double) delta_cpu_counters[i].kernel / (double)sanity_cpu_cycles; fraction_interrupt = (double)delta_cpu_counters[i].interrupt / (double)sanity_cpu_cycles; /* ass-u-me that it is only interrupt that is bogus, and assign all the "missing" cycles to it. raj 2005/09/14 */ estimated_fraction_interrupt = ((double)delta_cpu_counters[i].interrupt + (sanity_cpu_cycles - total_cpu_cycles)) / (double)sanity_cpu_cycles; if (debug) { fprintf(where,"\tfraction_idle %g\n",fraction_idle); fprintf(where,"\tfraction_user %g\n",fraction_user); fprintf(where,"\tfraction_kernel %g\n",fraction_kernel); fprintf(where,"\tfraction_interrupt %g WARNING, possibly under-counted!\n",fraction_interrupt); fprintf(where,"\testimated_fraction_interrupt %g\n", estimated_fraction_interrupt); } /* and finally, what is our CPU utilization? */ lib_local_per_cpu_util[i] = 100.0 - (fraction_idle * 100.0); #else /* and now some fun with integer math. i initially tried to promote things to long doubled but that didn't seem to result in happiness and joy. raj 2005-01-28 */ /* multiply by 100 and divide by total and you get whole percentages. multiply by 1000 and divide by total and you get tenths of percentages. multiply by 10000 and divide by total and you get hundredths of percentages. etc etc etc raj 2005-01-28 */ /* when the accounting for interrupt time gets its act together, we can use total_cpu_cycles rather than sanity_cpu_cycles, but until then, use sanity_cpu_ccles. raj 2005/09/14 */ fraction_idle = (delta_cpu_counters[i].idle * CALC_ACCURACY) / sanity_cpu_cycles; fraction_user = (delta_cpu_counters[i].user * CALC_ACCURACY) / sanity_cpu_cycles; fraction_kernel = (delta_cpu_counters[i].kernel * CALC_ACCURACY) / sanity_cpu_cycles; fraction_interrupt = (delta_cpu_counters[i].interrupt * CALC_ACCURACY) / sanity_cpu_cycles; estimated_fraction_interrupt = ((delta_cpu_counters[i].interrupt + (sanity_cpu_cycles - total_cpu_cycles)) * CALC_ACCURACY) / sanity_cpu_cycles; if (debug) { fprintf(where,"\tfraction_idle %"PRIu64"\n",fraction_idle); fprintf(where,"\tfraction_user %"PRIu64"\n",fraction_user); fprintf(where,"\tfraction_kernel %"PRIu64"\n",fraction_kernel); fprintf(where,"\tfraction_interrupt %"PRIu64"WARNING, possibly under-counted!\n",fraction_interrupt); fprintf(where,"\testimated_fraction_interrupt %"PRIu64"\n", estimated_fraction_interrupt); } /* and finally, what is our CPU utilization? */ lib_local_per_cpu_util[i] = 100.0 - (((float)fraction_idle / (float)CALC_ACCURACY) * 100.0); #endif if (debug) { fprintf(where, "lib_local_per_cpu_util[%d] %g\n", 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; 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_counters(starting_cpu_counters); } void cpu_stop_internal(void) { get_cpu_counters(ending_cpu_counters); }