/* * pr_stats.c: Functions used by sar to display statistics * (C) 1999-2021 by Sebastien GODARD (sysstat orange.fr) * *************************************************************************** * 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; either version 2 of the License, or (at your * * option) any later version. * * * * This program is distributed in the hope that it will be useful, but * * WITHOUT ANY WARRANTY; without 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., * * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA * *************************************************************************** */ #include #include #include #include #include "sa.h" #include "ioconf.h" #include "pr_stats.h" #ifdef USE_NLS #include #include #define _(string) gettext(string) #else #define _(string) (string) #endif extern uint64_t flags; extern int dish; extern char timestamp[][TIMESTAMP_LEN]; extern unsigned long avg_count; /* *************************************************************************** * Display current activity header line. * * IN: * @p_timestamp Timestamp for previous stat sample. * @a Activity structure. * @pos Header to display, 0 being the first header (headers * are delimited by the '|' character). * @iwidth First column width (generally this is the item name). * A negative value means that the corresponding field * shall be displayed at the end of the line, with no * indication of width. * @vwidth Column width for stats values. * @offline_bitmap Bitmap for offline items (e.g. CPU). *************************************************************************** */ void print_hdr_line(char *p_timestamp, struct activity *a, int pos, int iwidth, int vwidth, unsigned char *offline_bitmap) { char hline[HEADER_LINE_LEN] = ""; char cfld[16], dfld[16]; char *hl, *tk, *it = NULL; int i = -1, j, k; int p = pos; strncpy(hline, a->hdr_line, sizeof(hline) - 1); hline[sizeof(hline) - 1] = '\0'; for (hl = strtok(hline, "|"); hl && (pos > 0); hl = strtok(NULL, "|"), pos--); if (!hl) /* Bad @pos arg given to function */ return; printf("\n%-11s", p_timestamp); if (strchr(hl, '&')) { j = strcspn(hl, "&"); if ((a->opt_flags & 0xff00) & (1 << (8 + p))) { /* Display whole header line */ *(hl + j) = ';'; } else { /* Display only the first part of the header line */ *(hl + j) = '\0'; } } /* Display each field */ for (tk = strtok(hl, ";"); tk; tk = strtok(NULL, ";"), i--) { if (strchr(tk, '*')) { strncpy(cfld, tk, sizeof(cfld) - 1); k = strcspn(cfld, "*"); if (k >= strlen(cfld)) continue; /* Should not happen */ cfld[k] = '\0'; for (j = 0; (j < a->nr_ini) && (j < a->bitmap->b_size + 1); j++) { if (!(a->bitmap->b_array[j >> 3] & (1 << (j & 0x07)))) /* Don't display current item if not selected */ continue; if (offline_bitmap && (offline_bitmap[j >> 3] & (1 << (j & 0x07)))) /* Don't display current item if offline */ continue; if (j == 0) { printf(" %*s", vwidth, "all"); } else { snprintf(dfld, sizeof(dfld), "%s%d%s", cfld, j - 1, cfld + k + 1); dfld[sizeof(dfld) - 1] = '\0'; printf(" %*s", vwidth, dfld); } } continue; } if (iwidth > 0) { printf(" %*s", iwidth, tk); iwidth = 0; continue; } if ((iwidth < 0) && (iwidth == i)) { it = tk; iwidth = 0; } else { printf(" %*s", vwidth, tk); } } if (it) { printf(" %s", it); } printf("\n"); } /* *************************************************************************** * Display CPU statistics. * NB: The stats are only calculated over the part of the time interval when * the CPU was online. As a consequence, the sum (%user + %nice + ... + %idle) * will always be 100% on the time interval even if the CPU has been offline * most of the time. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second (independent of the * number of processors). Unused here. *************************************************************************** */ __print_funct_t print_cpu_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i; unsigned long long deltot_jiffies = 1; struct stats_cpu *scc, *scp; unsigned char offline_cpu_bitmap[BITMAP_SIZE(NR_CPUS)] = {0}; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST + DISPLAY_CPU_ALL(a->opt_flags), 7, 9, NULL); } /* * @nr[curr] cannot normally be greater than @nr_ini * (since @nr_ini counts up all CPU, even those offline). * If this happens, it may be because the machine has been * restarted with more CPU and no LINUX_RESTART has been * inserted in file. * No problem here with @nr_allocated. Having been able to * read @nr[curr] structures shows that buffers are large enough. */ if (a->nr[curr] > a->nr_ini) { a->nr_ini = a->nr[curr]; } /* * Compute CPU "all" as sum of all individual CPU (on SMP machines) * and look for offline CPU. */ if (a->nr_ini > 1) { deltot_jiffies = get_global_cpu_statistics(a, prev, curr, flags, offline_cpu_bitmap); } /* * Now display CPU statistics (including CPU "all"), * except for offline CPU or CPU that the user doesn't want to see. */ for (i = 0; (i < a->nr_ini) && (i < a->bitmap->b_size + 1); i++) { /* * Should current CPU (including CPU "all") be displayed? * Note: @nr[curr] is in [1, NR_CPUS + 1]. * Bitmap size is provided for (NR_CPUS + 1) CPUs. * Anyway, NR_CPUS may vary between the version of sysstat * used by sadc to create a file, and the version of sysstat * used by sar to read it... */ if (!(a->bitmap->b_array[i >> 3] & (1 << (i & 0x07))) || offline_cpu_bitmap[i >> 3] & (1 << (i & 0x07))) /* Don't display CPU */ continue; scc = (struct stats_cpu *) ((char *) a->buf[curr] + i * a->msize); scp = (struct stats_cpu *) ((char *) a->buf[prev] + i * a->msize); printf("%-11s", timestamp[curr]); if (i == 0) { /* This is CPU "all" */ cprintf_in(IS_STR, " %s", " all", 0); if (a->nr_ini == 1) { /* * This is a UP machine. In this case * interval has still not been calculated. */ deltot_jiffies = get_per_cpu_interval(scc, scp); } if (!deltot_jiffies) { /* CPU "all" cannot be tickless */ deltot_jiffies = 1; } } else { cprintf_in(IS_INT, " %7d", "", i - 1); /* Recalculate interval for current proc */ deltot_jiffies = get_per_cpu_interval(scc, scp); if (!deltot_jiffies) { /* * If the CPU is tickless then there is no change in CPU values * but the sum of values is not zero. * %user, %nice, %system, %iowait, %steal, ..., %idle */ cprintf_pc(DISPLAY_UNIT(flags), 5, 9, 2, 0.0, 0.0, 0.0, 0.0, 0.0); if (DISPLAY_CPU_DEF(a->opt_flags)) { cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, 100.0); printf("\n"); } /* * Four additional fields to display: * %irq, %soft, %guest, %gnice. */ else if (DISPLAY_CPU_ALL(a->opt_flags)) { cprintf_pc(DISPLAY_UNIT(flags), 5, 9, 2, 0.0, 0.0, 0.0, 0.0, 100.0); printf("\n"); } continue; } } if (DISPLAY_CPU_DEF(a->opt_flags)) { cprintf_pc(DISPLAY_UNIT(flags), 6, 9, 2, ll_sp_value(scp->cpu_user, scc->cpu_user, deltot_jiffies), ll_sp_value(scp->cpu_nice, scc->cpu_nice, deltot_jiffies), ll_sp_value(scp->cpu_sys + scp->cpu_hardirq + scp->cpu_softirq, scc->cpu_sys + scc->cpu_hardirq + scc->cpu_softirq, deltot_jiffies), ll_sp_value(scp->cpu_iowait, scc->cpu_iowait, deltot_jiffies), ll_sp_value(scp->cpu_steal, scc->cpu_steal, deltot_jiffies), scc->cpu_idle < scp->cpu_idle ? 0.0 : ll_sp_value(scp->cpu_idle, scc->cpu_idle, deltot_jiffies)); printf("\n"); } else if (DISPLAY_CPU_ALL(a->opt_flags)) { cprintf_pc(DISPLAY_UNIT(flags), 10, 9, 2, (scc->cpu_user - scc->cpu_guest) < (scp->cpu_user - scp->cpu_guest) ? 0.0 : ll_sp_value(scp->cpu_user - scp->cpu_guest, scc->cpu_user - scc->cpu_guest, deltot_jiffies), (scc->cpu_nice - scc->cpu_guest_nice) < (scp->cpu_nice - scp->cpu_guest_nice) ? 0.0 : ll_sp_value(scp->cpu_nice - scp->cpu_guest_nice, scc->cpu_nice - scc->cpu_guest_nice, deltot_jiffies), ll_sp_value(scp->cpu_sys, scc->cpu_sys, deltot_jiffies), ll_sp_value(scp->cpu_iowait, scc->cpu_iowait, deltot_jiffies), ll_sp_value(scp->cpu_steal, scc->cpu_steal, deltot_jiffies), ll_sp_value(scp->cpu_hardirq, scc->cpu_hardirq, deltot_jiffies), ll_sp_value(scp->cpu_softirq, scc->cpu_softirq, deltot_jiffies), ll_sp_value(scp->cpu_guest, scc->cpu_guest, deltot_jiffies), ll_sp_value(scp->cpu_guest_nice, scc->cpu_guest_nice, deltot_jiffies), scc->cpu_idle < scp->cpu_idle ? 0.0 : ll_sp_value(scp->cpu_idle, scc->cpu_idle, deltot_jiffies)); printf("\n"); } } } /* *************************************************************************** * Display tasks creation and context switches statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pcsw_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_pcsw *spc = (struct stats_pcsw *) a->buf[curr], *spp = (struct stats_pcsw *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 2, 9, 2, S_VALUE(spp->processes, spc->processes, itv), S_VALUE(spp->context_switch, spc->context_switch, itv)); printf("\n"); } /* *************************************************************************** * Display interrupts statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_irq_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i; struct stats_irq *sic, *sip; if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); // TODO: Check for offline CPU } for (i = 0; (i < a->nr[curr]) && (i < a->bitmap->b_size + 1); i++) { /* * If @nr[curr] > @nr[prev] then we consider that previous * interrupt value was 0. */ sic = (struct stats_irq *) ((char *) a->buf[curr] + i * a->msize); sip = (struct stats_irq *) ((char *) a->buf[prev] + i * a->msize); /* * Note: @nr[curr] gives the number of interrupts read (1 .. NR_IRQS + 1). * Bitmap size is provided for (NR_IRQS + 1) interrupts. * Anyway, NR_IRQS may vary between the version of sysstat * used by sadc to create a file, and the version of sysstat * used by sar to read it... */ /* Should current interrupt (including int "sum") be displayed? */ if (a->bitmap->b_array[i >> 3] & (1 << (i & 0x07))) { if (DISPLAY_ZERO_OMIT(flags) && !memcmp(sip, sic, STATS_IRQ_SIZE)) continue; /* Yes: Display it */ printf("%-11s", timestamp[curr]); if (!i) { /* This is interrupt "sum" */ cprintf_in(IS_STR, " %s", " sum", 0); } else { cprintf_in(IS_INT, " %9d", "", i -1); } cprintf_f(NO_UNIT, 1, 9, 2, S_VALUE(sip->irq_nr, sic->irq_nr, itv)); printf("\n"); } } } /* *************************************************************************** * Display swapping statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_swap_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_swap *ssc = (struct stats_swap *) a->buf[curr], *ssp = (struct stats_swap *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 2, 9, 2, S_VALUE(ssp->pswpin, ssc->pswpin, itv), S_VALUE(ssp->pswpout, ssc->pswpout, itv)); printf("\n"); } /* *************************************************************************** * Display paging statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_paging_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_paging *spc = (struct stats_paging *) a->buf[curr], *spp = (struct stats_paging *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 8, 9, 2, S_VALUE(spp->pgpgin, spc->pgpgin, itv), S_VALUE(spp->pgpgout, spc->pgpgout, itv), S_VALUE(spp->pgfault, spc->pgfault, itv), S_VALUE(spp->pgmajfault, spc->pgmajfault, itv), S_VALUE(spp->pgfree, spc->pgfree, itv), S_VALUE(spp->pgscan_kswapd, spc->pgscan_kswapd, itv), S_VALUE(spp->pgscan_direct, spc->pgscan_direct, itv), S_VALUE(spp->pgsteal, spc->pgsteal, itv)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (spc->pgscan_kswapd + spc->pgscan_direct - spp->pgscan_kswapd - spp->pgscan_direct) ? SP_VALUE(spp->pgsteal, spc->pgsteal, spc->pgscan_kswapd + spc->pgscan_direct - spp->pgscan_kswapd - spp->pgscan_direct) : 0.0); printf("\n"); } /* *************************************************************************** * Display I/O and transfer rate statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_io_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_io *sic = (struct stats_io *) a->buf[curr], *sip = (struct stats_io *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); /* * If we get negative values, this is probably because * one or more devices/filesystems have been unmounted. * We display 0.0 in this case though we should rather tell * the user that the value cannot be calculated here. */ cprintf_f(NO_UNIT, 7, 9, 2, sic->dk_drive < sip->dk_drive ? 0.0 : S_VALUE(sip->dk_drive, sic->dk_drive, itv), sic->dk_drive_rio < sip->dk_drive_rio ? 0.0 : S_VALUE(sip->dk_drive_rio, sic->dk_drive_rio, itv), sic->dk_drive_wio < sip->dk_drive_wio ? 0.0 : S_VALUE(sip->dk_drive_wio, sic->dk_drive_wio, itv), sic->dk_drive_dio < sip->dk_drive_dio ? 0.0 : S_VALUE(sip->dk_drive_dio, sic->dk_drive_dio, itv), sic->dk_drive_rblk < sip->dk_drive_rblk ? 0.0 : S_VALUE(sip->dk_drive_rblk, sic->dk_drive_rblk, itv), sic->dk_drive_wblk < sip->dk_drive_wblk ? 0.0 : S_VALUE(sip->dk_drive_wblk, sic->dk_drive_wblk, itv), sic->dk_drive_dblk < sip->dk_drive_dblk ? 0.0 : S_VALUE(sip->dk_drive_dblk, sic->dk_drive_dblk, itv)); printf("\n"); } /* *************************************************************************** * Display memory and swap statistics. This function is used to * display instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_memory_stats(struct activity *a, int prev, int curr, int dispavg) { struct stats_memory *smc = (struct stats_memory *) a->buf[curr]; static unsigned long long avg_frmkb = 0, avg_bufkb = 0, avg_camkb = 0, avg_comkb = 0, avg_activekb = 0, avg_inactkb = 0, avg_dirtykb = 0, avg_anonpgkb = 0, avg_slabkb = 0, avg_kstackkb = 0, avg_pgtblkb = 0, avg_vmusedkb = 0, avg_availablekb = 0; static unsigned long long avg_frskb = 0, avg_tlskb = 0, avg_caskb = 0; int unit = NO_UNIT; unsigned long long nousedmem; if (DISPLAY_UNIT(flags)) { /* Default values unit is kB */ unit = UNIT_KILOBYTE; } if (DISPLAY_MEMORY(a->opt_flags)) { if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ nousedmem = smc->frmkb + smc->bufkb + smc->camkb + smc->slabkb; if (nousedmem > smc->tlmkb) { nousedmem = smc->tlmkb; } cprintf_u64(unit, 3, 9, (unsigned long long) smc->frmkb, (unsigned long long) smc->availablekb, (unsigned long long) (smc->tlmkb - nousedmem)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, smc->tlmkb ? SP_VALUE(nousedmem, smc->tlmkb, smc->tlmkb) : 0.0); cprintf_u64(unit, 3, 9, (unsigned long long) smc->bufkb, (unsigned long long) smc->camkb, (unsigned long long) smc->comkb); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (smc->tlmkb + smc->tlskb) ? SP_VALUE(0, smc->comkb, smc->tlmkb + smc->tlskb) : 0.0); cprintf_u64(unit, 3, 9, (unsigned long long) smc->activekb, (unsigned long long) smc->inactkb, (unsigned long long) smc->dirtykb); if (DISPLAY_MEM_ALL(a->opt_flags)) { /* Display extended memory statistics */ cprintf_u64(unit, 5, 9, (unsigned long long) smc->anonpgkb, (unsigned long long) smc->slabkb, (unsigned long long) smc->kstackkb, (unsigned long long) smc->pgtblkb, (unsigned long long) smc->vmusedkb); } printf("\n"); /* * Will be used to compute the average. * We assume that the total amount of memory installed can not vary * during the interval given on the command line. */ avg_frmkb += smc->frmkb; avg_bufkb += smc->bufkb; avg_camkb += smc->camkb; avg_comkb += smc->comkb; avg_activekb += smc->activekb; avg_inactkb += smc->inactkb; avg_dirtykb += smc->dirtykb; avg_anonpgkb += smc->anonpgkb; avg_slabkb += smc->slabkb; avg_kstackkb += smc->kstackkb; avg_pgtblkb += smc->pgtblkb; avg_vmusedkb += smc->vmusedkb; avg_availablekb += smc->availablekb; } else { /* Display average values */ nousedmem = avg_frmkb + avg_bufkb + avg_camkb + avg_slabkb; cprintf_f(unit, 3, 9, 0, (double) avg_frmkb / avg_count, (double) avg_availablekb / avg_count, (double) smc->tlmkb - ((double) nousedmem / avg_count)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, smc->tlmkb ? SP_VALUE((double) (nousedmem / avg_count), smc->tlmkb, smc->tlmkb) : 0.0); cprintf_f(unit, 3, 9, 0, (double) avg_bufkb / avg_count, (double) avg_camkb / avg_count, (double) avg_comkb / avg_count); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (smc->tlmkb + smc->tlskb) ? SP_VALUE(0.0, (double) (avg_comkb / avg_count), smc->tlmkb + smc->tlskb) : 0.0); cprintf_f(unit, 3, 9, 0, (double) avg_activekb / avg_count, (double) avg_inactkb / avg_count, (double) avg_dirtykb / avg_count); if (DISPLAY_MEM_ALL(a->opt_flags)) { cprintf_f(unit, 5, 9, 0, (double) avg_anonpgkb / avg_count, (double) avg_slabkb / avg_count, (double) avg_kstackkb / avg_count, (double) avg_pgtblkb / avg_count, (double) avg_vmusedkb / avg_count); } printf("\n"); /* Reset average counters */ avg_frmkb = avg_bufkb = avg_camkb = avg_comkb = 0; avg_activekb = avg_inactkb = avg_dirtykb = 0; avg_anonpgkb = avg_slabkb = avg_kstackkb = 0; avg_pgtblkb = avg_vmusedkb = avg_availablekb = 0; } } if (DISPLAY_SWAP(a->opt_flags)) { if (dish) { print_hdr_line(timestamp[!curr], a, SECOND, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(unit, 2, 9, (unsigned long long) smc->frskb, (unsigned long long) (smc->tlskb - smc->frskb)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, smc->tlskb ? SP_VALUE(smc->frskb, smc->tlskb, smc->tlskb) : 0.0); cprintf_u64(unit, 1, 9, (unsigned long long) smc->caskb); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (smc->tlskb - smc->frskb) ? SP_VALUE(0, smc->caskb, smc->tlskb - smc->frskb) : 0.0); printf("\n"); /* * Will be used to compute the average. * We assume that the total amount of swap space may vary. */ avg_frskb += smc->frskb; avg_tlskb += smc->tlskb; avg_caskb += smc->caskb; } else { /* Display average values */ cprintf_f(unit, 2, 9, 0, (double) avg_frskb / avg_count, ((double) avg_tlskb / avg_count) - ((double) avg_frskb / avg_count)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, avg_tlskb ? SP_VALUE((double) avg_frskb / avg_count, (double) avg_tlskb / avg_count, (double) avg_tlskb / avg_count) : 0.0); cprintf_f(unit, 1, 9, 0, (double) avg_caskb / avg_count); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (avg_tlskb != avg_frskb) ? SP_VALUE(0.0, (double) avg_caskb / avg_count, ((double) avg_tlskb / avg_count) - ((double) avg_frskb / avg_count)) : 0.0); printf("\n"); /* Reset average counters */ avg_frskb = avg_tlskb = avg_caskb = 0; } } } /* *************************************************************************** * Display memory and swap statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_memory_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_memory_stats(a, prev, curr, FALSE); } /* *************************************************************************** * Display average memory statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_memory_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_memory_stats(a, prev, curr, TRUE); } /* *************************************************************************** * Display kernel tables statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg True if displaying average statistics. *************************************************************************** */ void stub_print_ktables_stats(struct activity *a, int curr, int dispavg) { struct stats_ktables *skc = (struct stats_ktables *) a->buf[curr]; static unsigned long long avg_dentry_stat = 0, avg_file_used = 0, avg_inode_used = 0, avg_pty_nr = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(NO_UNIT, 4, 9, (unsigned long long) skc->dentry_stat, (unsigned long long) skc->file_used, (unsigned long long) skc->inode_used, (unsigned long long) skc->pty_nr); printf("\n"); /* * Will be used to compute the average. * Note: Overflow unlikely to happen but not impossible... */ avg_dentry_stat += skc->dentry_stat; avg_file_used += skc->file_used; avg_inode_used += skc->inode_used; avg_pty_nr += skc->pty_nr; } else { /* Display average values */ cprintf_f(NO_UNIT, 4, 9, 0, (double) avg_dentry_stat / avg_count, (double) avg_file_used / avg_count, (double) avg_inode_used / avg_count, (double) avg_pty_nr / avg_count); printf("\n"); /* Reset average counters */ avg_dentry_stat = avg_file_used = avg_inode_used = avg_pty_nr = 0; } } /* *************************************************************************** * Display kernel tables statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_ktables_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_ktables_stats(a, curr, FALSE); } /* *************************************************************************** * Display average kernel tables statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_ktables_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_ktables_stats(a, curr, TRUE); } /* *************************************************************************** * Display queue and load statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_queue_stats(struct activity *a, int curr, int dispavg) { struct stats_queue *sqc = (struct stats_queue *) a->buf[curr]; static unsigned long long avg_nr_running = 0, avg_nr_threads = 0, avg_load_avg_1 = 0, avg_load_avg_5 = 0, avg_load_avg_15 = 0, avg_procs_blocked = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(NO_UNIT, 2, 9, (unsigned long long) sqc->nr_running, (unsigned long long) sqc->nr_threads); cprintf_f(NO_UNIT, 3, 9, 2, (double) sqc->load_avg_1 / 100, (double) sqc->load_avg_5 / 100, (double) sqc->load_avg_15 / 100); cprintf_u64(NO_UNIT, 1, 9, (unsigned long long) sqc->procs_blocked); printf("\n"); /* Will be used to compute the average */ avg_nr_running += sqc->nr_running; avg_nr_threads += sqc->nr_threads; avg_load_avg_1 += sqc->load_avg_1; avg_load_avg_5 += sqc->load_avg_5; avg_load_avg_15 += sqc->load_avg_15; avg_procs_blocked += sqc->procs_blocked; } else { /* Display average values */ cprintf_f(NO_UNIT, 2, 9, 0, (double) avg_nr_running / avg_count, (double) avg_nr_threads / avg_count); cprintf_f(NO_UNIT, 3, 9, 2, (double) avg_load_avg_1 / (avg_count * 100), (double) avg_load_avg_5 / (avg_count * 100), (double) avg_load_avg_15 / (avg_count * 100)); cprintf_f(NO_UNIT, 1, 9, 0, (double) avg_procs_blocked / avg_count); printf("\n"); /* Reset average counters */ avg_nr_running = avg_nr_threads = 0; avg_load_avg_1 = avg_load_avg_5 = avg_load_avg_15 = 0; avg_procs_blocked = 0; } } /* *************************************************************************** * Display queue and load statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_queue_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_queue_stats(a, curr, FALSE); } /* *************************************************************************** * Display average queue and load statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_queue_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_queue_stats(a, curr, TRUE); } /* *************************************************************************** * Display serial lines statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_serial_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, j, j0, found; struct stats_serial *ssc, *ssp; if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { ssc = (struct stats_serial *) ((char *) a->buf[curr] + i * a->msize); if (WANT_SINCE_BOOT(flags)) { /* * We want to display statistics since boot time. * Take the first structure from buf[prev]: This is a * structure that only contains 0 (it has been set to 0 * when it has been allocated), and which exists since * there is the same number of allocated structures for * buf[prev] and bur[curr] (even if nothing has been read). */ ssp = (struct stats_serial *) ((char *) a->buf[prev]); found = TRUE; } else { found = FALSE; if (a->nr[prev] > 0) { /* Look for corresponding serial line in previous iteration */ j = i; if (j >= a->nr[prev]) { j = a->nr[prev] - 1; } j0 = j; do { ssp = (struct stats_serial *) ((char *) a->buf[prev] + j * a->msize); if (ssc->line == ssp->line) { found = TRUE; break; } if (++j >= a->nr[prev]) { j = 0; } } while (j != j0); } } if (!found) continue; if (DISPLAY_ZERO_OMIT(flags) && !memcmp(ssp, ssc, STATS_SERIAL_SIZE)) continue; printf("%-11s", timestamp[curr]); cprintf_in(IS_INT, " %3d", "", ssc->line); cprintf_f(NO_UNIT, 6, 9, 2, S_VALUE(ssp->rx, ssc->rx, itv), S_VALUE(ssp->tx, ssc->tx, itv), S_VALUE(ssp->frame, ssc->frame, itv), S_VALUE(ssp->parity, ssc->parity, itv), S_VALUE(ssp->brk, ssc->brk, itv), S_VALUE(ssp->overrun, ssc->overrun, itv)); printf("\n"); } } /* *************************************************************************** * Display disks statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_disk_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, j; struct stats_disk *sdc, *sdp, sdpzero; struct ext_disk_stats xds; char *dev_name; int unit = NO_UNIT; memset(&sdpzero, 0, STATS_DISK_SIZE); if (DISPLAY_UNIT(flags)) { /* Default values unit is kB */ unit = UNIT_KILOBYTE; } if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, DISPLAY_PRETTY(flags) ? -1 : 0, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { sdc = (struct stats_disk *) ((char *) a->buf[curr] + i * a->msize); if (!WANT_SINCE_BOOT(flags)) { j = check_disk_reg(a, curr, prev, i); } else { j = -1; } if (j < 0) { /* * This is a newly registered device or we want stats since boot time. * Previous stats are zero. */ sdp = &sdpzero; } else { sdp = (struct stats_disk *) ((char *) a->buf[prev] + j * a->msize); } if (DISPLAY_ZERO_OMIT(flags) && !memcmp(sdp, sdc, STATS_DISK_SIZE)) continue; /* Get device name */ dev_name = get_device_name(sdc->major, sdc->minor, sdc->wwn, sdc->part_nr, DISPLAY_PRETTY(flags), DISPLAY_PERSIST_NAME_S(flags), USE_STABLE_ID(flags), NULL); if (a->item_list != NULL) { /* A list of devices has been entered on the command line */ if (!search_list_item(a->item_list, dev_name)) /* Device not found */ continue; } /* Compute service time, etc. */ compute_ext_disk_stats(sdc, sdp, itv, &xds); printf("%-11s", timestamp[curr]); if (!DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %9s", dev_name, 0); } cprintf_f(NO_UNIT, 1, 9, 2, S_VALUE(sdp->nr_ios, sdc->nr_ios, itv)); cprintf_f(unit, 3, 9, 2, S_VALUE(sdp->rd_sect, sdc->rd_sect, itv) / 2, S_VALUE(sdp->wr_sect, sdc->wr_sect, itv) / 2, S_VALUE(sdp->dc_sect, sdc->dc_sect, itv) / 2); /* See iostat for explanations */ cprintf_f(unit, 1, 9, 2, xds.arqsz / 2); cprintf_f(NO_UNIT, 2, 9, 2, S_VALUE(sdp->rq_ticks, sdc->rq_ticks, itv) / 1000.0, xds.await); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, xds.util / 10.0); if (DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %s", dev_name, 0); } printf("\n"); } } /* *************************************************************************** * Display network interfaces statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_dev_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, j; struct stats_net_dev *sndc, *sndp, sndzero; double rxkb, txkb, ifutil; int unit = NO_UNIT; memset(&sndzero, 0, STATS_NET_DEV_SIZE); if (DISPLAY_UNIT(flags)) { /* Default values unit is bytes */ unit = UNIT_BYTE; } if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, DISPLAY_PRETTY(flags) ? -1 : 0, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { sndc = (struct stats_net_dev *) ((char *) a->buf[curr] + i * a->msize); if (a->item_list != NULL) { /* A list of devices has been entered on the command line */ if (!search_list_item(a->item_list, sndc->interface)) /* Device not found */ continue; } if (!WANT_SINCE_BOOT(flags)) { j = check_net_dev_reg(a, curr, prev, i); } else { j = -1; } if (j < 0) { /* * This is a newly registered interface or we want stats since boot time. * Previous stats are zero. */ sndp = &sndzero; } else { sndp = (struct stats_net_dev *) ((char *) a->buf[prev] + j * a->msize); } if (DISPLAY_ZERO_OMIT(flags) && !memcmp(sndp, sndc, STATS_NET_DEV_SIZE2CMP)) continue; printf("%-11s", timestamp[curr]); if (!DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %9s", sndc->interface, 0); } rxkb = S_VALUE(sndp->rx_bytes, sndc->rx_bytes, itv); txkb = S_VALUE(sndp->tx_bytes, sndc->tx_bytes, itv); cprintf_f(NO_UNIT, 2, 9, 2, S_VALUE(sndp->rx_packets, sndc->rx_packets, itv), S_VALUE(sndp->tx_packets, sndc->tx_packets, itv)); cprintf_f(unit, 2, 9, 2, unit < 0 ? rxkb / 1024 : rxkb, unit < 0 ? txkb / 1024 : txkb); cprintf_f(NO_UNIT, 3, 9, 2, S_VALUE(sndp->rx_compressed, sndc->rx_compressed, itv), S_VALUE(sndp->tx_compressed, sndc->tx_compressed, itv), S_VALUE(sndp->multicast, sndc->multicast, itv)); ifutil = compute_ifutil(sndc, rxkb, txkb); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ifutil); if (DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %s", sndc->interface, 0); } printf("\n"); } } /* *************************************************************************** * Display network interface errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_edev_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, j; struct stats_net_edev *snedc, *snedp, snedzero; memset(&snedzero, 0, STATS_NET_EDEV_SIZE); if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, DISPLAY_PRETTY(flags) ? -1 : 0, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { snedc = (struct stats_net_edev *) ((char *) a->buf[curr] + i * a->msize); if (a->item_list != NULL) { /* A list of devices has been entered on the command line */ if (!search_list_item(a->item_list, snedc->interface)) /* Device not found */ continue; } if (!WANT_SINCE_BOOT(flags)) { j = check_net_edev_reg(a, curr, prev, i); } else { j = -1; } if (j < 0) { /* * This is a newly registered interface or we want stats since boot time. * Previous stats are zero. */ snedp = &snedzero; } else { snedp = (struct stats_net_edev *) ((char *) a->buf[prev] + j * a->msize); } if (DISPLAY_ZERO_OMIT(flags) && !memcmp(snedp, snedc, STATS_NET_EDEV_SIZE2CMP)) continue; printf("%-11s", timestamp[curr]); if (!DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %9s", snedc->interface, 0); } cprintf_f(NO_UNIT, 9, 9, 2, S_VALUE(snedp->rx_errors, snedc->rx_errors, itv), S_VALUE(snedp->tx_errors, snedc->tx_errors, itv), S_VALUE(snedp->collisions, snedc->collisions, itv), S_VALUE(snedp->rx_dropped, snedc->rx_dropped, itv), S_VALUE(snedp->tx_dropped, snedc->tx_dropped, itv), S_VALUE(snedp->tx_carrier_errors, snedc->tx_carrier_errors, itv), S_VALUE(snedp->rx_frame_errors, snedc->rx_frame_errors, itv), S_VALUE(snedp->rx_fifo_errors, snedc->rx_fifo_errors, itv), S_VALUE(snedp->tx_fifo_errors, snedc->tx_fifo_errors, itv)); if (DISPLAY_PRETTY(flags)) { cprintf_in(IS_STR, " %s", snedc->interface, 0); } printf("\n"); } } /* *************************************************************************** * Display NFS client statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_nfs_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_nfs *snnc = (struct stats_net_nfs *) a->buf[curr], *snnp = (struct stats_net_nfs *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 6, 9, 2, S_VALUE(snnp->nfs_rpccnt, snnc->nfs_rpccnt, itv), S_VALUE(snnp->nfs_rpcretrans, snnc->nfs_rpcretrans, itv), S_VALUE(snnp->nfs_readcnt, snnc->nfs_readcnt, itv), S_VALUE(snnp->nfs_writecnt, snnc->nfs_writecnt, itv), S_VALUE(snnp->nfs_accesscnt, snnc->nfs_accesscnt, itv), S_VALUE(snnp->nfs_getattcnt, snnc->nfs_getattcnt, itv)); printf("\n"); } /* *************************************************************************** * Display NFS server statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_nfsd_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_nfsd *snndc = (struct stats_net_nfsd *) a->buf[curr], *snndp = (struct stats_net_nfsd *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 11, 9, 2, S_VALUE(snndp->nfsd_rpccnt, snndc->nfsd_rpccnt, itv), S_VALUE(snndp->nfsd_rpcbad, snndc->nfsd_rpcbad, itv), S_VALUE(snndp->nfsd_netcnt, snndc->nfsd_netcnt, itv), S_VALUE(snndp->nfsd_netudpcnt, snndc->nfsd_netudpcnt, itv), S_VALUE(snndp->nfsd_nettcpcnt, snndc->nfsd_nettcpcnt, itv), S_VALUE(snndp->nfsd_rchits, snndc->nfsd_rchits, itv), S_VALUE(snndp->nfsd_rcmisses, snndc->nfsd_rcmisses, itv), S_VALUE(snndp->nfsd_readcnt, snndc->nfsd_readcnt, itv), S_VALUE(snndp->nfsd_writecnt, snndc->nfsd_writecnt, itv), S_VALUE(snndp->nfsd_accesscnt, snndc->nfsd_accesscnt, itv), S_VALUE(snndp->nfsd_getattcnt, snndc->nfsd_getattcnt, itv)); printf("\n"); } /* *************************************************************************** * Display network sockets statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_net_sock_stats(struct activity *a, int curr, int dispavg) { struct stats_net_sock *snsc = (struct stats_net_sock *) a->buf[curr]; static unsigned long long avg_sock_inuse = 0, avg_tcp_inuse = 0, avg_udp_inuse = 0, avg_raw_inuse = 0, avg_frag_inuse = 0, avg_tcp_tw = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(NO_UNIT, 6, 9, (unsigned long long) snsc->sock_inuse, (unsigned long long) snsc->tcp_inuse, (unsigned long long) snsc->udp_inuse, (unsigned long long) snsc->raw_inuse, (unsigned long long) snsc->frag_inuse, (unsigned long long) snsc->tcp_tw); printf("\n"); /* Will be used to compute the average */ avg_sock_inuse += snsc->sock_inuse; avg_tcp_inuse += snsc->tcp_inuse; avg_udp_inuse += snsc->udp_inuse; avg_raw_inuse += snsc->raw_inuse; avg_frag_inuse += snsc->frag_inuse; avg_tcp_tw += snsc->tcp_tw; } else { /* Display average values */ cprintf_f(NO_UNIT, 6, 9, 0, (double) avg_sock_inuse / avg_count, (double) avg_tcp_inuse / avg_count, (double) avg_udp_inuse / avg_count, (double) avg_raw_inuse / avg_count, (double) avg_frag_inuse / avg_count, (double) avg_tcp_tw / avg_count); printf("\n"); /* Reset average counters */ avg_sock_inuse = avg_tcp_inuse = avg_udp_inuse = 0; avg_raw_inuse = avg_frag_inuse = avg_tcp_tw = 0; } } /* *************************************************************************** * Display network sockets statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_sock_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_net_sock_stats(a, curr, FALSE); } /* *************************************************************************** * Display average network sockets statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_net_sock_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_net_sock_stats(a, curr, TRUE); } /* *************************************************************************** * Display IP network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_ip_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_ip *snic = (struct stats_net_ip *) a->buf[curr], *snip = (struct stats_net_ip *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 8, 9, 2, S_VALUE(snip->InReceives, snic->InReceives, itv), S_VALUE(snip->ForwDatagrams, snic->ForwDatagrams, itv), S_VALUE(snip->InDelivers, snic->InDelivers, itv), S_VALUE(snip->OutRequests, snic->OutRequests, itv), S_VALUE(snip->ReasmReqds, snic->ReasmReqds, itv), S_VALUE(snip->ReasmOKs, snic->ReasmOKs, itv), S_VALUE(snip->FragOKs, snic->FragOKs, itv), S_VALUE(snip->FragCreates, snic->FragCreates, itv)); printf("\n"); } /* *************************************************************************** * Display IP network errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_eip_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_eip *sneic = (struct stats_net_eip *) a->buf[curr], *sneip = (struct stats_net_eip *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 8, 9, 2, S_VALUE(sneip->InHdrErrors, sneic->InHdrErrors, itv), S_VALUE(sneip->InAddrErrors, sneic->InAddrErrors, itv), S_VALUE(sneip->InUnknownProtos, sneic->InUnknownProtos, itv), S_VALUE(sneip->InDiscards, sneic->InDiscards, itv), S_VALUE(sneip->OutDiscards, sneic->OutDiscards, itv), S_VALUE(sneip->OutNoRoutes, sneic->OutNoRoutes, itv), S_VALUE(sneip->ReasmFails, sneic->ReasmFails, itv), S_VALUE(sneip->FragFails, sneic->FragFails, itv)); printf("\n"); } /* *************************************************************************** * Display ICMP network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_icmp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_icmp *snic = (struct stats_net_icmp *) a->buf[curr], *snip = (struct stats_net_icmp *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 14, 9, 2, S_VALUE(snip->InMsgs, snic->InMsgs, itv), S_VALUE(snip->OutMsgs, snic->OutMsgs, itv), S_VALUE(snip->InEchos, snic->InEchos, itv), S_VALUE(snip->InEchoReps, snic->InEchoReps, itv), S_VALUE(snip->OutEchos, snic->OutEchos, itv), S_VALUE(snip->OutEchoReps, snic->OutEchoReps, itv), S_VALUE(snip->InTimestamps, snic->InTimestamps, itv), S_VALUE(snip->InTimestampReps, snic->InTimestampReps, itv), S_VALUE(snip->OutTimestamps, snic->OutTimestamps, itv), S_VALUE(snip->OutTimestampReps, snic->OutTimestampReps, itv), S_VALUE(snip->InAddrMasks, snic->InAddrMasks, itv), S_VALUE(snip->InAddrMaskReps, snic->InAddrMaskReps, itv), S_VALUE(snip->OutAddrMasks, snic->OutAddrMasks, itv), S_VALUE(snip->OutAddrMaskReps, snic->OutAddrMaskReps, itv)); printf("\n"); } /* *************************************************************************** * Display ICMP network errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_eicmp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_eicmp *sneic = (struct stats_net_eicmp *) a->buf[curr], *sneip = (struct stats_net_eicmp *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 12, 9, 2, S_VALUE(sneip->InErrors, sneic->InErrors, itv), S_VALUE(sneip->OutErrors, sneic->OutErrors, itv), S_VALUE(sneip->InDestUnreachs, sneic->InDestUnreachs, itv), S_VALUE(sneip->OutDestUnreachs, sneic->OutDestUnreachs, itv), S_VALUE(sneip->InTimeExcds, sneic->InTimeExcds, itv), S_VALUE(sneip->OutTimeExcds, sneic->OutTimeExcds, itv), S_VALUE(sneip->InParmProbs, sneic->InParmProbs, itv), S_VALUE(sneip->OutParmProbs, sneic->OutParmProbs, itv), S_VALUE(sneip->InSrcQuenchs, sneic->InSrcQuenchs, itv), S_VALUE(sneip->OutSrcQuenchs, sneic->OutSrcQuenchs, itv), S_VALUE(sneip->InRedirects, sneic->InRedirects, itv), S_VALUE(sneip->OutRedirects, sneic->OutRedirects, itv)); printf("\n"); } /* *************************************************************************** * Display TCP network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_tcp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_tcp *sntc = (struct stats_net_tcp *) a->buf[curr], *sntp = (struct stats_net_tcp *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 4, 9, 2, S_VALUE(sntp->ActiveOpens, sntc->ActiveOpens, itv), S_VALUE(sntp->PassiveOpens, sntc->PassiveOpens, itv), S_VALUE(sntp->InSegs, sntc->InSegs, itv), S_VALUE(sntp->OutSegs, sntc->OutSegs, itv)); printf("\n"); } /* *************************************************************************** * Display TCP network errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_etcp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_etcp *snetc = (struct stats_net_etcp *) a->buf[curr], *snetp = (struct stats_net_etcp *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 5, 9, 2, S_VALUE(snetp->AttemptFails, snetc->AttemptFails, itv), S_VALUE(snetp->EstabResets, snetc->EstabResets, itv), S_VALUE(snetp->RetransSegs, snetc->RetransSegs, itv), S_VALUE(snetp->InErrs, snetc->InErrs, itv), S_VALUE(snetp->OutRsts, snetc->OutRsts, itv)); printf("\n"); } /* *************************************************************************** * Display UDP network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_udp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_udp *snuc = (struct stats_net_udp *) a->buf[curr], *snup = (struct stats_net_udp *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 4, 9, 2, S_VALUE(snup->InDatagrams, snuc->InDatagrams, itv), S_VALUE(snup->OutDatagrams, snuc->OutDatagrams, itv), S_VALUE(snup->NoPorts, snuc->NoPorts, itv), S_VALUE(snup->InErrors, snuc->InErrors, itv)); printf("\n"); } /* *************************************************************************** * Display IPv6 sockets statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_net_sock6_stats(struct activity *a, int curr, int dispavg) { struct stats_net_sock6 *snsc = (struct stats_net_sock6 *) a->buf[curr]; static unsigned long long avg_tcp6_inuse = 0, avg_udp6_inuse = 0, avg_raw6_inuse = 0, avg_frag6_inuse = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(NO_UNIT, 4, 9, (unsigned long long) snsc->tcp6_inuse, (unsigned long long) snsc->udp6_inuse, (unsigned long long) snsc->raw6_inuse, (unsigned long long) snsc->frag6_inuse); printf("\n"); /* Will be used to compute the average */ avg_tcp6_inuse += snsc->tcp6_inuse; avg_udp6_inuse += snsc->udp6_inuse; avg_raw6_inuse += snsc->raw6_inuse; avg_frag6_inuse += snsc->frag6_inuse; } else { /* Display average values */ cprintf_f(NO_UNIT, 4, 9, 0, (double) avg_tcp6_inuse / avg_count, (double) avg_udp6_inuse / avg_count, (double) avg_raw6_inuse / avg_count, (double) avg_frag6_inuse / avg_count); printf("\n"); /* Reset average counters */ avg_tcp6_inuse = avg_udp6_inuse = avg_raw6_inuse = avg_frag6_inuse = 0; } } /* *************************************************************************** * Display IPv6 sockets statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_sock6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_net_sock6_stats(a, curr, FALSE); } /* *************************************************************************** * Display average IPv6 sockets statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_net_sock6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_net_sock6_stats(a, curr, TRUE); } /* *************************************************************************** * Display IPv6 network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_ip6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_ip6 *snic = (struct stats_net_ip6 *) a->buf[curr], *snip = (struct stats_net_ip6 *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 10, 9, 2, S_VALUE(snip->InReceives6, snic->InReceives6, itv), S_VALUE(snip->OutForwDatagrams6, snic->OutForwDatagrams6, itv), S_VALUE(snip->InDelivers6, snic->InDelivers6, itv), S_VALUE(snip->OutRequests6, snic->OutRequests6, itv), S_VALUE(snip->ReasmReqds6, snic->ReasmReqds6, itv), S_VALUE(snip->ReasmOKs6, snic->ReasmOKs6, itv), S_VALUE(snip->InMcastPkts6, snic->InMcastPkts6, itv), S_VALUE(snip->OutMcastPkts6, snic->OutMcastPkts6, itv), S_VALUE(snip->FragOKs6, snic->FragOKs6, itv), S_VALUE(snip->FragCreates6, snic->FragCreates6, itv)); printf("\n"); } /* *************************************************************************** * Display IPv6 network errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_eip6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_eip6 *sneic = (struct stats_net_eip6 *) a->buf[curr], *sneip = (struct stats_net_eip6 *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 11, 9, 2, S_VALUE(sneip->InHdrErrors6, sneic->InHdrErrors6, itv), S_VALUE(sneip->InAddrErrors6, sneic->InAddrErrors6, itv), S_VALUE(sneip->InUnknownProtos6, sneic->InUnknownProtos6, itv), S_VALUE(sneip->InTooBigErrors6, sneic->InTooBigErrors6, itv), S_VALUE(sneip->InDiscards6, sneic->InDiscards6, itv), S_VALUE(sneip->OutDiscards6, sneic->OutDiscards6, itv), S_VALUE(sneip->InNoRoutes6, sneic->InNoRoutes6, itv), S_VALUE(sneip->OutNoRoutes6, sneic->OutNoRoutes6, itv), S_VALUE(sneip->ReasmFails6, sneic->ReasmFails6, itv), S_VALUE(sneip->FragFails6, sneic->FragFails6, itv), S_VALUE(sneip->InTruncatedPkts6, sneic->InTruncatedPkts6, itv)); printf("\n"); } /* *************************************************************************** * Display ICMPv6 network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_icmp6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_icmp6 *snic = (struct stats_net_icmp6 *) a->buf[curr], *snip = (struct stats_net_icmp6 *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 17, 9, 2, S_VALUE(snip->InMsgs6, snic->InMsgs6, itv), S_VALUE(snip->OutMsgs6, snic->OutMsgs6, itv), S_VALUE(snip->InEchos6, snic->InEchos6, itv), S_VALUE(snip->InEchoReplies6, snic->InEchoReplies6, itv), S_VALUE(snip->OutEchoReplies6, snic->OutEchoReplies6, itv), S_VALUE(snip->InGroupMembQueries6, snic->InGroupMembQueries6, itv), S_VALUE(snip->InGroupMembResponses6, snic->InGroupMembResponses6, itv), S_VALUE(snip->OutGroupMembResponses6, snic->OutGroupMembResponses6, itv), S_VALUE(snip->InGroupMembReductions6, snic->InGroupMembReductions6, itv), S_VALUE(snip->OutGroupMembReductions6, snic->OutGroupMembReductions6, itv), S_VALUE(snip->InRouterSolicits6, snic->InRouterSolicits6, itv), S_VALUE(snip->OutRouterSolicits6, snic->OutRouterSolicits6, itv), S_VALUE(snip->InRouterAdvertisements6, snic->InRouterAdvertisements6, itv), S_VALUE(snip->InNeighborSolicits6, snic->InNeighborSolicits6, itv), S_VALUE(snip->OutNeighborSolicits6, snic->OutNeighborSolicits6, itv), S_VALUE(snip->InNeighborAdvertisements6, snic->InNeighborAdvertisements6, itv), S_VALUE(snip->OutNeighborAdvertisements6, snic->OutNeighborAdvertisements6, itv)); printf("\n"); } /* *************************************************************************** * Display ICMPv6 network errors statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_eicmp6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_eicmp6 *sneic = (struct stats_net_eicmp6 *) a->buf[curr], *sneip = (struct stats_net_eicmp6 *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 11, 9, 2, S_VALUE(sneip->InErrors6, sneic->InErrors6, itv), S_VALUE(sneip->InDestUnreachs6, sneic->InDestUnreachs6, itv), S_VALUE(sneip->OutDestUnreachs6, sneic->OutDestUnreachs6, itv), S_VALUE(sneip->InTimeExcds6, sneic->InTimeExcds6, itv), S_VALUE(sneip->OutTimeExcds6, sneic->OutTimeExcds6, itv), S_VALUE(sneip->InParmProblems6, sneic->InParmProblems6, itv), S_VALUE(sneip->OutParmProblems6, sneic->OutParmProblems6, itv), S_VALUE(sneip->InRedirects6, sneic->InRedirects6, itv), S_VALUE(sneip->OutRedirects6, sneic->OutRedirects6, itv), S_VALUE(sneip->InPktTooBigs6, sneic->InPktTooBigs6, itv), S_VALUE(sneip->OutPktTooBigs6, sneic->OutPktTooBigs6, itv)); printf("\n"); } /* *************************************************************************** * Display UDPv6 network traffic statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_net_udp6_stats(struct activity *a, int prev, int curr, unsigned long long itv) { struct stats_net_udp6 *snuc = (struct stats_net_udp6 *) a->buf[curr], *snup = (struct stats_net_udp6 *) a->buf[prev]; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 4, 9, 2, S_VALUE(snup->InDatagrams6, snuc->InDatagrams6, itv), S_VALUE(snup->OutDatagrams6, snuc->OutDatagrams6, itv), S_VALUE(snup->NoPorts6, snuc->NoPorts6, itv), S_VALUE(snup->InErrors6, snuc->InErrors6, itv)); printf("\n"); } /* *************************************************************************** * Display CPU frequency statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg True if displaying average statistics. *************************************************************************** */ void stub_print_pwr_cpufreq_stats(struct activity *a, int curr, int dispavg) { int i; struct stats_pwr_cpufreq *spc; static __nr_t nr_alloc = 0; static unsigned long long *avg_cpufreq = NULL; if (!avg_cpufreq || (a->nr[curr] > nr_alloc)) { /* Allocate array of CPU frequency */ SREALLOC(avg_cpufreq, unsigned long long, sizeof(unsigned long long) * a->nr[curr]); if (a->nr[curr] > nr_alloc) { /* Init additional space allocated */ memset(avg_cpufreq + nr_alloc, 0, sizeof(unsigned long long) * (a->nr[curr] - nr_alloc)); } nr_alloc = a->nr[curr]; } if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 7, 9, NULL); } for (i = 0; (i < a->nr[curr]) && (i < a->bitmap->b_size + 1); i++) { /* * The size of a->buf[...] CPU structure may be different from the default * sizeof(struct stats_pwr_cpufreq) value if data have been read from a file! * That's why we don't use a syntax like: * spc = (struct stats_pwr_cpufreq *) a->buf[...] + i; */ spc = (struct stats_pwr_cpufreq *) ((char *) a->buf[curr] + i * a->msize); if (!spc->cpufreq) /* This CPU is offline: Don't display it */ continue; /* * Note: @nr[curr] is in [1, NR_CPUS + 1]. * Bitmap size is provided for (NR_CPUS + 1) CPUs. * Anyway, NR_CPUS may vary between the version of sysstat * used by sadc to create a file, and the version of sysstat * used by sar to read it... */ /* Should current CPU (including CPU "all") be displayed? */ if (!(a->bitmap->b_array[i >> 3] & (1 << (i & 0x07)))) /* No */ continue; printf("%-11s", timestamp[curr]); if (!i) { /* This is CPU "all" */ cprintf_in(IS_STR, "%s", " all", 0); } else { cprintf_in(IS_INT, " %3d", "", i - 1); } if (!dispavg) { /* Display instantaneous values */ cprintf_f(NO_UNIT, 1, 9, 2, ((double) spc->cpufreq) / 100); printf("\n"); /* * Will be used to compute the average. * Note: Overflow unlikely to happen but not impossible... */ avg_cpufreq[i] += spc->cpufreq; } else { /* Display average values */ cprintf_f(NO_UNIT, 1, 9, 2, (double) avg_cpufreq[i] / (100 * avg_count)); printf("\n"); } } if (dispavg && avg_cpufreq) { /* Array of CPU frequency no longer needed: Free it! */ free(avg_cpufreq); avg_cpufreq = NULL; nr_alloc = 0; } } /* *************************************************************************** * Display CPU frequency statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pwr_cpufreq_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_cpufreq_stats(a, curr, FALSE); } /* *************************************************************************** * Display average CPU frequency statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_pwr_cpufreq_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_cpufreq_stats(a, curr, TRUE); } /* *************************************************************************** * Display fan statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg True if displaying average statistics. *************************************************************************** */ void stub_print_pwr_fan_stats(struct activity *a, int curr, int dispavg) { int i; struct stats_pwr_fan *spc; static __nr_t nr_alloc = 0; static double *avg_fan = NULL; static double *avg_fan_min = NULL; /* Allocate arrays of fan RPMs */ if (!avg_fan || (a->nr[curr] > nr_alloc)) { SREALLOC(avg_fan, double, sizeof(double) * a->nr[curr]); SREALLOC(avg_fan_min, double, sizeof(double) * a->nr[curr]); if (a->nr[curr] > nr_alloc) { /* Init additional space allocated */ memset(avg_fan + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); memset(avg_fan_min + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); } nr_alloc = a->nr[curr]; } if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, -2, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { spc = (struct stats_pwr_fan *) ((char *) a->buf[curr] + i * a->msize); printf("%-11s", timestamp[curr]); cprintf_in(IS_INT, " %5d", "", i + 1); if (dispavg) { /* Display average values */ cprintf_f(NO_UNIT, 2, 9, 2, (double) avg_fan[i] / avg_count, (double) (avg_fan[i] - avg_fan_min[i]) / avg_count); } else { /* Display instantaneous values */ cprintf_f(NO_UNIT, 2, 9, 2, spc->rpm, spc->rpm - spc->rpm_min); avg_fan[i] += spc->rpm; avg_fan_min[i] += spc->rpm_min; } cprintf_in(IS_STR, " %s\n", spc->device, 0); } if (dispavg && avg_fan) { free(avg_fan); free(avg_fan_min); avg_fan = NULL; avg_fan_min = NULL; nr_alloc = 0; } } /* *************************************************************************** * Display fan statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pwr_fan_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_fan_stats(a, curr, FALSE); } /* *************************************************************************** * Display average fan statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_pwr_fan_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_fan_stats(a, curr, TRUE); } /* *************************************************************************** * Display device temperature statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg True if displaying average statistics. *************************************************************************** */ void stub_print_pwr_temp_stats(struct activity *a, int curr, int dispavg) { int i; struct stats_pwr_temp *spc; static __nr_t nr_alloc = 0; static double *avg_temp = NULL; static double *avg_temp_min = NULL, *avg_temp_max = NULL; /* Allocate arrays of temperatures */ if (!avg_temp || (a->nr[curr] > nr_alloc)) { SREALLOC(avg_temp, double, sizeof(double) * a->nr[curr]); SREALLOC(avg_temp_min, double, sizeof(double) * a->nr[curr]); SREALLOC(avg_temp_max, double, sizeof(double) * a->nr[curr]); if (a->nr[curr] > nr_alloc) { /* Init additional space allocated */ memset(avg_temp + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); memset(avg_temp_min + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); memset(avg_temp_max + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); } nr_alloc = a->nr[curr]; } if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, -2, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { spc = (struct stats_pwr_temp *) ((char *) a->buf[curr] + i * a->msize); printf("%-11s", timestamp[curr]); cprintf_in(IS_INT, " %5d", "", i + 1); if (dispavg) { /* Display average values */ cprintf_f(NO_UNIT, 1, 9, 2, (double) avg_temp[i] / avg_count); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (avg_temp_max[i] - avg_temp_min[i]) ? ((double) (avg_temp[i] / avg_count) - avg_temp_min[i]) / (avg_temp_max[i] - avg_temp_min[i]) * 100 : 0.0); } else { /* Display instantaneous values */ cprintf_f(NO_UNIT, 1, 9, 2, spc->temp); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (spc->temp_max - spc->temp_min) ? (spc->temp - spc->temp_min) / (spc->temp_max - spc->temp_min) * 100 : 0.0); avg_temp[i] += spc->temp; /* Assume that min and max temperatures cannot vary */ avg_temp_min[i] = spc->temp_min; avg_temp_max[i] = spc->temp_max; } cprintf_in(IS_STR, " %s\n", spc->device, 0); } if (dispavg && avg_temp) { free(avg_temp); free(avg_temp_min); free(avg_temp_max); avg_temp = NULL; avg_temp_min = NULL; avg_temp_max = NULL; nr_alloc = 0; } } /* *************************************************************************** * Display temperature statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pwr_temp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_temp_stats(a, curr, FALSE); } /* *************************************************************************** * Display average temperature statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_pwr_temp_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_temp_stats(a, curr, TRUE); } /* *************************************************************************** * Display voltage inputs statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg True if displaying average statistics. *************************************************************************** */ void stub_print_pwr_in_stats(struct activity *a, int curr, int dispavg) { int i; struct stats_pwr_in *spc; static __nr_t nr_alloc = 0; static double *avg_in = NULL; static double *avg_in_min = NULL, *avg_in_max = NULL; /* Allocate arrays of voltage inputs */ if (!avg_in || (a->nr[curr] > nr_alloc)) { SREALLOC(avg_in, double, sizeof(double) * a->nr[curr]); SREALLOC(avg_in_min, double, sizeof(double) * a->nr[curr]); SREALLOC(avg_in_max, double, sizeof(double) * a->nr[curr]); if (a->nr[curr] > nr_alloc) { /* Init additional space allocated */ memset(avg_in + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); memset(avg_in_min + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); memset(avg_in_max + nr_alloc, 0, sizeof(double) * (a->nr[curr] - nr_alloc)); } nr_alloc = a->nr[curr]; } if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, -2, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { spc = (struct stats_pwr_in *) ((char *) a->buf[curr] + i * a->msize); printf("%-11s", timestamp[curr]); cprintf_in(IS_INT, " %5d", "", i); if (dispavg) { /* Display average values */ cprintf_f(NO_UNIT, 1, 9, 2, (double) avg_in[i] / avg_count); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (avg_in_max[i] - avg_in_min[i]) ? ((double) (avg_in[i] / avg_count) - avg_in_min[i]) / (avg_in_max[i] - avg_in_min[i]) * 100 : 0.0); } else { /* Display instantaneous values */ cprintf_f(NO_UNIT, 1, 9, 2, spc->in); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, (spc->in_max - spc->in_min) ? (spc->in - spc->in_min) / (spc->in_max - spc->in_min) * 100 : 0.0); avg_in[i] += spc->in; /* Assume that min and max voltage inputs cannot vary */ avg_in_min[i] = spc->in_min; avg_in_max[i] = spc->in_max; } cprintf_in(IS_STR, " %s\n", spc->device, 0); } if (dispavg && avg_in) { free(avg_in); free(avg_in_min); free(avg_in_max); avg_in = NULL; avg_in_min = NULL; avg_in_max = NULL; nr_alloc = 0; } } /* *************************************************************************** * Display voltage inputs statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pwr_in_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_in_stats(a, curr, FALSE); } /* *************************************************************************** * Display average voltage inputs statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_pwr_in_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_in_stats(a, curr, TRUE); } /* *************************************************************************** * Display huge pages statistics. This function is used to * display instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_huge_stats(struct activity *a, int curr, int dispavg) { struct stats_huge *smc = (struct stats_huge *) a->buf[curr]; static unsigned long long avg_frhkb = 0, avg_tlhkb = 0, avg_rsvdhkb = 0, avg_surphkb = 0; int unit = NO_UNIT; if (DISPLAY_UNIT(flags)) { /* Default values unit is kB */ unit = UNIT_KILOBYTE; } if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_u64(unit, 2, 9, (unsigned long long) smc->frhkb, (unsigned long long) (smc->tlhkb - smc->frhkb)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, smc->tlhkb ? SP_VALUE(smc->frhkb, smc->tlhkb, smc->tlhkb) : 0.0); cprintf_u64(unit, 2, 9, (unsigned long long) smc->rsvdhkb, (unsigned long long) (smc->surphkb)); printf("\n"); /* Will be used to compute the average */ avg_frhkb += smc->frhkb; avg_tlhkb += smc->tlhkb; avg_rsvdhkb += smc->rsvdhkb; avg_surphkb += smc->surphkb; } else { /* Display average values */ cprintf_f(unit, 2, 9, 0, (double) avg_frhkb / avg_count, ((double) avg_tlhkb / avg_count) - ((double) avg_frhkb / avg_count)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, avg_tlhkb ? SP_VALUE((double) avg_frhkb / avg_count, (double) avg_tlhkb / avg_count, (double) avg_tlhkb / avg_count) : 0.0); cprintf_f(unit, 2, 9, 0, (double) avg_rsvdhkb / avg_count, (double) avg_surphkb / avg_count); printf("\n"); /* Reset average counters */ avg_frhkb = avg_tlhkb = avg_rsvdhkb = avg_surphkb = 0; } } /* *************************************************************************** * Display huge pages statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_huge_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_huge_stats(a, curr, FALSE); } /* *************************************************************************** * Display huge pages statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_huge_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_huge_stats(a, curr, TRUE); } /* *************************************************************************** * Display CPU weighted frequency statistics. This function is used to * display instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ void print_pwr_wghfreq_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, k; struct stats_pwr_wghfreq *spc, *spp, *spc_k, *spp_k; unsigned long long tis, tisfreq; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 7, 9, NULL); } for (i = 0; (i < a->nr[curr]) && (i < a->bitmap->b_size + 1); i++) { /* * The size of a->buf[...] CPU structure may be different from the default * sizeof(struct stats_pwr_wghfreq) value if data have been read from a file! * That's why we don't use a syntax like: * spc = (struct stats_pwr_wghfreq *) a->buf[...] + i; */ spc = (struct stats_pwr_wghfreq *) ((char *) a->buf[curr] + i * a->msize * a->nr2); spp = (struct stats_pwr_wghfreq *) ((char *) a->buf[prev] + i * a->msize * a->nr2); /* * Note: a->nr is in [1, NR_CPUS + 1]. * Bitmap size is provided for (NR_CPUS + 1) CPUs. * Anyway, NR_CPUS may vary between the version of sysstat * used by sadc to create a file, and the version of sysstat * used by sar to read it... */ /* Should current CPU (including CPU "all") be displayed? */ if (!(a->bitmap->b_array[i >> 3] & (1 << (i & 0x07)))) /* No */ continue; /* Yes: Display it */ printf("%-11s", timestamp[curr]); if (!i) { /* This is CPU "all" */ cprintf_in(IS_STR, "%s", " all", 0); } else { cprintf_in(IS_INT, " %3d", "", i - 1); } tisfreq = 0; tis = 0; for (k = 0; k < a->nr2; k++) { spc_k = (struct stats_pwr_wghfreq *) ((char *) spc + k * a->msize); if (!spc_k->freq) break; spp_k = (struct stats_pwr_wghfreq *) ((char *) spp + k * a->msize); tisfreq += (spc_k->freq / 1000) * (spc_k->time_in_state - spp_k->time_in_state); tis += (spc_k->time_in_state - spp_k->time_in_state); } /* Display weighted frequency for current CPU */ cprintf_f(NO_UNIT, 1, 9, 2, tis ? ((double) tisfreq) / tis : 0.0); printf("\n"); } } /* *************************************************************************** * Display USB devices statistics. This function is used to * display instantaneous and summary statistics. * * IN: * @a Activity structure with statistics. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ void stub_print_pwr_usb_stats(struct activity *a, int curr, int dispavg) { int i, j; char fmt[16]; struct stats_pwr_usb *suc, *sum; if (dish) { printf("\n%-11s BUS idvendor idprod maxpower", (dispavg ? _("Summary:") : timestamp[!curr])); printf(" %-*s product\n", MAX_MANUF_LEN - 1, "manufact"); } for (i = 0; i < a->nr[curr]; i++) { suc = (struct stats_pwr_usb *) ((char *) a->buf[curr] + i * a->msize); printf("%-11s", (dispavg ? _("Summary:") : timestamp[curr])); cprintf_in(IS_INT, " %6d", "", suc->bus_nr); cprintf_x(2, 9, suc->vendor_id, suc->product_id); cprintf_u64(NO_UNIT, 1, 9, /* bMaxPower is expressed in 2 mA units */ (unsigned long long) (suc->bmaxpower << 1)); snprintf(fmt, 16, " %%-%ds", MAX_MANUF_LEN - 1); cprintf_s(IS_STR, fmt, suc->manufacturer); cprintf_s(IS_STR, " %s\n", suc->product); if (!dispavg) { /* Save current USB device in summary list */ for (j = 0; j < a->nr_allocated; j++) { sum = (struct stats_pwr_usb *) ((char *) a->buf[2] + j * a->msize); if ((sum->bus_nr == suc->bus_nr) && (sum->vendor_id == suc->vendor_id) && (sum->product_id == suc->product_id)) /* USB device found in summary list */ break; if (!sum->bus_nr) { /* * Current slot is free: * Save USB device in summary list. */ *sum = *suc; a->nr[2] = j + 1; break; } } if (j == a->nr_allocated) { /* * No free slot has been found for current device. * So enlarge buffers then save device in list. */ reallocate_all_buffers(a, j); sum = (struct stats_pwr_usb *) ((char *) a->buf[2] + j * a->msize); *sum = *suc; a->nr[2] = j + 1; } } } } /* *************************************************************************** * Display USB devices statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_pwr_usb_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_usb_stats(a, curr, FALSE); } /* *************************************************************************** * Display average USB devices statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_pwr_usb_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_pwr_usb_stats(a, 2, TRUE); } /* *************************************************************************** * Display filesystems statistics. This function is used to * display instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. *************************************************************************** */ __print_funct_t stub_print_filesystem_stats(struct activity *a, int prev, int curr, int dispavg) { int i, j, j0, found; struct stats_filesystem *sfc, *sfp, *sfm; int unit = NO_UNIT; char *dev_name; if (DISPLAY_UNIT(flags)) { /* Default values unit is B */ unit = UNIT_BYTE; } if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line((dispavg ? _("Summary:") : timestamp[!curr]), a, FIRST + DISPLAY_MOUNT(a->opt_flags), -1, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { sfc = (struct stats_filesystem *) ((char *) a->buf[curr] + i * a->msize); /* Get name to display (persistent or standard fs name, or mount point) */ dev_name = get_fs_name_to_display(a, flags, sfc); if (a->item_list != NULL) { /* A list of devices has been entered on the command line */ if (!search_list_item(a->item_list, dev_name)) /* Device not found */ continue; } found = FALSE; if (DISPLAY_ZERO_OMIT(flags) && !dispavg) { if (a->nr[prev] > 0) { /* Look for corresponding fs in previous iteration */ j = i; if (j >= a->nr[prev]) { j = a->nr[prev] - 1; } j0 = j; do { sfp = (struct stats_filesystem *) ((char *) a->buf[prev] + j * a->msize); if (!strcmp(sfp->fs_name, sfc->fs_name)) { found = TRUE; break; } if (++j >= a->nr[prev]) { j = 0; } } while (j != j0); } } if (!DISPLAY_ZERO_OMIT(flags) || dispavg || WANT_SINCE_BOOT(flags) || !found || (found && memcmp(sfp, sfc, STATS_FILESYSTEM_SIZE2CMP))) { printf("%-11s", (dispavg ? _("Summary:") : timestamp[curr])); cprintf_f(unit, 2, 9, 0, unit < 0 ? (double) sfc->f_bfree / 1024 / 1024 : (double) sfc->f_bfree, unit < 0 ? (double) (sfc->f_blocks - sfc->f_bfree) / 1024 / 1024 : (double) (sfc->f_blocks - sfc->f_bfree)); cprintf_pc(DISPLAY_UNIT(flags), 2, 9, 2, /* f_blocks is not zero. But test it anyway ;-) */ sfc->f_blocks ? SP_VALUE(sfc->f_bfree, sfc->f_blocks, sfc->f_blocks) : 0.0, sfc->f_blocks ? SP_VALUE(sfc->f_bavail, sfc->f_blocks, sfc->f_blocks) : 0.0); cprintf_u64(NO_UNIT, 2, 9, (unsigned long long) sfc->f_ffree, (unsigned long long) (sfc->f_files - sfc->f_ffree)); cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, sfc->f_files ? SP_VALUE(sfc->f_ffree, sfc->f_files, sfc->f_files) : 0.0); cprintf_in(IS_STR, " %s\n", dev_name, 0); } if (!dispavg) { /* Save current filesystem in summary list */ for (j = 0; j < a->nr_allocated; j++) { sfm = (struct stats_filesystem *) ((char *) a->buf[2] + j * a->msize); if (!strcmp(sfm->fs_name, sfc->fs_name) || !sfm->f_blocks) { /* * Filesystem found in list (then save again its stats) * or free slot (end of list). */ *sfm = *sfc; if (j >= a->nr[2]) { a->nr[2] = j + 1; } break; } } if (j == a->nr_allocated) { /* * No free slot has been found for current filesystem. * So enlarge buffers then save filesystem in list. */ reallocate_all_buffers(a, j); sfm = (struct stats_filesystem *) ((char *) a->buf[2] + j * a->msize); *sfm = *sfc; a->nr[2] = j + 1; } } } } /* *************************************************************************** * Display filesystems statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_filesystem_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_filesystem_stats(a, prev, curr, FALSE); } /* *************************************************************************** * Display average filesystems statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_filesystem_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_filesystem_stats(a, prev, 2, TRUE); } /* *************************************************************************** * Display Fibre Channel HBA statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_fchost_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i, j, j0, found; struct stats_fchost *sfcc, *sfcp, sfczero; memset(&sfczero, 0, sizeof(struct stats_fchost)); if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, -1, 9, NULL); } for (i = 0; i < a->nr[curr]; i++) { sfcc = (struct stats_fchost *) ((char *) a->buf[curr] + i * a->msize); if (WANT_SINCE_BOOT(flags)) { sfcp = (struct stats_fchost *) ((char *) a->buf[prev]); found = TRUE; } else { found = FALSE; if (a->nr[prev] > 0) { /* Look for corresponding structure in previous iteration */ j = i; if (j >= a->nr[prev]) { j = a->nr[prev] - 1; } j0 = j; do { sfcp = (struct stats_fchost *) ((char *) a->buf[prev] + j * a->msize); if (!strcmp(sfcc->fchost_name, sfcp->fchost_name)) { found = TRUE; break; } if (++j >= a->nr[prev]) { j = 0; } } while (j != j0); } } if (!found) { /* This is a newly registered host */ sfcp = &sfczero; } printf("%-11s", timestamp[curr]); cprintf_f(NO_UNIT, 4, 9, 2, S_VALUE(sfcp->f_rxframes, sfcc->f_rxframes, itv), S_VALUE(sfcp->f_txframes, sfcc->f_txframes, itv), S_VALUE(sfcp->f_rxwords, sfcc->f_rxwords, itv), S_VALUE(sfcp->f_txwords, sfcc->f_txwords, itv)); cprintf_in(IS_STR, " %s\n", sfcc->fchost_name, 0); } } /* *************************************************************************** * Display softnet statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_softnet_stats(struct activity *a, int prev, int curr, unsigned long long itv) { int i; struct stats_softnet *ssnc = (struct stats_softnet *) a->buf[curr], *ssnp = (struct stats_softnet *) a->buf[prev]; unsigned char offline_cpu_bitmap[BITMAP_SIZE(NR_CPUS)] = {0}; if (dish || DISPLAY_ZERO_OMIT(flags)) { print_hdr_line(timestamp[!curr], a, FIRST, 7, 9, NULL); } /* * @nr[curr] cannot normally be greater than @nr_ini * (since @nr_ini counts up all CPU, even those offline). * If this happens, it may be because the machine has been * restarted with more CPU and no LINUX_RESTART has been * inserted in file. */ if (a->nr[curr] > a->nr_ini) { a->nr_ini = a->nr[curr]; } /* Compute statistics for CPU "all" */ get_global_soft_statistics(a, prev, curr, flags, offline_cpu_bitmap); for (i = 0; (i < a->nr_ini) && (i < a->bitmap->b_size + 1); i++) { /* * Should current CPU (including CPU "all") be displayed? * Note: a->nr is in [1, NR_CPUS + 1]. * Bitmap size is provided for (NR_CPUS + 1) CPUs. * Anyway, NR_CPUS may vary between the version of sysstat * used by sadc to create a file, and the version of sysstat * used by sar to read it... */ if (!(a->bitmap->b_array[i >> 3] & (1 << (i & 0x07))) || offline_cpu_bitmap[i >> 3] & (1 << (i & 0x07))) /* No */ continue; /* * The size of a->buf[...] CPU structure may be different from the default * sizeof(struct stats_pwr_cpufreq) value if data have been read from a file! * That's why we don't use a syntax like: * ssnc = (struct stats_softnet *) a->buf[...] + i; */ ssnc = (struct stats_softnet *) ((char *) a->buf[curr] + i * a->msize); ssnp = (struct stats_softnet *) ((char *) a->buf[prev] + i * a->msize); if (DISPLAY_ZERO_OMIT(flags) && !memcmp(ssnp, ssnc, STATS_SOFTNET_SIZE)) continue; printf("%-11s", timestamp[curr]); if (!i) { /* This is CPU "all" */ cprintf_in(IS_STR, " %s", " all", 0); } else { cprintf_in(IS_INT, " %7d", "", i - 1); } cprintf_f(NO_UNIT, 5, 9, 2, S_VALUE(ssnp->processed, ssnc->processed, itv), S_VALUE(ssnp->dropped, ssnc->dropped, itv), S_VALUE(ssnp->time_squeeze, ssnc->time_squeeze, itv), S_VALUE(ssnp->received_rps, ssnc->received_rps, itv), S_VALUE(ssnp->flow_limit, ssnc->flow_limit, itv)); printf("\n"); } } /* *************************************************************************** * Display pressure-stall CPU statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ void stub_print_psicpu_stats(struct activity *a, int prev, int curr, int dispavg, unsigned long long itv) { struct stats_psi_cpu *psic = (struct stats_psi_cpu *) a->buf[curr], *psip = (struct stats_psi_cpu *) a->buf[prev]; static unsigned long long s_avg10 = 0, s_avg60 = 0, s_avg300 = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) psic->some_acpu_10 / 100, (double) psic->some_acpu_60 / 100, (double) psic->some_acpu_300 / 100); /* Will be used to compute the average */ s_avg10 += psic->some_acpu_10; s_avg60 += psic->some_acpu_60; s_avg300 += psic->some_acpu_300; } else { /* Display average values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) s_avg10 / (avg_count * 100), (double) s_avg60 / (avg_count * 100), (double) s_avg300 / (avg_count * 100)); /* Reset average counters */ s_avg10 = s_avg60 = s_avg300 = 0; } cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ((double) psic->some_cpu_total - psip->some_cpu_total) / (100 * itv)); printf("\n"); } /* *************************************************************************** * Display pressure-stall CPU statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_psicpu_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psicpu_stats(a, prev, curr, FALSE, itv); } /* *************************************************************************** * Display average pressure-stall CPU statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_psicpu_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psicpu_stats(a, prev, curr, TRUE, itv); } /* *************************************************************************** * Display pressure-stall I/O statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ void stub_print_psiio_stats(struct activity *a, int prev, int curr, int dispavg, unsigned long long itv) { struct stats_psi_io *psic = (struct stats_psi_io *) a->buf[curr], *psip = (struct stats_psi_io *) a->buf[prev]; static unsigned long long s_avg10 = 0, s_avg60 = 0, s_avg300 = 0, f_avg10 = 0, f_avg60 = 0, f_avg300 = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous "some" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) psic->some_aio_10 / 100, (double) psic->some_aio_60 / 100, (double) psic->some_aio_300 / 100); /* Will be used to compute the average */ s_avg10 += psic->some_aio_10; s_avg60 += psic->some_aio_60; s_avg300 += psic->some_aio_300; } else { /* Display average "some" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) s_avg10 / (avg_count * 100), (double) s_avg60 / (avg_count * 100), (double) s_avg300 / (avg_count * 100)); /* Reset average counters */ s_avg10 = s_avg60 = s_avg300 = 0; } cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ((double) psic->some_io_total - psip->some_io_total) / (100 * itv)); if (!dispavg) { /* Display instantaneous "full" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) psic->full_aio_10 / 100, (double) psic->full_aio_60 / 100, (double) psic->full_aio_300 / 100); /* Will be used to compute the average */ f_avg10 += psic->full_aio_10; f_avg60 += psic->full_aio_60; f_avg300 += psic->full_aio_300; } else { /* Display average "full" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) f_avg10 / (avg_count * 100), (double) f_avg60 / (avg_count * 100), (double) f_avg300 / (avg_count * 100)); /* Reset average counters */ f_avg10 = f_avg60 = f_avg300 = 0; } cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ((double) psic->full_io_total - psip->full_io_total) / (100 * itv)); printf("\n"); } /* *************************************************************************** * Display pressure-stall I/O statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_psiio_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psiio_stats(a, prev, curr, FALSE, itv); } /* *************************************************************************** * Display average pressure-stall I/O statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_psiio_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psiio_stats(a, prev, curr, TRUE, itv); } /* *************************************************************************** * Display pressure-stall memory statistics. This function is used to display * instantaneous and average statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @dispavg TRUE if displaying average statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ void stub_print_psimem_stats(struct activity *a, int prev, int curr, int dispavg, unsigned long long itv) { struct stats_psi_mem *psic = (struct stats_psi_mem *) a->buf[curr], *psip = (struct stats_psi_mem *) a->buf[prev]; static unsigned long long s_avg10 = 0, s_avg60 = 0, s_avg300 = 0, f_avg10 = 0, f_avg60 = 0, f_avg300 = 0; if (dish) { print_hdr_line(timestamp[!curr], a, FIRST, 0, 9, NULL); } printf("%-11s", timestamp[curr]); if (!dispavg) { /* Display instantaneous "some" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) psic->some_amem_10 / 100, (double) psic->some_amem_60 / 100, (double) psic->some_amem_300 / 100); /* Will be used to compute the average */ s_avg10 += psic->some_amem_10; s_avg60 += psic->some_amem_60; s_avg300 += psic->some_amem_300; } else { /* Display average "some" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) s_avg10 / (avg_count * 100), (double) s_avg60 / (avg_count * 100), (double) s_avg300 / (avg_count * 100)); /* Reset average counters */ s_avg10 = s_avg60 = s_avg300 = 0; } cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ((double) psic->some_mem_total - psip->some_mem_total) / (100 * itv)); if (!dispavg) { /* Display instantaneous "full" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) psic->full_amem_10 / 100, (double) psic->full_amem_60 / 100, (double) psic->full_amem_300 / 100); /* Will be used to compute the average */ f_avg10 += psic->full_amem_10; f_avg60 += psic->full_amem_60; f_avg300 += psic->full_amem_300; } else { /* Display average "full" values */ cprintf_pc(DISPLAY_UNIT(flags), 3, 9, 2, (double) f_avg10 / (avg_count * 100), (double) f_avg60 / (avg_count * 100), (double) f_avg300 / (avg_count * 100)); /* Reset average counters */ f_avg10 = f_avg60 = f_avg300 = 0; } cprintf_pc(DISPLAY_UNIT(flags), 1, 9, 2, ((double) psic->full_mem_total - psip->full_mem_total) / (100 * itv)); printf("\n"); } /* *************************************************************************** * Display pressure-stall memory statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_psimem_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psimem_stats(a, prev, curr, FALSE, itv); } /* *************************************************************************** * Display average pressure-stall memory statistics. * * IN: * @a Activity structure with statistics. * @prev Index in array where stats used as reference are. * @curr Index in array for current sample statistics. * @itv Interval of time in 1/100th of a second. *************************************************************************** */ __print_funct_t print_avg_psimem_stats(struct activity *a, int prev, int curr, unsigned long long itv) { stub_print_psimem_stats(a, prev, curr, TRUE, itv); }