Current Path : /usr/src/usr.bin/ctlstat/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/usr.bin/ctlstat/ctlstat.c |
/*- * Copyright (c) 2004, 2008, 2009 Silicon Graphics International Corp. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions, and the following disclaimer, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * substantially similar to the "NO WARRANTY" disclaimer below * ("Disclaimer") and any redistribution must be conditioned upon * including a substantially similar Disclaimer requirement for further * binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDERS OR CONTRIBUTORS BE LIABLE FOR SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGES. * * $Id: //depot/users/kenm/FreeBSD-test2/usr.bin/ctlstat/ctlstat.c#4 $ */ /* * CAM Target Layer statistics program * * Authors: Ken Merry <ken@FreeBSD.org>, Will Andrews <will@FreeBSD.org> */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/usr.bin/ctlstat/ctlstat.c 231772 2012-02-15 17:28:09Z ken $"); #include <sys/ioctl.h> #include <sys/types.h> #include <sys/param.h> #include <sys/time.h> #include <sys/sysctl.h> #include <sys/resource.h> #include <sys/queue.h> #include <sys/callout.h> #include <stdint.h> #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <fcntl.h> #include <getopt.h> #include <string.h> #include <errno.h> #include <err.h> #include <ctype.h> #include <bitstring.h> #include <cam/scsi/scsi_all.h> #include <cam/ctl/ctl.h> #include <cam/ctl/ctl_io.h> #include <cam/ctl/ctl_scsi_all.h> #include <cam/ctl/ctl_util.h> #include <cam/ctl/ctl_frontend_internal.h> #include <cam/ctl/ctl_backend.h> #include <cam/ctl/ctl_ioctl.h> /* * The default amount of space we allocate for LUN storage space. We * dynamically allocate more if needed. */ #define CTL_STAT_NUM_LUNS 30 /* * The default number of LUN selection bits we allocate. This is large * because we don't currently increase it if the user specifies a LUN * number of 1024 or larger. */ #define CTL_STAT_LUN_BITS 1024L static const char *ctlstat_opts = "Cc:Ddhjl:n:tw:"; static const char *ctlstat_usage = "Usage: ctlstat [-CDdjht] [-l lunnum]" "[-c count] [-n numdevs] [-w wait]\n"; struct ctl_cpu_stats { uint64_t user; uint64_t nice; uint64_t system; uint64_t intr; uint64_t idle; }; typedef enum { CTLSTAT_MODE_STANDARD, CTLSTAT_MODE_DUMP, CTLSTAT_MODE_JSON, } ctlstat_mode_types; #define CTLSTAT_FLAG_CPU (1 << 0) #define CTLSTAT_FLAG_HEADER (1 << 1) #define CTLSTAT_FLAG_FIRST_RUN (1 << 2) #define CTLSTAT_FLAG_TOTALS (1 << 3) #define CTLSTAT_FLAG_DMA_TIME (1 << 4) #define CTLSTAT_FLAG_LUN_TIME_VALID (1 << 5) #define F_CPU(ctx) ((ctx)->flags & CTLSTAT_FLAG_CPU) #define F_HDR(ctx) ((ctx)->flags & CTLSTAT_FLAG_HEADER) #define F_FIRST(ctx) ((ctx)->flags & CTLSTAT_FLAG_FIRST_RUN) #define F_TOTALS(ctx) ((ctx)->flags & CTLSTAT_FLAG_TOTALS) #define F_DMA(ctx) ((ctx)->flags & CTLSTAT_FLAG_DMA_TIME) #define F_LUNVAL(ctx) ((ctx)->flags & CTLSTAT_FLAG_LUN_TIME_VALID) struct ctlstat_context { ctlstat_mode_types mode; int flags; struct ctl_lun_io_stats *cur_lun_stats, *prev_lun_stats, *tmp_lun_stats; struct ctl_lun_io_stats cur_total_stats[3], prev_total_stats[3]; struct timespec cur_time, prev_time; struct ctl_cpu_stats cur_cpu, prev_cpu; uint64_t cur_total_jiffies, prev_total_jiffies; uint64_t cur_idle, prev_idle; bitstr_t bit_decl(lun_mask, CTL_STAT_LUN_BITS); int num_luns; int numdevs; int header_interval; }; #ifndef min #define min(x,y) (((x) < (y)) ? (x) : (y)) #endif static void usage(int error); static int getstats(int fd, int *num_luns, struct ctl_lun_io_stats **xlun_stats, struct timespec *cur_time, int *lun_time_valid); static int getcpu(struct ctl_cpu_stats *cpu_stats); static void compute_stats(struct ctl_lun_io_stats *cur_stats, struct ctl_lun_io_stats *prev_stats, long double etime, long double *mbsec, long double *kb_per_transfer, long double *transfers_per_second, long double *ms_per_transfer, long double *ms_per_dma, long double *dmas_per_second); static void usage(int error) { fputs(ctlstat_usage, error ? stderr : stdout); } static int getstats(int fd, int *num_luns, struct ctl_lun_io_stats **xlun_stats, struct timespec *cur_time, int *flags) { struct ctl_lun_io_stats *lun_stats; struct ctl_stats stats; int more_space_count; more_space_count = 0; if (*num_luns == 0) *num_luns = CTL_STAT_NUM_LUNS; lun_stats = *xlun_stats; retry: if (lun_stats == NULL) { lun_stats = (struct ctl_lun_io_stats *)malloc( sizeof(*lun_stats) * *num_luns); } memset(&stats, 0, sizeof(stats)); stats.alloc_len = *num_luns * sizeof(*lun_stats); memset(lun_stats, 0, stats.alloc_len); stats.lun_stats = lun_stats; if (ioctl(fd, CTL_GETSTATS, &stats) == -1) err(1, "error returned from CTL_GETSTATS ioctl"); switch (stats.status) { case CTL_SS_OK: break; case CTL_SS_ERROR: err(1, "CTL_SS_ERROR returned from CTL_GETSTATS ioctl"); break; case CTL_SS_NEED_MORE_SPACE: if (more_space_count > 0) { errx(1, "CTL_GETSTATS returned NEED_MORE_SPACE again"); } *num_luns = stats.num_luns; free(lun_stats); lun_stats = NULL; more_space_count++; goto retry; break; /* NOTREACHED */ default: errx(1, "unknown status %d returned from CTL_GETSTATS ioctl", stats.status); break; } *xlun_stats = lun_stats; *num_luns = stats.num_luns; cur_time->tv_sec = stats.timestamp.tv_sec; cur_time->tv_nsec = stats.timestamp.tv_nsec; if (stats.flags & CTL_STATS_FLAG_TIME_VALID) *flags |= CTLSTAT_FLAG_LUN_TIME_VALID; else *flags &= ~CTLSTAT_FLAG_LUN_TIME_VALID; return (0); } static int getcpu(struct ctl_cpu_stats *cpu_stats) { long cp_time[CPUSTATES]; size_t cplen; cplen = sizeof(cp_time); if (sysctlbyname("kern.cp_time", &cp_time, &cplen, NULL, 0) == -1) { warn("sysctlbyname(kern.cp_time...) failed"); return (1); } cpu_stats->user = cp_time[CP_USER]; cpu_stats->nice = cp_time[CP_NICE]; cpu_stats->system = cp_time[CP_SYS]; cpu_stats->intr = cp_time[CP_INTR]; cpu_stats->idle = cp_time[CP_IDLE]; return (0); } static void compute_stats(struct ctl_lun_io_stats *cur_stats, struct ctl_lun_io_stats *prev_stats, long double etime, long double *mbsec, long double *kb_per_transfer, long double *transfers_per_second, long double *ms_per_transfer, long double *ms_per_dma, long double *dmas_per_second) { uint64_t total_bytes = 0, total_operations = 0, total_dmas = 0; uint32_t port; struct bintime total_time_bt, total_dma_bt; struct timespec total_time_ts, total_dma_ts; int i; bzero(&total_time_bt, sizeof(total_time_bt)); bzero(&total_dma_bt, sizeof(total_dma_bt)); bzero(&total_time_ts, sizeof(total_time_ts)); bzero(&total_dma_ts, sizeof(total_dma_ts)); for (port = 0; port < CTL_MAX_PORTS; port++) { for (i = 0; i < CTL_STATS_NUM_TYPES; i++) { total_bytes += cur_stats->ports[port].bytes[i]; total_operations += cur_stats->ports[port].operations[i]; total_dmas += cur_stats->ports[port].num_dmas[i]; bintime_add(&total_time_bt, &cur_stats->ports[port].time[i]); bintime_add(&total_dma_bt, &cur_stats->ports[port].dma_time[i]); if (prev_stats != NULL) { total_bytes -= prev_stats->ports[port].bytes[i]; total_operations -= prev_stats->ports[port].operations[i]; total_dmas -= prev_stats->ports[port].num_dmas[i]; bintime_sub(&total_time_bt, &prev_stats->ports[port].time[i]); bintime_sub(&total_dma_bt, &prev_stats->ports[port].dma_time[i]); } } } *mbsec = total_bytes; *mbsec /= 1024 * 1024; if (etime > 0.0) *mbsec /= etime; else *mbsec = 0; *kb_per_transfer = total_bytes; *kb_per_transfer /= 1024; if (total_operations > 0) *kb_per_transfer /= total_operations; else *kb_per_transfer = 0; *transfers_per_second = total_operations; *dmas_per_second = total_dmas; if (etime > 0.0) { *transfers_per_second /= etime; *dmas_per_second /= etime; } else { *transfers_per_second = 0; *dmas_per_second = 0; } bintime2timespec(&total_time_bt, &total_time_ts); bintime2timespec(&total_dma_bt, &total_dma_ts); if (total_operations > 0) { /* * Convert the timespec to milliseconds. */ *ms_per_transfer = total_time_ts.tv_sec * 1000; *ms_per_transfer += total_time_ts.tv_nsec / 1000000; *ms_per_transfer /= total_operations; } else *ms_per_transfer = 0; if (total_dmas > 0) { /* * Convert the timespec to milliseconds. */ *ms_per_dma = total_dma_ts.tv_sec * 1000; *ms_per_dma += total_dma_ts.tv_nsec / 1000000; *ms_per_dma /= total_dmas; } else *ms_per_dma = 0; } /* The dump_stats() and json_stats() functions perform essentially the same * purpose, but dump the statistics in different formats. JSON is more * conducive to programming, however. */ #define PRINT_BINTIME(prefix, bt) \ printf("%s %jd s %ju frac\n", prefix, (intmax_t)(bt).sec, \ (uintmax_t)(bt).frac) const char *iotypes[] = {"NO IO", "READ", "WRITE"}; static void ctlstat_dump(struct ctlstat_context *ctx) { int iotype, lun, port; struct ctl_lun_io_stats *stats = ctx->cur_lun_stats; for (lun = 0; lun < ctx->num_luns;lun++) { printf("lun %d\n", lun); for (port = 0; port < CTL_MAX_PORTS; port++) { printf(" port %d\n", stats[lun].ports[port].targ_port); for (iotype = 0; iotype < CTL_STATS_NUM_TYPES; iotype++) { printf(" io type %d (%s)\n", iotype, iotypes[iotype]); printf(" bytes %ju\n", (uintmax_t) stats[lun].ports[port].bytes[iotype]); printf(" operations %ju\n", (uintmax_t) stats[lun].ports[port].operations[iotype]); PRINT_BINTIME(" io time", stats[lun].ports[port].time[iotype]); printf(" num dmas %ju\n", (uintmax_t) stats[lun].ports[port].num_dmas[iotype]); PRINT_BINTIME(" dma time", stats[lun].ports[port].dma_time[iotype]); } } } } #define JSON_BINTIME(prefix, bt) \ printf("\"%s\":{\"sec\":%jd,\"frac\":%ju},", \ prefix, (intmax_t)(bt).sec, (uintmax_t)(bt).frac) static void ctlstat_json(struct ctlstat_context *ctx) { int iotype, lun, port; struct ctl_lun_io_stats *stats = ctx->cur_lun_stats; printf("{\"luns\":["); for (lun = 0; lun < ctx->num_luns; lun++) { printf("{\"ports\":["); for (port = 0; port < CTL_MAX_PORTS;port++) { printf("{\"num\":%d,\"io\":[", stats[lun].ports[port].targ_port); for (iotype = 0; iotype < CTL_STATS_NUM_TYPES; iotype++) { printf("{\"type\":\"%s\",", iotypes[iotype]); printf("\"bytes\":%ju,", (uintmax_t)stats[ lun].ports[port].bytes[iotype]); printf("\"operations\":%ju,", (uintmax_t)stats[ lun].ports[port].operations[iotype]); JSON_BINTIME("io time", stats[lun].ports[port].time[iotype]); JSON_BINTIME("dma time", stats[lun].ports[port].dma_time[iotype]); printf("\"num dmas\":%ju}", (uintmax_t) stats[lun].ports[port].num_dmas[iotype]); if (iotype < (CTL_STATS_NUM_TYPES - 1)) printf(","); /* continue io array */ } printf("]}"); /* close port */ if (port < (CTL_MAX_PORTS - 1)) printf(","); /* continue port array */ } printf("]}"); /* close lun */ if (lun < (ctx->num_luns - 1)) printf(","); /* continue lun array */ } printf("]}"); /* close luns and toplevel */ } static void ctlstat_standard(struct ctlstat_context *ctx) { long double cur_secs, prev_secs, etime; uint64_t delta_jiffies, delta_idle; uint32_t port; long double cpu_percentage; int i; int j; cpu_percentage = 0; if (F_CPU(ctx) && (getcpu(&ctx->cur_cpu) != 0)) errx(1, "error returned from getcpu()"); cur_secs = ctx->cur_time.tv_sec + (ctx->cur_time.tv_nsec / 1000000000); prev_secs = ctx->prev_time.tv_sec + (ctx->prev_time.tv_nsec / 1000000000); etime = cur_secs - prev_secs; if (F_CPU(ctx)) { ctx->prev_total_jiffies = ctx->cur_total_jiffies; ctx->cur_total_jiffies = ctx->cur_cpu.user + ctx->cur_cpu.nice + ctx->cur_cpu.system + ctx->cur_cpu.intr + ctx->cur_cpu.idle; delta_jiffies = ctx->cur_total_jiffies; if (F_FIRST(ctx) == 0) delta_jiffies -= ctx->prev_total_jiffies; ctx->prev_idle = ctx->cur_idle; ctx->cur_idle = ctx->cur_cpu.idle; delta_idle = ctx->cur_idle - ctx->prev_idle; cpu_percentage = delta_jiffies - delta_idle; cpu_percentage /= delta_jiffies; cpu_percentage *= 100; } if (F_HDR(ctx)) { ctx->header_interval--; if (ctx->header_interval <= 0) { int hdr_devs; hdr_devs = 0; if (F_TOTALS(ctx)) { fprintf(stdout, "%s System Read %s" "System Write %sSystem Total%s\n", (F_LUNVAL(ctx) != 0) ? " " : "", (F_LUNVAL(ctx) != 0) ? " " : "", (F_LUNVAL(ctx) != 0) ? " " : "", (F_CPU(ctx) == 0) ? " CPU" : ""); hdr_devs = 3; } else { if (F_CPU(ctx)) fprintf(stdout, " CPU "); for (i = 0; i < min(CTL_STAT_LUN_BITS, ctx->num_luns); i++) { int lun; /* * Obviously this won't work with * LUN numbers greater than a signed * integer. */ lun = (int)ctx->cur_lun_stats[i ].lun_number; if (bit_test(ctx->lun_mask, lun) == 0) continue; fprintf(stdout, "%15.6s%d ", "lun", lun); hdr_devs++; } fprintf(stdout, "\n"); } for (i = 0; i < hdr_devs; i++) fprintf(stdout, "%s %sKB/t %s MB/s ", ((F_CPU(ctx) != 0) && (i == 0) && (F_TOTALS(ctx) == 0)) ? " " : "", (F_LUNVAL(ctx) != 0) ? " ms " : "", (F_DMA(ctx) == 0) ? "tps" : "dps"); fprintf(stdout, "\n"); ctx->header_interval = 20; } } if (F_TOTALS(ctx) != 0) { long double mbsec[3]; long double kb_per_transfer[3]; long double transfers_per_sec[3]; long double ms_per_transfer[3]; long double ms_per_dma[3]; long double dmas_per_sec[3]; for (i = 0; i < 3; i++) ctx->prev_total_stats[i] = ctx->cur_total_stats[i]; memset(&ctx->cur_total_stats, 0, sizeof(ctx->cur_total_stats)); /* Use macros to make the next loop more readable. */ #define ADD_STATS_BYTES(st, p, i, j) \ ctx->cur_total_stats[st].ports[p].bytes[j] += \ ctx->cur_lun_stats[i].ports[p].bytes[j] #define ADD_STATS_OPERATIONS(st, p, i, j) \ ctx->cur_total_stats[st].ports[p].operations[j] += \ ctx->cur_lun_stats[i].ports[p].operations[j] #define ADD_STATS_NUM_DMAS(st, p, i, j) \ ctx->cur_total_stats[st].ports[p].num_dmas[j] += \ ctx->cur_lun_stats[i].ports[p].num_dmas[j] #define ADD_STATS_TIME(st, p, i, j) \ bintime_add(&ctx->cur_total_stats[st].ports[p].time[j], \ &ctx->cur_lun_stats[i].ports[p].time[j]) #define ADD_STATS_DMA_TIME(st, p, i, j) \ bintime_add(&ctx->cur_total_stats[st].ports[p].dma_time[j], \ &ctx->cur_lun_stats[i].ports[p].dma_time[j]) for (i = 0; i < ctx->num_luns; i++) { for (port = 0; port < CTL_MAX_PORTS; port++) { for (j = 0; j < CTL_STATS_NUM_TYPES; j++) { ADD_STATS_BYTES(2, port, i, j); ADD_STATS_OPERATIONS(2, port, i, j); ADD_STATS_NUM_DMAS(2, port, i, j); ADD_STATS_TIME(2, port, i, j); ADD_STATS_DMA_TIME(2, port, i, j); } ADD_STATS_BYTES(0, port, i, CTL_STATS_READ); ADD_STATS_OPERATIONS(0, port, i, CTL_STATS_READ); ADD_STATS_NUM_DMAS(0, port, i, CTL_STATS_READ); ADD_STATS_TIME(0, port, i, CTL_STATS_READ); ADD_STATS_DMA_TIME(0, port, i, CTL_STATS_READ); ADD_STATS_BYTES(1, port, i, CTL_STATS_WRITE); ADD_STATS_OPERATIONS(1, port, i, CTL_STATS_WRITE); ADD_STATS_NUM_DMAS(1, port, i, CTL_STATS_WRITE); ADD_STATS_TIME(1, port, i, CTL_STATS_WRITE); ADD_STATS_DMA_TIME(1, port, i, CTL_STATS_WRITE); } } for (i = 0; i < 3; i++) { compute_stats(&ctx->cur_total_stats[i], F_FIRST(ctx) ? NULL : &ctx->prev_total_stats[i], etime, &mbsec[i], &kb_per_transfer[i], &transfers_per_sec[i], &ms_per_transfer[i], &ms_per_dma[i], &dmas_per_sec[i]); if (F_DMA(ctx) != 0) fprintf(stdout, " %2.2Lf", ms_per_dma[i]); else if (F_LUNVAL(ctx) != 0) fprintf(stdout, " %2.2Lf", ms_per_transfer[i]); fprintf(stdout, " %5.2Lf %3.0Lf %5.2Lf ", kb_per_transfer[i], (F_DMA(ctx) == 0) ? transfers_per_sec[i] : dmas_per_sec[i], mbsec[i]); } if (F_CPU(ctx)) fprintf(stdout, " %5.1Lf%%", cpu_percentage); } else { if (F_CPU(ctx)) fprintf(stdout, "%5.1Lf%% ", cpu_percentage); for (i = 0; i < min(CTL_STAT_LUN_BITS, ctx->num_luns); i++) { long double mbsec, kb_per_transfer; long double transfers_per_sec; long double ms_per_transfer; long double ms_per_dma; long double dmas_per_sec; if (bit_test(ctx->lun_mask, (int)ctx->cur_lun_stats[i].lun_number) == 0) continue; compute_stats(&ctx->cur_lun_stats[i], F_FIRST(ctx) ? NULL : &ctx->prev_lun_stats[i], etime, &mbsec, &kb_per_transfer, &transfers_per_sec, &ms_per_transfer, &ms_per_dma, &dmas_per_sec); if (F_DMA(ctx)) fprintf(stdout, " %2.2Lf", ms_per_dma); else if (F_LUNVAL(ctx) != 0) fprintf(stdout, " %2.2Lf", ms_per_transfer); fprintf(stdout, " %5.2Lf %3.0Lf %5.2Lf ", kb_per_transfer, (F_DMA(ctx) == 0) ? transfers_per_sec : dmas_per_sec, mbsec); } } } int main(int argc, char **argv) { int c; int count, waittime; int set_lun; int fd, retval; struct ctlstat_context ctx; /* default values */ retval = 0; waittime = 1; count = -1; memset(&ctx, 0, sizeof(ctx)); ctx.numdevs = 3; ctx.mode = CTLSTAT_MODE_STANDARD; ctx.flags |= CTLSTAT_FLAG_CPU; ctx.flags |= CTLSTAT_FLAG_FIRST_RUN; ctx.flags |= CTLSTAT_FLAG_HEADER; while ((c = getopt(argc, argv, ctlstat_opts)) != -1) { switch (c) { case 'C': ctx.flags &= ~CTLSTAT_FLAG_CPU; break; case 'c': count = atoi(optarg); break; case 'd': ctx.flags |= CTLSTAT_FLAG_DMA_TIME; break; case 'D': ctx.mode = CTLSTAT_MODE_DUMP; waittime = 30; break; case 'h': ctx.flags &= ~CTLSTAT_FLAG_HEADER; break; case 'j': ctx.mode = CTLSTAT_MODE_JSON; waittime = 30; break; case 'l': { int cur_lun; cur_lun = atoi(optarg); if (cur_lun > CTL_STAT_LUN_BITS) errx(1, "Invalid LUN number %d", cur_lun); bit_ffs(ctx.lun_mask, CTL_STAT_LUN_BITS, &set_lun); if (set_lun == -1) ctx.numdevs = 1; else ctx.numdevs++; bit_set(ctx.lun_mask, cur_lun); break; } case 'n': ctx.numdevs = atoi(optarg); break; case 't': ctx.flags |= CTLSTAT_FLAG_TOTALS; ctx.numdevs = 3; break; case 'w': waittime = atoi(optarg); break; default: retval = 1; usage(retval); exit(retval); break; } } bit_ffs(ctx.lun_mask, CTL_STAT_LUN_BITS, &set_lun); if ((F_TOTALS(&ctx)) && (set_lun != -1)) { errx(1, "Total Mode (-t) is incompatible with individual " "LUN mode (-l)"); } else if (set_lun == -1) { /* * Note that this just selects the first N LUNs to display, * but at this point we have no knoweledge of which LUN * numbers actually exist. So we may select LUNs that * aren't there. */ bit_nset(ctx.lun_mask, 0, min(ctx.numdevs - 1, CTL_STAT_LUN_BITS - 1)); } if ((fd = open(CTL_DEFAULT_DEV, O_RDWR)) == -1) err(1, "cannot open %s", CTL_DEFAULT_DEV); for (;count != 0;) { ctx.tmp_lun_stats = ctx.prev_lun_stats; ctx.prev_lun_stats = ctx.cur_lun_stats; ctx.cur_lun_stats = ctx.tmp_lun_stats; ctx.prev_time = ctx.cur_time; ctx.prev_cpu = ctx.cur_cpu; if (getstats(fd, &ctx.num_luns, &ctx.cur_lun_stats, &ctx.cur_time, &ctx.flags) != 0) errx(1, "error returned from getstats()"); switch(ctx.mode) { case CTLSTAT_MODE_STANDARD: ctlstat_standard(&ctx); break; case CTLSTAT_MODE_DUMP: ctlstat_dump(&ctx); break; case CTLSTAT_MODE_JSON: ctlstat_json(&ctx); break; default: break; } fprintf(stdout, "\n"); ctx.flags &= ~CTLSTAT_FLAG_FIRST_RUN; if (count != 1) sleep(waittime); if (count > 0) count--; } exit (retval); } /* * vim: ts=8 */