Windows fio: implement some more POSIX functions

[fio.git] / stat.c

#include <stdio.h>
#include <string.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <dirent.h>
#include <libgen.h>
#include <math.h>

#include "fio.h"
#include "diskutil.h"
#include "lib/ieee754.h"

void update_rusage_stat(struct thread_data *td)
{
        struct thread_stat *ts = &td->ts;

        getrusage(RUSAGE_SELF, &td->ru_end);

        ts->usr_time += mtime_since(&td->ru_start.ru_utime,
                                        &td->ru_end.ru_utime);
        ts->sys_time += mtime_since(&td->ru_start.ru_stime,
                                        &td->ru_end.ru_stime);
        ts->ctx += td->ru_end.ru_nvcsw + td->ru_end.ru_nivcsw
                        - (td->ru_start.ru_nvcsw + td->ru_start.ru_nivcsw);
        ts->minf += td->ru_end.ru_minflt - td->ru_start.ru_minflt;
        ts->majf += td->ru_end.ru_majflt - td->ru_start.ru_majflt;

        memcpy(&td->ru_start, &td->ru_end, sizeof(td->ru_end));
}

/*
 * Given a latency, return the index of the corresponding bucket in
 * the structure tracking percentiles.
 *
 * (1) find the group (and error bits) that the value (latency)
 * belongs to by looking at its MSB. (2) find the bucket number in the
 * group by looking at the index bits.
 *
 */
static unsigned int plat_val_to_idx(unsigned int val)
{
        unsigned int msb, error_bits, base, offset, idx;

        /* Find MSB starting from bit 0 */
        if (val == 0)
                msb = 0;
        else
                msb = (sizeof(val)*8) - __builtin_clz(val) - 1;

        /*
         * MSB <= (FIO_IO_U_PLAT_BITS-1), cannot be rounded off. Use
         * all bits of the sample as index
         */
        if (msb <= FIO_IO_U_PLAT_BITS)
                return val;

        /* Compute the number of error bits to discard*/
        error_bits = msb - FIO_IO_U_PLAT_BITS;

        /* Compute the number of buckets before the group */
        base = (error_bits + 1) << FIO_IO_U_PLAT_BITS;

        /*
         * Discard the error bits and apply the mask to find the
         * index for the buckets in the group
         */
        offset = (FIO_IO_U_PLAT_VAL - 1) & (val >> error_bits);

        /* Make sure the index does not exceed (array size - 1) */
        idx = (base + offset) < (FIO_IO_U_PLAT_NR - 1)?
                (base + offset) : (FIO_IO_U_PLAT_NR - 1);

        return idx;
}

/*
 * Convert the given index of the bucket array to the value
 * represented by the bucket
 */
static unsigned int plat_idx_to_val(unsigned int idx)
{
        unsigned int error_bits, k, base;

        assert(idx < FIO_IO_U_PLAT_NR);

        /* MSB <= (FIO_IO_U_PLAT_BITS-1), cannot be rounded off. Use
         * all bits of the sample as index */
        if (idx < (FIO_IO_U_PLAT_VAL << 1) )
                return idx;

        /* Find the group and compute the minimum value of that group */
        error_bits = (idx >> FIO_IO_U_PLAT_BITS) -1;
        base = 1 << (error_bits + FIO_IO_U_PLAT_BITS);

        /* Find its bucket number of the group */
        k = idx % FIO_IO_U_PLAT_VAL;

        /* Return the mean of the range of the bucket */
        return base + ((k + 0.5) * (1 << error_bits));
}

static int double_cmp(const void *a, const void *b)
{
        const fio_fp64_t fa = *(const fio_fp64_t *) a;
        const fio_fp64_t fb = *(const fio_fp64_t *) b;
        int cmp = 0;

        if (fa.u.f > fb.u.f)
                cmp = 1;
        else if (fa.u.f < fb.u.f)
                cmp = -1;

        return cmp;
}

static unsigned int calc_clat_percentiles(unsigned int *io_u_plat,
                                          unsigned long nr, fio_fp64_t *plist,
                                          unsigned int **output,
                                          unsigned int *maxv,
                                          unsigned int *minv)
{
        unsigned long sum = 0;
        unsigned int len, i, j = 0;
        unsigned int oval_len = 0;
        unsigned int *ovals = NULL;
        int is_last;

        *minv = -1U;
        *maxv = 0;

        len = 0;
        while (len < FIO_IO_U_LIST_MAX_LEN && plist[len].u.f != 0.0)
                len++;

        if (!len)
                return 0;

        /*
         * Sort the percentile list. Note that it may already be sorted if
         * we are using the default values, but since it's a short list this
         * isn't a worry. Also note that this does not work for NaN values.
         */
        if (len > 1)
                qsort((void*)plist, len, sizeof(plist[0]), double_cmp);

        /*
         * Calculate bucket values, note down max and min values
         */
        is_last = 0;
        for (i = 0; i < FIO_IO_U_PLAT_NR && !is_last; i++) {
                sum += io_u_plat[i];
                while (sum >= (plist[j].u.f / 100.0 * nr)) {
                        assert(plist[j].u.f <= 100.0);

                        if (j == oval_len) {
                                oval_len += 100;
                                ovals = realloc(ovals, oval_len * sizeof(unsigned int));
                        }

                        ovals[j] = plat_idx_to_val(i);
                        if (ovals[j] < *minv)
                                *minv = ovals[j];
                        if (ovals[j] > *maxv)
                                *maxv = ovals[j];

                        is_last = (j == len - 1);
                        if (is_last)
                                break;

                        j++;
                }
        }

        *output = ovals;
        return len;
}

/*
 * Find and display the p-th percentile of clat
 */
static void show_clat_percentiles(unsigned int *io_u_plat, unsigned long nr,
                                  fio_fp64_t *plist)
{
        unsigned int len, j = 0, minv, maxv;
        unsigned int *ovals;
        int is_last, scale_down;

        len = calc_clat_percentiles(io_u_plat, nr, plist, &ovals, &maxv, &minv);
        if (!len)
                goto out;

        /*
         * We default to usecs, but if the value range is such that we
         * should scale down to msecs, do that.
         */
        if (minv > 2000 && maxv > 99999) {
                scale_down = 1;
                log_info("    clat percentiles (msec):\n     |");
        } else {
                scale_down = 0;
                log_info("    clat percentiles (usec):\n     |");
        }

        for (j = 0; j < len; j++) {
                char fbuf[8];

                /* for formatting */
                if (j != 0 && (j % 4) == 0)
                        log_info("     |");

                /* end of the list */
                is_last = (j == len - 1);

                if (plist[j].u.f < 10.0)
                        sprintf(fbuf, " %2.2f", plist[j].u.f);
                else
                        sprintf(fbuf, "%2.2f", plist[j].u.f);

                if (scale_down)
                        ovals[j] = (ovals[j] + 999) / 1000;

                log_info(" %sth=[%5u]%c", fbuf, ovals[j], is_last ? '\n' : ',');

                if (is_last)
                        break;

                if (j % 4 == 3) /* for formatting */
                        log_info("\n");
        }

out:
        if (ovals)
                free(ovals);
}

static int calc_lat(struct io_stat *is, unsigned long *min, unsigned long *max,
                    double *mean, double *dev)
{
        double n = is->samples;

        if (is->samples == 0)
                return 0;

        *min = is->min_val;
        *max = is->max_val;

        n = (double) is->samples;
        *mean = is->mean.u.f;

        if (n > 1.0)
                *dev = sqrt(is->S.u.f / (n - 1.0));
        else
                *dev = 0;

        return 1;
}

void show_group_stats(struct group_run_stats *rs)
{
        char *p1, *p2, *p3, *p4;
        const char *ddir_str[] = { "   READ", "  WRITE" };
        int i;

        log_info("\nRun status group %d (all jobs):\n", rs->groupid);

        for (i = 0; i <= DDIR_WRITE; i++) {
                const int i2p = is_power_of_2(rs->kb_base);

                if (!rs->max_run[i])
                        continue;

                p1 = num2str(rs->io_kb[i], 6, rs->kb_base, i2p);
                p2 = num2str(rs->agg[i], 6, rs->kb_base, i2p);
                p3 = num2str(rs->min_bw[i], 6, rs->kb_base, i2p);
                p4 = num2str(rs->max_bw[i], 6, rs->kb_base, i2p);

                log_info("%s: io=%sB, aggrb=%sB/s, minb=%sB/s, maxb=%sB/s,"
                         " mint=%llumsec, maxt=%llumsec\n", ddir_str[i], p1, p2,
                                                p3, p4, rs->min_run[i],
                                                rs->max_run[i]);

                free(p1);
                free(p2);
                free(p3);
                free(p4);
        }
}

#define ts_total_io_u(ts)       \
        ((ts)->total_io_u[0] + (ts)->total_io_u[1])

static void stat_calc_dist(unsigned int *map, unsigned long total,
                           double *io_u_dist)
{
        int i;

        /*
         * Do depth distribution calculations
         */
        for (i = 0; i < FIO_IO_U_MAP_NR; i++) {
                if (total) {
                        io_u_dist[i] = (double) map[i] / (double) total;
                        io_u_dist[i] *= 100.0;
                        if (io_u_dist[i] < 0.1 && map[i])
                                io_u_dist[i] = 0.1;
                } else
                        io_u_dist[i] = 0.0;
        }
}

static void stat_calc_lat(struct thread_stat *ts, double *dst,
                          unsigned int *src, int nr)
{
        unsigned long total = ts_total_io_u(ts);
        int i;

        /*
         * Do latency distribution calculations
         */
        for (i = 0; i < nr; i++) {
                if (total) {
                        dst[i] = (double) src[i] / (double) total;
                        dst[i] *= 100.0;
                        if (dst[i] < 0.01 && src[i])
                                dst[i] = 0.01;
                } else
                        dst[i] = 0.0;
        }
}

static void stat_calc_lat_u(struct thread_stat *ts, double *io_u_lat)
{
        stat_calc_lat(ts, io_u_lat, ts->io_u_lat_u, FIO_IO_U_LAT_U_NR);
}

static void stat_calc_lat_m(struct thread_stat *ts, double *io_u_lat)
{
        stat_calc_lat(ts, io_u_lat, ts->io_u_lat_m, FIO_IO_U_LAT_M_NR);
}

static int usec_to_msec(unsigned long *min, unsigned long *max, double *mean,
                        double *dev)
{
        if (*min > 1000 && *max > 1000 && *mean > 1000.0 && *dev > 1000.0) {
                *min /= 1000;
                *max /= 1000;
                *mean /= 1000.0;
                *dev /= 1000.0;
                return 0;
        }

        return 1;
}

static void show_ddir_status(struct group_run_stats *rs, struct thread_stat *ts,
                             int ddir)
{
        const char *ddir_str[] = { "read ", "write" };
        unsigned long min, max, runt;
        unsigned long long bw, iops;
        double mean, dev;
        char *io_p, *bw_p, *iops_p;
        int i2p;

        assert(ddir_rw(ddir));

        if (!ts->runtime[ddir])
                return;

        i2p = is_power_of_2(rs->kb_base);
        runt = ts->runtime[ddir];

        bw = (1000 * ts->io_bytes[ddir]) / runt;
        io_p = num2str(ts->io_bytes[ddir], 6, 1, i2p);
        bw_p = num2str(bw, 6, 1, i2p);

        iops = (1000 * (uint64_t)ts->total_io_u[ddir]) / runt;
        iops_p = num2str(iops, 6, 1, 0);

        log_info("  %s: io=%sB, bw=%sB/s, iops=%s, runt=%6llumsec\n",
                                        ddir_str[ddir], io_p, bw_p, iops_p,
                                        ts->runtime[ddir]);

        free(io_p);
        free(bw_p);
        free(iops_p);

        if (calc_lat(&ts->slat_stat[ddir], &min, &max, &mean, &dev)) {
                const char *base = "(usec)";
                char *minp, *maxp;

                if (!usec_to_msec(&min, &max, &mean, &dev))
                        base = "(msec)";

                minp = num2str(min, 6, 1, 0);
                maxp = num2str(max, 6, 1, 0);

                log_info("    slat %s: min=%s, max=%s, avg=%5.02f,"
                         " stdev=%5.02f\n", base, minp, maxp, mean, dev);

                free(minp);
                free(maxp);
        }
        if (calc_lat(&ts->clat_stat[ddir], &min, &max, &mean, &dev)) {
                const char *base = "(usec)";
                char *minp, *maxp;

                if (!usec_to_msec(&min, &max, &mean, &dev))
                        base = "(msec)";

                minp = num2str(min, 6, 1, 0);
                maxp = num2str(max, 6, 1, 0);

                log_info("    clat %s: min=%s, max=%s, avg=%5.02f,"
                         " stdev=%5.02f\n", base, minp, maxp, mean, dev);

                free(minp);
                free(maxp);
        }
        if (calc_lat(&ts->lat_stat[ddir], &min, &max, &mean, &dev)) {
                const char *base = "(usec)";
                char *minp, *maxp;

                if (!usec_to_msec(&min, &max, &mean, &dev))
                        base = "(msec)";

                minp = num2str(min, 6, 1, 0);
                maxp = num2str(max, 6, 1, 0);

                log_info("     lat %s: min=%s, max=%s, avg=%5.02f,"
                         " stdev=%5.02f\n", base, minp, maxp, mean, dev);

                free(minp);
                free(maxp);
        }
        if (ts->clat_percentiles) {
                show_clat_percentiles(ts->io_u_plat[ddir],
                                        ts->clat_stat[ddir].samples,
                                        ts->percentile_list);
        }
        if (calc_lat(&ts->bw_stat[ddir], &min, &max, &mean, &dev)) {
                double p_of_agg = 100.0;
                const char *bw_str = "KB";

                if (rs->agg[ddir]) {
                        p_of_agg = mean * 100 / (double) rs->agg[ddir];
                        if (p_of_agg > 100.0)
                                p_of_agg = 100.0;
                }

                if (mean > 999999.9) {
                        min /= 1000.0;
                        max /= 1000.0;
                        mean /= 1000.0;
                        dev /= 1000.0;
                        bw_str = "MB";
                }

                log_info("    bw (%s/s)  : min=%5lu, max=%5lu, per=%3.2f%%,"
                         " avg=%5.02f, stdev=%5.02f\n", bw_str, min, max,
                                                        p_of_agg, mean, dev);
        }
}

static int show_lat(double *io_u_lat, int nr, const char **ranges,
                    const char *msg)
{
        int new_line = 1, i, line = 0, shown = 0;

        for (i = 0; i < nr; i++) {
                if (io_u_lat[i] <= 0.0)
                        continue;
                shown = 1;
                if (new_line) {
                        if (line)
                                log_info("\n");
                        log_info("    lat (%s) : ", msg);
                        new_line = 0;
                        line = 0;
                }
                if (line)
                        log_info(", ");
                log_info("%s%3.2f%%", ranges[i], io_u_lat[i]);
                line++;
                if (line == 5)
                        new_line = 1;
        }

        if (shown)
                log_info("\n");

        return shown;
}

static void show_lat_u(double *io_u_lat_u)
{
        const char *ranges[] = { "2=", "4=", "10=", "20=", "50=", "100=",
                                 "250=", "500=", "750=", "1000=", };

        show_lat(io_u_lat_u, FIO_IO_U_LAT_U_NR, ranges, "usec");
}

static void show_lat_m(double *io_u_lat_m)
{
        const char *ranges[] = { "2=", "4=", "10=", "20=", "50=", "100=",
                                 "250=", "500=", "750=", "1000=", "2000=",
                                 ">=2000=", };

        show_lat(io_u_lat_m, FIO_IO_U_LAT_M_NR, ranges, "msec");
}

static void show_latencies(double *io_u_lat_u, double *io_u_lat_m)
{
        show_lat_u(io_u_lat_u);
        show_lat_m(io_u_lat_m);
}

void show_thread_status(struct thread_stat *ts, struct group_run_stats *rs)
{
        double usr_cpu, sys_cpu;
        unsigned long runtime;
        double io_u_dist[FIO_IO_U_MAP_NR];
        double io_u_lat_u[FIO_IO_U_LAT_U_NR];
        double io_u_lat_m[FIO_IO_U_LAT_M_NR];
        time_t time_p;
        char time_buf[64];

        if (!(ts->io_bytes[0] + ts->io_bytes[1]) &&
            !(ts->total_io_u[0] + ts->total_io_u[1]))
                return;

        time(&time_p);
        ctime_r((const time_t *) &time_p, time_buf);

        if (!ts->error) {
                log_info("%s: (groupid=%d, jobs=%d): err=%2d: pid=%d: %s",
                                        ts->name, ts->groupid, ts->members,
                                        ts->error, (int) ts->pid, time_buf);
        } else {
                log_info("%s: (groupid=%d, jobs=%d): err=%2d (%s): pid=%d: %s",
                                        ts->name, ts->groupid, ts->members,
                                        ts->error, ts->verror, (int) ts->pid,
                                        time_buf);
        }

        if (strlen(ts->description))
                log_info("  Description  : [%s]\n", ts->description);

        if (ts->io_bytes[DDIR_READ])
                show_ddir_status(rs, ts, DDIR_READ);
        if (ts->io_bytes[DDIR_WRITE])
                show_ddir_status(rs, ts, DDIR_WRITE);

        stat_calc_lat_u(ts, io_u_lat_u);
        stat_calc_lat_m(ts, io_u_lat_m);
        show_latencies(io_u_lat_u, io_u_lat_m);

        runtime = ts->total_run_time;
        if (runtime) {
                double runt = (double) runtime;

                usr_cpu = (double) ts->usr_time * 100 / runt;
                sys_cpu = (double) ts->sys_time * 100 / runt;
        } else {
                usr_cpu = 0;
                sys_cpu = 0;
        }

        log_info("  cpu          : usr=%3.2f%%, sys=%3.2f%%, ctx=%lu, majf=%lu,"
                 " minf=%lu\n", usr_cpu, sys_cpu, ts->ctx, ts->majf, ts->minf);

        stat_calc_dist(ts->io_u_map, ts_total_io_u(ts), io_u_dist);
        log_info("  IO depths    : 1=%3.1f%%, 2=%3.1f%%, 4=%3.1f%%, 8=%3.1f%%,"
                 " 16=%3.1f%%, 32=%3.1f%%, >=64=%3.1f%%\n", io_u_dist[0],
                                        io_u_dist[1], io_u_dist[2],
                                        io_u_dist[3], io_u_dist[4],
                                        io_u_dist[5], io_u_dist[6]);

        stat_calc_dist(ts->io_u_submit, ts->total_submit, io_u_dist);
        log_info("     submit    : 0=%3.1f%%, 4=%3.1f%%, 8=%3.1f%%, 16=%3.1f%%,"
                 " 32=%3.1f%%, 64=%3.1f%%, >=64=%3.1f%%\n", io_u_dist[0],
                                        io_u_dist[1], io_u_dist[2],
                                        io_u_dist[3], io_u_dist[4],
                                        io_u_dist[5], io_u_dist[6]);
        stat_calc_dist(ts->io_u_complete, ts->total_complete, io_u_dist);
        log_info("     complete  : 0=%3.1f%%, 4=%3.1f%%, 8=%3.1f%%, 16=%3.1f%%,"
                 " 32=%3.1f%%, 64=%3.1f%%, >=64=%3.1f%%\n", io_u_dist[0],
                                        io_u_dist[1], io_u_dist[2],
                                        io_u_dist[3], io_u_dist[4],
                                        io_u_dist[5], io_u_dist[6]);
        log_info("     issued    : total=r=%lu/w=%lu/d=%lu,"
                                 " short=r=%lu/w=%lu/d=%lu\n",
                                        ts->total_io_u[0], ts->total_io_u[1],
                                        ts->total_io_u[2],
                                        ts->short_io_u[0], ts->short_io_u[1],
                                        ts->short_io_u[2]);
        if (ts->continue_on_error) {
                log_info("     errors    : total=%lu, first_error=%d/<%s>\n",
                                        ts->total_err_count,
                                        ts->first_error,
                                        strerror(ts->first_error));
        }
}

static void show_ddir_status_terse(struct thread_stat *ts,
                                   struct group_run_stats *rs, int ddir)
{
        unsigned long min, max;
        unsigned long long bw, iops;
        unsigned int *ovals = NULL;
        double mean, dev;
        unsigned int len, minv, maxv;
        int i;

        assert(ddir_rw(ddir));

        iops = bw = 0;
        if (ts->runtime[ddir]) {
                uint64_t runt = ts->runtime[ddir];

                bw = ((1000 * ts->io_bytes[ddir]) / runt) / 1024;
                iops = (1000 * (uint64_t) ts->total_io_u[ddir]) / runt;
        }

        log_info(";%llu;%llu;%llu;%llu", ts->io_bytes[ddir] >> 10, bw, iops,
                                                        ts->runtime[ddir]);

        if (calc_lat(&ts->slat_stat[ddir], &min, &max, &mean, &dev))
                log_info(";%lu;%lu;%f;%f", min, max, mean, dev);
        else
                log_info(";%lu;%lu;%f;%f", 0UL, 0UL, 0.0, 0.0);

        if (calc_lat(&ts->clat_stat[ddir], &min, &max, &mean, &dev))
                log_info(";%lu;%lu;%f;%f", min, max, mean, dev);
        else
                log_info(";%lu;%lu;%f;%f", 0UL, 0UL, 0.0, 0.0);

        if (ts->clat_percentiles) {
                len = calc_clat_percentiles(ts->io_u_plat[ddir],
                                        ts->clat_stat[ddir].samples,
                                        ts->percentile_list, &ovals, &maxv,
                                        &minv);
        } else
                len = 0;

        for (i = 0; i < FIO_IO_U_LIST_MAX_LEN; i++) {
                if (i >= len) {
                        log_info(";0%%=0");
                        continue;
                }
                log_info(";%2.2f%%=%u", ts->percentile_list[i].u.f, ovals[i]);
        }

        if (calc_lat(&ts->lat_stat[ddir], &min, &max, &mean, &dev))
                log_info(";%lu;%lu;%f;%f", min, max, mean, dev);
        else
                log_info(";%lu;%lu;%f;%f", 0UL, 0UL, 0.0, 0.0);

        if (ovals)
                free(ovals);

        if (calc_lat(&ts->bw_stat[ddir], &min, &max, &mean, &dev)) {
                double p_of_agg = 100.0;

                if (rs->agg[ddir]) {
                        p_of_agg = mean * 100 / (double) rs->agg[ddir];
                        if (p_of_agg > 100.0)
                                p_of_agg = 100.0;
                }

                log_info(";%lu;%lu;%f%%;%f;%f", min, max, p_of_agg, mean, dev);
        } else
                log_info(";%lu;%lu;%f%%;%f;%f", 0UL, 0UL, 0.0, 0.0, 0.0);
}

static void show_thread_status_terse_v2(struct thread_stat *ts,
                                        struct group_run_stats *rs)
{
        double io_u_dist[FIO_IO_U_MAP_NR];
        double io_u_lat_u[FIO_IO_U_LAT_U_NR];
        double io_u_lat_m[FIO_IO_U_LAT_M_NR];
        double usr_cpu, sys_cpu;
        int i;

        /* General Info */
        log_info("2;%s;%d;%d", ts->name, ts->groupid, ts->error);
        /* Log Read Status */
        show_ddir_status_terse(ts, rs, 0);
        /* Log Write Status */
        show_ddir_status_terse(ts, rs, 1);

        /* CPU Usage */
        if (ts->total_run_time) {
                double runt = (double) ts->total_run_time;

                usr_cpu = (double) ts->usr_time * 100 / runt;
                sys_cpu = (double) ts->sys_time * 100 / runt;
        } else {
                usr_cpu = 0;
                sys_cpu = 0;
        }

        log_info(";%f%%;%f%%;%lu;%lu;%lu", usr_cpu, sys_cpu, ts->ctx, ts->majf,
                                                                ts->minf);

        /* Calc % distribution of IO depths, usecond, msecond latency */
        stat_calc_dist(ts->io_u_map, ts_total_io_u(ts), io_u_dist);
        stat_calc_lat_u(ts, io_u_lat_u);
        stat_calc_lat_m(ts, io_u_lat_m);

        /* Only show fixed 7 I/O depth levels*/
        log_info(";%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%",
                        io_u_dist[0], io_u_dist[1], io_u_dist[2], io_u_dist[3],
                        io_u_dist[4], io_u_dist[5], io_u_dist[6]);

        /* Microsecond latency */
        for (i = 0; i < FIO_IO_U_LAT_U_NR; i++)
                log_info(";%3.2f%%", io_u_lat_u[i]);
        /* Millisecond latency */
        for (i = 0; i < FIO_IO_U_LAT_M_NR; i++)
                log_info(";%3.2f%%", io_u_lat_m[i]);
        /* Additional output if continue_on_error set - default off*/
        if (ts->continue_on_error)
                log_info(";%lu;%d", ts->total_err_count, ts->first_error);
        log_info("\n");

        /* Additional output if description is set */
        if (ts->description)
                log_info(";%s", ts->description);

        log_info("\n");
}

#define FIO_TERSE_VERSION       "3"

static void show_thread_status_terse_v3(struct thread_stat *ts,
                                        struct group_run_stats *rs)
{
        double io_u_dist[FIO_IO_U_MAP_NR];
        double io_u_lat_u[FIO_IO_U_LAT_U_NR];
        double io_u_lat_m[FIO_IO_U_LAT_M_NR];
        double usr_cpu, sys_cpu;
        int i;

        /* General Info */
        log_info("%s;%s;%s;%d;%d", FIO_TERSE_VERSION, fio_version_string,
                                        ts->name, ts->groupid, ts->error);
        /* Log Read Status */
        show_ddir_status_terse(ts, rs, 0);
        /* Log Write Status */
        show_ddir_status_terse(ts, rs, 1);

        /* CPU Usage */
        if (ts->total_run_time) {
                double runt = (double) ts->total_run_time;

                usr_cpu = (double) ts->usr_time * 100 / runt;
                sys_cpu = (double) ts->sys_time * 100 / runt;
        } else {
                usr_cpu = 0;
                sys_cpu = 0;
        }

        log_info(";%f%%;%f%%;%lu;%lu;%lu", usr_cpu, sys_cpu, ts->ctx, ts->majf,
                                                                ts->minf);

        /* Calc % distribution of IO depths, usecond, msecond latency */
        stat_calc_dist(ts->io_u_map, ts_total_io_u(ts), io_u_dist);
        stat_calc_lat_u(ts, io_u_lat_u);
        stat_calc_lat_m(ts, io_u_lat_m);

        /* Only show fixed 7 I/O depth levels*/
        log_info(";%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%;%3.1f%%",
                        io_u_dist[0], io_u_dist[1], io_u_dist[2], io_u_dist[3],
                        io_u_dist[4], io_u_dist[5], io_u_dist[6]);

        /* Microsecond latency */
        for (i = 0; i < FIO_IO_U_LAT_U_NR; i++)
                log_info(";%3.2f%%", io_u_lat_u[i]);
        /* Millisecond latency */
        for (i = 0; i < FIO_IO_U_LAT_M_NR; i++)
                log_info(";%3.2f%%", io_u_lat_m[i]);

        /* disk util stats, if any */
        show_disk_util(1);

        /* Additional output if continue_on_error set - default off*/
        if (ts->continue_on_error)
                log_info(";%lu;%d", ts->total_err_count, ts->first_error);

        /* Additional output if description is set */
        if (strlen(ts->description))
                log_info(";%s", ts->description);

        log_info("\n");
}

static void show_thread_status_terse(struct thread_stat *ts,
                                     struct group_run_stats *rs)
{
        if (terse_version == 2)
                show_thread_status_terse_v2(ts, rs);
        else if (terse_version == 3)
                show_thread_status_terse_v3(ts, rs);
        else
                log_err("fio: bad terse version!? %d\n", terse_version);
}

static void sum_stat(struct io_stat *dst, struct io_stat *src, int nr)
{
        double mean, S;

        if (src->samples == 0)
                return;

        dst->min_val = min(dst->min_val, src->min_val);
        dst->max_val = max(dst->max_val, src->max_val);

        /*
         * Compute new mean and S after the merge
         * <http://en.wikipedia.org/wiki/Algorithms_for_calculating_variance
         *  #Parallel_algorithm>
         */
        if (nr == 1) {
                mean = src->mean.u.f;
                S = src->S.u.f;
        } else {
                double delta = src->mean.u.f - dst->mean.u.f;

                mean = ((src->mean.u.f * src->samples) +
                        (dst->mean.u.f * dst->samples)) /
                        (dst->samples + src->samples);

                S =  src->S.u.f + dst->S.u.f + pow(delta, 2.0) *
                        (dst->samples * src->samples) /
                        (dst->samples + src->samples);
        }

        dst->samples += src->samples;
        dst->mean.u.f = mean;
        dst->S.u.f = S;
}

void sum_group_stats(struct group_run_stats *dst, struct group_run_stats *src)
{
        int i;

        for (i = 0; i < 2; i++) {
                if (dst->max_run[i] < src->max_run[i])
                        dst->max_run[i] = src->max_run[i];
                if (dst->min_run[i] && dst->min_run[i] > src->min_run[i])
                        dst->min_run[i] = src->min_run[i];
                if (dst->max_bw[i] < src->max_bw[i])
                        dst->max_bw[i] = src->max_bw[i];
                if (dst->min_bw[i] && dst->min_bw[i] > src->min_bw[i])
                        dst->min_bw[i] = src->min_bw[i];

                dst->io_kb[i] += src->io_kb[i];
                dst->agg[i] += src->agg[i];
        }

}

void sum_thread_stats(struct thread_stat *dst, struct thread_stat *src, int nr)
{
        int l, k;

        for (l = 0; l <= DDIR_WRITE; l++) {
                sum_stat(&dst->clat_stat[l], &src->clat_stat[l], nr);
                sum_stat(&dst->slat_stat[l], &src->slat_stat[l], nr);
                sum_stat(&dst->lat_stat[l], &src->lat_stat[l], nr);
                sum_stat(&dst->bw_stat[l], &src->bw_stat[l], nr);

                dst->io_bytes[l] += src->io_bytes[l];

                if (dst->runtime[l] < src->runtime[l])
                        dst->runtime[l] = src->runtime[l];
        }

        dst->usr_time += src->usr_time;
        dst->sys_time += src->sys_time;
        dst->ctx += src->ctx;
        dst->majf += src->majf;
        dst->minf += src->minf;

        for (k = 0; k < FIO_IO_U_MAP_NR; k++)
                dst->io_u_map[k] += src->io_u_map[k];
        for (k = 0; k < FIO_IO_U_MAP_NR; k++)
                dst->io_u_submit[k] += src->io_u_submit[k];
        for (k = 0; k < FIO_IO_U_MAP_NR; k++)
                dst->io_u_complete[k] += src->io_u_complete[k];
        for (k = 0; k < FIO_IO_U_LAT_U_NR; k++)
                dst->io_u_lat_u[k] += src->io_u_lat_u[k];
        for (k = 0; k < FIO_IO_U_LAT_M_NR; k++)
                dst->io_u_lat_m[k] += src->io_u_lat_m[k];

        for (k = 0; k <= 2; k++) {
                dst->total_io_u[k] += src->total_io_u[k];
                dst->short_io_u[k] += src->short_io_u[k];
        }

        for (k = 0; k <= DDIR_WRITE; k++) {
                int m;
                for (m = 0; m < FIO_IO_U_PLAT_NR; m++)
                        dst->io_u_plat[k][m] += src->io_u_plat[k][m];
        }

        dst->total_run_time += src->total_run_time;
        dst->total_submit += src->total_submit;
        dst->total_complete += src->total_complete;
}

void init_group_run_stat(struct group_run_stats *gs)
{
        memset(gs, 0, sizeof(*gs));
        gs->min_bw[0] = gs->min_run[0] = ~0UL;
        gs->min_bw[1] = gs->min_run[1] = ~0UL;
}

void init_thread_stat(struct thread_stat *ts)
{
        int j;

        memset(ts, 0, sizeof(*ts));

        for (j = 0; j <= DDIR_WRITE; j++) {
                ts->lat_stat[j].min_val = -1UL;
                ts->clat_stat[j].min_val = -1UL;
                ts->slat_stat[j].min_val = -1UL;
                ts->bw_stat[j].min_val = -1UL;
        }
        ts->groupid = -1;
}

void show_run_stats(void)
{
        struct group_run_stats *runstats, *rs;
        struct thread_data *td;
        struct thread_stat *threadstats, *ts;
        int i, j, nr_ts, last_ts, idx;
        int kb_base_warned = 0;

        runstats = malloc(sizeof(struct group_run_stats) * (groupid + 1));

        for (i = 0; i < groupid + 1; i++)
                init_group_run_stat(&runstats[i]);

        /*
         * find out how many threads stats we need. if group reporting isn't
         * enabled, it's one-per-td.
         */
        nr_ts = 0;
        last_ts = -1;
        for_each_td(td, i) {
                if (!td->o.group_reporting) {
                        nr_ts++;
                        continue;
                }
                if (last_ts == td->groupid)
                        continue;

                last_ts = td->groupid;
                nr_ts++;
        }

        threadstats = malloc(nr_ts * sizeof(struct thread_stat));

        for (i = 0; i < nr_ts; i++)
                init_thread_stat(&threadstats[i]);

        j = 0;
        last_ts = -1;
        idx = 0;
        for_each_td(td, i) {
                if (idx && (!td->o.group_reporting ||
                    (td->o.group_reporting && last_ts != td->groupid))) {
                        idx = 0;
                        j++;
                }

                last_ts = td->groupid;

                ts = &threadstats[j];

                ts->clat_percentiles = td->o.clat_percentiles;
                if (td->o.overwrite_plist)
                        memcpy(ts->percentile_list, td->o.percentile_list, sizeof(td->o.percentile_list));
                else
                        memcpy(ts->percentile_list, def_percentile_list, sizeof(def_percentile_list));

                idx++;
                ts->members++;

                if (ts->groupid == -1) {
                        /*
                         * These are per-group shared already
                         */
                        strncpy(ts->name, td->o.name, FIO_JOBNAME_SIZE);
                        if (td->o.description)
                                strncpy(ts->description, td->o.description,
                                                FIO_JOBNAME_SIZE);
                        else
                                memset(ts->description, 0, FIO_JOBNAME_SIZE);

                        ts->groupid = td->groupid;

                        /*
                         * first pid in group, not very useful...
                         */
                        ts->pid = td->pid;

                        ts->kb_base = td->o.kb_base;
                } else if (ts->kb_base != td->o.kb_base && !kb_base_warned) {
                        log_info("fio: kb_base differs for jobs in group, using"
                                 " %u as the base\n", ts->kb_base);
                        kb_base_warned = 1;
                }

                ts->continue_on_error = td->o.continue_on_error;
                ts->total_err_count += td->total_err_count;
                ts->first_error = td->first_error;
                if (!ts->error) {
                        if (!td->error && td->o.continue_on_error &&
                            td->first_error) {
                                ts->error = td->first_error;
                                strcpy(ts->verror, td->verror);
                        } else  if (td->error) {
                                ts->error = td->error;
                                strcpy(ts->verror, td->verror);
                        }
                }

                sum_thread_stats(ts, &td->ts, idx);
        }

        for (i = 0; i < nr_ts; i++) {
                unsigned long long bw;

                ts = &threadstats[i];
                rs = &runstats[ts->groupid];
                rs->kb_base = ts->kb_base;

                for (j = 0; j <= DDIR_WRITE; j++) {
                        if (!ts->runtime[j])
                                continue;
                        if (ts->runtime[j] < rs->min_run[j] || !rs->min_run[j])
                                rs->min_run[j] = ts->runtime[j];
                        if (ts->runtime[j] > rs->max_run[j])
                                rs->max_run[j] = ts->runtime[j];

                        bw = 0;
                        if (ts->runtime[j]) {
                                unsigned long runt = ts->runtime[j];
                                unsigned long long kb;

                                kb = ts->io_bytes[j] / rs->kb_base;
                                bw = kb * 1000 / runt;
                        }
                        if (bw < rs->min_bw[j])
                                rs->min_bw[j] = bw;
                        if (bw > rs->max_bw[j])
                                rs->max_bw[j] = bw;

                        rs->io_kb[j] += ts->io_bytes[j] / rs->kb_base;
                }
        }

        for (i = 0; i < groupid + 1; i++) {
                rs = &runstats[i];

                if (rs->max_run[0])
                        rs->agg[0] = (rs->io_kb[0] * 1000) / rs->max_run[0];
                if (rs->max_run[1])
                        rs->agg[1] = (rs->io_kb[1] * 1000) / rs->max_run[1];
        }

        /*
         * don't overwrite last signal output
         */
        if (!terse_output)
                log_info("\n");

        for (i = 0; i < nr_ts; i++) {
                ts = &threadstats[i];
                rs = &runstats[ts->groupid];

                if (is_backend)
                        fio_server_send_ts(ts, rs);
                else if (terse_output)
                        show_thread_status_terse(ts, rs);
                else
                        show_thread_status(ts, rs);
        }

        for (i = 0; i < groupid + 1; i++) {
                rs = &runstats[i];

                rs->groupid = i;
                if (is_backend)
                        fio_server_send_gs(rs);
                else if (!terse_output)
                        show_group_stats(rs);
        }

        if (is_backend)
                fio_server_send_du();
        else if (!terse_output)
                show_disk_util(0);

        free(runstats);
        free(threadstats);
}

static void *__show_running_run_stats(void *arg)
{
        struct thread_data *td;
        unsigned long long *rt;
        struct timeval tv;
        int i;

        rt = malloc(thread_number * sizeof(unsigned long long));
        fio_gettime(&tv, NULL);

        for_each_td(td, i) {
                rt[i] = mtime_since(&td->start, &tv);
                if (td_read(td) && td->io_bytes[DDIR_READ])
                        td->ts.runtime[DDIR_READ] += rt[i];
                if (td_write(td) && td->io_bytes[DDIR_WRITE])
                        td->ts.runtime[DDIR_WRITE] += rt[i];

                update_rusage_stat(td);
                td->ts.io_bytes[0] = td->io_bytes[0];
                td->ts.io_bytes[1] = td->io_bytes[1];
                td->ts.total_run_time = mtime_since(&td->epoch, &tv);
        }

        show_run_stats();

        for_each_td(td, i) {
                if (td_read(td) && td->io_bytes[DDIR_READ])
                        td->ts.runtime[DDIR_READ] -= rt[i];
                if (td_write(td) && td->io_bytes[DDIR_WRITE])
                        td->ts.runtime[DDIR_WRITE] -= rt[i];
        }

        free(rt);
        return NULL;
}

/*
 * Called from signal handler. It _should_ be safe to just run this inline
 * in the sig handler, but we should be disturbing the system less by just
 * creating a thread to do it.
 */
void show_running_run_stats(void)
{
        pthread_t thread;

        pthread_create(&thread, NULL, __show_running_run_stats, NULL);
        pthread_detach(thread);
}

static inline void add_stat_sample(struct io_stat *is, unsigned long data)
{
        double val = data;
        double delta;

        if (data > is->max_val)
                is->max_val = data;
        if (data < is->min_val)
                is->min_val = data;

        delta = val - is->mean.u.f;
        if (delta) {
                is->mean.u.f += delta / (is->samples + 1.0);
                is->S.u.f += delta * (val - is->mean.u.f);
        }

        is->samples++;
}

static void __add_log_sample(struct io_log *iolog, unsigned long val,
                             enum fio_ddir ddir, unsigned int bs,
                             unsigned long t)
{
        const int nr_samples = iolog->nr_samples;

        if (!iolog->nr_samples)
                iolog->avg_last = t;

        if (iolog->nr_samples == iolog->max_samples) {
                int new_size = sizeof(struct io_sample) * iolog->max_samples*2;

                iolog->log = realloc(iolog->log, new_size);
                iolog->max_samples <<= 1;
        }

        iolog->log[nr_samples].val = val;
        iolog->log[nr_samples].time = t;
        iolog->log[nr_samples].ddir = ddir;
        iolog->log[nr_samples].bs = bs;
        iolog->nr_samples++;
}

static inline void reset_io_stat(struct io_stat *ios)
{
        ios->max_val = ios->min_val = ios->samples = 0;
        ios->mean.u.f = ios->S.u.f = 0;
}

static void add_log_sample(struct thread_data *td, struct io_log *iolog,
                           unsigned long val, enum fio_ddir ddir,
                           unsigned int bs)
{
        unsigned long elapsed, this_window;

        if (!ddir_rw(ddir))
                return;

        elapsed = mtime_since_now(&td->epoch);

        /*
         * If no time averaging, just add the log sample.
         */
        if (!iolog->avg_msec) {
                __add_log_sample(iolog, val, ddir, bs, elapsed);
                return;
        }

        /*
         * Add the sample. If the time period has passed, then
         * add that entry to the log and clear.
         */
        add_stat_sample(&iolog->avg_window[ddir], val);

        /*
         * If period hasn't passed, adding the above sample is all we
         * need to do.
         */
        this_window = elapsed - iolog->avg_last;
        if (this_window < iolog->avg_msec)
                return;

        /*
         * Note an entry in the log. Use the mean from the logged samples,
         * making sure to properly round up. Only write a log entry if we
         * had actual samples done.
         */
        if (iolog->avg_window[DDIR_READ].samples) {
                unsigned long mr;

                mr = iolog->avg_window[DDIR_READ].mean.u.f + 0.50;
                __add_log_sample(iolog, mr, DDIR_READ, 0, elapsed);
        }
        if (iolog->avg_window[DDIR_WRITE].samples) {
                unsigned long mw;

                mw = iolog->avg_window[DDIR_WRITE].mean.u.f + 0.50;
                __add_log_sample(iolog, mw, DDIR_WRITE, 0, elapsed);
        }

        reset_io_stat(&iolog->avg_window[DDIR_READ]);
        reset_io_stat(&iolog->avg_window[DDIR_WRITE]);
        iolog->avg_last = elapsed;
}

void add_agg_sample(unsigned long val, enum fio_ddir ddir, unsigned int bs)
{
        struct io_log *iolog;

        if (!ddir_rw(ddir))
                return;

        iolog = agg_io_log[ddir];
        __add_log_sample(iolog, val, ddir, bs, mtime_since_genesis());
}

static void add_clat_percentile_sample(struct thread_stat *ts,
                                unsigned long usec, enum fio_ddir ddir)
{
        unsigned int idx = plat_val_to_idx(usec);
        assert(idx < FIO_IO_U_PLAT_NR);

        ts->io_u_plat[ddir][idx]++;
}

void add_clat_sample(struct thread_data *td, enum fio_ddir ddir,
                     unsigned long usec, unsigned int bs)
{
        struct thread_stat *ts = &td->ts;

        if (!ddir_rw(ddir))
                return;

        add_stat_sample(&ts->clat_stat[ddir], usec);

        if (td->clat_log)
                add_log_sample(td, td->clat_log, usec, ddir, bs);

        if (ts->clat_percentiles)
                add_clat_percentile_sample(ts, usec, ddir);
}

void add_slat_sample(struct thread_data *td, enum fio_ddir ddir,
                     unsigned long usec, unsigned int bs)
{
        struct thread_stat *ts = &td->ts;

        if (!ddir_rw(ddir))
                return;

        add_stat_sample(&ts->slat_stat[ddir], usec);

        if (td->slat_log)
                add_log_sample(td, td->slat_log, usec, ddir, bs);
}

void add_lat_sample(struct thread_data *td, enum fio_ddir ddir,
                    unsigned long usec, unsigned int bs)
{
        struct thread_stat *ts = &td->ts;

        if (!ddir_rw(ddir))
                return;

        add_stat_sample(&ts->lat_stat[ddir], usec);

        if (td->lat_log)
                add_log_sample(td, td->lat_log, usec, ddir, bs);
}

void add_bw_sample(struct thread_data *td, enum fio_ddir ddir, unsigned int bs,
                   struct timeval *t)
{
        struct thread_stat *ts = &td->ts;
        unsigned long spent, rate;

        if (!ddir_rw(ddir))
                return;

        spent = mtime_since(&td->bw_sample_time, t);
        if (spent < td->o.bw_avg_time)
                return;

        /*
         * Compute both read and write rates for the interval.
         */
        for (ddir = DDIR_READ; ddir <= DDIR_WRITE; ddir++) {
                uint64_t delta;

                delta = td->this_io_bytes[ddir] - td->stat_io_bytes[ddir];
                if (!delta)
                        continue; /* No entries for interval */

                rate = delta * 1000 / spent / 1024;
                add_stat_sample(&ts->bw_stat[ddir], rate);

                if (td->bw_log)
                        add_log_sample(td, td->bw_log, rate, ddir, bs);

                td->stat_io_bytes[ddir] = td->this_io_bytes[ddir];
        }

        fio_gettime(&td->bw_sample_time, NULL);
}

void add_iops_sample(struct thread_data *td, enum fio_ddir ddir,
                     struct timeval *t)
{
        struct thread_stat *ts = &td->ts;
        unsigned long spent, iops;

        if (!ddir_rw(ddir))
                return;

        spent = mtime_since(&td->iops_sample_time, t);
        if (spent < td->o.iops_avg_time)
                return;

        /*
         * Compute both read and write rates for the interval.
         */
        for (ddir = DDIR_READ; ddir <= DDIR_WRITE; ddir++) {
                uint64_t delta;

                delta = td->this_io_blocks[ddir] - td->stat_io_blocks[ddir];
                if (!delta)
                        continue; /* No entries for interval */

                iops = (delta * 1000) / spent;
                add_stat_sample(&ts->iops_stat[ddir], iops);

                if (td->iops_log)
                        add_log_sample(td, td->iops_log, iops, ddir, 0);

                td->stat_io_blocks[ddir] = td->this_io_blocks[ddir];
        }

        fio_gettime(&td->iops_sample_time, NULL);
}