X-Git-Url: https://git.kernel.dk/?p=fio.git;a=blobdiff_plain;f=steadystate.c;h=ad19318c2a23f50cda50f6aef7927e4f0adde022;hp=f5d804624d1ccca86ffebdc4254236e1542cad36;hb=HEAD;hpb=ec55e631a976779b94dc22f5ea5b229890bd5a6c diff --git a/steadystate.c b/steadystate.c index f5d80462..3e3683f3 100644 --- a/steadystate.c +++ b/steadystate.c @@ -2,25 +2,32 @@ #include "fio.h" #include "steadystate.h" -#include "helper_thread.h" bool steadystate_enabled = false; +unsigned int ss_check_interval = 1000; + +void steadystate_free(struct thread_data *td) +{ + free(td->ss.iops_data); + free(td->ss.bw_data); + td->ss.iops_data = NULL; + td->ss.bw_data = NULL; +} static void steadystate_alloc(struct thread_data *td) { - int i; + int intervals = td->ss.dur / (ss_check_interval / 1000L); - td->ss.bw_data = malloc(td->ss.dur * sizeof(unsigned long)); - td->ss.iops_data = malloc(td->ss.dur * sizeof(unsigned long)); - /* initialize so that it is obvious if the cache is not full in the output */ - for (i = 0; i < td->ss.dur; i++) - td->ss.iops_data[i] = td->ss.bw_data[i] = 0; + td->ss.bw_data = calloc(intervals, sizeof(uint64_t)); + td->ss.iops_data = calloc(intervals, sizeof(uint64_t)); + + td->ss.state |= FIO_SS_DATA; } void steadystate_setup(void) { - int i, prev_groupid; - struct thread_data *td, *prev_td; + struct thread_data *prev_td; + int prev_groupid; if (!steadystate_enabled) return; @@ -32,8 +39,8 @@ void steadystate_setup(void) */ prev_groupid = -1; prev_td = NULL; - for_each_td(td, i) { - if (td->ts.ss == NULL) + for_each_td(td) { + if (!td->ss.dur) continue; if (!td->o.group_reporting) { @@ -42,59 +49,56 @@ void steadystate_setup(void) } if (prev_groupid != td->groupid) { - if (prev_td != NULL) { - prev_td->ss.state |= __FIO_SS_DATA; + if (prev_td) steadystate_alloc(prev_td); - } prev_groupid = td->groupid; } prev_td = td; - } + } end_for_each(); - if (prev_td != NULL && prev_td->o.group_reporting) { - prev_td->ss.state |= __FIO_SS_DATA; + if (prev_td && prev_td->o.group_reporting) steadystate_alloc(prev_td); - } } -static bool steadystate_slope(unsigned long iops, unsigned long bw, +static bool steadystate_slope(uint64_t iops, uint64_t bw, struct thread_data *td) { int i, j; double result; struct steadystate_data *ss = &td->ss; - unsigned long new_val; + uint64_t new_val; + int intervals = ss->dur / (ss_check_interval / 1000L); ss->bw_data[ss->tail] = bw; ss->iops_data[ss->tail] = iops; - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_IOPS) new_val = iops; else new_val = bw; - if (ss->tail < ss->head || (ss->tail - ss->head == ss->dur - 1)) { - if (ss->sum_y == 0) { /* first time through */ - for(i = 0; i < ss->dur; i++) { - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_BUFFER_FULL || ss->tail - ss->head == intervals - 1) { + if (!(ss->state & FIO_SS_BUFFER_FULL)) { + /* first time through */ + for (i = 0, ss->sum_y = 0; i < intervals; i++) { + if (ss->state & FIO_SS_IOPS) ss->sum_y += ss->iops_data[i]; else ss->sum_y += ss->bw_data[i]; - j = ss->head + i; - if (j >= ss->dur) - j -= ss->dur; - if (ss->state & __FIO_SS_IOPS) + j = (ss->head + i) % intervals; + if (ss->state & FIO_SS_IOPS) ss->sum_xy += i * ss->iops_data[j]; else ss->sum_xy += i * ss->bw_data[j]; } + ss->state |= FIO_SS_BUFFER_FULL; } else { /* easy to update the sums */ ss->sum_y -= ss->oldest_y; ss->sum_y += new_val; - ss->sum_xy = ss->sum_xy - ss->sum_y + ss->dur * new_val; + ss->sum_xy = ss->sum_xy - ss->sum_y + intervals * new_val; } - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_IOPS) ss->oldest_y = ss->iops_data[ss->head]; else ss->oldest_y = ss->bw_data[ss->head]; @@ -105,31 +109,32 @@ static bool steadystate_slope(unsigned long iops, unsigned long bw, * equally spaced when they are often off by a few milliseconds. * This assumption greatly simplifies the calculations. */ - ss->slope = (ss->sum_xy - (double) ss->sum_x * ss->sum_y / ss->dur) / - (ss->sum_x_sq - (double) ss->sum_x * ss->sum_x / ss->dur); - if (ss->pct) - ss->criterion = 100.0 * ss->slope / (ss->sum_y / ss->dur); + ss->slope = (ss->sum_xy - (double) ss->sum_x * ss->sum_y / intervals) / + (ss->sum_x_sq - (double) ss->sum_x * ss->sum_x / intervals); + if (ss->state & FIO_SS_PCT) + ss->criterion = 100.0 * ss->slope / (ss->sum_y / intervals); else ss->criterion = ss->slope; dprint(FD_STEADYSTATE, "sum_y: %llu, sum_xy: %llu, slope: %f, " "criterion: %f, limit: %f\n", - ss->sum_y, ss->sum_xy, ss->slope, - ss->criterion, ss->limit); + (unsigned long long) ss->sum_y, + (unsigned long long) ss->sum_xy, + ss->slope, ss->criterion, ss->limit); result = ss->criterion * (ss->criterion < 0.0 ? -1.0 : 1.0); if (result < ss->limit) return true; } - ss->tail = (ss->tail + 1) % ss->dur; + ss->tail = (ss->tail + 1) % intervals; if (ss->tail <= ss->head) - ss->head = (ss->head + 1) % ss->dur; + ss->head = (ss->head + 1) % intervals; return false; } -static bool steadystate_deviation(unsigned long iops, unsigned long bw, +static bool steadystate_deviation(uint64_t iops, uint64_t bw, struct thread_data *td) { int i; @@ -137,79 +142,84 @@ static bool steadystate_deviation(unsigned long iops, unsigned long bw, double mean; struct steadystate_data *ss = &td->ss; + int intervals = ss->dur / (ss_check_interval / 1000L); ss->bw_data[ss->tail] = bw; ss->iops_data[ss->tail] = iops; - if (ss->tail < ss->head || (ss->tail - ss->head == ss->dur - 1)) { - if (ss->sum_y == 0) { /* first time through */ - for(i = 0; i < ss->dur; i++) - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_BUFFER_FULL || ss->tail - ss->head == intervals - 1) { + if (!(ss->state & FIO_SS_BUFFER_FULL)) { + /* first time through */ + for (i = 0, ss->sum_y = 0; i < intervals; i++) { + if (ss->state & FIO_SS_IOPS) ss->sum_y += ss->iops_data[i]; else ss->sum_y += ss->bw_data[i]; + } + ss->state |= FIO_SS_BUFFER_FULL; } else { /* easy to update the sum */ ss->sum_y -= ss->oldest_y; - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_IOPS) ss->sum_y += ss->iops_data[ss->tail]; else ss->sum_y += ss->bw_data[ss->tail]; } - if (ss->state & __FIO_SS_IOPS) + if (ss->state & FIO_SS_IOPS) ss->oldest_y = ss->iops_data[ss->head]; else ss->oldest_y = ss->bw_data[ss->head]; - mean = (double) ss->sum_y / ss->dur; + mean = (double) ss->sum_y / intervals; ss->deviation = 0.0; - for (i = 0; i < ss->dur; i++) { - if (ss->state & __FIO_SS_IOPS) + for (i = 0; i < intervals; i++) { + if (ss->state & FIO_SS_IOPS) diff = ss->iops_data[i] - mean; else diff = ss->bw_data[i] - mean; ss->deviation = max(ss->deviation, diff * (diff < 0.0 ? -1.0 : 1.0)); } - if (ss->pct) + if (ss->state & FIO_SS_PCT) ss->criterion = 100.0 * ss->deviation / mean; else ss->criterion = ss->deviation; - dprint(FD_STEADYSTATE, "sum_y: %llu, mean: %f, max diff: %f, " + dprint(FD_STEADYSTATE, "intervals: %d, sum_y: %llu, mean: %f, max diff: %f, " "objective: %f, limit: %f\n", - ss->sum_y, mean, ss->deviation, - ss->criterion, ss->limit); + intervals, + (unsigned long long) ss->sum_y, mean, + ss->deviation, ss->criterion, ss->limit); if (ss->criterion < ss->limit) return true; } - ss->tail = (ss->tail + 1) % ss->dur; - if (ss->tail <= ss->head) - ss->head = (ss->head + 1) % ss->dur; + ss->tail = (ss->tail + 1) % intervals; + if (ss->tail == ss->head) + ss->head = (ss->head + 1) % intervals; return false; } -void steadystate_check(void) +int steadystate_check(void) { - int i, j, ddir, prev_groupid, group_ramp_time_over = 0; + int ddir, prev_groupid, group_ramp_time_over = 0; unsigned long rate_time; - struct thread_data *td, *td2; - struct timeval now; - unsigned long group_bw = 0, group_iops = 0; - unsigned long long td_iops; - unsigned long long td_bytes; + struct timespec now; + uint64_t group_bw = 0, group_iops = 0; + uint64_t td_iops, td_bytes; bool ret; prev_groupid = -1; - for_each_td(td, i) { + for_each_td(td) { + const bool needs_lock = td_async_processing(td); struct steadystate_data *ss = &td->ss; if (!ss->dur || td->runstate <= TD_SETTING_UP || - td->runstate >= TD_EXITED || (ss->state & __FIO_SS_ATTAINED)) + td->runstate >= TD_EXITED || !ss->state || + ss->state & FIO_SS_ATTAINED) continue; td_iops = 0; @@ -223,41 +233,40 @@ void steadystate_check(void) prev_groupid = td->groupid; fio_gettime(&now, NULL); - if (ss->ramp_time && !(ss->state & __FIO_SS_RAMP_OVER)) { + if (ss->ramp_time && !(ss->state & FIO_SS_RAMP_OVER)) { /* - * Begin recording data one second after ss->ramp_time + * Begin recording data one check interval after ss->ramp_time * has elapsed */ - if (utime_since(&td->epoch, &now) >= (ss->ramp_time + 1000000L)) - ss->state |= __FIO_SS_RAMP_OVER; + if (utime_since(&td->epoch, &now) >= (ss->ramp_time + ss_check_interval * 1000L)) + ss->state |= FIO_SS_RAMP_OVER; } - td_io_u_lock(td); - for (ddir = DDIR_READ; ddir < DDIR_RWDIR_CNT; ddir++) { + if (needs_lock) + __td_io_u_lock(td); + + for (ddir = 0; ddir < DDIR_RWDIR_CNT; ddir++) { td_iops += td->io_blocks[ddir]; td_bytes += td->io_bytes[ddir]; } - td_io_u_unlock(td); + + if (needs_lock) + __td_io_u_unlock(td); rate_time = mtime_since(&ss->prev_time, &now); memcpy(&ss->prev_time, &now, sizeof(now)); - /* - * Begin monitoring when job starts but don't actually use - * data in checking stopping criterion until ss->ramp_time is - * over. This ensures that we will have a sane value in - * prev_iops/bw the first time through after ss->ramp_time - * is done. - */ - if (ss->state & __FIO_SS_RAMP_OVER) { - group_bw += 1000 * (td_bytes - ss->prev_bytes) / rate_time; - group_iops += 1000 * (td_iops - ss->prev_iops) / rate_time; + if (ss->state & FIO_SS_RAMP_OVER) { + group_bw += rate_time * (td_bytes - ss->prev_bytes) / + (ss_check_interval * ss_check_interval / 1000L); + group_iops += rate_time * (td_iops - ss->prev_iops) / + (ss_check_interval * ss_check_interval / 1000L); ++group_ramp_time_over; } ss->prev_iops = td_iops; ss->prev_bytes = td_bytes; - if (td->o.group_reporting && !(ss->state & __FIO_SS_DATA)) + if (td->o.group_reporting && !(ss->state & FIO_SS_DATA)) continue; /* @@ -269,37 +278,39 @@ void steadystate_check(void) dprint(FD_STEADYSTATE, "steadystate_check() thread: %d, " "groupid: %u, rate_msec: %ld, " - "iops: %lu, bw: %lu, head: %d, tail: %d\n", - i, td->groupid, rate_time, group_iops, - group_bw, ss->head, ss->tail); + "iops: %llu, bw: %llu, head: %d, tail: %d\n", + __td_index, td->groupid, rate_time, + (unsigned long long) group_iops, + (unsigned long long) group_bw, + ss->head, ss->tail); - if (td->o.ss & __FIO_SS_SLOPE) + if (ss->state & FIO_SS_SLOPE) ret = steadystate_slope(group_iops, group_bw, td); else ret = steadystate_deviation(group_iops, group_bw, td); if (ret) { if (td->o.group_reporting) { - for_each_td(td2, j) { + for_each_td(td2) { if (td2->groupid == td->groupid) { - td2->ss.state |= __FIO_SS_ATTAINED; + td2->ss.state |= FIO_SS_ATTAINED; fio_mark_td_terminate(td2); } - } + } end_for_each(); } else { - ss->state |= __FIO_SS_ATTAINED; + ss->state |= FIO_SS_ATTAINED; fio_mark_td_terminate(td); } } - } + } end_for_each(); + return 0; } int td_steadystate_init(struct thread_data *td) { struct steadystate_data *ss = &td->ss; struct thread_options *o = &td->o; - struct thread_data *td2; - int j; + int intervals; memset(ss, 0, sizeof(*ss)); @@ -311,27 +322,25 @@ int td_steadystate_init(struct thread_data *td) ss->dur = o->ss_dur; ss->limit = o->ss_limit.u.f; ss->ramp_time = o->ss_ramp_time; - ss->pct = o->ss_pct; + ss_check_interval = o->ss_check_interval / 1000L; - ss->state = o->ss; + ss->state = o->ss_state; if (!td->ss.ramp_time) - ss->state |= __FIO_SS_RAMP_OVER; + ss->state |= FIO_SS_RAMP_OVER; - ss->sum_x = o->ss_dur * (o->ss_dur - 1) / 2; - ss->sum_x_sq = (o->ss_dur - 1) * (o->ss_dur) * (2*o->ss_dur - 1) / 6; - - td->ts.ss = ss; + intervals = ss->dur / (ss_check_interval / 1000L); + ss->sum_x = intervals * (intervals - 1) / 2; + ss->sum_x_sq = (intervals - 1) * (intervals) * (2*intervals - 1) / 6; } /* make sure that ss options are consistent within reporting group */ - for_each_td(td2, j) { + for_each_td(td2) { if (td2->groupid == td->groupid) { struct steadystate_data *ss2 = &td2->ss; if (ss2->dur != ss->dur || ss2->limit != ss->limit || ss2->ramp_time != ss->ramp_time || - ss2->pct != ss->pct || ss2->state != ss->state || ss2->sum_x != ss->sum_x || ss2->sum_x_sq != ss->sum_x_sq) { @@ -339,7 +348,37 @@ int td_steadystate_init(struct thread_data *td) return 1; } } - } + } end_for_each(); return 0; } + +uint64_t steadystate_bw_mean(struct thread_stat *ts) +{ + int i; + uint64_t sum; + int intervals = ts->ss_dur / (ss_check_interval / 1000L); + + if (!ts->ss_dur) + return 0; + + for (i = 0, sum = 0; i < intervals; i++) + sum += ts->ss_bw_data[i]; + + return sum / intervals; +} + +uint64_t steadystate_iops_mean(struct thread_stat *ts) +{ + int i; + uint64_t sum; + int intervals = ts->ss_dur / (ss_check_interval / 1000L); + + if (!ts->ss_dur) + return 0; + + for (i = 0, sum = 0; i < intervals; i++) + sum += ts->ss_iops_data[i]; + + return sum / intervals; +}