[fio.git] / fio.c

/*
 * fio - the flexible io tester
 *
 * Copyright (C) 2005 Jens Axboe <axboe@suse.de>
 * Copyright (C) 2006 Jens Axboe <axboe@kernel.dk>
 *
 *  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 even 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., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 *
 */
#include <unistd.h>
#include <fcntl.h>
#include <string.h>
#include <signal.h>
#include <time.h>
#include <assert.h>
#include <sys/stat.h>
#include <sys/wait.h>
#include <sys/ipc.h>
#include <sys/shm.h>
#include <sys/ioctl.h>
#include <sys/mman.h>

#include "fio.h"
#include "os.h"

#define MASK    (4095)

#define ALIGN(buf)      (char *) (((unsigned long) (buf) + MASK) & ~(MASK))

int groupid = 0;
int thread_number = 0;
static char run_str[MAX_JOBS + 1];
int shm_id = 0;
static struct timeval genesis;
static int temp_stall_ts;

static void print_thread_status(void);

extern unsigned long long mlock_size;

/*
 * Thread life cycle. Once a thread has a runstate beyond TD_INITIALIZED, it
 * will never back again. It may cycle between running/verififying/fsyncing.
 * Once the thread reaches TD_EXITED, it is just waiting for the core to
 * reap it.
 */
enum {
        TD_NOT_CREATED = 0,
        TD_CREATED,
        TD_INITIALIZED,
        TD_RUNNING,
        TD_VERIFYING,
        TD_FSYNCING,
        TD_EXITED,
        TD_REAPED,
};

#define should_fsync(td)        ((td_write(td) || td_rw(td)) && (!(td)->odirect || (td)->override_sync))

static volatile int startup_sem;

#define TERMINATE_ALL           (-1)
#define JOB_START_TIMEOUT       (5 * 1000)

static void terminate_threads(int group_id)
{
        int i;

        for (i = 0; i < thread_number; i++) {
                struct thread_data *td = &threads[i];

                if (group_id == TERMINATE_ALL || groupid == td->groupid) {
                        td->terminate = 1;
                        td->start_delay = 0;
                }
        }
}

static void sig_handler(int sig)
{
        switch (sig) {
                case SIGALRM:
                        update_io_ticks();
                        disk_util_timer_arm();
                        print_thread_status();
                        break;
                default:
                        printf("\nfio: terminating on signal\n");
                        fflush(stdout);
                        terminate_threads(TERMINATE_ALL);
                        break;
        }
}

/*
 * The ->file_map[] contains a map of blocks we have or have not done io
 * to yet. Used to make sure we cover the entire range in a fair fashion.
 */
static int random_map_free(struct thread_data *td, unsigned long long block)
{
        unsigned int idx = RAND_MAP_IDX(td, block);
        unsigned int bit = RAND_MAP_BIT(td, block);

        return (td->file_map[idx] & (1UL << bit)) == 0;
}

/*
 * Return the next free block in the map.
 */
static int get_next_free_block(struct thread_data *td, unsigned long long *b)
{
        int i;

        *b = 0;
        i = 0;
        while ((*b) * td->min_bs < td->io_size) {
                if (td->file_map[i] != -1UL) {
                        *b += ffz(td->file_map[i]);
                        return 0;
                }

                *b += BLOCKS_PER_MAP;
                i++;
        }

        return 1;
}

/*
 * Mark a given offset as used in the map.
 */
static void mark_random_map(struct thread_data *td, struct io_u *io_u)
{
        unsigned long long block = io_u->offset / (unsigned long long) td->min_bs;
        unsigned int blocks = 0;

        while (blocks < (io_u->buflen / td->min_bs)) {
                unsigned int idx, bit;

                if (!random_map_free(td, block))
                        break;

                idx = RAND_MAP_IDX(td, block);
                bit = RAND_MAP_BIT(td, block);

                assert(idx < td->num_maps);

                td->file_map[idx] |= (1UL << bit);
                block++;
                blocks++;
        }

        if ((blocks * td->min_bs) < io_u->buflen)
                io_u->buflen = blocks * td->min_bs;
}

/*
 * For random io, generate a random new block and see if it's used. Repeat
 * until we find a free one. For sequential io, just return the end of
 * the last io issued.
 */
static int get_next_offset(struct thread_data *td, unsigned long long *offset)
{
        unsigned long long b, rb;
        long r;

        if (!td->sequential) {
                unsigned long long max_blocks = td->io_size / td->min_bs;
                int loops = 50;

                do {
                        r = os_random_long(&td->random_state);
                        b = ((max_blocks - 1) * r / (unsigned long long) (RAND_MAX+1.0));
                        rb = b + (td->file_offset / td->min_bs);
                        loops--;
                } while (!random_map_free(td, rb) && loops);

                if (!loops) {
                        if (get_next_free_block(td, &b))
                                return 1;
                }
        } else
                b = td->last_pos / td->min_bs;

        *offset = (b * td->min_bs) + td->file_offset;
        if (*offset > td->real_file_size)
                return 1;

        return 0;
}

static unsigned int get_next_buflen(struct thread_data *td)
{
        unsigned int buflen;
        long r;

        if (td->min_bs == td->max_bs)
                buflen = td->min_bs;
        else {
                r = os_random_long(&td->bsrange_state);
                buflen = (1 + (double) (td->max_bs - 1) * r / (RAND_MAX + 1.0));
                buflen = (buflen + td->min_bs - 1) & ~(td->min_bs - 1);
        }

        if (buflen > td->io_size - td->this_io_bytes[td->ddir])
                buflen = td->io_size - td->this_io_bytes[td->ddir];

        return buflen;
}

/*
 * Check if we are above the minimum rate given.
 */
static int check_min_rate(struct thread_data *td, struct timeval *now)
{
        unsigned long spent;
        unsigned long rate;
        int ddir = td->ddir;

        /*
         * allow a 2 second settle period in the beginning
         */
        if (mtime_since(&td->start, now) < 2000)
                return 0;

        /*
         * if rate blocks is set, sample is running
         */
        if (td->rate_bytes) {
                spent = mtime_since(&td->lastrate, now);
                if (spent < td->ratecycle)
                        return 0;

                rate = (td->this_io_bytes[ddir] - td->rate_bytes) / spent;
                if (rate < td->ratemin) {
                        fprintf(f_out, "%s: min rate %d not met, got %ldKiB/sec\n", td->name, td->ratemin, rate);
                        if (rate_quit)
                                terminate_threads(td->groupid);
                        return 1;
                }
        }

        td->rate_bytes = td->this_io_bytes[ddir];
        memcpy(&td->lastrate, now, sizeof(*now));
        return 0;
}

static inline int runtime_exceeded(struct thread_data *td, struct timeval *t)
{
        if (!td->timeout)
                return 0;
        if (mtime_since(&td->epoch, t) >= td->timeout * 1000)
                return 1;

        return 0;
}

static void fill_random_bytes(struct thread_data *td,
                              unsigned char *p, unsigned int len)
{
        unsigned int todo;
        double r;

        while (len) {
                r = os_random_double(&td->verify_state);

                /*
                 * lrand48_r seems to be broken and only fill the bottom
                 * 32-bits, even on 64-bit archs with 64-bit longs
                 */
                todo = sizeof(r);
                if (todo > len)
                        todo = len;

                memcpy(p, &r, todo);

                len -= todo;
                p += todo;
        }
}

static void hexdump(void *buffer, int len)
{
        unsigned char *p = buffer;
        int i;

        for (i = 0; i < len; i++)
                fprintf(f_out, "%02x", p[i]);
        fprintf(f_out, "\n");
}

static int verify_io_u_crc32(struct verify_header *hdr, struct io_u *io_u)
{
        unsigned char *p = (unsigned char *) io_u->buf;
        unsigned long c;

        p += sizeof(*hdr);
        c = crc32(p, hdr->len - sizeof(*hdr));

        if (c != hdr->crc32) {
                log_err("crc32: verify failed at %llu/%u\n", io_u->offset, io_u->buflen);
                log_err("crc32: wanted %lx, got %lx\n", hdr->crc32, c);
                return 1;
        }

        return 0;
}

static int verify_io_u_md5(struct verify_header *hdr, struct io_u *io_u)
{
        unsigned char *p = (unsigned char *) io_u->buf;
        struct md5_ctx md5_ctx;

        memset(&md5_ctx, 0, sizeof(md5_ctx));
        p += sizeof(*hdr);
        md5_update(&md5_ctx, p, hdr->len - sizeof(*hdr));

        if (memcmp(hdr->md5_digest, md5_ctx.hash, sizeof(md5_ctx.hash))) {
                log_err("md5: verify failed at %llu/%u\n", io_u->offset, io_u->buflen);
                hexdump(hdr->md5_digest, sizeof(hdr->md5_digest));
                hexdump(md5_ctx.hash, sizeof(md5_ctx.hash));
                return 1;
        }

        return 0;
}

static int verify_io_u(struct io_u *io_u)
{
        struct verify_header *hdr = (struct verify_header *) io_u->buf;
        int ret;

        if (hdr->fio_magic != FIO_HDR_MAGIC)
                return 1;

        if (hdr->verify_type == VERIFY_MD5)
                ret = verify_io_u_md5(hdr, io_u);
        else if (hdr->verify_type == VERIFY_CRC32)
                ret = verify_io_u_crc32(hdr, io_u);
        else {
                log_err("Bad verify type %d\n", hdr->verify_type);
                ret = 1;
        }

        return ret;
}

static void fill_crc32(struct verify_header *hdr, void *p, unsigned int len)
{
        hdr->crc32 = crc32(p, len);
}

static void fill_md5(struct verify_header *hdr, void *p, unsigned int len)
{
        struct md5_ctx md5_ctx;

        memset(&md5_ctx, 0, sizeof(md5_ctx));
        md5_update(&md5_ctx, p, len);
        memcpy(hdr->md5_digest, md5_ctx.hash, sizeof(md5_ctx.hash));
}

/*
 * Return the data direction for the next io_u. If the job is a
 * mixed read/write workload, check the rwmix cycle and switch if
 * necessary.
 */
static int get_rw_ddir(struct thread_data *td)
{
        if (td_rw(td)) {
                struct timeval now;
                unsigned long elapsed;

                gettimeofday(&now, NULL);
                elapsed = mtime_since_now(&td->rwmix_switch);

                /*
                 * Check if it's time to seed a new data direction.
                 */
                if (elapsed >= td->rwmixcycle) {
                        int v;
                        long r;

                        r = os_random_long(&td->rwmix_state);
                        v = 1 + (int) (100.0 * (r / (RAND_MAX + 1.0)));
                        if (v < td->rwmixread)
                                td->rwmix_ddir = DDIR_READ;
                        else
                                td->rwmix_ddir = DDIR_WRITE;
                        memcpy(&td->rwmix_switch, &now, sizeof(now));
                }
                return td->rwmix_ddir;
        } else if (td_read(td))
                return DDIR_READ;
        else
                return DDIR_WRITE;
}

/*
 * fill body of io_u->buf with random data and add a header with the
 * crc32 or md5 sum of that data.
 */
static void populate_io_u(struct thread_data *td, struct io_u *io_u)
{
        unsigned char *p = (unsigned char *) io_u->buf;
        struct verify_header hdr;

        hdr.fio_magic = FIO_HDR_MAGIC;
        hdr.len = io_u->buflen;
        p += sizeof(hdr);
        fill_random_bytes(td, p, io_u->buflen - sizeof(hdr));

        if (td->verify == VERIFY_MD5) {
                fill_md5(&hdr, p, io_u->buflen - sizeof(hdr));
                hdr.verify_type = VERIFY_MD5;
        } else {
                fill_crc32(&hdr, p, io_u->buflen - sizeof(hdr));
                hdr.verify_type = VERIFY_CRC32;
        }

        memcpy(io_u->buf, &hdr, sizeof(hdr));
}

static int td_io_prep(struct thread_data *td, struct io_u *io_u)
{
        if (td->io_prep && td->io_prep(td, io_u))
                return 1;

        return 0;
}

void put_io_u(struct thread_data *td, struct io_u *io_u)
{
        list_del(&io_u->list);
        list_add(&io_u->list, &td->io_u_freelist);
        td->cur_depth--;
}

static int fill_io_u(struct thread_data *td, struct io_u *io_u)
{
        /*
         * If using an iolog, grab next piece if any available.
         */
        if (td->read_iolog)
                return read_iolog_get(td, io_u);

        /*
         * No log, let the seq/rand engine retrieve the next position.
         */
        if (!get_next_offset(td, &io_u->offset)) {
                io_u->buflen = get_next_buflen(td);

                if (io_u->buflen) {
                        io_u->ddir = get_rw_ddir(td);

                        /*
                         * If using a write iolog, store this entry.
                         */
                        if (td->write_iolog)
                                write_iolog_put(td, io_u);

                        return 0;
                }
        }

        return 1;
}

#define queue_full(td)  list_empty(&(td)->io_u_freelist)

struct io_u *__get_io_u(struct thread_data *td)
{
        struct io_u *io_u = NULL;

        if (!queue_full(td)) {
                io_u = list_entry(td->io_u_freelist.next, struct io_u, list);

                io_u->error = 0;
                io_u->resid = 0;
                list_del(&io_u->list);
                list_add(&io_u->list, &td->io_u_busylist);
                td->cur_depth++;
        }

        return io_u;
}

/*
 * Return an io_u to be processed. Gets a buflen and offset, sets direction,
 * etc. The returned io_u is fully ready to be prepped and submitted.
 */
static struct io_u *get_io_u(struct thread_data *td)
{
        struct io_u *io_u;

        io_u = __get_io_u(td);
        if (!io_u)
                return NULL;

        if (td->zone_bytes >= td->zone_size) {
                td->zone_bytes = 0;
                td->last_pos += td->zone_skip;
        }

        if (fill_io_u(td, io_u)) {
                put_io_u(td, io_u);
                return NULL;
        }

        if (io_u->buflen + io_u->offset > td->real_file_size)
                io_u->buflen = td->real_file_size - io_u->offset;

        if (!io_u->buflen) {
                put_io_u(td, io_u);
                return NULL;
        }

        if (!td->read_iolog && !td->sequential)
                mark_random_map(td, io_u);

        td->last_pos += io_u->buflen;

        if (td->verify != VERIFY_NONE)
                populate_io_u(td, io_u);

        if (td_io_prep(td, io_u)) {
                put_io_u(td, io_u);
                return NULL;
        }

        gettimeofday(&io_u->start_time, NULL);
        return io_u;
}

static inline void td_set_runstate(struct thread_data *td, int runstate)
{
        td->runstate = runstate;
}

static int get_next_verify(struct thread_data *td, struct io_u *io_u)
{
        struct io_piece *ipo;

        if (!list_empty(&td->io_hist_list)) {
                ipo = list_entry(td->io_hist_list.next, struct io_piece, list);

                list_del(&ipo->list);

                io_u->offset = ipo->offset;
                io_u->buflen = ipo->len;
                io_u->ddir = DDIR_READ;
                free(ipo);
                return 0;
        }

        return 1;
}

static int sync_td(struct thread_data *td)
{
        if (td->io_sync)
                return td->io_sync(td);

        return 0;
}

static int io_u_getevents(struct thread_data *td, int min, int max,
                          struct timespec *t)
{
        return td->io_getevents(td, min, max, t);
}

static int io_u_queue(struct thread_data *td, struct io_u *io_u)
{
        gettimeofday(&io_u->issue_time, NULL);

        return td->io_queue(td, io_u);
}

#define iocb_time(iocb) ((unsigned long) (iocb)->data)

static void io_completed(struct thread_data *td, struct io_u *io_u,
                         struct io_completion_data *icd)
{
        struct timeval e;
        unsigned long msec;

        gettimeofday(&e, NULL);

        if (!io_u->error) {
                unsigned int bytes = io_u->buflen - io_u->resid;
                const int idx = io_u->ddir;

                td->io_blocks[idx]++;
                td->io_bytes[idx] += bytes;
                td->zone_bytes += bytes;
                td->this_io_bytes[idx] += bytes;

                msec = mtime_since(&io_u->issue_time, &e);

                add_clat_sample(td, idx, msec);
                add_bw_sample(td, idx);

                if ((td_rw(td) || td_write(td)) && idx == DDIR_WRITE)
                        log_io_piece(td, io_u);

                icd->bytes_done[idx] += bytes;
        } else
                icd->error = io_u->error;
}

static void ios_completed(struct thread_data *td,struct io_completion_data *icd)
{
        struct io_u *io_u;
        int i;

        icd->error = 0;
        icd->bytes_done[0] = icd->bytes_done[1] = 0;

        for (i = 0; i < icd->nr; i++) {
                io_u = td->io_event(td, i);

                io_completed(td, io_u, icd);
                put_io_u(td, io_u);
        }
}

/*
 * When job exits, we can cancel the in-flight IO if we are using async
 * io. Attempt to do so.
 */
static void cleanup_pending_aio(struct thread_data *td)
{
        struct timespec ts = { .tv_sec = 0, .tv_nsec = 0};
        struct list_head *entry, *n;
        struct io_completion_data icd;
        struct io_u *io_u;
        int r;

        /*
         * get immediately available events, if any
         */
        r = io_u_getevents(td, 0, td->cur_depth, &ts);
        if (r > 0) {
                icd.nr = r;
                ios_completed(td, &icd);
        }

        /*
         * now cancel remaining active events
         */
        if (td->io_cancel) {
                list_for_each_safe(entry, n, &td->io_u_busylist) {
                        io_u = list_entry(entry, struct io_u, list);

                        r = td->io_cancel(td, io_u);
                        if (!r)
                                put_io_u(td, io_u);
                }
        }

        if (td->cur_depth) {
                r = io_u_getevents(td, td->cur_depth, td->cur_depth, NULL);
                if (r > 0) {
                        icd.nr = r;
                        ios_completed(td, &icd);
                }
        }
}

static int do_io_u_verify(struct thread_data *td, struct io_u **io_u)
{
        struct io_u *v_io_u = *io_u;
        int ret = 0;

        if (v_io_u) {
                ret = verify_io_u(v_io_u);
                put_io_u(td, v_io_u);
                *io_u = NULL;
        }

        return ret;
}

/*
 * The main verify engine. Runs over the writes we previusly submitted,
 * reads the blocks back in, and checks the crc/md5 of the data.
 */
static void do_verify(struct thread_data *td)
{
        struct timeval t;
        struct io_u *io_u, *v_io_u = NULL;
        struct io_completion_data icd;
        int ret;

        td_set_runstate(td, TD_VERIFYING);

        do {
                if (td->terminate)
                        break;

                gettimeofday(&t, NULL);
                if (runtime_exceeded(td, &t))
                        break;

                io_u = __get_io_u(td);
                if (!io_u)
                        break;

                if (get_next_verify(td, io_u)) {
                        put_io_u(td, io_u);
                        break;
                }

                if (td_io_prep(td, io_u)) {
                        put_io_u(td, io_u);
                        break;
                }

                ret = io_u_queue(td, io_u);
                if (ret) {
                        put_io_u(td, io_u);
                        td_verror(td, ret);
                        break;
                }

                /*
                 * we have one pending to verify, do that while
                 * we are doing io on the next one
                 */
                if (do_io_u_verify(td, &v_io_u))
                        break;

                ret = io_u_getevents(td, 1, 1, NULL);
                if (ret != 1) {
                        if (ret < 0)
                                td_verror(td, ret);
                        break;
                }

                v_io_u = td->io_event(td, 0);
                icd.nr = 1;
                icd.error = 0;
                io_completed(td, v_io_u, &icd);

                if (icd.error) {
                        td_verror(td, icd.error);
                        put_io_u(td, v_io_u);
                        v_io_u = NULL;
                        break;
                }

                /*
                 * if we can't submit more io, we need to verify now
                 */
                if (queue_full(td) && do_io_u_verify(td, &v_io_u))
                        break;

        } while (1);

        do_io_u_verify(td, &v_io_u);

        if (td->cur_depth)
                cleanup_pending_aio(td);

        td_set_runstate(td, TD_RUNNING);
}

/*
 * Main IO worker function. It retrieves io_u's to process and queues
 * and reaps them, checking for rate and errors along the way.
 */
static void do_io(struct thread_data *td)
{
        struct io_completion_data icd;
        struct timeval s, e;
        unsigned long usec;

        td_set_runstate(td, TD_RUNNING);

        while (td->this_io_bytes[td->ddir] < td->io_size) {
                struct timespec ts = { .tv_sec = 0, .tv_nsec = 0};
                struct timespec *timeout;
                int ret, min_evts = 0;
                struct io_u *io_u;

                if (td->terminate)
                        break;

                io_u = get_io_u(td);
                if (!io_u)
                        break;

                memcpy(&s, &io_u->start_time, sizeof(s));

                ret = io_u_queue(td, io_u);
                if (ret) {
                        put_io_u(td, io_u);
                        td_verror(td, ret);
                        break;
                }

                add_slat_sample(td, io_u->ddir, mtime_since(&io_u->start_time, &io_u->issue_time));

                if (td->cur_depth < td->iodepth) {
                        timeout = &ts;
                        min_evts = 0;
                } else {
                        timeout = NULL;
                        min_evts = 1;
                }

                ret = io_u_getevents(td, min_evts, td->cur_depth, timeout);
                if (ret < 0) {
                        td_verror(td, ret);
                        break;
                } else if (!ret)
                        continue;

                icd.nr = ret;
                ios_completed(td, &icd);
                if (icd.error) {
                        td_verror(td, icd.error);
                        break;
                }

                /*
                 * the rate is batched for now, it should work for batches
                 * of completions except the very first one which may look
                 * a little bursty
                 */
                gettimeofday(&e, NULL);
                usec = utime_since(&s, &e);

                rate_throttle(td, usec, icd.bytes_done[td->ddir]);

                if (check_min_rate(td, &e)) {
                        td_verror(td, ENOMEM);
                        break;
                }

                if (runtime_exceeded(td, &e))
                        break;

                if (td->thinktime)
                        usec_sleep(td, td->thinktime);

                if (should_fsync(td) && td->fsync_blocks &&
                    (td->io_blocks[DDIR_WRITE] % td->fsync_blocks) == 0)
                        sync_td(td);
        }

        if (td->cur_depth)
                cleanup_pending_aio(td);

        if (should_fsync(td) && td->end_fsync) {
                td_set_runstate(td, TD_FSYNCING);
                sync_td(td);
        }
}

static void cleanup_io(struct thread_data *td)
{
        if (td->io_cleanup)
                td->io_cleanup(td);
}

static int init_io(struct thread_data *td)
{
        if (td->io_engine == FIO_SYNCIO)
                return fio_syncio_init(td);
        else if (td->io_engine == FIO_MMAPIO)
                return fio_mmapio_init(td);
        else if (td->io_engine == FIO_LIBAIO)
                return fio_libaio_init(td);
        else if (td->io_engine == FIO_POSIXAIO)
                return fio_posixaio_init(td);
        else if (td->io_engine == FIO_SGIO)
                return fio_sgio_init(td);
        else if (td->io_engine == FIO_SPLICEIO)
                return fio_spliceio_init(td);
        else {
                log_err("bad io_engine %d\n", td->io_engine);
                return 1;
        }
}

static void cleanup_io_u(struct thread_data *td)
{
        struct list_head *entry, *n;
        struct io_u *io_u;

        list_for_each_safe(entry, n, &td->io_u_freelist) {
                io_u = list_entry(entry, struct io_u, list);

                list_del(&io_u->list);
                free(io_u);
        }

        if (td->mem_type == MEM_MALLOC)
                free(td->orig_buffer);
        else if (td->mem_type == MEM_SHM) {
                struct shmid_ds sbuf;

                shmdt(td->orig_buffer);
                shmctl(td->shm_id, IPC_RMID, &sbuf);
        } else if (td->mem_type == MEM_MMAP)
                munmap(td->orig_buffer, td->orig_buffer_size);
        else
                log_err("Bad memory type %d\n", td->mem_type);

        td->orig_buffer = NULL;
}

static int init_io_u(struct thread_data *td)
{
        struct io_u *io_u;
        int i, max_units;
        char *p;

        if (td->io_engine & FIO_SYNCIO)
                max_units = 1;
        else
                max_units = td->iodepth;

        td->orig_buffer_size = td->max_bs * max_units + MASK;

        if (td->mem_type == MEM_MALLOC)
                td->orig_buffer = malloc(td->orig_buffer_size);
        else if (td->mem_type == MEM_SHM) {
                td->shm_id = shmget(IPC_PRIVATE, td->orig_buffer_size, IPC_CREAT | 0600);
                if (td->shm_id < 0) {
                        td_verror(td, errno);
                        perror("shmget");
                        return 1;
                }

                td->orig_buffer = shmat(td->shm_id, NULL, 0);
                if (td->orig_buffer == (void *) -1) {
                        td_verror(td, errno);
                        perror("shmat");
                        td->orig_buffer = NULL;
                        return 1;
                }
        } else if (td->mem_type == MEM_MMAP) {
                td->orig_buffer = mmap(NULL, td->orig_buffer_size, PROT_READ | PROT_WRITE, MAP_PRIVATE | OS_MAP_ANON, 0, 0);
                if (td->orig_buffer == MAP_FAILED) {
                        td_verror(td, errno);
                        perror("mmap");
                        td->orig_buffer = NULL;
                        return 1;
                }
        }

        p = ALIGN(td->orig_buffer);
        for (i = 0; i < max_units; i++) {
                io_u = malloc(sizeof(*io_u));
                memset(io_u, 0, sizeof(*io_u));
                INIT_LIST_HEAD(&io_u->list);

                io_u->buf = p + td->max_bs * i;
                io_u->index = i;
                list_add(&io_u->list, &td->io_u_freelist);
        }

        return 0;
}

static int create_file(struct thread_data *td, unsigned long long size)
{
        unsigned long long left;
        unsigned int bs;
        char *b;
        int r;

        /*
         * unless specifically asked for overwrite, let normal io extend it
         */
        if (!td->overwrite) {
                td->real_file_size = size;
                return 0;
        }

        if (!size) {
                log_err("Need size for create\n");
                td_verror(td, EINVAL);
                return 1;
        }

        temp_stall_ts = 1;
        fprintf(f_out, "%s: Laying out IO file (%LuMiB)\n",td->name,size >> 20);

        td->fd = open(td->file_name, O_WRONLY | O_CREAT | O_TRUNC, 0644);
        if (td->fd < 0) {
                td_verror(td, errno);
                goto done_noclose;
        }

        if (ftruncate(td->fd, td->file_size) == -1) {
                td_verror(td, errno);
                goto done;
        }

        td->io_size = td->file_size;
        b = malloc(td->max_bs);
        memset(b, 0, td->max_bs);

        left = size;
        while (left && !td->terminate) {
                bs = td->max_bs;
                if (bs > left)
                        bs = left;

                r = write(td->fd, b, bs);

                if (r == (int) bs) {
                        left -= bs;
                        continue;
                } else {
                        if (r < 0)
                                td_verror(td, errno);
                        else
                                td_verror(td, EIO);

                        break;
                }
        }

        if (td->terminate)
                unlink(td->file_name);
        else if (td->create_fsync)
                fsync(td->fd);

        free(b);
done:
        close(td->fd);
        td->fd = -1;
done_noclose:
        temp_stall_ts = 0;
        return 0;
}

static int file_size(struct thread_data *td)
{
        struct stat st;

        if (td->overwrite) {
                if (fstat(td->fd, &st) == -1) {
                        td_verror(td, errno);
                        return 1;
                }

                td->real_file_size = st.st_size;

                if (!td->file_size || td->file_size > td->real_file_size)
                        td->file_size = td->real_file_size;
        }

        td->file_size -= td->file_offset;
        return 0;
}

static int bdev_size(struct thread_data *td)
{
        unsigned long long bytes;
        int r;

        r = blockdev_size(td->fd, &bytes);
        if (r) {
                td_verror(td, r);
                return 1;
        }

        td->real_file_size = bytes;

        /*
         * no extend possibilities, so limit size to device size if too large
         */
        if (!td->file_size || td->file_size > td->real_file_size)
                td->file_size = td->real_file_size;

        td->file_size -= td->file_offset;
        return 0;
}

static int get_file_size(struct thread_data *td)
{
        int ret = 0;

        if (td->filetype == FIO_TYPE_FILE)
                ret = file_size(td);
        else if (td->filetype == FIO_TYPE_BD)
                ret = bdev_size(td);
        else
                td->real_file_size = -1;

        if (ret)
                return ret;

        if (td->file_offset > td->real_file_size) {
                log_err("%s: offset extends end (%Lu > %Lu)\n", td->name, td->file_offset, td->real_file_size);
                return 1;
        }

        td->io_size = td->file_size;
        if (td->io_size == 0) {
                log_err("%s: no io blocks\n", td->name);
                td_verror(td, EINVAL);
                return 1;
        }

        if (!td->zone_size)
                td->zone_size = td->io_size;

        td->total_io_size = td->io_size * td->loops;
        return 0;
}

static int setup_file_mmap(struct thread_data *td)
{
        int flags;

        if (td_rw(td))
                flags = PROT_READ | PROT_WRITE;
        else if (td_write(td)) {
                flags = PROT_WRITE;

                if (td->verify != VERIFY_NONE)
                        flags |= PROT_READ;
        } else
                flags = PROT_READ;

        td->mmap = mmap(NULL, td->file_size, flags, MAP_SHARED, td->fd, td->file_offset);
        if (td->mmap == MAP_FAILED) {
                td->mmap = NULL;
                td_verror(td, errno);
                return 1;
        }

        if (td->invalidate_cache) {
                if (madvise(td->mmap, td->file_size, MADV_DONTNEED) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        }

        if (td->sequential) {
                if (madvise(td->mmap, td->file_size, MADV_SEQUENTIAL) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        } else {
                if (madvise(td->mmap, td->file_size, MADV_RANDOM) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        }

        return 0;
}

static int setup_file_plain(struct thread_data *td)
{
        if (td->invalidate_cache) {
                if (fadvise(td->fd, td->file_offset, td->file_size, POSIX_FADV_DONTNEED) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        }

        if (td->sequential) {
                if (fadvise(td->fd, td->file_offset, td->file_size, POSIX_FADV_SEQUENTIAL) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        } else {
                if (fadvise(td->fd, td->file_offset, td->file_size, POSIX_FADV_RANDOM) < 0) {
                        td_verror(td, errno);
                        return 1;
                }
        }

        return 0;
}

static int setup_file(struct thread_data *td)
{
        struct stat st;
        int flags = 0;

        if (stat(td->file_name, &st) == -1) {
                if (errno != ENOENT) {
                        td_verror(td, errno);
                        return 1;
                }
                if (!td->create_file) {
                        td_verror(td, ENOENT);
                        return 1;
                }
                if (create_file(td, td->file_size))
                        return 1;
        } else if (td->filetype == FIO_TYPE_FILE &&
                   st.st_size < (off_t) td->file_size) {
                if (create_file(td, td->file_size))
                        return 1;
        }

        if (td->odirect)
                flags |= OS_O_DIRECT;

        if (td_write(td) || td_rw(td)) {
                if (td->filetype == FIO_TYPE_FILE) {
                        if (!td->overwrite)
                                flags |= O_TRUNC;

                        flags |= O_CREAT;
                }
                if (td->sync_io)
                        flags |= O_SYNC;

                flags |= O_RDWR;

                td->fd = open(td->file_name, flags, 0600);
        } else {
                if (td->filetype == FIO_TYPE_CHAR)
                        flags |= O_RDWR;
                else
                        flags |= O_RDONLY;

                td->fd = open(td->file_name, flags);
        }

        if (td->fd == -1) {
                td_verror(td, errno);
                return 1;
        }

        if (get_file_size(td))
                return 1;

        if (td->io_engine != FIO_MMAPIO)
                return setup_file_plain(td);
        else
                return setup_file_mmap(td);
}

static int switch_ioscheduler(struct thread_data *td)
{
        char tmp[256], tmp2[128];
        FILE *f;
        int ret;

        sprintf(tmp, "%s/queue/scheduler", td->sysfs_root);

        f = fopen(tmp, "r+");
        if (!f) {
                td_verror(td, errno);
                return 1;
        }

        /*
         * Set io scheduler.
         */
        ret = fwrite(td->ioscheduler, strlen(td->ioscheduler), 1, f);
        if (ferror(f) || ret != 1) {
                td_verror(td, errno);
                fclose(f);
                return 1;
        }

        rewind(f);

        /*
         * Read back and check that the selected scheduler is now the default.
         */
        ret = fread(tmp, 1, sizeof(tmp), f);
        if (ferror(f) || ret < 0) {
                td_verror(td, errno);
                fclose(f);
                return 1;
        }

        sprintf(tmp2, "[%s]", td->ioscheduler);
        if (!strstr(tmp, tmp2)) {
                log_err("fio: io scheduler %s not found\n", td->ioscheduler);
                td_verror(td, EINVAL);
                fclose(f);
                return 1;
        }

        fclose(f);
        return 0;
}

static void clear_io_state(struct thread_data *td)
{
        if (td->io_engine == FIO_SYNCIO)
                lseek(td->fd, SEEK_SET, 0);

        td->last_pos = 0;
        td->stat_io_bytes[0] = td->stat_io_bytes[1] = 0;
        td->this_io_bytes[0] = td->this_io_bytes[1] = 0;
        td->zone_bytes = 0;

        if (td->file_map)
                memset(td->file_map, 0, td->num_maps * sizeof(long));
}

/*
 * Entry point for the thread based jobs. The process based jobs end up
 * here as well, after a little setup.
 */
static void *thread_main(void *data)
{
        struct thread_data *td = data;

        if (!td->use_thread)
                setsid();

        td->pid = getpid();

        INIT_LIST_HEAD(&td->io_u_freelist);
        INIT_LIST_HEAD(&td->io_u_busylist);
        INIT_LIST_HEAD(&td->io_hist_list);
        INIT_LIST_HEAD(&td->io_log_list);

        if (init_io_u(td))
                goto err;

        if (fio_setaffinity(td) == -1) {
                td_verror(td, errno);
                goto err;
        }

        if (init_io(td))
                goto err;

        if (init_iolog(td))
                goto err;

        if (td->ioprio) {
                if (ioprio_set(IOPRIO_WHO_PROCESS, 0, td->ioprio) == -1) {
                        td_verror(td, errno);
                        goto err;
                }
        }

        if (nice(td->nice) == -1) {
                td_verror(td, errno);
                goto err;
        }

        if (init_random_state(td))
                goto err;

        if (td->ioscheduler && switch_ioscheduler(td))
                goto err;

        td_set_runstate(td, TD_INITIALIZED);
        fio_sem_up(&startup_sem);
        fio_sem_down(&td->mutex);

        if (!td->create_serialize && setup_file(td))
                goto err;

        gettimeofday(&td->epoch, NULL);

        if (td->exec_prerun)
                system(td->exec_prerun);

        while (td->loops--) {
                getrusage(RUSAGE_SELF, &td->ru_start);
                gettimeofday(&td->start, NULL);
                memcpy(&td->stat_sample_time, &td->start, sizeof(td->start));

                if (td->ratemin)
                        memcpy(&td->lastrate, &td->stat_sample_time, sizeof(td->lastrate));

                clear_io_state(td);
                prune_io_piece_log(td);

                do_io(td);

                td->runtime[td->ddir] += mtime_since_now(&td->start);
                if (td_rw(td) && td->io_bytes[td->ddir ^ 1])
                        td->runtime[td->ddir ^ 1] = td->runtime[td->ddir];

                update_rusage_stat(td);

                if (td->error || td->terminate)
                        break;

                if (td->verify == VERIFY_NONE)
                        continue;

                clear_io_state(td);
                gettimeofday(&td->start, NULL);

                do_verify(td);

                td->runtime[DDIR_READ] += mtime_since_now(&td->start);

                if (td->error || td->terminate)
                        break;
        }

        if (td->bw_log)
                finish_log(td, td->bw_log, "bw");
        if (td->slat_log)
                finish_log(td, td->slat_log, "slat");
        if (td->clat_log)
                finish_log(td, td->clat_log, "clat");
        if (td->write_iolog)
                write_iolog_close(td);
        if (td->exec_postrun)
                system(td->exec_postrun);

        if (exitall_on_terminate)
                terminate_threads(td->groupid);

err:
        if (td->fd != -1) {
                close(td->fd);
                td->fd = -1;
        }
        if (td->mmap)
                munmap(td->mmap, td->file_size);
        cleanup_io(td);
        cleanup_io_u(td);
        td_set_runstate(td, TD_EXITED);
        return NULL;

}

/*
 * We cannot pass the td data into a forked process, so attach the td and
 * pass it to the thread worker.
 */
static void *fork_main(int shmid, int offset)
{
        struct thread_data *td;
        void *data;

        data = shmat(shmid, NULL, 0);
        if (data == (void *) -1) {
                perror("shmat");
                return NULL;
        }

        td = data + offset * sizeof(struct thread_data);
        thread_main(td);
        shmdt(data);
        return NULL;
}

/*
 * Sets the status of the 'td' in the printed status map.
 */
static void check_str_update(struct thread_data *td)
{
        char c = run_str[td->thread_number - 1];

        switch (td->runstate) {
                case TD_REAPED:
                        c = '_';
                        break;
                case TD_EXITED:
                        c = 'E';
                        break;
                case TD_RUNNING:
                        if (td_rw(td)) {
                                if (td->sequential)
                                        c = 'M';
                                else
                                        c = 'm';
                        } else if (td_read(td)) {
                                if (td->sequential)
                                        c = 'R';
                                else
                                        c = 'r';
                        } else {
                                if (td->sequential)
                                        c = 'W';
                                else
                                        c = 'w';
                        }
                        break;
                case TD_VERIFYING:
                        c = 'V';
                        break;
                case TD_FSYNCING:
                        c = 'F';
                        break;
                case TD_CREATED:
                        c = 'C';
                        break;
                case TD_INITIALIZED:
                        c = 'I';
                        break;
                case TD_NOT_CREATED:
                        c = 'P';
                        break;
                default:
                        log_err("state %d\n", td->runstate);
        }

        run_str[td->thread_number - 1] = c;
}

/*
 * Convert seconds to a printable string.
 */
static void eta_to_str(char *str, int eta_sec)
{
        unsigned int d, h, m, s;
        static int always_d, always_h;

        d = h = m = s = 0;

        s = eta_sec % 60;
        eta_sec /= 60;
        m = eta_sec % 60;
        eta_sec /= 60;
        h = eta_sec % 24;
        eta_sec /= 24;
        d = eta_sec;

        if (d || always_d) {
                always_d = 1;
                str += sprintf(str, "%02dd:", d);
        }
        if (h || always_h) {
                always_h = 1;
                str += sprintf(str, "%02dh:", h);
        }

        str += sprintf(str, "%02dm:", m);
        str += sprintf(str, "%02ds", s);
}

/*
 * Best effort calculation of the estimated pending runtime of a job.
 */
static int thread_eta(struct thread_data *td, unsigned long elapsed)
{
        unsigned long long bytes_total, bytes_done;
        unsigned int eta_sec = 0;

        bytes_total = td->total_io_size;

        /*
         * if writing, bytes_total will be twice the size. If mixing,
         * assume a 50/50 split and thus bytes_total will be 50% larger.
         */
        if (td->verify) {
                if (td_rw(td))
                        bytes_total = bytes_total * 3 / 2;
                else
                        bytes_total <<= 1;
        }
        if (td->zone_size && td->zone_skip)
                bytes_total /= (td->zone_skip / td->zone_size);

        if (td->runstate == TD_RUNNING || td->runstate == TD_VERIFYING) {
                double perc;

                bytes_done = td->io_bytes[DDIR_READ] + td->io_bytes[DDIR_WRITE];
                perc = (double) bytes_done / (double) bytes_total;
                if (perc > 1.0)
                        perc = 1.0;

                eta_sec = (elapsed * (1.0 / perc)) - elapsed;

                if (td->timeout && eta_sec > (td->timeout - elapsed))
                        eta_sec = td->timeout - elapsed;
        } else if (td->runstate == TD_NOT_CREATED || td->runstate == TD_CREATED
                        || td->runstate == TD_INITIALIZED) {
                int t_eta = 0, r_eta = 0;

                /*
                 * We can only guess - assume it'll run the full timeout
                 * if given, otherwise assume it'll run at the specified rate.
                 */
                if (td->timeout)
                        t_eta = td->timeout + td->start_delay - elapsed;
                if (td->rate) {
                        r_eta = (bytes_total / 1024) / td->rate;
                        r_eta += td->start_delay - elapsed;
                }

                if (r_eta && t_eta)
                        eta_sec = min(r_eta, t_eta);
                else if (r_eta)
                        eta_sec = r_eta;
                else if (t_eta)
                        eta_sec = t_eta;
                else
                        eta_sec = 0;
        } else {
                /*
                 * thread is already done or waiting for fsync
                 */
                eta_sec = 0;
        }

        return eta_sec;
}

/*
 * Print status of the jobs we know about. This includes rate estimates,
 * ETA, thread state, etc.
 */
static void print_thread_status(void)
{
        unsigned long elapsed = time_since_now(&genesis);
        int i, nr_running, nr_pending, t_rate, m_rate, *eta_secs, eta_sec;
        char eta_str[32];
        double perc = 0.0;

        if (temp_stall_ts || terse_output)
                return;

        eta_secs = malloc(thread_number * sizeof(int));
        memset(eta_secs, 0, thread_number * sizeof(int));

        nr_pending = nr_running = t_rate = m_rate = 0;
        for (i = 0; i < thread_number; i++) {
                struct thread_data *td = &threads[i];

                if (td->runstate == TD_RUNNING || td->runstate == TD_VERIFYING||
                    td->runstate == TD_FSYNCING) {
                        nr_running++;
                        t_rate += td->rate;
                        m_rate += td->ratemin;
                } else if (td->runstate < TD_RUNNING)
                        nr_pending++;

                if (elapsed >= 3)
                        eta_secs[i] = thread_eta(td, elapsed);
                else
                        eta_secs[i] = INT_MAX;

                check_str_update(td);
        }

        if (exitall_on_terminate)
                eta_sec = INT_MAX;
        else
                eta_sec = 0;

        for (i = 0; i < thread_number; i++) {
                if (exitall_on_terminate) {
                        if (eta_secs[i] < eta_sec)
                                eta_sec = eta_secs[i];
                } else {
                        if (eta_secs[i] > eta_sec)
                                eta_sec = eta_secs[i];
                }
        }

        if (eta_sec != INT_MAX && elapsed) {
                perc = (double) elapsed / (double) (elapsed + eta_sec);
                eta_to_str(eta_str, eta_sec);
        }

        if (!nr_running && !nr_pending)
                return;

        printf("Threads running: %d", nr_running);
        if (m_rate || t_rate)
                printf(", commitrate %d/%dKiB/sec", t_rate, m_rate);
        if (eta_sec != INT_MAX && nr_running) {
                perc *= 100.0;
                printf(": [%s] [%3.2f%% done] [eta %s]", run_str, perc,eta_str);
        }
        printf("\r");
        fflush(stdout);
        free(eta_secs);
}

/*
 * Run over the job map and reap the threads that have exited, if any.
 */
static void reap_threads(int *nr_running, int *t_rate, int *m_rate)
{
        int i;

        /*
         * reap exited threads (TD_EXITED -> TD_REAPED)
         */
        for (i = 0; i < thread_number; i++) {
                struct thread_data *td = &threads[i];

                if (td->runstate != TD_EXITED)
                        continue;

                td_set_runstate(td, TD_REAPED);

                if (td->use_thread) {
                        long ret;

                        if (pthread_join(td->thread, (void *) &ret))
                                perror("thread_join");
                } else
                        waitpid(td->pid, NULL, 0);

                (*nr_running)--;
                (*m_rate) -= td->ratemin;
                (*t_rate) -= td->rate;
        }
}

static void fio_unpin_memory(void *pinned)
{
        if (pinned) {
                if (munlock(pinned, mlock_size) < 0)
                        perror("munlock");
                munmap(pinned, mlock_size);
        }
}

static void *fio_pin_memory(void)
{
        unsigned long long phys_mem;
        void *ptr;

        if (!mlock_size)
                return NULL;

        /*
         * Don't allow mlock of more than real_mem-128MB
         */
        phys_mem = os_phys_mem();
        if (phys_mem) {
                if ((mlock_size + 128 * 1024 * 1024) > phys_mem) {
                        mlock_size = phys_mem - 128 * 1024 * 1024;
                        fprintf(f_out, "fio: limiting mlocked memory to %lluMiB\n", mlock_size >> 20);
                }
        }

        ptr = mmap(NULL, mlock_size, PROT_READ | PROT_WRITE, MAP_PRIVATE | OS_MAP_ANON, 0, 0);
        if (!ptr) {
                perror("malloc locked mem");
                return NULL;
        }
        if (mlock(ptr, mlock_size) < 0) {
                munmap(ptr, mlock_size);
                perror("mlock");
                return NULL;
        }

        return ptr;
}

/*
 * Main function for kicking off and reaping jobs, as needed.
 */
static void run_threads(void)
{
        struct thread_data *td;
        unsigned long spent;
        int i, todo, nr_running, m_rate, t_rate, nr_started;
        void *mlocked_mem;

        mlocked_mem = fio_pin_memory();

        if (!terse_output) {
                printf("Starting %d thread%s\n", thread_number, thread_number > 1 ? "s" : "");
                fflush(stdout);
        }

        signal(SIGINT, sig_handler);
        signal(SIGALRM, sig_handler);

        todo = thread_number;
        nr_running = 0;
        nr_started = 0;
        m_rate = t_rate = 0;

        for (i = 0; i < thread_number; i++) {
                td = &threads[i];

                run_str[td->thread_number - 1] = 'P';

                init_disk_util(td);

                if (!td->create_serialize)
                        continue;

                /*
                 * do file setup here so it happens sequentially,
                 * we don't want X number of threads getting their
                 * client data interspersed on disk
                 */
                if (setup_file(td)) {
                        td_set_runstate(td, TD_REAPED);
                        todo--;
                }
        }

        gettimeofday(&genesis, NULL);

        while (todo) {
                struct thread_data *map[MAX_JOBS];
                struct timeval this_start;
                int this_jobs = 0, left;

                /*
                 * create threads (TD_NOT_CREATED -> TD_CREATED)
                 */
                for (i = 0; i < thread_number; i++) {
                        td = &threads[i];

                        if (td->runstate != TD_NOT_CREATED)
                                continue;

                        /*
                         * never got a chance to start, killed by other
                         * thread for some reason
                         */
                        if (td->terminate) {
                                todo--;
                                continue;
                        }

                        if (td->start_delay) {
                                spent = mtime_since_now(&genesis);

                                if (td->start_delay * 1000 > spent)
                                        continue;
                        }

                        if (td->stonewall && (nr_started || nr_running))
                                break;

                        /*
                         * Set state to created. Thread will transition
                         * to TD_INITIALIZED when it's done setting up.
                         */
                        td_set_runstate(td, TD_CREATED);
                        map[this_jobs++] = td;
                        fio_sem_init(&startup_sem, 1);
                        nr_started++;

                        if (td->use_thread) {
                                if (pthread_create(&td->thread, NULL, thread_main, td)) {
                                        perror("thread_create");
                                        nr_started--;
                                }
                        } else {
                                if (fork())
                                        fio_sem_down(&startup_sem);
                                else {
                                        fork_main(shm_id, i);
                                        exit(0);
                                }
                        }
                }

                /*
                 * Wait for the started threads to transition to
                 * TD_INITIALIZED.
                 */
                gettimeofday(&this_start, NULL);
                left = this_jobs;
                while (left) {
                        if (mtime_since_now(&this_start) > JOB_START_TIMEOUT)
                                break;

                        usleep(100000);

                        for (i = 0; i < this_jobs; i++) {
                                td = map[i];
                                if (!td)
                                        continue;
                                if (td->runstate == TD_INITIALIZED) {
                                        map[i] = NULL;
                                        left--;
                                } else if (td->runstate >= TD_EXITED) {
                                        map[i] = NULL;
                                        left--;
                                        todo--;
                                        nr_running++; /* work-around... */
                                }
                        }
                }

                if (left) {
                        log_err("fio: %d jobs failed to start\n", left);
                        for (i = 0; i < this_jobs; i++) {
                                td = map[i];
                                if (!td)
                                        continue;
                                kill(td->pid, SIGTERM);
                        }
                        break;
                }

                /*
                 * start created threads (TD_INITIALIZED -> TD_RUNNING).
                 */
                for (i = 0; i < thread_number; i++) {
                        td = &threads[i];

                        if (td->runstate != TD_INITIALIZED)
                                continue;

                        td_set_runstate(td, TD_RUNNING);
                        nr_running++;
                        nr_started--;
                        m_rate += td->ratemin;
                        t_rate += td->rate;
                        todo--;
                        fio_sem_up(&td->mutex);
                }

                reap_threads(&nr_running, &t_rate, &m_rate);

                if (todo)
                        usleep(100000);
        }

        while (nr_running) {
                reap_threads(&nr_running, &t_rate, &m_rate);
                usleep(10000);
        }

        update_io_ticks();
        fio_unpin_memory(mlocked_mem);
}

int main(int argc, char *argv[])
{
        if (parse_options(argc, argv))
                return 1;

        if (!thread_number) {
                log_err("Nothing to do\n");
                return 1;
        }

        disk_util_timer_arm();

        run_threads();
        show_run_stats();

        return 0;
}