libaio,io_uring: move common cmdprio_prep() code to cmdprio

[fio.git] / engines / libaio.c

/*
 * libaio engine
 *
 * IO engine using the Linux native aio interface.
 *
 */
#include <stdlib.h>
#include <unistd.h>
#include <errno.h>
#include <libaio.h>
#include <sys/time.h>
#include <sys/resource.h>

#include "../fio.h"
#include "../lib/pow2.h"
#include "../optgroup.h"
#include "../lib/memalign.h"
#include "cmdprio.h"

/* Should be defined in newest aio_abi.h */
#ifndef IOCB_FLAG_IOPRIO
#define IOCB_FLAG_IOPRIO    (1 << 1)
#endif

/* Hack for libaio < 0.3.111 */
#ifndef CONFIG_LIBAIO_RW_FLAGS
#define aio_rw_flags __pad2
#endif

static int fio_libaio_commit(struct thread_data *td);
static int fio_libaio_init(struct thread_data *td);

struct libaio_data {
        io_context_t aio_ctx;
        struct io_event *aio_events;
        struct iocb **iocbs;
        struct io_u **io_us;

        struct io_u **io_u_index;

        /*
         * Basic ring buffer. 'head' is incremented in _queue(), and
         * 'tail' is incremented in _commit(). We keep 'queued' so
         * that we know if the ring is full or empty, when
         * 'head' == 'tail'. 'entries' is the ring size, and
         * 'is_pow2' is just an optimization to use AND instead of
         * modulus to get the remainder on ring increment.
         */
        int is_pow2;
        unsigned int entries;
        unsigned int queued;
        unsigned int head;
        unsigned int tail;

        bool use_cmdprio;
};

struct libaio_options {
        struct thread_data *td;
        unsigned int userspace_reap;
        struct cmdprio cmdprio;
        unsigned int nowait;
};

static int str_cmdprio_bssplit_cb(void *data, const char *input)
{
        struct libaio_options *o = data;
        struct thread_data *td = o->td;
        struct cmdprio *cmdprio = &o->cmdprio;

        return fio_cmdprio_bssplit_parse(td, input, cmdprio);
}

static struct fio_option options[] = {
        {
                .name   = "userspace_reap",
                .lname  = "Libaio userspace reaping",
                .type   = FIO_OPT_STR_SET,
                .off1   = offsetof(struct libaio_options, userspace_reap),
                .help   = "Use alternative user-space reap implementation",
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
#ifdef FIO_HAVE_IOPRIO_CLASS
        {
                .name   = "cmdprio_percentage",
                .lname  = "high priority percentage",
                .type   = FIO_OPT_INT,
                .off1   = offsetof(struct libaio_options,
                                   cmdprio.percentage[DDIR_READ]),
                .off2   = offsetof(struct libaio_options,
                                   cmdprio.percentage[DDIR_WRITE]),
                .minval = 0,
                .maxval = 100,
                .help   = "Send high priority I/O this percentage of the time",
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
        {
                .name   = "cmdprio_class",
                .lname  = "Asynchronous I/O priority class",
                .type   = FIO_OPT_INT,
                .off1   = offsetof(struct libaio_options,
                                   cmdprio.class[DDIR_READ]),
                .off2   = offsetof(struct libaio_options,
                                   cmdprio.class[DDIR_WRITE]),
                .help   = "Set asynchronous IO priority class",
                .minval = IOPRIO_MIN_PRIO_CLASS + 1,
                .maxval = IOPRIO_MAX_PRIO_CLASS,
                .interval = 1,
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
        {
                .name   = "cmdprio",
                .lname  = "Asynchronous I/O priority level",
                .type   = FIO_OPT_INT,
                .off1   = offsetof(struct libaio_options,
                                   cmdprio.level[DDIR_READ]),
                .off2   = offsetof(struct libaio_options,
                                   cmdprio.level[DDIR_WRITE]),
                .help   = "Set asynchronous IO priority level",
                .minval = IOPRIO_MIN_PRIO,
                .maxval = IOPRIO_MAX_PRIO,
                .interval = 1,
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
        {
                .name   = "cmdprio_bssplit",
                .lname  = "Priority percentage block size split",
                .type   = FIO_OPT_STR_ULL,
                .cb     = str_cmdprio_bssplit_cb,
                .off1   = offsetof(struct libaio_options, cmdprio.bssplit),
                .help   = "Set priority percentages for different block sizes",
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
#else
        {
                .name   = "cmdprio_percentage",
                .lname  = "high priority percentage",
                .type   = FIO_OPT_UNSUPPORTED,
                .help   = "Your platform does not support I/O priority classes",
        },
        {
                .name   = "cmdprio_class",
                .lname  = "Asynchronous I/O priority class",
                .type   = FIO_OPT_UNSUPPORTED,
                .help   = "Your platform does not support I/O priority classes",
        },
        {
                .name   = "cmdprio",
                .lname  = "Asynchronous I/O priority level",
                .type   = FIO_OPT_UNSUPPORTED,
                .help   = "Your platform does not support I/O priority classes",
        },
        {
                .name   = "cmdprio_bssplit",
                .lname  = "Priority percentage block size split",
                .type   = FIO_OPT_UNSUPPORTED,
                .help   = "Your platform does not support I/O priority classes",
        },
#endif
        {
                .name   = "nowait",
                .lname  = "RWF_NOWAIT",
                .type   = FIO_OPT_BOOL,
                .off1   = offsetof(struct libaio_options, nowait),
                .help   = "Set RWF_NOWAIT for reads/writes",
                .category = FIO_OPT_C_ENGINE,
                .group  = FIO_OPT_G_LIBAIO,
        },
        {
                .name   = NULL,
        },
};

static inline void ring_inc(struct libaio_data *ld, unsigned int *val,
                            unsigned int add)
{
        if (ld->is_pow2)
                *val = (*val + add) & (ld->entries - 1);
        else
                *val = (*val + add) % ld->entries;
}

static int fio_libaio_prep(struct thread_data *td, struct io_u *io_u)
{
        struct libaio_options *o = td->eo;
        struct fio_file *f = io_u->file;
        struct iocb *iocb = &io_u->iocb;

        if (io_u->ddir == DDIR_READ) {
                io_prep_pread(iocb, f->fd, io_u->xfer_buf, io_u->xfer_buflen, io_u->offset);
                if (o->nowait)
                        iocb->aio_rw_flags |= RWF_NOWAIT;
        } else if (io_u->ddir == DDIR_WRITE) {
                io_prep_pwrite(iocb, f->fd, io_u->xfer_buf, io_u->xfer_buflen, io_u->offset);
                if (o->nowait)
                        iocb->aio_rw_flags |= RWF_NOWAIT;
        } else if (ddir_sync(io_u->ddir))
                io_prep_fsync(iocb, f->fd);

        return 0;
}

static inline void fio_libaio_cmdprio_prep(struct thread_data *td,
                                           struct io_u *io_u)
{
        struct libaio_options *o = td->eo;
        struct cmdprio *cmdprio = &o->cmdprio;

        if (fio_cmdprio_set_ioprio(td, cmdprio, io_u)) {
                io_u->iocb.aio_reqprio = io_u->ioprio;
                io_u->iocb.u.c.flags |= IOCB_FLAG_IOPRIO;
        }
}

static struct io_u *fio_libaio_event(struct thread_data *td, int event)
{
        struct libaio_data *ld = td->io_ops_data;
        struct io_event *ev;
        struct io_u *io_u;

        ev = ld->aio_events + event;
        io_u = container_of(ev->obj, struct io_u, iocb);

        if (ev->res != io_u->xfer_buflen) {
                if (ev->res > io_u->xfer_buflen)
                        io_u->error = -ev->res;
                else
                        io_u->resid = io_u->xfer_buflen - ev->res;
        } else
                io_u->error = 0;

        return io_u;
}

struct aio_ring {
        unsigned id;             /** kernel internal index number */
        unsigned nr;             /** number of io_events */
        unsigned head;
        unsigned tail;

        unsigned magic;
        unsigned compat_features;
        unsigned incompat_features;
        unsigned header_length; /** size of aio_ring */

        struct io_event events[0];
};

#define AIO_RING_MAGIC  0xa10a10a1

static int user_io_getevents(io_context_t aio_ctx, unsigned int max,
                             struct io_event *events)
{
        long i = 0;
        unsigned head;
        struct aio_ring *ring = (struct aio_ring*) aio_ctx;

        while (i < max) {
                head = ring->head;

                if (head == ring->tail) {
                        /* There are no more completions */
                        break;
                } else {
                        /* There is another completion to reap */
                        events[i] = ring->events[head];
                        atomic_store_release(&ring->head,
                                             (head + 1) % ring->nr);
                        i++;
                }
        }

        return i;
}

static int fio_libaio_getevents(struct thread_data *td, unsigned int min,
                                unsigned int max, const struct timespec *t)
{
        struct libaio_data *ld = td->io_ops_data;
        struct libaio_options *o = td->eo;
        unsigned actual_min = td->o.iodepth_batch_complete_min == 0 ? 0 : min;
        struct timespec __lt, *lt = NULL;
        int r, events = 0;

        if (t) {
                __lt = *t;
                lt = &__lt;
        }

        do {
                if (o->userspace_reap == 1
                    && actual_min == 0
                    && ((struct aio_ring *)(ld->aio_ctx))->magic
                                == AIO_RING_MAGIC) {
                        r = user_io_getevents(ld->aio_ctx, max,
                                ld->aio_events + events);
                } else {
                        r = io_getevents(ld->aio_ctx, actual_min,
                                max, ld->aio_events + events, lt);
                }
                if (r > 0)
                        events += r;
                else if ((min && r == 0) || r == -EAGAIN) {
                        fio_libaio_commit(td);
                        if (actual_min)
                                usleep(10);
                } else if (r != -EINTR)
                        break;
        } while (events < min);

        return r < 0 ? r : events;
}

static enum fio_q_status fio_libaio_queue(struct thread_data *td,
                                          struct io_u *io_u)
{
        struct libaio_data *ld = td->io_ops_data;

        fio_ro_check(td, io_u);

        if (ld->queued == td->o.iodepth)
                return FIO_Q_BUSY;

        /*
         * fsync is tricky, since it can fail and we need to do it
         * serialized with other io. the reason is that linux doesn't
         * support aio fsync yet. So return busy for the case where we
         * have pending io, to let fio complete those first.
         */
        if (ddir_sync(io_u->ddir)) {
                if (ld->queued)
                        return FIO_Q_BUSY;

                do_io_u_sync(td, io_u);
                return FIO_Q_COMPLETED;
        }

        if (io_u->ddir == DDIR_TRIM) {
                if (ld->queued)
                        return FIO_Q_BUSY;

                do_io_u_trim(td, io_u);
                io_u_mark_submit(td, 1);
                io_u_mark_complete(td, 1);
                return FIO_Q_COMPLETED;
        }

        if (ld->use_cmdprio)
                fio_libaio_cmdprio_prep(td, io_u);

        ld->iocbs[ld->head] = &io_u->iocb;
        ld->io_us[ld->head] = io_u;
        ring_inc(ld, &ld->head, 1);
        ld->queued++;
        return FIO_Q_QUEUED;
}

static void fio_libaio_queued(struct thread_data *td, struct io_u **io_us,
                              unsigned int nr)
{
        struct timespec now;
        unsigned int i;

        if (!fio_fill_issue_time(td))
                return;

        fio_gettime(&now, NULL);

        for (i = 0; i < nr; i++) {
                struct io_u *io_u = io_us[i];

                memcpy(&io_u->issue_time, &now, sizeof(now));
                io_u_queued(td, io_u);
        }
}

static int fio_libaio_commit(struct thread_data *td)
{
        struct libaio_data *ld = td->io_ops_data;
        struct iocb **iocbs;
        struct io_u **io_us;
        struct timespec ts;
        int ret, wait_start = 0;

        if (!ld->queued)
                return 0;

        do {
                long nr = ld->queued;

                nr = min((unsigned int) nr, ld->entries - ld->tail);
                io_us = ld->io_us + ld->tail;
                iocbs = ld->iocbs + ld->tail;

                ret = io_submit(ld->aio_ctx, nr, iocbs);
                if (ret > 0) {
                        fio_libaio_queued(td, io_us, ret);
                        io_u_mark_submit(td, ret);

                        ld->queued -= ret;
                        ring_inc(ld, &ld->tail, ret);
                        ret = 0;
                        wait_start = 0;
                } else if (ret == -EINTR || !ret) {
                        if (!ret)
                                io_u_mark_submit(td, ret);
                        wait_start = 0;
                        continue;
                } else if (ret == -EAGAIN) {
                        /*
                         * If we get EAGAIN, we should break out without
                         * error and let the upper layer reap some
                         * events for us. If we have no queued IO, we
                         * must loop here. If we loop for more than 30s,
                         * just error out, something must be buggy in the
                         * IO path.
                         */
                        if (ld->queued) {
                                ret = 0;
                                break;
                        }
                        if (!wait_start) {
                                fio_gettime(&ts, NULL);
                                wait_start = 1;
                        } else if (mtime_since_now(&ts) > 30000) {
                                log_err("fio: aio appears to be stalled, giving up\n");
                                break;
                        }
                        usleep(1);
                        continue;
                } else if (ret == -ENOMEM) {
                        /*
                         * If we get -ENOMEM, reap events if we can. If
                         * we cannot, treat it as a fatal event since there's
                         * nothing we can do about it.
                         */
                        if (ld->queued)
                                ret = 0;
                        break;
                } else
                        break;
        } while (ld->queued);

        return ret;
}

static int fio_libaio_cancel(struct thread_data *td, struct io_u *io_u)
{
        struct libaio_data *ld = td->io_ops_data;

        return io_cancel(ld->aio_ctx, &io_u->iocb, ld->aio_events);
}

static void fio_libaio_cleanup(struct thread_data *td)
{
        struct libaio_data *ld = td->io_ops_data;

        if (ld) {
                /*
                 * Work-around to avoid huge RCU stalls at exit time. If we
                 * don't do this here, then it'll be torn down by exit_aio().
                 * But for that case we can parallellize the freeing, thus
                 * speeding it up a lot.
                 */
                if (!(td->flags & TD_F_CHILD))
                        io_destroy(ld->aio_ctx);
                free(ld->aio_events);
                free(ld->iocbs);
                free(ld->io_us);
                free(ld);
        }
}

static int fio_libaio_post_init(struct thread_data *td)
{
        struct libaio_data *ld = td->io_ops_data;
        int err;

        err = io_queue_init(td->o.iodepth, &ld->aio_ctx);
        if (err) {
                td_verror(td, -err, "io_queue_init");
                return 1;
        }

        return 0;
}

static int fio_libaio_init(struct thread_data *td)
{
        struct libaio_data *ld;
        struct libaio_options *o = td->eo;
        struct cmdprio *cmdprio = &o->cmdprio;
        int ret;

        ld = calloc(1, sizeof(*ld));

        ld->entries = td->o.iodepth;
        ld->is_pow2 = is_power_of_2(ld->entries);
        ld->aio_events = calloc(ld->entries, sizeof(struct io_event));
        ld->iocbs = calloc(ld->entries, sizeof(struct iocb *));
        ld->io_us = calloc(ld->entries, sizeof(struct io_u *));

        td->io_ops_data = ld;

        ret = fio_cmdprio_init(td, cmdprio, &ld->use_cmdprio);
        if (ret) {
                td_verror(td, EINVAL, "fio_libaio_init");
                return 1;
        }

        return 0;
}

FIO_STATIC struct ioengine_ops ioengine = {
        .name                   = "libaio",
        .version                = FIO_IOOPS_VERSION,
        .flags                  = FIO_ASYNCIO_SYNC_TRIM,
        .init                   = fio_libaio_init,
        .post_init              = fio_libaio_post_init,
        .prep                   = fio_libaio_prep,
        .queue                  = fio_libaio_queue,
        .commit                 = fio_libaio_commit,
        .cancel                 = fio_libaio_cancel,
        .getevents              = fio_libaio_getevents,
        .event                  = fio_libaio_event,
        .cleanup                = fio_libaio_cleanup,
        .open_file              = generic_open_file,
        .close_file             = generic_close_file,
        .get_file_size          = generic_get_file_size,
        .options                = options,
        .option_struct_size     = sizeof(struct libaio_options),
};

static void fio_init fio_libaio_register(void)
{
        register_ioengine(&ioengine);
}

static void fio_exit fio_libaio_unregister(void)
{
        unregister_ioengine(&ioengine);
}