/* * MARS Long Distance Replication Software * * This file is part of MARS project: http://schoebel.github.io/mars/ * * Copyright (C) 2010-2014 Thomas Schoebel-Theuer * Copyright (C) 2011-2014 1&1 Internet AG * * 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ //#define BRICK_DEBUGGING #define MARS_DEBUGGING //#define IO_DEBUGGING #include #include #include #include #include #include #include #include #include #include #include "mars.h" #include "lib_timing.h" #include "lib_mapfree.h" #include "mars_aio.h" #define MARS_MAX_AIO 512 #define MARS_MAX_AIO_READ 32 struct timing_stats timings[3] = {}; struct threshold aio_submit_threshold = { .thr_ban = &mars_global_ban, .thr_parent = &global_io_threshold, .thr_limit = AIO_SUBMIT_MAX_LATENCY, .thr_factor = 10, .thr_plus = 10000, }; EXPORT_SYMBOL_GPL(aio_submit_threshold); struct threshold aio_io_threshold[2] = { [0] = { .thr_ban = &mars_global_ban, .thr_parent = &global_io_threshold, .thr_limit = AIO_IO_R_MAX_LATENCY, .thr_factor = 100, .thr_plus = 0, }, [1] = { .thr_ban = &mars_global_ban, .thr_parent = &global_io_threshold, .thr_limit = AIO_IO_W_MAX_LATENCY, .thr_factor = 100, .thr_plus = 0, }, }; EXPORT_SYMBOL_GPL(aio_io_threshold); struct threshold aio_sync_threshold = { .thr_ban = &mars_global_ban, .thr_limit = AIO_SYNC_MAX_LATENCY, .thr_factor = 100, .thr_plus = 0, }; EXPORT_SYMBOL_GPL(aio_sync_threshold); int aio_sync_mode = 2; EXPORT_SYMBOL_GPL(aio_sync_mode); ///////////////////////// own type definitions //////////////////////// ////////////////// some helpers ////////////////// #ifdef ENABLE_MARS_AIO static inline void _enqueue(struct aio_threadinfo *tinfo, struct aio_mref_aspect *mref_a, int prio, bool at_end) { #if 1 prio++; if (unlikely(prio < 0)) { prio = 0; } else if (unlikely(prio >= MARS_PRIO_NR)) { prio = MARS_PRIO_NR - 1; } #else prio = 0; #endif mref_a->enqueue_stamp = cpu_clock(raw_smp_processor_id()); mutex_lock(&tinfo->mutex); if (at_end) { list_add_tail(&mref_a->io_head, &tinfo->mref_list[prio]); } else { list_add(&mref_a->io_head, &tinfo->mref_list[prio]); } tinfo->queued[prio]++; atomic_inc(&tinfo->queued_sum); mutex_unlock(&tinfo->mutex); atomic_inc(&tinfo->total_enqueue_count); wake_up_interruptible_all(&tinfo->event); } static inline struct aio_mref_aspect *_dequeue(struct aio_threadinfo *tinfo) { struct aio_mref_aspect *mref_a = NULL; int prio; mutex_lock(&tinfo->mutex); for (prio = 0; prio < MARS_PRIO_NR; prio++) { struct list_head *start = &tinfo->mref_list[prio]; struct list_head *tmp = start->next; if (tmp != start) { list_del_init(tmp); tinfo->queued[prio]--; atomic_dec(&tinfo->queued_sum); mref_a = container_of(tmp, struct aio_mref_aspect, io_head); goto done; } } done: mutex_unlock(&tinfo->mutex); if (likely(mref_a && mref_a->object)) { unsigned long long latency; latency = cpu_clock(raw_smp_processor_id()) - mref_a->enqueue_stamp; threshold_check(&aio_io_threshold[mref_a->object->ref_rw & 1], latency); } return mref_a; } ////////////////// own brick / input / output operations ////////////////// static loff_t get_total_size(struct aio_output *output) { /* Workaround for races in the page cache. * It appears that concurrent reads and writes seem to * result in inconsistent reads in some very rare cases, due to * races. Sometimes, the inode claims that the file has been already * appended by a write operation, but the data has not actually hit * the page cache, such that a concurrent read gets NULL blocks. */ return mf_dirty_length(output->mf, DIRTY_COMPLETED); } static int aio_ref_get(struct aio_output *output, struct mref_object *mref) { loff_t total_size; if (unlikely(!output->brick->power.led_on)) return -EBADFD; if (unlikely(!output->mf)) { MARS_ERR("brick is not switched on\n"); return -EILSEQ; } if (unlikely(mref->ref_len <= 0)) { MARS_ERR("bad ref_len=%d\n", mref->ref_len); return -EILSEQ; } total_size = get_total_size(output); if (unlikely(total_size < 0)) { return total_size; } mref->ref_total_size = total_size; if (mref->ref_initialized) { _mref_get(mref); return mref->ref_len; } /* Buffered IO. */ if (!mref->ref_data) { struct aio_mref_aspect *mref_a = aio_mref_get_aspect(output->brick, mref); if (unlikely(!mref_a)) { MARS_ERR("bad mref_a\n"); return -EILSEQ; } if (unlikely(mref->ref_len <= 0)) { MARS_ERR("bad ref_len = %d\n", mref->ref_len); return -ENOMEM; } mref->ref_data = brick_block_alloc(mref->ref_pos, (mref_a->alloc_len = mref->ref_len)); if (unlikely(!mref->ref_data)) { MARS_ERR("ENOMEM %d bytes\n", mref->ref_len); return -ENOMEM; } #if 0 // ??? mref->ref_flags = 0; #endif mref_a->do_dealloc = true; atomic_inc(&output->total_alloc_count); atomic_inc(&output->alloc_count); } _mref_get_first(mref); return mref->ref_len; } static void aio_ref_put(struct aio_output *output, struct mref_object *mref) { struct file *file; struct aio_mref_aspect *mref_a; if (!_mref_put(mref)) { goto done; } if (output->mf && (file = output->mf->mf_filp) && file->f_mapping && file->f_mapping->host) { mref->ref_total_size = get_total_size(output); } mref_a = aio_mref_get_aspect(output->brick, mref); if (mref_a && mref_a->do_dealloc) { brick_block_free(mref->ref_data, mref_a->alloc_len); atomic_dec(&output->alloc_count); } aio_free_mref(mref); done:; } static void _complete(struct aio_output *output, struct aio_mref_aspect *mref_a, int err) { struct mref_object *mref; CHECK_PTR(mref_a, fatal); mref = mref_a->object; CHECK_PTR(mref, fatal); mars_trace(mref, "aio_endio"); if (err < 0) { MARS_ERR("IO error %d at pos=%lld len=%d (mref=%p ref_data=%p)\n", err, mref->ref_pos, mref->ref_len, mref, mref->ref_data); } else { mref_checksum(mref); mref->ref_flags |= MREF_UPTODATE; } CHECKED_CALLBACK(mref, err, err_found); done: if (mref->ref_rw) { mf_dirty_append(output->mf, DIRTY_FINISHED, mref->ref_pos + mref->ref_len); atomic_dec(&output->write_count); } else { atomic_dec(&output->read_count); } aio_ref_put(output, mref); atomic_dec(&output->work_count); atomic_dec(&mars_global_io_flying); return; err_found: MARS_FAT("giving up...\n"); goto done; fatal: MARS_FAT("bad pointer, giving up...\n"); } static void _complete_mref(struct aio_output *output, struct mref_object *mref, int err) { struct aio_mref_aspect *mref_a; _mref_check(mref); mref_a = aio_mref_get_aspect(output->brick, mref); CHECK_PTR(mref_a, fatal); _complete(output, mref_a, err); return; fatal: MARS_FAT("bad pointer, giving up...\n"); } static void _complete_all(struct list_head *tmp_list, struct aio_output *output, int err) { while (!list_empty(tmp_list)) { struct list_head *tmp = tmp_list->next; struct aio_mref_aspect *mref_a = container_of(tmp, struct aio_mref_aspect, io_head); list_del_init(tmp); _complete(output, mref_a, err); } } static void aio_ref_io(struct aio_output *output, struct mref_object *mref) { struct aio_threadinfo *tinfo = &output->tinfo[0]; struct aio_mref_aspect *mref_a; int err = -EINVAL; _mref_check(mref); if (unlikely(!output->brick->power.led_on)) { SIMPLE_CALLBACK(mref, -EBADFD); return; } _mref_get(mref); atomic_inc(&mars_global_io_flying); atomic_inc(&output->work_count); // statistics if (mref->ref_rw) { atomic_inc(&output->total_write_count); atomic_inc(&output->write_count); } else { atomic_inc(&output->total_read_count); atomic_inc(&output->read_count); } if (unlikely(!output->mf || !output->mf->mf_filp)) { goto done; } mapfree_set(output->mf, mref->ref_pos, -1); MARS_IO("AIO rw=%d pos=%lld len=%d data=%p\n", mref->ref_rw, mref->ref_pos, mref->ref_len, mref->ref_data); mref_a = aio_mref_get_aspect(output->brick, mref); if (unlikely(!mref_a)) { goto done; } _enqueue(tinfo, mref_a, mref->ref_prio, true); return; done: _complete_mref(output, mref, err); } static int aio_submit(struct aio_output *output, struct aio_mref_aspect *mref_a, bool use_fdsync) { struct mref_object *mref = mref_a->object; mm_segment_t oldfs; int res; struct iocb iocb = { .aio_data = (__u64)mref_a, .aio_lio_opcode = use_fdsync ? IOCB_CMD_FDSYNC : (mref->ref_rw != 0 ? IOCB_CMD_PWRITE : IOCB_CMD_PREAD), .aio_fildes = output->fd, .aio_buf = (unsigned long)mref->ref_data, .aio_nbytes = mref->ref_len, .aio_offset = mref->ref_pos, // .aio_reqprio = something(mref->ref_prio) field exists, but not yet implemented in kernelspace :( }; struct iocb *iocbp = &iocb; struct timing_stats *this_timing = &timings[mref->ref_rw & 1]; unsigned long long latency; mars_trace(mref, "aio_submit"); if (unlikely(output->fd < 0)) { MARS_ERR("bad fd = %d\n", output->fd); res = -EBADF; goto done; } oldfs = get_fs(); set_fs(get_ds()); latency = TIME_STATS( this_timing, res = sys_io_submit(output->ctxp, 1, &iocbp) ); set_fs(oldfs); threshold_check(&aio_submit_threshold, latency); atomic_inc(&output->total_submit_count); if (likely(res >= 0)) { atomic_inc(&output->submit_count); } else if (likely(res == -EAGAIN)) { atomic_inc(&output->total_again_count); } else { MARS_ERR("error = %d\n", res); } done: return res; } static int aio_submit_dummy(struct aio_output *output) { mm_segment_t oldfs; int res; int dummy; struct iocb iocb = { .aio_buf = (__u64)&dummy, }; struct iocb *iocbp = &iocb; oldfs = get_fs(); set_fs(get_ds()); res = sys_io_submit(output->ctxp, 1, &iocbp); set_fs(oldfs); if (likely(res >= 0)) { atomic_inc(&output->submit_count); } return res; } static int aio_start_thread( struct aio_output *output, struct aio_threadinfo *tinfo, int(*fn)(void*), char class) { int j; for (j = 0; j < MARS_PRIO_NR; j++) { INIT_LIST_HEAD(&tinfo->mref_list[j]); } tinfo->output = output; mutex_init(&tinfo->mutex); init_waitqueue_head(&tinfo->event); init_waitqueue_head(&tinfo->terminate_event); tinfo->should_terminate = false; tinfo->terminated = false; tinfo->thread = brick_thread_create(fn, tinfo, "mars_aio_%c%d", class, output->index); if (unlikely(!tinfo->thread)) { MARS_ERR("cannot create thread\n"); return -ENOENT; } return 0; } static void aio_stop_thread(struct aio_output *output, int i, bool do_submit_dummy) { struct aio_threadinfo *tinfo = &output->tinfo[i]; struct task_struct *thread = tinfo->thread; if (thread) { MARS_DBG("stopping thread %d ...\n", i); tinfo->should_terminate = true; // workaround for waking up the receiver thread. TODO: check whether signal handlong could do better. if (do_submit_dummy) { MARS_DBG("submitting dummy for wakeup %d...\n", i); use_fake_mm(); aio_submit_dummy(output); if (likely(current->mm)) { unuse_fake_mm(); } } // wait for termination MARS_DBG("waiting for thread %d ...\n", i); wait_event_interruptible_timeout( tinfo->terminate_event, tinfo->terminated, (60 - i * 2) * HZ); if (likely(tinfo->terminated)) { brick_thread_stop(tinfo->thread); } else { MARS_ERR("thread %d did not terminate - leaving a zombie\n", i); } } } static int aio_sync(struct file *file) { int err; switch (aio_sync_mode) { case 1: #if defined(S_BIAS) || (defined(RHEL_MAJOR) && (RHEL_MAJOR < 7)) err = vfs_fsync_range(file, file->f_path.dentry, 0, LLONG_MAX, 1); #else err = vfs_fsync_range(file, 0, LLONG_MAX, 1); #endif break; case 2: #if defined(S_BIAS) || (defined(RHEL_MAJOR) && (RHEL_MAJOR < 7)) err = vfs_fsync_range(file, file->f_path.dentry, 0, LLONG_MAX, 0); #else err = vfs_fsync_range(file, 0, LLONG_MAX, 0); #endif break; default: err = filemap_write_and_wait_range(file->f_mapping, 0, LLONG_MAX); } return err; } static void aio_sync_all(struct aio_output *output, struct list_head *tmp_list) { unsigned long long latency; int err; output->fdsync_active = true; atomic_inc(&output->total_fdsync_count); latency = TIME_STATS( &timings[2], err = aio_sync(output->mf->mf_filp) ); threshold_check(&aio_sync_threshold, latency); output->fdsync_active = false; wake_up_interruptible_all(&output->fdsync_event); if (err < 0) { MARS_ERR("FDSYNC error %d\n", err); } /* Signal completion for the whole list. * No locking needed, it's on the stack. */ _complete_all(tmp_list, output, err); } /* Workaround for non-implemented aio_fsync() */ static int aio_sync_thread(void *data) { struct aio_threadinfo *tinfo = data; struct aio_output *output = tinfo->output; MARS_DBG("sync thread has started on '%s'.\n", output->brick->brick_path); //set_user_nice(current, -20); while (!tinfo->should_terminate || atomic_read(&tinfo->queued_sum) > 0) { LIST_HEAD(tmp_list); int i; output->fdsync_active = false; wake_up_interruptible_all(&output->fdsync_event); wait_event_interruptible_timeout( tinfo->event, atomic_read(&tinfo->queued_sum) > 0, HZ / 4); mutex_lock(&tinfo->mutex); for (i = 0; i < MARS_PRIO_NR; i++) { struct list_head *start = &tinfo->mref_list[i]; if (!list_empty(start)) { // move over the whole list list_replace_init(start, &tmp_list); atomic_sub(tinfo->queued[i], &tinfo->queued_sum); tinfo->queued[i] = 0; break; } } mutex_unlock(&tinfo->mutex); if (!list_empty(&tmp_list)) { aio_sync_all(output, &tmp_list); } } MARS_DBG("sync thread has stopped.\n"); tinfo->terminated = true; wake_up_interruptible_all(&tinfo->terminate_event); return 0; } static int aio_event_thread(void *data) { struct aio_threadinfo *tinfo = data; struct aio_output *output = tinfo->output; struct aio_threadinfo *other = &output->tinfo[2]; struct io_event *events; int err = -ENOMEM; events = brick_mem_alloc(sizeof(struct io_event) * MARS_MAX_AIO_READ); MARS_DBG("event thread has started.\n"); //set_user_nice(current, -20); use_fake_mm(); if (!current->mm) goto err; err = aio_start_thread(output, &output->tinfo[2], aio_sync_thread, 'y'); if (unlikely(err < 0)) goto err; while (!tinfo->should_terminate || atomic_read(&tinfo->queued_sum) > 0) { mm_segment_t oldfs; int count; int i; struct timespec timeout = { .tv_sec = 1, }; if (unlikely(!(void*)output->ctxp)) { MARS_ERR("Oops, context vanished. queued_sum = %d\n", atomic_read(&tinfo->queued_sum)); break; } #ifdef CONFIG_MARS_DEBUG if (mars_hang_mode & 1) { brick_msleep(100); continue; } #endif oldfs = get_fs(); set_fs(get_ds()); /* TODO: don't timeout upon termination. * Probably we should submit a dummy request. */ count = sys_io_getevents(output->ctxp, 1, MARS_MAX_AIO_READ, events, &timeout); set_fs(oldfs); if (likely(count > 0)) { atomic_sub(count, &output->submit_count); } for (i = 0; i < count; i++) { struct aio_mref_aspect *mref_a = (void*)events[i].data; struct mref_object *mref; int err = events[i].res; if (!mref_a) { continue; // this was a dummy request } mref = mref_a->object; MARS_IO("AIO done %p pos = %lld len = %d rw = %d\n", mref, mref->ref_pos, mref->ref_len, mref->ref_rw); mapfree_set(output->mf, mref->ref_pos, mref->ref_pos + mref->ref_len); if (mref->ref_rw) mf_dirty_append(output->mf, DIRTY_COMPLETED, mref->ref_pos + mref->ref_len); /* Workaround for never implemented aio_fsync operation, * see also upstream commit 723c038475b78edc9327eb952f95f9881cc9d7. * FIXME: don't use aio anymore at all in the long-term future. */ if (output->brick->o_fdsync && err >= 0 && mref->ref_rw != READ && !mref->ref_skip_sync && !mref_a->resubmit++) { mars_trace(mref, "aio_fsync"); _enqueue(other, mref_a, mref->ref_prio, true); continue; } _complete(output, mref_a, err); } } err = 0; err: MARS_DBG("event thread has stopped, err = %d\n", err); aio_stop_thread(output, 2, false); unuse_fake_mm(); tinfo->terminated = true; wake_up_interruptible_all(&tinfo->terminate_event); brick_mem_free(events); return err; } #if 1 /* This should go to fs/open.c (as long as vfs_submit() is not implemented) */ #include void fd_uninstall(unsigned int fd) { struct files_struct *files = current->files; struct fdtable *fdt; unsigned long flags; MARS_DBG("fd = %d\n", fd); if (unlikely(fd < 0)) { MARS_ERR("bad fd = %d\n", fd); return; } spin_lock_irqsave(&files->file_lock, flags); fdt = files_fdtable(files); rcu_assign_pointer(fdt->fd[fd], NULL); spin_unlock_irqrestore(&files->file_lock, flags); } EXPORT_SYMBOL(fd_uninstall); #endif static atomic_t ioctx_count = ATOMIC_INIT(0); static void _destroy_ioctx(struct aio_output *output) { if (unlikely(!output)) goto done; aio_stop_thread(output, 1, true); use_fake_mm(); if (likely(output->ctxp)) { mm_segment_t oldfs; int err; MARS_DBG("ioctx count = %d destroying %p\n", atomic_read(&ioctx_count), (void*)output->ctxp); oldfs = get_fs(); set_fs(get_ds()); err = sys_io_destroy(output->ctxp); set_fs(oldfs); atomic_dec(&ioctx_count); MARS_DBG("ioctx count = %d status = %d\n", atomic_read(&ioctx_count), err); output->ctxp = 0; } if (likely(output->fd >= 0)) { MARS_DBG("destroying fd %d\n", output->fd); fd_uninstall(output->fd); put_unused_fd(output->fd); output->fd = -1; } done: if (likely(current->mm)) { unuse_fake_mm(); } } /* TODO: this is provisionary. We only need it for sys_io_submit() * which uses userspace concepts like file handles. * This should be replaced by a future kernelsapce vfs_submit() or * do_submit() which currently does not exist :( * Or, the whole aio brick should be replaced by something else. * A good candidate could be the new {read,write}_iter() infrastructure. * But only present at newer kernels. * Unfortunately I will have to support old kernels for a while :( */ static int _get_fd(void) { int err; do { /* see f938612dd97d481b8b5bf960c992ae577f081c17 * and 1a7bd2265fc57f29400d57f66275cc5918e30aa6 */ #if defined(get_unused_fd) || defined(get_unused_fd_flags) err = get_unused_fd(); #else err = get_unused_fd_flags(0); #endif /* safety workaround: skip standard Unix filehandles */ } while (err >= 0 && err <= 2); return err; } static int _create_ioctx(struct aio_output *output) { struct file *file; mm_segment_t oldfs; int err = -EINVAL; CHECK_PTR_NULL(output, done); CHECK_PTR_NULL(output->mf, done); file = output->mf->mf_filp; CHECK_PTR_NULL(file, done); err = _get_fd(); MARS_DBG("file %p '%s' new fd = %d\n", file, output->mf->mf_name, err); if (unlikely(err < 0)) { MARS_ERR("cannot get fd, err=%d\n", err); goto done; } output->fd = err; fd_install(err, file); use_fake_mm(); err = -ENOMEM; if (unlikely(!current->mm)) { MARS_ERR("cannot fake mm\n"); goto done; } MARS_DBG("ioctx count = %d old = %p\n", atomic_read(&ioctx_count), (void*)output->ctxp); output->ctxp = 0; oldfs = get_fs(); set_fs(get_ds()); err = sys_io_setup(MARS_MAX_AIO, &output->ctxp); set_fs(oldfs); if (likely(output->ctxp)) atomic_inc(&ioctx_count); MARS_DBG("ioctx count = %d new = %p status = %d\n", atomic_read(&ioctx_count), (void*)output->ctxp, err); if (unlikely(err < 0)) { MARS_ERR("io_setup failed, err=%d\n", err); goto done; } err = aio_start_thread(output, &output->tinfo[1], aio_event_thread, 'e'); if (unlikely(err < 0)) { MARS_ERR("could not start event thread\n"); goto done; } done: if (likely(current->mm)) { unuse_fake_mm(); } return err; } static int aio_submit_thread(void *data) { struct aio_threadinfo *tinfo = data; struct aio_output *output = tinfo->output; struct file *file; int err = -EINVAL; MARS_DBG("submit thread has started.\n"); file = output->mf->mf_filp; use_fake_mm(); while (!tinfo->should_terminate || atomic_read(&output->read_count) + atomic_read(&output->write_count) + atomic_read(&tinfo->queued_sum) > 0) { struct aio_mref_aspect *mref_a; struct mref_object *mref; int sleeptime; int status; wait_event_interruptible_timeout( tinfo->event, atomic_read(&tinfo->queued_sum) > 0, HZ / 4); mref_a = _dequeue(tinfo); if (!mref_a) { continue; } mref = mref_a->object; status = -EINVAL; CHECK_PTR(mref, error); mapfree_set(output->mf, mref->ref_pos, -1); if (mref->ref_rw) { mf_dirty_append(output->mf, DIRTY_SUBMITTED, mref->ref_pos + mref->ref_len); } mref->ref_total_size = get_total_size(output); // check for reads crossing the EOF boundary (special case) if (mref->ref_timeout > 0 && !mref->ref_rw && mref->ref_pos + mref->ref_len > mref->ref_total_size) { loff_t len = mref->ref_total_size - mref->ref_pos; if (len > 0) { if (mref->ref_len > len) mref->ref_len = len; } else { if (!mref_a->start_jiffies) { mref_a->start_jiffies = jiffies; } if ((long long)jiffies - mref_a->start_jiffies <= mref->ref_timeout) { if (atomic_read(&tinfo->queued_sum) <= 0) { atomic_inc(&output->total_msleep_count); brick_msleep(1000 * 4 / HZ); } _enqueue(tinfo, mref_a, MARS_PRIO_LOW, true); continue; } MARS_DBG("ENODATA %lld\n", len); _complete(output, mref_a, -ENODATA); continue; } } sleeptime = 1; for (;;) { status = aio_submit(output, mref_a, false); if (likely(status != -EAGAIN)) { break; } atomic_inc(&output->total_delay_count); brick_msleep(sleeptime); if (sleeptime < 100) { sleeptime++; } } error: if (unlikely(status < 0)) { MARS_IO("submit_count = %d status = %d\n", atomic_read(&output->submit_count), status); _complete_mref(output, mref, status); } } MARS_DBG("submit thread has stopped, status = %d.\n", err); if (likely(current->mm)) { unuse_fake_mm(); } tinfo->terminated = true; wake_up_interruptible_all(&tinfo->terminate_event); return err; } static int aio_get_info(struct aio_output *output, struct mars_info *info) { struct file *file; if (unlikely(!output || !output->mf || !(file = output->mf->mf_filp) || !file->f_mapping || !file->f_mapping->host)) return -EINVAL; info->tf_align = 1; info->tf_min_size = 1; info->current_size = get_total_size(output); MARS_DBG("determined file size = %lld\n", info->current_size); return 0; } //////////////// informational / statistics /////////////// static noinline char *aio_statistics(struct aio_brick *brick, int verbose) { struct aio_output *output = brick->outputs[0]; char *res = brick_string_alloc(4096); char *sync = NULL; int pos = 0; if (!res) return NULL; pos += report_timing(&timings[0], res + pos, 4096 - pos); pos += report_timing(&timings[1], res + pos, 4096 - pos); pos += report_timing(&timings[2], res + pos, 4096 - pos); snprintf(res + pos, 4096 - pos, "total " "reads = %d " "writes = %d " "allocs = %d " "submits = %d " "again = %d " "delays = %d " "msleeps = %d " "fdsyncs = %d " "fdsync_waits = %d " "map_free = %d | " "flying reads = %d " "writes = %d " "allocs = %d " "submits = %d " "q0 = %d " "q1 = %d " "q2 = %d " "| total " "q0 = %d " "q1 = %d " "q2 = %d " "%s\n", atomic_read(&output->total_read_count), atomic_read(&output->total_write_count), atomic_read(&output->total_alloc_count), atomic_read(&output->total_submit_count), atomic_read(&output->total_again_count), atomic_read(&output->total_delay_count), atomic_read(&output->total_msleep_count), atomic_read(&output->total_fdsync_count), atomic_read(&output->total_fdsync_wait_count), atomic_read(&output->total_mapfree_count), atomic_read(&output->read_count), atomic_read(&output->write_count), atomic_read(&output->alloc_count), atomic_read(&output->submit_count), atomic_read(&output->tinfo[0].queued_sum), atomic_read(&output->tinfo[1].queued_sum), atomic_read(&output->tinfo[2].queued_sum), atomic_read(&output->tinfo[0].total_enqueue_count), atomic_read(&output->tinfo[1].total_enqueue_count), atomic_read(&output->tinfo[2].total_enqueue_count), sync ? sync : ""); if (sync) brick_string_free(sync); return res; } static noinline void aio_reset_statistics(struct aio_brick *brick) { struct aio_output *output = brick->outputs[0]; int i; atomic_set(&output->total_read_count, 0); atomic_set(&output->total_write_count, 0); atomic_set(&output->total_alloc_count, 0); atomic_set(&output->total_submit_count, 0); atomic_set(&output->total_again_count, 0); atomic_set(&output->total_delay_count, 0); atomic_set(&output->total_msleep_count, 0); atomic_set(&output->total_fdsync_count, 0); atomic_set(&output->total_fdsync_wait_count, 0); atomic_set(&output->total_mapfree_count, 0); for (i = 0; i < 3; i++) { struct aio_threadinfo *tinfo = &output->tinfo[i]; atomic_set(&tinfo->total_enqueue_count, 0); } } #endif /* ENABLE_MARS_AIO */ //////////////// object / aspect constructors / destructors /////////////// static int aio_mref_aspect_init_fn(struct generic_aspect *_ini) { struct aio_mref_aspect *ini = (void*)_ini; INIT_LIST_HEAD(&ini->io_head); return 0; } static void aio_mref_aspect_exit_fn(struct generic_aspect *_ini) { struct aio_mref_aspect *ini = (void*)_ini; CHECK_HEAD_EMPTY(&ini->io_head); } MARS_MAKE_STATICS(aio); #ifdef ENABLE_MARS_AIO ////////////////////// brick constructors / destructors //////////////////// static int aio_brick_construct(struct aio_brick *brick) { return 0; } static int aio_switch(struct aio_brick *brick) { static int index; struct aio_output *output = brick->outputs[0]; const char *path = output->brick->brick_path; int flags = O_RDWR | O_LARGEFILE; int status = 0; MARS_DBG("power.button = %d\n", brick->power.button); if (!brick->power.button) goto cleanup; if (brick->power.led_on || output->mf) goto done; mars_power_led_off((void*)brick, false); if (brick->o_creat) { flags |= O_CREAT; MARS_DBG("using O_CREAT on %s\n", path); } if (brick->o_direct) { flags |= O_DIRECT; MARS_DBG("using O_DIRECT on %s\n", path); } output->mf = mapfree_get(path, flags); if (unlikely(!output->mf)) { MARS_ERR("could not open file = '%s' flags = %d\n", path, flags); status = -ENOENT; goto err; } output->index = ++index; status = _create_ioctx(output); if (unlikely(status < 0)) { MARS_ERR("could not create ioctx, status = %d\n", status); goto err; } status = aio_start_thread(output, &output->tinfo[0], aio_submit_thread, 's'); if (unlikely(status < 0)) { MARS_ERR("could not start theads, status = %d\n", status); goto err; } MARS_DBG("opened file '%s'\n", path); brick->mode_ptr = &output->mf->mf_mode; mars_power_led_on((void*)brick, true); done: return 0; err: MARS_ERR("status = %d\n", status); cleanup: if (brick->power.led_off) { goto done; } mars_power_led_on((void*)brick, false); for (;;) { int count = atomic_read(&output->work_count); if (count <= 0) break; MARS_DBG("working on %d requests\n", count); brick_msleep(1000); } aio_stop_thread(output, 0, false); brick->mode_ptr = NULL; _destroy_ioctx(output); mars_power_led_off((void*)brick, (output->tinfo[0].thread == NULL && output->tinfo[1].thread == NULL && output->tinfo[2].thread == NULL)); MARS_DBG("switch off led_off = %d status = %d\n", brick->power.led_off, status); if (brick->power.led_off) { if (output->mf) { MARS_DBG("closing file = '%s'\n", output->mf->mf_name); mapfree_put(output->mf); output->mf = NULL; } } return status; } static int aio_output_construct(struct aio_output *output) { init_waitqueue_head(&output->fdsync_event); output->fd = -1; return 0; } static int aio_output_destruct(struct aio_output *output) { if (unlikely(output->fd >= 0)) { MARS_ERR("active fd = %d detected\n", output->fd); } return 0; } ///////////////////////// static structs //////////////////////// static struct aio_brick_ops aio_brick_ops = { .brick_switch = aio_switch, .brick_statistics = aio_statistics, .reset_statistics = aio_reset_statistics, }; static struct aio_output_ops aio_output_ops = { .mref_get = aio_ref_get, .mref_put = aio_ref_put, .mref_io = aio_ref_io, .mars_get_info = aio_get_info, }; const struct aio_input_type aio_input_type = { .type_name = "aio_input", .input_size = sizeof(struct aio_input), }; static const struct aio_input_type *aio_input_types[] = { &aio_input_type, }; const struct aio_output_type aio_output_type = { .type_name = "aio_output", .output_size = sizeof(struct aio_output), .master_ops = &aio_output_ops, .output_construct = &aio_output_construct, .output_destruct = &aio_output_destruct, }; static const struct aio_output_type *aio_output_types[] = { &aio_output_type, }; #endif /* ENABLE_MARS_AIO */ const struct aio_brick_type aio_brick_type = { .type_name = "aio_brick", .brick_size = sizeof(struct aio_brick), .max_inputs = 0, .max_outputs = 1, #ifdef ENABLE_MARS_AIO .master_ops = &aio_brick_ops, .aspect_types = aio_aspect_types, .default_input_types = aio_input_types, .default_output_types = aio_output_types, .brick_construct = &aio_brick_construct, #else /* ENABLE_MARS_AIO */ .aspect_types = aio_aspect_types, /* dummy, shut up gcc */ #endif /* ENABLE_MARS_AIO */ }; EXPORT_SYMBOL_GPL(aio_brick_type); ////////////////// module init stuff ///////////////////////// int __init init_mars_aio(void) { MARS_DBG("init_aio()\n"); _aio_brick_type = (void*)&aio_brick_type; return aio_register_brick_type(); } void exit_mars_aio(void) { MARS_DBG("exit_aio()\n"); aio_unregister_brick_type(); }