mirror_zfs/module/zfs/vdev_disk.c

848 lines
21 KiB
C
Raw Normal View History

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright (C) 2008-2010 Lawrence Livermore National Security, LLC.
* Produced at Lawrence Livermore National Laboratory (cf, DISCLAIMER).
* Rewritten for Linux by Brian Behlendorf <behlendorf1@llnl.gov>.
* LLNL-CODE-403049.
* Copyright (c) 2012, 2014 by Delphix. All rights reserved.
*/
#include <sys/zfs_context.h>
#include <sys/spa.h>
#include <sys/vdev_disk.h>
#include <sys/vdev_impl.h>
#include <sys/fs/zfs.h>
#include <sys/zio.h>
#include <sys/sunldi.h>
char *zfs_vdev_scheduler = VDEV_SCHEDULER;
static void *zfs_vdev_holder = VDEV_HOLDER;
/*
* Virtual device vector for disks.
*/
typedef struct dio_request {
struct completion dr_comp; /* Completion for sync IO */
atomic_t dr_ref; /* References */
zio_t *dr_zio; /* Parent ZIO */
int dr_rw; /* Read/Write */
int dr_error; /* Bio error */
int dr_bio_count; /* Count of bio's */
struct bio *dr_bio[0]; /* Attached bio's */
} dio_request_t;
#ifdef HAVE_OPEN_BDEV_EXCLUSIVE
static fmode_t
vdev_bdev_mode(int smode)
{
fmode_t mode = 0;
ASSERT3S(smode & (FREAD | FWRITE), !=, 0);
if (smode & FREAD)
mode |= FMODE_READ;
if (smode & FWRITE)
mode |= FMODE_WRITE;
return (mode);
}
#else
static int
vdev_bdev_mode(int smode)
{
int mode = 0;
ASSERT3S(smode & (FREAD | FWRITE), !=, 0);
if ((smode & FREAD) && !(smode & FWRITE))
mode = MS_RDONLY;
return (mode);
}
#endif /* HAVE_OPEN_BDEV_EXCLUSIVE */
static uint64_t
bdev_capacity(struct block_device *bdev)
{
struct hd_struct *part = bdev->bd_part;
/* The partition capacity referenced by the block device */
if (part)
return (part->nr_sects << 9);
/* Otherwise assume the full device capacity */
return (get_capacity(bdev->bd_disk) << 9);
}
static void
vdev_disk_error(zio_t *zio)
{
#ifdef ZFS_DEBUG
printk("ZFS: zio error=%d type=%d offset=%llu size=%llu "
"flags=%x delay=%llu\n", zio->io_error, zio->io_type,
(u_longlong_t)zio->io_offset, (u_longlong_t)zio->io_size,
zio->io_flags, (u_longlong_t)zio->io_delay);
#endif
}
/*
* Use the Linux 'noop' elevator for zfs managed block devices. This
* strikes the ideal balance by allowing the zfs elevator to do all
* request ordering and prioritization. While allowing the Linux
* elevator to do the maximum front/back merging allowed by the
* physical device. This yields the largest possible requests for
* the device with the lowest total overhead.
*/
static int
vdev_elevator_switch(vdev_t *v, char *elevator)
{
vdev_disk_t *vd = v->vdev_tsd;
struct block_device *bdev = vd->vd_bdev;
struct request_queue *q = bdev_get_queue(bdev);
char *device = bdev->bd_disk->disk_name;
int error;
/*
* Skip devices which are not whole disks (partitions).
* Device-mapper devices are excepted since they may be whole
* disks despite the vdev_wholedisk flag, in which case we can
* and should switch the elevator. If the device-mapper device
* does not have an elevator (i.e. dm-raid, dm-crypt, etc.) the
* "Skip devices without schedulers" check below will fail.
*/
if (!v->vdev_wholedisk && strncmp(device, "dm-", 3) != 0)
return (0);
/* Skip devices without schedulers (loop, ram, dm, etc) */
if (!q->elevator || !blk_queue_stackable(q))
return (0);
/* Leave existing scheduler when set to "none" */
if (strncmp(elevator, "none", 4) && (strlen(elevator) == 4) == 0)
return (0);
#ifdef HAVE_ELEVATOR_CHANGE
error = elevator_change(q, elevator);
#else
/*
* For pre-2.6.36 kernels elevator_change() is not available.
* Therefore we fall back to using a usermodehelper to echo the
* elevator into sysfs; This requires /bin/echo and sysfs to be
* mounted which may not be true early in the boot process.
*/
#define SET_SCHEDULER_CMD \
"exec 0</dev/null " \
" 1>/sys/block/%s/queue/scheduler " \
" 2>/dev/null; " \
"echo %s"
{
char *argv[] = { "/bin/sh", "-c", NULL, NULL };
char *envp[] = { NULL };
argv[2] = kmem_asprintf(SET_SCHEDULER_CMD, device, elevator);
error = call_usermodehelper(argv[0], argv, envp, UMH_WAIT_PROC);
strfree(argv[2]);
}
#endif /* HAVE_ELEVATOR_CHANGE */
if (error)
printk("ZFS: Unable to set \"%s\" scheduler for %s (%s): %d\n",
elevator, v->vdev_path, device, error);
return (error);
}
/*
* Expanding a whole disk vdev involves invoking BLKRRPART on the
* whole disk device. This poses a problem, because BLKRRPART will
* return EBUSY if one of the disk's partitions is open. That's why
* we have to do it here, just before opening the data partition.
* Unfortunately, BLKRRPART works by dropping all partitions and
* recreating them, which means that for a short time window, all
* /dev/sdxN device files disappear (until udev recreates them).
* This means two things:
* - When we open the data partition just after a BLKRRPART, we
* can't do it using the normal device file path because of the
* obvious race condition with udev. Instead, we use reliable
* kernel APIs to get a handle to the new partition device from
* the whole disk device.
* - Because vdev_disk_open() initially needs to find the device
* using its path, multiple vdev_disk_open() invocations in
* short succession on the same disk with BLKRRPARTs in the
* middle have a high probability of failure (because of the
* race condition with udev). A typical situation where this
* might happen is when the zpool userspace tool does a
* TRYIMPORT immediately followed by an IMPORT. For this
* reason, we only invoke BLKRRPART in the module when strictly
* necessary (zpool online -e case), and rely on userspace to
* do it when possible.
*/
static struct block_device *
vdev_disk_rrpart(const char *path, int mode, vdev_disk_t *vd)
{
#if defined(HAVE_3ARG_BLKDEV_GET) && defined(HAVE_GET_GENDISK)
struct block_device *bdev, *result = ERR_PTR(-ENXIO);
struct gendisk *disk;
int error, partno;
bdev = vdev_bdev_open(path, vdev_bdev_mode(mode), zfs_vdev_holder);
if (IS_ERR(bdev))
return (bdev);
disk = get_gendisk(bdev->bd_dev, &partno);
vdev_bdev_close(bdev, vdev_bdev_mode(mode));
if (disk) {
bdev = bdget(disk_devt(disk));
if (bdev) {
error = blkdev_get(bdev, vdev_bdev_mode(mode), vd);
if (error == 0)
error = ioctl_by_bdev(bdev, BLKRRPART, 0);
vdev_bdev_close(bdev, vdev_bdev_mode(mode));
}
bdev = bdget_disk(disk, partno);
if (bdev) {
error = blkdev_get(bdev,
vdev_bdev_mode(mode) | FMODE_EXCL, vd);
if (error == 0)
result = bdev;
}
put_disk(disk);
}
return (result);
#else
return (ERR_PTR(-EOPNOTSUPP));
#endif /* defined(HAVE_3ARG_BLKDEV_GET) && defined(HAVE_GET_GENDISK) */
}
static int
vdev_disk_open(vdev_t *v, uint64_t *psize, uint64_t *max_psize,
uint64_t *ashift)
{
struct block_device *bdev = ERR_PTR(-ENXIO);
vdev_disk_t *vd;
int mode, block_size;
/* Must have a pathname and it must be absolute. */
if (v->vdev_path == NULL || v->vdev_path[0] != '/') {
v->vdev_stat.vs_aux = VDEV_AUX_BAD_LABEL;
return (EINVAL);
}
/*
* Reopen the device if it's not currently open. Otherwise,
* just update the physical size of the device.
*/
if (v->vdev_tsd != NULL) {
ASSERT(v->vdev_reopening);
vd = v->vdev_tsd;
goto skip_open;
}
vd = kmem_zalloc(sizeof (vdev_disk_t), KM_SLEEP);
if (vd == NULL)
return (ENOMEM);
/*
* Devices are always opened by the path provided at configuration
* time. This means that if the provided path is a udev by-id path
* then drives may be recabled without an issue. If the provided
* path is a udev by-path path, then the physical location information
* will be preserved. This can be critical for more complicated
* configurations where drives are located in specific physical
* locations to maximize the systems tolerence to component failure.
* Alternatively, you can provide your own udev rule to flexibly map
* the drives as you see fit. It is not advised that you use the
* /dev/[hd]d devices which may be reordered due to probing order.
* Devices in the wrong locations will be detected by the higher
* level vdev validation.
*/
mode = spa_mode(v->vdev_spa);
if (v->vdev_wholedisk && v->vdev_expanding)
bdev = vdev_disk_rrpart(v->vdev_path, mode, vd);
if (IS_ERR(bdev))
bdev = vdev_bdev_open(v->vdev_path,
vdev_bdev_mode(mode), zfs_vdev_holder);
if (IS_ERR(bdev)) {
kmem_free(vd, sizeof (vdev_disk_t));
return (-PTR_ERR(bdev));
}
v->vdev_tsd = vd;
vd->vd_bdev = bdev;
skip_open:
/* Determine the physical block size */
block_size = vdev_bdev_block_size(vd->vd_bdev);
/* Clear the nowritecache bit, causes vdev_reopen() to try again. */
v->vdev_nowritecache = B_FALSE;
/* Inform the ZIO pipeline that we are non-rotational */
v->vdev_nonrot = blk_queue_nonrot(bdev_get_queue(vd->vd_bdev));
/* Physical volume size in bytes */
*psize = bdev_capacity(vd->vd_bdev);
/* TODO: report possible expansion size */
*max_psize = *psize;
/* Based on the minimum sector size set the block size */
*ashift = highbit64(MAX(block_size, SPA_MINBLOCKSIZE)) - 1;
/* Try to set the io scheduler elevator algorithm */
(void) vdev_elevator_switch(v, zfs_vdev_scheduler);
return (0);
}
static void
vdev_disk_close(vdev_t *v)
{
vdev_disk_t *vd = v->vdev_tsd;
if (v->vdev_reopening || vd == NULL)
return;
if (vd->vd_bdev != NULL)
vdev_bdev_close(vd->vd_bdev,
vdev_bdev_mode(spa_mode(v->vdev_spa)));
kmem_free(vd, sizeof (vdev_disk_t));
v->vdev_tsd = NULL;
}
static dio_request_t *
vdev_disk_dio_alloc(int bio_count)
{
dio_request_t *dr;
int i;
dr = kmem_zalloc(sizeof (dio_request_t) +
sizeof (struct bio *) * bio_count, KM_SLEEP);
if (dr) {
init_completion(&dr->dr_comp);
atomic_set(&dr->dr_ref, 0);
dr->dr_bio_count = bio_count;
dr->dr_error = 0;
for (i = 0; i < dr->dr_bio_count; i++)
dr->dr_bio[i] = NULL;
}
return (dr);
}
static void
vdev_disk_dio_free(dio_request_t *dr)
{
int i;
for (i = 0; i < dr->dr_bio_count; i++)
if (dr->dr_bio[i])
bio_put(dr->dr_bio[i]);
kmem_free(dr, sizeof (dio_request_t) +
sizeof (struct bio *) * dr->dr_bio_count);
}
static void
vdev_disk_dio_get(dio_request_t *dr)
{
atomic_inc(&dr->dr_ref);
}
static int
vdev_disk_dio_put(dio_request_t *dr)
{
int rc = atomic_dec_return(&dr->dr_ref);
/*
* Free the dio_request when the last reference is dropped and
* ensure zio_interpret is called only once with the correct zio
*/
if (rc == 0) {
zio_t *zio = dr->dr_zio;
int error = dr->dr_error;
vdev_disk_dio_free(dr);
if (zio) {
zio->io_delay = jiffies_64 - zio->io_delay;
zio->io_error = error;
ASSERT3S(zio->io_error, >=, 0);
if (zio->io_error)
vdev_disk_error(zio);
zio_interrupt(zio);
}
}
return (rc);
}
BIO_END_IO_PROTO(vdev_disk_physio_completion, bio, error)
{
dio_request_t *dr = bio->bi_private;
int rc;
if (dr->dr_error == 0) {
#ifdef HAVE_1ARG_BIO_END_IO_T
dr->dr_error = -(bio->bi_error);
#else
if (error)
dr->dr_error = -(error);
else if (!test_bit(BIO_UPTODATE, &bio->bi_flags))
dr->dr_error = EIO;
#endif
}
/* Drop reference aquired by __vdev_disk_physio */
rc = vdev_disk_dio_put(dr);
/* Wake up synchronous waiter this is the last outstanding bio */
if (rc == 1)
complete(&dr->dr_comp);
}
static inline unsigned long
bio_nr_pages(void *bio_ptr, unsigned int bio_size)
{
return ((((unsigned long)bio_ptr + bio_size + PAGE_SIZE - 1) >>
PAGE_SHIFT) - ((unsigned long)bio_ptr >> PAGE_SHIFT));
}
static unsigned int
bio_map(struct bio *bio, void *bio_ptr, unsigned int bio_size)
{
unsigned int offset, size, i;
struct page *page;
offset = offset_in_page(bio_ptr);
for (i = 0; i < bio->bi_max_vecs; i++) {
size = PAGE_SIZE - offset;
if (bio_size <= 0)
break;
if (size > bio_size)
size = bio_size;
if (is_vmalloc_addr(bio_ptr))
page = vmalloc_to_page(bio_ptr);
else
page = virt_to_page(bio_ptr);
/*
* Some network related block device uses tcp_sendpage, which
* doesn't behave well when using 0-count page, this is a
* safety net to catch them.
*/
ASSERT3S(page_count(page), >, 0);
if (bio_add_page(bio, page, size, offset) != size)
break;
bio_ptr += size;
bio_size -= size;
offset = 0;
}
return (bio_size);
}
zvol processing should use struct bio Internally, zvols are files exposed through the block device API. This is intended to reduce overhead when things require block devices. However, the ZoL zvol code emulates a traditional block device in that it has a top half and a bottom half. This is an unnecessary source of overhead that does not exist on any other OpenZFS platform does this. This patch removes it. Early users of this patch reported double digit performance gains in IOPS on zvols in the range of 50% to 80%. Comments in the code suggest that the current implementation was done to obtain IO merging from Linux's IO elevator. However, the DMU already does write merging while arc_read() should implicitly merge read IOs because only 1 thread is permitted to fetch the buffer into ARC. In addition, commercial ZFSOnLinux distributions report that regular files are more performant than zvols under the current implementation, and the main consumers of zvols are VMs and iSCSI targets, which have their own elevators to merge IOs. Some minor refactoring allows us to register zfs_request() as our ->make_request() handler in place of the generic_make_request() function. This eliminates the layer of code that broke IO requests on zvols into a top half and a bottom half. This has several benefits: 1. No per zvol spinlocks. 2. No redundant IO elevator processing. 3. Interrupts are disabled only when actually necessary. 4. No redispatching of IOs when all taskq threads are busy. 5. Linux's page out routines will properly block. 6. Many autotools checks become obsolete. An unfortunate consequence of eliminating the layer that generic_make_request() is that we no longer calls the instrumentation hooks for block IO accounting. Those hooks are GPL-exported, so we cannot call them ourselves and consequently, we lose the ability to do IO monitoring via iostat. Since zvols are internally files mapped as block devices, this should be okay. Anyone who is willing to accept the performance penalty for the block IO layer's accounting could use the loop device in between the zvol and its consumer. Alternatively, perf and ftrace likely could be used. Also, tools like latencytop will still work. Tools such as latencytop sometimes provide a better view of performance bottlenecks than the traditional block IO accounting tools do. Lastly, if direct reclaim occurs during spacemap loading and swap is on a zvol, this code will deadlock. That deadlock could already occur with sync=always on zvols. Given that swap on zvols is not yet production ready, this is not a blocker. Signed-off-by: Richard Yao <ryao@gentoo.org>
2014-07-05 02:43:47 +04:00
static inline void
vdev_submit_bio(int rw, struct bio *bio)
{
#ifdef HAVE_CURRENT_BIO_TAIL
struct bio **bio_tail = current->bio_tail;
current->bio_tail = NULL;
submit_bio(rw, bio);
current->bio_tail = bio_tail;
#else
struct bio_list *bio_list = current->bio_list;
current->bio_list = NULL;
submit_bio(rw, bio);
current->bio_list = bio_list;
#endif
}
static int
__vdev_disk_physio(struct block_device *bdev, zio_t *zio, caddr_t kbuf_ptr,
size_t kbuf_size, uint64_t kbuf_offset, int flags, int wait)
{
dio_request_t *dr;
caddr_t bio_ptr;
uint64_t bio_offset;
int bio_size, bio_count = 16;
int i = 0, error = 0;
ASSERT3U(kbuf_offset + kbuf_size, <=, bdev->bd_inode->i_size);
retry:
dr = vdev_disk_dio_alloc(bio_count);
if (dr == NULL)
return (ENOMEM);
if (zio && !(zio->io_flags & (ZIO_FLAG_IO_RETRY | ZIO_FLAG_TRYHARD)))
bio_set_flags_failfast(bdev, &flags);
dr->dr_zio = zio;
dr->dr_rw = flags;
/*
* When the IO size exceeds the maximum bio size for the request
* queue we are forced to break the IO in multiple bio's and wait
* for them all to complete. Ideally, all pool users will set
* their volume block size to match the maximum request size and
* the common case will be one bio per vdev IO request.
*/
bio_ptr = kbuf_ptr;
bio_offset = kbuf_offset;
bio_size = kbuf_size;
for (i = 0; i <= dr->dr_bio_count; i++) {
/* Finished constructing bio's for given buffer */
if (bio_size <= 0)
break;
/*
* By default only 'bio_count' bio's per dio are allowed.
* However, if we find ourselves in a situation where more
* are needed we allocate a larger dio and warn the user.
*/
if (dr->dr_bio_count == i) {
vdev_disk_dio_free(dr);
bio_count *= 2;
goto retry;
}
/* bio_alloc() with __GFP_WAIT never returns NULL */
Illumos 5027 - zfs large block support 5027 zfs large block support Reviewed by: Alek Pinchuk <pinchuk.alek@gmail.com> Reviewed by: George Wilson <george.wilson@delphix.com> Reviewed by: Josef 'Jeff' Sipek <josef.sipek@nexenta.com> Reviewed by: Richard Elling <richard.elling@richardelling.com> Reviewed by: Saso Kiselkov <skiselkov.ml@gmail.com> Reviewed by: Brian Behlendorf <behlendorf1@llnl.gov> Approved by: Dan McDonald <danmcd@omniti.com> References: https://www.illumos.org/issues/5027 https://github.com/illumos/illumos-gate/commit/b515258 Porting Notes: * Included in this patch is a tiny ISP2() cleanup in zio_init() from Illumos 5255. * Unlike the upstream Illumos commit this patch does not impose an arbitrary 128K block size limit on volumes. Volumes, like filesystems, are limited by the zfs_max_recordsize=1M module option. * By default the maximum record size is limited to 1M by the module option zfs_max_recordsize. This value may be safely increased up to 16M which is the largest block size supported by the on-disk format. At the moment, 1M blocks clearly offer a significant performance improvement but the benefits of going beyond this for the majority of workloads are less clear. * The illumos version of this patch increased DMU_MAX_ACCESS to 32M. This was determined not to be large enough when using 16M blocks because the zfs_make_xattrdir() function will fail (EFBIG) when assigning a TX. This was immediately observed under Linux because all newly created files must have a security xattr created and that was failing. Therefore, we've set DMU_MAX_ACCESS to 64M. * On 32-bit platforms a hard limit of 1M is set for blocks due to the limited virtual address space. We should be able to relax this one the ABD patches are merged. Ported-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #354
2014-11-03 23:15:08 +03:00
dr->dr_bio[i] = bio_alloc(GFP_NOIO,
MIN(bio_nr_pages(bio_ptr, bio_size), BIO_MAX_PAGES));
if (unlikely(dr->dr_bio[i] == NULL)) {
vdev_disk_dio_free(dr);
return (ENOMEM);
}
/* Matching put called by vdev_disk_physio_completion */
vdev_disk_dio_get(dr);
dr->dr_bio[i]->bi_bdev = bdev;
BIO_BI_SECTOR(dr->dr_bio[i]) = bio_offset >> 9;
dr->dr_bio[i]->bi_rw = dr->dr_rw;
dr->dr_bio[i]->bi_end_io = vdev_disk_physio_completion;
dr->dr_bio[i]->bi_private = dr;
/* Remaining size is returned to become the new size */
bio_size = bio_map(dr->dr_bio[i], bio_ptr, bio_size);
/* Advance in buffer and construct another bio if needed */
bio_ptr += BIO_BI_SIZE(dr->dr_bio[i]);
bio_offset += BIO_BI_SIZE(dr->dr_bio[i]);
}
zvol processing should use struct bio Internally, zvols are files exposed through the block device API. This is intended to reduce overhead when things require block devices. However, the ZoL zvol code emulates a traditional block device in that it has a top half and a bottom half. This is an unnecessary source of overhead that does not exist on any other OpenZFS platform does this. This patch removes it. Early users of this patch reported double digit performance gains in IOPS on zvols in the range of 50% to 80%. Comments in the code suggest that the current implementation was done to obtain IO merging from Linux's IO elevator. However, the DMU already does write merging while arc_read() should implicitly merge read IOs because only 1 thread is permitted to fetch the buffer into ARC. In addition, commercial ZFSOnLinux distributions report that regular files are more performant than zvols under the current implementation, and the main consumers of zvols are VMs and iSCSI targets, which have their own elevators to merge IOs. Some minor refactoring allows us to register zfs_request() as our ->make_request() handler in place of the generic_make_request() function. This eliminates the layer of code that broke IO requests on zvols into a top half and a bottom half. This has several benefits: 1. No per zvol spinlocks. 2. No redundant IO elevator processing. 3. Interrupts are disabled only when actually necessary. 4. No redispatching of IOs when all taskq threads are busy. 5. Linux's page out routines will properly block. 6. Many autotools checks become obsolete. An unfortunate consequence of eliminating the layer that generic_make_request() is that we no longer calls the instrumentation hooks for block IO accounting. Those hooks are GPL-exported, so we cannot call them ourselves and consequently, we lose the ability to do IO monitoring via iostat. Since zvols are internally files mapped as block devices, this should be okay. Anyone who is willing to accept the performance penalty for the block IO layer's accounting could use the loop device in between the zvol and its consumer. Alternatively, perf and ftrace likely could be used. Also, tools like latencytop will still work. Tools such as latencytop sometimes provide a better view of performance bottlenecks than the traditional block IO accounting tools do. Lastly, if direct reclaim occurs during spacemap loading and swap is on a zvol, this code will deadlock. That deadlock could already occur with sync=always on zvols. Given that swap on zvols is not yet production ready, this is not a blocker. Signed-off-by: Richard Yao <ryao@gentoo.org>
2014-07-05 02:43:47 +04:00
/* Extra reference to protect dio_request during vdev_submit_bio */
vdev_disk_dio_get(dr);
if (zio)
zio->io_delay = jiffies_64;
/* Submit all bio's associated with this dio */
for (i = 0; i < dr->dr_bio_count; i++)
if (dr->dr_bio[i])
zvol processing should use struct bio Internally, zvols are files exposed through the block device API. This is intended to reduce overhead when things require block devices. However, the ZoL zvol code emulates a traditional block device in that it has a top half and a bottom half. This is an unnecessary source of overhead that does not exist on any other OpenZFS platform does this. This patch removes it. Early users of this patch reported double digit performance gains in IOPS on zvols in the range of 50% to 80%. Comments in the code suggest that the current implementation was done to obtain IO merging from Linux's IO elevator. However, the DMU already does write merging while arc_read() should implicitly merge read IOs because only 1 thread is permitted to fetch the buffer into ARC. In addition, commercial ZFSOnLinux distributions report that regular files are more performant than zvols under the current implementation, and the main consumers of zvols are VMs and iSCSI targets, which have their own elevators to merge IOs. Some minor refactoring allows us to register zfs_request() as our ->make_request() handler in place of the generic_make_request() function. This eliminates the layer of code that broke IO requests on zvols into a top half and a bottom half. This has several benefits: 1. No per zvol spinlocks. 2. No redundant IO elevator processing. 3. Interrupts are disabled only when actually necessary. 4. No redispatching of IOs when all taskq threads are busy. 5. Linux's page out routines will properly block. 6. Many autotools checks become obsolete. An unfortunate consequence of eliminating the layer that generic_make_request() is that we no longer calls the instrumentation hooks for block IO accounting. Those hooks are GPL-exported, so we cannot call them ourselves and consequently, we lose the ability to do IO monitoring via iostat. Since zvols are internally files mapped as block devices, this should be okay. Anyone who is willing to accept the performance penalty for the block IO layer's accounting could use the loop device in between the zvol and its consumer. Alternatively, perf and ftrace likely could be used. Also, tools like latencytop will still work. Tools such as latencytop sometimes provide a better view of performance bottlenecks than the traditional block IO accounting tools do. Lastly, if direct reclaim occurs during spacemap loading and swap is on a zvol, this code will deadlock. That deadlock could already occur with sync=always on zvols. Given that swap on zvols is not yet production ready, this is not a blocker. Signed-off-by: Richard Yao <ryao@gentoo.org>
2014-07-05 02:43:47 +04:00
vdev_submit_bio(dr->dr_rw, dr->dr_bio[i]);
/*
* On synchronous blocking requests we wait for all bio the completion
* callbacks to run. We will be woken when the last callback runs
* for this dio. We are responsible for putting the last dio_request
* reference will in turn put back the last bio references. The
* only synchronous consumer is vdev_disk_read_rootlabel() all other
* IO originating from vdev_disk_io_start() is asynchronous.
*/
if (wait) {
wait_for_completion(&dr->dr_comp);
error = dr->dr_error;
ASSERT3S(atomic_read(&dr->dr_ref), ==, 1);
}
(void) vdev_disk_dio_put(dr);
return (error);
}
int
vdev_disk_physio(struct block_device *bdev, caddr_t kbuf,
size_t size, uint64_t offset, int flags)
{
bio_set_flags_failfast(bdev, &flags);
return (__vdev_disk_physio(bdev, NULL, kbuf, size, offset, flags, 1));
}
BIO_END_IO_PROTO(vdev_disk_io_flush_completion, bio, rc)
{
zio_t *zio = bio->bi_private;
#ifdef HAVE_1ARG_BIO_END_IO_T
int rc = bio->bi_error;
#endif
zio->io_delay = jiffies_64 - zio->io_delay;
zio->io_error = -rc;
if (rc && (rc == -EOPNOTSUPP))
zio->io_vd->vdev_nowritecache = B_TRUE;
bio_put(bio);
ASSERT3S(zio->io_error, >=, 0);
if (zio->io_error)
vdev_disk_error(zio);
zio_interrupt(zio);
}
static int
vdev_disk_io_flush(struct block_device *bdev, zio_t *zio)
{
struct request_queue *q;
struct bio *bio;
q = bdev_get_queue(bdev);
if (!q)
return (ENXIO);
bio = bio_alloc(GFP_NOIO, 0);
/* bio_alloc() with __GFP_WAIT never returns NULL */
if (unlikely(bio == NULL))
return (ENOMEM);
bio->bi_end_io = vdev_disk_io_flush_completion;
bio->bi_private = zio;
bio->bi_bdev = bdev;
zio->io_delay = jiffies_64;
zvol processing should use struct bio Internally, zvols are files exposed through the block device API. This is intended to reduce overhead when things require block devices. However, the ZoL zvol code emulates a traditional block device in that it has a top half and a bottom half. This is an unnecessary source of overhead that does not exist on any other OpenZFS platform does this. This patch removes it. Early users of this patch reported double digit performance gains in IOPS on zvols in the range of 50% to 80%. Comments in the code suggest that the current implementation was done to obtain IO merging from Linux's IO elevator. However, the DMU already does write merging while arc_read() should implicitly merge read IOs because only 1 thread is permitted to fetch the buffer into ARC. In addition, commercial ZFSOnLinux distributions report that regular files are more performant than zvols under the current implementation, and the main consumers of zvols are VMs and iSCSI targets, which have their own elevators to merge IOs. Some minor refactoring allows us to register zfs_request() as our ->make_request() handler in place of the generic_make_request() function. This eliminates the layer of code that broke IO requests on zvols into a top half and a bottom half. This has several benefits: 1. No per zvol spinlocks. 2. No redundant IO elevator processing. 3. Interrupts are disabled only when actually necessary. 4. No redispatching of IOs when all taskq threads are busy. 5. Linux's page out routines will properly block. 6. Many autotools checks become obsolete. An unfortunate consequence of eliminating the layer that generic_make_request() is that we no longer calls the instrumentation hooks for block IO accounting. Those hooks are GPL-exported, so we cannot call them ourselves and consequently, we lose the ability to do IO monitoring via iostat. Since zvols are internally files mapped as block devices, this should be okay. Anyone who is willing to accept the performance penalty for the block IO layer's accounting could use the loop device in between the zvol and its consumer. Alternatively, perf and ftrace likely could be used. Also, tools like latencytop will still work. Tools such as latencytop sometimes provide a better view of performance bottlenecks than the traditional block IO accounting tools do. Lastly, if direct reclaim occurs during spacemap loading and swap is on a zvol, this code will deadlock. That deadlock could already occur with sync=always on zvols. Given that swap on zvols is not yet production ready, this is not a blocker. Signed-off-by: Richard Yao <ryao@gentoo.org>
2014-07-05 02:43:47 +04:00
vdev_submit_bio(VDEV_WRITE_FLUSH_FUA, bio);
Invalidate Linux buffer cache on vdevs upon each flush Userland tools such as blkid, grub2-probe and zdb will go through the buffer cache. However, ZFS uses on submit_bio() to bypass the buffer cache when performing IO operations on vdevs for efficiency purposes. This permits the on-disk state and buffer cache to fall out of synchronization. That causes seemingly random failures when tools reading stale metadata from the buffer cache try to access references to data that is no longer there. A particularly bad failure this causes involves grub2-probe, which is used by grub2-mkconfig. Ordinarily, a rootfs might be called rpool/ROOT/gentoo. However, when a failure occurs in grub2-probe, grub2-mkconfig will generate a configuration file containing /ROOT/gentoo, which omits the pool name and causes a boot failure. This is avoidable by calling invalidate_bdev() on each flush, which is a simple way to ensure that all non-dirty pages are wiped. Since userland tools rarely access vdevs directly, this should be a fancy noop >99.999% of the time and have little impact on IO. We could have tried a finer grained approach for the rare instances in which the vdevs are accessed frequently by userland. However, that would require consideration of corner cases and it is not worth the effort. Memory-wise, it would have been better to use a Linux kernel API hook to disable the buffer cache on such devices, but it provides us no way of doing that, so we opt for this approach instead. We should revisit that idea in the future when higher priority issues have been tackled. Signed-off-by: Richard Yao <ryao@gentoo.org> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #2150
2014-02-27 23:03:39 +04:00
invalidate_bdev(bdev);
return (0);
}
static void
vdev_disk_io_start(zio_t *zio)
{
vdev_t *v = zio->io_vd;
vdev_disk_t *vd = v->vdev_tsd;
zio_priority_t pri = zio->io_priority;
int flags, error;
switch (zio->io_type) {
case ZIO_TYPE_IOCTL:
if (!vdev_readable(v)) {
zio->io_error = SET_ERROR(ENXIO);
zio_interrupt(zio);
return;
}
switch (zio->io_cmd) {
case DKIOCFLUSHWRITECACHE:
if (zfs_nocacheflush)
break;
if (v->vdev_nowritecache) {
zio->io_error = SET_ERROR(ENOTSUP);
break;
}
error = vdev_disk_io_flush(vd->vd_bdev, zio);
if (error == 0)
return;
zio->io_error = error;
if (error == ENOTSUP)
v->vdev_nowritecache = B_TRUE;
break;
default:
zio->io_error = SET_ERROR(ENOTSUP);
}
zio_execute(zio);
return;
case ZIO_TYPE_WRITE:
if ((pri == ZIO_PRIORITY_SYNC_WRITE) && (v->vdev_nonrot))
Translate sync zio to sync bio Translate zio requests with ZIO_PRIORITY_SYNC_READ and ZIO_PRIORITY_SYNC_WRITE into synchronous bio requests by setting READ_SYNC and WRITE_SYNC flags. Specifically, WRITE_SYNC flag turns out to have a pronounced effect when writing to an SSD-based SLOG. When WRITE_SYNC is not set (WRITE is set instead), the block trace for a SLOG device looks as follows: ... 130,96 0 3 0.008968390 0 C W 830464 + 136 [0] 130,96 0 4 0.011999161 0 C W 830720 + 136 [0] 130,96 0 5 0.023955549 0 C W 831744 + 136 [0] 130,96 0 6 0.024337663 19775 A W 832000 + 136 <- (130,97) 829952 130,96 0 7 0.024338823 19775 Q W 832000 + 136 [z_wr_iss/6] 130,96 0 8 0.024340523 19775 G W 832000 + 136 [z_wr_iss/6] 130,96 0 9 0.024343187 19775 P N [z_wr_iss/6] 130,96 0 10 0.024344120 19775 I W 832000 + 136 [z_wr_iss/6] 130,96 0 11 0.026784405 0 UT N [swapper] 1 130,96 0 12 0.026805339 202 U N [kblockd/0] 1 130,96 0 13 0.026807199 202 D W 832000 + 136 [kblockd/0] 130,96 0 14 0.026966948 0 C W 832000 + 136 [0] 130,96 3 1 0.000449358 19788 A W 829952 + 136 <- (130,97) 827904 130,96 3 2 0.000450951 19788 Q W 829952 + 136 [z_wr_iss/19] 130,96 3 3 0.000453212 19788 G W 829952 + 136 [z_wr_iss/19] 130,96 3 4 0.000455956 19788 P N [z_wr_iss/19] 130,96 3 5 0.000457076 19788 I W 829952 + 136 [z_wr_iss/19] 130,96 3 6 0.002786349 0 UT N [swapper] 1 ... Here the 130,197 is the partition created on the log device when adding it to the pool, whereas the base device is 130,96. As one can see, the writes to the SLOG are not marked synchronous (the S is missing next to W), and the queue unplugs occur based on the timer (UT event) resulting in slightly over 2 msec latency of writes. This results in a sub-par performance of single stream synchronous writes (limited by latency of the SLOG). When the WRITE_SYNC is set, a similar trace looks as follows: ... 130,96 4 1 0.000000000 70714 A WS 4280576 + 136 <- (130,97) 4278528 130,96 4 2 0.000000832 70714 Q WS 4280576 + 136 [(null)] 130,96 4 3 0.000002109 70714 G WS 4280576 + 136 [(null)] 130,96 4 4 0.000003394 70714 P N [(null)] 130,96 4 5 0.000003846 70714 I WS 4280576 + 136 [(null)] 130,96 4 6 0.000004854 70714 D WS 4280576 + 136 [(null)] 130,96 5 1 0.000354487 70713 A WS 4280832 + 136 <- (130,97) 4278784 130,96 5 2 0.000355072 70713 Q WS 4280832 + 136 [(null)] 130,96 5 3 0.000356383 70713 G WS 4280832 + 136 [(null)] 130,96 5 4 0.000357635 70713 P N [(null)] 130,96 5 5 0.000358088 70713 I WS 4280832 + 136 [(null)] 130,96 5 6 0.000359191 70713 D WS 4280832 + 136 [(null)] 130,96 0 76 0.000159539 0 C WS 4280576 + 136 [0] 130,96 16 85 0.000742108 70718 A WS 4281088 + 136 <- (130,97) 4279040 130,96 16 86 0.000743197 70718 Q WS 4281088 + 136 [z_wr_iss/15] 130,96 16 87 0.000744450 70718 G WS 4281088 + 136 [z_wr_iss/15] 130,96 16 88 0.000745817 70718 P N [z_wr_iss/15] 130,96 16 89 0.000746705 70718 I WS 4281088 + 136 [z_wr_iss/15] 130,96 16 90 0.000747848 70718 D WS 4281088 + 136 [z_wr_iss/15] 130,96 0 77 0.000604063 0 C WS 4280832 + 136 [0] 130,96 0 78 0.000899858 0 C WS 4281088 + 136 [0] As one can see, all the writes are synchronous (WS), and I/O completions (e.g. from issue I to completion C) take 160-250 usec, or about 10x faster. Since WRITE_SYNC or READ_SYNC flags are among several factors that are considered when processing bio requests, it seems prudent to mark all the zio requests of synchronous priority with the READ/WRITE_SYNC flags to make them eligible for consideration as such by the Linux block I/O layer. Signed-off-by: Boris Protopopov <boris.protopopov@actifio.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #3529
2015-06-25 22:42:51 +03:00
flags = WRITE_SYNC;
else
flags = WRITE;
break;
case ZIO_TYPE_READ:
if ((pri == ZIO_PRIORITY_SYNC_READ) && (v->vdev_nonrot))
Translate sync zio to sync bio Translate zio requests with ZIO_PRIORITY_SYNC_READ and ZIO_PRIORITY_SYNC_WRITE into synchronous bio requests by setting READ_SYNC and WRITE_SYNC flags. Specifically, WRITE_SYNC flag turns out to have a pronounced effect when writing to an SSD-based SLOG. When WRITE_SYNC is not set (WRITE is set instead), the block trace for a SLOG device looks as follows: ... 130,96 0 3 0.008968390 0 C W 830464 + 136 [0] 130,96 0 4 0.011999161 0 C W 830720 + 136 [0] 130,96 0 5 0.023955549 0 C W 831744 + 136 [0] 130,96 0 6 0.024337663 19775 A W 832000 + 136 <- (130,97) 829952 130,96 0 7 0.024338823 19775 Q W 832000 + 136 [z_wr_iss/6] 130,96 0 8 0.024340523 19775 G W 832000 + 136 [z_wr_iss/6] 130,96 0 9 0.024343187 19775 P N [z_wr_iss/6] 130,96 0 10 0.024344120 19775 I W 832000 + 136 [z_wr_iss/6] 130,96 0 11 0.026784405 0 UT N [swapper] 1 130,96 0 12 0.026805339 202 U N [kblockd/0] 1 130,96 0 13 0.026807199 202 D W 832000 + 136 [kblockd/0] 130,96 0 14 0.026966948 0 C W 832000 + 136 [0] 130,96 3 1 0.000449358 19788 A W 829952 + 136 <- (130,97) 827904 130,96 3 2 0.000450951 19788 Q W 829952 + 136 [z_wr_iss/19] 130,96 3 3 0.000453212 19788 G W 829952 + 136 [z_wr_iss/19] 130,96 3 4 0.000455956 19788 P N [z_wr_iss/19] 130,96 3 5 0.000457076 19788 I W 829952 + 136 [z_wr_iss/19] 130,96 3 6 0.002786349 0 UT N [swapper] 1 ... Here the 130,197 is the partition created on the log device when adding it to the pool, whereas the base device is 130,96. As one can see, the writes to the SLOG are not marked synchronous (the S is missing next to W), and the queue unplugs occur based on the timer (UT event) resulting in slightly over 2 msec latency of writes. This results in a sub-par performance of single stream synchronous writes (limited by latency of the SLOG). When the WRITE_SYNC is set, a similar trace looks as follows: ... 130,96 4 1 0.000000000 70714 A WS 4280576 + 136 <- (130,97) 4278528 130,96 4 2 0.000000832 70714 Q WS 4280576 + 136 [(null)] 130,96 4 3 0.000002109 70714 G WS 4280576 + 136 [(null)] 130,96 4 4 0.000003394 70714 P N [(null)] 130,96 4 5 0.000003846 70714 I WS 4280576 + 136 [(null)] 130,96 4 6 0.000004854 70714 D WS 4280576 + 136 [(null)] 130,96 5 1 0.000354487 70713 A WS 4280832 + 136 <- (130,97) 4278784 130,96 5 2 0.000355072 70713 Q WS 4280832 + 136 [(null)] 130,96 5 3 0.000356383 70713 G WS 4280832 + 136 [(null)] 130,96 5 4 0.000357635 70713 P N [(null)] 130,96 5 5 0.000358088 70713 I WS 4280832 + 136 [(null)] 130,96 5 6 0.000359191 70713 D WS 4280832 + 136 [(null)] 130,96 0 76 0.000159539 0 C WS 4280576 + 136 [0] 130,96 16 85 0.000742108 70718 A WS 4281088 + 136 <- (130,97) 4279040 130,96 16 86 0.000743197 70718 Q WS 4281088 + 136 [z_wr_iss/15] 130,96 16 87 0.000744450 70718 G WS 4281088 + 136 [z_wr_iss/15] 130,96 16 88 0.000745817 70718 P N [z_wr_iss/15] 130,96 16 89 0.000746705 70718 I WS 4281088 + 136 [z_wr_iss/15] 130,96 16 90 0.000747848 70718 D WS 4281088 + 136 [z_wr_iss/15] 130,96 0 77 0.000604063 0 C WS 4280832 + 136 [0] 130,96 0 78 0.000899858 0 C WS 4281088 + 136 [0] As one can see, all the writes are synchronous (WS), and I/O completions (e.g. from issue I to completion C) take 160-250 usec, or about 10x faster. Since WRITE_SYNC or READ_SYNC flags are among several factors that are considered when processing bio requests, it seems prudent to mark all the zio requests of synchronous priority with the READ/WRITE_SYNC flags to make them eligible for consideration as such by the Linux block I/O layer. Signed-off-by: Boris Protopopov <boris.protopopov@actifio.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #3529
2015-06-25 22:42:51 +03:00
flags = READ_SYNC;
else
flags = READ;
break;
default:
zio->io_error = SET_ERROR(ENOTSUP);
zio_interrupt(zio);
return;
}
error = __vdev_disk_physio(vd->vd_bdev, zio, zio->io_data,
zio->io_size, zio->io_offset, flags, 0);
if (error) {
zio->io_error = error;
zio_interrupt(zio);
return;
}
}
static void
vdev_disk_io_done(zio_t *zio)
{
/*
* If the device returned EIO, we revalidate the media. If it is
* determined the media has changed this triggers the asynchronous
* removal of the device from the configuration.
*/
if (zio->io_error == EIO) {
vdev_t *v = zio->io_vd;
vdev_disk_t *vd = v->vdev_tsd;
if (check_disk_change(vd->vd_bdev)) {
vdev_bdev_invalidate(vd->vd_bdev);
v->vdev_remove_wanted = B_TRUE;
spa_async_request(zio->io_spa, SPA_ASYNC_REMOVE);
}
}
}
static void
vdev_disk_hold(vdev_t *vd)
{
ASSERT(spa_config_held(vd->vdev_spa, SCL_STATE, RW_WRITER));
/* We must have a pathname, and it must be absolute. */
if (vd->vdev_path == NULL || vd->vdev_path[0] != '/')
return;
/*
* Only prefetch path and devid info if the device has
* never been opened.
*/
if (vd->vdev_tsd != NULL)
return;
/* XXX: Implement me as a vnode lookup for the device */
vd->vdev_name_vp = NULL;
vd->vdev_devid_vp = NULL;
}
static void
vdev_disk_rele(vdev_t *vd)
{
ASSERT(spa_config_held(vd->vdev_spa, SCL_STATE, RW_WRITER));
/* XXX: Implement me as a vnode rele for the device */
}
vdev_ops_t vdev_disk_ops = {
vdev_disk_open,
vdev_disk_close,
vdev_default_asize,
vdev_disk_io_start,
vdev_disk_io_done,
NULL,
vdev_disk_hold,
vdev_disk_rele,
VDEV_TYPE_DISK, /* name of this vdev type */
B_TRUE /* leaf vdev */
};
/*
* Given the root disk device devid or pathname, read the label from
* the device, and construct a configuration nvlist.
*/
int
vdev_disk_read_rootlabel(char *devpath, char *devid, nvlist_t **config)
{
struct block_device *bdev;
vdev_label_t *label;
uint64_t s, size;
int i;
bdev = vdev_bdev_open(devpath, vdev_bdev_mode(FREAD), zfs_vdev_holder);
if (IS_ERR(bdev))
return (-PTR_ERR(bdev));
s = bdev_capacity(bdev);
if (s == 0) {
vdev_bdev_close(bdev, vdev_bdev_mode(FREAD));
return (EIO);
}
size = P2ALIGN_TYPED(s, sizeof (vdev_label_t), uint64_t);
label = vmem_alloc(sizeof (vdev_label_t), KM_SLEEP);
for (i = 0; i < VDEV_LABELS; i++) {
uint64_t offset, state, txg = 0;
/* read vdev label */
offset = vdev_label_offset(size, i, 0);
if (vdev_disk_physio(bdev, (caddr_t)label,
VDEV_SKIP_SIZE + VDEV_PHYS_SIZE, offset, READ_SYNC) != 0)
continue;
if (nvlist_unpack(label->vl_vdev_phys.vp_nvlist,
sizeof (label->vl_vdev_phys.vp_nvlist), config, 0) != 0) {
*config = NULL;
continue;
}
if (nvlist_lookup_uint64(*config, ZPOOL_CONFIG_POOL_STATE,
&state) != 0 || state >= POOL_STATE_DESTROYED) {
nvlist_free(*config);
*config = NULL;
continue;
}
if (nvlist_lookup_uint64(*config, ZPOOL_CONFIG_POOL_TXG,
&txg) != 0 || txg == 0) {
nvlist_free(*config);
*config = NULL;
continue;
}
break;
}
vmem_free(label, sizeof (vdev_label_t));
vdev_bdev_close(bdev, vdev_bdev_mode(FREAD));
return (0);
}
module_param(zfs_vdev_scheduler, charp, 0644);
Add missing ZFS tunables This commit adds module options for all existing zfs tunables. Ideally the average user should never need to modify any of these values. However, in practice sometimes you do need to tweak these values for one reason or another. In those cases it's nice not to have to resort to rebuilding from source. All tunables are visable to modinfo and the list is as follows: $ modinfo module/zfs/zfs.ko filename: module/zfs/zfs.ko license: CDDL author: Sun Microsystems/Oracle, Lawrence Livermore National Laboratory description: ZFS srcversion: 8EAB1D71DACE05B5AA61567 depends: spl,znvpair,zcommon,zunicode,zavl vermagic: 2.6.32-131.0.5.el6.x86_64 SMP mod_unload modversions parm: zvol_major:Major number for zvol device (uint) parm: zvol_threads:Number of threads for zvol device (uint) parm: zio_injection_enabled:Enable fault injection (int) parm: zio_bulk_flags:Additional flags to pass to bulk buffers (int) parm: zio_delay_max:Max zio millisec delay before posting event (int) parm: zio_requeue_io_start_cut_in_line:Prioritize requeued I/O (bool) parm: zil_replay_disable:Disable intent logging replay (int) parm: zfs_nocacheflush:Disable cache flushes (bool) parm: zfs_read_chunk_size:Bytes to read per chunk (long) parm: zfs_vdev_max_pending:Max pending per-vdev I/Os (int) parm: zfs_vdev_min_pending:Min pending per-vdev I/Os (int) parm: zfs_vdev_aggregation_limit:Max vdev I/O aggregation size (int) parm: zfs_vdev_time_shift:Deadline time shift for vdev I/O (int) parm: zfs_vdev_ramp_rate:Exponential I/O issue ramp-up rate (int) parm: zfs_vdev_read_gap_limit:Aggregate read I/O over gap (int) parm: zfs_vdev_write_gap_limit:Aggregate write I/O over gap (int) parm: zfs_vdev_scheduler:I/O scheduler (charp) parm: zfs_vdev_cache_max:Inflate reads small than max (int) parm: zfs_vdev_cache_size:Total size of the per-disk cache (int) parm: zfs_vdev_cache_bshift:Shift size to inflate reads too (int) parm: zfs_scrub_limit:Max scrub/resilver I/O per leaf vdev (int) parm: zfs_recover:Set to attempt to recover from fatal errors (int) parm: spa_config_path:SPA config file (/etc/zfs/zpool.cache) (charp) parm: zfs_zevent_len_max:Max event queue length (int) parm: zfs_zevent_cols:Max event column width (int) parm: zfs_zevent_console:Log events to the console (int) parm: zfs_top_maxinflight:Max I/Os per top-level (int) parm: zfs_resilver_delay:Number of ticks to delay resilver (int) parm: zfs_scrub_delay:Number of ticks to delay scrub (int) parm: zfs_scan_idle:Idle window in clock ticks (int) parm: zfs_scan_min_time_ms:Min millisecs to scrub per txg (int) parm: zfs_free_min_time_ms:Min millisecs to free per txg (int) parm: zfs_resilver_min_time_ms:Min millisecs to resilver per txg (int) parm: zfs_no_scrub_io:Set to disable scrub I/O (bool) parm: zfs_no_scrub_prefetch:Set to disable scrub prefetching (bool) parm: zfs_txg_timeout:Max seconds worth of delta per txg (int) parm: zfs_no_write_throttle:Disable write throttling (int) parm: zfs_write_limit_shift:log2(fraction of memory) per txg (int) parm: zfs_txg_synctime_ms:Target milliseconds between tgx sync (int) parm: zfs_write_limit_min:Min tgx write limit (ulong) parm: zfs_write_limit_max:Max tgx write limit (ulong) parm: zfs_write_limit_inflated:Inflated tgx write limit (ulong) parm: zfs_write_limit_override:Override tgx write limit (ulong) parm: zfs_prefetch_disable:Disable all ZFS prefetching (int) parm: zfetch_max_streams:Max number of streams per zfetch (uint) parm: zfetch_min_sec_reap:Min time before stream reclaim (uint) parm: zfetch_block_cap:Max number of blocks to fetch at a time (uint) parm: zfetch_array_rd_sz:Number of bytes in a array_read (ulong) parm: zfs_pd_blks_max:Max number of blocks to prefetch (int) parm: zfs_dedup_prefetch:Enable prefetching dedup-ed blks (int) parm: zfs_arc_min:Min arc size (ulong) parm: zfs_arc_max:Max arc size (ulong) parm: zfs_arc_meta_limit:Meta limit for arc size (ulong) parm: zfs_arc_reduce_dnlc_percent:Meta reclaim percentage (int) parm: zfs_arc_grow_retry:Seconds before growing arc size (int) parm: zfs_arc_shrink_shift:log2(fraction of arc to reclaim) (int) parm: zfs_arc_p_min_shift:arc_c shift to calc min/max arc_p (int)
2011-05-04 02:09:28 +04:00
MODULE_PARM_DESC(zfs_vdev_scheduler, "I/O scheduler");