mirror_zfs/module/os/linux/zfs/vdev_disk.c

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/*
* 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 https://opensource.org/licenses/CDDL-1.0.
* 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, 2019 by Delphix. All rights reserved.
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
* Copyright (c) 2023, 2024, Klara Inc.
*/
#include <sys/zfs_context.h>
#include <sys/spa_impl.h>
#include <sys/vdev_disk.h>
#include <sys/vdev_impl.h>
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
#include <sys/vdev_trim.h>
#include <sys/abd.h>
#include <sys/fs/zfs.h>
#include <sys/zio.h>
#include <linux/blkpg.h>
#include <linux/msdos_fs.h>
#include <linux/vfs_compat.h>
#ifdef HAVE_LINUX_BLK_CGROUP_HEADER
#include <linux/blk-cgroup.h>
#endif
/*
* Linux 6.8.x uses a bdev_handle as an instance/refcount for an underlying
* block_device. Since it carries the block_device inside, its convenient to
* just use the handle as a proxy.
*
* Linux 6.9.x uses a file for the same purpose.
*
* For pre-6.8, we just emulate this with a cast, since we don't need any of
* the other fields inside the handle.
*/
#if defined(HAVE_BDEV_OPEN_BY_PATH)
typedef struct bdev_handle zfs_bdev_handle_t;
#define BDH_BDEV(bdh) ((bdh)->bdev)
#define BDH_IS_ERR(bdh) (IS_ERR(bdh))
#define BDH_PTR_ERR(bdh) (PTR_ERR(bdh))
#define BDH_ERR_PTR(err) (ERR_PTR(err))
#elif defined(HAVE_BDEV_FILE_OPEN_BY_PATH)
typedef struct file zfs_bdev_handle_t;
#define BDH_BDEV(bdh) (file_bdev(bdh))
#define BDH_IS_ERR(bdh) (IS_ERR(bdh))
#define BDH_PTR_ERR(bdh) (PTR_ERR(bdh))
#define BDH_ERR_PTR(err) (ERR_PTR(err))
#else
typedef void zfs_bdev_handle_t;
#define BDH_BDEV(bdh) ((struct block_device *)bdh)
#define BDH_IS_ERR(bdh) (IS_ERR(BDH_BDEV(bdh)))
#define BDH_PTR_ERR(bdh) (PTR_ERR(BDH_BDEV(bdh)))
#define BDH_ERR_PTR(err) (ERR_PTR(err))
#endif
typedef struct vdev_disk {
zfs_bdev_handle_t *vd_bdh;
krwlock_t vd_lock;
} vdev_disk_t;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/*
* Maximum number of segments to add to a bio (min 4). If this is higher than
* the maximum allowed by the device queue or the kernel itself, it will be
* clamped. Setting it to zero will cause the kernel's ideal size to be used.
*/
uint_t zfs_vdev_disk_max_segs = 0;
/*
* Unique identifier for the exclusive vdev holder.
*/
static void *zfs_vdev_holder = VDEV_HOLDER;
/*
* Wait up to zfs_vdev_open_timeout_ms milliseconds before determining the
* device is missing. The missing path may be transient since the links
* can be briefly removed and recreated in response to udev events.
*/
static uint_t zfs_vdev_open_timeout_ms = 1000;
/*
* Size of the "reserved" partition, in blocks.
*/
#define EFI_MIN_RESV_SIZE (16 * 1024)
/*
* BIO request failfast mask.
*/
static unsigned int zfs_vdev_failfast_mask = 1;
/*
* Convert SPA mode flags into bdev open mode flags.
*/
#ifdef HAVE_BLK_MODE_T
typedef blk_mode_t vdev_bdev_mode_t;
#define VDEV_BDEV_MODE_READ BLK_OPEN_READ
#define VDEV_BDEV_MODE_WRITE BLK_OPEN_WRITE
#define VDEV_BDEV_MODE_EXCL BLK_OPEN_EXCL
#define VDEV_BDEV_MODE_MASK (BLK_OPEN_READ|BLK_OPEN_WRITE|BLK_OPEN_EXCL)
#else
typedef fmode_t vdev_bdev_mode_t;
#define VDEV_BDEV_MODE_READ FMODE_READ
#define VDEV_BDEV_MODE_WRITE FMODE_WRITE
#define VDEV_BDEV_MODE_EXCL FMODE_EXCL
#define VDEV_BDEV_MODE_MASK (FMODE_READ|FMODE_WRITE|FMODE_EXCL)
#endif
static vdev_bdev_mode_t
vdev_bdev_mode(spa_mode_t smode)
{
ASSERT3U(smode, !=, SPA_MODE_UNINIT);
ASSERT0(smode & ~(SPA_MODE_READ|SPA_MODE_WRITE));
vdev_bdev_mode_t bmode = VDEV_BDEV_MODE_EXCL;
if (smode & SPA_MODE_READ)
bmode |= VDEV_BDEV_MODE_READ;
if (smode & SPA_MODE_WRITE)
bmode |= VDEV_BDEV_MODE_WRITE;
ASSERT(bmode & VDEV_BDEV_MODE_MASK);
ASSERT0(bmode & ~VDEV_BDEV_MODE_MASK);
return (bmode);
}
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/*
* Returns the usable capacity (in bytes) for the partition or disk.
*/
static uint64_t
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
bdev_capacity(struct block_device *bdev)
{
#ifdef HAVE_BDEV_NR_BYTES
return (bdev_nr_bytes(bdev));
#else
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
return (i_size_read(bdev->bd_inode));
#endif
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
}
#if !defined(HAVE_BDEV_WHOLE)
static inline struct block_device *
bdev_whole(struct block_device *bdev)
{
return (bdev->bd_contains);
}
#endif
#if defined(HAVE_BDEVNAME)
#define vdev_bdevname(bdev, name) bdevname(bdev, name)
#else
static inline void
vdev_bdevname(struct block_device *bdev, char *name)
{
snprintf(name, BDEVNAME_SIZE, "%pg", bdev);
}
#endif
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/*
* Returns the maximum expansion capacity of the block device (in bytes).
*
* It is possible to expand a vdev when it has been created as a wholedisk
* and the containing block device has increased in capacity. Or when the
* partition containing the pool has been manually increased in size.
*
* This function is only responsible for calculating the potential expansion
* size so it can be reported by 'zpool list'. The efi_use_whole_disk() is
* responsible for verifying the expected partition layout in the wholedisk
* case, and updating the partition table if appropriate. Once the partition
* size has been increased the additional capacity will be visible using
* bdev_capacity().
zpool reports 16E expandsize on disks with oddball number of sectors The issue is caused by a small discrepancy in how userland creates the partition layout and the kernel estimates available space: * zpool command: subtract 9M from the usable device size, then align to 1M boundary. 9M is the sum of 1M "start" partition alignment + 8M EFI "reserved" partition. * kernel module: subtract 10M from the device size. 10M is the sum of 1M "start" partition alignment + 1m "end" partition alignment + 8M EFI "reserved" partition. For devices where the number of sectors is not a multiple of the alignment size the zpool command will create a partition layout which reserves less than 1M after the 8M EFI "reserved" partition: Disk /dev/sda: 1024 MiB, 1073739776 bytes, 2097148 sectors Units: sectors of 1 * 512 = 512 bytes Sector size (logical/physical): 512 bytes / 512 bytes I/O size (minimum/optimal): 512 bytes / 512 bytes Disklabel type: gpt Disk identifier: 49811D40-16F4-4E41-84A9-387703950D7F Device Start End Sectors Size Type /dev/sda1 2048 2078719 2076672 1014M Solaris /usr & Apple ZFS /dev/sda9 2078720 2095103 16384 8M Solaris reserved 1 When the kernel module vdev_open() the device its max_asize ends up being slightly smaller than asize: this results in a huge number (16E) reported by metaslab_class_expandable_space(). This change prevents bdev_max_capacity() from returing a size smaller than bdev_capacity(). Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: loli10K <ezomori.nozomu@gmail.com> Closes #1468 Closes #8391
2019-02-23 02:36:34 +03:00
*
* The returned maximum expansion capacity is always expected to be larger, or
* at the very least equal, to its usable capacity to prevent overestimating
* the pool expandsize.
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
*/
static uint64_t
bdev_max_capacity(struct block_device *bdev, uint64_t wholedisk)
{
uint64_t psize;
int64_t available;
if (wholedisk && bdev != bdev_whole(bdev)) {
/*
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
* When reporting maximum expansion capacity for a wholedisk
* deduct any capacity which is expected to be lost due to
* alignment restrictions. Over reporting this value isn't
* harmful and would only result in slightly less capacity
* than expected post expansion.
zpool reports 16E expandsize on disks with oddball number of sectors The issue is caused by a small discrepancy in how userland creates the partition layout and the kernel estimates available space: * zpool command: subtract 9M from the usable device size, then align to 1M boundary. 9M is the sum of 1M "start" partition alignment + 8M EFI "reserved" partition. * kernel module: subtract 10M from the device size. 10M is the sum of 1M "start" partition alignment + 1m "end" partition alignment + 8M EFI "reserved" partition. For devices where the number of sectors is not a multiple of the alignment size the zpool command will create a partition layout which reserves less than 1M after the 8M EFI "reserved" partition: Disk /dev/sda: 1024 MiB, 1073739776 bytes, 2097148 sectors Units: sectors of 1 * 512 = 512 bytes Sector size (logical/physical): 512 bytes / 512 bytes I/O size (minimum/optimal): 512 bytes / 512 bytes Disklabel type: gpt Disk identifier: 49811D40-16F4-4E41-84A9-387703950D7F Device Start End Sectors Size Type /dev/sda1 2048 2078719 2076672 1014M Solaris /usr & Apple ZFS /dev/sda9 2078720 2095103 16384 8M Solaris reserved 1 When the kernel module vdev_open() the device its max_asize ends up being slightly smaller than asize: this results in a huge number (16E) reported by metaslab_class_expandable_space(). This change prevents bdev_max_capacity() from returing a size smaller than bdev_capacity(). Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: loli10K <ezomori.nozomu@gmail.com> Closes #1468 Closes #8391
2019-02-23 02:36:34 +03:00
* The estimated available space may be slightly smaller than
* bdev_capacity() for devices where the number of sectors is
* not a multiple of the alignment size and the partition layout
* is keeping less than PARTITION_END_ALIGNMENT bytes after the
* "reserved" EFI partition: in such cases return the device
* usable capacity.
*/
available = bdev_capacity(bdev_whole(bdev)) -
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
((EFI_MIN_RESV_SIZE + NEW_START_BLOCK +
PARTITION_END_ALIGNMENT) << SECTOR_BITS);
zpool reports 16E expandsize on disks with oddball number of sectors The issue is caused by a small discrepancy in how userland creates the partition layout and the kernel estimates available space: * zpool command: subtract 9M from the usable device size, then align to 1M boundary. 9M is the sum of 1M "start" partition alignment + 8M EFI "reserved" partition. * kernel module: subtract 10M from the device size. 10M is the sum of 1M "start" partition alignment + 1m "end" partition alignment + 8M EFI "reserved" partition. For devices where the number of sectors is not a multiple of the alignment size the zpool command will create a partition layout which reserves less than 1M after the 8M EFI "reserved" partition: Disk /dev/sda: 1024 MiB, 1073739776 bytes, 2097148 sectors Units: sectors of 1 * 512 = 512 bytes Sector size (logical/physical): 512 bytes / 512 bytes I/O size (minimum/optimal): 512 bytes / 512 bytes Disklabel type: gpt Disk identifier: 49811D40-16F4-4E41-84A9-387703950D7F Device Start End Sectors Size Type /dev/sda1 2048 2078719 2076672 1014M Solaris /usr & Apple ZFS /dev/sda9 2078720 2095103 16384 8M Solaris reserved 1 When the kernel module vdev_open() the device its max_asize ends up being slightly smaller than asize: this results in a huge number (16E) reported by metaslab_class_expandable_space(). This change prevents bdev_max_capacity() from returing a size smaller than bdev_capacity(). Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: loli10K <ezomori.nozomu@gmail.com> Closes #1468 Closes #8391
2019-02-23 02:36:34 +03:00
psize = MAX(available, bdev_capacity(bdev));
} else {
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
psize = bdev_capacity(bdev);
}
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
return (psize);
}
static void
vdev_disk_error(zio_t *zio)
{
/*
* This function can be called in interrupt context, for instance while
* handling IRQs coming from a misbehaving disk device; use printk()
* which is safe from any context.
*/
printk(KERN_WARNING "zio pool=%s vdev=%s error=%d type=%d "
"offset=%llu size=%llu flags=%llu\n", spa_name(zio->io_spa),
zio->io_vd->vdev_path, zio->io_error, zio->io_type,
(u_longlong_t)zio->io_offset, (u_longlong_t)zio->io_size,
zio->io_flags);
}
static void
vdev_disk_kobj_evt_post(vdev_t *v)
{
vdev_disk_t *vd = v->vdev_tsd;
if (vd && vd->vd_bdh) {
spl_signal_kobj_evt(BDH_BDEV(vd->vd_bdh));
} else {
vdev_dbgmsg(v, "vdev_disk_t is NULL for VDEV:%s\n",
v->vdev_path);
}
}
static zfs_bdev_handle_t *
vdev_blkdev_get_by_path(const char *path, spa_mode_t smode, void *holder)
{
vdev_bdev_mode_t bmode = vdev_bdev_mode(smode);
#if defined(HAVE_BDEV_FILE_OPEN_BY_PATH)
return (bdev_file_open_by_path(path, bmode, holder, NULL));
#elif defined(HAVE_BDEV_OPEN_BY_PATH)
return (bdev_open_by_path(path, bmode, holder, NULL));
#elif defined(HAVE_BLKDEV_GET_BY_PATH_4ARG)
return (blkdev_get_by_path(path, bmode, holder, NULL));
#else
return (blkdev_get_by_path(path, bmode, holder));
#endif
}
static void
vdev_blkdev_put(zfs_bdev_handle_t *bdh, spa_mode_t smode, void *holder)
{
#if defined(HAVE_BDEV_RELEASE)
return (bdev_release(bdh));
#elif defined(HAVE_BLKDEV_PUT_HOLDER)
return (blkdev_put(BDH_BDEV(bdh), holder));
#elif defined(HAVE_BLKDEV_PUT)
return (blkdev_put(BDH_BDEV(bdh), vdev_bdev_mode(smode)));
#else
fput(bdh);
#endif
}
static int
vdev_disk_open(vdev_t *v, uint64_t *psize, uint64_t *max_psize,
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
uint64_t *logical_ashift, uint64_t *physical_ashift)
{
zfs_bdev_handle_t *bdh;
spa_mode_t smode = spa_mode(v->vdev_spa);
hrtime_t timeout = MSEC2NSEC(zfs_vdev_open_timeout_ms);
vdev_disk_t *vd;
/* 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;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
vdev_dbgmsg(v, "invalid vdev_path");
Use udev for partition detection When ZFS partitions a block device it must wait for udev to create both a device node and all the device symlinks. This process takes a variable length of time and depends on factors such how many links must be created, the complexity of the rules, etc. Complicating the situation further it is not uncommon for udev to create and then remove a link multiple times while processing the udev rules. Given the above, the existing scheme of waiting for an expected partition to appear by name isn't 100% reliable. At this point udev may still remove and recreate think link resulting in the kernel modules being unable to open the device. In order to address this the zpool_label_disk_wait() function has been updated to use libudev. Until the registered system device acknowledges that it in fully initialized the function will wait. Once fully initialized all device links are checked and allowed to settle for 50ms. This makes it far more likely that all the device nodes will exist when the kernel modules need to open them. For systems without libudev an alternate zpool_label_disk_wait() was updated to include a settle time. In addition, the kernel modules were updated to include retry logic for this ENOENT case. Due to the improved checks in the utilities it is unlikely this logic will be invoked. However, if the rare event it is needed it will prevent a failure. Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Richard Laager <rlaager@wiktel.com> Closes #4523 Closes #3708 Closes #4077 Closes #4144 Closes #4214 Closes #4517
2016-04-19 21:19:12 +03:00
return (SET_ERROR(EINVAL));
}
/*
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
* Reopen the device if it is currently open. When expanding a
* partition force re-scanning the partition table if userland
* did not take care of this already. We need to do this while closed
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
* in order to get an accurate updated block device size. Then
* since udev may need to recreate the device links increase the
* open retry timeout before reporting the device as unavailable.
*/
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
vd = v->vdev_tsd;
if (vd) {
char disk_name[BDEVNAME_SIZE + 6] = "/dev/";
boolean_t reread_part = B_FALSE;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_enter(&vd->vd_lock, RW_WRITER);
bdh = vd->vd_bdh;
vd->vd_bdh = NULL;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
if (bdh) {
struct block_device *bdev = BDH_BDEV(bdh);
if (v->vdev_expanding && bdev != bdev_whole(bdev)) {
vdev_bdevname(bdev_whole(bdev), disk_name + 5);
/*
* If userland has BLKPG_RESIZE_PARTITION,
* then it should have updated the partition
* table already. We can detect this by
* comparing our current physical size
* with that of the device. If they are
* the same, then we must not have
* BLKPG_RESIZE_PARTITION or it failed to
* update the partition table online. We
* fallback to rescanning the partition
* table from the kernel below. However,
* if the capacity already reflects the
* updated partition, then we skip
* rescanning the partition table here.
*/
if (v->vdev_psize == bdev_capacity(bdev))
reread_part = B_TRUE;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
}
vdev_blkdev_put(bdh, smode, zfs_vdev_holder);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
}
if (reread_part) {
bdh = vdev_blkdev_get_by_path(disk_name, smode,
zfs_vdev_holder);
if (!BDH_IS_ERR(bdh)) {
int error =
vdev_bdev_reread_part(BDH_BDEV(bdh));
vdev_blkdev_put(bdh, smode, zfs_vdev_holder);
if (error == 0) {
timeout = MSEC2NSEC(
zfs_vdev_open_timeout_ms * 2);
}
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
}
}
} else {
vd = kmem_zalloc(sizeof (vdev_disk_t), KM_SLEEP);
rw_init(&vd->vd_lock, NULL, RW_DEFAULT, NULL);
rw_enter(&vd->vd_lock, RW_WRITER);
}
/*
* Devices are always opened by the path provided at configuration
* time. This means that if the provided path is a udev by-id path
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
* then drives may be re-cabled 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
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
* locations to maximize the systems tolerance 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.
Use udev for partition detection When ZFS partitions a block device it must wait for udev to create both a device node and all the device symlinks. This process takes a variable length of time and depends on factors such how many links must be created, the complexity of the rules, etc. Complicating the situation further it is not uncommon for udev to create and then remove a link multiple times while processing the udev rules. Given the above, the existing scheme of waiting for an expected partition to appear by name isn't 100% reliable. At this point udev may still remove and recreate think link resulting in the kernel modules being unable to open the device. In order to address this the zpool_label_disk_wait() function has been updated to use libudev. Until the registered system device acknowledges that it in fully initialized the function will wait. Once fully initialized all device links are checked and allowed to settle for 50ms. This makes it far more likely that all the device nodes will exist when the kernel modules need to open them. For systems without libudev an alternate zpool_label_disk_wait() was updated to include a settle time. In addition, the kernel modules were updated to include retry logic for this ENOENT case. Due to the improved checks in the utilities it is unlikely this logic will be invoked. However, if the rare event it is needed it will prevent a failure. Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Richard Laager <rlaager@wiktel.com> Closes #4523 Closes #3708 Closes #4077 Closes #4144 Closes #4214 Closes #4517
2016-04-19 21:19:12 +03:00
*
* The specified paths may be briefly removed and recreated in
* response to udev events. This should be exceptionally unlikely
* because the zpool command makes every effort to verify these paths
* have already settled prior to reaching this point. Therefore,
* a ENOENT failure at this point is highly likely to be transient
* and it is reasonable to sleep and retry before giving up. In
* practice delays have been observed to be on the order of 100ms.
*
* When ERESTARTSYS is returned it indicates the block device is
* a zvol which could not be opened due to the deadlock detection
* logic in zvol_open(). Extend the timeout and retry the open
* subsequent attempts are expected to eventually succeed.
*/
hrtime_t start = gethrtime();
bdh = BDH_ERR_PTR(-ENXIO);
while (BDH_IS_ERR(bdh) && ((gethrtime() - start) < timeout)) {
bdh = vdev_blkdev_get_by_path(v->vdev_path, smode,
zfs_vdev_holder);
if (unlikely(BDH_PTR_ERR(bdh) == -ENOENT)) {
/*
* There is no point of waiting since device is removed
* explicitly
*/
if (v->vdev_removed)
break;
schedule_timeout_interruptible(MSEC_TO_TICK(10));
} else if (unlikely(BDH_PTR_ERR(bdh) == -ERESTARTSYS)) {
timeout = MSEC2NSEC(zfs_vdev_open_timeout_ms * 10);
continue;
} else if (BDH_IS_ERR(bdh)) {
Use udev for partition detection When ZFS partitions a block device it must wait for udev to create both a device node and all the device symlinks. This process takes a variable length of time and depends on factors such how many links must be created, the complexity of the rules, etc. Complicating the situation further it is not uncommon for udev to create and then remove a link multiple times while processing the udev rules. Given the above, the existing scheme of waiting for an expected partition to appear by name isn't 100% reliable. At this point udev may still remove and recreate think link resulting in the kernel modules being unable to open the device. In order to address this the zpool_label_disk_wait() function has been updated to use libudev. Until the registered system device acknowledges that it in fully initialized the function will wait. Once fully initialized all device links are checked and allowed to settle for 50ms. This makes it far more likely that all the device nodes will exist when the kernel modules need to open them. For systems without libudev an alternate zpool_label_disk_wait() was updated to include a settle time. In addition, the kernel modules were updated to include retry logic for this ENOENT case. Due to the improved checks in the utilities it is unlikely this logic will be invoked. However, if the rare event it is needed it will prevent a failure. Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Richard Laager <rlaager@wiktel.com> Closes #4523 Closes #3708 Closes #4077 Closes #4144 Closes #4214 Closes #4517
2016-04-19 21:19:12 +03:00
break;
}
}
if (BDH_IS_ERR(bdh)) {
int error = -BDH_PTR_ERR(bdh);
vdev_dbgmsg(v, "open error=%d timeout=%llu/%llu", error,
(u_longlong_t)(gethrtime() - start),
(u_longlong_t)timeout);
vd->vd_bdh = NULL;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
v->vdev_tsd = vd;
rw_exit(&vd->vd_lock);
return (SET_ERROR(error));
} else {
vd->vd_bdh = bdh;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
v->vdev_tsd = vd;
rw_exit(&vd->vd_lock);
}
struct block_device *bdev = BDH_BDEV(vd->vd_bdh);
/* Determine the physical block size */
int physical_block_size = bdev_physical_block_size(bdev);
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
/* Determine the logical block size */
int logical_block_size = bdev_logical_block_size(bdev);
/*
* If the device has a write cache, clear the nowritecache flag,
* so that we start issuing flush requests again.
*/
v->vdev_nowritecache = !zfs_bdev_has_write_cache(bdev);
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
/* Set when device reports it supports TRIM. */
v->vdev_has_trim = bdev_discard_supported(bdev);
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
/* Set when device reports it supports secure TRIM. */
v->vdev_has_securetrim = bdev_secure_discard_supported(bdev);
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
/* Inform the ZIO pipeline that we are non-rotational */
v->vdev_nonrot = blk_queue_nonrot(bdev_get_queue(bdev));
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/* Physical volume size in bytes for the partition */
*psize = bdev_capacity(bdev);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/* Physical volume size in bytes including possible expansion space */
*max_psize = bdev_max_capacity(bdev, v->vdev_wholedisk);
/* Based on the minimum sector size set the block size */
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
*physical_ashift = highbit64(MAX(physical_block_size,
SPA_MINBLOCKSIZE)) - 1;
*logical_ashift = highbit64(MAX(logical_block_size,
SPA_MINBLOCKSIZE)) - 1;
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_bdh != NULL)
vdev_blkdev_put(vd->vd_bdh, spa_mode(v->vdev_spa),
zfs_vdev_holder);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_destroy(&vd->vd_lock);
kmem_free(vd, sizeof (vdev_disk_t));
v->vdev_tsd = NULL;
}
static inline void
vdev_submit_bio_impl(struct bio *bio)
{
#ifdef HAVE_1ARG_SUBMIT_BIO
(void) submit_bio(bio);
#else
(void) submit_bio(bio_data_dir(bio), bio);
#endif
}
/*
* preempt_schedule_notrace is GPL-only which breaks the ZFS build, so
* replace it with preempt_schedule under the following condition:
*/
#if defined(CONFIG_ARM64) && \
defined(CONFIG_PREEMPTION) && \
defined(CONFIG_BLK_CGROUP)
#define preempt_schedule_notrace(x) preempt_schedule(x)
#endif
/*
* As for the Linux 5.18 kernel bio_alloc() expects a block_device struct
* as an argument removing the need to set it with bio_set_dev(). This
* removes the need for all of the following compatibility code.
*/
#if !defined(HAVE_BIO_ALLOC_4ARG)
#ifdef HAVE_BIO_SET_DEV
#if defined(CONFIG_BLK_CGROUP) && defined(HAVE_BIO_SET_DEV_GPL_ONLY)
/*
* The Linux 5.5 kernel updated percpu_ref_tryget() which is inlined by
* blkg_tryget() to use rcu_read_lock() instead of rcu_read_lock_sched().
* As a side effect the function was converted to GPL-only. Define our
* own version when needed which uses rcu_read_lock_sched().
*
* The Linux 5.17 kernel split linux/blk-cgroup.h into a private and a public
* part, moving blkg_tryget into the private one. Define our own version.
*/
#if defined(HAVE_BLKG_TRYGET_GPL_ONLY) || !defined(HAVE_BLKG_TRYGET)
static inline bool
vdev_blkg_tryget(struct blkcg_gq *blkg)
{
struct percpu_ref *ref = &blkg->refcnt;
unsigned long __percpu *count;
bool rc;
rcu_read_lock_sched();
if (__ref_is_percpu(ref, &count)) {
this_cpu_inc(*count);
rc = true;
} else {
#ifdef ZFS_PERCPU_REF_COUNT_IN_DATA
rc = atomic_long_inc_not_zero(&ref->data->count);
#else
rc = atomic_long_inc_not_zero(&ref->count);
#endif
}
rcu_read_unlock_sched();
return (rc);
}
#else
#define vdev_blkg_tryget(bg) blkg_tryget(bg)
#endif
#ifdef HAVE_BIO_SET_DEV_MACRO
/*
* The Linux 5.0 kernel updated the bio_set_dev() macro so it calls the
* GPL-only bio_associate_blkg() symbol thus inadvertently converting
* the entire macro. Provide a minimal version which always assigns the
* request queue's root_blkg to the bio.
*/
static inline void
vdev_bio_associate_blkg(struct bio *bio)
{
#if defined(HAVE_BIO_BDEV_DISK)
struct request_queue *q = bio->bi_bdev->bd_disk->queue;
#else
struct request_queue *q = bio->bi_disk->queue;
#endif
ASSERT3P(q, !=, NULL);
ASSERT3P(bio->bi_blkg, ==, NULL);
if (q->root_blkg && vdev_blkg_tryget(q->root_blkg))
bio->bi_blkg = q->root_blkg;
}
#define bio_associate_blkg vdev_bio_associate_blkg
#else
static inline void
vdev_bio_set_dev(struct bio *bio, struct block_device *bdev)
{
#if defined(HAVE_BIO_BDEV_DISK)
struct request_queue *q = bdev->bd_disk->queue;
#else
struct request_queue *q = bio->bi_disk->queue;
#endif
bio_clear_flag(bio, BIO_REMAPPED);
if (bio->bi_bdev != bdev)
bio_clear_flag(bio, BIO_THROTTLED);
bio->bi_bdev = bdev;
ASSERT3P(q, !=, NULL);
ASSERT3P(bio->bi_blkg, ==, NULL);
if (q->root_blkg && vdev_blkg_tryget(q->root_blkg))
bio->bi_blkg = q->root_blkg;
}
#define bio_set_dev vdev_bio_set_dev
#endif
#endif
#else
/*
* Provide a bio_set_dev() helper macro for pre-Linux 4.14 kernels.
*/
static inline void
bio_set_dev(struct bio *bio, struct block_device *bdev)
{
bio->bi_bdev = bdev;
}
#endif /* HAVE_BIO_SET_DEV */
#endif /* !HAVE_BIO_ALLOC_4ARG */
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(struct bio *bio)
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
{
struct bio_list *bio_list = current->bio_list;
current->bio_list = NULL;
vdev_submit_bio_impl(bio);
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
current->bio_list = bio_list;
}
static inline struct bio *
vdev_bio_alloc(struct block_device *bdev, gfp_t gfp_mask,
unsigned short nr_vecs)
{
struct bio *bio;
#ifdef HAVE_BIO_ALLOC_4ARG
bio = bio_alloc(bdev, nr_vecs, 0, gfp_mask);
#else
bio = bio_alloc(gfp_mask, nr_vecs);
if (likely(bio != NULL))
bio_set_dev(bio, bdev);
#endif
return (bio);
}
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
static inline uint_t
vdev_bio_max_segs(struct block_device *bdev)
{
/*
* Smallest of the device max segs and the tuneable max segs. Minimum
* 4, so there's room to finish split pages if they come up.
*/
const uint_t dev_max_segs = queue_max_segments(bdev_get_queue(bdev));
const uint_t tune_max_segs = (zfs_vdev_disk_max_segs > 0) ?
MAX(4, zfs_vdev_disk_max_segs) : dev_max_segs;
const uint_t max_segs = MIN(tune_max_segs, dev_max_segs);
#ifdef HAVE_BIO_MAX_SEGS
return (bio_max_segs(max_segs));
#else
return (MIN(max_segs, BIO_MAX_PAGES));
#endif
}
static inline uint_t
vdev_bio_max_bytes(struct block_device *bdev)
{
return (queue_max_sectors(bdev_get_queue(bdev)) << 9);
}
/*
* Virtual block IO object (VBIO)
*
* Linux block IO (BIO) objects have a limit on how many data segments (pages)
* they can hold. Depending on how they're allocated and structured, a large
* ZIO can require more than one BIO to be submitted to the kernel, which then
* all have to complete before we can return the completed ZIO back to ZFS.
*
* A VBIO is a wrapper around multiple BIOs, carrying everything needed to
* translate a ZIO down into the kernel block layer and back again.
*
* Note that these are only used for data ZIOs (read/write). Meta-operations
* (flush/trim) don't need multiple BIOs and so can just make the call
* directly.
*/
typedef struct {
zio_t *vbio_zio; /* parent zio */
struct block_device *vbio_bdev; /* blockdev to submit bios to */
abd_t *vbio_abd; /* abd carrying borrowed linear buf */
uint_t vbio_max_segs; /* max segs per bio */
uint_t vbio_max_bytes; /* max bytes per bio */
uint_t vbio_lbs_mask; /* logical block size mask */
uint64_t vbio_offset; /* start offset of next bio */
struct bio *vbio_bio; /* pointer to the current bio */
int vbio_flags; /* bio flags */
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
} vbio_t;
static vbio_t *
vbio_alloc(zio_t *zio, struct block_device *bdev, int flags)
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
{
vbio_t *vbio = kmem_zalloc(sizeof (vbio_t), KM_SLEEP);
vbio->vbio_zio = zio;
vbio->vbio_bdev = bdev;
vbio->vbio_abd = NULL;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
vbio->vbio_max_segs = vdev_bio_max_segs(bdev);
vbio->vbio_max_bytes = vdev_bio_max_bytes(bdev);
vbio->vbio_lbs_mask = ~(bdev_logical_block_size(bdev)-1);
vbio->vbio_offset = zio->io_offset;
vbio->vbio_bio = NULL;
vbio->vbio_flags = flags;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
return (vbio);
}
BIO_END_IO_PROTO(vbio_completion, bio, error);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
static int
vbio_add_page(vbio_t *vbio, struct page *page, uint_t size, uint_t offset)
{
struct bio *bio = vbio->vbio_bio;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
uint_t ssize;
while (size > 0) {
if (bio == NULL) {
/* New BIO, allocate and set up */
bio = vdev_bio_alloc(vbio->vbio_bdev, GFP_NOIO,
vbio->vbio_max_segs);
VERIFY(bio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
BIO_BI_SECTOR(bio) = vbio->vbio_offset >> 9;
bio_set_op_attrs(bio,
vbio->vbio_zio->io_type == ZIO_TYPE_WRITE ?
WRITE : READ, vbio->vbio_flags);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
if (vbio->vbio_bio) {
bio_chain(vbio->vbio_bio, bio);
vdev_submit_bio(vbio->vbio_bio);
}
vbio->vbio_bio = bio;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
}
/*
* Only load as much of the current page data as will fit in
* the space left in the BIO, respecting lbs alignment. Older
* kernels will error if we try to overfill the BIO, while
* newer ones will accept it and split the BIO. This ensures
* everything works on older kernels, and avoids an additional
* overhead on the new.
*/
ssize = MIN(size, (vbio->vbio_max_bytes - BIO_BI_SIZE(bio)) &
vbio->vbio_lbs_mask);
if (ssize > 0 &&
bio_add_page(bio, page, ssize, offset) == ssize) {
/* Accepted, adjust and load any remaining. */
size -= ssize;
offset += ssize;
continue;
}
/* No room, set up for a new BIO and loop */
vbio->vbio_offset += BIO_BI_SIZE(bio);
/* Signal new BIO allocation wanted */
bio = NULL;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
}
return (0);
}
/* Iterator callback to submit ABD pages to the vbio. */
static int
vbio_fill_cb(struct page *page, size_t off, size_t len, void *priv)
{
vbio_t *vbio = priv;
return (vbio_add_page(vbio, page, len, off));
}
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* Create some BIOs, fill them with data and submit them */
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
static void
vbio_submit(vbio_t *vbio, abd_t *abd, uint64_t size)
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
{
/*
* We plug so we can submit the BIOs as we go and only unplug them when
* they are fully created and submitted. This is important; if we don't
* plug, then the kernel may start executing earlier BIOs while we're
* still creating and executing later ones, and if the device goes
* away while that's happening, older kernels can get confused and
* trample memory.
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
*/
struct blk_plug plug;
blk_start_plug(&plug);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
(void) abd_iterate_page_func(abd, 0, size, vbio_fill_cb, vbio);
ASSERT(vbio->vbio_bio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
vbio->vbio_bio->bi_end_io = vbio_completion;
vbio->vbio_bio->bi_private = vbio;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/*
* Once submitted, vbio_bio now owns vbio (through bi_private) and we
* can't touch it again. The bio may complete and vbio_completion() be
* called and free the vbio before this task is run again, so we must
* consider it invalid from this point.
*/
vdev_submit_bio(vbio->vbio_bio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
blk_finish_plug(&plug);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
}
/* IO completion callback */
BIO_END_IO_PROTO(vbio_completion, bio, error)
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
{
vbio_t *vbio = bio->bi_private;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
zio_t *zio = vbio->vbio_zio;
ASSERT(zio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* Capture and log any errors */
#ifdef HAVE_1ARG_BIO_END_IO_T
zio->io_error = BIO_END_IO_ERROR(bio);
#else
zio->io_error = 0;
if (error)
zio->io_error = -(error);
else if (!test_bit(BIO_UPTODATE, &bio->bi_flags))
zio->io_error = EIO;
#endif
ASSERT3U(zio->io_error, >=, 0);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
if (zio->io_error)
vdev_disk_error(zio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* Return the BIO to the kernel */
bio_put(bio);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/*
* If we copied the ABD before issuing it, clean up and return the copy
* to the ADB, with changes if appropriate.
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
*/
if (vbio->vbio_abd != NULL) {
void *buf = abd_to_buf(vbio->vbio_abd);
abd_free(vbio->vbio_abd);
vbio->vbio_abd = NULL;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
if (zio->io_type == ZIO_TYPE_READ)
abd_return_buf_copy(zio->io_abd, buf, zio->io_size);
else
abd_return_buf(zio->io_abd, buf, zio->io_size);
}
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* Final cleanup */
kmem_free(vbio, sizeof (vbio_t));
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* All done, submit for processing */
zio_delay_interrupt(zio);
}
/*
* Iterator callback to count ABD pages and check their size & alignment.
*
* On Linux, each BIO segment can take a page pointer, and an offset+length of
* the data within that page. A page can be arbitrarily large ("compound"
* pages) but we still have to ensure the data portion is correctly sized and
* aligned to the logical block size, to ensure that if the kernel wants to
* split the BIO, the two halves will still be properly aligned.
*
* NOTE: if you change this function, change the copy in
* tests/zfs-tests/tests/functional/vdev_disk/page_alignment.c, and add test
* data there to validate the change you're making.
*
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
*/
typedef struct {
uint_t bmask;
uint_t npages;
uint_t end;
} vdev_disk_check_pages_t;
static int
vdev_disk_check_pages_cb(struct page *page, size_t off, size_t len, void *priv)
{
(void) page;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
vdev_disk_check_pages_t *s = priv;
/*
* If we didn't finish on a block size boundary last time, then there
* would be a gap if we tried to use this ABD as-is, so abort.
*/
if (s->end != 0)
return (1);
/*
* Note if we're taking less than a full block, so we can check it
* above on the next call.
*/
s->end = (off+len) & s->bmask;
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
/* All blocks after the first must start on a block size boundary. */
if (s->npages != 0 && (off & s->bmask) != 0)
return (1);
s->npages++;
return (0);
}
/*
* Check if we can submit the pages in this ABD to the kernel as-is. Returns
* the number of pages, or 0 if it can't be submitted like this.
*/
static boolean_t
vdev_disk_check_pages(abd_t *abd, uint64_t size, struct block_device *bdev)
{
vdev_disk_check_pages_t s = {
.bmask = bdev_logical_block_size(bdev)-1,
.npages = 0,
.end = 0,
};
if (abd_iterate_page_func(abd, 0, size, vdev_disk_check_pages_cb, &s))
return (B_FALSE);
return (B_TRUE);
}
static int
vdev_disk_io_rw(zio_t *zio)
{
vdev_t *v = zio->io_vd;
vdev_disk_t *vd = v->vdev_tsd;
struct block_device *bdev = BDH_BDEV(vd->vd_bdh);
int flags = 0;
/*
* Accessing outside the block device is never allowed.
*/
if (zio->io_offset + zio->io_size > bdev_capacity(bdev)) {
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
vdev_dbgmsg(zio->io_vd,
"Illegal access %llu size %llu, device size %llu",
(u_longlong_t)zio->io_offset,
(u_longlong_t)zio->io_size,
(u_longlong_t)bdev_capacity(bdev));
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
return (SET_ERROR(EIO));
}
if (!(zio->io_flags & (ZIO_FLAG_IO_RETRY | ZIO_FLAG_TRYHARD)) &&
v->vdev_failfast == B_TRUE) {
bio_set_flags_failfast(bdev, &flags, zfs_vdev_failfast_mask & 1,
zfs_vdev_failfast_mask & 2, zfs_vdev_failfast_mask & 4);
}
/*
* Check alignment of the incoming ABD. If any part of it would require
* submitting a page that is not aligned to the logical block size,
* then we take a copy into a linear buffer and submit that instead.
* This should be impossible on a 512b LBS, and fairly rare on 4K,
* usually requiring abnormally-small data blocks (eg gang blocks)
* mixed into the same ABD as larger ones (eg aggregated).
*/
abd_t *abd = zio->io_abd;
if (!vdev_disk_check_pages(abd, zio->io_size, bdev)) {
void *buf;
if (zio->io_type == ZIO_TYPE_READ)
buf = abd_borrow_buf(zio->io_abd, zio->io_size);
else
buf = abd_borrow_buf_copy(zio->io_abd, zio->io_size);
/*
* Wrap the copy in an abd_t, so we can use the same iterators
* to count and fill the vbio later.
*/
abd = abd_get_from_buf(buf, zio->io_size);
/*
* False here would mean the borrowed copy has an invalid
* alignment too, which would mean we've somehow been passed a
* linear ABD with an interior page that has a non-zero offset
* or a size not a multiple of PAGE_SIZE. This is not possible.
* It would mean either zio_buf_alloc() or its underlying
* allocators have done something extremely strange, or our
* math in vdev_disk_check_pages() is wrong. In either case,
* something in seriously wrong and its not safe to continue.
*/
VERIFY(vdev_disk_check_pages(abd, zio->io_size, bdev));
}
/* Allocate vbio, with a pointer to the borrowed ABD if necessary */
vbio_t *vbio = vbio_alloc(zio, bdev, flags);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
if (abd != zio->io_abd)
vbio->vbio_abd = abd;
/* Fill it with data pages and submit it to the kernel */
vbio_submit(vbio, abd, zio->io_size);
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
return (0);
}
/* ========== */
/*
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
* This is the classic, battle-tested BIO submission code. Until we're totally
* sure that the new code is safe and correct in all cases, this will remain
* available and can be enabled by setting zfs_vdev_disk_classic=1 at module
* load time.
*
* These functions have been renamed to vdev_classic_* to make it clear what
* they belong to, but their implementations are unchanged.
*/
/*
* Virtual device vector for disks.
*/
typedef struct dio_request {
zio_t *dr_zio; /* Parent ZIO */
atomic_t dr_ref; /* References */
int dr_error; /* Bio error */
int dr_bio_count; /* Count of bio's */
struct bio *dr_bio[]; /* Attached bio's */
} dio_request_t;
static dio_request_t *
vdev_classic_dio_alloc(int bio_count)
{
dio_request_t *dr = kmem_zalloc(sizeof (dio_request_t) +
sizeof (struct bio *) * bio_count, KM_SLEEP);
atomic_set(&dr->dr_ref, 0);
dr->dr_bio_count = bio_count;
dr->dr_error = 0;
for (int i = 0; i < dr->dr_bio_count; i++)
dr->dr_bio[i] = NULL;
return (dr);
}
static void
vdev_classic_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_classic_dio_get(dio_request_t *dr)
{
atomic_inc(&dr->dr_ref);
}
static void
vdev_classic_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_classic_dio_free(dr);
if (zio) {
zio->io_error = error;
ASSERT3S(zio->io_error, >=, 0);
if (zio->io_error)
vdev_disk_error(zio);
zio_delay_interrupt(zio);
}
}
}
BIO_END_IO_PROTO(vdev_classic_physio_completion, bio, error)
{
dio_request_t *dr = bio->bi_private;
if (dr->dr_error == 0) {
#ifdef HAVE_1ARG_BIO_END_IO_T
dr->dr_error = BIO_END_IO_ERROR(bio);
#else
if (error)
dr->dr_error = -(error);
else if (!test_bit(BIO_UPTODATE, &bio->bi_flags))
dr->dr_error = EIO;
#endif
}
/* Drop reference acquired by vdev_classic_physio */
vdev_classic_dio_put(dr);
}
static inline unsigned int
vdev_classic_bio_max_segs(zio_t *zio, int bio_size, uint64_t abd_offset)
{
unsigned long nr_segs = abd_nr_pages_off(zio->io_abd,
bio_size, abd_offset);
#ifdef HAVE_BIO_MAX_SEGS
return (bio_max_segs(nr_segs));
#else
return (MIN(nr_segs, BIO_MAX_PAGES));
#endif
}
static int
vdev_classic_physio(zio_t *zio)
{
vdev_t *v = zio->io_vd;
vdev_disk_t *vd = v->vdev_tsd;
struct block_device *bdev = BDH_BDEV(vd->vd_bdh);
size_t io_size = zio->io_size;
uint64_t io_offset = zio->io_offset;
int rw = zio->io_type == ZIO_TYPE_READ ? READ : WRITE;
int flags = 0;
dio_request_t *dr;
uint64_t abd_offset;
uint64_t bio_offset;
int bio_size;
int bio_count = 16;
int error = 0;
struct blk_plug plug;
unsigned short nr_vecs;
Linux compat: Minimum kernel version 3.10 Increase the minimum supported kernel version from 2.6.32 to 3.10. This removes support for the following Linux enterprise distributions. Distribution | Kernel | End of Life ---------------- | ------ | ------------- Ubuntu 12.04 LTS | 3.2 | Apr 28, 2017 SLES 11 | 3.0 | Mar 32, 2019 RHEL / CentOS 6 | 2.6.32 | Nov 30, 2020 The following changes were made as part of removing support. * Updated `configure` to enforce a minimum kernel version as specified in the META file (Linux-Minimum: 3.10). configure: error: *** Cannot build against kernel version 2.6.32. *** The minimum supported kernel version is 3.10. * Removed all `configure` kABI checks and matching C code for interfaces which solely predate the Linux 3.10 kernel. * Updated all `configure` kABI checks to fail when an interface is missing which was in the 3.10 kernel up to the latest 5.1 kernel. Removed the HAVE_* preprocessor defines for these checks and updated the code to unconditionally use the verified interface. * Inverted the detection logic in several kABI checks to match the new interface as it appears in 3.10 and newer and not the legacy interface. * Consolidated the following checks in to individual files. Due the large number of changes in the checks it made sense to handle this now. It would be desirable to group other related checks in the same fashion, but this as left as future work. - config/kernel-blkdev.m4 - Block device kABI checks - config/kernel-blk-queue.m4 - Block queue kABI checks - config/kernel-bio.m4 - Bio interface kABI checks * Removed the kABI checks for sops->nr_cached_objects() and sops->free_cached_objects(). These interfaces are currently unused. Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #9566
2019-11-12 19:59:06 +03:00
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/*
* Accessing outside the block device is never allowed.
*/
if (io_offset + io_size > bdev_capacity(bdev)) {
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
vdev_dbgmsg(zio->io_vd,
"Illegal access %llu size %llu, device size %llu",
(u_longlong_t)io_offset,
(u_longlong_t)io_size,
(u_longlong_t)bdev_capacity(bdev));
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
return (SET_ERROR(EIO));
}
retry:
dr = vdev_classic_dio_alloc(bio_count);
if (!(zio->io_flags & (ZIO_FLAG_IO_RETRY | ZIO_FLAG_TRYHARD)) &&
zio->io_vd->vdev_failfast == B_TRUE) {
bio_set_flags_failfast(bdev, &flags, zfs_vdev_failfast_mask & 1,
zfs_vdev_failfast_mask & 2, zfs_vdev_failfast_mask & 4);
}
dr->dr_zio = zio;
/*
* Since bio's can have up to BIO_MAX_PAGES=256 iovec's, each of which
* is at least 512 bytes and at most PAGESIZE (typically 4K), one bio
* can cover at least 128KB and at most 1MB. When the required number
* of iovec's exceeds this, we are forced to break the IO in multiple
* bio's and wait for them all to complete. This is likely if the
* recordsize property is increased beyond 1MB. The default
* bio_count=16 should typically accommodate the maximum-size zio of
* 16MB.
*/
abd_offset = 0;
bio_offset = io_offset;
bio_size = io_size;
for (int i = 0; i <= dr->dr_bio_count; i++) {
/* Finished constructing bio's for given buffer */
if (bio_size <= 0)
break;
/*
* If additional bio's are required, we have to retry, but
* this should be rare - see the comment above.
*/
if (dr->dr_bio_count == i) {
vdev_classic_dio_free(dr);
bio_count *= 2;
goto retry;
}
nr_vecs = vdev_classic_bio_max_segs(zio, bio_size, abd_offset);
dr->dr_bio[i] = vdev_bio_alloc(bdev, GFP_NOIO, nr_vecs);
if (unlikely(dr->dr_bio[i] == NULL)) {
vdev_classic_dio_free(dr);
return (SET_ERROR(ENOMEM));
}
/* Matching put called by vdev_classic_physio_completion */
vdev_classic_dio_get(dr);
BIO_BI_SECTOR(dr->dr_bio[i]) = bio_offset >> 9;
dr->dr_bio[i]->bi_end_io = vdev_classic_physio_completion;
dr->dr_bio[i]->bi_private = dr;
bio_set_op_attrs(dr->dr_bio[i], rw, flags);
/* Remaining size is returned to become the new size */
bio_size = abd_bio_map_off(dr->dr_bio[i], zio->io_abd,
bio_size, abd_offset);
/* Advance in buffer and construct another bio if needed */
abd_offset += 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_classic_dio_get(dr);
if (dr->dr_bio_count > 1)
blk_start_plug(&plug);
/* Submit all bio's associated with this dio */
for (int i = 0; i < dr->dr_bio_count; i++) {
if (dr->dr_bio[i])
vdev_submit_bio(dr->dr_bio[i]);
}
if (dr->dr_bio_count > 1)
blk_finish_plug(&plug);
vdev_classic_dio_put(dr);
return (error);
}
/* ========== */
BIO_END_IO_PROTO(vdev_disk_io_flush_completion, bio, error)
{
zio_t *zio = bio->bi_private;
#ifdef HAVE_1ARG_BIO_END_IO_T
zio->io_error = BIO_END_IO_ERROR(bio);
#else
zio->io_error = -error;
#endif
if (zio->io_error && (zio->io_error == 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 (SET_ERROR(ENXIO));
bio = vdev_bio_alloc(bdev, GFP_NOIO, 0);
if (unlikely(bio == NULL))
return (SET_ERROR(ENOMEM));
bio->bi_end_io = vdev_disk_io_flush_completion;
bio->bi_private = zio;
bio_set_flush(bio);
vdev_submit_bio(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);
}
BIO_END_IO_PROTO(vdev_disk_discard_end_io, bio, error)
{
zio_t *zio = bio->bi_private;
#ifdef HAVE_1ARG_BIO_END_IO_T
zio->io_error = BIO_END_IO_ERROR(bio);
#else
zio->io_error = -error;
#endif
bio_put(bio);
if (zio->io_error)
vdev_disk_error(zio);
zio_interrupt(zio);
}
/*
* Wrappers for the different secure erase and discard APIs. We use async
* when available; in this case, *biop is set to the last bio in the chain.
*/
static int
vdev_bdev_issue_secure_erase(zfs_bdev_handle_t *bdh, sector_t sector,
sector_t nsect, struct bio **biop)
{
*biop = NULL;
int error;
#if defined(HAVE_BLKDEV_ISSUE_SECURE_ERASE)
error = blkdev_issue_secure_erase(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS);
#elif defined(HAVE_BLKDEV_ISSUE_DISCARD_ASYNC_FLAGS)
error = __blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS, BLKDEV_DISCARD_SECURE, biop);
#elif defined(HAVE_BLKDEV_ISSUE_DISCARD_FLAGS)
error = blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS, BLKDEV_DISCARD_SECURE);
#else
#error "unsupported kernel"
#endif
return (error);
}
static int
vdev_bdev_issue_discard(zfs_bdev_handle_t *bdh, sector_t sector,
sector_t nsect, struct bio **biop)
{
*biop = NULL;
int error;
#if defined(HAVE_BLKDEV_ISSUE_DISCARD_ASYNC_FLAGS)
error = __blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS, 0, biop);
#elif defined(HAVE_BLKDEV_ISSUE_DISCARD_ASYNC_NOFLAGS)
error = __blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS, biop);
#elif defined(HAVE_BLKDEV_ISSUE_DISCARD_FLAGS)
error = blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS, 0);
#elif defined(HAVE_BLKDEV_ISSUE_DISCARD_NOFLAGS)
error = blkdev_issue_discard(BDH_BDEV(bdh),
sector, nsect, GFP_NOFS);
#else
#error "unsupported kernel"
#endif
return (error);
}
/*
* Entry point for TRIM ops. This calls the right wrapper for secure erase or
* discard, and then does the appropriate finishing work for error vs success
* and async vs sync.
*/
static int
vdev_disk_io_trim(zio_t *zio)
{
int error;
struct bio *bio;
zfs_bdev_handle_t *bdh = ((vdev_disk_t *)zio->io_vd->vdev_tsd)->vd_bdh;
sector_t sector = zio->io_offset >> 9;
sector_t nsects = zio->io_size >> 9;
if (zio->io_trim_flags & ZIO_TRIM_SECURE)
error = vdev_bdev_issue_secure_erase(bdh, sector, nsects, &bio);
else
error = vdev_bdev_issue_discard(bdh, sector, nsects, &bio);
if (error != 0)
return (SET_ERROR(-error));
if (bio == NULL) {
/*
* This was a synchronous op that completed successfully, so
* return it to ZFS immediately.
*/
zio_interrupt(zio);
} else {
/*
* This was an asynchronous op; set up completion callback and
* issue it.
*/
bio->bi_private = zio;
bio->bi_end_io = vdev_disk_discard_end_io;
vdev_submit_bio(bio);
}
return (0);
}
int (*vdev_disk_io_rw_fn)(zio_t *zio) = NULL;
static void
vdev_disk_io_start(zio_t *zio)
{
vdev_t *v = zio->io_vd;
vdev_disk_t *vd = v->vdev_tsd;
int error;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
/*
* If the vdev is closed, it's likely in the REMOVED or FAULTED state.
* Nothing to be done here but return failure.
*/
if (vd == NULL) {
zio->io_error = ENXIO;
zio_interrupt(zio);
return;
}
rw_enter(&vd->vd_lock, RW_READER);
/*
* If the vdev is closed, it's likely due to a failed reopen and is
* in the UNAVAIL state. Nothing to be done here but return failure.
*/
if (vd->vd_bdh == NULL) {
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_exit(&vd->vd_lock);
zio->io_error = ENXIO;
zio_interrupt(zio);
return;
}
switch (zio->io_type) {
case ZIO_TYPE_FLUSH:
if (!vdev_readable(v)) {
/* Drive not there, can't flush */
error = SET_ERROR(ENXIO);
} else if (zfs_nocacheflush) {
/* Flushing disabled by operator, declare success */
error = 0;
} else if (v->vdev_nowritecache) {
/* This vdev not capable of flushing */
error = SET_ERROR(ENOTSUP);
} else {
/*
* Issue the flush. If successful, the response will
* be handled in the completion callback, so we're done.
*/
error = vdev_disk_io_flush(BDH_BDEV(vd->vd_bdh), zio);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
if (error == 0) {
rw_exit(&vd->vd_lock);
return;
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
}
}
/* Couldn't issue the flush, so set the error and return it */
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_exit(&vd->vd_lock);
zio->io_error = error;
zio_execute(zio);
return;
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
case ZIO_TYPE_TRIM:
error = vdev_disk_io_trim(zio);
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
rw_exit(&vd->vd_lock);
if (error) {
zio->io_error = error;
zio_execute(zio);
}
Add TRIM support UNMAP/TRIM support is a frequently-requested feature to help prevent performance from degrading on SSDs and on various other SAN-like storage back-ends. By issuing UNMAP/TRIM commands for sectors which are no longer allocated the underlying device can often more efficiently manage itself. This TRIM implementation is modeled on the `zpool initialize` feature which writes a pattern to all unallocated space in the pool. The new `zpool trim` command uses the same vdev_xlate() code to calculate what sectors are unallocated, the same per- vdev TRIM thread model and locking, and the same basic CLI for a consistent user experience. The core difference is that instead of writing a pattern it will issue UNMAP/TRIM commands for those extents. The zio pipeline was updated to accommodate this by adding a new ZIO_TYPE_TRIM type and associated spa taskq. This new type makes is straight forward to add the platform specific TRIM/UNMAP calls to vdev_disk.c and vdev_file.c. These new ZIO_TYPE_TRIM zios are handled largely the same way as ZIO_TYPE_READs or ZIO_TYPE_WRITEs. This makes it possible to largely avoid changing the pipieline, one exception is that TRIM zio's may exceed the 16M block size limit since they contain no data. In addition to the manual `zpool trim` command, a background automatic TRIM was added and is controlled by the 'autotrim' property. It relies on the exact same infrastructure as the manual TRIM. However, instead of relying on the extents in a metaslab's ms_allocatable range tree, a ms_trim tree is kept per metaslab. When 'autotrim=on', ranges added back to the ms_allocatable tree are also added to the ms_free tree. The ms_free tree is then periodically consumed by an autotrim thread which systematically walks a top level vdev's metaslabs. Since the automatic TRIM will skip ranges it considers too small there is value in occasionally running a full `zpool trim`. This may occur when the freed blocks are small and not enough time was allowed to aggregate them. An automatic TRIM and a manual `zpool trim` may be run concurrently, in which case the automatic TRIM will yield to the manual TRIM. Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Tim Chase <tim@chase2k.com> Reviewed-by: Matt Ahrens <mahrens@delphix.com> Reviewed-by: George Wilson <george.wilson@delphix.com> Reviewed-by: Serapheim Dimitropoulos <serapheim@delphix.com> Contributions-by: Saso Kiselkov <saso.kiselkov@nexenta.com> Contributions-by: Tim Chase <tim@chase2k.com> Contributions-by: Chunwei Chen <tuxoko@gmail.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #8419 Closes #598
2019-03-29 19:13:20 +03:00
return;
case ZIO_TYPE_READ:
case ZIO_TYPE_WRITE:
zio->io_target_timestamp = zio_handle_io_delay(zio);
error = vdev_disk_io_rw_fn(zio);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_exit(&vd->vd_lock);
if (error) {
zio->io_error = error;
zio_interrupt(zio);
}
return;
default:
/*
* Getting here means our parent vdev has made a very strange
* request of us, and shouldn't happen. Assert here to force a
* crash in dev builds, but in production return the IO
* unhandled. The pool will likely suspend anyway but that's
* nicer than crashing the kernel.
*/
ASSERT3S(zio->io_type, ==, -1);
Add support for autoexpand property While the autoexpand property may seem like a small feature it depends on a significant amount of system infrastructure. Enough of that infrastructure is now in place that with a few modifications for Linux it can be supported. Auto-expand works as follows; when a block device is modified (re-sized, closed after being open r/w, etc) a change uevent is generated for udev. The ZED, which is monitoring udev events, passes the change event along to zfs_deliver_dle() if the disk or partition contains a zfs_member as identified by blkid. From here the device is matched against all imported pool vdevs using the vdev_guid which was read from the label by blkid. If a match is found the ZED reopens the pool vdev. This re-opening is important because it allows the vdev to be briefly closed so the disk partition table can be re-read. Otherwise, it wouldn't be possible to report the maximum possible expansion size. Finally, if the property autoexpand=on a vdev expansion will be attempted. After performing some sanity checks on the disk to verify that it is safe to expand, the primary partition (-part1) will be expanded and the partition table updated. The partition is then re-opened (again) to detect the updated size which allows the new capacity to be used. In order to make all of the above possible the following changes were required: * Updated the zpool_expand_001_pos and zpool_expand_003_pos tests. These tests now create a pool which is layered on a loopback, scsi_debug, and file vdev. This allows for testing of non- partitioned block device (loopback), a partition block device (scsi_debug), and a file which does not receive udev change events. This provided for better test coverage, and by removing the layering on ZFS volumes there issues surrounding layering one pool on another are avoided. * zpool_find_vdev_by_physpath() updated to accept a vdev guid. This allows for matching by guid rather than path which is a more reliable way for the ZED to reference a vdev. * Fixed zfs_zevent_wait() signal handling which could result in the ZED spinning when a signal was not handled. * Removed vdev_disk_rrpart() functionality which can be abandoned in favor of kernel provided blkdev_reread_part() function. * Added a rwlock which is held as a writer while a disk is being reopened. This is important to prevent errors from occurring for any configuration related IOs which bypass the SCL_ZIO lock. The zpool_reopen_007_pos.ksh test case was added to verify IO error are never observed when reopening. This is not expected to impact IO performance. Additional fixes which aren't critical but were discovered and resolved in the course of developing this functionality. * Added PHYS_PATH="/dev/zvol/dataset" to the vdev configuration for ZFS volumes. This is as good as a unique physical path, while the volumes are not used in the test cases anymore for other reasons this improvement was included. Reviewed by: Richard Elling <Richard.Elling@RichardElling.com> Signed-off-by: Sara Hartse <sara.hartse@delphix.com> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #120 Closes #2437 Closes #5771 Closes #7366 Closes #7582 Closes #7629
2018-07-24 01:40:15 +03:00
rw_exit(&vd->vd_lock);
zio->io_error = SET_ERROR(ENOTSUP);
zio_interrupt(zio);
return;
}
__builtin_unreachable();
}
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 (!zfs_check_disk_status(BDH_BDEV(vd->vd_bdh))) {
invalidate_bdev(BDH_BDEV(vd->vd_bdh));
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;
}
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 */
}
/*
* BIO submission method. See comment above about vdev_classic.
* Set zfs_vdev_disk_classic=0 for new, =1 for classic
*/
static uint_t zfs_vdev_disk_classic = 0; /* default new */
/* Set submission function from module parameter */
static int
vdev_disk_param_set_classic(const char *buf, zfs_kernel_param_t *kp)
{
int err = param_set_uint(buf, kp);
if (err < 0)
return (SET_ERROR(err));
vdev_disk_io_rw_fn =
zfs_vdev_disk_classic ? vdev_classic_physio : vdev_disk_io_rw;
printk(KERN_INFO "ZFS: forcing %s BIO submission\n",
zfs_vdev_disk_classic ? "classic" : "new");
return (0);
}
/*
* At first use vdev use, set the submission function from the default value if
* it hasn't been set already.
*/
static int
vdev_disk_init(spa_t *spa, nvlist_t *nv, void **tsd)
{
(void) spa;
(void) nv;
(void) tsd;
if (vdev_disk_io_rw_fn == NULL)
vdev_disk_io_rw_fn = zfs_vdev_disk_classic ?
vdev_classic_physio : vdev_disk_io_rw;
return (0);
}
vdev_ops_t vdev_disk_ops = {
.vdev_op_init = vdev_disk_init,
Distributed Spare (dRAID) Feature This patch adds a new top-level vdev type called dRAID, which stands for Distributed parity RAID. This pool configuration allows all dRAID vdevs to participate when rebuilding to a distributed hot spare device. This can substantially reduce the total time required to restore full parity to pool with a failed device. A dRAID pool can be created using the new top-level `draid` type. Like `raidz`, the desired redundancy is specified after the type: `draid[1,2,3]`. No additional information is required to create the pool and reasonable default values will be chosen based on the number of child vdevs in the dRAID vdev. zpool create <pool> draid[1,2,3] <vdevs...> Unlike raidz, additional optional dRAID configuration values can be provided as part of the draid type as colon separated values. This allows administrators to fully specify a layout for either performance or capacity reasons. The supported options include: zpool create <pool> \ draid[<parity>][:<data>d][:<children>c][:<spares>s] \ <vdevs...> - draid[parity] - Parity level (default 1) - draid[:<data>d] - Data devices per group (default 8) - draid[:<children>c] - Expected number of child vdevs - draid[:<spares>s] - Distributed hot spares (default 0) Abbreviated example `zpool status` output for a 68 disk dRAID pool with two distributed spares using special allocation classes. ``` pool: tank state: ONLINE config: NAME STATE READ WRITE CKSUM slag7 ONLINE 0 0 0 draid2:8d:68c:2s-0 ONLINE 0 0 0 L0 ONLINE 0 0 0 L1 ONLINE 0 0 0 ... U25 ONLINE 0 0 0 U26 ONLINE 0 0 0 spare-53 ONLINE 0 0 0 U27 ONLINE 0 0 0 draid2-0-0 ONLINE 0 0 0 U28 ONLINE 0 0 0 U29 ONLINE 0 0 0 ... U42 ONLINE 0 0 0 U43 ONLINE 0 0 0 special mirror-1 ONLINE 0 0 0 L5 ONLINE 0 0 0 U5 ONLINE 0 0 0 mirror-2 ONLINE 0 0 0 L6 ONLINE 0 0 0 U6 ONLINE 0 0 0 spares draid2-0-0 INUSE currently in use draid2-0-1 AVAIL ``` When adding test coverage for the new dRAID vdev type the following options were added to the ztest command. These options are leverages by zloop.sh to test a wide range of dRAID configurations. -K draid|raidz|random - kind of RAID to test -D <value> - dRAID data drives per group -S <value> - dRAID distributed hot spares -R <value> - RAID parity (raidz or dRAID) The zpool_create, zpool_import, redundancy, replacement and fault test groups have all been updated provide test coverage for the dRAID feature. Co-authored-by: Isaac Huang <he.huang@intel.com> Co-authored-by: Mark Maybee <mmaybee@cray.com> Co-authored-by: Don Brady <don.brady@delphix.com> Co-authored-by: Matthew Ahrens <mahrens@delphix.com> Co-authored-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Mark Maybee <mmaybee@cray.com> Reviewed-by: Matt Ahrens <matt@delphix.com> Reviewed-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #10102
2020-11-14 00:51:51 +03:00
.vdev_op_fini = NULL,
.vdev_op_open = vdev_disk_open,
.vdev_op_close = vdev_disk_close,
.vdev_op_asize = vdev_default_asize,
Distributed Spare (dRAID) Feature This patch adds a new top-level vdev type called dRAID, which stands for Distributed parity RAID. This pool configuration allows all dRAID vdevs to participate when rebuilding to a distributed hot spare device. This can substantially reduce the total time required to restore full parity to pool with a failed device. A dRAID pool can be created using the new top-level `draid` type. Like `raidz`, the desired redundancy is specified after the type: `draid[1,2,3]`. No additional information is required to create the pool and reasonable default values will be chosen based on the number of child vdevs in the dRAID vdev. zpool create <pool> draid[1,2,3] <vdevs...> Unlike raidz, additional optional dRAID configuration values can be provided as part of the draid type as colon separated values. This allows administrators to fully specify a layout for either performance or capacity reasons. The supported options include: zpool create <pool> \ draid[<parity>][:<data>d][:<children>c][:<spares>s] \ <vdevs...> - draid[parity] - Parity level (default 1) - draid[:<data>d] - Data devices per group (default 8) - draid[:<children>c] - Expected number of child vdevs - draid[:<spares>s] - Distributed hot spares (default 0) Abbreviated example `zpool status` output for a 68 disk dRAID pool with two distributed spares using special allocation classes. ``` pool: tank state: ONLINE config: NAME STATE READ WRITE CKSUM slag7 ONLINE 0 0 0 draid2:8d:68c:2s-0 ONLINE 0 0 0 L0 ONLINE 0 0 0 L1 ONLINE 0 0 0 ... U25 ONLINE 0 0 0 U26 ONLINE 0 0 0 spare-53 ONLINE 0 0 0 U27 ONLINE 0 0 0 draid2-0-0 ONLINE 0 0 0 U28 ONLINE 0 0 0 U29 ONLINE 0 0 0 ... U42 ONLINE 0 0 0 U43 ONLINE 0 0 0 special mirror-1 ONLINE 0 0 0 L5 ONLINE 0 0 0 U5 ONLINE 0 0 0 mirror-2 ONLINE 0 0 0 L6 ONLINE 0 0 0 U6 ONLINE 0 0 0 spares draid2-0-0 INUSE currently in use draid2-0-1 AVAIL ``` When adding test coverage for the new dRAID vdev type the following options were added to the ztest command. These options are leverages by zloop.sh to test a wide range of dRAID configurations. -K draid|raidz|random - kind of RAID to test -D <value> - dRAID data drives per group -S <value> - dRAID distributed hot spares -R <value> - RAID parity (raidz or dRAID) The zpool_create, zpool_import, redundancy, replacement and fault test groups have all been updated provide test coverage for the dRAID feature. Co-authored-by: Isaac Huang <he.huang@intel.com> Co-authored-by: Mark Maybee <mmaybee@cray.com> Co-authored-by: Don Brady <don.brady@delphix.com> Co-authored-by: Matthew Ahrens <mahrens@delphix.com> Co-authored-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Mark Maybee <mmaybee@cray.com> Reviewed-by: Matt Ahrens <matt@delphix.com> Reviewed-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #10102
2020-11-14 00:51:51 +03:00
.vdev_op_min_asize = vdev_default_min_asize,
.vdev_op_min_alloc = NULL,
.vdev_op_io_start = vdev_disk_io_start,
.vdev_op_io_done = vdev_disk_io_done,
.vdev_op_state_change = NULL,
.vdev_op_need_resilver = NULL,
.vdev_op_hold = vdev_disk_hold,
.vdev_op_rele = vdev_disk_rele,
.vdev_op_remap = NULL,
.vdev_op_xlate = vdev_default_xlate,
Distributed Spare (dRAID) Feature This patch adds a new top-level vdev type called dRAID, which stands for Distributed parity RAID. This pool configuration allows all dRAID vdevs to participate when rebuilding to a distributed hot spare device. This can substantially reduce the total time required to restore full parity to pool with a failed device. A dRAID pool can be created using the new top-level `draid` type. Like `raidz`, the desired redundancy is specified after the type: `draid[1,2,3]`. No additional information is required to create the pool and reasonable default values will be chosen based on the number of child vdevs in the dRAID vdev. zpool create <pool> draid[1,2,3] <vdevs...> Unlike raidz, additional optional dRAID configuration values can be provided as part of the draid type as colon separated values. This allows administrators to fully specify a layout for either performance or capacity reasons. The supported options include: zpool create <pool> \ draid[<parity>][:<data>d][:<children>c][:<spares>s] \ <vdevs...> - draid[parity] - Parity level (default 1) - draid[:<data>d] - Data devices per group (default 8) - draid[:<children>c] - Expected number of child vdevs - draid[:<spares>s] - Distributed hot spares (default 0) Abbreviated example `zpool status` output for a 68 disk dRAID pool with two distributed spares using special allocation classes. ``` pool: tank state: ONLINE config: NAME STATE READ WRITE CKSUM slag7 ONLINE 0 0 0 draid2:8d:68c:2s-0 ONLINE 0 0 0 L0 ONLINE 0 0 0 L1 ONLINE 0 0 0 ... U25 ONLINE 0 0 0 U26 ONLINE 0 0 0 spare-53 ONLINE 0 0 0 U27 ONLINE 0 0 0 draid2-0-0 ONLINE 0 0 0 U28 ONLINE 0 0 0 U29 ONLINE 0 0 0 ... U42 ONLINE 0 0 0 U43 ONLINE 0 0 0 special mirror-1 ONLINE 0 0 0 L5 ONLINE 0 0 0 U5 ONLINE 0 0 0 mirror-2 ONLINE 0 0 0 L6 ONLINE 0 0 0 U6 ONLINE 0 0 0 spares draid2-0-0 INUSE currently in use draid2-0-1 AVAIL ``` When adding test coverage for the new dRAID vdev type the following options were added to the ztest command. These options are leverages by zloop.sh to test a wide range of dRAID configurations. -K draid|raidz|random - kind of RAID to test -D <value> - dRAID data drives per group -S <value> - dRAID distributed hot spares -R <value> - RAID parity (raidz or dRAID) The zpool_create, zpool_import, redundancy, replacement and fault test groups have all been updated provide test coverage for the dRAID feature. Co-authored-by: Isaac Huang <he.huang@intel.com> Co-authored-by: Mark Maybee <mmaybee@cray.com> Co-authored-by: Don Brady <don.brady@delphix.com> Co-authored-by: Matthew Ahrens <mahrens@delphix.com> Co-authored-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Mark Maybee <mmaybee@cray.com> Reviewed-by: Matt Ahrens <matt@delphix.com> Reviewed-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Closes #10102
2020-11-14 00:51:51 +03:00
.vdev_op_rebuild_asize = NULL,
.vdev_op_metaslab_init = NULL,
.vdev_op_config_generate = NULL,
.vdev_op_nparity = NULL,
.vdev_op_ndisks = NULL,
.vdev_op_type = VDEV_TYPE_DISK, /* name of this vdev type */
.vdev_op_leaf = B_TRUE, /* leaf vdev */
.vdev_op_kobj_evt_post = vdev_disk_kobj_evt_post
};
/*
* The zfs_vdev_scheduler module option has been deprecated. Setting this
* value no longer has any effect. It has not yet been entirely removed
* to allow the module to be loaded if this option is specified in the
* /etc/modprobe.d/zfs.conf file. The following warning will be logged.
*/
static int
param_set_vdev_scheduler(const char *val, zfs_kernel_param_t *kp)
{
int error = param_set_charp(val, kp);
if (error == 0) {
printk(KERN_INFO "The 'zfs_vdev_scheduler' module option "
"is not supported.\n");
}
return (error);
}
static const char *zfs_vdev_scheduler = "unused";
module_param_call(zfs_vdev_scheduler, param_set_vdev_scheduler,
param_get_charp, &zfs_vdev_scheduler, 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");
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
int
param_set_min_auto_ashift(const char *buf, zfs_kernel_param_t *kp)
{
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
uint_t val;
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
int error;
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
error = kstrtouint(buf, 0, &val);
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
if (error < 0)
return (SET_ERROR(error));
if (val < ASHIFT_MIN || val > zfs_vdev_max_auto_ashift)
return (SET_ERROR(-EINVAL));
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
error = param_set_uint(buf, kp);
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
if (error < 0)
return (SET_ERROR(error));
return (0);
}
int
param_set_max_auto_ashift(const char *buf, zfs_kernel_param_t *kp)
{
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
uint_t val;
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
int error;
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
error = kstrtouint(buf, 0, &val);
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
if (error < 0)
return (SET_ERROR(error));
if (val > ASHIFT_MAX || val < zfs_vdev_min_auto_ashift)
return (SET_ERROR(-EINVAL));
Cleanup: 64-bit kernel module parameters should use fixed width types Various module parameters such as `zfs_arc_max` were originally `uint64_t` on OpenSolaris/Illumos, but were changed to `unsigned long` for Linux compatibility because Linux's kernel default module parameter implementation did not support 64-bit types on 32-bit platforms. This caused problems when porting OpenZFS to Windows because its LLP64 memory model made `unsigned long` a 32-bit type on 64-bit, which created the undesireable situation that parameters that should accept 64-bit values could not on 64-bit Windows. Upon inspection, it turns out that the Linux kernel module parameter interface is extensible, such that we are allowed to define our own types. Rather than maintaining the original type change via hacks to to continue shrinking module parameters on 32-bit Linux, we implement support for 64-bit module parameters on Linux. After doing a review of all 64-bit kernel parameters (found via the man page and also proposed changes by Andrew Innes), the kernel module parameters fell into a few groups: Parameters that were originally 64-bit on Illumos: * dbuf_cache_max_bytes * dbuf_metadata_cache_max_bytes * l2arc_feed_min_ms * l2arc_feed_secs * l2arc_headroom * l2arc_headroom_boost * l2arc_write_boost * l2arc_write_max * metaslab_aliquot * metaslab_force_ganging * zfetch_array_rd_sz * zfs_arc_max * zfs_arc_meta_limit * zfs_arc_meta_min * zfs_arc_min * zfs_async_block_max_blocks * zfs_condense_max_obsolete_bytes * zfs_condense_min_mapping_bytes * zfs_deadman_checktime_ms * zfs_deadman_synctime_ms * zfs_initialize_chunk_size * zfs_initialize_value * zfs_lua_max_instrlimit * zfs_lua_max_memlimit * zil_slog_bulk Parameters that were originally 32-bit on Illumos: * zfs_per_txg_dirty_frees_percent Parameters that were originally `ssize_t` on Illumos: * zfs_immediate_write_sz Note that `ssize_t` is `int32_t` on 32-bit and `int64_t` on 64-bit. It has been upgraded to 64-bit. Parameters that were `long`/`unsigned long` because of Linux/FreeBSD influence: * l2arc_rebuild_blocks_min_l2size * zfs_key_max_salt_uses * zfs_max_log_walking * zfs_max_logsm_summary_length * zfs_metaslab_max_size_cache_sec * zfs_min_metaslabs_to_flush * zfs_multihost_interval * zfs_unflushed_log_block_max * zfs_unflushed_log_block_min * zfs_unflushed_log_block_pct * zfs_unflushed_max_mem_amt * zfs_unflushed_max_mem_ppm New parameters that do not exist in Illumos: * l2arc_trim_ahead * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_arc_sys_free * zfs_deadman_ziotime_ms * zfs_delete_blocks * zfs_history_output_max * zfs_livelist_max_entries * zfs_max_async_dedup_frees * zfs_max_nvlist_src_size * zfs_rebuild_max_segment * zfs_rebuild_vdev_limit * zfs_unflushed_log_txg_max * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift * zfs_vnops_read_chunk_size * zvol_max_discard_blocks Rather than clutter the lists with commentary, the module parameters that need comments are repeated below. A few parameters were defined in Linux/FreeBSD specific code, where the use of ulong/long is not an issue for portability, so we leave them alone: * zfs_delete_blocks * zfs_key_max_salt_uses * zvol_max_discard_blocks The documentation for a few parameters was found to be incorrect: * zfs_deadman_checktime_ms - incorrectly documented as int * zfs_delete_blocks - not documented as Linux only * zfs_history_output_max - incorrectly documented as int * zfs_vnops_read_chunk_size - incorrectly documented as long * zvol_max_discard_blocks - incorrectly documented as ulong The documentation for these has been fixed, alongside the changes to document the switch to fixed width types. In addition, several kernel module parameters were percentages or held ashift values, so being 64-bit never made sense for them. They have been downgraded to 32-bit: * vdev_file_logical_ashift * vdev_file_physical_ashift * zfs_arc_dnode_limit_percent * zfs_arc_dnode_reduce_percent * zfs_arc_meta_limit_percent * zfs_per_txg_dirty_frees_percent * zfs_unflushed_log_block_pct * zfs_vdev_max_auto_ashift * zfs_vdev_min_auto_ashift Of special note are `zfs_vdev_max_auto_ashift` and `zfs_vdev_min_auto_ashift`, which were already defined as `uint64_t`, and passed to the kernel as `ulong`. This is inherently buggy on big endian 32-bit Linux, since the values would not be written to the correct locations. 32-bit FreeBSD was unaffected because its sysctl code correctly treated this as a `uint64_t`. Lastly, a code comment suggests that `zfs_arc_sys_free` is Linux-specific, but there is nothing to indicate to me that it is Linux-specific. Nothing was done about that. Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Jorgen Lundman <lundman@lundman.net> Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Alexander Motin <mav@FreeBSD.org> Original-patch-by: Andrew Innes <andrew.c12@gmail.com> Original-patch-by: Jorgen Lundman <lundman@lundman.net> Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu> Closes #13984 Closes #14004
2022-10-03 22:06:54 +03:00
error = param_set_uint(buf, kp);
Import vdev ashift optimization from FreeBSD Many modern devices use physical allocation units that are much larger than the minimum logical allocation size accessible by external commands. Two prevalent examples of this are 512e disk drives (512b logical sector, 4K physical sector) and flash devices (512b logical sector, 4K or larger allocation block size, and 128k or larger erase block size). Operations that modify less than the physical sector size result in a costly read-modify-write or garbage collection sequence on these devices. Simply exporting the true physical sector of the device to ZFS would yield optimal performance, but has two serious drawbacks: 1. Existing pools created with devices that have different logical and physical block sizes, but were configured to use the logical block size (e.g. because the OS version used for pool construction reported the logical block size instead of the physical block size) will suddenly find that the vdev allocation size has increased. This can be easily tolerated for active members of the array, but ZFS would prevent replacement of a vdev with another identical device because it now appears that the smaller allocation size required by the pool is not supported by the new device. 2. The device's physical block size may be too large to be supported by ZFS. The optimal allocation size for the vdev may be quite large. For example, a RAID controller may export a vdev that requires read-modify-write cycles unless accessed using 64k aligned/sized requests. ZFS currently has an 8k minimum block size limit. Reporting both the logical and physical allocation sizes for vdevs solves these problems. A device may be used so long as the logical block size is compatible with the configuration. By comparing the logical and physical block sizes, new configurations can be optimized and administrators can be notified of any existing pools that are sub-optimal. Reviewed-by: Ryan Moeller <ryan@iXsystems.com> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Co-authored-by: Matthew Macy <mmacy@freebsd.org> Signed-off-by: Matt Macy <mmacy@FreeBSD.org> Closes #10619
2020-08-21 22:53:17 +03:00
if (error < 0)
return (SET_ERROR(error));
return (0);
}
ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, open_timeout_ms, UINT, ZMOD_RW,
"Timeout before determining that a device is missing");
ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, failfast_mask, UINT, ZMOD_RW,
"Defines failfast mask: 1 - device, 2 - transport, 4 - driver");
vdev_disk: rewrite BIO filling machinery to avoid split pages This commit tackles a number of issues in the way BIOs (`struct bio`) are constructed for submission to the Linux block layer. The kernel has a hard upper limit on the number of pages/segments that can be added to a BIO, as well as a separate limit for each device (related to its queue depth and other scheduling characteristics). ZFS counts the number of memory pages in the request ABD (`abd_nr_pages_off()`, and then uses that as the number of segments to put into the BIO, up to the hard upper limit. If it requires more than the limit, it will create multiple BIOs. Leaving aside the fact that page count method is wrong (see below), not limiting to the device segment max means that the device driver will need to split the BIO in half. This is alone is not necessarily a problem, but it interacts with another issue to cause a much larger problem. The kernel function to add a segment to a BIO (`bio_add_page()`) takes a `struct page` pointer, and offset+len within it. `struct page` can represent a run of contiguous memory pages (known as a "compound page"). In can be of arbitrary length. The ZFS functions that count ABD pages and load them into the BIO (`abd_nr_pages_off()`, `bio_map()` and `abd_bio_map_off()`) will never consider a page to be more than `PAGE_SIZE` (4K), even if the `struct page` is for multiple pages. In this case, it will load the same `struct page` into the BIO multiple times, with the offset adjusted each time. With a sufficiently large ABD, this can easily lead to the BIO being entirely filled much earlier than it could have been. This is also further contributes to the problem caused by the incorrect segment limit calculation, as its much easier to go past the device limit, and so require a split. Again, this is not a problem on its own. The logic for "never submit more than `PAGE_SIZE`" is actually a little more subtle. It will actually never submit a buffer that crosses a 4K page boundary. In practice, this is fine, as most ABDs are scattered, that is a list of complete 4K pages, and so are loaded in as such. Linear ABDs are typically allocated from slabs, and for small sizes they are frequently not aligned to page boundaries. For example, a 12K allocation can span four pages, eg: -- 4K -- -- 4K -- -- 4K -- -- 4K -- | | | | | :## ######## ######## ######: [1K, 4K, 4K, 3K] Such an allocation would be loaded into a BIO as you see: [1K, 4K, 4K, 3K] This tends not to be a problem in practice, because even if the BIO were filled and needed to be split, each half would still have either a start or end aligned to the logical block size of the device (assuming 4K at least). --- In ideal circumstances, these shortcomings don't cause any particular problems. Its when they start to interact with other ZFS features that things get interesting. Aggregation will create a "gang" ABD, which is simply a list of other ABDs. Iterating over a gang ABD is just iterating over each ABD within it in turn. Because the segments are simply loaded in order, we can end up with uneven segments either side of the "gap" between the two ABDs. For example, two 12K ABDs might be aggregated and then loaded as: [1K, 4K, 4K, 3K, 2K, 4K, 4K, 2K] Should a split occur, each individual BIO can end up either having an start or end offset that is not aligned to the logical block size, which some drivers (eg SCSI) will reject. However, this tends not to happen because the default aggregation limit usually keeps the BIO small enough to not require more than one split, and most pages are actually full 4K pages, so hitting an uneven gap is very rare anyway. If the pool is under particular memory pressure, then an IO can be broken down into a "gang block", a 512-byte block composed of a header and up to three block pointers. Each points to a fragment of the original write, or in turn, another gang block, breaking the original data up over and over until space can be found in the pool for each of them. Each gang header is a separate 512-byte memory allocation from a slab, that needs to be written down to disk. When the gang header is added to the BIO, its a single 512-byte segment. Pulling all this together, consider a large aggregated write of gang blocks. This results a BIO containing lots of 512-byte segments. Given our tendency to overfill the BIO, a split is likely, and most possible split points will yield a pair of BIOs that are misaligned. Drivers that care, like the SCSI driver, will reject them. --- This commit is a substantial refactor and rewrite of much of `vdev_disk` to sort all this out. `vdev_bio_max_segs()` now returns the ideal maximum size for the device, if available. There's also a tuneable `zfs_vdev_disk_max_segs` to override this, to assist with testing. We scan the ABD up front to count the number of pages within it, and to confirm that if we submitted all those pages to one or more BIOs, it could be split at any point with creating a misaligned BIO. If the pages in the BIO are not usable (as in any of the above situations), the ABD is linearised, and then checked again. This is the same technique used in `vdev_geom` on FreeBSD, adjusted for Linux's variable page size and allocator quirks. `vbio_t` is a cleanup and enhancement of the old `dio_request_t`. The idea is simply that it can hold all the state needed to create, submit and return multiple BIOs, including all the refcounts, the ABD copy if it was needed, and so on. Apart from what I hope is a clearer interface, the major difference is that because we know how many BIOs we'll need up front, we don't need the old overflow logic that would grow the BIO array, throw away all the old work and restart. We can get it right from the start. Reviewed-by: Alexander Motin <mav@FreeBSD.org> Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Signed-off-by: Rob Norris <rob.norris@klarasystems.com> Sponsored-by: Klara, Inc. Sponsored-by: Wasabi Technology, Inc. Closes #15533 Closes #15588
2023-07-18 04:11:29 +03:00
ZFS_MODULE_PARAM(zfs_vdev_disk, zfs_vdev_disk_, max_segs, UINT, ZMOD_RW,
"Maximum number of data segments to add to an IO request (min 4)");
ZFS_MODULE_PARAM_CALL(zfs_vdev_disk, zfs_vdev_disk_, classic,
vdev_disk_param_set_classic, param_get_uint, ZMOD_RD,
"Use classic BIO submission method");