2020-02-28 13:04:17 +00:00
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// SPDX-License-Identifier: GPL-2.0
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2020-02-28 13:04:19 +00:00
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#include <linux/blkdev.h>
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2020-02-28 13:04:17 +00:00
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#include <linux/iversion.h>
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2022-10-19 14:50:51 +00:00
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#include "ctree.h"
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#include "fs.h"
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2022-10-19 14:50:49 +00:00
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#include "messages.h"
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2020-02-28 13:04:19 +00:00
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#include "compression.h"
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#include "delalloc-space.h"
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2022-05-31 15:06:34 +00:00
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#include "disk-io.h"
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2020-02-28 13:04:17 +00:00
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#include "reflink.h"
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#include "transaction.h"
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2021-05-31 08:50:53 +00:00
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#include "subpage.h"
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2022-10-19 14:51:00 +00:00
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#include "accessors.h"
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2022-10-26 19:08:27 +00:00
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#include "file-item.h"
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2022-10-26 19:08:30 +00:00
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#include "file.h"
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2022-10-26 19:08:40 +00:00
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#include "super.h"
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2020-02-28 13:04:17 +00:00
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#define BTRFS_MAX_DEDUPE_LEN SZ_16M
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static int clone_finish_inode_update(struct btrfs_trans_handle *trans,
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struct inode *inode,
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u64 endoff,
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const u64 destoff,
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const u64 olen,
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int no_time_update)
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{
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int ret;
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inode_inc_iversion(inode);
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2022-06-21 16:40:48 +00:00
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if (!no_time_update) {
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2023-10-04 18:52:08 +00:00
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inode_set_mtime_to_ts(inode, inode_set_ctime_current(inode));
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2022-06-21 16:40:48 +00:00
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}
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2020-02-28 13:04:17 +00:00
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/*
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* We round up to the block size at eof when determining which
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* extents to clone above, but shouldn't round up the file size.
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*/
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if (endoff > destoff + olen)
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endoff = destoff + olen;
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if (endoff > inode->i_size) {
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i_size_write(inode, endoff);
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2020-11-02 14:48:53 +00:00
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btrfs_inode_safe_disk_i_size_write(BTRFS_I(inode), 0);
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2020-02-28 13:04:17 +00:00
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}
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2023-09-22 10:37:22 +00:00
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ret = btrfs_update_inode(trans, BTRFS_I(inode));
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2020-02-28 13:04:17 +00:00
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if (ret) {
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btrfs_abort_transaction(trans, ret);
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btrfs_end_transaction(trans);
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goto out;
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}
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ret = btrfs_end_transaction(trans);
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out:
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return ret;
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}
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2020-08-31 11:42:47 +00:00
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static int copy_inline_to_page(struct btrfs_inode *inode,
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2020-02-28 13:04:19 +00:00
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const u64 file_offset,
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char *inline_data,
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const u64 size,
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const u64 datal,
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const u8 comp_type)
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{
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2021-05-31 08:50:53 +00:00
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struct btrfs_fs_info *fs_info = inode->root->fs_info;
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const u32 block_size = fs_info->sectorsize;
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2020-02-28 13:04:19 +00:00
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const u64 range_end = file_offset + block_size - 1;
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const size_t inline_size = size - btrfs_file_extent_calc_inline_size(0);
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char *data_start = inline_data + btrfs_file_extent_calc_inline_size(0);
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struct extent_changeset *data_reserved = NULL;
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struct page *page = NULL;
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2020-08-31 11:42:47 +00:00
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struct address_space *mapping = inode->vfs_inode.i_mapping;
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2020-02-28 13:04:19 +00:00
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int ret;
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ASSERT(IS_ALIGNED(file_offset, block_size));
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/*
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* We have flushed and locked the ranges of the source and destination
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* inodes, we also have locked the inodes, so we are safe to do a
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* reservation here. Also we must not do the reservation while holding
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* a transaction open, otherwise we would deadlock.
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*/
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2020-08-31 11:42:47 +00:00
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ret = btrfs_delalloc_reserve_space(inode, &data_reserved, file_offset,
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block_size);
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2020-02-28 13:04:19 +00:00
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if (ret)
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goto out;
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2020-08-31 11:42:47 +00:00
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page = find_or_create_page(mapping, file_offset >> PAGE_SHIFT,
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btrfs_alloc_write_mask(mapping));
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2020-02-28 13:04:19 +00:00
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if (!page) {
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ret = -ENOMEM;
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goto out_unlock;
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}
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2021-01-26 08:34:00 +00:00
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ret = set_page_extent_mapped(page);
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if (ret < 0)
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goto out_unlock;
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2020-08-31 11:42:47 +00:00
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clear_extent_bit(&inode->io_tree, file_offset, range_end,
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2020-02-28 13:04:19 +00:00
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EXTENT_DELALLOC | EXTENT_DO_ACCOUNTING | EXTENT_DEFRAG,
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2022-09-09 21:53:47 +00:00
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NULL);
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2020-08-31 11:42:47 +00:00
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ret = btrfs_set_extent_delalloc(inode, file_offset, range_end, 0, NULL);
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2020-02-28 13:04:19 +00:00
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if (ret)
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goto out_unlock;
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btrfs: fix deadlock when cloning inline extent and low on free metadata space
When cloning an inline extent there are cases where we can not just copy
the inline extent from the source range to the target range (e.g. when the
target range starts at an offset greater than zero). In such cases we copy
the inline extent's data into a page of the destination inode and then
dirty that page. However, after that we will need to start a transaction
for each processed extent and, if we are ever low on available metadata
space, we may need to flush existing delalloc for all dirty inodes in an
attempt to release metadata space - if that happens we may deadlock:
* the async reclaim task queued a delalloc work to flush delalloc for
the destination inode of the clone operation;
* the task executing that delalloc work gets blocked waiting for the
range with the dirty page to be unlocked, which is currently locked
by the task doing the clone operation;
* the async reclaim task blocks waiting for the delalloc work to complete;
* the cloning task is waiting on the waitqueue of its reservation ticket
while holding the range with the dirty page locked in the inode's
io_tree;
* if metadata space is not released by some other task (like delalloc for
some other inode completing for example), the clone task waits forever
and as a consequence the delalloc work and async reclaim tasks will hang
forever as well. Releasing more space on the other hand may require
starting a transaction, which will hang as well when trying to reserve
metadata space, resulting in a deadlock between all these tasks.
When this happens, traces like the following show up in dmesg/syslog:
[87452.323003] INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
[87452.323644] Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
[87452.324248] "echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
[87452.324852] task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
[87452.325520] Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
[87452.326136] Call Trace:
[87452.326737] __schedule+0x5d1/0xcf0
[87452.327390] schedule+0x45/0xe0
[87452.328174] lock_extent_bits+0x1e6/0x2d0 [btrfs]
[87452.328894] ? finish_wait+0x90/0x90
[87452.329474] btrfs_invalidatepage+0x32c/0x390 [btrfs]
[87452.330133] ? __mod_memcg_state+0x8e/0x160
[87452.330738] __extent_writepage+0x2d4/0x400 [btrfs]
[87452.331405] extent_write_cache_pages+0x2b2/0x500 [btrfs]
[87452.332007] ? lock_release+0x20e/0x4c0
[87452.332557] ? trace_hardirqs_on+0x1b/0xf0
[87452.333127] extent_writepages+0x43/0x90 [btrfs]
[87452.333653] ? lock_acquire+0x1a3/0x490
[87452.334177] do_writepages+0x43/0xe0
[87452.334699] ? __filemap_fdatawrite_range+0xa4/0x100
[87452.335720] __filemap_fdatawrite_range+0xc5/0x100
[87452.336500] btrfs_run_delalloc_work+0x17/0x40 [btrfs]
[87452.337216] btrfs_work_helper+0xf1/0x600 [btrfs]
[87452.337838] process_one_work+0x24e/0x5e0
[87452.338437] worker_thread+0x50/0x3b0
[87452.339137] ? process_one_work+0x5e0/0x5e0
[87452.339884] kthread+0x153/0x170
[87452.340507] ? kthread_mod_delayed_work+0xc0/0xc0
[87452.341153] ret_from_fork+0x22/0x30
[87452.341806] INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
[87452.342487] Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
[87452.343274] "echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
[87452.344049] task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
[87452.344974] Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
[87452.345655] Call Trace:
[87452.346305] __schedule+0x5d1/0xcf0
[87452.346947] ? kvm_clock_read+0x14/0x30
[87452.347676] ? wait_for_completion+0x81/0x110
[87452.348389] schedule+0x45/0xe0
[87452.349077] schedule_timeout+0x30c/0x580
[87452.349718] ? _raw_spin_unlock_irqrestore+0x3c/0x60
[87452.350340] ? lock_acquire+0x1a3/0x490
[87452.351006] ? try_to_wake_up+0x7a/0xa20
[87452.351541] ? lock_release+0x20e/0x4c0
[87452.352040] ? lock_acquired+0x199/0x490
[87452.352517] ? wait_for_completion+0x81/0x110
[87452.353000] wait_for_completion+0xab/0x110
[87452.353490] start_delalloc_inodes+0x2af/0x390 [btrfs]
[87452.353973] btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
[87452.354455] flush_space+0x24f/0x660 [btrfs]
[87452.355063] btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
[87452.355565] process_one_work+0x24e/0x5e0
[87452.356024] worker_thread+0x20f/0x3b0
[87452.356487] ? process_one_work+0x5e0/0x5e0
[87452.356973] kthread+0x153/0x170
[87452.357434] ? kthread_mod_delayed_work+0xc0/0xc0
[87452.357880] ret_from_fork+0x22/0x30
(...)
< stack traces of several tasks waiting for the locks of the inodes of the
clone operation >
(...)
[92867.444138] RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000246 ORIG_RAX: 0000000000000052
[92867.444624] RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73f97
[92867.445116] RDX: 0000000000000000 RSI: 0000560fbd5d7a40 RDI: 0000560fbd5d8960
[92867.445595] RBP: 00007ffc3371beb0 R08: 0000000000000001 R09: 0000000000000003
[92867.446070] R10: 00007ffc3371b996 R11: 0000000000000246 R12: 0000000000000000
[92867.446820] R13: 000000000000001f R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
[92867.447361] task:fsstress state:D stack: 0 pid:2508238 ppid:2508153 flags:0x00004000
[92867.447920] Call Trace:
[92867.448435] __schedule+0x5d1/0xcf0
[92867.448934] ? _raw_spin_unlock_irqrestore+0x3c/0x60
[92867.449423] schedule+0x45/0xe0
[92867.449916] __reserve_bytes+0x4a4/0xb10 [btrfs]
[92867.450576] ? finish_wait+0x90/0x90
[92867.451202] btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
[92867.451815] btrfs_block_rsv_add+0x1f/0x50 [btrfs]
[92867.452412] start_transaction+0x2d1/0x760 [btrfs]
[92867.453216] clone_copy_inline_extent+0x333/0x490 [btrfs]
[92867.453848] ? lock_release+0x20e/0x4c0
[92867.454539] ? btrfs_search_slot+0x9a7/0xc30 [btrfs]
[92867.455218] btrfs_clone+0x569/0x7e0 [btrfs]
[92867.455952] btrfs_clone_files+0xf6/0x150 [btrfs]
[92867.456588] btrfs_remap_file_range+0x324/0x3d0 [btrfs]
[92867.457213] do_clone_file_range+0xd4/0x1f0
[92867.457828] vfs_clone_file_range+0x4d/0x230
[92867.458355] ? lock_release+0x20e/0x4c0
[92867.458890] ioctl_file_clone+0x8f/0xc0
[92867.459377] do_vfs_ioctl+0x342/0x750
[92867.459913] __x64_sys_ioctl+0x62/0xb0
[92867.460377] do_syscall_64+0x33/0x80
[92867.460842] entry_SYSCALL_64_after_hwframe+0x44/0xa9
(...)
< stack traces of more tasks blocked on metadata reservation like the clone
task above, because the async reclaim task has deadlocked >
(...)
Another thing to notice is that the worker task that is deadlocked when
trying to flush the destination inode of the clone operation is at
btrfs_invalidatepage(). This is simply because the clone operation has a
destination offset greater than the i_size and we only update the i_size
of the destination file after cloning an extent (just like we do in the
buffered write path).
Since the async reclaim path uses btrfs_start_delalloc_roots() to trigger
the flushing of delalloc for all inodes that have delalloc, add a runtime
flag to an inode to signal it should not be flushed, and for inodes with
that flag set, start_delalloc_inodes() will simply skip them. When the
cloning code needs to dirty a page to copy an inline extent, set that flag
on the inode and then clear it when the clone operation finishes.
This could be sporadically triggered with test case generic/269 from
fstests, which exercises many fsstress processes running in parallel with
several dd processes filling up the entire filesystem.
CC: stable@vger.kernel.org # 5.9+
Fixes: 05a5a7621ce6 ("Btrfs: implement full reflink support for inline extents")
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Reviewed-by: David Sterba <dsterba@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-12-02 11:55:58 +00:00
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/*
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* After dirtying the page our caller will need to start a transaction,
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* and if we are low on metadata free space, that can cause flushing of
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* delalloc for all inodes in order to get metadata space released.
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* However we are holding the range locked for the whole duration of
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* the clone/dedupe operation, so we may deadlock if that happens and no
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* other task releases enough space. So mark this inode as not being
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* possible to flush to avoid such deadlock. We will clear that flag
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* when we finish cloning all extents, since a transaction is started
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* after finding each extent to clone.
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*/
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set_bit(BTRFS_INODE_NO_DELALLOC_FLUSH, &inode->runtime_flags);
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2020-02-28 13:04:19 +00:00
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if (comp_type == BTRFS_COMPRESS_NONE) {
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2021-05-31 08:50:53 +00:00
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memcpy_to_page(page, offset_in_page(file_offset), data_start,
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datal);
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2020-02-28 13:04:19 +00:00
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} else {
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2021-05-31 08:50:53 +00:00
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ret = btrfs_decompress(comp_type, data_start, page,
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offset_in_page(file_offset),
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2020-02-28 13:04:19 +00:00
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inline_size, datal);
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if (ret)
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goto out_unlock;
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flush_dcache_page(page);
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}
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/*
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* If our inline data is smaller then the block/page size, then the
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* remaining of the block/page is equivalent to zeroes. We had something
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* like the following done:
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*
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* $ xfs_io -f -c "pwrite -S 0xab 0 500" file
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* $ sync # (or fsync)
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* $ xfs_io -c "falloc 0 4K" file
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* $ xfs_io -c "pwrite -S 0xcd 4K 4K"
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*
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* So what's in the range [500, 4095] corresponds to zeroes.
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*/
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2022-06-01 11:47:54 +00:00
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if (datal < block_size)
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btrfs: use memzero_page() instead of open coded kmap pattern
There are many places where kmap/memset/kunmap patterns occur.
Use the newly lifted memzero_page() to eliminate direct uses of kmap and
leverage the new core functions use of kmap_local_page().
The development of this patch was aided by the following coccinelle
script:
// <smpl>
// SPDX-License-Identifier: GPL-2.0-only
// Find kmap/memset/kunmap pattern and replace with memset*page calls
//
// NOTE: Offsets and other expressions may be more complex than what the script
// will automatically generate. Therefore a catchall rule is provided to find
// the pattern which then must be evaluated by hand.
//
// Confidence: Low
// Copyright: (C) 2021 Intel Corporation
// URL: http://coccinelle.lip6.fr/
// Comments:
// Options:
//
// Then the memset pattern
//
@ memset_rule1 @
expression page, V, L, Off;
identifier ptr;
type VP;
@@
(
-VP ptr = kmap(page);
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-ptr = kmap(page);
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-VP ptr = kmap_atomic(page);
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-ptr = kmap_atomic(page);
)
<+...
(
-memset(ptr, 0, L);
+memzero_page(page, 0, L);
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-memset(ptr + Off, 0, L);
+memzero_page(page, Off, L);
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-memset(ptr, V, L);
+memset_page(page, V, 0, L);
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-memset(ptr + Off, V, L);
+memset_page(page, V, Off, L);
)
...+>
(
-kunmap(page);
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-kunmap_atomic(ptr);
)
// Remove any pointers left unused
@
depends on memset_rule1
@
identifier memset_rule1.ptr;
type VP, VP1;
@@
-VP ptr;
... when != ptr;
? VP1 ptr;
//
// Catch all
//
@ memset_rule2 @
expression page;
identifier ptr;
expression GenTo, GenSize, GenValue;
type VP;
@@
(
-VP ptr = kmap(page);
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-ptr = kmap(page);
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-VP ptr = kmap_atomic(page);
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-ptr = kmap_atomic(page);
)
<+...
(
//
// Some call sites have complex expressions within the memset/memcpy
// The follow are catch alls which need to be evaluated by hand.
//
-memset(GenTo, 0, GenSize);
+memzero_pageExtra(page, GenTo, GenSize);
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-memset(GenTo, GenValue, GenSize);
+memset_pageExtra(page, GenValue, GenTo, GenSize);
)
...+>
(
-kunmap(page);
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-kunmap_atomic(ptr);
)
// Remove any pointers left unused
@
depends on memset_rule2
@
identifier memset_rule2.ptr;
type VP, VP1;
@@
-VP ptr;
... when != ptr;
? VP1 ptr;
// </smpl>
Link: https://lkml.kernel.org/r/20210309212137.2610186-4-ira.weiny@intel.com
Signed-off-by: Ira Weiny <ira.weiny@intel.com>
Reviewed-by: David Sterba <dsterba@suse.com>
Cc: Alexander Viro <viro@zeniv.linux.org.uk>
Cc: Chaitanya Kulkarni <chaitanya.kulkarni@wdc.com>
Cc: Chris Mason <clm@fb.com>
Cc: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2021-05-05 01:40:07 +00:00
|
|
|
memzero_page(page, datal, block_size - datal);
|
2020-02-28 13:04:19 +00:00
|
|
|
|
2023-12-12 02:28:37 +00:00
|
|
|
btrfs_folio_set_uptodate(fs_info, page_folio(page), file_offset, block_size);
|
|
|
|
btrfs_folio_clear_checked(fs_info, page_folio(page), file_offset, block_size);
|
|
|
|
btrfs_folio_set_dirty(fs_info, page_folio(page), file_offset, block_size);
|
2020-02-28 13:04:19 +00:00
|
|
|
out_unlock:
|
|
|
|
if (page) {
|
|
|
|
unlock_page(page);
|
|
|
|
put_page(page);
|
|
|
|
}
|
|
|
|
if (ret)
|
2020-08-31 11:42:47 +00:00
|
|
|
btrfs_delalloc_release_space(inode, data_reserved, file_offset,
|
|
|
|
block_size, true);
|
|
|
|
btrfs_delalloc_release_extents(inode, block_size);
|
2020-02-28 13:04:19 +00:00
|
|
|
out:
|
|
|
|
extent_changeset_free(data_reserved);
|
|
|
|
|
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
/*
|
2020-02-28 13:04:19 +00:00
|
|
|
* Deal with cloning of inline extents. We try to copy the inline extent from
|
|
|
|
* the source inode to destination inode when possible. When not possible we
|
|
|
|
* copy the inline extent's data into the respective page of the inode.
|
2020-02-28 13:04:17 +00:00
|
|
|
*/
|
|
|
|
static int clone_copy_inline_extent(struct inode *dst,
|
|
|
|
struct btrfs_path *path,
|
|
|
|
struct btrfs_key *new_key,
|
|
|
|
const u64 drop_start,
|
|
|
|
const u64 datal,
|
|
|
|
const u64 size,
|
2020-02-28 13:04:19 +00:00
|
|
|
const u8 comp_type,
|
|
|
|
char *inline_data,
|
|
|
|
struct btrfs_trans_handle **trans_out)
|
2020-02-28 13:04:17 +00:00
|
|
|
{
|
2023-09-14 14:45:41 +00:00
|
|
|
struct btrfs_fs_info *fs_info = inode_to_fs_info(dst);
|
2020-02-28 13:04:17 +00:00
|
|
|
struct btrfs_root *root = BTRFS_I(dst)->root;
|
|
|
|
const u64 aligned_end = ALIGN(new_key->offset + datal,
|
|
|
|
fs_info->sectorsize);
|
2020-02-28 13:04:19 +00:00
|
|
|
struct btrfs_trans_handle *trans = NULL;
|
2020-11-04 11:07:32 +00:00
|
|
|
struct btrfs_drop_extents_args drop_args = { 0 };
|
2020-02-28 13:04:17 +00:00
|
|
|
int ret;
|
|
|
|
struct btrfs_key key;
|
|
|
|
|
2020-02-28 13:04:19 +00:00
|
|
|
if (new_key->offset > 0) {
|
2020-08-31 11:42:47 +00:00
|
|
|
ret = copy_inline_to_page(BTRFS_I(dst), new_key->offset,
|
|
|
|
inline_data, size, datal, comp_type);
|
2020-02-28 13:04:19 +00:00
|
|
|
goto out;
|
|
|
|
}
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
key.objectid = btrfs_ino(BTRFS_I(dst));
|
|
|
|
key.type = BTRFS_EXTENT_DATA_KEY;
|
|
|
|
key.offset = 0;
|
|
|
|
ret = btrfs_search_slot(NULL, root, &key, path, 0, 0);
|
|
|
|
if (ret < 0) {
|
|
|
|
return ret;
|
|
|
|
} else if (ret > 0) {
|
|
|
|
if (path->slots[0] >= btrfs_header_nritems(path->nodes[0])) {
|
|
|
|
ret = btrfs_next_leaf(root, path);
|
|
|
|
if (ret < 0)
|
|
|
|
return ret;
|
|
|
|
else if (ret > 0)
|
|
|
|
goto copy_inline_extent;
|
|
|
|
}
|
|
|
|
btrfs_item_key_to_cpu(path->nodes[0], &key, path->slots[0]);
|
|
|
|
if (key.objectid == btrfs_ino(BTRFS_I(dst)) &&
|
|
|
|
key.type == BTRFS_EXTENT_DATA_KEY) {
|
2020-02-28 13:04:19 +00:00
|
|
|
/*
|
|
|
|
* There's an implicit hole at file offset 0, copy the
|
|
|
|
* inline extent's data to the page.
|
|
|
|
*/
|
2020-02-28 13:04:17 +00:00
|
|
|
ASSERT(key.offset > 0);
|
2021-05-25 10:05:28 +00:00
|
|
|
goto copy_to_page;
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
} else if (i_size_read(dst) <= datal) {
|
|
|
|
struct btrfs_file_extent_item *ei;
|
|
|
|
|
|
|
|
ei = btrfs_item_ptr(path->nodes[0], path->slots[0],
|
|
|
|
struct btrfs_file_extent_item);
|
|
|
|
/*
|
2020-02-28 13:04:19 +00:00
|
|
|
* If it's an inline extent replace it with the source inline
|
|
|
|
* extent, otherwise copy the source inline extent data into
|
|
|
|
* the respective page at the destination inode.
|
2020-02-28 13:04:17 +00:00
|
|
|
*/
|
|
|
|
if (btrfs_file_extent_type(path->nodes[0], ei) ==
|
|
|
|
BTRFS_FILE_EXTENT_INLINE)
|
|
|
|
goto copy_inline_extent;
|
|
|
|
|
2021-05-25 10:05:28 +00:00
|
|
|
goto copy_to_page;
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
|
|
|
copy_inline_extent:
|
|
|
|
/*
|
|
|
|
* We have no extent items, or we have an extent at offset 0 which may
|
|
|
|
* or may not be inlined. All these cases are dealt the same way.
|
|
|
|
*/
|
|
|
|
if (i_size_read(dst) > datal) {
|
|
|
|
/*
|
2020-02-28 13:04:19 +00:00
|
|
|
* At the destination offset 0 we have either a hole, a regular
|
|
|
|
* extent or an inline extent larger then the one we want to
|
|
|
|
* clone. Deal with all these cases by copying the inline extent
|
|
|
|
* data into the respective page at the destination inode.
|
2020-02-28 13:04:17 +00:00
|
|
|
*/
|
2021-05-25 10:05:28 +00:00
|
|
|
goto copy_to_page;
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
2021-05-25 10:05:28 +00:00
|
|
|
/*
|
|
|
|
* Release path before starting a new transaction so we don't hold locks
|
|
|
|
* that would confuse lockdep.
|
|
|
|
*/
|
2020-02-28 13:04:17 +00:00
|
|
|
btrfs_release_path(path);
|
2020-02-28 13:04:19 +00:00
|
|
|
/*
|
|
|
|
* If we end up here it means were copy the inline extent into a leaf
|
|
|
|
* of the destination inode. We know we will drop or adjust at most one
|
|
|
|
* extent item in the destination root.
|
|
|
|
*
|
|
|
|
* 1 unit - adjusting old extent (we may have to split it)
|
|
|
|
* 1 unit - add new extent
|
|
|
|
* 1 unit - inode update
|
|
|
|
*/
|
|
|
|
trans = btrfs_start_transaction(root, 3);
|
|
|
|
if (IS_ERR(trans)) {
|
|
|
|
ret = PTR_ERR(trans);
|
|
|
|
trans = NULL;
|
|
|
|
goto out;
|
|
|
|
}
|
2020-11-04 11:07:32 +00:00
|
|
|
drop_args.path = path;
|
|
|
|
drop_args.start = drop_start;
|
|
|
|
drop_args.end = aligned_end;
|
|
|
|
drop_args.drop_cache = true;
|
|
|
|
ret = btrfs_drop_extents(trans, root, BTRFS_I(dst), &drop_args);
|
2020-02-28 13:04:17 +00:00
|
|
|
if (ret)
|
2020-02-28 13:04:19 +00:00
|
|
|
goto out;
|
2020-02-28 13:04:17 +00:00
|
|
|
ret = btrfs_insert_empty_item(trans, root, path, new_key, size);
|
|
|
|
if (ret)
|
2020-02-28 13:04:19 +00:00
|
|
|
goto out;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
write_extent_buffer(path->nodes[0], inline_data,
|
|
|
|
btrfs_item_ptr_offset(path->nodes[0],
|
|
|
|
path->slots[0]),
|
|
|
|
size);
|
btrfs: update the number of bytes used by an inode atomically
There are several occasions where we do not update the inode's number of
used bytes atomically, resulting in a concurrent stat(2) syscall to report
a value of used blocks that does not correspond to a valid value, that is,
a value that does not match neither what we had before the operation nor
what we get after the operation completes.
In extreme cases it can result in stat(2) reporting zero used blocks, which
can cause problems for some userspace tools where they can consider a file
with a non-zero size and zero used blocks as completely sparse and skip
reading data, as reported/discussed a long time ago in some threads like
the following:
https://lists.gnu.org/archive/html/bug-tar/2016-07/msg00001.html
The cases where this can happen are the following:
-> Case 1
If we do a write (buffered or direct IO) against a file region for which
there is already an allocated extent (or multiple extents), then we have a
short time window where we can report a number of used blocks to stat(2)
that does not take into account the file region being overwritten. This
short time window happens when completing the ordered extent(s).
This happens because when we drop the extents in the write range we
decrement the inode's number of bytes and later on when we insert the new
extent(s) we increment the number of bytes in the inode, resulting in a
short time window where a stat(2) syscall can get an incorrect number of
used blocks.
If we do writes that overwrite an entire file, then we have a short time
window where we report 0 used blocks to stat(2).
Example reproducer:
$ cat reproducer-1.sh
#!/bin/bash
MNT=/mnt/sdi
DEV=/dev/sdi
stat_loop()
{
trap "wait; exit" SIGTERM
local filepath=$1
local expected=$2
local got
while :; do
got=$(stat -c %b $filepath)
if [ $got -ne $expected ]; then
echo -n "ERROR: unexpected used blocks"
echo " (got: $got expected: $expected)"
fi
done
}
mkfs.btrfs -f $DEV > /dev/null
# mkfs.xfs -f $DEV > /dev/null
# mkfs.ext4 -F $DEV > /dev/null
# mkfs.f2fs -f $DEV > /dev/null
# mkfs.reiserfs -f $DEV > /dev/null
mount $DEV $MNT
xfs_io -f -s -c "pwrite -b 64K 0 64K" $MNT/foobar >/dev/null
expected=$(stat -c %b $MNT/foobar)
# Create a process to keep calling stat(2) on the file and see if the
# reported number of blocks used (disk space used) changes, it should
# not because we are not increasing the file size nor punching holes.
stat_loop $MNT/foobar $expected &
loop_pid=$!
for ((i = 0; i < 50000; i++)); do
xfs_io -s -c "pwrite -b 64K 0 64K" $MNT/foobar >/dev/null
done
kill $loop_pid &> /dev/null
wait
umount $DEV
$ ./reproducer-1.sh
ERROR: unexpected used blocks (got: 0 expected: 128)
ERROR: unexpected used blocks (got: 0 expected: 128)
(...)
Note that since this is a short time window where the race can happen, the
reproducer may not be able to always trigger the bug in one run, or it may
trigger it multiple times.
-> Case 2
If we do a buffered write against a file region that does not have any
allocated extents, like a hole or beyond EOF, then during ordered extent
completion we have a short time window where a concurrent stat(2) syscall
can report a number of used blocks that does not correspond to the value
before or after the write operation, a value that is actually larger than
the value after the write completes.
This happens because once we start a buffered write into an unallocated
file range we increment the inode's 'new_delalloc_bytes', to make sure
any stat(2) call gets a correct used blocks value before delalloc is
flushed and completes. However at ordered extent completion, after we
inserted the new extent, we increment the inode's number of bytes used
with the size of the new extent, and only later, when clearing the range
in the inode's iotree, we decrement the inode's 'new_delalloc_bytes'
counter with the size of the extent. So this results in a short time
window where a concurrent stat(2) syscall can report a number of used
blocks that accounts for the new extent twice.
Example reproducer:
$ cat reproducer-2.sh
#!/bin/bash
MNT=/mnt/sdi
DEV=/dev/sdi
stat_loop()
{
trap "wait; exit" SIGTERM
local filepath=$1
local expected=$2
local got
while :; do
got=$(stat -c %b $filepath)
if [ $got -ne $expected ]; then
echo -n "ERROR: unexpected used blocks"
echo " (got: $got expected: $expected)"
fi
done
}
mkfs.btrfs -f $DEV > /dev/null
# mkfs.xfs -f $DEV > /dev/null
# mkfs.ext4 -F $DEV > /dev/null
# mkfs.f2fs -f $DEV > /dev/null
# mkfs.reiserfs -f $DEV > /dev/null
mount $DEV $MNT
touch $MNT/foobar
write_size=$((64 * 1024))
for ((i = 0; i < 16384; i++)); do
offset=$(($i * $write_size))
xfs_io -c "pwrite -S 0xab $offset $write_size" $MNT/foobar >/dev/null
blocks_used=$(stat -c %b $MNT/foobar)
# Fsync the file to trigger writeback and keep calling stat(2) on it
# to see if the number of blocks used changes.
stat_loop $MNT/foobar $blocks_used &
loop_pid=$!
xfs_io -c "fsync" $MNT/foobar
kill $loop_pid &> /dev/null
wait $loop_pid
done
umount $DEV
$ ./reproducer-2.sh
ERROR: unexpected used blocks (got: 265472 expected: 265344)
ERROR: unexpected used blocks (got: 284032 expected: 283904)
(...)
Note that since this is a short time window where the race can happen, the
reproducer may not be able to always trigger the bug in one run, or it may
trigger it multiple times.
-> Case 3
Another case where such problems happen is during other operations that
replace extents in a file range with other extents. Those operations are
extent cloning, deduplication and fallocate's zero range operation.
The cause of the problem is similar to the first case. When we drop the
extents from a range, we decrement the inode's number of bytes, and later
on, after inserting the new extents we increment it. Since this is not
done atomically, a concurrent stat(2) call can see and return a number of
used blocks that is smaller than it should be, does not match the number
of used blocks before or after the clone/deduplication/zero operation.
Like for the first case, when doing a clone, deduplication or zero range
operation against an entire file, we end up having a time window where we
can report 0 used blocks to a stat(2) call.
Example reproducer:
$ cat reproducer-3.sh
#!/bin/bash
MNT=/mnt/sdi
DEV=/dev/sdi
mkfs.btrfs -f $DEV > /dev/null
# mkfs.xfs -f -m reflink=1 $DEV > /dev/null
mount $DEV $MNT
extent_size=$((64 * 1024))
num_extents=16384
file_size=$(($extent_size * $num_extents))
# File foo has many small extents.
xfs_io -f -s -c "pwrite -S 0xab -b $extent_size 0 $file_size" $MNT/foo \
> /dev/null
# File bar has much less extents and has exactly the same data as foo.
xfs_io -f -c "pwrite -S 0xab 0 $file_size" $MNT/bar > /dev/null
expected=$(stat -c %b $MNT/foo)
# Now deduplicate bar into foo. While the deduplication is in progres,
# the number of used blocks/file size reported by stat should not change
xfs_io -c "dedupe $MNT/bar 0 0 $file_size" $MNT/foo > /dev/null &
dedupe_pid=$!
while [ -n "$(ps -p $dedupe_pid -o pid=)" ]; do
used=$(stat -c %b $MNT/foo)
if [ $used -ne $expected ]; then
echo "Unexpected blocks used: $used (expected: $expected)"
fi
done
umount $DEV
$ ./reproducer-3.sh
Unexpected blocks used: 2076800 (expected: 2097152)
Unexpected blocks used: 2097024 (expected: 2097152)
Unexpected blocks used: 2079872 (expected: 2097152)
(...)
Note that since this is a short time window where the race can happen, the
reproducer may not be able to always trigger the bug in one run, or it may
trigger it multiple times.
So fix this by:
1) Making btrfs_drop_extents() not decrement the VFS inode's number of
bytes, and instead return the number of bytes;
2) Making any code that drops extents and adds new extents update the
inode's number of bytes atomically, while holding the btrfs inode's
spinlock, which is also used by the stat(2) callback to get the inode's
number of bytes;
3) For ranges in the inode's iotree that are marked as 'delalloc new',
corresponding to previously unallocated ranges, increment the inode's
number of bytes when clearing the 'delalloc new' bit from the range,
in the same critical section that decrements the inode's
'new_delalloc_bytes' counter, delimited by the btrfs inode's spinlock.
An alternative would be to have btrfs_getattr() wait for any IO (ordered
extents in progress) and locking the whole range (0 to (u64)-1) while it
it computes the number of blocks used. But that would mean blocking
stat(2), which is a very used syscall and expected to be fast, waiting
for writes, clone/dedupe, fallocate, page reads, fiemap, etc.
CC: stable@vger.kernel.org # 5.4+
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Reviewed-by: David Sterba <dsterba@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-11-04 11:07:34 +00:00
|
|
|
btrfs_update_inode_bytes(BTRFS_I(dst), datal, drop_args.bytes_found);
|
btrfs: reset last_reflink_trans after fsyncing inode
When an inode has a last_reflink_trans matching the current transaction,
we have to take special care when logging its checksums in order to
avoid getting checksum items with overlapping ranges in a log tree,
which could result in missing checksums after log replay (more on that
in the changelogs of commit 40e046acbd2f36 ("Btrfs: fix missing data
checksums after replaying a log tree") and commit e289f03ea79bbc ("btrfs:
fix corrupt log due to concurrent fsync of inodes with shared extents")).
We also need to make sure a full fsync will copy all old file extent
items it finds in modified leaves, because they might have been copied
from some other inode.
However once we fsync an inode, we don't need to keep paying the price of
that extra special care in future fsyncs done in the same transaction,
unless the inode is used for another reflink operation or the full sync
flag is set on it (truncate, failure to allocate extent maps for holes,
and other exceptional and infrequent cases).
So after we fsync an inode reset its last_unlink_trans to zero. In case
another reflink happens, we continue to update the last_reflink_trans of
the inode, just as before. Also set last_reflink_trans to the generation
of the last transaction that modified the inode whenever we need to set
the full sync flag on the inode, just like when we need to load an inode
from disk after eviction.
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-02-17 12:12:06 +00:00
|
|
|
btrfs_set_inode_full_sync(BTRFS_I(dst));
|
2020-04-04 20:20:22 +00:00
|
|
|
ret = btrfs_inode_set_file_extent_range(BTRFS_I(dst), 0, aligned_end);
|
2020-02-28 13:04:19 +00:00
|
|
|
out:
|
|
|
|
if (!ret && !trans) {
|
|
|
|
/*
|
|
|
|
* No transaction here means we copied the inline extent into a
|
|
|
|
* page of the destination inode.
|
|
|
|
*
|
|
|
|
* 1 unit to update inode item
|
|
|
|
*/
|
|
|
|
trans = btrfs_start_transaction(root, 1);
|
|
|
|
if (IS_ERR(trans)) {
|
|
|
|
ret = PTR_ERR(trans);
|
|
|
|
trans = NULL;
|
|
|
|
}
|
|
|
|
}
|
|
|
|
if (ret && trans) {
|
|
|
|
btrfs_abort_transaction(trans, ret);
|
|
|
|
btrfs_end_transaction(trans);
|
|
|
|
}
|
|
|
|
if (!ret)
|
|
|
|
*trans_out = trans;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
2020-02-28 13:04:19 +00:00
|
|
|
return ret;
|
2021-05-25 10:05:28 +00:00
|
|
|
|
|
|
|
copy_to_page:
|
|
|
|
/*
|
|
|
|
* Release our path because we don't need it anymore and also because
|
|
|
|
* copy_inline_to_page() needs to reserve data and metadata, which may
|
|
|
|
* need to flush delalloc when we are low on available space and
|
|
|
|
* therefore cause a deadlock if writeback of an inline extent needs to
|
|
|
|
* write to the same leaf or an ordered extent completion needs to write
|
|
|
|
* to the same leaf.
|
|
|
|
*/
|
|
|
|
btrfs_release_path(path);
|
|
|
|
|
|
|
|
ret = copy_inline_to_page(BTRFS_I(dst), new_key->offset,
|
|
|
|
inline_data, size, datal, comp_type);
|
|
|
|
goto out;
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
2022-10-27 12:21:42 +00:00
|
|
|
/*
|
|
|
|
* Clone a range from inode file to another.
|
2020-02-28 13:04:17 +00:00
|
|
|
*
|
2022-10-27 12:21:42 +00:00
|
|
|
* @src: Inode to clone from
|
|
|
|
* @inode: Inode to clone to
|
|
|
|
* @off: Offset within source to start clone from
|
|
|
|
* @olen: Original length, passed by user, of range to clone
|
|
|
|
* @olen_aligned: Block-aligned value of olen
|
|
|
|
* @destoff: Offset within @inode to start clone
|
|
|
|
* @no_time_update: Whether to update mtime/ctime on the target inode
|
2020-02-28 13:04:17 +00:00
|
|
|
*/
|
|
|
|
static int btrfs_clone(struct inode *src, struct inode *inode,
|
|
|
|
const u64 off, const u64 olen, const u64 olen_aligned,
|
|
|
|
const u64 destoff, int no_time_update)
|
|
|
|
{
|
2023-09-14 14:45:41 +00:00
|
|
|
struct btrfs_fs_info *fs_info = inode_to_fs_info(inode);
|
2020-02-28 13:04:17 +00:00
|
|
|
struct btrfs_path *path = NULL;
|
|
|
|
struct extent_buffer *leaf;
|
|
|
|
struct btrfs_trans_handle *trans;
|
|
|
|
char *buf = NULL;
|
|
|
|
struct btrfs_key key;
|
|
|
|
u32 nritems;
|
|
|
|
int slot;
|
|
|
|
int ret;
|
|
|
|
const u64 len = olen_aligned;
|
|
|
|
u64 last_dest_end = destoff;
|
btrfs: fix race between reflinking and ordered extent completion
While doing a reflink operation, if an ordered extent for a file range
that does not overlap with the source and destination ranges of the
reflink operation happens, we can end up having a failure in the reflink
operation and return -EINVAL to user space.
The following sequence of steps explains how this can happen:
1) We have the page at file offset 315392 dirty (under delalloc);
2) A reflink operation for this file starts, using the same file as both
source and destination, the source range is [372736, 409600) (length of
36864 bytes) and the destination range is [208896, 245760);
3) At btrfs_remap_file_range_prep(), we flush all delalloc in the source
and destination ranges, and wait for any ordered extents in those range
to complete;
4) Still at btrfs_remap_file_range_prep(), we then flush all delalloc in
the inode, but we neither wait for it to complete nor any ordered
extents to complete. This results in starting delalloc for the page at
file offset 315392 and creating an ordered extent for that single page
range;
5) We then move to btrfs_clone() and enter the loop to find file extent
items to copy from the source range to destination range;
6) In the first iteration we end up at last file extent item stored in
leaf A:
(...)
item 131 key (143616 108 315392) itemoff 5101 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 12288 nr 61440 ram 73728
This represents the file range [315392, 376832), which overlaps with
the source range to clone.
@datal is set to 61440, key.offset is 315392 and @next_key_min_offset
is therefore set to 376832 (315392 + 61440).
@off (372736) is > key.offset (315392), so @new_key.offset is set to
the value of @destoff (208896).
@new_key.offset == @last_dest_end (208896) so @drop_start is set to
208896 (@new_key.offset).
@datal is adjusted to 4096, as @off is > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the range
[208896, 212991] (a single page, which is
[@drop_start, @new_key.offset + @datal - 1]).
@last_dest_end is set to 212992 (@new_key.offset + @datal =
208896 + 4096 = 212992).
Before the next iteration of the loop, @key.offset is set to the value
376832, which is @next_key_min_offset;
7) On the second iteration btrfs_search_slot() leaves us again at leaf A,
but this time pointing beyond the last slot of leaf A, as that's where
a key with offset 376832 should be at if it existed. So end up calling
btrfs_next_leaf();
8) btrfs_next_leaf() releases the path, but before it searches again the
tree for the next key/leaf, the ordered extent for the single page
range at file offset 315392 completes. That results in trimming the
file extent item we processed before, adjusting its key offset from
315392 to 319488, reducing its length from 61440 to 57344 and inserting
a new file extent item for that single page range, with a key offset of
315392 and a length of 4096.
Leaf A now looks like:
(...)
item 132 key (143616 108 315392) itemoff 4995 itemsize 53
extent data disk bytenr 1801666560 nr 4096
extent data offset 0 nr 4096 ram 4096
item 133 key (143616 108 319488) itemoff 4942 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 16384 nr 57344 ram 73728
9) When btrfs_next_leaf() returns, it gives us a path pointing to leaf A
at slot 133, since it's the first key that follows what was the last
key we saw (143616 108 315392). In fact it's the same item we processed
before, but its key offset was changed, so it counts as a new key;
10) So now we have:
@key.offset == 319488
@datal == 57344
@off (372736) is > key.offset (319488), so @new_key.offset is set to
208896 (@destoff value).
@new_key.offset (208896) != @last_dest_end (212992), so @drop_start
is set to 212992 (@last_dest_end value).
@datal is adjusted to 4096 because @off > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the
invalid range of [212992, 212991] (which is
[@drop_start, @new_key.offset + @datal - 1]).
This range is empty, the end offset is smaller than the start offset
so btrfs_replace_file_extents() returns -EINVAL, which we end up
returning to user space and fail the reflink operation.
This all happens because the range of this file extent item was
already processed in the previous iteration.
This scenario can be triggered very sporadically by fsx from fstests, for
example with test case generic/522.
So fix this by having btrfs_clone() skip file extent items that cover a
file range that we have already processed.
CC: stable@vger.kernel.org # 5.10+
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:17 +00:00
|
|
|
u64 prev_extent_end = off;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
ret = -ENOMEM;
|
|
|
|
buf = kvmalloc(fs_info->nodesize, GFP_KERNEL);
|
|
|
|
if (!buf)
|
|
|
|
return ret;
|
|
|
|
|
|
|
|
path = btrfs_alloc_path();
|
|
|
|
if (!path) {
|
|
|
|
kvfree(buf);
|
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
path->reada = READA_FORWARD;
|
|
|
|
/* Clone data */
|
|
|
|
key.objectid = btrfs_ino(BTRFS_I(src));
|
|
|
|
key.type = BTRFS_EXTENT_DATA_KEY;
|
|
|
|
key.offset = off;
|
|
|
|
|
|
|
|
while (1) {
|
|
|
|
struct btrfs_file_extent_item *extent;
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
u64 extent_gen;
|
2020-02-28 13:04:17 +00:00
|
|
|
int type;
|
|
|
|
u32 size;
|
|
|
|
struct btrfs_key new_key;
|
|
|
|
u64 disko = 0, diskl = 0;
|
|
|
|
u64 datao = 0, datal = 0;
|
2020-02-28 13:04:19 +00:00
|
|
|
u8 comp;
|
2020-02-28 13:04:17 +00:00
|
|
|
u64 drop_start;
|
|
|
|
|
|
|
|
/* Note the key will change type as we walk through the tree */
|
|
|
|
ret = btrfs_search_slot(NULL, BTRFS_I(src)->root, &key, path,
|
|
|
|
0, 0);
|
|
|
|
if (ret < 0)
|
|
|
|
goto out;
|
|
|
|
/*
|
|
|
|
* First search, if no extent item that starts at offset off was
|
|
|
|
* found but the previous item is an extent item, it's possible
|
|
|
|
* it might overlap our target range, therefore process it.
|
|
|
|
*/
|
|
|
|
if (key.offset == off && ret > 0 && path->slots[0] > 0) {
|
|
|
|
btrfs_item_key_to_cpu(path->nodes[0], &key,
|
|
|
|
path->slots[0] - 1);
|
|
|
|
if (key.type == BTRFS_EXTENT_DATA_KEY)
|
|
|
|
path->slots[0]--;
|
|
|
|
}
|
|
|
|
|
|
|
|
nritems = btrfs_header_nritems(path->nodes[0]);
|
|
|
|
process_slot:
|
|
|
|
if (path->slots[0] >= nritems) {
|
|
|
|
ret = btrfs_next_leaf(BTRFS_I(src)->root, path);
|
|
|
|
if (ret < 0)
|
|
|
|
goto out;
|
|
|
|
if (ret > 0)
|
|
|
|
break;
|
|
|
|
nritems = btrfs_header_nritems(path->nodes[0]);
|
|
|
|
}
|
|
|
|
leaf = path->nodes[0];
|
|
|
|
slot = path->slots[0];
|
|
|
|
|
|
|
|
btrfs_item_key_to_cpu(leaf, &key, slot);
|
|
|
|
if (key.type > BTRFS_EXTENT_DATA_KEY ||
|
|
|
|
key.objectid != btrfs_ino(BTRFS_I(src)))
|
|
|
|
break;
|
|
|
|
|
|
|
|
ASSERT(key.type == BTRFS_EXTENT_DATA_KEY);
|
|
|
|
|
|
|
|
extent = btrfs_item_ptr(leaf, slot,
|
|
|
|
struct btrfs_file_extent_item);
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
extent_gen = btrfs_file_extent_generation(leaf, extent);
|
2020-02-28 13:04:19 +00:00
|
|
|
comp = btrfs_file_extent_compression(leaf, extent);
|
2020-02-28 13:04:17 +00:00
|
|
|
type = btrfs_file_extent_type(leaf, extent);
|
|
|
|
if (type == BTRFS_FILE_EXTENT_REG ||
|
|
|
|
type == BTRFS_FILE_EXTENT_PREALLOC) {
|
|
|
|
disko = btrfs_file_extent_disk_bytenr(leaf, extent);
|
|
|
|
diskl = btrfs_file_extent_disk_num_bytes(leaf, extent);
|
|
|
|
datao = btrfs_file_extent_offset(leaf, extent);
|
|
|
|
datal = btrfs_file_extent_num_bytes(leaf, extent);
|
|
|
|
} else if (type == BTRFS_FILE_EXTENT_INLINE) {
|
|
|
|
/* Take upper bound, may be compressed */
|
|
|
|
datal = btrfs_file_extent_ram_bytes(leaf, extent);
|
|
|
|
}
|
|
|
|
|
|
|
|
/*
|
|
|
|
* The first search might have left us at an extent item that
|
|
|
|
* ends before our target range's start, can happen if we have
|
|
|
|
* holes and NO_HOLES feature enabled.
|
btrfs: fix race between reflinking and ordered extent completion
While doing a reflink operation, if an ordered extent for a file range
that does not overlap with the source and destination ranges of the
reflink operation happens, we can end up having a failure in the reflink
operation and return -EINVAL to user space.
The following sequence of steps explains how this can happen:
1) We have the page at file offset 315392 dirty (under delalloc);
2) A reflink operation for this file starts, using the same file as both
source and destination, the source range is [372736, 409600) (length of
36864 bytes) and the destination range is [208896, 245760);
3) At btrfs_remap_file_range_prep(), we flush all delalloc in the source
and destination ranges, and wait for any ordered extents in those range
to complete;
4) Still at btrfs_remap_file_range_prep(), we then flush all delalloc in
the inode, but we neither wait for it to complete nor any ordered
extents to complete. This results in starting delalloc for the page at
file offset 315392 and creating an ordered extent for that single page
range;
5) We then move to btrfs_clone() and enter the loop to find file extent
items to copy from the source range to destination range;
6) In the first iteration we end up at last file extent item stored in
leaf A:
(...)
item 131 key (143616 108 315392) itemoff 5101 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 12288 nr 61440 ram 73728
This represents the file range [315392, 376832), which overlaps with
the source range to clone.
@datal is set to 61440, key.offset is 315392 and @next_key_min_offset
is therefore set to 376832 (315392 + 61440).
@off (372736) is > key.offset (315392), so @new_key.offset is set to
the value of @destoff (208896).
@new_key.offset == @last_dest_end (208896) so @drop_start is set to
208896 (@new_key.offset).
@datal is adjusted to 4096, as @off is > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the range
[208896, 212991] (a single page, which is
[@drop_start, @new_key.offset + @datal - 1]).
@last_dest_end is set to 212992 (@new_key.offset + @datal =
208896 + 4096 = 212992).
Before the next iteration of the loop, @key.offset is set to the value
376832, which is @next_key_min_offset;
7) On the second iteration btrfs_search_slot() leaves us again at leaf A,
but this time pointing beyond the last slot of leaf A, as that's where
a key with offset 376832 should be at if it existed. So end up calling
btrfs_next_leaf();
8) btrfs_next_leaf() releases the path, but before it searches again the
tree for the next key/leaf, the ordered extent for the single page
range at file offset 315392 completes. That results in trimming the
file extent item we processed before, adjusting its key offset from
315392 to 319488, reducing its length from 61440 to 57344 and inserting
a new file extent item for that single page range, with a key offset of
315392 and a length of 4096.
Leaf A now looks like:
(...)
item 132 key (143616 108 315392) itemoff 4995 itemsize 53
extent data disk bytenr 1801666560 nr 4096
extent data offset 0 nr 4096 ram 4096
item 133 key (143616 108 319488) itemoff 4942 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 16384 nr 57344 ram 73728
9) When btrfs_next_leaf() returns, it gives us a path pointing to leaf A
at slot 133, since it's the first key that follows what was the last
key we saw (143616 108 315392). In fact it's the same item we processed
before, but its key offset was changed, so it counts as a new key;
10) So now we have:
@key.offset == 319488
@datal == 57344
@off (372736) is > key.offset (319488), so @new_key.offset is set to
208896 (@destoff value).
@new_key.offset (208896) != @last_dest_end (212992), so @drop_start
is set to 212992 (@last_dest_end value).
@datal is adjusted to 4096 because @off > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the
invalid range of [212992, 212991] (which is
[@drop_start, @new_key.offset + @datal - 1]).
This range is empty, the end offset is smaller than the start offset
so btrfs_replace_file_extents() returns -EINVAL, which we end up
returning to user space and fail the reflink operation.
This all happens because the range of this file extent item was
already processed in the previous iteration.
This scenario can be triggered very sporadically by fsx from fstests, for
example with test case generic/522.
So fix this by having btrfs_clone() skip file extent items that cover a
file range that we have already processed.
CC: stable@vger.kernel.org # 5.10+
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:17 +00:00
|
|
|
*
|
|
|
|
* Subsequent searches may leave us on a file range we have
|
|
|
|
* processed before - this happens due to a race with ordered
|
|
|
|
* extent completion for a file range that is outside our source
|
|
|
|
* range, but that range was part of a file extent item that
|
|
|
|
* also covered a leading part of our source range.
|
2020-02-28 13:04:17 +00:00
|
|
|
*/
|
btrfs: fix race between reflinking and ordered extent completion
While doing a reflink operation, if an ordered extent for a file range
that does not overlap with the source and destination ranges of the
reflink operation happens, we can end up having a failure in the reflink
operation and return -EINVAL to user space.
The following sequence of steps explains how this can happen:
1) We have the page at file offset 315392 dirty (under delalloc);
2) A reflink operation for this file starts, using the same file as both
source and destination, the source range is [372736, 409600) (length of
36864 bytes) and the destination range is [208896, 245760);
3) At btrfs_remap_file_range_prep(), we flush all delalloc in the source
and destination ranges, and wait for any ordered extents in those range
to complete;
4) Still at btrfs_remap_file_range_prep(), we then flush all delalloc in
the inode, but we neither wait for it to complete nor any ordered
extents to complete. This results in starting delalloc for the page at
file offset 315392 and creating an ordered extent for that single page
range;
5) We then move to btrfs_clone() and enter the loop to find file extent
items to copy from the source range to destination range;
6) In the first iteration we end up at last file extent item stored in
leaf A:
(...)
item 131 key (143616 108 315392) itemoff 5101 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 12288 nr 61440 ram 73728
This represents the file range [315392, 376832), which overlaps with
the source range to clone.
@datal is set to 61440, key.offset is 315392 and @next_key_min_offset
is therefore set to 376832 (315392 + 61440).
@off (372736) is > key.offset (315392), so @new_key.offset is set to
the value of @destoff (208896).
@new_key.offset == @last_dest_end (208896) so @drop_start is set to
208896 (@new_key.offset).
@datal is adjusted to 4096, as @off is > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the range
[208896, 212991] (a single page, which is
[@drop_start, @new_key.offset + @datal - 1]).
@last_dest_end is set to 212992 (@new_key.offset + @datal =
208896 + 4096 = 212992).
Before the next iteration of the loop, @key.offset is set to the value
376832, which is @next_key_min_offset;
7) On the second iteration btrfs_search_slot() leaves us again at leaf A,
but this time pointing beyond the last slot of leaf A, as that's where
a key with offset 376832 should be at if it existed. So end up calling
btrfs_next_leaf();
8) btrfs_next_leaf() releases the path, but before it searches again the
tree for the next key/leaf, the ordered extent for the single page
range at file offset 315392 completes. That results in trimming the
file extent item we processed before, adjusting its key offset from
315392 to 319488, reducing its length from 61440 to 57344 and inserting
a new file extent item for that single page range, with a key offset of
315392 and a length of 4096.
Leaf A now looks like:
(...)
item 132 key (143616 108 315392) itemoff 4995 itemsize 53
extent data disk bytenr 1801666560 nr 4096
extent data offset 0 nr 4096 ram 4096
item 133 key (143616 108 319488) itemoff 4942 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 16384 nr 57344 ram 73728
9) When btrfs_next_leaf() returns, it gives us a path pointing to leaf A
at slot 133, since it's the first key that follows what was the last
key we saw (143616 108 315392). In fact it's the same item we processed
before, but its key offset was changed, so it counts as a new key;
10) So now we have:
@key.offset == 319488
@datal == 57344
@off (372736) is > key.offset (319488), so @new_key.offset is set to
208896 (@destoff value).
@new_key.offset (208896) != @last_dest_end (212992), so @drop_start
is set to 212992 (@last_dest_end value).
@datal is adjusted to 4096 because @off > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the
invalid range of [212992, 212991] (which is
[@drop_start, @new_key.offset + @datal - 1]).
This range is empty, the end offset is smaller than the start offset
so btrfs_replace_file_extents() returns -EINVAL, which we end up
returning to user space and fail the reflink operation.
This all happens because the range of this file extent item was
already processed in the previous iteration.
This scenario can be triggered very sporadically by fsx from fstests, for
example with test case generic/522.
So fix this by having btrfs_clone() skip file extent items that cover a
file range that we have already processed.
CC: stable@vger.kernel.org # 5.10+
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:17 +00:00
|
|
|
if (key.offset + datal <= prev_extent_end) {
|
2020-02-28 13:04:17 +00:00
|
|
|
path->slots[0]++;
|
|
|
|
goto process_slot;
|
|
|
|
} else if (key.offset >= off + len) {
|
|
|
|
break;
|
|
|
|
}
|
btrfs: fix race between reflinking and ordered extent completion
While doing a reflink operation, if an ordered extent for a file range
that does not overlap with the source and destination ranges of the
reflink operation happens, we can end up having a failure in the reflink
operation and return -EINVAL to user space.
The following sequence of steps explains how this can happen:
1) We have the page at file offset 315392 dirty (under delalloc);
2) A reflink operation for this file starts, using the same file as both
source and destination, the source range is [372736, 409600) (length of
36864 bytes) and the destination range is [208896, 245760);
3) At btrfs_remap_file_range_prep(), we flush all delalloc in the source
and destination ranges, and wait for any ordered extents in those range
to complete;
4) Still at btrfs_remap_file_range_prep(), we then flush all delalloc in
the inode, but we neither wait for it to complete nor any ordered
extents to complete. This results in starting delalloc for the page at
file offset 315392 and creating an ordered extent for that single page
range;
5) We then move to btrfs_clone() and enter the loop to find file extent
items to copy from the source range to destination range;
6) In the first iteration we end up at last file extent item stored in
leaf A:
(...)
item 131 key (143616 108 315392) itemoff 5101 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 12288 nr 61440 ram 73728
This represents the file range [315392, 376832), which overlaps with
the source range to clone.
@datal is set to 61440, key.offset is 315392 and @next_key_min_offset
is therefore set to 376832 (315392 + 61440).
@off (372736) is > key.offset (315392), so @new_key.offset is set to
the value of @destoff (208896).
@new_key.offset == @last_dest_end (208896) so @drop_start is set to
208896 (@new_key.offset).
@datal is adjusted to 4096, as @off is > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the range
[208896, 212991] (a single page, which is
[@drop_start, @new_key.offset + @datal - 1]).
@last_dest_end is set to 212992 (@new_key.offset + @datal =
208896 + 4096 = 212992).
Before the next iteration of the loop, @key.offset is set to the value
376832, which is @next_key_min_offset;
7) On the second iteration btrfs_search_slot() leaves us again at leaf A,
but this time pointing beyond the last slot of leaf A, as that's where
a key with offset 376832 should be at if it existed. So end up calling
btrfs_next_leaf();
8) btrfs_next_leaf() releases the path, but before it searches again the
tree for the next key/leaf, the ordered extent for the single page
range at file offset 315392 completes. That results in trimming the
file extent item we processed before, adjusting its key offset from
315392 to 319488, reducing its length from 61440 to 57344 and inserting
a new file extent item for that single page range, with a key offset of
315392 and a length of 4096.
Leaf A now looks like:
(...)
item 132 key (143616 108 315392) itemoff 4995 itemsize 53
extent data disk bytenr 1801666560 nr 4096
extent data offset 0 nr 4096 ram 4096
item 133 key (143616 108 319488) itemoff 4942 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 16384 nr 57344 ram 73728
9) When btrfs_next_leaf() returns, it gives us a path pointing to leaf A
at slot 133, since it's the first key that follows what was the last
key we saw (143616 108 315392). In fact it's the same item we processed
before, but its key offset was changed, so it counts as a new key;
10) So now we have:
@key.offset == 319488
@datal == 57344
@off (372736) is > key.offset (319488), so @new_key.offset is set to
208896 (@destoff value).
@new_key.offset (208896) != @last_dest_end (212992), so @drop_start
is set to 212992 (@last_dest_end value).
@datal is adjusted to 4096 because @off > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the
invalid range of [212992, 212991] (which is
[@drop_start, @new_key.offset + @datal - 1]).
This range is empty, the end offset is smaller than the start offset
so btrfs_replace_file_extents() returns -EINVAL, which we end up
returning to user space and fail the reflink operation.
This all happens because the range of this file extent item was
already processed in the previous iteration.
This scenario can be triggered very sporadically by fsx from fstests, for
example with test case generic/522.
So fix this by having btrfs_clone() skip file extent items that cover a
file range that we have already processed.
CC: stable@vger.kernel.org # 5.10+
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:17 +00:00
|
|
|
|
|
|
|
prev_extent_end = key.offset + datal;
|
2021-10-21 18:58:35 +00:00
|
|
|
size = btrfs_item_size(leaf, slot);
|
2020-02-28 13:04:17 +00:00
|
|
|
read_extent_buffer(leaf, buf, btrfs_item_ptr_offset(leaf, slot),
|
|
|
|
size);
|
|
|
|
|
|
|
|
btrfs_release_path(path);
|
|
|
|
|
|
|
|
memcpy(&new_key, &key, sizeof(new_key));
|
|
|
|
new_key.objectid = btrfs_ino(BTRFS_I(inode));
|
|
|
|
if (off <= key.offset)
|
|
|
|
new_key.offset = key.offset + destoff - off;
|
|
|
|
else
|
|
|
|
new_key.offset = destoff;
|
|
|
|
|
|
|
|
/*
|
|
|
|
* Deal with a hole that doesn't have an extent item that
|
|
|
|
* represents it (NO_HOLES feature enabled).
|
|
|
|
* This hole is either in the middle of the cloning range or at
|
|
|
|
* the beginning (fully overlaps it or partially overlaps it).
|
|
|
|
*/
|
|
|
|
if (new_key.offset != last_dest_end)
|
|
|
|
drop_start = last_dest_end;
|
|
|
|
else
|
|
|
|
drop_start = new_key.offset;
|
|
|
|
|
|
|
|
if (type == BTRFS_FILE_EXTENT_REG ||
|
|
|
|
type == BTRFS_FILE_EXTENT_PREALLOC) {
|
2020-09-08 10:27:22 +00:00
|
|
|
struct btrfs_replace_extent_info clone_info;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
/*
|
|
|
|
* a | --- range to clone ---| b
|
|
|
|
* | ------------- extent ------------- |
|
|
|
|
*/
|
|
|
|
|
|
|
|
/* Subtract range b */
|
|
|
|
if (key.offset + datal > off + len)
|
|
|
|
datal = off + len - key.offset;
|
|
|
|
|
|
|
|
/* Subtract range a */
|
|
|
|
if (off > key.offset) {
|
|
|
|
datao += off - key.offset;
|
|
|
|
datal -= off - key.offset;
|
|
|
|
}
|
|
|
|
|
|
|
|
clone_info.disk_offset = disko;
|
|
|
|
clone_info.disk_len = diskl;
|
|
|
|
clone_info.data_offset = datao;
|
|
|
|
clone_info.data_len = datal;
|
|
|
|
clone_info.file_offset = new_key.offset;
|
|
|
|
clone_info.extent_buf = buf;
|
btrfs: fix metadata reservation for fallocate that leads to transaction aborts
When doing an fallocate(), specially a zero range operation, we assume
that reserving 3 units of metadata space is enough, that at most we touch
one leaf in subvolume/fs tree for removing existing file extent items and
inserting a new file extent item. This assumption is generally true for
most common use cases. However when we end up needing to remove file extent
items from multiple leaves, we can end up failing with -ENOSPC and abort
the current transaction, turning the filesystem to RO mode. When this
happens a stack trace like the following is dumped in dmesg/syslog:
[ 1500.620934] ------------[ cut here ]------------
[ 1500.620938] BTRFS: Transaction aborted (error -28)
[ 1500.620973] WARNING: CPU: 2 PID: 30807 at fs/btrfs/inode.c:9724 __btrfs_prealloc_file_range+0x512/0x570 [btrfs]
[ 1500.620974] Modules linked in: btrfs intel_rapl_msr intel_rapl_common kvm_intel (...)
[ 1500.621010] CPU: 2 PID: 30807 Comm: xfs_io Tainted: G W 5.9.0-rc3-btrfs-next-67 #1
[ 1500.621012] Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS rel-1.13.0-0-gf21b5a4aeb02-prebuilt.qemu.org 04/01/2014
[ 1500.621023] RIP: 0010:__btrfs_prealloc_file_range+0x512/0x570 [btrfs]
[ 1500.621026] Code: 8b 40 50 f0 48 (...)
[ 1500.621028] RSP: 0018:ffffb05fc8803ca0 EFLAGS: 00010286
[ 1500.621030] RAX: 0000000000000000 RBX: ffff9608af276488 RCX: 0000000000000000
[ 1500.621032] RDX: 0000000000000001 RSI: 0000000000000027 RDI: 00000000ffffffff
[ 1500.621033] RBP: ffffb05fc8803d90 R08: 0000000000000001 R09: 0000000000000001
[ 1500.621035] R10: 0000000000000000 R11: 0000000000000000 R12: 0000000003200000
[ 1500.621037] R13: 00000000ffffffe4 R14: ffff9608af275fe8 R15: ffff9608af275f60
[ 1500.621039] FS: 00007fb5b2368ec0(0000) GS:ffff9608b6600000(0000) knlGS:0000000000000000
[ 1500.621041] CS: 0010 DS: 0000 ES: 0000 CR0: 0000000080050033
[ 1500.621043] CR2: 00007fb5b2366fb8 CR3: 0000000202d38005 CR4: 00000000003706e0
[ 1500.621046] DR0: 0000000000000000 DR1: 0000000000000000 DR2: 0000000000000000
[ 1500.621047] DR3: 0000000000000000 DR6: 00000000fffe0ff0 DR7: 0000000000000400
[ 1500.621049] Call Trace:
[ 1500.621076] btrfs_prealloc_file_range+0x10/0x20 [btrfs]
[ 1500.621087] btrfs_fallocate+0xccd/0x1280 [btrfs]
[ 1500.621108] vfs_fallocate+0x14d/0x290
[ 1500.621112] ksys_fallocate+0x3a/0x70
[ 1500.621117] __x64_sys_fallocate+0x1a/0x20
[ 1500.621120] do_syscall_64+0x33/0x80
[ 1500.621123] entry_SYSCALL_64_after_hwframe+0x44/0xa9
[ 1500.621126] RIP: 0033:0x7fb5b248c477
[ 1500.621128] Code: 89 7c 24 08 (...)
[ 1500.621130] RSP: 002b:00007ffc7bee9060 EFLAGS: 00000293 ORIG_RAX: 000000000000011d
[ 1500.621132] RAX: ffffffffffffffda RBX: 0000000000000002 RCX: 00007fb5b248c477
[ 1500.621134] RDX: 0000000000000000 RSI: 0000000000000010 RDI: 0000000000000003
[ 1500.621136] RBP: 0000557718faafd0 R08: 0000000000000000 R09: 0000000000000000
[ 1500.621137] R10: 0000000003200000 R11: 0000000000000293 R12: 0000000000000010
[ 1500.621139] R13: 0000557718faafb0 R14: 0000557718faa480 R15: 0000000000000003
[ 1500.621151] irq event stamp: 1026217
[ 1500.621154] hardirqs last enabled at (1026223): [<ffffffffba965570>] console_unlock+0x500/0x5c0
[ 1500.621156] hardirqs last disabled at (1026228): [<ffffffffba9654c7>] console_unlock+0x457/0x5c0
[ 1500.621159] softirqs last enabled at (1022486): [<ffffffffbb6003dc>] __do_softirq+0x3dc/0x606
[ 1500.621161] softirqs last disabled at (1022477): [<ffffffffbb4010b2>] asm_call_on_stack+0x12/0x20
[ 1500.621162] ---[ end trace 2955b08408d8b9d4 ]---
[ 1500.621167] BTRFS: error (device sdj) in __btrfs_prealloc_file_range:9724: errno=-28 No space left
When we use fallocate() internally, for reserving an extent for a space
cache, inode cache or relocation, we can't hit this problem since either
there aren't any file extent items to remove from the subvolume tree or
there is at most one.
When using plain fallocate() it's very unlikely, since that would require
having many file extent items representing holes for the target range and
crossing multiple leafs - we attempt to increase the range (merge) of such
file extent items when punching holes, so at most we end up with 2 file
extent items for holes at leaf boundaries.
However when using the zero range operation of fallocate() for a large
range (100+ MiB for example) that's fairly easy to trigger. The following
example reproducer triggers the issue:
$ cat reproducer.sh
#!/bin/bash
umount /dev/sdj &> /dev/null
mkfs.btrfs -f -n 16384 -O ^no-holes /dev/sdj > /dev/null
mount /dev/sdj /mnt/sdj
# Create a 100M file with many file extent items. Punch a hole every 8K
# just to speedup the file creation - we could do 4K sequential writes
# followed by fsync (or O_SYNC) as well, but that takes a lot of time.
file_size=$((100 * 1024 * 1024))
xfs_io -f -c "pwrite -S 0xab -b 10M 0 $file_size" /mnt/sdj/foobar
for ((i = 0; i < $file_size; i += 8192)); do
xfs_io -c "fpunch $i 4096" /mnt/sdj/foobar
done
# Force a transaction commit, so the zero range operation will be forced
# to COW all metadata extents it need to touch.
sync
xfs_io -c "fzero 0 $file_size" /mnt/sdj/foobar
umount /mnt/sdj
$ ./reproducer.sh
wrote 104857600/104857600 bytes at offset 0
100 MiB, 10 ops; 0.0669 sec (1.458 GiB/sec and 149.3117 ops/sec)
fallocate: No space left on device
$ dmesg
<shows the same stack trace pasted before>
To fix this use the existing infrastructure that hole punching and
extent cloning use for replacing a file range with another extent. This
deals with doing the removal of file extent items and inserting the new
one using an incremental approach, reserving more space when needed and
always ensuring we don't leave an implicit hole in the range in case
we need to do multiple iterations and a crash happens between iterations.
A test case for fstests will follow up soon.
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-09-08 10:27:20 +00:00
|
|
|
clone_info.is_new_extent = false;
|
btrfs: add missing inode updates on each iteration when replacing extents
When replacing file extents, called during fallocate, hole punching,
clone and deduplication, we may not be able to replace/drop all the
target file extent items with a single transaction handle. We may get
-ENOSPC while doing it, in which case we release the transaction handle,
balance the dirty pages of the btree inode, flush delayed items and get
a new transaction handle to operate on what's left of the target range.
By dropping and replacing file extent items we have effectively modified
the inode, so we should bump its iversion and update its mtime/ctime
before we update the inode item. This is because if the transaction
we used for partially modifying the inode gets committed by someone after
we release it and before we finish the rest of the range, a power failure
happens, then after mounting the filesystem our inode has an outdated
iversion and mtime/ctime, corresponding to the values it had before we
changed it.
So add the missing iversion and mtime/ctime updates.
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:18 +00:00
|
|
|
clone_info.update_times = !no_time_update;
|
2021-02-17 13:12:47 +00:00
|
|
|
ret = btrfs_replace_file_extents(BTRFS_I(inode), path,
|
|
|
|
drop_start, new_key.offset + datal - 1,
|
|
|
|
&clone_info, &trans);
|
2020-02-28 13:04:17 +00:00
|
|
|
if (ret)
|
|
|
|
goto out;
|
2022-02-17 12:12:08 +00:00
|
|
|
} else {
|
|
|
|
ASSERT(type == BTRFS_FILE_EXTENT_INLINE);
|
2020-02-28 13:04:18 +00:00
|
|
|
/*
|
|
|
|
* Inline extents always have to start at file offset 0
|
|
|
|
* and can never be bigger then the sector size. We can
|
|
|
|
* never clone only parts of an inline extent, since all
|
|
|
|
* reflink operations must start at a sector size aligned
|
|
|
|
* offset, and the length must be aligned too or end at
|
|
|
|
* the i_size (which implies the whole inlined data).
|
|
|
|
*/
|
|
|
|
ASSERT(key.offset == 0);
|
|
|
|
ASSERT(datal <= fs_info->sectorsize);
|
2022-02-17 12:12:08 +00:00
|
|
|
if (WARN_ON(type != BTRFS_FILE_EXTENT_INLINE) ||
|
|
|
|
WARN_ON(key.offset != 0) ||
|
2022-02-17 12:12:07 +00:00
|
|
|
WARN_ON(datal > fs_info->sectorsize)) {
|
|
|
|
ret = -EUCLEAN;
|
|
|
|
goto out;
|
|
|
|
}
|
2020-02-28 13:04:17 +00:00
|
|
|
|
2020-02-28 13:04:19 +00:00
|
|
|
ret = clone_copy_inline_extent(inode, path, &new_key,
|
|
|
|
drop_start, datal, size,
|
|
|
|
comp, buf, &trans);
|
|
|
|
if (ret)
|
2020-02-28 13:04:17 +00:00
|
|
|
goto out;
|
|
|
|
}
|
|
|
|
|
|
|
|
btrfs_release_path(path);
|
|
|
|
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
/*
|
btrfs: stop copying old file extents when doing a full fsync
When logging an inode in full sync mode, we go over every leaf that was
modified in the current transaction and has items associated to our inode,
and then copy all those items into the log tree. This includes copying
file extent items that were created and added to the inode in past
transactions, which is useless and only makes use more leaf space in the
log tree.
It's common to have a file with many file extent items spanning many
leaves where only a few file extent items are new and need to be logged,
and in such case we log all the file extent items we find in the modified
leaves.
So change the full sync behaviour to skip over file extent items that are
not needed. Those are the ones that match the following criteria:
1) Have a generation older than the current transaction and the inode
was not a target of a reflink operation, as that can copy file extent
items from a past generation from some other inode into our inode, so
we have to log them;
2) Start at an offset within i_size - we must log anything at or beyond
i_size, otherwise we would lose prealloc extents after log replay.
The following script exercises a scenario where this happens, and it's
somehow close enough to what happened often on a SQL Server workload which
I had to debug sometime ago to fix an issue where a pattern of writes to
prealloc extents and fsync resulted in fsync failing with -EIO (that was
commit ea7036de0d36c4 ("btrfs: fix fsync failure and transaction abort
after writes to prealloc extents")). In that particular case, we had large
files that had random writes and were often truncated, which made the
next fsync be a full sync.
$ cat test.sh
#!/bin/bash
DEV=/dev/sdi
MNT=/mnt/sdi
MKFS_OPTIONS="-O no-holes -R free-space-tree"
MOUNT_OPTIONS="-o ssd"
FILE_SIZE=$((1 * 1024 * 1024 * 1024)) # 1G
# FILE_SIZE=$((2 * 1024 * 1024 * 1024)) # 2G
# FILE_SIZE=$((512 * 1024 * 1024)) # 512M
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
# Create a file with many extents. Use direct IO to make it faster
# to create the file - using buffered IO we would have to fsync
# after each write (terribly slow).
echo "Creating file with $((FILE_SIZE / 4096)) extents of 4K each..."
xfs_io -f -d -c "pwrite -b 4K 0 $FILE_SIZE" $MNT/foobar
# Commit the transaction, so every extent after this is from an
# old generation.
sync
# Now rewrite only a few extents, which are all far spread apart from
# each other (e.g. 1G / 32M = 32 extents).
# After this only a few extents have a new generation, while all other
# ones have an old generation.
echo "Rewriting $((FILE_SIZE / (32 * 1024 * 1024))) extents..."
for ((i = 0; i < $FILE_SIZE; i += $((32 * 1024 * 1024)))); do
xfs_io -c "pwrite $i 4K" $MNT/foobar >/dev/null
done
# Fsync, the inode logged in full sync mode since it was never fsynced
# before.
echo "Fsyncing file..."
xfs_io -c "fsync" $MNT/foobar
umount $MNT
And the following bpftrace program was running when executing the test
script:
$ cat bpf-script.sh
#!/usr/bin/bpftrace
k:btrfs_log_inode
{
@start_log_inode[tid] = nsecs;
}
kr:btrfs_log_inode
/@start_log_inode[tid]/
{
@log_inode_dur[tid] = (nsecs - @start_log_inode[tid]) / 1000;
delete(@start_log_inode[tid]);
}
k:btrfs_sync_log
{
@start_sync_log[tid] = nsecs;
}
kr:btrfs_sync_log
/@start_sync_log[tid]/
{
$sync_log_dur = (nsecs - @start_sync_log[tid]) / 1000;
printf("btrfs_log_inode() took %llu us\n", @log_inode_dur[tid]);
printf("btrfs_sync_log() took %llu us\n", $sync_log_dur);
delete(@start_sync_log[tid]);
delete(@log_inode_dur[tid]);
exit();
}
With 512M test file, before this patch:
btrfs_log_inode() took 15218 us
btrfs_sync_log() took 1328 us
Log tree has 17 leaves and 1 node, its total size is 294912 bytes.
With 512M test file, after this patch:
btrfs_log_inode() took 14760 us
btrfs_sync_log() took 588 us
Log tree has a single leaf, its total size is 16K.
With 1G test file, before this patch:
btrfs_log_inode() took 27301 us
btrfs_sync_log() took 1767 us
Log tree has 33 leaves and 1 node, its total size is 557056 bytes.
With 1G test file, after this patch:
btrfs_log_inode() took 26166 us
btrfs_sync_log() took 593 us
Log tree has a single leaf, its total size is 16K
With 2G test file, before this patch:
btrfs_log_inode() took 50892 us
btrfs_sync_log() took 3127 us
Log tree has 65 leaves and 1 node, its total size is 1081344 bytes.
With 2G test file, after this patch:
btrfs_log_inode() took 50126 us
btrfs_sync_log() took 586 us
Log tree has a single leaf, its total size is 16K.
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-02-17 12:12:03 +00:00
|
|
|
* Whenever we share an extent we update the last_reflink_trans
|
|
|
|
* of each inode to the current transaction. This is needed to
|
|
|
|
* make sure fsync does not log multiple checksum items with
|
|
|
|
* overlapping ranges (because some extent items might refer
|
|
|
|
* only to sections of the original extent). For the destination
|
|
|
|
* inode we do this regardless of the generation of the extents
|
|
|
|
* or even if they are inline extents or explicit holes, to make
|
|
|
|
* sure a full fsync does not skip them. For the source inode,
|
|
|
|
* we only need to update last_reflink_trans in case it's a new
|
|
|
|
* extent that is not a hole or an inline extent, to deal with
|
|
|
|
* the checksums problem on fsync.
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
*/
|
btrfs: stop copying old file extents when doing a full fsync
When logging an inode in full sync mode, we go over every leaf that was
modified in the current transaction and has items associated to our inode,
and then copy all those items into the log tree. This includes copying
file extent items that were created and added to the inode in past
transactions, which is useless and only makes use more leaf space in the
log tree.
It's common to have a file with many file extent items spanning many
leaves where only a few file extent items are new and need to be logged,
and in such case we log all the file extent items we find in the modified
leaves.
So change the full sync behaviour to skip over file extent items that are
not needed. Those are the ones that match the following criteria:
1) Have a generation older than the current transaction and the inode
was not a target of a reflink operation, as that can copy file extent
items from a past generation from some other inode into our inode, so
we have to log them;
2) Start at an offset within i_size - we must log anything at or beyond
i_size, otherwise we would lose prealloc extents after log replay.
The following script exercises a scenario where this happens, and it's
somehow close enough to what happened often on a SQL Server workload which
I had to debug sometime ago to fix an issue where a pattern of writes to
prealloc extents and fsync resulted in fsync failing with -EIO (that was
commit ea7036de0d36c4 ("btrfs: fix fsync failure and transaction abort
after writes to prealloc extents")). In that particular case, we had large
files that had random writes and were often truncated, which made the
next fsync be a full sync.
$ cat test.sh
#!/bin/bash
DEV=/dev/sdi
MNT=/mnt/sdi
MKFS_OPTIONS="-O no-holes -R free-space-tree"
MOUNT_OPTIONS="-o ssd"
FILE_SIZE=$((1 * 1024 * 1024 * 1024)) # 1G
# FILE_SIZE=$((2 * 1024 * 1024 * 1024)) # 2G
# FILE_SIZE=$((512 * 1024 * 1024)) # 512M
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
# Create a file with many extents. Use direct IO to make it faster
# to create the file - using buffered IO we would have to fsync
# after each write (terribly slow).
echo "Creating file with $((FILE_SIZE / 4096)) extents of 4K each..."
xfs_io -f -d -c "pwrite -b 4K 0 $FILE_SIZE" $MNT/foobar
# Commit the transaction, so every extent after this is from an
# old generation.
sync
# Now rewrite only a few extents, which are all far spread apart from
# each other (e.g. 1G / 32M = 32 extents).
# After this only a few extents have a new generation, while all other
# ones have an old generation.
echo "Rewriting $((FILE_SIZE / (32 * 1024 * 1024))) extents..."
for ((i = 0; i < $FILE_SIZE; i += $((32 * 1024 * 1024)))); do
xfs_io -c "pwrite $i 4K" $MNT/foobar >/dev/null
done
# Fsync, the inode logged in full sync mode since it was never fsynced
# before.
echo "Fsyncing file..."
xfs_io -c "fsync" $MNT/foobar
umount $MNT
And the following bpftrace program was running when executing the test
script:
$ cat bpf-script.sh
#!/usr/bin/bpftrace
k:btrfs_log_inode
{
@start_log_inode[tid] = nsecs;
}
kr:btrfs_log_inode
/@start_log_inode[tid]/
{
@log_inode_dur[tid] = (nsecs - @start_log_inode[tid]) / 1000;
delete(@start_log_inode[tid]);
}
k:btrfs_sync_log
{
@start_sync_log[tid] = nsecs;
}
kr:btrfs_sync_log
/@start_sync_log[tid]/
{
$sync_log_dur = (nsecs - @start_sync_log[tid]) / 1000;
printf("btrfs_log_inode() took %llu us\n", @log_inode_dur[tid]);
printf("btrfs_sync_log() took %llu us\n", $sync_log_dur);
delete(@start_sync_log[tid]);
delete(@log_inode_dur[tid]);
exit();
}
With 512M test file, before this patch:
btrfs_log_inode() took 15218 us
btrfs_sync_log() took 1328 us
Log tree has 17 leaves and 1 node, its total size is 294912 bytes.
With 512M test file, after this patch:
btrfs_log_inode() took 14760 us
btrfs_sync_log() took 588 us
Log tree has a single leaf, its total size is 16K.
With 1G test file, before this patch:
btrfs_log_inode() took 27301 us
btrfs_sync_log() took 1767 us
Log tree has 33 leaves and 1 node, its total size is 557056 bytes.
With 1G test file, after this patch:
btrfs_log_inode() took 26166 us
btrfs_sync_log() took 593 us
Log tree has a single leaf, its total size is 16K
With 2G test file, before this patch:
btrfs_log_inode() took 50892 us
btrfs_sync_log() took 3127 us
Log tree has 65 leaves and 1 node, its total size is 1081344 bytes.
With 2G test file, after this patch:
btrfs_log_inode() took 50126 us
btrfs_sync_log() took 586 us
Log tree has a single leaf, its total size is 16K.
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-02-17 12:12:03 +00:00
|
|
|
if (extent_gen == trans->transid && disko > 0)
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
BTRFS_I(src)->last_reflink_trans = trans->transid;
|
btrfs: stop copying old file extents when doing a full fsync
When logging an inode in full sync mode, we go over every leaf that was
modified in the current transaction and has items associated to our inode,
and then copy all those items into the log tree. This includes copying
file extent items that were created and added to the inode in past
transactions, which is useless and only makes use more leaf space in the
log tree.
It's common to have a file with many file extent items spanning many
leaves where only a few file extent items are new and need to be logged,
and in such case we log all the file extent items we find in the modified
leaves.
So change the full sync behaviour to skip over file extent items that are
not needed. Those are the ones that match the following criteria:
1) Have a generation older than the current transaction and the inode
was not a target of a reflink operation, as that can copy file extent
items from a past generation from some other inode into our inode, so
we have to log them;
2) Start at an offset within i_size - we must log anything at or beyond
i_size, otherwise we would lose prealloc extents after log replay.
The following script exercises a scenario where this happens, and it's
somehow close enough to what happened often on a SQL Server workload which
I had to debug sometime ago to fix an issue where a pattern of writes to
prealloc extents and fsync resulted in fsync failing with -EIO (that was
commit ea7036de0d36c4 ("btrfs: fix fsync failure and transaction abort
after writes to prealloc extents")). In that particular case, we had large
files that had random writes and were often truncated, which made the
next fsync be a full sync.
$ cat test.sh
#!/bin/bash
DEV=/dev/sdi
MNT=/mnt/sdi
MKFS_OPTIONS="-O no-holes -R free-space-tree"
MOUNT_OPTIONS="-o ssd"
FILE_SIZE=$((1 * 1024 * 1024 * 1024)) # 1G
# FILE_SIZE=$((2 * 1024 * 1024 * 1024)) # 2G
# FILE_SIZE=$((512 * 1024 * 1024)) # 512M
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
# Create a file with many extents. Use direct IO to make it faster
# to create the file - using buffered IO we would have to fsync
# after each write (terribly slow).
echo "Creating file with $((FILE_SIZE / 4096)) extents of 4K each..."
xfs_io -f -d -c "pwrite -b 4K 0 $FILE_SIZE" $MNT/foobar
# Commit the transaction, so every extent after this is from an
# old generation.
sync
# Now rewrite only a few extents, which are all far spread apart from
# each other (e.g. 1G / 32M = 32 extents).
# After this only a few extents have a new generation, while all other
# ones have an old generation.
echo "Rewriting $((FILE_SIZE / (32 * 1024 * 1024))) extents..."
for ((i = 0; i < $FILE_SIZE; i += $((32 * 1024 * 1024)))); do
xfs_io -c "pwrite $i 4K" $MNT/foobar >/dev/null
done
# Fsync, the inode logged in full sync mode since it was never fsynced
# before.
echo "Fsyncing file..."
xfs_io -c "fsync" $MNT/foobar
umount $MNT
And the following bpftrace program was running when executing the test
script:
$ cat bpf-script.sh
#!/usr/bin/bpftrace
k:btrfs_log_inode
{
@start_log_inode[tid] = nsecs;
}
kr:btrfs_log_inode
/@start_log_inode[tid]/
{
@log_inode_dur[tid] = (nsecs - @start_log_inode[tid]) / 1000;
delete(@start_log_inode[tid]);
}
k:btrfs_sync_log
{
@start_sync_log[tid] = nsecs;
}
kr:btrfs_sync_log
/@start_sync_log[tid]/
{
$sync_log_dur = (nsecs - @start_sync_log[tid]) / 1000;
printf("btrfs_log_inode() took %llu us\n", @log_inode_dur[tid]);
printf("btrfs_sync_log() took %llu us\n", $sync_log_dur);
delete(@start_sync_log[tid]);
delete(@log_inode_dur[tid]);
exit();
}
With 512M test file, before this patch:
btrfs_log_inode() took 15218 us
btrfs_sync_log() took 1328 us
Log tree has 17 leaves and 1 node, its total size is 294912 bytes.
With 512M test file, after this patch:
btrfs_log_inode() took 14760 us
btrfs_sync_log() took 588 us
Log tree has a single leaf, its total size is 16K.
With 1G test file, before this patch:
btrfs_log_inode() took 27301 us
btrfs_sync_log() took 1767 us
Log tree has 33 leaves and 1 node, its total size is 557056 bytes.
With 1G test file, after this patch:
btrfs_log_inode() took 26166 us
btrfs_sync_log() took 593 us
Log tree has a single leaf, its total size is 16K
With 2G test file, before this patch:
btrfs_log_inode() took 50892 us
btrfs_sync_log() took 3127 us
Log tree has 65 leaves and 1 node, its total size is 1081344 bytes.
With 2G test file, after this patch:
btrfs_log_inode() took 50126 us
btrfs_sync_log() took 586 us
Log tree has a single leaf, its total size is 16K.
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-02-17 12:12:03 +00:00
|
|
|
|
|
|
|
BTRFS_I(inode)->last_reflink_trans = trans->transid;
|
btrfs: reduce contention on log trees when logging checksums
The possibility of extents being shared (through clone and deduplication
operations) requires special care when logging data checksums, to avoid
having a log tree with different checksum items that cover ranges which
overlap (which resulted in missing checksums after replaying a log tree).
Such problems were fixed in the past by the following commits:
commit 40e046acbd2f ("Btrfs: fix missing data checksums after replaying a
log tree")
commit e289f03ea79b ("btrfs: fix corrupt log due to concurrent fsync of
inodes with shared extents")
Test case generic/588 exercises the scenario solved by the first commit
(purely sequential and deterministic) while test case generic/457 often
triggered the case fixed by the second commit (not deterministic, requires
specific timings under concurrency).
The problems were addressed by deleting, from the log tree, any existing
checksums before logging the new ones. And also by doing the deletion and
logging of the cheksums while locking the checksum range in an extent io
tree (root->log_csum_range), to deal with the case where we have concurrent
fsyncs against files with shared extents.
That however causes more contention on the leaves of a log tree where we
store checksums (and all the nodes in the paths leading to them), even
when we do not have shared extents, or all the shared extents were created
by past transactions. It also adds a bit of contention on the spin lock of
the log_csums_range extent io tree of the log root.
This change adds a 'last_reflink_trans' field to the inode to keep track
of the last transaction where a new extent was shared between inodes
(through clone and deduplication operations). It is updated for both the
source and destination inodes of reflink operations whenever a new extent
(created in the current transaction) becomes shared by the inodes. This
field is kept in memory only, not persisted in the inode item, similar
to other existing fields (last_unlink_trans, logged_trans).
When logging checksums for an extent, if the value of 'last_reflink_trans'
is smaller then the current transaction's generation/id, we skip locking
the extent range and deletion of checksums from the log tree, since we
know we do not have new shared extents. This reduces contention on the
log tree's leaves where checksums are stored.
The following script, which uses fio, was used to measure the impact of
this change:
$ cat test-fsync.sh
#!/bin/bash
DEV=/dev/sdk
MNT=/mnt/sdk
MOUNT_OPTIONS="-o ssd"
MKFS_OPTIONS="-d single -m single"
if [ $# -ne 3 ]; then
echo "Use $0 NUM_JOBS FILE_SIZE FSYNC_FREQ"
exit 1
fi
NUM_JOBS=$1
FILE_SIZE=$2
FSYNC_FREQ=$3
cat <<EOF > /tmp/fio-job.ini
[writers]
rw=write
fsync=$FSYNC_FREQ
fallocate=none
group_reporting=1
direct=0
bs=64k
ioengine=sync
size=$FILE_SIZE
directory=$MNT
numjobs=$NUM_JOBS
EOF
echo "Using config:"
echo
cat /tmp/fio-job.ini
echo
mkfs.btrfs -f $MKFS_OPTIONS $DEV
mount $MOUNT_OPTIONS $DEV $MNT
fio /tmp/fio-job.ini
umount $MNT
The tests were performed for different numbers of jobs, file sizes and
fsync frequency. A qemu VM using kvm was used, with 8 cores (the host has
12 cores, with cpu governance set to performance mode on all cores), 16GiB
of ram (the host has 64GiB) and using a NVMe device directly (without an
intermediary filesystem in the host). While running the tests, the host
was not used for anything else, to avoid disturbing the tests.
The obtained results were the following (the last line of fio's output was
pasted). Starting with 16 jobs is where a significant difference is
observable in this particular setup and hardware (differences highlighted
below). The very small differences for tests with less than 16 jobs are
possibly just noise and random.
**** 1 job, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=23.8MiB/s (24.9MB/s), 23.8MiB/s-23.8MiB/s (24.9MB/s-24.9MB/s), io=1024MiB (1074MB), run=43075-43075msec
after this change:
WRITE: bw=24.4MiB/s (25.6MB/s), 24.4MiB/s-24.4MiB/s (25.6MB/s-25.6MB/s), io=1024MiB (1074MB), run=41938-41938msec
**** 2 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.7MiB/s-37.7MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54351-54351msec
after this change:
WRITE: bw=37.7MiB/s (39.5MB/s), 37.6MiB/s-37.6MiB/s (39.5MB/s-39.5MB/s), io=2048MiB (2147MB), run=54428-54428msec
**** 4 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=67.5MiB/s (70.8MB/s), 67.5MiB/s-67.5MiB/s (70.8MB/s-70.8MB/s), io=4096MiB (4295MB), run=60669-60669msec
after this change:
WRITE: bw=68.6MiB/s (71.0MB/s), 68.6MiB/s-68.6MiB/s (71.0MB/s-71.0MB/s), io=4096MiB (4295MB), run=59678-59678msec
**** 8 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=128MiB/s (134MB/s), 128MiB/s-128MiB/s (134MB/s-134MB/s), io=8192MiB (8590MB), run=64048-64048msec
after this change:
WRITE: bw=129MiB/s (135MB/s), 129MiB/s-129MiB/s (135MB/s-135MB/s), io=8192MiB (8590MB), run=63405-63405msec
**** 16 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=78.5MiB/s (82.3MB/s), 78.5MiB/s-78.5MiB/s (82.3MB/s-82.3MB/s), io=16.0GiB (17.2GB), run=208676-208676msec
after this change:
WRITE: bw=110MiB/s (115MB/s), 110MiB/s-110MiB/s (115MB/s-115MB/s), io=16.0GiB (17.2GB), run=149295-149295msec
(+40.1% throughput, -28.5% runtime)
**** 32 jobs, file size 1G, fsync frequency 1 ****
before this change:
WRITE: bw=58.8MiB/s (61.7MB/s), 58.8MiB/s-58.8MiB/s (61.7MB/s-61.7MB/s), io=32.0GiB (34.4GB), run=557134-557134msec
after this change:
WRITE: bw=76.1MiB/s (79.8MB/s), 76.1MiB/s-76.1MiB/s (79.8MB/s-79.8MB/s), io=32.0GiB (34.4GB), run=430550-430550msec
(+29.4% throughput, -22.7% runtime)
**** 64 jobs, file size 512M, fsync frequency 1 ****
before this change:
WRITE: bw=65.8MiB/s (68.0MB/s), 65.8MiB/s-65.8MiB/s (68.0MB/s-68.0MB/s), io=32.0GiB (34.4GB), run=498055-498055msec
after this change:
WRITE: bw=85.1MiB/s (89.2MB/s), 85.1MiB/s-85.1MiB/s (89.2MB/s-89.2MB/s), io=32.0GiB (34.4GB), run=385116-385116msec
(+29.3% throughput, -22.7% runtime)
**** 128 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=54.7MiB/s (57.3MB/s), 54.7MiB/s-54.7MiB/s (57.3MB/s-57.3MB/s), io=32.0GiB (34.4GB), run=599373-599373msec
after this change:
WRITE: bw=121MiB/s (126MB/s), 121MiB/s-121MiB/s (126MB/s-126MB/s), io=32.0GiB (34.4GB), run=271907-271907msec
(+121.2% throughput, -54.6% runtime)
**** 256 jobs, file size 256M, fsync frequency 1 ****
before this change:
WRITE: bw=69.2MiB/s (72.5MB/s), 69.2MiB/s-69.2MiB/s (72.5MB/s-72.5MB/s), io=64.0GiB (68.7GB), run=947536-947536msec
after this change:
WRITE: bw=121MiB/s (127MB/s), 121MiB/s-121MiB/s (127MB/s-127MB/s), io=64.0GiB (68.7GB), run=541916-541916msec
(+74.9% throughput, -42.8% runtime)
**** 512 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=85.4MiB/s (89.5MB/s), 85.4MiB/s-85.4MiB/s (89.5MB/s-89.5MB/s), io=64.0GiB (68.7GB), run=767734-767734msec
after this change:
WRITE: bw=141MiB/s (147MB/s), 141MiB/s-141MiB/s (147MB/s-147MB/s), io=64.0GiB (68.7GB), run=466022-466022msec
(+65.1% throughput, -39.3% runtime)
**** 1024 jobs, file size 128M, fsync frequency 1 ****
before this change:
WRITE: bw=115MiB/s (120MB/s), 115MiB/s-115MiB/s (120MB/s-120MB/s), io=128GiB (137GB), run=1143775-1143775msec
after this change:
WRITE: bw=171MiB/s (180MB/s), 171MiB/s-171MiB/s (180MB/s-180MB/s), io=128GiB (137GB), run=764843-764843msec
(+48.7% throughput, -33.1% runtime)
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-07-15 11:30:43 +00:00
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
last_dest_end = ALIGN(new_key.offset + datal,
|
|
|
|
fs_info->sectorsize);
|
|
|
|
ret = clone_finish_inode_update(trans, inode, last_dest_end,
|
|
|
|
destoff, olen, no_time_update);
|
|
|
|
if (ret)
|
|
|
|
goto out;
|
|
|
|
if (new_key.offset + datal >= destoff + len)
|
|
|
|
break;
|
|
|
|
|
|
|
|
btrfs_release_path(path);
|
btrfs: fix race between reflinking and ordered extent completion
While doing a reflink operation, if an ordered extent for a file range
that does not overlap with the source and destination ranges of the
reflink operation happens, we can end up having a failure in the reflink
operation and return -EINVAL to user space.
The following sequence of steps explains how this can happen:
1) We have the page at file offset 315392 dirty (under delalloc);
2) A reflink operation for this file starts, using the same file as both
source and destination, the source range is [372736, 409600) (length of
36864 bytes) and the destination range is [208896, 245760);
3) At btrfs_remap_file_range_prep(), we flush all delalloc in the source
and destination ranges, and wait for any ordered extents in those range
to complete;
4) Still at btrfs_remap_file_range_prep(), we then flush all delalloc in
the inode, but we neither wait for it to complete nor any ordered
extents to complete. This results in starting delalloc for the page at
file offset 315392 and creating an ordered extent for that single page
range;
5) We then move to btrfs_clone() and enter the loop to find file extent
items to copy from the source range to destination range;
6) In the first iteration we end up at last file extent item stored in
leaf A:
(...)
item 131 key (143616 108 315392) itemoff 5101 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 12288 nr 61440 ram 73728
This represents the file range [315392, 376832), which overlaps with
the source range to clone.
@datal is set to 61440, key.offset is 315392 and @next_key_min_offset
is therefore set to 376832 (315392 + 61440).
@off (372736) is > key.offset (315392), so @new_key.offset is set to
the value of @destoff (208896).
@new_key.offset == @last_dest_end (208896) so @drop_start is set to
208896 (@new_key.offset).
@datal is adjusted to 4096, as @off is > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the range
[208896, 212991] (a single page, which is
[@drop_start, @new_key.offset + @datal - 1]).
@last_dest_end is set to 212992 (@new_key.offset + @datal =
208896 + 4096 = 212992).
Before the next iteration of the loop, @key.offset is set to the value
376832, which is @next_key_min_offset;
7) On the second iteration btrfs_search_slot() leaves us again at leaf A,
but this time pointing beyond the last slot of leaf A, as that's where
a key with offset 376832 should be at if it existed. So end up calling
btrfs_next_leaf();
8) btrfs_next_leaf() releases the path, but before it searches again the
tree for the next key/leaf, the ordered extent for the single page
range at file offset 315392 completes. That results in trimming the
file extent item we processed before, adjusting its key offset from
315392 to 319488, reducing its length from 61440 to 57344 and inserting
a new file extent item for that single page range, with a key offset of
315392 and a length of 4096.
Leaf A now looks like:
(...)
item 132 key (143616 108 315392) itemoff 4995 itemsize 53
extent data disk bytenr 1801666560 nr 4096
extent data offset 0 nr 4096 ram 4096
item 133 key (143616 108 319488) itemoff 4942 itemsize 53
extent data disk bytenr 1903988736 nr 73728
extent data offset 16384 nr 57344 ram 73728
9) When btrfs_next_leaf() returns, it gives us a path pointing to leaf A
at slot 133, since it's the first key that follows what was the last
key we saw (143616 108 315392). In fact it's the same item we processed
before, but its key offset was changed, so it counts as a new key;
10) So now we have:
@key.offset == 319488
@datal == 57344
@off (372736) is > key.offset (319488), so @new_key.offset is set to
208896 (@destoff value).
@new_key.offset (208896) != @last_dest_end (212992), so @drop_start
is set to 212992 (@last_dest_end value).
@datal is adjusted to 4096 because @off > @key.offset.
So in this iteration we call btrfs_replace_file_extents() for the
invalid range of [212992, 212991] (which is
[@drop_start, @new_key.offset + @datal - 1]).
This range is empty, the end offset is smaller than the start offset
so btrfs_replace_file_extents() returns -EINVAL, which we end up
returning to user space and fail the reflink operation.
This all happens because the range of this file extent item was
already processed in the previous iteration.
This scenario can be triggered very sporadically by fsx from fstests, for
example with test case generic/522.
So fix this by having btrfs_clone() skip file extent items that cover a
file range that we have already processed.
CC: stable@vger.kernel.org # 5.10+
Reviewed-by: Boris Burkov <boris@bur.io>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-06-06 09:41:17 +00:00
|
|
|
key.offset = prev_extent_end;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
if (fatal_signal_pending(current)) {
|
|
|
|
ret = -EINTR;
|
|
|
|
goto out;
|
|
|
|
}
|
2020-09-22 08:27:29 +00:00
|
|
|
|
|
|
|
cond_resched();
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
ret = 0;
|
|
|
|
|
|
|
|
if (last_dest_end < destoff + len) {
|
|
|
|
/*
|
|
|
|
* We have an implicit hole that fully or partially overlaps our
|
|
|
|
* cloning range at its end. This means that we either have the
|
|
|
|
* NO_HOLES feature enabled or the implicit hole happened due to
|
|
|
|
* mixing buffered and direct IO writes against this file.
|
|
|
|
*/
|
|
|
|
btrfs_release_path(path);
|
|
|
|
|
btrfs: fix stale data exposure after cloning a hole with NO_HOLES enabled
When using the NO_HOLES feature, if we clone a file range that spans only
a hole into a range that is at or beyond the current i_size of the
destination file, we end up not setting the full sync runtime flag on the
inode. As a result, if we then fsync the destination file and have a power
failure, after log replay we can end up exposing stale data instead of
having a hole for that range.
The conditions for this to happen are the following:
1) We have a file with a size of, for example, 1280K;
2) There is a written (non-prealloc) extent for the file range from 1024K
to 1280K with a length of 256K;
3) This particular file extent layout is durably persisted, so that the
existing superblock persisted on disk points to a subvolume root where
the file has that exact file extent layout and state;
4) The file is truncated to a smaller size, to an offset lower than the
start offset of its last extent, for example to 800K. The truncate sets
the full sync runtime flag on the inode;
6) Fsync the file to log it and clear the full sync runtime flag;
7) Clone a region that covers only a hole (implicit hole due to NO_HOLES)
into the file with a destination offset that starts at or beyond the
256K file extent item we had - for example to offset 1024K;
8) Since the clone operation does not find extents in the source range,
we end up in the if branch at the bottom of btrfs_clone() where we
punch a hole for the file range starting at offset 1024K by calling
btrfs_replace_file_extents(). There we end up not setting the full
sync flag on the inode, because we don't know we are being called in
a clone context (and not fallocate's punch hole operation), and
neither do we create an extent map to represent a hole because the
requested range is beyond eof;
9) A further fsync to the file will be a fast fsync, since the clone
operation did not set the full sync flag, and therefore it relies on
modified extent maps to correctly log the file layout. But since
it does not find any extent map marking the range from 1024K (the
previous eof) to the new eof, it does not log a file extent item
for that range representing the hole;
10) After a power failure no hole for the range starting at 1024K is
punched and we end up exposing stale data from the old 256K extent.
Turning this into exact steps:
$ mkfs.btrfs -f -O no-holes /dev/sdi
$ mount /dev/sdi /mnt
# Create our test file with 3 extents of 256K and a 256K hole at offset
# 256K. The file has a size of 1280K.
$ xfs_io -f -s \
-c "pwrite -S 0xab -b 256K 0 256K" \
-c "pwrite -S 0xcd -b 256K 512K 256K" \
-c "pwrite -S 0xef -b 256K 768K 256K" \
-c "pwrite -S 0x73 -b 256K 1024K 256K" \
/mnt/sdi/foobar
# Make sure it's durably persisted. We want the last committed super
# block to point to this particular file extent layout.
sync
# Now truncate our file to a smaller size, falling within a position of
# the second extent. This sets the full sync runtime flag on the inode.
# Then fsync the file to log it and clear the full sync flag from the
# inode. The third extent is no longer part of the file and therefore
# it is not logged.
$ xfs_io -c "truncate 800K" -c "fsync" /mnt/foobar
# Now do a clone operation that only clones the hole and sets back the
# file size to match the size it had before the truncate operation
# (1280K).
$ xfs_io \
-c "reflink /mnt/foobar 256K 1024K 256K" \
-c "fsync" \
/mnt/foobar
# File data before power failure:
$ od -A d -t x1 /mnt/foobar
0000000 ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab
*
0262144 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
0524288 cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd
*
0786432 ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef
*
0819200 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
1310720
<power fail>
# Mount the fs again to replay the log tree.
$ mount /dev/sdi /mnt
# File data after power failure:
$ od -A d -t x1 /mnt/foobar
0000000 ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab
*
0262144 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
0524288 cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd
*
0786432 ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef
*
0819200 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
1048576 73 73 73 73 73 73 73 73 73 73 73 73 73 73 73 73
*
1310720
The range from 1024K to 1280K should correspond to a hole but instead it
points to stale data, to the 256K extent that should not exist after the
truncate operation.
The issue does not exists when not using NO_HOLES, because for that case
we use file extent items to represent holes, these are found and copied
during the loop that iterates over extents at btrfs_clone(), and that
causes btrfs_replace_file_extents() to be called with a non-NULL
extent_info argument and therefore set the full sync runtime flag on the
inode.
So fix this by making the code that deals with a trailing hole during
cloning, at btrfs_clone(), to set the full sync flag on the inode, if the
range starts at or beyond the current i_size.
A test case for fstests will follow soon.
Backporting notes: for kernel 5.4 the change goes to ioctl.c into
btrfs_clone before the last call to btrfs_punch_hole_range.
CC: stable@vger.kernel.org # 5.4+
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-16 11:09:25 +00:00
|
|
|
/*
|
|
|
|
* When using NO_HOLES and we are cloning a range that covers
|
|
|
|
* only a hole (no extents) into a range beyond the current
|
|
|
|
* i_size, punching a hole in the target range will not create
|
|
|
|
* an extent map defining a hole, because the range starts at or
|
|
|
|
* beyond current i_size. If the file previously had an i_size
|
|
|
|
* greater than the new i_size set by this clone operation, we
|
|
|
|
* need to make sure the next fsync is a full fsync, so that it
|
|
|
|
* detects and logs a hole covering a range from the current
|
|
|
|
* i_size to the new i_size. If the clone range covers extents,
|
|
|
|
* besides a hole, then we know the full sync flag was already
|
|
|
|
* set by previous calls to btrfs_replace_file_extents() that
|
|
|
|
* replaced file extent items.
|
|
|
|
*/
|
|
|
|
if (last_dest_end >= i_size_read(inode))
|
btrfs: reset last_reflink_trans after fsyncing inode
When an inode has a last_reflink_trans matching the current transaction,
we have to take special care when logging its checksums in order to
avoid getting checksum items with overlapping ranges in a log tree,
which could result in missing checksums after log replay (more on that
in the changelogs of commit 40e046acbd2f36 ("Btrfs: fix missing data
checksums after replaying a log tree") and commit e289f03ea79bbc ("btrfs:
fix corrupt log due to concurrent fsync of inodes with shared extents")).
We also need to make sure a full fsync will copy all old file extent
items it finds in modified leaves, because they might have been copied
from some other inode.
However once we fsync an inode, we don't need to keep paying the price of
that extra special care in future fsyncs done in the same transaction,
unless the inode is used for another reflink operation or the full sync
flag is set on it (truncate, failure to allocate extent maps for holes,
and other exceptional and infrequent cases).
So after we fsync an inode reset its last_unlink_trans to zero. In case
another reflink happens, we continue to update the last_reflink_trans of
the inode, just as before. Also set last_reflink_trans to the generation
of the last transaction that modified the inode whenever we need to set
the full sync flag on the inode, just like when we need to load an inode
from disk after eviction.
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2022-02-17 12:12:06 +00:00
|
|
|
btrfs_set_inode_full_sync(BTRFS_I(inode));
|
btrfs: fix stale data exposure after cloning a hole with NO_HOLES enabled
When using the NO_HOLES feature, if we clone a file range that spans only
a hole into a range that is at or beyond the current i_size of the
destination file, we end up not setting the full sync runtime flag on the
inode. As a result, if we then fsync the destination file and have a power
failure, after log replay we can end up exposing stale data instead of
having a hole for that range.
The conditions for this to happen are the following:
1) We have a file with a size of, for example, 1280K;
2) There is a written (non-prealloc) extent for the file range from 1024K
to 1280K with a length of 256K;
3) This particular file extent layout is durably persisted, so that the
existing superblock persisted on disk points to a subvolume root where
the file has that exact file extent layout and state;
4) The file is truncated to a smaller size, to an offset lower than the
start offset of its last extent, for example to 800K. The truncate sets
the full sync runtime flag on the inode;
6) Fsync the file to log it and clear the full sync runtime flag;
7) Clone a region that covers only a hole (implicit hole due to NO_HOLES)
into the file with a destination offset that starts at or beyond the
256K file extent item we had - for example to offset 1024K;
8) Since the clone operation does not find extents in the source range,
we end up in the if branch at the bottom of btrfs_clone() where we
punch a hole for the file range starting at offset 1024K by calling
btrfs_replace_file_extents(). There we end up not setting the full
sync flag on the inode, because we don't know we are being called in
a clone context (and not fallocate's punch hole operation), and
neither do we create an extent map to represent a hole because the
requested range is beyond eof;
9) A further fsync to the file will be a fast fsync, since the clone
operation did not set the full sync flag, and therefore it relies on
modified extent maps to correctly log the file layout. But since
it does not find any extent map marking the range from 1024K (the
previous eof) to the new eof, it does not log a file extent item
for that range representing the hole;
10) After a power failure no hole for the range starting at 1024K is
punched and we end up exposing stale data from the old 256K extent.
Turning this into exact steps:
$ mkfs.btrfs -f -O no-holes /dev/sdi
$ mount /dev/sdi /mnt
# Create our test file with 3 extents of 256K and a 256K hole at offset
# 256K. The file has a size of 1280K.
$ xfs_io -f -s \
-c "pwrite -S 0xab -b 256K 0 256K" \
-c "pwrite -S 0xcd -b 256K 512K 256K" \
-c "pwrite -S 0xef -b 256K 768K 256K" \
-c "pwrite -S 0x73 -b 256K 1024K 256K" \
/mnt/sdi/foobar
# Make sure it's durably persisted. We want the last committed super
# block to point to this particular file extent layout.
sync
# Now truncate our file to a smaller size, falling within a position of
# the second extent. This sets the full sync runtime flag on the inode.
# Then fsync the file to log it and clear the full sync flag from the
# inode. The third extent is no longer part of the file and therefore
# it is not logged.
$ xfs_io -c "truncate 800K" -c "fsync" /mnt/foobar
# Now do a clone operation that only clones the hole and sets back the
# file size to match the size it had before the truncate operation
# (1280K).
$ xfs_io \
-c "reflink /mnt/foobar 256K 1024K 256K" \
-c "fsync" \
/mnt/foobar
# File data before power failure:
$ od -A d -t x1 /mnt/foobar
0000000 ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab
*
0262144 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
0524288 cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd
*
0786432 ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef
*
0819200 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
1310720
<power fail>
# Mount the fs again to replay the log tree.
$ mount /dev/sdi /mnt
# File data after power failure:
$ od -A d -t x1 /mnt/foobar
0000000 ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab ab
*
0262144 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
0524288 cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd
*
0786432 ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef ef
*
0819200 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
*
1048576 73 73 73 73 73 73 73 73 73 73 73 73 73 73 73 73
*
1310720
The range from 1024K to 1280K should correspond to a hole but instead it
points to stale data, to the 256K extent that should not exist after the
truncate operation.
The issue does not exists when not using NO_HOLES, because for that case
we use file extent items to represent holes, these are found and copied
during the loop that iterates over extents at btrfs_clone(), and that
causes btrfs_replace_file_extents() to be called with a non-NULL
extent_info argument and therefore set the full sync runtime flag on the
inode.
So fix this by making the code that deals with a trailing hole during
cloning, at btrfs_clone(), to set the full sync flag on the inode, if the
range starts at or beyond the current i_size.
A test case for fstests will follow soon.
Backporting notes: for kernel 5.4 the change goes to ioctl.c into
btrfs_clone before the last call to btrfs_punch_hole_range.
CC: stable@vger.kernel.org # 5.4+
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-16 11:09:25 +00:00
|
|
|
|
2021-02-17 13:12:47 +00:00
|
|
|
ret = btrfs_replace_file_extents(BTRFS_I(inode), path,
|
|
|
|
last_dest_end, destoff + len - 1, NULL, &trans);
|
2020-02-28 13:04:17 +00:00
|
|
|
if (ret)
|
|
|
|
goto out;
|
|
|
|
|
|
|
|
ret = clone_finish_inode_update(trans, inode, destoff + len,
|
|
|
|
destoff, olen, no_time_update);
|
|
|
|
}
|
|
|
|
|
|
|
|
out:
|
|
|
|
btrfs_free_path(path);
|
|
|
|
kvfree(buf);
|
btrfs: fix deadlock when cloning inline extent and low on free metadata space
When cloning an inline extent there are cases where we can not just copy
the inline extent from the source range to the target range (e.g. when the
target range starts at an offset greater than zero). In such cases we copy
the inline extent's data into a page of the destination inode and then
dirty that page. However, after that we will need to start a transaction
for each processed extent and, if we are ever low on available metadata
space, we may need to flush existing delalloc for all dirty inodes in an
attempt to release metadata space - if that happens we may deadlock:
* the async reclaim task queued a delalloc work to flush delalloc for
the destination inode of the clone operation;
* the task executing that delalloc work gets blocked waiting for the
range with the dirty page to be unlocked, which is currently locked
by the task doing the clone operation;
* the async reclaim task blocks waiting for the delalloc work to complete;
* the cloning task is waiting on the waitqueue of its reservation ticket
while holding the range with the dirty page locked in the inode's
io_tree;
* if metadata space is not released by some other task (like delalloc for
some other inode completing for example), the clone task waits forever
and as a consequence the delalloc work and async reclaim tasks will hang
forever as well. Releasing more space on the other hand may require
starting a transaction, which will hang as well when trying to reserve
metadata space, resulting in a deadlock between all these tasks.
When this happens, traces like the following show up in dmesg/syslog:
[87452.323003] INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
[87452.323644] Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
[87452.324248] "echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
[87452.324852] task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
[87452.325520] Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
[87452.326136] Call Trace:
[87452.326737] __schedule+0x5d1/0xcf0
[87452.327390] schedule+0x45/0xe0
[87452.328174] lock_extent_bits+0x1e6/0x2d0 [btrfs]
[87452.328894] ? finish_wait+0x90/0x90
[87452.329474] btrfs_invalidatepage+0x32c/0x390 [btrfs]
[87452.330133] ? __mod_memcg_state+0x8e/0x160
[87452.330738] __extent_writepage+0x2d4/0x400 [btrfs]
[87452.331405] extent_write_cache_pages+0x2b2/0x500 [btrfs]
[87452.332007] ? lock_release+0x20e/0x4c0
[87452.332557] ? trace_hardirqs_on+0x1b/0xf0
[87452.333127] extent_writepages+0x43/0x90 [btrfs]
[87452.333653] ? lock_acquire+0x1a3/0x490
[87452.334177] do_writepages+0x43/0xe0
[87452.334699] ? __filemap_fdatawrite_range+0xa4/0x100
[87452.335720] __filemap_fdatawrite_range+0xc5/0x100
[87452.336500] btrfs_run_delalloc_work+0x17/0x40 [btrfs]
[87452.337216] btrfs_work_helper+0xf1/0x600 [btrfs]
[87452.337838] process_one_work+0x24e/0x5e0
[87452.338437] worker_thread+0x50/0x3b0
[87452.339137] ? process_one_work+0x5e0/0x5e0
[87452.339884] kthread+0x153/0x170
[87452.340507] ? kthread_mod_delayed_work+0xc0/0xc0
[87452.341153] ret_from_fork+0x22/0x30
[87452.341806] INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
[87452.342487] Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
[87452.343274] "echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
[87452.344049] task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
[87452.344974] Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
[87452.345655] Call Trace:
[87452.346305] __schedule+0x5d1/0xcf0
[87452.346947] ? kvm_clock_read+0x14/0x30
[87452.347676] ? wait_for_completion+0x81/0x110
[87452.348389] schedule+0x45/0xe0
[87452.349077] schedule_timeout+0x30c/0x580
[87452.349718] ? _raw_spin_unlock_irqrestore+0x3c/0x60
[87452.350340] ? lock_acquire+0x1a3/0x490
[87452.351006] ? try_to_wake_up+0x7a/0xa20
[87452.351541] ? lock_release+0x20e/0x4c0
[87452.352040] ? lock_acquired+0x199/0x490
[87452.352517] ? wait_for_completion+0x81/0x110
[87452.353000] wait_for_completion+0xab/0x110
[87452.353490] start_delalloc_inodes+0x2af/0x390 [btrfs]
[87452.353973] btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
[87452.354455] flush_space+0x24f/0x660 [btrfs]
[87452.355063] btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
[87452.355565] process_one_work+0x24e/0x5e0
[87452.356024] worker_thread+0x20f/0x3b0
[87452.356487] ? process_one_work+0x5e0/0x5e0
[87452.356973] kthread+0x153/0x170
[87452.357434] ? kthread_mod_delayed_work+0xc0/0xc0
[87452.357880] ret_from_fork+0x22/0x30
(...)
< stack traces of several tasks waiting for the locks of the inodes of the
clone operation >
(...)
[92867.444138] RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000246 ORIG_RAX: 0000000000000052
[92867.444624] RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73f97
[92867.445116] RDX: 0000000000000000 RSI: 0000560fbd5d7a40 RDI: 0000560fbd5d8960
[92867.445595] RBP: 00007ffc3371beb0 R08: 0000000000000001 R09: 0000000000000003
[92867.446070] R10: 00007ffc3371b996 R11: 0000000000000246 R12: 0000000000000000
[92867.446820] R13: 000000000000001f R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
[92867.447361] task:fsstress state:D stack: 0 pid:2508238 ppid:2508153 flags:0x00004000
[92867.447920] Call Trace:
[92867.448435] __schedule+0x5d1/0xcf0
[92867.448934] ? _raw_spin_unlock_irqrestore+0x3c/0x60
[92867.449423] schedule+0x45/0xe0
[92867.449916] __reserve_bytes+0x4a4/0xb10 [btrfs]
[92867.450576] ? finish_wait+0x90/0x90
[92867.451202] btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
[92867.451815] btrfs_block_rsv_add+0x1f/0x50 [btrfs]
[92867.452412] start_transaction+0x2d1/0x760 [btrfs]
[92867.453216] clone_copy_inline_extent+0x333/0x490 [btrfs]
[92867.453848] ? lock_release+0x20e/0x4c0
[92867.454539] ? btrfs_search_slot+0x9a7/0xc30 [btrfs]
[92867.455218] btrfs_clone+0x569/0x7e0 [btrfs]
[92867.455952] btrfs_clone_files+0xf6/0x150 [btrfs]
[92867.456588] btrfs_remap_file_range+0x324/0x3d0 [btrfs]
[92867.457213] do_clone_file_range+0xd4/0x1f0
[92867.457828] vfs_clone_file_range+0x4d/0x230
[92867.458355] ? lock_release+0x20e/0x4c0
[92867.458890] ioctl_file_clone+0x8f/0xc0
[92867.459377] do_vfs_ioctl+0x342/0x750
[92867.459913] __x64_sys_ioctl+0x62/0xb0
[92867.460377] do_syscall_64+0x33/0x80
[92867.460842] entry_SYSCALL_64_after_hwframe+0x44/0xa9
(...)
< stack traces of more tasks blocked on metadata reservation like the clone
task above, because the async reclaim task has deadlocked >
(...)
Another thing to notice is that the worker task that is deadlocked when
trying to flush the destination inode of the clone operation is at
btrfs_invalidatepage(). This is simply because the clone operation has a
destination offset greater than the i_size and we only update the i_size
of the destination file after cloning an extent (just like we do in the
buffered write path).
Since the async reclaim path uses btrfs_start_delalloc_roots() to trigger
the flushing of delalloc for all inodes that have delalloc, add a runtime
flag to an inode to signal it should not be flushed, and for inodes with
that flag set, start_delalloc_inodes() will simply skip them. When the
cloning code needs to dirty a page to copy an inline extent, set that flag
on the inode and then clear it when the clone operation finishes.
This could be sporadically triggered with test case generic/269 from
fstests, which exercises many fsstress processes running in parallel with
several dd processes filling up the entire filesystem.
CC: stable@vger.kernel.org # 5.9+
Fixes: 05a5a7621ce6 ("Btrfs: implement full reflink support for inline extents")
Reviewed-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: Filipe Manana <fdmanana@suse.com>
Reviewed-by: David Sterba <dsterba@suse.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2020-12-02 11:55:58 +00:00
|
|
|
clear_bit(BTRFS_INODE_NO_DELALLOC_FLUSH, &BTRFS_I(inode)->runtime_flags);
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
static void btrfs_double_extent_unlock(struct inode *inode1, u64 loff1,
|
|
|
|
struct inode *inode2, u64 loff2, u64 len)
|
|
|
|
{
|
2022-09-09 21:53:43 +00:00
|
|
|
unlock_extent(&BTRFS_I(inode1)->io_tree, loff1, loff1 + len - 1, NULL);
|
|
|
|
unlock_extent(&BTRFS_I(inode2)->io_tree, loff2, loff2 + len - 1, NULL);
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
|
|
|
static void btrfs_double_extent_lock(struct inode *inode1, u64 loff1,
|
|
|
|
struct inode *inode2, u64 loff2, u64 len)
|
|
|
|
{
|
2022-03-15 15:22:41 +00:00
|
|
|
u64 range1_end = loff1 + len - 1;
|
|
|
|
u64 range2_end = loff2 + len - 1;
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
if (inode1 < inode2) {
|
|
|
|
swap(inode1, inode2);
|
|
|
|
swap(loff1, loff2);
|
2022-03-15 15:22:41 +00:00
|
|
|
swap(range1_end, range2_end);
|
2020-02-28 13:04:17 +00:00
|
|
|
} else if (inode1 == inode2 && loff2 < loff1) {
|
|
|
|
swap(loff1, loff2);
|
2022-03-15 15:22:41 +00:00
|
|
|
swap(range1_end, range2_end);
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
2022-03-15 15:22:41 +00:00
|
|
|
|
2022-09-09 21:53:43 +00:00
|
|
|
lock_extent(&BTRFS_I(inode1)->io_tree, loff1, range1_end, NULL);
|
|
|
|
lock_extent(&BTRFS_I(inode2)->io_tree, loff2, range2_end, NULL);
|
2022-03-15 15:22:41 +00:00
|
|
|
|
|
|
|
btrfs_assert_inode_range_clean(BTRFS_I(inode1), loff1, range1_end);
|
|
|
|
btrfs_assert_inode_range_clean(BTRFS_I(inode2), loff2, range2_end);
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
static void btrfs_double_mmap_lock(struct inode *inode1, struct inode *inode2)
|
|
|
|
{
|
|
|
|
if (inode1 < inode2)
|
|
|
|
swap(inode1, inode2);
|
|
|
|
down_write(&BTRFS_I(inode1)->i_mmap_lock);
|
|
|
|
down_write_nested(&BTRFS_I(inode2)->i_mmap_lock, SINGLE_DEPTH_NESTING);
|
|
|
|
}
|
|
|
|
|
|
|
|
static void btrfs_double_mmap_unlock(struct inode *inode1, struct inode *inode2)
|
|
|
|
{
|
|
|
|
up_write(&BTRFS_I(inode1)->i_mmap_lock);
|
|
|
|
up_write(&BTRFS_I(inode2)->i_mmap_lock);
|
|
|
|
}
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
static int btrfs_extent_same_range(struct inode *src, u64 loff, u64 len,
|
|
|
|
struct inode *dst, u64 dst_loff)
|
|
|
|
{
|
2022-05-31 15:06:34 +00:00
|
|
|
struct btrfs_fs_info *fs_info = BTRFS_I(src)->root->fs_info;
|
2024-01-16 16:33:20 +00:00
|
|
|
const u64 bs = fs_info->sectorsize;
|
2020-02-28 13:04:17 +00:00
|
|
|
int ret;
|
|
|
|
|
|
|
|
/*
|
2022-03-24 01:29:04 +00:00
|
|
|
* Lock destination range to serialize with concurrent readahead() and
|
2020-02-28 13:04:17 +00:00
|
|
|
* source range to serialize with relocation.
|
|
|
|
*/
|
|
|
|
btrfs_double_extent_lock(src, loff, dst, dst_loff, len);
|
|
|
|
ret = btrfs_clone(src, dst, loff, len, ALIGN(len, bs), dst_loff, 1);
|
|
|
|
btrfs_double_extent_unlock(src, loff, dst, dst_loff, len);
|
|
|
|
|
2022-05-31 15:06:34 +00:00
|
|
|
btrfs_btree_balance_dirty(fs_info);
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
static int btrfs_extent_same(struct inode *src, u64 loff, u64 olen,
|
|
|
|
struct inode *dst, u64 dst_loff)
|
|
|
|
{
|
2021-08-26 14:44:36 +00:00
|
|
|
int ret = 0;
|
2020-02-28 13:04:17 +00:00
|
|
|
u64 i, tail_len, chunk_count;
|
|
|
|
struct btrfs_root *root_dst = BTRFS_I(dst)->root;
|
|
|
|
|
|
|
|
spin_lock(&root_dst->root_item_lock);
|
|
|
|
if (root_dst->send_in_progress) {
|
|
|
|
btrfs_warn_rl(root_dst->fs_info,
|
|
|
|
"cannot deduplicate to root %llu while send operations are using it (%d in progress)",
|
|
|
|
root_dst->root_key.objectid,
|
|
|
|
root_dst->send_in_progress);
|
|
|
|
spin_unlock(&root_dst->root_item_lock);
|
|
|
|
return -EAGAIN;
|
|
|
|
}
|
|
|
|
root_dst->dedupe_in_progress++;
|
|
|
|
spin_unlock(&root_dst->root_item_lock);
|
|
|
|
|
|
|
|
tail_len = olen % BTRFS_MAX_DEDUPE_LEN;
|
|
|
|
chunk_count = div_u64(olen, BTRFS_MAX_DEDUPE_LEN);
|
|
|
|
|
|
|
|
for (i = 0; i < chunk_count; i++) {
|
|
|
|
ret = btrfs_extent_same_range(src, loff, BTRFS_MAX_DEDUPE_LEN,
|
|
|
|
dst, dst_loff);
|
|
|
|
if (ret)
|
|
|
|
goto out;
|
|
|
|
|
|
|
|
loff += BTRFS_MAX_DEDUPE_LEN;
|
|
|
|
dst_loff += BTRFS_MAX_DEDUPE_LEN;
|
|
|
|
}
|
|
|
|
|
|
|
|
if (tail_len > 0)
|
|
|
|
ret = btrfs_extent_same_range(src, loff, tail_len, dst, dst_loff);
|
|
|
|
out:
|
|
|
|
spin_lock(&root_dst->root_item_lock);
|
|
|
|
root_dst->dedupe_in_progress--;
|
|
|
|
spin_unlock(&root_dst->root_item_lock);
|
|
|
|
|
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
static noinline int btrfs_clone_files(struct file *file, struct file *file_src,
|
|
|
|
u64 off, u64 olen, u64 destoff)
|
|
|
|
{
|
|
|
|
struct inode *inode = file_inode(file);
|
|
|
|
struct inode *src = file_inode(file_src);
|
2023-09-14 14:45:41 +00:00
|
|
|
struct btrfs_fs_info *fs_info = inode_to_fs_info(inode);
|
2020-02-28 13:04:17 +00:00
|
|
|
int ret;
|
2020-02-28 13:04:19 +00:00
|
|
|
int wb_ret;
|
2020-02-28 13:04:17 +00:00
|
|
|
u64 len = olen;
|
2024-01-16 16:33:20 +00:00
|
|
|
u64 bs = fs_info->sectorsize;
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
/*
|
|
|
|
* VFS's generic_remap_file_range_prep() protects us from cloning the
|
|
|
|
* eof block into the middle of a file, which would result in corruption
|
|
|
|
* if the file size is not blocksize aligned. So we don't need to check
|
|
|
|
* for that case here.
|
|
|
|
*/
|
|
|
|
if (off + len == src->i_size)
|
|
|
|
len = ALIGN(src->i_size, bs) - off;
|
|
|
|
|
|
|
|
if (destoff > inode->i_size) {
|
|
|
|
const u64 wb_start = ALIGN_DOWN(inode->i_size, bs);
|
|
|
|
|
2020-11-02 14:49:04 +00:00
|
|
|
ret = btrfs_cont_expand(BTRFS_I(inode), inode->i_size, destoff);
|
2020-02-28 13:04:17 +00:00
|
|
|
if (ret)
|
|
|
|
return ret;
|
|
|
|
/*
|
|
|
|
* We may have truncated the last block if the inode's size is
|
|
|
|
* not sector size aligned, so we need to wait for writeback to
|
|
|
|
* complete before proceeding further, otherwise we can race
|
|
|
|
* with cloning and attempt to increment a reference to an
|
|
|
|
* extent that no longer exists (writeback completed right after
|
|
|
|
* we found the previous extent covering eof and before we
|
|
|
|
* attempted to increment its reference count).
|
|
|
|
*/
|
|
|
|
ret = btrfs_wait_ordered_range(inode, wb_start,
|
|
|
|
destoff - wb_start);
|
|
|
|
if (ret)
|
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
/*
|
2022-03-24 01:29:04 +00:00
|
|
|
* Lock destination range to serialize with concurrent readahead() and
|
2020-02-28 13:04:17 +00:00
|
|
|
* source range to serialize with relocation.
|
|
|
|
*/
|
|
|
|
btrfs_double_extent_lock(src, off, inode, destoff, len);
|
|
|
|
ret = btrfs_clone(src, inode, off, olen, len, destoff, 0);
|
|
|
|
btrfs_double_extent_unlock(src, off, inode, destoff, len);
|
2020-02-28 13:04:19 +00:00
|
|
|
|
|
|
|
/*
|
|
|
|
* We may have copied an inline extent into a page of the destination
|
|
|
|
* range, so wait for writeback to complete before truncating pages
|
|
|
|
* from the page cache. This is a rare case.
|
|
|
|
*/
|
|
|
|
wb_ret = btrfs_wait_ordered_range(inode, destoff, len);
|
|
|
|
ret = ret ? ret : wb_ret;
|
2020-02-28 13:04:17 +00:00
|
|
|
/*
|
|
|
|
* Truncate page cache pages so that future reads will see the cloned
|
|
|
|
* data immediately and not the previous data.
|
|
|
|
*/
|
|
|
|
truncate_inode_pages_range(&inode->i_data,
|
|
|
|
round_down(destoff, PAGE_SIZE),
|
|
|
|
round_up(destoff + len, PAGE_SIZE) - 1);
|
|
|
|
|
2022-05-31 15:06:34 +00:00
|
|
|
btrfs_btree_balance_dirty(fs_info);
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
return ret;
|
|
|
|
}
|
|
|
|
|
|
|
|
static int btrfs_remap_file_range_prep(struct file *file_in, loff_t pos_in,
|
|
|
|
struct file *file_out, loff_t pos_out,
|
|
|
|
loff_t *len, unsigned int remap_flags)
|
|
|
|
{
|
|
|
|
struct inode *inode_in = file_inode(file_in);
|
|
|
|
struct inode *inode_out = file_inode(file_out);
|
2024-01-16 16:33:20 +00:00
|
|
|
u64 bs = BTRFS_I(inode_out)->root->fs_info->sectorsize;
|
2020-02-28 13:04:17 +00:00
|
|
|
u64 wb_len;
|
|
|
|
int ret;
|
|
|
|
|
|
|
|
if (!(remap_flags & REMAP_FILE_DEDUP)) {
|
|
|
|
struct btrfs_root *root_out = BTRFS_I(inode_out)->root;
|
|
|
|
|
|
|
|
if (btrfs_root_readonly(root_out))
|
|
|
|
return -EROFS;
|
|
|
|
|
2022-02-18 14:38:13 +00:00
|
|
|
ASSERT(inode_in->i_sb == inode_out->i_sb);
|
2020-02-28 13:04:17 +00:00
|
|
|
}
|
|
|
|
|
|
|
|
/* Don't make the dst file partly checksummed */
|
|
|
|
if ((BTRFS_I(inode_in)->flags & BTRFS_INODE_NODATASUM) !=
|
|
|
|
(BTRFS_I(inode_out)->flags & BTRFS_INODE_NODATASUM)) {
|
|
|
|
return -EINVAL;
|
|
|
|
}
|
|
|
|
|
|
|
|
/*
|
|
|
|
* Now that the inodes are locked, we need to start writeback ourselves
|
|
|
|
* and can not rely on the writeback from the VFS's generic helper
|
|
|
|
* generic_remap_file_range_prep() because:
|
|
|
|
*
|
|
|
|
* 1) For compression we must call filemap_fdatawrite_range() range
|
|
|
|
* twice (btrfs_fdatawrite_range() does it for us), and the generic
|
|
|
|
* helper only calls it once;
|
|
|
|
*
|
|
|
|
* 2) filemap_fdatawrite_range(), called by the generic helper only
|
|
|
|
* waits for the writeback to complete, i.e. for IO to be done, and
|
|
|
|
* not for the ordered extents to complete. We need to wait for them
|
|
|
|
* to complete so that new file extent items are in the fs tree.
|
|
|
|
*/
|
|
|
|
if (*len == 0 && !(remap_flags & REMAP_FILE_DEDUP))
|
|
|
|
wb_len = ALIGN(inode_in->i_size, bs) - ALIGN_DOWN(pos_in, bs);
|
|
|
|
else
|
|
|
|
wb_len = ALIGN(*len, bs);
|
|
|
|
|
|
|
|
/*
|
|
|
|
* Workaround to make sure NOCOW buffered write reach disk as NOCOW.
|
|
|
|
*
|
|
|
|
* Btrfs' back references do not have a block level granularity, they
|
|
|
|
* work at the whole extent level.
|
|
|
|
* NOCOW buffered write without data space reserved may not be able
|
|
|
|
* to fall back to CoW due to lack of data space, thus could cause
|
|
|
|
* data loss.
|
|
|
|
*
|
|
|
|
* Here we take a shortcut by flushing the whole inode, so that all
|
|
|
|
* nocow write should reach disk as nocow before we increase the
|
|
|
|
* reference of the extent. We could do better by only flushing NOCOW
|
|
|
|
* data, but that needs extra accounting.
|
|
|
|
*
|
|
|
|
* Also we don't need to check ASYNC_EXTENT, as async extent will be
|
|
|
|
* CoWed anyway, not affecting nocow part.
|
|
|
|
*/
|
|
|
|
ret = filemap_flush(inode_in->i_mapping);
|
|
|
|
if (ret < 0)
|
|
|
|
return ret;
|
|
|
|
|
|
|
|
ret = btrfs_wait_ordered_range(inode_in, ALIGN_DOWN(pos_in, bs),
|
|
|
|
wb_len);
|
|
|
|
if (ret < 0)
|
|
|
|
return ret;
|
|
|
|
ret = btrfs_wait_ordered_range(inode_out, ALIGN_DOWN(pos_out, bs),
|
|
|
|
wb_len);
|
|
|
|
if (ret < 0)
|
|
|
|
return ret;
|
|
|
|
|
|
|
|
return generic_remap_file_range_prep(file_in, pos_in, file_out, pos_out,
|
|
|
|
len, remap_flags);
|
|
|
|
}
|
|
|
|
|
2021-03-23 18:39:49 +00:00
|
|
|
static bool file_sync_write(const struct file *file)
|
|
|
|
{
|
|
|
|
if (file->f_flags & (__O_SYNC | O_DSYNC))
|
|
|
|
return true;
|
|
|
|
if (IS_SYNC(file_inode(file)))
|
|
|
|
return true;
|
|
|
|
|
|
|
|
return false;
|
|
|
|
}
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
loff_t btrfs_remap_file_range(struct file *src_file, loff_t off,
|
|
|
|
struct file *dst_file, loff_t destoff, loff_t len,
|
|
|
|
unsigned int remap_flags)
|
|
|
|
{
|
|
|
|
struct inode *src_inode = file_inode(src_file);
|
|
|
|
struct inode *dst_inode = file_inode(dst_file);
|
|
|
|
bool same_inode = dst_inode == src_inode;
|
|
|
|
int ret;
|
|
|
|
|
|
|
|
if (remap_flags & ~(REMAP_FILE_DEDUP | REMAP_FILE_ADVISORY))
|
|
|
|
return -EINVAL;
|
|
|
|
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
if (same_inode) {
|
2022-10-27 00:41:32 +00:00
|
|
|
btrfs_inode_lock(BTRFS_I(src_inode), BTRFS_ILOCK_MMAP);
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
} else {
|
2020-02-28 13:04:17 +00:00
|
|
|
lock_two_nondirectories(src_inode, dst_inode);
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
btrfs_double_mmap_lock(src_inode, dst_inode);
|
|
|
|
}
|
2020-02-28 13:04:17 +00:00
|
|
|
|
|
|
|
ret = btrfs_remap_file_range_prep(src_file, off, dst_file, destoff,
|
|
|
|
&len, remap_flags);
|
|
|
|
if (ret < 0 || len == 0)
|
|
|
|
goto out_unlock;
|
|
|
|
|
|
|
|
if (remap_flags & REMAP_FILE_DEDUP)
|
|
|
|
ret = btrfs_extent_same(src_inode, off, len, dst_inode, destoff);
|
|
|
|
else
|
|
|
|
ret = btrfs_clone_files(dst_file, src_file, off, len, destoff);
|
|
|
|
|
|
|
|
out_unlock:
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
if (same_inode) {
|
2022-10-27 00:41:32 +00:00
|
|
|
btrfs_inode_unlock(BTRFS_I(src_inode), BTRFS_ILOCK_MMAP);
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
|
|
} else {
|
|
|
|
btrfs_double_mmap_unlock(src_inode, dst_inode);
|
2020-02-28 13:04:17 +00:00
|
|
|
unlock_two_nondirectories(src_inode, dst_inode);
|
btrfs: exclude mmaps while doing remap
Darrick reported a potential issue to me where we could allow mmap
writes after validating a page range matched in the case of dedupe.
Generally we rely on lock page -> lock extent with the ordered flush to
protect us, but this is done after we check the pages because we use the
generic helpers, so we could modify the page in between doing the check
and locking the range.
There also exists a deadlock, as described by Filipe
"""
When cloning a file range, we lock the inodes, flush any delalloc within
the respective file ranges, wait for any ordered extents and then lock the
file ranges in both inodes. This means that right after we flush delalloc
and before we lock the file ranges, memory mapped writes can come in and
dirty pages in the file ranges of the clone operation.
Most of the time this is harmless and causes no problems. However, if we
are low on available metadata space, we can later end up in a deadlock
when starting a transaction to replace file extent items. This happens if
when allocating metadata space for the transaction, we need to wait for
the async reclaim thread to release space and the reclaim thread needs to
flush delalloc for the inode that got the memory mapped write and has its
range locked by the clone task.
Basically what happens is the following:
1) A clone operation locks inodes A and B, flushes delalloc for both
inodes in the respective file ranges and waits for any ordered extents
in those ranges to complete;
2) Before the clone task locks the file ranges, another task does a
memory mapped write (which does not lock the inode) for one of the
inodes of the clone operation. So now we have a dirty page in one of
the ranges used by the clone operation;
3) The clone operation locks the file ranges for inodes A and B;
4) Later, when iterating over the file extents of inode A, the clone
task attempts to start a transaction. There's not enough available
free metadata space, so the async reclaim task is started (if not
running already) and we wait for someone to wake us up on our
reservation ticket;
5) The async reclaim task is not able to release space by any other
means and decides to flush delalloc for the inode of the clone
operation;
6) The workqueue job used to flush the inode blocks when starting
delalloc for the inode, since the file range is currently locked by
the clone task;
7) But the clone task is waiting on its reservation ticket and the async
reclaim task is waiting on the flush job to complete, which can't
progress since the clone task has the file range locked. So unless
some other task is able to release space, for example an ordered
extent for some other inode completes, we have a deadlock between all
these tasks;
When this happens stack traces like the following show up in dmesg/syslog:
INFO: task kworker/u16:11:1810830 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:11 state:D stack: 0 pid:1810830 ppid: 2 flags:0x00004000
Workqueue: btrfs-flush_delalloc btrfs_work_helper [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
schedule+0x45/0xe0
lock_extent_bits+0x1e6/0x2d0 [btrfs]
? finish_wait+0x90/0x90
btrfs_invalidatepage+0x32c/0x390 [btrfs]
? __mod_memcg_state+0x8e/0x160
__extent_writepage+0x2d4/0x400 [btrfs]
extent_write_cache_pages+0x2b2/0x500 [btrfs]
? lock_release+0x20e/0x4c0
? trace_hardirqs_on+0x1b/0xf0
extent_writepages+0x43/0x90 [btrfs]
? lock_acquire+0x1a3/0x490
do_writepages+0x43/0xe0
? __filemap_fdatawrite_range+0xa4/0x100
__filemap_fdatawrite_range+0xc5/0x100
btrfs_run_delalloc_work+0x17/0x40 [btrfs]
btrfs_work_helper+0xf1/0x600 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x50/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
INFO: task kworker/u16:1:2426217 blocked for more than 120 seconds.
Tainted: G B W 5.10.0-rc4-btrfs-next-73 #1
"echo 0 > /proc/sys/kernel/hung_task_timeout_secs" disables this message.
task:kworker/u16:1 state:D stack: 0 pid:2426217 ppid: 2 flags:0x00004000
Workqueue: events_unbound btrfs_async_reclaim_metadata_space [btrfs]
Call Trace:
__schedule+0x5d1/0xcf0
? kvm_clock_read+0x14/0x30
? wait_for_completion+0x81/0x110
schedule+0x45/0xe0
schedule_timeout+0x30c/0x580
? _raw_spin_unlock_irqrestore+0x3c/0x60
? lock_acquire+0x1a3/0x490
? try_to_wake_up+0x7a/0xa20
? lock_release+0x20e/0x4c0
? lock_acquired+0x199/0x490
? wait_for_completion+0x81/0x110
wait_for_completion+0xab/0x110
start_delalloc_inodes+0x2af/0x390 [btrfs]
btrfs_start_delalloc_roots+0x12d/0x250 [btrfs]
flush_space+0x24f/0x660 [btrfs]
btrfs_async_reclaim_metadata_space+0x1bb/0x480 [btrfs]
process_one_work+0x24e/0x5e0
worker_thread+0x20f/0x3b0
? process_one_work+0x5e0/0x5e0
kthread+0x153/0x170
? kthread_mod_delayed_work+0xc0/0xc0
ret_from_fork+0x22/0x30
(...)
several other tasks blocked on inode locks held by the clone task below
(...)
RIP: 0033:0x7f61efe73fff
Code: Unable to access opcode bytes at RIP 0x7f61efe73fd5.
RSP: 002b:00007ffc3371bbe8 EFLAGS: 00000202 ORIG_RAX: 000000000000013c
RAX: ffffffffffffffda RBX: 00007ffc3371bea0 RCX: 00007f61efe73fff
RDX: 00000000ffffff9c RSI: 0000560fbd604690 RDI: 00000000ffffff9c
RBP: 00007ffc3371beb0 R08: 0000000000000002 R09: 0000560fbd5d75f0
R10: 0000560fbd5d81f0 R11: 0000000000000202 R12: 0000000000000002
R13: 000000000000000b R14: 00007ffc3371bea0 R15: 00007ffc3371beb0
task: fdm-stress state:D stack: 0 pid:2508234 ppid:2508153 flags:0x00004000
Call Trace:
__schedule+0x5d1/0xcf0
? _raw_spin_unlock_irqrestore+0x3c/0x60
schedule+0x45/0xe0
__reserve_bytes+0x4a4/0xb10 [btrfs]
? finish_wait+0x90/0x90
btrfs_reserve_metadata_bytes+0x29/0x190 [btrfs]
btrfs_block_rsv_add+0x1f/0x50 [btrfs]
start_transaction+0x2d1/0x760 [btrfs]
btrfs_replace_file_extents+0x120/0x930 [btrfs]
? lock_release+0x20e/0x4c0
btrfs_clone+0x3e4/0x7e0 [btrfs]
? btrfs_lookup_first_ordered_extent+0x8e/0x100 [btrfs]
btrfs_clone_files+0xf6/0x150 [btrfs]
btrfs_remap_file_range+0x324/0x3d0 [btrfs]
do_clone_file_range+0xd4/0x1f0
vfs_clone_file_range+0x4d/0x230
? lock_release+0x20e/0x4c0
ioctl_file_clone+0x8f/0xc0
do_vfs_ioctl+0x342/0x750
__x64_sys_ioctl+0x62/0xb0
do_syscall_64+0x33/0x80
entry_SYSCALL_64_after_hwframe+0x44/0xa9
"""
Fix both of these issues by excluding mmaps from happening we are doing
any sort of remap, which prevents this race completely.
Reviewed-by: Filipe Manana <fdmanana@suse.com>
Signed-off-by: Josef Bacik <josef@toxicpanda.com>
Signed-off-by: David Sterba <dsterba@suse.com>
2021-02-10 22:14:35 +00:00
|
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}
|
2020-02-28 13:04:17 +00:00
|
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|
|
2021-03-23 18:39:49 +00:00
|
|
|
/*
|
|
|
|
* If either the source or the destination file was opened with O_SYNC,
|
|
|
|
* O_DSYNC or has the S_SYNC attribute, fsync both the destination and
|
|
|
|
* source files/ranges, so that after a successful return (0) followed
|
|
|
|
* by a power failure results in the reflinked data to be readable from
|
|
|
|
* both files/ranges.
|
|
|
|
*/
|
|
|
|
if (ret == 0 && len > 0 &&
|
|
|
|
(file_sync_write(src_file) || file_sync_write(dst_file))) {
|
|
|
|
ret = btrfs_sync_file(src_file, off, off + len - 1, 0);
|
|
|
|
if (ret == 0)
|
|
|
|
ret = btrfs_sync_file(dst_file, destoff,
|
|
|
|
destoff + len - 1, 0);
|
|
|
|
}
|
|
|
|
|
2020-02-28 13:04:17 +00:00
|
|
|
return ret < 0 ? ret : len;
|
|
|
|
}
|