David Sterba 於 2018-05-23 00:28 寫到:
On Fri, Apr 27, 2018 at 03:05:24PM +0800, Ethan Lien wrote:
We should balance dirty metadata pages at the end of
btrfs_finish_ordered_io, since a small, unmergeable random write can
potentially produce dirty metadata which is multiple times larger than
the data itself. For example, a small, unmergeable 4KiB write may
produce:
16KiB dirty leaf (and possibly 16KiB dirty node) in subvolume tree
16KiB dirty leaf (and possibly 16KiB dirty node) in checksum tree
16KiB dirty leaf (and possibly 16KiB dirty node) in extent tree
Although we do call balance dirty pages in write side, but in the
buffered write path, most metadata are dirtied only after we reach the
dirty background limit (which by far onlys counts dirty data pages)
and
wakeup the flusher thread. If there are many small, unmergeable random
writes spread in a large btree, we'll find a burst of dirty pages
exceeds the dirty_bytes limit after we wakeup the flusher thread -
which
is not what we expect. In our machine, it caused out-of-memory problem
since a page cannot be dropped if it is marked dirty.
Someone may worry about we may sleep in btrfs_btree_balance_dirty(),
but
since we do btrfs_finish_ordered_io in a separate worker, it will not
stop the flusher consuming dirty pages. Also, we use different worker
for
metadata writeback endio, sleep in btrfs_finish_ordered_io help us
throttle the size of dirty metadata pages.
The described scenario sounds interesting. Do you have some scripted
steps to reproduce it?
It needs some time to reproduce the problem. In our case,
1. Create 4 subvolumes.
2. Run fio on each subvolume:
[global]
direct=0
rw=randwrite
ioengine=libaio
bs=4k
iodepth=16
numjobs=1
group_reporting
size=128G
runtime=1800
norandommap
time_based
randrepeat=0
3. Take snapshot on each subvolume and repeat fio on existing files.
4. Repeat step 2&3 until we get really big btrees.
In our case, by observing btrfs_root_item->bytes_used, we have 2GiB of
metadata in each subvolume tree and 12GiB of metadata in extent tree.
5. Stop all fio, take snapshot again, and wait until all delayed work is
completed.
6. Start all fio. Few seconds later we hit OOM when the flusher starts
to work.
It can be reproduced even when using nocow write.
btrfs_btree_balance_dirty detects congestion and can skip the balancing
eventually, so the case when it actually does something and waits is
the
point where things can go bad. From the last paragraph, it is clear
that
you have considered that, that's good.
Have you also considered calling __btrfs_btree_balance_dirty with
flush_delayed=0 ? This would avoid the waiting and I'm not sure if it's
really required here to get out of the situation.
Yes, btrfs_btree_balance_dirty_nodelay seems to be a better choice, I'll
add it to the v2 patch, thanks.
Anyway, I'll add the patch to for-next for more testing.
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