[PATCH] [RFC] xfs: wire up aio_fsync method
Jens Axboe
axboe at kernel.dk
Mon Jun 16 14:30:42 CDT 2014
On 06/16/2014 01:19 AM, Dave Chinner wrote:
> On Sun, Jun 15, 2014 at 08:58:46PM -0600, Jens Axboe wrote:
>> On 2014-06-15 20:00, Dave Chinner wrote:
>>> On Mon, Jun 16, 2014 at 08:33:23AM +1000, Dave Chinner wrote:
>>>> On Fri, Jun 13, 2014 at 09:23:52AM -0700, Christoph Hellwig wrote:
>>>>> On Fri, Jun 13, 2014 at 09:44:41AM +1000, Dave Chinner wrote:
>>>>>> On Thu, Jun 12, 2014 at 07:13:29AM -0700, Christoph Hellwig wrote:
>>>>>>> There doesn't really seem anything XFS specific here, so instead
>>>>>>> of wiring up ->aio_fsync I'd implement IOCB_CMD_FSYNC in fs/aio.c
>>>>>>> based on the workqueue and ->fsync.
>>>>>>
>>>>>> I really don't know whether the other ->fsync methods in other
>>>>>> filesystems can stand alone like that. I also don't have the
>>>>>> time to test that it works properly on all filesystems right now.
>>>>>
>>>>> Of course they can, as shown by various calls to vfs_fsync_range that
>>>>> is nothing but a small wrapper around ->fsync.
>>>>
>>>> Sure, but that's not getting 10,000 concurrent callers, is it? And
>>>> some fsync methods require journal credits, and others serialise
>>>> completely, and so on.
>>>>
>>>> Besides, putting an *unbound, highly concurrent* aio queue into the
>>>> kernel for an operation that can serialise the entire filesystem
>>>> seems like a pretty nasty user-level DOS vector to me.
>>>
>>> FWIW, the non-linear system CPU overhead of a fs_mark test I've been
>>> running isn't anything related to XFS. The async fsync workqueue
>>> results in several thousand worker threads dispatching IO
>>> concurrently across 16 CPUs:
>>>
>>> $ ps -ef |grep kworker |wc -l
>>> 4693
>>> $
>>>
>>> Profiles from 3.15 + xfs for-next + xfs aio_fsync show:
>>>
>>> - 51.33% [kernel] [k] percpu_ida_alloc
>>> - percpu_ida_alloc
>>> + 85.73% blk_mq_wait_for_tags
>>> + 14.23% blk_mq_get_tag
>>> - 14.25% [kernel] [k] _raw_spin_unlock_irqrestore
>>> - _raw_spin_unlock_irqrestore
>>> - 66.26% virtio_queue_rq
>>> - __blk_mq_run_hw_queue
>>> - 99.65% blk_mq_run_hw_queue
>>> + 99.47% blk_mq_insert_requests
>>> + 0.53% blk_mq_insert_request
>>> .....
>>> - 7.91% [kernel] [k] _raw_spin_unlock_irq
>>> - _raw_spin_unlock_irq
>>> - 69.59% __schedule
>>> - 86.49% schedule
>>> + 47.72% percpu_ida_alloc
>>> + 21.75% worker_thread
>>> + 19.12% schedule_timeout
>>> ....
>>> + 18.06% blk_mq_make_request
>>>
>>> Runtime:
>>>
>>> real 4m1.243s
>>> user 0m47.724s
>>> sys 11m56.724s
>>>
>>> Most of the excessive CPU usage is coming from the blk-mq layer, and
>>> XFS is barely showing up in the profiles at all - the IDA tag
>>> allocator is burning 8 CPUs at about 60,000 write IOPS....
>>>
>>> I know that the tag allocator has been rewritten, so I tested
>>> against a current a current Linus kernel with the XFS aio-fsync
>>> patch. The results are all over the place - from several sequential
>>> runs of the same test (removing the files in between so each tests
>>> starts from an empty fs):
>>>
>>> Wall time sys time IOPS files/s
>>> 4m58.151s 11m12.648s 30,000 13,500
>>> 4m35.075s 12m45.900s 45,000 15,000
>>> 3m10.665s 11m15.804s 65,000 21,000
>>> 3m27.384s 11m54.723s 85,000 20,000
>>> 3m59.574s 11m12.012s 50,000 16,500
>>> 4m12.704s 12m15.720s 50,000 17,000
>>>
>>> The 3.15 based kernel was pretty consistent around the 4m10 mark,
>>> generally only +/-10s in runtime and not much change in system time.
>>> The files/s rate reported by fs_mark doesn't vary that much, either.
>>> So the new tag allocator seems to be no better in terms of IO
>>> dispatch scalability, yet adds significant variability to IO
>>> performance.
>>>
>>> What I noticed is a massive jump in context switch overhead: from
>>> around 250,000/s to over 800,000/s and the CPU profiles show that
>>> this comes from the new tag allocator:
>>>
>>> - 34.62% [kernel] [k] _raw_spin_unlock_irqrestore
>>> - _raw_spin_unlock_irqrestore
>>> - 58.22% prepare_to_wait
>>> 100.00% bt_get
>>> blk_mq_get_tag
>>> __blk_mq_alloc_request
>>> blk_mq_map_request
>>> blk_sq_make_request
>>> generic_make_request
>>> - 22.51% virtio_queue_rq
>>> __blk_mq_run_hw_queue
>>> ....
>>> - 21.56% [kernel] [k] _raw_spin_unlock_irq
>>> - _raw_spin_unlock_irq
>>> - 58.73% __schedule
>>> - 53.42% io_schedule
>>> 99.88% bt_get
>>> blk_mq_get_tag
>>> __blk_mq_alloc_request
>>> blk_mq_map_request
>>> blk_sq_make_request
>>> generic_make_request
>>> - 35.58% schedule
>>> + 49.31% worker_thread
>>> + 32.45% schedule_timeout
>>> + 10.35% _xfs_log_force_lsn
>>> + 3.10% xlog_cil_force_lsn
>>> ....
>>>
>>> The new block-mq tag allocator is hammering the waitqueues and
>>> that's generating a large amount of lock contention. It looks like
>>> the new allocator replaces CPU burn doing work in the IDA allocator
>>> with the same amount of CPU burn from extra context switch
>>> overhead....
>>>
>>> Oh, OH. Now I understand!
>>>
>>> # echo 4 > /sys/block/vdc/queue/nr_requests
>>>
>>> <run workload>
>>>
>>> 80.56% [kernel] [k] _raw_spin_unlock_irqrestore
>>> - _raw_spin_unlock_irqrestore
>>> - 98.49% prepare_to_wait
>>> bt_get
>>> blk_mq_get_tag
>>> __blk_mq_alloc_request
>>> blk_mq_map_request
>>> blk_sq_make_request
>>> generic_make_request
>>> + submit_bio
>>> + 1.07% finish_wait
>>> + 13.63% [kernel] [k] _raw_spin_unlock_irq
>>> ...
>>>
>>> It's context switch bound at 800,000 context switches/s, burning all
>>> 16 CPUs waking up and going to sleep and doing very little real
>>> work. How little real work? About 3000 IOPS for 2MB/s of IO. That
>>> amount of IO should only take a single digit CPU percentage of one
>>> CPU.
>>
>> With thousands of threads? I think not. Sanely submitted 3000 IOPS,
>> correct, I would agree with you.
>>
>>> This seems like bad behaviour to have on a congested block device,
>>> even a high performance one....
>>
>> That is pretty much the suck. How do I reproduce this (eg what are
>> you running, and what are the xfs aio fsync patches)? Even if
>
> http://oss.sgi.com/pipermail/xfs/2014-June/036773.html
>
>> dispatching thousands of threads to do IO is a bad idea (it very
>> much is), gracefully handling is a must. I haven't seen any bad
>> behavior from the new allocator, it seems to be well behaved (for
>> most normal cases, anyway). I'd like to take a stab at ensuring this
>> works, too.
>>
>> If you tell me exactly what you are running, I'll reproduce and get
>> this fixed up tomorrow.
>
> Test case - take fs_mark:
>
> git://oss.sgi.com/dgc/fs_mark
>
> Apply the patch for aio fsync support:
>
> http://oss.sgi.com/pipermail/xfs/2014-June/036774.html
>
> Run this test:
>
> $ time ./fs_mark -D 10000 -S5 -n 50000 -s 4096 -L 5 -A \
> -d /mnt/scratch/0 -d /mnt/scratch/1 -d /mnt/scratch/2 \
> -d /mnt/scratch/3 -d /mnt/scratch/4 -d /mnt/scratch/5 \
> -d /mnt/scratch/6 -d /mnt/scratch/7 -d /mnt/scratch/8 \
> -d /mnt/scratch/9 -d /mnt/scratch/10 -d /mnt/scratch/11 \
> -d /mnt/scratch/12 -d /mnt/scratch/13 -d /mnt/scratch/14 \
> -d /mnt/scratch/15
>
> Drop the "-A" if you want to use normal fsync (but then you won't
> see the problem).
>
> Use a XFS filesystem that has at least 32 AGs (I'm using
> a sparse 500TB fs image on a virtio device). I'm also using mkfs
> options of "-m crc=1,finobt=1", but to use that last one you'll need
> a mkfs built from the xfsprogs git tree. It shouldn't make any
> difference to the result, though. I'm running on a VM with 16 CPUs
> and 16GB RAM, using fakenuma=4.
Can you try with this patch?
--
Jens Axboe
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