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Message-ID: <4A727F6F.9010005@cn.fujitsu.com>
Date: Fri, 31 Jul 2009 13:21:51 +0800
From: Gui Jianfeng <guijianfeng@...fujitsu.com>
To: Vivek Goyal <vgoyal@...hat.com>
CC: linux-kernel@...r.kernel.org,
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Subject: Re: [RFC] IO scheduler based IO controller V7
Hi Vivek,
Here are some test results for normal reads and write for IO Controller V7 by fio.
Tested with "fairness == 0". It seems performance gets better comparing with V6.
Mode Normal read | Random read | Normal write | Random write | Direct read | Direct Write
2.6.31-rc1 71,613KiB/s 3,606KiB/s 66,250KiB/s 9,420KiB/s 51,535KiB/s 55,752KiB/s
V7 70,540KiB/s 3,551KiB/s 64,548KiB/s 9,677KiB/s 53,530KiB/s 54,145KiB/s
Performance -1.5% -1.5% -2.6% +2.7% +3.9% -2.9%
Vivek Goyal wrote:
> Hi All,
>
> Here is the V7 of the IO controller patches generated on top of 2.6.31-rc4.
>
> For ease of patching, a consolidated patch is available here.
>
> http://people.redhat.com/~vgoyal/io-controller/io-scheduler-based-io-controller-v7.patch
>
> Previous versions of the patches was posted here.
>
> (V1) http://lkml.org/lkml/2009/3/11/486
> (V2) http://lkml.org/lkml/2009/5/5/275
> (V3) http://lkml.org/lkml/2009/5/26/472
> (V4) http://lkml.org/lkml/2009/6/8/580
> (V5) http://lkml.org/lkml/2009/6/19/279
> (V6) http://lkml.org/lkml/2009/7/2/369
>
> Changes from V6
> ===============
> - Introduced the notion of group_idling where we idle for next request to
> come from the same group before we expire it. It is along the lines of
> cfq's slice_idle thing to provide fairness. Switching to group idling
> now helps in the sense that we don't have to rely whether queue idling
> was turned on or not by CFQ. It becomes too much of debugging pain with
> different work loads and different kind of storage media. Introduction
> of group_idle should help.
>
> - Moved some of the code like dynamic queue idling update, arming queue
> idling timer, keeping track of average think time etc back to CFQ. With
> group idling we don't need it now. Reduce the amount of change.
>
> - Enabled cfq's close cooperator functionality in groups. So far this worked
> only in root group. Now it should work in non-root groups also.
>
> - Got rid of the patch where we calculated disk time based on average disk
> rate in some circumstances. It was giving bad numbers in early queue
> deletion cases. Also did not think that it was helping a lot. Remvoed it
> for the time being.
>
> - Added an experimental patch to map sync requests using bio tracking info and
> not task context. This is only for noop, deadline and AS.
>
> - Got rid of experimental patch of idling for async queues. Don't think it
> was helping.
>
> - Got rid of wait_busy and wait_busy_done logic from queue. Instead
> implemented it for groups.
>
> - Introduced oom_ioq to accomodate oom_cfqq change recently.
>
> - Broke-up elv_init_ioq() fn into smaller functions. It had 7 arguments and
> looked complicated.
>
> - Fixed a bug in blk_queue_io_group_congested(). Thanks to Munehiro Ikeda.
>
> - Merged gui's patch to fix the cgroup file format issue.
>
> - Merged gui's patch to update per group congestion limit when
> q->nr_group_requests is updated.
>
> - Fixed a bug where close cooperation will not work if we wait for all the
> requests to finish from previous queue.
>
> - Fixed group deletion accouting where deletion from idle tree were also
> appearing in the log.
>
> - Got rid of busy_rt_queues infrastructure.
>
> - Got rid of elv_ioq_request_dispatched(). An helper function just to
> increment a variable.
>
> Limitations
> ===========
>
> - This IO controller provides the bandwidth control at the IO scheduler
> level (leaf node in stacked hiearchy of logical devices). So there can
> be cases (depending on configuration) where application does not see
> proportional BW division at higher logical level device.
>
> LWN has written an article about the issue here.
>
> http://lwn.net/Articles/332839/
>
> How to solve the issue of fairness at higher level logical devices
> ==================================================================
> (Do we really need it? That's not where the contention for resources is.)
>
> Couple of suggestions have come forward.
>
> - Implement IO control at IO scheduler layer and then with the help of
> some daemon, adjust the weight on underlying devices dynamiclly, depending
> on what kind of BW gurantees are to be achieved at higher level logical
> block devices.
>
> - Also implement a higher level IO controller along with IO scheduler
> based controller and let user choose one depending on his needs.
>
> A higher level controller does not know about the assumptions/policies
> of unerldying IO scheduler, hence it has the potential to break down
> the IO scheduler's policy with-in cgroup. A lower level controller
> can work with IO scheduler much more closely and efficiently.
>
> Other active IO controller developments
> =======================================
>
> IO throttling
> -------------
>
> This is a max bandwidth controller and not the proportional one. Secondly
> it is a second level controller which can break the IO scheduler's
> policy/assumtions with-in cgroup.
>
> dm-ioband
> ---------
>
> This is a proportional bandwidth controller implemented as device mapper
> driver. It is also a second level controller which can break the
> IO scheduler's policy/assumptions with-in cgroup.
>
> TODO
> ====
> - code cleanups, testing, bug fixing, optimizations, benchmarking etc...
>
> Testing
> =======
>
> I have been able to do some testing as follows. All my testing is with ext3
> file system with a SATA drive which supports queue depth of 31.
>
> Test1 (Isolation between two KVM virtual machines)
> ==================================================
> Created two KVM virtual machines. Partitioned a disk on host in two partitions
> and gave one partition to each virtual machine. Put both the virtual machines
> in two different cgroup of weight 1000 and 500 each. Virtual machines created
> ext3 file system on the partitions exported from host and did buffered writes.
> Host seems writes as synchronous and virtual machine with higher weight gets
> double the disk time of virtual machine of lower weight. Used deadline
> scheduler in this test case.
>
> Some more details about configuration are in documentation patch.
>
> Test2 (Fairness for synchronous reads)
> ======================================
> - Two dd in two cgroups with cgrop weights 1000 and 500. Ran two "dd" in those
> cgroups (With CFQ scheduler and /sys/block/<device>/queue/fairness = 1)
>
> Higher weight dd finishes first and at that point of time my script takes
> care of reading cgroup files io.disk_time and io.disk_sectors for both the
> groups and display the results.
>
> dd if=/mnt/$BLOCKDEV/zerofile1 of=/dev/null &
> dd if=/mnt/$BLOCKDEV/zerofile2 of=/dev/null &
>
> 234179072 bytes (234 MB) copied, 3.9065 s, 59.9 MB/s
> 234179072 bytes (234 MB) copied, 5.19232 s, 45.1 MB/s
>
> group1 time=8 16 2471 group1 sectors=8 16 457840
> group2 time=8 16 1220 group2 sectors=8 16 225736
>
> First two fields in time and sectors statistics represent major and minor
> number of the device. Third field represents disk time in milliseconds and
> number of sectors transferred respectively.
>
> This patchset tries to provide fairness in terms of disk time received. group1
> got almost double of group2 disk time (At the time of first dd finish). These
> time and sectors statistics can be read using io.disk_time and io.disk_sector
> files in cgroup. More about it in documentation file.
>
> Test3 (Reader Vs Buffered Writes)
> ================================
> Buffered writes can be problematic and can overwhelm readers, especially with
> noop and deadline. IO controller can provide isolation between readers and
> buffered (async) writers.
>
> First I ran the test without io controller to see the severity of the issue.
> Ran a hostile writer and then after 10 seconds started a reader and then
> monitored the completion time of reader. Reader reads a 256 MB file. Tested
> this with noop scheduler.
>
> sample script
> ------------
> sync
> echo 3 > /proc/sys/vm/drop_caches
> time dd if=/dev/zero of=/mnt/sdb/reader-writer-zerofile bs=4K count=2097152
> conv=fdatasync &
> sleep 10
> time dd if=/mnt/sdb/256M-file of=/dev/null &
>
> Results
> -------
> 8589934592 bytes (8.6 GB) copied, 106.045 s, 81.0 MB/s (Writer)
> 268435456 bytes (268 MB) copied, 96.5237 s, 2.8 MB/s (Reader)
>
> Now it was time to test io controller whether it can provide isolation between
> readers and writers with noop. I created two cgroups of weight 1000 each and
> put reader in group1 and writer in group 2 and ran the test again. Upon
> comletion of reader, my scripts read io.dis_time and io.disk_group cgroup
> files to get an estimate how much disk time each group got and how many
> sectors each group did IO for.
>
> For more accurate accounting of disk time for buffered writes with queuing
> hardware I had to set /sys/block/<disk>/queue/iosched/fairness to "1".
>
> sample script
> -------------
> echo $$ > /cgroup/bfqio/test2/tasks
> dd if=/dev/zero of=/mnt/$BLOCKDEV/testzerofile bs=4K count=2097152 &
> sleep 10
> echo noop > /sys/block/$BLOCKDEV/queue/scheduler
> echo 1 > /sys/block/$BLOCKDEV/queue/iosched/fairness
> echo $$ > /cgroup/bfqio/test1/tasks
> dd if=/mnt/$BLOCKDEV/256M-file of=/dev/null &
> wait $!
> # Some code for reading cgroup files upon completion of reader.
> -------------------------
>
> Results
> =======
> 268435456 bytes (268 MB) copied, 6.65819 s, 40.3 MB/s (Reader)
>
> group1 time=8 16 3063 group1 sectors=8 16 524808
> group2 time=8 16 3071 group2 sectors=8 16 441752
>
> Note, reader finishes now much lesser time and both group1 and group2
> got almost 3 seconds of disk time. Hence io-controller provides isolation
> from buffered writes.
>
> Test4 (AIO)
> ===========
>
> AIO reads
> -----------
> Set up two fio, AIO read jobs in two cgroup with weight 1000 and 500
> respectively. I am using cfq scheduler. Following are some lines from my test
> script.
>
> ---------------------------------------------------------------
> echo 1000 > /cgroup/bfqio/test1/io.weight
> echo 500 > /cgroup/bfqio/test2/io.weight
>
> fio_args="--ioengine=libaio --rw=read --size=512M --direct=1"
> echo 1 > /sys/block/$BLOCKDEV/queue/iosched/fairness
>
> echo $$ > /cgroup/bfqio/test1/tasks
> fio $fio_args --name=test1 --directory=/mnt/$BLOCKDEV/fio1/
> --output=/mnt/$BLOCKDEV/fio1/test1.log
> --exec_postrun="../read-and-display-group-stats.sh $maj_dev $minor_dev" &
>
> echo $$ > /cgroup/bfqio/test2/tasks
> fio $fio_args --name=test2 --directory=/mnt/$BLOCKDEV/fio2/
> --output=/mnt/$BLOCKDEV/fio2/test2.log &
> ----------------------------------------------------------------
>
> test1 and test2 are two groups with weight 1000 and 500 respectively.
> "read-and-display-group-stats.sh" is one small script which reads the
> test1 and test2 cgroup files to determine how much disk time each group
> got till first fio job finished.
>
> Results
> ------
> test1 statistics: time=8 16 22403 sectors=8 16 1049640
> test2 statistics: time=8 16 11400 sectors=8 16 552864
>
> Above shows that by the time first fio (higher weight), finished, group
> test1 got 22403 ms of disk time and group test2 got 11400 ms of disk time.
> similarly the statistics for number of sectors transferred are also shown.
>
> Note that disk time given to group test1 is almost double of group2 disk
> time.
>
> AIO writes
> ----------
> Set up two fio, AIO direct write jobs in two cgroup with weight 1000 and 500
> respectively. I am using cfq scheduler. Following are some lines from my test
> script.
>
> ------------------------------------------------
> echo 1000 > /cgroup/bfqio/test1/io.weight
> echo 500 > /cgroup/bfqio/test2/io.weight
> fio_args="--ioengine=libaio --rw=write --size=512M --direct=1"
>
> echo 1 > /sys/block/$BLOCKDEV/queue/iosched/fairness
>
> echo $$ > /cgroup/bfqio/test1/tasks
> fio $fio_args --name=test1 --directory=/mnt/$BLOCKDEV/fio1/
> --output=/mnt/$BLOCKDEV/fio1/test1.log
> --exec_postrun="../read-and-display-group-stats.sh $maj_dev $minor_dev" &
>
> echo $$ > /cgroup/bfqio/test2/tasks
> fio $fio_args --name=test2 --directory=/mnt/$BLOCKDEV/fio2/
> --output=/mnt/$BLOCKDEV/fio2/test2.log &
> -------------------------------------------------
>
> test1 and test2 are two groups with weight 1000 and 500 respectively.
> "read-and-display-group-stats.sh" is one small script which reads the
> test1 and test2 cgroup files to determine how much disk time each group
> got till first fio job finished.
>
> Following are the results.
>
> test1 statistics: time=8 16 29085 sectors=8 16 1049656
> test2 statistics: time=8 16 14652 sectors=8 16 516728
>
> Above shows that by the time first fio (higher weight), finished, group
> test1 got 28085 ms of disk time and group test2 got 14652 ms of disk time.
> similarly the statistics for number of sectors transferred are also shown.
>
> Note that disk time given to group test1 is almost double of group2 disk
> time.
>
> Test5 (Fairness for async writes, Buffered Write Vs Buffered Write)
> ===================================================================
> Fairness for async writes is tricky and biggest reason is that async writes
> are cached in higher layers (page cahe) as well as possibly in file system
> layer also (btrfs, xfs etc), and are dispatched to lower layers not necessarily
> in proportional manner.
>
> For example, consider two dd threads reading /dev/zero as input file and doing
> writes of huge files. Very soon we will cross vm_dirty_ratio and dd thread will
> be forced to write out some pages to disk before more pages can be dirtied. But
> not necessarily dirty pages of same thread are picked. It can very well pick
> the inode of lesser priority dd thread and do some writeout. So effectively
> higher weight dd is doing writeouts of lower weight dd pages and we don't see
> service differentation.
>
> IOW, the core problem with async write fairness is that higher weight thread
> does not throw enought IO traffic at IO controller to keep the queue
> continuously backlogged. In my testing, there are many .2 to .8 second
> intervals where higher weight queue is empty and in that duration lower weight
> queue get lots of job done giving the impression that there was no service
> differentiation.
>
> In summary, from IO controller point of view async writes support is there.
> Because page cache has not been designed in such a manner that higher
> prio/weight writer can do more write out as compared to lower prio/weight
> writer, gettting service differentiation is hard and it is visible in some
> cases and not visible in some cases.
>
> Do we really care that much for fairness among two writer cgroups? One can
> choose to do direct writes or sync writes if fairness for writes really
> matters for him.
>
> Following is the only case where it is hard to ensure fairness between cgroups.
>
> - Buffered writes Vs Buffered Writes.
>
> So to test async writes I created two partitions on a disk and created ext3
> file systems on both the partitions. Also created two cgroups and generated
> lots of write traffic in two cgroups (50 fio threads) and watched the disk
> time statistics in respective cgroups at the interval of 2 seconds. Thanks to
> ryo tsuruta for the test case.
>
> *****************************************************************
> sync
> echo 3 > /proc/sys/vm/drop_caches
>
> fio_args="--size=64m --rw=write --numjobs=50 --group_reporting"
>
> echo $$ > /cgroup/bfqio/test1/tasks
> fio $fio_args --name=test1 --directory=/mnt/sdd1/fio/ --output=/mnt/sdd1/fio/test1.log &
>
> echo $$ > /cgroup/bfqio/test2/tasks
> fio $fio_args --name=test2 --directory=/mnt/sdd2/fio/ --output=/mnt/sdd2/fio/test2.log &
> ***********************************************************************
>
> And watched the disk time and sector statistics for the both the cgroups
> every 2 seconds using a script. How is snippet from output.
>
> test1 statistics: time=8 48 1315 sectors=8 48 55776 dq=8 48 1
> test2 statistics: time=8 48 633 sectors=8 48 14720 dq=8 48 2
>
> test1 statistics: time=8 48 5586 sectors=8 48 339064 dq=8 48 2
> test2 statistics: time=8 48 2985 sectors=8 48 146656 dq=8 48 3
>
> test1 statistics: time=8 48 9935 sectors=8 48 628728 dq=8 48 3
> test2 statistics: time=8 48 5265 sectors=8 48 278688 dq=8 48 4
>
> test1 statistics: time=8 48 14156 sectors=8 48 932488 dq=8 48 6
> test2 statistics: time=8 48 7646 sectors=8 48 412704 dq=8 48 7
>
> test1 statistics: time=8 48 18141 sectors=8 48 1231488 dq=8 48 10
> test2 statistics: time=8 48 9820 sectors=8 48 548400 dq=8 48 8
>
> test1 statistics: time=8 48 21953 sectors=8 48 1485632 dq=8 48 13
> test2 statistics: time=8 48 12394 sectors=8 48 698288 dq=8 48 10
>
> test1 statistics: time=8 48 25167 sectors=8 48 1705264 dq=8 48 13
> test2 statistics: time=8 48 14042 sectors=8 48 817808 dq=8 48 10
>
> First two fields in time and sectors statistics represent major and minor
> number of the device. Third field represents disk time in milliseconds and
> number of sectors transferred respectively.
>
> So disk time consumed by group1 is almost double of group2 in this case.
>
> Your feedback is welcome.
>
> Thanks
> Vivek
>
>
>
--
Regards
Gui Jianfeng
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