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Re: [Xen-devel] [PATCH 3/3] xen/block: add multi-page ring support



On 22/06/15 02:20, Bob Liu wrote:

On 06/09/2015 10:07 PM, Roger Pau Monné wrote:
El 09/06/15 a les 15.39, Konrad Rzeszutek Wilk ha escrit:
...
Roger, I put them (patches) on devel/for-jens-4.2 on

git://git.kernel.org/pub/scm/linux/kernel/git/konrad/xen.git

I think these two patches:
drivers: xen-blkback: delay pending_req allocation to connect_ring
xen/block: add multi-page ring support

are the only ones that haven't been Acked by you (or maybe they
have and I missed the Ack?)

Hello,

I was waiting to Ack those because the XenServer storage performance
folks found out that these patches cause a performance regression on
some of their tests. I'm adding them to the conversation so they can
provide more details about the issues they found, and whether we should
hold pushing this patches or not.


Hey,

Are there any updates? What's the performance regression problem?


Hi,

We were using the 2 last weeks to finish measurements on the multipage ring v5 patches in a range of diverse conditions.

The measurements were obtained under the following conditions:

- using blkback as the dom0 backend with a back-ported multipage ring v5 applied to our dom0 kernel 3.10.

- using a recent Ubuntu 15.04 kernel 3.19 with v5 frontend applied to be used as guest

- using a micron RealSSD P320h as the underlying local storage on a Dell PowerEdge R720 with 2 Xeon E5-2643 v2 cpus.

- fio 2.2.7-22-g36870 as the generator of synthetic loads in the guest. We used direct_io to skip caching in the guest and ran fio for 60s for a number of block sizes ranging from 512 bytes to 4MiB. We also tried pure random and pure sequential reads. Random reads were used to counter-act read-ahead prefetching at the underlying storage.

We noticed that using large (>16) queue depths in fio would saturate individual vcpus in the guest, so to better utilise the cpu resources in the guest, we chose to (a) fix the queue depth to 4 for each fio thread, (b) increase the guest vcpus to 16 and (c) vary the number of fio threads from 1 to 64.

We were interested in observing storage iops and throughput for different values of in-flight requests (= io depth * fio threads) generated by the guest. Our expectation was that iops and throughput with single-page and multi-page rings would be the same up to 32 in-flight requests (the number of requests that fit in a single-page ring), and then the single-page ring case would flat-line with >32 in-flight requests, whereas the multi-page ring case would continue to show improvements until hitting some other bottleneck. The effect should be more visible when using requests with smaller block sizes because the measurements are less likely to be affected by memory copy delays or large data transfer delays to storage.

These are the results we got for the conditions above with 4KiB blocks and random reads:

fio_threads  io_depth  in_flight   1-page_IOPS  8-page_IOPS
    1            4         4           19K          19K
    4            4        16           89K          89K
    8            4        32          149K         149K
   16            4        64          131K         198K
   32            4       128          127K         208K
   64            4       256          132K         209K

We believe that this data shows that there's a clear improvement when using multi-page rings when there are more than 32 in-flight requests. We observed similar improvements when writing, and across all small block sizes. For block sizes >=16KiB, the results were similar between single- and multi-page rings, and we attribute that to bottlenecks when transferring large amounts of data that is not present with smaller block sizes.

Another reason for using random reads in the synthetic fio tests above is that we noticed that when sequential reads are used there were some anomalies that we believe would affect a fair comparison:

(A)- in some situations with sequential read, we observed a decreasing number of merges in the guest (according to 'iostat -x -m 1') with small block sizes <=4KiB when increasing the number of ring pages. There were no merges whenever in_flight < ring_pages * 32. With larger in_flight requests (>=128) -- visible with both 8 fio_threads x 32 io_depth and 32 fio_threads x 8 io_depth -- storage throughput with 1 page was around 25% better than with 8 pages. This is the regression that Roger was talking about previously in this discussion. It seems related to the merges of requests occurring much more frequently with 1 page than with 8 pages. During the measurements, the average request queue size in iostat has always a similar value as the number of requests in the ring. I would appreciate potential explanations of why the guest kernel would behave like that. We believe that this regression is a corner-case that would be difficult to spot in a real-world load, where random reads are interspersed with sequential reads of many different block sizes and io depths, and we only spotted it because of our synthetic load with fio used a wide range of parameters with sequential reads. It may also be specific to the way that Linux handles this situation.

(B)- in other situations with sequential read (block sizes between 8KiB and 128KiB), we observed the storage throughput with 1 page was around 50% worse than with 8 pages. Again, this seems related to the existence of merges with 1 page but not with 8 pages, and I would appreciate potential explanations.

For sequential reads, arguably the performance difference spotted in (A) is counter balanced by the performance difference in (B), and they cancel each other out if all block sizes are considered together. For random reads, 8-page rings were similar or superior to 1-page rings in all tested conditions.

All considered, we believe that the multi-page ring patches improve the storage performance (apart from case (A)) and therefore should be good to merge.

Marcus

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