Small Datum

Monday, July 10, 2017

I overstated the CPU regression in MySQL 5.7

My series of posts on the low-concurrency CPU regression greatly overstated the regression from MySQL 5.6 to 5.7. Most of the regression was from the use of SSL which is enabled by default starting with 5.7. My results for 5.7 and 8.0 were slower courtesy of SSL while earlier versions of MySQL were not using SSL. I repeated tests for 5.7 and 8.0 with SSL disabled (ssl=0 in my.cnf) and now show a QPS loss of 10% to 20% from 5.6 to 5.7/8.0.

There is still a large regression from MySQL 5.0 to 8.0 and I will continue to document that and expect to help reduce it. I expect 86215 to be closed as not a bug.

tl;dr for in-memory sysbench at low concurrency

MySQL 5.7 and 8.0 lose 10% to 20% of QPS versus 5.6 for tests not dominated by range scans
InnoDB range scans were made faster starting in MySQL 5.7
In the worst case, MySQL 5.0 gets more than 2X the QPS versus 5.7 and 8.0.
The largest QPS regression occurs between MySQL 5.5 and 5.6.

Why

I should have noticed earlier in the process that SSL was the problem. I frequently rant about the value of explaining performance results and this is a reminder of that value. I didn't explain why MySQL 5.7 and 8.0 did worse than 5.6 and it turned out that my results were wrong. I spent some time debugging the slowdown using PMP and Linux perf but clearly I should have spent more time on that.

The short story is that I was trying to do too much and didn't have time to focus. Too much in this case meant I was too busy running tests and collecting results and didn't have time to explain the results. Lesson learned.

Configuration

I repeated tests for 5.7 and 8.0 with SSL disabled and share results for in-memory sysbench in this post.

I tested MySQL with upstream 5.0.96, 5.1.72, 5.5.51, 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. I disabled SSL for 5.7.17 and 8.0.1 by adding ssl=0 to my.cnf. I used the i5 NUC servers described here and the my.cnf used are here. I run mysqld and the sysbench client on the same server. The binlog is enabled but sync-on-commit is disabled. I also set innodb_purge_threads to 1 to avoid mutex contention on a small server.

Sysbench is run with 4 tables and 1M rows per table. Tests are repeated for 1, 2 and 4 clients. The database fits in the InnoDB buffer pool. My usage of sysbench is described here. That explains the helper scripts that invoke sysbench and collect performance metrics.

Results

The first table is the QPS for MySQL 5.7.17 and 8.0.1 relative to 5.6.35 for sysbench with one client. The QPS for 5.7.17 and 8.0.1 is better than 5.6.35 when the value is greater than 1 as it is for tests that do longer range scans because something was done to make that faster in modern InnoDB. In the tests not dominated by range scans the QPS for 5.7.17 and 8.0.1 are 10% to 20% less than for 5.6.35 and the loss from 5.6 to 5.7 is similar to the loss from 5.7 to 8.0.

QPS relative to 5.6.35
----------------------
5717 801 test
1.04 .96 update-index
.90 .84 update-nonindex
.91 .83 delete
.90 .82 write-only
1.06 1.03 read-write.range100
1.51 1.49 read-write.range10000
.94 .86 read-only.range10
1.11 1.01 read-only.range100
1.49 1.42 read-only.range1000
1.44 1.41 read-only.range10000
.95 .85 point-query
.89 .82 insert

The next table is the QPS for 5.1.72, 5.5.51, 5.6.35, 5.7.17 and 8.0.1 relative to 5.0.96 for the same tests using 1 sysbench client. In the worst case the QPS for 5.0.96 is 2.5X better than 8.0.1 and more than 2X better than 5.7.17. The worst case is for the update-only (update-index, update-nonindex) and point-query tests.

QPS relative to 5.0.96
----------------------
5172 5551 5635 5717 801 test
.89 .73 .45 .46 .43 update-index
.89 .59 .47 .42 .39 update-nonindex
.92 .92 .75 .68 .62 delete
.93 .93 .76 .68 .62 write-only
.92 .99 .65 .69 .67 read-write.range100
.95 .92 .55 .84 .82 read-write.range10000
.92 .89 .58 .55 .50 read-only.range10
.94 .91 .57 .63 .57 read-only.range100
.96 .92 .56 .83 .80 read-only.range1000
.95 .92 .55 .80 .78 read-only.range10000
.85 .77 .47 .45 .40 point-query
.95 .93 .81 .72 .67 insert

The data below has the QPS for each test. Each test was run for 1, 2 and 4 clients and my usage of sysbench is explained in a previous post.

update-index
1 2 4 concurrency/version
13047 19521 22763 inno5096
11592 18439 19833 inno5172
9486 14393 16389 inno5551
5806 9837 12354 inno5635
6013 10242 13498 inno5717
5585 9509 12771 inno801

update-nonindex
1 2 4 concurrency/version
22333 32560 32961 inno5096
19914 29050 31829 inno5172
13082 19164 21049 inno5551
10435 15680 18487 inno5635
9430 14120 19012 inno5717
8730 13277 17746 inno801

delete
1 2 4 concurrency/version
25893 35659 38785 inno5096
23777 38591 41418 inno5171
23726 33260 38085 inno5551
19461 28797 35684 inno5635
17621 26110 34634 inno5717
16146 24270 32245 inno801

write-only
1 2 4 concurrency/version
22364 32090 36125 inno5096
20907 32503 35141 inno5172
20727 29856 33173 inno5551
16892 25376 30915 inno5635
15176 22631 29425 inno5717
13778 20834 27262 inno801

read-write.range100
1 2 4 concurrency/version
17972 30414 42474 inno5096
16527 30055 41973 inno5172
17857 28714 41496 inno5551
11653 18109 25325 inno5635
12387 18359 25379 inno5717
12002 17727 24253 inno801

read-write.range10000
1 2 4 concurrency/version
608 1089 1556 inno5096
580 1033 1513 inno5171
557 996 1410 inno5551
337 604 849 inno5635
509 873 1067 inno5717
501 858 1039 inno801

read-only.range10
1 2 4 concurrency/version
30016 48794 78703 inno5096
27554 49464 76052 inno5172
26863 48108 77370 inno5551
17372 30663 50570 inno5635
16383 28695 48139 inno5717
14861 26625 45225 inno801

read-only.range100
1 2 4 concurrency/version
19891 34307 56572 inno5096
18636 34808 54051 inno5172
18125 33561 51729 inno5551
11247 20922 32930 inno5635
12453 22441 34585 inno5717
11387 21221 32934 inno801

read-only.range1000
1 2 4 concurrency/version
4623 8304 12115 inno5096
4429 8114 11757 inno5171
4272 7851 11167 inno5551
2590 4840 6816 inno5635
3859 7041 8764 inno5717
3682 6877 8395 inno801

read-only.range10000
1 2 4 concurrency/version
492 882 1259 inno5096
468 827 1222 inno5172
452 808 1147 inno5551
273 497 686 inno5635
392 700 865 inno5717
386 693 841 inno801

point-query
1 2 4 concurrency/version
41951 68718 123988 inno5096
35785 66515 111602 inno5172
32385 56441 81061 inno5551
19674 36269 55266 inno5635
18749 32669 55340 inno5717
16694 30372 51878 inno801

insert
1 2 4 concurrency/version
13932 14182 12795 inno5096
13194 15157 12521 inno5171
12968 17106 14447 inno5551
11288 16268 19355 inno5635
10039 15428 19922 inno5717
9306 14391 18763 inno801

Friday, June 30, 2017

One more time with sysbench, a small server & MySQL 5.6, 5.7 and 8.0

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

The good news is that I hope to begin debugging this problem next week. After fixing a few problems to reduce variance I am repeating tests to document the performance regression from MySQL 5.6 to 8.0. The first problem was fixed by disabling turbo boost on my Intel NUC servers to avoid thermal throttling. The other problem was the impact from mutex contention for InnoDB purge threads and I repeated tests with it set to 1 and 4. This is part of my series on low-concurrency CPU regressions for bug 86215.

tl;dr for in-memory sysbench on a small server with a fast SSD

most of the regression is from 5.6.35 to 5.7.17, much less is from 5.7.1 to 8.0.1
innodb_purge_threads=4 costs 10% to 15% of the QPS for write-heavy tests
QPS is 30% less for 5.7.17 & 8.0.1 vs 5.6.35 on write-only tests
QPS is 30% to 40% less for 5.7.17 & 8.0.1 vs 5.6.35 on read-write tests
QPS is 40% to 50% less for 5.7.17 & 8.0.1 vs 5.6.35 on read-only tests
QPS is 40% less for 5.7.17 & 8.0.1 vs 5.6.35 for point-query
QPS is 30% less for 5.7.17 & 8.0.1 vs 5.6.35 for insert-only

Configuration

I tested MySQL with upstream 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. I used the i5 NUC servers described here and the my.cnf used are here. I run mysqld and the sysbench client on the same server. The binlog is enabled but sync-on-commit is disabled.

Sysbench is run with 4 tables and 1M rows per table. The database fits in the InnoDB buffer pool. My usage of sysbench is described here. That explains the helper scripts that invoke sysbench and collect performance metrics. When I return home I will update this with the sysbench command lines that are generated by my helper scripts.

Results: write-only

Sorry, no graphs this time. I run sysbench for 1, 2 and 4 concurrent clients and share both the QPS for each test and then the QPS for MySQL 5.7.17 and 8.0.1 relative to 5.6.35. The ratio is less than 1 when the QPS is larger for 5.6.35.

All of these tests are run with innodb_purge_threads=1 which is the default for 5.6.35. The default for 5.7.17 and 8.0.1 is 4.

The first batch of results is from write-only tests. Most of the QPS regression is from MySQL 5.6.35 to 5.7.17. Excluding the update-index test, going from 5.6 to 5.7 loses about 30% of QPS.

update-index : QPS
1 2 4 concurrency/engine
5806 9837 12354 inno5635
5270 8798 11677 inno5717
4909 8176 10917 inno801

update-index : QPS relative to MySQL 5.6.35
1 2 4 concurrency/engine
.91 .89 .95 inno5717
.85 .83 .88 inno801

update-nonindex : QPS
1 2 4 concurrency/engine
10435 15680 18487 inno5635
7691 11497 14989 inno5717
7179 10845 14186 inno801

update-nonindex : QPS relative to MySQL 5.6.35
1 2 4 concurrency/engine
.74 .73 .81 inno5717
.69 .69 .77 inno801

delete : QPS
1 2 4 concurrency/engine
19461 28797 35684 inno5635
13525 19937 25466 inno5717
12551 18810 24023 inno801

delete : QPS relative to MySQL 5.6.35
1 2 4 concurrency/engine
.69 .69 .71 inno5717
.64 .65 .67 inno801

write-only : QPS
1 2 4 concurrency/engine
16892 25376 30915 inno5635
11765 17239 22061 inno5717
10729 16108 20682 inno801

write-only : QPS relative to MySQL 5.6.35
1 2 4 concurrency/engine
.70 .68 .71 inno5717
.64 .63 .67 inno801

Results: read-write

The next batch of results is from the classic read-write OLTP sysbench test. But I repeat it using different sizes for the range query. The regression is larger here than for the write-only tests above perhaps because of the regression for range scans. Going from 5.6.35 to 5.7.17 loses between 30% and 40% of the QPS. The regression is worse for longer range scans.

read-write.range100 : QPS

1 2 4 concurrency/engine

11653 18109 25325 inno5635

7520 10871 14498 inno5717

6965 10274 14098 inno801

read-write.range100 : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.65 .60 .57 inno5717

.60 .57 .56 inno801

read-write.range10000 : QPS

1 2 4 concurrency/engine

337 604 849 inno5635

202 386 443 inno5717

200 378 436 inno801

read-write.range10000 : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.60 .64 .52 inno5717

.59 .63 .51 inno801

Results: read-only
The next batch of results is from the classic read-only OLTP sysbench test. But I repeat it using different sizes for the range query. Most of the regression is from 5.6.35 to 5.7.17. Going from 5.6 to 5.7 loses between 40% and 50% of the QPS so the regression here is larger than above for the read-write tests. There isn't a larger regression for larger range queries.

read-only.range10 : QPS

1 2 4 concurrency/engine

17372 30663 50570 inno5635

10829 19021 25874 inno5717

10171 18743 25713 inno801

read-only.range10 : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.62 .62 .51 inno5717

.59 .61 .51 inno801

read-only.range100 : QPS

1 2 4 concurrency/engine

11247 20922 32930 inno5635

6815 12823 16225 inno5717

6475 12308 15834 inno801

read-only.range100 : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.61 .61 .49 inno5717

.58 .59 .48 inno801

read-only.range1000 : QPS

1 2 4 concurrency/engine

2590 4840 6816 inno5635

1591 2979 3408 inno5717

1552 2918 3363 inno801

read-only.range1000 : QPS relatie to MySQL 5.6.35

1 2 4 concurrency/engine

.61 .62 .50 inno5717

.60 .60 .49 inno801

read-only.range10000 : QPS

1 2 4 concurrency/engine

273 497 686 inno5635

161 304 355 inno5717

159 299 350 inno801

read-only.range10000 : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.59 .61 .52 inno5717

.68 .60 .51 inno801

Results: point-query and insert-only

Finally results for the last two tests -- point-query and insert-only. MySQL 5.7.17 loses about 40% of the QPS for point-query and 30% of the QPS for insert-only compared to 5.6.35.

point-query : QPS

1 2 4 concurrency/engine

19674 36269 55266 inno5635

11964 22941 29174 inno5717

11624 20679 29271 inno801

point-query : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.61 .63 .53 inno5717

.59 .57 .53 inno801

insert : QPS

1 2 4 concurrency/engine

11288 16268 19355 inno5635

7951 12176 15660 inno5717

7493 11277 14857 inno801

insert : QPS relative to MySQL 5.6.35

1 2 4 concurrency/engine

.70 .75 .81 inno5717

.66 .69 .77 inno801

innodb_purge_threads

Finally I repeated tests with innodb_purge_threads=4 to show the impact from that. On a small server (2 cores, 4 HW threads) there is too much mutex from innodb_purge_threads=4. As 4 is the default for 5.7.17 and 8.0.1 they suffer more than 5.6.35 when the default is used. The results above are for innodb_purge_threads=1 and then I repeated the tests with it set to 4. Here I show the QPS with purge_threads=4 / QPS with purge_threads=1. For the tests below QPS is reduced by 10% to 15% when innodb_purge_threads=4 on a small server. The insert-only test doesn't suffer, but there isn't anything to purge from the insert-only workload.

update-index

1 2 4 concurrency/engine

.85 .76 .75 inno5635

.76 .76 .77 inno5717

.89 .96 .89 inno801

update-nonindex

1 2 4 concurrency/engine

.82 .78 .88 inno5635

.77 .79 .86 inno5717

.86 .95 .91 inno801

delete

1 2 4 concurrency/engine

.84 .81 .82 inno5635

.84 .81 .87 inno5717

.87 .92 .94 inno801

write-only

1 2 4 concurrency/engine

.89 .85 .85 inno5635

.88 .86 .87 inno5717

.91 .95 .94 inno801

insert

1 2 4 concurrency/engine

.99 .99 .99 inno5635

.99 1.00 1.00 inno5717

1.01 1.01 1.00 inno801

Wednesday, June 28, 2017

MyISAM, small servers and sysbench at low concurrency

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

I am a big fan of Intel NUC servers but recently noticed that CPU performance varied frequently from thermal throttling for my NUC7i5bnh. To prevent this I disabled turbo boost for the CPUs. My old NUC servers (NUC5i3ryh) don't suffer from this because that CPU does not have turbo boost. Now I need to repeat many tests. Today I share results for a quick run of sysbench using MyISAM and InnoDB in MySQL 5.6, 5.7 and 8.0. This is part of my series on low-concurrency CPU regressions for bug 86215.

tl;dr for in-memory sysbench:

the QPS regression is from MySQL 5.6 to 5.7
the QPS regression is similar for MyISAM and InnoDB
the default value for innodb_purge_threads, which is 4, can cause too much mutex contention and a loss in QPS on small servers. For sysbench update-only I lose 25% of updates/second with 5.7.17 and 15% with 8.0.1 when going from innodb_purge_threads=1 to =4.

Configuration

I tested MySQL with upstream 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. I used the i5 NUC servers described here and the my.cnf used are here. I run mysqld and the sysbench client on the same server. The binlog is enabled but sync-on-commit is disabled. Sysbench is run with 4 tables and 1M rows per table.

My usage of sysbench is described here but in this case I ran a shorter version of the test and here are the command lines for MyISAM and for InnoDB. I used 1 table with 1M rows for an in-memory workload and ran update-index, update-nonindex, read-only with 10 to 10,000 rows and then point-query. Tests were run for 1 client and 3 minutes duration. I did this to quickly get results for MyISAM and InnoDB.

I noticed mutex contention from InnoDB purge threads and had been using the default value (innodb_purge_threads=4) so I repeated tests with innodb_purge_threads=1.

Results

In the tables below for MyISAM: 5635 is 5.6.35, 5717 is 5.7.17, 801 is 8.0.1. In the tables below for InnoDB: 5635 is 5.6.35, 5717-pX is 5.7.17 with innodb_purge_threads set to X, 801-pX is 8.0.1 with innodb_purge_threads set to X.

The first table shows the QPS for MyISAM.

5635 5717 801 release/test
11143 7995 7692 update-index
12572 8743 8106 update-nonindex
17177 10565 10403 read-only.range10
9994 6287 6337 read-only.range100
2088 1351 1299 read-only.range1000
208 142 145 read-only.range10000
20369 12106 11177 point-query

The next table shows the QPS for MyISAM relative to MyISAM in MySQL 5.6.35. Most of the QPS regression is from MySQL 5.6 to 5.7.

5635 5717 801 release/test
1.00 .72 .69 update-index
1.00 .70 .64 update-nonindex
1.00 .62 .61 read-only.range10
1.00 .63 .63 read-only.range100
1.00 .65 .62 read-only.range1000
1.00 .68 .70 read-only.range10000
1.00 .59 .55 point-query

The next table shows the QPS for InnoDB.

5635 5717-p4 5717-p1 801-p4 801-p1
5723 3949 5265 4434 4902 update-index
10565 5975 7770 6243 7287 update-nonindex
17408 11522 11020 10492 10717 read-only.range10
11262 6947 6887 6513 6726 read-only.range100
2611 1578 1576 1577 1627 read-only.range1000
277 163 166 161 164 read-only.range10000
20406 11671 11350 10978 11348 point-query

The last table shows the QPS for InnoDB relative to InnoDB in MySQL 5.6.35. Most of the QPS regression is from MySQL 5.6 to 5.7. For the update tests, InnoDB loses about 25% of QPS in MySQL 5.7.17 and about 15% in MySQL 8.0.1 with the default value of innodb_purge_threads, which is 4. Note that this server has 2 CPU cores and 4 hardware threads.

5635 5717-p4 5717-p1 801-p4 801-p1
1.00 .69 .92 .77 .86 update-index
1.00 .57 .74 .59 .69 update-nonindex
1.00 .66 .63 .60 .62 read-only.range10
1.00 .62 .61 .58 .60 read-only.range100
1.00 .60 .60 .60 .62 read-only.range1000
1.00 .59 .60 .58 .59 read-only.range10000

Wednesday, June 21, 2017

Linux perf and the CPU regression in MySQL 5.7

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

I used Linux perf to get more details on system performance while running the point-query test with modern sysbench. This is for an in-memory workload and part of my series on low-concurrency CPU regressions for bug 86215.

tl;dr

I have more explaining to do
The increase in instructions/query explains the decrease in queries/second from MySQL 5.6 to 5.7 to 8.0.

Configuration

I tested MySQL using upstream 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. My servers are described here and are named i3 NUC and i5 NUC.

My usage of sysbench, including the tests run, and the my.cnf used for each database engine is described here for MySQL 5.6, 5.7 and 8. The my.cnf files I share were for the i3 NUC. For the i5 NUC the InnoDB buffer pool and IO capacity options were increased using these values. The my.cnf files are here for 5.0, 5.1 and 5.5. I use the same server for mysqld and the sysbench clients. The binlog is enabled but sync-on-commit is disabled. Sysbench is run with 4 tables and 1M rows per table.

After loading the tables via the sysbench prepare option I ran the update-index test for a few minutes and then ran point-query with 1 client. After letting point-query warm up for 60 seconds I used this script to collect data from Linux perf. Output from Linux perf is here:

MySQL 5.6.35 for the i3 NUC and i5 NUC
MySQL 5.7.17 for the i3 NUC and i5 NUC
MySQL 8.0.1 for the i3 NUC and i5 NUC

Results

The charts below show the queries/second and instructions/query for each server/release with the point-query sysbench test and 1 client. For the i3 NUC the regression is from MySQL 5.7.17 to 8.0.1. For the i5 NUC it is from 5.6.35 to 5.7.17. Hopefully I will explain why the results are different between the i3 and i5 NUC servers. I am still collecting results from the CPUs I use at work and they don't match what I report here. So I have some explaining to do.

But it is clear to me that the increase in instructions/query explains the decrease in queries/second. Note that I run the sysbench client on the same host as mysqld so the instructions/query overhead includes the sysbench client and the real regression from MySQL 5.6 to 8.0 would be larger were that excluded.

Bar

Monday, June 19, 2017

Impact of perf schema on sysbench at low concurrency

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

As I document the low-concurrency CPU regressions in MySQL 5.7 and 8 one of the questions is whether the performance schema is part of the problem. I don't think it is as the worst-case overhead I measure is about 7% and the typical overhead is less than 5% for a single-threaded & in-memory workload.

Eventually I will repeat this test for workloads with more concurrency because there are overheads that won't be apparent at low-concurrency. The overhead is larger for simple queries, like sysbench point-query, and larger for complex queries. The overhead is also larger for in-memory workloads.

tl;dr - it isn't the perf schema

Configuration

I tested MySQL using upstream 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. My servers are described here but I only share results for the i5 NUC.

I enabled support for the performance schema at compile time. When tests were run I set performance_schema to 1 to enable it and to 0 to disable it. Nothing else was set in my.cnf for the perf schema.

My usage of sysbench, including the tests run, and the my.cnf used for each database engine is described here for MySQL 5.6, 5.7 and 8. The my.cnf files I share were for the i3 NUC. For the i5 NUC the InnoDB buffer pool and IO capacity options were increased using these values. I use the same server for mysqld and the sysbench clients. The binlog is enabled but sync-on-commit is disabled. Sysbench is run with 4 tables and 1M rows per table for 1, 2 and 4 concurrent clients. The database fits in the InnoDB buffer pool.

Results

The QPS for all tests is here. The next table is QPS relative to MySQL 5.6.35 with the perf schema enabled for each engine/configuration. For each release there isn't much difference between enabling (*-ps) and disabling (*-nops) the perf schema.

legend:
* 56-ps, 56-nops - 5.6.35 with and without perf schema
* 57-ps, 57-nops - 5.7.17 with and without perf schema
* 80-ps, 80-nops - 8.0.1 with and without perf schema

56-ps 56-nops 57-ps 57-nops 80-ps 80-nops release/test
1.00 1.02 0.66 0.68 0.73 0.76 update-index
1.00 1.02 0.57 0.59 0.61 0.64 update-nonindex
1.00 1.03 0.59 0.61 0.58 0.60 read-write.range100
1.00 1.03 0.59 0.59 0.58 0.58 read-write.range10000
1.00 1.05 0.61 0.61 0.57 0.60 read-only.range10
1.00 1.03 0.60 0.60 0.60 0.60 read-only.range10000
1.00 1.05 0.60 0.59 0.56 0.60 point-query
1.00 1.02 0.69 0.73 0.67 0.68 insert

The next table is the relative QPS for MySQL version X without the perf schema relative to the QPS for version X with the perf schema. It shows the relative the gain in QPS from disabling the perf schema for a given release. The maximum gain is about 7% but in most cases it is less than 5%. So the perf schema overhead doesn't explain the CPU regression from MySQL 5.6 to 8. It isn't a surprise that the largest overhead occurs for the point-query test because that test has the least complex queries.

5.6 5.7 8.0 release/test
1.02 1.03 1.04 update-index
1.02 1.03 1.05 update-nonindex
1.03 1.02 1.03 read-write.range100
1.03 1.00 1.00 read-write.range10000
1.05 1.00 1.05 read-only.range10
1.03 1.01 1.00 read-only.range10000
1.05 0.99 1.07 point-query
1.02 1.06 1.02 insert

Charts

Finally I have charts of the QPS for all tests. I don't have commentary for each chart. For the results below I use -ps for configurations when the perf schema was enabled and -nops when it was disabled.

Friday, June 16, 2017

Sysbench for MySQL 5.0, 5.1, 5.5, 5.6, 5.7 and 8

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

After sharing results for in-memory sysbench with MySQL 5.6, 5.7 and 8 I was curious about older releases and here I have results for MySQL 5.0, 5.1 and 5.5 in addition to 5.6, 5.7 and 8. This is one more result in my series on low-concurrency performance regressions.

tl;dr

MySQL 4.1 and 5.5 weren't great releases for performance. I skipped both in production.
The biggest drop in QPS between releases is from 5.6 to 5.7 and that drop often exceeds the drop from 5.0 to 5.6. What happened? Bug 86215 is open for this.

Configuration

I tested MySQL using upstream 5.0.96, 5.1.72, 5.5.51, 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I used the latin1 charset and latin1_swedish_ci collation. My servers are described here but I only share results for the i5 NUC.

I was able to compile and run MySQL 4.1.22 on the same server but have yet to share the results. The results weren't good and that matches my memory of 4.1 not being a great release. MySQL 4.0 was an awesome release but I have yet to get it running on Ubuntu 16.04 with gcc 4.7 or 4.8. There are segfaults soon after startup.

My usage of sysbench, including the tests run, and the my.cnf used for each database engine is described here for MySQL 5.6, 5.7 and 8. The my.cnf files I share were for the i3 NUC. For the i5 NUC the InnoDB buffer pool and IO capacity options were increased using these values. The my.cnf files are here for 5.0, 5.1 and 5.5. I use the same server for mysqld and the sysbench clients. The binlog is enabled but sync-on-commit is disabled. Sysbench is run with 4 tables and 1M rows per table for 1, 2 and 4 concurrent clients. The database fits in the InnoDB buffer pool.

Results

The QPS for all tests is here. Charts for some of the tests are below.

The table below lists the QPS relative to MySQL 5.0 for each test. When the value is 0.53 (see update-index for MySQL 8) then MySQL 8 gets 53% of the QPS compared to MySQL 5.0 and 5.0 is almost 2X faster. As reported in previous posts, the regression from 5.6 to 5.7 is large. Fortunately that performance loss hasn't been repeated from 5.7 to 8.

This gives me hope. At first I thought the problem was a steady loss of performance in each major release as features are added and code paths get longer. But now it looks like most of the problem arrived with MySQL 5.7. Maybe we can fix this.

5.0 5.1 5.5 5.6 5.7 8 release/test
---- ---- ---- ---- ---- ----
1.00 0.89 0.73 0.73 0.49 0.53 update-index
1.00 0.89 0.59 0.72 0.41 0.44 update-nonindex
1.00 0.92 0.99 1.04 0.62 0.60 read-write.range100
1.00 0.95 0.92 0.85 0.50 0.49 read-write.range10000
1.00 0.92 0.89 0.92 0.56 0.52 read-only.range10
1.00 0.95 0.92 0.84 0.50 0.50 read-only.range10000
1.00 0.85 0.77 0.76 0.45 0.42 point-query
1.00 0.95 0.93 1.22 0.84 0.82 insert

Charts

For update-index the biggest drop in QPS is from 5.6 to 5.7.

For update-nonindex the biggest drop in QPS is from 5.6 to 5.7. There is also a big drop from 5.1 to 5.5, but that is fixed in 5.6. Looks like 5.5 was a lousy release for performance.

For read-write.range100 the biggest drop in QPS is from 5.6 to 5.7.

For read-write.range10000 the biggest drop in QPS was from 5.6 to 5.7.

For read-only.range10 the biggest drop in QPS is from 5.6 to 5.7.

For read-only.range10000 the biggest drop in QPS is from 5.6 to 5.7.

For point-query the biggest drop in QPS is from 5.6 to 5.7.

For insert the QPS regression is small.

Monday, June 12, 2017

Linkbench, IO-bound & Intel NUC for MySQL 5.6, 5.7 & 8

Update - the regression isn't as bad as I have been reporting. Read this post to understand why.

Next up in my series on low-concurrency performance is Linkbench on Intel NUC servers with an IO-bound workload. The working set is larger than RAM and there many reads from and writes to storage. This is part of my work on bug 86215 and will be my last blog post on the topic for a few weeks. For more on Linkbench read the Facebook post and paper and my latest post.

tl;dr

For the i5 NUC at least 2/3 of the regression is from MySQL 5.6 to 5.7 and the remainder from 5.7 to 8. Most of this is explained by more CPU overhead in 5.7 and 8.
For the i3 NUC there is more variance, but that has a slower and older CPU that is less interesting to me. At this point I think the i3 NUC is useful to test builds and run MTR but not to test performance.

Configuration

I tested MySQL using upstream 5.6.35, 5.7.17 and 8.0.1. For 8.0.1 I repeated the test: first with the default charset/collation and then with latain1/latin1_swedish_ci.

My servers are described here. The charts below refer to the servers as i3 NUC and i5 NUC. Compared to the i3 NUC, the i5 NUC is newer, has a CPU that is 2X faster, 2X more RAM, 2X more storage and storage that is more than 2X faster.

The my.cnf used for each database engine is described here. The my.cnf files I share were for the i3 NUC. For the i5 NUC the InnoDB buffer pool and IO capacity options were increased using these values. I use the same server for mysqld and the sysbench clients. The binlog is enabled but sync-on-commit is disabled.

For this test I used maxid1=40M in the Linkbench configuration for the i3 NUC and maxid1=80M for the i5 NUC. I use Linkbench from here and helper scripts from here. My usage of Linkbench is described here. A sample command line to run the tests is:

bash all.sh rx ~/bin/mysql /data/m/data 40000001 sdb 1 3600 mysql lb.sql.inno 24 127.0.0.1 1

Results

The first pair of charts shows the absolute and relative insert rates during the load test. For the i3 NUC there is a regression from MySQL 5.6 to 5.7 but not to 8. Results for many of my tests have been less predictable on the i3 NUC perhaps because it has a much slower and older CPU. For the i5 NUC most of the regression is from MySQL 5.6 to 5.7.

The next pair of charts show the absolute value for CPU per insert followed by the inverse of the relative rates. The absolute value comes from the Mcpu/t column in my performance data. The i3 NUC results continue to be odd for MySQL 8. For the i5 NUC most of the CPU regression is from MySQL 5.6 to 5.7. For the i5 NUC the inverse of CPU per insert values are similar to the relative insert rates above and the CPU regression explains the drop in insert rates from MySQL 5.6 to 5.7 and 8.

The next pair of charts show the absolute transactions/second rates and the the rates relative to the value for MySQL 5.6. These are from the 24th hour of the transaction test. For the i3 NUC about 1/3 of the regression is from MySQL 5.6 to 5.7. For the i5 NUC about 2/3 of the regression is from MySQL 5.6 to 5.7.

The final pair of charts shows the absolute value for CPU per transaction followed by the inverse of the value relative to MySQL 5.6. These are from the 24th hour of the transaction test. The absolute value is from the Mcpu/t column in the performance data. For the i3 NUC about 1/3 of the CPU regression is from MySQL 5.6 to 5.7 and for the i5 NUC most of the regression is from MySQL 5.6 to 5.7. The second chart shows that the inverse of the relative CPU predicts the transaction rate and the CPU regression explains the transaction rate regression.

Metrics

All of the performance data is here and explained by a previous post.