Small Datum

Wednesday, December 1, 2021

Sysbench: MySQL 5.6, 5.7 & 8.0 on a small server

This has results for sysbench with MySQL versions 5.6.49, 5.7.35 and 8.0.2x using the same setup as previously used for the insert benchmark. The versions for 8.0.2x are 8.0.20, 8.0.22, 8.0.23, 8.0.26 and 8.0.27.

Executive summary:

For CPU-bound setups, MySQL 8.0.27 is slower than 5.6.49 on 39 of the 42 microbenchmarks. For the microbenchmarks when it was slower, on average it gets 72% of the throughput vs 5.6.49.
For IO-bound setups, MySQL 8.0.27 is slower than 5.6.49 on 27 of the 42 microbenchmarks, faster on 13 and had the same throughput on 2.
In most cases more CPU overhead in 8.0 is the reason it is slower than 5.6.

Details

See the Postgres post for more details on how I run sysbench. The summary is there are 43 invocations of sysbench and each is a microbenchmark. But a typo meant I only have results for 42 of the 43.

Three configurations were tested: 10M rows without prepared statements, 10M rows with prepared statements, 400M rows without prepared statements. The 10M row tests are CPU-bound as the database fits in memory. The 400M row test is usually IO-bound as the database is larger than memory. Below I call the test configurations 10m.prep0, 10m.prep1 and 400m.prep0. The database sizes are 2.9G at 10M rows and 91G at 400M rows after the initial load.

One of my goals was to understand the impact of using prepared statements with MySQL especially with respect to CPU overhead. They didn't make a big difference with the exception of the one test for which there is a performance bug with prepared statements (random-points.pre.range1000.pk1).

How to read the results

The presentation for these results is just text files pasted into gists. There are two types of files: qps and metrics.

The qps file has the relative QPS for each test where the relative QPS is the ratio: QPS-for-me / QPS-for-base.

QPS-for-me is the QPS for one of MySQL 5.6.49, 5.7.35 or 8.0.2x
QPS-for-base is the QPS for MySQL 5.6.49
Thus each line in the qps file has seven numeric columns and the first one has the value 1.00 (QPS-for-5.6.49 / QPS-for-5.6.49). The second through seventh columns have the values for (QPS-for-me / QPS-for-5.6.49) where me is 5.7.35, 8.0.20, 8.0.22, 8.0.23, 8.0.26 and 8.0.27 in that order. When the value in a column is less than 1.0 then that version is slower than 5.6.49.

The metrics file has absolute and relative (to results for 5.6.49) values for each of the 42 tests. This file is long so I start with the qps file and then consult the metrics file to understand why one result is better than another.

cpu/o - CPU per operation, measured by iostat. While there is a unit for this, I don't worry about that as it is most useful for comparing numbers between different test configurations so the units drop out.
r/o - storage reads per operation, measured by iostat
rKB/o - KB read from storage per operation, measured by iostat
wKB/o - KB written to storage per operation, measured by iostat
o/s - operations/second (QPS, inserts/s, etc). I tend to use QPS below for everything.
dbms - the MySQL version and configuration file

Results

Here are the qps and metrics files for the 10m.prep0 (CPU-bound, no prepared statements):

8.0.27 is faster than 5.6.49 on 3 of 42 tests (read-only.pre.range10000,pk1, read-only.range10000.pk1, update-index.range100,pk1). The first two do long range scans and the relative QPS is 1.25. For the update-index test the relative QPS is 1.48.
The relative QPS for 8.0.27 is less than 0.8 for 35 of the 42 tests. This means that 8.0.27 gets less than 80% of the throughput relative to 5.6.49 on 35 of the tests. The minimum relative QPS is 0.61. For the 39 tests on which 8.0.27 is slower than 5.6.49 the average of the relative QPS is 0.72.
For the tests in which the relative QPS in 8.0.27 is much less than one the cause is using more CPU/query. See the cpu/o column in the metrics file.
The speedup for update-index is harder to explain. 8.0.2x uses less CPU, but the difference isn't large enough to explain the improvement. The speedup for the read-only tests is mostly from using less CPU/query in 8.0.2x. See the cpu/o column in the metrics file.

Here are the qps and metrics files for the 10m.prep1 (CPU-bound, prepared statements):

Results are similar to 10m.prep0
8.0.27 is faster than 5.6.49 3 of 42 tests. The relative QPS is 1.24 for the read-only tests that do long range scans and 1.54 for the update-index test.
The relative QPS for 8.0.27 is less than 0.8 for 35 of the 42 tests.
The minimum relative QPS is 0.30 for random-points.pre.range1000.pk1 (AFAIK there is a known perf bug in the optimizer). MySQL 8.0.2x uses more than 3X CPU/query compared to 5.6.49. See the cpu/o column in the metrics file.
For the 39 tests on which 8.0.27 is slower than 5.6.49 the average of the relative QPS is 0.70.

Here are the qps and metrics files for the 400m.prep0 (IO-bound, no prepared statements):

8.0.27 is faster than 5.6.49 for 13 of the 42 tests (tests are listed below)
8.0.27 matched 5.6.49 QPS for 2 of the 42 tests (random-points.pre.range1000.pk1, random-points.range1000.pk1)
The relative QPS for 8.0.27 is less than 0.8 for 8 of the 42 tests (tests are listed below)
For the 27 tests on which 8.0.27 is slower than 5.6.49 the average of the relative QPS is 0.84

Relative QPS for 8.0.27 vs 5.6.49 when 8.0.27 is faster for the IO-bound tests:

1.22 point-query.pre.range100.pk1
1.02 random-points.pre.range10.pk1
1.05 read-only.pre.range100.pk1
1.13 read-only.pre.range10000.pk1
1.03 range-covered-pk.pre.range100.pk1
1.02 range-notcovered-pk.pre.range100.pk1
1.12 update-inlist.range100.pk1
1.17 read-only.range100.pk1
1.14 read-only.range10000.pk1
1.03 point-query.range100.pk1
1.05 random-points.range10.pk1
1.05 range-covered-pk.range100.pk1
1.06 range-notcovered-pk.range100.pk1

Relative QPS for 8.0.27 vs 5.6.49 when 8.0.27 is much slower for the IO-bound tests:

0.75 range-covered-si.pre.range100.pk1
0.68 update-one.range100.pk1
0.73 update-zipf.range100.pk1
0.55 read-write.range10.pk1
0.65 hot-points.range100.pk1
0.75 range-covered-si.range100.pk1
0.79 scan.range100.pk1
0.60 insert.range100.pk1

Sysbench: PostgreSQL 12, 13 and 14 on a small server

This has results for sysbench with PostgreSQL versions 12.4, 13.4 and 14.0 using the same setup as previously used for the insert benchmark.

Executive summary:

Postgres continues to be boring. There are a few regressions and more improvements.
There were ~40 tests and each ran for 5 minutes. Running each test for such a short time means there is more chance for confusing results. Alas, running each test for 30 minutes or more would have taken too long because I repeated the benchmark many times for different DBMS, configurations and database sizes. I started another round just for the Postgres IO-bound configuration that will take about 3 days to get results.

Details

See the insert benchmark post for more details on the hardware and Postgres configurations. As always, there are layers upon layers of shell scripts. The file all_small.sh lists the sequence in which the test steps are run and each step is run for 300 seconds with 1 connection (low concurrency!). From the all_small.sh script there were 42 different invocations of sysbench, each one is a microbenchmark. There should have been 43 but a typo got in the way. From 42 X 5 minutes for the tests plus more time for the load it takes 4 to 8 hours for all_small.sh to get results for each DBMS + configuration.

Three configurations were tested: 10M rows without prepared statements, 10M rows with prepared statements, 400M rows without prepared statements. The 10M row tests are CPU-bound as the database fits in memory. The 400M row test is usually IO-bound as the database is larger than memory. Below I call the test configurations 10m.prep0, 10m.prep1 and 400m.prep0. The database sizes are 2.6G at 10M rows and 99G at 400M rows after the initial load.

All of the shell scripts are here and the tests were run using a script like this.

I use my fork of sysbench that includes a few more tests (Lua scripts). The Lua scripts are here. My fork might be a few years behind upstream.

How to read the results

The presentation for these results is just text files pasted into gists. There are two types of files: qps and metrics.

The qps file has the relative QPS for each test where the relative QPS is the ratio: QPS-for-me / QPS-for-base.

QPS-for-me is the QPS for one of Postgres 12.4, 13.4 or 14.0
QPS-for-base is the QPS for Postgres 12.4.
Thus each line in the qps file has three numeric columns and the first one has the value 1.00 (QPS- for-12.4 / QPS-for-12.4). The value in the second column is the QPS for 13.4 relative to 12.4, and in the third is the QPS for 14.0 relative to 12.4. When the value in the second or third column is less than 1.0 then that version is slower than 12.4.

The metrics file has absolute and relative (to results for 12.4) values for each of the 42 test steps. This file is long so I start with the qps file and then consult the metrics file to understand why one result is better than another.

cpu/o - CPU per operation, measured by iostat. While there is a unit for this, I don't worry about that as it is most useful for comparing numbers between different test configurations so the units drop out.
r/o - storage reads per operation, measured by iostat
rKB/o - KB read from storage per operation, measured by iostat
wKB/o - KB written to storage per operation, measured by iostat
o/s - operations/second (QPS, inserts/s, etc). I tend to use QPS below for everything.
dbms - the Postgres version and configuration file

Results

Here are the qps and metrics files for the 10m.prep0 (CPU-bound, no prepared statements):

scan.range.pk1 has a regression in 13.4 that was mostly fixed in 14.0. The QPS relative to 12.4 is 0.82 for 13.4 and 0.96 for 14.0. From the metrics file there is a 30% increase in CPU overhead (see the cpu/o column) in 13.4. The scan test does a full scan of the test table using a WHERE clause that filters all rows: SELECT * from %s WHERE LENGTH(c) < 0.

Here are the qps and metrics files for the 10m.prep1 (CPU-bound, prepared statements):

Results are similar to 10m.prep0, the only regression is for scan.range.pk1 for 13.4.

Here are the qps and metrics files for the 400m.prep0 (IO-bound, no prepared statements):

scan.range.pk1 has a regression from CPU overhead for 13.4
read-write.range10.pk has a ~10% regression in 13.4 and 14.0. The biggest difference from the metrics file is for wKB/o. Perhaps this test needs to run for more time to get a better signal.
Five of the tests improve by ~10% or more in 13.4 and 14.0. I don't count the improvement for random-points.pre.range1000.pk1 because the QPS is too small (5 & 6) and rounding might explain the difference. Reduced CPU/query doesn't explain all of the improvements as in many cases there is also less IO/query but my Postgres expertise isn't strong enough to have a good guess. There have been improvements to vacuum and b-tree indexes that are likely part of the reason.

Tuesday, November 30, 2021

Insert benchmark: MySQL 5.6, 5.7 & 8.0 on a small server

I have another performance report for the insert benchmark using MySQL 5.6, 5.7 and 8.0 on a small server. As normal, I had to repeat the tests a few times: I make mistakes and also want results for new my.cnf settings. The goal for the tests is to understand how low-concurrency performance changes in new MySQL releases. Low-concurrency tests are great for finding CPU regressions. High-concurrency tests are also great but I only have small servers at home.

For the CPU-bound setup, new MySQL (8.0) gets between 10% and 37% less throughput than old MySQL (5.6) because 8.0 uses more CPU/query. The increase in CPU/query for MySQL from 5.6 to 8.0 is large while PostgreSQL avoids CPU regressions from 12.4 to 14.0.

Disclaimers:

Be careful about interpreting these results, the context here is a workload with simple queries.
These results have yet to be reviewed by others. There can be mistakes.
8.0.20 and 8.0.22 were exciting releases. Performance is slowly improving since then.

Details

Tests were run for MySQL versions 5.6.49, 5.7.35, 8.0.20, 8.0.22, 8.0.23, 8.0.26 and 8.0.27. I try to use similar my.cnf settings except when new versions have new features. The options are in the my56, my57 and my80 directories here (look for my.cnf.cy8). Scripts to build MySQL from source are here for MySQL 5.6, 5.7 and 8.0. One of the big changes I made was to add innodb_log_writer_threads=OFF to the MySQL 8.0 my.cnf settings. Without that the CPU overhead was much worse.

The test servers have 4 cores and tests were run with either 1 insert connection or 2 connections (rate limited inserts, not rate-limited queries). This page has links to explain the insert benchmark and perf report format. The test was run in CPU-bound and IO-bound modes. For each mode, X rows were inserted into a table without a secondary index, then 3 secondary indexes were created, then Y more rows were inserted. The values for X and Y were (20M, 20M) for CPU-bound and (500M, 10M) for IO-bound. After the inserts there were three insert+query steps where the insert connection was rate-limited to 100, 500 and 1000 inserts/s. Each query step was run for 2 hours.

The test server uses Ubuntu 20.04, gcc-9.3.0-17 and uname -a shows 5.4.0-89-generic. The database filesystem uses XFS with discard enabled.

Results

I have shell scripts to generate perf reports. The reports for CPU-bound and IO-bound are here and here. Below I use throughput ratios where the denominator is the value for MySQL 5.6.49 and the numerator is the value for another version. A value less than 1.0 means the new version is slower than 5.6.49.

Comments on CPU-bound (see the summary):

for the l.i0 test (inserts without secondary indexes) the throughput ratio is 0.63 for 8.0.27. The slowdown is explained by an increase in CPU/query. See the cpupq column here that is 15 for 5.6.49 and 21 for 8.0.27.
for the l.i1 test (inserts with secondary indexes) the throughput ratio is 0.73 for 8.0.27. The slowdown is explained by an increase in CPU/query. See the cpupq column here that is 32 for 5.6.49 and 43 for 8.0.27.
for the q100.1, q500.1 and q1000.1 tests the throughput ratios using the qps columns are 0.81, 0.76 and 0.74 for 8.0.27. This is probably explained by more CPU/query. See the cpupq columns for q100.1, q500.1 and q1000.1. The throughput ratios were much better for 8.0.22 than for 8.0.27 (0.94, 0.89 and 0.86) but I have not attempted to debug that. I was unable to explain why the wkbpi column is larger for 8.0.27 than 5.6.49 and larger means more write-amp (KB written/insert). It was larger for 8.0.27 when measured by iostat, but smaller when measured by global status counters like Innodb_dblwr_pages_written, Innodb_os_log_written, Innodb_data_written and Innodb_buffer_pool_pages_flushed. This remains a mystery. I am not sure it is possible to configure InnoDB writeback in 8.0 to match 5.6. The only difference in the my.cnf settings is the use of innodb_idle_flush_pct=1 for the 8.0 my.cnfs.

Comments on IO-bound (see the summary):

for the l.i0 test (inserts without secondary indexes) results are similar to the CPU-bound results above because this step is still CPU-bound, 8.0 is slower because it uses more CPU/query. See here.
for the l.x test (create index) 8.0 is faster than 5.6. I think significant changes were done for InnoDB create index. See here.
for the l.i1 test (inserts with secondary indexes) results for 8.0.26 & 8.0.27 are better than 5.6.49, but results for 8.0.20 and 8.0.22 and 8.0.23 is in between. With the new release process there can be significant changes for performance between point releases. See the ips column here. I think this is related to the big changes to redo log code in 8.0 as CPU/query (cpupq) and context switches/query (cspq) were larger in 8.0.20 and 8.0.22.
for the q100.1, q500.1 and q1000.1 tests the throughput ratios are larger than 1 as 8.0 is faster than 5.6, except for 8.0.20 which appears to be an exciting release. See the qps and cpupq columns here. MySQL 8.0.27 uses less CPU/query than 5.6.49.

Insert benchmark: PostgreSQL 12, 13 and 14 on a small server

I have another performance report for the insert benchmark using PostgreSQL 12.4, 13.4 and 14.0 on a small server. As normal, I had to repeat the tests a few times: I make mistakes and sometimes need results for new tuning options. The goal for the tests is to understand how low-concurrency performance changes in new PostgreSQL releases. Low-concurrency tests are great for finding CPU regressions. High-concurrency tests are also great but I only have small servers at home.

Executive summary:

Postgres is boring. There were no regressions.

Details

Tests were run for Postgres versions 12.4, 13.4 and 14.0. I used the same configuration file (see here). The script to build Postgres from source is here.

The test servers have 4 cores and tests were run with either 1 insert connection or 2 connections (rate limited inserts, not rate-limited queries). This page has links to explain the insert benchmark and perf report format. The test was run in CPU-bound and IO-bound modes. For each mode, X rows were inserted into a table without a secondary index, then 3 secondary indexes were created, then Y more rows were inserted. The values for X and Y were (20M, 20M) for CPU-bound and (500M, 10M) for IO-bound. After the inserts there were three insert+query steps where the insert connection was rate-limited to 100, 500 and 1000 inserts/s. Each query step was run for 2 hours.

The test server uses Ubuntu 20.04, gcc-9.3.0-17 and uname -a shows 5.4.0-89-generic. The database filesystem uses XFS with discard enabled.

Results

I have shell scripts to generate perf reports. The reports for CPU-bound and IO-bound are here and here. From the CPU-bound (see the summary) and IO-bound results (see the summary):

Postgres is boring. There were no regressions.

Sunday, November 21, 2021

Welll actually, LSM and B-tree

Things I read about LSM that make me go well actually:

LSM does sequential writes - well actually, writes are sequential logically (per-file) but not physically (per-device). From the physical perspective compaction writes are large & concurrent rather than sequential. Compaction writes to files sequentially but it is usually concurrent (multi-threaded) with a file written sequentially per-thread. There can also be small writes to the WAL. With concurrent compaction threads the large (maybe 1MB+) writes are interleaved at the device.
Compaction does merge-sort - well actually, that is a k-way merge, not a merge-sort.
Leveled compaction suffers from write-amplification - well actually, write-amplification was 10X smaller with MyRocks when the first workload was moved to it from InnodDB. Write-amp with leveled compaction is larger than with tiered, but that is the (C)RUM Conjecture in action: leveled means less space-amp at the cost of more write-amp. One of the problems is that the naive (hand-wavy) estimate of write-amp for leveled (~8 or ~10 per level) is frequently too pessimistic.
LSM suffers from write stalls - well actually, that is more true than the previous bullet points. But the real problem for an LSM is figuring out how to smooth the write stalls (reduce response time variance) and RocksDB needs to get better at that. Everything (b-tree, LSM, etc) suffers from write-stalls when ingest exceeds write back throughput and the easy way to reproduce that is a benchmark with WAL fsync disabled. A b-tree benefits from feedback that serves as a small write-stall - when the buffer pool is full of dirty pages and the working set is not cached then a write likely needs to wait for 1 page to be written back before it can read something into the buffer pool. But an LSM doesn't have that feedback as a write usually just needs something to be put into the memtable, non-unique secondary index maintenance doesn't require reads, and even reads needed to check unique constraints (likely for a PK) can be avoided in some cases with bloom filters. Checkpoint is one place where a b-tree can suffer from large write stalls. Not that many years ago the insert benchmark was great at documenting longer write-stalls related to checkpoint in InnoDB and WiredTiger. Fortunately those have been fixed. Postgres also had serious problems, now fixed, from checkpoint IO creating bursts of write IO that starve other IO (like reads for user queries). Checkpoint is a hard problem.

Saturday, November 13, 2021

DeWitt Clause vs the public cloud

The DeWitt Clause is the name of a clause in the terms of service that prevents a customer from disclosing performance of a licensed product. Things turned out OK for David DeWitt and he even went on to work for at least one company that now uses a DeWitt Clause for their database products.

I am not a lawyer but I have a strong opinion on the DeWitt Clause and non-compete agreements. I think both are anti-competitive and hope more is done to limit their usage.

One of the arguments for DeWitt Clauses is that benchmarking is hard, others will get it wrong and that can mislead customers. While the first parts are correct (it is hard, people will get it wrong) the last clause feels like a bad faith argument to me. Vendors haven't always pursued truth while running their benchmarks. I agree there will be plenty of benchmarketing in a world without DeWitt Clauses. I think the benefits outweigh the problems.

Database vendors

We used to think of this as a thing for legacy enterprise database vendors and many of the new vendors don't use it -- not MongoDB Atlas as of 24-Jun-2021, not CockroachDB as of 19-Oct-2021, not TimescaleDB as of 24-Sep-2020 and 5-Mar-2019, not Altinity as of 1-Jul-2021.

But other new vendors use it and this became news after Databricks published a great result for 100TB TPC-DS and a less than great result for SnowflakeDB. They then changed their license to the DeWitt Embrace Clause which is like copyleft for the DeWitt Clause. This means that if you disclose benchmark results for them, they are allowed to do the same for you. I hope the DeWitt Embrace Clause is embraced by more vendors who use a DeWitt Clause.

For the record, Snowflake quickly replied to the Databricks result. Frankly, I prefer to see a benchmarketing battle between Snowflake and Oracle. But it is awesome that the Snowflake response explains that anyone can repeat their result by signing up, spending about $300 and clicking a few buttons. Cloud DBMS is fun. The Snowflake ToS (as of 1-Nov-2021) don't have a DeWitt Clause.

Public cloud vendors

Switching from managed database providers to public cloud vendors the DeWitt Clause usage is interesting. From what I was able to find, Microsoft has the worst terms followed by Google:

AWS (as of 28-Oct-2021) allows benchmark disclosure via the DeWitt Embrace Clause
Microsoft was harder to find docs on. In this undated agreement if you offer a service on Azure that competes with them, then they are allowed to benchmark and disclose the results of your service. This is far more aggressive than any DeWitt Clause variant. But I didn't find any other mention of benchmarks (to allow or prevent them for Azure).
Oracle (a PDF dated 22-Jun-2020) has a DeWitt Clause and requires pre-approval for disclosure. They also don't allow performing a benchmark without pre-approval.
Google (as of 18-Oct-2021) has a DeWitt Clause and requires pre-approval for disclosure. They bans competitors from running benchmarks even when not disclosed. They added the DeWitt Clause on 6-Oct-2020.

Public cloud benchmarks

Examples of useful public cloud benchmarks that will be prevented in the future by DeWitt Clauses. I will add to this list as I look for them. For now there was just one from long ago that triggered this post:

Public cloud object storage perf by Zach Bjornson

More on Microsoft

This is the part in the Microsoft agreement that seems aggressive:

If Customer offers a service competitive to an Online Service, by using the Online Service, Customer agrees to waive any restrictions on competitive use and benchmark testing in the terms governing its competitive service. If Customer does not intend to waive such restrictions in its terms of use, Customer is not allowed to use the Online Service.

Wednesday, October 13, 2021

Compatible with MySQL or Postgres?

Open and closed source scale-out DBMS that are compatible with MySQL and Postgres have emerged on the market. This is great for the community but there will be much confusion about the meaning of compatible.

This post has yet to have anything on the cloud vendors in China. They are doing impressive work but I don't know enough about it. I am happy to update this post when I learn more.

But first, the MySQL and Postgres teams.

Team MySQL includes PlanetScale (Vitess), PingCAP (TiDB), Amazon (Aurora), MariaDB (Xpand), SingleStore, ClickHouse and Dolt.
Team Postgres includes CockroachDB, Yugabyte, Google (Spanner), Amazon (Aurora & Redshift), Microsoft (CitusDB), TimescaleDB, CrateDB, YellowBrick, Greenplum and Materialize.
It wouldn't be fair to exclude MongoDB, so Team MongoDB is MongoDB, Amazon (DocumentDB) and Microsoft (Cosmos DB API for MongoDB). But the rest of the post is about MySQL and PG.

One way to describe compatibility is via three levels: protocol, syntax and semantics. By upstream I mean MySQL and PostgreSQL.

protocol - an app can use existing client libraries to authenticate and connect
syntax - the DBMS will parse SQL that upstream parses. It is not guaranteed to provide semantics that matches upstream and some syntax can be (or might be) parsed but ignored. Syntax compatible implies a best effort to match upstream semantics but that isn't guaranteed nor must it be guaranteed to be useful.
semantics - the DBMS will match upstream semantics. This implies syntax compatible.

Note that syntax and semantics compatibility aren't all or nothing. A syntax compatible DBMS can be useful without supporting (parsing) 100% of the upstream syntax. A semantics compatible DBMS can be useful without supporting or matching behavior for 100% of upstream syntax.

Also note that semantics compatible implies syntax compatible. But protocol compatible implies neither.

Elsewhere in DBMS land

While this post is about MySQL and PostgreSQL, compatibility is growing in popularity elsewhere:

MariaDB provides an Oracle compatible mode that provides syntax but not protocol or semantics compatibility.
EnterpriseDB provides an Oracle compatibility product that I don't know much about.
Amazon will soon open source Babelfish that is protocol compatible with SQL Server.
Amazon DocumentDB is protocol, syntax and semantics compatible with (an older version of) MongoDB. It supports some (much) of the MongoDB 4.0 API as of October, 2021 per Wikipedia. Public statements suggest this was built on top of, or reusing, the Aurora PostgreSQL code.

Updates

added TimescaleDB to Team Postgres
added Redshift to Team Postgres
added SingleStore to Team MySQL
added ClickHouse to Team MySQL
added CrateDB to Team Postgres
added Dolt to Team MySQL
added Team MongoDB
added YellowBrick and Greenplum to Team Postgres
added Materialize to Team Postgres
Building a DBMS to be compatible with MySQL costs more than for Postgres. The Team Postgres projects can reuse BSD licensed PG code while the Team MySQL projects would have to respect the GPL.
I have a vague memory of this but to be JDBC compliant the MySQL JDBC driver does a few queries at connect time (either via tables or session/global variables). My JDBC-related bugs are here.