Personal blog of Yzmir Ramirez

I often need to install a certain version of MySQL, MariaDB, or Percona Server for MySQL to run some experiments, whether to check for behavior differences or to provide tested instructions. In this blog series, I will look into how you can install MySQL, MariaDB, or Percona Server for MySQL with Docker.  This post, part one, is focused on MySQL Server.

Docker is actually not my most preferred way as it does not match a typical production install, and if you look at service control behavior or file layout it is quite different.  What is great about Docker though is that it allows installing the latest MySQL version – as well as any other version – very easily.

Docker also is easy to use when you need a simple, single instance.  If you’re looking into some replication-related behaviors, DBDeployer may be a better tool for that.

These instructions are designed to get a test instance running quickly and easily; you do not want to use these for production deployments. All instructions below assume Docker is already installed.

First, you should know there are not one but two “official” MySQL Docker Repositories.  One of them is maintained by the Docker Team and is available by a simple docker run mysql:latest.  The other one is maintained by the MySQL Team at Oracle and would use a docker run mysql/mysql-server:latest  syntax.  In the examples below, we will use MySQL Team’s Docker images, though the Docker Team’s work in a similar way.

Installing the Latest MySQL Version with Docker

docker run --name mysql-latest  \
-p 3306:3306 -p 33060:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:latest

This will start the latest version of MySQL instance, which can be remotely accessible from anywhere with specified root password.  This is easy for testing, but not a good security practice (which is why it is not the default).

Connecting to MySQL Server Docker Container

Installing with Docker means you do not get any tools, utilities, or libraries available on your host directly, so you either install these separately, access created instance from a remote host, or use command lines shipped with docker image.

To Start MySQL Command Line Client with Docker Run:

docker exec -it mysql-latest mysql -uroot -pstrongpassword

To Start MySQL Shell with Docker Run:

docker exec -it mysql-latest mysqlsh -uroot -pstrongpassword

Managing MySQL Server in Docker Container

When you want to stop the MySQL Server Docker Container run:

docker stop mysql-latest

If you want to restart a stopped MySQL Docker container, you should not try to use docker run to start it again. Instead, you should use:

docker start mysql-latest

If something is not right, for example, if the container is not starting, you can access its logs using this command:

docker logs mysql-latest

If you want to re-create a fresh docker container from scratch you can run:

docker stop mysql-latest
docker rm mysql-latest

Followed by the

docker run

 command described above.

Passing Command Line Options to MySQL Server in Docker Container

If you want to pass some command line options to MySQL Server, you can do it this way:

docker run --name mysql-latest  \
-p 3306:3306 -p 33060:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:latest \
--innodb_buffer_pool_size=256M \
--innodb_flush_method=O_DIRECT \

Running Different MySQL Server Versions in Docker

If you just want to run one MySQL version at a time in Docker container, it is easy – you can just pick the version you want with Docker Image Tag and change the Name to be different in order to avoid name conflict:

docker run --name mysql-8.0.17  \
-p 3306:3306 -p 33060:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:8.0.17

This will start MySQL 8.0.17 in Docker Container.

docker run --name mysql-5.7  \
-p 3306:3306 -p 33060:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:5.7

And this will start the latest MySQL 5.7 in Docker.

Running Multiple MySQL Server Versions at the Same Time in Docker

The potential problem of running multiple MySQL Versions in Docker at the same time is TCP port conflict.   If you do not access Docker Container from outside, and just run utilities included in the same container, you can just remove port mapping (-p option) and you can run multiple containers:

docker run --name mysql-latest  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:latest

docker run --name mysql-8.0.17  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:8.0.17

In more common cases when you need to access Docker containers externally, you will want to map them to use different external port names.   For example, to start the latest MySQL 8 at ports 3306/33060 and MySQL 8.0.17 at 3307/33070,  we can use:

docker run --name mysql-latest  \
-p 3306:3306 -p 33060:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:latest


docker run --name mysql-8.0.17  \
-p 3307:3306 -p 33070:33060  \
-e MYSQL_ROOT_HOST='%' -e MYSQL_ROOT_PASSWORD='strongpassword'   \
-d mysql/mysql-server:8.0.17

There are a lot more things to consider if you’re going to use MySQL on Docker for anything beyond testing.  For more information check-out the MySQL Server Page on Docker Hub and MySQL Manual.

Recently, at Percona Live Europe 2019, Dimitri Kravchuk from Oracle mentioned that he observed some unclear drop in performance for MySQL on an ext4 filesystem with the latest Linux kernels. I decided to check this case out on my side and found out that indeed, starting from linux kernel 4.9, there are some cases with notable (up to 2x) performance drops for ext4 filesystem in direct i/o mode.

So what’s wrong with ext4? It started in 2016 from the patch that was pushed to kernel 4.9: “ext4: Allow parallel DIO reads”. The purpose of that patch was to help to improve read scalability in direct i/o mode. However, along with improvements in pure read workloads, it also introduced regression in intense mixed random read/write scenarios. And it’s quite weird, but this issue had not been noticed for 3 years. Only this summer was performance regression reported and discussed in LKML. As a result of this discussion, there is an attempt to fix it, but from my current understanding that fix will be pushed only to upcoming 5.4/5.5 kernels. Below I will describe what this regression looks like, how it affects MySQL workloads, and what workarounds we can apply to mitigate this issue.

ext4 Performance Regression

Let’s start by defining the scope of this ext4 performance regression. It will only have an impact if the setup/workload meets following conditions:
– fast ssd/nvme
– linux kernel>=4.9
– files resides on ext4 file system
– files opened with O_DIRECT flag
– at least some I/O should be synchronous

In the original report to LKML, the issue was observed/reproduced with a mixed random read/write scenario with sync I/O and O_DIRECT. But how do these factors relate to MySQL? The only files opened by InnoDB in O_DIRECT mode are tablespaces (*.ibd files), and I/O pattern for tablespaces consists of following operations:

– reads ibd data in synchronous mode
– writes ibd data in asynchronous mode
– posix_allocate to extend tablespace file followed by a synchronous write
– fsync

There are also extra I/O from WAL log files:

– writes data to log files in synchronous mode
– fsync

So in the case of InnoDB tablespaces that are opened with O_DIRECT, we have a mix of sync reads and async writes and it turned out that such a combination along with sync writes to innodb log file is enough to cause notable performance regression as well. I have sketched the workload for fio tool (see below) that simulates the I/O access pattern for InnoDB and have run it for SSD and NVMe drives for linux kernels 4.4.0, 5.3.0, and 5.3.0 with ext4 scalability fix.

[global]
filename=tablespace1.ibd:tablespace2.ibd:tablespace3.ibd:tablespace4.ibd:tablespace5.ibd
direct=1
bs=16k
iodepth=1

#read data from *.ibd tablespaces
[ibd_sync_read]
rw=randread
ioengine=psync

#write data to *.ibd tavlespaces
[ibd_async_write]
rw=randwrite
ioengine=libaio

#write data to ib* log file
[ib_log_sync_write]
rw=write
bs=8k
direct=0
ioengine=psync
fsync=1
filename=log.ib
numjobs=1

fio results on the chart:

Observations:

– for SATA/SSD drive there is almost no difference in throughtput, and only at 16 threads do we see a drop in reads for ext4/kernel-5.3.0. For ext4/kernel-5.3.0 mounted with dioread_nolock (that enables scalability fixes), we see that IOPS back and even look better.
– for NVMe drive the situation looks quite different – until 8 i/o threads IOPS for both reads and writes are more/less similar but after increasing pressure on i/o we see a notable spike for writes and similar drop for reads. And again mounting ext4 with dioread_nolock helps to get the same throughput as and for kernels < 4.9.

The similar performance data for the original issue reported to LKML (with more details and analysis) can be found in the patch itself.

How it Affects MySQL

O_DIRECT

Now let’s check the impact of this issue on an IO-bound sysbench/OLTP_RW workload in O_DIRECT mode. I ran a test for the following setup:

– filesystem: xfs, ext4/default, ext4/dioread_nolock
– drives: SATA/SSD and NVMe
– kernels: 4.4.0, 5.3.0, 5.3.0+ilock_fix

Observations

– in the case of SATA/SSD, the ext4 scalability issue has an impact on tps rate after 256 threads and drop is 10-15%
– in the case of NVMe and regular ext4 with kernel 5.3.0 causes performance drop in ~30-80%. If we apply a fix by mounting ext4 with dioread_nolock or use xfs,  throughput looks good.

O_DSYNC

As ext4 regression affects O_DIRECT, let’s replace O_DIRECT with O_DSYNC and look at results of the same sysbench/OLTP_RW workload on kernel 5.3.0:

Note: In order to make results between O_DIRECT and O_DSYNC comparable, I have limited available memory for MySQL instance by cgroup.

Observations:

In the case of O_DSYNC and regular ext4, the performance is just 10% less than for O_DIRECT/ext4/dioread_nolock and O_DIRECT/xfs and ~35% better than for O_DIRECT/ext4. That means that O_DSYNC can be used as a workaround for cases when you have fast storage and ext4 as filesystem but can’t switch to xfs or upgrade kernel.

Conclusions/workarounds

If your workload/setup is affected, there are the following options that you may consider as a workaround:

– downgrade linux kernel to 4.8
– install kernel 5.3.0 with fix and mount ext4 with dioread_nolock option
– if O_DIRECT is important, switch to xfs filesystem
– if changing filesystem is not an option,  replace O_DIRECT with O_DSYNC+cgroup

Recently I was doing some small testing by using EC2 instances on AWS and I noticed the execution time and performance highly depend on which time of the day I am running my scripts. I was using t3.xlarge instance type as I didn’t need many CPUs and memory for my tests, but from time to time I planned to use all the resources for a short time (few minutes), and this is when I noticed the difference.

First, let’s see what AWS says about T3 instances:

T3 instances start in Unlimited mode by default, giving users the ability to sustain high CPU performance over any desired time frame while keeping cost as low as possible.

In theory, I should not have any issues or performance differences. I have also monitored the CPU credit balance and there was no correlation between the balance and the performance at all, and because these were unlimited instances the balance should not have any impact.

I have decided to start a longer sysbench test on 3 threads to see how the QPS changes over the day.

As you can see, the Query Per Second could go down by almost 90%, which is a lot. It’s important to highlightthat the sysbench script should have generated a very steady workload. So what is this big difference? After checking all the graphs I found this:

Stealing! A lot of stealing! Here is a good article which explains stealing very well. So probably, I have a noisy neighbor. This instance was running in N. California. I have stopped it and tried to start new instances to repeat the test but I have always gotten very similar results. There was a lot of stealing which was hurting the performance a lot, probably because that region is very popular and resources are limited.

Out of curiosity, I have started two similar instances in the Stockholm region and repeated the same test and I got very steady performance as you can see here:

I guess this region is not that popular or filled yet, and we can see there is a huge difference between where you start your instance.

I also repeated the tests with the m5.xlarge instance type to see if it has the same behavior or not.

N. California

Stockholm

After I changed the instance type, we can see that both regions give very similar, steady performance, but if we take a closer look:

N. California

Stockholm

The instance in Stockholm still performs almost 5% more QPS as in N. California, and uses more CPU as well.

Conclusion

If you are using T2 and T3 instance types, you should monitor the CPU usage very closely because noisy neighbors can hurt your performance a lot.  If you need stable performance, T2 and T3 are not recommended but if you only need a short burst it might work but still, you have to monitor the steal. Other instance types can give you a much more stable performance but you could still see some difference between the regions.

Some say that the best password is the one you don’t have to remember. That’s possible with MySQL, thanks to the auth_socket plugin and its MariaDB version unix_socket.

Neither of these plugins is new, and some words have been written about the auth_socket on this blog before, for example: how to change passwords in MySQL 5.7 when using plugin: auth_socket. But while reviewing what’s new with MariaDB 10.4, I saw that the unix_socket now comes installed by default and is one of the authentication methods (one of them because in MariaDB 10.4 a single user can have more than one authentication plugin, as explained in the Authentication from MariaDB 10.4 document).

As already mentioned this is not news, and even when one installs MySQL using the .deb packages maintained by the Debian team, the root user is created so it uses the socket authentication. This is true for both MySQL and MariaDB:

root@app:~# apt-cache show mysql-server-5.7 | grep -i maintainers
Original-Maintainer: Debian MySQL Maintainers <pkg-mysql-maint@lists.alioth.debian.org>
Original-Maintainer: Debian MySQL Maintainers <pkg-mysql-maint@lists.alioth.debian.org>

Using the Debian packages of MySQL, the root is authenticated as follows:

root@app:~# whoami
root=
root@app:~# mysql
Welcome to the MySQL monitor.  Commands end with ; or \g.
Your MySQL connection id is 4
Server version: 5.7.27-0ubuntu0.16.04.1 (Ubuntu)

Copyright (c) 2000, 2019, Oracle and/or its affiliates. All rights reserved.
Oracle is a registered trademark of Oracle Corporation and/or its
affiliates. Other names may be trademarks of their respective
owners.

Type 'help;' or '\h' for help. Type '\c' to clear the current input statement.

mysql> select user, host, plugin, authentication_string from mysql.user where user = 'root';
+------+-----------+-------------+-----------------------+
| user | host      | plugin | authentication_string |
+------+-----------+-------------+-----------------------+
| root | localhost | auth_socket |                       |
+------+-----------+-------------+-----------------------+
1 row in set (0.01 sec)

Same for the MariaDB .deb package:

10.0.38-MariaDB-0ubuntu0.16.04.1 Ubuntu 16.04

MariaDB [(none)]> show grants;
+------------------------------------------------------------------------------------------------+
| Grants for root@localhost                                                                      |
+------------------------------------------------------------------------------------------------+
| GRANT ALL PRIVILEGES ON *.* TO 'root'@'localhost' IDENTIFIED VIA unix_socket WITH GRANT OPTION |
| GRANT PROXY ON ''@'%' TO 'root'@'localhost' WITH GRANT OPTION                                  |
+------------------------------------------------------------------------------------------------+
2 rows in set (0.00 sec)

For Percona Server, the .deb packages from the official Percona Repo are also setting the root user authentication to auth_socket. Here is an example of Percona Server for MySQL 8.0.16-7 and Ubuntu 16.04:

root@app:~# whoami
root
root@app:~# mysql
Welcome to the MySQL monitor.  Commands end with ; or \g.
Your MySQL connection id is 9
Server version: 8.0.16-7 Percona Server (GPL), Release '7', Revision '613e312'

Copyright (c) 2009-2019 Percona LLC and/or its affiliates
Copyright (c) 2000, 2019, Oracle and/or its affiliates. All rights reserved.
Oracle is a registered trademark of Oracle Corporation and/or its
affiliates. Other names may be trademarks of their respective
owners.

Type 'help;' or '\h' for help. Type '\c' to clear the current input statement.

mysql> select user, host, plugin, authentication_string from mysql.user where user ='root';
+------+-----------+-------------+-----------------------+
| user | host      | plugin | authentication_string |
+------+-----------+-------------+-----------------------+
| root | localhost | auth_socket |                       |
+------+-----------+-------------+-----------------------+
1 row in set (0.00 sec)

So, what’s the magic? The plugin checks that the Linux user matches the MySQL user using the SO_PEERCRED socket option to obtain information about the user running the client program. Thus, the plugin can be used only on systems that support the SO_PEERCRED option, such as Linux. The SO_PEERCRED socket option allows retrieving the uid of the process that is connected to the socket. It is then able to get the user name associated with that uid.

Here’s an example with the user “vagrant”:

vagrant@mysql1:~$ whoami
vagrant
vagrant@mysql1:~$ mysql
ERROR 1698 (28000): Access denied for user 'vagrant'@'localhost'

Since no user “vagrant” exists in MySQL, the access is denied. Let’s create the user and try again:

MariaDB [(none)]> GRANT ALL PRIVILEGES ON *.* TO 'vagrant'@'localhost' IDENTIFIED VIA unix_socket;
Query OK, 0 rows affected (0.00 sec)

vagrant@mysql1:~$ mysql
Welcome to the MariaDB monitor.  Commands end with ; or \g.
Your MariaDB connection id is 45
Server version: 10.0.38-MariaDB-0ubuntu0.16.04.1 Ubuntu 16.04
Copyright (c) 2000, 2018, Oracle, MariaDB Corporation Ab and others.
Type 'help;' or '\h' for help. Type '\c' to clear the current input statement.

MariaDB [(none)]> show grants;
+---------------------------------------------------------------------------------+
| Grants for vagrant@localhost                                                    |
+---------------------------------------------------------------------------------+
| GRANT ALL PRIVILEGES ON *.* TO 'vagrant'@'localhost' IDENTIFIED VIA unix_socket |
+---------------------------------------------------------------------------------+
1 row in set (0.00 sec)

Success!

Now, what about on a non-debian distro, where this is not the default? Let’s try it on Percona Server for MySQL 8 installed on a CentOS 7:

mysql> show variables like '%version%comment';
+-----------------+---------------------------------------------------+
| Variable_name   | Value                                   |
+-----------------+---------------------------------------------------+
| version_comment | Percona Server (GPL), Release 7, Revision 613e312 |
+-----------------+---------------------------------------------------+
1 row in set (0.01 sec)

mysql> CREATE USER 'percona'@'localhost' IDENTIFIED WITH auth_socket;
ERROR 1524 (HY000): Plugin 'auth_socket' is not loaded

Failed. What is missing? The plugin is not loaded:

mysql> pager grep socket
PAGER set to 'grep socket'
mysql> show plugins;
47 rows in set (0.00 sec)

Let’s add the plugin in runtime:

mysql> nopager
PAGER set to stdout
mysql> INSTALL PLUGIN auth_socket SONAME 'auth_socket.so';
Query OK, 0 rows affected (0.00 sec)

mysql> pager grep socket; show plugins;
PAGER set to 'grep socket'
| auth_socket                     | ACTIVE | AUTHENTICATION | auth_socket.so | GPL     |
48 rows in set (0.00 sec)

We got all we need now. Let’s try again:

mysql> CREATE USER 'percona'@'localhost' IDENTIFIED WITH auth_socket;
Query OK, 0 rows affected (0.01 sec)
mysql> GRANT ALL PRIVILEGES ON *.* TO 'percona'@'localhost';
Query OK, 0 rows affected (0.01 sec)

And now we can log in as the OS user “percona”.

[percona@ip-192-168-1-111 ~]$ whoami
percona
[percona@ip-192-168-1-111 ~]$ mysql -upercona
Welcome to the MySQL monitor.  Commands end with ; or \g.
Your MySQL connection id is 19
Server version: 8.0.16-7 Percona Server (GPL), Release 7, Revision 613e312


Copyright (c) 2009-2019 Percona LLC and/or its affiliates
Copyright (c) 2000, 2019, Oracle and/or its affiliates. All rights reserved.


Oracle is a registered trademark of Oracle Corporation and/or its
affiliates. Other names may be trademarks of their respective
owners.


Type 'help;' or '\h' for help. Type '\c' to clear the current input statement.


mysql> select user, host, plugin, authentication_string from mysql.user where user ='percona';
+---------+-----------+-------------+-----------------------+
| user    | host   | plugin   | authentication_string |
+---------+-----------+-------------+-----------------------+
| percona | localhost | auth_socket |                       |
+---------+-----------+-------------+-----------------------+
1 row in set (0.00 sec)

Success again!

Question: Can I try to log as the user percona from another user?

[percona@ip-192-168-1-111 ~]$ logout
[root@ip-192-168-1-111 ~]# mysql -upercona
ERROR 1698 (28000): Access denied for user 'percona'@'localhost'

No, you can’t.

Conclusion

MySQL is flexible enough in several aspects, one being the authentication methods. As we see in this post, one can achieve access without passwords by relying on OS users. This is helpful in several scenarios, but just to mention one: when migrating from RDS/Aurora to regular MySQL and using IAM Database Authentication to keep getting access without using passwords.

In MySQL 8.0.18 there is a new feature called Hash Joins, and I wanted to see how it works and in which situations it can help us. Here you can find a nice detailed explanation about how it works under the hood.

The high-level basics are the following: if there is a join, it will create an in-memory hash table based on one of the tables and will read the other table row by row, calculate a hash, and do a lookup on the in-memory hash table.

Great, but does this give us any performance benefits?

First of all, this only works on fields that are not indexed, so that is an immediate table scan and we usually do not recommend doing joins without indexes because it is slow. Here is where Hash Joins in MySQL can help because it will use an in-memory hash table instead of Nested Loop.

Let’s do some tests and see. First I created the following tables:

CREATE TABLE `t1` (
`id` int(11) NOT NULL AUTO_INCREMENT ,
`c1` int(11) NOT NULL DEFAULT '0',
`c2` int(11) NOT NULL DEFAULT '0',
PRIMARY KEY (`id`),
KEY `idx_c1` (`c1`)
) ENGINE=InnoDB;

CREATE TABLE `t2` (
`id` int(11) NOT NULL AUTO_INCREMENT ,
`c1` int(11) NOT NULL DEFAULT '0',
`c2` int(11) NOT NULL DEFAULT '0',
PRIMARY KEY (`id`),
KEY `idx_c1` (`c1`)
) ENGINE=InnoDB;

I have inserted 131072 random rows into both tables.

mysql> select count(*) from t1;
+----------+
| count(*) |
+----------+
| 131072   |
+----------+

First test – Hash Joins

Run a join based on c2 which is not indexed.

mysql> explain format=tree select count(*) from t1 join t2 on t1.c2 = t2.c2\G
*************************** 1. row ***************************
EXPLAIN: -> Aggregate: count(0)
-> Inner hash join (t2.c2 = t1.c2) (cost=1728502115.04 rows=1728488704)
-> Table scan on t2 (cost=0.01 rows=131472)
-> Hash
-> Table scan on t1 (cost=13219.45 rows=131472)

1 row in set (0.00 sec)

We have to use explain format=tree to see if Hash Join will be used or not, as normal explain still says it is going to be a Nested Loop, which I think it is very misleading. I have already filed a bug report because of this and in the ticket, you can see some comments from developers saying:

The solution is to stop using traditional EXPLAIN (it will eventually go away).

So this is not going to be fixed in traditional explain and we should start using the new way.

Back to the query; we can see it is going to use Hash Join for this query, but how fast is it?

mysql> select count(*) from t1 join t2 on t1.c2 = t2.c2;
+----------+
| count(*) |
+----------+
| 17172231 |
+----------+
1 row in set (0.73 sec)

0.73s for a more than 17m rows join table. Looks promising.

Second Test – Non-Hash Joins

We can disable it with an optimizer switch or optimizer hint.

mysql> select /*+ NO_HASH_JOIN (t1,t2) */ count(*) from t1 join t2 on t1.c2 = t2.c2;
+----------+
| count(*) |
+----------+
| 17172231 |
+----------+
1 row in set (13 min 36.36 sec)

Now the same query takes more than 13 minutes. That is a huge difference and we can see Hash Join helps a lot here.

Third Test – Joins Based on Indexes

Let’s create indexes and see how fast a join based on indexes is.

create index idx_c2 on t1(c2);
create index idx_c2 on t2(c2);

mysql> select count(*) from t1 join t2 on t1.c2 = t2.c2;
+----------+
| count(*) |
+----------+
| 17172231 |
+----------+
1 row in set (2.63 sec)

2.6s

  Hash Join is even faster than the Index-based join in this case.

However, I was able to force the optimizer to use Hash Joins even if an index is available by using ignore index:

mysql> explain format=tree select count(*) from t1 ignore index (idx_c2) join t2 ignore index (idx_c2) on t1.c2 = t2.c2 where t1.c2=t2.c2\G
*************************** 1. row ***************************
EXPLAIN: -> Aggregate: count(0)
-> Inner hash join (t2.c2 = t1.c2) (cost=1728502115.04 rows=17336898)
-> Table scan on t2 (cost=0.00 rows=131472)
-> Hash
-> Table scan on t1 (cost=13219.45 rows=131472)

1 row in set (0.00 sec)

I still think it would be nice if I can tell the optimizer with a hint to use Hash Joins even if an index is available, so we do not have to ignore indexes on all the tables. I have created a feature request for this.

However, if you read my first bug report carefully you can see a comment from a MySQL developer which indicates this might not be necessary:

BNL (Block Nested-Loop) will also go away entirely at some point, at which point this hint will be ignored.

That could mean they are planning to remove BNL joins in the future and maybe replace it with Hash join.

Limitations

We can see Hash Join can be powerful, but there are limitations:

• As I mentioned it only works on columns that do not have indexes (or you have to ignore them).
• It only works with equi-join conditions.
• It does not work with LEFT or RIGHT JOIN.

I would like to see a status metric as well to monitor how many times Hash Join was used, and for this, I filled another feature request.

Conclusion

Hash Join seems a very powerful new join option, and we should keep an eye on this because I would not be surprised if we get some other features in the future as well. In theory, it would be able to do Left and Right joins as well and as we can see in the comments on the bug report that Oracle has plans for it in the future.

From time to time you may have experienced that MySQL was not able to find the best execution plan for a query. You felt the query should have been faster. You felt that something didn’t work, but you didn’t realize exactly what.

Maybe some of you did tests and discovered there was a better execution plan that MySQL wasn’t able to find (forcing the order of the tables with STRAIGHT_JOIN for example).

In this article, we’ll see a new interesting feature available on MySQL 8.0 as well as Percona Server for MySQL 8.0: the histogram-based statistics.

Today, we’ll see what a histogram is, how you can create and manage it, and how MySQL’s optimizer can use it.

Just for completeness, histogram statistics have been available on MariaDB since version 10.0.2, with a slightly different implementation. Anyway, what we’ll see here is related to Percona Server and MySQL 8.0 only.

 

What is a histogram

We can define a histogram as a good approximation of the data distribution of the values in a column.

Histogram-based statistics were introduced to give the optimizer more execution plans to investigate and solve a query. Until then, in some cases, the optimizer was not able to find out the best possible execution plan because non-indexed columns were ignored.

With histogram statistics, now the optimizer may have more options because also non-indexed columns can be considered. In some specific cases, a query can run faster than usual.

Let’s consider the following table to store departing times of the trains:

CREATE TABLE train_schedule(
id INT PRIMARY KEY,
train_code VARCHAR(10),
departure_station VARCHAR(100),
departure_time TIME);

We can assume that during peak hours, from 7 AM until 9 AM, there are more rows, and during the night hours we have very few rows.

Let’s take a look at the following two queries:

SELECT * FROM train_schedule WHERE departure_time BETWEEN '07:30:00' AND '09:15:00';
SELECT * FROM train_schedule WHERE departure_time BETWEEN '01:00:00' AND '03:00:00';

Without any kind of statistics, the optimizer assumes by default that the values in the departure_time column are evenly distributed, but they aren’t. In fact, the first query returns more rows because of this assumption.

Histograms were invented to provide to the optimizer a good estimation of the rows returned. This seems to be trivial for the simple queries we have seen so far. But let’s think now about having the same table involved in JOINs with other tables. In such a case, the number of rows returned can be very important for the optimizer to decide the order to consider the tables in the execution plan.

A good estimation of the rows returned gives the optimizer the capability to open the table in the first stages in case it returns few rows. This minimizes the total amount of rows for the final cartesian product. Then the query can run faster.

MySQL supports two different types of histograms: “singleton” and “equi-height”. Common for all histogram types is that they split the data set into a set of “buckets”, and MySQL automatically divides the values into the buckets and will also automatically decide what type of histogram to create.

Singleton histogram

• one value per bucket
• each bucket stores
  • value
  • cumulative frequency
• well suited for equality and range conditions

Equi-height histogram

• multiple values per bucket
• each bucket stores
  • minimum value
  • maximum value
  • cumulative frequency
  • number of distinct values
• not really equi-height: frequent values are in separated buckets
• well suited for range conditions

How to use histograms

The histogram feature is available and enabled on the server, but not usable by the optimizer. Without an explicit creation, the optimizer works the same as usual and cannot get any benefit from the histogram-bases statistics.

There is some manual operation to do. Let’s see.

In the next examples, we’ll use the world sample database you can download from here: https://dev.mysql.com/doc/index-other.html

Let’s start executing a query joining two tables to find out all the languages spoken on the largest cities of the world, with more than 10 million people.

mysql> select city.name, countrylanguage.language from city join countrylanguage using(countrycode) where population>10000000; 
+-----------------+-----------+ 
| name            | language  | 
+-----------------+-----------+ 
| Mumbai (Bombay) | Asami     | 
| Mumbai (Bombay) | Bengali   | 
| Mumbai (Bombay) | Gujarati  | 
| Mumbai (Bombay) | Hindi     | 
| Mumbai (Bombay) | Kannada   | 
| Mumbai (Bombay) | Malajalam | 
| Mumbai (Bombay) | Marathi   | 
| Mumbai (Bombay) | Orija     | 
| Mumbai (Bombay) | Punjabi   | 
| Mumbai (Bombay) | Tamil     | 
| Mumbai (Bombay) | Telugu    | 
| Mumbai (Bombay) | Urdu      | 
+-----------------+-----------+ 
12 rows in set (0.04 sec)

The query takes 0.04 seconds. It’s not a lot, but consider that the database is very small. Use the BENCHMARK function to have more relevant response times if you like.

Let’s see the EXPLAIN:

mysql> explain select city.name, countrylanguage.language from city join countrylanguage using(countrycode) where population>10000000; 
+----+-------------+-----------------+------------+-------+---------------------+-------------+---------+-----------------------------------+------+----------+-------------+ 
| id | select_type | table           | partitions | type  | possible_keys       | key         | key_len | ref                               | rows | filtered | Extra       | 
+----+-------------+-----------------+------------+-------+---------------------+-------------+---------+-----------------------------------+------+----------+-------------+ 
| 1  | SIMPLE      | countrylanguage | NULL       | index | PRIMARY,CountryCode | CountryCode | 3       | NULL                              | 984  | 100.00   | Using index | 
| 1  | SIMPLE      | city            | NULL       | ref   | CountryCode         | CountryCode | 3       | world.countrylanguage.CountryCode | 18   | 33.33    | Using where | 
+----+-------------+-----------------+------------+-------+---------------------+-------------+---------+-----------------------------------+------+----------+-------------+

Indexes are used for both the tables and the estimated cartesian product has 984 * 18 = 17,712 rows.

Now generate the histogram on the Population column. It’s the only column used for filtering the data and it’s not indexed.

For that, we have to use the ANALYZE command:

mysql> ANALYZE TABLE city UPDATE HISTOGRAM ON population WITH 1024 BUCKETS; 
+------------+-----------+----------+-------------------------------------------------------+ 
| Table      | Op        | Msg_type | Msg_text                                              | 
+------------+-----------+----------+-------------------------------------------------------+ 
| world.city | histogram | status   | Histogram statistics created for column 'Population'. | 
+------------+-----------+----------+-------------------------------------------------------+

We have created a histogram using 1024 buckets. The number of buckets is not mandatory, and it can be any number from 1 to 1024. If omitted, the default value is 100.

The number of chunks affects the reliability of the statistics. The more distinct values you have, the more the chunks you need.

Let’s have a look now at the execution plan and execute the query again.

mysql> explain select city.name, countrylanguage.language from city join countrylanguage using(countrycode) where population>10000000;
+----+-------------+-----------------+------------+------+---------------------+-------------+---------+------------------------+------+----------+-------------+
| id | select_type | table           | partitions | type | possible_keys       | key         | key_len | ref                    | rows | filtered | Extra       |
+----+-------------+-----------------+------------+------+---------------------+-------------+---------+------------------------+------+----------+-------------+
|  1 | SIMPLE      | city            | NULL       | ALL  | CountryCode         | NULL        | NULL    | NULL                   | 4188 |     0.06 | Using where |
|  1 | SIMPLE      | countrylanguage | NULL       | ref  | PRIMARY,CountryCode | CountryCode | 3       | world.city.CountryCode |  984 |   100.00 | Using index |
+----+-------------+-----------------+------------+------+---------------------+-------------+---------+------------------------+------+----------+-------------+

mysql> select city.name, countrylanguage.language from city join countrylanguage using(countrycode) where population>10000000;
+-----------------+-----------+
| name            | language  |
+-----------------+-----------+
| Mumbai (Bombay) | Asami     |
| Mumbai (Bombay) | Bengali   |
| Mumbai (Bombay) | Gujarati  |
| Mumbai (Bombay) | Hindi     |
| Mumbai (Bombay) | Kannada   |
| Mumbai (Bombay) | Malajalam |
| Mumbai (Bombay) | Marathi   |
| Mumbai (Bombay) | Orija     |
| Mumbai (Bombay) | Punjabi   |
| Mumbai (Bombay) | Tamil     |
| Mumbai (Bombay) | Telugu    |
| Mumbai (Bombay) | Urdu      |
+-----------------+-----------+
12 rows in set (0.00 sec)

The execution plan is different, and the query runs faster.

We can notice that the order of the tables is the opposite as before. Even if it requires a full scan, the city table is in the first stage. It’s because of the filtered value that is only 0.06. It means that only 0.06% of the rows returned by the full scan will be used to be joined with the following table. So, it’s only 4188 * 0.06% = 2.5 rows. In total, the estimated cartesian product is 2.5 * 984 = 2.460 rows. This is significantly lower than the previous execution and explains why the query is faster.

What we have seen sounds a little counterintuitive, doesn’t it? In fact, until MySQL 5.7, we were used to considering full scans as very bad in most cases. In our case, instead, forcing a full scan using a histogram statistic on a non-indexed column lets the query to get optimized. Awesome.

 

Where are the histogram statistics

Histogram statistics are stored in the column_statistics table in the data dictionary and are not directly accessible by the users. Instead the INFORMATION_SCHEMA.COLUMN_STATISTICS table, which is implemented as a view of the data dictionary, can be used for the same purpose.

Let’s see the statistics for our table.

mysql> SELECT SCHEMA_NAME, TABLE_NAME, COLUMN_NAME, JSON_PRETTY(HISTOGRAM)  
    -> FROM information_schema.column_statistics  
    -> WHERE COLUMN_NAME = 'population'\G
*************************** 1. row ***************************
           SCHEMA_NAME: world
            TABLE_NAME: city
           COLUMN_NAME: Population
JSON_PRETTY(HISTOGRAM): {
  "buckets": [
    [
      42,
      455,
      0.000980632507967639,
      4
    ],
    [
      503,
      682,
      0.001961265015935278,
      4
    ],
    [
      700,
      1137,
      0.0029418975239029173,
      4
    ],
...
...
    [
      8591309,
      9604900,
      0.9990193674920324,
      4
    ],
    [
      9696300,
      10500000,
      1.0,
      4
    ]
  ],
  "data-type": "int",
  "null-values": 0.0,
  "collation-id": 8,
  "last-updated": "2019-10-14 22:24:58.232254",
  "sampling-rate": 1.0,
  "histogram-type": "equi-height",
  "number-of-buckets-specified": 1024
}

We can see for any chunk the min and max values, the cumulative frequency, and the number of items. Also, we can see that MySQL decided to use an equi-height histogram.

Let’s try to generate a histogram on another table and column.

mysql> ANALYZE TABLE country UPDATE HISTOGRAM ON Region;
+---------------+-----------+----------+---------------------------------------------------+
| Table         | Op        | Msg_type | Msg_text                                          |
+---------------+-----------+----------+---------------------------------------------------+
| world.country | histogram | status   | Histogram statistics created for column 'Region'. |
+---------------+-----------+----------+---------------------------------------------------+
1 row in set (0.01 sec)

mysql> SELECT SCHEMA_NAME, TABLE_NAME, COLUMN_NAME, JSON_PRETTY(HISTOGRAM)  FROM information_schema.column_statistics  WHERE COLUMN_NAME = 'Region'\G
*************************** 1. row ***************************
           SCHEMA_NAME: world
            TABLE_NAME: country
           COLUMN_NAME: Region
JSON_PRETTY(HISTOGRAM): {
  "buckets": [
    [
      "base64:type254:QW50YXJjdGljYQ==",
      0.02092050209205021
    ],
    [
      "base64:type254:QXVzdHJhbGlhIGFuZCBOZXcgWmVhbGFuZA==",
      0.04184100418410042
    ],
    [
      "base64:type254:QmFsdGljIENvdW50cmllcw==",
      0.05439330543933054
    ],
    [
      "base64:type254:QnJpdGlzaCBJc2xhbmRz",
      0.06276150627615062
    ],
    [
      "base64:type254:Q2FyaWJiZWFu",
      0.1631799163179916
    ],
    [
      "base64:type254:Q2VudHJhbCBBZnJpY2E=",
      0.20083682008368198
    ],
    [
      "base64:type254:Q2VudHJhbCBBbWVyaWNh",
      0.23430962343096232
    ],
    [
      "base64:type254:RWFzdGVybiBBZnJpY2E=",
      0.3179916317991631
    ],
    [
      "base64:type254:RWFzdGVybiBBc2lh",
      0.35146443514644343
    ],
    [
      "base64:type254:RWFzdGVybiBFdXJvcGU=",
      0.39330543933054385
    ],
    [
      "base64:type254:TWVsYW5lc2lh",
      0.41422594142259406
    ],
    [
      "base64:type254:TWljcm9uZXNpYQ==",
      0.44351464435146437
    ],
    [
      "base64:type254:TWljcm9uZXNpYS9DYXJpYmJlYW4=",
      0.4476987447698744
    ],
    [
      "base64:type254:TWlkZGxlIEVhc3Q=",
      0.5230125523012552
    ],
    [
      "base64:type254:Tm9yZGljIENvdW50cmllcw==",
      0.5523012552301255
    ],
    [
      "base64:type254:Tm9ydGggQW1lcmljYQ==",
      0.5732217573221757
    ],
    [
      "base64:type254:Tm9ydGhlcm4gQWZyaWNh",
      0.602510460251046
    ],
    [
      "base64:type254:UG9seW5lc2lh",
      0.6443514644351465
    ],
    [
      "base64:type254:U291dGggQW1lcmljYQ==",
      0.7029288702928871
    ],
    [
      "base64:type254:U291dGhlYXN0IEFzaWE=",
      0.7489539748953975
    ],
    [
      "base64:type254:U291dGhlcm4gQWZyaWNh",
      0.7698744769874477
    ],
    [
      "base64:type254:U291dGhlcm4gYW5kIENlbnRyYWwgQXNpYQ==",
      0.8284518828451883
    ],
    [
      "base64:type254:U291dGhlcm4gRXVyb3Bl",
      0.891213389121339
    ],
    [
      "base64:type254:V2VzdGVybiBBZnJpY2E=",
      0.9623430962343097
    ],
    [
      "base64:type254:V2VzdGVybiBFdXJvcGU=",
      1.0
    ]
  ],
  "data-type": "string",
  "null-values": 0.0,
  "collation-id": 8,
  "last-updated": "2019-10-14 22:29:13.418582",
  "sampling-rate": 1.0,
  "histogram-type": "singleton",
  "number-of-buckets-specified": 100
}

In this case, a singleton histogram was generated.

Using the following query we can see more human-readable statistics.

mysql> SELECT SUBSTRING_INDEX(v, ':', -1) value, concat(round(c*100,1),'%') cumulfreq,         
    -> CONCAT(round((c - LAG(c, 1, 0) over()) * 100,1), '%') freq   
    -> FROM information_schema.column_statistics, JSON_TABLE(histogram->'$.buckets','$[*]' COLUMNS(v VARCHAR(60) PATH '$[0]', c double PATH '$[1]')) hist  
    -> WHERE schema_name  = 'world' and table_name = 'country' and column_name = 'region';
+---------------------------+-----------+-------+
| value                     | cumulfreq | freq  |
+---------------------------+-----------+-------+
| Antarctica                | 2.1%      | 2.1%  |
| Australia and New Zealand | 4.2%      | 2.1%  |
| Baltic Countries          | 5.4%      | 1.3%  |
| British Islands           | 6.3%      | 0.8%  |
| Caribbean                 | 16.3%     | 10.0% |
| Central Africa            | 20.1%     | 3.8%  |
| Central America           | 23.4%     | 3.3%  |
| Eastern Africa            | 31.8%     | 8.4%  |
| Eastern Asia              | 35.1%     | 3.3%  |
| Eastern Europe            | 39.3%     | 4.2%  |
| Melanesia                 | 41.4%     | 2.1%  |
| Micronesia                | 44.4%     | 2.9%  |
| Micronesia/Caribbean      | 44.8%     | 0.4%  |
| Middle East               | 52.3%     | 7.5%  |
| Nordic Countries          | 55.2%     | 2.9%  |
| North America             | 57.3%     | 2.1%  |
| Northern Africa           | 60.3%     | 2.9%  |
| Polynesia                 | 64.4%     | 4.2%  |
| South America             | 70.3%     | 5.9%  |
| Southeast Asia            | 74.9%     | 4.6%  |
| Southern Africa           | 77.0%     | 2.1%  |
| Southern and Central Asia | 82.8%     | 5.9%  |
| Southern Europe           | 89.1%     | 6.3%  |
| Western Africa            | 96.2%     | 7.1%  |
| Western Europe            | 100.0%    | 3.8%  |
+---------------------------+-----------+-------+

 

Histogram maintenance

Histogram statistics are not automatically recalculated. If you have a table that is very frequently updated with a lot of INSERTs, UPDATEs, and DELETEs, the statistics can run out of date very soon. Having unreliable histograms can lead the optimizer to the wrong choice.

When you find a histogram was useful to optimize a query, you need to also have a scheduled plan to refresh the statistics from time to time, in particular after doing massive modifications to the table.

To refresh a histogram you just need to run the same ANALYZE command we have seen before.

To completely drop a histogram you may run the following:

ANALYZE TABLE city DROP HISTOGRAM ON population;

 

Sampling

The histogram_generation_max_mem_size system variable controls the maximum amount of memory available for histogram generation. The global and session values may be set at runtime.

If the estimated amount of data to be read into memory for histogram generation exceeds the limit defined by the variable, MySQL samples the data rather than reading all of it into memory. Sampling is evenly distributed over the entire table.

The default value is 20000000 but you can increase it in the case of a large column if you want more accurate statistics. For very large columns, pay attention not to increase the threshold more than the memory available in order to avoid excessive overhead or outage.

 

Conclusion

Histogram statistics are particularly useful for non-indexed columns, as shown in the example.

Execution plans that can rely on indexes are usually the best, but histograms can help in some edge cases or when creating a new index is a bad idea.

Since this is not an automatic feature, some manual testing is required to investigate if you really can get the benefit of a histogram. Also, the maintenance requires some scheduled and manual activity.

Use histograms if you really need them, but don’t abuse them since histograms on very large tables can consume a lot of memory.

Usually, the best candidates for a histogram are the columns with:

• values that do not change much over time
• low cardinality values
• uneven distribution

Install Percona Server 8.0, test and enjoy the histograms.

 

Further reading on the same topic: Billion Goods in Few Categories – How Histograms Save a Life?

 

In MySQL 8.0.18 there is a new feature called Explain Analyze when for many years we mostly had only the traditional Explain. I know there are different formats, but those based on the same information just show it in a different format with some extra details.

But Explain Analyze is a different concept. It is actually going to run the query and measure execution time by using the new iterator executor for each step. That topic itself deserves its own blog post on how the new iterator executor works, and I will write a post about that as well. But if you cannot wait and you would like to read up, here are some links to some additional information: Iterator executor analytics queries, Volcano iterator design, and Volcano iterator semijoin.

In this post, we are going to focus on what Explain Analyze can give us.

As always let’s start with some testing. I have my test server with a sbtest1 table:

CREATE TABLE `t1` (
`id` int(11) NOT NULL AUTO_INCREMENT,
`c1` int(11) NOT NULL DEFAULT '0',
`c2` int(11) NOT NULL DEFAULT '0',
PRIMARY KEY (`id`),
KEY `idx_c1` (`c1`)
) ENGINE=InnoDB AUTO_INCREMENT=262125 DEFAULT CHARSET=utf8mb4 COLLATE=utf8mb4_0900_ai_ci

There are almost 1 million rows in it:

mysql> select count(*) from sbtest1;

+----------+
| count(*) |
+----------+
| 999999 |
+----------+
1 row in set (0.32 sec)

Traditional Explain

mysql> explain select count(*) from sbtest1 where k > 500000\G
*************************** 1. row ***************************
id: 1
select_type: SIMPLE
table: sbtest1
partitions: NULL
type: range
possible_keys: idx3
key: idx3
key_len: 4
ref: NULL
rows: 493204
filtered: 100.00
Extra: Using where; Using index
1 row in set, 1 warning (0.00 sec)

Hopefully, most of you already know this output; we can see which table and index will be used and we can also see it is a range query and approximately it has to read 493204 Rows. With InnoDB we know that is just an estimation, it is not the real number. In the past, we had two options: either run the query and see the real number or run the query and check the handler statistics to get even more detailed information.

Now I am going to run the query and see the real row count:

mysql> select count(*) from sbtest1 where k > 500000\G
*************************** 1. row ***************************
count(*): 625262
1 row in set (0.10 sec)

So the query has to read 625262 rows and takes 0.10s.  Let’s have a look at Explain Analyze.

Explain Analyze

mysql> explain analyze select count(*) from sbtest1 where k > 500000\G
*************************** 1. row ***************************
EXPLAIN: -> Aggregate: count(0) (actual time=178.225..178.225 rows=1 loops=1)
-> Filter: (sbtest1.k > 500000) (cost=98896.53 rows=493204) (actual time=0.022..147.502 rows=625262 loops=1)
-> Index range scan on sbtest1 using idx3 (cost=98896.53 rows=493204) (actual time=0.021..96.488 rows=625262 loops=1)

1 row in set (0.18 sec)

It always uses the tree format and it took me some time to actually understand what all this information means. Unfortunately, the manual page does not really explain it.

Let me try to fill the gaps:

Index range scan on sbtest1 using idx3 –  this part is quite trivial, it says it is going to use a range scan on sbtest1 table and will use the idx3 index.

cost=98896.53 rows=493204 –  this is the cost and the same row number that traditional Explain gives us.

actual time=0.021..96.488 rows=625262 loops=1:

• 0.021 – The time to return first row (Init + first Read) in milliseconds.
• 96.488 – The time to return all rows (Init + all Read calls) in milliseconds.
• rows=625262 – The number of rows returned by this iterator. Finally, it is the exact number.
• loops=1 – The number of loops (number of Init calls).

The source for this information is here: Implement EXPLAIN ANALYZE.

We can see all this information with each step, which gives us great help and insights for query optimization.

But it is important to notice in the last step that the time is 178ms and it also reports 1 row in set (0.18 sec). So it says this query takes 0.18s! But the original query took only 0.10s.

The manual says:

This has naturally some overhead, but it seems this is only around 5–6% for an instrumented query
(entirely free for a non-instrumented query).

But with this very simple query, the overhead is already 80%, so we cannot really trust those numbers.

Let’s have a look on another query which takes more time, and see how this difference behaves:

mysql> select count(*) from sbtest1 t1 left join sbtest1 t2 on t1.k=t2.k;
+----------+
| count(*) |
+----------+
| 77902613 |
+----------+
1 row in set (15.42 sec)

mysql> explain analyze select count(*) from sbtest1 t1 left join sbtest1 t2 on t1.k=t2.k\G
*************************** 1. row ***************************
EXPLAIN: -> Aggregate: count(0) (actual time=26501.232..26501.233 rows=1 loops=1)
-> Nested loop left join (cost=810799.35 rows=4550475) (actual time=0.036..22572.530 rows=77902616 loops=1)
-> Index scan on t1 using idx3 (cost=108280.56 rows=986408) (actual time=0.026..176.645 rows=999999 loops=1)
-> Index lookup on t2 using idx3 (k=t1.k) (cost=0.25 rows=5) (actual time=0.001..0.017 rows=78 loops=999999)

1 row in set (26.50 sec)

It reports that the query is 60% slower than in real life.

Just out of curiosity I tried Explain Analyze with a Stored Procedure, but it didn’t work. One of the most painful tasks is to analyze and optimize a Stored Procedure because MySQL does not log the individual queries from a Procedure and it’s hard to actually see what is going under the hood.  (In Percona Server there are log_slow_sp_statements which will allow you to log the individual queries into a slow query log.)

I would love to see if Explain Analyze would run the procedure and then display the actual execution plan in a tree format. But maybe I am believing in a perfect world and I am too naive.

I also noticed some interesting behavior:

mysql> explain analyze select count(*) from sbtest1\G
*************************** 1. row ***************************
EXPLAIN: -> Count rows in sbtest1

1 row in set (0.13 sec)

If there isn’t a where condition, or group by, or anything else and just a simple count query, it does not give us the time for that step or how many rows were read or which index was used. I think here its a bit too minimalistic and some basic information would be good to see.

Conclusion

I think Explain Analyze is a great step in the right direction, and I am excited to see if in the future it gets even more features, but it should report more realistic times for execution time.

ProxySQL 2.0.7, released by ProxySQL, is now available for download in the Percona Repository along with Percona’s proxysql-admin tool.

ProxySQL is a high-performance proxy, currently for MySQL and database servers in the MySQL ecosystem (like Percona Server for MySQL and MariaDB). It acts as an intermediary for client requests seeking resources from the database. René Cannaò created ProxySQL for DBAs as a means of solving complex replication topology issues.

This release includes ProxySQL 2.0.7 which introduces many new features and enhancements and also fixes a number of bugs.

The proxysql-admin tool now supports MariaDB 10.4.

New Features

• PSQLADM-204: Add support of MariaDB 10.4

Improvements

• PSQLADM-195: A new option --with-stats-reset has been added to the proxysql-status script to display the  *_reset tables from the stats database. If this option is not specified, these tables are not displayed by default.

Bugs Fixed

• PSQLADM-157: In some cases, the proxysql-status script used the cat command to display a file without checking if the file existed and was readable.
• PSQLADM-181: When run with --update-cluster --write-node=<node_name>, the proxysql-admin tool now verifies that the writer nodes are not read-only.

The ProxySQL 2.0.7 source and binary packages available from the Percona download page for ProxySQL include ProxySQL Admin – a tool developed by Percona to configure Percona XtraDB Cluster nodes into ProxySQL. Docker images for release 2.0.7 are available as well. You can download the original ProxySQL from GitHub. GitHub hosts the documentation in the wiki format.

ProxySQL is available under Open Source license GPLv3.

MySQL Workbench is a great multi-purpose GUI tool for MySQL, which I think is not marketed enough by the MySQL team and is not appreciated enough by the community for what it can do.

MySQL Workbench Licensing

MySQL Workbench is similar to MySQL Server and is an Open-Core product. There is Community Edition which has GPL licensed source code on GitHub as well as the “MySQL Workbench Standard Edition (SE)” and “MySQL Workbench Enterprise Edition (EE)”  which are proprietary. The differences between the releases can be found in this document.

In this MySQL Workbench review, I focus on the MySQL Workbench Community Edition, often referred to as MySQL Workbench CE.

Downloading MySQL Workbench

You can download the current version of MySQL Workbench here.

Installing MySQL Workbench

Installation, of course, will be OS-dependent. I installed MySQL Workbench CE on Windows and it was quite uneventful.

 

Starting MySQL Workbench for the first time

If you go through the default MySQL Workbench install process, it will be started upon install completion.  And as it starts, it will check for MySQL Servers running locally, and because I do not have anything running locally, it won’t detect any servers.

 

You need to click on the little “+” sign near the “MySQL Connection” text to add a connection.   I think a clearer link to “Add Connection” by “Rescan Servers” would be more helpful.

Connection options are great. Besides support for TCP/IP and Local Socket/Pipe, MySQL Workbench also has support for TCP/IP over SSH, which is fantastic if you want to connect to servers reachable via SSH but do not have MySQL port open. 

When you have the connection created, you can open the main screen of MySQL Workbench which looks like this:

You can see there is a lot of stuff there!  Let’s look at some specific features.

MySQL Workbench Management Features

Server Status shows information about the running MySQL Server.  Of course, being an Oracle product, it is not designed to detect the alternative implementations.   In this case, Percona Server has a Thread Pool feature but it shows as N/A.  

Server Performance information graphs are updated in real-time and provide some idea about server load.

Client Connections shows current connections to MySQL Server.   This view has some nice features, for example, you can hide sleeping connections and look at running queries only, you can set the view to automatically refresh, and kill some queries and connections. You can also run EXPLAIN for Connection to see the query execution plan.   

How EXPLAIN for Connection works is a bit complicated.  As you click on EXPLAIN for Connection, the notebook containing the query opens up, but I would expect to see the explain output at this point:

You when need to click on the EXPLAIN icon to see the Query Explain Output:

Note you can get both EXPLAIN for the given query or EXPLAIN for CONNECTION, which can be different, especially in the case of this particular query, where the execution plan was abnormal.

There are multiple displays for EXPLAIN provided, including Tabular Explain and Raw JSON explain, if you want to see these, although having Visual Explain displayed is a unique MySQL Workbench feature.

I also like the feature of MySQL Workbench to provide additional details on connection, such as held locks as well as connection attributes, which can often help to find what particular application instance this query comes from.

Users and Privileges

This MySQL Workbench functionality allows you to view and manage your users:

It is not very advanced, but instead for the basic needs of understanding user privileges.  It has built-in support for Administrative Roles but there does not seem to be support for generic roles or some newer features such as locking accounts or requiring a change in password after a certain period of time, etc.

Status and System Variables

The Status and System Variables section in MySQL Workbench shows the formatted output of “SHOW GLOBAL STATUS” and “SHOW VARIABLES”:

I like the fact that the massive number of settings and variables are grouped into different categories and there is some help provided.  The fact that all values are only provided as raw numbers, without any formatting and not normalized per second when appropriate, make it hard to work with such information.

Data Export and Data Import/Restore

As you may expect, these provide the functionality to export and import schema and possibly data.  This basically provides GUI for mysqldump, which is a great help for more advanced use cases.

Instance Management

This is interesting; even though I set up a connection using SSH, MySQL Workbench does not automatically use it for host access. It needs to be configured separately instead, by clicking the little Wrench icon.

If you’re using Linux for Remote Management, you will need to provide quite a lot of details about the Linux version, packaging type, and even init scripts you use, which can easily be overwhelming.

I do wonder why there is no auto-detection of the system type implemented here.

If you configure Remote Management in MySQL Workbench properly, you could, in theory, be able to start/stop the server, look at server logs, and view options file.   It did not work well in my case. 

Performance  – Dashboard

The MySQL Workbench Performance Dashboard section shows a selection of Performance Graphs.  It is not very deep and only shows stats while MySQL Workbench is running, but it covers some good basics.

Performance – Reports

The Performance Reports section in MySQL Workbench is pretty cool; it shows a lot of reports based on MySQL’s sys schema. 

This is pretty handy, but I think it would benefit from having better formatting (so I do not have to count digits to see how much memory is used) and also numbers from the instance start often make little sense.

Performance Schema Setup

This is one of the hidden gems in MySQL Workbench.  Performance Schema configuration in MySQL can be rather complicated if you’re not familiar with it, and MySQL Workbench makes it a lot easier.   Its default Performance Schema controls are very basic.

However, if you enable the “Show Advanced” settings, it will give you this fantastic overview of Performance Schema: 

As well as allow you to modify the configuration in details:

Until this point, we have been operating in Administration View.  If you want to work with Database Schema, you want to switch MySQL Workbench to Schema View.

This view allows you to work with tables and other database schema objects.  The contextual menu provides different functions for different objects.

 

MySQL Workbench Query Editor

Finally, let’s take a look at the MySQL Workbench Query Editor. It has a lot of advanced features.   

First, I like that it is a multi-tab editor so you can have multiple Queries opened at once and you can switch between them easily.  It also has support for helpful snippets – both a large library of built-in ones as well as ones created by the user. It also has support for contextual help with can be quite helpful for beginners.

I like the fact MySQL Workbench adds LIMIT 1000 by default to queries it runs, and it also allows you to easily and conveniently edit the stored data.

Examine Field Types:

View Query execution statistics:

Though in this case, it seems to only show information derived from SHOW SESSION STATUS and not more advanced details available in Performance Schema. 

Visual Explain is quite a gem of MySQL Workbench too, but we covered it already.

Summary

In general, I’m quite impressed with the functionality offered with MySQL Workbench CE (Community Edition). For someone looking for a simple, free GUI for MySQL to run queries and provide basic help with administration you need to look no further. If you have more advanced needs, particularly in the monitoring or management space, you should look somewhere else. Oracle has MySQL Enterprise Monitor for this purpose which is a fully commercial product that comes with a MySQL Enterprise subscription.  If you are looking for an Open Source Database Monitoring-focused product, consider Percona Monitoring and Management.  

This blog post will help you configure a 3-node Percona XtraDB Cluster using a binary tarball on your local machine. Configuration files are auto-generated with mostly default configurations except for port/IP address details. The tool has the handy script to create configuration files and start multiple Percona XtraDB Cluster nodes on the fly, helping you to start PXC quickly without spending time on startup configuration as well as avoid using any virtual environments.  The script is available in the percona-qa github project. Currently, this script supports PXC binary tarball distributions only.

You can download the appropriate tarball package from the Percona-XtraDB-Cluster-8.0 downloads page. Once you have the packages available on your local machine, unpack the tarball package.

Note: You can use the DBDeployer tool to deploy PXC-5.7 servers easily. pxc-startup.sh script also works with PXC-5.7 packages.

Now we need to run the pxc-startup.sh script from the Percona XtraDB Cluster base directory. It will check out the PXC startup script called start_pxc.

The following steps will help you to start a 3-node PXC in CentOS 7.

1. Checkout pxc-startup.sh repo:

wget https://raw.githubusercontent.com/Percona-QA/percona-qa/master/pxc-tests/pxc-startup.sh

2. Download PXC binary tarball packages for CentOS7 (In this blog we will be using the PXC-8.0 experimental package):

wget https://www.percona.com/redir/downloads/TESTING/Percona-XtraDB-Cluster-8.0/centos7/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102.tar.gz

3. Unpack tarball package and run pxc-startup.sh script from Percona XtraDB Cluster base directory:

tar -xzf Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102.tar.gz

$ cd Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/

$ bash ../pxc-startup.sh
Added scripts: ./start_pxc
./start_pxc will create ./stop_pxc | ./*node_cli | ./wipe scripts
$

4. If you want to start the 3-node cluster, please use numeric 3 as parameter with ./start_pxc:

$ ./start_pxc 3
Starting PXC nodes…
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node1/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node1 started
  Configuration file : /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node1.cnf
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node2/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node2 started
  Configuration file : /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node2.cnf
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node3/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node3 started
  Configuration file : /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node3.cnf
$

The start_pxc script will also create shutdown(stop)/wipe/cli sanity scripts.

$ ls -1 *_node_cli wipe *_pxc
1_node_cli
2_node_cli
3_node_cli
start_pxc
stop_pxc
wipe
$

The ./stop_pxc script will stop all cluster nodes.

$ ./stop_pxc
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node3/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node3 halted
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node2/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node2 halted
Server on socket /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node1/socket.sock with datadir /home/vagrant/Percona-XtraDB-Cluster_8.0.15.5-27dev.4.2_Linux.x86_64.ssl102/node1 halted
$

The ./[1-3]_node_cli  scripts will help to login to the respective node using the MySQL client.

$ ./1_node_cli
[..]
node1:root@localhost> show status like 'wsrep_cluster_size';
+--------------------+-------+
| Variable_name      | Value |
+--------------------+-------+
| wsrep_cluster_size | 3     |
+--------------------+-------+

1 row in set (0.03 sec)
node1:root@localhost>

The ./wipe script will trigger stop_pxc script and move the data directory to .PREV.

$ ls  -d1 *.PREV
node1.PREV
node2.PREV
node3.PREV
$

The configuration files will be created in the base directory. You can also add custom configurations in the start_pxc script.

$ ls -1 *.cnf
node1.cnf
node2.cnf
node3.cnf
$