Personal blog of Yzmir Ramirez

Join Percona Chief Evangelist Colin Charles as he covers happenings, gives pointers and provides musings on the open source database community.

This week is clearly what I’d call a “MariaDB week” — plenty of announcements coming from MariaDB Corporation and MariaDB Foundation.

It started with Alibaba Cloud and MariaDB Announce the Launch of ApsaraDB RDS for MariaDB TX, which makes Alibaba Cloud the first public cloud to offer the enterprise offering of MariaDB, MariaDB TX 3.0. It is not available yet as of this announcement for rolling out from the interface, but I expect it will be soon. Exciting, as you can already get MariaDB Server on Amazon RDS for MariaDB, and you can join the waitlist preview for Azure.

MariaDB Corporation has received more funding from ServiceNow Ventures in the Series C round, and has gained a new board member in Pat Casey. ServiceNow is a user of MariaDB, and “ServiceNow’s platform runs on up to 85,000 MariaDB databases that serve more than 25 billion queries per hour.” There was an excellent keynote session at M|18 about how ServiceNow uses MariaDB. The Register refers to this as “protecting ServiceNow’s toolchain”.

For good measure, MariaDB acquired Clustrix as well. This is the second acquisition after MammothDB earlier in the year. It is worth reading the TechCrunch take on this. Clustrix, a Y Combinator company, has been around since 2006 and raised $72 million. The price of the acquisition was not announced. For a bit of behind the scenes chatter from ex-employee shareholders, Hacker News delivers.

From a MariaDB Foundation standpoint, we see Otto Kekäläinen, the MariaDB Foundation CEO stepping down. Thanks for all your hard work Otto! And maybe you missed it, but not long ago, Percona Became a Bronze Sponsor of MariaDB Foundation.

Speaking of conferences, the tutorial schedule and a sneak peek of sessions for Percona Live Europe Frankfurt have been announced. In addition, the Call for Papers – 2019 Annual MariaDB User Conference closes October 31, 2018.

Releases

• SQLite Release 3.25.1 now comes with enhancements to ALTER TABLE and window functions.
• Percona XtraDB Cluster 5.6.41-28.28
• Percona Server for MongoDB 3.2.21-3.12 and Percona Server for MongoDB 3.6.7-1.5

Link List

• MongoDB 4.1.3 is ready for testing and MMAPv1 has been removed. A very apt goodbye, “sometimes a piece of software has served its purpose and it’s time to move on. The original MongoDB storage engine, MMAPv1, was deprecated in 4.0 and will no longer be an option in 4.2.”
• Postgres 11 – a First Look — don’t forget to check out PostgreSQL 11 Beta 4.
• Mark Callaghan on durability debt, defined as “the amount of work that can be done to persist changes that have been applied to a database.“

Upcoming Appearances

• Open Source Summit Europe 2018 – 22-24 October 2018

Feedback

I look forward to feedback/tips via e-mail at colin.charles@percona.com or on Twitter @bytebot.

 

The post This Week in Data with Colin Charles 53: It’s MariaDB Week PLUS Percona Live Europe Update appeared first on Percona Database Performance Blog.

ProxySQL 1.4.10, released by ProxySQL, is now available for download in the Percona Repository along with an updated version of Percona’s proxysql-admin tool.

ProxySQL is a high-performance proxy, currently for MySQL and its forks (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.

The ProxySQL 1.4.10 source and binary packages available at https://percona.com/downloads/proxysql include ProxySQL Admin – a tool, developed by Percona to configure Percona XtraDB Cluster nodes into ProxySQL. Docker images for release 1.4.10 are available as well: https://hub.docker.com/r/percona/proxysql/. You can download the original ProxySQL from https://github.com/sysown/proxysql/releases.

Improvements

• PSQLADM-12: Implemented the writer-is-reader option in proxysql-admin. This is now a text option: ‘always’, ‘never’, and ‘ondemand’
• PSQLADM-64: Added the option --sync-multi-cluster-users which , that uses the same function as --sync-users but will not delete users on ProxySQL that don’t exist on MySQL
• PSQLADM-90: Added testsuites for host priority/slave/loadbal/writer-is-reader features
• Additional debugging support
  An additional --debug flag on scripts prints more output. All SQL calls are now logged if debugging is enabled.

Tool Enhancements

• proxysql-status
  proxysql-status now reads the credentials from the proxysql-admin.cnf file. It is possible to look only at certain tables (--files, --main, --monitor, --runtime, --stats). Also added the ability to filter based on the table name (--table)
• tests directory
  The proxysql-admin-testsuite.sh script can now be used to create test clusters (

  proxysql-admin-testsuite.sh <workdir> --no-test --cluster-one-only

   , this option will create a 3-node PXC cluster with 1 async slave and will also start proxyxql). Also added regression test suites.

• tools directory
  Added extra tools that can be used for debugging (mysql_exec, proxysql_exec, enable_scheduler, and run_galera_checker).

Bug Fixes

• PSQLADM-73: proxysql-admin did not check that the monitor user had been configured on the PXC nodes.
• PSQLADM-82: the without-check-monitor-user option did check the monitor user (even if it was enabled). This option has been replaced with use-existing-monitor-password.
• PSQLADM-83: proxysql_galera-checker could hang if there was no scheduler entry.
• PSQLADM-87: in some cases, proxysql_galera_checker was not moving a node to OFFLINE_SOFT if pxc_maint_mode was set to “maintenance”
• PSQLADM-88: proxysql_node_monitor was searching among all nodes, not just the read hostgroup.
• PSQLADM-91: Nodes in the priority list were not being picked.
• PSQLADM-93: If mode=’loadbal’, then the read_hostgroup setting was used from the config file, rather than being set to -1.
• PSQLADM-96: Centos used /usr/share/proxysql rather than /var/lib/proxysql
• PSQLADM-98: In some cases, checking the PXC node status could stall (this call now uses a TIMEOUT)

ProxySQL is available under OpenSource license GPLv3.

The post ProxySQL 1.4.10 and Updated proxysql-admin Tool Now in the Percona Repository appeared first on Percona Database Performance Blog.

Percona announces the release of Percona XtraDB Cluster 5.6.41-28.28 (PXC) on September 18, 2018. Binaries are available from the downloads section or our software repositories.

Percona XtraDB Cluster 5.6.41-28.28 is now the current release, based on the following:

• Percona Server for MySQL 5.6.41
• Codership WSREP API Rrelease 5.6.41
• Codership Galera library 3.24

Help us improve our software quality by reporting any bugs you encounter using our bug tracking system. As always, thanks for your continued support of Percona!

The post Percona XtraDB Cluster 5.6.41-28.28 Is Now Available appeared first on Percona Database Performance Blog.

It’s 2018. Maybe now is the time to start migrating your network to IPv6, and your database infrastructure is a great place to start. Unfortunately, many legacy applications don’t offer the option to connect to MySQL directly over IPv6 (sometimes even if passing a hostname). We can work around this by using ProxySQL’s IPv6 support which was added in version 1.3. This will allow us to proxy incoming IPv4 connections to IPv6-only database servers.

Note that by default ProxySQL only listens on IPv4. We don’t recommended changing that until this bug is resolved. The bug causes ProxySQL to segfault frequently if listening on IPv6.

In this example I’ll use centos7-pxc57-1 as my database server. It’s running Percona XtraDB Cluster (PXC) 5.7 on CentOS 7,  which is only accessible over IPv6. This is one node of a three node cluster, but l treat this one node as a standalone server for this example.  One node of a synchronous cluster can be thought of as equivalent to the entire cluster, and vice-versa. Using the PXC plugin for ProxySQL to split reads from writes is the subject of a future blog post.

The application server, centos7-app01, would be running the hypothetical legacy application.

Note: We use default passwords throughout this example. You should always change the default passwords.

We have changed the IPv6 address in these examples. Any resemblance to real IPv6 addresses, living or dead, is purely coincidental.

• 2a01:5f8:261:748c::74 is the IPv6 address of the ProxySQL server
• 2a01:5f8:261:748c::71 is the Percona XtraDB node

Step 1: Install ProxySQL for your distribution

Packages are available here but in this case I’m going to use the version provided by the Percona yum repository:

[...]
Installed:
proxysql.x86_64 0:1.4.9-1.1.el7
Complete!

Step 2: Configure ProxySQL to listen on IPv4 TCP port 3306 by editing /etc/proxysql.cnf and starting it

[root@centos7-app1 ~]# vim /etc/proxysql.cnf
[root@centos7-app1 ~]# grep interfaces /etc/proxysql.cnf
interfaces="127.0.0.1:3306"
[root@centos7-app1 ~]# systemctl start proxysql

Step 3: Configure ACLs on the destination database server to allow ProxySQL to connect over IPv6

mysql> GRANT SELECT on sys.* to 'monitor'@'2a01:5f8:261:748c::74' IDENTIFIED BY 'monitor';
Query OK, 0 rows affected, 1 warning (0.25 sec)
mysql> GRANT ALL ON legacyapp.* TO 'legacyappuser'@'2a01:5f8:261:748c::74' IDENTIFIED BY 'super_secure_password';
Query OK, 0 rows affected, 1 warning (0.25 sec)

Step 4: Add the IPv6 address of the destination server to ProxySQL and add users

We need to configure the IPv6 server as a mysql_server inside ProxySQL. We also need to add a user to ProxySQL as it will reuse these credentials when connecting to the backend server. We’ll do this by connecting to the admin interface of ProxySQL on port 6032:

[root@centos7-app1 ~]# mysql -h127.0.0.1 -P6032 -uadmin -padmin
mysql: [Warning] Using a password on the command line interface can be insecure.
Welcome to the MySQL monitor.
Commands end with ; or \g.
Your MySQL connection id is 4
Server version: 5.5.30 (ProxySQL Admin Module)
Copyright (c) 2009-2018 Percona LLC and/or its affiliates
Copyright (c) 2000, 2018, 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> INSERT INTO mysql_servers(hostgroup_id,hostname,port) VALUES (1,'2a01:5f8:261:748c::71',3306);
Query OK, 1 row affected (0.00 sec)
mysql> INSERT INTO mysql_users(username, password, default_hostgroup) VALUES ('legacyappuser', 'super_secure_password', 1);
Query OK, 1 row affected (0.00 sec)
mysql> LOAD MYSQL USERS TO RUNTIME;
Query OK, 0 rows affected (0.00 sec)
mysql> SAVE MYSQL USERS TO DISK;
Query OK, 0 rows affected (0.27 sec)
mysql> LOAD MYSQL SERVERS TO RUNTIME;
Query OK, 0 rows affected (0.01 sec)
mysql> SAVE MYSQL SERVERS TO DISK;
Query OK, 0 rows affected (0.30 sec)
mysql> LOAD MYSQL VARIABLES TO RUNTIME;
Query OK, 0 rows affected (0.00 sec)
mysql> SAVE MYSQL VARIABLES TO DISK;
Query OK, 95 rows affected (0.12 sec)

Step 5: Configure your application to connect to ProxySQL over IPv4 on localhost4 (IPv4 localhost)

This is application specific and so not shown here, but I’d configure my application to use localhost4 as this is in /etc/hosts by default and points to 127.0.0.1 and not ::1

Step 6: Verify

As I don’t have the application here, I’ll verify with mysql-client. Remember that ProxySQL is listening on 127.0.0.1 port 3306, so we connect via ProxySQL on IPv4 (the usage of 127.0.0.1 rather than a hostname is just to show this explicitly):

[root@centos7-app1 ~]# mysql -h127.0.0.1 -ulegacyappuser -psuper_secure_password
mysql: [Warning] Using a password on the command line interface can be insecure.
mysql> SELECT host FROM information_schema.processlist WHERE ID=connection_id();
+-----------------------------+
| host                        |
+-----------------------------+
| 2a01:5f8:261:748c::74:57546 |
+-----------------------------+
1 row in set (0.00 sec)
mysql> CREATE TABLE legacyapp.legacy_test_table(id int);
Query OK, 0 rows affected (0.83 sec)

The query above shows the remote host (from MySQL’s point of view) for the current connection. As you can see, MySQL sees this connection established over IPv6. So to recap, we connected to MySQL on an IPv4 IP address (127.0.0.1) and were successfully proxied to a backend IPv6 server.

The post Using ProxySQL to connect to IPv6-only databases over IPv4 appeared first on Percona Database Performance Blog.

Recently, I wrote a blog post showing how to enforce SELinux with Percona XtraDB Cluster (PXC). The Linux distributions derived from RedHat use SELinux. There is another major mandatory discretionary access control (DAC) system, AppArmor. Ubuntu, for example, installs AppArmor by default. If you are concerned by computer security and use PXC on Ubuntu, you should enforce AppArmor. This post will guide you through the steps of creating a profile for PXC and enabling it. If you don’t want to waste time, you can just grab my profile, it seems to work fine. Adapt it to your environment if you are using non-standard paths. Look at the section “Copy the profile” for how to install it. For the brave, let’s go!

Install the tools

In order to do anything with AppArmor, we need to install the tools. On Ubuntu 18.04, I did:

apt install apparmor-utils

The apparmor-utils package provides the tools we need to generate a skeleton profile and parse the system logs.

Create a skeleton profile

AppArmor is fairly different from SELinux. Instead of attaching security tags to resources, you specify what a given binary can access, and how, in a text file. Also, processes can inherit permissions from their parent. We will only create a profile for the mysqld_safe script and it will cover the mysqld process and the SST scripts as they are executed under it. You create the skeleton profile like this:

root@BlogApparmor2:~# aa-autodep /usr/bin/mysqld_safe
Writing updated profile for /usr/bin/mysqld_safe.

On Ubuntu 18.04, there seems to be a bug. I reported it and apparently I am not the only one with the issue. If you get a “KeyError” error with the above command, try:

root@BlogApparmor2:~# echo "#include <abstractions>" > /etc/apparmor.d/scripts
root@BlogApparmor2:~# aa-autodep /usr/bin/mysqld_safe

The aa-autodep command creates the profile “usr.bin.mysqld_safe” in the /etc/apparmor.d directory. The initial content is:

root@BlogApparmor2:~# cat /etc/apparmor.d/usr.bin.mysqld_safe
# Last Modified: Wed Jul 25 18:56:31 2018
#include <tunables/global>
/usr/bin/mysqld_safe flags=(complain) {
  #include <abstractions/base>
  #include <abstractions/bash>
  /bin/dash ix,
  /lib/x86_64-linux-gnu/ld-*.so mr,
  /usr/bin/mysqld_safe r,
}

I suggest you add, ahead of time, things you know are needed. In my case, I added:

/etc/mysql/** r,
/usr/bin/innobackupex mrix,
/usr/bin/wsrep_sst_xtrabackup-v2 mrix,
/usr/lib/galera3/* r,
/usr/lib/mysql/plugin/* r,
/usr/sbin/mysqld mrix,
/var/log/mysqld.log w,
owner /tmp/** rw,
owner /var/lib/mysql/** rwk,

This will save time on redundant questions later. Those entries are permissions granted to mysqld_safe. For example,

/etc/mysql** r

  allows to read everything in

/etc/mysql

  and its subdirectories. These lines need to go right after the

/usr/bin/mysqld_safe r,

  line. Once done, parse and load the profile with:

root@BlogApparmor2:~# apparmor_parser -r /etc/apparmor.d/usr.bin.mysqld_safe

Get a well behaved SST script

If you read my previous blog post on SELinux, you may recall the

wsrep_sst_xtrabackup-v2

  script does not behave well, security wise. The Percona developers have released a fixed version but it may not be available yet in a packaged form. In the meantime, you can download it from github.

Start iterating

My initial thought was to put the profile in complain mode, generate activity and parse the logs with aa-logprof to get entries to add to the profile. Likely there is something I am doing wrong but in complain mode, aa-logprof detects nothing. In order to get something I had to enforce the profile with:

root@BlogApparmor2:~# aa-enforce /etc/apparmor.d/usr.bin.mysqld_safe

Then, I iterated many times—like more than 20—over the following sequence:

1. rm -rf /var/lib/mysql/* # optional
2. systemctl start mysql &
3. tail -f /var/log/mysqld.log /var/log/kern.log
4. systemctl stop mysql
5. ps fax | egrep ‘mysqld_safe|mysqld’ | grep -v grep | awk ‘{print $1}’ | xargs kill -9 # sometimes
6. aa-logprof
7. if something was not right, jump back to step 1

See the next section for how to run aa-logprof. Once that sequence worked well, I tried SST (joiner/donor) roles and IST.

Parse the logs with aa-logprof

Now, the interesting part begins, parsing the logs. Simply begin the process with:

root@BlogApparmor2:~#  aa-logprof

and answer the questions. Be careful, I made many mistakes before I got it right, remember I am more a DBA than a Sysadmin. For example, you’ll get questions like:

Profile:  /usr/sbin/mysqld
Path:     /etc/hosts.allow
New Mode: r
Severity: unknown
 [1 - #include <abstractions/lxc/container-base>]
  2 - #include <abstractions/lxc/start-container>
  3 - /etc/hosts.allow r,
(A)llow / [(D)eny] / (I)gnore / (G)lob / Glob with (E)xtension / (N)ew / Audi(t) / Abo(r)t / (F)inish

AppArmor asks you how it should provide read access to the

/etc/hosts.allow

  file. If you answer right away with “A”, it will add

#include <abstractions/lxc/container-base>

 to the profile. With all the dependencies pulled by the lxc-related includes, you basically end up allowing nearly everything. You must first press “3” to get:

Profile:  /usr/sbin/mysqld
Path:     /etc/hosts.allow
New Mode: r
Severity: unknown
  1 - #include <abstractions/lxc/container-base>
  2 - #include <abstractions/lxc/start-container>
 [3 - /etc/hosts.allow r,]
(A)llow / [(D)eny] / (I)gnore / (G)lob / Glob with (E)xtension / (N)ew / Audi(t) / Abo(r)t / (F)inish

Notice the “[ ]” have moved to the bottom entry and then, press “A”. You’ll also get questions like:

Profile:  /usr/bin/mysqld_safe
Execute:  /bin/sed
Severity: unknown
(I)nherit / (C)hild / (N)amed / (X) ix On / (D)eny / Abo(r)t / (F)inish

For such a question, my answer is “I” for inherit. After a while, you’ll get through all the questions and you’ll be asked to save the profile:

The following local profiles were changed. Would you like to save them?
 [1 - /usr/bin/mysqld_safe]
(S)ave Changes / Save Selec(t)ed Profile / [(V)iew Changes] / View Changes b/w (C)lean profiles / Abo(r)t
Writing updated profile for /usr/bin/mysqld_safe.

Revise the profile

Do not hesitate to edit the profile if you see, for example, many similar file entries which could be replaced by a “*” or “**”. If you manually modify the profile, you need to parse it to load your changes:

root@BlogApparmor2:~# apparmor_parser -r /etc/apparmor.d/usr.bin.mysqld_safe

Copy the profile

Once you have a server running with AppArmor enforced on PXC, simply copy the profile to the other servers and parse it. For example:

root@BlogApparmor3:~# cd /etc/apparmor.d
root@BlogApparmor3:/etc/apparmor.d# scp ubuntu@10.0.4.76:/etc/apparmor.d/usr.bin.mysqld_safe .
ubuntu@10.0.4.76's password:
usr.bin.mysqld_safe                                   100% 2285     3.0MB/s   00:00
root@BlogApparmor3:/etc/apparmor.d# aa-enforce usr.bin.mysqld_safe
Setting /etc/apparmor.d/usr.bin.mysqld_safe to enforce mode.

You can always verify if the profile is enforced with:

root@BlogApparmor3:/etc/apparmor.d# aa-status
apparmor module is loaded.
42 profiles are loaded.
20 profiles are in enforce mode.
 /sbin/dhclient
 ...
 /usr/bin/mysqld_safe
 ...
 man_groff

Once enforced, I strongly advise to monitor the log files on a regular basis to see if anything has been overlooked. Similarly if you encounter a strange and unexpected behavior with PXC. Have the habit of checking the logs, it might save a lot of frustrating work.

Conclusion

As we have just seen, enabling AppArmor with PXC is not a difficult task, it just requires some patience. AppArmor is an essential component of a layered security approach. It achieves similar goals as the other well known DAC framework, SELinux. With the rising security concerns and the storage of sensitive data in databases, there are compelling reasons to enforce a DAC framework. I hope these two posts will help DBAs and Sysadmins to configure and enable DAC for PXC.

The post Lock Down: Enforcing AppArmor with Percona XtraDB Cluster appeared first on Percona Database Performance Blog.

Please join Percona’s Architect, Tibi Köröcz as he presents Utilizing ProxySQL for Connection Pooling in PHP on Tuesday August 14, 2018, at 8:00 am PDT (UTC-7) / 11:00 am EDT (UTC-4).

 

ProxySQL is a very powerful tool, with extended capabilities. This presentation will demonstrate how to use ProxySQL to gain functionality (seamless database backend switch) and correct problems (applications missing connection pooling).

The presentation will be a real-life study on how we use ProxySQL for connection pooling, database failover and load balancing the communication between our (third party) PHP-application and our master-master MySQL-cluster.
Also, we will show monitoring and statistics using Percona Monitoring and Management (PMM).

Register Now!

Tibor Köröcz

 

The post Webinar Tues 8/14: Utilizing ProxySQL for Connection Pooling in PHP appeared first on Percona Database Performance Blog.

ProxySQL 1.4.9, released by ProxySQL, is now available for download in the Percona Repository along with an updated version of Percona’s proxysql-admin tool.

ProxySQL is a high-performance proxy, currently for MySQL and its forks (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.

The ProxySQL 1.4.9 source and binary packages available at https://percona.com/downloads/proxysql include ProxySQL Admin – a tool, developed by Percona to configure Percona XtraDB Cluster nodes into ProxySQL. Docker images for release 1.4.9 are available as well: https://hub.docker.com/r/percona/proxysql/. You can download the original ProxySQL from https://github.com/sysown/proxysql/releases.

This release contains the following bug fixes and enhancements in ProxySQL Admin:

• PSQLADM-31:  proxysql-admin is now able to handle multiple ProxySQL instances using separate configuration files passed with the enable command. This new multi-instance functionality was the reason to fix detection of a hostgroup, which was previously hardcoded in the script (bug fixed PSQLADM-56), and to fix features broken on multiple clusters: host priority (bug fixed PSQLADM-63), user accounts sync (bug fixed PSQLADM-70), and, finally, reading right cluster name from scheduler by the Galera checker script, broken in case of a matching write hostgroup (bug fixed PSQLADM-69).
• BLD-1068: A “-percona” suffix added to the proxysql version now indicates the Percona built version.
• PSQLADM-62: The new  --without-check-monitor-user option allows using ProxySQL Admin tool  without human interaction, to provide an automatic deployment.
• PSQLADM-57: proxysql-admin script now checks if the current user has sufficient privileges on the ProxySQL data directory instead of unconditionally asking to be executed by root user.
• PSQLADM-67: When the cluster comes back online after the maintenance activity (in which all nodes are OFFLINE_SOFT and are moved to a reader hostgroup), Galera checker will now promote one of the read nodes to write node in singlewrite mode setup.
• PSQLADM-58: Now the proxysql_galera_checker script terminates if the monitor credentials do not match ones of Percona XtraDB Cluster, to avoid situations when monitor user password rotation puts the cluster to a read-only state until the next ProxySQL restart.

ProxySQL is available under the OpenSource license GPLv3.

The post ProxySQL 1.4.9 and Updated proxysql-admin Tool Now in the Percona Repository appeared first on Percona Database Performance Blog.

In this post we will review the most important Linux settings to adjust for performance tuning and optimization of a MySQL database server. We’ll note how some of the Linux parameter settings used OS tuning may vary according to different system types: physical, virtual or cloud. Other posts have addressed MySQL parameters, like Alexander’s blog MySQL 5.7 Performance Tuning Immediately After Installation. That post remains highly relevant for the latest versions of MySQL, 5.7 and 8.0. Here we will focus more on the Linux operating system parameters that can affect database performance.

Server and Operating System

Here are some Linux parameters that you should check and consider modifying if you need to improve database performance.

Kernel – vm.swappiness

The value represents the tendency of the kernel  to swap out memory pages. On a database server with ample amounts of RAM, we should keep this value as low as possible. The extra I/O can slow down or even render the service unresponsive. A value of 0 disables swapping completely while 1 causes the kernel to perform the minimum amount of swapping. In most cases the latter setting should be OK:

# Set the swappiness value as root
echo 1 > /proc/sys/vm/swappiness
# Alternatively, using sysctl
sysctl -w vm.swappiness=1
# Verify the change
cat /proc/sys/vm/swappiness
1
# Alternatively, using sysctl
sysctl vm.swappiness
vm.swappiness = 1

The change should be also persisted in /etc/sysctl.conf:

vm.swappiness = 1

Filesystems – XFS/ext4/ZFS

XFS

XFS is a high-performance, journaling file system designed for high scalability. It provides near native I/O performance even when the file system spans multiple storage devices.  XFS has features that make it suitable for very large file systems, supporting files up to 8EiB in size. Fast recovery, fast transactions, delayed allocation for reduced fragmentation and near raw I/O performance with DIRECT I/O.

The default options for mkfs.xfs are good for optimal speed, so the simple command:

# Use default mkfs options
mkfs.xfs /dev/target_volume

will provide best performance while ensuring data safety. Regarding mount options, the defaults should fit most cases. On some filesystems you can see a performance increase by adding the noatime mount option to the /etc/fstab.  For XFS filesystems the default atime behaviour is relatime, which has almost no overhead compared to noatime and still maintains sane atime values.  If you create an XFS file system on a LUN that has a battery backed, non-volatile cache, you can further increase the performance of the filesystem by disabling the write barrier with the mount option nobarrier. This helps you to avoid flushing data more often than necessary. If a BBU (backup battery unit) is not present, however, or you are unsure about it, leave barriers on, otherwise you may jeopardize data consistency. With this options on, an /etc/fstab file should look like the one below:

/dev/sda2              /datastore              xfs     defaults,nobarrier
/dev/sdb2              /binlog                 xfs     defaults,nobarrier

ext4

ext4 has been developed as the successor to ext3 with added performance improvements. It is a solid option that will fit most workloads. We should note here that it supports files up to 16TB in size, a smaller limit than xfs. This is something you should consider if extreme table space size/growth is a requirement. Regarding mount options, the same considerations apply. We recommend the defaults for a robust filesystem without risks to data consistency. However, if an enterprise storage controller with a BBU cache is present, the following mount options will provide the best performance:

/dev/sda2              /datastore              ext4     noatime,data=writeback,barrier=0,nobh,errors=remount-ro
/dev/sdb2              /binlog                 ext4     noatime,data=writeback,barrier=0,nobh,errors=remount-ro

Note: The data=writeback option results in only metadata being journaled, not actual file data. This has the risk of corrupting recently modified files in the event of a sudden power loss, a risk which is minimised with a presence of a BBU enabled controller. nobh only works with the data=writeback option enabled.

ZFS

ZFS is a filesystem and LVM combined enterprise storage solution with extended protection vs data corruption. There are certainly cases where the rich feature set of ZFS makes it an essential option to consider, most notably when advance volume management is a requirement. ZFS tuning for MySQL can be a complex topic and falls outside the scope of this blog. For further reference, there is a dedicated blog post on the subject by Yves Trudeau:

Disk Subsystem – I/O scheduler 

Most modern Linux distributions come with noop or deadline I/O schedulers by default, both providing better performance than the cfq and anticipatory ones. However it is always a good practice to check the scheduler for each device and if the value shown is different than noop or deadline the policy can change without rebooting the server:

# View the I/O scheduler setting. The value in square brackets shows the running scheduler
cat /sys/block/sdb/queue/scheduler
noop deadline [cfq]
# Change the setting
sudo echo noop > /sys/block/sdb/queue/scheduler

To make the change persistent, you must modify the GRUB configuration file:

# Change the line:
GRUB_CMDLINE_LINUX_DEFAULT="quiet splash"
# to:
GRUB_CMDLINE_LINUX_DEFAULT="quiet splash elevator=noop"

AWS Note: There are cases where the I/O scheduler has a value of none, most notably in AWS VM instance types where EBS volumes are exposed as NVMe block devices. This is because the setting has no use in modern PCIe/NVMe devices. The reason is that they have a very large internal queue and they bypass the IO scheduler altogether. The setting in this case is none and it is the optimal in such disks.

Disk Subsystem – Volume optimization

Ideally different disk volumes should be used for the OS installation, binlog, data and the redo log, if this is possible. The separation of OS and data partitions, not just logically but physically, will improve database performance. The RAID level can also have an impact: RAID-5 should be avoided as the checksum needed to ensure integrity is costly. The best performance without making compromises to redundancy is achieved by the use of an advanced controller with a battery-backed cache unit and preferably RAID-10 volumes spanned across multiple disks.

AWS Note: For further information about EBS volumes and AWS storage optimisation, Amazon has documentation at the following links:

https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/nvme-ebs-volumes.html

https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/storage-optimized-instances.html

Database settings

System Architecture – NUMA settings

Non-uniform memory access (NUMA) is a memory design where an SMP’s system processor can access its own local memory faster than non-local memory (the one assigned local to other CPUs). This may result in suboptimal database performance and potentially swapping. When the buffer pool memory allocation is larger than size of the RAM available local to the node, and the default memory allocation policy is selected, swapping occurs. A NUMA enabled server will report different node distances between CPU nodes. A uniformed one will report a single distance:

# NUMA system
numactl --hardware
available: 4 nodes (0-3)
node 0 cpus: 0 1 2 3 4 5 6 7
node 0 size: 65525 MB
node 0 free: 296 MB
node 1 cpus: 8 9 10 11 12 13 14 15
node 1 size: 65536 MB
node 1 free: 9538 MB
node 2 cpus: 16 17 18 19 20 21 22 23
node 2 size: 65536 MB
node 2 free: 12701 MB
node 3 cpus: 24 25 26 27 28 29 30 31
node 3 size: 65535 MB
node 3 free: 7166 MB
node distances:
node   0   1   2   3
  0:  10  20  20  20
  1:  20  10  20  20
  2:  20  20  10  20
  3:  20  20  20  10
# Uniformed system
numactl --hardware
available: 1 nodes (0)
node 0 cpus: 0 1 2 3 4 5 6 7
node 0 size: 64509 MB
node 0 free: 4870 MB
node distances:
node   0
  0:  10

In the case of a NUMA system, where numactl shows different distances across nodes, the MySQL variable innodb_numa_interleave should be enabled to ensure memory interleaving. Percona Server provides improved NUMA support by introducing the flush_caches variable. When enabled, it will help with allocation fairness across nodes. To determine whether or not allocation is equal across nodes, you can examine numa_maps for the mysqld process with this script:

# The perl script numa_maps.pl will report memory allocation per CPU node:
# 3595 is the pid of the mysqld process
perl numa_maps.pl < /proc/3595/numa_maps
N0        :     16010293 ( 61.07 GB)
N1        :     10465257 ( 39.92 GB)
N2        :     13036896 ( 49.73 GB)
N3        :     14508505 ( 55.35 GB)
active    :          438 (  0.00 GB)
anon      :     54018275 (206.06 GB)
dirty     :     54018275 (206.06 GB)
kernelpagesize_kB:         4680 (  0.02 GB)
mapmax    :          787 (  0.00 GB)
mapped    :         2731 (  0.01 GB)

Conclusion

In this blog post we examined a few important OS related settings and explained how they can be tuned for better database performance.

While you are here …

You might also find value in this recorded webinar Troubleshooting Best Practices: Monitoring the Production Database Without Killing Performance

 

The post Linux OS Tuning for MySQL Database Performance appeared first on Percona Database Performance Blog.

Percona announces the release of Percona XtraDB Cluster 5.7.22-29.26 (PXC) on June 29, 2018. Binaries are available from the downloads section or our software repositories.

Percona XtraDB Cluster 5.7.22-29.26 is now the current release, based on the following:

• Percona Server for MySQL 5.7.22
• Galera/Codership WSREP API Release 5.7.21
• Galera Replication library 3.23

Deprecated

The following variables are deprecated starting from this release:

• wsrep-force-binlog-format
• wsrep_sst_method = mysqldump

As long as the use of binlog_format=ROW is enforced in 5.7, wsrep_forced_binlog_format variable is much less significant. The same is related to mysqldump, as xtrabackup is now the recommended SST method.

New features

• PXC-907: New variable wsrep_RSU_commit_timeout allows to configure RSU wait for active commit connection timeout (in microseconds).
• Percona XtraDB Cluster now supports the keyring_vault plugin, which allows to store the master key in a vault server.
• Percona XtraDB Cluster  5.7.22 depends on Percona XtraBackup  2.4.12 in order to fully support vault plugin functionality.

Help us improve our software quality by reporting any bugs you encounter using our bug tracking system. As always, thanks for your continued support of Percona!

The post Percona XtraDB Cluster 5.7.22-29.26 Is Now Available appeared first on Percona Database Performance Blog.

Kubernetes, and its most popular distribution OpenShift, receives a lot of interest as a container orchestration platform. However, databases remain a foreign entity, primarily because of their stateful nature, since container orchestration systems prefer stateless applications. That said, there has been good progress in support for StatefulSet applications and persistent storage, to the extent that it might be already comfortable to have a production database instance running in Kubernetes. With this in mind, we’ve been looking at running Percona XtraDB Cluster in Kubernetes/OpenShift.

While there are already many examples on the Internet of how to start a single MySQL instance in Kubernetes, for serious usage we need to provide:

• High Availability: how can we guarantee availability when an instance (or Pod in Kubernetes terminology) crashes or becomes unresponsive?
• Persistent storage: we do not want to lose our data in case of instance failure
• Backup and recovery
• Traffic routing: in the case of multiple instances, how do we direct an application to the correct one
• Monitoring

Percona XtraDB Cluster in Kubernetes/OpenShift

Schematically it looks like this:

The picture highlights the components we are going to use

• Percona XtraDB Cluster to provide High Availability. Although it is possible to use regular MySQL Replication, the need for automatic master failover makes it quite complicated. Shlomi describes some possible approaches here, and we may implement some of this in Percona Server for MySQL in the future.
• (Optional) ProxySQL with proxysql-admin tools
• (Optional) Percona Monitoring and Management (PMM) Server with clients installed on each node
• Support for backup volumes

Running this in Kubernetes assumes a high degree of automation and minimal manual intervention.

We provide our proof of concept in this project: https://github.com/Percona-Lab/percona-openshift. Please treat it like a source for ideas and as an alpha-quality project, in no way it is production ready.

Details

In our implementation we rely on Helm, the package manager for Kubernetes.  Unfortunately OpenShift does not officially support Helm out of the box, but there is a guide from RedHat on how to make it work.

In the clustering setup, it is quite typical to use a service discovery software like Zookeeper, etcd or Consul. It may become necessary for our Percona XtraDB Cluster deployment, but for now, to simplify deployment, we are going to use the DNS service discovery mechanism provided by Kubernetes. It should be enough for our needs.

We also expect the Kubernetes deployment to provide Dynamic Storage Provisioning. The major cloud providers (like Google Cloud, Microsoft Azure or Amazon Cloud) should have it. Also, it might not be easy to have Dynamic Storage Provisioning for on-premise deployments. You may need to setup GlusterFS or Ceph to provide Dynamic Storage Provisioning.

The challenge with a distributed file system is how many copies of data you will end up having. Percona XtraDB Cluster by itself has three copies, and GlusterFS will also require at least two copies of the data, so in the end we will have six copies of the data. This can’t be good for write intensive applications, but it’s also not good from the capacity standpoint.

One possible approach is to have local data copies for Percona XtraDB Cluster deployments. This will provide better performance and less impact on the network, but in the case of a big dataset (100GB+ ) the node failure will require SST with a big impact on the cluster and network. So the individual solution should be tailored for your workload and your requirements.

Now, as we have a basic setup working, it would be good to understand the performance impact of running Percona XtraDB Cluster in Kubernetes.  Is the network and storage overhead acceptable or it is too big? We plan to look into this in the future.

Once again, our project is located at https://github.com/Percona-Lab/percona-openshift, we are looking for your feedback and for your experience of running databases in Kubernetes/OpenShift.

Before you leave …

Percona XtraDB Cluster

If this article has interested you and you would like to know more about Percona XtraDB Cluster, you might enjoy our recent series of webinar tutorials that introduce this software and how to use it.

The post Running Percona XtraDB Cluster in Kubernetes/OpenShift appeared first on Percona Database Performance Blog.