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== Master/Master database setup ==
== Overview ==
This article describes the setup process "Master/Master replication" for new Open-Xchange  database cluster. During configuration and initialization, other database operations must be prohibited.


The Master/Master replication is a vice versa setup of Master/Slave configurations. This Means each server is afterwards the slave of the other.  
You can choose between Galera or Master/Slave replication. We like to recommend to use Galera for higher redudancy, easier operations, und synchronous semantics (so you can run OX without our "replication monitor"). For POC or demo setups, a single standalone database setup might be sufficient.


Server IPs in the example are 1.1.1.1 and 9.9.9.9
== Standalone database setup ==


Startup both database machines and install the mysql server packages
=== Preparations ===
$ apt-get install mysql-server


During the installation, a dialog will show up to set a password for the MySQL 'root' user.
Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database server, please be prepared to wipe the datadir, i.e. take a <code>mysqldump</code> for later restoration into the properly configured master.


Open the MySQL configuration file on both servers:
  mysqldump --databases configdb oxdb_{5..14} > backup.sql
  $ vim /etc/mysql/my.cnf


Modify or enable the following configuration options in the mysqld-section, use 1 as ${unique Number} on the server 1.1.1.1 and 2 for 9.9.9.9:
Be sure to verify the list of databases.
bind-address            = 0.0.0.0
server-id              = ${unique Number}
log_bin                = /var/log/mysql/mysql-bin.log
binlog_format          = statement
* ''bindaddress'' specifies the network address where MySQL is listening for network connections. Since the MySQL slave and both Open-Xchange Servers are dedicated machines it is required to have the master accessible through the network.
* ''server-id'' is just a unique number within a environment with multiple MySQL servers. It needs to be unique for each server in a replication cluster.
* ''log-bin'' enables the MySQL binary log which is required for Master/Master replication. In general every statement triggered at the database is stored there to get distributed through the database cluster.


To apply the configuration changes, restart the MySQL servers.
=== Installation ===
$ /etc/init.d/mysql restart


Then login to MySQL with the credentials given at the MySQL installation process
Note: the following list is not an exclusive list or authorative statement about supported MySQL flavors / versions. Please consult the official support / system requirements statement.
$ mysql -u root -p
Enter password:


=== First Master configuration ===
Please follow the upstream docs for your preferred flavor to get the software installed on your system.
Choose one server to start with as the first Master (here we use 1.1.1.1).


Create a MySQL user with rights "REPLICATION". This account is used by the MySQL slave to fetch database updates. In this example, the username is "replication":
* MariaDB (10.1, 10.2): https://downloads.mariadb.org/
* Oracle MySQL Community Server (5.6, 5.7): https://dev.mysql.com/downloads/mysql/


  mysql> GRANT REPLICATION SLAVE ON *.* TO 'replication'@'9.9.9.9' IDENTIFIED BY 'secret';
Make sure to doublecheck the service is not running (or stop it) after installation as we need to perform some reconfigurations.


Verify that the MySQL daemon writes a binary log and note the log Position and File name:
  service mysql stop
  mysql> SHOW MASTER STATUS;
+------------------+----------+--------------+------------------+
| File            | Position | Binlog_Do_DB | Binlog_Ignore_DB |
+------------------+----------+--------------+------------------+
| mysql-bin.000001 |      1111 |              |                  |
+------------------+----------+--------------+------------------+


=== First Slave configuration ===
=== Configuration ===


On 9.9.9.9, set the MySQL system user as owner of the binary log that has just been copied to the slave.
MySQL configuration advise is given in our [[My.cnf|MySQL configuration article]]. Please consult that page for configuration information and create configuration files as described there.
$ chown mysql:adm /var/log/mysql/*


Configure MySQL on 9.9.9.9 to use 1.1.1.1 as Master Server. (Use the actual log File name and Position which you just obtained with the command SHOW MASTER STATUS  on 1.1.1.1. as explained above.)
Some settings we recommend to change require that the database gets re-initialized. We assume you don't have data there (since we are covering a fresh install) or you have taken a backup for later restore as explained above in the Preparations section.
mysql> CHANGE MASTER TO MASTER_HOST='1.1.1.1', MASTER_USER='replication', MASTER_PASSWORD='secret', MASTER_LOG_FILE='mysql-bin.000001', MASTER_LOG_POS=1111;


Start the MySQL slave replication
cd /var/lib/
  mysql> START SLAVE;
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql
# mariadb
mysql_install_db
# mariadb 10.2
mysql_install_db --user=mysql
# oracle 5.6
mysql_install_db -u mysql
# oracle 5.7
  mysqld --initialize-insecure --user=mysql


And check the status
(Don't be worried about the <code>insecure</code>, it just means we set the db root pw in the next steps.)
mysql> SHOW SLAVE STATUS\G;


"Slave_IO_Running" and "Slave_SQL_Running" should be set to "yes". Furthermore "Read_Master_Log_Pos" should be counting and "Seconds_Behind_Master" should be approaching the 0 mark.
Start the service. The actual command depends on your OS and on the MySQL flavor.


=== Second Master configuration ===
service mysql start


This means, the first Master/Slave Replication is working and the "reverse" replication needs to be prepared. Please now create the replication user on 9.9.9.9:
Run <code>mysql_secure_installation</code> for a "secure by default" installation:


  mysql> GRANT REPLICATION SLAVE ON *.* TO 'replication'@'1.1.1.1' IDENTIFIED BY 'secret';
mariadb-secure-installation


Verify that the MySQL daemon writes a binary log and remember the log Position:
That tool will ask for the current root password (which is empty by default) and subsequently questions like:
mysql> SHOW MASTER STATUS;
+------------------+----------+--------------+------------------+
| File            | Position | Binlog_Do_DB | Binlog_Ignore_DB |
+------------------+----------+--------------+------------------+
| mysql-bin.000009 |      9999|              |                  |
+------------------+----------+--------------+------------------+


=== Second Slave configuration ===
Change the root password? [Y/n]
Remove anonymous users? [Y/n]
Disallow root login remotely? [Y/n]
Remove test database and access to it? [Y/n]
Reload privilege tables now? [Y/n]


1.1.1.1 is now the slave in this context and 9.9.9.9 is the master. Log in to 1.1.1.1
You should answer all these questions with "yes".


Configure MySQL on 1.1.1.1 to use 9.9.9.9 as Master Server. Use the remembered log and file position from 1.1.1.1.
Configure a strong password for the MySQL <code>root</code> user.
mysql> CHANGE MASTER TO MASTER_HOST='9.9.9.9', MASTER_USER='replication', MASTER_PASSWORD='secret', MASTER_LOG_FILE='mysql-bin.000009', MASTER_LOG_POS=9999;


start the MySQL slave replication
The further steps in this guide omit <code>-u -p</code> arguments to the MySQL client. Rather than passing them on the command line [https://dev.mysql.com/doc/refman/5.7/en/password-security-user.html] it is recommended to place the credentials in a file like <code>/root/.my.cnf</code> like
mysql> START SLAVE;


and check the status
[client]
  mysql> SHOW SLAVE STATUS\G;
user=root
  password=wip9Phae3Beijeed


"Slave_IO_Running" and "Slave_SQL_Running" should be set to "yes". Furthermore  "Read_Master_Log_Pos" should be counting and "Seconds_Behind_Master" should be approaching the 0 mark.
Make sure the service is enabled by the OS's init system. The actual command depends on your OS and on the MySQL flavor.


Also check the syslog if the replication has been sucessfully started
  systemctl enable mysql.service
  $ tail -fn20 /var/log/syslog
Jul 26 19:03:45 dbslave mysqld[4718]: 090726 19:03:45 [Note] Slave I/O thread: connected to master 'replication@1.1.1.17:3306',  replication started in log 'mysql-bin.000001' at position 10000


=== Testing Master/Master ===
You should now be able to restore your previously taken backup.


On 1.1.1.1, create a new database in MySQL:
# If you took a dump for restore before
  mysql> CREATE DATABASE foo;
  mysql < backup.sql


Verify the database to als be available on 9.9.9.9 afterwards:
=== Configure OX to use with a standalone database ===
mysql> SHOW DATABASES;
+--------------------+
| Database          |
+--------------------+
| information_schema |
| foo                |
| mysql              |
+--------------------+


Delete the new database on 9.9.9.9:
Not much special wisdom here. OX was designed to be used with master/slave databases, and a standalone master works just as well, if we register it as a master, and not registering a slave.
mysql> DROP DATABASE foo;


Check if the database has also been removed on 1.1.1.1
For the ConfigDB, <code>configdb.properties</code> allows configuration of a <code>writeUrl</code> (which is set to the correct values if you use <code>oxinstaller</code> with the correct argument <code>--configdb-writehost</code>).
mysql> SHOW DATABASES;
+--------------------+
| Database          |
+--------------------+
| information_schema |
| mysql              |
+--------------------+


=== Creating Open-Xchange user ===
The single database is then used for reading and writing.
 
For the individiual UserDBs, use <code>registerdatabase -m true</code>.
 
== Galera database setup ==
 
=== Preparations ===
 
Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database to Galera cluster, please be prepared to wipe the datadir, i.e. take a <code>mysqldump</code> for later restoration into the properly configured master.
 
Depeding on the flavor of the current database, this can be something like
 
# mariadb or oracle mysql without GTIDs
mysqldump --databases configdb oxdb_{5..14} > backup.sql
# mysql 5.6 with GTIDs... we dont want GTIDs here
mysqldump --databases --set-gtid-purged=OFF configdb oxdb_{5..14} > backup.sql
 
Be sure to verify the list of databases.
 
=== Installation ===
 
Please follow the upstream docs for your preferred flavor to get the software installed on your system.
 
* Percona XtraDB Cluster (5.6, 5.7): https://www.percona.com/doc/percona-xtradb-cluster/LATEST/install/index.html
* MariaDB Galera Cluster (10.0, 10.1): https://mariadb.com/kb/en/library/getting-started-with-mariadb-galera-cluster/ (Note: with 10.0, socat is required, but not a package dependency, so you need to explicitly install also socat)
 
Make sure to doublecheck the service is not running (or stop it) after installation as we need to perform some reconfigurations.
 
service mysql stop
 
=== Configuration ===
 
Galera-specific MySQL configuration advise is included in our main [[My.cnf|MySQL configuration article]]. Please consult that page for configuration information.
 
That page suggests a setup were we add three custom config files to <code>/etc/mysql/ox.conf.d/</code>: <code>ox.cnf</code> for general tuning/sizing, <code>wsrep.cnf</code> for clusterwide galera configuration, and <code>host.cnf</code> for host-specific settings.
 
Adjust the general settings and tunings in <code>ox.cnf</code> according to your sizing etc.
 
Adjust <code>wsrep.cnf</code> to reflect local paths, cluster member addresses, etc.
 
Adjust <code>host.cnf</code> to give node-local IPs, etc.
 
Version-specific hints:
 
# percona 5.6: unknown variable 'pxc_strict_mode=ENFORCING' ... unset that one
# mariadb 10.1: add wsrep_on=ON
# mariadb 10.0 and 10.1: set wsrep_node_incoming_address=192.168.1.22:3306 in host.cnf, otherwise the status wsrep_incoming_addresses might not be shown correctly(?!)
 
Some settings we recommend to change require that the database gets re-initialized. We assume you don't have data there (since we are covering a fresh install) or you have taken a backup for later restore as explained above in the Preparations section.
 
cd /var/lib/
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql
# mariadb 10.0 and 10.1
mysql_install_db
# mariadb 10.2
mysql_install_db --user=mysql
# percona 5.6
mysqld --user=mysql
# percona 5.7
mysqld --initialize-insecure --user=mysql
 
(Don't be worried about the <code>insecure</code>, it just means we set the db root pw in the next steps.)
 
=== Cluster startup ===
 
Typically on startup a Galera node tries to join a cluster, and if it fails, it will exit. Thus, when no cluster nodes are running, the first cluster node to be started needs to be told to not try to join a cluster, but rather bootstrap a new cluster. The exact arguments vary from version to version and from flavor to flavor.
 
==== First node ====
 
So we initialize the cluster bootstrap on the first node:
 
# percona 5.6, 5.7
service mysql bootstrap-pxc
# mariadb 10.0
service mysql bootstrap
# mariadb 10.1, 10.2
galera_new_cluster
 
Run <code>mysql_secure_installation</code> for a "secure by default" installation:
 
mysql_secure_installation
 
The further steps in this guide omit <code>-u -p</code> arguments to the MySQL client. Rather than passing them on the command line [https://dev.mysql.com/doc/refman/5.7/en/password-security-user.html] it is recommended to place the credentials in a file like <code>/root/.my.cnf</code> like
 
[client]
user=root
password=wip9Phae3Beijeed
 
We need a Galera replication user:
 
CREATE USER 'sstuser'@'localhost' IDENTIFIED BY 'OpIdjijwef0';
-- percona 5.6, mariadb 10.0
GRANT RELOAD, LOCK TABLES, REPLICATION CLIENT ON *.* TO 'sstuser'@'localhost';
-- percona 5.7, mariadb 10.1, 10.2
GRANT PROCESS, RELOAD, LOCK TABLES, REPLICATION CLIENT ON *.* TO 'sstuser'@'localhost';
FLUSH PRIVILEGES;
 
(Debian specific note: MariaDB provided startup scripts use the distro's mechanism of verifying startup/shutdown using a system user, so we create that as well:
 
# mariadb 10.0, 10.1, 10.2
GRANT ALL PRIVILEGES ON *.* TO "debian-sys-maint"@"localhost" IDENTIFIED BY "adBexthTsI5TaEps";
 
If you do this, yo need to synchronize the <code>/etc/mysql/debian.cnf</code> file from the first node to the other nodes as well.)
 
==== Other nodes ====
 
On the other nodes, we only need to restart the service now, to trigger a full state transfer from the first node to the other nodes.
 
We recommend to do this serially to let one state transfer complete before the second state transfer.
 
==== First node (continued) ====
 
Only applicable if you used <code>galera_new_cluster</code> before rather than the service script: In order to get the systemctl status consistent, restart the service on the first node:
 
# mariadb 10.1, 10.2: restart the service so that the systemctl status is consistent
mysqladmin shutdown
service mysql bootstrap
 
=== Verify the replication ===
 
The key tool to verify replication status is
 
mysql> show status like "%wsrep%";
 
This will give a lot of output. You want to verify in particular
 
+------------------------------+--------------------------------------+
| Variable_name                | Value                                |
+------------------------------+--------------------------------------+
| wsrep_cluster_size          | 3                                    |
| wsrep_cluster_status        | Primary                              |
| wsrep_local_state            | 4                                    |
| wsrep_local_state_comment    | Synced                              |
| wsrep_ready                  | ON                                  |
+------------------------------+--------------------------------------+
 
You can also explicitly verify replication by creating / inserting DBs, tables, rows on one node and select on other nodes.
 
==== Troubleshooting ====
 
The logs are helpful. Always.
 
Common mistakes are listed below.
 
If the Galera module does not get loaded at all:
* Configuration settings in ''my.cnf'' which are incompatible to Galera
* Wrong path of the shared object providing the Galera plugin in wsrep.cnf (wsrep_provider)
 
If the first node starts, but the second / third nodes can not be added to the cluster:
* User for the replication not created correctly on the first Galera node
* SST fails due to missing / wrong version prerequisite packages (not everything is hardcoded in package dependencies -- make sure you got percona-xtrabackup installed in the correct version, and also socat). If SST fails, do not only look into mysqls primary error logs, but also into logfiles from the SST tool in /var/lib/mysql on the donor node.
 
=== Notes about configuring OX for use with Galera ===
 
==== Write requests ====
 
Open-Xchange supports Galera as database backend only in the configuration where all writes are directed to one Galera node. For availability, it makes sense to not configure one Galera node's IP address directly, but rather employ some HA solution which offers active-passive functionality. Options therefore are discussed below.
 
==== Read requests ====
 
Read requests can be directed to any node in the Galera cluster. Our standard approach is to recommend to use a loadbalancer to implement round-robin over all nodes in a Galera cluster for the read requests. But you can also chose to use a dedicated read node (the same node, or a different node, than the write node). Each of the approaches has its own advantages.
 
* Load balancer based setup: Read requests get distributed round-robin between the Galera nodes. Theoretically by distributing the load of the read requests, you benefit from lower latencies and more throughput. But this has never been benchmarked yet. For a discussion of available loadbalances, see next section. OX-wise, in this configuration, you have two alternatives:
** The Galera option wsrep_causal_reads=1 option enables you to configure OX with its replication monitor disabled (com.openexchange.database.replicationMonitor=false in configdb.properties). This is the setup which seems to perform best according to our experience as turning off the replication monitor reduces the commits on the DB and thus the write operations per second on the underlying storage significantly, which outweights the drawback from having higher commit latency due to fully synchronous mode.
** Alternatively, you can run Galera with wsrep_causal_reads=0 when switching on OX builtin replication monitor. This is also a valid setup.
* Use a designated floating IP for the read requests: This eliminates the need of a load balancer. With this option you will not gain any performance, but the quantitative benefit is unclear anyhow.
* Use the floating IP for the writes also for the reads: In this scenario, you direct all database queries only to one Galera node, and the other two nodes are only getting queries in case of a failure of that node. In this case, you can even use wsrep_causal_reads=0 while still having OX builtin replication monitor switched off. However we do not expect this option to be superior to the round-robin loadbalancer approach.
 
=== Loadbalancer options ===
 
While the JDBC driver has some round-robin load balancing capabilities built-in, we don't recommend it for production use since it lacks possibilities to check the Galera nodes health states.
 
Loadbalancers used for OX -> Galera loadbalancing should be able to implement active-passive instances for the write requests, and active-active (round-robin) instances for the read requests. (If they cannot implement active-passive, you can still take a floating IP therefore.) Furthermore it is required to configure node health checks not only on the TCP level (by a simple connect), but to query the Galera health status periodically, evaluating Galera WSREP status variables. Otherwise split-brain scenarios or other bad states cannot be detected. For an example of such an health check, see our [[Clustercheck]] page.
 
Some customers use loadbalancing appliances. It is important to check that if the (virtual) infrastructure offers "loadbalancer" instances that they satisfy the given requirements. Often this is not the case. In particular, a simple "DNS round robin" approach is not viable.
 
==== LVS/ipvsadm/keepalived ====
 
If you want to create your own loadbalancers based on Linux, we usually recommend LVS (Linux Virtual Servers) controlled by Keepalived. LVS is a set of kernel modules implementing a L4 loadbalancer which performs quite well. Keepalived is a userspace daemon to control LVS rules, using health checks to reconfigure LVS rules if required. Keepalived / LVS requires one (or, for availability, two) dedicated linux nodes to run on. This can be a disadvantage for some installations, but usually, it pays off. We provide some configuration information on Keepalived [[Keepalived|here]].
 
==== MariaDB Maxscale ====
 
Since Maxscale has become GA in 2015, it seems to have undergone significant stability, performance and functional improvements. We are currently experimenting with Maxscale and share our installation / configuration knowledge [[Maxscale|here]]. It looks quite promising and might become ''the standard replacement'' for HAproxy, while we still presume Keepalived offers superior robustness and performance, coming with the cost of the requirement for one (or more) dedicated loadbalancer nodes.
 
==== HAproxy ====
 
In case where the Keepalived based approach is not feasible due to its requirements on the infrastructure, it is also possible to use a HAproxy based solution where HAproxy processes run on each of the OX nodes, configured for one round-robin and one active/passive instance. OX is then connecting to the local HAproxy instances. It is vital to configure HAproxy timeouts different from the defaults, otherwise HAproxy will kill active DB connections, causing errors. Be aware that in large installations the number of (distributed) HAproxy instances can get quite large. Some configuration hints for HAproxy are available [[HAproxy|here]].
 
== Master/Slave database setup ==
 
While we also support also "legacy" (pre-GTID) Master/Slave replication, we recommend to use GTID based replication, for easier setup and failure recovery. Support for GTID based replication has been added with OX 7.8.0.
 
GTID has been available since MySQL 5.6, so no 5.5 installation instructions below, sorry. We try to be generic in this documentation (thus, applicable to Oracle Community Edition and MariaDB) and point out differences where needed. Note: Instructions below include information about Oracle Community MySQL 5.7 which is not yet formally supported.
 
=== Preparations ===
 
Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database to GTID master-slave, please be prepared to wipe the datadir, i.e. take a <code>mysqldump</code> for later restoration into the properly configured master.
 
Depeding on the flavor of the current database, this can be something like
 
# mariadb or oracle mysql without GTIDs
mysqldump --databases configdb oxdb_{5..14} > backup.sql
# mysql 5.6 with GTIDs... we dont want GTIDs here
mysqldump --databases --set-gtid-purged=OFF configdb oxdb_{5..14} > backup.sql
 
Be sure to verify the list of databases.
 
=== Installation ===
 
Software installation is identical for master and slave.
 
Please follow the instructions for installing from The vendors.
 
* Oracle Community Edition: https://dev.mysql.com/doc/mysql-apt-repo-quick-guide/en/
* MariaDB (10.0, 10.1): https://downloads.mariadb.org/mariadb/repositories/
 
Stop the service (if it is running):
 
service mysql stop
 
=== Configuration ===
 
Configuration as per configuration files is also identical for master and slave.
 
Consult [[My.cnf]] for general recommendations how to configure databases for usage with OX.
 
For GTID based replication, make sure you add some configurables to a new <code>/etc/mysql/ox.conf.d/gtid.cnf</code> file (assuming you are following our proposed schema of adding a <code>!includedir /etc/mysql/ox.conf.d/</code>" directive to <code>/etc/mysql/my.cnf</code>):
 
# GTID
log-bin=mysql-bin
server-id=...
log_slave_updates = ON
 
Oracle Community Edition: we need to add also
 
enforce_gtid_consistency = ON
gtid_mode = ON
 
(GTID mode is on by default on MariaDB.)
 
Use unique a <code>server-id</code> for each server; like <code>1</code> for the master, <code>2</code> for slave. For more complicated setups (like multiple slaves), adjust accordingly.
 
Since applying our configuration / sizing requires reinitialization of the MySQL datadir, we wipe/recreate it. Caution: this assumes we are running an empty database. If there is data in the database you want to keep, use mysqldump. See Preparation section above.
 
So, to initialize the datadir:
 
cd /var/lib/
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql
 
(When coming from an existing installation, be sure to wipe also old binlogs. They can confuse the server on startup. Their location varies by configuration.)
 
The step to initialize the datadir is different for the different DBs:
 
# MariaDB 10.0, 10.1
mysql_install_db
# MariaDB 10.2
mysql_install_db --user=mysql
# Oracle 5.6
mysql_install_db -u mysql
# Oracle 5.7
mysqld --initialize-insecure --user=mysql
 
(Don't be worried about the <code>insecure</code>, it just means we set the db root pw in the next steps.)
 
Then:
 
service mysql restart
mysql_secure_installation
 
We want to emphasize the last step to run "secure".
 
Steps up to here apply to both the designated master and slave. The next steps will apply to the master.
 
=== Replication Setup ===
 
==== Master Setup ====
 
Create a replication user on the master (but, as always, pick your own password, and use the same password in the slave setup below):
 
mysql -e "CREATE USER 'repl'@'gtid-slave.localdomain' IDENTIFIED BY 'IvIjyoffod2'; GRANT REPLICATION SLAVE ON *.* TO 'repl'@'gtid-slave.localdomain';"
 
Now would also be the time to restore a previously created mysqldump, or add other users you need for adminstration, monitoring etc (like <code>debian-sys-maint@localhost</code>, for example). Adding the OX users is explained below ("Creating Open-Xchange user").
 
# If you took a dump for restore before
mysql < backup.sql
 
To prepare for the initial sync of the slave, set the master read-only:
 
mysql -e "SET @@global.read_only = ON;"
 
Create a dump to initialize the slave:
 
# MariaDB
mysqldump --all-databases --triggers --routines --events --master-data --gtid > master.sql
# Oracle
mysqldump --all-databases --triggers --routines --events --set-gtid-purged=ON > master.sql
 
Transfer to the slave:
 
scp master.sql gtid-slave:
 
==== Slave Setup ====
 
Configure the replication master settings. Note we don't need complicated binlog position settings etc with GTID.
 
Yet again DB-specific (use the repl user password from above):
 
# MariaDB
mysql -e 'CHANGE MASTER TO MASTER_HOST="gtid-master.localdomain", MASTER_USER="repl", MASTER_PASSWORD="IvIjyoffod2";'
# Oracle
mysql -e "CHANGE MASTER TO MASTER_HOST='gtid-master.localdomain', MASTER_USER='repl', MASTER_PASSWORD='IvIjyoffod2', MASTER_AUTO_POSITION=1;"
# https://www.percona.com/blog/2013/02/08/how-to-createrestore-a-slave-using-gtid-replication-in-mysql-5-6/
mysql -e "RESET MASTER;"
 
Read the master dump:
 
mysql < master.sql
 
Start replication on the slave:
 
mysql -e 'START SLAVE;'
mysql -e 'SHOW SLAVE STATUS\G'
 
==== Master Setup (continued) ====
 
Finally, unset read-only on the master:
 
# on the master
mysql -e "SET @@global.read_only = OFF;"
 
=== Configure OX to use with Master/Slave replication ===
 
Not much special wisdom here. OX was designed to be used with master/slave databases. For the ConfigDB, <code>configdb.properties</code> allows configuration of a <code>readUrl</code> and <code>writeUrl</code> (both of which are set to the correct values if you use <code>oxinstaller</code> with the correct arguments <code>--configdb-readhost</code>, <code>--configdb-writehost</code>).
 
(Obviously, the master is for writing and the slave is for reading.)
 
For the individiual UserDBs, use <code>registerdatabase -m true</code> for the masters and <code>registerdatabase -m false -M ...</code> for the respective slaves.
 
Be sure to have enabled the replication monitor in <code>configdb.properties</code>: <code>com.openexchange.database.replicationMonitor=true</code> (which it is by default); while GTID can show synchronous semantics, it is specified to silently fall back to asynchronous in certain circumstances, so synchronity is not guaranteed.
 
We recommend, though, to not register the databases directly by their native hostname or IP, but rather use some kind of HA system in order to be able to easily move a floating/failover IP from the master to the slave in case of master failure. Configuring and running such systems (like, corosync/pacemaker, keepalived, or whatever) is out of scope of this documentation, however.
 
== Creating Open-Xchange user ==


Now setup access for the Open-Xchange Server database user 'openexchange' to configdb and the oxdb for both groupware server addresses. These databases do not exist yet, but will be created during the Open-Xchange Server installation.
Now setup access for the Open-Xchange Server database user 'openexchange' to configdb and the oxdb for both groupware server addresses. These databases do not exist yet, but will be created during the Open-Xchange Server installation.


In this example the IPs belong to the two different Open-Xchange Server IPs, please adjust them accordingly.
Notes:
  mysql> GRANT ALL PRIVILEGES ON *.* TO 'openexchange'@'10.20.30.213' IDENTIFIED BY 'secret';
 
  mysql> GRANT ALL PRIVILEGES ON *.* TO 'openexchange'@'10.20.30.215' IDENTIFIED BY 'secret';
* Please use a real password.
* The IPs in this example belong to the two different Open-Xchange Servers, please adjust them accordingly.
* If using a database on the same host as the middlware (usually done for POCs and demo installations), you need to grant also to the ''localhost'' host.
* Consult [[AppSuite:DB_user_privileges]] (or ''grep GRANT /opt/open-xchange/sbin/initconfigdb'') for an up-to-date list of required privileges. The following statement was correct as of the time of writing this section.
 
  mysql> GRANT CREATE, LOCK TABLES, REFERENCES, INDEX, DROP, DELETE, ALTER, SELECT, UPDATE, INSERT, CREATE TEMPORARY TABLES, SHOW VIEW, SHOW DATABASES ON *.* TO 'openexchange'@'10.20.30.213' IDENTIFIED BY 'IntyoyntOat1' WITH GRANT OPTION;
  mysql> GRANT CREATE, LOCK TABLES, REFERENCES, INDEX, DROP, DELETE, ALTER, SELECT, UPDATE, INSERT, CREATE TEMPORARY TABLES, SHOW VIEW, SHOW DATABASES ON *.* TO 'openexchange'@'10.20.30.215' IDENTIFIED BY 'IntyoyntOat1' WITH GRANT OPTION;

Latest revision as of 09:03, 16 September 2021

Overview

You can choose between Galera or Master/Slave replication. We like to recommend to use Galera for higher redudancy, easier operations, und synchronous semantics (so you can run OX without our "replication monitor"). For POC or demo setups, a single standalone database setup might be sufficient.

Standalone database setup

Preparations

Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database server, please be prepared to wipe the datadir, i.e. take a mysqldump for later restoration into the properly configured master.

mysqldump --databases configdb oxdb_{5..14} > backup.sql

Be sure to verify the list of databases.

Installation

Note: the following list is not an exclusive list or authorative statement about supported MySQL flavors / versions. Please consult the official support / system requirements statement.

Please follow the upstream docs for your preferred flavor to get the software installed on your system.

Make sure to doublecheck the service is not running (or stop it) after installation as we need to perform some reconfigurations.

service mysql stop

Configuration

MySQL configuration advise is given in our MySQL configuration article. Please consult that page for configuration information and create configuration files as described there.

Some settings we recommend to change require that the database gets re-initialized. We assume you don't have data there (since we are covering a fresh install) or you have taken a backup for later restore as explained above in the Preparations section.

cd /var/lib/
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql

# mariadb
mysql_install_db
# mariadb 10.2
mysql_install_db --user=mysql
# oracle 5.6
mysql_install_db -u mysql
# oracle 5.7
mysqld --initialize-insecure --user=mysql

(Don't be worried about the insecure, it just means we set the db root pw in the next steps.)

Start the service. The actual command depends on your OS and on the MySQL flavor.

service mysql start

Run mysql_secure_installation for a "secure by default" installation:

mariadb-secure-installation

That tool will ask for the current root password (which is empty by default) and subsequently questions like:

Change the root password? [Y/n]
Remove anonymous users? [Y/n]
Disallow root login remotely? [Y/n]
Remove test database and access to it? [Y/n]
Reload privilege tables now? [Y/n]

You should answer all these questions with "yes".

Configure a strong password for the MySQL root user.

The further steps in this guide omit -u -p arguments to the MySQL client. Rather than passing them on the command line [1] it is recommended to place the credentials in a file like /root/.my.cnf like

[client]
user=root
password=wip9Phae3Beijeed

Make sure the service is enabled by the OS's init system. The actual command depends on your OS and on the MySQL flavor.

systemctl enable mysql.service

You should now be able to restore your previously taken backup.

# If you took a dump for restore before
mysql < backup.sql

Configure OX to use with a standalone database

Not much special wisdom here. OX was designed to be used with master/slave databases, and a standalone master works just as well, if we register it as a master, and not registering a slave.

For the ConfigDB, configdb.properties allows configuration of a writeUrl (which is set to the correct values if you use oxinstaller with the correct argument --configdb-writehost).

The single database is then used for reading and writing.

For the individiual UserDBs, use registerdatabase -m true.

Galera database setup

Preparations

Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database to Galera cluster, please be prepared to wipe the datadir, i.e. take a mysqldump for later restoration into the properly configured master.

Depeding on the flavor of the current database, this can be something like

# mariadb or oracle mysql without GTIDs
mysqldump --databases configdb oxdb_{5..14} > backup.sql

# mysql 5.6 with GTIDs... we dont want GTIDs here
mysqldump --databases --set-gtid-purged=OFF configdb oxdb_{5..14} > backup.sql

Be sure to verify the list of databases.

Installation

Please follow the upstream docs for your preferred flavor to get the software installed on your system.

Make sure to doublecheck the service is not running (or stop it) after installation as we need to perform some reconfigurations.

service mysql stop

Configuration

Galera-specific MySQL configuration advise is included in our main MySQL configuration article. Please consult that page for configuration information.

That page suggests a setup were we add three custom config files to /etc/mysql/ox.conf.d/: ox.cnf for general tuning/sizing, wsrep.cnf for clusterwide galera configuration, and host.cnf for host-specific settings.

Adjust the general settings and tunings in ox.cnf according to your sizing etc.

Adjust wsrep.cnf to reflect local paths, cluster member addresses, etc.

Adjust host.cnf to give node-local IPs, etc.

Version-specific hints:

# percona 5.6: unknown variable 'pxc_strict_mode=ENFORCING' ... unset that one
# mariadb 10.1: add wsrep_on=ON
# mariadb 10.0 and 10.1: set wsrep_node_incoming_address=192.168.1.22:3306 in host.cnf, otherwise the status wsrep_incoming_addresses might not be shown correctly(?!)

Some settings we recommend to change require that the database gets re-initialized. We assume you don't have data there (since we are covering a fresh install) or you have taken a backup for later restore as explained above in the Preparations section.

cd /var/lib/
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql

# mariadb 10.0 and 10.1
mysql_install_db
# mariadb 10.2
mysql_install_db --user=mysql
# percona 5.6
mysqld --user=mysql
# percona 5.7
mysqld --initialize-insecure --user=mysql

(Don't be worried about the insecure, it just means we set the db root pw in the next steps.)

Cluster startup

Typically on startup a Galera node tries to join a cluster, and if it fails, it will exit. Thus, when no cluster nodes are running, the first cluster node to be started needs to be told to not try to join a cluster, but rather bootstrap a new cluster. The exact arguments vary from version to version and from flavor to flavor.

First node

So we initialize the cluster bootstrap on the first node:

# percona 5.6, 5.7
service mysql bootstrap-pxc
# mariadb 10.0
service mysql bootstrap
# mariadb 10.1, 10.2
galera_new_cluster

Run mysql_secure_installation for a "secure by default" installation:

mysql_secure_installation

The further steps in this guide omit -u -p arguments to the MySQL client. Rather than passing them on the command line [2] it is recommended to place the credentials in a file like /root/.my.cnf like

[client]
user=root
password=wip9Phae3Beijeed

We need a Galera replication user:

CREATE USER 'sstuser'@'localhost' IDENTIFIED BY 'OpIdjijwef0';
-- percona 5.6, mariadb 10.0
GRANT RELOAD, LOCK TABLES, REPLICATION CLIENT ON *.* TO 'sstuser'@'localhost';
-- percona 5.7, mariadb 10.1, 10.2
GRANT PROCESS, RELOAD, LOCK TABLES, REPLICATION CLIENT ON *.* TO 'sstuser'@'localhost';
FLUSH PRIVILEGES;

(Debian specific note: MariaDB provided startup scripts use the distro's mechanism of verifying startup/shutdown using a system user, so we create that as well:

# mariadb 10.0, 10.1, 10.2
GRANT ALL PRIVILEGES ON *.* TO "debian-sys-maint"@"localhost" IDENTIFIED BY "adBexthTsI5TaEps";

If you do this, yo need to synchronize the /etc/mysql/debian.cnf file from the first node to the other nodes as well.)

Other nodes

On the other nodes, we only need to restart the service now, to trigger a full state transfer from the first node to the other nodes.

We recommend to do this serially to let one state transfer complete before the second state transfer.

First node (continued)

Only applicable if you used galera_new_cluster before rather than the service script: In order to get the systemctl status consistent, restart the service on the first node:

# mariadb 10.1, 10.2: restart the service so that the systemctl status is consistent
mysqladmin shutdown
service mysql bootstrap

Verify the replication

The key tool to verify replication status is

mysql> show status like "%wsrep%";

This will give a lot of output. You want to verify in particular

+------------------------------+--------------------------------------+
| Variable_name                | Value                                |
+------------------------------+--------------------------------------+
| wsrep_cluster_size           | 3                                    |
| wsrep_cluster_status         | Primary                              |
| wsrep_local_state            | 4                                    |
| wsrep_local_state_comment    | Synced                               |
| wsrep_ready                  | ON                                   |
+------------------------------+--------------------------------------+

You can also explicitly verify replication by creating / inserting DBs, tables, rows on one node and select on other nodes.

Troubleshooting

The logs are helpful. Always.

Common mistakes are listed below.

If the Galera module does not get loaded at all:

  • Configuration settings in my.cnf which are incompatible to Galera
  • Wrong path of the shared object providing the Galera plugin in wsrep.cnf (wsrep_provider)

If the first node starts, but the second / third nodes can not be added to the cluster:

  • User for the replication not created correctly on the first Galera node
  • SST fails due to missing / wrong version prerequisite packages (not everything is hardcoded in package dependencies -- make sure you got percona-xtrabackup installed in the correct version, and also socat). If SST fails, do not only look into mysqls primary error logs, but also into logfiles from the SST tool in /var/lib/mysql on the donor node.

Notes about configuring OX for use with Galera

Write requests

Open-Xchange supports Galera as database backend only in the configuration where all writes are directed to one Galera node. For availability, it makes sense to not configure one Galera node's IP address directly, but rather employ some HA solution which offers active-passive functionality. Options therefore are discussed below.

Read requests

Read requests can be directed to any node in the Galera cluster. Our standard approach is to recommend to use a loadbalancer to implement round-robin over all nodes in a Galera cluster for the read requests. But you can also chose to use a dedicated read node (the same node, or a different node, than the write node). Each of the approaches has its own advantages.

  • Load balancer based setup: Read requests get distributed round-robin between the Galera nodes. Theoretically by distributing the load of the read requests, you benefit from lower latencies and more throughput. But this has never been benchmarked yet. For a discussion of available loadbalances, see next section. OX-wise, in this configuration, you have two alternatives:
    • The Galera option wsrep_causal_reads=1 option enables you to configure OX with its replication monitor disabled (com.openexchange.database.replicationMonitor=false in configdb.properties). This is the setup which seems to perform best according to our experience as turning off the replication monitor reduces the commits on the DB and thus the write operations per second on the underlying storage significantly, which outweights the drawback from having higher commit latency due to fully synchronous mode.
    • Alternatively, you can run Galera with wsrep_causal_reads=0 when switching on OX builtin replication monitor. This is also a valid setup.
  • Use a designated floating IP for the read requests: This eliminates the need of a load balancer. With this option you will not gain any performance, but the quantitative benefit is unclear anyhow.
  • Use the floating IP for the writes also for the reads: In this scenario, you direct all database queries only to one Galera node, and the other two nodes are only getting queries in case of a failure of that node. In this case, you can even use wsrep_causal_reads=0 while still having OX builtin replication monitor switched off. However we do not expect this option to be superior to the round-robin loadbalancer approach.

Loadbalancer options

While the JDBC driver has some round-robin load balancing capabilities built-in, we don't recommend it for production use since it lacks possibilities to check the Galera nodes health states.

Loadbalancers used for OX -> Galera loadbalancing should be able to implement active-passive instances for the write requests, and active-active (round-robin) instances for the read requests. (If they cannot implement active-passive, you can still take a floating IP therefore.) Furthermore it is required to configure node health checks not only on the TCP level (by a simple connect), but to query the Galera health status periodically, evaluating Galera WSREP status variables. Otherwise split-brain scenarios or other bad states cannot be detected. For an example of such an health check, see our Clustercheck page.

Some customers use loadbalancing appliances. It is important to check that if the (virtual) infrastructure offers "loadbalancer" instances that they satisfy the given requirements. Often this is not the case. In particular, a simple "DNS round robin" approach is not viable.

LVS/ipvsadm/keepalived

If you want to create your own loadbalancers based on Linux, we usually recommend LVS (Linux Virtual Servers) controlled by Keepalived. LVS is a set of kernel modules implementing a L4 loadbalancer which performs quite well. Keepalived is a userspace daemon to control LVS rules, using health checks to reconfigure LVS rules if required. Keepalived / LVS requires one (or, for availability, two) dedicated linux nodes to run on. This can be a disadvantage for some installations, but usually, it pays off. We provide some configuration information on Keepalived here.

MariaDB Maxscale

Since Maxscale has become GA in 2015, it seems to have undergone significant stability, performance and functional improvements. We are currently experimenting with Maxscale and share our installation / configuration knowledge here. It looks quite promising and might become the standard replacement for HAproxy, while we still presume Keepalived offers superior robustness and performance, coming with the cost of the requirement for one (or more) dedicated loadbalancer nodes.

HAproxy

In case where the Keepalived based approach is not feasible due to its requirements on the infrastructure, it is also possible to use a HAproxy based solution where HAproxy processes run on each of the OX nodes, configured for one round-robin and one active/passive instance. OX is then connecting to the local HAproxy instances. It is vital to configure HAproxy timeouts different from the defaults, otherwise HAproxy will kill active DB connections, causing errors. Be aware that in large installations the number of (distributed) HAproxy instances can get quite large. Some configuration hints for HAproxy are available here.

Master/Slave database setup

While we also support also "legacy" (pre-GTID) Master/Slave replication, we recommend to use GTID based replication, for easier setup and failure recovery. Support for GTID based replication has been added with OX 7.8.0.

GTID has been available since MySQL 5.6, so no 5.5 installation instructions below, sorry. We try to be generic in this documentation (thus, applicable to Oracle Community Edition and MariaDB) and point out differences where needed. Note: Instructions below include information about Oracle Community MySQL 5.7 which is not yet formally supported.

Preparations

Our configuration process includes wiping and reinitializing the datadir. This is usually not a problem in a fresh installation. If you want to upgrade an existing database to GTID master-slave, please be prepared to wipe the datadir, i.e. take a mysqldump for later restoration into the properly configured master.

Depeding on the flavor of the current database, this can be something like

# mariadb or oracle mysql without GTIDs
mysqldump --databases configdb oxdb_{5..14} > backup.sql

# mysql 5.6 with GTIDs... we dont want GTIDs here
mysqldump --databases --set-gtid-purged=OFF configdb oxdb_{5..14} > backup.sql

Be sure to verify the list of databases.

Installation

Software installation is identical for master and slave.

Please follow the instructions for installing from The vendors.

Stop the service (if it is running):

service mysql stop

Configuration

Configuration as per configuration files is also identical for master and slave.

Consult My.cnf for general recommendations how to configure databases for usage with OX.

For GTID based replication, make sure you add some configurables to a new /etc/mysql/ox.conf.d/gtid.cnf file (assuming you are following our proposed schema of adding a !includedir /etc/mysql/ox.conf.d/" directive to /etc/mysql/my.cnf):

# GTID
log-bin=mysql-bin
server-id=...
log_slave_updates = ON

Oracle Community Edition: we need to add also

enforce_gtid_consistency = ON
gtid_mode = ON

(GTID mode is on by default on MariaDB.)

Use unique a server-id for each server; like 1 for the master, 2 for slave. For more complicated setups (like multiple slaves), adjust accordingly.

Since applying our configuration / sizing requires reinitialization of the MySQL datadir, we wipe/recreate it. Caution: this assumes we are running an empty database. If there is data in the database you want to keep, use mysqldump. See Preparation section above.

So, to initialize the datadir:

cd /var/lib/
mv mysql mysql.old.datadir
mkdir mysql
chown mysql.mysql mysql

(When coming from an existing installation, be sure to wipe also old binlogs. They can confuse the server on startup. Their location varies by configuration.)

The step to initialize the datadir is different for the different DBs:

# MariaDB 10.0, 10.1
mysql_install_db

# MariaDB 10.2
mysql_install_db --user=mysql

# Oracle 5.6
mysql_install_db -u mysql

# Oracle 5.7
mysqld --initialize-insecure --user=mysql

(Don't be worried about the insecure, it just means we set the db root pw in the next steps.)

Then:

service mysql restart
mysql_secure_installation

We want to emphasize the last step to run "secure".

Steps up to here apply to both the designated master and slave. The next steps will apply to the master.

Replication Setup

Master Setup

Create a replication user on the master (but, as always, pick your own password, and use the same password in the slave setup below):

mysql -e "CREATE USER 'repl'@'gtid-slave.localdomain' IDENTIFIED BY 'IvIjyoffod2'; GRANT REPLICATION SLAVE ON *.* TO 'repl'@'gtid-slave.localdomain';"

Now would also be the time to restore a previously created mysqldump, or add other users you need for adminstration, monitoring etc (like debian-sys-maint@localhost, for example). Adding the OX users is explained below ("Creating Open-Xchange user").

# If you took a dump for restore before
mysql < backup.sql

To prepare for the initial sync of the slave, set the master read-only:

mysql -e "SET @@global.read_only = ON;"

Create a dump to initialize the slave:

# MariaDB
mysqldump --all-databases --triggers --routines --events --master-data --gtid > master.sql

# Oracle
mysqldump --all-databases --triggers --routines --events --set-gtid-purged=ON > master.sql

Transfer to the slave:

scp master.sql gtid-slave:

Slave Setup

Configure the replication master settings. Note we don't need complicated binlog position settings etc with GTID.

Yet again DB-specific (use the repl user password from above):

# MariaDB
mysql -e 'CHANGE MASTER TO MASTER_HOST="gtid-master.localdomain", MASTER_USER="repl", MASTER_PASSWORD="IvIjyoffod2";'

# Oracle
mysql -e "CHANGE MASTER TO MASTER_HOST='gtid-master.localdomain', MASTER_USER='repl', MASTER_PASSWORD='IvIjyoffod2', MASTER_AUTO_POSITION=1;"
# https://www.percona.com/blog/2013/02/08/how-to-createrestore-a-slave-using-gtid-replication-in-mysql-5-6/
mysql -e "RESET MASTER;"

Read the master dump:

mysql < master.sql

Start replication on the slave:

mysql -e 'START SLAVE;'
mysql -e 'SHOW SLAVE STATUS\G'

Master Setup (continued)

Finally, unset read-only on the master:

# on the master
mysql -e "SET @@global.read_only = OFF;"

Configure OX to use with Master/Slave replication

Not much special wisdom here. OX was designed to be used with master/slave databases. For the ConfigDB, configdb.properties allows configuration of a readUrl and writeUrl (both of which are set to the correct values if you use oxinstaller with the correct arguments --configdb-readhost, --configdb-writehost).

(Obviously, the master is for writing and the slave is for reading.)

For the individiual UserDBs, use registerdatabase -m true for the masters and registerdatabase -m false -M ... for the respective slaves.

Be sure to have enabled the replication monitor in configdb.properties: com.openexchange.database.replicationMonitor=true (which it is by default); while GTID can show synchronous semantics, it is specified to silently fall back to asynchronous in certain circumstances, so synchronity is not guaranteed.

We recommend, though, to not register the databases directly by their native hostname or IP, but rather use some kind of HA system in order to be able to easily move a floating/failover IP from the master to the slave in case of master failure. Configuring and running such systems (like, corosync/pacemaker, keepalived, or whatever) is out of scope of this documentation, however.

Creating Open-Xchange user

Now setup access for the Open-Xchange Server database user 'openexchange' to configdb and the oxdb for both groupware server addresses. These databases do not exist yet, but will be created during the Open-Xchange Server installation.

Notes:

  • Please use a real password.
  • The IPs in this example belong to the two different Open-Xchange Servers, please adjust them accordingly.
  • If using a database on the same host as the middlware (usually done for POCs and demo installations), you need to grant also to the localhost host.
  • Consult AppSuite:DB_user_privileges (or grep GRANT /opt/open-xchange/sbin/initconfigdb) for an up-to-date list of required privileges. The following statement was correct as of the time of writing this section.
mysql> GRANT CREATE, LOCK TABLES, REFERENCES, INDEX, DROP, DELETE, ALTER, SELECT, UPDATE, INSERT, CREATE TEMPORARY TABLES, SHOW VIEW, SHOW DATABASES ON *.* TO 'openexchange'@'10.20.30.213' IDENTIFIED BY 'IntyoyntOat1'  WITH GRANT OPTION;
mysql> GRANT CREATE, LOCK TABLES, REFERENCES, INDEX, DROP, DELETE, ALTER, SELECT, UPDATE, INSERT, CREATE TEMPORARY TABLES, SHOW VIEW, SHOW DATABASES ON *.* TO 'openexchange'@'10.20.30.215' IDENTIFIED BY 'IntyoyntOat1'  WITH GRANT OPTION;