Before you can do anything, you must initialize a database storage area on disk. We call this a database cluster. (The SQL standard uses the term catalog cluster.) A database cluster is a collection of databases that is managed by a single instance of a running database server. After initialization, a database cluster will contain a database named
postgres, which is meant as a default database for use by utilities, users and third party applications. The database server itself does not require the
postgres database to exist, but many external utility programs assume it exists. Another database created within each cluster during initialization is called
template1. As the name suggests, this will be used as a template for subsequently created databases; it should not be used for actual work. (See Chapter 23 for information about creating new databases within a cluster.)
In file system terms, a database cluster is a single directory under which all data will be stored. We call this the data directory or data area. It is completely up to you where you choose to store your data. There is no default, although locations such as
/var/lib/pgsql/data are popular. The data directory must be initialized before being used, using the program initdb which is installed with PostgreSQL.
If you are using a pre-packaged version of PostgreSQL, it may well have a specific convention for where to place the data directory, and it may also provide a script for creating the data directory. In that case you should use that script in preference to running
initdb directly. Consult the package-level documentation for details.
To initialize a database cluster manually, run
initdb and specify the desired file system location of the database cluster with the
-D option, for example:
initdb -D /usr/local/pgsql/data
Note that you must execute this command while logged into the PostgreSQL user account, which is described in the previous section.
Alternatively, you can run
initdb via the pg_ctl program like so:
pg_ctl -D /usr/local/pgsql/data initdb
This may be more intuitive if you are using
pg_ctl for starting and stopping the server (see Section 19.3), so that
pg_ctl would be the sole command you use for managing the database server instance.
initdb will attempt to create the directory you specify if it does not already exist. Of course, this will fail if
initdb does not have permissions to write in the parent directory. It's generally recommendable that the PostgreSQL user own not just the data directory but its parent directory as well, so that this should not be a problem. If the desired parent directory doesn't exist either, you will need to create it first, using root privileges if the grandparent directory isn't writable. So the process might look like this:
chown postgres /usr/local/pgsqlroot#
initdb -D /usr/local/pgsql/data
initdb will refuse to run if the data directory exists and already contains files; this is to prevent accidentally overwriting an existing installation.
Because the data directory contains all the data stored in the database, it is essential that it be secured from unauthorized access.
initdb therefore revokes access permissions from everyone but the PostgreSQL user, and optionally, group. Group access, when enabled, is read-only. This allows an unprivileged user in the same group as the cluster owner to take a backup of the cluster data or perform other operations that only require read access.
Note that enabling or disabling group access on an existing cluster requires the cluster to be shut down and the appropriate mode to be set on all directories and files before restarting PostgreSQL. Otherwise, a mix of modes might exist in the data directory. For clusters that allow access only by the owner, the appropriate modes are
0700 for directories and
0600 for files. For clusters that also allow reads by the group, the appropriate modes are
0750 for directories and
0640 for files.
However, while the directory contents are secure, the default client authentication setup allows any local user to connect to the database and even become the database superuser. If you do not trust other local users, we recommend you use one of
--pwfile options to assign a password to the database superuser. Also, specify
-A scram-sha-256 so that the default
trust authentication mode is not used; or modify the generated
pg_hba.conf file after running
initdb, but before you start the server for the first time. (Other reasonable approaches include using
peer authentication or file system permissions to restrict connections. See Chapter 21 for more information.)
initdb also initializes the default locale for the database cluster. Normally, it will just take the locale settings in the environment and apply them to the initialized database. It is possible to specify a different locale for the database; more information about that can be found in Section 24.1. The default sort order used within the particular database cluster is set by
initdb, and while you can create new databases using different sort order, the order used in the template databases that initdb creates cannot be changed without dropping and recreating them. There is also a performance impact for using locales other than
POSIX. Therefore, it is important to make this choice correctly the first time.
initdb also sets the default character set encoding for the database cluster. Normally this should be chosen to match the locale setting. For details see Section 24.3.
C and non-
POSIX locales rely on the operating system's collation library for character set ordering. This controls the ordering of keys stored in indexes. For this reason, a cluster cannot switch to an incompatible collation library version, either through snapshot restore, binary streaming replication, a different operating system, or an operating system upgrade.
Many installations create their database clusters on file systems (volumes) other than the machine's “root” volume. If you choose to do this, it is not advisable to try to use the secondary volume's topmost directory (mount point) as the data directory. Best practice is to create a directory within the mount-point directory that is owned by the PostgreSQL user, and then create the data directory within that. This avoids permissions problems, particularly for operations such as pg_upgrade, and it also ensures clean failures if the secondary volume is taken offline.
Generally, any file system with POSIX semantics can be used for PostgreSQL. Users prefer different file systems for a variety of reasons, including vendor support, performance, and familiarity. Experience suggests that, all other things being equal, one should not expect major performance or behavior changes merely from switching file systems or making minor file system configuration changes.
It is possible to use an NFS file system for storing the PostgreSQL data directory. PostgreSQL does nothing special for NFS file systems, meaning it assumes NFS behaves exactly like locally-connected drives. PostgreSQL does not use any functionality that is known to have nonstandard behavior on NFS, such as file locking.
The only firm requirement for using NFS with PostgreSQL is that the file system is mounted using the
hard option. With the
hard option, processes can “hang” indefinitely if there are network problems, so this configuration will require a careful monitoring setup. The
soft option will interrupt system calls in case of network problems, but PostgreSQL will not repeat system calls interrupted in this way, so any such interruption will result in an I/O error being reported.
It is not necessary to use the
sync mount option. The behavior of the
async option is sufficient, since PostgreSQL issues
fsync calls at appropriate times to flush the write caches. (This is analogous to how it works on a local file system.) However, it is strongly recommended to use the
sync export option on the NFS server on systems where it exists (mainly Linux). Otherwise, an
fsync or equivalent on the NFS client is not actually guaranteed to reach permanent storage on the server, which could cause corruption similar to running with the parameter fsync off. The defaults of these mount and export options differ between vendors and versions, so it is recommended to check and perhaps specify them explicitly in any case to avoid any ambiguity.
In some cases, an external storage product can be accessed either via NFS or a lower-level protocol such as iSCSI. In the latter case, the storage appears as a block device and any available file system can be created on it. That approach might relieve the DBA from having to deal with some of the idiosyncrasies of NFS, but of course the complexity of managing remote storage then happens at other levels.
If you see anything in the documentation that is not correct, does not match your experience with the particular feature or requires further clarification, please use this form to report a documentation issue.