User Guide - Debian & Ubuntu / PostgreSQL 9.4
Introduction
This user guide is intended to be followed sequentially from beginning to end — each section depends on the last. For example, the
Backup
section relies on setup that is performed in the
Quick Start
section. Once
pgBackRest
is up and running then skipping around is possible but following the user guide in order is recommended the first time through.
Although the examples are targeted at Debian/Ubuntu and
PostgreSQL
9.4, it should be fairly easy to apply this guide to any Unix distribution and
PostgreSQL
version. Note that only 64-bit distributions are currently supported due to 64-bit operations in the Perl code. The only OS-specific commands are those to create, start, stop, and drop
PostgreSQL
clusters. The
pgBackRest
commands will be the same on any Unix system though the locations to install Perl libraries and executables may vary.
Configuration information and documentation for PostgreSQL can be found in the PostgreSQL Manual .
Configuration information and documentation for PostgreSQL can be found in the PostgreSQL Manual .
A somewhat novel approach is taken to documentation in this user guide. Each command is run on a virtual machine when the documentation is built from the XML source. This means you can have a high confidence that the commands work correctly in the order presented. Output is captured and displayed below the command when appropriate. If the output is not included it is because it was deemed not relevant or was considered a distraction from the narrative.
All commands are intended to be run as an unprivileged user that has sudo privileges for both the
root
and
postgres
users. It's also possible to run the commands directly as their respective users without modification and in that case the
sudo
commands can be stripped off.
Concepts
The following concepts are defined as they are relevant to
pgBackRest
,
PostgreSQL
, and this user guide.
Backup
A backup is a consistent copy of a database cluster that can be restored to recover from a hardware failure, to perform Point-In-Time Recovery, or to bring up a new standby.
Full Backup
:
pgBackRest
copies the entire contents of the database cluster to the backup. The first backup of the database cluster is always a Full Backup.
pgBackRest
is always able to restore a full backup directly. The full backup does not depend on any files outside of the full backup for consistency.
Differential Backup
:
pgBackRest
copies only those database cluster files that have changed since the last full backup.
pgBackRest
restores a differential backup by copying all of the files in the chosen differential backup and the appropriate unchanged files from the previous full backup. The advantage of a differential backup is that it requires less disk space than a full backup, however, the differential backup and the full backup must both be valid to restore the differential backup.
Incremental Backup
:
pgBackRest
copies only those database cluster files that have changed since the last backup (which can be another incremental backup, a differential backup, or a full backup). As an incremental backup only includes those files changed since the prior backup, they are generally much smaller than full or differential backups. As with the differential backup, the incremental backup depends on other backups to be valid to restore the incremental backup. Since the incremental backup includes only those files since the last backup, all prior incremental backups back to the prior differential, the prior differential backup, and the prior full backup must all be valid to perform a restore of the incremental backup. If no differential backup exists then all prior incremental backups back to the prior full backup, which must exist, and the full backup itself must be valid to restore the incremental backup.
Restore
A restore is the act of copying a backup to a system where it will be started as a live database cluster. A restore requires the backup files and one or more WAL segments in order to work correctly.
Write Ahead Log (WAL)
WAL is the mechanism that
PostgreSQL
uses to ensure that no committed changes are lost. Transactions are written sequentially to the WAL and a transaction is considered to be committed when those writes are flushed to disk. Afterwards, a background process writes the changes into the main database cluster files (also known as the heap). In the event of a crash, the WAL is replayed to make the database consistent.
WAL is conceptually infinite but in practice is broken up into individual 16MB files called segments. WAL segments follow the naming convention
0000000100000A1E000000FE
where the first 8 hexadecimal digits represent the timeline and the next 16 digits are the logical sequence number (LSN).
Encryption
Encryption is the process of converting data into a format that is unrecognizable unless the appropriate password (also referred to as passphrase) is provided.
pgBackRest
will encrypt the repository based on a user-provided password, thereby preventing unauthorized access to data stored within the repository.
Upgrading pgBackRest
Upgrading pgBackRest from v1 to v2
Upgrading from
v1
to
v2
is fairly straight-forward. The repository format has not changed and all non-deprecated options from
v1
are accepted, so for most installations it is simply a matter of installing the new version.
However, there are a few caveats:
- The deprecated thread-max option is no longer valid. Use process-max instead.
- The deprecated archive-max-mb option is no longer valid. This has been replaced with the archive-queue-max option which has different semantics.
- The default for the backup-user option has changed from backrest to pgbackrest .
Many option names have changed to improve consistency although the old names from
v1
are still accepted. In general,
db-*
options have been renamed to
pg-*
and
backup-*
/
retention-*
options have been renamed to
repo-*
when appropriate.
PostgreSQL
and repository options must be indexed when using the new names introduced in
v2
, e.g.
pg1-host
,
pg1-path
,
repo1-path
,
repo1-type
, etc. Only one repository is allowed currently but more flexibility is planned for
v2
.
Installation
A new host named
pg1
is created to contain the demo cluster and run
pgBackRest
examples.
If
pgBackRest
has been installed before it's best to be sure that no prior copies of it are still installed. Depending on how old the version of pgBackRest is it may have been installed in a few different locations. The following commands will remove all prior versions of pgBackRest.
pg-primary
⇒
Remove prior
pgBackRest
installations
sudo rm -f /usr/bin/pgbackrest
sudo rm -f /usr/bin/pg_backrest
sudo rm -rf /usr/lib/perl5/BackRest
sudo rm -rf /usr/share/perl5/BackRest
sudo rm -rf /usr/lib/perl5/pgBackRest
sudo rm -rf /usr/share/perl5/pgBackRest
pgBackRest
is written in Perl which is included with Debian/Ubuntu by default. Some additional modules must also be installed but they are available as standard packages.
pg-primary
⇒
Install required Perl packages
sudo apt-get install libdbd-pg-perl libio-socket-ssl-perl libxml-libxml-perl
Debian/Ubuntu packages for
pgBackRest
are available at
apt.postgresql.org
. If they are not provided for your distribution/version it is easy to download the source and install manually.
pg-primary
⇒
Download version
2.01
of
pgBackRest
sudo wget -q -O - \ https://github.com/pgbackrest/pgbackrest/archive/release/2.01.tar.gz | \ sudo tar zx -C /root
pg-primary
⇒
Install
pgBackRest
sudo cp -r /root/pgbackrest-release-2.01/lib/pgBackRest \ /usr/share/perl5
sudo find /usr/share/perl5/pgBackRest -type f -exec chmod 644 {} +
sudo find /usr/share/perl5/pgBackRest -type d -exec chmod 755 {} +
sudo mkdir -m 770 /var/log/pgbackrest
sudo chown postgres:postgres /var/log/pgbackrest
sudo touch /etc/pgbackrest.conf
sudo chmod 640 /etc/pgbackrest.conf
sudo chown postgres:postgres /etc/pgbackrest.conf
pgBackRest
requires a companion C library that enhances performance and enables the `checksum-page` option and encryption. Pre-built packages are generally a better option than building the C library manually but the steps required are given below for completeness. Depending on the distribution a number of packages may be required which will not be enumerated here.
pg-primary
⇒
Build and Install C Library
sudo sh -c 'cd /root/pgbackrest-release-2.01/libc && \ perl Makefile.PL INSTALLMAN1DIR=none INSTALLMAN3DIR=none'
sudo make -C /root/pgbackrest-release-2.01/libc test
sudo make -C /root/pgbackrest-release-2.01/libc install
Although most of
pgBackRest
is written in Perl, the main executable is written in C. This allows certain time-critical commands (like async
archive-push
) to run more quickly.
pg-primary
⇒
Build and Install Binary
sudo make -C /root/pgbackrest-release-2.01/src
sudo make -C /root/pgbackrest-release-2.01/src install
pgBackRest
should now be properly installed but it is best to check. If any dependencies were missed then you will get an error when running
pgBackRest
from the command line.
pg-primary
⇒
Make sure the installation worked
sudo -u postgres pgbackrest
pgBackRest 2.01 - General help Usage: pgbackrest [options] [command] Commands: archive-get Get a WAL segment from the archive. archive-push Push a WAL segment to the archive. backup Backup a database cluster. check Check the configuration. expire Expire backups that exceed retention. help Get help. info Retrieve information about backups. restore Restore a database cluster. stanza-create Create the required stanza data. stanza-delete Delete a stanza. stanza-upgrade Upgrade a stanza. start Allow pgBackRest processes to run. stop Stop pgBackRest processes from running. version Get version. Use 'pgbackrest help [command]' for more information.
Quick Start
The Quick Start section will cover basic configuration of
pgBackRest
and
PostgreSQL
and introduce the
backup
,
restore
, and
info
commands.
Setup Demo Cluster
Creating the demo cluster is optional but is strongly recommended, especially for new users, since the example commands in the user guide reference the demo cluster; the examples assume the demo cluster is running on the default port (i.e. 5432). The cluster will not be started until a later section because there is still some configuration to do.
pg-primary
⇒
Create the demo cluster
sudo -u postgres /usr/lib/postgresql/9.4/bin/initdb \ -D /var/lib/postgresql/9.4/demo -k -A peer
sudo pg_createcluster 9.4 demo
Configuring already existing cluster (configuration: /etc/postgresql/9.4/demo, data: /var/lib/postgresql/9.4/demo, owner: 5000:5000) Ver Cluster Port Status Owner Data directory Log file 9.4 demo 5432 down postgres /var/lib/postgresql/9.4/demo /var/log/postgresql/postgresql-9.4-demo.log
By default
PostgreSQL
will only accept local connections. The examples in this guide will require connections from other servers so
listen_addresses
is configured to listen on all interfaces. This may not be appropriate for secure installations.
pg-primary
:
/etc/postgresql/9.4/demo/postgresql.conf
⇒
Set
listen_addresses
listen_addresses = '*'
For demonstration purposes the
log_line_prefix
setting will be minimally configured. This keeps the log output as brief as possible to better illustrate important information.
pg-primary
:
/etc/postgresql/9.4/demo/postgresql.conf
⇒
Set
log_line_prefix
listen_addresses = '*'
log_line_prefix = ''
log_line_prefix = ''
Configure Cluster Stanza
A stanza is the configuration for a
PostgreSQL
database cluster that defines where it is located, how it will be backed up, archiving options, etc. Most db servers will only have one Postgres database cluster and therefore one stanza, whereas backup servers will have a stanza for every database cluster that needs to be backed up.
It is tempting to name the stanza after the primary cluster but a better name describes the databases contained in the cluster. Because the stanza name will be used for the primary and all replicas it is more appropriate to choose a name that describes the actual function of the cluster, such as app or dw, rather than the local cluster name, such as main or prod.
It is tempting to name the stanza after the primary cluster but a better name describes the databases contained in the cluster. Because the stanza name will be used for the primary and all replicas it is more appropriate to choose a name that describes the actual function of the cluster, such as app or dw, rather than the local cluster name, such as main or prod.
The name 'demo' describes the purpose of this cluster accurately so that will also make a good stanza name.
pgBackRest
needs to know where the base data directory for the
PostgreSQL
cluster is located. The path can be requested from
PostgreSQL
directly but in a recovery scenario the
PostgreSQL
process will not be available. During backups the value supplied to
pgBackRest
will be compared against the path that
PostgreSQL
is running on and they must be equal or the backup will return an error. Make sure that
pg-path
is exactly equal to
data_directory
in
postgresql.conf
.
By default Debian/Ubuntu stores clusters in
/var/lib/postgresql/[version]/[cluster]
so it is easy to determine the correct path for the data directory.
When creating the
/etc/pgbackrest.conf
file, the database owner (usually
postgres
) must be granted read privileges.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure the
PostgreSQL
cluster data directory
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
pg1-path=/var/lib/postgresql/9.4/demo
pgBackRest
configuration files follow the Windows INI convention. Sections are denoted by text in brackets and key/value pairs are contained in each section. Lines beginning with
#
are ignored and can be used as comments.
Create the Repository
The repository is where
pgBackRest
stores backups and archives WAL segments.
It may be difficult to estimate in advance how much space you'll need. The best thing to do is take some backups then record the size of different types of backups (full/incr/diff) and measure the amount of WAL generated per day. This will give you a general idea of how much space you'll need, though of course requirements will likely change over time as your database evolves.
It may be difficult to estimate in advance how much space you'll need. The best thing to do is take some backups then record the size of different types of backups (full/incr/diff) and measure the amount of WAL generated per day. This will give you a general idea of how much space you'll need, though of course requirements will likely change over time as your database evolves.
For this demonstration the repository will be stored on the same host as the
PostgreSQL
server. This is the simplest configuration and is useful in cases where traditional backup software is employed to backup the database host.
pg-primary
⇒
Create the
pgBackRest
repository
sudo mkdir /var/lib/pgbackrest
sudo chmod 750 /var/lib/pgbackrest
sudo chown postgres:postgres /var/lib/pgbackrest
The repository path must be configured so
pgBackRest
knows where to find it.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure the
pgBackRest
repository path
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
Configure Archiving
Backing up a running
PostgreSQL
cluster requires WAL archiving to be enabled. Note that
at least
one WAL segment will be created during the backup process even if no explicit writes are made to the cluster.
pg-primary
:
/etc/postgresql/9.4/demo/postgresql.conf
⇒
Configure archive settings
archive_command = 'pgbackrest --stanza=demo archive-push %p'
archive_mode = on
listen_addresses = '*'
log_line_prefix = ''
max_wal_senders = 3
wal_level = hot_standby
archive_mode = on
listen_addresses = '*'
log_line_prefix = ''
max_wal_senders = 3
wal_level = hot_standby
The
wal_level
setting must be set to
archive
at a minimum but
hot_standby
and
logical
also work fine for backups. Setting
wal_level
to
hot_standy
and increasing
max_wal_senders
is a good idea even if you do not currently run a hot standby as this will allow them to be added later without restarting the primary cluster.
The
PostgreSQL
cluster must be restarted after making these changes and before performing a backup.
pg-primary
⇒
Restart the demo cluster
sudo pg_ctlcluster 9.4 demo restart
When archiving a WAL segment is expected to take more than 60 seconds (the default) to reach the
pgBackRest
repository, then the
pgBackRest
archive-timeout
option should be increased. Note that this option is not the same as the
PostgreSQL
archive_timeout
option which is used to force a WAL segment switch; useful for databases where there are long periods of inactivity. For more information on the
PostgreSQL
archive_timeout
option, see
PostgreSQL
Write Ahead Log
.
Configure Retention
pgBackRest
expires backups based on retention options.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure retention to 2 full backups
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
More information about retention can be found in the
Retention
section.
Configure Repository Encryption
The repository will be configured with a cipher type and key to demonstrate encryption.
It is important to use a long, random passphrase for the cipher key. A good way to generate one is to run:
openssl rand -base64 48
.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
pgBackRest
repository encryption
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
Once the repository has been configured and the stanza created and checked, the repository encryption settings cannot be changed.
Create the Stanza
The
stanza-create
command must be run on the host where the repository is located to initialize the stanza. It is recommended that the
check
command be run after
stanza-create
to ensure archiving and backups are properly configured.
pg-primary
⇒
Create the stanza and check the configuration
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info stanza-create
P00 INFO: stanza-create command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --stanza=demo
P00 INFO: stanza-create command end: completed successfully
Check the Configuration
The
check
command validates that
pgBackRest
and the
archive_command
setting are configured correctly for archiving and backups. It detects misconfigurations, particularly in archiving, that result in incomplete backups because required WAL segments did not reach the archive. The command can be run on the database or the repository host. The command may also be run on the standby host, however, since
pg_switch_xlog()
/
pg_switch_wal()
cannot be performed on the standby, the command will only test the repository configuration.
Note that pg_create_restore_point('pgBackRest Archive Check') and pg_switch_xlog() / pg_switch_wal() are called to force PostgreSQL to archive a WAL segment. Restore points are only supported in PostgreSQL >= 9.1 so for older versions the check command may fail if there has been no write activity since the last log rotation, therefore it is recommended that activity be generated by the user if there have been no writes since the last WAL switch before running the check command.
Note that pg_create_restore_point('pgBackRest Archive Check') and pg_switch_xlog() / pg_switch_wal() are called to force PostgreSQL to archive a WAL segment. Restore points are only supported in PostgreSQL >= 9.1 so for older versions the check command may fail if there has been no write activity since the last log rotation, therefore it is recommended that activity be generated by the user if there have been no writes since the last WAL switch before running the check command.
pg-primary
⇒
Check the configuration
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info check
P00 INFO: check command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --stanza=demo
P00 INFO: WAL segment 000000010000000000000001 successfully stored in the archive at '/var/lib/pgbackrest/archive/demo/9.4-1/0000000100000000/000000010000000000000001-3543f1551a7643d0892c0a27fddef588f24fc1c1.gz'
P00 INFO: check command end: completed successfully
Perform a Backup
To perform a backup of the
PostgreSQL
cluster run
pgBackRest
with the
backup
command.
pg-primary
⇒
Backup the demo cluster
sudo -u postgres pgbackrest --stanza=demo \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo
P00 WARN: no prior backup exists, incr backup has been changed to full
P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:05": backup begins after the next regular checkpoint completes P00 INFO: backup start archive = 000000010000000000000002, lsn = 0/2000028 [filtered 754 lines of output] P01 INFO: backup file /var/lib/postgresql/9.4/demo/base/1/11895 (0B, 100%) P01 INFO: backup file /var/lib/postgresql/9.4/demo/base/1/11885 (0B, 100%)
P00 INFO: full backup size = 19.2MB
P00 INFO: execute exclusive pg_stop_backup() and wait for all WAL segments to archive P00 INFO: backup stop archive = 000000010000000000000002, lsn = 0/20000F0 [filtered 4 lines of output]
By default
pgBackRest
will attempt to perform an incremental backup. However, an incremental backup must be based on a full backup and since no full backup existed
pgBackRest
ran a full backup instead.
The
type
option can be used to specify a full or differential backup.
pg-primary
⇒
Differential backup of the demo cluster
sudo -u postgres pgbackrest --stanza=demo --type=diff \ --log-level-console=info backup
[filtered 4 lines of output] P01 INFO: backup file /var/lib/postgresql/9.4/demo/global/pg_control (8KB, 97%) checksum d64c883c4b0664ab2528bf7e6f1df82cc48b0308 P01 INFO: backup file /var/lib/postgresql/9.4/demo/backup_label (236B, 100%) checksum ff8e781310f038470e768e41c0fbae409a987cbd
P00 INFO: diff backup size = 8.2KB
P00 INFO: execute exclusive pg_stop_backup() and wait for all WAL segments to archive P00 INFO: backup stop archive = 000000010000000000000004, lsn = 0/40000F0 [filtered 4 lines of output]
This time there was no warning because a full backup already existed. While incremental backups can be based on a full
or
differential backup, differential backups must be based on a full backup. A full backup can be performed by running the
backup
command with
--type=full
.
More information about the
backup
command can be found in the
Backup
section.
Schedule a Backup
Backups can be scheduled with utilities such as cron.
In the following example, two cron jobs are configured to run; full backups are scheduled for 6:30 AM every Sunday with differential backups scheduled for 6:30 AM Monday through Saturday. If this crontab is installed for the first time mid-week, then pgBackRest will run a full backup the first time the differential job is executed, followed the next day by a differential backup.
#m h dom mon dow command 30 06 * * 0 pgbackrest --type=full --stanza=demo backup 30 06 * * 1-6 pgbackrest --type=diff --stanza=demo backup
Once backups are scheduled it's important to configure retention so backups are expired on a regular schedule, see
Retention
.
Backup Information
Use the
info
command to get information about backups.
pg-primary
⇒
Get info for the demo cluster
sudo -u postgres pgbackrest info
stanza: demo status: ok db (current) wal archive min/max (9.4-1): 000000010000000000000002 / 000000010000000000000004
full backup: 20180320-001305F
timestamp start/stop: 2018-03-20 00:13:05 / 2018-03-20 00:13:10 wal start/stop: 000000010000000000000002 / 000000010000000000000002 database size: 19.2MB, backup size: 19.2MB repository size: 2.2MB, repository backup size: 2.2MB
diff backup: 20180320-001305F_20180320-001311D
timestamp start/stop: 2018-03-20 00:13:11 / 2018-03-20 00:13:14 wal start/stop: 000000010000000000000004 / 000000010000000000000004 database size: 19.2MB, backup size: 8.2KB repository size: 2.2MB, repository backup size: 400B backup reference list: 20180320-001305F
Each stanza has a separate section and it is possible to limit output to a single stanza with the
--stanza
option. The stanza '
status
' gives a brief indication of the stanza's health. If this is '
ok
' then
pgBackRest
is functioning normally. The '
wal archive min/max
' shows the minimum and maximum WAL currently stored in the archive. Note that there may be gaps due to archive retention policies or other reasons.
The backups are displayed oldest to newest. The oldest backup will
always
be a full backup (indicated by an
F
at the end of the label) but the newest backup can be full, differential (ends with
D
), or incremental (ends with
I
).
The '
timestamp start/stop
' defines the time period when the backup ran. The '
timestamp stop
' can be used to determine the backup to use when performing Point-In-Time Recovery. More information about Point-In-Time Recovery can be found in the
Point-In-Time Recovery
section.
The '
wal start/stop
' defines the WAL range that is required to make the database consistent when restoring. The
backup
command will ensure that this WAL range is in the archive before completing.
The '
database size
' is the full uncompressed size of the database while '
backup size
' is the amount of data actually backed up (these will be the same for full backups). The '
repository size
' includes all the files from this backup and any referenced backups that are required to restore the database while '
repository backup size
' includes only the files in this backup (these will also be the same for full backups). Repository sizes reflect compressed file sizes if compression is enabled in
pgBackRest
or the filesystem.
The '
backup reference list
' contains the additional backups that are required to restore this backup.
Restore a Backup
Backups can protect you from a number of disaster scenarios, the most common of which are hardware failure and data corruption. The easiest way to simulate data corruption is to remove an important
PostgreSQL
cluster file.
pg-primary
⇒
Stop the demo cluster and delete the
pg_control
file
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres rm /var/lib/postgresql/9.4/demo/global/pg_control
Starting the cluster without this important file will result in an error.
pg-primary
⇒
Attempt to start the corrupted demo cluster
sudo pg_ctlcluster 9.4 demo start
The PostgreSQL server failed to start. Please check the log output:
postgres: could not find the database system
Expected to find it in the directory "/var/lib/postgresql/9.4/demo", but could not open file "/var/lib/postgresql/9.4/demo/global/pg_control": No such file or directory
To restore a backup of the
PostgreSQL
cluster run
pgBackRest
with the
restore
command. The cluster needs to be stopped (in this case it is already stopped) and all files must be removed from the
PostgreSQL
data directory.
pg-primary
⇒
Remove old files from demo cluster
sudo -u postgres find /var/lib/postgresql/9.4/demo -mindepth 1 -delete
pg-primary
⇒
Restore the demo cluster and start
PostgreSQL
sudo -u postgres pgbackrest --stanza=demo restore
sudo pg_ctlcluster 9.4 demo start
This time the cluster started successfully since the restore replaced the missing
pg_control
file.
More information about the
restore
command can be found in the
Restore
section.
Backup
The Backup section introduces additional
backup
command features.
Fast Start Option
By default
pgBackRest
will wait for the next regularly scheduled checkpoint before starting a backup. Depending on the
checkpoint_timeout
and
checkpoint_segments
settings in
PostgreSQL
it may be quite some time before a checkpoint completes and the backup can begin.
pg-primary
⇒
Incremental backup of the demo cluster with the regularly scheduled checkpoint
sudo -u postgres pgbackrest --stanza=demo --type=incr \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo --type=incr P00 INFO: last backup label = 20180320-001305F_20180320-001311D, version = 2.01
P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:26": backup begins after the next regular checkpoint completes
P00 INFO: backup start archive = 000000020000000000000006, lsn = 0/6000028 P01 INFO: backup file /var/lib/postgresql/9.4/demo/pg_multixact/offsets/0000 (8KB, 33%) checksum 0631457264ff7f8d5fb1edc2c0211992a67c73e6 [filtered 10 lines of output]
When
--start-fast
is passed on the command-line or
start-fast=y
is set in
/etc/pgbackrest.conf
an immediate checkpoint is requested and the backup will start more quickly. This is convenient for testing and for ad-hoc backups. For instance, if a backup is being taken at the beginning of a release window it makes no sense to wait for a checkpoint. Since regularly scheduled backups generally only happen once per day it is unlikely that enabling the
start-fast
in
/etc/pgbackrest.conf
will negatively affect performance, however for high-volume transactional systems you may want to pass
--start-fast
on the command-line instead. Alternately, it is possible to override the setting in the configuration file by passing
--no-start-fast
on the command-line.
pg-primary
:
/etc/pgbackrest.conf
⇒
Enable the
start-fast
option
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg-primary
⇒
Incremental backup of the demo cluster with an immediate checkpoint
sudo -u postgres pgbackrest --stanza=demo --type=incr \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo --start-fast --type=incr P00 INFO: last backup label = 20180320-001305F_20180320-001326I, version = 2.01
P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:30": backup begins after the requested immediate checkpoint completes
P00 INFO: backup start archive = 000000020000000000000007, lsn = 0/7000028 P01 INFO: backup file /var/lib/postgresql/9.4/demo/global/pg_control (8KB, 97%) checksum 33dfd47798b7959b0e8de89de53938b29672ffae [filtered 8 lines of output]
Automatic Stop Option
Sometimes
pgBackRest
will exit unexpectedly and the backup in progress on the
PostgreSQL
cluster will not be properly stopped.
pgBackRest
exits as quickly as possible when an error occurs so that the cause can be reported accurately and is not masked by another problem that might happen during a more extensive cleanup.
Here an error is intentionally caused by removing repository permissions.
pg-primary
⇒
Revoke write privileges in the
pgBackRest
repository and attempt a backup
sudo chmod 550 /var/lib/pgbackrest/backup/demo/
sudo -u postgres pgbackrest --stanza=demo --type=incr \ --log-level-console=info backup
[filtered 2 lines of output] P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:34": backup begins after the requested immediate checkpoint completes P00 INFO: backup start archive = 000000020000000000000008, lsn = 0/8000028
P00 ERROR: [047]: unable to create path '/var/lib/pgbackrest/backup/demo/20180320-001305F_20180320-001334I': Permission denied
P00 INFO: backup command end: aborted with exception [047]
Even when the permissions are fixed
pgBackRest
will still be unable to perform a backup because the
PostgreSQL
cluster is stuck in backup mode.
pg-primary
⇒
Restore write privileges in the
pgBackRest
repository and attempt a backup
sudo chmod 750 /var/lib/pgbackrest/backup/demo/
sudo -u postgres pgbackrest --stanza=demo --type=incr \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo --start-fast --type=incr P00 INFO: last backup label = 20180320-001305F_20180320-001330I, version = 2.01 P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:36": backup begins after the requested immediate checkpoint completes
P00 ERROR: [057]: ERROR: a backup is already in progress
HINT: Run pg_stop_backup() and try again.: select to_char(current_timestamp, 'YYYY-MM-DD HH24:MI:SS.US TZ'), pg_xlogfile_name(lsn), lsn::text from pg_start_backup('pgBackRest backup started at 2018-03-20 00:13:36', true) as lsn
Enabling the
stop-auto
option allows
pgBackRest
to stop the current backup if it detects that no other
pgBackRest
backup process is running.
pg-primary
:
/etc/pgbackrest.conf
⇒
Enable the
stop-auto
option
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
stop-auto=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
stop-auto=y
Now
pgBackRest
will stop the old backup and start a new one so the process completes successfully.
pg-primary
⇒
Perform an incremental backup
sudo -u postgres pgbackrest --stanza=demo --type=incr \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo --start-fast --stop-auto --type=incr P00 INFO: last backup label = 20180320-001305F_20180320-001330I, version = 2.01
P00 WARN: the cluster is already in backup mode but no pgBackRest backup process is running. pg_stop_backup() will be called so a new backup can be started.
P00 INFO: execute exclusive pg_stop_backup() and wait for all WAL segments to archive
P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:13:38": backup begins after the requested immediate checkpoint completes
P00 INFO: backup start archive = 000000020000000000000009, lsn = 0/9000028 P01 INFO: backup file /var/lib/postgresql/9.4/demo/global/pg_control (8KB, 97%) checksum 2bb3f7cb57a717f41bc60542ea8e629a22410a70 [filtered 8 lines of output]
Although useful this feature may not be appropriate when another third-party backup solution is being used to take online backups as
pgBackRest
will not recognize that the other software is running and may terminate a backup started by that software. However, it would be unusual to run more than one third-party backup solution at the same time so this is not likely to be a problem.
Note that
pg_dump
and
pg_basebackup
do not take online backups so are not affected. It is safe to run them in conjunction with
pgBackRest
.
Archive Timeout
During an online backup
pgBackRest
waits for WAL segments that are required for backup consistency to be archived. This wait time is governed by the
pgBackRest
archive-timeout
option which defaults to 60 seconds. If archiving an individual segment is known to take longer then this option should be increased.
Retention
Generally it is best to retain as many backups as possible to provide a greater window for
Point-in-Time Recovery
, but practical concerns such as disk space must also be considered. Retention options remove older backups once they are no longer needed.
Full Backup Retention
Set
repo1-retention-full
to the number of full backups required. New backups must be completed before expiration will occur — that means if
repo1-retention-full=2
then there will be three full backups stored before the oldest one is expired.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
repo1-retention-full
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
stop-auto=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
stop-auto=y
Backup
repo1-retention-full=2
but currently there is only one full backup so the next full backup to run will not expire any full backups.
pg-primary
⇒
Perform a full backup
sudo -u postgres pgbackrest --stanza=demo --type=full \ --log-level-console=detail backup
[filtered 763 lines of output] P00 INFO: backup command end: completed successfully P00 INFO: expire command begin 2.01: --log-level-console=detail --log-level-stderr=off --no-log-timestamp --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo
P00 DETAIL: archive retention on backup 20180320-001305F, archiveId = 9.4-1, start = 000000010000000000000002
P00 DETAIL: no archive to remove, archiveId = 9.4-1 P00 INFO: expire command end: completed successfully
Archive
is
expired because WAL segments were generated before the oldest backup. These are not useful for recovery — only WAL segments generated after a backup can be used to recover that backup.
pg-primary
⇒
Perform a full backup
sudo -u postgres pgbackrest --stanza=demo --type=full \ --log-level-console=info backup
[filtered 763 lines of output] P00 INFO: backup command end: completed successfully P00 INFO: expire command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-full=2 --stanza=demo
P00 INFO: expire full backup set: 20180320-001305F, 20180320-001305F_20180320-001311D, 20180320-001305F_20180320-001326I, 20180320-001305F_20180320-001330I, 20180320-001305F_20180320-001338I
P00 INFO: remove expired backup 20180320-001305F_20180320-001338I P00 INFO: remove expired backup 20180320-001305F_20180320-001330I [filtered 3 lines of output]
The
20180320-001305F
full backup is expired and archive retention is based on the
20180320-001343F
which is now the oldest full backup.
Differential Backup Retention
Set
repo1-retention-diff
to the number of differential backups required. Differentials only rely on the prior full backup so it is possible to create a
rollingset of differentials for the last day or more. This allows quick restores to recent points-in-time but reduces overall space consumption.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
repo1-retention-diff
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-diff=1
repo1-retention-full=2
start-fast=y
stop-auto=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-diff=1
repo1-retention-full=2
start-fast=y
stop-auto=y
Backup
repo1-retention-diff=1
so two differentials will need to be performed before one is expired. An incremental backup is added to demonstrate incremental expiration. Incremental backups cannot be expired independently — they are always expired with their related full or differential backup.
pg-primary
⇒
Perform differential and incremental backups
sudo -u postgres pgbackrest --stanza=demo --type=diff backup
sudo -u postgres pgbackrest --stanza=demo --type=incr backup
Now performing a differential backup will expire the previous differential and incremental backups leaving only one differential backup.
pg-primary
⇒
Perform a differential backup
sudo -u postgres pgbackrest --stanza=demo --type=diff \ --log-level-console=info backup
[filtered 10 lines of output] P00 INFO: backup command end: completed successfully P00 INFO: expire command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-diff=1 --repo1-retention-full=2 --stanza=demo
P00 INFO: expire diff backup set: 20180320-001349F_20180320-001356D, 20180320-001349F_20180320-001401I
P00 INFO: remove expired backup 20180320-001349F_20180320-001401I P00 INFO: remove expired backup 20180320-001349F_20180320-001356D
Archive Retention
Although
pgBackRest
automatically removes archived WAL segments when expiring backups (the default expires WAL for full backups based on the
repo1-retention-full
option), it may be useful to expire archive more aggressively to save disk space. Note that full backups are treated as differential backups for the purpose of differential archive retention.
Expiring archive will never remove WAL segments that are required to make a backup consistent. However, since Point-in-Time-Recovery (PITR) only works on a continuous WAL stream, care should be taken when aggressively expiring archive outside of the normal backup expiration process.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
repo1-retention-diff
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-diff=2
repo1-retention-full=2
start-fast=y
stop-auto=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-cipher-pass=zWaf6XtpjIVZC5444yXB+cgFDFl7MxGlgkZSaoPvTGirhPygu4jOKOXf9LO4vjfO
repo1-cipher-type=aes-256-cbc
repo1-path=/var/lib/pgbackrest
repo1-retention-diff=2
repo1-retention-full=2
start-fast=y
stop-auto=y
pg-primary
⇒
Perform differential backup
sudo -u postgres pgbackrest --stanza=demo --type=diff \ --log-level-console=info backup
[filtered 7 lines of output] P00 INFO: execute exclusive pg_stop_backup() and wait for all WAL segments to archive P00 INFO: backup stop archive = 000000020000000000000012, lsn = 0/120000F0
P00 INFO: new backup label = 20180320-001349F_20180320-001410D
P00 INFO: backup command end: completed successfully P00 INFO: expire command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-diff=2 --repo1-retention-full=2 --stanza=demo
pg-primary
⇒
Expire archive
sudo -u postgres pgbackrest --stanza=demo --log-level-console=detail \ --repo1-retention-archive-type=diff --repo1-retention-archive=1 expire
P00 INFO: expire command begin 2.01: --log-level-console=detail --log-level-stderr=off --no-log-timestamp --repo1-cipher-pass=--repo1-cipher-type=aes-256-cbc --repo1-path=/var/lib/pgbackrest --repo1-retention-archive=1 --repo1-retention-archive-type=diff --repo1-retention-diff=2 --repo1-retention-full=2 --stanza=demo P00 DETAIL: archive retention on backup 20180320-001343F, archiveId = 9.4-1, start = 00000002000000000000000A, stop = 00000002000000000000000A P00 DETAIL: archive retention on backup 20180320-001349F, archiveId = 9.4-1, start = 00000002000000000000000B, stop = 00000002000000000000000B
P00 DETAIL: archive retention on backup 20180320-001349F_20180320-001405D, archiveId = 9.4-1, start = 00000002000000000000000E, stop = 00000002000000000000000E
P00 DETAIL: archive retention on backup 20180320-001349F_20180320-001410D, archiveId = 9.4-1, start = 000000020000000000000012
P00 DETAIL: remove archive: archiveId = 9.4-1, start = 00000002000000000000000C, stop = 00000002000000000000000D P00 DETAIL: remove archive: archiveId = 9.4-1, start = 00000002000000000000000F, stop = 000000020000000000000011
P00 INFO: expire command end: completed successfully
The
20180320-001349F_20180320-001405D
differential backup has archived WAL segments that must be retained to make the older backups consistent even though they cannot be played any further forward with PITR. WAL segments generated after
20180320-001349F_20180320-001405D
but before
20180320-001349F_20180320-001410D
are removed. WAL segments generated after the new backup
20180320-001349F_20180320-001410D
remain and can be used for PITR.
Since full backups are considered differential backups for the purpose of differential archive retention, if a full backup is now performed with the same settings, only the archive for that full backup is retained for PITR.
Restore
The Restore section introduces additional
restore
command features.
Delta Option
Restore a Backup
in
Quick Start
required the database cluster directory to be cleaned before the
restore
could be performed. The
delta
option allows
pgBackRest
to automatically determine which files in the database cluster directory can be preserved and which ones need to be restored from the backup — it also
removes
files not present in the backup manifest so it will dispose of divergent changes. This is accomplished by calculating a
SHA-1
cryptographic hash for each file in the database cluster directory. If the
SHA-1
hash does not match the hash stored in the backup then that file will be restored. This operation is very efficient when combined with the
process-max
option. Since the
PostgreSQL
server is shut down during the restore, a larger number of processes can be used than might be desirable during a backup when the
PostgreSQL
server is running.
pg-primary
⇒
Stop the demo cluster, perform delta restore
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta \ --log-level-console=detail restore
[filtered 692 lines of output] P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/base/12134/PG_VERSION - exists and matches backup (4B, 99%) checksum 8dbabb96e032b8d9f1993c0e4b9141e71ade01a1 P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/base/1/PG_VERSION - exists and matches backup (4B, 99%) checksum 8dbabb96e032b8d9f1993c0e4b9141e71ade01a1
P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/PG_VERSION - exists and matches backup (4B, 100%) checksum 8dbabb96e032b8d9f1993c0e4b9141e71ade01a1
P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/global/12086 - exists and is zero size (0B, 100%) P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/global/12038 - exists and is zero size (0B, 100%) [filtered 83 lines of output] P01 DETAIL: restore file /var/lib/postgresql/9.4/demo/base/1/11885 - exists and is zero size (0B, 100%) P00 INFO: write /var/lib/postgresql/9.4/demo/recovery.conf
P00 INFO: restore global/pg_control (performed last to ensure aborted restores cannot be started)
P00 INFO: restore command end: completed successfully
pg-primary
⇒
Restart
PostgreSQL
sudo pg_ctlcluster 9.4 demo start
Restore Selected Databases
There may be cases where it is desirable to selectively restore specific databases from a cluster backup. This could be done for performance reasons or to move selected databases to a machine that does not have enough space to restore the entire cluster backup.
To demonstrate this feature two databases are created: test1 and test2. A fresh backup is run so
pgBackRest
is aware of the new databases.
pg-primary
⇒
Create two test databases and perform a backup
sudo -u postgres psql -c "create database test1;"
CREATE DATABASE
sudo -u postgres psql -c "create database test2;"
CREATE DATABASE
sudo -u postgres pgbackrest --stanza=demo --type=incr backup
Each test database will be seeded with tables and data to demonstrate that recovery works with selective restore.
pg-primary
⇒
Create a test table in each database
sudo -u postgres psql -c "create table test1_table (id int); \ insert into test1_table (id) values (1);" test1
INSERT 0 1
sudo -u postgres psql -c "create table test2_table (id int); \ insert into test2_table (id) values (2);" test2
INSERT 0 1
One of the main reasons to use selective restore is to save space. The size of the test1 database is shown here so it can be compared with the disk utilization after a selective restore.
pg-primary
⇒
Show space used by test1 database
sudo -u postgres du -sh /var/lib/postgresql/9.4/demo/base/16384
6.4M /var/lib/postgresql/9.4/demo/base/16384
Stop the cluster and restore only the test2 database. Built-in databases (
template0
,
template1
, and
postgres
) are always restored.
pg-primary
⇒
Restore from last backup including only the test2 database
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta \ --db-include=test2 restore
sudo pg_ctlcluster 9.4 demo start
Once recovery is complete the test2 database will contain all previously created tables and data.
pg-primary
⇒
Demonstrate that the test2 database was recovered
sudo -u postgres psql -c "select * from test2_table;" test2
id ---- 2 (1 row)
The test1 database, despite successful recovery, is not accessible. This is because the entire database was restored as sparse, zeroed files.
PostgreSQL
can successfully apply WAL on the zeroed files but the database as a whole will not be valid because key files contain no data. This is purposeful to prevent the database from being accidentally used when it might contain partial data that was applied during WAL replay.
pg-primary
⇒
Attempting to connect to the test1 database will produce an error
sudo -u postgres psql -c "select * from test1_table;" test1
psql: FATAL: relation mapping file "base/16384/pg_filenode.map" contains invalid data
Since the test1 database is restored with sparse, zeroed files it will only require as much space as the amount of WAL that is written during recovery. While the amount of WAL generated during a backup and applied during recovery can be significant it will generally be a small fraction of the total database size, especially for large databases where this feature is most likely to be useful.
It is clear that the test1 database uses far less disk space during the selective restore than it would have if the entire database had been restored.
pg-primary
⇒
Show space used by test1 database after recovery
sudo -u postgres du -sh /var/lib/postgresql/9.4/demo/base/16384
152K /var/lib/postgresql/9.4/demo/base/16384
At this point the only action that can be taken on the invalid test1 database is
drop database
.
pgBackRest
does not automatically drop the database since this cannot be done until recovery is complete and the cluster is accessible.
pg-primary
⇒
Drop the test1 database
sudo -u postgres psql -c "drop database test1;"
DROP DATABASE
Now that the invalid test1 database has been dropped only the test2 and built-in databases remain.
pg-primary
⇒
List remaining databases
sudo -u postgres psql -c "select oid, datname from pg_database order by oid;"
oid | datname -------+----------- 1 | template1 12134 | template0 12139 | postgres
16385 | test2
(4 rows)
Point-in-Time Recovery
Restore a Backup
in
Quick Start
performed default recovery, which is to play all the way to the end of the WAL stream. In the case of a hardware failure this is usually the best choice but for data corruption scenarios (whether machine or human in origin) Point-in-Time Recovery (PITR) is often more appropriate.
Point-in-Time Recovery (PITR) allows the WAL to be played from the last backup to a specified time, transaction id, or recovery point. For common recovery scenarios time-based recovery is arguably the most useful. A typical recovery scenario is to restore a table that was accidentally dropped or data that was accidentally deleted. Recovering a dropped table is more dramatic so that's the example given here but deleted data would be recovered in exactly the same way.
pg-primary
⇒
Backup the demo cluster and create a table with very important data
sudo -u postgres pgbackrest --stanza=demo --type=diff backup
sudo -u postgres psql -c "begin; \ create table important_table (message text); \ insert into important_table values ('Important Data'); \ commit; \ select * from important_table;"
message ----------------
Important Data
(1 row)
It is important to represent the time as reckoned by
PostgreSQL
and to include timezone offsets. This reduces the possibility of unintended timezone conversions and an unexpected recovery result.
pg-primary
⇒
Get the time from
PostgreSQL
sudo -u postgres psql -Atc "select current_timestamp"
2018-03-20 00:14:45.019624+00
Now that the time has been recorded the table is dropped. In practice finding the exact time that the table was dropped is a lot harder than in this example. It may not be possible to find the exact time, but some forensic work should be able to get you close.
pg-primary
⇒
Drop the important table
sudo -u postgres psql -c "begin; \ drop table important_table; \ commit; \ select * from important_table;"
ERROR: relation "important_table" does not exist
LINE 1: ...le important_table; commit; select * from important_... ^
Now the restore can be performed with time-based recovery to bring back the missing table.
pg-primary
⇒
Stop
PostgreSQL
, restore the demo cluster to
2018-03-20 00:14:45.019624+00
, and display
recovery.conf
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta \ --type=time "--target=2018-03-20 00:14:45.019624+00" restore
sudo -u postgres cat /var/lib/postgresql/9.4/demo/recovery.conf
restore_command = 'pgbackrest --stanza=demo archive-get %f "%p"'
recovery_target_time = '2018-03-20 00:14:45.019624+00'
The
recovery.conf
file has been automatically generated by
pgBackRest
so
PostgreSQL
can be started immediately. Once
PostgreSQL
has finished recovery the table will exist again and can be queried.
pg-primary
⇒
Start
PostgreSQL
and check that the important table exists
sudo pg_ctlcluster 9.4 demo start
sudo -u postgres psql -c "select * from important_table"
message ----------------
Important Data
(1 row)
The
PostgreSQL
log also contains valuable information. It will indicate the time and transaction where the recovery stopped and also give the time of the last transaction to be applied.
pg-primary
⇒
Examine the
PostgreSQL
log output
sudo -u postgres cat /var/log/postgresql/postgresql-9.4-demo.log
LOG: database system was interrupted; last known up at 2018-03-20 00:14:40 UTC
LOG: starting point-in-time recovery to 2018-03-20 00:14:45.019624+00
LOG: restored log file "00000004.history" from archive LOG: restored log file "000000040000000000000017" from archive [filtered 2 lines of output] LOG: incomplete startup packet LOG: restored log file "000000040000000000000018" from archive
LOG: recovery stopping before commit of transaction 686, time 2018-03-20 00:14:45.182277+00
LOG: redo done at 0/180157F0
LOG: last completed transaction was at log time 2018-03-20 00:14:44.86087+00
LOG: selected new timeline ID: 5 LOG: restored log file "00000004.history" from archive [filtered 4 lines of output]
This example was rigged to give the correct result. If a backup after the required time is chosen then
PostgreSQL
will not be able to recover the lost table.
PostgreSQL
can only play forward, not backward. To demonstrate this the important table must be dropped (again).
pg-primary
⇒
Drop the important table (again)
sudo -u postgres psql -c "begin; \ drop table important_table; \ commit; \ select * from important_table;"
ERROR: relation "important_table" does not exist
LINE 1: ...le important_table; commit; select * from important_... ^
Now take a new backup and attempt recovery from the new backup.
pg-primary
⇒
Perform a backup then attempt recovery from that backup
sudo -u postgres pgbackrest --stanza=demo --type=incr backup
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta \ --type=time "--target=2018-03-20 00:14:45.019624+00" restore
sudo pg_ctlcluster 9.4 demo start
sudo -u postgres psql -c "select * from important_table"
ERROR: relation "important_table" does not exist
LINE 1: select * from important_table ^
Looking at the log output it's not obvious that recovery failed to restore the table. The key is to look for the presence of the
recovery stopping before...and
last completed transaction...log messages. If they are not present then the recovery to the specified point-in-time was not successful.
pg-primary
⇒
Examine the
PostgreSQL
log output to discover the recovery was not successful
sudo -u postgres cat /var/log/postgresql/postgresql-9.4-demo.log
LOG: database system was interrupted; last known up at 2018-03-20 00:14:55 UTC
LOG: starting point-in-time recovery to 2018-03-20 00:14:45.019624+00
LOG: restored log file "00000005.history" from archive LOG: restored log file "000000050000000000000019" from archive LOG: redo starts at 0/19000028
LOG: consistent recovery state reached at 0/190000F0
LOG: redo done at 0/190000F0 LOG: incomplete startup packet [filtered 9 lines of output]
Using an earlier backup will allow
PostgreSQL
to play forward to the correct time. The
info
command can be used to find the next to last backup.
pg-primary
⇒
Get backup info for the demo cluster
sudo -u postgres pgbackrest info
stanza: demo status: ok db (current) wal archive min/max (9.4-1): 00000002000000000000000A / 000000050000000000000019 full backup: 20180320-001343F timestamp start/stop: 2018-03-20 00:13:43 / 2018-03-20 00:13:48 wal start/stop: 00000002000000000000000A / 00000002000000000000000A database size: 19.2MB, backup size: 19.2MB repository size: 2.2MB, repository backup size: 2.2MB full backup: 20180320-001349F timestamp start/stop: 2018-03-20 00:13:49 / 2018-03-20 00:13:54 wal start/stop: 00000002000000000000000B / 00000002000000000000000B database size: 19.2MB, backup size: 19.2MB repository size: 2.2MB, repository backup size: 2.2MB diff backup: 20180320-001349F_20180320-001410D timestamp start/stop: 2018-03-20 00:14:10 / 2018-03-20 00:14:13 wal start/stop: 000000020000000000000012 / 000000020000000000000012 database size: 19.2MB, backup size: 8.2KB repository size: 2.2MB, repository backup size: 400B backup reference list: 20180320-001349F incr backup: 20180320-001349F_20180320-001422I timestamp start/stop: 2018-03-20 00:14:22 / 2018-03-20 00:14:27 wal start/stop: 000000030000000000000014 / 000000030000000000000014 database size: 31.7MB, backup size: 12.5MB repository size: 3.7MB, repository backup size: 1.5MB backup reference list: 20180320-001349F
diff backup: 20180320-001349F_20180320-001439D
timestamp start/stop: 2018-03-20 00:14:39 / 2018-03-20 00:14:43 wal start/stop: 000000040000000000000017 / 000000040000000000000017 database size: 25.5MB, backup size: 6.3MB repository size: 3MB, repository backup size: 771.6KB backup reference list: 20180320-001349F incr backup: 20180320-001349F_20180320-001454I timestamp start/stop: 2018-03-20 00:14:54 / 2018-03-20 00:14:57 wal start/stop: 000000050000000000000019 / 000000050000000000000019 database size: 25.5MB, backup size: 1.7MB repository size: 3MB, repository backup size: 200.8KB
backup reference list: 20180320-001349F, 20180320-001349F_20180320-001439D
The default behavior for restore is to use the last backup but an earlier backup can be specified with the
--set
option.
pg-primary
⇒
Stop
PostgreSQL
, restore from the selected backup, and start
PostgreSQL
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta \ --type=time "--target=2018-03-20 00:14:45.019624+00" \ --set=20180320-001349F_20180320-001439D restore
sudo pg_ctlcluster 9.4 demo start
sudo -u postgres psql -c "select * from important_table"
message ----------------
Important Data
(1 row)
Now the the log output will contain the expected
recovery stopping before...and
last completed transaction...messages showing that the recovery was successful.
pg-primary
⇒
Examine the
PostgreSQL
log output for log messages indicating success
sudo -u postgres cat /var/log/postgresql/postgresql-9.4-demo.log
LOG: database system was interrupted; last known up at 2018-03-20 00:14:40 UTC
LOG: starting point-in-time recovery to 2018-03-20 00:14:45.019624+00
FATAL: the database system is starting up LOG: restored log file "00000004.history" from archive [filtered 3 lines of output] LOG: incomplete startup packet LOG: restored log file "000000040000000000000018" from archive
LOG: recovery stopping before commit of transaction 686, time 2018-03-20 00:14:45.182277+00
LOG: redo done at 0/180157F0
LOG: last completed transaction was at log time 2018-03-20 00:14:44.86087+00
LOG: restored log file "00000005.history" from archive LOG: restored log file "00000006.history" from archive [filtered 7 lines of output]
S3 Support
pgBackRest
supports storing repositories in
Amazon S3
. The bucket used to store the repository must be created in advance —
pgBackRest
will not do it automatically.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
S3
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
process-max=4
repo1-cipher-type=none
repo1-path=/
repo1-retention-diff=2
repo1-retention-full=2
repo1-s3-bucket=demo-bucket
repo1-s3-endpoint=s3.amazonaws.com
repo1-s3-key=accessKey1
repo1-s3-key-secret=verySecretKey1
repo1-s3-region=us-east-1
repo1-s3-verify-ssl=n
repo1-type=s3
start-fast=y
stop-auto=y
pg1-path=/var/lib/postgresql/9.4/demo
[global]
process-max=4
repo1-cipher-type=none
repo1-path=/
repo1-retention-diff=2
repo1-retention-full=2
repo1-s3-bucket=demo-bucket
repo1-s3-endpoint=s3.amazonaws.com
repo1-s3-key=accessKey1
repo1-s3-key-secret=verySecretKey1
repo1-s3-region=us-east-1
repo1-s3-verify-ssl=n
repo1-type=s3
start-fast=y
stop-auto=y
Commands are run exactly as if the repository were stored on a local disk.
pg-primary
⇒
Create the stanza
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info stanza-create
P00 INFO: stanza-create command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-type=none --repo1-path=/ --repo1-s3-bucket=demo-bucket --repo1-s3-endpoint=s3.amazonaws.com --repo1-s3-key=--repo1-s3-key-secret= --repo1-s3-region=us-east-1 --no-repo1-s3-verify-ssl --repo1-type=s3 --stanza=demo
P00 INFO: stanza-create command end: completed successfully
File creation time in
S3
is relatively slow so commands benefit by increasing
process-max
to parallelize file creation.
pg-primary
⇒
Backup the demo cluster
sudo -u postgres pgbackrest --stanza=demo \ --log-level-console=info backup
P00 INFO: backup command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --process-max=4 --repo1-cipher-type=none --repo1-path=/ --repo1-retention-diff=2 --repo1-retention-full=2 --repo1-s3-bucket=demo-bucket --repo1-s3-endpoint=s3.amazonaws.com --repo1-s3-key=--repo1-s3-key-secret= --repo1-s3-region=us-east-1 --no-repo1-s3-verify-ssl --repo1-type=s3 --stanza=demo --start-fast --stop-auto
P00 WARN: no prior backup exists, incr backup has been changed to full
P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:15:18": backup begins after the requested immediate checkpoint completes P00 INFO: backup start archive = 000000070000000000000019, lsn = 0/19000028 [filtered 995 lines of output] P02 INFO: backup file /var/lib/postgresql/9.4/demo/base/1/11905 (0B, 100%) P03 INFO: backup file /var/lib/postgresql/9.4/demo/base/1/11907 (0B, 100%)
P00 INFO: full backup size = 25.5MB
P00 INFO: execute exclusive pg_stop_backup() and wait for all WAL segments to archive P00 INFO: backup stop archive = 000000070000000000000019, lsn = 0/19000128 [filtered 4 lines of output]
Delete a Stanza
The
stanza-delete
command removes data in the repository associated with a stanza. Use this command with caution — it will permanently remove all backups and archives from the
pgBackRest
repository for the specified stanza.
To delete a stanza:
To delete a stanza:
- Shut down the PostgreSQL cluster associated with the stanza (or use --force to override).
- Run the stop command on the repository host.
- Run the stanza-delete command on the repository host.
pg-primary
⇒
Stop
PostgreSQL
cluster to be removed
sudo pg_ctlcluster 9.4 demo stop
pg-primary
⇒
Stop
pgBackRest
for the stanza
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info stop
P00 INFO: stop command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --repo1-cipher-type=none --repo1-path=/ --repo1-s3-bucket=demo-bucket --repo1-s3-endpoint=s3.amazonaws.com --repo1-s3-key=--repo1-s3-key-secret= --repo1-s3-region=us-east-1 --no-repo1-s3-verify-ssl --repo1-type=s3 --stanza=demo
P00 INFO: stop command end: completed successfully
pg-primary
⇒
Delete the stanza
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info stanza-delete
P00 INFO: stanza-delete command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-cipher-type=none --repo1-path=/ --repo1-s3-bucket=demo-bucket --repo1-s3-endpoint=s3.amazonaws.com --repo1-s3-key=--repo1-s3-key-secret= --repo1-s3-region=us-east-1 --no-repo1-s3-verify-ssl --repo1-type=s3 --stanza=demo
P00 INFO: stanza-delete command end: completed successfully
Dedicated Repository Host
The configuration described in
Quickstart
is suitable for simple installations but for enterprise configurations it is more typical to have a dedicated
repository
host where the backups and WAL archive files are stored. This separates the backups and WAL archive from the database server so
database
host failures have less impact. It is still a good idea to employ traditional backup software to backup the
repository
host.
Installation
A new host named
repository
is created to store the cluster backups.
The
pgbackrest
user is created to own the
pgBackRest
repository. Any user can own the repository but it is best not to use
postgres
(if it exists) to avoid confusion.
repository
⇒
Create
pgbackrest
sudo adduser --disabled-password --gecos "" pgbackrest
pgBackRest
is written in Perl which is included with Debian/Ubuntu by default. Some additional modules must also be installed but they are available as standard packages.
repository
⇒
Install required Perl packages
sudo apt-get install libdbd-pg-perl libio-socket-ssl-perl libxml-libxml-perl
Debian/Ubuntu packages for
pgBackRest
are available at
apt.postgresql.org
. If they are not provided for your distribution/version it is easy to download the source and install manually.
repository
⇒
Download version
2.01
of
pgBackRest
sudo wget -q -O - \ https://github.com/pgbackrest/pgbackrest/archive/release/2.01.tar.gz | \ sudo tar zx -C /root
repository
⇒
Install
pgBackRest
sudo cp -r /root/pgbackrest-release-2.01/lib/pgBackRest \ /usr/share/perl5
sudo find /usr/share/perl5/pgBackRest -type f -exec chmod 644 {} +
sudo find /usr/share/perl5/pgBackRest -type d -exec chmod 755 {} +
sudo mkdir -m 770 /var/log/pgbackrest
sudo chown pgbackrest:pgbackrest /var/log/pgbackrest
sudo touch /etc/pgbackrest.conf
sudo chmod 640 /etc/pgbackrest.conf
sudo chown pgbackrest:pgbackrest /etc/pgbackrest.conf
pgBackRest
requires a companion C library that enhances performance and enables the `checksum-page` option and encryption. Pre-built packages are generally a better option than building the C library manually but the steps required are given below for completeness. Depending on the distribution a number of packages may be required which will not be enumerated here.
repository
⇒
Build and Install C Library
sudo sh -c 'cd /root/pgbackrest-release-2.01/libc && \ perl Makefile.PL INSTALLMAN1DIR=none INSTALLMAN3DIR=none'
sudo make -C /root/pgbackrest-release-2.01/libc test
sudo make -C /root/pgbackrest-release-2.01/libc install
Although most of
pgBackRest
is written in Perl, the main executable is written in C. This allows certain time-critical commands (like async
archive-push
) to run more quickly.
repository
⇒
Build and Install Binary
sudo make -C /root/pgbackrest-release-2.01/src
sudo make -C /root/pgbackrest-release-2.01/src install
repository
⇒
Create the
pgBackRest
repository
sudo mkdir /var/lib/pgbackrest
sudo chmod 750 /var/lib/pgbackrest
sudo chown pgbackrest:pgbackrest /var/lib/pgbackrest
Setup Trusted SSH
pgBackRest
requires trusted (no password) SSH to enable communication between the hosts.
repository
⇒
Create
repository
host key pair
sudo -u pgbackrest mkdir -m 750 /home/pgbackrest/.ssh
sudo -u pgbackrest ssh-keygen -f /home/pgbackrest/.ssh/id_rsa \ -t rsa -b 4096 -N ""
pg-primary
⇒
Create
pg-primary
host key pair
sudo -u postgres mkdir -m 750 -p /home/postgres/.ssh
sudo -u postgres ssh-keygen -f /home/postgres/.ssh/id_rsa \ -t rsa -b 4096 -N ""
Exchange keys between
repository
and
pg-primary
.
repository
⇒
Copy
pg-primary
public key to
repository
sudo ssh root@pg-primary cat /home/postgres/.ssh/id_rsa.pub | \ sudo -u pgbackrest tee -a /home/pgbackrest/.ssh/authorized_keys
pg-primary
⇒
Copy
repository
public key to
pg-primary
sudo ssh root@repository cat /home/pgbackrest/.ssh/id_rsa.pub | \ sudo -u postgres tee -a /home/postgres/.ssh/authorized_keys
Test that connections can be made from
repository
to
pg-primary
and vice versa.
repository
⇒
Test connection from
repository
to
pg-primary
sudo -u pgbackrest ssh postgres@pg-primary
pg-primary
⇒
Test connection from
pg-primary
to
repository
sudo -u postgres ssh pgbackrest@repository
Configuration
The
repository
host must be configured with the
pg-primary
host/user and database path. The primary will be configured as
db1
to allow a standby to be added later.
repository
:
/etc/pgbackrest.conf
⇒
Configure
pg1-host
/
pg1-host-user
and
pg1-path
[demo]
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
[global]
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
The database host must be configured with the repository host/user. The default for the
repo1-host-user
option is
pgbackrest
. If the
postgres
user does restores on the repository host it is best not to also allow the
postgres
user to perform backups. However, the
postgres
user can read the repository directly if it is in the same group as the
pgbackrest
user.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure
repo1-host
/
repo1-host-user
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
log-level-file=detail
repo1-host=repository
pg1-path=/var/lib/postgresql/9.4/demo
[global]
log-level-file=detail
repo1-host=repository
Commands are run the same as on a single host configuration except that some commands such as
backup
and
expire
are run from the
repository
host instead of the
database
host.
Create the stanza in the new repository.
repository
⇒
Create the stanza
sudo -u pgbackrest pgbackrest --stanza=demo stanza-create
Check that the configuration is correct on both the
database
and
repository
hosts. More information about the
check
command can be found in
Check the Configuration
.
pg-primary
⇒
Check the configuration
sudo -u postgres pgbackrest --stanza=demo check
repository
⇒
Check the configuration
sudo -u pgbackrest pgbackrest --stanza=demo check
Perform a Backup
To perform a backup of the
PostgreSQL
cluster run
pgBackRest
with the
backup
command on the
repository
host.
repository
⇒
Backup the demo cluster
sudo -u pgbackrest pgbackrest --stanza=demo backup
P00 WARN: no prior backup exists, incr backup has been changed to full
Since a new repository was created on the
repository
host the warning about the incremental backup changing to a full backup was emitted.
Restore a Backup
To perform a restore of the
PostgreSQL
cluster run
pgBackRest
with the
restore
command on the
database
host.
pg-primary
⇒
Stop the demo cluster, restore, and restart
PostgreSQL
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta restore
sudo pg_ctlcluster 9.4 demo start
A new backup must be performed due to the timeline switch.
repository
⇒
Backup the demo cluster
sudo -u pgbackrest pgbackrest --stanza=demo backup
Asynchronous Archiving
The
archive-async
option offloads WAL archiving to a separate process (or processes) to improve throughput. It works by
looking aheadto see which WAL segments are ready to be archived beyond the request that PostgreSQL is currently making via the archive_command . WAL segments are transferred to the archive directly from the pg_xlog / pg_wal directory and success is only returned by the archive_command when the WAL segment has been safely stored in the archive.
The spool directory is created to hold the current status of WAL archiving. Status files written into the spool directory are typically zero length and should consume a minimal amount of space (a few MB at most) and very little IO. All the information in this directory can be recreated so it is not necessary to preserve the spool directory if the cluster is moved to new hardware.
NOTE:
In the original implementation of asynchronous archiving, WAL segments were copied to the spool directory before compression and transfer. The new implementation copies WAL directly from the
pg_xlog
directory. If asynchronous archiving was utilized in
v1.12
or prior, read the
v1.13
release notes carefully before upgrading.
pg-primary
⇒
Create the spool directory
sudo mkdir -m 750 /var/spool/pgbackrest
sudo chown postgres:postgres /var/spool/pgbackrest
The spool path must be configured and asynchronous archiving enabled. Asynchronous archiving automatically confers some benefit by reducing the number of ssh connections made to the backup server, but setting
process-max
can drastically improve performance. Be sure not to set
process-max
so high that it affects normal database operations.
pg-primary
:
/etc/pgbackrest.conf
⇒
Configure the spool path and asynchronous archiving
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
[global]
archive-async=y
log-level-file=detail
repo1-host=repository
spool-path=/var/spool/pgbackrest
[global:archive-push]
process-max=2
pg1-path=/var/lib/postgresql/9.4/demo
[global]
archive-async=y
log-level-file=detail
repo1-host=repository
spool-path=/var/spool/pgbackrest
[global:archive-push]
process-max=2
The
archive-async.log
file can be used to monitor the activity of the asynchronous process. A good way to test this is to quickly push a number of WAL segments.
pg-primary
⇒
Test parallel asynchronous archiving
sudo -u postgres psql -c " \ select pg_create_restore_point('test async push'); select pg_switch_xlog(); \ select pg_create_restore_point('test async push'); select pg_switch_xlog(); \ select pg_create_restore_point('test async push'); select pg_switch_xlog(); \ select pg_create_restore_point('test async push'); select pg_switch_xlog(); \ select pg_create_restore_point('test async push'); select pg_switch_xlog();"
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info check
P00 INFO: check command begin 2.01: --log-level-console=info --log-level-file=detail --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-host=repository --stanza=demo
P00 INFO: WAL segment 000000080000000000000026 successfully stored in the archive at '/var/lib/pgbackrest/archive/demo/9.4-1/0000000800000000/000000080000000000000026-9dd1f997ce8f9211974d215e29cf5a8b855d92b3.gz'
P00 INFO: check command end: completed successfully
Now the log file will contain parallel, asynchronous activity.
pg-primary
⇒
Check results in the log
sudo -u postgres cat /var/log/pgbackrest/demo-archive-async.log
-------------------PROCESS START------------------- P00 INFO: archive-push command begin 2.01: --archive-async --log-level-console=warn --log-level-file=detail --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --process-max=2 --repo1-host=repository --spool-path=/var/spool/pgbackrest --stanza=demo
P00 INFO: push 3 WAL file(s) to archive: 000000080000000000000021...000000080000000000000023 P02 DETAIL: pushed WAL file 000000080000000000000022 to archive P01 DETAIL: pushed WAL file 000000080000000000000021 to archive P02 DETAIL: pushed WAL file 000000080000000000000023 to archive
P00 INFO: archive-push command end: completed successfully -------------------PROCESS START------------------- P00 INFO: archive-push command begin 2.01: --archive-async --log-level-console=warn --log-level-file=detail --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --process-max=2 --repo1-host=repository --spool-path=/var/spool/pgbackrest --stanza=demo
P00 INFO: push 2 WAL file(s) to archive: 000000080000000000000024...000000080000000000000025 P02 DETAIL: pushed WAL file 000000080000000000000025 to archive P01 DETAIL: pushed WAL file 000000080000000000000024 to archive
P00 INFO: archive-push command end: completed successfully -------------------PROCESS START------------------- P00 INFO: archive-push command begin 2.01: --archive-async --log-level-console=warn --log-level-file=detail --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --process-max=2 --repo1-host=repository --spool-path=/var/spool/pgbackrest --stanza=demo
P00 INFO: push 1 WAL file(s) to archive: 000000080000000000000026 P01 DETAIL: pushed WAL file 000000080000000000000026 to archive
P00 INFO: archive-push command end: completed successfully
Parallel Backup / Restore
pgBackRest
offers parallel processing to improve performance of compression and transfer. The number of processes to be used for this feature is set using the
--process-max
option.
repository
⇒
Check the number of CPUs
sudo lscpu
Architecture: x86_64 CPU op-mode(s): 32-bit, 64-bit Byte Order: Little Endian
CPU(s): 8
On-line CPU(s) list: 0-7 Thread(s) per core: 1 [filtered 17 lines of output]
It is usually best not to use more than 25% of the available CPUs for the
backup
command. Backups don't have to run that fast as long as they are performed regularly and the backup process should not impact database performance, if at all possible.
The restore command can and should use all available CPUs because during a restore the
PostgreSQL
cluster is shut down and there is generally no other important work being done on the host. If the host contains multiple clusters then that should be considered when setting restore parallelism.
repository
⇒
Perform a backup with single process
sudo -u pgbackrest pgbackrest --stanza=demo --type=full backup
repository
:
/etc/pgbackrest.conf
⇒
Configure
pgBackRest
to use multiple
backup
processes
[demo]
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
[global]
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
[global]
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
repository
⇒
Perform a backup with multiple processes
sudo -u pgbackrest pgbackrest --stanza=demo --type=full backup
repository
⇒
Get backup info for the demo cluster
sudo -u pgbackrest pgbackrest info
stanza: demo status: ok db (current) wal archive min/max (9.4-1): 000000080000000000000028 / 000000080000000000000029 full backup: 20180320-001642F
timestamp start/stop: 2018-03-20 00:16:42 / 2018-03-20 00:16:50
wal start/stop: 000000080000000000000028 / 000000080000000000000028 database size: 25.5MB, backup size: 25.5MB repository size: 3MB, repository backup size: 3MB full backup: 20180320-001652F
timestamp start/stop: 2018-03-20 00:16:52 / 2018-03-20 00:16:59
wal start/stop: 000000080000000000000029 / 000000080000000000000029 database size: 25.5MB, backup size: 25.5MB repository size: 3MB, repository backup size: 3MB
The performance of the last backup should be improved by using multiple processes. For very small backups the difference may not be very apparent, but as the size of the database increases so will time savings.
Starting and Stopping
Sometimes it is useful to prevent
pgBackRest
from running on a system. For example, when failing over from a primary to a standby it's best to prevent
pgBackRest
from running on the old primary in case
PostgreSQL
gets restarted or can't be completely killed. This will also prevent
pgBackRest
from running on
cron
.
pg-primary
⇒
Stop the
pgBackRest
services
sudo -u postgres pgbackrest stop
New
pgBackRest
processes will no longer run.
repository
⇒
Attempt a backup
sudo -u pgbackrest pgbackrest --stanza=demo backup
P00 ERROR: [062]: raised from remote process on 'pg-primary': stop file exists for all stanzas
Specify the
--force
option to terminate any
pgBackRest
process that are currently running. If
pgBackRest
is already stopped then stopping again will generate a warning.
pg-primary
⇒
Stop the
pgBackRest
services again
sudo -u postgres pgbackrest stop
P00 WARN: stop file already exists for all stanzas
Start
pgBackRest
processes again with the
start
command.
pg-primary
⇒
Start the
pgBackRest
services
sudo -u postgres pgbackrest start
It is also possible to stop
pgBackRest
for a single stanza.
pg-primary
⇒
Stop
pgBackRest
services for the
demo
stanza
sudo -u postgres pgbackrest --stanza=demo stop
New
pgBackRest
processes for the specified stanza will no longer run.
repository
⇒
Attempt a backup
sudo -u pgbackrest pgbackrest --stanza=demo backup
P00 ERROR: [062]: raised from remote process on 'pg-primary': stop file exists for stanza demo
The stanza must also be specified when starting the
pgBackRest
processes for a single stanza.
pg-primary
⇒
Start the
pgBackRest
services for the
demo
stanza
sudo -u postgres pgbackrest --stanza=demo start
Replication
Replication allows multiple copies of a
PostgreSQL
cluster (called standbys) to be created from a single primary. The standbys are useful for balancing reads and to provide redundancy in case the primary host fails.
Installation
A new host named
pg-standby
is created to run the standby.
pgBackRest
is written in Perl which is included with Debian/Ubuntu by default. Some additional modules must also be installed but they are available as standard packages.
pg-standby
⇒
Install required Perl packages
sudo apt-get install libdbd-pg-perl libio-socket-ssl-perl libxml-libxml-perl
Debian/Ubuntu packages for
pgBackRest
are available at
apt.postgresql.org
. If they are not provided for your distribution/version it is easy to download the source and install manually.
pg-standby
⇒
Download version
2.01
of
pgBackRest
sudo wget -q -O - \ https://github.com/pgbackrest/pgbackrest/archive/release/2.01.tar.gz | \ sudo tar zx -C /root
pg-standby
⇒
Install
pgBackRest
sudo cp -r /root/pgbackrest-release-2.01/lib/pgBackRest \ /usr/share/perl5
sudo find /usr/share/perl5/pgBackRest -type f -exec chmod 644 {} +
sudo find /usr/share/perl5/pgBackRest -type d -exec chmod 755 {} +
sudo mkdir -m 770 /var/log/pgbackrest
sudo chown postgres:postgres /var/log/pgbackrest
sudo touch /etc/pgbackrest.conf
sudo chmod 640 /etc/pgbackrest.conf
sudo chown postgres:postgres /etc/pgbackrest.conf
pgBackRest
requires a companion C library that enhances performance and enables the `checksum-page` option and encryption. Pre-built packages are generally a better option than building the C library manually but the steps required are given below for completeness. Depending on the distribution a number of packages may be required which will not be enumerated here.
pg-standby
⇒
Build and Install C Library
sudo sh -c 'cd /root/pgbackrest-release-2.01/libc && \ perl Makefile.PL INSTALLMAN1DIR=none INSTALLMAN3DIR=none'
sudo make -C /root/pgbackrest-release-2.01/libc test
sudo make -C /root/pgbackrest-release-2.01/libc install
Although most of
pgBackRest
is written in Perl, the main executable is written in C. This allows certain time-critical commands (like async
archive-push
) to run more quickly.
pg-standby
⇒
Build and Install Binary
sudo make -C /root/pgbackrest-release-2.01/src
sudo make -C /root/pgbackrest-release-2.01/src install
Setup Trusted SSH
pgBackRest
requires trusted (no password) SSH to enable communication between the hosts.
pg-standby
⇒
Create
pg-standby
host key pair
sudo -u postgres mkdir -m 750 -p /home/postgres/.ssh
sudo -u postgres ssh-keygen -f /home/postgres/.ssh/id_rsa \ -t rsa -b 4096 -N ""
Exchange keys between
repository
and
pg-standby
.
repository
⇒
Copy
pg-standby
public key to
repository
sudo ssh root@pg-standby cat /home/postgres/.ssh/id_rsa.pub | \ sudo -u pgbackrest tee -a /home/pgbackrest/.ssh/authorized_keys
pg-standby
⇒
Copy
repository
public key to
pg-standby
sudo ssh root@repository cat /home/pgbackrest/.ssh/id_rsa.pub | \ sudo -u postgres tee -a /home/postgres/.ssh/authorized_keys
Test that connections can be made from
repository
to
pg-standby
and vice versa.
repository
⇒
Test connection from
repository
to
pg-standby
sudo -u pgbackrest ssh postgres@pg-standby
pg-standby
⇒
Test connection from
pg-standby
to
repository
sudo -u postgres ssh pgbackrest@repository
Hot Standby
A hot standby performs replication using the WAL archive and allows read-only queries.
pgBackRest
configuration is very similar to
pg-primary
except that the
standby_mode
setting will be enabled to keep the cluster in recovery mode when the end of the WAL stream has been reached.
pg-standby
:
/etc/pgbackrest.conf
⇒
Configure
pgBackRest
on the standby
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
recovery-option=standby_mode=on
[global]
repo1-host=repository
pg1-path=/var/lib/postgresql/9.4/demo
recovery-option=standby_mode=on
[global]
repo1-host=repository
The demo cluster must be created (even though it will be overwritten restore) in order to create the
PostgreSQL
configuration files.
pg-standby
⇒
Create demo cluster
sudo pg_createcluster 9.4 demo
Now the standby can be created with the
restore
command.
pg-standby
⇒
Restore the demo standby cluster
sudo -u postgres pgbackrest --stanza=demo --delta restore
sudo -u postgres cat /var/lib/postgresql/9.4/demo/recovery.conf
standby_mode = 'on' restore_command = 'pgbackrest --stanza=demo archive-get %f "%p"'
Note that the
standby_mode
setting has been written into the
recovery.conf
file. Configuring recovery settings in
pgBackRest
means that the
recovery.conf
file does not need to be stored elsewhere since it will be properly recreated with each restore. The
--type=preserve
option can be used with the
restore
to leave the existing
recovery.conf
file in place if that behavior is preferred.
The
hot_standby
setting must be enabled before starting
PostgreSQL
to allow read-only connections on
pg-standby
. Otherwise, connection attempts will be refused.
pg-standby
:
/etc/postgresql/9.4/demo/postgresql.conf
⇒
Enable
hot_standby
and configure logging
hot_standby = on
log_filename = 'postgresql.log'
log_line_prefix = ''
log_filename = 'postgresql.log'
log_line_prefix = ''
pg-standby
⇒
Start
PostgreSQL
sudo pg_ctlcluster 9.4 demo start
The
PostgreSQL
log gives valuable information about the recovery. Note especially that the cluster has entered standby mode and is ready to accept read-only connections.
pg-standby
⇒
Examine the
PostgreSQL
log output for log messages indicating success
sudo -u postgres cat /var/log/postgresql/postgresql-9.4-demo.log
LOG: could not bind IPv6 socket: Cannot assign requested address HINT: Is another postmaster already running on port 5432? If not, wait a few seconds and retry. LOG: database system was interrupted; last known up at 2018-03-20 00:16:53 UTC
LOG: entering standby mode
LOG: restored log file "00000008.history" from archive LOG: incomplete startup packet LOG: restored log file "000000080000000000000029" from archive LOG: redo starts at 0/29000028 LOG: consistent recovery state reached at 0/29000128
LOG: database system is ready to accept read only connections
An easy way to test that replication is properly configured is to create a table on
pg-primary
.
pg-primary
⇒
Create a new table on the primary
sudo -u postgres psql -c " \ begin; \ create table replicated_table (message text); \ insert into replicated_table values ('Important Data'); \ commit; \ select * from replicated_table";
message ----------------
Important Data
(1 row)
And then query the same table on
pg-standby
.
pg-standby
⇒
Query new table on the standby
sudo -u postgres psql -c "select * from replicated_table;"
ERROR: relation "replicated_table" does not exist
LINE 1: select * from replicated_table; ^
So, what went wrong? Since
PostgreSQL
is pulling WAL segments from the archive to perform replication, changes won't be seen on the standby until the WAL segment that contains those changes is pushed from
pg-primary
.
This can be done manually by calling
pg_switch_xlog()
which pushes the current WAL segment to the archive (a new WAL segment is created to contain further changes).
pg-primary
⇒
Call
pg_switch_xlog()
sudo -u postgres psql -c "select *, current_timestamp from pg_switch_xlog()";
pg_switch_xlog | now ----------------+------------------------------- 0/2A0199E0 | 2018-03-20 00:17:28.430251+00 (1 row)
Now after a short delay the table will appear on
pg-standby
.
pg-standby
⇒
Now the new table exists on the standby (may require a few retries)
sudo -u postgres psql -c " \ select *, current_timestamp from replicated_table"
message | now ----------------+-------------------------------
Important Data | 2018-03-20 00:17:34.988692+00
(1 row)
Check the standby configuration for access to the repository.
pg-standby
⇒
Check the configuration
sudo -u postgres pgbackrest --stanza=demo --log-level-console=info check
P00 INFO: check command begin 2.01: --log-level-console=info --log-level-stderr=off --no-log-timestamp --pg1-path=/var/lib/postgresql/9.4/demo --repo1-host=repository --stanza=demo
P00 INFO: switch xlog cannot be performed on the standby, all other checks passed successfully
P00 INFO: check command end: completed successfully
Streaming Replication
Instead of relying solely on the WAL archive, streaming replication makes a direct connection to the primary and applies changes as soon as they are made on the primary. This results in much less lag between the primary and standby.
Streaming replication requires a user with the replication privilege.
pg-primary
⇒
Create replication user
sudo -u postgres psql -c " \ create user replicator password 'jw8s0F4' replication";
CREATE ROLE
The
pg_hba.conf
file must be updated to allow the standby to connect as the replication user. Be sure to replace the IP address below with the actual IP address of your
pg-primary
. A reload will be required after modifying the
pg_hba.conf
file.
pg-primary
⇒
Create
pg_hba.conf
entry for replication user
sudo -u postgres sh -c 'echo \ "host replication replicator 172.17.0.5/32 md5" \ >> /etc/postgresql/9.4/demo/pg_hba.conf'
sudo pg_ctlcluster 9.4 demo reload
The standby needs to know how to contact the primary so the
primary_conninfo
setting will be configured in
pgBackRest
.
pg-standby
:
/etc/pgbackrest.conf
⇒
Set
primary_conninfo
[demo]
pg1-path=/var/lib/postgresql/9.4/demo
recovery-option=standby_mode=on
recovery-option=primary_conninfo=host=172.17.0.3 port=5432 user=replicator
[global]
repo1-host=repository
pg1-path=/var/lib/postgresql/9.4/demo
recovery-option=standby_mode=on
recovery-option=primary_conninfo=host=172.17.0.3 port=5432 user=replicator
[global]
repo1-host=repository
It is possible to configure a password in the
primary_conninfo
setting but using a
.pgpass
file is more flexible and secure.
pg-standby
⇒
Configure the replication password in the
.pgpass
file.
sudo -u postgres sh -c 'echo \ "172.17.0.3:*:replication:replicator:jw8s0F4" \ >> /home/postgres/.pgpass'
sudo -u postgres chmod 600 /home/postgres/.pgpass
Now the standby can be created with the
restore
command.
pg-standby
⇒
Stop
PostgreSQL
and restore the demo standby cluster
sudo pg_ctlcluster 9.4 demo stop
sudo -u postgres pgbackrest --stanza=demo --delta restore
sudo -u postgres cat /var/lib/postgresql/9.4/demo/recovery.conf
primary_conninfo = 'host=172.17.0.3 port=5432 user=replicator' standby_mode = 'on' restore_command = 'pgbackrest --stanza=demo archive-get %f "%p"'
pg-standby
⇒
Start
PostgreSQL
sudo pg_ctlcluster 9.4 demo start
The
PostgreSQL
log will confirm that streaming replication has started.
pg-standby
⇒
Examine the
PostgreSQL
log output for log messages indicating success
sudo -u postgres cat /var/log/postgresql/postgresql-9.4-demo.log
[filtered 9 lines of output] LOG: database system is ready to accept read only connections LOG: restored log file "00000008000000000000002A" from archive
LOG: started streaming WAL from primary at 0/2B000000 on timeline 8
Now when a table is created on
pg-primary
it will appear on
pg-standby
quickly and without the need to call
pg_switch_xlog()
.
pg-primary
⇒
Create a new table on the primary
sudo -u postgres psql -c " \ begin; \ create table stream_table (message text); \ insert into stream_table values ('Important Data'); \ commit; \ select *, current_timestamp from stream_table";
message | now ----------------+-------------------------------
Important Data | 2018-03-20 00:17:46.077739+00
(1 row)
pg-standby
⇒
Query table on the standby
sudo -u postgres psql -c " \ select *, current_timestamp from stream_table"
message | now ----------------+-------------------------------
Important Data | 2018-03-20 00:17:46.333002+00
(1 row)
Backup from a Standby
pgBackRest
can perform backups on a standby instead of the primary. Standby backups require the
pg-standby
host to be configured and the
backup-standby
option enabled. If more than one standby is configured then the first running standby found will be used for the backup.
repository
:
/etc/pgbackrest.conf
⇒
Configure
pg2-host
/
pg2-host-user
and
pg2-path
[demo]
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.4/demo
[global]
backup-standby=y
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.4/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.4/demo
[global]
backup-standby=y
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
Both the primary and standby databases are required to perform the backup, though the vast majority of the files will be copied from the standby to reduce load on the primary. The database hosts can be configured in any order.
pgBackRest
will automatically determine which is the primary and which is the standby.
repository
⇒
Backup the demo cluster from
pg2
sudo -u pgbackrest pgbackrest --stanza=demo --log-level-console=detail backup
[filtered 2 lines of output] P00 INFO: execute exclusive pg_start_backup() with label "pgBackRest backup started at 2018-03-20 00:17:47": backup begins after the requested immediate checkpoint completes P00 INFO: backup start archive = 00000008000000000000002C, lsn = 0/2C0000C8
P00 INFO: wait for replay on the standby to reach 0/2C0000C8 P00 INFO: replay on the standby reached 0/2C000168
P02 INFO: backup file pg-standby:/var/lib/postgresql/9.4/demo/base/12139/12007 (392KB, 20%) checksum bc70f685fbac13fe44177419cd01f86b4fa93165
P01 INFO: backup file pg-primary:/var/lib/postgresql/9.4/demo/global/pg_control (8KB, 20%) checksum 3527ba100189801ef33ed2c69c4e960e25065016
P02 INFO: backup file pg-standby:/var/lib/postgresql/9.4/demo/base/12139/12010 (232KB, 32%) checksum 7942be329b7fd64c7b84de7c5d9f17cde491c7dd
P01 INFO: backup file pg-primary:/var/lib/postgresql/9.4/demo/backup_label (238B, 32%) checksum cacb1ae43120aaae237e7dfeb0b91bb8cf262dc9
P02 INFO: backup file pg-standby:/var/lib/postgresql/9.4/demo/base/12139/11891 (128KB, 39%) checksum cd83363e762186bf64d2867a3a7a55b359dbcfbb P02 INFO: backup file pg-standby:/var/lib/postgresql/9.4/demo/base/12139/11892 (88KB, 43%) checksum 48841ee2c6fcee738cf9bcb10d4c93a325fb2fc7 [filtered 33 lines of output]
This incremental backup shows that most of the files are copied from the
pg-standby
host and only a few are copied from the
pg-primary
host.
pgBackRest
creates a standby backup that is identical to a backup performed on the primary. It does this by starting/stopping the backup on the
pg-primary
host, copying only files that are replicated from the
pg-standby
host, then copying the remaining few files from the
pg-primary
host. This means that logs and statistics from the primary database will be included in the backup.
Upgrading PostgreSQL
Immediately after upgrading
PostgreSQL
to a newer major version, the
pg-path
for all
pgBackRest
configurations must be set to the new database location and the
stanza-upgrade
run on the repository host. If the database is offline use the
--no-online
option.
The following instructions are not meant to be a comprehensive guide for upgrading
PostgreSQL
, rather they outline the general process for upgrading a primary and standby with the intent of demonstrating the steps required to reconfigure
pgBackRest
. It is recommended that a backup be taken prior to upgrading.
pg-primary
⇒
Stop old cluster and install new
PostgreSQL
version
sudo pg_ctlcluster 9.4 demo stop
sudo apt-get install postgresql-9.5
Stop the old cluster on the standby since it will be restored from the newly upgraded cluster.
pg-standby
⇒
Stop old cluster and install new
PostgreSQL
version
sudo pg_ctlcluster 9.4 demo stop
sudo apt-get install postgresql-9.5
Create the new cluster and perform upgrade.
pg-primary
⇒
Create new cluster and perform the upgrade
sudo -u postgres /usr/lib/postgresql/9.5/bin/initdb \ -D /var/lib/postgresql/9.5/demo -k -A peer
sudo pg_createcluster 9.5 demo
sudo -u postgres sh -c 'cd /var/lib/postgresql && \ /usr/lib/postgresql/9.5/bin/pg_upgrade \ --old-bindir=/usr/lib/postgresql/9.4/bin \ --new-bindir=/usr/lib/postgresql/9.5/bin \ --old-datadir=/var/lib/postgresql/9.4/demo \ --new-datadir=/var/lib/postgresql/9.5/demo \ --old-options=" -c config_file=/etc/postgresql/9.4/demo/postgresql.conf" \ --new-options=" -c config_file=/etc/postgresql/9.5/demo/postgresql.conf"'
[filtered 68 lines of output] Creating script to delete old cluster ok
Upgrade Complete
---------------- Optimizer statistics are not transferred by pg_upgrade so, [filtered 4 lines of output]
Configure the new cluster settings and port.
pg-primary
:
/etc/postgresql/9.5/demo/postgresql.conf
⇒
Configure
PostgreSQL
archive_command = 'pgbackrest --stanza=demo archive-push %p'
archive_mode = on
listen_addresses = '*'
log_line_prefix = ''
max_wal_senders = 3
port = 5432
wal_level = hot_standby
archive_mode = on
listen_addresses = '*'
log_line_prefix = ''
max_wal_senders = 3
port = 5432
wal_level = hot_standby
Update the
pgBackRest
configuration on all systems to point to the new cluster.
pg-primary
:
/etc/pgbackrest.conf
⇒
Upgrade the
pg1-path
[demo]
pg1-path=/var/lib/postgresql/9.5/demo
[global]
archive-async=y
log-level-file=detail
repo1-host=repository
spool-path=/var/spool/pgbackrest
[global:archive-push]
process-max=2
pg1-path=/var/lib/postgresql/9.5/demo
[global]
archive-async=y
log-level-file=detail
repo1-host=repository
spool-path=/var/spool/pgbackrest
[global:archive-push]
process-max=2
pg-standby
:
/etc/pgbackrest.conf
⇒
Upgrade the
pg-path
[demo]
pg1-path=/var/lib/postgresql/9.5/demo
recovery-option=standby_mode=on
recovery-option=primary_conninfo=host=172.17.0.3 port=5432 user=replicator
[global]
repo1-host=repository
pg1-path=/var/lib/postgresql/9.5/demo
recovery-option=standby_mode=on
recovery-option=primary_conninfo=host=172.17.0.3 port=5432 user=replicator
[global]
repo1-host=repository
repository
:
/etc/pgbackrest.conf
⇒
Upgrade
pg1-path
and
pg2-path
, disable backup from standby
[demo]
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.5/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.5/demo
[global]
backup-standby=n
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.5/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.5/demo
[global]
backup-standby=n
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg-primary
⇒
Copy hba configuration
sudo cp /etc/postgresql/9.4/demo/pg_hba.conf \ /etc/postgresql/9.5/demo/pg_hba.conf
Before starting the new cluster, the
stanza-upgrade
command must be run on the server where the
pgBackRest
repository is located.
repository
⇒
Upgrade the stanza
sudo -u pgbackrest pgbackrest --stanza=demo --no-online \ --log-level-console=info stanza-upgrade
P00 INFO: stanza-upgrade command begin 2.01: --no-backup-standby --log-level-console=info --log-level-stderr=off --no-log-timestamp --no-online --pg1-host=pg-primary --pg2-host=pg-standby --pg1-host-user=postgres --pg2-host-user=postgres --pg1-path=/var/lib/postgresql/9.5/demo --pg2-path=/var/lib/postgresql/9.5/demo --repo1-path=/var/lib/pgbackrest --stanza=demo
P00 INFO: stanza-upgrade command end: completed successfully
Start the new cluster and confirm it is successfully installed.
pg-primary
⇒
Start new cluster
sudo pg_ctlcluster 9.5 demo start
Test configuration using the
check
command.
pg-primary
⇒
Check configuration
sudo -u postgres pg_lsclusters
Ver Cluster Port Status Owner Data directory Log file 9.4 demo 5432 down postgres /var/lib/postgresql/9.4/demo /var/log/postgresql/postgresql-9.4-demo.log 9.5 demo 5432 online postgres /var/lib/postgresql/9.5/demo /var/log/postgresql/postgresql-9.5-demo.log
sudo -u postgres pgbackrest --stanza=demo check
Remove the old cluster.
pg-primary
⇒
Remove old cluster
sudo pg_dropcluster 9.4 demo
Install the new
PostgreSQL
binaries on the standby and create the cluster.
pg-standby
⇒
Remove old cluster and create the new cluster
sudo pg_dropcluster 9.4 demo
sudo pg_createcluster 9.5 demo
Run the
check
on the repository host. The warning regarding the standby being down is expected since the standby cluster is down. Running this command demonstrates that the repository server is aware of the standby and is configured properly for the primary server.
repository
⇒
Check configuration
sudo -u pgbackrest pgbackrest --stanza=demo check
P00 WARN: [056]: raised from remote process on 'pg-standby': could not connect to server: No such file or directory Is the server running locally and accepting connections on Unix domain socket "/var/run/postgresql/.s.PGSQL.5432"?
Run a full backup on the new cluster and then restore the standby from the backup. The backup type will automatically be changed to
full
if
incr
or
diff
is requested.
repository
⇒
Run a full backup
sudo -u pgbackrest pgbackrest --stanza=demo --type=full backup
pg-standby
⇒
Restore the demo standby cluster
sudo -u postgres pgbackrest --stanza=demo --delta restore
pg-standby
:
/etc/postgresql/9.5/demo/postgresql.conf
⇒
Configure
PostgreSQL
hot_standby = on
pg-standby
⇒
Start
PostgreSQL
and check the
pgBackRest
configuration
sudo pg_ctlcluster 9.5 demo start
sudo -u postgres pgbackrest --stanza=demo check
Backup from standby can be enabled now that the standby is restored.
repository
:
/etc/pgbackrest.conf
⇒
Reenable backup from standby
[demo]
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.5/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.5/demo
[global]
backup-standby=y
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y
pg1-host=pg-primary
pg1-host-user=postgres
pg1-path=/var/lib/postgresql/9.5/demo
pg2-host=pg-standby
pg2-host-user=postgres
pg2-path=/var/lib/postgresql/9.5/demo
[global]
backup-standby=y
process-max=3
repo1-path=/var/lib/pgbackrest
repo1-retention-full=2
start-fast=y