gitlab-org--gitlab-foss/doc/administration/geo/replication/multiple_servers.md

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Geo for multiple nodes (PREMIUM SELF)

This document describes a minimal reference architecture for running Geo in a multi-node configuration. If your multi-node setup differs from the one described, it is possible to adapt these instructions to your needs.

Architecture overview

Geo multi-node diagram

diagram source - GitLab employees only

The topology above assumes the primary and secondary Geo sites are located in two separate locations, on their own virtual network with private IP addresses. The network is configured such that all machines in one geographic location can communicate with each other using their private IP addresses. The IP addresses given are examples and may be different depending on the network topology of your deployment.

The only external way to access the two Geo sites is by HTTPS at gitlab.us.example.com and gitlab.eu.example.com in the example above.

NOTE: The primary and secondary Geo sites must be able to communicate to each other over HTTPS.

Redis and PostgreSQL for multiple nodes

Because of the additional complexity involved in setting up this configuration for PostgreSQL and Redis, it is not covered by this Geo multi-node documentation.

For more information on setting up a multi-node PostgreSQL cluster and Redis cluster using the Omnibus GitLab package, see:

NOTE: It is possible to use cloud hosted services for PostgreSQL and Redis, but this is beyond the scope of this document.

Prerequisites: Two independently working GitLab multi-node sites

One GitLab site serves as the Geo primary site. Use the GitLab reference architectures documentation to set this up. You can use different reference architecture sizes for each Geo site. If you already have a working GitLab instance that is in-use, it can be used as a primary site.

The second GitLab site serves as the Geo secondary site. Again, use the GitLab reference architectures documentation to set this up. It's a good idea to log in and test it. However, be aware that its data is wiped out as part of the process of replicating from the primary site.

Configure a GitLab site to be the Geo primary site

The following steps enable a GitLab site to serve as the Geo primary site.

Step 1: Configure the primary frontend nodes

  1. Edit /etc/gitlab/gitlab.rb and add the following:

    ##
    ## The unique identifier for the Geo site. It's recommended to use a
    ## physical location as a name, for example "us-east", instead of
    ## "secondary" or "geo". It's case-sensitive, and most characters are
    ## allowed. It should be the same for all nodes in a Geo site.
    ##
    gitlab_rails['geo_node_name'] = '<node_name_here>'
    
    ##
    ## Disable automatic migrations
    ##
    gitlab_rails['auto_migrate'] = false
    

After making these changes, reconfigure GitLab so the changes take effect.

NOTE: PostgreSQL and Redis should have already been disabled on the application nodes during normal GitLab multi-node setup. Connections from the application nodes to services on the backend nodes should have also been configured. See multi-node configuration documentation for PostgreSQL and Redis.

Configure the other GitLab site to be a Geo secondary site

A secondary site is similar to any other GitLab multi-node site, with three major differences:

  • The main PostgreSQL database is a read-only replica of the Geo primary site's PostgreSQL database.
  • There is an additional PostgreSQL database for each Geo secondary site, called the "Geo tracking database", which tracks the replication and verification state of various resources.
  • There is an additional GitLab service geo-logcursor

Therefore, we set up the multi-node components one by one and include deviations from the normal multi-node setup. However, we highly recommend configuring a brand-new GitLab site first, as if it were not part of a Geo setup. This allows verifying that it is a working GitLab site. And only then should it be modified for use as a Geo secondary site. This helps to separate Geo setup problems from unrelated multi-node configuration problems.

Step 1: Configure the Redis and Gitaly services on the Geo secondary site

Configure the following services, again using the non-Geo multi-node documentation:

NOTE: NFS can be used in place of Gitaly but is not recommended.

Step 2: Configure Postgres streaming replication

Follow the Geo database replication instructions.

If using an external PostgreSQL instance, refer also to Geo with external PostgreSQL instances.

Step 3: Configure the Geo tracking database on the Geo secondary site

If you want to run the Geo tracking database in a multi-node PostgreSQL cluster, then follow Configuring Patroni cluster for the tracking PostgreSQL database.

If you want to run the Geo tracking database on a single node, then follow the instructions below.

  1. Generate an MD5 hash of the desired password for the database user that the GitLab application uses to access the tracking database:

    The username (gitlab_geo by default) is incorporated into the hash.

    gitlab-ctl pg-password-md5 gitlab_geo
    # Enter password: <your_password_here>
    # Confirm password: <your_password_here>
    # fca0b89a972d69f00eb3ec98a5838484
    

    Use this hash to fill in <tracking_database_password_md5_hash> in the next step.

  2. On the machine where the Geo tracking database is intended to run, add the following to /etc/gitlab/gitlab.rb:

    ##
    ## Enable the Geo secondary tracking database
    ##
    geo_postgresql['enable'] = true
    geo_postgresql['listen_address'] = '<ip_address_of_this_host>'
    geo_postgresql['sql_user_password'] = '<tracking_database_password_md5_hash>'
    
    ##
    ## Configure PostgreSQL connection to the replica database
    ##
    geo_postgresql['md5_auth_cidr_addresses'] = ['<replica_database_ip>/32']
    gitlab_rails['db_host'] = '<replica_database_ip>'
    
    # Prevent reconfigure from attempting to run migrations on the replica database
    gitlab_rails['auto_migrate'] = false
    

After making these changes, reconfigure GitLab so the changes take effect.

If using an external PostgreSQL instance, refer also to Geo with external PostgreSQL instances.

Step 4: Configure the frontend application nodes on the Geo secondary site

In the minimal architecture diagram above, there are two machines running the GitLab application services. These services are enabled selectively in the configuration.

Configure the GitLab Rails application nodes following the relevant steps outlined in the reference architectures, then make the following modifications:

  1. Edit /etc/gitlab/gitlab.rb on each application node in the Geo secondary site, and add the following:

    ##
    ## Enable GitLab application services. The application_role enables many services.
    ## Alternatively, you can choose to enable or disable specific services on
    ## different nodes to aid in horizontal scaling and separation of concerns.
    ##
    roles ['application_role']
    
    ## `application_role` already enables this. You only need this line if
    ## you selectively enable individual services that depend on Rails, like
    ## `puma`, `sidekiq`, `geo-logcursor`, etc.
    gitlab_rails['enable'] = true
    
    ##
    ## Enable Geo Log Cursor service
    ##
    geo_logcursor['enable'] = true
    
    ##
    ## The unique identifier for the Geo site. It's recommended to use a
    ## physical location as a name, for example "eu-west", instead of
    ## "secondary" or "geo". It's case-sensitive, and most characters are
    ## allowed. It should be the same for all nodes in a Geo site.
    ##
    gitlab_rails['geo_node_name'] = '<node_name_here>'
    
    ##
    ## Disable automatic migrations
    ##
    gitlab_rails['auto_migrate'] = false
    
    ##
    ## Configure the connection to the tracking database
    ##
    geo_secondary['enable'] = true
    geo_secondary['db_host'] = '<geo_tracking_db_host>'
    geo_secondary['db_password'] = '<geo_tracking_db_password>'
    
    ##
    ## Configure connection to the streaming replica database, if you haven't
    ## already
    ##
    gitlab_rails['db_host'] = '<replica_database_host>'
    gitlab_rails['db_password'] = '<replica_database_password>'
    
    ##
    ## Configure connection to Redis, if you haven't already
    ##
    gitlab_rails['redis_host'] = '<redis_host>'
    gitlab_rails['redis_password'] = '<redis_password>'
    
    ##
    ## If you are using custom users not managed by Omnibus, you need to specify
    ## UIDs and GIDs like below, and ensure they match between nodes in a
    ## cluster to avoid permissions issues
    ##
    user['uid'] = 9000
    user['gid'] = 9000
    web_server['uid'] = 9001
    web_server['gid'] = 9001
    registry['uid'] = 9002
    registry['gid'] = 9002
    

NOTE: If you had set up PostgreSQL cluster using the omnibus package and had set postgresql['sql_user_password'] = 'md5 digest of secret', keep in mind that gitlab_rails['db_password'] and geo_secondary['db_password'] contains the plaintext passwords. This is used to let the Rails nodes connect to the databases.

NOTE: Make sure that current node's IP is listed in postgresql['md5_auth_cidr_addresses'] setting of the read-replica database to allow Rails on this node to connect to Postgres.

After making these changes Reconfigure GitLab so the changes take effect.

In the architecture overview topology, the following GitLab services are enabled on the "frontend" nodes:

  • geo-logcursor
  • gitlab-pages
  • gitlab-workhorse
  • logrotate
  • nginx
  • registry
  • remote-syslog
  • sidekiq
  • puma

Verify these services exist by running sudo gitlab-ctl status on the frontend application nodes.

Step 5: Set up the LoadBalancer for the Geo secondary site

The minimal architecture diagram above shows a load balancer at each geographic location to route traffic to the application nodes.

See Load Balancer for GitLab with multiple nodes for more information.

Step 6: Configure the backend application nodes on the Geo secondary site

The minimal architecture diagram above shows all application services running together on the same machines. However, for multiple nodes we strongly recommend running all services separately.

For example, a Sidekiq node could be configured similarly to the frontend application nodes above, with some changes to run only the sidekiq service:

  1. Edit /etc/gitlab/gitlab.rb on each Sidekiq node in the Geo secondary site, and add the following:

    ##
    ## Enable the Sidekiq service
    ##
    sidekiq['enable'] = true
    gitlab_rails['enable'] = true
    
    ##
    ## The unique identifier for the Geo site. It's recommended to use a
    ## physical location as a name, for example "eu-west", instead of
    ## "secondary" or "geo". It's case-sensitive, and most characters are
    ## allowed. It should be the same for all nodes in a Geo site.
    ##
    gitlab_rails['geo_node_name'] = '<node_name_here>'
    
    ##
    ## Disable automatic migrations
    ##
    gitlab_rails['auto_migrate'] = false
    
    ##
    ## Configure the connection to the tracking database
    ##
    geo_secondary['enable'] = true
    geo_secondary['db_host'] = '<geo_tracking_db_host>'
    geo_secondary['db_password'] = '<geo_tracking_db_password>'
    
    ##
    ## Configure connection to the streaming replica database, if you haven't
    ## already
    ##
    gitlab_rails['db_host'] = '<replica_database_host>'
    gitlab_rails['db_password'] = '<replica_database_password>'
    
    ##
    ## Configure connection to Redis, if you haven't already
    ##
    gitlab_rails['redis_host'] = '<redis_host>'
    gitlab_rails['redis_password'] = '<redis_password>'
    
    ##
    ## If you are using custom users not managed by Omnibus, you need to specify
    ## UIDs and GIDs like below, and ensure they match between nodes in a
    ## cluster to avoid permissions issues
    ##
    user['uid'] = 9000
    user['gid'] = 9000
    web_server['uid'] = 9001
    web_server['gid'] = 9001
    registry['uid'] = 9002
    registry['gid'] = 9002
    

    You can similarly configure a node to run only the geo-logcursor service with geo_logcursor['enable'] = true and disabling Sidekiq with sidekiq['enable'] = false.

    These nodes do not need to be attached to the load balancer.