Reference architecture: Up to 40 RPS or 2,000 users
DETAILS: Tier: Free, Premium, Ultimate Offering: Self-managed
This page describes the GitLab reference architecture designed to target a peak load of 40 requests per second (RPS), the typical peak load of up to 2,000 users, both manual and automated, based on real data.
For a full list of reference architectures, see Available reference architectures.
- Target Load: API: 40 RPS, Web: 4 RPS, Git (Pull): 4 RPS, Git (Push): 1 RPS
- High Availability: No. For a highly-available environment, you can follow a modified 3K or 60 RPS reference architecture.
- Cost calculator template: See cost calculator templates section
- Cloud Native Hybrid: Yes
- Unsure which Reference Architecture to use? Go to this guide for more info.
Service | Nodes | Configuration | GCP | AWS | Azure |
---|---|---|---|---|---|
External Load balancer3 | 1 | 4 vCPU, 3.6 GB memory | n1-highcpu-4 |
c5n.xlarge |
F4s v2 |
PostgreSQL1 | 1 | 2 vCPU, 7.5 GB memory | n1-standard-2 |
m5.large |
D2s v3 |
Redis2 | 1 | 1 vCPU, 3.75 GB memory | n1-standard-1 |
m5.large |
D2s v3 |
Gitaly5 | 1 | 4 vCPU, 15 GB memory5 | n1-standard-4 |
m5.xlarge |
D4s v3 |
Sidekiq6 | 1 | 4 vCPU, 15 GB memory | n1-standard-4 |
m5.xlarge |
D4s v3 |
GitLab Rails6 | 2 | 8 vCPU, 7.2 GB memory | n1-highcpu-8 |
c5.2xlarge |
F8s v2 |
Monitoring node | 1 | 2 vCPU, 1.8 GB memory | n1-highcpu-2 |
c5.large |
F2s v2 |
Object storage4 | - | - | - | - | - |
Footnotes:
- Can be optionally run on reputable third-party external PaaS PostgreSQL solutions. See Provide your own PostgreSQL instance and Recommended cloud providers and services for more information.
- Can be optionally run on reputable third-party external PaaS Redis solutions. See Provide your own Redis instance and Recommended cloud providers and services for more information.
- Recommended to be run with a reputable third-party load balancer or service (LB PaaS). Also note that sizing depends on selected Load Balancer as well as additional factors such as Network Bandwidth. Refer to Load Balancers for more information.
- Should be run on reputable Cloud Provider or Self Managed solutions. See Configure the object storage for more information.
- Gitaly specifications are based on the use of normal-sized repositories in good health. However, if you have large monorepos (larger than several gigabytes) this can significantly impact Git and Gitaly performance and an increase of specifications will likely be required. Refer to large monorepos for more information.
- Can be placed in Auto Scaling Groups (ASGs) as the component doesn't store any stateful data. However, Cloud Native Hybrid setups are generally preferred as certain components such as like migrations and Mailroom can only be run on one node, which is handled better in Kubernetes.
NOTE: For all PaaS solutions that involve configuring instances, it's recommended to deploy them over multiple availability zones for resilience if desired.
@startuml 2k
skinparam linetype ortho
card "**External Load Balancer**" as elb #6a9be7
together {
collections "**GitLab Rails** x2" as gitlab #32CD32
card "**Sidekiq**" as sidekiq #ff8dd1
}
card "**Prometheus**" as monitor #7FFFD4
card "**Gitaly**" as gitaly #FF8C00
card "**PostgreSQL**" as postgres #4EA7FF
card "**Redis**" as redis #FF6347
cloud "**Object Storage**" as object_storage #white
elb -[#6a9be7]-> gitlab
elb -[#6a9be7]--> monitor
gitlab -[#32CD32]--> gitaly
gitlab -[#32CD32]--> postgres
gitlab -[#32CD32]-> object_storage
gitlab -[#32CD32]--> redis
sidekiq -[#ff8dd1]r-> object_storage
sidekiq -[#ff8dd1]----> redis
sidekiq .[#ff8dd1]----> postgres
sidekiq -[hidden]-> monitor
monitor .[#7FFFD4]u-> gitlab
monitor .[#7FFFD4]-> gitaly
monitor .[#7FFFD4]-> postgres
monitor .[#7FFFD4,norank]--> redis
monitor .[#7FFFD4,norank]u--> elb
monitor .[#7FFFD4]u-> sidekiq
@enduml
Requirements
Before starting, see the requirements for reference architectures.
Testing methodology
The 2k architecture is designed to cover a large majority of workflows and is regularly smoke and performance tested by the Test Platform team against the following endpoint throughput targets:
- API: 40 RPS
- Web: 4 RPS
- Git (Pull): 4 RPS
- Git (Push): 1 RPS
The above targets were selected based on real customer data of total environmental loads corresponding to the user count, including CI and other workloads.
If you have metrics to suggest that you have regularly higher throughput against the above endpoint targets, large monorepos or notable additional workloads these can notably impact the performance environment and further adjustments may be required. If this applies to you, we strongly recommended referring to the linked documentation as well as reaching out to your Customer Success Manager or our Support team for further guidance.
Testing is done regularly via our GitLab Performance Tool (GPT) and its dataset, which is available for anyone to use. The results of this testing are available publicly on the GPT wiki. For more information on our testing strategy refer to this section of the documentation.
The load balancers used for testing were HAProxy for Linux package environments or equivalent Cloud Provider services via NGINX Ingress for Cloud Native Hybrids. Note that these selections do not represent a specific requirement or recommendation as most reputable load balancers are expected to work.
Set up components
To set up GitLab and its components to accommodate up to 40 RPS or 2,000 users:
- Configure the external load balancing node to handle the load balancing of the GitLab application services nodes.
- Configure PostgreSQL, the database for GitLab.
- Configure Redis.
- Configure Gitaly, which provides access to the Git repositories.
- Configure the main GitLab Rails application to run Puma, Workhorse, GitLab Shell, and to serve all frontend requests (which include UI, API, and Git over HTTP/SSH).
- Configure Prometheus to monitor your GitLab environment.
- Configure the object storage used for shared data objects.
- Configure advanced search (optional) for faster, more advanced code search across your entire GitLab instance.
Configure the external load balancer
In a multi-node GitLab configuration, you'll need an external load balancer to route traffic to the application servers.
The specifics on which load balancer to use, or its exact configuration is beyond the scope of GitLab documentation but refer to Load Balancers for more information around general requirements. This section will focus on the specifics of what to configure for your load balancer of choice.
Readiness checks
Ensure the external load balancer only routes to working services with built in monitoring endpoints. The readiness checks all require additional configuration on the nodes being checked, otherwise, the external load balancer will not be able to connect.
Ports
The basic ports to be used are shown in the table below.
LB Port | Backend Port | Protocol |
---|---|---|
80 | 80 | HTTP (1) |
443 | 443 | TCP or HTTPS (1) (2) |
22 | 22 | TCP |
- (1): Web terminal support requires
your load balancer to correctly handle WebSocket connections. When using
HTTP or HTTPS proxying, this means your load balancer must be configured
to pass through the
Connection
andUpgrade
hop-by-hop headers. See the web terminal integration guide for more details. - (2): When using HTTPS protocol for port 443, you will need to add an SSL certificate to the load balancers. If you wish to terminate SSL at the GitLab application server instead, use TCP protocol.
If you're using GitLab Pages with custom domain support you will need some
additional port configurations.
GitLab Pages requires a separate virtual IP address. Configure DNS to point the
pages_external_url
from /etc/gitlab/gitlab.rb
at the new virtual IP address. See the
GitLab Pages documentation for more information.
LB Port | Backend Port | Protocol |
---|---|---|
80 | Varies (1) | HTTP |
443 | Varies (1) | TCP (2) |
- (1): The backend port for GitLab Pages depends on the
gitlab_pages['external_http']
andgitlab_pages['external_https']
setting. See GitLab Pages documentation for more details. - (2): Port 443 for GitLab Pages should always use the TCP protocol. Users can configure custom domains with custom SSL, which would not be possible if SSL was terminated at the load balancer.
Alternate SSH Port
Some organizations have policies against opening SSH port 22. In this case, it may be helpful to configure an alternate SSH hostname that allows users to use SSH on port 443. An alternate SSH hostname will require a new virtual IP address compared to the other GitLab HTTP configuration above.
Configure DNS for an alternate SSH hostname such as altssh.gitlab.example.com
.
LB Port | Backend Port | Protocol |
---|---|---|
443 | 22 | TCP |
SSL
The next question is how you will handle SSL in your environment. There are several different options:
- The application node terminates SSL.
- The load balancer terminates SSL without backend SSL and communication is not secure between the load balancer and the application node.
- The load balancer terminates SSL with backend SSL and communication is secure between the load balancer and the application node.
Application node terminates SSL
Configure your load balancer to pass connections on port 443 as TCP
rather
than HTTP(S)
protocol. This will pass the connection to the application node's
NGINX service untouched. NGINX will have the SSL certificate and listen on port 443.
See the HTTPS documentation for details on managing SSL certificates and configuring NGINX.
Load balancer terminates SSL without backend SSL
Configure your load balancer to use the HTTP(S)
protocol rather than TCP
.
The load balancer will then be responsible for managing SSL certificates and
terminating SSL.
Since communication between the load balancer and GitLab will not be secure, there is some additional configuration needed. See the proxied SSL documentation for details.
Load balancer terminates SSL with backend SSL
Configure your load balancers to use the 'HTTP(S)' protocol rather than 'TCP'. The load balancers will be responsible for managing SSL certificates that end users will see.
Traffic will also be secure between the load balancers and NGINX in this scenario. There is no need to add configuration for proxied SSL since the connection will be secure all the way. However, configuration will need to be added to GitLab to configure SSL certificates. See the HTTPS documentation for details on managing SSL certificates and configuring NGINX.
Configure PostgreSQL
In this section, you'll be guided through configuring an external PostgreSQL database to be used with GitLab.
Provide your own PostgreSQL instance
You can optionally use a third party external service for PostgreSQL.
A reputable provider or solution should be used for this. Google Cloud SQL and Amazon RDS are known to work. However, Amazon Aurora is incompatible with load balancing enabled by default from 14.4.0. See Recommended cloud providers and services for more information.
If you use a third party external service:
- Note that the HA Linux package PostgreSQL setup encompasses PostgreSQL, PgBouncer and Consul. All of these components would no longer be required when using a third party external service.
- Set up PostgreSQL according to the database requirements document.
- Set up a
gitlab
username with a password of your choice. Thegitlab
user needs privileges to create thegitlabhq_production
database. - Configure the GitLab application servers with the appropriate details. This step is covered in Configuring the GitLab Rails application.
Standalone PostgreSQL using the Linux package
-
SSH in to the PostgreSQL server.
-
Download and install the Linux package of your choice. Be sure to follow only installation steps 1 and 2 on the page.
-
Generate a password hash for PostgreSQL. This assumes you will use the default username of
gitlab
(recommended). The command will request a password and confirmation. Use the value that is output by this command in the next step as the value ofPOSTGRESQL_PASSWORD_HASH
.sudo gitlab-ctl pg-password-md5 gitlab
-
Edit
/etc/gitlab/gitlab.rb
and add the contents below, updating placeholder values appropriately.-
POSTGRESQL_PASSWORD_HASH
- The value output from the previous step -
APPLICATION_SERVER_IP_BLOCKS
- A space delimited list of IP subnets or IP addresses of the GitLab Rails and Sidekiq servers that will connect to the database. Example:%w(123.123.123.123/32 123.123.123.234/32)
# Disable all components except PostgreSQL related ones roles(['postgres_role']) # Set the network addresses that the exporters used for monitoring will listen on node_exporter['listen_address'] = '0.0.0.0:9100' postgres_exporter['listen_address'] = '0.0.0.0:9187' postgres_exporter['dbname'] = 'gitlabhq_production' postgres_exporter['password'] = 'POSTGRESQL_PASSWORD_HASH' # Set the PostgreSQL address and port postgresql['listen_address'] = '0.0.0.0' postgresql['port'] = 5432 # Replace POSTGRESQL_PASSWORD_HASH with a generated md5 value postgresql['sql_user_password'] = 'POSTGRESQL_PASSWORD_HASH' # Replace APPLICATION_SERVER_IP_BLOCK with the CIDR address of the application node postgresql['trust_auth_cidr_addresses'] = %w(127.0.0.1/32 APPLICATION_SERVER_IP_BLOCK) # Prevent database migrations from running on upgrade automatically gitlab_rails['auto_migrate'] = false
-
-
Copy the
/etc/gitlab/gitlab-secrets.json
file from the first Linux package node you configured and add or replace the file of the same name on this server. If this is the first Linux package you are configuring then you can skip this step. -
Reconfigure GitLab for the changes to take effect.
-
Note the PostgreSQL node's IP address or hostname, port, and plain text password. These will be necessary when configuring the GitLab application server later.
Advanced configuration options are supported and can be added if needed.
Configure Redis
In this section, you'll be guided through configuring an external Redis instance to be used with GitLab.
NOTE: Redis is primarily single threaded and doesn't significantly benefit from an increase in CPU cores. Refer to the scaling documentation for more information.
Provide your own Redis instance
You can optionally use a third party external service for the Redis instance with the following guidance:
- A reputable provider or solution should be used for this. Google Memorystore and AWS ElastiCache are known to work.
- Redis Cluster mode is specifically not supported, but Redis Standalone with HA is.
- You must set the Redis eviction mode according to your setup.
For more information, see Recommended cloud providers and services.
Standalone Redis using the Linux package
The Linux package can be used to configure a standalone Redis server. The steps below are the minimum necessary to configure a Redis server with the Linux package:
-
SSH in to the Redis server.
-
Download and install the Linux package of your choice. Be sure to follow only installation steps 1 and 2 on the page.
-
Edit
/etc/gitlab/gitlab.rb
and add the contents:## Enable Redis roles(["redis_master_role"]) redis['bind'] = '0.0.0.0' redis['port'] = 6379 redis['password'] = 'SECRET_PASSWORD_HERE' gitlab_rails['enable'] = false # Set the network addresses that the exporters used for monitoring will listen on node_exporter['listen_address'] = '0.0.0.0:9100' redis_exporter['listen_address'] = '0.0.0.0:9121' redis_exporter['flags'] = { 'redis.addr' => 'redis://0.0.0.0:6379', 'redis.password' => 'SECRET_PASSWORD_HERE', }
-
Copy the
/etc/gitlab/gitlab-secrets.json
file from the first Linux package node you configured and add or replace the file of the same name on this server. If this is the first Linux package node you are configuring then you can skip this step. -
Reconfigure GitLab for the changes to take effect.
-
Note the Redis node's IP address or hostname, port, and Redis password. These will be necessary when configuring the GitLab application servers later.
Advanced configuration options are supported and can be added if needed.
Configure Gitaly
Gitaly server node requirements are dependent on data size, specifically the number of projects and those projects' sizes.
WARNING: Gitaly specifications are based on high percentiles of both usage patterns and repository sizes in good health. However, if you have large monorepos (larger than several gigabytes) or additional workloads these can significantly impact the performance of the environment and further adjustments may be required. If this applies to you, we strongly recommended referring to the linked documentation as well as reaching out to your Customer Success Manager or our Support team for further guidance.
Due to Gitaly having notable input and output requirements, we strongly recommend that all Gitaly nodes use solid-state drives (SSDs). These SSDs should have a throughput of at least 8,000 input/output operations per second (IOPS) for read operations and 2,000 IOPS for write operations. If you're running the environment on a Cloud provider, refer to their documentation about how to configure IOPS correctly.
Be sure to note the following items:
- The GitLab Rails application shards repositories into repository storage paths.
- A Gitaly server can host one or more storage paths.
- A GitLab server can use one or more Gitaly server nodes.
- Gitaly addresses must be specified to be correctly resolvable for all Gitaly clients.
- Gitaly servers must not be exposed to the public internet, as Gitaly's network traffic is unencrypted by default. The use of a firewall is highly recommended to restrict access to the Gitaly server. Another option is to use TLS.
NOTE: The token referred to throughout the Gitaly documentation is an arbitrary password selected by the administrator. This token is unrelated to tokens created for the GitLab API or other similar web API tokens.
The following procedure describes how to configure a single Gitaly server named
gitaly1.internal
with the secret token gitalysecret
. We assume your GitLab
installation has two repository storages: default
and storage1
.
To configure the Gitaly server, on the server node you want to use for Gitaly:
-
Download and install the Linux package package of your choice. Be sure to follow only installation steps 1 and 2 on the page, and do not provide the
EXTERNAL_URL
value. -
Edit the Gitaly server node's
/etc/gitlab/gitlab.rb
file to configure storage paths, enable the network listener, and to configure the token:NOTE: You can't remove the
default
entry fromgitaly['configuration'][:storage]
because GitLab requires it.# Avoid running unnecessary services on the Gitaly server postgresql['enable'] = false redis['enable'] = false nginx['enable'] = false puma['enable'] = false sidekiq['enable'] = false gitlab_workhorse['enable'] = false prometheus['enable'] = false alertmanager['enable'] = false gitlab_exporter['enable'] = false gitlab_kas['enable'] = false # Prevent database migrations from running on upgrade automatically gitlab_rails['auto_migrate'] = false # Configure the gitlab-shell API callback URL. Without this, `git push` will # fail. This can be your 'front door' GitLab URL or an internal load # balancer. gitlab_rails['internal_api_url'] = 'https://gitlab.example.com' # Gitaly gitaly['enable'] = true # The secret token is used for authentication callbacks from Gitaly to the GitLab internal API. # This must match the respective value in GitLab Rails application setup. gitlab_shell['secret_token'] = 'shellsecret' # Set the network addresses that the exporters used for monitoring will listen on node_exporter['listen_address'] = '0.0.0.0:9100' gitaly['configuration'] = { # ... # # Make Gitaly accept connections on all network interfaces. You must use # firewalls to restrict access to this address/port. # Comment out following line if you only want to support TLS connections listen_addr: '0.0.0.0:8075', prometheus_listen_addr: '0.0.0.0:9236', # Gitaly Auth Token # Should be the same as praefect_internal_token auth: { # ... # # Gitaly's authentication token is used to authenticate gRPC requests to Gitaly. This must match # the respective value in GitLab Rails application setup. token: 'gitalysecret', }, # Gitaly Pack-objects cache # Recommended to be enabled for improved performance but can notably increase disk I/O # Refer to https://docs.gitlab.com/ee/administration/gitaly/configure_gitaly.html#pack-objects-cache for more info pack_objects_cache: { # ... enabled: true, }, storage: [ { name: 'default', path: '/var/opt/gitlab/git-data', }, { name: 'storage1', path: '/mnt/gitlab/git-data', }, ], }
-
Copy the
/etc/gitlab/gitlab-secrets.json
file from the first Linux package node you configured and add or replace the file of the same name on this server. If this is the first Linux package node you are configuring then you can skip this step. -
Reconfigure GitLab for the changes to take effect.
-
Confirm that Gitaly can perform callbacks to the internal API:
- For GitLab 15.3 and later, run
sudo /opt/gitlab/embedded/bin/gitaly check /var/opt/gitlab/gitaly/config.toml
. - For GitLab 15.2 and earlier, run
sudo /opt/gitlab/embedded/bin/gitaly-hooks check /var/opt/gitlab/gitaly/config.toml
.
- For GitLab 15.3 and later, run
Gitaly TLS support
Gitaly supports TLS encryption. To be able to communicate
with a Gitaly instance that listens for secure connections you will need to use tls://
URL
scheme in the gitaly_address
of the corresponding storage entry in the GitLab configuration.
You will need to bring your own certificates as this isn't provided automatically. The certificate, or its certificate authority, must be installed on all Gitaly nodes (including the Gitaly node using the certificate) and on all client nodes that communicate with it following the procedure described in GitLab custom certificate configuration.
NOTE: The self-signed certificate must specify the address you use to access the Gitaly server. If you are addressing the Gitaly server by a hostname, add it as a Subject Alternative Name. If you are addressing the Gitaly server by its IP address, you must add it as a Subject Alternative Name to the certificate.
It's possible to configure Gitaly servers with both an unencrypted listening
address (listen_addr
) and an encrypted listening address (tls_listen_addr
)
at the same time. This allows you to do a gradual transition from unencrypted to
encrypted traffic, if necessary.
To configure Gitaly with TLS:
-
Create the
/etc/gitlab/ssl
directory and copy your key and certificate there:sudo mkdir -p /etc/gitlab/ssl sudo chmod 755 /etc/gitlab/ssl sudo cp key.pem cert.pem /etc/gitlab/ssl/ sudo chmod 644 key.pem cert.pem
-
Copy the cert to
/etc/gitlab/trusted-certs
so Gitaly will trust the cert when calling into itself:sudo cp /etc/gitlab/ssl/cert.pem /etc/gitlab/trusted-certs/
-
Edit
/etc/gitlab/gitlab.rb
and add:gitaly['configuration'] = { # ... tls_listen_addr: '0.0.0.0:9999', tls: { certificate_path: '/etc/gitlab/ssl/cert.pem', key_path: '/etc/gitlab/ssl/key.pem', }, }
-
Delete
gitaly['listen_addr']
to allow only encrypted connections. -
Save the file and reconfigure GitLab.
Configure Sidekiq
Sidekiq requires connection to the Redis, PostgreSQL and Gitaly instances. It also requires a connection to Object Storage as recommended.
NOTE: If you find that the environment's Sidekiq job processing is slow with long queues you can scale it accordingly. Refer to the scaling documentation for more information.
To configure the Sidekiq server, on the server node you want to use for Sidekiq:
-
SSH in to the Sidekiq server.
-
Download and install the Linux package of your choice. Be sure to follow only installation steps 1 and 2 on the page.
-
Create or edit
/etc/gitlab/gitlab.rb
and use the following configuration:# https://docs.gitlab.com/omnibus/roles/#sidekiq-roles roles(["sidekiq_role"]) # External URL external_url 'https://gitlab.example.com' ## Redis connection details gitlab_rails['redis_port'] = '6379' gitlab_rails['redis_host'] = '10.1.0.6' # IP/hostname of Redis server gitlab_rails['redis_password'] = 'Redis Password' # Gitaly and GitLab use two shared secrets for authentication, one to authenticate gRPC requests # to Gitaly, and a second for authentication callbacks from GitLab-Shell to the GitLab internal API. # The following two values must be the same as their respective values # of the Gitaly setup gitlab_rails['gitaly_token'] = 'gitalysecret' gitlab_shell['secret_token'] = 'shellsecret' git_data_dirs({ 'default' => { 'gitaly_address' => 'tcp://gitaly1.internal:8075' }, 'storage1' => { 'gitaly_address' => 'tcp://gitaly1.internal:8075' }, 'storage2' => { 'gitaly_address' => 'tcp://gitaly2.internal:8075' }, }) ## PostgreSQL connection details gitlab_rails['db_adapter'] = 'postgresql' gitlab_rails['db_encoding'] = 'unicode' gitlab_rails['db_host'] = '10.1.0.5' # IP/hostname of database server gitlab_rails['db_password'] = 'DB password' ## Prevent database migrations from running on upgrade automatically gitlab_rails['auto_migrate'] = false # Sidekiq sidekiq['listen_address'] = "0.0.0.0" ## Set number of Sidekiq queue processes to the same number as available CPUs sidekiq['queue_groups'] = ['*'] * 4 ## Set the network addresses that the exporters will listen on node_exporter['listen_address'] = '0.0.0.0:9100' # Object Storage ## This is an example for configuring Object Storage on GCP ## Replace this config with your chosen Object Storage provider as desired gitlab_rails['object_store']['enabled'] = true gitlab_rails['object_store']['connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' } gitlab_rails['object_store']['objects']['artifacts']['bucket'] = "<gcp-artifacts-bucket-name>" gitlab_rails['object_store']['objects']['external_diffs']['bucket'] = "<gcp-external-diffs-bucket-name>" gitlab_rails['object_store']['objects']['lfs']['bucket'] = "<gcp-lfs-bucket-name>" gitlab_rails['object_store']['objects']['uploads']['bucket'] = "<gcp-uploads-bucket-name>" gitlab_rails['object_store']['objects']['packages']['bucket'] = "<gcp-packages-bucket-name>" gitlab_rails['object_store']['objects']['dependency_proxy']['bucket'] = "<gcp-dependency-proxy-bucket-name>" gitlab_rails['object_store']['objects']['terraform_state']['bucket'] = "<gcp-terraform-state-bucket-name>" gitlab_rails['backup_upload_connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' } gitlab_rails['backup_upload_remote_directory'] = "<gcp-backups-state-bucket-name>" gitlab_rails['ci_secure_files_object_store_enabled'] = true gitlab_rails['ci_secure_files_object_store_remote_directory'] = "gcp-ci_secure_files-bucket-name" gitlab_rails['ci_secure_files_object_store_connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' }
-
Copy the
/etc/gitlab/gitlab-secrets.json
file from the first Linux package node you configured and add or replace the file of the same name on this server. If this is the first Linux package node you are configuring then you can skip this step. -
To ensure database migrations are only run during reconfigure and not automatically on upgrade, run:
sudo touch /etc/gitlab/skip-auto-reconfigure
Only a single designated node should handle migrations as detailed in the GitLab Rails post-configuration section.
-
Save the file and reconfigure GitLab.
-
Verify the GitLab services are running:
sudo gitlab-ctl status
The output should be similar to the following:
run: logrotate: (pid 192292) 2990s; run: log: (pid 26374) 93048s run: node-exporter: (pid 26864) 92997s; run: log: (pid 26446) 93036s run: sidekiq: (pid 26870) 92996s; run: log: (pid 26391) 93042s
Configure GitLab Rails
This section describes how to configure the GitLab application (Rails) component.
In our architecture, we run each GitLab Rails node using the Puma webserver, and have its number of workers set to 90% of available CPUs, with four threads. For nodes running Rails with other components, the worker value should be reduced accordingly. We've determined that a worker value of 50% achieves a good balance, but this is dependent on workload.
On each node perform the following:
-
Download and install the Linux package of your choice. Be sure to follow only installation steps 1 and 2 on the page.
-
Create or edit
/etc/gitlab/gitlab.rb
and use the following configuration. To maintain uniformity of links across nodes, theexternal_url
on the application server should point to the external URL that users will use to access GitLab. This would be the URL of the load balancer which will route traffic to the GitLab application server:external_url 'https://gitlab.example.com' # Gitaly and GitLab use two shared secrets for authentication, one to authenticate gRPC requests # to Gitaly, and a second for authentication callbacks from GitLab-Shell to the GitLab internal API. # The following two values must be the same as their respective values # of the Gitaly setup gitlab_rails['gitaly_token'] = 'gitalysecret' gitlab_shell['secret_token'] = 'shellsecret' git_data_dirs({ 'default' => { 'gitaly_address' => 'tcp://gitaly1.internal:8075' }, 'storage1' => { 'gitaly_address' => 'tcp://gitaly1.internal:8075' }, 'storage2' => { 'gitaly_address' => 'tcp://gitaly2.internal:8075' }, }) ## Disable components that will not be on the GitLab application server roles(['application_role']) gitaly['enable'] = false nginx['enable'] = true sidekiq['enable'] = false ## PostgreSQL connection details gitlab_rails['db_adapter'] = 'postgresql' gitlab_rails['db_encoding'] = 'unicode' gitlab_rails['db_host'] = '10.1.0.5' # IP/hostname of database server gitlab_rails['db_password'] = 'DB password' ## Redis connection details gitlab_rails['redis_port'] = '6379' gitlab_rails['redis_host'] = '10.1.0.6' # IP/hostname of Redis server gitlab_rails['redis_password'] = 'Redis Password' # Set the network addresses that the exporters used for monitoring will listen on node_exporter['listen_address'] = '0.0.0.0:9100' gitlab_workhorse['prometheus_listen_addr'] = '0.0.0.0:9229' puma['listen'] = '0.0.0.0' # Add the monitoring node's IP address to the monitoring whitelist and allow it to # scrape the NGINX metrics. Replace placeholder `monitoring.gitlab.example.com` with # the address and/or subnets gathered from the monitoring node gitlab_rails['monitoring_whitelist'] = ['<MONITOR NODE IP>/32', '127.0.0.0/8'] nginx['status']['options']['allow'] = ['<MONITOR NODE IP>/32', '127.0.0.0/8'] # Object Storage # This is an example for configuring Object Storage on GCP # Replace this config with your chosen Object Storage provider as desired gitlab_rails['object_store']['enabled'] = true gitlab_rails['object_store']['connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' } gitlab_rails['object_store']['objects']['artifacts']['bucket'] = "<gcp-artifacts-bucket-name>" gitlab_rails['object_store']['objects']['external_diffs']['bucket'] = "<gcp-external-diffs-bucket-name>" gitlab_rails['object_store']['objects']['lfs']['bucket'] = "<gcp-lfs-bucket-name>" gitlab_rails['object_store']['objects']['uploads']['bucket'] = "<gcp-uploads-bucket-name>" gitlab_rails['object_store']['objects']['packages']['bucket'] = "<gcp-packages-bucket-name>" gitlab_rails['object_store']['objects']['dependency_proxy']['bucket'] = "<gcp-dependency-proxy-bucket-name>" gitlab_rails['object_store']['objects']['terraform_state']['bucket'] = "<gcp-terraform-state-bucket-name>" gitlab_rails['backup_upload_connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' } gitlab_rails['backup_upload_remote_directory'] = "<gcp-backups-state-bucket-name>" gitlab_rails['ci_secure_files_object_store_enabled'] = true gitlab_rails['ci_secure_files_object_store_remote_directory'] = "gcp-ci_secure_files-bucket-name" gitlab_rails['ci_secure_files_object_store_connection'] = { 'provider' => 'Google', 'google_project' => '<gcp-project-name>', 'google_json_key_location' => '<path-to-gcp-service-account-key>' } ## Uncomment and edit the following options if you have set up NFS ## ## Prevent GitLab from starting if NFS data mounts are not available ## #high_availability['mountpoint'] = '/var/opt/gitlab/git-data' ## ## Ensure UIDs and GIDs match between servers for permissions via NFS ## #user['uid'] = 9000 #user['gid'] = 9000 #web_server['uid'] = 9001 #web_server['gid'] = 9001 #registry['uid'] = 9002 #registry['gid'] = 9002
-
If you're using Gitaly with TLS support, make sure the
git_data_dirs
entry is configured withtls
instead oftcp
:git_data_dirs({ 'default' => { 'gitaly_address' => 'tls://gitaly1.internal:9999' }, 'storage1' => { 'gitaly_address' => 'tls://gitaly1.internal:9999' }, 'storage2' => { 'gitaly_address' => 'tls://gitaly2.internal:9999' }, })
-
Copy the cert into
/etc/gitlab/trusted-certs
:sudo cp cert.pem /etc/gitlab/trusted-certs/
-
-
Copy the
/etc/gitlab/gitlab-secrets.json
file from the first Linux package node you configured and add or replace the file of the same name on this server. If this is the first Linux package node you are configuring then you can skip this step. -
To ensure database migrations are only run during reconfigure and not automatically on upgrade, run:
sudo touch /etc/gitlab/skip-auto-reconfigure
Only a single designated node should handle migrations as detailed in the GitLab Rails post-configuration section.
-
Reconfigure GitLab for the changes to take effect.
-
Run
sudo gitlab-rake gitlab:gitaly:check
to confirm the node can connect to Gitaly. -
Tail the logs to see the requests:
sudo gitlab-ctl tail gitaly
When you specify https
in the external_url
, as in the previous example,
GitLab expects that the SSL certificates are in /etc/gitlab/ssl/
. If the
certificates aren't present, NGINX will fail to start. For more information, see
the HTTPS documentation.
GitLab Rails post-configuration
-
Designate one application node for running database migrations during installation and updates. Initialize the GitLab database and ensure all migrations ran:
sudo gitlab-rake gitlab:db:configure
Note that this requires the Rails node to be configured to connect to the primary database directly, bypassing PgBouncer. After migrations have completed, you must configure the node to pass through PgBouncer again.
-
Configure fast lookup of authorized SSH keys in the database.
Configure Prometheus
The Linux package can be used to configure a standalone Monitoring node running Prometheus:
-
SSH in to the Monitoring node.
-
Download and install the Linux package of your choice. Be sure to follow only installation steps 1 and 2 on the page.
-
Edit
/etc/gitlab/gitlab.rb
and add the contents:roles(['monitoring_role']) nginx['enable'] = false external_url 'http://gitlab.example.com' # Prometheus prometheus['listen_address'] = '0.0.0.0:9090' prometheus['monitor_kubernetes'] = false
-
Prometheus also needs some scrape configurations to pull all the data from the various nodes where we configured exporters. Assuming that your nodes' IPs are:
1.1.1.1: postgres 1.1.1.2: redis 1.1.1.3: gitaly1 1.1.1.4: rails1 1.1.1.5: rails2
Add the following to
/etc/gitlab/gitlab.rb
:prometheus['scrape_configs'] = [ { 'job_name': 'postgres', 'static_configs' => [ 'targets' => ['1.1.1.1:9187'], ], }, { 'job_name': 'redis', 'static_configs' => [ 'targets' => ['1.1.1.2:9121'], ], }, { 'job_name': 'gitaly', 'static_configs' => [ 'targets' => ['1.1.1.3:9236'], ], }, { 'job_name': 'gitlab-nginx', 'static_configs' => [ 'targets' => ['1.1.1.4:8060', '1.1.1.5:8060'], ], }, { 'job_name': 'gitlab-workhorse', 'static_configs' => [ 'targets' => ['1.1.1.4:9229', '1.1.1.5:9229'], ], }, { 'job_name': 'gitlab-rails', 'metrics_path': '/-/metrics', 'static_configs' => [ 'targets' => ['1.1.1.4:8080', '1.1.1.5:8080'], ], }, { 'job_name': 'gitlab-sidekiq', 'static_configs' => [ 'targets' => ['1.1.1.4:8082', '1.1.1.5:8082'], ], }, { 'job_name': 'static-node', 'static_configs' => [ 'targets' => ['1.1.1.1:9100', '1.1.1.2:9100', '1.1.1.3:9100', '1.1.1.4:9100', '1.1.1.5:9100'], ], }, ]
-
Save the file and reconfigure GitLab.
Configure the object storage
GitLab supports using an object storage service for holding numerous types of data. It's recommended over NFS for data objects and in general it's better in larger setups as object storage is typically much more performant, reliable, and scalable. See Recommended cloud providers and services for more information.
There are two ways of specifying object storage configuration in GitLab:
- Consolidated form: A single credential is shared by all supported object types.
- Storage-specific form: Every object defines its own object storage connection and configuration.
The consolidated form is used in the following examples when available.
Using separate buckets for each data type is the recommended approach for GitLab. This ensures there are no collisions across the various types of data GitLab stores. There are plans to enable the use of a single bucket in the future.
Enable incremental logging
GitLab Runner returns job logs in chunks which the Linux package caches temporarily on disk in /var/opt/gitlab/gitlab-ci/builds
by default, even when using consolidated object storage. With default configuration, this directory needs to be shared through NFS on any GitLab Rails and Sidekiq nodes.
While sharing the job logs through NFS is supported, it's recommended to avoid the need to use NFS by enabling incremental logging (required when no NFS node has been deployed). Incremental logging uses Redis instead of disk space for temporary caching of job logs.
Configure advanced search
DETAILS: Tier: Premium, Ultimate Offering: Self-managed
You can leverage Elasticsearch and enable advanced search for faster, more advanced code search across your entire GitLab instance.
Elasticsearch cluster design and requirements are dependent on your specific data. For recommended best practices about how to set up your Elasticsearch cluster alongside your instance, read how to choose the optimal cluster configuration.
Cloud Native Hybrid reference architecture with Helm Charts (alternative)
Run select components of cloud-native GitLab in Kubernetes with the GitLab Helm chart. In this setup, you can run the equivalent of GitLab Rails in the Kubernetes cluster called Webservice. You also can run the equivalent of Sidekiq nodes in the Kubernetes cluster called Sidekiq. In addition, the following other supporting services are supported: NGINX, Toolbox, Migrations, Prometheus.
Hybrid installations leverage the benefits of both cloud native and traditional compute deployments. With this, stateless components can benefit from cloud native workload management benefits while stateful components are deployed in compute VMs with Linux package installations to benefit from increased permanence.
Refer to the Helm charts Advanced configuration documentation for setup instructions including guidance on what GitLab secrets to sync between Kubernetes and the backend components.
NOTE: This is an advanced setup. Running services in Kubernetes is well known to be complex. This setup is only recommended if you have strong working knowledge and experience in Kubernetes. The rest of this section assumes this.
NOTE: The 2,000 reference architecture is not a highly-available setup. To achieve HA, you can follow a modified 3K or 60 RPS reference architecture.
WARNING: Gitaly Cluster is not supported to be run in Kubernetes. Refer to epic 6127 for more details.
Cluster topology
The following tables and diagram detail the hybrid environment using the same formats as the typical environment above.
First are the components that run in Kubernetes. These run across several node groups, although you can change the overall makeup as desired as long as the minimum CPU and Memory requirements are observed.
Component Node Group | Target Node Pool Totals | GCP Example | AWS Example |
---|---|---|---|
Webservice | 12 vCPU 15 GB memory (request) 21 GB memory (limit) |
3 x n1-standard-8
|
3 x c5.2xlarge
|
Sidekiq | 3.6 vCPU 8 GB memory (request) 16 GB memory (limit) |
2 x n1-standard-4
|
2 x m5.xlarge
|
Supporting services | 4 vCPU 15 GB memory |
2 x n1-standard-2
|
2 x m5.large
|
- For this setup, we recommend and regularly test Google Kubernetes Engine (GKE) and Amazon Elastic Kubernetes Service (EKS). Other Kubernetes services may also work, but your mileage may vary.
- GCP and AWS examples of how to reach the Target Node Pool Total are given for convenience. These sizes are used in performance testing but following the example is not required. Different node pool designs can be used as desired as long as the targets are met, and all pods can deploy.
- The Webservice and Sidekiq target node pool totals are given for GitLab components only. Additional resources are required for the chosen Kubernetes provider's system processes. The given examples take this into account.
- The Supporting target node pool total is given generally to accommodate several resources for supporting the GitLab deployment as well as any additional deployments you may wish to make depending on your requirements. Similar to the other node pools, the chosen Kubernetes provider's system processes also require resources. The given examples take this into account.
- In production deployments, it's not required to assign pods to specific nodes. However, it is recommended to have several nodes in each pool spread across different availability zones to align with resilient cloud architecture practices.
- Enabling autoscaling, such as Cluster Autoscaler, for efficiency reasons is encouraged, but it's generally recommended targeting a floor of 75% for Webservice and Sidekiq pods to ensure ongoing performance.
Next are the backend components that run on static compute VMs using the Linux package (or External PaaS services where applicable):
Service | Nodes | Configuration | GCP | AWS |
---|---|---|---|---|
PostgreSQL1 | 1 | 2 vCPU, 7.5 GB memory | n1-standard-2 |
m5.large |
Redis2 | 1 | 1 vCPU, 3.75 GB memory | n1-standard-1 |
m5.large |
Gitaly | 1 | 4 vCPU, 15 GB memory | n1-standard-4 |
m5.xlarge |
Object storage3 | - | - | - | - |
Footnotes:
- Can be optionally run on reputable third-party external PaaS PostgreSQL solutions. See Provide your own PostgreSQL instance and Recommended cloud providers and services for more information.
- Can be optionally run on reputable third-party external PaaS Redis solutions. See Provide your own Redis instance and Recommended cloud providers and services for more information.
- Should be run on reputable Cloud Provider or Self Managed solutions. See Configure the object storage for more information.
NOTE: For all PaaS solutions that involve configuring instances, it's recommended to implement a minimum of three nodes in three different availability zones to align with resilient cloud architecture practices.
@startuml 2k
skinparam linetype ortho
card "Kubernetes via Helm Charts" as kubernetes {
card "**External Load Balancer**" as elb #6a9be7
together {
collections "**Webservice**" as gitlab #32CD32
collections "**Sidekiq**" as sidekiq #ff8dd1
}
collections "**Supporting Services**" as support
}
card "**Gitaly**" as gitaly #FF8C00
card "**PostgreSQL**" as postgres #4EA7FF
card "**Redis**" as redis #FF6347
cloud "**Object Storage**" as object_storage #white
elb -[#6a9be7]-> gitlab
gitlab -[#32CD32]--> gitaly
gitlab -[#32CD32]--> postgres
gitlab -[#32CD32]-> object_storage
gitlab -[#32CD32]--> redis
sidekiq -[#ff8dd1]--> gitaly
sidekiq -[#ff8dd1]-> object_storage
sidekiq -[#ff8dd1]--> postgres
sidekiq -[#ff8dd1]--> redis
@enduml
Kubernetes component targets
The following section details the targets used for the GitLab components deployed in Kubernetes.
Webservice
Each Webservice pod (Puma and Workhorse) is recommended to be run with the following configuration:
- 4 Puma Workers
- 4 vCPU
- 5 GB memory (request)
- 7 GB memory (limit)
For 40 RPS or 2,000 users we recommend a total Puma worker count of around 12 so in turn it's recommended to run at least 3 Webservice pods.
For further information on Webservice resource usage, see the Charts documentation on Webservice resources.
NGINX
It's also recommended deploying the NGINX controller pods across the Webservice nodes as a DaemonSet. This is to allow the controllers to scale dynamically with the Webservice pods they serve as well as take advantage of the higher network bandwidth larger machine types typically have.
Note that this isn't a strict requirement. The NGINX controller pods can be deployed as desired as long as they have enough resources to handle the web traffic.
Sidekiq
Each Sidekiq pod is recommended to be run with the following configuration:
- 1 Sidekiq worker
- 900m vCPU
- 2 GB memory (request)
- 4 GB memory (limit)
Similar to the standard deployment above, an initial target of 4 Sidekiq workers has been used here. Additional workers may be required depending on your specific workflow.
For further information on Sidekiq resource usage, see the Charts documentation on Sidekiq resources.
Supporting
The Supporting Node Pool is designed to house all supporting deployments that don't need to be on the Webservice and Sidekiq pools.
This includes various deployments related to the Cloud Provider's implementation and supporting GitLab deployments such as GitLab Shell.
If you wish to make any additional deployments such as Container Registry, Pages or Monitoring, it's recommended to deploy these in this pool where possible and not in the Webservice or Sidekiq pools, as the Supporting pool has been designed specifically to accommodate several additional deployments. However, if your deployments don't fit into the pool as given, you can increase the node pool accordingly. Conversely, if the pool in your use case is over-provisioned you can reduce accordingly.
Example config file
An example for the GitLab Helm Charts for the above 40 RPS or 2,000 reference architecture configuration can be found in the Charts project.