debian-mirror-gitlab/doc/administration/scaling/index.md
2020-04-22 19:07:51 +05:30

18 KiB

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reference, concepts

Scaling

GitLab supports a number of scaling options to ensure that your self-managed instance is able to scale out to meet your organization's needs when scaling up a single-box GitLab installation is no longer practical or feasible.

Please consult our high availability documentation if your organization requires fault tolerance and redundancy features, such as automatic database system failover.

GitLab components and scaling instructions

Here's a list of components directly provided by Omnibus GitLab or installed as part of a source installation and their configuration instructions for scaling.

Component Description Configuration instructions
PostgreSQL Database PostgreSQL configuration
Redis Key/value store for fast data lookup and caching Redis configuration
GitLab application services Unicorn/Puma, Workhorse, GitLab Shell - serves front-end requests (UI, API, Git over HTTP/SSH) GitLab app scaling configuration
PgBouncer Database connection pooler PgBouncer configuration (PREMIUM ONLY)
Sidekiq Asynchronous/background jobs Sidekiq configuration
Gitaly Provides access to Git repositories Gitaly configuration
Prometheus and Grafana GitLab environment monitoring Monitoring node for scaling

Third-party services used for scaling

Here's a list of third-party services you may require as part of scaling GitLab. The services can be provided by numerous applications or vendors and further advice is given on how best to select the right choice for your organization's needs.

Component Description Configuration instructions
Load balancer(s) Handles load balancing, typically when you have multiple GitLab application services nodes Load balancer configuration
Object storage service Recommended store for shared data objects Cloud Object Storage configuration
NFS Shared disk storage service. Can be used as an alternative for Gitaly or Object Storage. Required for GitLab Pages NFS configuration

Reference architectures

Single-node installation

This solution is appropriate for many teams that have a single server at their disposal. With automatic backup of the GitLab repositories, configuration, and the database, this can be an optimal solution if you don't have strict availability requirements.

You can also optionally configure GitLab to use an external PostgreSQL service or an external object storage service for added performance and reliability at a relatively low complexity cost.

References:

Multi-node installation (scaled out for availability)

This solution is appropriate for teams that are starting to scale out when scaling up is no longer meeting their needs. In this configuration, additional application nodes will handle frontend traffic, with a load balancer in front to distribute traffic across those nodes. Meanwhile, each application node connects to a shared file server and PostgreSQL and Redis services on the back end.

The additional application servers adds limited fault tolerance to your GitLab instance. As long as one application node is online and capable of handling the instance's usage load, your team's productivity will not be interrupted. Having multiple application nodes also enables zero-downtime updates.

References:

In this section we'll detail the Reference Architectures that can support large numbers of users. These were built, tested and verified by our Quality and Support teams.

Testing was done with our GitLab Performance Tool at specific coded workloads, and the throughputs used for testing were calculated based on sample customer data. We test each endpoint type with the following number of requests per second (RPS) per 1000 users:

  • API: 20 RPS
  • Web: 2 RPS
  • Git: 2 RPS

NOTE: Note: Note that depending on your workflow the below recommended reference architectures may need to be adapted accordingly. Your workload is influenced by factors such as - but not limited to - how active your users are, how much automation you use, mirroring, and repo/change size. Additionally the shown memory values are given directly by GCP machine types. On different cloud vendors a best effort like for like can be used.

2,000 user configuration

Service Nodes Configuration1 GCP type AWS type2
GitLab Rails3 3 8 vCPU, 7.2GB Memory n1-highcpu-8 c5.2xlarge
PostgreSQL 3 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
PgBouncer 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Gitaly4 5 6 X 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis7 3 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
Consul + Sentinel7 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Sidekiq 4 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
Cloud Object Storage8 - - - -
NFS Server5 6 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
Monitoring node 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
External load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Internal load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large

5,000 user configuration

Service Nodes Configuration1 GCP type AWS type2
GitLab Rails3 3 16 vCPU, 14.4GB Memory n1-highcpu-16 c5.4xlarge
PostgreSQL 3 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
PgBouncer 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Gitaly4 5 6 X 8 vCPU, 30GB Memory n1-standard-8 m5.2xlarge
Redis7 3 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
Consul + Sentinel7 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Sidekiq 4 2 vCPU, 7.5GB Memory n1-standard-2 m5.large
Cloud Object Storage8 - - - -
NFS Server5 6 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
Monitoring node 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
External load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Internal load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large

10,000 user configuration

Service Nodes GCP Configuration1 GCP type AWS type2
GitLab Rails3 3 32 vCPU, 28.8GB Memory n1-highcpu-32 c5.9xlarge
PostgreSQL 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
PgBouncer 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Gitaly4 5 6 X 16 vCPU, 60GB Memory n1-standard-16 m5.4xlarge
Redis7 - Cache 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis7 - Queues / Shared State 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis Sentinel7 - Cache 3 1 vCPU, 1.7GB Memory g1-small t2.small
Redis Sentinel7 - Queues / Shared State 3 1 vCPU, 1.7GB Memory g1-small t2.small
Consul 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Sidekiq 4 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Cloud Object Storage8 - - - -
NFS Server5 6 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
Monitoring node 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
External load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Internal load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large

25,000 user configuration

Service Nodes Configuration1 GCP type AWS type2
GitLab Rails3 5 32 vCPU, 28.8GB Memory n1-highcpu-32 c5.9xlarge
PostgreSQL 3 8 vCPU, 30GB Memory n1-standard-8 m5.2xlarge
PgBouncer 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Gitaly4 5 6 X 32 vCPU, 120GB Memory n1-standard-32 m5.8xlarge
Redis7 - Cache 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis7 - Queues / Shared State 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis Sentinel7 - Cache 3 1 vCPU, 1.7GB Memory g1-small t2.small
Redis Sentinel7 - Queues / Shared State 3 1 vCPU, 1.7GB Memory g1-small t2.small
Consul 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Sidekiq 4 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Cloud Object Storage8 - - - -
NFS Server5 6 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
Monitoring node 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
External load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Internal load balancing node9 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge

50,000 user configuration

Service Nodes Configuration1 GCP type AWS type2
GitLab Rails3 12 32 vCPU, 28.8GB Memory n1-highcpu-32 c5.9xlarge
PostgreSQL 3 16 vCPU, 60GB Memory n1-standard-16 m5.4xlarge
PgBouncer 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Gitaly4 5 6 X 64 vCPU, 240GB Memory n1-standard-64 m5.16xlarge
Redis7 - Cache 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis7 - Queues / Shared State 3 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
Redis Sentinel7 - Cache 3 1 vCPU, 1.7GB Memory g1-small t2.small
Redis Sentinel7 - Queues / Shared State 3 1 vCPU, 1.7GB Memory g1-small t2.small
Consul 3 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Sidekiq 4 4 vCPU, 15GB Memory n1-standard-4 m5.xlarge
NFS Server5 6 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
Cloud Object Storage8 - - - -
Monitoring node 1 4 vCPU, 3.6GB Memory n1-highcpu-4 c5.xlarge
External load balancing node9 1 2 vCPU, 1.8GB Memory n1-highcpu-2 c5.large
Internal load balancing node9 1 8 vCPU, 7.2GB Memory n1-highcpu-8 c5.2xlarge

  1. The architectures were built and tested with the Intel Xeon E5 v3 (Haswell) CPU platform on GCP. On different hardware you may find that adjustments, either lower or higher, are required for your CPU or Node counts accordingly. For more information, a Sysbench benchmark of the CPU can be found here. ↩︎

  2. AWS-equivalent configurations are rough suggestions and may change in the future. They have not yet been tested and validated. ↩︎

  3. In our architectures we run each GitLab Rails node using the Puma webserver and have its number of workers set to 90% of available CPUs along with 4 threads. ↩︎

  4. Gitaly node requirements are dependent on customer data, specifically the number of projects and their sizes. We recommend 2 nodes as an absolute minimum for HA environments and at least 4 nodes should be used when supporting 50,000 or more users. We also recommend that each Gitaly node should store no more than 5TB of data and have the number of gitaly-ruby workers set to 20% of available CPUs. Additional nodes should be considered in conjunction with a review of expected data size and spread based on the recommendations above. ↩︎

  5. NFS can be used as an alternative for both repository data (replacing Gitaly) and object storage but this isn't typically recommended for performance reasons. Note however it is required for GitLab Pages. ↩︎

  6. We strongly recommend that any Gitaly and / or NFS nodes are set up with SSD disks over HDD with a throughput of at least 8,000 IOPS for read operations and 2,000 IOPS for write as these components have heavy I/O. These IOPS values are recommended only as a starter as with time they may be adjusted higher or lower depending on the scale of your environment's workload. If you're running the environment on a Cloud provider you may need to refer to their documentation on how configure IOPS correctly. ↩︎

  7. Recommended Redis setup differs depending on the size of the architecture. For smaller architectures (up to 5,000 users) we suggest one Redis cluster for all classes and that Redis Sentinel is hosted alongside Consul. For larger architectures (10,000 users or more) we suggest running a separate Redis Cluster for the Cache class and another for the Queues and Shared State classes respectively. We also recommend that you run the Redis Sentinel clusters separately as well for each Redis Cluster. ↩︎

  8. For data objects such as LFS, Uploads, Artifacts, etc. We recommend a Cloud Object Storage service over NFS where possible, due to better performance and availability. ↩︎

  9. Our architectures have been tested and validated with HAProxy as the load balancer. However other reputable load balancers with similar feature sets should also work instead but be aware these aren't validated. ↩︎