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Connecting GitLab with a Kubernetes cluster
Introduced in GitLab 10.1.
Connect your project to Google Kubernetes Engine (GKE) or an existing Kubernetes cluster in a few steps.
Overview
With one or more Kubernetes clusters associated to your project, you can use Review Apps, deploy your applications, run your pipelines, use it with Auto DevOps, and much more, all from within GitLab.
There are two options when adding a new cluster to your project; either associate your account with Google Kubernetes Engine (GKE) so that you can create new clusters from within GitLab, or provide the credentials to an existing Kubernetes cluster.
NOTE: Note: From GitLab 11.6 you can also associate a Kubernetes cluster to your groups. Learn more about group Kubernetes clusters.
Adding and creating a new GKE cluster via GitLab
TIP: Tip: Every new Google Cloud Platform (GCP) account receives $300 in credit upon sign up, and in partnership with Google, GitLab is able to offer an additional $200 for new GCP accounts to get started with GitLab's Google Kubernetes Engine Integration. All you have to do is follow this link and apply for credit.
NOTE: Note: The Google authentication integration must be enabled in GitLab at the instance level. If that's not the case, ask your GitLab administrator to enable it. On GitLab.com, this is enabled.
Requirements
Before creating your first cluster on Google Kubernetes Engine with GitLab's integration, make sure the following requirements are met:
- A billing account is set up and you have permissions to access it.
- The Kubernetes Engine API is enabled. Follow the steps as outlined in the "Before you begin" section of the Kubernetes Engine docs.
Creating the cluster
If all of the above requirements are met, you can proceed to create and add a new Kubernetes cluster to your project:
-
Navigate to your project's Operations > Kubernetes page.
NOTE: Note: You need Maintainer permissions and above to access the Kubernetes page.
-
Click Add Kubernetes cluster.
-
Click Create with Google Kubernetes Engine.
-
Connect your Google account if you haven't done already by clicking the Sign in with Google button.
-
From there on, choose your cluster's settings:
- Kubernetes cluster name - The name you wish to give the cluster.
- Environment scope - The associated environment to this cluster.
- Google Cloud Platform project - Choose the project you created in your GCP console that will host the Kubernetes cluster. Learn more about Google Cloud Platform projects.
- Zone - Choose the region zone under which the cluster will be created.
- Number of nodes - Enter the number of nodes you wish the cluster to have.
- Machine type - The machine type of the Virtual Machine instance that the cluster will be based on.
-
Finally, click the Create Kubernetes cluster button.
After a couple of minutes, your cluster will be ready to go. You can now proceed to install some pre-defined applications.
Adding an existing Kubernetes cluster
To add an existing Kubernetes cluster to your project:
-
Navigate to your project's Operations > Kubernetes page.
NOTE: Note: You need Maintainer permissions and above to access the Kubernetes page.
-
Click Add Kubernetes cluster.
-
Click Add an existing Kubernetes cluster and fill in the details:
-
Kubernetes cluster name (required) - The name you wish to give the cluster.
-
Environment scope (required)- The associated environment to this cluster.
-
API URL (required) - It's the URL that GitLab uses to access the Kubernetes API. Kubernetes exposes several APIs, we want the "base" URL that is common to all of them, e.g.,
https://kubernetes.example.com
rather thanhttps://kubernetes.example.com/api/v1
. -
CA certificate (optional) - If the API is using a self-signed TLS certificate, you'll also need to include the
ca.crt
contents here. -
Token - GitLab authenticates against Kubernetes using service tokens, which are scoped to a particular
namespace
. The token used should belong to a service account withcluster-admin
privileges. To create this service account:-
Create a
gitlab
service account in thedefault
namespace:kubectl create -f - <<EOF apiVersion: v1 kind: ServiceAccount metadata: name: gitlab namespace: default EOF
-
Create a cluster role binding to give the
gitlab
service accountcluster-admin
privileges:kubectl create -f - <<EOF kind: ClusterRoleBinding apiVersion: rbac.authorization.k8s.io/v1 metadata: name: gitlab-cluster-admin subjects: - kind: ServiceAccount name: gitlab namespace: default roleRef: kind: ClusterRole name: cluster-admin apiGroup: rbac.authorization.k8s.io EOF
NOTE: Note: For GKE clusters, you will need the
container.clusterRoleBindings.create
permission to create a cluster role binding. You can follow the Google Cloud documentation to grant access. -
-
Project namespace (optional) - You don't have to fill it in; by leaving it blank, GitLab will create one for you. Also:
- Each project should have a unique namespace.
- The project namespace is not necessarily the namespace of the secret, if
you're using a secret with broader permissions, like the secret from
default
. - You should not use
default
as the project namespace. - If you or someone created a secret specifically for the project, usually with limited permissions, the secret's namespace and project namespace may be the same.
-
-
Finally, click the Create Kubernetes cluster button.
After a couple of minutes, your cluster will be ready to go. You can now proceed to install some pre-defined applications.
To determine the:
- API URL, run
kubectl cluster-info | grep 'Kubernetes master' | awk '/http/ {print $NF}'
. - Token:
- List the secrets by running:
kubectl get secrets
. Note the name of the secret you need the token for. - Get the token for the appropriate secret by running:
kubectl get secret <SECRET_NAME> -o jsonpath="{['data']['token']}" | base64 -D
.
- List the secrets by running:
- CA certificate, run
kubectl get secret <secret name> -o jsonpath="{['data']['ca\.crt']}" | base64 -D
.
Security implications
CAUTION: Important: The whole cluster security is based on a model where developers are trusted, so only trusted users should be allowed to control your clusters.
The default cluster configuration grants access to a wide set of functionalities needed to successfully build and deploy a containerized application. Bare in mind that the same credentials are used for all the applications running on the cluster.
Access controls
When creating a cluster in GitLab, you will be asked if you would like to create an Attribute-based access control (ABAC) cluster, or a Role-based access control (RBAC) one.
Whether ABAC or RBAC is enabled, GitLab will create the necessary service accounts and privileges in order to install and run GitLab managed applications:
-
If GitLab is creating the cluster, a
gitlab
service account withcluster-admin
privileges will be created in thedefault
namespace, which will be used by GitLab to manage the newly created cluster. -
A project service account with
edit
privileges will be created in the project namespace (also created by GitLab), which will be used in deployment jobs.NOTE: Note: Restricted service account for deployment was introduced in GitLab 11.5.
-
When you install Helm Tiller into your cluster, the
tiller
service account will be created withcluster-admin
privileges in thegitlab-managed-apps
namespace. This service account will be added to the installed Helm Tiller and will be used by Helm to install and run GitLab managed applications. Helm Tiller will also create additional service accounts and other resources for each installed application. Consult the documentation of the Helm charts for each application for details.
If you are adding an existing Kubernetes cluster, ensure the token of the account has administrator privileges for the cluster.
The following sections summarize which resources will be created on ABAC/RBAC clusters.
Attribute-based access control (ABAC)
Name | Kind | Details | Created when |
---|---|---|---|
gitlab |
ServiceAccount |
default namespace |
Creating a new GKE Cluster |
gitlab-token |
Secret |
Token for gitlab ServiceAccount |
Creating a new GKE Cluster |
tiller |
ServiceAccount |
gitlab-managed-apps namespace |
Installing Helm Tiller |
tiller-admin |
ClusterRoleBinding |
cluster-admin roleRef |
Installing Helm Tiller |
Project namespace | ServiceAccount |
Uses namespace of Project | Creating/Adding a new GKE Cluster |
Project namespace | Secret |
Token for project ServiceAccount | Creating/Adding a new GKE Cluster |
Role-based access control (RBAC)
Name | Kind | Details | Created when |
---|---|---|---|
gitlab |
ServiceAccount |
default namespace |
Creating a new GKE Cluster |
gitlab-admin |
ClusterRoleBinding |
cluster-admin roleRef |
Creating a new GKE Cluster |
gitlab-token |
Secret |
Token for gitlab ServiceAccount |
Creating a new GKE Cluster |
tiller |
ServiceAccount |
gitlab-managed-apps namespace |
Installing Helm Tiller |
tiller-admin |
ClusterRoleBinding |
cluster-admin roleRef |
Installing Helm Tiller |
Project namespace | ServiceAccount |
Uses namespace of Project | Creating/Adding a new GKE Cluster |
Project namespace | Secret |
Token for project ServiceAccount | Creating/Adding a new GKE Cluster |
Project namespace | RoleBinding |
edit roleRef |
Creating/Adding a new GKE Cluster |
Security of GitLab Runners
GitLab Runners have the privileged mode enabled by default, which allows them to execute special commands and running Docker in Docker. This functionality is needed to run some of the Auto DevOps jobs. This implies the containers are running in privileged mode and you should, therefore, be aware of some important details.
The privileged flag gives all capabilities to the running container, which in
turn can do almost everything that the host can do. Be aware of the
inherent security risk associated with performing docker run
operations on
arbitrary images as they effectively have root access.
If you don't want to use GitLab Runner in privileged mode, first make sure that you don't have it installed via the applications, and then use the Runner's Helm chart to install it manually.
Installing applications
GitLab provides a one-click install for various applications which can be added directly to your configured cluster. Those applications are needed for Review Apps and deployments.
NOTE: Note:
With the exception of Knative, the applications will be installed in a dedicated namespace called
gitlab-managed-apps
. In case you have added an existing Kubernetes cluster
with Tiller already installed, you should be careful as GitLab cannot
detect it. In this event, installing Tiller via the applications will
result in the cluster having it twice. This can lead to confusion during
deployments.
Application | GitLab version | Description | Helm Chart |
---|---|---|---|
Helm Tiller | 10.2+ | Helm is a package manager for Kubernetes and is required to install all the other applications. It is installed in its own pod inside the cluster which can run the helm CLI in a safe environment. |
n/a |
Ingress | 10.2+ | Ingress can provide load balancing, SSL termination, and name-based virtual hosting. It acts as a web proxy for your applications and is useful if you want to use Auto DevOps or deploy your own web apps. | stable/nginx-ingress |
Cert Manager | 11.6+ | Cert Manager is a native Kubernetes certificate management controller that helps with issuing certificates. Installing Cert Manager on your cluster will issue a certificate by Let's Encrypt and ensure that certificates are valid and up-to-date. | stable/cert-manager |
Prometheus | 10.4+ | Prometheus is an open-source monitoring and alerting system useful to supervise your deployed applications. | stable/prometheus |
GitLab Runner | 10.6+ | GitLab Runner is the open source project that is used to run your jobs and send the results back to GitLab. It is used in conjunction with GitLab CI/CD, the open-source continuous integration service included with GitLab that coordinates the jobs. When installing the GitLab Runner via the applications, it will run in privileged mode by default. Make sure you read the security implications before doing so. | runner/gitlab-runner |
JupyterHub | 11.0+ | JupyterHub is a multi-user service for managing notebooks across a team. Jupyter Notebooks provide a web-based interactive programming environment used for data analysis, visualization, and machine learning. We use this custom Jupyter image that installs additional useful packages on top of the base Jupyter. You will also see ready-to-use DevOps Runbooks built with Nurtch's Rubix library. More information on creating executable runbooks can be found at Nurtch Documentation. Note: Authentication will be enabled for any user of the GitLab server via OAuth2. HTTPS will be supported in a future release. | jupyter/jupyterhub |
Knative | 11.5+ | Knative provides a platform to create, deploy, and manage serverless workloads from a Kubernetes cluster. It is used in conjunction with, and includes Istio to provide an external IP address for all programs hosted by Knative. You will be prompted to enter a wildcard domain where your applications will be exposed. Configure your DNS server to use the external IP address for that domain. For any application created and installed, they will be accessible as <program_name>.<kubernetes_namespace>.<domain_name> . This will require your kubernetes cluster to have RBAC enabled. |
knative/knative |
NOTE: Note: As of GitLab 11.6 Helm Tiller will be upgraded to the latest version supported by GitLab before installing any of the above applications.
Getting the external IP address
NOTE: Note: With the following procedure, a load balancer must be installed in your cluster to obtain the external IP address. You can use either Ingress, or Knative's own load balancer (Istio) if using Knative.
In order to publish your web application, you first need to find the external IP address associated to your load balancer.
Let GitLab fetch the IP address
Introduced in GitLab 10.6.
If you installed Ingress or Knative, you should see the Ingress IP address on this same page within a few minutes. If you don't see this, GitLab might not be able to determine the IP address of your ingress application in which case you should manually determine it.
Manually determining the IP address
If the cluster is on GKE, click the Google Kubernetes Engine link in the
Advanced settings, or go directly to the
Google Kubernetes Engine dashboard
and select the proper project and cluster. Then click Connect and execute
the gcloud
command in a local terminal or using the Cloud Shell.
If the cluster is not on GKE, follow the specific instructions for your
Kubernetes provider to configure kubectl
with the right credentials.
The output of the following examples will show the external IP address of your
cluster. This information can then be used to set up DNS entries and forwarding
rules that allow external access to your deployed applications.
If you installed the Ingress via the Applications, run the following command:
kubectl get svc --namespace=gitlab-managed-apps ingress-nginx-ingress-controller -o jsonpath='{.status.loadBalancer.ingress[0].ip} '
For Istio/Knative, the command will be different:
kubectl get svc --namespace=istio-system knative-ingressgateway -o jsonpath='{.status.loadBalancer.ingress[0].ip} '
Some Kubernetes clusters return a hostname instead, like Amazon EKS. For these platforms, run:
kubectl get service ingress-nginx-ingress-controller -n gitlab-managed-apps -o jsonpath="{.status.loadBalancer.ingress[0].hostname}".
Otherwise, you can list the IP addresses of all load balancers:
kubectl get svc --all-namespaces -o jsonpath='{range.items[?(@.status.loadBalancer.ingress)]}{.status.loadBalancer.ingress[*].ip} '
Using a static IP
By default, an ephemeral external IP address is associated to the cluster's load balancer. If you associate the ephemeral IP with your DNS and the IP changes, your apps will not be able to be reached, and you'd have to change the DNS record again. In order to avoid that, you should change it into a static reserved IP.
Read how to promote an ephemeral external IP address in GKE.
Pointing your DNS at the cluster IP
Once you've set up the static IP, you should associate it to a wildcard DNS
record, in order to be able
to reach your apps. This heavily depends on your domain provider, but in case
you aren't sure, just create an A record with a wildcard host like
*.example.com.
.
Setting the environment scope [PREMIUM]
When adding more than one Kubernetes clusters to your project, you need to differentiate them with an environment scope. The environment scope associates clusters with environments similar to how the environment-specific variables work.
The default environment scope is *
, which means all jobs, regardless of their
environment, will use that cluster. Each scope can only be used by a single
cluster in a project, and a validation error will occur if otherwise.
Also, jobs that don't have an environment keyword set will not be able to access any cluster.
For example, let's say the following Kubernetes clusters exist in a project:
Cluster | Environment scope |
---|---|
Development | * |
Staging | staging/* |
Production | production/* |
And the following environments are set in .gitlab-ci.yml
:
stages:
- test
- deploy
test:
stage: test
script: sh test
deploy to staging:
stage: deploy
script: make deploy
environment:
name: staging/$CI_COMMIT_REF_NAME
url: https://staging.example.com/
deploy to production:
stage: deploy
script: make deploy
environment:
name: production/$CI_COMMIT_REF_NAME
url: https://example.com/
The result will then be:
- The development cluster will be used for the "test" job.
- The staging cluster will be used for the "deploy to staging" job.
- The production cluster will be used for the "deploy to production" job.
Multiple Kubernetes clusters
Introduced in GitLab Premium 10.3.
With GitLab Premium, you can associate more than one Kubernetes clusters to your project. That way you can have different clusters for different environments, like dev, staging, production, etc.
Simply add another cluster, like you did the first time, and make sure to set an environment scope that will differentiate the new cluster with the rest.
Deployment variables
The Kubernetes cluster integration exposes the following deployment variables in the GitLab CI/CD build environment.
Variable | Description |
---|---|
KUBE_URL |
Equal to the API URL. |
KUBE_TOKEN |
The Kubernetes token of the project service account. |
KUBE_NAMESPACE |
The Kubernetes namespace is auto-generated if not specified. The default value is <project_name>-<project_id> . You can overwrite it to use different one if needed, otherwise the KUBE_NAMESPACE variable will receive the default value. |
KUBE_CA_PEM_FILE |
Path to a file containing PEM data. Only present if a custom CA bundle was specified. |
KUBE_CA_PEM |
(deprecated) Raw PEM data. Only if a custom CA bundle was specified. |
KUBECONFIG |
Path to a file containing kubeconfig for this deployment. CA bundle would be embedded if specified. This config also embeds the same token defined in KUBE_TOKEN so you likely will only need this variable. This variable name is also automatically picked up by kubectl so you won't actually need to reference it explicitly if using kubectl . |
NOTE: NOTE:
Prior to GitLab 11.5, KUBE_TOKEN
was the Kubernetes token of the main
service account of the cluster integration.
Troubleshooting missing KUBECONFIG
or KUBE_TOKEN
GitLab will create a new service account specifically for your CI builds. The new service account is created when the cluster is added to the project. Sometimes there may be errors that cause the service account creation to fail.
In such instances, your build will not be passed the KUBECONFIG
or
KUBE_TOKEN
variables and, if you are using Auto DevOps, your Auto DevOps
pipelines will no longer trigger a production
deploy build. You will need to
check the logs to debug why the service
account creation failed.
A common reason for failure is that the token you gave GitLab did not have
cluster-admin
privileges as GitLab expects.
Another common problem for why these variables are not being passed to your
builds is that they must have a matching
environment:name
. If
your build has no environment:name
set, it will not be passed the Kubernetes
credentials.
Enabling or disabling the Kubernetes cluster integration
After you have successfully added your cluster information, you can enable the Kubernetes cluster integration:
- Click the Enabled/Disabled switch
- Hit Save for the changes to take effect
You can now start using your Kubernetes cluster for your deployments.
To disable the Kubernetes cluster integration, follow the same procedure.
Removing the Kubernetes cluster integration
NOTE: Note: You need Maintainer permissions and above to remove a Kubernetes cluster integration.
NOTE: Note:
When you remove a cluster, you only remove its relation to GitLab, not the
cluster itself. To remove the cluster, you can do so by visiting the GKE
dashboard or using kubectl
.
To remove the Kubernetes cluster integration from your project, simply click the Remove integration button. You will then be able to follow the procedure and add a Kubernetes cluster again.
What you can get with the Kubernetes integration
Here's what you can do with GitLab if you enable the Kubernetes integration.
Deploy Boards
Available in GitLab Premium.
GitLab's Deploy Boards offer a consolidated view of the current health and status of each CI environment running on Kubernetes, displaying the status of the pods in the deployment. Developers and other teammates can view the progress and status of a rollout, pod by pod, in the workflow they already use without any need to access Kubernetes.
> Read more about Deploy Boards
Canary Deployments
Available in GitLab Premium.
Leverage Kubernetes' Canary deployments and visualize your canary deployments right inside the Deploy Board, without the need to leave GitLab.
> Read more about Canary Deployments
Kubernetes monitoring
Automatically detect and monitor Kubernetes metrics. Automatic monitoring of NGINX ingress is also supported.
> Read more about Kubernetes monitoring
Auto DevOps
Auto DevOps automatically detects, builds, tests, deploys, and monitors your applications.
To make full use of Auto DevOps(Auto Deploy, Auto Review Apps, and Auto Monitoring) you will need the Kubernetes project integration enabled.
Web terminals
NOTE: Note:
Introduced in GitLab 8.15. You must be the project owner or have maintainer
permissions
to use terminals. Support is limited to the first container in the
first pod of your environment.
When enabled, the Kubernetes service adds web terminal
support to your environments. This is based on the exec
functionality found in
Docker and Kubernetes, so you get a new shell session within your existing
containers. To use this integration, you should deploy to Kubernetes using
the deployment variables above, ensuring any pods you create are labelled with
app=$CI_ENVIRONMENT_SLUG
. GitLab will do the rest!
Read more
Integrating Amazon EKS cluster with GitLab
- Learn how to connect and deploy to an Amazon EKS cluster.