Air-gapped environment

SUSE® Rancher Prime Cluster API provides support for an air-gapped environment out-of-the-box by leveraging features of the Cluster API Operator, the required dependency for installing SUSE® Rancher Prime Cluster API.

To provision and configure Cluster API providers, Turtles uses the CAPIProvider resource to allow managing Cluster API Operator manifests in a declarative way. Every field provided by the upstream CAPI Operator resource for the desired spec.type is also available in the spec of the CAPIProvider resouce.

To install Cluster API providers in an air-gapped environment the following will need to be done:

  1. Configure the Cluster API Operator for an air-gapped environment:

    • The operator chart will be fetched and stored as a part of the Turtles chart.

    • Provide image overrides for the operator from an accessible image repository.

  2. Configure Cluster API providers for an air-gapped environment:

    • Provide fetch configuration for each provider from an accessible location (e.g., an internal github/gitlab server) or from pre-created ConfigMaps within the cluster.

    • Provide image overrides for each provider to pull images from an accessible image repository.

  3. Configure SUSE® Rancher Prime Cluster API for an air-gapped environment:

    • Collect and publish SUSE® Rancher Prime Cluster API images and publish to the private registry. Example of cert-manager installation for the reference.

    • Provide fetch configuration and image values for core and caprke2 providers in values.yaml.

    • Provider image value for the Cluster API Operator helm chart dependency in values.yaml. Image values specified with the cluster-api-operator key will be passed along to the Cluster API Operator.

Example Usage

As an admin, I need to fetch the vSphere provider (CAPV) components from within the cluster because I am working in an air-gapped environment.

In this example, there is a ConfigMap in the capv-system namespace that defines the components and metadata of the provider. It can be created manually or by running the following commands:

# Get the file contents from the GitHub release
curl -L https://github.com/kubernetes-sigs/cluster-api-provider-vsphere/releases/download/v1.8.5/infrastructure-components.yaml -o components.yaml
curl -L https://github.com/kubernetes-sigs/cluster-api-provider-vsphere/releases/download/v1.8.5/metadata.yaml -o metadata.yaml

# Create the configmap from the files
kubectl create configmap v1.8.5 --namespace=capv-system --from-file=components=components.yaml --from-file=metadata=metadata.yaml --dry-run=client -o yaml > configmap.yaml

This command example would need to be adapted to the provider and version you want to use. The resulting config map will look similar to the example below:

apiVersion: v1
kind: ConfigMap
metadata:
  labels:
    provider-components: vsphere
  name: v1.8.5
  namespace: capv-system
data:
  components: |
    # Components for v1.8.5 YAML go here
  metadata: |
    # Metadata information goes here

A CAPIProvider resource will need to be created to represent the vSphere infrastructure provider. It will need to be configured with a fetchConfig. The label selector allows the operator to determine the available versions of the vSphere provider and the Kubernetes resources that need to be deployed (i.e. contained within ConfigMaps which match the label selector).

Since the provider’s version is marked as v1.8.5, the operator uses the components information from the ConfigMap with matching label to install the vSphere provider.

apiVersion: turtles-capi.cattle.io/v1alpha1
kind: CAPIProvider
metadata:
  name: vsphere
  namespace: capv-system
spec:
  name: vsphere
  type: infrastructure
  version: v1.8.5
  configSecret:
    name: vsphere-variables
  fetchConfig:
    selector:
      matchLabels:
        provider-components: vsphere
  deployment:
    containers:
    - name: manager
      imageUrl: "gcr.io/myregistry/capv-controller:v1.8.5-foo"
  variables:
    CLUSTER_TOPOLOGY: "true"
    EXP_CLUSTER_RESOURCE_SET: "true"
    EXP_MACHINE_POOL: "true"

Additionally the CAPIProvider overrides the container image to use for the provider using the deployment.containers[].imageUrl field. This allows the operator to pull the image from a registry within the air-gapped environment.

Situation when manifests do not fit into ConfigMap

There is a limit on the maximum size of a ConfigMap - 1MiB. If the manifests do not fit into this size, Kubernetes will generate an error and provider installation fail. To avoid this, you can archive the manifests and put them in the ConfigMap that way.

For example, you have two files: components.yaml and metadata.yaml. To create a working config map you need:

  1. Archive components.yaml using gzip cli tool

    gzip -c components.yaml > components.gz
  2. Create a ConfigMap manifest from the archived data

    kubectl create configmap v1.8.5 --namespace=capv-system --from-file=components=components.gz --from-file=metadata=metadata.yaml --dry-run=client -o yaml > configmap.yaml
  3. Edit the file by adding "provider.cluster.x-k8s.io/compressed: true" annotation

    yq eval -i '.metadata.annotations += {"provider.cluster.x-k8s.io/compressed": "true"}' configmap.yaml
    without this annotation operator won’t be able to determine if the data is compressed or not.
  4. Add labels that will be used to match the ConfigMap in fetchConfig section of the provider

    yq eval -i '.metadata.labels += {"my-label": "label-value"}' configmap.yaml
  5. Create a ConfigMap in your kubernetes cluster using kubectl

    kubectl create -f configmap.yaml