Pre-provisioned Air-gapped Define Environment
Fulfill the prerequisites for using a pre-provisioned infrastructure when Air-Gapped
The instructions below outline how to fulfill the prerequisites for using pre-provisioned infrastructure when using air-gapped. In DKP 2.5.0, there is a new complete DKP air-gapped bundle available to download which contains all the DKP components needed for air-gapped installation. (i.e. dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz
)
Air-Gapped Registry Prerequisites
DKP in an air-gapped environment requires a local container registry of trusted images to enable production level Kubernetes cluster management. In an environment with access to the internet, you retrieve artifacts from specialized repositories dedicated to them such as Docker images contained in DockerHub and Helm Charts that come from a dedicated Helm Chart repository. However, in an air-gapped environment, you need local repositories to store Helm charts, Docker images and other artifacts. Tools such as jFrog, Harbor and Nexus handle multiple types of artifacts in one local repository.
JFrog Artifactory - If you use Jfrog Artifactory or Jfrog Container Registry, you must update to a new version of the software. Any build newer than version 7.11 will work, as we have confirmed that older versions are not compatible.
Nexus Registry - If you use Nexus Registry, there was an issue that prevented usage with DKP 2.X and OCI Images, but support for OCI Images was added here in this publicly available Jira ticket:[NEXUS-21087] Support OCI registry format - Sonatype JIRA
Harbor Registry - Any newer version than Harbor Registry v2.1.1-5f52168e will support OCI images.
Bastion Host
If you have not set up a Bastion Host yet, refer to that section of the Documentation.
Load the Bootstrap Image
Assuming you have downloaded
dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz
from the download site mentioned above, extract the tarball to a local directory:CODEtar -xzvf dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz && cd dkp-v2.5.2
Load the bootstrap Docker image on your bastion machine:
CODEdocker load -i konvoy-bootstrap-image-v2.5.2.tar
CODEpodman load -i konvoy-bootstrap-image-v2.5.2.tar
Copy Air-gapped Artifacts onto Cluster Hosts
Using the Konvoy Image Builder, you can copy the required artifacts (such as charts, java or OS packages like RPM or Deb) onto your cluster hosts.
Assuming you have downloaded
dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz
, extract the tarball to a local directory:CODEtar -xzvf dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz && cd dkp-v2.5.2/kib
The Kubernetes image bundle will be located in
kib/artifacts/images
and you will want to verify image and artifacts.Verify the image bundles exist in
kib/artifacts/images
:CODE$ ls kib/artifacts/images/ kubernetes-images-1.25.4-d2iq.1.tar kubernetes-images-1.25.4-d2iq.1-fips.tar
Verify the artifacts for your OS exist in the
artifacts/
directory and export the appropriate variables:CODE$ ls kib/artifacts/ 1.25.4_centos_7_x86_64.tar.gz 1.25.4_redhat_8_x86_64_fips.tar.gz containerd-1.6.17-d2iq.1-rhel-7.9-x86_64.tar.gz containerd-1.6.17-d2iq.1-rhel-8.6-x86_64_fips.tar.gz pip-packages.tar.gz 1.25.4_centos_7_x86_64_fips.tar.gz 1.25.4_rocky_9_x86_64.tar.gz containerd-1.6.17-d2iq.1-rhel-7.9-x86_64_fips.tar.gz containerd-1.6.17-d2iq.1-rocky-9.0-x86_64.tar.gz 1.25.4_redhat_7_x86_64.tar.gz 1.25.4_ubuntu_20_x86_64.tar.gz containerd-1.6.17-d2iq.1-rhel-8.4-x86_64.tar.gz containerd-1.6.17-d2iq.1-rocky-9.1-x86_64.tar.gz 1.25.4_redhat_7_x86_64_fips.tar.gz containerd-1.6.17-d2iq.1-centos-7.9-x86_64.tar.gz containerd-1.6.17-d2iq.1-rhel-8.4-x86_64_fips.tar.gz containerd-1.6.17-d2iq.1-ubuntu-20.04-x86_64.tar.gz 1.25.4_redhat_8_x86_64.tar.gz containerd-1.6.17-d2iq.1-centos-7.9-x86_64_fips.tar.gz containerd-1.6.17-d2iq.1-rhel-8.6-x86_64.tar.gz images
For example, for RHEL 8.4 you would set:
CODEexport OS_PACKAGES_BUNDLE=1.25.4_redhat_8_x86_64.tar.gz export CONTAINERD_BUNDLE=containerd-1.6.17-d2iq.1-rhel-8.4-x86_64.tar.gz
Export the following environment variables, ensuring that all control plane and worker nodes are included:
CODEexport CONTROL_PLANE_1_ADDRESS="<control-plane-address-1>" export CONTROL_PLANE_2_ADDRESS="<control-plane-address-2>" export CONTROL_PLANE_3_ADDRESS="<control-plane-address-3>" export WORKER_1_ADDRESS="<worker-address-1>" export WORKER_2_ADDRESS="<worker-address-2>" export WORKER_3_ADDRESS="<worker-address-3>" export WORKER_4_ADDRESS="<worker-address-4>" export SSH_USER="<ssh-user>" export SSH_PRIVATE_KEY_FILE="<private key file>"
SSH_PRIVATE_KEY_FILE
must be either the name of the SSH private key file in your working directory or an absolute path to the file in your user’s home directory.Generate an
inventory.yaml
which is automatically picked up by thekonvoy-image upload
in the next step. Thisinventory.yaml
should exclude any GPU workers, which will be handled in steps #6-7.CODEcat <<EOF > inventory.yaml all: vars: ansible_user: $SSH_USER ansible_port: 22 ansible_ssh_private_key_file: $SSH_PRIVATE_KEY_FILE hosts: $CONTROL_PLANE_1_ADDRESS: ansible_host: $CONTROL_PLANE_1_ADDRESS $CONTROL_PLANE_2_ADDRESS: ansible_host: $CONTROL_PLANE_2_ADDRESS $CONTROL_PLANE_3_ADDRESS: ansible_host: $CONTROL_PLANE_3_ADDRESS $WORKER_1_ADDRESS: ansible_host: $WORKER_1_ADDRESS $WORKER_2_ADDRESS: ansible_host: $WORKER_2_ADDRESS $WORKER_3_ADDRESS: ansible_host: $WORKER_3_ADDRESS $WORKER_4_ADDRESS: ansible_host: $WORKER_4_ADDRESS EOF
Upload the artifacts onto cluster hosts with the following command:
BASHkonvoy-image upload artifacts \ --container-images-dir=./artifacts/images/ \ --os-packages-bundle=./artifacts/$OS_PACKAGES_BUNDLE \ --containerd-bundle=artifacts/$CONTAINERD_BUNDLE \ --pip-packages-bundle=./artifacts/pip-packages.tar.gz
The
konvoy-image upload artifacts
command copies all OS packages and other artifacts onto each of the machines in your inventory. When you create the cluster, the provisioning process connects to each node and runs commands to install those artifacts and consequently Kubernetes running. KIB uses variable overrides to specify base image and container images to use in your new machine image. The variable overrides files for NVIDIA and FIPS can be ignored unless adding an overlay feature.
Use the --overrides flag and reference either
fips.yaml
oroffline-fips.yaml
manifests located in the overrides directory or see these pages in the documentation:
GPU Only Steps
If the NVIDIA runfile installer has not been downloaded, then retrieve and install the download first by running the following command. The first line in the command below downloads and installs the runfile and the second line places it in the artifacts directory.
- CODE
curl -O https://download.nvidia.com/XFree86/Linux-x86_64/470.82.01/NVIDIA-Linux-x86_64-470.82.01.run mv NVIDIA-Linux-x86_64-470.82.01.run artifacts
6. Create an inventory for GPU Nodes.
cat <<EOF > gpu_inventory.yaml
all:
vars:
ansible_port: 22
ansible_ssh_private_key_file: $SSH_PRIVATE_KEY_FILE
ansible_user: $SSH_USER
hosts:
$GPU_WORKER_1_ADDRESS:
ansible_host: $GPU_WORKER_1_ADDRESS
EOF
7. Upload the artifacts to the gpu nodepool with the nvidia-runfile
flag
konvoy-image upload artifacts --inventory-file=gpu_inventory.yaml \
--container-images-dir=./artifacts/images/ \
--os-packages-bundle=./artifacts/$OS_PACKAGES_BUNDLE \
--containerd-bundle=artifacts/$CONTAINERD_BUNDLE \
--pip-packages-bundle=./artifacts/pip-packages.tar.gz \
--nvidia-runfile=./artifacts/NVIDIA-Linux-x86_64-470.82.01.run
KIB uses variable overrides to specify base image and container images to use in your new machine image. The variable overrides files for NVIDIA and FIPS can be ignored unless adding an overlay feature.
Use the overrides flag (EX:
--overrides overrides/fips.yaml
) and reference eitherfips.yaml
oroffline-fips.yaml
manifests located in the overrides directory or see these pages in the documentation:
Load your Registry
Before creating a Kubernetes cluster, you need the required images in a local registry if operating in an air-gapped environment. This registry must be accessible from both the bastion machine and either the AWS EC2 instances (if deploying to AWS) or other machines that will be created for the Kubernetes cluster.
If you do not already have a local registry set up, please refer to Local Registry Tools page for more information.
Assuming you have downloaded
dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz
, extract the tarball to a local directory:CODEtar -xzvf dkp-air-gapped-bundle_v2.5.2_linux_amd64.tar.gz && cd dkp-v2.5.2
Set an environment variable with your registry address with this command:
CODEexport REGISTRY_ADDRESS=<registry-address>:<registry-port> export REGISTRY_USERNAME=<username> export REGISTRY_PASSWORD=<password>
Execute the following command to load the air-gapped image bundle into your private registry:
CODEdkp push image-bundle --image-bundle ./container-images/konvoy-image-bundle-v2.5.2.tar --to-registry $REGISTRY_ADDRESS --to-registry-username $REGISTRY_USERNAME --to-registry-password $REGISTRY_PASSWORD
It may take some time to push all the images to your image registry, depending on the performance of the network between the machine you are running the script on and the registry.