Disclaimer: “Like my earlier posts, I want to be clear, this post is based on a pre-GA version of the vSphere with Kubernetes. While the assumption is that not much should change between the time of writing and when the product becomes generally available, I want readers to be aware that feature behaviour and the user interface could still change before then.”
Supervisor Cluster Overview
Let’s begin with a look at the inventory of my Supervisor Cluster. I have my 3 physical ESXi hosts which now behave as my Kubernetes worker nodes, I have my 3 control plane virtual machines for running the Kubernetes API server and other core K8s components. I also have my NSX-T Edge cluster, deployed to my WLD via VCF 4.0 SDDC Manager.
Another interesting way to view this deployment is via the Kubernetes CLI command, kubectl. Let’s do that next. First, we need to find the Load Balancer IP address assigned to my Supervisor cluster. To find that, navigate to vSphere Client > Workload Management > Clusters. Here we will find the Control Plane Node IP address, highlighted below. This address has been allocated from the Ingress range that was configured during the NSX-T Edge deployment.
If we now point a browser at this IP address, the following landing page is displayed, which importantly for us, include the Kubernetes CLI Tools, kubectl and kubectl-vsphere.
Once these tools are downloaded to a desktop/workstation, we can use them to login to our Supervisor Cluster ‘context’, and query the cluster details.
$ kubectl-vsphere login --vsphere-username firstname.lastname@example.org --server=188.8.131.52 --insecure-skip-tls-verify Password: ********* Logged in successfully. You have access to the following contexts: 184.108.40.206 If the context you wish to use is not in this list, you may need to try logging in again later, or contact your cluster administrator. To change context, use `kubectl config use-context <workload name>` $ kubectl get nodes -o wide NAME STATUS ROLES AGE VERSION INTERNAL-IP EXTERNAL-IP OS-IMAGE KERNEL-VERSION CONTAINER-RUNTIME 422b0e3d39560ed4ea84169e6b77d095 Ready master 2d2h v1.16.7-2+bfe512e5ddaaaa 10.244.0.132 <none> VMware Photon OS/Linux 4.19.84-1.ph3-esx docker://18.9.9 422b341edb277e79d5ec7da8b50bf31a Ready master 2d2h v1.16.7-2+bfe512e5ddaaaa 10.244.0.130 <none> VMware Photon OS/Linux 4.19.84-1.ph3-esx docker://18.9.9 422ba68078f4aaf4c9ba2afb27d4e945 Ready master 2d2h v1.16.7-2+bfe512e5ddaaaa 10.244.0.131 <none> VMware Photon OS/Linux 4.19.84-1.ph3-esx docker://18.9.9 esxi-dell-g.rainpole.com Ready agent 2d2h v1.16.7-sph-30923be 10.27.51.7 <none> <unknown> <unknown> <unknown> esxi-dell-j.rainpole.com Ready agent 2d2h v1.16.7-sph-30923be 10.27.51.122 <none> <unknown> <unknown> <unknown> esxi-dell-l.rainpole.com Ready agent 2d2h v1.16.7-sph-30923be 10.27.51.124 <none> <unknown> <unknown> <unknown> $
We can see the same 3 x control plane VMs and 3 x worker nodes seen from the vCenter inventory. Another thing we can do is query the namespaces that exist on the Supervisor Cluster, which is quite a bit different to native Kubernetes, and even Enterprise PKS.
$ kubectl get ns NAME STATUS AGE default Active 2d3h kube-node-lease Active 2d3h kube-public Active 2d3h kube-system Active 2d3h vmware-system-capw Active 2d3h vmware-system-csi Active 2d3h vmware-system-kubeimage Active 2d3h vmware-system-nsx Active 2d3h vmware-system-registry Active 2d3h vmware-system-tkg Active 2d3h vmware-system-ucs Active 2d3h vmware-system-vmop Active 2d3h $
And if you were so inclined, you could take a look at all of the currently running Pods on the Supervisor Cluster by running kubectl get pods -A.
Creating our first Namespace
Let’s head back to the vSphere Client, and navigate to Workload Management > Namespaces. This will take us to the following landing page where we can create our first namespace.
A namespace here is simply a way of dividing the resources of the cluster between multiple consumers. For all intents and purpose, we can look at namespaces on the Supervisor Cluster as being very similar to vSphere Resource Pools. When creating the namespace you need to choose a Cluster object from the inventory, and then provide a name and optional description. In this example, I have simply called it cormac-ns.
On successfully creating the namespace, you will be placed into the following view in the vSphere Client. The Status window tells us that the namespace was created successfully. It also has some inventory information, as well as a link to the tools page, which we have already visited. Capacity and Usage allows us to edit CPU, Memory and Storage limits for the namespace. Tanzu Kubernetes is only applicable when we deploy a Tanzu Kubernetes Grid (TKG) guest cluster. We will revisit this in an upcoming post.
I think much of the settings and information displayed here is quite straight-forward to digest. I will mentioned Storage however. You will need to ‘Add Storage’ to the namespace by selecting a Storage Policy from the available list of policies created on this vSphere environment. I am going to keep things simple by selecting the default vSAN storage policy, but of course you can get more granular, depending on the number of hosts that are in the cluster, as well as the data services that you have enabled on the vSAN cluster.
After the storage policy (or policies) has been assigned to the namespace, it becomes available as a Kubernetes Storage Class in our namespace. Let’s return to the kubectl CLI and demonstrate this. First, we will see that our new namespace (cormac-ns) is created. Then we will logout and log back in to the Supervisor Cluster to pick up our new ‘context’. Note that there may be other ways to do this, but this is the way that I found to work for me. When we log back in, we can see that the cormac-ns namespace is already set as the context (* against it), so no need to change the context after logging back in.
$ kubectl get ns NAME STATUS AGE cormac-ns Active 15m default Active 2d3h kube-node-lease Active 2d3h kube-public Active 2d3h kube-system Active 2d3h vmware-system-capw Active 2d3h vmware-system-csi Active 2d3h vmware-system-kubeimage Active 2d3h vmware-system-nsx Active 2d3h vmware-system-registry Active 2d3h vmware-system-tkg Active 2d3h vmware-system-ucs Active 2d3h vmware-system-vmop Active 2d3h $ kubectl config get-contexts CURRENT NAME CLUSTER AUTHINFO NAMESPACE * 220.127.116.11 18.104.22.168 wcp:22.214.171.124:email@example.com $ kubectl-vsphere logout Your KUBECONFIG context has changed. The current KUBECONFIG context is unset. To change context, use `kubectl config use-context <workload name>` Logged out of all vSphere namespaces. $ kubectl-vsphere login --vsphere-username firstname.lastname@example.org --server=126.96.36.199 --insecure-skip-tls-verify Password: Logged in successfully. You have access to the following contexts: 188.8.131.52 cormac-ns If the context you wish to use is not in this list, you may need to try logging in again later, or contact your cluster administrator. To change context, use `kubectl config use-context <workload name>` $ kubectl config get-contexts CURRENT NAME CLUSTER AUTHINFO NAMESPACE 184.108.40.206 220.127.116.11 wcp:18.104.22.168:email@example.com * cormac-ns 22.214.171.124 wcp:126.96.36.199:firstname.lastname@example.org cormac-ns $ kubectl get sc NAME PROVISIONER AGE vsan-default-storage-policy csi.vsphere.vmware.com 2d2h $
With the final command above, displaying of Storage Classes, we can see that the default vSAN storage policy is now available for use by Persistent Volumes in the Supervisor Cluster. The Storage Window in the Namespace Summary in the vSphere UI will report the number of Persistent Volume Claims that exist in the namespace. We will see this shortly.
We will leave the namespace for the present and do one more action. We will now enable the Harbor Image Registry on the Supervisor Cluster. Once that is enabled, we will push an image up to the Image Registry and use it to deploy our first application on the Supervisor Cluster.
Enable Harbor Image Registry
A really neat feature of the Supervisor Cluster is that it includes an embedded Harbor Image Registry for container images. To enable the Image Registry, select the Cluster object in the vCenter inventory then navigate to Configure > Namespaces > Image Registry as shown below:
Click on the Enable Harbor button. It prompts you to choose a Storage Policy for the persistent volumes required by the Harbor application (I chose vSAN default once again). Immediately a new namespace is created called vmware-system-registry, and this is where the PodVMs that back the Harbor application are deployed. There are 7 PodVMs created in total, and when deployment completes, a link to the Harbor UI is provided.
And because the Cloud Native Storage (CNS) is fully integrated with the Supervisor Cluster, we can see the 4 x Persistent Volumes that were deployed on behalf of the Harbor application. Pretty cool, huh?
Let’s also take a look at the Harbor Image Registry namespace as that has some interesting info now.
We can see the Storage window now report 4 PVCs, as well as a Storage Policy (vSAN default) with a 200GB limit. The Capacity and Usage is also showing some usage. If we click on the EDIT LIMITS and expand the Storage, we see that although there is no overall Storage Limit, the amount of storage that can be consumed by the vSAN default storage policy is 200GB.
The last item to point out is that there are now 7 running Pods (blue line). Some Pods were in a state of Pending (yellow line), but now they are running – this is normal. There are no failed Pods (red line).
Push an Image to Harbor
The next step is to push an image to the Harbor Image Registry. The first step is to establish trust. To do that, you will need to login to Harbor UI using SSO credentials, and get the Registry Certificate from the Repository, as shown below.
This certificate will then have to be copied to your docker certificates location on your local laptop/desktop/workstation. On my Ubuntu 17.10, this location is in /etc/docker/certs.d. You then create a directory to match the FQDN or IP address of your Harbor Registry and place the downloaded registry cert there. Otherwise you will hit x509 errors try to communicate to the registry.
With the cert in place, we can pull down an image from an internet repository, tag it and push it to our Harbor registry. The push command format is registry/project/repository:tag. So my Harbor registry is 188.8.131.52 (another Ingress IP address provided by NSX-T). My project is cormac-ns, created automatically for every namespace in the Supervisor Cluster. The repository is busybox and since no tag is provide, :latest is used.
$ docker pull k8s.gcr.io/busybox Using default tag: latest latest: Pulling from busybox a3ed95caeb02: Pull complete 138cfc514ce4: Pull complete Digest: sha256:d8d3bc2c183ed2f9f10e7258f84971202325ee6011ba137112e01e30f206de67 Status: Downloaded newer image for k8s.gcr.io/busybox:latest k8s.gcr.io/busybox:latest $ docker tag k8s.gcr.io/busybox 184.108.40.206/cormac-ns/busybox $ docker push 220.127.116.11/cormac-ns/busybox The push refers to repository [18.104.22.168/cormac-ns/busybox] 5f70bf18a086: Pushed 44c2569c4504: Pushed latest: digest: sha256:d2af0ba9eb4c9ec7b138f3989d9bb0c9651c92831465eae281430e2b254afe0d size: 1146 $
The image is now stored in our Harbor Image Registry and can be referenced by any manifest YAML files that we use to deploy apps on the Supervisor Cluster.
Create our first StatefulSet
Just to complete this first exercise with vSphere with Kubernetes, I’ll create a small application in my own namespace. I will download the image, push it to Harbor and then use it within my own manifest file. The application will be my trusty Cassandra StatefulSet application that I’ve used many times before. You’ve seen how to do the push and pull to Harbor, so I won’t repeat the steps here. Instead, I will simple create the service and the 3 x replica StatefulSet for the application and query the StatefulSet, including its Service, Pods and PVCs, after deployment.
Let’s use kubectl to query this StatefulSet after it has been deployed:
$ kubectl get sts NAME READY AGE cassandra 3/3 6m57s
This is the Service:
$ kubectl get svc NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE cassandra ClusterIP 10.96.0.35 <none> 9042/TCP 8m38s
These are the Pods:
$ kubectl get pods NAME READY STATUS RESTARTS AGE cassandra-0 1/1 Running 0 6m56s cassandra-1 1/1 Running 0 6m8s cassandra-2 1/1 Running 0 91s
And finally the PVCs, which also appear in CNS of course:
$ kubectl get pvc NAME STATUS VOLUME CAPACITY ACCESS MODES STORAGECLASS AGE cassandra-data-cassandra-0 Bound pvc-019d8f46-ccc8-402c-a038-6acd36abd103 1Gi RWO vsan-default-storage-policy 7m46s cassandra-data-cassandra-1 Bound pvc-3143a4d4-0d23-482a-8720-5e2912cd3e33 1Gi RWO vsan-default-storage-policy 6m58s cassandra-data-cassandra-2 Bound pvc-a4c5e528-7868-46d0-9df0-b5304ed90925 1Gi RWO vsan-default-storage-policy 3m7s
Here are the volumes in CNS, where I filtered on the app:cassandra, so we do not display the Harbor volumes that we already looked at earlier:
Let’s now return to the Namespace view in vSphere Client. We can now see some more interesting details around Storage, Capacity and Usage, and Pods. There are now 3 running Pods (I requested 3 replicas in my StatefulSet manifest) along with 3 Persistent Volume Claims, which we saw in the CNS view previously.
Pretty neat. OK – I hope this has given you a reasonable appreciation of some of the things that can be done in the Supervisor Cluster. Check back through my previous VCF 4.0 posts if you want to see how easy it was to deploy it in the first place. Stay tuned, and we will take a close look at the Tanzu Kubernetes Grid guest cluster, deployed in a namespace, in a future post.