Kubernetes Secrets in MicroK8s

Kubernetes Secrets in MicroK8s

A quick dive into how secrets are managed and stored in Kubernetes, MicroK8s in particular, noting some of the related security concerns.

Table of contents

Installing MicroK8s

Working with Kubernetes secrets


If you are looking for a desktop version of Kubernetes in your everyday development work on your laptop or workstation, you may consider MicroK8s. MicroK8s is a low footprint, minimal Kubernetes distribution (by Canonical) for developers, cloud, clusters, Edge, and IoT.

One of the main features of MicroK8s is the built-in high availability, which could make it an attractive option in production-grade cluster deployments. As you may expect, production environments are subject to stricter security requirements. In this article, we'll look at how secrets are stored in MicroK8s and how secure they might be.

Let's start by installing MicroK8s.

Installing MicroK8s

You may follow the installation steps described here, depending on your platform of choice. In this article, we'll cover MicroK8s on macOS, Ubuntu, and RHEL/CentOS. Below are the steps for installing MicroK8s on each platform, at the time of this writing.


We use Homebrew to install MicroK8s. On macOS, MicroK8s is installed using Multipass, a lightweight cross-platform VM manager. Run the following commands and, when prompted to use and configure Multipass, answer yes:

brew update
brew install ubuntu/microk8s/microk8s

Now, you can install MicroK8s with the following command:

microk8s install

By default, the MicroK8s installer creates a Multipass VM with 3 vCPUs, 4 GB RAM, and 48 GB disk space. You can be more specific, by specifying the number of vCPUs (2), memory (4 GB), and disk space (30 GB), with the following command:

microk8s install --cpu 2 --mem 4 --disk 30

Since on macOS MicroK8s runs inside a VM, the easiest way to interact with MicroK8s is via the kubectl CLI. Let's install it:

brew install kubernetes-cli

Next, point the local kubeconfig to the MicroK8s cluster:

mkdir ~/.kube
microk8s config > ~/.kube/config

Make sure you can interact with MicroK8s:

kubectl get nodes

The command should yield the following (or similar) output:

microk8s-vm   Ready    <none>   127m   v1.21.0-3+121713cef81e03

Let's look at how to install MicroK8s on Ubuntu next.


On your Linux system, make sure swap is turned off:

sudo swapoff -a
sudo sed -i '/\s*swap\s*/s/^\(.*\)$/# \1/g' /etc/fstab

On Ubuntu, we use Snap to install MicroK8s. The following command installs version 1.21 of MicroK8s:

sudo snap install microk8s --classic --channel=1.21/stable

Next, we'll look at how to install MicroK8s on RHEL/CentOS.


On your Linux system, make sure swap is turned off:

sudo swapoff -a
sudo sed -i '/\s*swap\s*/s/^\(.*\)$/# \1/g' /etc/fstab

On CentOS 7.6 and newer, we need to install the Snap package manager from the EPEL (Extra Packages for Enterprise Linux) repository:

sudo yum install epel-release

Next, install and configure Snap:

sudo yum install -y snapd
sudo systemctl enable --now snapd.socket
sudo ln -s /var/lib/snapd/snap /snap

Finally, install MicroK8s, using a stable channel (e.g. 1.21):

sudo snap install microk8s --classic --channel=1.21/stable

With MicroK8s installed, let's create some arbitrary Kubernetes secrets.

Working with Kubernetes secrets

We'll use the kubectl command to create a generic Kubernetes secret (hello-login), storing some login credentials (username and password):

kubectl create secret generic hello-login \
    --from-literal="username=admin" \

After the secret has been created, we can retrieve its JSON representation with the following command:

kubectl get secret hello-login -o json

You'll notice the related data element containing the secrets:

"data": {
    "password": "UEBzc3cwcmQ=",
    "username": "YWRtaW4="

Or, you can directly retrieve it with:

kubectl get secret hello-login -o jsonpath='{ .data }' && echo

The credentials are base64-encoded strings and you can decode them with the following commands, revealing the related secrets in clear text:

echo "YWRtaW4=" | base64 --decode && echo
echo "UEBzc3cwcmQ=" | base64 --decode && echo

So far, so good. As Kubernetes administrators, we are entitled to view and handle secrets at our discretion. But are these secrets secure? We know they are stored in MicroK8s' persistent storage. Standard Kubernetes distributions use etcd as their storage backend while MicroK8s uses Dqlite. Dqlite ("Distributed SQLite") is a fault-tolerant implementation of SQLite, a lightweight, fast, embedded, and persistent SQL database, written in C.

We can, of course, configure MicroK8s to use etcd but the question remains: are the secrets encrypted? This question is among the first we'd face in the security review of a Kubernetes deployment.

So, let's take a closer look at our secrets in MicroK8s and Dqlite.

MicroK8s secrets and Dqlite

A brief look at the source code of MicroK8s on Github reveals that the Dqlite endpoint is localhost:19001 and the related database files are in ${SNAP_DATA}/var/kubernetes/backend. In our case, the ${SNAP_DATA} directory is /var/snap/microk8s/current.

On a macOS system, for the next steps, you need MicroK8s terminal access. The following command connects to the related Multipass VM: multipass connect microk8s-vm

Before connecting to the Dqlite database using your terminal, let's define a helper variable pointing to the Dqlite database directory:


Next, we use the dqlite command-line utility to connect to the Dqlite database:

sudo /snap/microk8s/current/bin/dqlite \
    -c ${dbdir}/cluster.crt \
    -k ${dbdir}/cluster.key \
    -s localhost:19001 k8s

At the dqlite> command-line prompt, query the current tables in the database schema:

select name from sqlite_master where type = "table"

We get the following output:


The MicroK8s data it's in the kine table. Let's look for anything similar to our hello-login secret:

select name from kine where name like "%hello%"

We get the following output:


Now, let's query our hello-login secret:

select name, value from kine where name = "/registry/secrets/default/hello-login"

Here's an excerpt from the output:

/registry/secrets/default/hello-login|[107 56 115 0 ...]

The output hints to a key-value pair, with the key /registry/secrets/default/hello-login, and the value pointing to a sequence of ASCII character codes: 107=k, 56=8, 115=s, etc. Let's copy the entire sequence of ASCII character codes within the square brackets and assign it to a variable value (showing only an excerpt below):

value="107 56 115 ..."

To get a more readable and user-friendly representation of the related content, run the following command to decode the sequence of ASCII character codes into plain text:

echo "$value" | awk '{
  for(i=1; i<=NF; i++)
    if ($i > 31 && $i < 127 || $i == 10)
      printf("%c", $i);
      printf(" ", $i);
  print "";

We notice that the output is not encrypted, and we can see our secrets in clear:


 v1  Secret   

 hello-login    default" *$079b6736-74ab-43e9-aa08-a465e19fa8a02 8 B         z   s
 kubectl-create  Update  v1"         2 FieldsV1:A
 password  P@ssw0rd  
 username  admin  Opaque  "

While unencrypted secrets could be safe within the security context of the MicroK8s application domain, an attacker could still gain access to the underlying storage and read the data. This is where "encryption at rest" becomes relevant, to ensure the data is encrypted on disk. Let's look at how to encrypt our secrets in MicroK8s.

Encrypting secrets at rest in MicroK8s

First, let's generate a 32-byte random secret to serve as our encryption key:

head -c 32 /dev/urandom | base64

In our case, the output is:


Next, we create a simple Kubernetes encryption configuration file, named k8s-crypto.yaml. You may save this file to a location of your choice. We'll put it in our home folder (e.g., /home/ubuntu/). Copy/paste the key generated above into the secret attribute:

apiVersion: apiserver.config.k8s.io/v1
kind: EncryptionConfiguration
  - resources:
    - secrets
    - aescbc:
        - name: k8s-crypto
          secret: IQrWOCP9g8yQmeCTMdZBrhPVG8WfgEo31B7ueLgFjo8=
    - identity: {}

As you may notice, we're using a reasonably strong encryption method with AES and CBC. Before we go into configuring the MicroK8s API server to use encryption at rest, let's find out more about the kube-apiserver configuration. Look up the kubelite process with the following command:

pgrep -an kubelite

In our case, the output is (reformatted for a better view):

/snap/microk8s/2210/kubelite \
  --scheduler-args-file=/var/snap/microk8s/2210/args/kube-scheduler \
  --controller-manager-args-file=/var/snap/microk8s/2210/args/kube-controller-manager \
  --proxy-args-file=/var/snap/microk8s/2210/args/kube-proxy \
  --kubelet-args-file=/var/snap/microk8s/2210/args/kubelet \
  --apiserver-args-file=/var/snap/microk8s/2210/args/kube-apiserver \
  --kubeconfig-file=/var/snap/microk8s/2210/credentials/client.config \

We can see that the --apiserver-args-file option parameter points to /var/snap/microk8s/2210/args/kube-apiserver. Edit the /var/snap/microk8s/2210/args/kube-apiserver file (e.g., sudo vi ...) and add the following line, pointing the encryption provider configuration to our k8s-crypto.yaml file:


Save the file and restart the MicroK8s daemon-kubelite service:

sudo systemctl restart snap.microk8s.daemon-kubelite

Our old secrets, including hello-login, would still be unencrypted, since secrets are only encrypted on write. The following command performs an in-place update of all secrets in MicroK8s and re-encrypts them according to the encryption provider we just configured:

kubectl get secrets --all-namespaces -o json | kubectl replace -f -

Depending on the size of your cluster, the command may take a while, or you may have to run it in smaller batches, targeting individual namespaces. Alternatively, you can delete the hello-login secret (kubectl delete secret hello-login) and re-create it.

Now, let's retrace the steps described in the MicroK8s Secrets and Dqlite section and retrieve our hello-login secret again. You'll see that, this time the secret is encrypted.

MicroK8s could be a viable solution for a low-footprint Kubernetes cluster and, with a bit of tinkering, you can have your secrets encrypted at rest.


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