Encrypt PVCs using CSI and Kubernetes Secrets in IKS
This article discusses the PVC encryption methods used with the Kubernetes Container Storage Interface. For details about using Portworx with CSI, refer to the Portworx with CSI page.
Prerequisites
In order to perform the steps in this document, you must have Portworx with CSI enabled.
Encrypt your volumes
You can encrypt your volumes in one of two ways:
- Per StorageClass
- Per PVC
Encrypt your volumes per StorageClass
You can encrypt your volumes by specifying the encryption key in a Kubernetes secret. This secret can be same as the one created to host the authentication token. Using this method, you can handle both authentication and encryption together, and multiple PVCs referring to this storage class can use the same secret for encryption.
Step 1: Create a Kubernetes secret that contains the passphrase used for encrypting the Portworx volume
Enter the following command, specifying your own passphrase in mysecret-passcode-for-encryption
, which encrypts the PVC:
kubectl create secret generic volume-secrets -n kube-system --from-literal=mysql-pvc-secret-key=<mysecret-passcode-for-encryption>
Step 2: Create a CSI Kubernetes secret that points to the Kubernetes encryption secret
The CSI implementation reads the Kubernetes secret px-secret
and passes its contents to Portworx. The px-secret
must contain values for the following fields, which tell Portworx which Kubernetes secret to fetch the encryption passphrase from:
SECRET_NAME
: The name you have given your secret (in this case,volume-secrets
).SECRET_KEY
: The key for accessing the encryption key in the referencedSECRET_CONTEXT
/SECRET_NAME
.SECRET_CONTEXT
: The namespace in which you created the secret (in this case,kube-system
).
Enter the following command:
kubectl create secret generic px-secret -n kube-system --from-literal=SECRET_NAME=volume-secrets --from-literal=SECRET_KEY=mysql-pvc-secret-key --from-literal=SECRET_CONTEXT=kube-system
Step 3: Create a CSI storage class for encrypted PVC
Create the storage class which refers to the CSI secret you created in step 2 above. Specify the following:
csi.storage.k8s.io/provisioner-secret-name
: the name of your CSI secretcsi.storage.k8s.io/provisioner-secret-namespace
: the namespace in which your CSI secret is locatedcsi.storage.k8s.io/node-publish-secret-name
: the name of your CSI secretcsi.storage.k8s.io/node-publish-secret-namespace
: the namespace in which your CSI secret is located
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: px-csi-db-encrypted-k8s
provisioner: pxd.portworx.com
parameters:
repl: "3"
secure: "true"
io_profile: auto
io_priority: "high"
csi.storage.k8s.io/provisioner-secret-name: px-secret
csi.storage.k8s.io/provisioner-secret-namespace: kube-system
csi.storage.k8s.io/node-publish-secret-name: px-secret
csi.storage.k8s.io/node-publish-secret-namespace: kube-system
reclaimPolicy: Delete
volumeBindingMode: Immediate
allowVolumeExpansion: true
Encrypt your volumes per PVC
You can encrypt volumes by allowing your users to specify encryption keys in their PVCs. Using this method, each PVC will use its own key for encryption. Follow the steps below to create two PVCs which use different passphrases for encryption:
Step 1: Create two Kubernetes secrets to house the encryption keys for your two PVCs
Kubernetes secrets can be in the Portworx namespace or in a user namespace. In this example we will be creating Kubernetes secrets in the user namespace default
.
Enter the following command to create the secret for your first PVC, specifying your own passphrase for mysecret-passcode-for-encryption
, which encrypts the PVC:
kubectl create secret generic volume-secrets-1 --from-literal=mysql-pvc-secret-key-1=mysecret-passcode-for-encryption-1
Enter the same command to create the secret for your second PVC, optionally specifying a different secret name and a different namespace. This example places both PVCs in default
namespace:
kubectl create secret generic volume-secrets-2 --from-literal=mysql-pvc-secret-key-2=mysecret-passcode-for-encryption-2
Step 2: Create two additional Kubernetes secrets that refer to the encryption key secrets
Enter the following command to create another secret associated with your first PVC, specifying the following options:
- This secret's name (
mysql-pvc-1
in this example) - The
-n
option with the same namespace which the first Kubernetes secret you created to house your encryption key points to (csi-test-demo
in this example) - The
--from-literal=SECRET_NAME=
option and the name of the encryption key secret you created - The
--from-literal=SECRET_KEY=
option and the key from inside the PVC's encryption key secret - The
--from-literal=SECRET_CONTEXT=
option and the encryption key secret's namespace as described in step 1
kubectl create secret generic mysql-pvc-1 -n csi-test-demo --from-literal=SECRET_NAME=volume-secrets-1 --from-literal=SECRET_KEY=mysql-pvc-secret-key-1 --from-literal=SECRET_CONTEXT=csi-test-demo
Enter the same command for your second PVC, but specify a different secret name and optionally, a different namespace:
kubectl create secret generic mysql-pvc-2 -n csi-test-demo --from-literal=SECRET_NAME=volume-secrets-2 --from-literal=SECRET_KEY=mysql-pvc-secret-key-2 --from-literal=SECRET_CONTEXT=csi-test-demo
Step 3: Create a CSI storage class for encrypted PVCs
Create a StorageClass CRD, specifying the ${pvc.name}
and ${pvc.namespace}
template variables:
kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
name: px-csi-db-encrypted-pvc-k8s
provisioner: pxd.portworx.com
parameters:
repl: "3"
secure: "true"
io_profile: auto
io_priority: "high"
csi.storage.k8s.io/provisioner-secret-name: ${pvc.name}
csi.storage.k8s.io/provisioner-secret-namespace: ${pvc.namespace}
csi.storage.k8s.io/node-publish-secret-name: ${pvc.name}
csi.storage.k8s.io/node-publish-secret-namespace: ${pvc.namespace}
reclaimPolicy: Delete
volumeBindingMode: Immediate
allowVolumeExpansion: true
Step 4: Create encrypted PVCs
Create two encrypted PVCs, one for each of the secrets you created in the preceding steps:
-
Create the
mysql-pvc-1
PVC that uses the passcode you created previously. In the example, that passcode ismysecret-passcode-for-encryption-1
:kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: mysql-pvc-1
namespace: csi-test-demo
spec:
storageClassName: px-csi-db-encrypted-pvc-k8s
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 2Gi -
Create the
mysql-pvc-2
PVC that uses the passcode you created previously. In the example, that passcode ismysecret-passcode-for-encryption-2
:kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: mysql-pvc-2
namespace: csi-test-demo
spec:
storageClassName: px-csi-db-encrypted-pvc-k8s
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 2Gi
The templatized parameters in the CSI storage class point to the name and namespace of the PVC itself. This ensures that each PVC requires a separate Kubernetes secret of the same name in the same namespace. In this way, each PVC gets encrypted with its own passphrase.