Setting Up a Private Docker Registry with LKE and Object Storage

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Hosting a private Docker registry alongside your Kubernetes cluster allows you to securely manage your Docker images while also providing quick deployment of your apps. This guide will walk you through the steps needed to deploy a private Docker registry on a Linode Kubernetes Engine (LKE) cluster. At the end of this tutorial, you will be able to locally push and pull Docker images to your registry. Similarly, your LKE cluster’s pods will also be able to pull Docker images from the registry to complete their deployments.

Before you Begin

Note
This guide was written using Kubernetes version 1.17.
  1. Deploy a LKE Cluster. This example was written using a node pool with two 2 GB nodes. Depending on the workloads you will be deploying on your cluster, you may consider using nodes with higher resources.

  2. Install Helm 3, kubectl, and Docker to your local environment.

    Note
    For Docker installation instructions on other operating systems, see Docker’s official documentation.
  3. Configure kubectl to work with your new LKE cluster. See Connect to your LKE Cluster with kubectl.

  4. Generate an Object Storage key pair and ensure you save it in a secure location. You will need the key pair for a later section in this guide. Finally create an Object Storage bucket to store your registry’s images. Throughout this guide, the example bucket name will be registry.

  5. Purchase a domain name from a reliable domain registrar. Using Linode’s DNS Manager, create a new Domain and add an DNS “A” record for a subdomain named registry. Your subdomain will host your Docker registry. This guide will use registry.example.com as the example domain.

    Note
    Optionally, you can create a Wildcard DNS record, *.example.com. In a later section, you will point your DNS A record to a Linode NodeBalancer’s external IP address. Using a Wildcard DNS record, will allow you to expose your Kubernetes services without requiring further configuration using the Linode DNS Manager.

In this Guide

In this guide you will:

Install the NGINX Ingress Controller

An Ingress is used to provide external routes, via HTTP or HTTPS, to your cluster’s services. An Ingress Controller, like the NGINX Ingress Controller, fulfills the requirements presented by the Ingress using a load balancer.

In this section, you will install the NGINX Ingress Controller using Helm, which will create a Linode NodeBalancer to handle your cluster’s traffic.

  1. Add the stable Helm charts repository to your Helm repos:

    helm repo add ingress-nginx https://kubernetes.github.io/ingress-nginx
  2. Update your Helm repositories:

    helm repo update
  3. Install the NGINX Ingress Controller. This installation will result in a Linode NodeBalancer being created.

    helm install ingress-nginx ingress-nginx/ingress-nginx

    You will see a similar output after issuing the above command (the output has been truncated for brevity):

    NAME: ingress-nginx
    LAST DEPLOYED: Thu Jul 14 19:27:24 2022
    NAMESPACE: default
    STATUS: deployed
    REVISION: 1
    TEST SUITE: None
    NOTES:
    The ingress-nginx controller has been installed.
    It may take a few minutes for the LoadBalancer IP to be available.
    You can watch the status by running 'kubectl --namespace default get services -o wide -w ingress-nginx-controller'
    ...

    In the next section, you will use your Linode NodeBalancer’s external IP address to update your registry’s domain record.

Update your Subdomain’s IP Address

  1. Access your NodeBalancer’s assigned external IP address.

    kubectl --namespace default get services -o wide -w ingress-nginx-controller

    The command will return a similar output:

    NAME                          TYPE           CLUSTER-IP      EXTERNAL-IP    PORT(S)                      AGE     SELECTOR
    ingress-nginx-controller   LoadBalancer   10.128.169.60   192.0.2.0   80:32401/TCP,443:30830/TCP   7h51m   app.kubernetes.io/component=controller,app.kubernetes.io/instance=ingress-nginx,app.kubernetes.io/name=ingress-nginx
  2. Copy the IP address of the EXTERNAL IP field and navigate to Linode’s DNS manager and update your domain’s’ registry A record with the external IP address. Ensure that the entry’s TTL field is set to 5 minutes.

Now that your NGINX Ingress Controller has been deployed and your subdomain’s A record has been updated, you are ready to enable HTTPS on your Docker registry.

Enable HTTPS

Note

Before performing the commands in this section, ensure that your DNS has had time to propagate across the internet. This process can take several hours. You can query the status of your DNS by using the following command, substituting registry.example.com for your subdomain and domain.

dig +short registry.example.com

If successful, the output should return the IP address of your NodeBalancer.

To enable HTTPS on your Docker registry, you will create a Transport Layer Security (TLS) certificate from the Let’s Encrypt certificate authority (CA) using the ACME protocol. This will be facilitated by cert-manager, the native Kubernetes certificate management controller.

In this section you will install cert-manager using Helm and the required cert-manager CustomResourceDefinitions (CRDs). Then, you will create a ClusterIssuer and Certificate resource to create your cluster’s TLS certificate.

Install cert-manager

  1. Install cert-manager’s CRDs.

    kubectl apply --validate=false -f https://github.com/jetstack/cert-manager/releases/latest/download/cert-manager.crds.yaml
  2. Create a cert-manager namespace.

    kubectl create namespace cert-manager
  3. Add the Helm repository which contains the cert-manager Helm chart.

    helm repo add jetstack https://charts.jetstack.io
  4. Update your Helm repositories.

    helm repo update
  5. Install the cert-manager Helm chart. These basic configurations should be sufficient for many use cases, however, additional cert-manager configurable parameters can be found in cert-manager’s official documentation.

    helm install cert-manager jetstack/cert-manager --namespace cert-manager
  6. Verify that the corresponding cert-manager pods are now running.

    kubectl get pods --namespace cert-manager

    You should see a similar output:

    NAME                                       READY   STATUS    RESTARTS   AGE
    cert-manager-579d48dff8-84nw9              1/1     Running   3          1m
    cert-manager-cainjector-789955d9b7-jfskr   1/1     Running   3          1m
    cert-manager-webhook-64869c4997-hnx6n      1/1     Running   0          1m

Create a ClusterIssuer Resource

Now that cert-manager is installed and running on your cluster, you will need to create a ClusterIssuer resource which defines which CA can create signed certificates when a certificate request is received. A ClusterIssuer is not a namespaced resource, so it can be used by more than one namespace.

  1. Create a directory named registry to store all of your Docker registry’s related manifest files and move into the new directory.

    mkdir ~/registry && cd ~/registry
  2. Using the text editor of your choice, create a file named acme-issuer-prod.yaml with the example configurations. Replace the value of email with your own email address.

    File: ~/registry/acme-issuer-prod.yaml
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    apiVersion: cert-manager.io/v1
    kind: ClusterIssuer
    metadata:
      name: letsencrypt-prod
    spec:
      acme:
        email: user@example.com
        server: https://acme-v02.api.letsencrypt.org/directory
        privateKeySecretRef:
          name: letsencrypt-secret-prod
        solvers:
        - http01:
            ingress:
              class: nginx
    • This manifest file creates a ClusterIssuer resource that will register an account on an ACME server. The value of spec.acme.server designates Let’s Encrypt’s production ACME server, which should be trusted by most browsers.

      Note
      Let’s Encrypt provides a staging ACME server that can be used to test issuing trusted certificates, while not worrying about hitting Let’s Encrypt’s production rate limits. The staging URL is https://acme-staging-v02.api.letsencrypt.org/directory.
    • The value of privateKeySecretRef.name provides the name of a secret containing the private key for this user’s ACME server account (this is tied to the email address you provide in the manifest file). The ACME server will use this key to identify you.

    • To ensure that you own the domain for which you will create a certificate, the ACME server will issue a challenge to a client. cert-manager provides two options for solving challenges, http01 and DNS01. In this example, the http01 challenge solver will be used and it is configured in the solvers array. cert-manager will spin up challenge solver Pods to solve the issued challenges and use Ingress resources to route the challenge to the appropriate Pod.

  3. Create the ClusterIssuer resource:

    kubectl create -f acme-issuer-prod.yaml

Create a Certificate Resource

After you have a ClusterIssuer resource, you can create a Certificate resource. This will describe your x509 public key certificate and will be used to automatically generate a CertificateRequest which will be sent to your ClusterIssuer.

  1. Using the text editor of your choice, create a file named certificate-prod.yaml with the example configurations. Replace the value of email with your own email address. Replace the value of spec.dnsNames with your own domain that you will use to host your Docker registry.

    File: ~/registry/certificate-prod.yaml
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    apiVersion: cert-manager.io/v1
    kind: Certificate
    metadata:
      name: docker-registry-prod
    spec:
      secretName: letsencrypt-secret-prod
      duration: 2160h # 90d
      renewBefore: 360h # 15d
      issuerRef:
        name: letsencrypt-prod
        kind: ClusterIssuer
      dnsNames:
      - registry.example.com
    Note
    The configurations in this example create a Certificate that is valid for 90 days and renews 15 days before expiry.
  2. Create the Certificate resource:

    kubectl create -f certificate-prod.yaml
  3. Verify that the Certificate has been successfully issued:

    kubectl get certs

    When your certificate is ready, you should see a similar output:

    NAME                   READY   SECRET                    AGE
    docker-registry-prod   True    letsencrypt-secret-prod   42s

    All the necessary components are now in place to be able to enable HTTPS on your Docker registry. In the next section, you will complete the steps need to deploy your registry.

Deploy your Docker Registry

You will now complete the steps to deploy your Docker Registry to your Kubernetes cluster using a Helm chart. Prior to deploying your Docker registry, you will first need to create a username and password in order to enable basic authentication for your registry. This will allow you to restrict access to your Docker registry which will keep your images private. Since, your registry will require authentication, a Kubernetes secret will be added to your cluster in order to provide your cluster with your registry’s authentication credentials, so that it can pull images from it.

Enable Basic Authentication

To enabled basic access restriction for your Docker registry, you will use the htpasswd utility. This utility allows you to use a file to store usernames and passwords for basic HTTP authentication. This will require you to log into your Docker registry prior to being able to push or pull images from and to it.

  1. Install the htpasswd utility. This example is for an Ubuntu 18.04 instance, but you can use your system’s package manager to install it.

    sudo apt install apache2-utils -y
  2. Create a file to store your Docker registry’s username and password.

    touch my_docker_pass
  3. Create a username and password using htpasswd. Replace example_user with your own username. Follow the prompt to create a password.

    htpasswd -B my_docker_pass example_user
  4. View the contents of your password file.

    cat my_docker_pass

    Your output will resemble the following. You will need these values when deploying your registry in the Configure your Docker Registry section of the guide.

    example_user:$2y$05$8VhvzCVCB4txq8mNGh8eu.8GMyBEEeUInqQJHKJUD.KUwxastPG4m

Grant your Cluster Access to your Docker Registry

Your LKE Cluster will also need to authenticate to your Docker registry in order to pull images from it. In this section, you will create a Kubernetes Secret that you can use to grant your cluster’s kubelet with access to your registry’s images.

  1. Create a secret to store your registry’s authentication information. Replace the option values with your own registry’s details. The --docker-username and --docker-password should be the username and password that you used when generating credentials using the htpasswd utility.

    kubectl create secret docker-registry regcred \
      --docker-server=registry.example.com \
      --docker-username=example_user \
      --docker-password=3xampl3Passw0rd \
      --docker-email=user@example.com

Configure your Docker Registry

Before deploying the Docker Registry Helm chart to your cluster, you will define some configurations so that the Docker registry uses the NGINX Ingress controller, your registry Object Storage bucket, and your cert-manager created TLS certificate. See the Helm Chart’s official documentation for more information about registries.

Note
If you have not yet generated an Object Storage key pair and created an Object Storage bucket to store your registry’s images, do so now before continuing with the rest of this section.
  1. Create a new file named docker-configs.yaml using the example configurations. Ensure you replace the following values in your file:

    • ingress.hosts with your own Docker registry’s domain
    • ingress.tls.secretName with the name you used when creating your Certificate
    • ingress.tls.hosts with the domain for which you wish to secure with your TLS certificate.
    • secrets.s3.accessKey with the value of your Object Storage account’s access key and secrets.s3.secretKey with the corresponding secret key.
    • secrets.htpasswd with the value returned when you view the contents of your my_docker_pass file. However, ensure you do not remove the |- characters. This ensures that your YAML is properly formatted. See step 4 in the Enable Basic Authentication section for details on viewing the contents of your password file.
    • s3.region with your Object Storage bucket’s cluster region, s3.regionEndpoint with your Object Storage bucket’s region endpoint, and s3.bucket with your registry’s Object Storage bucket name. For more information about these values, see Access Buckets and Files through URLs.
    File: ~/registry/docker-configs.yaml
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    ingress:
      enabled: true
      hosts:
        - registry.example.com
      annotations:
        cert-manager.io/cluster-issuer: letsencrypt-prod
        nginx.ingress.kubernetes.io/proxy-body-size: "0"
        nginx.ingress.kubernetes.io/proxy-read-timeout: "6000"
        nginx.ingress.kubernetes.io/proxy-send-timeout: "6000"
      tls:
        - secretName: letsencrypt-secret-prod
          hosts:
          - registry.example.com
    storage: s3
    secrets:
      htpasswd: |-
        example_user:$2y$05$8VhvzCVCB4txq8mNGh8eu.8GMyBEEeUInqQJHKJUD.KUwxastPG4m    
      s3:
        accessKey: "myaccesskey"
        secretKey: "mysecretkey"
    s3:
      region: us-east-1
      regionEndpoint: us-east-1.linodeobjects.com/
      secure: true
      bucket: registry
    Multipart uploads

    If you require multipart uploading when pushing to your Docker registry, you can set and increase the threshold of the multipartcopythresholdsize value using an additional configData parameter in your docker-configs.yaml file.

    The example below sets the threshold size to 5GB (5368709120 bytes):

    configData:
      storage:
        s3:
          multipartcopythresholdsize: 5368709120
    
    • The NGINX Ingress annotation nginx.ingress.kubernetes.io/proxy-body-size: "0" disables a maximum allowed size client request body check and ensures that you won’t receive a 413 error when pushing larger Docker images to your registry. The values for nginx.ingress.kubernetes.io/proxy-read-timeout: "6000" and nginx.ingress.kubernetes.io/proxy-send-timeout: "6000" are sane values to begin with, but may be adjusted as needed.
  2. Deploy your Docker registry using the configurations you created in the previous step:

    helm repo add twuni https://helm.twun.io
    helm repo update
    helm install twuni/docker-registry -f docker-configs.yaml
    Note
    If a deprecation error appears during the installation using helm use the following command: helm repo add twuni https://helm.twun.io.
  3. Navigate to your registry’s domain and verify that your browser loads the TLS certificate.

    Verify that your Docker registrys site loads your TLS certificate

    You will interact with your registry via the Docker CLI, so you should not expect to see any content load on the page.

Push an Image to your Docker Registry

You are now ready to push and pull images to your Docker registry. In this section you will pull an existing image from Docker Hub and then push it to your registry. Then, in the next section, you will use your registry’s image to deploy an example static site.

  1. Use Docker to pull an image from Docker Hub. This example is using an image that was created following our Create and Deploy a Docker Container Image to a Kubernetes Cluster guide. The image will build a Hugo static site with some boiler plate content. However, you can use any image from Docker Hub that you prefer.

    sudo docker pull leslitagordita/hugo-site:v10
  2. Tag your local Docker image with your private registry’s hostname. This is required when pushing an image to a private registry and not the central Docker registry. Ensure that you replace registry.example.com with your own registry’s domain.

    sudo docker tag leslitagordita/hugo-site:v10 registry.example.com/leslitagordita/hugo-site:v10
  3. At this point, you have never authenticated to your private registry. You will need to log into it prior to pushing up any images. Issue the example command, replacing registry.example.com with your own registry’s URL. Follow the prompts to enter in the username and password you created in the Enable Basic Authentication section.

    sudo docker login registry.example.com
  4. Push the image to your registry. Ensure that you replace registry.example.com with your own registry’s domain.

    sudo docker push registry.example.com/leslitagordita/hugo-site:v10

    You should see a similar output when your image push is complete

    The push refers to repository [registry.example.com/leslitagordita/hugo-site]
    925cbd794bd8: Pushed
    b9fee92b7ac7: Pushed
    1658c062e6a8: Pushed
    21acf2dde3fe: Pushed
    588c407f9029: Pushed
    bcf2f368fe23: Pushed
    v10: digest: sha256:3db7ab6bc5a893375af6f7cf505bac2f4957d8a03701d7fd56853712b0900312 size: 1570

Create a Test Deployment Using an Image from Your Docker Registry

In this section, you will create a test deployment using the image that you pushed to your registry in the previous section. This will ensure that your cluster can authenticate to your Docker registry and pull images from it.

  1. Using Linode’s DNS manager to create a new subdomain A record to host your static site. The example will use static.example.com. When creating your record, assign your cluster’s NodeBalancer external IP address as the IP address. You can find the external IP address with the following command:

    kubectl --namespace default get services -o wide -w nginx-ingress-controller

    The command will return a similar output. Use the value of the EXTERNAL-IP field to create your static site’s new subdomain A record.

    NAME                          TYPE           CLUSTER-IP      EXTERNAL-IP    PORT(S)                      AGE     SELECTOR
    nginx-ingress-controller   LoadBalancer   10.128.169.60   192.0.2.0   80:32401/TCP,443:30830/TCP   7h51m   app.kubernetes.io/component=controller,app=nginx-ingress,release=nginx-ingress
  2. Using a text editor, create the static-site-test.yaml file with the example configurations. This file will create a deployment, service, and an ingress.

    File: ~/registry/staic-site-test.yaml
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    apiVersion: networking.k8s.io/v1
    kind: Ingress
    metadata:
      name: static-site-ingress
      annotations:
        nginx.ingress.kubernetes.io/backend-protocol: "HTTP"
    spec:
      ingressClassName: nginx
      rules:
      - host: static.example.com
        http:
          paths:
          - path: /
            pathType: Prefix
            backend:
              service:
               name: static-site
               port:
                number:80
    ---
    apiVersion: v1
    kind: Service
    metadata:
      name: static-site
    spec:
      type: NodePort
      ports:
      - port: 80
        targetPort: 80
      selector:
        app: static-site
    ---
    apiVersion: apps/v1
    kind: Deployment
    metadata:
      name: static-site
    spec:
      replicas: 3
      selector:
        matchLabels:
          app: static-site
      template:
        metadata:
          labels:
            app: static-site
        spec:
          containers:
          - name: static-site
            image: registry.example.com/leslitagordita/hugo-site:v10
            ports:
            - containerPort: 80
          imagePullSecrets:
          - name: regcred
    • In the Deployment section of the manifest, the imagePullSecrets field references the secret you created in the Grant your Cluster Access to your Docker Registry section. This secret contains the authentication credentials that your cluster’s kubelet can use to pull your private registry’s image.
    • The image field provides the image to pull from your Docker registry.
  3. Create the deployment.

    kubectl create -f static-site-test.yaml
  4. Open a browser and navigate to your site’s domain and view the example static site. Using our example, you would navigate to static.example.com. The example Hugo site should load.

(Optional) Tear Down your Kubernetes Cluster

To avoid being further billed for your Kubernetes cluster and NodeBlancer, delete your cluster using the Linode Cloud Manager. Similarly, to avoid being further billed for our registry’s Object Storage bucket, see Cancel Object Storage.

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