Tutorial

How To Set Up an Nginx Ingress on DigitalOcean Kubernetes Using Helm

How To Set Up an Nginx Ingress on DigitalOcean Kubernetes Using Helm

The author selected the Free and Open Source Fund to receive a donation as part of the Write for DOnations program.

Introduction

Kubernetes Ingresses offer a flexible way to route traffic from beyond your cluster to internal Kubernetes Services. Ingress Resources are objects in Kubernetes that define rules for routing HTTP and HTTPS traffic to Services. For these to work, an Ingress Controller must be present to implement the rules by accepting traffic (most likely via a Load Balancer) and routing it to the appropriate Services. Most Ingress Controllers use only one global Load Balancer for all Ingresses, which is more efficient than creating a Load Balancer per every Service you wish to expose.

Helm is a package manager for managing Kubernetes. Using Helm Charts with Kubernetes provides configurability and lifecycle management to update, rollback, and delete a Kubernetes application.

In this guide, you’ll set up the Kubernetes-maintained Nginx Ingress Controller using Helm. You’ll then create an Ingress Resource to route traffic from your domains to example Hello World back-end services. Once you’ve set up the Ingress, you’ll install Cert Manager to your cluster to provision Let’s Encrypt TLS certificates automatically that will secure your Ingresses.

If you’re looking for a managed Kubernetes hosting service, check out our simple, managed Kubernetes service built for growth.

Prerequisites

  • A Kubernetes cluster above version 1.20, set up with your connection configuration configured as the kubectl default. This setup will use a DigitalOcean Kubernetes cluster with three nodes, but you could also create a cluster manually. To create a Kubernetes cluster in the DigitalOcean Cloud Panel, see our Kubernetes Quickstart.

  • The kubectl command-line tool installed in your local environment and configured to connect to your cluster. You can read more about installing kubectl in the official documentation. If you are using a DigitalOcean Kubernetes cluster, instructions on how to configure kubectl are in the Connect to your Cluster section when you create your cluster, and you can also refer to the How to Connect to a DigitalOcean Kubernetes Cluster docs.

  • The DigitalOcean command-line client, doctl, installed on your machine. See How To Use doctl for more information on using doctl.

  • The Helm 3 package manager available in your development environment. Complete Step 1 of the How To Install Software on Kubernetes Clusters with the Helm 3 Package Manager tutorial.

  • A fully registered domain name with two available A records. This tutorial will use hw1.your_domain and hw2.your_domain throughout. You can purchase a domain name on Namecheap, get one for free on Freenom, or use the domain registrar of your choice. These A records will be directed to a Load Balancer that you will create in Step 2.

Step 1 — Setting Up Hello World Deployments

Before you deploy the Nginx Ingress, you will deploy a “Hello World” app called hello-kubernetes to have some Services to which you’ll route the traffic. To confirm that the Nginx Ingress works properly in the next steps, you’ll deploy it twice, each time with a different welcome message that will be shown when you access it from your browser.

You’ll store the deployment configuration on your local machine. If you’d like, you can also create a directory for this tutorial in which you’ll store the configuration. The first deployment configuration will be in a file named hello-kubernetes-first.yaml. Create it with your preferred text editor:

  1. nano hello-kubernetes-first.yaml

Add the following lines:

hello-kubernetes-first.yaml
apiVersion: v1
kind: Service
metadata:
  name: hello-kubernetes-first
spec:
  type: ClusterIP
  ports:
  - port: 80
    targetPort: 8080
  selector:
    app: hello-kubernetes-first
---
apiVersion: apps/v1
kind: Deployment
metadata:
  name: hello-kubernetes-first
spec:
  replicas: 3
  selector:
    matchLabels:
      app: hello-kubernetes-first
  template:
    metadata:
      labels:
        app: hello-kubernetes-first
    spec:
      containers:
      - name: hello-kubernetes
        image: paulbouwer/hello-kubernetes:1.10
        ports:
        - containerPort: 8080
        env:
        - name: MESSAGE
          value: Hello from the first deployment!

This configuration defines a Deployment and a Service. The Deployment consists of three replicas of the paulbouwer/hello-kubernetes:1.7 image and an environment variable named MESSAGE (you will see its value when you access the app). The Service here is defined to expose the Deployment in-cluster at port 80.

Save and close the file.

Then, create this first variant of the hello-kubernetes app in Kubernetes by running the following command:

  1. kubectl create -f hello-kubernetes-first.yaml

The -f option directs the create command to use the file hello-kubernetes-first.yaml.

You’ll receive the following output:

Output
service/hello-kubernetes-first created deployment.apps/hello-kubernetes-first created

To verify the Service’s creation, run the following command:

  1. kubectl get service hello-kubernetes-first

The output will be the following:

Output
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE hello-kubernetes-first ClusterIP 10.245.124.46 <none> 80/TCP 7s

You’ll find that the newly created Service has a ClusterIP assigned, which means that it is working properly. All traffic sent to it will be forwarded to the selected Deployment on port 8080. Now that you have deployed the first variant of the hello-kubernetes app, you’ll work on the second one.

Create a new file called hello-kubernetes-second.yaml:

  1. nano hello-kubernetes-second.yaml

Add the following lines:

hello-kubernetes-second.yaml
apiVersion: v1
kind: Service
metadata:
  name: hello-kubernetes-second
spec:
  type: ClusterIP
  ports:
  - port: 80
    targetPort: 8080
  selector:
    app: hello-kubernetes-second
---
apiVersion: apps/v1
kind: Deployment
metadata:
  name: hello-kubernetes-second
spec:
  replicas: 3
  selector:
    matchLabels:
      app: hello-kubernetes-second
  template:
    metadata:
      labels:
        app: hello-kubernetes-second
    spec:
      containers:
      - name: hello-kubernetes
        image: paulbouwer/hello-kubernetes:1.10
        ports:
        - containerPort: 8080
        env:
        - name: MESSAGE
          value: Hello from the second deployment!

This variant has the same structure as the previous configuration. To avoid collisions, you vary the name used for the Deployment and Service names. You also update the value of the message that will load in the browser.

Save and close the file.

Now create it in Kubernetes with the following command:

  1. kubectl create -f hello-kubernetes-second.yaml

The output will be:

Output
service/hello-kubernetes-second created deployment.apps/hello-kubernetes-second created

Verify that the second Service is up and running by listing all of your Services:

  1. kubectl get service

The output will be similar to this:

Output
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE hello-kubernetes-first ClusterIP 10.245.124.46 <none> 80/TCP 49s hello-kubernetes-second ClusterIP 10.245.254.124 <none> 80/TCP 10s kubernetes ClusterIP 10.245.0.1 <none> 443/TCP 65m

Both hello-kubernetes-first and hello-kubernetes-second are listed, which means that Kubernetes has created them successfully.

You’ve created two deployments of the hello-kubernetes app with accompanying Services. Each one has a different message set in the deployment specification differentiate them during testing. In the next step, you’ll install the Nginx Ingress Controller itself.

Step 2 — Installing the Kubernetes Nginx Ingress Controller

Now you’ll install the Kubernetes-maintained Nginx Ingress Controller using Helm.

The Nginx Ingress Controller consists of a Pod and a Service. The Pod runs the Controller, which constantly polls the /ingresses endpoint on the API server of your cluster for updates to available Ingress Resources. The Service is of type LoadBalancer. Because you are deploying it to a DigitalOcean Kubernetes cluster, the cluster will automatically create a DigitalOcean Load Balancer through which all external traffic will flow to the Controller. The Controller will then route the traffic to appropriate Services, as defined in the Ingress Resources.

Only the LoadBalancer Service knows the IP address of the automatically created Load Balancer. Some apps (such as ExternalDNS) will need to know its IP address but can only read the configuration of an Ingress. The Controller can be configured to publish the IP address on each Ingress by setting the controller.publishService.enabled parameter to true during helm install. It is recommended to enable this setting to support applications that may depend on the IP address of the Load Balancer.

To install the Nginx Ingress Controller to your cluster, you’ll first need to add its repository to Helm by running:

  1. helm repo add ingress-nginx https://kubernetes.github.io/ingress-nginx

The output will be:

Output
"ingress-nginx" has been added to your repositories

Update your system to let Helm know what it contains:

  1. helm repo update

It may take a moment to load:

Output
Hang tight while we grab the latest from your chart repositories... ...Successfully got an update from the "ingress-nginx" chart repository Update Complete. ⎈Happy Helming!⎈

Finally, run the following command to install the Nginx ingress:

  1. helm install nginx-ingress ingress-nginx/ingress-nginx --set controller.publishService.enabled=true

This command installs the Nginx Ingress Controller from the stable charts repository, names the Helm release nginx-ingress, and sets the publishService parameter to true.

Once it has run, you will receive an output similar to this (this output has been truncated):

Output
NAME: nginx-ingress LAST DEPLOYED: Thu Dec 1 11:40:28 2022 NAMESPACE: default STATUS: deployed REVISION: 1 TEST SUITE: None NOTES: ...

Helm has logged what resources it created in Kubernetes as a part of the chart installation.

Run this command to watch the Load Balancer become available:

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

This command fetches the Nginx Ingress service in the default namespace and outputs its information, but the command does not exit immediately. With the -w argument, it watches and refreshes the output when changes occur.

While waiting for the Load Balancer to become available, you may receive a pending response:

Output
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE SELECTOR nginx-ingress-ingress-nginx-controller LoadBalancer 10.245.3.122 <pending> 80:30953/TCP,443:30869/TCP 36s ...

After some time has passed, the IP address of your newly created Load Balancer will appear:

Output
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE SELECTOR nginx-ingress-ingress-nginx-controller LoadBalancer 10.245.3.122 167.99.16.184 80:30953/TCP,443:30869/TCP 2m29s ...

Next, you’ll need to ensure that your two domains are pointed to the Load Balancer via A records. This is done through your DNS provider. To configure your DNS records on DigitalOcean, see How to Manage DNS Records.

You’ve installed the Nginx Ingress maintained by the Kubernetes community. It will route HTTP and HTTPS traffic from the Load Balancer to appropriate back-end Services configured in the Ingress Resources. In the next step, you’ll expose the hello-kubernetes app deployments using an Ingress Resource.

Step 3 — Exposing the App Using an Ingress

Now you’re going to create an Ingress Resource and use it to expose the hello-kubernetes app deployments at your desired domains. You’ll then test it by accessing it from your browser.

You’ll store the Ingress in a file named hello-kubernetes-ingress.yaml. Create it using your editor:

  1. nano hello-kubernetes-ingress.yaml

Add the following lines to your file:

hello-kubernetes-ingress.yaml
apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
  name: hello-kubernetes-ingress
  annotations:
    kubernetes.io/ingress.class: nginx
spec:
  rules:
  - host: "hw1.your_domain_name"
    http:
      paths:
      - pathType: Prefix
        path: "/"
        backend:
          service:
            name: hello-kubernetes-first
            port:
              number: 80
  - host: "hw2.your_domain_name"
    http:
      paths:
      - pathType: Prefix
        path: "/"
        backend:
          service:
            name: hello-kubernetes-second
            port:
              number: 80

You define an Ingress Resource with the name hello-kubernetes-ingress. Then, you specify two host rules so that hw1.your_domain is routed to the hello-kubernetes-first Service, and hw2.your_domain is routed to the Service from the second deployment (hello-kubernetes-second).

Remember to replace the highlighted domains with your own, then save and close the file.

Create it in Kubernetes by running the following command:

  1. kubectl apply -f hello-kubernetes-ingress.yaml

You can now navigate to hw1.your_domain in your browser. The first deployment will load:

Hello Kubernetes - First Deployment

The second variant (hw2.your_domain) will display a different message:

Hello Kubernetes - Second Deployment

You have verified that the Ingress Controller correctly routes requests, in this case from your two domains to two different Services.

You’ve created and configured an Ingress Resource to serve the hello-kubernetes app deployments at your domains. In the next step, you’ll set up Cert-Manager to secure your Ingress Resources with free TLS certificates from Let’s Encrypt.

Step 4 — Securing the Ingress Using Cert-Manager

To secure your Ingress Resources, you’ll install Cert-Manager, create a ClusterIssuer for production, and modify the configuration of your Ingress to use the TLS certificates. Once installed and configured, your app will be running behind HTTPS.

ClusterIssuers are Cert-Manager Resources in Kubernetes that provision TLS certificates for the whole cluster. The ClusterIssuer is a specific type of Issuer.

Before installing Cert-Manager to your cluster via Helm, you’ll create a namespace for it:

  1. kubectl create namespace cert-manager

You’ll need to add the Jetstack Helm repository to Helm, which hosts the Cert-Manager chart. To do this, run the following command:

  1. helm repo add jetstack https://charts.jetstack.io

Helm will return the following output:

Output
"jetstack" has been added to your repositories

Then, update Helm’s chart cache:

  1. helm repo update

It may take a moment for the update:

Output
Hang tight while we grab the latest from your chart repositories... ...Successfully got an update from the "ingress-nginx" chart repository ...Successfully got an update from the "jetstack" chart repository Update Complete. ⎈Happy Helming!⎈

Finally, install Cert-Manager into the cert-manager namespace by running the following command:

  1. helm install cert-manager jetstack/cert-manager --namespace cert-manager --version v1.10.1 --set installCRDs=true

In this command, you also set the installCRDs parameter to true in order to install cert-manager CustomResourceDefinition manifests during the Helm install. At the time of writing, v1.10.1 was the latest version. You can refer to ArtifactHub to find the latest version number.

You will receive the following output:

Output
NAME: cert-manager LAST DEPLOYED: Wed Nov 30 19:46:39 2022 NAMESPACE: cert-manager STATUS: deployed REVISION: 1 TEST SUITE: None NOTES: cert-manager v1.10.1 has been deployed successfully! ...

The output indicates that the installation was successful.

The NOTES of the output (which has been truncated in the display above) states that you need to set up an Issuer to issue TLS certificates.

You’ll now create one that issues Let’s Encrypt certificates, and you’ll store its configuration in a file named production_issuer.yaml. Create and open this file:

  1. nano production_issuer.yaml

Add the following lines:

production_issuer.yaml
apiVersion: cert-manager.io/v1
kind: ClusterIssuer
metadata:
  name: letsencrypt-prod
spec:
  acme:
    # Email address used for ACME registration
    email: your_email_address
    server: https://acme-v02.api.letsencrypt.org/directory
    privateKeySecretRef:
      # Name of a secret used to store the ACME account private key
      name: letsencrypt-prod-private-key
    # Add a single challenge solver, HTTP01 using nginx
    solvers:
    - http01:
        ingress:
          class: nginx

This configuration defines a ClusterIssuer that contacts Let’s Encrypt in order to issue certificates. You’ll need to replace your_email_address with your email address to receive any notices regarding the security and expiration of your certificates.

Save and close the file.

Roll it out with kubectl:

  1. kubectl apply -f production_issuer.yaml

You will receive the following output:

Output
clusterissuer.cert-manager.io/letsencrypt-prod created

With Cert-Manager installed, you’re ready to introduce the certificates to the Ingress Resource defined in the previous step. Open hello-kubernetes-ingress.yaml for editing:

  1. nano hello-kubernetes-ingress.yaml

Add the highlighted lines:

hello-kubernetes-ingress.yaml
apiVersion: networking.k8s.io/v1
kind: Ingress
metadata:
name: hello-kubernetes-ingress
annotations:
  kubernetes.io/ingress.class: nginx
  cert-manager.io/cluster-issuer: letsencrypt-prod
spec:
  tls:
  - hosts:
    - hw1.your_domain
    - hw2.your_domain
    secretName: hello-kubernetes-tls
  rules:
  - host: "hw1.your_domain_name"
    http:
      paths:
      - pathType: Prefix
        path: "/"
        backend:
          service:
            name: hello-kubernetes-first
            port:
              number: 80
  - host: "hw2.your_domain_name"
    http:
      paths:
      - pathType: Prefix
        path: "/"
        backend:
          service:
            name: hello-kubernetes-second
            port:
              number: 80

The tls block under spec defines what Secret will store the certificates for your sites (listed under hosts), which the letsencrypt-prod ClusterIssuer issues. The secretName must be different for every Ingress you create.

Remember to replace the hw1.your_domain and hw2.your_domain with your own domains. When you’ve finished editing, save and close the file.

Re-apply this configuration to your cluster by running the following command:

  1. kubectl apply -f hello-kubernetes-ingress.yaml

You will receive the following output:

Output
ingress.networking.k8s.io/hello-kubernetes-ingress configured

You’ll need to wait a few minutes for the Let’s Encrypt servers to issue a certificate for your domains. In the meantime, you can track progress by inspecting the output of the following command:

  1. kubectl describe certificate hello-kubernetes-tls

The end of the output will be similar to this:

Output
Events: Type Reason Age From Message ---- ------ ---- ---- ------- Normal Issuing 2m34s cert-manager-certificates-trigger Issuing certificate as Secret does not exist Normal Generated 2m34s cert-manager-certificates-key-manager Stored new private key in temporary Secret resource "hello-kubernetes-tls-hxtql" Normal Requested 2m34s cert-manager-certificates-request-manager Created new CertificateRequest resource "hello-kubernetes-tls-jnnwx" Normal Issuing 2m7s cert-manager-certificates-issuing The certificate has been successfully issued

When the last line of output reads The certificate has been successfully issued, you can exit by pressing CTRL + C.

Navigate to one of your domains in your browser. You’ll find the padlock appears next to the URL, signifying that your connection is now secure.

In this step, you installed Cert-Manager using Helm and created a Let’s Encrypt ClusterIssuer. You then updated your Ingress Resource to take advantage of the Issuer for generating TLS certificates. In the end, you have confirmed that HTTPS works correctly by navigating to one of your domains in your browser.

Conclusion

You have now successfully set up the Nginx Ingress Controller and Cert-Manager on your DigitalOcean Kubernetes cluster using Helm. You are now able to expose your apps to the internet at your domains, secured using Let’s Encrypt TLS certificates.

For further information about the Helm package manager, read this Introduction to Helm.

Thanks for learning with the DigitalOcean Community. Check out our offerings for compute, storage, networking, and managed databases.

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Firstly, Thank you so much for this documentation. It helped me setup an TLS for my apps. This documentation has become a tad bit outdated. I would like to help you to update.

  • The current latest version URL for CRD of cert-manager is: https://raw.githubusercontent.com/jetstack/cert-manager/release-0.11/deploy/manifests/00-crds.yaml
  • In Production Issuer: the apiVersion: cert-manager.io/v1alpha2
  • In annotations for the ingress: the value becomes cert-manager.k8s.io/cluster-issuer

I have tried this tutorial and another that did not use helm to install the nginx-ingress and I can’t seem to get either of them working.

I have the two hello-kubernetes deployments up with two pods each, I have the ingress configured and seems to be configured correctly.

I have the A records in the dns pointed to the IP address of the load balancer, but I don’t get any response from either of the services.

I have change the real domain to xxxxx.

Any ideas what I’m doing wrong??

thom@vm1:/projects/tlm$ kubectl get all
NAME                                                 READY   STATUS    RESTARTS   AGE
pod/hello-kubernetes-first-786757b576-9qw5z          1/1     Running   0          16m
pod/hello-kubernetes-first-786757b576-hwlzv          1/1     Running   0          16m
pod/hello-kubernetes-second-66cc8f5d9b-8qtvv         1/1     Running   0          15m
pod/hello-kubernetes-second-66cc8f5d9b-w824n         1/1     Running   0          15m
pod/nginx-ingress-controller-7658988787-fdql4        1/1     Running   0          15m
pod/nginx-ingress-default-backend-7f5d59d759-zgnnh   1/1     Running   0          15m

NAME                                    TYPE           CLUSTER-IP       EXTERNAL-IP      PORT(S)                      AGE
service/hello-kubernetes-first          ClusterIP      10.245.32.51     <none>           80/TCP                       16m
service/hello-kubernetes-second         ClusterIP      10.245.115.242   <none>           80/TCP                       15m
service/kubernetes                      ClusterIP      10.245.0.1       <none>           443/TCP                      5d5h
service/nginx-ingress-controller        LoadBalancer   10.245.114.161   159.203.159.77   80:31383/TCP,443:32645/TCP   15m
service/nginx-ingress-default-backend   ClusterIP      10.245.251.24    <none>           80/TCP                       15m

NAME                                            READY   UP-TO-DATE   AVAILABLE   AGE
deployment.apps/hello-kubernetes-first          2/2     2            2           16m
deployment.apps/hello-kubernetes-second         2/2     2            2           15m
deployment.apps/nginx-ingress-controller        1/1     1            1           15m
deployment.apps/nginx-ingress-default-backend   1/1     1            1           15m

NAME                                                       DESIRED   CURRENT   READY   AGE
replicaset.apps/hello-kubernetes-first-786757b576          2         2         2       16m
replicaset.apps/hello-kubernetes-second-66cc8f5d9b         2         2         2       15m
replicaset.apps/nginx-ingress-controller-7658988787        1         1         1       15m
replicaset.apps/nginx-ingress-default-backend-7f5d59d759   1         1         1       15m



thom@vm1:~$ kubectl describe ingress
Name:             hello-kubernetes-ingress
Namespace:        default
Address:          159.203.159.77
Default backend:  default-http-backend:80 (<none>)
Rules:
  Host                Path  Backends
  ----                ----  --------
  hw1.xxxxx.com
                         hello-kubernetes-first:80 (10.244.0.175:8080,10.244.0.234:8080)
  hw2.xxxxx.com
                         hello-kubernetes-second:80 (10.244.0.197:8080,10.244.0.242:8080)
Annotations:
  kubernetes.io/ingress.class:  nginx
Events:
  Type    Reason  Age   From                      Message
  ----    ------  ----  ----                      -------
  Normal  CREATE  12m   nginx-ingress-controller  Ingress default/hello-kubernetes-ingress
  Normal  UPDATE  11m   nginx-ingress-controller  Ingress default/hello-kubernetes-ingress

thom@vm1:~$ nslookup hw1.xxxxx.com
Server:         127.0.0.53
Address:        127.0.0.53#53

Non-authoritative answer:
Name:   hw1.xxxxx.com
Address: 159.203.159.77

thom@vm1:~$ curl hw1.xxxxx.com
curl: (52) Empty reply from server

thom@vm1:~$ wget hw1.xxxxx.com
--2019-06-05 14:50:26--  http://hw1.xxxxx.com/
Resolving hw1.xxxxx.com (hw1.xxxxx.com)... 159.203.159.77
Connecting to hw1.xxxxx.com (hw1.xxxxx.com)|159.203.159.77|:80... connected.
HTTP request sent, awaiting response... No data received.
Retrying.

McFly, have you got any idea how to get the real IP address of a connecting user routed through to a pod? All I’m getting are the IP addresses of internal Kubernetes nodes:

https://kuard.gearstone.uk - See that the Real IP is from a 10.x.x.x network?

Hello, thank you for the great tutorial. At the moment I am writing I have an issue at step 2. It says `$ helm install nginx-ingress ingress-nginx/ingress-nginx --set controller.publishService.enabled=true

Error: INSTALLATION FAILED: cannot re-use a name that is still in use $ helm upgrade --install nginx-ingress ingress-nginx/ingress-nginx --set controller.publishService.enabled=true

Error: UPGRADE FAILED: pre-upgrade hooks failed: 1 error occurred: * timed out waiting for the condition ` how can I remove everything and start again?

This comment has been deleted

    If you created Kubernetes cluster around June 2024 with the latest Kubernetes and Ingress Nginx version and get 404 error when trying to access hw1.<domain>, the hello-kubernetes-ingress.yaml needs one additional line. The yaml file needs this line to set the ingressClassName to nginx. The line should be inserted right below spec so it hello-kubernetes-ingress.yaml looks something like:

    spec:
      ingressClassName: nginx
      rules:
    - host: "hw1.xyz.com"
    

    After that hw1.xyz.com and hw2.xyz.com goes to the right pod instead of getting routed to the default rule.

    Thanks for this excellent tutorial!!

    The meaning of “controller.publishService.enabled” seems vague, both in the official documentation, and here as well.

    After trying it out, as “true” and “false”, what happens when it’s “true” is that the Ingress Resource (of “kind: Ingress”, listed by “kubectl get ingress”) displays the Load Balancer’s IP address in its status.

    If controller.publishService.enabled=false, then the Ingress Resource (of “kind: Ingress”, listed by “kubectl get ingress”) displays the Node’s IP address in its status. This is probably not what you expect.

    Since controller.publishService.enabled is true by default, there might not be a reason to discuss the setting, and it could be omitted.

    Thank you. All steps went smoothly and Its running just fine.

    Thank you for this tutorial. I’m stuck at Step 4 — Securing the Ingress Using Cert-Manager.

    I am failing to apply the updated hello-kubernetes-ingress.yaml implementing the tls spec. Up until there everything seemed fine.

    I get a “resource name may not be empty” error.

    error: error when retrieving current configuration of:
    Resource: "networking.k8s.io/v1, Resource=ingresses", GroupVersionKind: "networking.k8s.io/v1, Kind=Ingress"
    Name: "", Namespace: "default"
    from server for: "hello-kubernetes-ingress.yaml": resource name may not be empty
    

    Running a diff with whats working ATK on the cluster

    kubectl diff  -f hello-kubernetes-ingress.yaml                      
    error: resource name may not be empty
    
    

    Here is the file I am submitting

    (hello-kubernetes-ingress.yaml)

    
    apiVersion: networking.k8s.io/v1
    kind: Ingress
    metadata:
    name: hello-kubernetes-ingress
    annotations:
      cert-manager.io/cluster-issuer: letsencrypt-prod
      kubernetes.io/ingress.class: nginx
    spec:
      tls:
      - hosts:
        - hw1.roitsystems.ca
        - hw2.roitsystems.ca
        secretName: hello-kubernetes-tls
      rules:
      - host: "hw1.roitsystems.ca"
        http:
          paths:
          - pathType: Prefix
            path: "/"
            backend:
              service:
                name: hello-kubernetes-first
                port:
                  number: 80
      - host: "hw2.roitsystems.ca"
        http:
          paths:
          - pathType: Prefix
            path: "/"
            backend:
              service:
                name: hello-kubernetes-second
                port:
                  number: 80
    
    

    The back-end services are up, and the DNS entries are valid

    morgane@hackmare hello-world % kubectl get svc hello-kubernetes-first
    NAME                     TYPE        CLUSTER-IP       EXTERNAL-IP   PORT(S)   AGE
    hello-kubernetes-first   ClusterIP   10.245.177.165   <none>        80/TCP    31h
    
    morgane@hackmare hello-world % kubectl get svc hello-kubernetes-second
    NAME                      TYPE        CLUSTER-IP       EXTERNAL-IP   PORT(S)   AGE
    hello-kubernetes-second   ClusterIP   10.245.129.167   <none>        80/TCP    30h
    morgane@hackmare hello-world % 
    

    Cluster info…

    kubectl version
    WARNING: This version information is deprecated and will be replaced with the output from kubectl version --short.  Use --output=yaml|json to get the full version.
    Client Version: version.Info{Major:"1", Minor:"25", GitVersion:"v1.25.2", GitCommit:"5835544ca568b757a8ecae5c153f317e5736700e", GitTreeState:"clean", BuildDate:"2022-09-21T14:33:49Z", GoVersion:"go1.19.1", Compiler:"gc", Platform:"darwin/amd64"}
    Kustomize Version: v4.5.7
    Server Version: version.Info{Major:"1", Minor:"25", GitVersion:"v1.25.4", GitCommit:"872a965c6c6526caa949f0c6ac028ef7aff3fb78", GitTreeState:"clean", BuildDate:"2022-11-09T13:29:58Z", GoVersion:"go1.19.3", Compiler:"gc", Platform:"linux/amd64"}
    morgane@hackmare hello-world % 
    
    

    Thank you very much for this tutorial! Got it working :)

    It would be really valuable if you could provide this as well as an terraformed version. Tried it myself but got stuck with the loadbalancer chicken-egg problem. As I cannot (or don’t know how) to extract the load balancers IP I cannot make A-records for the domain for example.

    I think for beginners like me this would be very valuable!

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