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Wojtek Krzywiec
Wojtek Krzywiec

Posted on • Updated on • Originally published at wkrzywiec.Medium

Deployment of multiple apps on Kubernetes cluster — Walkthrough

Cover image by Joseph Barrientos on Unsplash

With this blog post I would like to show you how you can deploy couple applications on minikube (local Kubernetes) cluster.

This is second part one of my series on Kubernetes where I compare how to run applications on Kubernetes cluster using 3 approaches:

In the first article I've described some basic concepts of Kubernetes and what kind of a problem does it solves.

Architecture

Before making hands dirty let’s see the overall architecture that we want to deploy:

architecture

It’s based on my previous project — kanban-board, and include 3 services:

  • database,

  • backend service (kanban-app, written in Java with Spring Boot)

  • and frontend (kanban-ui, written with Angular framework).

Apart from them I want to deploy the Adminer — UI application to get inside a database.

To enter one of these two UI apps user will need to type one of following URLs in the web browser:

  • kanban.k8s.com

  • adminer.k8s.com

The picture above is simplified, just for you to understand the main idea behind this project. Unfortunately it doesn’t contain any information of what kind of Kubernetes Objects we need to create.

cluster

If you don’t know what some of these objects are, like Ingress or ClusterIP, don’t worry. I’ll explain all of that in a minute 😉.

Install Docker, kubectl & minikube

First you need to install all necessary dependencies. Here are links to official documentations which are covering most of popular OSes:

  • Docker (container deamon),

  • kubectl (a CLI tool to interact with cluster),

  • minikube (locally installed, lightweight Kubernetes cluster).

Start minikube

Once you’ve got everything installed you can start the minikube cluster by running the CLI command in terminal:

> minikube start
😄  minikube v1.8.1 on Ubuntu 18.04
✨  Automatically selected the docker driver
🔥  Creating Kubernetes in docker container with (CPUs=2) (8 available), Memory=2200MB (7826MB available) ...
🐳  Preparing Kubernetes v1.17.3 on Docker 19.03.2 ...
  ▪ kubeadm.pod-network-cidr=10.244.0.0/16
🚀  Launching Kubernetes ... 
🌟  Enabling addons: default-storageclass, storage-provisioner
⌛  Waiting for cluster to come online ...
🏄  Done! kubectl is now configured to use "minikube"
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To check the status of the cluster:

> minikube status
host: Running
kubelet: Running
apiserver: Running
kubeconfig: Configured
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To check that kubectl is properly configured:

> kubectl cluster-info
Kubernetes master is running at [https://127.0.0.1:32768](https://127.0.0.1:32768)
KubeDNS is running at [https://127.0.0.1:32768/api/v1/namespaces/kube-system/services/kube-dns:dns/proxy](https://127.0.0.1:32768/api/v1/namespaces/kube-system/services/kube-dns:dns/proxy)

To further debug and diagnose cluster problems, use 'kubectl cluster-info dump'.
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Modify hosts file

To make the http://adminer.k8s.com & http://kanban.k8s.com work you need to edit the hosts file on your PC.

The location of it depends on the OS:

When you find it, add following lines:

<MINIKUBE_IP>   adminer.k8s.com
<MINIKUBE_IP>   kanban.k8s.com
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A value for <MINIKUBE_IP> placeholder is individual per machine. To figure it out you need to have minikube up and running. If you're sure it's working you can run the command:

> minikube ip
172.17.0.2
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In my case, I need to add following lines to the hosts file:

172.17.0.2  adminer.k8s.com
172.17.0.2  kanban.k8s.com
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Add Adminer

Finally everything is set up and we can start with deploying applications. First one will be Adminer app.

In Kubernetes world the smallest deployable object is a Pod. It can hold one or more (Docker, cri-o) containers and also has some metadata information (e.g name, labels) that are needed. Sometimes Pods can be treated as single applications, because they usually have only one single container inside.

But we won’t create Pods in this exercise 😜. Not directly at least 😉.

The problem with them is that if you’re creating them manually you won’t be able to easily scale their number. Also if your application inside the Pod crushes your Pods also crushes and there is no mechanism to restart it again.

Luckily there is a Deployment for help 🍾.

In order to create it for Adminer you need to have a file called adminer-deployment.yaml which is defined as follows:

apiVersion: apps/v1
kind: Deployment
metadata:
  name: adminer
  labels:
    app: adminer
    group: db
spec:
  replicas: 1
  selector:
    matchLabels:
      app: adminer    # indicates which Pods (with which labeles) need be handled by this Deployment
  template:
    metadata:         # indicates the metadata that will be added to each Pod
      labels:
        app: adminer
        group: db
    spec:
      containers:     # defines a running container inside the Pod
        - name: adminer
          image: adminer:4.7.6-standalone
          ports:
            - containerPort: 8080   # which port of the container is exposed to the Pod
          env:
            - name: ADMINER_DESIGN
              value: pepa-linha
            - name: ADMINER_DEFAULT_SERVER
              value: postgres
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First section is responsible for defining of what kind of object we’re creating (apiVersion , kind) followed by some metadata including name & labels ( metadata).

Next section — spec — is called specification where we define specifications of a Deployment:

  • replicas — indicates how many Pods of the same type will be created,

  • selector.matchLabels —defines how Deployment will find Pods that it needs to take care of, in this case it will look for a Pod which is labeled with app: adminer,

  • template.metadata — tells what metadata will be added to each Pod, in this case all of them* *will have labels : app: adminer , group: db .

  • template.spec.containers — is a list of containers that will be inside a Pod. In this case I put only one container, which is based on adminer:4.7.6-standalone Docker image and exposes containerPort: 8080 . Moreover with env section we inject environment variable to the container to configure Adminer UI (full documentation can be found here).

Now you can run following command in the terminal:

> kubectl apply -f adminer-deployment.yaml
deployment.apps/adminer created
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To check if everything is ok you can run:

> kubectl get deployments
NAME      READY   UP-TO-DATE   AVAILABLE   AGE
adminer   1/1     1            1           30s

> kubectl describe deployment adminer
... many details about the Deployment ...

> kubectl get pods
NAME                     READY  STATUS   RESTARTS  AGE
adminer-994865d4b-kqck5  1/1    Running  0         24m

> kubectl describe pod adminer-994865d4b-kqck5**
... many details about the Pod ...
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Great! It worked! But there is a problem. How to open the Adminer page?

To handle this problem we need to use another type of Kubernetes object — Service.

Per design Kubernetes is assigning the IP for each Pod, which might be problematic, because Pods don’t leave forever. Actually they are constantly created and deleted, all the time. And for each new Pod new IP is assigned. And that’s creates some kind of networking hell, because other applications inside the cluster would need to update the IP addresses of connected with Pods every time new instance is created.

Luckily Services are to the rescue. They solve that problem by having a single DNS name for all Pods *handled by the *Deployment. So no matter what IP address Pod have, all applications are pointing to the Service which do all the job - finding the right Pod. Plus Services are taking care of load balancing of the traffic if there are more than Pod replicas.

To create such object add new YAML file with Service definition adminer-svc.yaml:

apiVersion: v1
kind: Service
metadata:
  name: adminer
  labels: 
    group: db
spec:
  type: ClusterIP
  selector:             # indicates into which pods ClusterIP provides access
    app: adminer
  ports:
    - port: 8080          # port exposed outside ClusterIP
      targetPort: 8080    # port exposed by Pod
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This one is a little bit shorter. But like the last time there is section defining the type of the object and it’s metadata. Then there is a spec section where couple of properties are set:

  • type: ClusterIP —indicates what type of the Service we want to deploy. There are several types, but I’ve decided to use ClusterIP. And the main reason for that is because I didn’t want to expose every Pod outside the cluster. What ClusterIP does is that it exposes assigned Pods to other *Pod*s inside the cluster, but not outside.

  • selector — here we say to which Pods this Service provide access, in this case it provide access to a Pod with app: adminer label.

  • ports — indicates the mappings of the port exposed by the Pod to the ClusterIP port which will be available for other applications inside cluster.

And now we can create this Service with command:

> kubectl apply -f adminer-svc.yaml
service/adminer created
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And to check if everything is working:

> kubectl get svc
NAME       TYPE       CLUSTER-IP    EXTERNAL-IP  PORT(S)   AGE
adminer    ClusterIP  10.99.85.149  <none>       8080/TCP  9s
kubernetes ClusterIP  10.96.0.1     <none>       443/TCP   3m34s

> kubectl describe svc adminer
... many details about the ClusterIP...
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Okey! So am I able now to open the Adminer page?

Of course not 😜. We need to do one more thing.

Add Ingress Controller

As it was mentioned before, ClusterIP exposes the app only for other apps inside the cluster. And in order to get to it from outside of it we need to use a different approach.

Here comes Ingress to the rescue, which is a gateway to our cluster. And the object that we need to create is called Ingress Controller and it’s an implementation of Ingress.

But here is the tricky part. There are lots of Ingress Controllers available. Some of them are opensource, but some of them are paid one. For this project I’ve chosen an “official” Kubernetes Ingress Controller based on Nginx. But please be not confused with another one, also based on Nginx but created by NGINX Inc - this one is paid. Apart from these both there are also other* Ingress Controller*s available like Kong Ingress, or Traefik.

Based on the official documentation before setting up the Ingress Controller rules we need to run following command:

> kubectl apply -f https://raw.githubusercontent.com/kubernetes/ingress-nginx/nginx-0.30.0/deploy/static/mandatory.yaml
namespace/ingress-nginx created
configmap/nginx-configuration created
configmap/tcp-services created
configmap/udp-services created
serviceaccount/nginx-ingress-serviceaccount created
clusterrole.rbac.authorization.k8s.io/nginx-ingress-clusterrole created
role.rbac.authorization.k8s.io/nginx-ingress-role created
rolebinding.rbac.authorization.k8s.io/nginx-ingress-role-nisa-binding created
clusterrolebinding.rbac.authorization.k8s.io/nginx-ingress-clusterrole-nisa-binding created
deployment.apps/nginx-ingress-controller created
limitrange/ingress-nginx created
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This one created some objects that are inside the cluster.

Moreover you will need to enable Ingress addon in minikube with the command:

> minikube addons enable ingress
🌟  The 'ingress' addon is enabled
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So then we can move to defining the routing rule to get inside the Adminer web page. Therefore we need to create an Ingress object defined in a file ingress-controller.yaml:

apiVersion: networking.k8s.io/v1beta1
kind: Ingress
metadata:
  name: ingress-service
  annotations:
    kubernetes.io/ingress.class: nginx
spec:
  rules:
    - host: adminer.k8s.com
      http:
        paths:
          - path: /
            backend:  
              serviceName: adminer
              servicePort: 8080
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As usual, first there is a definition of kind of the *Kubernete*s object we want to create. Then it’s followed by metadata with the name of the object as usual and also add a new section — annotations .

This one is very important for Ingress because with that we can configure its behavior. In my example, I’ve used the most simple one, but there are a lot more of possibilities.

And finally there is a spec section where we provided first rule, that all requests from the host adminer.k8s.com will be routed to the ClusterIP with a name adminer . ClusterIP, neither Deployment nor Pod!

After applying it into the cluster:

> kubectl apply -f ingress-controller.yaml
ingress.networking.k8s.io/ingress-controller created
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And finally after typing http://adminer.k8s.com in a web browser this page show up:

adminer

Awesome! But how to login to the database? Wait, but what database? We don’t have any database at all!

Add PostgreSQL database

Right, we need to set up our database. To do that we need to create another pair of Deployment-ClusterIP, but this time with PostgreSQL.

And here, again is a tricky part. Databases are not the “usual” stateless services, they store information and should not be as easily killed as “regular” Pods are. Even if it crashes we want to have data persisted somewhere. Therefore we need to create a space (directory) on our disk, which will be accessible by PostgreSQL container and will be outside the Kubernetes cluster.

In order to do that we need to create a new type of object called — PersistentVolumeClaim. It provides some storage located on our computer (or server) for Pods.

To create it once again we create a YAML file with a name — postgres-pvc.yaml:

apiVersion: v1
kind: PersistentVolumeClaim
metadata:
  name: postgres-persistent-volume-claim
spec:
  accessModes:
    - ReadWriteOnce
  resources:
    requests:
      storage: 4Gi
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Again first sections include the definition of the type of object we want to create together with some metadata. Then in the spec section we tell Kubernetes that this Volume has read-write access right and we want to use 4GiB of memory (I know maybe that’s too much for such small example).

And after applying it in the terminal:

> kubectl apply -f postgres-pvc.yaml
persistentvolumeclaim/postgres-persistent-volume-claim created
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And to find out if everything is ok:

> kubectl get pvc
NAME       STATUS VOLUME  CAPACITY  ACCESS MODE  STORAGECLASS   AGE
postgres.. Bound  pvc-43. 4Gi       RWO          standard       40s

> kubectl describe pvc postgres-persistent-volume-claim
... many details about the PersistentVolumeClaim...
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Next, we should be able to create Deployment & ClusterI*P for *PostgreSQL, but first I would like to introduce new type of Kubernetes object, which will hold some configuration values and is called — ConfigMap.

This type of object is very useful when we want to inject environment variables to multiple containers in the Pods. It makes configuration of multiple Pods/Deployments very clean because we can have a single point of truth for our configuration. And if we decide to change it, we can do that in one place.

In this project I want keep the database configuration in ConfigMap, because I want to pass database config values to two Pods — one for postgres Deployment, and one for the backend service.

The definition of the ConfigMap is in the postgres-config.yaml file and is as follows:

apiVersion: v1
kind: ConfigMap
metadata:
  name: postgres-config
  labels:
    group: db
data:
  POSTGRES_DB: kanban
  POSTGRES_USER: kanban
  POSTGRES_PASSWORD: kanban
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Except the usual sections — apiVersion , kind and metadata there is a new one instead of specdata . It’s were there are pairs of keys & values for environment variables that we will be injecting to the containers.

To create thisobject we need to run the command:

> kubectl apply -f postgres-config.yaml
configmap/postgres-config created
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And to check it we can run commands:

> kubectl get configmap
NAME              DATA   AGE
postgres-config   3      2m31s

> kubectl describe configmap postgres-config
... many details about the ConfigMap...
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Now we can move on to the definition of PostgreSQL Deploymentpostgres-deployment.yaml:

apiVersion: apps/v1
kind: Deployment
metadata:
  name: postgres
  labels:
    app: postgres
    group: db
spec:
  replicas: 1
  selector:
    matchLabels:
      app: postgres
  template:
    metadata:
      labels:
        app: postgres
        type: db
    spec:
      volumes:                         # indicates which PVC are available for this Deployment
        - name: postgres-storage
          persistentVolumeClaim:
            claimName: postgres-persistent-volume-claim
      containers:
        - name: postgres
          image: postgres:9.6-alpine
          ports:
            - containerPort: 5432
          envFrom:
            - configMapRef:
                name: postgres-config
          volumeMounts:                 # indicates which Volume (from spec.template.spec.volumes) should be used
            - name: postgres-storage                # name of the Volume
              mountPath: /var/lib/postgresql/data   # path inside the container
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As most of the parts where already discussed I’ll skip them and move to new ones:

  • spec.template.spec.volumes — here we’re adding created PVC to the Deployment, so all containers inside of it will be able to use it,

  • spec.template.spec.containers[0].image — here we specify what Docker image we want to use for our database,

  • spec.template.spec.containers[0].envFrom — indicates from which ConfigMap we want to inject environment variables,

  • spec.template.spec.containers[0].volumeMounts — tells Kubernetes which Volume to use (defined in the spec.template.spec.volumes section) and map it to a particular folder inside the container — basically all data inside the mountPath will be stored outside the cluster.

Similarly, we define the ClusterIP with a file postgres-svc.yaml:

apiVersion: v1
kind: Service
metadata:
  name: postgres
  labels: 
    group: db
spec:
  type: ClusterIP
  selector:             
    app: postgres
  ports:
    - port: 5432  
      targetPort: 5432  
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There is nothing new here, except the port mapping which is specific for PostgreSQL.

To create both objects we can run:

> kubectl apply -f postgres-deployment.yaml
deployment.apps/postgres created

> kubectl apply -f postgres-svc.yaml
service/postgres created
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And now if you go to the Adminer once again, type following credentials:

    System:   PostgreSQL
    Server:   postgres
    Username: kanban
    Password: kanban
    Database: kanban
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You should be able to login to a page:

database

Awesome! The database is set up, so we can move on to kanban-app (backend) and kanban-ui (frontend) services.

Add kanban-app

First let’s provide all necessary definitions for backend service. As it was for Adminer, we need also to have create Deployment and Service for backend service.

Therefore, the kanban-app-deployment.yaml file looks as follows:

apiVersion: apps/v1
kind: Deployment
metadata:
  name: kanban-app
  labels:
    app: kanban-app
    group: backend
spec:
  replicas: 1
  selector:
    matchLabels:
      app: kanban-app
  template:
    metadata:
      labels:
        app: kanban-app
        group: backend
    spec:
      containers:
        - name: kanban-app
          image: wkrzywiec/kanban-app:k8s
          ports:
            - containerPort: 8080
          envFrom:
            - configMapRef:
                name: postgres-config
          env:
            - name: DB_SERVER
              value: postgres
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In the container specification I provided my own Docker image which I’ve published on Docker Hub. It exposes port 8080 and uses some of the environment variables located either in ConfigMap ( envFrom.configMapRef ) or from manually added environment variable only for this Deploymentenv .

Next, we define the kanban-app-svc.yaml file:

apiVersion: v1
kind: Service
metadata:
  name: kanban-app
  labels: 
    group: backend
spec:
  type: ClusterIP
  selector:
    app: kanban-app
  ports:
    - port: 8080
      targetPort: 8080
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There are no new things there in compare to previous Services.

To apply both definitions we need to run the commands:

> kubectl apply -f kanban-app-deployment.yaml
deployment.apps/kanban-app created

> kubectl apply -f kanban-app-svc.yaml
service/kanban-app created
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Now you would want to test it, but in order to do so we need to configure the Ingress Controller so we can enter the Swagger UI page to check the API of the backend service.

We need to add a new host to the ingress-controller.yaml file so it will looks as follows:

apiVersion: networking.k8s.io/v1beta1
kind: Ingress
metadata:
  name: ingress-service
  annotations:
    kubernetes.io/ingress.class: nginx
spec:
  rules:
    - host: adminer.k8s.com
      http:
        paths:
          - path: /
            backend:  
              serviceName: adminer
              servicePort: 8080
    - host: kanban.k8s.com
      http:
        paths: 
          - path: /api/
            backend:
              serviceName: kanban-app
              servicePort: 8080
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And then apply those changes to the cluster by running the command:

> kubectl apply -f ingress-controller.yaml
ingress.networking.k8s.io/ingress-service configured
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Now, if you enter the http://kanban.k8s.com/api/swagger-ui.html address in the web browser you should get the overview of the REST API that this application is providing.

swagger

You can also go to the Adminer (http://adminer.k8s.com) and check if new tables were added to the database (they were added by the Liquibase script during start up of kanban-app).

kanban db

Add kanban-ui

And at last, we can add the UI application. Again, we need to define the Deployment and ClusterIP.

Here is the kanban-ui-deployment.yaml file

apiVersion: apps/v1
kind: Deployment
metadata:
  name: kanban-ui
  labels:
    app: kanban-ui
    group: frontend
spec:
  replicas: 1
  selector:
    matchLabels:
      app: kanban-ui
  template:
    metadata:
      labels:
        app: kanban-ui
        group: frontend
    spec:
      containers:
        - name: kanban-ui
          image: wkrzywiec/kanban-ui:k8s
          ports:
            - containerPort: 80
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And kanban-ui-svc.yaml file:

apiVersion: v1
kind: Service
metadata:
  name: kanban-ui
  labels: 
    group: backend
spec:
  type: ClusterIP
  selector:
    app: kanban-ui
  ports:
    - port: 80
      targetPort: 80
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Nothing special in both files, so we can go right away to applying both of them to the cluster:

> kubectl apply -f kanban-ui-deployment.yaml 
deployment.apps/kanban-ui created

> kubectl apply -f kanban-ui-svc.yaml
service/kanban-ui created
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And again, to test it we need to expose it outside cluster. For that we need to configure Ingress Controller:

apiVersion: networking.k8s.io/v1beta1
kind: Ingress
metadata:
  name: ingress-service
  annotations:
    kubernetes.io/ingress.class: nginx
spec:
  rules:
    - host: adminer.k8s.com
      http:
        paths:
          - path: /
            backend:  
              serviceName: adminer
              servicePort: 8080
    - host: kanban.k8s.com
      http:
        paths: 
          - path: /api/
            backend:
              serviceName: kanban-app
              servicePort: 8080
          - path: /
            backend:
              serviceName: kanban-ui
              servicePort: 80
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And now, if you open the address — http://kanban.k8s.com you should get this page:

kanban-ui

You can now add Kanban boards, tasks, etc.

But one more point before the wrap up.

How the kanban-ui is connected with kanban-app?

The answer to this question is in the configuration file of Nginx server, included in the Docker image of kanban-uidefault.conf.

server {
    listen 80;
    server_name kanban-ui;
    root /usr/share/nginx/html;
    index index.html index.html;

    location /api/kanbans {
        proxy_pass http://kanban-app:8080/api/kanbans;
    }

    location /api/tasks {
        proxy_pass http://kanban-app:8080/api/tasks;
    }

    location / {
        try_files $uri $uri/ /index.html;
    }
}
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In above example the address http://kanban-app:8080 is a DNS address of the ClusterIP, not the Deployment.

Conclusion

With this blog post I’ve tried to walk you through all the steps to deploy couple applications into a local Kubernetes cluster.

But there is one problem. How to avoid creating such great number of YAML files? And is it a single command with which we could deploy all these objects all at once?

For a second question there is a simple answer — you can run the kubectl apply command not on every single file but on the entire folder where they are located i.e.:

> kubectl apply -f ./k8s
deployment.apps/adminer created
service/adminer created
ingress.networking.k8s.io/ingress-service created
namespace/ingress-nginx created
configmap/nginx-configuration created
configmap/tcp-services created
configmap/udp-services created
serviceaccount/nginx-ingress-serviceaccount created
clusterrole.rbac.authorization.k8s.io/nginx-ingress-clusterrole created
role.rbac.authorization.k8s.io/nginx-ingress-role created
rolebinding.rbac.authorization.k8s.io/nginx-ingress-role-nisa-binding created
clusterrolebinding.rbac.authorization.k8s.io/nginx-ingress-clusterrole-nisa-binding deployment.apps/nginx-ingress-controller created
limitrange/ingress-nginx created
deployment.apps/kanban-app created
service/kanban-app created
deployment.apps/kanban-ui created
service/kanban-ui created
configmap/postgres-config created
deployment.apps/postgres created
persistentvolumeclaim/postgres-persistent-volume-claim created
service/postgres created
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But for the first question, how to avoid such boilerplate code there is no simple question. But I’ll try to address it in my next post, where I’ll deploy same services, but using Helm.

As usual here are links to my repositories, first with all Kubernetes YAML files:

wkrzywiec/k8s-helm-helmfile on github.com

And second with the source code of kanban-app & kanban-ui:
wkrzywiec/kanban-board on github.com

References

Top comments (1)

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jhawithu profile image
Alok Kumar

Very nice article, lots of learning, keep posting. I also created a full course on Kubernetes in 10hr on YouTube, please have a look and motivate me. Thanks
youtu.be/toLAU_QPF6o