Joget DX 8 Stable Released
The stable release for Joget DX 8 is now available, with a focus on UX and Governance.
Kubernetes is the leading open source container orchestration platform. Originally created by Google based on their need to support massive scale, Kubernetes is now under the purview of Cloud Native Computing Foundation (CNCF), a vendor-neutral foundation managing popular open source projects.
There are several basic and essential concepts that need to be understood:
A Kubernetes cluster consists of one or more nodes. Nodes are machines (VMs, physical servers, etc) that run the applications.
A Pod is the smallest Kubernetes object that contains one or more containers, storage resources, network IP and other configuration.
A Service defines a set of Pods and how they are accessed.
A Volume is a shared storage for containers, and many different types are supported.
These Kubernetes objects are defined in YAML format in .yaml files
A command line interface tool, kubectl, is used to manage these objects via the Kubernetes API.
Simplified view of Kubernetes objects
There are many more concepts in Kubernetes, but the basic ones above should suffice to get started with Kubernetes.
There are many Kubernetes solutions available for different requirements from different providers, ranging from community tools for local testing, to production environments from cloud providers and enterprise vendors.
For the purpose of this tutorial we’ll use Minikube, a tool that runs a single-node Kubernetes cluster in a virtual machine for local development and testing. We’ll be using a Mac running macOS, but you can adapt the instructions for your OS.
The first step is to install a VM platform. We’ll use the open source VirtualBox as the VM platform. Follow the download and installation instructions at https://www.virtualbox.org/wiki/Downloads
The next step is to install the Kubernetes command-line tool, kubectl, which allows you to run commands against Kubernetes clusters e.g. deploy applications, inspect resources, view logs, etc.
1. Download and set executable:
curl -LO https://storage.googleapis.com/kubernetes-release/release/$(curl -s https://storage.googleapis.com/kubernetes-release/release/stable.txt)/bin/darwin/amd64/kubectl \ && chmod +x ./kubectl
2. Move the binary to your PATH:
sudo mv ./kubectl /usr/local/bin/kubectl
3. Test to ensure the version you installed is up-to-date:
kubectl version
Full instructions are at https://kubernetes.io/docs/tasks/tools/install-kubectl/
Now let’s install Minikube, a tool that runs a single-node Kubernetes cluster in a virtual machine on your laptop.
1. Download and set executable:
curl -Lo minikube https://storage.googleapis.com/minikube/releases/latest/minikube-darwin-amd64 \ && chmod +x minikube
2. Move the binary to your PATH:
sudo mv minikube /usr/local/bin
Full instructions are available at https://kubernetes.io/docs/tasks/tools/install-minikube/
1. Start Minikube and create a cluster:
minikube start
The output will be similar to this:
minikube v1.8.1 on Darwin 10.14.6 Automatically selected the hyperkit driver Downloading VM boot image ... Creating hyperkit VM (CPUs=2, Memory=3072MB, Disk=20000MB) ... Preparing Kubernetes v1.17.3 on Docker 19.03.6 ... Launching Kubernetes ... Enabling addons: default-storageclass, storage-provisioner Waiting for cluster to come online ... Done! kubectl is now configured to use "minikube"
1. Run a sample HTTP application
kubectl run hello-minikube --image=gcr.io/google_containers/echoserver:1.4 --port=8080
2. Expose the service so that external connections can be made
kubectl expose deployment hello-minikube --type=NodePort
3. Inspect the pod
kubectl get pod
4. Once the STATUS is Running, test the service using curl
curl $(minikube service hello-minikube --url)
5. Delete the service and deployment
kubectl delete services hello-minikube kubectl delete deployment hello-minikube
Full instructions are available at https://kubernetes.io/docs/setup/minikube/#quickstart
To deploy a MySQL database image, we’ll use an example YAML file provided in the kubernetes website k8s.io.
1. Create persistent storage using PersistentVolume and PersistentVolumeClaim
kubectl apply -f https://k8s.io/examples/application/mysql/mysql-pv.yaml
2. Deploy the MySQL image
kubectl apply -f https://k8s.io/examples/application/mysql/mysql-deployment.yaml
3. Inspect the deployment
kubectl describe deployment mysql kubectl get pods -l app=mysql kubectl describe pvc mysql-pv-claim
4. Run MySQL client to test
kubectl run -it --rm --image=mysql:5.6 --restart=Never mysql-client -- mysql -h mysql -ppassword
Full instructions are available at https://kubernetes.io/docs/tasks/run-application/run-single-instance-stateful-application/
Once the MySQL database is running, let’s run a Docker image for Joget Enterprise that connects to that MySQL service.
1. Deploy joget image using an example YAML file. Download the contents of joget-dx-deployment.yaml into a file with the same name and run kubectl.
kubectl apply -f joget-dx-deployment.yaml
2. Inspect the deployment
kubectl describe deployment joget kubectl get pods -l app=joget
3. Once the STATUS is Running, get the URL for the service
minikube service joget --url
4. Access the URL in a browser with an additional /jw in the path to access the Joget App Center e.g. http://192.168.99.100:32496/jw
You now have a running installation of Joget, and you’ll be able to visually build a full app in 30 minutes without coding.
Now we can demonstrate how Kubernetes can be used to manually increase and decrease the number of Pods running.
1. Scale the deployment to 2 pods (called replicas)
kubectl scale --replicas=2 deployment joget
2. Examine the running pods, and you should see 2 pods running Joget
kubectl get pods NAME READY STATUS RESTARTS AGE joget-7d879db895-c9sbb 1/1 Running 0 27s joget-7d879db895-wpnsf 1/1 Running 0 37m mysql-7b9b7999d8-lk9gq 1/1 Running 0 65m
3. Scale the deployment down to 1 pod
kubectl scale --replicas=1 deployment joget
4. Examine the running pods, and you should now see 1 pod running Joget.
kubectl get pods