Quikly spin up an AWS EKS Kubernetes cluster using AWS CloudFormation.

Infrastructure as Code (IaC) is the recommended way to manage the cloud infrastructure that your application runs on. IaC allows you to incrementailly add/remove infrastructure as your application changes.

IaC really shines when you need to spin up a new environment. Lets say you get a huge customer who wants to be on their own instance. You can be up in running withing the hour.

This project contains 3 CloudFormation scripts. They must be created in order because they depend on each other: 1.) VPC 2.) Kubernetes Cluster (EKS) 3.) Worker Nodes (EC2)

• AWS Account
• EC2 Key Pair
• cim.sh - npm install -g cim
• AWS CLI - Amazon EKS requires at least version 1.15.32 of the AWS CLI
• kubectl & heptio-authenticator-aws

This creates the Amazon Virtual Private Cloud that our Kubernetes cluster will run inside.

Amazon Virtual Private Cloud (Amazon VPC) lets you provision a logically isolated section of the AWS Cloud where you can launch AWS resources in a virtual network that you define.

cd vpc
cim stack-up

This creates the AWS Kubernetes EKS Cluster that our worker nodes will be associated with.

Amazon Elastic Container Service for Kubernetes (Amazon EKS) makes it easy to deploy, manage, and scale containerized applications using Kubernetes on AWS.

cd cluster
cim stack-up

Record the ClusterName and ClusterEndpoint outputs because they are needed in the next few steps.

Also log into your aws account and record your new AWS EKS Kubernetes Base64 Encoded CA Cert. It is also needed in a later step.

This creates the EC2 nodes that will run our Kubernetes containers.

Amazon Elastic Compute Cloud (Amazon EC2) is a web service that provides secure, resizable compute capacity in the cloud. It is designed to make web-scale cloud computing easier for developers.

Copy the ClusterName output from the previous step into the corresponding ClusterName parameter within _cim.yml.

cd nodes
cim stack-up

Record the NodeInstanceRole outputs because it is needed later.

Once all of your stacks are up it's time to configure your local environment to connect to your new Kubernetes cluster. We also have to configure your worker nodes and associate them with your cluster.

https://docs.aws.amazon.com/eks/latest/userguide/getting-started.html#eks-configure-kubectl

We need to configure kubectl so it knows how to authenticate and connect to your new AWS EKS Kubernetes cluster.

kubectl uses config files called kubeconfig to store your cluster information.

To create your kubeconfig file:

1.) Create the default ~/.kube directory if it does not already exist.

mkdir -p ~/.kube

2.) Open your favorite text editor and copy the kubeconfig code block below into it.

apiVersion: v1
clusters:
- cluster:
    server: <endpoint-url>
    certificate-authority-data: <base64-encoded-ca-cert>
  name: kubernetes
contexts:
- context:
    cluster: kubernetes
    user: aws
  name: aws
current-context: aws
kind: Config
preferences: {}
users:
- name: aws
  user:
    exec:
      apiVersion: client.authentication.k8s.io/v1alpha1
      command: heptio-authenticator-aws
      args:
        - "token"
        - "-i"
        - "<cluster-name>"
        # - "-r"
        # - "<role-arn>"
      # env:
        # - name: AWS_PROFILE
        #   value: "<aws-profile>"

3.) Replace the <endpoint-url> with the endpoint URL that was created for your cluster. This will be the ClusterEndpoint output from the cluster stack.

4.) Replace the <base64-encoded-ca-cert> with the certificateAuthority.data that was created for your cluster. Log into your aws account and copy this value from your new EKS cluster.

5.) Replace the <cluster-name> with your cluster name. This will be the ClusterName output from the cluster stack.

6.) (Optional) To have the Heptio authenticator assume a role to perform cluster operations (instead of the default AWS credential provider chain), uncomment the -r and <role-arn> lines and substitute an IAM role ARN to use with your user.

7.) (Optional) To have the Heptio authenticator always use a specific named AWS credential profile (instead of the default AWS credential provider chain), uncomment the env lines and substitute <aws-profile> with the profile name to use.

8.) Save the file to the default kubectl folder, with your cluster name in the file name. For example, if your cluster name is <cluster-name>, save the file to ~/.kube/config-<cluster-name>.

9.) Add that file path to your KUBECONFIG environment variable so that kubectl knows where to look for your cluster configuration.

export KUBECONFIG=$KUBECONFIG:~/.kube/config-<cluster-name>

10.) (Optional) Add the configuration to your shell initialization file so that it is configured when you open a shell.

11.) Test your configuration.

kubectl get svc

Output:

NAME             TYPE        CLUSTER-IP   EXTERNAL-IP   PORT(S)   AGE
svc/kubernetes   ClusterIP   10.100.0.1   <none>        443/TCP   1m

Awesome. Now your kubectl is configured!

Next we need to enable the worker nodes to join your cluster.

Download, edit, and apply the AWS authenticator configuration map:

1.) Download the configuration map.

curl -O https://amazon-eks.s3-us-west-2.amazonaws.com/1.10.3/2018-06-05/aws-auth-cm.yaml

2.) Open the file with your favorite text editor. Replace the <ARN of instance role (not instance profile)> snippet with the NodeInstanceRole value that you recorded in the previous procedure, and save the file.

This will be the NodeInstanceRole output from the nodes stack.

Important

Do not modify any other lines in this file.

apiVersion: v1
kind: ConfigMap
metadata:
  name: aws-auth
  namespace: kube-system
data:
  mapRoles: |
    - rolearn: <ARN of instance role (not instance profile)>
      username: system:node:{{EC2PrivateDNSName}}
      groups:
        - system:bootstrappers
        - system:nodes

3.) Apply the configuration. This command may take a few minutes to finish.

kubectl apply -f aws-auth-cm.yaml

4.) Watch the status of your nodes and wait for them to reach the Ready status.

kubectl get nodes --watch

Congratulations - Your new AWS EKS Kubernetes cluster is ready.

Check out our EKS Microservice example to see how we use CodePipeline, CodeBuild, and ECR to build, test, publish, and deploy a simple microservice web app to our new Kubernetes cluster.

cd nodes
cim stack-delete

cd cluster
cim stack-delete

cd vpc
cim stack-delete