Terraform module for bootstrapping a Kubernetes cluster with kubeadm on AWS.
This module allows to create AWS infrastructure and bootstrap a Kubernetes cluster on it with a single command.
Running the module results in a freshly bootstrapped Kubernetes cluster — like what you get after manually bootstrapping a cluster with kubeadm init and kubeadm join.
The module also creates a kubeconfig file on your local machine so that you can access the cluster right away.
The number and types of nodes, the Pod network CIDR block, and many other parameters are configurable.
Notes:
- The module does not install any CNI plugin in the cluster, which reflects the behaviour of kubeadm
- For now, the created clusters are limited to a single master node
The module is intended to be used for experiments. It automates the process of bootstrapping a cluster, which allows you to create a series of clusters quickly and then run experiments on them.
The module does on purpose not produce production-ready cluster, for example, by installing a CNI plugin, because this might interfere with experiments that you want to run on the bootstrapped clusters.
In other words, since the module does not install a CNI plugin by default, you can use this module to test arbitrary configurations of CNI plugins on a freshly bootstrapped cluster.
In order to use this module, make sure to meet the following prerequisites.
Install Terraform as described in the Terraform documentation.
If you use macOS, you can simply do:
brew install terraformInstall the AWS CLI as described in the AWS CLI documentation.
Once this is done, run the following command:
aws configureAnd enter your AWS Access Key ID and AWS Secret Access Key in the interactive dialog.
You can find the AWS Access Key ID of your AWS user account on the IAM page of the AWS Console. The AWS Secret Access Key is only displayed immediately after creating a new AWS user and you should keep it safe.
The above command saves your credentials in a file named ~/.aws/credentials.
You can verify that the AWS credentials have been correctly configured with the following command:
aws sts get-caller-identityThe output should be something like:
{
"UserId": "XYZXYZXYZXYZXYZXYZXYZ",
"Account": "123123123123",
"Arn": "arn:aws:iam::123123123123:user/myusername"
}Verify that the Account field matches the ID of your AWS account (which you can find on the My Account page in the AWS Console), and that the Arn field includes the name of your AWS user.
The module requires the ssh and scp commands, which are most probably already installed on your system. In case they aren't, you can install them with:
# Linux
sudo apt-get install openssh-client
# macOS
brew install opensshThe module, by default, uses the default SSH key par ~/.ssh/id_rsa and ~/.ssh/id_rsa.pub to set up SSH acess to your cluster nodes. In case you don't have this key pair, you can create it with:
ssh-keygenNote that you can configure a different SSH key pair through the module's input variables.
The following demonstrates a minimal usage of the module using all the default values. This will create a Kubernetes cluster with a single master node and two worker nodes.
Create an empty directory and save the following configuration in a file named main.tf:
provider "aws" {
region = "eu-central-1"
}
module "cluster" {
source = "weibeld/kubeadm/aws"
version = "0.2.4"
}The
regionvariable specifies the AWS region in which the cluster will be created. You can insert your desired AWS region there.
Now, run the following command:
terraform initThe terraform init command downloads the module as well as the latest versions of any required providers.
Next, run:
terraform applyThe terraform apply command first displays all the AWS resources that it's planning create, and asks you in an interactive dialog if you want to proceed.
Type yes to proceed.
If you want to skip the interactive dialog and automatically proceed, you can use
terraform apply --auto-approve.
To delete the Kubernetes cluster, run the following command:
terraform destroyThe terraform destroy command first displays all the AWS resources it's planning to delete, and asks you for confirmation to proceed.
Type yes to proceed.
Again, if you want to skip the interactive dialog and automatically proceed, you can use
--auto-approveflag.
After a few minutes, all the AWS resources that you previously created should be deleted, and your AWS account should be in exactly the same state as before you created the Kubernetes cluster.
Running terraform apply with this configuration results in the creation of a Kubernetes cluster with one master node and two worker nodes in one of the default subnets of the default VPC of the eu-central-1 region.
The cluster is given a random name (e.g. relaxed-ocelot) and the module creates a kubeconfig file on your local machine that is named after the cluster it belongs to (e.g. relaxed-ocelot.conf). By default, this kubeconfig file is created in your current working directory.
You can use this kubeconfig file to access the cluster. For example:
kubectl --kubeconfig relaxed-ocelot.conf get nodesNote that if you execute the above command, you will see that all nodes are
NotReady. This is the expected behaviour because the cluster does not yet have a CNI plugin installed.
You may also set the KUBECONFIG environment variable so that you don't need to set the --kubeconfig flag for every kubectl command:
export KUBECONFIG=$(pwd)/relaxed-ocelot.confNote that when you delete the cluster with
terraform destroy, the kubeconfig file is currently not automatically deleted, thus you have to clean it up yourself if you don't want to have it sticking around.
The module also sets up SSH access to the nodes of the cluster. By default, it uses the OpenSSH default key pair consisting of ~/.ssh/id_rsa (private key) and ~/.ssh/id_rsa.pub (public key) on your local machine for this. Thus, you can connect to the nodes of the cluster as follows:
ssh -i ~/.ssh/id_rsa ubuntu@<PUBLIC-IP>The public IP addresses of all the nodes are specified in the output of the module, which you can display with terraform output.
For details about the created AWS resources, see AWS resources below. For more advanced usage examples, see the examples.
The module depends on the following prerequisites:
With the default settings (1 master node and 2 worker nodes), the module creates the following AWS resources:
| Explicitly created | Implicitly created (default sub-resources) |
|---|---|
| 4 Security Groups | |
| 1 Key Pair | |
| 1 Elastic IP | |
| 3 EC2 Instances | 3 Volumes, 3 Network Interfaces |
Total: 15 resources
Note that each node results in the creation of 3 AWS resources: 1 EC2 instance, 1 Volume, and 1 Network Interface. Consequently, you can add or subtract 3 from the total number of created AWS resources for each added or removed worker node. For example:
- 1 worker node: total 12 AWS resources
- 2 worker nodes: total 15 AWS resources
- 3 worker nodes: total 18 AWS resources
You can list all AWS resources in a given region with the Tag Editor in the AWS Console.
Note that Key Pairs are not listed in the Tag Editor.
The module assigns a tag with a key of kubeadm:cluster and a value corresponding to the cluster name to all explicitly created resources. For example, if the cluster name is relaxed-ocelot, all of the above explicitly created resources will have the following tag:
kubeadm:cluster=relaxed-ocelot
This allows you to easily identify the resources that belong to a given cluster.
Note that the implicitly created sub-resources (such as the Volumes and Network Interfaces of the EC2 Instances) won't have the
kubeadm:clustertag assigned.
Additionally, the EC2 instances will get a tag with a key of kubeadm:node and a value corresponding to the Kubernetes node name. For the master node, this is:
kubeadm:node=master
And for the worker nodes:
kubeadm:node=worker-X
Where X is an index starting at 0.
By default, the kubeadm module creates the cluster in the default VPC of the specified AWS region.
The network submodule allows you to create a dedicated VPC for your cluster.
See the cluster in dedicated VPC example for how to use the network submodule together with the kubeadm module.