# Provisioning Compute Resources Kubernetes requires a set of machines to host the Kubernetes control plane and the worker nodes where containers are ultimately run. In this chapter, you will provision virtual machines required for running a secure and highly available Kubernetes cluster. ## Networking The Kubernetes [networking model](https://kubernetes.io/docs/concepts/cluster-administration/networking/#kubernetes-model) assumes a flat network in which containers and nodes can communicate with each other. In cases where this is not desired [network policies](https://kubernetes.io/docs/concepts/services-networking/network-policies/) can limit how groups of containers are allowed to communicate with each other and external network endpoints. > Setting up network policies is out of scope for this tutorial. ### Virtual Network In this section Virtual Network will be setup to host the Kubernetes cluster. 1. Open Virtual Machine Manager, and from menu, go to Edit -> Connection Details. 2. Go to Virtual Networks tab, and click the plus(+) button at the left lower side of the window. 3. Type `kubernetes-nw` in the textbox named `Network Name`, and click Forward. 4. Type `10.240.0.0/24` in the textbox named `Network`, type `10.240.0.2` in the textbox named `Start`, type `10.240.0.254` in the textbox named `end`, and click Forward. 5. You will be asked whether enabling IPv6 or not. Don't check the checkbox, and click Forward. 6. Click the radiobutton named `Forwarding to physical network`, type `kubernetes-nw.com` in the textbox named `DNS Domain Name`, and click Finish. 7. Click the network created above, and take a note of the value of Device. This value will be needed when setting routing. ## Virtual Machines The virtual machines in this lab will be provisioned using [Ubuntu Server](https://www.ubuntu.com/server) 16.04. Each virtual machines will be provisioned with a fixed private IP address to simplify the Kubernetes bootstrapping process. The following virtual machines will be setup in this chapter: | Name | vCPU | Ram (MB) | Hostname | IP Address | |--------------|------|----------|--------------|-------------| | lb-1 | 1 | 256 | lb-1 | 10.240.0.10 | | controller-1 | 1 | 512 | controller-1 | 10.240.0.11 | | controller-2 | 1 | 512 | controller-2 | 10.240.0.12 | | controller-3 | 1 | 512 | controller-3 | 10.240.0.13 | | worker-1 | 1 | 1024 | worker-1 | 10.240.0.21 | | worker-2 | 1 | 1024 | worker-2 | 10.240.0.22 | | worker-3 | 1 | 1024 | worker-3 | 10.240.0.23 | | client-1 | 1 | 256 | client-1 | 10.240.0.99 | ### Base Image As installing OS to each virtual machine manually is time-consuming, using a base image where OS is already installed is very handy. In this tutorial, `ubuntu-xenial.qcow2` is assumed to be the base image. ### Kubernetes Controllers Create three virtual instances which will host the Kubernetes control plane: 1. Open a terminal, or login to the linux server, and move to the directory where the base image exists (maybe `/var/lib/libvirt/images`?). 2. Create images for Kubernetes controllers backed by the base image: ``` # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-controller-1.qcow2 # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-controller-2.qcow2 # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-controller-3.qcow2 ``` (Using each image created above, repeat from 3. to 7..) 3. Open Virtual Machine Manager, and click the icon named 'Create a new virtual machine'. 4. Check the radiobutton named `Importing existing disk image`, and click Forward 5. Click Browse, click the n-th controller image, click Choose Volume, choose the operating system (`Ubuntu 16.04` in this case), and click Forward. 6. Type `512` in the textbox named `Memory`, and click Forward. 7. Type `controller-n`, click Network selection, select the network `kubernetes-nw`, and click Finish. (Todo: Setup Network Interface) ### Kubernetes Workers Each worker instance requires a pod subnet allocation from the Kubernetes cluster CIDR range. The pod subnet allocation will be used to configure container networking in a later exercise. The `pod-cidr` instance metadata will be used to expose pod subnet allocations to compute instances at runtime. > The Kubernetes cluster CIDR range is defined by the Controller Manager's `--cluster-cidr` flag. In this tutorial the cluster CIDR range will be set to `10.200.0.0/16`, which supports 254 subnets. Create three virtual machines which will host the Kubernetes worker nodes: 1. Open a terminal, or login to the linux server, and move to the directory where the base image exists (maybe `/var/lib/libvirt/images`?). 2. Create images for Kubernetes controllers backed by the base image: ``` # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-worker-1.qcow2 # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-worker-2.qcow2 # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-worker-3.qcow2 ``` (Using each image created above, repeat from 3. to 7..) 3. Open Virtual Machine Manager, and click the icon named 'Create a new virtual machine'. 4. Check the radiobutton named `Importing existing disk image`, and click Forward 5. Click Browse, click the n-th controller image, click Choose Volume, choose the operating system (`Ubuntu 16.04` in this case), and click Forward. 6. Type `512` in the textbox named `Memory`, and click Forward. 7. Type `worker-n`, click Network selection, select the network `kubernetes-nw`, and click Finish. (Todo: Setup Network Interface) ### Load Balancer for Kubernetes API Server Kuberentes API Server... 1. Open a terminal, or login to the linux server, and move to the directory where the base image exists (maybe `/var/lib/libvirt/images`?). 2. Create images for Kubernetes controllers backed by the base image: ``` # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-lb-1.qcow2 ``` 3. Open Virtual Machine Manager, and click the icon named 'Create a new virtual machine'. 4. Check the radiobutton named `Importing existing disk image`, and click Forward 5. Click Browse, click the n-th controller image, click Choose Volume, choose the operating system (`Ubuntu 16.04` in this case), and click Forward. 6. Type `512` in the textbox named `Memory`, and click Forward. 7. Type `lb-1`, click Network selection, select the network `kubernetes-nw`, and click Finish. ### Client for Kubernetes Create a virtual machine, instead of Cloud Shell in GCP, that will be used as a client for Kubernetes. 1. Open a terminal, or login to the linux server, and move to the directory where the base image exists (maybe `/var/lib/libvirt/images`?). 2. Create images for Kubernetes controllers backed by the base image: ``` # qemu-img create -f qcow2 ubuntu-xenial.qcow -b ubuntu-xenial-client-1.qcow2 ``` 3. Open Virtual Machine Manager, and click the icon named 'Create a new virtual machine'. 4. Check the radiobutton named `Importing existing disk image`, and click Forward 5. Click Browse, click the n-th controller image, click Choose Volume, choose the operating system (`Ubuntu 16.04` in this case), and click Forward. 6. Type `512` in the textbox named `Memory`, and click Forward. 7. Type `client-1`, click Network selection, select the network `kubernetes-nw`, and click Finish. ### Setup The Hostname and The IP Address of each Virtual Machine As described above, the IP address of each virtual machine should be fixed. Referring to the environment information described above, Set the IP Address to each virtual machine. 1. Login to the virtual machine. 2. Set the hostname: ``` $ sudo hostnamectl set-hostname ``` 3. Edit configuration of network interfaces: ``` $ sudo vi /etc/network/interfaces $ cat /etc/network/interfaces ``` `interfaces` must look like this: ``` master@lb-0:~$ cat /etc/network/interfaces # This file describes the network interfaces available on your system # and how to activate them. For more information, see interfaces(5). source /etc/network/interfaces.d/* # The loopback network interface auto lo iface lo inet loopback # The primary network interface auto ens3 # The interface for kubernetes-nw iface ens3 inet static # static is set. address 10.240.0.10 # IP Address of the virtual machine netmask 255.255.255.0 # netmask of kubernetes-nw gateway 10.240.0.1 # gateway of kubernetes-nw dns-nameservers 10.240.0.1 # nameserver of kubernetes-nw master@lb-0:~$ ``` 4. Reboot. ``` $ sudo reboot ``` ### Modify `hosts` Though resolving hostnames is unnecessary, ... 1. In the host PC, create a text file listing IP addresses and hostnames: ``` $ cat << EOF > new_hosts 10.240.0.11 controller-1 10.240.0.12 controller-2 10.240.0.13 controller-3 10.240.0.10 lb-1 10.240.0.21 worker-1 10.240.0.22 worker-2 10.240.0.23 worker-3 10.240.0.99 client-1 EOF ``` ### Verification List the compute instances in your default compute zone: ``` gcloud compute instances list ``` > output ``` NAME ZONE MACHINE_TYPE PREEMPTIBLE INTERNAL_IP EXTERNAL_IP STATUS controller-0 us-west1-c n1-standard-1 10.240.0.10 XX.XXX.XXX.XXX RUNNING controller-1 us-west1-c n1-standard-1 10.240.0.11 XX.XXX.X.XX RUNNING controller-2 us-west1-c n1-standard-1 10.240.0.12 XX.XXX.XXX.XX RUNNING worker-0 us-west1-c n1-standard-1 10.240.0.20 XXX.XXX.XXX.XX RUNNING worker-1 us-west1-c n1-standard-1 10.240.0.21 XX.XXX.XX.XXX RUNNING worker-2 us-west1-c n1-standard-1 10.240.0.22 XXX.XXX.XX.XX RUNNING ``` ## Configuring SSH Access SSH will be used to configure the controller and worker instances. When connecting to compute instances for the first time SSH keys will be generated for you and stored in the project or instance metadata as describe in the [connecting to instances](https://cloud.google.com/compute/docs/instances/connecting-to-instance) documentation. Test SSH access to the `controller-0` compute instances: ``` gcloud compute ssh controller-0 ``` If this is your first time connecting to a compute instance SSH keys will be generated for you. Enter a passphrase at the prompt to continue: ``` WARNING: The public SSH key file for gcloud does not exist. WARNING: The private SSH key file for gcloud does not exist. WARNING: You do not have an SSH key for gcloud. WARNING: SSH keygen will be executed to generate a key. Generating public/private rsa key pair. Enter passphrase (empty for no passphrase): Enter same passphrase again: ``` At this point the generated SSH keys will be uploaded and stored in your project: ``` Your identification has been saved in /home/$USER/.ssh/google_compute_engine. Your public key has been saved in /home/$USER/.ssh/google_compute_engine.pub. The key fingerprint is: SHA256:nz1i8jHmgQuGt+WscqP5SeIaSy5wyIJeL71MuV+QruE $USER@$HOSTNAME The key's randomart image is: +---[RSA 2048]----+ | | | | | | | . | |o. oS | |=... .o .o o | |+.+ =+=.+.X o | |.+ ==O*B.B = . | | .+.=EB++ o | +----[SHA256]-----+ Updating project ssh metadata...-Updated [https://www.googleapis.com/compute/v1/projects/$PROJECT_ID]. Updating project ssh metadata...done. Waiting for SSH key to propagate. ``` After the SSH keys have been updated you'll be logged into the `controller-0` instance: ``` Welcome to Ubuntu 18.04 LTS (GNU/Linux 4.15.0-1006-gcp x86_64) ... Last login: Sun May 13 14:34:27 2018 from XX.XXX.XXX.XX ``` Type `exit` at the prompt to exit the `controller-0` compute instance: ``` $USER@controller-0:~$ exit ``` > output ``` logout Connection to XX.XXX.XXX.XXX closed ``` Next: [Provisioning a CA and Generating TLS Certificates](04-certificate-authority.md)