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series: K8s on vSphere
tags:
- vmware
- linux
- shell
- automation
- kubernetes
- containers
- infrastructure-as-code
- packer
comment: true # Disable comment if false.
---
I've been leveraging the open-source Tanzu Community Edition Kubernetes distribution for a little while now, both [in my home lab](/tanzu-community-edition-k8s-homelab) and at work, so I was disappointed to learn that VMware was [abandoning the project](https://github.com/vmware-tanzu/community-edition). TCE had been a pretty good fit for my needs, and now I needed to search for a replacement. VMware is offering a free version of Tanzu Kubernetes Grid as a replacement, but it comes with a license solely for non-commercial use so I wouldn't be able to use it at work. And I'd really like to use the same solution in both environments to make development and testing easier on me.
There are a bunch of great projects for running Kubernetes in development/lab environments, and others optimized for much larger enterprise environments, but I struggled to find a product that felt like a good fit for both in the way TCE was. My workloads are few and pretty simple so most enterprise K8s variants (Tanzu included) would feel like overkill, but I do need to ensure everything remains highly-available in the data centers at work.
Plus, I thought it would be a fun learning experience to roll my own Kubernetes on vSphere!
In the next couple of posts, I'll share the details of how I'm using Terraform to provision production-ready vanilla Kubernetes clusters on vSphere (complete with the vSphere Container Storage Interface plugin!) in a consistent and repeatable way. I also plan to document one of the ways I'm leveraging these clusters, which is using them as a part of a Gitlab CI/CD pipeline to churn out weekly VM template builds so I never again have to worry about my templates being out of date.
I have definitely learned a ton in the process (and still have a lot more to learn), but today I'll start by describing how I'm leveraging Packer to create a single VM template ready to enter service as a Kubernetes compute node.
[HashiCorp Packer](https://www.packer.io/) is a free open-source tool designed to create consistent, repeatable machine images. It's pretty killer as a part of a CI/CD pipeline to kick off new builds based on a schedule or code commits, but also works great for creating builds on-demand. Packer uses the [HashiCorp Configuration Language (HCL)](https://developer.hashicorp.com/packer/docs/templates/hcl_templates) to describe all of the properties of a VM build in a concise and readable format.
You might ask why I would bother with using a powerful tool like Packer if I'm just going to be building a single template. Surely I could just do that by hand, right? And of course, you'd be right - but using an Infrastructure as Code tool even for one-off builds has some pretty big advantages.
- **It's fast.** Packer is able to build a complete VM (including pulling in all available OS and software updates) in just a few minutes, much faster than I could click through an installer on my own.
- **It's consistent.** Packer will follow the exact same steps for every build, removing the small variations (and typos!) that would surely show up if I did the builds manually.
- **It's great for testing changes.** Since Packer builds are so fast and consistent, it makes it incredibly easy to test changes as I go. I can be confident that the *only* changes between two builds will be the changes I deliberately introduced.
- **It's self-documenting.** The entire VM (and its guest OS) is described completely within the Packer HCL file(s), which I can review to remember which packages were installed, which user account(s) were created, what partition scheme was used, and anything else I might need to know.
- **It supports change tracking.** A Packer build is just a set of HCL files so it's easy to sync them with a version control system like Git to track (and revert) changes as needed.
Packer is also extremely versatile, and a broad set of [external plugins](https://developer.hashicorp.com/packer/plugins) expand its capabilities to support creating machines for basically any environment. For my needs, I'll be utilizing the [vsphere-iso](https://developer.hashicorp.com/packer/plugins/builders/vsphere/vsphere-iso) builder which uses the vSphere API to remotely build VMs directly on the hypervisors.
Sounds pretty cool, right? I'm not going to go too deep into "how to Packer" in this post, but HashiCorp does provide some [pretty good tutorials](https://developer.hashicorp.com/packer/tutorials) to help you get started.
## Prerequisites
### Install Packer
Before being able to *use* Packer, you have to install it. On Debian/Ubuntu Linux, this process consists of adding the HashiCorp GPG key and software repository, and then simply installing the package:
You can learn how to install Packer on other systems by following [this tutorial from HashiCorp](https://developer.hashicorp.com/packer/tutorials/docker-get-started/get-started-install-cli).
### Configure privileges
Packer will need a user account with sufficient privileges in the vSphere environment to be able to create and manage a VM. I'd recommend using an account dedicated to automation tasks, and assigning it the required privileges listed in [the `vsphere-iso` documentation](https://developer.hashicorp.com/packer/plugins/builders/vsphere/vsphere-iso#required-vsphere-privileges).
My Kubernetes node template will use Ubuntu 20.04 LTS as the OS so I'll go ahead and download the [server installer ISO](https://releases.ubuntu.com/20.04.5/) and upload it to a vSphere datastore to make it available to Packer.
After the OS is installed and minimimally configured, I'll need to add in Kubernetes components like `containerd`, `kubectl`, `kubelet`, and `kubeadm`, and then apply a few additional tweaks to get it fully ready.
You can see the entirety of my Packer configuration [on GitHub](https://github.com/jbowdre/vsphere-k8s/tree/main/packer), but I'll talk through each file as we go along.
### File/folder layout
After quite a bit of experimentation, I've settled on a preferred way to organize my Packer build files. I've found that this structure makes the builds modular enough that it's easy to reuse components in other builds, but still consolidated enough to be easily manageable. This layout is, of course, largely subjective - it's just what works well *for me*:
- The `certs` folder holds the Base64-encoded PEM-formatted certificate of my [internal Certificate Authority](/ldaps-authentication-tanzu-community-edition/#prequisite) which will be automatically installed in the provisioned VM's trusted certificate store.
- The `data` folder stores files for [generating the `cloud-init` configuration](#user-datapkrtplhcl) that will automate the OS installation and configuration.
- The `scripts` directory holds a [collection of scripts](#post_install_scripts) used for post-install configuration tasks. Sure, I could just use a single large script, but using a bunch of smaller ones helps keep things modular and easy to reuse elsewhere.
-`variables.pkr.hcl` declares [all of the variables](#variablespkrhcl) which will be used in the Packer build, and sets the default values for some of them.
-`ubuntu-k8s.auto.pkrvars.hcl` [assigns values](#ubuntu-k8sautopkrvarshcl) to those variables. This is where most of the user-facing options will be configured, such as usernames, passwords, and environment settings.
-`ubuntu-k8s.pkr.hcl` is where the [build process](#ubuntu-k8spkrhcl) is actually described.
Let's quickly run through that build process, and then I'll back up and examine some other components in detail.
### `ubuntu-k8s.pkr.hcl`
#### `packer` block
The first block in the file tells Packer about the minimum version requirements for Packer as well as the external plugins used for the build:
```
// BLOCK: packer
// The Packer configuration.
packer {
required_version = ">= 1.8.2"
required_plugins {
vsphere = {
version = ">= 1.0.8"
source = "github.com/hashicorp/vsphere"
}
sshkey = {
version = ">= 1.0.3"
source = "github.com/ivoronin/sshkey"
}
}
}
```
As I mentioned above, I'll be using the official [`vsphere` plugin](https://github.com/hashicorp/packer-plugin-vsphere) to handle the provisioning on my vSphere environment. I'll also make use of the [`sshkey` plugin](https://github.com/ivoronin/packer-plugin-sshkey) to dynamically generate SSH keys for the build process.
This will generate an ECDSA keypair, and the public key will include the identifier `packer_key` to make it easier to manage later on. Using this plugin to generate keys means that I don't have to worry about storing a private key somewhere in the build directory.
#### `locals` block
Locals are a type of Packer variable which aren't explicitly declared in the `variables.pkr.hcl` file. They only exist within the context of a single build (hence the "local" name). Typical Packer variables are static and don't support string manipulation; locals, however, do support expressions that can be used to change their value on the fly. This makes them very useful when you need to combine variables into a single string or concatenate lists of SSH public keys (such as in the highlighted lines):
This block also makes use of the built-in [`templatefile()` function](https://developer.hashicorp.com/packer/docs/templates/hcl_templates/functions/file/templatefile) to insert build-specific variables into the `user-data` file for [`cloud-init`](https://cloud-init.io/) (more on that in a bit).
The `source` block tells the `vsphere-iso` builder how to connect to vSphere, what hardware specs to set on the VM, and what to do with the VM once the build has finished (convert it to template, export it to OVF, and so on).
This block brings everything together and executes the build. It calls the `source.vsphere-iso.ubuntu-k8s` block defined above, and also ties in a `file` and a few `shell` provisioners. `file` provisioners are used to copy files (like SSL CA certificates) into the VM, while the `shell` provisioners run commands and execute scripts. Those will be handy for the post-deployment configuration tasks, like updating and installing packages.
```text
// BLOCK: build
// Defines the builders to run, provisioners, and post-processors.
So you can see that the `ubuntu-k8s.pkr.hcl` file primarily focuses on the structure and form of the build, and it's written in such a way that it can be fairly easily adapted for building other types of VMs. Very few things in this file would have to be changed since so many of the properties are derived from the variables.
You can view the full file [here](https://github.com/jbowdre/vsphere-k8s/blob/main/packer/ubuntu-k8s.pkr.hcl).
### `variables.pkr.hcl`
Before looking at the build-specific variable definitions, let's take a quick look at the variables I've told Packer that I intend to use. After all, Packer requires that variables be declared before they can be used.
Most of these carry descriptions with them so I won't restate them outside of the code block here:
```text
/*
DESCRIPTION:
Ubuntu Server 20.04 LTS variables using the Packer Builder for VMware vSphere (vsphere-iso).
*/
// BLOCK: variable
// Defines the input variables.
// vSphere Credentials
variable "vsphere_endpoint" {
type = string
description = "The fully qualified domain name or IP address of the vCenter Server instance. ('vcenter.lab.local')"
}
variable "vsphere_username" {
type = string
description = "The username to login to the vCenter Server instance. ('packer')"
sensitive = true
}
variable "vsphere_password" {
type = string
description = "The password for the login to the vCenter Server instance."
sensitive = true
}
variable "vsphere_insecure_connection" {
type = bool
description = "Do not validate vCenter Server TLS certificate."
default = true
}
// vSphere Settings
variable "vsphere_datacenter" {
type = string
description = "The name of the target vSphere datacenter. ('Lab Datacenter')"
}
variable "vsphere_cluster" {
type = string
description = "The name of the target vSphere cluster. ('cluster-01')"
}
variable "vsphere_datastore" {
type = string
description = "The name of the target vSphere datastore. ('datastore-01')"
}
variable "vsphere_network" {
type = string
description = "The name of the target vSphere network. ('network-192.168.1.0')"
}
variable "vsphere_folder" {
type = string
description = "The name of the target vSphere folder. ('_Templates')"
}
// Virtual Machine Settings
variable "vm_name" {
type = string
description = "Name of the new VM to create."
}
variable "vm_guest_os_language" {
type = string
description = "The guest operating system lanugage."
default = "en_US"
}
variable "vm_guest_os_keyboard" {
type = string
description = "The guest operating system keyboard input."
default = "us"
}
variable "vm_guest_os_timezone" {
type = string
description = "The guest operating system timezone."
default = "UTC"
}
variable "vm_guest_os_type" {
type = string
description = "The guest operating system type. ('ubuntu64Guest')"
}
variable "vm_firmware" {
type = string
description = "The virtual machine firmware. ('efi-secure'. 'efi', or 'bios')"
default = "efi-secure"
}
variable "vm_cdrom_type" {
type = string
description = "The virtual machine CD-ROM type. ('sata', or 'ide')"
default = "sata"
}
variable "vm_cpu_count" {
type = number
description = "The number of virtual CPUs. ('2')"
}
variable "vm_cpu_cores" {
type = number
description = "The number of virtual CPUs cores per socket. ('1')"
}
variable "vm_cpu_hot_add" {
type = bool
description = "Enable hot add CPU."
default = true
}
variable "vm_mem_size" {
type = number
description = "The size for the virtual memory in MB. ('2048')"
}
variable "vm_mem_hot_add" {
type = bool
description = "Enable hot add memory."
default = true
}
variable "vm_disk_size" {
type = number
description = "The size for the virtual disk in MB. ('61440' = 60GB)"
default = 61440
}
variable "vm_disk_controller_type" {
type = list(string)
description = "The virtual disk controller types in sequence. ('pvscsi')"
default = ["pvscsi"]
}
variable "vm_disk_thin_provisioned" {
type = bool
description = "Thin provision the virtual disk."
default = true
}
variable "vm_disk_eagerly_scrub" {
type = bool
description = "Enable VMDK eager scrubbing for VM."
default = false
}
variable "vm_network_card" {
type = string
description = "The virtual network card type. ('vmxnet3' or 'e1000e')"
default = "vmxnet3"
}
variable "common_vm_version" {
type = number
description = "The vSphere virtual hardware version. (e.g. '19')"
}
variable "common_tools_upgrade_policy" {
type = bool
description = "Upgrade VMware Tools on reboot."
default = true
}
variable "common_remove_cdrom" {
type = bool
description = "Remove the virtual CD-ROM(s)."
default = true
}
// Template and Content Library Settings
variable "common_template_conversion" {
type = bool
description = "Convert the virtual machine to template. Must be 'false' for content library."
default = false
}
variable "common_content_library_name" {
type = string
description = "The name of the target vSphere content library, if used. ('Lab-CL')"
default = null
}
variable "common_content_library_ovf" {
type = bool
description = "Export to content library as an OVF template."
default = false
}
variable "common_content_library_destroy" {
type = bool
description = "Delete the virtual machine after exporting to the content library."
default = true
}
variable "common_content_library_skip_export" {
type = bool
description = "Skip exporting the virtual machine to the content library. Option allows for testing / debugging without saving the machine image."
default = false
}
// Snapshot Settings
variable "common_snapshot_creation" {
type = bool
description = "Create a snapshot for Linked Clones."
default = false
}
variable "common_snapshot_name" {
type = string
description = "Name of the snapshot to be created if create_snapshot is true."
default = "Created By Packer"
}
// OVF Export Settings
variable "common_ovf_export_enabled" {
type = bool
description = "Enable OVF artifact export."
default = false
}
variable "common_ovf_export_overwrite" {
type = bool
description = "Overwrite existing OVF artifact."
default = true
}
variable "common_ovf_export_path" {
type = string
description = "Folder path for the OVF export."
}
// Removable Media Settings
variable "common_iso_datastore" {
type = string
description = "The name of the source vSphere datastore for ISO images. ('datastore-iso-01')"
}
variable "iso_url" {
type = string
description = "The URL source of the ISO image. ('https://releases.ubuntu.com/20.04.5/ubuntu-20.04.5-live-server-amd64.iso')"
}
variable "iso_path" {
type = string
description = "The path on the source vSphere datastore for ISO image. ('ISOs/Linux')"
}
variable "iso_file" {
type = string
description = "The file name of the ISO image used by the vendor. ('ubuntu-20.04.5-live-server-amd64.iso')"
}
variable "iso_checksum_type" {
type = string
description = "The checksum algorithm used by the vendor. ('sha256')"
}
variable "iso_checksum_value" {
type = string
description = "The checksum value provided by the vendor."
}
variable "cd_label" {
type = string
description = "CD Label"
default = "cidata"
}
// Boot Settings
variable "vm_boot_order" {
type = string
description = "The boot order for virtual machines devices. ('disk,cdrom')"
default = "disk,cdrom"
}
variable "vm_boot_wait" {
type = string
description = "The time to wait before boot."
}
variable "vm_boot_command" {
type = list(string)
description = "The virtual machine boot command."
default = []
}
variable "vm_shutdown_command" {
type = string
description = "Command(s) for guest operating system shutdown."
default = null
}
variable "common_ip_wait_timeout" {
type = string
description = "Time to wait for guest operating system IP address response."
}
variable "common_shutdown_timeout" {
type = string
description = "Time to wait for guest operating system shutdown."
}
// Communicator Settings and Credentials
variable "build_username" {
type = string
description = "The username to login to the guest operating system. ('admin')"
}
variable "build_password" {
type = string
description = "The password to login to the guest operating system."
sensitive = true
}
variable "build_password_encrypted" {
type = string
description = "The encrypted password to login the guest operating system."
sensitive = true
default = null
}
variable "ssh_keys" {
type = list(string)
description = "List of public keys to be added to ~/.ssh/authorized_keys."
sensitive = true
default = []
}
variable "build_remove_keys" {
type = bool
description = "If true, Packer will attempt to remove its temporary key from ~/.ssh/authorized_keys and /root/.ssh/authorized_keys"
default = true
}
// Communicator Settings
variable "communicator_port" {
type = string
description = "The port for the communicator protocol."
}
variable "communicator_timeout" {
type = string
description = "The timeout for the communicator protocol."
}
variable "communicator_insecure" {
type = bool
description = "If true, do not check server certificate chain and host name"
default = true
}
variable "communicator_ssl" {
type = bool
description = "If true, use SSL"
default = true
}
// Provisioner Settings
variable "cloud_init_apt_packages" {
type = list(string)
description = "A list of apt packages to install during the subiquity cloud-init installer."
default = []
}
variable "cloud_init_apt_mirror" {
type = string
description = "Sets the default apt mirror during the subiquity cloud-init installer."
default = ""
}
variable "post_install_scripts" {
type = list(string)
description = "A list of scripts and their relative paths to transfer and run after OS install."
default = []
}
variable "pre_final_scripts" {
type = list(string)
description = "A list of scripts and their relative paths to transfer and run before finalization."
default = []
}
// Kubernetes Settings
variable "k8s_version" {
type = string
description = "Kubernetes version to be installed. Latest stable is listed at https://dl.k8s.io/release/stable.txt"
default = "1.25.3"
}
```
The full `variables.pkr.hcl` can be viewed [here](https://github.com/jbowdre/vsphere-k8s/blob/main/packer/variables.pkr.hcl).
Packer automatically knows to load variables defined in files ending in `*.auto.pkrvars.hcl`. Storing the variable values separately from the declarations in `variables.pkr.hcl` makes it easier to protect sensitive values.
And then I'll specify the VM's boot device order, as well as the boot command that will be used for loading the `cloud-init` coniguration into the Ubuntu installer:
Once the installer is booted and running, Packer will wait until the VM is available via SSH and then use these credentials to log in. (How will it be able to log in with those creds? We'll take a look at the `cloud-init` configuration in just a minute...)
Finally, I'll create two lists of scripts that will be run on the VM once the OS install is complete. The `post_install_scripts` will be run immediately after the operating system installation. The `update-packages.sh` script will cause a reboot, and then the set of `pre_final_scripts` will do some cleanup and prepare the VM to be converted to a template.
Okay, so we've covered the Packer framework that creates the VM; now let's take a quick look at the `cloud-init` configuration that will allow the OS installation to proceed unattended.
See the bits that look `${ like_this }`? Those place-holders will take input from the [`locals` block of `ubuntu-k8s.pkr.hcl`](#locals-block) mentioned above. So that's how all the OS properties will get set, including the hostname, locale, LVM partition layout, username, password, and SSH keys.
View the full file [here](https://github.com/jbowdre/vsphere-k8s/blob/main/packer/data/user-data.pkrtpl.hcl). (The `meta-data` file is [empty](https://github.com/jbowdre/vsphere-k8s/blob/main/packer/data/meta-data), by the way.)
### `post_install_scripts`
After the OS install is completed, the `shell` provisioner will connect to the VM through SSH and run through some tasks. Remember how I keep talking about this build being modular? That goes down to the scripts, too, so I can use individual pieces in other builds without needing to do a lot of tweaking.
You can find all of the scripts [here](https://github.com/jbowdre/vsphere-k8s/tree/main/packer/scripts).
#### `wait-for-cloud-init.sh`
This simply holds up the process until the `/var/lib/cloud//instance/boot-finished` file has been created, signifying the completion of the `cloud-init` process:
The [`file` provisioner](#build-block) mentioned above helpfully copied my custom CA certs to the `/tmp/certs/` folder on the VM; this script will install them into the certificate store:
I want to make sure that this VM keeps the same IP address following the reboot that will come in a few minutes, so I 'll set a quick `cloud-init` option to help make sure that happens:
```shell
#!/bin/sh -eu
echo '>> Preserving network settings...'
echo 'manual_cache_clean: True' | sudo tee -a /etc/cloud/cloud.cfg
```
#### `configure-sshd.sh`
Then I just set a few options for the `sshd` configuration, like disabling root login:
```shell
#!/bin/bash -eu
echo '>> Configuring SSH'
sudo sed -i 's/.*PermitRootLogin.*/PermitRootLogin no/' /etc/ssh/sshd_config
sudo sed -i 's/.*PubkeyAuthentication.*/PubkeyAuthentication yes/' /etc/ssh/sshd_config
sudo sed -i 's/.*PasswordAuthentication.*/PasswordAuthentication yes/' /etc/ssh/sshd_config
```
#### `install-k8s.sh`
This script is a little longer and takes care of all the Kubernetes-specific settings and packages that will need to be installed on the VM.
First I enable the required `overlay` and `br_netfilter` modules:
sudo containerd config default | sudo tee /etc/containerd/config.toml
sudo systemctl restart containerd
```
Then disable swap:
```shell
# Disable swap
echo ".. disable swap"
sudo sed -i '/[[:space:]]swap[[:space:]]/ s/^\(.*\)$/#\1/g' /etc/fstab
sudo swapoff -a
```
Next I'll install the Kubernetes components and (crucially) `apt-mark hold` them so they won't be automatically upgraded without it being a coordinated change:
```shell
# Install Kubernetes
echo ".. install kubernetes version ${KUBEVERSION}"
Lastly, I'll be sure to update all installed packages (excepting the Kubernetes ones, of course), and then perform a reboot to make sure that any new kernel modules get loaded:
```shell
#!/bin/bash -eu
echo '>> Checking for and installing updates...'
sudo apt-get update && sudo apt-get -y upgrade
echo '>> Rebooting!'
sudo reboot
```
### `pre_final_scripts`
After the reboot, all that's left are some cleanup tasks to get the VM ready to be converted to a template and subsequently cloned and customized.
#### `cleanup-cloud-init.sh`
I'll start with cleaning up the `cloud-init` state:
```shell
#!/bin/bash -eu
echo '>> Cleaning up cloud-init state...'
sudo cloud-init clean -l
```
#### `enable-vmware-customization.sh`
And then be (re)enable the ability for VMware to be able to customize the guest successfully:
echo 'disable_vmware_customization: true' | sudo tee -a /etc/cloud/cloud.cfg
sudo vmware-toolbox-cmd config set deployPkg enable-custom-scripts true
```
#### `zero-disk.sh`
I'll also execute this handy script to free up unused space on the virtual disk. It works by creating a file which completely fills up the disk, and then deleting that file:
Lastly, let's do a final run of cleaning up logs, temporary files, and unique identifiers that don't need to exist in a template. This script will also remove the SSH key with the `packer_key` identifier since that won't be needed anymore.
Now that all the ducks are nicely lined up, let's give them some marching orders and see what happens. All I have to do is open a terminal session to the folder containing the `.pkr.hcl` files, and then run the Packer build command:
The `-on-error=abort` option makes sure that the build will abort if any steps in the build fail, and `-force` tells Packer to delete any existing VMs/templates with the same name as the one I'm attempting to build.
{{% /notice %}}
And off we go! Packer will output details as it goes which makes it easy to troubleshoot if anything goes wrong.
![Packer build session in the terminal](packer_terminal_progress.jpg)
In this case, though, everything works just fine, and I'm met with a happy "success" message!
And I can pop over to vSphere to confirm that everything looks right:
![The new template in vSphere](template_in_vsphere.png)
## Next steps
My brand new `k8s-u2004` template is ready for use! In the next post, I'll walk through the process of *manually* cloning this template to create my Kubernetes nodes, initializing the cluster, and installing the vSphere integrations. After that process is sorted out nicely, we'll take a look at how to use Terraform to do it all automagically. Stay tuned!