k3OS is a Linux distribution designed to remove as much OS maintenance
as possible in a Kubernetes cluster. It is specifically designed to only
have what is needed to run k3s. Additionally
the OS is designed to be managed by kubectl
once a cluster is bootstrapped.
Nodes only need to join a cluster and then all aspects of the OS can be managed
from Kubernetes. Both k3OS and k3s upgrades are handled by the k3OS operator.
Download the ISO from the latest release and run it
in VMware, VirtualBox, KVM, or bhyve. The server will automatically start a single node Kubernetes cluster.
Log in with the user rancher
and run kubectl
. This is a "live install" running from the ISO media
and changes will not persist after reboot.
To copy k3OS to local disk, after logging in as rancher
run sudo k3os install
. Then remove the ISO
from the virtual machine and reboot.
Live install (boot from ISO) requires at least 2GB of RAM. Local install requires 1GB RAM.
Core design goals of k3OS are
- Minimal OS for running Kubernetes by way of k3s
- Ability to upgrade and configure using
kubectl
- Versatile installation to allow easy creation of OS images.
Critical to the design of k3OS is how that file system is structured. A booted system will look as follows
/etc - ephemeral
/usr - read-only (except /usr/local is writable and persistent)
/k3os - system files
/home - persistent
/var - persistent
/opt - persistent
/usr/local - persistent
All configuration in the system is intended to be ephemeral. If you change anything in /etc
it
will revert on next reboot. If you wish to persist changes to the configuration they must be done
in the k3OS config.yaml
which will be applied on each boot.
The entire user space is stored in /usr
and as read-only. The only way to change /usr
is to
change versions of k3OS. The directory /usr/local
is a symlink to /var/local
and therefore
writable.
The k3OS directory contains the core operating system files references on boot to construct the file system. It contains squashfs images and binaries for k3OS, k3s, and the Linux kernel. On boot the appropriate version for all three will be chosen and configured.
Persistent changes should be kept in /var
, /usr/local
, /home
, or /opt
.
Most of the user-space binaries comes from Alpine and are repackaged for k3OS. Currently the kernel source is coming from Ubuntu 20.04 LTS. Some code and a lot of inspiration came from LinuxKit
Interactive installation is done from booting from the ISO. The installation is done by running
k3os install
. The k3os install
sub-command is only available on systems booted live.
An installation to disk will not have k3os install
. Follow the prompts to install k3OS to disk.
The installation will format an entire disk. If you have a single hard disk attached to the system it will not ask which disk but just pick the first and only one.
Installation can be automated by using kernel cmdline parameters. There are a lot of creative solutions to booting a machine with cmdline args. You can remaster the k3OS ISO, PXE boot, use qemu/kvm, or automate input with packer. The kernel and initrd are available in the k3OS release artifacts, along with the ISO.
The cmdline value k3os.mode=install
or k3os.fallback_mode=install
is required to enable automated installations.
Below is a reference of all cmdline args used to automate installation
cmdline | Default | Example | Description |
---|---|---|---|
k3os.mode | install | Boot k3OS to the installer, not an interactive session | |
k3os.fallback_mode | install | If a valid K3OS_STATE partition is not found to boot from, run the installation | |
k3os.install.silent | false | true | Ensure no questions will be asked |
k3os.install.force_efi | false | true | Force EFI installation even when EFI is not detected |
k3os.install.device | /dev/vda | Device to partition and format (/dev/sda, /dev/vda) | |
k3os.install.config_url | https://gist.github.com/.../dweomer.yaml | The URL of the config to be installed at /k3os/system/config.yaml |
|
k3os.install.iso_url | https://github.com/rancher/k3os/../k3os-amd64.iso | ISO to download and install from if booting from kernel/vmlinuz and not ISO. | |
k3os.install.no_format | true | Do not partition and format, assume layout exists already | |
k3os.install.tty | auto | ttyS0 | The tty device used for console |
k3os.install.debug | false | true | Run installation with more logging and configure debug for installed system |
k3os.install.power_off | false | true | Shutdown the machine after install instead of rebooting |
By default k3OS expects one partition to exist labeled K3OS_STATE
. K3OS_STATE
is expected to be an ext4 formatted filesystem with at least 2GB of disk space. The installer will create this
partitions and file system automatically, or you can create them manually if you have a need for an advanced file system layout.
You can install k3OS to a block device from any modern Linux distribution. Just download and run install.sh. This script will run the same installation as the ISO but is a bit more raw and will not prompt for configuration.
Usage: ./install.sh [--force-efi] [--debug] [--tty TTY] [--poweroff] [--takeover] [--no-format] [--config https://.../config.yaml] DEVICE ISO_URL
Example: ./install.sh /dev/vda https://github.com/rancher/k3os/releases/download/v0.10.0/k3os.iso
DEVICE must be the disk that will be partitioned (/dev/vda). If you are using --no-format it should be the device of the K3OS_STATE partition (/dev/vda2)
The parameters names refer to the same names used in the cmdline, refer to README.md for
more info.
To remaster the ISO all you need to do is copy /k3os
and /boot
from the ISO to a new folder. Then modify /boot/grub/grub.cfg
to add whatever kernel cmdline args for auto-installation.
To build a new ISO just use the utility grub-mkrescue
as follows:
# Ubuntu: apt install grub-efi grub-pc-bin mtools xorriso
# CentOS: dnf install grub2-efi grub2-pc mtools xorriso
# Alpine: apk add grub-bios grub-efi mtools xorriso
mount -o loop k3os.iso /mnt
mkdir -p iso/boot/grub
cp -rf /mnt/k3os iso/
cp /mnt/boot/grub/grub.cfg iso/boot/grub/
# Edit iso/boot/grub/grub.cfg
grub-mkrescue -o k3os-new.iso iso/ -- -volid K3OS
GRUB2 CAVEAT: Some non-Alpine installations of grub2 will create ${ISO}/boot/grub2
instead of ${ISO}/boot/grub
which will generally lead to broken installation media. Be mindful of this and modify the above commands
(that work with this path) accordingly. Systems that exhibit this behavior typically have grub2-mkrescue
on the path instead of grub-mkrescue
.
A special mode of installation is designed to install to a current running Linux system. This only works on ARM64 and x86_64. Download install.sh
and run with the --takeover
flag. This will install k3OS to the current root and override the grub.cfg. After you reboot the system k3OS will then delete all files on the root partition that are not k3OS and then shutdown. This mode is particularly handy when creating cloud images. This way you can use an existing base image like Ubuntu and install k3OS over the top, snapshot, and create a new image.
In order for this to work a couple of assumptions are made. First the root (/) is assumed to be an ext4 partition. Also it is assumed that grub2 is installed and looking for the configuration at /boot/grub/grub.cfg
. When running --takeover
ensure that you also set --no-format
and DEVICE must be set to the partition of /
. Refer to the AWS packer template to see this mode in action. Below is any example of how to run a takeover installation.
./install.sh --takeover --debug --tty ttyS0 --config /tmp/config.yaml --no-format /dev/vda1 https://github.com/rancher/k3os/releases/download/v0.10.0/k3os.iso
If you have a custom ARMv7 or ARM64 device you can easily use an existing bootable ARM image to create a k3OS setup.
All you must do is boot the ARM system and then extract k3os-rootfs-arm.tar.gz
to the root (stripping one path,
look at the example below) and then place your cloud-config at /k3os/system/config.yaml
. For example:
curl -sfL https://github.com/rancher/k3os/releases/download/v0.10.0/k3os-rootfs-arm.tar.gz | tar zxvf - --strip-components=1 -C /
cp myconfig.yaml /k3os/system/config.yaml
sync
reboot -f
This method places k3OS on disk and also overwrites /sbin/init
.
On next reboot your ARM bootloader and kernel should be loaded,
but then when user space is to be initialized k3OS should take over.
One important consideration at the moment is that k3OS assumes the root device is not read only.
This typically means you need to remove ro
from the kernel cmdline.
This should be fixed in a future release.
All configuration is done through a single cloud-init style config file that is either packaged in the image, downloaded though cloud-init or managed by Kubernetes. The configuration file is found at
/k3os/system/config.yaml
/var/lib/rancher/k3os/config.yaml
/var/lib/rancher/k3os/config.d/*
The /k3os/system/config.yaml
file is reserved for the system installation and should not be
modified on a running system. This file is usually populated by during the image build or
installation process and contains important bootstrap information (such as networking or cloud-init
data sources).
The /var/lib/rancher/k3os/config.yaml
or config.d/*
files are intended to be used at runtime.
These files can be manipulated manually, through scripting, or managed with the Kubernetes operator.
A full example of the k3OS configuration file is as below.
ssh_authorized_keys:
- ssh-rsa AAAAB3NzaC1yc2EAAAADAQAB...
- github:ibuildthecloud
write_files:
- encoding: ""
content: |-
#!/bin/bash
echo hello, local service start
owner: root
path: /etc/local.d/example.start
permissions: '0755'
hostname: myhost
init_cmd:
- "echo hello, init command"
boot_cmd:
- "echo hello, boot command"
run_cmd:
- "echo hello, run command"
k3os:
data_sources:
- aws
- cdrom
modules:
- kvm
- nvme
sysctl:
kernel.printk: "4 4 1 7"
kernel.kptr_restrict: "1"
dns_nameservers:
- 8.8.8.8
- 1.1.1.1
ntp_servers:
- 0.us.pool.ntp.org
- 1.us.pool.ntp.org
wifi:
- name: home
passphrase: mypassword
- name: nothome
passphrase: somethingelse
password: rancher
server_url: https://someserver:6443
token: TOKEN_VALUE
labels:
region: us-west-1
somekey: somevalue
k3s_args:
- server
- "--cluster-init"
environment:
http_proxy: http://myserver
https_proxy: http://myserver
taints:
- key1=value1:NoSchedule
- key1=value1:NoExecute
Refer to the configuration reference for full details of each configuration key.
Since k3OS is built on k3s all Kubernetes configuration is done by configuring
k3s. This is primarily done through environment
and k3s_args
keys in config.yaml
.
The write_files
key can be used to populate the /var/lib/rancher/k3s/server/manifests
folder with apps you'd like to deploy on boot.
Refer to k3s docs for more information on how to configure Kubernetes.
All configuration can be passed as kernel cmdline parameters too. The keys are dot
separated. For example k3os.token=TOKEN
. If the key is a slice, multiple values are set by
repeating the key, for example k3os.dns_nameserver=1.1.1.1 k3os.dns_nameserver=8.8.8.8
. You
can use the plural or singular form of the name, just ensure you consistently use the same form. For
map values the form key[key]=value
form is used, for example k3os.sysctl[kernel.printk]="4 4 1 7"
.
If the value has spaces in it ensure that the value is quoted. Boolean keys expect a value of
true
or false
or no value at all means true
. For example k3os.install.efi
is the same
as k3os.install.efi=true
.
Configuration is applied in three distinct phases: initrd
, boot
, runtime
. initrd
is run during the initrd phase before the root disk has been mounted. boot
is run after
the root disk is mounted and the file system is setup, but before any services have started.
There is no networking available yet at this point. The final stage runtime
is executed after
networking has come online. If you are using a configuration from a cloud provider (like AWS
userdata) it will only be run in the runtime
phase. Below is a table of which config keys
are supported in each phase.
Key | initrd | boot | runtime |
---|---|---|---|
ssh_authorized_keys | x | x | |
write_files | x | x | x |
hostname | x | x | x |
run_cmd | x | ||
boot_cmd | x | ||
init_cmd | x | ||
k3os.data_sources | x | ||
k3os.modules | x | x | x |
k3os.sysctls | x | x | x |
k3os.ntp_servers | x | x | |
k3os.dns_nameservers | x | x | |
k3os.wifi | x | x | |
k3os.password | x | x | x |
k3os.server_url | x | x | |
k3os.token | x | x | |
k3os.labels | x | x | |
k3os.k3s_args | x | x | |
k3os.environment | x | x | x |
k3os.taints | x | x |
Networking is powered by connman
. To configure networking a couple of helper keys are
available: k3os.dns_nameserver
, k3os.ntp_servers
, k3os.wifi
. Refer to the
reference for a full explanation of those keys. If you wish
to configure a HTTP proxy set the http_proxy
, and https_proxy
fields in k3os.environment
.
All other networking configuration should be done by configuring connman directly by using the
write_files
key to create connman service
files.
Upgrading and reconfiguring k3OS is all handled through the Kubernetes operator. The operator is still in development. More details to follow. The basic design is that one can set the desired k3s and k3OS versions, plus their configuration and the operator will roll that out to the cluster.
Integration with rancher/system-upgrade-controller has been implemented as of v0.9.0.
To enable a k3OS node to automatically upgrade from the latest GitHub release you will need to make sure it has the label
k3os.io/upgrade
with value latest
(for k3OS versions prior to v0.11.x please use label plan.upgrade.cattle.io/k3os-latest
). The upgrade controller will then spawn an upgrade job
that will drain most pods, upgrade the k3OS content under /k3os/system
, and then reboot. The system should come back up running the latest
kernel and k3s version bundled with k3OS and ready to schedule pods.
If your k3OS installation is running a version prior to the v0.9.0 release or one of its release candidates you can setup the system upgrade controller to upgrade your k3OS by following these steps:
# apply the system-upgrade-controller manifest (once per cluster)
kubectl apply -f https://raw.githubusercontent.com/rancher/k3os/v0.10.0/overlay/share/rancher/k3s/server/manifests/system-upgrade-controller.yaml
# after the system-upgrade-controller pod is Ready, apply the plan manifest (once per cluster)
kubectl apply -f https://raw.githubusercontent.com/rancher/k3os/v0.10.0/overlay/share/rancher/k3s/server/manifests/system-upgrade-plans/k3os-latest.yaml
# apply the `plan.upgrade.cattle.io/k3os-latest` label as described above (for every k3OS node), e.g.
kubectl label nodes -l k3os.io/mode plan.upgrade.cattle.io/k3os-latest=enabled # this should work on any cluster with k3OS installations at v0.7.0 or greater
For single-node or development use cases, where the operator is not being used, you can upgrade the rootfs and kernel with the following commands. If you do not specify K3OS_VERSION, it will default to the latest release.
When using an overlay install such as on Raspberry Pi (see ARM Overlay Installation) the original distro kernel (such as Raspbian) will continue to be used. On these systems the k3os-upgrade-kernel script will exit with a warning and perform no action.
export K3OS_VERSION=v0.10.0
/usr/share/rancher/k3os/scripts/k3os-upgrade-rootfs
/usr/share/rancher/k3os/scripts/k3os-upgrade-kernel
You should always remember to backup your data first, and reboot after upgrading.
These scripts have been deprecated as of v0.9.0 are still on the system at /usr/share/rancher/k3os/scripts
.
To build k3OS you just need Docker and then run make
. All artifacts will be put in ./dist/artifacts
.
If you are running on Linux you can run ./scripts/run
to run a VM of k3OS in the terminal. To exit
the instance type CTRL+a c
to get the qemu console and then q
for quit.
The source for the kernel is in https://github.com/rancher/k3os-kernel
and similarly you
just need to have Docker and run make
to compile the kernel.
Below is a reference of all keys available in the config.yaml
A list of SSH authorized keys that should be added to the rancher
user. k3OS primarily
has one user, rancher
. The root
account is always disabled, has no password, and is never
assigned a ssh key. SSH keys can be obtained from GitHub user accounts by using the format
github:${USERNAME}
. This is done by downloading the keys from https://github.com/${USERNAME}.keys
.
Example
ssh_authorized_keys:
- "ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQC2TBZGjE+J8ag11dzkFT58J3XPONrDVmalCNrKxsfADfyy0eqdZrG8hcAxAR/5zuj90Gin2uBR4Sw6Cn4VHsPZcFpXyQCjK1QDADj+WcuhpXOIOY3AB0LZBly9NI0ll+8lo3QtEaoyRLtrMBhQ6Mooy2M3MTG4JNwU9o3yInuqZWf9PvtW6KxMl+ygg1xZkljhemGZ9k0wSrjqif+8usNbzVlCOVQmZwZA+BZxbdcLNwkg7zWJSXzDIXyqM6iWPGXQDEbWLq3+HR1qKucTCSxjbqoe0FD5xcW7NHIME5XKX84yH92n6yn+rxSsyUfhJWYqJd+i0fKf5UbN6qLrtd/D"
- "github:ibuildthecloud"
A list of files to write to disk on boot. These files can be either plain text, gziped, base64 encoded, or base64+gzip encoded.
Example
write_files:
- encoding: b64
content: CiMgVGhpcyBmaWxlIGNvbnRyb2xzIHRoZSBzdGF0ZSBvZiBTRUxpbnV4...
owner: root:root
path: /etc/connman/main.conf
permissions: '0644'
- content: |
# My new /etc/sysconfig/samba file
SMDBOPTIONS="-D"
path: /etc/sysconfig/samba
- content: !!binary |
f0VMRgIBAQAAAAAAAAAAAAIAPgABAAAAwARAAAAAAABAAAAAAAAAAJAVAAAAAA
AEAAHgAdAAYAAAAFAAAAQAAAAAAAAABAAEAAAAAAAEAAQAAAAAAAwAEAAAAAAA
AAAAAAAAAwAAAAQAAAAAAgAAAAAAAAACQAAAAAAAAAJAAAAAAAAcAAAAAAAAAB
...
path: /bin/arch
permissions: '0555'
- content: |
15 * * * * root ship_logs
path: /etc/crontab
Set the system hostname. This value will be overwritten by DHCP if DHCP supplies a hostname for the system.
Example
hostname: myhostname
All three keys are used to run arbitrary commands on startup in the respective phases of initrd
,
boot
and runtime
. Commands are ran after write_files
so it is possible to write a script to
disk and run it from these commands. That often makes it easier to do longer form setup.
These are the data sources used for download config from cloud provider. The valid options are:
aws
cdrom
digitalocean
gcp
hetzner
openstack
packet
scaleway
vultr
More than one can be supported at a time, for example:
k3os:
data_sources:
- openstack
- cdrom
When multiple data sources are specified they are probed in order and the first to provide /run/config/userdata
will halt further processing.
A list of kernel modules to be loaded on start.
Example
k3os:
modules:
- kvm
- nvme
Kernel sysctl to setup on start. These are the same configuration you'd typically find in /etc/sysctl.conf
.
Must be specified as string values.
k3os:
sysctl:
kernel.printk: 4 4 1 7 # the YAML parser will read as a string
kernel.kptr_restrict: "1" # force the YAML parser to read as a string
Fallback ntp servers to use if NTP is not configured elsewhere in connman.
Example
k3os:
ntp_servers:
- 0.us.pool.ntp.org
- 1.us.pool.ntp.org
Fallback DNS name servers to use if DNS is not configured by DHCP or in a connman service config.
Example
k3os:
dns_nameservers:
- 8.8.8.8
- 1.1.1.1
Simple wifi configuration. All that is accepted is name
and passphrase
. If you require more
complex configuration then you should use write_files
to write a connman service config.
Example:
k3os:
wifi:
- name: home
passphrase: mypassword
- name: nothome
passphrase: somethingelse
The password for the rancher
user. By default there is no password for the rancher
user.
If you set a password at runtime it will be reset on next boot because /etc
is ephemeral. The
value of the password can be clear text or an encrypted form. The easiest way to get this encrypted
form is to just change your password on a Linux system and copy the value of the second field from
/etc/shadow
. You can also encrypt a password using openssl passwd -1
.
Example
k3os:
password: "$1$tYtghCfK$QHa51MS6MVAcfUKuOzNKt0"
Or clear text
k3os:
password: supersecure
The URL of the k3s server to join as an agent.
Example
k3os:
server_url: https://myserver:6443
The cluster secret or node token. If the value matches the format of a node token it will automatically be assumed to be a node token. Otherwise it is treated as a cluster secret.
Example
k3os:
token: myclustersecret
Or a node token
k3os:
token: "K1074ec55daebdf54ef48294b0ddf0ce1c3cb64ee7e3d0b9ec79fbc7baf1f7ddac6::node:77689533d0140c7019416603a05275d4"
Labels to be assigned to this node in Kubernetes on registration. After the node is first registered in Kubernetes the value of this setting will be ignored.
Example
k3os:
labels:
region: us-west-1
somekey: somevalue
Arguments to be passed to the k3s process. The arguments should start with server
or agent
to be valid.
k3s_args
is an exec-style (aka uninterpreted) argument array which means that when specifying a flag with a value one
must either join the flag to the value with an =
in the same array entry or specify the flag in an entry by itself
immediately followed the value in another entry, e.g.:
# K3s flags with values joined with `=` in single entry
k3os:
k3s_args:
- server
- "--cluster-cidr=10.107.0.0/23"
- "--service-cidr=10.107.1.0/23"
# Effectively invokes k3s as:
# exec "k3s" "server" "--cluster-cidr=10.107.0.0/23" "--service-cidr=10.107.1.0/23"
# K3s flags with values in following entry
k3os:
k3s_args:
- server
- "--cluster-cidr"
- "10.107.0.0/23"
- "--service-cidr"
- "10.107.1.0/23"
# Effectively invokes k3s as:
# exec "k3s" "server" "--cluster-cidr" "10.107.0.0/23" "--service-cidr" "10.107.1.0/23"
Environment variables to be set on k3s and other processes like the boot process. Primary use of this field is to set the http proxy.
Example
k3os:
environment:
http_proxy: http://myserver
https_proxy: http://myserver
Taints to set on the current node when it is first registered. After the node is first registered the value of this field is ignored.
k3os:
taints:
- "key1=value1:NoSchedule"
- "key1=value1:NoExecute"
Copyright (c) 2014-2020 Rancher Labs, Inc.
Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.