Kubernetes driver
The Kubernetes driver lets you connect your local development or CI environments to builders in a Kubernetes cluster to allow access to more powerful compute resources, optionally on multiple native architectures.
Synopsis
Run the following command to create a new builder, named kube
, that uses the
Kubernetes driver:
$ docker buildx create \
--bootstrap \
--name=kube \
--driver=kubernetes \
--driver-opt=[key=value,...]
The following table describes the available driver-specific options that you
can pass to --driver-opt
:
Parameter | Type | Default | Description |
---|---|---|---|
image |
String | Sets the image to use for running BuildKit. | |
namespace |
String | Namespace in current Kubernetes context | Sets the Kubernetes namespace. |
default-load |
Boolean | false |
Automatically load images to the Docker Engine image store. |
replicas |
Integer | 1 | Sets the number of Pod replicas to create. See scaling BuildKit |
requests.cpu |
CPU units | Sets the request CPU value specified in units of Kubernetes CPU. For example requests.cpu=100m or requests.cpu=2 |
|
requests.memory |
Memory size | Sets the request memory value specified in bytes or with a valid suffix. For example requests.memory=500Mi or requests.memory=4G |
|
requests.ephemeral-storage |
Storage size | Sets the request ephemeral-storage value specified in bytes or with a valid suffix. For example requests.ephemeral-storage=2Gi |
|
limits.cpu |
CPU units | Sets the limit CPU value specified in units of Kubernetes CPU. For example requests.cpu=100m or requests.cpu=2 |
|
limits.memory |
Memory size | Sets the limit memory value specified in bytes or with a valid suffix. For example requests.memory=500Mi or requests.memory=4G |
|
limits.ephemeral-storage |
Storage size | Sets the limit ephemeral-storage value specified in bytes or with a valid suffix. For example requests.ephemeral-storage=100M |
|
nodeselector |
CSV string | Sets the pod's nodeSelector label(s). See
node assignment. |
|
annotation |
CSV string | Sets additional annotations on the deployments and pods. | |
labels |
CSV string | Sets additional labels on the deployments and pods. | |
tolerations |
CSV string | Configures the pod's taint toleration. See node assignment. | |
serviceaccount |
String | Sets the pod's serviceAccountName . |
|
schedulername |
String | Sets the scheduler responsible for scheduling the pod. | |
timeout |
Time | 120s |
Set the timeout limit that determines how long Buildx will wait for pods to be provisioned before a build. |
rootless |
Boolean | false |
Run the container as a non-root user. See rootless mode. |
loadbalance |
String | sticky |
Load-balancing strategy (sticky or random ). If set to sticky , the pod is chosen using the hash of the context path. |
qemu.install |
Boolean | false |
Install QEMU emulation for multi platforms support. See QEMU. |
qemu.image |
String | tonistiigi/binfmt:latest |
Sets the QEMU emulation image. See QEMU. |
Scaling BuildKit
One of the main advantages of the Kubernetes driver is that you can scale the number of builder replicas up and down to handle increased build load. Scaling is configurable using the following driver options:
-
replicas=N
This scales the number of BuildKit pods to the desired size. By default, it only creates a single pod. Increasing the number of replicas lets you take advantage of multiple nodes in your cluster.
-
requests.cpu
,requests.memory
,requests.ephemeral-storage
,limits.cpu
,limits.memory
,limits.ephemeral-storage
These options allow requesting and limiting the resources available to each BuildKit pod according to the official Kubernetes documentation here.
For example, to create 4 replica BuildKit pods:
$ docker buildx create \
--bootstrap \
--name=kube \
--driver=kubernetes \
--driver-opt=namespace=buildkit,replicas=4
Listing the pods, you get this:
$ kubectl -n buildkit get deployments
NAME READY UP-TO-DATE AVAILABLE AGE
kube0 4/4 4 4 8s
$ kubectl -n buildkit get pods
NAME READY STATUS RESTARTS AGE
kube0-6977cdcb75-48ld2 1/1 Running 0 8s
kube0-6977cdcb75-rkc6b 1/1 Running 0 8s
kube0-6977cdcb75-vb4ks 1/1 Running 0 8s
kube0-6977cdcb75-z4fzs 1/1 Running 0 8s
Additionally, you can use the loadbalance=(sticky|random)
option to control
the load-balancing behavior when there are multiple replicas. random
selects
random nodes from the node pool, providing an even workload distribution across
replicas. sticky
(the default) attempts to connect the same build performed
multiple times to the same node each time, ensuring better use of local cache.
For more information on scalability, see the options for
docker buildx create
.
Node assignment
The Kubernetes driver allows you to control the scheduling of BuildKit pods
using the nodeSelector
and tolerations
driver options.
You can also set the schedulername
option if you want to use a custom scheduler altogether.
You can use the annotations
and labels
driver options to apply additional
metadata to the deployments and pods that's hosting your builders.
The value of the nodeSelector
parameter is a comma-separated string of
key-value pairs, where the key is the node label and the value is the label
text. For example: "nodeselector=kubernetes.io/arch=arm64"
The tolerations
parameter is a semicolon-separated list of taints. It accepts
the same values as the Kubernetes manifest. Each tolerations
entry specifies
a taint key and the value, operator, or effect. For example:
"tolerations=key=foo,value=bar;key=foo2,operator=exists;key=foo3,effect=NoSchedule"
These options accept CSV-delimited strings as values. Due to quoting rules for
shell commands, you must wrap the values in single quotes. You can even wrap all
of --driver-opt
in single quotes, for example:
$ docker buildx create \
--bootstrap \
--name=kube \
--driver=kubernetes \
'--driver-opt="nodeselector=label1=value1,label2=value2","tolerations=key=key1,value=value1"'
Multi-platform builds
The Kubernetes driver has support for creating multi-platform images, either using QEMU or by leveraging the native architecture of nodes.
QEMU
Like the docker-container
driver, the Kubernetes driver also supports using
QEMU (user
mode) to build images for non-native platforms. Include the --platform
flag
and specify which platforms you want to output to.
For example, to build a Linux image for amd64
and arm64
:
$ docker buildx build \
--builder=kube \
--platform=linux/amd64,linux/arm64 \
-t <user>/<image> \
--push .
Warning
QEMU performs full-CPU emulation of non-native platforms, which is much slower than native builds. Compute-heavy tasks like compilation and compression/decompression will likely take a large performance hit.
Using a custom BuildKit image or invoking non-native binaries in builds may
require that you explicitly turn on QEMU using the qemu.install
option when
creating the builder:
$ docker buildx create \
--bootstrap \
--name=kube \
--driver=kubernetes \
--driver-opt=namespace=buildkit,qemu.install=true
Native
If you have access to cluster nodes of different architectures, the Kubernetes
driver can take advantage of these for native builds. To do this, use the
--append
flag of docker buildx create
.
First, create your builder with explicit support for a single architecture, for
example amd64
:
$ docker buildx create \
--bootstrap \
--name=kube \
--driver=kubernetes \
--platform=linux/amd64 \
--node=builder-amd64 \
--driver-opt=namespace=buildkit,nodeselector="kubernetes.io/arch=amd64"
This creates a Buildx builder named kube
, containing a single builder node
named builder-amd64
. Assigning a node name using --node
is optional. Buildx
generates a random node name if you don't provide one.
Note that the Buildx concept of a node isn't the same as the Kubernetes concept of a node. A Buildx node in this case could connect multiple Kubernetes nodes of the same architecture together.
With the kube
builder created, you can now introduce another architecture into
the mix using --append
. For example, to add arm64
:
$ docker buildx create \
--append \
--bootstrap \
--name=kube \
--driver=kubernetes \
--platform=linux/arm64 \
--node=builder-arm64 \
--driver-opt=namespace=buildkit,nodeselector="kubernetes.io/arch=arm64"
Listing your builders shows both nodes for the kube
builder:
$ docker buildx ls
NAME/NODE DRIVER/ENDPOINT STATUS PLATFORMS
kube kubernetes
builder-amd64 kubernetes:///kube?deployment=builder-amd64&kubeconfig= running linux/amd64*, linux/amd64/v2, linux/amd64/v3, linux/386
builder-arm64 kubernetes:///kube?deployment=builder-arm64&kubeconfig= running linux/arm64*
You can now build multi-arch amd64
and arm64
images, by specifying those
platforms together in your build command:
$ docker buildx build --builder=kube --platform=linux/amd64,linux/arm64 -t <user>/<image> --push .
You can repeat the buildx create --append
command for as many architectures
that you want to support.
Rootless mode
The Kubernetes driver supports rootless mode. For more information on how rootless mode works, and it's requirements, see here.
To turn it on in your cluster, you can use the rootless=true
driver option:
$ docker buildx create \
--name=kube \
--driver=kubernetes \
--driver-opt=namespace=buildkit,rootless=true
This will create your pods without securityContext.privileged
.
Requires Kubernetes version 1.19 or later. Using Ubuntu as the host kernel is recommended.
Example: Creating a Buildx builder in Kubernetes
This guide shows you how to:
- Create a namespace for your Buildx resources
- Create a Kubernetes builder.
- List the available builders
- Build an image using your Kubernetes builders
Prerequisites:
- You have an existing Kubernetes cluster. If you don't already have one, you can follow along by installing minikube.
- The cluster you want to connect to is accessible via the
kubectl
command, with theKUBECONFIG
environment variable set appropriately if necessary.
-
Create a
buildkit
namespace.Creating a separate namespace helps keep your Buildx resources separate from other resources in the cluster.
$ kubectl create namespace buildkit namespace/buildkit created
-
Create a new builder with the Kubernetes driver:
$ docker buildx create \ --bootstrap \ --name=kube \ --driver=kubernetes \ --driver-opt=namespace=buildkit
Note
Remember to specify the namespace in driver options.
-
List available builders using
docker buildx ls
$ docker buildx ls NAME/NODE DRIVER/ENDPOINT STATUS PLATFORMS kube kubernetes kube0-6977cdcb75-k9h9m running linux/amd64, linux/amd64/v2, linux/amd64/v3, linux/386 default * docker default default running linux/amd64, linux/386
-
Inspect the running pods created by the build driver with
kubectl
.$ kubectl -n buildkit get deployments NAME READY UP-TO-DATE AVAILABLE AGE kube0 1/1 1 1 32s $ kubectl -n buildkit get pods NAME READY STATUS RESTARTS AGE kube0-6977cdcb75-k9h9m 1/1 Running 0 32s
The build driver creates the necessary resources on your cluster in the specified namespace (in this case,
buildkit
), while keeping your driver configuration locally. -
Use your new builder by including the
--builder
flag when running buildx commands. For example: :# Replace <registry> with your Docker username # and <image> with the name of the image you want to build docker buildx build \ --builder=kube \ -t <registry>/<image> \ --push .
That's it: you've now built an image from a Kubernetes pod, using Buildx.
Further reading
For more information on the Kubernetes driver, see the buildx reference.