apiVersion: "v1"
kind: "BuildConfig"
metadata:
name: "sample-build"
spec:
resources:
limits:
cpu: "100m" (1)
memory: "256Mi" (2)
The following sections provide instructions for advanced build operations including setting build resources and maximum duration, assigning builds to nodes, chaining builds, build pruning, and build run policies.
By default, builds are completed by pods using unbound resources, such as memory and CPU. These resources can be limited.
You can limit resource use in two ways:
Limit resource use by specifying resource limits in the default container limits of a project.
Limit resource use by specifying resource limits as part of the build configuration. ** In the following example, each of the resources
, cpu
, and memory
parameters are optional:
apiVersion: "v1"
kind: "BuildConfig"
metadata:
name: "sample-build"
spec:
resources:
limits:
cpu: "100m" (1)
memory: "256Mi" (2)
1 | cpu is in CPU units: 100m represents 0.1 CPU units (100 * 1e-3). |
2 | memory is in bytes: 256Mi represents 268435456 bytes (256 * 2 ^ 20). |
However, if a quota has been defined for your project, one of the following two items is required:
A resources
section set with an explicit requests
:
resources:
requests: (1)
cpu: "100m"
memory: "256Mi"
1 | The requests object contains the list of resources that correspond to the list of resources in the quota. |
A limit range defined in your project, where the defaults from the LimitRange
object apply to pods created during the build process.
Otherwise, build pod creation will fail, citing a failure to satisfy quota.
When defining a BuildConfig
object, you can define its maximum duration by setting the completionDeadlineSeconds
field. It is specified in seconds and is not set by default. When not set, there is no maximum duration enforced.
The maximum duration is counted from the time when a build pod gets scheduled in the system, and defines how long it can be active, including the time needed to pull the builder image. After reaching the specified timeout, the build is terminated by OpenShift Container Platform.
To set maximum duration, specify completionDeadlineSeconds
in your BuildConfig
. The following example shows the part of a BuildConfig
specifying completionDeadlineSeconds
field for 30 minutes:
spec:
completionDeadlineSeconds: 1800
This setting is not supported with the Pipeline Strategy option. |
Builds can be targeted to run on specific nodes by specifying labels in the nodeSelector
field of a build configuration. The nodeSelector
value is a set of key-value pairs that are matched to Node
labels when scheduling the build pod.
The nodeSelector
value can also be controlled by cluster-wide default and override values. Defaults will only be applied if the build configuration does not define any key-value pairs for the nodeSelector
and also does not define an explicitly empty map value of nodeSelector:{}
. Override values will replace values in the build configuration on a key by key basis.
If the specified |
Assign builds to run on specific nodes by assigning labels in the nodeSelector
field of the BuildConfig
, for example:
apiVersion: "v1"
kind: "BuildConfig"
metadata:
name: "sample-build"
spec:
nodeSelector:(1)
key1: value1
key2: value2
1 | Builds associated with this build configuration will run only on nodes with the key1=value2 and key2=value2 labels. |
For compiled languages such as Go, C, C++, and Java, including the dependencies necessary for compilation in the application image might increase the size of the image or introduce vulnerabilities that can be exploited.
To avoid these problems, two builds can be chained together. One build that produces the compiled artifact, and a second build that places that artifact in a separate image that runs the artifact.
In the following example, a source-to-image (S2I) build is combined with a docker build to compile an artifact that is then placed in a separate runtime image.
Although this example chains a S2I build and a docker build, the first build can use any strategy that produces an image containing the desired artifacts, and the second build can use any strategy that can consume input content from an image. |
The first build takes the application source and produces an image containing a WAR
file. The image is pushed to the artifact-image
image stream. The path of the output artifact depends on the assemble
script of the S2I builder used. In this case, it is output to /wildfly/standalone/deployments/ROOT.war
.
apiVersion: v1
kind: BuildConfig
metadata:
name: artifact-build
spec:
output:
to:
kind: ImageStreamTag
name: artifact-image:latest
source:
git:
uri: https://github.com/openshift/openshift-jee-sample.git
ref: "master"
strategy:
sourceStrategy:
from:
kind: ImageStreamTag
name: wildfly:10.1
namespace: openshift
The second build uses image source with a path to the WAR file inside the output image from the first build. An inline dockerfile
copies that WAR
file into a runtime image.
apiVersion: v1
kind: BuildConfig
metadata:
name: image-build
spec:
output:
to:
kind: ImageStreamTag
name: image-build:latest
source:
dockerfile: |-
FROM jee-runtime:latest
COPY ROOT.war /deployments/ROOT.war
images:
- from: (1)
kind: ImageStreamTag
name: artifact-image:latest
paths: (2)
- sourcePath: /wildfly/standalone/deployments/ROOT.war
destinationDir: "."
strategy:
dockerStrategy:
from: (3)
kind: ImageStreamTag
name: jee-runtime:latest
triggers:
- imageChange: {}
type: ImageChange
1 | from specifies that the docker build should include the output of the image from the artifact-image image stream, which was the target of the previous build. |
2 | paths specifies which paths from the target image to include in the current docker build. |
3 | The runtime image is used as the source image for the docker build. |
The result of this setup is that the output image of the second build does not have to contain any of the build tools that are needed to create the WAR
file. Also, because the second build contains an image change trigger, whenever the first build is run and produces a new image with the binary artifact, the second build is automatically triggered to produce a runtime image that contains that artifact. Therefore, both builds behave as a single build with two stages.
By default, builds that have completed their lifecycle are persisted indefinitely. You can limit the number of previous builds that are retained.
Limit the number of previous builds that are retained by supplying a positive integer value for successfulBuildsHistoryLimit
or failedBuildsHistoryLimit
in your BuildConfig
, for example:
apiVersion: "v1"
kind: "BuildConfig"
metadata:
name: "sample-build"
spec:
successfulBuildsHistoryLimit: 2 (1)
failedBuildsHistoryLimit: 2 (2)
1 | successfulBuildsHistoryLimit will retain up to two builds with a status of completed . |
2 | failedBuildsHistoryLimit will retain up to two builds with a status of failed , canceled , or error . |
Trigger build pruning by one of the following actions:
Updating a build configuration.
Waiting for a build to complete its lifecycle.
Builds are sorted by their creation timestamp with the oldest builds being pruned first.
Administrators can manually prune builds using the 'oc adm' object pruning command. |
The build run policy describes the order in which the builds created from the build configuration should run. This can be done by changing the value of the runPolicy
field in the spec
section of the Build
specification.
It is also possible to change the runPolicy
value for existing build configurations, by:
Changing Parallel
to Serial
or SerialLatestOnly
and triggering a new build from this configuration causes the new build to wait until all parallel builds complete as the serial build can only run alone.
Changing Serial
to SerialLatestOnly
and triggering a new build causes cancellation of all existing builds in queue, except the currently running build and the most recently created build. The newest build runs next.