Managing image streams

Image streams provide a means of creating and updating container images in an on-going way. As improvements are made to an image, tags can be used to assign new version numbers and keep track of changes. This document describes how image streams are managed.

Why use imagestreams

An image stream and its associated tags provide an abstraction for referencing container images from within OKD. The image stream and its tags allow you to see what images are available and ensure that you are using the specific image you need even if the image in the repository changes.

Image streams do not contain actual image data, but present a single virtual view of related images, similar to an image repository.

You can configure builds and deployments to watch an image stream for notifications when new images are added and react by performing a build or deployment, respectively.

For example, if a deployment is using a certain image and a new version of that image is created, a deployment could be automatically performed to pick up the new version of the image.

However, if the image stream tag used by the deployment or build is not updated, then even if the container image in the container image registry is updated, the build or deployment continues using the previous, presumably known good image.

The source images can be stored in any of the following:

  • OKD’s integrated registry.

  • An external registry, for example registry.redhat.io or quay.io.

  • Other image streams in the OKD cluster.

When you define an object that references an image stream tag, such as a build or deployment configuration, you point to an image stream tag and not the repository. When you build or deploy your application, OKD queries the repository using the image stream tag to locate the associated ID of the image and uses that exact image.

The image stream metadata is stored in the etcd instance along with other cluster information.

Using image streams has several significant benefits:

  • You can tag, rollback a tag, and quickly deal with images, without having to re-push using the command line.

  • You can trigger builds and deployments when a new image is pushed to the registry. Also, OKD has generic triggers for other resources, such as Kubernetes objects.

  • You can mark a tag for periodic re-import. If the source image has changed, that change is picked up and reflected in the image stream, which triggers the build or deployment flow, depending upon the build or deployment configuration.

  • You can share images using fine-grained access control and quickly distribute images across your teams.

  • If the source image changes, the image stream tag still points to a known-good version of the image, ensuring that your application do not break unexpectedly.

  • You can configure security around who can view and use the images through permissions on the image stream objects.

  • Users that lack permission to read or list images on the cluster level can still retrieve the images tagged in a project using image streams.

Configuring image streams

An ImageStream object file contains the following elements.

Imagestream object definition

  1. apiVersion: image.openshift.io/v1
  2. kind: ImageStream
  3. metadata:
  4. annotations:
  5. openshift.io/generated-by: OpenShiftNewApp
  6. labels:
  7. app: ruby-sample-build
  8. template: application-template-stibuild
  9. name: origin-ruby-sample (1)
  10. namespace: test
  11. spec: {}
  12. status:
  13. dockerImageRepository: 172.30.56.218:5000/test/origin-ruby-sample (2)
  14. tags:
  15. - items:
  16. - created: 2017-09-02T10:15:09Z
  17. dockerImageReference: 172.30.56.218:5000/test/origin-ruby-sample@sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d (3)
  18. generation: 2
  19. image: sha256:909de62d1f609a717ec433cc25ca5cf00941545c83a01fb31527771e1fab3fc5 (4)
  20. - created: 2017-09-01T13:40:11Z
  21. dockerImageReference: 172.30.56.218:5000/test/origin-ruby-sample@sha256:909de62d1f609a717ec433cc25ca5cf00941545c83a01fb31527771e1fab3fc5
  22. generation: 1
  23. image: sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d
  24. tag: latest (5)
1The name of the image stream.
2Docker repository path where new images can be pushed to add or update them in this image stream.
3The SHA identifier that this image stream tag currently references. Resources that reference this image stream tag use this identifier.
4The SHA identifier that this image stream tag previously referenced. Can be used to rollback to an older image.
5The image stream tag name.

Image stream images

An image stream image points from within an image stream to a particular image ID.

Image stream images allow you to retrieve metadata about an image from a particular image stream where it is tagged.

Image stream image objects are automatically created in OKD whenever you import or tag an image into the image stream. You should never have to explicitly define an image stream image object in any image stream definition that you use to create image streams.

The image stream image consists of the image stream name and image ID from the repository, delimited by an @ sign:

  1. <image-stream-name>@<image-id>

To refer to the image in the ImageStream object example, the image stream image looks like:

  1. origin-ruby-sample@sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d

Image stream tags

An image stream tag is a named pointer to an image in an image stream. It is abbreviated as istag. An image stream tag is used to reference or retrieve an image for a given image stream and tag.

Image stream tags can reference any local or externally managed image. It contains a history of images represented as a stack of all images the tag ever pointed to. Whenever a new or existing image is tagged under particular image stream tag, it is placed at the first position in the history stack. The image previously occupying the top position is available at the second position. This allows for easy rollbacks to make tags point to historical images again.

The following image stream tag is from an ImageStream object:

Image stream tag with two images in its history

  1. tags:
  2. - items:
  3. - created: 2017-09-02T10:15:09Z
  4. dockerImageReference: 172.30.56.218:5000/test/origin-ruby-sample@sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d
  5. generation: 2
  6. image: sha256:909de62d1f609a717ec433cc25ca5cf00941545c83a01fb31527771e1fab3fc5
  7. - created: 2017-09-01T13:40:11Z
  8. dockerImageReference: 172.30.56.218:5000/test/origin-ruby-sample@sha256:909de62d1f609a717ec433cc25ca5cf00941545c83a01fb31527771e1fab3fc5
  9. generation: 1
  10. image: sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d
  11. tag: latest

Image stream tags can be permanent tags or tracking tags.

  • Permanent tags are version-specific tags that point to a particular version of an image, such as Python 3.5.

  • Tracking tags are reference tags that follow another image stream tag and can be updated to change which image they follow, like a symlink. These new levels are not guaranteed to be backwards-compatible.

    For example, the latest image stream tags that ship with OKD are tracking tags. This means consumers of the latest image stream tag are updated to the newest level of the framework provided by the image when a new level becomes available. A latest image stream tag to v3.10 can be changed to v3.11 at any time. It is important to be aware that these latest image stream tags behave differently than the Docker latest tag. The latest image stream tag, in this case, does not point to the latest image in the Docker repository. It points to another image stream tag, which might not be the latest version of an image. For example, if the latest image stream tag points to v3.10 of an image, when the 3.11 version is released, the latest tag is not automatically updated to v3.11, and remains at v3.10 until it is manually updated to point to a v3.11 image stream tag.

    Tracking tags are limited to a single image stream and cannot reference other image streams.

You can create your own image stream tags for your own needs.

The image stream tag is composed of the name of the image stream and a tag, separated by a colon:

  1. <imagestream name>:<tag>

For example, to refer to the sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d image in the ImageStream object example earlier, the image stream tag would be:

  1. origin-ruby-sample:latest

Image stream change triggers

Image stream triggers allow your builds and deployments to be automatically invoked when a new version of an upstream image is available.

For example, builds and deployments can be automatically started when an image stream tag is modified. This is achieved by monitoring that particular image stream tag and notifying the build or deployment when a change is detected.

Image stream mapping

When the integrated registry receives a new image, it creates and sends an image stream mapping to OKD, providing the image’s project, name, tag, and image metadata.

Configuring image stream mappings is an advanced feature.

This information is used to create a new image, if it does not already exist, and to tag the image into the image stream. OKD stores complete metadata about each image, such as commands, entry point, and environment variables. Images in OKD are immutable and the maximum name length is 63 characters.

The following image stream mapping example results in an image being tagged as test/origin-ruby-sample:latest:

Image stream mapping object definition

  1. apiVersion: image.openshift.io/v1
  2. kind: ImageStreamMapping
  3. metadata:
  4. creationTimestamp: null
  5. name: origin-ruby-sample
  6. namespace: test
  7. tag: latest
  8. image:
  9. dockerImageLayers:
  10. - name: sha256:5f70bf18a086007016e948b04aed3b82103a36bea41755b6cddfaf10ace3c6ef
  11. size: 0
  12. - name: sha256:ee1dd2cb6df21971f4af6de0f1d7782b81fb63156801cfde2bb47b4247c23c29
  13. size: 196634330
  14. - name: sha256:5f70bf18a086007016e948b04aed3b82103a36bea41755b6cddfaf10ace3c6ef
  15. size: 0
  16. - name: sha256:5f70bf18a086007016e948b04aed3b82103a36bea41755b6cddfaf10ace3c6ef
  17. size: 0
  18. - name: sha256:ca062656bff07f18bff46be00f40cfbb069687ec124ac0aa038fd676cfaea092
  19. size: 177723024
  20. - name: sha256:63d529c59c92843c395befd065de516ee9ed4995549f8218eac6ff088bfa6b6e
  21. size: 55679776
  22. - name: sha256:92114219a04977b5563d7dff71ec4caa3a37a15b266ce42ee8f43dba9798c966
  23. size: 11939149
  24. dockerImageMetadata:
  25. Architecture: amd64
  26. Config:
  27. Cmd:
  28. - /usr/libexec/s2i/run
  29. Entrypoint:
  30. - container-entrypoint
  31. Env:
  32. - RACK_ENV=production
  33. - OPENSHIFT_BUILD_NAMESPACE=test
  34. - OPENSHIFT_BUILD_SOURCE=https://github.com/openshift/ruby-hello-world.git
  35. - EXAMPLE=sample-app
  36. - OPENSHIFT_BUILD_NAME=ruby-sample-build-1
  37. - PATH=/opt/app-root/src/bin:/opt/app-root/bin:/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin
  38. - STI_SCRIPTS_URL=image:///usr/libexec/s2i
  39. - STI_SCRIPTS_PATH=/usr/libexec/s2i
  40. - HOME=/opt/app-root/src
  41. - BASH_ENV=/opt/app-root/etc/scl_enable
  42. - ENV=/opt/app-root/etc/scl_enable
  43. - PROMPT_COMMAND=. /opt/app-root/etc/scl_enable
  44. - RUBY_VERSION=2.2
  45. ExposedPorts:
  46. 8080/tcp: {}
  47. Labels:
  48. build-date: 2015-12-23
  49. io.k8s.description: Platform for building and running Ruby 2.2 applications
  50. io.k8s.display-name: 172.30.56.218:5000/test/origin-ruby-sample:latest
  51. io.openshift.build.commit.author: Ben Parees <bparees@users.noreply.github.com>
  52. io.openshift.build.commit.date: Wed Jan 20 10:14:27 2016 -0500
  53. io.openshift.build.commit.id: 00cadc392d39d5ef9117cbc8a31db0889eedd442
  54. io.openshift.build.commit.message: 'Merge pull request #51 from php-coder/fix_url_and_sti'
  55. io.openshift.build.commit.ref: master
  56. io.openshift.build.image: centos/ruby-22-centos7@sha256:3a335d7d8a452970c5b4054ad7118ff134b3a6b50a2bb6d0c07c746e8986b28e
  57. io.openshift.build.source-location: https://github.com/openshift/ruby-hello-world.git
  58. io.openshift.builder-base-version: 8d95148
  59. io.openshift.builder-version: 8847438ba06307f86ac877465eadc835201241df
  60. io.openshift.s2i.scripts-url: image:///usr/libexec/s2i
  61. io.openshift.tags: builder,ruby,ruby22
  62. io.s2i.scripts-url: image:///usr/libexec/s2i
  63. license: GPLv2
  64. name: CentOS Base Image
  65. vendor: CentOS
  66. User: "1001"
  67. WorkingDir: /opt/app-root/src
  68. Container: 86e9a4a3c760271671ab913616c51c9f3cea846ca524bf07c04a6f6c9e103a76
  69. ContainerConfig:
  70. AttachStdout: true
  71. Cmd:
  72. - /bin/sh
  73. - -c
  74. - tar -C /tmp -xf - && /usr/libexec/s2i/assemble
  75. Entrypoint:
  76. - container-entrypoint
  77. Env:
  78. - RACK_ENV=production
  79. - OPENSHIFT_BUILD_NAME=ruby-sample-build-1
  80. - OPENSHIFT_BUILD_NAMESPACE=test
  81. - OPENSHIFT_BUILD_SOURCE=https://github.com/openshift/ruby-hello-world.git
  82. - EXAMPLE=sample-app
  83. - PATH=/opt/app-root/src/bin:/opt/app-root/bin:/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin
  84. - STI_SCRIPTS_URL=image:///usr/libexec/s2i
  85. - STI_SCRIPTS_PATH=/usr/libexec/s2i
  86. - HOME=/opt/app-root/src
  87. - BASH_ENV=/opt/app-root/etc/scl_enable
  88. - ENV=/opt/app-root/etc/scl_enable
  89. - PROMPT_COMMAND=. /opt/app-root/etc/scl_enable
  90. - RUBY_VERSION=2.2
  91. ExposedPorts:
  92. 8080/tcp: {}
  93. Hostname: ruby-sample-build-1-build
  94. Image: centos/ruby-22-centos7@sha256:3a335d7d8a452970c5b4054ad7118ff134b3a6b50a2bb6d0c07c746e8986b28e
  95. OpenStdin: true
  96. StdinOnce: true
  97. User: "1001"
  98. WorkingDir: /opt/app-root/src
  99. Created: 2016-01-29T13:40:00Z
  100. DockerVersion: 1.8.2.fc21
  101. Id: 9d7fd5e2d15495802028c569d544329f4286dcd1c9c085ff5699218dbaa69b43
  102. Parent: 57b08d979c86f4500dc8cad639c9518744c8dd39447c055a3517dc9c18d6fccd
  103. Size: 441976279
  104. apiVersion: "1.0"
  105. kind: DockerImage
  106. dockerImageMetadataVersion: "1.0"
  107. dockerImageReference: 172.30.56.218:5000/test/origin-ruby-sample@sha256:47463d94eb5c049b2d23b03a9530bf944f8f967a0fe79147dd6b9135bf7dd13d

Working with image streams

The following sections describe how to use image streams and image stream tags.

Do not run workloads in or share access to default projects. Default projects are reserved for running core cluster components.

The following default projects are considered highly privileged: default, kube-public, kube-system, openshift, openshift-infra, openshift-node, and other system-created projects that have the openshift.io/run-level label set to 0 or 1. Functionality that relies on admission plugins, such as pod security admission, security context constraints, cluster resource quotas, and image reference resolution, does not work in highly privileged projects.

Getting information about image streams

You can get general information about the image stream and detailed information about all the tags it is pointing to.

Procedure

  • To get general information about the image stream and detailed information about all the tags it is pointing to, enter the following command:

    1. $ oc describe is/<image-name>

    For example:

    1. $ oc describe is/python

    Example output

    1. Name: python
    2. Namespace: default
    3. Created: About a minute ago
    4. Labels: <none>
    5. Annotations: openshift.io/image.dockerRepositoryCheck=2017-10-02T17:05:11Z
    6. Docker Pull Spec: docker-registry.default.svc:5000/default/python
    7. Image Lookup: local=false
    8. Unique Images: 1
    9. Tags: 1
    10. 3.5
    11. tagged from centos/python-35-centos7
    12. * centos/python-35-centos7@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    13. About a minute ago
  • To get all of the information available about a particular image stream tag, enter the following command:

    1. $ oc describe istag/<image-stream>:<tag-name>

    For example:

    1. $ oc describe istag/python:latest

    Example output

    1. Image Name: sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    2. Docker Image: centos/python-35-centos7@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    3. Name: sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    4. Created: 2 minutes ago
    5. Image Size: 251.2 MB (first layer 2.898 MB, last binary layer 72.26 MB)
    6. Image Created: 2 weeks ago
    7. Author: <none>
    8. Arch: amd64
    9. Entrypoint: container-entrypoint
    10. Command: /bin/sh -c $STI_SCRIPTS_PATH/usage
    11. Working Dir: /opt/app-root/src
    12. User: 1001
    13. Exposes Ports: 8080/tcp
    14. Docker Labels: build-date=20170801

    More information is output than shown.

  • Enter the following command to discover which architecture or operating system that an image stream tag supports:

    1. $ oc get istag <image-stream-tag> -ojsonpath="{range .image.dockerImageManifests[*]}{.os}/{.architecture}{'\n'}{end}"

    For example:

    1. $ oc get istag busybox:latest -ojsonpath="{range .image.dockerImageManifests[*]}{.os}/{.architecture}{'\n'}{end}"

    Example output

    1. linux/amd64
    2. linux/arm
    3. linux/arm64
    4. linux/386
    5. linux/mips64le
    6. linux/ppc64le
    7. linux/riscv64
    8. linux/s390x

Adding tags to an image stream

You can add additional tags to image streams.

Procedure

  • Add a tag that points to one of the existing tags by using the `oc tag`command:

    1. $ oc tag <image-name:tag1> <image-name:tag2>

    For example:

    1. $ oc tag python:3.5 python:latest

    Example output

    1. Tag python:latest set to python@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25.
  • Confirm the image stream has two tags, one, 3.5, pointing at the external container image and another tag, latest, pointing to the same image because it was created based on the first tag.

    1. $ oc describe is/python

    Example output

    1. Name: python
    2. Namespace: default
    3. Created: 5 minutes ago
    4. Labels: <none>
    5. Annotations: openshift.io/image.dockerRepositoryCheck=2017-10-02T17:05:11Z
    6. Docker Pull Spec: docker-registry.default.svc:5000/default/python
    7. Image Lookup: local=false
    8. Unique Images: 1
    9. Tags: 2
    10. latest
    11. tagged from python@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    12. * centos/python-35-centos7@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    13. About a minute ago
    14. 3.5
    15. tagged from centos/python-35-centos7
    16. * centos/python-35-centos7@sha256:49c18358df82f4577386404991c51a9559f243e0b1bdc366df25
    17. 5 minutes ago

Adding tags for an external image

You can add tags for external images.

Procedure

  • Add tags pointing to internal or external images, by using the oc tag command for all tag-related operations:

    1. $ oc tag <repository/image> <image-name:tag>

    For example, this command maps the docker.io/python:3.6.0 image to the 3.6 tag in the python image stream.

    1. $ oc tag docker.io/python:3.6.0 python:3.6

    Example output

    1. Tag python:3.6 set to docker.io/python:3.6.0.

    If the external image is secured, you must create a secret with credentials for accessing that registry.

Updating image stream tags

You can update a tag to reflect another tag in an image stream.

Procedure

  • Update a tag:

    1. $ oc tag <image-name:tag> <image-name:latest>

    For example, the following updates the latest tag to reflect the 3.6 tag in an image stream:

    1. $ oc tag python:3.6 python:latest

    Example output

    1. Tag python:latest set to python@sha256:438208801c4806548460b27bd1fbcb7bb188273d13871ab43f.

Removing image stream tags

You can remove old tags from an image stream.

Procedure

  • Remove old tags from an image stream:

    1. $ oc tag -d <image-name:tag>

    For example:

    1. $ oc tag -d python:3.5

    Example output

    1. Deleted tag default/python:3.5.

See Removing deprecated image stream tags from the Cluster Samples Operator for more information on how the Cluster Samples Operator handles deprecated image stream tags.

Configuring periodic importing of image stream tags

When working with an external container image registry, to periodically re-import an image, for example to get latest security updates, you can use the --scheduled flag.

Procedure

  1. Schedule importing images:

    1. $ oc tag <repository/image> <image-name:tag> --scheduled

    For example:

    1. $ oc tag docker.io/python:3.6.0 python:3.6 --scheduled

    Example output

    1. Tag python:3.6 set to import docker.io/python:3.6.0 periodically.

    This command causes OKD to periodically update this particular image stream tag. This period is a cluster-wide setting set to 15 minutes by default.

  2. Remove the periodic check, re-run above command but omit the --scheduled flag. This will reset its behavior to default.

    1. $ oc tag <repositiory/image> <image-name:tag>

Importing and working with images and image streams

The following sections describe how to import, and work with, image streams.

Importing images and image streams from private registries

An image stream can be configured to import tag and image metadata from private image registries requiring authentication. This procedures applies if you change the registry that the Cluster Samples Operator uses to pull content from to something other than registry.redhat.io.

When importing from insecure or secure registries, the registry URL defined in the secret must include the :80 port suffix or the secret is not used when attempting to import from the registry.

Procedure

  1. You must create a secret object that is used to store your credentials by entering the following command:

    1. $ oc create secret generic <secret_name> --from-file=.dockerconfigjson=<file_absolute_path> --type=kubernetes.io/dockerconfigjson
  2. After the secret is configured, create the new image stream or enter the oc import-image command:

    1. $ oc import-image <imagestreamtag> --from=<image> --confirm

    During the import process, OKD picks up the secrets and provides them to the remote party.

Allowing pods to reference images from other secured registries

The .dockercfg $HOME/.docker/config.json file for Docker clients is a Docker credentials file that stores your authentication information if you have previously logged into a secured or insecure registry.

To pull a secured container image that is not from OpenShift image registry, you must create a pull secret from your Docker credentials and add it to your service account.

The Docker credentials file and the associated pull secret can contain multiple references to the same registry, each with its own set of credentials.

Example config.json file

  1. {
  2. "auths":{
  3. "cloud.openshift.com":{
  4. "auth":"b3Blb=",
  5. "email":"you@example.com"
  6. },
  7. "quay.io":{
  8. "auth":"b3Blb=",
  9. "email":"you@example.com"
  10. },
  11. "quay.io/repository-main":{
  12. "auth":"b3Blb=",
  13. "email":"you@example.com"
  14. }
  15. }
  16. }

Example pull secret

  1. apiVersion: v1
  2. data:
  3. .dockerconfigjson: ewogICAiYXV0aHMiOnsKICAgICAgIm0iOnsKICAgICAgIsKICAgICAgICAgImF1dGgiOiJiM0JsYj0iLAogICAgICAgICAiZW1haWwiOiJ5b3VAZXhhbXBsZS5jb20iCiAgICAgIH0KICAgfQp9Cg==
  4. kind: Secret
  5. metadata:
  6. creationTimestamp: "2021-09-09T19:10:11Z"
  7. name: pull-secret
  8. namespace: default
  9. resourceVersion: "37676"
  10. uid: e2851531-01bc-48ba-878c-de96cfe31020
  11. type: Opaque

Procedure

  • If you already have a .dockercfg file for the secured registry, you can create a secret from that file by running:

    1. $ oc create secret generic <pull_secret_name> \
    2. --from-file=.dockercfg=<path/to/.dockercfg> \
    3. --type=kubernetes.io/dockercfg
  • Or if you have a $HOME/.docker/config.json file:

    1. $ oc create secret generic <pull_secret_name> \
    2. --from-file=.dockerconfigjson=<path/to/.docker/config.json> \
    3. --type=kubernetes.io/dockerconfigjson
  • If you do not already have a Docker credentials file for the secured registry, you can create a secret by running:

    1. $ oc create secret docker-registry <pull_secret_name> \
    2. --docker-server=<registry_server> \
    3. --docker-username=<user_name> \
    4. --docker-password=<password> \
    5. --docker-email=<email>
  • To use a secret for pulling images for pods, you must add the secret to your service account. The name of the service account in this example should match the name of the service account the pod uses. The default service account is default:

    1. $ oc secrets link default <pull_secret_name> --for=pull

Working with manifest lists

You can import a single sub-manifest, or all manifests, of a manifest list when using oc import-image or oc tag CLI commands by adding the --import-mode flag.

Refer to the commands below to create an image stream that includes a single sub-manifest or multi-architecture images.

Procedure

  • Create an image stream that includes multi-architecture images, and sets the import mode to PreserveOriginal, by entering the following command:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name> \
    2. --import-mode='PreserveOriginal' --reference-policy=local --confirm

    Example output

    1. ---
    2. Arch: <none>
    3. Manifests: linux/amd64 sha256:6e325b86566fafd3c4683a05a219c30c421fbccbf8d87ab9d20d4ec1131c3451
    4. linux/arm64 sha256:d8fad562ffa75b96212c4a6dc81faf327d67714ed85475bf642729703a2b5bf6
    5. linux/ppc64le sha256:7b7e25338e40d8bdeb1b28e37fef5e64f0afd412530b257f5b02b30851f416e1
    6. ---
  • Alternatively, enter the following command to import an image with the Legacy import mode, which discards manifest lists and imports a single sub-manifest:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name> \
    2. --import-mode='Legacy' --confirm

    The —import-mode= default value is Legacy. Excluding this value, or failing to specify either Legacy or PreserveOriginal, imports a single sub-manifest. An invalid import mode returns the following error: error: valid ImportMode values are Legacy or PreserveOriginal.

Limitations

Working with manifest lists has the following limitations:

  • In some cases, users might want to use sub-manifests directly. When oc adm prune images is run, or the CronJob pruner runs, they cannot detect when a sub-manifest list is used. As a result, an administrator using oc adm prune images, or the CronJob pruner, might delete entire manifest lists, including sub-manifests.

    To avoid this limitation, you can use the manifest list by tag or by digest instead.

Configuring periodic importing of manifest lists

To periodically re-import a manifest list, you can use the --scheduled flag.

Procedure

  • Set the image stream to periodically update the manifest list by entering the following command:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name> \
    2. --import-mode='PreserveOriginal' --scheduled=true

Configuring SSL/TSL when importing manifest lists

To configure SSL/TSL when importing a manifest list, you can use the --insecure flag.

Procedure

  • Set --insecure=true so that importing a manifest list skips SSL/TSL verification. For example:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name> \
    2. --import-mode='PreserveOriginal' --insecure=true

Specifying architecture for —import-mode

You can swap your imported image stream between multi-architecture and single architecture by excluding or including the --import-mode= flag

Procedure

  • Run the following command to update your image stream from multi-architecture to single architecture by excluding the --import-mode= flag:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name>
  • Run the following command to update your image stream from single-architecture to multi-architecture:

    1. $ oc import-image <multiarch-image-stream-tag> --from=<registry>/<project_name>/<image-name> \
    2. --import-mode='PreserveOriginal'

Configuration fields for —import-mode

The following table describes the options available for the --import-mode= flag:

ParameterDescription

Legacy

The default option for —import-mode. When specified, the manifest list is discarded, and a single sub-manifest is imported. The platform is chosen in the following order of priority:

  1. Tag annotations

  2. Control plane architecture

  3. Linux/AMD64

  4. The first manifest in the list

PreserveOriginal

When specified, the original manifest is preserved. For manifest lists, the manifest list and all of its sub-manifests are imported.