Chapter 2. Preparing to update a cluster
2.1. Preparing to update to OpenShift Container Platform 4.14
Learn more about administrative tasks that cluster admins must perform to successfully initialize an update, as well as optional guidelines for ensuring a successful update.
2.1.1. RHEL 9.2 micro-architecture requirement change
OpenShift Container Platform is now based on the RHEL 9.2 host operating system. The micro-architecture requirements are now increased to x86_64-v2, Power9, and Z14. See the RHEL micro-architecture requirements documentation. You can verify compatibility before updating by following the procedures outlined in this KCS article.
Without the correct micro-architecture requirements, the update process will fail. Make sure you purchase the appropriate subscription for each architecture. For more information, see Get Started with Red Hat Enterprise Linux - additional architectures
2.1.2. Kubernetes API deprecations and removals
OpenShift Container Platform 4.14 uses Kubernetes 1.27, which removed several deprecated APIs.
A cluster administrator must provide a manual acknowledgment before the cluster can be updated from OpenShift Container Platform 4.13 to 4.14. This is to help prevent issues after upgrading to OpenShift Container Platform 4.14, where APIs that have been removed are still in use by workloads, tools, or other components running on or interacting with the cluster. Administrators must evaluate their cluster for any APIs in use that will be removed and migrate the affected components to use the appropriate new API version. After this evaluation and migration is complete, the administrator can provide the acknowledgment.
Before you can update your OpenShift Container Platform 4.13 cluster to 4.14, you must provide the administrator acknowledgment.
2.1.2.1. Removed Kubernetes APIs
OpenShift Container Platform 4.14 uses Kubernetes 1.27, which removed the following deprecated APIs. You must migrate manifests and API clients to use the appropriate API version. For more information about migrating removed APIs, see the Kubernetes documentation.
Resource | Removed API | Migrate to |
---|---|---|
|
|
|
2.1.2.2. Evaluating your cluster for removed APIs
There are several methods to help administrators identify where APIs that will be removed are in use. However, OpenShift Container Platform cannot identify all instances, especially workloads that are idle or external tools that are used. It is the responsibility of the administrator to properly evaluate all workloads and other integrations for instances of removed APIs.
2.1.2.2.1. Reviewing alerts to identify uses of removed APIs
Two alerts fire when an API is in use that will be removed in the next release:
-
APIRemovedInNextReleaseInUse
- for APIs that will be removed in the next OpenShift Container Platform release. -
APIRemovedInNextEUSReleaseInUse
- for APIs that will be removed in the next OpenShift Container Platform Extended Update Support (EUS) release.
If either of these alerts are firing in your cluster, review the alerts and take action to clear the alerts by migrating manifests and API clients to use the new API version.
Use the APIRequestCount
API to get more information about which APIs are in use and which workloads are using removed APIs, because the alerts do not provide this information. Additionally, some APIs might not trigger these alerts but are still captured by APIRequestCount
. The alerts are tuned to be less sensitive to avoid alerting fatigue in production systems.
2.1.2.2.2. Using APIRequestCount to identify uses of removed APIs
You can use the APIRequestCount
API to track API requests and review whether any of them are using one of the removed APIs.
Prerequisites
-
You must have access to the cluster as a user with the
cluster-admin
role.
Procedure
Run the following command and examine the
REMOVEDINRELEASE
column of the output to identify the removed APIs that are currently in use:$ oc get apirequestcounts
Example output
NAME REMOVEDINRELEASE REQUESTSINCURRENTHOUR REQUESTSINLAST24H ... csistoragecapacities.v1.storage.k8s.io 14 380 csistoragecapacities.v1beta1.storage.k8s.io 1.27 0 16 custompolicydefinitions.v1beta1.capabilities.3scale.net 8 158 customresourcedefinitions.v1.apiextensions.k8s.io 1407 30148 ...
ImportantYou can safely ignore the following entries that appear in the results:
-
The
system:serviceaccount:kube-system:generic-garbage-collector
and thesystem:serviceaccount:kube-system:namespace-controller
users might appear in the results because these services invoke all registered APIs when searching for resources to remove. -
The
system:kube-controller-manager
andsystem:cluster-policy-controller
users might appear in the results because they walk through all resources while enforcing various policies.
You can also use
-o jsonpath
to filter the results:$ oc get apirequestcounts -o jsonpath='{range .items[?(@.status.removedInRelease!="")]}{.status.removedInRelease}{"\t"}{.metadata.name}{"\n"}{end}'
Example output
1.27 csistoragecapacities.v1beta1.storage.k8s.io 1.29 flowschemas.v1beta2.flowcontrol.apiserver.k8s.io 1.29 prioritylevelconfigurations.v1beta2.flowcontrol.apiserver.k8s.io
-
The
2.1.2.2.3. Using APIRequestCount to identify which workloads are using the removed APIs
You can examine the APIRequestCount
resource for a given API version to help identify which workloads are using the API.
Prerequisites
-
You must have access to the cluster as a user with the
cluster-admin
role.
Procedure
Run the following command and examine the
username
anduserAgent
fields to help identify the workloads that are using the API:$ oc get apirequestcounts <resource>.<version>.<group> -o yaml
For example:
$ oc get apirequestcounts csistoragecapacities.v1beta1.storage.k8s.io -o yaml
You can also use
-o jsonpath
to extract theusername
anduserAgent
values from anAPIRequestCount
resource:$ oc get apirequestcounts csistoragecapacities.v1beta1.storage.k8s.io \ -o jsonpath='{range .status.currentHour..byUser[*]}{..byVerb[*].verb}{","}{.username}{","}{.userAgent}{"\n"}{end}' \ | sort -k 2 -t, -u | column -t -s, -NVERBS,USERNAME,USERAGENT
Example output
VERBS USERNAME USERAGENT list watch system:kube-controller-manager cluster-policy-controller/v0.0.0 list watch system:kube-controller-manager kube-controller-manager/v1.26.5+0abcdef list watch system:kube-scheduler kube-scheduler/v1.26.5+0abcdef
2.1.2.3. Migrating instances of removed APIs
For information about how to migrate removed Kubernetes APIs, see the Deprecated API Migration Guide in the Kubernetes documentation.
2.1.2.4. Providing the administrator acknowledgment
After you have evaluated your cluster for any removed APIs and have migrated any removed APIs, you can acknowledge that your cluster is ready to upgrade from OpenShift Container Platform 4.13 to 4.14.
Be aware that all responsibility falls on the administrator to ensure that all uses of removed APIs have been resolved and migrated as necessary before providing this administrator acknowledgment. OpenShift Container Platform can assist with the evaluation, but cannot identify all possible uses of removed APIs, especially idle workloads or external tools.
Prerequisites
-
You must have access to the cluster as a user with the
cluster-admin
role.
Procedure
Run the following command to acknowledge that you have completed the evaluation and your cluster is ready for the Kubernetes API removals in OpenShift Container Platform 4.14:
$ oc -n openshift-config patch cm admin-acks --patch '{"data":{"ack-4.13-kube-1.27-api-removals-in-4.14":"true"}}' --type=merge
2.1.3. Assessing the risk of conditional updates
A conditional update is an update target that is available but not recommended due to a known risk that applies to your cluster. The Cluster Version Operator (CVO) periodically queries the OpenShift Update Service (OSUS) for the most recent data about update recommendations, and some potential update targets might have risks associated with them.
The CVO evaluates the conditional risks, and if the risks are not applicable to the cluster, then the target version is available as a recommended update path for the cluster. If the risk is determined to be applicable, or if for some reason CVO cannot evaluate the risk, then the update target is available to the cluster as a conditional update.
When you encounter a conditional update while you are trying to update to a target version, you must assess the risk of updating your cluster to that version. Generally, if you do not have a specific need to update to that target version, it is best to wait for a recommended update path from Red Hat.
However, if you have a strong reason to update to that version, for example, if you need to fix an important CVE, then the benefit of fixing the CVE might outweigh the risk of the update being problematic for your cluster. You can complete the following tasks to determine whether you agree with the Red Hat assessment of the update risk:
- Complete extensive testing in a non-production environment to the extent that you are comfortable completing the update in your production environment.
- Follow the links provided in the conditional update description, investigate the bug, and determine if it is likely to cause issues for your cluster. If you need help understanding the risk, contact Red Hat Support.
Additional resources
2.1.4. etcd backups before cluster updates
etcd backups record the state of your cluster and all of its resource objects. You can use backups to attempt restoring the state of a cluster in disaster scenarios where you cannot recover a cluster in its currently dysfunctional state.
In the context of updates, you can attempt an etcd restoration of the cluster if an update introduced catastrophic conditions that cannot be fixed without reverting to the previous cluster version. etcd restorations might be destructive and destabilizing to a running cluster, use them only as a last resort.
Due to their high consequences, etcd restorations are not intended to be used as a rollback solution. Rolling your cluster back to a previous version is not supported. If your update is failing to complete, contact Red Hat support.
There are several factors that affect the viability of an etcd restoration. For more information, see "Backing up etcd data" and "Restoring to a previous cluster state".
Additional resources
2.1.5. Best practices for cluster updates
OpenShift Container Platform provides a robust update experience that minimizes workload disruptions during an update. Updates will not begin unless the cluster is in an upgradeable state at the time of the update request.
This design enforces some key conditions before initiating an update, but there are a number of actions you can take to increase your chances of a successful cluster update.
2.1.5.1. Choose versions recommended by the OpenShift Update Service
The OpenShift Update Service (OSUS) provides update recommendations based on cluster characteristics such as the cluster’s subscribed channel. The Cluster Version Operator saves these recommendations as either recommended or conditional updates. While it is possible to attempt an update to a version that is not recommended by OSUS, following a recommended update path protects users from encountering known issues or unintended consequences on the cluster.
Choose only update targets that are recommended by OSUS to ensure a successful update.
2.1.5.2. Address all critical alerts on the cluster
Critical alerts must always be addressed as soon as possible, but it is especially important to address these alerts and resolve any problems before initiating a cluster update. Failing to address critical alerts before beginning an update can cause problematic conditions for the cluster.
In the Administrator perspective of the web console, navigate to Observe
2.1.5.2.1. Ensure that duplicated encoding headers are removed
Before updating, you will receive a DuplicateTransferEncodingHeadersDetected
alert if any route records a duplicate Transfer-Encoding
header issue. This is due to the upgrade from HAProxy 2.2 in previous OpenShift Container Platform releases to HAProxy 2.6 in OpenShift Container Platform 4.14. Failing to address this alert will result in applications that send multiple Transfer-Encoding
headers becoming unreachable through routes.
To mitigate this issue, update any problematic applications to no longer send multiple Transfer-Encoding
headers. For example, this could require removing duplicated headers in your application configuration file.
For more information, see this Red Hat Knowledgebase article.
2.1.5.3. Ensure that the cluster is in an Upgradable state
When one or more Operators have not reported their Upgradeable
condition as True
for more than an hour, the ClusterNotUpgradeable
warning alert is triggered in the cluster. In most cases this alert does not block patch updates, but you cannot perform a minor version update until you resolve this alert and all Operators report Upgradeable
as True
.
For more information about the Upgradeable
condition, see "Understanding cluster Operator condition types" in the additional resources section.
2.1.5.4. Ensure that enough spare nodes are available
A cluster should not be running with little to no spare node capacity, especially when initiating a cluster update. Nodes that are not running and available may limit a cluster’s ability to perform an update with minimal disruption to cluster workloads.
Depending on the configured value of the cluster’s maxUnavailable
spec, the cluster might not be able to apply machine configuration changes to nodes if there is an unavailable node. Additionally, if compute nodes do not have enough spare capacity, workloads might not be able to temporarily shift to another node while the first node is taken offline for an update.
Make sure that you have enough available nodes in each worker pool, as well as enough spare capacity on your compute nodes, to increase the chance of successful node updates.
The default setting for maxUnavailable
is 1
for all the machine config pools in OpenShift Container Platform. It is recommended to not change this value and update one control plane node at a time. Do not change this value to 3
for the control plane pool.
2.1.5.5. Ensure that the cluster’s PodDisruptionBudget is properly configured
You can use the PodDisruptionBudget
object to define the minimum number or percentage of pod replicas that must be available at any given time. This configuration protects workloads from disruptions during maintenance tasks such as cluster updates.
However, it is possible to configure the PodDisruptionBudget
for a given topology in a way that prevents nodes from being drained and updated during a cluster update.
When planning a cluster update, check the configuration of the PodDisruptionBudget
object for the following factors:
-
For highly available workloads, make sure there are replicas that can be temporarily taken offline without being prohibited by the
PodDisruptionBudget
. -
For workloads that aren’t highly available, make sure they are either not protected by a
PodDisruptionBudget
or have some alternative mechanism for draining these workloads eventually, such as periodic restart or guaranteed eventual termination.
Additional resources
2.2. Preparing to update a cluster with manually maintained credentials
The Cloud Credential Operator (CCO) Upgradable
status for a cluster with manually maintained credentials is False
by default.
-
For minor releases, for example, from 4.12 to 4.13, this status prevents you from updating until you have addressed any updated permissions and annotated the
CloudCredential
resource to indicate that the permissions are updated as needed for the next version. This annotation changes theUpgradable
status toTrue
. - For z-stream releases, for example, from 4.13.0 to 4.13.1, no permissions are added or changed, so the update is not blocked.
Before updating a cluster with manually maintained credentials, you must accommodate any new or changed credentials in the release image for the version of OpenShift Container Platform you are updating to.
2.2.1. Update requirements for clusters with manually maintained credentials
Before you update a cluster that uses manually maintained credentials with the Cloud Credential Operator (CCO), you must update the cloud provider resources for the new release.
If the cloud credential management for your cluster was configured using the CCO utility (ccoctl
), use the ccoctl
utility to update the resources. Clusters that were configured to use manual mode without the ccoctl
utility require manual updates for the resources.
After updating the cloud provider resources, you must update the upgradeable-to
annotation for the cluster to indicate that it is ready to update.
The process to update the cloud provider resources and the upgradeable-to
annotation can only be completed by using command line tools.
2.2.1.1. Cloud credential configuration options and update requirements by platform type
Some platforms only support using the CCO in one mode. For clusters that are installed on those platforms, the platform type determines the credentials update requirements.
For platforms that support using the CCO in multiple modes, you must determine which mode the cluster is configured to use and take the required actions for that configuration.
Figure 2.1. Credentials update requirements by platform type
- Red Hat OpenStack Platform (RHOSP) and VMware vSphere
These platforms do not support using the CCO in manual mode. Clusters on these platforms handle changes in cloud provider resources automatically and do not require an update to the
upgradeable-to
annotation.Administrators of clusters on these platforms should skip the manually maintained credentials section of the update process.
- IBM Cloud and Nutanix
Clusters installed on these platforms are configured using the
ccoctl
utility.Administrators of clusters on these platforms must take the following actions:
-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. -
Configure the
ccoctl
utility for the new release and use it to update the cloud provider resources. -
Indicate that the cluster is ready to update with the
upgradeable-to
annotation.
-
Extract and prepare the
- Microsoft Azure Stack Hub
These clusters use manual mode with long-term credentials and do not use the
ccoctl
utility.Administrators of clusters on these platforms must take the following actions:
-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. - Manually update the cloud provider resources for the new release.
-
Indicate that the cluster is ready to update with the
upgradeable-to
annotation.
-
Extract and prepare the
- Amazon Web Services (AWS), global Microsoft Azure, and Google Cloud Platform (GCP)
Clusters installed on these platforms support multiple CCO modes.
The required update process depends on the mode that the cluster is configured to use. If you are not sure what mode the CCO is configured to use on your cluster, you can use the web console or the CLI to determine this information.
2.2.1.2. Determining the Cloud Credential Operator mode by using the web console
You can determine what mode the Cloud Credential Operator (CCO) is configured to use by using the web console.
Only Amazon Web Services (AWS), global Microsoft Azure, and Google Cloud Platform (GCP) clusters support multiple CCO modes.
Prerequisites
- You have access to an OpenShift Container Platform account with cluster administrator permissions.
Procedure
-
Log in to the OpenShift Container Platform web console as a user with the
cluster-admin
role. -
Navigate to Administration
Cluster Settings. - On the Cluster Settings page, select the Configuration tab.
- Under Configuration resource, select CloudCredential.
- On the CloudCredential details page, select the YAML tab.
In the YAML block, check the value of
spec.credentialsMode
. The following values are possible, though not all are supported on all platforms:-
''
: The CCO is operating in the default mode. In this configuration, the CCO operates in mint or passthrough mode, depending on the credentials provided during installation. -
Mint
: The CCO is operating in mint mode. -
Passthrough
: The CCO is operating in passthrough mode. -
Manual
: The CCO is operating in manual mode.
ImportantTo determine the specific configuration of an AWS, GCP, or global Microsoft Azure cluster that has a
spec.credentialsMode
of''
,Mint
, orManual
, you must investigate further.AWS and GCP clusters support using mint mode with the root secret deleted. If the cluster is specifically configured to use mint mode or uses mint mode by default, you must determine if the root secret is present on the cluster before updating.
An AWS, GCP, or global Microsoft Azure cluster that uses manual mode might be configured to create and manage cloud credentials from outside of the cluster with AWS STS, GCP Workload Identity, or Microsoft Entra Workload ID. You can determine whether your cluster uses this strategy by examining the cluster
Authentication
object.-
AWS or GCP clusters that use mint mode only: To determine whether the cluster is operating without the root secret, navigate to Workloads
Secrets and look for the root secret for your cloud provider. NoteEnsure that the Project dropdown is set to All Projects.
Platform Secret name AWS
aws-creds
GCP
gcp-credentials
- If you see one of these values, your cluster is using mint or passthrough mode with the root secret present.
- If you do not see these values, your cluster is using the CCO in mint mode with the root secret removed.
AWS, GCP, or global Microsoft Azure clusters that use manual mode only: To determine whether the cluster is configured to create and manage cloud credentials from outside of the cluster, you must check the cluster
Authentication
object YAML values.-
Navigate to Administration
Cluster Settings. - On the Cluster Settings page, select the Configuration tab.
- Under Configuration resource, select Authentication.
- On the Authentication details page, select the YAML tab.
In the YAML block, check the value of the
.spec.serviceAccountIssuer
parameter.-
A value that contains a URL that is associated with your cloud provider indicates that the CCO is using manual mode with short-term credentials for components. These clusters are configured using the
ccoctl
utility to create and manage cloud credentials from outside of the cluster. -
An empty value (
''
) indicates that the cluster is using the CCO in manual mode but was not configured using theccoctl
utility.
-
A value that contains a URL that is associated with your cloud provider indicates that the CCO is using manual mode with short-term credentials for components. These clusters are configured using the
-
Navigate to Administration
Next steps
- If you are updating a cluster that has the CCO operating in mint or passthrough mode and the root secret is present, you do not need to update any cloud provider resources and can continue to the next part of the update process.
- If your cluster is using the CCO in mint mode with the root secret removed, you must reinstate the credential secret with the administrator-level credential before continuing to the next part of the update process.
If your cluster was configured using the CCO utility (
ccoctl
), you must take the following actions:-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. -
Configure the
ccoctl
utility for the new release and use it to update the cloud provider resources. -
Update the
upgradeable-to
annotation to indicate that the cluster is ready to update.
-
Extract and prepare the
If your cluster is using the CCO in manual mode but was not configured using the
ccoctl
utility, you must take the following actions:-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. - Manually update the cloud provider resources for the new release.
-
Update the
upgradeable-to
annotation to indicate that the cluster is ready to update.
-
Extract and prepare the
Additional resources
2.2.1.3. Determining the Cloud Credential Operator mode by using the CLI
You can determine what mode the Cloud Credential Operator (CCO) is configured to use by using the CLI.
Only Amazon Web Services (AWS), global Microsoft Azure, and Google Cloud Platform (GCP) clusters support multiple CCO modes.
Prerequisites
- You have access to an OpenShift Container Platform account with cluster administrator permissions.
-
You have installed the OpenShift CLI (
oc
).
Procedure
-
Log in to
oc
on the cluster as a user with thecluster-admin
role. To determine the mode that the CCO is configured to use, enter the following command:
$ oc get cloudcredentials cluster \ -o=jsonpath={.spec.credentialsMode}
The following output values are possible, though not all are supported on all platforms:
-
''
: The CCO is operating in the default mode. In this configuration, the CCO operates in mint or passthrough mode, depending on the credentials provided during installation. -
Mint
: The CCO is operating in mint mode. -
Passthrough
: The CCO is operating in passthrough mode. -
Manual
: The CCO is operating in manual mode.
ImportantTo determine the specific configuration of an AWS, GCP, or global Microsoft Azure cluster that has a
spec.credentialsMode
of''
,Mint
, orManual
, you must investigate further.AWS and GCP clusters support using mint mode with the root secret deleted. If the cluster is specifically configured to use mint mode or uses mint mode by default, you must determine if the root secret is present on the cluster before updating.
An AWS, GCP, or global Microsoft Azure cluster that uses manual mode might be configured to create and manage cloud credentials from outside of the cluster with AWS STS, GCP Workload Identity, or Microsoft Entra Workload ID. You can determine whether your cluster uses this strategy by examining the cluster
Authentication
object.-
AWS or GCP clusters that use mint mode only: To determine whether the cluster is operating without the root secret, run the following command:
$ oc get secret <secret_name> \ -n=kube-system
where
<secret_name>
isaws-creds
for AWS orgcp-credentials
for GCP.If the root secret is present, the output of this command returns information about the secret. An error indicates that the root secret is not present on the cluster.
AWS, GCP, or global Microsoft Azure clusters that use manual mode only: To determine whether the cluster is configured to create and manage cloud credentials from outside of the cluster, run the following command:
$ oc get authentication cluster \ -o jsonpath \ --template='{ .spec.serviceAccountIssuer }'
This command displays the value of the
.spec.serviceAccountIssuer
parameter in the clusterAuthentication
object.-
An output of a URL that is associated with your cloud provider indicates that the CCO is using manual mode with short-term credentials for components. These clusters are configured using the
ccoctl
utility to create and manage cloud credentials from outside of the cluster. -
An empty output indicates that the cluster is using the CCO in manual mode but was not configured using the
ccoctl
utility.
-
An output of a URL that is associated with your cloud provider indicates that the CCO is using manual mode with short-term credentials for components. These clusters are configured using the
Next steps
- If you are updating a cluster that has the CCO operating in mint or passthrough mode and the root secret is present, you do not need to update any cloud provider resources and can continue to the next part of the update process.
- If your cluster is using the CCO in mint mode with the root secret removed, you must reinstate the credential secret with the administrator-level credential before continuing to the next part of the update process.
If your cluster was configured using the CCO utility (
ccoctl
), you must take the following actions:-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. -
Configure the
ccoctl
utility for the new release and use it to update the cloud provider resources. -
Update the
upgradeable-to
annotation to indicate that the cluster is ready to update.
-
Extract and prepare the
If your cluster is using the CCO in manual mode but was not configured using the
ccoctl
utility, you must take the following actions:-
Extract and prepare the
CredentialsRequest
custom resources (CRs) for the new release. - Manually update the cloud provider resources for the new release.
-
Update the
upgradeable-to
annotation to indicate that the cluster is ready to update.
-
Extract and prepare the
Additional resources
2.2.2. Extracting and preparing credentials request resources
Before updating a cluster that uses the Cloud Credential Operator (CCO) in manual mode, you must extract and prepare the CredentialsRequest
custom resources (CRs) for the new release.
Prerequisites
-
Install the OpenShift CLI (
oc
) that matches the version for your updated version. -
Log in to the cluster as user with
cluster-admin
privileges.
Procedure
Obtain the pull spec for the update that you want to apply by running the following command:
$ oc adm upgrade
The output of this command includes pull specs for the available updates similar to the following:
Partial example output
... Recommended updates: VERSION IMAGE 4.14.0 quay.io/openshift-release-dev/ocp-release@sha256:6a899c54dda6b844bb12a247e324a0f6cde367e880b73ba110c056df6d018032 ...
Set a
$RELEASE_IMAGE
variable with the release image that you want to use by running the following command:$ RELEASE_IMAGE=<update_pull_spec>
where
<update_pull_spec>
is the pull spec for the release image that you want to use. For example:quay.io/openshift-release-dev/ocp-release@sha256:6a899c54dda6b844bb12a247e324a0f6cde367e880b73ba110c056df6d018032
Extract the list of
CredentialsRequest
custom resources (CRs) from the OpenShift Container Platform release image by running the following command:$ oc adm release extract \ --from=$RELEASE_IMAGE \ --credentials-requests \ --included \1 --to=<path_to_directory_for_credentials_requests> 2
This command creates a YAML file for each
CredentialsRequest
object.For each
CredentialsRequest
CR in the release image, ensure that a namespace that matches the text in thespec.secretRef.namespace
field exists in the cluster. This field is where the generated secrets that hold the credentials configuration are stored.Sample AWS
CredentialsRequest
objectapiVersion: cloudcredential.openshift.io/v1 kind: CredentialsRequest metadata: name: cloud-credential-operator-iam-ro namespace: openshift-cloud-credential-operator spec: providerSpec: apiVersion: cloudcredential.openshift.io/v1 kind: AWSProviderSpec statementEntries: - effect: Allow action: - iam:GetUser - iam:GetUserPolicy - iam:ListAccessKeys resource: "*" secretRef: name: cloud-credential-operator-iam-ro-creds namespace: openshift-cloud-credential-operator 1
- 1
- This field indicates the namespace which must exist to hold the generated secret.
The
CredentialsRequest
CRs for other platforms have a similar format with different platform-specific values.For any
CredentialsRequest
CR for which the cluster does not already have a namespace with the name specified inspec.secretRef.namespace
, create the namespace by running the following command:$ oc create namespace <component_namespace>
Next steps
-
If the cloud credential management for your cluster was configured using the CCO utility (
ccoctl
), configure theccoctl
utility for a cluster update and use it to update your cloud provider resources. -
If your cluster was not configured with the
ccoctl
utility, manually update your cloud provider resources.
2.2.3. Configuring the Cloud Credential Operator utility for a cluster update
To upgrade a cluster that uses the Cloud Credential Operator (CCO) in manual mode to create and manage cloud credentials from outside of the cluster, extract and prepare the CCO utility (ccoctl
) binary.
The ccoctl
utility is a Linux binary that must run in a Linux environment.
Prerequisites
- You have access to an OpenShift Container Platform account with cluster administrator access.
-
You have installed the OpenShift CLI (
oc
).
-
Your cluster was configured using the
ccoctl
utility to create and manage cloud credentials from outside of the cluster. -
You have extracted the
CredentialsRequest
custom resources (CRs) from the OpenShift Container Platform release image and ensured that a namespace that matches the text in thespec.secretRef.namespace
field exists in the cluster.
Procedure
Set a variable for the OpenShift Container Platform release image by running the following command:
$ RELEASE_IMAGE=$(oc get clusterversion -o jsonpath={..desired.image})
Obtain the CCO container image from the OpenShift Container Platform release image by running the following command:
$ CCO_IMAGE=$(oc adm release info --image-for='cloud-credential-operator' $RELEASE_IMAGE -a ~/.pull-secret)
NoteEnsure that the architecture of the
$RELEASE_IMAGE
matches the architecture of the environment in which you will use theccoctl
tool.Extract the
ccoctl
binary from the CCO container image within the OpenShift Container Platform release image by running the following command:$ oc image extract $CCO_IMAGE --file="/usr/bin/ccoctl" -a ~/.pull-secret
Change the permissions to make
ccoctl
executable by running the following command:$ chmod 775 ccoctl
Verification
To verify that
ccoctl
is ready to use, display the help file. Use a relative file name when you run the command, for example:$ ./ccoctl.rhel9
Example output
OpenShift credentials provisioning tool Usage: ccoctl [command] Available Commands: alibabacloud Manage credentials objects for alibaba cloud aws Manage credentials objects for AWS cloud azure Manage credentials objects for Azure gcp Manage credentials objects for Google cloud help Help about any command ibmcloud Manage credentials objects for IBM Cloud nutanix Manage credentials objects for Nutanix Flags: -h, --help help for ccoctl Use "ccoctl [command] --help" for more information about a command.
2.2.4. Updating cloud provider resources with the Cloud Credential Operator utility
The process for upgrading an OpenShift Container Platform cluster that was configured using the CCO utility (ccoctl
) is similar to creating the cloud provider resources during installation.
On AWS clusters, some ccoctl
commands make AWS API calls to create or modify AWS resources. You can use the --dry-run
flag to avoid making API calls. Using this flag creates JSON files on the local file system instead. You can review and modify the JSON files and then apply them with the AWS CLI tool using the --cli-input-json
parameters.
Prerequisites
-
You have extracted the
CredentialsRequest
custom resources (CRs) from the OpenShift Container Platform release image and ensured that a namespace that matches the text in thespec.secretRef.namespace
field exists in the cluster. -
You have extracted and configured the
ccoctl
binary from the release image.
Procedure
Use the
ccoctl
tool to process allCredentialsRequest
objects by running the command for your cloud provider. The following commands processCredentialsRequest
objects:Example 2.1. Amazon Web Services (AWS)
$ ccoctl aws create-all \1 --name=<name> \2 --region=<aws_region> \3 --credentials-requests-dir=<path_to_credentials_requests_directory> \4 --output-dir=<path_to_ccoctl_output_dir> \5 --create-private-s3-bucket 6
- 1
- To create the AWS resources individually, use the "Creating AWS resources individually" procedure in the "Installing a cluster on AWS with customizations" content. This option might be useful if you need to review the JSON files that the
ccoctl
tool creates before modifying AWS resources, or if the process theccoctl
tool uses to create AWS resources automatically does not meet the requirements of your organization. - 2
- Specify the name used to tag any cloud resources that are created for tracking.
- 3
- Specify the AWS region in which cloud resources will be created.
- 4
- Specify the directory containing the files for the component
CredentialsRequest
objects. - 5
- Optional: Specify the directory in which you want the
ccoctl
utility to create objects. By default, the utility creates objects in the directory in which the commands are run. - 6
- Optional: By default, the
ccoctl
utility stores the OpenID Connect (OIDC) configuration files in a public S3 bucket and uses the S3 URL as the public OIDC endpoint. To store the OIDC configuration in a private S3 bucket that is accessed by the IAM identity provider through a public CloudFront distribution URL instead, use the--create-private-s3-bucket
parameter.
Example 2.2. Google Cloud Platform (GCP)
$ ccoctl gcp create-all \ --name=<name> \1 --region=<gcp_region> \2 --project=<gcp_project_id> \3 --credentials-requests-dir=<path_to_credentials_requests_directory> \4 --output-dir=<path_to_ccoctl_output_dir> 5
- 1
- Specify the user-defined name for all created GCP resources used for tracking.
- 2
- Specify the GCP region in which cloud resources will be created.
- 3
- Specify the GCP project ID in which cloud resources will be created.
- 4
- Specify the directory containing the files of
CredentialsRequest
manifests to create GCP service accounts. - 5
- Optional: Specify the directory in which you want the
ccoctl
utility to create objects. By default, the utility creates objects in the directory in which the commands are run.
Example 2.3. IBM Cloud
$ ccoctl ibmcloud create-service-id \ --credentials-requests-dir=<path_to_credential_requests_directory> \1 --name=<cluster_name> \2 --output-dir=<installation_directory> \3 --resource-group-name=<resource_group_name> 4
- 1
- Specify the directory containing the files for the component
CredentialsRequest
objects. - 2
- Specify the name of the OpenShift Container Platform cluster.
- 3
- Optional: Specify the directory in which you want the
ccoctl
utility to create objects. By default, the utility creates objects in the directory in which the commands are run. - 4
- Optional: Specify the name of the resource group used for scoping the access policies.
Example 2.4. Microsoft Azure
$ ccoctl azure create-managed-identities \ --name <azure_infra_name> \1 --output-dir ./output_dir \ --region <azure_region> \2 --subscription-id <azure_subscription_id> \3 --credentials-requests-dir <path_to_directory_for_credentials_requests> \ --issuer-url "${OIDC_ISSUER_URL}" \4 --dnszone-resource-group-name <azure_dns_zone_resourcegroup_name> \5 --installation-resource-group-name "${AZURE_INSTALL_RG}" 6
- 1
- The value of the
name
parameter is used to create an Azure resource group. To use an existing Azure resource group instead of creating a new one, specify the--oidc-resource-group-name
argument with the existing group name as its value. - 2
- Specify the region of the existing cluster.
- 3
- Specify the subscription ID of the existing cluster.
- 4
- Specify the OIDC issuer URL from the existing cluster. You can obtain this value by running the following command:
$ oc get authentication cluster \ -o jsonpath \ --template='{ .spec.serviceAccountIssuer }'
- 5
- Specify the name of the resource group that contains the DNS zone.
- 6
- Specify the Azure resource group name. You can obtain this value by running the following command:
$ oc get infrastructure cluster \ -o jsonpath \ --template '{ .status.platformStatus.azure.resourceGroupName }'
Example 2.5. Nutanix
$ ccoctl nutanix create-shared-secrets \ --credentials-requests-dir=<path_to_credentials_requests_directory> \1 --output-dir=<ccoctl_output_dir> \2 --credentials-source-filepath=<path_to_credentials_file> 3
- 1
- Specify the path to the directory that contains the files for the component
CredentialsRequests
objects. - 2
- Optional: Specify the directory in which you want the
ccoctl
utility to create objects. By default, the utility creates objects in the directory in which the commands are run. - 3
- Optional: Specify the directory that contains the credentials data YAML file. By default,
ccoctl
expects this file to be in<home_directory>/.nutanix/credentials
.
For each
CredentialsRequest
object,ccoctl
creates the required provider resources and a permissions policy as defined in eachCredentialsRequest
object from the OpenShift Container Platform release image.Apply the secrets to your cluster by running the following command:
$ ls <path_to_ccoctl_output_dir>/manifests/*-credentials.yaml | xargs -I{} oc apply -f {}
Verification
You can verify that the required provider resources and permissions policies are created by querying the cloud provider. For more information, refer to your cloud provider documentation on listing roles or service accounts.
Next steps
-
Update the
upgradeable-to
annotation to indicate that the cluster is ready to upgrade.
Additional resources
2.2.5. Manually updating cloud provider resources
Before upgrading a cluster with manually maintained credentials, you must create secrets for any new credentials for the release image that you are upgrading to. You must also review the required permissions for existing credentials and accommodate any new permissions requirements in the new release for those components.
Prerequisites
-
You have extracted the
CredentialsRequest
custom resources (CRs) from the OpenShift Container Platform release image and ensured that a namespace that matches the text in thespec.secretRef.namespace
field exists in the cluster.
Procedure
Create YAML files with secrets for any
CredentialsRequest
custom resources that the new release image adds. The secrets must be stored using the namespace and secret name defined in thespec.secretRef
for eachCredentialsRequest
object.Example 2.6. Sample AWS YAML files
Sample AWS
CredentialsRequest
object with secretsapiVersion: cloudcredential.openshift.io/v1 kind: CredentialsRequest metadata: name: <component_credentials_request> namespace: openshift-cloud-credential-operator ... spec: providerSpec: apiVersion: cloudcredential.openshift.io/v1 kind: AWSProviderSpec statementEntries: - effect: Allow action: - s3:CreateBucket - s3:DeleteBucket resource: "*" ... secretRef: name: <component_secret> namespace: <component_namespace> ...
Sample AWS
Secret
objectapiVersion: v1 kind: Secret metadata: name: <component_secret> namespace: <component_namespace> data: aws_access_key_id: <base64_encoded_aws_access_key_id> aws_secret_access_key: <base64_encoded_aws_secret_access_key>
Example 2.7. Sample Azure YAML files
NoteGlobal Azure and Azure Stack Hub use the same
CredentialsRequest
object and secret formats.Sample Azure
CredentialsRequest
object with secretsapiVersion: cloudcredential.openshift.io/v1 kind: CredentialsRequest metadata: name: <component_credentials_request> namespace: openshift-cloud-credential-operator ... spec: providerSpec: apiVersion: cloudcredential.openshift.io/v1 kind: AzureProviderSpec roleBindings: - role: Contributor ... secretRef: name: <component_secret> namespace: <component_namespace> ...
Sample Azure
Secret
objectapiVersion: v1 kind: Secret metadata: name: <component_secret> namespace: <component_namespace> data: azure_subscription_id: <base64_encoded_azure_subscription_id> azure_client_id: <base64_encoded_azure_client_id> azure_client_secret: <base64_encoded_azure_client_secret> azure_tenant_id: <base64_encoded_azure_tenant_id> azure_resource_prefix: <base64_encoded_azure_resource_prefix> azure_resourcegroup: <base64_encoded_azure_resourcegroup> azure_region: <base64_encoded_azure_region>
Example 2.8. Sample GCP YAML files
Sample GCP
CredentialsRequest
object with secretsapiVersion: cloudcredential.openshift.io/v1 kind: CredentialsRequest metadata: name: <component_credentials_request> namespace: openshift-cloud-credential-operator ... spec: providerSpec: apiVersion: cloudcredential.openshift.io/v1 kind: GCPProviderSpec predefinedRoles: - roles/iam.securityReviewer - roles/iam.roleViewer skipServiceCheck: true ... secretRef: name: <component_secret> namespace: <component_namespace> ...
Sample GCP
Secret
objectapiVersion: v1 kind: Secret metadata: name: <component_secret> namespace: <component_namespace> data: service_account.json: <base64_encoded_gcp_service_account_file>
-
If the
CredentialsRequest
custom resources for any existing credentials that are stored in secrets have changed permissions requirements, update the permissions as required.
Next steps
-
Update the
upgradeable-to
annotation to indicate that the cluster is ready to upgrade.
2.2.6. Indicating that the cluster is ready to upgrade
The Cloud Credential Operator (CCO) Upgradable
status for a cluster with manually maintained credentials is False
by default.
Prerequisites
-
For the release image that you are upgrading to, you have processed any new credentials manually or by using the Cloud Credential Operator utility (
ccoctl
). -
You have installed the OpenShift CLI (
oc
).
Procedure
-
Log in to
oc
on the cluster as a user with thecluster-admin
role. Edit the
CloudCredential
resource to add anupgradeable-to
annotation within themetadata
field by running the following command:$ oc edit cloudcredential cluster
Text to add
... metadata: annotations: cloudcredential.openshift.io/upgradeable-to: <version_number> ...
Where
<version_number>
is the version that you are upgrading to, in the formatx.y.z
. For example, use4.12.2
for OpenShift Container Platform 4.12.2.It may take several minutes after adding the annotation for the upgradeable status to change.
Verification
-
In the Administrator perspective of the web console, navigate to Administration
Cluster Settings. To view the CCO status details, click cloud-credential in the Cluster Operators list.
-
If the Upgradeable status in the Conditions section is False, verify that the
upgradeable-to
annotation is free of typographical errors.
-
If the Upgradeable status in the Conditions section is False, verify that the
- When the Upgradeable status in the Conditions section is True, begin the OpenShift Container Platform upgrade.
2.3. Preflight validation for Kernel Module Management (KMM) Modules
Before performing an upgrade on the cluster with applied KMM modules, you must verify that kernel modules installed using KMM are able to be installed on the nodes after the cluster upgrade and possible kernel upgrade. Preflight attempts to validate every Module
loaded in the cluster, in parallel. Preflight does not wait for validation of one Module
to complete before starting validation of another Module
.
2.3.1. Validation kickoff
Preflight validation is triggered by creating a PreflightValidationOCP
resource in the cluster. This spec contains two fields:
releaseImage
- Mandatory field that provides the name of the release image for the OpenShift Container Platform version the cluster is upgraded to.
pushBuiltImage
-
If
true
, then the images created during the Build and Sign validation are pushed to their repositories. This field isfalse
by default.
2.3.2. Validation lifecycle
Preflight validation attempts to validate every module loaded in the cluster. Preflight stops running validation on a Module
resource after the validation is successful. If module validation fails, you can change the module definitions and Preflight tries to validate the module again in the next loop.
If you want to run Preflight validation for an additional kernel, then you should create another PreflightValidationOCP
resource for that kernel. After all the modules have been validated, it is recommended to delete the PreflightValidationOCP
resource.
2.3.3. Validation status
A PreflightValidationOCP
resource reports the status and progress of each module in the cluster that it attempts or has attempted to validate in its .status.modules
list. Elements of that list contain the following fields:
lastTransitionTime
-
The last time the
Module
resource status transitioned from one status to another. This should be when the underlying status has changed. If that is not known, then using the time when the API field changed is acceptable. name
-
The name of the
Module
resource. namespace
-
The namespace of the
Module
resource. statusReason
- Verbal explanation regarding the status.
verificationStage
Describes the validation stage being executed:
-
image
: Image existence verification -
build
: Build process verification -
sign
: Sign process verification
-
verificationStatus
The status of the Module verification:
-
true
: Verified -
false
: Verification failed -
error
: Error during the verification process -
unknown
: Verification has not started
-
2.3.4. Preflight validation stages per Module
Preflight runs the following validations on every KMM Module present in the cluster:
- Image validation stage
- Build validation stage
- Sign validation stage
2.3.4.1. Image validation stage
Image validation is always the first stage of the preflight validation to be executed. If image validation is successful, no other validations are run on that specific module.
Image validation consists of two stages:
- Image existence and accessibility. The code tries to access the image defined for the upgraded kernel in the module and get its manifests.
-
Verify the presence of the kernel module defined in the
Module
in the correct path for futuremodprobe
execution. If this validation is successful, it probably means that the kernel module was compiled with the correct Linux headers. The correct path is<dirname>/lib/modules/<upgraded_kernel>/
.
2.3.4.2. Build validation stage
Build validation is executed only when image validation has failed and there is a build
section in the Module
that is relevant for the upgraded kernel. Build validation attempts to run the build job and validate that it finishes successfully.
You must specify the kernel version when running depmod
, as shown here:
$ RUN depmod -b /opt ${KERNEL_VERSION}
If the PushBuiltImage
flag is defined in the PreflightValidationOCP
custom resource (CR), it also tries to push the resulting image into its repository. The resulting image name is taken from the definition of the containerImage
field of the Module
CR.
If the sign
section is defined for the upgraded kernel, then the resulting image will not be the containerImage
field of the Module
CR, but a temporary image name, because the resulting image should be the product of Sign flow.
2.3.4.3. Sign validation stage
Sign validation is executed only when image validation has failed. There is a sign
section in the Module
resource that is relevant for the upgrade kernel, and build validation finishes successfully in case there was a build
section in the Module
relevant for the upgraded kernel. Sign validation attempts to run the sign job and validate that it finishes successfully.
If the PushBuiltImage
flag is defined in the PreflightValidationOCP
CR, sign validation also tries to push the resulting image to its registry. The resulting image is always the image defined in the ContainerImage
field of the Module
. The input image is either the output of the Build stage, or an image defined in the UnsignedImage
field.
If a build
section exists, the sign
section input image is the build
section’s output image. Therefore, in order for the input image to be available for the sign
section, the PushBuiltImage
flag must be defined in the PreflightValidationOCP
CR.
2.3.5. Example PreflightValidationOCP resource
This section shows an example of the PreflightValidationOCP
resource in the YAML format.
The example verifies all of the currently present modules against the upcoming kernel version included in the OpenShift Container Platform release 4.11.18, which the following release image points to:
quay.io/openshift-release-dev/ocp-release@sha256:22e149142517dfccb47be828f012659b1ccf71d26620e6f62468c264a7ce7863
Because .spec.pushBuiltImage
is set to true
, KMM pushes the resulting images of Build/Sign in to the defined repositories.
apiVersion: kmm.sigs.x-k8s.io/v1beta2 kind: PreflightValidationOCP metadata: name: preflight spec: releaseImage: quay.io/openshift-release-dev/ocp-release@sha256:22e149142517dfccb47be828f012659b1ccf71d26620e6f62468c264a7ce7863 pushBuiltImage: true