# subscription-manager repos --disable="rhel-7-server-ose-3.1-rpms" \ --enable="rhel-7-server-ose-3.2-rpms" \ --enable="rhel-7-server-extras-rpms"
As an alternative to performing an automated upgrade, you can manually upgrade your OpenShift cluster. To manually upgrade without disruption, it is important to upgrade each component as documented in this topic.
Before you begin your upgrade, familiarize yourself now with the entire procedure. Specific releases may require additional steps to be performed at key points before or during the standard upgrade process.
Ensure that you have met all prerequisites before proceeding with an upgrade. Failure to do so can result in a failed upgrade. |
If you are on OpenShift Enterprise 3.0, you must first upgrade to 3.1 before upgrading to 3.2. Further, if you are currently using the Pacemaker HA method, you must first upgrade to the native HA method before upgrading to 3.2, as the Pacemaker method is no longer supported starting with 3.2. See the OpenShift Enterprise 3.1 upgrade documentation for instructions. |
Starting with RHBA-2016:1208, upgrades from OpenShift Enterprise 3.1 to 3.2 are supported for clusters using the containerized installation method. See Known Issues. |
To prepare for a manual upgrade, follow these steps:
If you are upgrading from OpenShift Enterprise 3.1 to 3.2, manually disable the 3.1 channel and enable the 3.2 channel on each host:
# subscription-manager repos --disable="rhel-7-server-ose-3.1-rpms" \ --enable="rhel-7-server-ose-3.2-rpms" \ --enable="rhel-7-server-extras-rpms"
On RHEL 7 systems, also clear the yum cache:
# yum clean all
Install or update to the latest available version of the atomic-openshift-utils package on each RHEL 7 system, which provides files that will be used in later sections:
# yum install atomic-openshift-utils
Because RHEL Atomic Host 7 systems cannot use yum, you must download the atomic-openshift-utils package on a subscribed RHEL 7 system and copy the following file to any RHEL Atomic Host 7 systems to be used later:
/usr/share/ansible/openshift-ansible/playbooks/common/openshift-cluster/upgrades/files/nuke_images.sh
This file was previously located at /usr/share/ansible/openshift-ansible/playbooks/byo/openshift-cluster/upgrades/docker/files/nuke_images.sh. |
Install or update to the following latest available *-excluder packages on each RHEL 7 system, which helps ensure your systems stay on the correct versions of atomic-openshift and docker packages when you are not trying to upgrade, according to the OpenShift Enterprise version:
# yum install atomic-openshift-excluder atomic-openshift-docker-excluder
These packages add entries to the exclude
directive in the host’s
/etc/yum.conf file.
Create an etcd backup on each master. The etcd package is required, even if
using embedded etcd, for access to the etcdctl
command to make the backup. The
package is installed by default for RHEL Atomic Host 7 systems. If the master is
a RHEL 7 system, ensure the package is installed:
# yum install etcd
Then, create the backup:
# ETCD_DATA_DIR=/var/lib/origin (1) # etcdctl backup \ --data-dir $ETCD_DATA_DIR \ --backup-dir $ETCD_DATA_DIR.bak.<date> (2)
1 | This directory is for embedded etcd. If you use a separate etcd cluster, use /var/lib/etcd instead. |
2 | Use the date of the backup, or some unique identifier, for <date> .
The command will not make a backup if the --backup-dir location
already exists. |
For any upgrade path, ensure that you are running the latest kernel on each RHEL 7 system:
# yum update kernel
upgrade your master hosts first:
Run the following command on each master to remove the atomic-openshift packages from the list of yum excludes on the host:
# atomic-openshift-excluder unexclude
upgrade the atomic-openshift packages or related images.
For masters using the RPM-based method on a RHEL 7 system, upgrade all installed atomic-openshift packages:
# yum upgrade atomic-openshift\*
For masters using the containerized method on a RHEL 7 or RHEL Atomic Host 7
system, set the IMAGE_VERSION
parameter to the version you are upgrading to
in the following files:
/etc/sysconfig/atomic-openshift-master (single master clusters only)
/etc/sysconfig/atomic-openshift-master-controllers (multi-master clusters only)
/etc/sysconfig/atomic-openshift-master-api (multi-master clusters only)
/etc/sysconfig/atomic-openshift-node
/etc/sysconfig/atomic-openshift-openvswitch
For example:
IMAGE_VERSION=v3.2.1.31
Restart the master service(s) on each master and review logs to ensure they restart successfully.
For single master clusters:
# systemctl restart atomic-openshift-master # journalctl -r -u atomic-openshift-master
For multi-master clusters:
# systemctl restart atomic-openshift-master-controllers # systemctl restart atomic-openshift-master-api # journalctl -r -u atomic-openshift-master-controllers # journalctl -r -u atomic-openshift-master-api
Because masters also have node components running on them in order to be configured as part of the OpenShift SDN, restart the atomic-openshift-node and openvswitch services:
# systemctl restart atomic-openshift-node # systemctl restart openvswitch # journalctl -r -u openvswitch # journalctl -r -u atomic-openshift-node
Run the following command on each master to add the atomic-openshift packages back to the list of yum excludes on the host:
# atomic-openshift-excluder exclude
upgrade any external etcd hosts using the RPM-based method on a RHEL 7 system:
upgrade the etcd package:
# yum update etcd
Restart the etcd service and review the logs to ensure it restarts successfully:
# systemctl restart etcd # journalctl -r -u etcd
If you are performing a cluster upgrade that requires updating Docker to version 1.10, such as OpenShift Enterprise 3.1 to 3.2 or 3.2.0 to 3.2.1, you must also perform the following steps if you are not already on Docker 1.10:
The node component on masters is set by default to unschedulable status during initial installation, so that pods are not deployed to them. However, it is possible to set them schedulable during the initial installation or manually thereafter. If any of your masters are also configured as a schedulable node, skip the following Docker upgrade steps for those masters and instead run all steps described in Upgrading Nodes when you get to that section for those hosts as well. |
Run the following script on each master and external etcd host to remove all containers and images, which is required to avoid a long upgrade process for older images after Docker is updated. Containers and images for pods backed by replication controllers will be recreated automatically:
# chmod u+x /usr/share/ansible/openshift-ansible/playbooks/common/openshift-cluster/upgrades/files/nuke_images.sh # /usr/share/ansible/openshift-ansible/playbooks/common/openshift-cluster/upgrades/files/nuke_images.sh
upgrade Docker.
For RHEL 7 systems:
# yum update docker
Then, restart the docker service and review the logs to ensure it restarts successfully:
# systemctl restart docker # journalctl -r -u docker
For RHEL Atomic Host 7 systems, upgrade to the latest Atomic tree if one is available:
If upgrading to RHEL Atomic Host 7.2.5, this upgrades Docker to version 1.10. See the OpenShift Enterprise 3.2.1.1 release notes for details and known issues. |
# atomic host upgrade
After the upgrade is completed and prepared for the next boot, reboot the host and ensure the docker service starts successfully:
# systemctl reboot # journalctl -r -u docker
After a cluster upgrade, the recommended default cluster roles may have been updated. To check if an update is recommended for your environment, you can run:
# oadm policy reconcile-cluster-roles
This command outputs a list of roles that are out of date and their new proposed values. For example:
# oadm policy reconcile-cluster-roles apiVersion: v1 items: - apiVersion: v1 kind: ClusterRole metadata: creationTimestamp: null name: admin rules: - attributeRestrictions: null resources: - builds/custom ...
Your output will vary based on the OpenShift version and any local customizations you have made. Review the proposed policy carefully. |
You can either modify this output to re-apply any local policy changes you have made, or you can automatically apply the new policy using the following process:
Reconcile the cluster roles:
# oadm policy reconcile-cluster-roles \ --additive-only=true \ --confirm
Reconcile the cluster role bindings:
# oadm policy reconcile-cluster-role-bindings \ --exclude-groups=system:authenticated \ --exclude-groups=system:authenticated:oauth \ --exclude-groups=system:unauthenticated \ --exclude-users=system:anonymous \ --additive-only=true \ --confirm
Reconcile security context constraints:
# oadm policy reconcile-sccs \ --additive-only=true \ --confirm
After upgrading your masters, you can upgrade your nodes. When restarting the atomic-openshift-node service, there will be a brief disruption of outbound network connectivity from running pods to services while the service proxy is restarted. The length of this disruption should be very short and scales based on the number of services in the entire cluster.
One at at time for each node that is not also a master, you must disable scheduling and evacuate its pods to other nodes, then upgrade packages and restart services.
Run the following command on each node to remove the atomic-openshift packages from the list of yum excludes on the host:
# atomic-openshift-excluder unexclude
As a user with cluster-admin privileges, disable scheduling for the node:
# oadm manage-node <node> --schedulable=false
Evacuate pods on the node to other nodes:
The |
# oadm manage-node <node> --evacuate --force
upgrade the node component packages or related images.
For nodes using the RPM-based method on a RHEL 7 system, upgrade all installed atomic-openshift packages:
# yum upgrade atomic-openshift\*
For nodes using the containerized method on a RHEL 7 or RHEL Atomic Host 7
system, set the IMAGE_VERSION
parameter in the
/etc/sysconfig/atomic-openshift-node and /etc/sysconfig/openvswitch
files to the version you are upgrading to. For example:
IMAGE_VERSION=v3.2.1.31
Restart the atomic-openshift-node and openvswitch services and review the logs to ensure they restart successfully:
# systemctl restart atomic-openshift-node # systemctl restart openvswitch # journalctl -r -u atomic-openshift-node # journalctl -r -u openvswitch
If you are performing a cluster upgrade that requires updating Docker to version 1.10, such as OpenShift Enterprise 3.1 to 3.2 or 3.2.0 to 3.2.1, you must also perform the following steps if you are not already on Docker 1.10:
Run the following script to remove all containers and images, which is required to avoid a long upgrade process for older images after Docker is updated. Containers and images for pods backed by replication controllers will be recreated automatically:
# chmod u+x /usr/share/ansible/openshift-ansible/playbooks/common/openshift-cluster/upgrades/files/nuke_images.sh # /usr/share/ansible/openshift-ansible/playbooks/common/openshift-cluster/upgrades/files/nuke_images.sh
upgrade Docker.
For RHEL 7 systems:
# yum update docker
Then, restart the docker service and review the logs to ensure it restarts successfully:
# systemctl restart docker # journalctl -r -u docker
After Docker is restarted, restart the atomic-openshift-node service again and review the logs to ensure it restarts successfully:
# systemctl restart atomic-openshift-node # journalctl -r -u atomic-openshift-node
For RHEL Atomic Host 7 systems, upgrade to the latest Atomic tree if one is available:
If upgrading to RHEL Atomic Host 7.2.5, this upgrades Docker to version 1.10. See the OpenShift Enterprise 3.2.1.1 release notes for details and known issues. |
# atomic host upgrade
After the upgrade is completed and prepared for the next boot, reboot the host and ensure the docker service starts successfully:
# systemctl reboot # journalctl -r -u docker
Re-enable scheduling for the node:
# oadm manage-node <node> --schedulable
Run the following command on the node to add the atomic-openshift packages back to the list of yum excludes on the host:
# atomic-openshift-excluder exclude
Repeat these steps on the next node, and continue repeating these steps until all nodes have been upgraded.
After all nodes have been upgraded, as a user with cluster-admin privileges, verify that all nodes are showing as Ready:
# oc get nodes NAME LABELS STATUS master.example.com kubernetes.io/hostname=master.example.com Ready,SchedulingDisabled node1.example.com kubernetes.io/hostname=node1.example.com Ready node2.example.com kubernetes.io/hostname=node2.example.com Ready
If you have previously deployed a router, the router deployment configuration must be upgraded to apply updates contained in the router image. To upgrade your router without disrupting services, you must have previously deployed a highly-available routing service.
Edit your router’s deployment configuration. For example, if it has the default router name:
# oc edit dc/router
Apply the following changes:
... spec: template: spec: containers: - env: ... image: registry.access.redhat.com/openshift3/ose-haproxy-router:v3.2.1.31 (1) imagePullPolicy: IfNotPresent ...
1 | Adjust the image version to match the version you are upgrading to. |
You should see one router pod updated and then the next.
The registry must also be upgraded for changes to take effect in the registry
image. If you have used a PersistentVolumeClaim
or a host mount point, you
may restart the registry without losing the contents of your registry.
Deploying
a Docker Registry details how to configure persistent storage for the registry.
Edit your registry’s deployment configuration:
# oc edit dc/docker-registry
Apply the following changes:
... spec: template: spec: containers: - env: ... image: registry.access.redhat.com/openshift3/ose-docker-registry:v3.2.1.31 (1) imagePullPolicy: IfNotPresent ...
1 | Adjust the image version to match the version you are upgrading to. |
Images that are being pushed or pulled from the internal registry at the time of upgrade will fail and should be restarted automatically. This will not disrupt pods that are already running. |
By default, the quick and advanced installation methods automatically create default image streams, InstantApp templates, and database service templates in the openshift project, which is a default project to which all users have view access. These objects were created during installation from the JSON files located under the /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/ directory.
Because RHEL Atomic Host 7 cannot use yum to update packages, the following steps must take place on a RHEL 7 system. |
Update the packages that provide the example JSON files. On a subscribed Red Hat Enterprise Linux 7 system where you can run the CLI as a user with cluster-admin permissions, install or update to the latest version of the atomic-openshift-utils package, which should also update the openshift-ansible- packages:
# yum update atomic-openshift-utils
The openshift-ansible-roles package provides the latest example JSON files.
After a manual upgrade, get the latest templates from openshift-ansible-roles:
rpm -ql openshift-ansible-roles | grep examples | grep v1.2
In this example, /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/image-streams/image-streams-rhel7.json is the latest file that you want in the latest openshift-ansible-roles package.
/usr/share/openshift/examples/image-streams/image-streams-rhel7.json is not
owned by a package, but is updated by Ansible. If you are upgrading outside of
Ansible. you need to get the latest .json files on the system where you are
running oc
, which can run anywhere that has access to the master.
Install atomic-openshift-utils and its dependencies to install the new content into /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/.:
$ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/image-streams/image-streams-rhel7.json $ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/image-streams/dotnet_imagestreams.json $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/image-streams/image-streams-rhel7.json $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/image-streams/dotnet_imagestreams.json
Update the templates:
$ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/ $ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/db-templates/ $ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/infrastructure-templates/ $ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/xpaas-templates/ $ oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/xpaas-streams/ $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/ $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/db-templates/ $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/infrastructure-templates/ $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/xpaas-templates/ $ oc replace -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/xpaas-streams/
Errors are generated for items that already exist. This is expected behavior:
# oc create -n openshift -f /usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/ Error from server: error when creating "/usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/cakephp-mysql.json": templates "cakephp-mysql-example" already exists Error from server: error when creating "/usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/cakephp.json": templates "cakephp-example" already exists Error from server: error when creating "/usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/dancer-mysql.json": templates "dancer-mysql-example" already exists Error from server: error when creating "/usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/dancer.json": templates "dancer-example" already exists Error from server: error when creating "/usr/share/ansible/openshift-ansible/roles/openshift_examples/files/examples/v1.2/quickstart-templates/django-postgresql.json": templates "django-psql-example" already exists
Now, content can be updated. Without running the automated upgrade playbooks, the content is not updated in /usr/share/openshift/.
After updating the default image streams, you may also want to ensure that the images within those streams are updated. For each image stream in the default openshift project, you can run:
# oc import-image -n openshift <imagestream>
For example, get the list of all image streams in the default openshift project:
# oc get is -n openshift NAME DOCKER REPO TAGS UPDATED mongodb registry.access.redhat.com/openshift3/mongodb-24-rhel7 2.4,latest,v3.1.1.6 16 hours ago mysql registry.access.redhat.com/openshift3/mysql-55-rhel7 5.5,latest,v3.1.1.6 16 hours ago nodejs registry.access.redhat.com/openshift3/nodejs-010-rhel7 0.10,latest,v3.1.1.6 16 hours ago ...
Update each image stream one at a time:
# oc import-image -n openshift nodejs The import completed successfully. Name: nodejs Created: 10 seconds ago Labels: <none> Annotations: openshift.io/image.dockerRepositoryCheck=2016-07-05T19:20:30Z Docker Pull Spec: 172.30.204.22:5000/openshift/nodejs Tag Spec Created PullSpec Image latest 4 9 seconds ago registry.access.redhat.com/rhscl/nodejs-4-rhel7:latest 570ad8ed927fd5c2c9554ef4d9534cef808dfa05df31ec491c0969c3bd372b05 4 registry.access.redhat.com/rhscl/nodejs-4-rhel7:latest 9 seconds ago <same> 570ad8ed927fd5c2c9554ef4d9534cef808dfa05df31ec491c0969c3bd372b05 0.10 registry.access.redhat.com/openshift3/nodejs-010-rhel7:latest 9 seconds ago <same> a1ef33be788a28ec2bdd48a9a5d174ebcfbe11c8e986d2996b77f5bccaaa4774
In order to update your S2I-based applications, you must manually trigger a new
build of those applications after importing the new images using |
Use the following to upgrade an already-deployed EFK logging stack.
The following steps apply when upgrading from OpenShift Enterprise 3.1 to 3.2, or are applying an asynchronous update to 3.2. These steps pull the latest 3.2 logging images. |
Ensure you are working in the project where the EFK stack was previously deployed. For example, if the project is named logging:
$ oc project logging
Scale down your Fluentd instances to 0:
$ oc scale dc/logging-fluentd --replicas=0
Wait until they have terminated. This helps prevent loss of data by giving them time to properly flush their current buffer and send any logs they were processing to Elasticsearch.
Scale down your Kibana instances:
$ oc scale dc/logging-kibana --replicas=0
If you have an operations deployment, also run:
$ oc scale dc/logging-kibana-ops --replicas=0
Once confirming your Fluentd and Kibana pods have been terminated, scale down the Elasticsearch pods:
$ oc scale dc/logging-es-<unique_name> --replicas=0
If you have an operations deployment, also run:
$ oc scale dc/logging-es-ops-<unique_name> --replicas=0
After confirming your Elasticsearch pods have been terminated, rerun the deployer to generate any missing or changed features.
Follow the first step in Deploying the EFK Stack. After the deployer completes, re-attach the persistent volume claims you were previously using, then deploy a template that is created by the deployer:
$ oc process logging-support-template | oc apply -f -
Deployment of logging components is intended to happen automatically based on tags being imported into the image streams created in the previous step. However, as not all tags are automatically imported, this mechanism has become unreliable as multiple versions are released. Therefore, manual importing may be necessary as follows.
For each image stream logging-auth-proxy
, logging-kibana
,
logging-elasticsearch
, and logging-fluentd
, manually import the
tag corresponding to the IMAGE_VERSION
specified (or defaulted)
for the deployer.
$ oc import-image <name>:<version> --from <prefix><name>:<tag>
For example:
$ oc import-image logging-auth-proxy:3.2.1 \ --from registry.access.redhat.com/openshift3/logging-auth-proxy:3.2.1 $ oc import-image logging-kibana:3.2.1 \ --from registry.access.redhat.com/openshift3/logging-kibana:3.2.1 $ oc import-image logging-elasticsearch:3.2.1 \ --from registry.access.redhat.com/openshift3/logging-elasticsearch:3.2.1 $ oc import-image logging-fluentd:3.2.1 \ --from registry.access.redhat.com/openshift3/logging-fluentd:3.2.1
Next, scale Elasticsearch back up incrementally so that the cluster has time to rebuild.
To begin, scale up to 1:
$ oc scale dc/logging-es-<unique_name> --replicas=1
Follow the logs of the resulting pod to ensure that it is able to recover its indices correctly and that there are no errors:
$ oc logs -f <pod_name>
If that is successful, you can then do the same for the operations cluster, if one was previously used.
After all Elasticsearch nodes have recovered their indices, continue to scale it back up to the size it was prior to doing maintenance. Check the logs of the Elasticsearch members to verify that they have correctly joined the cluster and recovered.
Now scale Kibana and Fluentd back up to their previous state. Because Fluentd was shut down and allowed to push its remaining records to Elasticsearch in the previous steps, it can now pick back up from where it left off with no loss of logs, provided any unread log files are still available on the node.
In the latest version, Kibana will display indices differently now in order to prevent users from being able to access the logs of previously created projects that have been deleted.
Due to this change, your old logs will not appear automatically. To migrate your
old indices to the new format, rerun the deployer with -v MODE=migrate
in addition
to your prior flags. This should be run while your Elasticsearch cluster is running, as the
script must connect to it to make changes.
This only impacts non-operations logs. Operations logs will appear the same as in previous versions. There should be minimal performance impact to Elasticsearch while running this and it will not perform an install. |
After upgrading an already-deployed Cluster Metrics install, you must update to a newer version of the metrics components.
The update process stops all the metrics containers, updates the metrics configuration files, and redeploys the newer components.
It does not change the metrics route.
It does not delete the metrics persistent volume claim. Metrics stored to persistent volumes before the update are available after the update completes.
The update deletes all non-persisted metric values and overwrites local changes to the metrics configurations. For example, the number of instances in a replica set is not saved. |
To update, follow the same steps as when the metrics components were
first deployed,
using the
correct template,
except this time, specify the MODE=refresh
option:
$ oc new-app -f metrics-deployer.yaml \ -p HAWKULAR_METRICS_HOSTNAME=hm.example.com,MODE=refresh (1)
1 | In the original deployment command, there was no MODE=refresh . |
During the update, the metrics components do not run. Because of this, they cannot collect data and a gap normally appears in the graphs. |
Some OpenShift releases may have additional instructions specific to that release that must be performed to fully apply the updates across the cluster. Read through the following sections carefully depending on your upgrade path, as you may be required to perform certain steps at key points during the standard upgrade process described earlier in this topic.
See the OpenShift Enterprise 3.2 Release Notes to review the latest release notes.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.0 that are not already mentioned inline during the standard manual upgrade process.
The upgrade to OpenShift Enterprise 3.2.1.1 involves updating to Docker 1.10. The steps to properly upgrade Docker are higlighted and included inline in the Upgrading Master Components and Upgrading Nodes sections. No other additional manual steps are required for this release.
See the Known Issues for OpenShift Enterprise 3.2.1.1 for more details on using OpenShift Enterprise and Docker 1.10. |
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.4 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.9 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.13 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.15 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.17 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.21 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.23 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.26 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.28 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.30 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.31-2 that are not already mentioned inline during the standard manual upgrade process.
There are no additional manual steps for the upgrade to OpenShift Enterprise 3.2.1.31-4 that are not already mentioned inline during the standard manual upgrade process.
To verify the upgrade, first check that all nodes are marked as Ready:
# oc get nodes NAME LABELS STATUS master.example.com kubernetes.io/hostname=master.example.com,region=infra,zone=default Ready node1.example.com kubernetes.io/hostname=node1.example.com,region=primary,zone=east Ready
Then, verify that you are running the expected versions of the docker-registry and router images, if deployed:
# oc get -n default dc/docker-registry -o json | grep \"image\" "image": "openshift3/ose-docker-registry:v3.2.1.31", # oc get -n default dc/router -o json | grep \"image\" "image": "openshift3/ose-haproxy-router:v3.2.1.31",
After upgrading, you can use the diagnostics tool on the master to look for common issues:
# oadm diagnostics ... [Note] Summary of diagnostics execution: [Note] Completed with no errors or warnings seen.