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Troubleshooting the installation program workflow

Before troubleshooting the installation environment, it is critical to understand the overall flow of the installer-provisioned installation on bare metal. The following diagrams illustrate a troubleshooting flow with a step-by-step breakdown for the environment.

Flow-Diagram-1

Workflow 1 of 4 illustrates a troubleshooting workflow when the install-config.yaml file has errors or the Fedora CoreOS (FCOS) images are inaccessible. See Troubleshooting install-config.yaml for troubleshooting suggestions.

Flow-Diagram-2

Workflow 2 of 4 illustrates a troubleshooting workflow for bootstrap VM issues, bootstrap VMs that cannot boot up the cluster nodes, and inspecting logs. When installing an OKD cluster without the provisioning network, this workflow does not apply.

Flow-Diagram-3

Workflow 3 of 4 illustrates a troubleshooting workflow for cluster nodes that will not PXE boot. If installing using Redfish virtual media, each node must meet minimum firmware requirements for the installation program to deploy the node. See Firmware requirements for installing with virtual media in the Prerequisites section for additional details.

Flow-Diagram-4

Workflow 4 of 4 illustrates a troubleshooting workflow from a non-accessible API to a validated installation.

Troubleshooting install-config.yaml

The install-config.yaml configuration file represents all of the nodes that are part of the OKD cluster. The file contains the necessary options consisting of but not limited to apiVersion, baseDomain, imageContentSources and virtual IP addresses. If errors occur early in the deployment of the OKD cluster, the errors are likely in the install-config.yaml configuration file.

Procedure
  1. Use the guidelines in YAML-tips.

  2. Verify the YAML syntax is correct using syntax-check.

  3. Verify the Fedora CoreOS (FCOS) QEMU images are properly defined and accessible via the URL provided in the install-config.yaml. For example:

    $ curl -s -o /dev/null -I -w "%{http_code}\n" http://webserver.example.com:8080/rhcos-44.81.202004250133-0-qemu.<architecture>.qcow2.gz?sha256=7d884b46ee54fe87bbc3893bf2aa99af3b2d31f2e19ab5529c60636fbd0f1ce7

    If the output is 200, there is a valid response from the webserver storing the bootstrap VM image.

Troubleshooting bootstrap VM issues

The OKD installation program spawns a bootstrap node virtual machine, which handles provisioning the OKD cluster nodes.

Procedure
  1. About 10 to 15 minutes after triggering the installation program, check to ensure the bootstrap VM is operational using the virsh command:

    $ sudo virsh list
     Id    Name                           State
     --------------------------------------------
     12    openshift-xf6fq-bootstrap      running

    The name of the bootstrap VM is always the cluster name followed by a random set of characters and ending in the word "bootstrap."

  2. If the bootstrap VM is not running after 10-15 minutes, verify libvirtd is running on the system by executing the following command:

    $ systemctl status libvirtd
    ● libvirtd.service - Virtualization daemon
       Loaded: loaded (/usr/lib/systemd/system/libvirtd.service; enabled; vendor preset: enabled)
       Active: active (running) since Tue 2020-03-03 21:21:07 UTC; 3 weeks 5 days ago
         Docs: man:libvirtd(8)
               https://libvirt.org
     Main PID: 9850 (libvirtd)
        Tasks: 20 (limit: 32768)
       Memory: 74.8M
       CGroup: /system.slice/libvirtd.service
               ├─ 9850 /usr/sbin/libvirtd

    If the bootstrap VM is operational, log in to it.

  3. Use the virsh console command to find the IP address of the bootstrap VM:

    $ sudo virsh console example.com
    Connected to domain example.com
    Escape character is ^]
    Red Hat Enterprise Linux CoreOS 43.81.202001142154.0 (Ootpa) 4.3
    SSH host key: SHA256:BRWJktXZgQQRY5zjuAV0IKZ4WM7i4TiUyMVanqu9Pqg (ED25519)
    SSH host key: SHA256:7+iKGA7VtG5szmk2jB5gl/5EZ+SNcJ3a2g23o0lnIio (ECDSA)
    SSH host key: SHA256:DH5VWhvhvagOTaLsYiVNse9ca+ZSW/30OOMed8rIGOc (RSA)
    ens3:  fd35:919d:4042:2:c7ed:9a9f:a9ec:7
    ens4: 172.22.0.2 fe80::1d05:e52e:be5d:263f
    localhost login:

    When deploying an OKD cluster without the provisioning network, you must use a public IP address and not a private IP address like 172.22.0.2.

  4. After you obtain the IP address, log in to the bootstrap VM using the ssh command:

    In the console output of the previous step, you can use the IPv6 IP address provided by ens3 or the IPv4 IP provided by ens4.

    $ ssh core@172.22.0.2

If you are not successful logging in to the bootstrap VM, you have likely encountered one of the following scenarios:

  • You cannot reach the 172.22.0.0/24 network. Verify the network connectivity between the provisioner and the provisioning network bridge. This issue might occur if you are using a provisioning network.

  • You cannot reach the bootstrap VM through the public network. When attempting to SSH via baremetal network, verify connectivity on the provisioner host specifically around the baremetal network bridge.

  • You encountered Permission denied (publickey,password,keyboard-interactive). When attempting to access the bootstrap VM, a Permission denied error might occur. Verify that the SSH key for the user attempting to log in to the VM is set within the install-config.yaml file.

Bootstrap VM cannot boot up the cluster nodes

During the deployment, it is possible for the bootstrap VM to fail to boot the cluster nodes, which prevents the VM from provisioning the nodes with the FCOS image. This scenario can arise due to:

  • A problem with the install-config.yaml file.

  • Issues with out-of-band network access when using the baremetal network.

To verify the issue, there are three containers related to ironic:

  • ironic

  • ironic-inspector

Procedure
  1. Log in to the bootstrap VM:

    $ ssh core@172.22.0.2
  2. To check the container logs, execute the following:

    [core@localhost ~]$ sudo podman logs -f <container_name>

    Replace <container_name> with one of ironic or ironic-inspector. If you encounter an issue where the control plane nodes are not booting up from PXE, check the ironic pod. The ironic pod contains information about the attempt to boot the cluster nodes, because it attempts to log in to the node over IPMI.

Potential reason

The cluster nodes might be in the ON state when deployment started.

Solution

Power off the OKD cluster nodes before you begin the installation over IPMI:

$ ipmitool -I lanplus -U root -P <password> -H <out_of_band_ip> power off

Inspecting logs

When experiencing issues downloading or accessing the FCOS images, first verify that the URL is correct in the install-config.yaml configuration file.

Example of internal webserver hosting FCOS images
bootstrapOSImage: http://<ip:port>/rhcos-43.81.202001142154.0-qemu.<architecture>.qcow2.gz?sha256=9d999f55ff1d44f7ed7c106508e5deecd04dc3c06095d34d36bf1cd127837e0c
clusterOSImage: http://<ip:port>/rhcos-43.81.202001142154.0-openstack.<architecture>.qcow2.gz?sha256=a1bda656fa0892f7b936fdc6b6a6086bddaed5dafacedcd7a1e811abb78fe3b0

The coreos-downloader container downloads resources from a webserver or from the external quay.io registry, whichever the install-config.yaml configuration file specifies. Verify that the coreos-downloader container is up and running and inspect its logs as needed.

Procedure
  1. Log in to the bootstrap VM:

    $ ssh core@172.22.0.2
  2. Check the status of the coreos-downloader container within the bootstrap VM by running the following command:

    [core@localhost ~]$ sudo podman logs -f coreos-downloader

    If the bootstrap VM cannot access the URL to the images, use the curl command to verify that the VM can access the images.

  3. To inspect the bootkube logs that indicate if all the containers launched during the deployment phase, execute the following:

    [core@localhost ~]$ journalctl -xe
    [core@localhost ~]$ journalctl -b -f -u bootkube.service
  4. Verify all the pods, including dnsmasq, mariadb, httpd, and ironic, are running:

    [core@localhost ~]$ sudo podman ps
  5. If there are issues with the pods, check the logs of the containers with issues. To check the logs of the ironic service, run the following command:

    [core@localhost ~]$ sudo podman logs ironic

Investigating an unavailable Kubernetes API

When the Kubernetes API is unavailable, check the control plane nodes to ensure that they are running the correct components. Also, check the hostname resolution.

Procedure
  1. Ensure that etcd is running on each of the control plane nodes by running the following command:

    $ sudo crictl logs $(sudo crictl ps --pod=$(sudo crictl pods --name=etcd-member --quiet) --quiet)
  2. If the previous command fails, ensure that Kubelet created the etcd pods by running the following command:

    $ sudo crictl pods --name=etcd-member

    If there are no pods, investigate etcd.

  3. Check the cluster nodes to ensure they have a fully qualified domain name, and not just localhost.localdomain, by using the following command:

    $ hostname

    If a hostname is not set, set the correct hostname. For example:

    $ sudo hostnamectl set-hostname <hostname>
  4. Ensure that each node has the correct name resolution in the DNS server using the dig command:

    $ dig api.<cluster_name>.example.com
    ; <<>> DiG 9.11.4-P2-RedHat-9.11.4-26.P2.el8 <<>> api.<cluster_name>.example.com
    ;; global options: +cmd
    ;; Got answer:
    ;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 37551
    ;; flags: qr aa rd ra; QUERY: 1, ANSWER: 1, AUTHORITY: 1, ADDITIONAL: 2
    
    ;; OPT PSEUDOSECTION:
    ; EDNS: version: 0, flags:; udp: 4096
    ; COOKIE: 866929d2f8e8563582af23f05ec44203d313e50948d43f60 (good)
    ;; QUESTION SECTION:
    ;api.<cluster_name>.example.com. IN A
    
    ;; ANSWER SECTION:
    api.<cluster_name>.example.com. 10800 IN	A 10.19.13.86
    
    ;; AUTHORITY SECTION:
    <cluster_name>.example.com. 10800 IN NS	<cluster_name>.example.com.
    
    ;; ADDITIONAL SECTION:
    <cluster_name>.example.com. 10800 IN A	10.19.14.247
    
    ;; Query time: 0 msec
    ;; SERVER: 10.19.14.247#53(10.19.14.247)
    ;; WHEN: Tue May 19 20:30:59 UTC 2020
    ;; MSG SIZE  rcvd: 140

    The output in the foregoing example indicates that the appropriate IP address for the api.<cluster_name>.example.com VIP is 10.19.13.86. This IP address should reside on the baremetal network.

Troubleshooting a failure to initialize the cluster

The installation program uses the Cluster Version Operator to create all the components of an OKD cluster. When the installation program fails to initialize the cluster, you can retrieve the most important information from the ClusterVersion and ClusterOperator objects.

Procedure
  1. Inspect the ClusterVersion object by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusterversion -o yaml
    Example output
    apiVersion: config.openshift.io/v1
    kind: ClusterVersion
    metadata:
      creationTimestamp: 2019-02-27T22:24:21Z
      generation: 1
      name: version
      resourceVersion: "19927"
      selfLink: /apis/config.openshift.io/v1/clusterversions/version
      uid: 6e0f4cf8-3ade-11e9-9034-0a923b47ded4
    spec:
      channel: stable-4.1
      clusterID: 5ec312f9-f729-429d-a454-61d4906896ca
    status:
      availableUpdates: null
      conditions:
      - lastTransitionTime: 2019-02-27T22:50:30Z
        message: Done applying 4.1.1
        status: "True"
        type: Available
      - lastTransitionTime: 2019-02-27T22:50:30Z
        status: "False"
        type: Failing
      - lastTransitionTime: 2019-02-27T22:50:30Z
        message: Cluster version is 4.1.1
        status: "False"
        type: Progressing
      - lastTransitionTime: 2019-02-27T22:24:31Z
        message: 'Unable to retrieve available updates: unknown version 4.1.1
        reason: RemoteFailed
        status: "False"
        type: RetrievedUpdates
      desired:
        image: registry.svc.ci.openshift.org/openshift/origin-release@sha256:91e6f754975963e7db1a9958075eb609ad226968623939d262d1cf45e9dbc39a
        version: 4.1.1
      history:
      - completionTime: 2019-02-27T22:50:30Z
        image: registry.svc.ci.openshift.org/openshift/origin-release@sha256:91e6f754975963e7db1a9958075eb609ad226968623939d262d1cf45e9dbc39a
        startedTime: 2019-02-27T22:24:31Z
        state: Completed
        version: 4.1.1
      observedGeneration: 1
      versionHash: Wa7as_ik1qE=
  2. View the conditions by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusterversion version \
         -o=jsonpath='{range .status.conditions[*]}{.type}{" "}{.status}{" "}{.message}{"\n"}{end}'

    Some of most important conditions include Failing, Available and Progressing.

    Example output
    Available True Done applying 4.1.1
    Failing False
    Progressing False Cluster version is 4.0.0-0.alpha-2019-02-26-194020
    RetrievedUpdates False Unable to retrieve available updates: unknown version 4.1.1
  3. Inspect the ClusterOperator object by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusteroperator

    The command returns the status of the cluster Operators.

    Example output
    NAME                                  VERSION   AVAILABLE   PROGRESSING   FAILING   SINCE
    cluster-baremetal-operator                      True        False         False     17m
    cluster-autoscaler                              True        False         False     17m
    cluster-storage-operator                        True        False         False     10m
    console                                         True        False         False     7m21s
    dns                                             True        False         False     31m
    image-registry                                  True        False         False     9m58s
    ingress                                         True        False         False     10m
    kube-apiserver                                  True        False         False     28m
    kube-controller-manager                         True        False         False     21m
    kube-scheduler                                  True        False         False     25m
    machine-api                                     True        False         False     17m
    machine-config                                  True        False         False     17m
    marketplace-operator                            True        False         False     10m
    monitoring                                      True        False         False     8m23s
    network                                         True        False         False     13m
    node-tuning                                     True        False         False     11m
    openshift-apiserver                             True        False         False     15m
    openshift-authentication                        True        False         False     20m
    openshift-cloud-credential-operator             True        False         False     18m
    openshift-controller-manager                    True        False         False     10m
    openshift-samples                               True        False         False     8m42s
    operator-lifecycle-manager                      True        False         False     17m
    service-ca                                      True        False         False     30m
  4. Inspect individual cluster Operators by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusteroperator <operator> -oyaml (1)
    1 Replace <operator> with the name of a cluster Operator. This command is useful for identifying why an cluster Operator has not achieved the Available state or is in the Failed state.
    Example output
    apiVersion: config.openshift.io/v1
    kind: ClusterOperator
    metadata:
      creationTimestamp: 2019-02-27T22:47:04Z
      generation: 1
      name: monitoring
      resourceVersion: "24677"
      selfLink: /apis/config.openshift.io/v1/clusteroperators/monitoring
      uid: 9a6a5ef9-3ae1-11e9-bad4-0a97b6ba9358
    spec: {}
    status:
      conditions:
      - lastTransitionTime: 2019-02-27T22:49:10Z
        message: Successfully rolled out the stack.
        status: "True"
        type: Available
      - lastTransitionTime: 2019-02-27T22:49:10Z
        status: "False"
        type: Progressing
      - lastTransitionTime: 2019-02-27T22:49:10Z
        status: "False"
        type: Failing
      extension: null
      relatedObjects: null
      version: ""
  5. To get the cluster Operator’s status condition, run the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusteroperator <operator> \
         -o=jsonpath='{range .status.conditions[*]}{.type}{" "}{.status}{" "}{.message}{"\n"}{end}'

    Replace <operator> with the name of one of the operators above.

    Example output
    Available True Successfully rolled out the stack
    Progressing False
    Failing False
  6. To retrieve the list of objects owned by the cluster Operator, execute the following command:

    oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusteroperator kube-apiserver \
       -o=jsonpath='{.status.relatedObjects}'
    Example output
    [map[resource:kubeapiservers group:operator.openshift.io name:cluster] map[group: name:openshift-config resource:namespaces] map[group: name:openshift-config-managed resource:namespaces] map[group: name:openshift-kube-apiserver-operator resource:namespaces] map[group: name:openshift-kube-apiserver resource:namespaces]]

Troubleshooting a failure to fetch the console URL

The installation program retrieves the URL for the OKD console by using [route][route-object] within the openshift-console namespace. If the installation program fails the retrieve the URL for the console, use the following procedure.

Procedure
  1. Check if the console router is in the Available or Failing state by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get clusteroperator console -oyaml
    apiVersion: config.openshift.io/v1
    kind: ClusterOperator
    metadata:
      creationTimestamp: 2019-02-27T22:46:57Z
      generation: 1
      name: console
      resourceVersion: "19682"
      selfLink: /apis/config.openshift.io/v1/clusteroperators/console
      uid: 960364aa-3ae1-11e9-bad4-0a97b6ba9358
    spec: {}
    status:
      conditions:
      - lastTransitionTime: 2019-02-27T22:46:58Z
        status: "False"
        type: Failing
      - lastTransitionTime: 2019-02-27T22:50:12Z
        status: "False"
        type: Progressing
      - lastTransitionTime: 2019-02-27T22:50:12Z
        status: "True"
        type: Available
      - lastTransitionTime: 2019-02-27T22:46:57Z
        status: "True"
        type: Upgradeable
      extension: null
      relatedObjects:
      - group: operator.openshift.io
        name: cluster
        resource: consoles
      - group: config.openshift.io
        name: cluster
        resource: consoles
      - group: oauth.openshift.io
        name: console
        resource: oauthclients
      - group: ""
        name: openshift-console-operator
        resource: namespaces
      - group: ""
        name: openshift-console
        resource: namespaces
      versions: null
  2. Manually retrieve the console URL by executing the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get route console -n openshift-console \
         -o=jsonpath='{.spec.host}' console-openshift-console.apps.adahiya-1.devcluster.openshift.com

Troubleshooting a failure to add the ingress certificate to kubeconfig

The installation program adds the default ingress certificate to the list of trusted client certificate authorities in ${INSTALL_DIR}/auth/kubeconfig. If the installation program fails to add the ingress certificate to the kubeconfig file, you can retrieve the certificate from the cluster and add it.

Procedure
  1. Retrieve the certificate from the cluster using the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig get configmaps default-ingress-cert \
         -n openshift-config-managed -o=jsonpath='{.data.ca-bundle\.crt}'
    -----BEGIN CERTIFICATE-----
    MIIC/TCCAeWgAwIBAgIBATANBgkqhkiG9w0BAQsFADAuMSwwKgYDVQQDDCNjbHVz
    dGVyLWluZ3Jlc3Mtb3BlcmF0b3JAMTU1MTMwNzU4OTAeFw0xOTAyMjcyMjQ2Mjha
    Fw0yMTAyMjYyMjQ2MjlaMC4xLDAqBgNVBAMMI2NsdXN0ZXItaW5ncmVzcy1vcGVy
    YXRvckAxNTUxMzA3NTg5MIIBIjANBgkqhkiG9w0BAQEFAAOCAQ8AMIIBCgKCAQEA
    uCA4fQ+2YXoXSUL4h/mcvJfrgpBfKBW5hfB8NcgXeCYiQPnCKblH1sEQnI3VC5Pk
    2OfNCF3PUlfm4i8CHC95a7nCkRjmJNg1gVrWCvS/ohLgnO0BvszSiRLxIpuo3C4S
    EVqqvxValHcbdAXWgZLQoYZXV7RMz8yZjl5CfhDaaItyBFj3GtIJkXgUwp/5sUfI
    LDXW8MM6AXfuG+kweLdLCMm3g8WLLfLBLvVBKB+4IhIH7ll0buOz04RKhnYN+Ebw
    tcvFi55vwuUCWMnGhWHGEQ8sWm/wLnNlOwsUz7S1/sW8nj87GFHzgkaVM9EOnoNI
    gKhMBK9ItNzjrP6dgiKBCQIDAQABoyYwJDAOBgNVHQ8BAf8EBAMCAqQwEgYDVR0T
    AQH/BAgwBgEB/wIBADANBgkqhkiG9w0BAQsFAAOCAQEAq+vi0sFKudaZ9aUQMMha
    CeWx9CZvZBblnAWT/61UdpZKpFi4eJ2d33lGcfKwHOi2NP/iSKQBebfG0iNLVVPz
    vwLbSG1i9R9GLdAbnHpPT9UG6fLaDIoKpnKiBfGENfxeiq5vTln2bAgivxrVlyiq
    +MdDXFAWb6V4u2xh6RChI7akNsS3oU9PZ9YOs5e8vJp2YAEphht05X0swA+X8V8T
    C278FFifpo0h3Q0Dbv8Rfn4UpBEtN4KkLeS+JeT+0o2XOsFZp7Uhr9yFIodRsnNo
    H/Uwmab28ocNrGNiEVaVH6eTTQeeZuOdoQzUbClElpVmkrNGY0M42K0PvOQ/e7+y
    AQ==
    -----END CERTIFICATE-----
  2. Add the certificate to the client-certificate-authority-data field in the ${INSTALL_DIR}/auth/kubeconfig file.

Troubleshooting SSH access to cluster nodes

For added security, you cannot SSH into the cluster from outside the cluster by default. However, you can access control plane and worker nodes from the provisioner node. If you cannot SSH into the cluster nodes from the provisioner node, the nodes might be waiting on the bootstrap VM. The control plane nodes retrieve their boot configuration from the bootstrap VM, and they cannot boot successfully if they do not retrieve the boot configuration.

Procedure
  1. If you have physical access to the nodes, check their console output to determine if they have successfully booted. If the nodes are still retrieving their boot configuration, there might be problems with the bootstrap VM .

  2. Ensure you have configured the sshKey: '<ssh_pub_key>' setting in the install-config.yaml file, where <ssh_pub_key> is the public key of the kni user on the provisioner node.

Cluster nodes will not PXE boot

When OKD cluster nodes will not PXE boot, execute the following checks on the cluster nodes that will not PXE boot. This procedure does not apply when installing an OKD cluster without the provisioning network.

Procedure
  1. Check the network connectivity to the provisioning network.

  2. Ensure PXE is enabled on the NIC for the provisioning network and PXE is disabled for all other NICs.

  3. Verify that the install-config.yaml configuration file includes the rootDeviceHints parameter and boot MAC address for the NIC connected to the provisioning network. For example:

    control plane node settings
    bootMACAddress: 24:6E:96:1B:96:90 # MAC of bootable provisioning NIC
    Worker node settings
    bootMACAddress: 24:6E:96:1B:96:90 # MAC of bootable provisioning NIC

Installing creates no worker nodes

The installation program does not provision worker nodes directly. Instead, the Machine API Operator scales nodes up and down on supported platforms. If worker nodes are not created after 15 to 20 minutes, depending on the speed of the cluster’s internet connection, investigate the Machine API Operator.

Procedure
  1. Check the Machine API Operator by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig \
       --namespace=openshift-machine-api get deployments

    If ${INSTALL_DIR} is not set in your environment, replace the value with the name of the installation directory.

    Example output
    NAME                          READY   UP-TO-DATE   AVAILABLE   AGE
    cluster-autoscaler-operator   1/1     1            1           86m
    cluster-baremetal-operator    1/1     1            1           86m
    machine-api-controllers       1/1     1            1           85m
    machine-api-operator          1/1     1            1           86m
  2. Check the machine controller logs by running the following command:

    $ oc --kubeconfig=${INSTALL_DIR}/auth/kubeconfig \
         --namespace=openshift-machine-api logs deployments/machine-api-controllers \
         --container=machine-controller

Troubleshooting the Cluster Network Operator

The Cluster Network Operator is responsible for deploying the networking components. It runs early in the installation process, after the control plane nodes have come up but before the installation program removes the bootstrap control plane. Issues with this Operator might indicate installation program issues.

Procedure
  1. Ensure the network configuration exists by running the following command:

    $ oc get network -o yaml cluster

    If it does not exist, the installation program did not create it. To find out why, run the following command:

    $ openshift-install create manifests

    Review the manifests to determine why the installation program did not create the network configuration.

  2. Ensure the network is running by entering the following command:

    $ oc get po -n openshift-network-operator

Unable to discover new bare metal hosts using the BMC

In some cases, the installation program will not be able to discover the new bare metal hosts and issue an error, because it cannot mount the remote virtual media share.

For example:

ProvisioningError 51s metal3-baremetal-controller Image provisioning failed: Deploy step deploy.deploy failed with BadRequestError: HTTP POST
https://<bmc_address>/redfish/v1/Managers/iDRAC.Embedded.1/VirtualMedia/CD/Actions/VirtualMedia.InsertMedia
returned code 400.
Base.1.8.GeneralError: A general error has occurred. See ExtendedInfo for more information
Extended information: [
  {
    "Message": "Unable to mount remote share https://<ironic_address>/redfish/boot-<uuid>.iso.",
    "MessageArgs": [
      "https://<ironic_address>/redfish/boot-<uuid>.iso"
    ],
    "MessageArgs@odata.count": 1,
    "MessageId": "IDRAC.2.5.RAC0720",
    "RelatedProperties": [
      "#/Image"
    ],
    "RelatedProperties@odata.count": 1,
    "Resolution": "Retry the operation.",
    "Severity": "Informational"
  }
].

In this situation, if you are using virtual media with an unknown certificate authority, you can configure your baseboard management controller (BMC) remote file share settings to trust an unknown certificate authority to avoid this error.

This resolution was tested on OKD 4.11 with Dell iDRAC 9 and firmware version 5.10.50.

Troubleshooting worker nodes that cannot join the cluster

Installer-provisioned clusters deploy with a DNS server that includes a DNS entry for the api-int.<cluster_name>.<base_domain> URL. If the nodes within the cluster use an external or upstream DNS server to resolve the api-int.<cluster_name>.<base_domain> URL and there is no such entry, worker nodes might fail to join the cluster. Ensure that all nodes in the cluster can resolve the domain name.

Procedure
  1. Add a DNS A/AAAA or CNAME record to internally identify the API load balancer. For example, when using dnsmasq, modify the dnsmasq.conf configuration file:

    $ sudo nano /etc/dnsmasq.conf
    address=/api-int.<cluster_name>.<base_domain>/<IP_address>
    address=/api-int.mycluster.example.com/192.168.1.10
    address=/api-int.mycluster.example.com/2001:0db8:85a3:0000:0000:8a2e:0370:7334
  2. Add a DNS PTR record to internally identify the API load balancer. For example, when using dnsmasq, modify the dnsmasq.conf configuration file:

    $ sudo nano /etc/dnsmasq.conf
    ptr-record=<IP_address>.in-addr.arpa,api-int.<cluster_name>.<base_domain>
    ptr-record=10.1.168.192.in-addr.arpa,api-int.mycluster.example.com
  3. Restart the DNS server. For example, when using dnsmasq, execute the following command:

    $ sudo systemctl restart dnsmasq

These records must be resolvable from all the nodes within the cluster.

Cleaning up previous installations

In case of an earlier failed deployment, remove the artifacts from the failed attempt before trying to deploy OKD again.

Procedure
  1. Power off all bare-metal nodes before installing the OKD cluster by using the following command:

    $ ipmitool -I lanplus -U <user> -P <password> -H <management_server_ip> power off
  2. Remove all old bootstrap resources if any remain from an earlier deployment attempt by using the following script:

    for i in $(sudo virsh list | tail -n +3 | grep bootstrap | awk {'print $2'});
    do
      sudo virsh destroy $i;
      sudo virsh undefine $i;
      sudo virsh vol-delete $i --pool $i;
      sudo virsh vol-delete $i.ign --pool $i;
      sudo virsh pool-destroy $i;
      sudo virsh pool-undefine $i;
    done
  3. Delete the artifacts that the earlier installation generated by using the following command:

    $ cd ; /bin/rm -rf auth/ bootstrap.ign master.ign worker.ign metadata.json \
    .openshift_install.log .openshift_install_state.json
  4. Re-create the OKD manifests by using the following command:

    $ ./openshift-baremetal-install --dir ~/clusterconfigs create manifests

Issues with creating the registry

When creating a disconnected registry, you might encounter a "User Not Authorized" error when attempting to mirror the registry. This error might occur if you fail to append the new authentication to the existing pull-secret.txt file.

Procedure
  1. Check to ensure authentication is successful:

    $ /usr/local/bin/oc adm release mirror \
      -a pull-secret-update.json
      --from=$UPSTREAM_REPO \
      --to-release-image=$LOCAL_REG/$LOCAL_REPO:${VERSION} \
      --to=$LOCAL_REG/$LOCAL_REPO

    Example output of the variables used to mirror the install images:

    UPSTREAM_REPO=${RELEASE_IMAGE}
    LOCAL_REG=<registry_FQDN>:<registry_port>
    LOCAL_REPO='ocp4/openshift4'

    The values of RELEASE_IMAGE and VERSION were set during the Retrieving OpenShift Installer step of the Setting up the environment for an OpenShift installation section.

  2. After mirroring the registry, confirm that you can access it in your disconnected environment:

    $ curl -k -u <user>:<password> https://registry.example.com:<registry_port>/v2/_catalog
    {"repositories":["<Repo_Name>"]}

Miscellaneous issues

Addressing the runtime network not ready error

After the deployment of a cluster you might receive the following error:

`runtime network not ready: NetworkReady=false reason:NetworkPluginNotReady message:Network plugin returns error: Missing CNI default network`

The Cluster Network Operator is responsible for deploying the networking components in response to a special object created by the installation program. It runs very early in the installation process, after the control plane (master) nodes have come up, but before the bootstrap control plane has been torn down. It can be indicative of more subtle installation program issues, such as long delays in bringing up control plane (master) nodes or issues with apiserver communication.

Procedure
  1. Inspect the pods in the openshift-network-operator namespace:

    $ oc get all -n openshift-network-operator
    NAME                                    READY STATUS            RESTARTS   AGE
    pod/network-operator-69dfd7b577-bg89v   0/1   ContainerCreating 0          149m
  2. On the provisioner node, determine that the network configuration exists:

    $ kubectl get network.config.openshift.io cluster -oyaml
    apiVersion: config.openshift.io/v1
    kind: Network
    metadata:
      name: cluster
    spec:
      serviceNetwork:
      - 172.30.0.0/16
      clusterNetwork:
      - cidr: 10.128.0.0/14
        hostPrefix: 23
      networkType: OVNKubernetes

    If it does not exist, the installation program did not create it. To determine why the installation program did not create it, execute the following:

    $ openshift-install create manifests
  3. Check that the network-operator is running:

    $ kubectl -n openshift-network-operator get pods
  4. Retrieve the logs:

    $ kubectl -n openshift-network-operator logs -l "name=network-operator"

    On high availability clusters with three or more control plane nodes, the Operator will perform leader election and all other Operators will sleep. For additional details, see Troubleshooting.

Addressing the "No disk found with matching rootDeviceHints" error message

After you deploy a cluster, you might receive the following error message:

No disk found with matching rootDeviceHints

To address the No disk found with matching rootDeviceHints error message, a temporary workaround is to change the rootDeviceHints to minSizeGigabytes: 300.

After you change the rootDeviceHints settings, boot the CoreOS and then verify the disk information by using the following command:

$ udevadm info /dev/sda

If you are using DL360 Gen 10 servers, be aware that they have an SD-card slot that might be assigned the /dev/sda device name. If no SD card is present in the server, it can cause conflicts. Ensure that the SD card slot is disabled in the server’s BIOS settings.

If the minSizeGigabytes workaround is not fulfilling the requirements, you might need to revert rootDeviceHints back to /dev/sda. This change allows ironic images to boot successfully.

An alternative approach to fixing this problem is by using the serial ID of the disk. However, be aware that finding the serial ID can be challenging and might make the configuration file less readable. If you choose this path, ensure that you gather the serial ID using the previously documented command and incorporate it into your configuration.

Cluster nodes not getting the correct IPv6 address over DHCP

If the cluster nodes are not getting the correct IPv6 address over DHCP, check the following:

  1. Ensure the reserved IPv6 addresses reside outside the DHCP range.

  2. In the IP address reservation on the DHCP server, ensure the reservation specifies the correct DHCP Unique Identifier (DUID). For example:

    # This is a dnsmasq dhcp reservation, 'id:00:03:00:01' is the client id and '18:db:f2:8c:d5:9f' is the MAC Address for the NIC
    id:00:03:00:01:18:db:f2:8c:d5:9f,openshift-master-1,[2620:52:0:1302::6]
  3. Ensure that route announcements are working.

  4. Ensure that the DHCP server is listening on the required interfaces serving the IP address ranges.

Cluster nodes not getting the correct hostname over DHCP

During IPv6 deployment, cluster nodes must get their hostname over DHCP. Sometimes the NetworkManager does not assign the hostname immediately. A control plane (master) node might report an error such as:

Failed Units: 2
  NetworkManager-wait-online.service
  nodeip-configuration.service

This error indicates that the cluster node likely booted without first receiving a hostname from the DHCP server, which causes kubelet to boot with a localhost.localdomain hostname. To address the error, force the node to renew the hostname.

Procedure
  1. Retrieve the hostname:

    [core@master-X ~]$ hostname

    If the hostname is localhost, proceed with the following steps.

    Where X is the control plane node number.

  2. Force the cluster node to renew the DHCP lease:

    [core@master-X ~]$ sudo nmcli con up "<bare_metal_nic>"

    Replace <bare_metal_nic> with the wired connection corresponding to the baremetal network.

  3. Check hostname again:

    [core@master-X ~]$ hostname
  4. If the hostname is still localhost.localdomain, restart NetworkManager:

    [core@master-X ~]$ sudo systemctl restart NetworkManager
  5. If the hostname is still localhost.localdomain, wait a few minutes and check again. If the hostname remains localhost.localdomain, repeat the previous steps.

  6. Restart the nodeip-configuration service:

    [core@master-X ~]$ sudo systemctl restart nodeip-configuration.service

    This service will reconfigure the kubelet service with the correct hostname references.

  7. Reload the unit files definition since the kubelet changed in the previous step:

    [core@master-X ~]$ sudo systemctl daemon-reload
  8. Restart the kubelet service:

    [core@master-X ~]$ sudo systemctl restart kubelet.service
  9. Ensure kubelet booted with the correct hostname:

    [core@master-X ~]$ sudo journalctl -fu kubelet.service

If the cluster node is not getting the correct hostname over DHCP after the cluster is up and running, such as during a reboot, the cluster will have a pending csr. Do not approve a csr, or other issues might arise.

Addressing a csr
  1. Get CSRs on the cluster:

    $ oc get csr
  2. Verify if a pending csr contains Subject Name: localhost.localdomain:

    $ oc get csr <pending_csr> -o jsonpath='{.spec.request}' | base64 --decode | openssl req -noout -text
  3. Remove any csr that contains Subject Name: localhost.localdomain:

    $ oc delete csr <wrong_csr>

Routes do not reach endpoints

During the installation process, it is possible to encounter a Virtual Router Redundancy Protocol (VRRP) conflict. This conflict might occur if a previously used OKD node that was once part of a cluster deployment using a specific cluster name is still running but not part of the current OKD cluster deployment using that same cluster name. For example, a cluster was deployed using the cluster name openshift, deploying three control plane (master) nodes and three worker nodes. Later, a separate install uses the same cluster name openshift, but this redeployment only installed three control plane (master) nodes, leaving the three worker nodes from a previous deployment in an ON state. This might cause a Virtual Router Identifier (VRID) conflict and a VRRP conflict.

  1. Get the route:

    $ oc get route oauth-openshift
  2. Check the service endpoint:

    $ oc get svc oauth-openshift
    NAME              TYPE        CLUSTER-IP      EXTERNAL-IP   PORT(S)   AGE
    oauth-openshift   ClusterIP   172.30.19.162   <none>        443/TCP   59m
  3. Attempt to reach the service from a control plane (master) node:

    [core@master0 ~]$ curl -k https://172.30.19.162
    {
      "kind": "Status",
      "apiVersion": "v1",
      "metadata": {
      },
      "status": "Failure",
      "message": "forbidden: User \"system:anonymous\" cannot get path \"/\"",
      "reason": "Forbidden",
      "details": {
      },
      "code": 403
  4. Identify the authentication-operator errors from the provisioner node:

    $ oc logs deployment/authentication-operator -n openshift-authentication-operator
    Event(v1.ObjectReference{Kind:"Deployment", Namespace:"openshift-authentication-operator", Name:"authentication-operator", UID:"225c5bd5-b368-439b-9155-5fd3c0459d98", APIVersion:"apps/v1", ResourceVersion:"", FieldPath:""}): type: 'Normal' reason: 'OperatorStatusChanged' Status for clusteroperator/authentication changed: Degraded message changed from "IngressStateEndpointsDegraded: All 2 endpoints for oauth-server are reporting"
Solution
  1. Ensure that the cluster name for every deployment is unique, ensuring no conflict.

  2. Turn off all the rogue nodes which are not part of the cluster deployment that are using the same cluster name. Otherwise, the authentication pod of the OKD cluster might never start successfully.

Failed Ignition during Firstboot

During the Firstboot, the Ignition configuration may fail.

Procedure
  1. Connect to the node where the Ignition configuration failed:

    Failed Units: 1
      machine-config-daemon-firstboot.service
  2. Restart the machine-config-daemon-firstboot service:

    [core@worker-X ~]$ sudo systemctl restart machine-config-daemon-firstboot.service

NTP out of sync

The deployment of OKD clusters depends on NTP synchronized clocks among the cluster nodes. Without synchronized clocks, the deployment may fail due to clock drift if the time difference is greater than two seconds.

Procedure
  1. Check for differences in the AGE of the cluster nodes. For example:

    $ oc get nodes
    NAME                         STATUS   ROLES    AGE   VERSION
    master-0.cloud.example.com   Ready    master   145m   v1.31.3
    master-1.cloud.example.com   Ready    master   135m   v1.31.3
    master-2.cloud.example.com   Ready    master   145m   v1.31.3
    worker-2.cloud.example.com   Ready    worker   100m   v1.31.3
  2. Check for inconsistent timing delays due to clock drift. For example:

    $ oc get bmh -n openshift-machine-api
    master-1   error registering master-1  ipmi://<out_of_band_ip>
    $ sudo timedatectl
                   Local time: Tue 2020-03-10 18:20:02 UTC
               Universal time: Tue 2020-03-10 18:20:02 UTC
                     RTC time: Tue 2020-03-10 18:36:53
                    Time zone: UTC (UTC, +0000)
    System clock synchronized: no
                  NTP service: active
              RTC in local TZ: no
Addressing clock drift in existing clusters
  1. Create a Butane config file including the contents of the chrony.conf file to be delivered to the nodes. In the following example, create 99-master-chrony.bu to add the file to the control plane nodes. You can modify the file for worker nodes or repeat this procedure for the worker role.

    See "Creating machine configs with Butane" for information about Butane.

    variant: openshift
    version: 4.0
    metadata:
      name: 99-master-chrony
      labels:
        machineconfiguration.openshift.io/role: master
    storage:
      files:
      - path: /etc/chrony.conf
        mode: 0644
        overwrite: true
        contents:
          inline: |
            server <NTP_server> iburst (1)
            stratumweight 0
            driftfile /var/lib/chrony/drift
            rtcsync
            makestep 10 3
            bindcmdaddress 127.0.0.1
            bindcmdaddress ::1
            keyfile /etc/chrony.keys
            commandkey 1
            generatecommandkey
            noclientlog
            logchange 0.5
            logdir /var/log/chrony
    1 Replace <NTP_server> with the IP address of the NTP server.
  2. Use Butane to generate a MachineConfig object file, 99-master-chrony.yaml, containing the configuration to be delivered to the nodes:

    $ butane 99-master-chrony.bu -o 99-master-chrony.yaml
  3. Apply the MachineConfig object file:

    $ oc apply -f 99-master-chrony.yaml
  4. Ensure the System clock synchronized value is yes:

    $ sudo timedatectl
                   Local time: Tue 2020-03-10 19:10:02 UTC
               Universal time: Tue 2020-03-10 19:10:02 UTC
                     RTC time: Tue 2020-03-10 19:36:53
                    Time zone: UTC (UTC, +0000)
    System clock synchronized: yes
                  NTP service: active
              RTC in local TZ: no

    To setup clock synchronization prior to deployment, generate the manifest files and add this file to the openshift directory. For example:

    $ cp chrony-masters.yaml ~/clusterconfigs/openshift/99_masters-chrony-configuration.yaml

    Then, continue to create the cluster.

Reviewing the installation

After installation, ensure the installation program deployed the nodes and pods successfully.

Procedure
  1. When the OKD cluster nodes are installed appropriately, the following Ready state is seen within the STATUS column:

    $ oc get nodes
    NAME                   STATUS   ROLES           AGE  VERSION
    master-0.example.com   Ready    master,worker   4h   v1.31.3
    master-1.example.com   Ready    master,worker   4h   v1.31.3
    master-2.example.com   Ready    master,worker   4h   v1.31.3
  2. Confirm the installation program deployed all pods successfully. The following command removes any pods that are still running or have completed as part of the output.

    $ oc get pods --all-namespaces | grep -iv running | grep -iv complete