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After successfully deploying an installer-provisioned cluster, consider the following postinstallation procedures.

Optional: Configuring NTP for disconnected clusters

OKD installs the chrony Network Time Protocol (NTP) service on the cluster nodes. Use the following procedure to configure NTP servers on the control plane nodes and configure worker nodes as NTP clients of the control plane nodes after a successful deployment.

Configuring NTP for disconnected clusters

OKD nodes must agree on a date and time to run properly. When worker nodes retrieve the date and time from the NTP servers on the control plane nodes, it enables the installation and operation of clusters that are not connected to a routable network and thereby do not have access to a higher stratum NTP server.

Procedure
  1. Create a Butane config, 99-master-chrony-conf-override.bu, including the contents of the chrony.conf file for the control plane nodes.

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

    Butane config example
    variant: openshift
    version: 4.11.0
    metadata:
      name: 99-master-chrony-conf-override
      labels:
        machineconfiguration.openshift.io/role: master
    storage:
      files:
        - path: /etc/chrony.conf
          mode: 0644
          overwrite: true
          contents:
            inline: |
              # Use public servers from the pool.ntp.org project.
              # Please consider joining the pool (https://www.pool.ntp.org/join.html).
    
              # The Machine Config Operator manages this file
              server openshift-master-0.<cluster-name>.<domain> iburst (1)
              server openshift-master-1.<cluster-name>.<domain> iburst
              server openshift-master-2.<cluster-name>.<domain> iburst
    
              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
    
              # Configure the control plane nodes to serve as local NTP servers
              # for all worker nodes, even if they are not in sync with an
              # upstream NTP server.
    
              # Allow NTP client access from the local network.
              allow all
              # Serve time even if not synchronized to a time source.
              local stratum 3 orphan
    1 You must replace <cluster-name> with the name of the cluster and replace <domain> with the fully qualified domain name.
  2. Use Butane to generate a MachineConfig object file, 99-master-chrony-conf-override.yaml, containing the configuration to be delivered to the control plane nodes:

    $ butane 99-master-chrony-conf-override.bu -o 99-master-chrony-conf-override.yaml
  3. Create a Butane config, 99-worker-chrony-conf-override.bu, including the contents of the chrony.conf file for the worker nodes that references the NTP servers on the control plane nodes.

    Butane config example
    variant: openshift
    version: 4.11.0
    metadata:
      name: 99-worker-chrony-conf-override
      labels:
        machineconfiguration.openshift.io/role: worker
    storage:
      files:
        - path: /etc/chrony.conf
          mode: 0644
          overwrite: true
          contents:
            inline: |
              # The Machine Config Operator manages this file.
              server openshift-master-0.<cluster-name>.<domain> iburst (1)
              server openshift-master-1.<cluster-name>.<domain> iburst
              server openshift-master-2.<cluster-name>.<domain> iburst
    
              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 You must replace <cluster-name> with the name of the cluster and replace <domain> with the fully qualified domain name.
  4. Use Butane to generate a MachineConfig object file, 99-worker-chrony-conf-override.yaml, containing the configuration to be delivered to the worker nodes:

    $ butane 99-worker-chrony-conf-override.bu -o 99-worker-chrony-conf-override.yaml
  5. Apply the 99-master-chrony-conf-override.yaml policy to the control plane nodes.

    $ oc apply -f 99-master-chrony-conf-override.yaml
    Example output
    machineconfig.machineconfiguration.openshift.io/99-master-chrony-conf-override created
  6. Apply the 99-worker-chrony-conf-override.yaml policy to the worker nodes.

    $ oc apply -f 99-worker-chrony-conf-override.yaml
    Example output
    machineconfig.machineconfiguration.openshift.io/99-worker-chrony-conf-override created
  7. Check the status of the applied NTP settings.

    $ oc describe machineconfigpool

Enabling a provisioning network after installation

The assisted installer and installer-provisioned installation for bare metal clusters provide the ability to deploy a cluster without a provisioning network. This capability is for scenarios such as proof-of-concept clusters or deploying exclusively with Redfish virtual media when each node’s baseboard management controller is routable via the baremetal network.

You can enable a provisioning network after installation using the Cluster Baremetal Operator (CBO).

Prerequisites
  • A dedicated physical network must exist, connected to all worker and control plane nodes.

  • You must isolate the native, untagged physical network.

  • The network cannot have a DHCP server when the provisioningNetwork configuration setting is set to Managed.

  • You can omit the provisioningInterface setting in OKD 4.10 to use the bootMACAddress configuration setting.

Procedure
  1. When setting the provisioningInterface setting, first identify the provisioning interface name for the cluster nodes. For example, eth0 or eno1.

  2. Enable the Preboot eXecution Environment (PXE) on the provisioning network interface of the cluster nodes.

  3. Retrieve the current state of the provisioning network and save it to a provisioning custom resource (CR) file:

    $ oc get provisioning -o yaml > enable-provisioning-nw.yaml
  4. Modify the provisioning CR file:

    $ vim ~/enable-provisioning-nw.yaml

    Scroll down to the provisioningNetwork configuration setting and change it from Disabled to Managed. Then, add the provisioningIP, provisioningNetworkCIDR, provisioningDHCPRange, provisioningInterface, and watchAllNameSpaces configuration settings after the provisioningNetwork setting. Provide appropriate values for each setting.

    apiVersion: v1
    items:
    - apiVersion: metal3.io/v1alpha1
      kind: Provisioning
      metadata:
        name: provisioning-configuration
      spec:
        provisioningNetwork: (1)
        provisioningIP: (2)
        provisioningNetworkCIDR: (3)
        provisioningDHCPRange: (4)
        provisioningInterface: (5)
        watchAllNameSpaces: (6)
    1 The provisioningNetwork is one of Managed, Unmanaged, or Disabled. When set to Managed, Metal3 manages the provisioning network and the CBO deploys the Metal3 pod with a configured DHCP server. When set to Unmanaged, the system administrator configures the DHCP server manually.
    2 The provisioningIP is the static IP address that the DHCP server and ironic use to provision the network. This static IP address must be within the provisioning subnet, and outside of the DHCP range. If you configure this setting, it must have a valid IP address even if the provisioning network is Disabled. The static IP address is bound to the metal3 pod. If the metal3 pod fails and moves to another server, the static IP address also moves to the new server.
    3 The Classless Inter-Domain Routing (CIDR) address. If you configure this setting, it must have a valid CIDR address even if the provisioning network is Disabled. For example: 192.168.0.1/24.
    4 The DHCP range. This setting is only applicable to a Managed provisioning network. Omit this configuration setting if the provisioning network is Disabled. For example: 192.168.0.64, 192.168.0.253.
    5 The NIC name for the provisioning interface on cluster nodes. The provisioningInterface setting is only applicable to Managed and Unmanaged provisioning networks. Omit the provisioningInterface configuration setting if the provisioning network is Disabled. Omit the provisioningInterface configuration setting to use the bootMACAddress configuration setting instead.
    6 Set this setting to true if you want metal3 to watch namespaces other than the default openshift-machine-api namespace. The default value is false.
  5. Save the changes to the provisioning CR file.

  6. Apply the provisioning CR file to the cluster:

    $ oc apply -f enable-provisioning-nw.yaml

Configuring an external load balancer

You can configure an OKD cluster to use an external load balancer in place of the default load balancer.

Configuring an external load balancer depends on your vendor’s load balancer.

The information and examples in this section are for guideline purposes only. Consult the vendor documentation for more specific information about the vendor’s load balancer.

Red Hat supports the following services for an external load balancer:

  • Ingress Controller

  • OpenShift API

  • OpenShift MachineConfig API

You can choose whether you want to configure one or all of these services for an external load balancer. Configuring only the Ingress Controller service is a common configuration option. To better understand each service, view the following diagrams:

An image that shows an example network workflow of an Ingress Controller operating in an OKD environment.
Figure 1. Example network workflow that shows an Ingress Controller operating in an OKD environment
An image that shows an example network workflow of an OpenShift API operating in an OKD environment.
Figure 2. Example network workflow that shows an OpenShift API operating in an OKD environment
An image that shows an example network workflow of an OpenShift MachineConfig API operating in an OKD environment.
Figure 3. Example network workflow that shows an OpenShift MachineConfig API operating in an OKD environment
Considerations
  • For a front-end IP address, you can use the same IP address for the front-end IP address, the Ingress Controller’s load balancer, and API load balancer. Check the vendor’s documentation for this capability.

  • For a back-end IP address, ensure that an IP address for an OKD control plane node does not change during the lifetime of the external load balancer. You can achieve this by completing one of the following actions:

    • Assign a static IP address to each control plane node.

    • Configure each node to receive the same IP address from the DHCP every time the node requests a DHCP lease. Depending on the vendor, the DHCP lease might be in the form of an IP reservation or a static DHCP assignment.

  • Manually define each node that runs the Ingress Controller in the external load balancer for the Ingress Controller back-end service. For example, if the Ingress Controller moves to an undefined node, a connection outage can occur.

OpenShift API prerequisites
  • You defined a front-end IP address.

  • TCP ports 6443 and 22623 are exposed on the front-end IP address of your load balancer. Check the following items:

    • Port 6443 provides access to the OpenShift API service.

    • Port 22623 can provide ignition startup configurations to nodes.

  • The front-end IP address and port 6443 are reachable by all users of your system with a location external to your OKD cluster.

  • The front-end IP address and port 22623 are reachable only by OKD nodes.

  • The load balancer backend can communicate with OKD control plane nodes on port 6443 and 22623.

Ingress Controller prerequisites
  • You defined a front-end IP address.

  • TCP ports 443 and 80 are exposed on the front-end IP address of your load balancer.

  • The front-end IP address, port 80 and port 443 are be reachable by all users of your system with a location external to your OKD cluster.

  • The front-end IP address, port 80 and port 443 are reachable to all nodes that operate in your OKD cluster.

  • The load balancer backend can communicate with OKD nodes that run the Ingress Controller on ports 80, 443, and 1936.

Prerequisite for health check URL specifications

You can configure most load balancers by setting health check URLs that determine if a service is available or unavailable. OKD provides these health checks for the OpenShift API, Machine Configuration API, and Ingress Controller backend services.

The following examples demonstrate health check specifications for the previously listed backend services:

Example of a Kubernetes API health check specification
Path: HTTPS:6443/readyz
Healthy threshold: 2
Unhealthy threshold: 2
Timeout: 10
Interval: 10
Example of a Machine Config API health check specification
Path: HTTPS:22623/healthz
Healthy threshold: 2
Unhealthy threshold: 2
Timeout: 10
Interval: 10
Example of an Ingress Controller health check specification
Path: HTTP:1936/healthz/ready
Healthy threshold: 2
Unhealthy threshold: 2
Timeout: 5
Interval: 10
Procedure
  1. Configure the HAProxy Ingress Controller, so that you can enable access to the cluster from your load balancer on ports 6443, 443, and 80:

    Example HAProxy configuration
    #...
    listen my-cluster-api-6443
        bind 192.168.1.100:6443
        mode tcp
        balance roundrobin
      option httpchk
      http-check connect
      http-check send meth GET uri /readyz
      http-check expect status 200
        server my-cluster-master-2 192.168.1.101:6443 check inter 10s rise 2 fall 2
        server my-cluster-master-0 192.168.1.102:6443 check inter 10s rise 2 fall 2
        server my-cluster-master-1 192.168.1.103:6443 check inter 10s rise 2 fall 2
    
    listen my-cluster-machine-config-api-22623
        bind 192.168.1.1000.0.0.0:22623
        mode tcp
        balance roundrobin
      option httpchk
      http-check connect
      http-check send meth GET uri /healthz
      http-check expect status 200
        server my-cluster-master-2 192.0168.21.2101:22623 check inter 10s rise 2 fall 2
        server my-cluster-master-0 192.168.1.1020.2.3:22623 check inter 10s rise 2 fall 2
        server my-cluster-master-1 192.168.1.1030.2.1:22623 check inter 10s rise 2 fall 2
    
    listen my-cluster-apps-443
            bind 192.168.1.100:443
            mode tcp
            balance roundrobin
        option httpchk
        http-check connect
        http-check send meth GET uri /healthz/ready
        http-check expect status 200
            server my-cluster-worker-0 192.168.1.111:443 check port 1936 inter 10s rise 2 fall 2
            server my-cluster-worker-1 192.168.1.112:443 check port 1936 inter 10s rise 2 fall 2
            server my-cluster-worker-2 192.168.1.113:443 check port 1936 inter 10s rise 2 fall 2
    
    listen my-cluster-apps-80
            bind 192.168.1.100:80
            mode tcp
            balance roundrobin
        option httpchk
        http-check connect
        http-check send meth GET uri /healthz/ready
        http-check expect status 200
            server my-cluster-worker-0 192.168.1.111:80 check port 1936 inter 10s rise 2 fall 2
            server my-cluster-worker-1 192.168.1.112:80 check port 1936 inter 10s rise 2 fall 2
            server my-cluster-worker-2 192.168.1.113:80 check port 1936 inter 10s rise 2 fall 2
    # ...
  2. Use the curl CLI command to verify that the external load balancer and its resources are operational:

    1. Verify that the cluster machine configuration API is accessible to the Kubernetes API server resource, by running the following command and observing the response:

      $ curl https://<loadbalancer_ip_address>:6443/version --insecure

      If the configuration is correct, you receive a JSON object in response:

      {
        "major": "1",
        "minor": "11+",
        "gitVersion": "v1.11.0+ad103ed",
        "gitCommit": "ad103ed",
        "gitTreeState": "clean",
        "buildDate": "2019-01-09T06:44:10Z",
        "goVersion": "go1.10.3",
        "compiler": "gc",
        "platform": "linux/amd64"
      }
    2. Verify that the cluster machine configuration API is accessible to the Machine config server resource, by running the following command and observing the output:

      $ curl -v https://<loadbalancer_ip_address>:22623/healthz --insecure

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 200 OK
      Content-Length: 0
    3. Verify that the controller is accessible to the Ingress Controller resource on port 80, by running the following command and observing the output:

      $ curl -I -L -H "Host: console-openshift-console.apps.<cluster_name>.<base_domain>" http://<load_balancer_front_end_IP_address>

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 302 Found
      content-length: 0
      location: https://console-openshift-console.apps.ocp4.private.opequon.net/
      cache-control: no-cache
    4. Verify that the controller is accessible to the Ingress Controller resource on port 443, by running the following command and observing the output:

      $ curl -I -L --insecure --resolve console-openshift-console.apps.<cluster_name>.<base_domain>:443:<Load Balancer Front End IP Address> https://console-openshift-console.apps.<cluster_name>.<base_domain>

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 200 OK
      referrer-policy: strict-origin-when-cross-origin
      set-cookie: csrf-token=UlYWOyQ62LWjw2h003xtYSKlh1a0Py2hhctw0WmV2YEdhJjFyQwWcGBsja261dGLgaYO0nxzVErhiXt6QepA7g==; Path=/; Secure; SameSite=Lax
      x-content-type-options: nosniff
      x-dns-prefetch-control: off
      x-frame-options: DENY
      x-xss-protection: 1; mode=block
      date: Wed, 04 Oct 2023 16:29:38 GMT
      content-type: text/html; charset=utf-8
      set-cookie: 1e2670d92730b515ce3a1bb65da45062=1bf5e9573c9a2760c964ed1659cc1673; path=/; HttpOnly; Secure; SameSite=None
      cache-control: private
  3. Configure the DNS records for your cluster to target the front-end IP addresses of the external load balancer. You must update records to your DNS server for the cluster API and applications over the load balancer.

    Examples of modified DNS records
    <load_balancer_ip_address>  A  api.<cluster_name>.<base_domain>
    A record pointing to Load Balancer Front End
    <load_balancer_ip_address>   A apps.<cluster_name>.<base_domain>
    A record pointing to Load Balancer Front End

    DNS propagation might take some time for each DNS record to become available. Ensure that each DNS record propagates before validating each record.

  4. Use the curl CLI command to verify that the external load balancer and DNS record configuration are operational:

    1. Verify that you can access the cluster API, by running the following command and observing the output:

      $ curl https://api.<cluster_name>.<base_domain>:6443/version --insecure

      If the configuration is correct, you receive a JSON object in response:

      {
        "major": "1",
        "minor": "11+",
        "gitVersion": "v1.11.0+ad103ed",
        "gitCommit": "ad103ed",
        "gitTreeState": "clean",
        "buildDate": "2019-01-09T06:44:10Z",
        "goVersion": "go1.10.3",
        "compiler": "gc",
        "platform": "linux/amd64"
        }
    2. Verify that you can access the cluster machine configuration, by running the following command and observing the output:

      $ curl -v https://api.<cluster_name>.<base_domain>:22623/healthz --insecure

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 200 OK
      Content-Length: 0
    3. Verify that you can access each cluster application on port, by running the following command and observing the output:

      $ curl http://console-openshift-console.apps.<cluster_name>.<base_domain> -I -L --insecure

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 302 Found
      content-length: 0
      location: https://console-openshift-console.apps.<cluster-name>.<base domain>/
      cache-control: no-cacheHTTP/1.1 200 OK
      referrer-policy: strict-origin-when-cross-origin
      set-cookie: csrf-token=39HoZgztDnzjJkq/JuLJMeoKNXlfiVv2YgZc09c3TBOBU4NI6kDXaJH1LdicNhN1UsQWzon4Dor9GWGfopaTEQ==; Path=/; Secure
      x-content-type-options: nosniff
      x-dns-prefetch-control: off
      x-frame-options: DENY
      x-xss-protection: 1; mode=block
      date: Tue, 17 Nov 2020 08:42:10 GMT
      content-type: text/html; charset=utf-8
      set-cookie: 1e2670d92730b515ce3a1bb65da45062=9b714eb87e93cf34853e87a92d6894be; path=/; HttpOnly; Secure; SameSite=None
      cache-control: private
    4. Verify that you can access each cluster application on port 443, by running the following command and observing the output:

      $ curl https://console-openshift-console.apps.<cluster_name>.<base_domain> -I -L --insecure

      If the configuration is correct, the output from the command shows the following response:

      HTTP/1.1 200 OK
      referrer-policy: strict-origin-when-cross-origin
      set-cookie: csrf-token=UlYWOyQ62LWjw2h003xtYSKlh1a0Py2hhctw0WmV2YEdhJjFyQwWcGBsja261dGLgaYO0nxzVErhiXt6QepA7g==; Path=/; Secure; SameSite=Lax
      x-content-type-options: nosniff
      x-dns-prefetch-control: off
      x-frame-options: DENY
      x-xss-protection: 1; mode=block
      date: Wed, 04 Oct 2023 16:29:38 GMT
      content-type: text/html; charset=utf-8
      set-cookie: 1e2670d92730b515ce3a1bb65da45062=1bf5e9573c9a2760c964ed1659cc1673; path=/; HttpOnly; Secure; SameSite=None
      cache-control: private