$ oc get ptpoperatorconfig/default -n openshift-ptp -ojsonpath='{.spec}' | jq
You can expand single-node OpenShift clusters with GitOps Zero Touch Provisioning (ZTP). When you add worker nodes to single-node OpenShift clusters, the original single-node OpenShift cluster retains the control plane node role. Adding worker nodes does not require any downtime for the existing single-node OpenShift cluster.
Although there is no specified limit on the number of worker nodes that you can add to a single-node OpenShift cluster, you must revaluate the reserved CPU allocation on the control plane node for the additional worker nodes. |
If you require workload partitioning on the worker node, you must deploy and remediate the managed cluster policies on the hub cluster before installing the node. This way, the workload partitioning MachineConfig
objects are rendered and associated with the worker
machine config pool before the GitOps ZTP workflow applies the MachineConfig
ignition file to the worker node.
It is recommended that you first remediate the policies, and then install the worker node. If you create the workload partitioning manifests after installing the worker node, you must drain the node manually and delete all the pods managed by daemon sets. When the managing daemon sets create the new pods, the new pods undergo the workload partitioning process.
Adding worker nodes to single-node OpenShift clusters with GitOps ZTP is a Technology Preview feature only. Technology Preview features are not supported with Red Hat production service level agreements (SLAs) and might not be functionally complete. Red Hat does not recommend using them in production. These features provide early access to upcoming product features, enabling customers to test functionality and provide feedback during the development process. For more information about the support scope of Red Hat Technology Preview features, see Technology Preview Features Support Scope. |
For more information about single-node OpenShift clusters tuned for vDU application deployments, see Reference configuration for deploying vDUs on single-node OpenShift.
For more information about worker nodes, see Adding worker nodes to single-node OpenShift clusters.
For information about removing a worker node from an expanded single-node OpenShift cluster, see Removing managed cluster nodes by using the command line interface.
You can configure the additional worker node with a DU profile.
You can apply a RAN distributed unit (DU) profile to the worker node cluster using the GitOps Zero Touch Provisioning (ZTP) common, group, and site-specific PolicyGenTemplate
resources. The GitOps ZTP pipeline that is linked to the ArgoCD policies
application includes the following CRs that you can find in the out/argocd/example/policygentemplates
folder when you extract the ztp-site-generate
container:
common-ranGen.yaml
group-du-sno-ranGen.yaml
example-sno-site.yaml
ns.yaml
kustomization.yaml
Configuring the DU profile on the worker node is considered an upgrade. To initiate the upgrade flow, you must update the existing policies or create additional ones. Then, you must create a ClusterGroupUpgrade
CR to reconcile the policies in the group of clusters.
If the DU profile was deployed using the GitOps Zero Touch Provisioning (ZTP) plugin version 4.11 or earlier, the PTP and SR-IOV Operators might be configured to place the daemons only on nodes labelled as master
. This configuration prevents the PTP and SR-IOV daemons from operating on the worker node. If the PTP and SR-IOV daemon node selectors are incorrectly configured on your system, you must change the daemons before proceeding with the worker DU profile configuration.
Check the daemon node selector settings of the PTP Operator on one of the spoke clusters:
$ oc get ptpoperatorconfig/default -n openshift-ptp -ojsonpath='{.spec}' | jq
{"daemonNodeSelector":{"node-role.kubernetes.io/master":""}} (1)
1 | If the node selector is set to master , the spoke was deployed with the version of the GitOps ZTP plugin that requires changes. |
Check the daemon node selector settings of the SR-IOV Operator on one of the spoke clusters:
$ oc get sriovoperatorconfig/default -n \
openshift-sriov-network-operator -ojsonpath='{.spec}' | jq
{"configDaemonNodeSelector":{"node-role.kubernetes.io/worker":""},"disableDrain":false,"enableInjector":true,"enableOperatorWebhook":true} (1)
1 | If the node selector is set to master , the spoke was deployed with the version of the GitOps ZTP plugin that requires changes. |
In the group policy, add the following complianceType
and spec
entries:
spec:
- fileName: PtpOperatorConfig.yaml
policyName: "config-policy"
complianceType: mustonlyhave
spec:
daemonNodeSelector:
node-role.kubernetes.io/worker: ""
- fileName: SriovOperatorConfig.yaml
policyName: "config-policy"
complianceType: mustonlyhave
spec:
configDaemonNodeSelector:
node-role.kubernetes.io/worker: ""
Changing the |
Commit the changes in Git, and then push to the Git repository being monitored by the GitOps ZTP ArgoCD application.
The PTP configuration resources and SR-IOV network node policies use node-role.kubernetes.io/master: ""
as the node selector. If the additional worker nodes have the same NIC configuration as the control plane node, the policies used to configure the control plane node can be reused for the worker nodes. However, the node selector must be changed to select both node types, for example with the "node-role.kubernetes.io/worker"
label.
You can create policies for worker nodes.
Create the following policy template:
apiVersion: ran.openshift.io/v1
kind: PolicyGenTemplate
metadata:
name: "example-sno-workers"
namespace: "example-sno"
spec:
bindingRules:
sites: "example-sno" (1)
mcp: "worker" (2)
sourceFiles:
- fileName: MachineConfigGeneric.yaml (3)
policyName: "config-policy"
metadata:
labels:
machineconfiguration.openshift.io/role: worker
name: enable-workload-partitioning
spec:
config:
storage:
files:
- contents:
source: data:text/plain;charset=utf-8;base64,W2NyaW8ucnVudGltZS53b3JrbG9hZHMubWFuYWdlbWVudF0KYWN0aXZhdGlvbl9hbm5vdGF0aW9uID0gInRhcmdldC53b3JrbG9hZC5vcGVuc2hpZnQuaW8vbWFuYWdlbWVudCIKYW5ub3RhdGlvbl9wcmVmaXggPSAicmVzb3VyY2VzLndvcmtsb2FkLm9wZW5zaGlmdC5pbyIKcmVzb3VyY2VzID0geyAiY3B1c2hhcmVzIiA9IDAsICJjcHVzZXQiID0gIjAtMyIgfQo=
mode: 420
overwrite: true
path: /etc/crio/crio.conf.d/01-workload-partitioning
user:
name: root
- contents:
source: data:text/plain;charset=utf-8;base64,ewogICJtYW5hZ2VtZW50IjogewogICAgImNwdXNldCI6ICIwLTMiCiAgfQp9Cg==
mode: 420
overwrite: true
path: /etc/kubernetes/openshift-workload-pinning
user:
name: root
- fileName: PerformanceProfile.yaml
policyName: "config-policy"
metadata:
name: openshift-worker-node-performance-profile
spec:
cpu: (4)
isolated: "4-47"
reserved: "0-3"
hugepages:
defaultHugepagesSize: 1G
pages:
- size: 1G
count: 32
realTimeKernel:
enabled: true
- fileName: TunedPerformancePatch.yaml
policyName: "config-policy"
metadata:
name: performance-patch-worker
spec:
profile:
- name: performance-patch-worker
data: |
[main]
summary=Configuration changes profile inherited from performance created tuned
include=openshift-node-performance-openshift-worker-node-performance-profile
[bootloader]
cmdline_crash=nohz_full=4-47 (5)
[sysctl]
kernel.timer_migration=1
[scheduler]
group.ice-ptp=0:f:10:*:ice-ptp.*
[service]
service.stalld=start,enable
service.chronyd=stop,disable
recommend:
- profile: performance-patch-worker
1 | The policies are applied to all clusters with this label. |
2 | The MCP field must be set to worker . |
3 | This generic MachineConfig CR is used to configure workload partitioning on the worker node. |
4 | The cpu.isolated and cpu.reserved fields must be configured for each particular hardware platform. |
5 | The cmdline_crash CPU set must match the cpu.isolated set in the PerformanceProfile section. |
A generic MachineConfig
CR is used to configure workload partitioning on the worker node. You can generate the content of crio
and kubelet
configuration files.
Add the created policy template to the Git repository monitored by the ArgoCD policies
application.
Add the policy in the kustomization.yaml
file.
Commit the changes in Git, and then push to the Git repository being monitored by the GitOps ZTP ArgoCD application.
To remediate the new policies to your spoke cluster, create a TALM custom resource:
$ cat <<EOF | oc apply -f -
apiVersion: ran.openshift.io/v1alpha1
kind: ClusterGroupUpgrade
metadata:
name: example-sno-worker-policies
namespace: default
spec:
backup: false
clusters:
- example-sno
enable: true
managedPolicies:
- group-du-sno-config-policy
- example-sno-workers-config-policy
- example-sno-config-policy
preCaching: false
remediationStrategy:
maxConcurrency: 1
EOF
You can add one or more worker nodes to existing single-node OpenShift clusters to increase available CPU resources in the cluster.
Install and configure RHACM 2.6 or later in an OpenShift Container Platform 4.11 or later bare-metal hub cluster
Install Topology Aware Lifecycle Manager in the hub cluster
Install Red Hat OpenShift GitOps in the hub cluster
Use the GitOps ZTP ztp-site-generate
container image version 4.12 or later
Deploy a managed single-node OpenShift cluster with GitOps ZTP
Configure the Central Infrastructure Management as described in the RHACM documentation
Configure the DNS serving the cluster to resolve the internal API endpoint api-int.<cluster_name>.<base_domain>
If you deployed your cluster by using the example-sno.yaml
SiteConfig
manifest, add your new worker node to the spec.clusters['example-sno'].nodes
list:
nodes:
- hostName: "example-node2.example.com"
role: "worker"
bmcAddress: "idrac-virtualmedia+https://[1111:2222:3333:4444::bbbb:1]/redfish/v1/Systems/System.Embedded.1"
bmcCredentialsName:
name: "example-node2-bmh-secret"
bootMACAddress: "AA:BB:CC:DD:EE:11"
bootMode: "UEFI"
nodeNetwork:
interfaces:
- name: eno1
macAddress: "AA:BB:CC:DD:EE:11"
config:
interfaces:
- name: eno1
type: ethernet
state: up
macAddress: "AA:BB:CC:DD:EE:11"
ipv4:
enabled: false
ipv6:
enabled: true
address:
- ip: 1111:2222:3333:4444::1
prefix-length: 64
dns-resolver:
config:
search:
- example.com
server:
- 1111:2222:3333:4444::2
routes:
config:
- destination: ::/0
next-hop-interface: eno1
next-hop-address: 1111:2222:3333:4444::1
table-id: 254
Create a BMC authentication secret for the new host, as referenced by the bmcCredentialsName
field in the spec.nodes
section of your SiteConfig
file:
apiVersion: v1
data:
password: "password"
username: "username"
kind: Secret
metadata:
name: "example-node2-bmh-secret"
namespace: example-sno
type: Opaque
Commit the changes in Git, and then push to the Git repository that is being monitored by the GitOps ZTP ArgoCD application.
When the ArgoCD cluster
application synchronizes, two new manifests appear on the hub cluster generated by the GitOps ZTP plugin:
BareMetalHost
NMStateConfig
The |
You can monitor the installation process in several ways.
Check if the preprovisioning images are created by running the following command:
$ oc get ppimg -n example-sno
NAMESPACE NAME READY REASON
example-sno example-sno True ImageCreated
example-sno example-node2 True ImageCreated
Check the state of the bare-metal hosts:
$ oc get bmh -n example-sno
NAME STATE CONSUMER ONLINE ERROR AGE
example-sno provisioned true 69m
example-node2 provisioning true 4m50s (1)
1 | The provisioning state indicates that node booting from the installation media is in progress. |
Continuously monitor the installation process:
Watch the agent install process by running the following command:
$ oc get agent -n example-sno --watch
NAME CLUSTER APPROVED ROLE STAGE
671bc05d-5358-8940-ec12-d9ad22804faa example-sno true master Done
[...]
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Starting installation
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Installing
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Writing image to disk
[...]
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Waiting for control plane
[...]
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Rebooting
14fd821b-a35d-9cba-7978-00ddf535ff37 example-sno true worker Done
When the worker node installation is finished, the worker node certificates are approved automatically. At this point, the worker appears in the ManagedClusterInfo
status. Run the following command to see the status:
$ oc get managedclusterinfo/example-sno -n example-sno -o \
jsonpath='{range .status.nodeList[*]}{.name}{"\t"}{.conditions}{"\t"}{.labels}{"\n"}{end}'
example-sno [{"status":"True","type":"Ready"}] {"node-role.kubernetes.io/master":"","node-role.kubernetes.io/worker":""}
example-node2 [{"status":"True","type":"Ready"}] {"node-role.kubernetes.io/worker":""}