Category: IBM Power Systems

  • 🚀 Builds for OpenShift 1.5 is now GA!

    Now available on OpenShift 4.16–4.19, this release brings powerful new features for building container images natively on your cluster—including support for ppc64le!

    🔧 Highlights:

    • NodeSelector & Scheduler support via shp CLI
    • Shallow Git cloning for faster builds

    💡 Built on Shipwright, Builds 1.5 simplifies image creation with Kubernetes-native APIs, Buildah/S2I strategies, and full CLI + web console integration.

    Perfect for teams running on IBM Power Systems or running Multi-Architecture Compute clusters. Start building smarter, faster, and more consistently across all the architectures in your cluster.

    📘 Learn more: https://docs.redhat.com/en/documentation/builds_for_red_hat_openshift/1.5/html/release_notes/ob-release-notes

  • Great News… IBM has Open Source Wheel Packages for Linux on Power

    Priya Seth posted about Open Source Wheel Packages for Linux on Power:

    IBM provides a dedicated repository of Python wheel packages optimized for the Linux on Power (ppc64le) architecture. These pre-built binaries simplify Python development on Power systems by eliminating the need to compile packages from source—saving time and reducing complexity.

    Wheel files (.whl) are the standard for distributing pre-compiled Python packages. For developers working on Power architecture, having access to architecture-specific wheels ensures compatibility and speeds up development.

    IBM hosts a curated collection of open-source Python wheels for the ppc64le platform listed at https://open-source-edge.developerfirst.ibm.com/

    Use pip to download the package without installing it:

    pip download <package_name>==<version> --prefer-binary --index-url=https://wheels.developerfirst.ibm.com/ppc64le/linux --verbose --no-deps
    

    Replace <package_name> and <version> with the desired values.

    Whether you’re building AI models, data pipelines, or enterprise applications, this repository helps accelerate your Python development on Power.

    You can also refer to https://community.ibm.com/community/user/blogs/nikhil-kalbande/2025/08/01/install-wheels-from-ibm-python-wheel-repository

  • Playing with Container Lifecycle Hooks and ContainerStopSignals

    DRAFT This is not a complete article. I haven’t yet fully tested and vetted the steps I built. I will come back and hopefully update.

    Kubernetes orchestrates Pods across multiple nodes. When a Pod lands on a node, the Kubelet admits the Pod and its containers, and manages the lifecycle of the containers. When the Pod is terminated, the kubelet sends a SIGTERM signal to the running processes. In Kubernetes Enhancement – Container Stop Signals #4960, custom Pod stopSignal is allowed: spec.containers[].lifecycle.stopSignal and you can use one of sixty-five additional stop signals to stop the Pod. While behind a feature gate, you can see supportedStopSignalsLinux.

    For example, a user may use SIGQUIT signal to stop a container in the Pod. To do so with kind,

    1. Enable the ContainerStopSignals featuregate in a kind config called kind-cluster-config.yaml
    kind: Cluster
    apiVersion: kind.x-k8s.io/v1alpha4
    featureGates:
      ContainerStopSignals: true
    nodes:
    - role: control-plane
      kubeadmConfigPatches:
      - |
        kind: ClusterConfiguration
        apiServer:
            extraArgs:
              v: "1"
        scheduler:
            extraArgs:
              v: "1"
        controllerManager:
            extraArgs:
              v: "1"
      - |
        kind: InitConfiguration
        nodeRegistration:
          kubeletExtraArgs:
            v: "1"
    - role: worker
      kubeadmConfigPatches:
      - |
        kind: JoinConfiguration
        nodeRegistration:
          kubeletExtraArgs:
            v: "1"
    
    1. Download kind
    mkdir -p dev-cache
    GOBIN=$(PWD)/dev-cache/ go install sigs.k8s.io/kind@v0.29.0
    
    1. Start the kind cluster
    KIND_EXPERIMENTAL_PROVIDER=podman dev-cache/kind create cluster \
    		--image quay.io/powercloud/kind-node:v1.33.1 \
    		--name test \
    		--config kind-cluster-config.yaml\
    		--wait 5m
    
    1. Create a namespace
    apiVersion: v1
    kind: Namespace
    metadata:
      labels:
        kubernetes.io/metadata.name: lifecycle-test
        pod-security.kubernetes.io/audit: restricted
        pod-security.kubernetes.io/audit-version: v1.24
        pod-security.kubernetes.io/enforce: restricted
        pod-security.kubernetes.io/warn: restricted
        pod-security.kubernetes.io/warn-version: v1.24
      name: lifecycle-test
    
    1. Create a Pod
    apiVersion: v1
    kind: Pod
    metadata:
      name: test
      namespace: lifecycle-test
    spec:
      containers:
      - name: test
        command: ["/bin/sh", "-c"]
        args:
          - function cleanup() { echo "CALLED SIGQUIT"; };
            trap cleanup SIGQUIT;
            sleep infinity
        image: registry.access.redhat.com/ubi9/ubi
        lifecycle:
          stopSignal: SIGQUIT
    
    1. Check kubectl describe pod/test -n lifecycle-test

    You’ve seen how this feature functions with Kubernetes and can take advantage of ContainerStopSignals in your environment.

    References

    1. Tracker: Kubernetes Enhancement – Container Stop Signals #4960 issue 30051
    2. KEP-4960: Container Stop Signals
    3. Kubernetes Documentation: Container Lifecycle Hooks
    4. An Introductory Guide to Managing the Kubernetes Pods Lifecycle
    5. Stop Signals
  • Great Job Team: Next-generation DataStage is now supported on IBM Power (ppc64le) with 5.2.0

    The IBM Team announced support for DataStage on IBM Power.

    IBM Cloud Pak for Data now supports the DataStage service on IBM Power servers. This means that you can run your data integration and extract, transform, and load (ETL) workloads directly on IBM Power, just like you already do on x86. With this update, it is easier than ever to use your existing Power infrastructure for modern data and AI projects.

    With the release of IBM DataStage 5.2.0, the DataStage service is now officially supported on IBM Power (ppc64le). This enables clients to run enterprise-grade ETL and data integration workloads on the Power platform, offering flexibility, performance, and consistency across architectures.

    See https://www.ibm.com/docs/en/software-hub/5.2.x?topic=requirements-ppc64le-hardware and https://community.ibm.com/community/user/blogs/yussuf-shaikh/2025/07/15/datastage-5-2-0-is-now-supported-on-ibm-power

  • Using procMount in your Kubernetes Pod

    Recently, I ran across Kubernetes Enhancement Proposal (KEP) 4265 where the authors update the Pod.spec.procMount capability to manage /proc visibility in a Pod’s security context. With this KEP moving to on-by default in v1.29.0, Unmasked disables masking and allows all paths in /proc (not just read-only).

    What this means is the Default procMount prevents containers from accessing sensitive kernel data or interacting with host-level processes. With this enhancement, you can run unprivileged containers inside a container (a container-in-a-container), build container images within a Pod, and use buildah in a Pod.

    The authors said it best in the KEP:

    The /proc filesystem is a virtual interface to kernel data structures. By default, Kubernetes instructs container runtimes to mask or restrict access to certain paths within /proc to prevent accidental or malicious exposure of host information. But this becomes problematic when users want to:

    Here is an example of creating a Pod:

    1. create the project
    oc new-project proc-mount-example
    
    1. Create the Pod
    cat << EOF | oc apply -f -
    apiVersion: v1
    kind: Pod
    metadata:
      name: nested-container-builder
      namespace: proc-mount-example
    spec:
      securityContext:
        runAsUser: 0
      containers:
      - name: builder
        image: registry.access.redhat.com/ubi9/ubi
        securityContext:
          privileged: true
          procMount: Unmasked
        command: ["/bin/sh"]
        args: ["-c", "sleep 3600"]
    EOF
    
    1. Switch to terminal and install podman
    oc rsh nested-container-builder
    dnf install -y podman
    
    1. Change the Shell (so you know when the parent is in focus…)
    export PS1="parent-container# "
    podman run --name abcd --rm -it registry.access.redhat.com/ubi9/ubi sh
    
    1. Run a privileged command again
    parent-container# podman run --name abcd --rm -it registry.access.redhat.com/ubi9/ubi sh
    sh-5.1# dnf install -y podman
    
    1. Now Run another in the nested one, you’ll see a failure in the /dev/net/tun.
    sh-5.1# podman run --name abcd --rm -it registry.access.redhat.com/ubi9/ubi sh
    Trying to pull registry.access.redhat.com/ubi9/ubi:latest...
    Getting image source signatures
    Checking if image destination supports signatures
    Copying blob ea2f7ff2baa2 done   | 
    Copying config 4da9fa8b5a done   | 
    Writing manifest to image destination
    Storing signatures
    ERRO[0018] Preparing container d402a22ebe452597a83b3795639f86e333c1dbb142703737d6d705c6a6f445c7: setting up Pasta: pasta failed with exit code 1:
                    Failed to open() /dev/net/tun: No such file or directory
                                                                            Failed to set up tap device in namespace 
    Error: mounting storage for container d402a22ebe452597a83b3795639f86e333c1dbb142703737d6d705c6a6f445c7: creating overlay mount to /var/lib/containers/storage/overlay/ab589890d52b88e51f1f945b55d07ac465de1cefd2411d8fab33b4d2769c4404/merged, mount_data="lowerdir=/var/lib/containers/storage/overlay/l/K6CXJGRTW32MPWEIMAH4IGCNZ5,upperdir=/var/lib/containers/storage/overlay/ab589890d52b88e51f1f945b55d07ac465de1cefd2411d8fab33b4d2769c4404/diff,workdir=/var/lib/containers/storage/overlay/ab589890d52b88e51f1f945b55d07ac465de1cefd2411d8fab33b4d2769c4404/work,nodev,volatile": using mount program /usr/bin/fuse-overlayfs: unknown argument ignored: lazytime
    fuse: device not found, try 'modprobe fuse' first
    fuse-overlayfs: cannot mount: No such file or directory
    : exit status 1
    

    It has the default access:

    • Default: Maintains the current behavior—masking sensitive /proc paths. If procMount is not specified, it defaults to Default, ensuring backward compatibility and preserving security for most workloads.
    • Unmasked: Bypasses the default masking, giving the container full access to /proc.

    Allowing unmasked access to /proc is a privileged operation. A container with root access and an unmasked /proc could potentially interact with the host system in dangerous ways. This powerful feature should be carefully used.

    Good luck.

    References

  • Configuring KubeletConfig for podsPerCore and maxPods

    I found a useful KubeletConfig.

    In Kubernetes, the podsPerCore parameter, when used in node configuration, specifies the maximum number of pods that can run on a node based on the number of its CPU cores. The default value for podsPerCore is 0, which essentially disables this limit, meaning there’s no constraint imposed based on the number of cores.

    You can check your current settings using:

    $ oc debug node/worker-1
    sh-4.4# chroot /host
    sh-4.4# cat /etc/kubernetes/kubelet.conf | grep maxPods
      "maxPods": 250,
    sh-4.4# cat /etc/kubernetes/kubelet.conf | grep podsPerCore
      "podsPerCore": 10,
    

    In you environment substitute worker-1 for a node name of a ndoe that belongs to your MachineConfigPool.

    You can change your configuration using:

    apiVersion: machineconfiguration.openshift.io/v1
    kind: KubeletConfig
    metadata:
      name: set-max-pods-core 
    spec:
      machineConfigPoolSelector:
        matchLabels:
          pools.operator.machineconfiguration.openshift.io/worker: "" 
      kubeletConfig:
        podsPerCore: 10 
        maxPods: 250 
    

    Reference

    1. podsPerCore – https://docs.redhat.com/en/documentation/openshift_container_platform/4.14/html/postinstallation_configuration/post-install-node-tasks
    2. defaults – https://access.redhat.com/solutions/6998814
  • Introducing the Open Source Edge for IBM Power

    Learn more about what the IBM Power team is doing with OpenSource.

    The IBM Power team is excited to introduce Open Source Edge for IBM Power, an evolution of our previous tool, the Open Source Power Availability Tool (OSPAT) for finding open source packages for Power. While OSPAT provided a snapshot of available packages that are updated periodically, Open Source Edge takes things further by offering more details, more currency, real-time data access, and interactive features to help you explore the open source resources that are available on Power.


    Open Source Edge offers all Power developers and users a central location to keep on top of the latest packages and their versions available for Linux on Power. While designing solutions, it is often critical to compose a solution with a variety of components, and in the software world, those components and their versions change rapidly. Also, with an increasingly turbulent security environment, understanding not just which versions are available, but the composition of those individual components, the individual security profile of each component, and having transparency into the build process and environment becomes increasingly critical.

    Read more at https://open-source-edge.developerfirst.ibm.com/ and https://community.ibm.com/community/user/blogs/hiro-miyamoto/2025/06/26/introducing-the-open-source-edge-for-ibm-power

  • Setting up Local Storage Operator and OpenShift Data Foundation on IBM Power

    Here are my notes from LSO and ODF setup on Power

    Install Local Storage Operator

    1. Log in to the OpenShift Web Console.
    2. Click Operators OperatorHub.
    3. Type local storage in the Filter by keyword
​ box to find the Local Storage Operator from the list of operators and click on it.
    4. Set the following options on the Install Operator page:
      1. Update channel as stable.
      1. Installation Mode as A specific namespace on the cluster.
      1. Installed Namespace as Operator recommended namespace openshift-local-storage.
      1. Approval Strategy as Automatic.
    5. Click Install.

    Setup Labels for Storage Nodes

    1. Add label to the workers which are being used by ODF, this should be the workers where the storage are attached
    oc get nodes -l node-role.kubernetes.io/worker= -oname \
        | xargs -I {} oc label {} cluster.ocs.openshift.io/openshift-storage=
    
    1. Rescan the scsi bus so we get all of the devices added.
    oc get nodes -l node-role.kubernetes.io/worker= -oname \
        | xargs -I {} oc debug {} -- chroot /host rescan-scsi-bus.sh 
    
    1. Build the by-id paths
    oc get nodes -l node-role.kubernetes.io/worker= -oname \
        | xargs -I {} oc debug {} -- chroot /host udevadm trigger --settle
    

    note: don’t worry about Failed to write 'change' to '/sys/devices/vio/4004/uevent', ignoring: No such device events.

    1. Discover the local volumes using LocalVolumeDiscovery
    cat << EOF | oc apply -f -
    apiVersion: local.storage.openshift.io/v1alpha1
    kind: LocalVolumeDiscovery
    metadata:
      name: auto-discover-devices
      namespace: openshift-local-storage
    spec:
      nodeSelector:
        nodeSelectorTerms:
        - matchExpressions:
          - key: cluster.ocs.openshift.io/openshift-storag
            operator: Exists
    EOF
    
    1. Check the LocalVolumeDiscovery is started and Discovering
    oc get LocalVolumeDiscovery -n openshift-local-storage -oyaml auto-discover-devices
    ...
    status:
      conditions:
      - lastTransitionTime: "2025-06-26T01:27:03Z"
        message: successfully running 3 out of 3 discovery daemons
        status: "True"
        type: Available
      observedGeneration: 2
      phase: Discovering
    
    1. Now that it’s ready, we’re going to find the disks:
    # oc get LocalVolumeDiscoveryResult -n openshift-local-storage -ojson | jq -r '.items[].status.discoveredDevices[] | select(.status.state == "Available" and .type == "disk").path' | sort -u
    /dev/sde
    /dev/sdf
    /dev/sdg
    /dev/sdh
    
    1. Create the Local Volume
    cat << EOF | oc apply -f -
    apiVersion: local.storage.openshift.io/v1
    kind: LocalVolume
    metadata:
      name: localblock
      namespace: openshift-local-storage
    spec:
      logLevel: Normal
      managementState: Managed
      nodeSelector:
        nodeSelectorTerms:
          - matchExpressions:
              - key: cluster.ocs.openshift.io/openshift-storage
                operator: Exists
      storageClassDevices:
        - devicePaths:
            - /dev/sde
            - /dev/sdf
            - /dev/sdg
            - /dev/sdh
          storageClassName: localblock
          volumeMode: Block
    EOF
    
    1. Check the LocalVolume is ready oc get LocalVolume -n openshift-local-storage -oyaml
      status:
        conditions:
        - lastTransitionTime: "2025-06-26T18:40:20Z"
          message: Ready
          status: "True"
          type: Available
        generations:
        - group: apps
          hash: ""
          lastGeneration: 2
          name: diskmaker-manager
          namespace: openshift-local-storage
          resource: DaemonSet
        managementState: Managed
        observedGeneration: 1
        readyReplicas: 0
    

    If ready, we can proceed.

    1. Navigate to ODF Operator.

    2. Click Create StorageSystem. Select localblock.

    You can rpoceed with setup from there.

    Thanks to T K Chasan

  • Kudos to the IBM Power team for enabling Maximo Application Suite on IBM Power.

    Kudos to the IBM Power team for enabling Maximo Application Suite on IBM Power.

    IBM has enabled Maximo Application Suite (MAS) 9.x on IBM Power (ppc64le), installable on Red Hat OpenShift 4.17+, offering a resilient, secure, and sustainable platform for enterprise asset management. MAS streamlines asset lifecycles, enhances reliability, and reduces operational costs. Running MAS on Power delivers 99.9999% availability, robust security, and lower energy consumption compared to competitive systems.

    References

    1. Blog https://community.ibm.com/community/user/blogs/julie-mathew/2025/06/24/enabling-maximo-application-suite-9x-on-ibm-power
    2. Availability of MAS 9.1 on IBM Power – Announcement letter
    3. MAS documentation What’s New in MAS 9.1
  • Expanding Open Source Access: GitHub Actions Now Available for IBM Power, IBM Z and IBM LinuxONE

    Exciting news from IBM… .IBM is bringing GitHub Actions runners to IBM Power, Z, and LinuxONE platforms—streamlining CI/CD for open-source projects across diverse architectures. This milestone empowers developers with seamless cross-platform automation, eliminating the need for multiple CI tools.

    IBM actively collaborating with open-source communities and offering personalized onboarding support. Join us in shaping the future of open development—explore our GitHub repo, contribute, and grow with us! đŸ’»đŸŒ

    For more information reach out at https://community.ibm.com/community/user/blogs/mick-tarsel/2025/06/23/github-actions-power-z