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Specialized hardware and driver enablement
Learn about hardware enablement on OpenShift Container Platform
Abstract
Chapter 1. About specialized hardware and driver enablement
Many applications require specialized hardware or software that depends on kernel modules or drivers. You can use driver containers to load out-of-tree kernel modules on Red Hat Enterprise Linux CoreOS (RHCOS) nodes. To deploy out-of-tree drivers during cluster installation, use the kmods-via-containers
framework. To load drivers or kernel modules on an existing OpenShift Container Platform cluster, OpenShift Container Platform offers several tools:
- The Driver Toolkit is a container image that is a part of every OpenShift Container Platform release. It contains the kernel packages and other common dependencies that are needed to build a driver or kernel module. The Driver Toolkit can be used as a base image for driver container image builds on OpenShift Container Platform.
- The Special Resource Operator (SRO) orchestrates the building and management of driver containers to load kernel modules and drivers on an existing OpenShift or Kubernetes cluster.
- The Node Feature Discovery (NFD) Operator adds node labels for CPU capabilities, kernel version, PCIe device vendor IDs, and more.
Chapter 2. Driver Toolkit
Learn about the Driver Toolkit and how you can use it as a base image for driver containers for enabling special software and hardware devices on Kubernetes.
The Driver Toolkit 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.
2.1. About the Driver Toolkit
Background
The Driver Toolkit is a container image in the OpenShift Container Platform payload used as a base image on which you can build driver containers. The Driver Toolkit image contains the kernel packages commonly required as dependencies to build or install kernel modules, as well as a few tools needed in driver containers. The version of these packages will match the kernel version running on the Red Hat Enterprise Linux CoreOS (RHCOS) nodes in the corresponding OpenShift Container Platform release.
Driver containers are container images used for building and deploying out-of-tree kernel modules and drivers on container operating systems like RHCOS. Kernel modules and drivers are software libraries running with a high level of privilege in the operating system kernel. They extend the kernel functionalities or provide the hardware-specific code required to control new devices. Examples include hardware devices like Field Programmable Gate Arrays (FPGA) or GPUs, and software-defined storage (SDS) solutions, such as Lustre parallel file systems, which require kernel modules on client machines. Driver containers are the first layer of the software stack used to enable these technologies on Kubernetes.
The list of kernel packages in the Driver Toolkit includes the following and their dependencies:
-
kernel-core
-
kernel-devel
-
kernel-headers
-
kernel-modules
-
kernel-modules-extra
In addition, the Driver Toolkit also includes the corresponding real-time kernel packages:
-
kernel-rt-core
-
kernel-rt-devel
-
kernel-rt-modules
-
kernel-rt-modules-extra
The Driver Toolkit also has several tools which are commonly needed to build and install kernel modules, including:
-
elfutils-libelf-devel
-
kmod
-
binutilskabi-dw
-
kernel-abi-whitelists
- dependencies for the above
Purpose
Prior to the Driver Toolkit’s existence, you could install kernel packages in a pod or build config on OpenShift Container Platform using entitled builds or by installing from the kernel RPMs in the hosts machine-os-content
. The Driver Toolkit simplifies the process by removing the entitlement step, and avoids the privileged operation of accessing the machine-os-content in a pod. The Driver Toolkit can also be used by partners who have access to pre-released OpenShift Container Platform versions to prebuild driver-containers for their hardware devices for future OpenShift Container Platform releases.
The Driver Toolkit is also used by the Special Resource Operator (SRO), which is currently available as a community Operator on OperatorHub. SRO supports out-of-tree and third-party kernel drivers and the support software for the underlying operating system. Users can create recipes for SRO to build and deploy a driver container, as well as support software like a device plugin, or metrics. Recipes can include a build config to build a driver container based on the Driver Toolkit, or SRO can deploy a prebuilt driver container.
2.2. Pulling the Driver Toolkit container image
The driver-toolkit
image is available from the Container images section of the Red Hat Ecosystem Catalog and in the OpenShift Container Platform release payload. The image corresponding to the most recent minor release of OpenShift Container Platform will be tagged with the version number in the catalog. The image URL for a specific release can be found using the oc adm
CLI command.
2.2.1. Pulling the Driver Toolkit container image from registry.redhat.io
Instructions for pulling the driver-toolkit
image from registry.redhat.io
with podman or in OpenShift Container Platform can be found on the Red Hat Ecosystem Catalog. The driver-toolkit image for the latest minor release will be tagged with the minor release version on registry.redhat.io for example registry.redhat.io/openshift4/driver-toolkit-rhel8:v4.10
.
2.2.2. Finding the Driver Toolkit image URL in the payload
Prerequisites
- You obtained the image pull secret from the Red Hat OpenShift Cluster Manager.
-
You installed the OpenShift CLI (
oc
).
Procedure
The image URL of the
driver-toolkit
corresponding to a certain release can be extracted from the release image using theoc adm
command:$ oc adm release info 4.10.0 --image-for=driver-toolkit
Example output
quay.io/openshift-release-dev/ocp-v4.0-art-dev@sha256:0fd84aee79606178b6561ac71f8540f404d518ae5deff45f6d6ac8f02636c7f4
- This image can be pulled using a valid pull secret, such as the pull secret required to install OpenShift Container Platform.
$ podman pull --authfile=path/to/pullsecret.json quay.io/openshift-release-dev/ocp-v4.0-art-dev@sha256:<SHA>
2.3. Using the Driver Toolkit
As an example, the Driver Toolkit can be used as the base image for building a very simple kernel module called simple-kmod.
The Driver Toolkit contains the necessary dependencies, openssl
, mokutil
, and keyutils
, needed to sign a kernel module. However, in this example, the simple-kmod kernel module is not signed and therefore cannot be loaded on systems with Secure Boot
enabled.
2.3.1. Build and run the simple-kmod driver container on a cluster
Prerequisites
- You have a running OpenShift Container Platform cluster.
-
You set the Image Registry Operator state to
Managed
for your cluster. -
You installed the OpenShift CLI (
oc
). -
You are logged into the OpenShift CLI as a user with
cluster-admin
privileges.
Procedure
Create a namespace. For example:
$ oc new-project simple-kmod-demo
The YAML defines an
ImageStream
for storing thesimple-kmod
driver container image, and aBuildConfig
for building the container. Save this YAML as0000-buildconfig.yaml.template
.apiVersion: image.openshift.io/v1 kind: ImageStream metadata: labels: app: simple-kmod-driver-container name: simple-kmod-driver-container namespace: simple-kmod-demo spec: {} --- apiVersion: build.openshift.io/v1 kind: BuildConfig metadata: labels: app: simple-kmod-driver-build name: simple-kmod-driver-build namespace: simple-kmod-demo spec: nodeSelector: node-role.kubernetes.io/worker: "" runPolicy: "Serial" triggers: - type: "ConfigChange" - type: "ImageChange" source: git: ref: "master" uri: "https://github.com/openshift-psap/kvc-simple-kmod.git" type: Git dockerfile: | FROM DRIVER_TOOLKIT_IMAGE WORKDIR /build/ # Expecting kmod software version as an input to the build ARG KMODVER # Grab the software from upstream RUN git clone https://github.com/openshift-psap/simple-kmod.git WORKDIR simple-kmod # Build and install the module RUN make all KVER=$(rpm -q --qf "%{VERSION}-%{RELEASE}.%{ARCH}" kernel-core) KMODVER=${KMODVER} \ && make install KVER=$(rpm -q --qf "%{VERSION}-%{RELEASE}.%{ARCH}" kernel-core) KMODVER=${KMODVER} # Add the helper tools WORKDIR /root/kvc-simple-kmod ADD Makefile . ADD simple-kmod-lib.sh . ADD simple-kmod-wrapper.sh . ADD simple-kmod.conf . RUN mkdir -p /usr/lib/kvc/ \ && mkdir -p /etc/kvc/ \ && make install RUN systemctl enable kmods-via-containers@simple-kmod strategy: dockerStrategy: buildArgs: - name: KMODVER value: DEMO output: to: kind: ImageStreamTag name: simple-kmod-driver-container:demo
Substitute the correct driver toolkit image for the OpenShift Container Platform version you are running in place of “DRIVER_TOOLKIT_IMAGE” with the following commands.
$ OCP_VERSION=$(oc get clusterversion/version -ojsonpath={.status.desired.version})
$ DRIVER_TOOLKIT_IMAGE=$(oc adm release info $OCP_VERSION --image-for=driver-toolkit)
$ sed "s#DRIVER_TOOLKIT_IMAGE#${DRIVER_TOOLKIT_IMAGE}#" 0000-buildconfig.yaml.template > 0000-buildconfig.yaml
Create the image stream and build config with
$ oc create -f 0000-buildconfig.yaml
After the builder pod completes successfully, deploy the driver container image as a
DaemonSet
.The driver container must run with the privileged security context in order to load the kernel modules on the host. The following YAML file contains the RBAC rules and the
DaemonSet
for running the driver container. Save this YAML as1000-drivercontainer.yaml
.apiVersion: v1 kind: ServiceAccount metadata: name: simple-kmod-driver-container --- apiVersion: rbac.authorization.k8s.io/v1 kind: Role metadata: name: simple-kmod-driver-container rules: - apiGroups: - security.openshift.io resources: - securitycontextconstraints verbs: - use resourceNames: - privileged --- apiVersion: rbac.authorization.k8s.io/v1 kind: RoleBinding metadata: name: simple-kmod-driver-container roleRef: apiGroup: rbac.authorization.k8s.io kind: Role name: simple-kmod-driver-container subjects: - kind: ServiceAccount name: simple-kmod-driver-container userNames: - system:serviceaccount:simple-kmod-demo:simple-kmod-driver-container --- apiVersion: apps/v1 kind: DaemonSet metadata: name: simple-kmod-driver-container spec: selector: matchLabels: app: simple-kmod-driver-container template: metadata: labels: app: simple-kmod-driver-container spec: serviceAccount: simple-kmod-driver-container serviceAccountName: simple-kmod-driver-container containers: - image: image-registry.openshift-image-registry.svc:5000/simple-kmod-demo/simple-kmod-driver-container:demo name: simple-kmod-driver-container imagePullPolicy: Always command: ["/sbin/init"] lifecycle: preStop: exec: command: ["/bin/sh", "-c", "systemctl stop kmods-via-containers@simple-kmod"] securityContext: privileged: true nodeSelector: node-role.kubernetes.io/worker: ""
Create the RBAC rules and daemon set:
$ oc create -f 1000-drivercontainer.yaml
After the pods are running on the worker nodes, verify that the
simple_kmod
kernel module is loaded successfully on the host machines withlsmod
.Verify that the pods are running:
$ oc get pod -n simple-kmod-demo
Example output
NAME READY STATUS RESTARTS AGE simple-kmod-driver-build-1-build 0/1 Completed 0 6m simple-kmod-driver-container-b22fd 1/1 Running 0 40s simple-kmod-driver-container-jz9vn 1/1 Running 0 40s simple-kmod-driver-container-p45cc 1/1 Running 0 40s
Execute the
lsmod
command in the driver container pod:$ oc exec -it pod/simple-kmod-driver-container-p45cc -- lsmod | grep simple
Example output
simple_procfs_kmod 16384 0 simple_kmod 16384 0
2.4. Additional resources
- For more information about configuring registry storage for your cluster, see Image Registry Operator in OpenShift Container Platform.
Chapter 3. Special Resource Operator
Learn about the Special Resource Operator (SRO) and how you can use it to build and manage driver containers for loading kernel modules and device drivers on nodes in an OpenShift Container Platform cluster.
The Special Resource Operator 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.
3.1. About the Special Resource Operator
The Special Resource Operator (SRO) helps you manage the deployment of kernel modules and drivers on an existing OpenShift Container Platform cluster. The SRO can be used for a case as simple as building and loading a single kernel module, or as complex as deploying the driver, device plugin, and monitoring stack for a hardware accelerator.
For loading kernel modules, the SRO is designed around the use of driver containers. Driver containers are increasingly being used in cloud-native environments, especially when run on pure container operating systems, to deliver hardware drivers to the host. Driver containers extend the kernel stack beyond the out-of-the-box software and hardware features of a specific kernel. Driver containers work on various container-capable Linux distributions. With driver containers, the host operating system stays clean and there is no clash between different library versions or binaries on the host.
3.2. Installing the Special Resource Operator
As a cluster administrator, you can install the Special Resource Operator (SRO) by using the OpenShift CLI or the web console.
3.2.1. Installing the Special Resource Operator by using the CLI
As a cluster administrator, you can install the Special Resource Operator (SRO) by using the OpenShift CLI.
Prerequisites
- You have a running OpenShift Container Platform cluster.
-
You installed the OpenShift CLI (
oc
). -
You are logged into the OpenShift CLI as a user with
cluster-admin
privileges. - You installed the Node Feature Discovery (NFD) Operator.
Procedure
Install the SRO in the
openshift-operators
namespace:Create the following
Subscription
CR and save the YAML in thesro-sub.yaml
file:Example Subscription CR
apiVersion: operators.coreos.com/v1alpha1 kind: Subscription metadata: name: openshift-special-resource-operator namespace: openshift-operators spec: channel: "stable" installPlanApproval: Automatic name: openshift-special-resource-operator source: redhat-operators sourceNamespace: openshift-marketplace
Create the subscription object by running the following command:
$ oc create -f sro-sub.yaml
Switch to the
openshift-operators
project:$ oc project openshift-operators
Verification
To verify that the Operator deployment is successful, run:
$ oc get pods
Example output
NAME READY STATUS RESTARTS AGE nfd-controller-manager-7f4c5f5778-4lvvk 2/2 Running 0 89s special-resource-controller-manager-6dbf7d4f6f-9kl8h 2/2 Running 0 81s
A successful deployment shows a
Running
status.
3.2.2. Installing the Special Resource Operator by using the web console
As a cluster administrator, you can install the Special Resource Operator (SRO) by using the OpenShift Container Platform web console.
Prerequisites
- You installed the Node Feature Discovery (NFD) Operator.
Procedure
- Log in to the OpenShift Container Platform web console.
Install the Special Resource Operator:
- In the OpenShift Container Platform web console, click Operators → OperatorHub.
- Choose Special Resource Operator from the list of available Operators, and then click Install.
- On the Install Operator page, select a specific namespace on the cluster, select the namespace created in the previous section, and then click Install.
Verification
To verify that the Special Resource Operator installed successfully:
- Navigate to the Operators → Installed Operators page.
Ensure that Special Resource Operator is listed in the openshift-operators project with a Status of InstallSucceeded.
NoteDuring installation, an Operator might display a Failed status. If the installation later succeeds with an InstallSucceeded message, you can ignore the Failed message.
If the Operator does not appear as installed, to troubleshoot further:
- Navigate to the Operators → Installed Operators page and inspect the Operator Subscriptions and Install Plans tabs for any failure or errors under Status.
-
Navigate to the Workloads → Pods page and check the logs for pods in the
openshift-operators
project.
NoteThe Node Feature Discovery (NFD) Operator is a dependency of the Special Resource Operator (SRO). If the NFD Operator is not installed before installing the SRO, the Operator Lifecycle Manager will automatically install the NFD Operator. However, the required Node Feature Discovery operand will not be deployed automatically. The Node Feature Discovery Operator documentation provides details about how to deploy NFD by using the NFD Operator.
3.3. Using the Special Resource Operator
The Special Resource Operator (SRO) is used to manage the build and deployment of a driver container. The objects required to build and deploy the container can be defined in a Helm chart.
The example in this section uses the simple-kmod SpecialResource
object to point to a ConfigMap
object that is created to store the Helm charts.
3.3.1. Building and running the simple-kmod SpecialResource by using a config map
In this example, the simple-kmod kernel module shows how the Special Resource Operator (SRO) manages a driver container. The container is defined in the Helm chart templates that are stored in a config map.
Prerequisites
- You have a running OpenShift Container Platform cluster.
-
You set the Image Registry Operator state to
Managed
for your cluster. -
You installed the OpenShift CLI (
oc
). -
You are logged into the OpenShift CLI as a user with
cluster-admin
privileges. - You installed the Node Feature Discovery (NFD) Operator.
- You installed the SRO.
-
You installed the Helm CLI (
helm
).
Procedure
To create a simple-kmod
SpecialResource
object, define an image stream and build config to build the image, and a service account, role, role binding, and daemon set to run the container. The service account, role, and role binding are required to run the daemon set with the privileged security context so that the kernel module can be loaded.Create a
templates
directory, and change into it:$ mkdir -p chart/simple-kmod-0.0.1/templates
$ cd chart/simple-kmod-0.0.1/templates
Save this YAML template for the image stream and build config in the
templates
directory as0000-buildconfig.yaml
:apiVersion: image.openshift.io/v1 kind: ImageStream metadata: labels: app: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} 1 name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} 2 spec: {} --- apiVersion: build.openshift.io/v1 kind: BuildConfig metadata: labels: app: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverBuild}} 3 name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverBuild}} 4 annotations: specialresource.openshift.io/wait: "true" specialresource.openshift.io/driver-container-vendor: simple-kmod specialresource.openshift.io/kernel-affine: "true" spec: nodeSelector: node-role.kubernetes.io/worker: "" runPolicy: "Serial" triggers: - type: "ConfigChange" - type: "ImageChange" source: git: ref: {{.Values.specialresource.spec.driverContainer.source.git.ref}} uri: {{.Values.specialresource.spec.driverContainer.source.git.uri}} type: Git strategy: dockerStrategy: dockerfilePath: Dockerfile.SRO buildArgs: - name: "IMAGE" value: {{ .Values.driverToolkitImage }} {{- range $arg := .Values.buildArgs }} - name: {{ $arg.name }} value: {{ $arg.value }} {{- end }} - name: KVER value: {{ .Values.kernelFullVersion }} output: to: kind: ImageStreamTag name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}}:v{{.Values.kernelFullVersion}} 5
Save the following YAML template for the RBAC resources and daemon set in the
templates
directory as1000-driver-container.yaml
:apiVersion: v1 kind: ServiceAccount metadata: name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} --- apiVersion: rbac.authorization.k8s.io/v1 kind: Role metadata: name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} rules: - apiGroups: - security.openshift.io resources: - securitycontextconstraints verbs: - use resourceNames: - privileged --- apiVersion: rbac.authorization.k8s.io/v1 kind: RoleBinding metadata: name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} roleRef: apiGroup: rbac.authorization.k8s.io kind: Role name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} subjects: - kind: ServiceAccount name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} namespace: {{.Values.specialresource.spec.namespace}} --- apiVersion: apps/v1 kind: DaemonSet metadata: labels: app: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} annotations: specialresource.openshift.io/wait: "true" specialresource.openshift.io/state: "driver-container" specialresource.openshift.io/driver-container-vendor: simple-kmod specialresource.openshift.io/kernel-affine: "true" specialresource.openshift.io/from-configmap: "true" spec: updateStrategy: type: OnDelete selector: matchLabels: app: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} template: metadata: labels: app: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} spec: priorityClassName: system-node-critical serviceAccount: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} serviceAccountName: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} containers: - image: image-registry.openshift-image-registry.svc:5000/{{.Values.specialresource.spec.namespace}}/{{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}}:v{{.Values.kernelFullVersion}} name: {{.Values.specialresource.metadata.name}}-{{.Values.groupName.driverContainer}} imagePullPolicy: Always command: ["/sbin/init"] lifecycle: preStop: exec: command: ["/bin/sh", "-c", "systemctl stop kmods-via-containers@{{.Values.specialresource.metadata.name}}"] securityContext: privileged: true nodeSelector: node-role.kubernetes.io/worker: "" feature.node.kubernetes.io/kernel-version.full: "{{.Values.KernelFullVersion}}"
Change into the
chart/simple-kmod-0.0.1
directory:$ cd ..
Save the following YAML for the chart as
Chart.yaml
in thechart/simple-kmod-0.0.1
directory:apiVersion: v2 name: simple-kmod description: Simple kmod will deploy a simple kmod driver-container icon: https://avatars.githubusercontent.com/u/55542927 type: application version: 0.0.1 appVersion: 1.0.0
From the
chart
directory, create the chart using thehelm package
command:$ helm package simple-kmod-0.0.1/
Example output
Successfully packaged chart and saved it to: /data/<username>/git/<github_username>/special-resource-operator/yaml-for-docs/chart/simple-kmod-0.0.1/simple-kmod-0.0.1.tgz
Create a config map to store the chart files:
Create a directory for the config map files:
$ mkdir cm
Copy the Helm chart into the
cm
directory:$ cp simple-kmod-0.0.1.tgz cm/simple-kmod-0.0.1.tgz
Create an index file specifying the Helm repo that contains the Helm chart:
$ helm repo index cm --url=cm://simple-kmod/simple-kmod-chart
Create a namespace for the objects defined in the Helm chart:
$ oc create namespace simple-kmod
Create the config map object:
$ oc create cm simple-kmod-chart --from-file=cm/index.yaml --from-file=cm/simple-kmod-0.0.1.tgz -n simple-kmod
Use the following
SpecialResource
manifest to deploy the simple-kmod object using the Helm chart that you created in the config map. Save this YAML assimple-kmod-configmap.yaml
:apiVersion: sro.openshift.io/v1beta1 kind: SpecialResource metadata: name: simple-kmod spec: #debug: true 1 namespace: simple-kmod chart: name: simple-kmod version: 0.0.1 repository: name: example url: cm://simple-kmod/simple-kmod-chart 2 set: kind: Values apiVersion: sro.openshift.io/v1beta1 kmodNames: ["simple-kmod", "simple-procfs-kmod"] buildArgs: - name: "KMODVER" value: "SRO" driverContainer: source: git: ref: "master" uri: "https://github.com/openshift-psap/kvc-simple-kmod.git"
From a command line, create the
SpecialResource
file:$ oc create -f simple-kmod-configmap.yaml
To remove the simple-kmod kernel module from the node, delete the simple-kmod SpecialResource
API object using the oc delete
command. The kernel module is unloaded when the driver container pod is deleted.
Verification
The simple-kmod
resources are deployed in the simple-kmod
namespace as specified in the object manifest. After a short time, the build pod for the simple-kmod
driver container starts running. The build completes after a few minutes, and then the driver container pods start running.
Use
oc get pods
command to display the status of the build pods:$ oc get pods -n simple-kmod
Example output
NAME READY STATUS RESTARTS AGE simple-kmod-driver-build-12813789169ac0ee-1-build 0/1 Completed 0 7m12s simple-kmod-driver-container-12813789169ac0ee-mjsnh 1/1 Running 0 8m2s simple-kmod-driver-container-12813789169ac0ee-qtkff 1/1 Running 0 8m2s
Use the
oc logs
command, along with the build pod name obtained from theoc get pods
command above, to display the logs of the simple-kmod driver container image build:$ oc logs pod/simple-kmod-driver-build-12813789169ac0ee-1-build -n simple-kmod
To verify that the simple-kmod kernel modules are loaded, execute the
lsmod
command in one of the driver container pods that was returned from theoc get pods
command above:$ oc exec -n simple-kmod -it pod/simple-kmod-driver-container-12813789169ac0ee-mjsnh -- lsmod | grep simple
Example output
simple_procfs_kmod 16384 0 simple_kmod 16384 0
The sro_kind_completed_info
SRO Prometheus metric provides information about the status of the different objects being deployed, which can be useful to troubleshoot SRO CR installations. The SRO also provides other types of metrics that you can use to watch the health of your environment.
3.4. Prometheus Special Resource Operator metrics
The Special Resource Operator (SRO) exposes the following Prometheus metrics through the metrics
service:
Metric Name | Description |
---|---|
|
Returns the nodes that are running pods created by a SRO custom resource (CR). This metric is available for |
|
Represents whether a |
|
Represents whether the SRO has finished processing a CR successfully (value |
| Returns the number of SRO CRs in the cluster, regardless of their state. |
3.5. Additional resources
- For information about restoring the Image Registry Operator state before using the Special Resource Operator, see Image registry removed during installation.
- For details about installing the NFD Operator see Node Feature Discovery (NFD) Operator.
Chapter 4. Node Feature Discovery Operator
Learn about the Node Feature Discovery (NFD) Operator and how you can use it to expose node-level information by orchestrating Node Feature Discovery, a Kubernetes add-on for detecting hardware features and system configuration.
4.1. About the Node Feature Discovery Operator
The Node Feature Discovery Operator (NFD) manages the detection of hardware features and configuration in an OpenShift Container Platform cluster by labeling the nodes with hardware-specific information. NFD labels the host with node-specific attributes, such as PCI cards, kernel, operating system version, and so on.
The NFD Operator can be found on the Operator Hub by searching for “Node Feature Discovery”.
4.2. Installing the Node Feature Discovery Operator
The Node Feature Discovery (NFD) Operator orchestrates all resources needed to run the NFD daemon set. As a cluster administrator, you can install the NFD Operator by using the OpenShift Container Platform CLI or the web console.
4.2.1. Installing the NFD Operator using the CLI
As a cluster administrator, you can install the NFD Operator using the CLI.
Prerequisites
- An OpenShift Container Platform cluster
-
Install the OpenShift CLI (
oc
). -
Log in as a user with
cluster-admin
privileges.
Procedure
Create a namespace for the NFD Operator.
Create the following
Namespace
custom resource (CR) that defines theopenshift-nfd
namespace, and then save the YAML in thenfd-namespace.yaml
file:apiVersion: v1 kind: Namespace metadata: name: openshift-nfd
Create the namespace by running the following command:
$ oc create -f nfd-namespace.yaml
Install the NFD Operator in the namespace you created in the previous step by creating the following objects:
Create the following
OperatorGroup
CR and save the YAML in thenfd-operatorgroup.yaml
file:apiVersion: operators.coreos.com/v1 kind: OperatorGroup metadata: generateName: openshift-nfd- name: openshift-nfd namespace: openshift-nfd spec: targetNamespaces: - openshift-nfd
Create the
OperatorGroup
CR by running the following command:$ oc create -f nfd-operatorgroup.yaml
Create the following
Subscription
CR and save the YAML in thenfd-sub.yaml
file:Example Subscription
apiVersion: operators.coreos.com/v1alpha1 kind: Subscription metadata: name: nfd namespace: openshift-nfd spec: channel: "stable" installPlanApproval: Automatic name: nfd source: redhat-operators sourceNamespace: openshift-marketplace
Create the subscription object by running the following command:
$ oc create -f nfd-sub.yaml
Change to the
openshift-nfd
project:$ oc project openshift-nfd
Verification
To verify that the Operator deployment is successful, run:
$ oc get pods
Example output
NAME READY STATUS RESTARTS AGE nfd-controller-manager-7f86ccfb58-vgr4x 2/2 Running 0 10m
A successful deployment shows a
Running
status.
4.2.2. Installing the NFD Operator using the web console
As a cluster administrator, you can install the NFD Operator using the web console.
Procedure
- In the OpenShift Container Platform web console, click Operators → OperatorHub.
- Choose Node Feature Discovery from the list of available Operators, and then click Install.
- On the Install Operator page, select A specific namespace on the cluster, and then click Install. You do not need to create a namespace because it is created for you.
Verification
To verify that the NFD Operator installed successfully:
- Navigate to the Operators → Installed Operators page.
Ensure that Node Feature Discovery is listed in the openshift-nfd project with a Status of InstallSucceeded.
NoteDuring installation an Operator might display a Failed status. If the installation later succeeds with an InstallSucceeded message, you can ignore the Failed message.
Troubleshooting
If the Operator does not appear as installed, troubleshoot further:
- Navigate to the Operators → Installed Operators page and inspect the Operator Subscriptions and Install Plans tabs for any failure or errors under Status.
-
Navigate to the Workloads → Pods page and check the logs for pods in the
openshift-nfd
project.
4.3. Using the Node Feature Discovery Operator
The Node Feature Discovery (NFD) Operator orchestrates all resources needed to run the Node-Feature-Discovery daemon set by watching for a NodeFeatureDiscovery
CR. Based on the NodeFeatureDiscovery
CR, the Operator will create the operand (NFD) components in the desired namespace. You can edit the CR to choose another namespace
, image
, imagePullPolicy
, and nfd-worker-conf
, among other options.
As a cluster administrator, you can create a NodeFeatureDiscovery
instance using the OpenShift Container Platform CLI or the web console.
4.3.1. Create a NodeFeatureDiscovery instance using the CLI
As a cluster administrator, you can create a NodeFeatureDiscovery
CR instance using the CLI.
Prerequisites
- An OpenShift Container Platform cluster
-
Install the OpenShift CLI (
oc
). -
Log in as a user with
cluster-admin
privileges. - Install the NFD Operator.
Procedure
Create the following
NodeFeatureDiscovery
Custom Resource (CR), and then save the YAML in theNodeFeatureDiscovery.yaml
file:apiVersion: nfd.openshift.io/v1 kind: NodeFeatureDiscovery metadata: name: nfd-instance namespace: openshift-nfd spec: instance: "" # instance is empty by default topologyupdater: false # False by default operand: image: registry.redhat.io/openshift4/ose-node-feature-discovery:v4.10 imagePullPolicy: Always workerConfig: configData: | core: # labelWhiteList: # noPublish: false sleepInterval: 60s # sources: [all] # klog: # addDirHeader: false # alsologtostderr: false # logBacktraceAt: # logtostderr: true # skipHeaders: false # stderrthreshold: 2 # v: 0 # vmodule: ## NOTE: the following options are not dynamically run-time configurable ## and require a nfd-worker restart to take effect after being changed # logDir: # logFile: # logFileMaxSize: 1800 # skipLogHeaders: false sources: cpu: cpuid: # NOTE: whitelist has priority over blacklist attributeBlacklist: - "BMI1" - "BMI2" - "CLMUL" - "CMOV" - "CX16" - "ERMS" - "F16C" - "HTT" - "LZCNT" - "MMX" - "MMXEXT" - "NX" - "POPCNT" - "RDRAND" - "RDSEED" - "RDTSCP" - "SGX" - "SSE" - "SSE2" - "SSE3" - "SSE4.1" - "SSE4.2" - "SSSE3" attributeWhitelist: kernel: kconfigFile: "/path/to/kconfig" configOpts: - "NO_HZ" - "X86" - "DMI" pci: deviceClassWhitelist: - "0200" - "03" - "12" deviceLabelFields: - "class" customConfig: configData: | - name: "more.kernel.features" matchOn: - loadedKMod: ["example_kmod3"]
For more details on how to customize NFD workers, refer to the Configuration file reference of nfd-worker.
Create the
NodeFeatureDiscovery
CR instance by running the following command:$ oc create -f NodeFeatureDiscovery.yaml
Verification
To verify that the instance is created, run:
$ oc get pods
Example output
NAME READY STATUS RESTARTS AGE nfd-controller-manager-7f86ccfb58-vgr4x 2/2 Running 0 11m nfd-master-hcn64 1/1 Running 0 60s nfd-master-lnnxx 1/1 Running 0 60s nfd-master-mp6hr 1/1 Running 0 60s nfd-worker-vgcz9 1/1 Running 0 60s nfd-worker-xqbws 1/1 Running 0 60s
A successful deployment shows a
Running
status.
4.3.2. Create a NodeFeatureDiscovery CR using the web console
Procedure
- Navigate to the Operators → Installed Operators page.
- Find Node Feature Discovery and see a box under Provided APIs.
- Click Create instance.
-
Edit the values of the
NodeFeatureDiscovery
CR. - Click Create.
4.4. Configuring the Node Feature Discovery Operator
4.4.1. core
The core
section contains common configuration settings that are not specific to any particular feature source.
core.sleepInterval
core.sleepInterval
specifies the interval between consecutive passes of feature detection or re-detection, and thus also the interval between node re-labeling. A non-positive value implies infinite sleep interval; no re-detection or re-labeling is done.
This value is overridden by the deprecated --sleep-interval
command line flag, if specified.
Example usage
core:
sleepInterval: 60s 1
The default value is 60s
.
core.sources
core.sources
specifies the list of enabled feature sources. A special value all
enables all feature sources.
This value is overridden by the deprecated --sources
command line flag, if specified.
Default: [all]
Example usage
core: sources: - system - custom
core.labelWhiteList
core.labelWhiteList
specifies a regular expression for filtering feature labels based on the label name. Non-matching labels are not published.
The regular expression is only matched against the basename part of the label, the part of the name after '/'. The label prefix, or namespace, is omitted.
This value is overridden by the deprecated --label-whitelist
command line flag, if specified.
Default: null
Example usage
core: labelWhiteList: '^cpu-cpuid'
core.noPublish
Setting core.noPublish
to true
disables all communication with the nfd-master
. It is effectively a dry run flag; nfd-worker
runs feature detection normally, but no labeling requests are sent to nfd-master
.
This value is overridden by the --no-publish
command line flag, if specified.
Example:
Example usage
core:
noPublish: true 1
The default value is false
.
core.klog
The following options specify the logger configuration, most of which can be dynamically adjusted at run-time.
The logger options can also be specified using command line flags, which take precedence over any corresponding config file options.
core.klog.addDirHeader
If set to true
, core.klog.addDirHeader
adds the file directory to the header of the log messages.
Default: false
Run-time configurable: yes
core.klog.alsologtostderr
Log to standard error as well as files.
Default: false
Run-time configurable: yes
core.klog.logBacktraceAt
When logging hits line file:N, emit a stack trace.
Default: empty
Run-time configurable: yes
core.klog.logDir
If non-empty, write log files in this directory.
Default: empty
Run-time configurable: no
core.klog.logFile
If not empty, use this log file.
Default: empty
Run-time configurable: no
core.klog.logFileMaxSize
core.klog.logFileMaxSize
defines the maximum size a log file can grow to. Unit is megabytes. If the value is 0
, the maximum file size is unlimited.
Default: 1800
Run-time configurable: no
core.klog.logtostderr
Log to standard error instead of files
Default: true
Run-time configurable: yes
core.klog.skipHeaders
If core.klog.skipHeaders
is set to true
, avoid header prefixes in the log messages.
Default: false
Run-time configurable: yes
core.klog.skipLogHeaders
If core.klog.skipLogHeaders
is set to true
, avoid headers when opening log files.
Default: false
Run-time configurable: no
core.klog.stderrthreshold
Logs at or above this threshold go to stderr.
Default: 2
Run-time configurable: yes
core.klog.v
core.klog.v
is the number for the log level verbosity.
Default: 0
Run-time configurable: yes
core.klog.vmodule
core.klog.vmodule
is a comma-separated list of pattern=N
settings for file-filtered logging.
Default: empty
Run-time configurable: yes
4.4.2. sources
The sources
section contains feature source specific configuration parameters.
sources.cpu.cpuid.attributeBlacklist
Prevent publishing cpuid
features listed in this option.
This value is overridden by sources.cpu.cpuid.attributeWhitelist
, if specified.
Default: [BMI1, BMI2, CLMUL, CMOV, CX16, ERMS, F16C, HTT, LZCNT, MMX, MMXEXT, NX, POPCNT, RDRAND, RDSEED, RDTSCP, SGX, SGXLC, SSE, SSE2, SSE3, SSE4.1, SSE4.2, SSSE3]
Example usage
sources: cpu: cpuid: attributeBlacklist: [MMX, MMXEXT]
sources.cpu.cpuid.attributeWhitelist
Only publish the cpuid
features listed in this option.
sources.cpu.cpuid.attributeWhitelist
takes precedence over sources.cpu.cpuid.attributeBlacklist
.
Default: empty
Example usage
sources: cpu: cpuid: attributeWhitelist: [AVX512BW, AVX512CD, AVX512DQ, AVX512F, AVX512VL]
sources.kernel.kconfigFile
sources.kernel.kconfigFile
is the path of the kernel config file. If empty, NFD runs a search in the well-known standard locations.
Default: empty
Example usage
sources: kernel: kconfigFile: "/path/to/kconfig"
sources.kernel.configOpts
sources.kernel.configOpts
represents kernel configuration options to publish as feature labels.
Default: [NO_HZ, NO_HZ_IDLE, NO_HZ_FULL, PREEMPT]
Example usage
sources: kernel: configOpts: [NO_HZ, X86, DMI]
sources.pci.deviceClassWhitelist
sources.pci.deviceClassWhitelist
is a list of PCI device class IDs for which to publish a label. It can be specified as a main class only (for example, 03
) or full class-subclass combination (for example 0300
). The former implies that all subclasses are accepted. The format of the labels can be further configured with deviceLabelFields
.
Default: ["03", "0b40", "12"]
Example usage
sources: pci: deviceClassWhitelist: ["0200", "03"]
sources.pci.deviceLabelFields
sources.pci.deviceLabelFields
is the set of PCI ID fields to use when constructing the name of the feature label. Valid fields are class
, vendor
, device
, subsystem_vendor
and subsystem_device
.
Default: [class, vendor]
Example usage
sources: pci: deviceLabelFields: [class, vendor, device]
With the example config above, NFD would publish labels such as feature.node.kubernetes.io/pci-<class-id>_<vendor-id>_<device-id>.present=true
sources.usb.deviceClassWhitelist
sources.usb.deviceClassWhitelist
is a list of USB device class IDs for which to publish a feature label. The format of the labels can be further configured with deviceLabelFields
.
Default: ["0e", "ef", "fe", "ff"]
Example usage
sources: usb: deviceClassWhitelist: ["ef", "ff"]
sources.usb.deviceLabelFields
sources.usb.deviceLabelFields
is the set of USB ID fields from which to compose the name of the feature label. Valid fields are class
, vendor
, and device
.
Default: [class, vendor, device]
Example usage
sources: pci: deviceLabelFields: [class, vendor]
With the example config above, NFD would publish labels like: feature.node.kubernetes.io/usb-<class-id>_<vendor-id>.present=true
.
sources.custom
sources.custom
is the list of rules to process in the custom feature source to create user-specific labels.
Default: empty
Example usage
source: custom: - name: "my.custom.feature" matchOn: - loadedKMod: ["e1000e"] - pciId: class: ["0200"] vendor: ["8086"]
4.5. Using the NFD Topology Updater
The Node Feature Discovery (NFD) Topology Updater is a daemon responsible for examining allocated resources on a worker node. It accounts for resources that are available to be allocated to new pod on a per-zone basis, where a zone can be a Non-Uniform Memory Access (NUMA) node. The NFD Topology Updater communicates the information to nfd-master, which creates a NodeResourceTopology
custom resource (CR) corresponding to all of the worker nodes in the cluster. One instance of the NFD Topology Updater runs on each node of the cluster.
To enable the Topology Updater workers in NFD, set the topologyupdater
variable to true
in the NodeFeatureDiscovery
CR, as described in the section Using the Node Feature Discovery Operator.
4.5.1. NodeResourceTopology CR
When run with NFD Topology Updater, NFD creates custom resource instances corresponding to the node resource hardware topology, such as:
apiVersion: topology.node.k8s.io/v1alpha1 kind: NodeResourceTopology metadata: name: node1 topologyPolicies: ["SingleNUMANodeContainerLevel"] zones: - name: node-0 type: Node resources: - name: cpu capacity: 20 allocatable: 16 available: 10 - name: vendor/nic1 capacity: 3 allocatable: 3 available: 3 - name: node-1 type: Node resources: - name: cpu capacity: 30 allocatable: 30 available: 15 - name: vendor/nic2 capacity: 6 allocatable: 6 available: 6 - name: node-2 type: Node resources: - name: cpu capacity: 30 allocatable: 30 available: 15 - name: vendor/nic1 capacity: 3 allocatable: 3 available: 3
4.5.2. NFD Topology Updater command line flags
To view available command line flags, run the nfd-topology-updater -help
command. For example, in a podman container, run the following command:
$ podman run gcr.io/k8s-staging-nfd/node-feature-discovery:master nfd-topology-updater -help
-ca-file
The -ca-file
flag is one of the three flags, together with the -cert-file
and `-key-file`flags, that controls the mutual TLS authentication on the NFD Topology Updater. This flag specifies the TLS root certificate that is used for verifying the authenticity of nfd-master.
Default: empty
The -ca-file
flag must be specified together with the -cert-file
and -key-file
flags.
Example
$ nfd-topology-updater -ca-file=/opt/nfd/ca.crt -cert-file=/opt/nfd/updater.crt -key-file=/opt/nfd/updater.key
-cert-file
The -cert-file
flag is one of the three flags, together with the -ca-file
and -key-file flags
, that controls mutual TLS authentication on the NFD Topology Updater. This flag specifies the TLS certificate presented for authenticating outgoing requests.
Default: empty
The -cert-file
flag must be specified together with the -ca-file
and -key-file
flags.
Example
$ nfd-topology-updater -cert-file=/opt/nfd/updater.crt -key-file=/opt/nfd/updater.key -ca-file=/opt/nfd/ca.crt
-h, -help
Print usage and exit.
-key-file
The -key-file
flag is one of the three flags, together with the -ca-file
and -cert-file
flags, that controls the mutual TLS authentication on the NFD Topology Updater. This flag specifies the private key corresponding the given certificate file, or -cert-file
, that is used for authenticating outgoing requests.
Default: empty
The -key-file
flag must be specified together with the -ca-file
and -cert-file
flags.
Example
$ nfd-topology-updater -key-file=/opt/nfd/updater.key -cert-file=/opt/nfd/updater.crt -ca-file=/opt/nfd/ca.crt
-kubelet-config-file
The -kubelet-config-file
specifies the path to the Kubelet’s configuration file.
Default: /host-var/lib/kubelet/config.yaml
Example
$ nfd-topology-updater -kubelet-config-file=/var/lib/kubelet/config.yaml
-no-publish
The -no-publish
flag disables all communication with the nfd-master, making it a dry run flag for nfd-topology-updater. NFD Topology Updater runs resource hardware topology detection normally, but no CR requests are sent to nfd-master.
Default: false
Example
$ nfd-topology-updater -no-publish
4.5.2.1. -oneshot
The -oneshot
flag causes the NFD Topology Updater to exit after one pass of resource hardware topology detection.
Default: false
Example
$ nfd-topology-updater -oneshot -no-publish
-podresources-socket
The -podresources-socket
flag specifies the path to the Unix socket where kubelet exports a gRPC service to enable discovery of in-use CPUs and devices, and to provide metadata for them.
Default: /host-var/liblib/kubelet/pod-resources/kubelet.sock
Example
$ nfd-topology-updater -podresources-socket=/var/lib/kubelet/pod-resources/kubelet.sock
-server
The -server
flag specifies the address of the nfd-master endpoint to connect to.
Default: localhost:8080
Example
$ nfd-topology-updater -server=nfd-master.nfd.svc.cluster.local:443
-server-name-override
The -server-name-override
flag specifies the common name (CN) which to expect from the nfd-master TLS certificate. This flag is mostly intended for development and debugging purposes.
Default: empty
Example
$ nfd-topology-updater -server-name-override=localhost
-sleep-interval
The -sleep-interval
flag specifies the interval between resource hardware topology re-examination and custom resource updates. A non-positive value implies infinite sleep interval and no re-detection is done.
Default: 60s
Example
$ nfd-topology-updater -sleep-interval=1h
-version
Print version and exit.
-watch-namespace
The -watch-namespace
flag specifies the namespace to ensure that resource hardware topology examination only happens for the pods running in the specified namespace. Pods that are not running in the specified namespace are not considered during resource accounting. This is particularly useful for testing and debugging purposes. A *
value means that all of the pods across all namespaces are considered during the accounting process.
Default: *
Example
$ nfd-topology-updater -watch-namespace=rte
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